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ISBN: 0-8247-0538-6 This book is printed on acid-free paper. Headquarters Marcel Dekker, Inc. 270 Madison Avenue, New York, NY 10016 tel: 212-696-9000; fax: 212-685-4540 Eastern Hemisphere Distribution Marcel Dekker AG Hutgasse 4, Postfach 812, CH-4001 Basel, Switzerland tel: 41-61-261-8482; fax: 41-61-261-8896 World Wide Web http://www.dekker.com The publisher offers discounts on this book when ordered in bulk quantities. For more information, write to Special Sales/Professional Marketing at the headquarters address above. Copyright 䉷 2001 by Marcel Dekker, Inc.
All Rights Reserved.
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Preface
Ever since Emil Fischer established the stereochemical configuration of D-(⫹)-glucose at the end of the nineteenth century, carbohydrate chemistry has become an important branch of organic chemistry. Steady advances in carbohydrate synthetic and analytical methods have been made over the past hundred years. However, it is the past two decades that have seen remarkable new discoveries in the biology of carbohydrates and provided renewed impetus to the synthesis of complex glycoconjugates and pursuit of their medicinal and industrial applications. Glycobiology has emerged as an internationally recognized field of study and a potentially promising route to the discovery of novel medicines. Critical biological processes—including regulation of the growth and mobility of cells, immune responses, and reactions of cells to hormones and growth factors—all depend on carbohydrates. In addition, many viruses and bacteria use cell surface carbohydrates to get into cells and initiate infections. The diversity of roles played by carbohydrates makes them exciting new targets for the development of novel treatments for cancer, infectious diseases, inflammation, and cardiovascular disorders. The spur in glycobiology research resulted in the appearance of several enormously successful carbohydrate-based drugs including but certainly not limited to heparin (an anticoagulant) and Relenza (an antiviral). Increasing numbers of organic chemists are venturing into the field of glycochemistry to bring in their own chemical expertise and to expand the area into a truly multidisciplinary field. A major motivation among carbohydrate chemists is to develop tools for probing the biological functions of glycosylation. Genome sequencing projects present a vast repertoire of biosynthetic enzymes that may be targeted by selective carbohydrate-based drugs. Advances in automated oligosaccharide synthesis are highly significant as complex structures will soon be widely attainable and exploited in studies of biological phenomena. Their integration into complex assemblies (polymers, dendrimers, and liposomes) will provide cell surface mimics of unparalleled fidelity. Studies of glycobiology will benefit from the convergent application of chemical and biological techniques. Thus, in the past few years, glycochemistry has advanced from studies of chemical glycosylation reactions and synthesis of oligosaccharides to iii
iv
Preface
chemo-enzymatic and solid-phase synthesis of glycoconjugates, carbohydrate combinatorial libraries, multivalent glycoconjugates, carbohydrate–peptide hybrids, and much more. It is the aim of this book to capture the essence of these latest developments and to provide a comprehensive review of modern glycochemistry in one collected volume. In recognition of the great potential applications of glycochemistry in the pharmaceutical and chemical industries, we solicited chapters that contain pertinent examples of the development of carbohydrate-based pharmaceuticals and commercial polymers. Each chapter is written by experts in their respective fields. Many are young scientists who have just begun research programs in carbohydrate chemistry. Although some chapters include relatively detailed experimental procedures for novel synthetic methodology, the book is intended to provide a reference framework for the latest developments in the field of glycochemistry. Recent trends in glycochemistry are presented in three parts: synthesis, principles and applications. The first six chapters provide a comprehensive, up-to-date review on the chemical synthesis of complex carbohydrates for their potential use in biological systems. The following seven chapters reveal some fundamental principles that are used to design and exploit carbohydrates for their effects in biological settings. The remaining five chapters examine the applicability of enzymes towards the chemo-enzymatic synthesis and modification of carbohydrates and polysaccharides. In Chapter 1, Peter Seeberger reflects on the promising strategies for the solid support synthesis of oligosaccharides and glycoconjugates. The chapter puts in focus the glycal assembly method and reveals protecting group strategies for carbohydrate components, synthesis of biologically important oligosaccharides, and selective glycosylation strategies. Chapters 2 and 3 bring to light the potential of strategies for stereoselective glycosylation. David Gin examines a number of methodologies used in the glycosylation of 1-hydroxy donors and points out that in the direct dehydrative coupling with an appropriate dehydrating agent, the formation of undesired by-products of hemiacetal self-condensation can be minimized even when only a slight excess of the glycosyl acceptor components is employed. David Crich examines the glycosyl triflates as extremely reactive glycosyl donors. They are prepared from anomeric sulfoxides or thioglycosides upon activation with triflic anhydride or benzenesulfenyl triflate and provide access to the elusive -mannopyranoside, which can be found in many biologically important oligomers. Hydrolytic vulnerability of O-linked glycosides makes the C-glycosides attractive sugar mimics and stable drug candidates. Maarten Postema and Daniel Calimente (Chapter 4) report on the many methods for the preparation of both ␣- and -Cglycosides that have been developed, as well as some new approaches currently in the literature. One of the key issues surrounding the synthesis of C-glycosides concerns the stereochemistry of the C-glycosidation step, which has seen a remarkable improvement over the years. As C-glycosides make their way to the forefront of carbohydrate synthesis, many mild conditions will be examined, and these sophisticated synthetic methods will facilitate their production. Todd Lowary (Chapter 5) focuses on two major polysaccharides containing Darabinofuranose, namely, arabinogalactan and lipoarabinomannan, in a quest to identify new antibiotics. These glycopolymers are found as important components of the cell wall of the Actinomycete family. Although there is now an understanding of the
Preface
v
structure of mycobacterial arabinan, the biosynthetic pathway is yet to be understood. These investigations will depend critically on the access to synthetic oligosaccharides and their analogs, which are reviewed extensively. In Chapter 6, Biao Yu and Yongzheng Hui discuss the relevance of saponins and their chemical synthesis. This important class of glycosidic steroids is found mainly in plants used as herbal medicines. However, a major issue surrounding the saponins is their ambiguous mechanism of action. The authors discuss two important strategies for the construction of saponins, each involving protective group manipulation and various glycosylation methodologies. Increasing interest in traditional herbal medicine and in ‘‘carbohydrate drugs’’ should bring further attention to this group of natural glycosides. In Chapters 7–13, the focus shifts to the biochemistry of carbohydrates and the exploration of fundamental principles related to cell signaling and protein–carbohydrate interactions on a molecular level. Sialic acids are a class of nine-carbon monosaccharides found at the termini of oligosaccharides in many mammalian cellular systems. Randall Halcomb and Mark Chappell (Chapter 7) summarize the most current sialylation technology. Both chemical and enzymatic methodologies for coupling sialic acid to various carbohydrate moieties are examined while providing the reader with chemical detail that one requires to work in this field. In Chapter 8, David Mann and Laura Kiessling explore a number of fundamental binding principles such as the energetics surrounding hydrogen bonding, metal chelation, hydrophobic effects, coulombic interactions, and the role of water in protein–carbohydrate interactions. The information provides a prelude to the concept of multivalency in understanding the principles, methodologies, and techniques used to increase an overall binding affinity between carbohydrates and proteins. One technique used to achieve multivalency revolves around linking carbohydrates to polymeric supports so as to increase the number of binding sites as well as obtain optimal distal properties for effective binding. Rene´ Roy (Chapter 9), another pioneer in the application of multivalency effects in glycobiology, discusses some novel multivalent glycotools for biochemical investigations related to sialic acid. Roy describes methodology to produce sialyloligosaccharides, functionalized sialosides, sialoside clusters, N- and O-linked glycopeptides, amphiphilic calix[4]arene nanostructures, glycopolymers, and glycodendrimers. Hybrid dendrimer–polymer glycoclusters are also introduced as new and exciting complexes to show increased binding affinity. In Chapters 10 and 11, Jalal Haddad and Shahriar Mobashery, Lakshmi Kotra, and Mei-Zheng Liu examine the diversity of aminoglycosides and their significant role as antibiotics. They reveal the specificity of aminoglycosides for binding to RNA constructs derived from the HIV–RRE and TAR RNA activator regions and examine the varying inhibitory effects of aminoglycans on different microorganisms. They also introduce methodologies in the synthesis of aminoglycoside antibiotics by examining the chemical strategies that have been developed. In Chapter 12, Bryan Yeung, Pek Chong, and Peter Petillo survey the chemical preparation of the glycosaminoglycans, oligosaccharides of hyaluronan, chondroitin sulfate, dermatan sulfate, keratan sulfate, heparin, and heparan sulfate. Despite the biological importance of these ubiquitous carbohydrate polymers, there are few reports of the chemical syntheses of glycosaminoglycan (GAG) oligosaccharides. The multiple functionality of GAGs provides an excellent scaffold on which structure–
vi
Preface
activity relationships can be studied, but their syntheses present an unparalleled challenge to the synthetic carbohydrate chemist. The authors recognize the difficulty in the construction of these highly functionalized carbohydrates and present newly developed protecting groups as well as glycosylation procedures to synthetically access GAG fragments. In Chapter 13, Jacquelyn Gervay-Hague and Thomas Weathers, Jr., discuss some of the more recent chemistry behind pyranosyl sugar amino acids and the important role they play in biological systems. The authors make a complex group of carbohydrates seem relatively simple and interesting by addressing the important issues and illustrating them with clear, concise pictorial schemes. Included are the synthesis of C-aminoglycosides, protecting groups, the chemistry of glycosidic linkage, strategies for block synthesis, and the introduction of solid-phase synthesis of mixed sugar amino acid conjugates. The emphasis of this chapter is twofold: to describe the synthesis of aminoglycans oligomers and to examine the stable secondary structural characteristics of amido-linked oligomers. Chapters 14–18 are meant to pioneer a chemo-enzymatic approach to the construction of carbohydrates. One of the underlying themes of this book is the exploitation of the complexity of carbohydrates and applying various methodologies to simplify their production. In Chapter 14, Xiangping Qian, Keiko Sujino, Monica Palcic, and Murray Ratcliffe discuss the potential of glycosyltransferases in oligosaccharide synthesis. The authors focus on the enzymes responsible for creating various glycosidic linkages and the sugar donor requirements for glycosyltransferases as well as giving some detailed information for applying this knowledge to largescale carbohydrate synthesis. Chapter 15, written by H. N. Cheng and Qu-Ming Gu, discusses the application of biotransformations to polysaccharides modification. Polysaccharides are natural materials ideally suited for enzymatic modifications. The chapter introduces lipasecatalyzed and -galactosidase–catalyzed modifications of carbohydrate polymers. Peter Andreana, Wei Zhang, and Peng George Wang (Chapter 16) take a close look at the ␣-gal epitope as a case study. This carbohydrate sequence is responsible for the hyperacute organ rejection associated with xenotransplantation. Efficient production of this carbohydrate epitope can lead to increased studies directed toward solving the xenotransplantation conundrum. The authors examine both chemical and enzymatic routes for synthesizing the epitope and present some important physical properties associated with binding of the carbohydrate to the protein (epitope–antibody interaction). Bacterial glycosyltransferases, the topic of Chapter 17, by Przemyslaw Kowal, Xi Chen, and Peng George Wang, are enzymes responsible for the assembly of bacterial cell walls (e.g., succinoglycan) and lipopolysaccharides or polysaccharide structures attached to the lipids of the outer membrane of gram-negative bacterial cells. Lipopolysaccharides are at the forefront of bacterial interactions with the outside world. These structures have been found to be essential in processes ranging from root nodulation to human pathogenicity. Therefore studies on the corresponding glycosyltransferases are of great importance and interest. The authors mention an emerging technology using biosynthetic pathway engineering to produce carbohydrates on a large scale. We envision that such technology will be rapidly developed into commercial use.
Preface
vii
Scarlett Goon and Carolyn Bertozzi close the book with a chapter discussing metabolic substrate engineering as a tool for glycobiology. In this approach, metabolic pathways are intercepted with unnatural monosaccharide substrates, leading to their incorporation into cell surface oligosaccharides. This provides an innovative method for studying the functions of the surface sugar structures. Modified substrates might also block biosynthetic enzymes, producing phenotypes similar to those induced by glycosyltransferase inhibitors. This chapter focuses on the flux of carbohydrate precursors and synthetic carbohydrate analogs through the metabolic pathways of the cell and the information that can be gained from investigating such processes. This book is intended for graduate students and researchers in carbohydrate chemistry, biochemistry, medicinal chemistry, and glycobiology in both academic and industrial laboratories. We feel privileged to have attracted such a distinguished group of investigators and express our sincerest gratitude for their time and effort in making this endeavor a meaningful contribution. Peng George Wang Carolyn R. Bertozzi
Contents
Preface Contributors Introduction: New Challenges in Carbohydrate Research
Chi-Huey Wong
1. Solid Phase Oligosaccharide Synthesis Peter H. Seeberger
iii xi xv 1
2. Dehydrative Glycosylation with 1-Hydroxy Donors David Gin
33
3. Chemistry of Glycosyl Triflates: Synthesis of  -Mannopyranosides David Crich
53
4. C-Glycoside Synthesis: Recent Developments and Current Trends Maarten H. D. Postema and Daniel Calimente
77
5.
D-Arabinofuranosides from Mycobacteria: Synthesis and Conformation Todd L. Lowary
133
6. Chemical Synthesis of Bioactive Steroidal Saponins Biao Yu and Yongzheng Hui
163
7. Recent Developments in Technology for Glycosylation with Sialic Acid Randall L. Halcomb and Mark D. Chappell
177
8. The Chemistry and Biology of Multivalent Saccharide Displays David A. Mann and Laura L. Kiessling
221
9. Designing Novel Multivalent Glycotools for Biochemical Investigations Related to Sialic Acid Rene´ Roy 10. Aminoglycoside Antibiotics: Structures and Mechanisms of Action Jalal Haddad, Lakshmi P. Kotra, and Shahriar Mobashery
277 307 ix
x
Contents
11. Methodologies in Syntheses of Aminoglycoside Antibiotics Jalal Haddad, Mei-Zheng Liu, and Shahriar Mobashery
353
12. Synthesis of Glycosaminoglycans Bryan K. S. Yeung, Pek Y. C. Chong, and Peter A. Petillo
425
13. Pyranosyl Sugar Amino Acid Conjugates: Their Biological Origins, Synthetic Preparations, and Structural Characterization Jacquelyn Gervay-Hague and Thomas M. Weathers, Jr.
493
14. Glycosyltransferases in Oligosaccharide Synthesis Xiangping Qian, Keiko Sujino, R. Murray Ratcliffe, and Monica M. Palcic
535
15. Biotransformation of Polysaccharides H. N. Cheng and Qu-Ming Gu
567
16. From a Carbohydrate Sequence to Extensive Research Programs: The ␣-gal Epitope as a Case Study Peter R. Andreana, Wei Zhang, and Peng George Wang
581
17. Microbial Glycosyltransferases Przemyslaw Kowal, Xi Chen, and Peng George Wang
625
18. Metabolic Substrate Engineering as a Tool for Glycobiology Scarlett Goon and Carolyn R. Bertozzi
641
Index
675
Contributors
Peter R. Andreana Michigan
Department of Chemistry, Wayne State University, Detroit,
Carolyn R. Bertozzi Departments of Chemistry and Molecular and Cell Biology, Howard Hughes Medical Institute, and University of California, Berkeley, California Daniel Calimente Michigan
Department of Chemistry, Wayne State University, Detroit,
Mark D. Chappell Department of Chemistry and Biochemistry, University of Colorado, Boulder, Colorado Xi Chen
Department of Chemistry, Wayne State University, Detroit, Michigan
H. N. Cheng
Hercules Incorporated, Wilmington, Delaware
Pek Y. C. Chong Department of Chemistry, University of Illinois at Urbana-Champaign, Urbana, Illinois David Crich Illinois
Department of Chemistry, University of Illinois at Chicago, Chicago,
Jacquelyn Gervay-Hague son, Arizona
Department of Chemistry, University of Arizona, Tuc-
David Gin Department of Chemistry, University of Illinois at Urbana-Champaign, Urbana, Illinois Scarlett Goon Departments of Chemistry and Molecular and Cell Biology, Howard Hughes Medical Institute, and University of California, Berkeley, California Qu-Ming Gu Jalal Haddad igan
Hercules Incorporated, Wilmington, Delaware Department of Chemistry, Wayne State University, Detroit, Mich-
Randall L. Halcomb Department of Chemistry and Biochemistry, University of Colorado, Boulder, Colorado xi
xii
Contributors
Yongzheng Hui State Key Laboratory of Bio-organic and Natural Product Chemistry, Shanghai Institute of Organic Chemistry, Chinese Academy of Sciences, Shanghai, China Laura L. Kiessling Departments of Chemistry and Biochemistry, University of Wisconsin–Madison, Madison, Wisconsin Lakshmi P. Kotra Michigan
Department of Chemistry, Wayne State University, Detroit,
Przemyslaw Kowal Michigan
Department of Chemistry, Wayne State University, Detroit,
Mei-Zheng Liu Michigan
Department of Chemistry, Wayne State University, Detroit,
Todd L. Lowary Ohio
Department of Chemistry, The Ohio State University, Columbus,
David A. Mann Department of Chemistry, University of Wisconsin–Madison, Madison, Wisconsin Shahriar Mobashery Michigan Monica M. Palcic Alberta, Canada
Department of Chemistry, Wayne State University, Detroit,
Department of Chemistry, University of Alberta, Edmonton,
Peter A. Petillo Department of Chemistry, University of Illinois at Urbana-Champaign, Urbana, Illinois Maarten H. D. Postema Detroit, Michigan Xiangping Qian Alberta, Canada
Department of Chemistry, University of Alberta, Edmonton,
R. Murray Ratcliffe Rene´ Roy Canada
Department of Chemistry, Wayne State University,
SYNSORB Biotech Inc., Calgary, Alberta, Canada
Department of Chemistry, University of Ottawa, Ottawa, Ontario,
Peter H. Seeberger Department of Chemistry, Massachusetts Institute of Technology, Cambridge, Massachusetts Keiko Sujino Canada
Department of Chemistry, University of Alberta, Edmonton, Alberta,
Peng George Wang Michigan
Department of Chemistry, Wayne State University, Detroit,
Thomas M. Weathers, Jr. son, Arizona
Department of Chemistry, University of Arizona, Tuc-
Contributors
xiii
Bryan K. S. Yeung Department of Chemistry, University of Illinois at UrbanaChampaign, Urbana, Illinois Biao Yu State Key Laboratory of Bio-organic and Natural Product Chemistry, Shanghai Institute of Organic Chemistry, Chinese Academy of Sciences, Shanghai, China Wei Zhang
Department of Chemistry, Wayne State University, Detroit, Michigan
Introduction: New Challenges in Carbohydrate Research
Over the past 30 years, most of the important discoveries in the biological sciences have been associated with proteins and nucleic acids, and thus chemists have been most active in conducting their research to address the relationship between the structure and function of these macromolecules as well as to develop small molecules as mechanistic probes or drug candidates to target these two types of biopolymers. This rapid progress of development is undoubtedly due to—other than the importance of proteins and nucleic acids in biological functions—the availability of various powerful tools (such as the polymerase chain reaction, solid-phase synthesizers, sequence analysis, and sensitive assay systems) to both chemists and biologists, and the close interplay between these two disciplines. Carbohydrates, especially oligo- and polysaccharides and their conjugates with proteins and lipids, have been neglected. Although carbohydrates display enormous structural and functional diversity—fulfilling roles as energy sources and as elements for recognition and for the control of structure, function, and dynamics of proteins —their precise functions at the molecular level are poorly understood. This slow pace of development in carbohydrate research is due mainly to the lack of tools available to the biologist interested in carbohydrates, and to a lesser extent to the chemist. No amplification method is available to prepare functionally important oligo- or polysaccharides in quantities large enough for structural analysis; no general method is available for the synthesis of glycoproteins with well-defined carbohydrate structures to investigate the roles that carbohydrates play in glycoprotein structure and function; and no solid-phase synthesizer is available for the synthesis of oligoand polysaccharides. From a medicinal chemistry point of view, carbohydrates are an uninteresting class of molecules for drug development because they are too difficult to synthesize on a large scale and too hydrophilic to have good bioavailability, and they are generally orally inactive and unstable. Perhaps the most fundamental problem is that carbohydrates bind their receptors or enzymes with weak affinity, usually with dissociation constants in the millimolar range. Polyvalent interactions are, however, xv
xvi
Introduction
often used in sugar-mediated intercellular recognitions to increase affinity and specificity and to control or regulate function (such as signaling and cell surface protein shedding). The weak affinity in sugar–receptor interactions is attributed to a few causes: 1) there is a lack of hydrophobic groups in sugars which are often dominant in high-affinity receptor–ligand interactions; 2) the energy associated with multiply hydrogen-bond and other electrostatic interactions in sugar–receptor recognitions is significantly diminished by competition from bulk solvent; and 3) the flexible nature of many hydrogen-bond interactions results in a significant entropic penalty when they become constrained in space upon binding. In addition, it appears that not all functional groups of a carbohydrate ligand are essential for binding. Despite these bottlenecks, it is important to develop new strategies and methods to study carbohydrate-mediated biological recognition processes and to investigate their mechanisms of action, since understanding the mechanism of carbohydrate function may lead to the development of carbohydrate-based therapeutics. Recent advances in carbohydrate chemistry and biology have helped to solve some of the problems. Of particular significance are, for example, the development of new methods for the synthesis of complex carbohydrates, glycolipids, and glycoproteins, the design of carbohydrate mimetics including polyvalent mimetics and glycosyltransfer enzyme inhibitors, the manipulation of cell surface carbohydrates to probe intercellular interactions, the development of carbohydrate-based antibiotics targeting RNA and cell surface peptidoglycans, the study of sulfation in carbohydrate recognition, the study of carbohydrate effect on protein structure and function, and the development of carbohydrate-based vaccines. Future efforts perhaps may be directed to: 1) determine the structures of glycosyltransferases and postmodification enzymes such as sulfotransferases and carbohydrate receptors involved in metastasis, inflammation, and immunoresponse (e.g., CD1-glycolipid–TCR complex); 2) understand carbohydrate-mediated intercellular interaction and signaling; 3) design small molecules targeting carbohydrate–receptor and carbohydrate–enzyme interactions; and 4) develop efficient and rapid methods for the synthesis of oligosaccharides and glycoproteins and for their structural and functional analyses. In this new era of functional genomics, it is anticipated that more tools will be developed to facilitate discovery in glycobiology and that carbohydrate-based therapeutic breakthroughs will be realized. Chi-Huey Wong The Scripps Research Institute La Jolla, California
1 Solid Phase Oligosaccharide Synthesis Peter H. Seeberger Massachusetts Institute of Technology, Cambridge, Massachusetts
I.
INTRODUCTION
Polysaccharides are the structurally most complex of the major classes of biopolymers. While nucleic acids and proteins are linear assemblies, polysaccharides are structurally and stereochemically more diverse. Additional complexity is added to the polysaccharide structure by the formation of glycoconjugates such as glycolipids and glycoproteins [1]. Oligosaccharides in the form of glycoconjugates mediate a variety of events, including inflammation, immunological response, metastasis, and fertilization [2,3]. Cell surface carbohydrates act as biological markers of various tumors and as binding sites for other substances, including pathogens [4]. The increased understanding of the important roles oligosaccharides and glycoconjugates play in fundamental life-sustaining processes has stimulated a need for access to usable quantities of these materials. Glycoconjugates commonly exist as microheterogeneous mixtures and are difficult to isolate in homogeneous form, therefore yielding only small amounts of the desired material. The problems associated with isolation from natural sources give rise to opportunities for chemical synthesis [5]. The developments in synthetic carbohydrate chemistry have centered on finding solutions to two important challenges: the need to differentiate similar functionality (hydroxyl or amino) contained on each monosaccharide and the need to induce the selective formation of a variety of glycosidic linkages. Unlike linkages found in the other two classes of repeating biopolymers, each glycosidic bond to be fashioned in a growing oligosaccharide ensemble constitutes a new locus of stereogenicity. In response to these two key challenges, a wide variety of protecting group strategies 1
2
Seeberger
[6] and increasingly powerful and selective glycosylating agents have been developed [7]. Still, the synthesis of complex oligosaccharides and glycoconjugates remains a difficult and time-consuming task. The introduction of solid support synthesis methods for preparation of structurally defined oligopeptides [8] and oligonucleotides [9] has led to tremendous improvements in terms of synthesis speed and efficiency. The advantages of solid phase synthesis, such as maximized yields by use of excess reagents, ease of purification, and synthesis automation, are now well appreciated. The biopolymers obtained by these rapid synthetic methods significantly impacted the fields of peptide and nucleic acid biochemistry. Glycobiology would benefit in many ways from straightforward synthetic methods, which could be used by nonexperts to prepare oligosaccharides. Since the level of complexity associated with the synthesis of oligosaccharides on a polymer support is much greater than that associated with the other two classes of repeating biooligomers, this task seemed for a long time too difficult to tackle. The development of protocols for the solid support synthesis of oligosaccharides and glycopeptides requires the scientists in the field to find solutions to several problems: (1) selection of an overall synthetic strategy and development of methods for attachment of the carbohydrate to the polymeric support through the ‘‘reducing’’ or the ‘‘nonreducing’’ end, (2) choice of a solid support material, (3) selection of a linker (‘‘support-bound protecting group’’) that is stable during the synthesis but can be easily cleaved when desired, (4) a highly flexible protecting group strategy, (5) stereospecific and high-yielding coupling reactions, and (6) ‘‘on-resin’’ methods to monitor chemical transformations. Pioneering efforts in the area of solid support oligosaccharide synthesis were undertaken in the early 1970s by several research groups, utilizing the limited set of glycosylating agents available at the time. While some fundamental issues were explored, the lack of glycosylation reactions compatible with polymeric supports impeded further progress. This early work has been reviewed [10] and is not covered in this chapter. Since these initial attempts, a great deal of progress has been achieved in assembling relatively complex carbohydrate ensembles through simplification and refinement of protecting group strategies and the development of new and powerful glycosylation methodology. This progress is a result of the efforts that have focused on solid support oligosaccharide synthesis since the early 1990s. The different approaches to solid support oligosaccharide synthesis by chemical rather than enzymatic methods are summarized in this chapter. Much effort has been focused on the use of soluble, polyethylene glycol (PEG) based polymeric supports for the synthesis of oligosaccharides. Reaction development using these soluble polymers has proven quite facile, since the reactions are run under homogeneous conditions and conventional analytical methods may be employed [11]. A number of glycosylation strategies have been explored by Krepinsky and coworkers [12] and van Boom et al. [13]. An orthogonal glycosylation strategy in conjunction with soluble polymeric supports has been developed [14]. In 1996 a very innovative ‘‘gatekeeper’’ approach [15] to the synthesis of oligosaccharides containing -mannosidic linkages was introduced. This work, which used a PEG polymer [16], was reviewed in 1998 [17] and is not covered in this chapter.
Solid Phase Oligosaccharide Synthesis
II.
3
SYNTHETIC STRATEGIES
Three major strategies have been explored for the solid support synthesis of oligosaccharides and glycoconjugates. In one variation, the first carbohydrate is anchored to the support via its ‘‘reducing’’ end (see Scheme 1, Case 1). The carbohydrate bound to the solid support functions as an acceptor in the coupling event to a solution-based donor (D). In the cycle, a unique acceptor hydroxyl must be exposed
Scheme 1
Glycosyl acceptor (Case 1) and donor (Case 2) bound to the solid support, and bidirectional synthesis (Case 3): S, solid support; P, unique protecting group; X, activating group; asterisk, uniquely differentiated hydroxyl group.
4
Seeberger
in the now elongated, resin-bound carbohydrate construct. In Case 1, this strategy virtually demands for the donor (D) employed in the preceding glycosidation step a uniquely removable blocking group at the site of the next proposed elongation. The need to expose the unique hydroxyl group in the context of the polymer support will necessitate multiple functional group manipulations in synthesizing D. Alternatively, the carbohydrate that is to undergo elongation may be mounted to the support somewhere in a ‘‘nonreducing’’ region, thereby making the reducing end available as a glycosyl donor for coupling with solution based acceptor A (Case 2). The use of A, of course, demands that the precise acceptor site be properly identified. In anticipation of the next coupling event, the reducing end of acceptor A is so functionalized that a new donor capability can be installed at the anomeric carbon of the elongated construct. This approach necessitates in the acceptor an anomeric group that does not serve as a glycosyl donor itself but rather may be converted in a straightforward manner into a glycosyl-donating moiety. A hybrid of both strategies is the bidirectional synthesis approach (Case 3), which is based on the orthogonal glycosylation concept. The first monosaccharide (A/D) may serve as glycosyl donor as well as glycosyl acceptor and is attached to the support matrix through a position other than the anomeric center. This glycoside contains an anomeric leaving group (as for Case 2), and in addition exhibits an uniquely distinguished acceptor site (analogous to Case 1). During the initial phase of the synthesis the support-bound sugar functions as a glycosyl acceptor A without compromising the chemical integrity of the anomeric moiety. In this fashion, oligosaccharide synthesis following the Case 1 paradigm may be carried out. If an orthogonal set of glycosylating conditions is used, the support-bound sugar may be activated to serve as a glycosyl donor in chain elongation to follow a Case 1 synthetic scheme. This chapter discusses the different approaches to solid phase oligosaccharide synthesis developed to date, grouped by the overall synthetic paradigm they obey.
III.
THE GLYCOSYL DONOR BOUND STRATEGY: THE GLYCAL ASSEMBLY APPROACH
A.
Overview of the Glycal Assembly Approach
While the donor-bound paradigm (Case 2) minimizes the number of protecting group manipulations that have to be carried out on the solid support, it mandates the presence of a latent glycosyl donor moiety in the solution-based glycosyl acceptor. Glycal building blocks fulfill these requirements, since they serve as glycosyl acceptors but may be converted into powerful glycosylating agents. Danishefsky and coworkers successfully explored the application of the glycal assembly method to the solid support synthesis of oligosaccharides and glycoconjugates [18]. The general principle of the glycal assembly method is outlined in Scheme 2. Attachment of a glycal to a solid support through the nonreducing end results in the presence of a terminal glycal function that may be readily converted into donor 2. Since glycals are employed as the solution-based acceptor, the protecting group scheme used for the identification of hydroxyls predestined for glycosylation remains relatively simple. Compound 2 could be a 1,2-anhydro sugar [19], derived by reaction with an epoxidizing agent, or it could be a transient species, derived by activation with an
Solid Phase Oligosaccharide Synthesis
5
Scheme 2 Use of the glycal assembly method in a general strategy for the synthesis of oligosaccharides on a solid support.
iodonium source [20]. Support-bound 2 acts as a glycosyl donor when treated with a solution of acceptor glycal 3, along with any necessary agents to promote the glycosylation, thereby forming 4. The process can be repeated to assemble the desired oligosaccharide, followed by retrieval from the support and purification by chromatographic methods. All studies on the solid support synthesis of oligosaccharides by the glycal assembly approach employed a polystyrene 1% divinylbenzene copolymer, which is commonly used in solid support peptide synthesis because of its high loading capacity, compatibility with a wide range of reaction conditions, and low price. The first glycal was linked to the solid support through a disilane linkage that could be cleaved rapidly and completely by treatment with fluoride [21]. The validity of the approach was first demonstrated by the synthesis of a linear tetrasaccharide [22] and a hexasaccharide 13 [23] as outlined in Scheme 3. Polymerbound galactal 5 was converted to the 1,2-anhydro sugar 6 by epoxidation with 3,3dimethyldioxirane [24]. Polymer-bound 6 acted as a glycosyl donor when reacted with a solution of 7 in the presence of zinc chloride, resulting in the formation of disaccharide 8a. Upon repetition, this glycosylation procedure accommodated the secondary alcohol glycosyl acceptor 10 as well as disaccharide acceptor 12. Fluoridolysis with tetrabutylammonium fluoride (TBAF) was used to cleave the desired products from the polymeric support and furnish hexasaccharide 13 in 29% overall yield from 5 [16]. B.
Solid Phase Synthesis of Blood Group Determinants
Carbohydate blood group determinants in the form of glycoproteins or glycolipids were found to play key roles in cell adhesion and other binding phenomena [25,26]. Furthermore, glycoconjugates related to these blood group substances have been recognized as markers for the onset of various tumors. These tumor-associated antigens are currently being studied in vaccines for cancer immunotherapy [27,28]. The
6
Seeberger
Solid Phase Oligosaccharide Synthesis
Scheme 3
Solid phase synthesis of a hexasaccharide by the glycal assembly method.
7
8
Seeberger
glycal assembly approach outlined above found its first applications in the synthesis of a H-type 2 tetrasaccharide (Scheme 4) [29,30]. Treatment of polymer-bound 1,2-anhydro sugar 6 with a solution of glucal acceptor 14 provided disaccharide 15. Upon opening of a 1,2-anhydro sugar during glycosylation, a C2 hydroxyl group is exposed, which may in turn serve as a glycosyl acceptor to form branched oligosaccharides [31]. Compound 15 was fucosylated using a solution of fucosyl donor 16 [32] to furnish trisaccharide 17. Treatment of 17a with TBAF provided trisaccharide glycal 17b in 50% overall yield from 5. Because of the lack of solid support methodology to fashion glycosidic linkages bearing C2-acylamino functions, solution phase chemistry had to be employed to access the H-type 2 blood group determinant glycal 18. Ready functionalization at the reducing end was achieved through the terminal glycal handle. The Lewisb blood group antigen (Leb) is of particular interest because it has been identified as a mediator for the binding of Helicobacter pylori to human gastric epithelium [33]. Clinical studies have identified H. pylori as a causative agent in gastric and duodenal ulcers [34], and antimicrobial treatments are an effective means to combat infection [35]. Since bacterial attachment is a prerequisite for infection [36], analogs of the Leb oligosaccharide may serve as therapeutic alternatives to broad spectrum antibiotics. The first approach to Leb addressed the synthesis of the core tetrasaccharide 22, which was assembled on the polymer support as depicted in Scheme 5 [37]. Polymer-bound galactal 19 was epoxidized with dimethyldioxirane and then reacted with a solution of glucal derivative 20 to give disaccharide diol 21. This reaction proceeded in highly regioselective fashion wherein glycosylation occurred at the allylic position at C3 of 20. Bisfucosylation of 21 using donor 16 provided polymerbound tetrasaccharide glycal 22a. Treatment of 22a with TBAF gave 22b, which
Scheme 4
Solid phase synthesis of an H-type blood group determinant by the glycal assembly method.
Solid Phase Oligosaccharide Synthesis
Solid phase synthesis of the Lewisb blood group determinant pentasaccharide glycal.
9
Scheme 5
10
Seeberger
was obtained in a 40% overall yield from 19. Initially, solution chemistry was used to further convert glycal 34b into a hexasaccharide of the Leb system, whereupon 34b was conjugated with human serum albumin to provide the desired neoglycoprotein. These approaches toward the synthesis of blood group determinants on a solid support were hampered by a serious shortcoming in the methodological arsenal of the glycal assembly method. While this strategy permitted rapid and concise access to -glycosidic linkages, solution phase methodology solution had to be used for construction of N-acetylamine glucosidic linkages prevalent in biologically important blood group determinants, gangliosides, and N-linked glycopeptides [37]. To install the appropriate functionality at C2, solution phase chemistry has relied on a trans-diaxial addition of an iodonium electrophile in the presence of an amine to form an iodosulfonamide. Displacement of iodine proceeds presumably through an aziridine intermediate and may be induced by a thiolate nucleophile to fashion thioethyl 2-amidoglycosyl donors [38]. Successful transfer of this method to the solid support allowed polymer-bound glycals to be converted into thioethyl glycosyl donors. These donors were in turn coupled with a variety of glycosyl acceptors, including glycals [39]. After an efficient coupling protocol for the synthesis of -2-amidoglucosidic linkages had been established, the difficulties encountered during the earlier synthesis of the Lewisb pentasaccharide glycal could be overcome. Branched tetrasaccharide 22a was converted into the thioethyl donor 23. Coupling to galactal acceptor 24 yielded 71% of the desired pentasaccharide 25a (Scheme 5). TBAF was used to effect retrieval of the pentasaccharide, affording 25b in 20% overall yield from 19 [32]. C.
Generation and Use of Thioethyl Donors on the Solid Support
While the use of glycals on the solid support allowed for the construction of galactosyl linkages with great efficiency even with hindered glycosyl acceptors, the analogous -glucosidic linkages could not be prepared reliably. In the galactose series, the anhydride is relatively stable to very mild Lewis acids, particularly anhydrous zinc chloride, because a conformationally constraining cyclic carbonate protecting group is used. The stability allows for galactosylation of even hindered acceptors such as C4 hydroxyls flanked by protecting groups at C3 and C6. No analogous constrained glucosyl epoxy donor is available, and glucosyl systems in the presence of zinc chloride are highly reactive and thus are prone to donor deterioration. To overcome the problems associated with the formation of -glucosidic linkages, an approach that allowed for the conversion of glycals into thioethyl glycosyl donors was developed in solution phase [40]. These thioethyl glycosyl donors constitute a class of extremely powerful glycosylating agents upon activation with thiophilic reagents [41]. The glycal-derived donors were equipped with a C2 pivaloyl neighboring group and coupled to glycal acceptors to fashion a variety of glycosidic linkages with high efficiency. Pivaloyl neighboring groups had been shown by Kunz and others to prevent the formation of orthoester products during glycosylations [42]. Conversion of 26 to the protected thioethyl glycosyl donors 27 was achieved through epoxidation with dimethyldioxirane to yield the 1,2-anhydro sugar, followed
Solid Phase Oligosaccharide Synthesis
11
by opening of this intermediate by ethanethiol in the presence of a trace of acid. Thioethyl glycoside 27 was obtained in 91% yield and transformed into fully protected thioethyl donor 28a by pivaloylation in near quantitative yield. Support-bound thioglycoside 28a was activated using methyl triflate as a thiophile, while the nonnucleophilic base di-tert-butylpyridine (DTBP) provided stability for the glycal linkage during coupling. In model studies the formation of -glucosyl (1→4), -glucosyl (1→3), and -glucosyl (1→6) linked disaccharides was achieved in good yield and complete selectivity [43]. After an efficient coupling protocol involving support-bound thioethyl glucosyl donors had been established, this methodology was applied to the synthesis of tetrasaccharide 31 containing exclusively -(1→4) glucosidic linkages. Transformation of disaccharide glycal 29a into the C2 pivaloyl thioethyl glycosyl donor was followed by coupling to provide trisaccharide 30a in 45% overall yield from 26. Conversion of 30a to the thioethyl glycosyl donor was followed by coupling to glycal acceptor 14 to yield the desired tetrasaccharide 31a. After cleavage from the support 31b was obtained from 26 in 20% yield over nine steps, corresponding to 84% average yield per step (Scheme 6). D.
Solid Phase Synthesis of N-Linked Glycopeptides
N-linked and O-linked glycoproteins are the two major subgroups of glycoproteins, with the former being the most abundant in nature [44]. The biosynthesis of these glycoproteins results from cotranslational glycosylation usually occurring in the endoplasmic reticulum. The sugars of N-linked glycoproteins are usually attached by an oligosaccharyltransferase to an asparagine having the glycosylation sequence AsnX-Ser/Thr. Advances in glycopeptide synthesis have been achieved by several groups [45–47]. The synthesis of N-linked glycopeptides [48] on the solid support using a terminal glycal of a synthetic oligosaccharide domain aimed at a highly convergent synthetic strategy [49]. Polymer-supported trisaccharide 32 was reacted with anthracenesulfonamide and I(sym-coll)2ClO4 to form intermediate 33 (Scheme 7). Reaction of the iodosulfonamide 33 with tetra-n-butylammonium azide, followed by acetylation, provided the anomeric azide 34. The anthracenesulfonamide linkage can be cleaved under mild conditions such as 1,3-propanedithiol and Hu¨nig’s base, which concomitantly effected the reduction of the azide. The resulting amine was coupled with pentapeptide 35 in the presence of IIDQ to afford the protected glycopeptide 36. Orthogonal protecting groups on the C- and N-termini of the peptide provided the opportunity to extend the peptide chain while the ensemble was bound to the solid support. Alternatively, after removal from the support, the liberated peptide terminus may provide a functionality for linking to a carrier molecule to generate other glycoconjugates. The C-terminus of 36 was deprotected to give the acid 37, which was coupled to tripeptide 38 with a free N-terminus to give glycopeptide 39. Retrieval from the solid support afforded trisaccharide-octapeptide 40 in 18% overall yield from 19 [50]. IV.
STRATEGIES USING SUPPORT-BOUND GLYCOSYL ACCEPTORS
The solid support synthesis of oligopeptides and oligonucleotides is routinely carried out by reacting a support-bound structure (acceptor) with an excess of a solution-
12 Seeberger
Using glycal-derived polymer-bound thioethyl glucosyl donors in the synthesis of a -(1→4) linked tetrasaccharide.
Scheme 6
Solid Phase Oligosaccharide Synthesis
Synthesis of N-linked glycopeptides on a solid support.
13
Scheme 7
14
Seeberger
based reactive species (donor). While the glycal assembly method, which utilizes a support-bound reactive species, has been used very successfully for the synthesis of oligosaccharides and glycopeptides, all other synthetic approaches explored to date have followed an acceptor-bound strategy. The acceptor-bound paradigm allows for the glycosyl donor to be used in excess during elongation of the growing oligosaccharide from the reducing to the nonreducing end. Because the donor is used in excess, side reactions that usually affect the glycosyl donor, resulting in inactive degradation products, do not impact the overall yield. Each hydroxyl group to serve as a glycosyl acceptor needs to be distinguished by a unique protecting group, which may be removed before each coupling cycle. In this section synthetic strategies employing a variety of glycosylating agents are reviewed. A.
Synthesis of Oligosaccharides Using Glycosyl Sulfoxides
The use of anomeric sulfoxides as glycosylating reagents was reported by Kahne and coworkers in 1989 [51]. Upon activation with triflic anhydride at low temperatures, anomeric sulfoxides are transformed into extremely reactive glycosyl donors, which can glycosylate very hindered acceptors. The excellent reactivity of the sulfoxide donors coupled with the selectivity achieved by use of a participating group in the C2 position prompted their use in the synthesis of oligosaccharides on the solid support [52]. Merrifield’s resin (polystyrene cross-linked with 1% divinylbenzene) was chosen as a polymer matrix, and an anomeric hydroxy thiophenyl ether moiety was selected as linker to the solid support (Scheme 8). The thiophenyl linkage is stable to all coupling and deprotection conditions but may be cleaved readily with mercuric trifluoroacetate. The first monosaccharide 42 was selectively deprotected and coupled by addition of 4 equiv of galactosyl sulfoxide 44, in the presence of DTBP as a base, and triflic anhydride as activator. Coupling at ⫺60⬚C for 30 min, filtration, and washing were followed by deprotection of the acetyl group. One further coupling and cleavage from the polymeric support by reaction with mercuric trifluoride furnished trisaccharide 50 in 52% overall yield. It was estimated that each coupling proceeded in 94–95% yield based on a detachment efficiency of 70–75% (as determined by solution phase studies). The glycosyl sulfoxide strategy successfully accommodated secondary hydroxyl acceptor groups, and ␣-fucosidic linkages were generated by the use of fucosyl sulfoxides [52]. These advances in the solid support synthesis of oligosaccharides using glycosyl sulfoxides were applied to the preparation of a combinatorial library of approximately 1300 disaccharides and trisaccharides [53]. A polystyrene–polyethylene glycol (PS-PEG) copolymer that swells in a wide range of solvents, including water, was employed in the syntheis of these libraries. Screening of the carbohydrate structures against a bacterial lectin from Bauthinia purpurea was performed with the carbohydrate structures still attached to the resin beads. Use of a chemical tagging system developed by Still and coworkers [54] allowed for rapid structure determination of the hits in the screening assay. Alternate binding structures with higher affinity than the natural ligand for the lectin of interest were identified in this manner. The glycosyl sulfoxide method has proven very efficient and flexible in constructing a variety of glycosidic linkages on the solid support. Combinatorial carbohydrate libraries prepared by this strategy hold great potential for the identification
Solid Phase Oligosaccharide Synthesis
Scheme 8
15
Solid phase synthesis of a trisaccharide by the glycosyl sulfoxide method.
of natural and nonnatural lectin ligands. While the synthesis of larger oligosaccharide structures using the glycosyl sulfoxide method still needs to be demonstrated, this strategy holds great potential for many applications. B.
Synthesis of Oligosaccharides Using Glycosyl Trichloroacetimidates
Among the multitude of glycosylating agents now at the disposal of the synthetic chemist, glycosyl trichloroacetimidates have become the most widely used building blocks. These donors have been used to prepare a large number of very complex oligosaccharides and glycoconjugates in solution phase [55]. High coupling yield, versatility, and excellent selectivity are hallmarks of this approach to oligosaccharide synthesis. Recently the first syntheses of oligosaccharides using trichloroacetimidate donors on the solid support have been reported. Schmidt and coworkers initially used Merrifield’s resin and explored a variety of ether and thioether linkers [56]. Attach-
16
Seeberger
ment of the first residue via a thioether linkage proved most reliable, and cleavage was successfully effected by reaction with a nucleophile. Reaction with water or methanol in the presene of N-bromosuccinimide yielded the lactol or the methyl glycoside, respectively. A two-step coupling cycle (Scheme 9) was used to assemble a series of (1→2) linked mannosides. Removal of the temporary acetyl-protecting group by sodium methoxide in methanol was followed by coupling of the trichloroacetimidate mannosyl donor 53 to the exposed axial C2 hydroxyl group. Repetition of this cycle and cleavage of the thioether linker resulted in assembly of the desired tetrasaccharide 56 in 34% overall yield. Penta- and hexamannosides obtained by using this method were characterized by mass spectrometry, but no yields were reported [57]. In addition to 1,2-trans-glycosides, disaccharides containing the synthetically more challenging 1,2-cis-glycosidic linkage were prepared. Fucosyl trichloroacetimidate was coupled to the C2 position of a support-bound mannosyl acceptor under the agency of trimethylsilyl triflate (TMSOTf) to yield 54% of the desired disaccharide [57]. Promising results were also obtained for the synthesis of a (1→2) trimannoside, which was prepared on a mercaptoethyl-functionalized controlled pore glass (CPG) solid support. This nonswelling support performed well under the described coupling and deprotection conditions [58]. More recently, the trichloroacetimidate strategy has been applied to the synthesis of a branched pentasaccharide unit common to most complex N-glycan structures (Scheme 10). Reaction of mannosyl donor 57 with thiol-functionalized resin resulted in attachment to the polymer matrix through the reducing end of the sugar 58. Removal of the benzoyl protecting groups on the C3 and C6 positions was effected by treatment with sodium methoxide to furnish diol 59. Dimannosylation was accomplished by reaction with trichloroacetimidate mannosyl donor 53 to afford solid support bound trisaccharide 60 in 38% overall yield. Cleavage of the acetyl protecting groups of the axial C2 hydroxyl functionalities revealed support-bound trisaccharide diol 61. Conversion of 61 to pentasaccharide 63 was achieved by reaction with glucosamine donor 62. Cleavage of the thioether linker with N-bromosuccinimide in the presence of methanol furnished the desired pentasaccharide methyl glycoside in 20% overall yield. Adinolfi et al. [59] explored the use of different solid supports for the synthesis of disaccharides employing trichloroacetimidate donors. The glycosyl acceptor was connected through the C2, C3, or C6 hydroxyl group to amino-functionalized solid support via a succinimide linker. Polystyrene, PS-PEG copolymer (TentaGel), and CPG supports were tested for their performance with trichloroacetimidate donors. Best coupling yields (95%) were obtained in these studies when the donor was reacted with acceptor bound to CPG or polystyrene support. PEG-containing copolymers performed significantly poorer in these glycosylations. Hunt and Roush [60] used a solid phase method to prepare 6-deoxy di- and trisaccharides. A sulfonate linker was employed to connect the first monosaccharide, a glycal, via its C6 position to the polymer resin. A galactosyl trichloroacetimidate donor was used in the first coupling reaction, followed by cleavage from the solid support by treatment with NaI to furnish pure disaccharides in 85–91% yield. Reduction with Bu3SnH (AIBN) provided the desired 6-deoxydisaccharide. These impressive initial accomplishments using trichloroacetimidate glycosyl donors on the solid support underscore the potential this strategy holds for the
Solid Phase Oligosaccharide Synthesis
Synthesis of ␣ (1→2) mannosides by the trichloroacetimidate strategy.
17
Scheme 9
18
Seeberger
Scheme 10
Use of trichloroacetimidate donors in the preparation of a branched pentasaccharide.
synthesis of complex oligosaccharide structures containing a variety of glycosidic linkages. Before the assembly of larger constructs may be contemplated, the overall yield and recovery will have to be improved. Novel linkers that are completely stable throughout the synthesis as well as improved coupling protocols should remedy these shortcomings.
Solid Phase Oligosaccharide Synthesis
C.
19
Solid Support Synthesis of Oligosaccharides Using Thioglycosides
Next to anomeric trichloroacetimidates, thioglycosides are the glycosyl donors most widely used in the synthesis of complex oligosaccharides and glycoconjugats. Thioglycosides may be prepared in high yield and are exceptionally stable, allowing for prolonged storage even at room temperature. Reaction with thiophiles such as methyl triflate or dimethylthiomethylsulfonium triflate (DMTST) ensures efficient activation of thioglycosides for the formation of glycosidic linkages [41]. In solution phase, thioethyl glycosides have found application in the synthesis of very complex oligosaccharides and in the preparation of a combinatorial carbohydrate library [61]. Straightforward synthetic access, stability, and high-yielding, selective glycosylation reactions made thioglycoside donors ideal for application to the solid support synthesis of oligosaccharides. Nicolaou and coworkers utilized phenolic polystyrene equipped with a photolabile, readily available o-nitrobenzyl linker in the synthesis of heptasaccharide 72 from mycelial walls of Phytophthora megasperma (Scheme 11) [62]. This heptasaccharide consists entirely of  (1→6) or (1→3) glucosidic linkages and had previously been prepared by using solution phase methods [63] and block synthesis on a soluble PEG polymer [13]. Silyl ethers and fluorenylmethyloxy carbonyl (Fmoc) protective groups were employed to provide temporary protection of the hydroxyl functionalities to be glycosylated in the coupling steps that followed. Removal of the silyl ether protecting group by fluoridolysis to yield 64 was followed by coupling of 4 equiv of the solution-bound thiodonor 65 in the presence of the activator DMTST. The coupling to form 66 proceeded in greater than 95% yield according to material recovered after cleavage from the resin. Consecutive deprotection and coupling steps resulted in assembly of the desired heptasaccharide 71 still attached to the polymeric support. Photolytic cleavage of the linker, treatment with sodium methoxide to remove the ester protecting groups, and hydrogenolysis to cleave the benzyl ethers yielded unprotected heptasaccharide 72. Alternatively, fully protected heptasaccharide was obtained by acetylation of the anomeric hydroxyl group support in 20% overall yield from 64 after photolytic cleavage from the solid support [62]. After having established a reliable and efficient reaction sequence for the synthesis of oligosaccharides Nicolaou et al. further improved upon their initial strategy [64]. A 4-benzyloxybenzoic acid spacer was incorporated between the photolabile linker and the anomeric position of the first glycoside to provide access to either unprotected oligosaccharides or oligosaccharide glycosyl donors (Scheme 12). Support-bound acceptor 73 was converted into trisaccharide 77 following the synthetic strategy established earlier (see above). Cleavage from the resin was effected photolytically to furnish the fully protected trisaccharide 80 in 63% yield from 73. Alternatively, the protected trisaccharide was cleaved from the polymer with concomitant activation by exposure to PhSSiMe3/ZnI2/nBu4NI, furnishing phenylthiotrisaccharide donor 79 (Scheme 12; pp. 21 and 22). Support-derived trisaccharide building block 79 was used in a block synthesis of dodecasaccharide 82 (Scheme 13; p. 23). Reaction of support-bound glycosyl acceptor 78 with 79 furnished hexasaccharide 81. Removal of a silyl protecting group and coupling with trisaccharide donor 79 was repeated twice, followed by photolytic cleavage of the linker to furnish dodecasaccharide 82 in 10% yield from 73 [64].
20
Synthesis of a heptasaccharide employing thioglycoside donors.
Seeberger
Scheme 11
Solid Phase Oligosaccharide Synthesis
Preparation of trisaccharide thioglycoside building blocks on a solid support.
21
Scheme 12
22
Continued.
Seeberger
Scheme 12
Solid Phase Oligosaccharide Synthesis
Scheme 13
Assembly of a dodecasaccharide by the building block strategy on the solid phase.
23
24
Seeberger
The two examples of solid support oligosaccharide synthesis employing thioglycosides demonstrate the power of this strategy in the preparation of large carbohydrate structures. For the first time, a very large oligosaccharide was constructed via a block synthesis strategy in which every block itself was prepared on a solid support. The synthesis of combinatorial carbohydrate libraries using this strategy should certainly be possible. D.
Synthesis of Oligosaccharides Using Pentenyl Glycosides
Fraser-Reid and coworkers have established n-pentenyl glycosides as a class of powerful and versatile glycosyl donors [65]. Activation by a variety of reagents [e.g., Niodosuccinimide (NIS), TESOTf] furnished various glycosidic linkages in high yield and excellent selectivity in solution phase synthesis. More recently, the application of n-pentenyl glycosides to the synthesis of oligosaccharides on a solid support has been explored [66]. Both donor- and acceptor-bound synthetic strategies were investigated initially. Attachment of a pentenyl glycoside through the C6 hydroxyl group to the solid support was achieved via a photolabile 3-amino-3-(2-nitrophenyl)propionyl linker. Glycosylation using NIS and TESOTf as activating agents did not result in clean formation of the desired disaccharide product but also yielded lactol by donor degradation. An acceptor-bound synthetic strategy was more successful. Model studies with a glucose acceptor that was anchored to the solid support via its anomeric position showed that ␣- and -glucosidic and C2 amino glucosidic linkages could be furnished in average coupling yields of greater than 90%. Reaction development was aided by 13C gel phase NMR spectroscopy to analyze the formed products [69]. After these initial studies, the synthesis of a support-bound, fully deprotected trisaccharide was achieved (Scheme 14). Chiron’s polystyrene-grafted ‘‘crowns’’ were chosen as solid support material because they are more amendable to parallel synthesis than traditional polymer supports. A photolabile o-nitrobenzyl linker was selected to attach the first amino glucoside 83 through its anomeric position to the solid support. Removal of the C6 dinitrobenzyl protecting group was followed by coupling with pentenyl mannoside 84 and resulted in formation of the desired disaccharide 85. Removal of the C2 chloroacetyl protecting group and coupling of pentenyl galactose donor 86 furnished trisaccharide 87. Global deprotection followed by peracetylation and photolytic cleavage from the solid support provided trisaccharide 88, but no yield was reported [66]. E.
Bidirectional Glycosylation Strategy for the Solid Phase Synthesis of Oligosaccharides
The preceding sections discussed the strengths and weaknesses of the donor- and acceptor-bound synthetic strategies developed to date for the synthesis of complex oligosaccharides. Boons et al. recently described an approach that combines both strategies in a bidirectional solid phase oligosaccharide synthesis [67]. The use of orthogonal glycosylating agents during the synthesis is an absolute prerequisite for the success of this bidirectional strategy. Trichloroacetimidate glycosides may be activated and function as glycosyl donors in coupling reactions with glycosyl acceptors containing an anomeric thioglycoside. The C6 hydroxyl group of thioethyl glycoside 89 (Scheme 15) was connected to TentaGel resin via a succinate
Solid Phase Oligosaccharide Synthesis
Scheme 14
Application of n-pentenyl glycosides to solid phase synthesis: preparation of a trisaccharide.
25
26
Bidirectional strategy for the synthesis of oligosaccharide libraries.
Seeberger
Scheme 15
Solid Phase Oligosaccharide Synthesis
27
linker. First, the exposed C4 hydroxyl functionality of 89 served as glycosyl acceptor in the reaction with solution-based trichloroacetimidate donor 90 in the presence of TMSOTf as promoter. Without the need for further protecting group manipulations, support-bound disaccharide thioglycoside 91 was activated with NIS/TMSOTf [68] to serve as a glycosyl donor in the reaction with solution-based glycosyl acceptor 92. This strategy served to generate a combinatorial library of trisaccharides while minimizing the necessary protecting group manipulations. This bidirectional approach stands to combine the advantages of the acceptorbound approach, such as use of excess donor during the synthesis, with the opportunity to fashion glycoconjugates through the anomeric position formerly possible only in a donor-bound paradigm. Other combinations of orthogonal glycosylating agents and the applicability of this strategy to the synthesis of larger oligosaccharide structures will have to be addressed in future studies. V.
‘‘ON-RESIN’’ ANALYTICAL METHODS
Development of a reliable solid phase methodology for the synthesis of oligosaccharides and glycopeptides has been greatly hampered by the lack of convincing ‘‘on-resin’’ analytical techniques. In most of the syntheses outlined above, it was necessary to cleave the products or intermediates of multistep syntheses from the resin to allow for the use of classical spectroscopic means (e.g., solution state NMR and mass spectrometry). The cleavage method analysis is time-consuming and wasteful in the context of multistep syntheses. Polystyrene–PEG copolymers may be analyzed by gel phase NMR spectroscopy but are quite expensive and allow only for relatively low loading [69]. Two NMR-based approaches for the on-resin analysis of polystyrene resins have been developed to aid reaction development by monitoring of the solid support matrix. A.
High-Resolution Magic Angle Spinning NMR Spectroscopy
The effectiveness of the glycal assembly approach to solid support oligosaccharide synthesis was impressively documented by on-resin analysis. The ‘‘crude product’’ of the multistep synthesis of trisaccharide 32 (Scheme 16) was monitored by highresolution magic angle spinning NMR (HR-MAS) [70].
Scheme 16
Solid phase synthesis of a trisaccharide by the glycal assembly method.
28
Seeberger
HR-MAS experiments proved to be an ideal way of monitoring the solid support synthesis by obtaining 1H NMR, 13C NMR, and 1H-13C NMR spectra of high quality. The 1H NMR (Scheme 17) of the crude product of this synthesis showed that only one product was obtained. Spin-echo techniques were used to suppress NMR peaks derived from the polymeric matrix. Since its introduction, this technique has greatly facilitated the development of novel synthetic schemes of oligosaccharides and glycopeptides on a solid support. B.
Gated-Decoupling–
13
C NMR Spectroscopy After 13C Enrichment
Wong et al. monitored the solid support synthesis of the sialyl Lewisx tetrasaccharide using 13C-enriched linker and protecting groups [71]. The 13C-labeled linker was attached to the polymer support and functioned as an internal integration standard for the 13C-enriched protecting groups of the growing oligosaccharide. After each coupling reaction, the NMR signal of the protecting group at the growing end of the molecule was compared with the signal of the internal standard to quantify the coupling. This method does not require special NMR hardware such as an HR-MAS probe but can be carried out in standard 5 mm NMR tubes. On the other hand, this method yields no detailed structural information regarding the anomeric purity of the compound prepared. The chemical integrity of the glycosidic linkages formed must be determined after cleavage of the target molecule from the solid support.
VI.
CONCLUSIONS AND OUTLOOK
Over the last 5 years a number of very promising strategies for the solid support synthesis of oligosaccharides and glycoconjugates have been developed. Several of the glycosylating reagents successfully used in solution have yielded promising results under the soild phase paradigm. While a number of different solid support matrices and linkers have been explored, much work in this area remains to be done. The rapid developments in combinatorial chemistry on the solid support have created novel support matrices, which will find application to solid phase oligosaccharide synthesis. Innovative linkers will be required to allow for the use of highly flexible protecting group strategies in the synthesis of branched oligosaccharides. Given the progress in the development of methods for the on-resin analysis of oligosaccharides, reaction development and optimization will be drastically accelerated. Novel glycosylating agents and orthogonal glycosylating schemes will further impact solid support synthesis. Alternative glycosylation methods such as the use of glycosyltransferase-catalyzed reactions on the solid support have also made great strides. For the synthesis of diverse structures, including natural and nonnatural glycoconjugates, chemical synthesis will be of paramount importance. While much progress has been made, many challenges remain before a flexible, high-yielding and absolutely selective strategy for the synthesis of oligosaccharides on the solid support becomes available. Once these problems have been solved, the construction of an automated oligosaccharide synthesizer may become feasible. Detailed studies concerning the structure and function of oligosaccharides and glycoconjugates will be possible once rapid access to complex glycoconjugates is a reality.
Solid Phase Oligosaccharide Synthesis
Spectrum of 32 obtained by high-resolution magic angle spinning 1H NMR spectroscopy.
29
Scheme 17
30
Seeberger
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2. 3.
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30. 31. 32. 33.
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71.
2 Dehydrative Glycosylation with 1-Hydroxy Donors David Gin University of Illinois at Urbana-Champaign, Urbana, Illinois
I.
INTRODUCTION
The preparation of complex carbohydrates has emerged as a major focus in synthetic organic chemistry, and this is no doubt a result of the growing awareness of the many important roles of this class of molecules in biology [1]. Perhaps the most important reaction in the chemical synthesis of carbohydrates is the formation of the glycosidic bond, for this is the primary means for the controlled assembly of complex oligosaccharides and glycoconjugates from monosaccharide precursors. Thus a variety of methods have been developed to effect the glycosylation process. Much of the effort has focused on the general coupling strategy outlined in Scheme 1 [2]. In this strategy, one begins with a carbohydrate coupling partner (1), which is subjected to initial derivatization whereby the anomeric substituent is transformed into a latent leaving group (LG). The resulting intermediate 2, or glycosyl donor, is typically isolated, and in a second step the anomeric leaving group is activated with an appropriate glycosylation promoter or catalyst. This process usually takes place in the presence of a nucleophilic glycosyl acceptor (Nu-H), which undergoes an effective displacement of the leaving group to form the anomeric bond in the product glycoside (3). Within the last century, a variety of leaving groups have been developed for the generation of various glycosyl donors that can undergo efficient coupling in the second step. Some of these are listed in Scheme 1, and all have proven to be useful to some extent in complex carbohydrate synthesis [2]. A far less developed strategy for glycosidic bond formation is a direct dehydrative coupling procedure in which one begins with a 1-hydroxy carbohydrate (1) 33
34
Scheme 1
Gin
Traditional glycosylation strategies [2].
as the glycosyl donor (Scheme 2). This approach offers a complementary if not more efficient strategy for glycosylation in that a distinct anomeric derivatization step to generate an isolable glycosyl donor 2 is obviated. As such, all the operations of anomeric derivatization, activation, and bond formation are combined into a one-pot procedure. Despite its potential advantages, however, this strategy has not been extensively employed in complex oligosaccharide synthesis. The establishment of a viable synthetic method calls for the overcoming of such inherent difficulties associated with this approach as the reversibility of the process and the propensity for hemiacetal self-coupling, in addition to the common glycosylation obstacles such as coupling efficiency and high anomeric stereoselectivity. This chapter summarizes recent advances in the development of nonenzymatic direct dehydrative glycosylations with 1-hydroxy glycosyl donors. The concept of direct dehydrative glycosylation is not a new one. One of the earliest glycosylation methods is the Fischer procedure [3], currently adopted for preparation of simple glycosides (Scheme 3). In this process an unprotected monosaccharide (4) is treated with an excess of an alkyl alcohol in the presence of an acid catalyst, resulting in the net loss of water and substitution at the anomeric position by the alcohol acceptor. Usually a desiccant is not present in this hemiacetalto-acetal exchange process; as a result, the equilibrium can favor the formation of the glycoside product 5 only through the use of a large excess of the alcohol acceptor (typically employed as the reaction solvent or cosolvent). In the original glycosylation procedure, HCl was used as the acid catalyst, with the coupling event usually proceeding at elevated temperatures. Over the years, a number of other Brønsted acid catalysts have been found to be effective in this process, including various inorganic and sulfonic acids [4,5] as well as acidic resins [6]. In addition, a host of Lewis acid catalysts have been employed [7], giving rise to substrate-specific variants of the Fischer protocol. In fact, with selected Lewis acid promoters such as FeCl3
Scheme 2
Direct dehydrative glycosylations.
Glycosylation with 1-Hydroxy Donors
Scheme 3
35
Fischer glycosylation [3]. R = methyl, ethyl, n-propyl, i-propyl, amyl, allyl,
benzyl, etc.
[8], it is possible to favor the formation of the kinetic furanoside product over the thermodynamically more stable pyranoside adducts [9]. While it is not the goal of this section of the chapter to present a comprehensive summary of Fischer glycosylation methods, it is worth emphasizing that this protocol and its variants have, over the last century, remained one of the most popular methods for the preparation of simple alkyl glycosides. Indeed, this venerable method, with its simplicity and versatility, has frequently been chosen as the starting point for the preparation of C1-protected monosaccharide building blocks for complex molecule syntheses. Despite the widespread use of the Fischer method, it has yet to be shown to be effective in the controlled assembly of complex oligosaccharides. Because of the acidic medium under which the acetal exchange process occurs, only simple alcohols devoid of acid-labile functionality are employed as glycosyl acceptors. Moreover, the necessity of a large excess of acceptor to favor equilibrium formation of glycoside 5 precludes the use of complex or valuable molecules as nucleophilic acceptors. Typically the preparation of oligosaccharides by modified Fischer protocols has been limited to the preparation of carbohydrate oligomers of varying size and complexity [10,11]. To establish a method for controlled glycosylation with 1-hydroxy carbohydrates, mild dehydrative coupling conditions are required that favor the cross-condensation of distinct hemiacetal donor and nucleophilic acceptor substrates. One approach toward this end is to employ a set of reagents that can rapidly and completely activate the C1-hydroxyl functionality in 1 to generate, in situ, a highly reactive intermediate that incorporates a transient leaving group at the anomeric position. The requirement for rapid activation of the anomeric hydroxyl is obviously necessary to minimize the extent of hemiacetal self-condensation, and the in situ formation of an extremely potent leaving group at C1 would allow for facile glycosidic bond construction with a nucleophilic acceptor without the need for isolation of an intermediate glycosyl donor. II.
COUPLING VIA GLYCOSYL HALIDES
Koto and coworkers have developed a dehydrative coupling procedure employing the in situ generation of a glycosyl bromide intermediate (6, Scheme 4) [12,13]. In this procedure, a stoichiometric quantity of TMS-Br is introduced into a reaction mixture containing equimolar quantities of the 1-hydroxy glycosyl donor 1, the alcohol acceptor (R⬘OH), CoBr2, and tetrabutylammonium bromide. The glycosyl bromide 6, generated in situ, then proceeds to glycosylate the alcohol acceptor. Glycosyl bromides are well-established donors in the Koenigs–Knorr procedure [14], wherein these intermediates are typically isolated and activated with a halophilic promoter to
36
Gin
Scheme 4 Dehydrative glycosylations via glycosyl bromides [12,13,15]. * Using alternate method: MeSO3H, CoBr2, Et4NClO4.
effect glycosylation. However, the method of Koto and coworkers is distinct in that the intermediate 6 is both generated and consumed in situ under the reaction conditions, resulting in a net dehydration via a one-pot coupling process. The authors tentatively attribute the feasibility of this one-pot procedure to (1) the favorable ˚ molecular sieves acting both as a HBr scavenger and as a desiccant, effects of the 4 A and (2) the functioning of CoBr2 both as an effective desiccant and as a glycosyl bromide activator in the coupling stage with R⬘OH. This procedure was used to glycosylate a number of alkyl alcohols with 2,3,4,6tetra-O-benzyl-D-glucose, resulting in very good to moderate yields, depending on the complexity of the alcohol acceptor (e.g., 8–12). In these couplings, only trace amounts of products arising from hemiacetal self-coupling were detected, and the presence of Bu4NBr favored the formation of the ␣ anomer of the product glycosides. It is worth noting that in an earlier related report, the reagent combination of [MeSO3H, CoBr2, Et4NClO4] was also employed by Koto to effect the desired dehydrative glycosylation [15]. Under these reaction conditions, it is presumed that HBr is generated, leading to the formation of 6; however, this protocol generally led to diminished yields (e.g., 8 and 10) compared with the above-mentioned TMS-Br ⭈CoBr2 procedure.
Glycosylation with 1-Hydroxy Donors
III.
37
COUPLING VIA GLYCOSYL SULFONATES
The in situ generation and coupling of glycosyl sulfonate esters of 1-hydroxy glycosyl donors has also been investigated in the context of direct dehydrative glycosylation. Early work by Leroux and Perlin highlighted the generation of glycosyl trifluoromethanesulfonates 13 as useful reactive intermediates for glycosylation in the presence of Bu4NBr and the acid scavenger s-collidine (Scheme 5) [16]. Their initial attempts at the glycosylation of the acceptor R⬘OH directly with triflate 13 in the absence of Bu4NBr were unsuccessful (i.e., 1 → 13 → 7), presumably as a consequence of the instability of the highly reactive triflate species. However, the introduction of Bu4NBr served to rapidly convert 13 into the more stable glycosyl bromide 6, which then proceeds to glycosylate the acceptor R⬘OH. With this protocol, isolation of the glycosyl bromide 6 is again unnecessary, allowing for an overall one-pot process. The authors also highlight this as a useful method for the generation of glycosyl bromides under nonacidic conditions.
Scheme 5 Dehydrative glycosylations via glycosyl triflates [16]. * Using alternate method: (Me2SO2)2O, s-collidine; R⬘OH.
38
Gin
With this procedure, a number of simple alcohols were glycosylated to generate carbohydrate products such as 14–17. With glycosyl donors incorporating a C2-acyl functionality such as an acetate ester, the corresponding orthoester adduct (e.g., 18) is generated, the obvious result of acceptor addition to the bicyclic oxygen-stabilized carbocation that arises through neighboring group participation. It should be noted that the use of methanesulfonic anhydride in place of triflic anhydride also led to similar glycoside adducts (e.g., 14 and 18). When (MeSO2)2O is used as the dehydrating reagent, however, the addition of Bu4NBr is not necessary because the intermediate glycosyl methanesulfonate, which can directly glycosylate the acceptor at ambient temperature, has increased stability. Although the use of triflic anhydride and s-collidine in the absence of bromide ion was ineffective for glycosylation, the use of triflic anhydride alone was found to be useful for the coupling of 1-hydroxy glycosyl donors. Pavia et al. [17] have shown that the treatment of 1-hydroxy donors with triflic anhydride in the absence of any acid scavenger led to the formation of (1,1⬘)-linked disaccharides 19, the products of self-coupling of the 1-hydroxy donor (Scheme 6). The presumed mechanism [18] of this transformation involves (1) activation of the hemiacetal with trace amounts of triflic acid for conversion to the glycosyl triflate 13 (or the corresponding oxocarbenium triflate), (2) the rapid coupling of the highly reactive intermediate 13 with unactivated 1, and (3) the action of triflic anhydride as a desiccant to favor formation of the (1,1⬘)-disaccharide 19. Although this is a relatively efficient method for the preparation of symmetrical trehalose analogs (e.g., 20 and 21), it is often the case that the self-condensation product of the hemiacetal donor is an unwanted side product of dehydrative glycosylation. However, if this coupling procedure is performed in the presence of an excess (2–4 equiv) of an alcohol glycosyl acceptor R⬘OH, heterocouplings do take place (e.g., 22 and 23). Pavia has used this protocol to prepare complex galactosyl-O-glycopeptides [19]. Koto has shown that glycosyl arylsulfonates can also be used as intermediates in couplings with 1-hydroxy glycosyl donors. The direct glucosylation of several simple alcohol acceptors with 2,3,4,6-tetra-O-benzyl-D-glucose can be accomplished with the ternary mixture of p-nitrobenzenesulfonyl chloride, silver triflate, and triethylamine as the acid scavenger (Scheme 7) [20]. Simple alcohols such as methyl alcohol, cyclohexylmethyl alcohol, and dihydrocholesterol are glycosylated efficiently via the glycosyl sulfonate 24, and the formation of trehalose by-products is minimized as a result of rapid anomeric sulfonylation. In addition, couplings performed in the presence of N,N-dimethylacetamide generally lead to higher proportions of the ␣ anomer (26) [21]. This procedure can be used to prepare glucuronides (27) [22], as well as other complex oligosaccharides such as the branched-chain oligosaccharides of the sarsasaponins (e.g., 28–30) [23]. Other dehydrative glycosylations employing glycosyl arylsulfonates include the formation of transient glycosyl tosylates from 1-hydroxy donors, reported by Szeja (Scheme 8) [24]. For obvious reasons, all the preceding dehydrative coupling methods call for care to exclude moisture from the reaction. However, the method of Szeja is distinct in that it effects a dehydrative coupling with 2,3,4,6-tetra-O-benzylD-glucose in an aqueous cosolvent under phase transfer conditions, presumably via in situ formation of the intermediate tosylate 31. Using a mixture of p-toluenesulfonyl chloride, an excess (4 equiv) of the alcohol acceptor, a solvent mixture of CH2Cl2 and 40% NaOH(aq), and BnEt3NCl as the phase transfer catalyst, simple alcohols
Glycosylation with 1-Hydroxy Donors
Scheme 6
39
Dehydrative glycosylations via glycosyl triflates [17–19].
such as benzyl alcohol, cholesterol, and even tertiary alcohols such at t-butyl alcohol can be glucosylated with good ␣-selectivity (e.g., 15, 32, 33). IV.
COUPLING VIA GLYCOSYL OXOPHOSPHONIUM INTERMEDIATES
The in situ generation of glycosyl oxophosphonium salts has been shown to be useful for one-pot couplings with 1-hydroxy glycosyl donors. The most common method employed for the generation of the carbohydrate oxophosphonium intermediates 35 occurs by way of the Mitsunobu protocol [25] or variants thereof (Scheme 9). The method typically employs the initial reaction of a dialkyl azodicarboxylate with a phosphine substrate in the presence of a weak acid to generate a quaternary phosphonium salt, 34. With this reagent, it is known that a variety of alcohols can be
40
Gin
Scheme 7 Dehydrative glycosylations via glycosyl arylsulfonates [20–23]. * Coupling performed in the presence of 2.5 equiv AcNMe2.
activated to form the corresponding oxophosphonium species, which can then be displaced (SN2) by a variety of weak-acid nucleophiles, including carboxylic acids, phenols, N-hydroxyimides, imides, and oximes. The process, being a one-pot dehydration, was therefore studied in the context of activation of the carbohydrate C1hemiacetal function. Early reports by Jurczak et al. [26] focused on the preparation of N-glycosylphthalimides from various furanoses and pyranoses employing diethyl azodicarboxylate, triphenylphosphine, and phthalimide as glycosyl acceptor; however, yields were typically low (5–43%). The use of N-hydroxyphthalimide as the glycosyl acceptor, on the other hand, led to a dramatic increase in coupling efficiency (e.g., 36) [27] with both pyranose and furanose donors. The utility of this particular glycosylation was demonstrated in the preparation of a key alkoxyamino glycosyl linker in Nicolaou’s synthesis of the oligosaccharide portion of calicheamicin ␥ [28].
Glycosylation with 1-Hydroxy Donors
Scheme 8
41
Dehydrative glycosylations via glycosyl arylsulfonates [24].
Simple alkyl alcohols are typically poor acceptor substrates for this type of coupling owing to the insufficient acidity of the acceptor component to aid in the formation of the phosphonium salt 34. To overcome this difficulty, Szarek and coworkers [29] introduced a mercuric halide salt to facilitate the formation of 34, thereby effecting dehydrative glycosylation of alcohol acceptors (e.g., 37) with hemiacetal donors. Carboxylic acids are generally good nucleophiles in the Mitsunobu reaction and have also been demonstrated to function as efficient glycosyl acceptors with this protocol. Smith has refined and used this method for glycosyl ester formation [30] as one of the key convergent steps (i.e., 38) in the synthesis of a (⫹)-phyllanthoside [31]. Likewise, phenolic nucleophiles have also been shown to be useful acceptors. Early reports involved efficient glycosylations to prepare simple phenyl glycosides [32– 34] followed by the preparation of more complex ones such as 39 [35], an intermediate in Ogawa’s total of synthesis of hygromycin A [36]. Roush’s preparation of the olivomycin fragment 40 [37], highlighting the utility of the method in complex molecule synthesis and its tolerance to a wide variety of sensitive functionalities, is of particular interest. Mukaiyama and coworkers have developed an alternate method for the generation of glycosyl oxophosphonium intermediates. This method is based on Hendrickson’s earlier work concerning the development of phosphonium anhydride dehydrating reagents, prepared by the reaction of triphenylphosphine oxide (2 equiv) and triflic anhydride (1 equiv) [38]. With the reagent combination of tributyl phosphine oxide (2 equiv) and triflic anhydride (1 equiv), Mukaiyama reported that the resulting diphosphonium salt 41 (Scheme 10) [39] efficiently converted the hemiacetal functionality of 1-hydroxy carbohydrates to the anomeric oxophosphonium species 42, an effective glycosylating agent. In the presence of i-Pr2NEt as an acid scavenger, glycosylation of a number of simple alcohols, O-TMS-protected alcohol acceptors, and even azide acceptors, can be effected with 2,3,5-tri-O-benzyl-D-furanose to afford the product glycosides (e.g., 43–45).
42
Scheme 9
Gin
Dehydrative glycosylations via glycosyl oxophosphonium intermediates [26– 37]. DEAD = diethyl azodicarboxylate; DIAD = diisopropyl azodicarboxylate.
Glycosylation with 1-Hydroxy Donors
Scheme 10
V.
43
Dehydrative glycosylations via glycosyl oxophosphonium intermediates [39].
COUPLING VIA GLYCOSYL OXOSULFONIUM INTERMEDIATES
We have developed a new method for dehydrative glycosylation involving the in situ generation of glycosyl oxosulfonium species [40]. The use of reactive dimethylsulfonium reagents for hydroxyl activation has been investigated in depth, primarily in the context of hydroxyl oxidation to form a carbonyl functionality [41]. Similar activation of a carbohydrate hemiacetal should therefore lead to the formation of an anomeric oxosulfonium species such as 47 (Scheme 11), which would likely function as an efficient glycosyl donor. The key challenge is the development of a reaction protocol in which sulfoxide displacement (or dissociation) at the anomeric center of 47 is favored over other possible reaction manifolds such as oxidation or elimination. In our procedure (Scheme 11), initial activation of diphenyl sulfoxide with triflic anhydride presumably generates diphenyl sulfide bis(triflate) 46. In situ activation of the hemiacetal hydroxyl function in 1 by 46 would afford the oxosulfonium triflate 47, which then undergoes coupling with the appropriate acceptor to afford the glycosylated product 3. By employing diphenyl sulfoxide, which does not incorporate protons adjacent to the sulfur center, ylide formation from 47 is precluded, and thus oxidation via intramolecular proton transfer (i.e., Moffatt–Swern oxidation) is avoided. Furthermore, triflic anhydride serves as an ideal reagent for sulfoxide activation in that (1) activation of dimethyl sulfoxide with triflic anhydride to induce nucleophilic attack at sulfur has been reported in a limited number of cases in the contexts of Swern-type oxidations [42], sulfilimine synthesis [43], alkene functionalization [44], and quinone methide generation [45]; and (2) the anionic by-product of activation, triflate, is a weak nucleophile and thus should not obstruct glycosidic bond formation with the desired acceptor.
44
Scheme 11
Gin
Dehydrative glycosylations via glycosyl oxosulfonium intermediates [40].
The glycosylation method just described was used to couple a variety of acceptors with 2,3,4,6-tetra-O-benzyl-D-glucopyranose. For example, phenol, ethanethiol, and 1,3,5-trimethoxybenzene underwent efficient glycosylation to yield the corresponding O-aryl, S-alkyl, and C-aryl glycosides in good yield (48–50). Moreover, the N-glycosylation of amide functionalities, which has been reported to occur with only the most reactive of nonenzymatic glycosylation procedures [46], was
Glycosylation with 1-Hydroxy Donors
45
found to proceed smoothly with N-(trimethylsilyl)trimethylacetamide to afford 51. In addition, the glycosylation of tertiary alcohols (e.g., 33) was shown to be equally efficient when this new method was used. To determine whether C2-neighboring group effects would influence the glycosylation stereochemistry in this procedure, 2,3,4,6-tetra-O-benzoyl-D-glucopyranose, a donor incorporating multiple electronwithdrawing protective groups, was also employed as a coupling partner. This donor was coupled with carbohydrate acceptors to form the corresponding (1→6)- and (1→4)-linked disaccharides 53 and 54 with complete -selectivity. Furanose donors are also compatible with this method, as evidenced by the formation of 52, the product of dehydrative N-glycosylation of bis(O-TMS)-thymine. Finally, the free NH functionality of a carbamate is compatible under these reaction conditions, allowing access to 2-amino-2-deoxy-glycosides (e.g., 55) with this protocol. VI.
COUPLINGS VIA GLYCOSYL OXOTITANIUM AND THIO-TIN INTERMEDIATES
Glycosyl oxotitanium intermediates were found to be useful in the furanosylation of various glycosyl acceptors. As long ago as 1989, Mukaiyama and coworkers had shown that [1,2-benzenediolato(2-)-O,O⬘]-oxotitanium (56) is a useful Lewis acid catalyst for aldol [47] and Michael reactions of ketene silyl acetals [48]. Used in combination with triflic anhydride, this Lewis acid was also found to be an effective dehydrating agent (Scheme 12) [49]. Treatment of 56 with triflic anhydride presumably leads to the formation of the bis(titanium) salt 57, which activates a 1-hydroxy glycosyl donor to form the intermediate anomeric oxotitanium species 58. This intermediate was shown to be an effective glycosyl donor to various alcohol and trimethylsilyl ether nucleophiles (e.g., 59–61). Mukaiyama et al. also found the use of diphenyltin sulfide and triflic anhydride to be suitable for furanoside formation with C1-hydroxy furanose donors (Scheme 13) [50]. Following activation of the hemiacetal with this pair of reagents, a glycosyl acceptor is introduced, in the form of an alcohol or a TMS-ether, to yield the product glycoside. Excellent anomeric selectivity can be achieved with 2,3,5-tri-O-benzyl-Dribofuranose as the donor (e.g., 60, 63), with the selectivity depending on the presence or absence of LiClO4 as an additive. The authors presumed that in the absence of LiClO4, the reactive intermediate 64 (Scheme 14) is generated, whereby the ␣ face is sterically shielded by virtue of coordination of tin(IV) with the C2-oxygen of the donor, leading to near exclusive information of the  adduct 65. Conversely, the presence of LiClO4 (15 equiv) may serve to convert 64 into the ion pair 66, in which the perchlorate anion is situated on the  face, trans to the C2 substituent, favoring acceptor approach onto the ␣ face. It is worth noting that the intermediacy of the corresponding C1-O-TMS derivative of the 1-hydroxy donor has also been suggested in these coupling reactions when TMS–ether acceptors are employed [51]. VII.
COUPLINGS VIA GLYCOSYL ISOUREA INTERMEDIATES
Carbodiimide reagents have long been known to be effective dehydrating agents in coupling reactions [52]. Tsutsumi et al. have shown that simple carbodiimide reagents are also effective in the context of dehydrative couplings with 1-hydroxy glycosyl donors (Scheme 15) [53]. Reactions of alcohols with carbodiimides have been known
46
Gin
Scheme 12
Dehydrative glycosylations via glycosyl oxotitanium intermediates [49].
to occur in the presence of CuCl to form O-alkyl isoureas [54]. This transformation was applied to C1-glycosyl hemiacetals 1 with dicyclohexyl carbodiimide to generate the corresponding O-glycosyl isourea 68, which proceeds to glycosylate appropriate acceptors via expulsion of dicyclohexyl urea from the anomeric center. This one-pot procedure was found to be effective at elevated temperatures (80–85⬚C) with a variety of phenolic nucleophiles (e.g., 69–72) in addition to several thiophenolic nucleophiles (e.g., 73). The high -selectivity of the coupling reactions presumably arises from SN2 displacement of the corresponding ␣-glycosyl isourea intermediate, which is generated at elevated temperatures in the activation stage. VIII.
COUPLING VIA LEWIS ACID CATALYSIS
Acid catalysis in glycosylations with 1-hydroxy glycosyl donors has traditionally employed the Fischer glycosylation procedure or variants thereof in which simple glycosyl acceptors are employed in vast excess. Within the last several years, a series
Glycosylation with 1-Hydroxy Donors
Scheme 13
47
Dehydrative glycosylations via glycosyl thio-tin intermediates [50,51].
of dehydrative glycosylations using Lewis acid catalysts in the presence of a desiccant has been reported, employing equimolar or only slight excesses of various nucleophilic acceptors (Scheme 16, Table 1). Inanaga and coworkers reported the use of the catalyst combination of Yb(OTf)3 and methoxyacetic acid (0.1 equiv of each) employing only 1.2 equiv of the glycosyl acceptor (Table 1, entries 1–3) [55]. Anomeric mixtures were obtained with pyranose donors, while the ribofuranose donor 77 afforded high -selectivities.
Scheme 14
Perchlorate ion and anomeric selectivity [50].
48
Gin
Scheme 15
Dehydrative glycosylations via glycosyl isoureas [53].
Scheme 16
Dehydrative glycosylations via Lewis acid catalysis: Selected coupling partners
[55–60].
Glycosylation with 1-Hydroxy Donors
Table 1
Entry
49
Dehydrative Glycosylations via Lewis Acid Catalysis Coupling partners
Catalyst(s)
Reagents
1
77 ⴙ 78
2
77 ⴙ 79
3
74 ⴙ 81
4
74 ⴙ 78
Yb(OTf )3, MeOCH2CO2H Yb(OTf )3, MeOCH2CO2H Yb(OTf )3, MeOCH2CO2H Zn(OTf )2
5
75 ⴙ 79
Zn(OTf )2
6
76 ⴙ 79
Zn(OTf )2
7
77 ⴙ 78
Sn(OTf )2, (TMS)2O
TMSCl (1.5 equiv), CH3CN (23⬚C) TMSCl (1.5 equiv), CH2Cl2 (23⬚C) TMSCl (1.5 equiv), CH2Cl2 (23⬚C) Drierite, MeNO2 (23⬚C)
8
77 ⴙ 79
Sn(OTf )2, (TMS)2O
Drierite, MeNO2 (23⬚C)
9
77 ⴙ 78
Sn(OTf )2, (TMS)2O
10
75 ⴙ 80
Sn(OTf )2TMSCl
11
77 ⴙ 78
[Ph3C]⫹ [B(C6F5)4]⫺
Drierite, LiClO4 (1.5 equiv), MeNO2 (23⬚C) Drierite, LiClO4 (3.5 equiv), PhH (23⬚C) Drierite, EtNO2 (0⬚C)
12
77 ⴙ 80
[Ph3C]⫹ [B(C6F5)4]⫺
Drierite, EtNO2 (0⬚C)
13
77 ⴙ 78
Ph2Sn — —S, AgClO4
PhH, 3A-MS (23⬚C)
14
77 ⴙ 79
Ph2Sn — —S, AgClO4
PhH, 3A-MS (23⬚C)
15
77 ⴙ 78
PhCH3, 3A-MS (23⬚C)
16
77 ⴙ79
Lawesson’s reagent, AgClO4 Lawesson’s reagent, AgClO4
4A-MS, CH2Cl2 (reflux) 4A-MS, CH2Cl2 (reflux) Cl(CH2)2Cl (53⬚C)
PhCH3, 3A-MS (23⬚C)
Yield (%) (␣ : ) 92 (0:100) 98 (04:96) 85 (48:52) 76 (55:45) 61 (62:38) 43 (88:12) 97 (05:95) 97 (05:95) 96 (94:06) 86 (96:04) 90 (09:91) 92 (04:96) 89 (13:87) 90 (04:96) 79 (24:76) 90 (04:96)
Ref. 55 55 55 56 56 56 57 57 57 58 59 59 60 60 60 60
The authors found that simple thiols also are effective acceptors in this coupling ˚ molecular sieves, the glycoside yields were method, and, in the presence of 4 A uniformly high. The work of Susaki established that Zn(OTf)2 can be employed in dehydrative glycosylation [56]. The combination of Zn(OTf)2 and TMSCl was found to be useful for glycosidic bond formation with both glycosyl ester donors, as well as 1-hydroxy carbohydrate donors (entries 4–6). In these couplings, the ratio of donor to acceptor to TMSCl to Zn(OTf)2 is 1:2:1.5:0.3, with either acetonitrile or CH2Cl2 as the reaction solvent. Benzylated gluco-, galacto-, and mannopyranose donors generally afforded good yields of alkyl glycosides with anomeric selectivities that vary with
50
Gin
the nature of the coupling substrates. It is worth noting that couplings were significantly less efficient when an excess (1.5 equiv) of Zn(OTf)2 was employed. In a variety of the Lewis acid catalysts also surveyed by Mukaiyama and coworkers, benzylated furanose and pyranose substrates were found to be effective donors [57,58]. With the catalyst combination of the Sn(OTf)2 (0.01 equiv) and TMS2O (0.1 equiv) in the presence of anhydrous calcium sulfate, 2,3,5-tri-O-benzylD-furanose 77 can be used to directly glycosylate the alcohols 78 and 79 with high -stereoselectivity (Table 1, entries 7, 8). The couplings are presumed to proceed via the TMS ether derivatives of the coupling partners, which are generated in situ, and the high -selectivity is likely a result of product formation under thermodynamic control. In the presence of LiClO4 (1.5 equiv) as an additive, however, a dramatic reversal of the anomeric selectivity is observed, likely owing to the formation of the oxocarbenium perchlorate 66 (Scheme 14) as the active glycosylating agent (entries 9, 10). Various other glycosyl acceptors in addition to those in Table 1 were shown to be compatible with the Sn(OTf)2 /TMS2O method, including Cnucleophiles such as 1,3,5-trimethoxybenzene and O-silyl ketene acetals. Although the Sn(OTf)2 /TMS2O Lewis acid system is highlighted in Table 1, Mukaiyama has also demonstrated that other Lewis acid catalyst systems can be used, such as those incorporating Yb(OTf)3, La(OTf)3, and SnCl2, leading to comparable coupling efficiencies and stereoselectivities. In addition to metallic Lewis acid catalysts, it has been demonstrated that trityl salts can be used for the efficient ribofuranosylation of alcohols [59]. With 77 as the donor and 3 mol% of [Ph3C]⫹[B(C6F5)4]⫺ catalyst in the presence of anhydrous CaSO4, high yields of various furanosides were obtained with only 1.3 equiv of the alcohol acceptors, affording high selectivity for the thermodynamic  isomer (entries 11, 12). In these studies, other counterions for the trityl cation were investigated ⫺ ⫺ in Mukaiyama’s survey of catalysts, including BF⫺ 4 , ClO4 , and SbCl6 , but ⫹ ⫺ [Ph3C] [B(C6F5)4] was found to be the most efficient in terms of yield, anomeric selectivity, and ease of catalyst handling. Two-component dehydrative catalysts have also been reported by Mukaiyama and coworkers for ribofuranosylation of alcohols. One such system is based on an earlier report by these investigators of the Ph2Sn — —S/Tf2O reagent combination for dehydrative coupling. When a catalytic amount of Ph2Sn — —S in combination with AgClO4 (0.2 equiv each) [60] were employed in the coupling of 77 with alkyl alcohols (1.2 equiv), good yields were obtained favoring the  anomer of the product furanosides (entries 13, 14). The presumed active catalytic agent in the reaction is the Sn(IV) species 82. In like manner, the two-component catalyst system of Lawesson’s reagent and AgClO4 (0.2 equiv each) was found to be effective for coupling transformations (entires 15, 16), where the phosphonium species 83 is believed to be the active catalyst.
Glycosylation with 1-Hydroxy Donors
IX.
51
CONCLUSION
The importance of the development of new glycosylation methods cannot be disputed. Although many new variants of the traditional glycosylation processes have been developed over the years, comparatively fewer methods have been developed for direct dehydrative coupling with 1-hydroxy donors. The methods summarized in this chapter address many of the inherent obstacles associated with this strategy. For example, with the appropriate dehydrating agent in the glycosylation, the formation of the undesired by-products of hemiacetal self-condensation can be minimized, even when only a slight excess of the glycosyl acceptor component is employed in the coupling. Further development of these and other dehydrative coupling strategies will certainly establish this to be an efficient approach for the controlled assembly of complex carbohydrates. REFERENCES 1.
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(a) Synthetic Oligosaccharides. Indispensable Probes for the Life Sciences, Kovac, P., ed. ACS Symposium Series 560; American Chemical Society: Washington, DC, 1994. (b) Dwek, R. A. Chem. Rev. 1996, 96, 683–720. (a) Preparative Carbohydrate Chemistry; Hanessian, S., Ed.; Marcel Dekker: New York, 1997, Chapters 12–22. (b) Boons, G.-J. Tetrahedron 1996, 52, 1095–1121. (c) Danishefsky, S. J.; Bilodeau, M. T. Angew. Chem. Int. Ed. Engl. 1996, 35, 1380–1419. (d) Schmidt, R. R.; Kinzy, W. Adv. Carbohydr. Chem. Biochem. 1994, 50, 21–123. (e) Toshima, K.; Tatsuta, K. Chem. Rev. 1993, 93, 1503–1531. (f ) Sinay¨, P. Pure Appl. Chem. 1991, 63, 519–528. (a) Fischer, E. Chem. Ber. 1893, 26, 2400–2412. (b) Bochkov, A. F.; Zaikov, G. E. Chemistry of the O-Glycosidic Bond. Pergamon: Oxford, 1979. McCurry Jr., P. M.; Pickens, C. E. U.S. Patent 4,950,743, 1990. Wessel, H. P. J. Carbohydr. Chem. 1988, 7, 263–269. For example: Nepogod’ev, S. A.; Backinowsky, L. V.; Grzeszczyk, B.; Zamojski, A. Carbohydr. Res. 1994, 254, 43–60. For example: (a) Fischer, B.; Nudelman, A.; Ruse, M.; Herzig, J.; Gottlieb, H. E. J. Org. Chem. 1984, 49, 4988–4993. (b) Kuhn, M.; von Wartburg, A. Helv. Chim. Acta 1968, 51, 1631–1641. (c) Kochetkov, N. K.; Khorlin, A. J.; Bochkov, A. F. Tetrahedron Lett. 1964, 289–293. Lubineau, A.; Fischer, J.-C. Synth. Commun. 1991, 21, 815–818. Smirnyagin, V.; Bishop, C. T. Can. J. Chem. 1968, 46, 3085–3090. Defaye, J.; Gadelle, A. Carbohydr. Res. 1989, 186, 177–188. Brochette, S.; Descotes, G.; Bouchu, A.; Queneau, Y. J. Carbohydr. Chem. 1998, 17, 879–891. Koto, S.; Morishima, N.; Zen, S. Bull. Chem. Soc. Jpn. 1982, 55, 1543–1547. Koto, S.; Morishima, N.; Kusuhara, C.; Sekido, S.; Yoshida, T.; Zen, S. Bull. Chem. Soc. Jpn. 1982, 55, 2995–2999. Paulsen, H. Angew. Chem. Int. Ed. Engl. 1982, 21, 155–173. Koto, S.; Morishima, N.; Zen, S. Chem. Lett. 1976, 1109–1110. Leroux, J.; Perlin, A. S. Carbohydr. Res. 1978, 67, 163–178. Pavia, A. A.; Rocheville, J.-M.; Ung, S. N. Carbohydr. Res. 1980, 79, 79–89. Pavia, A. A.; Ung-Chhun, S. N. Can. J. Chem. 1981, 59, 482–489. Lacombe, J. M.; Pavia, A. A. J. Org. Chem. 1983, 48, 2557–2563. Koto, S.; Sato, T.; Morishima, N.; Zen, S. Bull. Chem. Soc. Jpn. 1908, 53, 1761–1762. Koto, S.; Morishima, N.; Owa, M.; Zen, S. Carbohydr. Res. 1984, 130, 73–83.
