Meiobenthology: The Microscopic Motile Fauna of Aquatic Sediments

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Meiobenthology The Microscopic Motile Fauna of Aquatic Sediments

Olav Giere

Meiobenthology The Microscopic Motile Fauna of Aquatic Sediments 2nd revised and extended edition with 125 Figures, 20 Tables, and 41 Information Boxes

Prof. Dr. Olav Giere Universität Hamburg Zoologisches Institut und Zoologisches Museum Martin-Luther-King-Platz 3 20146 Hamburg Germany [email protected]

ISBN: 978-3-540-68657-6

e-ISBN: 978-3-540-68661-3

Library of Congress Control Number: 2008927365 © 2009 Springer-Verlag Berlin Heidelberg This work is subject to copyright. All rights are reserved, whether the whole or part of the material is concerned, specifically the rights of translation, reprinting, reuse of illustrations, recitation, broadcasting, reproduction on microfilm or in any other way, and storage in data banks. Duplication of this publication or parts thereof is permitted only under the provisions of the German Copyright Law of September 9, 1965, in its current version, and permission for use must always be obtained from Springer. Violations are liable to prosecution under the German Copyright Law. The use of general descriptive names, registered names, trademarks, etc. in this publication does not imply, even in the absence of a specific statement, that such names are exempt from the relevant protective laws and regulations and therefore free for general use. Cover design: WMX Design GmbH, Heidelberg Cover illustration: Two interstitial Amblyosyllis (Annelida: Syllidae); courtesy of Nathan W. Riser, Institute of Marine Science, Nahant, Mass., USA. Printed on acid-free paper 9 8 7 6 5 4 3 2 springer.com

To Gaby, to whom I owe it all.

Preface to the Second Edition

Also bestimmt die Gestalt die Lebensweise des Thieres, und die Weise zu leben sie wirkt auf alle Gestalten mächtig zurück. So the shape of an animal patterns its manner of living, likewise their manner of living exerts on the animals’ shape massive effects. goethe 1806: Metamorphose der Thiere

Encouraged by the friendly acceptance of the first edition and stimulated by numerous requests and comments from the community of meiobenthologists, this second edition updates my monograph on meiobenthology. The revised text emphasizes new discoveries and developments of relevance; it has been extended by adding chapters on meiofauna in areas not covered before, such as the polar regions, mangroves, and hydrothermal vents. As I attempted to keep up with the actual literature for the whole field of meiobenthos—taxonomy and ecology, marine and freshwater—I became a little discouraged upon noticing the flood of literature that had appeared in the few years after the publication of the first edition. Has there been a multiplication of new meiobenthologists or an inflation of their industrious efforts? How could I compile this plethora of new data; how to select, what to omit? The need to extract general information from the details, and to modify and amalgamate them within a greater context; this difficult “condensation” process was the key to my approach. It forced me to be selective, to focus on one goal: to write a readable compendium that will serve the interested biologist, the fellow benthologist and the student alike. Avoiding a style with constructions that are too sophisticated should also enhance the comprehension of those readers that are not natively familiar with the English language. Since the first edition, meiofaunal research has made, I believe, major progress in three general areas: (a) systematics, diversity, and distribution; (b) ecology, food webs vii

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and energy flow; and (c) environmental aspects, including studies of anthropogenic impacts. (a) In the area of systematics, diversity and distribution, molecular biological studies suggest that some of the “smaller” meiobenthic groups, such as Kinorhyncha, Gastrotricha and Rotifera, hold key positions in metazoan phylogeny, linking various invertebrate lines into new units (e.g., Ecdysozoa, Scalidophora, Cycloneuralia, Lophotrochozoa). Genetic fine-scale diversification has become an indispensable tool for understanding distribution processes and biogeographic patterns. With enhanced studies in exotic and remote areas, the meiobenthos continues to be a haven for the discovery of unknown animals, even of high taxonomic rank, e.g., Micrognathozoa. Reports on meiofauna from polar or tropical regions, deep-sea bottoms or hydrothermal vents were limited in the first edition due to the scarcity of pertinent studies. Recent comprehensive publications have now recognized these formerly exotic areas as being in the research mainstream, and are covered here in separate chapters. Problems of principal biological relevance, such as the study of distribution patterns or the relation of body size to distribution, have been tackled using meiofauna as tools. The high number of meiobenthic species found under even extreme or impoverished ecological conditions puts meiobenthos at the forefront of biodiversity and “census of life” studies. Taxonomic, functional and genetic diversity as influenced by ecological and/ or anthropogenic variables are widely acknowledged matters of concern. Molecular screening methods allow large numbers of species to be recorded upon expending reasonable effort. (b) Today, essays on aquatic environments mostly consider the relevant role of meiobenthos. Mucus agglutinations and microorganisms are increasingly recognized to be important components that structure the sediment texture and provide the basis for many meiobenthic food chains. Trophic fluxes can be followed using new techniques, such as by assessing isotopic signatures. Metabolic pathways visualized by fluorescence imaging enable us to broaden our limited knowledge of the physiology of meiobenthos. Combined with advanced statistics, such as multivariate analyses, we can achieve results that link meiobenthos to general ecological paradigms. (c) The reactions of biota to environmental threats are increasingly based on evaluations of the meiofauna, underlining their inherent advantages (small size, ubiquity, abundance). With improved processing and culturing methods, pollution experiments are now often based on meiobenthic animals, apply population dynamics and use micro-/mesocosm studies. Standardized bioassays include meiofauna and have become commercially available. The increased role of meiofauna in this field is reflected by new chapters on the impact of metal compounds and pesticides. The use of molecular techniques can alleviate the problem of rapid mass identification, e.g., in nematodes. All of these research fields tie meiobenthology closer to the “mainstream,” which should be a main goal of future meiobenthic research. If this second edition can

Preface

ix

synthesize these modern scientific achievements, meiobenthology could indeed play a key role in assessing the health of our environment, and will not just represent a playground for singular interests. Several comprehensive publications on meiobenthos published in the last few years are contributing to this goal. Of broad interest are monographic publications on freshwater meiobenthos (Hakenkamp and Palmer 2000; Hakenkamp et al. 2002; Robertson et al. 2000a; Rundle et al. 2002). The new edition of the classic treatise Methods for the Study of Marine Benthos (Eleftheriou and McIntyre 2005) contains competent contributions to sediment analysis, sampling strategies and meiofauna techniques (Somerfield et al. 2005). It also covers statistical and analytical methods that assess ecosystem functioning and measure energy flow through benthic populations. Therefore, in this edition of Meiobenthology I have condensed the information in some chapters referring to “Methods for the Study of Marine Benthos.” Lesser known are the meiofauna reviews of Galhano (1970, in Portuguese) and Gal’tsova (1991, in Russian), which were not mentioned in the first edition. In other chapters of this edition (e.g., on polluted sites), the scope has been expanded by adding short accounts of the impacts of metals and pesticides on meiobenthos. The most conspicuous novelty is the highlighted boxes, which either contain the essence of a particular section or comment on special aspects. The figures have been redesigned for higher clarity, and some outdated paragraphs have been shortened or omitted. To maximize readability not all of the publications on which I drew are cited; on the other hand, on several occasions the same publication is cited in a different context in order to make the chapters independently readable and understandable. The resulting reference list is meant to provide an archive of detailed studies in all fields of meiobenthology. A comprehensive index and a glossary explaining specific terms facilitate the use of this book. Because of their ease of accessibility for the general reader, I accentuate references in widely distributed, English-dominated journals. As much as all this may help to improve the distribution and didactic impact of this book, I especially hope, for the sake of the student reader, that Springer-Verlag publishes this new edition at a competitive price that is affordable to all interested in the great world of small organisms. I hope that this edition will be considered as readable and received as warmly by the readers as the 1993 edition. Despite all the care that I have taken, I could not consider every contribution, and so I apologize especially to those colleagues who have published in less common native languages or in journals with restricted distributions, whose results have not been considered here. My particular regrets remain realizing how much valuable knowledge is “hidden” to most of us in the numerous publications that have appeared in Russian over the last few years, much of it unnoticed by many of us. Mistakes in the first edition, for which I apologize, have hopefully been eliminated. I regret and take the responsibility for remaining omissions or erroneous interpretations. Should this book draw the attention of benthic ecologists to the relevance of meiobenthos and foster further research in this field, it has accomplished its goals. Perhaps it represents the last chance to write a monographic textbook that amalgamates bits of information into a coherent context before electronic databases,

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pictures and information networks produce a glut of innumerable details and publications—an information jungle in which the beginner especially can easily become lost. Meiobenthology is now increasingly represented on the Internet: the International Association of Meiobenthologists (I.A.M.) and also many colleagues have often designed comprehensive homepages with address and publication lists. New editions of the I.A.M. newsletter Psammonalia are regularly published online (http://www. meiofauna.org/) and include pictures and even short movie galleries. Also, CD-ROMs and databases of computer-based pictorial identification keys have attained increasing importance (European Limnofauna; European Register of Marine Species, ERMS; separate databases for Nematoda, Harpacticoida, Turbellaria). With this book I conclude many of my activities in meiobenthology. To express my feelings I could do worse than adopting the words of a good friend and protagonist of meiobenthos research, Prof. Bruce C. Coull, who upon his retirement wonderfully characterized his feelings and probably those of many other fellow meiobenthologists of our peer group: “I maintain an interest in all things meiofaunal and it has been a great life studying them. I hope that the next generation of researchers will learn much more about these creature friends and that the researchers have as much fun as I have had trying to understand our ubiquitous and omnipresent aquatic denizens.” Acknowledgements The second edition has been carefully proof-read again by my friend Robert P. Higgins (Ashville, NC, USA). His dedication and encouragement constantly accompanied me while writing this text. Important chapters have been kindly reviewed by two other good friends and experts, Bruce C. Coull (Columbia, SC, USA) and Walter Traunspurger (Bielefeld, Germany). I owe a large intellectual debt to all those many colleagues who invaluably helped me by sending literature, giving comments and, most importantly, kept encouraging me to complete this work. There are far too many to mention them all here by name. I thank Mrs. M. Hänel for her detailed drawings and particularly Mrs. A. Kröger (both Hamburg) for her most valuable and patient computer skills when designing the figures. Finally, Springer-Verlag (Heidelberg, Berlin) is to be thanked for its continuous interest in this project and its “author-friendly” support throughout the correspondence.

Hamburg, July 2008

Olav Giere

Preface to the First Edition

Studies on meiobenthos, the motile microscopic fauna of aquatic sediments, are gaining in importance, revealing trophic cycles and allowing the impacts of anthropogenic factors to be assessed. The bottom of the sea, the banks of rivers and the shores of lakes contain higher concentrations of nutrients, more microorganisms and a richer fauna than the water column. Calculations on the role of benthic organisms reveal that the “small food web”, i.e., microorganisms, protozoans, microphytobenthos, and smaller metazoans, play a dominant role in the turnover of organic matter (Kuipers et al. 1981). New animal groups—even those of high taxonomic status—are often of meiobenthic size and continue to be described. Two of the most recent animal groups ranked as phyla, the Gnathostomulida and the Loricifera, represent typical meiobenthos. Up to now, a textbook introducing the microscopic organisms of the sediments, their ecological demands and biological properties has not existed, despite the significance of meiobenthos indicated above. A recent book entitled Introduction to the Study of Meiofauna (Higgins and Thiel 1988) gives valuable outlines for practical investigation, and Stygofauna Mundi, a monograph edited by Botosaneanu (1986a), focuses on zoogeographical aspects of mainly freshwater forms, but neither was intended to be a comprehensive text on the subject of meiobenthology. The purpose of this book is to provide a general overview of the framework and the theoretical background of the scientific field of meiobenthology. The first of three major parts describes the habitat of meiobenthos and some of the methods used for its investigation; the second part deals with morphological and systematic aspects of meiofauna, and the third part reports on the meiofauna of selected biotopes and on community and synecological aspects of meiobenthos. However, a monographic text cannot include an adequate survey of general benthic ecology, or be a textbook on the zoology of microscopic animal groups. The primary purpose of this text is to provide an ecologically oriented scientific basis for meiobenthic studies. Further advice for practical investigations is found in important compilations by Higgins and Thiel (1988), Holme and McIntyre (1984), and Gray (1981). Hence, aspects of sampling procedures and strategies, statistical treatment and fauna processing will be treated here only briefly. In these fields, the present work should be considered a supplement to the books mentioned above and instead focuses on some critical hints, methodological limitations, and a few neglected practical aspects. xi

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Writing this book was particularly difficult because the literature on meiofauna is so widely dispersed in journals and congress proceedings and has so rapidly increased in volume that complete coverage is impossible. Regardless of my efforts, therefore, there is no pretence that this text is absolutely comprehensive. Where it is important for the general context, the major chapters of the book contain some overlap in terms of information. This is deliberate; it provides the reader with chapters that are complete in themselves and avoids the need for too many crossreferences. Also, in order to maintain a readable, coherent style, citations of specific references had to be restricted. Thus, the “reference list” of this text does not represent all of the sources drawn upon during the production of this book. The selection of topics and the emphasis given to them is admittedly subjective. In particular, the brief treatment of freshwater meiobenthos (Chapter 8.2) by no means reflects the exhaustive achievements and importance of this field of meiobenthology. This book does not include the nanobenthos, since this represents a microbiota that is completely different from the meiobenthos in its size range, methodology, and taxonomical composition (mainly prokaryotes, often autotrophic protists and fungi). Where appropriate, references compiled in a “Recommended reading” paragraph are given at the ends of many chapters. They will serve as supplementary information and, hopefully, will compensate for my own subjectivity. Should incorrect or misunderstood data be reported in the text, I would be most grateful to be informed of this. This book resulted from a series of lectures for advanced students given by the author over a period of several years at the University of Hamburg. Studying the tiny organisms living in sand and mud fascinated many of the students and provided the encouragement and persistent stimulus needed to write this book. It will achieve its goal if it further promotes interest in the diverse and cryptic microscopic world of meiobenthic animals, emphasizes their ecological importance, from both theoretical and practical viewpoints, and contributes to the awareness that small animals often play a key role in large ecosystems, which are becoming increasingly threatened. Acknowledgements I am deeply obliged to Dr. Robert P. Higgins (Washington, DC), who critically reviewed the entire text, and not only for linguistic flaws. My thanks go out to my graduate students who supported me in selecting figures and designing graphs. I am grateful to several of my colleagues for their valuable comments on parts of the text, and for providing me with manuscripts that were sometimes still in press and for other helpful hints. It was my intention to include only originals or redrawn figures. This was possible through the patient work of A. Mantel and M. Hänel (both in Hamburg), for which I am most grateful.

Hamburg, July 1993

Olav Giere

Contents

1

2

Introduction to Meiobenthology . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .

1

1.1 1.2

Meiobenthos and Meiofauna: Definitions . . . . . . . . . . . . . . . . . . . . . A History of Meiobenthology. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .

1 2

The Biotope: Factors and Study Methods . . . . . . . . . . . . . . . . . . . . . . . .

7

2.1

Abiotic Factors (Sediment Physiography) . . . . . . . . . . . . . . . . . . . . . 2.1.1 Sediment Pores and Particles . . . . . . . . . . . . . . . . . . . . . . . . . 2.1.2 Granulometric Characteristics . . . . . . . . . . . . . . . . . . . . . . . . 2.1.3 The Sediment–Water Regime . . . . . . . . . . . . . . . . . . . . . . . . . 2.1.4 Physicochemical Characteristics. . . . . . . . . . . . . . . . . . . . . . . Biotic Habitat Factors: A Connected Complex . . . . . . . . . . . . . . . . . 2.2.1 Detritus and Particulate Organic Matter (POM). . . . . . . . . . . 2.2.2 Dissolved Organic Matter (DOM) . . . . . . . . . . . . . . . . . . . . . 2.2.3 Mucus, Exopolymers, and Biofilms . . . . . . . . . . . . . . . . . . . . 2.2.4 Bacteria . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 2.2.5 Microphytobenthos . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 2.2.6 Higher Plants. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 2.2.7 Animals Structuring the Ecosystem . . . . . . . . . . . . . . . . . . . . Conclusion: The Microtexture of Natural Sediments . . . . . . . . . . . . .

7 7 9 14 22 37 38 40 41 43 48 53 53 59

Sampling and Processing Meiofauna . . . . . . . . . . . . . . . . . . . . . . . . . . . .

63

3.1

63 63 64 72 72 73 77 80 84

2.2

2.3 3

Sampling . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 3.1.1 Number of Replicates and Size of Sampling Units . . . . . . . . 3.1.2 Sampling Devices . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 3.2 Processing of Meiofaunal Samples. . . . . . . . . . . . . . . . . . . . . . . . . . . 3.2.1 Preserving Meiofauna in Their Natural Void System . . . . . . . 3.2.2 Extraction of Meiofauna . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 3.2.3 Fixation and Preservation . . . . . . . . . . . . . . . . . . . . . . . . . . . . 3.2.4 Processing and Identifying Meiofaunal Organisms . . . . . . . . 3.3 Extraction of Pore Water. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .

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4

Contents

Biological Characteristics of Meiofauna . . . . . . . . . . . . . . . . . . . . . . . . .

87

4.1

87

Adaptations to the Biotope . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 4.1.1 Adaptations to Narrow Spaces: Miniaturization, Elongation, Flexibility . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 4.1.2 Adaptations to the Mobile Environment: Adhesion, Special Locomotion, Reinforcing Structures . . . . 4.1.3 Adaptations to the Three-Dimensional Dark Environment: Static Organs, Reduction of Pigment and Eyes . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 4.1.4 Adaptations Related to Reproduction and Development . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .

87 92

97 99

5 Meiofauna Taxa: A Systematic Account . . . . . . . . . . . . . . . . . . . . . . . . . 103 5.1

5.2

5.3

5.4

5.5 5.6

5.7 5.8

Protista (Protoctista) . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 5.1.1 Foraminifera (Rhizaria: Granuloreticulosa) . . . . . . . . . . . . . . 5.1.2 Heliozoa (Actinopodia). . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 5.1.3 Amoebozoa (“Rhizopoda”): Gymnamoebea, Testacea. . . . . . 5.1.4 Ciliophora (Ciliata) . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . Cnidaria. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 5.2.1 Hydroida (Medusae) . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 5.2.2 Hydroida (Polyps). . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 5.2.3 Scyphozoa. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 5.2.4 Anthozoa. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . Free-Living Platyhelminthes: Turbellarians . . . . . . . . . . . . . . . . . . . . 5.3.1 Major Turbellarian Groups . . . . . . . . . . . . . . . . . . . . . . . . . . . 5.3.2 Distributional and Ecological Aspects . . . . . . . . . . . . . . . . . . Gnathifera . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 5.4.1 Gnathostomulida. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 5.4.2 Rotifera, Rotatoria . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 5.4.3 Micrognathozoa . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . Nemertinea . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . Nemathelminthes: A Valid Taxon? . . . . . . . . . . . . . . . . . . . . . . . . . . . 5.6.1 Nematoda (Free-Living) . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 5.6.2 Kinorhyncha . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 5.6.3 Priapulida . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 5.6.4 Loricifera . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 5.6.5 Gastrotricha. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . Tardigrada . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . Crustacea. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 5.8.1 Cephalocarida . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 5.8.2 Anostraca: Anomopoda (“Cladocera”; “Branchiopoda”) . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 5.8.3 Ostracoda . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .

103 103 107 107 108 114 116 116 118 118 119 120 123 127 127 129 133 134 136 137 156 158 160 162 165 171 172 173 175

Contents

5.9

5.10 5.11

5.12 5.13

5.14

5.15 5.16 5.17 5.18

5.19 6

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5.8.4 Mystacocarida. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 5.8.5 Copepoda: Harpacticoida . . . . . . . . . . . . . . . . . . . . . . . . . . 5.8.6 Copepoda: Cyclopoida and Siphonostomatoida . . . . . . . . . 5.8.7 Malacostraca . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . Chelicerata: Acari . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 5.9.1 Halacaroidea: Halacaridae . . . . . . . . . . . . . . . . . . . . . . . . . 5.9.2 Freshwater Mites: “Hydrachnidia,” Stygothrombiidae, and Others . . . . . . . . . . . . . . . . . . . . . . 5.9.3 Palpigradi (Arachnida) . . . . . . . . . . . . . . . . . . . . . . . . . . . . 5.9.4 Pycnogonida, Pantopoda. . . . . . . . . . . . . . . . . . . . . . . . . . . Terrigenous Arthropoda (Thalassobionts) . . . . . . . . . . . . . . . . . . . . Annelida . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 5.11.1 Polychaeta. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 5.11.2 Oligochaeta . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 5.11.3 Annelida “Incertae sedis” . . . . . . . . . . . . . . . . . . . . . . . . . . Sipuncula . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . Mollusca . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 5.13.1 Monoplacophora and Aplacophora. . . . . . . . . . . . . . . . . . . 5.13.2 Gastropoda . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . Tentaculata . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 5.14.1 Brachiopoda . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 5.14.2 Bryozoa, Ectoprocta . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . Kamptozoa, Entoprocta . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . Echinodermata . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 5.16.1 Holothuroidea . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . Chaetognatha . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . Tunicata (Chordata) . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 5.18.1 Ascidiacea. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 5.18.2 Sorberacea. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . Meiofaunal Taxa: Concluding Remarks . . . . . . . . . . . . . . . . . . . . . .

180 181 189 190 201 201 205 205 206 207 207 208 215 218 221 223 223 225 226 226 227 228 229 229 230 231 231 232 233

Evolutionary and Phylogenetic Effects in Meiobenthology . . . . . . . . . . 235 6.1 6.2

Body Structures of Evolutionary Relevance . . . . . . . . . . . . . . . . . . . 235 Meiofauna in the Fossil Record . . . . . . . . . . . . . . . . . . . . . . . . . . . . 239

7 Patterns of Meiofauna Distribution . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 243 7.1 7.2

7.3 7.4

Evolutionary Aspects . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . Zoogeographic Aspects. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 7.2.1 Mechanisms of Dispersal . . . . . . . . . . . . . . . . . . . . . . . . . . 7.2.2 Geological Structures and Processes . . . . . . . . . . . . . . . . . Ecological Aspects of Distributional Importance: Horizontal Patterns . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . Vertical Zonation of Meiobenthos . . . . . . . . . . . . . . . . . . . . . . . . . .

243 249 250 256 259 261

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Contents

Meiofauna from Selected Biotopes and Regions . . . . . . . . . . . . . . . . . . . 267 8.1 8.2

8.3

8.4

8.5 8.6 8.7

8.8

9

Polar Regions . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 8.1.1 Sea Ice. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . Marine Subtropical and Tropical Regions . . . . . . . . . . . . . . . . . . . . . 8.2.1 Tropical Sands . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 8.2.2 Mangroves. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . The Deep-Sea . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 8.3.1 The Habitat . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 8.3.2 The Meiofauna . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . Dysoxic, Anoxic, and Sulfidic Environments: Discussing the Thiobios . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 8.4.1 Reducing Habitats of the Thiobios . . . . . . . . . . . . . . . . . . . . . 8.4.2 Thiobiotic Meiobenthos . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 8.4.3 Survival of Thiobios Under Anoxia and Sulphide – Mechanisms and Adaptations. . . . . . . . . . . . . . . . 8.4.4 Food Spectrum of the Thiobios . . . . . . . . . . . . . . . . . . . . . . . 8.4.5 Distribution and Succession of the Thiobios . . . . . . . . . . . . . 8.4.6 Diversity and Evolution of the Thiobios. . . . . . . . . . . . . . . . . 8.4.7 Chemoautotrophy-Based Ecosystems: Vents, Seeps, and Other Exotic Habitats . . . . . . . . . . . . . . . . . . . . . . Phytal Habitats and Hard Substrates. . . . . . . . . . . . . . . . . . . . . . . . . . Brackish Water Sites . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . Freshwater Biotopes . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 8.7.1 Running Waters: Stream and River Beds . . . . . . . . . . . . . . . . 8.7.2 The Groundwater System . . . . . . . . . . . . . . . . . . . . . . . . . . . . 8.7.3 Standing Waters, Lakes. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . Polluted Habitats. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 8.8.1 General Aspects and Method Survey . . . . . . . . . . . . . . . . . . . 8.8.2 Selected Cases of Pollution and Meiofauna . . . . . . . . . . . . . .

