Metabolic Bone Disease and Clinically Related Disorders, Third Edition

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Metabolic Bone Disease Third Edition

This Page Intentionally Left Blank

Metabolic Bone Disease and C1inically Re1at ed Disorders

Edited by

LOUISV. AVIOLI Washington University Medical Center St. Louis, Missouri

STEPHEN M. KRANE Harvard Medical School Massachusetts General Hospital Boston, Massachusetts

ACADEMIC PRESS San Diego

London

Boston

New York

Sydney

Tokyo

Toronto

This book is printed on acid-flee paper.

Copyright 9 1998, 1990, 1977 by ACADEMIC PRESS All Rights Reserved. No part of this publication may be reproduced or transmitted in any form or by any means, electronic or mechanical, including photocopy, recording, or any information storage and retrieval system, without permission in writing from the publisher. Academic Press a division of Harcourt Brace & Company 525 B Street, Suite 1900, San Diego, California 92101-4495, USA http ://www. apnet.com Academic Press Limited 24-28 Oval Road, London NW 1 7DX, UK http ://www.hbuk.co.uk/ap/ Library of Congress Card Catalog Number: 97-074394 International Standard Book Number: 0-12-068700-3

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Contents

Contributors Preface

xi

The Nature of the Mineral Phase in Bone" Biological and Clinical Implications

CHAPTER 2

xv

MELVIN J. GLIMCHER

II. III.

CHAPTER 1

Embryology and Cellular Biology of Bone

LAWRENCE G. RAISZ AND GIDEON A. RODAN

2 I~ Embryonic Skeletal Development II. Limb Development and Pattern Regulation 2 III. Bone Morphogenetic Proteins and Development 4 IV. The Role of Parathyroid Hormone-Related Peptide in Development 4 V~ Fibroblast Growth Factors and Skeletal Development 4 5 VI. Cells of the Osteoblast Lineage 9 VII. The Osteoclast VIII. Cell-Cell Interaction in Bone Remodeling 12 Colony-Stimulating Factors and Bone 13 IX. X. The Transforming Growth Factor [3 Family 13 XI. Other Growth Factors (FGE VEGE PDGF, and HGF) 15 16 XII. Cell-Matrix Interactions References 17

IV. V.

Biological Functions of the Mineral Phase 23 The General Nature of the Mineral Phase in Bone and the Changes That Occur with Time 28 Postulated Phases Other Than Apatite as the Initial Solid Ca-P Mineral Phase Deposited in Bone 29 Crystal Size and Shape 32 Recent Studies of the Structure of Bone Apatites and the Applications of These Data to Clinical and Experimental Abnormalities and Diseases of Bone 36 References 46

CHAPTER 3 Parathyroid Hormone and Parathyroid Hormone-Related Peptide in Calcium Homeostasis, Bone Metabolism, and Bone Development: The Proteins, Their Genes, and Receptors JOHN T. PoTrs, JR. AND HARALD JUPPNER

I. Introduction: Regulators of Mineral Ion Homeostasis 52 53 II. Parathyroid Hormone 67 III. Parathyroid Hormone-Related Peptide IV. Receptors That Mediate Analogous and Distinct Molecular Actions of PTH and PTHrP 73 V~ Summary: Overall Biological Roles of PTH and PTHrP and Their Cloned Receptors 82 References 83

vi

Contents

CHAPTER 4

CHAPTER 7

Calcitonin

Z. J. MARTIN, D. M. FINDLAY, J. M. MOSELEY, AND P. M. SEXTON

Io Nature of Calcitonin

II. III. IV. V. VI. VII. VIII.

96

Chemistry 98 Biosynthesis 99 Secretion and Metabolism 101 Actions of Calcitonin 102 Calcitonin Receptor 108 Calcitonin in Clinical Medicine Summary 113 References 114

Disorders of Phosphate Homeostasis

KEITH HRUSKAAND ANANDARUPGUPTA I. Phosphate Homeostasis II. Hypophosphatemia III. Hyperphosphatemia References 230

CHAPTER 8

113

207 216 226

Bone Biopsies: A Modern Approach

MARIE=CLAUDE MONIER-FAUGERE, M. CHRIS LANGUB, AND HARTMUT H. MALLUCHE

Io Function and Structure of the Skeleton

CHAPTER 5 Vitamin D Metabolism and Biological Function MICHAEL F. HOLICK AND JOHN S. ADAMS

I. II. III. IV. Wo

VI. VII. VIII. IX. X.

XI. XlI.

History of Vitamin D 124 Photobiology of Vitamin D3 127 Intestinal Absorption of Vitamin D 131 Metabolism of Vitamin D to 25-Hydroxyvitamin D 132 Metabolism of 25-Hydroxyvitamin D to 1,25-Hydroxyvitamin D 135 Altemative Metabolism of 25-Hydroxyvitamin D and 1,25-Dihydroxyvitamin D 139 Metabolism of Vitamin D2 141 Biological Actions of 1,25(OH)2D 142 Biological Actions of 1,25(OH)2D in Tissues Regulating Calcium Balance 144 Actions of Vitamin D Metabolites and Analogs in Nonclassical Target Tissues 145 Assays for Vitamin D and Its Metabolites 148 Conclusion 155 References 156

237

II. III. IV. V. VI.

Bone Biopsies 244 247 Mineralized Bone Histology Techniques Molecular Bone Histology 249 Evaluation of Bone 251 Indications For and Information Derived from Bone Biopsies 256 VII. Information Derived from Molecular Histology 267 References 269

CHAPTER 9

Noninvasive Assessment of Bone

MARTIN UFFMANN, THOMAS e. FUERST, MICHAEL JERGAS, AND HARRY K. GENANT

I. II. III. IV.

Introduction 275 Radiation-Based Assessment of Bone 277 Assessment of Bone without Radiation 292 Standardization and Quality Assurance in Dual X-Ray Absorptiometry 298 V. Clinical Applications 301 References 303

CHAPTER 10 Biochemical Markers of Bone Turnover CLAUS CHRISTIANSEN, CHRISTIAN HASSAGER, AND BENTE JUEL RIIS

CHAPTER 6 Pathophysiology of Calcium, Phosphate, and Magnesium Absorption ROBERTO CIVITELLI, KONSTANTINOS ZIAMBARAS, AND RATTANA LEELAwATTANA

I. Calcium II. Phosphate III. Magnesium References

165 183 190 195

I. Introduction 313 II. Bone Matrix, Minerals, and Cells 314 III. Bone Tumover: Modeling and Remodeling 314 IV. Biochemistry of Bone Turnover 315 V. Markers of Bone Formation 316 VI. Markers of Bone Resorption 318 VII. 24-Hour Variation in Markers of Bone Tumover 321

vii

Contents VIII. Potential Use of Biochemical Markers IX. Conclusions 324 References 324

321

CHAPTER 14

EDUARDO SLATOPOLSKY AND JAMES A. DELMEZ Io

CHAPTER 11

Osteomalacia and Related Disorders

IV. Wo

VI. VII. VIII.

Introduction

443

II. Secondary Hyperparathyroidism and Osteitis Fibrosa 443 III. Osteomalacia

451

IV. Bone Histology

A. M. PARFITT

II. III.

Renal Osteodystrophy

Bone Mineralization and the Mechanisms of Osteoid Accumulation 328 Manifestations of Osteomalacia 338 Etiological Classification and Pathogenesis of Osteomalacia 349 Osteomalacia Resulting from Abnormal Vitamin D Metabolism 354 Vitamin D and Age-Related Osteoporosis 360 Osteomalacia Resulting from Abnormal Phosphate Metabolism 361 Osteomalacia with Normal Vitamin D and Phosphate Metabolism 367 Therapeutic Intervention in Osteomalacia 370 References 374

451

V. Clinical and Biochemical Features of Altered Divalent-Ion Metabolism 453 VI. Radiographic Features of Renal Osteodystrophy 455 VII. Extraskeletal Calcifications

456

VIII. Therapeutic Approach to Renal Osteodystrophy 456 References

460

CHAPTER 15 Surgical Treatment for Hyperparathyroidism GERARD M. DOHERTY AND SAMUEL A. WELLS, JR. I. History of Surgery for Hyperparathyroidism

465

II. Primary Hyperparathyroidism: Preoperative Evaluation 466

CHAPTER 12

Osteoporosis Pathogenesis and Therapy

MICHAEL KLEEREKOPER AND LOUIS V. AVIOLI

I. II. III. IV. V.

Definition 387 Physiological Osteoporosis Diagnostic Aids 390 Classification 395 Management 397 References 406

389

III. Primary Hyperparathyroidism: Conduct of the Operation 469 IV. Primary Hyperparathyroidism: Management of Patients with Persistent or Recurrent Hyperparathyroidism 472 V. Operative Management of Patients with Parathyroid Carcinoma 475 VI. Operative Management of Patients with Renal Osteodystrophy 475 VII. Postoperative Management References

CHAPTER 13 Primary Hyperparathyroidism JOHN T. POTTS, JR. I. Introduction 411 II. Etiology and Pathology 412 III. Clinical Features: Changing Clinical Presentation 418 IV. Diagnosis and Differential Diagnosis 426 V. Medical Management of Hypercalcemia and Hyperparathyroidism 431 VI. Summary 435 References 435

475

477

CHAPTER 16 Familial Benign Hypocalciuric Hypercalcemia and Other Syndromes of Altered Responsiveness to Extracellular Calcium EDWARD M. BROWN, MEI B AI, AND MARTIN POLLAK I. Introduction

479

II. Syndromes of Extracellular Calcium Resistance 480 III. Autosomal Dominant HypocalcemiamA Syndrome of Increased Responsiveness of Target Tissues to Ca o2+ 493

viii

Contents

IV. Summary and Conclusions References 496

496

CHAPTER 20

Sarcoidosis and Related Disorders NORMAN H. BELL

CHAPTER 17 Hypoparathyroidism and Pseudohypoparathyroidism MICHAEL A. LEVINE

I. II. III. IV. V. VI. VII. VIII.

Introduction 501 Pathophysiology of Hypocalcemia Signs and Symptoms of Hypocalcemia Specific Causes of Functional Hypoparathyroidism 505 Pseudohypoparathyroidism 510 Diagnosis 519 Treatment 521 Conclusion 522 References 522

I. Granulomatous and Infectious Diseases II. Lymphoma and Solid Tumors 613 III. Miscellaneous Diseases 614 References 615

607

502 504

CHAPTER 21 Bone Disease in Rheumatological Disorders STEVEN R. GOLDRING AND RICHARD P. POLISSON

I. II. III. IV. V.

CHAPTER 18 Bone Disease in Hyperthyroidism

Introduction 621 Rheumatoid Arthritis 622 626 Seronegative Spondyloarthropathies 628 Systemic Lupus Erythematosus 628 Juvenile Rheumatoid Arthritis References 633

DOUGLAS S. R o s s

531 I~ Grades of Hyperthyroidism 532 II. Overt Hyperthyroidism III. Endogenous Subclinical Hyperthyroidism 534 IV. Exogenous Subclinical Hyperthyroidism: Thyroid Hormone Suppressive Therapy 535 539 V~ Thyroid Hormone Replacement Therapy Treatment and Prevention of Thyroid HormoneVI. Mediated Bone Loss 539 541 VII. Conclusions References 541

CHAPTER 22 Hypercalcemia of Malignancy GREGORY R. MUNDY

I. Pathophysiology 637 II. Clinical Features 642 III. Treatment 643 References 646

CHAPTER 23 CHAPTER 19

I~ Introduction

545 Incidence and Epidemiology 545 Histopathology 547 Focal Manifestations 554 Local Complications 562 Metabolic Aspects of Paget's Disease Systemic Complications and Associated Diseases 578 581 VIII. Drug Treatment IX. Surgery 592 593 X. Etiology References 596

II. III. IV. V.

I~ Historical Aspects

II. III. IV. V. VI. VII.

DAVID W. ROWE AND JAY R. SHAPIRO

Paget's Disease of Bone

FREDERICK R. SINGER AND STEPHEN M. KRANE

Osteogenesis Imperfecta

VI. 569 VII. VIII. IX.

651 Perspective: Clinical Introduction 651 Clinical Features 657 Pathophysiology 663 Collagen Biochemistry and Bone Cell Biology as Related to OI 666 Biochemical and Molecular Tools for the Identification of Mutations in Patients with OI 670 Molecular Pathophysiology of OI 673 Therapy 678 Future Diagnostic and Therapeutic Directions 681 References 683

Contents

in

CHAPTER 24 Skeletal Disorders Characterized by Osteosclerosis or Hyperostosis MICHAEL P. WHYTE

I~ Introduction

II. III. IV. V. VI. VII. VIII. IX. X. XI. XII. XIII. XIV. XV. XVI. XVII. XVIII.

697 Osteopetrosis 698 Carbonic Anhydrase II Deficiency 703 Pycnodysostosis 705 Osteomesopyknosis 707 Progressive Diaphyseal Dysplasia (CamuratiEngelmann Disease) 707 Endosteal Hyperostosis 710 Osteopoikilosis 713 Osteopathia Striata 715 Melorheostosis 716 Mixed Sclerosing Bone Dystrophy 718 Fibrodysplasia Ossificans Progressiva 719 Axial Osteomalacia 722 Fibrogenesis Imperfecta Ossium 726 Fluorosis 728 Pachydermoperiostosis 729 Hepatitis C-Associated Osteosclerosis 731 Other Disorders 731 References 732

CHAPTER 25 Kidney Stones: Pathogenesis, Diagnosis, and Therapy CHARLES Y. C. PAK I. Introduction 739 740 II. Hypercalciuria 747 III. Hyperuricosuria 748 IV. Hyperoxaluria 750 V. Hypocitraturia 752 VI. Gouty Diathesis 753 VII. Cystinuria VIII. Infection with Urea-Splitting Organisms 755 IX. Conservative Management References 756

CHAPTER 26

755

Metabolic Bone Disease in Children

FRANCIS H. GLORIEUX, GERARD KARSENTY, AND RAJESH V. THAKKER

I. Introduction 759 II. Skeletal Development III. Rickets and Osteomalacia References 777

Index

785

759 764


Contributors

Numbers in parentheses indicate the pages on which the authors' contributions begin.

Gerard M. Doherty (465) Section of Endocrine and Oncologic Surgery, Washington University School of Medicine, St. Louis, Missouri 63110 D. M. Findlay (95) St. Vincent's Institute of Medical Research and The University of Melbourne Department of Medicine, St. Vincent's Hospital, Fitzroy, Victoria 3065, Australia Thomas P. Fuerst (275) Osteoporosis & Arthritis Group, Department of Radiology, University of California, San Francisco, San Francisco, California 94143 Harry K. Genant (275) Osteoporosis & Arthritis Research Group, Department of Radiology, University of California, San Francisco, San Francisco, California 94143 Melvin J. Glirneher (23) Laboratory for the Study of Skeletal Disorders and Rehabilitation, Department of Orthopaedic Surgery, Harvard Medical School, Children's Hospital, Boston, Massachusetts 02115 Francis H. Glorieux (759) Genetics Unit, Shriners Hospital for Children and Departments of Surgery and Pediatrics, McGill University, Montr6al, Qu6bec H3G 1A6, Canada Steven R. Goldring (621) Department of Medicine Harvard Medical School, Medical Services (Arthritis Unit), Massachusetts General Hospital, Boston, Massachusetts 02215; Department of Medicine, Beth Israel Deaconess Medical Center, Boston, Massachusetts 02115; and New England Baptist Bone and Joint Institute, Boston, Massachusetts 02215

John S. Adams (123) University of California, Los Angeles, Los Angeles, California 90048 Louis V. Avioli (387) Division of Bone and Mineral Diseases, Washington University School of Medicine, St. Louis, Missouri 63110 Mei Bai (479) Endocrine-Hypertension Division, Department of Medicine, Brigham and Women's Hospital, and Harvard Medical School, Boston, Massachusetts 02115 Norman H. Bell (607) Departments of Medicine and Pharmacology, Medical University of South Carolina and Ralph H. Johnson Department of Veterans Affairs Medical Center, Charleston, South Carolina 29401 Edward M. Brown (479) Endocrine-Hypertension Division, Department of Medicine, Brigham and Women's Hospital, and Harvard Medical School, Boston, Massachusetts 02115 Claus Christiansen (313) Center for Clinical and Basic Research, Ballerup, Denmark Roberto Civitelli (165) Division of Bone and Mineral Diseases, Washington University School of Medicine, St. Louis, Missouri 63110 James A. Delmez (443) The Renal Division and Chromalloy American Kidney Center, Washington University School of Medicine, St. Louis, Missouri 63110

xi

xii

Anandarup Gupta (207) Renal Division, Washington University School of Medicine, St. Louis, Missouri 63110 Christian Hassager (313) Center for Clinical and Basic Research, Ballerup, Denmark Michael F. Holick (123) Boston University Medical Center, Boston, Massachusetts 02118 Keith Hruska (207) Renal Division, Washington University School of Medicine, St. Louis, Missouri 63110 Michael Jergas (275) Department of Radiology, St. Josef Hospital, Ruhr-University of Bochum, Bochum, Germany Harald Jiippner (51) Endocrine Unit, Massachusetts General Hospital, Harvard Medical School, Boston, Massachusetts 02114 Gerard Karsenty (759) Molecular Genetics, The University of Texas, MD Anderson Cancer Center, Houston, Texas 77030 Michael Kleerekoper (387) Department of Medicine, Wayne State University, Detroit, Michigan 48201 Stephen M. Krane (545) Department of Medicine, Harvard Medical School and Arthritis Unit, Massachusetts General Hospital, Boston, Massachusetts 02114 M. Chris Langub (237) Division of Nephrology, Bone and Mineral Metabolism, Department of Internal Medicine, University of Kentucky, Lexington, Kentucky 40536 Rattana Leelawattana (165) Division of Bone and Mineral Diseases, Washington University School of Medicine, St. Louis, Missouri 63110 Michael A. Levine (501) Division of Endocrinology and Metabolism, Department of Medicine, The Johns Hopkins University School of Medicine, Baltimore, Maryland 21205 Hartmut H. Malluche (237) Division of Nephrology, Bone and Mineral Metabolism, Department of Internal Medicine, University of Kentucky, Lexington, Kentucky 40536 T. J. Martin (95) St. Vincent's Institute of Medical Research and The University of Melbourne Department of Medicine, St. Vincent's Hospital, Fitzroy, Victoria 3065, Australia

Contributors

Marie-Claude Monier-Faugere (237) Division of Nephrology, Bone and Mineral Metabolism, Department of Internal Medicine, University of Kentucky, Lexington, Kentucky 40536 J. M. Moseley (95) St. Vincent's Institute of Medical Research and The University of Melbourne Department of Medicine, St. Vincent's Hospital, Fitzroy, Victoria 3065, Australia Gregory R. Mundy (637) University of Texas Health Science Center, San Antonio, Texas 78284 Charles Y. C. Pak (739) University of Texas Southwestern Medical Center at Dallas, Dallas, Texas 75235 A. M. Parfitt (327) Division of Endocrinology and Center for Osteoporosis and Metabolic Bone Disease, University of Arkansas for Medical Sciences, Little Rock, Arkansas 72205 Richard P. Polisson (621) Department of Medicine Harvard Medical School, Medical Services (Arthritis Unit), Massachusetts General Hospital, Boston, Massachusetts 02215; Department of Medicine, Beth-Israel Deaconess Medical Center, Boston, Massachusetts 02215; and New England Baptist Bone and Joint Institute, Boston, Massachusetts 02215 Martin Pollak (479) Renal Division, Department of Medicine, Brigham and Women's Hospital, and Harvard Medical School, Boston, Massachusetts 02115 John T. Potts Jr. (51, 411) Endocrine Unit, Massachusetts General Hospital, Harvard Medical School, Boston, Massachusetts 02114 Lawrence G. Raisz (1) Division of Endocrinology and Metabolism, University of Connecticut Health Center, Farmington, Connecticut 06030 Bente Juel Riis (313) Center for Clinical and Basic Research, Ballerup, Denmark Gideon A. Rodon (1) Department of Bone Biology/Osteoporosis, Merck Sharp & Dohme Research Labs, West Point, Pennsylvania 19486 Douglas S. Ross (531) Thyroid Unit, Massachusetts General Hospital, Boston, Massachusetts 02114 David W. Rowe (651) Department of Pediatrics, University of Connecticut Health Center, Farmington, Connecticut 06032

Contributors

P. M. Sexton (95) St. Vincent's Institute of Medical Research and The University of Melbourne Department of Medicine, St. Vincent's Hospital, Fitzroy, Victoria 3065, Australia Jay R. Shapiro (651) Department of Medicine, Johns Hopkins Medical School, Baltimore, Maryland 21224 Frederick R. Singer (545) John Wayne Cancer Institute, Santa Monica, California 90404 Eduardo Slatopolsky (443) The Renal Division and Chromalloy American Kidney Center, Washington University School of Medicine, St. Louis, Missouri 63110 Rajesh V. Thakker (759) MRC Molecular Endocrinology Group, Royal Postgraduate Medical School, Hammersmith Hospital, London W12 0NN, United Kingdom

xiii

Martin Uffmann (275) Osteoporosis & Arthritis Research Group, Department of Radiology, University of California, San Francisco, San Francisco, California 94143 Samuel A. Wells, Jr. (465) Department of Surgery, Washington University School of Medicine, St. Louis, Missouri 63110 Michael P. Whyte (697) Divisions of Bone and Mineral Diseases, Washington University School of Medicine, St. Louis, Missouri 63110; and Metabolic Research Unit, Shriners Hospital for Children, St. Louis, Missouri 63131 Konstantinos Ziambaras (165) Division of Bone and Mineral Diseases, Washington University School of Medicine, St. Louis, Missouri 63110


Preface

and monocytes, whereas when c-fos is knocked out, monocyte-macrophages are produced but osteoclasts are not. Since the knockout of c-src surprisingly resulted only in osteopetrosis with osteoclasts present in bone but functionally defective with no ruffled border, we await the elucidation of the precise role of c-src in osteoclast function. Knowledge of how osteoclasts utilize their unique, specialized cellular machinery to resorb bone, dramatically demonstrated in several laboratories, will be useful not only in understanding bone resorption but also in developing unique therapeutic agents to modulate bone resorption in patients. In this regard, we should also recognize that a peptidomimetic antagonist of the osteoclast OLv[33integrin has already been used to inhibit bone resorption in animal models of osteoporosis. We have also acquired an abundance of knowledge about osteoblasts, how they differentiate from precursor mesenchymal stem cells, and how several hormones, cytokines, and growth factors control their biological activities. The most striking set of observations appeared in the May 30, 1997, issue of Cell, too late to be discussed in this book. These observations relate to a transcription factor CBFA1, a member of the core-binding factor family. Deletion of the gene in mice results in a total lack of bone with retention of the partially calcified cartilagenous skeleton. Furthermore, most of the features of the human syndrome of cleidocranial dysplasia can be accounted for by mutations in the CBFA1 gene. These findings provide new insights into mechanisms of differentiation of cells of the osteogenic lineage. There has been extensive research in an effort to define those factors that control skeletal differentiation. The bone morphogenic proteins (BMPs) were first cloned in 1988, but their importance in skeletal biology in particular and biology in general has only recently

Twenty years have now elapsed since the first edition of Metabolic Bone Disease and Clinically Related Disorders was published in two volumes, and 7 years have elapsed since the second edition was published in a single volume. Since the appearance of the last volume there has been enormous progress in our field, much of which can be ascribed to the development of the powerful technologies of molecular genetics. As a result of these recent advancements we are much more cognizant of bone biology and the pathophysiology of several human skeletal disorders. New animal models that serve to increase our understanding of bone diseases have also been developed. The availability of new diagnostic tools enables us to measure bone mass with a precision that permits the identification of patients with osteoporosis who are at risk for fracture and the assessment of the efficacy of treatment. Furthermore, more specific serum and urinary assays have been developed to measure markers of bone formation and resorption that improve our ability to evaluate pathological alterations in bone turnover and to measure responses to therapy. Finally, new therapeutic agents with proven efficacy in retarding bone loss of osteoporotic individuals and decreasing fracture incidence have been introduced. With respect to the basic biology of bone, a great deal of knowledge about the genesis and differentiation of bone cell populations has been accumulated. The stages of differentiation of osteoclasts from pluripotent stem cells have been better defined, based primarily on findings from studies of mutations in mice and rats and the capacity to introduce null mutations into the mouse genome. It has been established that the stem cell precursor of osteoclasts is also the precursor of monocyte-macrophages and that these developmental pathways are well defined. A null mutation in the gene for spi-1, a transcription factor, results in depletion of osteoclasts XV

xvi been appreciated. New members of the BMP family of secreted signaling molecules are constantly being discovered. Spontaneous mutations in mice such as the short ear mouse have been shown to be due to mutations in BMPs. Similarly, the GDF genes related to BMPs have also been the sites of spontaneous mutations in mice as well as in humans. The extraordinary phenotypes of mouse and human brachypodism, ascribable to mutations in GDF5 genes, are excellent examples. Many other genes have now been found to play major roles in skeletal development. These include the basic helixloop-helix family of transcription factors, the hox genes, the pax genes, fibroblast growth factors, hedgehogs, wnt, and noggin. Elucidation of the roles of many of these important genes in regulating skeletal development in mammals has been possible because of important observations in Drosophila and chicks. Identification of the mutation in the FGF receptor-3 in achondroplasia, the most common form of human dwarfism, has been a major triumph. From observations of human diseases such as osteogenesis imperfecta, we recognized that mutations, even those involving single base substitutions, could have profound effects on skeletal development and remodeling. Since publication of the second edition of Metablic Bone Disease and Clinically Related Disorders in 1990, mutations in other genes that encode proteins of the extracellular matrix have also been identified in humans and animals. These include mutations in the genes that encode the fibrillar components of the cartilagenous matrix such as type II, type IX, and type XI collagens and result in abnormal structure of cartilage on articular surfaces and epiphyses as well as defects in metaphyseal bone remodeling. Another example is the recent identification of mutations in the cartilage oligomeric protein (COMP) in pseudoachondroplasia. We have been the beneficiaries of knowledge derived from manipulation of the mouse genome. Examples include the introduction of null mutations in the BMP-7 gene. The results of introducing a null mutation in the osteocalcin gene were indeed surprising, since deletion of the gene resulted in a skeleton that not only was normally mineralized but also contained an excessive amount of bone. Thus, the absence of osteocalcin results in increased bone formation without affecting bone resorption. On the other hand, deletion of the matrix GLA protein had no effect on the skeleton but did result in extraordinary ectopic calcification of blood vessel walls. Our understanding of the pathophysiology of human disorders has also advanced considerably since the last edition of this volume. Much of this progress can be ascribed to the identification of receptors for the major calcitropic hormones, parathyroid hormone (PTH) and calcitonin, and the characterization of the calcium sensor

Preface initially identified on the surface of parathyroid cells. A new PTH-2 receptor, which, unlike the PTH/PTHrP receptor, interacts almost exclusively with PTH and not with PTHrP, has been characterized. We now recognize that a mutation in the PTH/PTHrP receptor gene is responsible for the phenotype (hypercalcemia, low circulating PTH, abnormal skeletal growth) in patients with Jansen metaphyseal chondrodysplasia and results from constitutive activation of the receptor. Similarly, mutations in the calcium sensor can now explain the clinical abnormalities in some patients with so-called familial benign (hypocalciuric) hypercalcemia. What a surprise to discover that the mechanism of X-linked hypophosphatemic tickets in osteomalacia is due not to a mutation in the phosphate transporter gene (not on the X chromosome) but to a mutation in another gene (i.e., PEX) located on the X chromosome. All evidence indicates that PEX is a membrane-bound zinc metalloprotease and possibly an ectoenzyme. We are aware of several tantalizing observations on the potential genetic contribution to the most common disease that we deal with, osteoporosis. The significance of polymorphisms in the vitamin D receptor gene and other genes is yet to be established, but it is likely that the genetic underpinning of osteoporosis will soon be clarified. The alternative strategies being developed to decipher genetic determinants of osteoporosis (e.g., those that employ inbred strains of mice) provide much greater statistical power to assess the relationships between genes and complex phenotypes than do twin studies or association studies. Although the use of dual-energy X-ray absorptiometry is now commonplace, there was only brief mention of this technique in our last edition. Much attention has been directed toward the use of various bone markers in evaluating patients with osteoporosis and identifying individuals at risk and following therapy. These include measurement of free pyridinolines, measurement of the pyridinoline-derived crosslinks, and development of convenient assays for bone-specific alkaline phosphatase. It is likely that even more useful markers will soon be developed. For our patients, newly available therapies, such as potent bisphosphonates, are strikingly effective in preventing bone loss and even result in a gain of bone mass. It is clear that the prevention of bone loss by these agents results in decreased propensity to fracture, and their availability should prove to be invaluable in the longterm management of patients with osteoporosis. Calcitonins are still being used, and the availability of preparations that can be given by routes other than injection certainly represents an advance. Nevertheless, the administration of calcitonin preparations in disorders such as osteoporosis and Paget's disease will probably be largely replaced by potent oral and parenteral bisphos-

Preface phonates. Evaluation of the therapeutic efficacy and potential pitfalls of estrogen therapy in osteoporosis continues. Most recently, the development of selective estrogen receptor modulators (SERMs), stimulated in part by the observations on the use of tomoxifen in patients with breast cancer, now offers new promise in preventing bone loss in postmenopausal women without concerns of developing breast cancer or uterine cancer. In fact, the SERM may also prove effective in minimizing cardiovascular morbidity and mortality because of their estrogen-like effects on circulating lipids and other determinants of cardiovascular risk. In this third edition of Metabolic Bone Disease, we continue our attempts to present a correlated view of metabolic bone diseases and related topics emphasizing the relationships among genetics, molecular biology, biochemistry, pathology, and clinical manifestations. We have once again attempted to accomplish this in a single volume and recognize that the approach, emphasis, and style differ in each chapter. We have, however, selected major contributors to our field as authors of these chapters while still recognizing these differences in style and approach. Whereas the previous edition contained 24 chapters, the new edition has 26 chapters. The contents

xvii of the majority of the chapters have been updated either by the same authors or by others who graciously agreed to accept the challenge. Although the chapters "Metabolic Bone Disease in Patients with Gaucher's Disease" and "The Diagnosis and Management of Bone Tumors" that appeared in the previous edition of Metabolic Bone Disease and Clinically Related Disorders have been deleted from this new edition, new chapters including the "Surgical Treatment for Hyperparathyroidism," "Familial Benign Hypocalciuric Hypercalcemia and Other Syndromes of Altered Responsiveness to Extracellular Calcium," and "Hypoparathyroidism and Pseudohypoparathyroidism" have been added. We have been fortunate that Academic Press, which published our first edition in 1977, has reassumed the role as publisher for this third edition. Finally, we are particularly grateful to Dr. Jasna Markovac and her staff for their patience, professionalism, and support, which they generously expressed during the preparation of this volume. LOUIS V. AVIOLI STEPHEN M. KRANE


2HAPTER

Embryology and Cellular Biology of Bone LAWRENCE G.

RAISZ

GIDEON m. RODAN

Division of Endocrinology and Metabolism, University of Connecticut Health Center, Farmington, Connecticut 06030 Department of Bone Biology/Osteoporosis, Merck Sharp & Dohme Research Labs, West Point, Pennsylvania 19486

I. II. III. IV.

Embryonic Skeletal Development Limb Development and Pattern Regulation Bone Morphogenetic Proteins and Development The Role of Parathyroid Hormone-Related Peptide in Development V. Fibroblast Growth Factors and Skeletal Development VI. Cells of the Osteoblast Lineage

Evolution of the mineralized skeleton was a key factor in the emergence of terrestrial vertebrates. Furthermore, mobility on dry land and erect posture, which freed the upper limbs for other tasks, are both skeletal functions that were crucial for human evolution. Normal skeletal functions are one of the foundations of health and well-being, and their compromise, caused for example by osteoporosis or osteoarthritis, is a major and sometimes early manifestation of aging. The development of the skeleton as an organ system that can successfully fulfill its three functionsmmechanical support of soft tissues, ion homeostasis, and housing of hemopoiesisminvolves complex and finely tuned processes, which start early in embryonic life and continue into adulthood. Spontaneous and experimentally targeted gene mutations that affect the skeleton have provided increasing molecular insights into these processes. Following is a very brief description of skeletal development and illustrative examples of specific genes that control it. METABOLIC BONE DISEASE

VII. VIII. IX. X. XI. XII.

The Osteoclast Cell-Cell Interaction in Bone Remodeling Colony-Stimulating Factors and Bone The Transforming Growth Factor 13 Family Other Growth Factors (FGF, VEGF, PDGF, and HGF) Cell-Matrix Interactions References

Four types of overlapping phenomena are involved in development: (1) cellular migration; (2) cellular differentiation, whereby cells start making the specific proteins, carbohydrates, and lipids that characterize cartilage or bone; (3) patterning, the organization in space of various cells, which give the organ the intended shape; and (4) acquisition of the ability for feedback responses, which integrate the organ into the organism, as exemplified by bone remodeling. As stated, these are interconnected and each is governed by a large number of molecular signals. Current knowledge for the molecular basis of the regulation of skeletal development is derived in part from the effects of disruption (loss of function) or overexpression (gain of function) of specific genes, which cause genetic abnormalities in humans or animals. These can occur spontaneously or are experimentally induced. The products of these genes do not act in isolation but interact closely with multiple other factors, each contributing either intracellularly or extracellularly in an Copyright 9 1998 by Academic Press. All fights of reproduction in any form reserved.

2 autocrine, paracrine, or matricrine manner to differentiation or pattern formation. At the anatomical level, we recognize two skeletal tissues: cartilage and bone. Each of them can be divided into subtypes with various cellular composition, dependent on location and function (see below).

I. E M B R Y O N I C SKELETAL D E V E L O P M E N T Bones are derived from three embryonic structures: the neural crest, which through the branchial arches gives rise to the craniofacial bones; the sclerotomes, which give rise to the axial skeleton; and the lateral plate mesoderm, which gives rise to the appendicular skeleton (limbs). The axial (skull, vertebrae, fibs, and pelvis) and appendicular (limbs) skeleton starts embryologically with a cartilage model in which ossification centers appear. These are characterized by vascular invasion, differentiation of cells into osteoblasts, the bone-forming cells, and deposition of bone matrix and its mineralization. At the periphery of the cartilage model, a similar sequence of events forms a bony envelope that becomes the periosteum. At the two ends of the bones, the cartilage specializes to form a growth zone called the epiphyseal growth plate, where at least three types of cartilage cells can be identified: (1) proliferating cells; (2) differentiated chondrocytes, which elaborate the cartilagespecific matrix; and (3) hypertrophic chondrocytes, which are larger and are surrounded by mineralizing matrix. The composition of the cartilage matrix changes during chondrocyte maturation, the major cartilage collagen is type 2, a homotrimer. A characteristic collagen of hypertrophic chondrocytes is type 10. Mutations in cartilage collagens have been associated with various diseases (e.g., type 2 mutations with chondrodysplasias, type 10 with spondylometaphyseal dysplasia and metaphyseal chondrodysplasia, and type 11 with spondyloepiphyseal dysplasia ([Stickler's syndrome]). 1Proteoglycans are also prominent components of the cartilage matrix and sulfation defects can also produce malformations (e.g., diastrophic dysplasia). 2 Mutations in the aggrecan gene were shown to cause cartilage matrix deficiency. 3 The mineralized cartilage matrix serves as a scaffold for the deposition of bone, following vascular invasion, and is subsequently removed (resorbed) by large cells, chondroclasts, which are morphologically similar to the bone-resorbing cells, the osteoclasts. The area where bone replaces cartilage is called the primary spongiosa and the process is endochondral ossification. Farther towards the center of the bone where no cartilage remnants


are left, we find in the interior of the bone spicules in a honeycomb arrangement, forming the spongiosa or cancellous bone. This area and the rest of the interior of the bone is filled with bone marrow, where the constituents of the hemopoietic system are made. Two processes are involved in providing the shape and architecture of bone: modeling and remodeling. Modeling is the formation of bone on surfaces where bone had not been previously removed by osteoclastic resorption as seen, for example, in periosteal bone growth. In remodeling, which accounts for most but not all bone formation in adult life, bone is deposited on surfaces from which bone was previously removed by osteoclasts. This form of bone formation does not involve cartilage replacement. The craniofacial bones are also formed by a process which does not involve cartilage replacement, called membranous bone formation. Within membranous structures that precede the skull and facial bones, following cellular condensation, cells differentiate into osteoblasts and start the bone-forming process. These bones will also develop a periosteal structure surrounding cancellous bone and some bone marrow. To summarize this section, the neural crest gives rise to the bones of the face and the skull through de novo (membranous) bone formation. The sclerotomes and the lateral plate mesoderm give rise to the vertebral column and limbs, respectively, through endochondral bone formation, where cartilage is replaced by bone and bone growth occurs at the epiphyseal growth plate. Molecular aspects of the control of these processes are discussed below.

II. LIMB D E V E L O P M E N T AND PATTERN REGULATION A feature observed by experimental embryologists long ago was that cells acquire a sense of their position in the organism or in an organ relative to the cephalocaudal, anteroposterior, or lateral orientation (left vs. right) and dorsoventral. Recently, genetic studies, especially in Drosophila, started unraveling the molecular basis for pattern formation, which strongly impacts on skeletal development. Relatively high up in the regulatory hierarchy are the mammalian Hox genes, which correspond to the Drosophila HOM-C homeotic genes. 4 These genes appeared early in evolution and increased in number through gene duplication. In mammals, there are 38 Hox genes organized in four clusters, Hoxa to Hoxd, up to 13 genes per cluster ( 1 - 1 3 paralogs, not each cluster has all 13 paralogs). Each Hox protein has a 6 0 - a m i n o acid "homeo

CHAPTER 1 Embryology and Cellular Biology of Bone domain," which binds with high affinity the A/T-rich elements in DNA, thus acting as transcription regulators, most likely of multiple genes. In each cluster, the Hox genes are expressed sequentially from the 3' to the 5' end of the chromosome, as a function of the progress of development, the 3' genes being expressed in the anterior structures and the 5' genes in the posterior ones. This relationship named by Lewis "co-linearity" is believed to be one of the mechanisms for the control of the anteroposterior axis of the embryo. Indeed, it was found in the mouse that loss of function mutations in Hoxc-8, Hoxb-4, Hoxa-2, Hoxd-3, or Hoxd-13 cause anterior transformations in the axial skeleton, recognized by changes in vertebral morphology. Loss of function mutations in Hoxa-1 and Hoxa-3, for example, produce effects on cranial and mesenchymal neural crest and cause changes in hind-brain segmentation. 4 Mutations in Hoxd-13 were shown to cause synpolydactyly (fusion of digits). 5 0 v e r e x p r e s s i o n of Hoxd-6 produces an extra digit in the chick wing. 6 Mice lacking Hoxa-11 and H o x d - l l completely lack the radius and ulna. 7 The upstream regulators of Hox gene expression and the downstream genes they control started to be identified only recently. The mixed lineage leukemia (MLL) gene was shown to be required for the expression of Hoxa-7 and Hoxc-9, and its absence produced homeotic transformations of the axial skeleton and sternal malformations. 8 Inactivation of the CDX1 gene by homologous recombination abolished the expression of the Hoxa-7 gene. 9 Krox-20 is an up-regulator of Hoxb-2. 4 Retinoic acid (RA) has long been known to produce changes in limb or palate development, and RA response elements have been identified in the Hoxb-1 gene. ~~ In limb development, sonic hedgehog also seems to be upstream of Hox genes (see below). Another upstream gene shown to regulate Hox expression is bmi-1, the absence of which was shown to cause posterior transformation of the axial skeleton, whereas its overexpression produces the opposite phenotype. ~1 Other homeobox genes, which are not part of the Hox clusters, were shown to have effects on skeletal development. Mutation of an msx-2 gene is associated with the Boston-type craniosynostosis. ~2 MHox deletion was shown to produce in mice shortening of the skull, face, and l i m b s . 13'14 Recent experimental studies on limb development have offered significant insight into the mechanism of pattern formation and development and the factors involved. It has been known for almost 20 years that in the chick limb bud there are groups of cells that control limb development, the zone of polarizing activity (ZPA) and the apical ectodermal ridge (AER). ~5 If ZPA, which is on the posterior edge of the limb bud, is transplanted

3 to the anterior edge of the other limb bud, it produces a mirror image set of digits. Retinoic acid, endogenously present on the posterior side, can duplicate this phenomenon when applied at the anterior site, instead of the ZPA. 16 Various genes have been shown by in situ hybridization to be expressed in the limb bud. Genes of the Hoxd complex are centered on the posterior side, genes of the Hoxa complex in a proximodistal orientation, and other homeobox-containing genes are found in the distal tip of the limb bud. The sonic hedgehog gene (SHH) co-localizes the ZPA and is also capable of producing duplications. 17 The bone morphogenetic proteins (BMP) 2 and 4 of the transforming growth factor [3 (TGF-f3) family also co-localize with ZPA, as well as fibroblast growth factor 4 (FGF-4) and FGF-8, which are found in the posterior half of the apical ectodermal ridge, and can replace its function. 18-2~ The data support the following model for the interaction between these various factors, based on their endogenous expression and the effect of their exogenous application to chick limb buds. FGF-8 initiates limb bud outgrowth and participates in the activation of SHH expression and its maintenance in the lateral plate mesoderm. SHH induces the production of FGF-4. 21 FGF-4 is the endogenous signal that controls limb outgrowth and maintains the ZPA. SHH, which can mimic ZPA activity is the ZPA signal and it also up-regulates FGF expression, establishing a positive-feedback loop. 22 The growth factor wnt-7a, which is expressed in the dorsal ectoderm, stimulates SHH expression. 23 Thus, the major factors which constitute the ZPA are FGF-4, FGF-8, wnt-7A, and SHH. The Engrailed-1 gene is a homeodomain-containing transcription factor expressed in the ventral limb ectoderm. Its absence results in dorsal transformation, probably as a result of lack of suppression of Wnt-7a expression. 24 SHH 25 also induces the local expression of BMP-2, TGF-[3, and Hoxd-13, the mutation of which produces anterior transformation of the sacral vertebra. BMP-2 and BMP-4, acting either as homodimers or heterodimers, are found in the polarizing region and can be induced by retinoic acid, but BMP-2 beads do not cause digit duplication. ~5 It has been suggested that the BMPs participate in epithelial mesenchymal interaction. BMP-4 has also been implicated in determining the dorsal ventral axis of the early embryo, probably via the transcription factor Mix.1. 26 Thus, experimental development biology studies in chick limb bud have suggested ways in which FGFs, BMPs, Hox and hedgehog molecules, as well as retinoic acid, may interact to control tissue patterning. As already stated, based on mutations, each of these families of molecules have been implicated in skeletal development. Further examples follow.

4

III. BONE MORPHOGENETIC PROTEINS AND DEVELOPMENT BMPs were discovered based on their ability to induce bone when injected subcutaneously or intramuscularly. BMPs are expressed during development in skeletal and other tissues 27 and two spontaneous genetic defects in mice were shown to be associated with B MP mutations. The short ear mutation (SE) is characterized by changes in the shape of the sternum and the external ear cartilage. These defects are found to be caused by a mutation in BMP-5. 28 Another mouse mutation, brachypodism, is characterized by the shortening of some, but not all, long bones. This defect is caused by a mutation in the growth and differentiation factor 5 (GDF-5). 29 BMP-5 is expressed during development in the condensing mesenchymal cells of the ear cartilage and GDF5 in the cartilage of the affected limbs. The remarkable selectivity of this defect, similar to those produced by changes in individual Hox genes, illustrates the high degree of local control in development.

IV. THE ROLE OF PARATHYROID HORMONE-RELATED PEPTIDE IN DEVELOPMENT Parathyroid hormone-related peptide (PTHrP) was discovered as the agent that is released from certain tumors and is responsible for hypercalcemia of malignancy by acting on the PTH/PTHrP receptor, mimicking PTH action. In attempts to define the physiological role of PTHrP, the gene was deleted in mice through homologous recombination in embryonic stem cells. The mice died soon after birth and the major defect was in the growth cartilage where an accelerated maturation into hypertrophic chondrocytes was observed, suggesting that PTHrP delays chondrocyte differentiation. 3~ Mutation of the PTH/PTHrP receptor was embryonically lethal by day 14.5 and embryos were small. The crossing of PTH/ PTHrP receptor ( + / - ) heterozygotes with black Swiss mice increases survival of PTH/PTHrP receptor ( - / - ) embryos until birth. The phenotype was similar to that of PTHrP ( - / - ) and was consistent with that of Jensen osteochondrodystrophy in patients who have a point mutation in the PTH/PTHrP receptor gene. 3~'32 PTHrP was recently found to be co-expressed with Indian hedgehog (IHH), a member of the hedgehog family mentioned above in limb development, and its misexpression delayed chondrocyte differentiation into hypertrophic cells. 33 This led to the hypothesis that PTHrP may mediate the hedgehog signal. Since IHH and SHH have similar biological activities, either SHH or PTHrP were


added to limb explants from normal or PTH/PTHrP receptor ( - / - ) mice. Both agents retarded chondrocyte differentiation in limbs of normal mice, but not in mutant [PTHrP receptor ( - / - ) ] mice. Furthermore, SHH had no effect on chondrocyte differentiation in PTHrP ( - / - ) mice, supporting the hypothesis that PTHrP is the downstream mediator of the IHH effect. The hedgehog proteins play additional roles in skeletal development. There are at least three hedgehog genes: SHH, mentioned above in the context of limb development; desert hedgehog (DHH); and IHH, mentioned above as inducing PTHrP expression. SHH was also implicated in determining the left/right symmetry and the specification of sclerotome cell lines. ~8'34 As mentioned above in limb development, SHH also induces the expression of BMP-2, as well as FGF-4. Recently, the 92-kDa serine/threonine kinase fused has been implicated in the signal transduction pathway of HH. 35

V. FIBROBLAST GROWTH FACTORS AND SKELETAL DEVELOPMENT FGFs modulate growth and differentiation of bone and cartilage cells in vitro and are expressed, along with FGF receptors, in skeletal tissues during development. Nine FGFs and four FGFRs have been reported. Their features and effects on bone cells are summarized later in this chapter. In the context of skeletal development, FGFs act as mitogens, morphogens, and suppressors of differentiation. FGF expression patterns during development suggest that they might be involved in the proximal distal patternings of the limb. As mentioned above, FGF-2, FGF-4, and FGF-8 are expressed in the AER. FGF-2 and FGF-4 support limb outgrowth and can substitute for AER in limb buds. ~80verexpression of FGF-2 on the anterior aspect of the chick limb bud results in duplication of digits. Overexpression of FGF-1, FGF-2, or FGF-4 in the flank produces an extra limb. 19 The putative target cells of FGFs are chondrocytes, and it was shown that FGF-1 and FGF-2 promote the repair of damaged cartilage, 36 while FGF-2 inhibits the terminal differentiation of rabbit chondrocytes in culture. 37 However, the most compelling evidence for the role of FGF in skeletal development comes from mutations in FGF receptor genes, which cause skeletal abnormalities. A mutation in FGFR-1 causes Pfeiffer's syndrome. 38 A mutation in FGFR-2 results in Crouzon's syndrome, characterized by craniosynostosis and skeletal abnormalities in the limbs. 39 Mutations of various domains of FGFR-3 cause achondroplasia, thanatophoric dysplasia, and hypochondroplasia. 4~ Achondroplasia, a common cause of dwarfism, 42 is caused by a gain of

CHAPTER 1 Embryology and Cellular Biology of Bone function mutation, which causes constitutive activation of the receptor associated with suppression of osteogenesis, consistent with inhibition of osteoblastic differentiation in culture. 43 This was further confirmed by the disruption of the FGFR-3 gene in mice by the method of homologous recombination in embryonic stem cells. 44 Shortening of the limbs, which is observed in transgenic mice with overexpression of FGF-2, is also consistent with FGF-2 inhibiting bone growth. 45 The lack of FGFR-3 caused an expansion of the proliferating and hypertrophic zones in the epiphyseal cartilage, which further indicates that activation of FGFR-3 controls bone development by exerting a negative effect on osteogenesis. The above discussion focused on regulatory molecules, such as growth and differentiation factors and transcription factors. To the latter, one can add AP-2, recently shown to be essential for cranial closure, its absence causing severe dysmorphogenesis of the face and skull, as well as defects in the bones of the trunk region 46 and in the central nervous system. 47 Other genes required for cranial closure are the paired genes Pax-3 48 and twist. 49 Activating transcription factor 2 (ATF-2) is another general transcription factor belonging to the ATF/CREB family, the absence of which caused in mice chondrodysplasia and severely stunted growth with reduced spine length and shortened extremities. 5~ Yet another transcription factor, SOX-9, was found to be responsible in humans for the syndrome of campomelic dysplasia, usually a lethal syndrome characterized by severe skeletal abnormalities, defects in cartilage formation, as well as autosomal sex reversal. The SOX genes are sex-determining-region Y (SRY)-related genes. SOX-9 contains a HNG DNA-binding box of 78 amino acids, which is 71% similar to that of SRY. 51'52 SOX-9 was shown to be expressed during chondrogenesis in mouse embryos. Mutations in genes coding for extracellular matrix constituents have been known for some time to cause skeletal anomalies. Mutations in type 1 collagen, primarily in the procollagen region, are responsible for most cases of osteogenesis imperfecta. 1 As mentioned above, mutations in type 10 and 11 collagen cause severe anomalies in cartilage development and a mutation in a sulfate transporter, which probably affects the production of the sulfate proteoglycans, causing diastrophic dysplasia. 2 The deletion of the osteocalcin genes in mice was recently shown to increase cortical thickness as a result of increased bone formation, 53 suggesting that this gene regulates osteoblastic bone formation. To summarize this section, we have entered the era when one of the big biological riddlesmunderstanding how an organism develops from a single c e l l m h a s started unraveling. The players are gradually being iden-

5 tiffed through spontaneous or experimental gene mutations, which lead to loss or gain of function. For the skeleton, these include, among others, the Hox genes, FGFs and their receptors, hedgehogs (IHH, SHH, and DHH), BMPs, Wnt, PTHrP, retinoids, and the respective receptors. This list does not include all the genes that have been implicated in skeletal development, and their number is likely to continue to grow. In addition, the much more complicated task that lies ahead is to figure out how these genes interact and how they influence the number, position, and phenotypic expression of the cells responsible for the structure and function of the skeletal tissues.

VI. CELLS LINEAGE

OF THE

OSTEOBLAST

(Fig. 1 - 1) A. T h e O s t e o b l a s t P h e n o t y p e

Osteoblasts are anatomically/histologically defined as the plump cuboidal cells, organized in continuous layers along osteoid, the nonmineralized bone matrix on bone surfaces. The osteoblasts elaborate that matrix, which is 90% collagen, and possess at the ultrastructural level the characteristic features of protein-producing and-secreting cells: an abundance of endoplasmic reticulum and Golgi structures polarized towards the matrix side of the cell. These cells also have a distinct, large, oval nucleus. Osteoblasts are clearly polarized and seem to work in tandem, since the bone matrix is organized in extracellular collagen fibrils that exceed the dimension of single cells. The secretory osteoblast is therefore a cell which synthesizes and elaborates large amounts of type I collagen, as well as the noncollagenous matrix proteins found in bone: bone sialoprotein, osteopontin, osteonectin, osteocalcin, certain proteoglycans, and others. About 10 days after its elaboration, the matrix mineralizes. The alkaline phosphatase ectoenzyme, present at high levels in osteoblasts, is essential for this process, since its absence in the genetic disorder hypophosphatasia produces severe rickets. 54 To carry out their function in the context of the integrated tissue and organism, osteoblasts respond to autocrine, paracrine, and matricrine stimuli and are thus endowed with appropriate receptors. They also elaborate specific cytokines and factors for these regulatory functions. Although none of the osteoblastic features or products, including the bone matrix proteins, its receptors, or cytokines are totally unique for this cell, their combination and their level of expression define the osteoblastic phenotype. Following is a brief enumeration and description of these "osteoblastic markers."

6


FIGURE 1-1 Morphology of osteoblasts. A, In the low-power electron micrograph, a layer of osteoblasts that are tightly connected to each other forming a syncytium is seen on the upper (forming) side of the bone; on the lower side, cells that may represent either inactive osteoblasts or precursor cells are less tightly connected to each other so that there is no true syncytium on the bone surface. A relatively inactive osteocyte is seen within the bone. B, A higher power view shows one of the processes extending from an osteoblast toward the mineralized bone and connecting through gap junctions with a process from an internal osteocyte. The unmineralized osteoid contains collagen bundles of increasing size. Mineralization is at first spotty, but ultimately there is a dense and continuous mineralization front. (Courtesy of Dr. M. Holtrop.)

Collagen is the most abundant protein in the organism; 19 types have been described, 5 of which are helical (I, II, III, V, and XI). 1 The osteoblasts synthesize type 1 collagen and do not make type 2, which is produced by chrondrocytes, or type 3, the product of connective tissue, skin, or tendon fibroblasts. Type 1 is also abundantly present in those tissues, although its supramolecular organization is tissue specific, which may account in part for the selective mineralization of bone. Type 1 collagen in bone forms unique intra- and intermolecular crosslinks between lysine residues, which generate pyridinoline- and deoxypyridinoline-containing peptides, the excretion of which is today the best marker of bone resorption (degradation). 55 Osteocalcin or bone-gla protein, 56'57 although not always present in bone, is the most bone-specific protein. The only other cell where osteocalcin production was reported is the megakaryocyte. Osteocalcin appears to be absent in woven bone and more abundant in bones

from older animals. 58 Except for Paget's disease, there is generally a reasonably good correlation between the rate of bone formation and the circulating levels of osteocalcin, one of the biochemical markers of bone formation. 59 The normal serum levels are about 10 ng/ml. 6~ Like for other noncollagenous proteins, the function of osteocalcin is not firmly established. Recent "knockout" experiments in mice suggest that it suppresses osteoblastic bone formation. 53 Bone sialoprotein (BSP) is a 320-amino-acid glycoprotein 61 found in bone, dentin, cementum, and hypertrophic cartilage. 62-64 It contains an RGD sequence, which binds to integrins, the cell attachment receptors. Like osteopontin (see below), it is both sulfated and phosphorylated. 58'65'66 It is present at the onset of bone f o r m a t i o n , 67 but its precise function is not known. Osteopontin is also a glycoprotein with a protein backbone of about 32 kDa, produced and secreted by osteoblasts. It is found in many other tissues, where it was indepen-

CHAPTER 1 Embryologyand Cellular Biology of Bone dently discovered and named (2ar, SPP-1, uropontin, Eta-l). 68-71 In bone, it is synthesized also by osteocytes and osteoclasts. 72'73 Like BSP, it contains an RGD sequence and binds to the integrin vitronectin receptor, serving as a substrate for the attachment of osteoblasts or osteoclasts in vitro. Osteopontin is associated with inflammation, restenosis, and tumor invasion. TM Its precise function in bone is not known; it is found on the reversal line where osteoclastic resorption has stopped and osteoblastic bone formation started. 75 The two proteoglycans found in bone are decorin and biglycan. TM They are also found in articular and epiphyseal cartilage as well as in the subperichondral regions and in the periosteum. 77 Although, strictly speaking, bone formation cannot be observed in vitro, many of these proteins are produced and secreted by osteoblastic cells in culture. Such ex vivo experiments helped define the osteoblastic phenotype and study of the regulation of the production of these osteoblastic products by hormones, cytokines, and growth factors and the dependence of their expression on osteoblast maturation/ differentiation. 78-8~ In vivo, the expression of these osteoblastic genes can be followed by in situ hybridization and immunochemistry. Both types of studies show that the expression of osteoblast phenotypic genes is sequential, rather than synchronous, and may vary as a function of the type of osteoblast and osteogenesis (see below). Alkaline phosphatase (ALP) is a 65-kDa ectoenzyme, which requires zinc and dimerization for cleaving nonspecifically organophosphates at a neutral pH. The bone/ liver/kidney-ubiquitous (tissue nonspecific) isoenzyme is one of the three expressed in humans, the others being the intestinal and the placental one. 54 The bone enzyme differs in its glycosylation pattern from that of the liver and kidney. This made it possible to develop bone specific monoclonal antibodies, and skeletal ALP in the circulation is now a biochemical marker for bone formation. Although many other cells contain this ectoenzyme in their membrane, its level is at least 100 times higher in osteoblasts. The absence of this enzyme in hypophosphatasia causes tickets and the accumulation of phosphoethanolamine and pyridoxal-5-phosphate. 8~ In vitro and in vivo studies have identified a large number of factors which can regulate osteoblastic proliferation, differentiation, and activity, including factors produced by osteoblasts themselves. In vitro studies have shown that osteoblasts have receptors for many factors, not all of which may play a role in vivo. This list includes PTH; PTHrP; estrogens; androgens; progestins; glucocorticoids; 1,25-dihydroxyvitamin D3 [1,25(OH)2D3]; retinoids; prostanoids (primarily PGE and PGF2~); (IGF-1) and IGF-2, insulin; FGFs, TGF-[3s and BMPs; EGF; PDGF-a and -b; interleukins (IL) -1, - 3 , - 4 , - 8 , and-11; TNF-ot; LIF; ANF; endothelin; and

7 colony-stimulating factors. Factors shown to be produced by osteoblasts include: IGF-1 and-2; PGE2 and PGF2~; I L - 1 , - 3 , - 6 , - 8 , and-11; B M P - 2 , - 4 , - 6 , and-7; TGF-[31 and TGF-[33; FGF-2; VEGF; LIF; MCSF; and granulocyte-macrophage colony-stimulating factor (GMCSF). These lists are incomplete. Some factors stimulate the production of other factors; for example, agents which up-regulate cyclic adenosine monophosphate (cAMP) such as PTH, PTHrP, or PGE stimulate IGF-1 and VEGF synthesis and secretion. 82-85 TGF-[3, BMPs, IL-1, and other agents stimulate PGE2 production, 86-89 which in turn is down-regulated by glucocorticoids. FGF stimulates TGF-13 synthesis and secretion. IL-1 and IL-6 stimulate IL-11 secretion, which acts on osteoclasts. Estrogens suppress IL-6 production. Not all osteoblastic cells produce and respond to all factors. For example, it has been observed in situ that only certain osteoblastlineage cells with a specific morphology were rich in PTH receptors. 9~ Taken together, these observations suggest that: (1) cells of the osteoblastic lineage (see below regarding osteocytes and lining cells) act as receivers and transmitters of bone remodeling signals, and (2) that there are hierarchial feedback loops and cascades, some factors inducing other factors. Additional cells, including osteoclasts, vascular endothelial cells, and possibly macrophages and other hemopoietic cells, may participate in these interactions (see Section VIII). Cell-cell interaction between osteoblasts is also mediated by gap junctions, which may explain their apparently coordinated function. Osteoblasts express the gap junction proteins connexin-43 and connexin-45 9~'92 and connexin-43 up-regulation was associated with stimulation of osteoblastic differentiation. 93 To summarize, the family of osteoblastic cells includes cells that produce the extracellular proteins in the bone matrix: type 1 collagen and the noncollagenous proteins osteopontin, BSP, osteocalcin, osteonectin, decorin, biglycan, and others. Specific osteoblastic cells possess receptors for stimuli of bone remodeling, including systemic hormones [PTH, sex steroids, glucocorticoids, 1,25(OH)2D3, insulin, thyroid hormone], local factors (prostanoids and cytokines, interleukins), etc. Osteoblastic cells also secrete many regulatory factors, such as IL-6, PGE, IGF-1, TGF-[3, and others, which generates a complex system of interacting arrays that coordinate the three bone functions: mechanical support, ion homeostasis, and hemopoiesis.

B. O s t e o b l a s t D i f f e r e n t i a t i o n As mentioned above, bone is derived embryologically either from the neural crest, from branchial arches, or from sclerotomes. In all cases, osteoblasts originate from

8

mesenchymal cells, which can give rise to other cell types: fibroblasts, myoblasts, chondroblasts, adipocytes, and tendon cells. It is not clear if this spectrum of differentiation potential is present in a single given stem cell. Calvaria-derived clonal cells were shown to give rise to adipocytes, myoblasts, chondroblasts, and osteoblasts. 94 Periosteal cells can probably differentiate into bone and cartilage cells following fracture. Mesenchymal cells in the bone marrow were proposed to have both osteogenic and adipogenic potential. 95 The transition of bone to tendon in Sharpey's fibers and the ossification of some tendons (at least in the turkey) is consistent with the common cellular origin for bone and tendon. Ectopic bone formation induced by "calciphylaxis" or BMPs indicates that mesenchymal cells with osteogenic potential are present in muscle and dermis. Pathological stimulation of such cells to become osteogenic is probably occurring in fibrodysplasia ossificans progressiva. 96 The stimuli required for osteogenic differentiation of mesenchymal cells probably differ for different types and stages of "osteogenic commitment" of such cells. Friendenstein many years ago distinguished between "committed" and "inducible" osteogenic cells, based on the stimuli required for the formation of bone in diffusion chambers implanted in animals. 97 The differentiation program is likely to be triggered by the induction of upregulation of transcription factors, which in turn induce the phenotype (osteoblast) -specific genes. The best paradigm for the up-regulation of such transcriptional control genes, sometimes called "master" genes, is the differentiation of muscle where myo-D, myogenin, and myf-5 play such a role. 98'99 Since myoblasts are also derived from mesenchymal cells, it was expected that analogous transcription factors, known as helix-loop-helix (HLH) factors, based on their structure, would initiate the differentiation of osteoblasts, chondroblasts, adipocytes, etc. No osteoblast-specific HLH transcription factors have been found so far. A key transcription factor involved in adipocyte differentiation was found to be the peroxisome proliferator activated receptor ~/ (PPAR-~/), which belongs to the family of steroid, retinoid, and vitamin D receptors. 1~176 External signals, which induce the transcription factors, should include growth and differentiation factors, as described for limb development: fibroblast growth factors, BMPs, hedgehog, etc. It was shown, for example, that B MP can induce osteoblastic differentiation in certain cell types ~~ and at the same time suppress myoblast differentiation in myogenic competent cells. ~~ Thus, although the details are not fully known, one can summarize as follows. Osteoblasts are derived from mesenchymal cells, which can have different levels of commitment for osteogenic differentiation. External stimuli, growth and differentiation factors, hormones,


and cell-cell and cell-matrix interactions induce in precursor cells transcription factors which "turn on" the osteoblastic phenotype. These factors are both nonspecific (such as early genes, fog, egr, etc.) and "tissuespecific" factors, which remain to be described, Differentiated cells are defined by the proteins they make, which include receptors, enzymes, etc., responsible for their tissue-specific function. As mentioned above, osteoblasts have very few tissue-specific proteins, may be osteocalcin and bone sialoprotein. However, the combination and abundance of proteins made by osteoblasts are clearly characteristic of this phenotype. Not all "phenotypic" genes are expressed in all osteoblastic cells. There is strong indication that osteoblasts in cortical bone are different from those in cancellous bone and they may differ somewhat from bone to bone. For example, parathyroid hormone was reported to be a stronger stimulator of bone formation in cancellous than in cortical bone. ~~ In a given bone, osteoblasts also differ from each other; for example, it was shown that PTH receptors are present in some osteoblasts and absent in others. 9~In vitro, cells of osteoblastic origin show a very wide spectrum of features with respect to the proteins they produce and the receptors they have. 73 Osteoblastic cells produce growth and differentiation factors, including TGF-[3, bFGF, PTHrP, IGF and IGF-binding proteins, BMP-4, and CSF-1. Osteoblasts also possess cyclooxygenase, both type 1 and type 2 (inducible), and produce PGE and other prostanoids. Osteoblasts are thus well endowed to participate in autocrine and paracrine signaling, and osteoblasts are believed to play a central role in the regulation of bone remodeling (see below). As mentioned above, not all osteoblastic cells exhibit all phenotype-related genes, and the genes they exhibit are sequentially expressed. The sequence of expression may differ according to the type of bone or osteoblast. In rat calvaria and metatarsal bones, alkaline phosphatase and BSP seem to be early markers, judging by the distance of cells which express these mRNAs, from the osteoid, v20steopontin and osteocalcin seem to be expressed only in the cell layer contiguous to osteoid, while collagen is expressed in all cell layers. The sequence is roughly similar to that observed in rat calvariaderived osteoblastic cells in culture, g~ Such cells, under appropriate conditions, form nodules that mineralize in the presence of [3-glycerophosphate. As observed in other differentiating cells, there is a reciprocal relationship in osteoblasts as well between proliferation and the expression of differentiation-related genes. Histologically, some osteoblasts appear to differentiate either into lining cells, which cover the mineralized osteoid at the end of the formation period, or into osteocytes, which are incorporated into the matrix. Only recently have osteocytes been isolated using specific an-

CHAPTER 1 Embryology and Cellular Biology of Bone tibodies. 1~ have long projections, which traverse the matrix and most likely form a communicating network throughout bone. Electric conductivity through bone is consistent with communication between osteocytes via gap junctions. ~~ Osteocytes and lining cells are ideally located to perceive strain changes in the matrix and were proposed to mediate the response of bone to mechanical loads. 1~ Mechanical stimulation was shown to increase the production of PGE2 by osteoblast lineage c e l l s 1~ and PGE2 stimulates both bone resorption and bone formation. Indomethacin, an inhibitor of PGE2 production, was shown to block mechanical effects on bone remodeling. ~~ TGF-[3 inhibits osteoclast formation and activity 1~ and stimulates bone formation when injected next to the periosteum in v i v o . 1~~ Macrophage colony-stimulating factor (M-CSF) and IL-1, -6, and -11 will be discussed below in the context of osteoblast/osteoclast interaction. PGI2 has also been implicated in the mechanical effects on b o n e . TM Growth and differentiation factors can also modulate each other's production and that of various receptors, which can generate feedback loops and signal cascades. We are dealing therefore in this system with multiple interactions generated by a diversity of osteoblastic lineage cells, each responding to specific stimuli and emitting various signals, which upon integration yield the marvelous performance of functional bone. To summarize this section, the osteoblastic lineage contains the matrix-producing cells and "signaling" cells, likely to include the osteocytes and lining cells. Osteoblastic cells differentiate from mesenchymal cells in response to growth and differentiation factors. The

9 factors responsible for osteoblastic differentiation during normal bone remodeling in the adult have not been established. Such factors are likely to stimulate the induction of up-regulation of transcription factors, which participate in turning on the osteoblastic phenotype. These transcription factors remain to be identified.

VII. THE

OSTEOCLAST

(Fig. 1 - 2 )

Osteoclasts are the bone resorbing (degrading) cells. They are large (up to 100 txm), multinucleated (usually two to five nuclei per cell but sometimes many more), and are formed by the fusion of mononuclear cells, which already contain many of the features of the mature osteoclasts and are also capable of normal resorption. Actively resorbing osteoclasts are polarized, the part of the cell involved in resorption consisting of an actincontaining membrane ring firmly attached to bone, which circumscribes a highly convoluted membrane, the ruffled border, which is the resorbing organ of the cell (see below). 112'113 Histologically, osteoclasts can be seen often in groups acting in cancellous bone on the bone surface and in cortical bone digging conical (haversian) canals. The lifespan of an osteoclast is estimated from histological studies at 3 to 4 weeks and the demise of the osteoclast is probably by apoptosis. TM Many bone diseases, including osteoporosis, are characterized by loss of bone, often due to excessive osteoclastic bone resorption due either to an increase in osteoclast number or activity. The osteoclast has therefore been a major target of therapeutic approaches to bone diseases.

FIGURE 1--2 Morphologyof osteoclasts. A, An osteoclast from PTH-stimulated bone in vivo. Notice the many nuclei, the large vacuoles at the site of resorption on the left, and the abundant mitochondria. B, A high-power view of the ruffled border in the act of degrading a spicule of bone. It is surrounded by a clear zone that attaches the osteoclast to the bone and separates the ruffled border area from the surrounding extracellular fluid. (Courtesy of Dr. M. Holtrop.)

10


A. Osteoclast Origin and Differentiation There is ample evidence that osteoclasts are of hemopoietic origin, they are related to monocytes/macrophages and probably derive from granulocyte-macrophage colony forming unit (CFU-GM) cells. Early osteoclast precursors have not been isolated using cell sorting or other methods, but osteoclast progenitors were reported to be present in the circulation, both in mice and humans, in the cellular fraction, which contains the monocytes. 115 In an experimental system, which uses fetal mouse metatarsal bones prior to osteoclast development to identify tissues which contain osteoclastogenic precursors, 116 those were found in bone marrow, as well as in liver and spleen, sites of hemopoiesis in the embryo. Earlier evidence demonstrating the hemopoietic origin of osteoclasts is based on the ability of bone marrow transplants to cure certain types of osteopetrosis, based on absence or malfunctioning of osteoclasts in animals and sometimes in humans. 117'118 During the last 10 years, experimental osteoclastogenesis has been produced in vitro by co-culturing bone marrow or spleen cells, usually from mouse, with a supportive feeder layer. 119 The cells required for the differentiation of osteoclastic cells could be either calvaria-derived osteoblasts, some but not all osteoblastic cell lines from calvaria, and mesenchymal, so-called stromal cells from bone marrow, which were selected for this capability. 12~ Using such a system, osteoclasts can be generated in vitro from bone marrow from various species in the presence of 1,25(OH)2D3. Direct contact between the living cells of the feeder layer and osteoclast progenitors is necessary for osteoclast generation and function. 121 Various stimuli promote or enhance osteoclast formation in this system, probably by acting on the "inducing" cells. These include, in addition to 1,25(OH)ED3: PTH, tumor necrosis factor ct (TNF-o0 PGE2, interleukin-1, interleukin-ll, and interleukin-6 in the presence of soluble interleukin-6 receptor. 119'122 Some feeder cells also require glucocorticoids. Like in the differentiation of other cell types, the sequence of events should start with extracellular signals, which induce transcription factors, initially early genes and then factors which turn-on the phenotypespecific genes. There are probably several signals conveyed by feeder layer cells to osteoclast progenitors. Among the genes up-regulated by 1,25(OH)2D3, C3 complement was shown to promote osteoclastogenesis. 122 CSF-1 is another important gene expressed by osteoblastic cells, both as a secreted and membrane-bound form demonstrated to be necessary for osteoclast formation by its absence in the osteopetrotic mutation op/op, lz3'124 Hepatocyte growth factor (scatter factor) was reported to promote osteoclastogenesis in vitro, its role

in vivo remains to be established. 125-127 TGF-[3 was shown to inhibit osteoclast formation. 128 Three of the transcription factors involved in osteoclast differentiation were revealed by osteopetrotic mutations. Deletion of src by homologous recombination (src-k.o.) produced an osteopetrotic phenotype in mice, characterized by the lack of ruffled border in osteoclasts. 129'13~The kinase activity of c-src is apparently not required to rescue, at least partially, the osteopetrotic phenotype. TM Another experimental mutation, which produced osteopetrosis, is the deletion of the early gene c-fos. 132 An osteopetrotic phenotype in mice was also shown to be due to the lack of a transcription factor PU-1.133 The downstream targets of these mutations are not yet known. For human osteopetrosis, only one mutated gene has been identified so far, carbonic anhydrase ( C A - I I ) TM and it was reported that bone marrow-derived osteoclast-like cells from a patient with craniometaphyseal dysplasia lacked the vacuolar proton pump. 135 Several genes are considered to be " m a r k e r s " of the osteoclastic phenotype. Osteoclasts have over 1 million receptors for calcitonin, the hormone that inhibits osteoclast activity. 136 Osteoclasts express very high levels of the vitronectin receptor integrin (]~v~3, the epitope of a monoclonal antibody thought initially to be osteoclast specific. 137 Tartrate-resistant acid phosphatase is highly abundant in osteoclasts. ~38 Another lysosomal hydrolytic enzyme, cathepsin K, was also cloned initially from osteoclasts, where its levels are extremely high. 139'14~Osteoclasts also express several proteins involved in the acidification process, which are not unique to this cell. These include a vacuolar ATPase and the associated chloride channel, 141-143 CA-II, 144 chloride bicarbonate exchanger, 145 sodium proton antiporter, 146 and sodium/ potassium A T P a s e . 147 Osteoclasts also produce the extracellular matrix osteopontin, which contains the RGD sequence and could be a ligand for the C~vl33receptor. Another structure reported to be present in osteoclasts is the potassium proton ATPase. 148 Many of these so-called phenotypic markers were shown to be present in the mononuclear cells prior to f u s i o n . 149 To summarize this section, osteoclasts are cells of hemopoietic origin related to monocyte/macrophages. Their differentiation from progenitor cells, which have not been isolated, can be reproduced in culture in the presence of osteoblasts or bone marrow stromal feeder cells. The growth and differentiation factors, which promote osteoclast differentiation in vivo, have not been identified but several agents, such as PTH, PGE2, and IL-1, which stimulate bone resorption, enhance osteoclast formation in culture. Osteopetrotic mutations have identified several genes essential for osteoclast development and function: CSF-1, src, fos, PU-1, and CA-II.

CHAPTER 1 Embryology and Cellular Biology of Bone B. O s t e o c l a s t F u n c t i o n Multinucleated osteoclasts are probably formed on or close to the surface of mineralized bone. This surface has probably been prepared for resorption by lining cell removal of a thin layer of matrix. 15~ Direct contact with mineral is probably important for osteoclast activation, since nonmineralized matrix is not readily resorbed. This is apparent in tickets and osteomalacia, where matrix accumulation is observed in cartilage and bone. Integrins, the heterodimeric cell attachment receptors, have been implicated in osteoclast attachment and/or activation, particularly the vitronectin receptor Otv[33,which also binds osteopontin and bone sialoprotein. 137 Osteopontin is an extracellular matrix glycoprotein produced by osteoblasts and other cells, as well as osteoclasts. TM Inhibitors of OLv[33, such as snake venom echistatin and blocking antibodies, were shown to inhibit bone resorption. 152-~54 Significant morphological changes occur during osteoclast activation. The cell becomes highly polarized and develops three clearly distinguishable membrane domains. 155 In fight contact with the bone surface is an organelle-free actin-rich ring through which the cell attaches tightly to bone. This ring, called the sealing or clear zone, separates the two other membrane domains. Facing the bone in a circle of about 500 ixm2, delineated by the clear zone, is the highly convoluted membrane called the ruffled border, produced by the insertion of vesicles with lysosomal characteristics. This membrane, the ruffled border, contains the structures that carry out the bone resorption function. Outside the clear zone is the rest of the osteoclast membrane called, by analogy to other polarized cells, the basolateral surface, which differs both in appearance and composition from the ruffled border. Bone resorption has two major components: (1) dissolution of the mineral, caused by acidification within the resorption lacuna and (2) digestion (hydrolysis) of the matrix proteins by cysteine proteinases, cathepsins, metalloproteinases, and collagenases. The osteoclast is endowed with several structures to acidify the lacuna to a pH of 4 or less. In the ruffled border, the proton pump, a vacuolar ATPase, has been localized by immunochemistry TM and the proton pump inhibitor bafilomycin A was shown to inhibit bone resorption. T M This is a multicomponent, ubiquitous pump present in the internal vacuoles of all cells, but it was suggested that it may differ somewhat in osteoclasts as a result of alternative splicing. 158 In the cytoplasm, acidification is aided by the presence of carbonic anhydrase, which catalyzes the conversion of bicarbonate into CO2 and protons. Sulfonamides, which inhibit this enzyme, reduce bone resorption, and a genetic defect of CA-II deficiency causes osteopetrosis. T M In the baso-

11 lateral membrane, there is a bicarbonate chloride exchanger, and its inhibition reduced resorption as well. 145 In the ruffled border chloride, transported by a chloride channel, is a counter ion for the proton pump. 159 The osteoclast has a number of other ion channels, including inward and outward potassium-rectifying channels, 16~ calcium channels, and others, yet to be described, as well as very abundant sodium-potassium ATPase in the basolateral membrane, 147 which contribute to the regulation of the membrane potential and the ionic homeostasis in this actively acidifying cell. To serve the energy needs for this hard work, the osteoclast is endowed with a large number of mitochondria, localized primarily above the ruffled border. It has recently been suggested that calcium phosphate is crossing the cell following mineral solubilization. In vitro, it was shown that low pH (e.g., 6.8) increases osteoclast activity and high calcium (>2.5 mM) decreases it. 163-166 There is not full agreement on the enzymes involved in matrix degradation. Among the cysteine proteinases, cathepsin K seems to be the most abundant one 167 (based on mRNA) and also has the ability to degrade nondenatured type 1 collagen. Cathepsin L and S are also present in osteoclasts. A cathepsin L-deficient (knock-out) mouse had no apparent bone defects. ~68 However, congenital cathepsin K deficiency in humans causes picnodysostosis, characterized by osteopetrosis and bone anomalies. ~4~ It was reported that osteoclasts produce neutral collagenase (MMP1), although there is no consensus on this assertion. Collagenase is also produced by osteoblasts and probably deposited in the matrix along with collagen. Inhibitors of collagenase suppress bone resorption in vitro; however, the role of this enzyme in vivo is not fully established. In vitro, osteoclasts resorb a certain site for several hours and then move to a separate site and may act similarly in Y i v o . 169 A single osteoclast may be involved in the resorption of more than one lacuna. In vivo, one often sees several osteoclasts resorbing side-by-side, suggesting the possibility of positive feedback, whereby an active osteoclast recruits additional ones analogous to leukocytes during inflammation. The lifespan of osteoclasts has been estimated histologically at 2 to 4 weeks and there is evidence that osteoclasts undergo apoptosis. T M It is not known what controls the termination of osteoclast resorption at a particular site in vivo, nor is it known if osteoclasts require sustained activation in order to resorb bone. In vitro, in certain systems, the presence of osteoblast lineage cells seems to be necessary for osteoclast activity. TM Systemic physiological agents, which increase osteoclast number and possibly activity, include parathyroid hormone, thyroid hormone, and the lack of estrogen, as discussed elsewhere. Local factors include IL-1 and TNF-ct, possibly involved in the bone destruction associated with

12 inflammation in periodontal disease and rheumatoid arthritis. The systemic hormone that inhibits osteoclast activity is calcitonin, but its role in the adult in calcium homeostasis or bone metabolism is questionable. Neither calcitonin deficiency nor excess calcitonin, produced endogenously by thyroid tumors, has an effect on calcium levels or bone mass. Recently, it was reported that mechanical strain in the matrix, to which osteoclasts are attached, may control osteoclast activity. 17~ This is an interesting observation, since it would explain in part the adaptation of bone structure to mechanical loads. To summarize this section, osteoclasts are activated when they come in contact with the prepared mineralized bone surface. Integrins may play a role in this process. Active osteoclasts form a resorption lacuna delineated by the tightly sealing clear zone. The ruffled border in the lacuna secretes protons, which solubilize the mineral, and proteases, including cathepsins, which digest the matrix. The lifespan of osteoclasts is about 2 weeks.

VIII. C E L L - C E L L INTERACTION IN BONE REMODELING Bone remodeling is initiated by signals that prepare the bone surface for resorption and attract osteoclasts to carry out this function. It is known that elevated PTH or thyroid hormone and reduced levels of estrogen in women and testosterone in men increase the number of sites at which remodeling occurs; however, the mechanism for specifying a particular site for bone remodeling is not well understood. Cytokines that increase remodeling include IL-1, TNF-c~, PGE, and TGF-[3; their local generation, such as in periodontal disease or rheumatoid arthritis, could be the initiating factor in those cases. The only perturbation shown experimentally to initiate remodeling at specific sites is mechanical stimulation. ~72 It is possible that mechanical function indeed specifies the sites at which remodeling will normally occur and the hormonal background in the organism determines its intensity. This could explain the more than additive effects of immobilization and calcium deficiency or estrogen deficiency on bone lOSS. 173 Similarly, local elevation of cytokines, such as PGE2, could specify remodeling sites, especially since PGE2 has also been implicated in mediating mechanical effects on bone. The cells that perceive mechanical perturbations and those that secrete cytokines are good candidates for initiating the cell-cell interactions that set remodeling into motion. The cells best situated to detect mechanically induced deformation of the matrix are the osteoblast lineage-derived osteocytes and lining cells. Biochemical changes, including elevations in PGI2, have indeed been observed in oste-


ocytes soon following mechanical stimulation. 111 The way osteocytes and lining cells may perceive matrix deformation could be via the integrins through which they attach to the matrix. Integrins are heterodimeric macromolecular receptors, which in addition to their attachment function also participate in signal transduction. 174 Cytokine-producing cells include local monocyte/ macrophages, as well as osteoblast lineage cells shown to produce IL-6 and IL-1 1 in response to IL-1, for example. Over 15 years ago, it was proposed on the basis of the responsiveness of osteoblast lineage cells to parathyroid hormone, prostaglandins, and other resorptioninducing agents that osteoblastic cells mediate the effect of those agents on osteoclastic bone resorption. 175 The following observations support this notion. Preparation of the resorption surface, as mentioned above, seems to require collagenase activity, which removes a matrix protective layer and uncovers the mineral in bone. This function is probably carried out by osteoblast-lineage cells. Collagenase production and secretion in osteoblastic cells was shown to be stimulated by parathyroid h o r m o n e . 176'177 The interaction of osteoblast-lineage and other cells with osteoclasts can occur at several levelsmosteoclast formation, osteoclast activity, or osteoclast s u r v i v a l m a n d may involve diffusible or membrane-associated regulatory factors. The best documented interaction so far is the requirement of osteoblastic or stromal lineage cells for osteoclast generation in culture, reviewed above under osteoclast differentiation. Essentially, in vitro, direct contact with living feeder cells is required for osteoclast generation. Recently, it was shown, at least for osteoclasts generated in culture, that contact with osteoblasts is also required for bone resorption. ~21 No soluble factors that are secreted by osteoblasts and activate the osteoclast directly have been purified or cloned so far. Osteoclasts may be activated by contact with mineralized bone, the way macrophages are activated by phagocytic particles. It is also possible that fusion of mononuclear osteoclasts to multinucleated cells occurs on the bone surface. The chemotactic signal, which attracts osteoclasts or osteoclast precursors to the bone surface during remodeling, is not known. Collagen fragments have been shown to be chemotactic for many cell types. A specific case of osteoblast lineage/stromal cell control of osteoclast generation is the proposed action of estrogen via suppression of cytokine production. 178 Another aspect of cell-cell interaction during remodeling is initiation of the bone formation sequence following bone resorption. The molecular basis for this process, called "coupling," has not been elucidated, lv90steoblast differentiation probably starts several cell layers away from the surface of the matrix, where osteoblastic markers such as elevated alkaline phosphatase can be

CHAPTER 1 Embryology and Cellular Biology of Bone detected. It has been proposed that growth factors such as IGF-2 or TGF-[3 released or activated during bone resorption initiate the bone formation that follows; however, direct in vivo information for this mode of coupling has not yet been obtained. At any rate, locally, bone formation follows bone resorption in most cases. Systemically, as estimated by biochemical markers of resorption and formation, the two processes also change in tandem, suggesting communication or coordination between bone-forming and bone-resorbing cells. Further insights into ~J~e molecular basis of this phenomenon could offer new therapeutic approaches to diseases such as osteoporosis.

IX. COLONY-STIMULATING FACTORS AND BONE Bone is the site of hemopoiesis, and the close relationship between bone and bone marrow has suggested: (1) that bone cells or their precursors may provide the environment and factors needed for hemopoiesis and (2) if an expansion of bone marrow is necessary, due to hypoxia for example, bone resorption will occur in response to factors secreted by hemopoietic cells. 18~ The association between bone and bone marrow seems to be part of a built-in genetic program, since even in ectopic bone, formed in muscle or skin by the administration of bone morphogenetic proteins, ossicles are colonized by bone marrow. In vitro, growth and differentiation of hemopoietic cells of the different lineages require colony-stimulating factors. Some of these were shown to be produced by osteoblastic cells and some were shown to influence the formation of the hemopoietically derived osteoclasts (reviewed above). IL-3 and the kit ligand or stem cell factor and the FLT3/FLK2 ligand act on early precursors of the hemopoietic lineage. ~81'182 IL-3, as well as GM-CSF and macrophage colony-stimulating factor (M-CSF or CSF-1), were shown to be produced by mouse calvafia. ~83 M-CSF promotes the differentiation of monocytes into macrophages and is of special interest to bone, since a mutation in this gene, which interfered with normal protein expression in mice, caused osteopetrosis due to osteoclast absence. Macrophages are also reduced in these mice but not equally in all tissues and there is a measure of recovery of the osteopetrotic phenotype with age. TM The involvement of CSF-1 in the osteopetrotic phenotype has convincingly been demonstrated, not only by the gene defect but by the curative effect of exogenous 185 CSF-1 treatment. CSF-1 seems to be required at multiple stages of osteoclast maturation and, under certain conditions, can increase osteoclast generation. 186 .~87 However, under other conditions, both GM-CSF and

13 CSF-1 reduce osteoclast generation from mouse bone marrow in vitro, possibly by diverting the differentiation pathway into the monocyte/macrophage direction. ~88 CSF-1 was shown to be produced by osteoblasts, in both a secreted and a bound f o r l T l . 189 Mice that lack GM-CSF expression due to disruption by homologous recombination were normal, fertile, and had no apparent defect in hemopoiesis, but had a high incidence of pulmonary infections. ~9~Mice lacking both CSF-1 and GM-CSF had osteopetrosis, similar to the CSF-1 ( - / - ) mice. 191 In vitro, GM-CSF stimulates the generation of osteoclastic cells from mouse bone marrow. 192 Overexpression of granulocyte colony-stimulating factor (G-CSF) in mice caused an increase in osteoclast number and osteopenia. 193 In summary, colony-stimulating factors were discovered based on their requirement for in vitro hemopoiesis. Some of them, such as IL-3 and CSF-1, are expressed by osteoblasts. The role of CSF-1 in osteoclastogenesis, at least in mice, has clearly been demonstrated by the osteopetrotic phenotype of CSF-1 ( - / - ) mutants. Its role and that of other colony-stimulating factors in bone resorption and formation in humans remains to be determined.

X. THE TRANSFORMING GROWTH FACTOR [~ FAMILY Members of the TGF-[3 family, including the BMPs, are homo- or heterodimeric proteins of about 25 kDa, generated by cleavage from larger inactive precursors of about 100 kDa. TGF-[3 is initially associated with a latency-binding protein of 130 kDa in platelets and 190 kDa in osteoblasts, and significant activation steps are necessary for producing active factor. In mammals, there are three independently coded proteins: TGF-[31, TGF-[32, and TGF-[33, which have slightly different functions. TFG-[3s are produced by platelets, osteoblasts, and other cells, but bone is the largest repository of TGF[3 in the body. Interestingly, the bone loss produced by lack of mechanical load was shown to be prevented by TGF-[3 administration. TM When locally injected into bone or next to the periosteum, TGF-[3 stimulates bone formation, 11~ as well as resorption, but the balance is positive. TGF-[3 is elevated in fracture callus and has been implicated in fracture healing. 195 Unlike BMPs, TGF-[3 does not stimulate bone formation when injected into muscle or skin, but was reported to augment the osteogenic effect of demineralized bone matrix. 196 TGF-[3 acts on multiple targets in vivo, the most pronounced effect being immunosuppression, observed pri-

14 marily with TGF-[31, which limits its potential for pharmacological use. In vitro, TGF-[3s were shown to have multiple effects on mesenchymal cells. They stimulate the production of extracellular matrix proteins, including fibronectin, collagen, osteonectin, osteopontin, proteoglycans, etc., and their respective receptors, and inhibit the production of procollagenase and plasminogen activator, thus having an anabolic effect. In many cells, TGF-[3 inhibits proliferation, which is the basis of its bioassay in mink lung fibroblasts. However, in some cells including some bone cells, TGF-[3 can be mitogenic. 197 In the MC3T3 mouse calvaria-derived cells, TGF-[3 inhibits osteoblastic maturation. 198 In vitro, TGF-[3 inhibits osteoclast formation from bone marrow stromal cells. 1~ Taken together, these observations indicate that the action of TGF-[3 depends on cell type and state of differentiation. Attempts to deduce the physiological function of TGF-[3 in vivo were made using targeted gene disruption experiments in mice. TGF-[31 knock-out produced mice that were normal until weening, when they died from massive infections. 199 Prior to that, they were apparently protected by TGF-[3 present in the milk. This emphasized again the important role of TGF-[3 in the immune system. TGF-[33 knock-outs had a cleft palate, indicating a role in palate fusion. 2~176 The fact that TGF-[3 is considered to play an important role in the regulation of bone remodeling is demonstrated by the observation of osteoporosis and increased bone turnover in transgenic mice with osteoblast-specific overexpression of TGF-[3. 2~ Receptors for this family of growth/differentiation factors have recently been identified. 2~ There are basically three types of TGF-[3 receptor: type 3 is a proteoglycan ([3-glycan), which does not seem to be involved in signal transduction. Types 1 and 2 form heterodimers in the presence of ligand and possibly tetramers. Both type 1 and type 2 receptors are threonine/serine kinases. According to the current model the ligand binds first to type 2, which then activates type 1, and type 1 phosphorylates downstream targets that feed into the MAP kinase cascade. 2~ The same receptors or type of receptors are also mediating the signals of BMPs. So far, five type 1 receptors have been cloned from mammalian systems. These are ActR-1, ActR-1B, BMP-R1A, B MP-R1B, and T[3R-1. The four type 2 receptors are BMPR-2, ActR-2, ActR-2B, and T[3R-2. A type 2 receptor for mifllerian inhibiting substance, which belongs to this family, has also been cloned. Recently, it was shown that among the downstream mediators of TGF-[3 action are the MAD (mothers against DPP) proteins related to the Drosophila MAD proteins, which mediate the BMP-related decapentaplegic (DPP) signal in the fly. 2~ Furthermore, the analogous Xenopus XMAD2 was shown to recognize the activin response element and


form a complex with the activin-dependent early gene transcription factor or Mix-2. 2~ The BMPs belong to this family and were discovered based on their ability to induce bone formation when injected subcutaneously or intramuscularly via a process that follows the stages of endochondral bone formation. It has been proposed that ectopic bone formation of fibrodysplasia progressiva ossificans is due to abnormal BMP production. 96 To date, about 13 BMPs have been cloned which, based on their homology, can be divided into subfamilies. They are structurally related to the DPP protein in Drosophila, which controls wing development, and to Vg-1 protein in Xenopus. As mentioned above, BMPs play an important role in limb development and other aspects of development. 2~ When injected into bone or near to bone, BMPs are active stimulators of bone formation. At least two BMPs, BMP-2 and BMP-7, are being developed for clinical use in the repair of fractures and bone defects. The role of B MP-5 and GDF-5 in skeletal development, revealed by spontaneous deletion of these genes in mice, was discussed above. Recently, experimental deletion of the BMP-7 gene was shown to cause severe defects in the development of the kidneys, where it is highly expressed, as well as the eye. It also altered skeletal patterning. 2~ Similar deletion of BMP-2 or BMP-4 caused early embryonic lethality before skeletal formation. 27 The expression of BMPs in limb development was reviewed above. MAD proteins were shown to also mediate downstream effects of BMPs; for example, Smadl was shown to translocate to the nucleus in response to BMP-4 and to mimic the effects of BMP-4 in Xenopus embryo. 2~ Interestingly, BMP-4, as well as BMP-2 and BMP-7, are expressed in the interdigital region in developing chick limb bud and seem to be required for apoptosis, which was inhibited by dominant negative type 1 BMP receptor. 2~ In vivo, BMP-2 and BMP-4 were immunolocalized in osteoblasts during fracture repair, 2~ as well as BMPR-1A and BMPR-1B, 21~the receptors for BMP-4 and BMP-7. In vitro, BMPs stimulate osteoblast and chondrocyte differentiation and suppress myogenic differentiation in appropriate precursor c e l l s . 211'212 In summary, BMPs are expressed during embryogenesis and control the development of many organs, including the skeleton. In the adult organism, they induce osteogenesis when injected into muscle or dermis or next to bone. BMPs are being developed for the healing of nonunion fractures and repair of bone defects. B MP mRNA is expressed in adult bone and healing fractures. The role of BMPs in bone remodeling and their therapeutic potential for osteoporosis is not known. TGF-[3s the first proteins discovered in this family, also stimulate bone formation when injected locally in bone, but effects

CHAPTER 1 Embryologyand Cellular Biology of Bone on other systems, such as immunosuppression, may preclude its therapeutic use.

XI. OTHER GROWTH FACTORS (FGF, VEGF, PDGF, AND HGF) FGFs are a family of proteins, members of which were shown, as mentioned above, to be involved in skeletal development and potentially in bone formation. To date, nine FGFs, products of different genes, have been characterized. FGF-1 (acidic FGF) and FGF-2 (basic FGF) lack a signal sequence for secretion. FGF-3 or oncogene int2; FGF-4 or oncogene hst; FGF-5, also discovered as an oncogene; FGF-6, oncogene hst2; FGF-7, keratinocyte growth factor (KGF); FGF-8, androgen-induced growth factor; and FGF-9, gliaactivating factor which, like FGF-1 and FGF-2, lacks a signal sequence. The molecular weight of these singlepeptide chains is around 20 kDa; for FGF-2 and FGF-3 multiple spliced variants were reported. Major reported target cells for FGF-1 and -2 are endothelial and neural cells; for FGF-3, mouse mammary carcinoma; for FGF-4, Kaposi's sarcoma and limb development; for FGF-5, inhibition of hair elongation; for FGF-7, epidermis, wound healing, and branching morphogenesis; for FGF-8, androgen-dependent tumors; and for FGF-9, glial cells. Four human FGF receptors with 55% to 72% identity have been identified. 2~3They differ, both with respect to ligand affinity and tissue distribution. The FGFRs are subject to alternative splicing, which generates receptors with different numbers of extracellular Ig-like domains involved in ligand binding. The intracellular domains contain the tyrosine kinase, which is activated following receptor dimerization and phosphorylates downstream targets in the MAP kinase cascade. Alternative splicing of FGFR-1 a n d - 3 is tissue specific and generates significant tissue selectivity for FGF responses. 214 Virtually all receptor forms respond to FGF-1, the B exon of the receptor is expressed in epithelial tissue and the C exon in mesenchymal tissue. FGF-3 stimulates the B form of FGF receptor 1 and 2 and FGF-7, the B form of FGF receptor 2. These highly interesting recent observations provide fascinating insight into specificity achieved for this family of factors by alternative receptor splicing. In addition to these signal transduction receptors, FGFs also bind with low affinity to heparan sulfate containing proteoglycan-binding sites, which contribute to FGF interaction with its signaling receptors. 215 The role of various FGFs in skeletal development, deduced from its expression and mutations in FGF receptors, was reviewed above. FGF was shown to be expressed during fracture repair and to accelerate callus formation when exogenously applied. 36'216'217 It was re-

15 cently shown that systemic administration of FGF-1 or FGF-2 into rats increases bone formation. 218'219 In vitro, FGFs are potent mitogens for osteoblastic cells and in some systems suppress the expression of phenotype-related genes, 43,aa~but FGF also increases the formation of mineralized nodules from bone marrow stromal cells. TM Since FGF is produced by endothelial cells, as well as osteoblasts, and was shown to upregulate the expression of TGF-[3222 in osteoblastic cells, it could play a role in cell-cell communication associated with bone formation. Vascular endothelial growth factor (VEGF), also known as vascular permeability factor (VPF), is produced in four isoforms of 206, 189, 165, and 121 amino acids. The 165 AA is the predominant form. These molecules act as dimers and, like FGF, bind to sulfated proteoglycans. VEGFs are among the most potent and selective angiogenic factors. 223 VEGFs are up-regulated in response to hypoxia, providing an in vivo feedback loop for increased tissue oxygen perfusion. 224 VEGF has been implicated in the hypervascularization associated with retinopathies and tumor growth. 225'226 In bone cells, VEGF was shown to be up-regulated by PGE2 via cAMP-mediated mechanism, 85 possibly participating in the osteogenic effect of prostanoids. Glucocorticoids suppressed VEGF expression in bone cells. Two types of VEGF receptors have been identified. The c-fms-like tyrosine kinase, fit-1227 and the kinase domain-containing receptors K D R . 228 B o t h are about 1300 amino acids long and have seven extracellular Ig-like domains. Deletion of either receptor by homologous recombination in mice is lethal by day 8 or 10 of embryonic life. KDR knock-out causes total absence of vascular endothelial cells; whereas, fit knock-out results in poor organization of blood vessels. 229-231 The production of VEGF by osteoblastic cells and the known importance of angiogenesis for osteogenesis suggests that this growth factor may play an important role in bone metabolism. Platelet-derived growth factor (PDGF) is a 30-kDa polypeptide. There are two forms, A and B, and only the dimeric chains AA, B B, or AB are biologically active. Similarly, there are two PDGF receptors, et and [3, single-peptide chains with 44% identity. These transmembrane receptors have a tyrosine kinase cytoplasmic domain, related to the CSF-1 receptor, and to the kit oncogene. PDGFA binds primarily to receptor et and PDGFB to both. Like for other growth factors, receptor activation is induced by dimerization in the presence of ligand. PDGFA is expressed in rat osteoblasts and its expression is up-regulated by TGF-[31 or PDGE Both PDGF AA and BB are potent mitogens for osteoblastic cells in culture. As expected from the reciprocal relationship be-

16


tween proliferation and differentiation, they suppress collagen synthesis and matrix production. PDGF levels are elevated during fracture repair. The high abundance of PDGF in the clot following fracture makes it a strong candidate for action during the initial phases of callus formation. There is no knowledge if it plays a role in later bone formation and remodeling. 232 Hepatocyte growth factor (HGF) or scatter factor is a heterodimer consisting of a 60-kDa oL and a 30-kDa [3 chain connected by a disulfide bond. HGF has multiple types of effects on many tissues in the body, including proliferation, motility, inhibition of growth, effects on differentiation, adhesion, etc. 233 The HGF receptor is the m e t protooncogene, a heterodimer of a 50-kDa extracellular and 145-kDa transmembrane peptide with a cytoplasmic tyrosine kinase domain, both produced from a single-peptide chain by proteolytic cleavage. TM HGFR is expressed in normal epithelium melanocytes, endothelial cells, microglial cells, neurons, hematopoietic cells and, of course, liver cells. HGF levels increase markedly during liver regeneration following ablation. HGF was shown to play a role in organogenesis and embryonic development and its deletion causes embryonic lethality. During development, it is expressed in lung, kidney, and the central nervous system. An HGFlike receptor called RON was shown to be highly expressed in hematopoietic stem cells and monocytes. It was recently reported that HGF promotes osteoclast formation.125-127 Except for this observation, not much is known so far on the role of HGF and skeletogenesis.

XII. C E L L - M A T R I X INTERACTIONS In multicellular organisms, all cells are connected by cell-cell and cell-matrix contacts. For tissues such as bone, where matrix is not only very abundant but important for one of its major functions, mechanical support, cell-matrix interaction has particular importance. There are several ways in which the matrix is likely to influence cell function. During development, the matrix has been shown to play an instructive function in cell migration and differentiation. In vitro, nontransformed mesenchymal cells require attachment to matrix for proliferation and similar dependence may operate in vivo. It was shown that the signals induced by fibronectin attachment lead to the expression of cylin D1,17~ a molecule required for cell cycling. The matrix can store growth factors" FGFs, IGFs, PDGF, and TGF-[3 have all been purified from bone matrix. And last but not least, in bone the matrix probably influences cell behavior by deforming under mechanical loads and transmitting this information to the cells. The primary adhesion receptors through which cells attach to the matrix are the inte-

grins. 174 Integrins are heterodimeric, transmembrane receptors. They contain an oL chain of 120 to 150 kDa and a [3 chain of 90 to 210 kDa, connected by disulfide bridges. Both have very short intracellular domains, which interact with the cytoskeleton via cytoskeleton attachment proteins, such as paxillin, vinculin, tallin, and oL-actinin, and participate in signal transduction. There are at least nine oL and a similar number of [3 chains coded by separate genes and the pairing between o~ and 13 chains, which is not unique, determines the preference for ligand binding. For example, oL2131for type 1 collagen; c~5131for fibronectin; OL4[~1 for laminin; O[v~l, O~v~3, OLv[35for vitronectin; and so on. Binding requires calcium and ligand specificity is not unique; for example, OLv[33 also binds fibronectin, osteopontin, bone sialoprotein, etc. The integrins present in osteoblasts include a2131, the collagen receptor; 0L5131, the fibronectin receptor; and 0~v[35, the vitronectin receptor. 137 Integrins are probably involved in the deposition of the extracellular matrix and may carry out the highly organized deposition of collagen fibers in bone. Beta1 integrins were shown to mediate gel retraction in fibroblasts in vitro. 235 Conversely, the integrins probably mediate the perception of matrix deformation in response to mechanical stress, which was shown to correlate with bone formation: reduced bone formation under conditions of immobilization or weightlessness and increased bone formation with mechanical stimulation. In smooth muscle cells, which also respond to mechanical strain, that response was blocked by integrin antibodies. 236 The major osteoclast integrins are OLv[33and av[31, the vitronectin receptors which bind osteopontin and bone sialoprotein, and OL2[~1 the collagen receptor. 137 Osteoclast precursors may also have some of the [32 integrins found in monocyte/macrophages, such as MAC-1. A role for integrins, especially OLv[33,has been strongly implicated in osteoclast function (see above). Antibodies against OLv[33,as well as snake venoms which bind preferentially to this receptor, echistin and kistrin, were shown to inhibit osteoclast activity in vitro and bone resorption in v i v o . 153"237 The precise mechanism for this inhibition has not been determined. It could be due either to interference with osteoclast attachment, osteoclast activation, or osteoclast migration. It was shown in the osteoclast that the addition of OLv[33ligands can produce a surge in intracellular calcium. 238 Osteoclast activity was also reported to be influenced by mechanical function, but it is not known if this is a direct or indirect effect. To summarize this section, cell-matrix interaction is likely to play an important role in osteoblast and osteoclast differentiation and function. Given the mechanical function of the bone matrix and the effects of mechanical loads on bone remodeling, cell-matrix interaction

CHAPTER 1


s h o u l d p l a y a r o l e in t h i s p r o c e s s . I n t e g r i n s , t h e c e l l u l a r a d h e s i o n r e c e p t o r s , a r e l i k e l y to m e d i a t e t h a t i n t e r a c t i o n .

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~HAPTER

The Nature of the Mineral Phase in Bone: Biological and Clinical Implications M E L V I N J. G L I M C H E R

Laboratory for the Study of Skeletal Disorders and Rehabilitation, Department of Orthopaedic Surgery, Harvard Medical School, Children's Hospital, Boston, Massachusetts 02115

I. Biological Functions of the Mineral Phase II. The General Nature of the Mineral Phase in Bone and the Changes that Occur with Time III. Postulated Phases Other than Apatite as the Initial Solid Ca-P Mineral Phase Deposited in Bone

IV. Crystal Size and Shape V. Recent Studies of the Structure of Bone Apatites and the Applications of these Data to Clinical and Experimental Abnormalities and Diseases of Bone References

The subjects that will be presented in this chapter are: (1) The nature of the mineral phase in bone; that is, the chemical composition and crystal structure of the solid calcium-phosphate (Ca-P) mineral phase in bone, and the changes that occur in the mineral phase p e r se with time and maturation; (2)the relationship of these maturational changes which occur with time to the biological, physiological, and mechanical functions of the crystals and to Ca and P mineral metabolism; and (3) the ultrastructural location of the mineral phase and its relationship to the basic underlying physical chemical mechanism responsible for the initiation of calcification.

extent on the exact size, shape, chemical composition, and crystal structure of the mineral crystallites. The mineral phase acts on the one hand as an ion reservoir and on the other hand as an excellently designed structural material that determines in large part the mechanical properties of b o n e s u b s t a n c e (the structural material), and consequently of bone tissue and of bone as an organ. The importance of the role of bone mineral as an ion reservoir can be appreciated from the fact that about 99% of the total body calcium, about 85% of the total body phosphorus, and from --~ 90% and --~ 50%, respectively, of the total body sodium and magnesium are ass o c i a t e d with bone crystals, which consequently serve as the major source for the transport of these ions to and from the extracellular fluids. As a result, the bone crystals play a critical role in maintaining the concentrations of these and other ions in the extracellular fluid (homeostasis), which are critical for a variety of physiological functions (e.g., nerve conduction, muscle contraction)

I. BIOLOGICAL FUNCTIONS OF THE MINERAL PHASE The solid Ca-P mineral phase in bone performs two major functions, both of which depend to a significant METABOLIC BONE DISEASE

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24

MELVIN J. GLIMCHER

and many other important biochemical reactions. For some of the ions like Ca, the critical physiological concentration of this ion must be maintained in the extracellular fluids within a very limited narrow range, not only for normal functioning of a variety of tissues such as the nervous system, but for the viability of the organism. From the structural standpoint, the mechanical properties of the bone substance result from the impregnation of the otherwise soft, pliable organic matrix of bone tissue by the rock-like but brittle Ca-P crystals of apatite which converts the soft organic matrix to a relatively hard, rigid material (bone substance). The bone substance (cells, organic matrix and bone mineral) is therefore a material that scientists and engineers refer to as a two-phase or multiple-phase composite material whose combined properties are quite different than the simple algebraic sum of its components. In the case of bone, the Ca-P crystals are extremely brittle, and the collagen is very flexible with little to no compressive strength but very high tensile strength. When the collagen and the mineral phase are combined in the very special way as they exist in bone at the molecular and ultrastructural level (see later sections), it creates an essentially twophase, composite material or substance with mechanical properties quite unlike a simple addition or mixture of the two components. Instead, the two-phase substance is particularly tailored to most efficiently provide the structural material or fabric from which the microscopic and gross elements are fashioned, viz., the trabecular bony, lace-like network of cancellous bone and the osteones (and other architectural microscopic structures in nonosteonal bone) of compact bone (Fig. 2 - 1 , see Color Plate). As in any gross structure, the three-dimensional

disposition of the individual building elements is critical and enables the assembly of the structural units to withstand the particular forces and stresses applied to the structure as a whole. The same is true of the arrangements of the osteones of compact bone with respect to the three-dimensional shape of the gross bone (skull, long bones), and indeed of the disposition and orientation of the collagen fibrils and fibers in individual lamellae of the osteones, and the axial deviation of the collagen fibrils and fibers from one lamella to another. Moreover, recent evidence has demonstrated that this plywood-like structure also rotates around the long axis of the osteone ("twisted plywood sheets") elegantly described by Boulignand and Giraud-Guille 1-3 (Fig. 2 - 2 ) . All of these elegant three-dimensional (3-D) relationships of the microscopic architectural elements of bone substance (for example, the 3-D spatial orientation of the long axes of the osteones with respect to the long axis of a long bone, the 3-D spatial orientation and disposition of the orientations of collagen fibers and mineral components of the individual lamellae of the osteones, and the 3-D relationship of the orientations of collagen fibers of one lamella and its adjacent lamellae) vary from section to section in the same bone depending on the kind, intensity, and distribution of the stresses on the particular volume of bone sampled. As will be pointed out later in the chapter, the mineral crystallites of apatite are also elegantly ordered, spatially distributed, and oriented with respect to the individual collagen fibril within which they are located. 4 Even at an intermediate level of the anatomical hierarchy, the collagen fibrils in individual collagen fibers

FIGURE 2--2 Schematicdemonstrating that there is an additional axial rotation of the collagen fibers in each of the lamellae of an osteon. (Courtesy of Dr. Marie-Madeleine Giraud-Guille.)

CHAPTER 2

The Nature of the Mineral Phase in Bone

25

FIGURE 2 - 3 Electron micrograph of compact lamellar bone of chick diaphysis. Note that the apatite crystals are not only distributed axially along the long axis (horizontal in the photograph) of the individual collagen fibrils but that they are also in lateral register (vertical dimension of photograph) as well.

are arranged in lateral register over relatively large distances and v o l u m e s of the bone (Fig. 2 - 3 ) . At the next higher level of the a n a t o m i c a l hierarchy, the 3-D organization and spatial distribution of bone as a tissue is equally well organized and ordered to m e e t the m e c h a n i c a l forces applied, viz., the 3-D spatial distribution of the cancellous trabecular plates and sheets so clearly o b s e r v e d in the femoral head and n e c k (Fig. 2 - 4 ) . The same is true of the shape, contour, and distribution of bone as an organ. As examples, note the femur, where there is a specific and appropriate angle of the femoral head and neck to the shaft of the bone to m a x i m i z e hip function and the efficiency of the muscles which supply the p o w e r for m o t i o n and the distribution of forces onto the shaft, and the changing crosssectional profile and variable thickness of the hollow shaft of a f e m u r (see Fig. 2 - 5 ) and other long bones which are reflections of the intensity and distribution of the local stresses applied to the bone at that particular position along the length of the diaphysis. The diaphyseal long bones are hollow rather than solid cylinders, because the m a x i m u m stresses on a cylinder subjected to bending forces occur in the structure farthest f r o m the center or centroid. Thus the m o s t efficient way to distribute the bone mass and use the least a m o u n t of material while also decreasing the weight of the cylinder is to concentrate the bone substance at the outer circumferential periphery of the cylinder. Thus bone, at all levels of the a n a t o m i c a l hierarchy from the gross shape of a bone as an o r g a n , its organ-

FIGURE 2--4 Human femoral head and neck. Note the highly specific organized distribution of the elements of the cancellous tissue (trabecular plates) which correspond very closely to the distribution of mechanical stresses imposed on mechanical loading of the femoral head. Note also the increased mass of the bone substance along the medial wall of the cortex of the upper portion of the femoral neck which is subjected to a great deal more compressive force than the lateral wall due to bending stresses.

26

MELVIN J. GLIMCHER

FIGURE 2--5 A, Cross-sectional slices of the femoral shaft showing different overall profiles and different mass distribution of bone substance within the profiles. This is felt to be regulated by the intensity and nature of the stresses induced by the forces applied to the femur. B, Young lamb tibia. Note flaring of upper end, which articulates with lower end of femur, and marked differences in cross-sectional profiles of lower and upper ends of the bone. (Courtesy of Nicholas Nehamas, Princeton, NJ.)

ization as a tissue, and the manner in which the molecular components are combined to form a multiple-phase composite structural material (bone substance), is very efficiently designed to meet both its mechanical and its multiple biological functions as well.

The distribution of the cancellous bone tissue (e.g., femoral head and neck) and bone substance in various locations along a diaphyseal shaft results in a marked economy in the amount of bone substance needed to meet the mechanical stresses to which it is subjected.

CHAPTER 2 The Nature of the Mineral Phase in Bone Even the flaring out and broadening of the ends of the long bones is an excellent design to increase the surface of the articular cartilage at the ends of bones where they articulate with the articular cartilage of the other bone of the joint. Thus by increasing the surface area of the articular cartilage which bears the load, the stress (force per unit area) applied to the cartilage is decreased significantly. All of these highly ordered geometrical and spatial characteristics of bone as a substance, a tissue, and an organ emphasize how the overall skeletal system has been biologically fashioned in order for bone to function most effectively as a structural substance, as a tissue (cancellous and compact bone), and as an organ (femur, rib) to meet its many physiological and specific mechanical functions (Fig. 2 - 6 ) . Later we will also point out that many of these characteristics as well as the size, shape, specific area, and overall area of the inorganic crystals as well as their location and relationship to the collagen fibrils have also been extremely well designed to meet their biological functions as an ion reservoir for homeostasis of the extracellular fluids, to facilitate their interaction with specific organic components of the matrix and certain bone cells (see below), and to fashion bone substance as an outstanding and efficient structural material. As noted above, recent evidence has indicated that the bone crystals are not only important biologically as an ion reservoir maintaining the ionic homeostasis of the extracellular fluids, and as a major structural element in determining the mechanical properties of bone substance, but they may also play important local roles in cell and matrix interactions that help regulate bone matrix synthesis and resorption 5-8 (Fig. 2 - 6 ) . An example of a crystal-matrix protein-cell signal interaction is the experiment that demonstrated that when osteocalcin (a non-collagenous bone matrix protein) was bound to apatite crystals and implanted in the subcutaneous tissues of an experimental animal, it chemotactically induced a migration of large monocytic cells to the crystal-osteocalcin complex where the cells proceeded to differentiate to active osteoclasts and resorbed the crystals. When the crystals alone were implanted, or when they were coated with albumin, a serum protein found in relatively large concentrations in bone and which probably is bound to the crystals, they initiated a typical macrophage inflammatory response. The cells did not differentiate to osteoclasts and the crystals were not resorbed. 6 These data may explain in part a characteristic feature of tickets, characterized by a marked diminution in the amount of apatite crystals deposited in the organic matrix of bone and cartilage, and in which the rate of the endochondral sequence of ossification is decreased. This occurs despite the fact that the normal sequence (but not the rate) of the cellular

27

FIGURE 2--6 Venndiagram showing the interactions between the internal and surface receptors of the cells and their gene expressions, of the constituents of the organic matrix, and the inorganic crystals of apatite. (Courtesy of Dr. Peter Hauschka.)

differentiation of the cartilage cells of the growth plate is maintained. However, the diminution or failure to calcify the hypertrophic zone of the cartilage matrix is accompanied by a very marked decrease in the invasion of the hypertrophic cartilage by blood vessels and osteoclasts (chondroclasts), and the subsequent formation of bone on the surfaces of the calcified cartilage by osteoblasts accompanying the blood vessels, possibly in part, because of the very significant decrease or absence of the mineral phase in the matrix of the hypertrophic zone of the growth plate. Consequently, there is a marked decrease in the amount of, or even a lack of, osteocalcin bound to the mineral phase. Similarly, it may also help explain why the more mineralized portions of bone are preferentially resorbed by osteoclasts during the normal turnover and remodeling of bone. Although not a direct function of bone mineral or of bone tissue, bone as an organ does provide for another important general physiological function: the marrow spaces, especially of cancellous bone, act as a host or depository for the precursors of the blood cells as well as the progenitor cells of bone. Conceptually, it is not surprising that the crystal structure and the fine, short-range 3-D order of the crystals and the environment of the reactive groups, especially on their surfaces, determines to a large extent their physical chemical reactive properties, and thus their potential biological functions. This dependence of physiological and biological function on the 3-D spatial distribution of the ion and atom constituents of the crystals is similar to what has been found for other biological components such as proteins. In addition, a very important physiological poifit to note is that like some of the other com-

28 ponents in bone such as the collagen, for example, significant changes occur in the composition, short-range order, and surface chemistry of the crystals as a function of the time that the crystals are present in the tissue (i.e., the age of the crystals). These maturational changes significantly alter their interaction properties and consequently their biological, physiological, and structural functions. Thus a " y o u n g " apatite crystal not only differs in its composition from an " o l d " apatite crystal, but also in its short-range order, surface composition, and structure. Importantly, the environment, lability, and reactivity of the surface constituents of the crystals, especially of the HPO4 and CO3 groups, are also significantly different. All of these changes in the crystals change their interaction properties and therefore their potential participation in a variety of biological and chemical functions. Thus any change in the relative rates of bone formation and bone resorption that significantly alters the age distribution of the crystals in bone will also directly alter their role in both mineral metabolism and in the mechanical properties of bone as a substance and as a tissue. It is precisely because the biological functions of the bone mineral ultimately depend on the precise chemical composition, physical chemical properties, and crystal structure of the mineral phase that so much attention has recently been directed at elucidating and clarifying these characteristics. 9-43 It is important to keep in mind that significant changes in both the chemical composition and structure occur in the mineral phase with time (i.e., the mineral phase changes with time after its initial deposition in the tissue). As will be discussed in some detail in a subsequent section, these changes in the mineral phase that occur after their initial deposition in the tissue (the maturation of the crystals) must be kept in mind when attempting to understand and correctly interpret the overall changes in mineral metabolism in vivo either as a function of the age of the organism and more importantly when trying to explain the serum and other changes (e.g., 45Ca uptake and disappearance) observed in normal subjects and especially in patients with metabolic bone diseases, in which the rates of bone formation and resorption have been significantly altered. In these latter instances, the amount and proportion of new bone and old bone, and therefore of the proportion of young crystals and older crystals, has also been markedly changed. This in tum significantly alters the population distribution of bone mineral as a function of bone mineral age and consequently of their physical chemical interaction properties and their biological functions. This makes it impossible to derive a direct relationship between the rate of new bone formation or resorption and new mineral deposition using the uptake, rate of uptake, or rate of disappearance of 45Ca from the serum after

MELVIN J. GLIMCHER

infusing it into the bloodstream and comparing these data with "normal" values or previous values of the patient or of normal standards: the solid mineral phase that is interacting with the ions in the extracellular fluids such as 45Ca is not the same mineral phase that was present under normal circumstances before the rates of bone formation and/or resorption and new mineral deposition were altered by disease or metabolic changes. In the case of an increase in new bone formation, for example, the very young crystals, now making up a larger proportion of the crystals exposed to the extracellular fluids containing 45Ca than existed under normal physiological conditions, are also more reactive and, therefore the 45Ca will not only be more rapidly incorporated into the newly forming crystals of the new bone, but the newly formed crystals will continue to exchange with 45Ca more readily than the older crystals even after their initial deposition. Thus the uptake rate and disappearance rates represent both the fact that there are more crystals being formed and the fact that the new crystals formed and for some time thereafter will continue to exchange more rapidly with 45Ca. Unfortunately, such considerations are rarely taken into account in clinical studies, which may in part account for some of the significant discrepancies noted in metabolic studies between predicted bone and bone mineral accretion and tumover values and those actually observed and measured directly.

II. THE GENERAL NATURE OF THE MINERAL PHASE IN BONE AND THE CHANGES THAT OCCUR WITH TIME The bone mineral has been known by chemical analyses to contain calcium and phosphorus as its principal constituents for over 150 years and since 1894 to be a calcium phosphate carbonate. 44 The first reports of its crystal structure were published by DeJong 45 and Roseberry et al. 46 Both groups of investigators identified the bone mineral as a hydroxyapatite (HA) based on the reflections generated by x-ray diffraction. Unfortunately, progress in identifying in detail the exact chemical composition and specific spatial arrangement of its constituents at any stage of its development (i.e., from its initial deposition to the final mature mineral) has been very slow. Indeed, these parameters are still not known in detail more than 70 years after the bone mineral was first identified as an apatite similar to HA by DeJong. 45 The obstacles that have prevented a definitive resolution of the problem are manymbiological, crystallographic, and technical (for a review, see Elliott29). In the first place, the apatite phase in bone is very poorly crystal-

29

CHAPTER 2 The Nature of the Mineral Phase in Bone line, generating only a few broad and poorly resolved xray diffraction reflections which by themselves do not permit one to assign to it a unique crystal structure or composition (i.e., one cannot differentiate by x-ray diffraction and chemical composition between a number of similar apatitic or apatite-like structures). Indeed, a number of what appear to be closely related but distinct chemical and structural Ca-P compounds give the same or very similar apatitic x-ray diffraction patterns. The poor x-ray diffraction pattern generated by the bone mineral has also precluded the detection of small amounts of Ca-P compounds other than and in addition to apatite. Chemical and physical analyses of bone mineral has also demonstrated that the bone mineral contains small but significant amounts of ions not present in pure HA, such as HPO 2- and CO3, both of which play highly significant roles in the physical, chemical, and interaction properties of the crystals and thus in determining their potential biological and mechanical functions. The ideal stoichiometry and the Ca-P molar ratio of hydroxyapatite, 1.67, is also rarely found in bone, especially in very young bone mineral which has a Ca-P ratio significantly less than 1.67. The bone mineral has also been shown to contain very strongly bound and/or ultrastructurally trapped water; but water is not a true constituent of the pure crystals or HA which has a constituent unit cell and overall formula, Cal0(PO4)6(OH)2. As will be described in detail later, bone apatite is not hydroxyapatite. It is a Ca-deficient apatite, either due to a substitution of Na or Mg for Ca, 47 or a true deficiency of Ca ions not substituted for by another cation, in which electrical neutrality is accomplished by the addition of protons to form HPO4 groups accompanied by the creation of crystal vacancies, 48 or both. The crystals contain both HPO4 and CO3 ions in various different environments and locations within the lattice structure and on the surface of the crystals, which change as a function of time. The crystals do not contain O H groups: they are not an hydroxyapatite. The critical ratio of the important calcium ions in bone mineral is therefore Ca Ca 1217 Ca P + CO-----------~'not -p-. ' The p + CO3 ratio provides an in-

the initial Ca-P solid phase formed in bone has been postulated by several investigators to be a Ca-P solid phase structurally and chemically different than apatite: a precursor solid phase that undergoes a solid state transformation to apatite or dissolves and is recrystallized and replaced by apatite. The two most prominent candidates postulated are (1) an amorphous (non-crystalline) Ca-P solid referred to as amorphous calcium-phosphate ( A C P ) 49-52 and (2) a crystalline calcium-phosphate, octocalcium phosphate (OCP) [Ca8(HPO4)2(PO4)4 9 5 H 2 0 ] , 53'54 which has many crystallographic and compositional features similar to apatite, but importantly contains crystalline water as an integral constituent of its lattice structure. 55-64 The conceptual and experimental basis for the proposition that the initial Ca-P solid phase formed during the calcification of bone is an amorphous and not a crystalline solid was introduced in 1966 by Eanes, Termine, Posner, and colleagues 49-52 (Fig. 2 - 7 , see Color Plate). Their proposal was based on the fact that the x-ray diffraction pattern generated by bone from the youngest animals contained only a few and more poorly resolved broader diffraction peaks than the diffraction patterns generated by bone from older animals--indeed, there is a progressive increase in the overall quality of the diffraction patterns generated, sharper, less broadened, and better resolved reflections, viz., the crystals are "more crystalline" with increased age (Fig. 2 - 8 ) . These inves-

8

dex of the vacancies in the crystal lattice.

III. POSTULATED PHASES OTHER THAN APATITE AS THE INITIAL SOLID CA-P MINERAL PHASE DEPOSITED IN BONE A. A m o r p h o u s C a - P Although the Ca-P crystals of even young bone generate an x-ray diffraction pattern of apatite, the nature of

,~Z)~

45 ~

40 ~

3,5~

30 ~

2.5~

20 ~

FIGURE 2--8 X-ray diffraction patterns generated from the midportion of the diaphysis of chick bone as a function of age. A, Seventeen-day embryonic (periosteal scrapings). B, Five-week postnatal chick. C, Two-year-oldpostnatal chick. D, Standard, highly crystalline synthetic hydroxyapatite. (From Bonar LC, Rouffose AH, Sabine WK, et al: X-ray diffraction studies of the crystallinity of bone mineral in newly synthesized and density fractionated bone. Calcif Tissue Int 35: 202-209, 1983.)

30 tigators reasoned that this phenomenon could arise not only from the fact that the younger crystals were smaller but also because there was more disorder in the structure of the individual crystals. Indeed, they postulated that if one extrapolated this relative disorder in the crystal lattice to the initial Ca-P solid phase formed, it was possible that the initial solid phase was completely disordered, viz., it had no long range order at all, it was amorphous (Fig. 2 - 7 , see Color Plate). They also postulated that with time the amorphous phase was replaced or underwent a solid phase transition to apatite. They based their hypotheses on the concepts outlined and on a series of in vitro precipitation experiments, in which they followed the structural and chemical composition of the Ca-P solids formed in vitro from solutions of Ca and P at neutral or slightly alkaline conditions as a function of the time elapsed after a solid phase was formed. They found that the first solid phase formed was indeed amorphous by x-ray diffraction. With time, the amorphous Ca-P solid phase in contact with the original mother liquor progressively converted to typical, poorly crystalline apatite similar in its x-ray diffraction characteristics and chemical composition to bone apatite. A similar set of experiments using rat bone from animals varying in age from very young postnatal animals to mature animals revealed, as already noted, very poorly crystalline apatite assessed by x-ray diffraction from the very youngest animals, which gradually improved (more "crystalline") with increasing age and maturity. Using an indirect method based on the ratios of the intensities of the apatite reflections and the total Ca-P contents of the samples compared with similar ratios from a series of standards composed of various proportions of synthetic amorphous Ca-P and crystalline apatite, they calculated that a very significant amount of the Ca-P solid phase of the very young bone was not contributing to the x-ray diffraction reflections (i.e., this portion of the Ca-P mineral phase was therefore "amorphous"). Moreover, the amorphous fraction (ACP) decreased with increasing age of the animals. They concluded from these data and their calculations that the very major Ca-P solid phase in the bone matrix of the youngest animals consisted of A CP. Importantly, because the percentage of ACP diminished only very slowly as a function of age, viz., the rate of ACP deposition was greater than the rate at which ACP was converted to poorly crystalline apatite, they concluded that not only was ACP the initial Ca-P solid phase formed, but it remained the major constituent of the mineral phase throughout the continued development and maturation of bone and the accretion of additional mineral phase almost to the point of complete mineralization. The ACP theory was a very attractive hypothesis: It accounted for the progressive change in chemical com-

MELVIN J. GLIMCHER

position with age and maturation as the proportions of ACP and poorly crystalline apatite changed. It explained the increasing intensity of the x-ray diffraction intensities with time as more and more of the ACP (which does not generate or contribute to the intensities of the x-ray diffraction reflections) was converted to poorly crystalline apatite. The ACP formed in vitro also had a low Ca-P ratio, contained tightly bound or crystalline H20, and had other characteristics of newly deposited bone mineral. It is not surprising, therefore, that the ACP theory of the nature of the initial deposits of Ca-P in bone and the changes that occur in the mineral during maturation received very wide international acceptance for more than 20 years. However, as more and more experimental data were compiled, and other structural and compositional factors were taken into account, such as the fact that the bone mineral contains carbonate and HPO4, constituents which change in concentration and in their environment with time and significantly alter the x-ray diffraction characteristics, and the fact that bone apatite is calcium deficient either due to replacement with other cations such as Na and/or M g 47 and/or a true deficiency of Ca ions creating spatial vacancies 48 or both, all of which were found experimentally to change the x-ray diffraction patterns of synthetic apatite standards, some doubt was cast on the validity of the indirect method of determining whether ACP was present in bone mineral and, if so, the quantitative proportion of ACP relative to the total Ca-P mineral phase present. When all of these and other factors were taken into account, the calculated proportions of ACP in bone mineral markedly decreased. Indeed, the ACP content of some samples of young bone previously calculated to contain 70% or more of ACP was now recalculated to be less than one-half of this value. Similarly, a sample of mature bone previously found to contain a significant amount of ACP was now calculated to contain less than 10% ACE an amount indistinguishable experimentally from samples containing no ACE

B. O c t o c a l c i u m - P h o s p h a t e ( O C P ) In the case of OCP, the choice of this crystalline component as the initial Ca-P mineral phase deposited in bone was based on the very close similarity in crystal structure and composition to HA; the very easy and rapid conversion of OCP to HA in vitro; theoretical and experimental thermodynamic and solubility studies; and the presence of water in bone apatites even at very high elevated temperatures which could, at least in part, be accounted for by the presence of water in OCP, particularly in young bone. In the case of both ACP and OCP as well as apatite, however, the obstacles that prevented

CHAPTER 2 The Nature of the Mineral Phase in Bone a clear-cut solution to the problem of defining the exact nature of the initial Ca-P solid phase deposited in bone were both biological and technical. From the biological point of view, there are clear data that significant changes occur in both the chemical composition and structure of the bone mineral with time after its initial deposition in the tissue. Consequently, the amount and proportion of new and old bone and therefore of young and older bone crystals also changes significantly as a function of the rate of bone turnover. During normal aging there is a progressive decrease in the rate of bone turnover and therefore there is a steady progression of a shift in the distribution of crystals as a function of the age of the crystals: there is a larger proportion of " o l d e r " crystals with increasing age of the animal and therefore a significant change in their reactivity and their ability to carry out their potential biological functions. Indeed, after the crystals reach a certain maturity, for example, little exchange of the carbonate groups is possible, even in vitro. 48 The relative rates of bone formation and resorption during the continuous remodeling of bone that normally occurs therefore results in an inhomogeneity of the crystals with respect to their age in any given gross or even microscopic sample of bone. Therefore, to experimentally determine the nature of the initial Ca-P solid phase and any transitional stages as the Ca-P solid phase matures to its final apatitic state, and the pathways and extent of the maturational changes in bone apatite, it becomes necessary to devise methods to obtain samples of bone that are homogeneous with respect to the age of the crystals. This is especially critical in the study of the nature of the initial crystals formed. Failure to recognize these biological impediments, and the use of whole bone samples to characterize the mineral phase provides data reflecting only the average properties of a heterogeneous sample of bone mineral containing various proportions of crystals ranging in age from the very youngest crystals to the very oldest crystals as a function of the age of the animal, has accounted for a good deal of the difficulty in characterizing the bone mineral and the changes that occur with time, and, most especially, in defining the nature of the initial CaP mineral phase deposited. The exception to this occurs in very young embryos such as embryonic chicks in which at the very earliest stages of bone growth and development, the rate of bone remodeling is extremely rapid and the total bone mass is turned over in 10 to 15 hours or less, and in slightly older embryos in 24 hours or less. Also, in very mature, old bone in which there is a very slow rate of turnover, 80% to 90% of the bone mineral was found to be in one density fraction when subjected to differential centrifugation. Thus, the errors due to heterogeneity of the age of the bone crystals are very much reduced but not eliminated if one uses whole

31 bone from very young embryos or from very mature postnatal animals. The third requirement was that one must utilize direct methods to detect the presence of ACP and/or crystal phases other than apatite, and use a variety of special techniques to characterize the solid phase. The problem of obtaining more homogenous samples with respect to the age of the crystals to study the initial very earliest deposits of the bone mineral as well as charting the changes that occur with time and maturation was solved in several different ways. First, by using the very youngest chick embryos as noted, and also in the very same embryos, scraping the very outer layer of the periosteal bony cuff of very young (i.e., 1 1- to 12-day) chick embryos in order to obtain the youngest and most recently deposited bone containing the youngest crystals. Third, it was also possible to obtain much more homogenous samples of embryonic and postnatal bone by differential centrifugation of finely milled bone in organic solvents. We note that we very early learned that exposure of bone crystals to water, for even very short periods of time, especially in the case of very young and highly reactive crystals, very quickly resulted in changes in the structure and composition of the crystals. This led to our development of non-aqueous methods to prepare sections of bone for electron microscopy and for structural analyses. 65 Indeed, for the spectral studies used to characterize the structure of the bone crystals, we extended the non-aqueous techniques to the cleaning and dissection of the bone. This is an important point, especially when dealing with the very youngest specimen in which the solid mineral phase is extremely labile and reactive and in which changes are rapidly induced when exposed to water. With regard to the physical chemical measurements, the bone samples were studied for the presence of ACP directly, using the technique of x-ray radial distribution function analysis (RDF) and high-resolution x-ray diffractometry. 66 In the case of OCP, there are several specific major x-ray reflections and specific spectral peaks when examined by Fourier transform infrared spectroscopy (FT-IR) and 31p nuclear magnetic resonance (NMR), which are unique to OCP and which can be used to identify definitively if this crystalline compound (OCP) is present. These x-ray diffraction reflections and unique spectral peaks of OCP were not present in bone mineral. 48 RDF analyses also failed to detect ACP in the mineral phase. The only crystalline Ca-P solid phase detected was apatite. Another obstacle in studying the very earliest bone mineral formed is the fact that in such samples containing the first crystals deposited, the overwhelming proportion of organic matrix present in the bone sample relative to the bone mineral can seriously alter the x-ray

32 and spectral characteristics of the mineral phase. Indeed, in the very youngest embryonic bone that we have studied to date, the presence of such an overwhelming proportion of organic matrix constituents completely obstructed the detection and characterization of the mineral phase by x-ray diffraction, FT-IR, and 31p NMR. Thus in order to examine the very earliest bone mineral, it was also necessary to develop techniques that would remove the organic matrix constituents from the bone, leaving only the bone mineral, and to accomplish this in a fashion that did not alter the crystal structure, chemical composition, or size of the crystals. This was only recently accomplished. 65 This not only permitted the direct visualization of the bone crystals free of organic matrix constituents by transmission electron microscopy (TEM), but also allowed us to characterize the composition of the very youngest crystals by x-ray diffraction, FT-IR, and 31p NMR spectroscopy. The method of isolating native crystals from biologically calcified tissues has also been successfully applied to progressively older bone and to other tissues such as calcified cartilage, 67 enamel, dentine, and to very old fossil samples of bone. It has also allowed us to chart changes in the size, shape, composition, and structure of the crystal as a function of age and maturation of the crystals. Using this technique, we were able to isolate the youngest bone crystals examined to date, obtained from the periosteal cuff of 7to 8-day-old chick femora. The concentration of the solid phase (i.e., the mineral content in the original tissue) varied from less than 1% to 2% (compared to ---66% in fully mineralized bone). When the isolated crystals were examined by electron microscopy, small crystals typical of bone apatite crystals were observed containing calcium and phosphorus identified by electron microscopic microprobe analysis, and identified structurally as apatite crystals by electron diffraction, x-ray diffraction, FT-IR, and 31p NMR spectroscopy. No evidence for the presence of ACP or OCP was obtained. The only crystalline solid phase detected was a poorly crystallized apatite (unpublished data). However, as we have pointed out in the past, 48 the failure to detect an ACP solid phase or a crystalline OCP phase does not rule out the possibility that ACP or OCP (or other compounds) may be precursors of apatite which are so rapidly and immediately converted to apatite that only an undetectably small amount of the solid phase remains in the tissue at any one time. Considering the extremely small size of the early crystals of bone, especially their thickness, in many cases no more than one unit cell, it is possible that the initial biologically formed, solid Ca-P, precursor phase formed prior to the poorly crystalline apatite phase, will be found to be a bidimensional structure whose short range and atomic and ionic organization and order is different from any crys-

MELVIN J. GLIMCHER

talline 3-D solid. However, for the moment, the only solid Ca-P phase detected even in the earliest stage examined is a very poorly crystalline apatite, distinctly and importantly different than hydroxyapatite. It is important to note the major differences between the possible presence of such an initial transitory Ca-P solid phase different than apatite which so rapidly converts to apatite that it cannot be detected even in the very earliest Ca-P mineral phase deposited in bone examined to date, and the original, amorphous Ca-P theory, 49-52 which concluded that the transition of the ACP to apatite was so slow that ACP was the major CaP solid phase present in bone throughout the development and maturation of bone until final maturity was reached, at which time ACP was markedly diminished or absent. Indeed, in experiments in which a sample of very young bone mineral was examined by both the indirect technique of Termine, Posner, et al. and by RDF, we found that 95% to 100% of the mineral phase was calculated to consist of ACP by the indirect method, whereas no ACP was detected by RDF analysis--only a poorly crystalline apatite phase was identified. At the present time, therefore, the available data do not support the ACP theory that an amorphous Ca-P solid phase is the first solid Ca-P formed during the calcification of bone, and that it remains as a major, albeit diminishing solid phase as a function of the age of the mineral phase. Similarly, there is no direct structural evidence that OCP is the initial Ca-P mineral phase present in bone or that it at any time is present in bone mineral at concentrations detectable by methods currently available. Further, more difficult experiments attempting to obtain data from even younger stages of the mineral phase will be necessary to establish the exact nature of the first nucleated solid phase of Ca-P. Until that is accomplished, the data to date have identified the initial earliest Ca-P solid phase deposited as nanocrystals of a Ca-deficient apatite, most likely containing vacancies as a result of a calcium deficiency, as well as the fact that it contains no OH groups. 27'28'68-71 The bone apatites contain HPO4 and CO3 groups, whose location and environments vary with the age of the crystals. Moreover, 31p solid state NMR spectroscopy has revealed that the HPO4 groups in bone mineral are unique and unlike those present in OCP, brushite (CaHPO4 92HzO) or any other solid phase of Ca-P containing HPO4 including synthetic apatites. 21

IV. CRYSTAL

SIZE AND SHAPE

As noted, the presence of significant amounts of organic matrix constituents in bone has been a major obstacle not only in defining and characterizing the earliest

CHAPTER 2 The Nature of the Mineral Phase in Bone mineral phase formed, but also in the elucidation of the habit and size of the crystals and their internal fine structure. With regard to crystal shape (habit) and size, the problem is further compounded by the intimate relationship of the very small mineral crystals and the collagen fibrils within which the crystals are embedded and their dense accumulation in the tissue (Fig. 2 - 3 ) . However, when viewed in sections by high resolution electron microscopy, one observes regions where the crystals have extremely low electron densities over a relatively broad area, and others where the crystals are seen as very thin and very electron dense lines (Fig. 2 - 9 ) . Both observations are very suggestive and consistent with the conclusion that the crystal habit is that of very small, very thin plates (nanocrystals), first observed by Robinson and Bishop in 1950, 72 Robinson in 1952, 73 and later confirmed by others. Unfortunately, the dense packing of the crystals and their very low density when viewed approximately at fight angles or even obliquely to the surfaces of the putative flat crystal plates, both of which obscure the outlines of the individual crystals, as well as a lack of knowledge of the exact angle at which the crystals are being viewed, have precluded an accurate description of the exact size and shape of the crystals as determined by standard T E M of tissue sections, or of the changes in their size, shape, composition, and electron

33 diffraction characteristics that may occur with normal aging and maturation of the crystals, or in pathological conditions. This is especially true in the more heavily mineralized regions of bone. Nonetheless, the conclusion that the crystals are plate-like, based on the data noted above, is consistent with observations made on such sections when the specimens are tilted in a goniometer device in the electron microscope. 74-76 Recent topographic, 3-D computer reconstruction analyses of thick sections of calcified and ossified turkey tendon using high voltage electron microscopy 77 have not only vividly delineated the relationship between collagen fibrils and the inorganic crystals but have also provided very convincing evidence that the crystals are thin plates. On the other hand, results from early and more recent studies in which attempts have been made to determine the size and shape (habit) of the crystals in bone and other collagenous-rich tissues by indirect methods such as small angle x-ray scattering 78-85 have indicated that the crystals in bone are needle-like rather than thin plates. Similar conclusions have also been reached from T E M studies of young newly formed bone crystals in tissue sections. 86 The length of the crystals and their a/b size measurements have also been estimated on calculations based on the extent of line width broadening of the few resolved or partially resolved x-ray diffraction peaks. However,

FIGURE 2--9 Electron micrograph of an unstained, longitudinal section of young undecalcified embryonic chick bone. The dense mineral phase appears to "stain" the collagen fibril at regular intervals along its axial length. In some areas, the inorganic crystals can be seen on edge as dark lines. This may be the result of the plate-like crystals being viewed on edge or as bent or folded plates.67 Most of the mineral phase is not resolvable into individual crystals. The very low electron-dense regions consist of the plate-like crystals lying fiat on the grid. This indicates that the crystals are very thin.

34

MELVIN J. GLIMCHER

such measurements are probably equally or more dependent on the degree of disorder in the crystal structure than on their size. The results obtained by small angle x-ray scattering and modeling have been questioned on theoretical and conceptual grounds based on the fact that such measurements must be made on particles that do not interact with each other, a situation that does not exist in the case of bone containing relatively immobile, close packed, interacting bone crystals. Indeed, Wachtel and Weiner 87 have in an elegant experiment demonstrated that when bone crystals are examined by small angle x-ray scattering in bone tissue, the ratio of 1/w indicates that they are needles, whereas when isolated crystals are extracted and dispersed in ethanol and the small angle x-ray scattering measurements repeated, the 1/w ratio clearly indicates that they are plates. Importantly, one should also note that small angle x-ray scattering does n o t provide direct m e a s u r e m e n t s of the crystals in any dimension, but merely the r a t i o s that depict shape. We believe that the electron microscopic observations of isolated bone crystals and the 3-D observations of calcified and ossified turkey tendon have conclusively established that the crystals in bone of species as varied as chicken, fish, mouse, turkey, and bovine exist as small thin plates. The lack of correlation between the shape and size of the crystals as determined by direct TEM visualization of the individual isolated bone crystals and by indirect calculations made from either x-ray line broadening measurements or from small angle x-ray diffraction scattering data and modeling 78-85 as well as from TEM of young bone 86 clearly points out that all of the indirect methods (such as x-ray diffraction line broad-

ening, FT-IR, and small angle x-ray diffraction and modeling) as well as TEM of bone sections fail to provide accurate information about the precise size or shape of the crystals. For example, recent studies of stereograms of electron micrographs of very young isolated crystals in our laboratories from a variety of calcified tissues have indicated that the very thin plates of apatite crystals are curved, bent, and folded on themselves and on immediately adjacent crystals, giving the appearance of very electron dense thin lines and the illusion that very thin needle- or rod-like crystals are being viewed on edge. 69 This may account for many of the apparent needle-like rods observed in thin sections of young bone 86 and in cartilage by TEM. 88-93 However, some of the very electron dense lines may indeed be due to plates viewed on edge. It also means that the thickness of such dense lines may not be a true measurement of crystal thickness. This general phenomenon was pointed out by Hodge. 94 The most convincing evidence that the crystals in bone are plates are the studies of the habit and size distribution of isolated bone crystals by electron microscopy, 65 (Fig. 2 - 1 0 ) including those of the very newly formed bone from the periosteal cuff of 7- to 8-day-old chick embryonic femurs. No rod or rod-like crystals were observed at this or any other stage of crystal age or maturation. Similar findings were reported for the isolated crystals of calcified cartilage 67 and the crystals deposited during osteoblast cell culture. 95 Of interest, however, was the finding that a small proportion of the crystals from samples of the very youngest bone, also present but to a lesser extent in samples of older bone, contained crystals very much smaller than the average size of the crystals. The very smallest of these crystals

FIGURE 2-- 10 Electronmicrographs of isolated crystals from bovine bone free of organic constraints. Crystals are clearly plates. The very low electron density of the crystals lying fiat in the grid indicates that the crystals are very thin.

CI-IAr'X~ 2 The Nature of the Mineral Phase in Bone were somewhat irregularly shaped, and roughly square, whose dimensions ranged from 1 to 2 nm. The presence of such small crystals of that shape and size and ones somewhat larger, as well as the usual larger, more common and characteristic "rectangular" plates, may explain the concern raised by attendees at a recent meeting, 96 namely, the difficulty of being able to conceive, thermodynamically, how apatite "nuclei" could be formed in the size and shape of the characteristic, rectangular plate-like crystals (---200 A-400 A • ---35 to 75 A x --~10 to 40 A) observed by TEM of thin sections of even the very youngest bone. In the first place, we have already pointed out the difficulties of assessing the size and shape of bone apatite crystals by TEM of thin sections. However, 3-D reconstruction from high voltage electron microscopy when modified to highlight the electron density of the mineral phase and diminish or abolish the electron density contribution of the organic matrix, clearly shows a very wide range of crystal size, especially of their length, even correcting for foreshortening. This is consistent with our findings using isolated crystals. Secondly, there appears to be some confusion between the thermodynamically conceptual "nuclei" and the first solid phase that can be observed visually even by electron microscopy. Even the smallest crystals observed by T E M m l e t alone the "relatively large" characteristic, rectangular nanocrystals~do not represent the "thermodynamically conceptual nuclei" (i.e., that critical size cluster of atoms and ions representing the first transition of a solution phase of Ca and P to a solid phase). 4 Although the size and shape of the nuclei induced in bone by heterogeneous nucleation in vivo are not known, Katz 97 has calculated the number of atoms and ions in apatite nuclei heterogeneously nucleated by collagen fibrils in vitro (ranging from 11 to 13). Not only would it be unlikely that one could observe particles of that size and low electron density by TEM of sections of bone tissue or from preparations of isolated crystals, but it would also be unlikely because of the extraordinarily rapid growth of the crystals that occurs immediately after nuclei are formed. Our observations of samples of isolated bone crystals that contained some irregularly square shaped crystals, --~1 to 2 nm in size, however, suggests that after this stage of crystal growth has been reached, there is a continued, rapid, but preferential crystal growth along the c-axis of the crystals producing a thin, rectangular plate. The physiological and biomechanical consequences of such small crystals in bone are important in order for the crystals to carry out their various biological and mechanical functions. First, the surface area of the individual crystals and the number of the total ions and atoms that are located on the crystal surfaces as well as the total surface area of the mineral phase in the skeletal

35 system that are able to exchange or react with the atoms, ions, and other constituents of the extracellular fluid and of the organic matrix is extraordinarily high (several square miles). This permits for the very rapid and extensive exchange, addition, and dissolution of the mineral mass and the constituent ions and atoms in the lattice, on the surface, or in the hydration shell of the crystals such as calcium, magnesium, phosphorus, sodium, carbonate, etc. (i.e., its ion reservoir and homeostasis functions). Mechanically, the highly ordered location and orientation of the very small nanocrystals located within the collagen fibrils not only contribute significantly to the structural rigidity and strength of the bone substance but their nanocrystal size permits an acceptable range of flexibility without fracture or disruption of the bone substance. This would not be possible if the "hardness" of the bone were accomplished by the random distribution of the mineral phase into the organic matrix or even if very large, brittle apatite crystals were impregnated into the collagen fibrils. Indeed, even a simple mixture of collagen fibrils and apatite crystals similar in size and shape to those of bone, or collagen molecules in solution aggregated to a gel in the presence of apatite crystals, produce substances with almost none of the structural properties of bone, in which case the small nanocrystals are deposited within the collagen fibrils in specific ordered locations and in a highly oriented fashion 4'77'98-1~176 (Fig. 2 - 1 1 to 2-20). In this instance, electron microscopy of bone at various stages of mineralization starting from the initial deposition of crystals within the collagen fibrils to the last steps of full mineralization of the fibrils has not only provided visual observations of the intimate relationship between the inorganic crystals of apatite and the collagen fibrils but, very importantly, has provided the physical chemical basis that confirms the original hypothesis that calcification of the collagen fibrils m the event that converts the soft organic matrix in bone to a hard, structural substance or fabric m occurs by the heterogeneous nucleation of apatite crystals within the collagen fibrils in selected, spatially and physical chemical independent nucleation sites. The calcification of the collagen fibrils is the event that hardens the bone substance and provides its structural properties. While there are many ways in which the heterogeneous nucleation of apatite crystals within the collagen fibril can be regulated (changes in the metastability of the EC fluids, complexing with phosphoproteins, etc.), it is critical to distinguish between the basic physical chemical mechanism as to why the crystals are induced to form within the collagen fibrils (heterogeneous nucleation) and the many ways by which the system can be altered to regulate this basic physical chemical process. Purified collagens, aggregated into native type fibrils, are able to nucleate apatite crystals from

36

MELVIN

J. G L I M C H E R

FIGURE 2 - - 1 1 Electron micrograph of the middyaphysis of late embryonic chick bone during early stages of calcification. Similar findings were obtained from early postnatal chicks from the same region during the early stages of calcification of this later stage of chick bone development. Collagen fibrils are seen in cross section. Note mineralfree collagen fibrils (CF) and fibrils in varying stages of mineralization, that is, impregnated with a solid phase of calcium phosphate. The spaces between the fibrils are essentially free of mineral particles. The calcification of each of the fibrils and of the spatially separated sites within the fibrils along the axial length of a single fibril represent physical chemical independent sites of crystal nucleation. Two osteoblast processes (OP) are indicated. (From Landis WJ, Paine MC, Glimcher MJ: Electron microscopic observations of bone tissue prepared anhydrously in organic solvents. J U1trastruct Res 59:1, 1977.)

metastable solutions of Ca and P in v i t r o 1~176 and when implanted in the peritoneal cavities of animals, l~176 The induction time for nucleation to begin is greatly diminished if the collagen fibrils are complexed with the native resident phosphoproteins or other phosphoproteins such as phosvitin. Enzymatic removal of the phosphate groups from the collagen-phosphoprotein complexes eliminates the added advantage of the intact collagen-phosphoprotein complexes. These data demonstrate that the reduction of the induction time induced by the complexing of phosphoproteins to collagen is due to the phosphate groups per se. 101 - 103

V. RECENT STUDIES OF THE STRUCTURE OF BONE APATITES AND THE APPLICATIONS OF THESE DATA TO CLINICAL AND EXPERIMENTAL ABNORMALITIES AND DISEASES OF BONE Over the past 6 to 7 years there has been an increased awareness that there are important differences between

the biological apatites and the geological and synthetic apatites, including those precipitated from solutions simulating extracellular fluids. Moreover, it has also become clear that the crystals initially formed, either biologically in a tissue or during in vitro precipitation, undergo a series of compositional and structural changes as a function of the time they remain in the tissue or remain in contact with the solution from which they were precipitated. These changes are collectively referred to as "maturation." Importantly, the reactivity of the crystals (i.e., their ability to interact with the ions and proteins in the ECF and with cells, and therefore their ability to carry out their biological and structural functions) is directly related to the structure and composition of the crystals, particularly the surface components. To address these problems, attention has been directed at the fine structure, short range order of the crystals, and the environment of two of the minor but important ions that play a major role in determining the reactivity of the crystals, CO3 and HPO4. These studies have included computer-generated deconvolution of FT-IR spectra, with and without curve-fitting, solid state, magic-angle spinning 31p NMR spectroscopy, and FT-IR microscopy of

CHAPTER 2


37

FIGURE 2--12 A and B, Electron micrographs of cross-sections of a fully calcified intermuscular fish bone of a pickerel. In this flexible bone, the collagen fibrils are relatively widely spaced from one another making it possible to determine whether the crystals are located between, or within the collagen fibrils. It is clear from this electron micrograph, as well as electron micrographs from other species of fish, 98 that the crystals are located within the collagen fibers. Note that there are no matrix vesicles observed. No other intracellular or extracellular calcified structures are present in the intramuscular bones of this or many other fish species.98 Note that there are few if any matrix vesicles present (either calcified or uncalcified) in chick bone in the late stages of embryonic development or postnatally (Fig. 2-10). (See also Landin SJ, Paine MC, Hodgens KJ, Glimcher MJ: Matrix vesicles in embryonic chick bone: Considerations of their identification, number, distribution, and possible effects on calcification of extracellular matrices. J Ultrastruct Mol Struct Res 95:142-163, 1986.) The mineral phase is located at these stages of development within the collagen fibrils. The basic two-phase composite material of bone substance which determines the mechanical properties of the bone substance are the calcified collagen fibrils.

tissue sections. These have revealed a number of important new details about the structure and composition of bone crystals, the changes that occur during the maturation of the crystals, and some of the factors that regulate the process. These techniques, especially FT-IR TM and FTIR microscopy, 1~ have been used to study various diseases and experimentally produce abnormalities in bone. First, as we have already pointed out, it is important to note that the apatite crystals of bone are not hydroxyapatite. Not only do they not contain hydroxyl groups, but the short range order and organization is distinctly different than synthetic or geological apatites. Indeed, in a recent, as yet unpublished study we were able to distinguish synthetic apatites from bone apatites using a new experimental technique using solid state magic-

angle spinning 31p N M R . These fundamental differences between bone apatites, and particularly synthetic apatites, which are used in m a n y in vitro studies, and which attempt to relate the results of certain perturbations of the solution phase during the precipitation of synthetic apatite crystal in vitro, or their interaction properties with organic components, or changes induced in the physical structure and chemical composition of the crystals once the solid state has been achieved by the introduction of specific ions or organic constituents, must be taken into account if one attempts to postulate what might happen or what has happened under certain conditions in vivo, or to interpret the role of specific ions or organic constituents on the crystallographic structure of the mineral phase, the size of the crystals, the " c r y s t a l l i n i t y " of the

38

FIGURE 2-- 13

Higher magnifications of a section similar to those depicted in Figure 2 - 1 2 A and B. Electron micrograph of unstained fish bone which was not decalcified. The dense particles, identified by electron diffraction as Ca-P apatite crystals, are located essentially within the collagen fibrils, as observed in this electron micrograph in which collagen fibrils are seen primarily in cross-sectional profile. Inset shows two adjacent collagen fibrils in cross-sectional profile at higher magnification. Mineral particles are located within the collagen fibrils. The location of the crystals within the collagen fibrils and not in the extracellular spaces is an important point in trying to establish the actual mechanism as to how and why the crystals are nucleated within the collagen fibrils, and the possible role of other factors which may regulate the nucleation event within the collagen fibrils. Care must be directed at distinguishing between the mechanism wherein crystals are nucleated within the collagen fibrils and the possible physical, chemical, and other factors which may regulate the basic

mechanism.

mineral phase, the mechanism of the induction of the mineral phase, or the phase transitions which occur after the initial mineral phase is formed and matures to a final phase, etc. 117-121 Secondly, one should also be aware of the limitations of certain techniques used to evaluate such changes in the crystals either in vitro or in vivo. For example, because of the very small size of the nanocrystals of bone and apatite synthesized in vitro to sim-

MELVIN J. GLIMCHER

ulate bone crystals, x-ray diffraction analyses provide only very limited information. Indeed, it cannot distinguish between bone apatites and apatites synthesized to simulate bone apatite, even when the compositions of the two are markedly different or purposefully altered over a wide range of compositions. This is due to the fact that the small crystals of bone and of synthetic apatite crystals are also poorly crystalline, and therefore generate only a few x-ray reflections which, in addition, are also poorly resolved (Fig. 2-8). Thus, despite compositional and structural changes in the crystals as a function of the time that they spend in the tissue (maturation) or in the mother liquor from which they were precipitated in vitro (maturation), x-ray diffraction may not show any discemible change, or if some overall change does occur such as better or less well-resolved reflections, it will not be possible to discem what has taken place to have caused such changes, viz., change in crystal size, increased or decreased perfection of the short- and long-range order, or the presence of small amounts of non-apatitic solid phases of Ca-P which may also alter the x-ray diffraction pattem. Because of the frequency with which x-ray diffraction is used to explain the results of experiments that result in changes in the mineral phase, and the conclusions and implications drawn from such experiments, we reiterate that it is possible to synthesize crystals with a very broad range of compositions including Ca-P ratios, all of which generate an apatitic x-ray pattern similar to those generated by "normal" bone crystals. In particular, we note again that the composition, short-range order, local environments of the crystals change significantly with the age o f the crystals in vitro or in vivo and that these ages are reflected in changes in the "crystallinity" of the mineral phase as "deduced" by x-ray diffraction. Therefore, if a disease process or an experimentally induced perturbation alters the rates of bone resorption or both which alters the proportion of young and old crystals in the bone, it will result in significant changes in the x-ray diffraction pattern and possibly in other spectral analyses as well. However, we should not conclude, as some investigators have, that the perturbated processes per se have directly altered the composition or structure of the crystals. The perturbation may have simply changed the relative proportion of young and old crystals in the tissue or in the in vitro synthesized precipitate. Nor should one attempt to interpret the mechanism of such changes or to attribute these alterations to changes in crystal size or the perfection of the crystallographic order of its constituent ions and atoms from x-ray diffraction data alone. With respect to the term "crystallinity" or "index of crystallinity," 122 which is often used to characterize bone and other biological and synthetic apatites, and to note

CHAPTER 2 The Nature of the Mineral Phase in Bone

39

FIGURE 2-- 14

A series of high-voltage electron micrographs illustrating the successive stages of mineral deposition in herring bone tissue. Thick (1-1xm) cross sections of collagen fibrils were treated completely anhydrously for specimen preparation. A, The very first electron-dense deposits (arrows) are seen to occur within the boundary of the collagen fibril. B and C, As the mineralization progresses further, it is apparent that no mineral particles have been deposited in the extracellular spaces between the fibrils. The deposition of mineral particles in the adjacent collagen fibrils demonstrates that the nucleation of Ca-P crystals in each of the fibrils and in each of the hole zones is an independent physical chemical event.

changes in apatites that have occurred as a result of experimental perturbations in their preparation in vitro or as the result of in vivo alterations in bone metabolism, we note that "crystallinity" or "index of crystallinity" is a function of both crystal size and how well the atoms and ions of the crystals are ordered, that is, the perfection and extent of the ordered disposition of the individual ion and atom constituents in the crystals. "Crystallinity" or "index of crystallinity" is most commonly measured or evaluated from certain characteristics of the x-ray diffraction pattern generated, principally by the number of reflections, the resolution of the reflections, and the breadth of the reflections at a

particular height of the reflections. It has also been evaluated from FT-IR spectra by several different methods. For example, it is possible to prepare a series of separate samples of large, highly ordered crystals in which each separate sample consists of crystals that differ in size from the other separate samples. Under these circumstances, it would be possible to obtain relatively accurate data of the size of the crystals, or certainly of the relative size of the crystals in each of the separate samples by analyses of the characteristics of the x-ray diffraction patterns generated by the crystals, all of which would have many, well-resolved peaks that would vary somewhat in the breadth of the individual reflections.

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MELVIN J. GLIMCHER

FIGURE 2-- 15

A and B, High-voltage electron stereomicrographs of a pickerel fish to be prepared anhydrously seen in cross-sectional profile. A' and B', Higher magnification of the same regions illustrating the electron-dense Ca-P particles located within collagen fibrils. Three dimensional location of these mineral crystallites can be fully appreciated by stereoscopic examination, eliminating the possibility that these minerals are located on the surface of the section.

The FT-IR spectra, however, which depend more on internal order or disorder and vary much less on crystal size, would in this instance not provide a very good or possibly any information relative to the size of the crystals. Similarly, one could prepare a series of separate samples of large crystals of roughly the same size in which each of the separate samples contained crystals that differed in how well the atoms and other constituents were ordered (i.e., differences in the perfection of the short- and long-range order). Under these circumstances, it would be possible to detect these differences in crystal perfection by changes in the x-ray diffraction patterns and, depending on the nature of the disorder, by FT-IR and possibly 31p NMR spectroscopy as well. However, in the case of the very small nanocrystals of bone apatites and of the equally small, synthetic nanocrystals precipitated in vitro similar to bone apatites, the "crystallinity" or "index of crystallinity" will depend on both the size of the very small crystals and the fact that the ions or atom constituents of the crystals are not as well ordered, in part because so many of these atoms

and ions are located on the surfaces of the crystals, many in an ordered configuration unlike those in the internal lattice, especially the labile environments of CO3 and HPO4. Since both the small crystal size and the relative disorder of the crystal structure contribute to the characteristics of the x-ray diffraction patterns generated by such nanocrystals, especially in the very young crystals, and to the spectral characteristics of the crystals by FTIR and 31p NMR, it is not possible to separate or distinguish which of the variables (size or disorder) or what proportion of the spectra can be attributed to the size or the internal disorder of the crystals. However, since the average size of the apatite crystals of bone as determined by the direct visualization of isolated crystals by TEM does not increase very much as a function of the age of the crystals, 67 the very poor x-ray diffraction patterns generated by the youngest embryonic bone crystals, which improves with the age of the animal, is probably due in large measure to the degree of perfection of the short- and long-range order and very much less to changes in the average size of the crystals. Similarly,

CHAPTER 2 The Nature of the Mineral Phase in Bone

41

FIGURE 2--16 Schematic of the Hodge-Petruska model of type I collagen fibrils demonstrating that the fibrils contain a very large volume of highly organized space probably in the form of channels. There are also present smaller spaces (pores) between individual collagen macromolecules. The Hodge-Petruska model answered the perplexing question of how so much mineral could be accommodatedin the closely packed collagen fibrils without completelydisrupting and destroying the structure of the fibrils.

with the exception of the large apatite crystals of enamel, which increase in size significantly with age and time of maturation, changes in the x-ray diffraction patterns of bone apatites during maturation in vitro and in vivo, probably represent to a greater extent changes in the internal order of the crystals and less to their size. Although the x-ray diffraction characteristics and the FT-IR spectra generated by the nanocrystals of bone apatite used to characterize their "degree of crystallinity" for the most part reflect their lattice crystallographic disorder, especially at the lower end of the scale (viz., very poorly crystalline mineral phase such as occurs in the very youngest embryonic bone or newly synthesized bone at any stage of development), these characteristics probably also reflect to a lesser extent the increased proportion of the very smallest nanocrystals observed by TEM of preparations of isolated crystals 67 and by 3-D high-voltage electron microscopic tomography of calcifying and ossifying turkey tendon. 77 Therefore, one must view with caution the interpretation of in vitro experiments in which changes are introduced into the solution phase from which crystals are precipitated or from experiments in which crystals are incubated after precipitation with various ions and other components, and changes noted in their x-ray diffraction characteristics and/or the FT-IR spectra, or in their solubility and other characteristics, and these results interpreted as due to

changes in crystal size or changes in crystallographic perfection, especially if x-ray diffraction alone has been used to analyze the crystals.

Specific Ions 1. CO3 IONS There are two major sites in the crystal lattice into which CO3 ions can be introduced: the OH sites (type A carbonate apatite) and the PO4 sites (type B carbonate apatite). 123'~24 CO3 ions in these lattice positions are relatively stable and not very reactive or exchangeable.~3C NMR spectroscopy studies of synthetic carbonate aparites and enamel aparites, however, have identified five magnetically inequivalent CO3 ions (viz., three different environments in addition to the A and B sites). 13 These different sites may be the result, as already noted, of the different chemical environments in which they are located and/or geometric factors, such as shorter bond links between carbon and oxygen which would shield the carbon atom, or distortions of the planar structure possibly by rearranging the p-electrons in the bonding orbitals of the Type A carbonate. Further analysis of these data and other structural data in the literature suggest that the three additional carbonate sites or environ-

42

MELVIN J. GLIMCHER

FIGURE 2--18 FIGURE 2 - 1 7

Experimental proof that most of the crystals are indeed located within the hole zone channels of the collagen fibrils was provided by additional electron micrographs of very young chick bone in which both the mineral phase and the intraband period of the collagen fibril containing the crystals were photographed in a single section. The identification of the location of the mineral phase in bone collagen between the a 3 and c 3 bands places the crystals in the hole zone channels. (From Glimcher MJ, Krane SM: The organization and structure of bone, and the mechanism of calcifications. In Ramachandran GN, Gould BS (eds): Treatise on Collagen, vol 7B. New York, Academic Press, 1968.)

ments are labile and very reactive, whereas the other two stable lattice carbonate locations are stabile and very much less reactive. Similar findings have been observed in ~3C studies of bone crystals, but the very low intensifies and somewhat poorer resolution have precluded a detailed interpretation of the ~3C spectra in bone crystals. FT-IR studies of bone crystals have also identified labile environments for CO3 ions in both biological apatites from bone, calcified cartilage, dentine and enamel, and in synthetic apatites similar to bone apatites. It is likely that these labile, very reactive carbonate groups are located on the surface of the crystals and not in the lattice proper. These very reactive carbonate groups are very important as far as the biological and structural functions of the crystals are concerned.

Schematic to illustrate that the majority of the crystals initially deposited in the collagen fibrils are located in the hole zone (channels).

2. HPO4 IONS Although HPO4 ions have been demonstrated by chemical analysis, 14 F T - I R , 14'19 and most recently by 31p NMR solid state, magic-angle spectroscopy, 9-1~'2~ both in biological and synthetic apatites with or without the presence of carbonate groups, it is very likely that the HPO4 ions do not exist as single "entities" in specific sites. 21 It is much more likely that there exist regions within the crystal lattice and on the crystal surfaces in which the packing density of the protons is greater than in other regions and that in these regions the protons are spatially closer to particular P O 4 ions. 21 As in the case with CO3 ions, stable HPO4 "groups" are also present in the crystal lattice, and labile, very reactive HPO4 groups are present on the surface of the crystals. From kinetic studies it would appear that both labile CO3 and labile HPO4 groups occupy the same surfaces. These labile HPO4 groups, like the labile CO3 groups, are very reactive and, also like the labile CO3 groups, are probably responsible for a major share of the interaction properties of bone apatite crystals. Recent studies of synthetic and bone apatites and other calcium phosphate solids containing HPO4 groups using a modified technique of differential crosspolarization, solid state 31p NMR magic angle spinning

CHAPTER2 The Nature of the Mineral Phase in Bone

43 ing CO3 and HPO4 ions from synthetic or geological apatites containing CO3 and HPO4 ions. In addition to the labile and stable HPO4 groups and the major phosphorus constituent of apatite, stable PO4 ions, high-resolution computer-generated deconvoluted FT-IR studies have identified at least two environments of labile P04 ions that were first detected only in very y o u n g c r y s t a l s . 14'19 Curve fitting of the deconvoluted FTIR spectra have more clearly demonstrated the labile PO4 groups. The presence of such labile PO4 groups may account for the very slight irregularity of the PO4 peak observed in certain preparations of young bone crystals examined by cross-polarization, solid state 31p NMR spectroscopy.

3. CHANGES IN CO3 AND HPO4 IONS DURING MATURATION (AGING OF CRYSTALS)

FIGURE 2--19

Schematic to illustrate that further calcification of the collagen fibrils occurs both by primary heterogeneous nucleation and by secondary, tertiary nucleation, etc., that is, nucleation from crystals already formed either from heterogeneous nucleation, or from secondary nucleation and are propagated in the collagen pores, eventually filling all of the available space within the fibril, and converting the soft pliable fibrils and fibers into a continuous hard substance and fabric. High-voltage 3-D electron microscopy 98 has also demonstrated that there is expansion of the collagen fibrils in the region of the hole zones, which permits the deposition of additional crystals of apatite. At this point in the calcification of the collagen fibrils, the --~700-A axial period of the mineral phase reflecting their position within the hole zone regions of the collagen fibril, which do have an axial repeat of --~700 A, is lost due to the deposition of crystals throughout the available spaces including the pore spaces.

spectroscopy have for the first time been able to obtain the spectrum from the small number of HPO4 groups present in bone and synthetic apatites directly in the presence of the very major PO4 peak. Previous 31p NMR studies 9'1~have assumed the presence of HPO4 groups by comparing the 31p NMR spectroscopy patterns with model compounds containing HPO4 groups such as Ca HPO4" 2H20 (brushite). The studies that have directly analyzed the 31p NMR spectral characteristics of the HPO4 groups in bone crystals have shown that the HPO4 groups are unique and are unlike those present in octocalcium phosphate, amorphous calcium phosphate, and brushite as well as synthetic apatites precipitated from solution. 21 These data once again emphasize the significant differences between the biological apatites contain-

Studies of changes in the total content of CO3 and HPO4 ions and of the labile and stable environments of these ions in small synthetic crystals similar to bone apatites have revealed that the very earliest crystals formed have a high concentration of HPO4 ions and a very low concentration of CO3 ions. In both instances, a large proportion of these ions are in very labile, highly reactive environments. Most of these ions are located on the surface of the crystals as determined by the kinetics of dissolution experiments. With time there is a progressive increase in the CO3 concentration which occurs first on the surface as labile ions, and which later displace some of the surface HPO4 ions. During further stages of the maturation, CO3 ions are progressively incorporated from the surface into stable positions in the apatite lattice as HPO4 groups (H § ions) in the lattice are displaced. Thus the stable CO3 groups in the crystal lattice increase during maturation while those on the surface present as labile CO3 ions decrease during maturation. 1e'14'17'19'48 Both the surface labile HPO4 groups and the stable HPO4 groups in the lattice decrease during maturation. Additional important studies have now correlated reactivity and ease of exchange of the CO3 ions as a function of the stage of maturation. 48 The crucial role of CO3 ions in the maturation of apatite crystals was demonstrated using synthetic apatite crystals precipitated in vitro, in which CO3 crystals were precipitated from solutions containing high concentrations of CO3 ions and from solutions containing a very low concentration of CO3 ions. These experiments clearly demonstrated that the initial crystals formed were independent of the CO3 concentrations of the initial solutions from which the crystals were precipitated: the crystals formed from solutions containing high concentrations as well as low concentrations of CO3 ions were characterized by their very low concentration of CO3 ions and relatively high concentra-

44

MELVIN J. GLIMCHER

FIGURE 2--20 Schematic showing the progressive calcification of the collagen fibrils and the loss of the axial periodicity of the mineral phases at the stage of maximum calcification. Calcification of mitochondria has been reported in the cartilage and questionably in bone. A great deal of attention has been focused on the calcification of matrix vesicles, which are very likely to be portions of the cell and cell membrane "pinched off." We emphasize as we have in the past, that (1) calcification of the vesicles and of the individual fibrils and indeed of the specific hole zone regions in a single fibril are all independent sites for nucleation. There is no way that the solid crystals in the matrix vesicles or, indeed the crystals in one channel of a single fibril which is spatially separated from another channel, or the crystals from one fibril spatially separated from another fibril, can directly induce the nucleation of crystals in any other spatially distinct sites. It is very unlikely that the solid-phase crystals can " s w i m " from the matrix vesicles specifically to the hole zone regions of the collagen fibrils. [From Glimcher MJ: On the form and function of bone: From molecules to organs. Wolff's Law revisited. In Veis A (ed): The Chemistry and Biology of Mineralized Connective Tissues. New York, Elsevier North-Holland, 1981, pp 618-673.] Neither can they " s e e d " the collagen fibrils by the release of the crystals from the matrix vesicles and induce additional crystals to form in the extracellular fluids between the fibrils. If that occurred, one would easily observe that the extracellular spaces between the fibrils would be occupied by crystals and that this would occur before calcification was initiated in the crystals. It is quite clear from the electron micrographs presented that this does not occur. As noted, matrix vesicles are observed only in the early phases of embryonic development of bone. With maturation of the bone, the number of matrix vesicles rapidly declines and, eventually, they are not found in the extracellular matrix of the more mature, developing embryonic and postnatal bone. Thus, during the embryonic and early and late postnatal stages of development, the initial bone tissue containing the matrix vesicles is wholly resorbed and the new bone tissue that has formed to replace it during the progressive growth and development of the bone to its adult stage is mineralized in the absence of matrix vesicles. During all of these stages, calcification occurs in the collagen fibrils. The precise biological function of the matrix vesicles in the early stages of bone development, or in some cases, in very rapidly synthesized bone (e.g., during the repair of bone defects or fractures) is not clear. Their absence in the later stages of embryonic bone development and in the postnatal period and their absence in the intermuscular bones of a number of fish species, in which it is the collagen fibrils which are calcified, establishes that the calcification of matrix vesicles is not obligatory for the calcification of collagen fibrils, which is, as we have pointed out, the component that hardens bone tissue.

tions of HPO4 ions, both of which were in labile environments. These data are wholly consistent with the findings obtained from the very early crystals formed in bone, cartilage, dentine, and enamel, all of which were found to have very low concentrations of CO3 and high concentrations of HPO4, both of which, like the in vitro crystals, were in labile environments. Thus the concen-

tration of CO3 ions in the solutions from which the crystals are formed in vitro or in vivo has little or no effect on the nature of the initial crystals formed. However, the evolution and nature of the maturational changes were also found to be highly dependent on the concentration of the CO3 ions in the solutions with which the crystals were subsequently equilibrated. However, there were

CHAPTER2 The Nature of the Mineral Phase in Bone distinct changes in the nature and pattern of the maturation processes depending on whether the initial crystals formed from solution (independent of whether the crystals were formed from solutions containing high or low CO3 concentrations) were equilibrated shortly after their precipitation with CO3-rich or CO3-poor solutions. In the former case (CO3-rich solutions), the maturational changes observed were very similar to those found during the maturation of bone crystals in vivo. On the other hand, if the initial crystals formed (both those precipitated from solutions with high or low concentrations of CO3 ions) were then equilibrated with solutions with low concentrations of CO3 ions, the evolution of the maturation changes were distinctly different than those occurring in bone crystals in vivo, and more closely resembled the nature and pathway observed in enamel crystals in vivo: continued low concentrations of CO3 and HPO4 .48 Interestingly, the crystals that evolved with maturation changes similar to those observed in bone crystals did not incorporate OH ions, whereas those that followed the maturational changes similar to those observed during the maturation of enamel crystals did eventually incorporate OH ions which increased in extent with time of maturation (enamel does contain OH groups that progressively increase during maturation). Interestingly, the evolution and the maturational changes were also dependent on the length of time that elapsed after precipitation and before the crystals precipitated in CO3-free solutions were equilibrated in CO3poor solutions. If this time was prolonged, there was less and less tendency for the crystals formed in CO3-rich solutions or CO3-poor solutions to mature in the same fashion as bone crystals in vivo. Indeed, if the elapsed time between precipitation and reequilibration with CO3rich solution was prolonged, the crystals precipitated from solutions with rich CO3 concentrations, despite incubation and equilibration in CO3-rich solutions, followed the maturation pathway of enamel crystals and not those of bone crystals. It is clear from these experiments that it is the CO3 concentration in the equilibrium solution during maturation that regulates the nature and rate of the maturational changes observed, and that this critical, relatively high concentration of CO3 must be present shortly after the crystals are formed if the rate and, most importantly, the path of maturation observed in bone crystals in vivo is followed by in vitro synthesized crystals. The reactivity of the labile and stable CO3 groups has also been studied using 13C-~2C exchange experiments. These studies showed that labile CO3 ions on the surface of the crystals are exchanged very rapidly, but are not exchanged or are exchanged only very slowly once they are incorporated into stable positions in the apatite lattice. It was interesting that the last CO3 ions incorporated

45 into lattice positions were in regions of less "crystallinity" than the first CO3 ions incorporated into the lattice structure. Another interesting finding was the interdependence of CO3 and HPO4 ions in establishing the compositions and short-range order and their environments of the apatite crystals: apatite crystals that contained only a few labile phosphate ions had little capacity to mature and incorporate CO3 into lattice positions, and underwent very few of the normal maturational changes in the composition and environment of both the HPO4 and CO3 ions observed both in vitro and in vivo, including the fact that CO3 ions were not incorporated into the interior of the crystals in stable CO3 sites (substituting in OH positions and for PO4 ions). Conversely, if the apatite crystals are rich in both labile C O 3 and labile HPO4 ions, they show a great potential for undergoing the maturational changes observed in bone crystals in vivo: the CO3 ions that do substitute for HPO4 ions on the surface can later be incorporated into the interior lattice of the maturing crystals in the two main stabile CO3 sites. An overview of the maturation processes that occur in vivo and in CO3-rich equilibrium solutions in vitro, which are similar to those that occur in vivo, begins by an exchange of CO3 ions from the solution phase displacing the labile non-apatitic HPO4 ions on the surface of the crystals. These labile carbonated domains increase in number as the less stable initially formed crystals, which are rich in labile phosphate species, are replaced by a solid phase whose surface is rich in labile CO3 ions. Substitution of one divalent ion (HPO4) by another divalent ion (CO3) does not modify the charge balance or the number of calcium ions. The number of vacancies is not changed during the process, nor is there is an increase in crystal size of the crystals equilibrated in CO3rich solutions. 4. MG IONS

A fairly large number of other atomic elements are associated with the bone crystals in very low concentrations. The phrase "associated with the crystals" is used advisedly, since it is not known for certain whether such ions are located in the lattice structure of the crystals, adsorbed on the surfaces of the crystals, or whether they are present in the more peripheral "hydration shell" enveloping the crystals. Magnesium (Mg) is one such ion. Mg is the fourth most abundant cation in the body and the second most abundant cation in the intracellular fluid. 125 Because of the signal importance of Mg in bone metabolism 125 and as a vital component in other important biochemical processes and enzymatic reactions, 126-132 and because a major portion (--~50% of the total body Mg) is associated with the mineral phase of bone, we chose to use it as an example of the problems facing investigators seeking to uncover exactly how el-

46 ements such as Mg are associated with the bone crystals (viz., precisely where the Mg ions are located, since their location and their environment will, in large part, determine as they do for CO3 and HPO4, how easily they can participate in the regulation of homeostasis of Mg in the ECF and in other biological functions as well). Similarly, the postulated direct roles of Mg in the formation, size, crystallinity, solubility, and other characteristics of the crystals will also depend on the precise location of the Mg ions with respect to the lattice and surfaces of the crystals. Although it is commonly stated that two-thirds of the Mg ions present in bone are an integral part of the apatite lattice, 125 presumably replacing Ca atoms, there is little direct evidence to support this conclusion, and a great deal of evidence that suggests that the vast majority, or, indeed, all of the Mg atoms are either located on the surface of the crystals and/or in the more peripheral "hydrated shell" that envelopes the crystals. These latter conclusions were based on the conceptual framework developed by Neuman and Neuman ~33 and later by Holmes et al. TM who proposed that, because of the small nanocrystal size of the bone crystals and their very large surface area with respect to their size, as well as the fact that the crystal surfaces contain charged constituents, that ions such as Na and Mg cannot only be incorporated into the apatitic lattice but can also be associated with bone crystals as bound counterions directly on the surfaces of the crystals or in the peripheral hydration shell. The "hydration shell" described by Neuman and Neuman ~33 was conceived by Holmes et al. TM as 100- to 300-A intercrystalline "pores" containing water. Both concepts have the same implication (viz., water compartments between the nanocrystals in which specific ions are concentrated). Experimentally, Neuman and Mulryan, ~35 using small, synthetic crystals of apatite precipitated from solutions containing Mg under conditions simulating those in vivo, performed kinetic and equilibration experiments using 2SMg. They found from such studies that 90% or more of the Mg ions were very rapidly changeable and, therefore, were located either on the surface or in the peripheral hydrated shell. They found no convincing evidence for the presence of stable Mg in the structural lattice of the apatites. On the other hand, in similar experiments using apatite crystals simulating those crystals present in bone, other investigators 47'~36-~39 concluded that a few Mg ions present in the apatite precipitates were actually incorporated into the apatite lattice displacing Ca. However, these conclusions, which were based principally on changes in the apatitic lattice parameters measured by x-ray diffraction, were questioned because of the poor resolution of the x-ray diffraction patterns generated which precluded the precise and sufficiently accurate measurements nec-

MELVIN J. GLIMCHER

essary to calculate the very small differences noted in the lattice parameters. As has been pointed out 29 there are a number of other changes that could occur when precipitating apatite crystals in the presence of Mg that could account for the changes in lattice parameters. 29 Several authors have shown that the uptake of Mg could be increased by increasing the uptake of CO3 ions. 137 However, it has been argued that, rather than increasing the inclusions of Mg into the apatite lattice, the additional uptake of Mg by the crystals may have been due to complexing with CO3 ions on the surfaces of the crystals or in the hydration shell. Several authors have suggested that the changes in the lattice parameters may also be accounted for by alterations other than the introduction of Mg into the apatitic lattice, for example, by surface compositional changes or by the formation of small amounts of other Ca, Mg, and PO4 solid phases. Except for the few exceptions noted, attempts to incorporate Mg into the apatite lattice have been carried out on large, highly crystalline hydroxyapatite crystals synthesized in most cases at high temperatures, or under very severe hydrolytic conditions. Even under these circumstances, it has not been possible to definitively demonstrate by x-ray diffraction that Mg was indeed incorporated into the lattice structure of the apatites. Similarly, very detailed conceptual and experimental studies concluded that it was very unlikely from the theoretical crystallographic calculations and from the experimental data that Mg ions could be incorporated as an integral part of the apatite lattice. 14~ To solve and settle these important questions requires direct crystallographic structural analysis utilizing single crystals of the putative Mg-substituted apatites combined with spectral evidence. Unfortunately, it has not been possible to date to prepare single crystals of apatite containing Mg and there are currently no special spectral methods available to study the environment of Mg in preparations of apatite crystals that contain or which are associated with small amounts of Mg. The fact that Mg may not be an integral part of the apatitic lattice does not in any way preclude the Mg ions present on the surface or in the hydrated shell of the crystals from participating in the homeostasis functions of the mineral phase. Indeed, their location on the surfaces and in the hydration shell of the crystals would permit them to respond more readily, since total dissolution of the crystals would not be necessary to release Mg ions into the ECF nor new crystals formed to remove Mg ions from the ECF. References 1. Boulignand Y, Giraud-Guille MM: Spatial organization of collagen fibrils in skeletal tissue: Analogies with liquid crystals.