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22.
Koto, S.; Miura, T.; Hirooka, M.; Tomaru, A.; Iida, M.; Kanemitsu, M.; Takenaka, K.; Masuzawa, S.; Miyaji, S.; Kuroyanagi, N.; Yagishita, M.; Zen, S.; Yago, K.; Tomonaga, F. Bull. Chem. Soc. Jpn. 1996, 69, 3247–3259. Koto, S.; Morishima, N.; Uchino, M.; Fukuda, M.; Yamazaki, M.; Zen, S. Bull. Chem. Soc. Jpn. 1988, 61, 3943–3950. Szeja, W. Synthesis, 1988, 223–224. (a) Hughes, D. L. Org. Prep. Proced. Int. 1996, 28, 127–164. (b) Mitsunobu, O. Synthesis 1981, 1–28. Jurczak, J.; Grynkiewicz, G.; Zamojski, A. Carbohydr. Res. 1975, 39, 147–150. Grochowski, E.; Jurczak, J. Carbohydr. Res. 1976, 50, C15–C16. Nicolaou, K. C.; Groneberg, R. D. J. Am. Chem. Soc. 1990, 112, 4085–4086. Szarek, W. A.; Jarrell, H. C.; Jones, J. K. N. Carbohydr. Res. 1977, 57, C13–C16. Smith, A. B. III; Hale, K. J.; Rivero, R. A. Tetrahedron Lett. 1986, 27, 5813–5816. Smith, A. B. III; Rivero, R. A.; Hale, K. J.; Vaccaro, H. A. J. Am. Chem. Soc. 1991, 113, 2092–2112. Grynkiewicz, G. Carbohydr. Res. 1977, 53, C11–C12. Kometani, T.; Kondo, H.; Fujimori, Y. Synthesis, 1988, 1005–1007. Roush, W. R.; Lin, X.-F. J. Org. Chem. 1991, 56, 5740–5742. Chida, N.; Ohtsuka, M.; Ogawa, S. Chem. Lett. 1988, 969–972. Chida, N.; Ohtuka, M.; Nakazawa, K.; Ogawa, S. J. Org. Chem. 1991, 56, 2976–2983. Roush, W. R.; Lin, X.-F. J. Am. Chem. Soc. 1995, 117, 2236–2250. (a) Hendrickson, J. B.; Schwartzman, S. M. Tetrahedron Lett. 1975, 277–280. (b) Hendrickson, J. B.; Hussoin, S. Md. J. Org. Chem. 1989, 54, 1144–1149. Mukaiyama, T.; Suda, S. Chem. Lett. 1990, 1143–1146. Garcia, B. A.; Poole, J. L.; Gin, D. Y. J. Am. Chem. Soc. 1997, 119, 7597–7598. Tidwell, T. T. Synthesis 1990, 857–870. Hendrickson, J. B.; Schwartzman, S. M. Tetrahedron Lett. 1975, 273–276. Coburn, M. D.; Hayden, H. H.; Coon, C. L.; Mitchell, A. R. Synthesis 1986, 490–492. Nenajdenko, V. G.; Vertelezkij, P. V.; Gridnev, I. D.; Shevchenko, N. E.; Balenkova, E. S. Tetrahedron 1997, 53, 8173–8180. Corey, E. J.; Gin, D. Y.; Kania, R. S. J. Am. Chem. Soc. 1996, 118, 9202–9203. Kahne, D.; Walker, S.; Cheng, Y.; Van Engen, D. J. Am. Chem. Soc. 1989, 111, 6881– 6882. Hara, R.; Mukaiyama, T. Chem. Lett. 1989, 1909–1912. Mukaiyama, T.; Hara, R. Chem. Lett. 1989, 1171–1174. Suda, S.; Mukaiyama, T. Chem. Lett. 1991, 431–434. Mukaiyama, T.; Matsubara, K.; Suda, S. Chem. Lett. 1991, 981–984. Mukaiyama, T.; Matsubara, K. Chem. Lett. 1992, 1041–1044. Williams, A.; Ibrahim, I. T. Chem. Rev. 1981, 81, 589–636. Tsutsumi, H.; Ishido, Y. Carbohydr. Res. 1981, 88, 61–75. Schmidt, E.; Moosmu¨ller, F. Liebigs Ann. Chem. 1955, 597, 235–240. Inanaga, J.; Yokoyama, Y.; Hanamoto, T. J. Chem. Soc. Chem. Commun. 1993, 1090– 1091. Susaki, H. Chem. Pharm. Bull. 1994, 42, 1917–1918. Mukaiyama, T.; Matsubara, K.; Hora, M. Synthesis, 1994, 1368–1373. Uchiro, H.; Miyazaki, K.; Mukaiyama, T. Chem. Lett. 1997, 403–405. Uchiro, H.; Mukaiyama, T. Chem. Lett. 1996, 79–80. Shimomura, N.; Mukaiyama, T. Bull. Chem. Soc. Jpn. 1994, 67, 2532–2541.
23. 24. 25. 26. 27. 28. 29. 30. 31. 32. 33. 34. 35. 36. 37. 38. 39. 40. 41. 42. 43. 44. 45. 46. 47. 48. 49. 50. 51. 52. 53. 54. 55. 56. 57. 58. 59. 60.
3 Chemistry of Glycosyl Triflates: Synthesis of -Mannopyranosides David Crich University of Illinois at Chicago, Chicago, Illinois
I.
INTRODUCTION
Among the numerous and varied glycosyl donors known, the glycosyl sulfonates have been somewhat neglected in recent years, despite their considerable potential in stereoselective glycosylation having been demonstrated over 20 years ago by Schuerch and coworkers. This unfortunate circumstance perhaps arose because of the difficulties encountered by the early workers in the isolation of pure samples. Recent work from our laboratories in Chicago has revealed that glycosyl triflates may be very readily accessed from either glycosyl sulfoxides or thioglycosides and that these substances have excellent reactivity toward a broad spectrum of glycosyl acceptors even at ⫺78⬚C. The main part of this chapter is therefore concerned with the development of the chemistry of the glycosyl triflates and, especially, with their applications in the synthesis of -mannopyranosides. However, there are useful lessons to be learned from the precedents alluded to above, and it is with this in mind that we begin with an overview of the earlier work. II.
GLYCOSYL SULFONATES
The first reported preparation of a glycosyl sulfonate, in 1929, involved the heating of acetobromoglucose with silver toluenesulfonate in diethyl ether; Helferich and Gootz noted that the product was white and crystalline but decomposed in a matter of hours in chloroform solution at room temperature [1]. Many years after this inauspicious start, Schuerch and his coworkers turned their attention to an exploration of the uses of glycosyl sulfonates as glycosyl donors. Thus, in a 1973 paper that presaged many of the later developments, Kronzer and Schuerch suggested that the 53
54
Crich
treatment of 2,3,4,6-tetra-O-benzyl-␣-D-glucopyranosyl chloride (1) or bromide with silver triflate at ⫺78⬚C in dichloromethane or diethyl ether provided the anomeric triflate 2 (Scheme 1) [2]. They opined that, owing to the strongly electron-withdrawing nature of the triflate group, this substance probably had the ␣ configuration. It was also noted that subsequent couplings with methanol, conducted at ⫺78⬚C, were -selective in dichloromethane but unselective in diethyl ether, and the difference was attributed to the superior shielding of the ␣ face provided by the tighter ion pair in dichloromethane [2]. The rapidity of the reactions, both the initial formation of the triflate and its subsequent reaction with methanol at ⫺78⬚C, were also noted at this time [2]. Prompted by the extreme reactivity of the triflates and the desire to work with isolable, characterized intermediates, Schuerch and Eby subsequently turned their attention to the use of toluenesulfonates and mesylates [3]. Thus, 2,3,4,6-tetra-Obenzyl-␣-D-glucopyranosyl chloride, or bromide, was allowed to react with silver toluenesulfonate in acetonitrile at room temperature. The authors were able to use standard vacuum line techniques to remove the silver halide by filtration and obtain an 1H NMR spectrum of the product in deuteriochloroform: the characteristics of the anomeric proton (␦ 6.1, 3J1,2 = 3.5 Hz) led to the attribution of the ␣ stereochemistry. In the case of the analogous 2,3,4-tri-O-benzyl-6-O-(N-phenylcarbamoyl) series, signals attributed to the -toluenesulfonate (␦ 5.5, 3J1,2 = 8.0 Hz) accounted for approximately 15% of the reaction mixture [3]. In agreement with the earlier report of Helferich and Gootz, complete decomposition was noted after several hours at room temperature. Coupling reactions of the so-formed 2,3,4,6-tetra-O-benzyl-1-O-tosyl␣-D-glucopyranose, conducted with methyl 2,3,4,-tri-O-benzyl-␣-D-glucopyranoside in a range of solvents, gave moderate yields but little selectivity. Kinetic measurements, carried out polarimetrically, revealed no clear dependence of reaction rate on alcohol structure or concentration and suggested to the authors that the couplings were SN1 in character and involved a series of interchanging tight ion pairs [3]. Eby and Schuerch also noted that the anomeric toluenesulfonates formed from silver toluenesulfonate and peracylated (acetyl, benzoyl) glucosyl halides were considerably more stable, and less reactive, and upon exposure to methanol led to mixtures of ␣- and -glucosides as well as to orthoesters. These latter results prompted them to suggest that the esterified toluenesulfonates would probably be of little use in glycosylation [3]. Schuerch and his coworkers also investigated the galactopyranosyl toluenesulfonates and triflates. As in the glucose series, these were formed from the corresponding bromides by metathesis reactions with the appropriate silver sulfonates [4,5]. With a series of differentially 6-O-protected 2,3,4-tri-O-benzylgalactopyranosyl
Scheme 1
Chemistry of Glycosyl Triflates
55
sulfonates, excellent yields and high ␣-selectivity were obtained upon coupling to a range of alcohols in various solvents. It was noted that the ␣-selectivity was minimized with the use of the triflate leaving group, albeit for reactions conducted at ⫺78⬚C, in contrast to the other members of the series when room temperature was used. In the case of the reaction of the 4,6-di-O-(N-phenylcarbamoyl)-2,3-di-O-benzylgalactopyranosyl triflate with methanol, high -selectivity was exceptionally obtained. These results were again all interpreted in terms of more or less tight ion pairs [4,5]. Finally, Srivastava and Schuerch studied the formation of -mannopyranosides and the related -rhamnopyranosides, using a range of glycosyl sulfonates as donors [6,7]. In this most difficult series, the authors emphasized the increased anomeric effect resulting from the antiparallel dipoles of the C1—O and C2—O bonds and sought to maximize this contribution by installing a strongly electron-withdrawing, nonparticipating protecting group on O2. Thus, 3,4,6-tri-O-benzyl-2-O-mesyl-␣-Dmannopyranosyl chloride (4) was prepared and reacted with a range of silver sulfonates to give the corresponding ␣-mannosyl sulfonates. Subsequent exposure to methanol or cyclohexanol, usually in acetonitrile, then gave the mannopyranosides in high yield and excellent -selectivity. Only one carbohydrate-based alcohol (6) was used as glycosyl acceptor, but this too gave excellent -selectivity especially with the 2,2,2-trifluoroethanesulfonate 5 as donor (Scheme 2). In considering the mechanism of their mannosylation reaction, Srivastava and Schuerch suggested that the electron-withdrawing sulfonate ester at the 2-position served to render the reactive ion pair in the SN1 mechanism tighter on the ␣ face than was the case in the glucose and galactose series. In this manner the ␣ face was considered to be highly shielded toward approach of the nucleophile, with the displacement taking on the high stereoselectivity normally associated with SN2 processes [6,7]. Similar -selectivities were obtained from a 3,4-di-O-benzyl-2-O-mesyl␣-L-rhamnopyranosyl tosylate [6,7]. Although the authors obtained excellent
Scheme 2
56
Crich
-selectivity and yields in their mannosylations and rhamnosylations, they repeatedly alluded to the high moisture sensitivity of the anomeric sulfonates, as in the earlier glucose and galactose series, and the need to work on vacuum lines. Presumably this, and the need to remove the somewhat unconventional 2-O-mesylate protecting group subsequent to coupling, prevented them from developing the full potential of the method and applying it in the synthesis of oligosaccharides. More or less contemporaneously with the work of Schuerch, Leroux and Perlin studied the sulfonylation of pyranoses. Thus, 2,3,4,6-tetra-O-benzyl-␣-D-glucopyranose was treated in cold dichloromethane with triflic anhydride in the presence of 2,4,6-collidine, leading to a purported anomeric triflate. However, the authors noted that subsequent addition of methanol or ethanol did not lead to the formation of the glycoside in acceptable yields [8,9]. Subsequently, it was discovered that conducting the triflation in the presence of tetrabutylammonium bromide resulted in the formation of the ␣-glucopyranosyl bromide and that addition of an alcohol then led cleanly to the glycoside. In these reactions Perlin and Leroux typically carried out the triflation/bromide displacement at ⫺70⬚C, noting that bromide formation was complete after 15–30 min; the reaction mixture was warmed to room temperature before addition of the alcohol. However, it was also noted that bromide formation could be conducted at room temperature without apparent detriment. These workers also investigated the use of 2,3,4,6-tetra-O-acetyl--D-glucopyranose (8), with its potentially participating protecting groups, as substrate. In the presence of collidine but the absence of bromide ion, an orthoester (10) was isolated in 44% yield. When bromide ion was included in the reaction mixture, acetobromoglucose (11) was isolated in 50% yield and there was no indication of orthoester formation. It was suggested that both reactions proceeded by way of the -triflate (9), which was trapped either by further pyranose or by bromide ion according to the conditions employed (Scheme 3) [8,9]. The reaction of methanesulfonic anhydride with 2,3,4,6-tetra-O-benzyl-␣-Dglucopyranose in dichloromethane in the presence of collidine, followed by addition of methanol, resulted in the formation of a 3:2 ␣/ mixture of the methyl glycosides, isolated in 87% yield. Since glycosylation was achieved without the need for addition of the quaternary ammonium bromide, unlike the case of triflic anhydride, it was concluded that the glucosyl mesylate was considerably more stable and allowed for the displacement reaction to take place. Moreover, the anomeric ratio suggested that the ␣ and  anomers of this mesylate were in equilibrium, with displacement of the  anomer occurring more rapidly. When 2,3,4,6-tetra-O-acetyl--D-glucopyranose was treated with methanesulfonic anhydride, a crystalline product was obtained in 74% yield and assigned as the ␣-glucosyl mesylate. Indeed the characteristics of this substance were comparable to those of the compound obtained by Schuerch upon treatment of acetobromoglucose with silver methanesulfonate [8,9]. When methanesulfonyl chloride was allowed to react with 2,3,4,6-tetra-O-benzylglucopyranose and collidine in dichloromethane, the ␣-glucopyranosyl chloride was isolated regardless of whether the quaternary ammonium bromide was included. Addition of methanol to the reaction mixture resulted in the formation of an anomeric mixture of methyl glycosides. Similar results were obtained with toluenesulfonyl chloride, although it was noted that the initial sulfonylation was somewhat slower [8,9]. The use of tosyl chloride in the dehydrative coupling of alcohols with pyranoses was later revisited by Szeja and his coworkers, with the difference that aqueous
Chemistry of Glycosyl Triflates
57
Scheme 3
phase transfer conditions were used, and glycosyl toluenesulfonates were implied as intermediates [10,11]. Koto and coworkers investigated the coupling of tetra-O-benzyl-␣-D-glucopyranose and a range of acceptor alcohols with the aid of a mixture of 4-nitrobenzenesulfonyl chloride and silver triflate [12–15]. In the presence of triethylamine, the ␣-glycoside predominated, whereas the inclusion of N,N-dimethylacetamide resulted in the isolation of the  anomer. It was suggested that the anomeric hydroxyl group was sulfonylated with the sulfonyl chloride to a glucopyranosyl 4nitrobenzenesulfonate and subsequently converted to the active glycosyl donor, the glucopyranosyl triflate, by the action of silver triflate. However, given the relative acidities of triflic and 4-nitromethanesulfonic acid and the related work of Szeja, carried out in the absence of silver triflate, the formation of a covalent glycosyl triflate in this work appears to be somewhat unlikely. The inversion of stereoselectivity on inclusion of the N,N-dimethylacetamide was explained by invoking the formation of an ␣-N,N-dimethylacetimidate ester [12,13]. Pavia et al. revisited the reactions of tetra-O-benzylglucopyranose (12) with trifluoromethanesulfonic anhydride, but in the absence of base. They discovered that the corresponding trehalose derivatives (13) were formed in good yield, predominantly as the ␣,␣ form (Scheme 4) [16]. Comparable results were obtained in the galacto-, manno-, and arabinopyranose series as with fructofuranose [16]. When trifluoromethanesulfonic anhydride was added to a mixture of a perbenzyl-protected glycopyranose and an acceptor alcohol, such as various serine, threonine and hydroxproline derivatives, coupling was achieved in good yield [17]. Pavia and coworkers carried out a careful study of the mechanism of these reactions using 19F-NMR spectroscopy. They concluded that they were observing simple acid-catalyzed dehydrative couplings in which water was removed from the
58
Crich
Scheme 4
equilibrium in the form of a salt with triflic acid (TfO⫺ H3O⫹), which is insoluble in dichloromethane. The authors specifically excluded the intermediacy of a covalently bound glucosyl triflate on the grounds that the reaction did not occur below 15⬚C, whereas Perlin’s reactions succeeded at ⫺70⬚C [18]. III.
MANNOSYL TRIFLATES FROM MANNOSYL SULFOXIDES AND THIOGLYCOSIDES: THE -MANNOSYLATION REACTION
Several years ago in Chicago, we were engaged in developing a solution to the wellknown -mannoside problem [19] involving the inversion of the much more readily accessible ␣-mannosides by a sequence of hydrogen atom abstraction, radical inversion, and diastereoselective quenching (Scheme 5) [20,21]. With the fundamental chemistry, which was developed using commercially available ␣-methyl mannopyranoside as substrate in hand, it became necessary to prepare a genuine ␣-disaccharide for inversion. We selected Kahne’s excellent sulfoxide method [22–24] for numerous reasons, which included the reported excellent yields for coupling to extremely hindered alcohols at low temperatures, the absence of any metal salt as promoter, and the implication that the coupling proceeded through quenching of the oxacarbenium ion, hence should provide the ␣-mannoside. Other than a brief footnote in their original communication noting that the anomeric stereoselectivity was a function of the stereochemistry at C2 of the sulfoxide donor [22], Kahne and his coworkers had not described the application of their method to the mannose series. Jarmila Brunckova thus prepared S-ethyl 4,6-benzylidene-␣-Dthiomannopyranoside by standard means and converted it to the 3-O-benzyl-2-Otert-butyldimethylsilyl derivative (14) by the aegis of dibutyltin oxide and benzyl bromide, then TBDMS triflate. Oxidation with mCPBA then gave the sulfoxide (15) required for coupling [21]. Brunckova noted the highly selective sulfoxidation process, which gave essentially a single diastereomer, in contrast to the unselective oxidations -thioglycosides observed previously [23], but was unable to assign configuration at the time. In fact it was several years before Jan Mataka and Sanxing Sun were able to prepare crystalline derivatives suitable for X-ray analysis and so assign the configuration as SR [25]. Brunckova then mixed the sulfoxide with methyl
Scheme 5
Chemistry of Glycosyl Triflates
59
Scheme 6
2,3,4-tri-O-acetyl-␣-D-glucopyranoside (16) and 2,6-di-tert-butyl-4-methylpyridine (DTBMP), a hindered base, in diethyl ether at ⫺78⬚C and activated the sulfoxide by dropwise addition of triflic anhydride. In line with our expectations, a good yield of a 10:1 mixture of glycosides (17) favoring the ␣ anomer was obtained (Scheme 6) [21]. The TBDMS protecting group was removed and was replaced by the radical precursor, and the radical inversion procedure was conducted with moderate success, comparable to that seen with the ␣-methyl mannoside [21]. Sanxing Sun, a new student, sought to prepare more of the ␣-disaccharide (17) and subsequently to improve the radical inversion process. He repeated Brunckova’s preparation with the minor, but fortuitous, difference that the sulfoxide was activated with triflic anhydride before addition of the acceptor alcohol. To our amazement, an excellent yield was obtained of an anomeric mixture favoring the -mannoside by a factor of roughly 10 (Scheme 7) [26,27]. Consideration of this unanticipated reversal of diastereoselectivity led us to propose a mechanism in which, under all conditions, the sulfoxide 15 (Scheme 8) undergoes rapid sulfonylation leading to a sulfonium ion 18. We then postulated that this sulfonium ion collapses to the oxacarbenium ion 19 which, when generated in
Scheme 7
60
Crich
Scheme 8
the presence of the donor a` la Brunckova, is trapped axially to give the anticipated ␣-mannoside (17␣). On the other hand, we suggested that, under the Sun conditions, the oxacarbenium ion is trapped by triflate anion to give an ␣-mannosyl triflate 20. Then, on subsequent addition of the acceptor, an SN2-like process occurs with formation of the -mannoside (17) [27,28]. This mechanistic hypothesis also provided a reason for the poor -selectivity observed with secondary alcohol acceptors, even under the Sun conditions, namely, the well-known retardation of SN2 reactions by steric hindrance, leading to the interference of a dissociative mechanism via a Curtin–Hammett type of kinetic scheme. We predicted therefore that reducing the size of the O2 protecting group on mannose would accelerate the SN2 process for any given alcohol and so lead to increased -selectivity. We also predicted that a change in solvent from diethyl ether to dichloromethane would further shift any ion pair/covalent triflate equilibrium toward the covalent triflate and so similarly lead to enhanced -selectivity [27,28]. Both hypotheses were readily tested and confirmed. Thus, the series of sulfoxides 15, 21 and 22, with decreasing bulk of the O2 protecting group, were prepared and coupled to the rhamnosyl acceptor 23. As seen from Table 1, selectivity increases both as the size of the protecting group decreases and as the solvent is changed from diethyl ether to dichloromethane. Ultimately, with the 2-O-benzyl donor in dichloromethane as solvent, the ␣ anomer of the product was not detectable [28]. These conditions were then applied to the -mannosylation of a range of primary and secondary carbohydrate acceptors with considerable success (Table 2) [27,28]. Attention was next focused on the use of alternative, nonparticipating protecting groups for the mannosyl donor, and the allyl group was found to be satisfactory at both O2 and O3 (Scheme 9) [27]. Indeed, Zongmin Dai and Greg Barba subsequently used a 2-O-allyl protected donor to form the -mannoside linkage in the Hyriopsis schlegelii trisaccharide and the caloporside disaccharide, respectively [29– 31]. Further work, however, revealed the 4,6-benzylidene group to be indispensable for high -selectivity, inasmuch as a 2,3,4,6-tetra-O-benzyl protected mannosyl donor gave very poor selectivity (Scheme 10) [27,28].
Chemistry of Glycosyl Triflates
Table 1
61
Reaction of Glycosyl Donors with 23 in Ether and CH2Cl2 Product and yield (%)b
Donor
a
Protocola
-Mannoside
␣-Mannoside
:␣
Et2O
A
24, 49
24␣, 30
1.6 : 1
Et2O
A
25, 76
25␣, 15
5.1 : 1
Et2O
A
26, 74
26␣, 11
6.7 : 1
CH2Cl2
B
24, 82
24␣, 11
7.5 : 1
CH2Cl2
B
25, 92
25␣, 7
13.1 : 1
CH2Cl2
B
26, 90
26␣, 0
>25 : 1
Solvent
A, Protocol A: addition of ROH to premixed donor, Tf2O, and DTBMP in ether/benzene; Protocol B, addition of ROH to premixed donor, Tf2O, and DTBMP in CH2Cl2. b All except 26 and 26␣ isolated after treatment of the reacton mixture with TBAF.
Table 2
Coupling of Secondary Acceptors to 22 and 27 in CH2Cl2 Product and yield (%)
-Mannoside
␣-Mannoside
:␣
29, 93
29␣, 5
18.6 : 1
27
31, 90
31␣, 6
15.0 : 1
27
33, 94
33␣, 5
18.8 : 1
27
35, 31
35␣, 8
3.8 : 1a
27
37, 72
37␣, 13
5.5 : 1
27
39, 94
39␣, 3
31.3 : 1
33, 91
33␣, 7
13.0 : 1
Donor
a
Acceptor
The reaction mixture was allowed to come to room temperature and stirred there for 24 h before workup.
Chemistry of Glycosyl Triflates
63
Scheme 9
Scheme 10
With a series of successful couplings in hand, we returned to the question of mechanism and the hypothesis of glycosyl triflates as the key reaction intermediates. A donor 44, lacking any diastereotopic benzyl hydrogens, was prepared and its 1HNMR spectrum recorded in CD2Cl2 in the presence of DTBMP at ⫺78⬚C. Cold (⫺78⬚C) Tf2O was then added, and a rapidly recorded spectrum showed the sulfoxide to have been completely consumed and converted to a new carbohydrate species [32]. This new substance was characterized in the 1H-NMR spectrum by its anomeric proton, a broad singlet, which resonated at ␦ 6.20. In the 13C-NMR spectrum the anomeric carbon had a chemical shift ␦ of 104.6 and a 1JCH coupling of 184.5 Hz. These data indicated that a strongly electron-withdrawing group was covalently linked through oxygen to the ␣ position of the mannopyranose ring, providing strong support for the ␣-mannosyl triflate (45) hypothesis. Confirmatory evidence was obtained when treatment of the mannsoyl bromide 46 with AgOTf and DTBMP in CD2Cl2 gave indistinguishable spectra [32]. This experiment also provided strong support for Schuerch’s earlier hypothesis that glycosyl triflates were formed at low temperature upon treatment of glycosyl halides with AgOTf (see above). Addition of methanol at ⫺78⬚C to these NMR tube experiments resulted in the very rapid formation of mannosides (47) with high -selectivity, in full agreement with the general mechanism proposed (Scheme 11) [32]. A tetra-O-methylmannosyl sulfoxide 48 was prepared as a surrogate for the unselective tetrabenzyl donor 42. Again, low-temperature 1H and 13C NMR experiments indicated clean formation of a covalently oxygen-linked intermediate and, again, the same spectra were obtained going out from the bromide and AgOTf [32]. A first clue to reasons underlying the differing selectivity of the tetramethyl (or benzyl) and 4,6-benzylidene series was obtained in the course of attempts to record a CH-gated, coupled 13C-NMR spectrum of 49. Substantial decomposition occurred
64
Crich
Scheme 11
over the acquisition time, unlike the case of the 4,6-benzylidene donor (44), which prevented us from obtaining the 1JCH coupling constant. This difference in stability was confirmed by a series of variable temperature experiments, which revealed the 4,6-benzylidene protected triflate (45) to decompose around ⫺10⬚C, whereas its tetramethyl congener (49) did so some 20 degrees lower (⫺30⬚C). These latter observations provide strong support for the notion that the ␣/-selectivity in these couplings is a function of the equilibrium between the covalently bound triflate and the ion pair. The less stable the triflate, as reflected in the lower decomposition temperature, the greater the population of the ion pair and the greater the likelihood that ␣-mannosylation will occur through a Curtin–Hammett type of kinetic scheme. The increased stability of the 4,6-benzylidene protected triflates may be rationalized in terms of Fraser-Reid’s concept of a torsionally disarming protecting group [33]. In effect, the sofa conformation of the oxacarbenium ion imposes a twist and torsional strain on the acetal ring, which increases the energy of the oxacarbenium ion with respect to that of the covalently bound triflate. This effect is not present in the perether protected systems.
The basic mechanistic hypothesis (Scheme 8) suggests that the -mannosides are formed in an SN2-like manner from the ␣-triflate. The NMR experiments provide overwhelming support for the formation of these triflates and, in the 4,6-benzylidene series, for their stereochemistry. However, there remains the possibility, which we cannot rule out, that the covalently bound triflates simply serve as a reservoir for the storage of extremely reactive contact ion pairs. In this hypothesis, which echoes that of Schuerch (see above), the ␣-triflate dissociates to a contact ion pair in which the anion is intimately associated with the ␣ face of the oxacarbenium ion and so sterically prevents approach from that face. In this hypothesis, reduced selectivity, as
Chemistry of Glycosyl Triflates
65
Scheme 12
seen with the per-ether protected donors, arises from intervention of solvent and of solvent-separated ion pairs. This hypothesis therefore requires a change in the equilibrium between contact ion pairs and solvent-separated ion pairs in going from the 4,6-benzylidene series to the per-ether protected series. Again we fall back on the extra strain imposed on the oxacarbenium ion by the 4,6-benzylidene group, which will have the effect of shifting the CIP/covalent triflate equilibrium toward the covalently bound species, hence of reducing the likelihood of intervention of a solvent-separated ion pair. This variation of the original mechanism is presented in Scheme 12. Although we have provided compelling evidence for the formation of mannosyl triflates in our system, it is not implied that related triflates are formed in all sulfoxide glycosylation reactions. Indeed, Kahne and his coworkers subsequently investigated the mechanism of their reaction and found that in many cases the original sulfoxide is rearranged to isolable sulfenate esters, which also serve as glycosyl donors as shown, for example, in Scheme 13 [34]. The precise reasons for the different reactivity patterns are not clear and are the subject of ongoing research in our laboratory. In the course of our investigations into the mechanism of the reaction, we became aware of the extreme electrophilicity of the by-product benzenesulfenyl tri-
Scheme 13
66
Crich
Scheme 14
flate (53). As demonstrated by control experiments, this species is itself able to convert glycosyl sulfoxides into glycosyl triflates on a time scale comparable to that of the Tf2O activation (Scheme 14) [32]. Sanxing Sun was so struck by the electrophilicity of PhSOTf that he tested its ability to convert thioglycosides into triflates at ⫺78⬚C. His curiosity was immediately rewarded when low-temperature NMR experiments indeed showed this reagent to cleanly convert a mannosyl thioglycoside (54) into triflate (45) within the space of minutes at ⫺78⬚C (Scheme 15) [27,35]. Sun then went on and provided a series of examples of his new reaction, involving coupling to primary, secondary, and tertiary alcohols as set out in Table 3 [27,35]. The obvious advantage of this new method is that it eliminates the need to oxidize thioglycosides to sulfoxides. The disadvantage is that the reagent has to be freshly prepared in situ from AgOTf and benzenesulfenyl chloride which, itself, has only limited shelf life. In 1997 Gin and coworkers published an intriguing new method for the dehydrative coupling of pyranoses with alcohols in which the pyranose (61) is activated with a mixture of diphenyl sulfoxide and triflic anhydride before addition of the acceptor alcohol, leading to the formation of the coupled product (63) in excellent yield [36]. It was suggested that this chemistry, a development of that of Perlin and Pavia (see above), proceeds via the sulfonylation of the sulfoxide and attack of the pyranose on the so-formed sulfonium salt (62). In a NMR experiment, the mannosyl sulfonium salt (65) has been shown to be stable at low temperature in the absence of nucleophiles (Scheme 16). Indeed, it could even be generated by addition of diphenyl sulfoxide to the corresponding glycosyl triflate (49), which was generated from the fluoride (64) with trimethylsilyl triflate. Glycosyl triflates therefore appear not to be intermediates in this chemistry [37]. IV.
-THIOMANNOSIDES
Thiols are generally regarded as better nucleophiles than alcohols in substitution reactions. Accordingly, Hongmei Li investigated the use of thiols as nucleophiles in
Scheme 15
Chemistry of Glycosyl Triflates
Table 3
67
-Mannoside Formation from Thioglycosides with PhSOTf in CH2Cl2 Product and yield (%)
:␣
26, 95
>25 : 1
55
33, 95
25 : 1
Glycosyl donor
Glycosyl acceptor
(Table 3 continues on p. 68)
our -mannosylation protocol, with the expectation that even higher -selectivity would be observed. This proved to be the case with a range of primary, secondary, and tertiary thiols (Table 4) with no ␣-thiomannoside being detected in any case. The yields, although good, were nevertheless somewhat less than we had typically observed with alcohols [38]. We attribute this phenomenon to the partial capture of the soft nucleophiles by one or other of the several sulfur-based electrophilic byproducts present in the reaction mixture.
Table 3
Continued
Glycosyl donor 55
a
After treatment with TBAF.
Scheme 16 68
Glycosyl acceptor
Product and yield (%)
:␣
60, 90
>25 : 1
26,a 80
10 : 1
Chemistry of Glycosyl Triflates
Table 4 Acceptor
V.
69
Synthesis of -Thiomannosides from Sulfoxide 27 Product
Yield (%)
69
74
70
77
72
54
Acceptor
Product
Yield (%)
74
71
76
63
␣-SELECTIVE MANNOSYLATION REACTIONS
In our continuing search for alternatives to the 4,6-benzylidene protecting group, and for 2,3-protecting groups that will confer enhanced selectivity even in the 4,6-benzylidene series, we have encountered several systems, which, contrary to our initial expectations, were highly ␣-selective. Zongmin Dai, recalling the very early work of Perlin in which the 2,3-O-carbonate was found to be highly -selective when used in the mannosyl bromide/insoluble silver salt method [39], prepared the 2,3-O-carbonate (77) of S-phenyl 4,6-benzylidene-␣-D-mannothiopyranoside and investigated its reaction with 1,2;3,4-diacetone-D-galactose (78) by the benzenesulfenyl triflate method (Scheme 17). She found to her surprise that the only product isolated was the ␣-mannoside 79 [40]. Earlier Sanxing Sun had looked at the use of the 2,3;4,6diacetonide 80 as glycosyl donor in conjunction with methyl 2,3,4-tri-O-acetyl-␣-Dglucpyranoside as acceptor and had obtained a 1:1 ratio of the ␣- and -mannosides [27]. Again, this result was surprising in view of the fact that Garegg had earlier successfully employed the 2,3;4,6-dicyclohexylidene protecting system in the synthesis of -mannosides by the mannosyl bromide/insoluble silver salt method [41].
70
Crich
Scheme 17
We interpret both these results in terms of the general mechanism and the effect of the protecting groups on the covalent triflate/ion pair equilibrium. Thus, the fivemembered cyclic 2,3-O protecting groups lead to considerable flattening of the pyranose ring and so raise the ground state energy of the triflate. The barrier to formation of the flattened oxacarbenium is therefore reduced and the equilibrium shifted more in its favor. This effect is more pronounced in the carbonate than the acetonide, owing to the sp2 nature of the atoms in the bridge, and so leads to higher ␣-selectivity in that case. Zongmin Dai also investigated the use of a 2-O-TBDMS-3-O-benzoyl protected 4,6-O-benzylidene donor (81) but, again, excellent ␣-selectivity was observed [40]. This result must arise from neighboring group participation by the 3-O-benzoate. Models demonstrate that the twist–boat conformation (82) imposed by such participation on the pyranose ring is not unduly straining even though the system is 4,6benzylidene protected.
Weiling Cai prepared and investigated the Ley type [42,43] 3,4-bisacetal protected donor 83 in the expectation that the second ring would serve a similar rigidifying function as the 4,6-benzylidene group. This was not to be the case, and again excellent ␣-selectivity was observed in coupling to a number of acceptors (Table 5) [40].
Chemistry of Glycosyl Triflates
Table 5
71
␣-Mannoside Formation from Thioglycoside 83 with PhSOTf in CH2Cl2
Glycosyl acceptor
Product and yield (%)
␣:
84, 52
>95 : 5
85, 57
>95 : 5
86, 88
>95 : 5
87, 62
>95 : 5
88, 60
>95 : 5
72
Crich
With hindsight this result could have been predicted, inasmuch as Fraser-Reid’s earlier experimental and computational work on the formation of oxacarbenium ions from pentenyl glycosides showed this to be more facile with a six-membered ring bridging the 3- and 4-positions than in the absence of such a ring, and certainly much more facile than in the case of 4,6-benzylidene protected systems [33]. Thus, this system also fits the general mechanistic scheme, with the ␣-selectivity being again due to a shift in the covalent triflate/ion pair equilibrium. Furthermore, the reversal of selectivity seen across the series 4,6-benzylidene/tetrabenzyl/3,4-bisacetal is in full agreement with the increasing stability of the oxacarbenium ions, as predicted computationally by Fraser-Reid in the glucose series [33].
VI.
4,6-BENZYLIDENE PROTECTED GLUCOSYL TRIFLATES
Weiling Cai prepared a 4,6-O-benzylidene-2,3-di-O-benzyl-␣-D-glucopyranosyl thioglycoside 89 and oxidized it to the sulfoxide 90 in the expectation that activation under the standard conditions for -mannosylation would lead to the formation of -glucosides. Low-temperature studies in CD2Cl2 showed that both the sulfoxide and the thioglycoside, upon activation with Tf2O or PhSOTf, respectively, provided the ␣-glucosyl triflate 91 (␦H1 = 6.3; ␦C1 = 100.6; 3JH1,H2 = 3.5 Hz) in high yield (Scheme 18). However, all couplings except that to methanol were highly ␣-selective (Table 6) [44]. It is unlikely that this reversal of selectivity can be explained by reduced stability of the glucosyl triflate: variable temperature NMR studies showed that decomposition of the triflate did not set in until above 0⬚C (i.e., above the decomposition temperature of the corresponding mannosyl triflate). We believe that this result is a function of the differing extent of the anomeric effect in the two series. In effect it is known that the anomeric effect is considerably stronger in mannopyranose than glucopyranose derivatives [45,46]. Thus we suggest that the ␣- and -triflates are in dynamic equilibrium and that the reduced anomeric effect in the glucose series permits a population of the more reactive -triflate sufficient for it to serve as a donor in an SN2-like fashion, with Curtin–Hammett kinetics, leading preferentially to the ␣-glucosides observed. A similar rationale was advanced decades ago by Lemieux
Scheme 18
Chemistry of Glycosyl Triflates
Table 6
73
␣-Glucoside Formation Product and yield (%)
␣:
92, 98
>95 : 5
89
93, 87
>95 : 5
89
94, 70
>95 : 5
89
96, 85
>95 : 5
98, 89
>95 : 5
99, 72
>1 : 7.5
Glucosyl donor
90
Glycosyl acceptor
MeOH
74
Crich
for the formation of ␣-glucosides from ␣-acetobromoglucose in the presence of added bromide ion [45,47]. VII.
SUMMARY
Glycosyl triflates may be prepared rapidly and cleanly at ⫺78⬚C in CH2Cl2 solution from anomeric sulfoxides or thioglycosides upon activation with triflic anhydride or benzenesulfenyl triflate, respectively. These triflates are extremely reactive glycosyl donors and, when applied in conjunction with the 4,6-benzylidene protecting group, provide a very facile entry into the -mannopyranosides. ACKNOWLEDGMENTS I thank the numerous talented students and postdoctorals whose hard work and diligence has contributed, and continues to contribute, to the development of glycosyl triflate chemistry in my laboratory. The National Institutes of Health (GM 57335) are gratefully acknowledged for their support of this work. REFERENCES 1. 2. 3. 4. 5. 6. 7. 8. 9. 10. 11. 12. 13. 14. 15. 16. 17. 18. 19.
20. 21. 22. 23. 24. 25. 26. 27.
B Helferich, R Gootz. Ber Dtsch Chem Ges 62:2788–2792, 1929. FJ Kronzer, C Schuerch. Carbohydr Res 27:379–390, 1973. R Eby, C Schuerch. Carbohydr Res 34:79–90, 1974. V Marousek, TJ Lucas, PE Wheat, C Schuerch. Carbohydr Res 60:85–96, 1978. TJ Lucas, C Schuerch. Carbohydr Res 39:39–45, 1975. VK Srivastava, C Schuerch. Carbohydr Res 79:C13–C16, 1980. VK Srivastava, C Schuerch. J Org Chem 46:1121–1126, 1981. J Leroux, AS Perlin. Carbohydr Res 47:C8–C10, 1976. J Leroux, AS Perlin. Carbohydr Res 67:163–178, 1978. W Szeja, J Bogusiak. Synthesis 224–225, 1988. W Szeja. Synthesis 223–224, 1988. S Koto, N Morishima, S Zen. Carbohydr Res 130:73–83, 1984. N Morishima, S Koto, S Zen. Chem Lett 1039–1040, 1982. S Koto, S Inada, T Yoshida, M Toyama, S Zen. Can J Chem 59:255–259, 1981. S Koto, T Sato, N Morishima, S Zen. Bull Chem Soc Jpn 53:1761–1762, 1980. AA Pavia, JM Rocheville, SN Ung. Carbohydr Res 79:79–89, 1980. JM Lacombe, AA Pavia, JM Rocheville. Can J Chem 59:473–481, 1981. AA Pavia, SN Ung-Chhun. Can J Chem 59:482–489, 1981. F Barresi, O Hindsgaul. Synthesis of -D-mannose containing oligosaccharides. In SH Khan, RA O’Neill, eds. Modern Methods in Carbohydrate Synthesis. Amsterdam: Harwood Academic Publishers, 1996, pp 251–276. J Brunckova, D Crich, Q Yao. Tetrahedron Lett 35:6619–6622, 1994. D Crich, S Sun, J Brunckova. J Org Chem 61:605–615, 1996. D Kahne, S Walker, Y Cheng, DV Engen. J Am Chem Soc 111:6881–6882, 1989. L Yan, D Kahne. J Am Chem Soc 118:9239–9248, 1996. C Thompson, M Ge, D Kahne. J Am Chem Soc 121:1237–1244, 1999. D Crich, J Mataka, S Sun, K-C Lam, AR Rheingold, DJ Wink. J Chem Soc Chem Commun 2763–2764, 1998. D Crich, S Sun. J Org Chem 61:4506–4507, 1996. D Crich, S Sun. Tetrahedron 54:8321–8348, 1998.
Chemistry of Glycosyl Triflates 28. 29. 30. 31. 32. 33. 34. 35. 36. 37. 38. 39. 40. 41. 42. 43. 44. 45. 46.
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D Crich, S Sun. J Org Chem 62:1198–1199, 1997. D Crich, Z Dai. Tetrahedron Lett 53:1681–1684, 1998. D Crich, Z Dai. Tetrahedron 55:1569–1580, 1999. D Crich, GR Barba. Tetrahedron Lett 39:9339–9342, 1998. D Crich, S Sun. J Am Chem Soc 119:11217–11223, 1997. CW Andrews, R Rodebaugh, B Fraser-Reid. J Org Chem 61:5280–5289, 1996. J Gildersleeve, RA Pascal, D Kahne. J Am Chem Soc 120:5961–5969, 1998. D Crich, S Sun. J Am Chem Soc 120:435–436, 1998. BA Garcia, JL Poole, DY Gin. J Am Chem Soc 119:7597–7598, 1997. BA Garcia, DY Gin. J Am Chem Soc 122:4269–4279, 2000. D Crich, H Li. J Org Chem 65:801–805, 2000. PAJ Gorin, AS Perlin. Can J Chem 39:2474–2485, 1961. D Crich, W Cai, Z Dai. J Org. Chem 65:1291–1297, 2000. PJ Garegg, T Iversen, R Johansson. Acta Chem Scand B34:505–508, 1980. A Hense, SV Ley, H Osborn, DR Owen, J-F Poisson, SL Warriner, KE Wesson. J Chem Soc Perkin Trans 1:2023–2031, 1997. J-L Montchamp, F Tian, ME Hart, JW Frost. J Org Chem 61:3897–3900, 1996. D Crich, W Cai. J Org Chem 64:4926–4930, 1999. RU Lemieux, AR Morgan. Can J Chem 43:2214–2221, 1965. RU Lemieux. Rearrangements and isomerizations in carbohydrate chemistry. In P De Mayo, ed. Molecular Rearrangements, Part 2. New York: Wiley Interscience, 1964, pp 709–769. RU Lemieux, KB Hendriks, RV Stick, K James. J Am Chem Soc 97:4056–4062, 1975.
4 C-Glycoside Synthesis: Recent Developments and Current Trends Maarten H. D. Postema and Daniel Calimente Wayne State University, Detroit, Michigan
I.
INTRODUCTION
The chemistry of C-glycoside compounds has been of considerable interest over the last 20 years. This class of compounds is defined as compounds in which the exocyclic oxygen atom of an O-glycoside has been replaced by a carbon atom (Fig. 1). C-Glycosides are not solely man-made, but are the creation of nature, as attested by the occurrence of many C-glycoside natural products. Unlike the corresponding Oglycosides, C-glycosides are unaffected by hydrolytic or enzymatic cleavage and therefore would seem to be ideally suited for use as stable sugar mimics. They possess a level of chemical stability comparable to that of cyclic ethers. Several reviews have appeared on the subject of C-glycoside preparation, as well as two monographs. Many methods for the preparation of both the ␣- and -C-glycosides have been developed, and new approaches are still appearing in the literature. This chapter covers the literature from the end of 1994 to early 1999, with other inclusions as deemed appropriate. Following the organization of earlier work [1], we select the mode reactivity of the anomeric center to define the category. The chapter discusses free radical chemistry, C1 anions, Wittig chemistry–cyclization chemistry, transition metal mediated chemistry, sigmatropic chemistry, and approaches based on cationic chemistry. The chapter focuses on the most recent and novel developments in the field, but all the relevant references are included whenever possible. 77
78
Postema and Calimente
Figure 1
II.
FREE RADICAL APPROACHES
A.
Introduction
The use of free radical chemistry at the anomeric center to produce carbon–carbon bonds, especially in an intramolecular fashion, remains a popular method for Cglycoside synthesis. A review entitled ‘‘C-Glycosidation Technology with Free Radical Reactions’’ appeared in early 1998, and the reader is referred to that source [2] as well as to the more traditional ones for complete overviews on the subject. Again, the coverage here focuses on the most recent developments. B.
Intermolecular Approaches
1.
Anomeric Radicals
Wang has studied the trapping of anomeric pyranosyl radicals with t-butylisocyanide to give anomeric cyanides. The readily available acetylated gluco derivative 1 when exposed to t-butylisocyanide in the presence of AIBN and tris(trimethylsilylsilane), gave a 73% yield of the ␣ isomer 2. Other sugars were examined and gave products with yields in the range of 22–71%, (Scheme 1) [3]. Junker and Fessner examined the addition of anomeric radicals to vinyl phosphonic dialkyl esters to deliver Cglycosyl-phosphonates directly. Thus exposure of 3 to standard radical conditions in the presence of vinyl phosphonic dimethyl ester gave 4 in 31% yield. Several other sugars were examined and generally gave yields of similar magnitude with excellent ␣ : ratios, (Scheme 1) [4].
Scheme 1
C-Glycoside Synthesis
79
Scheme 2
The use and application to C-glycoside preparation of a different radical initiator also have been reported [5]. Schwartz has reported that treatment of glycosyl halides with (Cp2TiCl2)2 leads to glycals, presumably via the anomeric organometallic intermediate 6. However, if the reaction is carried out in the presence of a Michael acceptor, such as MVK, then the initially formed radical can be trapped and undergo carbon–carbon bond formation to give the ␣-C-glycoside 9. Methyl acrylate and acrylonitrile were also examined as radical traps. The product is presumably formed as the titanium enolate 8, which should be useful for further transformations (Scheme 2) [6]. Witzack et al. also carried out the following intermolecular radical addition to the levoglucosenone 11. The addition was highly exo-face selective and product 12 was obtained in 26% yield along with the remainder of product being that of direct reduction of 10, (Scheme 3) [7]. Allylations have continued to serve as useful reactions, and Bertozzi et al., found that radical allylation of the 2-deoxy-2-phthalimido derivatives 13 and 14 gives good to excellent selectivity of the -allylated isomers 15 and 16, (Scheme 4). This is contrasted to allylations of the 2-deoxy-2-acetyl derivative, which gives mainly the ␣ product, which is the normal stereochemical course for additions of these types. Presumably the steric bulk of the phthalimido group plays a role in directing the stereochemistry of the addition [8]. Praly et al. cleverly used radical allylation of sugars to obtain -C-glycosides. Treatment of the 1-bromoglucopyranosyl chloride 18 with tri-n-butylallyltin under photolytic conditions gave the intermediate -allyl compound 19. When 19 was further exposed to standard radical reducing conditions (Bu3SnH, h) the expected -allyl C-glycoside 20 was formed in good yield. Alternatively, 19 could be treated
Scheme 3
80
Postema and Calimente
Scheme 4
Scheme 5
Scheme 6
with DBU in acetonitrile to afford the product of elimination 21 in good yield (Scheme 5). The same chemistry was carried out on the D-manno and D-galacto derivatives which gave the analogous compounds in similar yields [9]. Work by Magnusson dealt with the application of allylic sulfones as radical acceptors for allylic carbon–carbon bond formation at the radical center. Various acceptors were utilized, and the products are shown in Scheme 6 [10]. The Kolbe electrolysis of sugar acids to give radicals and their subsequent trapping with a radical source gave the chain-extended C-glycoside 27 as the major product (Scheme 7). Compounds such as 27 are useful as stable nonionic tensides and are expected to show liquid crystalline properties [11]. 2.
Radical Addition to Sugar Olefins
Vismara, Nicotra, and their colleagues used glycoexenitol, 30 and 32 as radical acceptors in the preparation of precursors for isosteres of glycolipids and glycoproteins. In this case, the formed radical is anomeric, and reduction by tin hydride from the axial direction should then give the -C-glycoside. The additions proceeded cleanly to give only 31 and 33 as the major products of (␣ : = 10:4) noting that the yields
C-Glycoside Synthesis
81
Scheme 7
Scheme 8
Scheme 9
are quantitative when based on the amount of recovered glycoexenitol. Gervay has added thiolacetic acid to 32 to obtain 34 in good yield, (Scheme 8) [12]. Motherwell published the full paper corresponding to his initial work on radical additions to difluoromethylene-linked C-glycosides. Scheme 9 shows an application of the atom transfer work developed by Curran with iodide 34 to give the bis-C,Cdialkylglycoside in fair yield [13]. C.
Intramolecular Approaches
Fraser-Reid has published a full account of his work on serial radical cyclizations with carbohydrates. The example shown (38 → 40, Scheme 10) illustrates the complexity of the frameworks that can be accessed by careful application of this methodology [14]. Work by Beau, Skrydstrup, and their colleagues has focused on the generation of anomeric radicals from anomeric sulfones by treatment with samarium iodide [15]. If a radical trap is present, the second electron transfer to form the C1 anion does not have time to occur to any appreciable extent, and the formed radical can then
82
Postema and Calimente
Scheme 10
be trapped. The trapping with a sugar acetylene to give the ␣-C-glycoside 44 is illustrated in Scheme 11. Hung and Wong used glycosyl phosphates as radical precursors en route to Cglycosides via intramolecular samarium diiodide mediated cyclization as shown in Scheme 11 [16]. Work by Czernecki et al. focused on intramolecular additions of 2deoxy-2-amino sugars. Exposure of the diallylated species 47 to tin hydride in the presence of triethylborane gave compound 48 in 74% yield as the sole product [17]. Lee et al. carried out intramolecular cyclizations to C-glycoside-like structures using aldehydes such as 49. Exposure of 49 to tributyltin hydride and AIBN gave an Ostannyl ketyl intermediate that underwent 5-exo cyclization to give 50 and 51 in a 46:54 ratio in 91% combined yield, (Scheme 11) [18].
Scheme 11
C-Glycoside Synthesis
83
Scheme 12
Although not radical in nature, this class of species is electron deficient and their inclusion here is warranted. Vasella has continued his work on glycosyl carbenes. The carbene generated from 52, when trapped with dimethyl fumarate of Nphenylmaleimide, gave 53 and 54, respectively (Scheme 12) [19]. III.
C1-ANION APPROACHES
A.
Introduction
The chemistry associated with the anomeric center is cationic by nature. One interesting approach to C-glycoside synthesis is to reverse the electronic character of this center from electrophilic to nucleophilic. Hence anions at the anomeric center (glycosyl anions) have now become fairly common in the synthesis of C-glycosides. Of course, one limitation of this method was the presence of heteroatoms at C2, since any discrete anion at C1 would surely cause an elimination reaction to occur and in turn produce the corresponding glycal (55 → 58, Scheme 13). This is in fact a very common way of preparing sugar glycals from sugars. As a consequence of this limitation, the chemistry of 2-deoxy C1 anions (56 → 59) has been extensively explored. An interesting development in this area came with the observation that if the hydroxyl group at O2 is unprotected, deprotonation followed by anion formation at C1 can occur to give species 57, which can go on to react with a suitable electrophile to deliver 60, after workup. It should be noted that a publication dealing with the preparation of anomeric stannanes from 2,3-dihydro-4H-pyran-4-ones has appeared [20]. A related, and important observation was that anomeric organosamarium species possessing a protected oxygen atom at C2 are stable enough to react via the anomeric carbon atom with suitable electrophiles to give access to C-glycosides (61 → 62, Scheme 13) [21]. B.
Dianion Approaches
1.
O2 Sugars
Work by the groups of Vasella and Kessler (Scheme 14) focused on the preparation of dianions from the corresponding 1,2-anhydro sugars. Thus treatment of 63 with Ph3SnLi gave 64 as the major product in 65% yield. Exposure to an excess of nBuLi resulted in formation of dianion 65, which was then quenched with a variety
84
Postema and Calimente
Scheme 13
of electrophiles to give the  isomers (66–69 ) as the major compounds in all cases, attesting to the configurational stability of these anions at low temperature [22]. This strategy was then applied to the preparation of the anomeric  and ␣ acids 72 and 76. The  isomer 72 was prepared by application of the epoxide-opening strategy above, while the ␣ acid 76 was synthesized by using the procedure originally developed by Kessler and coworkers. Once prepared, the acids were coupled with the protected asparagine amino acid 78 to give the unnatural C-glycosylated amino acids 73 and 74 (Scheme 15) [23]. Glycosyl phenyl sulfoxides also serve as a good source of dianions. The ␣sulfoxide was metallated to the dianionic species, treated with a suitable aldehyde to give alcohol 81 and reduced product 82 (Scheme 16) [24]. 2.
2-Deoxyamino Sugars
The Kessler group then investigated the question of whether similar dianion chemistry could be carried out with the corresponding 2-deoxy-2-amino sugars. Accordingly, compound 83 was treated with thionyl chloride to give the intermediate 2-deoxy-2-aminoglucosyl chloride, which was then treated sequentially with n-butyllithium and lithium naphthalenide to give intermediate 84. Quenching with a variety of electrophiles gave modest to good yields of the 2-deoxy-2-amino-␣-C-gly-
Scheme 14
C-Glycoside Synthesis
85
Scheme 15
Scheme 16
Scheme 17
cosides 85 stereoselectively (Scheme 17) [25]. Similar chemistry was also carried out in the galacto series [26]. The corresponding  dianion 84 could be accessed by first converting 83 to the ␣-pyranosyl chloride followed by SN2 displacement with tributylstannyllithium to give 84. Deprotonation and subsequent halogen metal exchange was followed by quenching with various electrophiles to provide the -isomeric C-glycosides 87 [25]. The chemistry was then applied to the preparation of a C-glycoside-based analog of N-glucoaspargine 88 (Scheme 18) [27]. C.
Anomeric Organosamarium Species: O2 Sugars
Work in the area of O2 sugars was spurred by the following observations: upon treatment of 89 with samarium iodide (to obtain an anomeric free radical that would
86
Postema and Calimente
Scheme 18
then cyclize onto the pendant acetylene), three products were obtained. The first, 91, was the expected product of free radical cyclization in 25% yield; the product of elimination 58 (11%) and the product of simple deoxygenation 90 (60%) also were isolated (Scheme 19). This was very surprising, since the elimination product is produced from the organometallic anomeric samarium species that then undergoes a 1,2-elimination, but 90 is derived from protonation of the same intermediate organometallic species! This implies that the organometallic species is stable enough to be deprotonated to give 90 [28]. The workers then took advantage of this reactivity to generate anions at the anomeric center of 2-oxygenated sugars and have succeeded in showing that pyridyl sulfones make excellent precursors for such reactions. When O2 is protected at a tbutyldimethylsilyl ether, acceptable yields of -C-glycosides are obtained from the corresponding -pyridyl sulfone (92 → 93, Scheme 20). When the ␣-manno derivative 94 was used, a good yield of the corresponding ␣-C-glycoside 95 was obtained [15]. The authors attribute the discrepancy in yields to the ability of the manno intermediate to attain a reactive boat conformation that is more stable than the gluco derivative. With anomeric phosphates such as 96 as precursors, Wong has used a similar reaction to prepare ␣-C-manno pyranosides. Good yields of ␣-C-glycosides were obtained (Scheme 20). In the absence of the electrophile, the 1-deoxy sugars were the main products formed. The use of furanoside 98 gave good yields of Cglycoside products [16]. The results were obtained in the gluco series paralleled those of Beau and coworkers. Scheme 21 shows the reaction of the 2-deoxy-2-amino sugar 100 reacting with samarium iodide and cyclohexanone to give the desired C-glycoside 101 as the major compound [29]. When the azide was used in lieu of the protected amine function, only the product of elimination was formed. This indicates a possible complexation between the acetimido oxygen atom (Scheme 21, second equation) and the samarium atom, resulting in stabilization of the ␣-organosamarium species, since normally,
Scheme 19
C-Glycoside Synthesis
87
Scheme 20 anomerization to the more stable -organosamarium species would be expected to take place. In this case the complexation holds the organosamarium intermediate in the ␣ configuration. It may also be possible that a chair flip of 102 occurs to give 103, which can then react via the equatorial direction to ultimately give the ␣-Cglycoside [30]. The same workers applied their methodology to the preparation of a C-glycoside analog of the Tn antigen. The Tn antigen epitope is expressed in over 70%
Scheme 21
88
Postema and Calimente
Scheme 22
of human epithelial cancers. This epitope is a major tumor-associated O-linked glycoprotein. The same antigen has also been identified as a partial structure of the HIV envelope glycoprotein gp120. The workers designed an analog in which the interglycosidic serine oxygen atom was replaced with a methylene group. The anomeric pyridyl sulfone 100 was coupled with aldehyde 104 to give 105 as a mixture of isomers. Radical deoxygenation was followed by standard manipulations to deliver the analog building block 106 (Scheme 22) [31]. Lindhart and coworkers also relied on a samarium-mediated condensation reaction to prepare ␣-C-glycosides related to N-acetylneuraminic acid (Neu5Ac). Neu5Ac is frequently found as the terminating residue of cell surface glycoproteins and glycolipids and is involved in a number of important biological events such as intracellular interactions, adhesion, and aggregation. A stable analog that would be hydrolytically inert was desired, and thus sulfone 109 was exposed to standard samarium iodide conditions (Scheme 23). However, it gave only the net product of reduction 110 [32]. When the same reaction was carried out with pyridyl sulfone 111 in the presence of the shown cyclic ketone, a 90% yield of 112 was obtained. Several other carbonyl compounds were also used as electrophiles with the corresponding pyridyl sulfone and gave good yields of coupled products. However, the reaction did not proceed with hindered carbonyl compounds [32]. Matsuda and coworkers have found that if such 2-keto-thioglycosides are treated with samarium iodide in THF followed by quenching with a carbonyl compound, good yields of C-glycosides are obtained, with the ␣ isomer (114) predominating in a ratio of 9:1 (Scheme 24) [33]. Kocienski et al. showed that the ␣-glycosyl copper(I) compound 115 reacts with the molybdenum complex 116 to give an excellent yield of the allylic ␣-Cglycoside 117 (Scheme 25). The corresponding -glycosyl copper(I) reagent gave a
Scheme 23
C-Glycoside Synthesis
89
Scheme 24
Scheme 25 49% yield of the corresponding -C-glycoside. When the mirror image of the cationic complex was used, the stereochemistry of the newly formed stereogenic center was found to be reversed [34]. IV.
APPROACHES BASED ON WITTIG CHEMISTRY
A.
Introduction
The reaction of sugar lactols with Wittig-type reagents and cyclization to C-glycosides is a traditional method for preparing C-glycosides. This section addresses the reactions of sugar lactones, the Wittig reaction of sugar lactols with unstabilized ylides and their subsequent cyclizations, and reactions of lactols with stabilized ylides and their conversion into C-glycosides. B.
Reaction of Sugar Lactones
Chapleur and coworkers have published a full account on their work dealing with the dichloroolefination of sugar lactones [35]. They found that sugar-based lactones give good yields of dichloroolefins when treated with a carbon tetrachloride-triphenylphosphine reagent combination. Some of the products along with their yields are boxed in Scheme 26. The same group has also found that reaction of certain chloroolefins such as 121 with mCPBA in dichloromethane gives compounds of the general structure 122 [36]. The reaction is thought to proceed via formation from dichloromethane of chlorine radicals that do not undergo addition to chloroolefins, since they are poor radical acceptors, but instead combine to give molecular chlorine that then undergo ionic addition to the double bond to give the observed products.
90
Scheme 26
Postema and Calimente
C-Glycoside Synthesis
91
Scheme 27
The same group also courageously discovered that the reaction of sugar lactones with the stabilized ylide 125 under high-temperature sealed-tube conditions gives good yields of the corresponding Wittig products (Scheme 27)! No mechanistic explanation is offered, but the sealed-tube conditions are crucial for success. No reaction occurs if the products are heated under reflux at similar temperatures under atmospheric pressure [37]. When the same reaction was carried out on sugar lactones that had a judiciously placed free hydroxyl, cyclized structures were obtained. For example, reaction of 126 with 125 gave a 1:1 mixture of 127 and 128. Compound 127 results from Michael addition of the free hydroxyl addition onto the ␣,-unsaturated ester function (Scheme 27) [38]. C.
Wittig Reaction with Unstabilized Ylides Followed by Cyclization
The Wittig reaction of a sugar lactol with an unstabilized ylide to give a hydroxy olefin poised to undergo electrophilic-induced cyclization is a common method for the preparation of C-glycosides. Martin et al. converted 129 to olefin 130 and followed this by inversion and introduction of the nitrogen substituent to give 131. Mercury-induced cyclization was followed by treatment with iodine to give compound 132. Presumably the benzyl carbamate participates to form a new C—O bond during the treatment of the organomercurial intermediate with iodine. Compound 132 could also be debenzylated and treated with base go give 133, the ␣ homoanalog of galactostatin. Alternatively, 132 was transformed into 134, and exposure to potassium carbonate then gave 135, the 1,N-anhydro derivative, a potential inhibitor of both ␣- and -galactosidases, (Scheme 28) [39]. Work from the same group showed that olefin 137, available via Wittig reaction of 136, could be reductively aminated to give a mixture of amines 138 and 139 in a 5:2 ratio (Scheme 29). NIS promoted cyclization of 138, and 139 then gave 140 and 141, respectively, in good yield. Similar chemistry was carried out in the galacto series [40].
92
Postema and Calimente
Scheme 28
Nicotra et al. observed that 144 or 145, obtained by mercury-induced cyclization of 142 and 143, could not be converted to the desired iodo compound 146. The workers had to resort to introducing the 2-deoxynitrogen substituent after the phosphonate had been introduced as shown in Scheme 30. The ketone was converted to an oxime and with diborane gave the gluco isomer 149 in 64% diastereomeric excess [41]. Schmidt et al. also used electrophilic cyclization to gain access to C-glycosides, in this instance to produce 2-deoxy C-aryl glycosides. Known aldehyde 150 was olefinated and gave a mixture of isomeric olefins 151, which were converted to 152 and 153 and separated. Compounds 153a–c and 152c were exposed to NIS in acetonitrile and gave good yields of the  isomers exclusively. Protecting group manipulation and removal of the iodine atom then gave the -C-aryl glycosides 155a–c (Scheme 31) [42]. Work by Tius has shown that the preference for formation of the axial organomercurial is not due solely to coordination of the incoming mercurio species to the C2 oxygen substituent. Oxymercuration of 156, a compound in which there is no C2 substituent, gave a 60:40 ratio of 157 and 158, respectively. Interestingly enough, cyclization of the TBS derivative 159 gave 160 as the exclusive product (Scheme 32). Compound 160 was transformed into the known triacetate 162 by standard methods. The axial OTBS groups and equatorial methyl group are preferred because van der Waals repulsions that occur between the OTBS groups when they are equatorial are of greater energy than the 1,3-diaxial interactions that occur when the groups are disposed axially [43]. Hydroxy olefin 164 was epoxidized with mCPBA to give a mixture of Cglycosides 165 and 166 in the yields shown in Scheme 33. Compound 165 then served as a building block for C-nucleoside synthesis [44]. Two groups reported a novel cyclization reaction when a suitably protected sugar derivative was treated with triflic anhydride in the presence of pyridine. Thus, exposure of 136 to the aforementioned conditions gave an excellent yield of the vinyl C-furanoside 169. Several other sugars were examined, and all gave good yields of the corresponding furanosides. The reaction proceeds via triflation of the free hydroxyl group to give 167, and displacement with the C3 benzyloxy group provided 168, which is then debenzylated to deliver 169 [45,46]. Sharma and coworkers found that exposure of
C-Glycoside Synthesis
Scheme 29
93
94
Postema and Calimente
Scheme 30
alcohol olefins such as 170 to Wacker oxidation conditions gave a good yield of the corresponding keto-furanoside 171 and the C-glycoside 172 in a 4:1 ratio (Scheme 33) [47]. D.
Wittig Reaction with Stabilized Ylides Followed by Cyclization
1.
With Unprotected or Partially Protected Sugars
The situation with stabilized ylides is rather different from that with unstabilized ones because the formed product has the potential to undergo Michael addition to the corresponding C-glycoside. It is not clear what factors control the question of cyclization selectivity, but it is certain that reaction conditions and substrate structure both play an important role for the reaction in question. It has been shown that free sugars can be converted to the free olefins when exposed to stabilized ylides (173 → 174, Scheme 34) [48]. This reaction was later applied by others [49] to the preparation of open-chain sugar ␣,-unsaturated ester derivatives. As shown in the second equation of Scheme 34, compound 175 was then efficiently converted to 177, a compound that has been previously converted to KDO. Demailly and coworkers have shown that when Reformatsky ‘‘type’’ conditions are applied to this mode of bond formation, a preponderance of open-chain com-
Scheme 31
C-Glycoside Synthesis
Scheme 32
Scheme 33
Scheme 34
95
96
Postema and Calimente
Scheme 35
pounds such as 179 can be isolated. These results are contrasted to those obtained when the same conditions were applied to the protected sugar derivatives, in which chelation of the lone free hydroxyl with the ester carbonyl causes a template effect favoring stereoselective cyclization to the -C-glycoside as shown by 181. In the unprotected case, the formed zinc bromide presumably ties up two vicinal hydroxyl groups, thereby disfavoring cyclization to the C-glycoside (Scheme 35) [50]. 2.
With Protected Sugars
Similar chemistry was applied to the protected glucosamine derivative 183, and the -C-glycoside compound 184 was produced in 50% yield (Scheme 36) [51]. Murai and coworkers used the Wittig reaction on a protected aldehyde to give the Z-olefin in 78% yield along with 15% of the E-olefin after acid-catalyzed deprotection of the acetal. Exposure to base then gave the C-glycoside derivative 187, along with some dimer in 92% combined yield (Scheme 37) [52]. The thioamidephosphonate was reacted with the manno derivative 188 and gave a good yield of C-glycoside 189 (␣ : ratio of 21:78). Compound 189 was then converted into the glycine-C-glycosyl compound 190 (Scheme 37) [53]. Davis and coworkers carried out a Wittig–cyclization sequence with the partially protected 2-deoxyamino sugar 191 using an amino acid based phosphonate. Reaction of 191 with the cesium enolate 192 gave a 53% yield of epimers 193 and 194 (1:1 ratio) in which epimerization of the 2-amino group had taken place. The manno isomer 194 was then epimerized to the more stable gluco 193 derivative by simple treatment with t-BuOLi in methanol (Scheme 38) [54].
Scheme 36
C-Glycoside Synthesis
97
Scheme 37
Scheme 38
V.
TRANSITION METAL MEDIATED APPROACHES TO C-GLYCOSIDES
A.
Introduction
Several years ago transition metal mediated reactions in the area of C-glycoside synthesis were primarily limited to palladium and to a lesser extent nickel and manganese. Over the last few years several other metals, including chromium, molybdenum, tungsten, cobalt, and rhodium, have been utilized in C-glycoside synthesis. This section discusses the chemistry of palladium, which is divided into Stille-type couplings and -allyl complexes. This is followed by considerations of the chemistry of chromium and the above-listed metals. A review by Frappa and Sinou entitled ‘‘Transition Metal Catalysed Functionalization at the Anomeric Center of Carbohydrates’’ appeared in early 1997 [55]. B.
Use of Palladium
1.
Cross-Coupling Reactions
Falck et al. used the anomeric stannane 195 under palladium/copper-mediated coupling conditions with phenyl chlorothionoformate and ethyl chlorothiolformate to deliver 196 and 197, respectively. Coupling with benzoyl chloride proved sluggish and gave only low yields of the desired C-glycosides [56]. Work from the same group relied on a similar reaction as the key step in the short synthesis of the cytotoxic natural product (⫹)-goniofufurone (202). Compound 199 (available in one
98
Postema and Calimente
step from commercial D-glucurono-6,3-lactone) was converted to 200 in eight steps, and exposure to the proper conditions gave a 60–65% yield of product 201. Selective reduction and deprotection completed the sequence to provide natural 202 (Scheme 39) [57]. Snieckus has used his lithiation methodology in tandem with Suzuki–Miyama cross-couplings to produce C-glycoside-like structures. Vinyl iodide 204 was coupled with a variety of aryl boronic acids to give the corresponding aryl derivatives 205– 208 in excellent yield [58]. In work directed at synthesizing the core of the papulacandin natural products, Brimble and Chan carried out a Suzuki coupling of the boronic acid 211 with the iodo glycal 212 and obtained a 25% yield of the desired product 213, along with large amounts of the product of protiodeboronation. The use of the Stille reaction (both with and without copper as cocatalyst) for the coupling of 210 and 212 gave only 11% of the same desired product 213 (Scheme 40) [59]. Work from the same group addressing a Stille approach to C-glycoside derivatives of kalafungin has been published [60]. Lowary, Bock, and coworkers have prepared carbon-linked glycopeptides, such as 216, via Sonogashira coupling of glycosyl acetylene 214 and aromatic iodide 215 (Scheme 41) [61]. 2.
-Allyl Complexes
Sinou and coworkers published a full account of their work on the synthesis of 2,3unsaturated aryl C-glycosides via -allyl-type methodology [62]. They showed that the reaction of aryl Grignard reagents with 217␣ under transition metal catalysis leads to either the ␣- or -C-glycoside in good yield. When palladium is used as the metal, -allyl complex formation is followed by intermolecular attack of the Grignard reagent from the bottom ␣ face, leading to 220, the product of net retention. A complementary approach involves the use of nickel catalysis to give the product of net inversion. In this case transmetallation of the -allyl intermediate with the Grignard reagent gives 221 and reductive syn elimination then delivers 222. As far as catalyst choice is concerned, the catalysts PdCl2(dppf ) and NiCl2(dppe) gave the best results. Numerous Grignard reagents were also examined as part of this work (Scheme 42). Daves has continued his work directed at using palladium-mediated processes to achieve C-nucleoside synthesis. Coupling of iodide 223 with glycal 224 gave a good yield of adduct 225, which was subsequently desilylated and oxidized to furnish 226. The coupling of several other iodides and glycals was also examined [63]. A Spanish group recently employed -allyl chemistry to prepare a potentially useful anti-HIV agent. Olefin 227 was treated with two of 1,3-diketones (R = Me, Ph) to give the diketo-2,3-unsaturated C-glycosides 228. Condensation with a variety of hydrazine derivatives then gave access to a small library of 2⬘,3⬘-unsaturated pyrazole C-glycosides 229a–j (Scheme 43) [64]. Exposure of 230 and 231 to diethyl allylmalonate in the presence of sodium hydride and tetrakis(triphenylphosphine)palladium in tetrahydrofuran gave C-glycosides 232 and 233, respectively, in good yield (Scheme 44). Metallo-ene cyclization of both 232 and 233 gave the same cis product of cyclization 234 in 83–89% yield [65]. Genet has used -allyl chemistry to extend the chain of a preexisting C-glycoside. The example shown in Scheme 44 is illustrative. Exposure of 235 (available from the corresponding -glycosyl aldehyde by condensation with vinyl magnesium
C-Glycoside Synthesis
Scheme 39
99
100
Postema and Calimente
Scheme 40
Scheme 41
Scheme 42
bromide followed by acylation) to Pd(dppe)2 and sodio malonate gave the chainextended C-glycoside derivative 236 in 71% yield. Several other examples were studied and gave comparable yields of C-glycoside products [66]. C.
Use of Cobalt
Luengo and Gleason utilized Murai’s cobalt chemistry to produce the equatorial Cglycoside 238 in 85% yield, followed by desilylation and conversion of 239 to 241. The final step, standard coupling, then gave 244 the potential GDP-fucose inhibitor (Scheme 45). Several other analogs were also prepared [67].
C-Glycoside Synthesis
Scheme 43
Scheme 44
Scheme 45
101
102
Postema and Calimente
Scheme 46
Photolysis of the anomeric cobaloxime 245 in the presence of maleic anhydride and PhSSPh gave 246 in 46% yield. The reaction proceeds via radical intermediates and the formed ␣-carbonyl radical is trapped with PhSSPh to give the formed adducts. Then syn--H elimination led to 247 in quantitative yield (Scheme 46) [68]. D.
Use of Rhodium
McDonald et al. used a rhodium-catalyzed cyclotrimerization reaction to gain access to aryl C-glycosides (Scheme 47). Their work began with the conversion of lactone 248 to alkynyl glycal 249 by standard methods. Exposure of 249 or 251 to 254 in the presence of ClRh(Ph3P)3 in protic solvent furnished the product glycals 252 and 253, respectively, in the indicated yields [69]. Dialkyne 255 was also subjected to similar conditions and gave C-aryl spiroglycoside 257, a compound structurally related to the papulacandin natural products. E.
Chromium, Tungsten, and Molybdenum
Do¨tz and coworkers prepared several interesting and novel glycosylidene carbenes (259–261 ) by reaction of lithiated glycal 258 with the appropriate metal carbonyl derivative. The synthetic utility of the formed carbenes was demonstrated by reaction with 3-hexyne to give a mixture of complexed and uncomplexed adducts 262 and 263, respectively. The anomeric chromium carbene 264 was converted to 265 by exposure to ethoxy ethyne (Scheme 48) [70]. The same workers have carried out a similar chromium-mediated benzannulation (266 → 268), this time with the chromium on the aromatic fragment [71]. Other sugar-based carbenes have also been prepared [72]. Postema and coworkers have used ring-closing metathesis to prepare C1-glycals, compounds convertible to C-glycosides (Scheme 49). The sequence is both general and convergent. Ester formation (269 → 270) is followed by methylenation to give 271, and ring-closing metathesis is then carried out with the Schrock catalyst 272 to deliver the generic C1-glycal 273. The reaction tolerates alkyl and aryl groups at the anomeric center. Very hindered groups (R = t-Bu) were not good substrates because the methylenation step did not proceed in good yield. This was presumably due to the steric hindrance [73]. The chemistry has been extended to the preparation of a number 1,6-linked C-disaccharides. The conversion of 274 to 277 exemplifies the strength and versatility of this approach to C-glycoside synthesis. Compound 277 was converted to the 2-deoxy -C-disaccharide and also to the -C-disaccharide by standard methods (not shown). A small library of glycal C-disaccharides was prepared by use of this novel methodology [74].
C-Glycoside Synthesis
Scheme 47
103
104
Postema and Calimente
Scheme 48
Scheme 49
VI.
SIGMATROPIC APPROACHES
A.
Introduction
This section focuses on the use of concerted processes in the preparation of Cglycosides. The topics covered are cycloaddition reactions and Wittig rearrangements as approaches to C-glycoside synthesis. B.
Cycloaddition Approaches
1.
Diels–Alder
Several types of Diels–Alder reactions have been applied to the preparation of Cglycosides. Some of these include approaches to prepare the sugar ring or to append
C-Glycoside Synthesis
105
Scheme 50
a ring on an existing C-glycosyl derivative. Dipolar cycloadditions have also been utilized. (a) From Sugar Dienes or Glycals. Lubineau et al. reported an aqueous Diels– Alder approach to the trehalo derivative 281. Cycloaddition of 279 in water at 140⬚C gave a mixture of four isomers, of which the major compound, 280a, was separated, debenzoylated, and reduced to give 281. Compound 281 showed only modest activity (IC50 = 47 mM) as an inhibitor or porcine kidney trehalase (Km = 3 mM) (Scheme 50) [75]. In attempting to prepare sugar-based radical acceptors, Martin and Xie found that treatment of 282 with base to generate enone 283 gave instead the dimerized product 284; the result of a [4⫹2] cycloaddition reaction. Compound 283 was never isolated from the reaction mixture (Scheme 51) [76]. Quayle and coworkers used a Stille coupling approach to prepare a number of sugar-based dienes that then under-
Scheme 51
106
Postema and Calimente
Scheme 52
went a facile cycloaddition reaction with Cookson’s reagent 287 to give good yields of the cycloadducts. The reaction shown in Scheme 51 is illustrative [77]. Work in this area has also been carried out with noncyclic carbohydrates. Reaction of the nitro sugar 289 with cyclopentanedienone gave a mixture of 291 and 290 in a 1.9:1 ratio (Scheme 52) [78]. Dondoni used his masked formyl derivative in a hetero-Diels–Alder approach to carbon-linked disaccharides. Cycloaddition of 293 with ethyl vinyl ether gave a mixture of isomers; the major compound, 294, is shown in Scheme 52. The cycloadduct was then converted to 295 via standard methods [79]. (b) De Novo Ring Formation. Varelis and Johnson utilized a hetero-Diels–Alder reaction to prepare the pyran ring system 300. The olefin diastereomers were separated, and reduction followed by acetylation gave 298. Ireland ester rearrangement of 299 proceeded with syn selectivity to deliver the 1,6-dialkyl C-glycoside-like structure 300 (Scheme 53) [80]. Hanna and coworkers used a [2⫹2] cycloaddition approach for the preparation of precursor en route to forskolin. Dichloroketene cycloaddition with glycal 301 was followed by reductive dechlorination to give 302 in 80% overall yield. Several steps were required to convert 302 into the forskolin (304) Diels–Alder precursor 303 (Scheme 54) [81]. (c) Other Cycloadditions. Holzapfel and van der Merwe utilized a palladium-mediated [3⫹2] cycloaddition of nitroglycal 305 to deliver the C-glycosides 306 and 307 in a 1:2.4 ratio (Scheme 55) [82]. The 1,3-dipolar nitrone cycloaddition has also been employed for the preparation of pseudo-aza-C-disaccharides from glycals. Ex-
C-Glycoside Synthesis
Scheme 53
Scheme 54
107
Scheme 55
108
Postema and Calimente
posure of nitrone 308 to 3 equiv of glucal 309 in toluene at 100⬚C for 3 days gave a 61% yield of the adduct 310. The protecting groups were removed by standard methods to yield an intermediate polyol and cleavage of the N—O bond then delivered to the target compound 311 (48% over four steps; Scheme 55) [83]. 2.
Wittig Rearrangements
In 1997 Nakai and coworkers wrote a mini-review on the general area of subject of Wittig rearrangements [84]. Scheme 56 shows an application of the Wittig rearrangement (312 → 313) with a benzyl ether used as the starting material. Scheme 56 also illustrates the use of the propargylic substrates 314 and 317. The rearrangement proceeds with retention of configuration. This high selectivity is attributed to the tightly bound lithium-coordinated transition state, as in 315 [85]. Nakai has also employed the Wittig rearrangement in the preparation of the zaragozic acid core (319 → 320, Scheme 57). This work disclosed a violation of the principle of retention of configuration: when 321 was treated with butyllithium, a product with a net inversion of configuration at the anomeric center 322 was obtained. The authors suggest that steric hindrance of the groups on the ring caused radical recombination to occur from the less hindered bottom ␣ face (Scheme 57) [86]. VII. A.
CATIONIC APPROACHES Introduction
This section, the largest of the entire chapter in terms of number of citations, relies on the natural mode of reactivity at the anomeric center. Because of the large number of references, only an overview is presented here. Relevant references are included
Scheme 56
C-Glycoside Synthesis
109
Scheme 57
whenever possible. The section is divided into the formation of C-glycosides from reaction of glycals and 1,2-anhydro sugars, heteroatomic glycosyl derivatives, and sugar lactones with various nucleophiles. Section VII.E deals with the preparation of aryl C-glycosides. B.
Use of Glycals
1.
Reaction Under Lewis Acid Catalysis
The reaction of glycals with allylsilanes, enol ethers, or silyl acetylenes has received considerable attention over recent years. In 1996 Toshima et al. employed environmentally friendly montmorillonite K-10 (clay) to catalyze the addition of allylsilanes to sugar glycals for the purpose of obtaining allyl C-glycosides. Reaction of the galactal derivative 323 as shown in Scheme 58 gave a good yield of the ␣- and allyl C-glycosides, with the 324 as the major isomer [87]. Work from the same group has also shown that the glycal does not have to be protected for the allylation to work, at least with conventional Lewis acid catalysts. This is exemplified by the conversion of 325 to 326 (Scheme 58) [88].
Scheme 58
110
Postema and Calimente
Scheme 59
Panek and Schaus continued their work with crotyl silanes and their addition to glycals (319 → 320) as shown in Scheme 59 [89]. Grieco et al. utilized [LiCo(B9C2H11)2] as a catalyst for the condensation of an allylic acetate with glycal 331 to give the C-glycosides 332. The use of this catalyst is interesting because it mimics the effect of highly polar media (5 M LiClO4 in Et2O) for reactions of these types [90]. Portella et al. showed that the acylsilanes and the glycal 309, in the presence of CF3SiMe3 and TBAF, react to give the C-glycosides 334 as a mixture of anomers [91]. Hayashi et al. cyanated (335 → 336) unprotected glycals in the presence of a catalytic amount of palladium(II) acetate (Scheme 59) [92]. Csuk et al. also examined some reactions of various glycals with a hindered silyl enol ether under Lewis acid catalyzed conditions (not shown) [93]. Isobe has continued his explorations of the reactivity of silyl acetylenes with glycals. The sugar-based acetylene 338 is condensed with glycal 337 to give the disaccharide 339 [94]. This area was reviewed in 1998 [95]. Steel et al. used actinium perchlorate to catalyze the dimerization of glucal. Three products were isolated in the yields shown. Separate treatment of 342 with boron trifuluoride etherate and triethylsilane then gave 343 in good yield (Scheme 60) [96]. 2.
With ‘‘Organometallic’’ Nucleophiles
Dorgan and Jackson [97] extended the work of Thorn and Gallagher [98], reaction of organozinc with glycals to give the corresponding C1 enitols (309 → 344), to the synthesis of C-linked glycosyl amino acids. This is exemplified by the conversion of 309 to 347 (Scheme 61). It has been reported that the glycal 348 undergoes cyclopropanation to give 349 or 350 as the major products, depending on the choice of reagent [99]. Treatment of 348 with ethyl diazoacetate in the presence of rhodium diacetate gave a 59% yield
C-Glycoside Synthesis
Scheme 60
111
112
Postema and Calimente
Scheme 61
of the ester cyclopropane 351 [100]. Hoberg and Claffey showed that treatment of the related glycal 352 under similar conditions gave 353 as the major product in 87% yield, with only trace amounts of the other three possible isomers (Scheme 62) [101]. The formed cyclopropanes have proved to be useful in several cases. For instance, 350 has been ring-expanded to the bicyclo olefin 354 by exposure to TMSOTf [102]. Compound 355 was also found to undergo ring opening to the dihalide 356, albeit in low yield [101]. In addition, 351 was converted to the Fuc-GDP analog 357, a potential transition state based inhibitor (Scheme 63) [103]. Van Boom and Sinay¨ have collaborated to show that the reaction of acetylides with 1,2-anhydro sugars under the influence of zinc chloride catalysis gives the ␣ isomer as the major product. Accordingly, reaction of 358 and 359 under the aforementioned conditions gave 360 in good yield. Standard protecting group manipulations then gave the C-disaccharide 361. The reaction is postulated to proceed via intermediate C [104]. Evans and coworkers have found that allylstannanes serve as good nucleophiles for oxirane opening of the 1,2-anhydro sugars under Lewis acid catalysis. Treatment of 358 with either 362 or 363 in the presence of tributyltin triflate gave good yields of the corresponding -allyl-C-glycosides 364 and 365 (Scheme 64) [105].
Scheme 62
C-Glycoside Synthesis
113
Scheme 63
Scheme 64
Gervay et al. reported reduction of the diastereomeric epoxides, giving regioisomeric mixtures of alcohols (369 and 370) (Scheme 65) [106]. Related work (not shown) has been reported by Panza et al. [107]. C.
Use of Lactones with Organometallic-Based Nucleophiles
Dondoni and Scherrmann published a full account of their thiazole-based approach to formyl C-glycosides. Addition of the thiazololithio species to lactone 371 gave
114
Postema and Calimente
Scheme 65 the ␣-C-glycoside 372 as the major product. Reduction under standard conditions followed reduction–epimerization, and demasking of the protected aldehyde group then gave 373 (Scheme 66) [108]. Geneˆt et al. used a similar protocol to access C-glycosyl aldehydes. Both the dithiane group (375 → 377) and an acetylene (378 → 377) served well as masked aldehyde equivalents (Scheme 66) [109]. Heterocyclic nucleophiles have also been utilized with pyranose sugars to prepare potential glucosidase inhibitors. In the case shown in Scheme 67, Lewis acid mediated silane reduction did not work owing to chelation of the Lewis acid with the imidazole group, and a slightly longer route was required to effect the reduction [110]. Epoxide alkyl -C-glycosides, potential inhibitors of -glucan hydrolases, have also been prepared from sugar lactones (374 → 377) [111]. The reaction of 2-deoxy-2-azido sugar lactones seems to parallel the reactivity of the corresponding 2-oxygenated lactones as shown for the conversion of 389 to 392 (Scheme 68) [112]. Martin and Saavedra utilized a conceptually related approach, the reduction of hemiacetals to give -alkyl products, in the preparation of aza sugar analogs. Addition of (methoxymethoxy)methyllithium to lactone 374 gave 394, and this was followed by conversion to diketone 395. Reductive amination then furnished the protected C-aza sugar 396 (Scheme 68) [113]. Wightman et al. showed that in furanose sugars, reduction of C-glycoside lactols gives 1,2-anti products predominantly. It seems that silane reduction occurs preferentially from the same face as the vicinal oxygen substituent (Scheme 69) [114]. The reaction of enolates with lactones has also been carried out to give chainextended sugars. Three approaches have been published, two on samarium diiodide mediated chemistry [115,116] and one on classical Claisen-type chemistry [117]. Representative examples are shown in Scheme 70. D.
Use of Glycosyl Halides, S-Glycosides, Lactols, and O-Glycosides
1.
Glycosyl Halides
Glycosyl halides are popular electrophilic coupling partners for C-glycoside synthesis. The area of ␣-monohalo ethers in synthesis has been reviewed [118]. Heteroatoms at the 2-position have been well tolerated, as can be seen from the examples shown in Scheme 71. Alkylation of 407 with the potassium salt of diethylmalonate
C-Glycoside Synthesis
Scheme 66
115
116
Scheme 67
Scheme 68
Scheme 69
Postema and Calimente
C-Glycoside Synthesis
117
Scheme 70
Scheme 71
gave the -C-glycoside 408 after decarboxylation [119]. Under the influence of silver ion, the displacement of the anomeric bromide in 410 with the tin acetylide shown, gave the the ␣ product 411 exclusively. Here, the stereochemical outcome is rationalized on the basis of attack of the formed oxonium from the ␣ face under the influence of the anomeric effect [120]. Similar chemistry has also been carried out
118
Postema and Calimente
Scheme 72
on the 2-oxygenated compounds. Aza sugars have also been found to be reactive toward electrophilic C-glycosidation upon conversion to the anomeric fluorides. Several nucleophiles were examined, and Scheme 71 shows the allylation and reaction with silyl enol ethers of 413 [121]. Veyrie`res et al. found that the allylsilane 417 reacts with a variety of pyranose derivatives to give good yields of allylated and functionalized C-glycosides (Scheme 72) [122]. 2-Thioglycosyl chlorides, derived from ionic addition of RSCl to glycals, have been found to react with Grignard reagents to give the -gluco C-glycosides 426. The same chlorides also react with silyl enol ethers and allyltrimethylsilane to give the corresponding C-glycosides, 425 (Scheme 73) [123,124]. Intramolecular C-glycosidations have also been explored. For example, exposure of 427 to AgBF4 with strict exclusion of water gave a 74% yield of 428. The benzylic positions were oxidized to furnish 429, and ester cleavage then gave the free C-glycoside 430 (Scheme 74) [125]. Lo´pez and Go´mez found that treatment of pyranosyl chlorides with a suitable organolithium gave acceptable yields of the corresponding C1-glycals 432–434 (Scheme 75). No mechanistic explanation was offered. One possibility could be elimination of the benzyloxy group to generate the C1-chloro glycal, followed by addition of the organometallic to the double bond at C1 and subsequent elimination of chloride [126].
Scheme 73
C-Glycoside Synthesis
119
Scheme 74
Scheme 75
2.
Thioglycosides
Thioglycosides have received some attention over the last few years. The ethyl thioglycoside 435 has been found to be a good substrate for the selective formation of the ␣-glycosyl cyanide 436 (Scheme 76) [127]. Craig has continued his work on template directed C-glycosidations. Work directed at the C-glycosidation of 437, shown in Scheme 77 [128], is highlighted by the preparation of 2,3-dideoxy-D-manno-2-octulopyranosonic acid (444). Accordingly, thioglycoside 437 was exposed to AgOTf and gave the cis-fused C-glycoside 438 in 64% yield. Oxidative cleavage followed by reduction led to 442, which was desulfonylated to give the fragmentation product 443. Standard manipulations then afforded the target acid 444 [129]. 3.
Anomeric Acetates and Imidates
The formate group has been used at the anomeric center to install acetylenic moieties (445 → 446, Scheme 78) [130], while an acetate function served admirably as the activating function on a tetrahydropyran ring to install an allyl group in the synthesis of the F-ring 448 of the spongistatins. The TBS groups were first replaced with acetates to ensure -C-glycosidation [131]. C-Glycosidation of furanosyl acetates is still a popular method for introduction of carbon-based groups at the anomeric center. Scheme 79 shows some recent examples. The entries highlight the use of a diethylthiocarbamoyl function as a partic-
Scheme 76
120
Postema and Calimente
Scheme 77
ipating group to control the facial selectivity of C-glycosidation [132]. This is significant, since the lack of a group at C2 hinders stereocontrol in the 2-deoxyribofuranosides [133]. It has also been found that scandium perchlorate serves as a good catalyst for the selective ␣-C-glycosidation of perbenzylated ribofuranosyl acetates [134]. Heteroatom-based siloxy dienes have received attention in recent years as an efficient method for building up ring frameworks. The subject has been reviewed, and only a few applications are illustrated here [135]. This is a powerful process, since in a relatively small number of steps several rings can be joined together. The first two equations [136,137] of Scheme 80 show how a single butenolide unit can be attached, while the last sequence illustrates an iterative methodology [138]. It should be noted that in the addition of trimethylsiloxy furan to the anomeric acetate,
Scheme 78
C-Glycoside Synthesis
121
Scheme 79
a mixture of four compounds is possible. Usually the erythro product 463 was obtained in a 6:4 ratio. The two examples in Scheme 81 illustrate the use of a cyclic enol ether reacting with anomeric acetate 467 to give 468 [139], as well as the reaction of an olefin with the same acetate to give the novel ring-fused product 469 [140]. The final example demonstrates the use of amino acid derived enol ether 470 reacting with a glycosyl imidate 469 under Lewis acid catalysis to give a low yield of the carbon-linked threonine isostere 471 (Scheme 82) [141].
Scheme 80
122
Postema and Calimente
Scheme 81
Scheme 82
4.
Lactols
There are two reports of the use of lactols as precursors to C-glycosides. Wang and Gross found that when triol 472 was treated with nitroethane under the outlined conditions, a 50% yield of the C-glycoside 473 was obtained as the major product [142]. D-Glucose (474) was found to undergo condensation with the barbituric acid derivative 475 to afford 476. Alkylation then gave the C-glycosyl derivative 477 (Scheme 83) [143]. 5.
Alkyl Glycosides
During their synthesis of the F-ring (480) of halichondrin B, Yonemitsu and coworkers relied on allylation of the methyl glycoside derivative 478 to deliver 479, which was converted to the target (Scheme 84) [144]. Johnson has carried out a
Scheme 83
C-Glycoside Synthesis
123
Scheme 84
highly selective allylation on the nojirimycin analog 481 to provide 482, which was then converted to the indolizine analog 438 (Scheme 84) [145]. Schmidt converted the TCP-protected glucosamine derivative to 484 via a cationic allylation reaction. Compound 485 was then converted to the amino acid analog 486. The -selective allylation is noteworthy and is presumably due to the steric bulk of the phthalidebased amino protecting group, (Scheme 84) [146]. Ley et al. found that exposure 487 to stannic chloride furnished a good yield of the disaccharide derivative 488 as a 1:1 mixture of isomers (Scheme 84) [147]. Two groups have prepared C-glycoside analogs of the natural product (⫹)hydantocidin via Lewis acid mediated C-glycosidation of the acetal derivative 489 [148]. Sano and coworkers succeeded in converting 490 to the succinimide analog 493 (Scheme 85) [149]. A synthesis of the spirohydrouracil nucleoside analog of (⫹)-hydantocidin has also appeared [150]. E.