268 270 276 278 280 284 284 287 296 296 298 302 307 308 309 313 317 324 328 329 338 344 349 349 361

Synecological Perspectives in Meiobenthology . . . . . . . . . . . . . . . . . . . . 373 9.1 9.2 9.3

9.4

Community Structure and Diversity . . . . . . . . . . . . . . . . . . . . . . . . . . 9.1.1 Processes of Recolonization . . . . . . . . . . . . . . . . . . . . . . . . . . Community Structure and Size Spectra . . . . . . . . . . . . . . . . . . . . . . . The Meiobenthos in the Benthic Energy Flow . . . . . . . . . . . . . . . . . . 9.3.1 General Considerations. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 9.3.2 Assessing Production: Abundance, Biomass, P/B Ratio, Respiration . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 9.3.3 The Energetic Divergence Between Meiofauna and Macrofauna . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . The Position of Meiofauna in the Benthic Ecosystem: A Compilation of Energy Fluxes . . . . . . . . . . . . . . . . . . . . . . . . . . . . 9.4.1 The Meiofauna as Members of the “Small Food Web” . . . . . 9.4.2 Links Between the Meiofauna and the Macrofauna . . . . . . . . 9.4.3 Meiofauna as an Integrative Benthic Complex. . . . . . . . . . . .

373 375 377 383 383 387 397 400 402 406 410

Contents

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10 Retrospect on Meiobenthology and Outlook on New Approaches and Future Research. . . . . . . . . . . . . . . . . . . . . . . 417 References . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .

423

Glossary . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .

503

Index . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .

513

Chapter 1

Introduction to Meiobenthology

1.1

Meiobenthos and Meiofauna: Definitions

The terms “macrobenthos” and “microbenthos” were already well established when in 1942 Molly F. Mare coined the term “meiobenthos” to define an assemblage of benthic metazoans that can be distinguished from macrobenthos by their small sizes (note that the Greek “µειος” means “smaller”). Therefore, the study of meiobenthos per se is a relatively new component of benthic research, despite the fact that meiobenthic animals have been known about since the early days of microscopy. This book will mainly focus on metazoan meiofauna, which mirrors the author’s field of expertise. Hence, the term “meiobenthos” is used here synonymously to “meiofauna.” However, an ecological picture cannot be drawn without also considering relevant benthic protists (e.g., ciliates, foraminiferans, amoebozoans), and microalgae (e.g., diatoms). Today, members of the meiofauna are considered mobile and sometimes also haptosessile benthic animals, smaller than macrofauna but larger than microfauna (the latter term is now restricted mostly to Protozoa). The formal size boundaries of meiofauna are operationally defined, based on the standardized mesh width of sieves with 500 µm (1,000 µm) as upper and 44 µm (63 µm) as lower limits: all fauna that pass through the coarse sieve but are retained by the finer sieve during sieving are considered meiofauna. In a recent move, a lower size limit of 31 µm has been suggested by deep-sea meiobenthologists in order to quantitatively retain even the smallest meiofaunal organisms (mainly nematodes). Using biomass as a measure, meiofauna (in freshwater) have been defined to include all mobile benthic organisms with masses of between 2 and 20 µg (Hakenkamp et al. 2002). What began as an arbitrarily defined size-range of benthic invertebrates has since been supported by studies on the size spectra of marine benthic fauna. Quantitative sizetaxon studies (Schwinghamer 1981a; Warwick 1984; Warwick et al. 1986a; Duplisea and Hargrave 1996—see Sect. 9.2) infer that the (marine) meiofauna represent a separate biologically and ecologically defined group of animals, a concept well known in the case of the (interstitial) meiofauna of sands (Remane 1933, see Sect. 1.2). In addition to the “permanent” meiofauna, members of the “temporary” meiofauna belong to the meiofaunal size category only as newly settled larvae that later grow

O. Giere, Meiobenthology, 2nd edition, doi: 10.1007/b106489, © Springer-Verlag Berlin Heidelberg 2009

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1 Introduction to Meiobenthology

to become macrofauna. An exact upper size limit that will be passed by these temporarily small organisms (often juvenile molluscs and annelids) is difficult to define. Meiofauna are mostly found in and on soft sediments, but also on and among epilithic plants and other hard substrates (e.g., animal tubes). Even the surfaces of barren rocks with their biofilm and detritus cover are suitable habitats. Under each footprint of moist shore sediment we often find 50,000–100,000 meiobenthic animals! Indeed, it is unclear why the meiobenthos was not recognized earlier as a valid intermediate between the micro- and the macrobenthos. It seems inconsistent with the fact that the microscopic fauna in the water column had long been considered an established faunistic assemblage. Personally, I believe that bare sand bottoms and beaches and the often odiferous muds were considered unlikely habitats for diverse fauna of minute dimensions. More detailed reading: Warwick (1989), Palmer et al. (2006), Rundle et al. (2002).

Box 1.1 Meiofauna, Meiobenthos: Definitions The term “meiofauna” denotes microscopically small, motile aquatic animals living mostly in and on soft substrates at all depths in the marine and freshwater realm. Although originally restricted to small metazoans, ecological connections suggest that larger protozoans (ciliates, amoebozoans) should also be included in the scope of meiofauna. In the context of this book, this wider definition is used synonymously with meiobenthos. Formally defined by sieve mesh sizes of between 44 and 500 mm, meiobenthos is increasingly considered an ecological unit of its own, an important link between microand macrobenthos. In contrast to permanent meiobenthos, the newly settled larvae of many macrobenthic animals are temporary meiofauna.

1.2

A History of Meiobenthology

Taxonomic descriptions and biological investigations of minute benthic animals were being published by the mid nineteenth century. One of the first of these was on the discovery of a minute aberrant mollusc, the aplacophoran Chaetoderma by Lovén in 1844, then described as a new worm genus, and the Kinorhyncha described by Dujardin in 1851. In 1901, Kovalevsky studied Microhedylidae (Gastropoda) in the Eastern Mediterranean, and in 1904, Giard described the first archiannelid Protodrilus from the coast of Normandy. He even stated that the microscopic fauna were so rich “that it would take years to study them.” However, these pioneers of meiofauna considered only isolated taxa—often the exceptional species of known invertebrate groups—not their ecological niches and community aspects.

1.2 A History of Meiobenthology

3

Since then, field investigations were biased towards commercially interesting macrofauna. Consequently, a suitable methodology for specifically sampling the smaller benthic animals had to be developed. It was Remane who first used finemeshed plankton nets to filter the “coastal ground water,” and he used dredges with sacks of fine gauze to perform equally pioneering studies of the microscopic fauna of (eulittoral) muddy bottoms (“pelos”) and of the small organisms associated with surfaces of aquatic plants (“phyton”) ). Remane summarized this work in a monograph entitled Verteilung und Organisation der benthonischen Mikrofauna der Kieler Bucht (1933), where he first used the word “Sandlückenfauna.” The corresponding term “interstitial fauna,” introduced by Nicholls (1935), comprised all animals living in interstices, not only those of meiobenthic size, e.g,. polychaetes in a pebble beach. Aside from his important descriptions of new kinds of animals, the significance of Remane’s work is reflected by his contention that the meiobenthic fauna of sand were not merely a loose aggregation of isolated forms, but “a biocoenosis different not only in species number and occurrence, but also in characteristics of form and function” (Figs. 8.11 and 8.12). In his 1952 paper, Remane embodied this concept in the word “Lebensformtypus,” which has since been incorporated into the terminology of general ecology. The ubiquity and complexity of this smaller benthos became much clearer with the development of effective grabs (Petersen 1913) and dredges (Mortensen 1925) for sampling subtidal bottoms. With improved methods (e.g., Moore and Neill 1930; Krogh and Spärck 1936), studies on the small benthos soon emerged from many parts of the world. From Remane’s school came numerous German scientists of considerable influence in meiofaunal research, e.g., Ax, Gerlach, Noodt, to name just a few. Through their work Remane’s stimulus even proliferated to further generations of meiobenthologists (Westheide, Schminke, Riemann) in Germany. From Britain, Moore (1930, 1931), Nicholls (1935) and Mare (1942) initiated the study of meiofauna. At the beginning of the 1960s Boaden and Gray were among the first to perform experiments with marine meiofauna. In 1969, McIntyre compiled the first review, Ecology of Marine Meiobenthos, which is still a valuable source of information, particularly for data on meiofauna from tropical areas. By studying the fauna of the Normandy coast of the Channel, the Swedish researcher Swedmark focused attention on the rich interstitial fauna, and described many hitherto unknown species. His review The Interstitial Fauna of Marine Sand (1964) is considered a classic among early meiofaunal literature. Working along the shores of the Mediterranean Sea, Delamare Deboutteville concentrated his research into the meiobenthos on the brackish transition areas between the marine and freshwater realms. He was the first to conduct meiofaunal research along the African shores. His book Biologie des Eaux Souterraines Littorales et Continentales (1960) is another much-esteemed compendium of meiofaunal research. What about North America, now one of the main centers of meiofaunal research? The early marine meiofaunal studies were linked to just a few names, e.g., Pennak, Sanders, and Zinn, who discovered important new crustacean groups. Some European scientists working in the US also contributed to the further development of this field: the studies of the Austrians Riedl, Wieser and Rieger in the 1950–1980s

4


stimulated several American students to become meiobenthologists. The 1960s saw the beginning of American investigations directed primarily at ecology (e.g., Tietjen), which continue to be a major thrust of American meiobenthology, and are mostly concentrated along the Atlantic and Gulf coasts of the United States. Beginning in the 1970s the school of Coull began investigating the soft-bottom meiofauna, often addressing environmental problems (disturbance, predation, pollution) and using field experimental methods in estuarine soft bottoms. Its impact drew the attention of general marine benthologists to meiofauna. The development of meiobenthology in the freshwater realm went separate ways, used different methods, and even produced a separate nomenclature. Still now, research on freshwater meiobenthos is not well coupled with its marine counterpart, although both Remane and Delamare Deboutteville often emphasized the connections between marine and freshwater meiofauna, especially those of a zoogeographical and evolutionary nature. Similar to the situation in the marine field, important taxonomic work was performed early in the nineteenth century, especially on benthic freshwater copepods (e.g., the works of Sars, Claus, Lang, Gurney), but freshwater meiobenthology, as an ecological discipline, started later. It developed independently with the Russian Sassuchin and colleagues (1927), who sampled at a river shore. They first described the “psammon,” i.e., the fauna and flora of sand. Today, this term is specified as “mesopsammon,” the fauna between sand grains (= interstitial fauna of sands), in contrast to the mostly macrobenthic “epipsammon” (i.e., species that live burrowing in the sand) and “endopsammon” (species that live burroweing in the sand). Wiszniewski (1934) conducted similar studies in Polish rivers and lakes that emphasized the important role of rotifers (see Sect. 8.7). While in England, Germany, France and Belgium early papers on the freshwater psammon remained rather isolated and mainly taxonomic in nature, it was the American Pennak who included a wider faunal spectrum in his ecological and faunistic considerations. His monograph Ecology of the Microscopic Metazoa Inhabiting the Sandy Beaches of Some Wisconsin Lakes (1940) is one of the classic publications in freshwater meiobenthology. His ecological comparison of freshwater and marine interstitial fauna (1951) provided valuable insights into the characteristics of these two biomes, an approach later continued in the USA by Palmer and Strayer. Related to the research of Delamare Deboutteville were the investigations of Angelier (1953) on the river shores and banks in the south of France exposed during the dry season. Detailed granulometric and physiographic descriptions of the biotopes are a characteristic of this work. The importance of the hydrological regime was the subject of the meiobenthos studies by Ruttner-Kolisko (beginning in 1953) in Austrian mountain streams and rivers. In Switzerland Chappuis started a series of investigations (beginning in 1942) on the fauna of the groundwater. He found the “stygobios” to be a distinct faunal element (see Sect. 8.2.1). The “hyporheic” biotopes beneath streams and rivers were the research domain of Karaman (1935), Orghidan (1955) and collaborators. They were attracted by the interesting subterranean fauna of karstic rivers in

1.2 A History of Meiobenthology

5

Southeast Europe and contributed much to the early knowledge of cave meiobenthos, today also termed “troglobitic” fauna. From the 1960s Danielopol worked intensively on hyporheic and lacustrine meiobenthos, mainly in Austria. Although specializing in ostracods, he and his colleague Stock from Holland also focused on general evolutionary aspects, discussing the colonization pathways for subterranean habitats (see Sect. 8.7.2). The ecology of groundwater fauna has been well covered in a volume edited by Gibert et al. (1994). A summary of methods for studying freshwater meiofauna has been provided by Palmer et al. (2006). Based mainly on lake meiofauna, Rundle et al. (2002) provided a competent review of freshwater meiobenthos. Meiofauna of lotic ecosystems (streams) is covered in a special volume edited by Robertson et al. (2000a,c). Enhancing our insight into their similarities and differences will hopefully reduce the historical separation between marine and freshwater meiofaunal research. Today, several hundred scientists are working to expand our knowledge of meiofauna from alpine lakes to the deep-sea floor, from tropical reefs to polar sea ice. However, despite an increasing number of meiobenthologists working in Africa, South America, Asia and Australia, the meiobenthos in these continents is as yet largely unknown. Studies of the deep-sea meiobenthos gain increasing momentum with the development of sophisticated maneuverable vehicles. As in other biological sciences, the structure of meiobenthological research evolved from isolated and individualistic taxonomic descriptions to assessments of abundance and distribution principles worked out by teams. These were the foundation for ecological research that, after implementing sophisticated statistical methods, could tackle complex problems such as pathways of distribution, community functioning and the impact of disturbances. From there, studies on environmental effects and on anthropogenic disturbance and pollution using meiofauna as sentinels were a logical consequence. The future of meiobenthology (see Chap. 10) will largely depend on how well we understand how to incorporate the specific potentials of meiobenthic animals into mainstream benthic research. The adoption of molecular methods will decisively contribute to future development. We should address the importance of global climate change and advocate more strongly than before the value of using the ubiquitous and speciose meiofauna to assess the health of ecosystems. Most meiobenthologists are members of the International Association of Meiobenthologists (IAM) (http://www.meiofauna.org/) and thus receive its newsletter Psammonalia for information on current fields of interest, members’ research projects and recent literature. The triennial conferences of the IAM are important occasions for the mutual exchange of results, experiences and developments, and members from countries that are now starting to perform meiobenthic research are increasingly participating in these conferences. The website provides information on upcoming events, new results and the e-mail addresses of all of the members. Scientists from remote places that are often cut off from the mainstream of meiofaunal research can also use such electronic media to easily contact their colleagues and access recent literature. The development of electronic species registers, iden-

6


tification guides, and expert lists (e.g., the European Register of Marine Species, ERMS; NEMYS) has enabled easier access in order to solve the diversity problem of meiofauna. Thus, due to the increasing “globalization” of meiofaunal research through new technical achievements, meiofaunal research will be better dispersed into areas hampered by their social or geographical isolation. More detailed reading: Remane (1933); Pennak (1940); Swedmark (1964); Delamare Deboutteville (1960); Ax (1966); Schwoerbel (1967); McIntyre (1969); Coull and Chandler (1992); Gibert et al. (eds. 1994); Robertson et al. (2000c); Rundle et al. (2002).

Box 1.2 Meiobenthology: A Young Research History Meiofaunal research, especially meiobenthic ecology, as initiated by Remane, is a fairly young field. Aside from singular and scattered early descriptions of strange tiny organisms, the field of marine meiofaunal research originated in the first decades of the twentieth century in Europe, starting with taxonomic and basic ecological work. More complex ecological approaches were characteristic of research carried out between 1960 and 1980 in Europe and particularly in the US. Freshwater studies began independently in eastern European rivers, Swiss streams, and North American lakes. Marine and freshwater studies of meiobenthos developed along different lines and only recently prompted the ecological parallels a common nomenclature. Reasons for the relatively late start of multidirectional meiofaunal research may include the inconspicuous nature of meiobenthic organisms and their unspectacular habitats. This may have confounded the real phylogenetic and ecological roles of meiofauna. Today, the International Meiofauna Association and its triennial conferences bring together work in all fields of meiofauna research and most scientists that are studying meiobenthos.

Chapter 2

The Biotope: Factors and Study Methods

2.1 2.1.1

Abiotic Factors (Sediment Physiography) Sediment Pores and Particles

When describing the habitats of meiofauna, grain size is a key factor since it directly determines spatial and structural conditions and indirectly determines the physical and chemical milieu of the sediment. Poorly sorted sediment particles (e.g., sand mixed with gravel and silt) become tightly packed and the interstitial pore volume is often reduced to only 20% of the total volume. Well-sorted (coarse) sediments contain up to 45% pore volume. According to RuttnerKolisko (1962), most field samples of unsorted freshwater sand have 40% pore volume. Aside from pore volume, the external surface area of the sediment particles is an important determinant of meiobenthic life. It directly defines the area available for the establishment of biofilms (mucus secretions of bacteria, fungi, diatoms, fauna), which, under natural conditions, form the matrix into which the sediment particles are embedded. Thus, particle surface is an important parameter for microscopic animal life. This internal surface is unbelievably large: for a 1-m3 stream gravel it has been calculated to amount to about 400 m2. One gram of dry fine sand with a median particle diameter of 63–300 µm may have a total surface area of 8–12.5 m2; if it consists mostly of diatom shells, this value can even exceed 20 m2, whereas for 1 g of coarse-grained calcareous sand a value of just 1.8 m2 was calculated (Suess 1973; Mayer and Rossi 1982). In addition to size, the grain shape also determines the sorting of the sediment. Angular, splintery particles are packed tighter than spherical ones. A higher angularity leads to more structural complexity, less water permeability and usually higher abundance of meiofauna (Fig. 2.1; see Conrad 1976). A direct correlation between pore dimensions and body size of meiofaunal animals has been demonstrated experimentally (Williams 1972). In general, mesobenthic species moving between the sand grains prefer coarse sands, while endo- and epibenthic ones are


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2 The Biotope: Factors and Study Methods

Fig. 2.1 The pore system in sediments consisting of grains with a round shape (glass beads; left) vs. natural grains of angular shape (right); note differences in pore space due to different packing. (After Conrad 1976; modified)

mostly encountered in fine to silty sediments. These sediment differences affect the two major groups of meiobenthos, nematodes and harpacticoids. The finer sediments are preferred by most nematodes, while coarser ones are often favored by harpacticoids (Coull 1985). Within the nematode taxon, the preference for a specific grain size was found to relate to certain ecological types (Wieser 1959a). “Sliders” live in the wide voids of coarse sand; below a critical median grain size of about 200 µm, the interstices become too narrow. Thus, fine sand and mud will be populated by “burrowers” (Fig. 2.2). The particle shape determines the colonization of the sediment by meiofauna through indirect action via water content and by permeability (Sect. 2.1.3). The colonization of sand by meiobenthos is also determined by the grain structure, the roughness of edges, and the shapes of grain surfaces and cracks. These are important parameters that structure the microhabitats of different bacterial colonies (Meadows and Anderson 1966). Sand grains with diameters of >300 µm frequently have more plain surfaces than smaller particles; they also have a different bacterial epigrowth. This diversification has been shown to attract different meiofauna (Marcotte 1986a, Watling 1988). Likewise, in comparative experiments, cores of different grain sizes have been colonized by different meiobenthos. This emphasizes the capacity of meiofaunal species to chose and “recognize” their preferred sediment (Boaden 1962; Gray 1965; Hadl et al. 1970; Vanreusel 1991). Although the direct structural impact of the sediment particles is mostly confounded by other factors, e.g., biofilms, water flow, etc. (see Table 2 in Snelgrove and Butman 1994), there are strong affinities of specific meiofauna for specific sediments (Schratzberger et al. 2004). The structure and dimensions of the pore system are also directly correlated with the anatomy of the inhabitants and the functions of their organs (Ax 1966; Lombardi and Ruppert 1982).

2.1 Abiotic Factors (Sediment Physiography) >400 µm >400 µm 9ϕ

63 40 cm × h−1) exceeded diffusive transport by at least three orders of magnitude (Precht and Huettel 2003). Each lengthwise beach meter is percolated by several cubic meters of seawater each day. The yearly volume of the global shelf filtered (the “subtidal pump”) by the forces of percolation far exceeds the precipitation volume on land (Riedl and Machan 1972; Riedl et al. 1972). Berelson et al. (1999) calculated that within two hundred days the entire water column of Port Phillip Bay, Melbourne (Australia) passes through the sediment. In a tidal beach, 1 m2 of coarse sand filtered 14 L of water each hour (Rusch and Huettel 2000), a value also confirmed for Mediterranean shores (Precht and Huettel 2004). Even the small-scale topography of sandy bottoms massively influences advective water flux and particle transport. On the exposed sides of sediment mounds or ripple marks, surface water and organic particles penetrated about seven times deeper into the sediment than on the sheltered sides (Ziebis et al 1996; Huettel and Rusch 2000). The small-scale topography also directs the water flow, with intrusion occurring mainly in the ripple troughs and release occurring after filtration at the crests (Precht and Huettel 2004).