CHAPTER 2


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nucleational core of growth plate vesicles. Bone Miner 17: 2 9 0 - 295, 1992. Register TC, McLean FM, Low MG, Wuthier RE: Roles of alkaline phosphatase and labile internal mineral in matrix vesicle-mediated calcification: Effect of selective release of membrane-bound alkaline phosphatase and treatment with isosmotic pH 6 buffer. J Biol Chem 261:9354-9360, 1986. Wu LNY, Sauer GR, Wuthier RE: Induction of mineral deposition by primary cultures of chicken growth plate chondrocytes in ascorbate-containing media: Evidence of an association between matrix vesicles and collagen. J Biol Chem 264:2134621355, 1989. Wuthier RE: Mechanism of matrix vesicle-mediated mineralization of cartilage. ISI Atlas Sci Biochem 1:231-241, 1988. Kim H-M, Rey C, Glimcher MJ: Isolation of calcium-phosphate crystals of bone by nonaqueous methods at low temperature. J Bone Miner Res 10:1589-1601, 1995. Grynpas MD, Bonar LC, Glimcher MJ: Failure to detect an amorphous calcium-phosphate solid phase in bone mineral: A radial distribution function study. Calcif Tissue Int 36:291301, 1984. Kim H-M, Rey C, Glimcher MJ: X-ray diffraction, electron microscopy and Fourier transform infrared spectroscopy of apatite crystals isolated from chicken and bovine calcified cartilage. Calcif Tissue Int 59:58-63, 1996. Rey C, Miquel JL, Facchini L, et al: Hydroxyl groups in bone mineral. Bone 16:583-586, 1995. Miquel JL, Facchini L, Legrand AP, et al: Characterization and conversion study into natural living bone of calcium phosphate bioceramics by solid NMR. Clin Mater 5:115-125, 1990. Termine JD, Eanes ED, Greenfield DJ, et al: Hydrazine-deproteinized bone mineral: Physical and chemical properties. Calcif Tissue Int 12:73-90, 1973. Yesinowski JP, Eckert H: Hydrogen environments in calcium phosphates: 1H MASS NMR at high spinning speeds. J Am Chem Soc 109:6274, 1987. Robinson RA, Bishop FW: Methods of preparing bone and tooth samples for viewing in the electron microscope. Science 111:655-657, 1950. Robinson RA: An electron-microscopic study of the crystalline inorganic component of bone and its relationship to the organic matrix. J Bone Joint Surg 34:389-434, 1952. Landis WJ, Paine MC, Glimcher MJ: Electron microscopic observations of bone tissue prepared anhydrously in organic solvents. J Ultrastruct Res 59:1-30, 1977. Bocciarelli DS: Morphology of crystallites in bone. Calcif Tissue Res 5:261-269, 1970. Bocciarelli DS: Apatite microcrystals in bone and dentine. J Microsc 16:21-34, 1973. Landis WJ, Song MJ, Leith A, et al: Mineral and organic matrix interaction in normally calcifying tendon visualized in three dimensions by high-voltage electron microscope tomography and graphic image reconstruction. J Struct Biol 110:39-54, 1993. Engstrom A, Finean JB: Low-angle X-ray diffraction of bone. Nature 171:564, 1953. Finean JB, Engstrom A: The low-angle scatter of X-rays from bone tissue. Biochim Biophys Acta 11:178-189, 1953. Carlstrom D, Finean J: X-ray diffraction studies on the ultrastructure of bone. Biochim Biophys Acta 13:183-191, 1954. Finean JB, Engstrom A: Low-angle reflection in x-ray diffraction patterns of bone tissue. Experientia X : 6 3 - 6 4 , 1954. Carlstrom D: X-ray crystallographic studies on apatites and calcified structures. Acta Radiol Suppl 121:7-54, 1955.

CHAPTER 2


83. Fratzl P, Fratzl-Zelman N, Klaushofer K, et al: Nucleation and growth of mineral crystals in bone studied by small-angle xray scattering. Calcif Tissue Int 48:407-413, 1991. 84. Fratzl P, Fratzl-Zelman N, Klaushofer K: Collagen packing and mineralization. Biophysics 64:260-266, 1993. 85. Fratzl P: Statistical model for the mineral structure in bone. J Stat Phys 77:124-144, 1994. 86. Traub W, Arad T, Weiner S: Origin of mineralized crystal growth in collagen fibrils. Matrix 12:251-255, 1992. 87. Wachtel E, Weiner S: Small-angle x-ray scattering study of dispersed crystals from bone and tendon. J Bone Miner Res 9: 1651-1655, 1994. 88. Arsenault AR, Hunziker EB: Electron microscopic analysis of mineral deposits in the calcifying epiphyseal growth plate. Calcif Tissue Int 42:119-126, 1988. 89. Arsenault AR, Grynpas MD: Crystals in calcified epiphyseal cartilage and cortical bone of the rat. Calcif Tissue Int 43: 219-225, 1988. 90. Bonucci E: Fine structure of early calcification. J Ultrastruct Res 20:33-50, 1967. 91. Bonucci E: Further investigation on the organic/inorganic relationships in calcifying cartilage. Calcif Tissue Int 3:38-54, 1969. 92. Bonucci E, Silvestrini G, Digrezia R: The ultrastructure of the organic phase associated with the inorganic substance in calcified tissues. Clin Orthop 233:243-261, 1988. 93. Bonucci E: Comments on the ultrastructural morphology of the calcification process: An attempt to reconcile matrix vesicles, collagen fibrils and crystal ghosts. Bone Miner 17:219-222, 1992. 94. Hodge AJ: In discussion of: Grynpas et al., The emergence and maturation of the first apatite crystals in an in vitro bone formation system. Connect Tissue Res 21:227-237, 1989. 95. Rey C, Kim H-M, Gerstenfeld L, Glimcher MJ: Structural, chemical characteristics, and maturation of the calcium-phosphate crystals formed during the calcification of the organic matrix synthesized by chicken osteoblasts in cell culture. J Bone Miner Res 10:1577-1588, 1995. 96. Rey C, Kim H-M, Gerstenfeld L, Glimcher MJ: Characterization of the apatite crystals of bone and their maturation in osteoblast cell culture: Comparison with native bone crystals. Connect Tissue Res 35:343-349, 1996. 97. Katz EP: The kinetics of mineralization in vitro. Biochim Biophys Acta 194:121 - 129, 1969. 98. Lee DD, Glimcher MJ: Three-dimensional spatial relationship between the collagen fibrils and the inorganic calcium phosphate crystals of pickerel (Americanus americanus and herring (Clupea harengus) bone. J Mol Biol 217:487-501, 1991. 99. Glimcher MJ: Recent studies of the mineral phase in bone and its possible linkage to the organic matrix by protein-bound phosphate bonds. Phil Trans R Soc London B 304:479-508, 1984. 100. Glimcher MJ: A basic architectural principle in the organization of mineralized tissues. Clin Orthoped Relat Res 61:16-36, 1968. 101. Glimcher MJ, Hodge AJ, Schmitt FO: Macromolecular aggregation states in relation to mineralization: The collagen hydroxyapatite system as studied in vitro. Proc Natl Acad Sci USA 43:860-867, 1957. 102. Glimcher MJ: Molecular biology of mineralized tissues with particular reference to bone. Rev Mod Physics 31:359-393, 1959. 102a. Mergenhagen SE, Martin GR, Rizzo AA, et al: Calcification in vivo of implanted collagens. Biochim Biophys Acta 43:563565, 1960.

49 102b. Goldhaber P, Burr TJ Jr., Glimcher MJ: Calcification of purified, native type (---700 A axial repeat) reconstituted collagen and decalcified bone powder in Millipore filters implanted in the peritoneal cavity of rats. Presented at Gordon Conference, Meridian, NH (unpublished). 103. Glimcher MJ: Mechanism of calcification: Role of collagen fibills and collagen-phosphoprotein complexes in vitro and in vivo. Anat Rec 224(2):139-153, 1989. 104. Rey C, Lian J, Grynpas M, et al: Non-apatitic environments in bone mineral: FT-IR detection, biological properties and changes in several disease states. Connect Tissue Res 21:267273, 1989. 105. Boskey AL, Pleshko N, Doty SB, Mendelsohn R: Applications of Fourier transform infrared (FT-IR) microscopy to the study of mineralization in bone and cartilage. Cells Mater 2:290220, 1992. 106. Boskey AL, Camacho NP, Gadaleta S, et al: Applications of Fourier transform infrared microscopy to the study of biologic mineralization. L'Eurobiologiste 30:259- 267, 1996. 107. Gadaleta SJ, Camacho NP, Mendelsohn R, Boskey AL: Fourier transform infrared microscopy of calcified turkey leg tendon. Calcif Tissue Int 58:17-23, 1996. 108. Gadaleta SJ, Landis WJ, Boskey AL, Mendelsohn R: Polarized FT-IR microscopy of calcified turkey leg tendon. Connect Tissue Res 34:203- 211, 1996. 109. Paschalis EP, Jacenko O, Olsen B, et al: Fourier transform infrared microspectroscopic analysis identified alterations in mineral properties in bones from mice transgenic for type X collagen. Bone 19:151 - 156, 1996. 110. Paschalis EP, Jacenko O, Olsen B, et al: The role of type X collagen in endochondral ossification as deduced by Fourier transform infrared microscopy analysis. Calcif Tissue Int (in press) 1997. 111. Boskey AL, Camacho NO, Mendelsohn R, et al: FT-IR microscopic mappings of early mineralization in check limb bud mesenchymal cell cultures. Calcif Tissue Int 42:443-448, 1992. 112. Boskey AL, Pleshko N, Binderman, Mendelsohn R: Mineralization during in vitro calcification: An FT-IR microscopic mappings of early mineralization in chick limb bud mesenchymal cell cultures. Calcif Tissue Int 51:443-448, 1992. 113. Mendelsohn R. Hassenkhani A, DiCarlo E, Boskey AL: FT-IR microscopy of endochondral ossification at 10Ix spatial resolution. Calcif Tissue Int 44:20- 24, 1989. 114. Pleshko N, Mendelsohn R, Boskey AL: Developmental changes in bone mineral: An FT-IR microscopy study. Calcif Tissue Int 41:72-77, 1992. 115. Pleshko N, Mendelsohn R, Boskey AL: A novel IR spectroscopic method for the determination of crystallinity of hydroxyapatite minerals. Biophy J 60:786-793, 1991. 116. Paschalis EP, DiCarlo E, Betts F, et al: FT-IR microscopic analysis of human iliac crest biopsies from normal bone. Connect Tissue Res 34:287, 1996. 117. Aoba T, Moreno EC, Chimoda S: Competitive adsorption of magnesium and calcium ions onto synthetic and biological apatites. Calcif Tissue Int 41:143-150, 1992. 118. Bigi A, Foresti E, Gregorini R, et al: The role of magnesium on the structure of biological apatites. Calcif Tissue Int 40: 439-444, 1992. 119. Blumenthal NC, Betts F, Posner AS: Stabilization of amorphous calcium phosphate by Mg and ATE Calcif Tissue Res 23:245-250, 1977. 120. Boskey AL, Rimnac CM, Bansal M, et al: Effect of short-term hypomagnesemia on the chemical and mechanical properties of rat bone. J Orthop Res 10:774-783, 1992.

5D

121. Cohen L, Laro A, Kitzes R: Bone magnesium, crystallinity index and state of body magnesium in subjects with senile osteoporosis, maturity-onset diabetes and women treated with contraceptive preparations. Magnesium 2:70-75, 1983. 122. Bonar LC, Roufosse AH, Sabine WK, et al: X-ray diffraction studies of the crystallinity of bone mineral in newly synthesized and density fractionated bone. Calcif Tissue Int 35:202-209, 1983. 123. LeGeros RZ, LeGeros JP: Carbonate analysis of synthetic mineral and biological apatites. J Dent Res 62:259, 1983. 124. LeGeros RZ, Trautz OR, LeGeros JP, Klein E: Carbonate substitution in the apatitic structure. Bull Soc Chim Fr 4:17121718, 1968. 125. Rude RK: Magnesium homeostasis. In Bilezikian JP, Raissz LG, Rodan GA (eds): Principles of Bone Biology. San Diego, Academic Press, 1996, pp 2 7 7 - 293. 126. Rude RK, Oldham SB: Disorders of magnesium metabolism. In Cohen RD, Lewis B, Alberti KGMM, Denmon AM (eds): The Metabolic and Molecular Basis of Acquired Disease. London, Baillier Tindall, 1990, pp 1124-1148. 127. Wacker WEC, Parish AF: Medical progress: Magnesium metabolism. N Engl J Med 45:658-663, 1968. 128. Wacker WEC, Parish AF: Medical progress: Magnesium metabolism (continued). N Engl J Med 45:712-716, 1968. 129. Wacker WEC, Parish AF: Medical progress: Magnesium metabolism (concluded). N Engl J Med 45:772-776, 1968. 130. Elin RJ: Assessment of magnesium status. Clin Chem 33: 1965-1970, 1987. 131. Wallach S: Availability of body magnesium during magnesium deficiency. Magnesium 7:262-270, 1988. 132. Wallach S: Effects of magnesium of skeletal metabolism. Magnes Trace Elem 9:1 - 14, 1990.

MELVIN J. GLIMCHER 133. Neuman FW, Neuman MW: The nature of the mineral phase of bone. Chem Rev 53:1, 1953. 134. Holmes JM, Davies DH, Meath WJ, Beebe RA: Gas adsorption and surface structure of bone mineral. Biochemistry 3:20192023, 1964. 135. Neuman WF, Mulryan B J: Synthetic hydroxyapatite crystals: IV. Magnesium incorporation. Calcif Tissue Res 7:133-138, 1971. 136. LeGeros RZ, Daculsi G, Kijkowska R, Kerebel B: The effect of magnesium on the formation of apatites and whitlockites. In Itokawa K, Durlach J (eds): Proc Magnesium Symposiums, 1988. Magnesium in Health and Disease. New York, Libbey, 1989, pp 11 - 19. 137. LeGeros RZ, Kijkowska R, Bautista C, LeGeros JP: Synergistic effects of magnesium and carbonate on properties of biological and synthetic apatites. Connect Tissue Res 33:203-209, 1995. 138. LeGeros RZ, Miravite MA, Quirolgico GB, Curzon MEJ: The effect of some trace elements on the lattice parameters of human and synthetic apatites. Calcif Tissue Res 22:$362-$367, 1975. 139. Boulet M, Marier JR, Rose D: Effect of magnesium on formation of calcium phosphate precipitatives. Archs Biochem Biophys 96:629-636, 1962. 140. Driessens FCM, Verbeeck RMH, Heijligers HJM: Some physical properties of Na- and CO3-containing apatites synthesized at high temperatures. Inorganica Chim Acta 80:19-23, 1983. 141. Driessens FCM, Verbeeck RMH: Domomite as a possible magnesium-containing phase in human tooth enamel. Calcif Tissue Int 37:376-380, 1984. 142. Featherstone JDB, Mayer I, Driessens FCM, et al: Synthetic apatites containing Na, Mg, and CO3 and their comparison with tooth enamel mineral. Calcif Tissue Int 35:169-171, 1983.

_~HAPTER

Parathyroid Hormone and Parathyroid Hormone~ Related Peptide in Calcium Homeostasis Bone Metabolism and Bone Development: The Proteins, Their Genes, and Receptors JOHN T. POTTS, JR. AND HARALD JOPPNER Endocrine Unit, Massachusetts General Hospital, Harvard Medical School, Boston, Massachusetts 02114

I. II. III. IV.

Introduction: Regulators of Mineral Ion Homeostasis Parathyroid Hormone Parathyroid Hormone-Related Peptide Receptors that Mediate Analogous and Distinct Molecular Actions of PTH and PTHrP

METABOLIC BONE DISEASE

V. Summary: Overall Biological Roles of PTH and PTHrP, and Their Cloned Receptors References

51

Copyright 9 1998 by AcademicPress. All rights of reproductionin any form reserved.

52

JOHN T. POTTS, JR. AND HARALDJOPPNER I. I N T R O D U C T I O N :

REGULATORS

OF MINERAL

ION HOMEOSTASIS Parathyroid hormone (PTH) and the active form of vitamin D, 1,25-dihydroxyvitamin D3 [1,25(OH)zD3], are the principal physiological regulators of calcium homeostasis for humans and all terrestrial vertebrates. ~'2 The actions of both hormones are coordinated, and each influences the synthesis and secretion of the other. 1,25(OH)zD3 is critical for the day-to-day and week-to-week calcium balance; PTH is vital for the minute-to-minute regulation of extracellular calcium concentration, and mediates its actions through a Gprotein-coupled receptor, the PTH/PTHrP receptor. 3'4 The PTH/PTHrP receptor also serves several other, still incompletely characterized functions, not directly related to the control of calcium homeostasis. Particularly important is the receptor's role in bone development, where it mediates the actions of parathyroid hormone-related peptide (PTHrP). PTHrP was first discovered as the most important cause of the humoral hypercalcemia of malignancy syndrome, and it is now known to be of considerable importance for chondrocyte proliferation and differentiation, and thus for bone elongation. 5'6 As discussed below, PTH and PTHrP share some structural and functional similarities but are distinct molecules that mediate their unique physiological roles through the common PTH/PTHrP receptor. Current evidence indicates that intact PTH and PTHrP, or proteolytic fragments of either peptide, interact also with other, not yet isolated, receptors. 7-~4'3~However, the biological functions mediated through these receptors are still unknown. Extracellular calcium concentration is maintained within narrow limits to ensure a multitude of important cellular functions. 15'16 Furthermore, an adequate supply of calcium is required to mineralize the skeleton, which contains over 99% of the body's calcium. Bone, in turn, through its continuous remodeling, serves as a calcium reservoir. Food intake is discontinuous; intestinal calcium absorption thus occurs only intermittently and calcium content of the diet may be low, even when isocaloric. Therefore, the maintenance of a constant blood calcium concentration constitutes a major homeostatic challenge for most terrestrial vertebrates, and requires control of urinary calcium losses, efficient intestinal calcium absorption, and, if necessary, the rapid mobilization of calcium from the skeletal reservoir. ~6By contrast, regulation of calcium in blood and tissue fluids of marine animals poses a different environmental challenge inasmuch as the concentration of calcium in seawater exceeds that in extracellular fluid so that calcium disposal

(and the conservation of phosphate) is the principal challenge, not the prevention of hypocalcemia. 17 Phosphate, at least in early evolutionary history, was scarce in seawater, by contrast to its abundant supply in diets of terrestrial animals. It is attractive to speculate that certain aspects of mineral ion metabolism in modem terrestrial vertebrates may reflect earlier evolutionary challenges, specifically the efficient gastrointestinal absorption and renal retention of phosphate and the less efficient intestinal absorption and renal conservation of calcium. To maintain extracellular calcium concentrations at a constant level, PTH acts directly on bone and kidney, and indirectly via 1,25(OH)zD3 on the intestine. 1'~5 Through these mechanisms, it increases the flow of calcium into the extracellular fluid and thus maintains normal blood calcium concentrations. ~6 PTH synthesis and secretion are stimulated by a decrease in extracellular calcium, and are, conversely, inhibited by increased concentrations of this mineral ion (Fig. 3 - 1 ) . This negative feedback regulation of PTH production by blood calcium, and the resulting modulation of its biological activity, is the most important homeostatic mechanism for controlling calcium concentrations in the extracellular fluid. PTH also has important effects on the regulation of inorganic phosphate concentration, principally through renal actions, but these effects are best understood as a secondary rather than a homeostatic action. Daily urinary phosphate clearance most closely correlates with dietary intake of phosphate, and is independent of changes in

FIGURE 3--1 Physiologicalactions of PTH. The hormone acts directly on receptors in bone and kidney and indirectly (through vitamin D) on gut to raise the concentration of calcium in the extracellular fluid (ECF) compartment. Calcium in the ECF in turn exerts a negative feedback inhibition on the parathyroid gland to reduce the rate of PTH secretion.

CHAPTER 3 Parathyroid Hormone and Parathyroid Hormone-Related Peptide PTH secretion. Phosphate is abundant in the food chain in terrestrial existence. Therefore, phosphate deficiency, unlike nutritional calcium deficiency, is rarely the result of an environmental challenge, but rather caused by urinary phosphate wasting due to rare genetic disorders or t u m o r s . 18'19 Whenever calcium is released by dissolution of bone through PTH-dependent mechanisms, which would serve as a defense, for example, in a period of starvation to defend blood calcium content (desirable), phosphate is simultaneously liberated, increasing its concentration in blood (undesirable). High blood phosphate levels p e r s e tend to lower calcium concentrations through multiple mechanisms; it is therefore beneficial to excrete any excess phosphate in urine and to minimize, at the same time, urinary calcium losses by enhancing its tubular reabsorption. PTH protects calcium homeostasis efficiently by promoting urinary phosphate excretion while lowering urinary calcium excretion; PTH thus functions effectively by its combined bone and renal actions. There have been considerable advances in the chemical and functional characterization of PTH and PTHrP, and their genes, as well as the isolation and/or characterization of different receptors (especially the common PTH/PTHrP receptor) that mediate the endocrine and paracrine/autocrine actions of both hormones. These advances achieved initially through traditional methods of peptide chemistry and synthesis, later combined with techniques of molecular, developmental, and cellular biology, have led to a much improved understanding of the structure and function of these ligands (PTH and PTHrP), their receptors, and their biological actions throughout fetal and adult life.

II. PARATHYROID H O R M O N E During evolution parathyroid glands first appear as discrete organs in amphibians (i.e., with the migration of vertebrates from an aqueous to a terrestrial existence). ~7'2~ Although parathyroid glands have not been identified in fish or invertebrate species, PTH-like immunoreactivity was detected in the pituitary of several fish species ~7'2~'22and a nucleofide sequence with significant homology to the mammalian PTH gene was identified in trout genomic DNA. 23 Other reports provided evidence for a PTHrP-like substance in several nonmammalian v e r t e b r a t e s p e c i e s , 24-26 suggesting that homologs of both peptides developed early in vertebrate evolution. In mammals, PTH was thought to be produced exclusively by the parathyroid glands. However, small amounts of its mRNA were recently detected in the rat hypothalamus, 27'28 indicating that PTH may be produced

53

in the central nervous system (CNS), where it could act either through the PTH/PTHrP receptor or the PTH-2 receptor, which are both expressed in various sections of the brain. 29-31 PTH shares structural and functional similarities with PTHrP, and possibly another PTH-like peptide that was recently purified from the hypothalamus. This putative PTH-like entity was shown to interact predominantly with the PTH-2 receptor and not at all, or very poorly, with the common PTH/PTHrP receptor that is used by PTH and PTHrP. 32 PTH-dependent regulation of mineral ion homeostasis is largely mediated through the PTH/PTHrP receptor, which belongs to a novel family of G-protein-coupled receptors33-35; the receptor is most abundantly expressed in the target tissues for PTH actions (i.e. kidney and b o n e ) . 36'37 The PTH/PTHrP receptor is, however, also found in a large variety of other fetal and adult tissues, and at particularly high concentrations in growth plate chondrocytes) 8-4~ It is likely that the PTH/PTHrP receptor mediates in tissues other than kidney and bone, the paracrine/autocrine actions of PTHrP, rather than the endocrine actions of PTH. Other receptors that interact with intact PTH or its fragments have also been described, but these novel, so far insufficiently characterized receptors probably mediate functions that are not involved in the control of calcium homeostasis.

A. Chemistry The first biologically active extracts of parathyroid hormone from bovine glands were made in 1925 by using hot 5% hydrochloric acid, which partially degraded the protein. 41 Further purification of the hormone was not achieved for 30 years, when Aurbach 42 and Rasmussen et al. 43 developed improved extraction procedures with denaturing solvents (phenol, urea) that did not degrade the hormonal polypeptide. Subsequent efforts led to the isolation and structural analysis of bovine, porcine, and human PTH. The bovine and porcine hormones were extracted and purified from parathyroid glands collected as a by-product of meat-packing c e n t e r s . 41'42'44-47 The limited supplies of human tissue, however, required the development of special procedures for the extraction and purification of peptides to increase yields of the human hormone. 48 Isohormonal forms of PTH were suspected to exist on the basis of fractions isolated during the final chromatography of extracts of parathyroid glands in urea. However, only one hormonal isoform has been purified and characterized structurally in the bovine. 47 The amino acid sequence of the major form of bovine PTH and that of the porcine and human hormones were determined by the then standard techniques of protein chemists; automated, stepwise removal and identification

54

JOHN T. POTTS, JR. AND HARALDJOr'r'NER

of amino acids from the amino-terminal end of the intact polypeptide and from peptide fragments prepared by proteolytic digestions of P T H . 49-54 With the advent of recombinant DNA cloning and sequencing techniques, peptide hormone sequences were deduced from nucleotide sequence without requiting isolation of the protein p e r se; these techniques were used to determine the sequence of rat, chicken, and dog PTH. 55-58 The primary structure of human PTH and those of other vertebrate species are shown in Figure 3 - 2 . Nucleotide sequence analyses of the bovine and human PTH genes confirmed the amino acid sequence of the hormones determined earlier by protein structural analysis. 59-61 Not shown in Figure 3 - 2 are the points of difference between findings of two groupsmglutamine rather than glutamic acid at position 22 in the bovine, porcine, and human hormones, and lysine and leucine rather than leucine and aspartic acid at positions 28 and 30, respectively, of the human hormone. 52 Despite extensive reinvestigation of the sequences by protein structural techniques, 62"63 no explanation for the discrepancy in results has been found. One explanation is the presence of isohormones in the bovine, porcine and human species that contain the sequence differences proposed for each molecule by Brewer et al., 52'62 but as yet no isohormones with these structural features have been reported. Inasmuch as synthetic peptides used in parathyroid research today are based largely, if not exclusively, on the sequences of bovine, human, and porcine hormone 5~ that were confirmed by nucleotide sequence analysis, 59-61 only these amino acid sequences are included in Figure 3 - 2 . There is extensive sequence homology among human, bovine, porcine, dog, and rat PTH; the hormone from each of these vertebrate species is a single-chain polypeptide of 84 amino acids, which is devoid of cysteines or substituted amino acid residues, and has a molecular

1

10

20

weight of approximately 9300. There is a preponderance of basic residues conferring an overall positive charge to the molecule. The middle portion of the molecule is quite hydrophobic and exhibits the greatest structural differences among species; this region is also the site of proteolytic attack in peripheral tissues (see Section II.C). Differences in the amino acid sequence can account for the reduced reactivity of hormone from one species with antisera raised against hormone from a second species. Chicken PTH departs significantly from the overall pattern seen with the mammalian hormones. It has two sequence deletions in the hydrophobic middle portion of the sequence and one larger addition of amino acids near the carboxyl-terminus (see Fig. 3-2). The aminoterminal region, associated with most known biological actions, shows high homology with PTH from other vertebrate species, but has several amino acid changes in the 1 3 - 2 2 region. Overall, this biologically important, amino-terminal region of PTH shows strong homology among all known vertebrate species; however, the degree of sequence preservation in PTH is less than that noted in PTHrP; furthermore, the middle and carboxylterminal regions show greater sequence variation in PTH than in PTHrP, including changes of amino acid charge (see Fig. 3 - 2 and later Fig. 3-10). The development of solid-phase methods for peptide synthesis was an important stimulus for the understanding of structure/activity relationships for PTH. 64 A series of peptide syntheses defined the 1 - 3 4 region of the molecule as essential and sufficient for full calciumhomeostatic activity in multiple bioassay systems, 65'66 and allowed comparisons of the biological activity of full-length PTH and synthetic peptide fragments (Table 3-1). The subsequent synthesis of hundreds of PTH and, later, of PTHrP analogues and fragments defined the minimal sequence of PTH that retained measurable cy-

30

40

human bovlne porolne dog rat ohloken 50

human bovlne porcine dog rat r162

70

60

D K A D V N V

L T

D K A --D V / V D K Ai~Ivt~v I D K A D VI,]V

LB

i

I

H L R A A V Q K K S I D L D K AII~N

80

K A K

S Q

K A KUQ LlUlK A KUQ L T K A K S Q i

V LN

KIWI KIIII~

FIGURE 3--2 Alignmentof the amino acid sequences of all known vertebrate PTH species. Conserved residues are shown in white letters on black background; numbers indicate the positions of amino acids in the mammalian peptide sequences.

CHAPTER3 ParathyroidHormone and Parathyroid Hormone-Related Peptide TABLE 3-- 1

55

Comparison of Biological Activity of Parathyroid Peptides from Different Species Potency, MRC U/mg a In Vitro Rat Renal Adenyl Cyclase Assay

In Vivo Chick Hypercalcemia Assay

Native hormones Bovine 1 - 8 4 Porcine 1 - 8 4 Human 1 - 8 4

3000 (2500-4000) 1000 (850-1250) 350 (275-425)

2500 (2100-4000) 4800 (3300-7000)

Synthetic fragments Bovine 1 - 34 Human 1 - 34 [Alal]-Human 1 - 3 4

5400 (3900-8000) 1700 (1400-2150) 4300 (3400-5400)

Peptide

10,000 (9060-13,400) 7700 (5200-11,100) 7400 (5200-9700)

aValues expressed as mean potency with 95% confidence items, based on Medical Research Council research standard A for parathyroid hormone. Reprinted, by permission, from Rosenblatt M, Kronenberg HM, Potts JT Jr: In DeGroot L (ed): Endocrinology. Philadelphia, WB Saunders Co, 1989, pp 848-891.

clic adenosine monophosphate (cAMP)- stimulating activity [PTH(1-27)] and demonstrated the critical importance of residues 1 and 2 for stimulating adenylate cyclase. 66-73 A series of PTH analogues with aminoterminal deletions led to the early concept of separable binding and activation domains within the PTH molecule. 67'68 The analysis of a series of amino-terminally truncated PTH analogs, PTH(3-34), PTH(5-34), PTH(7-34), PTH(10- 34), and PTH(15-34), 68 demonstrated a stepwise loss of binding affinity with progressive shortening of the amino-terminus. The peptide PTH(7-34) retained specific, although greatly reduced, binding affinity yet showed no significant agonist activity in most systems such that it could be used as an inhibitor of PTH action in vitro and in v i v o . 7~ Evolutionary conservation of the 2 5 - 3 4 region among human, 54 b o v i n e , 49'5~ porcine, 51 and rat P T H 55'74 sequences led to a series of synthetic peptides and their evaluation in radioreceptor assays. Analyses of these PTH analogues and of additional PTH fragments shortened at the amino-terminus, including PTH(20-34) and PTH(25-34), led to the concept that PTH(25-34) comprised a principal binding domain of the PTH(1-34) molecule; however, the markedly lower binding affinity of these peptides demonstrated the contribution of sequences from the amino-terminus for high-affinity binding. 67'68'75 The important contribution of position 12 in PTH antagonist design was evidenced by the 10- to 30fold greater potency of D-Trp substituted analogues as inhibitors of PTH(1-34) a c t i o n s . 68'75'76 Considerable information is accumulating which indicates that regions of PTH(1-84) other than the aminoterminal 34 residues may be responsible for novel bio-

logical actions, although the analysis of these effects is still limited to in vitro studies. For example, a series of synthetic peptides encompassing the central region of PTH delineated a putative chondrocyte mitogenic domain, which does not appear to involve cAMP activation, to a core region, PTH(30-34). 77'78 Furthermore, competition binding assays with renal plasma membranes and rat osteosarcoma cells have demonstrated binding sites for carboxyl-terminal PTH(53-84) which are discrete from those that bind PTH(1-34). 9'79-81 The observation that amino- and carboxyl-terminal fragments of PTH elicited contrasting effects on alkaline phosphatase activity, 82-84 and, in other systems, osteoclast activity, 85 supports the existence of a receptor with specificity for the carboxyl-terminal portion of PTH. Recent studies that led to the characterization of ~80- and ~30-kDa proteins, represent an important step in the effort to clone and define the chemical/functional properties of this novel receptor/binding protein which in turn may further clarify the biological role of midregional/ carboxyl-terminal PTH fragments which bind to and activate it. 1~ Conformational analysis of PTH presents a formidable challenge. Ideally the hormone-receptor complex would be co-crystallized to permit analysis by x-ray diffraction of the intermolecular interactions that are characteristic of the biologically active hormone-receptor complex. Such analysis, as has been done with growth hormone and its receptor 86 (an analysis made feasible because the soluble, extracellular domain of the growth hormone receptor is sufficient for high-affinity hormone binding), allowed molecular modeling of ligand/receptor interaction to proceed on a rational basis. Similar struc-

56 tural data would be desirable for a G-protein-linked receptor such as the PTH/PTHrP receptor with bound ligands, such as PTH or PTHrP. However, these receptors are embedded in a plasma membrane and have several membrane-spanning helices, and are thus likely to have a significantly more complex structure. Furthermore, binding of PTH or PTHrP to this complicated receptor molecule and its subsequent activation probably involves several domains, including extracellular loops as well as membrane-spanning domains, and not just the aminoterminal, extracellular domain as in the growth hormone receptor. Such a lipid-embedded multidomain structure cannot so far either be crystallized or subjected to multidimensional nuclear magnetic resonance (NMR) analysis. However, the three-dimensional structure of PTH and PTHrP as free ligands was analyzed using either P T H ( 1 - 8 4 ) or the active fragments of PTH and PTHrP by various physicochemical methods including NMR, and the results of these studies have been summarized in a recent review. 1 Of particular interest was the question whether some common structural features might be discerned for both ligands that would explain the equivalent binding of PTH and PTHrP to the common PTH/ PTHrP receptor. A two-dimensional NMR study of the 1 - 3 4 fragment of PTHrP revealed that in aqueous solution, pH 4.5, residues 3 - 9 are oL-helical, residues 10-13 and 1 6 - 1 9 form two types I [3-turns, and residues 2 0 - 3 4 form a nonhelical but ordered conformation. 87 Early NMR studies of P T H ( 1 - 3 4 ) in aqueous solution failed to detect an ordered structureSS; however, an ordered structure was found when the peptide was analyzed after being dissolved in the helix-promoting solvent trifluoroethanol (TFE). 89 A more recent study of P T H ( 1 - 3 7 ) in an aqueous solvent led to a model in which an oL-helix was detected between residues 5 - 1 0 , and residues 17 through at least residue 28. 90 Between these two helical regions there is a flexible link, residues 12 and 13, and a [3-turn, residues 14-17; the helical carboxyl-terminal end of the ( 1 - 3 7 ) molecule is bent back to become parallel with the helical region at the amino-terminus. Strong hydrophobic interactions detected between tryptophan 23 and leucine 15 stabilize the structure. Thus, the amino-terminal fragments of PTH and PTHrP have, even when studied under similar conditions, clearly distinctive secondary structures that may reflect their limited primary structural similarity (see Fig. 3-11). Since both peptides nonetheless bind to and activate the same PTH/PTHrP receptor with similar or indistinguishable affinity and efficacy, respectively, 91-94 it is conceivable that both ligands may develop a similar and highly specific conformation when part of an active

JOHN T. POTTS, JR. AND HARALD JOPPNER

hormone/receptor complex, a conformation not detected so far when the peptides are analyzed as free ligands in various solvents.

2. Regulation of Biosynthesis and Secretion 1. HISTORICAL PERSPECTIVE Accounts of the early studies that led to the elucidation of the biosynthetic pathways involved in the formation, cellular transport, and metabolism of PTH are provided in several reviews. 95-98 Studies of hormone biosynthesis in vitro, in which pulse-chase incubations of slices of parathyroid tissue with radioactive amino acids were used, led to the identification of the precursor preproPTH.99-104 PreproPTH was one of the first secreted proteins to have its initial translational product defined. The precursor includes a hydrophobic leader or signal sequence which, as reviewed below, plays a central role in directing export of the protein through the cell for secretion. 96-99 Highly sensitive protein-sequencing techniques were utilized to determine from PTH precursors, biosynthetically labeled with radioactive amino acids, the complete primary structure of both preproPTH (115 amino acids) and proPTH (90 amino acids). 99'1~176 PreproPTH and proPTH consists of P T H ( 1 - 8 4 ) with the addition of amino-terminal extension peptides that comprise 31 amino acids (pre-sequence) and 6 amino acids (pro-sequence), respectively. Specific labeling of preproPTH in cell-free systems containing radioactive methionine bound to the initiator methionyl transfer RNA established that the amino-terminal methionine at position - 3 1 of preproPTH is the first amino acid incorporated into the nascent peptide during ribosomal synthesis and indicated that preproPTH is not a cleavage product of an even larger precursor with additional amino-terminal extensions. 1~ The elucidation of the nucleotide sequence of the cDNA and the gene encoding preproPTH (see following) confirmed that preproPTH is the initial and complete hormonal product. The application of molecular cloning and nucleotide sequencing techniques provided complete cDNA sequences encoding several mammalian preproPTH species as well as the genes for the bovine, human, and rat P T H . 55'61'1~176 The presence of a termination codon immediately following the codon for glutamine at position 84 of PTH, plus evidence that there is only a single gene copy per haploid genome, ruled out the existence of additional precursors of PTH. Although the nucleotide sequence analysis also established as correct the assignment of glutamic acid to position 22, it necessitated a new assignment in human PTH, asparagine at residue

CHAPTER 3 Parathyroid Hormone and Parathyroid Hormone-Related Peptide

sequence serves to both bind to signal-recognition particles and direct its own cleavage (Fig. 3-3). A series of mutant preproPTH molecules has been expressed in GH4 cells using retroviral vectors. The functional analysis of these mutants revealed distinct functional domains within the leader sequence that showed that the first six amino acids of the aminoterminal region are dispensable, and that the hydrophobic core is vital for membrane transport. 117'118The region bordering the signal cleavage site influences the efficiency of membrane transport, and the efficiency and specificity of signal cleavage. Detailed molecular analysis of genomic DNA of a patient with familial hypoparathyroidism further illustrated the important role of the signal sequence for normal secretion. 119 A point mutation in the nucleotide sequence encoding the signal sequence changes residue - 1 4 , normally cysteine, to arginine and thereby inserts a charged residue into the hydrophobic core of the signal sequence. When this mutant preproPTH is expressed in vitro in cell-free extracts or in cultured cells, translocation across the endoplasmic reticulum, signal sequence cleavage, and subsequent secretion are all defective, and thus explain the clinical phenotype of affected individuals. Many secreted proteins have prohormone forms that are usually cleaved at dibasic residues during the maturation process. These prohormone-specific sequences can occur anywhere in the precursor protein, but their apparent functions can vary from protein to protein. For example, the dibasic residues of the corticotropin-[3-

76, instead of aspartic acid; the former being missed because of deamidation prior to protein sequence analysis. 2. FUNCTION OF THE PRECURSOR MOLECULES AND THE SIGNAL SEQUENCE The amino acid substitutions found in signal sequences are generally conservative ones. Like most other signal sequences found at the beginning of precursors of secreted proteins, the signal sequences of preproPTH (1) contain at least one positively charged amino acid near the amino-terminus, (2) contain an uninterrupted stretch of hydrophobic and nonpolar amino acids, and (3) end with small amino acids just before and at the third residue proximal to the " p r e " sequence cleavage sites. 111 This signal sequence (sometimes called leader sequence), found at the amino-terminus of secreted proteins, is instrumental in the initial binding to the endoplasmic reticulum of polyribosomes. 112'113 As the leader sequence emerges from the ribosome, it binds to an 1 IS particle called the signal-recognition particle. TM The signal-recognition particle subsequently binds to a receptor on the rough endoplasmic reticulum, thereby bringing the polyribosome to the endoplasmic reticulum. T M The polyribosome then leaves the signalrecognition particle-receptor complex and binds independently to the endoplasmic reticulum. As protein synthesis continues, the precursor protein is transferred across the membrane of the endoplasmic reticulum. Before synthesis of the protein is complete, the signal sequence is cleaved off by a signal peptidase. The signal

PTH Gene

DNA---m=:~:t~mmm--

-sensing receptor gene mutation. Nat Genet 8:303-307, 1994. 151. Heath H III, Odelberg S, Jackson CE, et al: Clustered inactivating mutations and benign polymorphisms of the calcium receptor gene in familial benign hypocalciuric hypercalcemia suggest receptor functional domains. J Clin Endocrinol Metab 81: 1312-1317, 1996. 152. Pearce SH, Williamson C, Kifor O, et al: A familial syndrome of hypocalcemia with hypercalciuria due to mutations in the calcium-sensing receptor. N Engl J Med 335:1115-1122, 1997. 153. Brown EM, Hebert SC: Calcium-receptor-regulated parathyroid and renal functions. Bone 20:303-309, 1997. 154. Mayer GP, Hurst JG: Sigmoidal relationship between parathyroid hormone secretion rate and plasma calcium concentration in calves. Endocrinology 102:1036-1042, 1978. 155. Harris ST, Segre GV, Meng XU: Suppression and stimulation test of human parathyroid function employing an amino-terminal radioimmunoassay (unpublished data). 156. Grant FD, Conlin PR, Brown EM: Rate and concentration dependence of parathyroid hormone dynamics during stepwise changes in serum ionized calcium in normal humans. J Clin Endocrinol Metab 71:370- 378, 1990. 157. Brent GA, LeBoff MS, Seely EW, et al: Relationship between the concentration and rate of change of calcium and serum intact parathyroid hormone levels in normal humans. J Clin Endocrinol Metab 67:944-950, 1988. 158. Nussbaum SR, Zahradnik RJ, Lavigne JR: A highly sensitive two-site immunoradiometric assay of parathyrin (PTH) and its clinical utility in evaluating patients with hypercalcemia. Clin Chem 33:1364, 1987. 159. Mayer GP, Hurst JG: Comparison of the effects of calcium and magnesium on parathyroid hormone secretion rate in calves. Endocrinology 102:1803-1807, 1978. 160. Habener JF, Potts JTJ: Relative effectiveness of magnesium and calcium on the secretion and biosynthesis of parathyroid in vitro. Endocrinology 98:197-202, 1976.

88 161. Brown EM, Thatcher JG, Watson EJ, Leombruno R: Extracellular calcium potentiates the inhibitory effects of magnesium on parathyroid function in dispersed bovine parathyroid cells. Metabolism 33:171-176, 1984. 162. Anast CS, Mohs JM, Kaplan SI, Burns TW: Evidence for parathyroid failure in magnesium deficiency. Science 177:606-608, 1972. 163. Anast CS, Winnacker JL, Forte LF, Burns TW: Impaired release of parathyroid hormone in magnesium deficiency. J Clin Endocrinol Metab 42:707-717, 1976. 164. Rude RK: Magnesium homeostasis. In Bilezikian JP, Raisz LG, Rodan GA (eds): Principles of Bone Biology. New York, Academic Press, 1996. 165. Rude RK, Oldham SB, Singer FR: Functional hypoparathyroidism and parathyroid hormone end-organ resistance in human magnesium deficiency. Clin Endocrinol 5:209-224, 1976. 166. Health HI: Biogenic amines and the secretion of parathyroid hormone and calcitonin. Endocr Rev 1:319-338, 1980. 167. Blum JW, Fischer JA, Hunziker WH: Parathyroid hormone responses to catecholamines and to changes of extracellular calcium in cows. J Clin Invest 61:1113-1122, 1978. 168. Mayer GP, Hurst JG, Barto JA: Effect of epinephrine on parathyroid hormone secretion in calves. Endocrinology 104:11811187, 1979. 169. Dietel M, Dorn G, Montz R, Altenahr E: Influence of vitamin D3, 1,25-dihydroxyvitamin D3, and 24,25-dihydroxyvitamin D 3 on parathyroid hormone secretion, adenosine 3',5'-monophosphate release, and ultrastructure of parathyroid glands in organ culture. Endocrinology 105:237-245, 1979. 170. Chertow BS, Baker GR, Henry HL, Norman AW: Effects of vitamin D metabolites on bovine parathyroid hormone release in vitro. Am J Physiol 238:E384-E387, 1980. 171. Cantley LK, Russell J, Lettieri D, Sherwood LM: 1,25Dihydroxyvitamin D3 suppresses parathyroid hormone secretion from bovine parathyroid cells in tissue culture. Endocrinology 117:2114-2119, 1985. 172. Sherwood LM, Potts JTJ, Care AD: Evaluation by radioimmunoassay of factors controlling the secretion of parathyroid hormone. Nature 209:52-55, 1966. 173. Morrissey J, Slatapolsky E: Effect of aluminum on parathyroid hormone secretion. Kidney Int 29(Suppl):S41-S44, 1986. 174. Williams GA, Longley RS, Browser EN: Parathyroid hormone secretion in normal man and in primary hyperparathyroidism: Role of histamine H2 receptors. J Clin Endocrinol Metab 52: 122-127, 1981. 175. Brown EM, Gardner DG, Windeck RA: /3-Adrenergically stimulated adenosine 3',5'-monophosphate accumulation in a parathyroid hormone release from dispersed human parathyroid cells. J Clin Endocrinol Metab 48:618-626, 1979. 176. Fischer JA, Oldham SB, Sizemore GW, Arnaud CD: Calcitonin stimulation of parathyroid hormone secretion in vitro. Horm Metab Res 3:223- 224, 1971. 177. Windeck R, Brown EM, Gardner GD, Aurbach GE: Effect of gastrointestinal hormones on isolated bovine parathyroid cells. Endocrinology 103:2020-2025, 1978. 178. Lancer SR, Bowser EN, Williams GA, Hargis EK: The effect of growth hormone on parathyroid function in rats. Endocrinology 98:1289-1293, 1976. 179. Gardner DG, Brown EM, Windeck RG, Aurbach GD: Prostaglandin E2 stimulation of adenosine 3',5'-monophosphate accumulation and parathyroid hormone release in dispersed bovine parathyroid cells. Endocrinology 103:577-582, 1978. 180. Au W: Cortisol stimulation of parathyroid hormone secretion by rat parathyroid glands in organ culture. Science 193:1015-1017, 1976.

JOHN T. POTTS, JR. AND HARALD JUPPNER

181. Sethi R, Kukrega SC, Bowser EN: Effect of secretin on parathyroid hormone and calcitonin secretion. J Clin Endocrinol Metab 52:153-157, 1981. 182. Hargis GK, Williams GA, Reynolds WA: Effect of somatostatin on parathyroid hormone and calcitonin secretion. Endocrinology 102:745-750, 1978. 183. Williams GA, Hargis GK, Ensinck JM: Role of endogenous somatostatin in the secretion of parathyroid hormone and calcitonin. Metabolism 28:950-954, 1979. 184. Licata AA, Au WY, Vera J, Bartter FC: Effect of prostaglandin E1 on the metabolism of rat parathyroid glands in vitro. Biochim Biophys Acta 582:59-66, 1979. 185. Deftos LJ, Lorenzi M, Bohanon N: Somatostatin does not suppress plasma parathyroid hormone. J Clin Endocrinol Metab 43: 205 - 207, 1976. 186. Brown EM: PTH secretion in vivo and in vitro. Miner Electrolyte Metab 8:130-150, 1982. 187. Berson SA, Yalow RS: Immunochemical heterogeneity of parathyroid hormone in plasma. J Clin Endocrinol Metab 28:10371947, 1968. 188. Silverman R, Yalow RS: Heterogeneity of parathyroid hormone: Clinical and physiologic implications. J Clin Invest 52:19581971, 1973. 189. Habener JF, Powell D, Murray TM: Parathyroid hormone secretion and metabolism in vivo. Proc Natl Acad Sci USA 68: 2 9 8 6 - 2991, 1971. 190. Bringhurst FR, Stern AM, Yotts M: Peripheral metabolism of PTH: Fate of the biologically active amino-terminus in vivo. Am J Physiol 255:E886-E893, 1988. 191. Bringhurst FR, Stern AM, Yotts M: Peripheral metabolism of [355]PTH in vivo: Influence of alterations in calcium availability and parathyroid status. Endocrinology 122:237-245, 1989. 192. Brossard JH, Clouthier M, Roy L, et al: Accumulation of a non(1-84) molecular form of parathyroid hormone (PTH) detected by intact PTH assay in renal failure: Importance in the interpretation of PTH values. J Clin Endocrinol Metab 81:3923-3929, 1996. I 193. Arnaud CD, Goldsmith RS, Bordier PS, Sizemore GW: Influence of immunoheterogeneity of circulating parathyroid hormone on results of radioimmunoassays of serum in man. Am J Med 56:785-793, 1974. 194. Segre GV, D'Amour P, Hultman A, Potts JTJ: Effects of hepatectomy, nephrectomy, and nephrectomy/uremia on the metabolism of parathyroid hormone in the rat. J Clin Invest 6 7 : 4 3 9 448, 1981. 195. Canterbury JM, Reiss E: Multiple immunoreactive molecular forms of parathyroid hormone in human serum. Proc Soc Exp Biol Med 140:1393-1398, 1972. 196. Fisher JA, Binswanger U, Dietrich FM: Human parathyroid hormone: Immunological characterization of antibodies against a glandular extract and the synthetic amino-terminal fragments 112 and their use in the determination of immunoreactive hormone in human sera. J Clin Invest 54:1382-1394, 1974. 197. Goldsmith RS, Furzyfer J, Johnson WJ: Etiology of hyperparathyroidism and bone disease during chronic hemodialysis: III. Evaluation of parathyroid suppressibility. J Clin Invest 5 2 : 1 7 3 180, 1973. 198. Hruska KA, Kopelman R, Rutherford WE: Metabolism of immunoreactive parathyroid hormone in the dog: The role of the kidney and the effects of chronic renal disease. J Clin Invest 56: 3 9 - 4 8 , 1975. 199. Fisher JA, Binswanger U, Dietrich FM: Immunological characterization of antibodies against a glandular extract and the synthetic amino-terminal fragments 1-12 and 1-34 and their use in

CHAPTER 3

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216. 217.

218. 219.

Parathyroid Hormone and Parathyroid H o r m o n e - R e l a t e d Peptide

the determination of immunoreactive hormone in human sera. J Clin Invest 54:1382-1394, 1972. Canterbury JM, Bricker LA, Levey GS: Metabolism of bovine parathyroid hormone: Immunological and biological characteristics of fragments generated by liver perfusion. J Clin Invest 55:1245-1253, 1975. Barling P, Bibby N: Study of the localization of [3H]bovine parathyroid hormone in bone by light microscope autoradiography. Calcif Tissue Int 37:441-446, 1985. Hruska KA, Martin K, Mennes P: Degradation of parathyroid hormone and fragment production by the isolated perfused dog kidney: The effect of glomerular filtration rate and perfusate Ca ++ concentrations. J Clin Invest 60:501-510, 1977. Goltzmann D, Henderson B, Loveridge N: Cytochemical bioasay of parathyroid hormone: Characteristics of the assay and analysis of circulating hormonal forms. J Clin Invest 65:13091317, 1980. Grunbaum D, Wesler M, Antos M: Bioactive parathyroid hormone in canine progressive renal insufficiency. Am J Physiol 247:E442-E448, 1984. DiBella FP, Gilkinson JB, Flueck J, Arnaud CD: Carboxyterminal fragments of human parathyroid tumors: Unique new source of immunogens for the production of antisera potentially useful in the radioimmunoassay of parathyroid hormone in human serum. J Clin Endocrinol Metab 46:604-612, 1978. Davis R, Talmage RV: Evidence for liver inactivation of parathyroid hormone. Endocrinology 66:312, 1960. Habener JF, Segre GV, Powell D: Immunoreactive parathyroid hormone in circulation of man. Nature 238:152-154, 1972. Segre GV, Habener JF, Powell D: Parathyroid hormone in human plasma: Immunochemical characterization and biological implications. J Clin Invest 52:3163-3172, 1972. Zull JE, Repke DW: Studies with tritiated polypeptide hormones: I The preparation and properties of an active highly tritiated derivative of parathyroid hormone: Acetamidinoparathyroid hormone. J Biol Chem 247:2195, 1972. Neumann WF, Neuman MW, Sammon PJ: The metabolism of labeled parathyroid hormone: III. Calcif Tissue Res 18:251261, 1975. Singer FR, Segre GV, Habener JF, Potts JTJ: Peripheral metabolism of bovine parathyroid hormone in the dog. Am J Med 56: 774, 1975. Martin KJ, Hruska KA, Greenwalt A: Selective uptake of intact parathyroid hormone by the liver: Differences between hepatic and renal uptake. J Clin Invest 58:781-788, 1976. Segre GV, D'Amour P, Potts JT: Metabolism of radioiodinated bovine parathyroid hormone in the rat. Endocrinology 99: 1645-1652, 1976. Habener JF, Mayer GP, Dee PC, Potts JTJ: Metabolism of amino- and carboxyl-sequence immunoreactive parathyroid hormone in the bovine: Evidence for peripheral cleavage of hormone. Metabolism 25:385, 1976. Catherwood BD, Friedler RM, Singer FR: Sites of clearance of endogenous parathyroid hormone in the vitamin D-deficient dog. Endocrinology 98:228, 1976. Martin KJ, Hruska KA, Lewis J: The renal handling of parathyroid hormone. J Clin Invest 60:808-814, 1977. Martin KJ, Hruska KA, Freitag JJ: The peripheral metabolism of parathyroid hormone. N Engl J Med 301:1092-1098, 1979. Ashkenazi A, Winslow JW, Peralta EG: An M2 muscarinic phosphoinositide turnover. Science 238:672-675, 1987. Flueck JA, Dibella FB, Edis AJ: Immunoheterogeneity of parathyroid hormone in venous effluent serum from hyperfunctioning parathyroid glands. J Clin Invest 60:1367-1375, 1977.

89

220. Sherwood LM, Rodman JS, Lundberg WB: Evidence for a precursor to circulating parathyroid. Proc Natl Acad Sci USA 67: 1631 - 1638, 1970. 221. MacGregor RR, Hamilton JW, Kent GN: The degradation of proparathormone and parathormone by parathyroid and liver cathepsin B. J Biol Chem 254:4428-4433, 1979. 222. MacGregor RR, Hamilton JW, Shofstall RE, Cohn DV: Isolation and characterization of porcine parathyroid cathespin B. J Biol Chem 254:4423-4427, 1979. 223. Morrissey JJ, Hamilton JW, MacGregor RR, Cohn DV: The secretion of parathromone and glycosylated proteins by parathyroid cells in culture. Biochem Biophys Res Commun 82:12791286, 1978. 224. Morrissey JJ, Hamilton JW, MacGregor RR, Cohn DV: The secretion of parathormone fragments 34-84 and 37-84 by dispersed porcine parathyroid cells. Endocrinology 107:164-171, 1980. 225. Martin TJ, Greenberg PB, Melick RA: Nature of human parathyroid hormone secreted by monolayer cell cultures. J Clin Endocrinol Metab 34:437-440, 1972. 226. Hanley DA, Takatsuki K, Sherwood LM: Evidence for release of fragments of parathyroid hormone during "perifusion" of bovine parathyroid glands in vitro. 59th Annual Meeting of the Endocrine Society, Chicago, 1977. 227. Neumann WF, Neuman MW, Lane K: The metabolism of labeled parathyroid hormone: V. Collected biological studies. Calcif Tissue Res 18:271, 1975. 228. Hruska KA, Korkor A, Martin K, Slatopolsky E: Peripheral metabolism of intact parathyroid hormone: Role of liver and kidney and the effect of chronic renal failure. J Clin Invest 67:885, 1981. 229. D'Amour P, Huet P, Segre GV, Rosenblatt M: Characteristics of bovine parathyroid hormone extraction by dog liver in vitro. Am J Physiol 241 :E208, 1981. 230. Segre GV, Niall HD, Habener JR: Metabolism of parathyroid hormone: Physiological and clinical significance. Am J Med 56: 774, 1974. 231. Segre GV, Niall HD, Sauer RT: Edman degradation of radioiodinated parathyroid hormone: Application to sequence analysis and hormone metabolism in vivo. Biochemistry 16:2417, 1977. 232. D'Amour P, Segre GV, Roth SI, Potts JTJ: Analysis of parathyroid hormone and its fragments in rat tissues: Chemical identification and microscopical localization. J Clin Invest 63:89, 1979. 233. Segre GV, Perkins AS, Witters LA, Potts JTJ: Metabolism of parathyroid hormone by isolated rat Kupffer cells and hepatocytes. J Clin Invest 67:449-457, 1981. 234. Zull JE, Chuang J: Characterization of parathyroid hormone fragments produced by cathespin D. J Biol Chem 260:1608, 1985. 235. Blind E, Schmidt-Gay KH, Scharla S, et al: Two-side assay of intact parathyroid hormone in the investigation of primary hyperparathyroidism and other disorders of calcium metabolism compared with a midregion assay. J Clin Endocrinol Rehab 67: 353-360, 1988. 236. Shimizu T, Yoshitomi K, Nakamura M, Imai M: Effect of parathyroid hormone on the connecting tubule from the rabbit kidney: Biphasic response of transmural voltage. Pflugers Arch 416: 2 5 4 - 261, 1990. 237. Suki WN: Calcium transport in the nephron. Am J Physiol 237: F 1 - F 6 , 1979. 238. Torikai S, Wang M-S, Klein KL, Kurokawa K: Adenylate cyclase and cell cyclic AMP of rat cortical thick ascending limb of Henle. Kidney Int 20:649-654, 1981. 239. Morel F, Imbert-Teboul M, Charbardes D: Distribution of hormone-dependent adenylate cyclase in the nephron and its physiological significance. Annu Rev Physiol 43:569-581, 1981.

90 240. Greger R, Lang F, Oberleithner H: Distal site of calcium reabsorption in the rat nephron. Pflugers Arch 374:153-157, 1978. 241. Agus ZS, Gardner LB, Beck LH, Goldberg M: Effects of parathyroid hormone on renal tubular reabsorption of calcium, sodium and phosphate. Am J Physiol 224:1143-1148, 1973. 242. Imai M: Effects of parathyroid hormone and N6,O2-dibutyryl cyclic AMP on Ca2 + transport across the rabbit distal nephron segments perfused in vitro. Pflugers Arch 390:145-151, 1981. 243. Shareghi GR, Stoner LC: Calcium transport across segments of the rabbit distal nephron in vitro. Am J Physio1235:F367-F375, 1978. 244. Bouhtiauy I, LaJeunesse D, Brunette MG: The mechanism of parathyroid hormone action on calcium reabsorption by the distal tubule. Endocrinology 128:251-258, 1991. 245. Bacskai B J, Friedman PA: Activation of latent Ca2+ channels in renal epithelial cells by parathyroid hormone. Nature 347: 3 88- 391, 1990. 246. Fraser DR, Kodicek E: Regulation of 25-hydroxycholecalciferol1-hydroxylase activity in kidney by parathyroid hormone. Nature 241:163-166, 1973. 247. Garabedian M, Holick MF, Deluca HF, Boyle IT: Control of 25hydrocholecalciferol metabolism by parathyroid glands. Proc Natl Acad Sci USA 69:1673-1676, 1972. 248. Fox J, Mathew MB: Heterogeneous response to PTH in aging rats: Evidence for skeletal PTH resistance. Am J Physiol 260: E933-E937, 1991. 249. Norman AW, Roth J, Orci L: The vitamin D endocrine system: Steroid metabolisms, hormone receptors and biological response. Endocr Rev 3:331-366, 1982. 250. Shigematsu T, Horiuchi N, Ogura Y: Human parathyroid hormone inhibits renal 24-hydroxylase activity of 25-hydroxyvitamin D3 by a mechanism involving adenosine 3',5'monophosphate in rats. Endocrinology 118:1583-1589, 1986. 251. Tanaka Y, Lorenc RS, Deluca HF: The role of 1,25-dihydroxyvitamin D3 and parathyroid hormone in the regulation of chick renal 25-hydroxy-vitamin D3-24-hydroxylase. Arch Biochem Biophys 171:521-526, 1975. 252. Wen SF: Micropuncture studies of phosphate transport in the proximal tubule of the dog: The relationship to sodium reabsorption. J Clin Invest 53:143-153, 1974. 253. Amiel C, Kuntziger H, Richet G: Micropuncture study of handling of phosphate by proximal and distal nephron in normal and parathyroidectomized rat: Evidence for distal reabsorption. Pfiugers Arch 317:93-109, 1970. 254. Bengele HH, Lechene CP, Alexander EA: Phosphate transport along the inner medullary collecting duct of the rat. Am J Physiol 237:F48-F54, 1979. 255. Pastoriza-Munoz E, Colindres RE, Lassiter WE, Lechene C: Effect of parathyroid hormone on phosphate reabsorption in rat distal convolution. Am J Physiol 235:F321-F330, 1978. 256. Gmaj P, Murer H: Cellular mechanisms of inorganic phosphate transport in kidney. Physiol Rev 66:36-70, 1986. 257. Malmstrom K, Murer H: Parathyroid hormone inhibits phosphate transport in OK cells but not in LLC-PK1 and JTC-12.P3 cells. Am J Physiol 251 :C23-C31, 1986. 258. Caverzasio J, Rizzoli R, Bonjour JV: Sodium-dependent phosphate transport inhibited by parathyroid hormone and cyclic AMP stimulation in an opossum kidney cell line. J Biol Chem 261:3233-3237, 1986. 259. Goligorsky MS, Menton DN, Hruska KA: Parathyroid hormoneinduced changes of the brush border membrane topography and cytoskeleton in cultured renal proximal tubular cells. J Membr Biol 92:151-162, 1986. 260. Jaeger P, Jones W, Kashgadan M, et al: Parathyroid hormone directly inhibits tubular reabsorption of bicarbonate in normo-

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395. Vasavada RC, Cavaliere C, D'Ercole AJ, et al: Overexpression of parathyroid hormone-related protein in the pancreatic islet of transgenic mice causes islet hyperplasia, hyperinsulinemia and hypoglycemia. J Biol Chem 271:1200-1208, 1996. 396. Nutt RF, Caulfield MP, Levy JJ, et al: Removal of partial agonism from parathyroid hormone (PTH)-related protein-(734)NH2 by substitution of PTH amino acids at positions 10 and 11. Endocrinology 127:491-493, 1990. 397. Guo J, Lanske B, Liu B, et al: Ablation of PTH/PTHrP receptors in conditionally immortalized, PTH-responsive chondrocyte cell lines. J Bone Miner Res 10(Suppl 1):S172, 1995. 398. Usdin TB, Modi W, Bonner TI: Assignment of the human PTH2 receptor gene (PTHR2) to chromosome 2q33 by fluorescence in situ hybridization. Genomics 37:140-141, 1996. 399. Jouishomme H, Whitfield JF, Chakravarthy B, et al: The protein kinase-C activation domain of the parathyroid hormone. Endocrinology 130:53-59, 1992. 400. Neugebauer W, Surewicz WK, Gordon HL, et al: Structural elements of human parathyroid hormone and their possible relation to biological activities. Biochemistry 31:2056-2063, 1992. 401. Rixon RH, Whitfield JF, Gagnon L, et al: Parathyroid hormone fragments may stimulate bone growth in ovariectomized rats by activating adenylyl cyclase. J Bone Miner Res 9:1179-1189, 1994. 402. Somjen D, Binderman I, Schltiter K, et al: Stimulation by defined parathyroid hormone fragments of cell proliferation in skeletal-derived cell cultures. Biochem J 272:781-785, 1990. 403. Fukayama S, Tashjian AH, Davis JN: Signaling by N- and Cterminal sequences of parathyroid hormone-related protein in hippocampal neurons. Proc Natl Acad Sci USA 92:1018210886, 1995. 404. Wallis GA: Bone growth: Coordinating chondrocyte differentiation. Curr Biol 6:1577-1580, 1996. 405. Frame B, Poznanski AK: Conditions that may be confused with rickets. In DeLuca HF, Anast CS (eds): Pediatric Diseases Related to Calcium. New York, Elsevier, 1980, pp 269-289. 406. Schmidtke J, Pape B, Kreugel U, et al: Restriction fragment length polymorphism at the human parathyroid hormone gene locus. Hum Genet 67:428-431.

~HAPTER z

Calcltonln T. J. MARTIN, D. M. FINDLAY, J. M. MOSELEY, AND P. M. SEXTON St. Vincent's Institute of Medical Research and The University of Melboume Department of Medicine, St. Vincent's Hospital, Fitzroy, Victoria 3065, Australia

I. II. III. IV. V.

Nature of Calcitonin Chemistry Biosynthesis Secretion and Metabolism Actions of Calcitonin

VI. Calcitonin Receptor VII. Calcitonin in Clinical Medicine VIII. Summary Acknowledgments References

When it became established that parathyroid hormone acted directly on bone to promote its resorption, the idea developed that parathyroid hormone was the major hormonal factor governing calcium homeostasis in the body. This was the basis of the McLean and Urist 1 hypothesis developed in the mid 1950s that the serum calcium was regulated by appropriate changes in the secretion rate of parathyroid hormone by a negative feedback control system. In 1961, Rasmussen 2 questioned this in suggesting that if the bone were the only means of regulating serum calcium level in conjunction with the parathyroids, the resulting feedback system would lead to wide fluctuations in serum calcium. It had been known for some time that parathyroid hormone lowered the urinary calcium, and Rasmussen made use of this in extending the McLean-Urist theory to involve the kidney. He considered that the kidney regulator was rapid to respond, sensitive to small fluctuations in hormone concentration, and of limited capacity; the bone regulator was slow to respond, relatively insensitive, but of nearly unlimited capacity. The renal action conserved serum calcium by rapidly inhibiting urinary secretion of calcium, the skeletal action by causing a less rapid dissolution of calcium from the bone matrix to the extracellular fluid. Although this seemed a more satisfactory METABOLIC BONE DISEASE

explanation of calcium control, Copp and his associates looked persistently for a better o n e . 3'4 In experiments in which they perfused the thyroparathyroid apparatus of dogs and sheep, they obtained evidence for the secretion, in response to a high calcium stimulus, of a factor that rapidly lowered systemic plasma calcium. 3 They called this calcitonin, and suggested that it was produced by the parathyroid glands. 4 After this discovery, Hirsch et al. looked afresh at some observations made in their laboratory. It had been noted that rats parathyroidectomized by cautery showed a more rapid and profound fall in serum calcium than rats parathyroidectomized by surgical excision. 5 Hirsch et al. then found that acid extracts of rat thyroid glands caused hypocalcemia when injected into r a t s . 6 They suggested that cautery of the thyroid gland during parathyroidectomy caused the release of a factor from the thyroid gland that provoked a greater fall in serum calcium than that which occurred following simple removal of the parathyroid glands (Fig. 4 - 1 ) . They called this activity "thyrocalcitonin" and showed that it could be extracted from the thyroid glands of several species, but not from other tissues. At the same time, Maclntyre's group provided support for Copp's work by demonstrating in thyroparathyroid perfusion studies in the dog that 95


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a potent, rapidly acting calcium-lowering hormone existed. 7 Subsequent perfusion studies in the goat showed that this activity was released from the thyroid gland. 8 In this species it was possible to perfuse either the external parathyroid alone or the thyroid plus parathyroid glands together (Fig. 4 - 2 ) . Furthermore, autogenous thyroid extract injected into the goats rapidly lowered the systemic serum calcium. It soon became clear that calcitonin and thyrocalcitonin were identical, were products of the thyroid gland in mammals, and probably represented an important new hormone involved in the regulation of calcium metabolism in the body.

logical assay contributed to the fact that calcitonins of several species were isolated and sequenced within a few years of its discovery. The recognition of calcitonin as a hypocalcemic hormone was hailed for several years as an answer to the tight control of plasma calcium. As information emerged about its action, however, it became apparent that this was not so, at least in the mature animal. The ability of calcitonin to inhibit osteoclastic bone resorption is beyond doubt, but the physiological significance of this seems likely to vary, for instance, during growth and development. Finally, the recognition of calcitonin's origin in the " C " or parafollicular cells of the mammalian thyroid drew attention to a second endocrine system in the thyroid gland, deriving its origin from the cells of the ultimobranchial bodies, which in birds and fish remain as discrete organs.

Comparison of the effects of thyroparathyroidectomy with parathyroidectomy by cautery and surgery in the rat. (From Hirsch PF, Gauthier GF, Munson PL: Thyroid hypocalcemic principle and recurrent laryngeal nerve injury as factors affecting response to parathyroidectomy in rats. Endocrinology 73:244-251, 1963.)

I. NATURE OF CALCITONIN Experiments in several species rapidly confirmed that calcitonin was a peptide released from the thyroid gland in response to a hypercalcemic stimulus and capable of rapidly lowering the plasma calcium and phosphorus levels. It was shown to produce this effect independent of the kidney or intestine, and it acted as an inhibitor of bone resorption. Evidence for this is summarized later in this chapter (see Section V.A). The calcium-lowering effect of calcitonin was the basis for its biological assay, and indeed the convenience and sensitivity of the bio-

A. Embryological Origin of Calcitonin-Producing Cells Much of the early work on the localization of calcitonin-producing cells comes from Pearse and his colleagues, who suggested that the "mitochondrion-rich" cells of the thyroid were responsible for calcitonin secretion. 9 When they observed electron microscopic

CHAPTER4 Calcitonin changes in the parafollicular cells of the dog thyroid following high calcium perfusion of the gland, they ascribed to these cells the function of either synthesizing or storing calcitonin, and gave them the name C cells. These cells are identical with the argyrophil parafollicular cells described in the dog by Nonidez, 1~ and in other species (e.g., the pig) they occupy epifollicular and follicular positions. 11 Pearse produced further evidence that the C cells may produce a polypeptide hormone by demonstrating their property of uptake of 5-hydroxytryptophan, 11 a faculty common to other polypeptide hormone-producing cells (e.g., the pancreatic islet cells) and pituitary corticotrophs and melanotrophs (APUD cells). At the same time he pointed out that there were two possibilities for the embryological origin of the C c e l l s n t h e ultimobranchial bodies and the neural crest h a n d he favored the former site of origin. Subsequent cytochemical studies confirmed the ultimobranchial origin of the parafollicular C cells in the rodent thyroid, 12 and it is considered that the ultimobranchial and C cells derived originally from the neural crest. The ultimobranchial body arises in the embryos of all vertebrates, with the exception of the cyclostomes, caudal to the last branchial arch, one on either side. Its fate in the adult varies across species. In lower vertebrates it remains as a distinct structure that may persist on both sides or unilaterally. In mammals it becomes fused with the thyroid during embryonic life and here gives rise to calcitoninsecreting C c e l l s . 13 No function had previously been ascribed to the ultimobranchial body, but seasonal changes in its structure had been observed in lizards, bats, and frogs. The presence of secretory material in the follicles of the ultimobranchial bodies of reptiles, amphibians, and fish suggested an endocrine function, but there was no indication as to its nature. 14-~6 It was thought that the ultimobranchial body might form reserves of parathyroid or thymic tissue in conditions of stress, or possibly that it had undergone regression during evolution and lost its original function. Observations of the teleost A s t y a n a x mexicanus revealed that the ultimobranchial body hypertrophied after the fish had been kept in the dark for periods of between 4 months and 2 years. TM These changes were associated with skeletal deformities, but the authors attributed them to a parathyroid function of the ultimobranchial body. Hypertrophy of the ultimobranchial body had also been observed in frogs 15 under conditions of calcium stress and during metamorphic climax when calcium is being transferred from stores in the paravertebral lime sacs for incorporation into bone. Thus there was some evidence for involvement of the ultimobranchial body in changes in calcium metabolism, but no specific mechanisms were known. Throughout their work, Pearse's group emphasized the variable ultimate fate of the ultimobranchial bodies

97 in different species. After originating from the neural crest, these bodies migrate forward during embryonic development. Although the ultimobranchial bodies remain as separate endocrine glands in birds, fish, and reptiles, in some submammalian species the cells can be found in other tissues of the neck and in the lung. In the lizard, for example, the main source of calcitonin is the lung, 16 although calcitonin-producing cells are present in other parts of the neck. Although in the rat the C cells are virtually all within the thyroid, this is not the case with several other mammals. In humans, for example, there is evidence for calcitonin-producing cells in the thymus and the lung, and it is therefore difficult to determine the result of calcitonin deficiency in mammals by experimentation or in humans by clinical observation. The association of calcitonin with granules in the parafollicular cells of the rat was suggested by experiments showing that administration of calcium to rats resuited in discharge from these cells of granules visible on electron microscopy. 17 In addition to the demonstration of the peptide hormone-secreting properties of C cells by histochemistry, calcitonin was identified in the C cells of the dog and the pig by immunofluorescence. This was later confirmed by in situ hybridization localization of calcitonin messenger ribonucleic acid (mRNA) to the C cells of the thyroid. TM

B. C a l c i t o n i n in Vertebrates a n d N o n v e r t e b r a t e s There has been considerable interest in the discovery that immunoreactive calcitonin-like material can be detected in the nervous systems of prevertebrate species including the sea squirt Ciona intestinalis, 19 the pond snail L y m n a e a stagnalis, 2~ a number of protochordates, and a cyclostome, Myxine. 21 These species lack bony skeletons, and the occurrence of human calcitonin-like molecules in their nervous systems suggests that the bone-regulating function of the calcitonins may be a later evolutionary development in vertebrates. Human calcitonin-like immunoreactivity (hCT-I) also exists in human cerebrospinal fluid, 22 although no direct evidence for the origin of this material is available. Low levels of hCT-I were found in extracts of postmortem human brain. 23"24 However, in addition to hCTI, low levels of material immunologically and chromatographically similar to salmon calcitonin sCT (sCT-I) also occurred. 24 The highest concentration of immunoreactivity was found in the hypothalamus, which is consistent with the hypothalamus containing the highest level of calcitonin receptors (see Section V.F). The concentrations of CT-I in the brain were ---10 times greater than those in serum and cerebrospinal fluid. 24 Similarly, extracts of rat brain diencephalon revealed the existence

98 of a biologically active sCT-like peptide 25 which was distinct from the low levels of hCT-I reported in earlier studies. 26 Although hCT-I has been detected in rat brain, there is only limited evidence for the presence of rat calcitonin (rCT) mRNA. In a Northern blot analysis of hypothalamus, a low level of rCT mRNA was observedZ7; however, S 1 nuclease assay of various brain regions failed to detect calcitonin mRNA expression, indicating that levels of calcitonin mRNA must be less than 0.2% of that of calcitonin gene-related peptide 28 (see Section II.B). The existence of multiple types of calcitonin within one species is sustained by the immunological detection of at least two forms of calcitonin in fish, reptiles, amphibia, mammals, and birds, 29-31 while the existence of a gene expressing a sCT-like peptide in humans is supported by hybridization of chicken calcitonin (cCT) cDNA to Northern blots of human medullary thyroid carcinoma tissue. 32 A role for a sCT-like peptide as a neurotransmitter or neuromodulator is supported by the presence of sCT-I within the central nervous system of lower vertebrates. In pigeon, the distribution and levels of peptide detected by a sCT-specific radioimmunoassay 33 are consistent with findings in rat b r a i n y with the highest amount detected in the hypothalamus followed by midbrain and low levels in brainstem. Immunohistochemical studies in lizard brain further demonstrated sCT-I, localized to varicosities and terminals in the diencephalon, although not in other brain regions. 34 Furthermore, the levels of calcitonin-like peptide detected in the rat diencephalon 25 were in accord with the reported levels of other neuropeptides, including CGRP and neuropeptide y,35.36 consistent with a potential role of a sCT-like peptide acting as a neurotransmitter or neuromodulator in mammalian brain. Intriguingly, the rat C lb isoform of the calcitonin receptor (CTR) (see Section VI-B) has very little interaction with the thyroidally derived form of calcitonin. 37'38 This receptor isoform is enriched in brain and may form a physiological target for endogenous sCT-like peptides. Furthermore, the C3-amylin receptor has high affinity for the teleost but not mammalian calcitonins in the rat, 39'4~ and as such this receptor phenotype is also a potential substrate for sCT-like peptides. Immunoreactivity equivalent to the thyroidally derived or ultimobranchial-derived form of calcitonin has also been found in the anterior pituitary of both mammals and lower vertebrates. 23'26'41-45 Although calcitoninlike immunoreactivity is also reported to occur in the intermediate pituitary, 41'43'44 this finding is not routinely reproducible. 42'44 The identity of the pituitary calcitonin remains to be determined. While reacting to specific hCT-antisera, the rat pituitary material does not react with all hCT-antisera, nor does preabsorption clearly

T.J. MARTIN, D. M. FINDLAY, J. M. MOSELEY, AND P. M. SEXTON

abolish pituitary staining. 43 This suggests that the pituitary calcitonin-like material is not equivalent to the thyroidal form of calcitonin. Consistent with this, Northern blot analysis of anterior pituitary, using cDNA to thyroidal calcitonin mRNA, failed to detect expression of calcitonin mRNA. 46'47 More recent data indicate that a sCT-like peptide may also be present in the anterior pituitary, with release of sCT-like peptide from cultured rat anterior pituitary cells. 48 Salmon CT-I also occurs in the mouse pituitary carcinoma cell line oL-TSH.49 The physiological significance of calcitonin-like immunoreactivity in the pituitary remains to be determined; however, calcitonin receptors are present in the intermediate pituitary 5~ and therefore the calcitonin-like material may act as a paracrine regulator of these receptors.

II. CHEMISTRY Several groups almost simultaneously published the sequence of pig calcitonin (pCT) 52'53 and within months pCT had been chemically synthesized. 54 It is a 32-aminoacid peptide with a carboxyl-terminal proline amide and a disulfide bridge between cysteine residues at positions 1 and 7. The sequence and synthesis of salmon ultimobranchial calcitonin were to follow shortly. 55 Copp had noted in making extracts of salmon ultimobranchial glands that the hormone was extremely potent. Indeed the pure or synthetic salmon hormone, at 3000 to 5000 MRC units/ mg, was 20 to 40 times more potent than calcitonins of mammalian origin. At the same time it was pointed out that medullary carcinoma of the thyroid was most likely a tumor of cells of ultimobranchial origin. This led to the extraction and purification of human calcitonin from medullary thyroid carcinoma tissue, 56 and subsequent synthesis of the human peptide. 57 Based on their amino acid sequence homologies, the different species (Fig. 4 - 3 ) have been classified into three groups as follows: 1. Artiodactyl, which includes porcine, bovine, and ovine, which differ by four amino acids. 2. Primate/rodent, which includes human and rat calcitonins, differing by two amino acids. 3. Teleost/avian, which includes salmon, eel, goldfish, and chicken, differing by four amino acids.

A. S t r u c t u r e / A c t i v i t y R e l a t i o n s h i p s The sequences of several mammalian and fish calcitonins are shown in Figure 4 - 3 . They are all 32-aminoacid peptides with a common 1 - 7 disulfide bridge and a proline amide at position 32, which is essential for

CHAPTER 4 Calcitonin 1 C G C C C C G

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activity. There are considerable differences in the sequences of the carboxy-terminal two thirds of these molecules. In several different biological assays, the order of potency of the calcitonins is teleost > artiodactyl > human, although it is important to note that the absolute efficacies vary greatly between CTRs of different species and of receptor isoforms within species. For example, hCT is 3- to 50-fold less potent than sCT at the human CTR (hCTR) 58-6~ and more than 1000-fold less potent at sheep brain membrane receptors. 61 Studies of substituted, deleted, and otherwise modified calcitonins have provided considerable information regarding structure/activity relationships of the calcitonin molecule. For example, it was deduced that the ring structure serves to protect and stabilize the molecule so that replacement of the disulfide bridge with an N - N bond in aminosuberic 1 - 7 eel calcitonin was found to provide increased biological stability and potency. 62 Despite this, linear analogs of sCT may retain full hypocalcemic activity and adenylate cyclase activation. 63 Circular dichroism studies indicate that sCT exhibits considerable secondary structure in the presence of lipid, consistent with the generation of an amphipathic oL-helix between residues 8 and 2 2 . 64,65 However, the less potent hCT has reduced propensity to form this secondary structure. Modifications of residues in the 8 - 2 2 sequence that alter the ability of sCT to form secondary structure have yielded conflicting results, in terms of the hypocalcemic potency of the analogs. 64-69 In some cases analogs with less secondary structure had correspondingly lower hypocalcemic activity, 65'67 whereas other analogs are fully active, 64'66'68 suggesting that conformational flexibility may also contribute to activity 67'69 and that factors other than secondary structure are also critical for ligand binding and receptor activation. Likely reasons for the conflicting results are first, the relative stability in vivo, compared with in vitro, of the various peptides; second, the use of different receptor types to assess the efficacy of the peptides; and third, a divergence between the relative potency of the peptides for

binding and activation of adenylate cyclase. These latter two points are illustrated in the following examples from our own work. The use of sCT analogs with varying capacities to form oL-helices revealed divergence in the responses of different receptors. 7~ This was most apparent for the stimulation of cyclic adenosine monophosphate (cAMP) production by the rat receptor isoforms C la and C l b (see Section VI.B). In cells expressing the C la receptor, helical analogs were equipotent with both sCT and analogs that have reduced or absent helical structure, consistent with their potencies in the rat hypocalcemic assay, and suggest that this latter function is mediated via interaction with C la receptors. In contrast, the nonhelical analogs were 100- to 1000-fold less potent than, for example, sCT at the C lb receptor. In addition, the general finding across receptors of several species was that reduction in the ability of sCT analogs to form helix structures had a greater impact on the potency of the analogs in competition for 125I-sCT binding than in cAMP accumulation. This disparity between the relative potencies of the peptides in studies of binding competition and cAMP accumulation was also seen in experiments to examine the basis of the high potency of sCT, relative to hCT, using chimeric sCT/hCT molecules. 7~These studies also highlighted the importance of the type of receptor used to study relative calcitonin peptide potencies. It was found that residues present in the carboxy-terminal half of sCT are more important for binding competition with the rat C la, rat C lb, and human CT receptors, whereas residues in the amino-terminal half of sCT are more important for binding competition with the porcine CTR.

III. BIOSYNTHESIS A. C a l c i t o n i n a n d Its P r e c u r s o r s The medullary carcinoma of the thyroid provided the source for studies of the amino acid sequence of hCT

100

T.J. MARTIN, D. M. FINDLAY, J. M. MOSELEY, AND P. M. SEXTON The complete sequences of the cDNA for human, v4 rat, 75'76 chicken, 77 and sheep 78 calcitonins and the DNA sequence of the full human calcitonin gene, 79 have been determined. These show that the hormone is flanked in the precursor by N- and C-terminal peptides (Fig. 4 - 4 ) , but the biological significance of these peptides is unknown. The human calcitonin gene has been located in the p 14-qter region of chromosome 11.8~

and has allowed detailed analysis of the calcitonin gene in rat and humans. Thus calcitonin is synthesized as a large molecular-weight precursor (136 amino acids) with a leader sequence at the amino terminus, which is cleaved during transport of the molecule into the endoplasmic reticulum. The location of dibasic amino acid residues at either end of the (1-32) calcitonin sequence in the precursor molecule ensures cleavage of the prohormone to yield mature calcitonin (Fig. 4 - 4 ) . In addition to cleavage, however, it is essential, as discussed earlier, that the proline residue at position 32 is amidated. The residue immediately following the proline in the precursor is glycine, which has been suggested 71 to provide the amide group for the preceding amino acids. A potentially important posttranslational modification of calcitonin is that of glycosylation. 72 It had been noted that the tripeptide sequence, Asn-Leu-Ser, found within the amino-terminal ring structure of calcitonin (Fig. 4 3) is invariate among the calcitonins of different species. This sequence is an acceptor site for N-linked glycosylation. This, together with evidence for glycosylation of tumor calcitonin, led to detailed studies showing that the calcitonin precursor is indeed a glycoprotein 73 and that the only N-linked glycosylation site in the entire precursor was within the calcitonin portion itself. The biological significance of calcitonin glycosylation has yet to be determined.

B. C a l c i t o n i n G e n e - R e l a t e d P e p t i d e a n d A l t e r n a t i v e S p l i c i n g o f the P r i m a r y C a l c i t o n i n Gene mRNA Transcript It has been found that the calcitonin gene transcript actually encodes two distinct peptides, which arise by tissue-specific alternative splicing of the mRNA. The original observation was that serially transplanted rat medullary thyroid cancers changed from states of high to low or absent calcitonin production. 81 The low producers were found to produce different mRNA transcripts, which encoded a peptide termed "calcitonin gene-related peptide" (CGRP). The mature CGRP and calcitonin mRNAs predict proteins which share sequence identity in the amino terminal regions (Fig. 4 - 4 ) , but in the carboxy-terminal regions the nucleotide sequences

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are entirely different. The mature, secreted 32- and 37amino-acid CT and CGRP peptides, respectively, result from cleavage of both amino- and carboxy-terminal flanking sequences, at cleavage sites depicted in Figure 4 - 4 . 8z The pattem of expression of calcitonin and CGRP mRNA transcripts corresponds to the immunochemical analysis of the peptides. 83 Calcitonin mRNA is found almost exclusively in the thyroid and CGRP mRNA is found primarily in the nervous system. However, aberrant expression of CGRP may be seen in medullary thyroid carcinoma, as suggested above. Two different calcitonin/CGRP genes, oL and [3, have been identified in man and rat. 84 The calcitonin/CGRP gene was one of the first examples of a cellular gene exhibiting alternative, tissuespecific processing of its primary mRNA transcript and has served as an important paradigm to study the molecular mechanisms of RNA splicing. Processing of the pre-mRNA to the calcitonin mRNA transcript involves usage of exon 4 as a 3'-terminal exon with concomitant polyadenylation at the end of exon 4 (Fig. 4 - 4 ) . Processing to produce the CGRP mRNA involves the exclusion of exon 4 and direct ligation of exon 3 to exon 5, with polyadenylation at the end of exon 6. Much work has been done to illuminate the mechanisms by which this differential splicing is achieved, 85 although it remains to be fully elucidated. Briefly, however, the hCT/ CGRP exon 4 can be characterized as having weak processing signals, like many differential exons. Weak differential exons are frequently associated with special enhancer sequences that facilitate exon recognition in the presence of accessory factors that bind to the enhancer. 86 Indeed, such an enhancer, located in the intron downstream of exon 4, has been described for the calcitonin/ CGRP gene. In addition, sequences within exon 4 are necessary for the inclusion of exon 4. 85 Another hormone of the calcitonin family is amylin (Fig. 4 - 3 ) , a 37-amino-acid peptide produced by the pancreatic [3-cells which modulates glycogen synthesis and glucose uptake in skeletal muscle and can induce insulin resistance in this tissue in v i t r o . 87"88 Amylin has about 40% sequence homology with CGRP (Fig. 4 - 3 ) , and its gene has been localized to chromosome 12. Although amylin and CGRP have biological effects distinct from those of calcitonin, at high concentrations they may mediate calcitonin-like effects, such as inhibition of bone resorption. 89 A receptor distinct from calcitonin or CGRP receptors with high affinity for amylin has recently been identified. 39 However, it is important to note that sCT can also compete for binding with high affinity at amylin binding sites. 39 Since sCT has been the ligand primarily used for calcitonin binding and functional analysis of calcitonin action, it is possible that this has introduced a degree of ambiguity into interpretation of these studies.

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IV. SECRETION AND METABOLISM Calcitonin secretion from the C cells is clearly dependent on the prevailing serum calcium level. Any tendency toward lowering of the calcium level results in storage of calcitonin within the granules of the C cells; these stores are readily discharged as the serum calcium is elevated. Although there is little doubt that calcium is an important secretagogue for calcitonin in normal or tumor C cells, the exact mechanisms by which calcium provokes exocytosis of calcitonin have not been fully elucidated. It has recently been shown, however, that the same extracellular calcium-sensing receptor that is found in parathyroid cells, 9~ where its activation leads to decreased parathyroid hormone secretion, is also found in C cells and that its presence correlates with the extracellular calcium sensing function. 91 This calcium receptor is likely to represent the primary molecular entity through which C cells detect changes in extracellular calcium and control calcitonin release, suggesting that activation of the same receptor can either stimulate or inhibit hormone secretion in different cell types. Reduction in numbers of granules and vesicles occurred during induced calcitonin secretion in v i v o 17 and from thyroid s l i c e s , 92 but alteration of calcium levels did not influence the release of calcitonin from isolated pig thyroid granules, 93 consistent with the view that calcitonin release may be mediated at the cell membrane, and intracellular stores repleted from the storage granules as the intracellular concentration falls. Agents that elevate C cell cAMP may stimulate calcitonin secretion, since cAMP analogs have been shown to have this effect in v i v o 94 and in vitro. 95 Probably the most important calcitonin secretagogues apart from calcium, however, are the gastrointestinal hormones. In the pig, gastrin appears to be an effective physiological secretagogue, 96 providing part of the evidence that has led to a view of calcitonin's physiological role as a hormone important postprandially, capable of counteracting the effect of a calcium meal and of parathyroid hormone action by preventing the efflux of calcium from bone into blood. 97 Although there is some evidence in favor of this role in the pig and r a t , 97 it is difficult to envisage it as being important in adult humans. However, this awaits further study. Other gastrointestinal hormones, including glucagon, cholecystokinin, and secretin, are also capable of promoting calcitonin secretion. 97 The gastrin analog pentagastrin has been used clinically as a provocative test for calcitonin secretion in patients with medullary carcinoma of the thyroid. Other hormones that influence calcium homeostasis may also directly or indirectly influence calcitonin secretion. 1,25-dihydroxyvitamin D3 [1,25(OH)zD3] adminis-

102


tration has been reported to increase plasma calcitonin levels; this was suggested to occur via specific thyroid C cell receptors for 1,25(OH)2D3, which modify secretion of calcitonin. 98 Both calcitonin and 1,25(OH)2D3 levels are raised in pregnancy and lactation, 99 and it has been suggested that calcitonin may act to protect the skeleton in the face of increased calcium demand by the fetus. Most of this information on the regulation of calcitonin secretion comes from observations made during acute experiments with assays of calcitonin released into plasma or culture medium. The development of cDNA and oligonucleotide probes has allowed studies of the factors influencing calcitonin mRNA production. The serum and thyroid concentrations of calcitonin increase markedly with age in the rat, and this is associated with substantial increases in thyroid content of calcitonin mRNA. TM The mechanisms of this are undetermined. In the same study, TM increasing calcium concentrations did not alter hybridizable calcitonin mRNA in response to calcium. T M Thus, in normal rats subjected to acute calcium stimulation in vivo, thyroid calcitonin mRNA was increased as measured in hybridization experiments and by translatable preprocalcitonin. TM Furthermore, in a medullary thyroid carcinoma cell line, phorbol esters selectively increased calcitonin transcription while inhibiting cellular proliferation. 1~176 On current evidence it seems that calcium can stimulate both synthesis and secretion of calcitonin by thyroid C cells. Delineation of the molecular mechanisms by which translatable calcitonin is increased by calcium will be of considerable interest. Calcitonin is degraded by liver and kidney to inactive fragments, the half-life of the peptide in blood being only a few minutes. Teleost calcitonins are considerably

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more resistant to breakdown by tissue and serum enzymes than are the mammalian calcitonins. Injected salmon calcitonin, for example, has a much longer half life than either pig or human calcitonin. 1~ Although this might contribute to the greater biological potency in vivo of sCT, the more important factor is the greater affinity of sCT for receptors. Using the most specific and sensitive radioimmunoassays, the level of calcitonin in human blood appears to be less than 10 pg/ml in normal subjects.

V. ACTIONS OF CALCITONIN A. Bone Resorption Addition of calcitonin to resorbing bone in vitro inhibited bone resorption, 1~176 an effect that appeared to be explained by a direct action on osteoclasts, inhibiting their production and activity. Calcitonin treatment of resorbing bone in vitro resulted in rapid loss of osteoclast ruffled borders and decreased release of lysosomal enzymes. In vivo evidence was also consistent with an inhibitory action upon bone resorption. Thus, calcitonin infused into rats resulted in an immediate reduction in the rate of excretion of hydroxyproline, consistent with the action of the hormone inhibiting the breakdown of bone collagen. 1~ Furthermore, kinetic studies in rats led to similar conclusions, with no evidence to suggest any increase in the active uptake of calcium by bone. 1~176 For example, when calcitonin was infused into rats that had been injected 12 hours previously with 45Ca, hormone treatment lowered plasma calcium without affecting plasma 45Ca levels (Fig. 4 - 5 ) . Under these experi-

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CHAPTER 4

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mental conditions, disappearance of radioactivity from the plasma reflected uptake of 45Ca by the skeleton. The failure of calcitonin to influence this reflects an action of the hormone to prevent calcium efflux from bone and is not consistent with active stimulation of calcium uptake by bone. Studies of the actions of hormones on isolated bone cell populations have established that calcitonin acts directly on osteoclasts. Autoradiographic experiments using biologically active iodinated sCT as receptor ligand have pointed to osteoclasts as the only discernible bone cell targets. ~~ Consistent with this are the observations of its actions in organ culture, especially the demonstration that calcitonin-treated osteoclasts in cultured mouse calvaria rapidly lose their ruffled borders. TM A similar in vivo observation of loss of ruffled border in osteoclasts has been made in patients with Paget's disease, in w h o m bone biopsies were taken before and 30 minutes after an injection of calcitonin. 1'2 In the same clinical study, calcitonin was noted to decrease the number of osteoclasts in addition to altering their ultrastructure. Studies using isolated osteoclast preparations 1~3'114 point to a direct effect of calcitonin upon the osteoclast, in which the hormone rapidly inhibits the activity of osteoclasts. In further experiments 115 it was also noted that, while isolated osteoclasts remained quiescent in calcitonin as long as the hormone was present, they regained activity when osteoblasts were added to the culture. This escape of osteoclasts from inhibition by calcitonin took place at a rate proportional to the number of osteoblasts with which they were in contact. In other studies, Chambers showed that calcitonin reduced the cytoplasmic spreading of isolated osteoclasts in a dose-dependent manner. 115 Parathyroid hormone had no effect unless osteoblasts were co-cultivated with the osteoclasts, in which case addition of parathyroid hormone resulted in a marked increase in cytoplasmic spreading of osteoclasts. It cannot be assumed that these phenomena reflect the responses of cells in bone, but this work provided for the first time some useful direct observations of actions of hormones on isolated bone cell preparations containing osteoclasts. These observations are consistent with the view that the osteoblasts (or " l i n i n g " cells) might mediate the actions of bone-resorbing hormones by producing factors that stimulate the osteoclast 1~6 and also with the view that calcitonin acts directly upon the osteoclast. The molecular mechanisms by which calcitonin decreases osteoclast function have yet to be fully defined. The rapid effects of the hormone may be brought about through actions on a cytoskeletal function of osteoclasts, after initial events involving generation of several intracellular second messengers. Early events in calcitonin signal transduction have been studied in a variety of cell

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types and are described later (see Section VI.C). With the development of improved methods of studying isolated osteoclasts, it has been possible to establish clearly that mammalian osteoclasts possess abundant, specific, high-affinity receptors for calcitonin and that calcitonin stimulates cAMP formation in a sensitive and dose-dependent manner 117 as well as increases in intracellular Ca 2+ levels. 115 The other means by which calcitonin could inhibit resorption is through inhibition of osteoclast formation. In vivo data and results from calcitonin inhibition of resorption in organ culture are consistent with this. The development of methods of studying osteoclast formation in vitro from hemopoietic precursor cells 118 has allowed this question to be addressed directly. There were several reports of calcitonin inhibiting osteoclast-like cell formation in bone marrow cultures of human, 119 baboon, 12~ and mouse 118 origin. However, these experiments were all conducted at relatively high calcitonin concentrations. In recent studies using lower concentrations of calcitonin, which nevertheless reduced calcitonin receptor m R N A expression in developing mouse osteoclasts 12~ (Fig. 4 - 6 ) , there was no reduction in osteoclast formation. The multinucleated osteoclasts formed under calcitonin treatment, however, had fewer nuclei, and, notably in this and in another study, 122 evi-

FIGURE 4--6 Effectof continuous treatment of mouse bone marrow cultures with CT. Cultures were maintained for 8 days in the presence of 1,25(OH)2D3 with (+) or without (-) 10-1~ sCT. Reverse transcription/PCR of mRNA extracted at the times indicated, was amplified using primers specific for the mouse CTR sequence or murine GAPDH. In the presence of CT, osteoclast-like cells developed, which were deficient in CTR and CTR mRNA. (Data from the authors' group.)

104 dence was obtained for the generation of osteoclasts which are deficient in calcitonin receptor m R N A and protein, but nevertheless capable of resorbing bone. This observation may be relevant to the mechanism of "esc a p e " from calcitonin action, which is considered in Section VI.D of this chapter. It should be stressed that the failure of calcitonin to inhibit osteoclast formation in such osteoclast-generating cell culture systems, except perhaps at very high calcitonin concentrations, does not exclude the possibility that inhibition of osteoclastogenesis contributes to calcitonin action in vivo. The emergence in vitro of osteoclasts deficient in calcitonin receptors complicates such experiments. Although it is interesting to consider that such a phenomenon might take place also in vivo, and even contribute to calcitonin resistance, it seems unlikely to be a consistent and major feature of in vivo responses. Although there has been no demonstration of calcitonin receptors in osteoblast-like cells, or of a direct biochemical effect of the hormone upon such cells, the administration of calcitonin has been observed to produce rapid changes in osteocytes, in which osteocyte shrinkage took place and was followed by the formation of hydroxyapatite crystals in the perilacunae and pericanaliculae. ~23 The rapid changes in the bone lining cells produced by calcitonin were enhanced by phosphate, ~24 and could be related to the possible involvement of phosphate ions in the action of calcitonin, which has been argued by Talmage. 97 Most important, however, the proposal that calcitonin acts directly upon lining cells to reduce calcium efflux from bone (in direct opposition to the action of parathyroid hormone) implies that these cells should possess receptors for calcitonin, but there is no direct evidence for this. Parathyroid hormone and the other major bone-resorbing hormones have been shown to increase plasminogen activator production by osteoblast-like cells, both normal and malignant, ~25 raising the possibility of a neutral protease derived from osteoblasts contributing to the process of matrix degradation, either directly or indirectly. This increase is not influenced by calcitonin. At present there is no convincing evidence for the existence of calcitonin receptors in cells of the osteoblast lineage, but the possibility cannot be excluded that a calcitonin-responsive subpopulation exists. It is of interest to note that calcitonin receptors and c A M P response have been found to occur in late passage cultures of a parathyroid h o r m o n e - r e s p o n s i v e osteogenic sarcoma cell line that is phenotypically osteoblast. Subclones have been developed that respond to both parathyroid hormone and calcitonin. ~26 Although it is possible that such cells reflect the existence within the osteoblast series of cells capable of a calcitonin response, it is also likely that this is a property of these malignant cells, with no relevance to normal osteoblasts.

T.J. MARTIN, D. M. FINDLAY,J. M. MOSELE¥, AND E M. SEXTON B. B o n e F o r m a t i o n Although there is no good evidence for a stimulatory effect of calcitonin upon bone formation, some early evidence was obtained for a stimulatory effect on osteoblasts. In rats treated chronically with calcitonin, an increase in the number of osteoblasts was observed in the b o n e s . 127 Furthermore, calcitonin treatment in vitro of cultures of mouse radius rudiments led to an increased net amount of bone tissue that was associated with an increased number of osteoblasts, 128 leading to the suggestion that calcitonin might have a stimulatory effect on bone formation in addition to its inhibition of resorption. It is difficult to explain such observations in the light of current views of the coupling of bone resorption to formation. It is considered that any change in bone resorption is rapidly followed by a change in formation rate in the same direction. Thus, inhibition of bone resorption by calcitonin would be expected to be accompanied by inhibition of bone formation. Indeed, this is the experience, for example, in the use of calcitonin in the treatment of Paget's disease. In in vivo experiments, no effect of calcitonin was detected on the incorporation of labeled proline into bone hydroxyproline in rats chronically treated with calcitonin. 129 To the present time, therefore, it cannot be concluded that calcitonin has an anabolic effect on bone, and indeed it seems more likely that it would be "antianabolic." In normal humans, calcitonin was shown to inhibit the excretion of hydroxyproline-containing peptides, consistent with its effect of inhibiting bone resorption, but treatment also inhibited the excretion of nondialyzable hydroxyproline, which reflects bone collagen synthesis. ~3° This can be interpreted as an inhibitory effect of calcitonin upon bone collagen synthesis, accompanying the decrease in breakdown in bone. It is interesting to note that in those acute experiments in humans, ~3° calcitonin decreased urinary hydroxyproline excretion acutely after injection, but several hours later the rates of excretion returned to pretreatment levels. With continued treatment, however, there was a gradual fall in hydroxyproline excretion, such as is seen in Paget's disease patients treated chronically with calcitonin. This is interpreted as a dual action of calcitonin, on the one hand acutely inhibiting the function of osteoclasts, and on the other a chronic effect of inhibiting the generation of new osteoclasts. Calcitonin treatment of rats led to increased matrixinduced bone formation TM which appeared to be associated with a stimulated proliferation of cartilage and bone precursor cells. The effect was seen provided the calcitonin treatment was begun before cartilage formation. After that time no effect was observed. It is not clear that this can be regarded as evidence for an ana-

CHAPTER 4

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bolic effect of calcitonin upon bone formation. The conclusion at present must be that there is no direct effect of calcitonin upon bone cells resulting in increased anabolic function. Rather, it seems likely that the reverse is the case, as an indirect consequence of inhibition of bone resorption by calcitonin.

C. Calcitonin, Bone, and Calcium Homeostasis It is worth considering how the discovery of calcitonin and its mechanism of action have influenced modern views of the regulation of the extracellular fluid calcium, and the contribution to this of bone. Older concepts of calcium homeostasis that considered only parathyroid hormone and bone were questioned with the suggestion that if bone were the only means of regulating the serum calcium level in conjunction with parathyroid hormone, control would be inadequate. Hence the suggestion that the parathyroid hormone action on the kidney might contribute. The arrival of a new calcium-lowering hormone seemed to solve the problem. However, events proved otherwise. Concepts of the role of bone in maintaining extracellular fluid calcium had relied upon observations made in the young, growing rat. Hence it was calculated that for the tibia in a young rat there was an accretion rate of 6.2% of the bone calcium per day, a resorption rate of 4.7% of the bone calcium per day, and an exchangeable fraction equivalent to 3.0% of the total calcium in the bone. 132 Thus it was clear that if accretion continued at the same rate and resorption was inhibited, the result would be a lowering of plasma calcium. The younger the animal, the more rapid the bone resorption rate. It would therefore be expected that the calciumlowering effect of calcitonin should be greater in younger than in older animals. This was indeed the case in the r a t 133 (Fig. 4 - 7 ) , in which it was noted that in the biological assay of calcitonin, which depends on the calcium-lowering effect of the hormone, the response became less marked with increasing age of the animals. It should be noted, however, that the ability of calcitonin to counteract the effect of a calcium load was not impaired in older animals, at least in the r a t , TM a n observation that has not been explained and that has not been extended to other species. Dependence of the hypocalcemic action of calcitonin upon the prevailing rate of bone resorption was also noted in other species, and it soon became clear that in normal adult humans even quite large doses of calcitonin had little effect on plasma calcium levels. In those subjects in whom bone turnover was increased (e.g., in thyrotoxicosis, Paget's disease), calcitonin treatment acutely inhibited bone resorption and resulted in a lowering of the plasma calcium. ~35

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It has been proposed that the hypocalcemic action of calcitonin is related to the availability of circulating inorganic phosphate. 9v In r a t s , 136 and in patients with chronic renal failure, 137 the degree of calcium lowering in response to calcitonin was found to be proportional to the initial blood phosphorus concentration. It has been claimed that no hypocalcemia followed calcitonin injection in rats maintained for several weeks on a phosphorus-deficient diet. 97 In contrast, Robinson et al. showed that in parathyroidectomized rats fed a low-phosphorus, high-calcium diet for 17 days, calcitonin lowered plasma calcium by a mechanism consistent with inhibition of bone resorption. 1~ It seems that the acute effect of calcitonin on serum calcium is related to the prevailing rate of bone resorption. If that is accepted, lack of a calcium-lowering effect of the hormone in the mature animal or human is not surprising, since the process of bone resorption is a slow one in maturity. It may be that the role of calcitonin in its effect on bone throughout life is that of a regulator of the bone resorptive process, whatever the overall rate of the latter. In the young, or in pathological states of increased bone resorption in maturity (e.g., Paget's disease, thyrotoxicosis), calcitonin inhibition of bone resorption can lower the serum calcium level, and there

106

T.J. MARTIN, D. M.

may even be a calcium homeostatic role for endogenous calcitonin in those circumstances. In a normal adult animal, however, when bone turnover is slow, no effect on serum calcium is obtained with calcitonin. The physiological function of calcitonin in maturity may nevertheless be to regulate the bone resorptive process, in either a continuous or intermittent manner. It follows that calcitonin should not necessarily be regarded as a "calcium-regulating hormone" in maturity, but may yet be shown to be such in stages of rapid growth (e.g., in the young or in states of increased bone turnover). It is nevertheless important that bone resorption be regulated, and calcitonin is the only hormone known to be capable of carrying out this function by a direct action on bone. Such a role might become more important in circumstances in which skeletal loss particularly needs to be prevented (e.g., in pregnancy and lactation). 138 Evidence in support of such an important physiological role for endogenous calcitonin in protecting against bone loss is provided by the experiments of Yamomoto e t al., 139 who showed that cancellous bone loss in thyroparathyroidectomized rats treated with parathyroid hormone was greater than that in similarly treated shamoperated controls.

D. Renal Effects of Calcitonin Although calcitonin lowered plasma calcium in the absence of the kidneys, it was noted that in parathyroidectomized rats with very low levels of plasma calcium, calcitonin had no effect on calcium but lowered phosphorus. 137 When this phosphate-lowering effect was found to be prevented by nephrectomy 1~ it was considered that in some circumstances the kidneys might be involved in the phosphate-lowering effect of calcitonin. Indeed, a phosphaturic effect of thyroid extract had been shown in intact r a t s , 14~ and infusion of calcitonin in parathyroidectomized rats led to a dose-dependent phosphat u r i a . 141 The effect on phosphate excretion was only a minor one in comparison with the phosphaturic effect of parathyroid hormone, and although it was demonstrated in human subjects also, 135 in several species calcitonin failed to have any effect on phosphate excretion. Thus, it has seemed unlikely that the phosphaturic effect is of any major physiological significance. The hormone was also noted to promote excretion of inorganic sulfate in r a t s 142 and humans, ~45 probably reflecting a shared renal tubular transport system between sulfate and phosphate. A number of other renal effects of calcitonin have been noted, including a transient increase in calcium excretion,135,143-145 due probably to inhibition of renal tubular calcium reabsorption. Although this has not usually been regarded as an important effect of calcitonin,

FINDLAY,

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MOSELEY, AND

P. M. SEXTON

recent observations link it to the calcium-lowering effect of calcitonin in patients with metastatic bone disease. The use of calcitonin in the treatment of hypercalcemia due to cancer has been based exclusively on the inhibition of osteolysis by calcitonin. Some evidence has been produced that failure of the kidneys to excrete the calcium load derived from bone breakdown is a major contributor to the hypercalcemia. 146 This prompted careful studies of the relative contributions to the hypocalcemic effect of calcitonin of its renal and skeletal components. 147 It was concluded that inhibition of renal tubular reabsorption by calcitonin can induce a rapid fall in serum calcium, and that the magnitude of this effect depends upon the correction of volume depletion, which inevitably accompanies hypercalcemia. Thus, the calciuretic action of calcitonin may assume greater importance than hitherto suspected. Calcitonin was found to produce a natriuretic effect in human subjects, 135''48 and study of the renal effects of calcitonin in rats pointed to striking increases in sodium excretion. 149 The effects were more marked with sCT than with calcitonins of mammalian origin, 149 raising the possibility that the natriuretic property of calcitonin from lower vertebrates might be of functional significance in those species, or that these effects were mediated by C3 receptors, which display high affinity for both sCT and amylin (see Section VI.B). Calcitonin receptors have been demonstrated clearly in rat kidney, 15~ and a further action on the kidney is to enhance 1-hydroxylation of 25-hydroxyvitamin D in the proximal straight tubule of the kidney. 15! Since autoradiographic studies ~52 and polymerase chain reaction (PCR) 152 analysis of calcitonin receptor mRNA expression have failed to localize calcitonin receptors in the proximal tubule, it seems unlikely that these actions are mediated by direct actions on calcitonin receptors. The action of calcitonin upon adenylate cyclase activity has been localized in the human nephron predominantly to the medullary and cortical portions of the thick ascending limb and to the early portion of the distal convoluted tubule. 154 The co-localization of the calcitonin receptor mRNA expression (Fig. 4 - 8 ) and cell surface receptors 152 with G-protein-sensitive adenylate cyclase is consistent with cAMP being an important mediator of calcitonin action in this organ (Fig. 4 - 8 ) . A further renal effect of calcitonin was noted as a result of studies of calcitonin effects upon a pig kidney cell line. 155 The hormone was found to stimulate greatly the production of the neutral protease, plasminogen activator. 156 This effect appeared to be related to calcitonin's actions on cAMP formation in the cells, and hormone treatment also was associated with marked inhibition of cell replication. In the same cells, calcitonin treatment enhanced the transcription of plasminogen ac-

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activation of C3 receptors, which have high affinity for amylin and sCT, but not hCT or rCT. These include inhibition of gastric acid secretion, inhibition of pancreatic enzyme secretion, and impairment of glucose tolerance.

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FIGURE 4--8 Distributionof Cla-receptor mRNAs along rat nephron. Each point represents mean value obtained from one animal (a total of 5 to 13 samples were analyzed for each structure). Dashed line indicates detection threshold of assay (50 molecules sample). (Redrawn from Firsov D, Bellanger A-C, Marsy S, et al: Quantitative RT-PCR analysis of calcitonin receptor mRNAs in the rat nephron. Am J Physiol 38:F702-F709, 1995.)

tivator mRNA, the data indicating that calcitonin was able to activate the plasminogen activator gene in those cells. 157 Subsequent studies in humans showed that calcitonin treatment resulted in increased urinary plasminogen activator activity. 158 The plasminogen activator/ plasmin system is an important local regulator of many functions, the nature of which depends on the local tissue environment. Its involvement in the local actions of calcitonin is an intriguing possibility that merits further study. The tissue effects of plasminogen activator depend on its location--thus, they are likely to be very different between kidney and bone. It is worth noting that the bone-resorbing hormones increased plasminogen activator production in osteoblast-like cells, 125 and that this effect was not influenced by calcitonin.

E. Calcitonin and the Gastrointestinal Tract It has been suggested that the function of calcitonin is to prevent rises in plasma calcium taking place after ingestion of calcium-containing m e a l s . 97'159 This is based on the observation made in pigs that calcium meals do not alter the plasma calcium, but that during the feeding period there is a rise in plasma calcitonin levels. This is a possible role for the hormone in humans, particularly in stages of growth, in which intermittent secretion in response to oral calcium loads could inhibit bone resorption and decrease the movement of calcium from bone to blood at a time when calcium was being absorbed from the intestine. However, much more study is needed in humans to define the relationship of calcitonin secretion to feeding and to gastrointestinal hormones. Other gastrointestinal effects of calcitonin are probably not physiological and, as discussed above, may relate to

F. Calcitonin in the Central Nervous System The origin of calcitonin-producing cells in the neural crest raised the possibility of calcitonin involvement in neural function. Both immunoreactive calcitonin and calcitonin receptors have been demonstrated in the brain and nervous system of rats, humans, and other species. 21'23'33 Immunoreactive calcitonin related antigenically to human calcitonin has been demonstrated in the nervous systems of protochordates, lizards, and pigeons. 21 Recent data, again obtained with radioimmunoassay, point to the presence of low levels of sCT-like peptide material in the human thyroid and in the paraventricular mesencephalic region of the brain. 16~ It has been suggested that this might be a vestige of a highly conserved gene for calcitonin. 16~ In addition to the well-characterized calcitonin receptors of bone and kidney, calcitonin receptors are also abundant in the central nervous system (CNS), 23'161-163 where central injection of calcitonin induces potent effects that include analgesia and inhibition of appetite and gastric acid secretion (reviewed in Sexton15~ Autoradiographic mapping of rat CT-binding sites revealed high densities associated with parts of the ventral striatum and amygdala, the hypothalamic and preoptic areas, as well as most of the circumventricular organs. High-density binding also occurs in parts of the periaqueductal gray, the reticular formation, most of the midline raphe nuclei, parabrachial nuclei, locus coeruleus, and nucleus of the solitary tract. 164-169 The central actions of calcitonin correlate well with the location of calcitonin-binding sites. The periaqueductal gray is important in central regulation of pain, and calcitonin binding within this region is likely to be involved in calcitonin-induced analgesia, 165 ' 170 ' 171 while the hypothalamic binding parallels the multiple hypothalamic actions of calcitonin, which include modulation of hormone r e l e a s e , 172'173 as well as decreased a p p e t i t e , 174-176 gastric acid secretion, 177'178 and intestinal motility. 179 Recently, and as also discussed in Section VI.B, cloning studies demonstrated that calcitonin receptors in rat brain are heterogeneous and exist as two distinct isof O r l T I S . 37'180 Calcitonin-specific binding sites in brain have been termed C1 sites 15~ and the two receptor isoforms are termed C la and C lb receptors. The two receptors are identical, except that the C lb sequence encodes a 37-amino-acid insert in the second extracellular domain, which confers altered ligand recognition. Both receptors

108

demonstrate high apparent affinity for sCT, but differ greatly in their affinity for hCT. C la receptors bind hCT with an apparent affinity two to three orders of magnitude less potent than sCT, whereas C lb receptors have negligible affinity for hCT. 37'38'18~PCR-based studies on the distribution of calcitonin receptor mRNA confirmed that message for both receptor isoforms is present in rat brain. 37,18~ Studies with helical and nonhelical analogs of sCT had previously suggested the existence of two potential subtypes of calcitonin-binding sites in rat brain membranes. 66 A calcitonin-linear (CT-L) type interacted with nonhelical sCT analogs with high affinity, and a calcitonin-helical (CT-H) type interacted with these analogs with a low affinity. While both types of receptors bind the helical sCT with high affinity, only the CT-L receptor binds with high affinity to hCT, which also has a reduced helical structure. The partial competition of 125I-sCT binding by hCT in the rat forebrain lsz supported the existence of multiple binding sites. These receptors are analogous to the C l a and C lb calcitonin receptor isoforms, with the specificity of interaction of the cloned receptors with helical and nonhelical sCT analogs equivalent to the CT-L and CT-H receptors, respectively. 7~ Receptor localization studies have predominantly used the fish-type calcitonins to identify receptors. 164-168'183Salmon CT, however, does not differentiate between rat C 1a and C lb receptors. Moreover, sCT also binds with high affinity to C3-amylin receptors, 39'4~ complicating interpretation of the binding distribution and its potential physiological significance. By utilizing the differences in ligand-specificity of the Cla, Clb, and C3-amylin receptors, Hilton and colleagues 51 demonstrated that distribution of C la and C lb receptors in brain was predominantly parallel. Brain regions containing C la but little or no C lb binding sites were restricted to the nucleus of the solitary tract, area postrema, and the intermediate lobe of the pituitary. In contrast, no nuclei containing exclusively C lb receptors were found, although parts of the mesencephalic and pontine reticular formation and the thalamic paraventricular nucleus were enriched in C lb receptors, relative to the density of C 1a receptors in other brain regions. The C3-amylin receptors are almost ubiquitously expressed in regions also expressing the C la receptor isoform but occur in only a subset of the nuclei labeled also with the C la-specific ligand 125IhCT. 4~ However, in restricted parts of the accumbens nucleus and fundus striati, the binding sites appear to be predominantly of the C3-receptor phenotype. 51 Only very limited structure/activity studies have been carried out in regard to the central actions of calcitonin. Indeed, in many experiments, sCT has been used to characterize either receptor localization or pharmacological action of calcitonin in the CNS. Consequently, in many


cases it is unclear whether the reported actions of calcitonin are mediated through the classic C 1-type calcitonin receptors or via C3-type amylin receptors of equivalent distribution. For example, although the analgesic action of calcitonin can be delineated as acting independently of C3-amylin receptors based both on receptor distribution studies and lack of an amylin-induced analgesic action, n~ the anorexic action of calcitonin may be primarily due to interaction with the C3 receptors. In support of the later assertion, the actions of amylin and calcitonin are paralleled (both are nonaversive agents) 184'185 and the mammalian calcitonins are relatively weaker at inhibiting appetite than lowering plasma calcium (a Cla-mediated action), 186'187 consistent with the specificity of C3-amylin receptors. 39'4~ Clearly, further studies need to be done to resolve the roles that the different receptors play in the central actions of calcitonin and related peptides. CGRP has been identified by immunocytochemistry in the central and peripheral nervous systems 188'189 and its receptors have been mapped in the brain, w~ It is uncertain whether CGRP has any significant effect on calcium metabolism, but its wide distribution and potent biological effects could indicate an important local function in several organ systems.

VI. CALCITONIN

RECEPTOR

Because preparation of osteoclasts suitable for biochemical study has only recently been possible, information on calcitonin receptor interactions was initially obtained from studies in other cell types. In mammals, calcitonin receptors were identified by direct binding studies in many cell types (e.g., in rat kidney, 192 human placenta, 193 human 23 and r a t 26'162'163 brain, human lymphoid cells, 194 cultured pig kidney cells, 156 human cancer cell lines derived from lung 195 and breast, 196 and a subclone from rat osteogenic sarcoma cells126). Calcitonin receptors have also been demonstrated in trout gill. w7

A. R e c e p t o r C l o n i n g Understanding of calcitonin receptor biology has undergone a dramatic change with the recent cDNA cloning of the calcitonin receptor of pig, 198 human, 58 rat, 37'18~ mouse, 199 and rabbit 2~176 origin. Based on amino acid homology, these receptors belong to a sub-family of the very large 7-transmembrane domain, G-protein-linked receptor class (Fig. 4 - 9 ) . This subfamily includes receptors for parathyroid hormone (PTH)/parathyroid hormone-related peptide (PTHrP), 2~ secretin, 2~ growth hormone releasing hormoneY 3 vasoactive intestinal

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polypeptide, TM glucagon-like peptide-I, 2~ pituitary adenylate cyclase activating peptide, 2~ gastric inhibitory polypeptide, 2~ and corticotropin releasing factor. 2~176 Nucleotide sequence analysis of the cloned calcitonin receptors indicated open reading frames that translate to polypeptides of around 500 amino acids, depending on the pattern of mRNA splicing. 37'58'198 Hydropathy plots indicate the presence of 7-transmembrane domains and a signal peptide at the far N-terminus. 37 There are four potential N-linked glycosylation sites in the hCTR and rCTR sequences, three of which are conserved in the porcine (p)CTR receptor. The presence of glycosylation was suggested by previous biochemical studies which indicated that the hCTR is associated with glycosyl moieties, the major contributors of which are N-acetyl-Dglucosamine residues. 21~ Posttranslational modification of the calcitonin receptor was confirmed by comparison of the predicted receptor molecular masses of--~50 kDa with those estimated from cross-linking 21~ or western blot 212 analysis, which suggest molecular masses of ---80 kDa.

B. R e c e p t o r I s o f o r m s Receptor cloning led to the discovery of calcitonin receptor isoforms (Fig. 4 - 9 ) , which arise from alternative splicing of the primary mRNA transcript and result in receptor heterogeneity. In the case of the rCTR, two isoforms were identified by cDNA cloning from a hypothalamic library. 37 These two forms, termed C la and C lb, differ structurally in that C lb contains a 37-aminoacid sequence in the second extracellular loop, which is not present in the C la form. The nomenclature here relates to that of Sexton et al., 181 who reported binding sites in rat brain, designated C1 (which bind calcitonin with high affinity), C2 (corresponding to high-affinity CGRP sites), and C3 (which interact with both peptides and which were later characterized as being high-affinity

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amylin receptors). 39 Functional studies of these isoforms have revealed interesting differences between C la and C lb. These isoforms displayed different ligand recognition, with the C lb form essentially not recognizing hCT o r r f T . 37'38'70 The kinetics of ligand binding were also very different; sCT binds to C la receptors essentially irreversibly, while binding to C lb receptors is rapidly and completely reversible. 38 Salmon CT activates intracellular signal transduction similarly via either receptor type (see below). Although the cloning data provided the first direct evidence for heterogeneity of the rCTR, there were some earlier data indicating that this might be the case. In studying calcitonin-binding sites in the brain, Nakamuta et a l . 66 found these to be heterogeneous with respect to recognition of analogs of calcitonin with different propensity for helix formation in solution. As discussed above (see Sections II.A and V.F), cells stably transfected with C la receptors have been used to show that helical calcitonin analogs are equipotent with analogs that have reduced or absent helical structure. In contrast, at C lb receptors, the nonhelical analogs were several orders of magnitude less potent than sCT.70 Using reverse transcriptase-polymerase chain reaction (RT-PCR) analysis of rat tissues and cells, the distribution of mRNA encoding C l a and C l b receptor isoforms was determined. 37'18~ Both C l a and C l b mRNA are abundant in the hypothalamus, nucleus accumbens, cerebral cortex, and brainstem. The predominant mRNA species outside the central nervous system (e.g., in the kidney) is Cla. UMR106-06 osteogenic sarcoma cells express essentially C 1a receptor mRNA only. Osteoclasts express predominantly C l a receptor, 2~3 whereas no calcitonin receptor could be detected by RTPCR in rat calvarial osteoblasts. In general, these studies showed an unexpectedly wide tissue distribution of calcitonin receptor mRNA, and this was the case also with studies in human tissues. 214'215 The functional signifi-

FIGURE 4--9 Schematiclinear diagram illustrating known splice variations within the CTR. At least four different insertions or deletions into the coding region of the receptors have been described. (1) a 71-bp insertion into the 5' end of the receptor, which provides an upstream, in-frame, potential translation start site,2~8(2) a deletion of 125-bp located in the N-terminus of the receptor coding region, which is predicted to generate an N-terminal deletion of 47 amino acids in the mature protein,TM (3) a 48-bp insertion into the predicted first intracellular domain of the r e c e p t o r , 58'214'216 and (4) a lll-bp insertion into the predicted second extracellular domain of the r e c e p t o r . 37 e, extracellular domain; i, intracellular domain; TM, transmembrane domain.

110 cance of the calcitonin receptor in most tissues remains to be explored. It is likely that the structural variations of the rCTR species are the result of alternative splicing of the primary RNA transcript, although no classic splice consensus sequences have been found in the nucleotide sequences surrounding the insert sequence in C lb. However, Southern blot analysis results were consistent with a single rCTR gene. 37 Although the rCTR gene has not been isolated, the insert sequence of C lb does occur at an equivalent position to the junction of exons 8 and 9 in the pCTR gene. 216 The hCTR gene is located on chromosome band 7q21.2-q21.3 217 or band q22. 2~8 The mouse (m)CTR gene has been localized to the proximal region of chromosome 6,199 which is homologous to the 7q region of the human chromosome 7. The structural heterogeneity within the rCTR is also present in the mCTR, which possesses virtually the same insert in the second extracellular loop. 199 T h e pCTR gene was mapped to chromosome band 9ql 1-q12. 216 In the case of the hCTR, there is no compelling evidence for a receptor isoform corresponding to the rat and mouse C lb form, although its presence in some tissues was suggested by a minor PCR fragment in one study. 214 However, several forms of the hCTR have been identified (Fig. 4 - 9 ) . The human isoforms expressed most abundantly are, first, the form originally cloned an ovarian cancer cell line, possessing a 16-amino-acid insert in the intracellular domain58; and second, an isoform cloned from the T47D breast cancer cell line, in which the insert sequence is absent. 214 The insert-negative receptor appears to be much more abundant in most tissues than the insert-positive receptor; however, transcripts encoding the latter are well represented in ovary and placenta, 214 suggesting tissue-specific regulation of this receptor isoform. Our own studies, 219 and those by other groups, 217'218'22~have now investigated the functional significance of the receptor isoforms. We found that the binding affinity and kinetics were identical for the two forms. In contrast, the presence of the insert greatly reduced the ability of the receptor to couple to adenylate cyclase, with EDs0 values 100-fold higher than those of the insert-negative form. Calcitonin-induced stimulation of a transient intracellular Ca 2+ response, via activation of phospholipase C, was abolished for the insert-positive receptor isoform. 219 The rate of ligand-induced internalization of the insert-positive form of the receptor was significantly impaired relative to the insert-negative form, suggesting that this process may be dependent on intracellular signaling. 219 Unlike the pig calcitonin receptor gene, where the 16-amino-acid insert sequence was contiguous with exon 8, 216 nucleotide sequence encoding the 16-amino-acid insert in the hCTR has been located in a separate exon of the hCTR gene. 219'22~ An additional


hCTR isoform has been described in which the first 47 amino acids of the amino-terminal extracellular domain are truncated. 222 This transcript represents a minority mRNA species in many of the tissues expressing the fulllength calcitonin receptor mRNA. Comparison of the truncated and full-length molecules by transfection revealed similar binding constants as well as calcitoninmediated cAMP production. 222 Sequencing of cDNA clones from a giant cell tumor revealed the presence or absence of a 71-bp insert in the 5'-untranslated region of the mRNA. 218 The functional significance of this sequence remains unclear. In addition to intraspecies variants of the calcitonin receptor, there are primary structural differences between species, which are likely to influence tertiary structure and hence ligand recognition or signal transduction. Indeed, and as discussed above, studies to date have revealed several dramatic differences in the ligand recognition of the rCTR hCTR and pCTRs. 7~ For example, sCT and hCT were almost equipotent in activating the hCTR, while hCT was essentially inactive at the pCTR. Analysis of the predicted amino acid sequences of the pig, human, and rat receptors revealed 78% identity between the human receptor cloned from BIN 67 ovarian cancer cells 58 and the rat C l a receptor, 37 and 67% identity between the pig receptor cloned from LLC-PK1 cells 198 and the rat C la receptor. The availability of a large number of calcitonins and analogs continues to facilitate detailed investigation of functional differences among calcitonin receptors, now that it is possible to investigate properties of expressed recombinant receptors. Already there are a number of studies from which it is possible to derive a working model of calcitonin/calcitonin receptor interactions. Studies using receptor chimeras of hCTR and glucagon receptor provided evidence for a two-site hormonereceptor interaction model, the data suggesting that both the N-terminal extracellular extension and the extracellular loops cooperate to bind calcitonin, while activation of signaling is primarily via interaction with the extracellular loops. 212 Supportive of this model are the results of experiments using CTR/PTHR receptor chimeras together with CT/PTH peptide chimeras. This work suggested that the N-terminus of the calcitonin molecule interacts with the extracellular loops and/or the transmembrane domains to activate the receptor, while binding is stabilized by interactions between C-terminal portions of the calcitonin molecule and the extracellular extension of the receptor. 223 To date there are few studies to elucidate the structure/function of intracellular domains of the calcitonin receptor. As discussed above, the naturally occurring insert in the first intracellular loop of the hCTR blocks calcitonin-induced activation of phospholipase C and subsequent increases in intracellular Ca 2§ levels. 219 Deletion of the C-terminal intracellular

CHAPTER4 Calcitonin tail of the pCTR interfered with calcitonin-induced internalization of this receptor in transfected cells. TM

C. Signal Transduction Early experiments showed that osteoclast-rich cultures derived from mouse calvariae 2z5 show a rise in cAMP formation in response to calcitonin. Confirmation that the osteoclast is a direct target for calcitonin, and that calcitonin acts in these cells to increase cAMP levels, came from experiments using highly enriched rat osteoclasts 226 or human osteoclastoma cells. 227 Moreover, both dibutyryl cAMP 228 and forskolin, which directly activate adenylate cyclase, 229 inhibit bone resorption. Calcitonin was shown to increase adenylate cyclase activity in the medullary and cortical portions of the thick ascending limb of Henle's loop, in the early portion of the distal convoluted tubule, and to some extent in the collecting tubule. 154 Interestingly, recent quantitative RTPCR confirmed the selective expression of calcitonin receptor mRNA in the same regions of the nephron previously shown to be calcitonin responsive, ~53 which was consistent with our autoradiographic localization of renal calcitonin receptor. 152 Calcitonin induction of cAMP has now been documented in a large number of calcitonin receptor-beating cell lines in culture including LLC-PK~ pig kidney cells 23~ and cancers of lung, ~95 breast, 196 and bone, 126 the evidence suggesting that coupling of the calcitonin receptor to adenylate cyclase activation occurs via receptor interaction with the G proteins of the G~s family. It is now clear that many of the G-protein-coupled receptors interact with multiple G proteins. In the case of the calcitonin receptor, there is ample evidence that calcitonin may also induce increases in cytoplasmic calcium concentrations ([Ca2+]i). For example, it is apparent that in the osteoclast, signaling through both cAMP and changes in [Ca2+]i are important in calcitonin action. TM Although controversial and potentially species specific, retraction of osteoclasts by calcitonin, and calcitonin-induced cytoskeletal changes, at least in the mouse, appear to be mainly mediated by the protein kinase A pathway. 232 On the other hand, inhibition of osteoclastic bone resorption by calcitonin can be mimicked by both dibutyryl cAMP and phorbol esters or blocked by protein kinase C inhibitors. 233 These results suggest that alternative G protein coupling can mediate calcitonin activation of either adenylate cyclase or phospholipase C, leading in the latter case to raised intracellular inositol triphosphate levels and thence increased [Ca2+], which together with the co-liberated diacylglycerol, activate protein kinase C. Calcitonin apparently causes either no change, or an inhibition of adenylate cyclase activity, in

111 brain tissue. 234'e35 Despite this, calcitonin receptors cloned from brain are capable of coupling to G~s protein in other cell types. 37'18~ In hepatocytes, calcitonin-induced activation of adenylate cyclase has not been shown, but calcitonin, even at very low concentrations, is capable of increasing [Ca2+]i .236 There is a recent report that calcitonin prevented CCl4-induced oxyradical formation and cellular damage in hepatocytes by a C lb receptor-mediated activation of protein kinase C . 237 In LLC-PK~ pig kidney cells, calcitonin can, in a cell cycle-dependent manner, induce changes mediated by either cAMP or [cae+]i .e38 Finally, expression of cloned receptors in a variety of cell types has conclusively shown that calcitonin receptors of human, 2~4 rat, 28 and porcine 239'e4~origin are capable of signaling through both cAMP- and CaZ+-activated second-messenger systems. It is important to note that comparison of the calcium response in cell lines expressing different calcitonin receptor levels has suggested that the magnitude of the response is proportional to the receptor density. 241 This relationship has been clearly shown for the TSH 242 and PTH/PTHrP receptors 243 and it is possible that relative receptor density in target tissues may influence the signaling pathway(s) activated. Calcitonin-induced [cae+]i fluxes are rapid and sustained in the presence of extracellular calcium. TM In the absence of extracellular calcium, the sustained phase is not seen. These results suggest that the initial response is mediated by inositol 1,4,5-triphosphate (IP3), which stimulates the release of calcium from intracellular stores. Calcitonin stimulation of IP3, probably generated by Gq-mediated activation of phospholipase C, has been shown in the case of cloned pCTR 239'24~ and hCTRs. 214 The sustained phase of the Ca 2+ response is dependent on extracellular calcium, and current evidence, as discussed below, suggests that this is mediated by calcium inflow through plasma membrane calcium channels. An interesting "calcium-sensing" function of the hCTR was recently reported, whereby calcitonin receptor-bearing cells were rendered sensitive to extracellular calcium in terms of increased [Ca2+]i .241 Although initially reported to be independent of calcitonin, subsequent work in cells transfected with the hCTR, 245 rCTR, and pig CTRs TM showed that sensitivity to extracellular calcium is in fact dependent upon preexposure of cells to calcitonin. Thus calcitonin treatment of calcitonin receptor-bearing cells, in the presence of extracellular calcium, causes a sustained rise in [Ca2+]i, the extent of which is dependent on the concentration of the extracellular calcium. Since osteoclasts, which express high levels of calcitonin receptor, ~7 are reportedly exposed to calcium concentrations as high as 26 mM during bone resorption, 246 this phenomenon may have par-

1 12 ticular relevance for this cell type. In isolated osteoclasts, calcitonin and extracellular C a 2+ both produce intracellular C a 2+ transients. 247 Interestingly, calcitonin and [CaZ+]e greatly potentiate the signal produced by either agent alone. 248 The mechanisms underlying this phenomenon are not yet known but two possibilities are: (1) that this is analogous to the receptor-activated calcium entry seen for a number of other receptor systems where calcium inflow apparently results from emptying of intracellular calcium stores 249 and (2) that this involves a mechanism independent of these events, since there is now evidence that calcium "sensing" results from lower concentrations of calcitonin than those required to produce intracellular calcium transients. 245 It is becoming recognized that signals generated by cell surface receptors of various classes are subject to modulation by other receptors. An intriguing example of this "cross-talk" is a finding in osteoclasts that calcitonin can down-regulate the cell signals induced by a fragment of the bone extracellular matrix molecule, bone sialoprotein (BSP). 25~ BSP and osteopontin, a related molecule also found in bone extracellular matrix, can both bind to osteoclasts, via the OLv[33integrin receptor, and induce intracellular C a 2+ mobilization. TM Calcitonin was also shown to inhibit osteopontin mRNA in isolated rabbit osteoclasts. 252 Given that BSP and/or osteopontin can act as attachment molecules for osteoclasts, 253 reduction of osteopontin formation by calcitonin could be one means by which calcitonin inhibits osteoclast activity and thus bone resorption. Calcitonin can potently modulate the growth of some calcitonin receptor-beating cells. Calcitonin was shown to stimulate the growth of human prostate cancer cells, in which calcitonin increases intracellular C a 2+ and cAMP levels. TM On the other hand, calcitonin treatment inhibited the growth of T47D human breast cancer cells, an action believed to be mediated by the specific activation of the type II isoenzyme of the cAMP-dependent protein kinase. 255 Recently, several points of intersection of cAMP-mediated pathways and those of growth factor-stimulated proliferation pathways have been identified, 256'257 although none of these intracellular mechanisms have yet been explored with respect to calcitonin. Recent reports also support a role for Ca2+-ac tivated pathways in growth modulation, with depletion of intracellular C a 2+ stores by thapsigargin being implicated in inhibition of cell growth 258 while mitogenesis by thrombin and bradykinin appeared to involve Gq-mediated increases in [Ca2+]i .259 Again, the role of these pathways in calcitonin-mediated growth modulation remains to be determined, but the above considerations are of potential importance, given the demonstrated inhibition of growth, by calcitonin, of human breast cancer cells. 255

Y.J. MARTIN, D. M. FINDLAY, J. M. MOSELEY, AND P. M. SEXTON

D. Receptor Regulation: The "Escape" Phenomenon The molecular and cellular biology of the calcitonin receptor in osteoclasts has been amenable to study following the development of a means to derive osteoclasts in vitro, 118 in addition to the cloning of the calcitonin receptor. In osteoclasts generated in mouse bone marrow cultures treated with 1,25(OH)2D3, as well as in freshly isolated osteoclasts from newborn rat, the calcitonin receptor and calcitonin receptor mRNA are abundantly expressed. 213 In this cell type the C la receptor was found to be the isoform most abundantly expressed, with C lb detectable in lesser amounts. 213 In mouse marrow cultures, calcitonin receptor mRNA could be detected by RT-PCR very early, before receptor detection by autoradiography. Furthermore, at a stage when only very few calcitonin receptor-positive cells were seen against a background of mainly stromal cells in these cultures, it was even possible to detect calcitonin receptor m R N A by the less sensitive method of Northern blot hybridization. This observation implies that the developing osteoclasts in the marrow cultures are very rich in calcitonin receptor mRNA. The calcitonin receptor has been shown to be subject to both homologous and heterologous regulation, the latter by a number of factors including glucoc o r t i c o i d s , 26~ activators of protein kinase C, 262 and transforming growth factor ~.263 Calcitonin-induced down-regulation of the calcitonin receptor was first demonstrated in various transformed cell l i n e s , 264'266 and later in primary cultures of kidney cells. 267 Receptor loss from the cell surface was shown to be due to an energydependent cellular internalization of the ligand-receptor complex. 268 The molecular mechanisms involved in these events remain to be fully elucidated, but appear to be cell type dependent. As noted for the PTH/PTHrP receptor, 269 ligand-induced phosphorylation of the hCTR has recently been demonstrated 27~ and may be important in receptor regulation. Preincubation of calcitonin receptor-beating cell lines with calcitonin resulted also in persistent activation of adenylate cyclase, which was shown to be due to persistent occupancy of cell-surface receptors by poorly dissociable sCY. 271'272 Calcitonin treatment also resulted in desensitization of the cells to a subsequent challenge with calcitonin, which was thought to be due to receptor loss from the cell surface and possibly to an uncoupling of the remaining receptors from signal t r a n s d u c t i o n . 271'272 Although calcitonin inhibits bone resorption, it has been found in vitro and in vivo that calcitonin inhibition is followed by " e s c a p e . ''273'274 " E s c a p e " is defined as an increase in resorption in bones stimulated to resorb

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by a resorptive agent, despite the continued presence of concentrations of calcitonin that were maximally inhibitory. Furthermore, rats treated chronically with calcitonin become refractory to the hypocalcemic action of the peptide) 75 Data from the in vitro experiments suggested that "escape" was due to a change in responsiveness to calcitonin rather than a loss of activity of the hormone. An interesting feature of the phenomenon is that the development of escape in vitro can be prevented by concomitant treatment of the bones w i t h glucocorticoid, 276 which more recent experiments indicate might be due to antagonism by glucocorticoid of calcitonin-induced calcitonin receptor down-regulation in osteoclasts. 261 The phenomenon of "escape" is such an integral part of calcitonin action that it has to be borne in mind whenever the hormone is being used therapeutically. It helps to explain why calcitonin is less effective than might be expected in the treatment of such states of excessive bone resorption as hyperparathyroidism and malignant hypercalcemia. The biochemical and cellular mechanisms by which calcitonin induces refractoriness to its own action have been the subject of intense study in recent years. Studies of osteoclasts in c u l t u r e 276-278 have shown that calcitonin treatment results in down-regulation of the calcitonin receptor, which is nevertheless different from that seen in other cell types in that down-regulation is considerably prolonged. 276 These results were consistent with the hypothesis that the resistance to calcitonin that typifies the clinical phenomenon of "escape" might be due to reduced calcitonin sensitivity of osteoclasts. Evidence for this had previously been obtained by elegant experiments in bone organ culture. TM We have shown that either s h o r t 276'279 o r continuous 121 treatment of osteoclasts with calcitonin results in a rapid and prolonged downregulation of calcitonin mRNA, whereas in the nonosteoclastic human breast cancer T47D cells, there was no decrease in calcitonin receptor mRNA levels, z76 Significantly, calcitonin-treated osteoclasts regained the ability to resorb bone, 122 again suggesting that functional, calcitonin-resistant osteoclasts result from exposure to pharmacological doses of calcitonin. It was also found that in the continuous presence of calcitonin, resorptive osteoclast-like cells, that had very low levels of calcitonin receptor mRNA, formed in mouse bone marrow cultures TM (Fig. 4-6). These results, therefore, indicate that calcitonin-induced decreased responsiveness of osteoclasts to calcitonin is at least partly due to suppression of calcitonin receptor and its mRNA in existing osteoclasts and to the development of newly formed osteoclasts that have very low levels of calcitonin receptor. It is interesting to note that in bone organ culture, "escape" was prevented by irradiation, which would inhibit proliferation of osteoclast precursors, 28~ and that "es-

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cape" was accompanied by the formation of small, newly formed active osteoclasts. TM Down-regulation of calcitonin receptor and of calcitonin receptor mRNA in mature mouse osteoclasts, but not in nonosteoclastic cells, appears to be mediated by activation of cAMPdependent protein kinase. 282

VII. CALCITONIN IN CLINICAL MEDICINE The discussions in this chapter of the mechanism of action of calcitonin provide background to the use of calcitonin in therapy. Its specific uses are considered in detail elsewhere in this volume, but one of the most important unanswered questions concerning the role of calcitonin in physiology, pathology, and therapeutics is whether its role as an inhibitor of bone resorption is such that calcitonin deficiency can lead to the development of osteoporosis. The corollary would be that calcitonin could be used in the treatment of osteoporosis. Initial reports that basal calcitonin levels are lower in women than in men, 283'284 fall with age in both, 285 and are reduced in osteoporotic women 286 gave rise to considerable interest in the possible use of calcitonin in the treatment of postmenopausal osteoporosis. However, enthusiasm has been tempered by subsequent data showing no difference in basal calcitonin levels between postmenopausal osteoporotic and age-matched normal w o m e n . 287'288 Calcitonin has an established place in the treatment of Paget's disease of bone, and is increasingly used in osteoporosis, where its effectiveness in nasal spray form has been established. 289

VIII. SUMMARY Calcitonin is a polypeptide hormone whose major recognized effect in mammals, including humans, is to inhibit bone resorption. This it does by acutely inhibiting osteoclast activity, and perhaps also by inhibiting the generation of osteoclasts, although the in vitro evidence for the latter is conflicting. Because bone resorption is rapid enough to contribute to the maintenance of extracellular fluid calcium only in stages of growth or in certain disease states in maturity, in which bone resorption is increased, it follows that only in those circumstances does calcitonin injection result in a significant fall in plasma calcium. Thus, although calcitonin was discovered as a calcium-lowering hormone in experiments that were carried out in young animals, it may be that its function throughout life is that of a regulator of the bone resorption process. This might not necessarily contribute

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to acute maintenance of plasma calcium in maturity. Consideration of the "physiological" role of calcitonin often fails to take into account the need to regulate the bone resorptive process, however slowly that may be proceeding, and whether or not it contributes to maintenance of the plasma calcium level. Thus, the general role of calcitonin in skeletal metabolism may indeed be that of the most important inhibitor of the bone resorptive process, acting to prevent excessive skeletal loss throughout life, and especially at times at which skeletal loss becomes a risk, for example, in rapid growth, pregnancy and lactation, immobilization, and certain pathological states (Paget's disease of bone, thyrotoxicosis, hyperparathyroidism). This working model of calcitonin action and function can be applied to any discussion of the hormone's role in therapy or in pathogenesis of bone disease. The last few years have opened fascinating new aspects of calcitonin physiology. This includes particularly the cloning of the calcitonin receptor and the finding of a number of functionally different calcitonin receptor isoforms, the discovery of calcitonin and of calcitonin receptor sites in the brain, leading to the possible role of calcitonin as a neuropeptide. The most interesting areas we have to address now are the physiological significance of the receptor isoforms, the details of calcitonininduced intracellular signaling, and the potential role of calcitonin in cell growth and differentiation.

Acknowledgments These authors acknowledge the support of The National Health and Medical Research Council of Australia and The Anti-Cancer Council of Victoria in funding their work. Their thanks are also extended to Mrs. A. Carruthers for her help in the preparation of the manuscript.

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~HAPTER

.

Vitamin D Metabolism and Biological Function MICHAEL

F. H O L I C K

J O H N S. A D A M S

Boston University Medical Center, Boston, Massachusetts 02118 University of California, Los Angeles, Los Angeles, California 90048

I. II. III. IV. V.

History of Vitamin D Photobiology of Vitamin D3 Intestinal Absorption of Vitamin D Metabolism of Vitamin D to 25-Hydroxyvitamin D Metabolism of 25-Hydroxyvitamin D to 1,25-Hydroxyvitamin D VI. Alternative Metabolism of 25-Hydroxyvitamin D and 1,25-Dihydroxyvitamin D VII. Metabolism of Vitamin D2

VIII. Biological Actions of 1,25(OH)2D IX. Biological Actions of 1,25(OH)2D in Tissues Regulating Calcium Balance X. Actions of Vitamin D Metabolites and Analogs in Nonclassical Target Tissues XI. Assays for Vitamin D and Its Metabolites XII. Conclusion References

The secosterol vitamin D has its origin dating back at least 0.5 billion years ago, when it was produced in ocean dwelling phytoplankton while they were being exposed to sunlight, possibly to act as a sunscreen. 1 With the evolution of the terrestrial vertebrates, vitamin D became important for the development and maintenance of the ossified skeleton. One of the principal physiological functions of vitamin D is to maintain normal circulating concentrations of calcium and phosphorus for support of neuromuscular function and bone ossification. Vitamin D is able to accomplish this by enhancing the efficiency of the small intestine to absorb dietary calcium and phosphorus and increasing the mobilization of calcium stores from the bone. During the past two decades, intense research has revealed that vitamin D is not a vitamin but a hormone. Once vitamin D is made in the skin or ingested in the diet it undergoes successive hydroxylations in the liver METABOLIC BONE DISEASE

and kidney to be transformed to 1,25-dihydroxyvitamin D [1,25(OH)2D]. 2 1,25(OH)2D is the hormonally active form of vitamin D that leaves the kidney and travels in the circulation to its various target tissues and cells to carry out its physiological functions. This knowledge has led to the development of assays for vitamin D metabolites, which have been invaluable in obtaining solid clinical evidence that acquired and inherited disorders of vitamin D metabolism are the cause of several hypo- and hypercalcemic disorders. Although the major target tissues for 1,25(OH)2D are the small intestine, bone, and kidney, recently it has been revealed that such diverse tissues and cells as the skin, pancreas, parathyroid gland, stomach, gonads, brain, monocytes, and activated T and B lymphocytes possess low-capacity, high-affinity nuclear receptors for this hormone. In a variety of experimental systems, both in vivo and in vitro, 1,25(OH)2D has been shown to inhibit tu123

Copyright 9 1998 by Academic Press. All rights of reproduction in any form reserved.

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MICHAEL E HOLICK AND JOHN S. ADAMS

mor cell proliferation and promote cellular differentiation; to stimulate insulin, thyroid-stimulating hormone, and interleukin-1 synthesis or release; to inhibit parathyroid hormone (PTH) and interleukin-2 synthesis and secretion; and to induce peripheral monocytes to mature into osteoclast-like cells. Although the physiological relevance of these observations is unclear at present, these revelations have given rise to speculation that 1,25(OH)2D is important for the recruitment of bone marrow stem cells to form new osteoblasts and osteoclast-like cells and to the novel use of 1,25(OH)2D for the treatment of lymphomas and psoriasis. The purpose of this chapter is to review the recent advances in the photobiology, biochemistry, and physiology of vitamin D and to recount how this fundamental knowledge has been useful for the diagnosis and treatment of a variety of disturbances in calcium and bone metabolism as well as diseases as diverse as psoriasis and cancer.

I. HISTORY OF VITAMIN D A. Rickets and the Environment There is firm evidence that most plants and animals that live on the Earth today have the capacity to produce vitamin D during exposure to sunlight. 1'3 In terms of human history, however, historians state that the disease rickets was reported to occur in humans as early as the 2nd century AD, but the disease was not considered a significant health problem until people began to congregate into the cities in northern Europe just prior to its industrialization. 4 In the mid-17th century, Whistler, Glisson, and DeBoot each independently recognized that many of the children who lived in the sunless alleyways in the industrialized cities developed a severe disease of the bones. They noted that this disease was associated with deformities of the skeleton, particularly enlargement of the epiphyses of the joints of the long bones and the rib cage (commonly referred to as the rachitic rosary), bending of the spine, enlargement of the head, curvature of the thighs, and weak and toneless muscles, especially of the extremities (Fig. 5-1).4'5 The incidence of this debilitating bone disease increase dramatically during the Industrial Revolution, especially in northern Europe and North America, and by the latter part of the 19th century, autopsy studies done in Leiden, the Netherlands, suggested that approximately 80% to 90% of children raised in the crowded cities of these areas had the disease. 6 As early as 1822, the Polish physician Sniadecki realized the importance of sun exposure for the prevention and cure of rickets. 7 He realized that children living in the inner city of Warsaw had a very high incidence of

FIGURE 5 - - 1 Child with rickets showing rachitic rosary of the rib cage, bowed legs, deformity of the long bones, and muscle weakness. (From Fraser D, Scriver CR: Hereditary disorders associated with vitamin-D resistance or defective phosphate metabolism. In DeGroot L, et al (eds): Endocrinology, vol 2. New York, Grune & Stratton, 1979, pp 797-807.)

this bone disease, whereas children living in the rural areas outside of Warsaw were essentially free of this disorder. He advocated if the parents' financial status permits, it is best to take the children out into the country and keep them as much as possible in the dry, open, and pure air. If not, at least they should be carried out in the open air, especially in the sun, direct action of which on our bodies must be regarded as one of the most efficient methods for the prevention and cure of this disease. 7 However, little attention was focused on the environment as a cause for this disorder until 1889 when an investigative committee of the British Medical Association reported that rickets was unknown in the rural districts of the British highlands but that it was prevalent in the large industrial towns. 8 A year later, Palm 9 reported his epidemiological survey that included clinical observations from a number of physicians throughout the British Empire and the Orient. His information revealed that

CI-IAPTER 5 Vitamin D Metabolism and Biological Function rickets was rare in children living in impoverished cities in China, Japan, and India where the people received poor nutrition and lived in squalor, whereas the children of the middle-class and poor who lived in the industrialized cities in the British Isles had a high incidence of rickets. Based on this survey he urged the following: the establishment of a sunshine recorder in the heart of the city to record the chemical activity of the sun's rays rather than its heat; the removal of rachitic children, as early as possible, from the large towns to a locality where sunshine abounds and the air is dry and bracing; the systematic use of sunbaths as a preventative and therapeutic measure in rickets and other diseases; and the education of the public to the appreciation of sunshine as a means of health. However, it was difficult at the time for people to believe that such a simple remedy as exposure to sunlight could have any significant effect on curing this crippling bone disease. At the turn of the 20th century, many theories had surfaced as to the cause of the debilitating disease, including infection, poor nutrition, lack of activity, and an inherited disorder. In 1905, Buchholz 6 exposed 16 rachitic children to a carbon-arc light source and suggested that there was a favorable response. However, in 1919 Huldschinsky demonstrated unequivocally for the first time that phototherapy alone was curative. He reported four patients with severe tickets who were cured (based on x-ray examination) after being treated with exposure to a mercury-vapor quartz lamp. ~~ He speculated that the radiation responsible for this cure was the same radiation that causes melanization of the skin. He also showed that the effect of phototherapy was not local, inasmuch as exposure of one arm had equal and dramatic curative effects on both arms. Two years later, Hess and Unger ~ exposed seven rachitic children on the roof of a New York City hospital to varying periods of sunshine and reported that x-ray examinations showed marked improvement of the tickets of each child as evidenced by calcification of the epiphyses.

B. V i t a m i n D" T h e N u t r i e n t During the 19th century, cod-liver oil was frequently used for the prevention and cure of rickets. This knowledge prompted an intense investigation to determine what nutrient was responsible for preventing rickets. In 1919, Mellanby ~2 reported that he could produce rickets in dogs by feeding them oatmeal and could cure the disease by adding cod-liver oil to their diet. In 1921, McCollum and colleagues 13 reported that profound influence of dietary phosphorus on the calcification of cartilage and ossification of bone in growing rats. They demonstrated that rats given a diet deficient in phosphorus and the antirachitic factor developed rickets, whereas

125 rats given diets adequate in calcium and phosphorus but deficient in the antirachitic factor developed osteoporosis but not tickets. With this experimental model they examined the question of whether the antirachitic factor in cod-liver oil was identical to or distinct from vitamin A. In 1922, these workers oxidized cod-liver oil, destroying all vitamin A activity, and showed that the oxidized oil retained its antirachitic properties. Thus, it became clear that the antirachitic factor present in cod-liver oil was not vitamin A but a new fat-soluble vitamin that was to be called vitamin D. The fact that the antirachitic factor could be generated in the skin after exposure to sunlight or ultraviolet radiation or could be obtained from codliver oil caused some confusion as to whether there was more than one antirachitic factor. This issue was resolved when Powers et al. TM reported that radiation from a mercury-vapor quartz lamp had similar if not identical healing effects on rachitic rats when compared with those brought about by the administration of cod-liver oil. Once it was known that exposure to sunlight could prevent and cure the disease, Steenbock and Black 15 and Hess and Weinstock 16 independently demonstrated that exposure of food and a variety of other substances to the vitamin D-producing radiation from the mercury-vapor quartz lamp could impart antirachitic properties to these substances. These investigators reported that exposure of rat liver, human serum, olive, cotton and linseed oils, lettuce, growing wheat, rat chow, and a variety of other substances endowed each with antirachitic properties. This concept was used to make milk antirachitic by adding the precursor of vitamin D to milk and exposing it to radiation from a mercury-arc lamp. Today, 400 IU (10 txg) of vitamin D2 or vitamin D3 is directly added to milk and other foods, resulting in almost complete elimination of rickets in the United States and in countries that use this practice. Once it was established that the antirachitic factor could be produced in vitro by the ultraviolet (UV) irradiation of plant and animal tissues, several investigators began the quest to isolate and structurally identify the antirachitic factor. Originally, it was thought that the substance that was activated by UV radiation was cholesterol in animals and phytosterol in vegetable foods. 15'17 However, cholesterol lost the property of becoming antirachitic when it was purified by chemical means. It was concluded that the precursor of vitamin D (called provitamin D) was not cholesterol itself, but a substance associated with it. TM The findings that ergosterol, a yeast sterol, had an intense ultraviolet absorption band at 280 nm (which was similar to the UV absorption maximum for the cholesterol-like sterol that had antirachitic properties) and that this yeast sterol could be rendered antirachitic by exposure to ultraviolet radiation suggested that the parent substance of vitamin D was either ergos-

126


terol or a highly unsaturated sterol similar to ergosterol. These observations prompted the quest of several laboratories to isolate and structurally identify the antirachitic factor. Reerink and van Wijk m and Askew et al. 2~ purified vitamin D from irradiated ergosterol and reported almost identical UV absorption spectra with X max at 265 and 262 nm, respectively. Initial characterization of vitamin D established that the structure retained the secondary hydroxyl group of the parent ergosterol, that ring B was opened between carbon 9 and 10, and that there were three double bonds in conjunction with each other (Fig. 5 - 2 ) . Finally, in 1948 x-ray crystallographic analysis of a heavy atom derivative of vitamin D yielded the spacial orientation of vitamin D as a molecule that is quite different from its parent sterol (Fig. 5 - 2 ) . The first vitamin D that was isolated from the irradiation of ergosterol was designated vitamin D1. However, the product was found to be an impure mixture of vitamin D and lumisterol and the term was dropped. Vitamin D was finally purified from its irradiation products and was named ergocalciferol (vitamin D2) (Fig. 5 - 2 ) . Initially, it was thought that vitamin D2 was iden-

tical to the vitamin D that was present in fish-liver oils and was produced in the skin by exposure to sunlight. However, in the 1930s it was reported that vitamin D obtained from the irradiation of ergosterol had little antirachitic activity in chickens, whereas the vitamin D that was isolated from the irradiation of cholesterol-like sterol yielded a very potent antirachitic substance. 21-23 The confusion as to whether vitamin D2 w a s identical to the substance produced in skin was resolved when Windaus et al. 24 reported the synthesis of a new provitamin D analogue that was similar to ergosterol with the exception that the side chain was that of cholesterol (Fig. 5 - 2 ) . This provitamin D was called provitamin D3 or 7dehydrocholesterol and upon irradiation gave rise to cholecalciferol (vitamin D3) (Fig. 5 - 2 ) . This new vitamin D had equal antirachitic activity in chick and rat to the vitamin D that was isolated from the cholesterol-like sterol and was identical to the vitamin D found in fishliver oils and mammalian skin. 25 Therefore, it was concluded that 7-dehydrocholesterol rather than ergosterol was the parent compound present in the skin and that the resulting photoproduct was vitamin D3.

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Structure of vitamins D3 and D2 and their respective precursors, 7-dehydrocholesterol and ergosterol. The only structural difference between vitamins D2 and D3 is their side chains; the side chain for vitamin D2 contains a double bond between carbon-22 and carbon-23 and a carbon-24 methyl group. (From MacLaughlin JA, Holick MF: Photobiology of vitamin D3 in the skin. In Goldsmith LA (ed): Biochemistry and Physiology of the Skin, vol 2. London, Oxford University Press, 1983, pp 734-754.)

CHAPTER 5

127

Vitamin D Metabolism and Biological Function

II. P H O T O B I O L O G Y

OF VITAMIN

imately 10% is reflected and the other 90% is absorbed or scattered. 26 During exposure to sunlight, UV-B photons are transmitted into the epidermis and dermis where cytoplasmic stores of provitamin D3 are located. The 5,7diene of provitamin D3 absorbs this radiation, causing cleavage of ring B between carbons 9 and 10 and the formation of a 6,7-cis-conjugated triene to form a 9,10seco (seco from the Greek term split) sterol known as previtamin D3 (Fig. 5--3). 27 In adult skin, approximately 50% of the entire cutaneous stores of provitamin D3 are

D3

A. P h o t o s y n t h e s i s of P r e v i t a m i n D3 in H u m a n Skin The sun emits a broad spectrum of radiation. The high-energy photons that are most damaging to life on Earth (below 290 nm) are absorbed by the thin layer of ozone that envelops the Earth. When radiation between 290 and 315 nm (UV-B radiation) hits the skin, approx-

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128

MICHAELE HOLICKAND JOHN S. ADAMS

found in the epidermis while the other 50% reside in the dermis. 27 When adult Caucasians and blacks are exposed to sunlight, approximately 70% to 80% and 95% to 98% of the UV-B photons are absorbed in the epidermis, respectively. Therefore, approximately 80% to 90% of the previtamin D3 that is formed occurs in the actively growing layers of the epidermis (stratum basale and stratum spinosum) while less than 20% occurs in the dermis. 27 In neonates, about 50% of the provitamin D3 stores in the skin are present in the dermis, and because the epidermis transmits more UV-B photons into the dermis, the dermis is also a major site for previtamin D3 synthesis. Once previtamin D3 is made in the skin, it immediately begins to thermally equilibrate to vitamin D3 by a temperature-dependent process (Fig. 5--3). 27 This thermal equilibration takes approximately 10 hours to reach completion at body temperature (37 ~ C) in humans. 27'28 Because most of the cutaneous previtamin D3 synthesis in adults occurs in the actively growing layers of the epidermis, which is in close proximity to the dermal capillary bed, changes in the temperature of the surface of the skin resulting from exposure to very warm or cold climates do not significantly alter the rate of conversion of previtamin D3 to vitamin D3 in humans. 27 Although the exact mechanism for how vitamin D3 exits the epidermal cells and journey to the dermal capillary bed is unknown, it is now appreciated that previtamin D3 is made in the plasma membrane and as a result is entrapped within the membrane due to its conformation. 29 Once it isomerizes to vitamin D3, the change in conformation results in it being jettisoned into the extracellular space where it is drawn into the dermal capillary bed by the vitamin D-binding protein.

B. Regulation of Previtamin D3 Synthesis in Human Skin In 1967, Loomis 3~ popularized a theory that skin pigmentation evolved for the purpose of regulating vitamin D3 synthesis in the skin. He suggested that peoples living at or near the equator would have died of vitamin D intoxication as a result of daily exposure to intense solar radiation were it not for the evolution of more melanin pigmentation in the skin. Melanin is a natural sunscreen that is produced by the epidermis and acts as a neutral density filter absorbing wavelengths of sunlight that are responsible for producing previtamin D3 in human skin. 31 Although it is clear that melanin can compete with 7dehydrocholesterol for UV-B photons and therefore limit previtamin D3 synthesis in the skin, this cannot be the only explanation for why Caucasians exposed to prolonged sunlight do not become vitamin D intoxicated.

It is now appreciated that there is a more fundamental process that regulates the photosynthesis of previtamin D3 in human skin. Previtamin D3 is sensitive to both thermal energy and ultraviolet radiation. Once previtamin D3 is formed in the epidermis and dermis, it can either thermally isomerize to vitamin D3 or during exposure to sunlight absorb a photon of UV-B radiation and isomerize to biologically inert isomers lumisterol and tachysterol (Fig. 5-3). 32 Thus, if a Caucasian is exposed to sunlight at the equator, during the initial few minutes of exposure provitamin D3 is rapidly converted to previtamin D3 (Fig. 5-4). Prolonged exposure to sunlight, however, does not increase previtamin D3 production, but rather previtamin D3 absorbs UV-B radiation and undergoes isomerization to form lumisterol and, to a small extent, tachysterol (Fig. 5-4). 32 Thus, prolonged exposure to sunlight does not necessarily increase previtamin D3 synthesis. In addition to the photolysis of previtamin D3 in human skin that limits the amount of previtamin D3 that is ultimately formed during a single exposure to sunlight, it is now appreciated that vitamin D3 is exquisitely sensitive to exposure to sunlight. On a sunny day in Boston in June, vitamin D3 is efficiently converted to 5,6-trans-vitamin D3 and suprasterols 1 and 2 (Fig. 5--3). 33 The physiological roles of the photoisomers of previtamin D3 and vitamin D3 are unknown at present.

C. Other Factors That Regulate the Cutaneous Production of Vitamin D3 The photoproduction of previtamin D3 in any layer of skin is dependent on the concentration of provitamin D3, the presence of chromophores that compete with provitamin D3 for UV-B photons, and the quantum of UV-B photons that are able to penetrate the skin and are absorbed by the provitamin D3 chromophore. The average concentration of provitamin D3 in a 6.25 cm 2 area of young adult human skin is approximately 5 Ixg for the epidermis and 1 to 3 Ixg for the dermis. 34 There is an inverse relation between the concentrations of provitamin D3 in the epidermis with age. 34 Compared with elderly adults, young adults can make two to three times more previtamin D3 in their skin when they are exposed to the same amount of sunlight (Fig. 5--5). 34-36 Sunscreens, which are effective in preventing the damaging effects of sunlight, also prevent the beneficial effects of sunlight, the photosynthesis of previtamin D3 in human skin. 31 The topical application of a sunscreen with a sun protection factor of 8 can completely block the photosynthesis of previtamin D3 in human skin and prevent the elevation of the concentration of vitamin D3 in the circulation after a whole-body exposure to a dose of ul-

CHAPTER 5

129


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absorbing chromophores that are present in the skin, such as melanin, urocanic acid, proteins, and RNA and DNA. An increase in the zenith angle either by the daily rotation of the Earth or by an increase in the distance north or south from the equator shifts the spectral distribution of sunlight toward longer wavelengths because of greater subtraction of shorter wavelengths (UV-B) by atmospheric absorption and scattering. 5 It is well known that in northern latitudes children are more prone to develop rickets during and immediately after the winter when compared with spring, summer, and fall. Originally it was thought that the principal cause for this was that children wore more clothing and were outdoors less. However, there is a more fundamental reason for this phenomenon. There is now evidence that exposure to sunlight between the months of November and March, in Boston (42 ~ N), does not result in any cutaneous production of previtamin D3. 33 However, in Los Angeles

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FIGURE 5 - 4 An analysis of the photolysis of 7-dehydrocholestrol (7-DHC) in the basal cells and the appearance of the photoproducts previtamin D3 (preD3), lumisterol (L), and tachysterol (T) with increasing time of exposure to equatorial simulated sunlight. (From Holick MF, MacLaughlin JA, Doppelt SH: Science 211:590, 1981. Copyright 1981 by the American Association for the Advancement of Science.)

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traviolet radiation that is equivalent to a minimal erythemal dose (Fig. 5--6). 31'36 Clothing-like sunscreens absorb solar ultraviolet radiation and therefore also prevent the cutaneous synthesis of vitamin D3 .37 The percentage conversion of cutaneous provitamin D3 to previtamin D3 is also influenced by the solar zenith angle, which is inversely related to the amount of ultraviolet B photons in the solar spectrum, and by U V - B -

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130

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(34 ~ N) and Puerto Rico (18 ~ N), sunlight produces previtamin D3 in the skin throughout the year (Fig. 5 - - 7 ) . 36,38

D. Effect o f W h o l e - B o d y U l t r a v i o l e t I r r a d i a t i o n on C i r c u l a t i n g C o n c e n t r a t i o n s o f V i t a m i n D

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FIGURE 5 - - 8 Serum concentrations of vitamin D from healthy young adults who received a single oral dose of either 10,000 or 25,000 IU of vitamin D2 or a whole-body exposure to 1 MED of simulated solar ultraviolet B radiation. (From Holick MF: Sunlight, vitamin D and human health. In Holick MF, Jung EG (eds): Proceedings, Symposium on the Biological Effects of Light. Berlin, Water De Gruyter & Co, 1994, pp 3 - 1 5 . )

after exposure, whereas exposure to the same amount of radiation had no effect on serum vitamin D concentrations in the black volunteers (Fig. 5 - 9 ) . 41 The black subjects were then exposed to a dose of radiation that was equivalent to 6 times the MED for the Caucasian subjects (exposure of the Caucasian subjects to this amount of radiation would have caused severe second-degree

a n d Its M e t a b o l i t e s When young, healthy adult volunteers were exposed to a single whole-body dose of ultraviolet radiation that caused minimal erythema (1 minimal erythemal dose [MED]), the circulating vitamin D concentrations increased from a baseline value of 2 ng/ml to 24 ng/ml within 24 hours and retumed to a baseline value within 1 week after the exposure (Fig. 5 - - 8 ) . 39 This is equivalent to taking between 10,000 and 25,000 IU of vitamin D2 orally (Fig. 5-8). 40 The apparent half-life of vitamin D in the serum was determined to be about 48 h o u r s . 39 Based on the assumption that the plasma volume is about 5% of the mean body weight, it was estimated that at least 30 Ixg of vitamin D3 w a s released from each square meter of body surface area after exposure to 1 MED of ultraviolet radiation. 39 The role of skin pigment and ethnic background on limiting the cutaneous formation of vitamin D3 w a s examined by exposing slightly pigmented Caucasians, moderately pigmented immigrants of Indian and Pakistani extraction, and heavily pigmented black volunteers to a single dose of ultraviolet radiation. Whole-body exposure of Caucasian subjects to 1.5 times their MED greatly increased the serum vitamin D concentrations by up to 60-fold 24 to 48 hours

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Serum vitamin D concentration in two lightly pigmented Caucasian (A) and three heavily pigmented black subjects (B) after total-body exposure to 0.054 J/cm 2 of UVR. C, Serial change in circulating vitamin D after reexposure of one black subject (e in panel B) to a 0.32 J/cm 2 dose of UVR. (From Clemens TL, Adams JS, Henderson SL, Holick MF: Increased skin pigment reduces the capacity of the skin to synthesize vitamin D. Lancet 1:74, 1982.)

CHAPTER 5 Vitamin D Metabolism and Biological Function sunburn), and circulating concentrations of vitamin D increased approximately 30-fold during the 24 hours after exposure (Fig. 5--9). 41 It is well recognized that Asians of Indian and Pakistani extraction living in Great Britain are more prone to develop rickets and osteomalacia. Although this may be due to the high phytate content in their diet, there has been some question as to whether these individuals have the same capacity as that of Caucasians and blacks to produce vitamin D3. Indians and Pakistanis have the same capacity as that of Caucasians and blacks to produce vitamin D3 in their skin as evidenced by increasing circulating concentrations of vitamin D that are comparable to those of Caucasian subjects exposed to 1 MED of ultraviolet radiation. 42 Hence, blacks and Asians of Indian and Pakistani extraction have the same capacity as that of Caucasians to produce vitamin D3 but require a much larger dose of ultraviolet radiation to do so because of the pigmentation that is present in their skin. Although a single whole-body exposure to ultraviolet radiation has a dramatic effect on elevating the circulating concentration of vitamin D in a dose-dependent fashion, the effect on the circulating concentration of 25(OH)D and 1,25(OH)2D is minimal. The serum 25(OH)D concentration increased only gradually, reaching a 50% increase in 7 to 14 days after exposure. 39 There was no significant increase in circulating concentrations of 1,25(OH)2D in the Caucasian subjects exposed to 1 and 3 MEDs of ultraviolet radiation. 39 Vitamin D deficiency does not appear to alter provitamin D concentrations in the skin. 39 When vitamin D-deficient patients were exposed to 1 MED of whole-body ultraviolet radiation, their circulating concentrations of vitamin D and 25(OH)D increased in a fashion almost identical to that seen for the vitamin D-sufficient volunteers. 39 However, the serum 1,25(OH)2D concentrations in the vitamin D-deficient patients increased by three- to fourfold within 7 days after the exposure and persisted to this concentration throughout the next 2 weeks. 39 In these patients, the increase in circulating concentrations of 1,25(OH)2D was most likely due to the fact that the high circulating concentrations of PTH enhanced the renal metabolism of 25(OH)D to 1,25(OH)2D (see separate section on vitamin D metabolism and regulation for details). 39

131 angle of the sun does not permit sufficient vitamin D3 production in skin. 38'4~ V e r y few foods contain vitamin D naturally; these include liver, egg yolks, and fish-liver oils. Several countries practice the fortification of some foods with vitamin D. In the United States, milk is the principal dietary component that is subject to vitamin D fortification with either vitamin D2 or vitamin D3. However, milk cannot always be depended on as the sole source of vitamin D, since it is now recognized that the vitamin D content in milk can be highly variable. Three separate studies have revealed that about 80% of milk samples tested did not contain more than 80% of the vitamin D that was supposed to be in the milk and about 10% of skim milk had no detectable vitamin D. 43-45 In other countries, some cereals, margarine, and breads also have small quantities of vitamin D added to them. When vitamin D is ingested, this fat-soluble compound is incorporated into the chylomicron fraction and absorbed through the lymphatic system. Approximately 80% of the vitamin D enters the body via this mechanism. After the ingestion of a single dose of 50,000 IU of vitamin D2, circulating concentrations of vitamin D are increased by as early as 4 hours, peak at 12 hours, and gradually decline to near baseline by 72 hours (Fig. 5 - 1 0 ) . 46 Although aging significantly decreases the capacity of the skin to produce vitamin D3, aging does not appear to significantly affect the intestinal absorption of vitamin D (Fig. 5 - 1 0 ) . 47 On the other hand, intestinal malabsorption syndromes such as Crohn's disease, cystic fibrosis, and Whipple's disease can effectively prevent

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132

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FIGURE 5--11 Serum vitamin D concentrations in seven patients with intestinal fat malabsorption syndromes after a single oral dose

of 50,000 IU (1.25 mg) of vitamin D2. For comparison, the means and standard errors of vitamin D concentrations measured in seven normal control subjects after a similar dose are indicated by the closed circles and dashed lines (-o-). Note that two patients, one with Crohn' s ileocolitis (patient F) and one with ulcerative colitis (patient G), had essentially normal absorption curves. Five patients, however, showed a dramatic lack of response, with no values shown above 10 ng/ml. (From Lo CW, Paris PW, Clemens TL, et al: Vitamin D absorption in healthy subjects and in patients with intestinal malabsorption syndromes. Am J Clin Nutr 42:644, 1985. Reproduced with permission from the American Society for Clinical Nutrition and The American Journal of Clinical Nutrition.)

the intestinal absorption of vitamin D, whereas diseases that affect the more distal small intestine and large intestine appear to have little effect on the intestinal absorption of this fat-soluble vitamin (Fig. 5-11).46 A simple method to determine whether an individual is capable of absorbing vitamin D is to conduct a provocative vitamin D absorption test. A blood sample is obtained before and 12 hours after a single oral administration of 50,000 IU of vitamin D2 (Fig. 5 - 1 1 ) . 46 If no elevation in the circulating concentration of vitamin D is observed, complete malabsorption of vitamin D should be suspected; however, an increase in the circulating concentration of vitamin D is reflective of vitamin D absorption, and the patient's dose of vitamin D can therefore be tailored accordingly. 46 Thus, patients who suffer from chronic liver disease or who have a disease of the small intestine are more prone to develop vitamin D deficiency owing to the inability to absorb this fatsoluble vitamin.

IV. METABOLISM OF VITAMIN D TO 25-HYDROXYVITAMIN D A. Hepatic Metabolism Vitamin D3 made in the skin or ingested in the diet along with dietary vitamin D2 enters the circulation and

is bound to a vitamin D - b i n d i n g protein. 2 Vitamin D (the use of the term vitamin D without a subscript refers to either or both vitamin D2 and vitamin D3) is transported to the liver where it is hydroxylated on carbon 25 to generate the major circulating form of vitamin D, 25-hydroxyvitamin D [25(OH)D] (Fig. 5 - 1 2 ) . 2,48 The vitamin D 25-hydroxylases are located in the mitochondria and microsomes of the parenchymal cells. The enzymatic reaction is supported by reduced N A D P and molecular oxygen. 48 Although the mammalian liver has a large reserve of the vitamin D-25-hydroxylase, it is not the sole site for vitamin D 25-hydroxylation. In avian species, the kidney and intestine are capable of metabolizing vitamin D3 to 25(OH)D3, 49 and hepatectomized rats metabolize vitamin D3 to 25(OH)D3 to a small degree. 5~ Vitamin D2 and vitamin D3 as well as vitamin D analogues, such as dihydrotachysterol and l c~hydroxyvitamin D3, are metabolized in the liver to their 25-hydroxy counterparts. 2 There is some evidence, however, that because the vitamin D - b i n d i n g protein does not bind to vitamin D2 as tightly as it does to vitamin D3, vitamin D2 is more available as a substrate for the hepatic enzyme and, therefore, is more efficiently converted to 25(OH)D2. 51 The half-life of 25(OH)D in the human circulation is about 2 to 3 weeks, and its concentration is a good reflection of the cumulative effects of dietary intake of vitamin D and exposure to sunlight. 2 It should be recognized, however, that the liver vitamin D-25-hydroxylase is relatively well regulated, inasmuch as the relative increase in circulating concentration of 25(OH)D3 in comparison to the cumulative intake of vitamin D3 is relatively small (Fig. 5 - 1 3 ) . 52 This may, in part, be due to negative feedback regulation of the hepatic vitamin D-25-hydroxylase by vitamin D, 25(OH)D, and/or 1,25(OH)2D3 .53

B. Clinical Disorders Patients with severe parenchymal and cholestatic liver disease often have low circulating concentrations of 25(OH)D (Table 5 - 1 ) . 54 This is partly due to the associated intestinal malabsorption of vitamin D as well as a decrease in the reservoir of the vitamin D-25-hydroxylase in the liver. Originally, it was believed that the low circulating concentration of 25(OH)D was responsible, in part, for the debilitating bone disease associated with severe liver failure. However, there is no correlation between the severity of the bone disease and circulating concentrations of 25(OH)D, and treatment of these patients with 25(OH)D or its metabolites provides no benefit. 54'55 However, because these patients are more prone to vitamin D deficiency due to associated fat malabsorption, it is wise to increase the vitamin D intake and

CHAPTER 5


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FIGURE 5--12 The photochemical, thermal, and metabolic pathways for vitamin D 3. Circled letters and numbers denote specific enzymes" (Z)7-dehydrocholesterol reductase; Q vitamin D-25-hydroxylase; (~ 25(OH)D- 1c~-hydroxylase; (~ 25(OH)D-24R-hydroxylase; (~)25(OH)D-26-hydroxylase. (From Holick MF, Potts JT Jr: Vitamin D. In Isselbacher KJ, et al (eds): Harrison's Principle of Internal Medicine, 10th ed. New York, McGraw-Hill, 1983, pp. 1944-1949.)

monitor circulating concentrations of 25(OH)D. The 25(OH)D concentrations in these patients should be maintained in the mid-normal range of approximately 25 to 45 ng/ml. Some patients will benefit by increasing the dose or frequency of oral administration of vitamin D once it has been determined, using the provocative oral

vitamin D absorption test, 46 that the patient can absorb vitamin D. Otherwise, intravenous or intramuscular injections of vitamin D or increased exposure to sunlight will often provide adequate vitamin D nutrition for these patients. In disease states in which there is an increase in the metabolism of 25(OH)D to 1,25(OH)2D, such as

134

MICHAEL E HOLICK AND JOHN S. ADAMS 160-

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vitamin D - d e p e n d e n t rickets type II, sarcoidosis and other chronic granulomatous disorders, primary hyperparathyroidism, and hyperphosphatemic tumoral calcinosis, it has been reported that the circulating concentrations of 25(OH)D are often decreased, but usually not below the normal values. 53 Patients with nephrotic syndrome who have marked proteinuria (>4 g/24 hr) may have decreased concentrations of 25(OH)D in the circulation as a result of a loss in the urine of the vitamin D - b i n d i n g protein (which is similar in molecular weight to albumin) with its tightly bound 25(OH)D. Thus, the turnover of 25(OH)D is markedly increased, and these patients will often benefit from additional vitamin D sup-

TABLE 5--1 Serum Concentrations of 25(OH)D in Disorders of Calcium, Phosphorus, and Bone Metabolism Serum

Disease State

25(OH)D

Vitamin D deficiency Intestinal malabsorption syndromes Liver disorders Nephrotic syndrome Osteopenia in the aged Vitamin D intoxication

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plementation. 56 There is no need to treat these patients with either 25(OH)D3 or 1,25(OH)2D3. It is well documented that there is an association between osteomalacia or rickets and anticonvulsant drug therapy in epileptic patients. 57 Initially, it was thought that this resistance was because phenytoin and phenobarbital induced liver microsomal enzymes that rapidly metabolized and inactivated vitamin D and its metabolites. However, it now appears that these drugs also disrupt calcium homeostasis by additional mechanisms. Phenytoin inhibits vitamin D - d e p e n d e n t and vitamin D-independent intestinal calcium transport. Phenobarbital increases bile secretion (thereby increasing the turnover of vitamin D) and has a negative effect on the kinetics of the vitamin D-25-hydroxylase. 58 This problem appears to be more severe in children and adults who are institutionalized and who are taking several antiseizure medications. There does not appear to be a disruption in calcium or bone metabolism in otherwise healthy individuals who are taking a single anticonvulsant drug for prolonged periods of time. It has been reported that free-living cardiac patients free of known disorders of calcium metabolism have normal circulating concentrations of 25(OH)D despite 2 years of treatment with conventional doses of phenytoin. 59 The hallmark of this disorder is low circulating 25(OH)D. The associated disorders in calcium and bone metabolism are reversed

CHAPTER 5 Vitamin D Metabolism and Biological Function

135 of this hormone with skin, bone cells, and/or peripheral monocytes being touted as the most likely tissues with the enzymatic machinery 65-68 and capacity 69'7~to produce enough 1,25(OH)2D to be detectable in blood; patients who have had a bilateral nephrectomy or who have severe renal failure have very low but detectable levels of the hormone. 71 In the absence of disease, whether other tissues besides the kidney can produce enough 1,25(OH)2D to maintain normal serum levels is unlikely. The renal 25(OH)D-l-hydroxylase (1-hydroxylase) is a mitochondrial cytochrome P-450, mixed-function oxidase that requires reduced NADP and molecular oxygen for its activity (Fig. 5-14). 48 The enzyme is located in the epithelial cells of the proximal convoluted tubule of the normal mammalian kidney. 72 One group of investigators recently claimed to have isolated the enzyme in pure f o r l T l , 73 while another group TM reported the isolation of a cDNA for the 1-hydroxylase mRNA from a vitamin D-deficient rat kidney library; the latter group employed as probe the cDNA for the rat 24-hydroxylase mRNA. Confirmation of the successful isolation and cloning of the 1-hydroxylase will require documentation of its fulllength amino acid sequence and the expression of a vitamin D-metabolizing P-450, which has a high affinity for substrate 25(OH)D in cells that normally lack the 1hydroxylase.

when the oral intake of vitamin D is increased to raise 25(OH)D into the normal range. 60

V. METABOLISM OF 25-HYDROXYVITAMIN D TO 1,25-HYDROXYVITAMIN D A. R e n a l 2 5 ( O H ) D - l o L - H y d r o x y l a s e Once 25(OH)D is formed in the liver, it is transported on the serum vitamin D - b i n d i n g protein to other tissue sites for further metabolism, primarily for hydroxylation on either C-1 of the A-ring or C-24 in the molecular side chain of 25(OH)D (Fig. 5-12). 2,48,60 In most mammalian species, including humans, the principal site for the metabolism of 25(OH)D to 1,25(OH)2D is the kidney. Normal circulating concentrations of 1,25(OH)2D are between 15 and 65 pg/ml, with the circulating half-life of the hormone between 4 and 6 hours. 6] During the third trimester of pregnancy the placenta plays a significant part in maintaining relatively high circulating concentrations of 1,25(OH)2D by metabolizing 25(OH)D to 1 , 2 5 ( O H ) 2 D . 62-64 There have also been reports that there are other " n o r m a l " extrarenal sites for the production

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136


of the ferredoxin which contributes electrons to the 1hydroxylase enzyme, s3'84 Whether messengers in these same transduction pathways also regulate expression of the gene encoding the 1-hydroxylase has not been determined since the gene for the enzyme has not been cloned (see below). A change in the serum phosphate concentration is the other major regulator of 1,25(OH)zD production; in adult humans dietary phosphorus restriction causes an increase in circulating concentrations of 1,25(OH)zD to 80% above control values, an increase not due to accelerated metabolic clearance of this hormone. 79 Dietary phosphorous supplementation will have the opposite effect. 79 Human volunteers who received phosphorus supplements to their diet showed an abrupt decrease in the serum concentration of 1,25(OH)zD reaching a nadir within 2 to 4 days; after 10 days of supplementation the mean concentration of 1,25(OH)2D was 29% lower than the value measured when the phosphorus was normal and the production rate of hormone decreased significantly without any change in the metabolic clearance rate (Fig. 5-15). Although the mechanism by which a drop in the serum phosphate level will increase renal 1,25(OH)zD production remains uncertain, there is no doubt that there exists a concerted, cooperative attempt of the calciumphosphorus-PTH axis in man to regulate the conversion of 25(OH)D to 1,25(OH)zD in the kidney (Fig. 5-16). It is well known that the body adapts to the increased need for calcium by enhancing the efficiency of the intestine to absorb dietary calcium during pregnancy, 62-64

B. R e g u l a t i o n o f 2 5 ( O H ) D M e t a b o l i s m The synthesis of 1,25(OH)2D by the renal 1-hydroxylase is normally strictly regulated, with levels of the hormone product 1,25(OH)2D being some 1000-fold less plentiful in the circulation than that of the principal substrate for the enzyme 25(OH)D. 61 Hormone synthesis in the kidney is stimulated by an increase in the serum PTH concentration, a decrease in the serum phosphate concentration, and a decrease in the activity of the competing vitamin D-24-hydroxylase. 3'8'6~ In vivo, hypocalcemia also enhances renal 1-hydroxylase activity, but the majority of this activity is indirectly mediated through an increase in the secretion of parathyroid hormone. 48'77A drop in the serum calcium concentration will be immediately registered by the parathyroid cell calcium-sensing receptor, which will release its inhibition on PTH production and secretion. An increase in the circulating PTH will directly stimulate the renal 1hydroxylase, while a PTH-mediated phosphaturic response and a subsequent decrement in the serum phosphate level will indirectly promote 1,25(OH)zD production. 48'6~176 The mechanism by which parathyroid hormone exerts direct influence on the renal metabolism of 25(OH)D has not been firmly established, but recent information suggests that interaction of PTH with its receptor on cells in the proximal convoluted tubule transduces a stimulatory signal through both the protein kinase A and protein kinase C pathways, 81'82 effecting transient changes in the phosphorylation status

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TIME (days) FIGURE 5-- 15 Effect of changes in the oral intake of phosphorus on the fasting serum concentrations of 1,25(OH)2D and phosphorus in six healthy men. The bracketed points depict mean values + SEM. (From Portale AA, Halloran BE Murphy MM, Morris RC Jr: Oral intake of phosphorus can determine the serum concentration of 1,25-dihydroxyvitamin D by determining its production rate in humans. J Clin Invest 77:7-12, 1986.)