Aryl C-Glycosides
1.
Lewis Acid Monoarylation
Several different catalyst systems, anomeric activators, and applications of Lewis acid catalyzed reactions for aryl C-glycoside synthesis have been published over recent years and a few are presented in Scheme 86. Inazu et al. used the dimethylphosphinothioate groups [151], while Satoh et al. introduced the use of AgOTfa/ SnCl4 as a novel catalyst system [152]. Schmidt et al. continued the use of the trichloroacetimidate group, this time directed at the preparation of bis(C-glycosyl) flavanoid precursors [153]. Sato’s group has also used glycosyl fluorides to prepare precursors for C-glycosyl flavanoids (Scheme 86) [154]. Mallareddy and Rao prepared analogs of monocerin via intramolecular aryl C-glycosidation, (Scheme 86)
124
Scheme 85
Scheme 86
Postema and Calimente
C-Glycoside Synthesis
125
Scheme 87
[155]. Andrews and Larsen also carried out Lewis acid catalyzed glycosidations of naphthalene derivatives with anomeric acetates to gain access to the ring systems of the Angucycline antibiotics [156]. Suzuki has also published an account of his work on novel Lewis acid catalysts in organic synthesis [157]. Toshima et al. found that unprotected 2-deoxy sugars, as either reducing sugars or methyl glycosides, will undergo C-glycosidation to give aryl C-glycosides [158]. The reaction has been catalyzed by TMSOTf, and it has also been found that montmorillonite K-10, used in excess, also works with unprotected sugars (Scheme 87) [159]. Work by Park et al. deals with regioselective acylation of the 2⬘-hydroxyl group on a free aloesin glucopyranoside (not shown) [160]. The normal course for these O → C-glycoside rearrangement is to deliver the  or equatorial product preferentially. Suzuki et al. found that if O4 and O3 are protected by extremely bulky groups, such as t-butyldiphenylsilyl, the ␣ anomer is the major product of the reaction. This result is contrasted to the case of the use of smaller groups, such as TBS groups, which produces ony the  isomer (Scheme 88). So the stereochemistry of the glycosidation can be controlled by judicious choice of protecting groups [161]. 2.
Lewis Acid Mediated Diarylation
A few groups have carried out multiple arylation reactions to give bis-C-glycosyl compounds (Scheme 89). Schmidt et al. used their trichloroacetimidate methodology
Scheme 88
126
Scheme 89
Postema and Calimente
C-Glycoside Synthesis
127
Scheme 90
in a sequential process to deliver 522 [153]. Kumazawa et al. employed anomeric fluorides under boron trifluoride catalysis to give the corresponding bis-C-glycosyl flavanoid precursor 526 [162]. Satoh, using his SnCl4 /AgOTfa catalyst system, was able to introduce a second sugar unit onto an existing aryl C-glycoside (Scheme 90) [163]. VIII.
SUMMARY
This chapter provides an updated overview of recent developments in the synthesis of C-glycoside compounds. The stereoselectivity of the C-glycosidation step has improved over recent years, and milder conditions for C—C bond formation are still being developed. The use of unprotected C-glycosides is another important advance that has recently come to fruition [164]. Also the use of modern methods based on metals seems to be increasing in popularity. REFERENCES 1. 2. 3. 4. 5. 6. 7. 8. 9. 10. 11. 12. 13. 14. 15. 16. 17. 18. 19.
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5 D-Arabinofuranosides
from Mycobacteria: Synthesis and Conformation Todd L. Lowary The Ohio State University, Columbus, Ohio
I.
INTRODUCTION
Unlike the majority of monosaccharides, the pentose arabinose exists in nature in all possible absolute and ring configurations, namely, D-arabinofuranose (D-Araf ), L-arabinofuranose (L-Araf ), L-arabinopyranose (L-Arap), and D-arabinopyranose (DArap). The pyranose forms are more rare and are found primarily either in protozoan parasites [1] or as constituents of plant saponins [2]. Oligo- and polysaccharides comprised of L-arabinofuranose are also widespread in the plant kingdom, where they are present as constituents of arabinoxylans [3], pectins [4], and hydroxyprolinerich glycoproteins (HPRGs) [5]. This chapter focuses on polysaccharides containing D-arabinofuranose and in particular the most prominent examples of these polymers, which are found as important components of the cell wall of members of the Actinomycetes family including the genera Mycobacteria, Corynebacteria, Nocardia, and Rhodococcus [6]. Although the majority of actinomycetes are benign to humans, among them are two important human pathogens, Mycobacterium tuberculosis and Mycobacterium leprae [7]. Infection by these organisms causes, respectively, tuberculosis and leprosy. Mycobacterial infections have attracted renewed attention in recent years owing to their increasing incidence in the industrialized world as well as the emergence of drug-resistant strains of these organisms [8]. Additionally, AIDS patients and others with compromised immune systems are susceptible to opportunistic infections caused by ‘‘atypical’’ mycobacteria including M. avium and M. kansasii [9]. 133
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The total number of people infected with M. tuberculosis has been estimated at a third of the world’s population and almost 3 million deaths from tuberculosis occur each year, making it the single most lethal bacterial disease [10]. Treating mycobacterial infections is difficult and usually requires a 6–12 month course of antibiotic therapy [11]. The need for antibiotics over an extended period is due largely to the structure of the mycobacterial cell wall, which serves as a formidable barrier to the passage of antibiotics into the organism as well as into the immune system of the human host. Drug regimens that are in current use generally include one or two antibiotics that inhibit cell wall biosynthesis (e.g., ethambutol or isoniazid), in combination with others that have intracellular targets (e.g., rifampicin or streptomycin). When administered together, such combinations destroy the integrity of the cell wall, which in turn allows other antibiotics to pass to the cell more efficiently [12]. Even ignoring the issue of drug resistance, the arsenal of drugs that are active against mycobacteria is relatively small [8], and thus there is a pressing need for the identification of new antibiotics. When considered along with the emergence of drug-resistant mycobacterial strains, this need becomes even more urgent. In the search to identify new antibiotics, one area receiving particular attention is the identification of compounds that act by inhibiting mycobacterial cell wall biosynthesis. An increasing number of papers on this topic have appeared in the last few years [13–17]. However, a detailed understanding of the cell wall structure has really become available only in the last decade [6,13], and an in-depth understanding of its biosynthesis is unavailable [13]. Many more fundamental chemical and biochemical studies need to be completed before the rational design of such antibiotics can be realized. The mycobacterial cell wall is composed, to a very large degree, of polysaccharides and lipids [6]. The two major polysaccharides are an arabinogalactan (AG) and a lipoarabinomannan (LAM). The predominant lipid species are mycolic acids, branched long-chain lipids characteristic to the actinomycetes. What is particularly unique about both AG and LAM is that all the arabinose and galactose residues are present in the furanose form. Since oligosaccharides containing furanose residues are xenobiotic to mammalian biochemistry, the enzymes that assemble these polysaccharides are ideal targets for drug action. This chapter focuses on the arabinan portions of the AG and LAM. Sections II–IV outline the structure, biochemical importance, and biosynthesis of these arabinans. Section V discusses the chemical syntheses of oligosaccharides containing D-arabinofuranose residues. Such compounds are important tools in biochemical studies leading to a more detailed understanding of cell wall biosynthesis. Section VI focuses on work that we and others are doing to elucidate the solution conformation of oligo- and polysaccharides containing D-arabinofuranose residues, and Section VII offers some concluding remarks. This review covers work published up to the end of 1998. II.
ARABINAN STRUCTURE
Only recently has a detailed picture of the structure of the mycobacterial cell wall emerged [6,18,19]. Although the constituent species present have been known for many years [20,21], the assembly of these constituents into a coherent structure has required lengthy investigations and has relied on a number of techniques including,
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in addition to methylation analysis, both NMR spectroscopy and fast-atom bombardment high-resolution mass spectrometry [6,18,19]. These studies were also greatly facilitated by the discovery [22] of hydrolytic enzymes capable of digesting both AG and LAM into small fragments, which are more amenable to these characterization methods. A.
Arabinogalactan
In common with gram-positive bacteria, mycobacteria have a layer of peptidoglycan immediately external to the cytoplasmic membrane. This peptidoglycan serves as the scaffold to which the AG is attached. Figure 1 is a schematic drawing of the overall structure of a single AG molecule [6]. A number of structural motifs are worthy of mention, and these are illustrated in Figure 2. Linkage of the AG to peptidoglycan is by way of a phosphodiester through a disaccharide comprised of rhamnose and N-acetylglucosamine (1). Attached to the 4-hydroxyl group of the rhamnose moiety is a linear chain of approximately 30 D-galactofuranose (D-Galf ) residues with alternating -(1→5) and -(1→6) linkages (2). Along the galactofuranose chain are branch points at which arabinan chains are attached. This arabinan contains in total approximately 70 D-arabinofuranose residues and consists primarily of linear ␣(1→5)-linked chains (3). However, there are periodic branch points at which another linear arabinan chain is attached via an ␣-(1→3) linkage (4). At the distal, nonreducing end of these chains is the branched hexasaccharide 5. In a single AG molecule, approximately two-thirds of these hexasaccharide motifs are esterified to mycolic acids at the four primary alcohols to provide 6. These lipids, which are unique to mycobacteria and other actinomycetes, are branched fatty acids containing 70–90 carbons as well as cyclopropane, ketone, hydroxyl, and methoxyl functionalities [23,24]. An example of one type of mycolic acid, a ketomycolate, 7, is shown in Figure 2. B.
Lipoarabinomannan
LAM, which has a less homogeneous structure than the AG, is attached noncovalently to the cytoplasmic membrane through the lipid portion of a phosphatidylinositol (PI) linker. A schematic drawing of LAM is presented in Figure 3 [6]. A mannan, comprised of ␣-(1→6) linked D-mannopyranose residues, is covalently bound via a glycosidic linkage to the inositol O6. Approximately half these mannose residues carry an ␣-(1→2) D-mannopyranosyl branch. An arabinan very similar to that found in the AG is attached at the termini of the mannan. In common with the AG arabinan, the major structural motif is an ␣-(1→5)-linked chain with periodic branch points, and hexasaccharide 5 at the nonreducing termini. However, there are fewer branch points, and thus the ratio of linear to branched arabinofuranose in LAM is greater than in AG. In addition, while the hexasaccharide motifs (5) found in the AG are esterified to mycolic acids, in LAM these moieties are found either unsubstituted or, in particularly virulent strains, capped with short mannopyranosyl oligosaccharides (8). When capped with the mannose residues, the polymer is referred to as ManLAM. Other structural features have been discovered more recently. For example, hexasaccharide 5 found in LAM of M. smegmatis is capped with inositol phosphates (9), thus providing a new type of LAM termed PI-GAM (phosphoinositol-glyceroarabino-mannan) [25,26].
136
Schematic representation of mycobacterial arabinogalactan (AG).
Lowary
Figure 1
D-Arabinofuranosides from
Figure 2
III.
Mycobacteria
137
Structural motifs present in mycobacterial AG and LAM.
ROLE OF THE AG AND LAM IN DISEASE PROGRESSION
The AG together with the mycolic acids comprise the major structural component of the mycobacterial cell wall; intercalated within this framework is LAM. These polymers play paramount roles in enabling these organisms to survive in the human host. For example, in contrast to many other microorganisms, mycobacteria can thrive in human macrophages instead of being killed by them [27]. This property is believed to be due, in large part, to the impenetrable nature of the cell wall envelope. In addition to protecting the organism from macrophage destruction, the cell wall is believed to substantially reduce the flow of antibiotics into the organism [12,28] and to be involved in the initial stages of the infection by the binding of cell wall oligosaccharides to host receptors [29]. A.
Arabinogalactan
The mycolic esters at the nonreducing ends of the AG present a formidable hydrophobic barrier that prevents the passage of antibiotics into the organism [28]. The currently accepted structural model of the mycolyl–AG complex was initially proposed by Minnikin in 1982 [24] and is illustrated in Figure 4. In this model the mycolic acid chains are packed side by side, perpendicular to the plane of the cy-
138
Schematic representation of mycobacterial lipoarabinomannan (LAM).
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Figure 3
D-Arabinofuranosides from
Figure 4
Mycobacteria
139
Schematic drawing of the mycolyl–AG complex.
toplasmic membrane. The tight packing of these chains results in very low fluidity of the cell wall, which in some cases is essentially crystalline [30,31]. The fluidity is dependent on the mycolic acids present, which in turn are species specific [31]. However, in all cases a major problem in treating mycobacterial infections is the passage of drugs through this lipid barrier into the host. This model was initially criticized by some, who suggested that the AG was too large to accommodate the tight packing of the lipid chains [28]. However, a more detailed look at the structure of the AG provides a solution to this problem. A distinguishing feature of mycobacterial AG is the almost exclusive presence of furanosyl (Araf or Galf ) residues. Furanoside rings are known to be much less conformationally well defined than their pyranoside counterparts [32]. It has been suggested that this inherent increased flexibility, in addition to the predominant coupling of these residues through linkages that involve primary hydroxyl groups, results in the polysaccharide being a scaffold of high flexibility. This in turn allows the polymer to adopt a conformation that facilitates the orientation of the mycolic acids into tightly packed parallel arrays. Additionally, this proposal provides a reasonable explanation for what, from an evolutionary standpoint, seems odd. Polysaccharides containing furanosyl residues are expected to be less thermodynamically stable than those possessing pyranose rings, and it therefore appears that these organisms have developed a system whereby glycan stability is traded for the protection afforded by the tightly packed mycolic acids. B.
Lipoarabinomannan
The major antigenic component of the mycobacterial cell wall is LAM. It should be pointed out that although not explicitly shown in Figure 4, LAM is interspersed throughout the mycolyl–AG framework, and this polymer is believed to be long enough that any groups found at the nonreducing terminus (e.g., the mannopyranosyl oligosaccharides) extend through the mycolic acid layer and are expressed on the outer surface of the cell wall [33]. LAM has been suggested to play critical roles in many immunomodulatory events occurring during progression of the disease. Among these are the inhibition of macrophage activation [34], the neutralization of potentially cytotoxic O2 free radicals [35], the induction of cytokines [36–38], the inhi-
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bition of protein kinase activities [39], and the induced expression of collegenases that destroy the extracellular matrix of the lung [40]. LAM in which the primary hydroxyl groups of 5 are capped with mannopyranosyl oligosaccharides (8, ManLAM) has been suggested to be involved in the infection process. It is believed that these terminal mannose residues initiate infection by adhering to human cells through their recognition by human mannose binding proteins [41–43]. In contrast to the capping of 5 by mannopyranosyl residues, mycobacterial species (e.g., M. smegmatis) in which this motif is capped with inositol phosphate residues (8) are avirulent. It has been proposed that the lack of pathogenicity of this species arises from the induction of tumor necrosis factor ␣ (TNF-␣) by the inositol phosphate moieties, which in turn results in the killing of the bacteria by macrophages [26]. Perhaps the most important recent discovery is that T cells recognize LAM via antigen presentation pathways that are independent of the major histocompatibility complex (MHC) [44,45]. It was shown that LAM is initially recognized by a mannose receptor and the protein CD14 before it is processed and then complexed with CD1b. This complex is then expressed on the surface of the antigen-presenting cell. Recognition by the T cell requires both the carbohydrate and lipid portion of LAM, and two distinct cell lines have been shown to differentiate between structurally different LAM fragments. Thus it appears that there is a significant amount of specificity in T-cell responses mediated by the LAM-complexed CD1 glycoproteins. IV.
ARABINAN BIOSYNTHESIS
Given the critical importance of AG and LAM to the survival of mycobacteria, there is increasing interest in developing new drugs for the treatment of these diseases, which act by inhibiting the enzymes involved in their biosynthesis. Inhibitors of the glycosyltransferases involved in the assembly of the furanosidic oligosaccharide portions of the glycoconjugates are particularly attractive targets. Glycans of this type are unknown in humans, and therefore blocking these biosynthetic pathways will have little deleterious effect on the host. However, for rational drug design to succeed, more details about the biosynthetic pathways leading to the formation of these polysaccharides are required. Although the overall features of this process are known [13,18,19], many of the details are not. The -(1→2)- and ␣-(1→5)-linked arabinose residues are incorporated into the polymer from the activated polyprenyl sugar phosphate 10, which is in turn synthesized from glucose via 5-phosphoribose pyrophosphate (pRpp) [46–48]. Elongation of the polymer chain is believed to involve a family of arabinosyltransferases (AraT’s) that recognize both 10 and arabinofuranoside-based acceptors of differing structures (Fig. 5) [18,19,49,50]. In AG biosynthesis, the entire polysaccharide appears to be assembled as a polyprenol diphosphate intermediate, which is transferred to peptidoglycan prior to the addition of the mycolate esters [18]. In LAM biogenesis, the arabinan portion is believed to be synthesized as a polyprenol phosphate that is transferred to lipomannan [51]. Incorporation of arabinose into AG has been demonstrated through the use of synthetic, radiolabeled 10 and mycobacterial membrane extracts [50]. These reactions are believed to involve membrane-bound substrates and enzymes and to occur extracellularly. While to date none of these putative glycosyltransferases have been purified to homogeneity, the gene cluster that encodes for one or more of these AraT’s
D-Arabinofuranosides from
Figure 5
Mycobacteria
141
A typical reaction catalyzed by mycobacterial arabinosyltransferases (AraT’s).
has been cloned and expressed [52–54]. In addition, an assay for their activity that uses mycobacterial membrane preparations as the enzyme source has been developed [49,50]. The assay measures the incorporation of radiolabeled arabinose from 10 into arabinan, and it has been used to screen both potential substrates and inhibitors [46,47,55,56]. Although the natural acceptor substrates for these enzymes are lipid-bound intermediates, these AraT’s also recognize small arabinofuranosyl oligosaccharides. A few of the oligoarabinosides that have been shown to be substrates for these enzymes are illustrated in Figure 6 [49,55]. Arabinofuranose disaccharides appear to be the minimum epitopes. Furthermore, investigation of the AraT recognition of the disaccharide ␣-D-Araf-(1→5)-␣-D-Araf-R (13–15 ) and the trisaccharide ␣-D-Araf(1→5)-␣-D-Araf-(1→5)-␣-D-Araf-R (16, 17) revealed that glycosides with R = octyl (14, 17) are better substrates and those with R = methyl (13, 16). Surprisingly, the dodecyl glycoside 15 was a poorer substrate than 13. In the investigation of 14 and 17, the products of the enzymatic reactions were isolated and their structures elucidated [49]. In both cases, mixtures of two products, corresponding to addition of an Araf residue to either the 2- or the 5-position of the terminal residue in the oligosaccharide acceptor, were obtained. From this study it was concluded that 10 was the source of the -(1→2)-, and ␣-(1→5)-linked Araf residues. Less is known about the formation of the ␣-(1→3) branch points than about the -(1→2) and ␣-(1→5) linkages. Only -(1→2) and ␣-(1→5) linkages are formed by the incubation of small oligosaccharide substrates with 10 in the presence of a mycobacterial membrane preparations [49]. However, additional work [57] demonstrated that when radioactive 10 is incubated with endogenous acceptors and a mycobacterial membrane preparation, a polymer essentially identical to native AG can be obtained. Additionally the radioactivity in the polymer was equally distributed
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Lowary
Figure 6 Arabinofuranosyl oligosaccharides tested as substrates for mycobacterial arabinosyltransferases.
throughout, which suggests that 10 is the major, and possibly sole, source of Araf residues. The lack of ␣-(1→3) linkages formed in the initial study [49] could be attributed to a number of factors: (1) the instability or absence of ␣-(1→3) AraT activity in the membrane preparation, (2) the possibility that this enzyme recognizes oligosaccharide substrates larger than those investigated, or (3) the possibility that another activated donor (e.g., a sugar nucleotide) is used by this AraT. Although the presence of UDP-Araf in mycobacteria has been reported [58], the incorporation of arabinose from this source into arabinan has not been demonstrated. The range of donor substrates that are tolerated by these enzymes has also been explored. A series of analogs was prepared, each one differing from 10 only in the identity of the lipid chain, and the set was screened for biological activity [56]. It was discovered that conjugates of C50 and C55 prenols were substrates, while those compounds with shorter ( Ag2CO3 > silver salicylate > HgBr2 > Hg(CN)2 [6]. Generally, the more reactive silver promoters furnish higher stereoselectivities than the mercury salts, but give lower overall yields. In the majority of cases examined, the compound of choice was the most active promoter, AgOTf, or the least reactive, Hg(CN)2. Glycosyl halides are the typical sialyl donors in these processes. Sialyl chlorides are generally less reactive than bromides, but they are not as susceptible to decomposition and are sufficiently active under silver ion promotion to make them the most common halogenated glycosyl donor [2]. Sialyl fluorides are useful for glycosylation reactions but are usually activated under Lewis acidic conditions. An advantage of using fluoride glycosyl donors is their inherent preference to form glycosides. Under Koenigs–Knorr conditions, -sialyl chloride 13 leads to predominantly the ␣-glycoside 15 in a glycosylation with primary alcohol 14 [7a]. However, when the -fluoride 16 is activated with BF3 ⭈ OEt2, the -glycoside 17 is afforded in a 5:1  :␣ mixture of anomers (Scheme 7). Methods derived from the Koenigs–Knorr approach are useful for glycosylation reactions involving reactive alcohols, such as primary alcohols. Unfortunately,
Scheme 7
Glycosylation with Sialic Acid
183
when more hindered secondary alcohols are employed, the greater steric bulk of the nucleophile leads to lower stereoselectivities and yields. This is an important factor because many naturally occurring sialosides contain linkages to secondary alcohols. Sialyl bromides can be employed as more reactive donors in these instances. As a representative example, Paulsen and Von Reessen used a sialyl bromide to apply the Koenigs–Knorr method to the synthesis of an ␣-2,3-linked disaccharide (Scheme 8) [7b]. Glycosylation of the galactose acceptor 19 with sialyl bromide 18 led to the desired disaccharide 20, although with poor stereoselectivity (ca. 1:1 ␣ :). The low yields of Koenigs–Knorr glycosylations with secondary alcohols are partly due to elimination of the sialyl halide and formation of the 2,3-dehydro derivative 21. Many of the methods of activation using Koenigs–Knorr conditions require heterogeneous promoters and long reaction times at room temperature. In addition, the expense and toxicity of silver and mercury makes these methods impractical for large-scale syntheses. Consequently much research has focused on the development of glycosyl donors that could be activated at low temperature, under mild conditions, and without the need for heavy metal promoters. Sialic acid thioglycosides, although initially synthesized for use as biological probes, have been found to be excellent glycosyl donors. Hasegawa and coworkers utilized thioglycosides in the synthesis of several ␣-2,3- and ␣-2,6-linked disaccharides. The methylsulfide donor 22 was activated by using the thiophile dimethyl(methylthio)sulfonium triflate (DMTST) at ⫺15⬚C in the presence of either acceptor 23 or 25 to provide compounds 24 and 27, respectively, as exclusively the ␣-glycosides (Scheme 9) [8]. High stereoselectivities were observed for these glycosylations when the reactions were performed in acetonitrile, even though the thioglycoside starting material was a 1:1 mixture of anomers. This finding suggests that the stereoselectivity was not derived from the donor configuration as in Koenigs– Knorr glycosylations, but must depend on the reaction conditions. In an attempt to determine the source of the stereocontrol, Sina¨y and coworkers examined glycosylations of the xanthate donor 27 in polar and nonpolar solvent systems (Scheme 10) [9,10]. Glycosylation of 28 in acetonitrile under DMTST activation afforded the ␣-2,3-linked disaccharide 29 in 26% yield as a 7:1 ␣ : mixture of diastereomers. However, the same reaction in CH2Cl2 gave exclusively the glycoside 30 in 25% yield (Scheme 10). The major by-product in both reactions was the 2,3-dehydro NeuAc derivative. Sina¨y proposed that the glycosylation in CH2Cl2 probably involved an oxocarbenium ion 31 that underwent axial attack to form the  product (Scheme 11). However in acetonitrile, formation of a -nitrilium intermediate 32, which undergoes SN2 attack to afford the ␣-glycoside, may be the stereocontrolling element. The effect of acetonitrile has been studied in glucose and galactose systems, where the presence of axial nitrilium ions was supported by trapping and spectroscopic studies, both performed at low temperatures [10]. The Whitesides group achieved a more efficient synthesis of ␣-sialosides from sialyl xanthates by modifying the reaction conditions of Sina¨y’s system [11]. Previously, Lo¨nn and coworkers had demonstrated that lower temperatures and the use of milder promoter, methylsulfenyl triflate, increased the product yield and reaction stereoselectivity [12]. Whitesides and coworkers introduced an even milder promoter, phenylsulfenyl triflate (PST), which itself was prepared in situ from silver triflate and phenylsulfenyl chloride [11]. When sialylations of xanthate donor 27 were pro-
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Scheme 8
Glycosylation with Sialic Acid
Scheme 9
Scheme 10
185
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Scheme 11
moted by PST at ⫺70⬚C in a 2:1 ratio of CH3CN to CH2Cl2, isolated yields of 60– 80% and stereoselectivities of 19:1 ␣ : were observed. A representative example is shown in Scheme 12. Interestingly, when the reaction was conducted under high dilution (0.01 M in donor) the stereoselectivity improved to better than 99:1 ␣ :, albeit at the expense of overall yield (52%). Regarding the reaction mechanism, Whitesides and coworkers also postulated that the presence of a -nitrilium ion was the source of stereocontrol. In their proposed mechanism, the xanthate 27 initially reacts with the PST promoter to form 35 (Scheme 13). Subsequent loss of 36 leads to the oxocarbenim intermediate 31. Attack by acetonitrile is presumed to occur from the less hindered ␣ face and leads to the presumably thermodynamically more favorable equatorial nitrilium ion 37 because of the reverse anomeric effect [13,14]. However the equatorial nitrilium ion is believed to be in equilibrium with the more reactive  species 32. Acetonitrile is then displaced from this species by the glycosyl acceptor in an SN2-like manner for form the ␣-glycosidic linkage in compound 38 The aforementioned experimental data do support this mechanism to some extent. First of all, the stereoselectivity is independent of the anomeric configuration of the starting material. A 1:1 mixture of xanthate anomers reacts to give predominantly the ␣-glycoside in acetonitrile, and the reaction by-product 36 was isolated and fully characterized. These data suggest that the xanthate is activated by the thiophilic promoter and glycosylation does not proceed through an SN2-type mechanism. Finally, Whitesides proposes that the gain in stereoselectivity that was observed by performing the reaction dilute in acetonitrile corresponds to an increase in the [MeCN]/[acceptor] ratio. The authors believe that a competition exists between acetonitrile and the acceptor alcohol for the oxocarbenium ion intermediate. When the concentration of the glycosyl acceptor is high enough, the alcohol reacts directly with oxocarbenium ion 32 to form the -glycoside. However, an increase in the amount of acetonitrile favors nitrilium ion formation over direct glycosylation, and since nitrilium ion formation is the stereocontrolling element, higher ␣ : ratios are observed. Takahashi and coworkers examined a novel approach to stereoselective sialylations by incorporating an auxiliary into the ester [15]. An electron-donating group with an appropriate linker to the carboxylate carbon was anticipated to stabilize an oxocarbenium ion through long-range participation. Activation of compound 39, where X is an electron-donating group, would produce oxocarbenium ion 40. This intermediate could be stabilized by X to provide an equilibrating mixture of  and
Glycosylation with Sialic Acid
Scheme 12
187
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Halcomb and Chappell
Scheme 13
␣ ‘‘onium’’ isomers, 41 and 42, respectively (Scheme 14). The authors predicted that the -onium species 41 would preferentially undergo attack to afford the ␣glycoside 44. Preliminary experiments revealed that a sialyl donor containing a methyl sulfide and a 2-carbon spacer within the ester was the optimum substrate for these studies. This sialyl donor 48 was synthesized as an approximately 1:1 mixture of anomers and was activated with N-iodosuccinimide and trifluoromethanesulfonic acid. Glycosylations of compound 48 were compared with the methyl ester control 45 in various solvents to determine the extent of the enhancement of stereoselectivity (Scheme 15). Interestingly, glycosylations of 2-[2-(2-azidoethoxy)ethoxy]ethanol with donor 45 in acetonitrile or dichloromethane gave the same product ratios (entries 1 and 2), suggesting that for this system acetonitrile does not provide an increase in stereoselectivity. However, the tethered donor 48 predominantly favored formation of the ␣-glycosides (entrites 3, 4, and 5), with the solvent dimethoxyethane (DME) providing the highest ␣ : ratios. Next, the sialyl donor 48 was utilized in the synthesis of ␣-2,6- and ␣-2,3-linked disaccharides under the optimal reaction conditions (entires 6 and 7). The selectivities observed were similar to those in the earlier
Glycosylation with Sialic Acid
189
Scheme 14
examples, although increased formation of products derived from elimination caused the reaction yields to drop significantly. A useful and powerful method that has been developed independently by Wong [16] and by Schmidt [17] and their colleagues utilizes sialyl phosphites as glycosyl donors. Phosphites are synthesized from the corresponding anomeric alcohols by reacting the latter with a phosphoramidite. This greatly shortens the reaction sequence needed to obtain the sialyl donors because many transformations that ordinarily would be needed to install a nonoxygen atom at the anomeric carbon are precluded, and several phosphoramidite reagents are readily available. An additional and significant advantage of these donors is that they are activated by many commonly used Lewis acids such as TMSOTf. Lewis acid activation is now a standard for glycoside synthesis, thus making these methods compatible with the most commonly used protecting group patterns and assembly strategies. Furthermore, sialyl phosphites are activated at low temperatures, and as a result generally provide products in high stereoselectivity. Some typical examples of the use of phosphites for
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Scheme 15
sialylation are the Wong lab’s synthesis 53 [18], an intermediate en route to the sialyl Lexis X antigen (Scheme 16) and the Schmidt lab’s synthesis of 56 (Scheme 17) [17a]. B.
Protection Strategies to Optimize Yields and Regiocontrol
The course and outcome of glycosylation reactions with sialic acid can be greatly influenced in some instances by seemingly insignificant modifications of the protecting groups on the glycosyl donor or acceptor. For example, simply employing a benzyl ester rather than the more commonly used methyl ester to protect the carboxylic acid of NeuAc, in combination with a sialyl chloride as donor using Koenigs–Knorr-type conditions, has profound consequences on the stereoselectivity of the glycosylation [19]. This fact was recorded by Ratcliff and coworkers, and has been widely utilized [19]. A representative example is shown in Scheme 18. The Boons laboratory has observed a dependence of the yield of glycosylation on the nature of the protecting group of the sialic acid C5 nitrogen [20]. When the nitrogen was engaged in an N,N-diacetylimide 60, yields significantly increased relative to the simple acetamide, the latter bearing only one acetyl group. This observation was utilized to efficiently construct NeuAc-␣-2,8-NeuAc linkages such as that in compound 62 (Scheme 19). The glycosylation of O8 of sialic acid by a sialyl
Glycosylation with Sialic Acid
Scheme 16
191
192
Scheme 17
Halcomb and Chappell
Scheme 18
Glycosylation with Sialic Acid
193
Scheme 19
donor is notoriously difficult to accomplish, and the donor 60 was nicely used to construct this linkage. A similar observation has been made by Hossain and Magnusson [21].
III.
USING DIRECTING GROUPS FOR STEREOCONTROL
Although several improved glycosyl donors have been developed to accomplish ‘‘direct’’ sialylations of acceptors, elimination reactions of the sialyl oxocarbenium ion intermediate often are significant competing nonproductive reaction pathways. Additionally, control of the stereochemistry at the NeuAc anomeric center is difficult and nontrivial. To alleviate these problems, several laboratories have investigated the use of stereodirecting auxiliaries at C3 of NeuAc. The postulate is that this group Y in 63 (Scheme 20) could, after activation, assist in stabilizing the positive charge of the oxocarbenium intermediate 64. In doing so, an intermediate such as 65 would be formed. Not only would this suppress elimination reactions, but one could imagine that the trajectory of attack of the glycosyl acceptor would be guided anti to the three-membered onium ion. As a result, the anomeric configuration might be assembled in a more predictable and ␣-selective fashion. Goto and coworkers, who were early contributors, synthesized compounds of this nature from the 2,3-dehydro sialic acid 21 [22]. The Goto group initially investigated hydroxyl groups at C3 as directors and used the reliable Koenigs–Knorr method for glycosylation (Scheme 21) [22]. The prototypical donor was the bromide 67. As a means of examining the versatility of this sialyl donor, the ␣-2,9 and ␣-2,8 NeuAc dimers were chosen as the synthetic targets. Treatment of 67 with silver triflate and a selectively protected sialic acid glycal 68 afforded 42% of the ␣-2,9 dimer 69 along with a 21% of the  anomer. The secondary alcohol 70 was also glycosylated with 67 to give 26% of disaccharide 71. Although the yield of the glycosylation was rather modest, the stereoselectivity was good (3:1 ␣ :). The Goto lab later found that bromides at C3 could also be used as directing groups [23]. This prompted a great deal of research into more convenient C3 substituents that would provide higher stereocontrol.
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Scheme 20
Ogawa and coworkers introduced C3 phenylselenyl and phenylthio substituents as stereocontrolling auxiliaries [24,25]. These directing groups had already been developed in the context of stereoselective syntheses of 2-deoxyglycosides by several groups [26]. Phenylthio and phenylselenyl neighboring groups were anticipated to provide better charge stabilization than a C3 hydroxyl substituent because of the increased polarizability of sulfur and selenium [26]. Initial glycosylation attempts with the phenylselenyl substituent proceeded with good stereoselectivity, although yields were low owing to elimination of a cationic selenium species to provide the corresponding 2,3-dehydro NeuAc derivative as the major product of the reaction [24]. The less polarizable phenylsulfide auxiliary was found to circumvent his problem [25]. Mercury-promoted glycosylation of the acceptor 73 with the donor 72 afforded the GM3 precursor 74 in good yield with no trace of the  isomer (Scheme 22). An additional benefit of using a sulfur auxiliary over a hydroxyl was its relative ease of removal in one step by a radical reduction. Treatment of 74 with Bu3SnH and AIBN provided the trisaccharide 75 in 75% yield. The phenylsulfide auxiliary was also used to synthesize an ␣-2,8 NeuAc dimer [25b]. The Ogawa group immobilized these types of sialyl donor on solid support resins and demonstrated their ability to act as donors in solid phase glycosylations [25c]. Thioglycoside donors combined with C3 phenylthio directing groups have been effectively employed by the Magnusson laboratory [27]. A disadvantage of auxiliary-directed glycosylation is that additional steps are required for the synthesis of the sialyl donor. To address this problem, the Whitesides group developed an expeditious route to a sialyl donor in two steps from the NeuAc glycal 21 (Scheme 23) [28]. Treatment of 21 with 2,4-dimethylbenzenesulfenyl chloride afforded the crystalline intermediate 76 in 85% yield. This compound was quan-
Glycosylation with Sialic Acid
Scheme 21
195
196
Halcomb and Chappell
Scheme 22
Glycosylation with Sialic Acid
197
Scheme 23
titatively converted to the thioglycoside 77 by treatment with sodium methanethiolate. Sialylations of 77 were achieved in good yield and stereoselectivity by using phenylsulfenyl triflate (PST) as a promoter and di-tert-butylpyridine (DTBP) as a proton scavenger. The most impressive application of this donor was for the synthesis of the ␣-2,3-linked disaccharide 78, which proceeded in 78% yield with no trace of the  isomer (Scheme 24). It was also demonstrated that the auxiliary could be efficiently removed by reduction with Bu3SnH and AIBN in 94% yield. In 1998 the Schmidt group looked to improve the efficiency and simplicity of sialyl glycosylations through the development of a phosphite donor containing a directing auxiliary at C3 [29]. The primary objective was to develop an auxiliary that could be more easily introduced and removed and would more effectively direct the stereochemistry while minimizing side reactions. It was postulated that a better auxiliary might be one that could form a cyclic five-membered onium intermediate rather than a three-membered one. Compound 79 was found to meet the requirements. Acid-catalyzed activation of sialyl phosphite 79 should lead to oxocarbenium ion 80 without the need for stoichiometric promoters (Scheme 25). The intermediate oxocarbenium ion should readily undergo attack by the thionobenzoate auxiliary to form the intermediate 81. Incorporation of the thionobenzoate auxiliary, which provides anchimeric assistance through a larger, more favorable five-membered ring, should provide higher stereocontrol than the three-membered episulfonium ions. Glycosylation should then proceed from the ␣ face to provide the desired sialoside 82. Following this reaction, the thionobenzoate auxiliary should be easily removed by treatment with Bu3SnH/AIBN. Many of the earlier syntheses of NeuAc derivatives containing auxiliaries were long and tedious because it was so difficult to obtain the correct stereochemistry at
198
Scheme 24
Scheme 25
Halcomb and Chappell
Glycosylation with Sialic Acid
199
Scheme 26
C3. However, Schmidt and coworkers discovered that the reaction of glycal 21 with OsO4 led to stereoselective dihydroxylation from the  face, providing diol 83 as the only product (Scheme 26). Subsequent regioselective introduction of the thiobenzoyl auxiliary was accomplished by treatment with N,N-dimethyl-␣-chlorobenzimidium chloride followed by dihydrogen sulfide. Compound 84 was obtained as the product of this sequence in 92% yield. Finally, the alcohol was converted to the glycosyl phosphite 79 in a straightforward manner. The utility of this donor was demonstrated in the synthesis of an ␣-2,3-disaccharide and an ␣-2,8-linked NeuAc dimer. Glycosylation of the protected lactose derivative 73 with donor 79 afforded an 88% yield of the protected GM3 analog 85, with no trace of the -glycoside (Scheme 27). Likewise, glycosylation of glycal 86 provided an unprecedented 83% yield of the ␣-2,8 NeuAc dimer 87, once again with no trace of the undesired  diastereomer. In both cases the auxiliary was removed with Bu3SnH/AIBN in good yield. IV.
USING SIALYLTRANSFERASES FOR THE SYNTHESIS OF SIALOSIDES
Enzyme-mediated glycosylations are powerful methods for the synthesis of complex carbohydrates, including those that contain sialic acid [30,31]. In mammalian systems, Leloir pathway glycosyltransferases are responsible for the biosynthesis of most glycoconjugates [32]. Sialyltransferases are a subset of the glycosyltransferases that transfer the NeuAc component of cytidinyl-5⬘-monophospho--N-acetylneuraminic acid (88, CMP-NeuAc) to acceptor hydroxyl groups with inversion of configuration at the anomeric center (Scheme 28) [30,31]. Transferase-mediated sialylations are not burdened by some of the pitfalls of chemical glycosylations, such as un-
200
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Scheme 27
Glycosylation with Sialic Acid
201
Scheme 28
wanted reaction pathways and the need for tedious protecting group schemes or stereocontrolling auxiliaries. In addition, sialyltransferases have been shown to tolerate several acceptor modifications [33], although less is known about their donor specificity because the requisite CMP-NeuAc sugar donors are so difficult to synthesize. Kinetic isotope effect studies with a particular transferase, namely, rat liver ␣2,6-sialyltransferase, have shown that there is significant charge buildup at the anomeric center in the transition state [34]. This suggests that the glycosylation proceeds through an SN1-like mechanism. CMP-NeuAc appears to be the common donor for all the sialyltransferases. However, each enzyme varies in regioselectivity and to some degree in acceptor specificity. Under the premise that an enzyme exists for the formation of each natural sialoside, there should be at least nine sialyltransferases responsible for the synthesis of the following disaccharides: NeuAc-␣-2,6-Gal, NeuAc-␣-2,3-Gal, NeuAc-␣-2,6-GalNac, NeuAc-␣-2,4-Gal, NeuAc-␣-2,4-GlcNac, NeuAc-␣-2,6-GlcNAc, NeuAc-␣-2,6-Man, NeuAc-␣-2,8-NeuAc, and NeuAc-␣-2,9NeuAc. However, only a small subset of the known and postulated sialyltransferases has been isolated and used for synthesis purposes. The sialyltransferases are membrane-bound proteins located in the endoplasmic reticulum (ER) and in the Golgi apparatus. Information about their sequence homology is limited, but they do appear to share a common topography [35]. A catalytic domain resides at the C-terminus followed by an N-terminal segment that anchors the enzyme into the ER or Golgi membrane. Soluble, catalytically active sialyltransferases that lack the anchor segment have been isolated from milk, serum, and other body fluids, suggesting that this N-terminal anchor is not necessary for the enzyme to retain catalytic activity. However, the ability to obtain from natural sources quantities of most sialyltransferases that would be needed for synthesis applications is hampered by low tissue concentrations and difficult purifications. The genes for members of some of the most common classes of sialyltransferases have been cloned and expressed [33a]. Expressing and isolating membranebound enzymes in high catalytic activity can be difficult; however, Paulson and coworkers replaced the anchor segment with a cleavable peptide in the expression of Gal--1,4-GlcNAc ␣-2,6-sialyltransferase [35a,b]. This allowed the enzymes to be secreted from the cell into the medium, thus simplifying the process of isolation. This technology has been used to express several sialyltransferases in quantities
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Scheme 29
suitable for synthesis. Gaining sialyltransferase accessibility is becoming a less serious problem as these enzymes become commercially available. A.
Synthesis of CMP-NeuAc and Related Derivatives
The primary method for the synthesis of CMP-NeuAc 88 is through the use of CMPNeuAc synthetase, an enzyme that catalyzes the condensation of cytidine triphosphate (CTP) with sialic acid to produce CMP-NeuAc (Scheme 29) [30]. CMP-NeuAc synthetase has been cloned from microbial sources and has been isolated from mammalian tissues [36,37]. The substrate specificity of each synthetase has been studied to some degree [36,37]. The mammalian version accepts C9 and some C8 modifications of NeuAc, as well as variations at the C5 position, such as replacement of the acetamide with OH (KDN) or hydroxylation of the acetamide (NeuAc). The microbial CMP-NeuAc synthetase has a high activity for C9-modified sialic acids, but does not tolerate alterations at the C5 position. Unfortunately, the microbial version is the more readily available enzyme, thus limiting the variety of analogs that can be prepared in this manner. Scheme 30 gives a representative sample of some important C9-derivatized CMP-NeuAc analogs [37]. Modifications at the C5 position are somewhat limited by the specificity of CMP-NeuAc synthetase for an amide at this position. Nevertheless, several analogs were prepared that incorporate sterically and electronically diverse substituents at C5 (Scheme 31) [37].
Scheme 30
Glycosylation with Sialic Acid
203
Scheme 31
Wong and coworkers first attempted the nonenzymatic synthesis of CMPNeuAc by employing phosphoramidite chemistry in a key step involving the ligation of a sialyl phosphoramidite and a selectively protected cytidine analog (Scheme 32) [38]. Treatment of NeuAc derivative 99 with 2-cyanoethyl chlorophosphoramidite resulted in the formation of the -sialyl phosphoramidite 100 in 89% yield. The sialyl donor was then coupled to the protected cytidine 101 under promotion by 1H tetrazole to afford the intermediate phosphite, which was immediately oxidized with tert-butyl hydroperoxide to provide the protected CMP-NeuAc 102. Deprotection of this intermediate was not reported; however, the Wong group demonstrated that the CMP-NeuAc core structure could be successfully synthesized utilizing phosphoramidite chemistry.
Scheme 32
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Halcomb and Chappell
The Schmidt group utilized a sialyl phosphite in a very different synthesis strategy (Scheme 33) [39]. Upon treatment of sialyl donor 54 with cytidine phosphoric acid 103, a phosphite–phosphate exchange reaction occurred to give compound 104 exclusively as the  isomer. Deacylation by treatment with sodium methoxide followed by ester saponification through the addition of water provided CMP-NeuAc 88. This method circumvented the need for an oxidation step or phosphorus deprotection. This method was also applied to the synthesis of another naturally occurring CMP-NeuAc derivative 105 [40]. Hata and coworkers took a different approach to the ligation by utilizing cytidine phosphoramidite 107 and the tertiary anomeric alcohol of 106 as coupling partners (Scheme 34) [41]. The coupling reaction successfully provided a phosphite intermediate, which was subsequently oxidized with tert-butyl hydroperoxide to provide the trialkyl phosphate 108. Attempts to purify the phosphotriester failed, but the production of 108 was supported by 31P NMR spectroscopy of the crude reaction mixture. The protecting groups were then removed under mild conditions by treatment with tetrakis(triphenylphosphine)palladium(0) in the presence of the allyl scavenger n-butylammonium bicarbonate. Following purification by size exclusion chromatography, CMP-NeuAc 88 was obtained in acceptable overall yield (25% for three steps). In a related synthesis of CMP-NeuAc, Kajihara and coworkers also used a cytidine phosphoramidite in the coupling reaction, although with different protecting group patterns on the coupling partners (Scheme 35) [42]. The reaction of 99 with phosphoramidite 109 provided the phosphite 110 as a mixture of phosphorus diastereomers. Phosphite oxidation and subsequent treatment with methoxide led to decomposition. As an alternative, the cyanoethyl protecting group was first removed with DBU; then complete deprotection by treatment with sodium methoxide and sodium hydroxide afforded CMP-NeuAc 88 in good yield. This stragety was also applied to the synthesis of CMP-NeuAc-␣-2,8-NeuAc 111 [43]. Halcomb and Chappell developed a route to CMP-NeuAc 88 that promises to be general for the synthesis of virtually any derivative thereof [44,45]. The route (Scheme 36) utilizes a condensation of sialic acid derivative 99 with the phosphoramidite 112 to afford the phosphite 113 in 62% yield. Oxidation of the phosphite provided the phosphotriester 114 [46], which was taken directly to the next transformation without purification (owing to its instability to chromatography). Deallylation of the phosphate gave compound 115 (61% for two steps), which was stable to silica gel chromatography. Compound 115 was deacylated with methoxide, and its methyl ester was subsequently saponified with NaOH to provide CMP-NeuAc 88. The derivatives shown in Scheme 37 were synthesized according to this protocol and were investigated as substrates for sialyltransferases (see below). The synthesis of a CMP-NeuAc derivative that was bound to a solid support through the 9-position of the sialic acid has been reported by the Kajihara group [47]. This derivative is quite useful in that it can be utilized to immobilize glycoproteins onto a solid support by transferring the sialic acid to the terminus of the carbohydrate chain of the glycoprotein. B.
Synthesis of Wild-Type and Mutant Sialosides
The Brossmer and Paulson groups have studied the sialyltransferase donor specificity with a series of C5 and C9 conjugates, all of which were prepared through the CMP-
Glycosylation with Sialic Acid
205
Scheme 33
206
Halcomb and Chappell
Scheme 34
NeuAc synthetase route [37]. The relative rates of these C9-modified CMP-NeuAc derivatives shown in Scheme 30 were compared against the natural donor CMPNeuAc in sialyltransferase assays that utilized enzymes from different sources with their appropriate natural acceptors. The rat liver ␣-2,6-sialyltransferase tolerated a wide range of functional groups without significant decreases in the relative rates. Synthetically useful relative rates were observed for most of the CMP-NeuAc analogs with porcine sialyltransferase and rat liver ␣-2,3-sialyltransferase. The exception was the 9-amino analog, which was a poor substrate for both enzymes. Overall, these assays demonstrated that a wide variety of modifications at the C9 position are tolerated by these sialyltransferases. The relative rates of sialylation for the C5-modified CMP-NeuAc derivatives shown in Scheme 31 were also determined [37]. All the C5-modified sialyl donors were accepted by the transferase enzymes, but the variants containing free amines were poor substrates for all the sialyltransferases examined. Generally, higher relative
Glycosylation with Sialic Acid
Scheme 35
207
208
Halcomb and Chappell
Scheme 36
Glycosylation with Sialic Acid
Scheme 37
209
210
Halcomb and Chappell
rates were observed for both ␣-2,6-sialyltransferases over the porcine ␣-2,3-sialyltransferase, although all the rates are high enough to be synthetically useful. This study has shown that numerous C5-modified CMP-NeuAc sialyl donors can be successfully utilized in the synthesis of modified glycoproteins. The sialyltransferases investigated were found to accept many variations at C5 and C9 of the sialic acid moiety. Halcomb and Chappell confirmed this fact with studies of sialyltransferases from different sources [45]. The C9- and C5-modified substrates in Scheme 37 were good substrates. However no activity was detected when compounds 111 and 117 were assayed. In addition to these examples, other CMP-NeuAc analogs that have been prepared and successfully transferred include C9 fluorescent compounds, C9 thioacetyl, C5 thioacetyl, and C4 dexoy [37]. A particularly useful modification introduced by the Wong lab incorporates a mercury atom at C9 (Scheme 38) [48]. Transfer of this sialic acid to glycoproteins could greatly aid in X-ray crystallographic analysis of these biomolecules. The field of solid phase synthesis has also benefited from enzyme technology. Several reports have described the use of sialyltransferases in the solid-supported synthesis of oligosaccharides that bear sialic acid [49]. Additionally, metabolic pathways have been harnessed by Bertozzi and coworkers to synthesize glycoconjugates on cell surfaces that bear modified sialic acids [50]. C.
Cofactor Regeneration
Enzymatic methods are efficient for the assembly of complex oligosaccharides on a small scale, although the high cost of sugar nucleotides and problems with product inhibition detract from this approach in large-scale reactions. The synthesis of CMPNeuAc by CMP-NeuAc synthetase requires stoichiometric amounts of expensive reagents, such as CTP, while the CMP by-product of the sialyltransferase reaction is an enzyme inhibitor. Ichikawa and Wong used the concept of in situ cofactor regeneration to alleviate these problems and increase the efficiency of sialylation (Scheme 39) [51]. The cascade begins with stoichiometric amounts of phosphoenolpyruvate (PEP), -allyl-N-acetyl lactosamine 120, NeuAc 1, and catalytic quantities of ATP and CMP. Initially, CMP is converted to CDP by nucleoside monophosphate kinase (NMK) in the presence of ATP. The CDP produced reacts with PEP under pyruvate kinase (PK) catalysis to form CTP. Next, CMP-NeuAc synthetase catalyzes the in situ formation of the sialyl donor from NeuAc and CTP. The pyrophosphate byproduct is decomposed to inorganic phosphate by inorganic pyrophosphatase (PPase). Subsequently, the ␣-2,6-sialyltransferase accomplishes the sialyation of the lactosamine acceptor 120 and produces the transferase inhibitor CMP as a by-product. The CMP concentrations are kept low by conversion to CDP, and in so doing the problem of product inhibition is minimized. The cycle afforded 21% of the sialylated trisaccharide 121, which is remarkable considering the complexity of the system and number of synthetic steps that can be avoided. V.
USING SIALIDASES FOR THE SYNTHESIS OF SIALOSIDES
A.
Sialylhydrolases
Sialidases are another class of enzymes that have been used in the synthesis of sialylated oligosaccharides. In addition to hydrolysis activity, sialidases are capable
Glycosylation with Sialic Acid
Scheme 38
211
212
Halcomb and Chappell
Scheme 39
Glycosylation with Sialic Acid
213
of sialoside transfer to alcohol donors. Using the 4-nitrophenylglycoside 122 as a sialyl donor, sialylidases can catalyze a transsialylation to an alcohol acceptor to generate the product 89, or hydrolyze to NeuAc 1 (Scheme 40). To complicate matters further, the product 89 may also undergo sialidase-catalyzed hydrolysis to form NeuAc. So if any product is to be isolated, the rate of sialyl transfer must be much faster than either hydrolysis rate. Thiem and Sauerbrei examined this concept to determine whether various sialidases could be used synthetically [52]. The rate of condensation, or reverse hydrolysis, was found to be negligible. However, the product hydrolysis rate was competitive with the rate of transsialylation to an alcohol acceptor. In an attempt to minimize product loss, reactions were stopped after 65–75% of the starting material had been consumed. Interestingly, a mixture of ␣-2,3 and ␣-2,6 regioisomers was obtained for reactions with an immobilized Vibrio cholerae sialidase (Scheme 41). In all cases, the ␣-2,6 isomer predominated, probably because of a combination of faster hydrolysis of the ␣-2,3 products (123 → 1 ⫹ 125) and lesser steric hinderance of the primary alcohol. Variations in the donor/acceptor ratio (1:7 optimized) had an effect on both reaction yield and regioselectivity, although most of the examples afforded only 2–3:1 ␣-2,6/␣-2,3 product ratios in 14–20% overall yield. Ajisaka et al. examined different sialidase sources and found that Newcastle disease virus (NDV) sialidase afforded predominantly the ␣-2,3 regioisomers, while Arthrobacter ureafaciens and Clostridium perfringens sialidases, in addition to the Vibrio cholerae sialidase examined by Thiem, favored the ␣-2,6-linked products [53]. Unfortunately, the reaction yields did not improve for the new enzymes, varying from 0.8% to 3.6% isolated yield. In the case of NDV sialidase, the high selectivity for ␣-2,3-sialosides stemmed from a large ␣-2,6/␣-2,3 hydrolysis ratio. Hydrolysis of the ␣-2,6 products was found to be 28 times faster than the ␣-2,3 isomers. Inter-
Scheme 40
214
Halcomb and Chappell
Scheme 41
estingly, the ␣-2,6 preference of the other three enzymes was not correlated to product hydrolysis rates. B.
trans-Sialidases
The Trypanosoma cruzi trans-sialidase catalyzes the reversible transfer of NeuAc from a NeuAc-␣-2,3-Gal--OR1 sequence to an acceptor bearing the Gal--OR2 motif (Scheme 42) [54]. The enzyme is a particularly useful sialidase because it has very little hydrolytic activity and tends to almost exclusively catalyze transsialylation to a galactose. However a major drawback to this method is that to drive the glycosylation to completion, there is a need for large quantities of complex ␣-2,3-linked sialyl donors, which are generally difficult to obtain from natural sources. Other natural donors with ␣-2,6- or ␣-2,8-linked sialic acids have been examined but were discovered to be poor sialyl donors for ␣-2,3-sialylations catalyzed by T. cruzi transsialidase [55]. Simple aryl ␣-sialosides, such as the 4-nitrophenyl glycoside 122 and methylumbelliferone glycoside 130 (Scheme 43), have been found to be excellent
Glycosylation with Sialic Acid
215
Scheme 42
substrates because of the irreversibility of the sialyl transfer, and these have become the most utilized sialyl donors for trans-sialidase-catalyzed glycosylations. The donor specificity of T. cruzi trans-sialidase was examined with various side chain modified NeuAc glycosides. Vandekerckhove and coworkers found that methoxy or deoxy modifications to C9 of a NeuAc-␣-2,3-Gal--OR donor did not affect trans-sialidase activity, although the same modifications at C4, C7, or C8 completely prevented transfer of the sialic acid. In addition, the C4- and C8-modified compounds were found to be mild inhibitors of the enzyme [56]. Lee and Lee extended these studies to more drastically modified NeuAc aryl glycosides [57]. The triol side chain of the methylumbelliferone-␣-ketoside 130 was cleaved with periodate to afford the C7 aldehyde, which underwent reductive amination with different amines to provide several novel sialyl donors. Three of these derivatized sialic acids (those of 132, 134, and 136) were successfully transferred to a lactose acceptor on analytical scales (50 nmol), albeit in much lower yield than NeuAc from aryl glycoside 130 (Scheme 44). NeuAc analogs containing longer alkyl chain and terminal amine substituents were found not to be substrates for the trans-sialidase. Nonetheless, these studies helped to define the substrate requirements for trans-sialidase acceptance, and the latter work provides a novel method for the synthesis of chromophore labeled sialylated oligosaccharides. Ito and Paulson designed a cofactor regeneration system that overcomes several limitations of trans-sialidase-catalyzed sialylations (Scheme 45) [58]. The trans-sialidase is used in conjunction with ␣-2,3-sialyltransferase to effectively broaden the
Scheme 43
216
Halcomb and Chappell
Scheme 44
Glycosylation with Sialic Acid
Scheme 45
217
218
Halcomb and Chappell
substrate specificity of the sialyltransferase. The -trimethylsilyl galactoside 139 is known to be a poor substrate for ␣-2,3-sialyltransferase; however, it is readily accepted by T. cruzi trans-sialidase. The sialylated oligosaccharide 138 was synthesized by the CMP-NeuAc regeneration system developed by Ichikawa and Wong [51]. Then 139 underwent a transsialylation with 138 to provide the desired GM4 precursor 141. The regeneration of 138 from the by-product 140 by sialyltransferase drives the equilibrium toward the product 141. This example demonstrates that trans-sialidases have some synthetic utility on their own but are much more general tools for oligosaccharide synthesis when coupled with sialyltransferases.
REFERENCES 1.
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8 The Chemistry and Biology of Multivalent Saccharide Displays David A. Mann and Laura L. Kiessling University of Wisconsin–Madison, Madison, Wisconsin
I.
INTRODUCTION
Recognition of the importance of carbohydrate binding proteins in regulating biological systems is fueling efforts to understand and manipulate these processes. Lectin–ligand interactions have been found to play key roles in a wide variety of life processes: bacterial and viral attachment, immune system function, transplant rejection, fertilization, cell targeting, and the inflammatory response [1–7]. Despite these significant functions for protein–carbohydrate interactions, observed dissociation constants are typically on the order of 10⫺4 –10⫺3 M for a monovalent carbohydrate adhesion to a single lectin binding site [3,8–10]. The low affinity of these interactions raises a critical question: How do natural systems exploit weak binding events? An attractive idea is that protein–carbohydrate interactions garner the requisite strength and specificity required to mediate important biological processes through multivalent contacts. Thus, multiple simultaneous interactions can occur between an array of associated lectin binding sites and a multivalent presentation of saccharide ligand epitopes [8,11–15]. This chapter describes recent efforts to investigate and manipulate multivalent binding events involving protein–carbohydrate interactions. We focus on how synthetic ligands have served as critical tools for dissecting, illuminating, and controlling these complex recognition processes and their functional consequences. There are several excellent reviews that discuss other aspects of multivalent protein–carbohydrate interactions [9,15–17]. II.
STRUCTURAL FEATURES AND ENERGETICS
A number of specific components contribute to the complex energetics of lectin– ligand interactions. The observed affinities (functional affinities, see Section II.B.1) 221
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for these processes arise from the features of the monovalent and multivalent binding interactions. As a prelude to an examination of specific multidentate interactions, this section describes the features of monovalent protein–saccharide complexation and the factors that contribute to the high functional affinities observed for many multivalent interactions. A.
Monovalent Interactions
The structural features of monovalent lectin–ligand complexes have been elucidated through X-ray crystallographic analysis [1,18–20]. These complexes have helped facilitate an understanding of the energetics of monovalent carbohydrate binding to proteins; they have facilitated structure-based free energy calculations, as well as providing a basis for interpretation of titration microcalorimetry experiments [10,21– 23]. Although proteins can bind carbohydrates tightly, lectin binding sites are often solvent-exposed indentations rather than deep binding pockets. In these shallow binding sites, contacts are made with a limited portion of the carbohydrate ligand (Figs. 1 and 2). Monovalent interactions appear to rely on hydrogen bonding, metal chelation, water displacement and reorganization, hydrophobic contacts, and Coulombic interactions. We will use specific protein–lectin interactions to illustrate these energetic contributions. 1.
Hydrogen Bonding
The density and diversity of stereochemical orientations available to saccharide hydroxyl groups suggests that hydrogen bonding interactions might play a role in their recognition by proteins. Although the energetic contributions of specific hydrogen bonding interactions are difficult to dissect, the directionality of these interactions is important for recognition and discrimination of saccharide ligands. For example, in the structure of the lectin concanavalin A (ConA) complexed with ␣-methyl mannopyranoside, hydrogen bonding interactions occur between the protein and the 3-, 4-, and 6-position hydroxyl groups of the saccharide [19]. There is no direct contact with the 2-position hydroxyl group, and ConA interacts with saccharides of both the gluco and manno configurations. The hydrogen bonding interactions, however, allow the lectin to discriminate between galactose and mannose (or glucose) derivatives. The amino acid side chains as well as the peptide backbone can contribute to recognition (Fig. 2). The side chain amide hydrogen of asparagine 14 can form a hydrogen bond with the 4-position hydroxyl group, whereas the backbone amide hydrogens of leucine 99 and tyrosine 100 are within reach of the ring and 6-position hydroxyl groups, respectively. This structure also illustrates another common feature of lectin–saccharide complexes: many side chains form bidentate hydrogen bonds. For example, the aspartic acid 208 carboxylate oxygens can interact with both the 4- and 6-position hydroxyl groups of mannose. In addition to direct contacts between the lectin and the saccharide, water-mediated hydrogen bonds commonly occur [22,24]. 2.
Metal Chelation
Many lectins depend on divalent metal cations, especially Ca2⫹, for carbohydrate binding. Two roles have been observed for metal cations. First, to preorganize side chains for saccharide binding, and second, to directly ligate saccharide hydroxyl
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Figure 1
The main chain of concanavalin A as determined by X-ray crystal structure analysis. The homotetramer and monomeric subunits are shown with bound ligand.
groups. Examples of the former can be found in the legume lectin structures, as observed in ConA, where Ca2⫹ and Mn2⫹ assist in organizing local structure and also in orienting protein functional groups for saccharide interaction (Fig. 2) [19]. Both modes of metal ion function are important in C-type lectin recognition. Direct coordination of a metal to both the complexed lectin and the target saccharide ligand is observed in C-type lectin structures [4,5] such as that of rat serum mannose binding protein A (MBP-A). In the model derived from X-ray crystallographic analysis, the
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Figure 2
Concanavalin A binding site showing metal chelation and hydrogen bond
networks.
saccharide hydroxyl groups act as ligands for the protein-bound calcium ion (Fig. 3). In addition, Ca2⫹ binding organizes protein side chain conformation to facilitate saccharide complexation [25]. The addition to these metal-cation-dependent lectins of chelating agents, such as EDTA, abrogates ligand binding, a result that emphasizes the importance of divalent metal ions in lectin activity. 3.
Hydrophobic Effects
Lectin binding sites, like the saccharides that bind to them, are amphiphilic. In addition to the hydrogen bonds that are important for orienting saccharides, the binding sites contain many hydrophobic groups that can contribute to saccharide binding affinity. The structure of MBP-A derived from X-ray crystallography illustrates the importance of hydrophobic binding regions complementary to those on the ligand (Fig. 4) [1]. For example, isoleucine 207 is located proximal to the 6-position methylene group of mannose, which should result in favorable van der Waals contacts. In many lectin–saccharide complexes, aromatic residues have been found to pack against one or more faces of the saccharide [26]. In the structure of MBP-A, the side chain of histidine 189 is near the 4-position C—H and 6-position O—H bonds, suggesting that interactions between the aromatic residue and nonpolar areas of the saccharide contribute to mannose binding in this system. 4.
Coulombic Interactions
Coulombic interactions between carbohydrate binding proteins and their ligands are pervasive. Carbohydrates often bear anionic charges, which are installed through attachment of sialic acid residues or by phosphorylation or sulfation of uncharged
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Figure 3
The mannose binding protein A (MBP-A) binding site, featuring calcium coordination to protein side chains as well as the 3- and 4-position hydroxyl groups of mannose.
Figure 4
The mannose binding protein A (MPB-A) binding site featuring van der Waals contacts with the mannose ligand.
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saccharides [27]. For proteins that bind sulfated polysaccharides such as heparin, salt bridges have been observed between positively charged lysine and arginine side chains and the anionic sulfate and carboxylate groups of the saccharide [28]. In contrast, some lectins bind anionic ligands without formation of salt bridges. For example, in the structure of sialic acid bound to influenza virus hemagglutinin, the carboxylate group of sialic acid hydrogen bonds to water and to a backbone amide proton [18]. Structural studies of the protein–saccharide complex in a related example, an MBP-A variant that binds the tetrasaccharide sialyl Lewis acid x (sLex) [29], also revealed that interactions between the protein side chains and the anionic carboxylate of sialic acid occurred indirectly rather than through a direct salt bridge. 5.
The Role of Water
The ability of water to act as both donor and acceptor of hydrogen bonds makes it an excellent mediator in protein–carbohydrate complexes. Results of numerous Xray crystallographic studies of protein–carbohydrate complexes attest to the pervasiveness of water-mediated hydrogen bonds in protein–carbohydrate interactions. Lectin-bound water molecules are proposed to act as an extension of the protein surface itself [1]. This idea is supported by the fact that water molecules occupy conserved sites in the structures of related lectins [24]. In addition, water molecules can mediate similar hydrogen bonding interactions in the complexes of different proteins with a specific carbohydrate ligand or in complexes of the same lectin with different saccharide ligands [1]. The energetic contribution of water to carbohydrate binding is controversial. From crystallographic and thermodynamic data and molecular modeling calculations, Lemieux [21,22] and Toone [10] have speculated that changes in hydration are a driving force for carbohydrate binding. They postulate that because carbohydrates and their binding sites are amphiphilic, an advantageous reorganization of water occurs upon binding. To gather experimental support of the importance of hydration in binding, Lemieux’s research group has generated oligosaccharide derivatives with polar groups attached to positions outside the binding site. These modifications, which should not disrupt critical binding interactions but do alter the saccharide solvation shell, affect ligand binding [22,30]. Most of the changes in saccharide solvation were detrimental to binding, a result that underscores the significant and impalpable role of water in carbohydrate–protein complexation. B.
Modes of Multivalent Ligand Function
Saccharides constitute one class of biologically important molecules whose function depends on multivalent presentation. In physiological settings, saccharide epitopes are not usually encountered in isolation, but rather in multivalent arrays. For example, high ligand density glycoproteins can serve as scaffolds for the presentation of saccharides. Alternatively, saccharides can be displayed in multivalent arrays through glycolipid clustering. Moreover, many saccharide binding proteins are multivalent because they form oligomeric quaternary structures or are present in multiple copies on a cell surface. To understand carbohydrate function, therefore, we need insight into how multivalent saccharide presentation affects recognition. Natural systems rely on assembling multiple weak monovalent binding events
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into multivalent arrays, and this strategy can lead to enhancements in the strength and specificity of the subsequent interaction. The importance of ligand multivalency, which is also referred to as the ‘‘cluster effect’’ [3], is widely recognized, but additional investigations are required to understand the increases in activity that are observed. Several types of interaction that can augment the observed activities of multivalent ligands are discussed in the following sections. Because of the difficulties associated with dissecting the mechanisms that contribute to the activity of a multivalent ligand, we use the term ‘‘functional affinity’’ to refer to the measured activity of a particular ligand. Functional affinity is a descriptor that has been used in studies of antibody–antigen interactions, which are also multivalent. Functional affinity is useful for the purposes of comparing monovalent and multivalent ligand activities because it describes a measurable quantity: the apparent association constant (or inhibition constant). The conditions under which an assay is conducted, however, must also be carefully considered. Many multivalent binding events, both in vivo and in vitro, do not occur under equilibrium conditions. Thus, the functional affinities of multivalent ligands can vary between assays, even when those of their monovalent counterparts do not (see Section III). 1.
Functional Affinity
As noted, monovalent binding energies are often weak, displaying dissociation constants in the millimolar range. The relative affinity preference of a lectin for two structurally related monovalent saccharide ligands can be slight. Presenting lectin binding sites in an array that can simultaneously recognize multiple clustered carbohydrate epitopes facilitates multivalent binding, a process that enhances not only the strength of the resulting interaction, but also the specificity. For example, a fourfold affinity preference for monovalent mannose over glucose binding to ConA is magnified to a 160-fold preference for a multivalent display of mannose over an analogous glucose polymer [31]. This enhancement in affinity and avidity, functional affinity, is thought to be the result of the combination of numerous multivalent binding modes. Characterizing the molecular features of these binding modes is a critical step in understanding lectin–ligand interactions. 2.
Antibody–Antigen Binding: A Context for Exploring Multivalent Saccharide Recognition
Multivalent interactions involving antibody binding to multivalent antigens have been studied extensively. Antibodies themselves can be multivalent, existing as the bivalent immunoglobulin D, E, and G types, the tetravalent IgE, or the immunoglubulin M type, displaying 10 associated binding sites. Models for multivalent antibody binding were developed by Crothers and Metzger in the 1970s [32–34]. These early studies emphasized that for multidentate ligands to simultaneously occupy multiple binding sites, they must present recognition epitopes that are both properly spaced and sufficiently flexible. As expected, these variables are also important in multivalent carbohydrate binding. Still, an understanding of how much increase in activity is to be gained by such presentation and how the structures of multivalent ligands should be optimized for maximal potencies remains a mystery. The following sections describe some of the molecular features and general mechanisms that lead to enhanced activities.
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The Chelate Effect
The simultaneous placement of saccharide residues from a multivalent ligand into multiple binding sites on an oligomeric lectin can lead to high functional affinities if the ligand epitopes are properly oriented to interact favorably with appropriate sites on the receptor. This situation, in which multiple receptor sites are occupied by a multidentate ligand, is an example of the chelate effect. The term ‘‘chelate effect’’ arises from the observation that ligands possessing more than one donor group are more effective at coordinating electrophilic metal centers than those that possess a single donor. Thus, the chelate effect describes multiple interactions, occurring after the first contact is made, as effectively intramolecular (Fig. 5A) [35]. The observed free energy of interaction (⌬Gobs) for an oligomeric receptor R1 —R2, . . . , —Rn with an oligomeric ligand, L1 —L2, . . . , —Ln will be related to the sum of the free energies of binding for each individual receptor. Thus, the binding is often estimated as follows: ⌬Gobs = ⌬G(R1 —L1) ⫹ ⌬G(R2 —L2) ⫹ ⭈ ⭈ ⭈ ⫹ ⌬G(Rn —Ln) This model predicts that the formation of additional contacts should give exponential affinity increases because only the first binding event exacts a translational entropy penalty. However, the entropic costs related to conformational flexibility are likely to be much higher for a multivalent protein–carbohydrate interaction. Page and Jencks recognized the potential utility of the chelate effect for devising highly effective inhibitors of target enzymes [35,36]. This idea was extended to devising multidentate ligands as potent inhibitors for multivalent receptors. For example, a synthetic nonnatural trimer of the glycopeptide antibiotic vancomycin binds with high functional affinity to the corresponding trimer of d-Ala-d-Ala, its dipeptide ligand. The affinity of this complex, stabilized by the chelate effect, is similar to that of the avidin–biotin interaction [37]. However, large distances (>40 ˚ ) separate the saccharide binding sites in many oligomeric lectins; therefore, long A spacers are required to link saccharide epitopes for multivalent binding. Thus, many attempts to design effective multivalent saccharide derivatives have been thwarted by the increases in conformational entropy inherent in the long linkers required for multivalent binding. The conformational entropy term is affected by the structural features of the multivalent ligand, such as the rigidity of the scaffold displaying the binding determinants and the relative orientation of each recognition element [15]. The functional affinity of multivalent ligands will reflect both the advantages of translational entropy gains and the disadvantages of conformational entropy penalties. 4.
Rebinding Leads to Decreased Off-Rates
The display of a receptor or ligand at high density can result in its partner exhibiting increased functional affinity, even if multipoint binding does not occur. The increase in apparent affinity can be rationalized by modeling the binding event as a two-step process. In the first phase, receptor and ligand form a transitory encounter complex. The second stage involves the transitory species proceeding to generate a stable complex or dissociating as a result of nonproductive binding (Fig. 5B). In the case of a multivalent partner, the probability of rebinding increases and that of dissociation decreases. Because the off-rates are slower for such an interaction, the observed
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Modes of multivalent binding. 229
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functional affinities are higher. For example, ligand affinities for proteins clustered on a membrane or immobilized on a surface can appear to be significantly higher than that of the corresponding species in solution [38,39]. Like the chelate effect, this mode of statistical enhancement benefits from a high effective concentration of the binding partner, although the magnitude of enhanced activity is likely to be smaller than that for systems that exploit chelation. An advantage of such a statistical effect, however, is that optimal spacing of the ligand epitope is not crucial. 5.
Receptor Clustering
For a multivalent ligand, an alternative to occupying multiple saccharide binding sites within an oligomeric receptor is to bind multiple receptors at the cell surface (Fig. 5C). This mode of interaction is similar to the chelate effect, although the entropic costs are different. Moreover, the resulting effects of complexation can be quite distinct. For example, once the initial translational penalty for ligand binding has been paid, additional interactions will result in some restriction of receptor mobility. Nevertheless, this cost is moderated because receptors in a fluid membrane diffuse in two dimensions rather than three. An advantage over the chelate effect is that the ligand scaffold need not precisely orient epitopes for binding as proper spacing can be adopted by receptor movement in the membrane. Consequently, there will be more orientations in which multiple receptor–ligand complexes can form. Finally, the interaction of multivalent ligands with membrane-bound receptors can lead to their clustering. Bringing receptors together via liganded clustering may have useful functional consequences [40,41]. 6.
Subsite Binding
Some lectins have demonstrated the presence of secondary binding sites that aid in ligand discrimination [1,42–46]. In binding to these lectins, ligand substituents may either interact with a second independent saccharide binding site or with regions adjacent to the primary binding site (Fig. 5D). Secondary saccharide binding sites can impose ligand selectivity that results in specificity for complexation of one oligosaccharide (or one multivalent ligand) over another [43]. Similarly, an extended building site can engage in further interactions with substituents on the ligand, such as an appended carbohydrate residue or a portion of the scaffold upon which the primary saccharide ligand is displayed [47–49]. Although the physiological relevance of such sites remains unknown, multivalent ligands that can target subsites and extended sites will be more effective and selective inhibitors. 7.
Steric Interference
Steric stabilization can result in increases in the activities of multivalent ligands designed to inhibit the interaction of receptors and ligands on opposing surfaces, as in the case of cell adhesion. Whitesides and coworkers have suggested that the binding of high molecular weight multivalent ligands to one surface (e.g., a virus) can preclude the attachment of a competing surface (e.g., a cell) by sterically blocking access to neighboring binding sites (Fig. 5E) [15,50]. This mechanism may be especially important for ligands that target cell surface receptors displayed at high densities (or high local densities). Moreover, a large multivalent ligand that can bind to one receptor may also block access to other receptors located at interstitial sites. For multivalent ligands operating by this mechanism, the nature of the scaffold em-
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ployed will play a role in steric repulsion in addition to providing conformation flexibility or rigidity. 8.
The Polyelectrolyte Effect
Many naturally occurring multivalent saccharide ligands are anionic. Placement of specific anionic groups can be critical for saccharide recognition (see Section II.A.4), but the charge density resulting from a multivalent display of such groups can influence their binding activities. In analogy to protein–DNA interactions, protein binding to highly anionic saccharide derivatives (such as heparan sulfate) can benefit from the polyelectrolyte effect. Charged functional groups on both lectin and ligand mobilize counterions when solvated. Ligand binding releases these ions into the bulk solution, a process that is entropically favorable (Fig. 5F). Additional energetic gains will result from multiple successive attachments [51]. III.
ANALYZING MULTIVALENT BINDING EVENTS
Publications focusing on assessing multivalent interactions often highlight the difficulties associated with assessing binding kinetics and thermodynamics for such processes [11,15,39]. Determining the true equilibrium constant for a multivalent binding event is complicated because, as described above, multiple types of binding interaction may contribute to the interaction under investigation. Thus, an inability to dissect the contributions of monovalent binding, multiple site binding, subsite binding, rebinding of multiple epitopes within one or more binding site, and other effects such as steric stabilization renders the analyses of these systems difficult. The evaluation of protein–carbohydrate interactions is complicated by the tendency of these substances to participate in multivalent binding and the low affinities of their monovalent interactions. These features dictate that the assay used to measure ligand activities be chosen carefully. Assays of several different types may be required to properly evaluate ligand potency. Moreover, generating data relevant to ligand function under physiological conditions can be a difficult and onerous task. Because throughput can be limited in assays that closely mimic physiological conditions, the best assay for screening potential inhibitors might necessarily be artificial, and also may not identify the best ligand (see Sections VI.4 and VII.B.2). Some of the more effective methods that have been employed to evaluate inhibitors of protein–saccharide interactions are described in the subsequent sections. A.
Fluorescence Anisotropy
Fluorescence anisotropy is a technique that can be used to monitor low-affinity monovalent lectin–ligand interactions [52–54]. An advantage of this technique is that it can be used directly to determine ligand binding constants and also to confirm that ligands are competing for a specific saccharide binding site. The basis of the method is the detection of changes in the fluorescence anisotropy of a ligand-bound fluorophore. When a protein binds the labeled ligand, there is an increase in the rotational correlation time of the fluorophore because the resulting complex is large and tumbles more slowly than the free ligand. An increase in fluorescence anisotropy results (Fig. 6), and these changes can be analyzed to afford a binding constant. Moreover, binding affinities of unlabeled ligands can also be obtained accurately and
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Figure 6 Schematic depiction of a fluorescence anisotropy assay. Fluorescently tagged molecules are excited by plane-polarized light; only molecules in the proper orientation are excited. Emitted light is detected in the original plane and in the perpendicular plane. The quantity of fluorescence observed in the two orientations is determined by the rate of tumbling, which depends on particle size and relates to binding.
efficiently by monitoring their ability to compete with a fluorescently labeled control ligand. The disadvantage of this method is that high concentrations of protein are needed to accurately determine the weak association constants typically observed for protein–carbohydrate interactions. Even when the protein can be readily produced or isolated, the high concentrations required can result in protein aggregation and/or precipitation. Overall, the method has many advantages, but its applicability depends on the system. B.
Turbidimetric Analysis
Turbidimetric analysis is useful for the study of multivalent interactions that result in the formation of large protein aggregates. The method is typically employed to evaluate the ability of multivalent saccharide derivatives to promote lectin crosslinking (Fig. 7). To conduct the assay, multivalent ligand and lectin are mixed and allowed to form cross-linked complexes; the formation of large protein aggregates is monitored by changes in the optical density of the solution [55–57]. The abilities of various multivalent ligands to cross-link lectin is correlated with their relative affinities. As a measure of monovalent ligand function, inhibitory potencies of these species can be obtained by evaluating their abilities to inhibit lectin cross-linking by a specific multivalent ligand. This analysis is complicated, however, by the possibility
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Figure 7 Multivalent ligand-induced lectin cross-linking. Multivalent ligands, which are able to simultaneously span two lectin molecules, can form cross-linked aggregates. These aggregates are detectable by spectroscopic means in a turbidimetric assay.
that the monovalent ligands could initially contribute to optical density increases. In principle, they could occupy binding sites on the lectin that do not directly result in cross-linking, thereby releasing epitopes on the multivalent ligand that then attract more lectin to the aggregate. The complexities of comparing monovalent and multivalent ligands by turbidimetric analysis are not the only disadvantages of this method. One potential problem is that it does not effectively report on the activities of multivalent ligands that act by simultaneously binding to multiple sites within a lectin oligomer. In addition, the relative activities of a multivalent ligand for two related lectins cannot be determined because the inherent solubilities of the lectins and their cross-linked complexes will differ. Importantly, because precipitation of the lectin–ligand complex occurs, the process is generally under kinetic control; consequently, the relative potencies of ligands may not correlate with their intrinsic affinities for the lectin. As with most assays of multivalent ligand function, the species being detected is not the initial protein–ligand complexation event. Still this assay is widely used because it can be conveniently and rapidly performed. C.
Enzyme-Linked Immunosorbant Assays
A wide range of variations on the enzyme-linked immunosorbant assay (ELISA) have been used to evaluate monovalent and multivalent inhibitors owing to the convenience and utility of these methods (Fig. 8) [58,59]. Generally, one binding partner is immobilized on the bottom of a microtiter plate, and a binding counterpart, labeled with a reporter, is allowed to adhere to the immobilized partner. Monovalent and multivalent compounds can be tested for their ability to inhibit the binding interaction. The reporter group can be a radiolabel, fluorophore, biotin, conjugated antibody, peroxidase, or other enzyme conjugate. In the case of a protein–saccharide interaction, either the lectin or the ligand can be immobilized. Inhibitory potencies obtained from ELISA and related assays provide an estimate of the functional affinity of various ligands, although confounding parameters can complicate the analysis. The immobilized partner is often displayed in a random mixture of orientations, some of which may not be optimal for binding. All soluble ligands will encounter these various receptor orientations; therefore a comparison of ligand activity generally affords the proper qualitative relative ranking. One problem with the variety of orientations observed is that they may not reflect those found in natural settings. Consequently, the artificial ligand spacing inherent in the ELISA can introduce a bias to
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Figure 8 An example of an ELISA. Monomeric lectin is immobilized in the bottom of a microtiter well. Labeled multivalent ligand binds to the lectin. The assay can also be set up to observe lectin binding to immobilized ligand.
the assay. ELISAs, however, are simple to perform and can be used for rapid screening of multiple inhibitors. D.
Cell Agglutination
The activities of both monovalent and multivalent ligands can be assessed in a cell agglutination assay if the targeted receptor has the ability to agglutinate cells. This assay is generally applied to evaluate the potencies of ligands for a multivalent lectin that recognizes saccharide epitopes on red blood cell surfaces, thereby causing hemagglutination (Fig. 9) [60]. The lectin and isolated cells are combined in a microtiter plate with conical wells. In the absence of lectin, or in the presence of an inhibitor, the cells eventually pellet by gravity in the bottom of the well. In contrast, when the cells are cross-linked they form a large aggregate network that covers the well. Inhibition of agglutination is detected by visual inspection. The human component of the analysis renders this assay subject to potential bias, and it also makes it difficult to rapidly screen ligand libraries. Nevertheless, hemagglutination is a convenient method of identifying either monovalent or multivalent inhibitors of lectin–ligand binding. E.
Surface Plasmon Resonance
Surface plasmon resonance (SPR) is an analytical method that can be used to evaluate protein–ligand interactions. It has only recently been applied to probe lectin–ligand interactions [11,61–66]. In SPR, the amount of material bound to a surface is quantified by monitoring the absorption of an evanescent wave. One binding partner is attached to the surface by covalent or noncovalent interactions, and its counterpart
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Figure 9 Hemagglutination of red blood cells. Red blood cells are combined with a lectin that can recognize cell surface carbohydrate ligands. In the presence of inhibitors, the cells pellet, forming a visually identifiable spot in the well. Because cross-linked cells cannot pellet; the well maintains a homogeneous red tint.
is allowed to flow over the surface (Fig. 10). Receptor–ligand association is monitored to generate an apparent on-rate, and dissociation to afford the apparent offrate. From these values, an equilibrium constant can be obtained. To overcome the complications associated with monitoring ligand function in a heterogeneous system, a competition assay can be employed in which inhibitors are evaluated for their ability to block the target binding interaction. Thus, multiple ligands can be screened rapidly with a single binding surface [67–69]. One advantage of SPR is that only small amounts of material are required for the analysis. In addition, the availability of automated sample injection and monitoring facilitates the rapid screening of large numbers of compounds. Since confounding interactions can complicate the analysis, the design and implementation of an optimal binding surface is critical for the generation of meaningful data. IV.
PLANT LECTIN–SACCHARIDE INTERACTIONS
The carbohydrate binding properties of plant lectins have been widely studied and exploited. Because many plant lectins can be readily isolated, numerous studies of
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Figure 10 Surface plasmon resonance analysis. A surface displaying ligand is examined under conditions of flow. Injection of lectin results in an increase in signal observed in the association phase of the curve. At equilibrium the surface achieves maximal binding. Measurement of the dissociation can yield off-rates. Competing ligands in solution can also be assayed.
these receptors have been conducted. The results serve as a foundation for understanding protein–carbohydrate interactions. Plant lectins can be classified by their source, and these groups include the legume, cereal, Amaryllidaceae and related families, and Moraceae and Euphorbiaceae lectins [5]. The lectins in all these classes assemble into multimeric proteins and can adopt a range of different quaternary structures including di- and tetrameric arrangements. The multimers formed afford multivalent displays presenting saccharide binding sites in a variety of spacings and orientations with documented multiplicities of 2 to as many as 12 binding sites, as in the case of the snowdrop lectin [70]. X-ray crystallographic studies have revealed the spatial relationships in many of these multiple binding site arrangements [1,5,42,71,72]. With the diversity of multivalent binding site displays and the large amount of structural and biophysical data available on them, highly accessible plant lectins serve as excellent receptors for the study of multivalent protein–carbohydrate interactions. A.
Concanavalin A
One of the most widely studied lectins to date is the glucose/mannose binding legume lectin from Concanavalia ensiformis (ConA) [73]. ConA is a tetramer at neutral pH, and X-ray crystallographic analyses revealed the tetrahedral arrangement of the protomers (Fig. 1) [19]. Each subunit contains a saccharide binding site; therefore, ConA can bind up to four saccharide epitopes simultaneously. Significant insight into the
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molecular basis for ConA–saccharide interactions has been obtained through X-ray crystallographic analyses of ConA and its saccharide complexes (Figs. 1 and 2) [19]. The binding site is organized by side chain interactions with two divalent metal cations, Mn2⫹ and Ca2⫹ (Fig. 2), and the minimum saccharide determinants that bind ConA are glucose and mannose residues [73]. The lectin exhibits a three- to fourfold binding preference for mannose over glucose and does not bind fucose or galactose appreciably [74–76]. Hydrogen bonding contacts from the protein to the 3-, 4-, and 6-position hydroxyl groups of the carbohydrate dictate ConA saccharide binding specificity. ConA binds relatively weakly to monosaccharides, but it interacts with higher affinities with oligosaccharides and glycoproteins [77]. For example, ConA binds the trimmanoside methyl 3,6-di-O-(␣-D-mannopyranosyl)-␣-D-mannopyranoside with approximately 100-fold higher affinity than methyl-␣-D-mannopyranoside [20,23,78,79]. The well-characterized molecular features of ConA–saccharide interactions and the protein’s ability to participate in multivalent recognition events render ConA an excellent subject for the study of multivalent recognition. 1.
Synthetic Multivalent Ligands Are Effective Inhibitors of Concanavalin A
A number of natural multidentate ligands, including oligosaccharides and glycoproteins [73,77,80,81], serve as highly effective ligands for tetrameric ConA. While these ligands provide useful information about ConA binding, the structures are so difficult to vary systematically that it is difficult to analyze binding data from such substrates. Synthetic ligands have been used, therefore, to address fundamental issues with regard to multivalent recognition by ConA. Major ligand classes that have been employed include low molecular weight derivatives, dendrimeric ligands, and linear polymers. Some of the most potent inhibitors of ConA are multidentate ligands synthesized by the ring-opening metathesis polymerization (ROMP). ROMP has emerged as an attractive approach to the synthesis of functional polymers [82]. The advent of defined, functionalized group tolerant, metal alkylidine initiators has offered new opportunities for the creation of tailored materials with significant biological properties. A generalized mechanism for the polymerization involves an initiation through coordination of the metal alkylidine with a strained cyclic alkene monomer (Fig. 11). A [2 ⫹ 2] cycloaddition between the initiator (2) and a monomer (1) unit generates a metallocyclobutane intermediate (3) that undergoes a ring opening to relieve strain, thereby generating a new metal alkylidene. This intermediate metallocarbene (4) can react with another monomer, and the sequence of events can continue until the monomer is consumed. The reaction can be terminated by the addition of an electron-rich enol ether (5), which results in the production of an unreactive metal carbene (7) and a terminated polymer chain (6). Because ROMP can be a living process and because the rate of initiation exceeds that of propagation, oligomers of controlled length and narrow molecular mass distribution can be generated. In addition, both the catalyst and the electron-rich enol ether afford an opportunity to attach unique end labels to either polymer terminus. Thus, ROMP offers advantages for the production of biologically active polymers [83]. To explore interactions of multivalent ligands with ConA, polymers with pendant mannose or glucose residues have been generated by ROMP. The saccharide epitopes were attached to norbornene monomers through C-glycoside linker units
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General scheme for ring-opening metathesis polymerization (ROMP). Monomer 1 and catalyst 2 continue to react until the monomer has been consumed yielding polymer 4, which can be end-capped with functionalized allyl ether 5.
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and polymers of high molecular mass were produced. These materials were highly effective inhibitors of ConA-facilitated red blood cell agglutination: they were up to 105-fold more potent than ␣-methyl glucopyranoside [31]. Other nonnatural saccharide-substituted polymers have also been found to be effective inhibitors of ConA [84,85]. In addition, dendrimers [86–88] and low molecular weight ligands [44,89– 93] show levels of activity that exceed those of mannose, although they do not approach those of the ROMP-generated polymers. Together, these results highlight the range of inhibitory activities that can be manifested by synthetic multidentate ligands. 2.
Specificity in Multivalent Recognition: Concanavalin A Discriminates Between Related Multidentate Ligands
The specificity of ligand binding for a multivalent protein–carbohydrate interaction was explored by using ConA. ConA binds both glucose and mannose residues, but it binds monovalent C-mannoside 9 with a slightly (0.2 kcal/mol) more favorable free energy than the corresponding C-glucoside 8 (Fig. 12) [54]. Whether the small difference observed in the monovalent binding event would be manifested with the corresponding multivalent ligands has been explored. By examining the ability of glucose- and mannose-substituted polymers to inhibit ConA-mediated agglutination, the inhibitory potencies of mannose-modified polymer 11 could be compared with the corresponding glucose counterpart 10 in a hemagglutinaton assay (Fig. 12). Not surprisingly, no difference in potency was detected between the glucose and mannose monovalent C-glycosides 8 and 9. The activity difference between the glucose- and mannose-substituted polymers, however, is greater than 100-fold [31]. Consequently, multivalent interaction yields higher specificity as well as affinity. An enhancement of specificity through multivalent saccharide display is also observed in the binding of cluster glycosides of N-acetylgalactosamine to the mammalian hepatic Gal/ GalNAc specific receptor with subnanomolar binding constants (see Section V.C) [94]. When evaluated for binding to the lectin from Bauhinia purpurea, resin-bound saccharides also elicited a dramatic increase in observed functional affinity [38]. Enhanced specificity through polyvalent binding to multivalent carbohydrates has also been observed in interactions with cell surface L-selectin (see below: Sections VII.B.2–VII.B.3) [95]. Enhancement of specificity through multivalent recognition is likely to be an important feature of saccharide recognition events in nature. 3.
The Chelate Effect: Multivalent Ligands That Can Span Two Saccharide Binding Sites Within the ConA Tetramer Are the Most Potent Inhibitors
Multipoint binding leads to an amplification in specificity, perhaps at least partly accounting for the high selectivity of multidentate ligand binding by ConA. In multipoint binding, multiple saccharide epitopes would coincidentally contact ConA, and if this model is important, ligands that could simultaneously occupy more than one saccharide binding site within the ConA tetramer would be expected to be more potent inhibitors. The large distance between the binding grooves, predicted to be ˚ from X-ray crystallographic analysis, is easily spanned by linear approximately 65 A polymers. Although few polymerization strategies offer control over polymer size, ROMP can be used to generate polymers of defined length.
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Figure 12 Kiessling’s C-gluco- (8) and mannopyranosides (9) demonstrate increased functional affinity and specificity when displayed as bivalent mannose (13) and glucose (12) ligands.
Kanai et al. set out to prepare and determine the ConA inhibitory potencies of series of mannose-substituted oligomers differing in length (Fig. 13) [84]. Studies by the Grubbs group suggested that ruthenium carbene complexes can carry out living polymerization with the initiation step approximately eightfold faster than propagation [82]. Therefore, by varying the ratio of monomer 14 to initiator 15 in the reaction mixture, multidentate mannose ligands 16a–c of controlled length could be assembled. The effect of polymer length on inhibitory potency was assessed in a ConA-mediated cell agglutination assay. Interestingly, the relative potency of the
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Figure 13
ROMP polymers of defined length. Varying the ratio of monomer (14) to catalyst (15) affords control over the average polymer 16 length (n).
multivalent displays (on a saccharide residue basis) initially increased significantly with increasing polymer length, but eventually reached a plateau. Molecular modeling studies suggest that when polymer 16 is composed of about 25 repeat units, it ˚ required to simultaneously place saccharide residues in two bindcan span the 65 A ing sites within the ConA tetramer (Fig. 14). As predicted, the potency of the oligomers beyond that length did not increase. An independent assay, in which surface plasmon resonance (SPR) was used to monitor inhibition of ConA binding to a glycolipid surface, reproduced the trends [68]. Specifically, a maximal functional affinity increase was observed for polymer 16b, which consisted of 25 monomer units. ConA structural data provides a context for interpreting mechanisms of multivalent ligand function; consequently, these studies represent strong evidence that lectins can use the chelate effect to increase the strength of a protein–carbohydrate interaction. Such mechanisms are likely also important in vivo.
Figure 14
(A) Multivalent polymer binding within one binding site. (B) Polymers of sufficient length can span two binding sites simultaneously. (C) Longer polymers yield no increase in potency.
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High Local Ligand Concentration Contributes to ConA Binding
Despite the importance of the chelate effect in the increased functional affinities of ConA for the multidentate ligands described above, the chelate effect is not the only contributing mechanism. If chelation was the only important process, oligomers composed of more residues than are required to span the binding sites should display decreased potencies when evaluated on a saccharide residue basis because noninteracting residues would detract from the observed affinity. This was not the case, however, inasmuch as potency did not decrease. Therefore, the potencies of the longer polymers are greater than the chelation model predicts (Fig. 14). We suspect that the high local concentration of saccharide residues available with these polymers decreases the rate of dissociation of the multivalent ligands, making rebinding more favorable. This statistical enhancement mode of multivalent binding also contributes to the increase in the observed affinity of ligands unable to span two sites (i.e., 1 mM for sLex) [211,212,224]. ROMP generated polymers bearing the simple sulfated saccharide derivatives 3sulfo- and 3,6-disulfogalactose were effective inhibitors of E-, P-, and L-selectin in a cell binding assay. Significantly, the 3,6-disulfogalactose-substituted derivative specifically targeted P-selectin. The IC50 of the polymer was 84 M, as determined on a per-saccharide-residue basis, while the IC50 of sLex was 3.4 mM [227]. Large liposomal arrays are also highly effective inhibitors of the selectins. For instance, multivalent liposomes bearing sLex inhibited binding of HL-60 cells to immobilized E-selectin with potencies 750-fold higher than monovalent analogs [228]. Other liposomal sLex displays with enhanced affinities also have been reported [210,223,229]. These higher order multivalent displays can act by several mechanisms including multisite binding and statistical and steric effects. Factors governing specificity and affinity for the lectins discussed earlier are also relevant in these examples. B.