2.1 Abiotic Factors (Sediment Physiography)

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The pore water velocity was first assessed by inserting heated thermistors into the sediment (Riedl and Machan 1972); microflowmeters based on minute thermistors were later used by researchers (LaBarbera and Vogel 1976; Davey et al. 1990). The cooling effect of the currents on a heated wire produces a voltage signal on a monitor, which, after calibration, indicates the microflow of water. Similarly, changes in the potential of a platinum wire used to measure the oxygen diffusion rate in sediments can be calibrated to record water microflows. Malan and McLachlan (1991) measured the pumping effects of waves and emphasized that most authors have underestimated wave-induced sediment water fluxes and their impact on the oxygen distribution. Long-term in situ records with oxygen microelectrodes have also indicated strong tide- and wave-dependent water pressure gradients (Weber et al. 2007). Precht and Huettel (2004) visualized the pore water flow in the field by applying fluorescent dye to the sediment and measuring it with an optical sensor (optode, see Sect. 2.1.4). Porosity. The total pore volume of a sediment core, its porosity or void ratio, depends in a complex way on the shape, sorting and mixing of the particles, and not just on the pore size available to the animals. Thus, it is not directly predictable from sieving data alone, but it is, of course, of relevance for physicochemical fluxes in the sediment. For mechanical measurements of porosity see Buchanan (1984) or Bale and Kenny (2005). Porosity profiles can also be calculated using electrodes, by measuring the resistivity of the sediment lattice (Archer et al. 1989). The velocity of the pore water flowing through the interstitial system does not depend solely on the hydrodynamics of the overlying water. The fluxes in the chemical milieu of sediments are strongly influenced by the sediment texture (see below). This, in turn, is controlled by bioturbation, sediment reworking, bioirrigation, and mucilage secretion of the benthic fauna (Graf and Rosenberg 1997; Pike et al. 2001; Berg et al. 2001; Murray et al. 2002; Meysman et al. 2006a,b), see below. Bioturbation. The biological reworking of sediments by endobenthic organisms, termed “bioturbation,” affects all sediments, limnetic and marine, from shallow tidal flats to deep-sea bottoms. In modern ecology, bioturbation is considered a major factor in the engineering of all benthic ecosystems (Meysman et al. 2006a) and in the creation of three-dimensional sediment structure (Lohrer et al. 2004). Because of its numerous biogeochemical implications, bioturbation probably had a massive influence on the archaic evolution of life (Bottjer et al. 2000; Dornbos et al. 2005; see Chap. 7). Among macrobenthos, bioturbation is mostly caused by the burrowing and digging of crustaceans and annelids. Bioturbative effects can extend to a sediment depth of >20 cm. Extrapolations suggest that in tidal flats the upper 10 cm of the sediment will become completely bioturbated once every three years. Depending on the population density, bioturbation can decrease compaction, and can even destabilize the bottom and increase its erodibility (Widdows et al. 2000). It provides a system of tubes and voids and enhances sediment mixing through particle exchange down to greater depths. Even sediment particles from a depth of 50 cm will be transferred to the surface. The burrows of the priapulid Halicryptus

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spinulosus or the decapod Trypea (Callianassa) create a “secondary surface” of 0.7 m2 per surface m2 in muddy bottoms (Förster and Graf 1992; Powilleit et al. 1994). Transport rates of 40–50 g sediment per individual and day have been recorded through the burrow and void system. The subsequent increased water penetration accelerates the transport of solutes and gases more than diffusion (Diaz et al. 1994; Berelson et al. 1999; Berg et al. 2001). Twenty-five percent of the overall oxygen flux is attributed to the irrigational activity of burrowing animals (Booij et al. 1994). Bioirrigative water and solute transport into the sediment can exceed normal diffusion by a factor of ten (Aller 1988; Aller and Aller 1992; Kristensen 1988; De Deckere et al. 2001). Thus, benthic fauna markedly increases the flux of particles and modifies the physical processes (Graf and Rosenberg 1997). This has both beneficial and aggravating effects: organic matter and pollutants can be removed from the surface and buried into deeper layers where degradation is slow. On the other hand, the export of contaminated pore water is enhanced by bioturbators (Green and Chandler et al. 1994; Levin et al. 1997). By altering the geochemical system with animal tubes, and particularly through the import of oxygenated water by irrigational fluxes into anoxic layers, heavy metal precipitates (sulfides) that are buried at depth will become dissolved and released into the surficial, oxygenated layers (Green and Chandler 1994). Also phosphates and ammonium compounds are released in considerable amounts from the sediment by bioturbation and bioirrigation. The result is (often undesirable) eutrophication with an enhanced production of microphytobenthos in the overlying water (Monaghan and Giblin 1994). Bioturbative effects have also been shown to cause an undersaturation of calcites in the surficial layers, leading to increased shell dissolution and mortality (Green et al. 1998). Just as the sources of bioturbation are very diverse, their effects on meiobenthos are also very complex: negative impacts through disturbance and destabilization, positive ones through the oxygen and organic matter supplied (Green and Chandler 1994; Aarnio et al., 1998, Schratzberger and Warwick 1999; Thistle et al. 1999; Koller et al. 2006). Using radioactive isotopes and fluorescent dye as tracers, Bradshaw et al. (2006) found only minor chemical effects of bioturbation in Baltic Sea sediments compared to those of physical processes. On a general scale, the chemical impacts of the biogenic mobilization of buried chemical pollutants on meiofauna have not yet been sufficiently evaluated. While macrofaunal burrows affect the sediment, even the dense net of mmfine burrows of meiofauna can have a considerable influence on sediment structure and fauna colonization (Reichelt 1991, Fenchel 1996; Jensen 1996). Among meiobenthos, effective bioturbators are ostracods, nematodes and, particularly at the surface, harpacticoid copepods. Cullen (1973) experimentally demonstrated the bioturbative impact of meiofauna. He found that their burrowing activities alone eliminated all surface traces of macrofauna within 14 days. In average sandy sediment, the burrowing of meiofauna will completely displace the pore water in 1–3 years (Reichelt 1991). Because of meiofaunal bioturbation the transport of solutes with the subsequent stimulation of microbial mineralization was


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increased up to threefold compared to molecular diffusion (Rysgaard et al. 2000). Meiofaunal activity induces considerable microscale oxygen dynamics along the chemoclines of sediments, as documented by online registration with 2D planar optodes (Oguri et al. 2006). Distribution patterns of meiofauna, especially their colonization of deeper, anoxic horizons, have been shown to be highly dependent on the burrow system providing favorable microhabitats (e.g., Thomson and Altenbach 1993). Modern methods imaging the animal-made void system and bioturbative effects include the use of X-rays or fluorescence tracer techniques (Diaz et al. 1994, Powilleit et al. 1994). One (cost-intensive) method of analyzing the compositions of sediment cores and visualizing their biogenic tubes and burrows is computer-assisted tomography (Rosenberg et al. 2007). An indirect and elegant in situ method of demonstrating mixing processes due to animal activity on-line is the recording of oxygen changes by (expensive) optical sensors (Wenzhöfer and Glud 2004).

2.1.3.3 Water Content and Water Saturation The water content (mass of water in relation to the wet mass of a sample) is linked to grain size and permeability. Fine-grained sediments saturated with water have higher water contents than coarse sands. Mud cores often contain >50 weight % of water, while medium sand will only hold about 25%. Water content is considered by Flemming and Delafontaine (2000) to be a universal master variable that is relevant to any other sediment parameter (attention: inaccuracies may arise from the incorrect use of “content” and “concentration;” content denotes the mass per unit mass, while concentration is the mass per unit volume!). Water saturation and water flow play a dominant role in structuring meiofaunal settlement. If the water content fluctuates the pore water is replaced and the meiofauna are supplied with oxygen and nutrients, while in the deeper, permanently water-saturated layers the pore water flow is reduced. In tidal shores, the occurrence of meiofauna can become restricted because of insufficient water content. Moreover, because of their reduced capillary forces water-unsaturated surface layers cause steep gradients of many abiotic factors, such as temperature and salinity (see Sect. 2.1.4), often with negative impacts on the meiobenthos. Particularly in eulittoral shores at ebb tide, the degree of moisture or the desiccation stress often correlates with the distribution of meiobenthos. Lack of water in the surface horizons can force meiofauna into deeper horizons. Many eulittoral meiofauna species adapt to the regular tidal alterations of water content and concomitant salinity fluctuations with preference reactions and migrations (Fig. 2.4; see Sect. 7.3, 7.4). McLachlan and Turner (1994), based on Delamare-Deboutteville (1960) and Salvat (1964), suggested a generalized stratification pattern of (South African) beaches and their meiofauna in relation to desiccation and water saturation (Fig. 2.5).

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dry sand swash zone

moist sand water-saturated

infiltration

low oxygen

brackish and fresh groundwater

Fig. 2.5 Stratification of a beach profile related to water content. (Compiled from various authors)

(a) An upper “dry sand stratum” is characterized by low water saturation and high fluctuations in temperature and salinity. Here, the prevalence of semi-terrestrial, specialized oligochaetes, mites and nematodes is contrasted with the scarcity of harpacticoids and turbellarians. (b) A partly underlying “moist sand stratum” (“zone of retention” in Salvat 1964) has an alternating water supply with fluctuations in temperature and salinity that decrease in the deeper strata. Due to the perpetually well-oxygenated conditions in this zone, meiofaunal abundance and diversity, particularly those of harpacticoids, increases. (c) In the “water table stratum” around the ground water layer, the sand is always water-saturated. In more sheltered beaches, restricted oxygen content and often brackish salinities lead to a reduced meiofaunal diversity and abundance. (d) The “low oxygen stratum,” where oxygen deficiency can extend down to a considerable depth, develops in beaches with a high content of organic matter; this zone can harbor meiofauna adapted to temporary oxygen depletion (see Sect. 8.4). Variations in this four-strata pattern primarily depend on the beach slope and result in different patterns of wave energy, particle size and nutrient supply: reflective, dissipative and intermediate beaches (Fig. 2.6). The tidal rhythm, local geography, high temperatures and different amounts of organic content will modify the above gradients. In flat-profiled and sheltered “dissipative” shores with medium-to-fine sand, the zonation is less developed.


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sand particle size physical gradient flow, moisture chemical gradients O2 , Eh relative importance of waves

relative importance of tides

reflective

intermediate

dissipative

drying

rentention

resurgence saturated

RPD

reduced

Fig. 2.6 Different beach types and their factor patterns. (After McLachlan and Turner 1994)

Conversely, in the exposed shore conditions of an “erosive” shore, the coarsegrained high-energy beaches have a “reflective” profile. Here, the waves prevent the occurrence of a low-oxygen stratum in the swash zone (“zone of resurgence,” Salvat 1964). This zone is characterized by intensive infiltration and circulation of interstitial water, and by a specialized interstitial fauna of reduced diversity and abundance. This physically controlled assemblage contrasts with the rich, often biologically controlled meiofauna of dissipative shores (Menn 2002b; see Sect. 9.4). Usually, moderately well-sorted medium sands provide the habitat with the most diverse meiofauna. In coarser sand, the species richness can be relatively high but population density may be low. Muddy sediments are more chemically controlled and often characterized by rich populations of a limited number of species restricted to the surface layer. In sublittoral sediments rich in organic matter, meiofaunal communities may be structured by the lack of pore water-flow and the resulting poor oxygen supply. In general, the correlation between hydrodynamic patterns, sediment structure and meiofaunal distribution is strong enough, particularly in littoral areas, to dominate all other factors. It often relates directly to the abundance and diversity of meiofauna, particularly nematodes (Vanreusel 1991, Menn 2002b, Gheskiere 2005). More detailed reading: Hylleberg and Henriksen (1980); Yingst and Rhoads (1980); Gray (1981); Buchanan (1984); Aller (1988); Giere et al. (1988a); Kristensen (1988); Watling (1988); McCall and Tevesz (1982); Hall (1994); McLachlan and Turner (1994); Snelgrove and Butman (1994); Graf and Rosenberg (1997); Widdows et al. (2000); Pearson (2001); Cadée (2001); Murray et al. (2002); Reise (2002); Bale and Kenny (2005); Meysman et al. (2006a).

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Box 2.2 The Sediment–Water Regime: Exposure, Permeability, Water Circulation, Bioturbation The exposure of a habitat, which depends on the impacts of waves and currents, determines agitation, erosion, suspension, sorting of the sediment and flow of interstitial water. The degree of exposure, a complex parameter, is difficult to assess and is often only estimated. The erosion and permeability of the sediment are influenced by the hydrodynamic system, the sizes and shapes of the particles, and their material (quartz or biogenic calcium carbonate). The presence of organic matrices (biofilms, fecal pellets) is also important. The sediment represents a huge filter system of the water flow that provides the benthos with particulate organic matter from the water column and with dissolved nutrients. If saturated, the water content, determined by the capillary (adhesive) forces between the particles, is high in silt and mud (>50%) and low in sand (about 25%). In tidal shores, meiobenthic living conditions are influenced by pore water exchange. The sediment as a habitat is further complicated by biotic factors like bioturbation. This burrowing activity of animals massively reworks and irrigates the sediment and enhances pore water flow and primary production. Compounds bound to the sediment can become dissolved, resulting in eutrophicating or polluting effects. Secretions and tubes compact the bottom. A complex web of particle mixing, in- and outflows, biosuspension and biocompaction links the sediment and water column. Various stratification patterns have been suggested for tidal shores. Based mainly on the beach slope, wave energy and tidal regime, dissipative accreting shores can be distinguished from reflective erosive beaches by grain size, water content, nutrients and oxygen supply. As meiofauna avoid strongly agitated sands, intermediate or dissipative beaches will be populated by more diverse and richer meiofauna.

2.1.4

Physicochemical Characteristics

2.1.4.1 Temperature Meiofauna are present in polar ice and tropical coral reefs, in the constantly cold deepsea and in the supralittoral fringe with frequent temperature fluctuations. Nevertheless, extremes of temperature can have a structuring impact on meiofauna, particularly in exposed tidal shores with their steep vertical thermal gradients. However, in sublittoral bottoms the influence of temperature on meiofaunal distribution is normally negligible. The steepness of the temperature gradient is strongly related to permeability (see Sect. 2.1.3). In water-saturated boreal mud flats of low permeability, surface and deeper layers can diverge widely in temperature, particularly at ebb tide. While summer temperatures can rise to >40 °C at the surface, those in the


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a

b Fig. 2.7a–b A typical temperature distribution in a boreal beach. a Summer aspect. b Winter aspect. (After Jansson 1966a)

depths are only 10–15 °C because of a strong vertical dampening. In wintertime, even under thick ice cover, the frozen ground at the surface does not extend beyond the uppermost 5 cm (Fig. 2.7). This dampening effect with depth, which is particularly evident when calculating monthly ranges (Table 2.3), is important for the existence of meiofauna in climatically harsh biotopes where sensitive species often perform vertical migrations if other conditions like oxygen supply are favorable. On the other hand, many meiofaunal animals are highly resistant to frost, either by supercooling or protective dehydration. In Lake Taimyr (Siberia) nematodes and oligochaetes have been reported to regularly survive for months frozen in ice at temperatures of −10 °C or less (Timm 1996). The Alaskan ice worm, a black enchytraeid oligochaete, lives permanently in crevices of ice at temperatures of below 0 °C (Goodman and Parrish 1971). The (terrestrial) Antarctic nematode

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Table 2.3 Monthly temperature ranges in 1964 at various sediment depths in a Scandinavian beach (Jansson 1967) Depth March April May July October Air −9.0 19.9 19.7 18.8 14.5 Surface −13.0 34.2 38.4 33.5 24.1 2 cm −8.7 26.0 33.0 24.0 12.8 10 cm −4.1 9.8 11.2 9.9 4.2 25 cm −1.0 2.8 3.4 – – 70 cm −0.5 0.8 0.5 0.6 1.0 Note: Values represent the differences between the lowest and highest temperatures (minus signs indicate when the sum of the minimum and maximum temperatures had negative values)

Panagrolaimus davidi survives temperatures as low as -80˚C and freezing down to >80 % of its water bodies (Smith et al. 2008). Polar sea ice is a permanent habitat for a rich, specialized “sympagic” meiofauna of ecological importance (Gradinger 1999a, Gradinger et al. 2005, see Sect. 8.1.1). Temperature can be conveniently and routinely measured with a variety of pointed semiconductor probes connected to electronic (field) instruments. Since only the narrow surface of the thin metal probe is temperature-sensitive, in situ measuring is possible even at a considerable penetration depth without much compaction or displacement of the sediment.

2.1.4.2 Salinity As with temperature, meiofaunal organisms exist under all salinity regimes from freshwater to brine seep areas, from brackish shores to deep-sea bottoms. Because many species are able to adapt to a wide range of salinities, there is often even a diverse meiofauna in those critical brackish water zones where Remane (1934) described a minimum number of species, mainly for macrofauna. Yet, depending much on the frequence of variations, salinity gradients can strongly determine occurrence and species composition of meiofauna (Ingole et al. 1998; Richmond et al. 2007). Habitat-adapted ranges of salinity tolerance or preference have been experimentally found in various meiofaunal species (Giere and Pfannkuche 1978; Ingole 1994; Moens and Vincx 2000b); the physiological capacity for salinity regulation was elegantly recorded for some littoral nematodes by Forster (1998) using an optical method based on the interference pattern of body fluids. Today the international salinity unit is PSU (Practical Salinity Units) which corresponds to ‰ S. In African volcanic lakes high conductivity (often together with extremes of pH, see below) not only structures the occurrence of different meiobenthic assemblages, it locally excludes the existence of meiofauna (Tudorancea and Taylor 2002). In tidal shores, the steep vertical and horizontal salinity gradients strongly depend, as with temperature, on the water permeability of the sediment. In muds with their water-saturated fine sediments and much reduced vertical water exchange capacity, the surface salinity at ebb tide can rise up to hypersaline conditions due to evaporation.


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After heavy rainfalls it can suddenly drop to almost zero. The effects of these fluctuations are greatest in the uppermost centimeter. At a depth of 2–5 cm, the fluctuations in salinity (as well as temperature) are much dampened and often remain amazingly constant. This offers mobile meiofauna a favorable refuge zone, while a drastic decline in meiofaunal abundance after flooding rains or tropical monsoonal rains has been reported for the surface layers (Alongi 1990b). At the highwater line of a North Sea mud flat, salinities of up to 40‰ PSU have been measured on a warm summer day, while immediately below at 5 cm depth, 30‰ PSU was not exceeded. At depths approaching the ground water level, the salinity often drops to brackish water conditions (about 20%). In contrast, on coarser, well-drained sandy beaches with a high permeability, precipitation can affect salinity to a depth of 30 cm (Reid 1932–33), creating adversely lowered salinity conditions for meiofauna, even in the depths. Consequently, in sandy beaches the drainage system is complicated by the effects of both precipitation and ground water currents. Even in fully marine shores without any direct freshwater influx at the surface, groundwater is often markedly reduced in salinity depending on the local geological, climatic and geographical conditions. In sublittoral bottoms, the salinity fluctuates less and is usually identical to that of the overlying water, and so it is hardly a limiting factor for meiobenthic populations. Only beneath brine seeps (Gulf of Mexico) and in brine basins (Mediterranean Sea) are meiofauna exposed to adversely high (>150 PSU) salinities. In the high shore, salinity gradients are difficult to record in detail because the amount of water available is often restricted. Two methods, microtitration and electrical conductivity measurements, are often used. Pointed conductivity electrodes measure the electric current between two platinum rings, which is modulated by the conductivity of the pore water. After calibration, this measurement is used to indicate the salinity of the water. In sediment with little moisture, conductivity measurements may be problematic. Here, the salinity of sediment water can be determined refractometrically. Special salinity refractometers are provided with a scale that is converted and calibrated for direct readings of salinity from only one drop of water extracted from the sediment. The precision of these instruments (±1 ‰ S) is usually sufficient for ecological studies of meiobenthos. As with all methods of salinity measurement, in brackish water the precisions of both the conductive and the refractometer methods suffer because the altered ion composition will cause deviations from the constant relationship that classically defines salinity measurements in pure ocean water.

2.1.4.3 Acidity/Alkalinity (pH Value) Water acidity, recorded in pH-units, used to play only a minor role for meiobenthos in the marine biome. The slight alkalinity of seawater (pH 7.5–8.5) makes it well buffered against pH fluctuations. Only in anoxic, hydrogen sulfide-containing sediments does the pH drop below 7, and rarely below 6. Hence, pH recordings are essential when sulfide concentrations are calculated (see below). On the other hand, in the surface layers of tidal flats, intensive assimilation of the abundant microalgae can increase the pore water pH to >9. In tropical tidal flats pH values of up to 10

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have been measured. Here, high pH in combination with other stress factors such as extreme temperatures and salinity can be detrimental. However, in the future there is a global risk that the dramatic rise in CO2 will increase the acidity of seawater, with negative effects on the benthos. pH and pCO2 are master variables in the formation of carbonate species (Cai and Reimers 1993), the relevance of which has been underlined by Green et al. (1998) based on manipulating the saturation state of carbonate. Hence, particularly calcareous shells and calcifying processes will be impaired by elevated acidity, as has been shown for macrobenthos. In spite of the high resilience of the sedimentary system, undersaturation of calcite (which is typical of many littoral sediments) massively increases mortality and causes shell dissolution in Foraminifera. The authors conclude that dissolution by undersaturation of calcite “likely represents an unrecognized source of mortality for carbonate-bearing meiofaunal-sized organisms.” Under stable deep-sea conditions, experimental CO2 deposition caused a decline in sediment pH of up to 0.75 units and significant defaunation among meiofaunal nematodes and protozoans (Thistle et al. 2005, 2006, 2007a). Even mild acidosis with a decrease in pH of only 0.1–0.2 caused mortality among meiobenthos of up to 30% in the affected area (Barry et al. 2005; see Sect. 8.3). In natural freshwater biotopes, extremes of pH can occur in mires and limestone waters, but also in spring lakes of volcanic origin. Many freshwater bodies are, of course, exposed to anthropogenic pollution, which often causes drastic fluctuations in the pH level. However, the buffering capacity of the sediments dampens the fluctuations in the pore water compared with the overlying water. Subterranean fauna is well adapted to the slightly acidic conditions in continental groundwater aquifers. Thus, a negative impact of acidity or alkalinity on freshwater meiofauna has rarely been demonstrated (Pennak 1988). A reduction in diversity and abundance does however occur in volcanic lakes, where extremely ionic conditions, e.g., alkaline and saline conditions (“soda lakes”), have been found to reduce the diversity or even to limit the occurrence of (nematode) meiofauna (Tudorancea and Zullini 1989; Muschiol and Traunspurger 2008). pH also has a major influence on the balance of many physiological reactions that are not related to calcification, e.g., respiratory processes. Since the effects of pH changes are often confounded by concomitant parameters (e.g., metabolic processes, oxygen binding) in the field, the specific impact of acidosis or elevated pH should be studied experimentally, separate from other factors. The measurement of pH in situ is not problematic when glass insertion electrodes with the reference electrode combined in the same shaft are used. Usually, the recording is done in parallel with redox potential measurements performed with a mV-meter calibrated for pH. Modern electrode design even prevents clogging of the diaphragm. Correct readings require that the temperature of the electrode’s internal filling equals that of the ambient water or sediment to be measured. Internal and external air pressures must also be equalized. A special pH electrode with a recorder integrated into its shaft has been developed to allow for measurements in a drop of pore water filling a small hollow. This even enables correct measurements of pH to be obtained in water-unsaturated shore sediments. pH electrodes in combination with pCO2 microelectrodes have been designed for combined recordings (Green et al. 1998).


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Box 2.3 Temperature, Salinity, Acidity In their normal ranges, temperature, salinity and acidity are not limiting to meiofauna. However, in polar or tropical shores, tidal flats or sea ice, and in volcanic waters, extreme values can become limiting for meiofauna and favor resilient communities of relatively low diversity. A global increase in CO2 will result in the lowering of seawater and sediment pH values and will influence the physiological pH balance and the formation of calcareous structures in sealife. The consequences for shallow-water meiofauna remain to be assessed. Dumping CO2 into the deep sea as a way of solving the CO2 problem seems an inappropriate and risky approach for benthic life.