CI-IAr'TEg5 Vitamin D Metabolism and Biological Function

FIGURE 5-- 16 Photosynthesis of vitamin D3 and the metabolism of vitamin D3 to 25-OH-D3 and 1,25(OH)2D3. Once formed, 1,25(OH)2D3 carries out the biological functions of vitamin D3 on the intestine and bone. Parathyroid hormone (PTH) promotes the synthesis of 1,25(OH)2D3, which, in tum, stimulates intestinal calcium transport and bone calcium mobilization and regulates the synthesis of PTH by negative feedback. (From Holick MF: Vitamin D: Photobiology, metabolism, mechanism of action, and clinical application. In Favus MJ (ed): Primer on the Metabolic Bone Diseases and Disorders of Mineral Metabolism, 3rd ed. Philadelphia, Lippincott-Raven, 1996, pp 7 4 - 8 1 . )

lactation, and periods of skeletal growth. 75 Hence, it is not surprising that there is evidence for estrogen, 85'86prolactin, 87 and growth hormone, 88-9~ either directly or indirectly through insulin-like growth factor 1 (IGF-1), 91 enhancing the renal production of 1,25(OH)2D in various in vitro and in vivo animal models. However, patients with hyperprolactinemia and acromegaly, who have high circulating concentrations of prolactin and growth hormone, respectively, do not exhibit increased circulating concentrations 1,25(OH)2D. 6~ The role of estrogen and progesterone on production of 1,25(OH)2D in the

137 human kidney also remains unclear. For example, although mean serum 1,25(OH)2D levels are known to be higher in growing children than in a d u l t s , 91'92 the circulating concentrations of the vitamin D hormone are not significantly altered in adolescent women with estrogen deficiency caused by anorexia nervosa. 93 Concentrations of testosterone increase dramatically at the onset of sexual maturation in boys, but these changes are not temporally associated with an increase in serum concentrations of 1,25(OH)2D. 92 At the opposite end of the reproductive scale it has been shown that menopausal females have lower 1,25(OH)2D levels than menstruating women. 86 However, this association appears not to be due more to an age-related diminishment of responsiveness of the 1-hydroxylase to PTH (Fig. 5 - 1 7 ) 94 than to any effect of gonadal steroids on the renal metabolism of 25(OH)D3 to 1,25(OH)2D3. The other major contributor to the circulating 1,25(OH)2D level is the activity of the vitamin D-24hydroxylase. Like the 1-hydroxylase, 24-hydroxylase is a magnesium-dependent, heme-binding mitochondrial enzyme requiring NADPH and molecular oxygen. 83 The cDNA and part of the gene for the human, rat, and chicken enzyme, now referred to as P450cc24, have been cloned. 95-98 Expression of P450cc24 is stimulated in kidney cells by 1,25(OH)2D, especially if the protein kinase C (PKC) pathway is also up-regulated. 99'1~176 PTH appears to exert an opposite, inhibitory effect on P450cc24 gene transcription 98 and 24,25(OH)2D synthesis. 1~176 There are two modes by which this mitochondrial, cytochrome P-450-1inked enzyme system regulates vitamin D balance in adult animals including man. Because it is co-expressed in the kidney along with the vitamin D-1-hydroxylase, the first mode of regulation is on substrate availability to the 1-hydroxylase. Like the 1-hydroxylase, the 24-hydroxylase exhibits a preference for 25-hydroxylated secosterol substrates. 84 Although its affinity for 25(OH)D is somewhat less than that of renal 1-hydroxylase, its capacity for substrate is substantially greater. 83 Hence, when up-regulated under the influence of circulating 1,25(OH)2D or diminished serum PTH levels, the 24-hydroxylase has the capacity to compete with the 1-hydroxylase for substrate 25(OH)D. Under physiological circumstances, this state of competitive substrate deprivation for the 1-hydroxylase will persist until the serum calcium and PTH concentration are normalized. The second mode of regulation imparted on the circulating 1,25(OH)2D concentration by the 24hydroxylase is at the level of catabolism of the 1,25(OH)2D hormone. The affinity of the 24-hydroxylase for 1,25(OH)2D is as great as it is for 25(OH)2D. 84 Considering the fact that the 24-hydroxylase is the initial step in the conversion of 1,25(OH)2D to non-biologically active, water-soluble, excretable metabolites of the hor-

138

MICHAEL F. HOLICK AND JOHN S. ADAMS

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HOURS FIGURE 5 - - 17 Effect of synthetic parathyroid hormone [hPTH-(1 - 34)] on concentrations of 1,25(OH)2D in normal subjects (solid circles). All values are expressed as the mean + SEM. The single asterisk denotes significant differences at p < 0.01, and the double asterisk at p < 0.05, between the level in the patients and that in the controls at corresponding time points. Asterisks also refer to significant differences between the preinfusion baseline levels and levels at particular time points. To convert values for 1,25(OH)zD to picomoles per liter, multiply by 2.36. (From Slovik DM, Adams JS, Neer RM, et al: Deficient production of 1,25-dihydroxyvitamin D in elderly osteoporotic patients. N Engl J Med 305: 372-374, 1981.)

mone, 76 up-regulation of this enzyme will contribute to the lowering of 1,25(OH)2D hormone levels.

C. Extrarenal Metabolism of 25(OH)D As early as 1940, Henneman et al. 1~ suggested that the intestine was hypersensitive to vitamin D in patients with sarcoidosis. The fact that an active metabolite of 25(OH)D could be made outside of the kidney was first confirmed by Barbour and colleagues in 1981.1~ These investigators reported high concentrations of a vitamin D metabolite detected as 1,25(OH)2D in the circulation of a hypercalcemic, anephric patient with the granulomaforming disease sarcoidosis (Fig. 5-18). Two years later, Adams et al. ~~ determined the macrophage to be the extrarenal source of this active vitamin D metabolite with unequivocal structural characterization of the metabolite as 1,25(OH)2D obtained by these same investigators in 1985.1~ It is now widely accepted that the overproduction of 1,25(OH)2D or a 1,25(OH)2D-like metabolite can cause hypercalciuria and frank hypercalcemia in many different granuloma-forming diseases ~~ of both infectious and noninfectious origin (Table 5 - 2 ) . By the 1980s data were accumulating to suggest that a vitamin D - m e d i a t e d disturbance in calcium metabolism was not confined to patients with granuloma-

forming diseases and could also be observed in patients with lymphoproliferative neoplasms. 1~ Most recent reports 114'115 indicate that the extrarenal overproduction of 1,25(OH)2D is the most common cause of hypercalciuria and hypercalcemia in patients with non-Hodgkin's and Hodgkin's lymphoma, especially in patients with Bcell neoplasms and whether or not the tumor is associated with the acquired immunodeficiency syndrome (AIDS). 1~ There are now at least four clear lines of clinical evidence to indicate that endogenous 1,25(OH)2D production in hypercalcemic/hypercalciuric patients with granuloma-forming diseases and lymphoma is dysregulated and not bound by the same set of endocrine factors known to regulate 1,25(OH)2D synthesis in the kidney. First, hypercalcemic patients with sarcoidosis possess a frankly high or inappropriately elevated serum 1,25(OH)2D concentration, although their serum PTH level is suppressed and their serum calcium and phosphate concentration is relatively elevated. 116'117 If 1,25(OH)2D synthesis were under the regulation of PTH, phosphate, and 1,25(OH)zD itself, then 1,25(OH)zD concentrations in such patients should be low. Second, the serum 1,25(OH)zD concentration in patients with active sarcoidosis is very sensitive to an increase in available substrate, ~ls while the serum 1,25(OH)zD level in normal individuals is not. Clinically, this aspect of dysregulation

CHAPTER 5 Vitamin D Metabolism and Biological Function Mediastinal Lymph Node Bx Bilateral (granuloma) Nephrectomy a ~t

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FIGURE 5-- 18 Relation of changes in serum levels of 1,25(OH)2D, iPTH, and calcium to doses of prednisone administered to control hypercalcemia. The solid portion of the bar representing the administration of prednisone indicates daily therapy, and the open portion indicates alternate-day therapy. Bx denotes biopsy. To convert values for 1,25(OH)2D to picomoles per liter, multiply by 2.36. To convert values for calcium to millimoles per liter, multiply by 0.25. (From Barbour GL, Coburn JW, Slatopolsky E, et al: Hypercalcemia in an anephric patient with sarcoidosis, evidence for extrarenal generation of 1,25-dihydroxyvitamin D. N Engl J Med 305:440-443, 1981.)

is manifest by the long-recognized association of the appearance of hypercalciuria and/or hypercalcemia in sarcoidosis patients in the summer months 119 or following beach-going holidays to geographic locations at lower latitudes than those at which the patient normally resides. 12~ Third, the rate of endogenous 1,25(OH)2D production, which is significantly increased in patients with sarcoidosis, is unusually sensitive to inhibition by factors (i.e., drugs) that do not influence the renal vitamin D-l-hydroxylase at the same doses. For example, antiinflammatory concentrations of glucocorticoids have long been recognized as effective combatants of sarcoidTM

TABLE 5--2 Human Granuloma-Forming Diseases Associated with the Extrarenal Overproduction of an Active Vitamin D Metabolite Sarcoidosis Tuberculosis Leprosy Disseminated candidiasis Histoplasmosis Coccidiodomycosis Crytococcosis Berylliosis Silicone-induced granulomatosis Eosinophilic granuloma Wegener' s granulomatosis Massive infantile fat necrosis

139 osis-associated hypercalcemia 1~ and shown to effectively lower elevated 1,25(OH)2D levels. 117 On the other hand, giving the same amount of glucocorticoid to patients without sarcoidosis is not associated with a clinically relevant reduction in the serum 1,25(OH)2D or calcium concentration. Chloroquine and its analog, hydroxychloroquine, are other examples of agents that appear to act preferentially on the extrarenal vitamin D-1hydroxylation reaction that is active in patients with sarcoidosis. 124-126 And fourth, in patients with either granuloma-forming disease or lymphoma the serum calcium and 1,25(OH)2D concentrations are positively correlated to indices of disease activity. ]~ Investigators 1~ have now generated a substantial body of experimental data from cells, including inflammatory cells harvested directly from patients with sarcoidosis, to indicate that the dysregulated vitamin D hormone synthesis in sarcoidosis is due to expression of a 1hydroxylase that is not different from the renal 1-hydroxylase, but rather to expression of the authentic 1hydroxylase in a macrophage, not a kidney cell. In fact, each of the above mentioned pieces of clinical evidence for dysregulated vitamin D hormone production in this disease can be borne out in vitro in cells from patients with this disease. 13~

VI. ALTERNATIVE METABOLISM OF 25-HYDROXYVITAMIN D AND 1,25-DIHYDROXYVITAMIN D

A. Metabolism of 25-Hydroxyvitamin D to 24,25-Dihydroxyvitamin D The body possesses a variety of enzymes that have the capacity to transform 25(OH)D into innumerable dihydroxy, trihydroxy, and tetrahydroxy metabolites (Fig. 5--19). 48'60'76'131-133 In the early 1970s, it was appreciated that vitamin D - d e f i c i e n t rats, when provided radioactive vitamin D3, efficiently converted the vitamin first to 25(OH)D3 and then to 1,25(OH)2D3 .48']33 However, when these animals were given a diet that was high in calcium and contained vitamin D, [3H]25(OH)D3 was converted to a metabolite that was more polar and was structurally identified as 24R,25-dihydroxyvitamin D3 [24,25(OH)2D3] 135 (Fig. 5 - 1 2 ) . Despite the fact that 25(OH)D2 has a methyl group in the S configuration on carbon-24, it, too, is metabolized to 24,25(OH)2D2. 24,25(OH)2D is the major circulating metabolite of 25(OH)D, and its concentration, which is usually 2 to 4 ng/ml, is a reflection of the 25(OH)D concentration. 48'6~ Although the kidney is the primary site for its production, most other tissues that possess nuclear TM

140

MICHAELE HOLICKAND JOHN S. ADAMS

25 (,OH)D3

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HO.-j~ 25 (OH~D3-1actone

FIGURE 5--19 Pathwayof 25(OH)D3 metabolism to 25(OH)D326,23-1actone. (From Napoli JL, Horst RL: Vitamin D metabolism. In Kumar R (ed): Vitamin D, Basic and Clinical Aspects. Boston, Martinus Nijhoff Publishing, 1984.)

receptors for 1,25(OH)2D also have the enzymatic machinery to produce this metabolite (Fig. 5--20). 48'6~ The renal 25(OH)D-24-hydroxylase is a mitochondrial enzyme requiring NADPH +, molecular oxygen, and magnesium ions. 48'6~ Originally, it was believed that parathyroid hormone, which enhanced the renal production of 1,25(OH)2D, was also responsible for decreasing the synthesis of 24,25(OH)zD. However, there is now firm evidence that parathyroid hormone does not influence the renal metabolism of 25(OH)D to 24,25(OH)zD. Parathyroid hormone stimulates the production of 1,25(OH)2D. This hormone, in turn, shuts off its own renal production and enhances the kidney's production of 24,25(OH)zD. 84'101'102'136'137 The physiological role of the 24-hydroxylation of 25(OH)D is unsettled at the present time. There are reports that 24,25(OH)2D3 is capable of (1) promoting hatchability of chicken eggs, ~38 (2) directly stimulating bone formation in vitro only in the presence of parathyroid hormone and 1,25(OH)2D3,139 (3) increasing the synthesis of proteoglycans in cultured chondrocytes, 14~ (4) improving calcium retention in anephric patients, TM and (5) more effectively promoting bone mineralization in humans when combined with 1,25(OH)2D3 than 1,25(OH)2D3 could by itself. ~42However, it is known that

24,25(OH)2D3 at physiological concentrations is biologically inert in anephric rats in inducing either intestinal transport or bone calcium mobilization. ~43 Its biological activity is restored when it is hydroxylated on carbon-1 to act as an analogue of 1,25(OH)2D3. This trihydroxy metabolite, 1,24,25-trihydroxyvitamin D3, is less active than 1,25(OH)2D3 in the stimulation of intestinal calcium transport and bone calcium mobilization. 143Furthermore, this 1-hydroxylated metabolite does not have any specific function in enhancing bone mineralization. To further evaluate the role of the carbon-24 hydroxylation of 25(OH)D3, an analogue of 25(OH)D3 that had its hydrogens at carbon-24 replaced with flourines (thus preventing this analogue from being hydroxylated on carbon-24), was synthesized and its biological activity evaluated. It was found that the 24,24'-difluoro-25hydroxyvitamin D3 has the same biological activity as 25(OH)D3 in (1) enhancing intestinal calcium transport, (2) mobilizing calcium from bones, and (3) healing rachitic lesions in rats. ~44 These results suggest that the carbon-24 hydroxylation of 25(OH)D3 is not essential for the physiological actions of vitamin D3 in the rat. An alternative explanation for the presence of the 25(OH)D24-hydroxylase in the kidney as well as other tissues that possess receptors for 1,25(OH)2D3 is that this enzyme acts as the initiator for the side-chain catabolism of 25(OH)D and 1,25(OH)2D. 145

B. Side-Chain and A-Ring Metabolism of 25(OH)D3

and 1,25(OH)zD3

Under physiological conditions, 25(OH)D is metabolized on carbon-26 to form 25S,26-dihydroxyvitamin D3 [25,26(OH)zD3] (Fig. 5--12). 146 The circulating concentrations of 25,26(OH)zD are also reflective of the vitamin D nutritional status of humans. Although 25,26(OH)zD3 does not have any special biological functions, it can mimic the biological actions of 1,25(OH)zD3 once it is hydroxylated in the kidney, 1,25S,26trihydroxyvitamin D3 (Fig. 5-12). 132'147Although little is known about the regulation of this metabolic step, it appears that the kidney is the principal site for this metabolism. The metabolism of 25(OH)D3 on carbon-23 yields a 23S,25-dihydroxyvitamin D3 (Fig. 5--19). 132'147 This metabolite is apparently a precursor for an additional metabolic step that gives rise to a rather unusual metabolite that has been identified as 25-hydroxyvitamin D323,26-1actone [25(OH)D3-1actone] (Fig. 5-19). 132 This lactone is found in the circulation of humans and other animals that have received pharmacological doses of vitamin D. Although there is no evidence that this lactone has vitamin D - l i k e activity on either the intestine or

CHAPTER5 Vitamin D Metabolism and Biological Function

141

1,2S(OH)2D3

.14

24-OHase Initiated _-,,-)~. ~ ~ ~ Catabolic Cascade

/

Calcitroic Acid ~

GGGTGAACG GGGGCA VDRE

aBP t~24-OHase ~ 9Osteocalcin ~ Osteopontin "~ AIk Pase

~Collagen

TranscriptionS ~ Regulation

mRNA level

Transepithellal Calcium Transport Modulation of Bone Metabolism Modulation of Intracellular Calcium

Regulation of Cell -'~ Proliferationand Differentiation

~c-myc ~c-fos ~c-sls

I

J I

III

j

II

FIGURE 5--20 Proposed mechanism of action of 1,25(OH)2D3 in target cells resulting in a variety of biological responses. The free form of 1,25(OH)2D3 (D3) enters the target cell and interacts with its nuclear vitamin D receptor (VDR), which is phosphorylated (P). The 1,25(OH)2D3-VDR complex combines with the retinoic acid X receptor (RXR) to form a heterodimer, which, in turn, interacts with the vitamin D-responsive element (VDRE), causing an enhancement or inhibition of transcription of vitamin D-responsive genes such as the 25-OH-D-24-hydroxylase (24OHase). (From Holick MF: Vitamin D: Photobiology, metabolism, mechanism of action, and clinical application. In Favus MJ (ed): Primer on the Metabolic Bone Diseases and Disorders of Mineral Metabolism, 3rd ed. Philadelphia, Lippincott-Raven, 1996, pp 74-81.)

bone, this compound is made in the kidney. It is curious that the vitamin D - b i n d i n g protein recognizes this metabolite with a binding affinity that is about five to seven times greater than that for 2 5 ( O H ) D 3 .48'132 In addition to the multiple hydroxylations that can occur in the side chain, the hydroxyls can also be oxidized. 24,25(OH)2D3 and 23,25(OH)2D3 are oxidized to 24-keto-25(OH)D3 and 23-keto-25(OH)D3, respectively. 48'132 The multitude of hydroxylations and oxidations that 25(OH)D3 can undergo are also seen for 1,25(OH)2D3. Therefore, the side chain of 1,25(OH)2D3 is recognized as a 25(OH)D3 substrate and can undergo further oxidation and hydroxylation at carbon23, carbon-24, and carbon-26 to form a number of metabolites including 1,24,25(OH)D3; 1,25,26(OH)D3; 24-keto-l,23,25(OH)3D3; 1,23,25(OH)3D3; and 1,25(OH)2D3-23,26-1actone. 48'6~ It is believed that the metabolic importance of the side-chain modifications is for the deactivation and rapid clearance of 1,25(OH)2D3. This is particularly true for the carbon-23 oxidation, which ultimately gives rise to a biologically inactive

water-soluble acid derivative known as let(OH)24, 25,26,27-tetranor-23(COOH) vitamin D3 (calcitroic a c i d ) . 48'6~ To date, more than 22 metabolites of vitamin D have been structurally identified. All of these metabolites are less biologically active on a weight basis than 1,25(OH)2D. In addition to the multiple hydroxylations in the side chain, 25(OH)D3 can have its A-ring oxidized whereby the carbon-19 is replaced with a keto group. This reaction occurs in vivo in ruminants and in vitro in chick kidney homogenates, resulting in the conversion of 25(OH)D3 to the cis and trans isomers of 10-keto-19-

nor-25-hydroxyvitamin D3.48'60'132

VII. METABOLISM

OF VITAMIN

D2

In the 1930s it was first appreciated that the vitamin D isolated from the irradiation of the sterol ergosterol yielded a vitamin D (vitamin D2) that had minimum biological activity in the chicken when compared with the

142 vitamin D (vitamin D3) that was isolated from the irradiation of 7-dehydrocholesterol. 2~-23 It is now recognized that vitamin D2 is about 10 to 20 times less active than vitamin D3 in the chicken. It has been assumed in mammals, including humans, that vitamin D2 and vitamin D3 have equal biological potency and are metabolized in identical fashion. However, it is known that in New World monkeys, as in chickens, the activities of vitamin D2 and vitamin D3 differ. 6~ Originally, it was believed that vitamin D: is metabolized in a fashion identical to that of vitamin D3. However, there are some exceptions. It is now recognized that the vitamin D-binding protein binds vitamin D2 1.5 to 2 times less efficiently than vitamin D3. This difference may be important because higher concentrations of the free form of vitamin D2 can enter into the liver parenchyma and be more efficiently metabolized to 25(OH)D2. 6~ Indeed, when a rat liver is perfused with an equal amount of vitamin D2 and vitamin D3, vitamin D2 is preferentially metabolized to 25(OH)D2 when compared with vitamin D3.51 Similar to vitamin D3, vitamin D: is metabolized to 25(OH)D2, which, in turn, is metabolized to 1,25-dihydroxyvitamin D2, 24R,25dihydroxyvitamin D2, and 25S,26-dihydroxyvitamin D2.149 1,25(OH)2D2 is further metabolized to 1,24,25trihydroxyvitamin D 2 u a process believed to be important for the deactivation of 1,25(OH)zD2. 6~176 Because vitamin D2 has a methyl group at carbon-28, unlike vitamin D3, this carbon is a target for a further hydroxylation to give rise to a variety of 28-hydroxylated metabolites, including 24,25,28-trihydroxyvitamin D~ and 1,24,25,28-tetrahydroxyvitamin D2.152 The physiological role of these metabolites remains uncertain; however, it is interesting to consider the possibility that 24,25, 28(OH)3D2 and 1,24,25,28(OH)4D2 could be metabolized so that the carbon-28 methyl is oxidized and removed to yield a side chain that looks more like the side chain for vitamin D3 .6~

VIII. BIOLOGICAL ACTIONS OF 1,25(OH)2D A. Cellular Mechanism of Action: Genomic There is agreement that most of the actions of 1,25(OH)2D to alter gene transcription directly are initiated by interaction of the hormone with the vitamin D receptor (VDR) (Fig. 5--20). 153-158 Similar to other steroid hormones, 159 the mammalian VDR is a rare intracellular protein. Depending on the species from which it is derived, the VDR has a molecular weight in the range of 48,000 to 60,000 daltons; the human VDR is the smallest VDR yet characterized. 48'16~It selectively binds the active metabolite, 1,25(OH)2D, with high affinity


(equilibrium dissociation "~10 -1~ M). 155 The classic dogma 159 for steroid hormones holds that the hormone traverses the cell membrane and binds to a receptor in the cytosol of the cell. Binding of the steroid to its specific receptor "activates" the receptor and promotes binding of the receptor to acceptor sites (regulatory sequences) on nuclear DNA. Binding of the hormonereceptor complex in the nucleus regulates the transcription of hormone-specific mRNAs which, in turn, govern the translation of protein. As has been recently suggested for other steroid hormones, 161-163 such a simple scenario may not be the case with 1,25(OH)zD3. Autoradiographic studies with radiolabeled 1,25 (OH)2D3164 as well as immunoperoxidase staining with anti-VDR monoclonal antibody 165 demonstrate predominantly nuclear localization of both the 1,25(OH)zD hormone and the VDR in target cells. Nuclear localization of the VDR and 1,25(OH)zD most likely represents specific binding of the VDR to the "downstream half site" of the vitamin D response element (VDRE) on genomic DNA and specific binding of the hormone to the receptor, respectively (Fig. 5-21B). 166-168 However, this interaction of the 1,25(OH)zD-VDR complex requires at least one other accessory protein, the retinoid X receptor (RXR). 169 Like the VDR, the RXR is a member of the steroid receptor superfamily and when given the opportunity will specifically bind 9-cis retinoic acid. ~7~When paired with the unliganded RXR, the VDR assumes a conformation that promotes 1,25(OH)zD binding and stable RXR-VDR dimer formation. These events, in turn, enhance the ability of the DNA binding domains of the RXR-VDR heterodimer to interact with the VDRE. When all critical elements of the receptor-DNA binding reaction are in place, the RXR, the VDR, 1,25(OH)zD and VDRE, then it is proposed that this complex promotes transcription of the vitamin D-responsive gene by interacting with other key elements (protein complexes) of the cell' s transcription machinery. ~7~A specific nucleotide sequence for a VDRE has now been identified in the promoter of six different genes recognized to be important in mammalian and avian mineral homeostasis (Fig. 5-21B). With the exception of the calbindin-28K gene VDRE in the mouse whose composite half sites are separated by four instead of three nucleotides, ~6~ all VDREs so far characterized are made up of an imperfect direct repeat of a hexnucleotide sequence separated by a three-nucleotide "spacer." Although the VDR's hormone-binding domain is distinct and at some intramolecular distance from the DNAbinding domain, ~56 as just discussed, it is apparent that these two separate regions of the protein are functionally linked168; hormone binding induces a covalent modification (phosphorylation) of the receptor, promotes heterodimerization with RXR, increases the receptor's af-

CHAPTER 5

143


C m Genes Regulated by a Vitamin D Response Element Gcne

~

,

Tissue

_

osteocalcin

bone

ostepontin

bone

1~3 integrin

bone

cal bind in- 28K

intestine

parathyroid hormone

parathyroid gland

vitamin D-24-hydroxylase

diverse

FIGURE 5--21 Panel A provides a schematic view of the functional domains of the vitamin D receptor. With the possible exception of a hormone-independent transcriptional activation domain in the amino terminal region of the receptor molecule, all residues (shown as dark lines) known to be important in hormone binding, receptor dimerization, and transcriptional activation reside in the carboxy terminal region of the receptor; this includes the phosphorylation site on the serine residue at position 208 which is considered important for the initiation of ligand-directed dimerization and transactivation. Panel B shows the preferred association of the hormone-occupied vitamin D receptor (VDR) with the unliganded retinoid X receptor (RXR) and interaction of the dimer partners with the consensus vitamin D response element (VDRE). Panel C summarizes those genes whose promoters are known to harbor a functional VDRE which acts to enhance gene transcription.

finity for binding to DNA, and activates (initiates) transcription. The domains of the V D R responsible for each of these functions is pictured schematically in Figure 5 - 2 1 A . Most noticeable is the spacial separation of the DNA-binding domain in the amino-terminus and the hormone-binding domain in the carboxy-terminus of the VDR. These two domains are separated by the so-called " h i n g e " region of the molecule. The " h i n g e " can vary substantially in size, and it is this part of the V D R that generally accounts for the variability in mass of the receptor from species to species. Also of interest is the fact that, aside from D N A binding, all major functions of the V D R reside within the hormone-binding domain. 16~ In fact, the functions of h o r m o n e binding, di-

merization, and transcriptional activation are reliant upon amino acid residues at the extremes of the hormone-binding domain. 168 The " p o l a r i t y " of these functional residues suggests that the central portion of the hormone-binding d o m a i n may be looped out in three-dimensional space, allowing relatively distant residues to c o m e in close contact with one another; confirmation of this hypothesis awaits x-ray crytallographic characterization of the VDR. In conclusion, the trancription of genes (Fig. 5 - 2 1 C ) under the influence of 1,25(OH)2D is subject to control at several different levels. This includes (1) the level of 1,25(OH)2D to which the target cell is exposed, (2) access to and binding of 1,25(OH)zD3 to the VDR, (3) the

144 appropriate phosphorylafion of the VDR, at least at the serine residue in position 208,16~ (4) the state of dimerization with the RXR or other potential dimer partners, 172'173 and (5) the access and interaction of the receptor complex with the VDRE; the latter may be determined by both the specific sequence of the response element as well as the presence of other proteins in the nucleus of the cell that may be competitive for the same D N A sequence 174-176 or competitive for the receptor complex itself. 173

B. Cellular Mechanism of Action: Nongenomic Binding of the 1,25(OH)2D3 to the VDR, binding of receptor-hormone to specific DNA sequences, gene transcription, and new protein synthesis may not be a prerequisite for all of the cellular actions of 1,25(OH)2D3. TM In fact, of the more than fifty documented, specific biological actions of the vitamin D hormone, a minority have been confirmed to take place at the level of gene transcription. 16~ In the intestinal epithelial cell, for instance, there is evidence that receptor-bound 1,25(OH)2D3 activates transcription of the calbindin 28K gene, 176 which codes for a calcium-binding protein postulated to be important in the transcellular transport of calcium in the intestine. 177'178However, administration to animals of inhibitors of either transcription or translation, which terminate 1,25(OH)2D3-directed CaBP production, will not block the 1,25(OH)2D3-mediated uptake of calcium across the luminal membrane of the cell. 179'18~ Furthermore, time-course experiments indicate that calcium uptake by the enterocyte precedes or coincides with the synthesis of hormone-specific CaB P, additional evidence that this 1,25(OH)2D3 effect is not dependent on new protein synthesis. Investigators have also demonstrated a 1,25(OH)zD3-specific change in the lipid composition of the brush border membrance that (1) either preceded or occurred simultaneously with the change in calcium transport rate across the membrane and (2) was also not affected by the administration of inhibitors of protein synthesis. These kinds of experimental results led to investigation of a direct effect of 1,25(OH)2D3 on the cell membrane. 181'182 In fact, currently available evidence suggests that the interaction of 1,25(OH)2D3 with a target cell may result in hormonespecific alterations in the cell at two levels, one of which is dependent on nuclear localization of the h o r m o n e VDR complex and another that is independent of traditional transcriptional events. TM The best characterized nongenomic action of 1,25(OH)zD3 is in fact the rapid transmembrane transport of calcium or "transcaltachia," 183 which is initiated by the opening of voltage-gated calcium (Ca 2+) channels in the


membrane. Vitamin D hormone-driven transcaltachia has been demonstrated to occur in the plasma membranes of intestinal epithelial cells, osteoblast like cells, hepatocytes, muscle, and parathyroid cells. TM According to Nemere et al., 184 transcaltachia is initiated by the interaction of the vitamin D compound with a plasma membrane receptor protein. Although not yet purified or extensively characterized from a functional standpoint, 131'185on the basis of its preference to bind vitamin Ds with a 6-s-cis rather than a 6-s-trans conformation, this plasma membrane receptor is proposed to be distinct from the nuclear VDR protein. It is proposed that when "activated" with ligand the putative membrane receptor opens a voltage-dependent Ca 2+ channel in the membrane that in tum activates phospholipases coupled to a variety of intracellular signaling pathways. 186

IX. BIOLOGICAL ACTIONS OF 1,25(OH)2D IN TISSUES REGULATING CALCIUM BALANCE A. Actions of 1,25(OH)2D on the Intestine The intestine was one of the first target tissues in which the actions of vitamin D and its active metabolite 1,25(OH)2D were carefully studied187; 50% or more of active intestinal calcium transport is vitamin D dependent. Vitamin D facilitates (1) the entry of calcium into the enterocyte, (2) the transit of calcium through the cell, and (3) the exit of the cation into the extracellular space at the basolateral membrane of the enterocyte. There are a number of vitamin D-dependent proteins in the intestine that appear to be temporally related to the transcellular transport of calcium. 188 At the brush border (luminal) membrane of the intestinal epithelial cell there is the aforementioned voltage-gated calcium channel that is functionally linked to a locally stimulated plasma membrane receptor for vitamin D and provides access of luminal calcium ions to the interior of the enterocyte. Once inside the cell, calcium binds to the high-affinity intestinal calcium binding protein, calbindin-28K. The mRNA for calbindin-28K gene is regulated by 1,25(OH)2D at both the level of transcription and message stability. 169 The calbindin-28K protein is proposed to be critical in buffeting the normally low cytoplasmic calcium concentration and in the transcellular movement of calcium. 178'187-189 Finally, there is a vitamin D responsive Ca-ATPase present in the basolateral membrane of the enterocyte. This protein is proposed to be the pump in the antiluminal membrane responsible for the movement of calcium out of the cell against a strong electrochemical gradient187; the mode of its regulation

145

CHAPTER5 Vitamin D Metabolism and Biological Function under the influence of 1,25(OH)2D, whether direct via the VDR or plasma membrane vitamin D receptor or indirect, is not known. 16~

these direct actions are controlled by the plasma membrane vitamin D receptor instead of the nuclear VDR is unknown.

B. A c t i o n s of 1,25(OH)2D in B o n e

C. A c t i o n s of 1,25(OH)2D in K i d n e y

Although vitamin D-deprived states in animals and man have long been associated with failure to normally mineralize bone, the prevailing view is that neither vitamin D nor any of its metabolites are directly responsible for the process of skeletal mineralization. Rather, 1,25(OH)2D, through its ability to stimulate the intestinal absorption of mineral ions, is critically important in the supply of calcium and phosphate to bone for adequate hydroxyapatite formation. 94 There is little convincing evidence that the hormone influences mature bone formation in vivo. In fact, more convincing are data that support a key role for the vitamin D hormone in regulation of the mobilization of calcium from bone. 19~ However, if 1,25(OH)2D does have a direct effect on bone and that effect is mediated at the genomic level, it is most likely controlled through the bone-forming cell, the osteoblast; expression of the VDR gene can only be demonstrated in mature osteoblasts, ~9~ not osteoclasts. For example, 1,25(OH)zD-mediated recruitment and differentiation of osteoclast progenitors into osteoclast-like cells appears to be dependent upon the physical presence of osteoblasts (or preosteoblasts), m Furthermore, it has been shown that exposure of osteoblasts to 1,25(OH)zD results in release of osteoclast-activating activity (OAF) that acts on neighboring bone-resorbing cells to mobilize calcium from the skeleton. ~5~ In vitro 1,25(OH)zD increases calcium uptake, IGF-1 receptor expression, and synthesis of specific collagenous and noncollagenous proteins in mature osteoblast-like c e l l s . 19~ More recently, the hormone has also been shown to downregulate expression of the id gene in osteoblast-like cells. 197This gene product is a member of the helix-loophelix family of proteins, which are suppressors of cell differentiation; 1,25(OH)zD-mediated suppression of this suppressor of differentiation is in accord with the acknowledged tenet that vitamin D hormones, like the retinoids, promote the progression of a cell to a more differentiated phenotype 198 (see section below). However, there may be some exceptions to the tenet that 1,25(OH)zD acts only indirectly on the osteoclast. 1,25(OH)zD appears to be vitally important in the promotion of osteoclast progenitor cell fusion into functionally competent, multinucleated osteoclasts ~9~ and may directly promote an increased [33 integrin expression in the osteoclast's bone-resorbing ruffled border199; integrin molecules appear to be key in localizing and anchoring osteoclasts to the resorbing surface of bone. Whether

Unlike PTH for which there is a clear role in the renal handling of phosphate and calcium and in stimulating 1,25(OH)2D production, 189 there is little evidence that 1,25(OH)2D3, or any other vitamin D metabolite or analog for that matter, has a direct physiological effect on the management of filtered calcium or phosphate) ~176 Although the VDR as well as vitamin D-responsive calcium-binding proteins (calbindins) are found in the distal nephron segments, their participation in regulating transcellular calcium transport in this part of the kidney is not well defined. 16~ Compared to some other tissues, the kidney is relatively enriched in the 1,25(OH)2Dinducible vitamin D 24-hydroxylase) ~ Interaction of 1,25(OH)2D with the VDR in renal tubule preparations results in enhanced expression of the 24-hydroxylase gene 2~ and increased local catabolism of 25(OH)D and 1,25(OH)2D.

D. A c t i o n s o f 1,25(OH)2D on P T H P r o d u c t i o n In comparison to the effects of 1,25(OH)2D to increase transcription of genes whose promoters contain the "classical" VDRE (Fig. 5-21C), 1,25(OH)2D will inhibit the synthesis and secretion of PTH by inhibition of PTH gene transcription. 2'2~176 In fact, 1,25(OH)2D administration has become the therapy of choice for patients with chronic renal failure and secondary hyperparathyroidism. T M Repression of transcription of the human PTH gene under the influence of 1,25(OH)2D is apparently mediated through a single, seven-nucleotide VDRE (AGGTTCA) rather than the two six-nucleotide half-site motifs that legislate up-regulation of transcription. 16~

X. A C T I O N S METABOLITES NONCLASSICAL

OF VITAMIN D AND ANALOGS TARGET

IN

TISSUES

A major impetus for investigators to search for a function of active vitamin D metabolites in tissues other than intestine, bone, kidney, and the parathyroid gland were studies documenting the localization of the VDR and radiolabeled 1,25(OH)2D in a variety of tissues not previously thought to be a site for the action of the hormone (Table 5-3). It should be pointed out that many of these

146


TABLE 5--3 1,25(OH)2D3 Receptor Distribution Among Mammalian Tissues Intestine Kidney Bone Parathyroid Brain Pituitary Parotid Pancreas Stomach Skin

Thymus Lymphocytes Monocytes/macrophages Testes Ovary Uterus Placenta Breast Embryonic liver Embryonic muscle

less of progress in analog development, it is of considerable interest to note that the naturally occurring hormone 1,25(OH)2D still appears to be the most effective vitamin D metabolite in "side-by-side" testing with synthetic analogs irrespective of the cell, tissue, or disease process being investigated. 131'2~ The apparent superiority of the naturally occurring hormone begs the question whether 1,25(OH)2D is operating through genomic, nongenomic, or both pathways in cellular targets responsive to synthetic analogs.

B. D i f f e r e n t i a t i n g and A n t i p r o l i f e r a t i v e Effects o f 1,25(OH)2D nonclassical target tissues and proposed "alternative" functions of 1,25(OH)2D were initially discovered in experiments performed in vitro, so the physiological significance of some of these effects remains to be definitively elucidated in vivo in humans. What follows is a discussion of the effects of vitamin D metabolites and analogs in tissues and cells where these "alternative" actions have been best characterized. There is no doubt that our knowledge of these and of a number of less well-characterized functions of the family of vitamin D molecules in other tissues will be expanding in the future. However, what we do know currently is that many of these functions of 1,25(OH)2D are not directly related to maintenance of mineral ion homeostasis. Furthermore, we know that some of these "alternative" actions may be affected by analogs of vitamin D that do not have the same calcium regulating potential of the naturally occurring hormone, 1,25(OH)2D; implicit in this argument is the suggestion that actions of these vitamin D analogs are not transduced through the VDR. 2~176

A. N o n h y p e r c a l c e m i c A n a l o g s of V i t a m i n D 1,25(OH)2D is attractive as a therapeutic agent. The hormone is active at relatively low circulating concentrations, it has an easily manageable and manipulatable biological half-life in the human host, it can be measured in the circulation with relative ease, and it can be taken orally. The problem is its narrow therapeutic index; when employed in concentrations great enough to transduce the desired effect in the target cell or tissue of interest, the vitamin D hormone is also likely to induce hypercalciuria and/or hypercalcemia. This has prompted investigators and pharmaceutical concerns to design and develop vitamin D analogs capable of transducing a specific effect without putting the patient at risk for hypercalciuria, renal stone disease, possible renal insufficiency, and eventually chronic hypercalcemia. 198 Many such compounds have now been developed. TM Regard-

Because of the identification in the VDR in cells of the myeloid series, the first evidence that 1,25(OH)2D possessed potent differentiating activity was provided by workers examining the effects of the hormone on mouse and human myeloblastic leukemia cell lines. Under the influence of 1,25(OH)2D these cells could be induced to differentiate into monocyte/macrophages (Table 5-3). The differentiating effect of 1,25(OH)2D3 has been extended to human cells; investigators showed that 1,25(OH)2D would promote the maturation of mononuclear cells from human bone marrow into monocytes or multinucleated macrophages. 2~176 In conjunction with its ability to promote the differentiated phenotype, 1,25(OH)2D has also been shown to exert an antiproliferative effect on almost every animal or human cultured cell population, malignant or nonmalignant, in which it has been examined. 21~ In fact, inhibition of cell proliferation by 1,25(OH)2D has been used as a bioassay of the hormone-receptor interaction in cultured human cells. 166 The universality of the prodifferentiating and antiproliferative effect of 1,25(OH)2D suggests that this action of the hormone is not cell specific. In fact, investigators have recently discovered that the endogenous cell cycle-blocking protein p21, a cyclin-dependent kinase inhibitor, is under the transcriptional control of 1,25(OH)2D. 217 When activated, the VDRE in the p21 promoter in the poorly differentiated myelomonocytic cell line U937 up-regulates transcription of p21, driving the cell to a more differentiated macrophage-like phenotype. These observations suggested early on that 1,25(OH)2D may be useful as adjuvant or even primary therapy for human neoplastic disorders. Experimental results with animals showed promise that the antiproliferative effect of the hormone might also be observed in vivo. The survival time of mice inoculated with myeloid leukemia cells can be prolonged, 213 while growth of human VDR-bearing tumor xenografts in immunoincompetent mice can be slowed by parenteral administration of

CHAPTER5 Vitamin D Metabolism and Biological Function 1 , 2 5 ( O H ) 2 D . 214 Unfortunately, the results of the first clinical trials of vitamin D metabolites and analogs in the management of myelodysplastic disorders have been disappointing. 218"219Nonetheless, investigation in this direction continues. 198 The differentiating effects of 1,25(OH)2D on two other cell types has received considerable attention in the recent past. As just discussed, it is now known that 1,25(OH)2D (1) can act as an important switch to direct marrow stem cells away from macrophage development and toward osteoclastogenesis 19~ and (2) can induce the fusion of monocytes into multinucleated giant cells with bone-resorbing potential in vitro. 2~ Given the fact that mature osteoclasts lack the V D R , 216 it is tempting to speculate that the action of 1,25(OH)2D at the level of bone is to amplify the pathway of maturation of stem cells in bone into multinucleated osteoclasts. The differentiation program of keratinocytes, skin cells that give rise to the epidermis, can also be altered by 1,25(OH)2D and related analogues. 22~As will be discussed below, this action of vitamin D metabolites and derivatives has been successfully transformed into therapy of patients with hyperproliferative, dedifferentiating epidermal diseases like psoriasis.

147 TABLE 5--4 Immunological Actions of Active Vitamin D Metabolites and Analogs Target Cell

Action

Macrophage or Antigen-presenting cell

q" Differentiation 1" p21 expression $ Apoptosis $ Proliferation J, c-myc expression 1" chemotaxis 1" [32 integrin expression 1" cell adhesion 1" giant cell formation 1" phagocytosis 1" reactive oxygen metabolite production 1" cidal activity 1" Fc receptor expression 1" IL-1 expression and secretion 1" hsp synthesis ,1, IL-12 expression and production $ HLA-DR, -DE -DQ expression $ TH cell profileration 1" TS cell proliferation $ IL-2 ,l, IFN-gamma ,l, IL-4 $ IL-5 ,l, IL-6 ,l, IL-7 $ TH cell-directed IgG2A production ,], delayed-type hypersensitivity ,[, IL-12 ,], cytotoxic capacity

Activated T-lymphocyte

C. Immunoregulatory Effects of 1,25(OH)2D The expression of the VDR in mitogen- or antigenactivated human lymphocytes and peripheral blood monocytes 221-226 as well as the ability of stimulated macrophage-like cells to make 1,25(OH)2 D227 suggests that production and interaction of active vitamin D metabolites with cells in the lymphocyte and monocyte/ macrophage lineage may modulate the immune response in animals, including man. A comprehensive compilation of the various effects of 1,25(OH)zD on immune cells is provided in Table 5 - 4 . It is important to point out that the immunomodulatory effects of endogenously synthesized 1,25(OH)zD have not been detected in v i v o in the peripheral blood of human subjects. Therefore, it is likely that the circulating concentration of 1,25(OH)zD is quantitatively inadequate to modulate the peripheral immune response. More likely is the possibility that the hormone is designed to act in an intracrine, autocrine, or paracrine mode at tissue sites of inflammation and not as an endocrine modifier of the human immune response. 224'228 Looking carefully at Table 5 - 4 , one can discern that the actions of 1,25(OH)ED and related analogs are generally directed toward stimulation of lymphokine-driven macrophage f u n c t i o n 228-231 o n the one hand and inhibition of lymphocyte responsiveness on the o t h e r . 229-233 The former includes promotion of macrophage phago-

Activated B-lymphocyte Natural killer cell

cytosis, killing, antigen processing, antigen presentation, and adjuvant monokine production. By contrast, the latter generally includes inhibition of the proliferation and action of the T-helper lymphocyte, type 1 (TH1) population, a33 including inhibition of (1) T-cell-directed immunoglobulin ( I g G 2 A ) p r o d u c t i o n , (2) lymphokine synthesis, and (3) generation of the delayed-type hypersensitivity r e a c t i o n . 224-226'229"23~ While there is abundant information on the effects of active vitamin D compounds on stimulated T-helper cell function, relatively little is known regarding the direct effects of active vitamin D metabolites and analogs on T-suppressor cell, natural killer (NK) cell, and B-lymphocyte function. Preliminary data suggest that 1,25(OH)2D may inhibit Tsuppressor cell proliferation, NK-cell activity, and selectively block IL-12 secretion by B-lymphocytes. 233

D. Potential Endocrine Effects of 1,25(OH)2D on Immune Cells When given parenterally, 1,25(OH)2D3 and related analogs have been shown to inhibit the development of

148

MICHAEL E HOLICKAND JOHN S. ADAMS

TH1 lymphocyte-directed autoimmune disease in mice, such as diabetes, systemic lupus erythematosis, and autoimmune encephalitis, and transplantation rejection in experimental animals. 131'23~ The potential utility of vitamin D derivatives in the treatment of human autoimmune disorders or in the prevention of tissue rejection in human organ transplant recipients has not yet been assessed. Furthermore, increased circulating concentrations of 1,25(OH)2D from either endogenous overproduction of the hormone (as can occur in some patients with granuloma-forming diseases or lymphoma) or from exogenously administered 1,25(OH)2D have not been shown to alter the function of either circulating monocytes or lymphocytes in man.

E. E f f e c t s o f 1,25(OH)zD3 on S k i n C e l l s In addition to being the source of vitamin D3 synthesis, 27 mammalian skin also appears to be a target for the active form of the hormone. Receptors for 1,25(OH)zD3 have been identified in rodent skin 236 and in cultured dermal fibroblasts and keratinocytes 212 from human hosts. Among the reported effects of 1,25(OH)zD3 on cultured human cells are inhibition of proliferation of fibroblasts and keratinocytes, 212 stimulation of 7dehydrocholesterol (provitamin D3)synthesis, 237'23s cornification of keratinocytes, 239 and increased melanogenesis in melanoma cells. 24~ The lack of bioeffective receptors for 1,25(OH)2D3 in the developing skin of patients with vitamin D - d e p e n d e n t rickets type II has been suggested as a cause for the alopecia observed in some of these patients242; however, administration of large doses of 1,25(OH)2D3 in such patients does not stimulate hair growth. 243 Oral (Fig. 5 - 2 2 ) 80,244 as well as topical

administration of 1,25(OH)2D3245 to patients with psoriasis, a hyperproliferative disorder of the epidermis, has been shown to have remarkable therapeutic effects. Several other analogs of 1,25(OH)zD3 have been topically administered for the treatment of p s o r i a s i s . 243'246-25~ One of the most widely studied 1,25(OH)zD3 analogs for the treatment of psoriasis is calcipotriol (calcipotriene). 185'246'251 This analog is rapidly metabolized, and therefore, has minimal calcemic activity. This medication is now considered the treatment of choice for psoriasis.

XI. ASSAYS FOR VITAMIN D AND I T S METABOLITES The ability to measure with precision vitamin D2 and vitamin D3 (collectively termed vitamin D) and their metabolites in the serum or plasma of human subjects has improved dramatically in the last 10 to 15 years. Before 1971, when the first competitive protein-binding assays for 25(OH)D were reported, 252'253 an estimate of the circulating concentration of active vitamin D metabolites was obtained solely by bioassay techniques. The "antirachitic" activity of human serum was determined by feeding a lipid extract of human serum to rats that were maintained on a high-calcium, low-phosphorus, vitamin D-deficient diet. One week later, the radii and ulnae were obtained, split, and stained with silver nitrate. The thickness of the line of new mineralization at the epiphyses "line test" was a measure of the effectiveness of the extract. 254 The ability of extracts of human serum to augment 45Ca transport in the duodenum of vitamin D deficient animals was another technique that was employed to measure vitamin D activity. 255'256 The advent

FIGURE 5--22 Viewsof the back of the legs of a female patient with erythrodermal psoriasis prior to treatment (A) and after 3 months of treatment with a daily oral dose of 2.0 lxg of 1,25(OH)2D3 (B). (From Holick MF: Vitamin D and the kidney. Kidney Int 32:912, 1987.)

CHAPTER 5 Vitamin D Metabolism and Biological Function

149

of competitive protein-binding assays and the discovery that vitamin D was metabolized to more active compounds 257'258 ushered in the modem era of vitamin D metabolite essay technology. The introduction of highperformance liquid chromatography (HPLC) for sample purification and the synthesis of radioligands of high specific activity are the two most important technological advances that have allowed the measurement of the less plentiful metabolites of 25(OH)D. For instance, it is now possible to detect 1,25(OH)2D, the active metabolite of the hormone, as low as 4.5 pg (10 fM) in a single milliliter of serum. 259 Although the progress in assay technology has been rapid in terms of the vitamin D metabolites that have been measured, only measurements of the serum levels of 25(OH)D and 1,25(OH)2D have been shown to be of clinical utility. For that reason, particular attention will be paid to a description of the methods and significance of assaying these two metabolites and only brief mention will be made of the measurement of vitamin D and some of its other metabolites.

A. Assay Techniques 1. MEASUREMENT OF VITAMIN D2 AND VITAMIN D3 Quantitation of vitamin D2 and vitamin D3 in the serum is an arduous task and, at the present time, provides little useful information to the clinician. Because vitamin DE and vitamin D3 are less polar than their hydroxylated metabolites, they cannot be purified or adequately resolved from one another on normal-phase HPLC. Therefore, if direct quantitation of vitamin D2 and vitamin D3 is desired, at least 2 ml of serum must be extracted and the lipid extract subjected to preparative open-column chromatography prior to purification on reverse-phase HPLC and quantitation on straight-phase HPLC (Table 5 - - 5 ) . 260-262 Although serial determinations of the vitamin D3 concentrations may provide an index of the

TABLE 5--5 25(OH)D

1,25(OH)2D

amount of vitamin D3 synthesized in the skin after exposure to UV-B radiation (Fig. 5 - - 7 ) , 39 it is not an adequate measure of the vitamin D status of the individual. This is simplified in Figure 5 - 2 3 , which shows the serum vitamin D concentrations in a group of normal subjects, all of whom had a normal serum concentration of 25(OH)D, who were sampled once during the summer and again in the winter. Because of the rapid disappearance of vitamin D from the serum, 39 the serum vitamin D concentration is variable and unpredictable. It may even be low in the summer if the person was not recently exposed to a significant amount of sunlight. However, there is now evidence suggesting that the serum vitamin D2 level may be useful in judging the adequacy of absorption of an oral dose of 50,000 IU of vitamin D2 (see Section III for details), thus providing a sensitive index of intestinal fat absorption and chylomicron formation. 46,263 2. MEASUREMENT OF 25-HYDROXYVITAMIN D2 AND 25-HYDROXYVITAMIN D3 As shown in Table 5 - 5 , the approach to determination of the 25(OH)D concentration may be varied, depending on the clinical situation and whether it is important to know the relative contributions of 25(OH)D3 and 25(OH)D2 to the overall circulating concentration of 25(OH)D. In assays not employing HPLC with direct UV absorbance for detection, a 25(OH)D concentration can be obtained easily from a few hundred microliters of serum. In all routine 25(OH)D assays, regardless of the method of detection, lipid extraction of the serum is necessary to dislodge the compound from the protein constituents of the serum that bind 25(OH)D. Lipid extraction for the 25(OH)D assay can be accomplished with a variety of solvents including chloroform and methanol, 264 methylene chloride and methanol, 265 diethyl ether, 216 acetonitrile, 267 or simply absolute ethanol. 268 The crude lipid extract may then be placed directly into a competitive protein-binding assay with some form of

Indications for Assay

Vitamin D deficiency Intoxication with exogenously administered vitamin D or 25(OH)D3 Following therapy with exogenously administered vitamin D or 25(OH)D3 Vitamin D-dependent rickets, type I Vitamin D-dependent rickets, type II Hypercalcemia of sarcoidosis and other granulomatous diseases Humoral hypercalcemia associated with lymphoma Intoxication with exogenously administered let(OH)D3 and 1,25(OH)zD3 Absorptive hypercalciuria Idiopathic hypercalcemia of infancy (Williams syndrome) Renal failure

150

MICHAEL F. HOLICK AND JOHN S. ADAMS 24-~

20,

-I00

50o o

16

12"

40-

{}

o o o

30

60

o

81,

20

8-

40

!

o

le

o

20

I0o oe

VITAMIN D (ng/ml)

80

A AA

25 (,OH)D (ng/ml)

1,25 (OH)2 D (pg/ml)

FIGURE 5--23 Distributionof circulating concentrations of vitamin D, 25(OH)D, and 1,25(OH)2D in healthy subjects determined in the authors' laboratory. Vitamin D and 25(OH)D values determined in subjects during summer months (open symbols) were higher than those determined during winter months (closed symbols), whereas no seasonal variation was apparent for 1,25(OH)2D concentration. Elderly adults (triangles) (aged 50 to 80 years) had significantly lower 25(OH)D concentrations than those in younger adults (circles). (From Clemens TL, Holick MF, Anast CS, Gray TK (eds): Perinatal Calcium and Phosphorus Metabolism. New York, Elsevier, 1983, pp 1-23.)

the serum vitamin D - b i n d i n g protein (DBP) and [3H]25(OH)D3 as the displaceable ligand. Most 25(OH)D assays employ whole serum from vitamin D - d e f i c i e n t rats as a source of binding protein. 25z'269 However, since only about 1% of the total binding sites on DBP are occupied by vitamin D or its metabolites, even in the vitamin D-sufficient state, serum from a vitamin D replete animal can be used without significantly altering the sensitivity of the assay. Obviously, whole lipid extracts will contain the total lipid complement of serum in addition to vitamin D, 25(OH)D, and other vitamin D metabolites. Therefore, it is not surprising that crude extracts containing 24,25(OH)zD, 25,26(OH)zD, and 25(OH)D3-23,26lactone, all of which are bound with high affinity by DBP, 27~ as well as other n o n - v i t a m i n D lipids that can bind to DBP yield values that are proportionately higher than values obtained after chromatography of the lipid extract, z7~ Hence, a clearly low or undetectable value for 25(OH)D in a nonchromatographic assay is indicative of vitamin D deficiency; however, a value in the lownormal range in such an assay does not exclude vitamin D deficiency. Preparative chromatography of the lipid extract on silicic acid 253 or LH-20 Sephadex 272 to isolate a 25(OH)D-containing fraction of the extract prior to assay provides a more accurate estimate of the serum concentration of 25(OH)D. Further chromatography on normal-phase HPLC can be employed to separate

25(OH)D2 and 25(OH)D3 so that the two metabolites can be assayed independently. 273 It should be emphasized that the mammalian DBP does not significantly discriminate between 25(OH)D3 and 25(OH)D2, so [3H]25(OH)D3 may be the radioligand used in assaying either of the 25(OH)D metabolites. The truest possible estimate of the total 25(OH)Dz and 25(OH)D3 concentration is obtained by direct quantitation of the metabolites by a sensitive UV detector (coupled to an H P L C ) . 26~ Inasmuch as the lower limits of detection by such an assay are in the range of 2 to 5 ng, direct quantitation of 25(OH)D2 and 25(OH)D3 requires the extraction of a larger volume of serum (2 to 5 ml), especially if the patient is thought to have vitamin D deficiency. Measurement of the 25(OH)D2 is of some clinical importance in the patient taking a multi-vitamin preparation containing vitamin D2. Since the hepatic microsomal vitamin D-25-hydroxylase does not distinguish between vitamin D2 and vitamin D3 as substrates,275 a low circulating concentration of 25(OH)D3 in such an individual may indicate that endogenous vitamin D3 synthesis is deficient and that the patient is dependent on dietary or therapeutic supplements of vitamin D2 to achieve an adequate vitamin D nutritional status. It should be noted, however, that in the United States foods are supplemented with either vitamin D2 or vitamin D3, and measurement of 25(OH)DE and 25(OH)D3 cannot be used as a method for determining the source of vitamin D.

CHAPTER5 VitaminD Metabolism and Biological Function

151

3. MEASUREMENT OF 1,25-DIHYDROXYVITAMIN D

receptor, many antibodies raised against 1,25(OH)2D3 analogues bind 1,25(OH)zD2 less avidly than 1,25(OH)aD3; therefore, the radioimmunoassays suffer from an inability to determine accurately the 1,25(OH)aDE contribution to the overall 1,25(OH)2D concentration. Second, antibodies raised against 1,25(OH)zD3 exhibit cross-reactivity with other vitamin D metabolites. Both of these deficiencies are related to the immunogen, which is usually a derivative of 1,25(OH)2D3 conjugated to bovine serum albumin through the side chain of the molecular or in the A-ring at the carbon-3 position. The lack of good immunogen is undoubtedly the explanation for the failure of workers to develop a good antibody against the hormone, a86-29~ Stern et al. 291'e92 have developed a very sensitive bioassay for 1,25(OH)2D that measures the release of 45Ca from prelabeled rat ulna and tibia maintained in organ culture. Although relatively labor-intensive by current standards, the bioassay does allow one to quantitate the biological effectiveness of a vitamin D metabolite or analogue. The cytoreceptor assay of Manolagas et al. 293'294 employs intact, receptor-possessing renal osteogenic sarcoma (ROS) cells and has the advantage of obviating the need for extensive chromatographic purification of the sample prior to assay. During the cytoreceptor assay, the ROS cells are incubated in an extracellular medium containing DBP, which binds 1,25(OH)2D with less affinity than many of the contaminating vitamin D metabolites; this leaves relatively more 1,25(OH)2D free to enter the ROS cells and to bind its own high-affinity, intracellular receptor.

The first serum assay for 1,25(OH)zD was reported in 1974276 just 3 years after the structural identification of 1,25(OH)D3 as the active metabolite of vitamin D3.277-279 The key to development of the assay was the detection of a high-affinity, low-capacity binding protein (receptor) in chick intestinal epithelium that could be employed as a specific binding protein in a radioligand binding assay. 28~ The original assay required extraction of a large volume of serum (20 ml) and three separate chromatographic purification steps before assay and was sensitive to only 50 pg/tube. In recent years the availability of tracers of high specific activity, the application of sophisticated chromatography for sample purification, and the use of techniques to promote receptor stability have combined to greatly improve sample preparation and the analysis. The 1,25(OH)2D assay is now available in most university hospitals and through several commercial laboratories. Although the assay for 1,25(OH)2D in patients' serum or plasma is obtained with relative ease, there exists significant variability in its performance and there are caveats in its application to human health or disease (see Section IX.B). A purified lipid extract of human serum or plasma can be analyzed for its content of 1,25(OH)2D in a variety of ways (Table 5-5). The classic binding protein in the competitive protein-binding assay for 1,25(OH)2D is the hormone's own receptor protein isolated from intestinal epithelium of vitamin D-deficient chicks. Vitamin D deficient birds are employed in order to improve the extraction of receptor that is not occupied by endogenously synthesized 1,25(OH)2D. A disadvantage in the use of the chick intestinal receptor in the binding assay is that it discriminates against 1,25(OH)2D2 binding in favor of 1,25(OH)2D3. Therefore, these two metabolites, which are biologically equipotent in humans, cannot be measured with comparable efficiency. This may account for the reports that the chick receptor assay underestimates the 1,25(OH)2D2 concentration by 23% to 6 0 % . 281-283 This failure is a significant liability when determining the serum concentration of 1,25(OH)2D in patients relying on ingested vitamin D2 for their vitamin D nutrition. These problems have been resolved with the increased use of the receptor derived from calf thymus, which binds 1,25(OH)2D3 and 1,25(OH)2D2 with equivalent affinity and capacity. T M In fact, this assay can now be employed for the measurement of 1,25(OH)2D in lipid extracts of small quantities of human serum (0.5 to 1.0 ml) after purification on a single silica cartridge. 285 Several radioimmunoassays have been developed for detection of 1,25(OH)2D in the s e r u m . 286-29~ Although potentially advantageous, radioimmunoassays suffer two major drawbacks. First, similar to the chick intestinal

4. MEASUREMENT OF 24,25-DIHYDROXYVITAMIN D

Owing to the high affinity of DBP for 24,25(OH)2DY 5 this metabolite can be readily detected with ease in a competitive protein-binding assay (Table 5-5). However, 24,25(OH)2D2 is bound two or three times less avidly than is 24,25(OH)zD3, 296'297 making an estimation of the overall 24,25(OH)2D concentration misleading in a person ingesting significant amounts of vitamin DE. Accurate estimation of the total 24,25(OH)zD concentration must, therefore, employ chromatographic techniques that resolve 24,25(OH)zD2 and 24,25(OH)zD3 and binding assays that use the appropriate radioinert metabolite in a standard curve. Recently, the use of a methylene chloride-isopropanol solvent system on a cyano-bonded ~-silica HPLC column has been shown to be capable of separating 24,25(OH)zD2 and 25(OH)D3-23,26-1actone, 298 two metabolites of 25(OH)D3 that co-migrate with 24,25(OH)2D on normal-phase HPLC ~-silica columns developed in hexane-isopropanol. It might be questioned whether determination of the circulating 24,25(OH)zD concentration warrants the effort required. Although suggested by a number of investigators, ~42'299a

152

MICHAEL F. HOLICK AND JOHN S. ADAMS

physiological role for 24,25(OH)2D in human mineral metabolism has not been unequivocally demonstrated (see Section VI.A). Until more convincing data are available, routine assay of 24,25(OH)2D cannot be advocated. 5. OTHER VITAMIN D METABOLITES

In recent years the measurement of two additional metabolites, 25,26(OH)2D and the 25(OH)D-23,26lactone, has been extensively investigated. For both, HPLC purification of the serum lipid extract is required prior to detection in a DBP-based competitive proteinbinding assay (Table 5-5). Neither metabolite has been shown to be of physiological significance in humans. In fact, the 25(OH)D3-23,26-1actone, a renal metabolite of 23,25(OH)2D3, 3~176 is detected in human serum only in states of vitamin D excess. The significance of the extraordinarily high affinity of DBP for the lactone is not currently known. High circulating concentrations of this metabolite can theoretically displace 25(OH)D and 1,25(OH)2D from the DBP, thereby facilitating the binding of these metabolites to the cellular receptor for 1,25(OH)2D in 12i1,'O.301

B. Clinical Utility of the 25(OH)D and 1,25(OH)2D Assays (Table 5-5) 1. 25(OH)D ASSAY The 25(OH)D concentration is the test of choice for determining the adequacy of vitamin D nutrition from either endogenous or exogenous sources. 2'6~ A very low or undetectable value in the competitive protein binding assay is indicative of (1) deficient substrate for the hepatic vitamin D-25-hydroxylase; (2) disease or hormonerelated alteration in the activity of the hepatic vitamin D-25-hydroxylase; (3) failure to synthesize DBP or loss of DBP-bound 25(OH)D; or (4) accelerated catabolism of 25(OH)D. The first may result from diminished cutaneous sunlight exposure of the patient or from a combination of deficient sunlight exposure and intestinal malabsorption of vitamin D in persons consuming a diet supplemented with vitamin D. In either case, it is important to point out that deficient endogenous synthesis of vitamin D is required for vitamin D deficiency to occur. Clements et al. 3~ recently reported that after oral or intravenous administration, neither vitamin D nor 25(OH)D undergoes significant enterohepatic circulation, precluding the possibility that one can become vitamin D - or 25(OH)D-deficient in the presence of adequate production of vitamin D3 in the skin. A number of hepatocellular diseases can contribute to 25(OH)D deficiency in patients in whom the availability of substrate, vitamin DE, or vitamin D3 is compromised. However, it

is unusual to encounter 25(OH)D deficiency in patients who are vitamin D-sufficient except for patients with severe liver disease, 54 because the " f r e e " 25(OH)D concentration in such individuals is usually not altered. 3~ Because human DBP is an alpha globulin with a relatively low molecular weight (58,000 daltons; albumin MW = 69,000), it is lost through the glomerular basement membrane in patients with nephrotic syndrome. The total serum concentration of 25(OH)D in such patients is directly correlated with the degree of proteinuria, and is expected to be low in patients with greater than 4 g of proteinuria per day. 56 Although patients with protein-losing enteropathies or severe burns may be subject to loss of DBP, 25(OH)D deficiency in such settings is rarely due to only a loss of DBP through the gastrointestinal tract or skin. Finally, in principle at least, the potential exists for accelerated 25(OH)D clearance from the serum as a cause for diminished circulating concentrations of the metabolite. It is known that administration of pharmacological doses of 1,25(OH)2D3 will accelerate 25(OH)D3 clearance in experimental animals 3~ and ameliorate the increase in the serum 25(OH)D concentration in humans 53 given large daily doses of vitamin D2 orally. An assessment of the adequacy of therapy and patient compliance with therapy with vitamin D3, vitamin D2, or 25(OH)D3 in patients requiting vitamin D supplementation (i.e., hypoparathyroidism) can be made by following the serum concentrations of 25(OH)D. Therapy in most cases is aimed at maintaining the 25(OH)D level in the high-normal range, usually between 25 and 45 ng/ ml. 2 Because 25(OH)D is bound with high affinity by the serum DBP, it has a long serum half-life, with estimates ranging from 12 to 60 days. 2 Its prolonged halflife makes infrequent measurements of the serum 25(OH)D concentration (every 2 to 3 months) adequate for monitoring therapy in the noncompliant patient. Measurement of the 25(OH)D concentration is also the test of choice in establishing the diagnosis of vitamin D intoxication from ingestion or parenteral administration of vitamin D or 25(OH)D3. Ingestion of large quantities of vitamin D may result in 25-hydroxylation of vitamin D by hepatic mitochondria, 3~176 which possess a vitamin D-25-hydroxylase of lower affinity for vitamin D (Km = 10 -6 M) than hepatic microsomes (Km = 10 -8 M) 3~176 but a greater capacity for conversion of vitamin D to 25(OH)D. 3~ The low-affinity, high-capacity mitochondral system 31~ does not appear to be productinhibitable as is its microsomal counterpart 31~ and is, therefore, capable of prolific 25(OH)D generation given enough substrate. Interestingly, in normal human subjects, excessive exposure to sunlight will not result in vitamin D3 intoxication, because only a limited amount of vitamin D3 will be formed in the skin (see Section II.B); with continued photon bombardment of the skin,

CHAPTER5 Vitamin D Metabolism and Biological Function

153

previtamin D3 will be preferentially converted to two nonbiologically active photoisomers, tachysterol and lumisterol (Fig. 5 - 3 ) and vitamin D3 is degraded to 5,6trans-vitamin D3 and suprasterols 1 and 2 (Fig. 5-5).

2. 1,25(OH)2D ASSAY In the authors' view there are few clinical circumstances in which a single determination of the serum concentration of 1,25(OH)2D, a metabolite with a circulating half-life of only 4 to 6 hours, will be of diagnostic value (Table 5 - 6 ) . The finding of a very low or undetectable serum 1,25(OH)2D concentration in a rachitic child with a normal or elevated serum concentration of 25(OH)D is indicative of vitamin D-dependent rickets type I, an inheritable defect, or absence of the renal 25(OH)D-loL-hydroxylase. TM A very high circulating concentration of 1,25(OH)2D in a rachitic child on vitamin D therapy is indicative of end-organ unresponsiveness to 1,25(OH)2D and the diagnosis of vitamin D dependent tickets type 11. 312 A high value for the 1,25(OH)2D assay may occur in patients intoxicated with either dihydrotachysterol (DHT), lc~-hydroxyvitamin D3 [ loL(OH)D3], o r 1,25(OH)2D3 .6~ Intoxication with the former compounds is dependent to a great extent on hepatic 25-hydroxylation of DHT and of l c~(OH)D3 to 25-hydroxydihydrotachysterol and 1,25(OH)2D3, respectively, which cross-react with the 1,25(OH)2D receptor. A frankly elevated or high-normal serum 1,25(OH)2D concentration in a hypercalcemic patient with sarcoidosis, 119'313 tuberculosis, 314 siliconeinduced granulomatous disease, 315 disseminated candidiasis, 316 o r l y m p h o m a 1~ represents inappropriate

TABLE 5 - - 6

endogenous production of the hormone in the presence of hypercalcemia (also see Section V.C). The autonomous, extrarenal synthesis of 1,25(OH)2D in sarcoidosis is almost always associated with extensive disease and high-intensity alveolitis. 317'318 The finding of an inappropriately high circulating 1,25(OH)2D concentration in such a patient with granulomatous disease or lymphoma portends an excellent calcium-lowering effect with glucocorticoid therapy. In an older individual with suspected granulomatous disease or lymphoma, the failure of glucocorticoids to lower the serum 1,25(OH)2D and calcium concentration within a few days strongly suggests the presence of a coexistent hypercalcemia-causing disease (i.e., primary hyperparathyroidism). Extrarenal 1,25(OH)2D synthesis by the placenta will elevate the total and " f r e e " concentration (that fraction of the total serum concentration not bound by a circulating binding protein) of 1,25(OH)2D in the serum during the third trimester of pregnancy. 319'32~ A meaningful interpretation of the serum 1,25(OH)25(OH)2D concentration in states of vitamin D deficiency is difficult. It may be increased, decreased, or normal, depending on the circumstances in which the sample is obtained. Obtaining serial values for 1,25(OH)2D in a single individual after a provocative stimulus to endogenous 1,25(OH)2D synthesis is currently being investigated in various clinical settings (e.g., postmenopausal osteoporosis). 94'321'322 However, at present, these techniques require frequent sampling and often prolonged stimulation of the renal 25(OH)D-lot-hydroxylase, such as a 6- to 12-hour infusion of hPTH(1-34), in order to measure a

Assay of Vitamin D and Vitamin D Metabolites Purification

Sterol

Detection

LPLC

HPLC

UV

X X

X X

X

X X X

X X

X X X X

X X X

24,25(OH)2D

X

X

25,26(OH)zD

X

X

25(OH)D-23,26-1actone

X

X

Vitamin D

CPBA

RIA

BIO

25(OH)D

1,25(OH)2D

LPLC, open column (low pressure) liquid chromatography; HPLC, high-performance liquid chromatography; UV, assay by ultraviolet light absorbance on HPLC; CPBA, competitive proteinbinding assay; RIA, radioimmunoassay; BIO, bioassay.

154


significant effect on the serum 1,25(OH)2D concentration (Fig. 5-17). For the sake of practicality, the provocative tests are not yet a clinically useful tool, but they may become so in the future.

C. The Use of Vitamin D Assays in the Evaluation of the Hypocalcemic and Hypercalcemic/Hypercalciuric Patient When confronted with a hypocalcemic patient, it is useful to consider whether the reduction in the serum ionized calcium concentration is due to deficiency in one or both of the calcemic hormones, 1,25(OH)zD and PTH. In the case of the former hormone, measurement of the serum 25(OH)D concentration provides the most valuable information in the majority of cases. Owing to its long serum half-life, a 25(OH)D measurement provides an excellent index of the amount of vitamin D that is metabolized in the liver and the amount of substrate [25(OH)D] available for synthesis of the active metabolite, 1,25(OH)zD. In the hypocalcemic patient, a frankly low 25(OH)D level almost always indicates deficient cutaneous synthesis and dietary intake of vitamin D. Patients with severe hepatocellular disease or nephrotic syndrome may have a low total serum calcium and 25(OH)D concentration due to either a decrease in hepatic synthesis or urinary loss of proteins that bind calcium (albumin, prealbumin) and 25(OH)D (DBP, albumin, lipoproteins) in the circulation. In such cases, a low serum concentration of ionized calcium and a compensatory elevation in the circulating PTH concentration may aid in establishing the presence of true ( " f r e e " ) 25(OH)D deficiency. Hypocalcemia with a normal or elevated 25(OH)D level points either to deficiency or decreased bioeffectiveness of PTH, an acquired abnormality in the metabolism of 25(OH)D to 1,25(OH)zD (i.e., renal failure), an inherited defect in 1,25(OH)2D synthesis, or a defect in the action of 1,25(OH)zD at its target tissues. The last two situations, both rare, can usually be distinguished on biochemical grounds by the circulating 1,25(OH)zD concentration, which will be low or nondetectable in patients with vitamin D-dependent rickets type I, and often dramatically increased in patients with vitamin D-dependent tickets type II. 2'6~ In patients with hypocalcemia and diminished synthesis, release, or endorgan effectiveness of PTH (i.e., patients with hypoparathyroidism, magnesium deficiency, or pseudohypoparathyroidism), the 1,25(OH)zD concentration will be inappropriately low. This is due to the lack of a stimulatory effect of PTH on the renal 25(OH)D-loL-hydroxylase and the inhibitory effect of hyperphosphatemia, a usual consequence of hypoparathyroidism, on the same

enzyme. However, because of overlap of the serum 1,25(OH)zD concentration into the normal range in such patients, measurement of this metabolite is not particularly helpful in establishing the diagnosis of hypoparathyroidism. Whereas the 25(OH)D assay has a central role in the evaluation of the hypocalcemic patient, the utility of this assay in the workup of a hypercalcemic patient is limited. Only if 25(OH)D is present in high concentrations in the circulation and it (or its metabolites) binds to the high-affinity receptor for 1,25(OH)zD is it capable of inducing hypercalcemia. Intoxication from an exogenous source may arise after ingestion of large amounts of vitamin D or 25(OH)D3, whereas intoxication with endogenously synthesized 25(OH)D may be the etiological explanation for the idiopathic hypercalcemia of infancy. The latter, referred to as the Williams syndrome when accompanied by the phenotypic markers of supravalvular aortic stenosis, elfin facies, and mental retardation, is a rare disorder that has been associated with an exaggerated increase in the serum concentration of 25(OH)D in response to a challenge with orally administered vitamin D2 .322 These children have also been shown to possess inappropriately elevated serum concentrations of 1,25(OH)zD. 323 In 25(OH)D intoxication, from either an exogenous or endogenous source, the serum 1,25(OH)zD concentration may be normal or even reduced unless there is some additional abnormality in the regulation of the l oL-hydroxylation of 25(OH)D. As alluded to previously, normal individuals do not become vitamin D [25(OH)D] intoxicated from endogenously synthesized vitamin D. Lifeguards, for instance, may develop circulating 25(OH)D concentrations that are well above the normal range (>100 mg/ml) but do not develop hypercalcemia or hypercalciuria. 3~ The usefulness of the 1,25(OH)zD assay in evaluating a patient with hypercalcemia and/or hypercalciuria is, for the most part, restricted to patients with suppressed PTH secretion; an elevation in the serum 1,25(OH)zD concentration is an expected accompaniment of primary hyperparathyroidism (unless renal failure is present), and there is little need for it to be measured when that diagnosis is certain or highly likely. Therefore, an inappropriate elevation in the serum 1,25(OH)zD concentration and a suppressed plasma PTH concentration in a hypercalciuric/hypercalcemic patient is highly suggestive of (1) exogenous intoxication with lc~(OH)D3, DHT, or 1,25(OH)zD3; (2) endogenous intoxication with 1,25(OH)zD as may occur in sarcoidosis, other granulomatous diseases, and lymphoma; or (3) absorptive hypercalciuria. 324 Determination of the serum 1,25(OH)zD concentration may be of help in discerning the presence of primary hyperparathyroidism in patients who are suspected to

CHAPTER 5 Vitamin D Metabolism and Biological Function harbor the disease but in whom confirmatory laboratory data are lacking. It should also be recognized that a frankly elevated serum 1,25(OH)2D concentration may not be present in a hypercalcemic/hypercalciuric patient with concomitant hepatocellular disease or nephrotic proteinuria resulting in diminished production or loss of serum proteins that bind 1,25(OH)2D. Although the "total" concentration of the hormone may be relatively low in such cases, the " f r e e " concentration of 1,25(OH)2D, which can adequately be determined from a knowledge of the serum albumin and DBP levels, 325 will be higher than normal.

XII. CONCLUSION As recently as 20 years ago, vitamin D was considered to be "just another one of those fat-soluble vitamins." The revelation that vitamin D must be hydroxylated in the liver and kidney to 1,25(OH)zD before it is biologically active opened a new chapter for vitamin D research, and clinical medicine. The finding that the kidney was responsible for the final activation step for vitamin D metabolism provided a new insight into the cause of vitamin D resistance that was often associated with patients who suffered from chronic renal failure. The availability of reliable assays for the measurement of the circulating concentration of 25(OH)D and 1,25(OH)zD has led to the identification of inbom and acquired disorders in 25(OH)D metabolism. These assays have provided new insights into the cause of a variety of hypo- and hypercalcemic disorders including vitamin D-dependent rickets types I and II, 326 primarily hyperparathyroidism, and tumor-induced hypercalcemia associated with certain lymphomas and chronic granulomatous disorders. The knowledge of the crucial role of the kidney's metabolic conversion of 25(OH)D to 1,25(OH)zD prompted the chemical synthesis of this kidney hormone and its 25-deoxy analogue, l oL-hydroxyvitamin D3. These drugs have provided the clinician with an effective means for the treatment of a variety of hypocalcemic disorders that are caused by acquired and inbom errors in the metabolism of 25(OH)D to 1,25(OH)zD. The discovery of a rare intracellular protein (receptor) that binds 1,25(OH)zD with high affinity and specificity has greatly advanced our understanding of the cellular mode of action of the hormone. In the 1970s the observation that a variety of tissues and cells (that are not classic target tissues for vitamin D) possessed nuclear receptors for 1,25(OH)zD3 opened up a new and exciting chapter in the evolving vitamin D story. It was found that such diverse tissues as the brain, parathyroid gland, gonad, thymus, pancreas, and skin had high-affinity,

155 low-capacity nuclear receptors for 1,25(OH)2D (Table 5 - 3 ) . In addition, several circulating mononuclear cell populations including monocytes and activated B and T lymphocytes possessed receptors for this hormone. The initial reaction to these observations was that this was an epiphenomenon with little biological importance. However, the observation that 1,25(OH)zD could induce differentiation of 1,25(OH)zD3 receptor-positive promyelocytic leukemic cells generated an enormous amount of interest regarding the potential biological effects of 1,25(OH)zD on "nonclassical" target tissues. In vivo and in vitro studies have revealed that 1,25(OH)zD can inhibit the proliferation and induce cellular differentiation of 1,25(OH)zD3 receptor-positive cells and enhance or inhibit the synthesis and secretion of a variety of hormones, growth factors, and immunoglobulins. The physiological importance of 1,25(OH)zD on (1) regulating hormone secretion, (2) inducing maturation of a variety of tissues including the skin, (3) altering immune function, and (4) affecting myocardial activity is unknown. However, it is known that patients with vitamin D-dependent tickets type II or simple vitamin D deficiency do not have overt alterations in their immune systems, cardiac function, skin appearance, or hormone responsiveness to provocative stimulation. Thus, although it is unlikely that 1,25(OH)zD is essential for the normal functioning of these tissues, the observation that 1,25(OH)zD can alter the biochemistry and physiology of receptor-positive tumor and normal cells has wide-ranging pharmacological and physiological applications. For example, the findings that parathyroid glands possess nuclear receptors for 1,25(OH)zD3 and that in vitro 1,25(OH)zD3 inhibits the expression of the parathyroid hormone gene 327 led to the intravenous use of 1,25(OH)zD3 as a method to suppress parathyroid hormone secretion in chronic renal failure patients with marked secondary hyperparathyroidism. 328 The observation that circulating monocytes possess receptors for 1,25(OH)zD3 and differentiate into osteoclast-like cells when exposed to this hormone has prompted the concept that 1,25(OH)2 may be important for the mobilization of stem cells for the bone remodeling process. Initially it was thought that 1,25(OH)zD would have great potential as an antitumor agent. However, it is now known that antimitogenic activity of 1,25(OH)zD3 is reversible 329 and that tumor clones that have a decreased number of receptors for this hormone are resistant to its antimitogenic activity. Furthermore, when the hormone is given in pharmacological doses, it causes severe hypercalcemia. 33~ Despite these problems, 1,25(OH)zD3 may be of great pharmacological value, especially for dermatology. Unlike tumor cells that can dedifferentiate when 1,25(OH)zD3 is removed from their environment, when 1,25(OH)zD3 induces human keratinocytes to dif-

156


ferentiate, it does so in an irreversible manner. One practical application is the effective use of 1,25(OH)2D3 for the treatment of hyperproliferative skin disorders such as psoriasis. It is well documented that 1,25(OH)2D3 causes many if not most of its biological effects by a nuclear-mediated mechanism. However, there is intriguing evidence that in some cells 1,25(OH)2D may also increase intracellular calcium concentrations and alter phosphoinositol metabolism in both receptor-positive and -negative c e l l s . 331'332 Thus, it may be possible to develop analogues of 1,25(OH)2D3 that have selective effects on the plasma membrane and cytosolic calcium concentrations, while others could be developed that would interact with the nucleus to induce antimitogenic activity. The next decade holds great promise for the field of vitamin D research. 1,25(OH)2D and its analogues offer great promise in areas of immunology, dermatology, cardiology, oncology, nephrology, and endocrinology. Thus, 1,25(OH)2D3 is a hormone whose clinical pharmacological potential is yet to be realized.

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324. Broadus AE, Insogna KL, Lang R, et al: A consideration of the hormonal basis and phosphate leak hypothesis of absorptive hypercalciuria. J Clin Endocrinol Metab 58:161-169, 1984. 325. Bikle DD, Siiteri PK, Ryzen E: Serum protein binding of 1,25dihydroxyvitamin D: A reevaluation by direct measurement of free metabolite levels. J Clin Endocrinol Metab 61:969-975, 1985. 326. Fraser D, Scriver CR: Hereditary disorders associated with vitamin-D resistance or defective phosphate metabolism. In DeGroot L, et al (eds): Endocrinology, vol 2. New York, Grune & Stratton, 1979, pp 797-807. 327. Silver J, Russell J, Sherwood LM: Regulation of preproparathyroid hormone mRNA in bovine parathyroid cells in culture by vitamin D metabolites. In Norman AW, Schaefer K, Grigoleit H-G, von Herrath D (eds): Vitamin D, Chemical, Biochemical and Clinical Update. Proc 6th Workshop, Vitamin D, Merano, Italy, 1985. Berlin, de Gruyter, 1985, pp 24-33. 328. Slatopolsky E, Weerts C, Thielan HR, et al: Marked suppression of secondary hyperparathyroidism by intravenous administration of 1,25-dihydroxycholecalciferol in uremic patients. J Clin Invest 74:2136-2143, 1984. 329. Bar-Shavit Z, Kahn AJ, Stone KR, et al: Reversibility of vitamin D-induced human leukemia cell-line maturation. Endocrinology 118:679-686, 1986. 330. Koeffler HP, Hirjik S, Itri L, and the Southern California Leukemia Group: 1,25-Dihydroxyvitamin D3. In vivo and in vitro effects on human preleukemic and leukemic cells. Cancer Treat Rep 69:1399-1407, 1985. 331. Baran DT, Moira ML: 1,25-Dihydroxyvitamin D increases hepatocyte cytosolic calcium levels: A potential regulator of vitamin D-hydroxylase. J Clin Invest 77:1622-1626, 1986. 332. Smith E, Holick MF: The skin: The site of vitamin D3 synthesis and a target tissue for its metabolite 1,25-dihydroxyvitamin D3. Steroids 49:103-131, 1987.

2 H A P T E R (~

Pathophysiology of Calcium, Phosphate, and Magnesium Absorption ROBERTO CIVITELLI, KONSTANTINOS ZIAMBARAS, AND RATTANA LEELAWATTANA Division of Bone and Mineral Diseases, Washington University School of Medicine, St. Louis, Missouri 63110

I. Calcium A. Physiology of Calcium Absorption B. Increased Calcium Absorptive States C. Decreased Calcium Absorptive States II. Phosphate A. Physiology of Phosphate Absorption B. Clinical Manifestations of Phosphate Disorders

C. Increased Phosphate Absorptive States D. Decreased Phosphate Absorptive States III. Magnesium A. Physiology of Magnesium Absorption B. Clinical Manifestations of Magnesium Disorders C. Increased Magnesium Absorptive States D. Decreased Magnesium Absorptive States References

I. C A L C I U M

A. P h y s i o l o g y o f C a l c i u m A b s o r p t i o n 1. CALCIUM BALANCE

Calcium is an essential element for survival. It not only serves as the principal component of the skeleton but also plays a vital role in a variety of physiological and biochemical processes, such as regulation of nerve excitability, muscle contraction, and blood coagulation. Calcium balance is a tightly controlled homeostatic mechanism and active processes are critical to the absorption of calcium through the intestine. Accordingly, pathological conditions that affect the major regulators of calcium absorption--primarily the vitamin D systemmresult in clinically relevant syndromes conditioned and maintained by an abnormal intestinal calcium absorption. METABOLIC BONE DISEASE

The relationship between calcium absorption and dietary calcium is curvilinear, reflecting the two major absorption mechanisms, passive diffusion and active, saturable absorption (Fig. 6-1). Up to a daily calcium intake of 1000 mg, net absorption increases linearly with calcium intake. Above that limit, calcium absorption tends to plateau, so that normally no more than 300 mg/ day is absorbed on average even if the dietary intake is raised. This threshold increases up to 500 mg/day at around puberty (discussed in Section I.A.5), but within these genetic limits, there is a wide individual variability in the efficiency of calcium absorption, which is believed 165

Copyright 9 1998by AcademicPress. All rightsof reproductionin any formreserved.

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6 to 7 weeks) diabetic rats develop a markedly increased intestinal calcium absorption, despite persistently low 1,25(OH)2D3 levels) ~7 At this stage of chronic diabetes, urinary losses of calcium are substantial, 217 and this may drive an enhancement of intestinal calcium absorption as a compensatory mechanism. Furthermore, chronic insulin deficiency causes intestinal hypertrophy, increased mucosa cell proliferation, and stimulation of several membrane transport systems. An insulin-dependent increase in in-

179

testinal absorption of calcium along with marked hypercalciuria has also been reported in humans with poorly controlled diabetes. 218

i. Preeclampsia Preeclampsia is associated with several abnormalities of calcium metabolism, such as marked hypocalciuria, 2~9 decreased 1,25(OH)zD3, 22~ elevated parathyroid hormone, T M and reduced level of ionized calcium. 222 In some patients, although not all, intestinal calcium absorption may be l o w . 219'221 3. INTRINSIC DEFECTS OF INTESTINAL C A L C I U M TRANSPORT

a. Aging A decreased intestinal calcium absorption 37'86'223 and a decline in the intestinal ability to adapt to a low-calcium diet have been consistently noted in elderly individuals. 22'81 As mentioned under Section I.A.5, two major hypotheses have been entertained to explain the declining calcium absorption, i.e., a decrease of 1,25(OH)2D3 and an intestinal resistance to the vitamin D metabolite. Although age-dependent declines in serum 1,25(OH)2D3 levels have been observed, 37'224 others have reported either unchanged 47'225 or even increased circulating 1,25(OH)2D3 .226'227 Furthermore, whereas a decreased conversion of 25(OH)D to 1,25(OH)2D3 has been found, kinetic studies in rats indicate that synthesis of 1,25(OH)2D3 actually increases with aging. 192 The latter finding would suggest that an intestinal resistance to 1,25(OH)2D3 develops with aging. Accordingly, a selective resistance to treatment with 25(OH)D in elderly women with fractures compared to subjects without fractures has been observed, despite equal increments in 1,25(OH)2D3 levels. 228 Furthermore, an age-related decrease of intestinal VDR was demonstrated in duodenal biopsies of normal w o m e n , 226 a s well as in r a t s . 223 However, other observations have not been consistent with the hypothesis of an intestinal resistance to vitamin D metabolites. Prolonged administration of 1,25(OH)2D3 could consistently improve calcium absorption in elderly women with vertebral fractures, 229 pointing to the existence of a reduced ability to synthesize 1,25(OH)2D3 in the elderly, rather than to an end-organ resistance. The two mechanisms might not be mutually exclusive, and the apparent discrepancies could be reconciled by observing that serum 1,25(OH)zD3 increases until age 65, starting to decline only thereafter 227'230 (Fig. 6 - 6 ) . These observations could be interpreted to suggest that vitamin D resistance develops earlier, representing the major factor responsible for the declining calcium absorption until the seventh decade; whereas a defect in 1,25(OH)zD3 production occurs in a later phase of life. Recent studies have shed a different light on this issue. Using a doubleisotope method to assess true fractional absorption, Ebel-

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ing et al. TM were able to induce increases of intestinal calcium absorption and serum 1,25(OH)2D3 of similar magnitude in elderly and young women after a 4-day low-calcium diet. TM To further complicate this matter, the same group did not find the expected correlation between age and true fractional calcium absorption in their patients, although the adaptation to low dietary calcium content was confirmed. 227'231 These most recent data appear to dampen the pathophysiological relevance of a decline of intestinal calcium absorption in elderly people. b. Menopause A decreased intestinal calcium absorption in postmenopausal women with fractures has been recognized since the early 1 9 6 0 S , 223'232'233 and a reduced ability of estrogen-deficient women to absorb calcium is considered one of the pathophysiological mechanisms of postmenopausal (type I) osteoporosis. 234 The incidence of calcium malabsorption in osteoporotic women can be as high as 60% to 70%, and fecal calcium exceeds calcium intake in a third of these women. Several lines of evidence support the notion that the reduced calcium absorption consequent to estrogen depletion is independent of aging. First, ovariectomy is followed by a rapid decline in net intestinal calcium absorption. 38'235'236 Second, in the transition between the preand postmenopausal period, fractional calcium absorption declines an additional 2%, independent of age. 81 Finally, among postmenopausal women, those who are osteoporotic have lower calcium absorption compared to " n o r m a l " peers. 38 Despite this rather convincing evidence, the pathogenesis of the menopause-related

decline of calcium absorption efficiency remains very controversial. Although estrogen deficiency acts independent of aging, similar pathophysiological mechanisms have been invoked to explain these phenomena. As in the case of aging, reduced serum levels 1,25(OH)zD3 have been reported in postmenopausal osteoporotic patients by some investigators, 47'224'237'23s but not by o t h e r s . 239-241 The increased bone resorption produced by estrogen deficiency, and the attendant reduction of parathyroid activity, could in theory explain a diminished 1,25(OH)zD3 synthesis, and in turn the decreased calcium absorption and negative calcium balance. Nevertheless, a number of women with calcium malabsorption have normal plasma 1,25(OH)zD3 levels, suggesting that these individuals may lose responsiveness to the action of 1,25(OH)2D3. In support of this hypothesis is the observation that stimulation of calcium absorption by 1,25(OH)2D3 is blunted in ovariectomized women, compared to age-matched controls, and that estrogen supplementation preserves the intestinal response to the vitamin D metabolite 46 (Fig. 6 - 7 ) . On the other hand, an earlier study demonstrated that it is possible to correct the calcium malabsorption in elderly postmenopausal women with 1,25(OH)2D3 therapy, provided that the treatment is continued long enough, 229 perhaps allowing for up-regulation of VDR. 152 Although the clinical evidence of a menopause-induced intestinal resistance cannot be considered conclusive, this hypothesis has been borne out of in vitro studies demonstrating a reduced number of intestinal vitamin D receptors after ovariectomy, 45'242 in addition to a decreased production of calbindin-D, and a reduced capacity of the basolateral membranes to actively accumulate c a l c i u m . 243'244 As in the case of aging, the hypotheses of an end-organ resistance and a deficient production of 1,25(OH)2D3 may coexist in postmenopausal women. The recent description of an association between osteoporosis and a certain VDR haplotype 9~in theory would provide a pathogenetic basis for a decreased endogenous responsiveness to vitamin D in postmenopausal women with osteoporosis. If different VDR alleles produce receptors with different functional activities, then a heterogeneity in calcium absorption efficiency could be expected in women, according to their VDR haplotype. A recent study seems to partially support this hypothesis, since fractional calcium absorption was found to be lower in women with a VDR genotype associated with low bone density. 245 However, such a difference was evident only at very low calcium intakes, 245 and the association between VDR allele distribution and osteoporosis is far from being universally accepted. c. Corticosteroid Excess Glucocorticoids are among the most commonly prescribed drugs, and unfortunately

CHAPTER 6 Pathophysiology of Calcium, Phosphate, and Magnesium Absorption

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800 mg/day) is seldom seen as a spontaneous occurrence. Additional magnesium may be provided by laxatives containing magnesium hydroxide or citrate salts, although hypermagnesemia may occur only when significant impairment of kidney function is associated. Accordingly, magnesium-based laxatives should not be given to renal failure patients. Patients with primary hyperparathyroidism have elevated serum magnesium and 1,25(OH)2D and increased urinary magnesium excretion after oral load compared to normal individuals. 362 Because fasting serum magnesium is not altered in these patients while their urinary magnesium is high, it seems reasonable to assume that the hypermagnesuria in primary hyperparathyroidism is in part related to an increased intestinal magnesium absorption. Although the mechanism of this increased absorption is not totally clear, the increased 1,25(OH)2D3 may provide a pathogenetic explanation. On the other hand, magnesium absorption is normal in patients with absorptive hypercalciuria, whose primary pathophysiological abnormality is an inappropriately high intestinal calcium absorption (see Section I.B.3). This observation further underlines the notion that calcium and magnesium absorption are mediated and regulated by different physiological pathways.

193

An increased intestinal absorption has also been advocated to explain the increased urinary excretion of magnesium occurring in normal subjects during very low dietary calcium (200 mg/day) regimens, as compared to individuals who consume high-calcium diets (1900 mg/ day). The increased 1,25(OH)2D3 driven by the secondary hyperparathyroidism of calcium deficiency may account for this phenomenon. 362 Dairy products are a very good source of calcium, phosphate, and magnesium, not only because of the substantial amount of these elements contained in milkderived food products but also because of the presence of lactose. When lactose or other nonabsorbable carbohydrates, such as fructo-oligosaccharides, are fermented by either intestinal lactase or the bacteria of the colonic flora, luminal pH becomes acidic, which favors magnesium solubilization. Addition of lactose to a highmagnesium diet increases apparent absorption by 17%, thus promoting more magnesium retention. 377 Likewise, fractional magnesium absorption can increase up to almost 80% in rats fed with fructo-oligosaccharides. 378Because water absorption does not change while colonic pH decreases as magnesium absorption increases, coIonic acidification is responsible for the magnesium hyperabsorption, rather than solvent drag. 379 A similar effect can be obtained with other saccharides resistant to digestion. However, this property is lost with food processing through heating and cooling, the so-called "retrograde process." It is believed that retrograded food is nonfermentable, so it cannot contribute to colonic acidification, and consequently it does not provide the additional beneficial effect on mineral absorption. 38~The monosaccharide fructose does not share the same positive action on magnesium absorption with disaccharides. Rats fed with fructose absorb more magnesium than rats fed with glucose. However, because those in the high-fructose group also excrete higher amounts of magnesium by the kidney, the result is actually a negative magnesium balance, despite the enhanced intestinal absorption. TM

D. D e c r e a s e d M a g n e s i u m A b s o r p t i v e States 1. DIETARY DEFICIENCY Because magnesium absorption is strictly dependent on the luminal concentration of the element, any chronic dietary restriction or deficiency results in reduced absorption. However, given the widespread presence of magnesium in most food products, such an occurrence is rare. Hypomagnesemia is not uncommon in hospitalized patients, 376 in whom many factors may contribute to magnesium loss, including acidosis, continuous use of diuretics, intravenous administration of sodium-

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ROBERTO CIVITELLI, KONSTANTINOSZIAMBARAS,AND RATTANALEELAWATTANA

containing fluid, and drugs that increase magnesuria. Whether nutritional deficiency and magnesium hypoabsorption participate in the mechanism leading to hypomagnesemia remains to be determined. 2. INTESTINAL DISEASES

Primary intestinal diseases associated with decreased transit time (stomach resection, chronic diarrhea), or loss of absorptive surface (short bowel syndrome), or with insufficient bile secretion (biliary fistula or atresia) can cause a magnesium deficit. It is questionable whether the vitamin D deficiency that develops in hepatobiliary disorders as a consequence of fat malabsorption has any contribution to the decreased magnesium absorption, which is largely a vitamin D-independent process. Abuse of laxatives may also cause hypomagnesemia secondary to decreased transit time. This possibility should be considered in lactating women. As a consequence of the mother's magnesium deficiency, the milk is poor in magnesium content and hypomagnesemia may develop in the infant, with deleterious consequences. 382 3. VITAMIN D DEFICIENCY a. Chronic Renal Failure

Patients with chronic renal failure often have high serum magnesium levels because of the inability to eliminate the element through the kidney. However, intestinal magnesium absorption in these subjects is reduced to less than 20% of dietary magnesium, as compared to the normal 40% to 50% fractional absorption. Although the precise mechanism that causes this relative magnesium hypoabsorption is still unknown, this phenomenon may represent an adaptive reaction to the severe hypermagnesemia, which may be related to the lower serum 1,25(OH)2D3 levels. b. Hypoparathyroidism and Pseudohypoparathyroidism A similar mechanism can be considered to explain

the hypomagnesemia that complicates hypoparathyroidism and pseudohypoparathyroidism. Intestinal magnesium absorption is reduced in these patients, whose serum 1,25(OH)2D3 levels are also lower. 362 Typically, the absorptive disorder of magnesium corrects after therapy with 1,25(OH)2D3 or other vitamin D metabolites. 362 4. INTRINSIC DEFECTS OF INTESTINAL MAGNESIUM ABSORPTION a. Primary Hypomagnesemia Primary hypomagnesemia is a rare genetic disease transmitted by autosomal recessive trait that causes hypomagnesemia in infants. The affected babies present with convulsions, hypocalcemia, and hypomagnesemia between 9 days and 4 months of age. Males are affected more frequently than

females. 382 The primary defect is an intestinal magnesium hypoabsorption caused by a defective active transport. If dietary magnesium is increased early, and serum magnesium levels are maintained within an acceptable range, the prognosis for these patients is relatively good. 383 b. Diabetes Mellitus In patients with diabetes mellitus, magnesium deficiency may decrease peripheral sensitivity to insulin, and thus worsen diabetic vasculopathy. 384 The mechanism for hypomagnesemia in diabetes is probably related to increased urinary magnesium loss, which occurs in poorly controlled disease. 384-386 Experiments in untreated insulin-dependent diabetic rats suggest that total magnesium absorption is not significantly decreased. However, because bowel weight is increased, the efficiency of magnesium absorption per gram of intestine is in fact decreased. 38v The mechanism of this phenomenon is still unknown, but it occurs early after rats develop insulin-dependent diabetes mellitus. Owing to the relative hypoabsorption and the dietary restrictions of grains and nuts, patients with diabetes should be considered at high risk of developing magnesium deficiency, especially when their metabolic abnormality is poorly controlled. 385 5. EXTRINSIC FACTORS THAT INHIBIT MAGNESIUM ABSORPTION

A number of dietary constituents may interfere with magnesium and decrease its absorption by reducing its bioavailability at sites of absorption. a. Cations Some cations can decrease the bioavailability of dietary magnesium via mechanisms that are not totally clear. Zinc interferes with magnesium absorption, as well as with phosphate absorption. In normal adult males, diets with high zinc content (142 mg/day) can decrease magnesium absorption by more than 10%, resulting in negative body magnesium balance, if dietary magnesium is low. 388 The mechanism of this inhibitory effect is uncertain. Competition of zinc and magnesium for the same absorptive sites along the intestine has been considered. Studies in animals also suggest that potassium may interfere with magnesium absorption. Lambs fed high-potassium diets (4.8% total potassium content in the diet) is associated with a 20% decrease of magnesium absorption. 389 However, there is no evidence of such a finding in humans. The evidence that dietary calcium can interfere with magnesium absorption is tenuous at best. Although rats fed high-calcium diet (five times the standard diet content) absorb significantly less magnesium than rats fed regular calcium, 39~such observation has not been reproduced in humans. Furthermore, increasing dietary calcium to 2000 mg/day does not affect

CHAPTER 6

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Pathophysiology of Calcium, Phosphate, and Magnesium Absorption

m a g n e s i u m absorption in either normal individuals, 361'362 or in patients with chronic renal failure. 361'391 Aluminum can slightly diminish m a g n e s i u m absorption. The presence of 2000 p p m a l u m i n u m in drinking water decreases m a g n e s i u m absorption by almost 10% in w e t h e r s . 346 This interference with m a g n e s i u m is evident only in early phases of a l u m i n u m administration (5 days), and after prolonged exposure of a l u m i n u m this effect is lost. The m e c h a n i s m by which a l u m i n u m alters m a g n e s i u m absorption is unknown. A l u m i n u m does not decrease magnesium bioavailability, but it can interfere with the absorption of fat-soluble vitamins. 392 Thus, a transient vitamin D deficiency can theoretically account for the decrease in m a g n e s i u m absorption.

b. Anions Of more concern for the possible development of m a g n e s i u m deficiency is the interference of m a g n e s i u m with anions, and in particular phosphate and oxalate. As it occurs for calcium, insoluble m a g n e s i u m phosphate or oxalate salts can form in the intestinal lumen, thus preventing the absorption of either ion. This possibility is exemplified by the special milk formulas that are used to feed very-low-birth-weight babies. These formulas contain high amounts of phosphate, and are given under the assumption that the high phosphate content may facilitate the skeletal d e v e l o p m e n t of these babies. 393 Unfortunately, when phosphate is increased to a calcium/phosphate ratio lower than 2:1, fractional intestinal m a g n e s i u m absorption decreases. 393 Thus, the possibility of h y p o m a g n e s e m i a should be considered in small babies when using formulas with high phosphate content. Although green leaf vegetables are an important source of magnesium, its absorbability is reduced by the presence of oxalic acid in some vegetables, such as spinach. Food processing can also modify the bioavailability of magnesium. For example, raw spinach has a poorer m a g n e s i u m bioavailability c o m p a r e d to boiled or fried spinach; however, raw spinach can still efficiently correct m a g n e s i u m deficiency in r a t s . T M Notably, the same considerations do not apply to calcium, for boiling or frying does not improve spinach calcium bioavailability. T M Phytate contained in m a n y vegetables negatively affects m a g n e s i u m absorption, as it does with calcium. Studies in rats would suggest that phytate can also increase intestinal loss of endogenous magnesium. 395 As noted for calcium, soybeans contain large amounts of phytate, which inhibits the absorption of cations, thus making diets based exclusively on soybeans inadequate to provide the daily requirements of minerals. A similar caution can be extended to infants fed with extruded food formula, in which phytase is destroyed by the extrusion process, and consequently m a g n e s i u m and calcium absorption is decreased by interaction with the remaining intact phytate. 35~

c. Other Other food products or additives that can theoretically interfere with mineral absorption have proven not to alter m a g n e s i u m homeostasis. A m o n g these, alginate, which interferes with iron absorption, does not inhibit either calcium or m a g n e s i u m absorption. T M Likewise, a high dietary meat content does not alter m a g n e s i u m absorption, despite the high amount of zinc contained in m e a t . 332 Although subjects who abuse alcohol are prone to h y p o m a g n e s e m i a and m a g n e s i u m deficiency, the cause of the deficiency is a combination of low m a g n e s i u m intake, pancreatic diseases, vitamin D deficit, vomiting, and urinary losses. Intestinal magnesium absorption is not impaired in these individuals. 396

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325. Gafter U, Edelstein SL, Hirsh J, Levi J: Metabolic acidosis enhances 1,25(OH)2D3-induced intestinal absorption of calcium and phosphorus in rats. Miner Electrolyte Metab 12:213-217, 1986. 326. Yeh JK, Aloia JF: Effect of glucocorticoids on the passive transport of phosphate in the different segments of the intestine in the rat. Bone Miner 2:11-19, 1987. 327. Yeh JK, Aloia JF, Semla HM: Interaction of cortisone and 1,25 dihydroxycholecalciferol on the intestinal calcium and phosphate absorption. Calcif Tissue Int 36:608-614, 1984. 328. Schroder B, Pfeffer E, Failing K, Breves G: Binding properties of goat intestinal vitamin D receptors affected by dietary calcium and/or phosphorus depletion. J Vet Med Assoc 42:411-417, 1995. 329. Armbrecht HJ: Age-related changes in calcium and phosphorus uptake by rat small intestine. Biochim Biophys Acta 882:281286, 1986. 330. McKane WR, Khosla S, Egan K, et al: Role of calcium intake in modulating age-related increases in parathyroid function and bone resorption. J Clin Endocrinol Metab 81:1699-1703, 1996. 331. Debiec H, Lorenc R: Influence of lactose on phosphate metabolism in rats. Br J Nutr 59:87-92, 1988. 332. Hunt JR, Gallagher SK, Johnson LK, Lykken GI: High- versus low-meat diets: Effect on zinc absorption, iron status and calcium, copper, iron, magnesium, manganese, nitrogen, phosphorus, and zinc balance in postmenopausal women. Am J Clin Nutr 62:621-632, 1995. 333. Rahnema S, Wu Z, Ohajuruka A, et al: Site of mineral absorption in lactating cows fed high-fat diets. J Anim Sci 72:229235, 1994. 334. Maier-Dobersberger T, Lochs H: Enteral supplementation of phosphate does not prevent hypophosphatemia during refeeding of cachectic patients. J Parenter Enter Nutr 18:182-184, 1994. 335. Agus ZS, Goldfarb S, Wasserman A: Disorders of calcium and phosphorus balance. In Brenner BM, Rector FC (eds): The Kidney. Philadelphia, WB Saunders Co, 1981, pp 940-1022. 336. Cai Q, Hodgson SF, Kao PC, et al: Inhibition of renal phosphate transport by a tumor product in a patient with oncogenic osteomalacia. N Engl J Med 330:1645-1649, 1994. 337. Brault BA, Meyer MH, Meyer RA: Malabsorption of phosphate by the intestine of young X-linked hypophosphatemic mice. Calcif Tissue Int 43:289-293, 1988. 338. Glorieux FH, Morin CL, Travers R, et al: Intestinal phosphate transport in familial hypophosphatemic rickets. Pediatr Res 10: 6 9 1 -6 9 6 , 1976. 339. Wilkins GE, Granleese S, Hegele RG, et al: Oncogenic osteomalacia: Evidence for a humoral phosphaturic factor. J Clin Endocrinol Metab 80:1628-1634, 1995. 340. Econs M J, Drezner MK: Tumor-induced osteomalacianunveil ing a new hormone. N Engl J Med 330:1679-1681, 1994. 341. Aschinberg LC, Solomon LM, Zeis PM, et al: Vitamin D-resistant rickets associated with epidermal nevus syndrome: Demonstration of a phosphaturic substance in the dermal lesion. J Pediatr 91:56-60, 1977. 342. Fraser D, Kooh SW, Kind HP: Pathogenesis of hereditary vitamin D dependent rickets. N Engl J Med 289:817-821, 1973. 343. Armbrecht HJ: Effect of age on calcium and phosphate absorption role of 1,25- dihydroxyvitamin D. Miner Electrolyte Metab 16:159-166, 1990. 344. Adler AJ, Fillipone EJ, Berlyne GM: Effect of chronic alcohol intake on muscle composition and metabolic balance of calcium and phosphate in rats. Am J Physiol 249:E584-E588, 1979. 345. Ghishan FK, Arab N, Shibata H: Intestinal phosphate transport in spontaneous hypertensive rats and genetically match controls. Gastroenterology 99:106-112, 1990.

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346. Allen VG, Fontenot JP, Rahmena SH: Influence of aluminum citrate and citric acid on mineral metabolism in wether sheep. J Anim Sci 68:2496-2505, 1990. 347. O'Donovan R, Baldwin D, Hammer M, et al: Substitution of aluminum salts by magnesium salts in control of dialysis hyperphosphatemia. Lancet 1:880-881, 1986. 348. Parsons V, Baldwin D, Moniz C, et al: Successful control of hyperparathyroidism in patients on continuous ambulatory peritoneal dialysis using magnesium carbonate and calcium carbonate as phosphate binders. Nephron 63:379-383, 1993. 349. Schwarz KB, Zimmerman DC, Alpers DH, Avioli LV: Gender differences in antacid-induced phosphate deprivation in rats. Gastroenterology 89:313- 320, 1985. 350. Kivisto B, Andersson H, Cederblad G, et al: Extrusion cooking of a high-fiber cereal product 2. Effects on apparent absorption of zinc, iron, calcium, magnesium, and phosphorus in humans. Br J Nutr 55:255-260, 1986. 351. Roubaty C, Portmann P: Relation between intestinal alkaline phosphatase activity and brush border membrane transport of inorganic phosphate, D-glucose, and D-glucose-6-phosphate. Pflugers Arch 412:482-490, 1988. 352. Borowitz SM, Granrud GS: Glucocorticoids inhibit intestinal phosphate absorption in developing rabbits. J Nutr 122:12731279, 1992. 353. Schwartz R, Spencer H, Welsh JJ: Magnesium absorption in human subjects from leafy vegetables intrinsically labeled with stable 26Mg. Am J Clin Nutr 39:571-576, 1984. 354. Schwartz R, Spencer H, Wentworth RA: Measurement of magnesium absorption in man using stable 26Mg as a tracer. Clin Chim Acta 87:265-273, 1978. 355. Harris I, Wilkinson AW: Magnesium depletion in children. Lancet 2:735-736, 1971. 356. Fine KD, Santa Ana CA, Porter J, Fordtran JS: Intestinal absorption of magnesium from food and supplements. J Clin Invest 88:396-402, 1991. 357. Kayne LH, Lee DBN: Intestinal magnesium absorption. Miner Electrolyte Metab 19:210- 217, 1993. 358. Hardwick LL, Jones MR, Brautbar N, Lee DBN: Site and mechanism of intestinal magnesium absorption. Miner Electrolyte Metab 16:174-180, 1990. 359. Hardwick LL, Jones MR, Brautbar N, Lee DBN: Magnesium absorption: Mechanisms and the influence of vitamin D, calcium and phosphate. J Nutr 121:13- 23, 1991. 360. Behar J: Magnesium absorption by the rat ileum and colon. Am J Physiol 227:334-340, 1974. 361. Brannan PG, Vergne-Marini P, Pak CYC: Magnesium absorption in the human small intestine. Results in normal subjects, patients with chronic renal disease and patients with absorptive hypercalciuria. J Clin Invest 57:1412-1418, 1976. 362. Nicar MJ, Pak CYC: Oral magnesium load test for the assessment of intestinal magnesium absorption. Miner Electrolyte Metab 8:44-51, 1982. 363. Hodgkinson A, Marshall DH, Nordin BEC: Vitamin D and magnesium absorption in man. Clin Sci 57:121-123, 1979. 364. Wilz DR, Gary RW, Dominguez JH: Plasma 1,25(OH)2-vitamin D concentrations and net intestinal calcium, phosphate, and magnesium absorption in humans. Am J Clin Nutr 32:20522060, 1979. 365. Pointillart A, Denis I, Colin C: Effects of dietary vitamin D on magnesium absorption and bone mineral contents in pigs on normal magnesium intakes. Magnes Res 8:19-25, 1995. 366. Leicht E, Biro G: Mechanisms of hypocalcaemia in the clinical form of severe magnesium deficit in the human. Magnes Res 5: 37-44, 1992.

367. Rude RK, Oldham SB, Singer FR: Functional hypoparathyroidism and parathyroid hormone end-organ resistance in human magnesium deficiency. Clin Endocrinol 5:209-224, 1976. 368. Northup JK, Smigel MD, Gilman AG: The guanine nucleotide activating site of the regulatory component of adenylate cyclase: Identification by ligand binding. J Biol Chem 257:1141611423, 1982. 369. Litosh I: G protein regulation of phospholipase C activity in a membrane-solubilized system occurs through a Mg 2+- and timedependent mechanism. J Biol Chem 266:4764-4771, 1991. 370. Volpe P, Alderson-Lang BH, Niklols GA: Regulation of inositol 1,4,5-triphosphate-induced Ca 2§ release. I. Effect of magnesium. Am J Physiol 258:C1077-C1085, 1990. 371. Fujimori A, Cheng S, Avioli LV, Civitelli R: Dissociation of second messenger activation by parathyroid hormone fragments in osteosarcoma cells. Endocrinology 128:3032-3039, 1991. 372. Fujimori A, Cheng S, Avioli LV, Civitelli R: Structure-function relationship of parathyroid hormone: Activation of phospholipase C, protein kinase A and C in osteosarcoma cells. Endocrinology 130:29- 36, 1992. 373. Risco F, Traba ML, De La Piedra C: Possible alterations of the in vivo 1,25(OH)ED3 synthesis and its tissue distribution in magnesium-deficient rats. Magnes Res 8:27-35, 1995. 374. Ferment O, Gamier PE, Touitou Y: Comparison of the feed-back effect of magnesium and calcium on parathyroid hormone secretion in man. J Endocrinol 113:117-122, 1987. 375. Wallace J, Scarpa A: Regulation of parathyroid hormone secretion in vitro by divalent cations and cellular metabolism. J Biol Chem 257:10613-10616, 1982. 376. Abbot LG, Rude RK: Clinical manifestations of magnesium deficiency. Miner Electrolyte Metab 19:314-322, 1993. 377. Greger JL, Gutkowski CM, Khazen RR: Interactions of lactose with calcium, magnesium and zinc in rats. J Nutr 119:16911997, 1989. 378. Ohta A, Ohtsuki M, Baba S, et al: Effects of fructooligosaccharides on the absorption of iron, calcium, and magnesium in iron-deficient anemic rats. J Nutr Sci Vitaminol 41:281-291, 1995. 379. Ohta A, Ohtsuki M, Baba S, et al: Calcium and magnesium absorption from the colon and rectum are increased in rats fed fructooligosaccharides. J Nutr 125:2417-2424, 1995. 380. Schulz AGM, Van Amelsvoort JMM, Beynen AC: Dietary native resistant starch but not retrograded resistant starch raises magnesium and calcium absorption in rats. J Nutr 123:17241731, 1993. 381. Van der Heijden A, Van den Berg GJ, Lemmens AG, Beynen AC: Dietary fructose v. glucose in rats raises urinary excretion, true absorption and ileal solubility of magnesium but decreases magnesium retention. Br J Nutr 72:567-577, 1994. 382. Geven WB, Monnens LAH, Willems JL: Magnesium metabolism in childhood. Miner Electrolyte Metab 19:308-313, 1993. 383. Milla PJ, Agget PJ, Wolff OH, et al: Studies in primary hypomagnesaemia: Evidence for defective carrier-mediated small intestinal transport of magnesium. Gut 20:1028-1033, 1979. 384. White JR, Campbell RK: Magnesium and diabetes. Ann Pharmacother 27:775-780, 1993. 385. Campbell RK, Nadler JL: Implications of Magnesium Deficiency in Diabetes. Bimark, New Jersey, 1993, pp 2 - 2 5 . 386. Whang R, Hampton EM, Whang DD: Magnesium homeostasis and clinical disorders of magnesium deficiency. Ann Pharmacother 28:220-226, 1994. 387. Miller LD, Schedl HP: Effects of diabetes on intestinal magnesium absorption in the rat. Am J Physiol 231:1039-1042, 1976.

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388. Spencer H, Norris C, Williams D: Inhibitory effects of zinc on magnesium balance and magnesium absorption in man. J Am Coil Nutr 13:479-484, 1994. 389. Green LW, Fontenot JP, Webb KE: Effect of dietary potassium on absorption of magnesium and other macroelements in sheep fed different levels of magnesium. J Anim Sci 56:1208-1213, 1983. 390. Kaup SM, Behling AR, Choquette L, Greger JL: Calcium and magnesium utilization in rats: Effect of dietary butter fat and calcium and of age. J Nutr 120:266-273, 1990. 391. Spencer H, Lesniak M, Gatza CA, et al: Magnesium absorption and metabolism in patients with chronic renal failure and in patients with normal renal function. Gastroenterology 79:2634, 1980. 392. Harvey SC: Gastric antacids, miscellaneous drugs for treatment of peptic ulcer, digestants and bile acids. In Goodman Gilman A, Goodman LS, Rail TW (eds): The Pharmacological Basis of

393.

394.

395.

396.

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Therapeutics. New York, Macmillan Publishing, 1985, pp 980993. Rodder SG, Mize CE, Forman LP, Uauy R: Effects of increased dietary phosphorus on magnesium balance in very low birthweight babies. Magnes Res 5:273-275, 1992. Kikunaga S, Ishii H, Takahashi M: The bioavailability of magnesium in spinach and the effect of oxalic acid on magnesium utilization examined in diets of magnesium-deficient rats. J Nutr Sci Vitaminol 41:671-685, 1995. Brink EJ, Van den Berg J, Van der Meer JM, et al: Inhibitory effect of soybean protein vs. casein on apparent absorption of magnesium in rats is due to greater excretion of endogenous magnesium. J Nutr 122:1910-1916, 1992. Rivlin RS: Magnesium deficiency and alcohol intake: Mechanisms, clinical significance and possible relation to cancer development. J Am Coil Nutr 13:416-423, 1994.


~HAPTER

,

Disorders of Phosphate Homeostasis KEITH HRUSKA A N D

ANANDARUP

GUPTA

Renal Division, Washington University School of Medicine, St. Louis, Missouri 63110

C. Differential Diagnosis of Hypophosphatemia D. Treatment of Hypophosphatemia III. Hyperphosphatemia A. Causes of Hyperphosphatemia B. Clinical Manifestations of Hyperphosphatemia C. Treatment of Hyperphosphatemia References

I. Phosphate Homeostasis A. Gastrointestinal Absorption of Phosphorus B. Renal Reabsorption of Phosphorus C. Bone Remodeling and Phosphate Transport II. Hypophosphatemia A. Causes B. Clinical and Biochemical Manifestations of Hypophosphatemia

many cellular reactions including biosynthesis derives from hydrolysis of adenosine triphosphate (ATP). Organic phosphate is an important component of phospholipids in cell membranes. Its concentration influences the activity of several metabolic pathways such as ammoniagenesis, glycolysis, gluconeogenesis, and the formation of 1,25-dihydroxyvitamin D3 [1,25(OH)zD3] from 25-hydroxyvitamin D3 [25(OH)D3]. Changes in serum phosphorus may also influence the dissociation of oxygen from hemoglobin through its regulation of the concentrations of 2,3-diphosphoglycerate (2,3-DPG).

I. PHOSPHATE HOMEOSTASIS The physiological concentration of serum phosphorus ranges from 2.8 to 4.5 mg/dl (0.9 to 1.45 mM) in adults. 1 There is a diurnal variation in serum phosphorus of 0.6 to 1.0 mg/dl the nadir occurring between 8 AM and 11 AM. Ingestion of meals rich in carbohydrate decreases serum phosphorus concentrations as a result of movement of phosphorus from the extracellular to the intracellular space. In the extracellular fluid, phosphorus is present predominantly in the inorganic form. In serum, phosphorus exists mainly as the free ion, and only a small fraction ( 50%), and contributes significantly to spinal bone mass measurements. 5

C. Comparison of Common Fracture Locations and Bone Measurement Sites There are several clinically established methods used for noninvasive bone assessment. Some of them are performed at typical fracture sites like the forearm [single x-ray absorptiometry and peripheral quantitative computed tomography (CT)], the spine (dual x-ray absorptiometry and quantitative CT), and the hip (dual x-ray absorptiometry). Other techniques are applied at remote

Bone densitometry has gained wide acceptance. Since different techniques have been developed and are clinically available, a variety of abbreviations exist. For example, the acronym DXA has been proposed and widely accepted for dual x-ray absorptiometry. 6 Still, different abbreviations (DEXA, DER, DRA, QDR, and DPX) are being used and therefore contribute to some confusion. There is general agreement that standard abbreviations for bone densitometry are necessary. Manufacturers and users in clinic and research have joined efforts in an International Standard Committee. 7 The following proposal for terminology reflects the development in bone densitometry and will be understood by both clinicians and researchers: DXA for dual x-ray absorptiometry, DPA for dual-photon absorptiometry, SXA for single xray absorptiometry, SPA for single photon absorptiometry, QCT for quantitative computed tomography, and pQCT for peripheral quantitative computed tomography. For newer techniques like ultrasound attenuation, ultrasound velocity, and magnetic resonance measurements appropriate acronyms still have to be agreed upon. QUS for quantitative ultrasound and QMR for quantitative magnetic resonance would be consistent with QCT and will be used here. However, these abbreviations need consensus development. 8

E. Principal Bone Measurement Techniques and Their History Numerous methods for the assessment of bone mineral density (BMD) have been developed during the last three decades. Some of their preceding techniques and principles reach back even to the 1930s. Radiation-based techniques like single photon absorptiometry, dual x-ray absorptiometry, and quantitative computed tomography have become standard methods with widespread use and acceptance in both clinical and research application. During the last few years, several new non-radiationbased methods have been applied for assessment of both bone density and structure. Promising results have been

CHAPTER9 NoninvasiveAssessment of Bone obtained, especially for ultrasound and magnetic resonance techniques. QUS, which in principle was introduced for bone assessment in the 1960s, has emerged as a promising option for the assessment of bone properties in recent years. New developments in hardware and software have considerably enhanced precision and improved clinical feasibility. However, the suitability of ultrasound methods for routine application has not yet been established. The newest modality for noninvasive bone assessment--quantitative magnetic resonance--is still in an early state of development. Similar to ultrasound, it combines the advantages of being a nonionizing-radiation technique and potentially providing structural information about bone. A brief survey of the various major techniques and their history is listed in Figure 9 - 1 .

II. RADIATION-BASED ASSESSMENT OF BONE

A. Appearance of Bone Loss in Conventional Radiographs Since the first days of roentgenology, osteoporotic fractures have been depicted; therefore conventional radiography is the oldest approach for assessing bone mineralization. As early as 1936 Lachmann and Whelan stated that only under very favorable radiographic conditions could decalcification of less than 20% be recognized. 9 These and other authors assumed that the loss in bone density must be as much as 20% to 40% before it can be detected on lateral radiographs of the thoracic and lumbar spine. 1~ Criteria such as increased radiolucency, reduction of cortical thickness, accentuation of vertebral end plates, and loss of horizontal trabeculae combined with the prominence of vertical trabeculae are generally regarded as signs of spinal osteopenia. However, Doyle et al. found none of these criteria to be reliable in assessing longitudinal changes in bone density in the course of osteoporosis, ll Besides its subjective character and its dependence on the reader, this method is influenced by many technical factors such as x-ray equipment, exposure settings, soft tissue thickness, film/ screen combination and film processing. In an attempt to classify radiographic manifestations of spinal osteopenia without the presence of fractures, Saville 12 introduced a score from 0 to 4. This index, however, has never gained widespread acceptance due to subjectivity and dependence on the experience of the observer. Therefore, efforts to detect bone mineral loss radiographically have been replaced by absorptiometric density measurements.

277

B. Radiographic Morphometry 1. VERTEBRAL BODY DEFORMITY Since the morbid event in osteoporosis is fracture, and the most common ones are vertebral fractures, they have been described as hallmarks of osteoporosis (e.g., one classical definition requires the presence of nontraumatic spinal compression fractures before the diagnosis can be made13). The assessment of vertebral fractures from spinal radiographs plays an important role in clinical practice. The same applies to radiography in the context of epidemiological studies or pharmaceutical trials, where osteoporotic fractures of the spine are a primary end point. Various efforts have been made to define objective, reliable, and reproducible methods to assess vertebral deformity as a measure of osteoporosis. The numerous methods can basically be divided into quantitative and semiquantitative assessment, although some of them have features from both approaches.

a. Quantitative Approach. One of the first studies using measurements of vertebral dimensions on lateral spine radiographs was described by Barnett and Nordin. TM They introduced an index that compares the anterior and midvertebral height in order to quantify vertebral biconcavity. Several quantitative morphometric approaches based on those vertebral height measurements have been developed, increasingly sophisticated with up to ten marker points placed on a vertebral body. 15-23 The methods employed have often been compared within the same population to examine the impact of methodology on assessment of vertebral fracture in both individual patients and individual vertebrae. Considerable differences in fracture sensitivity and specificity have been found by different a u t h o r s . 17'24-26 The intermethodology correlation has been only modest with two- to four-fold differences in the estimation of prevalent fractures. Unfortunately, there is no true "gold standard" for vertebral fractures and therefore the different methods or cutoff criteria cannot be judged independently. Despite having well-defined, objective tools, quantitative morphometry brings up several problems that may explain the difficulties in reliably distinguishing between osteoporotic fractures and other nonfracture deformities. For example, poor positioning, obesity, and spinal abnormalities like scoliosis and osteoarthritis result in magnified or distorted vertebral projection, which lowers the precision of measurement. Another problem is to define normal vertebral dimensions, since osteoporosis-related deformities in the spine are accompanied by degenera-

278

MARTIN UFFMANN, THOMAS P. FUERST, MICHAEL JERGAS, AND HARRY K. GENANT

FIGURE 9-- 1

Noninvasive methods for assessment of bone and preceding techniques.

tive changes with a broad overlap in vertebral measurement parameters. Nevertheless quantitative morphometry plays an important role in epidemiological studies and in clinical drug studies, particularly for long-term changes in follow-up examinations.

b. Semiquantitative Approach. Semiquantitative assessment of vertebral deformities means grading of vertebrae into a few categories based on visual determination only (Fig. 9-2). The reading includes alterations of vertebral heights as well as its shape relative to adjacent vertebrae and expected normal appearance. These criteria add a strong qualitative aspect to the interpretation. Therefore, an experienced reader is able to compensate for conditions that would lead to misclassification in quantitative analysis. In several studies semiquantitative assessment of vertebral fractures has rendered excellent intra- and interobserver reproducibility. 27'28

2. TRABECULAR PATTERN OF THE FEMUR Another approach to semiquantitative grading of osteopenic bone on radiographs has been described by Singh et al. 29 They developed a femoral trabecular index based on previous findings about altered trabecular patterns of the proximal femur in women with hip fracture. 3~ The radiographic appearance of the hip can be classified into six grades according to the distribution, thickness, and spacing of the compressive and tensile trabeculae assuming that during the process of bone loss the deterioration of trabeculae follows a distinct sequence (Fig. 9-3). The Singh index has been applied in a number of studies revealing varying associations with bone mass and fracture occurrence. A recent publication refused the hypothesis of organized loss of femoral trabeculae and instead indicated a generalized loss of bone. 31 The quantitative methods such as SPA, SXA, DPA, and DXA have changed the status of conventional ra-

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279

FIGURE 9 - 3 The Singh index is based on the assumption that the trabeculae in the proximal femur disappear in a predictable sequence depending on their original thickness. The classification ranges from grade VI (normal, all trabecular groups visible) to grade I (marked reduction of even the principal compressive trabeculae) according to the degree of bone loss. (Modified from Singh YM, Nagrath AR, Maini PS: Changes in trabecular pattern of the upper end of the femur as an index of osteoporosis. J Bone Joint Surg 52-A: 457-467, 1970.)

FIGURE 9--2 Grading scheme for a semiquantitative evaluation of vertebral deformities. A, Grade 0, normal. B, Grade 1, mild deformity, 20% to 25% reduction of any vertebral height. C, Grade 2, moderate deformity, 25% to 40% reduction of any vertebral height. D, Grade 3, severe deformity, >40% reduction of any vertebral height. The drawings illustrate reductions of the anterior height that correspond to the grade of the deformity. Reductions of the middle or posterior vertebral height or combinations thereof can be evaluated using the same grading scheme. (Courtesy of Dr. C. Y. Wu.)

diography for the assessment of osteoporosis. Nevertheless, quantitative radiography remains useful for the detection of specific alterations in certain clinical cases (e.g., subperiosteal resorption in hyperparathyroidism). Although D X A equipment already offers some imaging capabilities, radiography is still the primary modality for skeletal imaging, having unequaled spatial resolution. For detection of complications of osteoporosis such as fractures as well as differential diagnosis of other metabolic bone diseases or bone tumors, conventional radiography remains indispensable.

tours cortical indices as well as cortical area can be derived, assuming a circular shape of the bone cross-section (Fig. 9 - 4 ) . Virtually every long bone can be assessed, although the most c o m m o n l y used sites are the metacarpals. Initially, the precision was relatively poor due to operator interaction. Technical modifications like semiautomation and electronic calipers have improved this technique considerably, with reported shortterm precision errors between 0.4% and 2.0% for the cortical index in 12ivo. 33 Even in the older studies, a remarkable age-related loss of cortical indices has been found. In postmenopausal w o m e n with estrogen substitution after o o p h o r e c t o m y the annual decrease of combined cortical thickness (outer minus inner cortical diameter) was considerably smaller compared to the 34 control group (0.5% vs. 1.45%, respectively). In several studies, r a d i o g r a m m e t r y has been found to be a good discriminator b e t w e e n postmenopausal w o m e n with and without vertebral 35'36 or hip fractures, 37 even though the relatively simple m e a s u r e m e n t of cortical bone d o e s n ' t estimate intracortical resorption and porosity. The information provided by this technique is more useful in clinical research than for individual patient m a n a g e m e n t .

C. Radiogrammetry

D. Radiographic Absorptiometry

R a d i o g r a m m e t r y was the first approach for assessing 14 32 cortical bone quantitatively. ' With simple measurements of the inner and outer diameter of the bone con-

Since the early days of radiography it has been known that the photographic density on a film is roughly proportional to the mass of bone the x-ray b e a m passes

280


FIGURE 9 - 4 Schematicrepresentation of a cross section of a tubular bone, showing several parameters determined by radiogrammetry. [From Steiner E, Jergas J, Genant HK: Radiology of osteoporosis. In Marcus R, Feldman D, Kelsey J (eds): Osteoporosis. San Diego, Academic Press, 1996, pp 1019-1054.]

through. Based on this observation radiographic absorptiometry (RA), or photodensitometry, was developed by different investigators. 38-4~ The underlying principle had already been described in 1939. 41 This technique makes possible bone mass measurements from radiographs of the peripheral skeleton, most commonly the metacarpal and phalangeal bones. The measurement procedure can be performed by any standard radiology department. It simply requires a reference wedge on the film and an appropriate exposure technique (Fig. 9 - 5 ) . The developed radiographs are sent to a central reading facility where the reference and relevant bone locations are evaluated using a photodensitometer. RA became relatively widely used as a research technique in the 1960s, although it has subsequently been superseded by photon absorptiometry and x-ray absorptiometry. More recently, with the advent of computerized image processing, RA has become more precise 42 and gained new respect for use in the diagnosis of osteoporosis. In addition, recent studies in which radiographic absorptiometry was used have demonstrated that the detection of accelerated bone loss in the early menopause with this technique is comparable to other densitometry techniques. 43-45 Being cost-effective, easy to perform, and universally available, all make radiographic absorptiometry an increasingly attractive option for noninvasive bone assessment in both research and clinical practice.

The decay of this radionuclide can be measured with a whole-body counter and the total body calcium can be derived. The radiation dose required is relatively high (< 2.5 mSv). Although having good precision (1.5% to 2%) and accuracy (5%), 48'49 this technique reflects primarily

E. C o m p t o n S c a t t e r i n g T e c h n i q u e / N e u t r o n Activation Analysis With neutron activation analysis the total body calcium can be estimated. This technique was developed in the 1960S. 46'47 The patient is exposed to a uniform beam of neutrons designed to irradiate the whole body. A small fraction (about 0.2%) of the total c a l c i u m m t h e isotope 4 8 C a n i s converted into 49Ca with a half-life of 8.8 min.

FIGURE 9--5 Radiographicabsorptiometry. The simultaneous exposure of an aluminum wedge on a hand radiograph allows for a reproducible determination of bone density with an appropriate exposure technique. [FromJergas M, Genant HK: Quantitativebone mineral analysis. In Resnick D (ed): Diagnosis of Bone and Joint Disorders, 3rd ed. Philadelphia, WB Saunders Co, 1995, pp 1854-1884.]

CHAPTER 9 NoninvasiveAssessment of Bone cortical bone and does not reveal a change confined to a small part of the skeleton. Also, it cannot distinguish between normal bone and heterotopic calcium. Nevertheless, neutron activation analysis was once considered the gold standard of bone mass measurements and may have some implications as a reference method for calibration of absorptiometric bone mass measurement systems. For instance, the manufacturer of DXA instruments relies on cross-calibration for updating new instruments and analysis software. This may be appropriate for longitudinal precision, but also can propagate accuracy errors into newer instrument generations. 49'5~ Compton scattering techniques have been employed for bone mass measurements since the early 1970s. 51'52 They provide density estimation of selected volumes of bone and utilize the quantitative information extracted from the scattered radiation, not from the primary beam transmitted through the bone target. For inducing Compton scattering a relatively high photon energy is necessary, usually generated from a monoenergetic isotope source. Details about the effective dose of Compton scattering have not been published yet. However, when applied to the peripheral skeleton for a small volume, the radiation dose should be small. The bone target to be measured is defined by the position of the highly collimated gamma ray source and a highly collimated detector. Their projected pathways intersect perpendicularly to each other within the object and therefore define the volume 56 (Fig. 9 - 6 ) . Measurements obtained with this technique reflect not only the density of mineral substance within the bone

281 but also include a composite of all medullary components. The detected scatter is proportional to the electron density, independent of the atomic number. For this reason one must be aware of marrow fat effects. The precision of the technique has been established as 2% to 5%. Because of their extreme technical requirements and relatively high radiation dose, both neutron activation analysis and Compton scattering technique are regarded as investigational techniques limited to research. For clinical practice they have been superseded by absorptiometric devices for bone assessment, which are much more applicable, cost-effective, and easy to perform.

F. Photon and X-ray Absorptiometry with One or Two Spectrum Technique 1. SINGLE PHOTON AND X-RAY ABSORPTIOMETRY

Absorptiometric bone measurement techniques were developed in the 1960s and have been modified and improved since then. In 1963 Cameron and Sorenson introduced SPA; they even mentioned the dual energy approach in their original report. 54 A highly collimated photon beam from a radionuclide source is used to measure radiation attenuation at the measurement site. If the attenuation coefficients of bone and soft tissue are known, then the measured attenuation can be converted to BMD or bone mineral content (BMC) by using a

FIGURE 9--6 Schematicrepresentation of the source and the scatter for Compton scatter densitometry. [From Jergas M, Genant HK: Quantitative bone mineral analysis. In Resnick D (ed): Diagnosis of Bone and Joint Disorders, 3rd ed. Philadelphia, WB Saunders Co, 1995, pp 1854-1884.]

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FIGURE 9--7

Soft tissue contributes critically to the measured absorption in SPA. The introduction of a water bath in which the measured body part is immersed corrects for the inconstant path length that is caused by the soft tissue, as illustrated by the intensity profiles at the bottom line of the figure. [From Jergas M, Genant HK: Quantitative bone mineral analysis. In Resnick D (ed): Diagnosis of Bone and Joint Disorders, 3rd ed. Philadelphia, WB Saunders Co, 1995, pp 1854-1884.]

known standard (Fig. 9-7). For optimal tissue and bone separation the photon energy should be under 70 keV; mostly 1251is used. For correct measurement the bone must be surrounded by soft tissue of constant thickness. This is normally achieved by immersing the limb in a water bath, surrounding the scanning site with a water bag or other tissue equivalent material, or by compressing the limb to constant thickness. Therefore, SPA is confined to the appendicular skeleton. Clinical instruments based on this principle were available during the 1970s and 1980s. The precision obtained with early devices was 3% to 5% and the accuracy was about 3%. 55 Replacing the radionuclide source by an x-ray tube in more recently developed devices (SXA) has improved precision considerably. Other advantages are reduced examination time and cost-effectiveness for these systems.

2. DUAL PHOTON AND X-RAY ABSORPTIOMETRY Single energy measurements are not possible at sites with variable soft tissue thickness and composition (i.e., the axial skeleton, hip, or whole body). For these purposes dual energy techniques are employed to correct for unknown path length in the body. The initial approach to dual energy absorptiometry, dual photon absorptiometry (DPA), uses a radionuclide source at two effective discrete energy levels. Radiation of distinct energies is attenuated by tissues to different extents. From the attenuation profiles of both a high- and a low-energy beam, an attenuation profile ideally reflecting the bony components may be calculated (Fig. 9-8). The radionuclide sources for early DPA densitometers consisted of radionuclide combinations to generate two distinct energy levels. The dual emitter 153Gd (44 and 100 keV)

CHAPTER 9 NoninvasiveAssessment of Bone

283

FIGURE 9--8

Principle of DPA and DXA. Radiation of distinct energies is attenuated by tissues to different extents. In both soft tissue and bone, a low-energy beam is attenuated to a greater degree than a high-energy beam. In bone, this attenuation occurs to a much greater extent than in soft tissue. By entering the attenuation profiles for a low- and high-energy beam into a mathematical equation system, an attenuation profile of the bony components may be calculated. [From Jergas M, Genant HK: Quantitative bone mineral analysis. In Resnick D (ed): Diagnosis of Bone and Joint Disorders, 3rd ed. Philadelphia, WB Saunders Co, 1995, pp 1854-1884.]

was introduced in the 1970s and became the standard radionuclide source for DPA. 56 A dual energy technique involving x-rays was first introduced by Krokowski and Schlungbaum, who took lateral x-rays of the lumbar spine at 62 and 250 kV and then calculated bone density from photometric measurements of the lumbar vertebrae and the adjacent soft tissue. 57 Dual x-ray absorptiometry (DXA), based on this principle and the method of x-ray spectrophotometry, was introduced commercially as the direct successor to DPA in 1987. 58-61 In DXA, the radionuclide source is replaced by an x-ray tube. Depending on the manufac-

turer, two distinct energy level beams are either generated by the x-ray generator or filtered from an x-ray spectrum. The main advantages of an x-ray system over a DPA radionuclide system are shortened examination time due to an increased photon flux of the x-ray tube and greater accuracy and precision due to higher resolution and the lack of radionuclide decay. 62 DXA has taken the place of DPA, thereby reaching great acceptance in clinical practice and research. The usual anatomical sites for DXA measurement of bone mineral include the lumbar spine, proximal femur, and whole body, but peripheral sites can also be scanned. The digital im-

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age resulting from the measurement allows a gross survey of the region examined (Fig. 9 - 9 ) . The software of all DXA devices allows one to identify regions of interest with distinct compositions of trabecular and cortical bone such as the femoral neck and Ward's triangle, and the ultradistal or the distal third of the radius. Fractured vertebrae may be excluded from analysis. The examination procedure at the lumbar spine with the initial devices took 6 to 15 minutes. Newly developed devices using enhanced generators or a fan beam instead of a pencil beam x-ray source make the process even faster, shortening the examination time to 2 minutes o r l e s s . 63 The in vivo precision of the posteroanterior (PA) DXA examination of the lumbar spine is 0.5% to 1.5% with

an accuracy error of 1% to 10%. 6 4 - 6 9 Due to osteophytes, aortic calcifications, degenerative facet hypertrophy, and intervertebral disk space narrowing in degenerative disk disease, the measured bone mineral density may be increased artificially in the PA measurement of the lumbar spine (an important drawback of this method, especially in elderly patients); furthermore, the area projectional measurement includes substantial portions of compact bone, thereby reducing discrimination between osteoporotic and nonosteoporotic s u b j e c t s . 7~ A lateral examination of the lumbar spine makes possible an evaluation of the vertebral b o d y - - w i t h almost exclusive measurement of the trabecular bone. Therefore, the correlation between lateral DXA and QCT, which measures

FIGURE 9--9 Lumbarspine (upper left), hip (upper right), whole body (lower left), and forearm (lower right) as they are depicted by DXA. These are the typical anatomical sites that are used for the application of DXA.

CHAPTER 9 NoninvasiveAssessment of Bone the vertebral body, has been found to be stronger than that of PA DXA and Q C T . TM This method can reduce the errors intrinsic in the PA examination of the lumbar spine. However, overlap of the iliac crest may substantially increase the measured bone density primarily at the level L4, and L2 is overlapped by ribs in almost all patients. Nevertheless, the inclusion of all vertebral levels L2 through L4 usually yields the best precision and diagnostic sensitivity. 75"76Beyond that, the reproducibility of the lateral DXA measurement is poorer due to greater thickness and nonuniformity of the soft tissue in the lateral projection. 75'77-8~ The adverse effect on reproducibility of measurements of the spine in lateral decubitus has been addressed with newer densitometers using a tube-detector system that can be rotated. This G arm allows for lateral spine scanning with the patient in the supine position, thereby reducing obliquity with pelvis and rib overlap and improving the in vivo reproducibility to a b o u t 2 % . 76,82 Several studies indicate that an age decrease is more pronounced in lateral B MD. Formica et al. recently reported that this greater decrease with age may be explained by the increased fat content in the soft tissue baseline region in elder women. 83 Lateral supine DXA is also more strongly associated with prevalent vertebral fractures than is standard PA B MD, indicating a potentially superior diagnostic sensitivity of this m e t h o d . 76,84-86

Dual x-ray absorptiometry is also employed for measurements at the appendicular skeleton. Most standard DXA densitometers allow for the highly precise measurement of the radius using regions of interest like those derived from SPA and SXA measurements and also userdefined subregions. 87'88 Recently, specially designed DXA densitometers exclusively for the forearm have been introduced that may provide these measurements at a lower cost. Measurements of the calcaneus using standard DXA scanners have been performed recently by several researchers, demonstrating the ability of DXA to measure bone density reliably at this site. 89-9~ Low radiation dose, availability, and ease of use have made DXA the most widely used technique for measurements of bone density in clinical trials and epidemiological s t u d i e s . 92'93 Different DXA densitometers of one manufacturer usually yield comparable results, which, depending on the scan mode and region scanned, are often within the precision error of the densitometer. 94-98 For densitometers of different manufacturers, however, the results may vary substantially due to differences in bone standards, edge-detection algorithms, and regions of interest. Under the auspices of an international DXA standardization committee including all leading manufacturers of DXA equipment, a standardized BMD (sBMD, given in milligrams per square centimeter) for measurements at the lumbar spine, based on

285 the excellent in vivo correlation among all densitometers at this site, has been proposed. 99 The standardized B MD provides compatibility of DXA results at the lumbar spine obtained on different scanners. To provide similar standardization at other sites, changes of the analysis software are required due to substantial differences in the regions of interest between the different manufacturers. Being a projectional technique, the measured bone density in DXA does not reflect a true volumetric density but rather an area density, calculated as the quotient of the B MC and the area. This normalization by the projected area partly reduces the effect of body size. However, it does not take the true volume (e.g., of a vertebra) into account. For a constant volumetric bone density, a larger vertebra would typically yield higher area BMD results than a smaller one. Several volumetric estimates of bone density derived from either PA DXA or both PA and lateral DXA of the lumbar spine have been proposed. 84'1~176176 Volumetric estimates of bone density from paired PA and lateral measurements may be more strongly associated with prevalent vertebral fractures than the standard DXA measurements. 1~ A volumetric estimate of femoral neck bone density, bone mineral apparent density (BMAD), did not improve the predictive value of standard BMD measurements for future hip fractures in the context of a large epidemiological study. 1~ Further studies are required to confirm these early results and to establish the role of volumetric estimates of projectional bone density. Due to the high resolution, anatomical details of the examined region are depicted clearly with the resulting digital images. Using DXA for obtaining lateral images of the lumbar spine offers the advantage that the scanning b e a m m i n contrast to conventional cone beam radiographymis always parallel to the vertebral end plates. This allows a better definition of vertebral dimensions for a morphometric analysis. This method has been called morphometric x-ray absorptiometry, a name referring to the DXA approach. ~~176 Overlying structures like ribs or iliac crest may have an adverse effect on the morphometric analysis. To enhance the accuracy of this method, technical modifications of the x-ray tube and the detector system may provide images with higher resolution and thus enhance the analysis of vertebral deformities. The disadvantage of a higher resolution for MXA devices may be the required higher radiation dose to the patient compared to regular DXA. Beyond that, the same limitations that apply to the morphological analysis of conventional radiographs apply to MXA. These techniques are in a developmental stage, and image quality throughout the spine is still a major concern among researchers. However, if proven suitable for a diagnosis of vertebral fractures, for certain indications (e.g., clinical drug trials) MXA may be able to take the

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place of conventional spine radiography, offering low radiation exposure and simultaneous measurements of bone density. Architectural properties derived from conventional pelvic radiographs, such as thickness of the femoral cortex or width of the trochanteric region, were found to be associated with future hip fractures. 1~ However, one disadvantage of conventional radiography is that positioning is not as strictly standardized as it is with DXA. When using pencil beam technique with DXA there is no substantial magnification of the object studied. Researchers have studied geometric properties of the femur on DXA scans and found that the hip axis length was significantly associated with future hip fractures independent of age and bone mineral density. 1~ Measurement of the hip axis length has been automated, allowing for an uncomplicated and reproducible assessment of an individual's hip axis length. 1~ Similarly, geometric variables derived from DXA scans of the radius predicted the fracture load in vitro. 11~These studies primarily document the importance of architectural bone properties for the biomechanics of fracture and may potentially account for differences in the fracture risk between ethnic groups. ~1'112Further studies in this field are required, and the assessment of simple geometric variables may be an interesting asset to dual x-ray absorptiometry.

G. Q u a n t i t a t i v e C o m p u t e d T o m o g r a p h y 1. INTRODUCTION

Based on fundamental methods and technical evaluation described by numerous investigators in the 1970s, 113-12~clinical QCT of the spine was introduced in the early 1 9 8 0 S . 34"121 The usefulness of this technique, which has been widely investigated in recent years, lies in its ability to precisely determine true volumetric density (in milligrams per cubic centimeter) in three dimensions at any skeletal site. For measurements in the spine, the potential advantages of quantitative CT over DPA or DXA are its capability for providing both a direct density measurement and spatial separation of highly responsive trabecular bone from less responsive cortical bone. Therefore, QCT has been principally employed to determine trabecular bone density in the vertebral centrum. In this application, QCT has been used for assessment of vertebral fracture risk, 121-125 measurement of age-related bone loss, 85"126'127and follow-up of osteoporosis and other metabolic bone diseases. 128 The validity of this technique for measurement of vertebral cancellous bone is widely accepted and it is used at over 4000 centers worldwide. Generally, spinal QCT is performed on standard clinical

CT scanners. It employs an external bone mineral reference phantom to calibrate the CT number measurements to bone-equivalent values as well as special software to place regions of interest inside the vertebral body. 2. ACQUISITION TECHNIQUE

a. How Does QCT Measure Bone Density? For the measurement of vertebral bone density, a calibration phantom, containing several cylindrical channels of known densities of hydroxyapatite (HA) or KzHPO4, is placed under the patient's back and scanned simultaneously (Fig. 9-10). Normally, a lateral scout view is first taken to determine the mid levels of the lumbar vertebrae being scanned (usually L1 through L3), and each vertebra is subsequently imaged using a 1-cm slice thickness, with the gantry angled appropriately. Following data acquisition, the reconstructed image is analyzed with software that places a ROI in the central trabecular bone or cortical rim of the vertebral body. The average attenuation observed in the region of interest is converted to HA- or KzHPO4-equivalent densities using the equation of a regression line determined between the known densities and measured attenuation values of the calibration phantom channels. The calibrated BMD values measured for the individual vertebrae are subsequently averaged and the patient's average value is compared to a population-specific normative database adjusted for age and the type of CT scanner. In order to improve precision and reduce acquisition and analysis time, the sagittal location of mid vertebral slices and the axial placement of regions of interest can be highly automated. 129'13~The software automatically locates the vertebral body, maps its outer edges, and employs anatomical landmarks such as the spinous process and spinal canal to calculate size and location of the region of interest. The systems can place trabecular, cortical, or integral regions of interest. Typical automatic analysis time for a vertebral body is about 5 seconds, and total scanning time is several minutes. b. Single and Dual Energy Approach for QCT. QCT can be performed in single energy (SEQCT) or dual energy (DEQCT) modes, which differ in accuracy, precision, and radiation. The accuracy of SEQCT for spinal bone mineral determination depends on variable marrow fat composition in the vertebrae, the accuracy of the calibration standard, and beam hardening errors, and scatter, among other factors. 131-133 The principal source of error is marrow fat, which causes SEQCT measurements to underestimate BMD and overestimate BMD loss. However, vertebral marrow-fat content increases with age, and a simple correction procedure that takes this

CHAPTER 9


FIGURE 9--10 Quantitative CT. The lateral scout view (A) provides a rapid and simple method to define the midplane of four vertebral bodies (A), and a single 8- to 10-mm-thick section is obtained at each level (B). The classic oval region of interest is placed anteriorly in the middle of the vertebral body of three to four consecutive lumbar vertebrae and contains purely trabecular bone. For reference, regions of interest also are placed in the compartments of the calibration standards that contain distinct solutions of K2HPO4.

287

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into account can reduce the BMD accuracy errors to levels that are small compared with the biological variation. T M Additionally, marrow-fat errors can be further reduced by using a kVp setting that minimizes the fat sensitivity for the given scanner. Although it is possible to improve accuracy by employing DEQCT, this approach incurs reduced in vivo precision and higher dose, and thus is recommended only for research studies that require higher accuracy. 135'136 3. CLINICAL APPLICATIONS OF SPINAL

QCT

a. Fracture Discrimination. The in vivo precision errors of 2% to 4% and the accuracy errors of 5% to 15% reported for spinal QCT are generally higher than those observed for posteroanterior DXA of the spine and comparable with those of lateral DXA. However, QCT's ability to selectively assess the metabolically active and structurally important trabecular bone in the vertebral c e n t r u m 85'137-139 results in excellent ability to discriminate vertebral fracture and to measure bone loss, generally with better sensitivity than projectional methods such as DXA or DPA. Ross et al. employed prospective data to assess the predictive power of various BMD measurements for vertebral fracture and found that a spinal QCT measurement two standard deviations (2 SD) below the normative value was 40% more predictive of future vertebral fracture than was the corresponding spinal DPA measurement. Interestingly, they also found that both spinal DPA and QCT had statistically significant associations with fracture even when they were combined in the fracture prediction model, indicating that these two techniques may provide independent information about vertebral fracture risk. Other studies have examined BMD decrements between normal subjects and those with vertebral fractures. These studies reported that the decrement as measured by spinal QCT is significantly higher than that observed by posteroanterior DXA and that vertebral fracture discrimination is generally superior with QCT. 85'91'124'14~ b. Age- and Menopause-Related Bone Changes. Because the metabolic rate in the vertebral trabecular bone is substantially greater than that of the surrounding cortical bone, the ability of QCT to selectively measure trabecular bone gives it comparatively good sensitivity for measurement of bone loss following the menopause. In a cross-sectional study of 108 post-menopausal women, Gulgielmi et al. 85 measured overall bone loss rates of 1.96% per year with QCT compared with 0.97% per year and 0.45% per year, respectively, for lateral DXA and posteroanterior DXA. Generally, it has been found that the cross-sectional bone loss rate in females is typically 1.2% per year when measured with QCT and

a little over one half that value when measured with DXA or DPA. 128Block et al. carried out a comprehensive QCT study of the patterns of age-related bone loss rate and found that bone loss in women was best described by a two-phase (linear-exponential) regression, with a linear bone loss of 0.45 mg/cc/year up to the menopause, followed by a 25 mg/cc decrement during the early menopause, and an exponential pattern of bone loss of 1.99 mg/cc/year following the menopause. 126 4. PERSPECTIVES ON QCT a. Volumetric QCT at the Spine. While use of QCT has centered on two-dimensional characterization of vertebral trabecular bone, there is interest in developing three-dimensional, or volumetric, computed tomography (vQCT) techniques both to improve spinal measurements as well as to extend QCT assessments to the proximal femur (Fig. 9-11). These three-dimensional techniques encompass the entire object of interest either with stacked-slice or spiral CT scans and can employ anatomical landmarks to automatically define coordinate systems for reformatting of the CT data into anatomically relevant projections. In the spine, three-dimensional methods have been investigated to improve both longitudinal performance and discriminatory capability. Volumetric methods would be expected to improve the in vivo precision of QCT, first by employing image alignment techniques to reproducibly quantify the same volume of tissue in longitudinal studies, 142'143 and second by assessing the trabecular bone from the entire vertebral centrum, a volume roughly nine to ten times larger than the standard elliptical region of interest. However, assessment of a larger volume of interest coveting the trabecular bone in the centrum does not necessarily improve the identification of vertebral fracture over standard two-dimensional QCT methods. Thus, volumetric studies of regional B MD, which examine subregions of the centrum that may vary in their contribution to vertebral strength 144 ' 145 and studies of the cortical shell, 146-149the condition of which may be important for vertebral strength in osteoporotic individuals, 15~ are of interest for future investigation. b. Volumetric QCT at the Hip. Because of the proximal femur's complex architecture and dramatic threedimensional variation in its density, the two-dimensional QCT methods widely used in the spine cannot be used to assess the proximal femur. Thus, there is no clinically accepted QCT technique for the hip and virtually all densitometric assessment of the proximal femur is performed with DXA, which provides an integral measurement of trabecular and cortical bone. Early attempts to apply QCT methods to the proximal femur measured

CHAPTER 9 Noninvasive Assessment of Bone

289

FIGURE 9-- 11 A, Three-dimensional representation of excised lumbar vertebral body. The vertebral body, mounted in a water-filled cylinder, was encompassed with 3-mm contiguous slices; segmentation was obtained by mapping the bone surface using a contour tracking algorithm. B, Three-dimensional representation of proximal femur of patient with osteoporosis secondary to paraplegia. Proximal femur was encompassed with 3-mm contiguous slices, and segmentation was obtained by mapping the bone surface using a contour-tracking algorithm. (From Genant HK, Engelke K, Fuerst T, et al: Noninvasive assessment of bone mineral and structure: State of the art. J Bone Miner Res 11:707-730, 1996.)

purely trabecular bone, 151'152 because trabecular bone shows the earliest loss and will most effectively identify individuals at risk for fracture. However, the contributions of trabecular and cortical bone to proximal femur strength vary with the proximal femur site. 153 Thus, welldefined volumes of interest selectively measuring trabecular and cortical bone, as provided by QCT, may be important for assessment of bone strength at various sites in the proximal femur. Additionally, the crucial role of geometry in determining proximal femur strength has been well documented. 1~ QCT, with the inherent ability to resample data along any axis of interest, yields geometric information not obtainable with projectional techniques. For example, Lotz et al. resampled CT data along an axis defined by the peaks of the greater and lesser trochanters and found that the product of average intertrochanteric CT number and intertrochanteric area correlated extremely well (R2= 0.90) with in vitro fracture load in a configuration simulating a fall to the side. ~Sv In addition to assessment of proximal femur strength, vQCT could play a useful role in monitoring differential trabecular or cortical bone response to pharmacological interventions.

c. High-Resolution and Micro-Computed Tomography (HRCT/txCT). While the average BMD measured within a relatively large region of interest is a valuable

tool for the assessment of osteoporosis, an improved assessment of bone strength and fracture risk prediction may also require microstructural analysis. Apart from trabecular BMD, two main factors that affect bone strength are the architecture of the trabecular network and the thickness of the cortical shell. While the spatial resolution of clinical CT scanners (typically > 0.5 mm) is inadequate for highly accurate cortical measurements and for an analysis of discrete trabecular morphological parameters, newer CT developments try to address these issues. Two main approaches can be distinguished: (1) the development of new image acquisition and analysis protocols using existing clinical CT scanners; and (2) the development of new CT scanners for in vivo investigations of peripheral bones or for in vitro two- or threedimensional IxCT for structural analysis of very small bone samples (typically < 1 cm3). These efforts to develop new imaging and analysis protocols for existing scanners with limited spatial resolution have often focused on a regional analysis of BMD. In studies on the spine, Sandor et al. 146'158 divided the trabecular area into several regions of interest in the form of a spider net. The BMD was distributed in a Wshaped pattem with maximum B MD in the lateral and anterior portions of the vertebral body. Regions with highest BMD showed the highest loss with age. Hangartner and Gilsanz 159 and Sumner et al. 16~ addressed

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techniques to determine the peak appendicular cortical density and vertebral cortical thickness, respectively. Flynn et al. 161 used CT to determine regional bone density in 18 small cylindrical regions of interest in the lower lumbar spine. Pattern classification methods identified vertebral architectural density patterns that potentially provide enhanced fracture discrimination. Instead of the usual trabecular BMD analysis, BrailIon and colleagues 162 suggested analysis of the standard deviation of the BMD values as a parameter that partially reflects structural variations in the cross-sections of the lumbar vertebrae. A high BMD standard deviation indicates a high degree of gray level variations in the image and thus a highly networked bone architecture. Engelke et al., using a very-low-dose technique, applied this idea to a data set of 214 w o m e n . 163 However, this study did not confirm a significant potential of the BMD standard deviation as measured in trabecular spinal QCT to improve the capability of B MD to separate osteoporotic from nonosteoporotic s u b j e c t s . 163 Nevertheless, this technique could possibly be useful at higher radiation, which provides better depiction of structure. Another direction is the development of in vivo, highresolution, thin-slice CT (slice thickness, 1 to 1.5 mm). A high-resolution image of a vertebral body that clearly displays structural information in a higher dose CT image is shown in Figure 9 - 1 2 . However, the quantitative extraction of this information is difficult and the results often vary substantially according to which image processing technique is used. Some investigational work using thin-slice tomography has been published recently by Chevalier et al. 164 They measured a feature termed the trabecular fragmentation index (length of the trabec-

ular network divided by the number of discontinuities) to separate osteoporotic subjects from normal subjects. However, this index did not readily separate postmenopausal osteoporotic women with vertebral fractures from normal or osteopenic subjects. 164 A similar trabecular texture analysis approach was also reported by Ito. 165 Ultra-high-resolution CT scanners for peripheral skeletal in vivo measurements have been developed by Rtiegsegger et al. 114'166-168 The images, with a spatial resolution of 100 to 200 Ixm, show trabecular structure in the radius and the tibia. These state-of-the-art scanners probably approach the limits of spatial resolution achievable in vivo when administering acceptable exposure rates. The images can be used for quantitative trabecular structural analysis and also for a separate assessment of cortical BMD. Feldkamp et al. 169'170 constructed a IxCT system for in vitro three-dimensional analysis of small bone samples. The spatial resolution of 60 to 100 Ixm clearly separates individual trabeculae and thus allows for a three-dimensional analysis of a trabecular network. Based on data sets from this CT scanner, Engelke et al. 171'172 developed a three-dimensional digital model of trabecular bone that can be used to compare two- and three-dimensional structural analysis methods and to investigate the effect of decreasing spatial resolution and image processing technique on the extraction of structural parameters. Three-dimensional data sets can be used not only for calculating classic histomorphometric parameters like trabecular thickness a n d separation 173'174 but also for determining topological measurements like the Euler number, which is a measure of three-dimensional connectivity. 175 Another in vitro CT scanner with a spatial

FIGURE 9--12 High resolution (500 X 500 Ixm) CT image of a 1.0-mm slice of a vertebral body imaged in vivo. Trabecular structure is well delineated in gray-scale (A) and skeletonized (B) images. (From Genant HK, Engelke K, Fuerst T, et al: Noninvasive assessment of bone mineral and structure: State of the art. J Bone Miner Res 11:707-730, 1996.)

CHAPTER 9 Noninvasive Assessment of Bone resolution of 20 Ixm has recently been developed by Rtieggsegger et al. 176'177 Whereas the CT scanners described above use an x-ray tube as their radiation source, other investigators 178-18~ have explored the potential of high-intensity, tight-collimation synchrotron radiation, which allows for either faster scanning or higher spatial resolution for imaging bone specimens. 5. QCT AT PERIPHERAL SITES Special purpose peripheral QCT (pQCT) scanners have been employed for measurements of BMC and BMD of the peripheral skeleton. Initially, a radionuclide source (usually 125I) was used; however state-of-the-art scanners employ x-ray s o u r c e s . 168'181-186 Peripheral QCT allows for a true volumetric density measurement of appendicular bone without superimposition of other tissues and provides exact three-dimensional localization of the target volume. Ease of use and the ability to separately assess cortical and trabecular bone, and to measure BMD, BMC, and axial cross-sectional area, make the method an interesting alternative to SPA or SXA. There are about 700 pQCT systems in use, mostly in Europe. The great majority of these systems are clinical pQCT scanners; about 20 are ultra-high-resolution, highprecision pQCT systems for research applications. With the commonly used clinical pQCT scanner, measurements in the distal radius are performed at only one site with a single axial slice of 2.5 m m thickness located at the level that represents 4% of the ulnar length from the distal radial cortical end plate (Fig. 9-13). The short-term in vivo precision of the clinical pQCT has been measured using groups of healthy young vol-

291 unteers. Butz et a l . 187 found relative precision errors (CV) of 1.7% for trabecular, 0.8% for total, and 0.9% for cortical BMD measurements. Lehmann et al. 188 (pQCT with an x-ray source) and Schneider et al. 183 (pQCT with a radionuclide source) calculated absolute precision errors for trabecular regions of interest between 2.6 and 3.1 mg/cm 3, which resulted in CVs of under 1%. In a study by Grampp et al. 189 of pre- and postmenopausal women, the average absolute precision errors for the trabecular and total region were of the same order as in the previous studies (1.8 to 3.4 mg/cm 3, 3.8 to 8.5 mg/ cm 3, respectively), but the resulting CVs of the postmenopausal population were higher (0.9 to 2.1%, 1.1 to 2.6%, respectively), because of lower average BMD in their groups. Long-term in vitro precision with phantom measurements was calculated by Wapniarz et al. to be about 0 . 9 % . 19~ In vitro, the accuracy of the method was calculated to be about 2%. TM In a cadaver study in which radii were measured with pQCT and then ashed, Takada et al. found high correlations between total pQCT BMC and ash weight (r - 0.90) and between pQCT total BMD and ash weight (r = 0 . 8 2 ) . 191 The relationship between pQCT parameters and aging in healthy subjects was evaluated in several studies. Using a high-resolution scanner, Rtiegsegger et al. found that in contrast to trabecular BMD, which declined with age, cortical density (but not cortical B MC or area) remained constant between the ages of 20 and 70 years. TM Similar observations with a clinical pQCT scanner were made by Grampp et al., 192 who found only relatively small annual BMD changes in healthy volunteers of - 0 . 3 0 % in total, - 0 . 2 5 % in trabecular, and - 0 . 1 9 % in

FIGURE 9--13 pQCT cross-sectional image of forearm (left) showing declination of cortical bone and central trabecular bone (center). The cross-section is located at the level that represents 4% of the ulnar length from the distal radial end plate (right).

292


cortical BMD. In this study, the highest age-related changes in pQCT parameters measured at the radius occurred in the cortical thickness measures, with an average annual decrease of - 0 . 6 9 % in cortical BMC and - 0 . 5 2 % in cortical area indicating principally a thinning of the cortex by endosteal resorption. 192 Other studies found higher annual changes in BMD but did not consider BMC or cortical area. Schneider et al. 183 found annual decreases of 0.5% in the trabecular BMD of healthy women and 1.9% in osteoporotic women, and Butz et al. 187 found changes of 0.9% in the trabecular and 1.1% in the total BMD. The differences between the studies are not entirely clear but may be related to different criteria in the definition of the study subjects. The influence of B MD in trabecular and in cortical bone on the total BMD measured by pQCT was evaluated i n a study by Rico et al. with healthy young male and female volunteers. 193 Here, the cortical BMD proved to be more closely related to the total BMD than was trabecular BMD. This was indicated by the higher correlation coefficients for comparisons of pQCT total versus cortical BMD (r = 0.95), as compared to total versus trabecular (r = 0.62), and of trabecular versus cortical BMD (r = 0.43). In some studies, pQCT measurements of B MD at the radius were found to be successful in distinguishing between osteoporotic and nonosteoporotic patients, and in monitoring subjects during clinical studies. 168'181 However, other authors have reported conflicting results, especially for peripheral trabecular B M D . 194-196 The importance of the measurement of cortical bone p e r s e was suggested by Sparado et al., who found in a biomechanical study that the cortical shell contributes substantially to the mechanical strength of the distal radius. 197 The thinning of the cortical rim at the radius was a potential mechanism contributing to osteoporosis, 168'~81 and it identified this compartment as a promising location for B MC and thickness measurements. These findings were supported in a study by Grampp et al. w2 that examined the ability of BMD, BMC, and cross-sectional area to detect osteoporotic changes. Only the cortical area and BMC significantly distinguished between women with nontraumatic vertebral fractures and healthy postmenopausal women; these two parameters also showed the highest age-adjusted odds ratio for fracture risk. These data suggest that pQCT measurement of cortical rather than trabecular bone at the radius may have greater diagnostic sensitivity in terms of appendicular measurements. Modem pQCT scanners also incorporate a multislice data acquisition capability coveting a larger volume of bone as compared with the commonly used single-slice technique. ~98'199The measurement of several slices is potentially more representative of changes in the distal ra-

dius and may therefore reflect the bone status of an individual more accurately. If studies employing this multislice pQCT technique are successful, they may contribute to more extensive use (currently about 1000 systems worldwide) of this already promising technique.

III. ASSESSMENT OF BONE WITHOUT RADIATION A. Quantitative Ultrasound 1. BONE DENSITY AND QUALITY MEASUREMENT USING ULTRASOUND

The use of QUS for the assessment of skeletal status has seen continued and accelerating interest in recent years, z~176 The attractiveness of QUS lies in its low cost, portability, ease of use, and freedom from ionizing radiation. These benefits, combined with preliminary clinical results showing good diagnostic sensitivity and the ability to predict fracture risk, have encouraged further basic investigation and commercial development. Currently there are more than 12 commercially available QUS devices, although none has been approved for clinical use in the United States by the Food and Drug Administration (FDA). For this reason, in the United States QUS devices for bone assessment are found primarily at research centers. Nevertheless, QUS devices have a very wide distribution in Europe and Asia and are routinely used for clinical assessment of osteoporosis. By the end of 1996 more than 3000 clinical ultrasound units will be in use worldwide. 2. QUANTITATIVE ULTRASOUND PARAMETERS

These devices are used to measure both the velocity and the attenuation of ultrasound as it travels through bone. The choice of sites for the measurement of ultrasound properties is driven by the need for easy access to the bone (minimal intervening soft tissue) and the type of bone one wishes to examine (trabecular or cortical). Currently, devices are available to interrogate the calcaneus, phalanges, tibia, and patella. In each case the devices are of the transmission type, using two ultrasound transducers (a transmitter and receiver) positioned on each side of the bone to be measured (Fig. 9 - 1 4 ) . These devices measure ultrasound parameters in primarily trabecular bone at the calcaneus and patella, cortical bone at the tibia, and integral bone at the phalanges. The velocity parameter measured is often called the ultrasound transmission velocity (UTV) or more commonly the speed of sound (SOS). The ultrasound attenuation parameter is called broadband ultrasound attenuation (BUA).

CHAPTER 9


293

FIGURE 9--14 Schematic diagrams showing method of acquisition for two quantitative ultrasound measures. A, Calcaneal ultrasound measurement using a water bath for acoustic coupling. Paired transmitters and receivers measure both attenuation and velocity of ultrasound through the heel. Dry systems are available that use ultrasound gel for coupling. B, Ultrasound velocity measurement at the tibia with the SoundScan 2000. Probe measures speed of ultrasound wave propagation longitudinally through the tibial cortex. The fixed distance between the receivers and the difference in signal arrival time determine velocity.

a. Speed of Sound. The velocity of ultrasound wave propagation, or speed of sound, through bone is determined by dividing the distance traversed (e.g., bone diameter or length) by the transit time. The resulting velocity is quoted in meters per second (m/sec). Measurements of SOS are c o m m o n l y performed at the calcaneus, tibia, and phalanges. Velocity has also been measured in the patella, but a c o m m e r c i a l system is not currently available. Thus skeletal sites with both predominantly cortical or trabecular bone are assessable with ultrasound, although different devices are required for the various measurements. Table 9 - 1 shows typical values of SOS measured at these sites. The velocity of ultrasound in cortical bone is two to three times higher than at trabecular sites.

SOS at the heel is well established and several manufacturers (Achilles by Lunar Corporation, USA, Sahara by Hologic, Inc., USA, and CUBAclinical by M c C u e Ultrasonics, Ltd., UK) are producing devices to measure the heel in the mediolateral direction. While similar in concept, these devices differ in transducer design, analysis algorithms, and whether water or ultrasound gel are used to acoustically couple the transducers to the heel. Typical values range from 1400 to 1900 m/sec and precision errors are reported to be between 0.2% and 1 . 5 % . 201-203 Heel thickness and water temperature are parameters k n o w n to affect the velocity and are potential error sources for this measurement. 2~176 Clinical assessment of SOS at the phalanges was evaluated and first described by Jergas et al. 2~ M e a s u r e m e n t s

294


TABLE 9--1 Different Approaches for Assessment of Bone with Quantitative Ultrasound Anatomical Site

Biological

Precision

Range

(CV) a

Parameter

4 0 - 1 2 0 b 1.3-6.0%

Examination Time

Os calcis

BUA (dB/MHz)

Os calcis

SOS (m/s)

1400-1900

0.2-1.5%

10 min

Mid tibia

SOS (m/s)

3400-4200

0.2-1.0%

15 min

Phalanges

SOS (m/s)

1800-2000

0.5-1.0%

8 min

40

N -r" 30.

:

10 min

t'- 20~ O

.

r" aCV = coefficient of variation. bDependent on manufacturer.

performed at this site revealed significant differences in SOS between healthy and osteoporotic postmenopausal women. 2~ Independently, a group in Italy used a similar approach and recently developed a commercially available device (DBM Sonic 1200 by Igea s.r.1, Italy). 2~ Unlike other SOS evaluations, the measurement of SOS in the phalanges is amplitude dependent and is often referred to as AD-SOS. This in some sense combines both velocity and attenuation properties into a single measure. AD-SOS values (1800 to 2000 m/sec) are generally higher than those found in the calcaneus. The coefficient of variation for AD-SOS is reported to be 0 . 5 % . 209'210 The AD-SOS measurement has greater dependence on the operator than the heel measurements, and operator skill will determine precision. Another recently developed instrument measures SOS at the mid tibia in the longitudinal direction (SoundScan 2000 by Myriad Ultrasound Systems, Ltd., Israel) (see Fig. 9-14). At this site the device measures cortical bone and records higher velocities (3600 to 4200 m/sec). Precision of this measurement (0.2% to 1%) is as good as or better than other QUS techniques 21~-2~3 and, like the phalangeal measurement, is influenced by the operator. b. Broadband Ultrasound Attenuation. Broadband ultrasound attenuation is the second parameter measured by QUS. Ultrasound attenuation results from scattering and absorption of the ultrasound signals in bone, bone marrow, and surrounding soft tissue. Langton et al. were the first to show that the attenuation of ultrasound in bone is linear in the frequency range of 200 to 600 kHz. 214 Hence the slope of this relationship defines the attenuation parameter BUA, which has units of dB/MHz. Figure 9 - 1 5 shows examples of attenuation data collected over this range of frequencies. Currently, BUA is measured only in the heel. The short-term in vivo precision errors for BUA range from 1.3% to 6 % . 202'203'215 The relatively poor precision can be explained in part by variation in foot position and consequently the region of interest measured. One study of

5

Osteomalacia: generalized Generalized

HVOii HVOiii

> 12.5 > 12.5

> 100 od

> 10 > 10

---

> 12.5 100 >50

Focal Atypical

OV/BV b (%)

5r

aCorrected for regression on adjusted apposition rate in borderline cases. bCorrected for trabecular thickness in borderline cases. CUpper limit higher in renal osteodystrophy. dNo double label, so apposition rate zero. eCases with OV/BV between 5% and 10% are transitional between focal and generalized. fin cases with OV/BV between 5% and 10% or with Mlt between 50 and 100, will need BFR to discriminate from HVOi or other forms of high-turnover osteoporosis. O.Th, mean osteoid thickness (corrected for section obliquity); Mlt, mineralization lag time; OV/BV, osteoid volume per unit of bone volume.

softening of the adult skeleton include kyphosis, coxa vara, and pigeon breast. 1'2'4 Less obvious is subclinical basilar impression. 37 Protusio acetabuli can ultimately compress the pelvic inlet to a triradiate shape and narrow the pubic arch, so that childbirth is only possible by cesarian section. 6 But in most patients there is no deformity other than the normal effects of aging on the spine. Less usual manners of presentation include algodystrophy, probably as a result of increased load bearing by the remaining mineralized b o n e 38'39 and plantar fasciitis. 4~ The various types of fracture that occur in osteomalacia will be described after the radiographic changes. A few patients present with the effects of hypocalcemia, which are described in detail elsewhere in relation to hypoparathyroidism. Some rarer symptoms, possibly due to hypocalcemia, that have been reported in osteomalacia but not in hypoparathyroidism, are impaired function of the posterolateral columns of the spinal cord in the absence of vitamin B12 deficiency, and cochlear deafness. 4 1.

B O N E P A I N AND T E N D E R N E S S

Like bone pain in general, pain in osteomalacia is dull and poorly localized but clearly felt in the bones rather than in the j o i n t s . 2'4'41'42 I t is often persistent, made worse by weight-bearing and contraction of locally attached muscles, and rarely relieved completely by rest but sometimes by the adoption of a particular posture. The pain is usually symmetrical, beginning in the low back, later spreading to the pelvis and hips, upper thighs, upper back, and fibs. It is never of sciatic radiation and in the absence of fracture is rarely felt below the knees. The distribution of tenderness to percussion is similar, but usually includes the shins. Lateral compression of the

ribs and posterior compression of the sternum are useful maneuvers to elicit pain. The anatomical localization to the axial rather than the appendicular skeleton has been attributed to its higher proportion of cancellous bone, 2 which accumulates relatively more osteoid than cortical bone and probably undergoes deformation more easily. Although pain conforming to this description in every particular is easily recognized, usually it is less characteristic and is an uncertain basis for differential diagnosis. Some patients carry for many years one or more diagnoses that cover a broad spectrum of rheumatological and orthopedic practice. Often these diagnoses are erroneous, but the patients commonly have other reasons for pain that do not respond to treatment of osteomalacia. A significant minority of patients are completely free of pain, especially those with severe hypocalcemia. 6'43 Others suffer excruciating pain with the least movement or the slightest touch. In X-linked hypophosphatemia (XLH) there is often no bone pain until middle age despite lifelong osteomalacia in the absence of treatment, possibly because the cortices of weight-bearing bones are thicker, so that even softened cancellous bone is less subject to strain. Although the general characteristics of bone pain as a form of deep somatic pain can be accounted for by the type and distribution of nerve fibers in bone, 42 its specific characteristics in different clinical circumstances are unexplained. 2. M U S C L E W E A K N E S S

Muscles of the proximal limb girdles, especially the lower, are often weak in osteomalacia, the severity varying from a slight abnormality detectable only on careful examination to severe disability verging on complete paralysis. In the only quantitative study, in 12 vitamin D -

340 depleted patients, the force exerted during maximum voluntary isometric contraction of the quadriceps ranged from 14% to 67% of normal, with a mean of 37%. 44 Atrophy is mild in relation to the severity of weakness, tone is reduced, and fasciculation is absent, but deep tendon reflexes are increased. 4 In mild cases, true weakness must be distinguished from unwillingness to tense muscles because of pain. Specific symptoms include difficulty in rising from a chair 1~ or walking up or down stairs without using the arms, and a characteristic gait, described later. It is essential for the physician to observe the movements that the patient reports to be difficult. 5 Electromyography usually shows motor unit potentials that are of short duration and reduced amplitude and often polyphasic. 45'46 Muscle biopsy shows no unequivocal features of primary muscle disease but mean fiber cross-sectional area is reduced to about the same extent as muscle strength,44 with preferential loss of type II fibers. 46 The syndrome is commonly referred to as a myopathy, but the site of the lesion is unknown. There is variable evidence of a neurogenic component to the weakness, 4 but this could result from associated deficiencies of nutrients other than vitamin D. 45 The syndrome can occur in every form of osteomalacia except XLH, but it is more common in vitamin D-related cases. Among these, the frequency is only 10% to 30% when the diagnosis is made early by biopsy, but approaches 100% in endemic nutritional osteomalacia. 45 In gastrointestinal disorders with a high frequency of neurological abnormality, " m y o p a t h y " is found only in patients with vitamin D malabsorption and osteomalacia, 4 and further evidence for specificity is induction of the muscle histological changes by experimental vitamin D deficiency in the rat. 46 The similarity in clinical and laboratory findings between patients with " m y o p a t h y " associated with hypophosphatemia of various causes but variable severity suggests that a common mechanism is depletion of phosphate at some critical intracellular location; this could be the result of severe phosphate deficiency, a specific transport defect in muscle under genetic control, or lack of some direct action of one or more vitamin D metabolites on muscle. 47 In patients with vitamin D depletion, muscle cell adenosine triphosphate (ATP) and phosphoryl creatinine are reduced but do not correlate with the degree of weakness, 44 and preliminary nuclear magnetic resonance (NMR) studies in one patient with hypophosphatemic osteomalacia were inconclusive. 48 Experimental phosphate depletion reduces muscle cell ATP and actomyosin content in the rat, 4 but several other mechanisms are possible. Severe proximal " m y o p a t h y " in the aluminum-related osteomalacia that occurs during hemodialysis may be an exception to this generalization, reflecting instead the neurotoxicity of aluminum. 4

A . M . PARFITT

3. DIFFICULTY IN W A L K I N G Abnormal gait is the most frequent clinical manifestation of osteomalacia regardless of etiology49; it can be the result of either pain or weakness, but usually both contribute. A change in gait discriminates more reliably between young adults with and without nutritional osteomalacia than any other symptom. 5~Many patients feel pain only when walking, which they consequently undertake sparingly and gingerly. Because of weakness the legs may feel heavy and the patient tires easily, walks more slowly with a flat-footed, springless gait, and is more likely to stumble. 1 If the hip muscles can no longer keep the pelvis horizontal with asymmetrical support, the upper body bends laterally away from the outwardly swinging trailing leg, keeping the center of gravity over the leading leg. The combination of trunk oscillation, short steps, and wide track constitutes the classic penguin or duck-like waddling gait of advanced osteomalacia, ~'2'4'5 which is still common where vitamin D deficiency is endemic, 7'45 but is otherwise rare. A waddling gait must be differentiated from a broad-based gait resuiting from outward bowing of the femora in the absence of muscle weakness.