Inhibitory Potencies of Multivalent Ligands for the Selectins Are Influenced by Assay Method
It is difficult to develop an appropriate assay for all potential selectin ligands because multivalent ligands function by means of a very broad range of mechanisms. An added complication is that the selectins function under conditions of shear flow. Conducting high-throughput assays under conditions of flow is complex, and therefore the activities of potential ligands are generally evaluated under static conditions. A widely employed method involves monitoring the abilities of molecules to inhibit cell binding to an immobilized selectin (Fig. 8). This assay is convenient and can lead to the identification of potential lead structures; however, the cell surface presentation of the selectins may be quite important for their function [205,230–233]. Moreover, the static assay conditions may not reproduce ligand activities that might be observable under flow conditions [95]. 1.
The Presentation of the Receptor Is Important for Assessing Multivalent Ligand Activity
The importance of selectin presentation was illustrated in experiments conducted by Stahn et al., who compared the E-selectin inhibitory activity of BBA2, an anti-Eselectin monoclonal antibody, to that of sLex-decorated liposomes in two different static assays [223]. When the agents were evaluated for inhibition of HepG2 cell binding to E-selectin immobilized in a microtiter well, the antibody and the liposomes had similar activities. The antibody, however, was approximately 100-fold more active than the liposomal preparation at inhibiting binding of HepG2 cells to activated HUVEC cells expressing E-selectin. These results demonstrate the need to examine multiple assays and to critically evaluate the data obtained.
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Static Assays Afford Results Different from Those Carried Out Under Dynamic Conditions
Many biological processes take place under dynamic rather than static conditions. For example, the ability of the selectins to mediate the dynamic process of leukocyte rolling is a critical aspect of their function; yet most selectin inhibitors have been evaluated in static assays. A study evaluating multivalent L-selectin inhibitors revealed dramatic differences in their activities in static cell free versus dynamic cell rolling assays. To explore the recognition of multivalent ligands by L-selectin, the ring-opening metathesis polymerization method (ROMP) was used to generate materials presenting Lex epitopes differing in sulfation pattern [95]. These compounds were designed to mimic the glycoprotein mucins that bind L-selectin, such as GlyCAM-1, by displaying multiple copies of sulfated saccharide epitopes on an extended polypeptide backbone. Oligomers bearing 3⬘,6⬘-disulfo Lewis x(Glc) (61) and 3⬘,6-disulfo-Lewis x(Glc) (62) were more potent than their monovalent counterparts, 63 and 64, in assays to determine their ability to inhibit an L-selectin–IgG fusion protein binding to immobilized heparin (Fig. 31). However, their abilities to inhibit the rolling of L-selectin-transfected cells on GlyCAM-1 were very different. Only the 3⬘,6disulfo-Lewis x(Glc) polymer 62 (Fig. 31) was able to prevent rolling, and it did so with high efficacy (IC50 = 1 M; 15 M based on saccharide residue concentration). These results suggest that fluid flow may play an important role in the specificity of selectin–ligand interactions. Intriguingly, multivalent ligand 62 may bind cell surface L-selectin through multipoint attachment. Thus, multivalent synthetic ligands along with their natural counterparts may possess the ability to cluster L-selectin on the cell surface (Fig. 5C). 3.
Synthetic, Multivalent Ligands Designed to Induce L-Selectin Shedding
The release of a cell surface protein, often termed shedding, can serve to regulate its density on the cell surface and also affects the concentration of the soluble form in circulation [234]. L-selectin shedding is believed to occur during the inflammatory response, and this process may be involved in regulating cell rolling rates [187]. We hypothesized that multivalent ligand binding may cluster L-selectin and thereby trigger shedding. To test this idea, the ability of the 3⬘,6⬘-disulfo-Lewis x polymer 62 to cause L-selectin release from the cell surface was evaluated [41]. The amount of L-selectin on the cell surface of neutrophils after treatment with ligand was assessed by flow cytometry using the anti-L-selectin antibody, DREG56. Although the monovalent compound 64 had no effect on L-selectin levels, exposure of neutrophils to polymeric compound 62 led to a reduction in the amount of cell surface L-selectin. The ability of multivalent ligand 62 to induce L-selectin shedding suggests that natural ligands might function similarly. The demonstration that synthetic ligands can be designed to promote the shedding of a cell surface receptor has implications for understanding the mechanisms cells use to control protein display and for manipulating the concentration of cell surface receptors. The ability to trigger this response by exposure to a synthetic multivalent ligand also suggests a new therapeutic strategy for targeting the inflammatory response.
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Figure 31 Kiessling’s disulfated Lex constructs 63 and 64 elicited different physiological effects when appended on multivalent displays to afford 61 and 62.
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SUMMARY
Multivalent protein–carbohydrate interactions are prevalent in biological recognition processes. Despite their important roles, an understanding of these interactions is only beginning to emerge. This understanding is facilitated by new developments in the chemical synthesis of multivalent ligands and the use of those ligands to explore and manipulate multivalent recognition processes. Applications for such ligands are widespread, ranging from the investigation of cellular recognition to agents for tissue-selective drug delivery to molecules that can be used to evoke cellular responses. With a growing appreciation of the importance of multivalent interactions, these systems offer intriguing opportunities and challenges for chemistry and biology.
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209. 210. 211. 212. 213. 214.
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9 Designing Novel Multivalent Glycotools for Biochemical Investigations Related to Sialic Acid Rene´ Roy University of Ottawa, Ottawa, Ontario, Canada
I.
INTRODUCTION
Sialic acids constitute a family of more than 30 neuraminic acid derivatives varying by the nature of their substituents (acetyl, glycolyl, phosphate, sulfate) and by their relative positioning around the pyranose ring [1]. The most common member of this rather unusual nine-carbon amino acid sugar (5-amino-3,5-dideoxy-D-glycero-D-galacto-non-2-ulopyranosonic acid) is represented by N-acetylneuraminic acid (Neu5Ac, 1) (sometime abusively coined sialic acid itself ) (Scheme 1). Sialic acids are common mammalian sugars that usually end oligosaccharide sequences of glycolipids (gangliosides), N- and O-linked glycoproteins, and some proteoglycans. They are also found as ␣-(2-8/9)-linked polysaccharides in encapsulated bacteria. As such, sialic acids are forefront carbohydrate haptens responsible for a wide range of recognition events [2]. Cell surface sialosides are involved as anchoring motifs for microbial attachment. Various pathogenic agents such as viruses (influenza, coronavirus, Sendai, polyoma, rotaviruses), bacteria and bacterial toxins (Pseudomonas aeruginosa, Helicobacter pylori, E. coli, Vibrio cholerae, Bordella pertussis; cholera, tetanus toxins), and parasites (Streptococcus suis, Plasmodium falciparum, Trypanosoma cruzi) can adhere to and colonize host tissues after binding to sialosides [3]. It has also been demonstrated that bacterial infections [4] and cancer metastasis [5] can be prevented by blocking receptor sites with high serum carbohydrate concentrations including sialic acid. It is also involved in selectin-mediated cell adhesion related to leukocytes over recruitment to infected or damaged tissues [6]. 277
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Scheme 1
Unfortunately, medicinal applications of carbohydrate binding protein inhibitors suffer from major drawbacks. Except for a few marginal cases, carbohydrates show deceptively low binding affinities toward their receptor counterparts [7]. Moreover, simple or more complex oligosaccharides are poorly bioavailable and are rapidly catabolized through various glycosidases. A few strategies are being pursued to overcome these difficulties. Among these, the syntheses of carbohydrate analogs (deoxy, fluoro, epi, etc.), conformationally restricted analogs, and glycomimetics have been more or less successful. One promising example of rational drug design has recently emerged in the field of influenza flu virus neuraminidase inhibitors [8,9]. Compounds that mimic the transition states involved in ␣-sialoside hydrolyses have surpassed the classical lead Neu5Ac2en (2) (Ki 4 M). Thus, Glaxo Wellcome’s Zanamivir (4guanidino-Neu5Ac2en, GG167, 3) with a Ki of 0.1 nM [8] and Gilead Sciences prodrug GS4104 (4, Ki 1 nM) [9] have reached clinical phase II for a long-awaited drug treatment against flu virus infections. GS4104 proved effective against both influenza A and B strains in test animals. Another useful strategy for the design of potent microbial antiadhesins may rely on the rational syntheses of various multivalent glycoforms that can mimic multiantennary glycoproteins. It can be speculated that common oligosaccharide sequences might express further specificity and enhanced avidity through precise multivalent architectural antigen presentation. Numerous cases exist to point toward multivalency or ‘‘cluster’’ effects to ‘‘boost’’ carbohydrate–protein bindings [10]. Multivalent macromolecules would be particularly appealing for respiratory, gastrointestinal, and urinary tract infections where bioavailability does not constitute a major problem. Such novel, nonimmunogenic biopolymers may also find applications as carriers for drug delivery and as affinity adsorbents, both in vitro and in vivo, in cases calling for natural killer cell and macrophage activation. We and others have previously demonstrated that multivalent neoglycoconjugates constitute powerful inhibitors in a number of generally low-affinity carbohydrate–protein binding interactions [11–16]. Potent multivalent neoglycoconjugates
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have been scaffolded onto a wide range of carriers including polymers [11], polyamino acids [12], cyclodextrins [13], calix[4]arenes [14], carbohydrates [15], and dendrimers [16]. This last class of scaffolds is particularly appealing because the effects of size, shape, and valency can be controlled at will [17]. This chapter focuses on ongoing activities regarding the syntheses of multivalent sialosides. II.
SOURCES OF SIALIC ACID
The cost for commercially available sialic acid has dramatically declined over the last 10 years. Depending on the amount purchased, the cost can be as low as approximately $CDN 20–$CDN 30/g. A practical source, requiring no particular skills, consists of isolating sialic acid through a mild acid hydrolysis of the Collocalia mucin isolated from edible bird’s nest [18], which can be purchased from any Chinese grocery [$CDN 100/$CDN 200 g). The mucin is essentially a sialic acid–rich glycoprotein. Thus, 10 g (5% w/w) can be obtained in less than a week. Alternatively, sialic acid can be isolated from egg yolk [19], from cow’s milk [20], or from the complete acid hydrolysis of colominic acid, a bacterial polysaccharide produced by both E. coli K1 and Neisseria meningitidis serogroup B or C [␣-(2,8/9)]-polysialic acid [21]. It is also possible to produce several discrete oligomers by controlled acid hydrolysis of the polysaccharides [22]. Additionally, it has been feasible to produce the analogous N-glycolylneuraminic acid (NAc replaced by NCOCH2OH, Neu5Gc) and their corresponding oligomers by strong base hydrolysis of the N-acetyl groups of the polysaccharide (2 M NaOH, 110⬚C, 7 h); treatment with acetoxyacetyl chloride; followed by de-O-acetylation, and hydrolysis. Alternatively, the de-N-acetylated polysaccharide can be treated with acryloyl chloride and then reductively ozonolyzed [23]. This N-glycolylsialic acid analog is the key determinant epitope of the Hanganutziu–Deicher antigen [24] found in some patients who have been treated with animal serum (serum sickness). Moreover, it has been found in large quantity in tumor cells having abnormally high N-glycolyl GM3-ganglioside. A.
Useful Sialic Acid Derivatives as Precursors in Neoglycoconjugate Syntheses
As mentioned above, the sialic acid residue itself constitutes the key immunodominant epitope in several biological interactions. It was therefore appealing to generate a wide range of neoglycoconjugates containing solely sialic acid or its analogous Nglycolylated derivative. Nowadays, sialic acid can be readily prepared as O-, S-, N-, and C-glycosides. Stereospecific access to the first three forms can be achieved with complete anomeric stereocontrol. However, great difficulty still attends the synthesis of pure ␣-linked C-sialosides [25]. Fortunately, reports describing the use of samarium diiodide (SmI2) (Barbier’s conditions) seem to open the door toward improved stereocontrol [26]. The following subsections briefly highlight aspects of our approach toward the preparation of suitably functionalized sialosides. 1.
Stereospecific Anomeric Functionalization Under PTC Conditions
Generally, N-acetylneuraminic acid is ␣-glycosidically linked to D-galactose or to DN-acetylgalactosamine residues through ␣-(2–3/6) linkages or to another N-acetylneuraminic acid residue in ␣-(2–8/9) linkages [1]. In most cases, terminal Neu5Ac
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residues constitute the immunodominant epitopes; that is, most binding interactions occur through intrinsic Neu5Ac functionality, with the carboxyl group constituting the key polar group [27]. Based on cumulative observations [1], initial efforts were centered around the syntheses of ␣-sialoside derivatives alone. Anomeric phase transfer catalysis (PTC) has been systematically shown to take place through inversion of configuration through a seemingly SN2-type mechanism [28,29]. In spite of its quaternary nature and the absence of a potential participating group, acetochloroneuraminic acid (5), having an axial -chloro substituent, has always provided clean and high-yielding anomeric inversion with a wide range of nucleophiles under mild PTC conditions [29]. When tetrabutylammonium hydrogen sulfate (TBAHS) was used as phase transfer catalyst, 1 M sodium carbonate as aqueous phase, and ethyl acetate (or dichloromethane) as organic phase, -chloride 5 provided exclusively ␣-sialylated derivatives 6–11 in excellent yields (Scheme 2). The only by-product occasionally formed appeared to be peracetylated Neu5Ac2en (2) derivative, resulting from dehydrochlorination through an elimination side reaction (E2). For instance, treatment of chloride 5 with thioacetic acid, sodium azide, 4nitrophenol, 4-hydroxybenzaldehyde, 4-nitrothiophenol, or thiophenol afforded derivative 6 (66%) [30], 8 (94%) [31], 9a (90%) [32], 9b (65%) [33], 10 (81%) [34], or 11 (80%) [34], respectively. Chemoselective (35) de-S-acetylation of 6 (H2NNH2HOAc, DMF, room temperature < 30 min) or NaOMe in methanol at ⫺40⬚C [20] afforded 1-thioderivative 7 in 88% yield. The foregoing ␣-sialo derivatives were suitably functionalized for coupling to various multivalent carriers (see below). B.
Using Novel ‘‘Active–Latent’’ Glycosylation Strategy to Produce Sialyloligosaccharides
The biological significance of N-acetylneuraminic acid containing oligosaccharides has stimulated remarkable progress in devising glycosylation strategies [36]. However, efficient protocols for building sialylated oligosaccharides from monosaccharide components is still a major challenge. Initially, acetochloroneuraminic acid (5) has been the glycosyl donor most widely used for the synthesis of ␣-sialosides, but its efficacy necessitates the use of a temporarily incorporated participating group at C3 [37]. Phosphite [38] and S-ethyl xanthate [39] derivatives have met some successes, while thioglycosides remain the method of choice [40]. The ‘‘armed’’ (ether pro-
Scheme 2
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tecting groups at C2) and ‘‘disarmed’’ (ester protecting groups at C2) n-pentenyl glycosylation strategy introduced by Madsen and Fraser-Reid [41] has proven to be a powerful tool for complex oligosaccharide syntheses that also is applicable to thioglycosides and few other glycosyl donors (reviewed in Ref. 42). Despite the versatility of this approach, there remains opportunity to further fine-tune the leaving ability of the glycosyl donor and thus to realize a greater potential for oligosaccharide syntheses. Another versatile strategy, coined the ‘‘active–latent’’ glycosylation strategy, in which the reactivity of the carbohydrate units can be directly controlled by the aglycone, together with the differential protection of the glycone itself, enabled the synthesis of various oligosaccharide donors [34,43–47]. Two realizations were found to be analogous: that the nature of the substituents on the aryl thioglycosides could be used to modulate the nucleophilicity of the anomeric sulfur atom and that protecting groups that could be used as ‘‘armed’’ or ‘‘disarmed’’ glycosyl donors. Thus an electron-donating group (EDG: e.g., Me, OMe, NHAc, H) placed in the para position of the aryl moiety of an aryl thioglycoside provided ‘‘active’’ or ‘‘armed’’ glycosyl donors, while electron-withdrawing groups (EWG: e.g., NO2, Br, Cl) afforded ‘‘latent’’ or ‘‘disarmed’’ thioglycosyl donors that could be used as building blocks in blockwise oligosaccharide syntheses. ‘‘Latent’’ thioglycosyl derivatives, possessing one free hydroxyl group and corresponding to ‘‘temporary inactive’’ species, serves as glycosyl acceptors. Their reactivities can be ‘‘turned on’’ by transforming their electron-withdrawing thioaryl substituents (e.g., NO2) into electron-donating groups (e.g., NHAc), thus ‘‘reactivating’’ the sulfur atoms toward electrophilic promoters usually employed in glycosylation reactions. Alternatively, the ‘‘active’’ thioglycosyl donors should already possess EDG substituents on their aryl moieties. The ‘‘latent’’ thioglycosyl acceptors can be glycosylated with ‘‘active’’ thioglycosyl donors by using thiophilic promoters. The disaccharide can then be transformed into an ‘‘active’’ glycosyl donor by modification of the aryl substituents. Taking advantage of both ‘‘active–latent’’ and ‘‘armed–disarmed’’ concepts, it was possible to modulate the reactivities of thioglycosyl donors and acceptors by changing both the nature of the substituents in the para position of the aglycone’s thiophenyl group and the protecting groups at the C2 position [34,43–46]. This has expanded the reactivity differences between thioglycosyl donors and acceptors and thus provided improved flexibility for the proper choice of glycosyl donors and acceptors toward building complex sialylated oligosaccharides. Initially, the method was based on the differential reactivity conferred on each of the partners by the nature of the protecting groups and by the intrinsic nucleophilicity of the thioaryl leaving groups. However, as the method evolved, it became clear that the choice of the promoter was also an important factor to take into consideration. Indeed, it was demonstrated that a ‘‘disarmed’’ thioglycoside could be activated in the presence of powerful thiophilic promoters such as N-iodosuccinimide/trifluoromethanesulfonic acid (NIS/TfOH), whereas it remained inactivated in the presence of weak thiophilic reagent such as iodonium dicollidine perchlorate or methyl triflate [43,45]. An example of this strategy is illustrated in Scheme 3, which describes the synthesis of a positional isomer of sialyl LewisX. For instance, armed glycosyl donor phenyl 2-thio-␣-sialoside 11 was chemoselectively activated with NIS/TfOH in the
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Scheme 3
presence of latent 4-nitrophenyl thiolactoside 12 to provide sialyllactose derivative 13 in 47% yield. Then armed–active perbenzylated ethyl thiofucoside 14 was used to further regioselectively glycosylate trisaccharide 13 at O2⬘ of the galactose residue to give sialylated tetrasaccharide 15 in 63% yield (46). 4-Nitrophenyl sialyl-1-thiolactoside 13 still possesses an aglycone that can be further transformed into an active glycosyl donor (NO2 → NH2 → NHAc) or into a reactive acrylamido monomer (NH — COCH — —CH2) for copolymerization purpose [48]. C.
Syntheses of Suitably Functionalized Sialosides
It is clear that multivalent sialosides may offer numerous opportunities for ‘‘medicinal glycobiology.’’ They can be used to increase receptor binding interactions in areas such as flu virus inhibition of hemagglutination, anti-inflammatory agents (selectin antagonists), cancer vaccines and immunodiagnostics, and in treating gastrointestinal infections. Moreover, inasmuch as sialic acid receptor themselves might be organized as clusters, it appeared sound to synthesize multivalent glycoforms varying in molecular weights, shapes, valencies, and geometries to ‘‘scan’’ wide ranges of
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topographical areas. To this end, suitably functionalized N-acetylneuraminic acid derivatives were required. A convergent approach in which various sialoside haptens and other carbohydrates of interest could be attached to multivalent scaffolds at a late stage was chosen. This strategy offers the advantage of permitting further optimization of binding interactions where appropriate. General approaches in which N-acetylneuraminic acid derivatives could be used as either electrophiles, nucleophiles, or comonomers were considered. Using derivatives already obtained through PTC (Scheme 2), it was possible to provide the necessary building blocks. Thus, thioacetate 6 was readily de-S-acetylated into potent nucleophile 7 (NaOMe, MeOH, ⫺40⬚C, 30 min, 88%), which had been treated with 4-nitrobenzyl bromide (16), a wide variety of N-chloroacetamides 18, or galactosyl derivative 20 (Z. Gan, R. Roy, unpublished results) to afford key precursors 17 (74%), 19, or 21 (70%), respectively (Scheme 4). N-Chloroacetamides 18 represent typical examples of multivalent scaffolds onto which were built various N-acetylneuraminic acid dendrimers (see below). Multiple chloride substitutions were found to be very efficient and high yielding, together with providing a key 1H NMR signal (␦ 4.2 ppm) that was used to evaluate coupling efficiency. 4-Nitrophenyl O/S-sialosides 9 and 10 were reduced to amine derivatives 22 (HCO2NH4, 10% Pd-C, MeOH, reflux) or 23 (SnCl2, EtOH, reflux) which were directly transformed into comonomers 24 or 25 with acryloyl chloride (CH2 — — CHCOCl, CH2Cl2, Et3N, 86–88%) [49] (Scheme 5). Additionally, 4-aminophenyl 2thiosialoside 23 was converted into 4-isothiocyanatophenyl derivative 26 (CSCl2, DIPEA, CH2Cl2, 87%) for direct conversion into thiourea-linked PAMAM dendrimers [50]. Because it was also of interest to synthesize glycopeptidomimetics and glycopeptoids (see below) by either solution or solid phase synthesis, sialosyl azide 8 was reduced into amine 27 (10% Pd-C, MeOH, quant) and treated with sebacoyl
Scheme 4
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Scheme 5
chloride (28) or with Cbz-protected 6-aminocaproyl chloride 29 to give acid 30 [51] or amine 31 [52] after standard deprotection. Acid 30 was used in solid phase synthesis of hyperbranched dendrimers [51], while blockwise approach was used to transform amine 31 into oligopeptoids up to an octamer level [52]. With efficient (active–latent) and stereospecific (PTC) methodologies in hand for key building block syntheses, the stage was ready for multivalent sialoside preparations. III.
GLYCOFORMS, OLIGOPEPTOIDS, AND AMPHIPHILIC NANOSTRUCTURES
As stated, the search for carbohydrate ligands of high affinity and specificity is of prime interest in glycobiology. While classical structure–activity relationships (SARs) have led to the development of only a limited number of effective inhibitors through exhaustive enterprises, the rational design of glycoclusters or glycomimetics spanning cooperative pharmacophores has furthered our fundamental understanding of carbohydrate–protein interactions. Moreover, multivalent glycoforms may assist unraveling cooperative binding interactions as they really appear in in vivo experiments, a situation not always prevailing with isolated protein receptors or their recombinant forms. It is also stimulating to imagine the implications of glycoclusters in signal transduction. Neoglycoproteins, liposomes, and glycopolymers have been successfully used to demonstrate that multivalency does indeed amplify carbohydrate–protein binding interactions by factors as high as thousands. However, by their very nature, these neoglycoconjugates have ill-defined chemical structures. They are heterogeneous in size and carbohydrate contents. Additionally, neoglycoproteins have been shown to
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be immunogenic [53], and the same may hold for high molecular weight glycopolymers, which can mimic repeating units found on bacterial capsular polysaccharides. Thus, while such glycopolymers can demonstrate the role played by multivalency in recognition processes, they fail to allow precise biophysical analyses of the cluster effect. The following paragraphs illustrate our approach toward the rational design of sialic acid containing clusters. Sialoside clusters, like their other neoglycoconjugate analogs (liposomes, polymers, proteins), have been mainly used as inhibitors of flu virus hemagglutination [54] and as selectin antagonists [55]. Natural tetravalent [56] and semisynthetic divalent [57] sialyloligosaccharides have been prepared by means of chemoenzymatic sialylation of preisolated multiantennary glycans obtained by degradation of glycoproteins or simply by chemical sialylation of tethered glycosides. In recent examples, tetrameric and dimeric sialyl LewisX clusters showed inhibitory IC50 values of less than 50 nM and 0.15 mM in L-selectin-mediated lymphocyte endothelium interactions, respectively. The enzymatically prepared tetramer was a 60-fold better inhibitor than its corresponding monomer. The description of sialylated clusters was reviewed in 1997 [58] and is covered in detail here. Several pieces of evidence suggest that cooperative binding interactions from small clusters depend on both the overall number of sialic acid ligands and their relative positioning with respect to one another. For instance, we have shown that carbohydrate dimers can be nicely oriented and interspaced with very short spacers to provide efficient ‘‘cross-linkers’’ without the need to reach two binding sites from the same lectins [59]. Interestingly, analogous trimers were shown to be less effective on a per-saccharide basis in similar interactions when measured by turbidimetric and inhibition experiments. It was concluded that the ‘‘third’’ unbound ligand of a trimer acted counter-productively in the overall binding associations. These observations seem to hold when densely packed glycodendrimers are used as inhibitors (see below). As deeper appreciation of multivalent carbohydrate-protein interactions was gained, it became obvious that clusters of various shapes, size, and orientation would provide powerful ligands from which fundamental informations about receptors topography would be obtained. To address these issues, the systematic development of novel multivalent glycoclusters was deemed essential. A.
Neoglycopeptidomimetics
Solid phase glycopeptide synthesis is now routine operation in laboratories and has been used to prepare multivalent sialyl LewisX by chemoenzymatic combination [60]. Such a strategy allows investigators to obtain oligomers of varied valency (up to 8) and interspaced by determined numbers of amino acid residues. While this strategy is conceptually appealing, it still lacks the advantages conferred to peptidomimetics if therapeutically valuable products are foreseen. The design of peptide isosteres would be highly preferable, following common practice in drug developments. The recent development of peptoids derived from simple N-substituted oligoglycines seems to fulfill the required criteria of metabolic stability and synthetic simplicity [61]. Our laboratory has been involved in the design of related N- [62] and O-linked [63] glycopeptoids. Once model glycopeptoid syntheses had been established, we decided to prepare sialic acid oligopeptoids having controlled distances both between the backbone
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and between the repeating units [52]. To this end, a convergent blockwise approach with orthogonally protected derivatives was chosen. The following example illustrates the synthesis of linear sialic acid oligomers interspaced by two N-substituted glycine residues onto which was attached a 6-aminocaproic acid spacer (Scheme 6). ␣-Sialosyl azide 8 was transformed into Cbz-protected amine derivative, which upon hydrogenolysis afforded amine 31. A similar strategy has been used by Sabesan [64] to prepare saccharopeptides. This approach allows the preparation of the required ␣ anomer because this configuration is absolutely critical for the sialic acid’s biological activity. Amine 31 was then transformed into key building block 32 following initial treatment with tert-butylbromoacetate (75%) and N-bromoacetylation with bromoacetic anhydride (92%). This orthogonally protected intermediate 32 can be elongated from either direction depending on the strategy chosen. N-Alkylation of 32 by amine 31 afforded dimer 33 which has been N-acetylated to end group 34 (AcCl, 91%) or to middle group 35 after Cbz protection (89%). Sequential deprotection of tert-butyl ester or Cbz group followed by amide coupling (DCC) of the resulting amino acid derivatives afforded tri-, tetra-, hexa-, and octamers such as 36, after protecting group removal under standard conditions. The resulting ‘‘sialopeptoids’’ were thus made available for biological evaluation. Unfortunately, their inhibitory properties against influenza virus hemagglutination were rather negligible compared with dendrimers or polymers (see below). B.
Amphiphilic Calix[4]arene Nanostructures
Guided by the need to prepare well-defined clusters having good binding properties in solid phase enzyme immunosorbent assays (ELISA) while having readily exposed carbohydrate ligands, we became interested in synthesizing glycosylated calix [n]arene derivatives. In many ways, glycocalix[n]arenes, which possess guest–host capabilities that can be used as drug vectors, are structurally related to cyclodextrins. Additionally, they have advantages unsurpassed by the cyclodextrins because they can be readily modified at either ‘‘upper’’ or ‘‘lower’’ rim [65]. Commercially available p-tert-butylcalix[4]arene (37) is already equipped with a hydrophobic tail that has been useful in coating polystyrene microtiter plates [66]. Thus, by freezing 37 in the cone conformation upon treatment with ethyl bromoacetate, ester hydrolysis, and acid chloride formation, known [67] tetraacid chloride 38 was readily made available [68] (Scheme 7). Treatment of 38 with a slight excess of mono-Boc-protected 1,4-butanediamine gave 39 in 62%. Trifluoroacetolysis of the Boc protecting groups resulted in tetramine 40 quantitatively. N-Chloroacetylation ((ClCH2CO)2O, Et3N, CH2Cl2) gave 41 in 63% yield which, when treated with peracetylated thiosialoside 7 (Et3N, CH3CN, N2, 16 h, room temperature) and protecting group hydrolysis (NaOMe, then NaOH) gave 42 in 65% yield. In spite of having high hydrophobic content, tetrameric thiosialoside 42 was fairly water soluble (4.8 mM, 13 mg/mL). It showed strong binding affinity to the plant lectin wheat germ agglutinin (WGA) in a microtiter plate assay. Moreover, it formed insoluble cross-linked lattices with WGA as demonstrated by turbidimetric experiments. The insoluble complex could be inhibited by monomeric phenylthio ␣-sialoside 11 (free OH), thus demonstrating the specificity of the binding interaction. Following several observations leading to the easy formation of well-organized cross-linked lattices with simple clusters [59,68], including dimers [69], we became
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Scheme 7
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intrigued by the possibility of generating ‘‘sugar rods.’’ Several of these molecules could be synthesized via olefin self-metathesis reactions catalyzed by Grubb’s catalyst [(PCy3)2Cl2Ru — —CHPh] [70]. Additionally, they can be prepared from ␣-alkynyl sialosides (Z. Gan, R. Roy, unpublished data) by using palladium(0)-catalyzed crosscoupling chemistry (Sonogashira reaction) (71). These novel derivatives fall outside the scope of this chapter, so their synthesis will be described in due course.
IV.
GLYCOPOLYMERS
We introduced the term ‘‘glycopolymer’’ to identify water-soluble polymers onto which carbohydrate haptens are covalently appended [72]. In this respect, glycopolymers should differ from pseudopolysaccharides, which refer to chemically modified polysaccharides and to insoluble materials used in affinity chromatography. Curiously, we initially made the first sialylated glycopolymers [73] to screen anti–sialic acid antibodies obtained from a sialylated neoglycoproteins [18b,73–75]. The original aim was to generate an antigen deprived of cross-reactive hapten (Neu5Ac), which inevitably would have been produced from other protein carriers. It was then quickly realized that these copolymers offered great potential as inhibitors in cell adhesion processes. Patents for a cancer diagnostic kit consisting of a sialylated protein (vaccine) and an ELISA screening antigen (polymer) were filed several years ago [76]. While this activity was ongoing, we reported the inhibitory potential of these novel sialylated copolymers in influenza flu virus inhibition of hemagglutination. These early observations were then similarly made by several other groups [77,78]. Earlier reviews [10,11,58,79] had described numerous polymerization methods that have been used in synthesizing a wide range of glycopolymers. Amazingly, even though most methodologies can afford better organized copolymers than the one initially used (i.e., by random acrylamide copolymerization or modification), very few alternative methods have been exploited for sialosides. The syntheses and applications of glycopolymers are now covered in several reviews and book chapters [79–82], and only recent developments are highlighted. Reducing sugars can be reductively aminated with ammonia or other amines. The resulting amine derivatives can then be transformed into N-acrylamide monomers useful in copolymerization strategy. Unfortunately, acrylamide copolymerization affords polymers that may vary greatly in their batch-to-batch molecular weight distributions. An improved protocol consists of synthesizing polyacrylates (43) having active ester functionality NHS [83] or 4-NO2Ph [84] (Scheme 8). After aminolysis or hydrolysis, the molecular weight of the resulting polyacrylamides or polyacrylic acids can be compared against commercially available polymer standards used in HPLC. This allows the synthesis of reproducible lots of a given copolymer. Once established, the starting polyacrylates 43 can be treated with various amounts of any amine-containing sugars. Quenching the residual reactive esters with amine 1 (R1NH2) followed by amine 2 (R2NH2), or simply with ammonia or water, afforded copolymers having desired biophysical properties [77,83]. The second and third amines may include probes (e.g., biotin, fluorescamine), lipid groups, other sugars, and peptides. The strategy has also been elegantly used to generate sialopolymer libraries [85]. Sialic acid copolyacrylamides such as 44 were obtained with O/S-aryl
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Scheme 8
spacers [32,49], C-glycosides [86], and other related spacers [78]. GM3-type copolymer 45 was obtained using the foregoing procedure [48]. Thioaryl sialoside comonomer 46 [49] is easier than C-glycoside [25] to produce in a stereocontrolled manner. It is also resistant to sialidases that are simultaneously present on flu virions. Interestingly, it could be directly incorporated onto both poly-L-lysine and proteins by 1,4-conjugate additions (Michael addition) at pH 10 to provide biocompatible random copolymer 47 (Scheme 9) [87]. By analogy, reductively aminated ␣-(2,8)-polysialic acid (colominic acid) 48 can be N-acryloylated into compounds 49, which undergo 1,4-conjugate addition onto poly-L-lysine to provide copolymer 50, isolated as its biotin conjugate [87]. In 1998 Wong et al. [88] reported an analogous strategy whereby a lysoganglioside derivative was amidated to poly-L-glutamic acid (DP 540) together with the fluorescent tag 4,4-difluo5,7-dimethyl-4-bora-3a,4a-diaza-s-indacene-3-propionyl group (BODIPY) to give 51. The copolymer showed picomolar inhibition of H1N1 influenza hemagglutinin that corresponded to an improved binding of 1000-fold over gangliosides GM3 or lyso-GM3 and 105-fold relative to the monosaccharide sialyl lactose. Lipidlike copolymer 51 is thus as active as a polymerized liposome published in 1993 [89]. All the strategies discussed so far included sialylated copolymers having randomly distributed sialic acid residues. As these approaches failed to generate regular copolymers onto which the hapten distributions would be interspaced at constant distances, it was deemed necessary to prepare copolymers by addition polymerization [90]. Chapter 8 by Mann and Kiessling offers an alternative strategy for the use of ring-opening metathesis polymerization (ROMP) of norbornene derivatives to generate analogous polymers. The novel strategy described herein depends on a sialic acid monomer (53) having two amine groups that can be copolymerized by a reiterative addition process onto a bisisocyanate (Scheme 10) (R. Roy, Y. Makimura, unpublished data). Thus, 4-nitrophenyl sialoside 9a was reduced and treated with
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Scheme 9
bromoacetyl chloride. After N-alkylation with Cbz-protected 3,3⬘-iminobis(propylamine) [91], intermediate 52 was obtained in 75% yield. Hydrogenolysis provided diamine 53 quantitatively. Finally, addition polymerization of 53 with either 1,4-butanediamine or 1,6-hexanediamine bisisocyanates and ester hydrolysis gave low molecular weight copolymers 54 and 55 in ⬃50% yield, with a degree of polymerization of ⬃15. It is worth mentioning that all known glycopolymers have shown strong inhibitory properties when used in conjunction with carbohydrate binding proteins. The exact origins of the increased associative forces conferred on glycopolymers are not clearly understood. Aside from the individual binding site’s affinity constants (KD), which obviously remained unchanged, entropic penalties that occur upon binding are minimized with multivalent ligands. The ligands’ local high concentrations are certainly also affecting association/dissociation’s kinetics (kon /koff ). Some external fac-
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Scheme 10
tors such as steric stabilization have also been invoked to support the observations [92]. It is clear, however, that a closer examination of the active site’s topography is a critical factor to be elucidated for the sake of better designing potent ligands/ inhibitors. With this criterion in mind, increasing activity is being addressed in attempts to design neoglycoconjugates of intermediate size between small clusters (di-/trimers) and glycopolymers. Glycodendrimers seem to fulfill the foregoing requirement. Each neoglycoconjugate has its own strength and weaknesses and ultimately, it is the targeted application that will dictate which glycoforms will be favorable. Section V provides a brief overview of the progress and limitations encountered during the development of glycodendrimers since their first synthesis in 1993 [93]. V.
GLYCODENDRIMERS
Several reviews cover dendrimer syntheses and applications [94], but very few describe glycodendrimers as such [16,52,82,95,96]. Dendrimers can basically adopt two shapes: spherical, globular-like structures (58) and monodendritic (59–61 ) architectures (Scheme 11). The last family is particularly appealing because it can mimic complex multiantennary glycans found at the tips of natural glycoproteins. Moreover, from cumulative observations, spherical dendrimers, particularly large ones (i.e., ⱖ16–32-mer) have started to show their intrinsic structural limitations; that is, they suffer from severe steric accessibility. This situation is further amplified by the presence of complete bacterial and viral particles wherein the receptors are themselves clustered and congested. Alternatively, they have shown excellent inhibitory properties with soluble or surface-bound lectins and antibodies.
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Convergent (59 ⫹ 60) and divergent (56,57) strategies toward glycodendrimer 58.
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Glycodendrimers can be synthesized by both convergent and divergent strategies. Ideally, they can be simply prepared by conjugation of active carbohydrate derivatives onto preformed dendrimers (Scheme 11). Given the commercial availability of poly(amidoamine) (PAMAM, 56) and poly(propyleneimine) (Dab, 57) dendrimers, these amine-ending dendrimers are the most heavily exploited. Even though dendrimer surfaces can be constructed to exhibit all possible functionalities, amine-terminating groups are synthetically more appealing and have been used most extensively. The potentially useful thiolated dendrimers self-oxidize, while carboxylated dendrimers tend to form intramolecular anhydrides once activated. This last situation may cause defects upon carbohydrate attachment. Although alcohols seem also attractive, a priori, their direct use in glycosylation chemistry is hampered by potentially difficult complete anomeric stereocontrol. Amine-functionalized dendrimers have been used in several instances. Reducing sugars (62) can be directly anchored to PAMAM dendrimers by reductive amination [97], and sugar lactones (63), readily prepared from reducing sugars by oxidation with basic iodine solutions, can be amidated [98]. Aryl [50] or glycosyl [99] isothiocyanato derivatives (64) also react rapidly and efficiently with polyaminated dendrimers, even under aqueous conditions [100]. Incorporation of chloro- or bromoacetamido groups onto PAMAM dendrimers [XCH2COCl or (ClCH2CO)2O] afforded highly electrophilic species that react readily with thio sugars (65) (Scheme 12). The last approach has been successfully applied in double N-alkylation when bromoacylated carbohydrate derivatives (66) were used. It simultaneously allowed increasing surface group density [66,101]. These versatile strategies gave to glycodendrimers such as 67–71 high-yielding accesses that obviously are applicable to higher oligosaccharides. Sialylated dendrimers having modest activity in inhibition of hemagglutination of flu viruses have been prepared by using Fmoc-chemistry and L-lysine core in solid phase synthesis reactions [30,93]. Similarly, the foregoing dendrimers, together with analogous peptidomimetic-like dendrimers (72) built on 3,3⬘-iminobispropylamine cores [102,103] showed up to ⬃32-fold inhibition of binding of human ␣1-acid glycoprotein (orosomucoid) to the plant lectin wheat germ agglutinin or the slug lectin from Limax flavus (Scheme 13). Similar dendrimers having aryl ␣-D-mannopyranosides as surface group (L-lysine core) showed ⬃2000-fold increased inhibition of binding of yeast mannan to concanavalin A or pea lectin [104]. Nanomolar IC50s values have been reported for sialodendrimers 73 obtained by condensation of PAMAM 56 with p-isothiocyanatophenyl sialoside 26 [50] (Scheme 14). Additionally, dendritic 3⬘-sulfo-LewisX (Glc) bound to poly-L-lysine backbones inhibited the binding of E-selectin to sialyl–LewisX glycolipids 600 times better than the corresponding monomer [105]. The growth valency of the foregoing dendrimers was based on a 2n progression, where n is the generation (i.e., 2-, 4-, 8-, 16-mer, etc.). It has been deemed of interest to construct dendrimers with a 3n progression (i.e., 3-, 9-, 27-mer, etc.). To this end, we constructed sialodendrimers (74) based on a gallic acid core [106] (Scheme 15). The inhibition of certain interactions by large variations in glycodendrimer efficacy points to the need to design multivalent neoglycoconjugates with defined geometry, valency, and shapes. The seemingly modest results observed with some plant lectins further exemplify the problem encountered in glycobiology as opposed to other drug–protein interactions. A good model to clarify these observations has
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Divergent construction of glycodendrimers built on polyamine scaffolds using reductive amination (67), amide formation (68), thiourea bridging with isothiocyanates (64), thioethers (70), and novel double N-alkylation strategy (71).
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16-Mer dendritic sialoside constructed by solid-phase synthesis using 3,3⬘iminobis(propylamine) scaffold [91].
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Scheme 14 16-Mer sialodendrimer synthesized using divergent anchoring of isothiocyanotophenyl sialoside onto PAMAM backbone.
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Scheme 15 Dendritic 9-mer sialoside (3n growth) built on gallic acid core using hydrophilic oligoethyleneglycol spacer.
been recognized with cell adhesion molecules (selectins), where it was established that mediocre in vitro results with sialyllactose do not necessarily translate to poor in vivo experiments [107]. As seen from the synthesis of glycodendrimers derived from the oligosaccharide portion of ganglioside GM1 (Gal(1–3)GalNAc(1– 4)[Neu5Ac␣(2–3)]Gal(1–4)Glc) built on PAMAM and poly(propyleneimine) dendrimers [108], the inhibitory properties against cholera toxin B subunit and E. coli heat-labile enterotoxin showed IC50s values 15-fold lower than that of GM1 itself and 1000-fold lower than that of the oligosaccharide. Just as glycopolymers can be further glycosylated by classical enzymatic reactions via the necessary sugar nucleotides and the corresponding enzymes [109], glycodendrimers can be treated analogously. In this way, it has been straightforward to produce on a dendritic poly-L-lysine core N-acetylglucosamine-ending dendrimers sequentially elongated with UDP-galactose, CMP-Neu5Ac, and finally with GDP-
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fucose and the appropriate glycosyltransferases [110]. Notably, all eight branches of the preformed glycodendrimer could be fully glycosylated to provide octameric sialyl LewisX tetrasaccharides in excellent yields.
VI.
HYBRID DENDRIMER–POLYMERS
The take-home lesson to date is that several small glycoforms exhibit strong binding affinity. The best examples are derived from the pioneering work of Lee et al. [111], who showed that N-acetylgalactosaminide trimers may be few thousand times better than the monosaccharide in binding to hepatic asialoglycoprotein receptors (ASGRs) [112]. There is also a growing body of evidence suggesting that glycoclusters, when properly designed, showed increased affinity. Given the observations and interpretation by Whitesides et al. [92] that steric stabilization (i.e., wrapping of virion particles by sialopolymers) may be responsible for some of the observed increased affinity, it appeared tempting to combine the best of the accumulated observations to build dendritic-like glycopolymers. Such glycoforms already exist and were described in 1995 [113,114]. A fascinating example has been proposed by Fan et al. [113], who chemoenzymatically synthesized a dendritic mannoside (9-mer) ending with an N-acetylglucosaminide acrylamide derivative. The dendrimer was built by the transglycosylaiton of an asparagine, Man9GlcNAc2Asn glycopeptide, obtained by pronase digestion and transferred onto the GlcNAc monomer by means of the endo-N-acetylglucosaminidase isolated from Arthrobacter protophormiae. The resulting multiantennary copolymer was a better ligand than soybean agglutinin toward a recombinant rat mannose binding protein (MBP). An analogous strategy has been used by Furuike et al. [114] in the synthesis of an acrylamide-ending N-acetyllactosamine trimer that had been copolymerized with acrylamide. In a recent attempt to generate nontoxic polysialosides that would be powerful influenza flu virus hemagglutinin inhibitors as well as inhibiting infectivity, we synthesized the novel nanostructures shown in Scheme 16 [115]. To this end, poly(ethyleneimine) was used as scaffolding for the attachment of 4-isothiocyanatophenyl sialoside (deprotected 26) to give ‘‘classical’’ randomly substituted copolymers such as 75 (Scheme 16). The poly(ethyleneimine) (PEI) backbone was prepared by leaving-ring-opening cationic polymerization of 2-ethyl-2-oxazoline, with methyl tosylate as an initiator and morpholine as a terminator, followed by acid hydrolysis [116]. Alternatively, the secondary amines of the poly(ethyleneimine) were used as initiator for the second-generation cationic polymerization [117], which after sialoside conjugation gave comb–branch (G0) structures 76. For comparison purposes, PAMAM dendrimers having partial amine substitutions and interspacing hydroxyl groups [115] were prepared according to our published protocol (Scheme 14) to provide structures such as 77. Rod-shaped, cylindrical dendrimers synthesized by means of the PAMAM reiterative strategy onto PEI backbone [116] were also used to prepare dendritic copolymers like 78. Finally, use of hyperbranched PEI/PEI backbones gave dendrigraft structures 79 (PEI G1–G3). Preliminary results showed comb–branched (76) and dendrigraft (79) to be the most effective sialopolymers made to date (50,000-fold better than the monomer). They also blocked infection of mammalian cells in vitro. The results also varied significantly with various strains of influenza A (H2N2, X-31) and Sendai viruses.
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Scheme 16
Schematic representation of novel hyperbranched glycostructures illustrating: regularly interspaced ligands onto poly(ethyleneimine) backbone (75), comb-branch (G0) structure (76), interspaced spheroidal dendrimer (77), rod-shaped, cylindrical polymer with dendritic branch (78), and dendrigraft (79).
VII.
CONCLUSIONS
The construction of neoglycoconjugates has reached an unprecedented level of sophistication and imagination. This is undoubtedly the result of increased interest from the traditional glycobiology community as well as by a wide range of synthetic chemists now entering the field, a trend facilitated by access to modern analytical tools. The degree of refinement in the techniques employed to quantitate polyvalent interactions has also steadily increased over the last few years (reviewed in Ref. 92). The need for multivalent sialosides is just emerging as their implications in novel biological interactions are being continuously unraveled. Our ignorance about the in vivo receptors’ topography and valency requirements is amazingly challenging. It is our opinion that the synthetic demand for glycoclusters, glycopolymers, and hybrid molecules thereof will significantly increase within the next few years. The
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medicinal chemistry dogma for small-molecule therapeutics will also need to be revisited and adapted to glycopharmaceuticals. ACKNOWLEDGMENTS Financial support from the Natural Sciences and Engineering Research Council of Canada (NSERC) is gratefully acknowledged. I am particularly indebted to my past and present graduate students and postdoctoral fellows who had courageously tackled the chemistry of polysialosides: C. A. Laferrie`re, D. Zanini, S. J. Meunier, S. Cao, W. K. C. Park, M. Letellier, Q. Wu, S.-N. Wang, Z. Gan, M. Llinares, and U. K. Saha, and F. Hernandez Mate´o (visiting professor from Granada). Generous donation of sialic acid by Dr. M. Kawase from NGK Insulators, Ltd (Handa, Japan) is also acknowledged. REFERENCES 1.
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HJ Jennings, AK Bhattacharjee. Carbohydr Res 55:105–112, 1977. HJ Jennings, R Roy, F Michon. J Immunol 134:2651–2657, 1985. R Roy, RA Pon. Glycoconjugate J 7:3–12, 1990. H Higashi, M Naiki, S Matuo, K Okouchi. Biochem Biophys Res Commun 79:388– 395, 1977. (a) H Paulsen, P Matschulat. Liebigs Ann Chem 487–495, 1991. (b) JO Nagy, MD Bednarski. Tetrahedron Lett 32:3953–3956, 1991. IR Vlahov, PI Vlahova, RJ Linhardt. J Am Chem Soc 119:1480–1481, 1997. RU Lemieux. Acc Chem Res 29:373–380, 1996. R Roy, In: Y Sasson, R Neumann, eds. Handbook of Phase Transfer Catalysis. New York: Blackie Academic & Professional, 1997, pp 244–275. R Roy, FD Tropper, S Cao, JM Kim. ACS Symp Ser 659:163–180, 1997. R Roy, D Zanini, SJ Meunier, A Romonowska. ACS Symp Ser 560:104–119, 1994. FD Tropper, FO Andersson, S Braun, R Roy. Synthesis 618–620, 1992. R Roy, FO Andersson, G Harms, S Kelm, R Schauer. Angew Chem Int Ed Engl 31: 1478–1481, 1992. R Roy, FD Tropper, A Romanowska, M Letellier, L Cousineau, SJ Meunier, J Boratynski. Glycoconjugate J 8:75–81, 1991. S Cao, SJ Meunier, FO Andersson, M Letellier, R Roy. Tetrahedron: Asymm 5:2303– 2312, 1994. WKC Park, SJ Meunier, D Zanini, R Roy. Carbohydr Lett 1:179–184, 1995. (a) K Okamoto, T Goto. Tetrahedron 46:5835–5857, 1990. (b) MP DeNinno. Synthesis 583–593, 1991. (a) Y Ito, T Ogawa. Tetrehedron 46:89–102, 1990. (b) T Erce´govic, G Magnusson. J Org Chem 60:3378–3384, 1995. TJ Martin, RR Schmidt. Tetrahedron Lett 33:6123–6126, 1992. A Marra, P Sinay¨. Carbohydr Res 195:303–308, 1990. A Hasegawa, M Kiso. In: H Ogura, A Hasegawa, T Suami, eds. Carbohydrates. Synthetic Methods and Applications in Medicinal Chemistry. Weinheim: VCH, 1992, pp 243–266. R Madsen, B Fraser-Reid. In: SH Khan, RA O’Neil, eds. Modern Methods in Carbohydrate Synthesis. Amsterdam: Harwood Academic Publishers, 1996, pp 155–170. GJ Boons. Tetrahedron 52:1095–1121, 1996. S Cao. ‘‘Active–Latent’’ Glycosylation Strategy in Oligosaccharide and Glycoconjugate Syntheses. PhD dissertation, University of Ottawa, Ottawa, ON, Canada, 1996. R Roy, FO Andersson, M Letellier. Tetrahedron Lett 33:6053–6056, 1992. S Cao, F Herna´ndez-Mate´o, R Roy. J Carbohydr Chem 17:609–631, 1998. S Cao, Z Gan, R Roy. Carbohydr Res 318:75–81, 1999. S Raghavan, D Kahne. J Am Chem Soc 115:1580–1581, 1993. S Cao, R Roy. Tetrahedron Lett 37:3421–3424, 1996. CA Laferrie`re, R Roy, FO Andersson. Methods Enzymol 242:271–280, 1994. D Zanini, R Roy. J Org Chem 63:3486–3491, 1998. M Llinares, R Roy. J Chem Soc Chem Commun 2119–2120, 1997. (a) R Roy. Topics Curr Chem 187:241–274, 1997. (b) UK Saha, JM Kim, R Roy. Syntheses of glycoforms of biological interest. Proceedings of the Eighth European Carbohydrate Symposium, Spain, 1995, C IL-5. R Roy, CA Laferrie`re, RA Pon, A Gamian. Methods Enzymol 247:351–361, 1994. (a) GD Glick, JR Knowles. J Am Chem Soc 113:4701–4703, 1991. (b) S Sabesan, JØ Duus, P Domaille, S Kelm, JC Paulson. J Am Chem Soc 113:5865–5866, 1991. (c) S Sabesan, JØ Duus, S Neira, P Domaille, S Kelm, JC Paulson, K Bock. J Am Chem Soc 114:8363–8375, 1992. (d) SA DeFrees, W Kosch, W Way, JC Paulson, S Sabesan, RL Halcomb, DH Huang, Y Ichikawa, CH Wong. J Am Chem Soc 117:66–79, 1995.
25. 26. 27. 28. 29. 30. 31. 32. 33. 34. 35. 36. 37. 38. 39. 40.
41. 42. 43. 44. 45. 46. 47. 48. 49. 50. 51. 52.
53. 54.
Multivalent Glycotools and Sialic Acid 55. 56. 57. 58. 59. 60. 61.
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EE Simaek, GJ McGarvey, JA Jablonowski, C-H Wong. Chem Rev 98:833–862, 1998. A Seppo, JP Turunen, L Penttila¨, A Keane, O Renkonen, R Renkonen. Glycobiology 6:65–71, 1996. H Maaheimo, R Renkonen, JP Turunen, L Penttila¨, O Renkonen. Eur J Biochem 234: 616–625, 1995. R Roy. In ZJ Witczak, KA Nieforth, eds. Carbohydrates in Drug Design. New York: Marcel Dekker, 1997, pp 84–136. (a) R Roy, D Page´, S Figueroa Perez, V Verez Bencomo. Glycoconjugate J 15:251– 265, 1998. (b) See also: CF Brewer. Chemtracts-Biochem Mol Biol 6:165–179, 1996. C Unverzagt, S Kelm, JC Paulson. Carbohydr Res 251:285–301, 1994. RN Zuckermann, EJ Martin, DC Spellmeyer, GB Stauber, KR Shoemaker, JM Kerr, GM Figliozzi, DA Goff, MA Siani, RJ Simon, SC Banville, EG Brown, L Wang, LS Richter, WH Moos. J Med Chem 37:2678–2685, 1994. (a) UK Saha, R Roy. Tetrahedron Lett 38:7697–7700, 1997. (b) UK Saha, R Roy. J Chem Soc Chem Commun 201–202, 1996. (c) UK Saha, R Roy. Tetrahedron Lett 36: 3635–3638, 1995. (d) UK Saha, R Roy. J Chem Soc Chem Commun 2571–2573, 1995. (a) JM Kim, R Roy. Carbohydr Res 298:173–179, 1997. (b) JM Kim, R Roy. Tetrahedron Lett 38:3487–3490, 1997. (c) JM Kim, R Roy. Carbohydr Lett 1:465–468, 1996. S Sabesan. Tetrahedron Lett 38:3127–3130, 1997. (a) V Bo¨hmer. Angew Chem Int Ed Engl 34:713–745, 1995. (b) A Ikeda, S Shinkai. Chem Rev 97:1713–1734, 1997. R Roy, JM Kim. Angew Chem Int Ed Engl 38:369–372, 1999. F Arnaud-Neu, G Barrett, S Cremin, M Deasy, G Fergusson, SJ Harris, AJ Lough, G Lourdes, MA McKervey, MJ Schwing-Weill, P Schwinte. J Chem Soc Perkin Trans 2: 1119–1125, 1992. SJ Meunier, R Roy. Tetrahedron Lett 37:5469–5472, 1996. D Page´, R Roy. Biorg Med Chem Lett 6:1765–1770. (a) R Dominique, SK Das, R Roy. J Chem Soc Chem Commun 2437–2438, 1998. (b) SK Das, R Dominique, C Smith, J Nahra, R Roy. Carbohydr Lett 3:361–368, 1999. (c) YJ Hu, R Roy. Tetrahedron Lett 40:3305–3308, 1999. (a) K Sonogashira, Y Tohda, N Hagihara. Tetrahedron Lett 4467–4470, 1975. (b) R Roy, SK Das, R Dominique, MC Trono, F Herna´ndez-Mate´o, F Santoyo-Gonza´lez. Pure Appl Chem, 565–571, 1999. R Roy, FD Tropper, A Romanowska. Bioconjugate Chem 3:256–261, 1992. R Roy, CA Laferrie`re, A Gamian, HJ Jennings. J Carbohydr Chem 6:161–165, 1987. R Roy, CA Laferrie`re. Carbohydr Res 177:C1–C4, 1988. CA Laferrie`re. Synthesis of Sialic Acid Antigens. PhD dissertation, University of Ottawa, Ottawa, Ontario, Canada, 1990. R Roy, CA Laferrie`re, U.S. Patents 5,034, 516, 1991; 5,192,661, 1993. (a) A Gamian, M Chomik, CA Laferrie`re, R Roy. Can J Microbiol 37:233–237, 1991. (b) A Spaltenstein, GM Whitesides. J Am Chem Soc 113:686–687, 1991. (a) NE Nifant’ev, AS Shashkov, YE Tsvetkov, AB Tuzikov, IV Abramenko, DF Gluzman, NV Bovin. ACS Symp Ser 560:267–275, 1994. (b) MA Sparks, KW Williams, GM Whitesides. J Med Chem 36:778–783, 1993. (c) JO Nagy, P Wang, JH Gilbert, ME Schaefer, TG Hill, MR Callstrom, MD Bednarski. J Med Chem 35:4501–4502, 1992. R Roy. In GJ Boons, ed. Carbohydrate Chemistry. London: Chapman & Hall, 1998, pp 243–321. G Magnusson, AY Chernyak, J Kihlberg, LO Kononov. In YC Lee, RT Lee, eds. Neoglycoconjugates: Preparation and Applications. San Diego, CA: Academic Press, 1994, pp 53–143.
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82. 83. 84. 85. 86. 87.
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(a) R Roy, WKC Park, D Zanini, C Foxall, OP Srivastava. Carbohydr Lett 2:259–266, 1997. (b) R Roy, WKC Park, OP Srivastava, C Foxall. Bioorg Med Chem Lett 6:1399– 1402, 1996. (a) SJ Meunier, Q Wu, SN Wang, R Roy. Can J Chem 75:1472–1482, 1997. (b) R Roy, WKC Park, Q Wu, SN Wang. Tetrahedron Lett 36:4377–4380, 1995. MS Mulligan, JC Paulson, S DeFrees, ZL Zheng, JB Lowe, PA Ward. Nature 364: 149–151, 1993. JP Thompson, CL Schengrund. Glycoconjugate J 14:837–745, 1997. SI Nishimura, K Yamada. J Am Chem Soc 119:10555–10556, 1997. MM Palcic, H Li, D Zanini, RS Bhella, R Roy. Carbohydr Res 305:433–442, 1998. See also: D Zanini, R Roy. Bioconjugate Chem 8:187–192, 1997. RT Lee, YC Lee. In: YC Lee, RT Lee, eds. Neoglycoconjugates: Preparation and Applications. San Diego, CA: Academic Press, 1994, pp 23–50. YC Lee. In: G Bock, S Harnett, eds. Carbohydrate Recognition in Cellular Function. New York: John Wiley & Sons, 1989, pp 80–95. JQ Fan, MS Quensenbery, K Takegawa, S Iwahara, A Kondo, I Kato, YC Lee. J Biol Chem 270:17730–17735, 1995. T Furuike, N Nishi, S Tokura, SI Nishimura. Chem Lett 823–824, 1995. JD Reuter, A Myc, MM Hayes, Z Gan, R Roy, D Q, R Yin, LT Piehler, R Esfand, DA Tomalia, JR Baker Jr. Bioconjugate Chem 10:271–278, 1999. R Yin, Y Zhu, DA Tomalia. J Am Chem Soc 120:2678–2679, 1998. DA Tomalia, DM Hedstrand, MS Ferrito. Macromolecules 24:1435–1438, 1991.
10 Aminoglycoside Antibiotics: Structures and Mechanisms of Action Jalal Haddad, Lakshmi P. Kotra, and Shahriar Mobashery Wayne State University, Detroit, Michigan
I.
INTRODUCTION
The vast majority of compounds bearing amino sugars as the main component of their structures belong to the family of aminoglycoside antibiotics. Another term used is aminocyclitol antibiotics, because the most important members of this class with high antimicrobial activity contain an aminocyclitol moiety in their structures. This chapter briefly describes some important noncyclitol aminoglycosides, but our main focus is on aminocyclitol antibiotics, which are more important in terms of biological activity. Aminoglycoside antibiotics are antimicrobial agents potently active against both gram-positive and gram-negative bacteria. They show rapid concentration-dependent cidal action [1,2], and their activity is independent of the size of the bacterial inoculum [3]. Furthermore, their pharmacokinetics is predictable and they synergize with -lactam antibiotics. It is interesting to note that even though a number of resistance enzymes to these have been identified, such resistance cases have not disseminated widely in the clinic, as has been done with respect to -lactam antibiotics [4,5]. Aminoglycosides have relatively poor oral absorption; therefore they are generally administered intravenously [6]. All aminoglycosides possess the potential for renal and otovestibular toxicity, but despite these problems they remained useful for the treatment of serious infections and continue to be the antibiotic of choice in clinics because of their many desirable traits. Streptomycin [7], the first aminoglycoside to find clinical use, was second only to penicillin as an antibiotic in so doing. It was the very first antibiotic with activity against Mycobacterium tuberculosis, the microorganism that causes tuberculosis. In307
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deed, it was used in treatment of this disease just one year after its discovery [8]. Streptomycin remains effective as a key component of modern antimycobacterial therapy [9]. This initial finding led to the identification and characterization of several other clinically useful aminoglycosides over the subsequent 50 years. Aminoglycoside antibiotics are used for the treatment of infections. They exert their antibacterial properties by binding to the particular sites of RNA molecules in the bacterial ribosome [10–12]. As discussed later, this binding interferes with the fidelity of mRNA translation, results in miscoding, and leads ultimately to bacterial cell death [13–16]. Compounds in this class can interact with a variety of other biologically relevant RNA sequences. For instance, it is known that they inhibit growth of the human immunodeficiency virus (HIV-I) by blocking the binding of the regulatory protein Rev to its response element [17–19]. During the past five decades, numerous aminoglycosides of microbial origin have been isolated, their structures elucidated, and the compounds synthesized. Extension of these synthetic strategies in combination with the understanding of the mechanisms of bacterial resistance and the knowledge of binding ability of aminoglycoside antibiotics to various RNA molecules have opened new avenues for preparation of a large number of semisynthetic aminoglycoside antibiotics with remarkable potency against antibacterial-resistant organisms. Reviews by Hanessian et al. [20], Umezawa [21], and Cox et al. [22] deal with the chemistry of aminoglycosides; Price [23] has reviewed structure–activity relationships, and Umezawa et al. [24,25] have discussed the structure, synthesis, and biosynthesis of aminoglycoside antibiotics. This chapter summarizes what is known of the structural classes of aminoglycosides to date and presents state-of-the-art knowledge of the mechanisms for manifestation of the biological activities of these versatile antimicrobials. II.
AMINOGLYCOSIDE STRUCTURES
Naturally occurring aminoglycosides are amino sugars consisting of an aglycon unit, which can be cyclic or open chain. The aglycon is either streptamine, its related aminocyclitols, cyclitol, monoaminocyclitol, or a noncyclitol moiety. Therefore, these natural products can be divided into three major classes: (1) aminoglycosides containing streptamine and its related aminocyclitols, (2) aminoglycosides containing cyclitol and/or monoaminocyclitol, and (3) aminoglycosides having a noncyclitol moiety in their structures. A.
Aminocyclitol Aminoglycosides Containing Streptamine and Its Derivatives
The aglycon unit in aminocyclitol aminoglycosides that contain streptamine and its derivatives is 2-deoxystreptamine (compounds 1–3 ) 1 (2-DOS), streptamine 2, or streptidine 3. Most of the aminocyclitol aminoglycosides with high antibacterial activity have the 2-deoxystreptamine as the aglycon unit. The carbon atom bearing the amino group with the R configuration is assigned number 1 in the structure. The most active aminoglycosides are those with their sugar units substituted at positions 4 and 5, or 4 and 6, of the aglycon unit. By convention, the sugar unit attached to the 4-position
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Compounds 1–3
of 2-DOS is designated by the primed (⬘) numbers and those attached to the 5- or 6-positions are indicated by the double-primed (⬙) numbers. 1.
Aminoglycosides Containing 2-Deoxystreptamine
(a) 4-Substituted 2-Deoxystreptamine. Among 4-substituted-2-deoxystreptamine aminoglycosides, three pseudotrisaccharides, apramycin, oxyapramycin (14) [26], and saccharocin (15) (compounds 13–15 ) [27,28], show more potency than neamine (4) and are active against many resistant bacterial strains. Members of this group of pseudodisaccharides (compounds 4–12 ) are minor metabolites of Actinomycetes and show weak antibacterial activity [29–35]. (b) 5-Substituted 2-Deoxystreptamine. These aminoglycoside antibiotics have an unusual spiro ring junction in their structures. They show weak antibacterial activity
Compounds 4–12
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Compounds 13–15
and are relatively more toxic than neamine. Of these antibiotics, hygromycin B (16), produced by Streptomyces hygroscopicus [36], and destomycin A (17), produced by Streptomyces rimofaciens [37], are used as anthelmintics for poultry and swine. The antibiotic SS-56C is structurally related to A-396-I, having streptamine (2) instead of 2-deoxystreptamine (1) in its structure [38]. Another member of this group, produced by Saccharopolyspora hirsuta, has been characterized a 1-N-amidino-1-Ndemethyl-2-hydroxydestomycin A and is relatively weaker than destomycin A (17) [39]. In general, antibacterial activity of this class of aminoglycoside antibiotics against Staphylococcus aureus and Escherichia coli is lower than that of neamine, but these drugs are relatively active against Pseudomonas aeruginosa [38]. Compounds 19 and 20 are discussed in the literature [40,41] (compounds 16–20 ). (c) 6-Substituted 2-Deoxystreptamines. These pseudodisaccharides show weak antibacterial activity. Compound NK-1012-2 (21) is a fermentation product of Streptomyces kanamyceticus [32], and garamine (22) is one of the minor components of gentamicin-producing organisms [35]. (d) 4,5-Disubstituted 2-Deoxystreptamines. The most active members of this group are neomycins B and C (compounds 23 and 24, respectively), which are pseudotetrasaccharides produced by Streptomyces fradiae [42]. These antibacterial agents are clinically important and are used as a mixture for treatment of infectious diseases caused by both gram-positive and gram-negative bacteria. Paromomycins I and II (25 and 26, respectively) are clinically useful drugs, and as a mixture they are less toxic than neomycins. Neomycin B and paromomycin I (having five and six charged amino groups, respectively) show strong interactions with 16S ribosomal RNA in vitro and in vivo; they are good candidates for structure modification and synthesis of new drug [43]. Two pseudopentasaccharides, lividomycin A and mannosylparomomycin, and 4-O-␣-D-mannopyranosyl-substituted derivatives of lividomycin B (27) and paromomycin I (25), respectively. They are produced by the same organism that produces
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Compounds 16–20
lividomycin B and paromomycin [34]. 3-N-Methylparomomycin I has been isolated from the culture filtrate of Streptoverticillium sp. A1-R2827. The antibacterial activity of this compound is a little weaker than that of paromomycin I [44]. 6-Deamino6-hydroxyneomycin and 6-deamino-6-hydroxyparomomycin have been obtained from strains of Streptomyces (S. fradiae and S. rimosus, respectively). They are mixtures of C5 epimers, suggesting a status as intermediates in the biosynthesis of the parent antibiotics [45] (compounds 23–27 ; see pg. 312).
Compounds 21 and 22
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Compounds 23–27
The ribostamycin aminoglycosides are pseudotrisaccharides compounds 28–36 that lack the ring IV (neosamine) of neomycins in their structure [45–52]. They show antibacterial activity greater than neamine, but less than neomycins. (e) 4,6-Disubstituted 2-Deoxystreptamine. These pseudotrisaccharides (compounds 37–61 ) are effective against a variety of gram-positive and gram-negative bacteria but are highly susceptible to the drug resistance enzymes (see below). Kanamycins B and C are minor components of the kanamycin A producing organism Streptomyces kanamyceticus [53]. In comparison to kanamycins A and B, kanamycin C (39) has a much weaker antibacterial activity against S. aureus and E. coli. Tobramycin 42 or 3⬘-deoxykanamycin B is a clinically useful antibiotic because of its ability to avoid phosphorylation at the 3⬘-position by the resistance enzymes aminoglycoside 3⬘-phosphotransferases. Another important class of antibiotics in this group is the gentamicins (compounds 45–60 ), of which about 25 different compounds have been isolated from the same or different culture filtrates [35,57,58,59,60,61]. Commercially available gentamycin C, which is a valuable therapeutic agent, is a mixture of gentamicins C1, C1a, and C2. Gentamicins A3, B, and B1 bear a hydroxyl group instead of an amine at the C2⬘-position. Sisomicin 61 and related compounds are derivatives of gentamicin C, which have an unsaturated amino sugar moiety in their structures. Sisomicin is more active than the gentamicin C mixture, but it is also twofold more toxic (compounds 61–65 ; see pg. 317).
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Compounds 28–36
The aminoglycoside antibiotic 66-40G produced by Micromonospora inyoensis is 3⬙-N-demethylsisomicin [70], and the G-367S (compound 66; see pg. 317) produced by a strain of Dactylosporangium, has been characterized as 2⬘-N-formylsisomicin [71]. Seldomycins (compounds 67–69 ; see pg. 318) are another set of structurally related gentamicin aminoglycosides in this group. Seldomycin 5 is the most potent, having a methoxy group at the 4⬙-position of xylopyranose ring [72]. Seldomycin 2 is a pseudodisaccharide lacking the xylopyranose moiety. Seldomycin 5 is the only naturally occurring aminoglycoside antibiotic that has an amino group at the 2⬙position next to the 3⬙-amino group. 2.
Aminoglycosides Containing Streptamine, Streptidine, and Their Derivatives
(a) Streptamine-Containing Aminoglycosides. One of the aminoglycosides bearing a streptamine ring in its structure is SS-56C (Section II.A.1.b) [38], which is struc-
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Compounds 37–44
turally related to the destomycin family. Spectinomycins (compounds 70–72 ; see pg. 318) are another class in this series that contained actinamine (N,N⬘-dimethyl-2-epistreptamine) in their structures. Acmimycin (72), a spectinomycin analog having a cis–cis ring junction, is believed to have the following structure (see pg. 318) [44]. (b) Streptidine-Containing Aminoglycosides. Streptomycins (compounds 73–78 ; see pg. 319), an important class of aminoglycoside antibiotics, are pseudotrisaccharides or pseudotetrasaccharides that contain a 4-substituted streptidine moiety. Streptomycin, a potent chemotherapeutic agent, was the first aminoglycoside antibiotic, discovered in 1944 in the culture filtrate of Streptomyces griseus [7], as described earlier. Glebomycin [82] is an aminoglycoside antibiotic, that is structurally related to dihydrostreptomycin, having a carbamoyloxy group (NH2COO) instead of the guanidino group at the 1-position of the streptidine moiety. Antibiotic AC4437 is the deN-methyl-L-glucosamine analog of dihydrostreptomycin that shows weaker antibacterial activity than dihydrostreptomycin [83]. Ashimycins A and B are two streptomycin analogs (modified in the L-glucosamine unit) isolated from the fermentation broth of S. griseus [84]. Ashimycin A (compound 79; see pg. 319) carries a glycosidically linked sugar moiety having an
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Compounds 45–50
acid functional group in its structure, but the stereochemistry has not been established yet. 3.
Aminoglycosides Containing Cyclitol, Monoaminocyclitol, Diaminocyclitol, and Related Derivatives
(a) Cyclitol- and Monoaminocyclitol-Containing Aminoglycosides. Several aminoglycoside antibiotics containing monoaminocyclitol or cyclitol moiety are known. Among these, kasugamycins [85], myomycins [86,87], validamycins [88], and inosamycins [89] are of clinical interest (compounds 80–84 ; see pg. 320). The revised structure of validamycin A 85 (compounds 85–92 ; see pg. 320) was reported by Suami, Ogawa, and Chida [90] in 1980 and it turned to be 4-O--Dglucopyranosyl validamycin A, instead of the 3-O-glucosyl derivative previously reported by Kameda in 1972. Inosamycins (compounds 93–96 ; see pg. 321) are monoaminocyclitol-containing aminoglycosides produced by S. hygroscopicus; they are structurally related to the neomycin, paromomycin, and ribostamycin families but contain a 2-deoxy-scylloinosamine instead of 2-deoxystreptamine 1 as the aglycon unit [89]. Inosamycin E is a ribostamycin analog in which the amino group at position 1 is replaced by a hydroxyl function [89]. Inosamycin A 93 exhibits antibacterial activity comparable to that of neomycin, with lower toxicity than neomycin; however, inosamycin E is less active than ribostamycin. Boholmycin (compound 97; see pg. 321) is a pseudotetrasaccharide from S. hygroscopicus H617-25. Its structure consists of a heptose, two amino sugars, and dicarbamoyl-scyllo-inositol. It shows
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Compounds 58–60
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Compounds 61–65
weak antibacterial activity but exhibits a broad spectrum of activity against grampositive and gram-negative bacteria, including aminoglycoside-resistant strains [95]. Antibiotic X-14847 (compound 98; see pg. 321), produced by Micromonospora echinospora, has been identified at 1-O-(2-amino-2-deoxy-␣-D-glucopyranosyl)-Dmyo-inositol showing weak antibiotic activity [96]. (b) 1,4-Diaminocyclitol-Containing Aminoglycosides. This class includes fortimicins and related analogs. They are active antibiotics against most gram-positive and gram-negative bacteria, including those with resistant strains, but they are not active against Pseudomonas. In this class, the glycyl moiety plays an important role in activity of the compound, and those without this component (fortimicin B, sporaricin
Compound 66
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Compounds 67–69
Compounds 70 and 71
Compound 72
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Compounds 73–78
B, istamycins A0 and B0) show less potency (compounds 99–111 ; see pgs. 322 and 323). Sannamycin C (compound 112; see pg. 323) is a fortimicin analog, and its 4N-glycyl derivative inhibits gram-positive and gram-negative bacteria resistant to other aminoglycoside antibiotics [108]. In sannamycin C the methoxy group at position 3 is equatorial, whereas in sannamycin B the methoxy group holds an axial position.
Compound 79
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Compounds 80–84
Compounds 85–92
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Compound 97
Compound 98
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Compounds 99–109
In this series, (compounds 113 and 114; see pg. 323) lysinomicin (113) [109] and 2⬘-de-N-L-lysyllysinomocin [110] showed good antibacterial activity against several strains. Fortimicin KG3 (114) and its related analogs are another branch of this family that have an unsaturated amino sugar moiety similar to that of sisomicins in their structure. Among these, fortimicin KG3 has potent antibacterial activity [111]. Another fortimicin analog is sporaricin E or 2-deoxy fortimicin B, which shows weak antibacterial activity [112]. In a report by Morioka et al. it was demonstrated that a blocked mutant of istamycin producing Streptomyces tenjimariensis converts fortimicin B to 1-epi-dactimicin with inversion of the amino group at position 1 and N-4-acylation [113].
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Compounds 110 and 111
Compound 112
Compounds 113 and 114
B.
Noncyclitol Aminoglycosides
The noncyclitol aminoglycosides include several monosaccharides, disaccharides, and those with the open-chain aglycon units. Compounds 115–117 (see pg. 324), nojirimycin (115) [114], streptozotocin (116) [115], prumycin (117) [116], and a few others are monosaccharides with only weak antibacterial activity. Trehalosamines are representative of the disaccharides in this class of aminoglycosides and are relatively weak antibiotics. Trehalosamine (compound 118) [117], its 2-epimer mannosylglucosaminide [118], and the 4-amino derivative compound 119 [119] were isolated from culture filtrate of Streptomyces and showed weak an-
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Compounds 115–117
Compounds 118–120
tibacterial activity. The mannosylglucosaminide is a trehalosamine with an axial hydoxyl group at the 2-position, and the BMY-28251 compound 120 is the first example of an ␣,-trehalose antibiotic obtained from Bacillus pumilis [120]. The sorbistins (compounds 121–124 ) are monosaccharides having an openchain aglycon unit (1,4-diaminosorbitol) in their structures. Although they show weak antibacterial activity, they exert their antibiotic activity against many of the aminoglycoside-resistant strains. Sorbistin A1 is the most active compound in the class, showing activity 1/50 of that of kanamycin A against E. coli, but exhibiting some activity against resistant strains [121,122,123]. Trehazolin (compound 125) is a pseudodisaccharide that serves as a trehalase inhibitor from Micromonospora sp. strain SANK 62390 [124]. Salbastatin compound
Compounds 121–124
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Compounds 125 and 126
126 is another trehalase inhibitor [125], isolated from Streptomyces albus. These natural products are inhibitors of glycosidases, which play critical roles in intra- and intercellular processes including cell adhesion, membrane transportation, and signal transduction. III.
ENZYMATIC MODIFICATION OF AMINOGLYCOSIDES
Resistance to antibiotics manifests itself in different ways. The target of the antibiotic may be altered such that affinity for the drug may be reduced [126,127,128]. Or, the rate of the uptake of the drug into the bacterium may be attenuated such that the critical concentration necessary for saturating the binding site cannot be reached [129,130,131]. Alternatively, specific enzymes may evolve to alter the structure of the drug in bacterium, whereby the site for the binding shows lower affinity for the modified drug, thus manifesting resistance to the original drug. This third method for acquired resistance is the most common for aminoglycoside antibiotics [132,133,134,135]. Three classes of enzymes have evolved for aminoglycoside modification for the manifestation of the resistance phenotype. These enzymes are aminoglycoside acetyltransferases (Aac), aminoglycoside nucleotidyltransferases (Ant), and aminoglycoside phosphotransferases (Aph). The acetyltransferases transfer the acetyl group from acetyl coenzyme A to specific amines in aminoglycosides. The sites of these modifications are 1-, 3-, 2⬘-, and 6⬘-amino groups. The other two classes of enzymes transfer the adenyl or the phosphoryl group from ATP to hydroxyl groups in aminoglycosides. The common sites of adenyl transfer are hydroxyl groups at 2⬙- and 4⬘-hydroxyls of kanamycins and 3⬙- and 6-hydroxyls of streptomycin. The sites of phosphotransferase reactions are the hydroxyl groups at positions 3⬘ and 2⬙ of kanamycins and 3⬙ and 6 of streptomycin. The products of these enzymatic modifications are invariably poorer antibiotics because their binding to their ribosomal target sites has been impaired. The nature of these enzymes and state of the art in their mechanistic understanding were reviewed comprehensively in 1998 [134]. IV.
MECHANISM OF ACTION OF AMINOGLYCOSIDE ANTIBIOTICS
Aminoglycosides exhibit their antibiotic action primarily by entering the cell irreversibly by active transport, binding to the ribosomal RNA (rRNA), interfering with protein synthesis (translation process), and causing membrane damage resulting in leakage of the cell membrane [134,136,137]. These actions result in disruption of
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the integrity of the bacterial cell, ultimately leading to cell death. There are exceptions, however, to this mode of action, and a few of the aminoglycosides such as spectinomycin and kasugamycin are bacteriostatic; that is, they stop the growth of bacteria rather than killing the cell, although they too interact with rRNA. It is now well established that aminoglycosides bind to the RNA major groove at various important sites such as the A site (ribosomal acceptor site) and hammerhead regions (see below). Aminoglycosides enter bacteria in a biphasic and energy-dependent process. The initial phase (phase I) allows for transport of small quantities of aminoglycoside, although the amount that is required for antibacterial action is not known [134,138]. Phase I has been described as an energy-dependent active transport and entails a slow, linear uptake process [138,139,140]. Phase II of uptake is both energy and concentration dependent, and it shows a behavior similar to the diffusion of small molecules through channels. After uptake during phase I, aminoglycoside binds to the chain-elongating ribosomes and causes misreading of mRNA, resulting in malformed proteins. A few of these miscoded proteins become part of the cell surface and disrupt the integrity of the membrane. The damaged membrane subsequently allows more antibiotic molecules to enter the cell, where ultimately they reach a concentration that can inhibit the initiation of the translation process. Eventually, the combination of disrupted membrane and irreversible blocking of the protein biosynthesis kills the organism [136]. Ribosome plays an important role in selecting the correct EF-Tu-GTP–aminoacyl–tRNA ternary complex at the A site, which supplies the next amino acid to the elongating polypeptide during translation [141]. In the A-site region of ribosomal RNA, the highly conserved A1492 and A1493 point toward the minor groove in the A site [142]. It was proposed that when a complementary tRNA binds to the codon, the 2⬘-OH moieties on mRNA may interact with the N1-position of the conserved adenines, and perhaps this process is a beginning step in the communication needed for the codon–anticodon complex. It was suggested that binding of aminoglycosides to the rRNA decreases the dissociation rates of aminoacyl–tRNA, and stabilizes a high-affinity conformation of tRNA–mRNA complex [142]. This in turn may result in inhibition of the translation process and/or favor miscoding. In fact, in early 1960s, ribosomes were identified as the target sites of action for aminoglycosides such as streptomycin. However, the limitations of scientific knowledge at the time prevented the establishment of the relationship between the ribosome and the bactericidal activity [136]. A few years later, it was understood that binding to the ribosome of small molecules such as aminoglycosides can influence not only the catalytic activity of the ribosome but also its specificity; that is, such binding can lead to improper information processing in translation, transcription, and replication. The interactions of aminoglycosides with ribosome are concentration dependent [140]. At lower concentrations, streptomycin blocks the abundant polysomal ribosomes (chain elongating), whereas at higher concentrations, these molecules can bind all ribosomes, including the ones involved in initiation [136]. It was proposed that binding of streptomycin to the ‘‘initiating ribosome’’ is irreversible. However, this may be due to the irreversible uptake of aminoglycoside into the cell as well. The bactericidal activity of aminoglycosides is now supported by the involvement of almost every step of the mechanism given above [134]. However, there are still several unanswered questions relating to, for example, the nature of the miscoded
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proteins that are transported to the membrane, the enzymes/channels in the active transport of aminoglycosides into the cell, the nature of miscoding, and their effect on protein folding and membrane integration. Lately, there is increasing evidence of inhibition of self-splicing of group I introns by a number of aminoglycosides such as streptomycin, tobramycin, neomycin B, kanamycin, neamine, 5-epi-sisomicin and gentamicin [143,144,145,146]. It was shown that at reasonably low (micromolar) concentrations, several of these aminoglycosides can inhibit noncompetitively the thymidylate synthase group I intron RNA splicing in vitro. It appears that the ability of various aminoglycosides to inhibit intron self-splicing is purely structure dependent; and depending on the concentration of the aminoglycoside, one or both steps in the catalysis of group I intron selfsplicing are inhibited. It is very interesting, however, to learn that new activities are being discovered for these older antibiotics, and perhaps these findings will shed more light on the mechanism of action of aminoglycosides and their toxicity mechanisms. The similarities in the binding of aminoglycosides to ribosomal RNA and the catalytic self-splicing introns have led to the hypothesis that perhaps aminoglycosides were modulators of RNA activity in biologically evolving systems. Furthermore, during the coevolution of RNA and aminoglycosides, modern ribosomes have formed on which aminoglycosides exhibit similar binding properties [146,147]. V.
SITES OF RNA–AMINOGLYCOSIDE INTERACTIONS
Aminoglycoside antibiotics, as discussed in the preceding section, interact with RNA. Ribosome is the target for this class [10–12,148], and the antibiotics exert their antibacterial effects by binding to ribosomal RNA (rRNA) in the A site, causing misreading of the genetic code and inhibiting the process of translocation [149,150] (see above). Aminoglycoside antibiotics also interact with a variety of other biologically relevant RNA molecules. These include mRNA from human immunodeficiency virus (HIV-1), transactivation response element (TAR) [151], group I self-splicing introns [152], the hammerhead region of rRNA [153,154,155], and the hepatitis delta virus (HDV) ribozyme [156]. Next, we discuss recent developments in the binding of aminoglycoside antibiotics to RNA. A.
Binding of the Neomycin Class of Aminoglycosides to the A Site of 16S rRNA
Aminoglycoside antibiotics exert their antibacterial activity by interfering with protein biosynthesis. The common binding site for the structurally related aminoglycosides neamine (4), ribostamycin (28), paromomycin (25), and neomycin B (23) is localized in the A site of the prokaryotic 16S ribosomal RNA (rRNA) in the 30S subunit (Fig. 1a) [13–16,157]. These 2-deoxystreptamine-containing aminoglycoside antibiotics show a characteristic miscoding pattern that is distinct from that of streptomycin 73 [158], having a streptidine moiety in place of the 2-deoxystreptamine in its structure. They affect the codon–anticodon interaction in the A site of the 30S subunit by binding to the same site on rRNA, causing codon misreading and inhibiting translocation [149,150]. A specific interaction between the tRNA anticodons and mRNA codons is required for an accurate translation in the decoding region, which is formed by two short conserved sequences near the 3⬘ end of 16S rRNA (the nucleotide 1400–1500 region, Fig. 1b).
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Figure 1
(a) Secondary structure of the 16S rRNA from E. coli. (b) The sequence of the decoding region [arrow in (a)]. (c) The sequence of a 27-nucleotide RNA used to characterize aminoglycoside–RNA interaction, with the highly conserved A-site portion of the 16S boxed. (d) Structures of aminoglycoside antibiotics.
To investigate the interactions between paromomycin and rRNA, Puglisi and colleagues [15] designed a small RNA fragment that mimics the structure of the A site of E. coli 16S rRNA. From these investigations, it appears that the universally conserved C1407 ⭈ G1494 base pair, A1408, and A1493 are required for the binding of paromomycin to the wild-type rRNA. An asymmetrical internal loop produced by a universally conserved adenine residue at position 1492 must also be present. In addition, base pairing is required in the lower stem for aminoglycoside binding.
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Positions 1406 and 1495 are universally conserved uridines that form a U ⭈ U pair in the ribosome. Paromomycin typically binds to the U1406 ⭈ U1495 base pair. It binds to two binding sites, the A1406 ⭈ U1495 and U1406 ⭈ G1495 base pairs, but binds only weakly to the U1406 ⭈ A1495 base pair variant. Quantitative footprinting of oligonucleotide variants identified critical nucleotides for binding of paromomycin to the A-site oligonucleotide. These include the C1407 ⭈ G1494 base pair, the A⭈ U base pair at positions 1410 and 1490, and nucleotides A1408, A1493, and U1495. Puglisi and coworkers further characterized the structure and binding of paromomycin to the A-site rRNA by using NMR spectroscopy to determine the solution structure of the RNA–paromomycin complex (Fig. 2) [142]. Some salient features of this structure are as follows. 1. Paromomycin binds in the major groove of the A-site rRNA, within the internal loop (see Fig. 1). Distortion of the RNA backbone by the presence of the bulged nucleotide A1492 and noncanonical A1408 ⭈ A1493 base pair leads to the formation of a distinct binding pocket for paromomycin. 2. Rings I and II of paromomycin adopt chair conformations, and their equatorial amino and hydroxy moieties make specific contacts with RNA, stabilizing the RNA–antibiotic complex.
Figure 2 The RNA–paromomycin NMR structure. Paromomycin is shown by the cappedstick presentation. A portion of the RNA structure at the aminoglycoside binding site is shown as a surface.
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3. The two amino groups at positions 1 and 3 of the 2-deoxystreptamine moiety (ring II), found in all aminoglycosides that bind to the A site, make hydrogen bonds to U1495 and G1494, respectively, and are essential for specific binding of these antibiotics to the rRNA. 4. Ring I stacks above the base moiety of G1491 such that its hydroxyl groups at positions 3⬘ and 4⬘ are directed toward the phosphate moieties of A1493 and A1492, respectively, but they are not essential for antibiotic function. 5. Rings III and IV weakly contribute to specific binding, but the amino and hydroxyl groups of ring IV may have weak electrostatic interaction with the phosphate backbone of U1406, C1407, and U1490. 6. The A1408 ⭈ A1493 pair is essential for antibiotic binding in prokaryotic ribosomes and leads to formation of the specific binding pocket for ring I, whereas in the case of eukaryotic ribosomes having G1408 in place of A1408, a base pair of equivalent geometry cannot be formed, and paromomycin binds weakly to the G1408 ⭈ A1493 base pair. This RNA–paromomycin structure also explains a number of features that help show why modification of the aminoglycoside antibiotic by the resistance enzymes prevents the modified drug from binding to the ribosomal site. These features are as follows. 1. Disruption of the antibiotic binding pocket, formed by a base pair at positions 1409 and 1491, leads to aminoglycoside resistance in prokaryotes. 2. Enzymatic N1-methylation of A1408 is known to impair binding of the antibiotic to rRNA [128], a base that is a hydrogen bond acceptor in the A1408 ⭈ A1493 base pair. This modification gives resistance to kanamycins by disrupting the critical hydrogen bonding interactions between these two bases, which are required for aminoglycoside binding. 3. Enzymatic modification by acetylation of the amino group at position 3 of the 2-deoxystreptamine moiety would disrupt the essential hydrogen bonding between this amino group and G1494, as well as specific interactions with the A1493 phosphate. Any modification in ring I, which is tightly ensconced in the A1408 –A1493 pocket (e.g., such as the common 3⬘-phosphorylation or 6⬘-acetylation of aminoglycoside) prevents binding to rRNA by steric hindrance or undesired electrostatic interaction. Subsequently, the structure of the A-site region of rRNA in the absence of aminoglycoside was determined by Fourmy et al. by NMR spectroscopy [159]. Comparison of this structure with the paromomycin–rRNA complex indicated a local conformational change in the A-site RNA upon paromomycin binding. In the absence of paromomycin, the asymmetrical internal loop is closed by a Watson–Crick base pair (C1407 ⭈ G1494) and by two noncanonical base pairs (U1406 ⭈ U1495 and A1408 ⭈ A1493). The nucleic base A1492 stacks below A1493 and is intercalated between the upper and lower stems. Paromomycin binding stabilizes the conformation of A1492 and A1493, which are less well defined in the free RNA. It also changes the hydrogen bonding pattern of the A1408 ⭈ A1493 base pair such that hydrogen bonding increases from 1 in the free form to 2 in the bound form. Comparison of these free and bound conformations reveals that the two universally conserved residues, A1492 and A1493, are displaced toward the minor groove of the rRNA helix in the paromomycin–rRNA complex such that their N1-positions point into the minor groove of the A-site rRNA. These changes in the rRNA conformation, induced by the bound aminoglycoside,
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indicate a mechanism for the action of aminoglycoside antibiotics on translation, as elaborated shortly. Further studies on binding of the neomycin class of aminoglycosides to the A site of 16S rRNA revealed that neomycin B (23) binds to the rRNA with affinity similar to that of paromomycin (25) in slow exchange with the free form (Fig. 1d) [160]. This suggests that the change of the hydroxyl group with the amino group at position 6⬘ of ring I has little effect on aminoglycoside binding affinity. Other observations showed NMR chemical shift changes for ribostamycin (28) and neamine (4) similar to those collected for neomycin and paromomycin complexes, but with smaller magnitudes, indicating that rings I and II of the neomycin class of aminoglycosides are sufficient to direct their binding to a unique binding pocket on the model A-site RNA. The specificity of ribostamycin and neamine interactions with the A-site RNA also was demonstrated by footprinting on mutant oligonucleotides. The U1495 → A mutation resulted in significant decreases of binding affinity in paromomycin, ribostamycin, and neamine due to disruption of the ring II hydrogen bonding, indicating specific targeting to the A site of at least ring II of these aminoglycoside antibiotics. In a similar study, several functionalities in the major groove of the A-site RNA, including G1405 (N7), G1491 (N7), G1494 (N7), A1408 (N7), A1493 (N7), A1408 (N1), A1492 (N1), and A1493 (N1), as well as the pro-R phosphate oxygens of A1492 and A1493 in 16S rRNA (Fig. 1c) were identified as essential for a highaffinity paromomycin binding to the 16S rRNA from E. coli (161). Wong and colleagues investigated the specificity of ring IV of neomycin (Fig. 1) in binding to the A-site RNA [162]. They used the A-site RNA sequence previously employed by Puglisi and coworkers [15], which mimics the A site of the prokaryotic 16S ribosomal RNA as a binding target for antibiotic, to design a series of neomycin B derivatives modified in the idose ring (Fig. 3). The sequence of RNA with U1495 mutated to A (Fig. 3) was used as a negative control for in vitro binding studies because U1495 is a critical base for specific aminoglycoside binding, and replacement of this base with A leads to complete loss of specific binding [15,16]. The binding results showed similar specificity for neamine (4) and ribostamycin (28), but threefold lower affinity was observed for 28. Addition of an uncharged idose moiety to 28 to generate 129 does not change the affinity or specificity of binding, indicating the importance of the charged amino groups of the idose ring for binding. A 40-fold higher activity for compound 130, compared to 129, and further improvement of affinity in neomycin B (23) compared to that of 130, prove that the amino groups of idose ring are necessary for specific binding in vitro and that they cannot be replaced by the amino groups attached to flexible linkers. The basis for this assertion is that the addition of an amino group to ribostamycin via a flexible linker to furnish 127 increases the affinity to some extent, but specificity remains unaffected. Addition of one more amino group to generate 128 results in diminishing returns on the affinity without affecting the specificity. However, the minimum inhibitory concentration (MIC) data of these compounds showed comparable antibacterial activity to that of neomycin B, indicating that the in vivo activity does not always correlate well with the in vitro binding results. These discrepancies reflect probable conformational difference of the ribosome in vivo. Wong and coworkers in a recent investigation [163] studied the A-site-binding aminoglycosides, including the 4,5-disubstituted 2-deoxystreptamine derivatives (neomycin B, paromomycin, and ribostamycin) and the 4,6-disubstituted 2-deoxystrep-
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Figure 3 (a) Synthetic aminoglycosides to probe the role of ring IV of neomycin B. (b) The sequence of the model for the A-site RNA. (c) The sequence of RNA used as a negative control.
tamine aminoglycosides (kanamycins and gentamicins), to probe their specificities for the A site of the decoding region of rRNA. Two other structurally dissimilar Asite-binding antibiotics, hygromycin B (16) and apramycin (13), were tested as well. Figure 4 shows the structures of some aminoglycoside antibiotics. One common characteristic of all these A-site binders in chemical footprinting is the strong protection of G1494 (N7) of the 16S ribosomal RNA, although there are significant differences in terms of other footprints and resistance patterns. For example, methylation of G1405 (N7) confers resistance to gentamicins and kanamycins, but not to neomycin B. Surface plasmon resonance (SPR) [164] was used for direct observation of aminoglycoside interactions with the A-site RNA. These results indicated poor specificity for 4,6-disubstituted 2-deoxystreptamine aminoglycosides (kanamycins and gentamicins), good specificity for 4,5-disubstituted (neomycin class) antibiotics, moderate specificity for neamine, marginal specificity for apramycin (13), and none for hygromycin B (16). Likewise, streptomycin (73), which does not target the A site of the ribosome, shows no specificity for the A-site RNA sequence. These results suggest that the aminoglycosides target different regions of the same ribosomal RNA involving different RNA tertiary structural features, which cannot be well understood by the simple model for the A-site RNA.
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Structures of some aminoglycoside antibiotics.
Extending their work to search for small molecules that recognize RNA, Wong et al., considered the 1,3-hydroxyamine motif as a core for such molecules [162,165]. 1,3-Hydroxyamines can be effective motifs for molecular recognition of phosphodiesters because an interesting and common feature of almost all aminoglycoside antibiotics is the presence of a trans-1,3-hydroxyamine or cis-1,3-diamine motif. In fact, a model study by NMR spectroscopy [165] showed that the glyco-type 1,3hydroxyamines interact via multiple hydrogen bonds, with phosphodiesters and the Hougsteen face of guanine, which is typically stronger than the cyclic guanidine group (Fig. 5). To test these findings, new aminoglycoside derivatives were synthesized in a series bearing either one or both of these recognition motifs for RNA interaction
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Figure 5 Strong interactions of -1,3-hydroxyamine motif found in aminoglycoside antibiotics with (a) phosphodiesters and (b) Hougsteen face of guanine, compared to that of standard cyclic guanidine (c).