2.1.4.4

An Interacting Complex: Redox Potential, Oxygen, and Hydrogen Sulfide

Increasing temperatures and eutrophication cause a reduced oxygen supply, mostly associated with increases in hydrogen sulfide and ammonia in many areas. This is a particular problem for benthic biotopes, with their rich content of degradable, oxygen-consuming matter (see reviews by Diaz and Rosenberg 1995, Wu 2002). Redox potential. Before the development of suitable oxygen and sulfide electrodes, platinum electrodes were used to measure the overall reducing or oxidizing capacity of a sediment, the redox potential. The resulting values were simple to record but difficult to interpret. Nevertheless, redox values have become one of the most frequently provided environmental parameters in meiobenthic studies and are sometimes still used. However, redox potential recordings only vaguely reflect the supply of oxygen in the pore water, and the measurement of redox potentials can easily be deceptive: all of the controlling redox couples that occur in the sediment, in addition to those induced by free oxygen, are integrated in a redox potential reading and will influence the measurement. Moreover, a basic understanding of electrometry and some information about inherent flaws and errors is needed to avoid bias and misinterpretation. The electrical potential between an outer platinum electrode and an internal reference electrode is recorded with a mV-meter, which must be corrected to yield the “Eh value.” The response of the electrode depends to a high degree on the properties of the platinum surface. Eh measurements and their interpretation become even more of a problem because of the low reproducibility of replicate recordings from directly adjacent spots. This problem is largely caused by microchambers of decaying organic matter, entrapped air bubbles or animal tubes encountered by the pin-pointed electrode. In the field one can encounter values between +550 and –300 mV. In exposed sandy bottoms that are typically yellowish in color, positive values are obtained throughout, while in soft muds with rich organic content, the gray-to-black layers underneath a thin brighter surface layer will yield clearly negative redox values. The transition zone between positive and negative redox values is termed the

28


“redox potential discontinuity layer” (RPD layer). The RPD layer can periodically move up or down with an increase in the assimilation activity of surficial diatoms or with the incoming tide. Relation of redox values to sediment color. It is relevant to note (but is often disregarded, even in recent meiofaunal studies) that, for chemical reasons, the RPD threshold does not eo ipso parallel the shift from bright sediment layers to dark ones. Detailed Eh measurements have shown that the change from light (yellowish) to dark instead indicates the transformation of ferric iron to ferrous iron rather than the RPD (the redox potential can still be +125 mV, see Fig. 2.8a, and data in Sikora and Sikora 1982; Jørgensen 1982). Only in those cases where the transition layer is narrow and the change from bright to deeply black is abrupt (in muds) can the color change coincide with the RPD. In other words, a wide and diffuse transition from bright over gray to black just indicates the gradual disappearance of free oxygen to a layer with oxidized compounds, albeit without free oxygen. This is then followed by the fully reduced layers without any traces of free or bound oxygen. The value of an optical sediment indicator for the presence of oxygen is further limited in many calcareous sediments, where the iron-based change of the sediment color (brownish = ferric iron, grayish = iron sulfides) may be absent because of the low iron content in the sediment. For a long time it was considered a general and practical rule for interpreting Eh values that values of > +100 mV would indicate the presence of oxic pore water in the sediment, and < −100 mV its absence. Today, oxygen microelectrodes have shown that free oxygen can be absent in sediments with redox potentials as high as +300 mV. Differentiating between oxic (i.e., with free dissolved oxygen available to animals) and oxidized sediments (with compounds in an oxidized chemical state) is of prime importance for correct ecological interpretations (Sikora and Sikora 1982; Jørgensen 1988). In a coastal sandy sediment, Revsbech and Jørgensen (1986) demonstrated that the oxic zone was only 2 mm thick, while an oxidized sediment layer with a positive redox potential extended down to 3.5 cm. Microelectrode measurements have shown that the oxygen content of the pore water can be “zero” in sediment layers that are still brownish to yellowish, i.e., oxidized (Fig. 2.8a). Likewise, the presence of toxic hydrogen sulfide is not automatically indicated by grayish to dark sediments (see below). Only when oxygen or sulfide ions occur in excess and are not chemically bound will the pore water become oxic or sulfidic, respectively. Today it is preferable in meiobenthic studies to measure the oxygen concentration directly with small oxygen electrodes (see below) rather than using the redox potential as a difficult substitute that cannot demonstrate the microdistribution of oxic/anoxic niches. Oxygen. Oxygen is the predominant factor among the abiotic parameters determining the habitat conditions and the presence of meiofauna. Meiobenthic organisms have relatively large surface areas and mostly high oxygen demands; only a few specialized forms will prefer hypoxic conditions (see Sect. 8.4). Thus, the distribution of most meiofaunal communities can be correlated to the oxygen supply of the pore water. Technical progress has largely changed our conception of oxygen supply to the benthos. The classic picture of a vertical oxygen stratification must be abandoned.

2.1 Abiotic Factors (Sediment Physiography) 0 depth 0 [cm]

29

0.1

0.2

O2[mM]

O2

1 Eh

2 3 4 5 6

H2 S

7 −100 0

a

0

+100 +200 +300 Eh[mv]

0.2

0.4

H2S[mM]

Oxygen and Sulphide (µmol l−1) 0

200

400 0

Oxygen

1000

2000

Oxygen

Depth (mm)

0

Sulphide

1

pH

Sulphide

2

DARK b

7

LIGHT 8

7

8

9

Fig. 2.8a–b Oxygen and hydrogen sulfide gradients in two sediment profiles from tidal flats. a Showing relationship with the redox potential (Eh). b Showing relationship with the acidity (pH) and assimilation-induced changes. (a is after Revsbech and Jørgensen 1986; b is own recordings)

30


New microelectrometric techniques have revealed a much-differentiated pattern of oxic conditions in the sediment. Numerous micro-oxic niches occur within anoxic sediments, creating temporary microenvironments with a potential distributional effect for meiofauna (Forster et al. 1996) in the same vertical layer. Numerous geochemical cycles and microbial processes together with the bioturbative impact of sediment fauna and tidal fluctuations create a complicated three-dimensional net of oxic/anoxic microniches. Many sands and muds are only oxygenated in the uppermost millimeter-thin layer (Revsbech and Jørgensen 1986; Visscher et al. 1991). In intertidal flats densely populated by meiobenthos, recordings of oxygen and hydrogen sulfide taken with a set of microelectrodes (see below) showed a very strong periodicity in the fluctuations in oxygen and sulfide concentrations (De Beer et al. 2005a; Weber et al. 2007): At ebb tide, the oxygen content declined rapidly and anoxia (plus hydrogen sulfide) often even reached the surface layer. When bioturbation/irrigational fluxes are interrupted, rapid oxygen depletion through bacterial consumption will soon create hypoxic and anoxic conditions in previously oxic burrow walls, the preferred habitat of meiofauna (Wetzel et al. 1995, Fenchel 1996). The incoming tide reoxidizes the interstitial sediment water, even before the flats become inundated again. Even with tidal regularity, these intermittent fluctuations of oxygen and sulfide exert considerable ecological stress on meiofauna that was not realized before. Aside from the tidal fluctuations, the diurnal fluctuations of light exposure cause changing micro-oxic stratifications via the assimilation activity of the phytobenthos (Fig. 2.8b). Similarly variable oxygen conditions have also been reported for other biotopes (e.g., Archer and Devol 1992; Förster and Graf 1992). In seagrass beds, anoxic periods can be particularly destructive and long-lasting (Guerrini et al. 1998). Buried seagrass and algal remains caused black patches on tidal flats devoid of fauna (Neira and Rackemann 1996) and with a delayed recolonization by meiofauna (De Troch et al. 2005). Other microscale oxygen recordings have revealed that biogenic microtopographic surface structures such as small mounds modify the hydrodynamic and oxidative micropatterns (Ziebis et al. 1996). In a North Sea tidal flat, diffusion of oxygen from Arenicola burrows extended only about 1 mm into the surrounding fine sand (Wetzel et al. 1995), results which were also confirmed by Fenchel (1996) for burrows in the mm range (Fig. 2.9). Many microgradients of oxygen available to meiobenthic animals are, in fact, so steep that changes from fully oxic to anoxic conditions can occur within the µm range of microbial mats. The narrow transition zones from oxidized to anoxic layers can imply that aerobic and anaerobic microbial processes can take place at same depths, and that micro-oxic conditions can temporarily persist beside sulfidic ones (Fenchel 1996; Meyers et al. 1988). The view that the micro- and meiobenthos beneath the upper few millimeters live a largely anaerobic life (Revsbech et al. 1980a,b) has to be refined. In fact, these organisms seem to continuously oscillate between (micro)oxic islets, they tolerate short anoxic events which can momentarily cease, and their habitat changes temporarily under the influence of assimilation and tidal influx. Probably, many meiofauna are forced to intermittently gain energy by rapidly switching from aerobic metabolism


31

250

O2 (µM)

200

150 100

50 0 0

1

2

3

Distance from center of burrow (mm)

Fig. 2.9 Decrease in oxygen concentration around a thin worm burrow in a muddy bottom. (After Fenchel 1996a)

to phases of passive outlasting or anaerobic metabolism. The oxygen flux is also very limited in deeper shelf and slope sediments. (On the other hand, the deep-sea ooze, with its low content of organic particles, can stay oxidized all the way down to several centimeters in depth.) The fine-scale assessment of oxygen stratification directly in the pore water system became possible within the last few decades through the use of thin oxygen microelectrodes, which were introduced into experimental ecology mainly by Revsbech and his group (see Revsbech and Ward 1983; Revsbech and Jørgensen 1986). Protected from abrasion by a layer of semipermeable silicon rubber, and provided with a sturdy glass shaft, field versions have been designed (Fig. 2.10; Revsbech and Ward 1983). By ensheathing the electrode in a thin stainless steel shaft (Helder and Bakker 1985; Visscher et al. 1991), the risk of breaking this device during field use is further reduced. In contrast to polarographic oxygen electrodes, microelectrodes do not require any water flow and, if gold-coated, the presence of dissolved sulfide does not tarnish the minute measuring surface. However, these microelectrodes, with their critical limits of detection (5–10 mmol oxygen), hardly allow for discrimination between truly anoxic and hypoxic conditions—a problem of particular relevance in respiration experiments. Oxygen concentrations in this low range might be still relevant for adapted micro- and meiobenthos with high oxygen affinity (Watling 1991). The measuring threshold in oxygen recordings was minimized upon the development of novel optical oxygen electrodes (“optodes,” Klimant et al. 1995). These fiber-optic microsensors measure the extremely sensitive luminescence quenching of certain chemical dyes that emit light when oxidized. Their highest sensitivity occurs at an ecologically important low oxygen concentration, and their detection

32


guard silver cathode

epoxy

platinum wire

silver wire cathode

Ag /AgCl anode

sensing gold cathode

electrolyte

electrolyte silicone rubber membrane

10 mm

10 µm

Fig. 2.10 Oxygen microelectrode with a sturdy glass shaft. (After Revsbech and Ward 1983)

limit can be 0.1 µM (or 0.5 ppb). The most advanced recording method visualizing oxidative processes online and in situ is the development of 2-D planar opt(r)odes (Glud et al. 1996, 2001; Wenzhöfer and Glud 2004), by which the small-scale dynamics of oxygen distribution, caused by changes in water flow, assimilation or bioturbation, can be continuously and precisely registered on-line (Oguri et al. 2006). The inserted tiny oxygen-quenchable fluorophore creates an on-line, precise and highly stable “oxygen picture” over time. If constructed for field use, these optical sensors can bridge the gap between punctuated microelectrode measurements and the continuous, integrative recordings of chamber incubations. The minimal dimensions and the precision of these microelectrodes allow for the construction of novel microchambers and non-invasive, exact measurements of meiofaunal respiration to be obtained (Moodley et al. 2008; see Sect. 9.3.2). The major disadvantage of this instrumentation is its cost. In recent years microelectrodes and optodes have been adopted and modified by various working groups (Weber et al. 2007), but there is still a need to construct sturdier versions that are suitable for use by nonspecialists in field operations at a reasonable price.


33

WATER benthic microalgae

flow

O2

O2 O2

oxic

O2 O2

O2

O2

O2

O2 O2

anoxic

O2

benthic fauna

O2

O2 O2 O O2 2

O2

O2 O2

O2

SEDIMENT

Fig. 2.11 The microdistribution of oxygen in a shallow flat. (Courtesy Wenzhöfer)

The principally new conception of oxygen conditions in the benthic environment is illustrated in Fig. 2.11. The oxygen distribution is extremely patchy and variable, primarily due to the tidal cycle, bioturbation and organismic activities. The overall volume of oxic microniches grossly exceeds that of the “classical” two-dimensional sediment surface. Considering the complexity and dynamics of the “oxygen realm” and its ecophysiological implications for the small benthos, further microscale investigations, especially those performed under natural field conditions, are needed. It is obvious that oxygen recordings from pore water samples obtained with syringes or by centrifugation (see Sect. 3.3) cannot yield an accurate resolution of the oxygen conditions, whether performed by a micro-Winkler titration (Bryan et al. 1976; Peck and Uglow 1990) or with a polarographic electrode. The fetch area of the pore water is clearly not reproducible. These methods, often still used today, yield a misleading oxygen distribution and should be replaced by direct measurements with microelectrodes. The same holds true for the “oxygen diffusion rate” (ODR, see Jansson 1966a), an historical method that is difficult to interpret and of little relevance today. Hydrogen sulfide. Hydrogen sulfide (H2S) is, oxygen aside, perhaps the most relevant environmental parameter in benthic habitats. Under normal marine pH conditions, hydrogen sulfide is predominantly dissolved as HS− ion. Only in more reducing habitats at slightly acidic pH can the particularly toxic undissociated H2S molecules prevail. Because it (reversibly) blocks the cytochrome C oxidase of the intracellular respiratory chain, hydrogen sulfide is toxic to animals at just nanomolar to micromolar concentrations and profoundly influences the distribution of the benthos. Especially in marine biotopes, H2S can develop in high concentrations

34


through anaerobic microbial reduction of sulfate. Sulfide production can be maintained by sulfate reducers, even under low-oxygen conditions (Jørgensen 1988; Fukui and Takii 1990; Jørgensen and Bak 1991). Plant roots (e.g., Spartina) may enhance sulfide oxidation through both oxygen production and catalytic effects (Lee et al. 1999; Lee 2003). Because of the chemical balance between iron and sulfide ions, in temperate regions a considerable proportion of the generated sulfide will precipitate as iron sulfides, forming a grayish-to-black layer in the depths of the sediment. Particularly in the warm season, the deeper layers of muddy intertidal flats, rich in organic matter, develop high hydrogen sulfide concentrations that sometimes exceed 1 mmol l−1 (author’s unpublished data; Rey et al. 1992). In polluted sediments, dissolved hydrogen sulfide has an indirect but important impact in fixing toxic heavy metals such as cadmium as solid precipitates. In calcareous sediments of warm-water regions, with their low iron contents, this precipitation process is limited. Here, high concentrations of toxic dissolved hydrogen sulfide can develop without any blackening of the sediment (see above). In freshwater biotopes, periods of anoxia rarely give rise to comparably high concentrations of H2S. In this environment, sulfate ions are rare and sulfide is derived mostly from the organically bound protein sulfur. Despite its ecological relevance (see Sect. 8.4), hydrogen sulfide has mostly been ignored in field work and in experiments. In part, this may be due to the widely reported but prejudiced notion that H2S-smelling sediments are azoic. The difficulty involved in measuring this labile substance quantitatively may also have caused it to be neglected. Smell is a good criterion for detecting even low concentrations of hydrogen sulfide, because human olfactory organs sense hydrogen sulfide concentrations as low as 0.1 µm H2S. Today, hydrogen sulfide in sediment pore water is usually measured spectrophotometrically after the addition of methylene blue (Cline 1969; GilboaGarber 1971). There are some modifications of this method that mostly concern the calibration and the range of concentration. Pore water is obtained by suction corers (see Sect. 3.3) and injected right after extraction into the prepared vials filled with alkaline lead acetate, the precipitate is later dissolved in the laboratory. Although somewhat cumbersome, this “pore water method” with subsequent photometrical analysis remains a versatile and frequently used method of measuring hydrogen sulfide. As with oxygen, the stratification pattern of hydrogen sulfide in the sediment column is three-dimensional, extremely complex and characterized by sulfidic microniches directly adjacent to oxic spaces and by steep gradients (see Fig. 2.8b). Microelectrodes have been developed in order to obtain a realistic picture. Several companies offer a silver sulfide electrode combined with a reference system of calomel or Ag/AgJ. The recorded voltage (mV) is directly proportional to the logarithm of the S2− partial pressure. Therefore, it is essential to convert all hydrogen sulfide in its various pH-dependent stages of dissociation to S2− and to calibrate the electrode in relation to the ambient pH. In particular,

2.2 Abiotic Factors Csediment Physiography

35

the micro versions of this electrode, designed originally by Revsbech and Ward (1983), are of interest as insertion electrodes for field use. Early constructions suffered from technical problems (mechanical fragility and abrasion of the silver sulfide coating). Mounting the sulfide microelectrodes in the steel injection needles from medical syringes has made recent versions sturdier and sufficiently protected, even for use in sandy substrates (Van Gemerden et al. 1989). A particularly promising tool for simultaneous recordings of the closely interacting compounds combines an oxygen and a hydrogen sulfide electrode within one thin metal needle (Visscher et al. 1991). The construction of a needle-pointed amperometric sulfide microelectrode combines increased sensitivity with broad applicability (Kühl et al. 1998). Its field use in profiler experiments enabled minute gradients in microprofiles to be recorded. Visman (1996) designed an automatically controlled experimental oxygen/sulfide system with variable pH and temperature conditions that enables complex ecophysiological experiments with sulfide. Although even these new designs do not make measurements of hydrogen sulfide a simple and convenient task, they will hopefully help to ensure that this dominant factor in benthology is no longer neglected in the future. More detailed reading: Giere (1992); Grieshaber et al. (1994); Grieshaber and Völkel (1998); Wetzel et al. (2001).

Box 2.4 An Interwoven Complex: pH, Redox Potential, Oxygen, and Hydrogen Sulfide Oxygen availability and exposure to hydrogen sulfide often set the limits on the distribution of benthic animals. In turn, the development and stratification of these chemofactors depend significantly on biotic processes. The microbiological depletion of oxygen to zero restricts most meiobenthic organisms to the surface layer as a suitable habitat in many sediments. However, the boundary to the anoxic strata, which are often dominated by toxic hydrogen sulfide, changes its position because of tidal fluxes and assimilatory oxygen production. This is the preferred biotope for rich microbiota. Bioturbative processes performed by macro- and meiofauna and microtopographic structures (tubes, mounds) locally alter this vertical stratification, creating a complex threedimensional pattern of oxic and sulfidic microniches. This is often the basis for the notoriously patchy meiofaunal distribution. Measurements with thin microsensors give a more accurate picture of this microscale oxic/sulfidic regime. Their high sensitivity makes it possible to measure even the critical micro-oxic and microsulfidic ranges around the chemocline, which are relevant to many fauna in hypoxic and low-sulfidic sediments. Long-term measurements in benthic chambers have revealed that this micropattern of oxic/sulfidic conditions in the sediment is continuously changing, a scenario that has completely changed the former conception of a two-dimensionally layered system. (continued)

36


Box 2.4 (continued) Because of advances in oxygen microelectrodes and optodes, the use of redox potential as an indicator of oxic/sulfidic conditions is losing importance. Eh measurements in sediments are, at best, inexact and their interpretation is vague. An operational parameter with an integrative character, Eh does not reflect the fine-scaled and dynamic oxic/anoxic/sulfidic system. Commercially available oxygen microsensors remain expensive considering their fragility during field use. Technical attempts to produce robust constructions have been rare.

2.1.4.5 Inorganic Nutrients and Pollutants Nutrient enrichment and contaminants from anthropogenic pollution are factors that today have an important impact on the meiobenthos in many parts of the world (Nixon 1995). Because of physical adsorption and chemical bonds, nutrients and pollutants in the sediment are enriched by several orders of magnitude compared to the overlying water. Absorption of inorganic and organic nutrients, especially in carbonate sediments, is very high (Rasheed et al. 2003a). Once bound in the sediment, these substances are only slowly released into the water column. Retarded microbial decomposition in the oxygen-deficient deeper layers of many bottoms combined with high absorptive forces can cause long-lasting or chronic negative effects on the benthos. Thus, sediments often represent sinks for pollutants. Here, the intensive transport of oxygen in plant roots can have a phytoremediative effect (Lee 2003). Measurement of nitrogen and total phosphorus are summative indicators and are hardly adequate for assessing the situation. One potentially powerful method indicating the extent by which the meiofauna are aggravated by contaminants might be gene or genome analyses of exposed animals (Staton et al. 2001). In any case, eutrophication and pollution have been linked to patchy distribution patterns of meiofauna (Lambshead and Hodda 1994). In many coastal areas, while terrigenous eutrophication may have been abated in recent years, fish and mussel farms in formerly often oligotrophic, barely exposed environments (Norwegian fjords, Mediterranean Sea bights) create an ever-increasing source of nutrient input, which has consequences for meiofauna, especially in sheltered coastal sediments. Another widespread man-induced environmental factor in the meiobenthic habitat is sediment pollution by heavy metals, antifouling compounds (TBT), and pesticides. Because they usually have only a local impact, chemical agents are not considered here as general habitat factors. The reaction of meiofauna to chemical pollution will be detailed in the synecological part of this book (Sect. 8.8). More detailed reading: Kristensen (1988); Watling (1991); Huettel and Gust (1992); Chester (2002).

2.2 Biotic Habitat Factors: A Connected Complex

37

Box 2.5 The Abiotic Environment of the Meiobenthos In the natural environment all of the single factors described in the above section interact with counteracting and synergistic effects. Attractive nutrients are enriched by the highly absorptive bonds at the grain surfaces, as are noxious pollutants. Steep oxic gradients favor microbial life, but anoxia and (often co-occurring) hydrogen sulfide are highly toxic. Erosive water currents act negatively on meiofauna, but they also transport solutes and oxygen into the system. These interactions create a three-dimensional pattern of small-scale favorable microniches or adverse patches that represents the abiotic environment of meiobenthic animals. It is a system governed by currents and sediment composition as key factors, which influence a cascading, multifactorial network to which meiofauna respond in varying patterns and sequences. Experiments have revealed some of these reactions (e.g., to temperature or salinity), but the impacts of more complex factors (nutrients, toxicants) and particularly the role of the elusive chemical complexations are far from understood. In addition, in the field the numerous abiotic factors are constantly interacting with the equally complex system of biotic factors (see the following section).

2.2

Biotic Habitat Factors: A Connected Complex

Studies on the impact of biotic factors on meiobenthic communities have increased since about 1975, while work on abiotic factors dominated studies of the 1960s and early 1970s. Today, it is recognized that biotic factors can have a massive influence on the population structure of meiofauna and the benthic habitat in general (Woodin and Jackson, 1979a,b). The array of biotic factors in sediments extends from dead organic matter (detritus) and biogenic structures to mucus aggregates, sedimenting plankton, bacteria, and, of course, living organisms. Detritus—the remains of plants and animals—is the main component of particulate organic matter, but fecal pellets, mucous agglutinations from exudates and excretions, as well as dissolved organic substances also contribute to this complex. In nature, this organic matter is inseparably connected to bacterial growth, colloids, aggregate and biofilm production and remineralization (Jørgensen et al. 1981; Kepkay 1994; Azam 1998). In a wider sense, the activities of other fauna, such as disturbance, competition and predation, also represent biotic habitat factors for meiofauna (Figs. 15, 16). Community aspects of this subject will be discussed in Chap. 9. Watling (1988, 1991) pointed out that the classical methods of sediment analysis, derived from geology, give a misleading, denatured and biologically rather irrelevant picture of the sedimentary habitat. The world of benthic animals is not characterized by the mineral particles but by the delicate, flocculent organic matter that binds them into a highly adsorptive interwoven fabric. Consideration of the organic material, bacterial colonization, biofilm production, pore-water chemistry and bioirrigation is necessary to achieve a natural conception of the real sediment.