B. H i s t o p a t h o l o g y o f H V O The diagnostic criteria have already been discussed, but some additional histological features are important for understanding the structural abnormalities in the skeleton and for the interpretation of noninvasive indices of bone remodeling. Osteoid accumulation increases about 15-fold, with a range of 5- to 30-fold, but the absolute increase in OV/ B V is much greater in cancellous bone (10% to 60%) than in cortical bone (1% to 10%) because of the difference in their normal rate of turnover. 12'51 The corresponding decreases in mineralized bone volume are also much greater in cancellous bone, with values similar to those of patients with osteoporotic vertebral compression fractures. 12 Total cancellous bone volume, including osteoid, is usually normal or increased in extrinsic vitamin D deficiency but often reduced in intrinsic deficiency to levels intermediate between normality and established vertebral osteoporosis. 32 Because of increased bone turnover in HVOi, cortical bone porosity is increased about twofold, with little further change in HVOii and iii. Osteoid accumulation and porosity are reversible, but as a result of prolonged secondary hyperparathyroidism there is thinning of cortical bone due to increased net endosteal resorption, which is irreversible and forms the largest component of the total body bone mineral deficit. 13'5~With the increase in cancellous tissue space at the expense of the inner third of the cortex, the absolute amount of total

CHAPTER 11 Osteomalaciaand Related Disorders cancellous bone may be normal even if its relative amount (analogous to concentration) is reduced. 51 There are also qualitative changes in the bone. If completion of secondary mineralization is delayed, scattered areas of bone of subnormal mineral density may be revealed by quantitative microradiography or by permeability to basic fuschin. 4 Because of its high water content, such bone is more accessible than normal bone to exchange of mineral ions with the extracellular fluid. Low-density bone is seen especially around osteocyte lacunae, which may also be lined by thin osteoid-like seams. 4 The asymmetrical perilacunar abnormality observed in XLH appears to be specific for that condition. 52 As well as being wider, tetracycline fluorescent bands are frequently blurred and indistinct. 3'8 The second label may still be visible at the zone of demarcation, even when mineralization is completely arrested, either because outward diffusion is retarded by thicker osteoid seams or because of binding to some constituent of the cement surface. 4 Finally, scattered small foci of particulate mineral may be seen within the osteoid in toluidine-bluestained sections 3 and by electron microscopy. 53 The interpretation of osteoclast indices, whether expressed as number of cells or nuclei or as extent of surface in contact with osteoclasts, rests on the observation that osteoclasts normally resorb only mineralized bone and avoid osteoid, 4'54 probably because their mechanism of attachment to the bone surface is impaired. 55 In HVOi the surface extent of osteoclasts is increased, whether related to the total surface or the mineralized surface. As osteoid increases in extent, the osteoclast surface per unit of mineralized surface increases substantially, but in advanced osteomalacia the osteoclast surface per unit of total surface may remain unchanged. For example, if the relative osteoid surface is 95% of bone surface and mineralized surface 5%, an osteoclast surface of 1% of bone surface is within the normal reference range for postmenopausal females but represents 20% of the mineralized surface. With the combination of reduced surface available for normal resorption and severe hyperparathyroidism, osteoclasts in typical Howship's lacunae are observed on osteoid, which appears to be undergoing resorption that is morphologically indistinguishable from the resorption of mineralized bone. Although the relative extent is small, osteoid resorption can account for more than half of the total osteoclast surface. 54 For a full description of bone remodeling in osteomalacia it is necessary to consider the formation, resorption, and balance of unmineralized bone and mineralized bone separately. In a few patients with severe osteomalacia there are the typical findings of osteitis fibrosamdissecting or tunneling intratrabecular resorption, giant subendocortical resorption cavities, increased fibrous tissue deposition adjacent to the cancellous and endocortical surfaces,

341 within resorption cavities and within the marrow spaces, and formation of w o v e n b o n e . 42'56'57 In contrast to the osteitis fibrosa of hyperparathyroidism alone without a significant mineralization defect, in osteomalacia the osteoblasts cover a smaller than normal fraction of the osteoid surface 58 and when mineralization ceases altogether, the osteoid eventually becomes covered entirely by flat lining cells. 35 In vitamin D-related osteomalacia, the morphological effects of hyperparathyroidism become more evident as mineralization becomes more defective, in contrast to the inverse relationship observed in the aluminum-related osteomalacia of hemodialysis. 4 Osteoclast indices are also less increased in non-vitamin D-related hypophosphatemic osteomalacia, osteitis fibrosa is rare, and osteoid resorption does not occur.

C. S k e l e t a l R a d i o l o g y o f H V O Structural changes in bone detectable on x-ray result either from increased parathyroid hormone (PTH) secretion or from impaired mineralization. Secondary hyperparathyroidism accelerates net loss of bone from endocortical surfaces, leading to generalized thinning of cortical bone detected either by radiogrammetry or radial photon absorptiometry. 13'51'59 If the loss is rapid, the endosteal surfaces may appear more irregularly scalloped than usual. 42 Increased bone turnover increases cortical porosity, recognizable as cortical striation in the metacarpals and phalanges on high-resolution films of the hands. 6~For a particular level of increase in turnover, the extent of cortical striation remains stable, but if mineralization becomes defective with the transition from HVOi to HVOii, cortical striations accumulate because refilling of resorption tunnels by osteoid does not alter their radiographic appearance. 4 By contrast, cortical thinning is probably retarded by osteoid insulation of the endocortical surface. Phalangeal subperiosteal erosion, the most specific sign of hyperparathyroidism, is not as common as in renal osteodystrophy 4 but in the absence of Looser's zones (see later) may be the most tangible radiographic evidence of osteomalacia, since it is not seen in the usually less severe hyperparathyroidism of HVOi. Very rarely, patients with longstanding intestinal malabsorption develop generalized osteitis fibrosa cystica. 4 In no case has adequate bone histology been performed, so these patients could have undergone progression of HVOi without transition via osteomalacia, as occurs in renal osteodystrophy. The most common radiographic manifestation of impaired mineralization in cancellous bone is a nonspecific reduction in density, 42 usually referred to in the older literature as "demineralization" and in current literature as "osteopenia." Distinctive qualitative abnormalities in

342 trabecular pattern occur only when severe osteomalacia began in childhood, as in celiac disease, or in endemic vitamin D deficiency. 4 Many trabeculae were never formed and those present are more widely and irregularly spaced, and may become thicker and more clearly visible despite their lower mineral concentration. Horizontal lines of increased density in the metaphyses (Harris lines) resulting from resumption of growth after temporary arrest are also frequently seen in such patients. 4 Minor degrees of coarsening, blurring, and loss of detail have often been described but have not been validated by adequate bone histology and are of questionable value in differential diagnosis. 42 In most patients the appearances are indistinguishable from those of moderately severe age-related bone loss. Of greater specificity are changes in bone shape. Minor degrees of protrusio acetabuli, detected by measuring the relationship between the acetabular and ilioischial lines, are much more common in osteomalacia than in osteoporosis. 61 More familiar, although rare in current practice, are changes in the spine, with biconcavity that is symmetrical about the horizontal axis of each vertebra and of similar degree in adjacent vertebrae, contrasting with the irregular distribution of altered vertebral shape in osteoporosis. 2'42 If anterior vertebral height is preserved there is no deformity, but a regular kyphosis with moderate height loss may result from generalized anterior wedging. In some patients with associated osteitis fibrosa, the abnormal vertebral shape is accompanied by irregular end-plate sclerosis as in renal osteodystrophy, but osteosclerosis commonly occurs in osteomalacia only in X L H . 42'62 Bizarre spinal deformities can be seen in advanced endemic osteomalacia, 4 but substantial loss of trunk height with generalized vertebral compression is otherwise rare except in sporadic nonfamilial hypophosphatemia of adult onset, which in contrast to XLH is associated with severe trabecular osteopenia. 62 Osteomalacia in general has been claimed both to increase the risk of the osteoporotic type of vertebral compression f r a c t u r e 63 and to protect against such fractures2; this issue will be discussed in Section II.D. The best known radiographic feature of osteomalacia is the Looser's zone, a lucent band adjacent to the periosteum that represents an unhealed insufficiency type stress fracture. 2'8'42'64 Stress fractures are incomplete fissures without displacement that occur as a result of repeated nonviolent subthreshold trauma; they are commonly divided into fatigue fractures in normal bone subjected to abnormal stress and insufficiency fractures in abnormal bone subjected to normal s t r e s s . 42 In the osteomalacia of cadmium poisoning, the lucent band consists mainly of unmineralized woven bone; during healing, sometimes spontaneous, woven osteoid mineralizes and is replaced by lamellar bone. 65 Looser's zones

A . M . PARFITT

TABLE 1 1--3

Comparison of Classic Looser's Zones and Typical Stress Fractures a Looser's Zone

Stress Fractures

Direction

Perpendicular

Can be oblique

Lucent band

Present

Usually absent

Margins

Parallel

Can diverge

Adjacent bone

Normal

Can be abnormal b

Number

Multiple

Usually single

Symmetry

Present

Absent

Sclerosis

Absent

Present

Visible callus

Absent

Present

Healing

Slow or absent

Rapid

aModified from Parfitt AM: Bone fragility in osteomalacia: Mechanisms and consequences. In Uhthoff H (ed): Current Concepts of Bone Fragility. New York, Springer-Verlag, 1986, pp 2 6 5 -270. bFor example, in Paget's disease.

occur most commonly in ribs, pubic rami, and outer borders of scapulae and less commonly in femoral necks, metatarsals, and shafts of long bones. 1'2 At some sites of predilection, localization may be determined by proximity to arterial pulsation. 4'9 Although occasionally painless, they are more commonly associated with local tenderness and pain on activity. If the lesions are multiple, symmetrical, and perpendicular to the periosteum with parallel margins and, in the absence of treatment, persist without callus or adjacent sclerosis, the diagnosis of osteomalacia is certain, 4 but exact conformity to this complete description (to which the term Looser's zone should perhaps be restricted) is observed in fewer than 5% of patients with osteomalacia in current practice. More commonly the appearances are intermediate in one or more respects between Looser's zones and typical stress fractures 66 (Table 1 1-3). Such lesions can occur in the absence of osteomalacia and so lack diagnostic specificity 8'64 (Fig. 1 1 - 1 1). Indeed, in our recent experience, atypical lucent stress fractures are more often the result of osteoporosis than of osteomalacia, 64 although the relative frequency remains much lower in the more common condition. Looser's zones, like other types of stress fracture, show increased focal uptake on bone scan, which can lead to a mistaken diagnosis of metastatic disease 67 and to a fruitless and sometimes fatal search for a primary tumor. 4

D. Fractures Several types of fracture occur in patients with osteomalacia. 4 Looser's zones, like other types of stress frac-

CHAPTER 11 Osteomalaciaand Related Disorders

343

FIGURE 11-11

Atypical fractures in osteomalacia and osteoporosis. Upper panel, left: metatarsal fracture with central lucency and abundant callus formation in a patient with histologically verified osteomalacia; fight: metatarsal fractures with more organized callus but persistent central lucency in a patient with histologically verified absence of osteomalacia. Resemblance to a classic Looser's zone is somewhat greater in the latter case. Lower panel, left: incomplete fracture on medial aspect of upper femur in a patient with histologically verified osteomalacia; fight: similar fracture in patient with histologically verified absence of osteomalacia. Although subtrochantefic location is more suggestive of osteomalacia, the other characteristics of the fractures do not differ significantly.

ture, can extend to produce a complete fracture with separation or displacement. This is common in the metatarsals and is probably also the mechanism for subtrochanteric fractures in the upper femoral shaft. Multiple rib fractures in osteomalacia have caused death from hemothorax. Occasionally, a greenstick-type fracture can occur in severe osteomalacia, as in rickets. 42 When osteomalacia begins in childhood, the adult bones tend to be soft rather than brittle and fractures are rare; con-

versely, when osteomalacia begins in adult life, fractures are more common, occurring mainly in the extremities. They differ from fractures in a normal skeleton only in needing a lesser degree of trauma, and from fractures in an osteoporotic skeleton only in a more varied anatomical distribution. An exception to this generalization is spontaneous fracture of the sternum, which is virtually confined to adult-onset osteomalacia and myelomatosis (Fig. 11-12).

344

A.M. PARFITT

FIGURE 1 1 - 1 2 Combinationof angulation of sternum due to spontaneous fracture and vertebral biconcavity in a patient with aluminum-related dialysis osteomalacia.

The major factor contributing to increased fracture risk is accelerated loss of cortical bone due to secondary hyperparathyroidism, so that repeated fractures are a common mode of presentation in HVOi. ~3'15 The biomechanical significance of osteoid accumulation and cortical porosity is less clear. In an elderly population the ash content of a vertebral body is highly correlated with its compressive strength, which is equally reduced whether mineralized bone tissue is lost or replaced by unmineralized osteoid. 68 This effect is unlikely to be quantitatively important unless OV/BV exceeds 20%, but could increase vertebral fracture risk in those who have already lost cancellous bone. 63 Conversely, if bone matrix volume is normal, osteoid accumulation could decrease fracture risk by increasing elasticity. 1 Appendicular fractures are less common in HVOii and iii than in HVOi. ~5 This is partly because activity is limited by pain and weakness--indeed, fracture risk increases when these symptoms are relieved by treatment. But the main reason is that loss of cortical bone is less severe. In HVOi the deficit in forearm bone density is about 25%, ~3'15 whereas in HVOii and iii, it is about 17%. 51 This can be explained by more rapid progression and earlier diagnosis, which would reduce the durations of both accelerated bone loss and exposure to increased fracture risk. The role of deficiency and altered metabolism of vitamin D in the pathogenesis of hip and vertebral fractures will be discussed in more detail in Section V.

E. N o n i n v a s i v e I n d i c e s o f B o n e R e m o d e l i n g A bone biopsy gives detailed information about cellular events in a small region but is subject to appreciable sampling variation. 19 By contrast, radiokinetic and biochemical indices reflect the integrated activity of the entire skeleton, but are governed mainly by the frequency of remodeling activation and give no information on individual cell function. In osteomalacia there are increases both in urinary total hydroxyproline, an index of whole-body bone resorption, 69-71 and serum total alkaline phosphatase, an index of whole-body bone formation. 1'2'4'9 Newer indices of bone formation, such as osteocalcin 71 and C terminal collagen propeptide (PICP), 72 are also increased but to a relatively smaller extent. In addition, radiocalcium kinetics often show an increase in accretion, an estimate of bone formation, 4'9 and there are also increases in skeletal uptake of various bone-seeking isotopes such as radiostrontium 73 and technetium-labeled bisphosphonates 74 and in bone blood flow. 75 It is commonly inferred that bone turnover is high in osteomalacia, 9'~~ but this interpretation is at variance with the histomorphometric evidence. One explanation for the discrepancy is failure to differentiate between the different stages in the evolution of HVO. In HVOi, all methods of study are in agreement in showing increases in resorption, formation, and turnover, and it is likely that some patients included in previous reports did not have osteomalacia as rigorously

CHAPTER 11


345 though the distribution of h y d r o x y p r o l i n e - c o n t a i n i n g peptides b e t w e e n different c h r o m a t o g r a p h i c fractions is not altered. 69 M o r e difficult to explain are the increase in serum alkaline phosphatase, osteocalcin, and PICP. There is a high and significant correlation (r > 0.8) b e t w e e n log serum bone-specific alkaline phosphatase and log urinary hydroxyproline/creatinine in normal subjects and in several generalized disorders of bone. The regression slopes were similar, but in osteomalacia, alkaline phosphatase was higher relative to urinary h y d r o x y p r o l i n e than in any other condition. 78 Alkaline phosphatase also correlates (r > 0.7) with radiostrontium uptake in osteomalacia due to vitamin D depletion 79 but not with bone blood flow. 75 Matrix apposition rate in osteomalacia is reduced, but total matrix synthesis could be increased, balancing the increase in unmineralized matrix resorption; this could account for the significant correlations b e t w e e n several indices of osteoid accumulation and both serum alkaline phosphatase 8~ and osteocalcin. 71 Since osteocalcin is incorporated into b o n e matrix after mineralization begins, failure of mineralization w o u l d divert m o r e osteocalcin into the circulation, vl Inappropriate release of alkaline phosphatase might also reflect a disorder of osteoblast function induced by excess PTH, since aluminum-related osteomalacia in dialysis patients is usually a c c o m p a n i e d by relatively low levels of both P T H and alkaline phosphatase. 81

defined, but rather p r e o s t e o m a l a c i a with the histological, biochemical, and kinetic c o n s e q u e n c e s of secondary hyperparathyroidism. 58 But other patients in the cited studies had u n d o u b t e d osteomalacia despite lack of adequate histology. A n o t h e r possibility is the local increase in cellular activity in relation to healing fractures, as mentioned in the previous section. There m a y also have been inadvertent inclusion of patients in the early stages of healing when histologically determined formation rates are very high, but this is unlikely in patients needing a pharmacological rather than a physiological dose of vitamin D. Furthermore, in patients studied by double tetracycline labeling, the level of serum alkaline phosphatase increases with the severity of the mineralization defect, and is highest w h e n active mineralization has ceased 15 (Table 1 1 - 4 ) . Apparently increased kinetic accretion can probably be accounted for by the presence of significant amounts of bone of low mineral density and increased permeability, since this will enhance short- and m e d i u m - t e r m e x c h a n g e of radioactive calcium or strontium that m a y be impossible to differentiate from accretion without extended observation. 21 Increased uptake of labeled bisphosphonate correlates with serum alkaline phosphatase but not with radiocalcium k i n e t i c s . 74 It has been proposed that the bisphosphonate binds to some constituent of bone matrix and so is an index of osteoid accumulation with or without mineralization, 76 but in aluminumrelated osteomalacia, bisphosphonate uptake is low despite abundant osteoid. 7v Total h y d r o x y p r o l i n e excretion is highest in patients with subperiosteal erosion, 69 and could reflect P T H - m e d i a t e d resorption of unmineralized osteoid 54 even if the absolute level of resorption of mineralized bone was normal or even reduced. Utilization of n e w l y synthesized collagen might be defective, 4 al-

TABLE 11--4

F. A b n o r m a l i t i e s

of Bone Mineral Metabolism in H V O

The cardinal metabolic abnormality is reduced net intestinal absorption of c a l c i u m . 1'2'4-6'1~ Fecal calcium ex-

B i o c h e m i c a l Evolution of H V O

Normala (n = 23)

___2.1 ___0.5 _ 4.7(11) _ 0.11t

50.5 6.8 39.1 7.95

_ 6.3 _ 0.9(10) _ 3.7(8) ___0.39*

HVOiii (n = 28)

60.3 27.3 40.8 9.64

Plasma phosphate (mg/dl)

3.47 _ 0.08

3.36 +__0.11

2.91 _ 0.23*

2.64 _ 0.13

Plasma Ca • P (mg/dl)2

33.5 ___0.7

30.7 _ 1.1"

23.3 _ 1.6'

21.2 _ 1.2

Alkaline phosphatase (IU)

82.8 _ 3.9

132 _ 7.2t

201 +__31.1

284 _ 24.2*

4.01 _ 0.34

6.62 _ 0.79

5.94 _ 0.61

2.0 _ 0.26

57.2 6.0 46.0 9.12

HVOii (n = 11)

Age (years) Plasma calcidiol (ng/ml) Plasma calcitriol (pg/ml) Plasma calciums (mg/dl)

NcAMP (nM/dlGF)

+__ 1.3 ___3.0 +__6.9 _ 0.08

HVOi (n = 26)

58.1 4.1 21.7 8.02

___2.4 +__0.6(18)* _ 3.2(10) t _ 0.17

aVolunteers for bone biopsy. bCorrected for albumin. Stages defined as in Table 11-2. Number of analyses shown in parentheses when less than number of subjects. Data shown as mean _ SE. Significance levels shown for difference in mean values from column immediately to the left. *p < 0.05, *p < 0.01, *p < 0.001.

346 cretion is close to and can even exceed dietary intake, but urinary calcium is low and calcium balance rarely more negative than - 1 0 0 mg/day. 82 There is an equimolar deficit in net absorption of inorganic phosphate, but the relative change is much smaller. ~ According to the usual interpretation, calcium malabsorption leads in sequence to a fall in plasma calcium, secondary hyperparathyroidism, reduced renal tubular reabsorption of phosphate, hypophosphatemia, and reduction in calcium • phosphate product, which falls even further with the advent of more severe hypocalcemia. Eventually, deposition of mineral in osteoid is impaired because the supply of the relevant ions is reduced, and the alkaline phosphatase then rises. This traditional scheme requires considerable modification with regard to the order in which the changes occur, their pathophysiology, and their diagnostic significance. In HVOi, the mean plasma calcium is slightly reduced, but the individual values are almost always normal (Table 1 1-4). There is no adult counterpart to the early hypocalcemia of infantile nutritional rickets, 83 which reflects difficulty in releasing calcium from the rapidly growing skeleton, and is only rarely observed in older children. 84 PTH secretion is increased as shown both by radioimmunoassay 85-88 and by excretion of nephrogenous cyclic adenosine monophosphate (cAMP) ~5 (Table 11-4). Although mean TmP/GFR and plasma phosphate are both slightly reduced, individual values are usually normal. Twenty-four-hour urinary calcium excretion and fasting urinary calcium/creatinine are often but not invariably reduced. 85 As already mentioned (see Section II.E), a moderate elevation of alkaline phosphatase is the most consistent abnormality, but can be absent in subjects without osteopenia. 86 Unlike the various types of osteomalacia with hypophosphatemia due to n o n PTH-dependent defects in tubular phosphate reabsorption (referred to for convenience as primary), Albright and Reifenstein's first stage of "chemical osteomalacia with normal phosphatase ''89 does not occur during the evolution of HVO. The vitamin D metabolite levels depend on the etiology. In extrinsic vitamin D depletion the plasma calcidiol level at which abnormal mineral metabolism can first be detected in an individual is usually below 5 ng/ ml, 5'1~ but in subjects with values between 5 and 10 ng/ml there is a slight but statistically significant depression of mean plasma calcium and phosphate and urinary calcium and elevation of PTH, 85'87and most patients with histologically verified HVOi have calcidiol values in this range 15 (Table 11-4). With calcidiol values between 10 and 20 ng/ml, some subjects have a state of vitamin D insufficiency, in which calcidiol administration is followed by increases in serum calcitriol and calcium absorption, responses which do not occur in pa-

A.M. PARNTT tients with vitamin D sufficiency. 1~ In patients with intrinsic vitamin D depletion, the complete biochemical, histological, and bone densitometric syndrome of HVOi can occur at plasma calcidiol level between 10 and 20 ng/ml, 15 presumably because there is an independent mechanism for calcium malabsorption and consequent secondary hyperparathyroidism that is unrelated to vitamin D. Increased PTH secretion accounts for the normal mean level of plasma calcitriol. Although not evident from Table 11-4, which reports only data from patients who had bone biopsy, it is likely that in the earlier stages of intrinsic HVOi, plasma calcitriol levels are increased, 9~ as can also occur in anticonvulsanttreated patients. 9~ Further discussion of this will be postponed until Section III. Normal calcitriol levels in patients with extrinsic deficiency 7~'85 are even more puzzling, since in such patients the malabsorption of calcium that is thought to be the initial event is without obvious explanation. These paradoxes will be discussed later in relation to pathogenesis. With progression to HVO stages ii and iii, in general all the biochemical abnormalities become more severe. Plasma and urinary calcium, TmP/GFR, and plasma phosphate levels become lower, and PTH, NcAMP, and alkaline phosphatase levels become higher ~5 (Table 1 1 4), but there are many individual exceptions. PTH hypersecretion and parathyroid gland hyperplasia occur in response not only to hypocalcemia but to the independent stimulus of calcitriol deficiency. 92 Patients with severe hyperparathyroidism may get impaired tubular reabsorption of bicarbonate and amino acids as well as phosphate, resembling proximal renal tubular acidosis or the Fanconi syndrome, 4'~~ except for increased rather than decreased tubular reabsorption of calcium. Hypophosphatemia is adequately explained by increased PTH secretion without the need to postulate an additional effect of vitamin D metabolite deficiency. 47 Indeed, for the same increase in NcAMP, TmP/GFR is higher in secondary than in primary hyperparathyroidism because of the independent effect of plasma calcium on phosphate reabsorption. 43'93 Hypophosphatemia is of significantly lesser degree of HVO than in primary impairment of phosphate reabsorption, for both mean values and the frequency of individual low values. 1'41'94 Separation between the two groups is even clearer when the inverse relationship between TmP/GFR and NcAMP is considered. 43'47 Conversely, both individual and mean values for plasma calcium are almost always normal in patients with primary hypophosphatemia. The mean calcidiol level is not significantly lower in HVOii than in HVOi, but does fall further in HVOiii (Table 11-5). By contrast, the calcitriol levels can be normal in stage ii and do not become consistently subnormal until stage iii. Others have also found both normal and subnormal cal-

CHAPTER 11 Osteomalacia and Related Disorders

347

TABLE 11--5 Contrasting Features of Two Main Etiological Categories of Osteomalacia Primary Disorder Vitamin D Plasma calcium Plasma phosphate PTH secretion Alkaline phosphatase Osteoclast surfaceb Osteitis fibrosa Cortical thickness Cancellous volume

N or ,l, N or %a 1" or 1"1" 1"1" 1"1" Frequent $$ N or $

Phosphate N %%

N or 1" 1" 1" Rare $ 1" or $c

aOccasionally increased. bDifference clearer if referent is bone surface rather than mineralized surface. OVaries with type. N, normal: 1", $ change mild or slight; 1"1",$$ change severe or marked.

citriol levels in osteomalacia, although not classifying their cases in the same manner. 71'8~ In either HVOii or HVOiii, a minority of patients present with hypocalcemic tetany, often with absence of bone pain and radiographically less severe bone d i s e a s e . 4-6'43'79'95 Whether this is a pathogenetically distinct syndrome or simply one end of a spectrum is unclear, although probit analysis of plasma calcium values indicates two populations, 1 and in adolescent patients the values are bimodally distributed. 5 Because of lesser depression of phosphate reabsorption, higher than expected plasma phosphate, lower alkaline phosphatase, and lower incidence of phalangeal subperiosteal resorption, absence of the expected increase in PTH secretion was postulated. 4'79"89This has been refuted, although PTH assays (greater increase in normocalcemic patients) 95 and NcAMP excretion (greater increase in hypocalcemic patients) 43 have given different results. Patients with severe hypocalcemia are resistant to the effect of PTH, on both calcium release from bone and on tubular phosphate reabsorption but maintain a normal cAMP response to endogenous and sometimes exogenous P T H . 43'95-97 The biochemical resemblance to pseudohypoparathyroidism type II is even closer in patients with absolute rather than relative hyperphosphatemia, 95-97 especially if the cAMP response to exogenous PTH is impaired, 97 as may result from increased receptor occupancy. 98 The syndrome has been attributed to magnesium depletion, 1~ but this is only rarely the explanation, a3 The effect of PTH on phosphate reabsorption is blunted by

hypocalcemia, and is restored by treatment that raises the plasma calcium, 4'43 so that plasma calcium and phosphate levels change in opposite directions (instead of in the same direction, as in the usual response). 5 The role of a relative failure to increase tubular reabsorption of calcium in response to PTH 47 is difficult to assess. In vitamin D-deficient monkeys, the syndrome can be reproduced by reducing dietary calcium intake to about 5% of normal, '~176 but in osteomalacic patients no such clear relationship to dietary calcium intake is evident. 4'6 Neither insulation of bone surfaces by osteoid nor defective osteoclastic bone resorption accounts for severe hypocalcemia, since no histological difference was found between osteomalacic patients with low or with normal plasma calcium levels, 43 and some patients with the syndrome have radiographic as well as histological evidence of osteitis f i b r o s a . 95'96 Furthermore, PTHmediated resorption of cultured bone is unaffected by vitamin D deficiency, l~ There appears rather to be a failure of the calcium homeostatic system in bone, a system based not on osteoclastic bone resorption but on equilibration at quiescent bone surfaces. 21 The failure is unexplained, but its frequency during adolescence may be related to rapid skeletal growth. 5 The same mechanism operating with varying severity is probably the most important factor in all degrees of hypocalcemia in H V O . 1'47 The rarest and least well understood biochemical abnormality in HVO is hypercalcemia. 4 '95 .,02 Affected patients invariably have substantial parathyroid enlargement and high PTH levels and usually have radiographic osteitis fibrosa. Hypocalcemia is the primary stimulus to parathyroid cell proliferation as well as hormone secretion102; progression to hypercalcemia indicates that excessive cell proliferation has continued beyond the point needed to restore normocalcemia, in response to a different stimulus. The nature of the stimulus has not been established in vitamin D deficiency, but study of the analogous situation in chronic renal failure has suggested several possible mechanisms. These include calcitriol deficiency, loss of calcitriol receptors in parathyroid cells, and an increase in PTH secretory setpoint, '~ each of which could account for hypercalcemic secondary hyperparathyroidism. Because increased cell proliferation increases the probability of a mutation, 1~ some patients develop parathyroid adenomas. 102 ' 104 It is to such cases, that combine the hyperplasia of secondary hyperparathyroidism with the monoclonality of primary hyperparathyroidism, that the term "tertiary hyperparathyroidism" should be restricted. '~ In regions where vitamin D deficiency is endemic, it may be impossible in individual patients to distinguish between tertiary hyperparathyroidism as defined and coincidental primary hyperparathyroidism, '~ which may intensify vitamin D deficiency 106 by increasing the hepatic catabolism of calcidiol. In

348

A.M. PARFITT

either case, vitamin D deficiency may blunt the severity of the hypercalcemia, which may become evident only after vitamin D administration. 4'85

G. Summary of Temporal Evolution of HVO In HVOi or preosteomalacia, there are characteristically no symptoms until a fracture occurs, which is the main reason why the existence of this intermediary stage was unrecognized for so long. The only biochemical abnormality that would be revealed by routine screening is a raised plasma alkaline phosphatase. Both fasting and 24-hour urinary calcium excretion are usually reduced. Skeletal radiographs are either normal or show only nonspecific osteopenia, but bone densitometry reveals that age-related loss of bone is accelerated, especially appendicular cortical bone but also axial trabecular bone, with a corresponding increase in fracture risk. Plasma calcidiol is usually but not invariably low. There is both biochemical and histological evidence of secondary hyperparathyroidism and of increased bone turnover. Defective mineralization is either absent or no more severe than in primary hyperparathyroidism. Despite the lack of symptoms, lifelong treatment with some form of vitamin D is necessary to reduce PTH secretion to normal and prevent further irreversible bone loss. As mentioned earlier, the deficit in forearm bone density is greater in HVOi than in HVOii and iii despite less severe hyperparathyroidism (Table 11-5). This can only be explained by slower progression and consequent longer duration of accelerated cortical bone loss and increased fracture risk. It is likely that some patients remain arrested at this stage; a few progress to more severe hyperparathyroidism with radiographic osteitis fibrosa; but others eventually develop the complete clinical, biochemical, radiographic, and histological syndrome of osteomalacia. However, it may reasonably be assumed that all patients in stages ii or iii at the time of diagnosis traveled earlier through stage i.

H. Diagnostic Considerations As in all fields of medicine, the most important step in diagnosis is to keep the condition in mind in the appropriate clinical settings, which will be described in Section IV. In each setting the diagnostic value of a measurement must be independently validated and cannot be inferred from its importance in pathophysiology. But some aspects of diagnosis are logically considered here, because the existence of HVOi or preosteomalacia has

an important beating on the diagnostic process. Although crucial to understanding the disease, distinction between the different stages in the evolution of HVO is not essential for diagnosis, since it should not usually influence the decision to treat an individual patient with vitamin D. Consequently, the aim of diagnosis should be to identify HVO as early as possible in its evolution. Unfortunately, most diagnostic algorithms 49'50'94'107'108have been based on the erroneous assumption that only osteomalacia, defined rather strictly, needs treatment and hence recognition. The aim of preventing both occult bone loss and overt disease is best served by applying tests of high sensitivity (the probability of an abnormal result in a patient with disease) to the screening of populations at increased risk, 8'1~ even if such tests are of low specificity (the probability of a normal result in a patient without disease). Current commercial assays for intact PTH can easily detect modest increases due to mild vitamin D deftciency. 87'88 Other good screening tests are the plasma levels of total alkaline phosphatase and of calcidiol. For many tests, but especially alkaline phosphatase and urinary calcium, sensitivity is reduced by a large coefficient of variation, so that a biologically significant change could have occurred in an individual even though the result is still within the wide reference range. Sensitivity for alkaline phosphatase can be improved by more careful attention to sex and age differences, and both sensitivity and specificity can be improved by measurement of the bone-specific component. A low plasma calcidiol level is a poor predictor of bone histology,4'1~176just as a low vitamin B12 level is a poor predictor of bone marrow histology. Nevertheless, it is the best available index of suboptimal vitamin D nutriture and consequent increased risk of HVO. For the diagnosis of established osteomalacia without resort to an invasive procedure, test specificity is more important than sensitivity. 8 From this standpoint no test is very efficient when considered alone, especially in the very old in whom other causes for abnormal results are more prevalent. 11~ Nevertheless, if the plasma calcium and phosphate levels (or calcium • phosphate product) are low and the alkaline phosphatase is high, osteomalacia is likely, 1~ and if all three values are normal it is unlikely. ~1~Between these extremes, the diagnostic value can be improved by various discriminant functions based on biochemical values alone 94'1~ or combined with clinical and radiographic features. 1~ But the validity of any particular discriminant function depends on the prevalence of the condition of interest in a specific community and will not be the same in a young adult with suspected migrant osteomalacia, a nursing home resident with a hip fracture, or a patient with some form of intestinal malabsorption.

CHAPTER 11 Osteomalacia and Related Disorders

349

III. ETIOLOGICAL CLASSIFICATION AND PATHOGENESIS OF OSTEOMALACIA Osteomalacia can occur in diverse clinical settings, but in most types there is either a primary disorder of vitamin D metabolism or a primary ( n o n - P T H dependent) defect in the renal tubular reabsorption of phosphate. 5'8-1~ In the former, hypocalcemia and secondary hyperparathyroidism are usual and hypophosphatemia mild, whereas in the latter normocalcemia is the rule, secondary hyperparathyroidism is slight or absent, and indices of bone turnover are less increased but hypophosphatemia more severe (Table 11-5). In some forms of primary hypophosphatemia there are separate but interrelated disorders of both vitamin D and phosphate metabolism. Less common etiological categories are the presence of a mineralization inhibitor, a primary abnormality of bone matrix, or a defect in alkaline phosphatase.8-10

A. Overview of Defects in Vitamin D Metabolism Vitamin D metabolism can be affected at one of six levels (Table 11-6). Identification of the level is important in planning treatment, although the summation of independent factors at several levels may be needed to produce clinical effects, and some diseases affect more than one level. Each level is associated with a characteristic profile of vitamin D metabolite concentrations in blood (Table 11-6), but these must be interpreted with caution, since changes in vitamin D - b i n d i n g protein (DBP) can alter total concentrations without altering free

TABLE 11--6

concentrations. 111'112 Body stores of vitamin D, located mainly in fat and to a lesser extent in muscle, are derived either from the photochemical production in skin of cholecalciferol or from dietary intake and intestinal absorption of either chole- o r e r g o c a l c i f e r o l . 47"113'114 Although the former source is more physiological, 115 with current lifestyles the latter is equally important. 116 The distinction was made earlier between extrinsic vitamin D depletion, due to some combination of reduced skin synthesis and reduced intake, and intrinsic depletion, due to intestinal malabsorption of vitamin D, augmented by an additional mechanism for increased fecal loss of vitamin D . 117 Two infrequently emphasized features of normal vitamin D metabolism are relevant to the pathogenesis of osteomalacia: first, its wastefulness in normal circumstances, 5 and second, its susceptibility to disruption by calcium deficiency. ~8 Metabolic pathways leading from calciferol to calcitriol have been extensively investigated but are preferentially followed only when body stores are greatly depleted. Normally, about 70% of the daily supply of both calciferol and calcidiol is converted to more polar metabolites of low or absent biological activity that undergo biliary and eventually fecal excretion, 5 so that only about 10% of available calciferol is used for calcitriol production. The proportion following the alternate pathways can decrease to very low levels when necessary but increases to 90% for calciferol and 99% for calcidiol in vitamin D - t r e a t e d hypoparathyroidism. ~9 Despite their quantitative importance in overall vitamin D economy, little is known about either the metabolites formed or their mechanism of production, and even less about how distribution between different pathways is regulated. Because of the usual wide margin of safety, malabsorption of dietary vitamin D is rarely of sufficient se-

Possible Levels of Disturbances of Vitamin D Metabolism Plasma Metabolite Concentration

Level

Calciferola

Calcidiol

Calcitriolb

Extrinsic depletion Intrinsic depletion Impaired 25-hydroxylation Increased catabolism Impaired 1-hydroxylation Receptor defect

$ $ N ($)c N N

$ $ $ $ N N

N or $ N or $ N or $ N or $ $ 1"

alnferential, few measurements available. bMay be increased if there is a vitamin D-independent mechanism for reduced intestinal calcium absorption and secondary hyperparathyroidism.5 CDepends on compound affected.

35

0

A

verity to be the sole mechanism responsible for vitamin D depletion. The first additional mechanism to be proposed was interruption of a conservative enterohepatic circulation of calcidiol. 12~ This proposal accounted for depletion of vitamin D of dermal as well as dietary origin, but the magnitude of this pathway in human subjects, if it occurs at all, is much too small to fulfill its postulated role. 5'121 It now seems much more likely that the additional mechanism is accelerated catabolism of calcidiol in the liver initiated by calcium deprivation, 122 whether due to dietary deficiency or intestinal malabsorption. This effect is mediated by secondary hyperparathyroidism, either as a direct effect of increased circulating PTH 118'123'124or as an indirect effect of increased serum levels of calcitriol. 118'125 This mechanism explains the occurrence of vitamin D deficiency in geographic regions with high sun exposure but low calcium intake, 118 and contributes to vitamin D deficiency in a variety of gastrointestinal disorders. 5 The hepatic 25-hydroxylation of calciferol to calcidiol provides the principal transport form of vitamin D and an additional component of body stores, located mainly in m u s c l e . 113'114 This process is impaired in cirrhosis of the liver, 126 but rarely to a level that causes osteomalacia (unless there is also malabsorption, as in biliary cirrhosis) because the liver has such a large reserve capacity. 114 Significant calcidiol deficiency that is not due to depletion of its precursor is most commonly the result of increased catabolism to biologically inactive metabolites from drug-induced enzyme induction, 127 or from stimulation of existing enzymes by calcitriol o r P T H . 122'125 Loss of calcidiol bound to protein (both DBP and albumin) occurs in the nephrotic syndrome and leads to secondary hyperparathyroidism and osteoid accumulation in the absence of impaired renal f u n c t i o n . 128'129 A similar mechanism operates during continuous ambulatory peritoneal dialysis (CAPD), and urinary loss of calcidiol is also increased in patients with biliary cirrhosis.

114

Calcitriol deficiency with normal body stores of vitamin D is most commonly the result of chronic renal failure, but can also be due to a genetic defect in renal lt~-hydroxylation, referred to as hereditary hypocalcemia or vitamin D dependency type I. Plasma calcitriol levels are reduced by magnesium depletion, 114'13~ but osteomalacia as a consequence has not been demonstrated. Calcitriol synthesis is impaired by deficiency of PTH, but it is doubtful whether this causes osteomalacia, possibly because bone turnover is so low. 85 In a case be131 lieved initially to exemplify this relationship, the patient was subsequently found to have concurrent X L H . 132 However, there is one adequately documented case of osteomalacia due to pseudohypoparathyroidism with secondary hyperparathyroidism. 133 Very low plasma cal-

.

M. PARFITT

citriol levels are found during prolonged total parenteral nutrition, but have not been clearly related to the presence or type of metabolic bone disease. TM Finally, calcitriol may be ineffective because of one of several kinds of defect in its receptors, referred to as vitamin D dependency type II. Hereditary defects in calcitriol synthesis or receptor binding will not be considered further as causes of osteomalacia in this chapter. The role of such defects in the pathogenesis of age-related bone loss and fractures is discussed briefly in Section V.

B. O v e r v i e w o f D e f e c t s in Phosphate Metabolism The plasma phosphate level is regulated mainly by the tubular reabsorption of phosphate, best expressed as the mean renal threshold (TmP/GFR). 135 Intestinal absorption is much more efficient for phosphate than for calcium, net intestinal phosphate absorption remaining positive even with severe intestinal mucosal disease or with a large reduction in dietary intake. 47 Only if net absorption falls below 50 mg/day and the tubular transport mechanism is operating on the splay portion of the curve between the appearance and mean thresholds 135 can there be a sustained fall in plasma phosphate level below 2.5 mg/dl. Consequently, whole-body phosphate depletion sufficient to cause osteomalacia occurs only when net intestinal phosphate absorption becomes negative as a result of prolonged ingestion of large doses of phosphate-binding aluminum salts used as antacids. 136 With this exception, chronic hypophosphatemia causing osteomalacia is invariably the result of a low renal phosphate threshold. When not due to hyperparathyroidism, primary or secondary, reduced phosphate reabsorption can be either a solitary or principal defect, with or without glucosuria and/or glycinuria, or one component of the Fanconi syndrome 47 (Table 1 1-7). This term refers to a global disorder of proximal tubular function with glucosuria, generalized aminoaciduria, and impaired reabsorption of bicarbonate, urate, and less commonly, potassium, calcium, and sodium. Either type can be hereditary, usually presenting in infancy or early childhood, or nonhereditary, occurring at any age but most commonly during adolescence or adulthood. This simple approach to classification breaks down in some causes of the Fanconi syndrome, such as galactosemia or cystinosis, in which proximal tubule function is affected, not directly but as an indirect consequence of a nephrotoxic substance that accumulates in abnormal amounts because of a genetically determined enzyme defect that is unrelated to renal tubular transport. The classic form of hereditary hypophosphatemia is familial hypophosphatemic vitamin D-refractory tickets

CHAPTER 11 Osteomalacia and Related Disorders TABLE 1 1 - 7

351

Classification of Primary (non-PTH-Dependent) Defects in Tubular Reabsorption of Phosphate Causing Osteomalacia Plasma Calcitriol

Type Phosphate alone -L-_glucose

Hereditary Nonhereditary

Multiple (Fanconi syndrome)

Hereditary Nonhereditary

Classic Hypercalciuric Tumor-induced b Idiopathic

Normal a High Low Low c

Primary d Secondary e Internals External g Idiopathic

Low c Low c Variable Unknown Low c

relative to plasma phosphate. bProbably includes fibrous dysplasia and neurofibromatosis. CData inconclusive. dReduced reabsorption as a direct consequence of the genetic defect. eReduced as an indirect consequence of the genetic defect, via accumulation of a nephrotoxic agent such as cystine or galactose. SResulting from extrarenal disease, such as light-chain nephropathy. gResulting from the harmful effect of a drug or environmental toxin; except for cadmium, such agents usually do not cause osteomalacia. aLow

(or osteomalacia), often referred to as XLH because of the most common mode of inheritance. 62 Plasma calcitriol levels in the untreated state are normal for the rate of growth, but are lower than expected for the degree of hypophosphatemia 137 (Table 1 1-7). In a clinically similar disorder, hereditary hypercalciuric hypophosphatemia, the expected increase in plasma calcitriol levels occurs, leading to increased intestinal absorption of calcium. 138 In nonhereditary hypophosphatemia, most commonly due to a mesenchymal tumor, both symptoms and bone disease are more severe, and there is an absolute, not just a relative, deficiency of calcitriol. 139 There are numerous causes of the Fanconi syndrome, but most cases in adults leading to osteomalacia are either idiopathic or the result of light-chain nephropathy. 14~Limited data suggest that in the Fanconi syndrome, whether hereditary or acquired, the plasma calcitriol level is usually low, either relatively or absolutely. 47'~41 Renal tubular acidosis can be either a component of the Fanconi syndrome or unaccompanied by other primary defects in tubular reabsorption. 47 In the latter condition, the frequency and severity of hypophosphatemia are slightly greater than in vitamin D depletion, but less than in other types of hypophosphatemic osteomalacia. 1 There is no evidence for either absolute or relative calcitriol deftciency, 142 and it is possible that metabolic acidosis impairs mineralization directly, as well as by reducing phosphate reabsorption. Finally, severe hypophosphatemia probably accounts for the rare occurrence of osteomalacia in primary hyperparathyroidism without vitamin D deficiency, and after renal transplantation. 4

C. P a t h o g e n e s i s o f D e f e c t i v e M i n e r a l i z a t i o n Despite much progress 143 we still lack a complete understanding of how and why biological mineralization normally occurs only in some types of connective tissue and under close temporal and spatial control. Consequently, the pathophysiology of osteomalacia at the physicochemical, molecular, and cellular levels can be discussed only in a provisional and somewhat speculative manner. But several important general principles are known with reasonable certainty. 3 "8 58 ' 135 .143First, calcium, phosphate, and carbonate ions must be supplied and hydrogen ions removed for mineralization to occur. Second, the thermodynamic activities of the relevant ions in the fluid phase at sites of mineralization are influenced by, but are not the same as, those in the systemic extracellular fluid. Third, concentration gradients for the relevant ions between mineralizing and nonmineralizing sites can be maintained by cells (osteoblasts in bone or chondroblasts in cartilage), by structures derived from the cells, such as matrix vesicles, and by the ion-binding properties of macromolecules synthesized by the cells. Fourth, as well as chelating calcium, diverse proteins can have many other effects on mineralization, some positive and some negative. Fifth, the exact chemical composition and three-dimensional structure of connective tissue matrices are the most important determinants of where and when mineralization can occur. Although collagen is the most important matrix constituent, other structural proteins such as fibronectin and sialoprotein are also essential. Finally, there are differences as well as similar-

35

2

A

ities between the mineralization of growth plate cartilage and bone, TM which explain why rickets and osteomalacia can, under some circumstances, vary independently in severity and in response to treatment. 145 The role of vitamin D in sustaining normal mineralization has given rise to two related controversies. 146'147 First, is the action of vitamin D mediated solely by changes in the calcium and phosphate concentrations in E C F , 4'148 o r does it influence mineralization more directly? 4'149 Second, is calcitriol the only metabolite of physiological importance, other than as a precursor,85'148'15~ or must some other metabolite also be considered? 4'~49'151 In both cases the contestants have often failed to recognize the difference between an essential function that confers an absolute requirement and a contributory function that confers only a relative requirement. There is evidence that the morphological effects of vitamin D deficiency can be corrected by giving enough calcium and phosphate intravenously both in man 152 and in the rat, and that defects 153 in calcitriol receptor binding can also be bypassed by providing sufficient mineral substrate. ~54'~55 In the clinical studies the evidence is inconclusive 156 but if taken at face value then vitamin D is clearly not essential for mineralization. Nevertheless, it could have a direct action on bone cells that contributes 4 135 149 to the process in normal circumstances.' ' Similarly, calcitriol alone can completely prevent or correct all the effects of vitamin D deficiency both in humans 4'157'158and in the r a t , 159'16~ claims to t h e c o n t r a r y 149'151 reflecting the inability of intermittent oral administration to sustain an adequate blood level. 159 Clearly, other metabolites are not essential, but it remains possible that one or more contributes to the evolution and reversal of defective mineralization. Alternatively, locally produced as well as systemic calcitriol could be involved. 1.

E V I D E N C E FOR D I R E C T AS W E L L AS I N D I R E C T

E F F E C T S OF V I T A M I N D

A plasma total Ca • P product, in (mg/dl) 2, of less than 30 is a useful guide to the presence of infantile nutritional rickets, 4'~~ but in older children and adults there is rarely such a consistent relationship between the plasma composition and the state of mineralization. 1'2'4'5'8'161 There are significant correlations between plasma phosphate and adjusted apposition rate and between plasma calcium and mean osteoid thickness, 162but their magnitude is too low for useful prediction in individual patients. Calculation of an ion product more clearly related to the physical chemistry of bone mineral may remove some discrepancies,4 but many remain. A more serious flaw in this line of reasoning is that single measurements in the fasting state, as in normal clinical practice, do not adequately represent body fluid composition because of the substantial circadian varia-

.

M. PARFITT

tion. 21'163 Nevertheless, it seems unlikely that such variation could account for the absence of osteomalacia in some patients with a degree of persistent hypophosphatemia that in other patients would be regarded as a sufficient explanation for their osteomalacia. 162"164 Even in the rat, a species in which mineralization probably depends more closely on plasma composition than in humans, healing of rickets can be detected radiographically in response to vitamin D administration while the Ca • P product is still subnormal. 16~ The persistence in early osteomalacia of some doubly-labeled surfaces with normal or only moderately reduced rates of mineral apposition (see Section I.H) indicates that mineralization can proceed at the beginning of the osteoid seam lifespan, although it ceases prematurely. Mineralizing and nonmineralizing osteoid seams are often close together, sometimes even in direct continuity, and are exposed to the same microcirculation, so that the difference between them cannot be explained in terms of chemical changes alone. But at doubly-labeled seams a higher proportion of the surface is lined by osteoblasts, 35'165 suggesting that these cells, possibly in conjunction with the osteocytes derived from them lying within the osteoid, 166 are able to promote mineralization in the face of a moderate reduction in plasma ion product, but do so for a shorter period of time than normal in vitamin D depletion. When this function is lost, mineralization ceases even though matrix apposition continues slowly and the osteoid seam gets progressively thicker. In more severe osteomalacia, osteoblasts are fewer or absent altogether, 57 mineralization never begins, and double labels are not found. A similar relationship is observed during t r e a t m e n t u t h e recovery of mineralization in response to calcitriol administration, indicated by double labeling, occurs preferentially at surfaces where new osteoblasts have appeared. 167"168 The bone histological data in patients with osteomalacia strongly suggest that deficiency of calcitriol (and possibly also other metabolites) impairs some function of the osteoblast that favors mineralization. This proposal is consistent with the presence in osteoblasts of calcitriol receptors, 169 the autoradiographic localization of labeled calcitriol in osteoblast nuclei, 17~ the stimulation by calcitriol of the in vitro production by osteoblasts of alkaline phosphatase 171 and osteocalcin, 172 the in vivo enhancement by calcitriol of mineral apposition rate in young m i c e , 173 and the morphological changes induced by calcitriol in the cells lining quiescent bone surfaces 174 that are of osteoblast lineage. 19 It is also consistent with the abnormalities in collagen cross-linking and other changes in bone matrix maturation and composition that 28 146 have been found in vitamin D deficiency, ' although it is less clear that these are the result of a direct rather than an indirect effect of vitamin D on osteoblast func-

CHAPTER 11 Osteomalacia and Related Disorders tion. The proposal is also not in conflict with the evidence that unphysiologically high doses of calcitriol given to growing rats inhibit several aspects of osteoblast function and in some circumstances may even impair mineralization and lead to osteoid accumulation, 4'5'175 accounting for the paradoxical osteomalacia of prolonged hypervitaminosis D . 176 The usual approach to mineralization has been to study the physical chemistry of the solution in which the ions originate, and the events taking place in bone, and to largely ignore what happens in between. But the circulating ions have to traverse a rather complex pathway before they arrive at the site of mineralization (Fig. 11-13). Having left the capillary and diffused through marrow connective tissue, they must pass through a layer of osteoblasts and a layer of osteoid before they can reach the site of mineral deposition. Osteoblasts on the surface, osteocytes within the osteoid, and osteocytes within mineralized bone are joined by a communicating network of cellular processes within the canaliculi. Very little is known about how mineral ions actually travel through this complex structure, but it would be surprising if cellular transport mechanisms of some kind were not involved in the movement of ions from the extracellular fluid to the site of mineral deposition. Indeed, it

353 seems likely that calcitriol could stimulate the inward transport of calcium and/or phosphate ions through or between cells at sites of mineralization, 47'85 consistent with its known effects on the cells of the intestinal mucosa and possibly the renal tubule. The osteoblast thus influences mineralization in two ways, by its effects on matrix maturation, and by its effects on mineral transport. 5'9 Furthermore, calcium and phosphate ions must be regarded not just as substrates for apatite formation but as part of the environment of the cell which is involved in their transport, since osteoblast function is influenced by the circulating and presumably also local levels of calcium 3~ and phosphate. 5'162 The concept that mineralization normally depends both on the availability of substrate ions via the circulation and on the activity of osteoblasts, although by no means rigorously established, enables all the apparently conflicting data, laboratory and clinical, to be reconciled. The concept has the additional merit of providing a basis for unifying the pathogenesis of all major forms of osteomalacia, since hereditary or acquired defects in phosphate transport across the renal tubular epithelium that covers all bone s u r f a c e s . 47'177 2. EVIDENCE THAT THE EFFECTS OF VITAMIN D ARE NOT MEDIATED SOLELY BY CIRCULATING C A L C I T R I O L

FIGURE 1 1--13

Biochemical and morphological approaches to mineralization. On the left are shown the directional movements of ions between a blood vessel above and the bone below without reference to intervening structures. These structures are depicted diagrammatically on right. 25HCC, 25-hydroxycholecalciferol (calcidiol); 1,25DHCC, 1,25-dihydroxycholecalciferol (calcitriol); M., mineralization; interface, boundary between osteoid and mineralized bone. The osteoblasts and osteocytes can be influenced by circulating levels of calcium, phosphate, and calcitriol, and also by locally produced calcitriol, either autocrine or paracrine. [From Parfitt AM: Human bone mineralization studied by in vivo tetracycline labeling: Application to the pathophysiology of osteomalacia. Excerpta Medica International Congress, 4th International Symposium on Chemistry and Biology of Mineralized Tissues 1992, pp 465-474.]

In patients with histologically verified osteomalacia or with radiographically unambiguous rickets, plasma calcitriol concentrations can be within the appropriate reference ranges 4'1~176 (Table 11-5). The levels are indeed inappropriately low for the degrees of PTH hypersecretion and hypophosphatemia, 179 as is indicated by the very high levels attained during the early stages of treatment with vitamin D , 157'158'181 but the lack of target cell responses to a concentration of calcitriol that is normally adequate requires explanation. In adults with osteomalacia, both biochemical and histological indices of vitamin D depletion appear to correlate better with either the sum of calcidiol (in ng/ml) and calcitriol (in pg/ml) concentrations, or with calcidiol alone, than with calcitriol alone. 1~ This suggests that calcidiol, or some other metabolite for which calcidiol is a precursor, such as 24-hydroxycalcidiol, might function as an agonist for calcitriol. In infants with untreated tickets, the plasma Ca • P product correlated with the plasma concentration of calcitriol and not calcidiol, although a higher than normal calcitriol level was needed to maintain a normal product. TM This suggests that some other metabolite functions in permissive manner, so that a fall in its concentration below a critical level would increase the need for calcitriol, but without dose-related effects above the critical level. 4

35

4

A

Higher than normal calcitriol levels could be needed to correct hypocalcemia and to restore normal mineralization when the calcitriol-responsive cells are separated from the mineralized bone by a much wider than normal layer of uncalcified osteoid through which the mineral ions must travel 5 (Fig. 1 1-13). But no similar reason is evident for the failure of intestinal mucosal cells to accomplish normal calcium transport, at least in patients who do not have an independent cause for impaired calcium absorption, such as intestinal disease or anticonvulsant administration. 182 Theories that ascribe all manifestations of osteomalacia to deficiency of circulating calcitriol alone may be able to account for its persistence, but have much greater difficulty accounting for its initiation. At the onset of HVO, what sustains calcium malabsorption and a small but significant fall in plasma calcium when plasma calcitriol is maintained at a normal (or even increased) level by secondary hyperparathyroidism? A similar argument applies to the increased vitamin D requirement of primary hyperparathyroidism, due to accelerated calcidiol catabolism in the presence of increased plasma calcitriol levels. 1~ During the evolution of HVO there is an early fall in plasma concentrations of both calcidio115'41'8~ (Table 11-5) and 24-hydroxycalcidiol. 149'17sCalcium absorption and retention in bone are increased in man by pharmacological doses of 24-hydroxycalcidiol, 151 but there is no evidence for such effects at physiological blood levels. Calcidiol binds to intestinal receptors for calcitriol, but with approximately 500- to 1000-fold lower affinity, although calcidiol is only 100 times less effective than calcitriol in promoting bone resorption in vitro. 183 Seemingly, these differences in activity could be offset by the much higher total plasma concentration of calcidiol, but there is only a tenfold difference in free concentrations, based on recent estimates of the association constants for binding to the same circulating protein. 1~1 Consequently, a fall in plasma calcidiol level below normal could not significantly modify total receptor occupancy in the target cells that respond to circulating calcitriol, although some more complex effect on receptor function remains possible. 184 A more promising approach to the clinical paradox is the possibility that one or more dihydroxylated metabolites are produced locally in target tissues, as is strongly suggested by studies with isolated bone and intestinal cells 185'186and by the in vivo intestinal response to a pharmacological oral dose of calcidiol. ~87 If bone cell and intestinal cell l ot-hydroxylases were less influenced by PTH and phosphate than is the renal l et-hydroxylase, as is generally the case for extrarenal calcitriol production, 1~3 local production of calcitriol would be more substrate dependent than circulating calcitriol and would be impaired by a fall in plasma calcidiol concentration be-

.

M. PARFITT

low normal. Similar considerations would apply to local production of 24-hydroxycalcidiol, if this compound could be shown to have a physiologically important function. But it is more consistent with the evidence that only calcitriol is essential 5'159 to postulate that circulating calcitriol is most important for the regulation of calcium homeostasis, locally produced calcitriol is most important for the regulation of bone remodeling and mineralization, and both are important for the regulation of calcium absorption.

IV. OSTEOMALACIA

RESULTING

FROM ABNORMAL VITAMIN D METABOLISM A. E x t r i n s i c V i t a m i n D D e p l e t i o n Synthesis of vitamin D in the skin is reduced by residence at latitude distant from the equator, atmospheric pollution, and increased skin pigmentation. 5'8'~3'188 But the most important determinants are the duration of direct exposure to sunlight and the type and extent of protective clothing, which reflect cultural and social influences 5'7'8'189'19~ as well as individual choice. Seasonal fluctuation is important in the U.K.; vitamin D status in the winter is largely dependent on the extent of body stores accumulated during the previous summer and in many persons is only marginally adequate, with a high prevalence of subclinical deficiency. 5'~13'~9~ The same probably holds in many European countries. 116 Any chronic disease that impairs independence and mobility will inevitably reduce sun exposure or eliminate it altogether. 192 Differences in individual behavior, for whatever reason, can override the effect of latitude. ~9~ Foods naturally abundant in Vitamin D, such as swordfish, are consumed rarely if at all by most persons, so that dietary intake of vitamin D depends mainly on regional and national policy concerning fortification of food, for example, milk in the U.S. and margarine in the U.K. Differences in dietary intake of vitamin D contributed more than differences in latitude to variation in mean plasma calcidiol level between countries, although both effects were significant. ~6'~88 Loss of dietary vitamin D, especially the contribution from less exotic fish and from eggs, is most likely to be important in those with an aversion to fatty foods or in strict vegetarians. 1 9 3 - 1 9 5 Vitamin D in multiple nutritional supplements is an unreliable source because most of the other constituents promote its chemical decomposition. 196 The dietary requirement of vitamin D is increased in the elderly, ~3'1~6 who are more likely to be housebound or confined to nursing homes and are subject to age-related declines in the efficiency of vitamin D absorption, in the

CHAPTER 11 Osteomalacia and Related Disorders photochemical activation of 7-dehydrocholesterol in the skin, and in the ability of the kidney to make c a l c i t r i o l . 197 If the total supply of vitamin D, dermal and alimentary, is borderline, the occurrence of osteomalacia (and also of rickets) will be determined by other factors. Osteomalacia can occur locally in pagetic lesions 198because bone of high turnover either needs more vitamin D or permits the more rapid development of the histological expression of impaired mineralization; the opposite probably applies to bone of low turnover. 85 Pregnancy depletes vitamin D stores because calcidiol is transferred preferentially to the f e t u s , 199 which produces biochemical deterioration 2~176 and can precipitate overt osteomalacia. 6'2~ The sacrifice of maternal vitamin D stores ceases at part u r i t i o n , 196 but the calcium drain of lactation further weakens the bone particularly if the dietary intake of calcium is l o w . 6 Apart from its contribution to vitamin D deficiency, 118 calcium deficiency alone does not cause osteomalacia in adults but can do so in growing children. 2~ The risk of osteomalacia is probably greater in populations that use breads made from whole meal or high extraction flour as a staple source of c a l o r i e s . 4'2~ Such breads are rich in phytate, which binds dietary calcium and reduces its absorption, but the high fiber content is probably more important. Wheat fiber increases fecal excretion of bile acids 4 which could impair the absorption of vitamin D. A high-fiber diet also reduces the plasma half-life of labeled calcidiol with increased fecal loss, T M an effect probably initiated by calcium malabsorption, as previously explained. 122 In current practice in the developed countries, osteomalacia due to extrinsic (or privational) vitamin D depletion occurs mainly in two groups of p e r s o n s ~ i n young adults who have migrated from India or Pakistan, directly or via East Africa, to the U.K. and other European countries, ~~ and in the elderly of every country. 113'197 Migrant osteomalacia has received the most attention. Although the roles of genetic susceptibility, skin pigmentation, and type of cereal consumption have been debated for many years, it is now clear that the major risk factor for the migrant population as a whole is a drastic reduction in solar exposure together with persistence of a very low dietary vitamin D i n t a k e . 41'193'2~176 Although earlier studies were inconclusive, 2~ it now seems clear that a higher intake of chapatti and a low intake of meat, fish, and egg are additional risk factors205-207; the histological severity increases with the strictness of vegetarian practice. 2~ In one northem U.K. city there was a substantial improvement in various indices of vitamin D nutriture in the children of migrants over a 10-year period, probably reflecting adaptation to a Western lifestyle, but no improvement in the adults, 2~ a public health problem that is only partially s o l v e d . 2~176176

355 It is generally agreed that osteomalacia in the elderly is much more common in the U.K. than in the U.S., although prevalence in a random community sample has not been determined in a n y c o u n t r y . 2~ Reasons for increasing susceptibility with age were given earlier, why women remain more at risk than men long after cessation of childbearing is unknown. In the U.K., mean plasma calcidiol falls almost linearly with age in women from 30 to 90 years, 5'1~ subclinical vitamin D depletion is especially common in t h e elderly, 116'19~ and is the most important reason for impaired calcium absorption, 21~ but similar data are not available for men. According to reasonable histological criteria, osteomalacia is found in about 4% of unselected geriatric admissions in the U.K., a proportion that remained stable for almost 20 years. 21~ The prevalence is higher in nursing home residents and higher still in hip fracture patients113'214; whether the latter represents an etiological relationship will be discussed later. No comparable histological studies have been carried out in the U.S., although there are strong reasons for believing that the prevalence there would be lower in each of the four populations mentioned, but with the same rank order. 113'197 Even some healthy free-living persons in the U.S. have subclinical vitamin D depletion. 197'215 Contrary to earlier belief, privational osteomalacia does occur, especially with multiple risk f a c t o r s , 197'216 and being less common is more likely to be overlooked than in the U.K. 217

B. I n t r i n s i c V i t a m i n D D e p l e t i o n a n d Gastrointestinal Bone Disease Although much less prevalent worldwide than extrinsic vitamin D depletion, in the U.S. and other countries that practice fortification of dairy products with vitamin D, intrinsic depletion is the commonest cause of osteomalacia. In countries where it is common, extrinsic vitamin D depletion is a major determinant of the effect of intestinal disease on the skeleton218; this interaction is less evident in the U.S., although in Rochester (Minnesota) plasma calcidiol concentration in patients with adult celiac disease was significantly correlated with the duration of sun exposure. 219 Diverse other factors can influence the expression of vitamin D depletion in patients with gastrointestinal and hepatobiliary disease. Some have calcium malabsorption and consequent secondary hyperparathyroidism for reasons other than, or in addition to, vitamin D depletion. 15 Protein deficiency is common and could affect bone in many different ways. Finally, other nutrients not normally thought of in the context of metabolic bone disease may turn out to have important influences on the function of bone cells. 32 Probably for this reason nonosteomalacic osteopenia

356

A

.

with low bone turnover is especially common in patients with intestinal malabsorption, whether or not they have vitamin D depletion and secondary hyperparathyroidism. Vitamin D needs intraluminal bile salts for absorption by a similar mechanism to other lipid-soluble substances, and enters the circulation via chylomicra in mesenteric lymph. In patients with both intestinal malabsorption and vitamin D depletion, a causal relationship is commonly assumed but difficult to prove. It is necessary to measure fecal excretion of radioactively labeled vitamin D after oral administration, since the rise in plasma vitamin D reflects also the rates of tissue uptake for storage or metabolism. 22~ Calcidiol absorption is less dependent on bile and occurs directly into the portal circulation. 187'221 The increase in plasma calcidiol or the peak level after an oral load is even less specific than the rise in plasma vitamin D, correlating neither with measured absorption nor with the degree of steatorrhea. 222 But a low value, although mainly indicative of reduced body stores of vitamin D, sometimes provides more information than the basal plasma level alone 222'223 and so may help to establish the existence of vitamin D depletion, although not necessarily establishing the mechanism. Absorption of vitamin D is generally more depressed than absorption of calcidiol, but even with gross steatorrhea rarely falls below 40% of intake, 22~ a level that would rarely cause vitamin D depletion in an adult ingesting the U.S. RDA of 10 I~g/day. Extrinsic factors that need to be considered even in relatively sunny regions are self-imposed avoidance of fatty foods to reduce fecal bulk, and limited sun exposure because of chronic illness or concern with body image. 32 But in many gastrointestinal disorders, the frequency and severity of vitamin D depletion are difficult to explain by these factors alone. For example, osteomalacia can occur after intestinal bypass surgery despite prescription of 1.25 mg/day of vitamin D , 224 from which absorption of only 1% would prevent depletion. As previously mentioned, the most likely explanation is that biliary excretion of vitamin D metabolites is increased by calcium malabsorption and secondary hyperparathyroidism, either directly or via an increase in serum calcitriol. 125 Several authors have indicated the frequency of different absorptive and digestive disorders as causes of 165 223 osteomalacia ' (Table 11-8). Such lists reflect variation in surgical practice and individual physician interest as well as geographical differences in disease prevalence, and serve only to demonstrate the range of possibilities rather than to reveal epidemiological truth. An increase in serum total alkaline phosphatase can result from hepatobiliary disease or reflect the intestinal isoenzyme even in the absence of bone disease and so may be less useful in studies of prevalence than in extrinsic vitamin D depletion. But despite these possible

M. PARFITT TABLE 1 1--8 Frequency of Different Types of Intestinal Malabsorption as Causes of Osteomalacia at Henry Ford Hospital, 1976-1985 Type of Malabsorption

n

(%)

Postgastrectomy Adult celiac disease Bypass surgery Chronic pancreatitis Other short bowel Biliary Cirrhosis Total

14 8 7 4 2 1 36

(39) (22) (19) (11) (6) (3) (100)

drawbacks, total alkaline phosphatase is a useful predictor of HVO in adult celiac disease. 225 Not surprisingly, there is much more information on the frequency and severity of vitamin D depletion (indicated by low plasma calcidiol levels) and of abnormal bone mineral metabolism than of histologically verified HVO. Currently unexplained is the high frequency of osteomalacia in the absence of vitamin D depletion after biliopancreatic bypass for obesity. 226 Evidence for another form of bone disease in addition to HVO comes from several sources. Vertebral deformity and fractures are more common in patients who have had gastrectomy than in control subjects 227 and 5% of patients referred for evaluation of vertebral fracture gave a history of gastrectomy compared with only 1% in control subjects. 228 Significant cortical and/or trabecular osteopenia without osteoid accumulation and in the absence of other etiological factors such as corticosteroid therapy has been found after gastrectomy, 229 intestinal bypass surgery for obesity 32 and small bowel resection for Crohn's disease, 23~in primary biliary cirrhosis, TM and in longstanding ethanol a b u s e . 232 In all these disorders a common bone histomorphometric profile can be discerned with thinner but more extensive osteoid seams, a low adjusted apposition rate indicating reduced collagen synthesis by teams of osteoblasts, and a low bone formation rate indicating reduced remodeling activation. Reduced trabecular thickness is mainly the result of reduced wall thickness. 233 A very similar disorder is also found in beagles with intestinal malabsorption. 234 The state of decreased bone remodeling at the time of biopsy was probably preceded in many patients by high bone turnover typical of HVOi. Many of the patients still have vitamin D depletion and/or secondary hyperparathyroidism, to which their bone is not responding in the usual manner. A few patients show atypical osteomalacia as previously defined, with similar kinetic defects to low-turnover osteopenia but with increased

CHAPTER 11

Osteomalaciaand Related Disorders

surface and volume but not thickness of osteoid. 32 This most likely represents a transition from HVOi, in which the usual morphological expression of osteomalacia is blunted by an unusually severe defect in bone matrix synthesis by osteoblasts224; the same defect developing earlier in the course of the disease and accompanied by depression rather than stimulation of remodeling activation could prevent any osteoid accumulation in the patients with nonosteomalacic osteopenia (Fig. 11-14). Since these defects are similar to those found in patients with postmenopausal osteoporosis, 14'33 it is likely that in patients who have undergone accelerated bone loss whether from secondary hyperparathyroidism or from menopausal estrogen deficiency, impaired recruitment and activity of osteoblasts limit bone repair and predispose to fracture. 32'33 The previous discussion has emphasized the similarities between the various causes of intrinsic vitamin D deficiency, but there are also important differences. In postgastrectomy osteomalacia, extrinsic factors have been emphasized in the U . K . , 115'218'235 but hyperosteoidosis is common in countries where extrinsic vitamin D depletion is r a r e . 236'237 In most patients, steatorrhea is mild or absent and the most likely mechanism of vitamin D depletion is enhanced catabolism of 25-hydroxy D initiated by calcium malabsorption as previously described. 122'124 In representative asymptomatic patients studied on average 9 years after operation, plasma calcidiol was reduced and calcitriol increased, but there was moderate impairment of calcium absorption and appendicular osteopenia. 238 In cystic fibrosis, mild vitamin D

.:~,O~.~O NORMAL

HVOi

= GENERALIZED OM (ii) ~ .

. ~

GENERALIZED OM (iii)

-%--,~"LTO"

~-.,~ f = ATYPICAL OM

DEFECTIVE MATRIX APPOSITION DOMINANT

FIGURE 1 1 - 1 4

Possible deviations from normal development of HVO in intestinal bone disease. Transition from HVOi to atypical osteomalacia (OM) rather than to stage ii generalized OM reflects unusually severe depression of matrix synthesis, but if this continues very slowly, osteoid thickness will increase with eventual progression to stage iii generalized OM. If the initial increase in remodeling activation is blocked, the same defect in matrix synthesis with impaired mineralization will prolong formation period and lead directly to atypical osteomalacia. If remodeling activation is depressed by some additional agent, there will be no osteoid accumulation, the disorder of cell function resembling low turnover osteoporosis (LTO) but with normal instead of reduced osteoid seam thickness. If the mineralization defect persists, there will be gradual transition to atypical osteomalacia.

357 depletion and moderate osteopenia a r e c o m l T l O n , 239 but rickets is very rare despite the severity of steatorrhea 24~ and hyperosteoidosis has been verified histologically only in two adults, both with focal biliary cirrhosis and severe secondary hyperparathyroidism. 241'242 Osteomalacia is also rare in chronic pancreatitis and probably requires alcoholic liver disease as well as pancreatic enzyme deficiency. Vitamin D depletion is common in Crohn's disease, but is severe enough to cause osteomalacia only in patients who have undergone small intestinal resection, 243 especially if treated with cholestyramine for bile acidinduced diarrhea. T M After intestinal shunt surgery for obesity, serum calcidiol falls rapidly in the first 6 months and more slowly thereafter, and appendicular bone mass begins to fall after about 1 year despite little change in serum calcitriol. 245 Osteomalacia develops in about 12% of patients in Europe and in about 4% in the U.S., but for unknown reasons is less likely if hypomagnesemia is more severe. 32 Spontaneous improvement has been observed, 246 but progressive worsening of symptoms in the absence of diagnosis is more common. The potential risk of osteomalacia is greatest in adult celiac d i s e a s e 223'247'24s because the mucosal defect impairs absorption of vitamin D and calcium directly 73 and may also reduce local calcitriol synthesis. 187 Patients with mild subclinical celiac disease may manifest all the features of HVOi, which improve with a gluten-free diet. 249 In patients untreated for many years, osteomalacia develops in more than half, but can be forestalled by timely diagnosis. 247 Osteomalacia can occur even without steatorrhea and may be the presenting manifestation. 247'24sThe distinctive features conferred by onset in childhood (even if subclinical) were emphasized previously. 4 Unlike postgastrectomy osteomalacia, there is no response to ultraviolet irradiation 4 or to moderate doses of vitamin D in the absence of a gluten-free diet. 25~

C. Impaired 25-Hydroxylation and Hepatobiliary Bone Disease Despite the physiological necessity of 25-hydroxylation, its impairment is of only minor importance in clinical medicine, unless the supply of vitamin D is low. If liver destruction is so extensive that too little calcidiol can be produced despite adequate substrate, the patient will usually die before developing HVO. Furthermore, no genetic defect in the 25-hydroxylase has yet been identified. To understand what has been termed hepatic osteodystrophy, TM the separate effects of alcohol excess, loss of liver parenchyma, and cholestasis must be distinguished. Alcohol can cause osteopenia by a variety of

358 adverse effects on bone mineral metabolism unrelated to vitamin D . 232'252 Alcoholics are also especially prone to extrinsic vitamin D depletion, 253 which probably accounts for the coexistence of alcoholism and osteomalacia in a few patients with aseptic osteonecrosis. 254 Patients with cirrhosis of the liver, whether or not due to alcohol, often have mild steatorrhea 255 and impairment of vitamin D absorption. 4 Moderate reductions in plasma calcidiol in cirrhotic patients correlate with plasma albumin and other indices of liver function 254 probably because 25-hydroxylation is mildly impaired, ~26but plasma calcidiol can be raised above normal by oral vitamin D in the dose range 180 to 625 ixg/day. 4 In hemochromatosis venesection therapy increases plasma calcidiol, suggesting that iron accumulation can impair 25-hydroxylation independent of other effects on hepatocellular function. 256 In advanced cirrhosis, PTH secretion is slightly increased, but osteomalacia does not occur unless there is either cholestasis or extrinsic vitamin D depletion. 257 In chronic cholestasis, whether in primary biliary cirrhosis or due to hepatitis or to extrahepatic biliary tract disease, intraluminal bile salt deficiency causes steatorrhea and impaired absorption of both vitamin D and calcidiol. 258 Also, some metabolite of vitamin D other than calcidiol is lost in the urine in proportion to the rise in serum bilirubin. 5'114 Consequently, plasma calcidiol levels are low and there is malabsorption of calcium that can be reversed by treatment with vitamin D or its metabolites, 259 but the frequency of osteomalacia due only to these abnormalities has been greatly exaggerated. 251 Based on the kinetic criteria given earlier, or the osteoid measurements characteristic of these criteria, or on unequivocal clinical findings, the only acceptable published cases are from the north of England, 257'258or the far north of Sweden, 26~ where extrinsic vitamin D deficiency is common. Other patients were being treated for pruritus with cholestyramine, a drug that independently reduces vitamin D absorption. 261 In many other cases osteomalacia has been misdiagnosed because of one or more of the errors described in Section I, failure to exclude HVOi, or applying an unvalidated method to decalcified bone. 4 Data from the only definite case in the U.S. are shown in Figure 1 1-8. By far the most important component of hepatic osteodystrophy is severe osteoporosis, 25~'262made worse in a few cases by glucocorticoid therapy. 263 Bone pain and tenderness are frequently mentioned in clinical descriptions but they are the result of the multiple fractures to which these patients are especially prone, not of osteomalacia. Muscle weakness is also common, but can occur in primary biliary cirrhosis for several reasons unrelated to HVO. Even in asymptomatic patients there is significant vertebral osteopenia. 262 Bone turnover is usu-

A.M. PARFITT ally reduced, often markedly so, with low values for surface extent and volume of osteoid and extent and separation of tetracycline l a b e l i n g , 262'263 indicating both depressed remodeling activation and impaired osteoblast function. TM In other series bone tumover is increased in some patients. T M The indices of bone structure in transilial biopsies in primary biliary cirrhosis are very similar to those found in the nonosteomalacic osteopenia after intestinal shunt surgery, with cortical thinning and reduced thickness rather than density of trabecular plates. TM

D. Enzyme Induction and Anticonvulsant Bone Disease The quantitative importance of inactive vitamin D metabolites made in the liver was mentioned earlier. By analogy with other steroid hormones, their production in some cases depends on hepatic microsomal mixed function oxidases. 127 These enzymes are inducible, with increased microsomal content of one of several types of cytochrome P-450, by a wide variety of drugs, including barbiturates, phenytoin and several other anticonvulsants, and the antituberculous drug rifampicin. 267 The degree of enzyme induction is roughly indicated by the increase in metabolic clearance of antipyrine or in urinary excretion of D-glucaric acid or 6[3-hydroxycortisol, each marker showing a wide variation between different subjects taking the same drug, but correlating weakly with dose and blood level. 26v Some patients on long-term anticonvulsant therapy develop a syndrome of low plasma calcidiol, intestinal malabsorption of calcium, slight fall in plasma calcium, secondary hyperparathyroidism, and cortical osteopenia. 127'268-27~Although commonly referred to as anticonvulsant osteomalacia, this term is misleading on several counts. Radiographic evidence of mild tickets has been found in 8% of children, 4 but systematic surveys of bone histology in adults have invariably failed to disclose osteomalacia, 27~-273 except for a few doubtful cases in Scotland where privational vitamin D depletion is common, 4 and one case in an elderly psychiatric population. 274 With double tetracycline labeling, the bone formation rate is increased without defective mineralization, 57'271'273 and in this and every other respect the syndrome conforms exactly to the description of HVOi given earlier, with the exception of a higher incidence of acquired resistance to the phosphaturic effect of PTH 268 and disproportionate elevation of serum osteocalcin. 275 Osteomalacia, according to adequate clinical and radiographic and/or histological criteria, has been found in a few cases, but is largely confined to patients with only marginally adequate vitamin D supply, pro-

CHAPTER 11 Osteomalacia and Related Disorders longed treatment with multiple drugs, or other risk factors 4'5'127'276'277 (Fig. 11-8). The term "anticonvulsant osteomalacia" is also misleading because the implication of uniform pathogenesis takes no account of significant differences between drugs. 278 Phenobarbital is a more potent enzyme inducer than phenytoin and has been convincingly shown to enhance the catabolism of calciferol and calcidiol in the liver 4'127 but does not usually by itself reduce plasma calcidiol levels 279 or cause rickets, 4 probably because the formation of calcidiol is increased as well as its destruction. 4'127'278 Phenytoin has not been shown to have any direct effect on vitamin D catabolism, 114'275 but is more commonly associated with abnormal bone mineral metabolism than phenobarbitone because it can lead to hypocalcemia and secondary hyperparathyroidism by mechanisms unrelated to vitamin D , 269'273 such as impaired calcium release from bone and reduced calcium absorption. 4'5'~82'275 This would be expected to enhance calcidiol catabolism indirectly by the mechanism previously described. 5 A further complexity is that in the only prospective study, the early effect of phenytoin in newly diagnosed epileptics was to increase plasma calcitriol at the expense of calcidiol, with a corresponding increase in calcium absorption but without change in parathyroid function, 28~ consistent with the experimental demonstration of increased 1ot-hydroxylase activity. 4"278Multiple effects of phenytoin on vitamin D metabolism could account for differences in vitamin D m e t a b o l i t e profile 4'91'127'273'28~but make it more difficult to explain the production of osteomalacia, convincingly shown experimentally in the rat. TM Paradoxically, the best evidence for the clinical importance of enzyme induction and enhanced vitamin D catabolism comes from studies not with anticonvulsants, but with rifampicin and isoniazid. 282'283 Whatever the mechanism, anticonvulsant administration appears to increase vitamin D requirement by 10 to 15 txg/day in children 4'5 and possibly more in a d u l t s , 127'277'284 but whether this is clinically significant depends on the total dermal and dietary supply of vitamin D . 4'5'127'271 In otherwise healthy persons in sunny climates the effect is trivial, although non-vitamin D related effects of phenytoin may cause osteopenia. 273 By contrast, in mentally retarded institutional residents there is a substantial risk of clinically significant vitamin D depletion and its consequences. 277 At any level of supply, the amount by which requirement is increased depends on the dose and especially the number of drugs used, but also reflects individual susceptibility to enzyme induction. Consequently, both the frequency and the severity of the syndrome vary considerably between different populations. In some institutions, fractures due in part to anticonvulsant-induced osteopenia are a major

359 health problem and overt rickets is common, 285 but in other institutions prolonged immobility appears a more important determinant of bone density than anticonvulsant therapy. 4 As already emphasized, symptomatic bone disease is rare in noninstitutional settings, but the long-term effects of asymptomatic osteopenia are unknown. Although the clinical, biochemical, and histological abnormalities respond well to treatment, 127'286cortical bone loss is largely irreversible. 127 There is currently no consensus on whether all or only some anticonvulsant-treated patients should be given prophylactic vitamin D, if the latter, how they should be selected, and in either case whether ergoor cholecalciferol is more effective. ~27'27~

E. I m p a i r e d l o L - H y d r o x y l a t i o n a n d Renal Bone Disease The belief that chronic renal failure can impair the mineralization of bone has a long and controversial history. The term renal rickets was coined many years ago, 287 but its prevalence has been greatly overestimated because the radiographic appearances of metaphyseal osteitis fibrosa have so often been attributed mistakenly to rickets. 288 Quantitative bone histology frequently reveals substantial osteoid accumulation, 289 but the relative contributions of increased activation frequency and prolonged mineralization lag time (Fig. 1 1 - 6 ) could not be determined without double tetracycline labeling. In severe uremic hyperparathyroidism, osteoid seams are not only more extensive but thicker than normal because initial matrix apposition is more rapid, 19 so that all the static indices of osteoid accumulation can be reproduced, even though mineralization is normal. 31'57 The extent to which osteoid accumulation was excessive in relation to the histological severity of osteitis fibrosa was inversely related to the serum Ca • P product, 289 but in retrospect this relationship was most likely accounted for by the high prevalence of subclinical vitamin D deficiency in northern England that was not evident until measurement of serum 25(OH)D became possible. 5 Using tetracycline-based bone histomorphometry, the prevalence of osteomalacia in undialyzed patients with uncomplicated chronic renal failure was found to be very l o w . 29~ The risk of osteomalacia is increased by vitamin D deficiency, both in populations as already mentioned, and in individuals. TM Although not formally demonstrated, the adverse effects of vitamin D deficiency are probably potentiated by concomitant renal failure. Prolonged administration of aluminum-containing antacids to undialyzed patients can also predispose to osteomalacia because of either relative hypophosphatemia, 292 discussed in Section VI.A, or aluminum intoxication, 293 dis-

360 cussed in Section VII.A. Severe metabolic acidosis also increases the risk of osteomalacia. 294 The rarity of osteomalacia in chronic renal failure in the absence of one of these complications despite severe calcitriol deficiency is due partly to the protective effect of hyperphosphatemia, 292 and partly to the maintenance or calcitriol production in bone, provided the supply of its precursor calcidiol is maintained (Fig. 1 1-13).

V. VITAMIN D AND AGE-RELATED OSTEOPOROSIS Despite their obvious differences (Table 1 1-1), osteomalacia and osteoporosis have much in common. In both there is malabsorption of calcium, negative calcium balance, osteopenia, and increased fracture risk. In both, an initial state of high bone turnover, increased resorption, and accelerated bone loss is often followed by a state of low bone turnover and impaired osteoblast function. These similarities suggest a possible role for vitamin D in the pathogenesis, differential diagnosis, and treatment of osteoporosis. 4'295-297

A. Pathogenesis of Bone Loss and Fracture In type I (postmenopausal) osteoporosis, low-normal plasma calcitriol levels and impaired calcium absorption are secondary consequences of increased estrogendependent bone loss, and parathyroid function is normal or slightly depressed, but in type II (senile) osteoporosis, a primary abnormality in vitamin D metabolism probably contributes to bone loss. Functioning renal tissue mass declines with age, which reduces the ability to synthesize calcitriol in response to stimulation by PTH; aging itself may delay the response but does not alter its magnitude. 298 Because of this defect, augmented probably by other consequences of impaired renal function and possibly by an age-related decline in calcitriol receptor number or binding affinity, 299 PTH secretion increases with age to an extent that depends on the prevailing level of vitamin D nutriture. 21~176176 Since all forms of secondary hyperparathyroidism that have been adequately studied accelerate the age-related loss of cortical and to a lesser extent trabecular bone, ~3 it would be surprising if the same did not apply to the secondary hyperparathyroidism of aging. In France, where food is not fortified with vitamin D, HVOi may be an important cause of high bone turnover in patients with vertebral compression fractures, 63 but in late postmenopausal women without fracture, HVOi made only a small contribution to increased turnover. 3~176

A.M. PARFITT In the U.K., subclinical vitamin D deficiency is also common, and both lumbar spine and hip bone density correlate inversely with the severity of HVOi. 3~ In the U.S., high bone turnover is less common than in Europe in patients with compression fracture 11'33and reflects unusually prolonged effects of estrogen deficiency 295 rather than secondary hyperparathyroidism, except among those who have had a gastrectomy or other cause of intrinsic vitamin D deficiency. 228 But even in the U.S., serum 25(OH)D levels are reduced in some compression fracture patients. 3~ HVOi due to impaired 1 et-hydroxylation could account for the mild increase in OV/BV (3.5% to 8%), reversible by administration of alfacalcidol, in patients with vertebral compression fractures, who because of their advanced age would be classified as "type II" rather than "type I" osteoporosis. 3~ Muscle weakness and abnormal muscle histochemistry may also respond to alfacalcidol administration in these patients. 3~ As mentioned earlier, the prevalence of subclinical extrinsic vitamin D depletion, secondary hyperparathyroidism, and excess osteoid is frequently 1~3'3~176 but not invariably ~13'3~176 increased in patients with hip fracture. The available data are consistent with HVOi as an etiological factor, but it remains possible that hypovitaminosis D is a nonspecific marker of ill health and inactivity. In a controlled trial, vitamin D supplements failed to increase the ability of elderly hospitalized patients with low plasma calcidiol levels to carry out activities of daily living. 311 But hip fracture patients with normal osteoid indices and low plasma calcidiol levels have increased surface extent of osteoclastic resorption and more severe cortical osteopenia than those with normal levels. 12Also, increased osteoid accumulation and occasionally frank osteomalacia have been found in hip fracture patients with normal plasma levels of calcidiol but slightly reduced levels of calcitriol3~2; such an abnormality is less likely to be a nonspecific marker of ill health. These data increase the likelihood that HVOi, whether due to depletion or impaired metabolism of vitamin D, is a risk factor for hip fractures, but it is probably of etiological importance in only a small proportion of patients. 3~176

B. Differential Diagnosis and Treatment of Osteoporosis In all patients presenting with osteoporotic fractures of the spine or hip, especially after the age of 70, the physician should consider HVOi, which is both more common and easier to overlook than osteomalacia. If noninvasive indices of bone remodeling are increased, hyperparathyroidism (primary or secondary) and hyperthyroidism (endogenous or exogenous) must be excluded before resorting to estrogen replacement therapy. Serum


361 larly nursing home residents. Indeed, 800 IU of vitamin D, together with 1200 mg of calcium, significantly reduced the risk of hip fracture in such s u b j e c t s . 319 Since the protective effect was evident within 6 months, 32~ it could have reflected increased muscle strength and decreased propensity to fall rather than any change in bone strength. A protective effect of vitamin D against hip fracture was not observed in healthy free living elderly people 321 and may be confined to the frail elderly with low body mass. 322

osteocalcin correlates better with bone histology than alkaline phosphatase or urinary hydroxyproline 313 but has not yet been shown to be a better guide to the selection of treatment. Single-photon absorptiometry of the radius, although an inaccurate predictor of vertebral bone status, is a good index of PTH-dependent bone loss. 51 Finally, although iliac bone histomorphometry after double tetracycline labeling is primarily a research tool, measurement of osteoid in a Jamshidi needle specimen is a simple and nontraumatic procedure with the potential for wide application. 314 Vitamin D in a pharmacological dose is commonly used in the management of spinal osteoporosis, on the grounds that calcium alone would be inadequately absorbed and that subclinical osteomalacia would be corrected without the need for accurate diagnosis. It is doubtful whether in any other branch of medicine a treatment is so popular that combines such complete absence of supporting evidence with such potential for serious h a r m . 315'316 In addition to its well-known toxic effects on the kidney, a high dose of vitamin D has an adverse effect on bone 317 because one or more of its metabolites stimulates bone resorption. 175 Nevertheless, because subclinical vitamin D deficiency is common, small physiological doses in the range of 5 to 20 Ixg/day significantly reduce the rate of bone loss in healthy postmenopausal women, 318 and it is reasonable to give such doses to those at increased risk of vitamin D depletion, particu60-

VI. OSTEOMALACIA ABNORMAL

FROM

RESULTING

PHOSPHATE

METABOLISM Many of the similarities and differences between vitamin D-related and phosphate-related osteomalacia (Table 11-5) have already been referred to and can be readily accounted for, but one major question remains: What corresponds to HVOi in hypophosphatemic osteomalacia? In established cases, the relationships between osteoid seam thickness and both osteoid surface and effective apposition rate are the same as in HVO (Fig. 11-15), although seam thickness is greater and a higher proportion are in stage iii rather than stage ii. But there are almost no data on the mode of evolution at an earlier

9

I I ! I I !

50

9

o

9

I

O

'- 4 0 . ~o t--

I--E

/

/I

I I I I

9 9 9o$

\

MIt 100d

\

/ / / 0

~ o

~

2o

c"

-

~

10-

e/~f

i

0

A

FIGURE 1 1-- 15

I

20

~

!

i

40

i

~"-e

i

60

OS/BS (%)

l

I

80

A

I

|

0.1

100 B

0.2

0.3

Aj.AR (pm/d)

Osteoid thickness relationships in hypophosphatemic osteomalacia. Layout as in Figure 11-8 with static measurements on left (A) and kinetic measurements on right (B). Data are from 18 patients accumulated over 15 years, including 6 adults with XLH, 7 with nonhereditary hypophosphatemia (5 apparently without and 2 with a tumor, 1 cured by excision, with pre- and postoperative values joined), 2 with antacid-induced phosphate depletion (F-I), 1 with renal tubular acidosis secondary to Sj6gren's syndrome (A), 1 adult with hereditary hypercalciuric hypophosphatemia (O), and 1 with atypical osteomalacia following renal transplantation (A).

362

A.M. PARFITT

stage. The absence of focal osteomalacia indicates that, as in HVO, osteoid surface increases before osteoid thickness, but without a stimulus to increased remodeling activation analogous to secondary hyperparathyroidism, osteoid surface can increase only as a result of prolongation of the formation period, long known to be characteristic of hypophosphatemic osteomalacia. 323 It can be inferred that all patients with impaired mineralization due to hypophosphatemia evolve through a stage of atypical osteomalacia, in which a reduction in the rate of mineral apposition is accompanied by a parallel reduction in the rate of matrix apposition or, looked at from a different viewpoint, by an inversely proportional prolongation of mineralization lag time. As osteoid surface increases, the surface available for initiation or progression of remodeling would decrease, with a corresponding fall in bone formation rate, which would fall even further as mineralization became more defective. Except for one instance of atypical osteomalacia after renal transplantation (Fig. 11-15), data confirming this inference are lacking, most likely because the patients are not yet symptomatic and therefore not subjected to biopsy. Patients with hypophosphatemia, impaired osteoblast function, and reduced bone turnover but without osteomalacia 162'164 are presumably at an earlier stage at which disease progression is arrested because the fall in remodeling activation occurred sooner than would be dictated by the increase in osteoid surface, presumably from an independent cause. The situation is very similar to that in the nonosteomalacic low turnover form of intestinal bone disease (Fig. 11-14), with the difference that in hypophosphatemia this is the usual manner of evolution, whereas in HVO it is an uncommon variant.

dl), but the most consistent and diagnostically reliable abnormality is that urine phosphorus excretion is always less than 50 mg/24 hours and often much lower. By contrast, urinary calcium excretion is increased, sometimes to very high levels326; in one case nephrolithiasis resulted and led to unnecessary parathyroid s u r g e r y . TM Hypercalciuria was absent in the solitary case of tickets, possibly because the mineral content of bone was subnormal. 328 The clinical and biochemical syndrome of phosphorus depletion, except for osteomalacia, can be induced experimentally within a few weeks in normal subjects by high-dose antacid administration. 329'33~ The osteomalacia is histologically typical, without evidence of aluminum deposition, and with increased osteoclast extent, less than in HVO but more than in other forms of primary h y p o p h o s p h a t e m i a . 136'324'327'331 Consequently, the hypercalciuria probably results from increased net bone resorption as well as from increased calcium a b s o r p t i o n . 47"33~ Since plasma calcidiol and PTH levels are normal, both sources of urinary calcium probably depend on an increased plasma calcitriol concentration, known to be induced by phosphate depletion 329 and demonstrated in the most recent c a s e s . 136'324'326-328 In retrospect, this abnormality was first observed more than 30 years ago in a patient with an increased plasma level of vitamin D activity, measurable at that time only by bioassay. 333 All manifestations are quickly reversed with cessation of antacid administration combined, if necessary, with supplemental phosphate. Looser's zones have been observed to heal, and in one case there was histological verification of c u r e . 327 Other causes of osteomalacia with an increase in plasma calcitriol and/or hypercalciuria are shown in Table 11-9. In some of these conditions, calcitriol excess may paradoxically impair mineralization, as it does in the rat. 175

A. P h o s p h o r u s D e p l e t i o n Osteomalacia, according to reasonable criteria, has resulted from chronic phosphorus depletion in 16 c a s e s , 136'324-327 including two shown in Figure 11-15, and rickets in one case. 328 The patients with osteomalacia have ranged in age from 26 to 75 years and included 14 women and 2 men, in keeping with the greater susceptibility of women to hypophosphatemia on a lowphosphate diet. 329 They had taken phosphate-binding antacids--aluminum hydroxide with or without magnesium hydroxide--in large quantities usually for at least 2 years. The clinical and radiographic features do not differ from osteomalacia in general, although symptoms of general debility may be more frequent and severe. 33~ The plasma alkaline phosphatase is usually raised, but the abnormalities of bone mineral metabolism are unique. Plasma calcium is always normal and plasma phosphate usually but not invariably low (0.9 to 3.2 mg/

B. H e r e d i t a r y H y p o p h o s p h a t e m i a The gene responsible for this condition has been localized, both in a murine model and in XLH, the most common fOrlTl. TM In adults, the five separate but related components - - hypophosphatemia, impaired mineralization, retarded growth, osteosclerosis, and ligamentous ossificationmare of different relative importance and manner of expression than in c h i l d r e n . 62'335'336 Impaired tubular reabsorption of phosphate is lifelong, but in other family members may be accompanied only by relative shortness of stature. After epiphyseal closure, treatment is often withdrawn, but bone biopsy invariably shows osteomalacia and persistence of the asymmetrical perilacunar hypomineralization even in the absence of symptoms337'338; it is not known whether the same applies to hypophosphatemic relatives who never had rickets.

CHAPTER 11

363

Osteomalacia and Related Disorders TABLE 1 1 - 9

Unusual Causes of Osteomalacia with Increase in P l a s m a Calcitriol Concentration or Urinary Calcium Excretion or Both a Plasma Calcitriol

Phosphate depletion Hypercalciuric hypophosphatemiab Wilson's diseasec Cadmium poisoningc Hypercalcemic HPTd with D Myeloma + LCN (c.e)

Urinary Calcium Mixed

1" (Osseous)

$

1" 1" ? 9 $ $ or N

Cystinosisc

$

Oculocerebrorenal syndromec

9

Renal tubular acidosis Bartter's syndromeI

N ?

Vitamin D dependency type IF Calcium deficiencyh

1" 1"

aModified from Parfitt AM: Bone as a source of urinary calcium-osseus hypercalciuria. In Coe F (ed): Hypercalciuric States--Pathogenesis, Consequences and Treatment. New York, Grune & Stratton, 1984, pp 313-378, where additional references are given for conditions not discussed in present text. bReference 138; previously referred to as Gentil-Dent syndrome.332 CMultiple renal tubular defects of Fanconi type. dHyperparathyroidism (primary or tertiary) and vitamin D deficiency.1~ eLight-chain nephropathy. IRadiographic evidence of rickets; osteomalacia not verified. ~Defect in calcitriol receptor. hReference 202. Mixed hypercalciuriamincrease in net intestinal absorption as well as net bone resorption. Osseous hypercalciuriamincrease in net bone resorption a l o n e . 332

Some patients experience recurrence of bone pain and difficulty in walking, appearance or reappearance of L o o s e r ' s zones, and progression of deformity after cessation of treatment. Others develop s y m p t o m s for the first time in late adult life, and adults are especially prone to dental abscesses and degenerative joint disease. 336 These differences cannot be related to the apparent histological severity of the mineralization defect. In a unique family with X-linked recessive inheritance, the clinical features, mainly progressive lateral bowing of the femora, did not begin in any subject until adult life. 4 The coarsened trabecular pattern often present in children may progress to a generalized increase in trabecular bone density, especially in the axial skeleton, producing a radiographic resemblance to osteopetrosis or renal osteodystrophy. 62'335 Osteosclerosis may be especially severe in families with autosomal recessive rather than the more usual X-linked dominant inheritance. 339 Measurement of bone mineral density by a variety of methods 4'34~ indicates reduced thickness of n o n weight-bearing bone in the extremities and normal or increased cancellous mineralized bone volume, consistent with the histological findings. 338'34~ The radiographic

appearances reflect both the excess mineralized bone and the increased radiodensity of osteoid relative to other soft tissues because of its high sulphur content. Cortical thickness is often increased in weight-bearing bones because of compensatory buttressing during growth. 62'34~ Osteosclerosis is asymptomatic, but ossification of interosseous m e m b r a n e s , ligaments, tendons, and joint capsules at their sites of attachment to bone, collectively known as entheses, is an important cause of disability in adults with hereditary hypophosphatemia. 335'344'345 The process begins as a roughening and irregularity of the periosteal surfaces, but progresses by extension of ossification beyond the original confines of the bone. Occasionally, ossicles due to ectopic ossification not continuous with the bone appear in the extremities and around the joints of the pelvis. There is usually pain, stiffness, and limitation of motion in relation to affected sites, and both x-ray appearances and clinical disability increase with age without relation to sex or treatment. Probably because of retarded growth and consequent shortness of the pedicles, the lumbar spinal canal is often narrow with increased susceptibility to cord compression requiting surgical intervention. 62'346 Mild sensorineural

36

4

A

.

hearing loss probably due to involvement of the cochlea by ligamentous ossification and bony expansion is also quite c o m m o n . 347 The occurrence of similar lesions in a patient with cadmium-induced osteomalacia 335 suggests that they arise in response to prolonged tension on the surface of softened bones rather than representing an independent component of the genetic syndrome as previously suggested. 62

C. Nonhereditary Hypophosphatemia, Idiopathic and Oncogenous Hypophosphatemic osteomalacia sometimes appears for the first time in adolescence or adult life in the absence of tickets or retarded growth during childhood and with a negative family history. 62'348'349 In many cases the clinical, biochemical, and histological abnormalities have been cured by removal of a mesenchymal tumor~139'350 and several lines of evidence suggest that such a tumor is present in all cases. First, the characteristics that differ from hereditary hypophosphatemia (Table 11-10) are essentially identical in cases with and apparently without a tumor, including the frequency distribution of age of onset by decade. Second, with more

TABLE 11--10 Differences Between Two Forms of Hypophosphatemic Osteomalacia a Feature

Hereditary

Nonhereditary ~

Muscle weakness

No

Yes

Bone pain

No C

Yes

Increased glycinuria

No

Yes

Osteopenia

No

Yes

Vertebral collapse

No

Yes

Loss of trunk height

No

Yes

Fractures a

No

Yes

Perilacunar low-density bone

Yes

No e

Osteosclerosis

Yes

No

Enthesopathy

Yes

No i

Deafness

Yes

No

Phosphate depletion

No

Yes

aModified from Parfitt AM, Kleerekoper M: Clinical disorders of calcium, phosphorus and magnesium metabolism. In Maxwell M, Kleeman CR (eds): Clinical Disorders of Fluid and Electrolyte Metabolism, 3rd ed. New York, McGraw Hill, 1980, pp 9 4 7 - 1 1 5 2 . ~vVith or without a tumor. CMay occur in adults but rarely disabling. dLooser's zones occur in both. eEvidence inconclusive. I M a y depend on duration without treatment. Differences dependent only on age of onset are excluded.

M. PARFn'T

widespread recognition of the need to search for a tumor in adult-onset osteomalacia, reports of idiopathic cases have become notably less frequent, 35~ whereas twice as many tumorous cases were reported from 1980 through 1989 than in the preceding decade. 35~ Third, in many cases the tumors are so small that in an unfavorable location they could escape even the most sophisticated current methods of detection. TM Finally, in at least one case initially reported as idiopathic, a tumor has been discovered during more extended observation. 355 But in one case encountered by the author, a tumor has still not been found nearly 50 years after the onset of symptoms, so that an occult tumor must not only be very small but very slowly growing. The issue will likely not be settled until the pathophysiology is better understood. The interval between onset of symptoms and diagnosis in published cases has averaged about 5 years, with a range of 4 months to 19 years, and has not declined significantly in recent years. 35~ The onset can be at any age but in most cases is between 20 and 50 years. In less than 10% of cases the symptoms begin before age 10 or after age 70, the former presenting as rickets rather than as osteomalacia. 356 Unlike adults with hereditary hypophosphatemia, most patients have bone pain, muscle weakness, and difficulty in walking and many have Looser's zones. In contrast to hereditary hypophosphatemia, ligamentous ossification does not occur, and instead of axial osteosclerosis, there is often severe vertebral osteopenia with multiple compressions, loss of trunk height, and kyphosis, usually beginning 1 to 2 years after the other symptoms and progressing r a p i d l y . 348'349 Osteopenia is often generalized, with pronounced cortical thinning; multiple fractures, especially of the femoral necks, are common. Due to the severity of the disease and the frequent delay in diagnosis, many of these patients in the past developed bizarre and crippling deformities including multiple angulations of the long bones, scoliosis as well as kyphosis, and pigeon-chest due to fracture of the sternum. 4'6a Close to half of the patients, with or without tumor, have been bedridden before effective treatment w a s begun. 62'139 The biochemical features are similar to those of hereditary hypophosphatemia, but malabsorption of calcium is more severe and the plasma phosphate level is lower. The mean value was 1.64 mg/dl in 27 nontumorous cases tabulated by Fanconi 349 and 1.52 mg/dl in 41 tumorous cases tabulated by Ryan and Reiss, 139 whereas in adults with hereditary hypophosphatemia, the plasma phosphate is usually above 2.0 mg/dl. Renal tubular responsiveness to exogenous PTH was blunted in one tumoral c a s e 357 but exaggerated in one nontumoral c a s e , 353 in keeping with the reported effect of parathyroidectomy, 358 but the data are too fragmentary to conclude that there is a difference in pathogenesis. Plasma

CHARTER 11 Osteomalacia and Related Disorders calcitriol levels are uniformly low in the tumoral c a s e s , 139'35~ but have not been studied systematically in the nontumoral cases; in neither group does calcitriol administration consistently correct the defect in tubular reabsorption o f p h o s p h a t e , 139'35~ probably because this requires maintenance of a supraphysiological plasma level. Urinary calcium excretion is either normal or sometimes increased, presumably owing to increased net bone resorption as a result of phosphate depletion. 348 Urinary excretion of glycine is often increased but other amino acids are normal, although a few cases manifest the Fanconi syndrome with generalized aminoaciduria and glucosuria with or without hyperchloremic acidosis. 139'359 Histologically, the bone is similar to severe vitamin D deficiency but, as in hereditary hypophosphatemia, osteoclastic resorption is usually less p r o m i n e n t 4'351'357'36~ (Fig. 11-15). But in one case, resorption of osteoid was observed, indicating profound stimulation of osteoclast recruitment and activity. 361 Resection of a tumor when present is followed within a few days or weeks by a rise in low levels of plasma phosphate and calcitriol to normal, and by rapid improvement and eventual disappearance of symptoms and healing of Looser's zones. Return of normal mineralization and healing of the osteomalacia has been confirmed histologically in a few c a s e s 36~ (Fig. 11-15). The tumors presumably secrete one or more humoral agents that impair both phosphate reabsorption and l oLhydroxylation; in vitro confirmation of this presumption has been accomplished in different w a y s , 334'362"363 but the identity of the agent is still unknown. The tumors are mesenchymal but of variable origin in soft tissue or bone and with variable histological features, often diagnosed as hemangiopericytoma. Almost all have the two main features of extreme vascularity and large numbers of spindle cells and multinucleated giant ce11s139'364'365; about 10% of cases are malignant. 366 Osteomalacia (or tickets) that is clinically, biochemically, radiographically, and histologically very similar (except for earlier age of onset) occurs in some patients with fibrous dysplasia of bone (13 c a s e s ) , 367'368 neurofibromatosis (12 cases)369'37~ and linear sebaceous nevus syndrome (4 c a s e s ) . TM In these disorders also, a humoral origin is likely, but is in most cases impossible to prove, since the extent and multiplicity of lesions preclude surgical cure. However, partial excision of fibrous dysplasia in one case led to significant clinical and biochemical improvement. 367 If a tumor is not found, treatment with some form of vitamin D in pharmacological dose, together with supplemental phosphate and calcium, will lead to symptomatic relief and biochemical and radiographic improvement. 348 By analogy, with hereditary hypophosphatemia calcitriol should be superior to calciferol and has been very effective in tumoral c a s e s . 139'372 Only a moderate

365 response was noted initially with short-term administration in nontumoral c a s e s , 351'352 but an excellent long-term response was recently observed. 373 As in XLH, hypercalcemic hyperparathyroidism develops with unusual frequency during treatment, 374'375 and is probably analogous to tertiary hyperparathyroidism with longstanding vitamin D depletion. These issues are discussed more fully in Section VIII. A final peculiarity of idiopathic nonhereditary hypophosphatemia is that in at least two cases, spontaneous complete recovery has occurred, allowing treatment to be w i t h d r a w n . 36~ Osteomalacia has also been reported in a few patients with carcinoma of the prostate. 35~176 The plasma calcitriol level has been low in the three cases measured, 378'379 and the biochemical syndrome has been induced in nude mice transplanted with tumor tissue from affected patients, TM but there are several differences from the usual form of oncogenous osteomalacia just described. First, with one exception 377 osteomalacia has occurred in patients already known to have widespread osteoblastic metastases, with a total tumor burden that is much larger than in patients with a benign mesenchymal tumor. Second, hyperosteoidosis is due at least in part to stimulation of new woven bone by tumor c e l l s 38~ and is found also in patients with osteosclerosis for other reasons such as thorotrast toxicity 383 or myeloid metaplasia. T M Third, affected patients are usually hypocalcemic as well as hypophosphatemic, 382 the abnormalities being of similar severity to those in patients who have osteoblastic metastases without osteomalacia. 47 Finally, many patients with this form of osteomalacia lack clinical effects from it, with no proximal muscle weakness, bone pain no worse than can be accounted for by the osseous metastases, and no Looser's zones or other radiographic features of osteomalacia. However, two patients treated with vitamin D 377 o r calcitrio1379 derived substantial relief of bone pain.

D. F a n c o n i S y n d r o m e For the most part this is a childhood disorder, 1'2'141 although Wilson's disease occasionally presents with osteomalacia without preceding rickets. 385 Onset in adult life does not rule out a genetic basis, probably always autosomal dominant, 386'387 but most cases are sporadic. Some are due to a known cause of renal tubular damage such as industrial or environmental cadmium intoxication 4'5'65'335'388'389 o r light-chain proteinuria. 14~ Fanconi syndrome due to external toxicity other than cadmium rarely causes osteomalacia, presumably because the effects are usually reversible, 39~ but can cause rickets. TM Some cases are tumor induced, as mentioned earlier, but many are diagnosed by exclusion as idiopathic. 39e'393

366

A.M. PARFITT

There is usually a close clinical resemblance to nonhereditary hypophosphatemia without the Fanconi syndrome, although osteopenia is less prominent and the manifestations are less severe if bone biopsy is used to facilitate early diagnosis. 14~ Calcitriol levels when measured have usually been lOW, 141'394'395 except in one case of light-chain nephropathy, 14~probably because the defect in the proximal tubule occurs at a site of calcitriol synthesisS; experimental induction of the Fanconi syndrome by administration of maleic acid also impairs l oL-hydroxylation. 396 Consistent with calcitriol deficiency, calcium absorption is impaired, 397 except in Wilson's disease 398 and cadmium poisoning, 335 in which for unknown reasons it can be increased. Urinary calcium excretion is often high (Table 1 1-9); this sometimes results from associated proximal renal tubular acidosis and is correctable by alkali administration, 397 sometimes from phosphate depletion, 399'4~176 and sometimes from a separate defect in tubular reabsorption of calcium. Osteomalacia in the adult Fanconi syndrome responds well to treatment with oral phosphate either a l o n e , 399'4~176 o r combined with calcitriol if the plasma level is l o w . 14~ In the autosomal dominant form there may be a greater need for alkali as well, 2'387 which also helps to preserve renal function. 388

E. Renal Tubular Acidosis and Ureteral Diversion These two conditions have in common chronic metabolic acidosis in which the low plasma bicarbonate is balanced by an increase in chloride rather than in normally unmeasured anions such as lactate. Hyperchloremic acidosis also occurs with carbonic anhydrase administration and with congenital absence of carbonic anhydrase, 4~ but these conditions have not been shown to cause osteomalacia. Renal tubular acidosis (RTA) is conveniently classified as proximal, in which bicarbonate reabsorption is reduced and distal, in which the urine cannot be maximally acidified. 4~ Proximal RTA is usually a component of the Fanconi syndrome (see Section VII.D). Lone proximal RTA with rare exceptions occur only in infants, with spontaneous recovery after a few years, and does not cause rickets. 4 The concurrence of lone proximal RTA and osteomalacia 4~ is usually a consequence of vitamin D depletion and secondary hyperparathyroidism. 99 In a possible exception to this rule, 4~ the Fanconi syndrome was not adequately excluded. Adult-onset distal RTA in most cases is a complication of Sjrgren's syndrome or other cause of hyperglobulinemia. 4~176176 The major effects of RTA are potassium depletion, nephrolithiasis, and nephrocalcin o s i s , 1'2'141'4~ their severity varying with the dietary acid

load. 20steomalacia was frequent in the past, 4~ although rarely verified histologically. 332'4~176176 Overt osteomalacia is n o w uncommon, 4~176 most likely because treatment is started earlier as a result of routine biochemical screening 4~ and is more likely to require bone biopsy for diagnosis 4~ (Fig. 1 1-15). It closely resembles vitamin D-related osteomalacia 1'2 including the presence of proximal muscle weakness, 411 and secondary hyperparathyroidism. 412'413 In one case the latter caused bone disease from osteitis fibrosa rather than from osteomalacia, 414 as sometimes happens in gluten enteropathy (see Section II.C), but hyperparathyroid effects usually are less severe than in HVO. 1 In the related condition of ureteral diversion, hyperchloremic acidosis is the result of preferential reabsorption of chloride and/or hydrogen ions from urine in contact with colonic or ileal epithelium. After ureterosigmoidostomy, histologically verified osteomalacia has developed in 5 to 18 years, 4~ but with ileal replacement of ureters, osteomalacia has been manifest clinically in 2 years and histologically (in the absence of symptoms) in 6 months. 419 This form of osteomalacia is more common in the U.K. than in the U.S., and in several cases there has been marginal vitamin D deficiency. 417,418 In both forms of hyperchloremic acidosis, the pathogenesis of osteomalacia is obscure. Despite the combined effects of hypokalemia, acidemia, and hyperparathyroidism, which all independently reduce tubular reabsorption of phosphate, mean plasma phosphate is only slightly lower than in vitamin D depletion I and plasma calcium is normal, so that the relevant formation product is probably not as low. Hypophosphatemia is significant only in an occasional patient with osteomalacia due to ureteral diversion. 416 Ammonium chloride administration increases urinary calcium excretion with little change in plasma calcium by simultaneously increasing net bone resorption and decreasing tubular reabsorption of calcium, but PTH secretion is unaffected so that this is an imperfect model for R T A . 42~ Furthermore, absolute hypercalciuria is uncommon in RTA. 332 Contrary to the predictions from animal experiments, metabolic acidemia does not impair calcitriol synthesis in humans 42~ unless they have renal failure, 422 and calcitriol levels are normal in both RTA 141 and ureteral di404 418 version ' unless there is significant renal insufficiency. 417 The usual malabsorption of calcium in RTA is not explained by calcitriol deficiency, but may be another effect of acidemia or an indirect consequence of retarded growth. 5 Acidemia probably impairs minerali5 404 zation directly,' either by lowering trivalent p 043- disproportionately, 423 or by compromising the removal of hydrogen ions from sites of mineral deposition. But several paradoxes remain; nonhyperchloremic acidosis, as in glycogen storage disease, does not impair bone min-

CHAPTER 11 Osteomalacia and Related Disorders eralization, and in one family with isolated proximal RTA, hyperchloremic acidosis of similar severity to distal RTA was unaccompanied by any disorder of bone mineral metabolism. 424 Whatever the explanation, administration of alkali 1.5 to 2.5 mEq/kg body weight per day will usually raise plasma phosphate and heal the osteomalacia both in R T A 425-427 and in ureteral divers i o n 416'418'419 s o that vitamin D is only needed in severe cases, or when delay in diagnosis has resulted in significant renal failure from nephrocalcinosis. 2

VII. OSTEOMALACIA NORMAL

VITAMIN

WITH

D AND

PHOSPHATE M E T A B O L I S M A. I n h i b i t o r s o f M i n e r a l i z a t i o n Impaired mineralization and osteomalacia can be produced by sodium etidronate used in the treatment of Paget's disease, sodium fluoride used in the treatment of osteoporosis, and aluminum from a variety of sources in patients on maintenance hemodialysis. Aluminum accumulation also contributes to bone disease in patients receiving total parenteral nutrition, 428 and a similar mechanism could be involved in thorium-related osteomalacia resulting from thorotrast exposure. 383 In all varieties of toxic osteomalacia there is a high prevalence of both atypical and focal forms as defined in Section I.G. Indeed, with the exceptions of pseudohypoparathyroidism 133 and hypophosphatasia, 429 focal osteomalacia is observed only with inhibitors of mineralization. Sodium etidronate blocks mineralization in vitro and probably binds to the crystal surface of newly deposited mineral in 1;ivo. 43~ Osteoid accumulation and reduced tetracycline uptake were first observed with the use of etidronate in the treatment of osteoporosis, 431 but were regularly seen in the treatment of Paget's disease in a dose of 10 mg/kg/day or more, associated with increasing bone pain and increased fracture r i s k . 432'433 The mineralization defect develops earlier and is more severe in pagetic than in normal bone, 9 presumably because of the difference in t u r n o v e r . 58'433 In the largest series with individual data reported, osteomalacia was generalized in 1 1, focal in 5, and atypical in 4. 432 Although a dose of 5 mg/kg/day is generally considered to be s a f e , 433'434 focal osteomalacia is quite common after treatment with this dose for 6 months or longer 36 (Fig. 1 1-16), and in one case there was generalized osteomalacia presenting with a pathological fracture. 435 Even infrequent cyclical administration has led to atypical osteomalacia. 436 The high frequency of focal osteomalacia presumably results from the depression of remodeling activation by etidron-

367 ate leading to reduced bone turnover before the emergence of a significant mineralization defect, but the occurrence of atypical osteomalacia is less easy to explain. Etidronate-induced osteomalacia is reversible, but the excess osteoid may not begin to mineralize for 3 to 6 months after the drug is discontinued. 58 Newer bisphosphonates are much less potent inhibitors of mineralization and do not cause osteomalacia, but may induce secondary hyperparathyroidism. 437 In patients with osteoporosis treated with sodium fluoride, significant increases in the surface extent, thickness, and volume of unmineralized osteoid have usually been observed, but initially they result from stimulation of matrix synthesis rather than from impaired mineralization. 438'439 Histological evidence of osteomalacia was found in 8 of 14 patients after 2 years of treatment but was clinically manifest only in o n e . 438 Impaired mineralization can occur as early as 6 months but may improve spontaneously during continued administration. 439 Symptomatic osteomalacia attributed to fluoride treatment has been reported only in a very few individual cases, 44~ probably because osteoid is usually added to mineralized bone (appositional osteomalacia) rather than replacing it (substitutional osteomalacia), so that structural failure is less likely. 58 Osteomalacia is also found in some patients after prolonged treatment with niflumic acid, a fluorine containing antiinflammatory agent. 442 We have observed osteomalacia in ten cases, of which six were generalized, three focal and one atypical (Fig. 11-16). Symptoms were present only in one patient with focal osteomalacia who had a painful stress fracture of a pubic ramus resembling a Looser's zone. The available data suggest that sodium fluoride in high doses significantly impairs mineralization in some patients. The defect is not prevented by physiological levels of vitamin D or related to abnormal vitamin D metabolism; the value of pharmacological doses of vitamin D 443 o r its metabolites 439 is unclear. Lack of substrate for mineralization may contribute to the defect, which may or may not be associated with secondary hyperparathyroidism. 439 Probably, there is both a physicochemical effect of fluoride at the mineralization front and a direct toxic effect on osteoblasts. Since trabecular thickness increases more in patients who develop osteomalacia than in those who do not (Kleerekoper and Parfitt, unpublished data), osteomalacia could be a stage in the evolution of a successful therapeutic response rather than a harmful side effect, 439 but may contribute to an increased fracture rate in the first year of fluoride treatment, especially if the dose is too high. Disabling osteomalacia with multiple spontaneous fractures, sometimes including the sternum (Fig. 11-12), was frequent during the 1980s among patients on maintenance hemodialysis, 81'444 especially after parathyroid-

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Osteoid thickness relationships in drug-induced osteomalacia. Layout as in Figures 1 1 - 8 and 1 1 - 1 5 with static measurements on left (A) and kinetic measurements on right (B). Data are from three patients with Paget's disease treated with etidronate 5 mg/kg body weight for 12 to 20 months giving rise to focal osteomalacia (single closed triangles), and 10 patients with osteoporosis treated with sodium fluoride in various regimens, with pretreatment values (open symbols) and posttreatment values (closed symbols) joined. Osteomalacia was focal in three cases (triangles), atypical in one case (squares), and generalized in six cases (circles). Note that complete arrest of mineralization was observed in all three etidronate-treated patients but in only 1 of 10 fluoride-treated patients.

ectomy. 445 The prevalence declined with better control of aluminum exposure, but too much aluminum in municipal water can cause osteomalacia even in undialyzed patients. 446 Both atypical osteomalacia, referred to in this context as aplastic 81 or type 11,444 and focal osteomalacia, 447 are common. Some patients have low-turnover nonosteomalacic osteopenia, 448 which occurs also with relative hypoparathyroidism in the absence of aluminum. 449 The different histological patterns reflect varying severity of prior hyperparathyroid bone disease, and of independent effects of aluminum and other factors to inhibit bone matrix synthesis and mineralization 9450 In patients with generalized osteomalacia, the bone formation rate is no lower than in the osteomalacia of vitamin D depletion, but there is a closer resemblance to hypophosphatemic osteomalacia. The morphological expression of hyperparathyroidism is less apparent and the mineralization defect is more severe, with osteoid seams that are relatively thicker (Fig. 1 1-17), and tetracycline uptake more often completely absent. 451 Aluminum inhibits mineralization both in vitro 452 and in v i v o 453 and dialysis osteomalacia is undoubtedly associated with aluminum deposition at the bone interface, 444-45~ and can develop in less than 1 year after an abrupt increase in water aluminum concentration. 453 But aluminum in the cement line, which is the initial location of the bone interface, frequently does not block mineralization in patients with osteitis fibrosa, 45~ and mineralization resumes after renal transplantation 456 or after deferoxamine treatment 57 despite persistence of stainable aluminum at the cement line. Furthermore,

nonuremic vitamin D-deficient animals given aluminum accumulate it in bone without impairing the healing response to vitamin D. 457'458 Clearly other factors must be involved in the pathogenesis of aluminum-related osteomalacia. One such factor could be the plasma level of citrate, which complexes aluminum to form a more potent inhibitor of mineralization than any other aluminum salt. 459 Another could be direct effects of aluminum on the function of osteoblasts, in which cells aluminum can be demonstrated within mitochondria. 45~

B. Inability of Matrix to Mineralize Although abnormal matrix maturation may contribute to osteomalacia in vitamin D depletion, osteomalacia due to defective bone matrix alone in the absence of any disorder of bone mineral or vitamin D metabolism has been established only in fibrogenesis imperfecta ossium. 46~ In this rare condition, normal lamellar bone is replaced by matrix with no birefringence in polarized light and no fiber pattem detectable by light microscopy, but which by electron microscopy consists of a tangled mass of very thin, short, and irregularly curved fibers. 461 Mineralization of the abnormal matrix is delayed and retarded, but because the protein content of the matrix is reduced by as much as 75%, mineral density ultimately becomes higher than normal. 46~ Nevertheless, bone surfaces are covered by thick and extensive layers of unmineralized matrix, the ultrastructural appearance of the mineralization front is abnormal, 462 and conform-


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FIGURE 1 1 - - 1 7 Osteoid thickness relationships in aluminum-related osteomalacia occurring during maintenance hemodialysis. Layout as in Figures 1 1 - 8 , 11-15, and 11-16, with static measurements on left (A) and kinetic measurements on right (B). Data are from 46 patients, 15 with osteitis fibrosa (C)), 25 with generalized osteomalacia (O), 1 with focal osteomalacia (A), and 5 with aplastic bone disease (11); these represent an early stage of atypical osteomalacia with OV/BV between 5% and 10%. Note that there is considerable overlap in patients with and without osteomalacia by the static measurements, but clear demarcation by the kinetic measurements.

ity to the kinetic criteria for generalized osteomalacia has been demonstrated by double tetracycline labeling. 463 The condition most often presents in the fifth or sixth decade with intractable pain and multiple fractures, the patients often becoming unable to walk and dying within a few y e a r s . 464 The radiographic appearances are characteristic but can be confused with Paget's d i s e a s e . 463'465 Since there is always some normal bone, the matrix defect must begin in adult life, probably only a few years before the onset of symptoms. 46~In one case, histological and biochemical indices of bone resorption were increased, but there was no therapeutic response to calcitonin. 462 There is a high frequency of monoclonal gammopathy, and in one case with kappa light chains in serum and urine, complete clinical remission and resumption of normal bone formation and mineralization were achieved by combined treatment with cyclical melphalan and prednisolone. 466 A possible explanation for this extraordinary observation, which has far-reaching implications for the cell biology of bone, is that cytotoxic therapy eliminated a population of abnormal osteoblast precursors.

C. Disorders of Alkaline Phosphatase The role of alkaline phosphatase in mineralization has been discussed for many years and is still unclear, but osteomalacia occurs in hypophosphatasia, a genetic defect in the synthesis of alkaline phosphatase 467 and in so-

called axial osteomalacia, in which morphologically inactive osteoblasts stain with paradoxical intensity for alkaline phosphatase. 468 Hypophosphatasia is usually an autosomal recessive disorder that presents in infancy with rickets, raised intracranial pressure, hypercalcemia, nephrocalcinosis, and early death; in mild cases the onset is in later childhood, and spontaneous radiographic improvement c a n o c c u r . 467 There is partial and variable deficiency (10% to 30% of normal) of the bone/liver/kidney isoenzyme in cultured skin fibroblasts, 469 similar reductions of the bone-specific component of serum alkaline phosphatase, 47~and normal intestinal and placental isoenzymes. The plasma level and urinary excretion of phosphorylethanolamine are increased, most likely as a consequence of altered hepatic metabolism. But more diagnostically specific is an increased plasma level of pyridoxal 5'-phosphate. 467 The plasma level and urinary excretion of inorganic pyrophosphate are also increased; alkaline phosphatase functions as a pyrophosphatase in bone, and failure to hydrolyze pyrophosphate in matrix vesicles could account for the mineralization defect, which persists when epiphyseal cartilage from affected subjects is incubated in vitro in solutions that calcify normal cartilage. 467 There is no evidence for any abnormality in vitamin D metabolism. 471 Adult hypophosphatasia is much commoner than previously suspected and is characterized by early loss of permanent teeth; calcium pyrophosphate arthropathy; osteopenia and increased risk of stress fractures; and os467

370 teomalacia of variable severity, usually atypical, less commonly generalized, and occasionally f o c a l . 57'472 Alkaline phosphatase staining in osteoblasts is of markedly reduced intensity, and its surface extent is inversely correlated with the amount of osteoid. 472 Most patients with abnormal bone histology are asymptomatic. The same biochemical abnormalities are found in blood and urine as in the childhood forms. In some cases there is a history of tickets in childhood and the presence of deformities common in the childhood form such as prominent sternum and loss of normal curvature of the thoracic spine, 473 but in several large kindreds with autosomal dominant transmission the onset of clinical effects was clearly in adult l i f e . 467'472 The clinical expression of the biochemical defect varies considerably both within and between families. The term "axial osteomalacia" is applied to a disorder in which trabecular bone of the axial skeleton is of increased radiodensity with an irregular, coarsened, and sponge-like appearance. 474 In the most recent case, very high spinal bone density was confirmed by dual energy x-ray absorptiometry (DEXA). 475 Pain in affected bone is mild or absent, and fractures do not occur. Histologically, the trabecular plates are irregularly thickened and closely packed, with increased surface extent and width of osteoid and reduced extent and separation of tetracycline uptake, but both mineralized and unmineralized bone is of lamellar structure with normal birefringence. 1~ The mineralization defect may be f o c a l . 475 The appendicular skeleton is radiographically normal; in one case osteoid was abundant in the ilium and absent in a tibial malleolus, providing the first direct evidence that the mineralization defect is confined to the axial skeleton. 476 The disorder is sometimes classified with fibrogenesis imperfecta ossium as a matrix defect, but supporting evidence is lacking. The serum alkaline phosphatase has been raised only in 3 of 13 published cases, two from one family, all other cases being sporadic. 468 The only clue to pathogenesis is the increased alkaline phosphatase content of osteoblasts, which is disproportionate to the increase in serum level and inconsistent with other indices of osteoblast activity. A defect either in the release of alkaline phosphatase at sites of bone formation or in its biological effectiveness could account for impaired mineralization, but would not explain the osteosclerosis.

VIII. THERAPEUTIC INTERVENTION IN O S T E o M A L A C I A There is an important difference between the two main etiological categories. Vitamin D-related osteomalacia occur for the most part only in persons already

A.M. PARFITT known to be at risk and so in principle is largely preventable. By contrast, phosphate-related osteomalacia is usually less predictable, so that prevention is less often possible. Occasional measurement of urinary phosphate in patients on long-term antacid therapy would prevent phosphate depletion, and appropriate family surveillance might forestall symptoms in some genetic disorders. It is reasonable to continue treatment in familial hypophosphatemia after cessation of growth to minimize adult complications. 336 Routine multichannel biochemical screening probably leads to treatment of renal tubular acidosis before the onset of osteomalacia in most cases, but accidentally discovered hypophosphatemia is usually either transient or mild and of uncertain significance. 4'478 With these few exceptions, prevention can be usefully discussed only in relation to vitamin D.

A. Prevention of HVO The prevention of intrinsic vitamin D depletion is primarily an issue of public health rather than of individual patient care, but many studies carried out with the object of influencing public policy have been poorly designed. 2~ Attempts to eradicate migrant osteomalacia in the U.K. have included provision of free vitamin D tablets and various types of education, but neither measure has been convincingly demonstrated to improve health. 2~ Any policy that requires ostensibly healthy Asian adults to permanently change their habits with respect to diet or sun exposure or to take daily medication indefinitely will inevitably fail. More realistic is to give a single oral dose of 2.5 mg of calciferol annually just before winter, an effective and safe method of maintaining adequate plasma calcidiol levels in Asians throughout the y e a r . 479 Compliance with medical advice is likely to be better during pregnancy and 25 Ixg of calciferol daily during the last trimester would improve fetal growth and ossification and minimize the occurrence of neonatal hypocalcemia as well as protecting the mother. 48~ The same principles apply to prevention in the elderly. Very few will take a weekly serving of sardines or an annual vacation by the Mediterranean because of medical advice. Therapeutic ultraviolet irradiation is both physiological and effective, but it is also cumbersome, expensive, and potentially hazardous. ~13'481An oral vitamin D supplement of 20 Ixg/day given to old people at varying levels of risk in Ireland maintained satisfactory plasma levels of calcidiol, corrected any biochemical abnormalities indicative of subclinical HVO, and appeared to be entirely safe. 482 Unfortunately, the preparation used also supplied 60,000 IU/day of vitamin A, the long-term safety of which has not been rigorously established. Nevertheless, the observation supports the

CHAPTER 11 Osteomalaciaand Related Disorders proposal that the RDA for vitamin D in the U.S. should be increased to 15 to 20 Ixg/day in the elderly ~3 and should be heeded by those responsible for their nutritional needs. It should also encourage the governments of Northern European countries to adopt vitamin D fortification, at least to the level practiced in the U.S. and Canada, and preferably extended to a wider range of foods. There is still no satisfactory pharmaceutical preparation for giving a physiological daily dose of vitamin D to adults, w6 Prevention of HVO in patients with gastrointestinal or hepatobiliary disease or receiving anticonvulsant therapy depends on medical awareness of the risk in these populations. The best policy has not yet been determined, but to be successful, it should be applied before serum alkaline phosphatase has increased or cortical osteopenia has developed. The degree of vitamin D depletion varies widely between patients, and no single oral dose is uniformly safe and effective in prophylaxis. Absorption from intramuscular injections of vitamin D dissolved in oil is unpredictable, 483 and a water-soluble preparation that can be given intravenously is not generally available, w6 Individual monitoring is unavoidable and a reasonable policy is to give a capsule (not tablet) of 1.25 mg of ergocalciferol at a frequency that maintains plasma calcidiol between 20 and 40 ng/ml, although higher plasma levels will be needed in some patients with intestinal resection or refractory sprue. For most patients the requisite frequency will lie somewhere between once a month and once a day. An amount of supplemental calcium should be added, such that the combination maintains urinary calcium excretion between 100 and 250 mg/24 hours (or calcium/creatinine ratio between 0.1 and 0.2 mg/mg) and plasma calcium, alkaline phosphatase, and the best available index of parathyroid function within normal limits. With these guidelines, some patients will be treated unnecessarily, in the sense that they would never have developed symptoms even if nothing was done, but many patients will benefit and none will be harmed.

B. T r e a t m e n t o f H V O The aims of treatment are to relieve symptoms, restore bone strength by promoting mineralization of osteoid, and preserve mineralized bone by correcting secondary hyperparathyroidism. It is important that all three aims are explained to the patient and that the first is not permitted to overshadow the second and third. In extrinsic vitamin D depletion these aims are best served by giving a modest dose of vitamin D (25 to 50 Ixg/day), together with adequate supplemental calcium. Urgent treatment of hypocalcemia is occasionally required in

371 patients with osteomalacia. The responses to treatment and time course of healing will be described first, followed by some practical aspects of management and modifications of the regimen needed for other causes of HVO. 1. RESPONSE TO VITAMIN D

Giving a physiological dose of vitamin D to a patient with extrinsic vitamin D depletion produces a characteristic series of changes. 1'2'6'1~ The plasma calcitriol level begins to rise immediately and quickly reaches supranormal levels, intestinal calcium and phosphate absorption promptly increase, plasma calcium (if low) returns to normal in 1 to 4 weeks, PTH secretion falls rapidly but not to normal, and plasma phosphate rises to normal in 4 to 8 days and then to above normal for several months. Osteoclast function improves, and there is a rapid increase in urinary hydroxyproline. 7~Osteoblast function improves and mineralization resumes rapidly, probably within a week, plasma alkaline phosphatase increases further, calcium and phosphate are rapidly deposited in bone and external balance becomes positive usually by the second 4-day period, with low fecal as well as urinary calcium excretion. 6'41 Symptoms improve soon after and a previously bedridden patient may become able to walk without pain in a few weeks, but restoration of normal muscle power 44 and normal parathyroid function 85 can take up to 2 years or even longer, and it is important that the asymptomatic patient not default from follow-up. Osteoid indices and cortical porosity eventually return to normal, accompanied by large increases in vertebral and hip bone mineral density,10 but loss of cortical thickness is permanent. 57 Some of these changes will now be described in more detail. 2. EFFECT ON BONE MINERAL METABOLISM

When their substrate is depleted, both 25- and l cthydroxylase enzymes are maximally active and vitamin D is rapidly and almost quantitatively converted to calcitriol, so that the doses of calciferol and calcitriol needed for most rapid healing are almost the same, despite the 1000-fold difference in doses in other circumstances, such as the treatment of hypoparathyroidism. 484 Plasma calcidiol may not begin to rise for several weeks, but plasma calcitriol reaches three to five times the nor157 158 mal level and can remain elevated for many months, ' sustained by continued hypersecretion of PTH despite restoration of normocalcemia 85'86 and probably also by continued low blood levels of calciferol and calcidiol. Plasma phosphate rises by about 1.0 mg/dl to reach a normal value in the first week with a transient fall in urinary phosphate indicating increased tubular reabsorption, ~'4 and continues to rise to a peak value about 1.0 mg/dl higher than normal by 3 to 4 weeks, and then falls

3

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A

slowly for the next 6 m o n t h s . 41 Although both the rise in plasma calcium and the initial fall in PTH may contribute to the early rise in plasma phosphate, the later increase in tubular reabsorption of phosphate above normal is most likely the result of continued elevation of plasma calcitriol acting directly on the kidney. 484 3. EFFECT ON BONE MINERALIZATION AND REMODELING

Tetracycline-based histomorphometry during the healing of osteomalacia is limited, but serial measurement of the extent of toluidine blue stainable mineralization front supports the inference from balance studies that substantial mineral deposition begins within a week of starting treatment. 166'485'486 However, it is unlikely that normal mineralization is immediately restored over the entire osteoid surface, since this would require calcium retention of 2.0 to 3.0 g/day rather than the 0.5 to 1.0 g/day usually found. Furthermore, even the thickest osteoid seam should mineralize completely within 3 months, but mean seam thickness can take much longer to return completely to normal. The most likely explanation for the delay is that mineralization can begin immediately only where osteoblasts are still present. 35'165-167 Elsewhere, the flat cells coveting the osteoid surface must reacquire osteoblast function and morphological features, and additional osteoblasts must be recruited to maintain coverage of the surface, processes that probably continue for several months and are responsible for the further increase in serum alkaline phosphatase that begins soon after starting treatment. At some of the thickest seams mineralization may resume closer to the surface than the bone interface, leaving a layer of osteoid that remains permanently unmineralized as a residual "scar."35 In biopsies taken at varying times between 3 and 12 months after treatment was begun, mean values for mineral apposition rate were about 30% above normal and mean values for bone formation rate about five times greater than normal (Teotia and Parfitt, unpublished data). It is likely that osteomalacia heals by reversing its sequence of development, so that a patient in stage iii at the onset of treatment would pass successively through stage ii (return of double labels, but seam thickness still increased) and stage i (seam thickness normal, but formation rates still high) before returning completely to normal. This histological evolution is accompanied by a gradual fall in alkaline phosphatase and, when remineralization is almost complete, by a rise in urinary calcium excretion. With the increase in mineralized bone surface and continued hyperparathyroidism there is an increase in absolute surface extent and number of osteoclasts, and a decline in total bone matrix volume, even though mineralized bone volume is increasing. Bone turnover prob-

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ably remains elevated until the completion of parathy102 roid involution, which is a very slow process. 4. PRACTICAL ASPECTS OF MANAGEMENT The ability of 1et-hydroxylated metabolites to cure the osteomalacia of extrinsic vitamin D depletion 4'5'1~is important to the understanding of physiology and pathogenesis, but it is simpler and safer to give the precursor and rely on the regulated endogenous production of calcitriol which cannot lead to overtreatment and vitamin D intoxication. 484 Even in patients with age-related decline in renal function and l oL-hydroxylase activity, no advantage over calciferol has been demonstrated. 481 The dose of vitamin D is not critical, healing can be initiated with only 2 to 3 Ixg/day but will proceed more rapidly with a larger d o s e . 196'485 Calcium conservation is very efficient during the early stages of recovery,6 but supplemental calcium 1.0 to 2.0 g/day will restore mineralized bone and suppress parathyroid hypersecretion more quickly 488 and make it less likely that replenishment of the axial skeleton will occur at the expense of the appendicular skeleton. 13 The most impressive calcium retention has been achieved with microcrystalline hydroxyapatite, which provides all the required minerals in the correct proportion, 41'484 but this preparation is not currently available in the U.S. and any form of calcium is satisfactory. Cortical bone that was lost during the development of the disease cannot be replaced, 51 and with the resumption of normal physical activity the patient should be advised how to minimize the chance of falling. The treatment of osteomalacia due to intrinsic vitamin D depletion follows the same general principles, but differs in several points of detail. First, as for prevention, the dose of vitamin D varies over a wide range and is unpredictable. Second, although vitamin D itself is the cheapest and safest compound for prevention, and for the correction of extrinsic depletion, calcidiol has several potential advantages in patients with intestinal or hepatobiliary disease. It is more precisely formulated, 119 better absorbed, 22~bypasses any defect in 25-hydroxylation, leads to more predictable blood levels that can be monitored directly, 4'5'316 and is more rapid in onset and offset of its effects, so that the response to a change in dose can be detected more rapidly, 119'484but retains physiological regulation of 1-hydroxylation. Third, whatever compound is used, the dose requirement will be greatly affected by the response of the underlying disease to treatment, 4'5's and will (for example) show a larger and more rapid decline during the successful use of a glutenfree diet in celiac disease than during the attempted correction of pancreatic enzyme deficiency. Finally, because the dosage is both higher and varies more with time, more frequent and careful monitoring of the therapeutic response is required to avoid vitamin D intoxication. 47'196

CHAPTER 11 Osteomalaciaand Related Disorders This should be on the same lines as previously recommended for prevention, but with particular attention to the approach of plasma alkaline phosphatase to normal and a rise in urinary calcium excretion, which may both give warning of a need to reduce the dose. A moderate increase in plasma creatinine during healing may reflect a change in muscle metabolism rather than a decline in renal function, and so is not by itself an indication for any change in treatment. 489

C. Treatment of Hypophosphatemic Osteomalacia XLH, nonhereditary hypophosphatemia, and the Fanconi syndrome differ in many ways, but they have in common a primary (non-PTH-dependent) defect in tubular phosphate reabsorption and either relative or absolute impairment of calcitriol synthesis. In the absence of a tumor or of some reversible cause of renal tubular damage, 386 optimum treatment of all three conditions is based on some combination of supplemental phosphate and calcitriol. 8- ~o 24-hydroxy calcidiol may contribute to the control of phosphate-induced secondary hyperparathyroidism, 49~ and nonhypercalcemic analogues of calcitriol may prove to be advantageous. 49~ Otherwise the only medications that may be needed are supplemental calcium in severe nonhereditary hypophosphatemia, and alkali in renal tubular acidosis, primary or secondary, as was previously indicated.

373 The principal benefit of supplemental phosphate is direct enhancement of bone mineral deposition, but there can be additional benefits unrelated to a rise in plasma level. In patients with defective urinary acidification as well as impaired phosphate reabsorption, metabolic acidosis is improved by provision both of alkali and of additional urinary buffer to facilitate hydrogen ion excretion. 495 Also, phosphate supplements increase tubular reabsorption of calcium and reduce calcium excretion, even in the absence of metabolic acidosis. 47 When used in the treatment of hypercalcemia, supplemental phosphate may lead to hypocalcemia, soft tissue calcification, and impaired renal function47; these effects are not usually observed during the treatment of hypophosphatemic osteomalacia, although in patients treated with calcitriol as well, the severity of nephrocalcinosis is related to the dose of phosphate. 496 Diarrhea is troublesome in some patients, but the most serious complication of long-term treatment with phosphate is the emergence of hypercalcemic hyperparathyroidism needing surgical intervention. This has been reported after 2 to 18 years of treatment in 16 cases, 1 1 with XLH and 5 with nonfamilial hypophosphatemia, 3 with and 2 without a tumor. 374'375'497 The parathyroid pathology has been variable but with a predominance of multiple gland involvement. The pathogenesis is probably similar to the tertiary hyperparathyroidism of longstanding vitamin D depletion (see Section II.F), but a parathyroid adenoma was found in one patient with XLH who had never received phosphate. 374 2. CALCITRIOL

1. PHOSPHATE SUPPLEMENTATION Since phosphate is reasonably safe and sometimes effective by itself, 14~176176 it is logical to use it initially as the only treatment. In the hypercalciuric form of hereditary hypophosphatemia, only phosphate is needed and calcitriol is contraindicated. 492 With normal renal function, even a large phosphate supplement can produce only a modest increase in plasma phosphate, which depends much more on the renal threshold than on the phosphate load to be excreted. Assuming 70% to 75% absorption and a glomerular filtration rate (GFR) of 100 ml/min, the mean plasma phosphate will rise by about 0.5 mg/dl for each 1.0 g/day increment in elemental phosphorus intake, with a smaller rise in fasting plasma phosphate. Even this theoretical maximum will be attained only if the phosphate is administered as the potassium rather than as the sodium salt, since expansion of the extracellular fluid volume by sodium may reduce tubular phosphate reabsorption and partly offset the rise in plasma phosphate. 493 Conversely, the effect of the supplement can be augmented by dietary salt restriction 47 or by diuretic therapy. 494

The effect of vitamin D in a pharmacological dose in a nondepleted subject is quite different from its effect in physiological dose in a depleted subject. ~96 First, the 25and loL-hydroxylase enzymes are relatively inactive and are suppressed further by excess of the substrate so that the response is much slower in onset. Second, even when the maximum response has been achieved, less of the absorbed calcium and phosphate is retained in bone and much more is excreted in the urine. Finally, when treatment is stopped the effect may persist for many months because of the large capacity of body storage sites for calciferol and calcidiol. There may be only a modest or even no increase in plasma calcitriol, but a substantial rise in plasma calcidiol, 338 probably sufficient to increase the occupancy of calcitriol receptors despite its much lower affinity. Although with careful attention to detail, satisfactory results can be achieved with calciferol, 62'196'348 and early results in nonhereditary hypophosphatemia have shown little advantage for l ct-hydroxylated compounds, 351'352 it is likely that with increasing experience and better definition of optimum dose requirements calcitriol (or alfacalcidol, which produces

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calcitriol after hepatic 25-hydroxylation) will be the vitamin D metabolite of choice in all forms of hypophosphatemic osteomalacia. 1~ In vitamin D-replete patients, calcitriol increases intestinal absorption of calcium and phosphate more reliably than calciferol, but its most important therapeutic effect is to increase the renal tubular reabsorption of phosphate with a consequent rise in plasma phosphate. 338 Although commonly attributed to suppression of PTH secretion, 498 it is more likely a direct renal tubular effect of supraphysiological plasma levels of calcitrio1338'499 as occurs during the treatment of extrinsic vitamin D depletion. 484 In children, the doses needed to achieve this effect are in the range of 50 to 80 ng/kg/day, which corresponds to 2.5 to 5 Ixg/day (or 4 to 8 Ixg/dl of alfacalcidol) for most adults, preferably administered at frequent short intervals because of the short half-life. Even though the hypercalciuric and hypercalcemic effects are partly neutralized by concurrent administration of phosphate, that is very close to the intoxicating dose, particularly as the osteomalacia heals, and frequent and meticulous supervision is essential. Even so, it is difficult to avoid the development of nephrocalcinosis. 496 Once healing has been achieved, the dose can be reduced to a safer and more manageable level. 5'1~ The need for such large doses with their attendant hazards should be considered only after smaller doses have proved ineffective, since healing and symptomatic relief can often be accomplished by a dose that increases calcium absorption without increasing phosphate reabsorption, together with an adequate phosphate supplement. 14~ Concurrent calciferol does not prevent phosphate-induced tertiary hyperparathyroidism; the likely greater effectiveness of calcitriol, 497 24-hydroxy calcidiol, 49~ or nonhypercalcemic analogues of calcitrio1491 in this respect remains to be demonstrated.

Acknowledgments Many colleagues, present and former, contributed to the data and concepts presented in this chapter, but two were indispensable. D.S. Rao performed almost all of the transiliac bone biopsies, demonstrating that in expert hands it can be one of the safest and least unpleasant of all invasive procedures. A.R. Villanueva performed almost all the bone histomorphometry, with results that are a testament to his insight, skill, and experience.

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3. Aaron J: Histological aspects of the relationship between vitamin D and bone. In Lawson DEM (ed): Vitamin D. London, Academic Press, 1978. 4. Parfitt AM: Osteomalacia and related disorders. In Avioli LV, Krane SM (eds): Metabolic Bone Disease and Clinically Related Disorders, 2nd ed. Philadelphia, WB Saunders Co, 1990, pp 329-396. 5. Stanbury SW, Mawer EB: Metabolic Disturbances in Acquired Osteomalacia. In Cohen RD, Lewis B, Alberti KGMM, Denman AM (eds): The Metabolic and Molecular Basis of Acquired Disease. London, Bailliere Tindall, 1990, pp 1717-1782. 6. Parfitt AM, Chu HI: Pioneer clinical investigator of vitamin D deficiency and osteomalacia in China. A scientific and personal tribute (editorial). Calcif Tissue Int 37:335-339, 1985. 7. Lowenthal MN, Shany S: Osteomalacia in Bedouin women of the Negev. Israel J Med Sci 30:520-523, 1994. 8. Marel GM, McKenna MJ, Frame B: Osteomalacia. In Peck WA (ed): Bone and Mineral Research 4. Amsterdam, Elsevier, 1986, pp 335-412. 9. Goldring SR, Krane SM: Disorders of calcification: Osteomalacia and Rickets. In DeGroot LJ, et al (eds): Endocrinology, vol 2, 2nd ed. Philadelphia, WB Saunders Co, 1989. 10. Peacock M: Osteomalacia and rickets. In Nordin BEC, Need AG, Morris HA (eds): Metabolic Bone and Stone Disease, 3rd ed. London, Churchill Livingstone, 1993, pp 83-118. 11. Avioli LV, Baran DT, Whyte MP, et al: The biochemical and skeletal heterogeneity of "post-menopausal osteoporosis." In Barzel US (ed): Osteoporosis II. New York, Grune & Stratton, 1978, pp 49-64. 12. Parfitt AM: Bone fragility in osteomalacia: Mechanisms and consequences. In Uhthoff H (ed): Current Concepts of Bone Fragility. New York, Springer-Verlag, 1986, pp 265-270. 13. Parfitt AM: Accelerated cortical bone loss: Primary and secondary hyperparathyroidism. In Uhthoff H (ed): Current Concepts of Bone Fragility. New York, Springer-Verlag, 1986, pp 2 7 9 285. 14. Parfitt AM, Mathews C, Rao D, et al: Impaired osteoblast function in metabolic bone disease. In DeLuca HF, Frost H, Jee W, et al (eds): Osteoporosis: Recent Advances in Pathogenesis and Treatment. Baltimore, University Park Press, 1981, pp 321-330. 15. Rao DS, Villanueva A, Mathews M, et al: Histologic evolution of vitamin depletion in patients with intestinal malabsorption or dietary deficiency. In Frame B, Potts JT Jr (eds): Clinical Disorders of Bone and Mineral Metabolism. Amsterdam, Excerpta Medica, 1983, pp 224-226. 16. Parfitt AM: Skeletal heterogeneity and the purposes of bone remodeling: Implications for the understanding of osteoporosis. In Marcus R, Feldman D, Kelsey J (eds): Osteoporosis. San Diego, Academic Press, 1996, pp 315-329. 17. Parfitt AM: Osteonal and hemi-osteonal remodeling: The spatial and temporal framework for signal traffic in adult human bone. J Cell Biochem 55:273-286, 1994. 18. Jaworski ZF, Lok E: The rate of osteoclastic bone erosion in haversian remodeling sites of adult dog's rib. Calcif Tissue Res 10:103-112, 1972. 19. Parfitt AM: The physiologic and pathogenetic significance of bone histomorphometric data. In Coe FL, Favus MJ (eds): Disorders of Bone and Mineral Metabolism. New York, Raven Press, 1992, pp 475-489. 20. Parfitt AM: Human bone mineralization studied by in vivo tetracycline labeling: Application to the pathophysiology of osteomalacia. Exerpta Medica International Congress, 4th International Symposium on Chemistry and Biology of Mineralized Tissues, 1992, pp 465-474.

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415. Leite CA, Frame B, Frost HM, Arnstein AR: Osteomalacia following ureterosigmoidostomy. With observations on bone morphology and remodeling rate. Clin Orthop 49:103-108, 1966. 416. Donohoe JF, Freaney R, Muldowney FP: Osteomalacia in ureterosigmoidostomy. Ir J Med Sci 2:523-530, 1969. 417. Perry W, Allen LN, Stamp TCB, Walker PG: Vitamin D resistance in osteomalacia after ureterosigmoidostomy. N Engl J Med 297:1110-1112, 1977. 418. Cunningham J, Fraher LJ, Clemens TL, et al: Chronic acidosis with metabolic bone disease. Effect of alkali on bone morphology and vitamin D metabolism. Am J Med 73:199-204, 1982. 419. Salahudeen AK, Elliott RW, Ellis HA: Osteomalacia due to ileal replacement of ureters: Report of 2 cases. J Urol 131:335-337, 1984. 420. Adams ND, Gray RW, Lemann J Jr: The calciuria of increased fixed acid production in humans: Evidence against a role for parathyroid hormone and 1,25(OH)z-vitamin D. Calcif Tissue Int 28:233-238, 1979. 421. Kraut JE, Gordon EM, Ransom JC, et al: Effect of chronic metabolic acidosis on vitamin D metabolism in humans. Kidney Int 24:644-648, 1983. 422. Lu K-C, Lin S-H, Yu F-C, et al: Influence of metabolic acidosis on serum 1,25(OH)2D3 levels in chronic renal failure. Miner Electrolyte Metab 21:398-402, 1995. 423. Cochran M, Nordin BEC: Role of acidosis in renal osteomalacia. Br Med J 2:276-279, 1969. 424. Brenes LG, Brenes JN, Hernandez MM: Familial proximal renal tubular acidosis. A distinct clinical entity. Am J Med 63:244249, 1977. 425. Dundon S: Treatment of osteomalacia of renal tubular acidosis. Lancet 2:1204, 1972. 426. Richards P, Chamberlain MJ, Wrong OM: Treatment of renal tubular acidosis by sodium bicarbonate alone. Lancet 2 : 9 9 4 997, 1972. 427. Mautalen C, Montoreano R, Labarrere C: Effect of therapy upon the osteomalacia of renal tubular acidosis. J Clin Endocrinol Metab 42:875-881, 1976. 428. Ott SM, Maloney NA, Klein GL, et al: Aluminum is associated with low bone formation in patients receiving chronic parenteral nutrition. Ann Intern Med 98:910-914, 1983. 429. Weinstein RS, Whyte MP: Heterogeneity of adult hypophosphatasia. Report of severe and mild cases. Arch Intern Med 141: 727-731, 1981. 430. Russell RGG, Fleisch H: Pyrophosphate and diphosphonate in skeletal metabolism. Physiological clinical and therapeutic aspects. Clin Orthop 108:241-263, 1975. 431. Jowsey J, Riggs BL, Kelly PJ, et al: The treatment of osteoporosis with disodium ethane-l-hydroxy-l,l-diphosphonate. J Lab Clin Med 78:574-584, 1971. 432. Khairi MRA, Altman RD, DeRosa GP, et al: Sodium etidronate in the treatment of Paget's disease of bone. A study of longterm results. Ann Intern Med 87:656-663, 1977. 433. Krane SM: Etidronate disodium in the treatment of Paget's disease of bone. Ann Intern Med 96:619-625, 1982. 434. Alexandre N, Chapuy MC, Vignon E, et al: Treatment of Paget' s disease of bone with ethane-l, hydroxy-l,1 diphosphonate (EHDP) at a low dosage (5 mg/kg/day). Clin Orthop 174:193205, 1983. 435. Evans RA, Dunstan CR, Hills E, Wong SYP: Pathologic fracture due to severe osteomalacia following low-dose diphosphonate treatment of Paget's disease of bone. Aust NZ J Med 13:277279, 1983. 436. Thomas T, LaFage M-H, Alexandre C: Atypical osteomalacia after 2 year etidronate intermittent cyclic administration in osteoporosis. J Rheumatol 22:2183-2185, 1995.

CHAPTER 11


437. Rossini M, Gatti D, Zamberlan N, et al: Long-term effects of a treatment course with oral alendronate of postmenopausal osteoporosis. J Bone Miner Res 9:1833-1837, 1994. 438. Briancon D, Meunier PJ: Treatment of osteoporosis with fluoride, calcium, and vitamin D. Orthop Clin North Am 12:629648, 1981. 439. Lundy MW, Stauffer M, Wergedal JE, et al: Histomorphometric analysis of iliac crest bone biopsies in placebo-treated versus fluoride-treated subjects. Osteoporos Int 5:115-129, 1995. 440. Grennan DM, Palmer DG, Mathus RS, et al: Iatrogenic fluorosis. Aust NZ J Med 8:528-531, 1978. 441. Compston JE, Chadha S, Merrett AL: Osteomalacia developing during treatment of osteoporosis with sodium fluoride and vitamin D. Br Med J 281:910-911, 1980. 442. Bonvoisin B, Bouvier M, Meunier PJ, Lejeune E: Osteomalacie histologique induite par l'administration prolongee d'acide niflumique. Nouv Presse Med 11:1636, 1982. 443. Kleerekoper M, Frame B, Villanueva AR, et al: Treatment of osteoporosis with sodium fluoride altemating with calcium and vitamin D. In DeLuca HF, et al (eds): Osteoporosis: Recent Advances in Pathogenesis and Treatment. Baltimore, University Park Press, 1981. 444. Dunstan CR, Hills E, Norman AW, et al: The pathogenesis of renal osteodystrophy: Role of vitamin D, aluminum, parathyroid hormone, calcium and phosphorus. Q J Med 55:127-144, 1985. 445. Andress DL, Ott SM, Maloney NA, Sherrard D J: Effect of parathyroidectomy on bone aluminum accumulation in chronic renal failure. N Engl J Med 312:468-473, 1985. 446. O'Brien AAJ, Moore DP, Keogh JAB: Aluminum osteomalacia in chronic renal failure patients neither on dialysis nor taking aluminum containing phosphate binders. Ir J Med Sci 159:7476, 1990. 447. Boyce BF, Elder HY, Elliot HL, et al: Hypercalcaemic osteomalacia due to aluminum toxicity. Lancet 2:1009-1013, 1982. 448. Charhon SA, Chavassieux PM, Chapuy MC, et al: Low rate of bone formation with or without histologic appearance of osteomalacia in patients with aluminum intoxication. J Lab Clin Med 106:123-131, 1985. 449. Moriniere P, Cohen-Solal M, Belbrik S, et al: Disappearance of aluminic bone disease in a long term asymptomatic dialysis population restricting AI(OH)3 intake: Emergence of an idiopathic adynamic bone disease not related to aluminum. Nephron 53: 9 3 - 1 0 1 , 1989. 450. Parfitt AM: The localization of aluminum in bone: Implications for the mechanism of fixation and for the pathogenesis of aluminum-related bone disease (editorial). Int J Artif Organs 11: 7 9 - 9 0 , 1988. 451. Parfitt AM, Rao D, Stanciu J, Villanueva AR: Comparison of aluminum related with vitamin D related osteomalacia by tetracycline based bone histomorphometry. In Massry SG, Olmer M, Ritz E (eds): Phosphate and Mineral Homeostasis. Adv Exp Biol Med 208:283-287, 1986. 452. Blumenthal NC, Posner AS: In vitro model of aluminuminduced osteomalacia: Inhibition of hydroxyapatite formation and growth. Calcif Tissue Int 36:439-441, 1984. 453. Goodman WG, Henry DA, Horst R, et al: Parenteral aluminum administration in the dog: II. Induction of osteomalacia and effect on vitamin D metabolism. Kidney Int 25:370-375, 1984. 454. O'Brien AAJ, Moore DP, Keogh JAB: Acute epidemic aluminum osteomalacia secondary to water supply contamination. Ir J Med Sci 159:71-73, 1990. 455. Coumot-Witmer G, Zingraff J, Plachot JJ, et al: Aluminum localization in bone from hemodialyzed patients: Relationship to matrix mineralization. Kidney Int 20:375-385, 1981.

385 456. Podenphant J, Salem N, Sypitkowski C, et al: Reversal of aluminum related dialysis osteomalacia after transplantation. Proceedings, Fourth International Workshop on Bone Histomorphometry. Bone 6:405, 1985. 457. Hodsman AB, Anderson C, Leung FY: Accelerated accumulation of aluminum by osteoid matrix in vitamin D deficiency. Miner Electrolyte Metab 10:309-315, 1984. 458. Quarles DL, Dennis VW, Gitelman HJ, et al: Aluminum deposition at the osteoid-bone interface. An epiphenomenon of the osteomalacic state in vitamin D deficient dogs. J Clin Invest 75: 1441-1447, 1985. 459. Thomas WC, Meyer JL: Aluminum-induced osteomalacia: An explanation. Am J Nephrol 4:201 - 203, 1984. 460. Baker SL, Dent CE, Friedman N, Watson L: Fibrogenesis imperfecta ossium. J Bone Joint Surg 48B:804-825, 1966. 461. Swan CHJ, Shah K, Brewer DB, Cooke WT: Fibrogenesis imperfecta ossium. Q J Med 45:233-253, 1976. 462. Lang R, Vignery AMC, Jensen PS: Fibrogenesis imperfecta ossium with early onset: Observations after 20 years of illness. Bone 7:237-246, 1986. 463. Frame B, Frost HM, Pak CYC, et al: Fibrogenesis imperfecta ossium. A collagen defect causing osteomalacia. N Engl J Med 285:769-772, 1971. 464. Stoddart PGP, Wickremaratchi T, Hollingworth P, Watt I: Fibrogenesis imperfecta ossium. Br J Radiol 57:744-751, 1984. 465. Byers PD, Stamp TCB, Stoker D J: Case report 296. Skeletal Radiol 13:72-76, 1985. 466. Ralphs JR, Stamp TCB, Doppi~-,g-Hepenstal PJC, Ali SY: U1trastructural features of the osteoid of patients with fibrogenesis imperfecta ossium. Bone 10:243-249, 1989. 467. Whyte MP: Hypophosphatasia. In Scriver CR, et al (eds): The Metabolic and Molecular Bases of Inherited Disease, 7th ed, vol III. New York, McGraw-Hill, 1995. 468. Whyte MP, Fallon MD, Murphy WA, Teitelbaum SL: Axial osteomalacia. Clinical, laboratory and genetic investigation of an affected mother and son. Am J Med 71:1041-1049, 1981. 469. Whyte MP, Vrabel LA, Schwartz TD: Alkaline phosphatase deficiency in cultured skin fibroblasts from patients with hypophosphatasia: Comparison of the infantile, childhood, and adult forms. J Clin Endocrinol Metab 57:831-837, 1983. 470. Whyte MP, Walkenhorst DA, Fedde KN, et al: Hypophosphatasia: Levels of bone alkaline phosphatase immunoreactivity in serum reflect disease severity. J Clin Endocrinol Metab 81: 2142-2148, 1996. 471. Whyte MP, Seino Y: Circulating vitamin D metabolite levels in hypophosphatasia. J Clin Endocrinol Metab 55:178-180, 1982. 472. Fallon MD, Teitelbaum SL, Weinstein RS, et al: Hypophosphatasia: Clinicopathologic comparison of the infantile, childhood, and adult forms. Medicine 63:12-24, 1984. 473. Bethune JE, Dent CE: Hypophosphatasia in the adult. Am J Med 28:615-622, 1960. 474. Frame B, Frost HM, Ormond RB, Hunter RB: Atypical osteomalacia involving the axial skeleton. Ann Intem Med 55:632639, 1961. 475. Demiaux-Domenech B, Bonjour JP, Rizzoli R: Axial Osteomalacia: Report of a new case with selective increase in axial bone mineral density. Bone 18:633-637, 1996. 476. Whyte MP: Sclerosing bone dysplasias. In Primer on the Metabolic Bone Diseases and Disorders of Mineral Metabolism, 2nd ed. New York, Raven Press, 1993, pp 327-344. 477. VanErpecum KJ, Kroon HM, VanGroningen K, Harinck HIJ: Central and peripheral bone biopsy in a patient with axial osteomalacia. Neth J Med 28:505-508, 1985.

3

8

6

A

478. Lundberg E, Bergengren H, Lindqvist B: Mild phosphate diabetes in adults. Acta Med Scand 204:93-96, 1978. 479. Stephens WP, Berry JL, Klimiuk PS, Mawer EB: Annual highdose vitamin D prophylaxis in Asian immigrants. Lancet 2: 1199-1201, 1981. 480. Brooke OG, Brown IRF, Bone CDM, et al: Vitamin D supplements in pregnant Asian women: Effects on calcium status and fetal growth. Br Med J 1:751-754, 1980. 481. Toss G, Andersson R, Diffey BL, et al: Oral vitamin D and ultraviolet radiation for the prevention of vitamin D deficiency in the elderly. Acta Med Scand 212:157-161, 1982. 482. McKenna MJ, Freaney R, Meade A, Muldowney FP: Prevention of hypovitaminosis D in the elderly. Calcif Tissue Int 37:112116, 1985. 483. Whyte MP, Haddad JG Jr, Waiters DD, Stamp TCB: Vitamin D bioavailability: Serum 25-hydroxyvitamin D levels in man after oral, subcutaneous, intramuscular, and intravenous vitamin D administration. J Clin Endocrinol Metab 48:906-911, 1979. 484. Stamp TCB: Calcitriol dosage in osteomalacia, hypoparathyroidism and attempted treatment of myositis ossificans progressiva. Curr Med Res Opin 7:316-336, 1981. 485. Bordier PH, Miravet L, Marie P, et al: Action des metabolites de la vitamine D sur la mineralisation du tissu osseux et les troubles du metabolisme phosphocalcique au cours de l'osteomalacie hypovitaminique D. Rev Rhum 45:241-248, 1978. 486. Bordier PH, Hioco D, Rouqujer M, et al: Effects of intravenous vitamin D on bone and phosphate metabolism in osteomalacia. Calcif Tissue Res 4 : 7 8 - 8 3 , 1969. 487. Hosking DJ, Campbell GA, Kemm JR, et al: Safety of treatment for subclinical osteomalacia in the elderly. Br Med J 289:785787, 1984. 488. Cundy T, Kanis JA, Heynen G, et al: Failure to heal vitamin Ddeficiency rickets and suppress secondary hyperparathyroidism with conventional doses of 1,25-dihydroxy vitamin D3. Br Med J 284:883-885, 1982.

.

M. PAP.~ITT

489. Fonseca V, Weerakoon J, Mikhailidis DE et al: Plasma creatinine and creatinine clearance in nutritional osteomalacia. Lancet 1:1093-1095, 1984. 490. Carpenter TO, Keller M, Schwartz D, et al: 24,25 dehydroxyvitamin D supplementation corrects hyperparathyroidism and improves skeletal abnormalities in X-linked hypophosphatemic r i c k e t s - - a clinical research center study. J Clin Endocrinol Metab 81:2381 - 2388, 1996. 491. Hruska KA, Rifas L, Cheng S-L, et al: X-linked hypophosphatemic rickets and the murine Hyp homologue. Editorial review. Am J Physiol 268:F357-F362, 1995. 492. Tieder M, Arie R, Bab I, et al: A new kindred with hereditary hypophosphatemic rickets with hypercalciuria: Implications for correct diagnosis and treatment. Nephron 62:176-181, 1992. 493. Goldring SR, Krane SM: Cation effects on phosphate homeostasis in hypophosphatemic subjects. Adv Exp Med Biol 128: 361 - 368, 1980. 494. Alon U, Chan JCM: Effects of hydrochlorothiazide and amiloride in renal hypophosphatemic tickets. Pediatrics 75:754-763, 1985. 495. Rose GA: Role of phosphate in treatment of renal tubular hypophosphataemic tickets and osteomalacias. Br Med J 2:857861, 1964. 496. Verge CF, Lam A, Simpson JM, et al: Effects of therapy in Xlinked hypophosphatemic tickets. N Engl J Med 325:18431848, 1991. 497. Firth RG, Grant CS, Riggs BL: Development of hypercalcemic hyperparathyroidism after long-term phosphate supplementation in hypophosphatemic osteomalacia. Report of two cases. Am J Med 78:669-673, 1985. 498. Gertner JM, Brenton DB, Edwards RHT: loL-hydroxyvitamin D3 in the treatment of nutritional and metabolic tickets and osteomalacia. Clin Endocrinol 7(Suppl):239-244, 1977. 499. Petersen DJ, Boniface AM, Schranck FW, et al: X-linked hypophosphatemic tickets: A study (with literature review) of linear growth response to calcitriol and phosphate therapy. J Bone Miner Res 7:583-597, 1992.

_]HAPTER 1~

Osteoporosis Pathogenesis and Therapy MICHAEL

KLEEREKOPER

LOUIS V. AVIOLI

Department of Medicine, Wayne State University, Detroit, Michigan 48201 Division of Bone and Mineral Diseases, Washington University School of Medicine, St. Louis, Missouri 63110

E. Biochemical Markers of Bone Remodeling F. Clinical Characteristics IV. Classification V. Management A. Nonpharmacological Intervention B. Pharmacological Intervention C. On the Horizon References

I. Definition A. Epidemiology II. Physiological Osteoporosis III. Diagnostic Aids A. Radiology B. Densitometry C. Ultrasound D. Histomorphometry

having BMD greater than 2.5 SD below peak adult bone mass, whether or not a fragility fracture has occurred. 4 In order to distinguish this asymptomatic condition of having low bone mass without fractures from what has traditionally been termed osteoporosis, the WHO has suggested that the term severe osteoporosis be applied to subjects with low bone mass and fragility fractures. The Food and Drug Administration (FDA) in the United States has recently approved therapies for the treatment of osteoporosis, defining the disease as being present when BMD is greater than 2.0 SD below peak bone mass. Whether one chooses to define osteoporosis in an individual patient using the WHO or the FDA criteria is immaterial in most clinical circumstances. These arbitrarily defined cut-points should really be applied to an individual patient not so much as defining or diagnostic cut-points, but rather as intervention decision-making cut-points. The situation is entirely analogous to the diagnosis of hypertension or hypercholesterolemia. Diagnostic levels for both of these asymptomatic states have been defined by various authoritative groups but individual practitioners have developed their own intervention criteria, which vary with the clinical circumstance and are not strictly based on numerical criteria. With an

I. D E F I N I T I O N Osteoporosis, which has actually been described in prehistoric populations, 1 is a brittle bone disease manifest clinically by fragility fractures defined as fractures occurring in the absence of trauma or in response to only trivial trauma (force equal to or less than a fall from a standing height). In almost all patients, these fragility fractures are preceded by a long, silent period during which the bones become progressively more brittle without fracture occurring. While there are a number of putative risk factors for progressive bone loss and fracture risk, these are only applicable in population studies. In an individual subject the only means of detecting osteoporosis during this silent period is by direct, noninvasive measurement of bone mineral density (BMD). Reference intervals for peak adult bone mass have been established for each method of measuring BMD, and epidemiological studies have indicated that an individual's risk of sustaining an osteoporotic fracture doubles for each standard deviation (SD) by which the measurement is below the mean value for peak adult bone mass. 2'3 From this information, the World Health Organization (WHO) has defined osteoporosis as the state of METABOLIC BONE DISEASE

387

Copyright 9 1998by AcademicPress. All rightsof reproductionin any formreserved.

388


elevated blood pressure or serum cholesterol, or a low bone mass, clearly the further from the reference value is the observation in the individual patient, the more aggressive the intervention and monitoring. In fact, great caution should be used when considering putting a diagnostic label (hypertension, hypercholesterolemia, osteoporosis) on an asymptomatic patient simply on the basis of a physiological measurement. In addition to the anxiety such a label may cause in the patient, the diagnosis may have profound adverse implications for the patient's life and health insurance. Furthermore, it has been suggested that absenteeism from the work force is significantly greater in patients with a diagnosis of hypertension than their nonhypertensive co-workers, even when the stated cause for absenteeism is unrelated to the elevated blood pressure or its management. Given the frequency with which backache is the stated cause for absenteeism from the workplace, there is considerable risk that patients with osteoporosis without fracture would be absent even more frequently if they were additionally concerned about fracture risk, or erroneously related their backache to the low bone mass.

A. E p i d e m i o l o g y Peak adult bone mass is achieved sometime during the fourth and fifth decades of life, with a gradual, progressive decline in BMD beginning at about age 40 to 45 in all personsd Peak adult bone mass is greater in men than in women, and greater in African-Americans than in non-Hispanic whites. These differences in peak bone mass are reflected in gender and ethnic differences in the prevalence and incidence of osteoporosis and osteoporotic fractures later in life. At the menopause women experience a 7 to 10-year period of accelerated bone loss as a result of estrogen deficiency, widening this gender gap in the prevalence and incidence of osteoporosis and osteoporotic fractures. Based on a relatively small sample of women in Rochester, Minnesota, Melton has estimated the prevalence of osteoporosis (defined by the WHO criteria detailed above) to be in excess of 20 million women in the United States 6 (Table 12-1 and Fig. 12-1). The WHO has predicted the future occurrence of osteoporosis throughout the world (Fig. 12-2). The most startling aspect of these projections is that all of the persons projected to have a hip fracture in the year 2050 are already alive. There is a definite pattern to the development of osteoporotic fractures, with distal forearm (Colles') fractures being extremely uncommon in men at any age but rising sharply in incidence in women within 5 to 10 years of the menopause. 7 It has been estimated that at least 90% of all hip and spine fractures among elderly

TABLE 12-1 WHO Diagnostic Criteria for Osteoporosis a'b Normal

BMD within 1 SD of peak adult bone mass (PABM)

Low bone mass

BMD --> 1.0 but < 2.5 SD below PABM

Osteoporosis

BMD --> 2.5 SD below PABM

Severe osteoporosis

BMD --> 2.5 SD below PABM, with fractures

aFrom Melton LJ III: How many women have osteoporosis now? J Bone Miner Res 10(2):176, 1995. bproportion of women with osteoporosis (BMB > 2.5 SD below peak bone mass).

white women should be attributed to osteoporosis. 8 Fractures of the vertebral body are the most prevalent of the osteoporotic fractures occurring, with a peak age incidence between 65 and 70 in women. The incidence in men is about one third that in women and occurs some 5 to 10 years later. Fractures of the proximal femur (hip) are the most devastating of the osteoporotic fractures, occurring with increasing frequency after age 75 in women and age 80 in men. There are approximately 300,000 hip fractures each year in the United States in persons over age 65, with the incidence being twice as high in women. 9 Estimates of short-term (1 year or less) mortality following these hip fractures vary between 5% and 20% in different series, with mortality being twice as high in men than in women. 1~It should be emphasized that these mortality statistics reflect excess mortality after adjustment for age and comorbidities. Osteoporosis and its dreaded sequelae of progressive disability with associated neurological deficits, poor rehabilitation profile, 11'12excessive deaths, and escalating medical care expenditures is becoming a worldwide problem. In 1990 North America and Europe accounted for the majority of the 1.66 million fractures that occurred internationally. Since the elderly component of the population is increasing most rapidly in Africa, Asia, Latin America, and the Middle East, it has been projected that these geographical areas will account for over 70% of the 6.3 million fractures expected in the year 2050.13 More than 95% of all osteoporotic hip fractures occur after a fall, usually a fall to the side, but only a small fraction of falls result in hip fractures. 14 Fall prevention and attention to fall mechanics are assuming increasing importance in attempts to lessen the societal burden of osteoporotic hip fractures, which in 1995 exceeded $10 billion per annum in the United States. 15 While most attention is focused on fractures of the wrist, spine, and hip, fractures of the proximal humerus, distal femur, distal tibia and fibula, and ribs are increasingly common in the elderly and must be considered as clinical manifestations of osteoporosis. In fact, the contribution of nonhip fractures to

CHAPTER 12

Osteoporosis Pathogenesis and Therapy

389

FIGURE 12--1 Estimated skeletal status of United States white women in 1990, by age group. Osteopenia is bone density of the hip, spine, or distal forearm more than 1.0 but less than 2.5 SD below the young normal mean. Osteoporosis is bone density at one or more of these sites more than 2.5 SD below the mean and, when linked with a history of fracture, is deemed established osteoporosis. (From Melton LJ III: How many women have osteoporosis now? J Bone Miner Res 10:176, 1995.)

the substantial m o r b i d i t y and e x p e n d i t u r e s associated with o s t e o p o r o s i s has b e e n u n d e r e s t i m a t e d b y many. 15

II.

PHYSIOLOGICAL

OSTEOPOROSIS

T h e p h e n o m e n o n o f a p r o g r e s s i v e d e c l i n e in b o n e m a s s with age, after age 40 to 45, has a l r e a d y b e e n m e n -

tioned, as has the a c c e l e r a t e d b o n e loss of the m e n o p a u s e that occurs in all w o m e n w h o live l o n g e n o u g h . S i n c e t h e s e are u n i v e r s a l p h e n o m e n a in h u m a n s , this m u s t to s o m e e x t e n t be r e g a r d e d as part o f the n o r m a l p h y s i o l o g y o f a g i n g i n a s m u c h as e v e r y o n e w h o lives l o n g e n o u g h will e v e n t u a l l y d e v e l o p o s t e o p o r o s i s as defined in t e r m s o f a r e d u c t i o n f r o m p e a k b o n e mass. T h e r e is also an a p p a r e n t p h y s i o l o g i c a l o s t e o p o r o s i s o f p u b e r t y

FIGURE 12--2 Estimated number of fractures for men and women in different regions of the world in 1990, 2025 and 2050. (From Kanis JA, and WHO Study Group: Assessment of fracture risk and its application to screening for postmenopausal osteoporosis. WHO Technical Report Series 843:13, 1994.)

390 with a peak incidence of distal forearm (greenstick) fractures occurring in boys and gifts between ages 9 and 16. This observation may be explained by the fact that linear skeletal growth precedes the accumulation of skeletal mass during the growth spurt, in much the same manner that accumulation of muscle bulk occurs after the growth spurt of puberty. In boys, this peak pubertal incidence of distal forearm fractures returns to low levels after age 16 with little fluctuation thereafter throughout life. The same pattern is seen in gifts immediately following puberty, only to rise sharply again in women a few years after the menopause. The precise pathogenesis of the accelerated bone loss of the menopause is unknown. Although previous studies have revealed that peak bone mass is under genetic influence the contribution of genetic factors to postmenopausal bone turnover and bone loss is relatively insignificant. 16 That the bone loss is related to the cessation of gonadal steroid production is clearly established such that whenever there is a decline in gonadal steroids (estrogen in women, androgen in men) as a result of disease, therapy, or surgery, there is a transient (approximately 5- to 7-year) period of increased bone remodeling and accelerated bone loss reverting to basal, physiological rates of bone loss thereafter. Estrogen receptors have been identified in bone but at concentrations that are at least one order of magnitude lower than in more classic estrogen-dependent tissues such as the endometrium or breast. Therefore, it is unlikely that estrogen deficiency has direct effects on the skeleton. There is compelling evidence that estrogen modulates the local production of cytokines, interleukin-1 (IL-1) and interleukin-6 (IL-6), which in turn are responsible for increased bone resorption. 17-22 Considerable controversy surrounds the relative roles of IL-1 and IL-6 in this regard, 18'19 and quite possibly both are significantly involved. It is not yet known whether these, and possibly other cytokines, act directly on the skeleton or mature bone cells, or are indirectly involved in the recruitment and maturation of osteoprogenitor cells. 2~ Very little is known about possible cellular mechanisms underlying age-related bone loss, although most would agree that estrogen status and heredity are major determinants of premenopausal bone loss. 23 It seems well established that bone loss begins before there is any decline in ovarian estrogen production in women and commences well before any age-related decline in androgen production in men. A putative role for an agerelated decline in renal production of calcitriol (1,25dihydroxyvitamin D) with resultant decrease in intestinal absorption of calcium, elevation in parathyroid hormone, and negative skeletal balance has been postulated by several investigators. There is some observational and experimental support for this hypothesis, but in general


the process of age-related bone loss is so slow, and the physiological changes so subtle, that it has proven extremely difficult to formulate and substantiate any single hypothesis to account for the universal phenomenon of age-related bone loss. A most tenable hypothesis is that late consequences of estrogen deficiency rather than agerelated processes p e r s e a r e the principal causes of the secondary hyperparathyroidism and increased bone resorption in elderly women. 24 We should also recognize the observations that high bone turnover is associated with low bone mass and vertebral fractures in postmenopausal women, z5 and although bone turnover normally declines progressively after the menopause, it does not in patients with vertebral fractures and osteoporosis. 26

III. DIAGNOSTIC AIDS A. Radiology Plain radiographs are usually required for confirmation of fracture occurrence but have little additional role in most patients with osteoporosis. A decrease in total skeletal mass can be seen in advanced stages of bone loss, but it has been estimated that fully 30% of skeletal mass must be lost before it can be detected radiographically. Newer densitometric methods have supplanted plain radiographs for this purpose. Most long-bone fractures (proximal femur, distal radius, proximal humerus, distal tibia and fibula) can be detected clinically and confirmed radiographically. Fractures of the vertebral bodies pose a particular problem for several reasons. There is considerable variability in vertebral body size and shape, and several developmental and acquired abnormalities, such as Schuermann's disease, can mimic vertebral fractures. Additionally, a proportion of vertebral body fractures have either occurred spontaneously without symptoms or the proximate cause of the fracture has been forgotten by many patients. Several attempts have been made to develop population-specific reference data for vertebral body dimensions from the fourth thoracic (dorsal) through the fifth lumbar vertebra. Vertebral body dimensions can then be measured on radiographs of the thoracic and lumbar spine taken in the lateral projection, and deviations from the reference data can be used to define the presence or absence of a vertebral body fracture. These morphometfic approaches to detecting vertebral fractures probably result in some overestimate of fracture occurrence, and visual inspection of the radiograph by a trained and skilled musculoskeletal radiologist remains the "gold standard" for fracture detection in individual cases. Morphometfic methods have greater relevance in population studies and in clinical trials. 27 Since pelvic

391

CHAPTER 12 Osteoporosis Pathogenesis and Therapy radiographs present sufficient spatial resolution and contrast to evaluate the anatomical structures of the proximal femur, prediction of hip fractures can often be made using a combination of measurements 28 (Fig. 12-3). One important function of plain radiography in the evaluation of individual patients suspected of having an osteoporotic fracture is the detection of other diseases that might mimic osteoporosis. Fragility fractures can complicate metabolic diseases such as osteomalacia, hyperparathyroidism, and systemic mastocytosis, but these diseases generally have radiographic features that distinguish them from osteoporosis. The same is usually true also for genetic disorders such as osteogenesis imperfecta, and malignant diseases such as skeletal metastases and multiple myeloma, each of which is associated with fragility fractures. Occasionally, fractures prove difficult to verify with plain radiographs due to the site (fibs) or impaction without obvious skeletal deformity. In such cases radionuclide skeletal scintigraphy may be of benefit with new fractures associated with intense increased isotope uptake. Scintigraphy may also be of benefit in assessing the age of a vertebral fracture, with increased isotope

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\ i

i

36

FIGURE 12--3 Femoral and pelvic bones and placement of selected radiographic measurements: the thickness of the medial shaft cortex (SC) 3 cm below the lesser trochanter, the thickness of the medial cortex at the center of the femoral neck (NC), the width of the femoral head (HW), the width of the intertrochanteric region (TW), and acetabular bone width (AW). The region of the principle tensile group of trabeculae (PT) is marked. (From Gluer CC, Cummings SR, Pressman A, et al, for The Study of Osteoporotic Features Research Group: Prediction of hip fracture from pelvic radiographs: The study of osteoporotic fractures. J Bone Miner Res 9: 671, 1994.)

uptake persisting from 6 months to 2 years after the fracture. The pattern of fractures seen scintigraphically may also aid in the diagnosis of metastatic disease, particularly if there is discordance between the plain radiograph and the scintigraph (i.e., increased isotope uptake at a site without obvious radiographic abnormality).