[162]. Some of the new compounds showed strong antibiotic activities and were effective in binding to the A-site RNA sequence (Fig. 3b) and to a drug-resistant mutant RNA in the micromolar range. For instance, compound 128 (Fig. 3a) with the neamine moiety as the recognition motif showed a Kd value of 0.26 M [162], and the pyranoside derivative compound 131 bearing the 1,3-hydroxyamine motif as the core exhibited a Kd value in the range of 10 M in binding to the A-site RNA model [162,166]. Application of this strategy in designing small molecules that target RNA could lead to development of potent sequence-specific RNA binders and potential discovery of new aminoglycoside antibiotics with less toxicity. In a recent communication by Rando and colleagues [167], simple aminols were reported to be effective A-site RNA binders with a potency similar to or greater than the potent RNA binder aminoglycoside paromomycin (25). Discovery of these simple 1,3-(2)-aminol-containing molecules (e.g., 132 and 133), which act as potent substituents for the structurally complicated aminoglycosides in binding to the bacterial A-site decoding region, would pave the way for the design and synthesis of a new class of potent antibiotics.
Compound 131
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Compounds 132 and 133
The measured dissociation constant for compounds 132 and 133 were 1.01 ⫾ 0.03 and 2.95 ⫾ 0.04 M, respectively, which are in the range of the Kd value measured for paromomycin (Kd = 1.90 M) binding to the A-site decoding region. These data actually show twofold greater potency for aminol 132 than for paromomycin, despite the structural simplicity of 132. It is noteworthy that compound 132, which contains three stereogenic centers, could exhibit more potency for the binding with the A site when it is used as a diasteriomerically pure isomer. Perhaps 1,3-(2)aminol moiety represents the essential structural element of aminoglycosides required for RNA interaction. B.
Specificity of Aminoglycosides for Binding to RNA Constructs Derived from the HIV-RRE and TAR RNA Activator Regions
Aminoglycoside binding to RNA is not limited to binding to prokaryotic 16S ribosomal RNA. These positively charged molecules interact with the HIV-1 Rev Response Element (RRE) transcriptional activator region [17] and TAR RNA [151], interfere with intron splicing [146], and bind to hammerhead ribozymes [153]. The HIV-1 RRE is an important region of the viral RNA, required for accurate and successful transcription of the HIV-1 genome [168,169], and replication of RNA viruses is dependent on specific interactions between the viral RNAs and viral proteins, such as Rev and Tat. The function of the arginine-rich Rev protein appears to be transportation of the RNA through the nuclear membrane into the cytoplasm, where the RNA is translated into viral proteins [168,169,170]. Therefore, inhibitors that interfere with the Rev-RRE binding could lead to the development of drugs effective in the treatment of AIDS [17]. A particularly useful fragment of Rev protein is Rev30–50 (a 16-mer peptide derived from the Rev protein; Fig. 6), which interacts with RRE IIB much as the full Rev protein does [171]. It exists in an ␣-helical conformation [172], and modifications of the peptide that increase the ␣-helical content and affinity of the protein, led investigators to conclude that the Rev protein contains an ␣-helical domain, which specifically interacts with the RRE region of the viral RNA [173]. Rando and coworkers employed fluorescence anisotropy methods to quantitatively measure aminoglycoside–RNA interactions [174,175]. These investigators used the RRE IIB construct of the HIV-1 RRE transcriptional activation region to determine the affinities of aminoglycoside to this biologically relevant construct. In this study, a fluorescent analog of Rev34–50 (Fl-Rev34–50) was prepared and shown by
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Structures of HIV-1 RRE IIB RNA and Rev peptides.
fluorescence anisotropy measurements to bind to RRE IIB in a stoichiometric fashion, with a dissociation constant of 7.6 nM. On the other hand, when neomycin B (23) and tobramycin (42), as well as a series of 6⬘-substituted tobramycin analogs were bound to RRE IIB, in competition experiments with Fl-Rev34–50, binding affinities in the range of 1–2 M were reported. These results indicate that binding of aminoglycosides to the RRE IIB region of the construct is not highly selective. Similarly, aminoglycoside antibiotics block the binding of HIV-1 Tat-derived peptide to its viral RNA target in a transactivator-responsive region (TAR). In a study by Mei and colleagues [151], Tat, an 86 amino acid regulatory protein of HIV-1 that contains an arginine-rich basic domain (residues 47–58) involved in binding to TAR RNA (residues 1–59 of HIV-1 mRNA), was replaced by a synthetic 40 amino acid (Tat40) peptide consisting of the TAR binding domain of the Tat protein. Interactions of this peptide (Tat40) with a 31-nucleotide RNA (TAR31), which contained residues 18–44 of the native TAR RNA, in the presence and absence of aminoglycosides, were monitored by gel electrophoresis. Three classes of aminoglycoside antibiotics, neomycin B (23: a 4,5-disubstituted 2-deoxystreptamine aminoglycoside), gentamicin C (51: a 4,6-disubstituted 2-deoxystreptamine), and a structurally dissimilar aminoglycoside, streptomycin (73), were chosen for inhibition of Tat40 binding TAR31. Among these selected antibiotics, neomycin B exhibited an IC50 of 0.92 ⫾ 0.09 M, whereas IC50 values of streptomycin and gentamicin C were 9.5 ⫾ 0.8 and 45 ⫾ 4 M, respectively, suggesting that the IC50 values are not simply correlated to the number of charged amino groups in these antibiotics. For instance, streptomycin (⫹3 charge), which is 10-fold less effective than neomycin (⫹6 charge), is 5-fold more effective than gentamicin (⫹5 charge) in inhibiting Tat40 binding.
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RNA Molecules That Specifically Bind Aminoglycoside Antibiotics with High Affinities
Despite a paucity of information at the molecular level on the principles associated with specific recognition of RNA sequences by aminoglycosides, targeting RNA sequences and recognition of specific sites of RNA molecules by aminoglycoside antibiotics are topics of salient interest. However, recent developments in in vivo selection methods resulted in identification of particular RNA sequences that specifically bind to certain aminoglycoside antibiotics with high affinity [174,176,177]. Rando and colleagues [178] have shown recently that a small (40-nucleotide) stem–loop (J6f1), derived from the high-affinity RNA aptamer J6 [174], can still bind tobramycin (42) specifically and with high affinity, as is the case with J6 itself. This construct (Fig. 7), which is quite specific for tobramycin, contains two bulges, one of three nucleotides and another of one that are essential for high-affinity tobramycin binding. The J6f1 aptamer can stoichiometrically bind tobramycin with a dissociation constant in the range of 5 nM, and it discriminates among similar aminoglycosides for binding. The aminoglycoside binding site of this construct was defined by a combination of chemical interference studies, chemical modification, and mutational studies. It was found that specific interactions of tobramycin with certain nucleotide bases in the stem–loop region are responsible for recognition of the aminoglycoside by J6f1, and specific interactions of tobramycin with the phosphate backbone are apparently not important for binding. Rando and colleagues [178] concluded that interactions of their positively charged amino groups with the negatively charged phosphate backbone of the RNA may not result in high-affinity binding in the nanomolar range. However, most of the aminoglycoside binding RNA molecules described so far appear to bind aminoglycosides in the micromolar range. To generate strong binders in the nanomolar range, specific contacts between aminoglycoside and nucleotide bases, rather than
Figure 7
(a) Structures of tobramycin and the 40-nucleotide RNA sequence (J6f1). (b) Structures of the 27-nucleotide RNA aptamer I and the 26-nucleotide RNA aptamer II.
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interaction with phosphate backbone, appear to be essential in RNA–aminoglycoside binding. Patel and coworkers [179,180] undertook an NMR–molecular dynamics study to solve the solution structure of the tobramycin complexed with two RNA aptamers. The 27-nucleotide RNA construct I (Fig. 7b) specifically binds to tobramycin (42) with affinity in the nanomolar range [174]. These investigators solved a low-resolution structure for tobramycin bound to the RNA aptamer I [179]. Their initial findings showed that tobramycin binds to the major groove centered about a stem– loop junction site, such that significant segments of the antibiotic are encapsulated between the floor of the major groove and a looped-out cytosine residue that forms a flap over the binding pocket in the complex. The high-resolution solution structure of the tobramycin–RNA aptamer II complex [180] revealed that the ring II of tobramycin is centrally positioned in the deep groove (about the G9 ⭈ A18 mismatch pair), such that its hydroxyl groups face toward the floor of the groove (Fig. 8). The 2-deoxystreptamine moiety (ring I) has its hydrophobic face directed toward the floor of the deep grove centered about the U10 ⭈ A17 and positioned closer to the C9-U10-U11 bases of the RNA construct. The amino sugar ring II, which is centered about the U12 base, interacts with the RNA deep groove through its positively charged amino group at position 2⬘, whereas its amino group at position 6⬘ is directed toward the milieu. The RNA aptamer II (Fig. 7b) discriminates against closely related aminoglycoside antibiotics. For instance, kanamycin B (38), which contain a hydroxyl group at the 3⬘-position instead of a hydrogen, as in tobramycin 42, forms a 1:1 complex with the RNA aptamer II. Whereas kanamycin A (37: replacement of amino group at the 2⬘-position of kanamycin B with a hydroxyl group) binds poorly to the same RNA target. Similarly, gentamicin C (51), having 3⬙-NH2 replaced by NHCH3, shows poor binding ability for this RNA aptamer. These findings demonstrate the importance of the amino groups at positions 2⬘ and 3⬙ for specific interactions with the edges of the base pairs of the deep groove of this particular RNA aptamer, which result in high specificity of binding for tobramycin. D.
Aminoglycoside Binding to the Hammerhead Ribozyme
The hammerhead ribozymes, derived from self-cleaving sequences found within natural RNA replicons, are like other self-cleaving RNA molecules in that they undergo a transesterification reaction that generates the 5⬘-hydroxyl and 2⬘,3⬘-cyclic phosphate termini. Crystal structures of two hammerhead ribozymes have been reported [181,182,183], and they have been shown to be efficiently inhibited by aminoglycoside antibiotics, particularly neomycin B (23) [153]. The activities of the hammerhead ribozymes characterized to date are strongly stimulated by the presence of divalent metal ions, typically Mg2⫹, and it is suggested that competition of positively charged aminoglycosides with Mg2⫹ is relevant to aminoglycoside binding and inhibition [184]. On the other hand, Murray and colleagues [185] have demonstrated that metal ions are not obligatory chemical participants in the catalytic reactions and self-cleavage of hammerhead ribozyme. These findings suggest that the catalytic function of the ribozyme is influenced by the folded structure of the RNA itself, as well as the presence of a relatively dense positive charge, than by divalent metal ions.
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Figure 8
The NMR structure of the tobramycin–RNA complex. Tobramycin is shown by the capped-stick presentation. A portion of the RNA structure at the aminoglycoside binding site is shown as a surface.
Aminoglycoside binding to the hammerhead ribozyme 16 (HH16; Fig. 9a) [153] was found to be specifically effective with neomycin B. Interactions of the antibiotic with the enzyme–substrate complex were suggested to reduce the cleavage rate by stabilizing the ground state and destabilizing the transition state of the complex, leading to phosphodiester cleavage. These workers studied the inhibition as a function of pH and Mg2⫹ concentration and concluded that the positively charged antibiotic inhibits the hammerhead ribozyme by displacing critical magnesium ions at physiological pH. Wang and Tor [186], who probed the role of electrostatic interactions in aminoglycoside–RNA binding, found that the positively charged amino groups play an important role in affinity of binding and displacement of Mg2⫹ ions. These workers made a series of aminoglycosides with increasing number of amino groups (compounds 134–136 , Fig. 9b) by simple conversion of the hydroxymethyl group in the natural aminoglycosides to the basic aminomethyl group. All these synthetic amino
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Figure 9
(a) The secondary structure of the hammerhead ribozyme 16 (HH16) showing the enzyme (E16) and the substrate (S16). (b) Structures of some semisynthetic and natural aminoglycosides.
derivatives showed higher binding affinity for the hammerhead ribozyme than the parent compounds. For instance, 6⬙-amino-6⬙-deoxykanamycin A (134) showed enhanced affinity compared to kanamycin A (37), a poor RNA binder, and was as effective as kanamycin B (38), a natural product containing five amino groups. Likewise, 6⬙-amino-6⬙-deoxytobramycin 135 and 5⬙-amino-5⬙-deoxyneomycin B (136) showed about fivefold enhanced binding affinities for the hammerhead ribosome, suggesting the importance of the overall charge of these small molecule ligands for RNA binding affinity. These investigators [187] have also shown that the binding affinities of aminoglycosides for the hammerhead ribosome correlate with the basicity of the amino groups in these RNA binders. They compared binding affinities of two aminoglycoside antibiotics tobromycin (42) and kanamycin B (38), which have same number of amino groups (five). Tobramycin, which is 3⬘-deoxykanamycin B, inhibits the
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hammerhead ribozyme more effectively than kanamycin B itself. Therefore, the absence of a hydroxyl group next to an amino group might increase the basicity of that amino group inductively and enhance the RNA binding affinity of the compound. To probe this possibility, Wang and Tor [187] prepared a number of deoxygenated tobramycin analogs (compounds 137–140 ) and found increased inhibitory activity for 4⬘-, 2⬙-, and 4⬙-deoxy analogs, which involved hydroxyl group deletion on a carbon vicinal to an amino group. In contrast, 6⬙-deoxytobramycin (140), with hydroxyl deletion remote from an amino group, exhibited poorer inhibitory activity than the parent antibiotic. These results support the critical role of electrostatic interactions in RNA binding, indicating the importance of the basicity of the amino groups in RNA binding affinity of aminoglycoside antibiotics at physiological pH. Hermann et al. [188,189] have demonstrated that the positively charged amino groups of an aminoglycoside antibiotic are capable of displacing three or four magnesium ions located within the cavity formed by the deep grooves of stems I and II in the hammerhead crystal structure [182,183]. These workers used molecular dynamics simulations on complexes of the hammerhead RNA and aminoglycoside antibiotics and showed that the interactions between RNA and amino groups of aminoglycosides are almost identical with the observed interactions for Mg2⫹ in the hammerhead crystal structure [188]. It has also been noted that more than one solution conformation of aminoglycoside antibiotics could be docked with the hammerhead RNA. These would lead to a set of spatially oriented, positively charged amino groups that could be complementary in various ways to the field created by an electronegative cavity of the hammerhead RNA, which results in high-affinity binding. These high-affinity interactions of different solution conformations of aminoglycosides could be facilitated by water-mediated interaction between the antibiotic and the RNA molecules. This diversity in recognition and binding, derived from water-assisted, spatially positioned charges, suggests a three-dimensional electrostatics model rather than a highly spe-
Compounds 137–140
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cific drug–RNA interaction, for interaction between these charged antibiotics and different RNA molecules [190]. E.
Inhibition of Group I Introns by Aminoglycoside Antibiotics
Inhibition of the first step of splicing by binding of an exogenous guanosine to the G-binding site (guanosine binding site) in the ribozyme results in cleavage of the 5⬘ splice site via a transesterification process, leading to attachment of the guanosine to the first nucleotide of the intron. The second step of splicing, which involves a configurational transition for proper accommodation of the terminal nucleotide of the intron (always a guanosine) into the G-binding site, occurs via a second transesterification process that cleaves the 3⬘ splice site, resulting in ligation of exons and releasing of the intron [191,192]. Von Ahson and colleagues [144,146] demonstrated that aminoglycoside antibiotics inhibit self-splicing of group I intron RNA in vitro at micromolar concentrations. These workers tested a series of 4,5- and 4,6-disubstituted 2-deoxystreptamine aminoglycoside antibiotics, including neomycins, kanamycins, and gentamicins [146]. Of these, neomycin B (23) was found to be the most active aminoglycoside in inhibiting the splicing reaction. In the kanamycin family, the order of activity for inhibition of splicing was shown to be tobramycin (42) > kanamycin B (38) > kanamycin A (37) > kanamycin C (39). However, tobramycin and gentamicin C (51) exhibited inhibitory activities comparable to that of neomycin B, in the range of 1 M. It was thought that aminoglycoside antibiotics inhibit only the second step of the splicing of the td intron, but further study of structure–activity relationships between aminoglycoside and self-splicing of group I introns revealed that antibiotics other than gentamicin (e.g., 5⬘-epi-sisomicin) also inhibit the first step of splicing with inhibitory activity concentration similar to that of neomycin B, in the range of 0.5 M [144]. The known inhibitors of group I intron RNA self-splicing, including dGTP, ddGTP, arginine, and streptomycin, which exert their inhibitory effects by competing with the substrate guanosine, show Ki values in the millimolar range [143,193,194]. Therefore, guanosine (estimated intracellular concentration of 1 mM) would compete with these inhibitors, such that no inhibition would take place in vivo. On the other hand, these new inhibitors inhibit splicing by a different mechanism at micromolar concentration, and they show noncompetitive inhibition at high concentrations of guanosine [144]. To elucidate the mechanism of splicing, a mutant group I intron, having the conserved guanosine of the G-binding site replaced by an adenosine, was employed in splicing inhibition studies. This mutant variant was as sensitive to aminoglycoside antibiotics as the wild type, providing direct evidence that the antibiotics do not interact with the G-binding site. Furthermore, the results suggested that the binding site(s) might be in a region near the catalytic core of the group I introns and not necessarily at the G-binding site [144]. Further studies by von Ahsen and Noller [145] on footprinting the sites of interaction of neomycin with the catalytic group I intron RNA suggested that neomycin prevents docking of the p1 stem (bearing the 5⬘ splice site) to the catalytic core and inhibits cofactor binding. Aminoglycoside antibiotics as specific inhibitors of splicing might be of interest should they inhibit growth of the organisms [195], with possible applications in development of a new class of antifungal agents.
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Inhibition of the Human Hepatitis Delta Virus (HDV) by Aminoglycoside Antibiotics
The human hepatitis delta virus (HDV), a 1700-nucleotide single-stranded RNA virus, like other self-cleaving RNAs, undergoes a transesterification reaction that generates a 5⬘-hydroxyl group [196]. Both genomic and antigenomic sequences contain ribozymes that are important for viral replication, and it appears that the HDV ribozyme requires divalent metal ions for self-cleavage [185]. In 1996 Rogers et al. [156] used genomic and antigenomic plasmid constructs of the HDV ribozyme and demonstrated that autocatalytic activity of both HDV ribozymes can be inhibited by aminoglycosides at micromolar concentrations. A variety of aminoglycosides and nonaminoglycoside antibiotics known to inhibit the group I intron splicing were tested for their inhibitory activity against these selfcleaving HDV ribozymes. Among aminoglycoside antibiotics tested, only a small number, including gentamicin C (51), neomycin (23), and 5⬘-epi-sisomicin were active as inhibitors, yet their inhibitory activities were less than those for inhibition of the group I intron ribozyme. Kanamycin A (37) was a poor inhibitor, and paromomycin (25: having 6⬘-NH2 of neomycin B replaced by a hydroxyl group) showed poor activity relative to neomycin B. The mechanism whereby neomycin B inhibits ribozyme function has yet to be elucidated. However, existing results [156] suggest a competitive inhibition of this catalytic RNA by neomycin B, implying that this antibiotic inhibits HDV ribozyme cleavage by disruption of the divalent cationic binding near the catalytic core of the ribozyme.
VI.
TOXICITY OF AMINOGLYCOSIDE ANTIBIOTICS
It has been known for a long time that aminoglycoside antibiotics cause ototoxicity (i.e., mid-ear damage resulting in loss of hearing). It is known that aminoglycoside treatment results in the destruction of cochlear cells in the mid-ear that are responsible for the reception and analysis of sound. The cases of vestibular toxicity and loss of hearing are well documented owing to long-term use of aminoglycosides, in particular gentamicin [197]. Aminoglycosides are also known to cause vestibular nerve damage, causing loss of balance (ataxia), dizziness, and so on. Ototoxicity has been a serious problem associated with aminoglycosides. The mechanism of such toxicity has been elusive. Recently, a hypothesis for the aminoglycoside toxicity was proposed [198,199]. Observations that gentamicin chelates with iron and also forms free radicals led to the hypothesis that iron chelation and free radical generation might be sources of gentamicin toxicity. In addition, it was noted that free radical scavengers and iron chelators reduce the toxicity of gentamicin, as well as that of other aminoglycosides such as kanamycin and streptomycin [200]. Further experimentation will be necessary to confirm either mode of toxicity manifestation. Various studies with aminoglycosides have also led to the hypothesis that even after the use of aminoglycoside antibiotics has been discontinued, the compounds accumulate in the biological system and may manifest their toxic effects in symptoms such as ototoxicity. Loss of hearing, a result of hair cell toxicity, appears to be due to mitochondrial mutation in hair cells in individuals who are susceptible to this side effect [201].
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Aminoglycosides possess affinity toward prokaryotic RNA, due to which they exhibit strong binding to various sites on RNA. However, eukaryotic mitochondrial ribosomes (such as in hair cells) are structurally similar to their ancestral prokaryotic ribosomes. This perhaps explains the affinity of aminoglycosides to mitochondrial RNA and their ability to interfere in the process of protein synthesis in mitochondria [201]. From a study of 41 human families, it was concluded that the hypersensitivity toward aminoglycosides is transmitted via maternal lineage. Studies involving several hundred individuals indicated that a genetic mutation in mitochondrial 12S subunit of ribosomal RNA at position 1555 to a ‘‘G’’ was perhaps responsible for the hypersensitivity toward aminoglycosides [201]. From the comparison of secondary structures of prokaryotic rRNA and mitochondrial 16S rRNA, it was concluded that the G1555 mutation lies in a very highly conserved region of the stem–loop that is involved in aminoglycoside binding in bacteria. It was argued that the G1555 mutation forms an additional base pair with a cytosine on the opposite strand of rRNA, and this leads to shrinkage of the volume of rRNA at this site, allowing more space for aminoglycoside binding [201]. Based on this mechanism of mitochondrial toxicity, Hutchin and Cortopassi proposed a molecular mechanism of the toxicity to hair cells in conjunction with the foregoing rRNA mutation [201]. According to their hypothesis (Fig. 10), binding of aminoglycoside to the mitochondrial rRNA leads to mistranslation of mitochondrial proteins and a deficiency of mitochondrial complex I. These events lead to the deficiency of superoxide dismutase and cause overproduction of superoxide in mitochondria. Thus, the mitochondria are subjected to oxidative damage, leading to cell death. Evidence exists that intrastriatal administration of neomycin to rats causes damage to the glial cells in the central nervous system [202]. Upon coadministration of N-methyl-D-aspartate (NMDA), gliosis was enhanced, indicating that neomycin is acting at the NMDA receptors. Further, in the presence of NMDA receptor antagonists, the toxicity exhibited by neomycin was attenuated. However, paromamine and 2-deoxystreptamine did not produce such damage. This study shows that aminoglycosides such as neomycin may cause excitation of NMDA receptors, which may, at least in part, be the cause of ototoxicity of aminoglycosides. When the blood– brain barrier does not deter aminoglycosides, these compounds may cause central nervous system damage.
Figure 10 The hypothetical mechanism of damage to hair cells due to the aminoglycosideinduced mistranslation of mitochondrial genes [201].
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Aminoglycosides seem to function like polyamines at the NMDA receptors [203]. Endogenous polyamines such as spermine and spermidine and various derivatives of these compounds serve as positive modulators of NMDA receptors, and their interactions are complex. It is proposed that the primary and secondary amines present on the aminoglycoside molecules render the polyamine-like properties to aminoglycosides, and it appears that all the clinically useful aminoglycoside antibiotics exhibit polyamine-like properties with the NMDA receptor [203]. Surprisingly, individual sugar moieties in aminoglycosides did not produce potent modulation of NMDA receptor activity, indicating that the NMDA receptor binding is the property of the entire molecule rather than the effect of individual amino sugars. It also appears that an increased number of amino groups on an aminoglycoside does not necessarily increase the NMDA binding ability of aminoglycosides or increase the ototoxicity, although this remains a controversial issue. Recently, Sha and Schacht performed a study with gentamicin in guinea pigs and showed that simple iron chelators such as malic acid, tartaric acid, and even dimethyl sulfoxide, can protect these animals from the hearing loss caused by gentamicin [204]. Malic acid and tartaric acid are dicarboxylic acids that can chelate iron, and dimethyl sulfoxide scavenges free radicals such as hydroxyl radical. The most important and common acute toxicity caused by aminoglycoside treatment is renal dysfunction or nephrotoxicity, and comprehensive review articles on the molecular mechanisms of nephrotoxicity of aminoglycosides have been published [205,206,207]. Clinically, renal toxicity is manifested by the increase of blood urea and serum creatinine levels, as well as by alteration of the glomerular filtration rate (GFR). Although the effects of aminoglycosides on the kidney are reversible and rarely cause death, since renal clearance is affected, kidney dysfunction leads to complications in patients who are on multiple drugs and in other hospitalized patients. Aminoglycosides are not metabolized in the body significantly and are excreted by the kidneys. In kidneys, aminoglycosides are filtered through the glomerulus, and some amount is reabsorbed in the proximal tubule. Aminoglycosides bind to the brush-border membranes of proximal tubules and enter the tubular cells by endocytosis. Thus, aminoglycosides accumulate in the proximal tubular cells and distal parts of nephron, reaching concentrations much higher than those in serum. Following the uptake of aminoglycosides, proximal tubular epithelial cells show structural alterations leading to tubular necrosis by a number of mechanisms [205,206]. Aminoglycosides are known to be associated with lysosomes to form ‘‘myeloid bodies’’ and result in swelling of lysosomes. Additionally, aminoglycosides are implicated in altering the plasma membrane structure by binding to the phospholipids. Phospholipid catabolism in the proximal tubular cells is impaired by aminoglycosides owing to decreased activity of sphingomyelinase and phospholipase A1, leading to the accumulation of phospholipids in lysosomes. Aminoglycosides are protonated in the acidic environment of the lysosome and bind to the phospholipids. There is no experimental evidence on how the binding of aminoglycosides to the phospholipids inhibits the hydrolytic activity of phospholipases, but it is thought that aminoglycosides create a less favorable environment for the cleavage of phospholipids by the hydrolytic enzymes in the lysosome [207]. There are also hypotheses that aminoglycosides damage mitochondrial respiratory mechanisms, leading to decreased levels of ATP, and may alter the activity of Na⫹/K⫹-ATPase [206]. It is not clear which
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mechanism accounts for the proximal cell death, but damage of these cells leads to the altered GFR. Most of the data presented so far show that the phospholipidosis due to aminoglycosides leads to the tubular cell death, ultimately impairing renal function. Although the impairment of the kidneys by aminoglycosides is serious, the aminoglycoside-damaged cells in the proximal tubules are regenerated eventually, restoring the renal tissue architecture [205,208]. The extent of nephrotoxicity is a characteristic of the individual aminoglycoside antibiotics and appears to be directly related to the number of cationic groups on the aminoglycoside [207]. REFERENCES 1. 2. 3. 4.
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11 Methodologies in Syntheses of Aminoglycoside Antibiotics Jalal Haddad, Mei-Zheng Liu, and Shahriar Mobashery Wayne State University, Detroit, Michigan
I.
INTRODUCTION
Many aminoglycoside antibiotics that are being used as therapeutic agents are semisynthetic products. These compounds show excellent antibiotic properties, yet they suffer from ototoxicity and renal toxicity. Furthermore, bacterial resistance to aminoglycosides is widespread among pathogens, resulting in failure of these antibiotics in the treatment of infectious diseases. As a consequence, these antibiotics have been the targets of structure alteration to expand their spectrum of activity, to limit their susceptibility to resistance enzymes, and to reduce their undesirable toxic properties. Since, however, these compounds are multifunctional molecules, they present challenges in synthetic transformations, which have stimulated the development of chemistry special to them. The decade of 1970s witnessed a burst of activity in the development of synthetic methodology for aminoglycosides [1–4]. There has been renewed interest in these antibiotics because of the new properties that have been shown to be associated with aminoglycosides [5]. Yet another reason is the recent availability of three-dimensional structures for the aminoglycoside resistance enzymes [6] and RNA binding sites for these drugs. To make this chapter a definitive review of the chemistry of aminoglycosides, we discuss only briefly the most important contributions from the earlier literature. The major coverage centers on findings from the early 1980s to the present. II.
SELECTIVE N-PROTECTION AND MODIFICATION OF AMINOGLYCOSIDE ANTIBIOTICS
Aminoglycoside antibiotics that are being used currently for treatment of serious infections by Enterobacteriaceae or Pseudomonas aeruginosa, are mostly semisyn353
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Compounds 1–5
thetic compounds. These have been synthesized from their natural product parent precursors to increase their antibacterial activities and reduce the renal and otovestibular toxicity associated with these drugs [7]. Many of these semisynthetic antibiotics (compounds 1–5 ), such as netilmicin 1 (1-N-ethylsisomicin) [8], amikacin 2 [1-N-(S)-4-amino-2-hydroxybutanoylkanamycin A] [9], and isepamicin 3 [1-N-(S)-3amino-2-hydroxypropanoylgentamicin B] [10] are aminoglycosides modified at position 1 of the 2-deoxystreptamine moiety, prepared by selective protection and modification of the amino groups of the antibiotics. These synthetic targets are challenging because aminoglycosides often bear four to six amino groups with comparable reactivities. To overcome this problem, methods have been developed to take advantage of specificity of the amino groups of aminoglycosides for regioselective chemical modification, due to their varying nucleophilicity. In one method, regioselective modification can be achieved based on the differences in reactivities of the amino groups due to varying basicity or steric environment of these functional groups. The second and more important method, application of transition metal ions in temporary protection of some amino groups by complexation, leads to deactivation of the coordinated amino groups, leaving the others free for further chemical manipulation. A.
Selective Modification of Aminoglycosides Based on Varying Reactivities and Basicities of the Amino Groups
Kawaguchi et al. [9] selectively modified aminoglycosides to prepare amikacin 2, a valuable and potent analog of kanamycin A, with activity against many strains of
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the Enterobacteriaceae and P. aeruginosa that show resistance to most other aminoglycoside antibiotics [11]. The order of reactivity of the amino groups of kanamycin A (4), toward (benzyloxycarbonyloxy)-succinimide and other carbamoylating reagents is 6⬘-NH2 > 1NH2 > 3-NH2 > 3⬙-NH2. Therefore, the amino group at position 6⬘ was first protected by the reaction of benzyloxycarbonyloxy succinimide in low yield, and subsequently the (S)-4-amino-2-hydroxybutanoyl (ABH) group was introduced to the amino group at position 1 with poor selectivity. Removal of the Cbz group at position 6⬘ furnished amikacin. The same order of reactivity has also been observed for kanamycin B (5), which possesses an extra amino group at position 2⬘ with reactivity comparable to that of 6⬘-amino group (6⬘-NH2 > 2⬘-NH2 > 1-NH2 > 3-NH2 > 3⬙-NH2) [12]. Therefore, the 1-N-ABH derivative of kanamycin B was prepared by selective protection of the 2⬘and 6⬘-amino groups, and the resulting product was acylated by ABH to give the 1N-ABH analog with poor selectivity [12]. A similar sequence of reactions in the hands of several other investigators led in general to poor selectivity and formation of regioisomeric mixtures of products [13,14]. However, this method offers procedures that rely only on varying reactivities and basicities of the amino groups for selective protection, an approach that results in poor selectivity and does not seem to be a reliable means of regioselective modification of aminoglycoside antibiotics. B.
Application of Transition Metal Ions in Regioselective Modification of Aminoglycosides
Aminoglycoside antibiotics have long been known to make complexes with transition metal ions. It was discovered in 1966 that the addition of a solution of ammoniacontaining copper(I or II) salts to these amino sugars can be useful for analytical purposes [15]. In fact, addition of the ammonia solution of copper led to significant changes in optical rotation of the amino sugars bearing vicinal hydroxyl and amino groups [15]. After this early finding, transition metal salts were found to be useful for synthetic purposes when Hanessian et al. [16] took advantage of complexation of Cu(II) ion with the vicinal amino alcohol functions to selectively acylate the uncoordinated amino groups of kanamycin A via temporary chelation of the vicinal aminohydroxyl groups with Cu(II) ions. Soon after these initial results, the same chemistry was applied to other classes of aminoglycoside antibiotics, and a variety of other metal ions (Co2⫹, Ni2⫹, Cd2⫹, etc.) were employed as chelating agents for proximal (vicinal or nonvicinal) aminohydroxyl functions. For instance, sisomicin, gentamicins, and kanamycin A were selectively acylated by various acylating agents in the presence of Co2⫹, Ni2⫹, or Cu2⫹ by Nagabhushan et al. [17,18]. These workers demonstrated that Ni2⫹ and Co2⫹ temporarily mask the amino groups at 1- and 3⬙-positions, leaving the 3- and 6⬘-amino groups free for acylation. The data indicate that chelation of the vicinal (3⬙ and 4⬙), as well as nonvicinal (1 and 2⬙) aminohydroxyl groups, with these divalent ions led to protection of 1- and 3⬙-amino groups, allowing selective acylation of the uncoordinated sites. A similar strategy was used by Daniels and colleagues [19] to prepare 1-NAHB analogs of gentamicin B (6), kanamycin A (4), and 3⬘,4⬘-dideoxykanamycin B through their corresponding 3,6⬘-di- or 3,2⬘,6⬘-tri-N-acyl-protected derivatives. These investigators were able to prepare isepamicin (3) in high yield (60%) via chelation
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of the 1- and 3⬙-amino groups of gentamicin B (6) with cobalt(II) acetate. Acylation of the 3- and 6⬘-amino functions in complex 7 followed by the decomplexation of the coordinated amino groups with hydrogen sulfide gave compound 8, which then was converted to 3 by selective introduction of the aminohydroxypropanoyl group at position 1, and deprotection of the protecting groups (compounds 6–8 ). Among the other divalent transition metals, Zn2⫹ ion proved to be a very efficient chelating agent for work on the preparative scale [20–22]. It was employed by Tsuchiya et al. to prepare amikacin (2) by a sequence of reactions involving temporary protection to the 1- and 3⬙-amino groups of kanamycin A (4) by zinc complexation and acylation of the free amines at the 3- and 6⬘-positions to form the Cbz-protected derivative 9, followed by selective trifluoroacetylation at the 3⬙-position to furnish 10 (compounds 9, 10). The selective acylation at the 3⬙-position was believed to be directed by the neighboring hydroxyl group participation. Finally treatment of 10 with an active ester of (S)-4-(benzyloxycarbonylamino)-2-hydroxybutyric acid, followed by hydrogenolysis with palladium black, gave the product in high yield (>60%). The same procedure was also applied to prepare a 1-N-AHB derivative of kanamycin B [20]. A combination of metal ions can be used in selective acylation of amino groups in consecutive sequence of reactions as is described in the synthesis of 1-C-hydroxymethylkanamycin B [23]. In this synthesis, the amino groups of kanamycin B (5) at positions 3, 2⬘, and 6⬘ were first protected with di-tert-butyldicarbonate in the presence of Zn(II), and then the amino group at the 1-position was selectively protected
Compounds 6–8
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Compounds 9 and 10
in the presence of Cu(II), leaving the 3⬙-position free for further manipulation. The same combination of transition metals (Cu2⫹ and Zn2⫹) was also employed for regioselective protection of the amino groups in the syntheses of a series of deaminated derivatives of neamine [24]. When neamine (11) was treated with N-butoxycarbonyloxy-5-norbornene-endo-2,3-dicarboxamide (16) in the presence of Zn(II), the diBoc-protected derivative 12 was obtained, which was subsequently protected at position 3 with N-benzyloxycarbonyloxy-5-norbornene-endo-2,3-dicarboxamine (17) (compounds 11–17 ) in the presence of copper(II) to give the neamine derivative 13, having the 2⬘-amino group free. On the other hand, when initial protection of neamine 11 was performed in the presence of Cu(II), the neamine derivative 14 was formed, which was then converted to compound 15 by further manipulations. The hindered reagents 16 and 17 have also shown good selectivity for the seemingly unhindered amino groups in the absence of transition metal ions [25,26]. For instance, when neamine 11 was treated with 16 (1 equiv.), 6⬘-N-protected neamine derivative was exclusively formed in 65% isolated yield and 22% of the unreacted neamine was recovered. In a similar manner kanamycin A (4) was selectively protected at the 6⬘-position to give the monoprotected product in high yield (70%) [26]. Metal-directed protection of amino groups can even be further improved by using a mixture of divalent transition metals. For instance, treatment of kanamycin B (5) with di-tert-butyldicarbonate in the presence of Zn(II) acetate leads to protection at 3-, 2⬘-, and 6⬘-positions (see above), whereas when 5 was subjected to the same reagent in the presence of a mixture of Zn(II) and Cu(II) ions, compound 18 resulted, which is protected only at the 3- and 6⬘-positions. Subsequent treatment of this intermediate with Zn(II) acetate yielded a complex having the 1- and 3⬙-amino groups coordinated, allowing selective introduction of the Cbz group at the 2⬘-position to afford the derivative 19 [27] (compounds 18, 19). Among transition metal ions employed in regioselective modification of aminoglycosides, Zn2⫹ and Cu2⫹ are the most common. They have been used repeatedly
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in the syntheses of a variety of potent semisynthetic antibiotics, mainly 1-N-acylated derivatives, by several different research groups [23,28–31]. III.
GLYCOSYLATION METHODS
A.
1,2-trans Glycosylation
As known in the general oligosaccharide syntheses [32,33], 1,2-trans glycosylation is more convenient than 1,2-cis glycosylation, and it can be achieved by neighboring group participation of the acyl group protected hydroxyl or amino group at the C2 position of the glycosyl donor. Formation of a cyclic intermediate between the C1 and C2 atoms of the glycosyl donor in the presence of promoters prevents the ␣face attack and leaves the  face open for the approach of the glycosyl acceptor. In a recent synthesis of neomycin analogs [34], the glycosyl donor 21, having the Op-nitrobenzoyl group at position 2, was employed. In this synthesis, the neamine derivative 20 was used as the glycosyl acceptor to couple with 21 in the presence of borane trifluoride etherate as the promoter, to afford the key intermediate glycoside 22 (compounds 20–22 ). A similar strategy was also applied in several other examples of aminoglycoside synthesis [35–37]. B.
1,2-cis Glycosylation
Compared to 1,2-trans glycosylation, it is more difficult to construct 1,2-cis-glycosidic linkage in high selectivity and yield. However, this is what is needed in the syntheses of the majority of aminoglycoside antibiotics. A solution to this problem is found in the popular strategy of the use of glycosyl donors with nonparticipating protective groups as the substituent for the functionality at the position 2. This strategy gives 1,2-cis glycosides selectively due to the anomeric effect. For the amino sugars with the amino group at position 2, four glycosyl donors with various substituents at this position have been developed. The first strategy uses a Schiff base as the amino protective group in glycosylation reaction. Umezawa and colleagues [4] have successfully accomplished the total synthesis of paromamine, neamine, neomycin C, streptomycin, dihydrostreptomycin, and lividomycin B by the use of 4-methoxybenzylimino as the 2-amino substituent. For example, in total synthesis of streptomycin 26, the L-acetylbromoglucosamine derivative 23 was coupled with the acceptor alcohol 24 to afford the ␣-L-glycopyraniside 25 [38,39] (compounds 23–26 ).
Compounds 20–22
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Compounds 23–26
Alternatively, employment of the glycosyl donors bearing the 2,4-dinitrophenylamino substituent at position 2 in the presence of insoluble promoters such as AgOTf and AgClO4, led to the formation of the glycosidic linkage in favor of the 1,2-cis anomer in moderate yields. Thus, in total syntheses of fortimicin B (30) and ribostamycin, glycosylation of the glycosyl chloride 27 with the aminoinositol derivative 28 gave the corresponding ␣-glycoside 29 [40] (compounds 27–30 ).
Compounds 27–30
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The azido group is another nonparticipating protective group as an amine surrogate in the glycosyl donor counterpart for 1,2-cis glycosylation reaction. -Glycosyl chlorides, but not bromides owing to their instability, are the most commonly used donors in such condensation in the presence of soluble promoters. However, in situ formation of -glycosyl bromides from their corresponding chloride derivatives may be used for these glycosylation reactions. In the total synthesis of neomycin B (34), the 2-azido derivative 31 was condensed with the acceptor alcohol 32 to give the 1,2-cis-glycoside 33 in the presence of mercuric cyanide and mercuric bromide, which was subsequently reduced to afford the 2-amino product [41] (compounds 31–34 ). The final useful method for the 1,2-cis glycosylation reaction involves an addition–elimination–reduction sequence, developed by Lemieux in the 1970s [42– 44]. This strategy was successfully employed in the syntheses of streptomycin and gentamicins. For example, the addition of nitrosyl chloride to the acetylated glucal 35 resulted in the formation of the dimer adduct 36, which underwent reaction with the acceptor alcohol 37 to yield ␣-oximino glycoside intermediate 38. Compound 38 was subsequently reduced by hydrogenation and deprotection to afford gentamicin X2 (39) [43] (compounds 35–39 ). In the case of amino sugars with the hydroxyl group at position 2, the use of the benzyl group as the hydroxyl protective group leads to stereoselective formation of 1,2-cis-glycoside. Thus, the 2-O-benzyl-protected glycosyl bromide 40 was coupled with the alcohol derivative 41 to produce conveniently the ␣-glycosidic product 42 in 44% yield [45] (compounds 40–42 ). Besides the bromo and chloro functions as the anomeric leaving group, several other glycosyl donors have been utilized. For example, -glucopyranosyl fluoride was employed in the total synthesis of apramycin 48 and saccharocin (KA-5685) 49
Compounds 31–34
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Compounds 35–39
[46]. The glycosylation of the fluoride derivatives 43 or 44 with the aprosamine derivative 45 under modified Mukaiyama conditions selectively provided the 1,2cis-glycosides 46 and 47, respectively, in 40 and 24% yields. Also, the thioglycoside 50, activated by methyl trifluoromethanesulfonate, has been used for the preparation of sorbistin analogs by treatment with the glycosyl acceptor 51, to yield mainly ␣glycoside 52 [47] (compounds 43–52 ). It should be noted that the addition of aminocyclitol derivatives to glycals catalyzed by boron trifluoride etherate also affords 1,2-cis-aminoglycosides stereoselectively. Thus, the glycosyl product 54 with an ␣-anomeric linkage was obtained in 65% yield by addition of the alcohol 53 to the glycal 35 [48] (compounds 53, 54). In summary, although a large number of naturally occurring aminoglycoside antibiotics and their derivatives have been synthesized, glycosylation methods in this area have not been well developed. This is a major problem especially in 1,2-cis
Compounds 40–42
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Compounds 43–52
glycosylation, which often results in a mixture of anomeric products with low yield. In most cases, the modified Koenigs–Knorr condensation is still the most widely used method. IV.
TOTAL SYNTHESIS AND CHEMICAL MODIFICATION OF THE AMINOGLYCOSIDE ANTIBIOTICS
A.
4-Substituted 2-Deoxystreptamine-Containing Aminoglycosides: Paromamine, Neamine, Paromamine, Apramycin, and Related Compounds
1.
Neamine
The quinic acid derived 2,5,6-trideoxystreptamine analogs 61 was used to prepare 5,6-dideoxyneamine (62) biosynthetically from Streptomyces fradiae [49]. The crucial intermediate for synthesis of 61 was the hydroxyketone 55, which is readily available from quinic acid. Treatment of 55 with p-toluenesulfonyl chloride in pyridine gave enone 56, which after catalytic hydrogenation generated the saturated ketone 57. Stereoselective reduction of 57, followed by tosylation, furnished deriv-
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Compounds 53 and 54
ative 58, which underwent cyclohexylidene deprotection and selective tosylation to afford 59. Conversion of 59 to the diazo compound 60, followed by subsequent hydrogenation gave the streptamine derivative 61, which was employed to make the 5,6-dideoxyneamine 62. The intermediate 59 was also used to prepare the 3⬘,5,6trideoxykanamine analog 66 by a glycal coupling procedure; the glycal 63 was used for the glycosylation in the presence of a catalytic amount of boron trifluoride etherate to afford 64 and 65 as a mixture of ␣ and  isomers, respectively, in a 7:3 ratio. The ␣ isomer 64 was converted to 66 by sequential azide treatment, deacetylation, and catalytic reduction (compounds 55–66 ). Periodate oxidation has been used to prepare the sorbistin analog 68 from the appropriately protected neamine derivative 67 [50]. Likewise the acetal analog of 2deoxystreptamine (69) was prepared by selective cleavage of the C3—C4 bond of the neosamine moiety by subsequent oxidation, followed by borohydride reduction and deprotection (compounds 67–69 ). In an attempt to prepare potent analogs of neamine, Sitrin and colleagues [51] have synthesized a series of amino derivatives of neamine including 3⬘- and 4⬘amino analogs, as well as their 3⬘- and 4⬘-epimers. However, all these amino neamine derivatives were found to be less active than the parent compound. Reductive radical elimination (Barton deoxygenation) of the 3⬘,4⬘-xanthate derivative of neamine (70) has been used to prepare the key intermediate 71 (compounds 70, 71) for the synthesis of the 3⬘,4⬘-dideoxyneamine analog gentamine C1a [52]. In this synthesis, a precursor possessing free hydroxyl groups at positions 3⬘ and 4⬘ was treated with a mixture of carbon disulfide, aqueous sodium hydroxide, and methyl iodide in DMSO to afford compound 70. Subsequent reduction of 70 with tributyltin hydride furnished the olefin 71, which after catalytic hydrogenation and deprotection was converted to gentamine C1a. The 2⬘-nitro-2⬘-deaminoneamine 73, together with a 2⬘-nitro derivative of kanamycin B, have been synthesized as the first mechanism-based inactivators for aminoglycoside phosphotransferases [27]. Compound 73 was prepared from an appropriately protected neamine derivative (72) (compounds 72, 73), using trimethylsilyl chloride for protection of 2⬘-amino and hydroxyl groups. Then, selective deprotection of the silyl-protected amino group followed by oxidation of the free amino group with m-chloroperoxybenzoic acid (mCPBA), and deprotection of all protective groups with trifluoroacetic acid gave the title compound 73. Another report describes syntheses of 6⬘-N-substituted amino acid derivatives of neamine with alanine, phenylalanine, and lysine. These neamine analogs were
Syntheses of Aminoglycoside Antibiotics
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Compounds 55–66
prepared by using either an active ester method under controlled conditions, or a mixed anhydride method by blocking of all functional groups of neamine except the 6⬘-amino function, leaving it free for modification [53]. The same group has also reported the synthesis of 5⬘-epi-neamine by conversion of the C5⬘-aminomethyl moiety to the aldehyde function, followed by reductive amination [54]. Roestamadji et al. [24] synthesized a series of deaminated derivatives of neamine and kanamycin A to investigate the effect of electrostatic interactions in binding ability and activity of substrates bound to the active sites of aminoglycoside-modifying enzymes. The four deaminated analogs of neamine (compounds 74–77 ) were prepared by selective protection–deprotection of the amino groups to get tri-protected derivatives (e.g., compound 78). Reductive deamination of the corresponding free amino group via an intermediary formylated derivative (e.g., compound 79) using the Barton procedure, followed by deprotection of the protecting groups, resulted in the title compounds.
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Compounds 67–69
Compounds 70 and 71
Compounds 72 and 73
The neamine-derived aldehyde 81 has been prepared and used in combinatorial synthesis of a library of neomycin B mimetic aminoglycoside antibiotics, a strategy for the discovery of new inhibitors for binding to the Rev-responsive element of HIV mRNA [55]. The synthesis involves allylation of the selectively protected neamine derivative 80, followed by ozonolysis of the allylic double bond to generate the aldehyde functional group (compounds 80, 81). Recently an azo derivative of neamine was used by the same group to prepare a series of ribostamycin and neomycin analogs [34]. The 4⬘,4⬘-difluoroneamine (compound 82) was recently synthesized from an appropriately protected neamine derivative having the 3⬘-hydroxyl group free for
Syntheses of Aminoglycoside Antibiotics
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Compounds 74–79
Compounds 80 and 81
Compound 82
functional group manipulation. The presence of the powerful electron-withdrawing fluorine atoms next to the hydroxyl group at the 3⬘-position prevents phosphorylation of this hydroxyl group by aminoglycoside phosphotransferases, which are the cause of clinical resistance to aminoglycoside antibiotics. This compound can be used as a potential inhibitor for aminoglycoside phosphotransferases [APH(3⬘)s] [56]. In a study to explore the mechanism of phosphorylation of aminoglycoside antibiotics by phosphotransferases and to develop potent inhibitors for these en-
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Compounds 83–86
zymes, the conjoint molecules (compounds 83–86 ) were prepared. These compounds incorporate the structure of neamine to that of adenosine via carbon tethers. These molecules would take advantage of the availability of two distinct binding subunits for ATP and aminoglycosides in the active site of the enzymes. Hence, the conjoint molecules would bind the enzymes more effectively than the individual components for entropic reasons [57]. In another synthesis, neamine was linked by a spacer to a known isoquinoline sulfonamide protein kinase inhibitor to make the conjunct molecule (compound 87). A molecule such as 87 should bind the active site of these enzymes with great affinity [58]. 2.
Paromamine
Yoshikawa et al. [59] described the preparation of paromamine 92 from D-glucosamine. They used Pb(OAc)4 for decarboxylation and sodium borohydride for deacetoxylation in the key steps of the synthesis. The D-glucosamine-derived alcohol 88 was oxidized by the Jones reagent to furnish the corresponding 5-carboxyl analogs, which were decarboxylated with Pb(OAc)4 to give compound 89 as a mixture of ␣ and  isomers. Treatment of 89 with CH3NO2 in the presence of 1% NaOMeMeOH afforded the scyllo-nitrocyclitol glycoside 90. After protection of the hydroxyl groups and acetylation at position 2, this compound was reductively deacetoxylated with NaBH4 in EtOH to furnish 91, which was converted to paromamine 92 by subsequent deprotection, Raney nickel reduction, and catalytic hydrogenation (compounds 88–92 ).
Compound 87
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Compounds 88–92
trans-4-Aminocyclohexanol has been used to prepare the paromamine analog 93 (compounds 93–99 ) and the neamine derivatives 94, 95, and 96. In these syntheses the corresponding 2⬘-amino-␣-glycosides were prepared by the method of Lemieux using the dimeric 2-nitroso ␣-D-hexopyranosyl chlorides 97 and 98 with appropriately protected cyclohexanols to afford 2-oximino ␣-D-hexopyranosides (e.g., 99) [60]. Reductive deprotection in aqueous hydrazine gave the title compounds 93, 94, 95, and 96. However, none of these analogs exhibited minimum inhibitory concentration (MIC) values of less than 200 mg/mL. In another report, paromamine 92 was converted to the pseudodisaccharide 100, which is a constituent of the structure of oxyapramycin 101 (compounds 100, 101). Two-carbon chain elongation was performed by Wittig reaction on a 5⬘-aldehyde derivative followed by osmium tetraoxide hydroxylation, which after lactonization in the basic condition, followed by reduction and deprotection, afforded compound 100 [61]. Paromamine and its 3⬘-deoxy analog (lividamine) have been converted to the corresponding ethenic 6⬘-aldehyde derivatives 102 and 103, respectively. Reductive amination of the aldehydes followed by deprotection yielded the pseudodisaccharides 104, 105, 106, and 107, which showed less in vitro activity than the parent neamine [62] (compounds 102–107 ). 3.
Aspramycin
Abu et al. [63] described syntheses of two apramycin analogs, 6-O-(3-amino-3deoxy-␣-D-glucopyranosyl)- and 5-O-(-D-ribofuranosyl)-apramycin (108 and 109, respectively). To prepare these analogs, glycosylation reactions of a suitably protected derivative of apramycin with corresponding glucosyl or furanosyl chloride
370
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Compounds 93–99
were performed in the presence of mercuric cyanide. Antimicrobial activity results revealed that compound 108 was as active as apramycin against most gram-positive and gram-negative bacteria, and more active than apramycin against strains producing aminoglycoside-modifying enzymes. However, 109 was less active than 108 [63] (compounds 108, 109). Selective acylation of amino groups of apramycin and related aminoglycosides has been achieved in the presence of metal acetates [64], and paromamine has been used to synthesize the 4-O-(aminooctodiosyl)-2-deoxystreptamine (compound 110), a close analog of the pseudodisaccharide present in oxyapramycin [61,65].
Compounds 100 and 101
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Compounds 102–107
Compounds 108 and 109
Compound 110
Total syntheses of apramycin 48 and saccharosin 49 from neamine 11 have been described [46,66]. The two apramycin analogs 111 [67] and 112 [68] were prepared from an appropriately protected 2-deoxystreptamine derivative; BF3-catalyzed addition of alcohol (e.g., alcohol 113 to glycals 114 and 115) was used for construction of the second and third rings. The 2-deoxystreptamine derivative 113
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Compounds 111–116
was prepared from a suitably protected neamine analog by sequential periodate oxidation and base-catalyzed -elimination. Coupling of 113 with 115 in the presence of BF3 followed by catalytic hydrogenation afforded the precursor 116, which was employed for glycosylation with 115 to make the apramycin analog 111 (compounds 111–116 ). A series of N-acyl derivatives of apramycin, including ␥-amino-␣-hydroxybutyryl (AHB) and glycyl analogs have been prepared by Allen et al. [29], who used different transition metal ions, including Ni2⫹, Cu2⫹, and Zn2⫹, for regioselective acylation of the amino groups. These investigators demonstrated that acylation of the amino group of apramycin at position 2⬘ yields analogs with enhanced uptake, which can effectively penetrate the cell wall and kill bacteria. B.
5-Substituted 2-Deoxystreptamine-Containing Aminoglycoside: Destomycin and Related Compounds
Yoshimura and colleagues [69,70] effected a total synthesis of destomycin C 117. These workers used the pseudodisaccharide 118, which resulted from mannose and deoxystreptamine, for coupling with the destomic acid 119 (6-amino-6-deoxy-L-glycero-D-galacto-heptonic acid) to construct the orthoester linkage present at position 1⬙ of the molecule. Inversion of the configuration at the 4⬘-position was performed by sequential oxidation–reduction of the 4⬘-hydroxyl group in the desilylated derivative in two steps, which after removal of the protecting groups led to the formation of the antibiotic (compounds 117–119 ). C.
4,5-Disubstituted 2-Deoxystreptamine-Containing Aminoglycosides: Neomycins, Paromomycins, Lividomycins, and Related Compounds
1.
Neomycin B
A total synthesis of neomycin B (34) from condensation of neobiosamine and neamine derivatives has been described [71].
Syntheses of Aminoglycoside Antibiotics
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Compounds 117–119
Diazotization by sodium nitrite in a dilute solution of sulfuric acid has been used to convert amino groups of neomycin B at the 6⬘- and 6-positions to a hydroxyl group to make paromomycin I (120), the 6-deamino-6-hydroxyparomomycin I (121), and the 6-deamino-6-hydroxyneomycin B (122). These compounds were found to be less active than the parent antibiotic, particularly the tetra-amino derivative 121, which was the least active compound, showing about one-tenth the activity of penta-amino derivative 120 or 122 (compounds 120–122 ). These results indicated
Compounds 120–122
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Haddad et al.
that deletion of the amino group at position 6 reduces the intrinsic activity to a greater extent than the deamination at the 6⬘-position [72]. The 5⬙-hydroxy group of neomycin B was converted to an amino group by treatment of the 5⬙-tosylated derivative with sodium azide, followed by reduction of the azide to the amino group by triphenylphosphine in the presence of an aqueous solution of sodium hydroxide. The resulting 5⬙-amino neomycin B was shown to be a better RNA binder, slowing down the ribozyme cleavage more effectively than the parent compound [73]. A number of neomycin B derivatives have recently been synthesized to probe the role of ring IV (2,6-dideoxy-2,6-diamino--L-idopyranose) of neomycin B in the binding ability of the antibiotic to the ribosomal RNA. To address this role, analogs were synthesized in which the idose ring was replaced with a flexible mono- or diamino tail (123 and 124), or idose derivatives with no amino groups (125) or one amino group (126) were synthesized. The RNA binding data profile of these compounds showed that the idose ring by itself (without amino groups) does not contribute to the affinity or specificity of binding, indicating that the positively charged amino groups presented on the idose ring are necessary for specific binding. Likewise, these amino groups cannot be replaced by those that have flexible linkers [34]. To synthesize 123 and 124, reductive amination of the neamine-derived aldehyde 127 with the corresponding linear amines was employed, and the glycosylation method was used to prepare analogs 125 and 126 from coupling of the glycosyl acceptor 128 with corresponding idose derivative as glycosyl donors (compounds 123–128 ). 2.
Paromomycin
4⬘-Deoxy analogs of paromomycin (120) and paromamine (92) [74], as well as derivatives of paromomycin modified at the 4⬘-, 5⬙-, and 4-positions [75], have been
Compounds 123–128
Syntheses of Aminoglycoside Antibiotics
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made to examine their antibiotic activities against several sensitive and resistant strains. These include the 4⬘-deoxy-4⬘-epichloro 129, 4⬘-deoxy 130, 4⬘,4⬙-dideoxy 131, 5⬙-amino-4⬘,5⬙-dideoxy-4⬘-epichloro 132, and 5⬙-amino-4⬘,5⬙-dideoxyparomomycin 133, some of which showed good antibacterial activity against Staphylococcus-resistant strains (compounds 129–133 ). Among these semisynthetic paromomycins, compounds 131 and 132 showed activity comparable to the parent antibiotic, but together with analog 129 they were more active against 4⬘-adenyltransferase-producing organisms. Replacement of the 5⬙-hydroxyl with an amino group, to generate the derivatives 132 and 133, resulted in loss of activity. In another communication the same group described the preparation of a series of paromomycin analogs modified at the 3⬘-, 4⬘-, 1-, 6-, and 5⬙-positions. All the new antibiotics (3⬘,4⬘-deoxy 134, 5⬙-amino-3⬘,4⬘,5⬘-trideoxy 135, 3⬘-deoxy-4⬘-epi 136, 5⬙-amino-3⬘,5⬙-dideoxy-4⬘-epi 137, 1-deamino-6,3⬘,4⬘-trideoxy,-1,6--epi 138, and 4⬘-amino-4⬘-deoxyparomomycin 139) (compounds 134–139 ) showed more potency than paromomycin against organisms that produced 3⬘-phosphotransferase and 4⬘-adenyltransferase, and they were more effective than the parent compound in inhibition of the protein synthesis [76]. 3.
Lividomycin B
2-Hydroxy-2-deoxylividomycin B (143) and its 2⬙-regioisomer 144 have been synthesized by condensation of the protected idopyranosyl halide 140 with the pseudotrisaccharide derivative 141 [77]. The antibiotic activities of these compounds were in the order of lividomycin B 142 > 143 > 144, indicating the importance of 2amino group in antibacterial activity. Consequently, to address the effect of the aminoacyl substituent at the 1-amino group in antibacterial activity of compounds 145 and 146, two 1-N-[(S)-4-amino-2-hydroxybutanoyl] derivatives of 143 and 144 were prepared. The acylamide analog of 143 (compound 145) showed enhanced activity
Compounds 129–133
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Haddad et al.
Compounds 134–139
compared to 143, whereas the acylamido derivative of the 2⬙-regioisomer (146) showed marked diminution in activity [78] (compounds 140–146 ). The same group also synthesized 5⬙-deoxy-5⬙-fluorolividomycin B, using diethylaminosulfur trifluoride (DAST) as the fluorinating agent. The antibacterial activity of this fluorinated compound was reported to be less than that of the parent antibiotic [79]. 4.
Ribostamycin
The 2⬘,3⬘-epimino derivative of ribostamycin (149) was prepared from the corresponding 3⬘-tosyl derivative 148, using sodium hydride for the cyclization step. However, no intrinsic antimicrobial activity was observed for this epimino analog [80] (compounds 147–149 ). A glycosylation approach was used to prepare ribostamycin 147 and its 4⬙-thio analog from neamine and appropriately protected glycosyl donors ribofuranosyl or 4-thioribofuranosyl derivatives [81]. In another synthesis, D-glucosamine and ribose were used to prepare ribostamycin via an aminotrisaccharide intermediate [82]. A number of ribostamycin analogs (150–158 ) have been synthesized by glycosylation of various ribofuranosyl derivatives with the three protected sisamine analogs 159, 160, and 161 (compounds 150–161 ). These ribostamycin analogs showed only modest antibacterial activity, compared to ribostamycin [83]. 5.
Butirosins
A series of deoxy derivatives of butirosin A (162), including the 3⬘-deoxybutirosin A (163), 5⬙-amino-3⬘,5⬙-dideoxybutirosin (164), and 5⬙-amino-4⬘,5⬙-dideoxybutirosin A (165) were prepared by Woo et al. [84] via sequential deoxygenation of the corresponding trifluoromethylsulfonyl derivatives by nucleophilic substitution with sodium salt of thiophenol followed by reduction with sodium in liquid ammonia and
Syntheses of Aminoglycoside Antibiotics
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Compounds 140–146
catalytic hydrogenation. These deoxy analogs showed improved activities over butirosin and gentamicin against certain phosphotransferase-producing organisms, particularly Pseudomonas aeruginosa and Staphylococcus aureus. A number of 5⬙-amidino and 5⬙-guanidino analogs of butirosin A and its 4⬘deoxy derivative (compounds 165–168 ) were also prepared by another research group. Among these analogs, 166 showed the best activity against most strains tested, but it was similarly more toxic than the 5⬙-hydroxyl derivatives (e.g., butirosin A, 162 and 163) [85] (compounds 162–168 ). D.
4,6-Disubstituted 2-Deoxystreptamine-Containing Aminoglycosides: Kanamycins, Gentamicins, and Related Compounds
1.
Kanamycins
(a) Deoxykanamycins. Kanamycin A (4) has been used to prepare 2⬘-deoxykanamycin A (178), and 2⬘-epi-kanamycin A and B (179 and 180, respectively) by selective 2⬘-de-O-benzoylation and then 2⬘-triflylation [86]. In this synthesis, the hexa-O-benzoyl-protected derivative 169 was selectively deprotected at the 2⬘-position with hydrazine hydrate in pyridine to afford compound 170, which was treated with trifluoromethanesulfonic anhydride in pyridine to furnish the triflyl derivative 171. This compound was separately treated with benzenethioxide, sodium benzoate,
378
Haddad et al.
Compounds 147–149
and sodium azide to prepare compounds 172, 173, and 174, respectively. Treatments of 172 with NaOMe in MeOH and then Raney nickel, 173 with NaOMe in MeOH, and 174 with NaOMe in MeOH, then Pd-C and hydrogen, afforded the kanamycin analogs 175, 176, and 177, respectively, which were subjected to Ba(OH)2 to furnish the title compounds 178–180 (compounds 169–180 ). 3⬘-Deoxykanamycin A, an antibiotic resistant to 3⬘-phosphotransferase-modifying enzymes [(APH)3⬘-Ia’s], has been prepared via two different routes. One route used Barton’s deoxygenation protocol [87], and in another a mixture of 2⬘,3⬘- and 3⬘,4⬘-epoxy intermediates of kanamycin A derivatives resulted in the formation of a single product (3⬘-deoxy derivative) upon reduction with Raney nickel or sodium borohydride [88]. In another synthesis, Iwasawa and colleagues [89] used 3⬘-deoxyamikacin (181), which has shown better antibiotic activity than amikacin (2), to prepare a number of amikacin analogs including 5,3⬘-dideoxy- (182), 5,3⬘,6⬙-trideoxy- (183), and 3⬘,6⬙-dideoxyamikacin (184). The 5-deoxyamikacin 185 was also synthesized from amikacin (2). Among these analogs, 3⬘,6⬙-dideoxyamikacin (184) showed the strongest antibacterial activity compared to amikacin and the other deoxy derivatives (compounds 181–185 ). Syntheses of 2⬘,3⬘-dideoxykanamycin A, 2⬘,3⬘-dideoxyamikacin, and their related derivatives have been described [22]. 2⬘,3⬘-Dideoxykanamycin A was prepared by two different methods. In one, a 2⬘,3⬘-unsaturated intermediate was obtained by a modified version of the Tipson and Cohen method, which proceeds via triflylation
Syntheses of Aminoglycoside Antibiotics
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Compounds 150–161
of the vicinal hydroxyl groups at the 2⬘- and 3⬘-positions, followed by treatment of the product with sodium iodide in DMF in the absence of zinc dust. In the other method, a 2⬘,3⬘-epoxy derivative was employed and converted to a 2⬘,3⬘-iodohydrin derivative via hydrogen iodide assisted ring opening of the epoxide, which then was mesylated at the 2⬘-position to furnish the 2⬘,3⬘-unsaturated intermediate. The 2⬘,3⬘deoxyamikacin showed slightly enhanced antibacterial activity compared to amikacin. A number of kanamycin analogs, including 3⬘-deoxy-2⬘-epi-kanamycin A [90], 5-deoxy-, 5,4⬘-dideoxy-, 5-deoxy-5-epi-chloro-, and 5,4⬘-dideoxy-5,4⬘-di-epi-chlorokanamycin A [91], as well as 3⬘-deoxykanamycin B (tobramycin) [92], were prepared and tested against several sensitive and resistant organisms. Antibacterial activity data profile revealed that deoxygenation of kanamycin at the 5-position results in the loss of activity and that the 4⬘-epichlorination of kanamycin A results in lack of activity. 5,6⬙-Deoxykanamycin B has also been prepared by reduction of the corresponding dichloro derivative with tributylstannane, showing improved activity against Staphylococcus epidermidis ATCC 12228 and Klebsiella pneumoniae 602. It was slightly more active than kanamycin B against strains of S. aureus Apo-1, K. pneu-
380
Compounds 162–168
Compounds 169–180
Haddad et al.
Syntheses of Aminoglycoside Antibiotics
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Compounds 181–185
moniae, and E. coli, but showed a marked decrease in activity against P. aeruginosa [93]. Two other analogs of kanamycin A including 3⬘,4⬘-dideoxy and 4⬘-deoxy derivatives were synthesized by Yoneta and colleagues [94]. These compounds were synthesized from the 3⬘,4⬘-epoxy intermediate 186, which was derived from treatment of its 4⬘-O-mesylated precursor with sodium methoxide in methanol. Treatment of 186 with sodium iodide in the presence of sodium acetate and acetic acid afforded the iodohydin 187, which after tosylation at 3⬘-position was converted to the 3⬘-ene derivative 188 under thermal conditions. Removal of the protecting groups of the olefin 188, followed by catalytic hydrogenation, gave the 3⬘,4⬘-dideoxykanamycin A. Similarly catalytic hydrogenation of the iodohydrin 187 followed by treatment with methanolic sodium methoxide and trifluoroacetic acid afforded the 4⬘-deoxykanamycin A analog (compounds 186–188 ). An attempt to make 3⬘,4⬘-dideoxy analogs of kanamycin A and B by mutational biosynthesis in the presence of gentamicin-producing Micromonospora organisms
Compounds 186–188
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yielded combimicins (189), a mixture of aminoglycosides. These compounds are 3⬘,4⬘-dideoxy derivatives of 4⬙-C-methyl and 3⬙-N-methyl kanamycins and are structurally related to gentamicin C1a (190) (compounds 189–190 ). Combimicins have strong antibacterial activity against gram-negative and gram-positive bacteria, and combimicin B2 (R1 = NH2, R2 = H) has shown less ototoxicity than the gentamicin complex [95]. 3⬘,4⬘-Dideoxykanamycin B (dibekacin) 194 was synthesized by Matsuno and coworkers [96] and exhibited good antibacterial activity against both sensitive and resistant bacteria, including P. aeruginosa. The 4⬙,6⬙-O-cyclohexylidene kanamycin B derivative 191 was employed in this synthesis. Treatment of this compound with benzylsulfonyl chloride in pyridine afforded the derivative 192, which was subjected to sodium iodide in DMF to furnish the 3⬘,4⬘-unsaturated derivative 193. Cyclohexylidene deprotection with aqueous acetic acid (80%) followed by reductive desulfonylation of benzylsulfonyl groups under the Birch condition and catalytic hydrogenation of the double bond gave the 3⬘,4⬘-dideoxykanamycin B (194) in high yield. A multistep synthesis of 194 also was reported by Yoshikawa et al. [97], who used D-glucosamine to construct rings I and II, as well as D-glucose to assemble the idose moiety (ring III) of the antibiotic (compounds 191–194 ). Amino groups play an important role in antibacterial activity of aminoglycoside antibiotics. To probe this role, 3⬘,4⬘-dideoxykanamycin B (dibekacin: 194) was used to prepare hexa- and heptadeoxy derivatives (5,2⬘,3⬘,4⬘,4⬙,6⬙ and 5,2⬘,3⬘,4⬘,2⬙,4⬙,6⬙) of kanamycin A (4) and amikacin (2). The antibacterial activity data profile of these antibiotics revealed that the amino groups are essential for antibacterial activity, and that the 2⬙-hydroxy group and 1-N-(S)-4-amino-2-hydroxybutanoyl (AHB) moiety markedly increase the activity of the antibiotic [98]. 3⬘,4⬘,2⬙-Trideoxy- and 2⬙-deoxykanamycin B have also been synthesized, the former being more active than kanamycin B against resistant strains of P. aeruginosa [99]. Another report, by Albert and colleagues [100], describes the synthesis of 4⬙deoxykanamycin A together with 4⬙-epi-chloro-, 4⬙-epi-bromo-, and 4⬙-epi-iodokanamycin A. (b) epi-Kanamycins. The 4⬘-deoxy-5⬘-epi derivative of kanamycin B (197) was made from its 1,4-epoxy intermediate 195 using the sequences of reactions outlined
Compounds 189 and 190
Syntheses of Aminoglycoside Antibiotics
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Compounds 191–194
below to get the unsaturated derivative 196 (compounds 195–197 ). Reduction of the double bond followed by deprotection afforded the product. However, the resulting compound showed weak antibacterial activity [101]. 1-epi-Kanamycin A together with 1- and 3-epi-tobramycin have been synthesized by either catalytic hydrogenation over Raney nickel or electrochemical reduction of their corresponding 1- or 3-hydroxyimino derivatives. 1-epi-Kanamycin A showed lower activity than kanamycin A against most bacteria tested, but it was more active against P. aeruginosa. 1-epi-Tobramycin was slightly less active than the parent antibiotic, whereas the 3-epi derivative showed marked decrease in activity against most sensitive and resistant bacteria [102]. 1-epi-Kanamycin A (200) and its 1-N-acylamino derivative 201 were prepared by Takahashi et al. [103] to investigate the effect of C1 epimerization on antibiotic activity of kanamycin A. In this synthesis, oxidation of the kanamycin derivative 198 with hydrogen peroxide in the presence of sodium tungstate afforded the 1hydroxyimino derivative 199, which after deprotection and reduction with hydrogen– Raney nickel in aqueous ammonia furnished 1-epi-kanamycin A (200). This compound was converted to the 1-N-[(S)-4-amino-2-hydroxybutyryl] analog by regiospecific acylation in the presence of zinc acetate. Antibacterial activity results revealed that epimerization of the amino group at position 1 greatly reduces the original activity of the antibiotic (compounds 198–201 ). Several other kanamycin A analogs, including 4⬙-epi-kanamycin A together with 4⬙,5⬙-unsaturated, and 3⬙,4⬙-cyclic urethane by products [104], 4⬙-deoxy-4⬙,5⬙didehydro, and 4⬙-deoxy-5⬙-epi-kanamycin A [105], as well as a number of 4⬙-epianalogs (OH, F, N3) of amikacin [106] have also been prepared, all of which are much less active than the parent antibiotics.
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Compounds 195–197
(c) Halokanamycins. In an attempt to make more active antibiotics, Umemura and colleagues [107] synthesized halogenated derivatives of amikacin, including 6⬙chloro-6⬙-deoxyamikacin (compound 202), 6⬙-iodo-6⬙-deoxyamikacin (compound 203), and some other analogs, including compounds 204 and 205. Among these, the 6⬙-chloro-3⬘,6⬙-dideoxyamikacin showed the best activity, and the study concluded that substitution of the 6⬙-hydroxyl group of amikacin with chlorine enhances the antibacterial activity of the antibiotic against all bacteria except P. aeruginosa. On the other hand, it has been demonstrated that introduction of fluorine at the 6⬙position of amikacin lowers the activity to some extent [106]. Several other derivatives including 5-fluoro-, 6⬙-fluoro-, and 5,6⬙-difluorokanamycin A were prepared by Albert and coworkers [108]. In another synthesis by these investigators, 4⬙-bromo-, 4⬙-fluoro-, and 4⬙-aminokanamycin A were prepared by double inversion substitution reaction using the 4⬙-O-triflate 206 as the key syn-
Compounds 198–201
Syntheses of Aminoglycoside Antibiotics
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Compounds 202–205
thetic intermediate. This intermediate was first treated with sodium nitrite in DMF to give the corresponding 4⬙-epi-hydroxy derivative 207, which was subjected to triflic anhydride to furnish the 4⬙-epi-O-triflate 208. This compound was then converted to the corresponding bromo, fluoro, and azido derivatives 209–211 (compounds 206–211 ) by another nucleophilic displacement, using tetrabutylammonium bromide and fluoride in acetonitrile or sodium azide in DMF. Antibacterial activity screening showed no dramatic changes in activity for these compounds compare to those of kanamycin A [109]. The same group has also synthesized a number of 4⬙-epi-kanamycin A analogs, including 4⬙,6⬙-dideoxy-4⬙,6⬙-difluoro-, 4⬙,6⬙-dideoxy-4⬙-fluoro-, 6⬙-deoxy-6⬙-fluoro-,
Compounds 206–211
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and 6⬙-deoxy-4⬙-epi-kanamycin A, using a 4⬙,6⬙-ditriflyl derivative as the key intermediate. These compounds showed comparable or better activity for some strains tested [110]. 3⬘-Deoxy-3⬘-fluorokanamycins A and B have been synthesized and showed strong activities against both sensitive and resistant bacteria [111]. The 3⬘-deoxy-3⬘fluorokanamycin A (214), was prepared by condensation of the 3-fluoro-␣-glucopyranosyl derivative 212 with the appropriately protected compound 213 in the presence of mercury(II) cyanide followed by deprotection and hydrogenolysis (compounds 212–214 ). The same group also has described the syntheses of 6⬙-deoxy-6⬙-fluorokanamycin A, 6⬙-deoxy-6⬙-fluoroamikacin, and 1-N-[(R)- and (RS)-3-amino-2-fluoropropanoyl] kanamycin A, using the DAST reagent for fluorination of the corresponding hydroxyl groups of kanamycin A and amikacin derivatives [112]. The 2⬘,3⬘-dideoxy-2⬘-fluorokanamycin A 217 and its 1⬘-epimer have been prepared by coupling reaction of the fluoro sugar 215 and the pseudodisaccharide 216. The resulting analog 217 was only slightly less active than 3⬘-deoxykanamycin A, whereas the 1⬘-epimer was completely inactive [113] (compounds 215–217 ). A series of halogenated analogs of kanamycins, including 3⬘,4⬘,6⬘-trideoxy-6⬘fluorokanamycin C (218), 3⬘,4⬘-dideoxy-6⬘-C-fluoromethyl kanamycin B [114], 6⬙chloro-6⬙-deoxyamikacin (202) and some of its derivatives [115], as well as 3⬘deoxy-3⬘-fluorokanamycin A (219) and its 3⬘,4⬘-dideoxy-3⬘-fluoro analog 220 [45] were also prepared by the same research group. Antibacterial activity results showed weak activity for 6⬘-fluoro, moderate activity for 6⬘-fluoromethyl, and good activity (better than the parent antibiotics) for 3⬘-fluoro derivatives. Several other halogenated derivatives of kanamycins were synthesized by the Umezawa group. These include 3⬘-deoxy-3⬘-fluoro (219) and 3⬘-chloro-3⬘-deoxykanamycin A (221) [116], 4⬘-deoxy-4⬘-fluorokanamycin A and B (222 and 223, respectively) [117], 5-deoxy-5-fluoro-(224), 5,3⬘-dideoxy-5-fluoro-(225), 5,3⬘,4⬘-trideoxy5-fluoro-(226), and 5,5-difluoro-(227) derivatives of kanamycin B [118]. The antibacterial activity of the 3⬘-chloro analog 221 was one-sixth that of the 3⬘-fluoro derivative 219. Also the 4⬘-fluoro derivatives 222 and 223 were inactive against resistant bacteria producing phosphotransferase enzymes [APH(3⬘)s], slightly less active than the parent compounds against common bacteria, but very active against the kind that produce [AAD(4⬘)]. The 5-fluoro and 5,5-difluoro derivatives (com-
Compounds 212–214
Syntheses of Aminoglycoside Antibiotics
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Compounds 215–217
pounds 224–227 ) showed comparable or better activities and were markedly less toxic than the parent compounds (compounds 218–229 ). 3⬘-Deoxy-3⬘-fluoro (228) and 3⬘,4⬘-dideoxy-3⬘-fluorokanamycin B (229) [119], 5-deoxy-5-fluoro (230), and 5-deoxy-5,5-difluoro (231) derivatives of netilmicin (1) [120], as well as fluoroarbekacins (234–238 ) [121], were prepared by Umezawa’s group. Both fluorinated derivatives of kanamycin B were active against resistant bacteria producing 3⬘-phosphotransferase enzymes [119]. In the synthesis of fluorinated netilmicins (230 and 231), two other analogs, 5-epi-netilmicin (232) and 5epi-6⬘-N-methylnetilmicin (233) were also prepared. Compounds 230 and 232 showed activity similar to that of netilmicin, 231 was slightly less active than netilmicin, but 233 showed markedly reduced activity. In terms of toxicity, the 5-fluoro derivative 230 showed half to one-third the acute toxicity of netilmicin [120]. The fluorinated arbekacins (234–238 ) exhibited activity similar to that of arbekacin and were remarkably less toxic than the parent compound (compounds 230–238 ). These observations were suggestive of the fact that the presence of fluorine at the 5-position decreases the basicity of the 3-amino group and lowers the toxicity of the antibiotic [121]. A few other fluorinated kanamycins, including 5-deoxy-5-epi-fluoroamikacin, 5-deoxy-5-epi-fluoroarbekacin, and their related analogs, have been prepared to study the fluorination–toxicity relationship. In contrast to the low toxicities of the 5-fluoro derivatives [121], these epi-fluoro compounds showed acute toxicity values identical to those of arbekacin and amikacin [122]. This indicates the importance of stereoelectronic effects of the fluoro group at position 5 of the 2-deoxystreptomine moiety in toxicity of aminoglycoside antibiotics. The 3⬘-oxokanamycin A (239) has been recently synthesized. Compound 239, which adopts a hydrate chair conformation in aqueous solution, was shown to be an aminoglycoside antibiotic that can undergo a self and continuous phosphorylation– dephosphorylation process to generate the active antibiotic [123].
388
Compounds 218–229
Compounds 230–238
Haddad et al.
Syntheses of Aminoglycoside Antibiotics
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Compound 239
(d) N-Acylkanamycins. Umezawa and coworkers [124] further modified several analogs of 5,3⬘,4⬘-trideoxykanamycin B (240), including chloro, deoxy, and N-methyl compounds (241–245 ), to 1-N-[(S)-4-amino-2-hydroxybutyryl] derivatives (246– 251) (compounds 240–251 ). Antibacterial activity results were the best activity for compound 250 and were improved for 6⬙-chlorinated compounds against gram-positive bacteria, with a concomitant increase in toxicity, compared to the related 6⬙hydroxy derivatives, and marked increase in the activity by 1-N-acylation [124]. The same group has also reported the synthesis of 1-N-(2-aminoethoxycarbonyl) and 1-N-(3-aminopropoxycarbonyl) kanamycin A, the latter being less active than amikacin (2). However, the former showed activity similar to that of amikacin, implying that the (S)-4-aminohydroxybutyryl residue of amikacin can be replaced
Compounds 240–251
390
Haddad et al.
by a simple residue such as aminoethoxycarbonyl and retain its activity [125]. Reactions reported include enzymatic O-phosphorylation of kanamycin A and N-acetylation of tobramycin [126], regiospecific synthesis of 1-N-[(S)-4-amino-2-hydroxybutyryl]-2⬙-deoxykanamycin B from neamine [127], and preparation of 1-N-(2-aminoethanesulfonyl) derivatives of kanamycin A and B, ribostamycin, and dibekacin [128]. In contrast to earlier observations for 2⬙-deoxyaminoglycosides, the 1-N-acylamido-2⬙-deoxy derivative of kanamycin B showed loss of activity relative to amikacin [127]. All the aminoethanesulfonyl derivatives showed strong activity against both gram-positive and gram-negative bacteria, suggesting that the (S)-4amino-2-hydroxybutanoyl group can be replaced by a simple group such as aminoethanesulfonyl moiety and still be an effective antibiotic [128]. In another report, kanamycin A was biologically converted to amikacin by a mutant strain of the butirosin-producing organism Bacillus circulans [129]. 6⬘-N-Formimidoylamikacin (253), 6⬘-N-acetimidoylamikacin (254), and 6⬘-Nformimidoyldibekacin (256) have been synthesized from the appropriately protected amikacin and dibekacin derivatives 252 and 255, respectively (compounds 252–256 ). Compared to the parent antibiotics, all these compounds showed improved activity against resistant strains producing AAC(6⬘) enzyme; but in general, the 6⬘-N-amidination slightly decreased the antibacterial activity of kanamycins [21]. Another report described the synthesis of N-guanyl derivatives (at positions 6⬘, 2⬘, 3⬘) of kanamycin A and gentamicins C1, C1a, and C2 [130]. Likewise, a series of 3⬙-N-trifluoroacetyl derivatives of kanamycin A, possessing C5–C22 acyl groups, or related alkoxy, amino, and thiocarbonyl substituents at the C1 amino group have been synthesized and tested for their activity against herpes simplex virus type I (HSV-I) and influenza virus. The optimum antiviral activity was found for the C14– C16 acyl derivatives [131,132]. The same group also has prepared N-palmitoylkanamycin A derivatives modified at the 1-, 3-, 6⬘-, or 3⬙-amino groups having a 3⬙-
Compounds 252–256
Syntheses of Aminoglycoside Antibiotics
391
amino group free or acylated with trifluoroacetyl group. The antiviral activities of these compounds were excellent and almost similar to each other, but those with trifluoroacetyl group at the 3⬙-amino group exhibited reduced cytotoxicity on Vero cell [133]. Likewise, N-palmitoyl derivatives of kanamycin B, tobramycin (3⬘-deoxykanamycin B), dibekacin (3⬘,4⬘-dideoxykanamycin B), and gentamicin (C1, C1a, and C2 complex), and a few other aminoglycosides were prepared, all of which showed excellent antiviral activity [134]. Aminoglycoside antibiotics (257), including kanamycin A, tobramycin, and gentamicin C complex, have been acylated with 1 mole of disodium carbenicillin (258) to give monoacylated derivatives (e.g., 259) (compounds 257–259 ). The resulting compounds were devoid of antibacterial activity against several strains tested, however, and showed no toxicity [135]. The 1-N-(D-threo- and racemic erythro-3-amino-2-hydroxylbutanoyl)-2⬘,3⬘-dideoxykanamycins A have been synthesized by using a standard esterification procedure to acylate the amino group of kanamycin A at position 1 with the corresponding 3-azido-2-hydroxybutanoic acid. The antibacterial activities of these compounds were less than that of amikacin having a 4-amino-2-hydroxybutanoyl moiety at the 1-amino group [136]. In a study on the fluorination–toxicity relationship, investigators prepared 1N-acylamido derivatives of kanamycins, including (2R,3R)- and (2R,3S)-4-amino-3fluoro-2-hydroxybutanoylkanamycins A and B (compounds 262–265 ). The 1-N[(2R,3R)-4-amino-3-fluoro-2-hydroxybutanoyl] derivatives 262–264 showed activity similar to that of the related compounds [amikacin (2), arbekacin (260), and 1-N[(S)-4-amino-2-hydroxybutanoyl]-3⬘-deoxykanamycin B 261], whereas the (2R,3S)derivative 265 (compounds 260–265 ) showed decreased activity relative to 260. In toxicity, these compounds were similar to the parent antibiotics, and fluorination did not show any influence in the toxicity of the antibiotics [137]. 6⬘-N-Benzamido derivatives of kanamycin A and tobramycin having a chromium complex in the benzene ring were prepared for use as metallotracers in immunoassay studies. To make these compounds, N-hydroxysuccinimide-activated esters of these organochromiums were treated with kanamycin A or tobramycin to selectively produce the 6⬘-N-acylated derivative [138]. Different amino acid and peptide derivaties were used to synthesize a series of aminoacyl and dipeptidyl derivatives of kanamycin A and netilmicin modified at the 1-, and 6⬘-amino groups by selective acylation of the copper complexes of these antibiotics. However, none of these modified compounds were active against either gram-positive or gram-negative bacteria [139]. Recently, in a report from Abbott
Compounds 257–259
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Compounds 260–265
Laboratories, impurities of bulk amikacin were identified as 1,6⬘- and 1,3⬙-di-N-[(S)4-amino-2-hydroxybutyryl] kanamycin A [140]. In an attempt to probe structure–toxicity relationships of aminoglycoside antibiotics via fluorination, the fluoroacyl derivatives 1-N-[(2S,4S)- and (2S,4R)-5amino-4-fluoro-2-hydroxypentanoyl]dibekacin (266 and 267, respectively) were synthesized. These fluorinated analogs showed antibacterial activity almost similar to that of amikacin, but they were less toxic. Toxicities of these compounds were compared with those of arbekacin analogs 268–270 , and the investigators concluded that the observed decrease in toxicity is a function of the chain length rather than of the introduction of fluorine [31]. The fluorinated derivatives 266 and 267 showed toxicities analogous to 269, but lower than arbekacin 260 (compounds 266–270 ). The 3⬙-N-acetylation of arbekacin 260 and amikacin 2, the first example of 3⬙N-acetylation of aminoglycoside antibiotics by enzymatic modification, was reported in 1988. Subjection of kanamycin group antibiotics to an aminoglycoside 3-N-ace-
Compounds 266–270
Syntheses of Aminoglycoside Antibiotics
393
tyltransferase, AAC(3)-X, resulted in formation of 3⬙-N-acetyl derivatives of arbekacin and amikacin, but 3-N-acetyldibekacin was formed in the case of dibekacin 194, which lacks the (S)-4-amino-2-hydroxybutyryl moiety in its structure, showing the importance of this side chain in the enzymatic modification of kanamycins. Interestingly, 3⬙-N-acetylarbekacin showed antibacterial activity as high as that of 2⬘-Nacetylarbekacin, whereas the 3⬙-N-acetylamikacin exhibited no substantial activity. These results illuminate a novel aspect of arbekacin chemistry, distinct from the other aminoglycoside antibiotics [141]. (e) N-Hydroxy and C-Hydroxymethylkanamycins. Tsuchiya et al. prepared [142] 6⬘-N-hydroxykanamycin A and 6⬘-N-hydroxydibekacin by reduction of the corresponding 6⬘-aldoximes with sodium cyanoborohydride. However, these compounds showed very weak antibacterial activity. In other reports and in extensive work by van Schepdael et al. [143,144] the 6⬙-triisopropylbenzenesulfonyl ester derivative of kanamycin B (compound 271) was used to prepare a series of 6⬙-substituted kanamycin B analogs. In these compounds, the 6⬙-hydroxyl group was replaced with Cl, N3, NH2, NHMe, NMe2, alkylamido, thioalkyl, alkoxy, and a few other substituents [143]. Likewise, a number of analogs having the 1-position modified by the hydroxymethyl group axial to the 1-amino group were prepared [144]. These include the 6⬙chloro, 6⬙-amino, and 6⬙-acetamido derivatives 280, 281, and 282, respectively. To introduce the hydoxymethyl function at position 1, the Cbz-protected derivative 272 was deprotected by hydrogenolysis, and the resultant free amino group was oxidized to a nitro group with m-chloroperbenzoic acid to afford compound 273. This intermediate was subjected to paraformaldehyde in the presence of triethylamine to furnish the hydroxymethyl analog 274, which after hydrogenolysis in the presence of Raney nickel was converted to the amino derivative 275. Amino group protection followed by nucleophilic displacement at the 6⬙-position with lithium chloride or azide in anhydrous DMF afforded the chloro and azido derivative 276 and 277, respectively. Reduction of the azide function with triphenylphosphine in anhydrous pyridine followed by treatment with aqueous ammonia gave the amino derivative 278, which after acetylation with acetic anhydride afforded the acetamido analog 279. Removal of the protecting groups in 276, 277, and 279 with trifluoroacetic acid resulted in the formation of the title compounds 280, 281, and 282 (compounds 271– 282). However, these new antibiotics showed activity comparable to that of kanamycin B and were only slightly less toxic than the parent compound [145]. ( f ) Amino Kanamycins. 2⬙-Amino-2⬙-deoxyarbekacin (283), together with five related analogs (284–288 ) were synthesized by reductive amination from their corresponding 2⬙-oxo derivatives. For example, oxidation of the 2⬙-hydroxyl group of 289 by the Pfitzner–Moffatt procedure, followed by reductive amination, gave exclusively an equatorial 2⬙-amino group, which after protection with the Boc group afforded compound 290. Treatment of the Cbz-deprotected derivative 291 with N-hydroxysuccinimide ester of (S)-2-hydroxy-4-(p-methoxybenzyloxycarbonylamino)butyric acid in THF mainly gave the 1-N-acylated derivative, which after deprotection furnished the title compound 283 (compounds 283–291 ). All the new antibiotics showed good antibacterial activities against staphylococci and gram-negative bacteria with improved anti-MRSA activity. Among these analogs, compounds 283 and 286 exhibited excellent anti-MRSA activity and were less toxic than the parent antibiotic [30,146].
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Compounds 271–282
A series of 2⬙-amino-2⬙-deoxy and 2⬙-acylamido-2⬙-deoxy derivatives of 5deoxy-5-epi-fluorodibekacin (compounds 292–298 ) were also prepared via an oxidation–methoxyimination–reduction sequence to introduce the 2⬙-NH2 group. All the new compounds except 292 showed only limited or no antibacterial activity, and the epi-amino derivative 293 exhibited much lower activity than 292 [147] (compounds 292–298 ). In another synthesis, Wang et al. [73] prepared 6⬙-amino-6⬙-deoxykanamycin A, together with 6⬙-amino-6⬙-deoxytobramycin and 5⬙-amino-5⬙-deoxyneomycin B, by nucleophilic displacement of an azido group with a tosyl group in the O-tosylated derivatives. These amino-aminoglycosides were tested for their binding ability to RNA and showed improved binding ability, being much stronger RNA binders than their corresponding parent counterparts. (g) Deamino Kanamycins. A series of neamine and kanamycin A derivatives involving amino group deletions have been synthesized to investigate the importance of electrostatic interactions for both substrate recognition and enzymatic modification by resistant enzymes. The three deaminated kanamycin A analogs compounds 299– 301, together with those of neamine (see Section IV.A.1: compounds 74–77 ) were
Syntheses of Aminoglycoside Antibiotics
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Compounds 283–291
tested against resistant organisms harboring APH(3⬘)-Ia and APH(3⬘)-IIa, and the same organisms without the resistance enzymes. The resulting data showed virtually unmodified products in the face of these enzymes, indicating the importance of electrostatic interactions for enzymatic modification [24]. (h) Other Kanamycin Derivatives. Cyclic carbamate derivatives of kanamycin A have been prepared [148], and in another report regiospecific methylation and stereospecific hydrogenation were used to synthesize three kanamycin B analogs with the general formula of compound 302 [149]. The same group [150] has also reported conversion of the neosamine ring of kanamycin B to the bicyclo-oxazoctene unit compound 303 (part structure). Metal acetates were used for selective protection of the amino groups in the preparation of 2⬘-deamino-2⬘-nitrokanamycin B together with 2⬘-nitroneamine analog
396
Compounds 292–298
Compounds 299–301
Compounds 302 and 303
Haddad et al.
Syntheses of Aminoglycoside Antibiotics
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(see Section IV.A.1: compound 73). These compounds are the first mechanism-based inactivators for bacterial 3⬘-phosphotransfer enzymes [APH(3⬘)s] [27]. Synthesis of kanamycin A analogs having 6-amino-3-oxo-2,3,4,6-tetradeoxy-Dand L-glycero-hexopyranose in their structures (e.g., 306) were described by Kuwahara and Tsuchiya [151]. To make compound 306, the 1-thioglycoside 304 was condensed with appropriately protected disaccharide 305, using N-iodosuccinimide (NIS) in a slightly acidic solution (compounds 304–306 ). This compound was only slightly active against common bacterial strains, and the other isomers were devoid of antibacterial activity. Synthesis of 2⬙-modified dibekacin and arbekacin derivatives including 5deoxy-5,2⬙-di-epi-5-fluorodibekacin 310 and their 2⬙-oxo analogs (compounds 311 and 312, as hydrated ketones) also was reported by the same group [152]. To make compound 310, the intermediate 307 was fluorinated by DAST at position 5 of the 2-deoxystreptamine moiety and converted to fluoro derivative 308 after deacetylation of the acetyl group at the 2⬙-position by 1.0 M methanolic sodium methoxide. Triflylation of the 2⬙-hydroxyl group followed by treatment of the resulting triflate with sodium acetate in DMF afforded the 2⬙,3⬙-cyclic carbamate 309 with inversion of configuration at 2⬙-position. Sequential removal of the protecting groups led to the formation of the title compound 310. The oxo compound 311 was prepared from the intermediate 308 by pyridinium dichromate (PDC) oxidation, followed by deprotection with trifluoroacetic acid. The same synthetic route was also employed to prepare the 2⬙-oxoarbekacin 312 (compounds 307–312 ). The 2⬙-oxo derivatives 311 and 312 were collected as the hydrated form after removal of the protecting groups and upon treatment with water. All three analogs were less active than the parent antibiotics, indicating that the equatorial 2⬙-hydroxyl group is essential for antibacterial activity. In a study of ribozyme inhibitory effect, Wang and Tor [153] prepared covalently linked dimeric aminoglycosides derived from kanamycin A, tobramycin, and neomycin B. The resulting symmetrical or asymmetrical dimeric aminoglycosides showed enhanced affinity in binding to RNA in comparison with their monomeric counterparts. In another investigation, Sreedhara and Cowan [154] prepared a variety of metallokanamycin A compounds and tested them for their ability to cleave DNA at physiological pH. Only a mixture of Cu2⫹ and kanamycin A was found to be efficient in effecting the rapid degradation of plasmid DNA at 1 mM concentration. To improve the antibacterial activity of arbekacin, addition salts of this antibiotic with (⫺)-cis-1,2-epoxypropylsulfonic acid (compound 313) were prepared by making a hemisalt of 313 with (⫹)-␣-phenylethylamine, followed by treatment with
Compounds 304–306
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Compounds 307–312
arbekacin free base. Some of these compounds showed MIC as low as 0.10 mg/mL against S. aureus [155]. 2.