38


Abiotic factors will predominate in extreme biotopes only, such as in the swash zones of exposed beaches (Hockin 1982b). However, even in the wrack zones of tidal flats, trophic or predator–prey relationships are of significant importance (Giere 1973; Reise 1987; Menn 2002b). Living organisms (bacteria, microalgae, other animals) also represent important environmental factors that structure the habitats of meiobenthic animals. Among the biotic factors, probably the least known component with a potential influence on the meiobenthos are the microscopic fungi. Biotic factors interact in complex ways and are difficult to separate and measure. This is probably why they have been investigated far less than abiotic parameters. For better elucidation of this biotic–habitat interaction, the various components are presented separately below. Interpretations of data from such investigations have often been controversial and thus there are few meaningful generalizations. While this has been the case for the better studied macrobenthos (see reviews by Pearson 2001, Wilson 1991), it is even more valid in the case of meiobenthos.

2.2.1

Detritus and Particulate Organic Matter (POM)

Dead organic particles from any trophic level of an ecosystem, as well as organic input from external sources, regardless of its size, are considered to be detritus. Much of the detritus found in sediment samples is derived from dead plankton organisms trapped by the huge filtering systems of shores (Riedl 1971; McLachlan 1989; Berelson et al. 1999; Ólafsson et al. 1999; see Sect. 2.1.3). Decaying phytoplankton blooms can also result in the deposition of a fluffy layer of phytodetritus on the sea floor in coastal, sublittoral and deep-sea areas. These unconsolidated organic deposits, often agglutinated by mucous secretions, enhance the bacterial activity after relatively short time periods (a few days to weeks) and can subsequently cause a significant increase in meiofaunal abundance and diversity (Thiel et al. 1988/89; Fleeger et al. 1989; Lambshead and Gooday 1990; Riemann 1995; Witte et al. 2003; Vanaverbeke et al. 2004). In Kiel Bight (Baltic Sea), the benthic degradation of a phytoplankton bloom was completed after only three weeks (Graf et al. 1982). Especially in surface-feeding meiobenthos, the positive response to these blooms is very direct, while subsurface feeders tend to show a more indirect reaction (onset of reproduction periods, etc.) (Ólafsson and Elmgren 1997). In shallow, well-illuminated bottoms, benthic macroalgae and seagrass meadows also provide an ample source of detritus known to promote abundant meiofaunal populations (Novak 1989; Blanchard 1991; Urban-Malinga et al. 2008). In return, meiofauna have been shown to stimulate the decomposition of plant litter (Findlay and Tenore 1982; Alkemade et al. 1992). Experimental observations indicate that the detritus is not indiscriminately ingested by meiobenthic animals: debris of brown algae is preferred over red algae (Giere 1975; Rieper-Kirchner 1989), while mangrove litter (with its rich tannin content) is less attractive than other plant debris (Alongi 1987b). The differing origins, the multitude of stimulating and inhibiting substances contained in detritus, and the diversity of the degradation processes led Tenore et al. (1982)


39

to concentrate on the “available,” attractive detritus in his ecological studies. The organic remains of decaying macrofauna have been shown to be attractants for saprobiotic meiofauna, especially nematodes (Gerlach 1977; Ólafsson 1992), causing patchy meiofaunal aggregations. As far back as 1942, Mare stated that the amount of particulate organic matter (POM) had a significant influence on the distribution of meiofauna, a fact which has since been confirmed by many authors (Lee 1980a; Tenore and Rice 1980; Tietjen 1980; Warwick 1989). In silty muds, the dry weight of the organic particles can reach 10% of a sample, while for sandy shores this value is often 2 (Huettel et al. 1996), while organic particles accumulate in the troughs and the depressions around tubes (Hogue and Miller 1981; Hicks 1989). To obtain a gross measurement of the total organic matter, the ash-free dry weight of the dried sample is generally the parameter most commonly used. This parameter is the mass loss observed upon the combustion of the dried sample at about 400 °C to constant weight, usually for 2 h (for a comparison of methods and a suggested standard procedure for marine sediments see Beyers et al. 1978). Care must be taken to ensure that the combustion temperature does not exceed 580 °C (400 °C according to other authors) in order to avoid the volatilization of sediment carbonates and thus incorrect results. This “loss on ignition” approach yields inaccurate results for sediments with a high content of clay. A more accurate discrimination between the different components of organic matter (e.g., organic carbon, proteins, lipids, carbohydrates) requires high-temperature oxidation (Bale and Kenny 2005). Another method to determine the organic carbon is to measure the reductive potential of the organic matter by titration. A problem inherent in the assessment of organic content and, consequently, relevant to the analysis of meiofaunal nutrition and distribution is the inclusion of living organisms—microalgae and animals—in the bulk measurement of organic carbon. This is prone to cause a biased conclusion for the microbial and trophic potential of the sediment. Separation of the detritus-linked substances from the live organisms is possible by measuring the ATP content. The procedure for extracting ATP from sediment samples performed by Karl and La Rock (1975) uses the sensitive reaction of the luciferine test for oxidizing substances. However, the ATP contents of organisms vary with their living conditions and ontogenetic events. Consequently, the procedure must be carefully calibrated and the data replicated. The difficulty involved in many of these methods is not so much the technical procedure or the sensitivity of the measurement, but the correct interpretation of the data obtained. For an appropriate conversion of ATP content to weight in (nematode) biomass studies, Goerke and Ernst (1975) report an average ATP concentration of 1.35 mg ATP g−1 wet wt of meiobenthos (nematodes). Unless the oxygen conditions in the sediment are not adversely diminished, it can be generally assumed that an increase in organic matter will enhance meiofaunal abundance but will also change the community composition and the microdistribution (Ólafsson 1992; Creutzberg et al. 1984). Austen and Widdicombe (2006) were able

40


to experimentally show that, at intermediate doses, organic enrichment leads to an increase in the number of meiofauna, confirming that Huston’s general model (Huston 1979) is also valid for meiofauna.

2.2.2

Dissolved Organic Matter (DOM)

Though often disregarded, dissolved organic matter represents a huge reservoir, 20–30 times greater than that of POM. It originates mainly from bacterial excretion and decomposition (Van Oevelen et al. 2006b), but also from the leaching of decaying plant and animal materials or exudation from bacteria and plants. Therefore, DOM in the mud of Spartina salt marshes reaches particularly high concentrations (Gardner and Hanson 1979, see Table 2.4). High DOM values are often due to essential fatty acids derived from plants. Secretion by meiofauna such as nematodes is another source of DOM (Moens et al. 2005). Labile nonhumic substances like sugars (glucose, galactose, sucrose), free amino acids (alanine, glutamic acid, aspartic acid, ß-glutaric acid) and the refractory humic acids are the principal organic molecules which become highly enriched in the pore water; their concentrations in pore water are often one or two orders of magnitude higher than those in the overlying water. In freshwater habitats, where the concentration of DOM is even higher than in marine environments, dissolved organic matter plays substantial roles as both food and a possible source of attractants and releasers of developmental signals (Tranvik and Jørgensen 1995; Thomas 1997). The fluvial input into the oceanic pool is considerable. Neritic coastal zones are richer in DOM than the deeper oceanic sediments (Table 2.4). Dissolved free amino acids (DFAA) are Table 2.4 Dissolved free amino acids (DFAA) and total dissolved organic carbon (DOC)—a comparison of open water and pore water concentrations DFAA (mmol l−1) Seawater Oceanic regions:

Coastal regions: Mud Estuarine regions Spartina salt marsh Fjord, bight Fjord, 40 m depth Freshwater Lewes Brook, UK Lake Balaton, Hungary

In the water column

In pore water

Reference

0.5–1.0

12–50

0.06–6.0

0.5–12.5

Jørgensen (1979); Jørgensen et al. (1980) Thomas (1997)

1.0–3.0 1.8–28.5 8.9 0.5–12.5 1.3–2.6

15–220 16.0–56.0 3.9–28.5 8.7–28.5 0.3–3.8

Stephens et al. (1978) Jørgensen (1979) Gardner and Hanson (1979) Thomas (1997) Jørgensen et al. (1980) Landén and Hall (1998)

0.6–1.3 0.04–0.5

30–60 40–90

Thomas (1997) Thomas (1997)

8.1

Farke and Riemann (1980)

DOC (mg l−1) Coastal regions (silt)

1.7


41

particularly enriched in the upper 0–2 cm and often disappear in sediment strata below 10 cm. Why is the concentration of DOM in the upper sediment layers so high compared to the overlying water despite these releasing processes? The deposition of degradable detritus is higher on the bottom and in the sediment while degradation is generally lower because of the frequent lack of oxygen. Hence, the sediment particles with their relatively large surface areas and considerable adsorptive forces “retain” DOM in the pore water of the sediment. “New” sand grains with sharp edges have been found to adsorb more glucose than older ones with “smoothed” surfaces (MeyerReil et al. 1978). The multitude of substances present in DOM necessitate detailed and complicated chemical analyses (Volk et al. 1997; Burdige 2002). DOM is actively absorbed by either transepidermal uptake or “drinking” (intestinal uptake). Thus, intensive and permanent contact with the pore water system favors the utilization of DOM by bacteria and meiobenthic organisms (see Tranvik and Jørgensen 1995). This explains why sediments with high DOM concentrations are favored by meiobenthos, primarily by the soft-bodied ciliates, turbellarians and annelids with large relative surface areas (Petersen et al. 1988); but significant uptake also occurs in nematodes. An interesting new aspect of DOM uptake is the capacity of some nematodes to utilize acetate, which they can metabolize into polyunsaturated fatty acids, a pathway usually restricted to algae and bacteria. Dissolved organic matter (DOM) is released from the sediment into the water column. The slow process of physical diffusion is accelerated by hydrodynamic forces (storms, currents and waves) and by sediment reworking through meio- and macrobenthic animals. This meiofauna-related increase in solute transport seems to be in the range of 1.5–3-fold (Aller and Aller 1992; Rysgaard et al. 2000). Through the concomitant exchange processes, the activities of benthic animals can enhance the physical diffusion of sediment-bound substances by orders of magnitude, thus counteracting the adsorptive and accumulating sedimentary processes mentioned above (see also Hylleberg and Henriksen 1980; Aller and Yingst 1985; Kristensen et al. 1995). Habitats with high DOM concentrations in the sediment pore water such as flats, deltas and estuaries in the marine realm and eutrophic lakes in freshwater often attract meiobenthos, since DOM is intensively and primarily taken up by bacteria (Moriarty 1980), from which, in turn, the bulk of DOM is recycled (Van Oevelen et al. 2006a). Today, uptake rates of DOM are best indicated by radiotracer methods. Aside from the trophic aspects, the following section will point out that extracellular organic substances have an important structural effect, they cause agglutination of sediment particles, can increase sediment stability, and serve as signal substances that have informative value to aquatic organisms (Thomas 1997; Bale and Kenny 2005).

2.2.3

Mucus, Exopolymers, and Biofilms

In both marine and freshwater systems, exopolymer secretions (EPS) and mucous aggregates are considered key structures for the concentration and exchange of nutrients, for the formation of flocculent matter, often termed “snow,” and for the

42


nutrition and even transport of meiofauna (Yallop et al. 1994; Shanks and Walters 1997; Azam 1998; Wotton 2005). Organic carbon bound in colloids seems to represent a major carbon reservoir in seawater (Farke and Riemann 1980, Kepkay 1994). Microbial activity and coagulation by physical forces transform the colloids into aggregates to which flocculent detrital material adheres, forming nutrient-rich bioreactors. Mucus consists mainly of carbohydrates, especially polysaccharides and glucoproteins; a minor portion consists of loosely bound and labile amino and fatty acids (Meyer-Reil 1994). Passow (2000) regards transparent exopolymer particles as a “distinct group of polysaccharides” formed from dissolved precursor material. They coagulate particularly after phytoplankton blooming periods, but can also be experimentally generated. Condensed as macroaggregates (Logan et al. 1995), they contribute to the “marine snow/lake snow phenomenon” to which bacteria and meiofauna are closely associated (Shanks and Walters 1997; Heissenberger et al. 1996; Simon et al. 2002; Wotton 2005, see Chap. 7). Adhering detritus particles solidify this unconsolidated matrix and accelerate sedimentation. The mucous biofilm that develops on the bottom is excreted mainly by benthic microorganisms, especially bacteria and diatoms (Meyer-Reil 1994; Smith and Underwood 1998), as well as by benthic meio- and macrofauna. Particularly the mucus trails secreted by nematodes, but also those secreted by harpacticoids, enhance bacterial growth (Moens et al. 2005; De Troch et al. 2005). Decho and Lopez (1993) speak of an “exopolymer microenvironment” of bacteria. Its rich nutrient content (especially polysaccharides) and its capacity to affect the flux of dissolved organics favor colonization with rich bacterial stocks. An EPS coating on sediment particles increases their bioavailability for particle-ingesting meiofauna. The specific composition of the biofilm seems of particular relevance to the growth, reproduction and developmental phases of meiofauna (Brown et al. 2003; Dahms et al. 2007). This underlines the considerable trophic importance of exopolymer secretions for the micro- and meiofauna, from allogromid foraminiferans in tidal flats (Bernhard and Bowser 1992) to harpacticoids copepods and nematodes (Koski et al. 2005; Moens and Vincx 1997a; Riemann and Helmke 2002; Wotton 2005), from freshwater ecosystems to the deep sea. Labile components such as free amino acids are even thought to act as sources of information and communication for the microbenthos (Meyer-Reil 1994; Thomas 1997). While this superficial mucous biofilm is relevant nutritionally to meiofauna, it also modifies habitat characteristics, enhancing the cohesiveness and reducing the erodibility of the substratum (Yallop et al. 1994; Miller et al. 1996; Black 1997). Through this biostabilization of sediments, dissolved organics bound in mucus derivates also contribute to the heterogeneous spatial and temporal small-scale occurrence of meiofaunal populations. Decho (1990) contended that extracellular polysaccharides form “an extensive matrix of amorphous organic material which may provide the bulk of carbon sources for many benthic organisms.” In his seminal article, Azam (1998) states that microorganisms do not experience water as their ambient medium in the sediment, but rather a gel-like matrix of suspended polymers and colloids. He speaks of an “organic matter continuum” connecting DOM via colloids, aggregates and particle-embedded “suprapolymers” to POM. The carbohydrates that represent the


43

bulk of colloidal exopolymers can be readily measured (Underwood et al. 1995), but the physical structures of these mucoid and gelatinous substances in the void system, which determines the “world” of meiobenthos, are hard to demonstrate. The development of sophisticated methods (often fluorescence dyes) was required in order to visualize, manipulate and study these delicate mucous aggregates (Heissenberger and Herndl 1994; Heissenberger et al. 1996; Schumann and Rentsch 1998; Mari and Dam 2004; Neu et al. 2002). Today, it is conceivable that the study of mucus secretions and mixed colloidal aggregations and the comprehension of their ecological role will gain importance in future meiobenthological research. It should be promoted more, despite the inherent technical problems (see Murray et al. 2002). Discussing the role of dissolved organics and exopolymers in freshwater, Thomas (1997) stated “The assumption that the energy flow in aquatic ecosystems can be quantified solely by measuring rates of photosynthesis, ingestion of solid food and its digestion by higher organisms, is invalid.” This certainly also holds true for the marine realm (Meyer-Reil 1994).

2.2.4

Bacteria

Bacterial abundance and biomass are several orders of magnitude higher (abundance: 1000×) in the sediment than in the water column. This huge bacterial stock is closely linked to organic debris (detritus) and usually accounts for 4% of the total organic carbon (Jørgensen et al. 1981; Kemp 1990; Schallenberg and Kalff 1993). Experiments have demonstrated that it is the bacterial film, not the detrital substrate, that is preferably utilized by the “detritivorous” meiofauna (Fenchel 1969, 1970; Hargrave 1972; Meyer-Reil and Faubel 1980). Hence, the rich coating of detritus with bacteria may attract high concentrations of meiofauna. As the plant debris ages, the bacterial colonization grows and the protein content increases. This, in turn, makes aged detrital particles more attractive to meiofauna (Warwick 1989). Also, animal remains decomposed by bacterial degradation can attract meiofauna (nematodes) in the sediment so long as oxygen is present (Gerlach 1977a; Ólafsson 1992; Debenham et al. 2004). Other centers of bacterial growth include gradients, especially at the water/ sediment interface and in the sediment at chemical gradients. Many sulfideoxidizing microbes tend to concentrate in the oxic/anoxic interfaces of decomposing detrital particles, where they are exposed to irrigational fluxes and sediment reworking by infauna (Fenchel and Riedl 1970; Fenchel 1996). Here huge populations of “sulfur bacteria” are of considerable importance to meiofauna (Yingst and Rhoads 1980; Jørgensen and Bak 1991). Sulfur bacteria also thrive in fecal pellets produced by meio- and macrobenthos. Meadows and Tait (1985) found that bacterial numbers in fecal pellets in deep-sea sediments were several orders of magnitude higher than those in the surrounding sediments. In the anaerobic depths of nutrient-rich sediments, sulfate reducers and mat-building cyanobacteria develop rich populations (Jørgensen and Bak 1991; Stal 1991, Ramsing et al. 1993).

44


Attracted by nutrient aggregations, bacteria often occur in micropatches. These, in turn, are often the basis for the notorious patchy field distributions of bacterivorous meiofauna, even in seemingly homogeneous sediments (Blackburn and Fenchel 1999). In lentic coastal sediments the rich detritus/bacteria complex especially favors nematodes and other taxa linked to the “detritus/bacteria-based food chain.” In contrast, the more “microalgae-based” harpacticoids are less dependent on these factors (Montagna et al. 1989). A warmer climate or season favors bacterial growth. In temperate regions, peak populations occur in summer. In spring and summer, bacteria develop a characteristic extensive mucus coating and provide a rich mucoid nutritive source for deposit feeders (see below). The capacity of meiofauna to distinguish between various microbes (bacteria, microfungi) and to select certain groups or even strains as food has repeatedly been shown experimentally. This is probably the case for all meiobenthic groups, e.g., ciliates (Fenchel 1969), nematodes (Tietjen and Lee 1977; Tietjen 1980a; Moens et al. 1997, 1999b), harpacticoids (Carman and Thistle 1985), oligochaetes (Chua and Brinkhurst 1973; Dash and Cragg 1972), and polychaetes (Gray 1966a,b, 1971). Montagna (1995) found that meiobenthic rates of feeding on bacteria vary with the developmental stage, in terms of both the amount and the quality of the microbial food. In some cases, the functional correlation between the structures of the mouth parts or buccal armatures and the shapes of the bacteria have been demonstrated in more detail (Wieser 1959, 1960; Jensen 1983, 1987a for nematodes; Marcotte 1984, 1986a; Romeyn and Bouwman 1986 for harpacticoids). Selective bacterivory of meiobenthos is thought to result in a bacterial-induced zonation (mainly nematodes), as demonstrated in laboratory sediment tanks (Boucher and Chamroux 1976), or is a mechanism for microniche segregation (Moens et al. 1999b). Considering the extremely high bacterial productivity (on average 324 mgC m−2 d−1, Kemp, 1990) the bacterial stock does not seem to be limited under natural conditions by meiofaunal grazing (see Sect. 9.3). Quantifying the community structure and the abundance of bacterial microorganisms is a difficult task and not without serious methodological flaws. Bacterial number or biomass is typically underestimated and potentially inaccurate by a factor of two (Kemp 1990). The sonification of homogenized sediment in order to count bacteria is only 65–95% efficient. Direct counting of stained (vital dyes, fluorescent dyes) bacterial cells on the particle surface, although tedious, remains one of the more reliable procedures (DeFlaun and Mayer 1983). Even DAPI staining resulted in a considerable underestimate of the bacterial abundance (70%) and biovolume (60%) (Suzuki et al. 1993). Bacterial volume, a neglected parameter of relevance to metabolic processes, can be calculated more reliably through ultrastructural scanning methods (Kaye 1993). According to a detailed working protocol elaborated by Epstein and his group, the combination of careful sonification with tritiated thymidine or CTC labeling will result in particularly efficient enumeration of about 90–95% of the bacteria present (Epstein 1995; Epstein and Rossel, 1995a,b; Epstein et al. 1997). Moriarty (1980) recommends the determination of muramic acid as a good basis for calculations since this substance is a cell wall component of almost all prokaryotes. Another indirect method used to quantify sediment bacteria is the calculation of their biomass by phospholipid or ATP analysis (Findlay et al. 1989, Köster


45

and Meyer-Reil 2001). Schmidt et al. (1998) showed that scaling bacterial abundance to the fluid volume of pore water within the sediment yields a much greater consistency than traditional relations to dry sediment mass. Molecular screening techniques with general bacteria probes or the incorporation of radiolabeled markers (e.g., tritiated thymidine) are new methods that are increasingly being applied for quantitative recordings (e.g., Ramsing et al. 1993). Homogenization and subsequent Percoll flotation (Sect. 3.2.2) are also valuable improvements. The numbers of sediment bacteria can vary considerably depending on the evaluation method, on the local microtopography and physiography, and on the sediment quality, water content and climate, but are mostly in the range of 108–109 cells per ml sediment. Hence, the figures in Table 2.5 probably cannot be generalized. Only in the past decade have modern methods yielded more reliable quantitative abundance data. Bacterial biomass, biovolume and productivity are more indicative than abundance data of the importance of bacteria as an eminent ecofactor for meiofauna. In many sediments, bacterial biomass and production is equal to or exceeds that of the macrofauna (Kemp 1990; Bergtold and Traunspurger 2005). Usually, the bacterial density in sediments corresponds to the amount of degradable organic matter and is reciprocally related to the degree of exposure and the particle size of the sand fraction (Köster and Meyer-Reil 2001). Muddy bottoms and sea grass beds are microbially richer than sand, just as the wrack zone of a beach is richer than its surf zone or its sublittoral bottom. Moriarty (1980) found five times the amount of bacteria in seagrass beds than in the adjacent open sediment. The dependence of bacterial abundance on granulometry is demonstrated by the vertical profile in the North Atlantic (Vanreusel et al. 1995b) from the shelf to the continental slope (70–1,500 m depth). The sandy slope samples contain several orders of magnitude fewer bacteria than the deeper slope (Table 2.5). A rich supply of detritus and oxygen, for most microbes, makes the surface layers of the bottom more attractive than groundwater layers or the anoxic depths. Light-dependent cyanobacteria aggregate in mostly sandy sediments underneath a thin surficial mucus film (Yallop et al. 1994). On the surfaces of seagrass beds, 18% of all organic substances measured were contributed by live bacteria (Moriarty 1980), a significant nutritive amount, even for larger animals. In a sandy tidal flat, almost all of the carbon input was attributed to microbes (Joergensen and Mueller 1995). Typically, bacterial biomass equals about 4% of the total organic carbon (Kemp 1990). However, the world of meiobenthic animals is determined by a three-dimensional pattern of microniches and particle surfaces. Even at the microscopic scale, sediment particles are colonized by qualitatively and quantitatively different bacteria; this in turn implies differences in the compositions of bacterivorous meiofauna. Colonization of sand grains seems to be proportional to surface area. One mm2 of grain surface may be populated by up to 260 × 103 bacterial cells (Anderson and Meadows 1969)! This enormous number of bacteria is concentrated on only a very small portion of the huge overall surface (between 300 µm diameter) with fairly smooth surfaces are inhabited by bacterial flora that differ quantitatively and qualitatively from those on smaller particles with many crevices and depressions (Marcotte 1986a) and those of the water column. The relatively small surfaces of silt particles 100 × cm−2. Voids of sand, especially exposed sand, seem less densely populated: Helsingør beach (Denmark) yielded several 100 × cm−2; sandy flats of the island of Sylt only about 100–200 interstitial flagellates cm−3 (Hoppenrath 2000), belonging to about 140 taxa; and a beach at Roscoff (France) exhibited up to 2,000 mesopsammal flagellates cm−2 (Dragesco 1965). Sea ice harbors a considerable number and biomass of active flagellates, with a production only somewhat lower than that of diatoms. Freshwater sites also seem to be rich in flagellates, but numbers fluctuate heavily with season: in eutrophic limnic sediments, between 1–16 × 103 cells cm−3 were retrieved (Gasol 1993; Starink et al. 1996, see

52


also Kemp 1990). In oligotrophic lake sediments mean densities of about 80 × 103 flagellates were observed (Bergtold and Traunspurger 2004). As with bacteria, quantitative data may vary by orders of magnitude depending on the extraction methods used. Flotation methods yielded efficiencies of between 73 and 100% (Alongi 1986; Starink et al. 1994). Fixation can cause considerable shrinkage of both diatoms and microflagellates and has to be corrected for in order to avoid inaccurate estimates of biovolume and thus carbon biomass (Menden-Deuer et al. 2001). Closely linked to bacteria, most of the dense populations of flagellates in tidal sediments are heterotrophs grazing intensively on bacteria. However, at least in freshwater, the immense amounts of bacteria produced appear to be only marginally consumed (up to 5%, Kemp 1990; Starink et al. 1996; Hondeveld et al. 1992; Hoppenrath 2000). Using a new fluorescence technique, Starink et al. (1994) calculated that in lake sediments up to 70 bacteria were consumed per protist per hour, while in marine sediments the corresponding consumption was only around five bacterial cells. Microdistribution and abundance patterns also suggest a close trophic correlation between flagellates and ciliates (Santangelo and Lucchesi 1995), a link that had been observed earlier by Fenchel (1969). Kemp (1990) emphasized the preferred occurrence of flagellates in organic-enriched detrital surface layers of the sediment, while ciliates were more linked to the interstices of sand. A differentiating trophic specialization within the microphytobenthos was evident in tidal sand: Epstein et al. (1992) found that ciliates devour 93% of the dinoflagellate production, in contrast with only 6% of the diatom production. Dietrich (1999) contends that in brackish sediments rich in organic matter, about half of the flagellate stock is consumed by meiobenthos. More detailed reading: Round (1971); Patterson et al. (1989).