B. Densitometry Dual energy x-ray absorptiometry (DEXA) has become the gold standard for the noninvasive measurement of B MD. The method is accurate (> 95% to 98%), precise (0.5% to 2.5% error for repeat measurements), painless, and rapid (approximately 5 minutes per measurement site) and exposes the patient to very little more than background radiation. Densitometry (or other method for B MD measurement) remains the only method for diagnosing osteoporosis prior to fracture as described in detail in Section I of this chapter. Current equipment commercially available can measure BMD at the lumbar spine, the forearm, and the proximal femur, as well as the total body (where it can also provide accurate and precise information about body composition). As with any other clinical test, densitometry should only be obtained if a clinical decision is going to be made on the basis of the result obtained. For example, perimenopausal women who have already elected to begin estrogen replacement therapy do not require a bone mass measurement prior to initiating therapy, since more than 95% of these women will derive skeletal benefit from the therapy. Some women are reluctant to take estrogen unless a specific skeletal need can be demonstrated in their case. This can only be done with direct BMD measurement. In this regard, it should be emphasized that both lumbar spine and proximal femur measurements should be made when women are using bone density measurements as a means to effect the decision of whether or not to use hormonal replacement therapy. 29"3~Another indication is the patient in whom spine radiographs have demonstrated a vertebral deformity and there is uncertainty as to whether this resulted from low bone mass or from trauma. Patients on corticosteroid therapy and at increased risk for secondary osteoporosis should have BMD measured, as should patients with mild, asymptomatic primary hyperparathyroidism where the documentation of a low BMD is an indication for parathyroidectomy. There is no current consensus concerning the role of BMD measurement in patients who clearly have severe osteoporosis with fragility fractures. Some clinicians feel that a baseline measurement is important in order to properly monitor the response to therapy. Others feel that the therapeutic options are still so

392


limited that knowledge of BMD will not alter management. This dilemma will probably be solved as the cost of BMD testing decreases m currently $100 to $250 (U.S.) per measurement s i t e m a n d as more therapeutic options become available. Even greater controversy surrounds the timing of serial measurements of B MD. While the precision error is quite low, it is nonetheless extremely close to the anticipated annual rate of change in BMD, either progressive bone loss or in response to therapy. Unless there is reason to suspect a very rapid loss of bone (e.g., during the early phase of corticosteroid therapy) there is little clinical justification in obtaining repeat BMD measurements more frequently than once a year, and in many circumstances biannual measurement will suffice.

D. Histomorphometry

C. Ultrasound The definition of osteoporosis includes a statement conceming bone quantity ( " a reduction in bone mass") and quality ("microarchitectural deterioration"). The former can be measured by densitometry, but this method provides no measure of quality. Ultrasonography is gaining increasing acceptance as a measure of bone quality, although precisely what quality of bone is measured remains unclear. Ultrasound has several important potential advantages over densitometry in that it does not expose the patient to ionizing radiation, and is available using portable, small equipment that can be purchased generally at far lower cost than densitometry equipment. Ultrasound equipment has been developed to measure speed-of-sound ( S O S ) - - a l s o termed apparent velocity of ultrasound (AVU) and ultrasound transmission velocity ( U T V ) m , broadband ultrasound attenuation (BUA), and stiffness. Studies have been performed with measurements obtained predominantly at the calcaneus or patella, but other sites are accessible and have been studied. When osteoporosis has been defined on the basis of low BMD, all ultrasound parameters have been significantly lower in those with osteoporosis compared to appropriate control groups. More importantly, recent studies have demonstrated that ultrasound predicts incident vertebral deformity 31 and can also provide estimates of relative risk of hip fracture that are independent of B MD. 32 The potential of ultrasound is still emerging and will not be fully realized until there is a more clear identification of just where this technology fits in the intervention decision analysis of patients at risk for osteoporosis, and whether it is a surrogate for BMD, adjunctive to BMD, or perhaps preferred over BMD.

Most of what is now known about skeletal metabolism has been learned from microscopic examination of the skeleton, particularly dynamic histomorphometry with in vivo double tetracycline labeling. With this technique one can assess the extent of surface activity of osteoclasts and osteoblasts, the rate at which bone is being formed with deposition of new bone matrix, and the extent to which this newly formed matrix is being properly mineralized. Diagnostic information can be gleaned from skeletal histomorphometry, static or dynamic, which cannot be obtained with measurements of bone mineral density or biomarkers of bone tumover particularly if there is clinical suspicion of osteomalacia and serum or plasma levels of the vitamin D metabolites have provided equivocal results. A second example might be a rare case of systemic mastocytosis where it would be important to document excess mast cells in the biopsy specimen. Some authorities consider that all patients, particularly males, with unexplained or unexpected osteoporosis should have a bone biopsy.

E. Biochemical Markers of Bone Remodeling The mature adult skeleton is subject to continuous turnover, or remodeling, with removal of old bone and replacement at that site with new bone. Remodeling always takes place on skeletal surfaces, and always in discrete packets termed basic multicellular units (BMUs). Under normal physiological circumstances, 80% of skeletal surfaces are quiescent and 20% are actively involved in remodeling. What factor(s) determines the site and extent of remodeling is unknown. The process begins with recruitment of preosteoclasts that mature into osteoclasts which resorb a cavity to a depth of 50 /zm at a rate of 5 Ixrn/day. During this phase of bone resorption breakdown products of the fully mineralized skeleton (matrix protein and mineral, predominantly calcium) are removed from the skeleton, and transiently enter the circulation from which they are rapidly cleared by the kidney. Monitoring the urinary excretion of these breakdown products of bone resorption has recently become clinically available with the development of highly specific and sensitive assays for the pyridinium crosslinks of type I collagen of bone, and the amino- and carboxyl-terminal telopeptides of these cross-links (Table 12-2). Either a specific product of the osteoclast, or something released from the skeleton during the phase of osteoclast resorption, is a stimulus to the recruitment and/ or activation of osteoblasts. These cells line the newly

CHAPTER 12 OsteoporosisPathogenesis and Therapy

393

TABLE 12--2 Biochemical Markers of Bone Remodeling

disease in which red cell survival is not decreased but erythropoiesis is impaired. Assessing rates of bone remodeling are of potential importance in the evaluation of patients with osteoporosis. These biochemical studies have not yet been demonstrated to independently predict fracture risk (except in small studies of elderly women), nor can they reliably estimate current B MD, although attempts have been made to use the biochemistry as surrogates for densitometry. 33 However, biochemical assessment of the imbalance between resorption and formation can be used to predict, and monitor, changes in B MD, and this remains the current major role of these measurements in clinical medicine. The precision error for repeat measurements is 10% to 15% for serum-based assays (formation) and 25% to 30% for urine-based assays (resorption), which initially appears unacceptable in relation to the 0.5% to 2.5% precision of DEXA. However, anticipated rates of change in biochemical markers in response to therapy for osteoporosis is greatly in excess of these precision errors, exactly the opposite of the situation with DEXA. More importantly, these changes in biochemistry occur rapidly, 34 with significant decrements in markers of resorption detectable within 4 weeks of initiating antiresorptive therapy. Because of the sequence of resorption preceding formation, significant changes in markers of formation are not seen until 2 to 3 months after initiation of such therapy. Finally, and perhaps most importantly, these early biochemical responses to therapy predict changes in BMD detected 24 months later. The current best use of biochemical markers of bone remodeling is limited because of the limited therapeutic options for osteoporosis. Most markers of bone remodeling are increased in elderly subjects with vitamin D insufficiency and vary with its correction. 35 Ideally, one should also be able to tailor the dose of antiresorptive therapy to the magnitude of the abnormality in rates of resorption, adjusting the dose in relation to the skeletal response as reflected in the biomarkers of bone remodeling. Unfortunately, of the FDA-approved therapies available in the United States, dose adjustment is only possible with estrogen and alendronate, but not yet with calcitonin nasal spray. Estrogen and calcitonin are usually most effective in patients in whom the primary abnormality is an increase in bone resorption (high turnover), whereas alendronate appears to work equally well in patients with normal, low, and high turnover. Patients with low or normal turnover would also be expected to respond more favorably to agents that directly stimulate bone formation such as fluoride or parathyroid hormone. Since currently both of these approaches must still be regarded as experimental, it will be some time before the concept of tailoring therapy (drug type and dose) can be fully implemented into clinical practice.

Resorption Serum tartrate resistant acid phosphatase Urine hydroxyproline Pyridinoline: free and peptide-bound Deoxypyridinoline: free and peptide-bound Teleopeptides of collagen cross-links: amino-terminal, carboxylterminal Formation Serum bone specific alkaline phosphatase Serum procollagen extension peptides: amino-terminal carboxylterminal Turnover (both resorption and formation) Serum osteocalcin

formed resorption cavity and begin the repair (formation) process by filling in the cavity, from the base towards the surface, with matrix proteins, predominantly type I collagen. As newly synthesized bone matrix is deposited it becomes progressively more mineralized, again from the base towards the surface, until after approximately 90 days, a new BMU has refilled the resorption cavity. This phase of the remodeling cycle can be monitored by measuring circulating levels of proteins (or their breakdown products) synthesized and secreted by the osteoblast (Table 12-2). While the skeleton is in balance for that short period of time after peak adult bone mass is attained (see Section I), the amount of bone removed during resorption is normally completely replaced. Subsequently in later years, with each remodeling cycle there is always a slight excess of resorption over formation. This is a mechanistic way of describing the progressive negative balance of age-related bone loss. Any perturbation that increases the rate at which the skeleton is being remodeled will accelerate the rate of bone loss even though loss per remodeling cycle is unchanged. This has been termed "high-turnover" bone loss and is analogous to the rapid turnover of erythrocytes in hemolytic anemias, which are characterized by decreased red cell survival ("resorption") and an increased but inadequate reticulocytosis ("formation"). Most of the identifiable secondary causes of osteoporosis (see Section IV) result in high-turnover bone loss. Under other circumstances, most often with advanced age, there is an apparent defect in the coupling or signaling between resorption and formation. When this occurs, skeletal loss per remodeling cycle is increased so that accelerated bone loss can occur with normal or even low turnover. To continue the anemia analogy, this would be akin to anemia of chronic

394

MICHAEL KLEEREKOPERAND LOUIS V. AVIOLI F. C l i n i c a l C h a r a c t e r i s t i c s

Osteoporosis diagnosed only on the basis of a low BMD is entirely without symptoms. Once osteoporosis is complicated by fractures the clinical features relate to the site of fracture. The goal of orthopedic intervention for osteoporotic long-bone fractures is complete restoration of function to prefracture levels, and this can be achieved in most patients. A small proportion of patients sustaining a Colles' fracture are left with residual pain, deformity, and restricted mobility of the wrist. This also happens, but to a lesser extent, with distal tibia and fibula fractures. In contrast, restoration of prefracture functional state is achieved in less than half of the patients who sustain an osteoporotic hip fracture. Osteoporotic vertebral fractures require separate consideration. 27 An acute fracture episode will result in severe spinal pain, tenderness, and limitation of motion for about 6 weeks after which the tenderness should subside, the pain should be more paraspinal than spinal, and there should be improved range of motion. If the acute symptoms, particularly direct spinal tenderness, persist for longer than 8 weeks one must consider diagnoses other than osteoporosis such as metastases or myeloma. Only rarely does an acute osteoporotic vertebral fracture impinge on the spinal cord with resultant long tract symptoms and signs. 36 If this is present, diagnoses other than osteoporosis must again be considered, even if the fracture can be defined as a fragility fracture. As noted, some vertebral fractures can occur without an identifiable acute episode. Here the clinical presentation is progressive loss of stature, progressive spinal deformity, chronic back pain, protuberant abdomen (occasionally with gastrointestinal complaints such as early satiety), and altered body image. 1 Of particular importance is the progressive loss of stature. We and others have documented that women (and presumably men) who sustain vertebral fractures lose stature two to three times more rapidly than those who do n o t . 37 Progressive vertebral deformity is associated with an increased risk of general disability and the use of devices to assist ambulation in both men and women, with severe age-related progression of this syndrome observed primarily in women. 38 It is worthwhile to accurately record stature at each clinic visit, just as weight is recorded. Patients with acute back pain or exacerbation of existing pain who have not sustained 0.5 to 1.0 inch or more of height loss are unlikely to have sustained a new vertebral fracture as a cause of the back pain. Similarly, well-documented stature loss of 1.0 cm or more between clinic visits should alert the clinician to the possibility of an asymptomatic vertebral fracture. As mentioned, the presence of a fracture is a reliable, independent (of BMD) predictor of future fractures so

that detection of asymptomatic fractures is clinically important. 39 The clinical evaluation of any patient with osteoporosis, or being evaluated for osteoporosis risk, must include a careful history and physical examination with the intention of identifying potential secondary causes of osteoporosis (see Table 12-3), since these may be amenable to specific therapy. The initial investigations should also be geared towards screening for these secondary causes even in the absence of clinical clues from the history and physical exam. Since the yield will be low, these investigations should not be exhaustive and can be accomplished with a biochemical profile (hyperor hypocalcemia, renal and hepatic dysfunction, hypoalbuminemia, hyperglobulinemia, marked elevation of alkaline phosphatase), a complete blood count (CBC) (nutritional deficiency, marrow infiltrative diseases),

TABLE 1 2 - 3

A Pathogenetic Classification of Osteoporosis

Primary Juvenile Senile Idiopathic Young/middle-aged males Pregnancy Regional migratory II. Secondary Hormone excess Parathyroid (1~ or 2~ Thyroid Cortisol Hormone deficiency Estrogen Premenopausal Disease Drugs Postmenopausal Testosterone Diseases Postgastrectomy without vitamin D deficiency Systemic mastocytosis Immobilization Following organ transplantation Drugs Corticosteroids Thyroxine Alcohol Anticonvulsants Barbiturates Phenytoin Anticoagulants Heparin Coumadin Antimetabolites Methotrexate Cyclosporine

395

CHAPTER 12 Osteoporosis Pathogenesis and Therapy thyroid-stimulating hormone (TSH) (hyperthyroidism), and free testosterone in males. Although there is no indication for measuring circulating parathyroid hormone, calcitonin, or the vitamin D metabolites routinely, blood levels of 25(OH)D are often appropriate in the elderly (particularly if housebound or institutionalized) because of their tendency to become vitamin D deficient. 35 A more rigorous search for secondary osteoporosis should be undertaken in premenopausal women and in men who are neither hypogonadal nor alcoholic. A similar rigorous search should be undertaken in patients whose measured BMD is not only > 2.5 SD below peak adult bone mass but is also > 2.0 SD below mean values after adjustment for age, gender, and ethnicity. Occult Cushing's syndrome, 4~ late presentations of osteogenesis imperfecta, and systemic mastocytosis may manifest for the first time with fragility fractures or marked spinal deformities (Fig. 12-4). These evaluations will be dictated by the clinical presentation, but from extensive clinical experience it should be noted that in occasional patients osteoporosis with an increased urine free cortisol may be the only manifestation of hypercortisolism. Similarly, patients may present with "osteoporotic x-rays" as the manifestation of nontropical sprue. A typical history in these patients who turn out to have osteomalacia and not osteoporosis, is one of frequent but regular bowel movements for 5, 10, or more years. It is not peculiar for the patient to have denied any change in bowel habits during this time when questioned by physicians. Finally, it cannot be overemphasized that multiple myeloma and skeletal metastases and primary hyperparathyroidism can present clinically in a manner indistinguishable from osteoporosis. 42 The clinician must maintain a high index of suspicion for these disorders when entertaining a diagnosis of osteoporosis. Osteoporosis in males deserves special mention. 43-46 Males do not generally report gonadal dysfunction to their physicians and physicians in turn infrequently enquire about gonadal function in their male patients. Yet 30% to 50% of males with osteoporosis have had unrecognized hypogonadism for a decade or more before presenting with an osteoporotic f r a c t u r e . 46 Far less common, almost rare in most practices, is "idiopathic" osteoporosis in young to middle-aged males. 47 This disorder, of unknown etiology but often associated with hypercalciuria, presents with acute back pain resulting from a fragility fracture of a vertebral body during the course of daily work or leisure activity in otherwise healthy males aged 35 to 55. The radiographs have no distinguishing characteristics other than the fracture and the initial, appropriate evaluation is to seek an occult malignancy as the cause of the fracture. Unless idiopathic osteoporosis is considered early and intervention started, several more vertebral fractures complicate this

seemingly self-limited disease (4 to 5 years) while the fruitless search for identifiable cause continues. It must be remembered that nothing about the evaluation or management of idiopathic osteoporosis should interfere with the remainder of the workup for malignancy. Whether or not stress fractures related to athletic activity represent osteoporosis or simply mechanical overload of an otherwise healthy, normal skeleton remains unresolved. There is no doubt that these are overload fractures and the patient should be counseled about reducing her or his physical activity until the fracture heals, restarting the activity at a less intense level. In women with stress fractures from physical activity (which frequently occurs in those serving with the armed forces) it is essential to obtain a complete menstrual history, as many of these women will have oligomenorrhea or even amenorrhea and can be assumed to have estrogen deficiency bone loss. In that event a direct measurement of BMD will most likely reveal low bone mass, but it is questionable whether this would be sufficient to convince the patient to cut back on her exercise program. Most such women are aware that altered menses results from their physical activity, but pay scant attention to this. Measurement of BMD in women with stress fractures who have demonstrated no change in menses is probably not indicated, since it is unlikely to lead to specific intervention other than advice to decrease the amount of physical activity. In men with stress fractures from physical activity it is probably appropriate to measure serum free testosterone. B MD measurement is probably not justified unless the circulating testosterone is low.

IV. CLASSIFICATION Of the many ways to classify osteoporosis we have elected to focus on the etiological classification provided in Table 12-3. In this system the only primary forms of osteoporosis are those in which there is no understanding of the pathogenesis. All other forms of osteoporosis, including the most common postmenopausal osteoporosis, are classified as secondary. Amongst the secondary osteoporotic syndromes there are many conditions where the proximate cause of bone loss is known (e.g., postgastrectomy) even though there is little known about the basic mechanism(s) underlying the bone loss. Finally, there is a group of diseases or conditions manifest by low bone mass and fragility fractures that mimic osteoporosis, which are best not labeled or classified as osteoporosis. The majority of these disorders are characterized by both a localized and/or generalized effect on the skeleton, while we consider osteoporosis a generalized phenomenon in most instances.

FIGURE 12--4

Severe vertebral kyphosis in a young female with Cushing's syndrome before (A and B) and following surgical intervention (C and D).

CHAPTER 12 Osteoporosis Pathogenesis and Therapy V. M A N A G E M E N T A. N o n p h a r m a c o l o g i c a l i n t e r v e n t i o n 1. LIFESTYLE Osteoporosis can affect anyone, including those individuals who pay very careful attention to their lifestyle in that they eat properly; participate in regular load-bearing exercise; do not smoke; consume alcohol in only moderate amounts; and have no diseases, conditions, or medication use that might predispose to osteoporosis. Patients with osteoporosis who are not quite so particular about their lifestyle must be counseled about all the activities they can change in their daily living that might slow down the progression of bone loss. Patients who have had vertebral fractures need very specific instructions concerning changes in their activities of daily living such that they learn to bend, lift, stoop, and so forth in a manner that does not place undue stress and strain on the spine. Similar advice should also be given to those with very low bone mass who have not yet fractured. This advice needs to be very specific and include not only the use of postural exercises and the use of posture training supports 48 but also such mundane items as instructing check-out personnel at the supermarket to place fewer items in each shopping bag, not lifting up the comers of heavy mattresses in order to neaten the sheets and blankets, and careful attention to bending over a crib to pick up a grandchild. Patients must be counseled that an osteoporotic fracture is a very good predictor of the next fracture, and while encouraged to remain as active as possible, the activity must be done properly. Patients at risk for a hip fracture need additional advice about fall prevention, particularly "fall-proofing" the home environment. Poor lighting, electric and telephone cords, loose scatter rugs, and highly polished floors can all contribute to an increased risk of falling with resultant fracture. Those with failing vision must wear proper corrective spectacles and make sure to change them when appropriate if moving from indoors to the outside. Travel outdoors should be with some form of ambulatory support in the frail elderly (less frail spouse, child or companion, cane, walker), particularly in wet or icy conditions. 2. NUTRITION While osteoporosis is not a calcium deficiency disease, there is ample evidence that an adequate calcium supply throughout life minimizes osteoporotic fracture risk later in l i f e . 49 In studies that reported cross-sectional data on BMD and hip fracture prevalence from two communities in Yugoslavia, the farming community (and one

397 with greater exercise) that consumed more calcium had higher BMD and lower fracture prevalence than the urban community that consumed less calcium. 5~While presumptive evidence that lifetime dietary calcium intake has an influence on osteoporosis risk, it is not clear whether other differences between these communities (e.g., daily physical activity) might have accounted for the observed differences. Calcium supplements have been provided to monozygotic twin boys with one from each pair receiving calcium for 3 years while the other received placebo. 51 The twins on calcium supplements, particularly those who were studied before puberty, had a higher BMD than their brothers on placebo. This benefit in BMD was not maintained after the calcium supplements were discontinued, again suggesting that lifetime calcium intake is important. These and other d a t a 52'53 resulted in a National Institutes of Health (NIH) Consensus Development panel deriving new figures for suggested optimum daily calcium intake throughout life (Table 12-4). 54 These recommendations do ensure that less than 5% of those consuming these recommended amounts will have dietary calcium deficiency. Since calcium is available in many foods and calcium supplements are inexpensive and generally free of side-effects, this is a reasonable community prescription. In contrast to the benefits of calcium in optimizing B MD and minimizing osteoporosis risk, the situation concerning calcium therapy for established osteoporosis is unclear. 52'53 The accelerated bone loss of the menopause can be retarded to some extent by large doses of

TABLE 1 2 - 4

Optimal Calcium Requirements a

Group Infants Birth-6 months 6 months- 1 year Children 1- 5 years 6-10 years Adolescents/Young Adults 11-24 years Men 25-65 years Over 65 years Women 25- 50 years Over 50 years (postmenopausal) On estrogens Not on estrogens Over 65 years Pregnant and nursing

Optimal Daily Intake (mg) 400 600 800 800-1200 1200-1500 1000 1500 1000 1000 1500 1500 1200-1500

aFrom NIH Consensus Conference: Optimal calcium intake. JAMA 272:1942, 1994.

398 supplemental calcium, but not to the same extent as is seen with estrogen replacement. Not surprisingly, greatest benefit is obtained in those women with the lowest habitual intakes (< 400 mg/day) and in those studied 5 or more years following menopause where the overwhelming effects of estrogen deficiency are dissipating. 52 There is inadequate data on other nutrients and osteoporosis. The renal handling of calcium is controlled to some extent by the renal handling of sodium such that a high sodium intake promotes hypercalciuria with mild acceleration of bone loss. 55 For most persons this does not pose a significant problem, but occasional patients with hypercalciuria also have increased urine sodium excretion. The hypercalciuria will resolve with a reduced sodium intake. This is particularly worth considering in elderly folk who either eat frequently at restaurants or who consume many prepared foods characterized by preservation with high salt contents. A high-acid-ash diet (protein rich) has been implicated as a potential aggravating factor for osteoporosis, but clearly an adequate protein intake must be consumed during growth and development of the skeleton. Excess caffeine is alleged to be a risk factor for the development of osteoporosis, but on the basis of very limited data. 56 Similarly, alcohol when taken to excess is a risk factor for osteoporosis (e.g., direct toxic effects on the skeleton, liver disease, poor general nutrition, hypercortisolism, excess falls). Since excess alcohol is a risk factor for poor health and life expectancy in general, it is really not necessary to focus on the osteoporosis risk when counseling patients to avoid excess alcohol. It should be acknowledged, however, that women who drink alcohol and use oral estrogens for estrogen replacement may have significantly higher circulating estradiol levels than those reported in studies advocating the use of estrogen replacement therapy. 57 Vitamin D is a co-factor in normal skeletal growth and development, but surprisingly little is known about lifetime requirements for this vitamin; 400 IU/day (from sunlight exposure and/or oral intake) is sufficient to prevent tickets in children, but it is not known that higher intakes result in a higher BMD. Adult requirements for vitamin D are unknown but, while undoubtedly less than in children, it seems prudent to maintain an intake of 400 IU throughout life. Unlike calcium, where excess intake is harmless for the most part, excess vitamin D intake (> 5000 IU/day) should be avoided to minimize the risk of vitamin D toxicity, especially in the elderly, since body vitamin D content decreases with age, primarily as a result of restricted sunlight exposure, reduced capacity of the sun to produce vitamin D, and reduced vitamin D intake. An important prospective trial was recently completed in France wherein elderly (70 years and older) institu-

MICHAEL KLEEREKOPER AND LOUIS V. AVIOL!

tionalized women have been randomized to receive either a placebo or 1000 mg calcium plus 800 IU of vitamin D daily. 58 During 3 years of prospective follow-up, those on the supplements have sustained significantly fewer osteoporotic hip and other nonvertebral fractures. It is not certain whether this observation would be valid in the United States, where the food chain is fortified with vitamin D. It is also unclear whether the benefit seen in this French study results from calcium, vitamin D, or both. Vitamin D deficiency is associated with a mild proximal myopathy and increased risk of falling, and the observed effects could be explained by an effect on muscle rather than bone. Whatever the mechanism, it must be recognized that many elderly, particularly if institutionalized, do not have adequate sunlight exposure and are at risk for vitamin D deficiency. It would seem prudent, safe, and cost-effective to recommend a daily supplement of 1000 mg of calcium and 800 IU of vitamin D to all persons over age 75 in order to minimize the occurrence of secondary hyperparathyroidism and high-bone-turnover osteoporotic syndromes. 59 3. EXERCISE

Immobilization results in accelerated bone loss, while vigorous load-beating exercise during growth and development results in increased BMD. Between these extremes the skeletal benefits of exercise are unclear. Since there are many nonskeletal benefits of a regular aerobic and load-bearing exercise program, it is appropriate for all persons to participate in such activities. At times of accelerated bone loss (menopause, disease, or medication) even vigorous exercise is of minimal help in retarding bone loss, and certainly cannot substitute for estrogen replacement, for example. However, there are reports testifying to the additive effects of weightbeating exercises and estrogens on bone mineral density in older women. 6~ Persons who have sustained osteoporotic fractures, especially of the vertebral body or proximal femur and to a lesser extent the wrist, must be encouraged to enter an active physical therapy/rehabilitation program. Even non-load-bearing activities such as swimming will be of overall benefit to these patients despite the limited likelihood of a direct benefit to BMD. Such a program will markedly diminish the chronic back pain of vertebral fractures, improve posture, and probably reduce the risk of further fracture occurrence, although this is by no means well documented. Likewise, rehabilitation is essential following a hip fracture to reduce morbidity and mortality. The improved balance achieved by these activities will also reduce the risk of subsequent falls and fractures. The importance of balance, coordination, and muscle strength and tone in minimizing risk of fall and fracture cannot be overemphasized. 61'62

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399

B. Pharmacological Intervention

femur. Whenever ERT is started, bone loss will be prevented, no matter how many years have passed since the menopause. However, gains in bone mass with ERT are quite small (1% to 2% per year for 1 to 2 years) so that it is essential to commence ERT as soon after the menopause as possible to minimize irreversible bone loss. This therapy prevents bone loss as long as it is administered, but bone loss resumes as soon as therapy is discontinued. Epidemiological studies suggest that a minimum of 10 years of ERT/HRT is required to obtain maximal prophylactic benefit. 67 In established osteoporosis (low BMD with or without fracture) ERT/HRT prevents further bone loss and is associated with slight gains in BMD on the order of 1.5% to 2.5% per year for 1 to 2 years, with maintenance of B MD thereafter. There are recent data suggesting that response of the skeleton to estrogen is enhanced in osteoporosis with larger gains in bone mass seen in older women compared to women in the first few years after the menopause. In one study conducted in women aged 65, 1 year of transdermal estradiol was sufficient to significantly reduce prospectively measured vertebral fracture occurrence. 68 There is a prevailing opinion that ERT/HRT should be administered and continued indefinitely in order to prevent fracture. 69 It is also worth emphasizing that ERT/HRT initiated after 60 years of age and continued thereafter offers almost comparable protection as would be anticipated when treating younger postmenopausal women. 7~ Estrogen suppresses bone remodeling with a reduction in biochemical markers of resorption and formation seen within 3 months of therapy. 72 Discontinuation of therapy also results in a rapid loss of bone and a return of these markers to pretreatment levels within 3 months of interrupting therapy. Given the poor patient acceptance of and compliance with ERT/HRT, and that the concerns linking therapy to an increased occurrence of breast cancer 73 are duration dependent, a case could be made for intermittent therapy. However, to our knowledge, to date no formal prospective studies of this approach have been recorded.

1. ESTROGEN For the prevention of rapid bone loss at the menopause there is little doubt that estrogen replacement therapy (ERT) is the most effective and cost-effective intervention. In women with an intact uterus, progesterone should be prescribed together with estrogen [hormone replacement (HRT)] to minimize and possibly eliminate the potential for ERT-induced carcinoma of the endometrium. There are many potential compounds, doses, and combinations of ERT and HRT as well as many nonskeletal benefits, side effects, and other considerations, but a full discussion of these is beyond the scope of this chapter. There have been few formal dose-finding studies, and even fewer studies comparing one therapeutic option with another. However, there is considerable evidence that 0.625 mg/day of oral conjugated equine estrogen (CEE), or equivalent (Table 12-5), is sufficient to prevent early postmenopausal bone loss in 90% to 95% of all women. 63 While relatively large doses of progesterone alone (e.g., 20 mg/day of medroxyprogesterone acetate) will retard bone loss without estrogen, there is no evidence that HRT imparts a skeletal benefit over ERT. 63 Combining 0.3 mg/day of CEE with 1500 mg/ day of a calcium supplement has been shown to be as effective as 0.625 mg of CEE alone. 64 There is little cost advantage to this approach, and the potential compliance benefit of lesser estrogen dose must be weighed against the observations that compliance, which is a characteristic problem for women who consider estrogen therapy, 65 generally falls after the first year of estrogen treatment. 66 At the menopause, ERT/HRT is effective at the spine and proximal femur, although some studies have suggested that a higher dose (> 0.625 mg CEE) may be required to fully prevent bone loss from the proximal

TABLE 1 2 - 5 Hormone Replacement Therapies Approved for the Prevention and Treatment of Osteoporosis in the United States Drug

Dosage

Premarin a

0.625 mg/day

PremPro

0.625/2.5 mg/day

Premphase

0.625/5 mg/day

Ogen a

0.625 mg/day

Estrace a

0.5 mg/day

Estraderm a

0.05 mg twice a week

aEstrogen-only preparations, usually prescribed with progesterone in women with intact uterus.

2. CALCITONIN Although the physiological role of calcitonin in humans has not been established, it is well documented that this hormone can profoundly inhibit osteoclast function and retard bone loss, particularly when due to increased resorption (i.e., high-turnover bone lOSS). 72-81 Clinical trials have been conducted with synthetic salmon, eel, and human calcitonin (hCT), with salmon calcitonin (sCT) being the most potent of these. Until recently, sCT was only available as an injectable preparation requiting self-administered subcutaneous injections, severely limiting patient acceptance of this therapy. However, sCT is

400


now available as a nasal spray, with each metered dose providing 200 IU of the drug. The altered bioavailability of the nasal spray preparation makes this 200-unit dose approximately equivalent to 100 IU of the injectable preparations of sCT, which has also been approved by the FDA for osteoporosis therapy. The short- and long-term safety and efficacy of sCT in the treatment of osteoporosis has been well established during two decades of experience with the injectable preparation. Compared to patients treated with calcium alone, sCT increases B MD by approximately 1.5% to 2.0% over a 2-year period. 79 Placebo-controlled prospective studies are also consistent with reduction in fracture frequency. 79'8~Although intermittent therapy using 200 IU of nasal spray has proven effective in some postmenopausal patients, 82'83 this is not always the case 81 (Fig. 12-5). The response to calcitonin is similar to that obtained with ERT/HRT. 77 While there is a dosedependent response to sCT, side effects (nausea, flushing) limited the use of doses greater than 100 IU subcutaneously daily. Nasal spray sCT is not available in doses less than 200 IU/day, an effective dose for 75% of patients, and there is only minimal incremental benefit from 400 1-U/day.84 Short-term side effects of nausea and flushing are of minimal concern with this preparation. The major side effects relate to mild rhinitis and nasal stuffiness. Although sCT is currently considerably more expensive than ERT/HRT, it is certainly a viable alternative approach for those women who cannot or will not take estrogen therapy, and can also be considered appropriate therapy for nonhypogonadal males with osteoporosis. A few well-controlled short-term prospective studies in patients with vertebral fractures have indicated that VERTEBRAL BMD

3. BISPHOSPHONATES

1 0

SCT 200 iu daily

(n=29)

%

change

-1 SCT 200

2

iu M/W/F (n=29)

3

PLACEBO (n--39) 0

FIGURE 12--5

sCT has significant analgesic properties, 85'86presumed to relate to calcitonin-mediated release of endorphins. In these trials, which were conducted in patients where therapy was initiated in the immediate postvertebral fracture period, sCT (injectable and nasal spray) reduced overall morbidity, self-assessment of pain, and consumption of analgesics. 85'86 Since many clinicians report substantial albeit anecdotal experience of the analgesic benefits of sCT in the acute postfracture stage, this might be the best indication to commence sCT therapy. Without intervention, the acute pain following a vertebral fracture should subside within 6 weeks, but the patient is often left with chronic back pain. Since there are no data to suggest that sCT has any analgesic benefit for this chronic pain, it appears that the early benefit derives from local actions at the skeleton and not central, endorphin-mediated effects. An analgesic effect in patients with Paget' s disease of bone or skeletal metastases would support this local action. Estrogen, an equipotent inhibitor of bone resorption, has no apparent analgesic effects. While the mechanisms are unclear, as mentioned, relief of acute postfracture pain remains a good indication for initiating sCT therapy in osteoporotic patients who present with painful fracture syndromes. As with estrogen, sCT therapy can be shown to decrease rates of bone turnover and at least one study has indicated that intermittent (discontinuous) sCT therapy is effective. 8~ Certainly the major effect of sCT (and estrogen) to increase BMD is complete after 2 to 3 years, and it seems appropriate to reevaluate the therapeutic response at that time. At the end of therapy biochemical markers of remodeling should be in the normal range. These could be monitored at 3- to 6-month intervals, with therapy reinstituted as the markers begin to increase as a result of progressive bone loss.

6

12

18

24

(months)

Percentage change in vertebral BMD in all patients treated with either intranasal salmon calcitonin (sCT) 200 IU daily, sCT 200 IU twice weekly (MWF), or placebo. Vertical bars represent SEM (*P 50 6 hours). Hence, 1,25D plays a key role in the day-to-day maintenance of calcium balance. PTH stimulates the production of 1,25D by activating the renal l o~-hydroxylase enzyme 7, and 1,25D suppresses the synthesis and secretion of PTH. 8-~~ Thus, both PTH and 1,25D directly affect calcium homeostasis, and each exercises important regulatory effects on the other.

A. Alterations in Vitamin D Metabolism in Renal Failure" The Receptor Control of gene transcription by 1,25D is thought to be mediated by a receptor protein in target cells that has a high affinity and high specificity for the vitamin D metabolite. Although the mechanisms by which the receptor carries out the nuclear action of 1,25D is not fully understood, it is clear that the receptor can determine the response of the target cell to 1,25D. Korkor ~1 demonstrated that parathyroid glands (PTG) from patients with chronic renal failure (CRF) contained one third the number of receptors compared to parathyroid adenomas. Merke et al. 12 found in rats, 6 days after subtotal nephrectomy, that the PTG contained only half the number of receptors compared to PTG of sham-operated controis. Similar results were found by Brown et al. 13 in dogs. Although it has not been rigorously proven that vitamin D receptors (VDR) play a role in suppressing PTH synthesis and determining the sensitivity of the parathyroid gland to calcium, it is possible that the reduced

VDR numbers in PTG of uremic patients render the glands less responsive to the inhibitory action of 1,25D. Whether the levels of serum 1,25D determine the content of VDR in PTG is unclear. Navey-Many et al. 14 demonstrated that the administration of 1,25D led to a dosedependent increase in the mRNA for the VDR in the PTG of normal rats. Recently, Denda et al. demonstrated that the administration of 1,25D or its analog 22-oxacalcitriol (OCT) increases the number of VDR in the parathyroid glands of uremic rats. 15 These data are consistent with the view that 1,25D regulates its own receptor in parathyroid cells. An additional effect of 1,25D on PTG comes from the studies of Kremer et al. 16 who showed that exposure of quiescent bovine parathyroid cells in culture to serum resulted in increased 3H t h y midine incorporation, followed by an increase in the cell number. These changes were preceded by an increase in c-myc and c-fos protooncogene mRNA levels. However, 1,25D, when added to serum, blocked the increase in cmyc mRNA, and there was no increase in the number of parathyroid cells. These results indicated that 1,25D may directly modulate parathyroid cell proliferation by altering the expression of replication associated with specific oncogenes. Thus, 1,25D may be an important inhibitory growth factor of parathyroid cells, and low levels of 1,25D may allow parathyroid cells to proliferate. In addition, studies by Szabo et al. 17 in experimental animals with renal failure suggest that 1,25D administration suppresses parathyroid hyperplasia independent of changes in serum calcium. Once established, hyperplasia was not reversed by short-term 1,25D treatment. Fukuda et al. 18 have provided evidence for a decreased 1,25D receptor density in patients who have parathyroid hyperplasia. The investigators studied the VDR distribution of surgically excised PTG obtained from dialysis patients. They classified the parathyroids as exhibiting nodular or diffuse hyperplasia. They found a lower density of the VDR in PTG showing nodular hyperplasia than in those showing diffuse hyperplasia. A significant negative correlation was found between VDR density and the weight of the PTG (Fig. 14-2). In other words, the higher the levels of PTH in serum, the greater the degree of PTG hyperplasia and the lower the density of the VDR. These studies provide rational basis for understanding the difficulties in suppressing secondary hyperparathyroidism (SH) when the PTH levels are extremely high (> 1500 pg/ml). In addition, it is important to emphasize that in the PTG there is a component of the secretory mechanism that cannot be suppressed by either high ICA or pharmacological doses of 1,25D. Although this component of the secretory mechanism represents a small percentage of the total amount of PTH secreted by the PTG in normal individuals, it becomes extremely important in those patients in whom the PTG

CHAPTER 14 Renal Osteodystrophy

FIGURE 14--2 The relationship between parathyroid gland weight and percentage positive VDR staining. (Adapted from Fukuda N, Tanaka H, Tominaga Y, et al: Decreased 1,25-dihydroxyvitamin D3 receptor density is associated with a more severe form of parathyroid hyperplasia in chronic uremic patients. J Clin Invest 92: 1436-1443, 1993.)

are 50 to 100 times normal size. Many years ago, Gittes et al. 19 clearly demonstrated this p h e n o m e n o n in rats by implanting a large number of PTG in rats that had undergone a previous parathyroidectomy (PTX). The serum calcium decreased following PTX. However, after the implantation of 20 or 80 PTG, the rats developed severe hypercalcemia. One would expect that the hypercalcemia should suppress the release of PTH. However, it was clear from these experiments that the hypercalcemia continued due to the fact that a nonsuppressible component was present, and the large amount of tissue was responsible for the maintenance of hypercalcemia. Furthermore, when Mayer et al. 2~ measured the A-V difference of PTH across the PTG in cows, they found that despite induction of severe hypercalcemia (serum calcium up to 18 to 20 mg/dl), there was still a small component of PTH secretion from the PTG (Fig. 1 4 - 3 ) . Thus, the development of hyperplasia with a consequent increase of a nonsuppressible component and the low number of 1,25D receptors makes the PTG more resistant to the use of 1,25D in the treatment of SH.

B. Decreased Sensitivity to Calcium Evidence exists for an intrinsic abnormality of the PTG in uremia that leads to disordered calciumregulated PTH secretion. An insensitivity to the suppressive effect of calcium on PTH secretion has been shown in glands obtained from patients with CRF. 21'22 These observations suggest that one mechanism for the increased PTH levels in CRF may be a shift in the set-

445

FIGURE 14--3 Levels of plasma PTH before and after a calcium infusion. (Adapted from Mayer GP, Habener JF, Potts JT Jr: Parathyroid hormone secretion in vivo. Demonstration of a calcium-independent, nonsuppressible component of secretion. J Clin Invest 57:678683, 1976.)

point (defined as the ICa level that causes a 50% suppression of maximally stimulated PTH) for calciumregulated PTH secretion in addition to the increase in the mass of parathyroid tissue. The set-point for calcium in normal PTG was --~1.0 m M of calcium, whereas in patients with SH, the set-point was found to be increased to 1.26 m M of calcium. These abnormalities also are manifested by an increase in the calcium concentration required for the inhibition of the adenylate cyclase activity in membranes prepared from hyperplastic PTG obtained from patients with C R E 23 It is possible, therefore, that normal concentrations of ICa in serum may not be sufficient to suppress hyperplastic PTG. Thus, the serum calcium levels may have to be increased to the upper limits of normal to control the rise of PTH in patients with SH. Although the precise mechanism responsible for the decreased sensitivity to calcium in hyperplastic PTG is unknown, alterations in vitamin D metabolism (i.e., low levels of 1,25D and decreased number of V D R in the PTG) may account, in part, for the abnormal secretion of PTH in renal failure. Brown et al. 24 cloned a calcium receptor (Ca-R) localized in bovine parathyroid cell membranes. Although the molecular nature of such receptors(s) is unknown, parathyroid cells possess an extracellular calciumsensing mechanism that recognizes trivalent and polyvalent cations (such as neomycin) and regulates PTH secretion by changes in phosphoinositide turnover and

446 cytosolic calcium levels. This receptor features a large, extracellular domain containing clusters of acidic amino acids that are possibly involved in calcium binding. The extracellular domain is coupled to a cellular membranespanning domain similar to the G-protein-coupled receptor superfamily. 24 Pollack et al. 25 demonstrated that mutations in the human calcium-sensing receptor cause familiar hypocalciuric hypercalcemia and severe neonatal hyperparathyroidism. Recently, Kifor et al. 26 using immunohistochemistry techniques, demonstrated a 59% decrease in Ca-R in parathyroid glands of uremic patients. Similar results were demonstrated in adenomas of parathyroid glands obtained from patients with primary hyperparathyroidism. These investigators concluded that the degree of Ca-R reduction would be sufficient to account, at least in part, for the altered sensitivity to Ca observed in secondary hyperparathyroidism. Arnold et al. 27 examined the abnormality in primary and secondary hyperparathyroidism using chromosome inactivation analysis with the M2713 DNA polymorphism and by searching for monoclonal allelic losses at M2713 and at loci on chromosome l lq13. Seven of 11 (64%) uremic patients demonstrated at least one monoclonal parathyroid tumor, as did 38% of patients with primary chief cell hyperplasia. These findings suggest that monoclonal transformation of previous hyperplastic parathyroid tissue may be another factor responsible for the development of autonomous hyperparathyroidism. Thus, the combination of an enlarged parathyroid cell (hypertrophy), increased numbers of parathyroid cells (hyperplasia), abnormal calcium-regulated secretion of PTH, nodular appearance with loss of vitamin D receptors, decreased number of calcium receptors, and monoclonal changes may all participate in the development of nonsuppressible secondary hyperparathyroidism (Fig. 14-4). To further characterize the potential role of 1,25D on the abnormal set-point for the suppression of PTH by calcium, Delmez et al. 28 studied the suppression of PTH by calcium before and after 2 weeks of intravenous (IV) 1,25D in a group of hemodialysis patients. During hypercalcemic suppression, the calcium set-point for PTH fell from 5.24 mg/dl to 5.06 mg/dl after the administration of 1,25D. During hypocalcemic stimulation, the parathyroid response was attenuated by 1,25D. Thus, the suppression of PTH secretion during treatment with 1,25D appears to be due, in part, to an increase in the sensitivity of the PTG to ambient calcium levels (Fig. 14-5). Dunlay 29 found similar inhibitory effects with IV 1,25D in dialysis patients. After 10 weeks of IV 1,25D, there was a significant decrease in the levels of serum PTH. These investigators also found that the relation of ionized calcium-PTH sigmoidal curve was shifted to the

EDUARDO SLATOPOLSKYAND JAMES A. DELMEZ

Chronic Renal Failure

Phosphate /

l LowLove's '

Retention

1,25 (OH) 2 D 3 I

,

Resistance of ~ Bone to PTH

[ Hyperparathyroidism

/

t Shift in Set Point for Calcium

t?

t? .......

Decreased

Ca Sensor

1,25 (OH)z D 3 Receptors

FIGURE 1 4 - 4

Diagrammatic representation of the factors involved in the pathogenesis of secondary hyperparathyroidism.

left, suggesting an increase in the suppressive effect of calcium. Others have been unable to confirm these results. Several years ago 3~ we showed that the IV administration of 1,25D was very effective in the suppression of Ca

1000 -

!

-~.

750 E

o')

"I-

e--e Control o--o 1,25(OH)2D3

',~,,, Shift ~

500

O.

250 I

4.4 FIGURE 14--5

//

I

I

I

I

I

I

I

I

I

4.6 4.8 5.0 5.2 5.4 5.6 5.8 6.0 6.2 Ionized Calcium mgldl

The relationship between ionized calcium and serum PTH before ( e - - e ) and after treatment with 1,25(OH)zD3 (o--o). (Adapted from Delmez JA, Tindira C, Grooms P, et al: Parathyroid hormone suppression by intravenous 1,25-dihydroxyvitamin D: A role for increased sensitivity to calcium. J Clin Invest 83: 1349-1355, 1989.)

CHAgrER 14 Renal Osteodystrophy

447

FIGURE 1 4 - 6 Mean 1,25(OH)2D3 serum concentrations at various times after (o--o) bolus injection of 35 pM 1,25(OH)2D3 and at various times during (omo) continuous infusion of 70 pM 1,25(OH)2D3. (Adapted from Reichel H, Szabo A, Uhl J, et al: Intermittent versus continuous administration of 1,25-dihydroxyvitamin D3 in experimental renal hyperparathyroidism. Kidney Int 44:1259-1265, 1993.)

SH. Studies performed in 20 patients maintained on chronic hemodialysis given IV 1,25D demonstrated a marked suppression of PTH (70.1 _ 3.2%). On the other hand, studies performed in a group of patients treated with oral daily doses (0.5 txg) of 1,25D showed less suppression. We also demonstrated 31 in primary culture of bovine parathyroid cells that the suppression of PTH by 1,25D was dose dependent. Tsukamoto et al. 32 showed that 1,25D, when given as an oral pulse of 3 to 4 txg twice weekly, achieved a greater suppression than 0.5 Ixg daily. Reichel et al. 33 compared the effect of intermittent versus continuous administration of 1,25D in uremic rats with SH. One group of animals received 35 pM of 1,25D via intraperitoneal (IP) bolus on days 0 and 4. A second experimental group received a continuous infusion of 70 pM of 1,25D over 6 days via an osmotic minipump. Thus, over the same period of time, the two groups received the same amount of 1,25D. Peak 1,25D concentrations were significantly higher and PTH values were significantly lower in the group that received the two IP boluses compared to the group that received the continuous infusion (Fig. 14-6). The calculated timeaveraged increase in 1,25D serum concentrations during the 6 days was 254 pg/ml (42.3 pg/ml/24 hr) in continuous infusion-treated animals and 156 pg/ml (26.0 pg/ ml/24 hr) in bolus-treated animals. The degree of suppression of the prepro PTH/13-actin m R N A was also greater in the group that received the IP bolus compared to those animals treated with a constant infusion (Fig.

14-7). Moreover, the growth of the parathyroid glands was prevented only with the bolus administration (Fig. 14-8). Thus, these investigators conclude that the concentration of 1,25D achieved in serum is an important determinant of the response of PTG to 1,25D. Although 1,25D and calcium are negative regulatory elements in the upstream region of the PTH gene, they act on different locations. Both are of great importance and simultaneously may participate in the suppression of PTH secretion. The calcium responsive element was found around - 3 . 5 Kb upstream from the human PTH

FIGURE 14--7 Effectof bolus versus continuous 1,25(OH)2D3administration on prepro PTH mRNA. (Adapted from Reichel H, Szabo A, Uhl J, et al: Intermittent versus continuous administration of 1,25dihydroxyvitamin D3 in experimental renal hyperparathyroidism. Kidney Int 44:1259-1265, 1993.)

448

EDUARDO SLATOPOLSKY AND JAMES A. DELMEZ

FIGURE 1 4 - - 8 Effect of bolus versus continuous 1,25(OH)2D3 administration on parathyroid gland weight. (Adapted from Reichel H, Szabo A, Uhl J, et al: Intermittent versus continuous administration of 1,25-dihydroxyvitamin D 3 in experimental renal hyperparathyroidism. Kidney Int 44:1259-1265, 1993.)

gene, and its sequence consists of 12 palindromic bases with a gap of three bases. 34 In contrast, the negative vitamin D-responsive element was found in a 25-bp oligonucleotide spanning from - 1 2 5 to - 1 0 1 . 35 In order to determine the relationship of these two elements (ICa and 1,25D) in the suppression of the secretion of PTH in uremic rats, we induced hypocalcemia by feeding uremic rats a low-calcium diet. 36 We clearly demonstrate that pharmacological doses of 1,25D, that usually suppress SH, failed to block the synthesis of prepro PTH mRNA and the secretion of PTH. Thus, correction of both calcium and 1,25D are crucial in the treatment of SH.

C. P h o s p h a t e R e t e n t i o n Phosphate retention plays a key role in the pathogenesis of secondary hyperparathyroidism. 37-39 Reiss et al. 4~ reported that an oral load of phosphorus, providing 1.0 g of elemental phosphorus, led to an increase in serum phosphorus, a fall in ICa levels, and an increase in serum I-PTH in normal subjects. Several investigators have shown that long-term feeding of animals with a diet high in phosphate can produce parathyroid hyperplasia, increased levels of I-PTH, and a mild reduction in serum calcium l e v e l s . 41'42 Studies in experimental renal failure have shown that the restriction of dietary phosphate in proportion to the decrease in glomerular filtration rate (GFR) can prevent the development of secondary hyperparathyroidism in azotemic dogs followed for 2 months. 38 Subsequent studies 43 showed a substantial reduction of serum I-PTH levels in animals with renal failure treated with a phosphate-restricted diet for 2 years. Llach et al. 44 indicated that a reduction in dietary phos-

phate intake in proportion to the decrease in GFR over a 2-month period in humans with creatinine clearances of 50 to 90 ml/min was associated with a decrease in serum I-PTH to normal levels. When phosphate intake was reduced in patients with more advanced renal insufficiency, serum I-PTH fell substantially but remained above normal levels. 45 Other studies have shown that serum I-PTH levels correlate positively with the degree of hyperphosphatemia in patients undergoing dialysis, 46 an observation providing support for a role of hyperphosphatemia in causing parathyroid hypersecretion, particularly in patients with advanced uremia. Thus, phosphate loading could cause a small fall in the level of ionized calcium, or it may decrease the renal production of 1,25D 47 which may permit more secretion of PTH at any given levels of serum calcium. As renal disease advances and GFR falls below 25 ml/min, hyperphosphatemia is usual, 48 and hypocalcemia is more directly related to a markedly increased level of serum phosphorus. Although high concentrations of serum phosphate (7 to 9 mg/dl) precipitate calcium in soft tissues, the mechanism by which mild hyperphosphatemia affects the concentration of ionized calcium in serum is not known. It may decrease the release of calcium from bone 49 or affect the activity of the renal enzyme l oL-hydroxylase responsible for the conversion of 25(OH)D to 1,25(OH)2D. 47 Portale et al. 5~ demonstrated that, in patients with moderate renal insufficiency, phosphate restriction increased plasma 1,25D levels with a concomitant normalization of plasma PTH. This occurred despite no changes in serum phosphorus levels. Thus, the effect of phosphate on the l et-hydroxylase enzyme in early renal insufficiency may not be responsible for the development of hypocalcemia that may be seen in patients with advanced renal failure and severe hyperphosphatemia. Since reduced renal mass may limit the production of 1,25D in advanced renal insufficiency, we performed further studies in uremic dogs 52 to clarify the mechanism by which dietary phosphate restriction improved SH. We examined how dietary phosphate restriction could ameliorate SH without increasing the levels of 1,25D (Fig. 14-9). Our results confirmed an important effect of phosphorus restriction on suppressing SH. However, in contrast to previous findings in patients with moderate renal insufficiency, progressive reduction of dietary phosphorus did not increase plasma 1,25D levels (Fig. 14-10). Thus, in severe chronic renal failure phosphorus appears to regulate PTH secretion by a mechanism that is independent of calcitriol. In agreement with our results, Lucas 53 found that the administration of a low-phosphorus diet to patients with advanced renal insufficiency did not increase 1,25D levels. Plasma PTH levels significantly decreased, while serum calcium levels did not change. Schaefer 54 obtained similar results in

CHAPTER 14 Renal Osteodystrophy

FIGURE 14--9 Effects of dietary phosphorus and calcium on plasma ionized calcium (top), plasma phosphorus (middle), and PTH (bottom) in five uremic dogs. (Adapted from Lopez-Hilker S, Dusso A, Rapp N, et al: Phosphorus restriction reverses secondary hyperparathyroidism in chronic renal failure independent of changes in calcium and 1,25 dihydroxycholecalciferol. Am J Physiol 259:F432F437, 1990.)

a group of 17 patients with advanced renal insufficiency (plasma creatinine 8.7 mg/dl) in whom ketoacids were added to the diet. After 8 weeks of treatment, they found a significant decrease in the levels of plasma phosphorus and IPTH. There were no changes in plasma calcium or

FIGURE 14--10

Effects of dietary phosphorus and calcium on plasma 1,25(OH)2D3 in five uremic dogs. (Adapted from Lopez-Hilker S, Dusso A, Rapp N, et al: Phosphorus restriction reverses secondary hyperparathyroidism in chronic renal failure independent of changes in calcium and 1,25 dihydroxycholecalciferol. Am J Physiol 259: F432-F437, 1990.)

449 1,25D values. Tessitore et al. 55 also showed that dietary phosphorus restriction did not have an effect on 1,25D concentration when the GRF was less than 20 ml/min. In vitamin D-deficient rats, Dabbagh et al. 56 observed that in the presence of a normal plasma calcium concentration, the administration of a phosphorus-restricted diet prevented the development of SH. Recently we have shown that dietary phosphate restriction prevented parathyroid cell growth in uremic rats. In addition, high phosphate concentrations in the media post-transcriptionally stimulated PTH secretion in tissue culture. 57 Studies were performed in normal and uremic rats fed a low-phosphorus (0.2%) or highphosphorous (0.8%) diet for a period of 2 months. Parathyroid gland weight and serum PTH were similar in both groups of normal rats and uremic rats fed the 0.2% phosphorus diet. On the other hand, in uremic rats fed the 0.8% phosphorus diet, the parathyroid gland weight increased by approximately 120% compared to the normal animals fed the same diet. In the uremic rats fed a high-phosphorus diet PTH also increased from 29.1 • 6.1 Pg/ml to 130 • 25 pg/ml. There were no changes in ICa or 1,25D. In vitro studies with parathyroid glands of normal rats demonstrated that, when the phosphorus in the culture medium was increased from 0.2 mM to 2.8 mM, the amount of PTH secreted into the medium increased from 810 • 155 to 1492 • 182 pg/Ixg DNA per 5 hours. Since it took a minimum of 3 hours for phosphorus to increase the amount of PTH in the medium, the effect of phosphorus was mainly on PTH synthesis and eventually on secretion (Fig. 14-11). The addition of cycloheximide blocked the effect of phosphorus, suggesting that protein synthesis is necessary for the increment in PTH secretion. In conclusion, dietary phosphorus restriction improves secondary hyperparathyroidism in animals and subjects with advanced renal failure. This effect is not mediated by an increase in the levels of 1,25D or plasma ICa. In addition, high-phosphorus diets induce chief cell hyperplasia of parathyroid glands in uremic rats. Moreover, studies in vitro demonstrate that high phosphorus levels increase PTH synthesis and secretion. Thus, in addition to a well-known effect of phosphorus in the regulation of 1,25D synthesis, a high-phosphorus diet may have direct effect on the secretion of PTH. Although the mechanism of this effect is not yet known, phosphorus may potentially affect the phospholipid composition of the parathyroid cell membrane, calcium fluxes, and VDR, and perhaps have an effect on the calcium receptor in the parathyroid cell membrane. From the clinical point of view, significant data have accumulated indicating that, in the present of hyperphosphatemia, the parathyroid glands are resistant to the action of 1,25D. The new information of a direct action of

450

EDUARDO SLATOPOLSKY AND JAMES A. DELMEZ 2000

*

1800

2.8 P mM

~- 1600 Z s

*

1400

.~ 1200 I o_

0.2 P mM

10o0

rr" 800 I---

o ~< 600 z 400 200 0

o

,

9

~

;

-

4

,

s

;

It,

8

TIME IN HOURS

FIGURE 14-11

Time course for PTH secretion by normal intact rat parathyroid glands, incubated in a low (0.2 mM) (o) (n - 8) or high (2.8 mM) (o) (n = 8) phosphorus in the media (P < 0.05). The effects of phosphorus were not evident until 3 hours (From Slatopolsky E, Finch J, Denda M, et ah Phosphate restriction prevents parathyroid cell growth in uremic rats and high phosphate directly stimulates PTH secretion in tissue culture. J Clin Invest 97:2534-2540, 1996.)

phosphorus on PTH synthesis and chief cell hyperplasia emphasizes the importance of controlling serum phosphorus in chronic renal failure. Further studies are necessary to determine the precise mechanism at the molecular level by which phosphorus contributes to the regulation of PTH secretion in chronic renal failure.

The concept of skeletal resistance to PTH as an important factor in the development of secondary hyperparathyroidism has been challenged. Kaplan et al. 6~ fed dogs with chronic renal failure a low-phosphate diet and prevented the development of SH. Nonetheless, these animals developed skeletal resistance to the calcemic action of PTH. Thus, despite the presence of skeletal resistance to PTH, the dogs did not develop secondary hyperparathyroidism. However, Llach et al. 44 found that dietary phosphate restriction improved the calcemic response to an infusion of PTH in patients with mild renal insufficiency. It is possible that alterations in vitamin D metabolism could be responsible for the resistance to the calcemic action of PTH seen in uremia. In dogs with acute renal failure, 6~ treatment with 1,25(OH)2D3 resuited in partial correction of the blunted calcemic response to parathyroid extract. Other observations suggest that hyperphosphatemia accounts for the skeletal resistance to parathyroid extract in rats with acute renal failure. 62 Galceran et al. 63 studied the calcemic effects of PTH in dogs before and after the induction of chronic renal failure. The administration of calcitriol did not improve the calcemic response to PTH (Fig. 14-12). However, when the uremic dogs underwent a parathyroidectomy 24 hours before the infusion of PTH, the calcemic response returned to normal. Therefore, despite low levels of 1,25(OH)2D3 and maintenance of a uremic environment, removal of PTH from the circulation restored the calcemic response to exogenous PTH to normal. These 1.5

i D. Skeletal Resistance to the Calcemic Action of Parathyroid Hormone Skeletal resistance to the calcemic action of PTH may be an important cause of hypocalcemia in patients with renal insufficiency. The calcemic response to the infusion of parathyroid extract is blunted in hypocalcemic patients with renal failure compared to normal subjects or patients with hypoparathyroidism. 58 The finding of a delayed recovery from ethylenediaminotetraacetic acid (EDTA)-induced hypocalcemia in patients with mild renal insufficiency, despite a greater augmentation in serum I-PTH levels compared to normal subjects, indicates that the skeletal resistance to endogenous PTH appears early in the course of renal insufficiency. 59 Such data suggest that higher levels of PTH may be needed to maintain normal serum calcium levels in patients with renal failure.

1.0

oo 0.5

7 days NS

FIGURE 14--12

90 days

180 days 1,25(OH)2D 3 1,25(OH)2D 3 +TPTX T-PTX

P 75 yr of age; operative mortality 3.8% all prior to 1984; major morbidity 4%. NR, not reported; RLN, recurrent laryngeal nerve.

468 TABLE 15--2 NIH Consensus Conference Indications for Operation in Asymptomatic Primary Hyperparathyroidism a On initial evaluation: Markedly elevated serum calcium History of an episode of life-threatening hypercalcemia Reduced creatinine clearance Presence of kidney stone(s) detected by abdominal radiograph Markedly elevated 24-hour urinary calcium excretion Substantially reduced bone mass as determined by direct measurement During monitoring of an asymptomatic patient, these developments: Typical symptoms of the skeletal, renal, or GI systems Sustained serum calcium > 1.0 to 1.6 mg/dl above normal Significant decline in renal function (> 30% decline in creatinine clearance) Nephrolithiasis or worsening calciuria Significant decline in bone mass (to < 2 SD below age/gender/racematched mean) Significant neuromuscular or psychological symptoms Inability or unwillingness of patient to continue medical surveillance aModified from Potts JT Jr, Ackerman IP, Barker CF, et al: Diagnosis and management of asymptomatic primary hyperparathyroidism: Consensus development conference statement. Ann Intem Med 114:593-597, 1991. GI, gastrointestinal; SD, standard deviations.

proof that parathyroidectomy can prevent this is lacking. 18'27-29 A National Institutes of Health Consensus Development Conference reviewed this subject in 1990. 30 The panel confirmed that operation is indicated for all patients with symptoms of bone disease or renal stone disease. The indications for operation in asymptomatic patients (Table 15-2) were outlined, and the panel suggested semiannual follow-up for patients managed nonoperatively. In addition, operation was recommended for patients in whom medical surveillance was neither desirable nor suitable, as when the patient requests an operation, consistent follow-up is unlikely, coexistent illness complicates management, or the patient is less than 50 years of age. While the initial cost of a parathyroid operation is higher than medical monitoring, with time the cost of follow-up, including bone densitometry studies, laboratory work, and other tests, exceeds the cost of operative intervention; the operative cost can be minimized if the patient is treated by an experienced endocrine surgeon. 2~ Definitive resolution of this question regarding the best management of asymptomatic patients with hyperparathyroidism will require a randomized, controlled trial. 8. LOCALIZATION

That there is no need for parathyroid gland localization studies prior to cervical exploration in a previously

GERARD M. DOHERTY AND SAMUEL A. WELLS, JR.

unoperated patient with hyperparathyroidism is an area of some controversy. This view is reflected in the statement of the recent National Institutes of Health Consensus Conference statement: "Preoperative localization in patients without prior neck operation is rarely indicated and not proven to be cost-effective."3~ The fact that the surgeon must examine all four parathyroid glands before making a decision as to which should be resected obviates the routine use of localization procedures.

B. S p e c i a l E t i o l o g i c a l C o n s i d e r a t i o n s 1. FAMILIAL DISEASE Familial hyperparathyroidism can present as an isolated, autosomal dominant inherited disease, or more commonly as a part of multiple endocrine neoplasia (MEN) types I or IIA. A thorough family history may reveal the presence of a familial endocrinopathy. This is clinically important because the parathyroid disease in these patients is multiglandular. This demands an operative strategy designed for multiglandular disease, even if there is asymmetrical hypertrophy and one or more of the parathyroid glands appears grossly normal. 31 In addition, patients with MEN-I are also at risk for developing tumors of the pancreatic islet cells (especially functional gastrinomas or insulinomas), the pituitary gland (particularly prolactinomas), and the adrenal cortex. All patients with MEN-IIA develop medullary thyroid carcinoma, and about half of them develop pheochromocytomas. Management of these nonparathyroid tumors requires specific strategies designed around their natural histories. FHHH and neonatal severe hyperparathyroidism are rare conditions caused by a defect in the gene coding for the calcium-sensing receptor. Homozygote infants are often bom with hypotonia, poor feeding, constipation, respiratory distress, and neonatal severe hyperparathyroidism. 32 The 1-year survival in symptomatic untreated patients is less than 50%, and total parathyroidectomy with autotransplantation appears to be the treatment of choice. 33 A more conservative approach may be justified if the infant is asymptomatic. People who have one normal gene copy have FHHH. This benign condition represents an elevation in the calcium set-point. The patients have elevated serum calcium concentrations and mildly elevated serum PTH concentrations, but no complications of primary hyperparathyroidism. This disease can be distinguished from primary hyperparathyroidism by the normal 24-hour urine calcium. The genetic abnormalities associated with MEN-I, MEN-IIA, and FHHH have been identified, and it is now possible to identify affected family members by direct

CHAPTER 15 SurgicalTreatment for Hyperparathyroidism

genetic testing. 34-36'34a This simplifies the diagnosis and management of these patients.

469 asymptomatic patient, the altemative of nonoperative or medical management should be presented.

2. RADIATION EXPOSURE

Exposure to external beam radiation, particularly during childhood, carries an increased risk of later primary hyperparathyroidism. 37'38 This risk factor is important to elucidate, not because of differences in the parathyroid pathology, which is similar to patients without a history of radiation exposure, but because of the increased frequency of associated tumors in the thyroid or salivary glands, which might require attention at operation. 39 Careful examination of the neck preoperatively and postoperatively is important in patients with this history. The patient should be informed of the possible need for resection of a thyroid or salivary gland tumor if found at operation.

C. General Preoperative Assessment Patients undergoing neck exploration for hyperparathyroidism must be prepared for general anesthesia. The preoperative assessment should include a thorough history and physical examination to evaluate the risk of anesthesia for the particular patient. Neck exploration is typically not a physiologically stressful procedure, as there are only minor fluid shifts, and rarely significant blood loss. Severe hypercalcemia should be corrected before operation by saline diuresis and pharmacological means. Patients who have had previous cervical operations should have documentation of bilateral vocal cord function.

D. Informed Consent A thorough preoperative discussion can help the patient by giving them appropriate expectations about the operation. The patient should be made fully aware of the complications associated with the neck exploration, including potential damage to the superior and recurrent laryngeal nerves and the development of transient or permanent hypocalcemia. The possibility of an unsuccessful parathyroid search should be mentioned, and the patient should be made aware that repeat operation, including a mediastinal exploration, may be required if the planned operation is unsuccessful. Although the likelihood of these complications is small, it is best to discuss them prior to the initial neck exploration. In addition, the complications associated with general anesthetic, including allergic reactions to medications, and the rare occurrence of wound complications, such as postoperative bleeding or infection, should be presented. In the rare, truly

III. PRIMARY HYPERPARATHYROIDISM: CONDUCT OF THE OPERATION There are five cardinal rules which should be followed when operating on patients with primary hyperparathyroidism for the first time: (1) explore both sides of the neck and identify all four parathyroid glands; (2) determine which of the parathyroid glands is (are) enlarged; (3) resect the enlarged parathyroid glands and leave the normal size parathyroid gland(s) in situ; (4) when all four parathyroid glands are enlarged, perform either a subtotal (31/2-gland) parathyroidectomy, or a total parathyroidectomy with a heterotopic parathyroid autotransplantation; and (5) if no enlarged parathyroid glands are identified, do not resect a normal parathyroid gland. There is no special preoperative preparation for the patient. Most are admitted to the hospital early on the day of the operation; however, there have been reports of patients having parathyroidectomy on an outpatient basis, with discharge on the same day as the operation.

A. Exploration Most parathyroid glands are found in the usual anatomical positions; some variations in gland location are so frequent as to be considered "normal," and should be investigated in patients in whom a gland is not identified in a more usual site (Fig. 15-1). It is essential that the surgeon have a clear understanding of parathyroid gland embryology. The upper glands are derived from the fourth pharyngeal pouch, while the lower glands are derived from the third pharyngeal pouch. The thymus gland co-migrates with the lower gland; in the lower neck these structures separate so that the lower parathyroid lies close to the lower pole of the thyroid gland, while the thymus resides in the mediastinum. A remnant of the thymus gland can be identified protruding from the thoracic inlet adjacent to the inferior pole of the thyroid gland. The search for the lower parathyroid should begin in the thyrothymic ligament, since the parathyroid gland is usually close to, or within, it. The thyrothymic ligament is usually well formed, and appears as a cylindrical grayish structure below the thyroid lobe. In some people, the thymus gland may descend only a short distance, or not at all, during embryogenesis. If the associated parathyroid gland also fails to migrate, it will reside high in the neck as an "undescended para-

470

GERARD M. DOHERTY AND SAMUEL A. WELLS, JR.

FIGURE 15-- 1 Illustration of frequent ectopic locations of parathyroid tissue. (From Wells SA Jr, Leight GS, Ross AJ: Primary hyperparathyroidism. Curr Prob Surg 17:400-463, 1980.)

thymus." There can be varying stages of maldescent, and the surgeons must be aware of this, if the lower parathyroid gland cannot be found in its expected position. The most common sites of an ectopic lower parathyroid gland are either high in the neck, in the lateral neck associated with thymus tissue, or in the anterior mediastinum in association with the thymus gland. Also, as lower parathyroid glands increase in size, they may be pulled into the upper anterior mediastinum by negative intrathoracic pressure. Parathyroid glands within the mediastinum can frequently be removed by mobilizing the thymus through the cervical incision. Embryologically, the upper glands migrate with the lateral thyroid complex for only a short distance. Upper glands are more constant and posterior in location than the lower glands but can still present anywhere from the retropharyngeal area, to the carotid sheath or the posterior mediastinum. One common "acquired ectopic" position that occurs with enlarged upper parathyroid glands is along the esophagus reaching inferiorly into the mediastinum. These glands usually are tethered at the upper end, near the crossing of the inferior thyroid artery and the recurrent laryngeal nerve. With dissection of the local structures, the parathyroid can be separated from its usual location, slide inferiorly, and be missed. If exploration of these areas is unsuccessful in identifying a missing parathyroid gland, the thyroid lobe on the side

of the missing gland should be mobilized and palpated. Intraoperative ultrasound examination may be useful to identify an intrathyroidal parathyroid gland, or a gland in another ectopic location within the soft tissues of the neck. As a last resort, blind excision of the ipsilateral thyroid lobe is advocated by some surgeons. In patients with multinodular goiter, the upper parathyroid is prone to become enfolded within the thyroid parenchyma, where it may be difficult to identify. These anatomical landmarks are utilized to carefully explore each side of the neck, with the goal of identifying all four parathyroid glands in every patient. Although in the past some surgeons have advocated unilateral exploration if a single enlarged parathyroid gland and a normal parathyroid gland are identified on the first side of the neck explored, most surgeons now agree that all four parathyroid glands need to be identified at the initial exploration because of the possibility of multiplegland disease. 4~ Abnormal parathyroid glands on the contralateral side of the neck will be missed at exploration in about 10% of patients if a unilateral approach is utilized. Although frozen section has not been helpful in differentiating diseased and normal glands, many endocrine surgeons consider it essential for confirming the presence or absence of parathyroid tissue. Small, thin biopsy specimens are sharply incised from each gland with extreme care taken to avoid damaging their delicate

CHAPTER 15 Surgical Treatment for Hyperparathyroidism

471

blood supply. Some surgeons, alternatively, utilize frozen section selectively, to document only the abnormal parathyroid gland. 22 When an enlarged gland is identified, it is removed, trimmed of fat, and weighed. Parathyroid gland weight is the single most valuable datum obtained during the operation. If, after meticulous exploration, three or four parathyroid glands have been identified, none of which is enlarged, the operation should be terminated. Supernumerary glands may be present and should be sought at the initial procedure. This is particularly important in those patients with familial hyperparathyroidism or renal osteodystrophy, since the incidence of supernumery glands is higher. For this reason, the cervically accessible thymic tissue should be removed in these patients.

B. E x t e n t o f R e s e c t i o n The operative procedure performed is based on the number of enlarged glands identified (Table 15-3). In many instances, the pathologist cannot reliably distinguish a parathyroid adenoma from parathyroid hyperplasia on frozen section. If the surgeon determines that a parathyroid gland is enlarged, then it should be resected. Typically, single-gland disease has been treated by simple excision, whereas any combination of two- or threegland enlargement is treated by resection of the diseased tissue with the normal glands left in place. The question of whether two- or three-gland enlargement implies the presence of disease in all glands (hyperplasia) has not

TABLE 15--3 Author/Site Satava et al./Mayo Cliniclz Ronni-Sivula and Sivula/ H e l s i n k i 13

Rudberg et a l . / S w e d e n 14 Kristoffersson et al./Swedenis Roka et al./Vienna16 Wendt and Geipel/Berlin17 Hedback et al./SwedenTM Ud6n et al./San Francisco~ Kairaluoma et al./Finland2~ Doherty et al./St. L o u i s 21 Oertli et al./Basel, Switzerland22 Chigot et a l . / P a r i s 23

been resolved. If one gland is large and the remaining three are normal in size, resection of the single parathyroid cures virtually all patients. Patients with two- or three-gland disease should be managed by excising only the large glands. The incidence of persistent or recurrent hypercalcemia in these patients is 1 0 . 5 % . 41 The management of patients with four-gland disease is more difficult. In many of these patients, the disease occurs as a component of one of the familial syndromes, particularly MEN-I. Patients with four-gland parathyroid hyperplasia can be managed by subtotal parathyroidectomy (removing 31/2 glands) or by total parathyroidectomy with autotransplantation of some parathyroid tissue into the nondominant forearm. Both operations depend on meticulous identification of all parathyroid tissue. The putative advantage of the subtotal parathyroidectomy is that it leaves the remaining parathyroid tissue with its native blood supply. Total parathyroidectomy has the advantage of removing all abnormal parathyroid tissue from the neck and placing it in a site where reoperation for recurrent hyperparathyroidism would be simpler. In either operation, parathyroid tissue should be viably cryopreserved to allow later autografting if the patient has persistent hypoparathyroidism postoperatively. Subtotal parathyroidectomy for nonfamilial parathyroid hyperplasia has a reported incidence of recurrent hypercalcemia of 0% to 16%; the incidence of permanent hypoparathyroidism is 4% to 5%. Patients with MEN-I, however, have a recurrence rate of 26% to 36% with long term follow-up after subtotal parathyroidectomy (average time to recurrence > 5 years). Total parathyroidectomy has a similar risk of permanent hypo-

Pathology at Operation for Primary Hyperthyroidism Two- or Three-Gland Diseasea

Hyperplasia or Four-Gland Disease

Years

N

Adenoma

1970-72

327

84.7%

NR

9.2%

1956-79 1956-79 1961-83 1963-84 1980-88 1953-82 1980-90 1982-89 1992-93 1977-92 1978-92

289 441 311 186 59 896 250 92 39 170 78

84.1% 77% 80% 82.8% 74.5% 84.0% 78.4% 63% 76.9% 82.1% 94.9%

NR NR NR 11.3% 15.3% NR 6% 2.2% 2.6% NR 3.8%

15.2% 18% 15% 2.2% 1.7% 15.7% 14% 31.5% 20.5% 14.5% 1.3%

aSome authors report two- or three-gland enlargement separately from four-gland disease; this is noted where recorded. NR, not reported.

Carcinoma 0% 0.7% 0 0.3% 3.2% 1.7% 0.2% O% O% O% 3.5% O%

472

GERARDM. DOHERTYAND SAMUELA. WELLS,JR.

parathyroidism (5%) and a higher reported risk of recurrent hypercalcemia (familial, 64%; nonfamilial, 20%). Reoperation for recurrent hypercalcemia is greatly simplified by total parathyroidectomy with autotransplantation approach. Thus, given the currently available data, sporadic parathyroid hyperplasia can be acceptably treated by either operation. However, the substantial risk of recurrent hypercalcemia following either operation makes total parathyroidectomy with autotransplantation an attractive option for patients with familial disease. To attempt to definitively answer this question for patients with familial hyperparathyroidism, our group has recently begun a randomized prospective clinical trial of subtotal parathyroidectomy versus total parathyroidectomy with autograft. n

IV. PRIMARY HYPERPARATHYROIDISM: MANAGEMENT OF PATIENTS WITH PERSISTENT OR RECURRENT HYPERPARATHYROIDISM Patients with unsuccessful neck explorations almost always have either persistent or recurrent hypercalcemia. Persistent hyperparathyroidism pertains to patients who either have continued unabated hypercalcemia in the immediate postoperative period, or develop it within 6 months of the neck exploration. Recurrent hypercalcemia describes patients who are normocalcemic for 6 months after neck exploration before they develop an elevated blood calcium level. More often, persistent rather than recurrent hypercalcemia is the mode of presentation in patients who have unsuccessful neck explorations for hyperparathyroidism. Inadequately excised hyperplastic tissue is a common cause of both persistent and recurrent disease. Less common is the late local recurrence of adenoma or carcinoma as a result of tissue spilled from a broken gland that implanted at the time of initial operation. In most cases, review of the original operative notes and pathology report provides clues as to the position of residual tissue and the nature of the recurrence. 42 The location of parathyroids responsible for failed operations due to missed single adenoma found on reexploration in one large series is shown in Figure 15-2. Patients should have a clear indication for surgical management of their disease before reexploration. These can include serum level of calcium greater than 11.5 mg/dl, or complications of hypercalcemia, such as renal stones or osteopenia. Reexploration of asymptomatic patients with mild hypercalcemia is generally considered

%

1. Tracheo-esophageal groove

n=59 (27%)

2. Anterior mediastinum/thymus

n=38 (18%)

3. Normal upper

n=28 (13%)

4. Normal lower

-n=26 (12%)

5. Intrathyroid

n=22 (10%)

6. Undescended

n=18 (8.4%)

7. Carotid sheath

n=8

(3.7%)

8. Retroesophageal

n=7

(3.3%)

9. Other mediastinal

n=3

(1.4%)

10. Strap muscles

n=3

(1.4%)

11. Other

n=3

(1.4%)

FIGURE 1 5 - - 2 Sites of parathyroid resection in patients with persistent hyperparathyroidism due to missed parathyroid adenoma. [From Jaskowiak N, Fraker DL, Alexander HR, et al: A prospective trial evaluating a standard approach to reoperation for missed parathyroid adenoma. Ann Surg 224:308-320, 1996.]

unwise because the increased risk associated with the reoperation is thought to outweigh the potential benefits.

A. Localization In contrast to patients having their first operation for hyperparathyroidism, most surgeons agree that localization studies should be performed prior to reexploration. A combination of noninvasive studies should be utilized initially. If these are unsuccessful in demonstrating an abnormality, invasive studies (selective angiography and venous sampling for parathyroid hormone) are indicated. There are several noninvasive techniques for localizing hyperfunctioning parathyroid tissue. Barium swallow, cineesophagography, and thyroid scanning are

CHAPTER 15

473

Surgical Treatment for Hyperparathyroidism

rarely helpful, whereas c o m p u t e d tomographic (CT) scans, magnetic resonance imaging (MRI), technetiumthallium subtraction scanning, 99mTc-sestamibi scanning, and high-resolution real-time ultrasonography are variably useful in identifying enlarged parathyroid glands in patients studied (Table 1 5 - 4 ) . Sestamibi scanning is the newest of these techniques, and utilizes a radionuclide imaging agent originally d e v e l o p e d for cardiac imaging (Fig. 1 5 - 3 ) . During these studies, this agent was observed to image parathyroid tissue on delayed scans. Recently, sestamibi has been used for parathyroid imaging. The single-nuclide nature, short half-life, and highenergy profile of this technique provides advantages in lateral, oblique, and three-dimensional imaging compared to technetium-thallium scanning. Sestamibi scans and C T scans are most useful for identifying lesions in the neck and mediastinum. Ultrasound and C T examinations can be coupled with needle aspiration of an identified mass, followed by assay of the aspirate for PTH. Aspirate parathyroid h o r m o n e values that are twice the m e a n b a c k g r o u n d (peripheral venous) levels of parathyroid h o r m o n e indicate the presence of parathyroid tissue. 43 Specific testing algorithms depend on the available facilities and expertise, as the utility of each examination

TABLE 15--4

Ultrasound Sensitivity False-positive Scintigraphy Sensitivity False-positive CTscan Sensitivity False-positive MRIscan Sensitivity False-positive Angiography Sensitivity False-positive Parathyroid venous sampling Sensitivity False-positive Intraoperative ultrasound Sensitivity False-positive

will vary with the skill and e q u i p m e n t of the invasive radiologist. A typical strategy w o u l d be to obtain two initial c o m p l e m e n t a r y studies, such as ultrasound and sestamibi scanning. If these each demonstrate the same abnormality consistent with parathyroid tissue, no other studies are p e r f o r m e d and the patient is explored. If either study is negative or if one is contradictory of the other, additional tests are p e r f o r m e d to evaluate the area of concern. If no two noninvasive imaging tests provide reliable, confirmatory results, then selective arteriography and venous sampling for parathyroid h o r m o n e are employed. 44,4s Selective arteriography (Fig. 1 5 - 4 ) identifies hyperfunctioning parathyroid tissue in m a n y cases (Table 1 5 - 4 ) . Venous sampling may also be helpful in some patients, although interpretation is often complicated by the d e v e l o p m e n t of collateral venous drainage postoperatively. B e c a u s e selective venous sampling with P T H determination provides no direct image, but only lateralizes the side of the neck where the hyperfunctioning tissue is located, it m a y only help to direct the exploration to one or the other side of the neck. In a series from the National Institutes of Health, invasive studies identified the abnormal parathyroid gland in 41 of 43 patients w h o had negative or equivocal noninvasive

Parathyroid Localization Studies for Persistent or Recurrent H y p e r p a r a t h y r o i d i s m Miller et al. (1987) NIH44'57

Cheung et al. (1989) University of Michigan s8

Levin et al. (1987) UCSF45

n = 50 36.0% 14.0% n 34a 26.5% 5.95 % n=51 47.1% 2.0% n = 16 50% NR n = 43 60.4% 4.7% n = 30 80.0% 0 n = 18 77.7% 0

n = 17 23.5% 5.9% n 9a 55.6% 11.1% n = 15 26.7% 20.0% m

n = 41 58% 13% n = 39a 49% 23 % n=41 46% 15% n = 17 65% 18%

=

aTechnetium-thallium subtraction scanning. b 99 mTc-sestamibi-123 I imaging. NR, not reported.

=

n=9 22.2% 11.1% n = 23 39.1% 26.1% --

n = 28 71% 0

Weber et al. (1993) Emory University 59

n = 14~ 85.7% NR

Thompson et al. (1994) Mayo Clinic 6~ n = 39 43.6% 10.3% n = 45b/15a 62%/60% 2.2%/6.7% n=10 20% 0 n=3 0 0

474

GERARD M. DOHERTYAND SAMUELA. WELLS, JR. abnormal parathyroid tissue localized preoperatively. A direct approach to the localized disease should be used. If the disease is identified on one side of the neck, the opposite side is not typically explored, to avoid injury to the remaining parathyroids or the recurrent laryngeal nerve. The side of the neck that is explored should be fully investigated, to avoid any need for a third dissection in that area in the future. Intraoperative ultrasound is a useful adjunct during reoperative neck exploration (Fig. 1 5 - 5). 46,47

Surgical reexploration can be difficult. The goal of the reoperation should be to identify and remove the

If the disease has been localized in the anterior superior mediastinum, the neck should almost always be reexplored first. If the thymic remnant has not already been removed, it should be excised at this time. If the parathyroid tissue is not included in this tissue, or if scar tissue makes the exposure difficult, successful transcervical mediastinal exploration is sometimes possible using the Cooper thymectomy retractor, which permits more extensive mediastinal exploration and thymectomy through a cervical incision. 48 Any remaining thymic tissue is first isolated and examined; other adjacent tissues in the anterior mediastinum can be dissected as well. Median stemotomy and exploration is necessary in only 1% to 2% of patients with primary hyperparathyroidism. Usually, a vertical incision is made from the center of the cervical incision to the xiphoid. With this incision, there is excellent exposure of the mediastinum. Functional tests to prospectively detect the removal of abnormal parathyroid tissue while still in the operating room have been used on a limited basis. Urinary levels of cyclic adenosine monophosphate (cAMP) can be measured, and reflect circulating parathyroid hormone

FIGURE 15--4 Angiogramdemonstrating a recurrent parathyroid adenoma (arrow) in the aortopulmonary window supplied by a branch of the internal thoracic artery. Note the surgical clips from previous resection of adenomatous parathyroid tissue in this area.

FIGURE 15--5 Intraoperativeultrasound demonstrating a hypoechoic intrathyroidal parathyroid adenoma (arrow).

FIGURE 1 5 - 3 99mTC-sestamibi scan identifying parathyroid tissue in the right lower position in a patient with hyperparathyroidism (arrow). Symmetrical uptake higher in the neck represents submandibular glands.

studies. 44 Importantly, false-positive results, which could lead to fruitless exploration, were uncommon. These studies, while very accurate in centers with demonstrated expertise, also have potentially significant risks, such as transverse myelitis, cerebrovascular accident, and death.

B. Reoperation

CHAPTER 15 SurgicalTreatment for Hyperparathyroidism levels. This test has been used in the reoperative parathyroidectomy setting, but does not appear to add substantially to the intraoperative judgment of the experienced surgeon. 49'5~ More recently, some investigators have begun using rapid determinations of serum levels of parathyroid hormone intraoperatively in an attempt to detect when all of the abnormal parathyroid tissue has been removed. The utility of the approach remains to be demonstrated. Surgical reexploration is successful in experienced hands in more than 80% of cases; however, there is an increased incidence of postoperative complications. Unilateral recurrent laryngeal nerve injury occurs in 5% to 10% of patients and permanent hypoparathyroidism occurs in 10% to 20% of patients. Cryopreservation of excised parathyroid tissue is a mandatory component of the management of these patients, as it allows later autotransplantation if the patient becomes hypoparathyroid postoperatively. The risks of these complications are clearly outweighed by the clinical improvement in patients with advanced disease. Rarely, patients with symptomatic persistent hyperparathyroidism are not operative candidates because of concurrent illnesses; these patients may be considered for nonoperative angiographic parathyroid ablation if an enlarged parathyroid gland is identified. 51

V. O P E R A T I V E M A N A G E M E N T OF PATIENTS WITH PARATHYROID CARCINOMA Parathyroid carcinoma is a rare condition, accounting for less than 1% of all cases of hyperparathyroidism (Table 15-3). This diagnosis should be suspected when (1) a palpable neck mass is present; (2) the serum calcium level exceeds 14 mg/dL; (3) the serum PTH level is markedly elevated; and (4) a previously unoperated patient is hoarse from a recurrent laryngeal nerve invasion. 52 Compared with patients with benign disease, these patients tend to be younger and to have more symptoms. In contrast with the marked female predominance in benign disease, the male/female ratio in carcinoma is equal. Patients may have manifestations of both renal disease and bone disease. The affected gland is palpable in almost half of patients. At operation, the parathyroid carcinoma appears white and very firm, unlike adenomas, which are reddish brown and soft. It may be difficult to distinguish early parathyroid carcinoma from atypical parathyroid adenoma by histological and clinical criteria: the diagnosis is securely made only on the basis of local invasion or distant metastases. In these cases, DNA cytometry can be helpful as an aneuploid

475 pattern and higher nuclear DNA content are typical of carcinomas compared to adenomas. 53 The initial operation must be aggressive, yet meticulous, with e n b l o c resection of the parathyroid tumor and all adjacent invaded tissues, including the ipsilateral thyroid lobe. It is very important not to rupture the capsule and spill the tumor. Radical neck dissection is reserved for patients with clinically overt cervical node metastases. Neither chemotherapy nor radiation therapy have been shown to be of any benefit to patients with parathyroid carcinoma. Tumor recurrence is generally apparent within 6 months to 3 years of operation and may denote an incurable process. If the disease recurs, an attempt should be made to resect it because, if untreated, these patients usually succumb to uncontrolled hypercalcemia. The long-term prognosis is poor, and the opportunity for survival depends on complete initial resection. 54,55

VI. O P E R A T I V E M A N A G E M E N T OF PATIENTS WITH RENAL OSTEODYSTROPHY The indications for parathyroidectomy in patients with renal osteodystrophy (secondary hyperparathyroidism) are: (1) persistent and symptomatic hypercalcemia in prospective renal transplant patients; (2) bone pain or pathological fractures; (3) ectopic calcification; and (4) intractable itching. These patients can be managed by subtotal (31/2-gland) parathyroidectomy or total parathyroidectomy with heterotopic (forearm) autotransplantation. As in other forms of hyperplasia, reexploration for recurrent hyperparathyroidism is simplified by autotransplantation to the nondominant forearm. A randomized, prospective trial has been reported for patients with secondary hyperparathyroidism, comparing subtotal parathyroidectomy to total parathyroidectomy with autotransplantation (Fig. 15-6). 56 Of patients randomized to subtotal parathyroidectomy, 20% developed hypercalcemia and indications for reoperation within 40 months after the initial procedure. Because of improved clinical parameters (less pruritus and muscle weakness), improved radiological parameters, and the need for no reoperations, the total parathyroidectomy with autotransplantation is the procedure of choice.

VII. POSTOPERATIVE

MANAGEMENT

The postoperative recovery of patients after parathyroidectomy is generally uncomplicated, typically requiring a one- or two-night stay in the hospital. Cervical

476

GERARD M. DOHERTYAND SAMUELA. WELLS, JR. Patients with Chronic Renal Failure and Renal Osteodystrophy

.11

PANIX~tT'E

Subtotal Parathyroidectomy (n=20)

~

Total Parathyroidectomy + autotransplantation (n=20)

wo,, I

2 patients hypercalcemic but not yet reoperated

3 Dead

I

17 Well

3 1/2 year follow-up

FIGURE 15--6 Diagramof a randomized trial of parathyroidectomytechniques in patients with renal osteodystrophy (From Rothmund M, Wagner PK, Schark C: Subtotal parathyroidectomy versus total parathyroidectomy and autotransplantation in secondary hyperparathyroidism: A randomized trial. World J Surg 15:745-750, 1991.) Patients with conventional indications for parathyroidectomy in renal failure were randomized to total or subtotal resection. After 3.5 years, patients in the total parathyroidectomy/autotransplantationgroup were more likely to have normal serum calcium and alkaline phosphatase concentrations (p < 0.05), to have radiological improvement, and to have clinical improvement (pruritis and weakness, p < 0.05), than patients in the subtotal parathyroidectomy group. In addition, there were no patients who required, or who had indications for, reoperation in the total parathyroidectomy/autotransplantationgroup.

incisions heal well, and infectious complications are rare. However, the postoperative management of patients after parathyroidectomy requires consideration of some specific issues.

A. Airway Protection Any patient who has had operation on both sides of the neck, with exposure of the recurrent laryngeal nerves, is at risk for temporary or permanent, unilateral or bilateral, vocal cord paresis. This rare complication must nevertheless be considered at the completion of the operative procedure, as the patient emerges from general anesthesia and the endotracheal tube is removed. Unilateral vocal cord paresis affects phonation, but does not usually endanger ventilation or oxygenation. Patients with bilateral cord paresis may initially ventilate adequately through a patent anterior glottic chink, and may have nearly normal phonation, but may subsequently have decreased ventilatory capacity due to further edema or fatigue. Careful attention to the early postoperative airway is vital to avoid devastating complications.

B. Calcium Replacement After removal of hyperfunctioning parathyroid tissue with normal, vascularized parathyroid tissue left in situ, most patients become transiently hypocalcemic, and many require temporary oral calcium replacement be-

cause of serum calcium levels below 7.0 mg/dl, or symptoms of hypocalcemia. Typically, oral calcium is delivered as calcium gluconate 500 mg, two to four doses daily. Occasional patients will require oral vitamin D as well. The need for calcium and/or vitamin D replacement appears to correlate with the extent of preoperative bone disease. The nadir of the serum calcium concentration is typically reached within 48 to 72 hours after operation. Patients who become severely hypocalcemic with marked symptoms, and those who are unable to take the medications orally because of concomitant medical illness, will require intravenous calcium supplementation. Calcium gluconate (10% solution available as ampules containing 90 mg elemental calcium/10 ml) can be administered intravenously emergently over 10 minutes. Intravenous infusion supplementation is then begun as 60 ml (6 ampules) of 10% calcium gluconate in 500 ml of D5W (1 mg/ml elemental calcium) at 0.5 to 2.0 mg/kg/hr. The serum calcium concentration should be monitored periodically and the infusion adjusted appropriately. Patients who have total parathyroidectomy and autotransplantation will develop significant hypocalcemia, and should be started on oral calcium and vitamin D replacement immediately after operation in order to avoid severe hypocalcemia. Replacement should be adjusted to maintain the serum calcium concentration at the lower limit of normal. The parathyroid autografts typically perform adequately within 8 to 12 weeks. Autograft function is documented by comparing the parathyroid hormone levels in serum samples drawn from

CHAPTER 15

477

Surgical Treatment for Hyperparathyroidism

each antecubital fossa, above the parathyroid autograft. If there is a gradient between the arms, but the patient remains hypocalcemic, supplementation should be continued a n d m o r e t i m e a l l o w e d f o r t h e a u t o g r a f t to b e s t i m u l a t e d to p r o d u c e a d e q u a t e h o r m o n e . I f t h e r e is n o g r a d i e n t , t h e n it is l i k e l y t h a t t h e p a r a t h y r o i d g r a f t v e n o u s e f f l u e n t is d r a i n e d t h r o u g h a r o u t e o t h e r t h a n t h e a n t e c u b i t a l vein. Patients with renal osteodystrophy, and those rare patients w i t h v i t a m i n D r e s i s t a n t t i c k e t s , m a y h a v e v e r y marked

hypocalcemia

after

total

parathyroidectomy,

probably because of the severity of the b o n e disease. T h i s is c o m p o u n d e d

in t h e p a t i e n t s w i t h v i t a m i n D re-

s i s t a n c e b y t h e difficulty in m a i n t a i n i n g

a d e q u a t e re-

p l a c e m e n t u s i n g t h e g a s t r O i n t e s t i n a l tract. T h e s e difficulties

should

be

anticipated

and

treated

by

more

v i g o r o u s , a n d early, r e p l a c e m e n t o f c a l c i u m .

References 1. Sandstrom, I: On a new gland in man and several mammals (gladulae parathyroideae). Upsala Lak Foren Forh 15:441, 1879. 2. Gley E: Sur les fonctions du corps thyroide. C R Soc Biol 43: 841, 1891. 3. Erdheim J: Uber epithelkorperchenbefunde bei osteomalacie. S B Akad Wiss Math Naturw C1 116:311, 1907. 4. Schlagenhaufer F: Zwei failer von parathyreoideatumoren. Wien Klin Wochenschr 28:1362, 1915. 5. Mandl F: Therapeutischer Versuch bei einem Falle von Ostitis fibrosa generalisata mittels exstirpation eines epithelk orperchen Tumors. Zentrabl Chir 5:260, 1926. 6. Richardson EP, Aub JC, Bauer W: Parathyroidectomy is oseomalacia. Ann Surg 90:730, 1929. 7. Albright F: A page out of the history of hyperparathyroidism. J Clin Endocrinol Metab 8:637-657, 1948. 8. Barr DP, Bulger HA, Dixon HH: Hyperparathyroidism. JAMA 92:951-952, 1929. 9. Barr DP, Bulger MA: The clinical syndrome of hyperparathyroidism. Ann J Med Sci 179:449, 1930. 10. Thomas CG Jr: Presidential address: The glands of O w e n - - a perspective on the history of hyperparathyroidism. Surgery 108: 939-950, 1990. 11. Udrn P, Chan A, Duh Q-Y, et al: Primary hyperparathyroidism in younger and older patients: Symptoms and outcome of surgery. World J Surg 16:791-798, 1992. 12. Satava RMJ, Beahrs OH, Scholz DA: Success rate of cervical exploration for hyperparathyroidism. Arch Surg 110:625-628, 1975. 13. Ronni-Sivula H, Sivula A: Long-term effect of surgical treatment on the symptoms of primary hyperparathyroidism. Ann Clin Res 17:141-147, 1985. 14. Rudberg C, Akerstrrm G, Palmer M, et al: Late results of operation for primary hyperparathyroidism in 441 patients. Surgery 99:643-651, 1986. 15. Kristoffersson A, Dahlgren K, Granstrand B, Jarhult J: Primary hyperparathyroidism in Northern Sweden. Surg Gynecol Obstet 164:119-123, 1987.

16. Roka R, Niederle B, Kovarik J, et al: Clinical long-term results after parathyroidectomy for primary hyperparathyroidism. Acta Chir Scand 153:513-520, 1987. 17. Wendt F, Geipel D: Clinical aspects of surgery in hyperparathyroidism. Exp Clin Endocrinol 94:163-170, 1989. 18. Hedback G, Tisell L-E, Bengtsson B-A, et al: Premature death in patients operated on for primary hyperparathyroidism. World J Surg 14:829-836, 1990. 19. Bonjer HJ, Bruining HA, Birkenhager JC, et al: Single and multigland disease in primary hyperparathyroidism: Clinical followup, histopathology, and flow cytometric DNA analysis. World J Surg 16:737-744, 1992. 20. Kairaluoma MV, Makarainen H, Kellosalo J, et al: Results of surgery in primary hyperparathyroidism. Ann Chir Gynaecol 81: 309-315, 1992. 21. Doherty GM, Weber B, Norton J: Cost of unsuccessful surgery for primary hyperparathyroidism. Surgery 116:954- 958, 1994. 22. Oertli D, Richter M, Kraenzlin M, et al: Parathyroidectomy in primary hyperparathyroidism: Preoperative localization and routine biopsy of unaltered glands are not necessary. Surgery 117: 392-396, 1995. 23. Chigot J-P, Menegaux F, Achrafi H: Should primary hyperparathyroidism be treated surgically in elderly patients older than 75 years? Surgery 117:397-401, 1995. 24. Wells SA Jr: Surgical therapy of patients with primary hyperparathyroidism: Long-term benefits. J Bone Miner Res 6:S143S149, 1991. 25. Kenny AM, MacGillivray DC, Pilbeam CC, et al: Fracture incidence in postmenopausal women with primary hyperparathyroidism. Surgery 118:109-114, 1995. 26. Kochersberger G, Buckley NJ, Leight GS, et al: What is the clinical significance of bone loss in primary hyperparathyroidism? Arch Intern Med 147:1951, 1987. 27. Hedback G, Oden A, Tisell L-E: The influence of surgery on the risk of death in patients with primary hyperparathyroidism. World J Surg 15:399-407, 1991. 28. Palmer M, Bergstrom R, Akerstrom G, et al: Survival and renal function in untreated hypercalcaemia. Lancet 1:59-62, 1987. 29. Palmer M, Adami H-O, Bergstrom R, et al: Mortality after surgery for primary hyperparathyroidism: A follow-up of 441 patients operated on from 1956 to 1979. Surgery 102:1-7, 1987. 30. Potts JT Jr, Ackerman IP, Barker CF, et al: Diagnosis and management of asymptomatic primary hyperparathyroidism: Consensus development conference statement. Ann Intern Med 114: 593-597, 1991. 31. Marx SJ, Menczel J, Campbell G, et al: Heterogeneous size of the parathyroid glands in familial multiple endocrine neoplasia type 1. Clin Endocrinol 35:521-526, 1991. 32. Pollak MR, Brown EM, Chou Y-HW, et al: Mutations in the human Ca-sensing receptor gene cause familial hypocalciuric hypercalcemia and neonatal severe hyperparathyroidism. Cell 75:1297-1303, 1993. 33. Key LL, Thorne M, Pitzer B, et al: Management of neonatal hyperparathyroidism with parathyroidectomy and autotransplantation. J Pediatr 116:923- 926, 1990. 34. Pollak MR, Chou Y-HW, Marx SJ, et al: Familial hypocalciuric hypercalcemia and neonatal severe hyperparathyroidism: Effects of mutant gene dosage on phenotype. J Clin Invest 93:11081112, 1994. 34a. Chandrasekharappa SC, Guru SC, Manickam P, et al: Positional cloning of the gene for multiple endocrine neoplasia-type 1. Science 276:404-408, 1997. 35. Mulligan LM, Kwok JBJ, Healey CS, et al: Germ-line mutation of the RET proto-oncogene in multiple endocrine neoplasia type 2A. Nature 363:458-460, 1993.

478 36. Donis-Keller H, Dou S, Chi D, et al: Mutations in the RET proto-oncogene are associated with MEN 2A and FMTC. Hum Mol Genet 2(7):851-856, 1993. 37. Cohen J, Gierlowski TC, Schneider AB: A prospective study of hyperparathyroidism in individuals exposed to radiation in childhood. JAMA 264:581-584, 1990. 38. Christensson T: Hyperparathyroidism and radiation therapy. Ann Intern Med 89:216, 1978. 39. Tezelman S, Rodriguez JM, Shen W, et al: Primary hyperparathyroidism in patients who have received radiation therapy and in patients who have not received radiation therapy. J Am Coil Surg 180:81-87, 1995. 40. Duh Q-Y, Uden P, Clark OH: Unilateral neck exploration for primary hyperparathyroidism: Analysis of a controversy using a mathematical model. World J Surg 16:654-662, 1992. 41. Wells SA, Leight GS, Hensley M, Dilley WG: Hyperparathyroidism associated with the enlargement of two or three parathyroid glands. Ann Surg 202:533-538, 1985. 42. Levin KE, Clark OH: The reasons for failure in parathyroid operations. Arch Surg 124:911 - 915, 1989. 43. Macfarlane MP, Fraker DL, Shawker TH, et al: Use of preoperative fine-needle aspiration in patients undergoing reoperation for primary hyperparathyroidism. Surgery 116:959-965, 1994. 44. Miller DL, Doppman JL, Krudy AG, et al: Localization of parathyroid adenomas in patients who have undergone surgery. Part II. Invasive procedures. Radiology 162:138-141, 1987. 45. Levin KE, Gooding GAW, Okerlund M, et al: Localizing studies in patients with persistent or recurrent hyperparathyroidism. Surgery 102:917-925, 1987. 46. Kern KA, Shawker TH, Doppman JL, et al: The use of highresolution ultrasound to locate parathyroid tumors during reoperations for primary hyperparathyroidism. World J Surg 11: 579-585, 1987. 47. Norton JA, Shawker TH, Jones BL, et al: Intraoperative ultrasound and reoperative parathyroid surgery: An initial evaluation. World J Surg 10:631-639, 1986. 48. Wells SA, Cooper JD: Closed mediastinal exploration in patients with persistent hyperparathyroidism. Ann Surg 214:555-561, 1991.

GERARD M. DOHERTY AND SAMUEL A. WELLS, JR. 49. Darling GE, Marx SJ, Spiegel AM, et al: Prospective analysis of intraoperative and postoperative urinary cyclic adenosine 3',5'-monophosphate levels to predict outcome of patients undergoing reoperations for primary hyperparathyroidism. Surgery 104:1128-1136, 1988. 50. Norton JA, Brennan MF, Saxe AW, et al: Intraoperative urinary cyclic adenosine monophosphate as a guide to successful reoperative parathyroidectomy. Ann Surg 200:389-395, 1984. 51. Doherty GM, Doppman JL, Miller DL, et al: Results of a multidisciplinary strategy for management of mediastinal parathyroid adenoma as a cause of persistent primary hyperparathyroidism. Ann Surg 215:101 - 106, 1992. 52. Fujimoto Y, Obara T: How to recognize and treat parathyroid carcinoma. Surg Clin North Am 67:343, 1987. 53. Levin KE, Chew KL, Ljung B-M, et al: Deoxyribonucleic acid cytometry helps identify parathyroid carcinomas. J Clin Endocrinol Metab 67:779-784, 1994. 54. Wang C, Gaz RD: Natural history of parathyroid carcinoma. Diagnosis, treatment, and results. Am J Surg 149:522-527, 1985. 55. Fraker DL, Travis WD, Merendino JJJ, et al: Locally recurrent parathyroid neoplasms as a cause for recurrent and persistent primary hyperparathyroidism. Ann Surg 213:58-65, 1991. 56. Rothmund M, Wagner PK, Schark C: Subtotal parathyroidectomy versus total parathyroidectomy and autotransplantation in secondary hyperparathyroidism: A randomized trial. World J Surg 15:745-750, 1991. 57. Miller DL, Doppman JL, Shawker TH, et al: Localization of parathyroid adenomas in patients who have undergone surgery. Part I. Noninvasive imaging methods. Radiology 162:133-137, 1987. 58. Cheung PSY, Borgstrom A, Thompson NW: Strategy in reoperative surgery for hyperparathyroidism. Arch Surg 124:676-680, 1989. 59. Weber CJ, Vansant J, Alazraki N, et al: Value of technetium 99m sestamibi iodine 123 imaging in reoperative parathyroid surgery. Surgery 114:1011-1018, 1993. 60. Thompson GB, Mullan BE Grant CS, et al: Parathyroid imaging with technetium-99m-setsamibi: An initial institutional experience. Surgery 116:966-973, 1994.

7HAPTER 1 (

Familial Benign Hypocalciuric Hypercalcemia and Other Syndromes of Altered Responsiveness to Extracellular Calcium EDWARD M. BROWN,*

MEI BAI,* AND MARTIN POLLAKt

*Endocrine-Hypertension and #Renal Divisions, Department of Medicine, Brigham and Women's Hospital, and Harvard Medical School, Boston, Massachusetts 02115

I. Introduction II. Syndromes of Extracellular Calcium Resistance III. Autosomal Dominant Hypocalcemia--A Syndrome of Increased Responsiveness of Target Tissues to Cao2+

IV. Summary and Conclusions Acknowledgments References

the disorders but also the normal functions of the genes in question. Pioneering clinical investigators, in some cases working many years before the advent of molecular techniques, were remarkably astute in outlining a conceptual framework for understanding abnormalities in the interactions of hormones with their respective receptors. For example, Fuller Albright more than 50 years ago recognized that certain endocrine disorders result from target tissue resistance to hormones, such as the

I. I N T R O D U C T I O N The application of molecular techniques has greatly expanded our understanding of how cells communicate with one another. Endocrine diseases have proven to be a rich source of abnormalities in the mechanisms governing intercellular communication. Elucidation of the molecular details of these diseases, in turn, has frequently clarified not only the pathophysiology of METABOLIC BONE DISEASE

479


480 resistance to the actions of parathyroid hormone (PTH) in pseudohypoparathyroidism. ~ Subsequent work showed Albright's prescience by documenting that pseudohypoparathyroidism is associated with inactivating mutations in the guanine nucleotide binding (G) protein (Gs) through which the PTH receptor activates one of its principal intracellular signaling pathways, the adenylate cyclase-cyclic adenosine monophosphate (cAMP) system. 2 Conversely, activating mutations of Gs cause the peculiar skeletal and skin lesions of another syndrome described by Albright, polyostotic fibrous dysplasia. 3 Additional disorders have been described subsequently that arise from alterations in the biological activities of the cell surface receptors that couple to their intracellular signaling systems via G proteins. These receptors are members of the superfamily of G proteincoupled receptors (GPCRs) that share a common overall structure comprising an extracellular amino-terminus of widely varying size, seven hydrophobic membranespanning helices, and a cytoplasmic carboxyl-terminus. This superfamily includes several hundred or more members and encompasses receptors for a wide variety of extracellular first messengers, including numerous peptide hormones (e.g., PTH and calcitonin), neurotransmitters (e.g., biogenic amines), and prostaglandins as well as environmental stimuli such as photons (i.e., rhodopsin) and even odorants. 4-6 Inactivating mutations of GPCRs cause syndromes of hormonal resistance, while activating mutations produce inappropriate stimulation of the second messenger and other effector pathway(s) regulated by that receptor. 7'8 For example, inactivating mutations in the adrenocorticotropic hormone (ACTH) receptor produce adrenal insufficiency, 9 while activating mutations in the luteinizing hormone (LH) or PTH receptors cause precocious puberty 1~ and Jansen's syndrome, ~ respectively. The latter is a hypercalcemic disorder with biochemical abnormalities resembling primary hyperparathyroidism despite normal or suppressed PTH levels because of constitutive activation of the common receptor for PTH and the PTH-related peptide (PTHrP). Recent studies on the hormonal control of mineral ion homeostasis have considerably expanded our understanding of the mechanisms through which the extracellular calcium concentration (Ca 2+) is regulated. 12 This body of knowledge, in turn, has enabled elucidation of the molecular basis for several previously poorly understood hyper- and hypocalcemic syndromes whose clinical features had suggested reduced or increased responsiveness, respectively, to Ca 2+. This chapter will describe three such disorders: familial benign hypocalciuric hypercalcemia (FBHH), ~3 neonatal severe hyperparathyroidism (NSHPT), 14 and a form of autosomal dominant hypocalcemia (ADH). 15 In many but not all

EDWARD M. BROWN, MEI BAI, AND MARTIN POLLACK

cases, these disorders are caused by mutations in a recently cloned extracellular Ca 2+-sensing receptor (CAR), 16 which is a central mediator of the direct actions of Ca 2+ on parathyroid and C-cells as well as on a variety of additional cell types within the kidneys, brain, and other tissues. ~2 Thus, as with other endocrine disorders, the evidence gleaned from careful clinical investigation of genetic diseases of Ca2+-sensing provided critical clues that ultimately led to a greater molecular understanding of the normal physiology of this process.

II. SYNDROMES OF E X T R A C E L L U L A R CALCIUM RESISTANCE A. Familial Benign

Hypocalciuric Hypercalcemia 1. CLINICAL AND BIOCHEMICAL FEATURES OF FBHH In 1972, Foley et al. called attention to the remarkably benign clinical features of a hypercalcemic syndrome that they called familial benign hypercalcemia (FBH). ~7 Although several forms of familial hypercalcemia had been described previously (including a family that was later classified as having FBH18), this report clearly outlined the unique characteristics of patients with this syndrome. Subsequent detailed clinical studies of families with this disorder were carried out by Marx and coworkers 13 as well as by Heath et al. in the late 1970s and 1980S. 19'z~ Marx et al. termed this syndrome "familial hypocalciuric hypercalcemia" because of the characteristic abnormality in renal calcium handling found in affected family members. 21 Although there has never been a consensus as to which of these two names should be used to describe this inherited abnormality in calcium metabolism, we have chosen to call it FBHH in this chapter. FBHH is a rare genetic disorder of mineral ion metabolism that is inherited in an autosomal dominant fashion and is characterized by lifelong, generally asymptomatic hypercalcemia of mild to moderate severity (usually < 12 mg/dl). 2~ Despite their hypercalcemia, affected patients are generally remarkably free of the characteristic symptoms and complications that can afflict other hypercalcemic patients. The latter include most commonly mental disturbances; gastrointestinal abnormalities, particularly anorexia, nausea, and constipation; and renal complications, such as reductions in renal function, defective urinary concentrating ability, and nephrolithiasis or nephrocalcinosis. 22'23 Occasional families exhibit a higher calcium concentration (e.g., 12 to 13 to as high as 14.6 mg/dl in one case13), but affected mem-

CHazrE~ 16 Familial Benign Hypocalciuric Hypercalcemia bers of even these kindreds are generally remarkably free of symptoms. Although nonspecific symptoms encountered in other forms of hypercalcemia, such as fatigue, were reported in some early studies of FBHH, 13 these have not been corroborated in later studies, 2~ perhaps because ascertainment bias attributed symptoms to the disease in probands that were not confirmed in more detailed analyses of entire kindreds. Patients from some kindreds with FBHH have also had pancreatitis and chondrocalcinosis, 13 raising the possibility that these might be true complications of this condition. Pancreatitis, however, does not appear to be present more commonly in affected than in unaffected family members or the general population. Moreover, most patients with FBHH who developed pancreatitis had other known factors predisposing to this complication, such as alcoholism or gallstones. 24 Subsequent studies also have not shown an increased incidence of chondrocalcinosis in FBHH when large numbers of kindreds were examined. 2~ Law and Heath 2~ have described an apparently increased incidence of gallstones in FBHH, but this association has not been emphasized in other clinical series. As far as is known there is no increased incidence of hypertension in FBHH [a complication which does appear to be present with increased frequency in patients with primary hyperparathyroidism (PHPT)22'23], nor is there any documented reduction in the life expectancy of affected members of FBHH families. The degree of hypercalcemia found in patients with FBHH is similar to that seen in those with PHPT of mild to moderate severity. Affected individuals generally have some reduction in serum phosphate concentration, although to a lesser extent than those with PHPT. 13'2~Serum magnesium levels are often in the upper part of the normal range, and mild hypermagnesemia may be present in some cases in contrast to patients with PHPT, whose magnesium concentrations tend to be in the lower half of the normal range. ~]'25 In addition, most patients with FBHH exhibit inappropriately "normal" circulating levels of PTH despite their hypercalcemia, suggesting abnormal regulation of parathyroid function by Ca2+o . 2 4 With the recently developed immunoradiometric assays, which measure predominantly the intact, biologically active form of the hormone, PTH levels in affected 26 27 family members are often midnormal ' and may in some cases be in the lower part of the normal range, although occasional patients may have elevated PTH levels. 2s While most patients with PHPT have frankly elevated circulating levels of intact PTH, it is sometimes difficult to differentiate patients with FBHH from those with mild PHPT, particularly in the 5% to 10% of hyperparathyroid individuals with levels of PTH within the upper part of the normal rangeY Patients with FBHH

48 1 also exhibit abnormal PTH dynamics when administered agents lowering or raising the serum ionized calcium concentration, exhibiting an increase in "set-point" (the level of Ca2o+ half-maximally lowering circulating PTH levels). 28"29 That is, to suppress the PTH level to any given extent, these individuals require a serum calcium concentration slightly higher than that necessary to achieve a comparable degree of reduction in normal subjects. These findings further supported the notion that the parathyroid glands of patients with FBHH have a defect in Cao2+-sensing, 9 exhibiting mild to moderate resistance to the inhibitory effects of extracellular calcium on PTH secretion. A similar defect is present in many patients with PHPT, with only occasional patients having true autonomy of PTH secretion (e.g., PTH secretion that is totally nonsuppressible even with large increases in Cao2+). 3~ Patients with PHPT do tend to have additional defects in secretory control for PTH, however, showing increases in both maximal secretory rates at low levels of Ca 2+o and in the minimal, nonsuppressible secretory rate at high Ca2o+. 29'3~ In FBHH, however, resected parathyroid glands have most commonly exhibited only very mild parathyroid hyperplasia or have been classified as normal. 31'32 Serum levels of 25-hydroxyvitamin D [25(OH)D] and 1,25-dihydroxyvitamin D [1,25(OH)2D] are generally within the normal range in FBHH, 33-35 and intestinal ab-

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Bone mineral densities of the lumber spine ( L 1 - L 4 ) , mid radius, and distal radius in 16 women (shown as triangles) and 15 men (shown as circles) from 14 families with FBHH. The pooled results are shown by the brackets as mean ___ SEM and are shown in comparison to their standard deviations above or below age- and sex-specific mean values. Note that values of - 2 and + 2 show the 95% confidence limits of normal bone mineral density. [From Law WJ, Heath H III: Familial benign hypercalcemia (hypocalciuric hypercalcemia). Clinical and pathogenic studies in 21 families. Ann Intern Med 105:511-519, 1985.]

482


sorption of calcium is normal or slightly reduced. Interestingly, some individuals with FBHH reported by Heath et al. exhibited normal gastrointestinal Ca 2§ absorption and 1,25(OH)2D levels despite being on a low-calcium diet, suggesting a blunted homeostatic response to reduced dietary calcium. 3s The normal levels of 1,25(OH)2D and of intestinal Ca 2§ absorption in FBHH contrast with the frequently elevated levels of these two parameters in PHPT. 23 Although indices of bone turnover, such as urinary hydroxyproline excretion, may be slightly elevated in patients with F B H H , 36'37 bone mineral density is normal (Fig. 16-1) 20,36,38 and there does not appear to be any increase in the risk of fractures or other complications of bone disease. In a recently described kindred from Oklahoma, several family members had radiological evidence of osteomalacia, but this form of bone disease is very uncommon in other FBHH

though occasional families have been described in which some family members have hypercalciuria, 4~ it is currently unclear whether such individuals represent a variant of FBHH or have a coexistent abnormality in renal calcium handling that overrides the hypocalciuric effect of the FBHH gene(s). Of interest, the enhanced renal tubular reabsorption of calcium (but not that of magnesium) persists following induction of hypoparathyroidism by total parathyroidectomy (Fig. 1 6 - 2 B ) . 33'41 This result implies that the abnormal renal handling of calcium is not dependent upon PTH and represents an independent defect in the renal sensing/handling of Ca 2§ One careful study localized the abnormal renal calcium handling to the thick ascending limb of the nephron, 41 while another suggested that it took place in the proximal tubule. 42 Several additional aspects of renal function in individuals with FBHH are also suggestive of altered renal responsiveness to Cao2§ Renal blood flow and glomerular filtration rate, which can each be reduced in hypercalcemic patients, are both normal in FBHH. 13Moreover, patients with this disorder can concentrate their urine normally despite their hypercalcemia, 43 which produces defective maximal urinary concentrating ability in some hypercalcemic patients and overt nephrogenic diabetes insipidus (DI) in a few. 44 Therefore, both the clinical and biochemical features of FBHH suggested that it repre-

k i n d r e d s . 39

A very characteristic feature of FBHH is abnormally avid renal tubular reabsorption of calcium and magnesium despite the hypercalcemia present in these patients (Fig. 16-2A). 19'21 The renal calciurn/creatinine clearance ratio is less than 0.01 in about 80% of patients with FBHH, while it is higher than this in the vast majority of patients with PHPT and markedly so in other hypercalcemic disorders, where PTH is suppressed thereby further reducing renal tubular Ca 2+ reabsorption. A1-

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FIGURE 16--2 Altered renal handling of calcium in patients with FBHH compared to other conditions. A, The urinary calcium to creatinine clearance ratio in patients with FBHH expressed as a function of creatinine clearance relative to the values for patients with typical primary hyperparathyroidism. Note that approximately 80% of patients with FBHH show a clearance ratio of less than 0.01, while only one patient with primary hyperparathyroidism had a value this low. [From Marx SJ, Attie MF, Levine MA, et al: The hypocalciuric or benign variant of familial hypercalcemia: Clinical and biochemical features in fifteen kindreds. Medicine (Baltimore) 60:397-412, 1981.] B, The relationship between serum calcium concentration and urinary calcium excretion in patients with FBHH rendered surgically aparathyroid (closed symbols) compared to those with hypoparathyroidism alone (open symbols). (From Attie M, Gill JJ, Stock J, et al: Urinary calcium excretion in familial hypocalciuric hypercalcemia. J Clin Invest 72:667-676, 1983.)

CHAPTER 16 Familial Benign Hypocalciuric Hypercalcemia sented an inherited defect in the sensing and/or handling of Ca 2§ by parathyroid, kidney, and perhaps other tissues (e.g., there is a lack of the gastrointestinal or mental symptomatology usually associated with hypercalcemia). Prior to the recognition of FBHH as a distinct clinical entity, a number of patients were subjected to partial or total parathyroidectomy in the belief that they had a form of primary parathyroid hyperplasia. Indeed, even following the clinical differentiation of the disorder from primary hyperparathyroidism, patients with FBHH were sometimes confused with those having PHPT. 25 The clinical course of FBHH following attempts at parathyroidectomy was unusual and provided an additional hint that this disorder differed from typical hyperparathyroidism. In those patients undergoing parathyroid surgery, hypercalcemia recurred rapidly (within a few days or weeks) in 21 of 27 patients who underwent from one to four neck explorations; only two were rendered permanently normocalcemic. 24 In contrast, recurrence of hypercalcemia in various forms of primary parathyroid hyperplasia, if it occurs at all, does not take place for several years. Only patients rendered totally aparathyroid avoided recurrence of hypercalcemia (5 of the 27 reported patients described above). Principally because of the benign clinical course of nearly all cases of FBHH, but also because of the difficulty of obtaining a biochemical "cure" (which accomplishes nothing in an asymptomatic patient with FBHH), a consensus has emerged that surgical intervention should be avoided in this condition. 24 2. GENETIC HETEROGENEITY OF FBHH FBHH is inherited as an autosomal dominant disorder, with greater than 90% penetrance. 13'2~ Genetic analysis of four families with FBHH mapped the disease gene to band 3q21-2426 and formally proved that individuals with FBHH represented the heterozygous form of the disorder (e.g., they have one copy of the disease gene). 26 Subsequent studies have confirmed that the great majority of families with FBHH exhibit this same genetic linkage. 45'46 In one family, however, the disorder mapped to chromosome 19, (band 19p13.3),45 confirming the genetic heterogeneity of the clinical syndrome of FBHH. Another kindred from Oklahoma, not linked to either chromosome 3 or 19, has certain atypical features, including osteomalacia in some affected family members as well as a tendency of patients to show progressive increases in serum PTH as they age. 39'47 A severe variety of hyperparathyroidism (NSHPT), which is encountered rarely in newborns from FBHH families, has been shown to represent in a few cases the homozygous form of the disease that is linked to chromosome 3 and will be discussed in detail later (see Section II.B). 46'48

483 3. CLONING AND CHARACTERIZATION OF AN EXTRACELLULAR Ca2+-SENSING RECEPTOR (CAR) An additional line of research directed at understanding the molecular basis of Ca 2§ " o-sensing was being actively pursued during the time that the clinical and biochemical features of FBHH were elucidated. It was recognized that parathyroid cells, calcitonin (CT)secreting C-cells of the thyroid gland, various renal cells, and, indeed, a variety of other cell types respond directly to physiologically relevant changes in Cao2+.49 The mechanism(s) underlying the capacity of various 2+ cells to sense Cao , however, was obscure. The parathyroid cell represents a particularly striking example of 2+ Cao -sensing, responding to even minute (e.g., 2% to 3%) changes in serum ionized calcium concentration with reciprocal, severalfold changes in PTH secretion that restore Ca o2+ to normal by actions on effector tissues (e.g., kidney and bone). 49 A series of studies in the 1980s showed that altering Cao> modulated intracellular second messengers in parathyroid cells in ways that were very similar to those brought about in target tissues by the actions of so-called Cai+-mobilizing hormones on their cell surface, G protein-coupled receptors (e.g., angiotensin II) (for review, see Brown49). For example, elevating Cao2§ produced a transient followed by a sustained increase in the cytosolic Ca 2§ concentration (Ca~)5~ in association with activation of phospholipase C (PLC) 51 and increased turnover of polyphosphoinositides. These data provided indirect evidence for the presence of a CaR on the surface of the parathyroid cell that was coupled to stimulation of PLC. High Cao2+ also evoked a pertussis toxin-sensitive inhibition of adenylate cyclase in bovine parathyroid cells, suggesting that the putative CaR might also be linked to adenylate cyclase in an inhibitory fashion via the inhibitory Gprotein, G~, similar to a number of other GPCRs. 52 Additional tissues respond to Ca2o§ in ways that imply that they too express a similar Cao2+-sensing mechanism. In the kidney, for example, elevating Cao2§ directly inhibits the 1-hydroxylation of 25(OH)D in the proximal tubule 53 in addition to acting indirectly in this regard by reducing PTH secretion (e.g., PTH directly stimulates 1hydroxylation). In addition, in the thick ascending limb (TAL) of Henle's loop, Ca2+o exerts several actions on tubular function of potential relevance to calcium, fluid, and electrolyte metabolism. Elevated levels of C a o2+ inhibit the reabsorption of sodium chloride, 54 which may contribute to the impaired urinary concentrating capacity of some hypercalcemic subjects by reducing the generation of the countercurrent gradient in the renal medulla. 44 Raising the peritubular but not the luminal level of Ca 2+ (or Mg2o+) in perfused segments of the TAL also inhibits the reabsorption of both Ca 2+ and Mg2+, 55 poten-

484 tially providing a mechanism for autoregulating the tubular handling of these ions. There is likewise a pertussis toxin-sensitive inhibition of vasopressin-stimulated cAMP accumulation by high Ca 2+oin the medullary TAL (MTAL) 56"57that is reminiscent of the effect of Ca 2+o on cAMP metabolism in the parathyroid cell. 52 Finally, the reduced vasopressin-mediated urinary concentrating capacity in some hypercalcemic individuals appears to involve an action of Ca 2+ on the collecting duct. 58 These effects of Ca o2+ on renal function as well as others on a variety of other cell types [i.e., osteoclasts, osteoblasts, intestinal cells, and numerous other epithelial cells (for review, see Brown 49) suggested that specific mechanisms for sensing Ca 2+ might be a more widespread property than generally recognized. It proved difficult, however, to obtain more direct evidence for the presence of a CaR. One approach that had proven useful for cloning G protein-coupled receptors that activated PLC was the technique of expression cloning in Xenopus laevis oocytes. This method takes advantage of the fact that injection of mRNA from a cell normally expressing such a receptor enables the oocyte to synthesize the relevant receptor protein and express it on the cell surface. The receptor can then couple to the endogenous, G protein-activated PLC of the oocyte, thereby stimulating PI turnover and elevating Caa when exposed to a receptor agonist. 59 The increase in Cai, in turn, stimulates a Ca2+-activated chloride channel, which provides a readily measurable bioassay that can be used to screen for expression of the receptor by oocytes during the expression cloning process. Both Nemeth and coworkers 6~ and Shoback et al. 61 showed that X. laevis oocytes became responsive to agents thought to activate the putative parathyroid Cao2 + -sensing receptor following injection of the oocytes with mRNA extracted from bovine parathyroid glands. Thus it was likely that the expression cloning approach would be a feasible one for isolating the CaR and characterizing its molecular properties. Brown et al. 16 subsequently used this approach successfully to isolate a single full-length clone of the bovine parathyroid CaR. The 5.3-Kb cDNA, called BoPCaR (bovine parathyroid Ca2+-sensing receptor), encodes a predicted protein of 1085 amino acids similar to that shown in Figure 1 6 - 3 (which is the human homolog of the CaR) with three principal structural domains. The first is a putative, extracellular amino-terminal domain (ECD) of 613-amino-acid residues that contains nine predicted N-linked glycosylation sites and begins with an --~20-residue signal peptide. Recent studies have suggested that polycationic agonists bind, at least in part, to this portion of the CaR 62 as described in more detail later. The second domain of the receptor is a central core with seven membrane-spanning helices indicating that

EDWARD M. BROWN, MEI B AI, AND MARTIN POLLACK

the receptor is a member of the superfamily of G proteincoupled receptors. The last part is a 222-amino-acid, carboxyl-terminal tail that is predicted to be cytoplasmic. Within the C-terminal tail and other intracellular domains of the receptor (e.g., intracellular loops between the membrane-spanning segments) are four predicted protein kinase C (PKC) phosphorylation sites 16 that may contribute to the inhibition of the activation of PLC by high Ca 2§ following treatment of parathyroid cells with activators of P K C . 63-66 Since the cloning of BoPCaR, additional CaRs have been isolated using hybridizationbased strategies from human parathyroid 67 and kidney 68 as well as from rat kidney, 69 brain, 7~ and C-cells. 71 All show greater than 90% identity in their amino acid sequences to BoPCaR and represent the various species homologs of the same ancestral gene. To date no other isoforms of the receptor have been isolated. A structurally unrelated protein with putative Ca o2+-sensing " properties has been cloned independently by two research groups. 72'73 This protein, called megalin by one group in view of its very large size (--~500 kDa), 73 is a member of the LDL receptor superfamily and is heavily expressed in the parathyroid gland, proximal tubule of the kidney, and placenta. Additional studies of the expressed protein will be needed to assess fully whether it actually senses Ca 2+ o a physiologically relevant manner. The CaR activates PLC in a pertussis toxin-insensitive fashion, 74 most likely through a member of the Gq family of G proteins. 75 The most abundant member of this family in bovine parathyroid gland is Gll with lesser amounts of Gq.75 As noted previously, high Ca 2+ also produces a pertussis toxin-sensitive inhibition of cAMP accumulation in parathyroid cells. 52 Rogers et al. have reported in preliminary form that human embryonic kidney (HEK293) cells stably transfected with the CaR also exhibit inhibition of agonist-stimulated cAMP accumulation, suggesting that the CaR also couples to inhibition of adenylate cyclase via Gi .76 Structure/function studies of the CaR are in an early stage. Hammerland et al. have taken advantage of the modest degree of homology between the CaR and metabotropic glutamate receptors (mGluRs) (GPCRs for glutamate, the principal excitatory neurotransmitter in the brain) to construct C a R - m G l u R chimeras in order to determine where agonists interact with these receptors. 62 If the CaR ECD is replaced by that of an mGluR, the chimeric receptor now responds to glutamate as its ligand. Conversely, the chimeric receptor with the CaR ECD responds to Ca2+o as its ligand, albeit with a somewhat reduced apparent affinity. Therefore, the principal determinants of the binding of polycationic ligands to the CaR appear to reside within the large ECD. It has been suggested that agonists interact with regions within the CaR ECD that have a relatively high density of

CHAPTER 16 Familial Benign Hypocalciuric Hypercalcemia

485

FIGURE 16--3 Schematic representation of the proposed topological structure of the extracellular Ca2+-sensing receptor cloned from human parathyroid gland. SP, signal peptide; HS, hyrophobic segment. Also shown are missense and nonsense mutations causing either familial benign hypocalciuric hypercalcemia (FBHH) or autosomal dominant hypocalcemia (ADH), which are indicated using the three-letter amino acid code, with the normal amino acid indicated before and the FBHH or ADH mutation shown after the number of the relevant codon. [Modified from Brown EM, Harris HW Jr, Vassilev PM, Hebert SC: The Biology of the Extracellular Ca2+-Sensing Receptor. In Principles of Bone Biology. Raisz LG, Rodan G, Bilezikian JP (eds): New York, Academic Press, pp 243-262, 1996.]

acidic residues (e.g., glutamates and/or aspartates) reminiscent of those thought to bind Ca 2+ in low-affinity Ca2+-binding proteins, such as calsequestrin. 16 The CaR is expressed in a variety of tissues, including parathyroid gland, C-cells, intestine, lung, a variety of cells within the brain (including the subfornical organ, which is involved in angiotensin I I - m e d i a t e d thirst), and several types of kidney c e l l s . 16'69'7~ Within the kidney, the receptor is expressed most heavily in the CTAL with lower levels of expression in the MTAL, distal convoluted tubule (DCT), and collecting d u c t . 77 The use of anti-CaR antibodies has made it possible to show that the receptor protein is expressed on the basolateral surface of the epithelial cells of the CTAL and on the apical surface of those of the inner medullary collecting duct (IMCD). v7 As noted above, all of these nephron segments are capable of responding directly to Cao2 + . The physiological functions of the receptor in the CTAL and IMCD as well as in the MTAL will be discussed later (see Section I.B.4). Using sensitive techniques [e.g., re-

verse transcriptase polymerase chain reaction (RTPCR)], even lower levels of expression of CaR transcripts can be detected in the glomeruli and proximal convoluted and straight tubules, but the physiological relevance of the receptor in these sites remains to be determined. 77 4. CAR MUTATIONS IN FBHH3q: F B H H AS A SYNDROME OF Ca 2+ "Resistance" o

Since FBHH is a disorder in which there is abnormal Ca2+-sensing by parathyroid, kidney, and probably other tissues, there was an obvious rationale for searching for mutations in the newly cloned CaR. Pollak et al. initially mapped the human homolog of the CaR gene to the long arm of chromosome 3. 48 They then used a ribonuclease A (RNAse A) protection assay to screen for mutations in the human CaR gene in affected members of three unrelated families with FHH linked to the locus on chromosome 3. They identified a single, unique missense mutation in each family (i.e., mutations in which a

486 change in a single nucleotide base substitutes a new amino acid for the one normally coded for) (Fig. 16-3). Moreover, the observed mutations were not found in the genomic DNA of 50 normocalcemic individuals. All three mutations occurred in amino acid residues conserved between the human and bovine receptor genes. Two of the three families exhibited a mutation in the ECD of the CaR [R185Q (inadvertently described as R186E in the original publicationmnote that the numbering for the bovine CaR 48 is one higher than that for the human CaR 78 because of the presence of an extra amino acid in the ECD of the former) and E297K] and might, therefore, interfere with the binding of polycationic ligands to the receptor. The third family harbored a mutation (R795W) within the third intracellular loop, which could be important for binding G protein(s) and initiating signal transduction, as in other GPCRs. 6 Xenopus laevis oocytes injected with synthetic mRNA encoding a CaR engineered to contain the R795W missense mutation exhibited a markedly blunted response to 2+ 3+ Cao , Gdo , and neomycin, providing convincing evidence that this mutation impaired Ca 2+o-sensing." 48 Subsequent studies by several groups have uncovered a variety of additional mutations in the CaR in families with FBHH linked to chromosome 3 (Fig. 1 6 - - 3 ) . 46,79-82 In most cases each family has its own unique mutation. Most are missense mutations that cluster within several discrete regions of the CAR--(1) the first half of the ECD; (2) a region proximal to TM1 (the first membranespanning domain); and (3) the transmembrane domains, extra- and/or intracellular loops of the receptor (Fig. 16-3). In addition, several apparently benign polymorphisms have been described in the C-terminal tail of the CaR that are not associated with any change in Ca 2+ in individuals harboring them and are present in a substantial proportion of the population (--~10% to 30%). 81 There are, however, several additional types of mutations that have been discovered recently. One family has a nonsense mutation in codon 607 (e.g., a point mutation that substitutes a stop codon for the amino acid normally coded for) just proximal to T M 1 . 46 Such a mutation should result in synthesis of a presumptively inactive, truncated receptor that might well be secreted into the extracellular fluid. Another mutation includes both a one-nucleotide deletion and a transversion of an adjacent nucleotide (change from one nucleotide to another) within codon 747, which would be predicted to modify the downstream reading frame leading to premature termination of the protein at a stop codon following residue 776 within the transmembrane domains. 46 One additional type of mutation in a Nova Scotian family is the insertion of a 383-bp Alu repetitive sequence at codon 876. 82 This sequence is in the opposite orientation to the CaR gene and contains an exceptionally


long poly-A tract. Stop signals are present in all three reading frames within the Alu sequence, leading to a predicted truncation of the CaR protein following a long stretch of repeated phenylalanines (encoded by the triplet AAA). Thus this mutation would likely result in production of a nonfunctional protein that might well have compromised biological activity and/or fail to reach the

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CHAPTER 16 Familial Benign Hypocalciuric Hypercalcemia cell surface. Of interest, the size of the Alu element was found to approximately double in size in a subsequent generation of this family. 83 Despite the multiplicity of mutations identified to date in families with FBHH, only about two thirds of families with the form of the disorder linked to chromosome 3 have identifiable mutations within the coding sequence of the CaR gene or in regions close to the splice junctions of the seven exons of the CaR gene. In the remaining families, there are presumably mutations within introns or within upstream and/or downstream regulatory regions of the gene that interfere with its normal expression. Recent studies have undertaken expression of CaRs engineered to contain these various mutations in mammalian expression systems. 84 Examples of the effects of several of the point mutations on high CaoZ+-evoked increases in the Ca~ in transiently transfected human embryonic kidney (HEK293) cells are illustrated in Figure 16-4. Some of the mutations, such as R185Q and R795W, markedly reduce the apparent affinity and/or maximal activity of the mutated receptor. In other cases, however, such as T138M or R62M, the mutation only modestly reduces apparent affinity, without decreasing the maximal response to Cao2 + .84 Many of the mutant CaRs with the most severe reductions in biological activity show reduced quantities of the putatively mature, glycosylated form of the receptor on Western blot analysis. It is of interest that the elevation in serum calcium concentration in such families is generally mild. Indeed, the family with the nonsense mutation at codon 607 has very mild hypercalcemia 46 and, as described in greater detail below, mice with targeted deletion of one allele of the CaR also have mild hypercalcemia. 85 In contrast, mutations that severely impair the biological function of the receptor despite showing an essentially normal pattern on Western blot analysis can be associated with more severe hypercalcemia. This latter circumstance is exemplified by the families with the R795W or R185Q mutations. 84 In these two families, serum calcium concentrations average over 2 mg/dl and 3 mg/dl higher than the levels in unaffected family members, respectively. It seems likely that these two mutated receptors interfere in some way with the function of the normal receptor. This could conceivably occur through: (1) a reduction in the quantity of normal CaR reaching the cell surface; (2) formation of an inactive complex of mutant CaR with G protein(s), thereby decreasing the concentration of Gprotein available to the wild type receptor; and/or (3) formation of inactive complexes of normal and mutant receptors on the cell surface. Expression by transient transfection has also been performed of two mutant receptors containing the deletion and transversion in codon 74785a as well as the insertion of the Alu element in the region of the CaR gene encoding the carboxyl-terminal

487 tail of the CaR. 85b Both were totally nonfunctional and encoded truncated proteins on Western blot analysis that corresponded closely in their sizes to those predicted from the premature stop codons introduced by the mutations. Although the level of expression of the normal CaR in parathyroid and kidney has not been determined in FBHH, the development of mice with targeted deletion of the CaR (see Section II.B.5) has made it possible to carry out similar studies in an animal model of FBHH. In mice heterozygous for knockout of the CaR, the level of receptor protein in the parathyroid and kidney as assessed by immunocytochemistry and Western blot analysis, respectively, is approximately one half of that in the corresponding tissues from the wild-type mice. 85 It appears, therefore, that there is little up-regulation of expression of the CaR protein produced from the remaining normal allele and that a 50% reduction in receptor protein translates into a 10% to 20% increase in the setpoint for Ca2+-regulated PTH release in vivo. A further reduction in the level and/or function of the normal receptor on the cell surface produces a greater shift in setpoint, as in the cases of the families with the R185Q and R795W mutations. A related situation may exist in PHPT, where no point mutations could be found in the CaR gene, 86 but the intensity of CaR immunoreactivity was decreased in parathyroid adenomas relative to normal glands from the same patients. 87 The reduced immunostaining suggested a reduced level of expression of an otherwise normal CaR protein (at least in terms of its deduced amino acid sequence), thereby causing an increase in set-point for CaoZ+-regulated secretion. Of interest, the decrease in the intensity of CaR immunostaining averaged 60%, which might predict a slightly greater increase in set-point in patients with a parathyroid adenoma than in persons with FBHH, which is, in fact, the case. While much additional work is required to elucidate the structure/function relationships for the CaR, the following tentative conclusions can be drawn from the studies just described. Some FBHH mutations within the ECD produce a spectrum of alterations in the apparent affinity of the CaR for Ca 2+ (as well as for Gd3o+) without apparent changes in the level of expression of the mature protein, at least as assessed by Western blot analysis. 84 Therefore, the altered amino acid might be either directly or indirectly involved in determining the binding properties of the CaR for polycationic ligands. It seems unlikely, however, that the residues in question actually interact directly with the ligands, as in many cases the mutations are often associated with a net loss of positive charge (e.g., R62M). They might, on the other hand, determine more general features of the conformation of the ECD that, in turn, affect affinity for ligands. Even-

488 tually solution of the three-dimensional structure of the ECD will be needed to determine the precise nature of the interactions of the protein with its polycationic ligands. It seems likely that there is more than one binding site for Ca 2§ on the CaR. The Hill coefficient for activation of the transiently expressed CaR by Cao2§ is around 3, implying the presence of at least three interacting binding sites. 84 Conversely, the Hill coefficient for the activation of the receptor by Gd3o§ is about 1, raising the possibility that trivalent cations interact with the CaR in a manner that differs from that for the physiological ligand, Cao2+. Of interest in this regard, Hammerland et al., 62 in addition to studying a chimeric, C a R - m G l u R construct, also investigated a receptor engineered to lack essentially the entire ECD. This deletion mutant, while no longer activated by Ca o2+, still showed a relatively robust response to Gd3o§ albeit with a somewhat reduced apparent affinity. This result raises the possibility that there could be a site that binds Gdo3+, but perhaps not Cao2+ , within the extracellular loops or even TMDs of the CaR or that binding of Cao2§ to this site alone is not sufficient to initiate signal transduction. These observations with the CaR deletion mutant may also explain why CaRs harboring some FBHH mutations show no response to Ca 2§ but are activated reasonably well by Gd3o+84; perhaps the structure of the ECD in these mutated receptors has been severely compromised but a functional Gd3+o finding site remains intact. The mutations within the transmembrane domains of the CaR presumably disrupt conformational changes of the TMDs attendant upon the binding of ligand to the ECD that are required to transduce signals intracellularly to the site(s) of interactions of the receptor with G protein(s), most likely the intracellular loops (ICL). As noted previously, the one FBHH mutation described to date within an ICL p e r s e (R795W, within the third ICL), markedly impairs activation of PLC, presumably by interfering with this coupling to and/or activation of Gq or Gl1.48 While the third ICL plays a critical loop in determining the specificity of the coupling of many GPCRs to their G proteins, 4'5 recent studies have shown that for the homologous mGluRs, which couple to G proteins similar to those utilized by the CaR, the second loop may confer specificity for activation of Gi or Gq.88 Nevertheless, available data suggest that G proteins interact with multiple (probably all three) ICLs in GPCRs and likely with the carboxyl-terminal tail as well. 4-6 Therefore, it is not surprising that the substitution of a bulky hydrophobic residue for the basic arginine normally present at residue 795 of the CaR will interfere with the coupling of the receptor to its intracellular signal transduction system. Thus the spectrum of mutations encountered to date in FBHH has already provided useful clues


into structure/function relationships for the receptor. Moreover, it provides the basis for a targeted approach to elucidating these relationships further using sitedirected mutagenesis. Based on these results, we conclude the following: (1) FBHH is genotypically and phenotypically heterogeneous, but more than 90% of families likely have the form of the disorder linked to chromosome 3. (2) About two thirds of all individuals with FBHH linked to chromosome 3q show inactivating mutations within the coding region of the recently cloned CaR, and each family generally has its own unique mutation. The majority of mutations occur within the ECD and may reduce the affinity of the receptor for extracellular Ca 2§ or interfere with its biosynthesis or expression on the cell surface. Some occur in transmembrane or cytoplasmic domains and may disrupt processes involved in signal transduction. All likely impair the responsiveness of the CaR to Cao2+ , rendering patients with FBHH mildly to moderately "resistant" to the extracellular Ca 2§ signal. (3) Of the remaining one third of individuals with FBHH linked to the CaR gene, there are no detectable mutations in the coding region. These individuals may have defects in promoter or enhancer sequences of the CaR gene, which have not yet been characterized. (4) In occasional families the defect maps to other, as yet undefined genes either on chromosome 19p or elsewhere. (5) Because patients with FBHH have a generally benign clinical course, parathyroidectomy should not be performed except in very unusual clinical circumstances.

B. N e o n a t a l S e v e r e H y p e r p a r a t h y r o i d i s m 1. CLINICAL AND B I O C H E M I C A L FEATURES OF N S H P T

Neonatal primary hyperparathyroidism often presents dramatically as severe, symptomatic hypercalcemia with hyperparathyroid bone disease in infants under the age of 6 months. 24 This syndrome was actually described well before FBHH was recognized as an entity distinct from other forms of PTH-dependent hypercalcemia. 89'9~ A recent review of 49 cases of NSHPT found that most presented at birth or shortly thereafter, generally within the first week of life. 24 Common presenting symptoms include failure to thrive, anorexia, constipation, hypotonia, and respiratory distress. Additional manifestations comprise deformity of the chest wall and, less commonly, craniotabes, dysmorphic facies, and anovaginal or rectovaginal fistulas. 14"91-98 Respiratory complications may arise owing to thoracic deformity, including an actual flail chest syndrome because of multiple rib fractures, and are a major cause of morbidity. 24'91

CHAPTER 16 Familial Benign Hypocalciuric Hypercalcemia The hypercalcemia in NSHPT is typically severe, ranging from 14 to 20 mg/dl, and levels as high as 30.8 mg/dl have been described. 93 Interestingly, relative hypocalciuria has been documented in some cases, even in the absence of a family history of FBHH. 99 Although serum magnesium concentrations were not reported in many of the cases, when measured they have sometimes been elevated well above the upper limit of normal even when renal function was not compromised. 79 Serum PTH levels have been high in the majority of cases in which they were measured, often being increased five- to tenfold, although the degree of elevation can be mild in s o m e c a s e s . 99-1~ Skeletal radiographs show marked undermineralization, with fractures of the ribs and long bones, subperiosteal erosions, metaphyseal widening, and, occasionally, rickets. 91"1~ Histological examination of bone may show typical osteitis fibrosa cystica. TM At the time of parathyroidectomy, all four parathyroid glands are usually enlarged, sometimes being many times the mass of normal parathyroid glands in infants of this age. Histological examination shows chief cell or water-clear cell hyperplasia, although in cases where the glandular enlargement is less marked, the normal lack of fat in the parathyroid glands of children complicates interpretation of the histological findings. 14'24'1~ There have been no cases described in which a parathyroid adenoma caused NSHPT. There is, however, a relatively broad range of clinical severity encountered in NSHPT. In some cases, the hypercalcemia is less marked, in the range of 11 to 12 mg/dl, and cases have been reported where the disease ran a self-limited course, reverting to milder hypercalcemia by the age of 6 to 7 months with conservative treatment. 91'1~ The recent advent of techniques for identifying cases of NSHPT due to mutations in the CaR will doubtless widen the spectrum of the disease further. A particularly instructive case was recently identified of a homozygous female offspring of a consanguineous marriage of two individuals with heterozygous FHH whose serum calcium concentrations were in the upper part of the normal range. 79 This homozygous child did not present as NSHPT and was not diagnosed until age 32, when she was identified by mutational analysis. She was essentially asymptomatic, although she was mildly retarded, despite serum calcium concentrations of 15 to 17 mg/dl, accompanied by a serum magnesium concentration elevated to a similar extent (--~50% above the upper limit of the normal range) and a serum intact PTH level at the upper limit of normal. In spite of the degree of elevation of her serum calcium concentration, her renal function was normal, including her renal concentrating ability. Prior to 1982, 24 NSHPT was often fatal in severe cases if aggressive medical and surgical management

489 was delayed. As just noted, however, this is not invariably true in more recent cases, and wider recognition of the full clinical spectrum of the disorder as well as improvements in the medical therapy of severe hypercalcemia have permitted successful expectant medical management of NSHPT during the past 15 years. In symptomatic cases, initial management should include hydration and aggressive respiratory support. If the clinical condition is very severe or deteriorates during treatment, total parathyroidectomy with autotransplantation of part of one of the glands is recommended during the first month of l i f e . 24'1~176176Some authors recommend total parathyroidectomy with lifelong medical management of the resultant hypoparathyroidism. ~4'~~ The latter includes oral calcium supplementation and sufficient vitamin D replacement, generally with 1,25(OH)2D, to maintain low normal serum calcium concentrations. Because patients with CaR mutations would be expected to have relative hypocalciuria, the dose of vitamin D required for replacement is generally lower than needed for individuals with congenital or acquired primary hypoparathyroidism. There is dramatic clinical improvement following parathyroidectomy, with rapid healing of the skeletal abnormalities, even though the hypercalcemia usually recurs rapidly with less than total parathyroidectomy or following autotransplantation. ~4'24Indeed, during the past 15 years, similar clinical improvement has also been observed in infants with NSHPT managed medically. 24

2. G e n e t i c s o f N S H P T Since the first descriptions of FBHH, the presence of children with NSHPT in FBHH families has been noted by several investigators. 13'14'94'1~ In 1981, Marx et al. 13 reported their studies of 15 kindreds with FBHH, in which they found three patients from two families with neonatal severe hyperparathyroidism. One explanation for this association that they suggested was that NSHPT can in some cases be the homozygous form of FBHH. These investigators subsequently studied a family with two children affected by NSHPT. Their parents, who were related, had mild increases in serum ionized calcium concentration (total calcium levels were normal) as well as hypocalciuria. Additional family members had borderline and, in some cases, intermittent hypercalcemia. 1~ These clinical findings supported the hypothesis that NSHPT can be the homozygous form of FBHH and that apparently sporadic occurrences of NSHPT can result from the failure to recognize very mild hypercalcemia in family members who are heterozygous for the abnormal gene. (Indeed, the alteration in Cao2 + -sensing by the mutant CaR might in some cases be so mild that

490 overt hypercalcemia is not present, as in the recently reported Japanese family, 79 and that there is simply a subtle increase in serum calcium concentration to a level that is higher than in unaffected family members but remains within the normal range.) After localization of the FBHH gene to chromosome 3q in several families, 26 Pollak and co-workers investigated 11 FBHH families and showed that the abnormal gene mapped to chromosome 3q2 in all of them. 1~ Four families had consanguineous marriages of affected individuals resulting in children with NSHPT. The pattern of inheritance of genetic markers closely linked to the FBHH gene in these families was consistent with NSHPT being the homozygous form of the same disorder. Subsequent studies of the CaR gene in additional families in which both FBHH and NSHPT coexisted confirmed that inheriting two abnormal copies of the CaR gene can cause NSHPT. 48'8~ These patients do not have any normal CaRs, and as a result exhibit much more severe hypercalcemia than do patients with FBHH, with greater elevations in PTH, substantial parathyroid glandular enlargement, and markedly abnormal set-points for calcium-regulated PTH secretion. All of these findings indicate a state of severe parathyroid resistance to Ca 2+ in NSHPT, although if the defect in the FBHH gene is sufficiently mild, as in the Japanese family described above, NSHPT can escape detection in the neonatal period and be compatible with life. 3. MUTATIONS IN THE C A R IN N S H P T : HOMOZYGOUS VERSUS DE NOVO HETEROZYGOUS MUTATIONS

It is now established, as described in more detail below, that not all cases of NSHPT represent homozygous FBHH. Indeed, most cases of NSHPT have been reported to occur sporadically or in FBHH families with only one affected parent. 97"1~176 T h e latter situation might conceivably arise from the child with NSHPT being a compound heterozygote, harboring two CaR alleles, each with a with distinct mutation, one producing obvious hypercalcemia in one parent, but the other being sufficiently mild so as not to be biochemically detectable in the other parent. Alternatively, there might be a mutation in one allele of the CaR gene as well as in one allele of one of the other genes causing an FBHH-like clinical picture, including the one on chromosome 19p 45 as well as that present on neither chromosome 3 nor 19. 47 While the latter two circumstances have not been documented to date, the sizable proportion of FHH3q families without detectable mutations in the coding region of the CaR gene, as well as our ignorance concerning other genes causing FBHH, would make it difficult to exclude these scenarios at present.


Recent studies have documented the occurrence of clinically severe, neonatal hyperparathyroidism resulting from heterozygous d e n o v o CaR mutations in two sporadic cases 46 (i.e., caused by a single d e n o v o CaR mutation in the child of normal parents). Both infants had evidence of hyperparathyroid bone disease, although they had less severe hypercalcemia than is seen in NSHPT due to homozygous FHH. This may provide an explanation for the observed clinical spectrum in NSHPT, which ranges from the typically severe, lifethreatening manifestations (in patients homozygous for mutated CaR) to a more benign form of the disorder (i.e., in patients with d e n o v o heterozygous CaR mutations). Another possible explanation for the presence of a child with NSHPT whose father has FBHH but whose mother is unaffected would be the impact of the normal maternal calcium concentration on the abnormal Cao-2+ sensing of the parathyroid glands of the affected fetus in u t e r o . 1~ Calcium is actively transported across the placenta from mother to fetus, resulting in a higher fetal than maternal concentration of calcium. 1~ Therefore, a normal mother would expose fetal parathyroid glands with even mildly abnormal Ca2+-sensingo due to FBHH to a level of Ca 2+o that would be recognized as relatively hypocalcemic compared to that experienced by normal fetal parathyroid glands. This relative hypocalcemia would be expected to "overstimulate" the fetal parathyroids leading to the superimposition of " s e c o n d a r y " fetal/neonatal hyperparathyroidism upon the abnormal Ca2+-sensing already present due to FBHH. This hypothesis is supported by the observation that cases of NSHPT with autosomal dominant inheritance have been reported in cases where the father had FBHH while the mother was apparently n o r m a l . 14'24'25 With time postnatally, the secondary component of hyperparathyroidism would subside, causing eventual reversion to the clinical and biochemical features expected of FBHH. In most cases, however, it has not been apparent that children with FBHH who were born of a normal mother had more severe hypercalcemia than those born of an affected mother. Furthermore, there are no apparent phenotypic or biochemical differences between mice heterozygous for knockout of the CaR that are born to a normal mother or one who is heterozygous for CaR knockout. 85 Of interest, we recently documented another case of d e n o v o heterozygous NSHPT in a child harboring the same R185Q mutation described above that is associated with an elevation in serum calcium that is greater than observed in most cases of FBHH. 1~ In this case, the relatively large disparity between the set-points of the maternal and fetal parathyroid glands may have contributed to a greater degree of prenatal hyperparathyroidism and resultant hyperparathyroid bone disease in the fetus.

CHAPTER 16 Familial Benign Hypocalciuric Hypercalcemia These studies on NSHPT, which in the homozygous cases is a knockout of the human CaR, suggest the following perspectives on the function of the receptor in humans: (1) They highlight its importance in fetal and neonatal calcium metabolism; and (2) they also suggest a possible role for the CaR in the tonic inhibition of parathyroid cellular proliferation, since there is substantial parathyroid hyperplasia in NSHPT. 4. DEVELOPMENT OF MICE WITH TARGETED

DELETION OF THE CAR GENE Recently, Ho et al. have used the genetic technique of targeted disruption of the CaR gene to produce mice heterozygous or homozygous for deletion or knockout of the CaR gene that represent animal models of FBHH and NSHPT, respectively. These investigators introduced DNA coding for the neomycin resistance gene into the third exon of the CaR gene, with resultant absence of detectable CaR protein in the parathyroid and kidney of mice homozygous for CaR knockout and levels of the protein that were reduced by ---50% in the heterozygous mice. 8s Phenotypically, the heterozygous mice cannot be readily distinguished from their normal littermates, are fertile, and appear to have a normal lifespan. Their serum calcium concentrations (averaging 10.4 mg/dl) are about 10% higher than normal and they had magnesium levels that were likewise modestly but significantly higher than those of normal mice. Serum levels of PTH were about 50% higher than in the normal mice, and the calcium concentration in bladder urine was slightly lower than in the normal mice. Skeletal x-rays were not detectably different from those of the normal littermates. Thus the mice heterozygous for knockout of the CaR gene mimic in many ways the phenotypic and biochemical features of FBHH. The homozygous CaR knockout mice, in contrast, while of nearly normal size at birth, grow much more slowly than their normal or heterozygous littermates, 85 perhaps in part because they compete poorly for maternal milk with their more vigorous littermates. They are severely hypercalcemic, averaging 14.8 mg/dl with magnesium levels that were slightly but not significantly higher than those of the heterozygous mice. Serum PTH levels were nearly tenfold higher than the mean value of the normal mice, and the calcium concentration in bladder urine was lower than that of the normal mice despite the severe hypercalcemia. 85 Skeletal x-rays showed substantially reduced mineral density, kyphoscoliosis, and bowing of the long bones. Most of the homozygous mice died during the first 2 weeks of life, with only occasional ones surviving up to 3 or 4 weeks of age. Again, therefore, the clinical and biochemical abnormalities in mice homozygous for CaR knockout show many similarities to NSHPT in humans. While relatively little work has

491 been done using this animal model to study abnormalities in Ca2+-sensing in tissues normally expressing the CaR, these animal models of FBHH and NSHPT will likely be very useful for performing in vitro studies that are impossible in the human diseases. It is of interest, as noted before, that despite the complete lack of CaR production from one allele encoding the gene, there appears to be little, if any, up-regulation of production of the CaR protein from the remaining normal gene, as the levels of expression of the protein in parathyroid and kidney are approximately half of their normal levels. 85 In addition, this ---50% reduction in expression of the CaR protein in parathyroid is associated with a mild, --~10% increase in the apparent set-point of the parathyroid gland, consistent with the somewhat greater reduction in CaR immunoreactivity in parathyroid adenomas, which exhibit a somewhat greater increase in set-point in vitro. 87 Finally, most families have a degree of hypercalcemia that is comparable to that of mice heterozygous for knockout of the CaR, suggesting that the abnormal CaR allele in many cases acts as a null mutation (i.e., as if it were totally nonfunctional). 13'2~ In occasional families (e.g., those with R185Q or R795W), however, the abnormal protein appears to interfere in some fashion with the normal CaR, resulting in greater degree of elevation of Ca 2+. 5. IMPLICATIONS OF C A R MUTATIONS IN FBHH FOR UNDERSTANDING THE ROLE OF THE C A R IN THE

REGULATION OF PARATHYROID AND RENAL FUNCTION BY Ca2o§

FBHH3q and most cases of NSHPT represent, in effect, experiments in nature where there are reductions in the biological activity of the CaR. Therefore, examination of the alterations in the effects of Ca o2+ on various aspects of parathyroid and renal function in these patients provide useful clues into the normal role of the receptor in regulating these two tissues. Coupled with the recent development of mice with targeted deletion of the CaR gene, the tools are now in hand to elucidate which of the previously poorly characterized effects of Cao2§ on the function of various tissues are CaR mediated. a. The CaR a n d Ca o2 + -Regulated P a r a t h y r o i d Function.

As described previously, persons with FBHH have a modest (10% to 20%) increase in their set-point for 2+ Cao-regulated PTH secretion, 28'29 while parathyroid glands from two individuals with NSHPT that were studied in vitro showed considerably more severe resistance to Ca 2+o (the set-point was elevated by two- to fourfold or more). 1~176 Similarly, mice that are heterozygous or homozygous for knockout of the CaR gene exhibit mild and marked elevations, respectively, in both serum cal-

492 cium concentration and PTH. 85 Thus, the abnormalities in Ca2+-regulated PTH secretion in FBHH and NSHPT as well as in mice with deletion of one or both alleles of the CaR gene offer strong support for the CaR as a key mediator of the inhibitory effect of Ca 2+ on PTH secretion. Recent studies also suggest that the receptor is responsible for the high CaZ+-evoked suppression of PTH gene expression. ~1~Finally, the marked parathyroid cellular hyperplasia in NSHPT as well as in mice homozygous for targeted deletion of the CaR gene suggests that the CaR could also act to suppress parathyroid cellular proliferation. It remains to be determined whether the CaR is also responsible for additional effects of Ca 2+ on parathyroid function (for review, see Brown49), such as changes in cellular respiration, the activity of the hexose monophosphate shunt, and the intracellular degradation of PTH.

b. The CaR and CaZ+-Regulation of the Function of the TAL. As discussed above, FBHH is characterized by an inappropriate degree of reabsorption of calcium ions by the kidney given the ambient hypercalcemia, which persists even after parathyroidectomy. 33'4~ Studies by Attic and co-workers suggested that this abnormality in renal calcium handling takes place in the TAL, since individuals with FBHH showed an exaggerated calciuric response to administration of the loop diuretic, ethacrynic acid. 4~ The CaR is present in cells of the TAL based on studies using in situ hybridization, immunohistochemistry and RT-PCR. 77 Moreover, increases in the peritubular, but not luminal levels of Ca 2+ to which the TAL is exposed have been shown to inhibit reabsorption of calcium ions. 55 Recent studies suggest that Ca 2+ acts, at least in part, by inhibiting the activity of a potassium channel in the luminal membrane, whose activity is necessary to "recycle" potassium ions transported intracellularly by the apical Na+-K+-2C1 - co-transporter. 1~ The activity of the co-transporter, coupled with K + recycling, generates a lumen-positive potential gradient that drives passive, paracellular transport of Na +, Ca 2+, and Mg2+. 112 PTH stimulates this lumen-positive potential by a cAMP-dependent activation of the co-transporter. Following inhibition of the K + channel, there is an attendant reduction in net co-transporter activity because of the decrease in luminal K + concentration, thereby reducing the lumen-positive potential and divalent cation reabsorption. In effect, high Ca 2+ acts as a loop diuretic through its action on the overall activity of the co-transporter. Therefore, the alterations in the tubular handling of calcium in FBHH 4~ provide additional evidence that 2+ the CaR is responsible for high Cao -mediated modulation of Ca 2+ reabsorption by this segment of the nephron. In effect, the TAL, like the parathyroid cell, is "resistant" to Cao2+ in persons with FBHH, limiting


their ability to up-regulate urinary excretion of calcium in the presence of an elevated level of Cao2+, which, in turn, contributes to the maintenance of their hypercalcemia.

c. The CaR and the Control of Mg z+o Homeostasis. Individuals with FBHH can exhibit mild hypermagnesemia due, in large part, to excessive magnesium reabsorption in the distal nephron. 13 Moreover, in some individuals with NSHPT, Mg 2+o levels have been elevated roughly in proportion to the concomitant elevation in serum calcium concentration, raising the possibility that the CaR contributes to the "setting" of Mg2+. 79 Additional support for this hypothesis has come from the elevated serum levels of Mgo2+ in mice that are heterozygous or homozygous for knockout of the CaR gene, although the Mgo2+ level in the homozygotes was only slightly and not statistically significantly higher than in the heterozygotes. 85 What are the mechanisms through which the CaR could contribute to regulation of the serum Mg 2+ concentration? Previous in vitro studies had shown that elevated peritubular levels of not only Ca2+o but also Mg 2+o inhibit the reabsorption of both of these divalent cations in the TAL. 55 Moreover, both the cloned parathyroid 16 and renal 69 CaRs respond to Mg 2+ when expressed in X. laevis oocytes, although the potency of Mg o2+ is about two- to threefold less than that of Cao2+. The concentration of Mgoz+ in the TAL, however, is higher than in the initial glomerular filtrate, since relatively little Mg 2+ is reabsorbed prior to this segment of the nephron. 55 Perhaps the local Mg2o+ concentrations achieved in the TAL are sufficient to be sensed by the CaR, which could thereby play an important, although as yet unproven, role in the regulation of renal Mg 2+ reabsorption. In FBHH, the presence of abnormal CaRs with reduced activity leads to excessive Mg 2+ reabsorption and consequent hypermagnesemia. 13'2~However, unlike Ca 2+ reabsorption, the presence of PTH may be necessary for this inappropriate Mg 2+ reabsorption in FBHH, as this abnormality does not persist after parathyroidectomy. 4~ d. The CaR and Urinary Concentrating Ability. A long-recognized but poorly understood clinical consequence of hypercalcemia is a reduction in maximal uri' nary concentrating capacity, resulting in hyposthenuria and, in some cases, frank nephrogenic diabetes insipidus (NDI). 44 Studies in vivo have suggested that two principal factors contribute to this defect in urinary concentration: (1) Elevations in Caoz+ reduce NaC1 absorption in the thick ascending limb, 54 a site where the CaR is located on the basolateral side of the tubular epithelium. 77

CHAPTER 16 Familial Benign Hypocalciuric Hypercalcemia Reabsorption of NaC1 in the TAL contributes to generation of the countercurrent gradient that is required for vasopressin-elicited water flow. (2) Hypercalcemia also inhibits vasopressin action on water reabsorption in the collecting duct. 58 We recently demonstrated that the CaR is located on the apical surface of the tubular epithelium of the collecting ducts, particularly in the IMCD and papillary collecting ducts, where urinary concentration normally increases markedly during dehydration owing to the accompanying increase in circulating levels of vasopressin. 113 Individuals with FBHH show an alteration in maximal urinary concentration that provides additional indirect support for a role of the CaR in regulating water handing by the kidney. Unlike most hypercalcemic patients, persons with FBHH concentrate their urine normally despite their hypercalcemia. 43 This might occur because of deranged Ca2+-sensing in either MTAL or collecting duct as a result of reduced activity of mutant CaRs. Impaired Ca2+-sensingo in the MTAL could diminish the inhibitory action of hypercalcemia on NaC1 reabsorption and consequent generation of the medullary countercurrent gradient. Moreover, the presence of CaRs with reduced activity in the collecting duct could block the inhibitory action of hypercalcemia on vasopressin action in this nephron segment, likewise mitigating the development of NDI. In normal individuals, excreting a dilute urine during hypercalciuria could be a protective mechanism that reduces the risk of developing kidney stones and/or nephrocalcinosis when a concentrated urine is being elaborated because of dehydration. 112

C. Diagnostic and Therapeutic Implications of CaR Mutations Detection of mutations in the CaR in patients with sporadic asymptomatic hypercalcemia could clearly be helpful in diagnosing FBHH, although the size of the CaR coding sequence makes this a substantial undertaking if direct sequencing were performed. More rapid screening procedures, such as denaturing gradient gel electrophoresis or the use of RNase protection, could facilitate the process of screening for point mutations. 46'48 A negative screen for mutations is not of much value, however, as not all FBHH patients show CaR mutations, even when the disorder is linked to the chromosome 3 locus. Therefore, the diagnosis of FBHH will likely continue to be established by the traditional approach of documenting an autosomal dominant inheritance of asymptomatic hypercalcemia in family members other than the proband that is accompanied by relative hypocalciuria (calciurn/creatinine clearance ratio of < 0.01). In our experience, it is not uncommon for patients with

493 mild hyperparathyroidism to restrict their calcium intake voluntarily to the point where separation of their clearance ratios from those encountered in FBHH patients can be problematic. In this situation, particularly when firstdegree relatives are not readily available for family screening, dietary supplementation to a total of 1000 mg of elemental calcium daily can be very helpful, as it will usually increase urinary calcium excretion in patients with true primary hyperparathyroidism well above the levels seen with FBHH. Other causes of apparent hypocalciuria in otherwise typical primary hyperparathyroidism are vitamin D deficiency, the use of hypocalciuric agents such as lithium or thiazides and, occasionally, hypothyroidism. Screening of as many family members as possible of patients with a provisional diagnosis of FBHH for hypercalcemia is important, since even borderline hypercalcemic patients may harbor mutations. Mutational screening of the spouse of a hypercalcemic patient could potentially be of value in predicting risk for NSHPT in the offspring. In conjunction with family screening for hypercalcemia, mutational analysis could also be useful for the diagnosis of cases presenting with hyperparathyroidism in the neonatal period, especially in the absence of a family history of hypercalcemia. Finally, it will be of great interest to determine the nature of the additional gene defects that can give a clinical picture similar to the seen with FBHH3q. It is not currently known whether these represent additional components within the signal transductional pathway(s) utilized by the CaR, additional forms of CaR, or additional mechanisms through which parathyroid and kidney cells sense Cao2 + .

III. AUTOSOMAL DOMINANT HYPOCALCEMIA---A SYNDROME OF INCREASED RESPONSIVENESS OF TARGET TISSUES TO Ca2o§

A. The Spectrum of Inherited Hypocalcemias Familial isolated hypoparathyroidism is a rare disorder that occurs in autosomal dominant, autosomal recessive, or X-linked forms. TM The molecular basis for the autosomal recessive and X-linked forms of the disorder have not been defined. In a recent study of eight families with a diagnosis of autosomal dominant hypoparathyroidism, two were found to be linked to the gene for parathyroid hormone. 115 One was subsequently found to result from a mutation in the signal peptide-encoding region of the preproPTH gene. 116 Another family has subsequently been identified with a mutation in a splice

494


junction within the preproPTH gene. 117 The molecular basis for the disorder in other families with inherited forms of hypocalcemia, however, have been, until recently, obscure. The cloning of the CaR and the subsequent identification of inactivating mutations in the CaR gene in the autosomal dominant hypercalcemic disorder, FBHH, raised the possibility that an analogous, autosomal dominant hypocalcemic syndrome might result from activating mutations in the receptor. Subsequent studies described below established that this is indeed the case.

B. Clinical and Biochemical Features of Autosomal Dominant Hypocalcemia ADH has only been recognized as a distinct clinical entity for approximately 2 years, and approximately a dozen families have been described in which the syndrome has been proven to be present on the basis of the mutational analysis described in more detail later. 78"118-12~Nevertheless, the disorder appears to have certain characteristic clinical features that are in many ways what one might have predicted from the effects of activating CaR mutations that, in effect, " r e s e t " downwards the set-points of both the parathyroid and kidney for regulation by Ca 2+. That is, the disorder is the expression of a mild to moderate increase in responsiveness of target tissues to Cao2+ in contrast to the resistance to Ca 2+ present in FBHH. 12 ADH can be viewed, therefore, as "familial benign hypercalciuric hypocalcemia." As additional families are described, we will likely obtain a more detailed picture of the presentation and clinical course of this syndrome. Affected family members with ADH have hypocalcemia of a mild to moderate degree (---6 to 8 mg/dl) with an autosomal dominant pattern of i n h e r i t a n c e . 78'118-121 Individuals with ADH have relatively few symptoms, however, despite their hypocalcemia. Seizures are not uncommon, particularly in younger patients, although in many cases the seizures occur during febrile episodes and are not difficult to control. Other symptoms generally ascribed to hypocalcemia, such as paresthesias, tetany, and laryngospasm appear to be uncommon. Individuals with ADH, like those with classical primary hypoparathyroidism, tend to have hyperphosphatemia. In some kindreds, however, the serum phosphate may be normal in many affected family members, 12~perhaps because of the coexistent, normal levels of PTH (see below). Serum magnesium concentrations are not uncommonly in the lower part of the normal range or even subnormal in the untreated s t a t e . 121 Intact PTH levels are generally in the lower half of the normal range. In one case, further reduction in serum calcium concentration

in a patient with ADH caused a brisk increase in PTH level, suggesting a leftward shift in the set-point for Ca2+-regulated PTH release. ~5 The level of 1,25(OH)2D has been measured in relatively few cases and was generally normal. Urinary calcium excretion has been reported to be significantly higher in the untreated state than in patients with classical hypoparathyroidism, despite the fact that PTH levels are often well below the lower limit of normal in the latter and, therefore, lower than in ADH. 78'121 Careful studies will be needed, how ever, to define the relationship between serum and urinary calcium concentrations in ADH in the same way that this parameter was defined in FBHH and was instrumental in elucidating its pathophysiology. On the basis of the available data, it appears that patients with ADH respond to treatment with vitamin D and its metabolites in a characteristic manner that differs from the response of patients with true hypoparathyroidism. ADH patients seem to be unusually prone to marked hypercalciuria and to renal complications of "overtreatm e n t " with vitamin D, even in the absence of overt, treatment-related hypercalcemia. 121 These untoward effects of vitamin D therapy have included renal stones, nephrocalcinosis, and reversible (and even, in some cases, irreversible) reductions in renal function as well as polyuria and polydipsia, presumably as a result of nephrogenic diabetes insipidus. 121 That is, individuals with ADH appear to suffer from "hypercalcemic" complications even in the presence of normocalcemia, presumably as a result of resetting of their mineral ion homeostatic system as a result of enhanced responsiveness 2+ of target tissues to Cao .

C. Linkage of ADH to Chromosome 3 and Identification of CaR Mutations Finegold and c o - w o r k e r s 122 initially demonstrated that ADH was linked to a locus on chromosome 3 in the region where the gene for the CaR is located. Pollak and co-workers then identified a heterozygous missense mutation at codon 127 of the CaR (glu127ala). 12~ Additional missense mutations in the CaR have subsequently been identified in approximately ten families with A D H 78'118-12~ a s well as in a case of apparently sporadic hypocalcemia. 1~8 Most reside within the ECD of the receptor, providing further evidence for the key role of this part of the receptor in the mechanisms of its activation by polycationic agonists. Several mutations have recently been reported within the transmembrane helices of the receptor, 118 similar to the location of naturally occurring activating mutations that have been described in several other GPCRs. 7'8 In all cases this disorder has re-

CHAPTER 16 Familial Benign Hypocalciuric Hypercalcemia suited from heterozygous mutations, and, to date, no cases of homozygous A D H have been described. Pollak and co-workers expressed a mutant CaR engineered to contain the glu127ala mutation in X. l a e v i s oocytes and showed that the levels of IP3 were elevated relative to those in oocytes expressing the wild-type receptor at both low (0.5 mM) and high (5.0 mM) Uao'-2"+ . 120 We have recently expressed the same mutation in HEK293 cells using the same methodologies described above that were used to express the F B H H mutations. The mutated CaR shows a clear leftward shift for the CaZ+-evoked increase in Ca 2+ (Fig. 1 6 - 5 ) . The mechanism(s) by which these mutations could activate the CaR is presently unclear. Activating point mutations in other G-protein-coupled receptors, like the T S H and LH receptors, are present in transmembrane domains and presumably enhance the processes of signal transduction or mimic the active state of the receptor following ligand binding if the activating mutation is truly ligand independent. 1~ In the CaR, it is likely that mutations within the ECD enhance the affinity of the CaR for Ca 2+ or mimic the ligand-bound state of the extracellular domain, thereby initiating subsequent events in signal transduction at inappropriately low levels of extracellular calcium or even when C a o2+ is close to zero. Available

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495 data do not support an increased level of expression of the mutant CaR as a contributory factor, as the pattern observed on Western blot analysis for the glu127ala mutation was similar to that for the wild-type receptor. 84 Ultimately, it will be of considerable interest to determine from more detailed structural studies (e.g., x-ray diffraction) the mechanisms through which these activating mutations alter the binding properties of the CaR.

D. Clinical Features of ADH that Provide Clues to the Normal Physiological Role of the CaR Several clinical features of A D H provide additional indirect evidence for the importance of the CaR in setting the responsiveness of parathyroid and kidney to changes in Ca 2+. The parathyroid glands and kidneys of individuals with A D H appear overly responsive to extracellular calcium. Normalization of Ca 2+ in these individuals leads to hypercalciuria that may be excessive compared to that encountered in patients with primary hypoparathyroidism, as individuals with A D H seem unusually prone to the complications of hypercalciuria and hypercalcemia even at low-normal levels of Cao2+ . 121 These observations complement the ones described earlier in individuals with inactivating CaR mutations (who have inappropriate hypocalciuria despite their hypercalcemia) and confirm a major role for the CaR in regulating tubular reabsorption of calcium. Moreover, the apparently reciprocal abnormalities in water metabolism in A D H and F B H H provide further indirect evidence that the CaR is intimately involved in coordinating renal handling of C a 2+ and water.

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E. Diagnostic and Therapeutic Implications of Activating CaR Mutations

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4

5

Ca2+o (mM) FIGURE 16--5 Expressionof a mutant CaR bearing an ADH mutation (glu127ala) in HEK293 cells. Results indicate the effects of varying levels of Ca 2+ on the cytosolic calcium level in HEK293 cells transiently transfected with the wild-type CaR, a mutant CaR bearing the ADH mutation, glu127ala, or both the wild-type and mutant receptors. Note that the mutant receptor has an increase in its apparent affinity for C a o2+ and that in the co-transfected cells the Cao2 + -evoked increases in Cai take place at lower concentrations of Ca 2+ than in those transfected with the wild-type receptor alone. Thus in vivo the receptor is activated by lower than normal levels of Ca 2+ producing stable hypocalcemia. [From Bai M, Quinn S, Trivedi S, et ah Expression and characterization of inactivating and activating mutations of the human Cao2 + -sensing receptor. J Biol Chem 271"19537-19545, 1996.]

These studies suggest the existence of A D H as an entity distinct from typical hypoparathyroidism and could lead to recognition of a larger number of cases with ADH, many of which may previously have been classified as mild cases of familial isolated or sporadic hypoparathyroidism. This distinction is of great clinical importance, since patients with A D H may end up with irreversible renal damage if they are treated with calcitriol to normalize their serum calcium concentration. The recognition of cases with autosomal dominant hypocalcemia due to activating mutations of the CaR is important, since many of these individuals could be "overtreated" with calcium/vitamin D with deleterious, sometimes irreversible renal consequences if the disorder is not identified. TM The documentation of this condition

496


requires careful clinical and genetic characterization. The clinician should carefully consider this diagnosis in individuals with the p r e s u m e d diagnosis of familial hypoparathyroidism, particularly those who develop m a r k e d hypercalciuria and/or renal impairment when treated with vitamin D, so that complications such as nephrocalcinosis and renal failure can be prevented.

IV.

SUMMARY

AND

CONCLUSIONS

The recent cloning of a C a R from diverse tissues in various species demonstrates directly that cells can sense (i.e., recognize and r e s p o n d to) small changes in their ambient level of Ca 2+ through a G protein-coupled, cell surface receptor. Thus Ca 2+ acts as an extracellular first m e s s e n g e r in addition to carrying its better k n o w n role as an intracellular second messenger. Several of the tissues that express the C a R are key elements in the calcium homeostatic system that have been k n o w n for m a n y years to be able to sense Ca 2+, such as parathyroid and thyroidal C-cells. The presence of the C a R in the kidney, however, provides strong evidence that several of the well-recognized but poorly understood actions of Ca 2+o on renal function m i g h t be mediated by the CaR. These actions include the up-regulation of renal calcium and m a g n e s i u m excretion in response to h y p e r c a l c e m i a that c o m p l e m e n t s the indirect inhibition of renal reabsorption of Ca 2+ in this setting which results from high 2+ C a o - m e d i a t e d reduction for P T H secretion. The impaired renal concentrating capacity observed in some hypercalcemic patients is probably a manifestation of a homeostatically important integration of the regulation of renal calcium and water handling that decreases the risk of pathological deposition of calcium in the kidney w h e n there is a need to get rid of excessive calcium in the urine. In this regard, the h u m a n syndromes of Ca2o+ " r e s i s t a n c e " or " o v e r r e s p o n s i v e n s s " due to loss- or gain-of-function C a R mutations, respectively, have p r o vided useful experiments-in-nature that have helped to elucidate the importance of the C a R in normal physiology as well as in pathophysiology. M u c h remains to be learned, however, about the role of the C a R in places w h e r e it likely responds to changes in local rather than systemic levels of Ca 2+o, such as in the brain. In these locations, it m a y be an important modulator of the functions of neurons, responding to Ca 2+ as a n e u r o m o d u lator or even neurotransmitter. D e v e l o p m e n t of CaRbased therapeutics that either activate 124,125or inhibit the receptor m a y be very useful for treating a variety of disorders where the C a R is either under- or overactive, respectively. Finally, it w o u l d not be surprising if there were additional receptors for Ca 2+ or for other ions (the C a R may, in fact, function as a M g 2+ sensor), which

could malfunction in disease states and be a m e n a b l e to pharmacological manipulation with appropriate receptorbased drugs.

Acknowledgments The authors gratefully acknowledge the generous grant support of the USPHS (DK41415, 44588, 46422, and 48330 to E.M.B.; DK02138 to M.P.; and DK09436 to M.B.) as well as NPS Pharmaceuticals, Inc., and the St. Giles Foundation (to E.M.B.).

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2HAPTER

1:

Hypoparathyroidism and P s eudohyp op arathyroi di s in MICHAEL A.

I. II. III. IV. V.

LEVINE

Division of Endocrinology and Metabolism, Department of Medicine, The Johns Hopkins University School of Medicine, Baltimore, Maryland 21205

Introduction Pathophysiology of Hypocalcemia Signs and Symptoms of Hypocalcemia Specific Causes of Functional Hypoparathyroidism Pseudohypoparathyroidism

VI. Diagnosis VII. Treatment VIII. Conclusion Acknowledgments References

only 1% of the total body calcium within extracellular fluids and soft tissues. Calcium exists within three fractions in the serum: ---50% of serum calcium is ionized at normal plasma protein concentrations, ---10% is complexed to citrate and phosphate ions, and ---40% is protein bound. 1 Although conventional measurement of serum calcium implies determination of the total serum calcium concentration, more physiologically relevant information is obtained by measurement of the ionized calcium concentration. From a practical point of view, measurement of total serum calcium concentration provides a reasonable estimate of the ionized calcium concentration, but several caveats are worth noting. For example, decreased concentration of serum albumin, the major calcium-binding protein in the circulation, rather than a decrease in the concentration of ionized calcium, accounts for most cases of low total serum calcium in hospitalized patients. Sudden changes in the distribution of calcium between ionized and bound fractions may cause symptoms of hypocalcemia, even in patients who have normal hormonal mechanisms for the regulation of the ionized calcium concentration. Increases in the extracellular fluid

I. I N T R O D U C T I O N The term "functional hypoparathyroidism" refers to a group of metabolic syndromes in which hypocalcemia and hyperphosphatemia occur either from a failure of the parathyroid glands to secrete adequate amounts of biologically active parathyroid hormone (PTH) or, less commonly, from an inability of PTH to elicit appropriate biological responses in its target tissues. Plasma levels of PTH are typically reduced or absent in patients with true hypoparathyroidism. By contrast, patients with pseudohypoparathyroidism (PHP) have target tissue resistance to PTH that results in characteristically elevated plasma levels of PTH. Thus true hypoparathyroidism differs fundamentally and biochemically from PHP. Hypocalcemia is the biochemical hallmark of functional hypoparathyroidism. The serum concentration of calcium is normally maintained within narrow limits despite wide variations in dietary intake, the demands of the skeleton during growth, and losses during pregnancy and lactation. Approximately 99% of total body calcium is in the skeleton in the form of hydroxyapatite, leaving

METABOLIC BONE D I S E A S E

501


502 (ECF) concentration of anions, such as phosphate citrate, bicarbonate, or edetic acid, will increase the proportion of bound calcium and decrease ionized calcium until intact regulatory mechanisms normalize ionized calcium. Extracellular fluid pH also affects the distribution of calcium between ionized and bound fractions. Acidosis increases the ionized calcium, whereas alkalosis decreases it. Therefore, measurement of ionized calcium is preferred when evaluating symptoms of hypocalcemia in patients who have abnormal circulating proteins or normal levels of total serum calcium. 2 Plasma levels of ionized calcium can be measured in most clinical chemistry laboratories using now-standardized techniques. 3-5 However, when it is not possible, or practical, to determine the ionized calcium concentration directly, a "corrected" total calcium concentration can be derived using one of several proposed algorithms that are based on albumin or total protein concentrations. 2'6 None of these correction factors is absolutely accurate, but they often provide useful estimates of the true concentration of calcium in serum. 7 One widely used algorithm estimates that total serum calcium declines by approximately 0.8 mg/dl for each 1 g/dl decrease in albumin concentration, without a change in ionized calcium.