Gentamicins
An extensive report by a group from the Schering-Plough Corp., describes the synthesis of a series of hexopyranosyl, hexofuranosyl, pentopyranosyl, and pentofuranosyl derivatives of gentamicin C1 and C1a with general formula of 314 [156,157]. The same group also prepared several 1- or 3-substituted and 1- or 3-epi-substituted
Compound 313
Syntheses of Aminoglycoside Antibiotics
399
analogs of sisomicin and gentamicin (e.g., 315–324 ). These compounds were synthesized from the corresponding 1- and 3-oxo derivatives by suitable reductive techniques, and the oxo compounds themselves were prepared from selectively protected gentamicin and sisomicin derivatives by means of the Corey procedure, using 3,5di-tert-butyl-1,2-benzoquinone for deamination–oxidation. The 1-hydroxy, 1-epi-hydroxy, 1-alkylamino, and 1-epi-alkylamino derivatives (compounds 316, 317, 320, and 321 respectively) were all highly potent antibiotics, and epimerization at the 1position has not significant effect on biological activity. On the other hand, the 3hydroxy, 3-epi-hydroxy, and 3-epi-amino derivatives were essentially devoid of any antibacterial activity [158]. Likewise, a number of 1-N-carbonyl derivatives of gentamicins, sisomicin, and kanamycin A, including amino and thio analogs with the general formula (partial structure) of 325 (compounds 314–325 ), have been synthesized. Some of these, particularly the 1-N-aminoalkoxycarbonyl and 1-N-aminoalkylcarboxamido analogs, exhibited highly potent antibacterial activity [159]. In another report, by Paulson and Jansen [160] described synthesis of the sisomicin analog 328 by glycosylation of the suitably protected disaccharide 326 with furanosyl bromide 327 in the presence of mercury cyanide. Likewise, gentamicin X2 analogs (compounds 329–331 ) were prepared by glycosylation of an appropriate 2azido-glycosyl chloride with a garosaminyl-deoxystreptamine derivative. The antibacterial activity screening showed no activity for 330 and 331 [161]. The same group has also reported the synthesis of the tetra-N-acetylsisamine 333 (compounds
Compounds 314–325
400
Haddad et al.
326–333 ); the mechanism was selective degradation of the 1,2⬘,3,6⬘-tetra-N-acetylsisomicin (332) by periodate oxidation [162], and it was used, as well, for syntheses of sisomicins B and D and 5⬙-C-methylsisomicin B by the Koenigs–Knorr glycosylation method with appropriately protected glycosyl halides [163]. Aminoglycoside adenyltransferases were used by Coombe and George [126] to prepare adenylated sisomicin. In another report Kim-Wright and colleagues [164] described a glycosylation method used to prepare 2⬘-deoxy- and 2⬘,3⬘-dideoxygentamicin B, 2⬘-deaminogentamicin C1a, and 2⬘-deaminosisomicin from garamine and an appropriately protected glycal; all the products showed potent antibacterial activity against resistant strains. The same group has also prepared the 6⬙-aminogentamicin C2 (compound 336) by the intramolecular insertion reaction of the acyl nitrene group into the C-methyl group in compound 334 (partial structure). This thermal reaction
Compounds 326–333
Syntheses of Aminoglycoside Antibiotics
401
proceeds through the oxazolidinone intermediate 335, which after deprotection affords the title compound 336 [165] (compounds 334–337 ). Philippe et al. [166] reported the use of a quinic acid derived cyclic ␥-amino␣-hydroxy acid related to the 1-N-4-amino-2-hydroxybutyric acid (AHBA) to prepare a 1-N-acyl derivative of gentamicin C1a (compound 337). This new antibiotic showed less activity than gentamicin C1a against gentamicin-sensitive gram-negative organisms, but it was more active against gentamicin-resistant bacteria. To probe the role of the 1-amino group in aminocyclitol antibiotics, the same group used the sequence of reactions outlined below to prepare the 1-deaminogentamicin C2 derivative 341. The free amino group of the protected gentamicin C2 derivative 338 at position 1 was formylated with p-nitrophenyl formate to give 339 and dehydrated to isocyanide 340 in the presence of p-toluenesulfonyl chloride, and then phosphorus oxychloride and triethylamine. This compound was finally converted to the deamino derivative 341 (compounds 338–341 ) by reduction with the tributyltin hydride–AIBN procedure, followed by deprotection. The deaminated analog was neither a substrate nor an inhibitor for resistance enzymes, indicating that the 1-amino group is both essential for antibacterial activity and binding to the ribosomes [167]. A 3⬘,4⬘-dideoxy-3⬘-unsaturated derivative of neamine, made by Barton and coworkers [52], from its 3⬘,4⬘-bisxanthate intermediate via radical elimination reaction, was used for the synthesis of gentamicin C1a. Streicher et al. [130] elsewhere described the synthesis of N-guanyl derivatives of gentamicins C1, C1a, and C2 at positions 2⬘,3⬘, and 6⬘. Also, metal complexion has been used by Nagabhushan and colleagues [168] to prepare 1-N-ethylsisomicin (netilmicin) from a selectively protected sisomicin derivative. Other investigators have recently reported the synthesis of 1-N-ethylsisomicin by selective protection of the 3-, 2⬘-, and 6⬘-amino groups;
Compounds 334–337
402
Haddad et al.
Compounds 338–341
Zn(OAc)2 ⭈ 2H2O was used in methanol for selective acetylation with Ac2O and Et3N in THF, followed by decomplexation with NH3-EtOH solution and ethylation with NaBH(OAc)3 in AcOH-CHCl3 [169]. E.
Streptamine-Containing Aminoglycosides: Spectinomycins
The keto moiety of spectinomycin 342 has been converted to an amino group via a hydroxyl intermediate, leading to the (S) isomer 343 [170], or through reduction of its oxime, resulting in both (S) and (R) isomers 343 and 344 (compounds 342–344 ), respectively. The (R) epimer 344 exhibited activity comparable to that of spectinomycin, but the (S) epimer 343 showed no activity [171]. A number of 3⬘-N-acetylated and 3⬘-N-alkylated derivatives were prepared from the active isomer 344 and tested for antibacterial activity. Some of these analogs showed improved activity, and the most active analog, the N-ethyl derivative, was superior to spectinomycin in terms of activity and toxicity [172].
Compounds 342–344
Syntheses of Aminoglycoside Antibiotics
403
␣-Keto rearrangement of the N-protected spectinomycin 345 to the ␣-hydroxyl lactone 346 in the presence of bis(tributyltin) oxide and bromine or mild acid was reported by Hanessian and Roy [173]. This product (compound 347), which is related to spectinoic acid, was further degraded to 6-deoxy-D-isosaccharino-1,4-lactone 348 (compounds 345–348 ) by methonolysis (3% MeOH-HCl). Partially and fully N-demethylated spectinomycin analogs were also prepared by using oxygen on platinum black for catalytic N-demethylation. However, the resulting products showed reduced or no antibacterial activity [174]. A series of 6⬘-alkylated spectinomycin analogs (compound 349), synthesized by White et al. [175], showed an increase of activity with increasing of the lipophilicity of the antibiotic. Total synthesis of spectinomycin with stereocontrolled rearrangement of its analogs has been reported [176]. There are also reports of the preparation of modified spectinomycin at the 3⬘-position, including mono- and dihalogenated derivatives, as well as branched-chain analogues via diazoketone intermediates [177,178], and synthesis of racemic spectinomycin from a cyclohexylbutadienyl ether precursor [179]. Some of the 3⬘-modified derivatives showed improved activity relative to the parent antibiotic. 3⬘-Aminomethyldihydrospectinomycins have been synthesized via spectinomycin 3⬘-cyanohydrin intermediates [180], and the Tiffeneau–Demjanov diazonium ion rearrangement of the resulting 3⬘-aminomethyl derivative compound 350 has led to the preparation of a series of spectinomycin analogs (compounds 351,
Compounds 345–348
Compound 349
404
Haddad et al.
Compounds 350–353
352, and 353) incorporating a ring-expanded seven-membered ring sugar (e.g., 351). The 3⬘-(S) isomer of 350 gave only the corresponding epoxide 352 [181]. A synthesis of spectinomycin together with the preparation of its 5⬘-n-butyl analog (replacement of the methyl group with n-butyl group) has been described. The 5⬘-n-butyl derivative (trospectomycin or 6⬘-n-propylspectinomycin) showed potent antibacterial activity and is the only aminocyclitol antibiotic that is active against anaerobic bacteria [182]. F.
Striptidine-Containing Aminoglycosides: Streptomycins
Tsuchiya, Umezawa, and their colleagues have described the synthesis of the 3⬙deoxydihydrostreptomycin 355 by Barton deoxygenation of the 3⬙-O-imidazolylthiocarbonyl derivative with tributyltin hydride [183], 6-deoxydihydrostreptamin 356 by displacement of the tosyloxy group of a 6-O-tosyl derivative with chloride followed by hydrogenolysis with liquid ammonia [184], and 3⬙-epi-dihydrostreptamycin 357 by epimerization of the 3⬘-hydroxyl group via the N,O-carbonylallopyranoside intermediate 358 (part structure) [185]. The 3⬙-deoxy analog 355 exhibited remarkable activity against most resistant and sensitive bacteria, except P. aeruginosa. The 6deoxy derivative 356 showed less activity than dihydrostreptomycin, and the 3⬙-epi analog 357 was as active as the 3⬙-deoxy derivative 355 [186] (compounds 354– 358). Methylation of a selectively protected derivative with diazomethane in the presence of tin(II) chloride has been used to prepare 5-O- and 6-O-methyldihydrostreptomycin. However, these antibiotics were only slightly active, indicating the importance of C5 and the hydroxyl groups at positions 5 and 6 for binding to the bacterial ribosome [187]. A series of dihydrostreptomycin analogs modified at the guanidino groups was synthesized. Among these, an analog with a methyl group in the guanidine at position 1 was nearly as active as dihydrostreptomycin, but all analogs having a substituted guanidino group at position 3 were devoid of activity [188]. Photosensitive derivatives of streptomycin (nitroguaiacol derivatives) have also been prepared by modification of the streptose unit, to study the mode of action of the antibiotic [189]. G.
Monoaminocyclitol-Containing Aminoglycosides: Validoxylamines and Validomycins
In extensive work, Ogawa and colleagues have used glycosylation methods to prepare monoaminocyclitol-containing aminoglycoside antibiotics and their analogs. For
Syntheses of Aminoglycoside Antibiotics
405
Compounds 354–358
instance, condensation of DL-validamine with a bromocyclenitol derivative furnished stereoisomers of validoxylamine A [190], and DL-validoxylamines A and B were prepared from condensation of the epoxycyclohexane 359 with the valienamine derivative 360 under thermal conditions [191,192]. Likewise, racemic stereo- and regioisomers of validoxylamine A were prepared [193], and -glycosylation of validoxylamine A (361) with an ␣-D-glucopyranosyl chloride derivative led to the formal synthesis of validamycin A (365) [194] (compounds 359–366 ).
Compounds 359–366 (Part A)
406
Haddad et al.
Compounds 361–368 (Part B)
The same group also reported a total synthesis of 6⬙-epi-validamycin A 366 and its diastereomer in which the racemic cyclohexene epoxide 363 was used for condensation with the protected -D-glucopyranosyl validamine derivative 364. The oxirane 363 has also been used to prepare a DL-6⬘-epi-validoxylamine analog [195,196]. These workers extended their previous work to prepare a DL-2-deoxyvalidoxylamine B analog [197] and to report the first total synthesis of validamycin A via glycosylation of a partially protected validoxylamine A with an ␣-D-glucopyranosyl chloride [198]. Total syntheses of (⫹)-validamycin B (compound 367) [199,200], (⫹)-validamycin A (365) [201,202], validoxylamine B (362) [200], (⫹)-validoxylamine A (361) and (⫹)-validamycin E (compound 368) [202] have also been reported by the same group. In another report, cleavage of the imino bonds of validoxylamine A derivatives with N-bromosuccinimide was demonstrated. This method reports the preparation of synthetically useful derivatives of (⫹)-validamine and valienamine [203]. The same group has also reported the syntheses of (⫹)-validoxylamine G [204], (⫹)-validamycins C, D, and F [35], and (⫹)-validamycin H [36] by standard glycosylation procedures. Asano et al. [205] used a combination of enzymatic and chemical reactions to synthesize eight possible mono--D-glucosides of validoxylamine A. In another synthesis by Ogawa and coworkers [206], treatment of validoxylamine A or its per-Obenzylated derivative with NBS under different conditions resulted in the formation of mixtures of keto- and aminocyclitol derivatives (e.g., 369 and 370). These compounds were used to prepare the dimeric aminocyclitol 371, which is a potent trehalose inhibitor (compounds 369–371 ).
Compounds 369–371
Syntheses of Aminoglycoside Antibiotics
H.
1,4-Diaminocyclitol-Containing Aminoglycosides: Fortimicins, Istamicins, and Related Compounds
1.
Fortimicins
407
The total synthesis of fortimicin B was achieved by glycosylation of a protected ␣sugar chloride with a biscarbamate cyclitol [207]. (a) epo-Fortimicins. 2-O-Mesylfortimicin B has been used to prepare 2-deoxyfortimicins A and B, and 1-deamino-2-deoxy-2-epi-aminfortimicins A and B. The 2deoxyfortimicin A was more active than fortimicin A (compound 372), whereas the 2-epi-amino derivative was devoid of any activity [208]. The 2-epi-fortimicin B (compound 373) was prepared by solvolysis of a 1-N-acetyl-2-O-methanesulfonyl derivative of fortimicin B [209]. Also 1-epi-fortimicins A and B (compounds 374 and 375) were synthesized by epimerization of a 2-keto derivative of fortimicin A with subsequent borohydride reduction [210]. In other work, the 6⬘-epi-fortimicins A and B (compounds 377 and 378) were prepared by oxidative deamination of the 6⬘-amino group with N-chlorosuccinimide to get a 6⬘-keto analog (e.g., 376, partial structure), followed by reductive amination with sodium cyanoborohydride [211]. The 1-epi-fortimicin A (374) showed attenuation of activity against AAC(3)-I producing organisms, and the 6⬘-epi-fortimicin A (377) showed less activity than fortimicin A (372). On the other hand, the 2⬘-epi-fortimicin A prepared from 2⬘-epifortimicin B (373) showed improved antibacterial activity. Several other derivatives of fortimicins, including 1-deamino-2-deoxyfortimicins A and B, 1,2-di-epi-fortimicins, and 2-amino-1-deamino-2-deoxy-1-hydroxyfortimicin A [212], 3-O-demethyl-2,3-di-epi-, and 3-O-demethyl-3-epi-fortimicin A and B [213] have been prepared and tested for their antibacterial activities. The 1,2-di-
Compounds 372–378
408
Haddad et al.
epi- and 3-O-demethyl-2,3-di-epi-fortimicins A were almost half as active as fortimicin A, and the other analogs were devoid of activity. (b) N-Substituted Fortimicins. Base-catalyzed rearrangement of 3-O-demethylfortimicin A has led to formation of 1-N-glycyl-3-O-demethylfortimicin B and 3-Odemethylisofortimicin [214]. Other reports have described the syntheses of a wide variety of 4-N-acyl derivatives of fortimicin A [215] and 4,2⬘-di-N-substituted derivatives of fortimicin B. These include 2-aminoethyl, glycyl, (S)-4-amino-2-hydroxybutyl, and (S)-4-amino-2-hydroxybutyryl substituted analogs (compounds 379–384 ) [216]. Among these analogs, the 4-N-substituted derivative 381 was the most potent antibiotic and showed slightly better activity than fortimicin A (372). The other derivatives showed activity comparable to that of fortimicin A but were more active against resistant strain producing AAC(3)-I enzyme. The literature contains descriptions of the 4-N-glycylation of fortimicin B 30 via selective amino group protection [217] and the selective acylation of fortimicin B and 2-epi-fortimicin B derivatives with N-(N-benzyloxycarbonylglycyloxy)-succinimide [218], as well as 4-N-acyl to 2⬘-N-acyl migration of fortimicins under basic conditions [219]. The resulting 2-O-glycyl and 1-N-glycyl analogs, as well as 5deoxy derivatives of epi-fortimicin A, were devoid of antibacterial activity. Other reports describe the syntheses of 6⬘-N-methyl and 6⬘,6⬘-di-N-methylfortimicins A and B by reductive alkylation in the presence of aldehydes [220], alkylated and acylated derivatives of fortimicins modified at the 1-, 2⬘-, and 6⬘-amino groups [221], and 4de-N-methyl analogs of fortimicins A and B by the Ruschig degradation method [222]. Of these new analogs, the 2⬘-N-[(S)-4-amino-2-hydroxybutyl] fortimicin A was more potent than fortimicin A, 6⬘-N-methylfortimicin A was half as active as the parent compound, and the others were less active or devoid of any activity. Methods have been developed to prepare 4-N-arenesulfonyl and 4-N-alkanesulfonyl fortimicin B (compounds 386 and 387) from the 1,5-carbamate derivative 385. However, these analogs were found to be devoid of antibacterial activity [223] (compounds 385–390 ). Synthesis of 2-deoxy-3-demethyoxyfortimicin A (390) has been described by Tadanier and Hallas [224]. This compound was prepared from the methanesulfonyl derivative 388 by application of the Tipson–Cohen elimination protocol to give the
Compounds 379–384
Syntheses of Aminoglycoside Antibiotics
409
Compounds 385–390
2,3-unsaturated derivative 389 (partial structure) upon mild acid-catalyzed hydrolysis, which after glycylation with N-(N-benzyloxycarbonylglycyloxy)-succinimide, and removal of Cbz groups by hydrogenolysis, afforded the title compound 390. The overall activity of this antibiotic was approximately twice that of fortimicin A and showed improved activity against Pseudomonas species. Fortimicin B has been converted to dactimicin (391) by selective formimidation of the 2⬙-amino group with formimidate hydrochloride in dry ethanol [225]. Another report described the synthesis of a number of fortimicin KG2 analogs, including 3,4didemethyl, 4-demethyl, and 3-amino-4-demethoxy-4-deoxy derivatives from sisamine [226]. (c) Other Fortimicin Analogs. 2-Substituted fortimicins, including 2-amino-2deoxy and 2-chloro-2-deoxyfortimicin A and its 2-epimer (compounds 393–395 ), have been made by stereo- and regiospecific aziridine ring opening of the 2-deoxy1,2-epimino-2-epi-fortimicin B (392) with chloride or azide. However, all these new analogs were less active than fortimicin A [227] (compounds 391–395 ). The literature provides descriptions of the preparation of a series of fortimicin analogs modified in the sugar moiety [228], the formation of mono- and biscarbamate
410
Haddad et al.
Compounds 391–395
of fortimicin B [229], the synthesis of 2-amino-3-O-demethyl-2-deoxy- and 3-amino3-demethoxy fortimicin A [230], and a number of fortimicin analogs modified in the sugar ring, including 4⬘-hydroxyfortimicin D [231], 7⬘-C-propylfortimicin A [232], 7⬘-(3-hydroxypropyl)fortimicin A and its 6⬘-epimer [233], 7⬘-phenylfortimicin A and its 6⬘-epimer [234], and 3⬘-enofortimicin D [235]. Of these analogs, only 2-amino3-O-demethyl-2-deoxy- and 3-amino-3-demethoxyfortimicin A showed activity comparable to that of fortimicin A; the others were either inactive or less active than the parent compounds. Several synthetic methodologies have been employed to convert the 1,6-anhydromaltose derivative 396 to the 1,4-diaminocyclitol aminoglycoside 397 a fortimicin analog. However, this compound was approximately 25% as potent as fortimicin A [236]. The same precursor was also used to prepare fortimicin A analogue 398 via regio- and stereoselective introduction of azido and methylamino groups and transformation of the 1,6-anhydrohexopyranose moiety into a cyclitol ring [237] (compounds 396–398 ). 2.
Istamycins
3⬘,4⬘-Dideoxyneamine has been used to prepare demethylated analogs of istamycin A (399). Antibacterial activity screening of these compounds revealed that the 4-Nmethyl group is essential for antibacterial activity, since 4-N-demethylated derivatives exhibited weak activity, whereas 6⬘-N-3-O-didemethylistamycin A still showed activity [238]. The compounds 2⬙-N-formimidoylistamycin (403) and 2⬘-N-formimidoylstamycin B (404) have been prepared by treatment of appropriately protected istamycin A0 and B0 derivatives with N-tert-butoxycarbonylglycine (compounds 399–404 ). De-
Syntheses of Aminoglycoside Antibiotics
411
Compounds 396–398
protection of the 2-N-tert-butoxycarbonyl group followed by formimidation of the 2⬙-amino function with ethylformimidate hydrochloride and deprotection of the protecting groups led to the formation of the title compounds. These naturally occurring aminoglycosides have strong antibacterial activity, similar to istamycin A and B [239]. A number of istamycin B analogs, including 5-epi-, 3-O-demethyl-5-epi-, 3-Odemethyl-3-epi-, 3-demethoxy, 3-demethoxy-2⬙-N-formimidoyl [240], 3-O-demethyl, and several 2⬘-N-acyl and N-amidinyl [241] derivatives have been synthesized. Of these, the 3-demethoxy and 3-demethoxy-2⬙-N-formimidoyl analogs showed more potency than istamycin B and its 3-O-demethyl derivative. Various istamycin derivatives (compound 405) bearing different aminoacyl groups at the 4-amino group have been synthesized. These analogs, which have a combination of hydroxyl and amino groups for X and Y in their structures [e.g., (X, Y) = (NH2, OH), (OH, OH), (H, OH), (OH, NH2)], showed promising antibiotic activity. Of these, the antibiotic (compound 406) was tested with 54 bacteria and showed potent antibacterial activity, much higher than that of istamycin B [242]. 3.
Sporaricins
The three fluorinated derivatives of sporaricin A 407, including 3-demethoxy-3-fluoro (408), 3-demethoxy-epi-fluoro (409), and 3-demethoxy-3,3-difluoro (410), have been prepared from a protected 3-demethylsporaricin derivative. Direct fluorination of the
Compounds 399–404
412
Haddad et al.
Compounds 405 and 406
3-hydroxyl group with DAST gave the 3-fluoro derivative, and oxidation of the free hydroxyl group followed by sodium borohydride reduction and the subsequent fluorination afforded the epi-fluoro compound. Likewise, PCC oxidation of the hydroxyl group at position 3 followed by fluorination of the resulting oxo derivative furnished the difluoro analog. Of these analogs, the 3-fluoro derivative 408 showed less toxicity and more activity than sporaricin A [243]. Replacement of the 3-O-methyl group of sporaricin A with allyl group via hydroiodic acid assisted removal of the methyl group, followed by allylation of the free 3-hydroxyl group, led to preparation of the 3-O-substituted analogs 411–413 (compounds 407–413 ). These compounds were synthesized by epoxidation of the allylic double bond with mCPBA, followed by sequential treatment with sodium azide, water, or potassium cyanide. All these analogs exhibited high antibacterial activity against AAC(3)-I producing organisms. Among these analogs, compounds 411 and 413 showed enhanced activity against P. aeruginosa compared to the parent compound [244]. Total synthesis by a glycosylation method of the semisynthetic antibiotic 3-Omethylsporaricin A has been described [245]. Other reports describe the preparation of a series of fluorinated sporaricin A, including 3-fluoro and 3,3-difluoro derivatives
Compounds 407–413
Syntheses of Aminoglycoside Antibiotics
413
of 3-demethoxysporaricin A [246], as well as 5-deoxy-5-fluorosporicin A [247]. In this work, the direct fluorination method was used with the DAST reagent to make the fluorinated analogs. 4.
Lysinomicin
4-N-Glysyllysinomicin (415) and several 4-N-aminoacyl analogs of lysinomicin derivatives (compounds 416–418 ) have been prepared to examine the effect of 4-Naminoacylation on antibacterial activity of this class of aminoglycoside antibiotics (compounds 414–418 ). In contrast to lysinomicin, which is slightly more potent than fortimicin A (372), the new analogs showed lower activity than the 4-N-unsubstituted lysinomicin derivatives, indicating that the structure–activity relationship observed with fortimicins does not apply to lysinomicin derivatives [248]. 5.
Sannamycins
Ludin et al. [249] have described the synthesis of the pseudodisaccharide sannamycin 419, its 2-epimer, and a variety of other isomers including the enantiomers of sannamycin. These workers also prepared various other sannamycin analogs including 6⬘-de(N-methyl) sannamycin A (420) and its 2⬘-epi isomer 421, as well as derivatives 422 and 423, using the glycosyl donors 424 or 425 for glycosylation with sannaminetype glycosyl acceptor 426 (compounds 419–426 ). Among these analogs, compound 420 showed no activity, and 421 was slightly active, but much less active than the parent compound, sannamycin (419) [250]. I.
Other Aminocyclitol Aminoglycosides
Three ␣-glycosidase inhibitors of 2,5,6-trideoxystreptamine (compounds 427–429 ) have been prepared by glycosylation of the quinic acid derived ditosyloxycyclohexanol derivative 430, with the corresponding glycal derivatives (e.g., 431 and 432)
Compounds 414–418
414
Haddad et al.
Compounds 419–426
Compounds 427–432
as glycosyl donors. However these compounds were devoid of antibacterial activity, indicating that the presence of an ether linkage at the 4⬘-position (in comparison with apramycin, 48) is probably essential for antibacterial activity in this class of aminoglycoside antibiotics [251].
Syntheses of Aminoglycoside Antibiotics
J.
Noncyclitol Aminoglycosides
1.
Trehalosamines
415
Trehalosamine (433), an ␣,␣-(1→1)-linked disaccharide produced by Streptomyces lavendulae, is an aminoglycoside antibiotic composed of D-glucose and 2-amino-2deoxy-D-glucose [252]. Ogawa and colleagues [253,254] used a racemic inosamine derivative to prepare the trehalosamine analogs 434–436 by glycosylation with an appropriately protected glucopyranosyl bromide. Likewise, a number of pseudosugar analogs, including the ␣-D-glucosides 437 and 438, were synthesized by glycosylation of the -D-glucopyranose derivative 439 with the ␣-DL-glucopyranose 440 in the presence of trimethylsilyl trifluoromethanesulfonate (compounds 433–440 ). However, these compounds exhibited no antibacterial activity [37,254]. 2.
Acarviosins
Acarviosin 441, an ␣-glycosidase inhibitor, is a maltose-type pseudodisaccharide that can be prepared from methanolysis of acarbose 442 [255]. It has been shown to have five times more inhibitory activity than its precursor acarbose, for which the first total synthesis has been described by Ogawa’s group in 1989 [256]. The methylacarviosin 447, a core structure of acarbose and related pseudooligosaccharidic ␣-amylase inhibitors, together with its 6-hydroxy analog 448, were prepared by Shibata et al. [257] from the corresponding oligobiosaminide derivatives 443 and 444. The aziridine intermediates 445 and 446 were treated with hydrochloric acid to give the corresponding 6⬘-chloro derivative, and then elimination of the chlorine by base furnished the title compounds 447 and 448 as peracetylated derivatives (compounds 441–448 ). The same group has also prepared several other ␣-glucosidase inhibitors, including 1⬘,6⬘- and 3⬘,6⬘-anhydro derivatives of acarviosin [258], methylacarviosin
Compounds 433–440
416
Haddad et al.
Compounds 441–448 derivatives [259], and analogs of acarviosin and methyl acarviosin having ␣-D-manno configurations and saturated cyclohexane rings [260,261]. Another report by this group describes the synthesis of methyl 1⬘-epi-acarviosin and its 6-hydroxy analog [262]. Various other 1,6-anhydro acarviosins, including 2⬘-substituted derivatives having the 2⬘-hydroxyl group replaced with NH2 or F, as well as a diastereomeric methylacarviosin and its hydroxylated analog, have also been synthesized by the same group [263,264]. The total synthesis of the trehalose inhibitor salbostatin 451 was achieved by the coupling reaction of the ␣-valienamine derivative 449 with 1,5:2,3-dihydro-Dmannitol (450) under forcing conditions (sealed tube, 120⬚C) in a protic solvent [265] (compounds 449–451 ). K.
Aminocyclopentitol Aminoglycosides: Trehazolin and Trehalostatin
The total syntheses of the trehalose inhibitors trehazolin (452) [266,267] and its 5epi analog trehalostatin (453) [266,268] have been described by two different groups. The 5-epi derivative 453 possesses much weaker inhibitory activities than trehazolin toward two trehalases. Another publication by Boiron et al. [269] reports a synthesis of trehazolin 452 from D-glucose. In this synthesis three chiral centers of the starting compound, D-glucose, are conserved and the remaining two chiral centers of trehazolamine 456 are formed stereoselectively by reductive cyclization of the ketoxime ether 454. Reduction of this oxide ether leads to formation of the title compound 456 (compounds 452–456 ). In addition, different research groups have described syntheses of (⫹)-trehazolin [270,271], (⫹)-6-epitrehazolin [271], a tetrahydropyrano-[2,3-d] oxazol analog
Syntheses of Aminoglycoside Antibiotics
417
Compounds 449–451
Compounds 452–456
of trehazolin [272], and a series of trehazolin derivatives in which the ␣-D-glucopyranose unit was replaced by other mono- and disaccharide or carba sugar units [273]. The inhibitory activity results revealed that the four hydroxyl groups of the D-glucopyranosyl moiety of trehazolin are topologically essential for the hydrogen binding of the inhibitor to the active site of the enzyme. Furthermore, it appeared that the -D-glucopyranosyl residue is likely to facilitate the uptake of the compound into the cell [273].
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S Hanessian, TH Haskell. In: H Pigmann, D Horton, eds. Antibiotics Containing Sugars. New York/London: Academic Press, 1970, pp 139–211. S Umezawa. Adv Carbohydr Chem Biochem 30:11–182, 1974. DA Cox, K Richardson, BC Ross. In: PG Sammes, ed. The Aminoglycosides. New York: John Wiley & Sons, 1977, pp 1–90. S Umezawa, T Tsuchiya. In: H Umezawa, IR Hooper, eds. Handbook of Experimental Pharmacology. New York: Spring-Verlag, 1982, pp 37–110. J Haddad, LP Kotra, S Mobashery, Chapter 10, this volume. GD Wright, AM Berghuis, S Mobashery. In: BP Rosen and S Mobashery, eds. Resolving the Antibiotic Paradox: Progress in Understanding Drug Resistance and Development of New Antibiotics. New York: Plenum Press, 1998, pp 27–69. SA Lerner, RP Gaynes. In: SL Gorbach, JG Bartlett, NR Blacklow, eds. Infectious Diseases. Philadelphia: WB Saunders, 1992, pp 188. JJ Wright, A Cooper, PJL Daniels, TL Nagabhushan, D Rane, WN Turner, J Weinstein. J Antibiot 29:714–719, 1976. H Kawaguchi, T Naito, S Nakagawa, K Fujisawa. J Antibiot 25:695–708, 1972.
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I Daishiro, T Masaki, K Shinichi, T Tomio. Jpn Kokai Tokkyo Koho JP 09, 278, 787 [97,278,787]. T Tsuchiya, T Torii, S Umezawa. J Antibiot 35:1245–1247, 1982. I Watanabe, K Kamiya, T Yamaguchi, T Mori. Carbohydr Res 109:47–57, 1982. N Yasuda, K Matsuda, H Tsutsumi, T Takaya. J Antibiot 38:1512–1525, 1985. T Tsuchiya, T Torii, Y Suzuki, S Umezawa. Carbohydr Res 116:277–286, 1983. T Torii, T Tsuchiya, S Umezawa. Carbohydr Res 116:289–294, 1983. P Kurath, RS Stanaszek, M Cirovic. J Antibiot 35:1338–1344, 1982. C Ludin, T Weller, B Seitz, W Meier, S Erbeck, C Hoenke, R Krieger, M Keller, L Knothe, K Pelz, A Witmer, H Prinzbach. Leibigs Ann Chem 291–316, 1995. S Erbeck, XF Liang, D Hunkler, R Krieger, H Prinzhach. Eur J Org Chem 9:1935– 1948, 1998. N Rolland, G Vass, J Cleophax, A-M Sepulchre, SD Gero. Helv Chim Acta 65:1627– 1636, 1982. T Suami, S Ogawa, T Toyokuni. Chem Lett 611–612, 1983. S Ogawa, T Toyokuni, Y Hattori, T Nose, T Suami. Carbohydr Res 146:167–173, 1986. S Ogawa, Y Shibata. Carbohydr Res 170:116–123, 1987. B Junge, F Heiker, J Kurz, L Mu¨ller, DD Schmidt, C Wunsche. Carbohydr Res 128: 235–268, 1984. Y Shibata, S Ogawa. Carbohydr Res 189:309–322, 1989. Y Shibata, S Ogawa, T Suami. Carbohydr Res 200:486–492, 1990. S Ogawa, Y Shibata, Y Kosuge, K Yasuda, T Mizukoshi, C Uchida. J Chem Soc Chem Commun 1387–1388, 1990. Y Shibata, Y Kosuge, T Mizukoshi, S Ogawa. Carbohydr Res 228:377–398, 1992. S Ogawa, H Suguzaki. Chem Lett 1977–1980, 1986. S Ogawa, Y Nakamura. Carbohydr Res 226:79–89, 1992. S Ogawa, C Uchida, Y Shibata. Carbohydr Res 223:279–286, 1992. JC McAuliffe, RV Syick. Aust J Chem 50:219–224, 1997 JC McAuliffe, C Joseph, VR Stick, D Mutthew, G Tilbrook, GA Watts. Aust J Chem 51:91–95, 1998. T Yamagishi, C Uchida, S Ogawa. Chem Eur J 1:634–636, 1995. C Uchida, T Yamagishi, S Ogawa. J Chem Soc Perkin Trans 1 589–602, 1994. Y Kobayashi, H Miyazaki, M Shiozaki. J Org Chem 59:813–822, 1994. Y Kobayashi, H Miyazaki, M Shiozaki. J Antibiot 47:932–938, 1994. A Boiron, P Zillig, D Faber, B Giese. J Org Chem 63:5877–5882, 1998. BE Ledford, EM Carreira. J Am Chem Soc 117:11811–11812, 1995. J Li, F Lang, B Ganem. J Org Chem 63:3403–3410, 1998. M Shiozaki, T Mochizuki, H Hanzawa, H Haruyama. Carbohydr Res 288:99–108, 1996. C Uchida, H Kitahashi, S Watanabe, S Ogawa. J Chem Soc Perkin Trans I 1707–1717, 1995.
243. 244. 245. 246. 247. 248. 249. 250. 251. 252. 253. 254. 255. 256. 257. 258. 259. 260. 261. 262. 263. 264. 265. 266. 267. 268. 269. 270. 271. 272. 273.
12 Synthesis of Glycosaminoglycans Bryan K. S. Yeung, Pek Y. C. Chong, and Peter A. Petillo University of Illinois at Urbana-Champaign, Urbana, Illinois
I.
INTRODUCTION
The glycosaminoglycans (GAGs) are an important family of highly functionalized, linear, and negatively charged bioactive oligosaccharides that are ubiquitous components of animal connective tissue. Except for hyaluronan and heparin, which are also found in their free form, they exist as long chains covalently bound to a protein core, giving rise to macromolecular assemblies known as proteoglycans (PGs) [1– 7]. As major structural components of PGs, GAGs play both diverse and critical roles in lymphocyte trafficking [2], inflammatory response [3], wound repair and healing [4], and smooth muscle cell migration [5], and in conferring structural stability and resistance to deformation in cartilage [6]. The presence of GAGs on the surface of cells has been described in a number of systems and explains how GAGs achieve the diversity of roles played in various biological processes [7]. Moreover, their polyanionic character makes GAGs ideal cell surface receptors that bind circulating molecules in the extracellular matrix [8]. Glycosaminoglycan polymers consist of repeating disaccharide units usually composed of a 2-deoxy-2-amino sugar and an uronic acid partner. Single GAG chains may reach weights in excess of 1 MDa (Table 1). Mutual repulsion between negatively charged carboxylate groups contributes to the rigid structure of GAGs. Sulfate groups heterogeneously situated along the chain contribute to the inherent anionic character of the polymer and are often the sites of protein interactions. Depending on the type of amino sugar found in the polymer, GAGs can be classified into two broad categories: the glucosaminoglycans, based on D-glucosamine (hyaluronic acid, keratan sulfate, heparin, and heparan sulfate), and the galactosaminoglycans, based on D-galactosamine (chondroitin 4-sulfate, chondroitin 6-sulfate, and dermatan sulfate). 425
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Table 1
Summary of Glycosaminoglycan Structure and Occurrence
Glycosaminoglycan
Uronic acid
Hexosamine
Occurrence
N-Acetyl-D-glucosamine
Synovial fluid, vitreous body of the eye, loose connective tissue
D-Glucuronate
N-Acetyl-D-galactosamine Sulfation at C4 or C6
Cartilage and the intervertebral disc
L-Iduronate
N-Acetyl-D-glucosamine Sulfation at C4
Fibrous connective tissues (e.g., tendons, sclera, skin)
D-Galactose
N-Acetyl-D-glucosamine Sulfation at C4 or C6
KS(I): cornea, embryonic liver, lung KS(II): skeletal tissue
Heterogeneous mixture of D-glucuronate and L-iduronate
N-Acetyl-D-glucosamine Sulfation is usually incomplete and random
Heparin: found in granules of mast cells Heparan sulfate: cell surface component of many cell types
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D-Glucuronate
Synthesis of Glycosaminoglycans
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GAGs and their derivatives are widely used in biomedical applications, with heparin and heparan sulfate being the most widely used in clinical settings [9,10]. In particular, heparin’s remarkable anticoagulant activity has led to its use as an antithrombotic drug. Other biomedical applications of GAGs, including their potential as antiviral agents, are enormous. For example, a heparin decasaccharide and the polysulfonated heparin analog suramin were both reported to inhibit dengue virus infection of host cells [11]. Other viruses such as HIV also appear to be susceptible to polysulfated, negatively charged carbohydrate oligomers such as curdlan sulfate [12] and kakelokelose [13]. Curdlan sulfate is a sulfated semisynthetic polysaccharide that inhibits HIV-1 infection of human peripheral lymphocytes. Kakelokelose, a related polysulfated (1,6)-mannose polymer isolated from a marine source, also displays moderate anti-HIV activity. Although no consensus on the mode of activity currently exists, it is clear that the long, negatively charged chains of the polysaccharide bind to specific domains on the viral surface proteins, thereby neutralizing entry into the host cell. With the development of potential therapies based on the control of protein–GAG interactions for modifying cell–cell interaction, viral infection, and cell growth, the chemical preparation of GAG fragments and their analogs becomes increasingly important. This chapter surveys the chemical preparation of the glycosaminoglycan oligosaccharides of hyaluronan, chondroitin sulfate, dermatan sulfate, keratan sulfate, heparin, and heparan sulfate. Despite the biological importance of these ubiquitous carbohydrate polymers, there are surprisingly few reports of the chemical syntheses of GAG oligosaccharides. The multiple functionality of GAGs provides an excellent scaffold on which structure–activity relationships can be studied, but their syntheses present an unparalleled challenge to the synthetic carbohydrate chemist. The de novo construction of these highly functionalized carbohydrates has proven difficult, and only limited synthetic methodologies, exist for their assembly. For a long time, the lack of well-defined synthetic targets had discouraged organic chemists from the chemical synthesis of GAG oligosaccharides. Only in recent decades have the structures of these biologically active carbohydrate oligosaccharides been elucidated. This, together with the development of new carbohydrate synthetic methodology that utilizes newly developed protecting groups as well as glycosylation procedures, has made it possible to synthetically access GAG fragments that allow them to be analoged for new drug development. A.
Synthetic Strategies for GAG Preparation
As a result of their high degree of functionality, GAGs represent challenging synthetic targets. All GAGs have structural similarities that form the focal point of any synthetic effort. The disaccharide repeating units are composed of either -D-glucopyranosiduronic acid or ␣-L-idopyranosiduronic acid and a hexosamine residue of either -D-glucosamine or -D-galactosamine that is usually N-acetylated. Additionally, the linear, polymeric chains may be O-sulfated and N-sulfated to varying degrees. The order of the glycosidic bond forming events, the choice of starting amino functionality, and the timing of oxidation state adjustment of C6 all represent important considerations that must be addressed at the onset of any synthetic effort. As with any carbohydrate synthesis, multiple orthogonal protecting groups are required to allow reaction to be isolated to a particular site. The choice of protecting groups is crucial inasmuch as the final deprotection sequence may prove problematic [14].
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Formation of the (1,4)-glycosidic linkage between C4 of the uronic acid moiety and the hexosamine residue is generally more difficult than formation of the corresponding (1,3)-linkage. In addition to the steric deactivation of the C4 hydroxyl group, its nucleophilicity is lowered by the electron-withdrawing properties of the C6 ester in the uronic acid derivative [15]. Therefore, historically, the (1,4)linkage is formed early on in the synthetic sequence to yield disaccharide fragments, which are then further elaborated (Scheme 1). The uronic acid residue is typically masked as a selectively protected form of D-glucose or L-idose prior to glycosidic bond formation. When glycosylation is complete, the uronic acid moiety is produced by selective C6 deprotection and oxidation. Newly described and efficient glycosylation methodologies that utilize highly reactive glycosyl donors, such as Schmidt’s trichloroacetimidate method [16], Kahne’s sulfoxide chemistry [17], and the pentenyl glycosylation technique of FraserReid [18], now offer high-yielding glycosylation strategies to offset the poor nucleophilicity of uronic esters in GAG synthesis. The synthesis of GAGs requires the installation and protection of a 2-deoxy2-amino functionality. The hexosamine unit is either N-acetyl--D-glucosamine or N-acetyl--D-galactosamine, with the former being more extensively employed, largely because of its ready availability and relatively low cost. Galactosamine, a rare and expensive sugar, is less attractive for use as a starting material. Consequently, several methodologies have been developed for the installation of the 2amino functionality into D-glucal and D-galactal building blocks, both of which are readily available at modest cost. Regardless of the strategy, the N-protecting group employed must survive several chemical manipulations while maintaining facile conversion to the corresponding acetamide at the conclusion of the synthesis. Presumably, the most convenient N-protecting group for GAG synthesis would be the acetate group, since this would eliminate the need for an N-deprotection and acetylation sequence at the conclusion of the synthesis. However, the N-acetate group generally imports poor solubility to the sugar; therefore, a range of alternative N-protecting groups including phthalamide [19], azide [20], trichloroacetyl [21], trichloroethoxycarbonyl [22], and benzenesulfonamide [23] are currently employed. The widely used 2-deoxy-2-azido group has been accessed by the azidonitration [24] of D-glucal or D-galactal. In general, this route is more attractive for the preparation of N-acetyl galactosamine derivatives because it produces predominantly two isomers owing to the strong preference for the C2 azido group to exist in the equatorial orientation (presumably due to the sterically disfavored axial approach). On the other hand, azidonitration of D-glucal gives rise to four isomers: 1:1 mixtures of both the gluco- and mannoazidonitrate derivatives (Scheme 2). In either case, the C1 nitrate can then be transformed into a variety of functional groups such as halides, acetates, or methyl ethers. Additionally, the azide is stable under a wide range of glycosylation conditions and can readily be reduced and acetylated at the conclusion of the synthesis. The iodosulfonamidation method pioneered by Danishefsky and coworkers offers an alternative method of introducing a 2-deoxy-2-amino moiety into D-glucal or D-galactal scaffolds [25–29]. Briefly, trans-diaxial addition of a glycal is achieved by treatment with an iodonium ion source (sym-collidine iodonium perchlorate) followed by trapping with an arylsulfonamide (Scheme 3). The active glycosylating intermediate formed under basic conditions is believed to be the 1,2-sulfonylaziri-
Synthesis of Glycosaminoglycans
Scheme 1
A typical retrosynthetic analysis for GAGs.
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Scheme 2
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The synthesis of 2-deoxy-2-amino glucosides from glycals.
dine, which is an extremely powerful electrophile that promotes the -attack of a nucleophile at the anomeric carbon. Chain elongation can be achieved if the nucleophile is another glycal or a suitably differentiated glycosyl acceptor. Several procedures for the conversion of the 2-sulfonamide to the free amine have been reported and depend on the arylsulfonamide employed. Benzenesulfonamide can be converted to the corresponding amine by treatment with excess sodium in ammonia [26]. When 9-anthracenesulfonamide is used, conversion to the free amine can be achieved by treatment with thiophenol, 1,3-propanedithiol, or diisopropylethylamine. The milder reaction conditions required to cleave 9-anthracenesulfonamide derivatives are more likely to be compatible with other functional groups on the carbohydrate [30]. Since D-galactose is the C4 epimer of D-glucose, the selective inversion of the configuration at C4 on D-glucosamine derivatives provides efficient access to the corresponding D-galactosamine derivatives (Scheme 4). In this way, construction of GAG oligosaccharides may incorporate D-glucosamine units, which can then be inverted at C4 to afford the corresponding galactosaminoglycan. This C4 inversion has been achieved by formation of the C4 triflate followed by nucleophilic displacement
Scheme 3
Iodosulfonamidation of glycals to form 2-deoxy-2-amino glucosides.
Synthesis of Glycosaminoglycans
Scheme 4
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Epimerization of D-glucose to D-galactose.
[31b,32] and also by oxidation to the ketone followed by stereoselective reduction [33]. II.
HYALURONAN (HYALURONIC ACID)
Meyer and Palmer first isolated hyaluronan (hyaluronic acid) in 1934 from the vitreous body of bovine eyes, and its structure was elucidated by a combination of chemical and enzymatic methods [31]. Hyaluronan (HA) is a linear, unbranched repeating polymer of 2-acetamido-2-deoxy-D-glucopyranose (GlcNAc) linked (1,4) to D-glucuronic acid (GlcUA). The disaccharide repeating units are linked (1,3) to form the HA chain (Fig. 1). HA has been found in all mammalian tissues including the extracellular matrix [32,33], connective tissue, and synovial fluid [34]. Its intrinsic viscoelasticity confers mechanical properties to cartilage, where it interacts with proteoglycans to produce aggregates [35] that enable cartilage to resist compressive loads. Loss or collapse of this construct reduces the ability of the surrounding tissue to withstand mechanical stress, which in turn may accelerate the breakdown of cartilage [36]. Hyaluronan is becoming increasingly important in biomedical applications as more biological functions for the polymer are discovered. HA regulates such biological processes as cellular proliferation [37], cell–cell recognition, and cell migration and cell adhesion [38]. High concentrations of hyaluronan oligosaccharides have been shown to suppress the initial vascularization of blood vessels [39], while lower concentrations of low molecular weight HA fragments, produced by enzymatic cleavage, can stimulate the formation of blood capillaries [40]. This dual role and its nonimmunogenic properties have sparked interests in hyaluronan as a potentially
Figure 1
Polymeric HA, its degradation product, and methyl hyalobiuronic acid.
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useful antitumor drug [41]. HA is found in bacteria and can be produced in larger quantities than can be achieved by extraction methods [42]. Historically, the chemical preparation of small HA fragments aided in the structure elucidation of HA degradation products as well as providing units that can be used to probe the biological pathways and activities of HA. A step toward this goal was the synthesis of an HA disaccharide fragment, hyalobiuronic acid, which was repeatedly isolated as a degradation product of acid hydrolysis [43]. Identified as 2deoxy-2-amino-3-O-(-D-glucopyranosyluronic acid)-␣-D-glucose (II.2), the compound most likely existed as a mixture of ␣ and  anomers. The chemical preparation of II.2, reported simultaneously by Flowers and Jeanloz [44] and Takanashi et al. [45] in 1962, employed mercury-mediated Koenigs–Knorr glycosylation methodology. Subsequently, Jeanloz and Flowers reported the synthesis of methyl hyalobiuronic acid (II.3) by condensation of 1-bromo-2,3,4,6-tetra-O-acetyl-␣-D-glucopyranoside (II.4) with II.5 in the presence of mercuric cyanide [Hg(CN)2], followed by deacetylation to produce II.6 (Scheme 5). Removal of the 4,6-O-benzylidene with acid afforded II.7, methyl 2-acetamido-2-deoxy-3-O- (-D-glucopyranosyl)-␣-D-glucopyranoside, in 35% yield. Attempts to selectively oxidize C6 of the D-glucose moiety in II.7 to the corresponding carboxylic acid with platinum oxide proved unsuccessful. The inability to effect selective oxidation of C6 on the D-glucose moiety led to the use of II.8, methyl(2,3,4-tri-O-acetyl-␣-D-glucopyranosyl uronate) bromide, as an alternate glycosyl donor (Scheme 6). Glycosylation with II.5 in the presence of Hg(CN)2 afforded disaccharide II.9 in 54% yield, and subsequent removal of the benzylidene followed by acetylation gave the hexa-acetyl derivative II.10. Treatment of II.10 with lithium borohydride afforded 54% of a product identical to II.3. Warren and coworkers reported the synthesis of the protected tetrasaccharide of HA with a ␣-D-glucose derivative at the reducing end [46]. Their strategy utilized the glycosylation of two disaccharides, which were both derived from a common disaccharide precursor. Starting from the known glycosyl bromide II.11 [47], silver triflate–collidine mediated coupling of 4-penten-1-ol in CH2Cl2 afforded the acetylated pentenyl glycoside II.12 (Scheme 7). Deacetylation under Zemple´n conditions followed by treatment with 2,2-dimethoxypropane furnished the 4,6-O-isopropyli-
Scheme 5
The initial attempt to synthesize hyalobiuronic acid.
Synthesis of Glycosaminoglycans
Scheme 6
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The use of a glucuronic acid derivative to synthesize hyalobiuronic acid.
dene compound II.13. Subsequent bromoacetylation of the 3-OH gave the fully protected glycoside donor II.14 in 55% yield over two steps. Glycosyl acceptor II.15 was prepared by benzoylation of methyl 4,6-O-benzylidene-␣-D-glucopyranoside, removal of the benzylidene, and selective bromoacetylation at C6 of the resulting diol II.16. Glycosylation of II.15 with II.14 was carried out in the presence of N-iodosuccinamide (NIS) and a catalytic amount of silver triflate (AgOTf), to give the (1,4)-linked disaccharide II.16 in 68% yield (Scheme 8). The conversion of II.16 into the glycosyl acceptor II.17 was achieved by treatment with thiourea in methanol [48], followed by reinstallation of a bromoacetyl moiety at C6. Alternatively, conversion of II.16 into glycosyl donor II.18 was ef-
Scheme 7
Preparation of monomers used in the Warren synthesis of HA.
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Scheme 8
Yeung et al.
Warren synthesis of the fully protected HA tetrasaccharide.
fected by treatment with dichloromethylmethyl ether and freshly fused zinc chloride [49]. Donor II.18 proved to be fairly unstable, so after filtration of the insoluble salts, the crude syrup was dried azeotropically with toluene and used immediately in the next step. The target tetrasaccharide II.19 was obtained in 41% yield with silver triflate mediated coupling of II.17 and II.18 in collidine. The anomeric configuration of II.19 was determined by 1H NMR coupling constants, which indicated the presence of a single ␣ and three  linkages. Ogawa and coworkers have synthesized a series of hyaluronan fragments ranging from the di- to the tetrasaccharide with both N-acetylglucosamine and glucuronic acid at the reducing ends. The first HA target described was the tetrasaccharide II.20 with N-acetylglucosamine at the reducing end [19]. The strategy employed the use of two glycosyl donors II.21 and II.22, and a glycosyl acceptor II.23 (Scheme 9). Compound II.23 was prepared by glycosylation of donor II.24 with II.25 using trimethylsilyl triflate (TMSOTf) as a promoter to afford 87% of the corresponding disaccharide II.26. De-isopropylidenation followed by acetylation and removal of allyloxycarbonyl (Aloc) group afforded acceptor II.23 in 82% yield over three steps. Condensation of II.23 with donor II.22 in the presence of boron trifluoride etherate (BF3⭈Et2O) gave the corresponding trisaccharide II.24 in 88% yield (Scheme 10). Deprotection of the allyloxycarbonyl afforded the trisaccharide acceptor II.25. Tri-
Synthesis of Glycosaminoglycans
Scheme 9
The Ogawa synthesis of the HA tetrasaccharide with N-acetylglucosamine at the reducing end. 435
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Scheme 10
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Deprotection of the HA tetrasaccharide with N-acetylglucosamine at the re-
ducing end.
methylsilyl triflate promoted glycosylation of II.25 with donor II.21 gave the tetrasaccharide II.26 in 87% yield. Following hydrolysis of the isopropylidene and acetylation, removal of both levulinoyl groups furnished diol II.27. Oxidation of the primary alcohols to the corresponding diacid II.28 was achieved in two steps in 86% overall yield. Finally, deacylation of II.28 with methylamine in methanol followed by selective N-acetylation afforded the target tetrasaccharide II.20 in 82% yield over the two steps. Ogawa and coworkers also reported the synthesis of the corresponding HA tetrasaccharide having a glucuronic acid at the reducing end [50]. The strategy employed the prior formation of two (1,4)-linked disaccharides, followed by coupling of these disaccharides through the (1,3)-linkage to produce the target tetrasaccharide. The synthesis describes the preparation of two separate, orthogonally protected disaccharide units and highlights the use of Schmidt’s trichloroacetimidate glycosylation methodology. Construction of the target tetrasaccharide utilized the monomer units II.29 [51], II.30 [19], and II.31 (Scheme 11) [52]. Stereocontrolled glycosylation of II.30 with II.29 in the presence of boron trifluoride etherate (BF3⭈Et2O) afforded the corresponding disaccharide II.32 in 81% yield. Subsequent conversion of the methoxy-
Synthesis of Glycosaminoglycans
Scheme 11
The Ogawa synthesis of the HA tetrasaccharide with glucuronic acid at the reducing end.
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phenyl group into the trichloroacetimidate gave the glycosyl donor II.33 in 88% yield over two steps. Similarly, glycosylation of II.30 with II.31 under the same conditions produced the corresponding (1,4) dimer II.34 in 81% yield. Following this, treatment with tetrakis(triphenylphosphine)palladium ((Ph3P)4Pd) [53] and morpholine unblocked the 3⬘-OH and produced the disaccharide acceptor II.35 in 88% yield. Trimethylsilyl triflate promoted coupling of II.33 with II.35 gave, after acid hydrolysis of the isopropylidene, tetrasaccharide II.36 in 77% yield (Scheme 12). Compound II.36 was acetylated, and removal of the levulinoyl groups with hydrazine acetate unmasked the 6-OH on each of the glucuronic acid precursors. A Swern oxidation of the two primary hydroxyl groups was achieved in two steps to give the diacid II.37 in 76% overall yield. Finally, following deacylation of II.37 with methylamine in methanol, selective N-acetylation afforded the target tetrasaccharide II.38. Using the strategy developed and described by Ogawa and coworkers in the preparation of tetrasaccharides II.20 and II.38, the methodology was expanded to an additional set of HA-related di-, tri-, and tetrasaccharides having N-acetylglucosamine at the reducing end [54]. For the synthesis of II.39, II.40, and II.41, synthons II.42–II.46 were employed. Imidates II.42 and II.45 are precursors for the D-glucuronic acid moiety at the nonreducing terminal and internal position, respectively. Similarly, II.43, II.44, and II.46 [52] are precursors for the N-acetyl-D-glucosamine residue (Fig. 2). The preparation of each of the synthons is detailed and fully described by Ogawa and coworkers. The preparation of disaccharide II.39 is outlined in Scheme 13. Condensation of II.42 with II.43 using TMSOTf as a promoter afforded disaccharide II.47 in 81% yield. Treatment with aqueous TFA followed by acetylation replaced the isopropylidene moiety with two acetate groups, and subsequent de-levulinoylation with hydrazine acetate gave the primary alcohol II.48. A Swern oxidation of the primary
Scheme 12 end.
Deprotection of the HA tetrasaccharide with glucuronic acid at the reducing
Synthesis of Glycosaminoglycans
Figure 2
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Other HA fragments prepared by Ogawa and coworkers.
hydroxyl group was carried out in two steps with oxalyl chloride and dimethyl sulfoxide [55], followed by treatment with sodium chlorite [56] to give II.49 in 70% yield. Subsequent treatment with methylamine followed by selective N-acetylation afforded a disaccharide with an O-acetyl group present, indicating that acetylation
Scheme 13
The Ogawa synthesis of the HA disaccharide.
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Scheme 14
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The Ogawa synthesis of the HA trisaccharide.
was not selective at the 2-deoxy-2-amino position. Consequently, addition of sodium methoxide in methanol was required to produce the desired disaccharide II.39 (65%). The preparation of the trisaccharide II.40 was carried out by condensation of imidate II.45 with acceptor II.43 in the presence of TMSOTf to afford disaccharide II.50 in 87% yield (Scheme 14). Conversion of II.50 into glycosyl acceptor II.51 was achieved by de-isopropylidination and acetylation followed by removal of the allyloxycarbonyl group. Glycosyl acceptor II.51 was subsequently condensed with imidate II.44 in the presence of BF3⭈Et2O to give the trisaccharide derivative II.52 in 81% yield. The deprotection, oxidation, and N-acetylation sequence was achieved as described for II.39 to afford II.40 in 66% yield over four steps. The preparation of tetrasaccharide II.41 is outlined in Scheme 15. Boron trifluoride etherate mediated glycosylation of II.51 with imidate II.46 produced the corresponding trisaccharide (88%), which was readily converted to the glycosyl acceptor II.53 upon removal of the allyloxycarbonyl group. Under TMSOTf-catalyzed
Scheme 15
The Ogawa synthesis of the HA tetrasaccharide.
Synthesis of Glycosaminoglycans
441
conditions, acceptor II.53 and imidate II.42 were coupled to produce the fully protected tetrasaccharide II.54 in 87% yield. De-isopropylidenation, acetylation, and delevulinoylation provided the diol II.55. Conversion of II.55 into target tetrasaccharide II.41 was performed as described for the di- and trisaccharides. As demonstrated by Ogawa and coworkers, the preparation of HA oligosaccharides can be achieved in a stereocontrolled and high-yielding manner (80–90% yield). Although requiring two steps, the Swern oxidation is consistently high yielding, thereby demonstrating its utility over other types of oxidation that occasionally lead to low yields and mixtures of products. Danishefsky’s iodosulfonamidation methodology offers an alternate route to 2deoxy-2-amino functionalized sugars, although the reported use of N-protecting groups is limited to benzenesulfonamides. Carter and coworkers demonstrated the use of this methodology in the construction of the protected (1,4)-HA disaccharide (Scheme 16) [14]. Glycosylation of iodosulfonamide II.56 and II.57 in the presence of lithium tetramethylpiperidide (LTMP) and silver triflate (AgOTf) afforded disaccharide II.58 in 51% yield. Subsequent removal of the 4-methoxybenzyl ether with CAN followed by Jones oxidation of C6 and esterification with CH2N2 produced II.59 in 43% overall yield. However, all attempts to remove the benzenesulfonyl and benzyl protecting groups to yield the target disaccharide resulted in incomplete deprotection and/or decomposition. The problems associated with the deprotection of II.59 prompted the use of an alternate glycosyl donor, II.60 [57]. The use of II.61 eliminates the need to oxidize C6 after glycosylation. Moreover, II.61 incorporates a phthalamide as the N-protecting group, which is more easily removed. Glycosylation of II.60 and II.61 was carried out in the presence of AgOTf and sym-collidine [58] at ⫺30⬚C and, upon warming to room temperature, provided the protected disaccharide II.62 in 94% yield. Hydrogenolysis with 30% Pd/C afforded 75% of diol II.63. Unfortunately, removal of the tert-butyl ester with formic acid produced, in addition to II.64, an unidentified side product that could not be removed. Glycosylation of II.60 with alternate acceptor II.57 via AgOTf and sym-collidine afforded the corresponding
Scheme 16
The Carter synthesis of the (1,4)-HA disaccharide.
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disaccharide that could be purified only after removal of the 4-methoxybenzyl ether to give II.65 (Scheme 17). Jones oxidation followed by esterification with diazomethane provided II.66 in 58% yield. Complete deprotection and N-acetylation were achieved in four steps and 52% overall yield to give the target disaccharide II.67. Although the final published route of II.67 by Carter and coworkers utilized classic glycosylation methodology, their prior synthetic approach involving the iodosulfonamidation methodology demonstrates its own utility in effecting glycosidic bond formation. Unfortunately, the subsequent deprotection of the aromatic sulfonamides usually requires strongly reducing conditions that are incompatible with other functionalities on the GAG backbone. Deprotection of II.59 with Na0/NH3 led to less than 10% of the amine, while the majority of the resulting mass balance consisted of decomposed monomer fragments. It is apparent that the success of Danishefsky’s iodosulfonamidation methodology in GAG synthesis depends on the ability to remove the benzenesulfonamide group under mild conditions. Vedejs and Lin reported the use of SmI2 for the deprotection of arenesulfonamides, citing excellent yields without epimerization [59]. Based on these results, Hill and coworkers investigated the application of SmI2mediated deprotection of arylsulfonamides in the N-tosyl-2-deoxy-2-amino- and Nsulfonyl-2-deoxy-2-amino-glycosides, II.68 and II.58, made by the iodosulfonidation methodology (Scheme 18) [23]. Synthesis of the protected (1,4)-hyaluronan disaccharide II.58 was achieved as previously reported in 38% yield and the protected (1,3)-hyaluronan disaccharide II.68 was prepared by condensation of II.56 and II.69 in the presence of LTMP and AgOTf in 82% yield. Cleavage of the N-sulfonyl bond to the corresponding free amines (II.70 and II.71), achieved by using SmI2 and 1,3-dimethylpropyleneurea (DMPU), occurred in 48 and 60% yield, respectively. These reductions took longer than those reported by Vedejs (2–3 days vs. 24 h) and, in general, the phenyl sulfonamides are reduced more quickly than the corresponding tosylamides. Fukuyama and coworkers have found 2- and 4-nitrobenzenesulfonamides to be efficient N-protecting groups for both primary and secondary amines, undergoing facile deprotection with thiophenol or mercaptoacetic acid [60]. These sulfonamides may find utility in GAG synthesis as N-protecting groups. The preparation of the largest synthesized fragments of HA was reported by Blatter and Jacquinet [21]. The tetra- (II.72), hexa- (II.73), and octasaccharides (II.74) were prepared, with each fragment containing a methyl -D-glucopyranosi-
Scheme 17
Deprotection sequence to the (1,4)-HA disaccharide.
Synthesis of Glycosaminoglycans
Scheme 18
443
Iodosulfonamidation and deprotection with SmI2.
duronic acid residue at the reducing end. The approach differs from the earlier preparations of HA in that a direct coupling at C4 of D-glucuronic acid derivatives was used. The poor nucleophilicity of the coupling units was offset by the efficiency of the trichloroacetimidate glycosylation methodology. The synthesis of targets II.72, II.73, and II.74 was achieved from precursors II.75, II.76, and II.77, which were, in turn, constructed from disaccharide units II.78 and II.79 (Scheme 19). The key to this strategy was the synthesis of a common dimeric building block, II.80, which could be converted into both the glycosyl donor (II.78) and the acceptor (II.79). Disaccharide II.80 was obtained by coupling glycosyl donor (II.81) and acceptor (II.82) in the presence of TMSOTf (89% yield). Conversion of II.80 into imidate II.78 was achieved by removal of the 4-methoxyphenyl group with CAN to form the hemiacetal, followed by treatment with trichloroacetonitrile and DBU. Disaccharide II.78 was converted into the corresponding methyl glycoside (II.83) by condensation with methanol; however, the reaction proved to be irreproducible (60–90% yield). Consequently, an alternate acceptor (II.84) was employed and glycosylated with imidate II.81 to give disaccharide II.83 in 91% yield (Scheme 20). Removal of the chloroacetate (ClAc) group with thiourea provided acceptor II.79 in 96% yield. With II.78 and II.79 in hand, condensation in the presence of TMSOTf produced the tetrasaccharide II.75 in 87% yield. Removal of the trichloroacetyl group gave tetrasaccharide II.85. Further glycosylation of II.85 with imidate II.78, as described for the preparation of II.75, afforded the hexasaccharide derivative II.76 in 93% yield. Subsequent deprotection of II.76 gave alcohol II.86, which could be further condensed with imidate II.78 to afford octasaccharide II.77 in 93% yield, which upon dechloroacetylation gave II.87. Deprotection of II.85, II.86, and II.87 was carried out as follows. Conversion of the N-trichloroacetyl groups to the corresponding N-acetyl groups was achieved by treatment with tributylstannane and azoisobutylnitrile (AIBN) to give the corre-
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Scheme 19
Retrosynthesis of the tetra-, hexa-, and octasaccharides of HA.
Scheme 20
Preparation of the tetra-, hexa-, and octasaccharides.
Synthesis of Glycosaminoglycans
445
sponding acetamides II.88–II.90 in 88, 91, and 92% yield, respectively. Treatment of II.88–II.90 with aqueous acetic acid followed by saponification with aqueous sodium hydroxide afforded the target oligosaccharides II.72–II.74 , as their sodium salts in 80–83% overall yields. Pursuing our interest in probing the intramolecular hydrogen bonding network and the bond mobilities of the glycosidic linkages in hyaluronan, our group synthesized two complementary HA trisaccharides, II.91 and II.92 (Fig. 3) [61]. These trisaccharides represent the smallest fragments that contain all the structural features of polymeric hyaluronan. The synthesis of II.91, having N-acetylglucosamine at the reducing end, required the use of monomers II.93, II.94, and II.95 (Scheme 21). Condensation of sulfoxide II.93 and II.94 in the presence of Tf2O produced the corresponding (1,3)disaccharide II.96. Selective ring opening of the 4-methoxybenzylidene with sodium cyanoborohydride and TFA [62] revealed the 4-OH; however, all attempts to glycosylate the resulting alcohol with imidate II.95 were unsuccessful. Presumably the steric bulk of the pivaloyl ester at C3 in addition to the low reactivity of the 4-OH precluded the formation of the glycosidic bond. Alternatively, disaccharide acceptor II.97 could be readily obtained from II.96 by conversion of the pivaloyl esters to benzyl ethers followed by regioselective ring opening to reveal the 4-OH. Subsequent glycosylation of II.97 with imidate II.95, using TMSOTf as a catalyst, provided the fully protected trisaccharide II.98 in 86% yield. Reduction of both the trichloroethoxycarbonyl (troc) carbamate and the azide and subsequent conversion to the corresponding acetamido groups was carried out in one pot by treatment with cadmium dust in acetic acid/DMF [63], followed by reduction of the azide with thiol acetic acid (Scheme 22). Subsequent treatment with acetic anhydride provided the diacetamido derivative II.99 in 60% yield over three steps. Removal of the p-methoxybenzyl ether followed by oxidation of C6, using a catalytic amount of 2,2,6,6tetramethyl-1-piperidinyloxy (TEMPO) in the presence of sodium hypochlorite [64] (NaOCl), provided the fully functionalized trisaccharide (II.100) in 51% yield over two steps. Finally, hydrogenolysis using Pearlman’s catalyst followed by saponification with lithium hydroxide provided the target trisaccharide II.91 in 13 steps and 16% overall yield. The complementary trisaccharide, II.92, having glucuronic acid at the reducing end, was prepared from monomers II.95, II.101, and II.102 (Scheme 23). Condensation of methyl glycoside II.99 with imidate II.95, using TMSOTf as a catalyst, afforded the corresponding disaccharide II.103 in 93% yield. Saponification of II.103 followed by benzylidenation provided disaccharide acceptor II.104. However, saponification under Zemple´n conditions (methanolic sodium methoxide) resulted in the conversion of the troc group to the corresponding methyl carbamate. Consequently, a milder deacetylation method that used a guanidine/guanidinium nitrate solution [65] was adopted, and near-quantitative deacetylation was achieved in 20 min. Condensation of II.104 with the glycosyl donor II.102 with TMSOTf provided the fully protected trisaccharide II.105 in 87% yield. Reduction of the troc carbamate to the free amine was accomplished with cadmium in AcOH/DMF followed by acetylation to provide II.106. Removal of the p-methoxybenzyl ether and subsequent saponification yielded the pentaol, II.107 (Scheme 24).
446
Figure 3
The shortest HA fragments that contain structural features of polymeric HA.
Yeung et al.
Synthesis of Glycosaminoglycans
Scheme 21
Preparation of the HA trimer with N-acetylglucosamine at the reducing end. 447
448
Yeung et al.
Scheme 22
III.
The deprotection sequence for the HA trimer.
CHONDROITIN SULFATE
Chondroitin sulfates occur in tissues attached to proteoglycans and form a family of polysaccharides that differ in the degree and position of sulfation. Cartilage and the intervertebral disc contain the highest concentration: as much as 10% of the wet weight can be due to chondroitin sulfate [66]. Chondroitin sulfate is a repeating copolymer of D-glucuronic acid (GlcUA) and 4-O- or 6-O-sulfated 2-acetamido-2deoxy-D-galactose (GalNAc). Three different sulfated variants of chondroitin are known: the 4-O-sulfated, the 6-O-sulfated, and the 4,6-di-O-sulfated variants (Fig. 4). Several strategies have been developed and implemented to synthesize various oligomers of chondroitin sulfate. Jacquinet reported the synthesis of the methyl glycosides of chondroitin disaccharides (III.1, III.2, III.7, and III.8), which represent the four possible repeating units of chondroitin 4-O- and 6-O-sulfate [20]. The 4-O-sulfate (III.1) and 6-O-sulfate (III.2) of methyl 2-acetamido-2-deoxy3-O-(-D-glucopyranosyluronic acid)-(1,3)--D-galactopyranoside were obtained by condensation of glycosyl acceptors III.3 and III.4 with donors III.5 and III.6 (Scheme 25). The corresponding (1,4)-linked disaccharides III.7 and III.8 were obtained by condensation of glycosyl donors III.9 or III.10 and III.11 or III.12 with acceptors III.13 and III.14 (Scheme 26). The design of monomer building blocks for sulfated GAGs requires that the 4-OH and 6-OH of the galactosamine unit be orthogonally protected to facilitate regiospecific monosulfation. This resulted in the need for an increased number of protecting group transformations. Glycosyl acceptors III.3 and III.4, used in the preparation of the (1,3)-disaccharides, were obtained from methyl 2-azido-2-deoxy--D-galactopyranoside [67]. Selective 3,6-di-O-silylation followed by treatment with benzyl bromide led to the installation of the benzyl ether at C4. Desilylation occurred in situ under the benzylation reaction conditions to produce III.15 and subsequent 6-O-acetylation of III.15 with 1-acetylimidazole produced III.3 in 78% yield (Scheme 25). The preparation of III.4, carried out as reported earlier by Jacquinet and Sina¨y [67], was obtained from III.16 by regioselective ring opening of the isopropylidene to unmask the 3-OH. Glycosyl donors III.5 and III.6 were derived from the corresponding acetylated derivative III.17. Treatment of III.17 with dibutyltin oxide [68] afforded the hemi-
Synthesis of Glycosaminoglycans
Scheme 23
Preparation of the HA trimer with glucuronic acid at the reducing end.
449
450
Scheme 24
Yeung et al.
The deprotection sequence of the HA trimer.
acetal, which was then converted to the corresponding -imidate III.5. Alternative treatment of III.17 with hydrogen bromide gave the glycosyl bromide III.6. Condensation of III.3 with III.5 by means of TMSOTf gave III.18 (75% yield) as the precursor to the 4-O-sulfated chondroitin disaccharide. Similarly, condensation of III.3 with III.6 by means of AgOTf as a promoter also afforded III.18 in 90% yield. The disaccharide precursor to the 6-O-sulfated chondroitin disaccharide (III.19) was also obtained by the use of either glycosyl donor. Glycosylation of III.4 with imidate III.5 or bromide III.6 gave the desired disaccharide III.19 in 72 or 80% yield, respectively. Interestingly, for these specific substrates, the Koenigs– Knorr glycosylations for the preparation of III.18 and III.19 proceeded in higher yield than the corresponding trichloroacetimidate glycosylations.
Figure 4
The four possible repeating units of chondroitin sulfate.
Synthesis of Glycosaminoglycans
Scheme 25
The Jacquinet synthesis of the 4- and 6-O-sulfated chondroitin disaccharides.
451
452
Scheme 26
Yeung et al.
Azidonitration for the preparation of chondroitin sulfate disaccharides.
Simultaneous reduction of the benzyl ethers and the azide proved unsatisfactory in the presence of methyl esters. An alternate procedure utilized thioacetic acid to reductively N-acetylate the azide. Thus, treatment of III.18 and III.19 with thioacetic acid afforded the corresponding 2-deoxy-2-acetamido derivatives III.20 and III.21, respectively. Hydrogenolysis followed by sulfation with the sulfur trioxide–trimethylamine complex gave the corresponding 4- and 6-O-sulfated disaccharides III.22 and III.23. Final saponification of III.22 and III.23 with aqueous sodium
Synthesis of Glycosaminoglycans
453
hydroxide in methanol gave the target disaccharides III.1 and III.2 in 83 and 86 yield, respectively. Four different galactosamine imidate donors were designed and used in the preparation of the target (1,4)-linked disaccharides. These glycosyl donors, III.9– III.12, were all prepared by azidonitration of D-galactal (Scheme 26). Selective 3,6di-O-tert-butyldimethylsilylation of D-galactal followed by treatment with methoxyethoxymethyl chloride (MEMCl) and benzyl bromide gave III.24. Azidonitration of III.24 proceeded cleanly, and the product was subsequently converted to the corresponding hemiacetal III.25 with sodium nitrite [69]. The 4-(2-methoxyethoxymethyl) group in III.25 was replaced by an acetate group by treatment with aqueous TFA followed by acetylation. Subsequent l-O-deacetylation with benzylamine [70] gave III.26. Conversion of III.25 and III.26 to the corresponding imidates III.9 and III.10 was achieved in the usual manner. Similarly, preparation of the 6-O-sulfated galactosamine donors III.11 and III.12 utilized the selective 6-O-silylation of D-galactal followed by benzylation to afford alcohol III.27. Subsequent treatment with either MEMCl or benzoyl chloride provided the corresponding galactal derivative, III.28 or III.29. Azidonitration followed by hydrolysis to the hemiacetal and conversion into the corresponding trichloroacetimidate afforded donors III.11 and III.12. Glycosyl acceptors III.13 and III.14 were obtained by 6-O-selective chloroacetylation and tert-butyldimethylsilylation of methyl 2,3-di-O-benzyl--D-glucopyranoside, respectively. Glycosylations involving acceptors III.9–III.12 and donors III.13 and III.14 were carried out by using BF3⭈Et2O as a promoter and are summarized in Table 2. Most coupling products could be isolated only after deprotection of the 6-OH on the glucose unit. The reported yields for the glycosylations and the stereoselectivity of the (1,4)-linkages are moderate, at best. Lower selectivities observed may be due to the lack of a participating group at C2 on the glycosyl donors. Of the four different disaccharides prepared, only the deprotection/oxidation sequence of disaccharides III.32 and III.34 led to targets III.7 and III.8, respectively. All attempts at removing the methyl ether protecting groups in disaccharides III.31 and III.33 were unsuccessful. Preparation of the target disaccharide III.7 is described as follows. Transformation of azide III.32 to the N-acetate III.35 was achieved in 81% yield by sodium
Table 2
Glycosylation Conditions for the Chondroitin Disaccharides
Donor
Acceptor
Solvent
Product
Yield (%)
␣/ Ratio
III.9 III.9 III.9 III.10 III.10 III.11 III.11 III.12 III.12 III.12
III.13 III.13 III.14 III.13 III.14 III.13 III.14 III.13 III.14 III.14
1,2-Dichloroethane Toluene Toluene Toluene Toluene Toluene Toluene Toluene 1,2-Dichloroethane Toluene
III.31 III.31 III.31 III.32 III.32 III.33 III.33 III.34 III.34 III.34
30 66 40 50 65 35 32 40 32 60
1:6 1:10 1:9 1:3 1:20 2:3 1:3 2:3 1:8 1:11
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Yeung et al.
borohydride reduction followed by N-acetylation. Oxidation of the primary alcohol with pyridinium dichromate followed by saponification then gave III.36. Sulfation of the 4-OH on galactosamine as described above, and subsequent catalytic hydrogenation (Pd/C) afforded the target disaccharide III.7. The 6-O-sulfated derivative III.8 was prepared from disaccharide III.34, where oxidation followed by esterification with diazomethane gave the methyl ester III.37. Reductive N-acetylation, saponification, and sulfation produced derivative III.38, and subsequent hydrogenation afforded the target disaccharide III.8. More recently, Ogawa and coworkers have prepared 4-O-sulfated chondroitin di- and tetrasaccharides fragments that allow for chain elongation by the condensation of a dimeric repeating unit [71]. The key intermediate used for chain elongation was the (1,4)-disaccharide III.39, which was prepared from monomer building blocks III.40 and III.41 (Scheme 27). The glycosylations were carried out by using the trichloroacetimidate methodology with BF3⭈Et2O as the promoter. Condensation of III.40 and III.41 afforded the corresponding disaccharide III.42. To aid in purification, the tert-butyldimethylsilyl group was removed by subsequent treatment of the crude disaccharide with tetrabutylammonium fluoride and acetic acid to give III.43 [72]. Oxidation of C6 to the methyl ester by means of a Swern oxidation [73] followed by esterification with diazomethane produced the key intermediate III.39 in 96% yield over three steps. Disaccharide III.39 could then be transformed into both glycosyl donor III.44 and glycosyl acceptor III.45 (Scheme 28). Treatment of III.39 with cerium ammonium nitrate gave the corresponding hemiacetal, which was easily converted to the ␣-imidate III.44 in 95% yield. Conversion of III.39 to III.45 was achieved quantitatively by simple removal of the levulinoyl group with hydrazine acetate [74]. With III.44 and III.45 in hand, glycosylation furnished the fully protected tetrasaccharide III.46 in 50% yield.
Scheme 27
The key intermediate in the Ogawa synthesis of chondroitin sulfate derivatives.
Synthesis of Glycosaminoglycans
Scheme 28
Preparation of the tetrasaccharide of chondroitin sulfate.
455
456
Scheme 29
Yeung et al.
Deprotection and sulfation of the tetrasaccharide.
Deprotection and sulfation was achieved by reduction of the azide to the corresponding acetamide with thioacetic acid [75] to afford III.47 (Scheme 29). Subsequent de-levulinoylation followed by acetylation gave III.48 in 64% yield over two steps. Reductive opening of the bisbenzylidene acetals with sodium cyanoborohydride and acid [76] afforded III.49 in 51% yield and by-product III.50, formed by acetyl migration from C3 to C4 (31%). Sulfation of III.49 was carried out with the sulfur trioxide–trimethylamine complex to give III.51 in 92% yield. Deacetylation followed by hydrogenolysis provided the target tetrasaccharide III.52. The preparation of the disaccharide III.53 from III.45 was achieved in a similar manner (Scheme 30). Transformation of the azide to the corresponding acetamide was carried out with thioacetic acid. Acetylation and reductive opening of the benzylidene unblocked the 4-OH to give III.54. Sulfation, de-esterification, and hydrogenolysis afforded the target 4-O-sulfated disaccharide III.53 in 67% yield over three steps. In 1998 Ogawa and coworkers revisited the synthesis of chondroitin sulfate and prepared the di-, tri-, and tetrasaccharides in their nonsulfated, 4-O-sulfated, 6O-sulfated, and 4,6-di-O-sulfated forms (Fig. 5). As before, disaccharide III.39 was used as the primary building block for chain elongation.
Scheme 30
Preparation of the chondroitin sulfate disaccharide.
Synthesis of Glycosaminoglycans
Figure 5
Chondroitin sulfate derivatives prepared by Ogawa and coworkers.
457
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Yeung et al.
Chondroitin disaccharides III.56–III.59 were prepared by conversion of the azide in building block III.39 to the acetamide, which was achieved with thioacetic acid. Complete deprotection then afforded the nonsulfated disaccharide III.56. An exchange of the levulinoyl group in III.39 for the pivaloyl group to produce III.60 was utilized for the preparation of the sulfated variants (Scheme 31). Conversion of the azide to the acetamide (III.61) followed by regioselective benzylidene ring opening gave III.62. Subsequent sulfation (71%), saponification, and hydrogenolysis (88% in two steps) gave the target chondroitin 4-sulfate disaccharide (III.57). The corresponding 6-O-sulfated derivative (III.58) was prepared as follows. Starting from disaccharide III.62, acetylation followed by hydrogenolysis unmasked the 6-OH to give the corresponding alcohol with no acetate migration observed. Subsequent sulfation and saponification afforded III.58 in 87% yield over three steps. Quantitative preparation of the 4,6-di-O-sulfated disaccharide III.59 was achieved by treatment of the diol III.63 with the sulfur trioxide–trimethylamine complex. Alternatively, sulfation of III.62 followed by hydrogenolysis unmasked the 6-OH and subsequent sulfation provided III.59 in 71% yield. Chondroitin trisaccharides III.64–III.67 were obtained by coupling the disaccharide acceptor III.45 with methyl glucuronate trichloroacetimidate III.68 [77] in the presence of BF3⭈OEt to give the corresponding trisaccharide III.69. The azide was transformed into the corresponding acetamide III.70 by Lindlar reduction followed by acetylation (Scheme 32). Hydrogenation was favored over the use of thioacetic acid as it generally gave higher yields for oligomers larger than the disaccharide. Acid hydrolysis of the benzylidene acetal followed by saponification gave the nonsulfated trisaccharide (III.64). The 4-O-sulfated derivative (III.65) was prepared by reductive ring opening of III.70 to provide the 6-O-benzyl derivative III.71 in 69% yield with formation of 12% of the 4-O-benzylated product. Sulfation of the free 4-OH, saponification, and hydrogenolysis furnished the 4-O-sulfated trisaccharide III.65. The same synthetic strategy used to prepare the 6-O-sulfated disaccharide was applied to the corresponding trisaccharide. Acetylation of III.71 followed by hydrogenolysis afforded the primary alcohol III.72. Subsequent sulfation and saponification gave the target 6-O-sulfated trisaccharide III.66. The 4,6-di-O-disulfate (III.67) could not be obtained directly from the 4,6-diol. Consequently, hydrogenolysis of the 4-O-sulfated derivative III.73 unmasked the 6-OH, which was then sulfated to give target III.67 after saponification. The prolonged reaction time required for O-sulfation of the 6-OH (6 days, 71% yield) was attributed to the electronegativity of the neighboring sulfate. Tetrasaccharide derivatives (III.74–III.77 ) incorporate an internal and a terminal D-galactosamine residue with varying degrees of sulfation. The strategy for selective sulfation was identical to that used for the di- and trisaccharides. The tetrasaccharides were derived from the fully protected derivatives III.46 (Scheme 33). Reduction of the azides to the corresponding acetamides with thioacetic acid gave III.78 in 43% yield. As with the trisaccharides, higher yields were obtained when the azide was reduced in two steps: hydrogenation with Lindlar catalyst followed by acetylation (60% yield). Saponification of III.78 (88%), followed by hydrogenolysis (68%), gave the target nonsulfated tetrasaccharide III.74. The 4-O-sulfated derivative III.75 was obtained by first converting the levulinoyl ester into the corresponding privaloate, followed by regioselective opening of the benzylidene to give the desired secondary diol (III.79) in 65% yield, as well as a small amount of the 4-O-benzylated
Synthesis of Glycosaminoglycans
Scheme 31
The disaccharide synthesis. 459
460
Scheme 32
The trisaccharide synthesis. Yeung et al.
Synthesis of Glycosaminoglycans
Scheme 33
461
The tetrasaccharide synthesis.
regioisomer (15%). No acyl migration was observed when the pivaloyl ester was substituted for the corresponding acetate. Sulfation of the 4-OH, saponification, and hydrogenation furnished III.75 in 70% yield. When the regioselective sulfation of the tetraol III.80 was attempted for the chondroitin 6-sulfate tetrasaccharide, it proceeded slowly, yielding a single product after 2 days that was identified as the tetrasulfated derivative III.77. Therefore, the 6-O-sulfated derivative was obtained stepwise by acetylation of III.79 followed by hydrogenation of the two 6-O-benzyl ethers to afford the corresponding diol. Conventional sulfation and saponification afforded III.76 in 82% yield over three steps. Chondroitin differs from hyaluronan in two ways: the presence of sulfate esters and the configuration of the amino sugar (i.e., D-galactosamine instead of D-glucosamine). Since D-galactosamine is a rare and expensive starting material, it is usually prepared by the azidonitration of D-galactal as demonstrated in the earlier preparations of chondroitin and dermatan fragments. An alternate way of accessing D-galactosamine is by inversion of C4 in D-glucosamine, and indeed such conversions have been reported for both monomers [78] and neutral disaccharides [79] containing D-glucosamine. Coutant and Jacquinet used this approach to access saccharides con-
462
Yeung et al.
taining uronic acid moieties and reported the preparation of chondroitin 4-O-sulfate trisaccharide III.81 from the hyaluronic acid trisaccharide III.82 (Scheme 34) [80]. A trisaccharide derivative, in which the central D-glucosamine residue is flanked by two D-glucuronic acid residues, was chosen to test the validity of the strategy. Construction of the protected hyaluronic acid trisaccharide was achieved from the following monosaccharides: III.83, III.84, and III.85. The glucuronic acid precursor III.85 was glycosylated with glucosamine moiety III.84 by using N-iodosuccinamide (NIS) and trimethylsilyl triflate in dichloromethane to afford the corresponding disaccharide III.86 in 90% yield. In general, uronic esters are poor nucleophiles when glycosylation is at the C4 position. Presumably the ester moiety significantly reduces the nucleophilicity of the 4-OH, and as a result, necessitates the use of a D-glucose unit, where the C6 is selectively oxidized after coupling. Conversion of disaccharide III.86 into glycosyl acceptor III.87 was achieved in 92% yield by removal of the chloroacetyl ester with thiourea in pyridine–ethanol. Condensation of acceptor III.87 with imidate III.83 in the presence of trimethylsilyl triflate afforded the crystalline trisaccharide III.88 in 92% yield. Removal of the isopropylidene with aqueous acid followed by selective benzoylation of C6 gave III.82 (90%, two steps). Inversion of the configuration at C4 was carried out by treatment of III.82 with triflic anhydride in pyridine to form the 4-O-triflyl derivative followed by reaction with tetrabutylammonium nitrite, a reagent known to give the epi-hydroxyl analog [81], to afford the D-galacto product III.89 in 87% yield (Scheme 35). Transformation of the N-trichloroacetyl group to the acetamide was carried out with tributylstannane and azoisobutyronitrile [82] to give the crystalline acetamide III.90 in 92% yield. Sulfation of the free hydroxyl with the sulfur trioxide–trimethylamine complex gave 93% of III.91, which was saponified with sodium hydroxide in aqueous methanol to afford the target chondroitin 4-O-sulfate trisaccharide III.81 in 87% yield. While the syntheses of derivatives of the chondroitin sulfate disaccharides dominate the existing literature, Jacquinet and coworkers have reported the successful syntheses of the reducing disaccharides of chondroitin 4- and 6-sulfates on a multigram scale [83]. The synthetic sequence (Scheme 36) utilizes a silver triflate mediated glycosylation between bromide III.92 and benzyl glycoside III.93 to afford the disaccharide III.94 in 70% yield. After treatment with hot aqueous acetic acid, diol III.95 was obtained in 87% yield. The strategic choice of functionality in this common intermediate minimizes the number of postglycosylation transformations. Regioselective benzoylation of diol III.95 was achieved in 93% yield by treatment with benzoyl cyanide in pyridine. Consequent O-sulfation with the sulfur trioxide– trimethylamine complex followed by ion exchange chromatography afforded the sodium salt III.96 in 90% yield. Saponification of III.96 with lithium hydroperoxide and methanolic sodium hydroxide provided the disodium salt III.97 in 83% yield, which was subsequently subjected to hydrogenolysis to afford the chondroitin 4sulfate disaccharide III.98 in 97% yield. Preparation of chondroitin 6-sulfate from the common intermediate III.95 was achieved by regioselective sulfation at C6 with the sulfer trioxide–trimethylamine complex. The resulting monosulfated disaccharide III.99 was isolated in 90% yield. Saponification to the disodium salt III.100 occurred in 82% yield, and subsequent hydrogenolysis provided the chondroitin 6-sulfate disaccharide III.101 in 96% yield.
Synthesis of Glycosaminoglycans
Scheme 34
The use of C4 inversion in the preparation of the chondroitin sulfate trimer.
463
464
Scheme 35
The use of C4 inversion in the preparation of the chondroitin sulfate trimer.
Yeung et al.
Synthesis of Glycosaminoglycans
Scheme 36
Multigram-scale synthesis of chondroitin sulfate disaccharides.
465
466
Scheme 37
The combinatorial approach for chondroitin sulfate derivatives.
Yeung et al.
Synthesis of Glycosaminoglycans
Scheme 38
467
The combinatorial approach for chondroitin sulfate derivatives.
Recognizing the need for the facile generation of chondroitin sulfate disaccharides with varying sulfation patterns, Lubineau and Bonnaffe´ recently reported the use of a combinatorial approach to access eight chondroitin sulfate disaccharides (III.102 and III.103) from the key chondroitin sulfate disaccharide scaffold (III.104) bearing orthogonal protecting groups [84]. The synthesis of key disaccharide III.104 (Scheme 37) was achieved by the TMSOTf-mediated glycosylation of acceptor III.105 with trichloroacetimidate III.106 to produce disaccharide III.107 in 74% yield. Following methanolysis of the acetal- and stannylene-promoted alkylation, the disaccharide III.108 was obtained. Inversion of the configuration of C4 was achieved by Swern oxidation followed by K Selectride reduction, providing the galacto counterpart III.104, illustrating this inversion method as an effective alternative to triflate displacement. Orthogonal protecting group manipulations at C4 and C6 of benzyl glycoside III.104 followed by sulfation led to the four different sulfoforms III.109, consisting of the unsulfated, two mono-O-sulfated, and the di-O-sulfated derivatives (Scheme 38). These disaccharides were then hydrolyzed and fully deprotected to give the four sulfoforms III.102, which are unsulfated at the C2 position of the glucose moiety. Alternatively, sulfoforms III.109 were deprotected and sulfated at the C2 position of the glucose moiety prior to deprotection to afford the other four sulfoforms III.103. This combinatorial split-and-pool approach represents a powerful route to the preparation of sulfoforms of a given oligosaccharide. Additionally, it illustrates the use of O-sulfate esters as base and low-temperature, acid-stable protecting groups. IV.
DERMATAN SULFATE
Dermatan sulfate is an O-sulfated glycosaminoglycan first isolated from pigskin [85]. Structurally related to chondroitin, in that repeating disaccharide units consist of Dglucuronic acid and N-acetylgalactosamine, dermatan sulfate incorporates the C5 epimer of D-glucuronic acid, L-iduronic acid, in addition to N-acetylgalactosamine. Position and degree of sulfation are dependent on the source [86], but in general, the D-galactosamine residues are mainly sulfated at C4 and the adjacent L-iduronic
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residue can be sulfated or not. Dermatan sulfate possesses anticoagulant, profibrinolytic, and antithrombotic properties. Although dermatan sulfate does not directly inhibit thrombin, it accelerates heparin cofactor II (HCII) mediated inhibition of the thrombin [87]. The antithrombin activity of dermatan sulfate has been narrowed down to a binding domain on HCII. Biological activity could be induced with a hexasaccharide of dermatan sulfate [88] and, more recently, a nonasaccharide [89]. Since dermatan sulfate is a hybrid polymer comprising two types of disaccharide unit, N-acetylchondrosine and N-acetyldermosine (Fig. 6), the heterogeneity of the polymer complicates biological studies that use smaller fragments as probes. Moreover, the smaller fragments generally have a lower activity with respect to the parent polymeric dermatan sulfate [87], and the longer plyanionic chains are required for the formation of the ternary complex with thrombin. Fragments of dermatan that sulfate have been synthesized include the methyl glycoside derivatives of the basic monosulfated disaccharide, a hexasaccharide containing three disulfated residues and most recently, a basic disulfated disaccharide. Jacquinet and Sina¨y have reported the preparation of the methyl -glycosides of dermatan sulfate fragments starting from D-galactal and the readily available 1,6anhydro--L-idopyranose [90]. This report described the syntheses of disaccharides IV.22, IV.23, and IV.26 (see below: Schemes 41 and 42) and the determination of their anomeric configurations by 1H NMR spectroscopy. In addition, the syntheses of the target monosaccharides IV.7, IV.10, and IV.11 (Scheme 39), which differ in the position and degree of sulfation, were described and their observed NMR signals were used to constitute a firm basis for the structural assignment of the target disaccharides. The model monosaccharides just listed were prepared from common precursor IV.1 (Scheme 39), which was readily obtained by azidonitration of 3,4,6-tri-O-acetylD-galactal followed by deacetylation with sodium methoxide. Treatment of IV.1 with acetone and toluene p-sulfonic acid monohydrate at room temperature led to predominant formation of the thermodynamically favored 3,4-O-isopropylidene (IV.2) in 61% yield while also producing 27% of the 4,6-O-isopropylidene derivative IV.3. The position of the isopropylidene IV.2 was verified by the use of NMR chemical shift analysis to confirm the position of the acetate group in the resultant acetylated adduct IV.4. Synthesis of the 4-O-sulfate derivative (IV.7) from IV.2 utilized a step that differentiated the 3-OH and 4-OH positions: after benzylation and de-isopropylidination of IV.2, a selective methylation at the 3-OH of diol IV.5 was achieved via a tin procedure [91] to give methyl glycoside IV.6. Conversion of the azide into
Figure 6
Typical disaccharide units that comprise dermatan sulfate.
Synthesis of Glycosaminoglycans
Synthesis of the dermatan sulfate monosaccharides.