Box 2.6 Microphytobenthos: The Garden of Meiofauna About 20% of all organic carbon is produced by diatoms and flagellates in the uppermost millimeters of shallow sediments. Some 103 to 104 cells live in each cm3 of sediment. Combined with their high nutritive value, this emphasizes their central role in the world of meiofauna, where they often mediate between bacteria and meiofauna. Through their oxygen production and light-dependent migrations they provide the sediment layers with oxygen. Many meiofaunal groups have specialized on diatoms as a food source and linked their population dynamics to the annual peaks in their production (spring and autumn in temperate regions). Benthic, mostly heterotrophic flagellates are important bacterivores, however, their nutritional role for meiobenthos is not well known. Particularly in the surface layers, where both microphytobenthic groups co-occur, they can regulate the temporal and microdistributional patterns of meiobenthos. Due to their rich mucus secretion, diatoms produce a nutrient film for bacteria and an effective coagulant that protects sediment particles against erosion.


2.2.6

53

Higher Plants

Sessile macroalgae and seagrasses have a physically structuring effect that influences meiofaunal settlement and distribution (Wieser 1959b). The reduction of sediment agitation and the enhancement of particle suspension under a plant canopy favors meiofaunal abundance. Culms, thalli, mangrove pneumatophores, and holdfasts provide numerous niches and protection for small animals. These plant structures expand the available living space for meiobenthos from the sediment into the water column and into the phytal (see Sect. 8.5). Delicately branched algae or the fuzzy culms of seagrasses are more densely inhabited by meiofauna than the smooth thalli of algae or the blades of seagrass. Conversely, minute epigrowth organisms on plants (e.g., mucous tubes) favor meiofaunal colonization (Peachey and Bell 1997; Gwyther and Fairweather 2002). Plant roots and shoots have a similar structural effect in the sediment. Thus, structural complexity is often positively correlated with meiofaunal abundance and diversity (Remane 1933; Hicks 1985; Hall and Bell 1988; Hull 1997). This has also been experimentally tested using artificial substrates of various complexities (Atilla et al. 2005). In addition, there are also chemical and nutritional effects by which plants can influence the habitat conditions of meiofaunal biotopes. Enhanced bacterial growth at the frequently damaged and leaching frond ends of plants indirectly promotes the trophic possibilities for meiobenthos. Live plant roots have been found to metabolically create a favorable micro-oxic gradient system in their surrounding sediments (Teal and Kanwisher 1961; Lee et al. 1999), enhancing the density and heterogeneity of (nematode) meiofauna (Osenga and Coull 1983). Algal cover on soft bottoms was found to favor the development of meiofauna in mesocosm experiments (Ólafsson et al 2005). When decaying, the leaves of seagrasses represent an attractive and important source of valuable detritus (see Sect. 2.2.1). An aggravating impact on the meiobenthos by mechanical disturbances has been shown by Hicks (1989). His field experiments indicated that (artificial) seagrass not only promotes meiofaunal populations, but can also disturb mainly epibenthic meiofauna assemblages, probably through the sweeping action of the blades and alteration of the microtopography (depressions, ripples). Lower numbers of meiofauna on mangrove pneumatophores as compared to mimics may result from the secretion of anti-fouling substances produced by the plants (Gwyther and Fairweather 2005). A discussion of other effects of plants relevant to meiofaunal habitat will be presented in Sect. 8.5, which deals with the phytal.

2.2.7

Animals Structuring the Ecosystem

The effects of macrobenthos on the habitat conditions of meiobenthos are extremely variable, species-dependent and are often not clearly delimited (Ólafsson 2003). They comprise both negative interactions and positive, facilitative effects.

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Among the negative interactions, we can differentiate: (a) mechanical disturbance; (b) reduction by sediment ingestion; and (c) alterations of the chemical milieu. (a) Mechanical disturbances can be produced in areas with water currents by protruding macrofaunal tubes, which, enhance the boundary friction of the sediment and thus can exert an erosive force that negatively affects meiofauna (Eckman 1979; Gamenick and Giere 1994; Widdows et al. 2000; Ólafsson 2003). The spacing, the density and radius of the tubes largely govern whether the network of animal tubes will impair or promote meiofaunal life (see below). Those meiofaunal groups with a more passive, strictly sediment-bound lifestyle (nematodes, annelids) will be less affected, while the more epibenthic and temporarily suspended harpacticoids are more strongly affected (McCall and Fleeger 1995). Mechanical disturbance is caused also by disruption and reworking of the sediment, due to the digging of horse shoe crabs, rays, crabs, molluscs and sea urchins, the pipetting of Tellina (Bivalvia) siphons, and reworking by anthozoans, polychaetes, priapulids, amphipods, echinoids, fish and birds (Creed and Coull 1984; Reise 1987; Warwick et al. 1990 b; Hall et al. 1991; Ólafsson and Moore 1992; Ólafsson and Ndaro 1997; Aarnio et al. 1998). Meiofauna is usually considered relatively insensitive to disturbance and less persistently affected than macrofauna (Alongi 1985; Austen et al. 1989; Hall et al. 1991). Nevertheless, in open tidal flats, lugworm activity (Arenicola) led to a decrease of about 20% in meiofaunal density, as shown by exclusion experiments (Reise 1987, 2002). Physical disturbance (experimental raking) had a clearly negative effect on intertidal meiofauna (Austen and Widdicombe 2006). A study performed by Warwick et al. (1990b) enabled a discrimination of mechanical disturbance that reduced the stability of the sediment from pollution stress. The impact of shore crabs (Carcinus) on nematodes seems to be sediment-related (Schratzberger and Warwick 1999b): disturbance dominated in muddy bottoms, while predation prevailed in sands. Usually, disturbance-induced losses of meiofauna in tidal flats soon recover (see Sect. 9.1 on recolonization; Sherman and Coull 1980; Ólafsson and Moore 1990; Warwick et al. 1990b; Hall et al. 1991). The recovery potential of meiofauna in the deep sea is unknown, but disturbance-induced negative impacts of large epifauna on meiofauna have been documented (Thistle et al. 2008). (b) Sediment ingestion, the second impact type, occurs wherever deposit-feeding macrobenthos prevails: the feeding galleries of Arenicola marina contain lower numbers of nematodes (Jensen 1987a; Reise 1987); a negative impact of intensive digging was also noted for the priapulid Halicryptus (Aarnio et al. 1998). However, the reduction apparently depends on the intensity of the reworking and was not noted for other sediment feeders. The negative effects of disturbance by sediment ingestion can gradually merge into predator–prey relationships, particularly when meiofauna and macrofauna interact (meiofauna vs. burrowing polychaetes, crustaceans or fish, see Sect. 9.4.2). Disturbance (and predation) will mainly affect the meiofauna at the sediment surface and the upper sediment layers (Bell 1980). Some groups may react by performing


55

downward migration, which creates surface layers with reduced meiofaunal abundance. Effects of direct predation on meiofauna by macrofauna will be considered elsewhere (see Sect. 9.4.2). (c) Alterations in the chemical milieu, the third type of impact of macrobenthos on meiobenthos, affect meiofauna in mussel and oyster beds where thick layers of organic debris, fecal pellets and decaying algal mats accumulate. Here, oxygen soon limits the meiofauna in the layers beneath (Dittmann 1987; Dinet et al. 1990; Neira and Rackemann 1996; Reise 2002). Brominated compounds excreted by some echiurids and enteropneusts into their tube-wall linings have been suggested to exert a toxic impact on bacteria and meiobenthos (King 1986; Jensen et al. 1992b). In deep-sea bottoms, mangenese diagenesis may be affected by meiofaunal oxygen consumption (Shirayama and Swinbanks 1986). Among meiobenthic animals, the competition (mostly) caused by identical nutritional resources can structure the ecosystem. Trophic competition can cause spatial niche segregation and can ultimately lead to amensalism or mutual exclusion (e.g., Fenchel 1968a for ciliates; Joint et al. 1982 for nematodes). This exclusion has been documented as a within-group effect among meiobenthic species (nematodes, Ott 1972a; Alongi and Tietjen 1980, Santos et al. 2008a; harpacticoids, Chandler and Fleeger 1987). However, competitive exclusion has even been described between taxonomically distant meiofaunal groups (foraminiferans vs. harpacticoids, Chandler 1989; oligochaetes vs. turbellarians, Dörjes 1968; capitellid polychaetes vs. nematodes, Alongi and Tenore 1985; ciliates vs. nematodes, Bergtold et al. 2005). Competition can also result in a shift in life history characteristics (Heip 1980a, Marcotte 1983). A good example is the mutual exclusion of two species of the ciliate genus Condylostoma, C. arenarium and C. remanei, which have contrasting population dynamics, with maximum numbers occurring in June and November, respectively (Hartwig 1973b). Many negative interactions among certain meiofaunal taxa are difficult to analyze. Is the mutual exclusion of enchytraeid oligochaetes and turbellarians in the upper sandy beach, reported by Dörjes (1968), a result of trophic competition or merely an unknown, animal-mediated factor? Why is there a negative interrelation between the naidid Amphichaeta sannio and the nematode Tobrilus in the freshwater flats of the River Elbe (Schmidt 1989)? What causes the negative correlation between ciliates and freshwater nematodes (Bergtold et al. 2005), or that between the two bacterial symbiotic nematodes Catanema and Astomonema in mangrove muds (Bezerra et al. 2007). These questions remain largely unanswered. The causative factors of the inverse relationship between the harpacticoid Tisbe furcata and nematodes (Warwick 1987) and the contrasting population fluctuations of the gastrotrich Turbanella hyalina and its annelid counterpart Protodrilus symbioticus (Boaden and Erwin 1971) are also unknown. Similarly, the negative interaction between the foraminiferan Ammonia beccari and the harpacticoid Amphiascoides limicola in muds from tidal flats (Chandler 1989) has not been conclusively explained. Of particular relevance and widespread occurrence is the mutual regulation between permanent and temporary meiofauna (Elmgren 1978; Warwick 1989), which is in fact a series of effects ranging from predation to sediment reworking.

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Permanent meiofauna, through their more effective and intensive feeding activities, initially attenuate the population development of newly settled polychaetes, bivalves, and very young amphipods. Subsequently, the growing macrofaunal species, through their intensive sediment reworking and their direct predatory impact, have an aggravated negative influence on permanent meiofauna (Bell and Coull 1980; Watzin 1986). The extent to which large beds of suspension-feeding bivalves reduce suspended meiofaunal populations in tidal flats needs to be experimentally verified. First studies do not suggest a density reduction (Boeckner, Recife: O 10). Examples of positive mutual effects between species arose from experiments by Reise (1983), where the bioturbation of lugworms enhanced solute fluxes and acted positively on the development of bacteria and meiofauna. Facilitative effects among nematode species were also reported by Santos et al. (2008a,b). Other effects are of a more indirect nature, yet their impact on the structure of the habitat, increasing habitat heterogeneity, can be considerable. Levin et al. (1997) considered the rapid subduction of plant material into the sediment by nonselective macrobenthic deposit feeders (some polychaetes or sipunculids) to be a “keystone resource modification” which massively influences the structure of the bottom and the fate of settling organic matter (see also Sect. 2.2.1 and 9.4). This example shows that besides the animals themselves, animal-produced structures can also positively influence meiofauna (Murray et al. 2002; Ólafsson 2003). Tubes and burrows and mounds piled up by benthic animals can have a massive impact on the habitat conditions of meiofauna. Around the tubes of macrobenthic polychaetes, nematode numbers were up to five times higher than in the unstructured controls. The small mounds around the openings created by many crustaceans in soft sediments have been documented to massively influence the hydrodynamics of the water on a microscale and thus to modify the influx of oxic surface water and the drainage of pore water (Hüttel et al. 1996; Ziebis et al. 1996). Nematode numbers were doubled along the tubes of thalassinid decapods in sublittoral Mediterranean sand, and foraminiferans increased as much as a hundredfold in number (Koller et al. 2006). In the deep sea, where animal-created structures tend to persist for long periods, distinct habitat patches of polychaetes fostered the abundance of harpacticoid copepods (Thistle et al. 1993). Intensive promotion of meiobenthos colonization by macrofaunal burrows and tubes was found to be responsible (among other factors) for meiofaunal spatial patchiness. This close interdependence has been simulated by mathematical models that show a good agreement between the model and sample situations (Pfeifer et al. 1996). Such modeling needs to be used more commonly in meiofaunal research. One important stimulus is the enhanced bacterial growth resulting from tube flushing effects, which profoundly influence the porewater circulation and the geochemistry of the bottom (Alkemade et al. 1992; Webster 1992; De Beer et al. 2005a; Weber et al. 2007). Burrows of decapod crustaceans, especially those of thalassinids, can be termed “hot spots” for bacteria and meiofauna (Förster and Graf 1992 in the North Sea; Koller et al. 2006 in the Mediterranean; Dittmann 1996 in Australia). However, meiofaunal populations also more than doubled the transport


57

rates of solutes (Aller and Aller 1992; Rysgaard et al. 2000), an increase that is particularly important for the transport of oxygen in the deeper layers (Zühlke et al. 1998). In freshwaters, the bottom is often densely covered by protruding tubes and mounds of tubificid oligochaetes, which exert a corresponding positive role on the geochemistry at the sediment/water interface. Another stimulus with a positive effect on meiofaunal populations is the secretion of exopolymers and the enrichment with fine organic particles. This will solidify the texture and enhance organic content and bacterial stocks (Eckman et al. 1981, Dobbs and Guckert 1988; Meadows and Tait 1989; Meadows et al. 1990; Decho 1990; Nehring et al. 1990; Jensen 1996). Macrofaunal tubes can also provide protection for meiofauna from predators and thus have a positive effect (Bell and Coen 1982). As a result of biogenic structures in/at the bottom, meiofaunal species richness increased (Ólafsson 2003). A network of more or less permanent tubes can also be produced by some meiofauna, preferably in silty sediments, but also in mucous biofilms (harpacticoids, Chandler and Fleeger 1984; Williams-Howze and Fleeger 1987; nematodes, Cullen 1973; Riemann and Schrage 1978; Platt and Warwick 1980; Nehring et al. 1990; Jensen 1996; Fenchel 1996a; Mathieu et al. 2007). As a result of biogenic structures in/at the bottom meiofaunal species richness increased (Ólafsson 2003). Considering this array of factors that are beneficial to meiofauna, it is understandable that the positive effects of biogenic structures have been suggested to yield 10–50% of the meiofaunal colonization of tidal flats (Fig. 2.14), with even higher figures for harpacticoids and gnathostomulids (Reise 1981a). In exclusion experiments, the presence of lugworms was estimated to promote the abundance of >90% of meiofauna (Reise 1983). In recent years, various large-scale, man-made physical disturbances have affected the biotopes of meiofauna with increasing intensity and frequency, including maintenance dredging and habitat (beach) enhancement. Climatic extremes, intense fishing with bottom trawls and dikes and other constructions along the shores and waterways have escalated erosive forces in the last few years. Maintenance dredging and habitat (beach) enhancement have become regular counteractions by which huge masses of unconsolidated sediment are mechanically distorted. Amazingly, the meiofauna appear to recover much more quickly from these maximal disturbances than macrofauna, as micro/mesocosm experiments and large-scale field surveys have shown (Schratzberger et al. 2006; Bolam et al. 2006). Supported by meticulous statistical analyses, they disclosed that the impact of this mechanical sediment distortion was mitigated by the concomitant intensive transport of meiofauna with slush water and intensive migration activities. The meiofaunal species richness recovered from an initial reduction after relatively short periods (weeks), while density reductions remained for longer periods (>1 year) than in the reference areas. In sandy habitats recovery was quicker than in mud, and nematodes were less affected than harpacticoids. The recolonization processes of meiofauna in the freshly consolidated sediments must be differentiated. They not only follow passive settling, but also depend on the water transport capabilities of the taxa and their reproductive potentials (see Sect. 7.3).

unstr.

head

tail

0

10

Arenicola

cm

20 0 20

Nematoda x cm−3

unstr.

cm

0

5

10 20 0 20

Pygospio

Corophium

Fig. 2.14 Impact of biogenic structures on meiofaunal density. Nematodes around burrows of various tidal flat macrofauna in comparison with unstructured (unstr.) reference sites. (After Reise 1981a)

Box 2.7 Animals as Habitat Factors Direct interactions between meiobenthic animal groups often result in competition, niche partitioning or even mutual exclusion. Structuring effects through food competition are hard to delineate from predator–prey relations, especially when dealing with macrofauna–meiofauna interactions, but have even been documented between unrelated meiofaunal groups. Disturbance (the other animal-mediated structuring source), on the other hand, is due not only to predation but also to bioturbative effects. Mechanical disturbance of meiobenthos is mostly the result of sediment reworking by digging or bulldozing macrofauna, and has mostly adverse effects on meiofauna. However, only extreme and long-lasting disturbing effects tend to degrade the meiofauna for a long time. Short disturbance events are quickly compensated for, making meiobenthos fairly resistant to environmental stress. Burrows of benthos usually have a benign effect on meiobenthic populations; they diversify the habitat structure and ameliorate the mechanical and nutritional properties of the sediment by compaction. This positive structuring is enhanced by the greater influx rates of oxic water and attractive mucus secretions. Beyond that, protruding macrofaunal tubes provide shelter and foster the settling of organic particles, modulating the hydrodynamics at the surface.

2.3 Conclusion: The Microtexture of Natural Sediments

2.3

59

Conclusion: The Microtexture of Natural Sediments

Natural sediments are characterized by a net of intricately interacting abiotic and biotic (biogenic) factors rather than just the grain size, porosity or sorting of the particles. The interactive and multiple nature of numerous determinants in the field, illustrated in Fig. 2.15 and schematically in Fig. 2.16 was nicely demonstrated in a small study performed by Warwick et al. (1986b), who investigated the impact of the macrobenthic, tube-dwelling polychaete Streblosoma on the meiofaunal assemblage. Around the tubes that extend slightly above the surface there is an area with rich meiofauna, probably because of the improved flux conditions caused by the tube and also because of the worm’s mucus secretion and concomitant microbial activities. Slightly further away, in the grazing range of the polychaete, the meiofauna was impoverished through mechanical disturbance and perhaps uptake by Streblosoma. Mainly through the activation of geochemical fluxes and microbial activity, an inhomogeneous small-scale topography is created (Fig. 2.15) which supports the aggregation and a patchy distribution of meiofauna, even in superficially uniform sediments (Sun and Fleeger 1991). The mucus film secreted by bacteria, phytobenthos and many burrowing animals like nematodes and annelids decreases the amount of erosion and meiofaunal suspension from currents. This entire web of biotic ecofactors which influence the occurrence of meiofauna is intricately combined with and influenced by the multitude of abiotic parameters described in Sect. 2.1. Any schematic attempt to illustrate the complexity of the “meiobenthic habitat” (Fig. 2.16) is too static to adequately reflect the dynamic interactions of the components. In addition to the more regular factorial system, depicted in Fig. 2.16, the meiobenthic ecosystem is, of course, subject to stochastic or “accidental” factors, such as local irregular and temporary disturbances (e.g., storms, pollution events) and benefits (e.g., food input through the settling of larval forms or decaying macrofauna). These erratic alterations, even those of a small-scale nature, may influence the system unpredictably. They certainly contribute to the notoriously patchy distribution pattern of meiofauna and support their high diversity, two characteristics of meiobenthic communities that make generalization very difficult. A high diversity is also maintained by the well-developed nutritional selectivity of meiofauna, which seems to exceed that of macrofauna. The resulting differentiated resource partitioning of the available food stock renders biotic (trophic) factors more relevant than physiographic parameters: the occurrence and distribution of meiofauna appear to be controlled by a multifactorial dynamic network in which the biotic factors in particular must be considered. More detailed reading: Round (1971); Coull (1973, 1986), Coull and Bell (1979); Rhoads et al. (1977), Eckmann (1985), Warwick (1989), Decho (1990); Watling (1988, 1991); Reichelt (1991); Krumbein et al. (1995); Meyer-Reil (1994); Snelgrove and Butman (1994); Fenchel (1996a); Reise (2002); Murray et al. (2002); Ólafsson (2003); Meysman et al. (2006a).

animal tubes

faecal pellets

animal burrows

geochemical fluxes

increased stability

oxic

decaying organisms

sulfidic, anoxic

disturbance

mud, silt

Fig. 2.15 An illustration of the biotic factors structuring the occurrence of meiofauna in a tidal flat sediment. (Compiled from Meadows 1986; Anderson and Meadows 1978, and other authors)

sand

sediment water interface

wrack

erosion

60 2 The Biotope: Factors and Study Methods

2.3 Conclusion: The Microtexture of Natural Sediments

61

sublittoral: water currents, wave action

sedimentary complex

physicochemical complex

grain size composition

H 2S

eulittoral: atmospheric exposure of sites, tides

permeability

porosity

O2

water flow

To

pH

S‰

water supply (eulittoral)

H2O content

Meiofauna structure and distribution

dissolved organic matter

biogenic structures biogenic complex

mucus production

biofilms

biotic complex

bacteria

food

bioturbation predation

particulate organic matter, detritus

phytobenthos

disturbance

macro-zoobenthos

Fig. 2.16 A schematic factorial web structuring the habitat of meiobenthos

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Box 2.8 Sediments: The Real Picture The natural sedimentary fabric is an interacting, living system of organic components, mucous excretions, detrital agglutinations and microbial films interwoven with the inorganic particles. Thus, the real habitat of meiobenthos cannot be defined by grain size and sorting or characterized by sieving. Particulate organic matter (POM) and debris represent major components that are inseparably linked to bacterial coatings and biofilms produced by bacteria, diatoms and fauna. When oxygen is present, this organic complex is highly attractive to many meiofauna and is often the basis for their patchy microdistribution. Dissolved organic matter (DOM), which consists mainly of carbohydrates and amino acids and is released by many microorganisms, is mostly bound to colloidal complexes and mucous layers. It represents valuable nutrition for meiofauna. All of these components influence geochemical fluxes, microbial activities, the degree of biological reworking (bioturbation), and fauna-mediated bioirrigation and pelletization (Watling 1988, 1991; Meysman et al. 2006b). The huge surfaces of this nutrient-rich sedimentary web are ideal substrates for rich microbial colonization. Bacterial stocks that are orders of magnitude richer in the sediment than in the open water represent a dominant nutritive source for meiobenthos. The metabolic waste products of the meiofauna, in turn, attract bacteria. The spatially and temporally variable interactions between fauna, plants, bacteria and detritus become further complicated by the release of substances which exert specific stimulatory or inhibitory effects on all components of the system (Tenore and Rice 1980, Meadows 1986). Meiofaunal colonization is further controlled by biogenic microstructures such as animal burrows and tubes, mucus tracks, and fecal pellets. These are not only the nutritional basis for many meiofauna, but also act as mechanically important biostabilizers, reducing erosion. The complexity of this network renders the measurement of single parameters difficult. Recent advances in simulating and measuring have been accomplished using microelectrodes and on-line experiments. These innovative approaches will contribute to understanding the dynamics of the living sediment.