II. P A T H O P H Y S I O L O G Y OF HYPOCALCEMIA The concentration of extracellular ionized calcium is tightly regulated by PTH and 1,25-dihydroxyvitamin D [1,25(OH)zD; calcitriol]. PTH is synthesized in the four parathyroid glands as a preprohormone (115 amino acids), converted to a prohormone (90 amino acids) as it is transported across the rough endoplasmic reticulum, and stored in secretory granules as the mature 84-aminoacid hormone. PTH is secreted at a rate inversely proportional to the ambient serum ionized calcium concentration. Hormone secretion is tightly regulated through the interaction of extracellular calcium (and to a lesser extent other divalent cations) with specific calciumsensing receptors 3-1~ that are present on the surface of the parathyroid cell. Extracellular calcium stimulates a receptor-dependent signaling pathway that leads to the rapid but transient increase in intracellular calcium; the increase in cytosolic calcium inhibits release of PTH from the parathyroid cell. By contrast, PTH synthesis and secretion are increased when the extracellular calcium concentration is low. Over time, protracted hypocalcemia leads not only to increased PTH secretion but also to increased parathyroid gland mass. Fluctuations in the serum calcium concentration provoke rapid changes in PTH secretion that within minutes affect distal tubular calcium reabsorption and osteoclas-

MICHAEL A. LEVINE

tic bone resorption. In contrast to this short-loop feedback system, adjustments in the rate of gastrointestinal absorption of calcium via the P T H - v i t a m i n D axis occur over 1 to 2 days and constitute a long-loop feedback system. The integrated actions of PTH on these target tissues provides a precise system of control and maintains the serum ionized calcium concentration within a narrow range. PTH has direct effects on bone to regulate calcium exchange at osteocytic sites and to enhance osteoclastmediated bone resorption. In the kidney, PTH directly enhances distal tubular reabsorption of calcium, decreases the proximal tubular reabsorption of phosphate, and stimulates the metabolic conversion of 25-hydroxyvitamin D [25(OH)D] to 1,25(OH)2D, the active vitamin D metabolite. 1,25(OH)2D acts on bone to enhance bone resorption and on the gastrointestinal mucosa to increase absorption of dietary calcium. PTH exerts its effects on the target cells in bone and kidney by binding to specific membrane receptors that are coupled via guanine-nucleotide-binding proteins (G proteins) to the signal-generating enzymes adenylyl cyclase and phospholipase C (Fig. 17-1). The initial event in the expression of PTH action is binding of the hormone to specific receptors located on the plasma membrane of target cells. Molecular cloning of cDNAs encoding PTH receptors from several species ~1-~4 has indicated that bone and kidney cells express an identical receptor that binds PTH and parathyroid hormone-

Ri

PTH/PTHrPRc

G

PIP2~~ cAMP

1

PKA FIGURE 17-- 1

.

IP3

§

DAG PKC

Cell surface receptors for PTH are coupled to two classes of G proteins. Gs mediates stimulation of adenylyl cyclase (AC) and the production of cAME which in turn activates protein kinase A (PKA). Gq stimulates phospholipase C (PLC) to form the second messengers inositol-(1,4,5)-trisphosphate (IP3) and diacylglycerol (DAG) from membrane-bound phosphatidylinositol-(4,5)bisphosphate. IP3 increases intracellular calcium (Ca 2+) and DAG stimulates protein kinase C (PKC) activity. Each G protein consists of a unique oL chain and a [3~/dimer.

503

CHAPTER 17 Hypoparathyroidism and Pseudohypoparathyroidism related protein (PTHrP) with equivalent affinity. The PTH/PTHrP receptor is a member of a superfamily of receptor proteins that span the membrane in a serpentine fashion, threading themselves across the lipid bylayer through a series of seven o~-helical domains. These receptors are coupled by heterotrimeric (c~[3~/) G proteins 15 to signal effector molecules localized to the inner surface of the plasma membrane (Fig. 17-1). Highly specific associations among at least 20 G~, five G~, and 12 Gv chains generate a diversity of heterotrimeric G proteins that have the ability to discriminate amongst a multitude of receptor and effector molecules. Hormone binding to a receptor facilitates activation of the G protein, a process in which the oL chain exchanges bound guanosine diphosphate (GDP) for guanosine triphosphate (GTP) and dissociates from the [3~/dimer and the receptor. The free, GTP-bound form of the oL chain is the primary modulator of relevant effector molecules, although [3~/ dimers can also influence activity of many effectors (e.g., some forms of adenylyl cyclase and phospholipase C). An intrinsic GTPase associated with the oL chain acts as a molecular timing mechanism, and after a predetermined interval GTP is hydrolyzed to GDE The inactive GDP-bound oL chain reassociates with a [3~/ dimer, and the heterotrimeric G protein is ready for another cycle of hormone activation. Hormone binding to the PTH/PTHrP receptor is followed rapidly by the generation of a variety of second messengers, 16'17 including c A M E 18'19 inositol 1,4,5trisphosphate and diacylglycerol, 2~ and cytosolic calcium, 23'24 indicating that a single PTH/PTHrP receptor can couple not only to Gs to stimulate adenylyl cyclase, but also to Gq and GI~ to stimulate phospholipase C (Fig. 17-1). The best characterized mediator of PTH action is cyclic adenosine monophosphate (cAMP), which rapidly activates protein ldnase A. 25 The relevant target proteins that are phosphorylated by protein kinase A and precise mode(s) of action of these proteins remain uncharacterized, though metabolic enzymes, transcription factors, and ion channel proteins are strong candidates. The intracellular accumulation of cAMP triggers a biochemical chain reaction that begins with phosphorylation of specific protein substrates by cAMP-activated protein kinase A, and ultimately concludes with the physiological response of the cell to agonist recognition. In contrast to the well-recognized biological effects of cAMP in PTH target tissues, the physiological importance of metabolites of phosphotidylinositol and intracellular calcium as PTH-induced second messengers has not yet been established. Clinical disorders causing hypocalcemia occur if the production of biologically active PTH or 1,25(OH)2D is impaired or if target organ responses to these hormones are abnormal, either because of a specific biochemical

defect or because of generalized target organ damage (Table 17-1). In the hypoparathyroid states, in which PTH secretion or action is deficient, the normal effects of PTH on bone and kidney are absent. Bone resorption, and release of calcium from skeletal stores, is diminished. Renal tubular reabsorption of calcium is decreased, but because of hypocalcemia and low filtered load, urinary calcium excretion is low. In the absence of PTH action, urinary clearance of phosphate is decreased, and hyperphosphatemia is common. The deficiency of PTH action and the hyperphosphatemia impair renal production of

TABLE 17-- 1 Clinical Disorders Causing Hypocalcemia Hypoproteinemia (factitious or "pseudohypocalcemia") Hypoparathyroidism (inadequate secretion of PTH) Postsurgical Toxic agents (alcohol, irradiation) Developmental disorders of the parathyroid gland Magnesium excess or deficiency Idiopathic Autoimmune Genetic defects in the PTH gene Genetic defects in the calcium-sensing receptor gene Infiltration (iron, copper, tumor) Transient neonatal hypoparathyroidism Resistance to PTH action Pseudohypoparathyroidism Hypomagnesemia Disorders of vitamin D metabolism Decreased precursors Dietary deficiency Malabsorption Nephrotic syndrome or peritoneal dialysis Liver disease Disrupted enterohepatic circulation Decreased metabolic activation Renal disease 1oL-hydroxylasedeficiency (vitamin D-dependent rickets, type I) Resistance to vitamin D action Genetic defects in the vitamin D receptor (vitamin D-dependent rickets, type II) Decreased bone resorption Antiresorptive drug treatment Increased bone formation Hungry bones Osteoblastic tumor metastasis Miscellaneous Hyperphosphatemia Rhabdomyolysis Tumor lysis Phosphate infusion, ingestion, enema Citrate administration Respiratory alkalosis Acute severe illness (pancreatitis, burns, sepsis)

504

MICHAEL A. LEVINE

1,25(OH)2D. The low circulating levels of 1,25(OH)2D result in reduced intestinal calcium absorption as well as decreased bone resorption. Functional hypoparathyroidism, therefore, is characterized by a decreased entry of calcium into the extracellular fluid compartment from bone, kidney, and intestine and is associated with hypocalcemia and hyperphosphatemia. In states of vitamin D deficiency or vitamin D insensitivity, absorption of calcium from the intestine is markedly impaired. 1,25(OH)2D is also a potent stimulator of bone resorption, and its absence may also decrease the availability of calcium from bone. Because the parathyroid glands are intact in the vitamin D-deficient states, hypocalcemia induces secondary hyperparathyroidism and renal phosphate clearance is enhanced. Thus, hypocalcemia in vitamin D deficiency results from decreased intestinal absorption of calcium and a limited availability of calcium from bone despite secondary hyperparathyroidism; characteristically, it is accompanied by hypophosphatemia.

III. SIGNS

serum calcium levels27; thus, this sign cannot be considered diagnostic of hypocalcemia unless it is known that it was previously absent. Trousseau's sign is present if carpal spasm occurs after compression of the nerves in the upper arm. A typical protocol consists of inflation

AND SYMPTOMS

OF HYPOCALCEMIA Ionized calcium, rather than total calcium, is the primary determinant of symptoms in patients with hypocalcemia. A low extracellular fluid ionized calcium concentration enhances neuromuscular excitability, an effect that is potentiated by hypomagnesemia. 26 There is substantial variation among patients in the severity of symptoms, and there does not appear to be an absolute level of serum calcium at which symptoms can be expected. Patients with chronic hypocalcemia sometimes have few, if any, symptoms of neuromuscular irritability despite markedly depressed serum calcium concentrations. By contrast, patients with acute hypocalcemia frequently manifest many symptoms of tetany. Most patients with hypocalcemia will have some mild features of tetany, including circumoral numbness, paresthesias of the distal extremities, or muscle cramps. Symptoms of fatigue, hyperirritability, anxiety, and depression are also common. Clinical manifestations of marked hypocalcemia consist of carpopedal spasm, laryngospasm, and focal or sometimes life-threatening generalized seizures (which must be distinguished from the generalized tonic muscle contractions that occur in severe tetany). Clinical signs of the neuromuscular irritability associated with latent tetany include Chvostek's sign and Trousseau's sign. Chvostek's sign is elicited by tapping the facial nerve just anterior to the ear to produce ipsilateral contraction of the facial muscles. Slightly positive reactions occur in 10% to 30% of adults with normal

FIGURE 17--2 Electrocardiogram (ECG) of a patient with severe hypocalcemia. This ECG demonstrates the characteristic prolongation of the (corrected) QT interval, measured from the beginning of the QRS complex to the end of the T wave (arrows in bottom panel). The QT interval corresponds to the duration of ventricular depolarization and repolarization. The interval increases with decreasing heart rate and may be corrected (QTc) by measuring the RR interval and employing the following formula: QTc = QT/~v/(R - R). The second or plateau phase (ST segment) of the action potential is influenced by the serum calcium, and is of greater duration in hypocalcemic subjects. As the exact end of the T wave may be difficult to determine, some clinicians utilize the Q,Tc interval, which comprises the onset of the QRS complex to the apex of the T wave. [From Becker KL (ed): Principles and Practice of Endocrinology and Metabolism, 2nd ed. Philadelphia, JB Lippincott, 1995, with permission.]

CHAPTER 17 Hypoparathyroidism and Pseudohypoparathyroidism of a cuff on the upper arm to above systolic blood pressure for 3 to 5 minutes. Both of these signs can be absent even in patients with definite hypocalcemia. Hypocalcemia is also associated with nonspecific electroencephalographic changes, increases in intracranial pressure, and papilledema. A markedly depressed serum calcium concentration can have profound affects on the heart. The corrected QT (QTc) interval may be prolonged on the electrocardiogram (Fig. 17-2), and may be associated with arrhythmias or cardiac dysfunction that is generally reversible with treatment of the hypocalcemia. 28'29 Cardiac dysfunction may range from mild abnormality that is noted only with exercise 3~ to life-threatening heart failure. 31 The somatosensoryevoked potential recovery period may provide a useful tool for assessing the effects and recovery from hypocalcemia. 32 Additional signs may be associated with longstanding hypocalcemia. Ectodermal findings such as dry skin, coarse hair, and brittle nails are common, but they are frequently overlooked. Dental and enamel hypoplasia and absence of adult teeth indicate that hypocalcemia has been present since childhood. 33-35 The pattern of dental abnormality can be used to determine the age at which the patient first developed hypocalcemia. Calcification of the basal ganglia, and to a lesser extent the cerebral cortex, occurs in all forms of hypoparathyroidism and can be detected by computed tomographic (CT) scanning even when routine skull radiographs do not demonstrate intracerebral calcification. 36'37 Rarely, calcification of the basal ganglia is associated with neurological signs or symptoms that resemble Parkinson's disease or chorea. 38 An unusual neurological manifestation of hypocalcemia is an increased susceptibility to dystonic reactions induced by phenothiazines. 39 Subcapsular cataracts are common in untreated hypoparathyroidism and are most readily detected by slit lamp examination. Treatment may reverse or decrease the progression of the cataracts. Rickets and osteomalacia, although not characteristic, do occur occasionally in hypoparathyroidism after prolonged hypocalcemia. 4~ Patients with longstanding hypoparathyroidism have been reported to have significantly increased bone mineral density 42 whether they are treated 43 or not. 44

IV. SPECIFIC FUNCTIONAL

CAUSES

OF

HYPOPARATHYROIDISM

A. S u r g e r y a n d T o x i c A g e n t s Surgery is the most common cause of acquired hypoparathyroidism. Hypoparathyroidism may occur after parathyroid or thyroid surgery or after radical surgery

505 for laryngeal or esophageal carcinoma. 45 The resulting hypoparathyroidism can be transient or permanent, and sometimes may not develop for many years. 46 A chronic state of "decreased parathyroid reserve ''46 may exist in some patients who manifest hypocalcemia only when mineral homeostasis is stressed further by other factors such as pregnancy, lactation, or illness. Hypocalcemia occurs soon after removal of a hyperfunctioning parathyroid adenoma because the remaining parathyroid tissue is "suppressed" by previous hypercalcemia and is unable to secrete adequate amount of PTH. Hypoparathyroidism is usually transient because the normal parathyroid glands recover function quickly (generally within 1 week), even after long-term suppression. Transient postoperative hypocalcemia may be exaggerated or prolonged in those patients who have significant preexisting hyperparathyroid bone disease. In these patients the acute reduction of previously elevated serum levels of PTH results in an increased movement of serum calcium (and phosphorus) into remineralizing "hungry bones. ''47 Treatment with calcium and a short-acting vitamin D metabolite may be required until the bones heal. Permanent hypoparathyroidism is unusual after an initial neck exploration for primary hyperparathyroidism and develops in fewer than 1% to 2% of patients. The incidence is greatly increased with repeated neck surgery for recurrent or persistent hyperparathyroidism, after subtotal parathyroidectomy for parathyroid hyperplasia, or when surgery is performed by an inexperienced operator. The incidence of permanent hypoparathyroidism after thyroid surgery varies widely, and reflects the underlying thyroid lesion, the extent of surgery, and the experience of the surgeon. Hypoparathyroidism may occur as a result of direct injury or inadvertent removal or devascularization of the parathyroid glands. Permanent hypoparathyroidism is unlikely to occur after a hemithyroidectomy and should be relatively uncommon even after total thyroidectomy. 48'49 By contrast, transient hypoparathyroidism may occur in up to 33% of patients who undergo a total thyroidectomy for thyroid cancer 5~ or thyrotoxicosis. The fall in plasma calcium level generally occurs within 24 to 48 hours after surgery and often is sufficient to provoke symptoms of tetany. The basis for this acute hypocalcemia is not well understood. One mechanism that has been proposed for patients with thyrotoxicosis is similar to the "hungry bones" phenomenon that occurs after parathyroid surgery in patients with marked primary hyperparathyroidism. 51 Patients with severe hyperthyroidism often have increased bone resorption, elevated plasma ionized calcium levels, and suppressed parathyroid function. Although it has been proposed that hypocalcemia occurs as calcium moves rapidly into remineralizing bones after surgical correc-

506 tion of thyrotoxicosis, 52 the early development of hypocalcemia after surgery often precedes significant reduction of serum levels of thyroid hormones. A more likely explanation is that unappreciated damage has occurred to the parathyroid glands during surgery. Whatever the initiating cause, the development of hypocalcemia must indicate that the secretory response of the parathyroid glands is inadequate to maintain a normal serum calcium concentration.53'54 1. RADIATION AND DRUGS

In contrast to many other endocrine tissues, the parathyroid glands are particularly resistant to damage by a great many toxic agents. The administration of radioactive iodine for the treatment of benign or malignant thyroid disease or for the deliberate induction of hypothyroidism has only rarely caused permanent, symptomatic hypoparathyroidism. Similarly, external beam radiation appears to have little or no effect on parathyroid gland function. Parathyroid function is altered only occasionally by most chemotherapeutic or cytotoxic agents. Notable exceptions include asparaginase, which causes parathyroid necrosis in rabbits, and ethiofos, a radio- and chemoprotector that causes a dose-dependent and reversible inhibition of PTH secretion. 55'56 Along with its effects on the parathyroid gland, ethiofos also inhibits osteoclast activity. Thus, a significant component of its calcium-reducing effect derives from the ability of this agent to inhibit osteoclast-directed bone resorption and calcium release from skeletal stores. The most common toxic agent to affect parathyroid function is alcohol. 57 Transient hypoparathyroidism has been associated with ingestion of large quantities of alcohol. 58'59 2. INFILTRATIVE DISEASE OF THE PARATHYROIDS Infiltrative processes that affect the parathyroid gland may impair gland function and inhibit release of PTH. Idiopathic hemochromatosis and chronic transfusion therapy are often associated with significant deposition of iron in the parathyroid glands. 6~ Patients occasionally develop clinical hypoparathyroidism, but more commonly manifest decreased "parathyroid reserve" as a consequence of iron infiltration. 61 A similar pathophysiological process has been described in one patient with Wilson's disease and increased copper storage who developed symptomatic hypoparathyroidism. 62 Pathological involvement of the parathyroid glands can also occur in metastatic neoplasia, miliary tuberculosis, amyloidosis, and sarcoid, but clinical hypoparathyroidism rarely occurs in these conditions. 3. MAGNESIUM DEFICIENCY AND EXCESS

Although calcium is the major regulator of PTH secretion, magnesium can modulate PTH secretion in a

MICHAEL A. LEVINE

similar manner. Recent studies show that magnesium has approximately 30% to 50% of the effect of calcium on either stimulating or suppressing PTH secretion. 63 Hypermagnesemia may cause reversible hypocalcemia. This situation is most commonly encountered in obstetrical practice when high-dose magnesium infusions are used for the treatment of toxemia or premature labor. 64'65 Because the hypocalcemia is accompanied by significant hypermagnesemia, neuromuscular irritability should be less than that expected when similar calcium concentrations occur with normal magnesium; clinical tetany usually does not o c c u r . 26 While elevations in extracellular magnesium can suppress PTH secretion and lower serum calcium levels, hypocalcemia is more often a manifestation of magnesium depletion, 65 particularly in patients with chronic alcoholism. 55 As the serum magnesium level falls, the parathyroid gland responds by increasing secretion of PTH. However, as intracellular magnesium depletion develops, the ability of the parathyroid gland to secrete PTH is impaired, and hypocalcemia may ensue. 67 Magnesium depletion must become severe before symptomatic hypocalcemia occurs, but even mild degrees of magnesium depletion may result in a significant reduction in the serum calcium level. The majority of patients with magnesium depletion have low levels of PTH, or "normal" levels of PTH that are in fact inappropriate for the degree of hypocalcemia. 68 Therefore, a state of relative or functional hypoparathyroidism exists in these patients. By contrast, serum levels of PTH are elevated in hypocalcemic patients who have more severe magnesium depletion. 67-69 These patients show an impaired response to exogenous PTH, suggesting that refractoriness to PTH may develop with increasing degrees of magnesium depletion. Hypocalcemia can be readily reversed by magnesium therapy alone, but is not corrected by administration of calcium or vitamin D.

B. I d i o p a t h i c H y p o p a r a t h y r o i d i s m The term "idiopathic hypoparathyroidism" describes a heterogeneous group of rare disorders that share in common deficient secretion of PTH. The use of the term "idiopathic" to describe this group of disorders has greater historical than scientific relevance at present, as recent molecular and biochemical studies have revealed the cause of hypoparathyroidism in many of these disorders. Accordingly, the term "idiopathic" is a misnomer for many of these conditions. Although most cases are sporadic, the familial occurrence of idiopathic hypoparathyroidism has been reported. Within these families hypoparathyroidism may occur as part of a complex autoimmune disorder associated with multiple endocrine deficiencies (i.e., type 1 polyglandular syndrome) or in

CHAPTER 17 Hypoparathyroidism and Pseudohypoparathyroidism association with diverse developmental abnormalities (e.g., nephropathy, lymphedema, nerve deafness, or tetralogy of Fallot). The pleiotropic nature of many of these various syndromes has suggested that the genetic basis of PTH deficiency is not related to a specific defect intrinsic to the parathyroid gland.

C. Autoimmune Hypoparathyroidism Autoimmune hypoparathyroidism may occur alone or as a component of the type 1 polyglandular syndrome. TM The type 1 polyglandular syndrome may be sporadic or familial with an autosomal recessive inheritance pattern. vl The classic triad of this syndrome is hypoparathyroidism, adrenal insufficiency, and mucocutaneous candidiasis (HAM). The recognition that affected patients may have additional components has led to the suggestion that a more inclusive term be used to describe the syndrome: autoimmune polyendocrinopathy-candidiasisectodermal dystrophy (APECED). vl'v2 The syndrome is generally first recognized in early childhood, although a few individuals have developed the condition after the first decade of life. The clinical onset of the three principal components of the syndrome typically follows a predictable pattern, in which mucocutaneous candidiasis first appears at a mean age of 5 years, followed by hypoparathyroidism at a mean age of 9 years and adrenal insufficiency at a mean age of 14 years, v~ Patients may not manifest all three components of the clinical triad. Additional features occur in some patients, such as alopecia, keratoconjunctivitis, malabsorption and steatorrhea, gonadal failure, pernicious anemia, chronic active hepatitis, thyroid disease, and insulin-requiting diabetes mellitus. Antibodies directed against the parathyroid, thyroid, and adrenal glands are present in many patients v3 and a T-cell abnormality has been described. TM The presence of antibodies may not correlate well with the clinical findings. In those cases that have been examined pathologically, complete parathyroid atrophy or destruction has been demonstrated. In some patients, treatment of hypoparathyroidism has been complicated by apparent vitamin D "resistance," possibly related to coexistent hepatic disease or steatorrhea, or both. Despite increasing appreciation of the clinical and genetic features of this syndrome, the molecular basis for APECED remains unknown.

D. Isolated Hypoparathyroidism Isolated hypoparathyroidism, in which PTH deficiency is not associated with other endocrine disorders or developmental defects, is usually sporadic, but it may

507 occur on a familial basis. The age of onset is generally within the first decade, although hypocalcemia may not be first discovered until later in adult life. There is a high incidence of parathyroid antibodies in patients with isolated idiopathic hypoparathyroidism, and some cases may be examples of incomplete expression of the polyglandular type 1 syndrome (above). Some patients may possess antibodies that inhibit the secretion of PTH v5 rather than cause parathyroid gland destruction. 76 In other cases that have been examined pathologically, fatty replacement vv or atrophy with fatty infiltration and fibrosis TM has been described. Isolated hypoparathyroidism may be sporadic or familial, with inheritance of PTH deficiency by autosomal dominant, autosomal recessive, or X-linked modes of transmission, v9 The age at onset covers a broad range (1 month to 30 years), and the condition is often recognized first in the child rather than in the parent. Parathyroid antibodies are absent. As the location of the preproPTH gene has been mapped to l lp15, molecular genetic studies of familial isolated hypoparathyroidism have focused on kindreds in which inheritance of hypoparathyroidism is consistent with an autosomal mode of transmission. Genetic analysis of one pedigree in which hypoparathyroidism was inherited in an autosomal dominant manner showed linkage of hypoparathyroidism to the preproPTH gene locus. 8~ Subsequent DNA sequence analysis of the preproPTH gene in this kindred revealed that affected members had a heterozygous mutation consisting of a single base substitution (T ~ C) in exon 2. 81 This mutation results in the substitution of arginine (CGT) for cysteine (TGT) in the leader sequence of preproPTH. The substitution of a charged amino acid in the midst of the hydrophobic core of the leader sequence inhibits processing of the mutant preproPTH molecule to proPTH by signal peptidase 81 and is presumed to impair translocation of not only the mutant hormone but also the wild-type protein across the plasma membrane of the endoplasmic reticulum. Thus, this heterozygous mutation results in a dominant inhibitor phenotype that prevents processing of the wild-type preproPTH molecule. Familial hypoparathyroidism can also be transmitted as an autosomal recessive trait. An abnormality of the preproPTH gene has been found in one consanguineous family with autosomal recessive hypoparathyroidism. 82 Affected members of this family are homozygous for a single base transversion (G ~ C) at the exon 2-intron 2 boundary. This mutation alters the invariant gt dinucleotide of the 5' donor splice site that presumably affects annealing of the U 1-snRNP recognition component of the nuclear RNA splicing enzyme. Previous studies of similar donor splice site mutations in other genes have demonstrated that such mutations impair normal process-

508

ing of the nascent in mRNA. As PTH gene expression is generally confined to the parathyroid cell, analysis of preproPTH mRNA processing in these patients required reverse transcriptase polymerase chain reaction (RTPCR) to detect "illegitimate" or "ectopic" transcription of the PTH gene in cultured lymphoblasts. 82 Using this approach, a PTH cDNA that was 90 bp shorter than the corresponding wild-type form was amplified from cultured lymphoblasts of affected subjects. Nucleotide sequence analysis of the shortened cDNA revealed that exon 1 had been spliced to exon 3 in the mutant PTH mRNA, a process that resulted in the deletion of exon 2 from the mature transcript (i.e., exon skipping). 82 The loss of exon 2 eliminates both the initiation codon and the signal peptide sequence from the aberrant preproPTH mRNA, and explains the molecular basis for autosomal recessive hypoparathyroidism in this family. Although the molecular pathophysiology of hypoparathyroidism has been defined in these two families, both linkage analysis and gene sequencing have failed to disclose defects in the preproPTH gene in affected members of other autosomal kindreds. 8~ New insights into the molecular pathology of hypoparathyroidism have come from the recent cloning and characterization of the cDNA 9 and gene 85 encoding the calcium-sensing receptor, the cell surface protein that determines the calcium "set-point" of the parathyroid cell and thereby controls calcium-sensitive secretion of PTH. Initial studies demonstrated that heterozygous mutations that result in the loss of function of the calcium-sensing receptor are present in most patients with familial (benign) hypocalciuric hypercalcemia (FHH), an autosomal dominant disorder associated with decreased ability of calcium to suppress PTH secretion. 85-88 In several families some affected members have homozygous mutations that cause severe neonatal hyperparathyroidism, 89 a life-threatening hypercalcemic disorder in which parathyroid hyperplasia occurs. By contrast, mutations that lead to gain of function have been identified in several kindreds with autosomal dominant hypocalcemia, a syndrome associated with low serum levels of PTH and relative hypercalciuria. 9~ In other cases, linkage of hypocalcemia to the chromosomal locus for the calciumsensing receptor (3q21-24) has provided indirect evidence for the involvement of this gene with familial hypoparathyroidism. 92 Preliminary studies have identified similar activating mutations of the calcium-sensing receptor gene in many patients with sporadic hypoparathyroidism. In both familial and sporadic cases, each affected propositus has demonstrated a unique mutation, suggesting that new mutations must sustain this disorder in the population. These remarkable results suggest that mutation of calcium-sensing receptor gene may be the most common cause of genetic hypoparathyroidism.

MICHAEL A. LEVINE

The calcium-sensing receptor is expressed not only in the parathyroid gland but also in the kidney, where it appears to play an important role in regulating calcium reabsorption. 8'93'94Thus, loss of function mutations of the calcium-sensing receptor in patients with FHH is associated with decreased calcium clearance and hypocalciuria. By contrast, gain of function mutations in the calcium-sensing receptor are likely to account for the increased calcium clearance and relative hypercalciuria noted in patients with autosomal dominant hypocalcemia. Familial hypoparathyroidism can also be inherited as an X-linked disorder that is of course unrelated to specific defects in the preproPTH gene on chromosome 11. 95 Using a battery of X-chromosome gene markers, linkage studies of two large multigenerational families with X-linked hypoparathyroidism have localized a candidate gene to the region Xq26-27. 96 These results imply that the defective gene or genes in this syndrome may be important for parathyroid cell development or function. The early onset of hypocalcemia in affected individuals, and the apparent inability to identify parathyroid tissue in a single patient with this disorder at autopsy, 79 are consistent with a role for this genetic locus in the embryological development of the parathyroid glands (see below).

E. D e v e l o p m e n t a l D i s o r d e r s o f the Parathyroid Gland Hypoparathyroidism may result from agenesis or dysgenesis of the parathyroid glands. The most welldescribed example of parathyroid gland dysembryogenesis is the DiGeorge syndrome, in which maldevelopment of the third and fourth branchial pouches is frequently associated with congenital absence of not only the parathyroids but also the thymus. Because of thymic aplasia, T-cell-mediated immunity is impaired, and affected infants have an increased susceptibility to recurrent viral and fungal infections. Maldevelopment of the first and fifth branchial pouches occurs frequently as well, producing characteristic facial anomalies (Fig. 17-3), including hypertelorism; antimongoloid slant of the eyes; low-set and notched ears; short philtrum of the lip; and micrognathia (first branchial pouch); or aortic arch abnormalities, such as fight-sided arch, truncus arteriosus, or tetralogy of Fallot. Most cases of branchial pouch dysembryogenesis are sporadic, but familial occurrence with apparent autosomal dominant inheritance has been described. 97'98 Molecular mapping studies have demonstrated an association between the syndrome and deletions involving 22qll 99-1~ or 10p 1~176 in some patients, although it is important to note that most patients with

CHAPTER 17 Hypoparathyroidismand Pseudohypoparathyroidism

509

FIGURE 17--3

Photograph of an 18-month-old boy with DiGeorge syndrome showing characteristic features including mild hypertelorism; increased antimongoloid slant of the eyes; low-set, asymmetrical, malformed ears; and a short philtrum. Other features depicted are a broad nose, cupid bow mouth, and mandibular hypoplasia. Chest radiograph revealed a right-sided aortic arch and an absent thymic shadow. [From Kretschmer R, Say B, Brown D, Rosen F: Congenital aplasia of the thymus gland (DiGeorge's syndrome). N Engl J Med 279:1295, 1968.]

DiGeorge syndrome have normal karyotypes. A candidate gene (rnex 40) which encodes a putative DNAbinding protein that shares homology with the androgen receptor has been identified in this region. 1~ The loss of genetic material at 22qll results in hemizygosity of genes located in this region, and is associated with contiguous gene deletion syndromes that include not only the DiGeorge syndrome but also the overlapping conotruncal anomaly and velocardiofacial syndromes. 1~ Although most affected children with DiGeorge syndrome die of infections or cardiac failure by the age of 6, survival into adolescence or adulthood is possible when the syndrome is only partially expressed. Hypoparathyroidism occurs in more than 50% of patients who have the Kenney-Caffey syndrome, an unusual syndrome characterized by short stature, osteosclerosis, basal ganglion calcifications, and ophthalmic d e f e c t s . 79'1~ Hypoparathyroidism also occurs as a component of several other less well-characterized developmental syndromes. These include the Barakat syndrome, associated with familial nephrosis and sensorineural deafness~~ a novel syndrome described in a single kindred in which two affected brothers had lymphedema, prolapsing mitral valve, brachytelephalangy, and nephropathy~~ and a recently reported syndrome in one consanguineous family in which affected members showed severe growth failure plus dysmorphic features that include microcephaly, beaked nose, and crognathia. 1~~

F. Neonatal Hypocalcemia Shortly after birth there is a physiological fall in the serum calcium concentration, and during the first 3 days of life many normal infants will have serum calcium levels that are less than 8 mg/dl. Hypocalcemia in the neonate can be divided into early hypocalcemia, starting within the first 24 to 72 hours of life before feedings have been given, and late hypocalcemia, usually appearing after several days to weeks of feeding. 111'112 1. EARLY NEONATAL HYPOCALCEMIA Early neonatal hypocalcemia represents an exaggeration of the normal fall in serum calcium concentration and theoretically is due to deficient release of PTH by immature parathyroid glands. 1~3 Prematurity, low birth weight, hypoglycemia, maternal diabetes, difficult delivery, and respiratory distress syndrome are frequently associated findings. Hypocalcemia may be asymptomatic, but can manifest as irritability, muscular twitching, or convulsive seizures. Although the course is self-limited, symptomatic infants should be treated with oral or intravenous calcium. A more severe form of transient neonatal hypoparathyroidism and tetany can occur in children born to mothers with primary hyperparathyroidism or other causes of hypercalcemia. In these infants, exposure in utero to maternal hypercalcemia suppresses

510

MICHAEL A. LEVINE

parathyroid activity and apparently leads to impaired responsiveness of the parathyroid glands to hypocalcemia after birth. 1~4'115 2. LATE NEONATAL HYPOCALCEMIA Transient hypocalcemia that occurs 4 to 6 days (or later) after birth is considered to be a manifestation of relative immaturity of renal phosphorus handling or of the renal adenylyl cyclase system. Hypocalcemia may be precipitated by a high-phosphate diet and appears to occur particularly in those infants who are fed with artificial foods such as cow's m i l k - b a s e d formulas. ~16 In these infants, the renal response to PTH is inadequate and hypocalcemia ensues. The reduction of serum calcium ion concentration is probably secondary to elevated serum phosphate levels and should result in increased parathyroid gland activity. This form of hypocalcemia is the most common cause of seizures in the newborn period. Spontaneous recovery of normal mineral homeostasis typically occurs after a few weeks, but the serum calcium levels of symptomatic infants can be increased within 1 to 2 days by feeding a supplemented milk mixture with a high calcium/phosphorus (3:1 to 4:1) ratio.

due to an inability of the target organs, bone and kidney, to respond to PTH. In addition to the clinical and biochemical features of hypoparathyroidism, the patients described by Albright exhibited a distinctive constellation of developmental and skeletal defects, subsequently referred to as A1bright's hereditary osteodystrophy (AHO), and including a round face; short, stocky physique; brachydactyly; heterotopic ossification; and mental retardation. The relationship between the biochemical abnormalities (hypocalcemia and hyperphosphatemia) and A H O could not be explained by Albright, and yet remains unclarified. Indeed, in certain families some affected members may show both AHO and PTH resistance, whereas other family members may have A H O without evidence of any endocrine dysfunction, a disorder Albright termed "pseudopseudohypoparathyroidism" (pseudoPHP) to emphasize the physical similarities but biochemical differences between these patients and patients with PHE ~8 The diagnostic classification of PHP is further extended by the existence of additional variants in which patients manifest PTH resistance and biochemical hypoparathyroidism but lack any of the features of A H O . 119'12~ A classification of the many different forms of PHP is presented in Table 17-2.

V. P S E U D O H Y P O P A R A T H Y R O I D I S M In their original report of PHR Fuller Albright and his associates described the failure of patients with this syndrome to show a phosphaturic response to injected parathyroid extract, ll7 These observations led to the speculation that biochemical hypoparathyroidism in PHP was

TABLE 17--2

Characterization of the molecular basis for PHP commenced with the observations by Chase and Aurbach that cAMP mediates many of the actions of PTH on

Classification and Characteristic Features of the Various Forms of Pseudohypoparathyroidism PHP type Ia

Physical appearance

A. G e n e r a l P a t h o p h y s i o l o g y

PseudoPHP

PHP type Ib

PHP type Ic

PHP type II

Albright hereditary osteodystrophy, may be subtle or (rarely) absent

Normal

Albright hereditary osteodystrophy

Normal

Normal Normal Normal

Defective Defective Low

Defective Defective Low

Normal Defective Low

Hormone resistance

Defective Defective Low or (rarely) normal Generalized

Absent

Generalized

Gs~ activity Inheritance

Reduced Reduced Autosomal dominant

Normal Unknown

Limited to PTH target tissues Normal Unknown

Molecular d e f e c t

Heterozygous mutations in the GNAS1 gene

Limited to PTH target tissues Normal Autosomal dominant (most cases) Unknown (see t e x t )

Unknown

Unknown

Response to PTH Urine cAMP Urine phosphorous Serum calcium level

CHAPTER 17 Hypoparathyroidism and Pseudohypoparathyroidism kidney and bone, and that administration of biologically active PTH to normal subjects leads to a significant increase in the urinary excretion of nephrogenous cAMP and phosphate. 121 The PTH infusion test remains the most reliable test available for the diagnosis of PHP, and enables distinction between several variants of the syndrome (Fig. 17-4). Patients with PHP type I fail to show an appropriate increase in urinary excretion of both nephrogenous cAMP and phosphate, 121 suggesting that an abnormality in the renal PTH receptor-adenylyl cyclase complex that produces cAMP is the basis for impaired PTH responsiveness. Subsequent studies by Bell et al., in which administration of dibutyryl cAMP to patients with PHP type I produced a phosphaturic response, provided additional support for this theory, and demonstrated that the renal response mechanism to cAMP was intact. ~22 These studies have led to the conclusion that proximal renal tubule cells are unresponsive to PTH. By contrast, cells in other regions of the kidney appear responsive to PTH, as evidenced by the observation that urinary calcium excretion in patients with PHP type I is less than in patients with hormonopenic hypoparathyroidism after normalization of blood calcium levels in each group by vitamin D and oral calcium supplements. 123'124 Moreover, renal handling of calcium (and

FIGURE 17--4 Urinary cAMP excretion in response to an infusion of bovine parathyroid extract (300 USP units). The peak response in normal subjects (A) as well as those with pseudoPHP (not shown) is 50- to 100-fold times basal. Subjects with PHP type Ia (e) or PHP type Ib (o) show only a 2- to 5-fold increase. Urinary cAMP is expressed as nanomoles per deciliter (nM/dl) of GF, UcAMP(nM/dl GF) ~-~ UcAMP (nM/dl) • Scr e (mg/dl) UCr e (mg/dl). (From Levine MA, Jap TS, Mauseth RS, et al: Activity of the stimulatory guanine nucleotidebinding protein is reduced in erythrocytes from patients with pseudohypoparathyroidism and pseudopseudohypoparathyroidism: Biochemical, endocrine, and genetic analysis of Albright's hereditary osteodystrophy in six kindreds. J Clin Endocrinol Metab 62:497-502, 1986.)

511 sodium) in response to exogenous PTH also appears to be normal in patients with PHP type 1.125 These results indicate that calcium reabsorption in the distal tubule is responsive to circulating PTH in subjects with PHP type I, and imply that adequate amounts of cAMP are produced in these cells or that other second messengers (e.g., cytosolic calcium or diacylglycerol) may be responsible for PTH action (Fig. 17-1). Administration of PTH to subjects with the less common form of the disorder, PHP type II, produces a normal increase in urinary cAMP but fails to elicit an appropriate phosphaturic response. 119 These observations have suggested that PTH resistance in PHP type II resuits from a biochemical defect that is either unrelated or distal to the PTH-stimulated generation of cAMP. It has been generally assumed that bone cells in patients with PHP type I are innately resistant to PTH, but this remains unproved. In fact, cultured bone cells from a patient with PHP type I have been shown to increase intracellular cAMP normally in response to PTH treatment in v i t r o . 126 Evidence that bone cells are unresponsive to PTH is largely inferred from the observation that patients with PHP type I are hypocalcemic and that administration of PTH does not increase the plasma calcium level. However, clinical, roentgenographic, or histological evidence of increased bone turnover and demineralization (Fig. 1 7 - 5 ) is common in patients with PHP type I. There is a spectrum of bone disease in PHP: some subjects have apparently normal appearing bone, while others have radiological or histological evidence of significant bone resorption. 127 Patients with PHP type Ia typically have little or no evidence of diffuse skeletal involvement, while patients with PHP type Ib often demonstrate evidence of osteopenia or hyperparathyroid bone disease, including osteifis fibrosa cystica (Fig. 17-5). Cultured bone cells from one patient with PHP type Ib and osteitis fibrosa cystica were shown to have normal adenylyl cyclase responsiveness to PTH in vitro. 126 Patients with PHP may develop additional abnormalities in bone metabolism, including osteomalacia, 127 rickets, 128 renal osteodystrophy, 129 and osteopenia. 13~ These skeletal abnormalities result from excessive PTH or deficient 1,25(OH)2D3. One possible explanation for the variable bone responsiveness to PTH is the existence of two distinct cellular systems in bone upon which PTH exerts action: the remodeling system and the mineral mobilization or homeostatic system. The bone remodeling system appears to be more responsive to PTH in patients with PHP type I than the homeostatic system. This variability may reflect the lesser dependence of the remodeling system upon normal plasma levels of 1,25(OH)2D. Plasma levels of 1,25(OH)2D are reduced in hypocalcemic patients with PHP type I, 40 and could explain the concurrence of

512

FIGURE 17-5 Photograph and radiograph of hands of a patient with marked hyperparathyroid bone disease. Marked periosteal bone erosion in terminal phalanges has resulted in "pseudoclubbing." (From Levine MA, Parfrey NA, Feinstein RS: Pseudohypoparathyroidism. Johns Hopkins Med J 151:137-146, 1982.)

hypocalcemia and increased skeletal remodeling in many of these patients. Hypocalcemia leads to a compensatory overproduction of PTH, which could eventually overcome the 1,25(OH)2D dependency for remodeling but not for PTH-stimulated calcium mobilization. A role for 1,25(OH)2D in modulating the responsiveness of the calcium homeostatic system to PTH is suggested by several observations. First, the calcemic response to PTH is deficient not only in patients with PHP type I, but also in patients with other hypocalcemic disorders in which plasma levels of 1,25(OH)2D are low. Moreover, normalization of the plasma calcium level in patients with PHP type I by administration of physiological amounts of 1,25(OH)2D or pharmacological amounts of vitamin D restores calcemic responsiveness. TM Second, patients with PHP type I who have normal serum levels of calcium and 1,25(OH)2D3 without vitamin D treatment (so-called normocalcemic PHP) show a normal calcemic response to administered PTH. TM These findings suggest that 1,25(OH)2D deficiency is the basis for

MICHAEL A. LEVINE

the lack of a calcemic response to PTH in hypocalcemic patients with PHP type I, and challenge the premise that bone cells are intrinsically resistant to the actions of PTH. Subjects with PHP type I have increased serum levels of phosphate owing to an inability of PTH to decrease phosphate reabsorption in the kidney. Hypocalcemia p e r s e may also contribute to the development of hyperphosphatemia, as renal phosphate clearance is impaired by very low levels of intracellular calcium. Accordingly, restoration of plasma calcium levels to normal by chronic treatment with calcium and vitamin D can reduce elevated levels of serum phosphorus. Similar therapy has been shown to reverse the defective phosphaturic response to administered PTH in certain patients with PHP type I, although the urinary cAMP response remains markedly deficient. 132 Therefore, persistence of a blunted urinary cAMP response to PTH in PHP type I patients in whom chronic vitamin D therapy has led to normalization of plasma calcium levels and restoration of a phosphaturic response need not imply, as has been at least suggested, 132that there is no relationship between cAMP production and phosphate clearance. The overall evidence suggests that the disturbances in calcium, phosphorous, and vitamin D metabolism in most patients with PHP type I result directly or indirectly from reduced responsiveness of both bone and kidney to PTH. Hypocalcemia results from impaired mobilization of calcium from bone, reduced intestinal absorption of calcium [via deficient generation of 1,25(OH)2D], and urinary calcium loss. Of these defects, the diminished movement of calcium out of bone stores into the extracellular fluid probably has the greatest role in producing hypocalcemia. Intensive treatment with calcitriol [1,25(OH)2D] or other vitamin D analogs improves intestinal calcium absorption and bone calcium mobilization, restores plasma calcium to normal, and reduces circulating PTH levels. Thus, although PTH resistance appears to be the proximate biochemical defect, the major abnormalities in mineral metabolism found in patients with PHP type I can be largely explained on the basis of deficiency of circulating 1,25(OH)iD.

B. M o l e c u l a r Classification of P s e u d o h y p o p a r a t h y r o i d i s m Hormone action may be divided conceptually into prereceptor, receptor, and postreceptor events; defects in each of these steps have been proposed as the basis of hormone resistance in PHP (Fig. 17-1). For example, a circulating inhibitor of PTH action has been proposed as a cause of PTH resistance on the basis of studies showing an apparent dissociation between plasma levels of

CHAPTER 17 Hypoparathyroidism and Pseudohypoparathyroidism endogenous immunoreactive and bioactive PTH in subjects with PHP type I. Despite high circulating levels of immunoreactive PTH, the levels of bioactive PTH in many patients with PHP type I have been found to be within the normal range when measured with highly sensitive renal 133 and metatarsal TM cytochemical bioassay systems. Furthermore, plasma from many of these patients has been shown to diminish the biological activity of exogenous PTH in these in vitro bioassays. 135 Currently, the nature of this putative inhibitor or antagonist remains unknown. The observation that prolonged hypercalcemia can remove or reduce significantly the level of inhibitory activity in the plasma of patients with PHP has suggested that the parathyroid gland may be the source of the inhibitor. In addition, analysis of circulating PTH immunoactivity after fractionation of patient plasma by reversed-phase high-performance liquid chromatography has disclosed the presence of aberrant forms of immunoreactive PTH in many of these patients. 136 Although it is conceivable that a PTH inhibitor may cause PTH resistance in some patients with PHP, it is more likely that circulating antagonists of PTH action arise as a consequence of the sustained secondary hyperparathyroidism that results from the primary biochemical defect. By contrast, molecular studies have provided confirmation that defects in the PTH/PTHrP receptorG-protein-coupled signaling pathway are responsible for PTH resistance in many patients with PHP type I. 1.

PSEUDOHYPOPARATHYROIDISM

TYPE IA

AND PSEUDOPSEUDOHYPOPARATHYROIDISM

Cell membranes from patients with PHP type Ia show an approximately 50% reduction in expression or activity of Gs~ protein 137 (Fig. 17-6). This generalized deficiency of Gs~ may impair the ability of PTH, as well as many other hormones and neurotransmitters, to activate

1O 0 ._

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u

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60

..=

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pseudoPHP

PHP Ib

FIGURE 17--6 Gs. activity of erythrocyte membranes. Gs~ is quantified in complementation assays with $49 cyc membranes,which genetically lack Gs. but retain all other components necessary for hormone-response adenylyl cyclase activity. Activity is reduced approximately 50% in patients with AHO subjects with either PHP type Ia or pseudoPHP, but is normal in patients with PHP type Ib.

5 13 adenylyl cyclase and thereby may account for multihormone resistance. In addition to hormone resistance, patients with PHP type Ia also manifest the peculiar constellation of developmental and somatic defects that are collectively termed AHO 117 (Fig. 17-7). Early studies of PHP type Ia led to the identification of families in which some individuals had signs of AHO but lacked apparent hormone resistance (i.e., pseudoPHP). The observation that PHP type Ia and pseudoPHP can occur in the same family first suggested that these two disorders might reflect variability in expression of a single genetic lesion. Further support for this view derives from recent studies indicating that within a given kindred, subjects with either pseudoPHP or PHP type Ia have equivalent functional Gs~ deficiency (Fig. 17--6), 137'138 and that a transition from hormone responsiveness to hormone resistance may O c c u r . 139 It therefore seems reasonable to use the term AHO to simplify description of these two variants of the same syndrome, and to acknowledge the common clinical and biochemical characteristics that patients with PHP type Ia and pseudoPHP share. a. Molecular Defect The recent discovery that Gs~ deficiency results from heterozygous mutations in the gene encoding Gs~ (GNAS1) resolved the controversy surrounding the pattern of inheritance of AHO. Xlinked, 14~ autosomal dominant, 141 and autosomal recessive 142 inheritance of AHO had been proposed. However, the observation of father-to-son transmission of AHO with Gs~ deficiency excluded an X-linked mode of inheritance, 143 and the mapping of the GNAS1 gene to chromosome 20q13.2 --) 13.3144 provided final confirmation that AHO, including both PHP type Ia and pseudoPHP, is inherited in an autosomal dominant fashion. GNAS1 is a complex 20-Kb gene 145 comprised of 15 exons, including 2 alternative first exons. Alternative splicing of a nascent transcript accounts for the production of four mRNAs that encode Gs~. Deletion of exon 3 results in the loss of 15 codons from the mRNA, while use of an alternative splice site in exon 4 results in the insertion of a single additional codon into the mRNA. This generates two Gs~ proteins with apparent molecular weights of 45 kDa and two isoforms of apparent molecular weights of 52 k D a . 145 The alternatively spliced forms of Gs~ show a tissue-specific distribution. ~46 Biochemical characterization of the short and long forms of Gs~ has revealed subtle differences in the binding constant for GDP, the rate at which the forms are activated by agonist binding, efficiency of adenylyl cyclase stimulation, or the rate of GTP hydrolysis. None of these differences appear to be physiologically relevant, h o w e v e r . 147-149 Both long and short forms of Gs~ can stimulate adenylyl cyclase and open calcium channels. ~48

51

4

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FIGURE 17--7

Typical features of Albright's hereditary osteodystrophy. A, A young woman with characteristic features of AHO; note the short stature, disproportionate shortening of the limbs, obesity, and round face. B, Radiograph of patient's hands showing marked shortening of fourth and fifth metacarpals. C, Archibald sign, the replacement of "knuckles" with "dimples" due to the marked shortening of the metacarpal bones. D, Brachydactyly of the hand, note thumb sign ("murderer's thumb" or "potter's thumb") and shortening of the fourth and fifth digits. [From Levine MA, Schwindinger WE Downs RW, Jr, Moses AM: Pseudohypoparathyroidism. In Bilezikian JP, Marcus R, Levine MA (eds): The Parathyroids: Basic and Clinical Concepts. New York, Raven Press, 1994.]

Additional complexity in the processing of the GNAS1 gene may derive from the use of at least two alternative first exons that generate novel Gs~ transcripts. In one case, a transcript is produced with an exon 1' that lacks an initiator ATG; thus, a truncated, nonfunctional Gs~ protein is translated from an inframe ATG in exon 2.15~ In the other case, a transcript is generated that encodes a larger Gs~ isoform (XL~s) in which a novel 51-kDa protein is spliced to exons 2 through 13.15~Because these two alternative forms of Gs~ lack amino acid sequences encoded by exon 1, which are required for interaction with G~v and attachment to the plasma membrane, it is

likely that neither of these proteins can function as a transmembrane signal transducer. Molecular studies of DNA from subjects with AHO have disclosed a variety of GNAS1 gene mutations 152-16~ that lead to decreased expression or function of Gs~ protein (Fig. 17-8). Although most gene mutations impair expression of Gs~ m R N A , 132'161 in some subjects levels of Gs~ mRNA a r e n o r m a l 138'161'162 and encode dysfunctional Gs~ proteins. 153'154'159 A large variety of mutations in the GNAS1 gene have been identified, including missense mutations, 153'155'157'159point mutations in sequences required for efficient splicing, 156 and small dele-

CHAPTER 17 Hypoparathyroidism and Pseudohypoparathyroidism

I bp deletion 43 bp deletion

*A-G 1

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220 240 280 324

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$250R R258W(A) E259V

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346T 394 / N371

Mutations in the GNAS1 gene. The upper panel (A) depicts the human GNAS1 gene, which spans over 20 Kb and contains at least 13 exons and 12 introns. Unique mutations that result in loss of Gs, function are depicted; missense mutations are denoted by the symbol *. The lower panel (B) indicates the position of missense mutations above the protein structure. Two polymorphisms are denoted by the symbol +, and the position of the unchanged amino acid is denoted beneath the predicted Gs~ protein (B). The site of two missense mutations that result in gain of function (replacement of either Arg 2~ or Gln 227) in patients with MAS 214'215'268-271 or in sporadic tumors 271,zvz are depicted in italics. The mutation in exon 1 eliminates the initiator methionine codon and prevents synthesis of a normal Gs~ protein. ~57 The 4-bp deletions in exon 7 163'164 and exon 8,155 and the 1-bp deletion and insertion in exon 10 all shift the normal reading frame and prevent normal m R N A and/or protein synthesis. Mutations in intron 3 and at the donor splice junction between exon 10 and intron 10 cause splicing abnormalities that prevent normal m R N A synthesis. ~56 The mutations indicated with an asterisk represent missense mutations154'~55'159; the resultant amino acid substitutions are indicated in the schematic diagram of the Gs~ protein at the bottom of the figure. Some of these mutations may prevent

FIGURE 17--8

normal protein synthesis by altering protein secondary structure; the R231H substitution in exon 9 prevents normal interaction of the oLchain with the 13~/dimer153; the R385H substitution in exon 13 appears to encode an altered protein that cannot couple normally to receptorsTM and the A366S mutation encodes an activated Gs~ protein that is unstable at 37~

Although novel mutations have been found in nearly all of the kindreds studied, a 4-base deletion in exon 7 has been detected in five families, 163'164 and an unusual missense mutation in exon 13 (A366S; see below) has been identified in two unrelated young boys, ~59 suggesting that these two regions may be genetic " h o t spots." t i o n s . 152'155'156'162

b. Albright's Hereditary Osteodystrophy Subjects with PHP type Ia or pseudoPHP typically manifest a characteristic constellation of developmental defects, termed Albright's hereditary osteodystrophy, that includes short stature, obesity, a round face, shortening of

the digits (brachydactyly), subcutaneous ossification, and dental hypoplasia (Fig. 17-7). 117'118 Considerable variability occurs in the clinical expression of these features even among affected members of a single family, and all of these features may not be present in every case. 165 On rare occasion, it may be impossible to detect any features of AHO in an individual with Gs~ deficiency. ~55'~56 Although patients with AHO may be of normal height and weight, approximately 66% of children and 80% of adults are below the 10th percentile for height. This reflects a disproportionate shortening of the limbs, as arm span is less than height in the majority of patients. Obesity is a common feature of AHO and about one third

5

1

6

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C

of all patients with AHO are above the 90th percentile of weight for their age, despite their short stature ~65 (Fig. 17-7A). Patients with AHO typically have a round face, a short neck, and a flattened bridge of the nose. Numerous other abnormalities of the head and neck have also been noted. Ocular findings include hypertelorism, strabismus, nystagmus, unequal pupils, diplopia, microphthalmia, and a variety of abnormal findings on funduscopic exam that range from irregular pigmentation to optic atrophy and macular degeneration. Head circumference is above the 90th percentile in a significant minority of children. ~66 Dental abnormalities are common in subjects with PHP type Ia and include dentin and enamel hypoplasia, short and blunted roots, and delayed or absent tooth eruption. 167 Brachydactyly is the most reliable sign for the diagnosis of AHO, and may be symmetrical or asymmetrical and involve one or both hands or feet (Fig. 17-7). Shortening of the distal phalanx of the thumb is the most common abnormality; this is apparent on physical exam as a thumb in which the ratio of the width of the nail to its length is increased (so called "Murderer's thumb" or "potter's thumb"; Fig. 17-7D). Shortening of the metacarpals causes shortening of the digits, particularly the fourth and fifth. Shortening of the metacarpals may also be recognized on physical exam as dimpling over the knuckles of a clenched fist (Archibald's sign; Fig. 17-7C). Often, a definitive diagnosis requires careful examination of radiographs of the hands and feet (Fig. 17-7B). A specific pattern of shortening of the bones in the hand has been identified, in which the distal phalanx of the thumb and third through fifth metacarpals are the most severely shortened. 168'169This may be useful in distinguishing AHO from other unrelated syndromes in which brachydactyly occurs, such as familial brachydactyly, Turner's syndrome, and Klinefelter's syndrome. ~69 In addition to brachydactyly, several other skeletal abnormalities are present in AHO. Numerous deformities of the long bones have been reported, including a short ulna, bowed radius, deformed elbow or cubitus valgus, coxa vara, coxa valga, genu varum, and genu valgus deformities. 165 The most common abnormalities of the skull are hyperostosis frontalis interna and a thickened calvarium. The skeletal abnormalities of AHO may not be apparent until a child is 5 years old. 17~ Bone age is advanced 2 to 3 years in the majority of patients. 166 Spinal cord compression has been reported in several patients with AHO. 171 Patients with AHO develop heterotopic ossifications of the soft tissues or skin (osteoma cutis) that are unrelated to abnormalities in serum calcium or phosphorus levels. Osteoma cutis is present in 25% to 50% of cases of AHO, and is usually first noted in infancy or early childhood. Ossification of the skin and subcutaneous tissues may be the presenting cardinal feature of AHO in

H

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infancy or childhood in the absence of hypocalcemia or other features of A H O . 172'173 Blue-tinged, stony hard papular or nodular lesions that range in size from pinpoint up to 5 cm in diameter often occur at sites of minor trauma and may appear to be migratory on repeated exams. 173 Biopsy of these lesions reveals heterotopic ossification with spicules of mineralizing osteoid and calcified cartilage. The presence of these developmental and skeletal abnormalities does not necessarily indicate that the patient has AHO and Gs~ deficiency. Features of AHO, particularly shortened metacarpals or metatarsals, may occur in normal subjects, as well as in patients with hormone deficient hypoparathyroidism, 174-178 renal hypercalciu r i a , 179 and primary hyperparathyroidism. 18~ Moreover, several features of AHO, for example obesity, round face, brachydactyly, and mental retardation, are common to other disorders (e.g., Prader-Willi syndrome, acrodysostosis, Ullrich-Turner syndrome, Gardner's syndrome), many of which are associated with chromosomal defects. In some instances overlapping clinical features between AHO and other syndromes may lead to confusion. For example, AHO in a mother and her daughter has been associated with a proximal 15q chromosomal deletion resembling that found in Prader-Willi syndrome. 181 A growing number of reports have described small terminal deletions of chromosome 2q in patients with variable AHO-like phenotypes. Terminal deletion of 2q37 [del(2)(q37.3)] is the first consistent karyotypic abnormality that has been documented in patients with an AHO-like syndrome. 182'183These patients have normal endocrine function and normal Gso activity, however. 182 Thus, high-resolution chromosome analysis, biochemical/molecular analysis, and careful physical and radiological examination are essential in discriminating between these phenocopies and AHO. c. Multiple Hormone Resistance Although biochemical hypoparathyroidism is the most commonly recognized endocrine deficiency in PHP type Ia, early clinical studies described additional hormonal abnormalities, such as hypothyroidism 184'185 and hypogonadism. 186 Because available evidence suggests that Gs~ is present in all tissues, generalized deficiency of this protein could be the basis for not only PTH resistance, the hallmark of PHP type Ia, but could also explain the decreased responsiveness of diverse tissues (e.g., kidney, thyroid gland, gonads, and liver) to hormones that act via activation of adenylyl cyclase [e.g., PTH, thyroid-stimulating hormone (TSH), gonadotropins, and glucagon]. 123'18v'188 Primary hypothyroidism occurs in most patients with PHP type Ia. ~88 Typically, patients lack a goiter or antithyroid antibodies and have an elevated serum TSH with an exaggerated response to TRH. Serum levels of T4 may be low or low normal. Hypothyroidism may occur early

CHAPTER 17 Hypoparathyroidism and Pseudohypoparathyroidism in life prior to the development of hypocalcemia, and elevated serum levels of TSH are not uncommonly detected during neonatal screening. 189-191 Unfortunately, early institution of thyroid hormone replacement does not seem to prevent the development of mental retardation. 19~ Hypogonadism is common in subjects with PHP type Ia. Women may have delayed puberty, oligomenorrhea, and infertility. ~88 Plasma gonadotropins may be elevated, but are more commonly normal. Some patients show an exaggerated serum gonadotropin response to gonadotropin-releasing hormone ( G n - R H ) . 186'192 Features of hypogonadism may be less obvious in men. Serum testosterone may be normal or reduced. Testes may show evidence of a maturation arrest or may fail to descend normally. Fertility appears to be decreased in men with PHP type Ia. Deficiency of prolactin secretion (basal and in response to secretagogues such as TRH) had been reported in some patients with PHP type I, 193 but later studies have not confirmed these early findings. 188 Abnormal hormone responsiveness may occur in some tissues without obvious clinical sequelae. For example, the hepatic glucose response to glucagon is normal, although plasma cAMP concentrations fail to increase normally. 188'194 In other tissues significant hormone resistance does not occur despite the apparent reduction in Gs~. Diabetes insipidus is not a feature of AHO, and urine is concentrated normally in response to vasopressin in patients with PHP type Ia. 195 Although there is a report of adrenal insufficiency in a single individual with PHP type Ia, 196 hypoadrenalism is not a typical feature of PHP type Ia and adrenocortical responsiveness to ACTH is normal. 188

d. Neurosensory Abnormalities Patients with PHP type Ia frequently manifest distinctive o l f a c t o r y , 197 g u s tatory, 198 and auditory 199 abnormalities that are apparently unrelated to endocrine dysfunction. The molecular basis of these neurosensory deficits has become more obscure with the discovery of unique G proteins that regulate signal transduction pathways related to vision, 2~176176 olfaction, 2~ and taste. 2~ Mild to moderate mental retardation is common in patients with PHP type Ia. Farfel and Friedman assessed intelligence in 25 patients with PHP type I whose Gs~ activity had been determined. 204 The authors found an association between mental deficiency and Gs~ deficiency, and speculated that reduced cAMP levels in cortical tissue may lead to mental retardation. Other factors that might contribute to mental retardation in patients with PHP type Ia include hypothyroidism and hypocalcemia; however, efforts to control these have not prevented cognitive dysfunction in all patients, suggesting that Gs~ deficiency may cause a primary abnormality of neurotransmitter signaling.

517 e. Phenotypic Variability Molecular studies have provided a basis for Gs~ deficiency, but they do not explain the striking variability in biochemical and clinical phenotype. Why do some Gs~-Coupled pathways show reduced hormone responsiveness (e.g., PTH, TSH, gonadotropins), whereas other pathways are clinically unaffected [adrenocorticotropic hormone (ACTH) in the adrenal and vasopressin in the renal medulla]? Perhaps even more intriguing is the paradox that Gs~ deficiency can be associated with hormone resistance and AHO (PHP type Ia), AHO only (pseudoPHP), or no apparent consequences at all. 155 These observations, when considered in the context of studies showing that the number of Gs molecules in cell membranes greatly exceeds the number of either receptor or adenylyl cyclase molecules, 2~ raise issue with the hypothesis that a 50% deficiency of Gs~ can impair hormone responsiveness. Indeed, in vitro studies of the hormone responsiveness of tissues and cells from subjects with PHP type Ia have frequently provided conflicting results. 2~ Although the basis for the variable expression of Gs~ deficiency remains unknown, several observations argue against a simple genetic mechanism. First, clinical genetic studies have documented that PHP type Ia and pseudoPHP frequently occur in the same family, but are not present in the same generation. These findings are inconsistent with models in which chance determines phenotype or in which a second gene is interactive with the defective GNAS1 gene, as both PHP type Ia and pseudoPHP would be expected to occur with equal frequency and in the same sibship. Second, phenotypic expression of Gs~ deficiency appears to become more severe with each generation. 2~ This pattern had originally been attributed to genomic imprinting, 2~176 as reviews of published reports of AHO kindreds indicated that maternal transmission of Gs~ deficiency led to PHP type Ia, whereas paternal transmission of the defect led to pseudoPHP. 2~176176 Several lines of evidence argue against a model of simple genomic imprinting of GNAS1 as the basis for variable phenotype, however. First, analyses of available cells from patients with PHP type Ia and pseudoPHP have shown that these cells contain equivalent amounts of Gs~ protein. 2~ Second, the recent description of both maternal and paternal transmission of PHP type Ia 21~ in a single multiplex family with Gs, deficiency 211 has suggested that parental origin of the GNAS1 mutation may be unrelated to phenotype. And third, both GNAS1 gene alleles are actively transcribed in many fetal 212 and adult ~55'213human tissues, indicating than both GNAS1 alleles are expressed in a wide variety of tissues. These observations suggest that complex mechanisms, such as tissue-specific genomic imprinting, may be responsible for the variable expression of GNAS1 gene defects within members of a kindred. Further modification of the phenotype may derive from variability in

5 18 other components of the signal transduction pathway (e.g., there are multiple forms of adenylyl cyclase and phosphodiesterase that exhibit tissue-specific expression). Regardless of the mechanism, understanding how identical defects in GNAS1 can have such variable consequences in different tissues or in different individuals will reveal much about the biology of the GNAS1 gene. In AHO, inherited GNAS1 gene mutations reduce expression or function of Gs~ protein. By contrast, in the McCune-Albright syndrome, postzygotic somatic mutations in the GNAS1 gene (Fig. 17-8) enhance activity of the protein. 214'215 These mutations lead to constitutive activation of adenylyl cyclase, and result in proliferation and autonomous hyperfunction of hormonally responsive cells. The clinical significance of Gs~ activity as a determinant of hormone action is emphasized by the recent description by Iiri et al. 159 of two males with both precocious puberty and PHP type l a. These two unrelated boys had identical GNAS1 gene mutations in exon 13 (A366S) (Fig. 1 7 - 8 ) that resulted in a temperaturesensitive form of Gs~. This Gs~ is constitutively active in the cooler environment of the testis, while being rapidly degraded in other tissues at normal body temperature. Thus, different tissues in these two individuals could show hormone resistance (to PTH and TSH), hormone responsiveness (to ACTH), or hormone-independent activation (to LH). 2. PSEUDOHYPOPARATHYROIDISMTYPE IB

Subjects with PHP type I who lack features of AHO typically manifest hormone resistance that is limited to PTH target organs (Fig. 17-1) and have normal Gs~ activity (Fig. 17-6). 188 This variant is termed PHP type Ib. 216 Although patients with PHP type Ib fail to show a nephrogenous cAMP response to PTH, they often manifest skeletal lesions similar to those that occur in patients with hyperparathyroidism (Fig. 1 7 - - 5 ) . 217 These observations have suggested that at least one intracellular signaling pathway coupled to the PTH receptor may be intact in patients with PHP type Ib. The molecular basis for PTH resistance in PHP type Ib has not been identified. Specific resistance of target tissues to PTH, and normal activity of Gs~, has implicated decreased expression or function of the PTH/ PTHrP receptor as the cause for hormone resistance, however. Evidence in favor of this hypothesis comes from studies of cultured skin fibroblasts from patients with PHP type Ib. These studies suggest that the mechanisms responsible for PTH resistance are likely to be heterogeneous. Fibroblasts from some, but not all, PHP type Ib patients accumulate less cAMP in response to PTH 216'21s and contain decreased levels of mRNA encoding the PTH/PTHrP receptor. 219 Furthermore, in most cases, pretreatment of the cultured fibroblasts with dex-

MICHAEL A. LEVINE

amethasone normalizes the PTH-induced cAMP response and increases expression of PTH/PTHrP receptor mRNA. 219 Taken in the context of recent molecular studies that have failed to disclose mutations in the coding exons 22~ and promoter regions 221 of the PTH/PTHrP receptor gene or in the c D N A , 222 it is likely that the molecular defect in PHP type Ib resides in another gene(s) that regulates expression of the PTH/PTHrP receptor. Although most cases of PHP type l b appear to be sporadic, familial cases have been described in which transmission of the defect is most consistent with an autosomal dominant pattern. 12~ 3. PSEUDOHYPOPARATHYROIDISMTYPE IC

Resistance to multiple hormones has been described in several patients with AHO who do not have a demonstrable defect in Gs or Gi .172'188'224 This disorder is termed PHP type Ic. The nature of the lesion in such patients is unclear, but it could be related to some other general component of the receptor-adenylyl cyclase system, such as the catalytic unit. 225 Alternatively, these patients could have functional defects of Gs (or Gi) that do not become apparent in the assays presently available. 4. PSEUDOHYPOPARATHYROIDISMTYPE II

PHP type II is the least common form of PHE This variant of PHP is typically a sporadic disorder, although one case of familial PHP type II has been reported. 226 Patients do not have features of AHO. Renal resistance to PTH in PHP type II patients is manifested by a reduced phosphaturic response to administration of PTH, despite a normal increase in urinary cAMP excretion. 119 These observations suggest that the PTH receptoradenylyl cyclase complex functions normally to increase cAMP in response to PTH, and are consistent with a model in which PTH resistance arises from an inability of intracellular cAMP to initiate the chain of metabolic events that result in the ultimate expression of PTH action. Although supportive data are not yet available, a defect in cAMP-dependent protein kinase A has been proposed as the basis for this disorder. 119 Alternatively, the defect in PHP type II may not reside in an inability to generate a physiological response to intracellular cAMP: a defect in another PTH-sensitive signal transduction pathway may explain the lack of a phosphaturic response. One candidate is the PTH-sensitive phospholipase C pathway that leads to increased concentrations of the intracellular second messengers inositol 1,4,5trisphosphate and diacylglycero121'22 and cytosolic calcium 23'24'227'228 (Fig. 17 - 1 ) . In some patients with PHP type II the phosphaturic response to PTH has been restored to normal after serum levels of calcium have been normalized by treatment

CHAPTER 17 Hypoparathyroidismand Pseudohypoparathyroidism with calcium infusion or vitamin D . 229 These results point to the importance of Ca 2§ as an intracellular second messenger. Finally, a similar dissociation between the effects of PTH on generation of cAMP and tubular reabsorption of phosphate has been observed in patients with profound hypocalcemia due to vitamin D deficiency, 23~ suggesting that some cases of PHP type II may in fact represent vitamin D deficiency.

C. Natural History of Pseudohypoparathyroidism The natural history of PHP is quite variable. Although PHP is congenital, hypocalcemia is not present from birth, and the biochemical defects arise gradually during childhood. The initial manifestations of tetany typically occur between 3 and 8 years of age, but the significance of these findings may not be appreciated and the diagnosis of hypocalcemia may be delayed for months or even years. A progressive decline in serum calcium, preceded by increasing levels of serum phosphate, PTH, and 1,25(OH)2D3, has been documented in one child as he advanced from 3 to 31/2years of age. TM In a second report serial PTH infusions were used to evaluate hormone responsiveness. This child was shown to have a normal cAMP response at age 3 months when serum levels of calcium, phosphorous, and PTH were normal, but was found to have an abnormal cAMP response when retested at age 2.6 years after he had developed tetany and was found to be hypocalcemic. 139 At the time of his second PTH infusion, the child had markedly elevated serum concentrations of phosphorous and PTH and was receiving thyroxine for recently diagnosed hypothyroidi s m . 139 Some affected children show few symptoms of tetany and the diagnosis of PHP is recognized only later in life after hypocalcemia is inadvertently discovered or when features of AHO become obvious. Hypocalcemia may not always provide a clue to the clinical diagnosis of PHP, however, as some PHP patients are able to maintain a normal serum calcium level without treatment (i.e., normocalcemic PHP). 132

VI. DIAGNOSIS The diagnosis of hypoparathyroidism should be considered in any patient who has hypocalcemia and hyperphosphatemia. A low serum calcium level may be found during an evaluation of unexplained paresthesias or seizures, or may be discovered after multichannel analysis of a blood specimen obtained as part of a rou-

5 19 tine examination. PHP should be strongly suspected if the serum concentration of PTH is elevated, although occasionally serum levels of PTH are "inappropriately" normal in subjects with PHP owing to confounding hypomagnesemia 223 or other factors. 232 Hypocalcemia may be precipitated or worsened during times of "stress" on calcium homeostasis, such as during early pregnancy, lactation, or during an episode of acute pancreatitis. Although hypocalcemia is present in most patients with hypoparathyroidism by the end of the first decade of life, this biochemical finding may go undetected for many years. Cataracts and intracranial calcification, particularly of the basal ganglion, occur commonly in patients with all forms of chronic hypoparathyroidism. Thus the presence of these ectopic or metastatic calcifications does not help to discriminate among the various causes of hypocalcemia and hyperphosphatemia. 233 Intracranial calcifications are readily detected when CT scanning is employed, 234'235 and may occasionally be associated with symptoms such as Parkinson's disease. 236 Unusual presenting manifestations of PHP include neonatal hypothyroidism, 19~ unexplained cardiac failure, 237 Parkinson's disease, 236 and spinal cord compression. 238 A diagnosis of hypoparathyroidism can be made with reasonable certainty when hypocalcemia is accompanied by normal serum levels of phosphorous and magnesium and the plasma PTH concentration is low or inappropriately normal. By contrast, an elevated level of PTH should suggest the diagnosis of PHP, particularly when clinical features of AHO are present. Further corroboration of the diagnosis of PHP requires demonstration of normal renal function and normal serum levels of magnesium and 25(OH)D. The presence of AHO and/or manifestations of multihormone resistance, such as hypothyroidism or hypogonadism, favors a diagnosis of PHP type Ia. 188 When most or all of these features are present, more sophisticated tests may not be necessary to confirm the clinical diagnosis. Serum calcium levels can fluctuate in patients with PHP, and may spontaneously change from low to normal and vice versa, thus contributing to the confusion regarding the distinction between PHP and pseudoPHp.131'239 However, the abnormal cAMP response to administered PTH (below) does not become normal in PHP patients who become normocalcemic with or without treatment. Thus, the PTH infusion remains the most reliable test to distinguish between these two variants (Fig. 17-4).

A. Specialized Tests The biochemical hallmark of PHP is the failure of the target organs, bone and kidney, to respond normally to

520 PTH. Additional tests have been developed to identify subjects with PHP type Ia; these research tests, which are based on analysis of Gs~ protein or the GNAS1 gene, are only rarely indicated under typical clinical circumstances. The classical tests of Ellsworth and Howard, and of Chase, Melson, and Aurbach, involved the intravenous infusion of 200 to 300 USP units of bovine parathyroid extract (parathyroid injection, USP; Lilly) and subsequent measurement of urinary excretion of nephrogenous (or total) cAMP (Fig. 17-4) and phosphate. This relatively crude PTH preparation is no longer available, and has been replaced by synthetic peptides corresponding to the amino-terminal region of human PTH [e.g., Parathar; teriparatide acetate; hPTH(1-34); Rhone-Poulanc Rorer]. After infusion of synthetic hPTH(1-34), normal subjects and patients with hormonopenic hypoparathyroidism usually display a 10- to 20fold increase in urinary cAMP excretion, whereas patients with PHP type I (type Ia and type Ib) show a markedly blunted response regardless of their serum calcium concentration. The urinary cAMP response to infusion of synthetic hPTH fragments in patients with PHP type I is unrelated to serum calcium levels, but may be related to endogenous serum PTH levels. The maximal urinary cAMP response to PTH increases after suppression of endogenous PTH in patients with PHP type I, but nevertheless does not reach that of the normal range. 125 Thus, this test can distinguish patients with socalled normocalcemic PHP (i.e., patients with PTH resistance who are able to maintain normal serum calcium levels without treatment) from subjects with pseudoPHP (who will have a normal urinary cAMP response to PTH 12~'137) (Fig. 17-4). Tests that measure the calcemic response to PTH are no longer used as a means of diagnosing PHP. The definitive diagnosis of PHP at the present time depends on the demonstration of a deficient cAMP, 1,25(OH)2D3, or phosphate response to an active preparation of PTH. Several diagnostic protocols have been described in which the response to an infusion of synthetic hPTH(1-34) peptide is used to differentiate among disorders of PTH responsiveness. 24~ A standard protocol involves the infusion of this PTH fragment, 200 units in an adult and 3 units/kg body weight (200 units maximum) in children over the age of 3 years, intravenously over 10 m i n u t e s . 24~ Test subjects should be in a fasting state and active urine output should be initiated and maintained by the ingestion of 200 ml of water per hour, 2 hours prior to the infusion of PTH and continuing through the study. A baseline urine collection should be made in a 60-minute period preceding the PTH infusion. Starting at time 0 urine should be collected in separate collections at the 0- to 30-minute, 30to 60-minute and 60- to 120-minute time periods. Blood

MICHAEL A. LEVINE

samples should be obtained at time 0 and at 2 hours after the start of PTH infusion for measurement of serum creatinine and phosphorus concentrations. Urine samples should be analyzed for cAMP, phosphorus, and creatinine concentrations. The preferred unit for expression of urinary cAMP is nM/100 ml (or per liter) of glomerular filtrate (nM/dl GF). The cAMP response during the first 30 minutes after the start of PTH infusion best differentiates patients with PHP type I from those with hypoparathyroidism and from normal subjects than other parameters of cAMP metabolism. 243 The change in urinary cAMP per milligram creatinine during the same 30-minute period also discriminates well between patients with PHP and normal subjects or patients with hypoparathyroidism. 243 Several metabolic abnormalities such as hypo- and hypermagnesemia and metabolic acidosis may interfere with the renal generation and excretion of cAMP in response to P T H . 68'244-246 These abnormalities should be corrected if possible, but probably do not interfere with the interpretation of the test. Calculation of the phosphaturic response to PTH as the percentage decrease in tubular maximum for phosphate reabsorption (percentage fall in TmP/GF) during the first hour after PTH infusion yields the best separation between normal subjects and patients with PHP or hypoparathyroidism. 243 However, distinction between groups is also possible when the results are expressed as the fall in percentage tubular reabsorption of phosphorus (decrease in % TRP). A nomogram has been developed that facilitates calculation of TmP/GFR. 247 TmP/GFR is elevated in patients with PHP and hypoparathyroidism. Patients with hormone-deficient hypoparathyroidism have a steep fall in TmP/GFR during the first hour after beginning the infusion of PTH. This fall does not occur in patients with PHP (for further details see references by Mallette et al.24~ Although a normal phosphate response may occur in PHP type I patients with serum calcium or PTH levels in the normal range, 125 in patients with PHP type II the phosphaturic response to PTH is not changed despite at least a tenfold increase in cAMP excretion. Unfortunately, interpretation of the phosphaturic response to PTH is often complicated by random variations in phosphate clearance, and it is sometimes not possible to classify a phosphaturic response as normal or subnormal regardless of the criteria employed. More perplexing yet is the observation that biochemical findings that resemble PHP type II have been found in patients with various forms of vitamin D deficiency. 23~ In these patients, marked hypocalcemia is accompanied by hyperphosphatemia due presumably to an acquired dissociation between the amount of cAMP generated in the renal tubule and its effect on phosphate clearance.

CHAPTER 17 Hypoparathyroidism and Pseudohypoparathyroidism The plasma cAMP response to PTH can also be used to differentiate patients with PHP type I from normal subjects and from patients with hypoparathyroidi s m . 242'248'249 Patients with PHP type II can be expected to have normal responsiveness, however. This test offers few advantages over protocols that assess the urinary excretion of cAMP, as changes in plasma cAMP in normal subjects and patients with hypoparathyroidism are much less dramatic than changes in urinary cAMP, and urine must still be collected if one wishes to assess the phosphaturic response to PTH. One reasonable indication for measuring the plasma cAMP response to PTH is the evaluation of patients in whom proper collection of urine is not possible, such as young children. 248 The plasma 1,25(OH)2D3 response to PTH has been used to differentiate between hormone-deficient and hormone-resistant hypoparathyroidism. 241'25~ In contrast to normal subjects and patients with hypoparathyroidism, patients with PHP had no significant increase in circulating levels of 1,25(OH)2D3. This proposed test readily demonstrates the difference in the pathophysiology between hypoparathyroidism and PHP. Its clinical relevance is probably limited to distinguishing type I from type II PHP where the expected increase in the latter form of PHP might be a more reliable parameter than the phosphaturic response to PTH.

VII. TREATMENT Urgent treatment of acute or severe symptomatic hypocalcemia in patients with hypoparathyroidism is best accomplished by the intravenous infusion of calcium. Vitamin D is not required. The goal is alleviation of symptoms and prevention of laryngeal spasm and seizures. Hyperphosphatemia, alkalosis, and hypomagnesemia should be corrected. The serum calcium should be increased to the mid-normal range. The desired serum calcium levels can usually be obtained by injecting 1 to 3 g of calcium gluconate (93 to 279 mg of elemental calcium, 10 to 30 ml of 10% calcium gluconate) over a 10-minute period followed by continuous infusion of calcium (up to 100 mg/hr) using a solution of D5W containing 100 ml of 10% calcium gluconate (930 mg of elemental calcium) per liter. A 10% solution of calcium chloride is available for intravenous use but it is very irritating to the veins. The serum calcium level should be measured at frequent intervals, and the amount of intravenous calcium should be adjusted accordingly. Electrocardiographic monitoring is advisable when patients are receiving digitalis-like drugs because increasing serum calcium levels can predispose to digitalis toxicity. Oral calcium and vitamin D therapy should be

521 started as soon as possible and gradually adjusted to replace the need for intravenous calcium. TM The long-term treatment of hypocalcemia in patients with hypoparathyroidism involves the administration of oral calcium and vitamin D or analogues. Patients with PHP may require less intensive therapy than patients with PTH deficiency. The goals of therapy are to maintain serum ionized calcium levels in the normal range, to avoid hypercalciuria, and, in patients with PHP, to suppress PTH levels. Patients with hypoparathyroidism have increased urinary calcium excretion in relation to serum calcium and are therefore prone to hypercalciuria. 252 By contrast, patients with PHP have significantly lower urinary calcium in relation to s e r u m c a l c i u m 252'253 and can tolerate serum calcium levels that are within the normal range without developing hypercalciuria. TM Once normocalcemia has been attained, attention should be directed towards suppression of PTH levels to normal. This is important because elevated PTH levels in patients with PHP are frequently associated with increased bone remodeling. Hyperparathyroid bone disease, including osteitis fibrosa cystica 17~ and cortical osteopenia (Fig. 17-5), ~3~can occur in patients with PHP type Ib. These subjects may have elevated serum levels of alkaline phosphatase T M and urine hydroxyproline. 13~ In this regard calcitriol has an advantage over other vitamin D preparations, since it may inhibit PTH release directly 255 in addition to the indirect inhibition caused by elevating the serum calcium. Oral calcium is usually administered in amounts from 1 to 3 g of elemental calcium per day in divided doses. To assure optimal absorption, oral calcium supplements should be taken with water or other fluids, and with food in the stomach. 256 Many considerations are involved in the selection of a calcium supplement, and none are unique to the treatment of hypoparathyroidism. Calcium carbonate is an inexpensive form of calcium that is very convenient owing to its high content of elemental calcium (40%). When taken with food, absorption of calcium from calcium carbonate is adequate even in achlorhydric patients. Due to the low content of elemental calcium in calcium lactate (13%) and calcium gluconate (9%), patients must take many tablets to obtain adequate amounts of calcium. Thus, these salts are inconvenient and are often not acceptable to the patients. Calcium citrate is 21% calcium and is well absorbed even in the absence of gastric acid) 57 Although more expensive than many other forms of calcium, calcium citrate has the advantage of causing fewer gastrointestinal side effects. For those who prefer a liquid calcium supplement, calcium glubionate is very palatable and contains 252 mg calcium/10 ml. Ten to 30 ml of a 10% calcium chloride solution (360 to 1080 mg calcium) every 8 hours may

522 be very effective in patients with achlorhydria. 258 Hyperchloremic acidosis may occur, which can be prevented by giving half of the calcium as chloride and half as carbonate simultaneously. 258 Calcium phosphate salts should be avoided. All patients with hypoparathyroidism who are hypocalcemic will require vitamin D or analogues in addition to calcium. Calcitriol, the active form of vitamin D, is the most physiological treatment choice. Patients with PHP require about 75% as much calcitriol to maintain normocalcemia as do patients with hypoparathyroidi s m . 259 Almost all patients with hypoparathyroidism or PHP can be effectively treated with calcitriol in the amount of 0.25 Ixg twice a day to 0.5 Ixg four times a day. Because of the expense of calcitriol and the need to administer the drug several times per day, other vitamin D preparations may be preferred. Patients with all forms of hypoparathyroidism and PHP will respond to pharmacological doses of ergocalciferol and calcifidiol. Ergocalciferol is the least expensive choice for vitamin D therapy, and provides a long duration of action (with corresponding prolonged potential toxicity). Patients with PHP require lower doses of vitamin D than patients with hypoparathyroidism, 259 an observation that reflects the response of bone and renal distal tubular cells to endogenous P T H . 26~ Treatment with calcium and vitamin D usually decreases the elevated serum phosphate to a high normal level because of a favorable balance between increased urinary phosphate excretion and decreased intestinal phosphate absorption. In general, phosphate-binding gels such as aluminum hydroxide are not necessary. Attention should be directed to a number of special situations. Because thiazide diuretics can increase renal calcium reabsorption in patients with hypoparathyroidism, 261-263 the inadvertent institution or discontinuation of these drugs may respectively increase or decrease plasma calcium levels. 264 By contrast, furosamide and other loop diuretics can increase renal clearance of calcium and depress serum calcium levels. The administration of glucocorticoids antagonizes the action of vitamin D (and analogues) and may also precipitate hypocalcemia. The development of hypomagnesemia may also interfere with the effectiveness of treatment with calcium and vitamin D . 265 Experimental treatments for hypoparathyroidism include transplantation of cultured human parathyroid c e l l s 266 and daily injection of synthetic human P T H ( 1 3 4 ) . 267 P T H ( 1 - 3 4 ) has been shown to effectively normalize serum concentrations of calcium and phosphorous while causing less hypercalciuria than treatment with comparable doses of calcitriol. 267 Unfortunately, uncertainties regarding the future availability of human PTH(1-34), and the need to administer the drug by in-

MICHAEL A. LEVINE

jection, lessen overall enthusiasm for this form of treatment. Patients with AHO may require specific treatment for unusual problems related to their developmental and skeletal abnormalities. Patients with PHP type Ia should be treated for their associated hypogonadism and hypothyroidism. Ectopic calcification occurs in about 30% of patients with A H O , 166 but rarely causes a problem. However, at times large extraskeletal osteomas may o c c u r . 173 These may require surgical removal to relieve pressure symptoms.

VIII.

CONCLUSION

The identification, and molecular characterization, of the signal transduction pathways that regulate PTH secretion and action have facilitated development of new approaches to the investigation of the hypoparathyroidism and PHP. Advanced immunoassays now make possible the accurate and precise measurement of circulating concentrations of biologically active PTH, and innovative genetic techniques now offer the promise of future molecular diagnosis of these disorders. Ultimately, the insights gained from studies of these unusual patients will provide new information concerning the physiological regulation of PTH responsiveness in classical target tissues, such as bone and kidney, as well as in nonclassical targets. As with many other human disorders for which the disease gene has been identified, it is predicted that ability to diagnose these disorders on a molecular level will extend the clinical spectrum of disease. This prediction has already been fulfilled through our understanding of defects in genes encoding Gs~ and the calcium-sensing receptor. Future work will be directed towards identification of the molecular basis for other forms of hypoparathyroidism and PTH resistance so that all disorders of PTH action can be described on the basis of their pathophysiology.

Acknowledgments This work has been supported in part by grants from the National Institutes of Health (DK-34281 and DK-46720).

References 1. Marshall RW: Plasma fractions. In Nordin BEC (ed): Calcium, Phosphate and Magnesium Metabolism. London, Churchill Livingstone, 1976, p 162.

CHAPTER 17

Hypoparathyroidism and Pseudohypoparathyroidism

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526 126. Murray TM, Rao LG, Wong MM, et al: Pseudohypoparathyroidism with osteitis fibrosa cystica: Direct demonstration of skeletal responsiveness to parathyroid hormone in cells cultured from bone. J Bone Miner Res 8:83-91, 1993. 127. Burnstein MI, Kottamasu SR, Pettifor JM, et al: Metabolic bone disease in pseudohypoparathyroidism: Radiologic features. Radiology 155:351-356, 1985. 128. Dabbaugh S, Chesney RW, Langer LO, et al: Renal-nonresponsive, bone-responsive pseudohypoparathyroidism. A case with normal vitamin D metabolite levels and clinical features of rickets. Am J Dis Child 138:1030-1033, 1984. 129. Hall FM, Segall-Blank M, Genant HK, et al: Pseudohypoparathyroidism presenting as renal osteodystrophy. Skeletal Radiol 6:43-46, 1981. 130. Breslau NA, Moses AM, Pak CYC: Evidence for bone remodeling but lack of calcium mobilization response to parathyroid hormone in pseudohypoparathyroidism. J Clin Endocrinol Metab 57:638-644, 1983. 131. Drezner MK, Haussler MR: Normocalcemic pseudohypoparathyroidism. Am J Med 66:503-508, 1979. 132. Stogmann W, Fischer JA: Pseudohypoparathyroidism. Disappearance of the resistance to parathyroid extract during treatment with vitamin D. Am J Med 59:140-144, 1975. 133. de Deuxchaisnes CN, Fischer JA, Dambacher MA, et al: Dissociation of parathyroid hormone bioactivity and immunoreactivity in pseudohypoparathyroidism type I. J Clin Endocrinol Metab 53:1105-1109, 1981. 134. Bradbeer JN, Dunham J, Fischer JA, et al: The metatarsal cytochemical bioassay of parathyroid hormone: Validation, specificity, and application to the study of pseudohypoparathyroidism type I. J Clin Endocrinol Metab 67:1237-1243, 1988. 135. Loveridge N, Fischer JA, Nagant de Deuxchaisnes C, et al: Inhibition of cytochemical bioactivity of parathyroid hormone by plasma in pseudohypoparathyroidism type I. J Clin Endocrinol Metab 54:1274-1275, 1982. 136. Mitchell J, Goltman D: Examination of circulating parathyroid hormone in pseudohypoparathyroidism. J Clin Endocrinol Metab 61:328-334, 1985. 137. Levine MA, Jap TS, Mauseth RS, et al: Activity of the stimulatory guanine nucleotide-binding protein is reduced in erythrocytes from patients with pseudohypoparathyroidism and pseudopseudohypoparathyroidism: Biochemical, endocrine, and genetic analysis of Albright's hereditary osteodystrophy in six kindreds. J Clin Endocrinol Metab 62:497-502, 1986. 138. Levine MA, Ahn TG, Klupt SF, Kaufman KD, et al: Genetic deficiency of the alpha subunit of the guanine nucleotide-binding protein Gs as the molecular basis for Albright hereditary osteodystrophy. Proc Natl Acad Sci USA 85:617-621, 1988. 139. Barr DG, Stifling HF, Darling JA: Evolution of pseudohypoparathyroidism: An informative family study. Arch Dis Child 70: 337-338, 1994. 140. Mann JB, Alterman S, Hills AG: Albright's hereditary osteodystrophy comprising pseudohypoparathyroidism and pseudopseudohypoparathyroidism with a report of two cases representing the complete syndrome occurring in successive generations. Ann Intern Med 56:315-342, 1962. 141. Weinberg AG, Stone RT: Autosomal dominant inheritance in A1bright's hereditary osteodystrophy. J Pediatr 79:996-999, 1971. 142. Cedarbaum SD, Lippe BM: Probable autosomal recessive inheritance in a family with Albright's hereditary osteodystrophy and an evaluation of the genetics of the disorder. Am J Hum Genet 25:638-645, 1973. 143. Van Dop C, Bourne HR, Neer RM: Father to son transmission of decreased Ns activity in pseudohypoparathyroidism type Ia. J Clin Endocrinol Metab 59:825-828, 1984.

MICHAEL A. LEVINE 144. Levine MA, Modi WS, OBrien S J: Mapping of the gene encoding the alpha subunit of the stimulatory G protein of adenylyl cyclase (GNAS1) to 20q13.2-q13.3 in human by in situ hybridization. Genomics 11:478-479, 1991. 145. Kozasa T, Itoh H, Tsukamoto T, Kaziro Y: Isolation and characterization of the human Gs alpha gene. Proc Natl Acad Sci USA 85:2081-2085, 1988. 146. Bhatt B, Burns J, Flanner D, McGee J: Direct visualization of single copy genes on banded metaphase chromosomes by nonisotopic in situ hybridization. Nucl Acids Res 16:3951-3961, 1988. 147. Graziano MP, Freissmuth M, Gilman AG: Expression of Gs alpha in Escherichia coli. Purification and properties of two forms of the protein. J Biol Chem 264:409-418, 1989. 148. Mattera R, Graziano MP, Yatani A, et al: Splice variants of the alpha subunit of the G protein Gs activate both adenylyl cyclase and calcium channels. Science 243:804-807, 1989. 149. Jones DT, Masters SB, Bourne HR, Reed RR: Biochemical characterization of three stimulatory GTP-binding proteins. J Biol Chem 265:2671-2676, 1990. 150. Ishikawa Y, Bianchi C, Nadal-Ginard B, Homcy CJ: Alternative promoter and 5' exon generate a novel Gs alpha mRNA. J Biol Chem 265:8458-8462, 1990. 151. Kehlenbach RH, Matthey J, Huttner WB: XLets is a new type of G protein. Nature 372:804-808, 1994. 152. Shapira H, Mouallem M, Shapiro MS, et al: Pseudohypoparathyroidism type Ia: Two new heterozygous frameshift mutations in exons 5 and 10 of the Gs alpha gene. Hum Genet 97:73-75, 1996. 153. Farfel Z, Iiri T, Shapira H, et al: Pseudohypoparathyroidism, a novel mutation in the betagamma-contact region of Gs-alpha impairs receptor stimulation. J Biol Chem 271:19653-19655, 1996. 154. Schwindinger WF, Miric A, Zimmerman D, Levine MA: A novel Gsct mutant in a patient with Albright hereditary osteodystrophy uncouples cell surface receptors from adenylyl cyclase. J Biol Chem 269:25387-25391, 1994. 155. Miric A, Vechio JD, Levine MA: Heterogeneous mutations in the gene encoding the alpha subunit of the stimulatory G protein of adenylyl cyclase in Albright hereditary osteodystrophy. J Clin Endocrinol Metab 76:1560-1568, 1993. 156. Weinstein LS, Gejman PV, Friedman E, et al: Mutations of the Gs alpha-subunit gene in Albright hereditary osteodystrophy detected by denaturing gradient gel electrophoresis. Proc Natl Acad Sci USA 87:8287-8290, 1990. 157. Patten JL, Johns DR, Valle D, et al: Mutation in the gene encoding the stimulatory G protein of adenylate cyclase in A1bright's hereditary osteodystrophy. N Engl J Med 322:14121419, 1990. 158. Luttikhuis ME, Wilson LC, Leonard JV, Trembath RC: Characterization of a de novo 43-bp deletion of the Gs alpha gene (GNAS 1) in Albright hereditary osteodystrophy. Genomics 21: 455-457, 1994. 159. Iiri T, Herzmark P, Nakamoto JM, et al: Rapid GDP release from Gsa in patients with gain and loss of function. Nature 371: 164-168, 1994. 160. Lin CK, Hakakha MJ, Nakamoto JM, et al: Prevalence of three mutations in the Gs alpha gene among 24 families with pseudohypoparathyroidism type Ia. Biochem Biophys Res Commun 189:343-349, 1992. 161. Carter A, Bardin C, Collins R, et al: Reduced expression of multiple forms of the alpha subunit of the stimulatory GTPbinding protein in pseudohypoparathyroidism type Ia. Proc Natl Acad Sci USA 84:7266-7269, 1987.

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162. Mallet E, Carayon P, Amr S, et al: Coupling defect of thyrotropin receptor and adenylate cyclase in a pseudohypoparathyroid patient. J Clin Endocrinol Metab 54:1028-1032, 1982. 163. Weinstein LS, Gejman PV, de Mazancourt P, et al: A heterozygous 4-bp deletion mutation in the Gsa gene (GNAS 1) in a patient with Albright hereditary osteodystrophy. Genomics 13: 1319-1321, 1992. 164. Yu S, Yu D, Hainline BE, et al: A deletion hot-spot in exon 7 of the Gs alpha gene (GNAS1) in patients with Albright hereditary osteodystrophy. Hum Mol Genet 4:2001 - 2002, 1995. 165. Faull CM, Welbury RR, Paul B, Kendall Taylor P: Pseudohypoparathyroidism: Its phenotypic variability and associated disorders in a large family. Q J Med 78:251-264, 1991. 166. Fitch N: Albright's hereditary osteodystrophy: A review. Am J Med Genet 11:11 - 29, 1982. 167. Croft LK, Witkop CJ, Glas J: Pseudohypoparathyroidism. Oral Surg Oral Med Oral Pathol 20:758-770, 1965. 168. Graudal N, Galloe A, Christensen H, Olesen K: The pattem of shortened hand and foot bones in D- and E-brachydactyly can pseudohypoparathyroidism / pseudopseudohypoparathyroidism. ROFO Fortschr Geb Rontgenstr Nuklearmed 148:460-462, 1988. 169. Poznanski AK, Werder EA, Giedion A: The pattem of shortening of the bones of the hand in PHP and P P H P - - a comparison with brachydactyly E, Tumer syndrome, and acrodysostosis. Radiol 123:707-718, 1977. 170. Steinbach HL, Rudhe U, Jonsson M, et al: Evolution of skeletal lesions in pseudohypoparathyroidism. Radiol 85:670-676, 1965. 171. Alam SM, Kelly W: Spinal cord compression associated with pseudohypoparathyroidism. J R Soc Med 83:50-51, 1990. 172. Izraeli S, Metzker A, Horev G, et al: Albright hereditary osteodystrophy with hypothyroidism, normocalcemia, and normal Gs protein activity. Am J Med 43:764-767, 1992. 173. Prendiville JS, Lucky AW, Mallory SB, et al: Osteoma curls as a presenting sign of pseudohypoparathyroidism. Pediatr Dermatol 9:11 - 18, 1992. 174. Le Roith D, Burshell AC, Ilia R, Glick SM: Short metacarpal in a patient with idiopathic hypoparathyroidism. Isr J Med Sci 15:460-461, 1979. 175. Izraeli S, Metzker A, Horev G, et al: Albright hereditary osteodystrophy with hypothyroidism, normocalcemia, and normal Gs protein activity: A family presenting with congenital osteoma cutis. Am J Med Genet 43:764-767, 1992. 176. Shapira H, Friedman E, Mouallem M, Farfel Z: Familial A1bright's hereditary osteodystrophy with hypoparathyroidism: Normal structural Gsalpha gene. J Clin Endocrinol Metab 81: 1660-1662, 1996. 177. Isozaki O, Sato K, Tsushima T, et al: A patient of short stature with idiopathic hypoparathyroidism, round face and metacarpal signs. Endocrinol Jpn 31:363-367, 1984. 178. Moses AM, Rao KJ, Coulson R, Miller R: Parathyroid hormone deficiency with Albright's hereditary osteodystrophy. J Clin Endocrinol Metab 39:496-500, 1974. 179. Moses AM, Notman DD: Albright's osteodystrophy in a patient with renal hypercalciuria. J Clin Endocrinol Metab 49:794-797, 1979. 180. Sasaki H, Zsutsu N, Asano T, et al: Co-existing primary hyperparathyroidism and Albright's hereditary osteodystrophy--an unusual association. Postgrad Med J 61:153 - 155, 1985. 181. Hedeland H, Bemtorp K, Arheden K, Kristoffersson U: Pseudohypoparathyroidism type I and Albright's hereditary osteodystrophy with a proximal 15q chromosomal deletion in mother and daughter. Clin Genet 42:129-134, 1992.

527 182. Phelan MC, Rogers RC, Clarkson KB, et al: Albright hereditary osteodystrophy and del(2)(q37.3) in four unrelated individuals. Am J Med Genet 58:1-7, 1995. 183. Wilson LC, Leverton K, Oude Luttikhuis ME, et al: Brachydactyly and mental retardation: An Albright hereditary osteodystrophy-like syndrome localized to 2q37. Am J Hum Genet 56: 400-407, 1995. 184. Werder EA, Illig R, Bernsasconi S, et al: Excessive thyrotropinreleasing hormone in pseudohypoparathyroidism. Pediatr Res 9: 12-16, 1975. 185. Marx SJ, Hershman JM, Aurbach GD: Thyroid dysfunction in pseudohypoparathyroidism. J Clin Endocrinol Metab 33:822828, 1971. 186. Wolfsdorf JI, Rosenfield RL, Fang VS, et al: Partial gonadotrophin-resistance in pseudohypoparathyroidism. Acta Endocrinol 88:321-328, 1978. 187. Tsai KS, Chang CC, Wu DJ, et al: Deficient erythrocyte membrane Gs alpha activity and resistance to trophic hormones of multiple endocrine organs in two cases of pseudohypoparathyroidism. Taiwan I Hsueh Hui Tsa Chih 88:450-455, 1989. 188. Levine MA, Downs RW Jr, Moses AM, et al: Resistance to multiple hormones in patients with pseudohypoparathyroidism. Association with deficient activity of guanine nucleotide regulatory protein. Am J Med 74:545-556, 1983. 189. Yokoro S, Matsuo M, Ohtsuka T, Ohzeki T: Hyperthyrotropinemia in a neonate with normal thyroid hormone levels: The earliest diagnostic clue for pseudohypoparathyroidism. Biol Neonate 58:69-72, 1990. 190. Weisman Y, Golander A, Spirer Z, Farfel Z: Pseudohypoparathyroidism type Ia presenting as congenital hypothyroidism. J Pediatr 107:413-415, 1985. 191. Levine MA, Jap TS, Hung W: Infantile hypothyroidism in two sibs: An unusual presentation of pseudohypoparathyroidism type Ia. J Pediatr 107:919-922, 1985. 192. Downs RW Jr, Levine MA, Drezner MK, et al: Deficient adenylate cyclase regulatory protein in renal membranes from a patient with pseudohypoparathyroidism. J Clin Invest 71:231235, 1983. 193. Carlson HE, Brickman AS, Bottazzo CF: Prolactin deficiency in pseudohypoparathyroidism. N Engl J Med 296:140-144, 1977. 194. Brickman AS, Carlson HE, Levin SR: Responses to glucagon infusion in pseudohypoparathyroidism. J Clin Endocrinol Metab 63:1354-1360, 1986. 195. Moses AM, Weinstock RS, Levine MA, Breslau NA: Evidence for normal antidiuretic response to endogenous and exogenous arginine vasopressin in patients with guanine nucleotide-binding stimulatory protein-deficient pseudohypoparathyroidism. J Clin Endocrinol Metab 62:221-224, 1986. 196. Ridderskamp I, Schlaghecke R: Klin Wochenschr 68:927-931, 1990. 197. Weinstock RS, Wright HN, Speigel AM, et al: Olfactory dysfunction in humans with deficient guanine nucleotide-binding protein. Nature 322:635-636, 1986. 198. Henkin RI: Impairment of olfaction and of the tastes of sour and bitter in pseudohypoparathyroidism. J Clin Endocrinol Metab 28:624, 1968. 199. Koch T, Lehnhardt E, Bottinger H, et al: Sensorineural heating loss owing to deficient G proteins in patients with pseudohypoparathyroidism: Results of a multicentre study. Eur J Clin Invest 20:416-421, 1990. 200. Lochrie MA, Hurley JB, Simon MI: Sequence of the alpha subunit of photoreceptor G protein: Homologies between transducin, ras, and elongation factors. Science 228:96-99, 1985.

528 201. Lerea CL, Somers DE, Hurley JB, et al: Identification of specific transducin alpha subunits in retinal rod and cone photoreceptors. Science 234:77-80, 1986. 202. Jones DT, Reed RR: Golf: An olfactory neuron specific-G protein involved in odorant signal transduction. Science 244:790795, 1989. 203. McLaughlin SK, McKinnon PJ, Margolskee RF: Gustducin is a taste-cell specific G protein closely related to the transducins. Nature 357:563-568, 1992. 204. Farfel Z, Friedman E: Mental deficiency in pseudohypoparathyroidism type I is associated with Ns-protein deficiency. Ann Intern Med 105:197-199, 1986. 205. Levis MJ, Bourne HR: Activation of the alpha subunit of Gs in intact cells alters its abundance, rate of degradation, and membrane avidity. J Cell Biol 119:1297-1307, 1992. 206. Levine MA: Pseudohypoparathyroidism. In Bilezikian JP, Raisz LG, Rodan GA (eds): Principles of Bone Biology. San Diego, Academic Press, 1996, pp 853-876. 207. Wilson LC, Trembath RC: Albright's hereditary osteodystrophy. J Med Genet 31:779-784, 1994. 208. Davies SJ, Hughes HE: Imprinting in Albright's hereditary osteodystrophy. J Med Genet 30:101 - 103, 1993. 209. Wilson LC, Oude Luttikhuis ME, Clayton PT, et al: Parental origin of Gs alpha gene mutations in Albright's hereditary osteodystrophy. J Med Genet 31:835-839, 1994. 210. Schuster V, Kress W, Kruse K: Paternal and maternal transmission of pseudohypoparathyroidism type Ia in a family with A1bright hereditary osteodystrophy: No evidence of genomic imprinting [letter]. J Med Genet 31:84, 1994. 211. Schuster V, Eschenhagen T, Kruse K, et al: Endocrine and molecular biological studies in a German family with Albright hereditary osteodystrophy. Eur J Pediatr 152:185-189, 1993. 212. Campbell R, Gosden CM, Bonthron DT: Parental origin of transcription from the human GNAS 1 gene. J Med Genet 31:607614, 1994. 213. Namnoum AB, Merriam GR, Moses AM: Ovarian dysfunction in Albright's hereditary osteodystrophy. J Clin Endocrinol Metab 1997 (in press). 214. Weinstein LS, Shenker A, Gejman PV, et al: Activating mutations of the stimulatory G protein in the McCune-Albright syndrome. N Engl J Med 325:1688-1695, 1996. 215. Schwindinger WE Francomano CA, Levine MA: Identification of a mutation in the gene encoding the alpha subunit of the stimulatory G protein of adenylyl cyclase in McCune-Albright syndrome. Proc Natl Acad Sci USA 89:5152-5156, 1992. 216. Silve C, Santora A, Breslau N, et al: Selective resistance to parathyroid hormone in cultured skin fibroblasts from patients with pseudohypoparathyroidism type Ib. J Clin Endocrinol Metab 62:640-644, 1986. 217. Kidd GS, Schaaf M, Adler RA, et al: Skeletal responsiveness in pseudohypoparathyroidism: A spectrum of clinical disease. Am J Med 68:772-781, 1980. 218. Silve C, Suarez F, el Hessni A, et al: The resistance to parathyroid hormone of fibroblasts from some patients with type Ib pseudohypoparathyroidism is reversible with dexamethasone. J Clin Endocrinol Metab 71:631-638, 1990. 219. Suarez F, Lebrun JJ, Lecossier D, et al: Expression and modulation of the parathyroid hormone (PTH)/PTH-related peptide receptor messenger ribonucleic acid in skin fibroblasts from patients with type Ib pseudohypoparathyroidism. J Clin Endocrinol Metab 80:965-970, 1995. 220. Schipani E, Weinstein LS, Bergwitz C, et al: Pseudohypoparathyroidism type Ib is not caused by mutations in the coding exons of the human parathyroid hormone (PTH)/PTH-related

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peptide receptor gene. J Clin Endocrinol Metab 80:1611-1621, 1995. Bettoun JD, Minagawa M, Kwan MY, et al: Cloning and characterization of the promoter regions of the human parathyroid hormone (PTH)/PTH-related peptide receptor gene: Analysis of deoxyribonucleic acid from normal subjects and patients with pseudohypoparathyroidism type lb. J Clin Endocrinol Metab 82: 1031-1040, 1997. Fukumoto S, Suzawa M, Takeuchi Y, et al: Absence of mutations in parathyroid hormone (PTH)/PTH-related protein receptor complementary deoxyribonucleic acid in patients with pseudohypoparathyroidism type Ib. J Clin Endocrinol Metab 81: 2554-2558, 1996. Allen DB, Friedman AL, Greer FR, Chesney RW: Hypomagnesemia masking the appearance of elevated parathyroid hormone concentrations in familial pseudohypoparathyroidism. Am J Med Genet 31:153-158, 1988. Farfel Z, Brothers VM, Brickman AS, et al: Pseudohypoparathyroidism: Inheritance of deficient receptor-cyclase coupling activity. Proc Natl Acad Sci USA 78:3098-3102, 1981. Barrett D, Breslau NA, Wax MB, et al: New form of pseudohypoparathyroidism with abnormal catalytic adenylate cyclase. Am J Physiol 257:E277-E283, 1989. Van Dop C: Pseudohypoparathyroidism: Clinical and molecular aspects. Semin Nephrol 9:168-178, 1989. Civitelli R, Martin TJ, Fausto A, et al: Parathyroid hormonerelated peptide transiently increases cytosolic calcium in osteoblast-like cells: Comparison with parathyroid hormone. Endocrinology 125:1204-1210, 1989. Yamaguchi DT, Hahn TJ, Iida-Klein A, et al: Parathyroid hormone-activated calcium channels in an osteoblast-like clonal osteosarcoma cell line. J Biol Chem 262:7711-7718, 1987. Kruse K, Kracht U, Wohlfart K, Kruse U: Biochemical markers of bone turnover, intact serum parathyroid horn and renal calcium excretion in patients with pseudohypoparathyroidism and hypoparathyroidism before and during vitamin D treatment. Eur J Pediatr 148:535-539, 1989. Rao DS, Parfitt AM, Kleerekoper M, et al: Dissociation between the effects of endogenous parathyroid hormone on adenosine 3',5'-monophosphate generation and phosphate reabsorption in hypocalcemia due to vitamin D depletion: An acquired disorder resembling pseudohypoparathyroidism type II. J Clin Endocrinol Metab 61:285- 290, 1985. Tsang RC, Venkataraman P, Ho M, et al: The development of pseudohypoparathyroidism. Am J Dis Child 138:654-658, 1984. Attanasio R, Curcio T, Giusti M, et al: Pseudohypoparathyroidism. A case report with low immunoreactive parathyroid hormone and multiple endocrine dysfunctions. Minerva Endocrinol 11:267-273, 1986. Litvin Y, Rosler A, Bloom RA: Extensive cerebral calcification in hypoparathyroidism. Neuroradiology 21:271, 1981. Korn-Lubetzki I, Rubinger D, Siew F: Visualization of basal ganglion calcification by cranial computed tomography in a patient with pseudohypoparathyroidism. Isr J Med Sci 16:40-41, 1980. Sachs C, Sjoberg HE, Ericson K: Basal ganglia calcifications on CT: Relation to hypoparathyroidism. Neurology 32:779-782, 1982. Pearson DWM, Durward WE Fogelman I, et al: Pseudohypoparathyroidism presenting as severe Parkinsonism. Postgrad Med J 57:445-447, 1981. Miano A, Casadel G, Biasini G: Cardiac failure in pseudohypoparathyroidism. Helv Paediatr Acta 36:191 - 192, 1981.

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238. Cavallo A, Meyer WJ III, Bodensteiner JB, Chesson AL: Spinal cord compression: An unusual manifestation of pseudohypoparathyroidism. Am J Dis Child 134:706-707, 1980. 239. Breslau NA, Notman D, Canterbury JM, Moses AM: Studies on the attainment of normocalcemia in patients with pseudohypoparathyroidism. Am J Med 68:856-860, 1980. 240. Mallette LE: Synthetic human parathyroid hormone 1-34 fragment for diagnostic testing. Ann Intern Med 109:800-804, 1988. 241. McElduff A, Lissner D, Wilkinson M, et al: A 6-hour human parathyroid hormone (1-34) infusion protocol: Studies in normal and hypoparathyroid subjects. Calcif Tissue Int 41:267-273, 1987. 242. Furlong TJ, Seshadri MS, Wilkinson MR, et al: Clinical experiences with human parathyroid hormone 1-34. Aust N Z J Med 16:794-798, 1986. 243. Mallette LE, Kirkland JL, Gagel RF, et al: Synthetic human parathyroid hormone-(1-34) for the study of pseudohypoparathyroidism. J Clin Endocrinol Metab 67:964-972, 1988. 244. Beck N, Kim HP, Kim KS: Effect of metabolic acidosis on renal action of parathyroid hormone. Am J Physiol 228:1483-1488, 1975. 245. Beck N, Davis BB: Impaired renal response to parathyroid hormone in potassium depletion. Am J Physio1228:179-183, 1975. 246. Slatopolsky E, Mercado A, Morrison A, et al: Inhibitory effects of hypomagnesemia on the renal action of parathyroid hormone. J Clin Invest 58:1273-1279, 1976. 247. Walton RJ, Bijvoet OLM: Nomogram for derivation of renal threshold phosphate concentration. Lancet 309:310, 1975. 248. Stirling HF, Darling JA, Barr DG: Plasma cyclic AMP response to intravenous parathyroid hormone in pseudohypoparathyroidism. Acta Paediatr Scand 80:333-338, 1991. 249. Sohn HE, Furukawa Y, Yumita S, et al: Effect of synthetic 1-34 fragment of human parathyroid hormone on plasma adenosine 3', 5'-monophosphate (cAMP) concentrations and the diagnostic criteria based on the plasma cAMP response in EllsworthHoward test. Endocrinol Jpn 31:33-40, 1984. 250. Mirua R, Yumita S, Yoshinaga K, Furukawa Y: Response of plasma 1,25-dihydroxyvitamin D in the human PTH(1-34) infusion test: An improved index for the diagnosis of idiopathic hypoparathyroidism and pseudohypoparathyroidism. Calcif Tissue Int 46:309-313, 1990. 251. Lebowitz MR, Moses AM: Hypocalcemia. Semin Nephrol 12: 146-158, 1992. 252. Litvak J, Moldawer MP, Forbes AP, Henneman PH: Hypocalcemic hypercalciuria during vitamin D and dihydrotachysterol therapy of hypoparathyroidism. J Clin Endocrinol Metab 18: 246-252, 1958. 253. Yamamoto M, Takuwa Y, Masuko S, Ogata E: Effects of endogenous and exogenous parathyroid hormone on tubular reabsorption of calcium in pseudohypoparathyroidism. J Clin Endocrinol Metab 66:618-625, 1988. 254. Kolb FO, Steinbach HL: Pseudohypoparathyroidism with secondary hyperparathyroidism and osteitis fibrosa. J Clin Endocrinol Metab 22:59-64, 1962. 255. Slatopolsky E, Weerts C, Thielan J, et al: Marked suppression of secondary hyperparathyroidism by intravenous administration

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SHAPTER

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Bone Disease In 9 H y p er t h y r o l"d i s m DOUGLAS S. Ross

I. II. III. IV.

Thyroid Unit, Massachusetts General Hospital, Boston, Massachusetts 02114

Grades of Hyperthyroidism Overt Hyperthyroidism Endogenous Subclinical Hyperthyroidism Exogenous Subclinical Hyperthyroidism: Thyroid Hormone Suppressive Therapy

V. Thyroid Hormone Replacement Therapy VI. Treatment and Prevention of Thyroid Hormone-Mediated Bone Loss VII. Conclusions References

Severe osteopenia and fractures were among the primary clinical consequences of thyrotoxicosis prior to the availability of antithyroid drugs. In 1891 von Recklinghausen first described the " w o r m eaten" appearance of the long bones of a young woman who died from hyperthyroidism. 1 Plummer in 1928 described hyperthyroid patients with multiple fractures; at autopsy bones were friable, "easily crushed between the fingers," and "almost translucent when held up to the light." 2 With the introduction of the thionamide antithyroid drugs and radioiodine in the 1940s, severe manifestations of hyperthyroid bone disease became rare. Even today, however, thyrotoxic patients may still suffer from significant long-term adverse effects on skeletal integrity. In the last decade, the effects of even minimal hyperthyroidism on bone, and the potential detrimental effects from the use of thyroid hormone supplements, have been the major focus of clinical investigations.

TSH release, in turn, is regulated by the negative feedback of thyroid hormones on the pituitary thyrotrope. Because the negative feedback relationship between thyroxine and TSH is a linear-log relationship, small changes in thyroxine concentrations, even within the normal range, result in large changes in serum TSH concentrations. 3 With the advent of sensitive TSH assays in the late 1980s, serum TSH concentrations have replaced thyroxine levels as the most sensitive indicator of thyroid function. 4 Overt thyrotoxicosis refers to patients with elevated serum thyroxine (T4) and/or triiodothyronine (T3) concentrations and subnormal TSH concentrations. Subclinical hyperthyroidism is defined as a subnormal serum TSH level with normal serum levels of T4 and T3. Such patients have minimal hyperthyroidism, but are not necessarily asymptomatic. 5 If the hyperthyroidism originates from thyroidal overactivity or release of hormone from an inflamed thyroid gland, then the patient has endogenous hyperthyroidism. Exogenous hyperthyroidism occurs when patients are taking thyroid hormone supplements. Such patients may have overt hyperthyroidism if they are purposely taking thyroxine inappropriately (e.g., for weight reduction). The majority of patients with exogenous hyperthyroidism, however, have subclinical hy-

I. GRADES OF HYPERTHYROIDISM The thyroid gland is regulated by pituitary thyroidstimulating hormone (TSH; thyrotropin) production. METABOLIC BONE DISEASE

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perthyroidism. If the purpose of thyroid hormone therapy in hypothyroidism is to restore hormone levels to normal, replacement therapy with levothyroxine is administered. Overzealous replacement therapy may result in subclinical hyperthyroidism. Many patients are given thyroid hormone to suppress goitrous tissue or prevent regrowth of thyroid remnants or neoplasms. The goal of such therapy is to suppress serum TSH concentrations. Suppressive therapy by definition results in subclinical hyperthyroidism. This chapter is divided into separate sections. First, the effects of overt hyperthyroidism on bone and mineral metabolism are discussed, followed by consideration of endogenous subclinical hyperthyroidism, exogenous subclinical hyperthyroidism (suppressive therapy), and thyroid hormone replacement therapy.

II. OVERT HYPERTHYROIDISM Thyroid hormones have a direct resorptive effect upon bone. As a result hyperthyroid patients have loss of bone density, and a significant negative calcium balance. Basic studies will be reviewed with respect to cellular mechanisms by which thyroid hormone regulates bone cell metabolism, followed by consideration of clinical effects of thyroid hormone on bone and mineral metabolism, clinical thyrotoxic bone disease, and the effects of hyperthyroidism on bone mineral density.

A. C e l l u l a r E f f e c t s o f T h y r o i d H o r m o n e on Bone 1. CELL CULTURE

Thyroid hormone action at the cellular level requires T3 to bind a nuclear thyroid hormone receptor, which in turn interacts with thyroid response elements on thyroid hormone-responsive genes. 6 T4, the principal hormone secreted by the thyroid gland, is deiodinated to form T3 by one of two specific 5'-monodeiodinases present in most peripheral organs. 7 Nuclear T3 receptors have been characterized in several osteoblast cell lines including rat osteosarcoma ROS 17/2.8 cells 8'9 and UMR 106 cells, m mouse MC3T3-E1 cells, 1~ and human osteoblast cell lines. 12 Receptors have also been demonstrated in primary cultures of rat 13'14 and mouse ~5 osteoblasts. Although at high doses T3 usually inhibits cell replication in rat and mouse osteoblast cell lines, 9-~1'13'15 there is one report describing proliferation and differentiation of human osteoblast-like cells after T3 was added to culture medium. 16 T3 may also have direct nongenomic effects on bone via stimulation of the inositol phosphate secondmessenger pathway. ~7

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S

S. ROSS

T3 stimulates production of the bone proteins alkaline phosphatase 8'9'11'13 and osteocalcin (bone Gla protein) 8'9'13 in cultured rat and mouse osteoblast cell lines. Regulation of the levels of these mRNAs requires the presence of retinoids. TM T3 also increases IGF-1 and IGF-1 binding protein-2 production in cultured rat osteoblast cells 19'2~ and IGF-1 mRNA levels in cultured MC3T3-E1 osteoblast cells, 2~ although the significance of this finding with respect to osteoblast differentiation is not fully elucidated. T3 receptors have not been described in osteoclasts. Isolated osteoclasts do not respond directly to T3,22'23 although T3 increases bone resorption when rat osteoclastoma cells are co-incubated with rat osteoblast UMR cells in a bone slice resorption assay. 23 This effect occurs even when osteoblast cells are pretreated with T3, and the osteoblast cells are subsequently incubated with osteoclasts in the absence of T3. Thus osteoblasts appear to mediate thyroid hormone stimulation of osteoclast bone resorption, presumably via paracrine factors. 2. ORGAN CULTURE

Mundy et al. first demonstrated the direct effect of thyroid hormone on bone resorption in 1976. Using prelabeled rat femurs in organ culture, both T4 and T3 increased release of 45Ca into the medium. 24 Thyroid hormone also increases the release of both alkaline phosphatase and IGF-I. 25 Organ cultures of both long bones and calvaria have been utilized to study the effects of various paracrine factors on osteoclastic-mediated bone resorption as assessed by calcium release. Prostaglandin (PG) E2 and PGFI~ are increased after the addition of T3 to cultures or neonatal rat calvaria. 26 Nevertheless, indomethacin may inhibit 14'26'27 or have no effect 24"28'29 on calcium release from cultured bone. Interferon-~/26 and cyclosporin A 3~ inhibit thyroid hormone-mediated calcium release. Transforming growth factor 13 (TGF-[3) enhances thyroid hormone bone resorption 3~ and monoclonal antibody to TGF-[3 inhibits thyroid hormone-stimulated calcium release into media. ~5 Recent studies suggest that interleukin-6 (IL-6) is produced by osteoblasts and may stimulate osteoclast formarion and osteoclast-mediated bone resorption. 31 T3 potentiates the effects of IL-113 upon IL-6 release and bone resorption in cultured rat long bones. 27

B. B o n e a n d M i n e r a l M e t a b o l i s m The direct effects of thyroid hormone on bone resorption and the consequences thereof, as well as the additional effects of hyperthyroidism on calcium absorption, result in a significant negative calcium balance in


533 ~~.~I,"

1" T4, T3

f

r

,I, bone mineral density (osteoporosis) BLOOD

1~ BONE RESORPTION ,

URINE

1'PO4 1' renal TRP

/

.

1'c.

|

"

proline

1"c, _

~,P04

1

,j, conversion 25 OH-D to 1, 25 dI-OH-D

I,9gut absorption of Ca and PO 4

FIGURE 18--1 Bone mineral metabolism in hyperthyroidism. (From Wartofsky L: Does replacement thyroxine therapy cause osteoporosis? Adv Endocrinol Metab 4:157-175, 1993.)

thyrotoxic patients 32-34 (Fig. 18-1). Hypercalcemia due to resorption of bone occurs in only 5% to 8% of patients. 35 Serum albumin levels are lower in hyperthyroid patients than euthyroid c o n t r o l s , 36 and increased ionized calcium concentrations are found in up to 47% of patients. 37'38 Attempts to measure parathyroid hormone (PTH) levels in hyperthyroid patients were initially confounded by imprecise assays and occasional patients with coexistent primary hyperparathyroidism. Using intact PTH immunoassays, it is now clear that the elevated serum ionized calcium concentration suppresses PTH secretion. 39 This in turn results in an increased renal tubular reabsorption of phosphorus, and reduced conversion of 25-hydroxyvitamin D [25(OH)D] to 1,25-dihydroxyvitamin D [1,25(OH)2D]. 4~ 1,25(OH)2D levels are also subnormal in hyperthyroidism due to an increase in its metabolic clearance rate. 41 The reduced 1,25(OH)2D levels result in poor absorption of calcium and phosphorous from the gut. Calcium malabsorption in hyperthyroidism has been demonstrated in humans with tracer quantities of 45Ca administered orally. 42 This malabsorption is further aggravated by steatorrhea and increased gut motility seen in thyrotoxic patients, resuiting in further significant fecal calcium lOSS. 43 Calcium is also lost in the urine; parathyroid hormone suppression results in reduced renal tubular reabsorption of calcium, resulting in significant hypercalciuria. 44 The overall result is that hyperthyroid patients have a significant negative calcium balance.

C. Thyrotoxic Bone Disease Meunier and colleagues have reviewed the clinically apparent consequences of hyperthyroidism on the skel-

eton. 45 Fifteen of 187 patients (8%) with hyperthyroidism had symptoms. All were women, 80% were over the age of 50, two thirds had a fracture or severe bone pain, and three quarters had been hyperthyroid for less than a year. Radiological studies revealed generalized osteopenia. Vertebral compression fractures were common and in the absence of fracture, there was increased radiolucency of the spine. The phalanges showed a latticelike appearance to the trabecular bone, and a flaky appearance of cortical bone with striations on magnified views. Histomorphometric studies demonstrate more significant effects on cortical compared to trabecular bone. Trabecular bone volume was assessed by placing a grid over bone and determining the percentage of the grid occupied by calcified bone. Patients with overt hyperthyroidism had a 2.7% reduction in trabecular bone volume. In contrast, cortical bone demonstrated a 40% increase in osteoclast resorption surfaces and a 324% increase in cortical bone porosity. Although earlier studies indicate increased osteoid volume in hyperthyroidism, in this study there was no evidence of osteomalacia. Both cortical and trabecular bone undergo constant remodeling. Osteoclasts initiate the remodeling sequence by resorbing bone. Osteoblasts lay down new osteoid matrix which is subsequently remineralized. During the normal remodeling cycle, the amount of mineralized bone at the end of the cycle is equal to the amount of bone resorbed by osteoclasts, thus maintaining skeletal integrity. In overt hyperthyroidism, histodynamic studies using double tetracycline labeling demonstrate that the rate of remodeling and new remineralization fronts are increased to twice normal. Bone histomorphometry has been used by Eriksen to create three-dimensional reconstructions of the remod-

534

DOUGLASS. ROSS

eling sequence. 46 These reconstructions show that phases of resorption, laying down new matrix, and remineralization are all shortened in overt hyperthyroidism, but they are not shortened proportionately. Consequently, the normal remodeling cycle of approximately 200 days is halved, and each cycle is associated with a 9.6% loss of mineralized bone. The integrity of trabecular bone may also be undermined by the random accidental occurrence of osteoclast cutting cones perforating individual trabeculae, eliminating their ability to bear external stress. Since the rate of remodeling is increased twofold in overt hyperthyroidism, trabecular perforations also occur twice as frequently. Biochemical markers of bone turnover are increased in hyperthyroid patients. Alkaline phosphate is invariably increased in overt hyperthyroidism, and may remain elevated for months following treatment of hyperthyroidism; levels may increase during initial correction of hyperthyroidism, presumably reflecting increased osteoblastic activity as hyperthyroidism resolves. 47 Serum osteocalcin (bone Gla protein) is similarly increased in hyperthyroidism. 48'49 Urinary concentrations of bone collagen-derived pyridinium cross-links are increased in overt hyperthyroidism, and normalize shortly after treatment. 5~

D. B o n e D e n s i t y Bone density is reduced in overt hyperthyroidism. Controversy remains as to whether bone density can be normalized after treatment of the hyperthyroidism. In one of the earliest reports in 1971, Fraser and colleagues, using a simple x-ray assessment of bone density of the middle metacarpal, reported in a cross-sectional study that hyperthyroid patients had a 14% reduction in bone density, and that treated, previously hyperthyroid patients had a 5% reduction in bone density. 51 A recent study using dual energy x-ray absorptiometry (DEXA) of the lumbar spine demonstrated a 7.4% reduction in bone density in overt hyperthyroidism. 52 In several studies bone density has been measured before and after treatment of hyperthyroidism. Nielson and colleagues, using single-photon absorptiometry (SPA) of the forearm, found a 12% reduction in bone density in hyperthyroid patients that normalized after treatment. 53 Lind and Friis demonstrated a 28% reduction in SPA of the calcaneus that normalized after treatment. 54 In contrast, Krolner and colleagues, using dual-photon absorptiometry measurements of the lumbar spine, found a 13% reduction in bone density in hyperthyroidism, which was increased 1 year after treatment, but by only 3.7%. 55 Diamond and colleagues found hyperthyroid patients had a

12% reduction in bone density of the lumbar spine and a 13% reduction in bone density of the femoral trochanter that increased by only 6.6% and 3.2%, respectively, after 1 year of treatment. 56 Toh and colleagues found a 20% reduction in forearm SPA in hyperthyroid men that was only minimally improved 3 years after treatment. 57 In one other study an 11% increase in the DEXA of the lumbar spine was seen in treated hyperthyroid patients after 3 years. 58 There are two potentially confounding variables that need to be considered when assessing these data. First, the age of the patient, specifically the patient's menstrual status may be important when assessing the ability of bone to recover from thyrotoxicosis. Second, since thyroid hormone therapy may itself be a cause of reduced bone density (see below), it is important to note whether patients are receiving hormone replacement following ablative treatment for hyperthyroidism. Two recent studies help to address these issues. 59'6~ Franklyn and colleagues found reduced bone density of the femoral trochanter and lumbar spine in postmenopausal women with a history of thyrotoxicosis treated with radioiodine whether or not they were presently taking levothyroxine. 59 There was no reduction in bone density in premenopausal patients. Grant and colleagues also found postmenopausal women whose thyrotoxicosis had been treated with radioiodine 15 to 20 years earlier had reduced bone density (SPA distal forearm) whether or not they were taking levothyroxine. 6~Women treated by surgery 20 to 25 years earlier (i.e., patients treated with surgery were treated at a younger age) who were not receiving levothyroxine had normal bone density, while those receiving levothyroxine had reduced bone density. Overall, these data suggest that a prior history of hyperthyroidism is a risk for reduced bone density. Consistent with this are two recent reports which document that a prior history of hyperthyroidism results in an increased risk for hip fracture later in life. 61'62

III. ENDOGENOUS

SUBCLINICAL

HYPERTHYROIDISM Patients with endogenous subclinical hyperthyroidism have the mildest form of hyperthyroidism with normal serum concentrations of free T4 and T3, but subnormal serum TSH concentrations. 5 These patients are frequently elderly women with autonomy that has developed within a multinodular goiter; however, any form of hyperthyroidism can be subclinical. Mudde and colleagues measured the SPA of the forearm in patients with nodular goiter and subclinical hyperthyroidism, and compared their age-specific Z-scores to those of patients with nodular goiter who were euthyroid. 63 The patients


535

with subclinical hyperthyroidism had a significant reduction in mean Z-score to - 0 . 6 9 ; Z-scores were normal in the euthyroid patients. In addition, Z-scores were negatively correlated with serum free T 4 concentrations. F61des and colleagues also found that postmenopausal (but not premenopausal) women with nodular goiter and subclinical hyperthyroidism had reduced bone density at the radius and femoral neck, but not lumbar spine. 64 Treatment of postmenopausal women with endogenous subclinical hyperthyroidism with antithyroid drugs prevented further bone loss and resulted in significantly higher bone density after 2 years when compared to untreated controls with subclinical hyperthyroidism. 65 Parameters of bone metabolism have also been measured in endogenous subclinical hyperthyroidism. Faber and colleagues have shown elevations in serum osteocalcin concentrations in patients with nodular goiter and subclinical hyperthyroidism. 66 Serum osteocalcin levels were inversely correlated to serum TSH concentrations. These studies argue that endogenous subclinical hyperthyroidism has an adverse effect upon bone, especially in postmenopausal women, and that such patients may benefit from therapy aimed at normalizing serum TSH concentrations.

IV. EXOGENOUS SUBCLINICAL HYPERTHYROIDISM: THYROID HORMONE SUPPRESSIVE THERAPY Excessive use of exogenous thyroid hormone is a well-known cause of o v e r t hyperthyroidism. In 1982 Ettinger and Wingerd described reduced bone density in patients taking 3 to 4 grains of thyroid extract, 67 and in 1983 Fallon and colleagues described severe osteoporosis and fractures in three women taking excessive doses of thyroid hormones. 68 After sensitive TSH assays were introduced in the late 1980s, it became clear that in over half of the patients

TABLE 18-1

who were given levothyroxine in commonly recommended and prescribed doses, subclinical hyperthyroidism resulted. 69 A large number of clinical studies have been published since 1987. 7~ Overall, they support the conclusion that subclinical hyperthyroidism from levothyroxine therapy reduces cortical bone density more than trabecular bone density, and that significant reductions in bone density are seen primarily in postmenopausal women. Selected clinical studies are discussed below and recent selected studies are summarized in Tables 18-1 and 18-2.

A. B o n e D e n s i t y 1.

INITIAL

CROSS-SECTIONAL

STUDIES

Ross and colleagues first reported in 1987 that 28 premenopausal women who were taking levothyroxine for suppressive therapy of goitrous tissue had a 5% reduction in the SPA of the wrist after 5 years and a 9% reduction in bone density after 10 years of treatment. 72 None of these women had a prior history of hyperthyroidism. The average administered dose of levothyroxine was 0.171 mg/day, an accepted and recommended dose at the time, 73 but one that presently would be considered excessive even for suppressive therapy. Some of these patients were found to have elevated free T 4 concentrations and therefore would not precisely be considered " s u b c l i n i c a l " - - a concept that was in evolution at the time these data were published. TM Nonetheless, these data suggested that commonly prescribed doses of levothyroxine may be deleterious to bone. These results were confirmed by Paul and colleagues in a similar study of 31 premenopausal patients taking an average dose of 0.175 mg of levothyroxine. 75 There was a 12.8% reduction in the bone density of the femoral neck and a 10.1% reduction in the bone density of the femoral trochanter, although lumbar spine density, trabecular-rich bone, was unchanged. Concordant with

Thyroid Hormone Suppression and Bone Density: Cross-Sectional Studies in Premenopausal Women

Study

N

Wrist

D i a m o n d et al. 87

14

--

L e h m k e et al. 88

25

--

G o n z a l e z et al. 89

16

~

S t e p a n a n d L i m a n o v a 9~

20

Calcaneus

Hip $ 1 1%

--

F r a n k l y n et al. 93

18

M a r c o c c i et al. 94

47

~ --

G a r t o n et al. 95

20

--

Lumbar spine

536

DOUGLAS S. Ross

TABLE 1 8 - 2

Thyroid Hormone Suppression and Bone Density: Cross-Sectional Studies in Postmenopausal Women

Study

N

Wrist

Diamond et al. 87

10

$ 11%

Lehmke et al. 88

16

$ 15%

Gonzalez et al. 89

34

$

Stepan & Limanova 9~

25

Kung et al. 91

34

Franklin et al. 93

26

Schneider et al. 84

120

Giannini et al. 92

13

Hawkins et al. 82

84

Fujiyama et al. 83

12

Calcaneus

Hip $ 23%

$ 22%

Lumbar spine $ 16% __a

0.6 SD

+ lSD

$

7%

,l, 13%

$ 18%

$

,l, 5%

8%

$ 7%

a--indicates no change.

the histomorphometric studies in patients with overt hyperthyroidism (see above), this study suggested a more pronounced effect of thyroid hormone on cortical than trabecular bone. The study by Taelman and colleagues was one of the first to compare premenopausal women to postmenopausal women. 76 The reduction in bone density at the wrist was 5% in the premenopausal and 20% in the postmenopausal women; however, thyroid hormone dose was poorly controlled and many of the older women were likely on excessive doses of liothyronine. Two earlier studies highlighted the importance of excluding patients with a prior history of thyrotoxicosis. Adlin and colleagues reported that femoral neck bone density was reduced 9% and lumbar spine density 11% in 19 patients taking levothyroxine, although these charges no longer reached statistical significance if those patients with a prior history of hyperthyroidism were excluded. 77 Greenspan and colleagues also found that after excluding patients with a prior history of hyperthyroidism, changes in bone density were minimal. TM 2.

SUPPRESSIVE V E R S U S R E P L A C E M E N T T H E R A P Y

In several studies suppressive versus replacement doses of levothyroxine were compared; no significant difference in the two doses was found. 79-83 Ribot and colleagues reported that 21 patients taking 0.135 mg of levothyroxine daily with normal serum TSH concentrations had similar lumbar bone densities as 28 patients taking 0.154 mg/day with suppressed serum TSH concentrations. 79 Grant and colleagues reported that 34 patients taking 0.132 mg of levothyroxine with normal serum TSH concentrations had forearm bone density similar to those of 44 patients taking on average 0.155 mg of levothyroxine. In this study forearm density was

reduced 5% in the patients with suppressed serum TSH concentrations, but this did not reach statistical significance. 8~ Gam and colleagues 81 and Hawkins and colleagues 82 failed to show a difference in lumbar bone density between patients with normal and suppressed serum TSH. And in a recent study by Fujiyama and colleagues, the bone density was similar in patients taking on average 0.152 mg/day of levothyroxine with serum TSH levels less than 0.1 mU/liter compared to those taking 0.096 mg of levothyroxine with detectable serum TSH concentrations. 83 It is critical to note that the doses of levothyroxine used in these later studies were 54% to 90% of those in the initial reports, suggesting that clinician behavior had already been changed as a result of the first reports. Additionally, only the study by Grant and colleagues 8~had measured bone density at a cortical bone-rich site and comparisons made to controls who were not taking levothyroxine. Most of these studies are limited by small numbers of patients. Schneider and colleagues published a larger population-based study of bone density in 991 postmenopausal women that included 196 women taking thyroid hormone preparations. 84 Those women taking more than 1.6 ~g/kg body weight of levothyroxine daily ("suppressive therapy") had a 7% reduction in bone density at the distal radius, an 8% reduction at the hip, and a 5% reduction at the spine. In contrast, those women taking less than 1.6 ~g/kg body weight of levothyroxine ("replacement therapy") had no reduction in bone density (Fig. 18-2). 3.

SUPPRESSION F O R T H Y R O I D C A N C E R V E R S U S

SUPPRESSION F O R B E N I G N G O I T E R

In two studies bone losses in patients on suppressive therapy for benign goiter versus suppressive therapy for


537

FIGURE 1 8 - 2

Bone mineral densities in postmenopausal women living in Rancho Bemardo, CA, by current thyroid hormone dose level adjusted for age, body mass index, smoking, and use of thiazide diuretics, oral corticosteroids, and estrogen. (From Schneider DL, Barrett-Connor EL, Morton DJ: Thyroid hormone use and bone mineral density in elderly women: Effect of estrogen. JAMA 271:1245-1249, 1994.)

thyroid cancer were compared. The assumption is that the cancer groups were treated more aggressively with levothyroxine suppression than the patients with benign goiter. Mtiller and colleagues found that patients on suppressive therapy for thyroid cancer, but not patients with goiter, had a 5% reduction in bone density at extremity cortical-rich sites when compared to controls. Additionally, the patients with cancer had a 12% reduction in calcium bone index, a measure of total calcium in the central third of the skeleton, when compared to patients with goiter, s5 McDermott and colleagues found significant reductions in bone density in treatment of thyroid cancer or benign goiter in both cortical- and trabecularrich bone compared to controls. 86 In patients with thyroid cancer, bone density at cortical-rich sites (radius and femoral neck), but not trabecular-rich sites (lumbar spine), was lower than that in those receiving suppressive therapy for benign goiter. 4. R O L E OF MENSTRUAL STATUS Finally, most recent studies of suppressive therapy in thyroid cancer patients have noted the importance of menstrual status (Tables 18-1 and 18-2). Diamond and colleagues documented a 11% reduction in bone density of the hip in premenopausal women and a 23 % reduction in hip density in postmenopausal women; bone density was reduced 11% at the wrist and 16% at the lumbar spine but only in postmenopausal patients. 87 Lehmke and colleagues also reported significant reductions in density

at the radius and calcaneus, but not lumbar spine, that were significant only for postmenopausal women. 88 Gonzalez and colleagues found significant reductions at the wrist but not lumbar spine in postmenopausal women only. 89 Stepan and Limanova found reductions in lumbar spine but only in postmenopausal women. 9~ Kung and colleagues found an 18% reduction in lumbar spine and 12% to 13% reduction in femoral neck and trochanter in postmenopausal women 91 and Giannini and colleagues found a 7% reduction in bone density of the lumbar spine only in postmenopausal women. 92 In contrast, Franklyn and colleagues, in a well-designed study in which average levothyroxine dose was 0.19 1 mg/day reported no change in either femoral or vertebral bone density 93 in postmenopausal women. Nevertheless, Marcocci et al. 94 and Garton et al. 95 found no significant change in either femoral or vertebral bone density in premenopausal women on levothyroxine suppressive therapy. Later, however, a significant correlation of levothyroxine dose with annualized bone loss at the femoral neck, was observed. 5. LONGITUDINAL STUDIES

All of the studies discussed above are cross-sectional and therefore have limitations. In two small studies patients have been followed longitudinally. Stall and colleagues described ten patients who were inadvertently included in a large study following bone density in women but were retrospectively identified as having sub-

5

3

8

D

O

U

clinical hyperthyroidism due to levothyroxine therapy. 96 Their annualized rate of loss of density of the femoral neck was increased four- to fivefold, while bone loss of the spine was increased two- to threefold; only the loss at the spine was statistically significant. Pioli and colleagues prospectively followed 14 premenopausal women taking on average 0.147 mg of levothyroxine following thyroidectomy for goiter or thyroid cancer, and compared them to 24 age-matched controls over 3 years. 97 Spinal density fell at a rate of 2.6% per year in the levothyroxine-treated patients, and 0.2% per year in the controls. Curiously, there was no change in radial bone density. a. Meta-analysis A recent meta-analysis of the literature regarding bone density in patients with subclinical hyperthyroidism due to levothyroxine therapy found that there was a significant reduction in bone density for postmenopausal women only. 98 The analysis was based upon a theoretical bone containing 30% distal forearm, 29% femoral neck, and 41% lumbar spine.

G

L

A

S

S. ROSS

have failed to demonstrate an adverse effect of carefully monitored levothyroxine suppressive therapy in premenopausal women. Nevertheless, annualized bone loss in premenopausal women is correlated with levothyroxine dose. This suggests that the reduced doses of levothyroxine prescribed both as a result of the early reports in patients taking higher doses, and the use of sensitive TSH assays to closely monitor therapy, have significantly ameliorated the problem for premenopausal women.

B. Biochemical Markers of Bone Mineral Metabolism

Several parameters of bone metabolism other than bone density have been measured in addition in patients with subclinical hyperthyroidism taking thyroid hormone supplements. Variable abnormalities have been reported. Harvey and colleagues found that postmenopausal women with subclinical hyperthyroidism taking levothyroxine had increased urinary concentrations of the bone b. Does Calcitonin Deficiency Result in Loss of collagen-derived pyridinium cross-links pyridinoline Bone? It is unclear what role if any calcitonin defiand deoxypyridinoline. 1~ Ross and colleagues demonciency might have upon bone. In one prospective study strated an inverse negative correlation between serum by Pioli and colleagues, 97 the thyroidectomized patients osteocalcin and TSH concentrations in patients taking would have been calcitonin deficient compared to the levothyroxine. 1~ Krakauer and Kleerekoper found incontrol group. In most of the cross-sectional studies creased urinary hydroxyproline concentrations in pathere is the potential for significant differences in calcitients with subclinical hyperthyroidism taking an avertonin concentrations between patients and controls, since age dose of only 0.130 mg of levothyroxine daily. 1~ hypothyroidism from both surgery and radioiodine, 99'1~176 Giannini and colleagues found increased serum alkaline or chronic thyroiditis TM all adversely affect C-cell funcphosphatase and urine hydroxyproline concentrations in tion. Several studies have attempted to address this quespostmenopausal women taking on average 144 Ixg of tion. Prior to the appreciation that levothyroxine therapy levothyroxine daily, but not in premenopausal women might reduce bone density, McDermott and colleagues receiving on average 152 txg of levothyroxine daily. 92 In attributed reductions in bone density in thyroidectomized contrast, in three other studies, serum osteocalcin levels patients to calcitonin deficiency. ~~ Hurley and coland urinary excretion pyridinium cross-links were not leagues failed to show reduced bone density in a small increased in premenopausa195 or postmenopausa183 heterogeneous group of patients. ~~ Unfortunately, it is women taking levothyroxine, and serum osteocalcin levnow clear that as yet no experimental design has satisels were not increased in postmenopausal women taking factorily separated the variable of calcitonin deficiency levothyroxine. 82 from concurrent levothyroxine therapy, and therefore the potential role of calcitonin deficiency in these patients remains undefined. 89'1~176 6. CONCLUSIONS The data reviewed in this section suggest that subclinical hyperthyroidism from levothyroxine suppressive therapy adversely affects bone density in postmenopausal women at cortical-rich sites such as femoral neck. Significant reduction in bone at trabecular-rich sites such as lumbar spine have been variable. In contrast, despite initial reports that premenopausal women had reduced bone density at cortical-rich sites, most recent studies

C. Fractures Presently there is uncertainty as to whether patients taking levothyroxine have an increased rate of fractures despite almost a decade of clinical research on the effects of thyroid hormone on bone density. One preliminary study suggested a twofold increased risk of hip fracture in women taking thyroid supplements although serum TSH concentrations were not measured. 1~ Leese and colleagues reported on 1180 patients taking levothyrox-

539

CHAPTER 18 Bone Disease in Hyperthyroidism ine: 59% had suppressed serum TSH concentrations and 38% had normal serum TSH levels. 11~Over a 5-year period the overall fracture rate in women over age 65 was 0.9% for patients with a normal TSH and 2.5% for women with a subnormal TSH. These differences were not statistically significant. Solomon and colleagues interviewed 330 women taking levothyroxine but did not find an increased fracture rate. TM In contrast, as noted previously, women with a prior history of hyperthyroidism and bone density values similar to those noted in patients taking suppressive doses of levothyroxine do have an increased fracture r i s k . 61'62 One would anticipate that the reported reductions in bone densities in patients with subclinical hyperthyroidism would be sufficient to result in an increased fracture rate112; perhaps larger studies are required.

V. THYROID HORMONE REPLACEMENT THERAPY Overtly hypothyroid women who are started on levothyroxine for replacement therapy have a reduction in bone density. Krolner and colleagues prospectively followed eight women whose lumbar spine density fell by 13% after 1 year of levothyroxine replacement therapy. 55 Ribot and colleagues followed ten women for 1 year after starting levothyroxine and found a 5.4% and 7% reduction in the bone density of the lumbar spine and femoral neck, respectively. 79 In contrast Toh and Brown failed to show a reduced bone density in eight hypothyroid men who were treated with levothyroxine for 3 years. 113 The reason for this is suggested by Ericksen's analysis of the bone remodeling cycle in overt hypothyroidism. 46 The cycle is increased from about 200 to almost 700 days in overt hypothyroidism, and each cycle is associated with a 17% increase in mineralized bone. The histomorphometric study of Coindre and colleagues TM demonstrates the likely cause of this apparent loss in bone following institution of thyroid hormone replacement. Ten untreated hypothyroid patients were compared to 15 patients treated with levothyroxine and euthyroid controls. The untreated hypothyroid patients had a mean cortical width that was actually higher than that of euthyroid controls, and levothyroxine treatment was associated with a significant increase in resorption surfaces and cortical bone porosity, and a decrease in mean cortical width to levels similar to those seen in euthyroid controls. TM Thus it is likely that replacement therapy reduces bone density from elevated to normal values. Ross studied postmenopausal women with subclinical hypothyroidism in a randomized trial of levothyroxine therapy to determine if replacement therapy p e r s e might

be detrimental to bone. 115 If the loss in bone density seen during the early treatment of overt hypothyroidism were due to increased remodeling and osteoclast resorption preceding the return to normal steady-state conditions, then one would not expect a similar reduction in bone density when levothyroxine was administered to patients with subclinical hypothyroidism, since the initial abnormality in bone remodeling would be trivial in these patients. There was no reduction in bone density at either the wrist or lumbar spine after 14 months of levothyroxine replacement therapy in postmenopausal women with subclinical hypothyroidism. 115 Thus the apparent loss in bone during the initial treatment of hypothyroidism partly reflects the delay in reestablishing normal steadystate conditions. Nystrom and colleagues demonstrated increased serum concentrations of procollagen III peptide 6 months after the initiation of levothyroxine therapy, but procollagen III peptide levels were no different from untreated controls after 10 years of levothyroxine replacement. 116 These data also support the hypothesis that transient abnormalities in bone metabolism shortly after initiating levothyroxine replacement therapy reflect a delay in achieving normal steady-state dynamics. Many of the cross-sectional studies noted above comparing suppressive with replacement therapy demonstrated normal bone mineral density in women receiving replacement doses of levothyroxine. 79-83 Nevertheless, there is one cross-sectional study that did demonstrate reduced bone density in patients on replacement therapy. Kung and Pun reported on 26 premenopausal hypothyroid women with chronic lymphocytic thyroiditis who were treated with an average dose of 0.111 mg/day of levothyroxine for an average of 7.5 years. 117 TSH levels were carefully monitored and were normal throughout the study. Bone density of the femoral trochanter was reduced 7%, while there was no change in the density of the lumbar spine. While a review of present data suggest that this study is an outlier, it is possible that even replacement doses of levothyroxine could be detrimental to bone, since they fail to perfectly mimic normal physiology. Euthyroid patients taking levothyroxine have serum T4 concentrations that are on average 1 to 2 Ixg/dl higher than euthyroid untreated controls at a time when both s e r u m T3 and TSH concentrations are normal. ~18

VI. TREATMENT AND PREVENTION OF THYROID HORMONE-MEDIATED BONE LOSS Overt hyperthyroid requires rapid treatment to avoid skeletal as well as other complications of thyrotoxicosis. While treatment of endogenous subclinical hyperthyroid-

540

DOUGLAS

ism remains controversial, recent data demonstrate the benefit of antithyroid drugs in minimizing further loss in bone density. 65 Based on current information, one should strongly consider antithyroid therapy in estrogendeficient postmenopausal women with even minimal subclinical hyperthyroidism. For patients with exogenous subclinical hyperthyroidism, the major focus is on prevention of bone loss. Careful titration of levothyroxine replacement therapy should avoid subclinical hyperthyroidism altogether. Patients who are intentionally given suppressive doses of levothyroxine by definition have subclinical hyperthyroidism. It is still uncertain as to the degree of TSH suppression necessary in specific clinical settings. For example, many authors have recommended that patients with thyroid cancer maintain fully suppressed TSH concentrations (:Z: ).. E Z

,~

ol

ol

0 -r n U.I

800

40 z

_J r .J

=E :3

20 tu

400

01

:3

I

6

l

12

I

I

18

24

i

30

I

36

I

42

I

48

i

54

I

60

I

66

l

72

MONTHS

FIGURE 19--43

Result of a 72-month period of daily subcutaneous administration of human calcitonin to a 68year-old man with Paget's disease. The upper limit of normal for urinary hydroxyproline is 40 mg/24 hr and for serum alkaline phosphatase activity is 3 Bessey-Lowrey-Brock units.

have produced modest results. 3~176 In our own experience, only a minority of patients treated with salmon calcitonin by nasal spray had a response equivalent to that produced by parenteral administration. It should also be noted that human calcitonin is no longer commercially available. Since the advent of potent bisphosphonate therapy the use of parenteral salmon calcitonin therapy has decreased. In selected patients with mild to moderate disease activity it is still a reasonable option if bisphosphonate therapy proves ineffective or not tolerable.

C. Bisphosphonates Bisphosphonates (formerly diphosphonates) are synthetic analogues of inorganic pyrophosphate in which -P-C-P- bonds are substituted f o r - P - O - P - bonds. The bisphosphonates bind to the surface of calcium phosphate mineral. This property is responsible in part for localization of the bisphosphonates coupled to a radionuclide, in regions of active bone formation. In vitro, the bisphosphonates retard precipitation of calcium phosphate from solution and slow the growth and dissolution of hydroxyapatite crystals. Extensive studies in experimental animals and humans indicate that they inhibit

bone resorption and formation. The mode of action of bisphosphonates is complex and likely to involve direct effects on osteoclasts and osteoclast precursors as well as indirect effects on these cells through possible interactions with osteoblasts and macrophages. 3~ The mode of action also appears to be dependent on the structure of the side chains. The first bisphosphonate used to treat Paget's disease was disodium etidronate, which is usually administered at a dose of 5 mg/kg body weight daily for 6-month periods, e78'3~ Treatment with this dose results in a slow decrease in serum alkaline phosphatase activity and urinary hydroxyproline excretion, which reach a nadir between 3 and 6 months after beginning treatment. The decrease in urinary hydroxyproline excretion usually occurs prior to the decrease in serum alkaline phosphatase activity. After a 6-month period of treatment, their biochemical abnormalities may remain suppressed for 1 year or more 3~ in many patients. As has been found with calcitonin therapy, there are several patterns of biochemical response to disodium etidronate. 3~ Approximately 40% of patients have a prolonged response after a single course of therapy. These individuals are often those with modest initial elevation of biochemical indices of disease, although occasionally patients with markedly elevated alkaline phosphatase levels may also have a pro-

586

FREDERICK R. SINGER AND STEPHEN M. KRANE

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FIGURE 1 9 - 4 4 The control and treatment levels of urinary hydroxyproline, plasma alkaline phosphatase and salmon calcitonin-125I binding titer during an 11.5-month period when a 5 I-year-old male received 1200 MRC units of salmon calcitonin daily. The hydroxyproline data points represent the mean SE of at least five 24-hour urine collections during a 1-week period. The upper limit of normal is 40 mg/24 hours. The alkaline phosphatase data points represent the mean SE of at least three blood samples taken during the week. The upper limit of normal is 2.6 Bessey-Lowrey-Brock units. The binding titer is plotted on a log scale. (From Singer FR, Aldred JP, Neer RM, et al: J Clin Invest 51:2331, 1972.)

longed remission. A second group of patients 3~ (---45%) experience a good response to the initial course of therapy but require retreatment with disodium etidronate 3 to 63 months after the initial therapy, and then respond similarly to 20 mg/kg/day but not as well to 5 mg/kg/ day. The final group of patients 3~ (---15%) do not respond to retreatment during an average follow-up of 6 years. Resistance is best predicted by an initial urinary hydroxyproline level of more than ten times normal. Following high-dose disodium etidronate therapy, a reduction in cardiac output is observed coincident with reduction of biochemical activity. 31~The mean reduction of---27% is probably explained by a proportionate reduction in skeletal blood flow. 242 Other features of the clinical response to disodium etidronate are not identical to those produced by calcitonin, however. Bone pain may be relieved in 50% or more of patients 3~1 over a period of several months, but not infrequently a dramatic increase in bone pain develops in the site of pagetic lesions. 3~ This is more likely to occur with 20 mg/kg/ day, but we have noted a paradoxical increase in pain

even in patients treated with 5 mg/kg/day. After treatment is stopped, the pain usually resolves within several weeks to months. The pathogenesis of disodium etidronate-induced bone pain is not known but is likely related to inhibition of bone mineralization, which will be discussed subsequently. Another puzzling aspect of the response to disodium etidronate is that despite considerable suppression of biochemical indices of disease, the extent of osteolytic lesions may increase during treatment. 278'312-314 An example is illustrated in Figure 19-47. The increase in radiolucent lesions associated with disodium etidronate therapy is most likely to occur with a dose of 10 or 20 mg/kg/day. We have also observed worsening of osteolytic lesions in several patients treated with 5 mg/kg/day, although this is observed only in a minority of treated patients. Little evidence for healing of osteolytic lesions has been presented. In one report, two of three lesions healed during multiple courses of therapy. 315 In another report, radiological healing was evident in three patients with multiple osteolytic lesions but the results were not

CHAPTER 19 Paget's Disease of Bone

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consistent. 278 A minority of the lesions improved, but the majority deteriorated. After treatment is stopped, healing may occur spontaneously 3~6 and may be accelerated if calcitonin therapy is instituted. 278 The explanation for the paradoxical increase in bone pain experienced by some patients and the worsening of osteolytic lesions may be found in an examination of bone biopsies from treated patients. A characteristic find-

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ing in patients treated with 20 mg/kg/day is an increase in osteoid surface and osteoid seam thickness, which develops as a consequence of impaired mineralization. 316 This mineralization defect is probably dose-related, since in several series patients treated with 5 mg/kg/day infrequently accumulated e x c e s s o s t e o i d . 3~ Boyce et al., 3~8 however, noted osteomalacia in 9 of 13 transiliac biopsy specimens in patients treated for 6 months with

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N terminal direction after the procollagen chains have been aligned and stabilized by intrachain disulfide bonds present in the Cterminal domain (Fig. 2 3 - 8 , step F). The presence of glycine substitutions within the gly-X-Y triplet slow the rate of helix assembly. 328'329The presence of the proet2(I) chain facilitates helix assembly because homotrimeric molecules are slow to assemble. 33~ Until the triple helix is complete, specific proline and lysine residues can be posttranslationally modified by hydroxylation and, in the case of lysine, glycosylation with glucose and galactose. TM If the rate of helix formation is slowed, then the posttranslational modification process will continue, causing overhydroxylation and excessive glycosylation of lysine residues in the helical domain distal, or Nterminal to the point of helix stability. 332 This polarity of posttranslational modification provides an indirect localization of a mutation. The completed procollagen molecule is secreted from the cell by an exocytotic process that is poorly understood (Fig. 2 3 - 8 , step G). Mutant molecules with helical instability are inefficiently secreted from the cell and thus undergo intracellular degradation. 223 Chaperone proteins resident within the endoplasmic reticulum play a role in distinguishing certain types of mutation, particularly those within the C-terminal propeptide that interfere with procollagen chain assembly. 333-335 Specific extracellular procollagen peptidases cleave the N- and C-terminal propeptides, permitting the helical segment of the molecule to enter into the formation of the microfibril. 336 Lysyl oxidase, acting on specific lysine residues

670

DAVID W. ROWEAND JAY R. SHAPIRO

within the microfibril, initiates the formation of covalent crosslinks between procollagen molecules. 278 Mutations within procollagen that alter its susceptibility to enzymatic cleavage of collagen propeptides have been described. 337 In contrast to most enzymatic diseases that have a recessive inheritance, these structural mutations affect the procollagen substrate for these enzymes. The dominant inheritance pattems occur because one half of the molecules that accumulate in the tissue contain the abnormality. Mutations that primarily affect this aspect of collagen biosynthesis do not result in OI but are associated with EDS type VII. However, "overlap syndromes" with features of OI and EDS have been described that appear to result from mutations that destabilize the helix and affect the cleavage of the Nterminal propeptide. 43'338'339

C. C e l l u l a r R e g u l a t i o n o f B o n e C o l l a g e n Synthesis and Degradation Although bone collagen synthesis and degradation are highly regulated by the calcitropic hormones, 34~ cytokines, and growth f a c t o r s , 341 the influence of these factors on collagen synthesis in OI is unknown. In a manner yet to be defined, the osteoblast can increase collagen production when sensing mechanical stress while bone resorption occurs rapidly upon removal of gravitational f o r c e . 342 In cultured OI fibroblasts, mutant molecules that are initially incorporated into the matrix are gradually lost, providing a mechanism to improve the quality if not the quantity of m a t r i x . 343'344 However, OI bone cells do incorporate the mutated proteins into the matrix both in vitro and in intact bone but not skin. 345'346 This finding may be a partial explanation why the type I collagen mutations are expressed more dramatically in bone than in skin. The factor(s) mediating the increased bone turnover in certain forms of OI does not appear to be a primary or secondary alteration in calcitropic hormones. Clearly, areas for future research will be the mechanisms by which (1) cytokines, and locally acting growth factors each influence total collagen synthesis by the osteoblast, 347 and (2) how the cell recognizes the structurally compromised collagen molecule either before or after it is secreted into the matrix. The relative contribution of increased cell matrix production can result from a combination of increased output per osteoblast unit and an increase in the number of units per unit volume of bone tissue. Despite the fact that bone turnover in OI is high and frequently the bone tissue demonstrates hyperosteocytosis, there is a fundamental defect of matrix production and cell proliferation inherent to the OI bone cell. The inherent properties of the OI bone cells are revealed when grown in tissue

culture where they are removed from the local regulatory factors within the bone matrix. While the properties of OI bone cells indicate that they are fully differentiated osteoblasts, 348 the synthesis and accumulation of collagen and other proteins characteristic of mature bone matrix are signifcantly less than bone cells from an agematched individual. 349-352 The rate of proliferation and the density at confluence of OI-derived cells are significantly less than in cells from normal donors. The relative inefficiency of OI cells in cell culture is revealed when the two populations of cells derived from a mosaic individual are examined. 13 Although initially the cells that grow out in the dish contain the OI mutation, over time the cells containing the mutation are lost from the culture as the normal cells outgrow the OI cells. The synthetic and cell growth aspects appear to be more severe in OI bone cells than in fibroblasts. In many respects, cultured OI cells resemble cells from aged donors, as judged by their growth properties and the rates and even the relative proportion of the matrix protein produced. While this inherent property may be a primary consequence of the mutated collagen protein, it might reflect the chronic proliferative stress placed on the osteoprogenitor lineage pathway. In many respects, OI resembles a hemolytic anemia such as thalassemia or sickle cell disease. The hematopoietic lineage is dramatically stimulated in a futile attempt to produce adequate amounts of a functional globin. Because there appears to be a finite capacity of stem or early progenitor cells to maintain this replicatory activity, the long-term consequence can be an aplastic crisis. It would not be surprising that the same phenomenon could occur in OI and further complicate the pathogenic mechanisms for poor formation. The early stages of OI are characterized by a robust proliferative and synthetic output in the face of the inherent limited capacity. Over time, the lineage potential is gradually lost, which will contribute another major factor toward bone fragility.

VI. BIOCHEMICAL

AND MOLECULAR

TOOLS FOR THE IDENTIFICATION OF MUTATIONS

IN PATIENTS

WITH

OI

Cultured dermal fibroblasts have served as osteoblasts from affected individuals as useful tissues in which to study abnormalities in the synthesis or structure of type I collagen. Although the regulation of type I collagen in the fibroblast is not the same as that of the osteoblast, genetic abnormalities of bone collagen are presumed to be accurately reflected by the collagen synthesized by the fibroblast. This is not surprising, since there is only one copy of each type I collagen gene per haploid cell,

CHAPTER 23 Osteogenesis Imperfecta and therefore a mutation in the gene would be expressed in all cells that make type I collagen. Initial studies in OI characterized the abnormalities of type I collagen protein synthesis in OI, while newer techniques of polymerase chain reaction (PCR) and gene cloning have revealed the primary nucleotide alterations of collagen genes. Because these methods are becoming the basis for understanding the defects in all heritable connective tissue diseases, it is necessary that the clinician appreciate their underlying principles.

671 mutation can be localized to a specific cyanogen bromide fragment. 358 The consequences of a mutation that destabilizes the triple helix can be demonstrated by measuring the thermal stability of the molecule. 43'278 The intact collagen helix is resistant to proteolytic enzymes such as pepsin or trypsin. However, when the temperature is elevated toward 41.5~ the helix starts to unfold (denature) and becomes susceptible to the action of these enzymes. Thus, collagen molecules containing a mutation that destabilizes the helix will be degraded by these enzymes at or below physiological temperatures. 277'28~176

A. A n a l y s i s o f C o l l a g e n a n d P r o c o l l a g e n When dermal fibroblasts are cultured with radiolabeled proline, the radioactive collagen and procollagen bands can be identified by their electrophoretic mobility within polyacrylamide gels. From this analysis, amino acid deletions or insertions within the protein may be detected (see below). Quantization of the density of bands on the autoradiograph can be used to estimate the production rate of type I collagen and its oL chains. For example, diminished total synthesis can reveal a nonfunctional allele for one of the oL chains. 353 It can also indicate unbalanced production of oLchains; for example, if there is a population of molecules composed of three oL1(I) chains [oL1(1)3] rather than the normal heterotrimer of two oL1(I) chains and one oL2(I) chain. T M Evidence for impaired secretion of procollagen molecules can be obtained by separately analyzing the media and cell layer for their content of procollagen molecules. 223 Polyacrylamide gel electrophoresis of procollagen oL chains can demonstrate the presence of a gene deletion or insertion when it is greater than 30 amino acids. 28~ Since each collagen allele is diploid, the presence of such a mutation often results in a widened or duplicate oL chain band that represents both the normal and deleted allele. Evidence for even smaller mutations within the collagen helix can be obtained. 356 Since a mutation may delay the rate of helix formation, this results in excessive posttranslational hydroxylation and glycosylation of lysine residues which, in turn, results in a slowing of the migration rate within the acrylamide gel. A mutation of this type can be localized to a specific region of the helix if the collagen chains are cleaved into smaller fragments with cyanogen bromide and separated by electrophoresis. Since the collagen helix forms in a C--->N terminal direction, those cyanogen bromide fragments having delayed migration must have been positioned N-terminal to the mutation site, while those with a normal gel migration rate should be positioned C-terminal to the site of mutation. 357 Recent advances in protein microsequencing techniques also permit the identification of subtle mutations in type I collagen, particularly when the

B. M o l e c u l a r H y b r i d i z a t i o n Under proper experimental conditions, complementary strands of nucleic acid will anneal or hybridize in a very precise manner. 361 The minimum length of homology between two strands is 50 to 100 nucleotide bases, although hybridization between even shorter lengths is possible. A cloned segment of DNA is made radioactive and is used to detect the presence of a complementary strand of DNA or RNA within a mixture of many other base sequences. The hybridization probe can be either genomic DNA (containing introns and exons) or complementary DNA (cDNA produced by reverse transcription of mRNA) and used to detect a specific DNA or mRNA base sequence. Both forms of cloned DNA to type I collagen genes are now available from a number of research laboratories. They were constructed in a bacterial plasmid from RNA extracted from cultured fibroblasts or isolated from a genomic "library" constructed in lambda phage. Hybridization probes constructed with RNA have even greater sensitivity in detecting a complementary base sequence than do probes made from D N A . 362 However, it is the advent and application of PCR for amplifying segments of RNA or DNA for automated DNA sequencing that has led to an explosion of reported cases in OI in which the underlying mutation has been identified. 363'364A database of reported mutation has recently been established and is available through an intemet site (http://www.le.ac.uk/genetics/collagen/ collagen.html).365 At present the following methods can be undertaken with existing molecular hybridization probes. 1. SOUTHERN AND NORTHERN BLOT HYBRIDIZATION

A mixture of either DNA or RNA can be separated by molecular size within agarose gels and subsequently transferred and fixed to a nitrocellulose membrane. The membrane is incubated with a radiolabeled hybridization probe under defined conditions. After extensive washing,

672 a complementary strand of RNA or DNA is identified by exposing the membrane to an x-ray film. When DNA is identified by this procedure, it is referred to as a Southern blot (after the originator's name), while RNA blots are termed "Northern." In each case only complementary sequences will be hybridized from a complex mixture of unrelated sequences. This method is also used to indicate the size of a particular complementary RNA species or restriction fragment of DNA (see next). The limit of resolution by this method is 50 to 100 bases. 2. RESTRICTION FRAGMENT LENGTH POLYMORPHISMS

Restriction fragments of DNA are generated by commercially available specific bacterial nucleases that cleave DNA through highly defined sequences 4 to 6 bases in length. Since these sites occur infrequently within genomic DNA, their presence can be used to map DNA in a highly reproducible manner. 366 The method of restriction fragment length polymorphism (RFLP) is based on the fact that certain restriction cleavage sites within genomic DNA are lost due to silent base changes within the cleavage sequence. These variations are polymorphic within a population; however, within a family these base changes are transmitted as mendelian dominants. The method does not itself indicate the site of the mutation, but it does demonstrate that the mutation is located within the gene adjacent to or surrounding the p o l y m o r p h i c site. 367 Thus the demonstration of a polymorphism linked to a specific OI phenotype would focus research effort to that ot chain gene. While the approach is no longer used for specific mutation identification, it still is of use in excluding mutation within a collagen gene in association with a bone disorder within a pedigree or subpopulation. 53'368 3. LOCALIZATION OF MUTATION WITHIN COLLAGEN M R N A OR D N A

Because of the size and the multiple exons of the collagen, many investigators have utilized techniques that point to a specific fragment of the gene likely to harbor a mutation prior to initiating DNA sequencing. Early success was obtained by directly assessing collagen RNA for subtle differences in hybridization to an RNA or DNA template that can be detected by chemical


tension logarithmically amplify the original template such that sufficient DNA is available for analysis after 1 to 2 hours in an automated thermocycler. The template can be genomic DNA, in which case primers are selected to amplify clusters of exons and the included introns. Mature RNA lacking introns can be analyzed by first converting it to a cDNA with reverse transcriptase, giving rise to the acronym of RT-PCR. In either case, specific fragments are amplified throughout the length of the gene or RNA with primer sets derived from the known sequence of each COL1A1 or COL1A2 gene. A variety of methods have been developed to identify a single base pair mutation within the amplified fragment. They are based on a subtle difference of hybridization that occurs when DNA strands from the normal and mutant alleles are melted and reannealed. The resuiting mismatch can be detected by certain organic chemical r e a c t i o n s 373-376 or by subtle differences in migration within a denaturing gel electrophoresis. 377'378The third approach, which has attained the widest acceptance, is based on subtle differences in molecular conformation of single strands of DNA differing in a single base. Here, the PCR-amplified DNA is denatured and then separated by electrophoresis as single strands of DNA in a nondenaturing environment. The method is referred to as single-strand conformation polymorphism ( S S C P ) . 379 4. QUANTITATION OF A SPECIFIC M R N A

The most quantitative method is referred to as a dot blot hybridization. 38~ RNA extracted from tissue is diluted to different concentrations and fixed onto a nitrocellulose membrane. After the RNA is hybridized to a specific radiolabeled cDNA, the intensity of the radioactive spot on the x-ray film is compared to the signal from an RNA standard. However, if the probe crossreacts with other RNA species likely to be in the extract, then standard Northern blot hybridization is necessary. Although methods to quantitate using quantitative RT-PCR have been developed, 381 it is not always required because of the abundance of type I collagen mRNA in most tissue extracts. Any of these methods can be applied to RNA located within the cytoplasm or the nucleus of cultured cells and is valuable in studying regulatory mutations of collagen. 382

c l e a v a g e 369 or R N a s e s . 37~

All of the techniques now in common usage are based on PCR amplification of a specific fragment for subsequent analysis. Synthetic DNA primers that flank the region to be amplified and that are complementary to sequences on opposite strands of the DNA are used to hybridize its template. A thermostable DNA polymerase extends each primer making a copy of the template. Repeated cycles of denaturation, rehybridization, and ex-

C. D N A S e q u e n c i n g The advent of rapid and robotically automated DNA sequencing techniques now makes it possible to directly analyze for a mutation within a collagen gene by sequencing overlapping PCR-generated fragments. 383 While this approach is not routinely available, it has the

CHAPTER 23

673


advantage that all potential mutations within a fragment are identified, which is not the case for the method discussed above. However, direct sequencing to total cellular collagen RNA is unlikely to identify null mutation because the mutant template is less than 5% of the normal template. The most efficient approach combines the localization techniques with rapid sequencing.

VII. MOLECULAR PATHOPHYSIOLOGY

phenotypes will be presented in decreasing order of clinical severity.

A. L e t h a l ( T y p e II) O I The majority of research effort has been spent with cultured dermal fibroblasts derived from this type of OI. The best studied case, first identified by Penttinen, 386 has been shown to contain a 651-base-pair deletion within the midportion of one of the oLl(I) alleles (Fig. 2 3 - 9 , step A). This abnormality was first detected in the collagen oL1 chains by the presence of a doublet in the et 1(I) chain region by polyacrylamide gel electrophoresis. 223 Subsequently, a doublet was demonstrated in the etl(I) mRNA. When the etl(I) gene was analyzed it could be shown that one allele lacked a certain restriction site, while another restriction fragment was shortened by

OF OI

Because of the large number of cases of OI that have been studied at the protein and molecular level, the range of mutations of type I collagen that are associated with skeletal disease is well developed although still incompletely understood. 384'385 In the following discussion, the

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Type II OI. Deletion within one ctl(I) collagen allele. In this figure both the normal and abnormal allele of the diploid cell are depicted while only one of the two normal o~2(I) alleles are shown. A deletion within one of the ctl(I) alleles (step A) leads to an initial transcript (step B) and mature mRNA (step D) that is shortened relative to the product of the normal allele. The mRNAs are translated into proof chains that initiate assembly in a C---~N (step F). Any molecule that incorporated the translated product of the shortened et 1(I) mRNA will disrupt the stability of the helix distal to the location of the deletion. Since the procollagen molecules will incorporate either one or two of the abnormal chain, three quarters of the resulting procollagen population will be structurally unsound (step G).

674 about 500 bases. 387 The region of DNA containing the deletion has now been isolated and sequenced by two laboratories. 388'389 The analysis indicates that three exons and associated intervening sequences have been deleted, resulting in an mRNA lacking 252 bases which, in turn, code for a procollagen chain deficient in 84 amino acids (Fig. 2 3 - 9 , steps D and E). Mutations that interrupt the helix weaken the stability of all the procollagen molecules containing at least one of the abnormal procollagen oL chains. 28~ The concept is referred to as the "suicide model" and proposes that three out of four procollagen molecules will have incorporated one or two of the abnormal etl(I) alleles and will therefore be structurally unsound 39~(Fig. 2 3 - 9 , step G). The important findings that have been derived from this case are: (1) the destabilized collagen helix is more susceptible to thermal denaturation, which renders the molecule susceptible to tissue proteases43'278'28~ (2) interruption of the helix decreases the rate of secretion of abnormal molecules from the cell leading to dilatation of the rough endoplasmic reticulum, 223 thus a reduced amount of collagen accumulates in the extracellular space, and that which is secreted is structurally unsound and susceptible to extracellular proteolytic digestion391; and (3) interruption of the helix leads to posttranslational overmodification of the lysine residues in the helical domain, N-terminal to the point where the helix is disrupted. 392 This important point has been used to great advantage by Bonadio and Byers 393 to map the apparent mutations that interrupt the helix in other cases of lethal OI. Although the physiological significance of these changes is uncertain, it may affect the quality of fibril formation or the generation of intermolecular crosslinks ~ Despite the dramatic findings derived from the above lethal case, most cases of lethal OI do not have an oL1chain doublet, indicating that the mutation is below the resolution of this type of analysis. However, most cases do show a delay of oL-chain migration, suggesting posttranslational overmodification of lysine residues. 395 Byers has mapped the location of the putative mutation in some of these cases by determining which cyanogen bromide peptide has delayed migration on acrylamide gels. This analysis suggests that mutations in the Cterminal or midhelical domains of the oLl(I) chain are common to the lethal form of OI. These findings were confirmed by Bateman et a l . 396 and clearly shown to be the result of excessive hydroxylation and glycosylation of hydroxylysine residues consequent to the delay in helix formation. The data suggested that a mutation below the size of biochemical detectability was disrupting the formation of the helix. This possibility has been well demonstrated by two cases in which a cysteine substitution was found


within type I collagen molecules. This mutation was detected because cysteine is not normally present in the helical domain of type I collagen, and when it is present within two chains of the same molecule, it causes the chain to run as a dimer under nonreducing conditions. Besides cysteine, the other possible substitutions of firstposition glycine include arginine, alanine, serine, aspartic and glutamic acid, tryptophan, and v a l i n e . 397-399 In the case described by Steinmann et a l . 278 the cysteine mutation was found in a patient with type II OI, while in the case of Nicholls et al., the child had a mild form of the disease. 4~176 Recent nucleotide sequencing of the cloned DNA obtained from the lethal case demonstrated that the cysteine was a substitution for a first-position glycine. 4~176 In the mild case, there was no evidence of thermal destabilization of the molecules containing the mutation, suggesting that the cysteine was probably in an X or Y position. 4~ Glycine substitution within the oL2(I) chain is found in association with perinatal lethal OI, although it is less c o m m o n . 4~176 Genetic compound has been suggested as another cause of OI, but the interpretation of these early molecular studies should be reexamined with the newer DNA diagnostic techniques. Other types of mutation have the same consequence of interrupting the integrity of the collagen helix. Errors of splicing that cause exon skipping can truncate a segment of helix, resulting in disease severity that is related to the domain that is deleted. 4~ Inclusion of a segment of nonhelical sequence due to an error of splicing 4~ or a partial gene deletion 41~has been reported. Finally, base substitutions that arise within the C-terminal propeptide and result in lethal OI indicate that chain assembly is initially determined by the interactions in this region of the m o l e c u l e . 411'412 In summary, the unifying abnormality in most forms of lethal OI appears to be the deletion of genetic material or a point mutation of a first-position glycine, which has a deleterious effect on the stability of the helix. As a rule, the severity of the disease may be related to the location of the mutation. The more C-terminal within the helix, the greater the length of unstable helix. 413 It should be anticipated that there will be a spectrum of clinical severity ranging from perinatal lethal to severe type III OI reflecting the locus of the mutation and the length of the destabilized collagen h e l i x . 414'415

B. S e v e r e ( T y p e III) O I Although this is the most severe of the nonlethal forms of OI, a clear biochemical basis for the disease has not yet emerged. In the best studied case (Fig. 2 3 10), the affected child failed to synthesize oL2(I) chains and instead produced a type I et collagen trimer. 354'416

CHAPTER 23


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FIGURE 23--10

Type III OI. Failure of e~2(I) production. Both e~2(I) alleles of the diploid cell contain the same mutation, which is a 4-bp deletion that places the remainder of the coding region out of phase. The process of transcription and mRNA processing is unaffected. Because the frameshift mutation changes the amino acids within the ot2(I) C-terminal propeptide that are required for chain assembly, this chain does not become incorporated into the procollagen molecule (step F). The result is an oL1(I) trimer that is not sufficient to replace the function of the normal heterotrimer. The unincorporated c~2(I) chains are degraded intracellularly. The parents of this infant are obligate heterozygotes for this mutation and do synthesize a mixture of normal and homotrimer molecules. They do not have OI but may have premature osteoporosis.

However, the cultured fibroblasts do contain oL2(I) m R N A and nascent procollagen e~2(I) chains can be demonstrated intracellularly. 417"418 An S1 nuclease analysis of the collagen m R N A from this case demonstrated a 4-bp deletion. 419 This type of deletion places the remainder of the m R N A codons out of the correct reading phase (frameshift mutation) so that all the amino acids distal to the mutation are nonsense. 42~ The location of this mutation is in the C-terminal propeptide that is essential for initial procollagen chain assembly. Since both alleles are affected (the child was the product of a consanguineous union), no oL2(I) chains are found within the procollagen molecule. The c~l(I) trimer is able to form a helix, although it is less than the heterotrimer, and it shows biochemical evidence of excessive posttranslational modification. 421 It is interesting to note that another case with deficient oL2(I)-chain synthesis has been described in a patient with EDS and no bone disease. 422 This finding points out that the type I collagen genes are not necessarily expressed in a similar manner in all tis-

sues and urges caution in extending results from cultured fibroblasts as necessarily reflective of events within bone. Except for the oim mouse, no other cases resembling this mutation have been observed, nor have deletions similar to those described under lethal OI been reported within either oL chain. However, a range of glycine substitutions and exon skips of the helical domain or base substitution within the C-terminal propeptide of either the oLl(I) or oL2(I) chain have now been amply documented. 423-42s While the impression that a gradient of severity can be correlated to the position of the mutation, many exceptions exist suggesting that there are specifc domains within the molecule that are more tolerant of disruption. 429 In certain cases the inheritance of severe nonlethal OI appears to be autosomal recessive within the black population in South Africa. 35 Molecular studies do not show linkage to type I collagen and no abnormalities of collagen production could be demonstrated. 43~ Another po-

676


tential case of OI not linked to type I collagen was reported in an Irish pedigree. 43] Thus, mutation in genes other than type I collagen may produce an OI phenotype, but they are most unusual. Instead, most cases of apparent recessive inheritance of nonlethal OI are examples of germinal mosaicism of o n e p a r e n t . 432-434 However, undisclosed genetic compounds could be present.

C. Mild, Deforming OI (Type IV) Patients with this type of OI have been shown to synthesize two populations of type I collagen. One contains proet2 chains that migrate normally in polyacrylamide gels, the other containing slow migrating chains. The slow chain contains a mutation within the oL2(I) chain located in one case toward the N-terminal domain of the helix (Fig. 2 3 - 1 1). In this patient, a deletion of approx-

imately 30 amino acids was detected by the presence of a doublet of the ct2 chain on acrylamide gel electrophoresis, 352 which proved to result from an e x o n skip. 435 In other cases, thermal denaturation studies in association with a change in the oL2(I) chain 436 on delayed migration of the et2(I) chain in a patient with known linkage by RFLP to the tx2(I) gene 437 have been observed. A glycine substitution in the mid- or C-terminal region of the helix has been found in association with type IV O1, 438 although there are many exceptions to the correlations between disease severity and location of the helix interrupting mutation.

D. Mild Nondeforming OI (Type I) The abnormality common to type I OI leads to a decrease in the production of type I collagen rather than a

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Type IV OI. Deletions within the helical domain of the ct2(I) gene. In this illustration, both alleles of the oL2(I) gene of the diploid cell are shown, while only one of the two normal oLl(I) alleles are depicted (step A). The two ct2(I) alleles give rise to two populations of mRNA that are either normal or shortened in length (steps C and D). Similarly, two populations of oL2(I) molecules are synthesized of different size that become incorporated into the procollagen molecule (step F). Those molecules containing the abnormal ct2(I) chains have reduced helical stability. Since only 50% of the total procollagen population contain the abnormal ct2(I) chain, the severity of OI with this type of mutation is less severe than when the mutation is within the oL1(I) chain.