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Scheme 39
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an acetamido group followed by O-sulfation with sulfur trioxide–trimethylamine and subsequent removal of the benzyl ether afforded the desired sulfate IV.7 as its sodium salt. Alternatively, kinetic isopropylidination of IV.1 was demonstrated, using 2methoxypropene in dimethylformamide and toluene-p-sulfonic acid monohydrate conditions to produce the 4,6-O-isopropylidene derivative IV.3 in 85% yield. Subsequent methylation of the 3-OH with methyl iodide followed by removal of the isopropylidene protecting group by treatment with aqueous 90% trifluoroacetic acid afforded crystalline IV.8. Catalytic hydrogenolysis (Pd/C) of IV.8 produced the corresponding amine, which was then N-acetylated to provide 90% of crystalline IV.9. Selective O-sulfation of the 6-OH on IV.9 with the sulfur trioxide–trimethylamine complex in dimethylformamide and subsequent ion exchange chromatography produced the crystalline sulfate IV.10 as its sodium salt in 86% yield. Complete 4,6-Osulfation occurred in the presence of excess sulfating agent to give the disulfate IV.11 in 85% yield. Construction of the L-idopyranosyluronic acid donor moiety began with the benzylation of 1,6-anhydro--L-idopyranose to give 1,6-anhydro-2,3,4-tri-O-benzyl-L-idopyranose (IV.12). Acetolysis of IV.12 with acetic anhydride–trifluoroacetic acid gave 91% of IV.13 (Scheme 40). Subsequent treatment of IV.13 with methanolic sodium methoxide provided 2,3,4-tri-O-benzyl-L-idopyranose, which was monochloroacetylated with chloroacetyl chloride to give IV.14 in 84% yield, as a 5:2 mixture of ␣ and  anomers. Addition of dichloromethane saturated with hydrogen chloride gave 90% of the corresponding chloride IV.15, which was immediately condensed with methyl 4-O-acetyl-2-azido-6-O-benzyl-2-deoxy--D-galactopyranoside (IV.16). Compound IV.16 was prepared by regioselective ring opening [92] of a methyl orthoester (prepared from IV.5 by treatment with trimethyl orthoacetate and toluene p-sulfonic acid monohydrate). The glycosylation was carried out in the presence of silver triflate and 2,4,6-trimethylpyridine and, following O-chlorodeacetylation, afforded 58% of the ␣-linked disaccharide IV.17 and 30% of the corresponding -linked disaccharide IV.18. Reduction of the azide in the ␣-linked disaccharide IV.17, by using sodium borohydride in the presence of nickel dichloride hexahydrate and boric acid, followed by N-acylation, gave IV.19 in 81% yield (Scheme 41). Oxidation of the 6-OH on the idopyranosyl moiety was achieved with chromium trioxide in acetone–sulfuric acid and gave, after deacetylation, the crystalline acid IV.20. The free acid was converted to the sodium salt and O-sulfated to afford IV.21 in 81% yield. Finally, catalytic hydrogenolysis (Pd/C) provided 83% of the target disaccharide of N-acetyldermosine (IV.22). Additionally, catalytic hydrogenolysis of IV.20 provided the nonsulfated analog IV.23 in 86% yield. Similarly, the -linked disaccharide IV.18 was converted to the corresponding N-acetylated disaccharide IV.24 (81%) followed by oxidation, deacetylation, and Osulfation to give IV.25 (Scheme 42). Catalytic hydrogenolysis resulted in IV.26 in 87% yield after purification. Sina¨y and coworkers explored different approaches to the synthesis of the Nacetyldermosine disaccharide (IV.22) that resulted in the report of an improved synthetic route [93]. The strategy investigated initially used diol IV.5 (as an alternative glycosyl acceptor to IV.16) that relied on regioselective glycosylation of the more reactive equatorial 3-OH. This would eliminate the need for a deprotection sequence
Synthesis of Glycosaminoglycans
Scheme 40
Synthesis of the dermatan sulfate disaccharides.
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Synthesis of N-acetyldermosine.
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Scheme 41
Synthesis of Glycosaminoglycans
Scheme 42
Synthesis of N-acetylchondrosine.
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prior to sulfation of the axial 4-OH. However, glycosylation of diol IV.5 with methyl (2,3,4-tri-O-acetyl-␣-L-idopyranosyl bromide) uronate [94] (IV.27) was reported to produce a low yield (16%) of desired disaccharide IV.28 (Scheme 43). The major product isolated (66%) was the intermediate orthoester IV.29 [95]. The presence of the vicinal 4-OH appeared to complicate the rearrangement of orthoester IV.29 into IV.28. All attempts to effect this rearrangement with tin tetrachloride were unsuccessful, and an alternate strategy was then employed. Glycosyl acceptor IV.30, obtained by benzylidenation of IV.1 with ␣,␣-dimethoxytoluene and camphorsulfonic acid in nitromethane, was used instead. Silver triflate mediated glycosylation of IV.30 with IV.27 in the absence of 2,3,4-trimethylpyridine afforded the disaccharide IV.31 in 54% yield. Alternatively, trimethylsilyl triflate promoted glycosylation of IV.30 with the ␣-trichloroacetimidate IV.32 (obtained from glycosyl bromide IV.27) gave an improved yield of the disaccharide IV.31 (68%). The 4-OH of the galactopyranoside unit was selectively unmasked [96] to give 70% of IV.28, and then O-sulfated to produce disaccharide IV.33 in 94% yield. Saponification of IV.33 with sodium hydroxide followed by catalytic hydrogenolysis and N-acetylation provided the target disaccharide (IV.22) as the disodium salt. Using the same synthetic approach, Sina¨y and coworkers also reported the synthesis of the second repeating copolymer of dermatan sulfate, N-acetylchondrosine (IV.37) (Scheme 44). Silver triflate mediated glycosylation of IV.30 with methyl(2,3,4-tri-O-acetyl-␣-D-glucopyranosyl bromide)uronate (IV.34) gave the corresponding disaccharide IV.35. Compound IV.35 was then converted to the target disaccharide (IV.37) as described above, in 60% overall yield. Ogawa and Goto reported the synthesis of a dermatan sulfate hexasaccharide (IV.38) that utilized trichloroacetimidate glycosylations in a regio- and stereocontrolled manner according to the retrosynthetic route shown in Scheme 45 [97]. The target hexasaccharide IV.38 is derived from benzyl-protected precursor IV.39, which is in turn derived from IV.40 through oxidation, N-acetylation, and sulfation. The central tetrasaccharide was constructed by the repeated use of the imidate disaccharide IV.42, and the nonreducing end and reducing end units utilized monosaccharides IV.41 and IV.43 [98], respectively. The preparation of glycosyl donors IV.41 and IV.42 is detailed in the corresponding reference. The linear synthesis of the hexasaccharide started at the reducing end by the TMSOTf-promoted glycosylation of IV.43 with trichloroacetimidate IV.42 to produce trisaccharide IV.44 in 86% yield (Scheme 46). Removal of the levulinoyl group with hydrazine acetate and coupling of the resultant glycosyl acceptor IV.45 with another unit of IV.42 in the presence of tert-butyldimethylsilyl triflate afforded the pentasaccharide IV.46 in 87% yield. Following de-levulinoylation of IV.46 to IV.47, the terminal L-idose moiety was installed by glycosylation of IV.47 with IV.41 in the presence of tert-butyldimethylsilyl triflate to afford 99% of the hexasaccharide IV.48. Regioselective ring opening of the benzylidene followed by acetylation gave precursor IV.40 in 64% overall yield. Transformation of IV.40 to IV.49 was achieved sequentially by treatment with thioacetic acid [99], deprotection [100], and subsequent Swern oxidation and esterification. Deacetylation and saponification of the methyl esters with sodium hydroxide afforded IV.50. Finally, sulfation with sulfur trioxide–triethylamine complex gave IV.39, which upon hydrogenolysis (Pd/C) produced the target hexasaccharide IV.38.
Synthesis of Glycosaminoglycans
Scheme 43
The Sina¨y synthesis of sulfated N-acetyldermosine.
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Scheme 44
The Sina¨y synthesis of sulfated N-acetylchondrosine.
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Synthesis of Glycosaminoglycans
Scheme 45
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The Ogawa synthesis of the dermatan sulfate hexasaccharide.
Most recently, Jacquinet and Rochepeau-Jobron reported the preparation of the disulfated ␣(1,3)-linked disaccharide (IV.51) of dermatan sulfate [see later-Scheme 48) [101]. Earlier approaches to the D-galactosamine moiety relied on azidonitration of D-galactal to introduce the 2-amino functionality. Here, Jacquinet and RochepeauJobron demonstrated the efficiency of using D-glucosamine derivatives as D-galac-
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The Ogawa synthesis of the dermatan sulfate hexasaccharide.
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Scheme 46
Synthesis of Glycosaminoglycans
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tosamine precursors. Benzyl D-galactosamine derivatives IV.54 and IV.56 were thus obtained by selective inversion of the configuration at C4 of the corresponding Dglucosamine analogs in a three-step sequence (Scheme 47). Treatment of benzyl 2acetamido-2-deoxy-␣-D-glucopyranoside IV.52 [102] with pivaloyl chloride afforded the 3,6-di-O-pivaloyl derivative in 87% yield. Treatment of the unblocked 4-OH with trifluoromethanesulfonyl anhydride and pyridine followed by addition of water and subsequent heating at 90⬚C produced the 3,6-di-O-pivaloyl-D-galactopyranosyl intermediate IV.53 [103]. Deacylation of IV.53 afforded the crystalline triol IV.54 in 72% yield over the three steps. The same approach was used to achieve conversion of the -D-glucopyranoside (IV.55) to the corresponding galactal (IV.56) in 75% overall yield. Standard protecting group manipulation of galactopyranosides IV.54 and IV.56 gave the respective glycosyl acceptors IV.57 and IV.58. Glycosylations of IV.57 and IV.58 using both the trichloroacetimidate IV.59 and the chloride IV.60 as L-iduronic acid donors demonstrated that the trichloroacetimidates are superior candidates for the anomeric activation of L-iduronic acid moieties to form the desired ␣-linked disaccharide (Scheme 48). Condensation of IV.57 with IV.59 in the presence of trimethylsilyl triflate afforded the ␣-linked disaccharide IV.61 in 63% yield and the -linked anomer IV.62 in 27% yield. Interestingly, glycosylation of IV.57 or IV.58 with chloride IV.60 in the presence of silver triflate afforded very slowly, but exclusively, the corresponding -linked disaccharides in 70 and 60% yield, respectively. O-Dechloroacetylation of IV.61 by treatment with thiourea gave IV.62, which was subsequently reprotected as the hydrogenolyzable 4-methoxybenzyl ether with 4-methoxybenzyl trichloroacetimidate and triflic acid under phase transfer catalysis conditions [104]. Saponification of the benzoate and methyl esters with lithium hydroperoxide followed by methanolic sodium hydroxide and acidification then gave the acid IV.63. O-Sulfonation of IV.63 was achieved with the sulfur trioxide–trimethylamine complex to give the disulfate IV.64 as the sodium salt. Finally, hydrogenolysis of IV.64 with Pd/C in aqueous methanol afforded the target disaccharide IV.51.
V.
KERATAN SULFATE
Keratan sulfate occurs in two principal forms, keratan sulfate I and keratan sulfate II, which are distinguished by their linkages to the core protein. Keratan sulfate I, found exclusively in the cornea and the oligosaccharide, is linked to protein by an N-glycosylic linkage between N-acetyl-D-glucosamine and L-asparagine [106]. Found in skin, cartilage, and bone, keratan sulfate II differs from the first variant by an Oglycosidic linkage between N-acetyl-D-galactosamine and L-serine or L-threonine [107]. Generally, the length of keratan sulfate chains range from short (5–10 disaccharides), to medium (20–30 disaccharides). Structurally, keratan sulfate differs from the other glycosaminoglycans in that it contains a nonacidic residue. The uronic acid moiety is replaced by a neutral D-galactose residue, thereby simplifying its synthesis by obviating the need for elaboration at C6. Additionally, sulfation can occur at the 6-OH on either the D-galactose or the N-acetylglucosamine residue. In cases of low sulfation, keratan sulfates can have a very low anionic character, attributable to the
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Scheme 47
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Synthesis of the galactosamine derivatives.
lack of a carboxylate group. The copolymer subunit is internally (1,4)-linked between D-galactose and N-acetylglucosamine residues with (1,3)-linkages between subunits (Fig. 7). Ogawa and coworkers have synthesized a tetrasaccharide fragment of keratan sulfate I, V.1 [108]. The target V.1 was derived from the fully protected tetrasaccharide V.2, which was in turn assembled by glycosylations involving key components V.3, V.4, and V.5 (Scheme 49). Starting from the known monomers V.6 [109] and V.7 [110], silver triflate promoted condensation afforded 92% of the allyl disaccharide V.8 (Scheme 50). Deactylation of V.8 was carried out with lithium hydroxide and hydrogen peroxide [111] in tetrahydrofuran to give 91% of the corresponding diol. Subsequent treatment with benzyl bromide in the presence of potassium iodide and silver(I) oxide afforded V.9 in 90% yield. Deallylation of V.9 was achieved with a rhodium catalyst and 1,4-diazbicyclo[2.2.2]octane followed by mercury(II) oxide and mercury(II) chloride in 10% aqueous acetone [112] to give the crude hemiacetal. Acetylation afforded V.10 as a mixture of  and ␣ anomers (11:1) in 71% overall yield. Chemoselective deacetylation was achieved with hydrazine acetate [113] to afford 73% of the hemiacetal, which was then converted to the -imidate V.4 (87%) as described earlier. Glycosylation of V.4 with the known compound V.5 [114] in the presence of BF3⭈OEt2 gave the desired trisaccharide V.11 in 83% yield. Deacetylation of V.11 to the diol followed by treatment with tert-butylchlorodiphenylsilane [115] and imidazole gave the monosilyl ether V.12 in 78% yield. The final glycosylation step was carried out with imidate V.3 in the presence of BF3⭈OEt2 to afford 48% of the desired tetrasaccharide V.13. De-phthaloylation followed by acetylation gave 63% of V.2. Conversion of the target V.1 from V.2 was achieved as follows: removal of the p-methoxyphenyl protecting group was carried out with cerium(IV) ammonium nitrate to give the diol. Subsequent desilylation with tetrabutylammonium fluoride afforded triol V.14 in 78% yield. Sulfation of V.14 with sulfur trioxide– triethylamine complex produced 93% of the tri-O-sulfated derivative V.15. Finally, hydrogenolysis (Pd/C) of V.15 provided the tetrasaccharide fragment of keratan sulfate I (V.1) in 92% yield.
Synthesis of Glycosaminoglycans
Scheme 48
The use of galactosamine in the synthesis of dermatan sulfate derivatives.
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Figure 7
VI.
Keratan sulfate.
HEPARIN AND HEPARAN SULFATE
Heparin was originally isolated from liver in 1916 by Maclean, and its anticoagulant properties were immediately realized. However, structural complexity prevented the unambiguous establishment of the accepted chemical structure of heparin until the late 1960s [116]. Heparin’s remarkable pharmacological properties have resulted in a large body of research, including the chemical synthesis of heparin fragments and related analogs [117]. The literature pertaining to the synthesis of heparin, heparan sulfate, and their analogs is vast and has been reviewed [118]. Heparin (VI.1) (Fig. 8) is found in a variety of mammalian tissues and consists of a repeating, linear copolymer of (1,4)-linked uronic acid and glucosamine residues, where the uronic acid moiety consists of 90% iduronic acid and 10% glucuronic acid [119]. The most common copolymer of heparin is the trisulfated disaccharide, where sulfation is solely on glucosamine at the C2, C3, and C6 positions. In a number of structural variants, the 2-amino functionality can be sulfated, acetylated or unsubstituted, and consequently heparin formations are microheterogeneous [120]. The source of antithrombotic activity, hence the anticoagulant activity of heparin, is the result of specific affinity for the serine protease inhibitor antithrombin III (AT-III). Inhibition of AT-III in turn inactivates serine proteases factor Xa and thrombin (factor IIa), which are downstream members of the coagulation cascade [121]. AT-III is a weak inhibitor of factor Xa and thrombin, which is considerably enhanced upon the binding of heparin [122]. Different molecular weight fragments of heparin display different anticoagulant properties. Specifically, heparin polysaccharides above 5 kDa inhibit thrombin and factor Xa in the presence of AT-III, while lower molecular weight heparin fragments only inhibit factor Xa [123]. Studies on heparin fragments obtained from chemical or enzymatic degradation revealed that approximately one-third of the heparin chains had the ability to bind to AT-III [124]. These experiments suggested that a limited number of heparin fragments possessed the structural features that are the source of its biological activity. Subsequently, a unique pentasaccharide domain was identified as necessary and sufficient for binding and activation of AT-III (Fig. 9) [125]. The sequence contains three monosaccharide units that rarely occur in heparin: a 6-Osulfate-N-acetyl-␣-D-glucosamine (unit D in Fig. 9), a -D-glucuronic acid (unit E), and a 3,6-di-O-sulfate-N-sulfate-␣-D-glucosamine moiety (unit F). The D unit can be either N-acetylated (VI.3) or N-sulfated (VI.4) depending on the source of the polysaccharide. The discovery that this pentasaccharide was responsible for the biological activity of the larger polysaccharide chain was a considerable breakthrough,
Synthesis of Glycosaminoglycans
Scheme 49
The Ogawa synthesis of the keratan sulfate I tetrasaccharide, part 1.
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Scheme 50
The Ogawa synthesis of the keratan sulfate I tetrasaccharide, part 2. Yeung et al.
Synthesis of Glycosaminoglycans
Figure 8
485
Heparin and heparan sulfate.
and it highlights the role that synthesis of GAGs can play in revealing the molecular origin of their biological activities. The charged groups on the heparin pentasaccharide were originally thought to be required for AT-III activation [125]. To test this hypothesis, the methyl glycosides of heparin analogs that lacked charged groups at defined positions, or their de-Osulfated derivatives, were chemically synthesized and used to probe the binding properties of the pentasaccharide to AT-III. As expected, the presence and position of the charged sulfate groups are essential for binding to and activation of AT-III (summarized in Fig. 10). Anionically charged groups indicated with an asterisk are essential, inasmuch as their removal leads to more than 95% (***) or 75% (**) loss of anti-Xa activity. The sulfates indicated by a single asterisk (*) are sites that contribute weakly to or are nonessential for AT-III activation [121,126]. The introduction of an extra 3-O-sulfate group (VI.6) at the reducing end (unit H of Fig. 10) significantly increased the affinity for AT-III, and thus the bioefficacy over that of the natural pentasaccharide [127]. The identification of the specific sites of interaction within the heparin pentasaccharide catalyzed the synthesis of a myriad of heparin analogs (Fig. 11). Among these were a series of ‘‘nonglycosaminoglycan’’ pentasaccharide analogs containing
Figure 9
The heparin pentasaccharide necessary for binding and activation to AT-III.
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Figure 10
Essential and nonessential sites on heparin required for AT-III activation.
only O-sulfate esters and O-methyl ethers to varying degrees (VI.7) [128]. van Boeckel and coworkers combined structural properties that were shown not to affect AT-III activation by methylation of the free hydroxyls and replacement of N-sulfates for O-sulfates [129]. As expected, the methylated and O-sulfated heparin analogs displayed increased biological activity. Moreover, the synthesis of this class of analogs is greatly simplified because no amino sugars need be introduced, and protecting group chemistry is simplified because all nonsulfated hydroxyl groups are methylated. Heparan sulfate (VI.2) is a related repeating linear copolymer of variably sulfated uronic acid and glucosamine content. It contains an average of only one sulfate per disaccharide and is predominantly composed entirely of (1,4)-linked glucuronic acid (10–50%) to glucosamine. Whereas heparin is an intracellular polysaccharide, heparan sulfate is a common cell surface component of many tissue types. Heparan sulfate contains all the disaccharide copolymer variants that are found in heparin, with a higher frequency of the minor sequences. Additionally, heparan sulfate contains domain structures that have high levels of sulfation, which resemble heparin and may be involved in its binding to heparin binding proteins [130,131]. The increased microheterogeneity of complexity may explain its presence on the cell surface. VII.
CONCLUSION
The arsenal of synthetic methodology of carbohydrates has increased significantly in recent decades and coincides with the discovery and characterization of biologically active polysaccharides. Glycosaminoglycans showcase the intertwining of biology and chemistry, both of which are required to completely understand protein–GAG interactions that are essential to biological systems. Small GAG oligomers and analogs are useful probes of the specific biological interactions responsible for activity and the various strategies utilized in the synthesis of GAGs represent state-of-theart synthetic methodology. Early synthetic efforts employed Koenigs–Knorr-type
Synthesis of Glycosaminoglycans
Figure 11
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The nonglycosaminoglycan analogs of heparin sulfate.
glycosylations that were often low yielding with moderate ␣,-selectivities. Although halo sugars are still widely used today, new glycosylation strategies have been developed that achieve consistently high yields and selectivities. The strategy most widely utilized in GAG synthesis is Schmidt’s trichloroacetimidate methodology. The high efficiency and substrate generality of the method allow for the use of uronic acid building blocks. The design and installation of the hexosamine unit has also benefited from recent advances in synthetic methodology. The 2-deoxy-2-amino functionality was normally derived from glucosamine or galactose amine; however, azidonitration and sulfonamidation of glycals are particularly suited for GAG synthesis. The chemical synthesis of GAG oligomers, their derivatives, and analogs is an important tool in determining their biological roles. High degree of functionalization
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coupled with diversity among individual GAG members continue to make them challenging synthetic targets. As with heparin, the chemical preparations of GAGs play a critical role in probing and elucidating specific protein–GAG interactions. Chemical syntheses of heparin clearly established the anionic carboxylate and sulfate groups as the sites of protein interaction. The application of this methodology to other GAGs is forthcoming, but it is clear that only synthesis allows for the specific modifications needed to reveal the sites responsible for biological activity. REFERENCES 1. 2. 3. 4. 5.
6. 7. 8. 9. 10.
11. 12.
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13 Pyranosyl Sugar Amino Acid Conjugates: Their Biological Origins, Synthetic Preparations, and Structural Characterization Jacquelyn Gervay-Hague and Thomas M. Weathers, Jr. University of Arizona, Tucson, Arizona
I.
INTRODUCTION
Sometimes it is true that everything old is new again, which can be disheartening for the originators of an idea who see others receiving credit years later. In some cases, an idea consistently evolves over time and early insights are ‘‘rediscovered’’ many years later. In other situations, ideas are born before their time, when the tools required to assure their continued development are lacking. And, in some circumstances, the creators of an idea fail to fully realize its potential. There are elements of all these factors in this chapter on the use of pyranosyl sugar amino acids as amino acid equivalents. Perusal of the literature suggests that the idea of making pyranosyl sugar amino acids originated in the laboratories of Heyns and Paulsen, who synthetically prepared the first pyranosyl sugar amino acid in 1955. The accuracy with which the literature records the moment of inception is somewhat suspect, since reports of naturally occurring pyranosyl sugar amino acids quickly followed the syntheses. Natural product identification was facilitated by comparisons to synthetic materials presenting the possibility that collaborative efforts prompted the synthetic work. This seems especially plausible because there were relatively few syntheses published between 1955 and the late 1960s. This period was primarily dominated by reports on the isolation of several different pyranosyl sugar amino acids from natural sources. Hanessian and Haskell authored a prophetic disclosure describing the isolation and characterization 493
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of a pyranosyl sugar amino acid amidically linked to alanine. The possibility that the alanine could bridge sugar amino acids in a similar fashion to ␣-peptides did not go unnoticed by these researchers. In the late 1960s and into the mid-1970s new synthetic reports appeared in the literature. Most of these focused on the total synthesis of naturally occurring pyranosyl sugar amino acid conjugates. Then, in 1976, Fuchs and Lehmann published the first synthesis of sugar amino acids amidically linked in a fashion similar to ␣amino acids. Surprisingly, this disclosure received little attention for nearly 20 years. In the past 5 years, the chemistry of pyranosyl sugar amino acids has evolved into a new science at the forefront of chemical design, synthesis, and structural characterization. Parallel work by Fleet and coworkers has elegantly exploited furanosyl sugar amino acids. At the same time, the sugar amino acids are only a small part of a larger science encompassing the use of unnatural amino acids in the synthesis of new materials with defined secondary structures. II.
NATURALLY OCCURRING PYRANOSYL SUGAR AMINO ACIDS
Glycopeptides are a large class of naturally occurring molecules containing a carbohydrate glycosidically linked to an ␣-amino acid, which is typically a component of a peptide or protein. There are both N- and O-linked glycopeptides. N-Acetylgalactosamine linked ␣ to serine is the major O-glycosidic linkage, whereas N-acetylglucosamine linked  to asparaginine characterizes N-linked glycopeptides (Fig. 1) [1]. Sugar amino acids are carbohydrates containing both amine and carboxylic acid functionalities in place of hydroxyls and are structurally distinct from glycopeptides. Naturally occurring sugar amino acids come in several types, consisting of both amino furanosiduronic and pyranosiduronic acids. This chapter includes the latter class of compounds, often referred to as amino hexuronic acids. Hexuronic acids are six-carbon monosaccharides containing both an aldehyde and a chain-terminating carboxylic acid. The amino hexuronic acids have amine functionalities in place of hydroxyl groups normally found in sugars. 2-Acetamido-2-deoxy-D-galacturonic acid, a major immunogenic component of Salmonella typhosa [2], was the first naturally occurring amino hexuronic acid identified [3]. In 1962 Perkins reported that the cell wall of Micrococcus lysodeikticus
Figure 1
Pyranosyl
495
contained 2-amino-2-deoxymannuronic acid [4], and shortly thereafter, Hemophilus influenzae type d was shown to contain 2-acetamido-2-deoxy-D-glucuronic acid [5]. At about the same time, an antigenic staphylococcal polysaccharide was shown to be composed of 2-acetamido-2-deoxy-glucuronic acid glycosidically linked to 2-[(Nacetylalanyl)amino]-2-deoxyglucuronic acid (Fig. 2) [6]. It would appear that this was the first identification of a naturally occurring sugar amino acid amidically conjugated to an ␣-amino acid [7]. All possible hexose configurations have been found as amino hexuronic acids in bacteria, with the possible exception of idose [8]. In some cases, more than one hydroxyl is replaced by amine functionality; for example, 2,3-diamino-2,3-dideoxyglucuronic acid was isolated from the cell wall of Propionibacterium acnes [9]. Several more polysaccharides containing hexuronic acids linked to ␣-amino acids such as alanine, serine, and threonine have been characterized [7]. There are also examples of amino sugars linked to the carboxy terminus of ␣-amino acids (Fig. 3) [10]. Ezomycin A1 and gougerotin are natural nucleoside antibiotics comprising sugar amino acids conjugated to ␣-amino acids through amide bonds. Ezomycin A1 contains two pyranoses, both having ␥-amino acid functionalities, whereas gougerotin is a carbohydrate-based -amino acid (Fig. 4) [11]. Ezoaminuroic acid was the first naturally occurring 3-amino-3-deoxy-hexuronic acid to be identified [12]. Structure elucidation studies, chemical syntheses, and biochemical properties of these and related compounds have been reviewed [13,14]. Amino glyculosonic acids are members of another class of sugar amino acids that are 2-keto sugars with a C1 carboxylic acid. One of the most abundant representatives of this class of molecules is neuraminic acid, a nine-carbon sugar amino acid. There are several known derivatives of neuraminic acid, which are collectively called the sialic acids [15]. They are components of bacterial and viral capsular polysaccharides, and they are important constituents of mammalian cellular recognition elements. Besides the sialic acids, two other amino nonulosonic acids have been isolated from bacteria. These compounds are 5,7-diamino-3,5,7,9-tetradeoxynonulosonic acids. The amine functionalities of pseudaminic acid (Fig. 5) have been found acylated, formylated, and conjugated to serine in nature [16].
III.
SYNTHETIC STUDIES OF PYRANOSYL SUGAR AMINO ACIDS
A.
Syntheses of Natural Amino Hexuronic Acids
Several syntheses targeting amino hexuronic acids have been reported. Heyns and Paulsen synthesized the first sugar amino acids in 1955 [17]. In the event, benzyl2-N-carbobenzyloxy-2-deoxy-␣-D-glucopyranoside was reacted with oxygen and platinum to provide 2-N-carbobenzyloxy-2-deoxy-D-glucuronic acid, which after removal of the nitrogen protecting group yielded a ␦-sugar amino acid (Fig. 6). 2-Amino-2-deoxy-galacturonic acid was prepared in a similar fashion [18]. It is noteworthy that these synthetic efforts predated the identification of sugar amino acids in nature. The syntheses of ␣- and -phenylglycosides of 2-N-acetyl-2-deoxyglucuronic acid were described in 1958 [19], and in 1961 Weidmann and Zimmerman reported several different reactions of 2-amino-2-deoxyglucuronic acids [20]. These combined
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reports set the foundation for subsequent studies by Yoshimura et al., who prepared several derivatives of 2-amino-2-deoxyglycuronic acids [21]. Tsuji and coworkers were the first to synthesize a 3-amino-3-deoxyhexuronic acid, in 1968 [22]. They began with an isopropylidene glucofuranosiduronic ester and introduced the nitrogen functionality via hydrazone formation and subsequent reduction. Removal of the isopropylidene resulted in formation of amino allouronic acid (Fig. 7). Paulsen and coworkers used a very similar strategy in making 3-amino3-deoxyglucuronic acid [23]. Ogawa later published the synthesis of a 3-amino-3,4-dideoxyhexuronic acid in route to ezomycin [24]. In that account, a 1,6-anhydro epoxy sugar was reacted with sodium azide followed by antimony pentachloride to give methyl 3-azido-2-Obenzoyl-␣-D-glucospyranoside. Oxidation of the primary alcohol was achieved with potassium permanganate, and reduction of the azide was accomplished with hydrogenation (Fig. 8). Finally, in 1979 Horton reported the synthesis of 3-amino-2,3-dideoxyhexuronic acids. In six steps, methyl ␣-D-mannopyranoside was converted to a highly functionalized 3-acetamido-6-azido-2,3,6-trideoxy derivative. Photochemical activation of the azide provided an imine, which was subsequently hydrolyzed to the aldehyde. Bromine was used to oxidize the aldehyde to the acid, which was esterified with methyl iodide (Fig. 9). In their studies directed toward the synthesis of gougerotin, Watanabe and coworkers prepared methyl-4-O-mesyl galactopyranoside and reacted it with sodium azide; after deprotection, methyl 4-azido-4-deoxyglucopyranoside was obtained [25]. This compound was oxidized with platinum and oxygen to afford the 4-azido glucuronic acid (Fig. 10) [26]. The focus of these early synthetic studies was to prepare amino hexuronic acid derivatives that could be joined through O-glycosidic linkages, which are found in nature. B.
Syntheses of Unnatural Sugar Amino Acids
Fuchs and Lehmann demonstrated that C-glycoside amino acids could be prepared from selective ring opening of sugar-based anhydrides [27]. In the reaction, the anhydride was regioselectively reacted with ammonia to give a C-glycoside amide, which was subsequently converted to a nitrile by the action of tosyl chloride in pyridine. The nitrile was reduced with catalytic hydrogenation, and the major product resulted from migration of the C3 acetate to the C1 amine. The O- and N-acetyls were removed by saponification, using 2 N sodium hydroxide at 100⬚C (Fig. 11). In
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1994 a related heptonic amino acid was prepared by nitromethane addition to glucose, reduction of the nitro group, and oxidation of the primary hydroxyl group (Fig. 12) [28]. Fuchs and Lehmann also prepared 7-amino C-glycoside carboxylic acids from the corresponding C-glycoside nitriles, which were hydrolyzed to carboxylic acids. The C6 hydroxyls were selectively converted to azides and subsequently reduced with catalytic hydrogenation [29]. Although Hanessian and Haskell mentioned the possibility that naturally occurring sugar amino acids could be linked via amide bonds rather than glycosides, Fuchs and Lehmann were the first to reduce this to practice in a synthetic arena (see below). Kim and Hollingsworth prepared a C-glycoside of N-acetylglucosamine by alkylation of a pyranosyl bromide with malonate anion, giving an N-acetyl ␥-sugar amino acid after decarboxylation (Fig. 13) [30]. Galantinic acid is a somewhat related compound that can be considered to be a C-glycoside pyranosyl amine. It is an -amino acid that was thought to be a component of Galantin I, a naturally occurring peptide-based antibiotic. In 1992, however, Sakai and Ohfune showed that galantinic acid is a by-product of the isolation procedure, rather than a component of the natural product [31]. In earlier work, Ohfune and Kurokawa reported a stereocontrolled synthesis of galantinic acid from a serine-derived epoxide. Cuprate opening of the epoxide gave a conjugated ester that underwent Michael addition upon deprotection (Fig. 14) [32]. This example illustrates a subtle relationship between ␣-amino acids and sugar amino acids, since galantinic acid has structural entities related to both classes of compounds. Perhaps the interplay between sugar amino acids and ␣-amino acids is more clearly demonstrated in the synthesis of ␣-D-glucosyl-(R)-alanine reported by Axon and Beckwith [33]. In the reaction, (2R)-methyleneoxazolidinone was treated with 2,3,4,6-tetra-O-acetyl glucosyl iodide in the presence of sodium cyanoborohydride and tributyltin chloride to give the ␣-C-glycoside in 88% yield (Fig. 15).
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-C-Glycosides have also been prepared by the Lewis acid catalyzed addition of ketene acetals, derived from ␣-amino acids, to glycosyl bromides [34]. The acyl protecting group at C2 was critical in this reaction because it directed the  incorporation of the amino acid. However, benzoyl protecting groups were trapped by addition to the carbonyl rather than the anomeric carbon. This problem was overcome by using a pivaloyl (OCOt-butyl) protecting groups instead (Fig. 16). N-Linked -amino acid conjugates of sugars were reported by Kunz et al. [35]. Mannich reaction of bis(O-trimethylsilyl) ketene acetals and N-galactosylimines gave ␣-branched -amino acids in high diastereomeric ratios (Fig. 17). 1-Amino-1-deoxyglucuronic acids have also been prepared. In one account, 1,2,3,4-tetra-O-acetyl glucuronic acid was treated with iodine at 0⬚C, followed by the addition of trimethylsilyl azide. The acetates were removed with hydrazine and the azide was reduced with 1,2-ethanedithiol [36]. Other azido sugars have been used in the preparation of sugar amino acids. For example, Fleet and coworkers converted the isopropylidene of D-glucuronolactone into an ␣-azido lactone, which was subsequently reduced to an ␣-amino lactone [37]. Removal of the acetal protecting group unmasked the aldehyde, which underwent reductive amination and hydrolysis of the lactone to give a trihydroxypipecolinic acid (Fig. 18). Fleet developed this elegant methodology as a rapid entry into several picolinic acid derivatives, which are naturally occurring L-amino acids with known biological activity. These molecules further illustrate the difficulty in defining the difference between sugar amino acids and ␣-amino acids. In this case, they are arguably indistinguishable. C.
Syntheses of Neuraminic Acid Derived Amino Acids
In his review on complex carbohydrates, Nathan Sharon stated: ‘‘Neuraminic acid is a nine carbon sugar acid, with an amino group in the molecule’’ [38]. This simple and obvious declaration was an epiphany for Gervay-Hague, whose prior experience with NeuAc had been limited to the challenges of O-glycosylations. The realization that neuraminic acid is an amino acid presented new possibilities for its utilization in the production of novel materials. Sharon’s writing inspired a program in the Gervay-Hague laboratories directed to the synthesis of amino acid equivalents derived from neuraminic acid. Since N-acetyl neuraminic acid is the most abundant form of the sialic acids, it was important to first establish a method for removing the acyl group. This turned out to be remarkably difficult, since both acid and base hydrolyses led to retro aldol products rather than the desired amine. Borrowing from work published by Roy and Pon [39], the -methyl glycoside of NeuAc was prepared and successfully N-deacylated using 2 N sodium hydroxide at 100⬚C for 48 h. Realizing that these conditions would not be suitable for a wide variety of substrates, the investigators sought milder conditions. After much experimentation, it was found that treatment of the amide with tert-butoxycarbonyl (Boc) anhydride followed by mild hydrolysis with sodium methoxide provided the Boc-protected sugar amino acid in high yield [40]. This general strategy provided a reliable route to several N-protected neuraminic acid analogs, including ␣- and -O-methyl glycosides and a 2,3-dehydro derivative (Fig. 19). 2-Deoxy analogs of N-protected neuraminic acids were also prepared. The hydrido derivative was obtained by hydrogenation of N-acetyl-N-Boc-4,7,8,9-tetra-
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Figure 17 507
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Figure 18
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O-acetyl-2,3-dehydroneuraminic acid followed by treatment with sodium methoxide. The ␣-hydrido analog was synthesized from N-acetyl-2,4,7,8,9-penta-O-acetyl neuraminic acid benzyl ester under the action of hydrogen iodide in acetic acid. In the reaction, the anomeric acetate was converted to an iodide, which subsequently underwent reductive elimination to give the ␣-hydrido compound under thermodynamic conditions (Fig. 20) [41]. These combined syntheses efficiently provided five new sugar amino acids with functionality suitable for typical peptide coupling reactions. The foregoing synthetic efforts, targeting the design and syntheses of novel carbohydrate-based amino acids over the past 45 years, have established a solid foundation for an entirely new area of scientific inquiry—the use of sugar amino acids in the synthesis of novel and unnatural products. IV.
SYNTHESIS OF SUGAR AMINO ACID CONJUGATES
The first synthetic reports of sugar amino acid conjugation appeared in the early 1970s. Most of those studies were directed to the synthesis of nucleoside antibiotics containing hexuronic acids conjugated to ␣-amino acids [11]. The first suggestions that unnatural compounds were of synthetic interest appeared in two separate papers published in 1976. Yoshimura and coworkers demonstrated that a hexosaminuronic acid could be conjugated to a glucosamine via an amide bond [42]. These scientists were clearly influenced by earlier work on nucleoside antibiotics. Nonetheless, they
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Figure 20
did make amido-bonded disaccharides for the first time. Because one sugar was an acid and the other an amine, these systems were self-terminating (Fig. 21). Fuchs and Lehmann first demonstrated that homo-oligomers of sugar amino acids could be prepared. In their reaction, a glucose-derived sugar amino acid possessing an anomeric carboxylate and a C4 amino group was polymerized under basic conditions [43]. After the reaction mixture had been heated for 4 h at 100⬚C, a waterinsoluble precipitate formed (Fig. 22). The products were not rigorously characterized, but there was evidence that the precipitate was composed of dimers, trimers, and tetramers. Although these two reports clearly demonstrated the feasibility of using sugar amino acids in the production of novel and unnatural compounds, it was nearly 20
Figure 21
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Figure 22
years before an aggressive exploration of this rich field of chemistry began. The art that followed the pioneering work of Yoshimura, Fuchs, and Lehmann can be classified into two categories: (1) syntheses involving mixed congeners, having either self-terminating residues and/or a combination of sugar amino and ␣-amino acids, and (2) homo-oligomeric syntheses composed of one sugar amino acid joined in consecutive amido linkages. A.
Syntheses of Mixed Sugar Amino Acid Conjugates
In 1994 Kessler used a sugar amino acid as a dipeptide isostere [28]. He and coworkers proposed that the C-glycoside amine of glucuronic acid would have torsion angles comparable to those of dipeptides composed of glycine and either serine or threonine. They incorporated the sugar amino acid into different peptides and measured their ability to inhibit the release of growth hormone as somatostatin analogs. The results of these experiments suggested that sugar-based peptides hold promise as potent peptidomimetics. Toth and coworkers also prepared sugar amino acid derived peptides in route to modified enkephalins [44]. Two conjugates were prepared and studied. An azido glucuronic acid was immobilized on a trityl resin, and, after reduction, it was further conjugated to five ␣-amino acids (Leu-Phe-Gly-Gly-Tyr). A second derivative consisted of a sugar amino acid dimer conjugated to the same five ␣-amino acids. The pharmacology of these compounds was evaluated and the analog containing only one sugar amino acid was shown to be a potent and selective agonist of the ␦-opioid receptor (Fig. 23). Very recently, amino deoxyglucuronic acids were used in the construction of disaccharide libraries [45]. In the report, methyl 3-azido-3-deoxy-4-O-methyl--Dglucuronic acid was prepared and glycosidically linked to a protected glucosamine, yielding a disaccharide with both amino and carboxamide functionalities. The azide was subsequently reduced and reacted with several isocyanates, providing libraries of -linked disaccharides (Fig. 24). One incentive for making amido-linked sugars as mimics of glycosidically linked disaccharides was the possibility of effecting enzymatic resistance to glycosidic bond cleavage. Sabesan nicely illustrated this point in his work on amide-linked disaccharides containing NeuAc [46]. The 2-azido sugar was reduced and subsequently condensed with an activated galacturonic acid to afford only the ␣-aminolinked disaccharide. This compound was designed to be an isostere of the naturally occurring ␣-D-NeuAc-(2-6)--D-Gal glycosidic linkage (Fig. 25).
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Figure 24
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Figure 25
Gervay and coworkers used two different strategies to further explore the incorporation of NeuAc into mixed sugar amino acid conjugates. In the first report, sialyllactones were prepared and condensed with glycine under thermal conditions [47]. Both five- and six-membered lactones were reacted, anticipating that the ring strain in the 1,4-lactones would promote the reaction. Unfortunately, this was not the case, and only low yields of the desired conjugates were obtained. The six-membered lactones gave improved yields, but, in general, the reactions were not efficient. In later studies, NeuAc was efficiently conjugated to several ␣-amino acids using BOP and HOBT activation of the acid followed by addition of an ␣-amino acid [48]. This protocol provided a number of sugar amino acid peptides in nearly quantitative yields (Fig. 26). B.
Oligomeric Sugar Amino Acid Syntheses
In 1995 Nicolaou and coworkers initiated a renaissance in the construction of sugar amino acid conjugates with their synthesis of carbonucleotoids [49]. Although they did not prepare amide-linked carbohydrates, they did introduce the term ‘‘carbopeptoid’’ to designate such materials. Shortly thereafter, a number of papers directed toward the synthesis of carbopeptoids appeared. One of the earliest was reported by Wessel et al., who used nor-muramic acid derivatives and condensed them in solution by means of 2-chloro-4,6-dimethoxy-1,3,5-triazine (CDMT) in DMF to construct a tetramer (Fig. 27). Wessel later used solid phase synthesis to prepare a tetramer of amido-linked 2-amino-2-deoxyglucuronic acids [50]. In that disclosure, benzyl 2-fluoren-9-ylme-
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Figure 26
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Figure 27
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thoxycarbonyl (Fmoc) amino-2-deoxy-␣-D-glucuroniside was immobilized on Rink resin. After deprotection of the Fmoc group with piperidine, an Fmoc-protected amino glucuronic acid was added and amide formation was promoted by TATU [O(7-azabenzotriazol-1-yl)-1,1,3,3-tetramethyluronium tetrafluoroborate]. Iteration of this procedure culminated in the construction of a tetramer. Some difficulties encountered in immobilizing the first sugar residue may have been due to steric congestion at the resin surface. Subsequent couplings readily occurred, suggesting that the first residue may have served to extend the reaction centers away from the polymer bead (Fig. 28). The Ichikawa group also made amido-linked oligomers derived from amino Cglycoside carboxylic acids [51]. A Boc-protected -sugar amino acid was conjugated to phenylalanine and subsequently deprotected to give the free amine, which was coupled to another Boc-protected monomer. Diethylphosphoryl cyanide and triethylamine were used to activate the acid for coupling in the solution phase. A tetramer was synthesized and subsequently sulfated to increase solubility and to introduce negative charge (Fig. 29). This material was designed as a potential inhibitor of HIV replication, since it was known that sulfated polymeric carbohydrates inhibit HIV entry into T cells. Syncytium formation was completely blocked when CD4 cells were infected with
Figure 28
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Figure 29
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HIV in the presence of 50 M concentrations of the sulfated tetramer. Later, an even more potent inhibitor (IC50 = 1 M) was prepared from a sulfated tetramer comprised of amido-linked C7-amino-C1 heptonic acid monomers [52]. Goodnow et al. targeted anti-sense agents in their syntheses of amido-linked pyranosyl nucleosides [53]. Carbohydrate-based nucleic acids were sought because peptide nucleic acids self-aggregate, creating solubility and cellular entry problems. It was hoped that the rigid backbone of the amide-linked sugars would provide a scaffold allowing the bases to align in a Watson–Crick base-pairing fashion with DNA and/or RNA. Solid phase methods were used to prepare two nucleoside analogs of 2-amino-2-deoxyglucuronic acid and incorporate them into oligomers. Both the 10-residue and the 13-residue oligomers were water soluble (Fig. 30). The binding affinities of the two oligomers for selected DNA and RNA oligomers were determined from duplex formation and melt temperature measurements. The 10-mer bound complementary antiparallel DNA approximately 5⬚C lower than a known peptide nucleic acid, strongly supporting the Watson–Crick model. The amide-linked oligomers showed binding affinities for DNA that were greatly enhanced over glycosidically linked analogs. The van Boom laboratories investigated the possibility of replacing glycosidic linkages with amide linkages to enhance the biological activity of a phytoalexin elicitor [54]. Earlier, they had shown that an amidically terminated, branched hexasaccharide was as potent as the naturally occurring sugar terminating in a reduced sugar moiety. From a series of structure–activity relationship studies, they deduced that the conformation of the glycosidic linkages along the backbone was critical for the observed activity. Based on this information, they questioned whether an amidically linked backbone structure would show improved phytoalexin elicitor activity. A glycosidically linked dimer was converted to an amino acid equivalent and amidated with a terminating sugar at the anomeric position. The C6 carboxyl functionality was readied for chain elongation with a monomeric sugar amino acid, which was subsequently condensed with a glycosidically linked dimeric sugar amino acid. Finally, the carboxy terminus was capped (Fig. 31). Subsequent biological studies showed that the amide-linked analogs were completely inactive. These results, when contrasted with the work of Ichikawa and Goodnow, suggest that amide-linked carbohydrates may serve better as unique molecular scaffolds than as glycosidic linkage mimics. V.
SYNTHESES AND STRUCTURAL CHARACTERIZATION OF AMIDO-LINKED OLIGOMERS WITH STABLE SECONDARY STRUCTURE
A.
Non-Carbohydrate-Based Materials
Although this chapter is focused on carbohydrate-based compounds, it is important to briefly describe the pioneering work of Gellman and Seebach directed to the syntheses of amido-linked oligomers derived from - and ␥-amino acids that are not based on carbohydrates. These researchers and others [55] have engineered systems that adopt stable helical, sheet, and turn conformations in solution. Surprisingly, in many cases as few as four residues is sufficient to stabilize the conformation. This completely contrasts with oligomers derived from ␣-amino acids which typically require many more residues before conformational stability is established [56].
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Figure 30
Gellman introduced the term ‘‘foldamer’’ to refer to ‘‘any polymer with strong tendency to adopt a specific compact conformation’’ [57]. Early work from his group exemplified the rational design process. Computer-assisted analysis of several amidolinked -amino acids led to the proposal that trans 2-amino hexanoic acid and trans 2-amino pentanoic acid would form stable helical structures. Modeling predicted that the hexanoic system would form a 14-helix and the pentanoic system a 12-helix (Fig. 32). These structures were synthesized and their conformations were experimentally verified using a combination of NH/ND exchange rates, circular dichroism (CD), and X-ray crystallography. Seebach et al. reported the synthesis of - and ␥-peptides with stable secondary structures [58] and, independently, Hanessian et al. reported the synthesis of ␥-peptides that adopt helical structures in solution [59]. These combined studies showed important structural characteristics for - and ␥-peptides in contrast with ␣-peptides. For example, ␣-peptides adopt helical conformations stabilized by a 13-membered hydrogen bond between the carbonyl of the amino terminus and the amide NH of the fourth residue toward the C-terminus (3.6 residues per turn). -Peptides formed
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a 14-membered hydrogen bond between the carbonyl of the C-terminus and the NH of the amide two residues toward the N-terminus (3 residues per turn) (Fig. 33) [60]. Seebach’s ␥-peptides formed a 14-membered hydrogen bond between the carbonyl of the N-terminus and the carbonyl two residues toward the C-terminus (2.6 residues per turn) [61]. Of the many elegant studies reported by Gellman and coworkers, two are particularly relevant to the discussion at hand. The first was the formation of watersoluble -amino acid hexamers with stable helices in water [62]. Four different systems containing positively charged amine functionalities were prepared (Fig. 34). The charge promoted water solubility and, at the same time, prevented aggregation [63]. Structural analyses using the aforementioned techniques confirmed that these oligomers adopted a 14-helix conformation in aqueous solution. Demonstrating that conformationally stable, water-soluble candidates could be prepared was the first step toward using these new materials to solve biologically relevant problems. The Gellman laboratories later reported the chemical synthesis of a 17-mer based on the 12-helix forming trans-2-aminocyclopentanoic acids [64]. Charged amine functionalities in combination with neutral monomer units were incorporated into the oligomer to provide an amphiphilic secondary structure (Fig. 35). When tested for bactericidal and bacteriostatic activity against a vancomycin-resistant bacterial strain, this material exhibited activity similar to that of a known 23-mer
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Figure 34
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Figure 35
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Figure 36
␣-peptide inhibitor. Moreover, the -peptide was less destructive to red blood cells than was the ␣-peptide. In addition to their many structural studies on - and ␥-peptides, Seebach and coworkers showed that human receptors accept -peptides that mimic natural ␣peptides [65]. They modeled a cyclic -tetrapeptide placing phenylalanine, tryptophan, lysine, and threonine-like side chains in key positions designed to mimic a cyclic ␣-octapeptide derived from somatostatin (Fig. 36). Standard peptide chemistry that relied on Boc and benzyl protecting group strategies was used in the synthetic construction of the tetrapeptide. The protected form of the cyclic peptide was not soluble under normal conditions required for hydrogenolysis; however, the researchers were able to reduce the benzyl protecting group in THF with 6 equiv of lithium chloride. Radioligand binding assays were conducted to measure human somatostatin receptor affinities for the -tetrapeptide relative to the ␣-octapeptide. The -peptide was active in the micromolar range, whereas only nanomolar concentrations were required for the ␣-peptide. Although the -peptide was less active, it was shown to be peptidase resistant, an important consideration in terms of pursuing related compounds in the future. B.
Carbohydrate-Based Oligomers with Secondary Structure
Amide-linked carbohydrate-based oligomers with defined secondary structures were first engineered by Szabo et al. [66]. -Methoxy neuraminic acid was used as the monomer unit, and solid phase techniques were employed in the construction of oligomers ranging from dimer to octamer. Caproamide was incorporated at the carboxy terminus to prevent solvation of the terminal residue, a phenomenon commonly referred to as fraying (Fig. 37). The hydrophobic end group provided directionality
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Figure 37
to the growing chain, fashioned after a membrane-bound oligomer. It was anticipated that these combined factors would stabilize backbone hydrogen bonding interactions and lead to relatively small molecules with stable secondary structures. Caproamide was immobilized on Rink resin, and Fmoc-protected -methoxy neuraminic acids were condensed by using BOP and DIEA in N-methylpyrrolidinone (NMP). Flaherty et al. had earlier reported that solution phase coupling of neuraminic acids was sluggish, and only poor yields were realized (48 h, 25–30%) [40]. In contrast, the solid phase syntheses were completed in a few hours, as determined by the Kaiser test, and combined yields ranged from 44 to 55% indicating that each coupling step was far more efficient (Fig. 38). -Methoxy NeuAc was used as a sugar amino acid in the construction of oligomers for three primary reasons. First, it was readily available from a naturally occurring ␦-amino acid. Second, it was hypothesized that the trihydroxy side chain would increase water solubility in higher order oligomers. Finally, O-glycoside oligomers of NeuAc were known to have stable secondary structure in aqueous solution, and it seemed possible that amide-linked analogs would exhibit similar properties [67]. The second hypothesis was proved by the chemical syntheses of the oligomers, which were all shown to be highly water soluble. The oligomer secondary structures were probed using a combination of NH/ND exchange studies and CD, patterned after the studies of Gellman and Seebach. The exchange studies were originally performed in dimethyl sulfoxide (DMSO) because they were too rapid to be observed in water. The half-lives of NH/ND exchange were determined for the series of oligomers ranging from dimer to octamer. The dimer exchanged rapidly (half-life ⬃ 30 min). Two different exchange rates were observable for the trimer; the amino terminus amide exchanged fastest, on the same order as the dimer. The half-life of the internal amide was approximately 6 h. This was also true of the tetramer; the reducing end amide exchanged relatively quickly, but the internal amides took several hours. The rapid exchange of the reducing end amide was attributed to fraying. For the most part, as the oligomer length increased, the exchange rates of the internal amides slowed (the octamer was the slowest).
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Figure 38
CD spectra were recorded in water at neutral pH, and they correlated with the NH/ND studies (performed in DMSO) surprisingly well. The dimer, lacking an internal amide, did not show a signature CD. The other oligomers displayed an absorbance maximum at ⬃200 nm with a zero crossover at ⬃212 nm and a minimum at 200 nm, returning to zero at ⬃240 nm. The intensity of the maximum at 200 nm consistently increased with increasing length. These data completely correlated increasing secondary structural stability with increasing oligomer length. Shortly after this report, Fleet and coworkers reported that furanosyl-derived amido-linked sugar amino acids also adopt stable secondary structures in solution (Fig. 39) [68]. Gregar and Gervay-Hague recently prepared a series of ␣-methoxy NeuAc amido-linked oligomers and compared them to the -methoxy series [69]. The first noticeable difference was the NH/ND exchange rates, which were slow enough in water (pH = 3.0 phosphate buffer) to be measured. The exchange rates were fast for dimer and trimer, and essentially disappeared before the NMR spectra were acquired.
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Figure 39
The rates slowed for the tetramer, which exchanged similarly to the pentamer through octamer. CD spectra were also recorded in pH = 3.0 phosphate buffer solution. The CD signatures of these compounds showed a reverse trend from the -methoxy series, with an absorbance minimum at ⬃195 nm and a maximum at ⬃230 nm, returning to zero at ⬃260 nm (Fig. 40). Interestingly, there was a dramatic increase in the intensity of the absorbencies in going from trimer to tetramer, but the spectra of the longer oligomers (5-mer through 8-mer) were similar to the tetramer, which correlated exactly with the NH/ND studies. The CD and NMR studies indicated that the ␣-methoxy series formed stable secondary structures with as few as four residues.
Figure 40 CD spectra of ␣-methoxy NeuAc amido-linked oligomers recorded in phosphate buffer solution (pH 3).
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CD spectra of -methoxy NeuAc amido-linked oligomers recorded in phosphate buffer solution (pH 3).
Figure 41
For comparison purposes, CD spectra of the -methoxy series were recorded in pH 3.0 phosphate buffer solution. In contrast to the ␣-methoxy series, the octamer was clearly distinguishable from shorter oligomers, suggesting that it is significantly more stable (Fig. 41). NH/ND exchange studies in pH 3.0 buffer showed that all oligomers exchanged rapidly with the exception of the octamer. These combined studies clearly showed that both ␣- and -methoxy neuraminic acid-derived oligomers adopt stable secondary conformations in aqueous solution. However, the ␣ series required only four residues for stability, whereas the -series required eight. VI.
THE FUTURE
There are many intended applications of the scientific inquiries described in this chapter, including (1) use of unnatural amino acids in the construction of libraries, (2) use of the oligomers as peptido mimetics, and (3) incorporation of the oligomers in artificial protein engineering (see below). Artificial amino acids have routinely been incorporated into natural peptides in pharmacophore drug design. However, rapid elimination half-lives and biochemical degradation often contribute to poor efficacy for many of these compounds. The development of nonnatural peptides may lead to drug candidates with improved bioavailability profiles, since they would be resistant to biochemical degradation through the action of proteases and peptidases. Application to protein engineering requires the interaction of secondary structures to form tertiary structures. DeGrado and coworkers recently accomplished de novo design of helical bundles composed of natural ␣-peptides [70]. In earlier work, they described three principles that guide the design process: (1) complementary packing within the hydrophobic core, (2) specific interfacial interactions to promote
Pyranosyl
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interhelical associations, and (3) core and interfacial interactions to destabilize potential alternate conformations [71]. The distinctive packing of the amino acid side chains in the core of the bundle gives rise to a coiled coil, or superhelix. Coiled coils have biological relevance. For example, they are found in fibrous proteins such as fibrinogen and keratin [72] and are structural components of viral proteins [73]. De novo design of these macromolecular structures offers insight into the process of protein folding, in addition to providing new materials. The same would be true of de novo design of coiled coils composed of nonnatural peptides. As of this writing, 3⬚ structure in nonnatural peptides has not been reported. However, Gellman has offered a blueprint for the design of coiled coils based upon -peptides [74]. The possibility of creating carbohydrate-based ␦-peptides that adopt stable 3⬚ structures in solution is also of great interest. Determining the conditions that promote oligomer aggregation is an important step toward engineering artificial proteins. Beyond the obvious biomedical uses as drug delivery agents, biosensors, and affinity materials, compounds with unique structural motifs could serve as chemical catalysts. For example, just as natural proteins provide a hydrophobic medium in aqueous solution, properly designed carbohydrate-based proteins could provide a hydrophilic environment in an organic medium, opening up new possibilities for chemical transformations. It is clear that an idea born nearly 50 years ago has evolved into a rich science at the frontiers of synthetic design, structure elucidation, and materials production. Over the years, old chemistry was rediscovered and applied in new directions resulting in the birth of entirely new ideas. Many factors have contributed to the successes, including the introduction of combinatorial chemistry, the availability of biological screening assays, and the development of new and improved technologies for structure determination. Pyranosyl sugar amino acid conjugates will surely continue to provide a fertile field for scientific inquiry and discovery.
REFERENCES 1. 2.
Kornfeld, R.; Kornfeld, S. In The Biochemistry of Glycoproteins and Proteoglycans, Vol. XIV, William J. Lennarz, ed. Plenum Press: New York, 1980, pp. 1–33. Several other sources have also been identified: Torii, M.; Sakakiba, K.; Kuroda, K. Eur. J. Biochem. 1973, 37, 401–405. Karakawa, W. W.; Kane, J. A. J. Immunol. 1975, 114, 310–315. Liau, D.; Melly, M. A.; Hash, J. H. J. Bacteriol. 1974, 119, 913–922. Eguchi, H.; Kaya, S.; Araki, Y. Carbohydr. Res. 1992, 231, 147–158. Romanows, E.; Reinhold, V. Eur. J. Biochem. 1973, 36, 160–166. Reddy, G. P.; Hayat, U.; Xu, Q. W.; Reddy, K. V.; Wang, Y. H.; Chiu, K. W.; Morris, J. G.; Bush, C. A. Eur. J. Biochem. 1998, 255, 279–288. Williamson, A. R.; Zamenhof, S. J. Biol. Chem. 1963, 238, 2255–2258. Jeanes, A.; Burton, K. A.; Cadmus, M. C.; Knutson, C. A.; Rowin, G. L.; Sandford, P. A. Nat. New Biol. 1971, 233, 259. Fournier, J. M.; Vann, W. F.; Karakawa, W. W. Infect. Immun. 1984, 45, 87–93. Lee, J. C.; Michon, F.; Perez, N. E.; Hopkins, C. A.; Pier, G. B. Infect. Immun. 1987, 55, 2191–2197. Moreau, M.; Richards, J. C.; Fournier, J. M.; Byrd, R. A.; Karakawa, W. W.; Vann, W. F. Carbohydr. Res. 1990, 201, 285–297. Ichihara, N.; Ishimoto, N.; Ito, E. FEBS Lett. 1974, 40, 309–311. Konig, H.; Kandler, O. Arch. Microbiol. 1979, 123, 295–299. Kochetkov, N. K.; Kholodkova, E. V.; Stanislavsky, E. S. Eur. J. Biochem. 1987, 167, 549–561. Wu, T. C. M.; Park, J. T. J. Bacteriol. 1971, 108, 874.
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Gervay-Hague and Weathers Gademann, K.; Ernst, M.; Hoyer, D.; Seebach, D. Angew. Chem. Int. Ed. Engl. 1999, 38, 1223. Szabo, L.; Smith, B. L.; McReynolds, K. D.; Parril, A. L.; Morris, E. R.; Gervay, J. J. Org. Chem. 1998, 63, 1074. Brisson, J.-R.; Baumann, H.; Imberty, A.; Pe´rez, S.; Jennings, H. J. Biochemistry 1992, 31, 4996–5004. Fleet and coworkers have reported a number of successes in this area. The reader is referred to the rich literature provided by this laboratory, which is outside the scope of the present chapter: Estevez, J. C.; Arcron, H.; Wormald, M. R.; Brown, D.; Fleet, G. W. J. Tetrahedron Lett. 1994, 47, 8885. Estevez, J. C.; Arcron, H.; Wormald, M. R.; Brown, D.; Fleet, G. W. J. Tetrahedron Lett. 1994, 47, 8889. Kru¨lle, T. M.; Watson, K. A.; Gregoriou, M.; Johnson, L. N.; Crook, S.; Watkin, D. J.; Griffiths, R. C.; Nash, R. J.; Tsitsanou, K. E.; Zographos, S. E.; Oikonomakos, N. G.; Fleet, G. W. J. Tetrahedron Lett. 1995, 45, 8291. Brandstetter, T. W.; Wormald, M. R.; Dwek, R. A.; Butters, T. D.; Platt, F. M.; Tsitsanou, K. E.; Zographos, S. E.; Oikonomakos, N. G.; Fleet, G. W. J. Tetrahedron Asymm. 1996, 157. Estevez, J. C.; Smith, M. D.; Lane, A. L.; Crook, S.; Watkin, D. J.; Besra, G. S.; Brennan, P. J.; Nash, R. J.; Fleet, G. W. J. Tetrahedron Asymm. 1996, 387. Estevez, J. C. Burton, J. W.; Estevez, R. J.; Ardron, H.; Wormald, M. R.; Dwek, R. A.; Brown, D.; Fleet G. W. J. Tetrahedron Asymm. 1998, 2137. Smith, M. D.; Long, D. D.; Marquess, D. G.; Claridge, T. D. W.; Fleet, G. W. J. J. Chem. Soc. Chem. Commun. 1998, 2039. Gregar, T. Q.; Gervay-Hague, J. J. Am. Chem. Soc. Submitted. Walsh, S. T.; Cheng, H.; Bryson, J. W.; Roder, H.; DeGrado, W. F. Proc. Natl. Acad. Sci. USA 1999, 96, 5486–5491. Betz, S. F.; Liebman, P. A.; DeGrado, W. F. Biochemistry 1997, 36, 2450–2458. (a) Pauling, L.; Corey, R. B. Nature 1953, 171, 59–61. (b) Crick, F. H. C. Acta Crystallogr. 1953, 6, 685–697. Wilson, I. A.; Skehel, J. J.; Wiley, D. S. Nature 1981, 289, 366–373. Appella, D. H.; Christianson, L. A.; Karle, I. L.; Powell, D. G.; Gellman, S. H. J. Am. Chem. Soc. 1999, 121, 6206–6212.
14 Glycosyltransferases in Oligosaccharide Synthesis Xiangping Qian, Keiko Sujino, and Monica M. Palcic University of Alberta, Edmonton, Alberta, Canada R. Murray Ratcliffe SYNSORB Biotech Inc., Calgary, Alberta, Canada
I.
INTRODUCTION
Recent demonstrations that oligosaccharides play important roles in diverse biological events have resulted in renewed interest in the synthesis of oligosaccharides and their analogs. The availability of such molecules can facilitate studies on carbohydrate–protein recognition and help to elucidate molecular mechanisms of oligosaccharide-mediated biological processes [1,2] that could eventually lead to rationally designed carbohydrate-based therapeutics [3,4]. Despite many advances that have been made over the past decades, the chemical synthesis of oligosaccharides remains a challenge [5,6]. This is attributed to the inherent chemical difficulties presented by this class of molecules. Each monosaccharide carries at least three hydroxyl groups that must be protected and deprotected during synthesis. Also, glycosylation generates a new stereocenter at the anomeric carbon, and there are no general methods for the introduction of all types of glycosidic linkage in a manner that is both stereocontrolled and high yielding. The chemical synthesis of oligosaccharides is therefore very time-consuming and requires specialized expertise. The synthesis of oligosaccharide analogs containing modified sugars is an even more complex task than the preparation of natural structures. Almost twice as many steps are usually required for analog synthesis and the steps are more difficult, since most chemical protocols in the literature have been optimized for natural sugars. In nature, glycosyltransferase enzymes accomplish the ‘‘daunting’’ task of the construction of diverse and complex oligosaccharide [7–9]. These enzymes catalyze 535
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the transfer of a monosaccharide from a glycosyl donor (usually a sugar nucleotide) to a glycosyl acceptor in a regio- and stereospecific manner (Fig. 1). Pioneered by Barker [10,11], Whitesides [12] and Auge´ [13] and their colleagues, enzymatic synthesis by means of glycosyltransferases opened up a new venue for the preparation of oligosaccharides, avoiding many of the problems encountered in traditional chemical synthesis. Multistep protection and deprotection sequences are no longer required, since the glycosyl transfer catalyzed by glycosyltransferases is stereo- and regiospecific; thus the configuration of the newly formed anomeric center is absolute. Glycosyltransferases, unlike many catalysts used in organic synthesis, are environmentally benign and operate best in aqueous solution. Although glycosyltransferases exhibit high specificity for both the sugar nucleotide donor and acceptor, they have been shown to tolerate certain structural changes on both donor and acceptor substrates. An enzymatic approach to unnatural oligosaccharides greatly simplifies the synthetic scheme because the requirement for the chemistry is then reduced to the synthesis of more readily accessible smaller ‘‘primers’’ (mono- to trisaccharides), which can be elongated in a regio- and stereospecific manner using glycosyltransferases without additional protection and deprotection steps.
Figure 1 Reactions catalyzed by Leloir glycosyltransferases (B = uracil, guanine, cytosine). The acceptor glycosylation site is highlighted.
Glycosyltransferases
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With advances in molecular biology and biotechnology, more than 30 glycosyltransferases from mammalian [9,14], bacterial [15–17], and even viral [18] sources have been cloned, and many are now readily available in large multiunit quantities. For synthetic applications, the major sugar nucleotide donor substrates for mammalian glycosyltransferases are commercially available, and cost limitations for large-scale synthesis are rapidly being overcome with nucleotide donor recycling systems [12,19] and pathway engineering [20]. Glycosyltransferase-catalyzed synthesis of both natural and unnatural oligosaccharides is an important component of glycochemistry, as evidenced by the numerous comprehensive reviews that have appeared [21–25]. II.
GLYCOSYLTRANSFERASES
Glycosyltransferases can be divided into the Leloir and non-Leloir types according to the type of glycosyl donors they use [26]. Non-Leloir glycosyltransferases typically use glycosyl phosphates as donors, while Leloir glycosyltransferases utilize sugar nucleotides as donors and transfer the monosaccharide with either retention (retaining enzymes) or inversion (inverting enzymes) of the configuration of the anomeric center (Fig. 1). Most of the glycosyltransferases responsible for the biosynthesis of mammalian glycoproteins and glycolipids are Leloir glycosyltransferases. They are typically type II membrane proteins with a short cytoplasmic Nterminal domain, a hydrophobic transmembrane domain, a luminally oriented stem, and a large C-terminal catalytic domain [27]. With a few exceptions [28,29], each glycosyltransferase produces a unique glycosidic linkage. According to the ‘‘one enzyme–one linkage’’ hypothesis [30], there are estimated to be hundreds of glycosyltransferases responsible for the production of the diverse and complex oligosaccharide structures found in nature. Glycosyltransferases are classified according to their nucleotide donor sugars, the type of glycosidic linkage formed (␣ or ), and the specific hydroxyl group in the acceptor to which the monosaccharide is transferred. Mammalian glycosyltransferases use only nine main sugar nucleotides as building blocks to construct complex oligosaccharides. They are activated sugar donors of uridine diphosphate (UDP-Gal, UDPGlcNAc, UDP-Glc, UDP-GlcNAc, UDP-Xyl, UDP-GlcA), guanosine diphosphate (GDP-Fuc, GDP-Man), and cytidine monophosphate (CMP-sialic acid or CMPNeu5Ac). All the sugar units have the D configuration except for fucose, which has an L configuration. This chapter reviews the literature on enzymatic synthesis utilizing Leloir glycosyltransferases, with focus on galactosyltransferases, fucosyltransferases, and sialyltransferases, most of which are commercially available or widely accessible. Also, they are well studied in terms of their donor and acceptor specificity and have been used for the synthesis of both natural oligosaccharides and their analogs. As well, two practical examples for the synthesis of trisaccharide analogs are given. III.
GALACTOSYLTRANSFERASES
A.
 1,4-Galactosyltransferase
1,4-Galactosyltransferase (1,4-GalT, EC 2.4.1.22/38/90) has been commercially available for many years in unit quantities, where a unit is the amount of enzyme
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that converts one micromole of substrate to product per minute. It is the most widely studied glycosyltransferase with regard to substrate specificity and use in preparative synthesis and the first mammalian glycosyltransferase for which an X-ray crystal structure was determined [31]. Historically, 1,4-GalT was also the first enzyme used for the preparation of oligosaccharides on a large scale (>10 g) [12]. 1,4-GalT catalyzes the transfer of Gal from UDP-Gal to OH-4 of terminal -linked GlcNAc to form N-acetyllactosamine (LacNAc) (Fig. 2). The acceptor specificity shifts to glucose in the presence of the protein modifier ␣-lactalbumin, giving lactose as the major product. Since Berliner’s pioneering work demonstrating that 1,4-GalT could transfer glucose, 4-deoxy-Gal and arabinose from their corresponding UDP donors [32], donors with modifications at every OH group have been employed for the synthesis of numerous LacNAc analogs (Fig. 3). While the enzyme transfers 2-deoxy-Gal at a rate comparable to that of UDP-Gal [33], 3-deoxy [34], 6-deoxy [35,36], and 6deoxy-6-fluoro Gal [35,36] are transferred at reduced rates. The enzyme also utilizes UDP-GalNAc, UDP-GalNH2, and UDP-GlcNH2 donors [37,38] (Fig. 3). Replacement of the oxygen of Gal with sulfur in UDP-5⬘-thio-Gal is tolerated by 1,4-GalT [39], including transfer in the presence of ␣-lactalbumin [40]. The acceptor specificity of 1,4-GalT is equally relaxed, since numerous modifications in acceptors including the ring oxygen are possible as long as the 4-OH remains available for glycosylation (Fig. 3). The 4-OH is a ‘‘key polar group’’ [41] where replacement or modification yields analogs that no longer bind to the enzyme. The 2-NHAc group can be replaced with N-propanoyl [42,43], N-butanoyl [42], azido [38,44], allylcarbamate [45], and other amide derivatives, including bulky heterocycles, charged groups, and glycuronamides [46]. Acceptors with the 3-OH group deoxygenated [47,48], alkylated with a methyl or allyl group, or oxidized to the ketone are active as acceptors with reduced reaction rates [48]. The 6-OH group of GlcNAc can be methylated [43,48], deoxygenated [47], fucosylated [43], or replaced with F or SH [47]. GlcNAc bearing ␣-linked sialic acid at 6-OH is not a substrate;
Figure 2
The reaction catalyzed by 1,4-galactosyltransferase.
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Figure 3
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Unnatural donors and acceptors for 1,4-GalT.
however, if the carboxylic acid of NeuAc is derivatized with a methyl ester, the resulting compound is an acceptor with 4% the rate of transfer compared to the parent acceptor [43]. 1,4-GalT will utilize acceptors with the ring oxygen modified, including 5⬘thio-Glc and 1-deoxy-nojirimycin [48]. Glucal with a flattened ring [48] and (⫾)conduritol B are substrates; the latter mixture can be resolved because only a single galactosylated product (⫺)-conduritol B is produced [49]. In an exception to the
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‘‘one enzyme–one linkage’’ hypothesis, the enzyme transfers galactose to the anomeric position of 3-acetamido-3-deoxy-D-glucose acceptors giving a 1→1 trehalose type of linkage [29]. This atypical regiochemistry of galactosylation was also reported for N-acetyl-gentosamine, N-acetyl-5⬘-thiogentosamine, and xylose acceptors [50,51]. A variety of immobilized acceptors have been employed in solid phase or soluble polymer synthesis [52–58], and even UDP-GlcNAc is an acceptor substrate, yielding the nucleotide disaccharide UDP-N-acetyllactosamine [59]. Reactions at scales of 500 g or more with 1,4-GalT have been reported with in situ donor recycling [60]. Also 1,4-GalT enzymes have been found in bacterial sources, including Helicobacter pylori and Neisseria meningitidis [61–63] and utilized in 100 g reactions for N-acetyllactosamine production through bacterial coupling [64]. B.
␣1,3-Galactosyltransferase
␣1,3-Galactosyltransferase (␣1,3-GalT, EC 2.4.1.151) has recently attracted much attention because it catalyzes the transfer of Gal from UDP-Gal to 3-OH of the Gal residue in Gal1 → 4GlcNAc-R to form Gal␣1 → 3Gal1 → 4GlcNAc epitopes on glycoproteins and glycolipids (Fig. 4) [65–67]. This is the major xenoactive antigen that is responsible for hyperacute rejection in xenotransplantation [68,69]. ␣1,3-Galactosyltransferases from porcine and bovine tissues and recombinant bovine ␣1,3-galactosyltransferase have all been used for preparative synthesis, the latter for gram-scale reactions [66,70]. Recombinant porcine ␣1,3-GalT is now commercially available in unit quantities, and a fusion protein comprising UDP-Gal epimerase and ␣1,3-GalT has been engineered for large-scale synthesis [71]. ␣1,3-Galactosyltransferase transfers 3-deoxy-, 4-deoxy-, and 6-deoxy-Gal from the corresponding donor at very low rates ( 870 kDa) with a mean hydrodynamic diameter of polymer chain in aqueous solution grater than 69 nm at ambient temperature. The choice of using aromatic 50 and nonaromatic 45 ␣-mannoside ligands for the glycopolymers was based on the work completed by Firon et al. [157,158]. They discovered that close to mannose binding sites, E. coli has a hydrophobic region that favors aromatic ␣-mannosides such as p-nitrophenyl-␣-D-mannopyranoside. They also noticed that Salmonella species possess a binding site smaller than that of E. coli and devoid of a hydrophobic region. To test the avidity of binding toward specified bacteria cells, a control (56, in comparison with the multivalent counterpart 52B) containing both an ␣-gal monomer moiety and a mannose unit was synthesized. The same Ko¨enigs–Knorr glycosylation method was utilized to prepare 53. It was sequentially deacetylated by the Zemple´n method followed by saponification to give water-soluble 54 with a free carboxylic group. The lactosyl derivative was coupled with p-aminophenyl-␣-D-mannopyranoside by using diphenylphosphoryl azide (DPPA) as a promoter, which was demonstrated to activate glycopeptide coupling in the presence of free hydroxyl groups [159]. The reaction was conducted in DMF at room temperature to give conjugate 55 in 66% yield. Enzymatic galactosylation of compound 55 by using ␣1,3-galactosyltransferase provided the ␣-gal epitope containing conjugate 56. The ␣-gal–mannose glycopolymers were tested for their ability to function as multivalent ligands for the binding of E. coli K-12 HB101 bacterial cells. This E. coli strain contains mannose binding sites located on the surface of bacteria, which can bind yeast (Saccharomyces cerevisiae), resulting in visible agglutination. To evaluate the activity of glycopolymers 49 and 52A-B, their inhibitory effects on agglutination were compared with several controls, including the monovalent methyl-␣D-mannopyranoside, p-nitrophenyl ␣-D-mannopyranoside, ␣-gal-mannose conjugate 56, and polyvalent mannose copolymers 52C-D, with striking results. These results indicated that the glycopolymers 49 and 52A-B were effective in preventing agglutination at concentrations as low as 100 M. In comparison to methyl-␣-D-mannopyranoside, a dramatic increase in the inhibitory efficacy was observed with polyvalent mannose. However, p-nitrophenyl ␣-D-mannopyranoside was found to be the most potent inhibitor. This compound showed strong inhibition at concentrations as low as 90 M. Monovalent conjugate 56 and polymer 52B, bearing a hydrophobic aromatic ring, had comparable inhibitory effects. The polyvalency was unexpectedly overshadowed by van der Waals forces resulting from the packing of the aromatic ring against a hydrophobic binding pocket on the surface of the bacteria. It is noteworthy that no inhibition was observed with p-nitrophenyl ␣-D-galactopyranoside. This indicated that the mannose binding sites were highly specific. The ␣-gal residue was not able to compete with mannose in binding to the bacterial mannose receptors. To assess the activity of ␣-gal–mannose glycoconjugates binding to the antiGal antibodies, a previously reported inhibition-type enzyme-linked immunosorbent assay (ELISA) was conducted [21]. Mouse laminin having ␣-gal epitopes were fixed on ELISA plate as solid phase antigens. Test glycoconjugates were then incubated with human anti-Gal antibodies on the ELISA plate. The plate was washed and incubated with horseradish peroxidase (HRP) conjugated anti-human IgG antibody.
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After additional washing, a chromogenic compound was used to develop the color by an HRP reaction. Monovalent conjugate 56 (Fig. 24) and polymer 52B were tested with two controls: ␣-gal epitope ␣-D-Galp-(1→3)--D-Galp-(1→4)--D-Glcp and mannose copolymer 52D (Table 1). As illustrated in Table 2, conjugate 56 and polymer 52B bind effectively to human anti-Gal antibody. The polyvalency of the ␣-gal epitope on polymer 52B was clearly demonstrated by comparing the inhibition of compound 56 with polymer 52B at the same concentration of ␣-gal epitopes. Not surprisingly, polymer 52D, without having an ␣-gal epitope, did not bind to human anti-Gal antibodies. The results obtained from biological testing of anti-Gal antibodies in yeast mannan to E. coli K12 cells and human natural anti-Gal antibodies prove the efficacy of the constructed glycopolymers and glycoconjugates as potent inhibitors. Crossreactivities of mannose binding to anti-Gal antibodies and ␣-gal residue binding to bacteria were not observed in any of the experiments. These results demonstrate a potential for the viability of ligands to redirect human natural immunity against bacterial pathogens coated with xenoactive epitopes.
Figure 24
Synthesis of a monomeric ␣-gal/␣-mannose conjugate 56.
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Table 1
Agglutination Inhibition Assays
Inhibitor
Inhibiting concentration (M)a
Methyl-␣-D-mannopyranoside p-Nitrophenyl ␣-D-mannopyranoside p-Nitrophenyl ␣-D-galactopyranoside Compound 56 Polymer 49 Polymer 52A Polymer 52B Polymer 52C Polymer 52D
1.5 9.0 >2.0 1.0 1.5 1.0 1.0 1.0 1.0
a
⫻ ⫻ ⫻ ⫻ ⫻ ⫻ ⫻ ⫻ ⫻
10⫺2 10⫺5 10⫺2 10⫺4 10⫺3 10⫺3 10⫺4 10⫺3 10⫺4
Molar concentrations of mannose unit were used in all polymers.
B.
Amplified Binding Differentiation of anti-Gal Isotypes by ␣-gal Polymers
The existence of differentiating anti-Gal antibody isotypes has allowed so-called isotype switching, a distinct process of recognition for antigen–antibody complexation [160]. Recent studies involving newborn baboons heterotropically transplanted with baby pig hearts have elucidated the isotype switch effect. The porcine hearts were rejected 4–6 days posttransplantation [161]. Six days postrejection of the graft, distinct anti-Gal IgM and IgG antibodies were detected. After an additional week, anti-Gal IgG activity increased, whereas that of the IgM isotype decreased. The findings suggest that in course of xenograft rejection by maternal anti-Gal IgG molecules, the immune system of the neonatal baboon responds to ␣-gal epitopes on the xenografts, first producing anti-Gal IgM and subsequently anti-Gal IgG antibody molecules.
Table 2
Binding of the Human Natural Polyclonal anti-Gal Antibody IgG to ␣-gal–Mannose Glycoconjugates as Measured by ELISA
Glycoconjugate Laminin ␣-D-Galp-(1→3)--D-Galp-(1→4)-D-Glcp (0.1 mM) ␣-D-Galp-(1→3)--D-Galp-(1→4)-D-Glcp (1.0 nM) Compound 56 (0.1 nM) Compound 56 (1.0 nM) Polymer 52Ba (0.1 mM) Polymer 52Bb (1.0 mM) Polymer 52Db (0.1 mM) Polymer 52Db (1.0 mM)
OD655 (% inhibition) 0.799 0.427 0.279 0.386 0.278 0.241 0.183 0.784 0.729
(0%) (47%) (65%) (52%) (65%) (70%) (77%) (2%) (9%)
The molar concentrations used in polymer 52B were ␣-gal trisaccharide concentrations. b The molar concentrations used in polymer 52D were mannose concentrations. a
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In a continuation to determine the ␣-gal and anti-Gal binding affinity, neoglycopolymers of polyacrylamide backbone conjugated with varying densities of ␣-DGalp-(1→3)--D-Galp-(1→4)--D-Glcp trisaccharide epitopes (␣-gal epitopes) were designed and synthesized [162]. It is known that carbohydrates are typically expressed on the cell surface in clusters; thus their overall binding capacity with protein receptors (commonly with multiple binding sites) is enhanced over the affinity of individual monovalent ligands through cooperative multiple interactions. Therefore it is a logical choice to use multivalent ligands as potent synthetic inhibitors to effectively block the recognition process. Lee [163–165], Whitesides [147,166,167], Roy [168,169], and others [148,150] in recent years have demonstrated that the multivalent forms of carbohydrate ligands, either polymers or dendrimers, often have amplified inhibitory effects over their monovalent counterparts, although the levels of enhancement vary. Our group has been successful in illustrating that the overall avidity of certain ␣-gal-containing polymers toward anti-Gal antibodies is significantly enhanced by incorporating their ‘‘multivalent’’ or ‘‘polyvalent’’ effects. The synthesis of the ␣-gal-containing polymers was achieved by reacting preactivated poly [N-(acryloyloxy)succinimide] (pNAS) 58 with an ␣-gal trisaccharide derivative 59, followed by capping of the active esters with aqueous ammonia (Fig. 25) [166,167,170–173]. All ␣-gal polymers 60A–60F were prepared from a single batch of pNAS, which was obtained by polymerization of N-(acryloyloxy)succinimide (57). To determine the ‘‘parent’’ molecular weight of the polymer, gel filtration chromatography was preformed after the complete hydrolysis to poly(acrylic acid) sodium salt. The average molecular weight of the hydrolyzed polymer was 252 kDa, with a relatively narrow molecular weight distribution (Mw/Mn = 1.5). By varying the ratio of ␣-gal trisaccharide to active esters in pNAS, a series of polymers with different densities of ␣-gal was obtained. The ratios of ␣-gal unit to acrylamide unit obtained were determined by integrating the proton NMR peaks from the trisaccharide and acrylamide signals. To achieve polymerization of ␣-gal polymers, the important intermediate {N␣-D-Galp-(1→3)--D-Galp-(1→4)--D-Glucp-5-aminopentamide}, 59, was synthesized through a series of well-known reactions beginning with the glycosylation of a thioglycoside donor, 34, and the previously prepared acceptor, 33 [174]. Upon mild hydrogenation utilizing PtO2 in methanol for azido reduction and subsequent reaction with 5-chlorovaleryl chloride, compound 61 was obtained in 87% yield. Debenzylation followed by acetylation and subsequent azide addition to the anomeric valeryl chloride afforded compound 64, which was subjected to the Zemple´n method for deacetylation, yielding compound 65. The ␣-gal trisaccharide 59 was achieved by a very mild reduction procedure. Compound 63 (Fig. 26) was also obtained via an enzymatic glycosylation utilizing bifunctional protein technology, as mentioned earlier (Section III.D). In addition, an even more attractive synthesis of 59 [50,175–178] was achieved by using the bifunctional enzyme [179]. Reaction of disaccharide derivative 67 with UDP-glucose gave compound 59 (Fig. 27) in 52% yield. Polylactose 71 [180–182], with a lactose/acrylamide ratio of 1:1.25, was synthesized as a negative control for bioassays. The synthetic route is illustrated in Figure 28. Compound 68 was obtained in 79% yield by using the same transformation from 35 to 61 illustrated in Figure 25. Azide addition gave 69 in 84% yield.
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Chemosynthesis of ␣-gal-derivatized carbohydrate polymer 60. Reagents: (a) NIS, TfOH, CH2Cl2, 4A MS, ⫺30⬚C, 90%; (b) PtO2, H2, MeOH; (c) 5-chlorovaleryl chloride, Et3N, CH2Cl2, 87% (b and c); (d) Pd/C, H2, MeOH; (e) Py/Ac2O, DMAP, 89%; (f) NaN3, DMF, 70⬚C, 90%; (g) NaOMe, MeOH; (h) PtO2/H2, H2O-MeOH, 93% (g and h); (i) AIBN, PhH, reflux; (j) DMF, rt, 24 h; 65⬚C, 6h; rt, 24 h then NH3 ⭈ H2O, rt, 24 h.
Figure 25
The fully deprotected lactose derivative 67 was then obtained from 69 in 91% yield after deacetylation and hydrogenation. Polylactose 71 with a lactose/acrylamide ratio of 1:2.5 was prepared by reaction of pNAS (58) and intermediate 67, utilizing the same methodology as for the preparation of polymer 60B. Later, ELISA was used in an attempt to quantify the binding affinities of the newly synthesized ␣-gal-containing carbohydrate polymers 60 to anti-Gal antibodies [183]. Purified human (male, blood type AB) anti-Gal antibody was the primary antibody and mouse laminin as a natural source of ␣-gal were employed in the protocol. The concentrations of ␣-gal polymers at 50% inhibition (IC50) of anti-Gal antibody binding to ␣-gal epitopes on mouse laminin were quantified, and the IC50 data were summarized (Table 3). All the IC50 data presented in the text are the net ␣-gal trisaccharide concentrations (micromolar) calculated from the degree of functionalization and polymerization of each polymer, for comparison with the corresponding ␣-gal monomer explicitly. Results indicated that polymers 60A–60D inhibit the antibody with a higher binding affinity than the corresponding ␣-gal trisaccharide ␣-D-Galp-(1→3)--D-
The ␣-gal Epitope
Figure 26
Synthesis of 63 with galE-␣1,3-GT.
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Figure 27
Alternative route to the synthesis of compound 59.
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Figure 28 Synthesis of polylactose 71, with a lactose/acrylamide ratio of 1:2.5, as a control for bioassays. Reagents: (a) PtO2, H2, MeOH, then 2.5-chlorovaleryl chloride, Et3N, 79%; (b) NaN3, DMF, 70⬚C, 84%; (c) NaOMe, MeOH; (d) PtO2/H2, H2O-MeOH, 91% (two steps); (e) pNAS, DMF, rt, 24 h; 65⬚C, 6h; rt, 24 h, then NH3⭈H2O, 24 h.
Galp-(1→4)--D-GlcNAc 11 in all cases. The efficacy can be illustrated by the IC50 result for polymer 60C of 5.6 nM, which is 5.0 ⫻ 104-fold better than its trisaccharide analog 11 in inhibiting anti-Gal IgA. The enhancement proved to be greater for antiGal IgM and IgA than for anti-Gal IgG. For example, the activity enhancement of polymer 60B was 246-, 1.0 ⫻ 104-, and 4.4 ⫻ 104-fold better toward anti-Gal IgG, IgA, and IgM, respectively. This observation is consistent with the increasing numbers of binding sites from IgG to IgA to IgM. In human serum, IgM exists as a pentamer with 10 equivalent binding sites in one molecule; 80% of IgA exists as a monomer with two binding sites and 20% as higher order oligomers with multiple binding sites; IgG exists as a monomer with two binding sites. Therefore, a ‘‘mul-
Table 3 Inhibition of ␣-gal Polymers and Monomer Against the Binding of Purified Human anti-Gal Antibody (male, blood type: AB) to Mouse Laminin IC50 (M)b Compound
Ratioa
IgG
Monomer 11 Polymer 60A Polymer 60B Polymer 60C Polymer 60D Polymer 60E Polymer 60F Polylactose 71
— 1:1.8 1:2.5 1:3.3 1:6.4 1:15 1:29 1:2.5
69 ⫾ 5 0.37 ⫾ 0.08 0.28⫾ 0.05 2.8 ⫾ 0.9 7.2 ⫾ 2.7 60 ⫾ 5 93 ⫾ 16 N/I
IgA 55 0.016 0.0053 0.0070 0.043 0.86
⫾ 16 ⫾ 0.006 ⫾ 0.0023 ⫾ 0.0032 ⫾ 0.017 ⫾ 0.28 — N/I
IgM 277 0.0068 0.0063 0.0056 0.027 165
⫾ 24 ⫾ 0.0016 ⫾ 0.0015 ⫾ 0.0014 ⫾ 0.018 ⫾ 13 — N/I
Ratio of the unit of ␣-gal epitope (or lactose) to that of acrylamide in polymer. The concentration of inhibitor at 50% inhibition of the binding between purified anti-Gal antibody (16 g/mL) and mouse laminin in inhibition ELISA. Errors are reported as 2. N/I = no inhibition. a
b
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tivalent’’ effect is certainly more pronounced for antibodies (IgM, IgA) with increased protein–carbohydrate interaction sites. The effectiveness of ␣-gal polymers varied not only with antibody isotype, but also with the density of ␣-gal epitopes conjugated to the polymer. There was a steady increase inhibition efficacy for IgG and IgA from polymer 60E to 60B with increased ␣-gal densities in the polymers as denoted in Table 3. The same trend was observed for IgM from polymer 60E to 60C. However, polymer 60A, with a higher density of ␣-gal residues, exhibited a lower inhibition than polymer 60B for IgA binding, and the same level as 60B for IgG and IgM. The decrease in activity was rationalized by the thermodynamics of polyvalent interactions in biological systems in accordance with work by Whitesides et al. [147,167]. Negative cooperative interactions and the enthalpically diminished binding can be caused by unfavorable spatial conformation of polymers at high ligand concentration. The enhancements of inhibition by introducing more ␣-gal epitopes in 60A were obviously overcome by the simultaneous formation of noncooperative spatial conformation of the polymer as well as steric hindrance. Similar to the positive cooperative multivalent interactions, this negative effect is prevalent in antibodies with increased binding sites, such as IgA and IgM. Research is in progress to try to elucidate the detailed physical mechanism of the enhancement. To assess the practical application of ␣-gal polymers, inhibition ELISA was used to test intact human serum (male, blood type AB) instead of purified anti-Gal antibody (Table 4). The results also indicated the activity enhancement of the ␣-gal polymers in comparison to the monomer 11. The same trends were also observed in interaction of ␣-gal polymers with different isotypes of the antibody and with the varied densities of the ␣-gal epitope conjugated to the polymer. Interestingly, the IC50 results observed with the purified antibodies were consistently lower than the IC50 results with human sera. One explanation is that the purified antibodies were obtained from affinity column immobilized with ␣-gal trisaccharide similar in structure to the epitope on the polymer. Therefore, subsets of antibodies selected during the purification would bind most tightly to the polymer. Since the purified antibodies
Table 4 Inhibition of ␣-gal Polymers and Monomer Against the Binding of Human Serum (male, blood type: AB) to Mouse Laminin IC50 (M)b Compound
Ratioa
IgG
IgA
Monomer 11 Polymer 60A Polymer 60B Polymer 60C Polymer 60D Polymer 60E Polylactose 71
— 1:1.8 1:2.5 1:3.3 1:6.4 1:15 1:2.5
74 ⫾ 11 12 ⫾ 3 9.4 ⫾ 0.9 18 ⫾ 5 52 ⫾ 8 >500 N/I
306 ⫾ 22 1.14 ⫾ 0.26 0.12 ⫾ 0.04 0.091 ⫾ 0.003 3.3 ⫾ 0.7 >1000 N/I
IgM 268 0.070 0.035 0.031 0.38 89
⫾ 31 ⫾ 0.001 ⫾ 0.002 ⫾ 0.009 ⫾ 0.02 ⫾ 27 N/I
Ratio of the unit of ␣-gal epitope (or lactose) to that of acrylamide in polymer. The concentration of inhibitor at 50% inhibition of the binding between human serum (10 L) and mouse laminin in inhibition ELISA. Errors are reported as 2. N/I = no inhibition.
a
b
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from the affinity column contained 89% of IgM, 50% of IgA, and 42% of IgG of corresponding anti-Gal in human sera [184,185], the increased proportion of IgM in the purified anti-Gal would contribute to the increased inhibitory effect of the ␣-gal polymers. In an attempt to mimic cell transplantation situations, a flow cytometry assay [186,187] was carried out in which the inhibition of synthetic polymers against the binding of human natural anti-Gal antibodies in intact serum to ␣-gal epitopes on pig kidney cells from the American Type Culture Collection (PK15, ATCC) was measured. As expected, results from flow cytometry analysis demonstrated that ␣gal polymers exhibited enhanced inhibition activities in comparison to the monomer 59. With IC50 results of approximately 5.2 and 2.2 M, respectively, high levels of inhibition were achieved with polymers 60A and 60B against anti-Gal IgM binding to PK15 cells. In sharp contrast, the ␣-gal monomer 11 has no significant inhibitory effect up to 1 mM, whereas polylactose did not exhibit any inhibition up to 1 mM (Table 5). In all concentrations tested, in the range from 0.10 to 100 M, no inhibition was observed with monovalent ␣-gal trisaccharide. Clearly, the enhancement of inhibitory activity of the polymer is concentration dependent. At net trisaccharide concentration of 0.1 M, the enhancement of the polymer over the monomer was minimal, while at concentrations of 100 M, the inhibition of anti-Gal binding to PK15 cells by the polymer jumped to 68%. Our results also demonstrated that IC50 results of the polymers against antibody binding to cells were much higher (orders of magnitude) than the values for binding to laminin. This may be ascribed to the lower density of epitopes on the cell surface [20,184,188–190]. Moreover, the concentration of human sera used in cell assay was 2.5 times higher than that in laminin assay, which would bind more ␣-gal epitopes on the polymer. Other factors such as non-␣-gal antigen–antibody binding may contribute to the discrepancy in tandem [191]. In summary, the synthetic ␣-gal-conjugated polymers significantly enhanced activities in inhibition of human anti-Gal antibody binding to mouse laminin glycoproteins and mammalian PK15 cells. The significance to these findings extends into the amplified binding differences among the three anti-Gal isotypes, which can be selectively inhibited as a means for deciphering the various isotype antibodies.