Chapter 3

Sampling and Processing Meiofauna

Since methodology is the domain of Introduction to the Study of Meiofauna (Higgins and Thiel 1988) and the updated version of Methods for the Study of Marine Benthos (Eleftheriou and McIntyre, 2005; herein for meiobenthos: Somerfield et al. 2005), this chapter should be read in conjunction with those treatises. In order to avoid too much overlap, only the more important sampling methods will be presented here. In some cases, I will include supplementary hints of practical importance which are rarely mentioned elsewhere. Additional information, particularly more detail on sampling design and devices for sampling soft-bottom sediments, may be found in the methodological recommendations of Elmgren and Radziejewska (1989) and the compilation by Blomqvist (1991). Since sampling design, strategies and statistical evaluation vary with the scientific problem being addressed, it is impossible to describe universally applicable methods here. For freshwater, valuable sampling hints are given in Palmer et al. (2006). In addition to the usual textbooks for (biological) statistics, the critical review on the calculation of diversity by Hurlbert (1984) and the compilation by Underwood and Chapman (2005) are recommended. The problem of control sites, which is important when evaluating disturbances, is competently covered for meiofauna in Eskin and Coull (1984).

3.1

Sampling

Prior to each investigation, it is important to carefully consider the area to be sampled and the equipment to be used. Among other factors, this depends greatly on sediment characteristics, the animal taxa in question and their specific adaptations. The abundance of animals, their turnover and the rate of fluctuations will influence the appropriate sample size and sampling strategy.

3.1.1

Number of Replicates and Size of Sampling Units

Patchiness, a notorious and fundamental characteristic of meiofaunal distribution (Sun and Fleeger 1991), requires that parallel samples should be taken in order to achieve O. Giere, Meiobenthology, 2nd edition, doi: 10.1007/b106489, © Springer-Verlag Berlin Heidelberg 2009

63

64

3 Sampling and Processing Meiofauna

reliable quantitative meiofauna data. In practical work, it is not the mathematically unrealistic optimal number of samples but the cost-effectiveness (time and manpower) that has to be considered (Esteves et al. 1997). As a general rule, variation between replicates should be less than the variation between sampling stations. Instead of taking one large meiofaunal sample, it is more advisable to take several small subsamples and evaluate them separately (for details see Underwood and Chapman 2005). For a reliable assessment of mean temporal abundance, the strong temporal fluctuations in many meiofaunal groups require repeated samplings over short time intervals (e.g., weekly, fortnightly; see Armonies 1990). The classical procedure used to ascertain the optimal sample size (which kinds of samples require the least effort to evaluate and still yield reliable results?) is to initially count a larger unit and then compare it with data from subsamples of defined, smaller units. The counted data should not deviate by >10% from the expected ones. The calculation of species versus effort curves is a helpful means to avoid unnecessary input (Smith et al. 1985). However, because of the extreme heterogeneity in meiofaunal distribution patterns, it remains questionable whether this method is always applicable. There is a rule that the surface sampled by the corer should exceed the patch size, but in order to follow it the latter must be known. The relevance of this rule is illustrated in Fig. 3.1. A large number of small cores (0.5–1.0 cm2) are required to assess the heterogeneous microscale distribution pattern of meiofauna (Findlay 1982). Valuable guidelines for the application of the right sample size and the resulting test power are given by Sheppard (1999) and Underwood and Chapman (2005). Sample size and, accordingly, sampling gear have to be adapted to the wide size range of meiofaunal groups. If just one size class is considered (e.g., small but numerous ciliates or fairly large but infrequent oligochaetes), sampling can be optimized by using specialized corers and evaluating different sample volumes via different extraction methods. For studies on the entire assemblage of meiofauna within one sample site, either samplers of various sizes must be used in parallel, or one must compromise when selecting the sampling gear. In any case, presampling and, where possible, examining live meiofauna gives valuable information about the qualitative composition (of those taxa destroyed by fixation too) and local distribution of the meiofauna.

3.1.2

Sampling Devices

A wide variety of sampling devices have been designed for the collection of the various meiofaunal taxa, which differ in mobility, size and habitat. For detailed lists of sampling methods, sampling gear, suitability and efficiency, see Tables 5.1 and 5.2 in Eleftheriou and Moore (2005). Specifically for meiobenthos, Somerfield et al. (2005) compile collection methods and extraction techniques in their Table 6.1. Wells (1971) recommended 10 cm2 (= 3.6 cm ø) as the minimal sample area. This small version of a tube is applicable mostly for ciliates and other abundant small

3.1 Sampling

65 403.9-527.5 527.5-650.7 650.7-774.3 774.3-897.5 877.5-1021.1

2 cm

a

b

c

411.8-550.7 550.7-689.6 689.6-828.6 828.6-967.5 967.5-1106.4

382.1-532.1 532.1-682.5 682.5-832.5 832.5-982.8 982.8-1132.8

d

e

Fig. 3.1a–e Assessment of the meiofaunal distribution on an area of about 15 × 15 cm (0.2 m2) and its dependence on the sampling design. a “Actual” distribution of meiofauna on the sampling square, assessed by 81 cores. b, c Different sampling strategies resulting in different distribution patterns (d, e). (After Findlay 1982)

66


meiofauna (nematodes). It is often constructed from disposable syringes whose lower ends have been cut. For analyses of heterogeneous small-scale patterns (e.g., in ripple marks), even straws with surface areas of 90%, hardly varying with meiofaunal group, but it is advisable to repeat the Ludox treatment several times. The number of repetitions needed for quantitative evaluation has to be assessed via test runs. If the sediment can only be treated once without any repetition, a correction factor to improve the reliability of the data should be used (Heip et al. 1974). Even in soft muds, two repetitions and thorough centrifugation usually yield 95% retrieval of fauna. With some practice, this can be done in about 30 min per sample. The size of each subsample in the centrifuge depends on the size of the centrifugation beaker, but for sufficient accuracy the addition of at least four (ten is better) times the amount of Ludox (or a Ludox–seawater mixture) to the sediment sample and thorough suspension by careful mixing is required in each case. It is advantageous to remove pebbles and other heavy particles prior to the addition of Ludox. In clay sediments which tend to form stable clumps, the addition of a water-softening detergent like Calgon® (Barnett 1980) accompanied by prolonged stirring has been shown to aid the extraction of fauna without excessive damage (add one part to five parts of sample volume). In addition to their disaggregating effects, the ammonia contained in some detergents eliminates the smell of formalin (Cedhagen 1989). After the Ludox treatment great care must be taken to quickly flush the animals from the sieves into a seawater dish and to rinse the sieves immediately to ensure that the animals and sieves are not destroyed by gelling. In samples with very high silt contents (deep-sea samples), the addition of Kaolin powder after fixation and centrifugation in a Levasil® solution (Bayer) can help to bind the finest, most easily suspended particles and thus yields a higher extraction efficiency (Heiner and Neuhaus 2007). In a simplified yet effective version of the Ludox flotation which does not require centrifugation, Somerfield et al. (2005) suggested the repeated decantation of the sample in the Ludox solution. Ludox is meant for the processing of fixed samples, although most animals extracted from live samples will remain moving and only slightly malformed if they are quickly reintroduced into seawater. The detoxification of Ludox by dialysis is cumbersome, but possible (De Jonge and Bouwman 1977). Percoll® or a Percoll®–Sorbitol mixture allow for flotation without causing physiological harm to the animals (Schwinghamer 1981b), but the high costs of these substances make this approach prohibitive for routine processing. For protists, Starink et al. (1994) successfully used a modified Percoll® method. Meiofaunal groups with heavy shells, like foraminiferans or even small molluscs, can be extracted from the sediment using higher density decantation/flotation media, such as the nontoxic but expensive sodium polytungstate SPT (Robinson and Chandler 1993).

3.2.3

Fixation and Preservation

While some meiofaunal taxa are better preserved in alcohol (halacarids) or Bouin’s fluid (turbellarians) (see detailed list in Somerfield et al. 2005, Table 6.2), the usual fixative used for (marine) meiofauna is (buffered) formalin. Here, some hints and caveats are given for optimizing the fixation procedure:

78


- Formalin should be added such that its end concentration is an ~4% formaldehyde solution (= about 10% saturated formalin, which is a ~38% aqueous solution of formaldehyde). Membrane-filtered seawater is preferable for the dilution of saturated formalin, since it has an excellent buffer capacity and it enhances the osmolarity of the fixative with favorable results for preservation. An excess of CaCO3 (chips of natural chalk, limestone or marble) in the stock solution will help to increase the alkalinity. For longer preservation without damage to calcified structures, the required careful buffering of the acidic formalin can be done with any alkaline buffer; most commonly hexamethylene tetramine (“Borax”) buffer tablets 7.0 for use in hematology or a 1% mixture of sodium dihydrogenphosphate + disodium hydrogenphophate are used. Another option after 24 h in formalin is refixation in 70% ethanol. Decantation of formalin-fixed samples should be performed under a hood (it is carcinogenic and irritates the skin!). - To preserve many contractile, soft-bodied meiofauna, it is advisable to relax the animals by anesthetization previous to fixation. For seawater fauna, the compound most commonly used for this is a 7% solution of the nontoxic substance MgCl2. 6 H2O, isotonic with seawater. The MgCl2 crystals should be kept dry so that the right concentration can be obtained, since this hygroscopic compound tends to become wet after repeated use. A concentrated stock solution can avoid these problems. Another recommended anesthetic is Menthol (25 g dissolved in 100 ml of 96% ethanol). One drop of this concentrate in a Petri dish of water will relax the animals. - A better fixative than formalin, especially for problematic soft-bodied fauna, is glutaraldehyde. However, its high price and associated handling risks usually restrict this fixative to ultrastructural studies. When an ultrastructural investigation of the animals in addition to the routine treatment is desirable, the use of Trump’s fixative (McDowell 1978) is recommended. The advantage of this fixative is its durability and versatility; specimens or samples can be stored for years at room temperature, well fixed for both light and electron-microscopic inspections. With careful handling, Trump’s can be directly used (even in the field) without any subsequent change of buffer and further handling. Recipe: for 100 ml of Trump’s solution

- Dissolve 1.16 g NaH2PO4 · H2O and 0.27 g NaOH in 86 ml distilled H2O or -

in 86 ml Na cacodylate, 0.1 M (see below) Add 10 ml saturated formaline (»37%, F-79 grade) Add 4 ml 25% glutaraldehyde to make a mixture of final pH 7.2

The highly bactericidal sodium cacodylate buffer, which is used as a solvent for the phosphate buffer, enhances resistance to bacterial deterioration. Recipe: for 100 ml of 0.1 M Na cacodylate (Na dimethylarsenic acid trihydrate) - 2.14 g Na cacodylate trihydrate - Add 0.145 g CaCl2 dihydrate - Fill up to 100 ml with H2O dest.

3.2 Processing of Meiofaunal Samples

79

Sodium cacodylate buffer is also recommended for the bulk-fixation of a sample containing much seawater, because it has been observed that phosphate buffer in seawater causes precipitation. - Microwave fixation is a method described by Berg and Adams (1984) for histological purposes. However, for durable preservation of the animals, microwave treatment must be followed by the application of formalin or some other fixative/preservative. The suitability of this technique remains doubtful, since there is little evidence that it is superior to the traditional, easily available fixation and preservation methods. - In samples retrieved from the deep sea, the distribution pattern of the meiofauna in the core may change considerably during the considerable time needed to retrieve the sampling gear. This can be avoided by using devices (e.g., bell jars) that allow the injection of the fixative directly after sampling while the instrument is still at the bottom. - The appropriate method for long-term storage of selected (museum) specimens depends very much on the meiofaunal group studied and is difficult to generalize (for information, see Part 3 in Higgins and Thiel 1988; Table 6.2 in Somerfield et al. 2005). In general, for museum purposes, formalin-fixed specimens should be refixed in ethanol. Polychaetes tend to break apart when fixed directly in ethanol. - By shock freezing with liquid nitrogen, the predatory attacks of meiofauna can be visualized (Kennedy 1994b). This process is not accessible through conventional fixing or sorting. - A lysis method that makes the rich material archived in many collections available for molecular studies has been developed for nematodes (Bhadury et al. 2006c). Its applicability to other taxa remains to be tested. - Ethanol (70%) is the standard fixative for fauna with calcareous parts. With the progress made in molecular studies it has regained importance, since undamaged DNA is classically extracted only from material fixed in ethanol, preferably in pure ethanol (70% or 96%), while formalin destroys the DNA material. Technique refinement has allowed the extraction and amplification of DNA, even from single meiobenthos individuals (Schizas et al. 1997). Dimethyl sulfoxide (DMSO) is another highly penetrative fixative that is useful for molecular analyses. - The problem of enabling both reliable fixation and preparation for molecular processing has been solved—at least for nematodes—by short-term formalin fixation (Bhadury et al. 2005). It is contended here that general molecular scrutiny preceding storage in museum collections is the approach that should be adopted for diversity assessment in the future, and this can connect traditional morphological research with advanced molecular taxonomy. - There is an interesting resin technique (after fixation in glutaraldehyde fixative) that allows the fixation and permanent storage of large numbers of animals on one microscopic slide (Rieger and Ruppert 1978). The animals are embedded in resin cast in the form of microscopic slides, (optionally) together with some sediment particles. The resulting resin slide is applicable for taxonomic as well as morphological and ecological purposes and allows the storage of significant parts of the

80


samples as “ecotype material.” Depending on the taxonomic group, one disadvantage of this is the permanent nature of the enclosure; there is no option to change the animals’ positions at a later date if this is required during inspection. - Double-sided microscopic slides are a valuable tool for the close inspection and/or storage of specimens (Shirayama et al. 1993). Special storage slides are also commonly used in studies of foraminiferans and ostracods. For nematodes that are permanently mounted, Bates (1997) provides a recipe for sealing with Glyceel, a traditional embedding compound. - In cases where a sample contains too many animals for easy enumeration of all specimens, the total extracted meiofauna should be subdivided with a sample splitter to facilitate quantitative evaluation. A precision-made and statistically tested instrument allows subdivision into exactly equal parts. Today, the most reliable type, specially designed for meiofauna, is the “Jensen splitter” (Jensen 1982), which can be constructed in a good workshop. There are also some modifications of this very useful instrument for meiofaunal work. Quantitative drainage of the chambers can be improved by giving the bottoms of the chambers a slight slope towards the stopper holes. When mounted on somewhat longer supporting stands than those suggested by Jensen, the rinsing of the subsamples into dishes becomes easier. For other, simpler subdividing techniques, see Somerfield et al. (2005).

3.2.4 Processing and Identifying Meiofaunal Organisms A few instruments that are needed for the various procedures involved in handling and studying meiofaunal organisms will be mentioned here. They have proven very helpful in daily routine work with meiofauna, but are usually omitted from descriptions. Some hints about new identification techniques are also given at the end of this chapter. - The quantitative sorting of large numbers of organisms is much easier and more reliably done in specially made rectangular perspex trays called “Bogorov trays,” named after a Russian plankton specialist (Fig. 3.5). The inner surfaces of these trays are subdivided by a system of leveled bars, resulting in a meandering system of stripes for counting the extracted organisms. The widths of these stripes should be slightly less than the diameter of the eye field at the normal magnification of the dissecting microscope used for routine scanning. The advantage of this device when used for quantitative enumeration over any kind of Petri dish is its square shape and the bars. In the case of an accidental push or when working on board a ship, these bars largely prevent swashing and dislocation of the specimens and so they enable precise counting to continue. Straight lines, 1 cm apart and scratched across the bottom of the tray, support orientation. The overall size of the dish should be conveniently adjusted to the size of the microscopic stage. Slats on the underside of the dish prevent undesirable adhesion if the microscopic stage surface should become wet. A recent development, derived from the typical Bogorov tray, is a sorting tray where the

3.2 Processing of Meiofaunal Samples

81

Fig. 3.5 Sorting tray for meiofauna (a modified Bogorov tray); size 8 × 14 cm, height: 1.5 cm

meandering trough system has been milled by a cutter from a solid perspex plate (Fig. 3.5). Its precise manufacturing avoids the inevitable crevices and imperfections resulting from the gluing of perspex strips. For quantitative evaluation of the complete meiofaunal assemblage in a sample, the extracted contents should be inspected once at 10–15× magnification and another time at 30–50×. - For the removal of single live specimens from water samples, the use of a “mouth pipette” allows work to be completed far more rapidly than when using normal pipetting. We use the rimmed plastic protective tubes of syringe needles cut to a convenient length as mouth pieces for the pipettes. They allow a good yet relaxed hold between the teeth and are easily and inexpensively exchanged. However, each pipetting bears the risk of losing specimens in the glass tip and sucking up other unwanted particles. Coating with silicone can partly solve this problem. Animals clinging to the walls and the bottom of the dish are difficult to remove with a (mouth) pipette. - A far “cleaner” and more selective approach, but also one that is far more tedious, is “fishing” out specimens with thin needles or loops, formerly known as “irwin loops.” Stainless steel needle holders that are heavy enough to effectively reduce the natural slight vibrations (the resting tone) of the hand can be purchased from medical instrument suppliers. Their grip should firmly hold even the minute stainless steel pins used in entomology for small insects. The author found the long, flexible, yet sufficiently stiff needles used in acupuncture to be the optimal instruments for inspecting meiofauna; these are usable even without being clamped in a holder. The thinner types are extremely fine at the tip yet are durable and easier to handle than minute insect needles. The use of loops is recommended for removing more spherical organisms (ostracods, nauplii, cladocerans, eggs). They can be manufactured from very thin tungsten or nickel wire, which is available from suppliers of electronic equipment or laboratory equipment. The wire is then

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tightly twisted from both ends around a hooked needle to produce a loop. Fine adjustment to the desired loop diameter is achieved by further twisting it with another hooked handle. After slightly flattening the resulting loop by pressing it between the blades of forceps (combination pliers) and bending it into a convenient angle, the remaining ends of the wire are tightly twisted to form the shaft of the instrument, which is then inserted or glued into the grip of a needle holder. - Satisfying microphotographs of meiofauna are rare. For a professional standard of quality with sufficient depth of focus, special and expensive photomicroscopes (photostereomicroscopes are often even better) are required. When combined with microflashes they enable live photography. The problem of maintaining the animal in a desired position without risking smashes or losses is elegantly, though expensively, solved by the “compression chamber” devised by Uhlig and Heimberg (1981), which is commercially available. The use of video and digital cameras adapted to microscopes has considerably broadened the possibilities for the optical documentation of meiofauna. However, creating a didactically useful film on meiofauna requires that a great deal of professional effort be directed into “cutting” and editing. Two fully edited videofilms with commentary in English are available that aptly present the wide array of groups of organisms and their characteristics: (a)

(b)

Meiofauna of Marine Sediments (21 min, optionally PAL and NRSC systems) by J.A. Ott and A. Bochdansky, Vienna, Austria. This may be purchased from Verein Pro Mare, Biozentrum, Althahnstr. 14, A 1090, Vienna, Austria. Cryptic Fauna of Marine Sand (20 min) by R.P. Higgins, which can be obtained through the Society of Integrative and Comparative Biology. Digitized copies may become available soon.

- Today, software for computer-aided optometric studies and image analyses are widely available and can be conveniently used on the monitor screen. Using semi-automated image analysis software and conversion factors from the literature (see Sect. 9.3.2), Thomsen (1991) calculated the number, size, volume, and biomass of bacteria and meiofauna. Other novel techniques in microscopy (image EELS, laser scanning, 4D, cLS) can greatly increase our knowledge of analytical details, developmental processes, and structural complexes in meiofauna, contributing to novel interpretations of old problems (see Sect. 10). - Protocols for the computer-assisted, semi-automated calculation of meiofaunal biomass have been developed using digital microphotography (Baguley et al. 2004). This method combines a relatively large throughput with nondestructive handling, which enables subsequent taxonomic work. Traditional methods are calculations of volumes on the basis of a dot-counting overlay on top of microphotographs (e.g., Kaye 1993), a method derived from microbiology (bacteria volumes). - Electronic media and new software programs have increased the development of computer-assisted, partly interactive, identification keys for meiofaunal groups (e.g., Diederich et al. 2000 for nematodes; Wells 2007 for harpacticoids). Although an ever-growing number of pictures of meiofauna can be found on

3.3 Extraction of Pore Water

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various websites and homepages, the “identification” of the depicted forms, when not controlled by a specialist, should be met with skepticism. This pathway to publication is by no means scientifically warranted, and so these often impressive illustrations should only be taken as helpful indications. Electronic support for the design of illustrations (Bouck and Thistle 1998) can facilitate scientific drawing, a technique that is necessary for taxonomic descriptions but is often found to be cumbersome and difficult.