CHAPTER 23

677


cated protein that is unstable and does not participate in helix formation, 443 a transcript that is subject to rapid d e g r a d a t i o n in either the n u c l e a r or c y t o p l a s m i c comp a r t m e n t of the cell, or a transcript that is retained within the nucleus. 444

structural m u t a t i o n of the protein (Fig. 2 3 - 1 2 ) . T h e mutation is e x p r e s s e d in fibroblasts in cell culture as an elevation in the ratio of type III to type I collagen. 439 U n d e r l y i n g the reduction in type I collagen synthesis in one of these variants is one silent allele for the oLl(I) chain that results in h a l f - n o r m a l oL1(I) m R N A . 44~ Since a stable collagen m o l e c u l e requires two oLl(I) chains, 442 the net p r o d u c t i o n of type I collagen is limited by the availability of the oLl(I) chains. 353 A h e t e r o g e n e o u s variety of m o l e c u l a r m e c h a n i s m s can inactivate the output o f a function p r o c o l l a g e n cx1 (I) chain. T h e m o s t c o m m o n appears to be a p r e m a t u r e stop c o d o n or 1- to 2-bp insertion/deletion that induces a stop c o d o n within the m a t u r e R N A transcript. T h e c o n s e q u e n c e is either a trun-

Alpha 1 (1) ........ A. ~ ......... Mutation within Intronl' ,L B.

c o n f i r m e d by m u t a t i o n a l analysis in specific patients. 45~ T h e recessive o i m / + m o u s e m o d e l of OI m a y be a m o d e l of this f o r m of OI. This subtype of m i l d OI m i g h t be e x p e c t e d to h a v e subtle clinical differences

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FIGURE 23--12 Type I OI. Functionally inactive c~l(I) allele. Both the normal and abnormal allele of the otl(I) gene present in the diploid cell are shown, while only one of the normal oL2(I) alleles is illustrated (step A). In this mutation, those mRNAs transcribed from the allele that contain a mutation that alters the steps of mRNA maturation do not readily enter the cytoplasm for translation (step E). This reduces the total amount of c~l(I) mRNA within the cytoplasm. Instead, the abnormal mRNA accumulates within the nucleus (steps C and D). Those abnormally processed mRNAs that reach the cytoplasm do not produce a normal otl(I) chain because the introns contain stop codons that prevent the completion of the chain (step E). The net effect is the synthesis of c~l(I) and oL2(I) procollagen chains in a 1:1 ratio instead of a 2:1 ratio. Since a stable type I collagen molecule requires two oLl(I) chains, the output of normal molecules is reduced by 50% (steps F and G). The ot2(I) chains present in excess are degraded intracellularly, since a molecule composed of two or three c~2(I) chains is unstable (steps F and G).

678


from those due to a null allele because the pathophysiological basis of the disease is distinctly different. This is one example where correlating molecular and clinical phenotype may have practical significance. Dominant inheritance is usually present in most families with type I OI, although the variability in severity may be such that mildly affected individuals may go undetected. Since the biochemical findings are quite distinctive, once the abnormality can be demonstrated in affected individuals, it can be used to identify mildly affected family members. Family studies indicate that the disease can result as a new mutation that is then transmitted as a dominant trait.

E. Syndromes with Shared Features An interesting family with a dominantly inherited syndrome of joint and skin laxity, blue sclerae, and increased fracture history was reported by Sippola et al. 43 The molecular basis for the disorder was a small deletion at the extreme N-terminal portion of the oL2(I) chain. The effect of this mutation is an alteration in the rate of conversion of procollagen to collagen. This type of change has been observed in EDS type VII due to a mutation that affects the N-terminal procollagen peptidase cleavage site of the oL1(I) or oL2(I) chain. 28~ Apparently, the deletion present in this family places the cleavage site out of register with other determinants for the procollagen peptidase. 454 The abnormality also destabilizes a small portion of the collagen helix, which may account for the bone fragility.

F. Heritable Osteoporosis Pedigrees demonstrating familial transmission or clustering of osteopenia have been identified. 455 Subjects with this phenotype also display scoliosis and mild joint laxity. From the experience gained studying the milder forms of OI, there is reason to believe that abnormalities of type I collagen (or other matrix components) may be present in certain of these families. 456 A number of determined attempts to discern such patients from unselected osteoporotic patients 52 or pedigrees with familial osteoporosis have been unrewarding. 53 Nevertheless, it can be expected that variable degrees of osteopenia, reflecting the underlying defect of collagen or other matrix protein, do account for the transition in phenotype between type I OI and heritable osteoporosis. The problem is how to distinguish this potential subgroup clinically from other forms of osteoporosis.

VIII. THERAPY The physician involved in the treatment of OI assumes responsibility not only for acute events (e.g., fractures) but also for chronic care including physical and psychological support for both the patient and the family. This must be a team effort: excellent orthopedic care in the absence of comparable physical therapy will prove inadequate. A general pediatrician or internist should also be part of the team to evaluate the growth and development of the child with OI and care for the medical complications that appear in adulthood. Among the latter are pulmonary infection and respiratory insufficiency in severely affected patients of any age, dental care for those with DI, the evaluation and treatment of heating loss, and detection of secondary diseases which may aggravate the skeletal disorder such as diabetes mellitus or thyroid or parathyroid disease. Health professionals who treat this disease must appreciate the psychological needs of parents and the patient who is facing yet another crisis precipitated by a major fracture. 457 Families frequently relate stories of medical personnel who are insensitive to their pain or disability, or who do not appreciate the specific needs required by an individual with brittle bones. Parents are willing to teach the health team how they have learned to deal with these problems, but often find that the caregiver does not heed this advice. It is particularly important for the health professionals to listen to and learn from their patients with OI.

A. Medical Therapy A variety of hormones and mineral supplements considered effective in strengthening bone in postmenopausal osteoporosis and Paget's disease of bone have been administered to patients with OI. These have been summarized by Albright 458 and Gertner and R o o t , 459 who noted that 70% of the articles on medical treatment of OI claimed positive results for 20 different agents. It is not surprising that each ultimately proved ineffective, since none attack the primary defect in O I - - t h a t is, a failure to produce normal type I collagen. Modification of the collagen gene in vivo will be the ultimate curative therapy of OI. At this time, there is no effective hormonal, mineral, or vitamin therapy for any type of osteogenesis imperfecta. From the pathophysiology of OI as revealed by the histomorphological and molecular studies described above, it is now evident that the rationale for the previous therapeutic trials was not well founded. Salmon calcitonin was intended to suppress bone resorption and thereby favor bone f o r m a t i o n . 46~ Controlled studies of

CHAPTER 23 Osteogenesis Imperfecta calcitonin therapy have failed to confirm a significant effect on fracture rate or bone m o r p h o l o g y . 461'462 While it is true that certain forms of OI do have evidence of increased bone turnover, it is likely that defective bone collagen is the stimulus for this process. Inhibiting increased bone turnover would only lead to accumulation of more abnormal bone collagen and a compensatory fall in bone formation. However, a recent report of bisphosphonates in OI children suggest there is a significant reduction of bone pain and increase in ambulation. 463 If this observation is verified by controlled trials showing a long-term reduction in fracture frequency, then the role of inhibitors of resorption, and even the underlying pathophysiological concepts of OI bone, will require a major reevaluation. Several agents have been administered in an effort to increase bone formation. Clinical evidence suggests that anabolic steroids and estrogen therapy primarily decrease bone resorption; an effect on bone formation is probably minimal. 464 Ascorbic acid is a cofactor for prolyl hydroxylase, essential for the formation of stable collagen polymer. It promotes high collagen production by increasing gene transcription and stabilizing collagen m R N A , 465 and maintaining the osteoblast in a differentiated s t a t e . 466 However, there is no evidence that there is ascorbic acid resistance in OI or that supplemental ascorbic acid can increase collagen synthesis. 467 Fluoride therapy appears to increase bone mass in osteoporosis by stimulating proliferation of new osteoblasts. 468 Since a hypercellular bone matrix is frequently found in OI, it is unlikely that fluoride will be of value in most cases of OI. Indeed, two trials indicate that it is not effective in O I . 177'469 Growth hormone and insulin-like growth factor type 1 (IGF-1) are potent stimulators of bone formation and resorption in man 47~ and in rodent models. 472 A number of clinical trials of human growth hormone (hGH) are currently in progress. 179'182 While an anabolic and growth response characteristic of all individuals during the first treatment year was observed, there are no longterm data reported on efficacy or fracture frequency. Since the individuals treated had forms of OI resulting from the production of a mutant collagen molecule, the expectation would be that a fundamentally weak skeleton would be expected to carry a larger body mass. If any patient population might benefit from anabolic bone therapy, it would be a patient with a null COL1A1 gene within the category of type I OI. The experience with hGH or IGF-1 in osteoporotic humans (presumably not secondary to an underlying OI mutation) is still mixed and has not gained wide acceptance. The Mov-13 heterozygous mouse is an excellent example to test the hypothesis of GH utility in type I O1. 473,474 A particularly attractive strategy has been developed by King in which

679 the GH transgene driven by a globin promoter is expressed in erythroblasts. 475 This transgenic mouse strain has large bones and improved mechanical properties. However, when this transgene was bred into the oim/oin mouse, no improvement in mechanical properties was observed, as would be expected because the proportion of mutant c~1(I) trimeric molecules remains unchanged. 476 Unexpectedly, the mechanical properties of the oim/+ mouse did improve up to the level of the + / + mouse even though the oim/+ mouse is phenotypically normal. Clearly, the role of these growth factors, regardless of the way they are presented to bone, needs further evaluation of their effect on bone biology and mechanics before they receive widespread use in humans. Other agents have had an even less credible basis for their use. Calcium and vitamin D supplementation, 477 while not harmful when used in moderation, are inappropriate, since abnormalities in calcitropic hormones or calcium homeostasis have not been demonstrated. Magnesium supplements were intended to correct a postulated, but never confirmed, defect in pyrophosphate metabolism. 478 The flavinoids, ( + ) catechins, were intended to revert collagen and glycosaminoglycan synthesis towards " n o r m a l . " 479 Since these studies have not defined a specific abnormality, their use should be suspect. Flavinoids will decrease collagen production in vitro. 48~ Any future medical therapies must have a solid theoretical basis and be evaluated on a biochemically homogeneous group of patients. Furthermore, no longer can a change in fracture rate be used as the sole criterion of efficacy. Instead, accurate measurements of bone mineral content using dual photon absorptiometry or computer assisted tomography will be necessary to provide periodic quantitative and nonbiased assessments during therapy. Once positive changes are revealed by these techniques, then reliance on fracture rate or change in bone morphology will be possible.

B. S u r g i c a l T h e r a p y The primary goal in the surgical therapy of OI should be directed towards reducing deformity and promoting normal function. 482 This means that fractures must be carefully managed to diminish the possibility of deformity while limiting the period of immobilization. Aggressive surgical therapy should be considered so as to maintain limbs in as near a functional condition as possible. Muscle strength should be maintained between episodes of fracture. This requires the anticipation of deformity following fractures or with weight-beating, and the consideration of bone-straightening procedures even in severe, wheelchair-bound patients. Usually, realignment of a deformed limb requires the insertion of either

680


a pin or rod once the deformity has been corrected by manual (osteoclasis) or surgical (osteotomy) techniques. Proper timing of the rodding procedure is important; early, rather than late correction of deformity is advisable. This may mean inserting rods by age 3 to 5, depending on the child's mobility and extent of deformity. 483 Internal fixation of the femur using an extensible intramedullary rod with separate bone fragments being threaded onto the rod after the femur has been realigned is utilized to reduce the need for re-rodding as the child grows. 484 Percutaneous rodding allowing more frequent changes during growth has also been used. 485 Complications of rodding procedures include restriction of joint motion (although most patients gain near full range of motion at large joints), migration of the ends of the rod requiting reoperation, bending of the rod, nonunion of the fractured fragments, and rarely, development of hyperplastic

c a l l u s . 486

Moorefield and Miller 1~176 have summarized the longrange results of corrective limb surgery in 31 OI adults studied an average of 19 years postoperatively. Preoperative complications of fracture included limb-length discrepancy, exuberant callus, and common peroneal and radial nerve palsy. Eighteen patients were nonambulatory prior to surgery, and 13 used braces or crutches. At follow-up, only 8 patients remained nonambulatory and wheelchair-bound, 18 were able to walk with braces or crutches, and 5 were independent. Of the 28 patients who had undergone a total of 174 operations (6.2 per patient), follow-up x-rays and clinical examination revealed improvement of the deformity in 17, and no improvement in 11. The overall complication rate was 18%. Once rodded, many children are able to ambulate, sometimes walking for the first time, albeit using crutches or a brace. Similar success with extensible rodding procedures has been reported. 487 The positive impact on the child's psychosocial development may easily justify the surgical trauma and the risk of additional surgery. Upper limb surgery also involves insertion of a pin or rod (Sofield rod, Rush pins) following multiple osteotomies or external fracture and realignment of the limb. Rodding of the radius or ulna is more difficult than with the humerus, but is required less frequently. 488 Limited experience with hip and knee joint replacement has been reported. 489 Leg straightening procedures based on the Ilizarov method of lengthening has been utilized in an adult with mild OI with s o m e s u c c e s s . 49~ The surgical management of deformities of the spine has been reviewed by Benson and Newman. 1~ Because mechanical support (Milwaukee brace, plaster bracing) is not generally useful in OI patients, these authors recommend the use of posterior correction, with fusion or the use of the Harrington instrument inserted at an early age if the scoliosis exceeds 50 degrees. However, the

complication rate is high. Young-Hing and MacEwen have reported that of 29 patients with posterior spinal fusion without bracing and 20 with bracing, there were 5 pseudoarthroses, 2 fractured rods, 1 case of rod protrusion through the skin, and 7 cases where hooks were displaced. 491 The general impression is that severe scoliosis resulting in pulmonary insufficiency cannot be reversed by surgical means.

C. Orthotic Therapy In addition to the primary bone abnormality in OI, immobilization and the absence of weight-bearing further impede an improvement in skeletal mass and muscle strength in these patients. Furthermore, OI children have lax ligaments, which contribute to the instability of large joints. During cycles of fracture and repair, time spent on weight-beating and exercise is lost. The prolonged use of body casts and a reluctance on the part of the family or physician to urge physical therapy cost dearly in the effort to maintain skeletal mass. For example, the stimulus for new bone formation provided by pubertal hormone secretion may be negated while an adolescent spends weeks or months recovering from a major fracture. Individualized orthotic care and rehabilitative therapy are key to gaining confidence and promoting independent activity once fractures have healed. As stressed by Binder, 492 positioning of the infant with OI is critical to maintaining the strength of respiratory, spinal, and neck muscles. Swimming in a tub or heated pool is thought to be one of the most useful procedures, and this can be started as early as age 6 months in many children. A variety of exercises can be employed to assist muscle strengthening prior to ambulation. Children should be encouraged to move in any manner and by any means as early as possible so that weight-beating may strengthen limb and trunk m u s c l e s . 493 However, ambulation is usually delayed depending on the extent of deformity and susceptibility to fracture. B leck has proposed the principle of compression of the incompressible fluid muscle as one way of increasing the stress o n b o n e . 494 Plastic orthoses that conform to limb contour have been designed to promote more effective weight-beating. The principle is to brace the child when ambulation is first anticipated. Binder et a l . 492 have designed ultralight polypropylene braces, extending to the pelvis and fitted for ischial weight-beating (Fig. 23-13). Initially cylindrical, knee joints are added after a year or so. The child's adaptability to these braces is quite remarkable. Trials indicate that children will readily adapt to mechanical support and will become fully active in braces: the positive psychological effect on both the child and family is remarkable. During a limited

CHAPTER 23 OsteogenesisImperfecta

681 healthy peers. Continuing efforts to maximize physical and intellectual development are required to ensure the achievement of independent living in spite of a significant physical handicap. 5~176176 There are a number of voluntary organizations that are concerned with many of these issues as well as promoting research of the diseases, including the following: Osteogenesis Imperfecta Foundation 804 W. Diamond Avenue Gaithersburg, MD 20878 Tel: (301) 947-0083 and Children's Brittle Bone Foundation P.O. Box 27 Highland Park, IL 60035 Tel: (847) 433-4981 The physician who cares for an OI individual should make contact with the local OI group to learn of the resources available for his patient.

FIGURE 23--13 This 3-year-old child is standing in lightweight polypropylene braces, using a walker for support. Creative application of orthotic principles is essential to promote early ambulation, peer acceptance, normal schooling, and normal social development in the child with severe OI.

study, no exercise-related fractures occurred in four children while they were in braces. 495 Weight-bearing walkers and A-flame orthoses have been designed to permit stress on the lower limbs without full weight-bearing. Children confined to a wheelchair require special support to minimize the risk of scoliosis. Additional work on the subject using controlled studies will be required before the effect of early weight-beating on long bones or the spine in OI can be adequately a s s e s s e d . 496'497

IX. FUTURE THERAPEUTIC

DIAGNOSTIC DIRECTIONS

AND

Because OI has such a severe and long-term impact on the OI patient and family, it is important that the clinician be aware of emerging diagnostic and therapeutic modalities. It is hard for the family to face their daily disappointments with OI if their physician is not enthusiastic about future developments that may affect the lives of their OI patients. The insights gained into the molecular basis of OI that have developed within the past 5 years are astounding. Recent advances in molecular technologies lead many investigators to feel that the tools to define any type of gene mutation are now available. When these methods are applied to the problem of OI, the following developments can be anticipated.

D. P s y c h o l o g i c a l S u p p o r t s A. D i a g n o s i s The stress of repeated hospitalizations and the need to adapt to prolonged immobility in the hospital or at home places an incredible strain on family life. Little attention has been devoted by the medical community toward an understanding of why some families succeed and others fail in this difficult t a s k . 498'499 Unlike many other chronic illnesses, these families must rear a child with an exceptional intellectual potential but whose disease will always limit their ability to compete with their

Commercial sites for obtaining a molecular diagnosis for OI are now available. 5~176 This approach will permit identification of subjects carrying (or free of) a specific mutation in the collagen gene that is of particular value to a family in which one parent is a somatic mosaic. Specific mutation identification may be predictive of the functional nature of the collagen abnormality and its clinical expression, which should promote development

682


of the specific therapy aimed at the pathophysiological consequences of the mutation.

B. Animal Models for the Evaluation

of Therapy Until recently, every new therapeutic agent was evaluated in children, without much supportive animal data indicative that a positive outcome was possible. This approach is no longer acceptable, as there are many murine models now available to demonstrate potential efficacy. It is incumbent on the medical profession to demand animal data prior to human studies, because the young, impressionable, and desperate parents of an infant with severe OI are not in a position to be "informed consumers"; their infant, even less so. The potential risk and discomfort experienced by children treated with calcitonin and fluoride in the past pale against the use of growth factors, bisphosphonates, and bone marrow transplantation being considered in the future. Animal models have the added advantage that the effect of prolonged treatment or long-term consequences can be assessed in a relatively short period of time. An inherent danger of all medical trials has been apparent positive initial outcomes with little investigation of the long-term consequences. Fracture frequency in children is a notoriously bad indicator of bone strength, while this measurement can be made directly in a mouse. Finally, the murine models provide a stable genetic background to evaluate the effect of an intervention with the identical mutation in a large number of experimental subjects.

C. Somatic Gene Therapy Gene therapy for OI presents a radically different problem of therapy than most of the heritable disorders that are currently under investigation. These strategies are directed at diseases for which the underlying defect is a deficiency in the enzyme activity, receptor, or growth factor. OI more closely resembles the problems of gene therapy for the acquired immunodeficiency syndrome (AIDS), in which it is the presence of the abnormal gene product (the AIDS virus or mutant collagen molecules) that is causing the disease. In either case the essential problem is how to selectively remove the gene product while preserving the remaining cellular function. For OI it is even more complex because ideally only the mutant but not the normal gene product needs to be altered, yet the two products may differ by only a single base or amino acid. The clinical observation that suggests somatic gene therapy may have a role in OI comes from the obser-

vation of parents who are somatic mosaics for OI. Although they may have a degree of OI mosaicism reaching as high as 40%, rarely do they have evidence of bone disease, although other minor connective tissue features have been described. This suggests that the presence of the normal bone cells somehow inactivate the deleterious effect of the OI cells. Direct analysis of bone from the individuals with somatic mosaicism has never been performed, so the mechanism for the protective effect is unknown. It is possible that the OI bone cells have been completely replaced by normal cells due to the inefficiency of cell proliferation and production. Furthermore, the matrix synthetic capacity of the normal cells is so much greater that even if OI cells are present within bone, they may contribute little to the total matrix accumulation. A number of reports now suggest that bone marrow transplantation may achieve the desired mosaicism that might improve bone strength. Currently, very little is known about the ability of osteoprogenitor cells to be transplanted by a systemic route, even though this route is routinely used for hematopoietic engraftment. Studies of mice or humans who have had standard bone marrow transplantation suggest that marrow stromal and bone engraftment are controversial. 5~176 A number of research groups are exploring various ways in which the bone cell progenitors can be isolated, expanded, and then reinfused either systemically or directly within the bone marrow to achieve engraftment. 5~ This author feels that these very fundamental problems need to be investigated thoroughly in mice or other experimental animals before being applied to affected individuals. The second problem to overcome is the rejection of the transplant. Chronic use of immunosuppressives could be as damaging to bone as the underlying disease. The ideal strategy envisions harvesting stromal cell progenitors from the affected individual and genetically engineering them to reduce the production of the mutant gene product. It may be possible to specifically inactivate the mutant collagen gene with ribozymes that can discriminate a target that differs by a single base. 5~ This is a major advantage over standard antisense approaches, which inactivate transcripts from both collagen alleles, unless there is a major hybridization difference between the two transcripts. 51~ Trans-RNA splicing is another approach that requires evaluation. 512 While it does not discriminate at the nucleotide level, it has the advantage that an abnormal transcript is converted to a normal transcript. Finally, a technique to correct a mutation within genomic DNA of an intact cell population at an unexpected high frequency utilizing a chimeric RNA-DNA oligonucleotide has been reported. 513 If this approach proves to work in other laboratories, then the ideal tool for genetic engineering of a genomic mutation will be in hand.

CHAPTER 23


683

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DAVID W. ROWE AND JAY R. SHAPIRO 466. Franceschi RT, Iyer BS, Cui Y: Effects of ascorbic acid on collagen matrix formation and osteoblast differentiation in murine MC3T3-E1 cells. J Bone Miner Res 9:843-854, 1994. 467. Kurz D, Eyring EJ: Effects of vitamin C on osteogenesis imperfecta. Pediatrics 54:56-61, 1974. 468. Farley JR, Wegedal JE, Baylink DJ: Fluoride directly stimulates proliferation and alkaline phosphatase activity of bone-forming cells. Science 222:330-332, 1983. 469. Shoenfeld Y, Fried A, Ehrenfeld NE: Osteogenesis imperfecta. Review of the literature and presentation of 29 cases. Am J Dis Child 129:679-687, 1975. 470. Johansson AG, Lindh E, Blum WF, et al: Effects of growth hormone and insulin-like growth factor I in men with idiopathic osteoporosis. J Clin Endocrinol Metab 81:44-48, 1996. 471. Brixen K, Kassem M, Nielsen HK, et al: Short-term treatment with growth hormone stimulates osteoblastic and osteoclastic activity in osteopenic postmenopausal women m a dose response study. J Bone Miner Res 10:1865-1874, 1995. 472. Andreassen TT, Jorgensen PH, Flyvbjerg A, et al: Growth hormone stimulates bone formation and strength of cortical bone in aged rats. J Bone Miner Res 10:1057-1067, 1995. 473. Bonadio JF, Stewart TA, Baker AR, Goldstein SA: Local expression of human growth hormone in bone results in impaired mechanical integrity in the skeletal tissue of transgenic mice. J Orthop Res 14:598-604, 1996. 474. Jepsen KJ, Goldstein SA, Kuhn JL, et al: Type I collagen mutation compromises the post-yield behavior of Mov 13 long bone. J Orthop Res 14:493-499, 1996. 475. Saban J, Schneider GB, Bolt D, King D: Erythroid-specific expression of human growth hormone affects bone morphology in transgenic mice. Bone 18:47-52, 1996. 476. King D, Saban J, Flay N, et al: Localized production of growth hormone improves bone quality in a mouse model of osteogenesis imperfecta. J Bone Miner Res 11:$78 (abstract), 1996. 477. Gertner J, Baron R, Vigery A, Lasng R: Cyclical therapy of osteogenesis imperfecta with fluroide and 25 hydroxyvitamin D. Calcif Tissue Int 31:62 (abstract), 1980. 478. Granada JL, Falvo KA, Bullough P: Pyrophosphate levels and magnesium oxide therapy in osteogenesis imperfecta. Clin Orthop 126:228-231, 1977. 479. Cetta G, Balduini C, Valli M, et al: Influence of a flavinoid on some abnormalities of connective tissues in osteogenesis imperfecta. Presp Inherit Metab Dis 3:181-183, 1979. 480. Becker Y, Stevely W, Hamaburger Y, et al: Effect of flavonoid (+) cyanidanol-3 on procollagen biosynthesis and transport in normal and ataxia telangiectasis cultured skin fibroblasts. Connect Tissue Res 8:77-84, 1981. 481. Blumenkrantz N, Asboe-Hansen G: Effect of (+) catechin on connective tissue. Scand J Rheumatol 7:55-60, 1978. 482. Cole WG: Early surgical management of severe forms of osteogenesis imperfecta. Am J Med Genet 45:270-274, 1993. 483. Engelbert RH, Helders PJ, Keessen W, et al: Intramedullary rodding in type III osteogenesis imperfecta. Effects on neuromotor development in 10 children. Acta Orthop Scand 66:361-364, 1995. 484. Stockley I, Bell MJ, Sharrard WJ: The role of expanding intramedullary rods in osteogenesis imperfecta. J Bone Joint Surg Br 71:422-427, 1989. 485. McHale KA, Tenuta JJ, Tosi LL, McKay DW: Percutaneous intramedullary fixation of long bone deformity in severe osteogenesis imperfecta. Clin Orthop 305:242-248, 1994. 486. Porat S, Heller E, Seidman DS, Meyer S: Functional results of operation in osteogenesis imperfecta: Elongating and nonelongating rods. J Pediatr Orthop 11:200- 203, 1991.

CHAPTER 23

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487. Nicholas RW, James P: Telescoping intramedullary stabilization of the lower extremities for severe osteogenesis imperfecta. J Pediatr Orthop 10:219- 223, 1990. 488. Root L: Upper limb surgery in osteogenesis imperfecta. Clin Orthop 159:141-146, 1981. 489. Papagelopoulos PJ, Morrey BF: Hip and knee replacement in osteogenesis imperfecta. J Bone Joint Surg Am 75:572-580, 1993. 490. Ring D, Jupiter JB, Labropoulos PK, et al: Treatment of deformity of the lower limb in adults who have osteogenesis imperfecta. J Bone Joint Surg Am 78:220-225, 1996. 491. Yong-Hing K, MacEwen GD: Scoliosis associated with osteogenesis imperfecta: Results of treatment. J Bone Joint Surg 64B: 36-43, 1982. 492. Binder H, Hawks L, Graybill G, et al: Osteogenesis imperfecta: Rehabilitation approach with infants and young children. Arch Phys Med Rehabil 65:537-541, 1984. 493. Daly K, Wisbeach A, Sanpera I Jr, Fixsen JA: The prognosis for walking in osteogenesis imperfecta. J Bone Joint Surg Br 78:477-480, 1996. 494. Bleck EE: Nonoperative treatment of osteogenesis imperfecta: Orthotic and mobility management. Clin Orthop 159:111 - 122, 1981. 495. Gerber LH, Binder H, Weintrob J, et al: Rehabilitation of children and infants with osteogenesis imperfecta. A program for ambulation. Clin Orthop 251:254-262, 1990. 496. Binder H, Conway A, Gerber H: Rehabilitation approaches to children with osteogenesis imperfecta: A ten-year experience. Arch Phys Med Rehabil 74:386-390, 1993. 497. Binder H, Conway A, Hason S, et al: Comprehensive rehabilitation of the child with osteogenesis imperfecta. Am J Med Genet 45:265-269, 1993. 498. Brodin J: Children and adolescents with brittle bones--psychosocial aspects. Child Care Health Dev 19:341 - 347, 1993. 499. Cole DE: Psychosocial aspects of osteogenesis imperfecta: An update. Am J Med Genet 45:207-211, 1993. 500. Dubowski FM: Children with osteogenesis imperfecta. Nurs Clin North Am 11:709-715, 1976. 501. Werner P, Metz L, Dubowski F: Nursing care of an osteogenesis imperfecta infant and child. Clin Orthop 159:108-110, 1981. 502. Byers PH: Analysis is protein based with subsequent molecular studies. Contact Melanie Pepin at the University of Washington

503.

504.

505.

506.

507.

508.

509.

510.

511.

512.

513.

at 206-543-5464. Instructions for sample submission are provided at the web site: http://www.pathology.washington.edu/ byers.html. Prockop DJ: Analysis is genomic DNA based. Contact Maureen Kinnarney at Center for Gene Therapy, Alleghany University of Health Science at 215-762-7234. Instructions for sample submission are provided at the web site: http://healthlinks. washington.edu/helix/. Friedenstein AJ, Ivanov-Smolenski AA, Chajlakyan RK: Origin of bone marrow stromal mechanocytes in radiochimeras and heterotopic transplants. Exp Hematol 6:440-444, 1978. Hollings PE, Fitzgerald PH, Heaton DE, Beard MJ: Host origin of in vitro bone marrow fibroblasts after bone marrow transplantation in man. Int J Cell Cloning 2:348-351, 1984. Keating A, Singer JW, Killen PD, et al: Donor origin of the in vitro haemopoietic microenvironment after marrow transplantation in man. Nature 51:217- 305, 1982. Piersma AH, Ploemacher RE, Brockbank KM: Transplantation of bone marrow fibroblastoid stromal cells in mice via the intravenous route. Br J Haematol 54:285-292, 1983. Pereira RF, Halford KW, O'Hara MD, et al: Cultured adherent cells from marrow can serve as long-lasting precursor cells for bone, cartilage, and lung in irradiated mice. Proc Natl Acad Sci USA 92:4857-4861, 1995. Grassi G, Marini JC: Ribozymes - - structure, function and potential therapy for dominant genetic disorders. Ann Med 28: 499-510, 1996. Khillan JS, Li S-W, Prockop DJ: Partial rescue of a lethal phenotype of fragile bones in transgenic mice with a chimeric antisense gene directed against a mutated collagen gene. Proc Natl Acad Sci USA 91:6298-6302, 1994. Wang Q, Marini JC: Antisense oligodeoxynucleotides selectively suppress expression of the mutant alpha 2(1) collagen allele in type IV osteogenesis imperfecta fibroblasts. A molecular approach to therapeutics of dominant negative disorders. J Clin Invest 97:448-454, 1996. Mikheeva S, Jarrell KA: Use of engineered ribozymes to catalyze chimeric gene assembly. Proc Natl Acad Sci USA 93: 7486-7490, 1996. Colestrauss A, Yoon KG, Xiang YF, et al: Correction of the mutation responsible for sickle cell anemia by an RNA-DNA oligonucleotide. Science 273:1386-1389, 1996.


~ H A P T E R 2z

Skeletal Disorders Characterized By Osteosclerosis Or Hyperostosis MICHAEL P. WHYTE

Divisions of Bone and Mineral Diseases, Washington University School of Medicine, St. Louis, Missouri 63110 and Metabolic Research Unit, Shriners Hospital for Children, St. Louis, Missouri 63131

I. II. III. IV. V. VI.

Introduction Osteopetrosis Carbonic Anhydrase II Deficiency Pycnodysostosis Osteomesopyknosis Progressive Diaphyseal Dysplasia (Camurati-Engelmann Disease) VII. Endosteal Hyperostosis VIII. Osteopoikilosis IX. Osteopathia Striata

X. XI. XII. XIII. XIV. XV. XVI. XVII. XVIII.

provide insight into mineral metabolism and skeletal biology. Hereditary, neoplastic, hematological, infectious, endocrinological, metabolic, and dietary disturbances can be at fault. 2'7 Cumulatively, the number of patients is significant. 1'2 This chapter reviews the principal dysplastic disorders that cause osteosclerosis and/or hyperostosis and dis-

I. I N T R O D U C T I O N Though most are rare, there are many disorders of bone formation or skeletal homeostasis that cause either focal or generalized increases in skeletal mass (Tables 2 4 - 1 and 2 4 - 2 ) . 1-8 Some are mere radiological curiosities; others are difficult clinical problems. Some METABOLIC BONE DISEASE

Melorheostosis Mixed Sclerosing Bone Dystrophy Fibrodysplasia Ossificans Progressiva Axial Osteomalacia Fibrogenesis Imperfecta Ossium Fluorosis Pachydermoperiostosis Hepatitis C-Associated Osteosclerosis Other Disorders References

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Copyright 9 1998by AcademicPress. All rights of reproductionin any formreserved.

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MICHAEL P. WHYTE

TABLE 24--1 Disorders that Cause Generalized Osteosclerosis a Dysplasias Craniodiaphyseal dysplasia Craniometaphyseal dysplasia Dysosteosclerosis Endosteal hyperostosis Van Buchem's disease Sclerosteosis Frontometaphyseal dysplasia Infantile cortical hyperostosis (Caffey's disease) Melorheostosis Metaphyseal dysplasia (Pyle's disease) Mixed sclerosing bone dystrophy Oculodento-osseous dysplasia Osteodysplasia of Melnick and Needles Osteoectasia with hyperphosphatasia (hyperostosis corticalis) Osteopathia striata Osteopetrosis Osteopoikilosis Progressive diaphyseal dysplasia (Engelmann's disease) Pycnodysostosis Metabolic Carbonic anhydrase II deficiency Fluorosis Heavy metal poisoning Hypervitaminosis A, D Hyper-, hypo-, and pseudohypoparathyroidism Hypophosphatemic osteomalacia Milk-alkali syndrome Renal osteodystrophy Other Axial osteomalacia Fibrogenesis imperfecta ossium Ionizing radiation Lymphoma Mastocytosis Multiple myeloma Myelofibrosis Osteomyelitis Osteonecrosis Paget's disease Sarcoidosis Skeletal metastases Tuberous sclerosis aFrom Avioli LV, Krane SM (eds): Metabolic Bone Disease and Clinically Related Disorders, 2nd ed. Philadelphia, WB Saunders Co, 1990.

cusses briefly some of the secondary causes of increased skeletal mass. Osteosclerosis refers to thickening of trabecular (spongy) bone; hyperostosis refers to widening of cortical (compact) bone from apposition of osseous tissue at periosteal and/or endosteal surfaces)'* *Throughout the text, heritable disorders are referred to by the classification number(s) given by McKusick. 1 Recognition of the radiographic features of these conditions is essential for making a correct diagnosis; accordingly, I refer the reader to several excellent references that also illustrate the x-ray findings) -8

TABLE 24--2

Types of Osteosclerosis a

Cortical and Trabecular Bone (Both) Carbonic anhydrase II deficiency Dysosteosclerosis Osteopetrosis Pycnodysostosis Cortical Bone (Predominantly) Autosomal dominant osteosclerosis Diffuse idiopathic skeletal hyperostosis Endosteal hyperostosis (van Buchem's disease and sclerosteosis) Hypertrophic osteoarthropathy Pachydermoperiostosis Progressive diaphyseal dysplasia (Engelmann's disease) Trabecular Bone (Predominantly) Dysplastic Osteomesopyknosis Hematological Mastocytosis, myelofibrosis, polycythemia vera, sickle cell disease Metabolic Fluorosis, hyperparathyroidism, renal osteodystrophy, X-linked hypophosphatemic rickets, vitamin D toxicity Neoplastic Disorders Metastatic disease Myeloma, lymphoma, leukemia aFrom Avioli LV, Krane SM (eds): Metabolic Bone Disease and Clinically Related Disorders, 2nd ed. Philadelphia, WB Saunders Co, 1990.

II. OSTEOPETROSIS Osteopetrosis (marble bone disease) was first described by Albers-Sch6nberg in 19049; more than 300 cases have been reported. As discussed below, we now understand that "osteopetrosis" is a generic term used for a group of disorders with a similar pathogenesis. ~~ Two principal clinical forms are generally recognized; an autosomal dominant benign type (McKusick 166600) with few or no symptoms, 12 and an autosomal recessive malignant type (McKusick 259700) that is fatal during infancy or early childhood if untreated. ~3 Nevertheless, there appear to be at least nine distinct forms of osteopetrosis in humans (Table 24-3). 1~ An especially rare "intermediate" form, inherited as an autosomal recessive trait (McKusick 259710), manifests during childhood with some of the clinical problems associated with the malignant type, but has an uncertain impact on life expectancy. 14'15Carbonic anhydrase II (CA II) isoenzyme deficiency is an autosomal recessive condition (McKusick 259730) that was formerly called the syndrome of osteopetrosis/renal tubular acidosis/cerebral calcification. 16 Because the etiology of CA II deficiency is now known, the following section describes this entity. Malignant osteopetrosis with neuronal storage disease has been delineated in several infants. 17 Still rarer "lethal,"

CHAPTER 24 Skeletal Disorders Characterized By Osteosclerosis or Hyperostosis TABLE 24--3

Types of Osteopetrosis in Humans

Type

Inheritancea

Benign (adult) Type I Type II Malignant Carbonic anhydrase II deficiency Intermediate Lethal Malignant with neuronal storage disease Transient infantile Postinfectious

AD AR AR AR AR AR 9 m

aFrom Whyte MP: Osteopetrosis and the heritable forms of rickets. Royce PM, Steinmann B (eds): Connective Tissue and its Heritable Disorders. New York, Wiley-Liss, Inc, 1993, 563-589. AD: autosomal dominant; AR, autosomal recessive.

In

"postinfectious," and "transient" types of osteopetrosis have been reported. 1~ Although it is apparent that several genetic defects cause osteopetrosis in humans, the pathogenesis of all true forms is absent or greatly diminished osteoclast function. TM Consequently, there is accumulation of unresorbed skeletal tissue--including the primary spongiosa deposited at growth plates during endochondral bone formation. 1s-21 Though a generic term, "osteopetrosis" should no longer be used merely to refer to a generalized increase in skeletal mass. 10,11

A. Clinical Presentations Malignant forms of osteopetrosis cause symptoms beginning in infancy. 11'13 Nasal "stuffiness" is an early sign that has been attributed to malformation of the paranasal and mastoid sinuses. Subsequently, there is failure to thrive, and palsies of the optic, oculomotor, and facial nerves can result from compression by narrowed cranial foramina. Dentition is delayed and bones are fragile and often fracture. Short stature, a large head, frontal bossing, nystagmus, "adenoid appearance," hepatosplenomegaly, and genu valgum may be present. Some patients develop hydrocephalus or sleep apnea. 22 Retinal degeneration sometimes contributes to loss of vision. 23 Recurrent infection with spontaneous bruising and bleeding can occur from myelophthisis. Hypersplenism and hemolysis may exacerbate the anemia. Without successful treatment, death occurs during the first decade of life from pneumonia, sepsis, hemorrhage, or severe anemia. 13 Intermediate osteopetrosis causes short stature and there may be macrocephaly, cranial nerve deficits, ankylosed teeth (which predisposes to osteomyelitis of the

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jaw), recurrent fractures, and a mild or occasionally moderately severe anemia. 14'15 Benign osteopetrosis can manifest as a developmental disorder. Most affected individuals are asymptomatic. 12 The long bones are brittle, and pathological fractures may occur. Deafness, facial palsy, osteomyelitis of the jaw, visual or auditory impairment, psychomotor delay, carpal tunnel syndrome, 24 and osteoarthritis have also been reported. 12 Studies from Denmark propose that there are two types of benign osteopetrosis. 25'26However, the histological hallmark (unresorbed primary spongiosa) 1~ and presence of a biochemical marker in serum for osteoclast failure (creatine kinase, brain isoenzyme) 2v manifests only in the more common type II form (see below). 25'26

B. Laboratory Findings Serum acid phosphatase activity, apparently derived from defective osteoclasts, is often elevated. Recently, presence in serum of the brain isoenzyme of creatine kinase (BB-CK) has been found to distinguish the osteopetroses among disorders that increase skeletal m a s s .27 Standard biochemical parameters of mineral homeostasis are usually unremarkable. In malignant forms of osetopetrosis, however, serum calcium levels can be low with values reflecting the dietary calcium intake. 2s Furthermore, secondary hyperparathyroidism occurs with increased serum levels of calcitriol (1,25-dihydroxyvitamin D), 29 and hypocalcemia may lead to rachitic disease. There is a leukoerythroblastic anemia.

C. Radiological Features Generalized osteosclerosis with thick cortical bone is the principal radiological feature of osteopetrosis. 2-8 The apparent hyperostosis occurs because endosteal bone resorption fails to create a marrow cavity. Abnormal skeletal modeling and remodeling together cause the symmetrical increase in bone mass (Fig. 24-1). However, the skeleton may be uniformly dense, or the osteosclerosis may manifest as alternating dense and lucent bands suggesting a fluctuating disturbance in skeletal growth. Such banding is most commonly seen in the pelvis and near the ends of major long bones (Fig. 24-2). In the appendicular skeleton, metaphyses are typically widened because of the defective modeling. Erosion of the distal phalanges occurs rarely and is more characteristic of pycnodysostosis. Transverse pathological fracture of long bones is common (Fig. 24-3). Rachitic changes due to hypocalcemia have been described. 3~ In the axial

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FIGURE 2 4 - 1 Osteopetrosis (malignant form). Anteroposterior (AP) radiograph of the lower limbs of a neonate shows characteristic diffuse osteosclerosis, absence of medullary space, and poorly modeled metaphyses. Furthermore, growth plate widening and metaphyseal irregularity are consistent with rickets.

MICHAEL P. WHYTE

FIGURE 24--2

Osteopetrosis (intermediate form). AP radiograph of the distal femur of a 10-year-old boy shows a widened metadiaphyseal region with characteristic alternating dense and lucent bands. [From Avioli LV, Krane SM (eds): Metabolic Bone Disease and Clinically Related Disorders, 2nd ed. Philadelphia, WB Saunders Co,

1990.] skeleton, the cranium is usually thick and dense, with the base having the greatest osteosclerosis (Fig. 2 4 - 4 ) , and there is underpneumatization of the paranasal and mastoid sinuses. Vertebrae may exhibit lucent central bands (Fig. 2 4 - 5 ) or show a "bone-in-bone" (endobone) configuration on lateral view. The two proposed types of benign osteopetrosis are characterized by progressive osteosclerosis with either pronounced diffusely increased radiodensity of the skull and other bones (type I) or more selective sclerosis of the base of the skull together with typical endobone formation in the spine (type II). 25'26 For patients with osteopetrosis, skeletal scintigraphy retains its utility to demonstrate fractures, osteomyelitis, and so on. 31 Magnetic resonance imaging (MRI) of a few affected individuals has revealed a weaker signal from marrow spaces in malignant compared to benign disease. 32 Accordingly, MRI may prove useful to monitor patients treated by bone marrow transplantation (see later). Cranial MRI and computed tomography (CT) findings in infants and children have been reported. 33

D. Histopathological Findings Although the radiological features of osteopetrosis are often diagnostic, failure of osteoclasts to resorb skeletal tissue provides a histological finding that can be considered pathognomonic (Fig. 2 4 - 6 , see Color Plate); that is, presence of "islands" or " b a r s " of calcified cartilage (unresorbed primary spongiosa) within bony trabeculae distant from sites of endochondral bone formation. Normally, such cartilage remnants are removed by functioning osteoclasts during skeletal remodeling. 19-21'34-36 Osteoclasts themselves have been reported to be increased, normal, or decreased in number in osteopetrosis. In malignant forms, typically there are many of these multinucleated cells appropriately positioned at bone s u r f a c e s . 37 Nevertheless, their nuclei are especially numerous and ultrastructural abnormalities may be present, including absence of "ruffled borders" and "clear

CHAPTER 24

Skeletal Disorders Characterized By Osteosclerosis or Hyperostosis

FIGURE 24--3 Osteopetrosis(benign form). AP radiograph of the distal femur of a 22-year-old man shows homogeneous osteosclerosis with a transverse pathological fracture of the midshaft. [From Avioli LV, Krane SM (eds): Metabolic Bone Disease and Clinically Related Disorders, 2nd ed. Philadelphia, WB Saunders Co, 1990.]

zones," which are characteristics of osteoclasts that are actively resorbing bone. 34,3s'3s Marrow space is often crowded with fibrous tissue. 34'37 In benign osteopetrosis, osteoid may be increased, and osteoclasts can be scant and devoid of ruffled borders. 36

E. Etiology and Pathogenesis Although the more common forms of human osteopetrosis appear to be heritable (Table 2 4 - 3 ) , the defective gene loci of the types discussed thus far are unknown. Only CA II deficiency is understood at the molecular level (see below). 16 Theoretically, a defect in the microenvironment of the stem cell for the osteoclast, the stem cell itself, osteoclast

701

precursor cells, osteoclast heterokaryon formation, the mature osteoclast, or the skeletal matrix could account for osteopetrosis. ~8'2~ Animal models for osetopetrosis clearly illustrate various pathogenetic mechanisms. TM The osteopetrosis of CA II deficiency appears to result from failure of osteoclasts to secrete hydrogen ion for dissolution of o s s e o u s t i s s u e . 16 The etiology and precise pathogenesis are unknown for other human forms. 1~ Biosynthesis of an abnormal parathyroid hormone, 39 defective production of interleukin-2, 4~ and subnormal generation of superoxide necessary for bone resorption 41 are potential defects. The occurrence of osteopetrosis with neuronal storage disease (characterized by accumulation of ceroid lipofuscin) indicates that these patients may have a primary lysosomal defect. 17 Virus-like inclusions (nearly identical to those of the nucleocapsids of Paramyxoviridae) and antigens of respiratory syncytial virus and measles virus have been noted in some of the osteoclasts of several sporadic cases of benign osteopet r o s i s . 42 Their significance, however, is uncertain. Recently, retrovirus infection has been offered as an explanation for some types of osteopetrosis. 43 Primary immune defects may occur in osteopetrosis, but do not seem to be as common as believed previously. 2~ Detailed investigation of leukocyte function in malignant osteopetrosis has revealed abnormalities in circulating monocytes and granulocytes. 41'44 The myelophthisic disease in the malignant forms of osteopetrosis probably results from marrow crowding by bone, fibrous tissue, and numerous osteoclasts. 37 Skeletal fragility may be due to defective remodeling of woven bone to compact bone and/or to defective weaving of collagen fibrils necessary for osteons to become connected. 21 Presence of CK-BB in serum in true forms of osteopetrosis appears to reflect malfunctioning osteoclasts rather than a metabolic consequence of a hypoxic marrow. 27

F. Treatment Because the various forms of osteopetrosis can differ in outcome, a correct diagnosis (which may involve assessment of disease progression) and selection of an appropriate therapeutic approach a r e c r u c i a l . 1~ Transplantation of allogeneic bone marrow from a haploidentical donor has been followed by significant clinical improvement and reversal of neurological, hematological, radiological, and histopathological abnormalities in malignant osteopetrosis. 45-5~ Demonstration that osteoclasts, but not osteoblasts, were of donor origin after bone marrow transplantation has corroborated the hypothesis that osteoclast-mediated bone resorption is defective and that osteoclasts are normally derived from precursor cells in the marrow. 51 Transplantation of HLA-

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MICHAEL P. WHYTE

FIGURE 24--4 Osteopetrosis (intermediate form). Lateral radiograph of the skull of a 13-year-old boy shows osteosclerosis, especially apparent at the base. [From Avioli LV, Krane SM (eds): Metabolic Bone Disease and Clinically Related Disorders, 2nd ed. Philadelphia, WB Saunders Co, 1990.]

nonidentical marrow has considerably poorer outcome. 52 Since a variety of genetic defects appear to cause osteopetrosis, 1~ it is understandable that bone marrow transplantation may not be helpful in all patients. 18'21 Furthermore, older patients and those with especially severe sclerosis of the marrow cavity seem to fare less well with transplantation. 2~ Accordingly, bone biopsy may be helpful to support the rationale for and predict the outcome of bone marrow transplantation. It has been advised that rickets be treated before bone marrow transplantation so that donor osteoclasts will be able to resorb mineralized bone tissue. 54 Successful transplantation resuits in hypercalcemia in some patients. 55 Treatment with large oral doses of calcitriol together with a calcium-deficient diet has been reported to improve the malignant form of osteopetrosis as successfully as bone marrow transplantation. 28'53 Here, calcitriol appears to act therapeutically by stimulating osteoclast activity. However, a recent update indicates that some patients become resistant to this treatment. 56 A preliminary report of a long-term trial of this regimen in an adult with an apparently intermediate form of osteopetrosis describes improved hematopoietic function and decreased skeletal mass. 57 Early publications report some success with a calcium-deficient diet alone. 58 Ironically,

supplementation of dietary calcium may be necessary to correct rachitic disease from hypocalcemia. 54 Pharmacological doses of glucocorticoids appear to be beneficial for malignant osteopetrosis and are especially helpful in stabilizing patients with hepatomegaly and pancytopenia. 59'6~ Prednisone therapy together with a low-calcium, high-phosphate diet has been reported to be a potentially effective alternative treatment to marrow transplantation for malignant osteopetrosis. 61 Long-term infusion of parathormone seemed efficacious for one infant, 39 perhaps by increasing endogenous calcitriol levels. Recently, interferon g a m m a - l b treatment has been shown to diminish frequency of infection and improve hematological and skeletal manifestations in severe cases of osteopetrosis. 56'62 Osteomyelitis of the jaw can be treated with antibiotics and hyperbaric oxygenation. 63 Surgical decompression of the facial and optic nerves (evaluated best by CT rather than by radiological views of the optic foramena) may be SUCCessful. 22'23 Conventional radiographic study has failed to diagnose malignant osteopetrosis in utero at 20 weeks' gestation 64 but did detect the disease later in pregnancy. 65 Prenatal diagnosis of lethal disease at 18 weeks' gestation by ultrasound has recently been reported. 66

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703

f a m i l i e s . 16"74-76 Consanguinity is a common finding in

kindreds from the Arabian peninsula. 77 Perinatal history is generally unremarkable. Manifestations present in infancy or early childhood and include developmental delay, failure to thrive, or fracture. Investigation of short stature may also lead to the diagnosis. 16'76 Patients commonly, but not always, have mental subnormality. Dental malocclusion and compression of the optic nerves develop in some patients. The renal tubular acidosis is usually a " m i x e d " type (proximal and distal) and may account for apathy, muscle weakness, and hypotonia. Intermittent hypokalemic paralysis has been reported. Although most patients do not fracture, recurrent breaks in long bones can cause significant morbidity. TM The disorder, however, appears to be compatible with long life. 7°,75

B. L a b o r a t o r y F i n d i n g s

FIGURE 24--5 Osteopetrosis (intermediate form). Lateral radiograph of the lower thoracic spine of an 8-year-old boy shows osteosclerosis of ribs and vertebrae. Note the characteristic central lucent bands in each vertebra. [From Avioli LV, Krane SM (eds): Metabolic Bone Disease and Clinically Related Disorders, 2nd ed. Philadelphia, WB Saunders Co, 1990.]

Anemia, if present, is usually mild and apparently of nutritional origin. Bone marrow aspiration reveals normal findings. Metabolic acidosis has been noted as early as the neonatal p e r i o d , 77 and both proximal and distal renal tubular acidosis have been reported. TM Distal (type I) renal tubular acidosis seems established best; however, further studies are needed to define more precisely the defect in acid-base homeostasis. 78'79 Aminoaciduria and glycosuria are absent. TM

C. R a d i o l o g i c a l F e a t u r e s

III. CARBONIC ANHYDRASE II DEFICIENCY CA H deficiency is an inborn error of metabolism. 16 In 1972, three independent g r o u p s 67-69 described a new autosomal recessive syndrome characterized by radiological changes of osteopetrosis in patients with renal tubular acidosis. Cerebral calcification and histopathological confirmation of osteopetrosis were first reported in 1 9 8 0 . 7°'71 Three years later, deficiency of CA II isoenzyme was identified as the primary biochemical defect. 72 Mutations in the " c a n d i d a t e " CA II gene were first reported in 1992. 73

The radiological features of CA II deficiency are similar to those of other forms of osteopetrosis, except that the osteosclerosis can diminish spontaneously over years (Fig. 2 4 - 7 ) and basal ganglia calcification will typically appear. TM Radiological abnormalities of the skeleton were noted at the time of clinical presentation in all case reports, although one neonate had only very subtle findings. 77 CT has shown that the cerebral calcification is developmental (appearing between 2 and 5 years of age), increases during childhood, occurs in the gray matter of the cortex and basal ganglia, and is similar if not identical to that seen in idiopathic hypoparathyroidism or pseudohypoparathyroidism. 8°

D. H i s t o p a t h o l o g i c a l F i n d i n g s A. C l i n i c a l P r e s e n t a t i o n Descriptions of more than 20 patients with this rare inborn error of metabolism (McKusick 259730) reveal that there is clinical variability among affected

Autopsy studies have not been reported. Specimens of bone taken from four patients from two families have been examined histopathologically. 68'7° Changes characteristic of osteopetrosis TM were documented in each of

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MICHAEL P. WHYTE

FIGURE 24--7

Carbonic anhydrase II deficiency. A, AP radiograph of the proximal tibia and fibula of a 2-year-old girl shows features of osteopetrosis including widening of the metaphysis, diffuse osteosclerosis, and altemating radiodense and radiolucent bands. B, AP radiograph of proximal tibia and fibula of the same patient, at age 17, shows nearly complete resolution of features of osteopetrosis. A few very faint sclerotic lines remain in what appears to be otherwise normal bone. [From Avioli LV, Krane SM (eds): Metabolic Bone Disease and Clinically Related Disorders, 2nd ed. Philadelphia, WB Saunders Co, 1990.]

the three sisters first found to have CA II deficiency (Fig. 24-8). E. E t i o l o g y a n d P a t h o g e n e s i s CAs catalyze the initial step in the reaction C O 2 -Jv H + + H C O 3 and, therefore, function importantly in acid-base regulation. CA II has been identified in a variety of cell types and tissues including erythrocytes, eye, brain, kidney, cartilage, liver, lung, skeletal muscle, pancreas, and gastric mucosa 81's2 and is the most catalytically active isoenzyme of the CA family. 83 The other CA isoenzymes have a more restricted tissue distribution. Initially, studies of erythrocyte lysates indicated that deficiency of CA II accounted for this form of osteopetrosis; now a variety of mutations have been found in the CA II isoenzyme gene. 16 Red cell lysates reveal a deficiency of CA II but not of CA I. 72'74 Autosomal recessive inheritance for this disorder was supported by the observation that CA II levels are approximately halfnormal in heterozygous parents of patients. 16'72'74 H 2 0 ---) H2CO3 ~

Presence of osteopetrosis and renal tubular acidosis in CA II-deficient patients reveals a significant physiological role for CA II in the skeleton and kidney of humans. 16 Indeed, a variety of in vivo and in vitro studies indicate that CA is important for osteoclast function, likely by enabling pericellular pH to be lowered by the action of a H + pump. 18 Pharmacological inhibition of CA activity can block bone resorption in organ culture. 84 CA II is the CA isoenzyme present in osteoclasts. 85 The observation that CA II-deficient patients respond appropriately to an acetazolamide challenge with bicarbonaturia has provided evidence that a CA isoenzyme in addition to CA II functions importantly in the kidney. 78 Whether cerebral calcification is a direct or indirect effect of CA II deficiency is unclear. Mouse models for this disorder should help to define the role of CA II in mammal s. 16,86 The gene for CA II is located on chromosome 8 in humans. 87 Some of the clinical and biochemical heterogeneity observed among affected kindreds appears to be explained by different allelic defects in the CA II g e n e . 16,73

CHAPTER 24 Skeletal Disorders Characterized By Osteosclerosis or Hyperostosis

705

FIGURE 24--8 Carbonic anhydrase II deficiency. In this iliac crest specimen, defective osteoclastic function and true osteopetrosis is revealed by the presence of cartilage "islands" (short arrows) that reflect unresorbed primary spongiosia in trabecular bone (TB). Osteoclasts (long arrows) are present (Goldner stain; x 50) [From Avioli LV, Krane SM (eds): Metabolic Bone Disease and Clinically Related Disorders, 2nd ed. Philadelphia, WB Saunders Co, 1990.]

F. Treatment Prenatal diagnosis of CA II deficiency has not been reported. Renal tubular acidosis in CA II deficiency has been treated briefly with HCO3 supplementation, but the long-term outcome of this therapy has not been assessed fully. 77 Transfusion of CA II-replete erythrocytes to one patient failed to correct her systemic acidosis. This finding indicates that the renal acidification defect is not the result of CA II deficiency in erythrocytes, but intrinsic to the kidney. 88 Hence, bone marrow transplantation might affect the skeletal disease, but would not reverse the renal acidification defect. 16

IV. PYCNODYSOSTOSIS

Pycnodysostosis (McKusick 265800), first delineated in 1962, 89,90 is the disorder that is believed to have affected the French impressionist painter Henri de Toulouse-Lautrec (1864-1901).91 More than 100 cases from 50 kindreds have been described. 92 Pycnodysostosis is inherited as an autosomal recessive trait93-95; parental consanguinity has been described for about 30% of patients. Most reported cases have originated in Europe or the United States, but the condition has been

encountered in Israel and Indonesia, in Asian Indians, and in African blacks; it is especially common in the Japanese. 96

A. Clinical Presentation Pycnodysostosis is usually diagnosed during infancy or childhood because of disproportionate short stature together with additional dysmorphic features including a relatively large cranium with fronto-occipital prominence, small facies, obtuse mandibular angle, small chin, dental malocclusion with persistence of carious deciduous teeth, high-arched palate, proptosis, bluish sclerae, and a pointed and beaked nose. 5'93 The anterior fontanel is often palpably open, as are other major cranial sutures. The hands are small and square, the fingers are short and clubbed from acroosteolysis or aplasia of terminal phalanges, and the nails are hypoplastic. Recurrent deforming fractures (usually of the lower limbs), a narrowed thorax, pectus excavatum, kyphoscoliosis, increased lumbar lordosis, and genu valgum may o c c u r . 92 Mental retardation is present in about 10% of c a s e s . 93 Adult height ranges between 4'3" and 4'11". Atypical patients have been described, for example, with visceral manifestations and with rickets. 97

706

MICHAEL P. WHYTE B. L a b o r a t o r y F i n d i n g s

Patients are not anemic. Serum calcium and inorganic phosphate levels and alkaline phosphatase activity are generally normal.

and the orbital ridges are dense (Fig. 2 4 - 9 ) . There is hypoplasia of facial bones, sinuses, and terminal phalanges (Fig. 24-10). Vertebrae are sclerotic (transverse processes are uninvolved) and may have anterior and posterior concavities. Lumbosacral spondylolisthesis is not uncommon, and lack of segmentation of the atlas and axis can occur. Madelung's deformity may be present in the forearms. 92

C. R a d i o l o g i c a l F e a t u r e s Many of the radiological findings of pycnodysostosis are similar to those of osteopetrosis; for example, both conditions are characterized by generalized osteosclerosis and recurrent fractures. 98'99 However, pyknodysostosis differs from osteopetrosis by the following additional features; wormian bones; delayed closure of sutures and fontanels (prominently the anterior); obtuse mandibular angle; gracile clavicles that are hypoplastic at the lateral ends; partial absence of the hyoid bone; and hypoplasia or aplasia of the distal phalanges and ribs. 1~176Radiodense striations and endobones (bonewithin-bone) do not o c c u r . 2'5-7 In pycnodysostosis, the osteosclerosis is uniform, becomes apparent in childhood, and increases with age. However, it is not accompanied by the considerable modeling defects of osteopetrosis, although the long bones have thick cortices with narrow medullary cavities. In the skull, the calvarium and base are sclerotic

D. H i s t o p a t h o l o g i c a l F i n d i n g s Histopathological studies reveal normal cortical bone structure in pycnodysostosis, yet decreased osteoblastic and osteoclastic activity. 1~ A depressed rate of skeletal turnover has been reported. 1~ Electron microscopy of bone from two patients revealed findings consistent with defective degradation of skeletal collagen--perhaps due to an abnormality in the bone matrix itself, or in osteoclast function. 1~ In fact, osteoclasts in pycnodysostosis have been found to contain somewhat large cytoplasmic vacuoles that are usually filled with collagen fibrils. These observations suggest that there is defective extracellular or intracellular degradation of bone collagen. 1~ Ultrastructural study of cartilage, however, has also revealed abnormal inclusions in chondrocytes. 1~

FIGURE 24--9 Pycnodysostosis. Lateral radiograph of the skull of an infant shows that the cranial sutures are markedly widened. The base is sclerotic. (Courtesy of William H. McAlister, St. Louis, MO.) [From Avioli LV, Krane SM (eds): Metabolic Bone Disease and Clinically Related Disorders, 2nd ed. Philadelphia, WB Saunders Co, 1990.]

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707 F. T r e a t m e n t

There is no effective medical therapy for pycnodysostosis. Fractures of the long bones are usually transverse and heal at a satisfactory rate; however, massive callus formation and delayed union have been reported, l~ Internal fixation of long bones is made difficult by their hardness. Patients are, however, generally able to walk independently. 92 Extraction of teeth is difficult and several mandibles have been broken. 93 Osteomyelitis of the jaw responds to combined surgical and antibiotic therapy. 1~

V. OSTEOMESOPYKNOSIS

FIGURE 24--10 Pycnodysostosis. Posteroanterior (PA) radiograph of the hand shows that the bones are sclerotic and the distal phalanges are hypoplastic. (Courtesy of William H. McAlister, St. Louis, MO.) [From Avioli LV, Krane SM (eds): Metabolic Bone Disease and Clinically Related Disorders, 2nd ed. Philadelphia, WB Saunders Co, 1990.]

E. E t i o l o g y a n d P a t h o g e n e s i s In 1996, the molecular basis of pycnodysostosis was identified as cathepsin K gene defects. 1~ Cathepsin K is lysosomal cystine protease that is highly expressed in osteoclasts. A study of calcium homeostasis using 47Ca and 45Ca in one patient revealed a normal exchangeable calcium pool and unremarkable rate of bone accretion and calcium excretion. 1~ However, when the increased skeletal mass was considered, both the rate of bone accretion and the size of the exchangeable calcium pool appeared to be reduced. TM Thus, decreased bone resorption may account for the osteosclerosis. Similar kinetic studies, using SSSr, have been reported. 9~ Paramyxovirus-like inclusions, similar to those found in Paget's bone diseases, have been reported in the osteoclasts of two brothers with pycnodysostosis. 1~

Osteomesopyknosis (McKusick 166450) was first described in 1979 l~ and named in 1980.11~ This condition is inherited as an autosomal dominant trait. ~ Fewer than 20 cases have been reported. 1~ Patients are usually discovered incidentally during adolescence or early adulthood by radiographic study; lowback pain appears to be a common complaint. The youngest patient with characteristic lesions was 10 years old. 113 One affected woman was infertile from "ovarian sclerosis. ''1~1 Physical examination is generally unremarkable except for tenderness of the back. Routine biochemical studies were normal in all patients but one who had renal tubular acidosis. Osteomesopyknosis is characterized by patchy osteosclerosis localized to the spine, pelvis, and proximal parts of long bones. The osteosclerosis is especially prominent in the vertebral end plates (Fig. 2 4 - 1 1 ) . Lesions appear to be well demarcated by CT. 113 Bone scintigraphy has been reported to be normal. 113 Radiographic abnormalities may be unchanged for more than a decade. TM Histopathological studies of osteomesopyknotic bone have not been described.

VI. PROGRESSIVE DIAPHYSEAL DYSPLASIA (CAMURATI-ENGELMANN DISEASE) Progressive diaphyseal dysplasia (McKusick 131300) was first described in 1920 by Cockayne. TM Camurati noted in 1922 that the disorder could be inherited. 115 Engelmann characterized the severe form in 1929 and the condition is often called Engelmann's disease. 116 This is a developmental disorder that is inherited as an autosomal dominant trait, but with variable clinical and radiological penetrance. 1'117-119 More than 100 cases

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MICHAEL P. WHYTE

head, proptosis, and cranial nerve palsies when the skull is involved. ~23'124 Some patients have delayed puberty due to hypothalamic hypogonadotropic hypogonadism (personal observation). Increased intracranial pressure can occur. Physical examination may reveal palpable bony enlargement and hepatosplenomegaly and elicit diffuse skeletal tenderness on palpation. Some patients have Raynaud's phenomenon and evidence of vasculitis. 125

B. R a d i o l o g i c a l F e a t u r e s

FIGURE 24--11

Osteomesopyknosis. Lateral radiograph of the thoracic spine of this teenage girl reveals characteristic radiodense end plates.

have been reported. 119 All races appear to be affected. Hyperostosis occurs gradually along both the endosteal and periosteal surfaces of tubular bones. In especially severe cases, osteosclerosis is generalized and affects the skull and axial skeleton. Some adult carriers of the disorder have no radiographic abnormalities. Mild forms (believed to be transmitted as an autosomal recessive trait) were first reported by Ribbing. 117'12~

A. Clinical P r e s e n t a t i o n Leg pain, muscle wasting, decreased subcutaneous fat in the extremities, and a limping or broad-based and waddling gait during childhood are characteristic features of progressive diaphyseal dysplasia. Unless appropriate radiological studies are performed, the condition may be mistaken for a muscular dystrophy. 121'122Severely affected patients have a characteristic body habitus (Fig. 24-12) that includes an enlarged head, prominent fore-

Gradually spreading cortical hyperostosis of long bone diaphyses, secondary to proliferation of new bone on both the periosteal and the endosteal surfaces, is the primary radiographic feature of progressive diaphyseal dysplasia. 2-7 Hyperostosis is nearly symmetrical and occurs in the diaphyseal and metaphyseal regions of long bones. An important radiological feature is epiphyseal sparing by this process (Fig. 24-13). Diaphyseal width slowly increases. CT has shown that endosteal involvement is more extensive than periosteal hyperostosis. 126 Characteristically, the shafts of long bones have irregular surfaces (Fig. 24-14). The age of onset, rate of progression, and degree of diaphyseal sclerosis vary considerably among patients. Tibiae and femora are involved most frequently; less commonly the humeri, radii, and ulnae are affected. Occasionally, the short tubular bones show radiological changes. Progressive sclerosis of the vertebrae, skull, scapulae, clavicles, and pelvis may also occur. Cranial involvement, which appears as calvarial hyperostosis and sclerosis of the base of the skull (Fig. 24-15), can cause diagnostic confusion with mild forms of craniodiaphyseal dysplasia. With maturation of newly formed bone, the affected areas become more sclerotic. In severely affected children, osteopenia can accompany new bone formation. Focally increased radionuclide accumulation occurs during bone scintigraphy. In the milder forms of progressive diaphyseal dysplasia, which develop in adolescents or young adults, radiographic and scintigraphic studies may show skeletal abnormalities limited to the long bones of the lower limbs (Fig. 24-16). Comparison of the scintigraphic, radiographic, and clinical findings in four patients at different stages of the disease revealed generally concordant findings. In some patients, however, bone scans were rather unremarkable despite distinct abnormalities present radiographically; in these patients the disease process appeared to be quiescent. 127 Sequential radiological findings reveal a variable course for the disorder, but progressive bony involvement is the rule. Arrest of the disease process appears to

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709

FIGURE 24-- 12 Progressivediaphyseal dysplasia. A and B, This prepubescent 17-year-old girl with severe disease involvement has the characteristic body habitus including a paucity of muscle and subcutaneous fat in the limbs, thickening of the long bones, and cranial enlargement. [From Whyte MP: Rare disorders of skeletal formation and homeostasis. In Becker KL (ed): Principles and Practice of Endocrinology and Metabolism, 2nd ed. Philadelphia, JB Lippincott, 1995, pp 594-606.]

occur in s o m e c a s e s . 126'128 The MRI features of multiple cranial neuropathies have been described. 123

C. Histopathological Findings New bone formation is present in areas affected by progressive diaphyseal dysplasia. Peripheral to healthy cortical bone, there appears to be centripetal maturation and "cancellous compaction" of disorganized (woven) hyperostotic bone. 1iv In muscle, electron microscopy reveals atrophy of isolated muscle fibers, accumulation of endomyseal collagen fibrils, and thickening of pefivascular basement m e m b r a n e - - c h a n g e s that are similar in sporadic and familial cases. ~2~ Type II muscle fiber atrophy was noted in one patient with clinical evidence of myopathy but without degenerative changes on electron microscopy. ~22

D. E t i o l o g y a n d P a t h o g e n e s i s The autosomal gene defect that causes progressive diaphyseal dysplasia has not been mapped in the human genome. Some especially mild cases may reflect a separate, autosomal recessive disorder, called " R i b b i n g ' s disease." 117,120,129 However, clinically mild forms of progressive diaphyseal dysplasia can be transmitted as an autosomal dominant trait (MP Whyte and WA Murphy, unpublished observation). Some investigators argue that the clinical and laboratory findings in the full-blown condition and their responsiveness to glucocorticoid therapy indicate that progressive diaphyseal dysplasia is a systemic disorder that should be included among the inflammatory connective tissue diseases. 125 Greatly increased blood flow to affected bone was reported in two of four patients. 13~Ab-

7 10

MICHAEL P. WHYTE

FIGURE 24-- 13

Progressive diaphyseal dysplasia. AP radiograph of the left forearm of a 19-year-old woman with severe disease shows osteopenia with superimposed sclerosis of the diaphyses of the radius and ulna from proliferation of bone on the periosteal and endosteal surfaces. [From Avioli LV, Krane SM (eds): Metabolic Bone Disease and Clinically Related Disorders, 2nd ed. Philadelphia, WB Saunders Co, 1990.]

normal differentiation of monocytes-macrophages ultimately to osteoblasts has been described as a potential pathogenetic factor. TM

FIGURE 24-- 14

Progressive diaphyseal dysplasia. AP radiograph of the left forearm of a 41-year-old man (father of patient shown in Fig. 24-11) shows dense sclerosis resulting in thickening of the radial and ulnar cortices. [From Avioli LV, Krane SM (eds): Metabolic Bone Disease and Clinically Related Disorders, 2nd ed. Philadelphia, WB Saunders Co, 1990.]

toms in one patient in whom radiographic findings were progressing. 138 However, I have not observed symptomatic benefit in several patients treated with etidronate. In a few cases, my colleagues and I have noted relief of pain following a biopsy (cortical window) of an affected diaphysis. 117

E. Treatment Radiological studies show that the evolution of progressive diaphyseal dysplasia is slow and unpredictable. 127 Skeletal symptoms may remit during adolescence. Since 1967, glucocorticoid therapy (prednisone given in small doses on an alternate-day schedule) has been recognized to relieve bone pain. 132'133 Histological improvement of affected skeletal tissue has also been reported. 134-137 Intermittent courses of bisphosphonate (disodium etidronate) therapy seemed to improve symp-

VII. ENDOSTEAL HYPEROSTOSIS Endosteal hyperostosis is characterized by cortical bone thickening on the medullary (marrow) surface. Two principal forms have been describedmvan Buchem's disease and sclerosteosis. The form of endosteal hyperostosis first reported by van Buchem and colleagues in 1955139-141 is also called hyperostosis corticalis generalisata (McKusick 239100). This disorder is heritable,

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711

FIGURE 24--15 Progressivediaphyseal dysplasia. Lateral radiograph of the skull of a 19-year-old woman shows diffuse sclerosis of the cranial vault and base of the skull. Frontal bossing is present. [From Avioli LV, Krane SM (eds): Metabolic Bone Disease and Clinically Related Disorders, 2nd ed. Philadelphia, WB Saunders Co, 1990.]

either as an autosomal recessive type that is clinically severe (van B u c h e m ' s disease ) or as an autosomal dominant type that is more benign (Worth type). 142'143 H o w ever, these types of endosteal hyperostosis do not appear to be as common as the older literature suggests. In 1977, review of 41 reported cases showed that only 6 patients fit uniform diagnostic criteria; most had clinical and radiological features of sclerosteosis or other craniotubular disorders including craniodiaphyseal dysplasia. TM Sclerosteosis (cortical hyperostosis with syndactyly), like van B u c h e m ' s disease, is an autosomal recessive craniotubular hyperostosis; it is usually reported in the Afrikaner population of South Africa (McKusick 269500). Cases described from elsewhere often have Dutch ancestry as well. 143 Sclerosteosis was distinguished from van B u c h e m ' s disease in 1958 by some radiographic differences and by the presence of syndactyly. 145,146

A. Clinical Presentations Van Buchem's disease has been reported in children and adults. The gender distribution appears to be equal.

All adult patients have a markedly thickened jaw with wide angle, yet there is no prognathism, and dental malocclusion is uncommon. Progressive asymmetrical enlargement of the mandible occurs during puberty. Patients often live normally without complaints. However, recurrent facial paralysis, deafness, and optic atrophy due to narrowing of the cranial foramina are common and may begin during infancy. 147 There is no predisposition to fracture. Palpably thickened clavicles and ribs may also be present. Long bones can be painful to pressure, but range of motion appears to be normal. Sclerosteosis had until recently 14s been differentiated from van B u c h e m ' s disease because excessive height and syndactyly are present. Syndactyly may be the only clinical finding in sclerosteosis at birth. 149 During early childhood, however, there is overgrowth and sclerosis of the skeleton, especially the skull, with attendant facial disfiguration. 149 Patients are tall and heavy beginning in childhood. " G i g a n t i s m " has been used to describe their appearance. The jaw has a very square appearance. Deafness and facial palsy from cranial nerve entrapment may be among the presenting clinical manifestations. Some patients develop raised intracranial pressure and headache from a small cranial cavity. Brainstem compression may also occur. Syndactyly due to cutaneous or bony

712

MICHAEL P. WHYTE

ized osteosclerosis occurs because of involvement of most other bones, including the base of the skull (Fig. 24-18), facial bones and mandible (Fig. 24-19), vertebrae, pelvis, and ribs (Fig. 24-20). 2-8 In sclerosteosis, the skeleton, except for possible syndactyly, is normal in early childhood. The major radiological feature is progressive osteosclerosis and widening of the skull and mandible (including prognathism). 152The fibs, pelvis, vertebral pedicles, and tubular bones are somewhat dense. Modeling defects occur in the long bones where the cortices are thickened. Syndactyly, usually of the index and long fingers, is common (Fig. 2 4 21). Cranial CT findings in sclerosteosis have recently been reported in detail and have revealed that fusion of the ossicles as well as narrowing of the internal auditory canals and cochlear aqueducts account for the deafness. ~53

D. Histopathological Findings Van Buchem and co-workers suggested that the disorder is due to excessive formation of normal bone tissue. 141

Progressive diaphyseal dysplasia. AP radiograph of the left leg of a 19-year-old man with a mild form of Engelmann's disease shows focal sclerosis and cortical thickening of the midtibia (arrows). [From Avioli LV, Krane SM (eds): Metabolic Bone Disease and Clinically Related Disorders, 2nd ed. Philadelphia, WB Saunders Co, 1990.]

A recent multidisciplinary study of an American kindred with sclerosteosis included histomorphometric analysis of calvarium following in vivo tetracycline labeling. 151 Dense thickened trabeculae were associated with active appearing osteoblasts, increased total bone volume, elevated relative osteoid volume, and increased linear extent of bone formation and appositional rate. Osteoclastic bone resorption seemed to be depressed. 151

fusion of the index and middle fingers is a characteristic finding, but of variable severity. Fingernails are dysplastic. Intelligence is not affected. Life expectancy may be

E. Etiology and Pathogenesis

FIGURE 24-- 16

s h o r t e n e d . 15~

B. Laboratory Findings Alkaline phosphatase activity in serum is of bone origin, and may be increased in van Buchem's disease. Serum levels of calcium and inorganic phosphate are normal.

C. Radiological Features The principal radiographic feature of van Buchem's disease is endosteal hyperostosis producing dense homogeneous diaphyseal cortices that narrow the medullary canal (Fig. 24-17). 2-8 Long bones are properly shaped, but appear dense because of widening of the cortex from selective endosteal hyperostosis. General-

Osteoblast hyperactivity, with failure of osteoclasts to compensate, appears to account for the osteosclerosis of sclerosteosis. 151 No abnormality of pituitary function or of calcium homeostasis has been found. 154 A detailed assessment of the pathogenesis of the neurological defects is available. 151 Recent review of 50 patients with sclerosteosis in South Africa and 15 patients with van Buchem's disease in Holland revealed similar clinical and radiographic features that were more severe in sclerosteosis. Accordingly, Beighton and co-workers suggested that both disorders share the same faulty gene(s), but that the phenotypic variation is due to the epistatic effect of modifying genes. ~48

F. Treatment Surgical decompression of narrowed foramina may be helpful in some patients with cranial nerve palsy. 155 There is no effective medical treatment.

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713

FIGURE 24--17 Endostealhyperostosis. A, AP radiograph of the left leg of a 9-year-old boy shows bones that are of normal width yet have very thick cortices that constrict the medullary canal. B, Similar changes are present in his left forearm and hand. [From Avioli LV, Krane SM (eds): Metabolic Bone Disease and Clinically Related Disorders, 2nd ed. Philadelphia, WB Saunders Co, 1990.]

In sclerosteosis, syndactyly usually requires surgical intervention, but is especially difficult to correct if there is bony fusion. Patients are not prone to fracture. Surgery to correct prognathism is complicated by dense mandibular bone. A thorough discussion of the m a n a g e m e n t of the neurological dysfunction was published in 1983.154

VIII. OSTEOPOIKILOSIS Osteopoikilosis (McKusick 166700), literally translated, means "spotted b o n e s . " This radiological curiosity is inherited as an autosomal dominant trait with a high degree of penetrance. 156 In some kindreds, affected subjects also have connective tissue nevi (dermatofibrosis lenticularis disseminata), in which case the con-

dition is then called the Buschke-Ollendorff syndrome, 157 but family members can have either manifestation alone.

A. Clinical Presentation Osteopoikilosis is often diagnosed when radiological study is performed for unrelated reasons. Musculoskeletal pain has been described in some cases; however, the bony lesions are considered asymptomatic. If the condition is not recognized as a benign skeletal dysplasia, affected individuals may be subjected to diagnostic studies for other important disorders including metastatic disease to the skeleton. 158 The cutaneous nevi of dermatofibrosis lenticularis disseminata are most often noted on the lower trunk or limbs and appear before puberty. They may be congen-

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FIGURE 24-- 18 Endosteal hyperostosis. Lateral radiograph of the skull of the boy depicted in Figure 2 4 - 1 7 shows dense sclerosis of the cranial vault. [From Avioli LV, Krane SM (eds): Metabolic Bone Disease and Clinically Related Disorders, 2nd ed. Philadelphia, WB Saunders Co, 1990.]

FIGURE 24--19

Endosteal hyperostosis. Lateral radiograph of the mandible and facial bones of the boy depicted in Figures 2 4 - 1 7 and 2 4 - 1 8 show dense sclerosis of all osseous structures. [From Avioli LV, Krane SM (eds): Metabolic Bone Disease and Clinically Related Disorders, 2nd ed. Philadelphia, WB Saunders Co, 1990.]

P. WHYTE


715

poikilosis revealed excessive amounts of unusually broad, interlacing elastin fibers in the dermis. 157 The epidermis was unremarkable. Electron microscopy showed markedly branched elastin fibers. After digestion with pancreatic elastase, the lesions were formed to contain large amounts of desmosine. 157 The bony abnormalities are thickened trabeculae that merge with surrounding normal bone, or islands of cortical bone with haversian systems. Remodeling of mature lesions is inactive. ~56

D. Treatment Osteopoikilosis does not require treatment.

IX. OSTEOPATHIA STRIATA

FIGURE 24--20 Endosteal hyperostosis. AP radiograph of the ribs of the boy depicted in Figures 24-17 to 24-19 shows homogeneous dense osteosclerosis of all ribs (note: the central portions of the vertebrae are also sclerotic). [From Avioli LV, Krane SM (eds): Metabolic Bone Disease and Clinically Related Disorders, 2nd ed. Philadelphia, WB Saunders Co, 1990.]

ital. This dermatosis appears as small asymptomatic papules. Occasionally, the lesions are yellow or white disks or plaques or deep nodules, or streaks. 157'159

B. Radiological Features The principal radiologic feature of osteopoikilosis is focal bony sclerosis composed of numerous small overgrowths in the trabecular portions of the skeleton. Commonly affected sites are the metaepiphyseal regions of the long bones (Fig. 2 4 - 2 2 ) , the ends of the short tubular bones, and the carpal, tarsal, and pelvic bones (Fig. 2 4 - 2 3 ) . These foci are of variable shape, but tend to be round or oval. Once manifest, they are stable in size and shape for decades 2-s and do not avidly accumulate radionuclide on bone scintigraphy. 15s Metastatic lesions may mimic the radiographic appearance of osteopoiki1osis. 16~

C. Histopathological Studies Examination of dermatofibrosis lenticularis disseminata in 12 patients in two unrelated kindreds with osteo-

Osteopathia striata is a radiographic abnormality characterized by asymptomatic linear striations at the ends of long bones and in the ilium. 2-s This finding occurs alone or in a variety of syndromes such as (1) osteopathia striata with cranial sclerosis (McKusick 166500), inherited as an autosomal dominant trait ~61-~65" (2) osteopathia striata with focal dermal hypoplasia, also called Goltz's syndrome (McKusick 305600), 166'167 inherited as an X-linked recessive trait; or (3) osteopathia striata with pigmentary dermopathy (including white forelock), in which X-linked dominant inheritance seems likely (McKusick 311280) and the bony abnormalities have been shown to be developmental in early childhood. 168 Osteopathia striata also occurs as a component of a sclerosing bone disorder, even more radiologically complex, called mixed sclerosing bone dystrophy (see later).

A. Clinical Presentation When osteopathia striata occurs as an isolated finding, affected individuals are generally asymptomatic and the condition is a radiological curiosity. Musculoskeletal complaints of some sort may initiate the radiological studies that lead to the diagnosis. However, when there is cranial sclerosis, cranial nerve palsies and palatine malformations a r e c o m m o n . 164'169 In one such affected family, the diagnosis was reportedly made when a pregnant family member underwent ultrasound examination that disclosed an increased fetal biparietal diameter. ~7~ Osteopathia striata with focal dermal hypoplasia (Goltz's syndrome) is the most serious disorder featuring osteopathia striata. Affected boys have widespread linear lesions of dermal hypoplasia through which adipose tissue

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MICHAEL P. WHYTE

FIGURE 24--21 Sclerosteosis.A, PA radiograph of the hand of a 36-year-old man shows thickened, sclerotic tubular bones. B, PA radiograph of the hand of a 38-year-old man shows syndactyly of his second and third fingers in addition to osteosclerotic tubular bone. (Radiographs courtesy of Dr. Peter Beighton, Capetown, South Africa.) [From Avioli LV, Krane SM (eds): Metabolic Bone Disease and Clinically Related Disorders, 2nd ed. Philadelphia, WB Saunders Co, 1990.]

can herniate and have a variety of skeletal defects affecting the l i m b s . 166'167 Osteopathia striata with dermopathy and white forelock 168 may be associated with developmental deafness (personal observation). B. R a d i o l o g i c a l F e a t u r e s

D. T r e a t m e n t There is no medical treatment for osteopathia striata.

X. MELORHEOSTOSIS

Gracile linear striation of bone is the principal radiologic feature of osteopathia striata) -s This abnormality develops in the cancellous portions of the skeleton, particularly the metaepiphyseal ends of the long bones (Fig. 2 4 - 2 4 ) and the periphery of the iliac bones (Fig. 2 4 - 2 5 ) . Involvement of the carpal, tarsal, and tubular bones of the hands and feet is less common and more subtle. Once manifest, the striations are stable in appearance for years. They do not show focal radionuclide accumulation on bone scintigraphy. 158

Melorheostosis (MuKusick 155950), translated from the Greek, means flowing hyperostosis of the limbs. The radiological appearance of affected long bones has been likened to melted wax dripping down the side of a candle. The disorder was first described in 1922.171 About 200 cases have been reported. 172 No mendelian basis for melorheostosis has been established. 173'174

C. H i s t o p a t h o l o g i c a l F i n d i n g s

Melorheostosis usually manifests during childhood. Monomelic involvement is most common. Bilateral disease is asymmetrical. Pain and stiffness are the predom-

Histopathological studies have not been reported.

A. C l i n i c a l P r e s e n t a t i o n


7 17

B. Laboratory Findings Routine laboratory studies in melorheostosis (e.g., serum calcium and inorganic phosphate levels and alkaline phosphatase activity) are normal.

C. Radiological Features Dense, eccentric, irregular hyperostosis of the cortex and adjacent medullary canal of a single bone or of several adjacent bones is the principal radiological feature of melorheostosis. 2-8'~82 Any bone or anatomical region may be involved, but the condition is more common in the lower limbs (Figs. 2 4 - 2 6 and 24-27). Ectopic bone may develop in soft tissue adjacent to involved skeletal areas, particularly near joints. Melorheostotic bone accumulates radionuclide during bone scintigraphy. 158'183

D. Histological Findings

FIGURE 24--22 Osteopoikilosis.AP radiograph of the knee of a young woman shows multiple sclerotic foci of variable shape located in the metaepiphyseal regions of the distal femur and proximal tibia.

inant symptoms. Affected joints may become contracted and deformity also occurs. Cutaneous changes can overlie affected skeletal regions. Of 131 patients reported in one study, 17% had a dermatosis characterized by linear scleroderma-like areas, 175 sometimes with hypertric h o s i s . 176 Fibromas, fibrolipomas, lymphangiectasis, capillary hemangiomas, and arterial aneurysms may occur. 177 Vascular abnormalities have been documented in at least 5% of reported patients. ~78 The soft tissue abnormalities are often discovered earlier than the underlying hyperostosis. Therefore, it has been suggested that the linear scleroderma might represent the primary abnormality that extends deep into the skeleton. 179 In affected children, soft tissue contractures and premature fusion of epiphyses can cause leg length inequality as a principal clinical feature18~ however, their pain is less frequent than in adults. The skeletal changes appear to progress most rapidly during childhood; during the adult years they can stabilize or more gradually extend. ~8~

Unlike the skin lesions of true scleroderma, the sclerodermatous skin lesions of melorheostosis contain normal-appearing collagen. Therefore, the condition has been called "linear melorheostotic s c l e r o d e r m a . ''176'179'184 A melorheostotic skeletal lesion consists of endosteal thickening during infancy and periosteal bone formation during adulthood. 182 Affected bone is sclerotic and thickened with irregular lamellae that obliterate haversian systems. Fibrosis of intertrabecular spaces can occur. 182

E. Etiology and Pathogenesis The appearance of melorheostosis and soft tissue lesions in the distribution of sclerotomes, myotomes, and dermatomes suggests that a segmentary embryogenetic defect accounts for this sporadic mesodermal disorder. 172'182 An early postzygotic mutation has been suggested. 178

F. Treatment Surgical correction of contractures in children with melorheostosis is difficult; recurrent deformity is usual. The calcium channel blocking agent nifedipine has been reported to alleviate pain in one patient. ~85

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MICHAEL P. WHYTE

FIGURE 24--23 Osteopoikilosis.AP radiograph of left hemipelvis of this 39-year-old woman shows multiple small sclerotic foci throughout the innominate bone and the metaepiphyseal region of the left femur. [From Avioli LV, Krane SM (eds): Metabolic Bone Disease and Clinically Related Disorders, 2nd ed. Philadelphia, WB Saunders Co, 1990.]

XI. MIXED SCLEROSING BONE DYSTROPHY Mixed sclerosing bone dystrophy is the term offered by Walker in 1964 to describe two patients in w h o m radiological features of melorheostosis, osteopoikilosis, and osteopathia striata were present in combination. 186 Subsequently, cranial sclerosis and/or other skeletal defects were recognized to also occur (see Section IX) in some affected individuals. 187-19~ Although this is clearly a very heterogeneous disorder, review of the literature in 1981 resulted in a tentative classification that might help to identify possible subgroups. 19~

FIGURE 24--24 Osteopathia striata. AP radiograph of left knee of a 25-year-old woman shows vertical linear striations in the metaepiphyseal regions of the distal femur and proximal tibia. [From Avioli LV, Krane SM (eds): Metabolic Bone Disease and Clinically Related Disorders, 2nd ed. Philadelphia, WB Saunders Co, 1990.]

ically associated with each of these findings. The skull can be enlarged (Fig. 2 4 - 2 8 ) and cranial nerve entrapment may occur. Skeletal pain can trouble the patient.

B. Radiological Features Two or more patterns of osteosclerosis described thus f a r m t h a t is, osteopoikilosis, osteopathia striata, melorheostosis, focal osteosclerosis, cranial sclerosis, generalized cortical hyperostosis, or progressive diaphyseal d y s p l a s i a m a r e found in one patient (Figs. 2 4 - 2 9 and 2 4 - 3 0 ) . Often, only a portion of the skeleton is involved. 186'19~ Skeletal scintigraphy will reveal increased radionuclide uptake in areas of greatest osteosclerosis. 190,191

A. Clinical Presentation C. Histopathological Findings Patients with mixed sclerosing bone dystrophy who have components of cranial sclerosis and/or melorheostosis may be symptomatic from the complications typ-

Although some patients with mixed sclerosing bone dystrophy and generalized osteosclerosis have been re-

CHAPTER 24


FIGURE 2 4 - 2 5 Osteopathia striata. AP radiograph of the left hemipelvis of this 25-year-old woman shows linear striations that are distributed in a fan-like pattern in the iliac wing. [From Avioli LV, Krane SM (eds): Metabolic Bone Disease and Clinically Related Disorders, 2nd ed. Philadelphia, WB Saunders Co, 1990.]

ported to have " o s t e o p e t r o s i s , " detailed histopathological study of iliac crest bone from several affected individuals has failed to show remnants of primary spongiosa, thereby excluding absence of osteoclastmediated bone resorption. 19~

D. Etiology and Pathogenesis Delineation of m i x e d sclerosing bone dystrophy suggests a c o m m o n pathogenetic m e c h a n i s m for these forms of osteosclerosis or hyperostosis w h e n they occur separately. However, whereas osteopoikilosis and osteopathia striata have been shown clearly to be heritable, m i x e d sclerosing bone dystrophy, like melorheostosis, has been reported only as a sporadic disorder.

E. Treatment There is no effective medical treatment for mixed sclerosing bone dystrophy. Surgical correction of con-

719

FIGURE 24--26 Melorheostosis. AP radiograph of the left knee of a 42-year-old woman shows asymmetrical eccentric distribution of cortical thickening and dense medullary hyperostosis of the distal femur. [From Avioli LV, Krane SM (eds): Metabolic Bone Disease and Clinically Related Disorders, 2nd ed. Philadelphia, WB Saunders Co, 1990.]

tractures or of neurovascular c o m p r e s s i o n by osteosclerotic lesions m a y be necessary.

XII. FIBRODYSPLASIA OSSIFICANS PROGRESSIVA Fibrodysplasia ossificans progressiva (myositis ossificans progressiva) is characterized by a variety of congenital skeletal deformities together with recurrent, painful, progressive episodes of heterotopic formation of true bone in fascia, aponeuroses, ligaments, tendons, and connective tissue of voluntary muscles; smooth muscle is spared. Since the disorder was first described in 1692,192 more than 500 cases have been reported, w3'194 It appears to be transmitted as an autosomal dominant trait, but with very variable expressivity ( M c K u s i c k 135100). M o s t cases, however, are sporadic. 1 Caucasians are re-

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MICHAEL P. WHYTE

muscles of the mandible may lead to severe limitation of jaw movement and impair nutrition. Involvement of the musculature of the thorax can deform the chest (Fig. 2 4 - 3 2 ) and thereby cause restrictive lung disease and predispose the patient to pneumonia. Scoliosis occurs frequently. ~95 Although secondary amenorrhea is not unusual, successful reproduction has been reported. ~96 Deafness and alopecia occur with increased frequency.

B. Laboratory Findings Serum alkaline phosphatase activity in fibrodysplasia ossificans progressiva may be increased. Other routine biochemical studies are usually normal.

C. Radiological Features

FIGURE 24--27 Melorheostosis. AP radiograph of the left hemipelvis of a 42-year-old woman shows dense, eccentric, irregular hyperostosis of the acetabulum and proximal femur. [From Avioli LV, Krane SM (eds): Metabolic Bone Disease and Clinically Related Disorders, 2nd ed. Philadelphia, WB Saunders Co, 1990.]

ported most commonly; however, the disorder has been described in blacks. 192

A. Clinical Presentation Fibrodysplasia ossificans progressiva usually becomes manifest during the first decade of life, 194 but the age at presentation is highly variable. There are reports of involvement in u t e r o and beginning as late as early adulthood. Nevertheless, the diagnosis may be made at birth by the presence of a variety of congenital skeletal anomaliesmthe most characteristic being hallux valgus with microdactyly (Fig. 24-31). Microdactyly of the thumb may also be present. There can be synostosis and hypoplasia of the phalanges. Recurrent episodes of tender, rubbery, painful soft tissue swellings (that are sometimes associated with minor trauma) are followed by calcification and then heterotopic true bone formation. Early on, torticollis with involvement of the sternocleidomastoid muscle is noted, or the muscles of the shoulder girdle and dorsum of the trunk are affected. Fever may occur during these times and mimic an infectious process. Progressive episodes of heterotopic bone formation result in decreased range of motion, especially in the neck and shoulders. Involvement of the

A combination of anomalies of the digits and soft tissue ossification is the radiological hallmark of fibrodysplasia ossificans progressiva. ~97'198 There is ossification of fascia, tendons, aponeuroses, and other tissues in a characteristic pattern of progression. 199 The neck (Fig. 24-33A) and shoulders (Fig. 24-33B) tend to be involved earlier than the lower extremities (Fig. 24-34). Paraspinal muscles are especially prone to ossification. Ankylosis of the spine, rib cage, and joints limits mobility. During severe inflammation, portions of the skeleton are osteopenic. Otherwise, bones are generally well mineralized. Chief among the skeletal anomalies is disturbance of the formation of the great toe (Fig. 24-35). CT to detect soft tissue calcification appears to be the best radiological technique to diagnose an early lesion. 2~176 Skeletal scintigraphy with 99mTCmethylene diphosphonate will also be abnormal before ossification will be detected radiographically. New areas of disease activity can be detected early by this technique. 2~

D. Histopathological Findings Early lesions of fibrodysplasia ossificans progressiva are characterized by edema of fascial planes. The soft tissue mass is an edematous muscle or group of muscles. Multifocal interconnective nodules then form that are composed of fibroblasts. Later, osteoid, cartilage, and bone are present at the center of a fibrous connective tissue m a t r i x . 2~176 Fasciae, tendons, ligaments, and joint capsules may be involved. The pathological process has been identified as a form of endochondral bone formation. 2~ The ossification is characterized macroscopically by dense, flat, irregular areas of bone within the connective tissue of fascial planes, and this ossification ex-

CHAPTER 24


721

FIGURE 24--28 Mixed sclerosing bone dystrophy. A and B, This 49-year-old man has a very large head with prominent jaw and forehead. (From Pacifici R, Murphy MA, Teitelbaum SL, et al: Mixed-sclerosing-bone-dystrophy: 42-year follow-up of a case reported as osteopetrosis. Calcif Tissue Int 38:175-185, 1986.)

tends partly or completely around a muscle. 2~ Cancellous bone can eventually form. As the lesions mature, hematopoietic tissue will appear within the areas of trabecular bone. 2~ Muscle fibers may undergo secondary degenerative and atrophic change.

damental abnormality in the skeletal muscle (myositis), because histological and electromyographic abnormalities may occur prior to connective tissue proliferation. 2~ Recently, evidence for a fundamental disturbance in the biosynthesis of a bone morphogenetic protein has been demonstrated. 2~

E. E t i o l o g y a n d P a t h o g e n e s i s F. T r e a t m e n t a n d P r o g n o s i s The autosomal gene defect that causes fibrodysplasia ossificans progressiva is unknown. Paternal age appears to contribute importantly to the incidence of new dominant mutations, ~94'2~ Most cases appear to be sporadic. 1'2~ The pathogenesis is incompletely understood. It is unclear whether the disorder is due to a connective tissue abnormality that secondarily affects muscle or a primary abnormality in muscle itself. The term "fibrodysplasia ossificans progressiva" is favored by those who believe that connective tissue is primarily involved and its proliferation within skeletal muscle leads to atrophy and heterotopic bone formation. In support of this hypothesis, CT has shown that characteristic swelling of muscular fascial planes occurs before development of ectopic ossification. Multifocal sites of new bone formation develop adjacent to and extend around muscles. 2~ Some scholars in the field, however, see a fun-

There is no satisfactory medical treatment for fibrodysplasia ossificans progressiva. Adrenocorticotropic hormone or corticosteroids, calcium binders in the diet, and ethylenediaminetetraacetic acid (EDTA) infusion have not been successful. 21~ Treatment with the bisphosphonate disodium etidronate has resulted in a variable response. 211 Use of warfarin to inhibit gamma-carboxylation of osteocalcin in an effort to prevent ectopic bone formation has been of no noticeable clinical benefit. 212 Surgical release procedures for joint contractures, neurovascular entrapment, or to increase mandibular range of motion often provoke additional ectopic bone formation as does intramuscular vaccination. CT is useful to guide critical surgical intervention by identifying soft tissue changes and ossification that is not yet apparent by conventional radiography. 2~ In some cases, a course

722

FIGURE 24--29 Mixed sclerosing bone dystrophy. AP radiograph of the man shown in Figure 24-28; the left knee shows osteopoikilosis of the distal femoral epiphysis, osteopathia striata of the distal femoral and proximal tibial metaepiphyses, and melorheostosis of the distal femoral diaphysis. [From Avioli LV, Krane SM (eds): Metabolic Bone Disease and Clinically Related Disorders, 2nd ed. Philadelphia, WB Saunders Co, 1990.]

of e t h a n e - l - h y d r o x y - l , l - d i p h o s p h o n a t e (EHDP) appeared to delay the mineralization of newly formed bone matrix following surgery. 211 Despite widespread ectopic ossification, some patients live into the fifth decade. Most patients, however, die earlier from respiratory complications secondary to restricted pulmonary ventilation due to chest wall involvement. 194

XlII. AXIAL OSTEOMALACIA Axial osteomalacia is a rare disorder characterized by coarsening of the trabecular pattern on radiographic examination of the axial but not appendicular skeleton. The disorder was first described in 1961 by Frame and coworkers; the axial skeletons of three patients were noted radiographically to have " a unique coarsening and

MICHAEL P. WHYTE

FIGURE 24--30 Mixed sclerosing bone dystrophy. AP radiograph of the man shown in Figure 24-28; the left hemipelvis shows focal osteosclerosis of the ilium and a melorheostosis pattem of the proximal femur. [From Avioli LV, Krane SM (eds): Metabolic Bone Disease and Clinically Related Disorders, 2nd ed. Philadelphia, WB Saunders Co, 1990.]

sponge-like appearance. ''213 Their skulls and limbs were unremarkable. Osteoidosis was found on examination of undecalcified sections of bone. Fewer than 20 cases have been described. No mendelian pattern of transmission has been established, but autosomal dominant inheritance seems possible (McKusick 109130).

A. Clinical Presentation Most patients with axial osteomalacia have been middle-aged or elderly men. A few affected middle-aged w o m e n have been described. Radiographic manifestations, however, are likely to be present much earlier in life. 214 The disorder may be discovered incidentally; more frequently there is dull, vague, and chronic axial skeletal pain (often in the cervical region) that prompts x-ray study. Family histories have generally been reported to be negative for skeletal disease, but radiographic surveys have usually not been performed. Axial osteomalacia has been noted to be familial o n c e m a f fecting a black mother and son in w h o m polycystic liver


723

FIGURE 24--3 1 Fibrodysplasiaossificans progressiva. Typical hallux valgus deformity with microdactylyis present in this 14-year-old boy. [From Avioli LV, Krane SM (eds): Metabolic Bone Disease and Clinically Related Disorders, 2nd ed. Philadelphia, WB Saunders Co, 1990.]

and kidneys were also present. 214 Two other patients had features of ankylosing spondylitis. 215

cervical spine and ribs, and to a lesser extent in the lumbar spine. The appendicular skeleton is unaffected.

B. Laboratory Studies

D. H i s t o p a t h o l o g i c a l F i n d i n g s

Four cases of axial osteomalacia have been described in whom serum inorganic phosphate levels tended to be l o w . 215 In other patients, defective bone mineralization occurred despite normal serum levels of calcium and inorganic phosphate and increased alkaline phosphatase activity (bone isoenzyme). Serum levels of 25-hydroxyvitamin D [25(OH)D] and 1,25-dihydroxyvitamin D [1,25(OH)2D] were unremarkable in one patient. 214 One affected individual was found to be in strongly positive calcium and phosphorus balance. 216 Symptoms, elevated serum creatine kinase activity, and muscle biopsy features consistent with myopathy have been reported in a single patient. 214

C. Radiological Features The radiographic features of axial osteomalacia are essentially limited to the spine (Fig. 2 4 - 3 6 ) and pelvis (Fig. 24-37); the trabecular pattern is somewhat coarse and resembles that found in other types of osteomalacia. 5 Looser's zones, however, have not been reported. Radiographic changes appear to be most pronounced in the

In axial osteomalacia, osseous collagen has a normal lamellar pattern as shown by polarized light microscopy of rib specimens. Iliac crest specimens have distinct corticomedullary junctions, yet cortices may have both increased width and porosity. Trabeculae can have varied thickness, and total bone volume may be increased. Osteoidosis has been documented; that is, the width and extent of osteoid seams on trabecular bone surfaces and in cortical spaces may be increased. Biopsy of ribs and iliac crest following tetracycline labeling has confirmed the presence of osteomalacia, since most fluorescent "labels" were single, wide, and irregular. 214 Osteoblasts are flat and inactive-appearing ("lining") cells with reduced rough endoplasmic reticulum and Golgi zones and increased cytoplasmic glycogen. Nevertheless, they may stain intensely for alkaline phosphatase activity. Osteoclasts can be few, but histochemical studies show normal levels of acid phosphatase activity. Evidence of secondary hyperparathyroidism is absent. 214 Histological changes of osteomalacia following tetracycline labeling 215 help to distinguish axial osteomalacia from fibrogenesis imperfecta ossium 216 (see Section XIV).

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MICHAEL P. WHYTE

FIGURE 2 4 - 3 2

Fibrodysplasia ossificans progressiva. A and B, Marked narrowing of the thorax and frozen shoulders are present in this affected 14-year-old boy. [From Avioli LV, Krane SM (eds): Metabolic Bone Disease and Clinically Related Disorders, 2nd ed. Philadelphia, WB Saunders Co, 1990.]

FIGURE 24--33

Fibrodysplasia ossificans progressiva. A, Lateral radiograph of the neck of a 6-year-old boy shows ossifcation of dorsal soft tissues and ankylosis of all cervical apophyseal joints. B, AP radiograph of the shoulder of the same patient shows extensive soft tissue ossification. [From Avioli LV, Krane SM (eds): Metabolic Bone Disease and Clinically Related Disorders, 2nd ed. Philadelphia, WB Saunders Co, 1990.]

CHAPTER 24


725

FIGURE 24--34 Fibrodysplasia ossificans progressiva. AP radiograph of the pelvis of a 17-year-old boy shows extensive ossification about the right hip (note that the femoral head is dislocated and that the joint is ankylosed by the ossified periarticular tissue). [From Avioli LV, Krane SM (eds): Metabolic Bone Disease and Clinically Related Disorders, 2nd ed. Philadelphia, WB Saunders Co, 1990.]

E. Etiology and Pathogenesis F r a m e and colleagues suggested that axial osteomalacia is due to " u n k n o w n defects of local cellular origin. ''213 Electron microscopic studies of iliac crest tissue

FIGURE 24--36 Axial osteomalacia. Lateral radiograph of the lumbar spine of a 35-year-old man shows generalized osteosclerosis due to thickening of the trabeculae.

from one patient 214 s h o w e d osteoblasts with an inactive appearance, yet the presence of intact matrix vesicles within unmineralized osteoid. The possibility that this is a heritable disorder deserves further study. 214

F. Treatment

FIGURE 24--35 Fibrodysplasia ossificans progressiva. AP radiograph of the toes of a 9-year-old boy shows anomalies of the phalanges of the great toe. [From Avioli LV, Krane SM (eds): Metabolic Bone Disease and Clinically Related Disorders, 2nd ed. Philadelphia, WB Saunders Co, 1990.]

There is no effective medical therapy for axial osteomalacia. In one patient treated with stilbestrol and methyltestosterone, no i m p r o v e m e n t in s y m p t o m s or radiological features was noted. 217 Similarly, vitamin D2 therapy (as m u c h as 20,000 units/day for 3 years) resulted in no change in s y m p t o m s or radiographic pattern. 217 In a study of four cases, calcium and vitamin D2 therapy resulted in some small i m p r o v e m e n t in skeletal histology, but there was no s y m p t o m a t i c benefit; it was concluded that this treatment was of no practical value. 218 Since the s y m p t o m s and radiological findings in one patient did not change during an 18-year period, 217 and another patient r e m a i n e d well during 5 years of observation, 216 a relatively benign natural history for axial

726

MICHAEL P. WHYTE

FIGURE 24--37

Axial osteomalacia. AP radiograph of the pelvis of a 35-year-old man shows generalized osteosclerosis. (From Whyte MP, et al: Am J Med 71:1041 - 1049, 1981.)

osteomalacia seems possible. Treatment with vitamin D2 and mineral supplementation would seem risky, since the disorder appears to be due to a defect in the bone tissue itself, rather than in mineral homeostasis.

XIV. FIBROGENESIS IMPERFECTA OSSIUM Fibrogenesis imperfecta ossium, first described by Baker and Turnbull in 1950, 219 is a very rare condition. 219-228 In 1986, Lang and co-workers described one case and summarized the findings in six others. 228 Although radiological studies suggest a generalized decrease in bone mass, the coarse and dense appearance of trabeculae explain why it is discussed among the osteosclerotic disorders. Christman and colleagues, in 1981, reported three cases of axial osteomalacia and two cases of fibrogenesis imperfecta ossium and contrasted the clinical, biochemical, radiological, and histopathological features of both disorders. 216

life. Both men and women are affected. There is gradual onset of intractable skeletal pain and progressive immobility. The disease then runs a rapidly progressive and debilitating course, with spontaneous fractures being a prominent feature. Marked bony tenderness is usual. Patients generally become bedridden. One affected individual suffered acute agranulocytosis. 223 Another subject with radiological changes that simulated fibrogenesis imperfecta ossium had macroglobulinemia. 229

B. Laboratory Findings In fibrogenesis imperfecta ossium, serum levels of calcium and inorganic phosphate are normal; alkaline phosphatase activity is increased. Urinary levels of hydroxyproline may be normal or elevated. 228 There is generally no evidence of renal tubular dysfunction or aminoaciduria. Monoclonal gammopathy appears to be common. 226

C. Radiological Features A. Clinical Presentation Fibrogenesis imperfecta ossium is an acquired disorder that presents clinically in middle-age or late adult

The radiological features of fibrogenesis imperfecta ossium are found throughout the skeleton except in the skull. At first there may be only osteopenia and a slightly

CHAr~rER 24 Skeletal Disorders Characterized By Osteosclerosis or Hyperostosis abnormal appearance of trabecular bone. 228 Subsequently, the changes are generally consistent with osteomalacia; that is, alteration of the cancellous bone pattern, irregular bone density, and cortical thinning. Despite a generalized decrease in skeletal density, remaining trabeculae appear coarse and dense ("fishnet" pattern). Corticomedullary junctions then become indistinct, and cortices appear to be replaced by an abnormal trabecular pattern. A mixed lytic and sclerotic pattern may be present. 228 Pseudofractures can occur. Fracture deformities may be noted, although the contour of bones is generally normal. A "rugger jersey" spine is present in some patients and should not be confused with similar radiographic findings in patients with renal osteodystrophy. Periosteal reaction may occur along the shafts of long bones. The radiographic changes of fibrogenesis imperfecta ossium closely resemble those of axial osteomalacia; however, the disorders are distinguishable by different distributions of radiographic abnormalities

727

(generalized vs. axial). Furthermore, there are different histopathological findings. 218

D. H i s t o p a t h o l o g i c a l F i n d i n g s The basic lesion of fibrogenesis imperfecta ossium appears to be similar throughout the skeleton, but the amount of affected bone varies widely from site to site. Cortical bone (e.g., in the diaphyses of the femora and tibiae) may show the least abnormality. Osteoblasts and osteoclasts can be abundant, and osteoid seams are thick. There is an abnormal mineralization pattern. Tetracycline labeling reveals the presence of osteomalacia. 228 Characteristically, abnormal collagen is found where lamellar bone should be present (collagen in other tissues is unremarkable). On polarized light microscopy, bone collagen fibrils are not birefringent. Electron microscopy reveals them to be thin and randomly organized in a

FIGURE 24--38 Fluorosis. A, Lateral radiograph of the lower thoracic spine of an 82-year-old woman with osteoporosis shows demineralized vertebral bodies. B, Lateral radiograph of lower thoracic spine of the same patient, now age 87, shows mild osteosclerosis of vertebral bodies after five years of sodium fluoride therapy. [From Avioli LV, Krane SM (eds): Metabolic Bone Disease and Clinically Related Disorders, 2nd ed. Philadelphia, WB Saunders Co, 1990.]

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MICHAEL P. WHYTE

"tangled pattern," rather than in a lamellar distribution. 23~ Narrow and irregular bands of normal collagen fibrils may occasionally traverse regions of abnormal bone matrix. Only a few scattered areas of lamellar bone are noted. In some areas of abnormal matrix, unusual circular bodies of 300 to 500 nm diameter are present. 228 This abnormal bone matrix does not calcify properly, and wide osteoid seams are present. Unless biopsy specimens are viewed with polarized light or electron microscopy, this disorder may be mistaken for osteoporosis or the more common forms of osteomalacia. 228

F. T r e a t m e n t There is no effective medical therapy for fibrogenesis imperfecta ossium. Although the clinical course is generally one of deterioration, brief periods of clinical improvement c a n occur. 22s Vitamin D2 (or active metabolites) with calcium supplements has been tried without significant benefit. Calcification of soft tissues and of tendons and ligaments occurred in one patient who was treated with large doses of vitamin D2. Sodium fluoride, synthetic salmon calcitonin, and 24,25(OH)zD have also been used without apparent benefit. 228 Courses of melphalan and prednisone were followed by dramatic remission in one patient who had a monoclonal g a m m o p a t h y . 226,23~

E. E t i o l o g y a n d P a t h o g e n e s i s

XV. F L U O R O S I S The etiology of fibrogenesis imperfecta ossium is unknown. The disorder has been reported only sporadically and, therefore, genetic factors have not been implicated. Although any specific biochemical defect awaits discovery, the condition appears to be an acquired disorder of collagen synthesis in lamellar bone that, in some way, inhibits mineralization of the osseous matrix. Only the skeleton seems to be affected. There does not appear to be a defect in subperiosteal bone formation or in collagen in nonosseous tissues. In one patient who also had monoclonal gammopathy, a toxin produced by bone marrow was postulated. 226

FIGURE 24--39

Fluoride may cause osteosclerosis when ingested or inhaled chronically in various forlTlS. 231-234 Endemic fluorosis occurs in some regions (e.g., Punjab, India) from contaminated well water. 232 Men are more commonly affected than women, perhaps because their water consumption, as they perform manual labor, is greater. Leafy vegetables and tea grown in soil with a high content of fluoride, certain wines, and cooking salt represent other dietary sources of excessive amounts of fluoride. 234 However, fluorosis has also been reported as an occupational hazard, for example, in conjunction with alu-

Pachydermoperiostosis. Characteristic marked clubbing of the fingers of a 33-year-old man. [From Avioli LV, Krane SM (eds): Metabolic Bone Disease and Clinically Related Disorders, 2nd ed. Philadelphia, WB Saunders Co, 1990.]

CHAPTER 24 Skeletal Disorders Characterized By Osteosclerosis or Hyperostosis minum or fertilizer production. TM Prolonged administration of the nonsteroidal antiinflammatory agent niflumic acid, T M or sodium fluoride in attempted therapy for postmenopausal osteoporosis, 233 represent other potential etiologies.

A. Clinical Presentation Diffuse bone pain, stiffness, decreased joint mobility, and brownish discoloration and mottling of the teeth are the principal signs and symptoms in f l u o r o s i s . T M A "plantar fasciitis syndrome" characterized by painful and swollen feet has been described, but stress fracture of the calcaneus has been shown to be a likely cause of this discomfort. 235 Cranial nerve palsies, radiculopathies, and plexopathies can result from ligamentous calcification, exostoses, and osteophytoses.

B. Laboratory Findings Serum alkaline phosphatase activity may be increased in fluorosis, which could reflect osteoblast stimulation

729

by secondary hyperparathyroidism. Mineral balance studies have shown calcium retention. 236 Urinary hydroxyproline levels may be increased. Assay of fluoride in blood or urine can provide biochemical support for the diagnosis.

C. Radiological Features Fluorosis can result in osteosclerosis and radiographic changes consistent with osteomalacia. 235 In general, it is the cancellous portions of the skeleton that become sclerotic (Figs. 24-38). Characteristically, however, various ligaments also calcify. Irregularity at the insertion of muscles at the iliac spine and calcification of ligaments in the pelvis, vertebrae, and interosseous membranes are early radiological signs. 5 Later, there may be generalized osteosclerosis. Osteomalacia can develop, because fluoride stimulates osteoid synthesis, yet mineral deposition may be impaired. 237 In this circumstance, stress fractures in the proximal femur or calcaneus have been reported during fluoride therapy for osteoporosis. 235

D. Etiology and Pathogenesis Fluoride appears to cause osteosclerosis by a combination of mechanisms including direct stimulation of osteoblast mitogenic activity, formation of fluoroapatite crystals that are relatively resistant to osteoclastic resorption, and inducement of secondary hyperparathyroidism. 234'236'237

E. Treatment Treatment of fluorosis includes elimination of excessive intake of fluoride and, if osteomalacia is present, calcium and vitamin D supplementation to mineralize the fluoride-induced osteoidosis and to reduce the secondary hyperparathyroidism. 235

XVI. PACHYDERMOPERIOSTOSIS

FIGURE 24--40 Pachydermoperiostosis. PA radiograph of the hand of the patient shown in Figure 24-39 shows clubbing of the fingertips with associated hypertrophy of the distal phalangeal tufts (note also the widened tubular bones, particularly the middle phalangeal bases). [From Avioli LV, Krane SM (eds): Metabolic Bone Disease and Clinically Related Disorders, 2nd ed. Philadelphia, WB Saunders Co, 1990.]

Pachydermoperiostosis (hypertrophic osteoarthropathy: primary or idiopathic) was first described in 1868. 238 The condition is characterized by clubbing of the digits (Fig. 24-39), hyperhidrosis with thickening of the skin of especially the face and forehead, and periosteal new bone formation distally in the limbs. Autosomal dominant transmission with variable expression is established, 239 but autosomal recessive inheritance also appears to occur (McKusick 167100). 1

730

MICHAEL P. WHYTE A. C l i n i c a l P r e s e n t a t i o n

Men appear to be more severely affected by pachydermoperiostosis than are women, and blacks have it more often than others. 24~ Symptoms usually begin during adolescence, although earlier and later presentations have been reported. 239'24~ Some patients have all three major findings (pachyderma, cutis verticis gyrata, periostitis); others have one or two features. These abnormalities develop for about a decade and then become quiescent. 241 Gradual progressive enlargement of the hands and feet results in a paw-like appearance. Some patients appear to be acromegalic. 242 Often there are arthralgias of the ankles, knees, wrists, elbows, and occasionally, the small joints. Symptoms consistent with pseudogout may occur; chondrocalcinosis with calcium pyrophosphate crystals in synovial fluid has been reported in one patient. 243 Acroosteolysis has also been described. T M Stiffness and restricted motion of both appendicular and axial skeleton can occur. Cranial or spinal

nerves may be compressed. When there are cutaneous changes, they may include coarsening, thickening, furrowing, pitting, and oiliness of the skin of the face and scalp. Some patients fatigue easily. Myelophthisic anemia with extramedullary hematopoiesis may o c c u r . 245 Life expectancy appears to be n o r m a l . 24~

B. L a b o r a t o r y F i n d i n g s Synovial fluid in pachydermoperiostosis generally does not indicate inflammation.

C. R a d i o l o g i c a l F e a t u r e s Severe periostitis causing thickening of the distal aspect of tubular bones of the l i m b s - - e s p e c i a l l y the tibia, fibula, radius, and u l n a - - i s the major abnormality in pachydermoperiostosis. Clavicles, metacarpal, tarsal/

FIGURE 24--41 A, Pachydermoperiostosis. AP radiograph of the distal leg and ankle of the patient in Figure 24-39 shows extensive shaggy periosteal reaction along the interosseous membrane between the tibia and fibula (note also the extensive proliferative bone formation along the medial malleolus). B, Hypertrophicpulmonary osteoarthropathy. AP radiograph of the distal leg and ankle of a 30-year-old woman shows smooth, layered periosteal new bone formation along the medial aspect of the distal tibia [note that the medial malleolus (epiphysis) is not involved]. [From Avioli LV, Krane SM (eds): Metabolic Bone Disease and Clinically Related Disorders, 2nd ed. Philadelphia, WB Saunders Co, 1990.]

CHAPTER24 SkeletalDisorders Characterized By Osteosclerosis or Hyperostosis metatarsals, phalanges, pelvis, and base of the skull may also be affected. The spine is rarely involved. 5 Clubbing is apparent radiographically (Fig. 24-40). Sclerosis and expansion of the diaphyseal region of tubular bones resuits from periosteal thickening. These changes are widespread and symmetrical. In longstanding cases, ankylosis of joints--especially hands and f e e t - - m a y occur. 5 Acroosteolysis has also been reported with pachydermoperiostosis. 244,246 The major consideration in the differential diagnosis is secondary hypertrophic osteoarthropathy (pulmonary or otherwise). The radiological features are, however, somewhat different for primary and secondary disease. In pachydermoperiostosis, periosteal proliferation is more extreme, has an irregular appearance, and often extends to the epiphysis (Fig. 24-41A). In hypertrophic pulmonary osteoarthropathy, the periosteal reaction has a smoother, undulating appearance (Fig. 24-41B). 247 Skeletal scintigraphy in both conditions reveals regular and symmetrical diffuse uptake along the cortical mar-

731

gins of long bones, especially in the legs, which produces a "double-stripe" sign. 248

D. H i s t o p a t h o l o g i c a l F i n d i n g s Periosteal deposition of bone in pachydermoperiostosis results in a roughened cortical s u r f a c e . 249 The new bone undergoes cancellous compaction and may be difficult to distinguish from original cortex. 249 Synovial membrane shows mild cellular hyperplasia and thickening of subsynovial blood vessels. 25~ Electron microscopy shows a layered basement membrane.

E. E t i o l o g y and P a t h o g e n e s i s The genetic defect of pachydermoperiostosis is unknown. Blood flow is decreased to involved areas of bone in pachydermoperiostosis, but is increased in cases of secondary c l u b b i n g . 239'241'251'252 T h e arthralgias appear to stem from the associated periostitis. 253

XVII. HEPATITIS

C-ASSOCIATED

OSTEOSCLEROSIS In 1992, a new syndrome was characterized that features remarkably severe, developmental, generalized osteosclerosis and hyperostosis in hepatitis C-positive, former intravenous drug abusers. T M Periosteal, endosteal, and trabecular bone thickening occurs throughout the skeleton except in the cranium (Fig. 24-42). The forearms and legs are painful. Densitometric studies show bone mass that may be 200% to 300% above mean values for age and sex. Skeletal remodeling can be abnormally rapid and respond to calcitonin therapy. Gradual spontaneous remission in pain and normalization of bone remodeling may o c c u r . T M Tainted blood exposure is the common underlying history. 255 The etiology is unknown, but virus-induced stimulation of osteoblast function seems possible. T M

XVIII. OTHER DISORDERS

FIGURE 24--42 Hepatitis C-associated osteosclerosis. AP radiograph of the hip and proximal femur of this middle-aged man shows marked endosteal and periosteal bone formation and severe osteosclerosis characterized by thickened trabeculae.

As summarized in Tables 2 4 - 1 and 24-2, in addition to the primarily dysplastic osteosclerotic disorders discussed here, a relatively large number of other conditions result in either focal or generalized increases in skeletal mass. Although limitation of space does not permit a detailed discussion of these entities (the reader will find references 2 through 8 to be especially helpful

7

3

2

M

I

C

H

A

E

L

P. WHYTE

Acknowledgments This work was made possible by grant 15958 from Shriners Hospitals for Children and grant RR-00036 from the General Clinical Research Center Branch, Division of Research Facilities and Resources, National Institutes of Health.

References

FIGURE 2 4 - - 4 3 Disseminated prostatic carcinoma. Lateral radiograph of the lumbar spine of a 47-year-old man with widespread prostatic carcinoma shows characteristic radiodense vertebrae. Except for the margins of L3 (arrows), the osteosclerosis is quite uniform. [From Avioli LV, Krane SM (eds): Metabolic Bone Disease and Clinically Related Disorders, 2nd ed. Philadelphia, WB Saunders Co, 1990.]

sources

of information),

some

generalities

should be

noted. S a r c o i d o s i s o f the s k e l e t o n is t y p i c a l l y a s s o c i a t e d w i t h cystic and coarsely reticulated bone. Rarely, however, s c l e r o t i c l e s i o n s i n v o l v e t h e a x i a l s k e l e t o n o r l o n g tubular bones. T h e s e changes m a y occur well after the p u l m o n a r y d i s e a s e is a r r e s t e d . 256 A l t h o u g h m u l t i p l e m y e l o m a typically presents with generalized osteopenia or with osteolytic changes, widespread osteosclerosis can O c c u r . 257'258 L y m p h o m a , m y e l o s c l e r o s i s , a n d m a s t o c y t o sis a r e a d d i t i o n a l h e m a t o l o g i c a l c a u s e s o f i n c r e a s e d b o n e mass.

Metastatic

carcinomamprimarily

24-43)mcommonly

causes

prostate

osteosclerosis.

(Fig.

Osteoscle-

r o s i s is a t y p i c a l r a d i o l o g i c a l f e a t u r e o f P a g e t ' s b o n e

disease. 259 Diffuse osteosclerosis is also a relatively frequent radiographic finding in secondary hyperparathy-

roidism (as with renal disease), but can occur in primary hyperparathyroidism a s w e l l . 26~ Intoxication with either vitamin

A 261 o r D , 262

heavy metal poisoning, 263 milk-

alkali s y n d r o m e , 264 i o n i z i n g r a d i a t i o n , 265 o s t e o m y e l i t i s , 265 a n d o s t e o n e c r o s i s 2'5 are a d d i t i o n a l e t i o l o g i c a l f a c t o r s (Table 24-1

and 24-2).

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CHAPTER 24


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177. Applebaum RE, Caniano DA, Sun C-C, et al: Synchronous left subclavian and axillary artery aneurysms associated with melorheostosis. Surgery 99:249-153, 1986. 178. Fryns J-P: Melorheostosis and somatic mosaicism (letter). Am J Med Genet 58:199, 1995. 179. Muller SA, Henderson ED: Melorheostosis with linear scleroderma. Arch Dermatol 88:142-145, 1963. 180. Younge D, Drummond D, Herring J, et al: Melorheostosis in children: Clinical features and natural history. J Bone Joint Surg 61B:415-418, 1979. 181. Colavita N, Nicolais S, Orazi C, Falappa PG: Melorheostosis: Presentation of a case followed up for 24 years. Arch Orthop Trauma Surg 106:123-125, 1987. 182. Campbell CJ, Papademetriou T, Bonfiglio M: Melorheostosis: A report of the clinical, roentgenographic, and pathological findings in fourteen cases. J Bone Joint Surg 50A: 1281-1304, 1968. 183. Janousek J, Preston DF, Martin NL, et al: Bone scan in melorheostosis. J Nucl Med 17:1106-1108, 1976. 184. Wagers LT, Young AW Jr, Ryan SF: Linear melorheostotic scleroderma. Br J Dermatol 86:297-301, 1972. 185. Semble EL, Poehling GG, Prough DS, et al: Successful symptomatic treatment of melorheostosis with nifedipine. Clin Exp Rheumatol 4:277-280, 1986. 186. Walker GF: Mixed sclerosing bone dystrophies. J Bone Joint Surg 46B:546-552, 1964. 187. Abrahamson MN: Disseminated asymptomatic osteosclerosis with features resembling osteopoikilosis and osteopathia striata. J Bone Joint Surg 50A:991-996, 1968. 188. Ewald FC: Unilateral mixed sclerosing bone dystrophy associated with unilateral lympangiectasis and capillary haemangioma. J Bone Joint Surg 54A:878-880, 1972. 189. Kanis JA, Thompson JG: Mixed sclerosing dystrophy with regression of melorheostosis. Br J Radiol 48:400-402, 1975. 190. Whyte MP, Murphy WA, Fallon MD, et al: Mixed-sclerosingbone dystrophy: Report of a case and review of the literature. Skeletal Radiol 6:95-102, 1981. 191. Pacifici R, Murphy MA, Teitelbaum SL, et al: Mixed-sclerosingbone-dystrophy: 42-year follow-up of a case reported as osteopetrosis. Calcif Tissue Int 38:175-185, 1986. 192. Connor JM, Beighton P: Fibrodysplasia ossificans progressiva in South Africa: Case reports. S Afr Med J 61:404-406, 1982. 193. Rogers JG, Geho WB: Fibrodysplasia ossificans progressiva: A survey of forty-two cases. J Bone Joint Surg 61A:909-914, 1979. 194. Connor JM, Evans DAP: Fibrodysplasia ossificans progressiva: The clinical features and natural history of 34 patients. J Bone Joint Surg 64B:76-83, 1982. 195. Shah PB, Zasloff MA, Drummond D, et al: Spinal deformity in patients who have fibrodysplasia ossificans progressiva. J Bone Joint Surg 76A:1442-1450, 1994. 196. Fox S, Khoury A, Mootabar H, Greenwald EF: Myositis ossificans progressiva and pregnancy. Obstet Gynecol 69:453-455, 1987. 197. Cremin B, Connor JM, Beighton P: The radiological spectrum of fibrodysplasia ossificans progressiva. Clin Radiol 33:499508, 1982. 198. Thickman D, Bonakdar A, Clancy M, et al: Fibrodysplasia ossificans progressiva. Am J Roentgenol 139:935-941, 1982. 199. Kaplan FS, Tabas JA, Zasloff MA: Fibrodysplasia ossificans progressiva: A clue from the fly? Calcif Tissue Int 47:117-125, 1990. 200. Voynow JA, Charney EB: Fibrodysplasia ossificans progressiva presenting as osteomyelitis-like syndrome. Clin Pediatr 25: 373-375, 1986.

CHAPTER 24


201. Fang MA, Reinig JW, Hill SC, et al: Technetium-99m MDP demonstration of heterotopic ossification in fibrodysplasia ossificans progressiva. Clin Nucl Med 11:8-9, 1986. 202. Sumiyoshi K, Tsuneyoshi M, Enjoji M: Myositis ossificans. A clinicopathologic study of 21 cases. Acta Pathol Jpn 35:11091122, 1985. 203. Maxwell WA, Spicer SS, Miller RL, et al: Histochemical and ultrastructural studies in fibrodysplasia ossificans progressiva (myositis ossificans progressiva). Am J Pathol 87:483-498, 1977. 204. Kaplan FS, Tabas JA, Gannon FH, et al: The histopathology of fibrodysplasia ossificans progressiva: An endochondral process. J Bone Joint Surg 75A:220-230, 1993. 205. Reinig JW, Hill SC, Fang M, et al: Fibrodysplasia ossificans progressiva: CT appearance. Radiology 159:153-157, 1986. 206. Cramer SF, Ruehl A, Mandel MA: Fibrodysplasia ossificans progressiva. Cancer 48:1016-1021, 1981. 207. Rogers JG, Chase GA: Paternal age effect in fibrodysplasia ossificans progressiva. J Med Genet 16:147-148, 1979. 208. Lutwak L: Myositis ossificans progressiva: Mineral, metabolic, and radioactive calcium studies of the effects of hormones. Am J Med 37:269-293, 1964. 209. Shafritz AB, Shore EM, Gannon FH, et al: Overexpression of an osteogenic morphogen in fibrodysplasia ossificans progressiva. N Engl J Med 335:551-561, 1996. 210. Smith R: Myositis ossificans progressiva: A review of current problems. Semin Arthritis Rheum 4:369-380, 1975. 211. Smith R, Russell RGG, Woods CG: Myositis ossificans progressiva: Clinical features of eight patients and their response to treatment. J Bone Joint Surg 58B:48-57, 1976. 212. Moore SE, Jump AA, Smiley JD: Effect of warfarin sodium therapy on excretion of 4-carboxy-L-glutamic acid in scleroderma, dermatomyositis, and myositis ossificans progressiva. Arthritis Rheum 29:344-351, 1986. 213. Frame B, Frost HM, Ormond RS, et al: Atypical axial osteomalacia involving the axial skeleton. Ann Intern Med 55:632639, 1961. 214. Whyte MP, Fallon MD, Murphy WA, et al: Axial osteomalacia: Clinical, laboratory and genetic investigation of an affected mother and son. Am J Med 71:1041 - 1049, 1981. 215. Arnstein AR, Frame B, Frost HM: Recent progress in rickets and osteomalacia. Ann Intern Med 67:1296-1330, 1967. 216. Christman D, Wenger JJ, Dosch JC, et al: L'osteomalacie axiale analyse comparee avec la fibrogenese imparfaite. J Radiol 62: 37-41, 1981. 217. Condon JR, Nassim JR: Axial osteomalacia. Postgrad Med J 47: 817-820, 1971. 218. Nelson AM, Riggs BL, Jowsey JO: Atypical axial osteomalacia: Report of four cases with two having features of ankylosing spondylitis. Arthritis Rheum 21:715-722, 1978. 219. Baker SL, Turnbull HM: Two cases of hitherto undescribed disease characterized by a gross defect in the collagen of the bone matrix. J Pathol Bacteriol 62:132-134, 1950. 220. Baker SL, Dent CE, Friedman M, et al: Fibrogenesis imperfecta ossium. J Bone Joint Surg 48B:804-825, 1966. 221. Thomas WC Jr, Moore T: Fibrogenesis imperfecta ossium. Trans Am Clin Climatol Assoc 80:54-62, 1968 222. Goldring FC: Fibrogenesis imperfecta. J Bone Joint Surg 50B: 619-622, 1968. 223. Golde D, Greipp P, Sanzenbacher L, et al: Hematologic abnormalities in fibrogenesis imperfecta ossium. J Bone Joint Surg 53A:365, 1971. 224. Frame B, Frost HM, Pak CYC, et al: Fibrogenesis imperfecta ossium, a collagen defect causing osteomalacia. N Engl J Med 285:769-772, 1971.

737

225. Swam CHJ, Shah K, Brewer DB, et al: Fibrogenesis imperfecta ossium. Q J Med 45:233-253, 1976. 226. Stamp TCB, Byers PD, Ali SY, et al: Fibrogenesis imperfecta ossium: Remission with melphalan. Lancet 1:582-583, 1985. 227. Byers PD, Stamp TCB, Stoker D J: Fibrogenesis imperfecta (case report 296). Skeletal Radiol 13:72-76, 1985. 228. Lang R, Vignery AM, Jensen PS: Fibrogenesis imperfecta ossium with early onset: Observations after 20 years of illness. Bone 7:237-246, 1986. 229. Stanley P, Baker SL, Byers PD: Unusual bone trabeculation in a patient with macroglobulinaemia simulating fibrogenesis imperfecta ossium. Br J Radiol 44:305-313, 1971. 230. Ralphs JR, Stamp TCB, Dopping-Hepenstal PJC, Ali-SY: U1trastructural features of the osteoid of patients with fibrogenesis imperfecta ossium. Bone 10:243-249, 1989. 231. Roholm K: Fluorine Intoxication. London, HK Lewis, 1937. 232. Jolly SS, Singh BM, Mathur OC: Endemic fluorosis in Punjab (India). Am J Med 47:553-563, 1969. 233. Vischer TL (ed): Fluoride in Medicine. Bern, Hans Huber, 1970. 234. Krishnamachari KAVR: Skeletal fluorosis in humans: A review of recent progress in the understanding of the disease. Prog Food Nutr Sci 10:279- 314, 1986. 235. Schnitzler CM, Solomon L: Histomorphometric analysis of a calcaneal stress fracture: A possible complication of fluoride therapy for osteoporosis. Bone 7:193-198, 1986. 236. Srikantia SG, Siddiqu AH: Metabolic studies in skeletal fluorosis. Clin Sci 28:477-485, 1965. 237. Kanis JA, Meunier PJ: Should we use sodium fluoride to treat osteoporosis? A review. Q J Med 53:145-164, 1984. 238. Friedreich N: Hyperostose des gesammten Skelettes. Virchows Arch [Pathol Anat] 43:83-87, 1868. 239. Rimoin DL: Pachydermoperiostosis (idiopathic clubbing and periostosis). Genetic and physiologic consideration. N Engl J Med 272:923-931, 1965. 240. Matucci-Cerinic M, Lott T, Jajic IVO, et al: The clinical spectrum of pachydermoperiostosis (primary hypertrophic osteoarthropathy). Medicine 79:208- 214, 1991. 241. Herman MA, Massaro D, Katz S: Pachyderm~176176 ical spectrum. Arch Intern Med 116:919- 923, 1965. 242. Harbison JB, Nice CM Jr: Familial pachydermoperiostosis presenting as an acromegaly-like syndrome. Am J Roentgenol Radium Ther Nucl Med 112:532-536, 1971. 243. Appelboom T, Busscher H, Famaey JP: Chondrocalcinosis as a possible cause of arthritis in pachydermoperiostosis (letter). Arthritis Rheum 21:174, 1978. 244. Guyer PB, Brunton FJ, Wren MWG: Pachydermoperiostosis with acro-osteolysis: A report of five cases. J Bone Joint Surg 60B:219-223, 1978. 245. Neiman HL, Gompels BM, Martel W: Pachydermoperiostosis with bone marrow failure and gross extramedullary hematopoiesis. Report of a case. Radiology 110:553-554, 1974. 246. Hedayati H, Barmada R, and Skosey JL: Acrolysis in pachydermoperiostosis (primary or idiopathic hypertropic osteoarthropathy). Arch Intern Med 140:1087-1088, 1980. 247. Ali A, Tetalman M, Fordham EW: Distribution of hypertrophic pulmonary osteoarthropathy. Am J Roentgenol 134:771-780, 1980. 248. DeVries N, Datz FL, Manaster BJ: Case report 399: Pachydermoperiostosis (primary hypertrophic osteoarthropathy). Skeletal Radiol 15:658-662, 1986. 249. Vogl A, Goldfischer S: Pachydermoperiostosis: Primary or idiopathic hypertrophic osteoarthropathy. Am J Med 33:166-187, 1962. 250. Lauter SA, Vasey FB, Htittner I, et al: Pachydermoperiostosis: Studies on the synovium. J Rheumatol 5:85-95, 1978.

7

3

8

M

I

C

251. Fam AG, Chin-Sang H, Ramsay CA: Pachydermoperiostosis: Scintigraphic, thermographic, plethysmographic, and capillaroscopic observations. Ann Rheum Dis 42:98-102, 1983. 252. Kerber RE, Vogl A: Pachydermoperiostosis: Peripheral circulatory studies. Arch Intern Med 132:245-248, 1973. 253. Cooper RG, Freemont AJ, Riley M, et al: Bone abnormalities and severe arthritis in pachydermoperiostosis. Ann Rheum Dis 51:416-419, 1992. 254. Whyte MP, Teitelbaum SL, Reinus WR: Doubling skeletal mass during adult life: The syndrome of diffuse osteosclerosis after intravenous drug abuse. J Bone Miner Res 11:554-558, 1996. 255. Whyte MP, Reasner CA: Hepatitis C-associated osteosclerosis after blood transfusion. Am J Med 102:219-220, 1997. 256. Abdelwahab IF, Norman A: Osteosclerotic sarcoidosis. AJR Am J Roentgenol 150:161 - 162, 1988. 257. Shim MS, Mowry RW, Bodie FL: Osteosclerosis (punctate form) in multiple myeloma. South Med J 72:226-228, 1979. 258. Edelman RR, Kaufman H, Kolodny G: Case report 350. Skeletal Radiol 15:160-163, 1986.

H

A

E

L

P. WHYTE

259. Hamdy RC: Paget's Disease of Bone: Assessment and Management. East Sussex, UK, Praeger Publishers, 1981. 260. Van Holsbeeck M, Roex L, Favril A, et al: Osteosclerosis in primary hyperparathyroidism. Fortschr R/3ntgenstr 147:690691, 1987. 261. Frame B, Jackson CE, Reynolds WA, Umphrey JE: Hypercalcemia and skeletal effects in chronic hypervitaminosis A. Ann Intern Med 80:44-48, 1974. 262. Dewind LT: Hypervitaminosis D with osteosclerosis. Arch Dis Child 36:373-380, 1961. 263. Murphy WA, Seligman PA, Tillack T, et al: Osteosclerosis, osteomalacia, and bone marrow aplasia: A combined late complication of thorotrast administration. Skeletal Radiol 3:234-238, 1979. 264. Punsar S, Somer T: The milk-alkali syndrome. A report of three illustrative cases and a review of the literature. Acta Med Scand 173:435-449, 1963. 265. Jacobsson S, Hollender L, Lindberg S, Lansson A: Chronic sclerosing osteomyelitis of the mandible. Scintigraphic and radiographic findings. Oral Surg 45:167-174, 1978.

~ H A P T E R 2.

Kidney Stones: Pathogenesis, Diagnosis and Therapy CHARLES

I. II. III. IV. V.

Y. C . P A K

University of Texas Southwestern Medical Center at Dallas, Dallas, Texas 75235

Introduction Hypercalciuria Hyperuricosuria Hyperoxaluria Hypocitratufia

VI. VII. VIII. IX.

patients with appropriate medical treatments. 5 Third, most renal stones are spontaneously passed and may not require intervention for their removal. However, spontaneous stone passage is often associated with severe colic; this morbidity could be averted by medical prevention of new stone formation. Fourth, medical treatment could potentially correct extrarenal manifestations of the stone disease, 5 whereas surgical approach concentrates on stone removal alone. This chapter reviews advances in the medical area. Each of the principal causes of stone disease is discussed separately, with consideration of pathophysiology, diagnostic criteria, and medical prevention.

I. I N T R O D U C T I O N A. Current Status of the Field The recent introduction of extracorporeal shock wave lithotripsy I and nephrostolithotomy 2 have revolutionized the treatment of nephrolithiasis. Most stones can now be removed with greater ease and less morbidity. Because of these improved methods of stone removal, there has been a tendency to disparage the need for medical diagnosis and treatment. 3 However, it is clear that the medical approach cannot be ignored if ultimate control of nephrolithiasis is to be achieved. First, there is no evidence that removal of stones, no matter how easily achieved, would prevent recurrence of stones. Following lithotripsy, urinary biochemical abnormalities persist and stone formation recurs. 4 Second, it is now possible to identify the cause of stone formation in the vast majority of patients and to inhibit new stone formation in most METABOLIC BONE DISEASE

Gouty Diathesis Cystinuria Infection with Urea-Splitting Organisms Conservative Management References

B. Epidemiology and Chemical Composition Nephrolithiasis is common, affecting 1% to 5% of the population in the industrialized countries, with an annual incidence of 0.1% to 0.3%. Stones originating in the

739


740

CHARLES Y. C. PAK

bladder are rare in industrialized countries except in association with a foreign body (e.g., indwelling catheter), although they were common in antiquity. In industrialized countries, most stones are calcareous stones, composed mainly of calcium oxalate occurring alone (35% of all stones) or in combination with hydroxyapatite (35%). The remaining calcareous stones (5%) are represented by those composed principally of hydroxyapatite or brushite (CaHPO4-2H20). Noncalcareous stones, comprising up to 25% of all stones, are composed of uric acid, magnesium ammonium phosphate, cystine, and rarely xanthine, sodium urate, 2,8dihydroxyadenine, or triamterene. Stones composed principally of calcium oxalate are generally more common in men than in women, with a particular susceptibility for middle-aged, white men. Struvite stones and predominantly calcium phosphate stones are more common in women. Chemical composition of the stone may sometimes provide the diagnosis (e.g., cystine stones for cystinuria, struvite stones for urinary tract infection with urea-splitting organisms, and uric acid stones for gouty diathesis). The finding of calcium phosphate as the predominant phase suggests the diagnosis of distal renal tubular acidosis or primary hyperparathyroidism. However, the identification of the most common, calcium oxalate stones, has a limited diagnostic value, since they could result from a wide variety of metabolic and environmental disturbances.

C. Diagnostic Separation Based on "Physiological" Derangements It is known that patients with renal calculi suffer from a wide variety of physiological disturbances, 6 which are believed to be pathogenetically important in stone formation. It is presumed that these physiological disturbances could result from environmental influences as well as from metabolic factors (of hormonal or genetic origin). These derangements have served as the basis of a refined classification of nephrolithiasis 7 and a more rational approach to medical treatment. 8 According to this classification scheme (Table 25-1), calcareous renal calculi are due to hypercalciuria, hyperuricosuria, hyperoxaluria, inhibitor deficiency (hypocitraturia), and gouty diathesis. Noncalcareous calculi result from gouty diathesis, cystinuria, and urinary tract infection (with urea-splitting organisms). Some of these derangements are heterogeneous in origin. Thus, hypercalciuria may be due to an excessive intestinal calcium absorption, renal calcium leak, or excessive bone resorption. In the category of inhibitor deficiency, hypocitraturia will be described in detail, because of increasing rec-

TABLE 2 5 - 1

Classification of Nephrolithiasis

Calcareous Renal Calculi

Hypercalciuria Absorptive Renal Resorptive Hyperuricosuria Primary urate overproduction Dietary purine overindulgence Hyperoxaluria Primary Secondary Inhibitor deficiency Hypocitraturia Other Gouty diathesis Noncalcareous Renal Calculi

Gouty diathesis Uric acid stones Cystinuria Cystine stones Infection with urea-splitting organisms Struvite stones

ognition of its importance in stone formation. Other simple (small molecular weight) and complex (macromolecular) inhibitors of the crystallization of calcium salts have been identified in urine, including pyrophosphate, 9 glycopeptides, 1~ nephrocalcin, 11 glycosaminoglycans, 12 ribonucleic acids, and uropontins. ~3 Each cause of nephrolithiasis will now be considered in toto from the perspective of pathophysiology, diagnosis, and treatment.

II. HYPERCALCIURIA A. Causal Role of Hypercalciuria in Calcium Stone Formation Hypercalciuria could cause or contribute to calcium stone formation by the following mechanisms. First, it increases the saturation of urine with respect to stoneforming calcium salts. There is a direct correlation between urinary saturation of calcium oxalate or brushite and urinary calcium concentration. 14 Although a rise in urinary calcium may reduce the ionic oxalate through increased complexation of oxalate, this effect is generally less prominent than the increase in ionic calcium. Second, hypercalciuria induced by a high calcium intake raises the urinary saturation of calcium salts. 15 Despite suggestions to the contrary, the opposing effect of the reduction in urinary oxalate from binding by calcium in the intestinal tract is modest. Third, hypercalciuria re-

CHAPTER25 Kidney Stones: Pathogenesis, Diagnosis, and Therapy duces the urinary inhibitor activity against the crystallization of calcium salts through binding or inactivation of negatively charged inhibitors. 16 Fourth, persistent hypercalciuria is one of the most important determinants of continued stone formation during therapy. 17 Finally, correction of hypercalciuria by administration of thiazide or sodium cellulose phosphate restores the normal urinary physicochemical environment TM and retards the formation of new stones. 19 The etiological role of high urinary calcium concentration should not be confused with that of a high calcium intake. In stone-forming patients with normal intestinal calcium transport, a high-calcium diet may produce only a modest and transient hypercalciuria, because of intestinal adaptation reflected by a fall in calcium absorption from suppressed synthesis of parathyroid hormone (PTH) and calcitriol. 2~ In patients with absorptive hypercalciuria, however, a sustained marked hypercalciuria may ensue from the loss of intestinal adaptation. 2~

B. P a t h o p h y s i o l o g y o f H y p e r c a l c i u r i a The association of hypercalciuria with calcium nephrolithiasis has long been recognized. The term "idiopathic hypercalciuria" has been used to denote this entity. 22 The recent progress in pathophysiological elucidation mandates that this term be discarded. Our own view is to consider hypercalciuria of nephrolithiasis to comprise several entities of heterogeneous origin. This approach permits incorporation of prevailing major theories of hypercalciuria.

1. ABSORPTIVE HYPERCALCIURIA (FIG. 25-1) The primary abnormality in absorptive hypercalciuria is intestinal hyperabsorption of calcium. The consequent increase in the circulating concentration of calcium augments the renal filtered load and suppresses parathyroid function. Hypercalciuria ensues from the increased filtered load and the reduced tubular reabsorption of calcium associated with suppression of PTH secretion. The excessive renal loss of calcium compensates for the high calcium absorption from the intestinal tract and helps to maintain serum calcium concentration in the normal range. Absorptive hypercalciuria is heterogeneous and may be broadly categorized into vitamin D-independent and vitamin D-dependent subvariants. The former may be a primary jejunal abnormality, 23'24 because the high calcium absorption has been observed only in the jejunum and the absorption of magnesium and phosphate is normal. Moreover, the restoration of normal serum 1,25dihydroxyvitamin D [1,25(OH)2D] by ketoconazole does

741 not correct the exaggerated intestinal absorption or renal excretion of calcium. 25 In vitamin D-dependent absorptive hypercalciuria, there may be calcitriol overproduction or hypersensitivity. Ketoconazole therapy completely or partially corrects the hyperabsorption of calcium and hypercalciuria. 25 Calcitriol overproduction is supported by the finding of high serum 1,25(OH)2D concentration 26'27 and of accelerated calcitriol synthesis in vivo in some patients. 28'29 This subvariant may include hypophosphatemic absorptive hypercalciuria. Hypophosphatemia ensuing from renal phosphate leak is thought to cause intestinal hyperabsorption of calcium by stimulating the renal synthesis of 1,25(OH)2D. 3~ However, hypophosphatemia is uncommonly found and the full spectrum of this entity is rarely encountered in stone-forming patients. 31 Hypersensitivity to vitamin D is supported by the state of intestinal hyperabsorption of calcium in patients with normal circulating concentration of calcitriol, where ketoconazole challenge restores normal calcium absorption. 25 It resembles the state of up-regulation of the vitamin D receptor, produced by long-term treatment with 1,25(OH)2D in normal subjects. 32 Fasting urinary calcium may be high in some patients with absorptive hypercalciuria. In most of them, it is probably due to the incomplete renal clearance of excessively absorbed calcium. 33 Suppressed parathyroid function from increased intestinal absorption of calcium may contribute to fasting hypercalciuria by impairing renal tubular reabsorption of calcium. In some of them, fasting hypercalciuria may reflect the resorptive action of bone of vitamin D excess or hypersensitivity. 34 Some patients with absorptive hypercalciuria may show evidence of excessive bone loss. Spinal bone density may be depressed, although radial shaft density is generally normal. 35 Calcium balance may be negative. 36 The exact cause for bone loss is not known. It may be related to vitamin D excess or hypersensitivity. However, the available evidence does not indicate that the abnormality in absorptive hypercalciuria is attributable to mutations of the vitamin D receptor or is linked to a common vitamin D receptor genotype. 37 2. RENAL HYPERCALCIURIA The primary abnormality in renal hypercalciuria is believed to be the impairment of the renal tubular reabsorption of calcium (Fig. 25-1). The consequent reduction in the circulating concentration of calcium stimulates parathyroid function. There may be an excessive mobilization of calcium from bone and an enhanced intestinal absorption of calcium because of the PTH excess and the ensuing stimulation of the renal synthesis of 1,25(OH)2D. These effects restore serum calcium to-

742

CHARLES Y. C. PAK

Absorptive Hypercalciuria

I'~ Ca Absorption ] "~

I "~Serum Ca I ~, I

I* H.I

I u ,~

]

Renal Hypercalciuria

I§

I --~ I +serumCa I # !

~ . ,

,

I§ Ca Absorption ]

Resorptive Hypercalciuria

I~'PTHI ~-~ I~'BoneResorptionl ~-~ I-~SerumCal ~ """-~

1~"1,25-(OH)2D I ~

I~ UrinaryCa !

[+ Ca Absorption I

FIGURE 25--l Schemesfor absorptive hypercalciuria type I and type II, renal hypercalciuria, and resorptive hypercalciuria. Dashed line indicates compensatory inhibition. [From Pak CYC: Kidney Stones. In Foster SW, Wilson J (eds): Williams Textbook of Endocrinology. Philadelphia, WB Saunders Co, 1985.]

ward normal. Unlike primary hyperparathyroidism, serum calcium is normal, and the state of hyperparathyroidism is secondary. Some patients with hypercalciuric nephrolithiasis, albeit a minority in most series, have been shown to have biochemical presentation supporting operation of this scheme. The occurrence of high serum PTH or urinary cyclic adenosine monophosphate (cAMP), and elevated serum 1,25(OH)zD and intestinal calcium absorption, have been shown in such patients in the setting of normal serum calcium and fasting hypercalciuria (indicative of renal calcium l e a k ) . 26 The correction of renal calcium leak by thiazide restores normal serum 1,25(OH)zD and fractional calcium absorption commensurate with the correction of hyperparathyroidism. 38 These findings support the contention that 1,25(OH)zD synthesis is enhanced from secondary parathyroid stimulation and that intestinal calcium absorption is high owing to 1,25(OH)zD excess. The occurrence of a primary renal calcium leak is supported by three lines of evidence. First, fasting hypercalciuria is associated with parathyroid stimulation and is poorly corrected by the inhibition of intestinal calcium absorption (and removing the effect of absorbed calcium) with sodium cellulose phosphate. 33 Second, there is a unique natriuretic response to thiazide. When thiazide is given to block reabsorption of calcium and

sodium in the distal renal tubule, impaired proximal tubular function would be manifested as an exaggerated renal excretion of these cations. ! n our study, the exaggerated natriuretic and calciuric response to hydrochlorothiazide was encountered only in patients with documented renal hypercalciuria with secondary hyperparathyroidism. 39 Third, an exaggerated calciuric response to 100 g of glucose was encountered in patients with renal hypercalciuria with secondary hyperparathyroidism, not in those with absorptive hypercalciuria. 4~ Ingestion of readily metabolizable carbohydrate (without calcium) normally augments renal calcium excretion, believed to be due to an alteration in renal proximal tubular function. 41 It has been suggested that renal calcium leak is secondary to an excessive dietary intake of sodium. 42 However, in one preliminary study, institution of a low sodium intake (9 mEq/day) did not eliminate fasting hypercalciuria in patients with renal hypercalciuria. That renal calcium leak (and secondary hyperparathyroidism) had been longstanding is shown by changes disclosed in bone density. Although clinical bone disease is rare, bone density as measured by photon absorptiometry in the distal third of the radius is reduced in the group with renal hypercalciuria (as compared with age- and 43 sex-matched controls). These results indicate that secondary hyperparathyroidism exerts deleterious effects on

CHAPTER 25

743

Kidney Stones: Pathogenesis, Diagnosis, and Therapy

urinary calcium in normocalciuric patients with nephrolithiasis but not in normal subjects.

the skeleton. The lack of a more serious involvement is probably due to the compensatory intestinal hyperabsorption of calcium that results from the PTH-induced renal synthesis of 1,25(OH)zD. This compensation is often inadequate, since urinary calcium usually exceeds absorbed calcium indicative of negative calcium balance.

C. D i a g n o s t i c Criteria (Table 2 5 - 2 )

3. RESORPTIVE HYPERCALCIURIA Resorptive hypercalciuria (Fig. 25-1) is characterized by primary hyperparathyroidism. The initial event is excessive resorption of bone resulting from hypersecretion of PTH. Intestinal absorption of calcium is frequently elevated because of PTH-dependent stimulation of renal synthesis of 1,25(OH)zD. 27 These effects increase the circulating concentration and the renal filtered load of calcium. The occurrence of hypercalciuria in primary hyperparathyroidism seems paradoxical, since the primary renal effect of PTH is to stimulate tubular reabsorption of calcium. However, hypercalciuria is often encountered in primary hyperparathyroidism because PTHdependent augmentation of renal tubular reabsorption of calcium is "overcome" by an increase in the renal filtered load and by a suppressive effect of hypercalcemia on calcium reabsorption. There are other causes of resorptive hypercalciuria associated with nephrolithiasis. Excessive bone resorption from oncogenic hypercalcemia, thyrotoxicosis, and sarcoidosis occasionally result in stone formation. Enhanced renal excretion of prostaglandin E2 has been reported in patients with hypercalciuric nephrolithiasis. 44 Treatment with inhibitors of prostaglandin synthesis corrected the hypercalciuria in such patients and reduced

TABLE 2 5 - 2

Absorptive hypercalciuria type 17 is characterized by normal serum calcium and phosphorus, slightly high or normal fasting urinary calcium [ 5 mM/mg (> 0.2 mg/mg) creatinine], normal or suppressed parathyroid function (normal serum immunoreactive PTH) and high urinary calcium level for a restricted diet [10 mM (400 mg) calcium and 100 mM sodium/day] of more than 5 mM/day (200 mg/day). These values reflect increased intestinal calcium absorption, resulting parathyroid suppression, and hypercalciuria. Spinal bone density may be low in some patients, 35 although radial shaft bone density is generally normal. 43 Absorptive hypercalciuria type II 7 is characterized by the same biochemical features as type I except for normal urine calcium [< 5 mM/day (< 200 mg/day)] for a restricted diet of 10 mM (400 mg) calcium and 100 mM sodium/day. If these patients are placed on a diet of 25 mM/day (1000 mg/day) calcium and 100 mM/day sodium, urinary calcium exceeds 0.1 mM/kg body weight/ day (4 mg/kg/day) or 6 mM/day (250 mg/day). Renal hypercalciuria 7 has the following features: normal serum calcium, high fasting urinary calcium of greater than 0.03 mM/liter glomerular filtrate (> 0.11 mg/dl glomerular filtrate), and enhanced parathyroid ac-

Diagnostic Criteria a

Serum

AH-I AH-II RH HUCU EH Hypocit RTA Gouty diathesis Struvite stones

Urinary

Ca

P

PTH

1,25

Ca Fasting

Ca Load

Ca Restricted

UA

Ox

Cit

pH

oL

N N N N N/$ N N N N

N N N N N/$ N N N N

N N "]" N N/'I" N N/I" N N

N/l" N/q" 1" N N N N N N

N/q" N 1" N $ N 1" N N

1" 1" 1" N $ N N N N/q"

1" N 1" N $ N N/q" N N/l"

N N N 1" $ N N N/$ N

N N N N 1" N N N N

N N N N $ $ $ N $

N N N N N N N/q" $ 1"

1" "I'/N 1" N $ N $ N N

aFasting samples represent 2-hour collections obtained in morning following an overnight fast. Ca load samples were obtained over a 4-hour period subsequent to oral ingestion of 1 g Ca. Fractional Ca absorption (o0 was obtained from fecal recovery of radioactivity following oral administration of radiocalcium with 100 mg Ca. PTH, immunoreactive parathyroid hormone; 1", high; $, low; N, normal; 1,25, 1,25(OH)2D; UA, uric acid; Ox, oxalate; Cit, citrate; AH-I, absorptive hypercalciuria type I; AH-II, absorptive hypercalciuria type II; RH, renal hypercalciuria; HUCU, hyperuricosuric calcium nephrolithiasis; EH, enteric hyperoxaluria; Hypocit, idiopathic hypocitraturic calcium nephrolithiasis; RTA, incomplete renal tubular acidosis.

744

CHARLES Y. C. PAK

tivity (high serum immunoreactive PTH). These results indicate a renal leak of calcium with compensatory parathyroid stimulation. Evidence of parathyroid stimulation (high serum PTH) is critical for the diagnosis of renal hypercalciuria. Radial shaft bone density may be low in patients with renal hypercalciuria. 43 Primary hyperparathyroidism is characterized by hypercalcemia, hypophosphatemia, hypercalciuria, and increased or inappropriately high serum PTH. Bone density in the radial diaphysis is often low. 43 Hypercalcemic symptoms, peptic ulcer, or bone disease (osteitis, pathological fractures, osteoporosis) may be present. Reduced density of femoral neck and spine is encountered less commonly. 45

D. Treatment of Hypercalciuric Calcium Nephrolithiasis (Table 25- 3) 1. ABSORPTIVE HYPERCALCIURIA TYPE I No treatment program is capable of correcting the basic abnormality of absorptive hypercalciuria, although several drugs restore normal calcium excretion. Sodium cellulose phosphate administration is not an optimal therapy. 46 When given orally, this nonabsorbable ionexchange resin binds calcium and inhibits calcium absorption. However, decreased calcium absorption is due to limitation of the amount of intraluminal calcium available for absorption and not to correction of the disturbance in calcium transport. There are two potential complications of sodium cellulose phosphate therapy. 47 First, the agent may cause magnesium depletion by binding dietary magnesium. Second, sodium cellulose phosphate may produce secondary hyperoxaluria 48 by binding divalent cations in the intestinal tract, reducing formation of divalent cationoxalate complexes, and making more oxalate available for absorption. These complications may be prevented by oral magnesium supplementation (magnesium citrate, 10 mEq given twice a day separately from sodium cellulose phosphate) and moderate dietary restriction of oxalate. Under such circumstances, sodium cellulose phosphate (10 to 15 g/day, given with meals) lowers urinary calcium level, reduces urinary saturation of calcium salts, and retards new stone formation without significantly altering urinary oxalate or magnesium. 8 This drug is contraindicated in other forms of hypercalciuria because it may further stimulate parathyroid function and worsen negative calcium balance. Because of this potential complication, sodium cellulose phosphate should be given only in severe cases of absorptive hypercalciuria type I and in thiazide-resistant hypercalciuria, in whom there is normal bone density.

Thiazide does not decrease intestinal calcium absorption, 26 but it is widely used to treat this disorder because of its hypocalciuric action. However, thiazide may have limited long-term effectiveness in absorptive hypercalciuria type 1.49 It is usually effective in reducing the urinary calcium level during the first 2 years of treatment, but thereafter urinary calcium generally returns to the pretreatment range (Fig. 25-2). Intestinal calcium absorption persistently remains elevated throughout thiazide treatment. Thiazide may cause accretion of calcium in bone during the early years of therapy; eventually a low-turnover state of bone interferes with continued calcium accretion in the skeleton. 5~The "rejected" calcium would then be excreted in urine. In contrast, calcium retention does not occur in renal hypercalciuria because thiazide causes a decrease in intestinal calcium absorption commensurate following the reduction in urinary calcium. 38'49

The following guidelines for the use of these two agents are recommended until more selective therapies are found. Sodium cellulose phosphate is appropriate for patients with severe absorptive hypercalciuria type I [urinary calcium > 8.75 mM/day (> 350 mg/day)] and for patients resistant to or intolerant of thiazide therapy, without osteopenia. In patients at risk for bone disease (growing children, postmenopausal women, or elderly men), thiazide is the first choice. When thiazide becomes ineffective in lowering the urinary calcium, this treatment may be temporarily replaced by sodium cellulose phosphate or orthophosphate treatment (for --~6 months). Restoration of hypocalciuric response to thiazide may then ensue, permitting resumption of thiazide therapy. Potassium citrate (e.g., 15 to 20 mEq twice a day) should be given along with thiazide (e.g., trichlormethiazide 4 mg/day) to prevent hypokalemia and to augment citrate excretion. 51 Recent studies suggest that slow-release neutral potassium phosphate may be a promising treatment for absorptive hypercalciuria. 52 It reduces intestinal absorption of calcium by direct binding of calcium in the intestinal tract and by impairing renal calcitriol synthesis. A sustained reduction in urinary calcium is accompanied by a rise in urinary inhibitors (citrate and pyrophosphate). 2. ABSORPTIVE HYPERCALCIURIA TYPE I I

In absorptive hypercalciuria type II, a low-calcium diet [10 to 15 mM/day (400 to 600 mg/day)] and a high fluid intake (sufficient to maintain urine output greater than 2 liters/day) are appropriate 8 because normocalciuria can be restored by dietary calcium restriction alone and because increased urine volume reduces urinary saturation of calcium oxalate, brushite, and monosodium urate and inhibits spontaneous nucleation of calcium oxalate.

TABLE25-3

Optimal Treatment Programs for Nephrolithiasis

Treatment

Physiological Action

-

Indication

Sodium cellulose phosphate

.1intestinal calcium (Ca) absorption & urinary Ca

Thiazide

= intestinal Ca absorption urinary Ca (transient) urinary citrate

Absorptive hypercalciuria type I1

Low-Ca diet

Renal hypercalciuria

Thiazide

Hyperuricosuric Ca nephrolithiasis

Allopurinol Potassium citrate

& intestinal Ca absorption .1urinary Ca & urinary Ca (sustained) & intestinal Ca absorption & urinary uric acid

Absorptive hypercalciuria type I

Enteric hyperoxaluria

1' urinary

& oxalate intake Potassium citrate

.1urinary oxalate I' urinary citrate

Magnesium gluconate Calcium citrate

1' urinary citrate

Hypocitraturic Ca nephrolithiasis

Potassium citrate

Gouty diathesis

Potassium citrate

1'urinary pH

? urinary Mg

I' urinary I' urinary

Cystinuria

Penicillamine or tiopronin"

Infection stones

Acetohydroxamic acid

-1, decrease; 1',increase; =, no change.

pH

citrate

1'urinary pH k/=urinary Ca 1' urinary pH 1 undissociated uric acid I' urinary

"a-Mercaptopropionylglycine.

citrate

urinary saturation of Ca oxalate

& Ca phosphate saturation -1 urinary saturation of Ca salts

& urinary saturation of Ca oxalate and Ca phosphate urinary saturation of Ca salts

.1urate-induced crystallization of Ca salts & urinary saturation of Ca oxalate .1urate-induced crystallization of Ca salts .1urinary saturation of Ca oxalate & urinary saturation of Ca oxalate 1' inhibitor activity & urinary saturation of Ca oxalate

1' inhibitor activity

4 urinary saturation of Ca oxalate 1' inhibitor activity & urinary saturation of uric acid & Ca oxalate crystallization

citrate

Mixed disulfide with cysteine & urinary cystine urease activity

& NH: 1pH

-

Physicochernical Action

.1urinary saturation of cystine & urinary saturation of struvite

746

CH,~RLES Y.

C. PAK

ABSORPTIVE HYPERCALCIURIA 450

400

350 t'~ CB

E

E

:3 0

(D

r

ZD

300

250 _

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o

200

450 400 50 [

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7

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RENAL HYPERCALCIURIA

,oo t 350] .~

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Years on Thiazide Therapy FIGURE 25--2

Effect of long-term therapy on urinary calcium and fractional (intestinal) calcium absorption in absorptive and renal hypercalciurias. (From Preminger GM, Pak CYC: Eventual attenuation of hypocalciuric response to hydrochlorothiazide in absorptive hypercalciuria. J Urol 137:1104-1109, 1987.)

3. RENAL HYPERCALCIURIA Thiazide is the treatment of choice for renal hypercalciuria. 26'38 This agent corrects the renal leak of calcium directly by augmenting calcium absorption in the distal tubule and by causing extracellular volume depletion, which stimulates proximal tubular reabsorption of calcium. The ensuing correction of secondary hyperparathyroidism restores normal serum 1,25(OH)2D and intestinal calcium absorption. Physicochemically, the urine becomes less saturated with calcium oxalate and brushite, largely because of the reduced calcium excretion. 53

Moreover, urinary inhibitor activity, as reflected by an increase in the limit of metastability, occurs by an unknown mechanism. These effects are shared by hydrochlorothiazide (50 mg twice a day), chlorthalidone (25 mg/day), and trichlormethiazide (4 mg/day). Potassium supplementation (15 to 20 mEq twice a day) may be required to prevent hypokalemia and attendant hypocitraturia. Concurrent use of triamterene, a potassiumsparing agent, should be undertaken with caution because of the possibility of triamterene stone formation. 54 Amiloride may be used with thiazide, because it may also exert a hypocalciuric action, exaggerate the hypo-

CHAPTER 25 Kidney Stones: Pathogenesis, Diagnosis, and Therapy calciuric action of thiazide, and prevent hypokalemia. 55 However, amiloride does not augment citrate excretion. Thus in patients with hypercalciuric nephrolithiasis and hypocitraturia, in whom the use of potassium citrate is contemplated, it is probably wise to use thiazide alone without a potassium-sparing diuretic. 4. PRIMARY HYPERPARATHYROIDISM

There is no established medical treatment for the nephrolithiasis of primary hyperparathyroidism. Although orthophosphates have been recommended for disease of mild to moderate severity, 56 their safety or efficacy has not yet been proven. They should be used only when parathyroid surgery cannot be undertaken. Thiazide is contraindicated in primary hyperparathyroidism because of potential aggravation of hypercalcemia. Estrogen is a reasonable alternative in postmenopausal women with primary hyperparathyroidism in whom surgery is refused or contraindicated. 57 This treatment (e.g., conjugated estrogen 0.625 mg/day, 25 days of each month) has been shown to reduce serum calcium concentration (by inhibiting PTH-induced bone resorption) and thereby reduce urinary calcium. Parathyroidectomy is the optimal treatment for the nephrolithiasis of primary hyperparathyroidism. Following removal of abnormal parathyroid tissue, urinary calcium is restored to normal commensurate with a decline in serum concentration of calcium and intestinal calcium absorption. 58 The urinary environment becomes less saturated with respect to calcium oxalate and brushite, and its limit of metastability (formation product ratio, a measure of inhibitor activity) for these calcium salts increases. 59 There is typically a reduced rate of new stone formation, unless urinary tract infection is present.

III. HYPERURICOSURIA The association of hyperuricosuria with calcium nephrolithiasis is well known, and has received the appellation of hyperuricosuric calcium nephrolithiasis.

A. C a u s a l R o l e o f H y p e r u r i c o s u r i a in C a l c i u m Stone Formation Recurrent calcium nephrolithiasis (stones of calcium oxalate and/or calcium phosphate) can occur in subjects with hyperuricosuria with no other discernible cause for nephrolithiasis, provided that the urinary pH is greater than the dissociation constant (pKa) of 5.47 for the first proton of uric acid. 6~ The association of hyperuricosuria with calcium nephrolithiasis has led to the suggestion

747 that hyperuricosuria is pathogenetically important in calcium stone formation. 61 The following scheme has been proposed: the urine may be supersaturated with respect to monosodium urate because it has a high content of uric acid and a pH (> 5.5) in which monosodium urate is stable. 62 Either a colloidal or crystalline monosodium urate can form in such a supersaturated environment 63 and initiate the formation of calcium stones by (1) direct induction of heterogeneous nucleation of calcium oxalate or (2) adsorption of glycosaminoglycans (which are inhibitors of crystal aggregation or spontaneous nucleation of calcium oxalate). 64 The scheme is supported by the demonstration of supersaturation of urine with monosodium urate, 62 by the ability of monosodium urate to induce heterogeneous nucleation of calcium oxalate, 64 and by the capacity of monosodium urate to attenuate the inhibitory activity of heparin (model mucopolysaccharide) 64 or naturally occurring urinary macromolecules. 65 Moreover, the induction of hyperuricosuria by oral purine loading facilitates spontaneous precipitation of calcium oxalate in urine, commensurate with a rise in urinary saturation of monosodium urate. 63 Unfortunately, the presence of crystalline monosodium urate in urine has not yet been documented.

B. P a t h o p h y s i o l o g y o f H y p e r u r i c o s u r i a Uric acid is an end product of purine metabolism. It cannot be degraded in humans because they lack uricase, which is present in other mammalian species. The major site of disposal of uric acid is the kidney. Hyperuricosuria may ensue when the serum concentration and the renal filtered load of uric acid are increased as a result of (1) the availability of an excessive amount of substrate (e.g., from a diet high in purine-rich foods 66) or from accelerated degradation and turnover of nucleic acids, or (2) a disturbance in purine biosynthesis that causes overproduction of purine substrates for uric acid synthesis. A high urinary uric acid level can occur transiently when renal tubular reabsorption of uric acid is impaired, as during early stages of extracellular volume expansion or after administration of uricosuric agents such as probenecid. In the steady state, however, normal urinary uric acid concentration is restored in latter conditions because of the secondary decline in the serum concentration and renal filtered load of uric acid, even though the renal tubular reabsorption of uric acid remains impaired. 67 Hyperuricosuria may be the only observed physiological abnormality in patients with calcium nephrolithiasis. Such a defect (hyperuricosuric calcium urolithiasis) exists alone in approximately 10% of patients with renal

748

CHARLES Y. C. PAK

Although hyperuricosuria may coexist with the various forms of hypercalciuria, only the pure disorder is considered in this section. The most common cause of hyperuricosuria in patients with hyperuricosuric calcium oxalate nephrolithiasis is probably dietary overindulgence in purine-rich f o o d s . 66 Such individuals have a history of a liberal intake of meat, poultry, and fish. 63'66 Hyperuricosuria in such patients can be ameliorated by dietary purine c a l c u l i . 68"69

d e p r i v a t i o n . 63,66

However, about 30% of patients with hyperuricosuric calcium oxalate nephrolithiasis have hyperuricosuria as the result of uric acid overproduction. Hyperuricosuria persists despite long-term purine deprivation. No further studies have been performed to elucidate the nature of this apparent urate overproduction. During long-term thiazide therapy, hyperuricosuria and hyperuricemia may be encountered. 7~ Besides its customary action of augmenting renal tubular reabsorption of urate, thiazide may stimulate urate production or decrease the extrarenal disposal of urate.

C. Diagnostic Criteria (Table 25-2) Hyperuricosuric calcium oxalate nephrolithiasis 71 is characterized by hyperuricosuria [urinary uric acid > 3.6 mM/day (> 600 mg/day) in at least two of three urine samples], normal serum calcium, normal fasting and calcium load response, normal urinary calcium, normal urinary oxalate [< 500 ixM/day (< 45 mg/day)], and calcium nephrolithiasis. Hyperuricosuria, defined functionally here by the upper normal limit of 3.6 mM/day (600 mg/day), correlates with the urinary supersaturation with monosodium urate that is associated with the increased propensity for calcium stone formation. 62 [Other laboratories employ a higher upper limit for urinary uric acid, e.g., 4.5 mM/day (750 mg/day) for women and 4.8 mM/ day (800 mg/day) for men.] Urinary pH is typically greater than 5.5. Hyperuricosuria may be the only abnormality in patients with calcium stones, or it may coexist with various forms of hypercalciuria.

D. Treatment of Hyperuricosuric Calcium Nephrolithiasis (Table 25- 3) Allopurinol (300 mg/day) is the drug of choice in hyperuricosuric calcium oxalate nephrolithiasis resulting from uric acid overproduction, because of its ability to reduce uric acid synthesis and to lower urinary uric acid concentration. 61 Its use in hyperuricosuria associated with dietary purine overindulgence is also reasonable,

because dietary purine restriction may be impractical. Physicochemical changes ensuing from restoration of a normal urinary uric acid include an increase in the urinary limit of metastability of calcium oxalate. 63 Thus the spontaneous nucleation of calcium oxalate is retarded by treatment, probably by the inhibition of monosodium urate-induced stimulation of calcium oxalate crystallization. 64 Because of the potential exaggeration of the latter process, a moderate sodium restriction ( 6). 95 Because of the resulting enhanced dissociation of uric acid, the amount of undissociated uric acid decreases to levels found in normal controls [< 0.9 mM/day (< 150 mg/day)]. Thus potassium citrate therapy increases the solubility of uric acid, preventing uric acid stone formation. Moreover, this treatment inhibits formation of calcium stones by reducing urinary satu-

Normally, cystine is filtered and almost completely reabsorbed in the proximal nephron, so that less than 20 mg is excreted in urine each day. In cystinuria, the serum concentration and hence the renal filtered load of cystine are reduced. Exaggerated cystine excretion under this circumstance suggests a disturbance in renal handling of cystine. More than one defect can impair tubular reabsorption and back-diffusion of cystine. 1~ Similar defects in transport of other dibasic amino acids are present. However, exaggerated renal excretion of these amino acids and cystine may not be due to a single transport defect. 1~ Increasing the filtered load of one of these amino acids does not necessarily augment the excretion of others. T M The intestinal transport of dibasic amino acids may also be defective in cystinuria. The disorder has been classified into three types based on varying intestinal transport disturbances for these amino acids. 1~ The intestinal transport has been assessed by the in vitro uptake of radiolabeled amino acid by specimens of jejunal mucosa obtained by peroral biopsy and by studies of plasma cystine levels after oral cystine administration. In type I cystinuria, there is no uptake of cystine, lysine, or argi-

754

CHARLES Y. C. PAK

nine by jejunal mucosa, and plasma cystine concentration is not elevated after an oral cystine load. Thus there is defective intestinal transport of all three dibasic amino acids. In types II and III, the intestinal transport of dibasic amino acids is disturbed but less severely than in the type I presentation. In type II, some cystine is taken up by jejunal mucosa but at a reduced rate, and oral cystine loading does not increase the plasma cystine level. In type III cystinuria, the uptake of cystine and lysine by jejunal mucosa is variably reduced and the increment in plasma cystine after oral cystine loading is blunted. In the homozygous state, all three types of cystinuria involve excessive renal excretion of all four dibasic amino acids. 1~ In the heterozygous state, type I cystinuria is characterized by normal cystine excretion, whereas types II and III have elevated cystine and lysine excretion (although not quite up to the level encountered in the homozygous state), probably because of a prevailing (although reduced) intestinal uptake of these amino acids. Recently, discrete mutations in the dibasic amino acid transporter gene have been found in certain cystinuric patients. ~~176

C. Diagnostic Criteria The urinary sediment (preferably in fresh first morning void) should be examined for the presence of typical hexagonal cystine crystals. The urine sample should also be screened for "qualitative" cystine by the cyanidenitroprusside test. A positive reaction suggests that cystine excretion exceeds 75 mg/liter. A false-positive test may be encountered in patients with homocystinuria and acetonuria. On roentgenological examination, cystine calculi are radiopaque (although not as much) like calcareous calculi, but are more rounded and homogeneous in appearance. They may attain a staghorn size. If these studies are suggestive of the presence of cystinuria, urinary cystine excretion should be quantitated. Urinary cystine exceeding 250 mg/g creatinine is usually diagnostic of homozygous cystinuria. Stones passed or removed should be analyzed. The presence of cystine provides a definitive diagnosis of cystinuria.

D. Treatment of Cystine Nephrolithiasis (Table 25 - 3) A low-methionine diet has often been recommended for the control of cystine nephrolithiasis because methionine is a precursor of cystine. Although such a dietary maneuver may reduce cystine excretion, rigid methionine restriction is impractical. Dietary sodium restriction

may also reduce cystine excretion, 11~ but this beneficial effect may be neutralized by reduced solubility of cysfine resulting from loss of the "solubilizing" action of sodium. 1~ In patients with cystine calculi and moderate cystinuria [ 1 to 2 mM/day (250 to 500 mg/day)], conservative measures of high fluid intake and alkali administration should be attempted. The aim of fluid therapy is to increase urine volume sufficiently to reduce the cystine concentration below the solubility limit. At least 3 liters of fluid should be provided, including two 8-oz glassfuls with each meal and at bedtime. Patients should be directed to wake up at night to urinate and drink water. Additional fluids should be consumed when excessive sweating or intestinal fluid loss is present. A minimum urine output of 2 liters/day on a consistent basis is attainable by most patients with proper and persistent instruction. In theory, alkali therapy would enhance cystine solubility by raising urinary pH. However, substantial increases in cystine solubility do not occur until the urinary pH exceeds 7.5. The provision of alkali, no matter how much, rarely raises urinary pH above 7.5. When urinary pH increases above 7.0 with alkali therapy, calcium phosphate nephrolithiasis may be enhanced because of the enhanced urinary supersaturation of hydroxyapatite in an alkaline environment. Excessive alkali therapy therefore is not indicated. 1~ Thus a modest amount of alkali is recommended to maintain urinary pH in a high normal range (6.5 to 7.0). Potassium citrate has the advantages over sodium citrate that it does not cause hypercalciuria, is less likely to promote development of calcium s t o n e s , 95'111 and does not induce increased cystine excretion, ll~ The object of treatment with penicillamine or riopronin (et-mercaptopropionylglycine) is to reduce total cystine excretion by complexing cysteine, the monomeric form of cystine. Penicillamine or tiopronin may be added to the conservative treatment program in patients with moderate cystinuria when the conservative treatment is ineffective in controlling stone formation. In patients with severe cystinuria [> 2 mM/day (> 500 mg! day)], in whom conservative management alone is not likely to be effective, penicillamine or tiopronin therapy (together with conservative measures) may be begun. Penicillamine and tiopronin share with cysteine a free sulfhydryl group. 112 Thus, they undergo thiol-disulfide exchange with cystine to form penicillamine-cysteine or tiopronin-cysteine disulfide, which is much more soluble than cystine. After oral administration, a sufficient amount of penicillamine or tiopronin can be excreted in urine to complex cysteine and thereby lower cystine excretion. Unfortunately, penicillamine therapy is associated with frequent and sometimes severe side effects,

CHAPTER 25 Kidney Stones: Pathogenesis, Diagnosis, and Therapy including nephrotic syndrome, dermatitis, and pancytopenia. 113 Tiopronin has biochemical and clinical actions similar to those of penicillamine. TM However, it has a lower toxicity profile than penicillamine.

VIII. INFECTION WITH UREA-SPLITTING ORGANISMS A. Causal Role of Infection and Pathophysiology of Struvite Stone Formation Infection of the urinary tract with urea-splitting organisms may be associated with renal stones of struvite (magnesium ammonium phosphate) and of calcium carbonate apatite. 115 The critical determinant is the formation of ammonia in urine due to enzymatic degradation of urea by bacterial urease. The ammonia undergoes hydrolysis to form ammonium and hydroxyl ions. The resulting alkalinity of urine augments dissociation of phosphate to form triphosphate ions, and reduces the solubility of struvite. Although struvite stones may form de novo from infection alone, they also occur as a complication of other causes of renal calculi, such as hypercalciuria.

B. Diagnostic Criteria (Table 25-2) Lithiasis due to infection is disclosed by the presence of magnesium ammonium phosphate on stone analysis. Such struvite stones are often associated with pyuria, positive urine culture for urea-splitting organisms (Proteus, certain species of Staphylococcus, Pseudomonas, and Klebsiella), and high urinary pH (> 7.5). 115 Struvite stones are radiopaque and sometimes may attain a large (staghorn) size; they usually occur as mixtures with calcium carbonate apatite and tricalcium phosphate or less commonly with calcium oxalate. Some patients with struvite stones may have hypercalciuria. Urinary citrate may be low owing to bacterial enzymatic degradation of citrate.