Table 5 Inhibition of ␣-gal Polymers and Monomer Against the Binding of Human Serum (male, blood type: AB) to Pig Kidney (PK15) Cells IC50 (M)b Compound
Ratioa
IgG
IgA
IgM
Monomer 11 Polymer 60A Polymer 60B Polymer 60C Polylactose 71
— 1:1.8 1:2.5 1:3.3 1:2.5
⬃1000 595 407 774 N/I
>1000 — 63 — N/I
>1000 5.2 2.2 >1000 N/I
Ratio of the unit of ␣-gal epitope (or lactose) to that of acrylamide in polymer. The concentration of inhibitor at 50% inhibition of the binding between human sera and pig kidney cells in flow cytometry assay. N/I = no inhibition.
a
b
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The flow cytometry analysis proved that certain ␣-gal polymers were effective in inhibiting anti-Gal antibodies in human serum binding to pig kidney cells. Thus, such carbohydrate polymers can serve both as tools for evaluation of ␣-gal–anti-Gal interactions and as immunosuppressors in cell xenotransplantations.
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17 Microbial Glycosyltransferases Przemyslaw Kowal, Xi Chen, and Peng George Wang Wayne State University, Detroit, Michigan
I.
INTRODUCTION
Polysaccharides, besides nucleic acids and proteins, are the third class of macromolecules, yet they constitute the largest part of the planet’s biomass [1]. Unlike the linear nucleic acid and protein molecules, polysaccharides exhibit highly branched structures and a multiplicity of different, although related, types of linkage known as glycosidic bonds. Enzymes that catalyze the formation of these glycosidic bonds are referred to as glycosyltransferases (GTs). These enzymes use activated sugar molecules (donors) to attach saccharide residues to a variety of substrates (acceptors). The donor molecules most often are nucleotide diphospho sugars (e.g., UDP-Glc) but can also be sugar phosphates or disaccharides. The most common acceptor molecules are growing carbohydrate chains; however, a variety of other compounds such as lipids, proteins, or steroids can also serve this function [2]. Generally, glycosyltransferases are divided into two groups: processive and nonprocessive. Processive group enzymes are usually found in eukaryotic systems and include enzymes such as cellulose synthase and chitin synthase that are capable of sequentially attaching multiple residues to a growing carbohydrate chain. Most microbial transferases are nonprocessive and are responsible for the addition of single sugar residues. They are involved in the synthesis of complex polysaccharide structures with few or no repeating residues. These include various forms of lipopolysaccharides (LPS), the repeat units of succinoglycan and O-antigens on the surfaces of bacterial cells. The biological significance and functions of these complex structures have only recently begun to be unraveled. Polysaccharide synthesis does not follow a linear template, and the mechanisms that govern this synthesis are difficult to elucidate. Generally, glycosyltransferases display flexibility in their recognition of donor and acceptor substrates, a fact that 625
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has been exploited in the synthesis of natural and unnatural oligosaccharides. Glycosyltransferase specificities come from the recognition of some critical hydroxyls in their substrates where modifications are not tolerated. This is seen in the case of glucosyltransferases and galactosyltransferases that distinguish their respective substrates solely on the basis of the orientation of the hydroxyl at the fourth carbon. However, the exact in vivo substrate specificities of majority of GTs have not been determined. In the majority of cases, the formation of each type of glycosidic bond requires a different enzyme, and sometimes, different enzymes (encoded by separate genes) can form the same bond type. Bacterial glycosyltransferases, the topic of this chapter, are enzymes responsible for the assembly of bacterial cell walls (e.g., succinoglycan) and lipopolysaccharides or polysaccharide structures attached to the lipids of the outer membrane of gram-negative bacterial cells. Referred to as endotoxins because of their physiological and pharmacological properties, lipopolysaccharides are at the forefront of bacterial interactions with the outside world. These structures have been found to be essential in processes ranging from root nodulation to human pathogenicity. Therefore studies on the corresponding glycosyltransferases are of great importance and interest. II.
GLYCOSYLTRANSFERASES
Glycosyltransferases are enzymes involved in the synthesis of oligosaccharides and the transfer of sugar moieties to free hydroxyls or amine groups of a variety of nonsugar substrates. The reaction catalyzed by these enzymes is: Nucleotide—sugar ⫹ R—OH → R—O—sugar ⫹ nucleotide where R can be a free saccharide, glycoprotein, glycolipid (aglycone), or protein and lipid. The enzyme nomenclature comes from the donor specificity of these molecules; these enzymes that transfer glucose are termed glucosyltransferases, those utilizing galactose are called galactosyltransferases and so forth. Inversion or retention of anomeric configuration in conversion from donor to acceptor can be used as a means of further classification of this enormously varied group of molecules. A.
Catalytic Mechanism
Although the details of catalysis by glycosyltransferases have not been elucidated per se, a likely mechanism has been proposed by analogy to glycosyl hydrolases [3,4]. Glycosyltransferases share two major catalytic mechanisms [5]. The reaction can result in either retention or inversion of configuration at the anomeric carbon. Since nucleotide diphospho sugars (the most common donors) have the ␣ configuration, ␣-glycosyltransferases are said to proceed with retention, while -glycosyltransferases proceed with the inversion of the anomeric configuration. A single nucleophilic attack is necessary to generate the inversion of configuration in the so-called inverting enzymes (Fig. 1A). The retention mechanism is likely to involve a glycosyl enzyme intermediate (Fig. 1B), which forms from an oxocarbenium transition state [6]. B.
Processive or Nonprocessive: Structure–Function Relationship
Glycosyltransferase enzyme structure is divided into two domains: N-terminal domain A and C-terminal domain B. It has been noted that all glycosyltransferases
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Figure 1
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The catalytic mechanism of glycosyltransferases. (A) Inversion mechanism consisting of a single nucleophilic attack by the acceptor on the activated donor anomeric carbon. (B) Retention mechanism involving double nucleophilic substitution. The enzyme became transiently glycosylated and serves as the sugar donor in the subsequent steps [5]. The reaction goes through a proposed oxocarbenium transition state (middle left structure) [6]. Since aspartate and glutamate residues have been shown to be conserved and necessary for catalysis (see text), the general base and general acid functionalities shown are carboxylate groups. However, other functional groups could also perform these functions.
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share domain A, while the processive enzymes contain both domains A and B [5]. This has led to an assignment of functions for the respective domains. Domain A is thought to contain two sites, one responsible for binding the activated sugar donor and the other for binding the acceptor molecule. Domain B is thought to bind a second activated donor molecule so that the processive enzymes can add two sugars to the growing chain either at the same time or in quick succession. The double addition is important because it restores the orientation of the polysaccharide’s end. Polysaccharides such as cellulose or chitin adopt a twofold screw axis [7–9], and the addition of a single residue would result in a different conformation of the reducing end with respect to the rest of the polymer. A double addition could, in principle, also be accomplished if the processive enzyme used an activated disaccharide donor such as UDP-cellobiose. However, this has not been observed in living systems.
C.
Glycosyltransferase Structure
Other studies on the structure of glycosyltransferases have uncovered that groups of amino acid residues necessary for catalysis are usually conserved within families of proteins. This is exemplified by two ␣-glucosyltransferases: ␣-1,3-glucosyltransferase (RfaI) [10] and ␣-1,2-glucosyltransferase (RfaJ) [11]. Both proteins have been analyzed by means of hydrophobic cluster analysis (HCA) [12,13] and site-directed mutagenesis. The results revealed the existence of four highly conserved regions in RfaI, RfaJ, and other related proteins (Table 1). Within these regions there are four critical aspartic acid residues which, when replaced by site-directed mutagenesis, abolish the activity of the enzymes. These latest studies were further supplemented with the publication of the crystal structure of a nucleotide diphospho sugar transferase SpsA from Bacillus subtilis [14], the only currently available microbial glycosyltransferase structure. (The other two glycosyltransferases structures published are DNA-modifying -glucosyltransferase from bacteriophage T4 [15] and bovine -1,4-galactosyltransferase catalytic domain [16].) SpsA protein is a member of family 2 glycosyltransferases (see Ref. 17 for family classification) and is an inverting enzyme. The 256-residue nonprocessive protein is most likely involved in the production of mature spore coat of B. subtilis, but its natural substrate has not been determined. The structure reveals that residues 2–100 form the donor nucleotide binding site, which consists of four parallel  strands flanked by two ␣ helices. The remaining residues are folded into a  sheet, which is flanked by ␣ helices and forms a groove that binds the acceptor molecule. A cocrystal of SpsA and UDP shows the interactions between the protein and the donor nucleotide. The uracil stacks with Tyr 11. The binding of the base is further stabilized by a hydrogen bond between an invariant Asp 39 and N3 of uracil. Asp 99 coordinates to the Mn2⫹ ion bound to the phosphate moieties. Further binding interaction is provided by Lys 13, which forms a hydrogen bond with the ␣ phosphate. Two other aspartate residues, Asp 158 and Asp 191, hydrogen-bond to a glycerol molecule that is thought to occupy the acceptor binding site. Owing to its ideal placement, Asp 191 is suspected of being the catalytic residue. However, the bound glycerol molecule makes that assignment somewhat uncertain.
Alignmment of RfaI, RfaJ, and Related Proteinsa
Microbial Glycosyltransferases
Table 1
a
The four highly conserved regions are shown with the number of the residue at which they begin. Shaded areas correspond to the residues that deviate from the conserved sequences. Symbol x indicates residues that, when replaced, abolish the catalytic activity [11].
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Classification of Microbial Glycosyltransferases
Microbial glycosyltransferases are an extremely diverse group of enzymes. Their classification is made difficult by the lack of knowledge about their structure, functions and substrate specificities. Formally, glycosyltransferases are listed by the Enzyme Commission under EC 2.4.x.y registry numbers. They can be classified based on the reaction catalyzed and the substrate specificity according to the recommendations of the International Union of Biochemistry and Molecular Biology (IUBMB) [18]. A complementary classification scheme has been proposed that also considers sequence and structural feature similarities and how they relate to functions [17]. Such schemes have already been applied to a related group of enzymes, the glycosyl hydrolases [19]. To classify GTs, researchers [17] retrieved 35 known hexosyltransferase enzyme sequences and used them to perform BLAST similarity searches [20] with sequences available from the Swiss-Prot and EMBL/GenBank databases. The sequences were further compared by means of the hydrophobic cluster analysis method [12,13] and classified into 26 families on the basis of HCA similarity over a sequence of at least 100 amino acids (see Ref. 17). Hydrophobic cluster analysis is a sequence comparison and alignment method introduced by Gaboriaud and others in 1987 [12]. The method relies upon twodimensional representation of protein sequences to determine regions of probable structural similarity. The method has been successfully applied [5,17,21] to detect regions of structural similarity even in proteins with little sequence identity and when little or no three-dimensional information is available.
III.
GLYCOSYLTRANSFERASES IN NATURE: STRUCTURE OF THE BACTERIAL LIPOPOLYSACCHARIDES
Bacterial cells express an enormous variety of polysaccharide structures. Usually found protruding from the outer membrane, these entities include exopolysaccharide (EPS), lipopolysaccharide (LPS), and lipo-oligosaccharide (LOS). EPS can be found in both gram-positive and gram-negative cells and is made of repeating polysaccharide units. Membrane-attached EPS forms the cell capsule. However, it can also be released into the surrounding medium as slime. LPS is composed of lipid A, core polysaccharide, and O-antigen, whereas LOS is a variation of LPS that lacks the repeating units of the O-antigen. In some gram-negative cells (e.g., E. coli and Salmonella typhimurium), the outer leaflet of the outer membrane can be composed almost exclusively of lipid A molecules. Lipid A in E. coli [22,23], Salmonella typhimurium [24,25], and Neisseria meningitidis [26] consists of two ,1-6-linked 2,3-diacylglucosamine units. The fatty acid chains attached to the 2- and 3-positions are generally 2–6 carbons shorter than their counterparts in glycerophospholipids. In addition, the 2,3-diacyl chains contain an R-3-hydroxyl substituent. The R3-hydroxyls of the nonreducing sugar are esterified with laurate and myristate fatty acids. The structure is phosphorylated at the 1- and 4⬘-positions. The core polysaccharide is attached at the 6⬘-position of lipid A. The inner core consists of a KDO (3-deoxyD-manno-octulosonic acid) region and a heptose (Hep) region (Fig. 2). The number of residues varies between species.
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Figure 2 Schematic representation of the LOS structure of N. meningitidis and N. gonorrhoeae. Variations in the largest ␣ chain are responsible for most of the immunogenic properties of the LOS. Abbreviations: KDO, 3-deoxy-D-manno-2-octulosonic acid; Hep, L-glyceroD-manno-heptose; Glc, glucose; GlcNAc, N-acetylglucosamine; PEA, phosphoethanolamine. Note: C11 indicates an additional 11 carbon atoms, not the total chain length.
A.
LOS Biosynthesis in N. meningitidis and N. gonorrhoeae: A Case Study
The pathogens Neisseria gonorrhoeae and Neisseria meningitidis have received much attention in the last few years. Neisserial lipo-oligosaccharide (LOS) is distinct from the LPS of the enteric gram-negative bacilli. The differences include phosphorylation patterns, composition and attachment of acyl chains, and the lack of the repeating O-antigen characteristic of the enteric species. In Neisseria species, the core region consists of Hep2-Kdo2 unit that is further elaborated with oligosaccharide chains ␣, , and ␥. The ␣ chain is attached to Hep I of the core polysaccharide through a glucose residue. Chains  and ␥ are attached to the Hep II residue. The ␣ chain is of the most interest because it is the largest of the three and is responsible for most of the antigenic properties of the pathogens. It consists of only 2–5 sugar residues attached to the inner core structure, and the repeating units of the O-antigen are lacking. Length and composition of the ␣ chain are strain dependent. Antigenic variation caused by changes in the expression of immunotypes on the surface of the cell enables the cells to invade a host organism and evade its immune system [27,28].
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Various immunotypes express differing LOS structures. The N. gonorrhoeae strain F62 ␣-chain LOS structure and the enzymes involved in its biosynthesis are shown in Fig. 3. B.
Genes Involved in LOS ␣-Chain Synthesis
The genes encoding the proteins involved in LPS synthesis are spread throughout the bacterial chromosome. Many have been found in loci that contain clusters of genes. Interestingly, many of these genes have been found to be coexpressed with protein involved in aspects of cellular metabolism. For example, the KDO biosynthesis genes are found together with genes for glycolysis enzymes. Morse et al. [29] have observed that the changes in glucose metabolism are correlated to the changes in the LOS profile of N. gonorrhoeae. These changes have also altered complementmediated killing of the cells by human sera. Further, Tsai et al. [30] have observed that modifications in LOS profiles in N. meningitidis can be afforded by changes in growth media composition. All the transferase genes involved in the synthesis of the ␣ chain of meningococcal and gonococcal LOS are found in the lgt (lipo-oligosaccharide glycosyl transferase) cluster [27,31]. The lgt cluster contains up to five genes designated lgtA through lgtE. The functions of these genes have been elucidated and are listed in Fig. 3. C.
Poly-G Tracts and Variation of LOS Expression in Neisseria Species
The genetic mechanism of the variability of LOS expression in N. gonorrhoeae has been uncovered [32–35]. Three genes, lgtA, lgtC, and lgtD, in the lgt locus contain polyguanine (poly-G) tracts that code for glycine residues in the enzymes. It has been found that the length of the poly-G tracts in lgtA and lgtC is variable and undergoes slipped-strand mispairing. This mechanism inserts or deletes a G residue, leading to the rest of the gene being out of frame and therefore resulting in a truncated, inactive transferase. The variability in the expression of the transferase genes is reflected in the changes in LOS structure present on the surface of the cells. The variation has been found to occur at a frequency of once in 100–1000 generations [32].
IV.
SYNTHETIC APPLICATIONS OF GLYCOSYLTRANSFERASES
Over the past few years, glycosidases have been widely used for the preparation of a broad spectrum of glycoconjugates and derivatives employing either transglycosylation or reverse hydrolysis reactions [36]. The synthetic use of glycosyltransferases, especially of microbial origin, has so far been very limited. This is mainly due to two factors: low availability and high cost of both the enzymes and the nucleotidesugar donor cofactors. Currently, only five glycosyltransferases, all eukaryotic in origin, are commercially available: ␣1,3-glucosyltransferase, 1,4-galactosyltransferase, ␣1,2-mannosyltransferase, ␣2,3-sialyltransferase, and ␣2,6-sialyltransferase. These range in price from $25/unit to as much as $1800/unit (unit is defined as the transfer of 1 mol of sugar from donor to acceptor in 1 min at 37⬚C). However, the
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Figure 3 Structures of the two alternative ␣ chains of meningococcal LOS. The residues are attached in sequence by the transferases as shown. Transferases encoded by the IgtA, IgtC, and IgtD genes contain the poly-G tracts and are responsible for the phase variation in LOS. In fact, structure II is made only if IgtA is inactive. At certain stages of meningococcal infections, the chain may further be sialylated.
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number of microbial glycosyltransferases that have been overexpressed is continually increasing (Table 2) [14,37–62]. The commercially available enzymes have been employed in the synthesis of a large variety of natural and unnatural oligosaccharides [63–65]. The cost of nucleotide-sugar donors is also very high. UDP-Gal, used in the synthesis of the wellknown ␣-gal (Gal␣1-3Gal-R) epitopes is listed at $4000/g, making its stoichiometric use prohibitively expensive. A.
Making Oligosaccharides Accessible
There are three general approaches to oligosaccharide preparation. The first approach is the isolation of the desired compound from its natural source. This is, however, a very laborious and time-consuming method and may yield only small quantities of the desired product. The second and most well-established approach is to use chemical synthesis. There are a variety of methods available, but the synthesis is also time-consuming and requires much expertise. Multiple protection and deprotection steps for both donor and acceptor components are necessary to ensure desired regioand stereoselectivity. Enzymatic synthesis, as a third approach, is becoming a viable alternative to chemical synthesis, especially with increasing availability of recombinant and natural glycosyltransferase enzymes. The obvious advantages of enzymatic preparations are that they can be carried out in mild conditions, do not require protection and deprotection steps, and ensure required regio- and stereospecificity. As more and more glycosyltransferases became available, the remaining problem will be the cost of the nucleotide-sugar cofactors. Two approaches are being pursued to circumvent this predicament. The first is to change the donor requirement of the transferase by coexpressing it with an epimerase. For example, we have engineered a bacterial strain [unpublished data] that contains a plasmid-encoded fusion protein that consists of UDP-Gal-4-epimerase and bovine ␣-1,3-galactosyltransferase, the latter being a key enzyme in the biosynthesis of a terminal structure Gal␣1,3Gal1,4Glc(NAc)-R, known as ␣-Gal. This epitope has been implicated in the hyperacute rejection of tissue grafts in xenotransplantation [66–68]. The fusion with the epimerase enables us to use UDP-Glc instead of UDP-Gal, to enzymatically attach a galactose to lactose of N-acetyllactosamine as shown in Fig. 4. This affords a 40-fold cost reduction in production of the ␣-Gal trisaccharide. The second approach to the production of oligosaccharides is pathway engineering. This methodology has already been applied to the synthesis of variety of interesting compounds. Its use in the production of oligosaccharides was pioneered by researchers at the Tokyo Research Laboratories, Kyowa Hakko Kogyo Co., Ltd. [69]. The authors engineered three strains of bacteria and coupled them to produce UDP-galactose and globotriose. A recombinant strain of E. coli was engineered with UDP-Gal biosynthetic genes (galactose-1-phosphate uridyltransferase, galT; galactokinase, galK, glucose 1-phosphate uridyltransferase, galU; and pyrophosphatase, ppa). Corynebacterium ammoniagenes was used to convert inexpensive orotic acid to UTP. Finally, the production of globotriose (Gal␣1,4Lac) was accomplished in another recombinant E. coli strain that expressed the Neisseria gonorrhoeae lgtC gene encoding ␣-1,4-galactosyltransferase. The same methodology was also applied to the large-scale production of Nacetyllactosamine [70]. As before, three bacterial strains were coupled together. C.
Microbial Glycosyltransferase Enzymes for Which an Overexpression System Has Been Developed
Description
a
2.1.4.182
2.4.1.4
2.4.1.10
2.1.4.10
Organism
Accession numbera
Ref.
Acetobacter xylinum Bacillus subtilis Bacillus subtilis Bradyrhizobium japonicum Chlamydia pneumoniae Erwinia herbicola Erwinia herbicola Escherichia coli Haemophilus influenzae Helicobacter pylori Mycobacterium avium Neisseria gonorrhoeae Neisseria meningitidis Neisseria meningitidis Neisseria meningitidis Neisseria meningitidis Neisseria polysaccharea Photobacterium damsela JT0160 Pseudomonas aeruginosa Pseudomonas syringae Rhizobium leguminosarum Rhizobium leguminosarum Rhizobium leguminosarum Sinorhizobium meliloti Sinorhizobium meliloti Streptococcus equisimilis Streptococcus pyogenes Synechocystis sp. Zymomonas mobilis
U37258 P54166 P39621 L22756 Z31593 P21686 Q01330 P17443 P45011 AF008596 AF060183 U60664 U60663 U25839 U25839 U65788 AJ011781 AB012285 L28170 O68609 X94963 X94963 AF050103 P33695 P04341 AF023876 L20853 D90911 2107190A
37 38 39,14* 40 41 42 42 43 44 45 46 47 47,48 49 50 50 51 52 53,54 55 56 56 56 57 58 59,60 60 61 62
Accession numbers starting with P-Q are from the Swiss-Prot databank, others from the EMBL/GenBank (*crystal structure reference).
635
␣-Mannosyl transferase AceA Glc transferase YpfP (processive) SpsA protein Fucosyltransferase NodZ KDO-transferase KdtA (multifunctional) Zeaxanthin glucosyltransferase Zeaxanthin glucosyltransferase N-Acetylglucosamine transferase Lipid A disaccharide synthase LpxB ␣-1,3-Fucosyltransferase (HpfucT) Rhamnosyltransferase RtfA ␣-2,3-Sialyltransferase ␣-2,3-Sialyltransferase -1,3-GlcNAc transferase LgtA -1,4-Gal transferase LgtB ␣-1,4-Gal transferase LgtC Amylosucrase (processive) ␣-2,6-Sialyltransferase Bst Rhamnosyltransferase rhlAB Levansucrase lsc Galactosyltransferase LpcA KDO transferase LpcB Mannosyltransferase LpcC -1,4-Glc transferase ExoM GlcNAc transferase NodC Hyaluronan synthase 1 Hyaluronan synthase 1 Sucrose-phosphate synthase SpsA Levansucrase SucZE2
EC number
Microbial Glycosyltransferases
Table 2
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Figure 4 The fusion of epimerase (UDP-Gal-4-epimerase) and ␣1,3GalT (bovine ␣1,3 galactosyltransferase-EC 2.4.1.151) enables the use of UDP-Glc instead of UDP-Gal, a 40fold reduction in the cost of production of the ␣-Gal epitopes.
ammoniagenes was used to produce UTP from orotic acid, and an E. coli strain was engineered to express the UDP-Gal biosynthetic pathway. Another E. coli strain expressed recombinant lgtB gene from N. gonorrhoeae, encoding a -1,4-galactosyltransferase. The authors were able to obtain 107 g/L of product after a 38 h incubation period by supplying the cells with orotic acid, galactose, and N-acetylglucosamine (Fig. 5). This production system has the obvious advantages of not requiring purification of the enzymes involved and generating a final product in high yields from inexpensive starting materials. The only drawback seems to be the need to use multiple bacterial strains. V.
CONCLUSION
Carbohydrate research has lagged behind work done on the other two well-known macromolecules, proteins and nucleic acids. This was mostly due to the enormous variety and complexity of oligo/polysaccharide structures found in nature. With the discovery of the multiplicity of roles now assigned to carbohydrate molecules, there is an increasing need for methodologies that will allow researchers access to these structures. Organic synthetic methods are available for the production of oligosaccharides but carry disadvantages that make them difficult to apply. Enzymatic synthesis of carbohydrates is still in its infancy. Low availability of transferase enzymes and high cost of the activated sugar donor molecules make these methodologies prohibitively expensive. However, new methodologies are being developed that are focusing on two fronts: increasing the availability of glycosyltransferases and lowering the cost of cofactors. Finally, whole-cell systems are being developed that address both of these targets. These do not require the purification of the enzymes or the input of costly sugar donor molecules, and they can produce desired oligosaccharides in high quantity. Besides the functions they serve in the natural environment, novel applications are being sought for carbohydrates. Oligosaccharide moieties are used as vaccines in prevention of variety of microbial infections. Recently, new polysaccharide conjugate vaccines have been developed [71]. Polysaccharides have been discovered to have antibacterial properties. One such example is the modified disaccharide moiety of vancomycin, which alone exhibits novel antibacterial
Microbial Glycosyltransferases The production systems for globotriose (Gal␣1,4Lac) [69] and N-acetyllactosamine [70] as designed by researchers at the Tokyo Research Laboratories, Kyowa Hakko Kogyo Co. Ltd. Both IgtB and IgtC were from Neisseria gonorrhoeae.
Figure 5
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properties by inhibiting the transglycosylation step in peptidoglycan synthesis [72]. Immunoreactive oligosaccharides, such as the ␣-Gal epitopes have been used to enhance the immunogenicity of a tumor vaccine [73]. The need for oligosaccharides will grow in proportion to the number of their applications. Cost-effective methods of their synthesis are clearly needed. It is also clear that much further work will be required in this field. Only three glycosyltransferase crystal structures are currently available, and only one of these is a microbial glycosyltransferase [14]. The exact mechanism of action of these enzymes still awaits elucidation. However, as more and more of glycosyltransferase enzymes became available, their synthetic usefulness will inevitably increase and, as the first wholecell attempts [69,70] show, the use of microbial glycosyltransferases can be facile, efficient, and full of possibilities. REFERENCES 1. 2. 3. 4. 5. 6. 7. 8. 9. 10. 11. 12. 13. 14. 15. 16. 17. 18.
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18 Metabolic Substrate Engineering as a Tool for Glycobiology Scarlett Goon and Carolyn R. Bertozzi Howard Hughes Medical Institute and University of California, Berkeley, California
I.
INTRODUCTION
The biological importance of oligosaccharides was first recognized in the context of their role in metabolism and energy storage. During the past three decades, it has become apparent that complex oligosaccharides also regulate many of the fundamental processes occurring in a biological system. Of special interest are the oligosaccharides found on the surfaces of cells (Fig. 1), which guide their social behavior. Among many other responsibilities, oligosaccharides mediate cell–cell interactions, regulate the serum half-life of glycoproteins, and serve as specific ligands for bacteria, viruses, and parasites [1]. Progress toward the elucidation of oligosaccharide function has historically been impeded by their structural complexity and heterogeneity on cells [2]. The biosynthesis of glycoconjugates is determined by various factors, including the relative abundance and specificity of glycosyltransferases (the enzymes that build oligosaccharides one saccharide at a time), the spatial localization of these enzymes, the availability of nucleotide sugar donors, and the nature of the underlying substrate. Collectively, these factors result in a diverse array of heterogeneous structures that are difficult to control by using conventional genetic and biochemical tools. Considerable creativity has been exercised in the development of strategies for modulating oligosaccharide structures on cell surfaces in a well-defined fashion. For example, specific glycosidase and glycosyltransferase inhibitors [3–8] have provided insight into the biosynthesis of glycans as well as their roles in biological processes. Glycosyltransferases have been used to modify cell surface glycans by exogenous treatment [9–11]. Another approach, the subject of this chapter, is to intercept metabolic pathways with unnatural monosaccharide substrates. If incorporated into cell 641
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Figure 1
The landscape of the surfaces of cells.
surface oligosaccharides, modified sugars can aid in the elucidation of biological function (Fig. 2). Alternatively, modified substrates might block biosynthetic enzymes, producing phenotypes similar to those induced by glycosyltransferase inhibitors. We summarize here the historical development of metabolic substrate engineering as a tool for glycobiology. This chapter focuses on the journey of carbohydrate precursors and synthetic carbohydrate analogs through the metabolic pathways of the cell and the information that can be gained from investigating such processes. We begin with an overview of the structures of glycoconjugates on cell surfaces (for more comprehensive reviews, see Refs. 2, 12–14, and 24). Next, the pathways of monosaccharide interconversions inside the cell are summarized, providing a framework for opportunities in unnatural monosaccharide metabolism. Specific examples of modified sugars and their effects on cells are then presented. Finally, the biosynthetic pathway of sialic acid is discussed with respect to its utility for cell surface oligosaccharide engineering. II.
PROTOTYPICAL GLYCOCONJUGATES ON CELL SURFACES
Cell surface glycoconjugates can be grouped into four main classes: N-linked glycoproteins, O-linked glycoproteins, glycosyl phosphatidylinositol (GPI)-anchored proteins, and glycolipids. These are the major cell surface hosts of monosaccharides derived from intracellular metabolism. N-Linked glycosylation in eukaryotes is a cotranslational event that occurs in the endoplasmic reticulum (ER) [2,16]. It is found almost exclusively on proteins that contain the consensus sequence AsnXaaSer/Thr (where Xaa is any amino acid except Pro). Glycosylation of the asparagine residue in the appropriate sequon is mediated by a membrane-bound enzyme oligosaccharyl-
> Figure 2
Metabolic substrate engineering as a strategy for modulating cell surface oligosaccharide structure. Modified metabolic substrates can intercept a biosynthetic pathway in two ways: the pathway might be inhibited, leading to truncated structures on the cell surface, or the modified substrate might be incorporated into oligosaccharides in place of the normal substrate.
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transferase. This enzyme transfers an oligosaccharide with the structure Glc3Man9GlcNAc2 from a dolichol diphosphate precursor to the side chain of particular asparagine residues in the polypeptide chain (Fig. 3). During its journey through the secretory pathway, this tetradecasaccharide is first trimmed and then elaborated to form an N-linked glycan with a high-mannose, hybrid, or complex-type structure [16,17]. Examples of these structures are shown in Fig. 4 [25]. Unlike N-glycosylation, O-glycosylation begins with the transfer of a single monosaccharide residue, usually GalNAc, to a serine or threonine residue of the polypeptide chain [12]. The GalNAc residue is then further elongated through stepwise enzymatic modifications by glycosyltransferases, giving rise to specific core structures. To date, eight core structures have been identified by NMR spectroscopy or mass spectrometry (Fig. 5) [26–30]. These glycans can then be further elaborated by the addition of a sialic acid or Fuc residue, sulfate, methyl, acetyl, or poly-N-acetyllactosamine units. A subset of O-glycoproteins are the proteoglycans, which present long glycosaminoglycan chains from a peptide-proximal xylose residue (Fig. 6). GPI anchors are involved in cell signaling, protein targeting, and protein secretion [15,23]. The addition of a GPI anchor to a polypeptide is a posttranslational event that occurs in the endoplasmic reticulum (ER). The structures of GPI anchors are very complex. The core structure, consisting of ethanolamine, Man residues, GlcN, and phosphatidylinositol, is conserved from protozoan to mammalian organisms (Fig. 7). However, the peripheral structures vary through species and cell type. The conserved GPI core can be further modified by the addition to the core mannoses of ethanolamine phosphate residues, GalNAc residues, and Man residues. This entire structure is then bound to a lipid that is embedded in the membrane. Similar to Nglycosylation, GPI modification of proteins involves the transfer of a preassembled precursor, en bloc, to the C-terminus of a target protein by amide bond formation with the ethanolamine group. Glycolipids present oligosaccharide epitopes immediately proximal to the plasma membrane [18–22]. Most glycolipids can be classified into three major groups: sphingolipids, gangliosides, and glycero- and isoprenol-glycolipids [31]. The biosynthesis of glycolipids proceeds by stepwise addition of monosaccharide units to a lipid carrier in the compartments of the secretory pathway. As in the case of glycoprotein biosynthesis, the transfer of nucleotide-activated monosaccharides is mediated by glycosyltransferases. An example of a ganglioside, GM3, is shown in Fig. 8 [32].
III.
OVERVIEW OF METABOLIC SUBSTRATE ENGINEERING
The complex glycoconjugates expressed on eukaryotic cell surfaces (Figs. 3–8) comprise primarily 10 monosaccharides: Glc, Gal, Man, Fuc, GlcN, GlcNAc, GalNAc, Xyl, GlcUA, and sialic acid (Neu5Ac). These sugars can be biosynthesized de novo within a cell, often from Glc; or, in many cases, key metabolic intermediates can be supplied exogenously to a cell. The pathways for these interconversions are summarized in Figure 9 [33–36]. If the enzymes in these biosynthetic pathways could tolerate unnatural substrates, subtle modifications, such as replacement of a hydroxyl group with a hydrogen atom or halogen, could be introduced into cell surface glycans. This possibility attracted the attention of many groups interested in understanding how specific carbohydrate structures dictate molecular and cellular interactions. (text continues on p. 652)
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Figure 3 The oligosaccharide Glc3Man9GlcNA2 is a common precursor in the biosynthesis of the three types of N-linked oligosaccharides.
646 Examples of the three types of N-linked oligosaccharides found in human ␣-galactosidase A. Their common core structure is shown
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Figure 4 in gray.
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Figure 5 The eight O-linked core structures characterized to date: core 1, Gal1,3GalNAc; core 2, Gal1,3(GlcNAc1,6)GalNAc; core 3, GlcNAc1,3GalNAc; core 4, GlcNAc1,3(GlcNAc1,6)GalNAc; core 5, GalNAc␣1,3GalNAc; core 6, GlcNAc1,6GalNAc; core 7, GalNAc␣1,6GalNAc; core 8, Gal␣1,3GalNAc.
648
Figure 6
The core region of heparin and heparan sulfate. Goon and Bertozzi
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Figure 7
The conserved core structure of GPI anchors found in mammals. 649
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GM3.
Figure 8
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Metabolic Substrate Engineering Monosaccharide interconversions in eukaryotic cells. Structures in squared boxes serve as exogenous substrates. Structures in rounded boxes are the activated monosaccharide donors. For simplicity, reactions are shown to progress in the forward direction.
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Some early attempts at metabolic oligosaccharide engineering using halogenated and deoxy sugars resulted in cell death. In retrospect, we now know that some of these compounds are inhibitory of intracellular biosynthetic pathways [37,38]. However, the toxicity of halogenated and deoxy sugars could possibly be exploited therapeutically for antiviral, antibacterial, or anticancer therapy. Examples are presented in detail later in this chapter. Remarkably, some unnatural monosaccharides were shown to access the metabolic pathways within cells. Some analogs were transformed only to an intermediate stage in the biosynthesis, never reaching the cell surface as a glycoconjugate component. Nevertheless, through the study of the imbalances in metabolic intermediates induced by these compounds, much has been learned about the specificities and roles of the enzymes involved. Perhaps most interesting of all has been a small, but growing number of compounds that successfully navigate glycoconjugate biosynthetic pathways and are presented on the cell surface. Such analogs, discussed in detail later, fall into two major categories. First, deoxy sugars, when incorporated into glycans, can lack the necessary hydroxyl groups required for further elaboration of the glycoconjugate, thereby resulting in cell surfaces deficient in some distal epitopes. The other category of compounds, exemplified by ManNAc derivatives that are converted to cell surface sialic acids, decorate the cell surface with novel structural and functional motifs. A discussion of these will come at the end of this chapter. A.
Metabolic Studies with Modified Amino Sugars and N-Acetamido Sugars
The initiatory metabolic interference studies of the 1970s utilized amino sugars. Early work demonstrated that even the naturally occurring compound GlcN causes specific inhibition of viral glycoprotein synthesis at high concentrations [39]. Removal of exogenous GlcN from cell culture media resulted in a reversal of cytotoxicity. NBromoacetyl-GlcN and its tetra-O-acetyl derivative produced strong in vitro cytotoxicity against both Ehrlich and L1210 leukemia cells at micromolar concentrations (Table 1) [40]. Indeed, injection of the same compounds into mice bearing Ehrlich ascites tumors cured 85% of the mice, although successive injections ultimately produced resistance. The molecular basis for this interesting series of results was not explored, but it might reflect the nonspecific alkylating activity of the ␣-bromoacetamide. Accordingly, the corresponding fluoro and chloro derivatives, which are less reactive alkylating agents, were found to be inactive both in vitro and in vivo, with a toxicity level 10-fold lower than that of the bromo analog (Table 1). In a separate study, Fondy et al. demonstrated that although the toxicity of fluoroacetamido analogs of GlcNAc and GalNAc was not affected by the presence or absence of O-acetyl protecting groups, a fourfold increase in toxicity was observed for tetra-O-acetyl N-fluoroacetamido-ManN [41,42]. The toxic effects of the chloroand bromoacetamido analogs of GlcNAc, ManNAc, and GalNAc were more similar to that of the N-fluoroacetamido-ManN analog (Table 2). In general, the tetra-Oacetylated derivatives were markedly more toxic than their nonacetylated counterparts. Fondy et al. postulated that while the bromo and chloro analogs exert their toxic effects as lipophilic alkylating agents, the fluoroacetamido analogs might have a different mechanism of toxicity. Again, the molecular basis of this suggestion was not explored at the time.
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Table 1
Growth Inhibitory Activity of GlcN and GalN Analogs Against Erlich and L1210 Leukemia Cells
IC50 (M) R NH3Cl NHCOCH2F NHCOCH2Cl NHCOCH2Br
1
2
3
4
N/A ⱖ100 ⱖ100 ⱖ100
N/A 20 30–60 2–8
>1000 ⱖ100 ⱖ100 ⱖ100
220 30–80 20–30 4
The effects of amino sugars on cell viability have been evaluated using bacteria as well. The growth of Escherichia coli ML308 and K12 was inhibited by N-iodoacetamido-GlcN [43]. Further experiments indicated this compound inhibits the uptake of methyl-␣-D-glucoside by the bacterial cells, although complete inhibition was never observed. This effect is not surprising, considering that iodoacetamide reacts with several amino acid residues, such as Cys and His, and also with certain amino groups. It is possible that the iodoacetamide analogs irreversibly alkylated a key glucose transporter. Korytnyk and coworkers tested several pentaacetylhexosamine analogs for tumor cell toxicity and also evaluated their effects on glycoprotein biosynthesis [44]. Peracetylated GlcNAc inhibited the incorporation of [14C]GlcN into glycoproteins to a much greater extent than peracetylated GalNAc or ManNAc. However, protein biosynthesis was unaffected, as determined by levels of [3H]leucine incorporation.
Table 2
Toxicity of ManN, GlcN, and GalN Derivatives to B6D2F1 Mice
LD50 (mmol/kg) R
R⬘
ManN
GlcN
GalN
NHCOCH2F NHCOCH2F NHCOCH2Cl NHCOCH2Cl NHCOCH2Br NHCOCH2Br
H Ac H Ac H Ac
1.6 0.42 >3.7 1.6 >3.2 0.36
0.18 0.17 2.0 1.12 2.4 0.36
0.74 0.98 1.5 0.83 1.7 0.24
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Interestingly, replacement of the N-acetyl group of GlcNAc with a trifluoroacetyl group depressed [14C]GlcN incorporation by 31% within 5 h, while [3H]leucine incorporation was unaffected. Additionally, treatment of P288 cells with 1 mM GlcNAc resulted in no detectable change in ribonucleotide content, while treatment of cells with N-trifluoroacetyl-GlcN more than doubled the sugar-nucleotide content in the cell. The difference in the biological effects and metabolism of these compounds remains poorly understood, but a difference in cell permeability may be responsible. Derivatives in which the anomeric position of GlcNAc was modified were also evaluated as potential metabolic inhibitors of glycoconjugate biosynthesis [45,46]. In these fully acetylated compounds, the hydroxyl group at the anomeric position was replaced by a variety of groups including amino, N-chloroacetyl, N-bromoacetyl, N-iodoacetyl, N-trifluoroacetyl, and N-trifluoromethanesulfonyl groups. These GlcNAc derivatives were potent growth inhibitors of either mouse mammary adenocarcinoma TA3 or L1210 leukemia cells with IC50 values in the micromolar range (Table 3). Toxicity of these compounds might simply reflect their alkylating activity. Further modification of GlcNAc to S-glycosyl derivatives revealed that the 1-chloroacetylthio, 1-S-diphenylmethyl, and 1-S-trityl, inhibited the growth of TA3 cells at micromolar concentrations (Table 3). In yet another study, a ManN derivative con-
Table 3
Growth Inhibitory Activity of GlcNAc Derivatives Displaying Unnatural Anomeric Substituents Against TA3 Mammary Cells
IC50 (mM) R OH NH2 NHAc () NHAc (␣) N3 NHCOCH2Cl NHCOCH2Br NHCOCH2I NHCOCF3 NHSO2CF3 SCOCH2Cl SCHPh2 STr SCPh2( p-OMeC6H4) a
R⬘ = Ac a
0.27 0.32 0.19 0.22 1.0 0.26 0.019a 0.026a 0.2 0.007 0.25 0.8 N/A N/A
R⬘ = H >1a >1 N/A N/A >1 >1 0.62a N/A N/A N/A N/A N/A 0.053 0.016
IC50 values were determined using L1210 leukemia cells.
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taining a nitrosourea group at C2 was found to have antitumor activity [47]. The compound displayed an IC50 value against L1210 leukemia cells in the high micromolar range and increased the life span of leukemic mice by 35%. Although little mechanistic information was gleaned in these early studies, the differential effects of various unnatural substrates suggested possible engagement in metabolic pathways. B.
Halogenated Monosaccharides
Halogenated compounds have been widely used to study biological processes [48]. The halogens (F, Cl, Br, and I) are readily installed on synthetic analogs and might mimic a polar hydroxyl group. Among the halogens, fluorine has attracted the most attention. A comparison of bond lengths, van der Waals radii, and electronegativities indicates that the C—F bond quite closely resembles the C—OH bond [49]. The similar properties of the fluorine atom and hydroxyl group suggest that substitution might be tolerated by biosynthetic enzymes. The introduction of a fluorohexose or hexosamine analog into a biosynthetic pathway might lead to metabolic incorporation or metabolic disruption. An advantage to the use of fluorosugar analogs is the availability of additional analytical techniques, such as 19F NMR spectroscopy and radiolabeled 18F tracers, that facilitate characterization of downstream metabolic products [50–53]. Independent studies by Korytnyk and coworkers and May and Sartorelli have probed the effects of halogenated fucose (Fuc) and galactose (Gal) analogs on glycoconjugate biosynthesis [54–56]. Synthetic analogs bearing fluoro, chloro, bromo, or iodo groups at the 2- or 5-positions of Fuc, and the 6-position of Gal were shown to have inhibitory effects on the incorporation of the corresponding natural sugars, [3H]Fuc or [3H]Gal, into glycoproteins (Tables 4 and 5). The growth of murine L1210 leukemia cells was inhibited by 2-iodo-Fuc with an IC50 value of 0.06 mM (Table 4). Similarly, when mice with L1210 ascites tumors were injected with either 6fluoro-Gal (Table 5) or 2-bromo-Fuc (Table 4), their life span was prolonged by 32 and 25%, respectively. The 6-methanesulfonyl (Ms) analog of Gal had similar toxicity against L1210 leukemia cells. Other halogenated derivatives of Fuc such as 2bromo-Fuc, 6-chloro-Fuc, and 6-bromo-Fuc were much less toxic, with very little activity at concentrations above 1 mM (Table 4). The 6-halogenated analogs of Gal had inhibitory effects similar to those of their enantiomers, the corresponding 6halogenated-Fuc analogs (Table 5). Some halogenated analogs displayed cell-typespecific effects: 6-fluoro-Fuc did not inhibit the growth of L1210 leukemia cells at 1 mM, although it did reduce the incorporation of [3H]Fuc by 91% in human mammary tumor cells. Other compounds, such as 6-fluoro-Gal, although appearing nontoxic at 1 mM, had significant inhibitory effects toward the incorporation of [3H]Gal in P2888 murine lymphoma cells [55]. Westwood and coworkers have investigated the antitumor activity of fluorohexoses in vivo. From a panel of 6-halogenated Gal and Glc analogs, only 6-fluoro-Glc exhibited significant antitumor activity, blocking the growth of R-1 lymphoma up to 90% in mice [57]. Fluorohexosamine analogs that have been used in metabolic studies include 6fluoro-ManNAc, 6-fluoro-ManN, methyl 3-fluoro-ManNAc, 3-fluoro-GlcNAc, 4fluoro-GlcNAc, and 4-fluoro-GalNAc [58–60]. Many of these compounds were evaluated in both acetylated and nonacetylated forms. Among several 6-fluoro analogs
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Table 4
Toxicity or Growth Inhibitory Activity of Fuc Derivatives Against L1210 Leukemia Cells
R2
R3
R4
R6
IC50 (mM)
H Cl Br I Cl Br OH OH OH OH
OH OH OH OH OAc OAc OH OH OH OH
OH OH OH OH OAc OAc OH OH OH OH
H H H H H H F Cl Br I
1.0 0.2 No effect at 1.0 0.06 0.04 0.06 Slight effect at 1.0 Slight effect at 1.0 0.4 0.18
tested in murine L1210 leukemic cells, fully acetylated 6-fluoro-ManNAc had an IC50 value of 100 M, 6-fluoro-ManN had an IC50 value of 1 mM, and 6-fluoroManNAc was inactive (Table 6). The 3-fluoro analogs both inhibited cell growth at micromolar concentrations and reduced tumor growth by 50%. The 3-fluoro GlcNAc derivative also appeared to inhibit glycoconjugate biosynthesis. In the presence of the 3-fluoro analog, incorporation of [3H]GlcN was reduced by 41% and [3H]thymidine by only 7%. This indicates that 3-fluoro-GlcNAc competes in the
Table 5
Growth Inhibitory Activity of Various Halogenated Gal Derivatives Against L1210 Leukemia Cells
X
IC50 (mM)
F Cl Br I Ms
>1 1.0 0.13 >1 0.075
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Table 6
Growth Inhibitory Activity of Various ManNAc, GlcNAc, and GalNAc Derivatives Against L1210 Leukemia Cells
IC50 (mM) R1 OH OAc OH OMe (␣) OAc OAc OH OAc
R2
R3
R4
R6
ManN
GlcN
GalN
NHAc NHAc NH3Cl NHAc NHAc NHAc NHAc NHAc
OH OAc OH F F OH OAc OAc
OH OAc OH OAc OAc F F F
F F F OAc OAc OH OAc F
Inactive 0.1 1.0 0.043 N/A N/A N/A N/A
N/A N/A N/A N/A 0.027 Inactive 0.034 N/A
N/A N/A N/A N/A N/A N/A 0.035 0.024
pathway as GlcNAc itself. Contrary to the results in vitro, the 3-fluoro derivatives were relatively inactive in vivo, increasing life span by only 14% at 100 mg/kg. 4Fluoro-GalNAc, on the other hand, exhibited antitumor activity, increasing the life span of mice by 68% when administered a dosage of 50 mg kg⫺1 d⫺1 for 5 consecutive days. Since GalNAc is primarily contained in O-linked structures (Fig. 5) this might reflect an important role for O-linked glycoproteins in tumor growth. Despite the diverse behavior exhibited by the various halogenated Fuc and Gal derivatives, two clear trends emerged. First, the incorporation of 3H-labeled natural sugar analogs decreased with the increasing size of the halogen atom on the derivatized counterpart, and this was accompanied by an increase in cytotoxicity. This pair of effects suggests that more sterically demanding substituents are not tolerated by biosynthetic enzymes, thus minimizing biosynthetic competition with native substrates. Second, acetylated versions of all the derivatives were much more toxic than their analogous nonacetylated counterparts. This increase in toxicity could be attributed to the greater cellular permeability of these, and in general, any acetylated sugars [61]. Once inside a cell, esterases enzymatically remove the acetyl groups to produce a free monosaccharide that has full biological activity. Some reports suggest that partially deacetylated sugars can also enter the biosynthetic pathways [62]. Depending on the degree of deacetylation, these sugars may not be recognized by all biosynthetic enzymes for metabolism to cell surface glycans, thereby perhaps also contributing to the inhibitory and toxic effects of these compounds. Other studies addressed the conversion of fluorosugars to metabolic products, and ultimately to cell surface glycoconjugates. This section discusses the various fluorinated analogs that have been used in incorporation studies and the effects they had on the cell compared with their nonfluorinated counterparts. An analog of GlcNAc with a single fluorine atom on the N-acetamido group has been shown to
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be incorporated into glycosaminoglycans [63]. Glycosidase digestion of macromolecules isolated from rabbit tracheal explants that were incubated with radiolabeled N-fluoroacetyl-GlcN indicated the presence of these compounds within hyaluronic acid. These findings indicate that N-fluoroacetyl-GlcN traverses a pathway similar to GlcNAc and does not block the biosynthetic enzymes. Furthermore, cultivation of mouse embryo cells with N-fluoroacetyl-GlcN caused a 50% inhibition in the conversion of GlcNAc to UDP-GlcNAc, perhaps the result of alternate substrate competition [64]. Unlike the metabolism of the previous fluoro analogs, 4-fluoro-Man inhibits the synthesis of glycoproteins found on the vesicular stomatitis virus, probably through disruption of the biosynthesis of Glc3Man9GlcNAc2-PP-Dol [65]. At a concentration of 1 mM, 4-fluoro-Man specifically inhibited protein glycosylation of BHK21 cells infected with the virus. When the concentration was raised to 10 mM, general protein synthesis was also affected. It is possible that 4-fluoro-Man was incorporated into the oligosaccharide-Dol substrate and acted as a chain terminator, blocking further elaboration. Indeed, in Saccharomyces cerevisiae S288C, 4-fluoroMan is converted to the 1,6-bisphosphate, 6-phosphate, and GDP analogs [65]. Furthermore, 4-fluoro-Man was transferred by mannosyltransferase into the cell wall polysaccharide. The 3-fluoro analog, on the other hand, was transported into the cells at a lower rate and was not incorporated into cell wall glycoproteins. Although conversion of 3-fluoro-Man to its GDP derivative was much less efficient than the 4-fluoro analog, similar metabolites were isolated from the cells. 3-Fluoro-Glc is an inhibitor of glucose and galactose metabolism in yeast [67]. This analog also interferes with polysaccharide synthesis, as well as serving as a phosphate trap, as indicated by significant decreases in intracellular levels of phosphoglyceric acids, ATP, and UDP-Glc [68]. Exposure to 2-fluoro-Glc has a drastic effect on S. cerevisiae [69]. This toxic compound is a potent inhibitor of cell wall glucan biosynthesis and leads to cell wall degradation within a matter of hours. Similarly, Datema and Schwarz showed that 2-fluoro-Glc and 2-fluoro-Man inhibit formation of lipid-linked oligosaccharides in vivo [70]. 2-Fluoro-Man is a more potent antiviral agent that 2-fluoro-Glc in many virus– host cell systems [71]. Moreover, addition of exogenous Man, but not Glc, to culture media containing the fluorosugars, restored virus multiplication. A look at the metabolism of these analogs revealed that they are both activated by GTP or UTP, respectively, to yield their corresponding GDP or UDP derivatives [72]. 2-FluoroMan and 2-fluoro-Glc are incorporated into glycoproteins in both yeast and chicken embryo cells [71]. 2-Fluoro-Glc and 2-fluoro-Man were also found to be interconverted in vitro, presumably by epimerization. Furthermore, 2-fluoro-Glc appears to be converted to 2-fluoro-Gal. Therefore, these fluorinated sugars have multiple avenues for incorporation into glycoproteins. The metabolic fates of 2-fluoro-Gal have also received attention. Several groups have used 19F NMR spectroscopy and positron emission tomography (PET) with an 18 F label to track the substrate. These workers have determined that 2-fluoro-Gal is converted to 2-fluoro-Glc and also to phosphorylated and nucleotide-bound 2-fluoroGal analogs [51–53,71]. Thus, it is likely that 2-fluoro-Gal can be directly incorporated into glycoconjugates. 6-Fluoro derivatives of several hexoses have been investigated and found to have biological effects that significantly differed from the 2-fluoro derivatives men-
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tioned earlier. In particular, 6-fluoro-Gal inhibited the incorporation of [3H]Gal, but not of Man, Glc, or leucine into L1210 leukemic cells. Electron microscope autoradiography was used to show that this analog is activated to form the nucleotide analog and then localized to the Golgi compartment [73,74]. Moreover, upon treatment with 6-fluoro-Gal, cells showed a reduction in available sites for external modification using an ␣2,6-sialyltransferase, providing evidence that the analog was incorporated into cell surface glycoconjugates. Because of its importance in tumor glycosylation and blood antigen structures, Fuc has attracted attention as a target for metabolic structural modification [75]. 2Fluoro-Fuc was shown to be incorporated into glycoproteins in mouse fibroblasts [76]. Specific localization of 6-fluoro-Fuc in the Golgi apparatus, nuclear membrane, plasma membrane, and cytoplasm of human mammary tumor cells indicated glycoprotein incorporation there as well [54]. Likewise, the metabolites GDP-6-fluoroFuc and 6-fluoro-Fuc-1-phosphate have been directly observed in these cells. C.
Deoxy Sugars as Inhibitors of Biosynthesis
The Glc and Man analog 2-deoxy-D-glucose has been shown to be a general inhibitor of cellular metabolism. Early work by Woodward et al. showed that this deoxy sugar is a strong inhibitor of both the growth of yeast cells and their fermentation of Glc [77]. It blocks glycoconjugate biosynthesis and has antiviral activity [39,78–83]. Since 2-deoxy-Glc uses the same transport system as Glc, it might simply block Glc uptake, depriving cells of a key metabolic substrate [84–87]. This has been directly demonstrated at high concentrations in yeast, chick fibroblasts, and Ehrlich ascites carcinoma cells [88,89]. However, at lower concentrations, 2-deoxy-Glc is taken up and converted to its UDP and GDP analogs. Incorporation into cell wall glucans in yeast and glycoconjugates in mammalian cells has been demonstrated [81,90–94]. Within glycoconjugates, 2-deoxy-Glc might serve as a chain terminator for further elongation. Studies of altered cell surface architecture induced by treatment of 2-deoxy-Glc have been performed [90]. Lectin binding studies suggest that 2deoxy-Glc actually replaces Man, not Glc. Agglutination of cells by the lectins Ricinus communis (RCA) and Phaseolus vulgaris (PHA) [78], both of which bind to Gal and GalNAc residues, is significantly decreased during incubation with 2-deoxyGlc. This result indicates that the underlying mannosyl residues are unable to support further chain elongation to include elaboration with Gal or GalNAc, residues necessary for binding to these lectins. Another possibility is that the underlying Man residues are simply missing. However, binding of concanavalin A (ConA) [78,95], a Man-specific lectin, increases on cells incubated with 2-deoxy-Glc, suggesting that Man residues are present, perhaps as terminal residues if the 2-deoxy modification prevents further elongation. Other studies provide more direct evidence that 2-deoxyGlc functions as a Man substitute rather than a Glc substitute in cells. The addition of low doses of Man, but not Glc, to cells grown with 2-deoxy-Glc can reverse the effects of this anti-metabolite [96,97]. Addition of Man to cells grown with 2-deoxyGlc restores natural lectin agglutinating properties, further confirming that the compound functions as a Man mimic. Similar to 2-deoxy-Glc, it has been established that 2-deoxy-Gal is incorporated into glycoproteins in both rat and human cells [98–100]. When rats to which 2deoxy-Gal had been administered were injected with [3H]Fuc, a significant decrease
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in Fuc incorporation was observed. This result suggested that the missing 2-OH group on Gal prevented 2-fucosylation, and this was confirmed by treatment with an ␣1,2-fucosidase. Interestingly, analysis with ␣1,3- and ␣1,4-fucosidases revealed a corresponding increase in ␣1,3/␣1,4-fucosylation. Incubation of AS-30D rat ascites hepatoma cells with 2-deoxy-[1-14C]Gal [101] or the administration of this compound to rats [102,103] resulted in a large accumulation of 2-deoxy-Gal-1-phosphate. This metabolite comprised 78% of the total radioactivity detected in the liver, with the remaining metabolites being 20% UDP-2-deoxy-Gal and 0.7% UDP-2-deoxy-Glc [104]. The formation of the uridylate intermediates occurred only after high levels of 2-deoxy-Gal-1-phosphate had been achieved. The accumulation of UDP-2-deoxyGal-1-phosphate was attributed to the limited epimerization of UDP-2-deoxy-Gal-1phosphate to UDP-2-deoxy-Glc-1-phosphate. This phenotype is characteristic of uridylyltransferase-deficient cells and tissues induced by Gal and may serve as an excellent model for studying the cellular injury in galactosemia. 2-Deoxy-Fuc, a residue found to be a constituent of several natural products, was tested for inhibition and cytotoxicity properties in L1210 leukemia, mouse mammary adenocarcinoma (TA3), and P288 leukemia cells (Table 7) [105]. This compound had no significant effect on the growth of any of the cell lines tested. However, the fully acetylated version of this substrate was active as a growth inhibitor, and it exhibited significant influence on glycoprotein biosynthesis in cultured P288 leukemia cells. The methyl glycoside of the fully acetylated 2-deoxy-Fuc had an even greater effect on cell viability, with an IC50 of 500 M in L1210 leukemia cells; cell growth was inhibited to 43% of control cells. Furthermore, this compound decreased cellular incorporation of [3H]GlcN and [3H]leucine by 20 and 9%, respectively. In summary, much early work with subtly modified monosaccharide substrates suggested the capacity to alter cell surface glycosylation through metabolic processes.
Table 7
Growth Inhibitory Activity of 2-Deoxy Fuc Analogs Against L1210 Leukemia Cells
R1 OH OMe OMe OAc
R3
R4
IC50 (mM)
OH OH OAc OAc
OH OH OAc OAc
>1 >1 0.5 >1a
a IC50 value was determined using TA3 mammary cells.
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Direct application of the technique to the study of cell surface carbohydrate recognition was realized later, mostly using sialic acids, as summarized in Section IV. IV.
INTRODUCTION TO SIALIC ACIDS
Sialic acid is a unique monosaccharide typically found at the nonreducing end of oligosaccharides. Sialic acids serve as modulators for cell adhesion [106–108], ligand determinants for specific viral and bacterial receptors, and epitopes for lectin binding [109,110]. They can also mask underlying antigenic sites [111,112]. The metastatic potential of tumor cells has been positively correlated with the total sialic acid content of the cell [113]. Their biological significance suggests that manipulation of the sialic acid content of complex oligosaccharides, as well as modification of the sialic acid structure, may provide insight into the molecular basis of cell surface interactions. The remainder of this chapter focuses on the biosynthesis of sialic acids and incorporation of unnatural analogs into cell surface glycoconjugates. Sialic acid is a generic term used to represent a family of over 30 neuraminic acid derivatives [114–116]. The most abundant sialic acids are N-acetylneuraminic acid (Neu5Ac) and N-glycolylneuraminic acid (Neu5Gc). These sialic acids, in addition to a few other commonly found sialic acids, are shown in Table 8. While both eukaryotes and prokaryotes possess similar sialic acids, there exists some variation in the biosynthetic pathway leading to the expression of these compounds on the cell surface. The biosynthetic pathway of Neu5Ac in mammals is shown in Figure 10. In mammalian cells, exogenous ManNAc and Neu5Ac can be taken up, metabolized through the sialic acid biosynthetic pathway, and then expressed on the cell surface as sialosides [117]. Thus, cell surface glycoconjugates could be altered if unnatural ManNAc or sialic acid analogs exogenously introduced to the cell were successfully converted into sialoglycoconjugates.
Table 8
Some Commonly Found Sialic Acids
Common name
Abbreviation
N-Acetylneuraminic acid
Neu5Ac
N-Glycolylneuraminic acid
Neu5Gc
9-O-Acetyl-N-acetylneuraminic acid
Neu5,9Ac2
2-Keto-3-deoxynononic acid
Kdn
Structure
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A.
663
The Unnatural Substrate Tolerance of the Enzymes Involved in Sialic Acid Biosynthesis
The possibility that sialic acid biosynthesis might be amenable to interception with unnatural substrates was first suggested by studies of the individual enzymes in the pathway. Several groups have analyzed the tolerance of various enzymes for unnatural substrates, revealing sites on metabolic intermediates at which functional group substitutions might be tolerated. Of the enzymes involved in sialic acid biosynthesis, the two that have attracted the most attention are CMP-Neu5Ac-synthetase and various sialyltransferases. Both bacterial and mammalian homologs from these two enzyme families have been characterized. CMP-Neu5Ac-synthetase catalyzes the condensation of free Neu5Ac with CTP to make CMP-Neu5Ac. The enzymes from bovine brain and rat liver have been investigated with respect to their activity with unnatural sialic acids [118]. Sialic acids modified at C5 and C9 have been extensively studied; several of these are accepted by the enzyme and are successfully converted into the corresponding CMP– sialic acid analogs in yields of 40–90% [119] (Table 9). The efficiency of the reaction depended on the analog. While the enzyme tolerates rather large substituents at C9, structural perturbation at C5 must be conservative. Examples of acceptable modifications are shown in Table 9 [119–124]. The 4-deoxy derivative of Neu5Ac is also a substrate for CMP-Neu5Ac synthetase [125]. The large variety of compounds that have been successfully converted into their CMP analogs indicate that bovine CMPNeu5Ac-synthetase might be useful for in vitro enzymatic synthesis of unnatural CMP–sialic acid analogs. In eukaryotes, sialyltransferases are located in the Golgi compartments [126,127]. They transfer a sialic acid residue from CMP–sialic acid to a nonreducing Gal-, GalNAc-, GlcNAc-, or sialic acid residue via an ␣-glycosidic linkage. The possible linkages include ␣2,3, ␣2,6, or ␣2,8, and each is the product of a different sialyltransferase. Sialyltransferases from rat and human liver have been studied extensively [128]. Similar to CMP-Neu5Ac-synthetase, the broad specificity of sialyltransferases has made them useful for the synthesis of neoglycoconjugates containing a variety of sialic acid analogs. Examples of CMP–sialic acid analogs that have been successfully converted into glycoconjugates by sialyltransferases are shown in Table 10 [118–120,125,128–131]. Even perturbations as large as a fluorescein group at C5 or C9 are tolerated by some sialyltransferases, allowing one to install fluorescent probes in cell surface glycoconjugates [132,133]. This approach has provided a method for kinetic analysis of the rates of different sialyltransferases within cells [134,135]. Furthermore, the C9 fluorescein derivative has been used to localize sialyltransferases to the Golgi compartments in rat liver [127]. Although alterations at C5 and C9 can reduce efficiency of sialyltransferases, the reactions occur at a reasonable rate and are therefore useful for studying cellular processes.
< Figure 10
The sialoside biosynthetic pathway in eukaryotic cells: A, UDP-GlcNAc-2epimerase; B, ManNAc-6-kinase; C, Neu5Ac-9-PO2⫺ synthase; D, Neu5Ac-9-PO2⫺ phospha4 4 tase; E, CMP-Neu5Ac-synthetase; F, sialyltransferase. Enzymes A and B function together as a bifunctional enzyme.
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Table 9
A Limited Number of Sialic Acid Derivatives Are Recognized as Substrates for CMP–Sialic Acid Synthetase from Bovine Brain and Rat Liver
R1 H
R2 Ac
R3 OH
OH
OH
OH
OH
OH
OH
OH OH
Ac Ac
OH
Ac
OH
Ac
OH
Ac
OH
Ac
OH
Ac
N3 NH⫹3
SHgMe
Sialic acid biosynthesis in bacteria is less complex than in mammals. There are only three enzymes involved in Neu5Ac biosynthesis; they are the Neu5Ac– synthase, CMP-Neu5Ac-synthetase, and sialyltransferase. Although these enzymes were cloned only within the past 10 years, their straightforward overexpression in bacteria has allowed extensive studies to be performed. It was not until 4 years ago that the first bacterial Neu5Ac-synthase was cloned [136]. This enzyme, derived from E. coli K1, is unlike the mammalian enzyme in that it does not accept the ManNAc-6-PO2⫺ as a substrate. Rather, it condenses 4 ManNAc with phosphoenolpyruvate (PEP) to produce Neu5Ac. Furthermore, 6-N3 ManNAc can be converted to 9-N3 Neu5Ac, although only with 59% efficiency compared to the native substrate [137]. The E. coli synthase has also been shown to accept ManN as a substrate, albeit with only a minimal production of the sialic acid
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Table 10 A Limited Number of CMP–Sialic Acid Derivatives Are Accepted as Substrates by ␣2,3- and ␣2,6-Sialyltransferases from Bovine and Human Liver
R1 H OH OH
R2 Ac Ac Gc
R3 OH OAc OH
OH
OH
OH
OH
OH
OH
OH
OH
OH
OH
OH OH OH
Ac Ac Ac
OH
Ac
OH
Ac
OH
Ac
OH
Ac
F N3 NH⫹3
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Goon and Bertozzi Continued
R1
R2
OH
Ac
OH
Ac
R3
analog. This lack of specificity was also seen with the purified Neu5Ac-synthase from Neisseria meningitidis [138]. Since its initial identification in E. coli, the Neu5Ac-synthase gene has also been cloned from numerous microbial organisms including Helicobacter pylori. The availability of these enzymes promises to facilitate the enzymatic synthesis of sialic acid analogs. In contrast to the eukaryotic CMP-Neu5Ac-synthetases, the bacterial counterparts have not been extensively characterized. Therefore, it would be interesting to see whether the bacterial enzymes exhibit the same broad substrate specificity. Thus far, only 9-N3 and 9-NH⫹3 modified sialic acids have been tested with the E. coli and N. meningitidis CMP-Neu5Ac-synthetase [138,139]. While the 9-N3 analog was similar to Neu5Ac as a substrate for the enzyme, the 9-NH⫹3 derivative was a poor substrate. Unfortunately, many of the sialic acid analogs that were active as substrates for the mammalian enzyme have not yet been examined by means of bacterial enzymes. A few C5-modified analogs have been tested, namely, N-propanoyl sialic acid (SiaProp), N-glycolylneuraminic acid (Neu5Gc), and N-carbomethoxyneuraminic acid (Neu5CMe), and these were tolerated by the enzyme. 5-Azidoneuraminic acid was not a substrate for the enzyme, and N-carbobenzyloxyneuraminic acid (Neu5Cbz) coupled at a much slower rate than Neu5Ac [140]. While it would appear that the bacterial enzyme is more restrictive in its substrate specificity, it does show some tolerance for unnatural C5 and C9 substituted sialic acid derivatives. Sialylated glycoconjugates found in bacteria often mimic oligosaccharides found on the surface of mammalian cells [141–143]. The similarity in structure between the glycoconjugates of mammalian and bacterial cells might reflect a mechanism by which bacterial cells evade the host immune response. Given the similarity of bacterial and mammalian sialoglycoconjugate structures, the bacterial sialyltransferases might have substrate recognition properties similar to those of their mammalian counterparts. Unfortunately, few bacterial sialyltransferases have been cloned or characterized [144]. However, it is known that similar to mammalian sialyltransferases, bacterial sialyltransferases are membrane-associated proteins that are responsible for terminating glycans by transferring a sialic acid residue to a terminal
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GlcNAc, GalNAc, or Gal residue. Like their mammalian counterparts, they too are capable of producing ␣2,3-, ␣2,6-, or ␣2,8-linked sialosides. An ␣2,6-sialyltransferase isolated from the bacterium Photobacterium damsela is capable of sialylating 3⬘-sialylLacNAc oligosaccharides, generating a rare 3⬘,6⬘-disialylated structure [145]. Bacterial sialyltransferases are also capable of forming ␣2,9-linked structures. The ␣2,8- and ␣2,9-linked sialic acids are generally found as homopolymers that make up the capsule of pathogenic bacteria like N. meningitidis, E. coli K1, and E. coli Bos 12. Of the few bacterial sialyltransferases cloned, even fewer have been studied with respect to donor–substrate specificity. CMP-Neu5Ac, CMP-Neu5Gc, CMPSiaProp, and CMP-9-fluoro-Neu5Ac have been tested as substrates for the N. meningitidis ␣2,3-sialyltransferase [146–148]. While these substrates were effectively recognized, the small panel does not provide enough information to generalize the specificity of the enzyme. If the enzyme is to be useful in chemoenzymatic synthesis or in studying cellular processes, knowledge of its specificity with a broader panel of substrates would be useful. B.
Metabolic Conversion of ManNAc Analogs to Cell Surface Sialosides
The notion that unnatural analogs of ManNAc might be metabolized to sialic acids in living cells was first explored in the 1970s. Initial studies of the sialic acid biosynthetic pathway focused on the inhibitory properties of metabolic precursors [62,149,150]. It was discovered that some ManNAc analogs, while exhibiting a degree of toxicity to the cells, competed with native ManNAc and were incorporated into the sialic acid biosynthetic pathway. This finding, along with the earlier knowledge that cells can take up exogenous ManNAc and convert it into sialic acid [117,151], opened up many possibilities for cell surface modification. Figure 11 shows the different ManNAc analogs that have been successfully metabolized by cells and converted into cell surface sialosides. For example, peracetylated N-trifluoroacetyl ManN, although toxic to cells at high micromolar concentrations, competed with ManNAc in glycoconjugate biosynthesis [62]. The expression of metabolically modified sialic acids on the cell surface has been used to modulate several biological processes. Schmidt et al. showed that Npropanoylmannosamine (ManProp), which is metabolized to SiaProp, stimulates proliferation in specific cells found in the rat central nervous system (CNS) [152]. Incubation of cells from neonatal rat brain with ManProp successfully stimulated proliferation of astrocytes and microglia, but not of oligodendrocyte progenitor cells in culture. The basis for this proliferation is unclear, since all cells examined converted ManProp into cell surface SiaProp. Similarly, human diploid fibroblast cells grown with ManProp, N-butanoylmannosamine (ManBut), or N-pentanoylmannosamine (ManPent) lost their sensitivity to contact inhibition of growth [153]. Virus–receptor interactions have also been shown to be affected by these ManN derivatives [154,155]. Treatment of human B-lymphoma BJA-B cells or African green monkey kidney epithelium cells with either ManProp, ManBut, or ManPent resulted in structural modification of about 50% of total cell surface sialic acids. Polyoma viruses, which use sialic acids as ligands for binding prior to infection, show either reduced or enhanced ability to infect cells carrying these modified sialic
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ManNAc derivatives that are metabolically converted to the corresponding cell surface sialic acid analogs in mammalian cells.
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Figure 11
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acids, depending on the ManN analog used. The expression of modified sialic acids might therefore be a new mechanism to prevent viral infection. An analog similar to ManPent, but containing a ketone group on the N-acyl side chain, has been synthesized as a sialic acid precursor [156]. This derivative, called N-levulinoylmannosamine (ManLev), is converted to the corresponding sialic acid (SiaLev), delivering reactive ketone groups to cell surface glycoconjugates. The biosynthesis of N-levulinoyl sialic acid has been demonstrated in a variety of human cell lines (e.g., Jurkat, HeLa, and HL-60 cells). Scatchard analysis of ManLev-treated cells indicated the presence of at least several million derivatized sialic acid residues on the cell surface [157]. The expression of SiaLev on the cell surface introduces an orthogonal reactive group, the ketone, into cell surface glycans. The ketone group, which can undergo a number of coupling reactions under physiological conditions, can be used to introduce new recognition epitopes onto the cell surface, a method called ‘‘glycoform remodeling’’ [157]. In this fashion, large biomolecules can be displayed on cell surfaces by using chemical methods rather than conventional genetics tools. For example, it has been demonstrated that aminooxy- and hydrazidefunctionalized oligosaccharides can be chemoselectively reacted with SiaLev to further elongate the oligosaccharide chain. Modified sialic acids bearing ketones have been exploited in new approaches to selective drug delivery [156] and for targeting of diagnostic agents [158]. Other functionalized N-acyl side chains on ManN, such as the N-azido acetyl group, are also tolerated by the biosynthetic enzymes [159]. Discovery of this property opens up new opportunities for modifying sialic acids and reacting them with exogenous agents. V.
CONCLUSION
The field of metabolic substrate engineering has evolved from initial cytotoxicity studies using unnatural sugars, which produced empirical observations, to cell surface engineering using chemically defined epitopes. The transformation of this rapidly growing field is the result of molecular cloning efforts of the past decades, which have enabled detailed studies of enzyme specificities. Moreover, analytical tools such as mass spectrometry and HPLC have advanced to the point that characterization of unnatural metabolites within complex glycoconjugates is now possible. With the availability of powerful genetic and analytic methods, it should be possible to apply metabolic substrate engineering more broadly to fundamental studies of glycobiology. ACKNOWLEDGMENTS The authors thank Bristol-Myers Squibb and the National Institutes of Health (R01 GM58867-01) for generous funding. REFERENCES 1. 2. 3. 4.
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Index
ABH, 355 Acarbose, 415 Acarviosins, 415 Acetylation, 440 Acmimycin, 314 Acrylamide copolymerization, 289 Actinomycete, 134, 309 Acyloxonium ion, 147 Adam’s catalyst, 599 Adenine, 549 Aglycon, 308 AIBN (2,2⬘-azobisisobutyronitrile), 78 Alanine, 494, 495 Aliphatic aglycone, 560 Alkyl glycosides, 122 Allium, 163, 171 Allyl C-glycoside, 109 Allylic sulfones (radical acceptor), 80 Allylic ␣-C-glycoside, 88 ␣-amino acids, 494, 495 Amikacin, 354 Amino deoxyglucuronic acids, 511 glyculosonic acids, 495 hexuronic acids, 494, 495 kanamycins, 393 nonulosonic acids, 495 sugar, 593, 652 Aminocyclitol antibiotic, 307 Aminoglycoside, 307, 353 acetyltransferase, 325 adenyltransferase, 400 nucleotidyltransferase, 325 phosphotransferase, 325
Aminoglycoside-modifying enzyme, 365 Angucycline antibiotics, 125 1,2-Anhydro sugar, 5, 8, 83, 112 Anomeric effect, 72, 359 Anomeric sulfoxides, 14 Anthelmintics, 310 Antiadhesins, 278 Antibiotic therapy, 134 Anticancer agents, 165 Anticoagulant, 427, 482 Antifungal activity, 172 Anti-Gal IgG, 583 Anti-Gal IgM, 583 Anti-HIV agent, 98 Anti-inflammatory activity, 168 Anti-MRSA, 393 Antisense oligonucleotide-saccharide conjugates, 249 Anti-sialic acid antibodies, 289 Antithrombotic, 427, 482 Antitumor activity, 172, 174 Antiviral agents, 427 Antivirus antibodies, 256 Aparamycin 309, 333, 361, 415 Arabinan chain, 135 Arabinogalactan (AG), 134 Arabinopyranoside diol, 166 Arabinose, 133, 538, 542, 543 Arabinosyltransferases (AraT’s), 140 Arabinoxylans, 133 Aryl C-glycosides, 123 Arylsulfonamides, 428, 442 Ashimycin, 314 Asparaginine, 494 675
676 Asparagus, 163 Aspergillus oryzae, 577 Auxiliary-directed glycosylation, 194 Azide, 428 Azido glucuronic acid, 511 Azidonitration, 428, 461 Azoisobutylnitrile (AIBN), 443 Baby hamster kidney, 543 Bacillus circulans, 323, 390 Bacterial lipopolysaccharide, 630 Balanites aegyptica, 174 Barbituric acid, 122 Barton’s deoxygenation, 378 Bauhinia purpurea lectin, 243 BBA2, 266 Benzannulation, 102 Benzenesulfenyl triflate, 65 Benzenesulfonamide, 428 Benzoyl cyanide, 462 Benzoylation, 144 Bidirectional glycosylation strategy, 24 in solid phase synthesis, 24 Bifunctional enzyme, 588 Biomodified guar, 577 Biosynthesis of glycoconjugates, 640 Biotransformation of Polysaccharide, 567, 569 Blood group determinants, 5, 10 Boric acid, 470 Boron trifluoride etherate, 434 Bovine serum albumin (BSA), 266 Brookfield viscometer, 577 Butirosin, 333, 376, 380 Camphorsulfonic acid, 474 CAN, 443 Cancer diagnostic kit, 289 Cancer metastasis, 277 Caproamide, 526, 527 Capsular polysaccharides, 285, 495 Carba, 417 Carbenicillin, 391 Carbodiimide, 45 Carbohydrate drugs, 175 Carbohydrate-based nucleic acids, 518 therapeutics, 535 Carbohydrate-protein binding interactions, 278 Carbon-linked disaccharides, 106 hetero-Diels–Alder approach, 106
Index Carbonucleotoids, 513 Carbopeptoid, 513 Cardioactive properties, 174 Catalytic hydrogenation, 454, 470 CD spectra, 528–530 Cell adhesion, 5 Cerium(IV) ammonium nitrate, 480 Chelate effect, 228 Chinese herbal medicine, 172, 174 Cholera toxin B, 298 Cholestane saponins, 165 Chondroitin trisaccharides, 458 Clonezyme, 588, 596 Cluster effect, 227 CMP-NeuAc regeneration, 210 CMP-Neu5Ac, 298, 537 synthetase, 663–666 CMP-NeuAc, 199, 201 synthesis of, 202–204 CMP-sialic acid, 537 C-NMR Spectroscopy, 28 C-nucleoside synthesis, 98 Cobalt, 100 in C-glycoside synthesis, 100 Cofactor regeneration, 210 Coiled coils, 531 Collocalia mucin, 279 Combimicins, 382 Combinatorial synthesis, 243 Computer-assisted analysis, 519 ConA, 223, 239, 293 ConA-saccharide interactions, 236 Condensation reaction, 88 Cookson’s reagent, 106 Costacea, 172 Coulombic interactions, 224, 249 CPG (controlled pore glass) solid support, 16 Cross-Coupling reactions, 97 C-type lectin recognition, 223 Cyclization, 92 mercury-induced, 91, 92 Cycloaddition reaction, 104, 106 in C-glycoside synthesis, 104 Cyclodextrin, 555 Cytidine monophosphate, 537 Cytidine triphosphate (CTP), 202 Dactimicin, 322, 409 Danishefsky’s iodosulfonamidation method, 428
Index DBU (1,8-diazabicyclo[5.4.0]-7-undecene), 80, 443 De Novo Ring formation, 106 Deallylation, 480 Deamino kanamycin, 394 Dehydrative glycosylation, 36 via glycosyl bromides, 36 Dehydroisoandrosterone, 164–168 De-N-Acetyl GM3, 179 Density functional theory, 158 Deoxy sugar, 652, 659 DEPT, 600 Dermatan sulfate hexasaccharide, 474 Dermatan sulfate, 425, 467 Destomycin A, 310 Destomycin C, 372 D-glucuronic acid (GlcUA), 431, 443 Dianion approach, 83 Diazotization, 373 Dibekacin, 382, 390 Dibutyltin oxide, 448 Diels–Alder reaction, 104 Digitalis purpurea, 164 Dihydrostreptomycin, 314 Dioclea grandiflora lectin, 248 binding specificity, 246 Dioscorea, 163, 171, 172 Diosgenin, 164, 168, 169, 172 Diosgenyl saponins, 171, 172 DMTST (dimethylthiomethylsulfonium triflate), 19 Dodesaccharide, 19 block synthesis, 19 DQF-COSY, 600 DREG56 (anti-L-selectin antibody), 267 Drug regimens, 134 Drug-RNA interaction, 342 DTBMP (2,6-di-tert-butyl-4-methylpyridine), 59 DTBP (di-tert-butylpyridine), 11, 14 E. coli, 577 heat-liabile enterotoxin, 298 ELISA (enzyme-linked immunosorbant assay), 232, 242, 268, 610, 614 Endocytosis, 247, 252 Endothelial cells, 260 Enkephalins, 511 Enterobacteriaceae, 353 Enzymatic synthesis, 634 Esterase, 570 Eukaryote, 641
677 Exoanomeric effect, 153 Ezoaminuroic acid, 495 Ezomycin A1, 495, 498 Facial selectivity, 120 of C-glycosidation, 120 Fast-atom bombardment high-resolution mass spectrometry, 135 Fibringen, 531 Fibrosarcoma HT1080, 252 Fibrous proteins, 531 Fimbriae, 603 Fischer glycosylation, 35, 144, 146 Fischer protocol, 34 Flow cytometry analysis, 620 Flu virus hemagglutination, 293 inhibitors of, 285, 299 Fluorescence anisotropy, 231 Fluorinated netilmicin, 387 Fluorinated sporaricin A, 412 Fluorination-toxicity relationship, 391 Fluoro sugar, 386 Fluoroarbekacin, 387 Fluorohexosamine, 655 Fluorohexose, 655 Foldamer, 519 Formimidation, 409 Fortimicin, 317, 360 Fraser–Reid pentenyl glycosylation technique, 428 Fucosyltransferase, 543, 544 Functional affinity, 242 of ConA, 242 Furanose donor, 45 Galactosaminoglycans, 425 Galactose, 587 galactose-containing cellobiose, 577 metabolism, 587 Galactosemia, 660 Galactosidase, 577 Galactosyltransferase, 537, 540, 544, 584, 626 GalNAc, 540, 542 GalNAc-Ser, 494 Ganglioside, 10, 179, 644 Garamine, 30, 400 GDP-Fuc, 298, 537 inhibitor, 100 GDP-Man, 537 GEGOP, 602 Gene-saccharide conjugates, 249
678 Genetic engineering, 588 Gentamicin, 312, 333, 382, 398 GFR, 346 GlcNAc, 540, 541, 654 GlcNAc-Asn, 494 Glebomycin, 314 Gliosis, 344 Globotriose, 541, 542, 634 Glucotransferase, 626 Glucuronic acid, 434, 540 GlyCAM-1, 267 Glycocalix[n]arenes, 286 Glycoconjugate, 1, 4, 140, 560, 593 Glycodendrimer, 292, 293, 298, 299 Glycoform remodeling, 669 Glycolipid, 5, 177, 540, 549, 560, 644 Glycomimetics, 278 Glycopeptides, 2, 494 Glycopeptidomimetics, 283 Glycopolymer, 298, 603 Glycoproteins, 140, 177, 540, 549, 658 biosynthesis of, 653 Glycosaminoglycans (GAGs), 425, 479, 658 Glycosidase, 324, 588, 632 Glycosyl donor, 33 halide coupling, 35 halides, 114 electrophilic coupling reagents, 114 phosphite, 199 sulfonate, 37, 53 trichloroacetimidate, 15, 165 triflate, 39, 53, 55 Glycosylation, 181 enzyme-mediated, 199 with sialic acid, 181 Glycosyltransferase, 299, 535–538, 552, 555, 559, 587, 625, 640 Glycosyltransferase-catalyzed synthesis, 537 GM3-type copolymer, 290 Golgi apparatus, 584 Golgi compartment, 659 Gougerotin, 495, 498 Grignard reaction, 98 Grubb’s catalyst, 289 GS4104, 278 GTA, 542, 543 GTB, 542, 543 Guanidino, 314, 404 Guanine, 549 Guanosine diphosphate, 537 Guar, 571, 574, 578
Index HA, 256, 257 inhibitors of, 254 Halokanamycins, 384 Hanganutziu–Deicher antigen, 279 HAR, 582, 583 HDV, 343 Hecogenin, 164 Helicobacter pylori, 8, 540 Hemagglutination, 234, 259, 260 Hemagglutinin(HA), 253 Hemisalt, 397 Heparin, 226, 267, 425, 482 Hepatocyte lectin, 248 Hepatocytes, 249, 252 HepG2 cell, 266 Heptonic amino acid, 503 Heteomultimer, 247 Heterocoupling, 38 Hexasaccharide, 135 Hexosamine, 655 Hexosaminuronic acid, 509 High-density lipoprotein (HDL), 252 High-performance liquid chromatography, 559 (see also HPLC) High-throughput assays, 266 HIV replication, inhibitor of, 516 HL-60 cells, 266 HMQC, 600 Horseradish peroxidase, 610 HPLC, 559, 592 HRP, 611 HUVECs (human umbilical vein endothelial cells), 266 Hyaluronan, 425, 461 Hyaluronic acid, 425, 462 Hydroxyproline-rich glycoproteins (HPRGs), 133 Hygromycin, 310, 333 Hyperacute rejection, 582 IC50, 618 IEC, 592 Immunoadsorption, 584 Immunomodulatory, 139 Immunoreactive oliogosaccharide, 638 Immunosuppressive drug, 582 Immunosuppressor, 620 INAPT, 600 Inflammatory response, 425 Influenza A, 299 Influenza flu virus neuraminidase inhibitor, 278
Index Influenza virus hemagglutinin, 242, 248 Influenza virus, 253, 259 Inosamycin, 315, 321 Iodohydin, 381 Ion exchange chromatography, 560, 592 Isepamicin, 354 Isoniazid, 134 Istamycin, 317, 410, 411 Jones oxidation, 442 Kakelokelose, 427 Kanamycin, 312, 324, 354, 380 Karplus equation, 600 Kasugamycin, 315 Keratan sulfate, 425 Keratin, 531 Ketomycolate, 135 Klebsiella pneumoniae, 379 Ko¨enigs–Knorr glycosylation, 432, 604, 610 Kolbe electrolysis, 80 of sugar acids, 80 LacNAc, 538 LAM, 139 Lectin, 603 Lectin-ligand interaction, 210, 227 Leloir glycosyltransferase, 537 Leloir pathway glycosyltransferases, 199 Leloir types, 537 Leukocyte rolling, 267 Levoglucosenone, 79 Levulinoyl, 436 Lewis acid catalysis, 109 mediated diarylation, 125 monoarylation, 123 Lewis acids, 34 Lewis blood group antigen (Le b), 8 Ligand proteolysis, 252 Lindlar’s catalyst, 458 Lipase, 570, 571, 574 Lipoarabinomannan (LAM), 134 Lipopolysaccharide, 625 Liposomes, 249, 257, 284 Liriope muscari, 168 Lividomycin, 310 LOS, 632 Low-density lipoprotein(LDL), 252 Luciferase(Luc) gene, 249 Lukemic HL60, 252 Lymphocyte trafficking, 425
679 Lysine, 526 Lysinomicin, 319, 413 Lysoganglioside, 290 Lysosome, 345 Lysyllysinomocin, 319 Maidong, 168 Maidong saponin C, 168–171 Major histocompatibility complex (MHC), 140 MALDI, 559 ManLAM, 135 ManNAc, 661 Mannosyl triflates, 65 ManPent, 669 ManProp, 667 Matrix-assisted laser desorption ionizaton mass spectrometry, 559 MBP (mannose binding protein), 299 Merrifield’s resin, 14 Metallo-ene cyclization, 98 Metallokanamycin A, 397 Methoxyethoxymethyl chloride (MEMCl), 453 Methylacarviosin, 415 Methylation analysis, 135 Methylation, 542 Michael addition, 91 Microbial glycosyltransferase, 630 Micrococcus lysodeikticus, 494 Micromonospora, 381 Millex-GV filter, 561 Mitochondrial mutation, 343 Mitsunobu protocol, 39 reaction, 41 MM3, 158 Modified CMP-NeuAc sialyl donors, 210 Moffatt–Swern oxidation, 43 Monosaccharide, 569 Mycobacterium smegmatis, 135 Myomucin, 315 Myxoma virus, 551 N-acetylation, 436 Neamine, 309 Neighboring hydroxyl group participation, 356 Neisseria meningitidis, 279, 540 Neisserial lipo-oligosaccharide, 631 Neoglycoconjugates, 278, 292, 300 Neomycin, 310, 315 Nephrotoxicity, 345, 346
680 Netilmicin, 354, 387 Neu5Ac2en, 278 Neu5Ac-synthetase, 666 NeuAc glycal, 194 Neuraminidase, 256 inhibitor of, 256 Nickel dichloride hexahydrate, 470 Nitroglycal, 106 NMDA, 344 NMR spectroscopy, 27, 135, 559 Nojirimycin, 3222 Non-Leloir types, 537 Nuclear Overhauser effect (NOE), 153, 601 Nucleoside antibiotics, 495, 509 Nucleotide, 559 O2 sugars, 85 O-glycosylation, 644 Olefin self-metathesis reactions, 289 Oligobiosaminide, 415 Oligofuranoside, 155 Oligonucleotides, 2 Oligopepoids, 284 Oligopeptides, 2 Oligosaccharide, 1, 4, 143, 425, 535, 536, 560, 634 preparation of, 634 solid support synthesis, 19 synthesis of, 15, 24 Oncogenesis, 542 One-pot glycosylation, 174 Ophiopagon, 163, 168, 171, 172 Ornithogalum saudersia, 165 Otovestibular, 307 Oxazolidinone, 401 Oxirane, 406 Oxyapramycin, 309, 369, 370 Palladium, 97 in coupling reactions, 97 Palladium(II) acetate, 110 PAMAM, 283, 293 Paromamine, 333, 359 Paromomycin, 310, 315, 329 Pea lectin, 293 Pearlman’s catalyst, 445 Pectin lyase, 570 Pectin, 133, 570, 576 methylesterase, 570 Pentasaccharide, 592 Pentenyl galactose donor, 24 Peptidases, 530
Index Peptide coupling, 512 Peptidoglycan synthesis, 638 Peptidomimetics, 511 Perfluoroalkylation reaction, 170 Pfitzer–Moffatt procedure, 393 Phase transfer catalysis (PTC), 280 Phenolic nucleophiles, 46 Phenyl glycosides, 41 Phenylalanine, 526 Phenylsulfide auxiliary, 194 Phosphatidylcholine, 257 Phosphatidylinositol, 135 Phosphoinositol-glyceroarabino-mannan, 135 Phospholipid, 345 Photobacterium damsela, 552 Phthalamide, 428 Plasma membrane, 345, 644 PME, 570 pNAS, 613 Polyelectrolyte effect, 231 Polygalacturonase, 570 Polygonatum, 163 Polylactose, 613 Polylysine-asialoglycoprotein conjugates, 249 Polymeric hyaluronan, 445 Polyphyllin D, 172 Polyprenyl sugar phosphate, 140 Polysaccharide, 1, 133, 134, 567, 569, 570 Progesterone, 164 Propionibacterium acnes, 495 Proteases, 530 Proteoglycans (PGs), 425, 448 Prototypical glycoconjugates, 641 Prumycin, 323 Pseudomonas aeruginosa, 310, 353, 377, 381 PSEUROT 6.2, 155 PS-PEG (polystyrene-polyethylene glycol) copolymer, 14 PTC, 283 Purine, 549 Pyranosiduronic acids, 494 Pyranosyl sugar amino acids, 493 Quinic acid, 363, 401 Radical addition, 79 allylation, 79 cyclization, 81, 86 deoxygenation, 88
Index Reductive amination, 393 deamination, 365 Regiospecific acylation, 383 Renal dysfunction, 345 Reticulum, 584 Rev-RRE, 335 Rhodium catalyst, 480 Ribostamycin, 312, 315 Rifampicin, 134 Rink resin, 516, 527 ROMP (ring-opening metathesis polymerization), 290 Ruscus, 163 Saccharosin, 309, 371 Salbastatin, 325, 416 Salmonella typhosa, 494 Sannamycin, 319, 413 Saponification, 445 Saponin OSW-1, 165 Saponins, 133, 163 Sarsasaponins, 38 Schmidit glycosylation, 169 Schrock catalyst, 102 Schuerch’s hypothesis, 63 SEC, 592 Seldomycin, 313, 318 Selectin antagonists, 285 inhibitors, 265, 267 Selectins, 260, 298 Selective allylation, 123 Sendai viruses, 299 Serine protease, 482 Serine, 494, 495 Sialglycoconjugate, 661 Sialic acid, 177, 178, 253, 259, 277, 289, 495, 549, 551, 652, 661, 669 biosynthesis, 663, 664 synthesis of, 177 Sialidases, 210 Sialodendrimers, 293 Sialopeptoids, 286 SialTs, 549 Sialylated glycoconjugate, 666 Sialyl glycosylations, 197 Lewis acid x (sLex), 260 Lewisx, 281, 299, 582 Lexis X antigen, 190 Sialylactones, 513
681 Sialyllactose, 282, 298 Sialyl T antigen, 179 Sialyltransferase, 199, 201, 549, 663 Sisamine, 371 Sisomicin, 312, 399 Size-exclusion chromatograghy, 560, 592 SLex epitopes, 262 SLex, 263–267 Slug lectin, 293 SMCC, 252 SmI2 (Barbier’s conditions), 279 Smilax, 163 Snti-sense agents, 518 Solanum, 163 Solid phase synthesis, 2, 5, 8, 285 Somatostatin, 526 Sorbistin, 324, 362 Spectinoic acid, 403 Spectinomycins, 402 Sporaricins, 411 SPR (surface plasmon resonance), 241 Staphylococcus aureus, 377 Staphylococcus epidermidis, 379 Steroidal saponins, 163, 164 Stille reaction, 98 Streptamine, 308 Streptidine, 314 Streptomyces, 311 Streptomycin, 134, 307, 336, 342 Streptose, 404 Streptoverticillium, 311 Streptozotocin, 323 Sugar olefins, 80 Superhelix, 531 Support-bound glycosyl acceptors, 11 Surface plasmon resonance (SPR), 234 Suzuki–Miyama cross-coupling, 98 Swern oxidation, 438 Taccacheancer, 172 TFA, 445, 453 Thin-layer chromatography, 559 Thioaryl sialoside, 290 Thioethyl donors, 10, 11 Thioethyl glycosides, 11 Thioglycoside donors, 194 Thioglycosides, 119, 144 Threonine, 495, 526 Thrombin, 468, 482 Thymidylate synthase, 327 Tiffeneau–Demjanov diazonium ion, 403 Tigogenin, 164
682 Tipson–Cohen elimination protocol, 408 TMSOTf (Trimethylsilyl triflate), 16, 112 Tn antigen epitope, 87 Tobramycin, 333, 379 TOCSY, 600 Trehazolin, 324, 416 Tributylstannane, 379, 443 Trifluoroacetic acid (TFA), 470 Trityl resin, 511 Trospectomycin, 404 Tryptophan, 526 Tuberculosis, 307 Turbidimetric analysis, 232 UDP, 559 UDP-cellobiose, 628 UDP-Gal, 537, 542, 543, 559, 560, 605 UDP-galactose, 298 UDP-Glc, 537, 540, 543 UDP-GlcA, 537 UDP-GlcNAc, 537, 543 UDP-N-acetyllactosamine, 540 UDP-Xyl, 537 UMP, 559 Uridine, 560 Uronic acid, 425, 428 Vaccine, 586 Validamycin A, 405
Index Validamycin, 315 Validoxylamine, 405 Valienamine, 320, 405 Valiolamine, 320 van der Waals force, 610 Viral infection, 669 Wacker oxidation, 94, 170 Watson–Crick base-pairing, 518 WGA (wheat germ agglutinin), 286, 293 Wittig reaction, 89, 91, 369 of sugar lactol, 91 with protected sugars, 96 rearrangement, 108 with unprotected sugars, 94 Wittig-cyclization sequence, 96 Xenobiotic, 134 Xenotransplantation, 540, 581, 582, 584, 586 Yeast mannan, 293 YEE (ah-GalNAc)3, 247–249, 252 Ylide, 91, 94 Yucca, 163 Zanamivir (4-guanidino-Neu5Ac2en, GG167), 278 Zemple´n method, 445, 604