C. Treatment of Struvite Stones (Table 25-3) If longstanding control of infection with urea-splitting organisms can be achieved, new stone formation may be averted and some existing stones may be dissolved. Unfortunately, such control is difficult to obtain with antibiotic therapy. If a struvite stone is present, it is difficult to eradicate infection completely because the stone may harbor the organisms within its interstices. Even i f " s t e r -

755 ilization" of urine can be achieved by antibiotic therapy, reinfection by organisms harbored by the stones can occur. For this reason, surgical removal of the struvite stones is usually recommended. Acetohydroxamic acid, a urease inhibitor, reduces urinary saturation of struvite by preventing the formation of ammonium and hydroxyl ions. TM It may prevent stone growth and sometimes cause dissolution of existing stones. However, it may cause hemolytic anemia, thrombophlebitis, and nonspecific neurological symptoms (disorientation, tremulousness, and headache). 116

IX. CONSERVATIVE MANAGEMENT The conservative measures of high fluid intake and avoidance of dietary excess should be applied in all patients with nephrolithiasis. 117 They may be applied alone in patients with a single stone episode and inactive stone disease but should be instituted together with a specific medical treatment program in patients with recurrent stone disease, particularly if extrarenal manifestations are present. Some conservative programs are applicable to all forms of stone disease, whereas others are useful for particular causes. High fluid intake is the only nutritional modification that is useful in all forms of nephrolithiasis. 118 By increasing urine output, urinary concentration of constituent ions and saturation of stone-forming salts are lowered. Although dietary restriction of oxalate may be beneficial in all types of nephrolithiasis, it is particularly indicated when intestinal absorption of oxalate is increased, as in ileal disease and when calcium absorption is increased. Rigid calcium restriction [< 10 mM/day (< 400 mg/day)] is ill advised, even in patients who have high intestinal calcium absorption, because it is difficult to adhere to, may adversely affect general nutrition, and may cause negative calcium balance. However, moderate calcium restriction [10 to 15 mM/day (400 to 600 mg/ day)] may be useful in absorptive hypercalciuria because it alone may control the hypercalciuria in the less severe (type II) presentation and permit reduction of the dosage of medication necessary to restore normal urinary calcium concentration in the more severe (type I) presentation. Calcium restriction is neither necessary nor indicated in patients with nephrolithiasis with normal intestinal absorption of calcium. Moderate sodium restriction (100 mM/day) may be helpful in all forms of nephrolithiasis. Sodium excess raises urinary calcium and lowers urinary citrate. 88 Moreover, it attenuates the hypocalciuric action of thiazide and increases urinary saturation of monosodium urate. TM

756

CHARLES Y. C. PAK

References 1. Chaussy C, Brendel W, Schmiedt E: Extracorporeally induced destruction of kidney stones by shock waves. Lancet 2:12651268, 1980. 2. Segura JW, Patterson DE, LeRoy AJ, et al: Percutaneous lithotripsy. J Urol 130:1051 - 1054, 1983. 3. Resnick MI, Pak CYC: Are metabolic studies of urolithiasis necessary? J Urol 137:960-961, 1987. 4. Fine JK, Pak CYC, Preminger GM: Effect of medical management and residual fragments on recurrent stone formation following shock wave lithotripsy. J Urol 153:27-33, 1995. 5. Pak CYC: Role of medical prevention. J Urol 141:798-801, 1989. 6. Pak CYC, Skurla C, Harvey J: Graphic display of urinary risk factors for renal stone formation. J Urol 134:867-870, 1985. 7. Pak CYC, Britton F, Peterson R: Ambulatory evaluation of nephrolithiasis: Classification, clinical presentation and diagnostic criteria. Am J Med 69:19- 30, 1980. 8. Pak CYC, Peters P, Hurt G, et al: Is selective therapy of recurrent nephrolithiasis possible? Am J Med 71:615-622, 1981. 9. Fleisch H, Bisaz S: Isolation from urine of pyrophosphate a calcification inhibitor. Am J Physiol 203:671-675, 1962. 10. Kitamura T, Zerwekh JE, Pak CYC: Partial biochemical and physicochemical characterization of organic macromolecules in urine from patients with renal stones and control subjects. Kidney Int 21:379- 386, 1981. 11. Nakagawa Y, Abram V, Parks JH, et al: Urine glycoprotein crystal growth inhibitors. J Clin Invest 76:1455-1462, 1985. 12. Bowyer RC, Brockis JG, McCulloch RK: Glycosaminoglycans as inhibitors of calcium oxalate crystal growth and aggregation. Clin Chim Acta 95:23-28, 1979. 13. Worcester EM, Blumenthal SS, Beshensky AM, Lewand DL: The calcium oxalate crystal growth inhibitor protein produced by mouse kidney cortical cells in culture is osteopontin. J Bone Miner Res 7:1029-1036, 1992. 14. Pak CYC, Holt K: Nucleation and growth of brushite and calcium oxalate in urine of stone-formers. Metabolism 25:665673, 1976. 15. Pak CYC: Idiopathic renal lithiasis: New developments in evaluation and treatment. In Fleisch H, Robertson WG, Smith LH, Vahlensieck W (eds): Urolithiasis Research. New York, Plenum Publishing Corp, 1976, pp 213-244. 16. Zerwekh JE, Hwang TIS, Poindexter J, et al: Modulation by calcium of the inhibitor activity of naturally occurring urinary inhibitors. Kidney Int 33:1005-1008, 1988. 17. Strauss AL, Coe FL, Deutsch L, Parks JH: Factors that predict relapse of calcium nephrolithiasis during treatment. Am J Med 72:17 -24, 1982. 18. Pak CYC, Galosy RA: Propensity for spontaneous nucleation of calcium oxalate. Quantitative assessment by urinary FPR-APR discriminant score. Am J Med 69:681-689, 1980. 19. Yendt ER, Cohanim M: Prevention of calcium stones with thiazides. Kidney Int 13:397-409, 1978. 20. Sakhaee K, Baker S, Zerwekh J, et al: Limited risk of kidney stone formation during long-term calcium citrate supplementation in non-stone forming subjects. J Urol 152:324-327, 1994. 21. Pak CYC: Calcium metabolism. J Am Coil Nut 8:46S-53S, 1989. 22. Henneman PH, Benedict PH, Forbes AP, Dudley RH: Idiopathic hypercalciuria. N Engl J Med 259:802-807, 1958. 23. Brannan PG, Morawski S, Pak CYC, Fordtran JS: Selective jejunal hyperabsorption of calcium in absorptive hypercalciuria. Am J Med 66:425-428, 1979.

24. Pak CYC, Nicar MJ, Krejs GJ: Intestinal absorption of calcium, magnesium, phosphate and oxalate: Deviation from normal in idiopathic urolithiasis. In Schwille PO, Smith LH, Robertson WG, Vahlensieck W (eds): Urolithiasis and Related Clinical Research. Germany, Plenum Publishing Garmisch-Partenkirchen, 1985, pp 127-133. 25. Breslau NA, Preminger GM, Adams BV, Pak CYC: Use of ketoconazole to probe the pathogenetic importance of 1,25-(OH)2D in absorptive hypercalciuria. J Clin Endocrinol Metab 75: 1446-1452, 1992. 26. Pak CYC: Physiological basis for absorptive and renal hypercalciurias. Am J Physiol 237:F415-F423, 1979. 27. Kaplan RA, Haussler MR, Deftos LJ, et al: The role of l et,25dihydroxyvitamin D in the mediation of intestinal hyperabsorption of calcium in primary hyperparathyroidism and absorptive hypercalciuria. J Clin Invest 59:756-760, 1977. 28. Insogna KL, Broadus AE, Dreyer BE, et al: Elevated production rate of 1,25-dihydroxyvitamin D in patients with absorptive hypercalciuria. J Clin Endocrinol Metab 61:490-495, 1985. 29. Broadus AE, Horst RL, Lang R, et al: The importance of circulating 1,25-dihydroxyvitamin D in the pathogenesis of hypercalciuria and renal-stone formation in primary hyperparathyroidism. N Engl J Med 302:421-426, 1980. 30. Gray RW, Wilz DR, Caldas AE, et al: The importance of phosphate in regulating plasma 1,25-(OH)2-vitamin D levels in humans: Studies in healthy subjects in calcium stone formers and in patients with primary hyperparathyroidism. J Clin Endocrinol Metab 45:299-306, 1977. 31. Barilla DE, Zerwekh JE, Pak CYC: A critical evaluation of the role of phosphate in the pathogenesis of absorptive hypercalciuria. Miner Elecrolyte Metab 2:302-309, 1979. 32. Broadus AE, Erickson SB, Gertner JM, et al: An experimental human model of 1,25-dihydroxyvitamin D-mediated hypercalciuria. J Clin Endocrinol Metab 59:202-206, 1984. 33. Pak CYC, Galosy RA: Fasting urinary calcium and adenosine 3'-5'-monophosphonate: A discriminant analysis for the identification of renal and absorptive hypercalciuria. J Clin Endocrinol Metab 48:260-265, 1979. 34. Reynolds JJ, Holick MF, DeLuca HF: The role of vitamin D metabolites in bone resorption. Calcif Tissue Res 12:295-301, 1973. 35. Pietschmann F, Breslau NA, Pak CYC: Reduced vertebral bone density in hypercalciuric nephrolithiasis. J Bone Miner Res 7: 1383-1388, 1992. 36. Coe FL, Favus MJ, Crockett T, et al: Effects of low calcium diet on urine calcium excretion, parathyroid function and serum 1,25(OH)2D3 levels in patients with idiopathic hypercalciuria and in normal subjects. Am J Med 72:25-32, 1982. 37. Zerwekh JE, Hughes MR, Reed BY, et al: Evidence for normal vitamin D receptor messenger ribonucleic acid and genotype in absorptive hypercalciuria. J Clin Endocrinol Metab 80:29602965, 1995. 38. Zerwekh JE, Pak CYC: Selective effects of thiazide therapy on serum 1,25-dihydroxyvitamin D and intestinal calcium absorption in renal and absorptive hypercalciurias. Metabolism 29: 13-17, 1980. 39. Sakhaee K, Nicar MJ, Brater DC, Pak CYC: Exaggerated natriuretic and calciuric responses to hydrochlorothiazide in renal hypercalciuria but not in absorptive hypercalciuria. J Clin Endocrinol Metab 61:825-829, 1985. 40. Barilla DE, Townsend J, Pak CYC: An exaggerated augmentation of renal calcium excretion following oral glucose ingestion in patients with renal hypercalciuria. Invest Urol 15:486-488, 1978.

CHAPTER 25

Kidney Stones: Pathogenesis, Diagnosis, and Therapy

41. Lemann J, Piering WF, Lennon EJ: Possible role of carbohydrate-induced calciuria in calcium oxalate kidney stone formation. N Engl J Med 280:232-237, 1969. 42. Muldowney FP, Freaney R, Moloney MF: Importance of dietary sodium in the hypercalciuria syndrome. Kidney Int 22:292-296, 1982. 43. Lawoyin S, Sismilich S, Browne R, Pak CYC: Bone mineral content in patients with calcium urolithiasis. Metabolism 28: 1250-1254, 1979. 44. Buck AC, Lote CJ, Sampson WF: The influence of renal prostaglandins on urinary calcium excretion in idiopathic urolithiasis. J Urol 129:421-426, 1983. 45. Silverberg SJ, Shane E, Cruz L, et al: Skeletal disease in primary hyperparathyroidism. J Bone Miner Res 4:283- 291, 1989. 46. Pak CYC: Sodium cellulose phosphate: Mechanism of action and effect on mineral metabolism. J Clin Pharmacol 13:15-27, 1975. 47. Pak CYC: A cautious use of sodium cellulose phosphate in the management of calcium nephrolithiasis. Invest Urol 19:187190, 1981. 48. Hayashi Y, Kaplan RA, Pak CYC: Effect of sodium cellulose phosphate therapy on crystallization of calcium oxalate in urine. Metabolism 24:1273-1278, 1975. 49. Preminger GM, Pak CYC: Eventual attenuation of hypocalciuric response to hydrochlorothiazide in absorptive hypercalciuria. J Urol 137:1104-1109, 1987. 50. Pak CYC, Nicar MJ, Northcutt C: The definition of the mechanism of hypercalciuria is necessary for the treatment of recurrent stone formers. Contrib Nephrol 33:136-151, 1982. 51. Pak CYC, Peterson R, Sakhaee K, et al: Correction of hypocitraturia and prevention of stone formation by combined thiazide and potassium citrate therapy in thiazide-unresponsive hypercalciuric nephrolithiasis. Am J Med 79:284-288, 1985. 52. Breslau NA, Padalino P, Kok DJ, et al: Physicochemical effects of a new slow-release potassium phosphate preparation (UroPhos-K) in absorptive hypercalciuria. J Bone Miner Res 10: 394-400, 1993. 53. Woelfel A, Kaplan RA, Pak CYC: Effect of hydrochlorothiazide therapy on crystallization of calcium oxalate in urine. Metabolism 26:201-205, 1977. 54. Ettinger B, Oldroyd NO, Sorgel F: Triamterene nephrolithiasis. JAMA 244:2443-2445, 1980. 55. Leppla D, Browne R, Hill K, Pak CYC: Effect of amiloride with or without hydrochlorothiazide on urinary calcium and saturation of calcium salts. J Clin Endocrinol Metab 57:920-924, 1983. 56. Broadus AE, Magee JS, Mallette LE, et al: A detailed evaluation of oral phosphate therapy in selected patients with primary hyperparathyroidism. J Clin Endocrinol Metab 56:953-961, 1983. 57. Gallagher JC, Nordin BEC: Treatment with estrogens of primary hyperparathyroidism in postmenopausal women. Lancet i:503507, 1972. 58. Kaplan RA, Snyder WH, Stewart A, et al: Metabolic effect of parathyroidectomy on asymptomatic primary hyperparathyroidism. J Clin Endocrinol Metab 42:415-426, 1976. 59. Pak CYC: Effect of parathyroidectomy on crystallization of calcium salts in urine of patients with primary hyperparathyroidism. Invest Urol 17:146-148, 1979. 60. Finlayson B, Smith A: Stability of first dissociable proton of uric acid. J Chem Eng Data 19:94-97, 1974. 61. Coe FL: Hyperuricosuric calcium oxalate nephrolithiasis. Kidney Int 13:418-426, 1978. 62. Pak CYC, Waters O, Arnold L, et al: Mechanism for calcium nephrolithiasis among patients with hyperuricosuria: Supersaturation of urine with respect to monosodium urate. J Clin Invest 59:426-431, 1977.

7~7 63. Pak CYC, Barilla DE, Holt K, et al: Effect of oral purine load and allopurinol on the crystallization of calcium salts in urine of patients with hyperuricosuric calcium urolithiasis. Am J Med 65:593-599, 1978. 64. Pak CYC, Holt K, Zerwekh JE: Attenuation by monosodium urate of the inhibitory effect of glycosaminoglycans on calcium oxalate nucleation. Invest Urol 17:138-140, 1979. 65. Zerwekh JE, Holt K, Pak CYC: Natural urinary macromolecular inhibitors: Attenuation of inhibitory activity by urate salts. Kidney Int 23:838-841, 1983. 66. Coe FL, Kavalach AG: Hypercalciuria and hyperuricosuria in patients with calcium nephrolithiasis. N Engl J Med 291:13441350, 1974. 67. Breslau NA, Pak CYC: Lack of effect of salt intake on urinary uric acid excretions. J Urol 129:531-532, 1983. 68. Pak CYC: Medical management of nephrolithiasis in Dallas: Update 1987. J Urol 140:461-467, 1988. 69. Levy FL, Huet-Adams B, Pak CYC: Ambulatory evaluation of nephrolithiasis: An update from 1980. Am J Med 98:50-59, 1995. 70. Pak CYC, Tolentino R, Stewart A, et al: Enhancement of renal excretion of uric acid during long-term thiazide therapy. Invest Urol 3:191-193, 1978. 71. Coe FL, Raisen L: Allopurinol treatment of uric acid disorders in calcium stone formers. Lancet i:129-131, 1973. 72. Pak CYC, Peterson R: Successful treatment of hyperuricosuric calcium oxalate nephrolithiasis with potassium citrate. Arch Intern Med 146:863-868, 1986. 73. Earnest DL, Williams HE, Admirand WH: A physicochemical basis for treatment of enteric hyperoxaluria. Trans Assoc Am Physicians 88:224-234, 1975. 74. Smith LH, Fromm H, Hofmann AF: Acquired hyperoxaluric nephrolithiasis and intestinal disease. N Engl J Med 286:13711375, 1972. 75. Nicar MJ, Peterson R, Pak CYC: Use of potassium citrate as potassium supplement during thiazide therapy of calcium nephrolithiasis. J Urol 131:430-433, 1984. 76. Barilla DE, Notz C, Kennedy D, Pak CYC: Renal oxalate excretion following oral oxalate loads in patients with ileal disease and with renal and absorptive hypercalciurias. Am J Med 64: 579-585, 1978. 77. Harvey JA, Zobitz MM, Pak CYC: Calcium citrate: Reduced propensity for the crystallization of calcium oxalate in urine resulting from induced hypercalciuria of calcium supplementation. J Clin Endocrinol Metab 61:1223-1225, 1985. 78. Meyer JL, Smith LH: Growth of calcium oxalate crystals: Inhibition by natural urinary crystal growth inhibitors. Invest Urol 13:36-39, 1975. 79. Nicar MJ, Hill K, Pak CYC: Inhibition by citrate of spontaneous precipitation of calcium oxalate in vitro. J Bone Miner Res 2: 215-220, 1987. 80. Kok DJ, Bijvoet OLM, Papapoulos SE: Excessive crystal agglomeration with low citrate excretion in recurrent stone formers. Lancet i:1056-1058, 1986. 81. Simpson DP: Regulation of renal citrate metabolism by bicarbonate ion and pH: Observations in tissue slices and mitochondria. J Clin Invest 16:225-238, 1967. 82. Morrissey JF, Ochoa M, Lotspeich WD, et al: Citrate excretion in renal tubular acidosis. Ann Intern Med 58:159-166, 1963. 83. Preminger GM, Sakhaee K, Skurla C, Pak CYC: Prevention of recurrent calcium stone formation with potassium citrate therapy in patients with distal renal tubular acidosis. J Urol 134:20-23, 1985. 84. Rudman D, Dedonis JL, Fountain MT, et al: Hypocitraturia in patients with gastrointestinal malabsorption. N Engl J Med 303: 657-661, 1980.

7

5

8

C

H

A

85. Pak CYC, Fuller C, Sakhaee K, et al: Long-term treatment of calcium nephrolithiasis with potassium citrate. J Urol 134:1119, 1985. 86. Breslau NA, Brinkley L, Hill KD, Pak CYC: Relationship role of animal protein-rich diet to kidney stone formation and calcium metabolism. J Clin Endocrinol Metab 66:140-146, 1988. 87. Sakhaee K, Nigam S, Snell P, et al: Assessment of the pathogenetic role of physical exercise in renal stone formation. J Clin Endocrinol Metab 65:974-979, 1987. 88. Sakhaee K, Harvey JA, Padalino PK, et al: Potential role of salt abuse on the risk for kidney stone formation. J Urol 150:310312, 1991. 89. Uribarri J, Pak CYC: Renal stone risk factors in patients with type IV RTA. Kidney Int 23:784-787, 1994. 90. Fegan J, Khan R, Poindexter J, Pak CYC: Gastrointestinal citrate absorption in nephrolithiasis. J Urol 147:1212-1214, 1992. 91. Sakhaee K, Williams RH, Oh MS, et al: Alkali absorption and citrate excretion in calcium nephrolithiasis. J Bone Miner Res 8:787-792, 1993. 92. Preminger GM, Sakhaee K, Pak CYC: Hypercalciuria and altered intestinal calcium absorption occurring independently of vitamin D in incomplete distal renal tubular acidosis. Metabolism 36:176-179, 1987. 93. Kassirer JP, Berkman PM, Lawrenz DR, et al: The critical role of chloride in the correction of hypokalemic alkalosis in man. Am J Med 38:172-189, 1965. 94. Pak CYC, Fuller C: Idiopathic hypocitraturic calcium oxalate nephrolithiasis successfully treated with potassium citrate. Ann Intern Med 104:33-37, 1986. 95. Pak CYC, Sakhaee K, Fuller C: Successful management of uric acid nephrolithiasis with potassium citrate. Kidney Int 30:422428, 1986. 96. Khatchadourian J, Preminger GM, Whitson PM, et al: Clinical and biochemical presentation of gouty diathesis: Comparison of uric acid versus pure calcium stone formation. J Urol 154: 1665-1669, 1995. 97. Yu TF, Gutman AB: Uric acid nephrolithiasis in gout. Predisposing factors. Ann Intern Med 67:1133-1148, 1967. 98. Gutman AB, Yu TF: Uric acid nephrolithiasis. Am J Med 45: 7 5 6 - 779, 1968. 99. Henneman PH, Wallach S, Dempsey EF: Metabolic defect responsible for uric acid stone formation. J Clin Invest 4 1 : 5 3 7 542, 1962. 100. Gutman AB, Yu TF: Urinary ammonium excretion in primary gout. J Clin Invest 44:1474-1481, 1965. 101. Plante GE, Durivage J, Lemieux G: Renal excretion of hydrogen in primary gout. Metabolism 17:377- 385, 1968.

R

L

E

S

Y. C. PAK

102. Gutman AB, Yu TF: A three-component system for regulation of renal excretion of uric acid in man. Trans Assoc Am Physicians 74:353-365, 1961. 103. Thier SO, Segal S: Cystinuria. In Stanbury JB, Wyngaarden JB, Frederickson DS (eds): The Metabolic Basis of Inherited Disease. New York, McGraw-Hill, 1972, pp 1504-1519. 104. Pak CYC, Fuller CJ: Assessment of cystine solubility in urine and of heterogeneous nucleation between cystine and calcium salts. Invest Urol 129:1066-1070, 1983. 105. Broadus A, Thier S: Metabolic basis of renal stone disease. N Engl J Med 300:839-845, 1979. 106. Dent CE, Rose GA: Amino acid metabolism in cystinuria. Q J Med 20:205- 219, 1951. 107. Rosenberg LE, Downing S, Durant JL, et al: Cystinuria: Biochemical evidence for three genetically distinct diseases. J Clin Invest 45:365-371, 1966. 108. Calonge MJ, Gasparini P, Chillaron J, et al: Cystinuria caused by mutations in rBAT, a gene involved in the transport of cystine. Nat Genet 6:420-425, 1994. 109. Gitomer WL, Reed BY, Ruml LA, Pak CYC: A 335 base deletion in the mRNA coding for a dibasic amino acid transporterlike protein (SLC3A1) isolated from a patient with cystinuria. Genomics (in press). 110. Jaeger P, Portman L, Saunders A, et al: Anticystinuric effects of glutamine and of dietary sodium restriction. N Engl J Med 315: 1120-1123, 1986. 111. Sakhaee K, Nicar M, Hill K, Pak CYC: Contrasting effects of potassium citrate and sodium citrate therapies on urinary chemistries and crystallization of stone-forming salt. Kidney Int 24: 348-352, 1983. 112. Perrett D: The metabolism and pharmacology of D-penicillamine in man. J Rheumatol $8:41-50, 1981. 113. Halperin EC, Thier SO, Rosenberg LE: The use of D-penicillamine in cystinuria: Efficacy and untoward reactions. Yale J Biol Med 54:439-446, 1981. 114. Pak CYC, Fuller C, Sakhaee K, et al: Management of cystine nephrolithiasis with alpha-mercaptopropionylglycine (Thiola). J Urol 136:1003-1008, 1986. 115. Griffith DP: Struvite stones. Kidney Int 13:372-382, 1978. 116. Williams JJ, Rodman JS, Peterson CM: A randomized doubleblind study of acetohydroxamic acid in struvite nephrolithiasis. N Engl J Med 311:760-764, 1984. 117. Pak CYC, Smith LH, Resnick MI, Weinerth JL: Dietary management of idiopathic calcium urolithiasis. J Urol 131:850-852, 1984. 118. Pak CYC, Sakhaee K, Crowther C, Brinkley L: Evidence justifying a high fluid intake in treatment of nephrolithiasis. Ann Intern Med 93:36-39, 1980.

2 H A P T E R 2(

Metabolic Bone Disease in Children FRANCIS H.

GLORIEUX

Genetics Unit, Shriners Hospital for Children and Departments of Surgery and Pediatrics, McGill University, Montr6al, Qurbec, H3G 1A6 Canada

GERARD KARSENTY

Molecular Genetics, The University of Texas, MD Anderson Cancer Center, Houston, Texas 77030

R A J E S H W. T H A K K E R

MRC Molecular Endocrinology Group, Royal Postgraduate Medical School, Hammersmith Hospital, London, W12 0NN United Kingdom

III. Rickets and Osteomalacia References

I. Introduction II. Skeletal Development

lular matrix molecules. Although only a few of these anomalies have been presently ascribed to a metabolic bone disease in the strict sense of the term, it was felt that an overview of current knowledge on the genetic control of skeletal development would be a useful introduction to the present chapter.

I. I N T R O D U C T I O N As in adults, metabolic bone diseases in children are, for the most part, the clinical expression of alterations or dysfunctions of the various factors that control mineral homeostasis. The ensuing defective mineralization translates into tickets at the level of the epiphyseal growth plates, and osteomalacia on the endocortical and cancellous bone surfaces. The various forms of tickets and osteomalacia as they occur in the growing individual will be discussed in this chapter. It is important to keep in mind that these conditions will develop on the background of rapid skeletal growth and development. The clinical expression of rickets and osteomalacia will often include stunting of the growth rate and severe bone deformities. In recent years, the unraveling of the factors that control and influence skeletal development has grown at an exponential rate. Several human bone diseases have now been ascribed to functional anomalies of a growing list of factors, hormones and their receptors, and extracelMETABOLIC BONE DISEASE

II. S K E L E T A L

DEVELOPMENT A. O v e r v i e w

The vertebrate skeleton derives from several distinct embryological structures. 1-3 Most of the craniofacial skeleton originates primarily from neural crest cells (ectoderm), which emigrate from the neural tube (midbrain and rhombomeres) into predetermined branchial arches 4'5 and then migrate to the developing head. Only some pieces of the skull are of somitic origin (basi- and exooccipital) or derive of both ectodermal and mesodermal participation (sphenoid complex and otic capsule). 3 The 759


760

FRANCISH. GLO~EUX, GERARDKARSENTY,AND RAJESHV. THAKKER

rest of the skeleton results exclusively from mesodermal contribution. The ribs and vertebrae are derived from the sclerotome, a differentiated area of the mature somites; each trunk vertebrae arises from the development and fusion of the posterior and anterior halves of two consecutive somites. 6 Lastly, the appendicular skeleton is derived from lateral mesoderm. At the cellular level there is a common event that occurs in every future bone piece during development regardless of its embryonic origin. This event is the aggregation of mesenchymal cells into a condensate that represents the outline of each of the future skeletal elements. Thereafter these mesenchymal condensations will evolve differently depending on the type of ossification they will undergo, endochondral or intramembranous. 7 In most of the bones, including the axial and appendicular skeleton, ossification will occur through endochondral ossification where condensations form a cartilaginous template that is later replaced by bone. At their earliest stage, cells present in the mesenchymal condensation transiently express type I and type III collagens, noncartilaginous proteoglycans, and fibronectin. 8 Shortly after these mesenchymal condensations are identifiable, overt chondrogenesis begins marked by the synthesis and secretion of an extracellular matrix rich in types II, IX, and XI collagens and proteoglycans. 7'8 This process forms the "anlage" or model of the future skeleton. Chondrocytes in the center of these future bones become hypertrophic and synthesize type X collagen and alkaline phosphatase. The hypertrophic cartilage is degraded by invading blood vessels coming from the perichondfium, the hypertrophic chondrocytes die, and osteoblasts brought in by the blood vessels deposit bone matrix in the space previously occupied by the hypertrophic cartilage. 8 The ossification process spreads centrifugally, much of the cartilage anlage is converted by this process, and chondrocytes only remain at the end of bone in the articular cartilage and as a structure located between epiphysis and dyaphysis called the growth plate cartilage or epiphyseal cartilage. The growth plate contains different populations of chondrocytes, such as resting, proliferating, and hypertrophic chondrocytes, organized in columns. This structure is responsible for the longitudinal growth of bones; the cartilaginous matrix is primarily ossified and, when calcified, is resorbed by osteoclasts and replaced by a bone matrix elaborated by osteoblasts. 9 During childhood the cartilaginous protein matrix of the growth plate diminishes, the cellular columns become disorganized, and the whole structure is replaced by bone by the end of puberty through an, as yet, unknown mechanism. The second mechanism of ossification, termed "intramembranous ossification," occurs mostly in the skull and clavicle, and also in the diaphyses of the long bones

where it promotes progressive thickening directly under the periosteum. In that case, epithelial-mesenchymal interactions promote proliferation of a subset of mesenchymal cells to form the preosteogenic condensations. 7 In contrast to what is seen in endochondral ossification, these condensations undergo direct osteogenesis, without any cartilaginous stages. The mesenchymal cells differentiate directly into osteoblasts synthesizing increasing amounts of type I collagen and alkaline phosphatase, but no cartilage-specific collagens or proteoglycans. Three mouse mutants characterized by mesenchymal condensation defects have been described. 7'1~The recessive lethal congenital hydrocephalus (ch) mutation leads to extensive skeletal abnormalities such as missing, fused or misshaped bones. These defects are ascribed to alterations of the size of both prechondrogenic and preosteogenic condensations. The second mutation, phocomelia (Pa), leads to a disproportionate dwarfism with missing or reduced bones and presence of ectopic cartilage. In this case formation of condensations is delayed by 24 hours, the size of some being subsequently reduced. No gene has yet been identified as responsible for any of these two mutations. The third mutant, brachipodism (bp) shows a decreased length of long bones in the limbs and changes in the number of phalanges in toes. This mutation has been demonstrated to be due to thin, malformed digit condensations and failure of cleavage of these condensations at the location of future joints structures. 1~ Recently, this phenotype has been ascribed to mutations in the gene encoding Gdf5, one of the members of the bone morphogenetic family of secreted signaling molecules (see below). 11 Mutations in the Gdf5 gene in humans causes the Hunter-Thompson chondrodysplasia.12

B. T r a n s c r i p t i o n a l R e g u l a t i o n of Skeletal P a t t e r n i n g and Cell D i f f e r e n t i a t i o n Skeletal development is marked by two major events. One is the patterning of various skeletal elements, for which we know of a large set of genes involved. Interestingly, these genes do not appear to control the second event that is the commitment of mesenchymal cells to chondrogenic and osteogenic lineages, followed by the terminal differentiation of precursor cells into three specialized cell types: the chondrocyte in cartilage, and the osteoblast and osteoclast in bone. Fewer genes have been implicated in this latter process. Several families of transcription factors have been shown by genetic means to control skeletal patterning (Table 26-1). One of the most extensively studied groups is the homeobox (Hox) family of proteins (see Sharpe 13 for review). The homeobox genes formed a

CHAPTER 26

761

Metabolic Bone Disease in Children TABLE 2 6 - 1

Gene

Origin of Mutation

Homeobox genes Hoxa-1 Hoxa-2

KO KOa

Hoxa-3

KO

Hoxa-10 Hoxa- 11 Hoxa- 13

KO KO mmc

T r a n s c r i p t i o n F a c t o r s I n v o l v e d in S k e l e t a l D e v e l o p m e n t Human Condition or Mouse Mutation

Phenotype Otic capsule defect HTb of 2nd branchial arch derivatives in 1st branchial arch derivatives Misshaped and shorter maxilla, mandible, and hyoid bone Misshaped femurs and knee joints HT of T13-L1 Short fingers and toes Abnormal wrist bone

52, 53 14 54

Hypodactyly (Hd) mutant Hand-foot-genital syndrome

Hm d

References

55 56 57 58 59 60

Hoxb-4 Hoxd-3

KO KO

Hoxd-ll Hoxd-13

KO Hm KO

Msxl Msx2 MHox

KO Hm KO

Cdxl

KO

Partial HT of C1-C2 Fusion of the basoccipital with C1 Partial HT of C2-C1 HT S1 in L7, misshaped radius and ulna Branched and misshaped metacarpal and metatarsal bones $4 fused and transformed in $3 Delayed ossification of digits Extra digits and digit fusions Multiple craniofacial defects Craniosynostosis Altered craniofacial skeleton Bowing and shortening of radius + ulna and tibia + fibula Anterior HT of vertebrae

Paired-box genes Paxl Pax3

mm Hm

Absence of intervertebral disks Craniofacial abnormalities

Undulated (Un) mutant Waardenburg' s syndrome

20 21

Other classes Sox9

Hm

Bowed bones, hypoplastic scapulae, and axial skeleton abnormalities Osteopetrosis, failure in osteoclast differentiation (Poly) syndactyly

Campomelic dysplasia

23, 24

c-Fos Gli3 Krox 20 Bmi-1 Atf2 Twist Kr

KO Hm min KO KO KO Hm KO mm

Mild endochondral ossification defect Anteroposterior HT of axial skeleton Uniform dwarfism, endochondral ossification defect Craniosynostosis, brachydactyly, facial dysmorphism Craniosynostosis Abnormal hyoid bone

Synpolydactyly type II

61 14 15

Boston type craniosynostosis

17 18 62

63

Greig's syndrome Extra toes (Xt) mutant

Saethre-Chotzen syndrome Kreisler (kr) mutant

25, 26 64 65 68 66 67 69, 70 71 72

knock out by gene targeting. bHT, homeotic transformation. Cmm, spontaneous mutation in mouse. dHm, human disease. aKO,

f a m i l y of g e n e s h i g h l y c o n s e r v e d across species, like for i n s t a n c e b e t w e e n Caenorhabditis elegans and h u m a n s . M o r e than 39 H o x g e n e s h a v e a l r e a d y b e e n identified in the m o u s e . In v e r t e b r a t e s , the H o x g e n e s are a r r a n g e d in four g e n e clusters, and w i t h i n a g i v e n c l u s t e r the l o c a t i o n of i n d i v i d u a l g e n e s c o r r e s p o n d to their a n t e r o p o s t e r i o r e x p r e s s i o n pattern. H o x g e n e s h a v e b e e n i m p l i c a t e d in the p a t t e r n i n g o f the axial and a p p e n d i c u l a r skeleton. I n d e e d , i n a c t i v a t i o n or o v e r e x p r e s s i o n of H o x g e n e s resuits in d e l e t i o n or a d d i t i o n of skeletal e l e m e n t s , or in

the t r a n s f o r m a t i o n o f the s h a p e o f certain skeletal elem e n t s such as v e r t e b r a e into the s h a p e of a n o t h e r vertebra. This p r o c e s s is c a l l e d h o m e o t i c t r a n s f o r m a t i o n . F o r instance, i n a c t i v a t i o n of the H o x a - 2 g e n e results in the d e l e t i o n of the c r a n i o f a c i a l e l e m e n t s arising f r o m the s e c o n d b r a n c h i a l arch, w h e r e H o x a - 2 is n o r m a l l y exp r e s s e d . T h e s e e l e m e n t s are r e p l a c e d b y skeletal elem e n t s r e s e m b l i n g t h o s e d e r i v e d f r o m the first b r a n c h i a l arch. TM N o t all H o x m u t a t i o n s l e a d to a loss of function, for i n s t a n c e the e x p a n s i o n o f a p o l y a l a n i n e stretch lo-

762


cated upstream of the DNA binding domain of Hoxd-13 causes synpolydactyly in heterozygous individuals. 15 This is characterized by the insertion of an extra digit between digits III and IV in association with variable syndactyly. In homozygotes, the mutation causes altered growth of the metacarpal and metatarsal anlagen so that they resemble those of carpal and tarsal bones instead of long bones. The expansion of the NH2-terminal alanine stretch does not affect DNA binding but is thought to affect the ability of Hoxd-13 to interact with other proteins. 14 Another argument suggesting that this is not a loss-of-function mutation stems from the analysis of the phenotype of Hoxd-13-deficient mice that have very different and more severe abnormalities. 15 Another subclass of homeobox genes, termed Msx genes, which does not belong to one of the clusters mentioned above, have been shown to contribute to skeletal development (Table 26-1). For instance, Msx 1 null mice exhibit multiple craniofacial defects, ~7 and a mutation in the Msx2 gene is at the origin of an autosomal dominant form of craniosynostosis (Boston type). ~8 A second highly conserved family of transcription factors involved in skeletal patterning are the paired-box (Pax) genes (Table 26-1).19 In Drosophila, as well as in vertebrates, members of the Pax gene family have important roles in segmentation and neurogenesis. Their expression patterns during mouse embryogenesis suggest that Pax l and Pax9 have a role in the development of the vertebral column, whereas Pax3 is probably involved in the patterning of several crest derivatives. Indeed, mutations in the mouse Pax l cause the undulated (Un) phenotype characterized by vertebral development defects and kinky tails. Several Un-alleles are known, displaying a spectrum of severity in their phenotype. Homozygotes of the most severe phenotype completely lack vertebral bodies in the lumbar region, indicating that Pax l has an important role in the differentiation of cells originating from the sclerotome. 2~ Mutations in Pax3 are at the origin of the Waardenburg's syndrome, a dominantly inherited condition characterized by hearing loss, and pigmentation and craniofacial abnormalities. 2~ The genes mentioned above control patterning (i.e., the number and shape of skeletal elements). However, in the mutant animals or the affected individuals, the unaffected skeletal pieces exhibit the three specific cell types: chondrocytes in cartilage, and osteoblasts and osteoclasts in bone. This observation indicates that other transcription factors must control cell differentiation of these lineages. To this date, the study of the transcriptional control of cell differentiation in the skeleton is still at an early stage, with the most significant progress being made in chondrocyte and osteoclast biology. Sox9 is an Sryrelated gene thought to play a role during chondrocyte

differentiation. Sox9 is expressed in the sclerotomal compartment of the somites, in the mesenchymal condensation of the forming long bones and stops to be expressed upon completion of the skeletal anlage. 22 Human campomelic dysplasia, characterized by bowing of long bones, small scapulae, and vertebral abnormalities, has been linked to heterozygosity for a mutation in S o x 9 . 23'24 Another transcription factor, c-Fos, has been shown through genetic analysis in mice to be important for osteoclast differentiation. 25'26 c-Fos is expressed in macrophages and chondrocytes, and in its absence the osteoclasts fail to differentiate. As a result the homozygous mutant mice develop an osteopetrotic phenotype. Interestingly, these animals have no skeletal patterning defect providing genetic evidence that different transcription factors are regulating skeletal patterning and cell differentiation in the skeleton. At present, our knowledge of the transcriptional control of osteoblast differentiation is much less advanced.

C. Growth Factor Involvement in Skeletal Development With the development of the homologous recombination technology that allows generation, virtually at will, of mouse mutants, several families of growth factors have been demonstrated to be involved at various steps during skeletal development. For historical reasons the group of growth factors that initially received the most attention were the bone morphogenetic proteins (BMPs) (Table 26-2). This generic name regroups more than 15 identified members termed BMPs or GDFs, for growth and differentiation factors. 27 All of these molecules, except B MP1, belong to the TGF-I3 superfamily and can induce ectopic bone formation when implanted subcutaneously or in muscle. 28 The most remarkable aspect of this de novo bone formation is that it recapitulates all the events that occur in endochondral bone formation during development. 29 There is recruitment of mesenchymal cells, mesenchymal condensation, chondrocyte differentiation, and then vascular invasion bringing in osteoblast progenitors and differentiated osteoblasts. Consistent with the putative role of the BMPs during patterning of the skeleton stage, two mouse mutants, short ear (se) and brachypodism (bp) have been shown to be due to the disruption of Bmp5 29 and GdfS, 11 respectively. Short ear mice have a variety of changes in the size and shape of many small bones where Bmp5 is expressed. Mutations in other Bmps generate much more severe phenotypes, generally leading to early embryonic (Bmp2, Bmp4) or perinatal lethality (Bmp7), and in agreement with their broad pattern of expression 27 af-

763

CHAPTER 26 Metabolic Bone Disease in Children TABLE 2 6 - 2 Gene Bmp5 Bmp7 GDF5

Growth Factors, Hormones, and Their Receptors Involved in Skeletal Development

Origin of Mutation mma KOb HmC

Human Condition or Mouse Mutation

Phenotype Reduced or misshaped bones Extra digit in hindlimbs Shortening of long bones, metatarsal, and metacarpal bones

m m

FGFR1 FGFR2 FGFR3

Hm Hm Hm

Craniosynostosis Craniosynostosis Dwarfism

PTHrP

KO KO

PTH/PTHrP Receptor

Hm KO

Endochondral bone overgrowth Dwarfism Accelerated chondrocyte differentiation Short-limbed dwarfism Accelerated chondrocyte differentiation

Short-ear (Se) mutant Hunter-Thompson chondrodysplasia

References 30 31, 32 12

Brachypodism (bp) mutant Pfeiffer' s syndrome Crouzon' s syndrome Hypochondroplasia Anchondroplasia Thanatophoric dysplasia

11 73 74 33 35 36 37 38

Jansen' s chondrodysplasia

39 40

,,

amm, spontaneous mutation in mouse. bKO, knock out by gene targeting. CHm, human disease.

fecting various internal organs. This suggests that there may be a functional hierarchy in the Bmp family. Factors, like Bmp2 and Bmp4, are primarily required during early embryogenesis for some critical function independent of skeletal development, while others appear to function mainly during skeletal patterning. To date the only other Bmp for which genetic evidence has shown that it is implicated in patterning of some skeletal elements is Bmp7, the inactivation of the gene leading to preaxial polydactyly of the hindlimbs. 31'32 Another family of growth factors involved in skeletal development are the fibroblast growth factors (FGFs) and their receptors (FGFRs). They regulate multiple cellular functions including cell proliferation. To date three members of this family have been implicated in human diseases (Table 2 6 - 2 ) and one of them, FGFR3, has been the subject of the most intense investigation. Several mutations in this gene have been reported in humans, affecting various domains of the molecule and resuiting in different forms and severity of achondroplasia (Table 26-2). For instance, a mutation in the kinase intracellular domain leads to hypochondroplasia 33 whereas point mutations in the region encoding the transmembrane domain of this receptor have been shown to result in Crouzon' s syndrome 34 or in achondroplasia, 35 the most frequent cause of dwarfism. These mutations are gainof-function mutations, since transfection of a cDNA with the "achondroplasia mutation" into cells causes the re-

ceptor to become constitutively active, 36 and that inactivation of the FGFR3 in mice results in a different phenotype, showing long bone overgrowth and vertebrae with enlargement of the hypertrophic zone of the growth plates. 37 Another group of molecules whose function in skeletal development has been extensively studied by genetic approaches is the signaling complex parathyroid hormone-related peptide (PTHrP), PTH/PTHrP receptor. PTHrP-deficient mice display severe chondrodysplasia at birth with shortening of the growth plate cartilage due to an abnormal hypertrophic zone. 38 Similarly, a mutation in the PTH/PTHrP receptor was found in a patient with Jansen's metaphyseal chondrodysplasia, a rare form of short-limbed dwarfism. 39 This defect of chondrocyte differentiation could be explained by recent studies suggesting that PTHrP lies downstream of Indian hedgehog, a signaling molecule involved in the regulation of the rate of hypertrophic differentiation. 4~ In the postnatal period, the rapid growth and development of a normally formed skeleton may be compromised by mutations in key factors regulating mineral homeostasis, and thus disturbing the normal mineralization of cartilage and bone. Recent advances in molecular genetics have led to the cloning of several of the genes involved in the etiology of the major heritable metabolic bone diseases. They will be extensively discussed in this chapter.

764

FRANCIS H. GLORIEUX,GERARDKARSENTY,AND RAJESH V. THAKKER

D. Role of Matrix Molecules in the Formation of the Skeleton Because of their structural importance, the first extracellular molecules shown to be implicated in skeleton formation were the two major collagens, type I collagen in bone and type II collagen in cartilage. Mutations in the genes encoding these two molecules have been found to generate various deficiencies, among them osteogenesis imperfecta (type I collagen) and Stickler's syndrome (type II collagen) (see references 42 through 45 for review). Other genes encoding minor collagens like the type IX, X, and XI collagens have also been implicated in some human diseases (Table 2 6 - 3 ) . 44 For example, mutations in the genes encoding the oL1 and oL2 chains of type IX collagen were shown to generate degenerative joint disease 46 and multiple epiphyseal dysplasia (MED), 47 respectively. It is interesting to note that this same MED syndrome was also ascribed to a mutation in the cartilage oligomeric matrix protein (COMP) gene, that encodes a glycoprotein of the cartilage matrix. 48 This same gene was also found mutated in cases of pseudoachondroplasia. 49 Lastly, two members of the Gla family of extracellular proteins, osteocalcin and matrix gla protein (MGP), were shown by gene inactivation in mice to affect bone formation 5~ and bone growth, 51 respectively. In this latter case, null mice become dwarfed, longitudinal bone growth being rapidly arrested by ectopic calcification of

TABLE 2 6 - 3

the growth plate cartilage leading to complete disorganization of the chondrocyte columns.

III. RICKETS AND OSTEOMALACIA A. Definition In the strict sense of the term, rickets is caused by any interference with the process of endochondral bone formation, that is, the sequence of events that takes place in the epiphyseal growth plates and results in lengthening of the long bones. The other processes that involve rapid matrix mineralization during growth include remodeling of cancellous bone (to accommodate for the making of the marrow cavity) and apposition of periosteal bone (to increase bone width and cortical thickness). Defective mineralization of osteoid tissue throughout the skeleton results in excessive accumulation of osteoid tissue, or osteomalacia. Thus tickets occurs during growth in children, while osteomalacia occurs in both children and adults.

B. History The first treatise on rickets was published in 1650 by Francis Glisson. 79 This detailed description of the clinical features of rickets and discussion of the pathophysiology of the disease remains in many aspects actual.

Extracellular Matrix Molecules Involved in Skeletal Development

Gene

Origin of Mutation

COL1A1, COL1A2 COL2A1

Hma Hm

Brittle bone ___skeletal deformities Mild to lethal achondroplasia

COL9A1 COL9A2 COL10A1 COL11A1 COL 11A2 COMP

KOb Hm Hm mmc Hm Hm

Osteoarthritis Osteoarthritis Chondrodysplasia Short limb, hunchback Osteochondrodysplasia Short stature, osteoarthrosis

Osteocalcin (BGP) MGP

KO

Increased bone formation

KO

Dwarfism, ectopic calcification of growth plate cartilage

aHm, human disease. bKO, knock out by gene targeting. Cmm, spontaneous mutation in mouse.

Phenotype

Human Condition or Mouse Mutation Osteogenesis imperfecta Hypochondrogenesis Achondrogenesis type II Spondyloepiphyseal dysplasia Kniest' s dysplasia Stickler' s syndrome Multiple epiphyseal dysplasia Schmid's metaphyseal dysplasia Chondrodysplasia (cho) mutant Stickler' s syndrome Multiple epiphyseal dysplasia Pseudoachondroplasia

References 42, 43 44, 45

46 47 75, 76 77 78 48 49 50 51

CHAPTER 26 Metabolic Bone Disease in Children The possibility that rickets could be a heritable condition was already mentioned by Glisson, who also suggested treatment with large amounts of dairy products. In the mid-19th century, the Industrial Revolution in Europe and North America was paralleled by a steep increase in the incidence of rickets that was attributed to air pollution by smoke-emitting industrial plants. Although the effectiveness of cod-liver oil in the treatment of rickets had been reported, it was ignored to a large extent during the latter half of the 19th century. In the 1920s vitamin D was identified, and its deficiency was established as the major cause of rickets in children and osteomalacia in adults. 8~ The use of vitamin D for prevention and treatment largely eliminated vitamin D deficiency tickets. Shortly thereafter it was recognized that a small number of patients did not respond to the usual doses of vitamin D. They were classified as vitamin D-refractory or vitamin D-resistant rickets, 8~ and it was later demonstrated that they formed a heterogeneous group of disorders of various pathogenesis. On the background of rapid unraveling of the biochemistry and physiology of vitamin D, important new insights have been provided, in the last 25 years, into the pathogenesis of several types of vitamin D-refractory rickets.

C. Pathophysiology Bone formation and skeletal growth require the controlled production of a matrix (cartilage in the epiphyseal plate, and osteoid in metaphyseal areas and at sites of intramembranous bone formation), that will rapidly calcify when adequate concentrations of extracellular calcium and phosphate are available. The mineral phase will first be amorphous and then become crystalline in the form of hydroxyapatite with the basic formula Calo(PO4)6(OH)2. Failure to mineralize because of inadequate supply of mineral will result in excessive accumulation of unmineralized matrix. This will cause the characteristic swelling around the growth plates particularly evident at the wrists and ankles, and at the costochondral junction of the ribs where they form the classic rosary. The alteration of the natural sequence of endochondral bone formation will also slow down the growth in length of the various pieces of the axial and appendicular skeleton, resulting in an overall decrease of the linear growth rate that, in the extreme cases, may be completely stopped. Unmineralized bone is weakened and will bend or twist under the weight of the body and the pull of muscles. Fractures may occur, but more frequently skeletal deformities will appear: genu varum, genu valgum, coxa vara, tibial and femoral torsion, pelvic deformities, chest deformations, scoliosis, and kyphosis. In the infant, poor

765 mineralization of the skull may result in craniotabes. Thoracic deformities include pigeon breast deformity and lower rib cage flaring due to softening of the ribs and depression at the sites of insertion of the diaphragm (Harrison's groove). In an attempt to correct the hypocalcemia characteristic of the calcipenic forms of tickets, secondary hyperparathyroidism develops leading to increased bone resorption. This will lead to progressive decrease in bone mass and severe osteopenia, further increasing bone brittleness. By contrast, osteopenia never occurs in the phosphopenic forms of tickets as normocalcemia does not induce parathyroid reaction.

D. C l a s s i f i c a t i o n A number of classification schemes have been employed to categorize the various forms of rickets. As bone mineral is mostly made of calcium and phosphate, rickets and osteomalacia may arise from either primary calcipenia or primary phosphopenia (Table 26-4). The intent is not to discuss all of the reported forms but, rather, to concentrate on those that most frequently present clinically as well as discuss the most recent insights into the genetics and the molecular mechanisms underlying some of the heritable forms of rickets.

TABLE 26--4

Classification of Rickets

Calcipenic forms Dietary calcium deficiency Simple vitamin D deficiency Vitamin D deficiency secondary to Fat malabsorption Liver disease (?) Renal insufficiency Heritable forms Pseudo-vitamin D deficiency (PDDR) 25(OH)D- 1ot-hydroxylase defect Hypocalcemic vitamin D-resistant rickets (HVDRR) Alterations of the vitamin D receptor (VDR) Phosphopenic forms Insufficient intake Prematurity Total parenteral nutrition Use of phosphate binders Increased renal loss Fanconi syndrome by tubular damage Tumor induced rickets and osteomalacia (TIO) Heritable Increased renal loss Familial hypophosphatemia Sex-linked dominant (XLH) Sporadic form (new mutations) Autosomal dominant Hypercalciuric form (HHRH)

766


E. Radiographic Findings The most marked changes occur at the cartilagemetaphysis junction just under the growth plates. The space is widened by the accumulation of uncalcified cartilage which will cause fraying, cupping, widening, and fuzziness of the zone of provisional calcification. These changes are better and earlier detected in the most active growth plates: distal ulna and femur, and proximal and distal tibia. Changes in the diaphyses may not be evident when metaphyseal changes are first detected. They will appear later as coarse trabeculation and, in case of increased resorption, as cortical thinning and subperiosteal erosion. Another sign of hyperparathyroidism is the disappearance of the lamina dura that normally surrounds tooth sockets.

F. Biochemical Findings In calcipenic rickets, the initial reaction to decreased intestinal calcium absorption is hypocalcemia which may cause tetany or convulsions. In a second stage secondary hyperparathyroidism corrects the calcemia at the expense of the skeleton. Increased resorption will translate into progressive osteopenia and restore normal serum calcium levels. It is at this stage that the radiological changes become evident. The renal response to increased PTH includes increased reabsorption of calcium and reduced reabsorption of phosphate, leading to increased phosphaturia which, if sustained, results in hypophosphatemia, further compromising the mineralization process. In a third stage, with further bone demineralization, the calcemic response to PTH decreases and hypocalcemia reappears. In phosphopenic rickets, since serum calcium remains normal, there are no clinical signs of nerve irritability or secondary hyperparathyroidism. Hence the absence of osteopenia. The hallmark of this form of rickets (except in the rare cases where there is insufficient phosphate intake) is an increased renal loss that may have different mechanisms (see below). It is usually more severe in the acquired forms [i.e., tumor-induced osteomalacia (TIO)] than in the familial forms of hypophosphatemia. Serum alkaline phosphatase activity is uniformly elevated in all forms of rickets, and the levels reflect the severity of the bone disease. Normal values are up to 300 IU/liter in growing individuals. Although alkaline phosphatase is not specific to bone, the bone isozyme represents over 80% of total activity in growing individuals, who have no liver dysfunction. There is thus no need to assess the bone specific isozyme activity in children, the simple testing of total alkaline phosphatase ac-

tivity is adequate to evaluate the severity and monitor treatment of rickets. Serum 25-hydroxyvitamin D [25(OH)D] concentrations are depressed in vitamin D-deficiency rickets and are usually below 14 ng/ml (34 nmol/liter). In all other forms, concentrations are normal (14 to 45 ng/ml or 34 to 91 nmol/liter) or may be very much elevated in case of prior treatment with large amounts of vitamin D at time of referral of a vitamin D-refractory form. Serum concentrations of 1,25-dihydroxyvitamin D [1,25(OH)2D] vary widely. Normal values are 27 to 56 pg/ml (65 to 134 pmol/liter). They are elevated in cases of calcium deficiency, target organ resistance by alterations of the vitamin D receptor (HVDRR), and the hypercalciuric form of familial hypophosphatemia (HHRH). In simple vitamin D deficiency they may be either low, normal, or elevated. The reason for the normal or elevated levels is uncertain but may be related to a maximal up-regulation of l oL-hydroxylase, due to the deficiency, and the blood sample obtained after brief exposure to sunlight or the ingestion of a small amount of vitamin D. In pseudodeficiency (PDDR), serum 1,25(OH)2D levels are markedly decreased, sometimes undetectable. They do not increase significantly after administration of large amounts of vitamin D, reflecting the defect in loLhydroxylase activity. Interestingly, they are similarly decreased in TIO. The ability of TIO patients to maintain normocalcemia despite depressed levels of 1,25(OH)2D has not been explained.

G. Vitamin D Therapy Vitamin D2 or D3 is used in the treatment of vitamin D deficiency rickets. Initial dose may vary from 2000 to 5000 IU/day. Such low dosages decrease the probability of toxic effects and do not mask non-nutrient forms of rickets. Healing requires 6 to 12 weeks of therapy. The most sensitive biochemical index of healing is a return to normal of alkaline phosphatase activity. When achieved, vitamin D supplementation may be reduced to the recommended daily allowance of 400 IU. An adequate calcium intake is necessary to avoid severe hypocalcemia following the inception of vitamin D therapy and to ensure healing. Dietary intake or supplementation should provide about 50 mg/kg/day of elemental calcium. The use of vitamin D metabolites or their analogs has no place in the treatment of vitamin D deficiency. They should be restricted to the treatment of the various heritable forms of rickets (see below).

CHAPTER 26 Metabolic Bone Disease in Children H. H e r i t a b l e C a l c i p e n i c R i c k e t s Patients whose tickets had similarity to vitamin D resistant (hypophosphatemic) tickets in requiting large therapeutic doses of vitamin D and yet differed markedly in its clinical and biochemical features, were recognized as suffering from a separate disorder. 82 The clinical course of this disorder, despite an adequate intake of vitamin D, was similar to that of ordinary rickets due to vitamin D deficiency, and the disorder was therefore named pseudovitamin D-deficiency rickets. 83 It was noted that therapy with very large doses of vitamin D resulted in remission of the disease, and the disease was also called vitamin D-dependent rickets. 84 Clarification of the abnormalities in vitamin D metabolism 82 led to the recognition that this condition was likely due to a defect in the renal l oL-hydroxylase enzyme. It is characterized by low serum 1,25(OH)zD concentration and rapid and complete therapeutic response to calcitriol (i.e., 1,25(OH)zD3). Subsequently, another condition was recognized that develops despite high circulating concentrations of calcitriol. It is due to end-organ resistance to 1,25(OH)zD, consecutive to a spectrum of mutations affecting the vitamin D receptor (VDR) in target tissues. 1. PSEUDOVITAMIN D DEFICIENCY

Almost all the clinical and biochemical features of PDDR are similar to those of vitamin D-deficient rickets. Clinically, the child is well at birth and within the first year of life develops hypotonia, muscle weakness, inability to stand or walk, growth retardation, convulsions, frontal bossing, and the signs of severe rickets-rachitic rosary, thickened wrists and ankles, bowed legs, and fractures. A history of adequate intake of vitamin D is usually obtained. Laboratory investigations (Table 2 6 - 5 ) reveal hypocalcemia with secondary hyperparathyroidism and associated increased urinary cyclic adenosine monophosphate (cAMP) and amino acid excretion, elevated serum alkaline phosphatase activity, either hypo- or normophosphatemia, phosphaturia, a low urinary calcium excretion, and decreased intestinal absorption of calcium. The condition is inherited as an autosomal recessive trait 84-86 and the incidence of parenteral consanguinity is high. It is particularly frequent in French-Canadians from the Saguenay region of Quebec, where the estimated gene frequency is 0.02. 87 A similar syndrome in a mutant strain of domestic pigs has been described. 88'89 This porcine model is morphologically and biochemically similar to the human condition, and is also inherited as an autosomal recessive trait. The pathogenesis of this disorder was elucidated by studying vitamin D metabolism in affected patients. It

767 was observed that massive doses of vitamin D3 and high doses of 25(OH)D3 but only small doses of 1,25(OH)zD3 were required to correct the clinical and biochemical abnormalities in PDDR patients. 82 This provided indirect evidence that the condition was due to an inborn error of vitamin D metabolism in which there was a defect in the renal l a-hydroxylase enzyme, the enzyme which converts 25(OH)D3 to 1,25(OH)2D3. Studies of circulating vitamin D metabolites in patients further supported this hypothesis. The serum 25(OH)D3 concentration was normal in untreated patients and high in patients treated with vitamin D, whereas the serum concentration of 1,25(OH)zD3 was low in untreated patients 9~ and remained low in patients treated with vitamin D3 .91 Absence of l e~-hydroxylase activity was recently documented in decidual cells of human placenta, 92 which thus represent another target for the PDDR mutation. The recommended treatment for PDDR patients is replacement therapy with calcitriol. An initial dose of 1 to 3 Ixg/day will induce healing of rickets within 7 to 9 weeks. The maintenance dose is about half the initial dose 9~ and will probably have to be continued throughout life. It is remarkably stable, with only temporary increase during pregnancy (unpublished data). Molecular genetic studies utilizing linkage studies in affected French-Canadian families have mapped the PDDR gene to chromosome 12q 14. 93 In addition, linkage disequilibrium data using three closely linked polymorphic loci from this region were consistent with the presence of a founder effect in the French-Canadian population. In order to clone this gene, which is likely to encode the l oL-hydroxylase, a rat renal cDNA library constructed from kidneys of vitamin D-deficient rats was screened at reduced stringency, using a 3' rat 24hydroxylase cDNA that encompasses a common hemebinding domain of the molecule. 94 A full-length 2.4 Kb cDNA that encodes a predicted 55-kDa protein with 78% amino acid sequence similarity to the 24-hydroxylase within the heme-binding domain was identified. The protein sequence showed reduced similarity outside this region, and transient expression of the 2.4 Kb cDNA in embryonal carcinoma cells resulted in the production of a vitamin D metabolite that had the assay characteristics of 1,25(OH)eD. 94 Further mapping studies of the human homologue of this novel rat 2.4-Kb cDNA, that encodes the putative 1oL-hydroxylase, to chromosome 12q14 and the detection of mutations in PDDR patients will help to establish the candidacy of this clone as the l oL-hydroxylase gene.

2. HEREDITARY 1,25(OH)2D-RESIsTANT RICKETS HVDRR is an autosomal recessive disorder in which there is end-organ resistance to 1,25(OH)zD3. 95-97 The clinical features are similar to those found in PDDR

TABLE26-5

Biochemical and Genetic Details of the Major Forms of Familial Ricketsa Serum

TYpe Renal tubular defect Hypophosphatemic rickets (XLH) Lowe's syndrome Dent's disease Vitamin D metabolism defect Pseudo-vitamin Ddeficient rickets (PDDR) Hypocalcemic vitamin Dresistant rickets (HVDRR)

Ca2+

PO:-

Urineb

1,25(OH),D,

PTH

N

1

LlN

N

N/& N

1 1

1lN

NIT

1

1lN

1

1lN

PO:-

Ca2+

Aminoaciduria

Glucose

pH GAC CAC---~CAG AAA---)GAA GCC---~GAC TTC~ATC CGA-->CAA CGA---)CAA CGA-->TGA CGA--~CAA CGG---~CAG

Gly 33Asp His35Gln Lys45Glu Gly46Asp Phe47Ile Arg507Gln Arg730Gln Arg73 Stop Arg73Gln Arg80Glu

CAG---~TAG

Gln152Stop

m

109 211 212 213 212 214 109 215 109 216 217

Hinge 215

218 Vitamin D binding

TGT~TGG CGC---~CTC TAC-->TAA

Cys190Trp Leu274Arg Tyr295 Stop

CAC---~CAG

His305Gln

_

m

m

218 219 215

m

ergy x-ray absorptiometry (DXA)] is normal to high normal. On histological sections of trabecular bone, osteomalacia is characterized by excessive accumulation of unmineralized osteoid tissue and very little resorption activity. There is not osteopenia in sharp contrast with what is observed in calcipenic rickets (with secondary hyperparathyroidism). In keeping with a sex-linked dominant mode of inheritance, the disease manifestations are more severe in males than in females, some of whom may be asymptomatic, have no skeletal involvement, and exhibit only hypophosphatemia. ~3 They represent the "carriers" for the trait and provide evidence that hypophosphatemia cannot solely explain the bone changes. b. Biochemical Findings. The major abnormalities are hypophosphatemia and hyperphosphaturia resulting from a low threshold (TmP/GFR) for renal phosphate. Renal function is otherwise normal and glycosuria, aminoaciduria, and acidification defects are notably absent. A normal serum calcium and an absence of secondary hyperparathyroidism in untreated patients are also important diagnostic features (Table 26-5). Urinary calcium excretion and intestinal absorption of calcium and phosphate are low. 114 Serum alkaline phosphatase activity, which varies with age and correlates with the rate of bone formation, ~15 is elevated in affected individuals with tickets, but is normal in hypophosphatemic individuals without active bone disease. The circulating con-

centration of 25(OH)D3 is normal in hypophosphatemic patients ~6 and that of 1,25(OH)3D3 is either norma1117-12~ or low. 91 It has been argued that 1,25(OH)zD levels were inappropriately low in the face of chronic hypophosphatemia. Whatever the cause, this relative decrease in 1,25(OH)zD synthesis is not severe enough to significantly impair intestinal calcium absorption. Normocalcemia is the rule and there is no secondary hyperparathyroidism. c. Treatment. XLH had traditionally been treated with large doses of vitamin D. 8~ Infants received 10,000 to 25,000 IU/day of vitamin D, and older children up to 300,000 IU/day. ~21 This resulted in significant healing of the rickets and reduced the need for osteotomies of the tibia and femora to correct the bone deformities. ~5 However, hypophosphatemia persisted, growth rate was not markedly improved, and vitamin D intoxication with hypercalcemia and renal damage sometimes occurred.lZ2 To offset the phosphate loss, oral phosphate supplements (1 to 4 g/day) were administered at frequent intervals, four to five times a day, and were effective in producing normophosphatemia. 123 However, the hypocalcemic effect of phosphate therapy often induced secondary hyperparathyroidism ~23'124 and large doses of vitamin D were added to prevent it, increasing the risk of vitamin D intoxication and renal damage. A combination of 1,25(OH)zD3 (0.5 to 1.0 Ixg/day) plus phosphate seems to be the most effective treatment for this disease. 125-128

CHAPTER 26 Metabolic Bone Disease in Children This combined therapy resulted in improved phosphatemia and growth velocity. It also healed rickets and osteomalacia as assessed by a fall in serum alkaline phosphatase activity, and normalized radiographs and bone histology. However, complications of treatment do still occur, with nephrocalcinosis developing in some patients. 129 Phosphate-induced secondary hyperparathyroidism is a constant concern, as in some patients it may become autonomous and require surgery. 13~ Particularly in boys, the growth-promoting effects of therapy are not always striking. For that reason, the adjunct of recombinant growth hormone, as a third therapeutic component, was recently advocated. Definite positive effects have been observed in young XLH patients. TM Larger scale studies will be necessary to definitely establish the long-term benefits of this therapeutic regimen. d. Molecular Genetics. The first familial occurrence of vitamin D-resistant rickets was described in a mother, her son, and her daughter. 132 Skeletal deformities were used to ascertain the affected phenotype, and an autosomal dominant mode of inheritance was proposed. However, it was observed that the severity of skeletal deformities varied and that some hypophosphatemic females had no evidence of rickets. When hypophosphatemia was used as the discriminant, an X-linked dominant mode of inheritance was established. 112'113'133 The males were uniformly more severely affected than the females, who sometimes had no evidence of rickets. This variability in female patients, which is expected in an X-linked disease, can be explained by the Lyon hypothesis of X-chromosome inactivation, which states that one of the X chromosomes in a pair is randomly inactivated in each cell of the early female e m b r y o . TM The subsequent daughter cells have inactivation of the same X chromosome as their mother cell. Thus a female hypophosphatemic patient is a mixture of cells some of which have an active normal X chromosome and some of which have an active "hypophosphatemic" X chromosome. The relative proportions of each cell type vary from female to female, due to the randomness of the inactivation process, and this would in turn determine the variable expression of the X-linked hypophosphatemic rickets gene in females. Further support for this comes from phosphate infusion studies in hypophosphatemic patients and normals. These demonstrated that hypophosphatemic males (hemizygotes) had decreased maximum tubular capacity for reabsorbing phosphate (TmP), while hypophosphatemic females (heterozygotes) had a TmP that was intermediate between that of normals and hypophosphatemic males. 123 About one third of the patients present with a negative family history but cannot otherwise be differentiated from the XLH form. We have observed in two instances, such

771 "sporadic" female subjects to give birth to affected babies (unpublished). This implies that sporadic cases carry, in fact, new XLH mutations. It also indicates that the mutation rate for the trait is rather high. Family segregation studies (Fig. 2 6 - 1 ) using restriction fragment length polymorphisms (RFLPs) and microsatellite polymorphisms mapped the HYP gene to Xp22.1 and defined an approximate 1 cM (equivalent to 1 Mb) map around the disease lOCUS. 136-142 A contig (i.e., a series of overlapping clones) of the region was constructed using yeast artificial chromosomes (YACs) 143'144 and the size of the region containing the HYP gene was defined to be 350 Kb. Cosmids were isolated from this region and were used to identify possible microdeletions in XLH patients. Four such microdeletions ranging in size from 1 Kb to 55 Kb were identified, and the cosmids detecting these were used to search for the HYP gene by two approaches. 145 In one approach the cosmids were used to screen cDNA libraries of fetal brain, fetal liver and adult muscle, and in the other approach the DNA sequences of the cosmids were determined and examined for possible encoded regions. Both approaches indicated the presence of a gene in an --~100-Kb region, and a partial 1.9-Kb cDNA was isolated. Sequence analysis revealed that the gene encoded a protein that had similarities to the family of endopeptidase genes such as neutral endopeptidase, endothelin-coverting enzyme-l, and the Kell-antigen, and the gene was therefore called PEX (phosphate-regulating gene with homologies to endopeptidases on the X chromosome). These endopeptidases generally consist of a short cytoplasmic N-terminal domain, a single transmembrane domain, and a large extracellular C-terminal domain that contains a zincbinding motif and ten conserved cysteine residues. Analysis of the PEX partial sequence confirmed the presence of the putative transmembrane domain and part of the large extracellular domain that included the zincbinding motif and seven of the ten conserved cysteine residues. Mutational analysis of the PEX gene in XLH patients has identified a number of different genetic abnormalities which include nonsense mutations resulting from frame shifts due to base pair deletions and insertions; missense mutations; splice site mutations; and genomic deletions. 145-148 These mutations (i.e., the nonsense mutations) indicate that a loss of function of PEX is involved in the etiology of this form of hypophosphatemic tickets. However, the mechanisms whereby PEX mutations lead to the XLH phenotype remain to be elucidated by first determining the tissues in which PEX is expressed and second by defining its physiological role in these organs. An investigation for PEX expression by Northern blot analysis of human adult heart, brain, placenta, lung, liver, skeletal, muscle, kidney, and pancreas,

772

F ~ q c I s H. GLORIEUX, GERARD KARSENTY, AND RAJESH g. THAKKER

FIGURE 26-- 1 Segregation of DXS 1683 and HYP in family 5/95. Genomic DNA from the family members (upper panel) was used with [,y32p] adenosine triphosphate (ATP) for polymerase chain reaction (PCR) amplification of the polymorphic repetitive elements at the DXS 1683 locus. The PCR amplification products were detected by autoradiography on a polyacrylamide gel (lower panel). PCR products were detected from the DNA of each individual and were designated alleles as shown on the right. For example, individual 1.2, the affected mother, reveals two pairs of bands on autoradiography. The upper pair of bands is designated allele 2 and the lower pair of bands is designated allele 3. The upper band in the pair is the "true" allele, and the lower band in the pair is its associated "shadow" which results from slipped-strand mispairing during PCR. The segregation of these alleles together with the disease (HYP) can be studied in the family members, and the patemal allele is shown on the left. Thus, at DXS 1683, the disease is segregating with allele 3 and the probability that these two loci are linked can be expressed as a "LOD score," which is log10 of the odds ratio favoring linkage and is defined as the likelihood that two loci are linked at a specified recombination 19 versus the likelihood that the loci are not linked. In family 5/95, the disease and DXS1683 are co-segregating without recombination, and the likelihood of linkage at 19 = 0 is therefore 1. If the disease and DXS 1683 were not linked, then the disease would be associated with allele 2 in one half (1/2) of the children and with allele 3 in the remaining half (1/2) of the children. This is not observed in the seven children of generation II, in which all the affected children have inherited allele 3 and all the unaffected children have inherited allele 2. The likelihood that the two loci are not linked is (1/2). The odd ratio in favor of linkage between the disease and DXS 1683 loci at 19 = 0, in family 5/95, is therefore 1/(1/2) 7 (i.e., 128), and the LOD score is log10 128 = 2.10. LOD scores from different families can be combined and a LOD score >+3, establishes linkage between two loci. DXS1683 was shown by physical mapping studies and by construction of a YAC contig to be within less than 300 Kb of H Y P . 144 Individuals are represented as unaffected males (t3), affected male (I), unaffected female (o) and affected female (e).

a n d o f fetal h e a r t , b r a i n , liver, lung, a n d k i d n e y h a s n o t

e.

Tumor-Induced

Osteomalacia.

T u m o r - i n d u c e d or

a 6.6-Kb

o n c o g e n i c r i c k e t s a n d o s t e o m a l a c i a is a r a r e a c q u i r e d

m R N A t r a n s c r i p t h a s b e e n i d e n t i f i e d in m o u s e b o n e a n d c u l t u r e d o s t e o b l a s t s . 149 T h e g e n e r a l f u n c t i o n o f t h e n e u -

phaturia, low circulating 1,25(OH)zD levels, and rickets

identified PEX

mRNA

transcripts,

although

disorder characterized by hypophosphatemia, hyperphos-

and

a n d o s t e o m a l a c i a . It o c c u r s in p r e v i o u s l y u n a f f e c t e d in-

t h e r e b y alter t h e a c t i v i t y o f t h e s u b s t r a t e , w h i c h m a y b e

d i v i d u a l s . 14~ It is d i s c u s s e d h e r e b e c a u s e t h e r e are simi-

a h o r m o n e s u c h as o x y t o c i n , s u b s t a n c e P, a n g i o t e n s i n I, o r a n g i o t e n s i n II. 15~ T h e p u t a t i v e s u b s t r a t e t h a t P E X

phatemia

c l e a v e s h a s y e t to b e i d e n t i f i e d , a n d it is p o s t u l a t e d t h a t

d i f f e r e n c e s . T I O p a t i e n t s m a y h a v e u n d e t e c t a b l y l o w se-

this m a y p o s s i b l y b e a p h o s p h a t e - r e g u l a t i n g h o r m o n e , r e f e r r e d to as " p h o s p h a t o n i n , ''14~ that m a y a l s o b e se-

r u m concentrations of 1,25(OH)zD3 despite h y p o p h o s p h a t e m i a . T h e m e c h a n i s m s b y w h i c h T I O p a t i e n t s are

tral

endopeptidases

is

creted by some tumors

to

cleave

peptide

bonds

associated with hypophospha-

temic osteomalacia (see below).

larities b e t w e e n this t u m o r - i n d u c e d f o r m o f h y p o p h o s and

XLH.

There

are,

however,

important

a b l e to m a i n t a i n n o r m o c a l c e m i a d e s p i t e an e v i d e n t def e c t in 1 , 2 5 ( O H ) z D s y n t h e s i s h a v e n o t b e e n e l u c i d a t e d .

CHAPTER 26 Metabolic Bone Disease in Children Unlike XLH patients, TIO patients often suffer from a severe proximal myopathy. Aminoaciduria, most frequently glycinuria, and glycosuria are occasionally present. Typical rachitic changes are present on radiographs of bone metaphyses. There is also osteopenia, pseudofractures, and coarse trabeculation. On histological sections, almost all surfaces are covered by thick osteoid seams with no evidence of increased resorption. The tumors associated with TIO are usually of mesenchymal origin and include hemangiomas, angiosarcomas, giant cell tumors of bone, sclerosing angiomas, hemangiopericytomas, and nonossifying sarcomas. These tumors are often small, difficult to locate, and may involve any organ. Tumors of epithelial o r i g i n m f o r example, breast and prostatic carcinomas--have also been observed to be associated with this disorder. A complete surgical removal of the tumor rapidly corrects all the abnormalities, and it has been postulated that the tumor may secrete a factor, referred to as phosphatonin, 14~which inhibits the renal tubular reabsorption of phosphate. Recent studies of a sclerosing hemangioma from a patient with oncogenous osteomalacia have revealed that the medium in which the tumor cells were cultured was able to inhibit sodium-dependent phosphate transport in opossum kidney epithelial cells. TM This alteration in phosphate transport was not associated with an increase in cellular concentration of cAMP. In addition, the medium was found to have PTH-like immunoreactivity but no PTHrP immunoreactivity, and its action was not blocked by a PTH antagonist. The role of this possible humoral factor, which may represent a substrate for PEX in the control of phosphate homeostasis, remains to be elucidated. These functional studies are likely to be greatly facilitated by the investigation of two mouse models for human XLH (see below). The evident treatment of TIO is a complete resection of the involved tumor. When the tumor is not clearly identified or cannot be fully removed, medical therapeutic intervention is warranted. As in XLH, it is based on the association of 1,25(OH)2D3 (1 to 3 Ixg/day) and phosphate salts (2 to 4 g/day). Little information is available regarding the long-term effects of such treatment. It is likely that the same secondary effects in treated XLH patients (nephrocalcinosis and hyperparathyroidism) may also develop in treated TIO subjects. Thus careful monitoring of urinary calcium, and parathyroid and renal function is mandatory.

f Hypophosphatemic Mouse Models: hyp and gyro. The investigation of the etiology of X-linked hypophosphatemic rickets in man has been facilitated by the investigation of two hypophosphatemic mouse models. The first of them was reported when mutant male mice were observed to have a shortened trunk and limb

773 deformities in association with hypophosphatemia. 152 This mutant was allocated the gene symbol hyp. The second hypophosphatemic mouse model was called gyro, as the mutant mice exhibited circling behavior. ~53 The hyp mice showed close similarities to the human XLH. The hyp mice were characterized by dwarfism, diminished body weight, and bone deformities associated with rickets. Biochemical determinations demonstrated hypophosphatemia together with a high renal phosphate loss, elevated serum alkaline phosphatase, a marginally lower plasma calcium, a normal serum PTH concentration, and an absence of glycosuria and aminoaciduria. Serum 25(OH)D3 concentrations were either normal or low and 1,25(OH)2D3 concentrations were within the normal range. 122'154 Intestinal transport of phosphate was markedly reduced and that of calcium was mildly reduced. ~55 Vitamin D supplements had no effect on intestinal phosphate transport but increased intestinal calcium transport. Bone histology confirmed the presence of rickets and osteomalacia. 17~ The gyro mice exhibit circling behavior in addition to hypophosphatemic rickets. The original mutant was a circling female found among the offspring of a female that had received irradiation when a fetus of 17 days' gestation. 156 The gyro mice are similar to the hyp mice in morphological features, serum phosphate values, renal excretion of phosphate, and impairment of sodiumdependent phosphate co-transport by renal brush border membrane vesicles. ~53 Bone histology revealed osteomalacia. 153'157 The traits that differentiate the gyro from the hyp mice are a circling behavior, hyperactivity, deafness, lack of postural reflexes, oligospermia, male sterility, and a higher incidence of sudden death. Histopathological examination of the inner ear of male gyro mice showed three abnormalities in the organ of Corti: the acoustic ganglion was deficient in cell bodies, hair cells were degenerate, and the tectorial membrane was detached. The vestibular sense organs were also abnormal, the sacculus and utriculus were atrophic, and the semicircular canals were stenotic. These inner ear abnormalities were not found in male hyp mice. 153 Genetic studies of hyp and gyro mice mapped both disorders to the distal part of the mouse X chromosome, 152-153 and the location of the human HYP locus was found to be in the evolutionary conserved synthenic region. 136 The location of the murine hyp was refined by interspecific backcross studies, ~58 and pex, the murine homologue of the human PEX gene has been cloned. 149 The complete cDNA sequence of the mouse pex has been isolated and encodes a 749-amino-acid sequence that has 95% identity to the partial known human PEX sequence, which has homologies to the neutral endopeptidase family. Interestingly, Northern blot analysis of normal mouse bone and cultured osteoblasts revealed a

774


6.6 Kb mRNA indicating the presence of large untranslated regions of the pex mRNA transcript. However, pex mRNA transcripts were not similarly detected by Northern blot analysis from hyp mouse osteoblasts. Initially mutational analyses could not detect mutations in the hyp mouse pex coding region, suggesting that in hyp mice, the pex mutations might be within the regulatory or untranslated regions that then result in reduced pex gene expression. 149 Recently, deletions of the 3' and 5' pex regions have been reported in hyp and gyro mice, respectively. 159 These findings establish that Hyp and Gy are allelic mutations and that both provide homologous mouse models for X-linked hypophosphatemia. The latter should facilitate functional studies to further understand the pathophysiology of the human condition.

g. Studies of Phosphate Transport. In vivo and in vitro studies of phosphate transport in the normal and hyp mouse have shown that renal phosphate transport is complex and involves two (or more) gene products. Renal cross-transplantation studies in the hyp and normal mice indicate that the kidney may not be the major organ involved in pex expression and thereby directly in the etiology of hyp. 160"161 Kidneys transplanted from hyp mice to normal nephrectomized mice resulted in a normal conservation of phosphate, and kidneys transplanted from normal mice to nephrectomized hyp mice resulted in phosphate wasting. Thus, the disease was neither transferred nor corrected by renal cross-transplantation, thereby indicating that the hyp kidney is unlikely to have a direct etiological role in this disease. However, in vitro studies have demonstrated a renal tubular defect of phosphate transport in the hyp mouse. The site of the defect has been localized by micropuncture studies to the cells of the proximal convoluted t u b u l e . 162'163 Further definition of the site of the phosphate transport defect was provided by observing separately the fluxes of phosphate across the basolateral and luminal brush border membranes from hyp and normal m i c e . 164 These studies indicated that the abnormality of phosphate transport in the hyp mouse was the result of a defect in renal sodiumphosphate co-transport in the brush border membranes and that it was associated with a decrease in the sodiumphosphate co-transporter NPT2 mRNA and protein. ~65 However, the human NPT2 gene has been mapped to c h r o m o s o m e 5q35,166 and the mechanisms whereby a defect in the X-linked PEX gene result in reduced expression of the autosomal NPT2 gene remain to be defined. This defect in phosphate transport demonstrated by the in vitro studies of the hyp mouse appears to be confined to the kidney, as phosphate transport has been demonstrated to be normal in the jejunum 167 and the 0 steoblast. 168,169

h. Studies of Osteoblast Function. Several observations indicate that low serum phosphate levels cannot fully account for the bone abnormalities in XLH and that an osteoblast dysfunction contributes to the bone disease. Indeed, the severity of the bone lesions does not correlate with the degree of hypophosphatemia. 113 Furthermore, phosphate supplementation in affected patients and mutant mice heals the rickets but fails to correct osteomalacia. 125'17~ An intrinsic osteoblast defect was first proposed by F r o s t 171 in view of the hypomineralized periosteocytic lesions present in XLH bone. These lesions also seen in Hyp mice 172 are not observed in other forms of chronic hypophosphatemia and never completely disappear in treated patients despite correction of the osteomalacia. 173 This was further investigated in the mouse model. Transplantation studies of hyp osteoblasts indicate that osteoblasts are likely to be a major site of pex expression, consistent with the results from Northern blot analysis. 149 Transplantation of hyp osteoblasts into normal mice resulted in the production of abnormal bone that had increased volume and osteoid thickness. 174 These effects were intrinsic to the osteoblasts and independent of extrinsic factors such as hypophosphatemia, as similarly transplanted osteoblasts from phosphatedepleted normal mice produced normal bone. In vitro studies have also demonstrated hyp osteoblasts to have an abnormal response to 1,25(OH)zD3. Normal mouse osteoblasts respond to 1,25(OH)zD3 by increasing alkaline phosphatase activity and by decreasing cell proliferation, but these responses are absent in the hyp osteoblasts. 175 However, increasing the phosphate concentrations rendered the hyp osteoblasts responsive, thereby indicating that extracellular phosphate may modulate the hyp osteoblastic response to 1,25(OH)D3. 2. HEREDITARY HYPOPHOSPHATEMIC RICKETS WITH HYPERCALCIURIA

In 1962176 and 1964,177 two groups reported on a small number of children presenting with hypophosphatemic rickets and hypercalciuria. No explanations were given at the time for this uncommon association. In 1985, Tieder et al. 178 reported on nine cases, all part of a single large pedigree in which they have subsequently identified a number of asymptomatic individuals with "idiopathic hypercalciuria." 179 The HHRH clinical picture resembles that of XLH: lower limb deformities and stunted growth. Muscle weakness (not part of XLH) has been reported in some patients. On x-ray, active rickets and osteopenia are evident. The mode of inheritance is most probably autosomal recessive. B iochemically, there is normocalcemia, increased alkaline phosphatase activity, and hypophosphatemia due

CHAPTER 26 Metabolic Bone Disease in Children to increased renal phosphate loss. Hypercalciuria is most evident after a meal or an oral calcium load. It disappears after a 15-hour fast. The salient abnormality is an elevated serum concentration of 1,25(OH)zD, which is the probable cause of increased intestinal calcium absorption. It has been suggested that these high concentrations of 1,25(OH)zD were the expected response to hypophosphatemia, in contrast to the "inappropriately low" levels of the metabolite in XLH serum. This hypothesis remains untested. The genetic defect in HHRH is unknown. There has been no report of attempts at locating the HHRH locus on the genome, to establish possible linkage with genes involved in the control of phosphate transport. Treatment is based on supplementation with high doses of phosphate salts (1 to 3 g/day in four or five divided doses). Within a few weeks, muscle strength and bone pain improve substantially, and growth rate increases with the healing of rachitic lesions. Unlike XLH, there is no need for calcitriol as an adjunct to phosphate therapy, as basal circulating levels are very high. There is no report on long-term effects of the treatment. Noticeably, the common complications found in XLH (nephrocalcinosis and hyperparathyroidism) are not encountered in HHRH patients. 3. FANCONI SYNDROME

Fanconi syndrome is characterized by multiple defects of the proximal renal tubule. There is renal wastage of amino acids, glucose, bicarbonate (leading to metabolic acidosis), phosphate (leading to hypophosphatemia), sodium, uric acid, proteins, and potassium (leading to hypokalemia). Serum calcium is normal, and calciuria varies. The clinical manifestations included rickets, lower limb deformities, and impaired linear growth. Clearly, hypophosphatemia is the major factor underlying rickets and osteomalacia. It is possible, however, that acidosis plays a contributing role, since bone serves as a buffer for excess of hydrogen ion. The excess acid is buffered by calcium carbonate leading to dissolution of bone mineral and may cause hypercalciuria. A possible impairment of 1,25(OH)zD synthesis, due to tubular dysfunction and/or acidosis was also documented in animals, ~8~ but not in human studies. 181 Circulating levels of 1,25(OH)2D are normal in Fanconi syndrome, 182 a finding similar to what is observed in XLH patients. Rickets is treated, as in XLH, with a combination of phosphate and 1,25(OH)2D3. Dosage and monitoring follow the same guidelines as in XLH. Alkali therapy may be used to correct the metabolic acidosis and potassium supplements to control hypokalemia. Fanconi syndrome is often idiopathic, but may also be caused by toxic agents including mercury, lead, cad-

775 mium, streptozotocin, and outdated tetracycline. It may also be found in association with inborn errors of metabolism that affect proximal renal tubule function. These include glycogen storage disease, galactosemia, cystinosis, tyrosinemia, and hereditary fructose intolerance. In recent years, advances have been made in the molecular understanding of two such forms of Fanconi syndrome: the syndrome of Lowe and Dent's disease. They are discussed below.

a. The Oculocerebrorenal Syndrome of Lowe. The oculocerebrorenal (OCRL) syndrome of Lowe is an Xlinked recessive disorder that is characterized by congenital cataracts; mental retardation; muscular hypotonia; rickets; and defective proximal tubular reabsorption of bicarbonate, phosphate, and amino acids. 183 The disease is nearly always confined to males, who develop renal dysfunction in the first year of life, have delayed bone age and reduced height, and may die in childhood. Female carriers who have normal neurological and renal function can be identified in 80% of cases by micropunctate cortical lens opacities. 184'185Family studies have confirmed the X-linked recessive inheritance. ~86,187 The Lowe's syndrome gene was mapped to the distal part of the long arm of the X chromosome at X q 2 5 q26, by using RFLPs in family linkage studies 188 and subsequent analysis of a patient with Lowe's syndrome who had an X-chromosome break point helped to further localize the gene. 189 The use of YACs, which spanned the break point, to screen cDNA libraries identified a candidate gene (designated OCRL), which was absent or of an abnormal size in male patients with Lowe's syndrome. The predicted protein encoded by this gene revealed a 71% similarity to the gene on chromosome l p for human inositol polyphosphate-5-phosphatase, INPP5B. 19~ This enzyme, which was originally derived from platelets, catalyses the 5-phosphate from 1,4,5inositol triphosphate and from 1,3,4,5-inositol tetraphosphate, thereby presumably inactivating them as second messengers in the phosphatidyl-inositol signaling pathway. Point mutations and deletions were demonstrated in affected individuals, providing conclusive evidence that an altered OCRL gene is the cause of Lowe's syndrome. 191 Further functional expression studies 192 of the OCRL cDNA in baculovirus-infected Sf9 insect cells have revealed that the OCRL protein catalyzes three different reactions in the inositol phosphate pathway. These are the conversions of: inositol 1,4,5-triphosphate to inositol 1,4-biphosphate; of inositol 1,3,4,5-tetrasphosphate to inositol 1,3,4-triphosphate; and of phosphatidyl inositol 4,5-bisphosphate to phosphatidyl inositol 4phosphate, which represents a marked difference from that of the platelet-derived INPP5B. These studies indi-

776


cate that O C R L is mainly a lipid phosphatase that m a y control the cellular levels of the critical metabolite, phosphosphatidyl inositol 4,5-biphosphate, and that a deficiency of this e n z y m e results in the protean manifestations of L o w e ' s syndrome.

b. Dent's Disease. D e n t ' s disease is a renal tubular disorder characterized by a low-molecular-weight proteinuria, hypercalciuria, nephrocalcinosis, nephrolithiasis, and eventual renal failure. D e n t ' s disease is also associated with the other multiple proximal tubular defects of the Fanconi syndrome. ~93 However, the c o m m o n occurrences of hypercalciuria, nephrocalcinosis, and kidney stones in D e n t ' s disease and the unusual or rare association of these in other forms of the Fanconi synd r o m e are important differences. 194 H y p o p h o s p h a t e m i c rickets m a y develop as a c o n s e q u e n c e of h y p o p h o s p h a temia and cause severe limb deformities and shortness of stature. Treatment will be based on phosphate sup-

plements, but the adjunct of 1,25(OH)2D3 is very difficult to monitor in view of the underlying hypercalciuria (unpublished observation). An X-linked inheritance for D e n t ' s disease was postulated on the basis of a greater disease severity in males and an absence of m a l e - t o - m a l e transmission in the families. 193'195 Family linkage studies using X-linked polymorphic genetic markers localized the gene to X p l 1.22.195 In addition, a microdeletion involving the D N A probe M2713, which defines the locus D X S 2 5 5 , was identified in one family with D e n t ' s disease (Fig. 2 6 - 2 ) . This microdeletion was further characterized using YACs from a contig, and deletion m a p p i n g studies revealed that the microdeletion was approximately 515 Kb in size. A search for renal expressed genes from this region using the YACs as hybridization probes to screen a renal c D N A library identified a c D N A that e n c o d e d a protein of 746 amino acids with h o m o l o g i e s to the voltage-gated chloride channel (CLC) gene family, and

FIGURE 26--2 Segregation of Dent's disease with a microdeletion detected by M2713 in family 12/89 (upper panel). Probe M2713, which defines the locus DXS255 and has been localized to Xpll.22, hybridizes to EcoR1 fragments in the range 3 to 7 Kb in normal individuals, and heterozygosity in females exceeds 90%. Hybridization of the Southern blot (lower panel) from family 12/89 with probe M2713 demonstrated an absence of signals in all the affected males (11.3, 11.7, 111.3, 111.7, and IV.2) and only one fragment indicating heterozygosity was detected in the affected females (11.2, 11.6, 11.9, 11.12, and 111.2). A control hybridization of this Southern blot with the probe L1.28, which defines the locus DXS7, yielded signals from all the lanes and demonstrated the presence of DNA in each lane. Thus, a microdeletion involving M2713 is associated with Dent's disease in family 12/89, and this maps Dent's disease to Xpll.22. (From Pook MA, Wrong O, Wooding C, et al: Dent's disease, a renal Fanconi syndrome with nephrocalcinosis and kidney stones, is associated with a microdeletion involving DXS255 and maps to Xpll.22. Hum Mol Genet 2:2129-2134, 1993.)

CHAPTER 26 Metabolic Bone Disease in Children this novel channel is now referred to as CLC-5 and the gene as CLCN5. The CLC channels, which are structurally unrelated to other ion channels and form the only known large family of C1- channels, consist of about 12 transmembrane domains. 196 The first member, designated CLC-0, was cloned in 1990 from the electric organ of Torpedo marmorata and nine different CLCs (CLC-1 to CLC-7, and CLC-Ka and CLC-Kb) encoded, respectively, by genes CLCN1 to CLCN7, and CLCNKa and CLCNKb, have been identified in mammals. 196-198 These chloride channels are important for the control of membrane excitability, transepithelial transport, and possibly regulation of cell volume. 196 CLC channels are known to function as multimeric complexes, and recent studies have revealed that CLC-0 is a homodimer with two largely independent pores. 199-2~176 Some CLC genes are ubiquitously expressed (e.g., CLCN2), whereas others are tissue specific (e.g., CLCN1 is expressed in skeletal muscle and CLCN5 is expressed in kidney). To date, only CLCN1 and CLCN5 are known to have diseaseassociated mutations with the myotonia disorders of Thomsen and Becker, 2~176 and with the hereditary nephrolithiasis disorders (e.g., Dent's disease), respectively. T M The human CLCN5 gene consists of 12 exons that span 25 to 30 Kb of genomic DNA, 2~ and Northern blot hybridization analysis has identified a 9.5 Kb m R N A transcript that is predominantly expressed in the kidney and to a lesser extent in placenta and skeletal muscle. 196 The CLCN5 coding region, which consists of 2238 bp, is organized into 11 exons (exons 2 to 12) with 10 introns. Exon 2 and part of exon 3 encode the 57 amino acids of the N-terminal cytoplasmic domain; the 3' end of exon 3 and exons 4 to part of exon 10 encode the 491 amino acids of the transmembrane domains and loops; and the 3' end of exon 10, exon 11 and part of exon 12 encode the 198 amino acids of the C-terminal cytoplasmic domain. CLCN5 is highly conserved in primates, marsupials, rodents, reptiles, and birds. Heterologous expression of wild-type CLCN5 in Xenopus oocytes has revealed that the channel, CLC-5, conducts chloride currents that are outwardly rectifying and essentially time-independent. T M In addition, ion substitution experiments showed that there was a chloride---~iodide conductance sequence, which is consistent with that reported for the other chloride channels, CLC0, CLC-1, and CLC-2, of this family. Dent's disease is associated with different CLCN5 genetic abnormalities, and heterologous expression of such CLC-5 mutants in Xenopus oocytes has demonstrated an abolishment or a marked reduction in the chloride channels, thereby demonstrating their functional importance. T M Two other X-linked renal proximal tubular disorders associated with hypercalciuric nephrolithiasis and

777 similarities to Dent's disease have been reported. One of these disorders was reported in a North American family and referred to as X-linked recessive nephrolithiasis (XRN) 2~ and the other was reported in an Italian family and referred to as X-linked recessive hypophosphataemic rickets (XLRH). 2~ Family linkage studies of the XRN and XLRH kindreds localized both disease loci to X p l 1.22, 207,208 and genetic analysis of CLCN5 revealed mutations that resulted in a function loss of CLC-5. T M These results indicate that CLCN5 is a chloride channel whose functional loss results in a generalized proximal renal tubular defect (i.e., a Fanconi syndrome), which is associated with the hypercalciuria and nephrolithiasis of Dent's disease, XRN, and XLRH. However, the mechanisms whereby a loss of this renal chloride channel leads to hypercalciuria and the proximal tubular defects remains to be elucidated. The reabsorption of filtered protein occurs in the proximal tubule, whereas that of calcium occurs in the proximal tubule, thick ascending limb of Henle, and distal tubule; one possibility is that a loss of CLC-5 function in the proximal tubule may lead to a decrease in chloride reabsorption which in turn results in decreased calcium reabsorption. 2~ However, this does not explain the abnormal excretion of low-molecular-weight proteins, which are specifically absorbed in the proximal tubule by endocytosis and transported in an acidic vacuolar-lysomal system. 21~ A loss of chloride channel function in this system would prevent the dissipation of the charge that is generated by the electrogenic H+-ATPase pump for the provision of the acidic environment. However, these possibilities need to be explored, and the identification of the specific segments of the nephron that express CLCN5 will represent an important step in this pathway towards understanding further the role and function of CLC-5 in the etiology of hypercalciuria and renal stones.

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Index

A

Alkalosis, hypophosphatemia role, 222 Allopurinol, hyperuricosuric calcium nephrolithiasis treatment, 748 Aluminum hypercalcemia association, 429 hypophosphatemia role, 222 phosphate absorption effects, 190 renal osteodystrophy treatment, 460 Amylin, calcitonin biosynthesis, 101 Angioid streaks, Paget's disease association, 580-581 Ankylosing spondylitis Paget's disease association, 559-560 rheumatoid arthritis association, 626-628 Antibiotics, struvite stone treatment, 755 Anticonvulsant bone disease, enzyme induction, 358359 Antigens, Paget's disease diagnosis, 547, 560 Apatite, s e e Bone apatite Arthritis characteristics, 613 Paget's disease association, 579 rheumatoid arthritis, s e e Rheumatoid arthritis Autoimmune polyendocrinopathy- candidiasis- ectodermal dystrophy, characteristics, 507 Autosomal dominant hypocalcemia, 494-496 biochemical features, 494-495 chromosome 3 linkage, 495 clinical features, 494-495 diagnosis, 495-496 extracellular calcium ion-sensing receptor mutations, 495 therapy, 495-496 Axial osteomalacia clinical presentation, 722-723 etiology, 725 histopathological findings, 723-724

Absorptiometry, s e e s p e c i f i c t y p e s Acetohydroxamic acid, struvite stone treatment, 755 Acidosis hyperphosphatemia, 229 osteomalacia association, 366-367 phosphate absorption effects, 187 phosphate excretion effects, 213 Activating transcription factor 2, skeletal development role, 5 Adrenal hormones, phosphate excretion effects, 213 Age bone changes, computed tomography assessment, 288 calcium absorption effects, 171, 179-180 rheumatoid arthritis, 625 Albright's hereditary osteodystrophy, s e e a l s o Pseudohypoparathyroidism characteristics, 510, 515- 516 McCune-Albright syndrome, 220 Alcoholism hypophosphatemia role, 222 intestinal calcium transport effects, 181 - 182 Alendronate malignancy disease hypercalcemia treatment, 644645 osteoporosis management, 402 Paget's disease treatment, 589 Alfacalcidiol, osteoporosis management, 404-405 Alkaline phosphatase bone turnover marker, 316 characteristics, 7 hyperparathyroidism diagnosis, 467 mineralization defects, 369-370 Paget's disease association, 576-577, 591 785

786

Index

Axial osteomalacia (Continued) laboratory studies, 723 overview, 722 pathogenesis, 725 radiological features, 723 treatment, 725-726 Azotemia, hyperphosphatemia role, 228

B Benzothiadiazides, hypercalcemia diagnosis, 428-429 Bicarbonate bone apatite abnormalities, 41-45 hyperparathyroidism diagnosis, 467 Biglycan, characteristics, 7 Bile salts, calcium absorption role, 170-171, 177 Biochemical markers bone turnover assessment applications bone loss rate, 322-323 exogenous subclinical hyperthyroidism, 538 intervention assessment, 323-324 perimenopausal therapy, 322 biochemistry, 315-316 bone resorption markers calcium, 318-319 CrossLaps, 320-321 deoxypyridinoline, 319-320 free D-Pyr, 320 free Pyr, 320 hydroxylysine, 319 hydroxyproline, 318- 319 Osteomark N-terminal cross-links, 320 plasma tartrate-resistant acid phosphatase, 319 pyridinoline, 319-320 type I collagen carboxy-terminal pyridinoline cross-linked telopeptide, 321 type I collagen degradation products, 320-321 24-hour turnover marker variation, 321 marker formation alkaline phosphatases, 316 free bone gla protein, 318 procollagen peptides, 318 modeling, 314- 315 overview, 313- 314 remodeling, 314-315, 392-393 osteoporosis diagnosis, 392-393 Biopsies applications bone remodeling, 344-345 hyperparathyroidism, 260-261 low-turnover bone disease, 263-264 osteomalacia, 259-260, 344-345

osteoporosis, 256-259 pediatric diseases, 267 predominant hyperparathyroid bone disease, 262263 renal osteodystrophy, 261-266 renal stone formation, 266-267 constraints, 245 evaluation methods histomorphometric parameters, 253- 256 normal values, 256 qualitative evaluation, 251-252 quality control, 256 quantitative evaluation, 252-253 histology techniques applications, 267-269 dehydration, 247 embedding, 247 fixation, 247 immunohistochemistry, 251 sectioning, 247-248 in situ hybridization, 249-251,268-269 staining, 248-249 histomorphometric bone parameters balance, 255 bone formation, 254-255 bone structure, 253- 254 mineralization, 254- 255 molecular parameters, 255-256 remodeling, 255 resorption, 255 tumover, 255 pitfalls, 246-247 prerequisites, 244-245 techniques, 245-246 Bisphosphonates, see also specific types hypercalcemia management, 433 hyperphosphatemia role, 228 malignancy disease hypercalcemia treatment, 644645 osteoporosis management, 400-403, 626 Paget's disease treatment, 585-590 Blood clotting, osteogenesis imperfecta association, 663 hypophosphatemia manifestation, 224 Bone biopsies applications hyperparathyroidism, 260-261 low-turnover bone disease, 263-264 osteomalacia, 259-260, 344-345 osteoporosis, 256-259 pediatric diseases, 267 predominant hyperparathyroid bone disease, 262-263

Index Bone ( C o n t i n u e d ) renal osteodystrophy, 261-266 renal stone formation, 266-267 constraints, 245 pitfalls, 246-247 prerequisites, 244-245 techniques, 245-246 cell types, see specific types density measurement densitometry acronyms, 276 disease course evaluation, 303 ultrasound, 292, 392 development bone morphogenetic proteins, 3-4, 14, 762-763 cell-cell interaction, 12 cell lineage, 5-12 differentiation, 7-10 function, 10-12 origin, 9-10 phenotypes, 5-7 embryology, see Embryology fibroblast growth factor role, 3-5 histomorphometric parameters, 254- 255 limb development, 2-3 osteoblast cells, see Osteoblasts osteoclast cells, see Osteoclasts parathyroid hormone effects, 67 parathyroid hormone/parathyroid hormone-related peptide receptor effects, 77-78 parathyroid hormone-related peptide effects, 7273 pediatric disease role, 759-764 cell differentiation regulation, 760-762 growth factor involvement, 762-763 matrix molecules role, 764 transcriptional skeletal patterning regulation, 760-762 disease, see specific types evaluation methods, see also specific types histomorphometric parameters, 253- 256 noninvasive assessment techniques Compton scattering technique, 280-281 conventional radiographic bone images, 277 Cushing's syndrome, 303 densitometry acronyms, 276 disease course evaluation, 303 fracture locations, 276 historical perspectives, 276-277 magnetic resonance microscopy, 297-298 measurement sites, 276, 301 - 302 method comparison, 302 neutron activation analysis, 280-281 osteoporosis classification, 275, 301,303 perimenopausal evaluation, 303

787 quantitative computed tomography, 286-292 quantitative magnetic resonance, 296-297 quantitative ultrasound, 292-296 radiogrammetry, 279 radiographic absorptiometry, 279-280 radiographic morphometry, 277-279 relevance, 302 results interpretation, 301 single photon absorptiometry, 281-286 X-ray absorptiometry, 281-282, 298- 300, 391-392 normal values, 256 qualitative evaluation, 251-252 quality control, 256 quantitative evaluation, 252-253 fractures, see Fractures histology applications, 267-269 dehydration, 247 embedding, 247 fixation, 247 immunohistochemistry, 251 renal osteodystrophy adynamic bone, 452 divalent-ion metabolism alterations, 453-455 lesions, 452-453 osteomalacia, 452 secondary hyperparathyroidism, 451 sectioning, 247-248 in situ hybridization, 249-251,268-269 staining, 248-249 mineralization, see also Bone turnover biological function, 23-28 bone apatite phosphate abnormalities, 42-45 calcium-phosphorous deposition phase, 29-32 characteristics bone structure, 2 - 3, 28- 29, 314 crystal morphology, 32-36 histomorphometric parameters, 254-255 kinetic definition, 335-338 mineralization mechanisms, 328- 329 osteoid seam life history, 330-331 temporal changes, 28-29 defects bone apatite structure role, 36-41 calcitriol role, 353- 354 carbonate ion role, 41-45 hypovitaminosis D osteopathy histological evolution, 335-338 hypovitaminosis D osteopathy treatment, 371372 impaired mineralization, 334-335 magnesium ion role, 45-46 osteogenesis imperfecta, 665

788 Bone

Index (Continued)

Paget's disease, 569-571 phosphate ion role, 42-45 renal osteodystrophy, 453-455 vitamin D effects, 352-353 fluorescent label width, 332-334 octocalcium-phosphate deposition phase, 30-32 tetracycline-based kinetics, 334 tetracycline data interpretation, 329 modeling, s e e Bone turnover remodeling, s e e Bone turnover resorption calcitonin effects, 102-104, 113-114 1,25-dihydroxyvitamin D effects, 145 escape phenomenon, 112-113 histomorphometric parameters, 255 osteoclast cell role, s e e Osteoclasts skeletal structure balance, 242 bone marrow cells, 243-244 bone surfaces, 238 cancellous bone, 238 cortical bone, 238 histomorphometric parameters, 253- 254 inorganic minerals, 314 lamellar bone, 239-240 matrix, 314 modeling, 240-242 Paget's disease manifestations, 554-562 extremities, 560-562 jaw, 557 pelvis, 560-562 skull, 554-557 spine, 558-560 structural unit, 238-239 turnover, 242 woven bone, 239-240 Bone apatite abnormalities, 36-46 carbonate ions, 41-45 magnesium ions, 45-46 overview, 36-41 phosphate ions, 42-45 amorphous calcium-phosphorous deposition theory, 29-32 osteogenesis imperfecta pathophysiology, 665 temporal changes, 29 Bone density exogenous subclinical hyperthyroidism, 535-538 noninvasive assessment densitometry acronyms, 276 disease course evaluation, 303 ultrasound, 292, 392 overt hyperthyroidism, 534

Bone development, s e e Bone, development; Embryology Bone marrow cells characteristics, 243-244 transplantation calcium II deficiency syndrome treatment, 705 osteopetrosis treatment, 701-702 Bone matrix, s e e a l s o Collagen cell-matrix interactions, 16 characteristics, 314 metabolism, Paget's disease association, 571-575 collagenolysis, 572 hydroxylysine excretion, 572-573 hydroxyproline excretion, 572-573 noncollagenous bone protein metabolism, 574575 nondialyzable urinary hydroxyproline, 573-574 pagetic bone matrix, 571-572 serum procollagen peptides, 574 mineralization defects, 368-369 osteoid seam life history, 330-331 phosphate transport, 215 skeletal development role, 764 Bone morphogenetic proteins embryologic function, 3-4, 14 skeletal development role, 762-763 Bone sialoprotein, characteristics, 6 Bone turnover, s e e a l s o Bone, mineralization biochemical markers applications, 321-324 bone loss rate, 322-323 intervention assessment, 323-324 perimenopausal therapy, 322 biochemistry, 315- 316 bone resorption markers calcium, 318- 319 CrossLaps, 320-321 deoxypyridinoline, 319-320 free D-Pyr, 320 free Pyr, 320 hydroxylysine, 319 hydroxyproline, 318-319 Osteomark N-terminal cross-links, 320 plasma tartrate-resistant acid phosphatase, 319 pyridinoline, 319-320 type I collagen carboxy-terminal pyridinoline cross-linked telopeptide, 321 type I collagen degradation products, 320-321 exogenous subclinical hyperthyroidism, 538 24-hour turnover marker variation, 321 marker formation alkaline phosphatases, 316 free bone gla protein, 318

Index

789

Bone turnover ( C o n t i n u e d ) osteocalcin, 316- 318 procollagen peptides, 318 modeling, 314- 315 osteoporosis diagnosis, 392-393 overview, 313- 314 remodeling, 314-315, 392-393 characteristics, 242 histomorphometric parameters, 255 hyperthyroidism diagnosis, 428 low-turnover bone disease, 263-264 modeling overview, 314- 315 skeletal structure, 240-242 osteoclast cell role, see Osteoclasts remodeling bone mineralization, 328-329 cell-cell interaction, 12 function, 240-242 histomorphometric parameters, 255 hypovitaminosis D osteopathy treatment, 372 impaired mineralization, 367-369 minerals, see specific types noninvasive indices, 344-345 osteogenesis imperfecta pathophysiology, 665666 osteoid seam life history, 330-331 overview, 314- 315 Paget' s disease histopathology, 548- 553 phosphate transport role, 215-216 Brodie's abscess, Paget's disease histopathology, 553 Bums, hypophosphatemia association, 223

C Caffeine, intestinal calcium transport effects, 182 Calcidiol a-ring metabolism, 140-141 assay, 149-150 clinical disorders, 132-135 extrarenal regulation, 138-139 hepatic metabolism, 132 hepatobiliary disease association, 357-358 metabolic regulation, 136-138 osteoporosis management, 404-405 Paget's disease role, 570-571 renal bone disease association, 359-360 side-chain metabolism, 140-141 synthesis, 66 Calciferol, see Vitamin D Calcific periarthritis, Paget's disease association, 579 Calcinosis, see Chondrocalcinosis; Tumoral calcinosis Calcipotriol, intoxication, 615

Calcitonin actions, 102-108 bone formation, 104-105 bone resorption, 102-104, 113-114 calcium homeostasis, 105-106 gastrointestinal tract function, 107 neural function, 107-108 renal effects, 106-107 biosynthesis, 99-101 calcitonin gene mRNA transcript splicing, 100101 calcitonin gene-related peptide, 100-101 precursors, 99-100 calcitonin receptor, 108-113 cloning, 108-109 escape phenomenon, 112-113 isoforms, 109-111 regulation, 112-113 signal transduction, 111-112 characteristics, 96-98 calcitonin-producing cell origin, 96-97 chemistry, 98-99 vertebrate and nonvertebrates compared, 97-98 fibrogenesis imperfecta ossium treatment, 728 historical perspectives, 95-96 hypercalcemia management, 433, 643 malignancy disease hypercalcemia treatment, 643 metabolism, 101 - 102 osteogenesis imperfecta treatment, 678-679 osteoporosis management, 399-400, 626 Paget's disease association acute effects, 575-576 treatment, 581-585, 591 phosphate absorption effects, 185 secretion, 101 - 102 Calcitonin gene-related peptide calcitonin biosynthesis, 100-101 central nervous system distribution, 108 Calcitonin receptor cloning, 108-109 escape phenomenon, 112-113 isoforms, 109-111 regulation, 112-113 signal transduction, 111-112 Calcitriol antiproliferation effects, 146-147 a-ring metabolism, 140-141 assay, 151 biological actions, 142-144, 155-156 calcitonin secretion regulation, 101 - 102 calcium balance regulation, 144-145, 168-170, 173-174 differentiation effects, 146-147 endocrine effects, 147-148

790 Calcitriol ( C o n t i n u e d ) extrarenal 25-hydroxyvitamin D metabolism regulation, 138-139 25-hydroxyvitamin D metabolism regulation, 136138 hypercalcemic disorders calcipotriol intoxication, 615 Hodgkin' s disease, 613-614 leioblastoma, 614 leukemia, 613-614 lung carcinoma, 614 lymphomas, 613-614 rheumatoid arthritis, 613 sarcoidosis, 608-611 seminoma, 614 subcutaneous fat necrosis, 615 tuberculosis, 612-613 vitamin D intoxication, 615 William' s syndrome, 614-615 hyperphosphatemia manifestation, 229 hypoparathyroidism treatment, 522 hypophosphatemic osteomalacia treatment, 373-374 immunoregulatory effects, 147 intoxication, 615 luminal brush border phosphate transport, 208, 214 osteomalacia association deficiency effects, 350 treatment, 373-374 vitamin D regulation, 353-354 osteopetrosis treatment, 702 osteoporosis management, 404-405 Paget's disease role, 570-571 parathyroid hormone secretion regulation, 61 phosphate excretion regulation, 213- 214 pseudohypoparathyroidism pathophysiology, 511512, 520-521 renal 25-hydroxyvitamin D- lo~-hydroxylase, 135 renal osteodystrophy role, 444-445, 459 side-chain metabolism, 140-141 skin cell effects, 148 synthesis, 66 x-linked hypophosphatemic tickets role, 218-220 Calcium absorption pathophysiology, 165-183 decreased absorptive states, 176-183 bioavailability, 176-177 extrinsic inhibition, 182-183 intrinsic intestinal transport defects, 179-182 vitamin D deficiency, 177-179 increased absorptive states, 172-176 bioavailability, 173 vitamin D-dependent hyperabsorption, 173-175 vitamin D-independent hyperabsorption, 175176

Index physiology age function, 171 calcium balance, 165-166 dietary factors, 172 gastrointestinal function, 167-168, 170-171, 177 gender effects, 171 - 172 hormonal regulators, 168-170 intake, 166 intestinal absorption mechanisms, 167-168 measurement, 168 regulation, 168-172 reproductive function, 171 sources, 166-167 bone resorption marker, 318- 319 calcium II deficiency syndrome, 703-705 calcium-phosphorus bone mineral phase, 23-30 characteristics, 165 extracellular calcium response heightened response, s e e Autosomal dominant hypocalcemia overview, 479-480 resistance syndromes, s e e Familial benign hypocalciuric hypercalcemia; Neonatal severe primary hyperparathyroidism homeostasis regulation calcitonin role, s e e Calcitonin 1,25-dihydroxyvitamin D role, 52-53, 144-145 parathyroid hormone role, 52-53, 65-66, 105, 169, 445-448 hydroxyapatite crystals, s e e Bone, mineralization hyperoxaluric calcium nephrolithiasis treatment, 749 hyperparathyroidism treatment, 476-477 hypoparathyroidism treatment, 521 Paget's disease role, 570 parathyroid hormone secretion regulation, 60 renal osteodystrophy role parathyroid hormone secretion regulation, 445448 therapy, 458-459 sarcoidosis role, 609, 611 stone formation, s e e Nephrolithiasis Calcium citrate, hyperoxaluric calcium nephrolithiasis treatment, 749-750 Calcium gluconate, hypoparathyroidism treatment, 521 Calcium ion-sensing receptor altered response syndromes, s e e Autosomal dominant hypocalcemia; Familial benign hypocalciuric hypercalcemia; Neonatal severe primary hyperparathyroidism characterization, 483-485 cloning, 483-485, 496 mutations calcium ion resistance, 485-489 diagnostic effects, 493-496

Index Calcium ion-sensing receptor ( C o n t i n u e d ) homozygous versus d e n o v o heterozygous mutations, 490-491 identification, 493-494 parathyroid regulation, 492-493 renal function regulation, 482-483, 492-493, 496 targeted gene deletion mouse development, 491492 therapeutic effects, 493-496 overview, 479-480 physiology, 493-494 Calcium oxalate stones, s e e Nephrolithiasis cAMP calcitonin secretion regulation, 101, 104 pseudohypoparathyroidism pathophysiology, 510512, 517, 520-521 signal transduction role, 111-112 Camurati-Engelmann disease, s e e Progressive diaphyseal dysplasia Cancellous bone, characteristics, 238 Cancer, s e e Carcinomas; Sarcomas; Tumors Candidiasis-polyendocrinopathy- ectodermal dystrophy, characteristics, 507 Carbohydrates, hypophosphatemia manifestation, 224 Carbonate ions bone apatite abnormalities, 41-45 hyperparathyroidism diagnosis, 467 Carcinomas lungs, 614 parathyroid gland characteristics, 413-418 operative management, 475 Cardiovascular system hypophosphatemia manifestations, 224 osteogenesis imperfecta clinical features, 662 Paget's disease association, 579-580 Cartilage, s e e a l s o Bone, development bone articulation role, 27 skeletal development, 2 C cells calcitonin production, 96-97 calcitonin secretion, 101-102 Cell death, s e e Necrosis Central nervous system calcitonin role, 107-108 hypophosphatemia manifestations, 224 Chemotherapy, s e e s p e c i f i c t y p e s Children's diseases, s e e Pediatric diseases Chloroquine, sarcoidosis treatment, 612 Chondrocalcinosis familial benign hypocalciuric hypercalcemia association, 481 hyperparathyroidism association, 424 Paget's disease association, 579

791 Chondroclasts, s e e Osteoclasts Chondrodysplasia hypercalcemia association, 426-427 parathyroid hormone/parathyroid hormone-related peptide receptor mutation, 78-80 Chronic diarrheal syndrome, treatment, 751 Citrate, calcium stone formation, 750-752, 754 Clodronate osteoporosis management, 402 Paget's disease treatment, 588-589 Cloning calcitonin receptor, 108-109 calcium ion-sensing receptors, 483-485, 496 Clotting, osteogenesis imperfecta association, 663 Collagen, s e e a l s o Bone matrix bone three-dimensional structure, 24 characteristics, 5-6 markers bone resorption, 320-321 bone tumover, 318 osteogenesis imperfecta association biochemistry analysis, 671 assembly, 669-670 biosynthesis, 668-669 cellular regulation, 670 degradation, 670 gene structure, 667-668 protein structure, 666-667 secretion, 669-670 clinical features ear, 661 eye, 661 heart, 662 pulmonary function, 662 mRNA mutation localization, 672 Paget's disease association, bone matrix metabolism, collagenolysis, 572 procollagen peptides bone turnover marker, 318 osteogenesis imperfecta role, 671 Paget's disease association, bone matrix metabolism, 574 Colony-stimulating factors embryologic function, 13 malignant disease hypercalcemia pathophysiology, 642 Compton scattering technique, neutron activation analysis, 280-281 Computed tomography acquisition technique, 286-288 age-related bone changes, 288 fracture discrimination, 288 high-resolution tomography, 289-291

792

Index

Computed tomography ( C o n t i n u e d ) hip assessment, 288-289 menopause-related bone changes, 288 microcomputed tomography, 289-291 overview, 286 Paget's disease complications, 557-559 spine assessment, 288 volumetric tomography, 288-289 Cortical bone, characteristics, 238 Corticosteroids intestinal calcium transport effects, 180-181 malignancy disease hypercalcemia treatment, 645 Crohn' s disease calcium absorption effects, 177 phosphate absorption effects, 188 vitamin D depletion, 357 CrossLaps, bone resorption marker, 320-321 Crystallization, s e e Bone, mineralization Cystinuria, stone formation cystine role, 753 diagnostic criteria, 754 pathophysiology, 753-754 treatment, 754- 755

D Danlos-Ehlers syndrome, osteogenesis imperfecta association, 654, 660 Decorin, characteristics, 7 Demineralization, s e e Osteopenia Densitometry, s e e a l s o Ultrasound acronyms, 276 disease course evaluation, 303 exogenous subclinical hyperthyroidism, 535-538 osteoporosis diagnosis, 391-392 overt hyperthyroidism, 534 Dent's disease, characteristics, 776-777 Deoxypyridinoline, bone resorption marker, 319-320 Diabetes mellitus calcium absorption effects, 179 magnesium absorption effects, 193 Dialysis magnesium effects, 455 malignancy disease hypercalcemia treatment, 644 renal osteodystrophy therapy, 454-455, 459 Diarrheal syndrome, treatment, 751 Diet calcium absorption factors, 172 alcohol abuse, 181 - 182 caffeine effects, 182 fiber effects, 182-183 intake, 166, 176

lactose intolerance, 176-177 phosphate effects, 182 sources, 166-167 supplements, 458-459 vitamin D deficiency, 177 fiber intake, calcium absorption effects, 182-183 magnesium bioavailability, 194-195 deficiency, 193 intake, 191 osteoporosis management, 397-398 phosphate bioavailability, 188, 190 calcium effects, 187-188 deficiency, 188, 222 deprivation, 187 intake, 182-184 renal function, 214-215 sources, 183-184 Dietary fiber, calcium absorption effects, 182-183 DiGeorge syndrome, parathyroid gland development, 509 1,25-Dihydroxyvitamin D, s e e Calcitriol 24,25-Dihydroxyvitamin D assay, 151-152 metabolism, 139-140 Paget's disease role, 571 Diphosphonates, s e e Bisphosphonates Disodium etidronate fibrodysplasia ossificans progressiva treatment, 721 Paget's disease treatment, 586-588, 591 progressive diaphyseal dysplasia treatment, 710 Diuresis, hypercalcemia management, 217, 431-433, 644 DNA, sequencing, osteogenesis imperfecta analysis, 672-673 D-Pyr peptide, bone resorption marker, 320 Drugs, s e e Medications Dysplasia, s e e s p e c i f i c t y p e s

E Ear, osteogenesis imperfecta clinical features, 661 Ectodermal dystrophy, characteristics, 507 Edetate disodium, sarcoidosis treatment, 612 Ehlers-Danlos syndrome, osteogenesis imperfecta association, 654, 660 Electron microscopy bone apatite abnormality detection, 40-41 bone crystal structure analysis, 32-35 Ellison-Zollinger syndrome, peptic ulcer association, 424

Index Embryology bone development, 2-5, 104-105 bone morphogenetic proteins, 3-4, 14, 762-763 bone remodeling, cell-cell interaction, 12 cell-matrix interactions, 16 colony-stimulating factor role, 13 fibroblast growth factor role, 3-5, 14-15, 763 hepatocyte growth factor role, 15-16 limb development, 2-3 osteoblast cell lineage, 5-9 differentiation, 7-9 phenotypes, 5-7 osteoclasts, 9-12 differentiation, 9-10 function, 10-12 origin, 9-10 overview, 1 parathyroid gland development, 53, 469-471 parathyroid hormone-related peptide role, 4 pattern regulation, 2-3 platelet-derived growth factor role, 15 transforming growth factor [3 role, 13-14 vascular endothelial growth factor role, 15 Endocrine neoplasia, hyperparathyroidism role, 413-417 Endocrine system, s e e a l s o s p e c i f i c h o r m o n e s osteogenesis imperfecta role, 662-663 clotting, 663 pregnancy, 663 short stature, 662 thyroid function, 662 vitamin D metabolism, 147-148 Endosteal envelope, characteristics, 238 Endosteal hyperostosis characteristics, 710-712 treatment, 712-713 Engelmann-Camurati disease, s e e Progressive diaphyseal dysplasia Epidermal growth factor, malignant disease hypercalcemia pathophysiology, 641 Escape phenomenon, calcitonin receptor regulation, 112-113 Estrogen calcium absorption regulation, 169-170 hyperparathyroidism treatment, 747 osteoporosis management, 399, 405-406, 626 perimenopausal therapy evaluation, 303 phosphate absorption effects, 185 Estrogen receptor modulators, osteoporosis management, 405-406 Ethane- 1-hydroxy- 1,1-diphosphonate, fibrodysplasia ossificans progressiva treatment, 722 Ethnicity, calcium absorption effects, 171-172 Ethylenediaminetetraacetic acid, fibrodysplasia ossificans progressiva treatment, 721

793 Etidronate, s e e Disodium etidronate Exercise osteoporosis management, 398, 625 rheumatoid arthritis role, 625 Eye, osteogenesis imperfecta clinical features, 661

F Familial benign hypocalciuric hypercalcemia biochemical features, 480-483 clinical features, 480-483 differential diagnosis, 427 extracellular calcium ion-sensing receptor characterization, 483-485 cloning, 483-485 mutations, 485-489 resistance syndrome, 485-489 genetic heterogeneity, 483, 508 hypercalcemia association, 414, 427 parathyroid hormone secretion role, 59-61 renal function, 482-483, 492-493, 496 Familial hyperparathyroidism, s e e a l s o Hyperparathyroidism; Neonatal severe primary hyperparathyroidism etiology, 468-469 Familial hypoparathyroidism, s e e a l s o Hypoparathyroidism characteristics, 507-508 Familial hypophosphatemic vitamin D-refractory tickets, s e e Osteomalacia; Rickets Familial osteogenesis imperfecta, s e e Osteogenesis imperfecta Familial vitamin D-resistant rickets, characteristics, 771-772 Fanconi' s syndrome Dent's disease, 776-777 oculocerebrorenal syndrome of Lowe, 775-776 osteomalacia association, 365-366, 775 Fiber, calcium absorption effects, 182-183 Fibroblast growth factor limb development role, 3 skeletal development role, 4-5, 14-15, 763 Fibrogenesis imperfecta ossium characteristics, 726-728 treatment, 728 Fibrous dysplasia characteristics, 719-721 Paget's disease histopathology, 554 treatment, 721-722 Fluorosis characteristics, 728-729 treatment, 729 Flurbiprofen, sarcoidosis treatment, 612

794

Index

Fourier transform infrared spectroscopy amorphous calcium-phosphorus detection, 31-32 bone apatite abnormality detection, 36-40 Fractures exogenous subclinical hyperthyroidism complications, 538-539 noninvasive assessment computed tomography, 288 overview, 276 ultrasound, 296 osteogenesis imperfecta clinical features, 657-659 osteomalacia diagnosis, 342-344 Paget's disease complications, 562-564 rheumatoid arthritis complications, 626 Furosemide, malignancy disease hypercalcemia treatment, 643

progressive diaphyseal dysplasia treatment, 710 rheumatoid arthritis effects, 625-626 sarcoidosis treatment, 611-612 GNAS1 gene, pseudohypoparathyroidism pathophysiology, 513-515, 517-518, 520 Goiter, exogenous subclinical hyperthyroidism association, 536-537 Gout, Paget's disease association, 578 Gouty diathesis, calcium stone formation, 752-753 Granulomatous diseases, see specific types Growth factor, see specific types Growth hormone calcium absorption effects, 174 phosphate regulation, 187, 214

H G Gallium nitrate hypercalcemia management, 433 malignancy disease hypercalcemia treatment, 646 Paget's disease treatment, 591 Gastrointestinal tract calcium absorption, 167-168, 170-171, 177 hyperparathyroidism association, 424 magnesium absorption, 194 malignant disease hypercalcemia pathophysiology, 642 osteomalacia association, 355-357 phosphate absorption basolateral membrane phosphate exit, 209 hyperphosphatemia treatment, 230 hypophosphatemia, 222, 225 intestinal defects, 189-190 luminal brush transport, 208 malabsorption diseases, 188 transcellular phosphorus movement, 209 plasma calcium regulation calcitonin effects, 107 1,25-dihydroxyvitamin D effects, 144-145 vitamin D absorption, 131-132, 355-357 Gel electrophoresis, collagen analysis, osteogenesis imperfecta role, 671 Gender, calcium absorption effects, 171-172 Gene therapy, osteogenesis imperfecta management, 682 Genetic diseases, see specific types Gla protein, bone turnover marker, 318 Glucocorticoids hypercalcemia management, 434, 643 osteopetrosis treatment, 702 phosphate absorption effects, 187, 190

Heart, see Cardiovascular system Hedgehog proteins, skeletal development role, 4-5 Hemodialysis magnesium effects, 455 malignancy disease hypercalcemia treatment, 644 renal osteodystrophy therapy, 454-455, 459 Hemopoiesis, colony-stimulating factor role, 13 Hepatitis C-associated osteosclerosis, characteristics, 731 Hepatobiliary diseases calcium absorption effects, 177 25-hydroxylation impairment, 357-358 Hepatocyte growth factor, embryologic function, 1516 Hip computed tomography assessment, 288-289 walking difficulties, osteomalacia role, 340 Histology applications, 267-269 morphometric bone parameters balance, 255 bone formation, 254-255 bone structure, 253- 254 mineralization, 254-255 molecular parameters, 255-256 remodeling, 255 resorption, 255 turnover, 255 renal osteodystrophy, 451-453 adynamic bone, 452 high-turnover bone disease, 451 lesions, 452-453 low-turnover bone disease, 452 techniques dehydration, 247 embedding, 247

Index Histology ( C o n t i n u e d ) fixation, 247 immunohistochemistry, 251 sectioning, 247-248 in situ hybridization, 249-251,268-269 staining, 248-249 Histomorphometry, see also Radiographic morphometry bone biopsy parameters balance, 255 bone formation, 254-255 bone structure, 253-254 mineralization, 254- 255 molecular parameters, 255-256 remodeling, 255 resorption, 255 turnover, 255 osteoporosis diagnosis, 392 Hodgkin' s disease, characteristics, 613-614 H o x gene family, pattern regulation, 2-3 Human leukocyte antigen, Paget's disease diagnosis, 547, 560 Hydroxyapatite, see Bone, mineralization Hydroxychloroquine, sarcoidosis treatment, 612 Hydroxylysine bone resorption marker, 319 Paget's disease association, bone matrix metabolism, 572-573 Hydroxyproline bone resorption marker, 318-319 Paget's disease association, bone matrix metabolism, 572-574 25-Hydroxyvitamin D, see Calcidiol Hypercalcemia, see also Hypocalcemia calcitriol-induced disorders calcipotriol intoxication, 615 Hodgkin' s disease, 613-614 leioblastoma, 614 leukemia, 613-614 lung carcinoma, 614 lymphomas, 613-614 rheumatoid arthritis, 613 sarcoidosis, 608-611 seminoma, 614 subcutaneous fat necrosis, 615 tuberculosis, 612-613 vitamin D intoxication, 615 William' s syndrome, 614-615 familial benign hypocalciuric hypercalcemia biochemical features, 480-483 clinical features, 480-483 differential diagnosis, 427 extracellular calcium ion-sensing receptor characterization, 483-485

795 cloning, 483-485 mutations, 485-489 resistance syndrome, 485-489 genetic heterogeneity, 483 hyperparathyroidism diagnosis familial benign hypocalciuric hypercalcemia, 414, 427 Jansen's disease, 78-80, 426-427 lithium therapy, 427 preoperative evaluation, 466 malignant disease association clinical features, 642 pathophysiology colony-stimulating activity, 642 hematological malignancies, 638-639 lymphomas, 639 malignancy types, 637 metastasis solid tumors, 639-640 myeloma, 638-639 nonmetastasis solid tumors, 640-642 parathyroid hormone, 641-642 parathyroid hormone-related protein, 641 prostaglandins, 642 transforming growth factor, 641 treatment alendronate, 644-645 bisphosphonates, 644-645 calcitonin, 433, 643 corticosteroids, 645 furosemide, 643 gallium nitrate, 646 glucocorticoids, 643 hemodialysis, 644 indications, 642-643 indomethacin, 645 intravenous saline, 643 mithramycin, 645-646 oral phosphate, 645 pamidronate, 643-644 parenteral phosphate, 643 management bisphosphonates, 433, 644-645 calcitonin, 433, 643 diuresis, 217, 431-433, 644 gallium nitrate, 433, 646 glucocorticoids, 434, 643 mithramycin, 433-434, 645-646 phosphate, 434, 643-644 plicamycin, 433-434, 645-646 Paget's disease association, 578 Hypercalciuria calcium absorption effects, 175, 741 calcium stone formation causal role, 740-741

796 Hypercalciuria (Continued) diagnostic criteria, 743-744 pathophysiology, 741-743 treatment, 744-747 1,25-dihydroxyvitamin D therapy, 146 hereditary hypercalciuria hypophosphatemic tickets, 774-775 Paget's disease association, 578 sarcoidosis association, 609 vitamin D assay, 154-155 Hypermagnesemia, s e e a l s o Hypomagnesemia; Magnesium hypoparathyroidism, 194 Hyperostosis endosteal hyperostosis characteristics, 710- 712 treatment, 712- 713 melorheostosis, 716-717 overview, 697-698 Hyperoxaluria, calcium stone formation, 748-750 Hyperparathyroidism, s e e a l s o Hyperthyroidism; Hypoparathyroidism biopsy, 260-263 calcium absorption effects, 174, 743 clinical features articular manifestations, 424-425 gastrointestinal involvement, 424 hypertension, 425 neuromuscular manifestations, 423-424 parathyroid poisoning, 425 pediatric hyperparathyroidism, 425 pregnancy, 425-426 renal manifestations, 419, 743 skeletal involvement, 419-423 diagnosis, 426-431 aluminum intoxication, 429 differential diagnosis, 429-431 high bone turnover states hyperthyroidism, 428 immobilization, 428 thiazides, 428-429 hypercalcemia familial benign hypocalciuric hypercalcemia, 414, 427 Jansen's disease, 78-80, 426-427 lithium therapy, 427 milk-alkali syndrome, 173, 429 renal failure, 429 vitamin A intoxication, 429 vitamin D-related hypercalcemia, 428 etiology, 412-418 hypophosphatemia effects, 217 management, 434-435, 747 neonatal severe primary hyperparathyroidism

Index biochemical features, 489-490 clinical features, 489-490 extracellular calcium ion-sensing receptor mutations, 490-491 parathyroid regulation, 492-493 renal function, 492-493 targeted deletion mouse development, 491-492 genetics, 490 overview, 411-412 Paget' s disease histopathology, 553 pathology, 412-418 phosphate absorption effects, 187-188 renal osteodystrophy, 443-451 bone histology, 451 calcemic action resistance, 450-451 calcium sensitivity, 445-448 parathyroid hormone degradation, 451 parathyroid hormone resistance, 450-451 phosphate retention, 448-450 vitamin D metabolism alterations, 444-445 surgical treatment, 465-477 historical perspectives, 465-466 nephrolithiasis treatment, 747 operation conduct exploration, 469-471 resection extent, 471-472 parathyroid carcinoma, 475 postoperative management, 475-477 airway protection, 476 calcium replacement, 476-477 preoperative evaluation alkaline phosphatase measurement, 467 bicarbonate measurement, 467 calcium diagnosis, 466 familial disease etiology, 468-469 general assessment, 469 informed consent, 469 localization, 468 operation indicators, 467-468 parathyroid hormone measurement, 466-467 phosphate measurement, 467 physical findings, 465-466 radiation exposure, 469 recurrent hyperparathyroidism management, 472475 localization, 472-474 reoperation, 474-475 renal osteodystrophy, 459-460, 475 Hyperphosphatasemia, Paget's disease histopathology, 554 Hyperphosphatemia, s e e a l s o Hypophosphatemia causes acromegaly, 227 bisphosphonate administration, 228

Index Hyperphosphatemia (Continued) catabolism increase, 228-229 parathyroid hormone circulation, 227 phosphate salt administration, 229 pseudohypoparathyroidism, 227 respiratory acidosis, 229 tumoral calcinosis, 227-228 tumor lysis syndrome, 228 urinary excretion, 186, 226-227 vitamin D salt administration, 229 clinical manifestations, 229-230, 457-458 treatment, 230 Hyperprostaglandin E syndrome, calcium absorption effects, 174 Hyperthyroidism, s e e a l s o Hyperparathyroidism; Hypoparathyroidism calcium absorption effects, 178-179 diagnosis, 428 endogenous subclinical hyperthyroidism, 534-535 exogenous subclinical hyperthyroidism, 535-539 benign goiter suppression, 536-537 bone density, 535-538 bone mineral metabolism markers, 538 cross-sectional studies, 535- 536 fractures, 538-539 longitudinal studies, 537-538 menstrual status role, 537 suppressive versus replacement therapy, 536 thyroid cancer suppression, 536- 537 grades, 531 - 532 overt hyperthyroidism bone density, 534 mineral metabolism, 532-533 thyroid hormone effects, 532 thyrotoxic bone disease, 533- 534 Hypertrophic osteoarthropathy, characteristics, 729731 Hyperuricemia, Paget's disease association, 578 Hyperuricosuria, calcium stone formation, 747-748 Hypocalcemia, s e e a l s o Hypercalcemia inherited autosomal dominance, 494-496 biochemical features, 494-495 chromosome 3 linkage, 495 clinical features, 494-495 diagnosis, 495-496 extracellular calcium ion-sensing receptor mutations, 495 therapy, 495-496 magnesium deficiency effects, 189 neonatal hypocalcemia, 509- 510 pathophysiology, 502-504 symptoms, 501,504-505 vitamin D metabolism assays, 154-155 Hypocitraturia, calcium stone formation, 750- 752

797 Hypogonadism, pseudohypoparathyroidism association, 517 Hypomagnesemia, s e e a l s o Hypermagnesemia; Magnesium clinical manifestation, 192-193 intestinal calcium transport effects, 181 intestinal magnesium absorption defects, 194 treatment, 192 Hypoparathyroidism, s e e a l s o Hyperparathyroidism; Hyperthyroidism causes autoimmune hypoparathyroidism, 507 drugs, 506 idiopathic hypoparathyroidism, 506-507 isolated hypoparathyroidism, 507-508 magnesium imbalance, 506 neonatal hypocalcemia, 508-509 parathyroid gland development disorders, 508-509 parathyroid infiltrative disease, 506 radiation, 506 surgery, 505-506 toxic agents, 505-506 diagnosis, 519- 521 hypermagnesemia role, 194 hypocalcemia pathophysiology, 502-504 symptoms, 504-505 overview, 501-502 pseudohypoparathyroidism, 510- 519 molecular classification, 512-519 Albright's hereditary osteodystrophy, 510, 515516 multiple hormone resistance, 516-517 neurosensory abnormalities, 517 phenotypic variability, 517-518 type IA, 513-518 type IB, 518 type IC, 518 type II, 518-519 natural history, 519 pathophysiology, 510-512 treatment, 521 - 522 Hypophosphatemia, s e e a l s o Hyperphosphatemia biochemical manifestations, 223-225 causes acute leukemia, 222 acute respiratory alkalosis, 222 acute tubular necrosis diuretic phase, 217 alcoholism, 222 bums, 223 extracellular fluid volume expansion, 218 Fanconi's syndrome, 775-777 hereditary hypercalciuria hypophosphatemic tickets, 774-775

798

Index

Hypophosphatemia ( C o n t i n u e d ) hyperparathyroidism, 217 magnesium deficiency, 170, 218-220 malabsorption, 222 malnutrition, 222 McCune-Albright syndrome, 220 phosphate binder administration, 222 postobstructive diuresis, 217 post transplantation, 217- 218 renal tubular defects, 217 toxic shock syndrome, 222 urinary excretion, 217 vitamin D metabolism abnormalities, 188-189, 220 vitamin D-resistant tickets, 221 x-linked hypophosphatemic tickets, 188-189, 769-774 clinical manifestations, 186, 223-225 differential diagnosis, 225 osteomalacia association hereditary hypophosphatemia, 362-364 nonhereditary hypophosphatemia, 364-365 overview, 351 phosphorus depletion, 362 treatment, 225-226, 373-374 x-linked hypophosphatemic tickets biochemical findings, 770 clinical features, 188-189, 769-770 molecular genetics, 771-772 mouse models, 773-774 osteoblast function studies, 774 phosphate transport studies, 774 treatment, 770-771 tumor-induced osteomalacia, 772-773 Hypovitaminosis D osteopathy osteomalacia role bone mineral metabolism abnormalities, 345-348 diagnostic considerations, 348 histological evolution, 335-338 histopathology, 340-341 skeletal radiology, 341-342 temporal evolution, 348 prevention, 370-371 treatment bone mineral metabolism effects, 371-372 management aspects, 372-373 remodeling effects, 371-372 vitamin D response, 371

I Immunohistochemistry bone tissue applications, 251

1,25-dihydroxyvitamin D effects, 147-148 sarcoidosis, 607-609 Indomethacin, malignancy disease hypercalcemia treatment, 645 Infrared spectroscopy amorphous calcium-phosphorus detection, 31-32 bone apatite abnormality detection, 36-40 In situ hybridization applications, 268-269 techniques bone processing, 249-250 protocol, 251 Internet, osteogenesis imperfecta mutations, 671 Intestine, see Gastrointestinal tract Ipriflavone, osteoporosis management, 404

Jansen' s disease hypercalcemia association, 426-427 parathyroid hormone/parathyroid hormone-related peptide receptor mutation, 78-80 Jaw, Paget's disease manifestations, 557 Joints osteogenesis imperfecta clinical features, 659-660 Paget's disease manifestations, 561-562

K Ketoconazole, sarcoidosis treatment, 612 Kidneys 1,25-dihydroxyvitamin D metabolism, renal 25-hydroxyvitamin D-la-hydroxylase role, 135 25-hydroxyvitamin D metabolism, 138-139 kidney stones, see Nephrolithiasis renal function calcitonin effects, 106-107 calcium absorption, 178 calcium reabsorption, 65-66 chronic renal failure, 444-445 1,25-dihydroxyvitamin D synthesis, 66, 145 familial benign hypocalciuric hypercalcemia patients, 482-483, 492-493, 496 hypercalcemia association, 429, 482 hyperparathyroidism association, 418-419, 429 parathyroid hormone metabolism, 64-67 phosphorus reabsorption, 209-215 acid-base balance effects, 213 adrenal hormone effects, 213 cellular reabsorption mechanisms, 210-211 dietary phosphorus intake alterations, 214-215 growth hormone effects, 214 hyperphosphatemia, 186, 226-227

Index

799

Kidneys ( C o n t i n u e d ) hypophosphatemia, s e e Hypophosphatemia parathyroid hormone effects, 66, 211-213 stanniocalcin, 215 superficial-deep nephron transport compared, 210 vitamin D role, 213- 214 Kidney stones, s e e Nephrolithiasis Knee joint, Paget's disease manifestation, 561-562

L Lactate dehydrogenase, hyperphosphatemia role, 228 Lactation, calcium absorption effects, 175-176 Lactose intolerance, calcium absorption effects, 176-177 magnesium absorption effects, 193 Lamellar bone, characteristics, 239-240 Laxatives, magnesium absorption effects, 193 Leioblastoma, characteristics, 614 Leukemia characteristics, 613-614 hypophosphatemia role, 222 Leukocyte antigen, Paget's disease diagnosis, 547, 560 Levothyroxine, hyperthyroidism treatment, 537-538, 540-541 Lifestyle, osteoporosis management, 397 Limb development, embryology, 2-3 Lithium therapy, hypercalcemia association, 427 Liver calcium absorption effects, 177 hepatitis C-associated osteosclerosis, 731 25-hydroxylation impairment, 357-358 parathyroid hormone metabolism, 64-65 vitamin D-25-hydroxyvitamin D conversion, 132 Looser's zone, osteomalacia diagnosis, 342-344, 455456 Low-turnover bone disease, s e e a l s o Bone turnover biopsy, 263-264 Lungs osteogenesis imperfecta clinical features, 662 small cell carcinoma, 614 Lupus erythematosus, characteristics, 621,628 Lymphocytes, sarcoidosis pathology, 607-609 Lymphomas characteristics, 613-614 malignant disease hypercalcemia pathophysiology, 639

M Magnesium absorption pathophysiology, 191-194 decreased absorptive states, 193-195

disorders, clinical manifestations, 192-193 increased absorptive states, 193 physiology, 191-192 bone apatite abnormalities, 45-46 characteristics, 190-191 chronic hemodialysis effects, 455 hyperoxaluric calcium nephrolithiasis treatment, 749 hypomagnesemia, s e e Hypomagnesemia hypoparathyroidism induction, 506 intestinal calcium transport effects, 181 intestinal phosphate absorption effects, 189-190 Paget's disease role, 570 parathyroid hormone secretion regulation, 60-61 Magnetic resonance microscopy amorphous calcium-phosphorus detection, 31-32 bone apatite abnormality detection, 37, 40-41, 43 noninvasive bone assessment technique, 296-298 Markers, s e e Biochemical markers Marrow, s e e Bone marrow cells Matrix, s e e Bone matrix McCune-Albright syndrome, characteristics, 220 Medications, s e e a l s o s p e c i f i c t y p e s calcium absorption effects, 177-178, 182 hypoparathyroidism role, 506 osteogenesis imperfecta therapy, 678-679 Paget's disease treatment, 581-592 bisphosphonates, 585-590 calcitonin, 581-585 combination therapy, 591 gallium nitrate, 591 indications, 581 mithracin, 590-591 monitoring, 591-592 rheumatoid arthritis diagnosis effects, 625-626 rickets therapy, 134 Melorheostosis characteristics, 716-717 treatment, 717 Melphalan, fibrogenesis imperfecta ossium treatment, 728 Menopause, s e e a l s o Osteoporosis bone changes, computed tomography assessment, 288 bone turnover evaluation, 322 calcium absorption effects, 171 estrogen therapy evaluation, 303 intestinal calcium transport effects, 180 levothyroxine replacement therapy, 537-538, 540541 Microscopy, s e e s p e c i f i c t y p e s Migratory osteolysis, characteristics, 631 Milk-alkali syndrome calcium absorption effects, 173 characteristics, 429

800

Index

Milk production, calcium absorption effects, 175-176 Mineralization, s e e Bone, mineralization; Osteopenia Mithracin, Paget's disease treatment, 590-591 Mithramycin hypercalcemia management, 433-434 malignancy disease hypercalcemia treatment, 645646 Mixed sclerosing bone dystrophy, s e e a l s o Osteosclerosis characteristics, 718-719 treatment, 719 Mixed uremic osteodystrophy, s e e a l s o Renal osteodystrophy biopsy, 265 Morphometry, s e e Histomorphometry; Radiographic morphometry Mouse calcium ion-sensing receptor mutations, targeted gene deletion development, 491-492 hypophosphatemic tickets models, 773-774 osteogenesis imperfecta models, 655-656 Muscle, s e e Skeletal muscle Myeloma, malignant disease hypercalcemia pathophysiology, 638-639

N Necrosis acute tubular necrosis diuretic phase, 217 subcutaneous fat necrosis, 615 Neonatal hypocalcemia, characteristics, 509-510 Neonatal severe primary hyperparathyroidism biochemical features, 489-490 clinical features, 489-490 extracellular calcium ion-sensing receptor mutations, 490-491 parathyroid regulation, 492-493 renal function, 492-493 targeted deletion mouse development, 491-492 genetics, 490 Neoplasms, s e e Tumors Nephrolithiasis cystinuria, 753-755 formation, 266-267, 418 gouty diathesis, 752-753 hypercalciuria, 740-747 causal role, 740-741 diagnostic criteria, 743-744 pathophysiology, 741-743 treatment, 744-747 hyperoxaluria, 748-750 hyperuricosuria, 747-748 hypocitraturia, 750- 752

management, 755 overview chemical composition, 739-740 current field status, 739 diagnostic separation, 740 urea-splitting organism infections, 755 Nephrons, s e e Renal function Nephrotic syndrome, calcium absorption effects, 178 Nervous system calcitonin role, 107-108 hypophosphatemia manifestations, 224 Neural crest, development, 2 Neuromuscular system, hyperparathyroidism association, 423-424 Neurosensory abnormalities, pseudohypoparathyroidism association, 517 Neutron activation analysis, Compton scattering technique, 280-281 Nifedipine, melorheostosis treatment, 717 Northern blot, osteogenesis imperfecta mutation analysis, 671-672 Nuclear magnetic resonance microscopy amorphous calcium-phosphorus detection, 31-32 bone apatite abnormality detection, 37, 40-41, 43 noninvasive bone assessment technique, 296-298 Nutrition, s e e Diet

O Octocalcium phosphate, calcium-phosphorous mineral deposition, 30-32 Oculocerebrorenal syndrome of Lowe, characteristics, 775-776 Olbandronate, Paget's disease treatment, 590 Orthophosphates, hyperparathyroidism treatment, 747 Orthotics, osteogenesis imperfecta management, 680681 Osteitis fibrosa cyctica, hyperparathyroidism association bone histology, 451 calcemic action resistance, 450-451 calcium sensitivity, 445-448 parathyroid hormone degradation, 451 parathyroid hormone resistance, 450-451 phosphate retention, 448-450 skeletal changes, 419-423 vitamin D metabolism alterations, 444-445 Osteoarthritis, s e e a l s o Rheumatoid arthritis hypertrophic osteoarthropathy, 729-731 juvenile onset rheumatoid arthritis, 631-633 overview, 621

Index Osteoblasts cell lineage, 5 - 9 differentiation, 7 - 9 phenotypes, 5 - 7 characteristics, 243, 314 function studies, 774 mineralization influence, 353 Paget's disease histopathology, 5 4 8 - 5 5 1 , 5 9 3 - 5 9 4 parathyroid hormone effects, 67 phosphate transport, 215- 216 remodeling role, s e e Bone turnover Osteocalcin bone turnover marker, 316- 318 characteristics, 6 Paget's disease association, 574-575 Osteoclasts bone resorption regulation, 102-104, 113-114 characteristics, 9, 242-243, 314 differentiation, 9-10, 145 function, 10-12 malignancy stimulation factors, 639 origin, 9 - 1 0 Paget's disease histopathology, 547-548, 550-551, 593-595 parathyroid hormone effects, 67 phosphate transport, 215-216 signal transduction, 111-112 Osteodystrophy Albright' s hereditary osteodystrophy, 510, 515-516 biopsy, 261-266 renal osteodystrophy, s e e Renal osteodystrophy Osteogenesis imperfecta clinical features, 650-663 collagen-containing organs, 661-662 ear, 661 eye, 661 heart, 662 pulmonary function, 662 connective tissues, 659-661 joint hypermobility, 659-660 skin, 660 teeth, 660-661 differential diagnosis, 656-657 endocrine function, 662-663 clotting, 663 pregnancy, 663 short stature, 662 thyroid function, 662 heterogeneity, 652 historical perspectives, 651-652 phenotypes, 652-656 heritable osteoporosis, 654-655 mild deforming type IV, 653-654 mild nondeforming type I, 654

801 murine models, 655-656 neonatal lethal type II, 652-653 related skeletal-connective tissue syndromes, 654 prevalence, 657 skeletal system, 657-659 long bone fractures, 657-659 skull, 659 spine, 659 future research directions, 681-682 animal models, 682 diagnosis, 681-682 somatic gene therapy, 682 therapy evaluation, 682 mutation identification, 670-678 collagen analysis, 671 DNA sequencing, 672-673 molecular hybridization, 671-672 procollagen analysis, 671 overview, 651 pathophysiology bone mechanics, 665-666 bone mineral content, 665 collagen biochemistry, 666-670 assembly, 669-670 biosynthesis, 668-669 cellular regulation, 670 degradation, 670 gene structure, 667-668 protein structure, 666-667 hydroxyapatite quality, 665 molecular analysis, 673-678 heritable osteoporosis, 678 lethal type II, 673-674 mild deforming type IV, 676 mild nondeforming type I, 676-678 severe type III, 674-676 shared features, 678 skeletal histopathology, 663-665 lethal type II, 664 mild deforming type IV, 665 mild nondeforming type I, 665 severe nonlethal type III, 664-665 therapy, 678-681 medical therapy, 678-679 orthotic therapy, 680-681 psychological support, 680-681 surgical therapy, 679-680 Osteoids mineralization mechanisms maturation time, 331-332 osteoid seam life history, 330-331 tetracycline-based kinetics relationships, 334 Paget's disease histopathology, 552

802 Osteolysis, characteristics, 631 Osteomalacia, s e e a l s o Rickets axial osteomalacia clinical presentation, 722-723 etiology, 725 histopathological findings, 723-724 laboratory studies, 723 overview, 722 pathogenesis, 725 radiological features, 723 treatment, 725-726 biopsy, 259-260 bone mineralization mechanisms fluorescent label width, 332-334 hypovitaminosis D osteopathy histological evolution, 335-338 impaired mineralization, 334-335, 367-369 kinetic definition, 335-338 osteoid seam life history, 330-331 remodeling, 328-329 tetracycline-based kinetics, 334 tetracycline data interpretation, 329 juvenile onset, s e e Rickets manifestations bone remodeling noninvasive indices, 344-345 clinical features bone pain, 339 muscle weakness, 339-340 walking difficulty, 340 fractures, 342-344 hypovitaminosis D osteopathy bone mineral metabolism abnormalities, 345348 diagnostic considerations, 348 histopathology, 340- 341 skeletal radiology, 341-342 temporal evolution, 348 normal metabolic conditions alkaline phosphatase disorders, 369-370 matrix mineralization defects, 368-369 mineralization inhibitors, 367-368 oncogenic osteomalacia, 221-222 overview, 327-328 pathogenesis mineralization defects, 351 - 354 calcitriol role, 353-354 vitamin D effects, 352- 353 phosphate metabolism defects, 351 vitamin D metabolism defects, 349-350 phosphate metabolism defects, 361-367 depletion, 362 Fanconi's syndrome, 365-366, 775-777 hereditary hypophosphatemia, 362-364 nonhereditary hypophosphatemia, 364-365

Index renal tubular acidosis, 366-367 ureteral diversion, 366-367 renal osteodystrophy, 451-452, 455-456 therapeutic intervention hypophosphatemic osteomalacia treatment calcitriol, 373-374 phosphate supplementation, 373 hypovitaminosis D osteopathy treatment bone mineral metabolism effects, 371-372 management aspects, 372-373 prevention, 370-371 remodeling effects, 371-372 vitamin D response, 371-373 vitamin D metabolism defects anticonvulsant bone disease, 358-359 enzyme induction, 358-359 extrinsic depletion, 354-355 gastrointestinal bone disease, 355-357 hepatobiliary bone disease, 357-358 loL-hydroxylation impairment, 359-360 25-hydroxylation impairment, 357-358 intrinsic depletion, 355-357 pathogenesis, 349-350 renal bone disease, 359-360 Osteomark, bone resorption marker, 320 Osteomesopyknosis, characteristics, 707 Osteones, three-dimensional structure, 24 Osteopathia striata characteristics, 715- 716 treatment, 716 Osteopathy, s e e Hypovitaminosis D osteopathy Osteopenia bone turnover rate assessment, biochemical markers, 322-323 osteogenesis imperfecta association, 664-665 osteomalacia diagnosis, 342 osteoporosis pathogenesis, 360 rheumatoid arthritis diagnosis, 624-626 age effects, 625 disease activity, 625 drug effects, 625-626 fractures, 626 functional status, 625 osteoporosis treatment, 626 periarticular bone loss, 624 Osteopetrosis clinical presentations, 699 etiology, 701 histopathological findings, 700-701 laboratory findings, 699 overview, 698-699 pathogenesis, 701 radiological features, 699-700 treatment, 701-702

Index Osteopoikilosis characteristics, 713- 715 treatment, 715 Osteoporosis biopsy, 256-259 bone loss pathogenesis, 360 bone turnover assessment, s e e Bone turnover calcitonin role, 113 classification, 395- 396 definition, 387-388 diagnostic aids biochemical bone remodeling markers, 392393 clinical characteristics, 394-395 densitometry, 391- 392 histomorphometry, 392 radiology, 390- 391 ultrasound, 392 epidemiology, 388-389 fractures, s e e Fractures heritable forms, osteogenesis imperfecta association, 654-655, 678 management differential treatment, 360-361 future research directions parathyroid hormone, 405 selective estrogen receptor modulators, 405406 nonpharmacological intervention exercise, 398, 625 lifestyle, 397 nutrition, 397-398 pharmacological intervention alfacalcidiol, 404-405 bisphosphonates, 400-403, 626 calcidiol, 404-405 calcitonin, 399-400, 626 calcitriol, 404-405 estrogen, 399, 405-406, 626 ipriflavone, 404 pamidronate, 626 sodium fluoride, 403-404 thiazide diuretics, 405 rheumatoid arthritis patients, 626 noninvasive assessment, 275, 301,303 physiology, 389-390 Osteosclerosis, s e e a l s o Mixed sclerosing bone dystrophy associated disorders axial osteomalacia clinical presentation, 722-723 etiology, 725 histopathological findings, 723-724 laboratory studies, 723

803 overview, 722 pathogenesis, 725 radiological features, 723 treatment, 725-726 calcium II deficiency syndrome, 703-705 endosteal hyperostosis characteristics, 710-712 treatment, 712-713 fibrodysplasia ossificans progressiva characteristics, 719-721 treatment, 721-722 fibrogenesis imperfecta ossium, 726-728 fluorosis, 728-729 hepatitis C-associated osteosclerosis, 731 melorheostosis, 716-717 mixed sclerosing bone dystrophy, 718-719 osteomesopyknosis, 707 osteopathia striata, 715-716 osteopetrosis clinical presentations, 699 etiology, 701 histopathological findings, 700-701 laboratory findings, 699 overview, 698-699 pathogenesis, 701 radiological features, 699-700 treatment, 701-702 osteopoikilosis, 713- 715 pachydermoperiostosis, 729-731 progressive diaphyseal dysplasia, 707-710 clinical presentation, 708 etiology, 709-710 histopathological findings, 709 laboratory findings, 708-709 overview, 707-708 pathogenesis, 709-710 treatment, 710 pyknodysostosis, 705-707

P Pachydermoperiostosis, characteristics, 729-731 Paget' s disease differential diagnosis, 553- 554 drug treatment, 581-592 bisphosphonates, 585-590 calcitonin, 581-585 combination therapy, 591 gallium nitrate, 591 indications, 581 mithracin, 590-591 monitoring, 591-592 epidemiology, 545-547

804 Paget's disease ( C o n t i n u e d ) etiology, 593-596 focal manifestations, 554- 562 jaw complications, 557 knee pain, 561-562 pain, 554 pelvic deformities, 560-562 skull patterns, 554-557 spinal deformities, 558-560 histopathology, 547- 554 historical perspectives, 545, 593-596 incidence, 545-547 local complications, 562-569 fractures, 562-564 neoplasia, 564-569 metabolic aspects, 569-577 bone matrix metabolism, 571-577 calcitonin effects, 575-576 collagenolysis, 572 hydroxylysine excretion, 572-573 hydroxyproline involvement, 572-574 noncollagenous bone protein metabolism, 574575 pagetic bone matrix, 571-572 serum alkaline phosphatase, 576-577 serum procollagen peptides, 574 tartrate-resistant acid phosphatase, 577 mineral metabolism, 569-571 surgery, 592-593 systemic complications, 578-581 angioid streaks, 580-581 calcific periarthritis, 579 cardiovascular complications, 579-580 chondrocalcinosis, 579 gout, 578 hypercalcemia, 578 hypercalciuria, 578 hyperuricemia, 578 malabsorption syndrome, 581 pseudoxanthoma elasticum, 580-581 renal calculi, 578 skin changes, 580-581 Pain osteomalacia association, 339 Paget's disease association, 554, 561-562 Pamidronate malignancy disease hypercalcemia treatment, 643644 osteoporosis management, 402, 626 Paget's disease treatment, 588-589 Pancreatitis familial benign hypocalciuric hypercalcemia association, 481 hyperparathyroidism association, 424

Index Parathyroid gland carcinomas characteristics, 413-418 operative management, 475 circulating parathyroid hormone fragment origin, 63 -64 development, 53, 469-471 developmental disorders, 508-509 hyperparathyroidism role, s e e Hyperparathyroidism infiltrative disease, 506 parathyroidectomy, renal osteodystrophy therapy, 459-460, 475 parathyroid hormone biosynthesis, 58-59 renal failure role, 444-445 Parathyroid hormone action physiology bone, 67 kidneys calcium reabsorption, 65-66 phosphate reabsorption, 66, 211-213 renal effects, 67 vitamin D metabolite synthesis, 66 receptors, 73-82 biological role, 82-83 parathyroid hormone/parathyroid hormone-related peptide receptor, 74-80 parathyroid hormone-2 receptor, 80-81 structure-based design, 82 biosynthesis 1,25-dihydroxyvitamin D effects, 145 historical perspectives, 56-57 parathyroid hormone gene, 58, 507-508 precursor molecules, 57-58 regulation, 58-59 signal sequence function, 57-58 calcitonin production, 95 calcium homeostasis regulation, 52-53, 105, 169, 445 -448 chemistry, 53- 56 circulating forms, 61-65 biological significance, 61-63 fragment origin, 63-65 hyperparathyroidism role, s e e Hyperparathyroidism hyperphosphatemia, 227 hypocalcemia role, s e e Hypocalcemia hypophosphatemia, 217- 218 Jansen's disease role, 78-80, 426-427 magnesium absorption effects, 192-193 malignant disease hypercalcemia pathophysiology, 641-642 metabolism, 64-65 osteomalacia role, 345-348 osteoporosis management, 405 phosphate absorption effects, 185

Index Parathyroid hormone ( C o n t i n u e d ) phosphorus reabsorption role, 211-213 renal osteodystrophy role, s e e Renal osteodystrophy secretion, 59-61 x-linked hypophosphatemic tickets role, 218-220 Parathyroid hormone-related peptide action physiology, receptors, 73-82 biological role, 82-83 parathyroid hormone/parathyroid hormone-related peptide receptor, 74-80 parathyroid hormone-2 receptor, 80-81 structure-based design, 82 bone development role, 72-73 calcium homeostasis role, 69-72 embryologic function, 4 gene structure, 68-69 historical perspectives, 53, 67-68 hypocalcemia role, 503 malignant disease hypercalcemia pathophysiology, 638-639, 641 skeletal development role, 763 translated protein chemistry, 69-72 Parfollicular cells calcitonin production, 96-97 calcitonin secretion, 101-102 Pediatric diseases autoimmune polyendocrinopathy- candidiasis- ectodermal dystrophy, 507 bone biopsies, 267 DiGeorge syndrome, 509 hyperparathyroidism, 425 juvenile onset rheumatoid arthritis, 628-633 osteoarthritis, 631-633 reflex sympathic dystrophy, 629-631 regional migratory osteolysis, 631 neonatal hypocalcemia, 509- 510 neonatal severe primary hyperparathyroidism biochemical features, 489-490 clinical features, 489-490 extracellular calcium ion-sensing receptor mutations, 490-491 parathyroid regulation, 492-493 renal function, 492-493 targeted deletion mouse development, 491-492 genetics, 490 osteogenesis imperfecta, differential diagnosis, 656657 overview, 759 pseudohypoparathyroidism, 519 pyknodysostosis, 705-707 tickets, s e e Rickets skeletal deformities, 454 skeletal development, 759-764 cell differentiation regulation, 760-762

805 growth factor involvement, 762-763 matrix molecules role, 764 transcriptional skeletal patterning regulation, 760762 subcutaneous fat necrosis, 615 Pelvis, Paget's disease manifestations, 560-562 Penicillamine, cystine nephrolithiasis treatment, 754755 Peptic ulcers, hyperparathyroidism association, 424 Periarthritis, Paget's disease association, 579 Periosteal envelope, characteristics, 238 P E X gene, x-linked hypophosphatemic tickets role, 219 Phosphatase, s e e a l s o Alkaline phosphatase bone resorption marker, 319 Phosphate absorption pathophysiology clinical manifestations, 186, 351 decreased absorptive states, 188-190 extrinsic inhibiting factors, 190 intestinal malabsorption diseases, 188 intrinsic intestinal absorption defects, 189-190 nutritional deficiency, 188 vitamin D metabolism disorders, 188-189 parathyroid hormone effects, 66 calcium absorption effects, 182 characteristics, 183 homeostasis disorders hyperphosphatemia causes, 226-229 clinical manifestations, 229-230, 457-458 treatment, 230 hypophosphatemia, s e e Hypophosphatemia overview, 207- 216 bone remodeling, 215- 216 gastrointestinal absorption, 207-209, 222, 225, 230 renal reabsorption, 209-215 hydroxyapatite crystals, s e e Bone, mineralization hypercalcemia management, 434 hyperparathyroidism diagnosis, 467 hypophosphatemic osteomalacia treatment, 373 increased absorptive states, 186-190 bioavailability, 188, 190 vitamin D-dependent hyperabsorption, 186-187 vitamin D-independent hyperabsorption, 187-188 magnesium deficiency effects, 189-190 malignancy disease hypercalcemia treatment, 643, 645 physiology absorption mechanisms, 184 balance, 184 measurement, 184-185 regulation, 185

806 Phosphate ( C o n t i n u e d ) sources, 183-184 renal excretion, calcitonin effects, 106 renal osteodystrophy therapy, 457-458 transport studies, 774 Phosphorus amorphous calcium-phosphorus detection, 31-32 calcium-phosphorus bone mineral phase, 23-30 homeostasis regulation, vitamin D role excretion regulation, 213- 214 hyperabsorption, 186-187 uptake stimulation, 208, 220 renal reabsorption mechanisms, 209-215 acid-base balance effects, 213 adrenal hormone effects, 213 cellular reabsorption mechanisms, 210-211 dietary phosphorus intake alterations, 214-215 growth hormone effects, 214 hyperphosphatemia, 186, 226-227 hypophosphatemia, 217 parathyroid hormone effects, 66, 211-213 stanniocalcin, 215 superficial-deep nephron transport compared, 210 vitamin D role, 213-214 Photon absorptiometry, s e e a l s o X-ray absorptiometry noninvasive bone assessment dual photon absorptiometry, 282-286 single photon absorptiometry, 281-282 Platelet-derived growth factor, embryologic function, 15 Plicamycin hypercalcemia management, 433-434 malignancy disease hypercalcemia treatment, 645646 Polar activity zone, limb development, 3 Polyacrylamide gel electrophoresis, collagen analysis, osteogenesis imperfecta role, 671 Polyendocrinopathy- candidiasisectodermal dystrophy, characteristics, 507 Polyglandular syndrome, characteristics, 507 Polymerase chain reaction, osteogenesis imperfecta mutation analysis, 671-672 Potassium citrate cystine nephrolithiasis treatment, 754 gouty diathesis treatment, 753 hyperuricosuric calcium nephrolithiasis treatment, 748 hypocitraturic calcium nephrolithiasis treatment, 751-752 Prednisone fibrogenesis imperfecta ossium treatment, 728 progressive diaphyseal dysplasia treatment, 710 Predominant hyperparathyroid bone disease, biopsy, 262-263

Index Preeclampsia, calcium absorption effects, 179 Pregnancy calcium absorption effects, 175 hyperparathyroidism, 425-426 osteogenesis imperfecta complications, 663 Preosteomalacia, s e e Hypovitaminosis D osteopathy; Osteomalacia Primary hyperparathyroidism, s e e Hyperparathyroidism Procollagen peptides bone turnover marker, 318 osteogenesis imperfecta role, 671 Paget's disease association, bone matrix metabolism, 574 Progressive diaphyseal dysplasia, characteristics clinical presentation, 708 etiology, 709-710 histopathological findings, 709 laboratory findings, 708-709 overview, 707-708 pathogenesis, 709-710 treatment, 710 Prolactin, calcium absorption regulation, 169 Prostaglandins hyperprostaglandin E syndrome, 174 malignant disease hypercalcemia pathophysiology, 642 Pseudohypoparathyroidism, 510- 519, s e e a l s o Hypoparathyroidism hyperphosphatemia, 227 molecular classification, 512-519 Albright' s hereditary osteodystrophy, 510, 515516 multiple hormone resistance, 516- 517 neurosensory abnormalities, 517 phenotypic variability, 517-518 type IA, 513-518 type IB, 518 type IC, 518 type II, 518-519 natural history, 519 pathophysiology, 510-512 Pseudoxanthoma elasticum, Paget's disease association, 580-581 Psychological supports, osteogenesis imperfecta management, 680-681 Puberty, calcium absorption effects, 171 Pulmonary system osteogenesis imperfecta clinical features, 662 small cell carcinoma, 614 Pyknodysostosis characteristics, 705-707 treatment, 707 Pyridinoline, bone resorption marker, 319-321 Pyr peptide, bone resorption marker, 320

Index

807

R Race, calcium absorption effects, 171 - 172 Radiation, s e e a l s o Ultraviolet radiation exposure, hyperparathyroidism risk, 469 Radiographic morphometry, s e e a l s o Histomorphometry femur trabecular pattern assessment, 278-279 vertebral body deformity detection, 277-278 Radiography absorptiometry, 279-280 axial osteomalacia diagnosis, 723 calcium II deficiency syndrome diagnosis, 703 endosteal hyperostosis diagnosis, 712 fibrodysplasia ossificans progressiva diagnosis, 720 fibrogenesis imperfecta ossium diagnosis, 726-727 fluorosis diagnosis, 729 melorheostosis diagnosis, 717 mixed sclerosing bone dystrophy diagnosis, 718 osteopathia striata diagnosis, 716 osteopetrosis diagnosis, 699-700 osteopoikilosis diagnosis, 715 osteoporosis diagnosis, 390-391 pachydermoperiostosis diagnosis, 730-731 Paget's disease monitor, 555, 591-592 pyknodysostosis diagnosis, 706 radiogrammetry, 279 Reflex sympathic dystrophy, characteristics, 629-631 Regional migratory osteolysis, characteristics, 631 Remodeling, s e e Bone turnover Renal bone disease, l oL-hydroxylation impairment, 359-360 Renal calculi, Paget's disease association, 578 Renal function calcitonin effects, 106-107 calcium absorption, 178 calcium reabsorption, 65-66 chronic renal failure, 444-445 1,25-dihydroxyvitamin D synthesis, 66, 145 familial benign hypocalciuric hypercalcemia patients, 482-483, 492-493, 496 hypercalcemia association, 429, 482 hyperparathyroidism association, 418-419, 429 parathyroid hormone metabolism, 64-67 phosphorus reabsorption, 209-215 acid-base balance effects, 213 adrenal hormone effects, 213 cellular reabsorption mechanisms, 210-211 dietary phosphorus intake alterations, 214-215 growth hormone effects, 214 hyperphosphatemia, 186, 226-227 hypophosphatemia, s e e Hypophosphatemia parathyroid hormone effects, 66, 211-213 stanniocalcin, 215

superficial-deep nephron transport compared, 210 vitamin D role, 213- 214 stone formation, s e e Nephrolithiasis Renal osteodystrophy biopsy, 261-266 bone histology, 451-453 adynamic bone, 452 high-turnover bone disease, 451 lesions, 452-453 low-turnover bone disease, 452 divalent-ion metabolism alterations, 453-455 extraskeletal calcifications, 456-457 operative management, 475 osteomalacia, 451-452 overview, 443 radiographic features, 455-456 secondary hyperparathyroidism, 443-451 bone histology, 451 calcemic action resistance, 450-451 calcium sensitivity, 445-448 parathyroid hormone degradation, 451 parathyroid hormone resistance, 450-451 phosphate retention, 448-450 vitamin D metabolism alterations, 444-445 therapy, 457-460 aluminum accumulation, 460 calcium supplements, 458-459 hemodialysis dialysate calcium concentration, 459 parathyroidectomy, 459-460, 475 phosphate retention, 457-458 vitamin D, 459 Renal tubular acidosis hypophosphatemia association, 217 osteomalacia association, 366-367 Resorption, s e e Bone, resorption; Bone turnover Respiratory alkalosis, hypophosphatemia role, 222 Restriction fragment length polymorphisms, osteogenesis imperfecta mutation analysis, 672 Rheumatoid arthritis, s e e a l s o Osteoarthritis characteristics, 613 focal subchondral bone erosion, 622-624 generalized bone loss, 624-626 age effects, 625 disease activity, 625 drug effects, 625-626 fractures, 626 functional status, 625 osteoporosis treatment, 626 juvenile onset, 628-633 osteoarthritis, 631-633 reflex sympathic dystrophy, 629-631 regional migratory osteolysis, 631 marginal bone erosion, 622-624 periarticular bone loss, 624

808

Index

Rheumatological disorders, see specific t y p e s Rickets, see a l s o Osteomalacia biochemical findings, 766 classification, 765 definition, 764 drug therapy, 134 environmental association, 124-125 heritable calcipenic tickets, 767-769 heritable phosphopenic tickets, 769-777 Fanconi's syndrome, 775-777 hereditary hypercalciuria hypophosphatemic tickets, 774-775 x-linked hypophosphatemic rickets, 769-774 historical perspectives, 764-765 hypophosphatemia Fanconi's syndrome, 775-777 hereditary hypercalciuria hypophosphatemic tickets, 774-775 vitamin D-deficient rickets, 220-221 vitamin D-resistant tickets, 186, 221 x-linked hypophosphatemic tickets, 189, 218-220, 769-774 oncogenic osteomalacia, 221-222, 772-773 pathophysiology, 765 radiographic findings, 766 vitamin D therapy, 125-126, 766 Risedronate, Paget's disease treatment, 590 RNA calcitonin biosynthesis, calcitonin gene mRNA transcript splicing, 100-101 collagen mRNA mutation localization, osteogenesis imperfecta analysis, 672

S Saccharase, calcium absorption effects, 173 Saline, malignancy disease hypercalcemia treatment, 643 Sarcoidosis calcium absorption effects, 174 calcium metabolism abnormalities, 609 clinical manifestations, 611 immunology, 607-609 pathogenesis, 609-611,732 pathology, 607-609 treatment, 611-612 Sarcomas, Paget's disease complications, 564-569 Schmorl's nodule, Paget's disease histopathology, 553 Sclerosis, s e e Mixed sclerosing bone dystrophy; Osteosclerosis Sclerosteosis characteristics, 710-712 treatment, 712-713 Seminoma, characteristics, 614

Seronegative spondyloarthropathies, s e e s p e c i f i c t y p e s Sex type, calcium absorption effects, 171-172 Sialoprotein, characteristics, 6 Signal transduction, calcitonin role, 111-112 Skeletal development embryology, 2 fibroblast growth factor role, 3-5, 14-15, 763 pediatric disease role, 759-764 cell differentiation regulation, 760-762 growth factor involvement, 762-763 matrix molecules role, 764 transcriptional skeletal patterning regulation, 760762 Skeletal disorders, s e e s p e c i f i c t y p e s Skeletal muscle hyperparathyroidism association, 423-424 hypophosphatemia diagnosis, 224 osteomalacia effects, 339-340 Skeletal structure anatomy, 276 balance, 242 bone marrow cells, 243-244 bone surfaces, 238 cancellous bone, 238 cortical bone, 238 fractures, see Fractures lamellar bone, 239-240 modeling, 240-242 osteoblasts, s e e Osteoblasts osteoclasts, see Osteoclasts osteogenesis imperfecta clinical features, 657-659 structural unit, 238-239 turnover, 242 woven bone, 239-240 Skin osteogenesis imperfecta manifestations, 660 Paget's disease manifestations, 580-581 vitamin D metabolism 1,25-dihydroxyvitamin D effects, 148 photosynthesis, 127-128 Skull osteogenesis imperfecta clinical features, 659 Paget's disease manifestations, 554-557 Sodium alkali, gouty diathesis treatment, 753 Sodium cellulose phosphate, hypercalciuric calcium nephrolithiasis treatment, 744 Sodium citrate, cystine nephrolithiasis treatment, 754 Sodium fluoride fibrogenesis imperfecta ossium treatment, 728 osteoporosis management, 403-404 Sodium-phosphate co-transport proteins cellular phosphate reabsorption mechanisms, 210211,215 x-linked hypophosphatemic tickets role, 219

Index Sodium phytate, sarcoidosis treatment, 612 Somatic gene therapy, osteogenesis imperfecta management, 682 Southern blot, osteogenesis imperfecta mutation analysis, 671-672 SOX-9 transcription factor, skeletal development role, 5 Spine computed tomography assessment, 288, 558-559 osteogenesis imperfecta clinical features, 659 Paget's disease manifestations, 557-559 Spondylitis, s e e Ankylosing spondylitis Spondyloarthropathies, s e e s p e c i f i c t y p e s Stanniocalcin, phosphate excretion regulation, 215 Stress, osteogenesis imperfecta psychological management, 680-681 Struvite stones, formation, infection role, 755 Subcutaneous fat necrosis, characteristics, 615 Sudeck's atrophy, characteristics, 629-631 Surgery hyperparathyroidism treatment, 465-477 historical perspectives, 465-466 operation conduct exploration, 469-471 resection extent, 471-472 parathyroid carcinoma, 475 postoperative management, 475-477 airway protection, 476 calcium replacement, 476-477 preoperative evaluation alkaline phosphatase measurement, 467 bicarbonate measurement, 467 calcium diagnosis, 466 familial disease etiology, 468-469 general assessment, 469 informed consent, 469 localization, 468 operation indicators, 467-468 parathyroid hormone measurement, 466-467 phosphate measurement, 467 physical findings, 465-466 radiation exposure, 469 recurrent hyperparathyroidism management, 472475 localization, 472-474 reoperation, 474-475 renal osteodystrophy, 459-460, 475 hypoparathyroidism induction, 505-506 melorheostosis treatment, 717 osteogenesis imperfecta treatment, 679-680 Paget's disease treatment, 592-593 sclerosteosis treatment, 712-713 Syphilis, Paget's disease histopathology, 553 Systemic lupus erythematosus, characteristics, 621,628

809

T Tartrate-resistant acid phosphatase bone resorption markers, 319 Paget's disease association, 577 Teeth, osteogenesis imperfecta manifestations, 660661 N-Telopeptide bone resorption marker, 321 Paget's disease therapy monitor, 591-592 Tetracycline, bone mineralization mechanisms data interpretation, 329 kinetics, 334 Thiazides hypercalcemia diagnosis, 428-429 hypercalciuric calcium nephrolithiasis treatment, 744-746 hyperparathyroidism diagnosis, 428-429 osteoporosis management, 405 Thyrocalcitonin, s e e Calcitonin Thyroid gland calcitonin production, s e e Calcitonin osteogenesis imperfecta association, 662 Thyroid hormone, s e e a l s o Hyperthyroidism replacement therapy, 539-540 Thyroid-stimulating hormone, thyroid gland regulation, 531-532, 535-536, 538-540 Tiopronin, cystine nephrolithiasis treatment, 754-755 T lymphocytes, sarcoidosis pathology, 607-609 Tomography, s e e Computed tomography Toxic agents, hypoparathyroidism role, 505-506 Toxic shock syndrome, hypophosphatemia role, 222223 Toxins, hypoparathyroidism induction, 505-506 Transcription factors, skeletal development role, 5 Transforming growth factor embryologic function, 13-14 malignant disease hypercalcemia pathophysiology, 641 Transmission electron microscopy bone apatite abnormality detection, 40-41 bone crystal structure analysis, 32-35 Triiodothyronine, phosphate absorption effects, 187 Tuberculosis, characteristics, 612-613 Tumoral calcinosis, hyperphosphatemia, 227-228 Tumor lysis syndrome, hyperphosphatemia role, 228 Tumors calcitriol-induced hypercalcemia association, 613614 calcitriol therapy, 146-147 exogenous subclinical hyperthyroidism, thyroid cancer suppression, 536-537 malignant disease hypercalcemia association clinical features, 642

810

Index

Tumors ( C o n t i n u e d ) pathophysiology colony-stimulating activity, 642 hematological malignancies, 638-639 lymphomas, 613-614, 639 malignancy types, 637 metastasis solid tumors, 639-640 myeloma, 638-639 nonmetastasis solid tumors, 640-642 parathyroid hormone, 641-642 parathyroid hormone-related protein, 641 prostaglandins, 642 transforming growth factor, 641 treatment alendronate, 644-645 bisphosphonates, 644-645 calcitonin, 643 corticosteroids, 645 furosemide, 643 gallium nitrate, 646 glucocorticoids, 643 hemodialysis, 644 indications, 642-643 indomethacin, 645 intravenous saline, 643 mithramycin, 645-646 oral phosphate, 645 pamidronate, 643-644 parenteral phosphate, 643 osteomalacia induction, 772-773 Paget's disease complications, 564-569, 593 parathyroid carcinoma characteristics, 413-418 operative management, 475 pulmonary carcinoma, 614 seminoma, 614 Turnover, s e e Bone turnover

U Ultrasound, s e e a l s o Densitometry noninvasive bone assessment applications age-related changes, 295-296 bone strength measurement, 295 bone structure measurement, 295 fracture risk, 296 longitudinal monitoring, 296 osteoporosis, 295, 392 bone density measurement, 292 parameters, 292-295 broadband attenuation, 294-295 sound speed, 293-294

standardization, 295 Ultraviolet radiation, s e e a l s o Radiation vitamin D photobiology, 125-131 circulating concentrations, 130-131 cutaneous production, 128-130 human skin photosynthesis, 127-128 vitamin D production, 125-126 Uremic osteodystrophy, biopsy, 265 Ureteral diversion, osteomalacia association, 366-367 Uric acid stones, gouty diathesis, 752-753

V van Buchem's disease characteristics, 710-712 treatment, 712-713 Vascular endothelial growth factor, embryologic function, 15 Vascular system, s e e Cardiovascular system Vitamin A, hypercalcemia role, 429 Vitamin D hypercalcemia role, s e e Hypercalcemia hypermagnesemia role, 194 hypovitaminosis D osteopathy osteomalacia role bone mineral metabolism abnormalities, 345348 diagnostic considerations, 348 histological evolution, 335-338 histopathology, 340-341 skeletal radiology, 341-342 temporal evolution, 348 prevention, 370-371 treatment bone mineral metabolism effects, 371-372 management aspects, 372-373 remodeling effects, 371-372 vitamin D response, 371 intoxication, 615 metabolism abnormal physiology, 610-611 assays, 148-155 clinical utility, 152-154 1,25-dihydroxyvitamin Du measurement, 151 24,25-dihydroxyvitamin Du measurement, 151-152 25-hydroxyvitamin D measurement, 149-150 hypocalcemic evaluation, 154-155 vitamin Du measurement, 149 calcitriol effects, s e e Calcitriol defects extrinsic depletion, 354- 355 loL-hydroxylation impairment, 359-360

Index

811

Vitamin D ( C o n t i n u e d ) 25-hydroxylation impairment, 357-358 intrinsic depletion, 355-357 overview, 349- 350 saroidosis, s e e Sarcoidosis 1,25-dihydroxyvitamin D, s e e Calcitriol 24,25-dihydroxyvitamin Du conversion, 139140 historical perspectives, 124-126, 155 25-hydroxyvitamin D conversion, 132-135 a-ring metabolism, 140-141 clinical disorders, 132-135 hepatic metabolism, 132 side-chain metabolism, 140-141 intestinal absorption, 131 - 132 nonhypercalcemic analog actions, 146 normal physiology, 609-610 overview, 123-124 photobiology cutaneous production regulation, 128-130 photosynthesis in human skin, 127-128, 609 synthesis regulation, 128 ultraviolet irradiation effects, 130-131 renal osteodystrophy role secondary hyperparathyroidism, 444-445 therapy, 459 tickets, 124-125, 220-221,766 vitamin Du2, 141 - 142 osteomalacia role, s e e Osteomalacia osteoporosis association bone loss pathogenesis, 360 differential treatment, 360-361 phosphorus homeostasis regulation excretion regulation, 213- 214 hyperabsorption, 186-187 uptake stimulation, 208, 220 renal osteodystrophy therapy, 459 x-linked hypophosphatemic tickets treatment, 770771

W Warfarin, fibrodysplasia ossificans progressiva treatment, 721

William' s syndrome, characteristics, 614-615 Wilson's disease, osteomalacia association, 365-366 World wide web, osteogenesis imperfecta mutations, 671 Woven bone, characteristics, 239-240

X X-linked hypophosphatemic rickets, 769-774 biochemical fndings, 770 characteristics, 218-220 clinical features, 769-770 molecular genetics, 771-772 mouse models, 773-774 osteoblast function studies, 774 phosphate transport studies, 774 treatment, 770-771 tumor-induced osteomalacia, 772-773 vitamin D metabolism, 188-189 X-ray absorptiometry, s e e a l s o Photon absorptiometry noninvasive bone assessment dual X-ray absorptiometry cross-calibration, 299-300 methods, 282-286 osteoporosis diagnosis, 391-392 quality assurance, 298-299 standardization, 300 single X-ray absorptiometry, 281-282 X-ray diffractometry amorphous calcium-phosphorus detection, 31-32 bone apatite abnormality detection, 38-41 bone crystal structure analysis, 32-35 X rays hypovitaminosis D osteopathy detection, 341-342 renal osteodystrophy diagnosis, 455-456

Z Zoledronate, Paget's disease treatment, 590 Zollinger-Ellison syndrome, peptic ulcer association, 424 Zone of polar activity, limb development, 3


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