Box 3.1 Sampling and Evaluating Meiofauna The statistical precautions, sampling strategies and general devices used in benthic research are also relevant for the sampling of meiofauna and are wellcovered in pertinent methodological works, the latest being that by Eleftheriou and McIntyre (2005). The kind of sample processing applied is related to the type of sediment and goal of the study. Provided below is a summary of some practical hints for reliable treatment. - The correct sample size and number per study area to use depends on the number of specimens present. Therefore, it is important to pre-sample, evaluate subsamples and inspect living fauna. - Tube corers of varying size and numbers per sampler (Kajak corer, Craib corer, multicorer) are the most common and, if used correctly, the most reliable tools that have been tested for different sediment types and depths. Grab samplers (e.g., the van Veen grab) do not generally work quantitatively. - Live meiofauna are usually concentrated by decantation or by the “seawater ice method,” especially for soft-bodied animals. - For easier recognition of meiofauna the sample should be pre-stained (Rose Bengal). - The most effective quantitative extraction methods for fixed meiofauna are decanting or elutriation (for sands), and flotation with Ludox® for fine sand and mud. - For most studies, meiofauna are fixed in buffered formalin. For taxonomic purposes, soft-bodied taxa should be relaxed beforehand (MgCl2). Re-fixation in ethanol is best for long-term storage. Trump’s fixative allows for ultramicroscopic sections. - Fixation for molecular work is usually by alcohol; preferably by pure ethanol (96%). - To speed up evaluations of samples with abundant meiofauna, the use of a sample splitter is advised. - The use of a Bogorov tray is a more reliable and less cumbersome enumeration technique than sorting in Petri dishes. - Fine acupuncture needles are perfect instruments for sorting and dissecting meiofauna, as are tiny twisted loops of thin tungsten wire (“IRWIN loops”) for spherical objects.

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3.3


Extraction of Pore Water

The importance of pore water for meiobenthic animals requires analyses with methods that are mostly based on the extraction of free pore water. The inherent problem with this analytical procedure is the destruction of fine-scaled physical and chemical gradients which often characterize the meiobenthic habitat. Suction sampling. In accessible intertidal areas, the easiest way to extract pore water is to gently push a disposable glass pipette or a hypodermic syringe directly into the sediment and to obtain the pore water by suction. Water at the different horizons can be collected from a sediment core through lateral openings in the corer that are initially sealed. Pressing the core with a tightly fitting piston facilitates the extraction of the pore water (Jahnke 1988). A piece of fine nylon gauze (20 µm mesh size) or a commercially available copper grid used for transmission electron microscopy, sealed onto the tip of the pipette, prevents the clogging of the small opening by sediment particles. An effective and easily built device for obtaining pore water is a modified glass capillary (Fig. 3.6a). It has a tightly fitting syringe cap into which many holes have

a

b

Fig. 3.6a–b Pore water samplers. a Capillary syringe (after Howes and Wakeham 1985). b Pore water lance (after Giere et al. 1988a)

3.3 Extraction of Pore Water

85

been drilled with a microdrill. The opposite end of the glass capillary is connected to thin gas chromatography tubing (important: teflon tubing is not gas-tight and cannot be used to determine oxygen and hydrogen sulfide in pore water), connected to the glass tube via a tightly sealed syringe stub (Luer stub). Another tight syringe stub at the other end of the flexible tubing is connected to a small syringe (1 ml). Drawing the piston of the syringe with some care enables pore water to be obtained without air bubbles, which tend to penetrate into the tubes at their connecting ends. The insertion of a disposable microfilter in the tubing will filter turbid pore water. A pore water sampler particularly designed for flushing with nitrogen and which is therefore well suited to measurements of oxygen or sulfide content has been constructed by Zimmermann et al. (1978). Its considerable size renders it more suitable for permanent installation in the sediment to be investigated. Dye (1978) constructed a pointed metal tube with a sample port covered with fine gauze that, during insertion into the sediment, is tightly capped with a PVC sleeve. When the desired depth is attained, the sleeve is slid up and the pore water can enter the inner chamber from a connected syringe. For sublittoral sediments, a diver-operated “pore water lance” allows the extraction of pore water from a series of horizons. A modified version of the pore water lance, originally constructed by Balzer (Kiel), is described in detail in Giere et al. (1988) and is depicted in Fig. 3.6b. Through the series of samples extracted with this instrument, differentiated gradient profiles of pore water can be obtained for measurements. Its versatility and sturdiness make the pore water lance a reliable and effective tool at depths accessible to diving. Similar designs are now in use by several working groups. For soft bottoms in deep water, more complicated “harpoon samplers” with triggering devices have been constructed. As a spring-loaded piston moves up in the sampling chamber, pore water is sampled and filtered (Barnes 1973). Another suction corer for use in deep water has been designed by Sayles et al. (1976) for geochemical studies, but it can be modified for the smaller dimensions associated with meiobenthic studies. A damped piston moving in a cylinder is mounted on top of a pointed metal tube with a series of ports capped with some filtering device. Through the action of the triggered piston, pore water is sucked through the ports into a series of chambers mounted in the inner lumen of the tube. When hauled on deck, the water can be extracted from the chambers by syringes. Squeeze sampling. Reeburgh (1967) used a plastic squeezer equipped with filter screens on top of a drain tube. Mounted on a glass bottle, the squeezer is subjected to gas pressure and the pore water is efficiently squeezed and filtered out of the sediment. Centrifuge sampling. In coarse sand, and particularly in sediments of low porosity, the extraction of pore water by suction or squeezing becomes problematic and inefficient. Here, centrifuging yields much better results. After only a short centrifugation time and without further contamination, pore water can be extracted in quantities larger than those obtained by squeezing methods. Saager et al. (1990) developed specially manufactured centrifuge tubes with built-in filter

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units that filter the samples without any contamination. A further step towards maintaining an undisturbed pore water sample is to use special corers adapted to function directly as centrifuge tubes. More detailed reading: Giere et al. (1988); Pfannkuche and Thiel (1988); Somerfield et al. (2005).

Chapter 4

Biological Characteristics of Meiofauna

4.1

Adaptations to the Biotope

The heterogeneity of meiofaunal habitats is so large and meiobenthic taxa so diverse that there are only a few general trends in morphological adaptations, and these mostly apply to mesopsammic fauna. The most widespread and clearest adaptive features to a particular mesopsammic environment have evolved in the meiofauna of medium and coarse sands. The formative constraints on and the premises for entering the world of narrow voids in this interstitial environment will be detailed in the following sections.

4.1.1

Adaptations to Narrow Spaces: Miniaturization, Elongation, Flexibility

The prime requirement for all meiofauna to be successful is to be small, at least in one dimension (e.g., body width). This adaptive constraint becomes evident when comparing body sizes of related animals from various habitats (Fig. 4.1) or the proportion of small animals within a taxon for various habitats (Fig. 4.2) Particularly in those meiobenthic animals that predominantly belong to macrobenthic groups (Table 4.1), the decrease in body size is striking and believed to have intrinsic lower limits for the various animal groups: 0.5–1 mm in many taxa (Swedmark 1964), 0.3 mm in copepods (Serban 1960). Dwarfism is mainly accomplished by reducing the number of cells while keeping the average cell size fairly constant. Rotifers consist of only about 1,000 cells, and the nematode Caenorhabditis elegans in the male phase of 959 somatic cells (and in the subsequent female phase of 1,031 cells), of which every lineage is thoroughly known. Yet, as an exception, loriciferan species (sometimes only 50 µm long; perhaps the smallest known metazoans) reportedly consist of as many as 10,000 or more cells (Kristensen 1991a). Dwarfism often leads to a simplification of body organization or to a loss of organs (number of segments, legs, gonads, loss of eyes), and, along the lines of regressive evolution, it can phylogenetically lead to new taxa that are restricted to interstitial refuges (see Chap. 6). O. Giere, Meiobenthology, 2nd edition, doi: 10.1007/b106489, © Springer-Verlag Berlin Heidelberg 2009

87

88

4 Biological Characteristics of Meiofauna 1.6 1.4 1.2 1.0 0.8 0.6 0.4 0.2 0.0 mm

open water

muds

phytal

sand

Fig. 4.1 A comparison of copepod sizes (in mm) in various habitats. (After Kunz 1935)

80

70

60

50

40

30

20

10

0 %

in phytal

in muds

in coarse sand

in medium sand

Fig. 4.2 The proportions of small copepods (< 0.5 mm length) in various habitats. (After Lang 1948)

4.1 Adaptations to the Biotope

89

Table 4.1 Examples of dwarfism in interstitial animals belonging to large taxa (after Remane 1933, extended) Animal group (genus, species) Body size [mm] 0.4 Cnidaria (Halammohydra ) 0.4 Polychaeta (Nerillidium, Diurodrilus ) 1.0 Gastropoda (Microhedyle ) 1.5 Priapulida (Meiopriapulus ) 0.8 Crustacea, Tanaidacea (Pseudotanais mortenseni) 1.2 Crustacea, Isopoda (Microcharon sp.) 1.0 Crustacea, Amphipoda (Ingolfiella petkovskii) 3.0 Echinodermata, Holothuria (Labidoplax) 3–4 Ascidiacea (Psammostyela )

Adaptation to the interstitial habitat is often achieved by reducing the width only, and slender bodies can be surprisingly long (see, e.g., among ciliates the Trachelocercidae, among turbellarians the Coelogynoporidae, among nematodes the Stilbonematinae, among polychaetes the “archiannelid” Polygordius, among oligochaetes the gutless phallodriline genera, e.g., Olavius, and among the Acari the oribatid Nematalycidae). A filiform body shape, sometimes with a corresponding reorganization of the internal organs, offers advantages that are only indirectly related to the small habitat dimensions. The locomotory active surface (via ciliation or body musculature) becomes enlarged, effects of adhesion and anchoring become improved, and the extreme ratio of body surface to body diameter supports transepidermal uptake and diffusion of dissolved organic substances and enables a complex pattern of tactile stimuli. While the length-to-width ratio normally ranges from 3:1 to 10:1, it can reach 100:1 in, for example, interstitial nemerteans, some polychaetes and oligochaetes (compare the “width index” of Remane 1933). Some specialized nematodes, crustaceans and other groups attain similar size relations (Jensen 1986; 1987b). This convergent adaptive advantage of body elongation is particularly apparent in representatives that belong to groups that normally have a more ovalto-round shape (Fig. 4.3). Extreme flexibility is an important adaptation for life in the labyrinth of the interstitial system of sand grains. In soft-bodied, vermiform animals this is rather easily accomplished, but in animal groups with a chitinous cuticle, which often have compact body sections, the body must become more articulated, resulting in small, uniform segments (e.g., in interstitial harpacticoids, tanaidaceans, isopods, amphipods). Through this modification, the body attains an overall vermiform shape, flexible enough to easily allow U-turns. In those interstitial worms where the number of segments is not constantly fixed, the number of segments is often greatly enhanced (some oligochaetes have >150 segments, and the polychaete Polygordius has up to 185 segments). Perhaps linked to the trend for elongating the body and clinging to the substratum is the frequent development of a tapering body end, forming a tail, which is convergently present in numerous interstitial animal groups (Fig. 4.4). It is doubtful

Avelia (Ciliata)

Vannuccia (Turbellaria) Haplognathia (Gnathostomulida)

Polygordius (Polychaeta)

Cylindropsyllus (Harpacticoida)

Nematotanais (Tanaidacea)

Nematalycus (Acari)

Fig. 4.3 Convergent trend for body elongation in interstitial meiofauna. All figures are depicted at the same scale. (After Remane 1933, extended)

Marenda nematoides (Foraminifera)

90 4 Biological Characteristics of Meiofauna

Spirostomum filum Thylacorhynchus caudatus

PLATHELMINTHES

Boreocelis urodasyoides

GASTROTRICHA

Urodasys viviparus

NEMATODES

Trefusia longicauda

Fig. 4.4 Interstitial animals with a tail. All figures are depicted at the same scale. (After Ax 1963, extended)

PRIAPULIDA CILIATA

Tubiluchus troglodytes

ASCIDIACEA

Heterostigma fagei

4.1 Adaptations to the Biotope 91

92

4 Biological Characteristics of Meiofauna

that there is a common function for this structure. While the tails in animals like Urodasys (Gastrotricha), Tubiluchus troglodytes (Priapulida), Trefusia longicauda (Nematoda), or Batillipes bullacaudatus (Tardigrada, with an inflatable terminal bubble) appear to function as a device anchoring against displacement, in others it has instead been interpreted as a tactile organ (Ax 1963). Another frequent adaptation to the interstitial environment is flattening of the body. This appears to enable the animals to squeeze through narrow crevices and to increase body flexibility. Also, it enhances the forces of friction against the substratum, important for effective movement by wriggling. As in body elongation, there are also physiological and behavioral advantages to becoming flat (oxygen diffusion, transepidermal nutrient uptake, enlargement of the contact zone with the sand grains, development of a “creeping sole”). In groups with a roundish shape, a dorsoventral depression is an exceptional phenomenon that occurs mainly in interstitial forms (e.g., in the ciliates Remanella, Kentrophoros and Loxophyllum, in some chromadorid nematodes, in the oligochaete Olavius planus, and even in some crustaceans like mystacocarids and specialized ostracods).

4.1.2

Adaptations to the Mobile Environment: Adhesion, Special Locomotion, Reinforcing Structures

For many meiobenthic animals, adhesion is an important adaptation that allows them to live in a mobile environment. Solid external cuticular plates, shells and rings can serve as anchoring devices that increase adhesion to the sediment. These characterize some interstitial halacarids, ostracods and harpacticoid species as well as epsilonematid and desmoscolecid nematodes. Combined with scales, spicules and thorns, these structures are also frequently found in gastrotrichs, kinorhynchs, loriciferans, priapulids (particularly the priapulid larva), and in aplacophoran molluscs. The development of adhesive or “haptic” structures is particularly frequent in the interstitial fauna of mobile sands (Fig. 4.5). Aside from these mechanical/structural means, adhesion to sand grains is also achieved through a variety of physiological and behavioral adaptations (Fig. 4.6). Functionally, these organs are mostly based on the “dual gland system” (e.g., many nematodes, gastrotrichs and rotifers; Tyler 1976; Hermans 1983), where one gland contains the adhesive mucus and the neighboring gland produces the releasing compound. – Secretion of viscid mucus on the whole body surface: many nematodes, turbellarians, gastropods, annelids – Excretion of sticky coelomic fluid through caudal coelomopores in interstitial oligochaetes (Marionina) – Adhesive glands concentrated in particular regions, forming special structures: an adhesive “girdle” in the turbellarian Rhinepera and the polychaete Dinophilus, posterior haptic “toes” in many rotifers, gastrotrichs and in the annnelids Diurodrilus, Saccocirrus, Hesionides, Protodrilus,


93

60

50

40

30

20

10

0 %

In mud *

In mud *

Among plants

In sand

* Different sites

Fig. 4.5 Percentage of haptic animals among meiofauna from various habitats. (After Remane 1933)

– Haptic setae: in ciliates (cirri), gastrotrichs, many nematodes (Draconematidae, Epsilonematidae), kinorhynchs and in many ostracods – Strongly adhesive flagellae in interstitial flagellates (e.g., Amphidinium testudo) Besides glandular adhesion, there are examples of mechanical adhesion, such as the viscid disks on the toes of the tardigrade Batillipes (see Fig. 5.27) or the flattened body of the harpacticoid Porcellidium (see Figs. 5.34 and 8.10a). Parallel to the structural and morphological features mentioned above, an effective adhesion process requires behavioral adaptations. The animals must react to perilous water currents, sediment displacement or other sudden disturbances with an immediate adhesion impulse. After a while, contact through glandular excretions will be chemically released or will become physically ruptured by the movements of the animal (the oligochaete Marionina). In the phytal, where larger and more complex substrates are present for clinging, typical adaptations of the meiofauna include clinging legs, often equipped with long bristles and spines (Halacarida, Tardigrada, Harpacticoida, Ostracoda; see Sect. 8.5), or the suckerlike protrusion in the harpacticoid copepod Porcellidium (see Fig. 8.10a). Many meiobenthic animals have developed specialized locomotive organs and characteristic modes of locomotion, often in conjunction with adhesion or elongation of the body.

Thaumastoderma (Gastrotricha)

Batillipes (Tardigrada) Diurodrilus (Polychaeta)

Rhinepera (Plathelminthes)

Cicerina (Plathelminthes)

Encentrum (Rotifera)

Fig. 4.6 Interstitial animals with characteristic adhesive structures. All figures are depicted at the same scale (After Remane 1933, extended)

Turbanella (Gastrotricha)



95

– Gliding by means of ciliation (Fig. 4.7). An unusually large number of ciliated animals live interstitially in the sand. Here, gliding is not only typical of ciliates, turbellarians and gastrotrichs, where it is a group characteristic, but also of many meiobenthic polychaetes (archiannelids), molluscs, hydroids (Halammohydra) and, in a modified way, rotifers that move with their wheel organ. Many ciliated animals move very quickly, particularly members of the proseriate platyhelminth family Otoplanidae, and some gastrotrichs seem to “swim” through the coarse sand, although they are animals that show positive thigmotactic behavior and so in fact remain in contact with the substratum. – Wriggling, i.e., undulatory propulsion by alternate pushing and bending, is typically used by nematodes that possess only longitudinal musculature. However, wriggling also occurs in specialized oligochaetes like the enchytraeid Grania, which has a rather solid cuticle and a thick longitudinal musculature but only a thin circular muscle layer. Also, some gastrotrichs with a thick cuticle and some turbellarians exhibit writhing and kicking movements. Some psammobiotic harpacticoids do not move through leg strokes but with a general wriggling of the vermiform body, which pushes the animal through the sand. – Crawling on the sand grains occurs relatively rarely in some slow-moving groups. It is typical of halacarids, ostracodes and tardigrades. – Burrowing is common only in the meiobenthos of soft muds, where it is achieved through peristaltic contractions of the body musculature (as in some annelids) or

Fig. 4.7 Percentage of ciliated meiobenthos among total fauna. (After Remane 1933)

96


by the typical protrusion–eversion of an introvert (sipunculids, priapulids, loriciferans). Kinorhynchs derive their name from this kind of motion. In crustaceans inhabiting soft muds, digging is realized by powerful leg movements (some harpacticoids, ostracods, tanaids and cladocerans). – Climbing through the thicket of sand grains or plants by extending long, elastic and often sticky appendages and drawing the body behind is a typical movement of some exceptional interstitial animals whose “normal” relatives are pelagic swimmers or sessile benthic forms: the mesopsammic genera of cnidarians (Psammohydra, Otohydra), the meiobenthic anthozoan Sphenotrochus, the slow-moving brachiopod Gwynia, the mobile bryozoon Monobryozoon, the small holothurian Leptosynapta, or the sand-living ascidian Psammostyela. – Somewhat related to climbing is the iterative contraction–elongation of the whole body with alternating fixation of the body ends (looping). Characteristic of inch worms (the larvae of geometrid butterflies) and hirudinids, this type of movement occurs fairly frequently in meiobenthic animals, mostly in conjunction with rhythmic body elongation and subsequent adhesion to the substratum (Fig. 4.8). It characterizes the movements of very different meiobenthos such as the hydrozoans Psammohydra nanna, Cryptohydra thieli, and Protohydra leuckarti, epsilonematid and draconematid nematodes, the gastrotrich Macrodasys, several turbellarian platyhelminths, synaptid holothurians, the tiny gastropod Unela, rotifers adhering alternatively with their “toes” and their wheel organs (such as Philodina), and the annelid Rheomorpha.

Macrodasys (Gastrotricha)

Draconema (Nematoda)

Rheomorpha (Annelida)

Epsilonema (Nematoda)

Fig. 4.8 “Looping” movements in various meiobenthic taxa. All figures are depicted at the same scale. (Various authors)


97

Members of meiobenthic groups living in the interstitials of sand are frequently “armored” with structures interpreted as reinforcements and protection from mechanical stress (pressure, agitation of sediment; Fig. 4.9). However, in cases where the animals live in rarely exposed soft mud, the mechanically protective character of these structures is doubtful and they probably instead provide a means of increased adhesion (see above). Internal crystals, fibrils and spicules occur repeatedly in interstitial animals. Some ciliates have conspicuous fibrils (e.g., Diophrys, Aspidisca) and spicules (Remanella) in their cytoplasm. The turbellarian Acanthomacrostomum spiculiferum derives its species name from its armature of internal spicules in “sagittocysts” (Gschwentner et al. 2002). The family of acoel plathelminths Sagittiferidae is named after their numerous internal spicules. Other meiobenthic forms belonging to soft-bodied groups like molluscs and holothurians contain a lattice of characteristic spicules: for example the snails Rhodope and Hedylopsis as well as the minute sea cucumber Leptosynapta (see Rieger and Sterrer 1975). Another way of stiffening the body is the vasculariza---tion and turgescence of cells in tissues or intercellular spaces. Cushion-like structures occur in some polychaetes, many gastrotrichs (Rieger et al. 1974; Teuchert 1978), some monhysterid nematodes (van de Velde and Coomans 1989), and turbellarians. In the turbellarians Nematoplana and Coelogynopora, intestinal cells form a stiffening, “chordoid” tissue extending through the longitudinal axis of the body. Also, the characteristic accumulation of turgescent cells in the prostomium of the interstitial oligochaete genus Aktedrilus (Tubificidae) probably has a stiffening function that adapts the worm to burrowing through the sand. Alveolar external tissue has also developed in the interstitial chaetognath Spadella interstitialis (Kapp and Giere 2005). The layer of vacuolized chambers in the egg capsules of some turbellarians from exposed sands should also be mentioned in this context.

4.1.3

Adaptations to the Three-Dimensional Dark Environment: Static Organs, Reduction of Pigment and Eyes

The presence of static organs in many meiofauna is considered to result from the need for orientation in a wide three-dimensional sediment system—comparable to the corresponding phenomenon seen for many members living in the water column. As an exception from the general body structure of the group, static organs (organelles) occur in some meiobenthic members of ciliates (Remanella) and hydroids (Halammohydra, Pinushydra), turbellarians (Acoela and otoplanid Proseriata), enoplid Nemertinea (Ototyphlonemertes), marine enchytraeid oligochaetes (Grania), the isopod group Anthuridea, and the meiobenthic synaptid holothurians. In the latter, they have developed in not only the interstitial forms but also among the larger relatives. Body pigmentation is reduced in many meiobenthic animals that live in a dark environment. They are whitish-opaque or transparent, which enables microscopic

Acanthiella (Plathelminthes)

Rhodope (Gastropoda)

Falcidens (Aculifera)

Lepidodasys (Gastrotricha)

Fig. 4.9 Structures that reinforce the bodies of meiobenthic animals. All figures are depicted at the same scale. (Various authors)

Nematoplana (Plathelminthes)



99

scrutiny of their internal organs for identification without dissection. The lack of body pigments and prevalence of transparent tissues is particularly striking in comparison with their larger relatives from the epibenthos. However, there are some exceptions to the rule of general pigment reduction in meiobenthos. Particularly in the calcareous sands of warm-water regions, white pigmentation of meiofauna is common. Symbiotic relationships with white sulfur bacteria make gutless tubificids, stilbonematid nematodes and some ciliates shiny white. Sometimes, even an orange-to-pink or yellowish color (Meiopriapulus fijiensis, polychaetes, ostracods, some harpacticoids) blends in well with the pink-to-orange shine of some coralline sands. In phytal meiofauna we find some colorful halacarids (Copidognathus) and turbellarians (Procerodes). Whether this coloration actually represents a camouflage adaptation aimed at avoiding motion-oriented or nonselective macrobenthic predators is unknown. In any case, it sometimes makes them difficult for the researcher to discern. Endobenthic meiofauna are mostly blind; only a few epibenthic forms such as naidid oligochaetes, ostracods, harpacticoids, and tardigrades have retained simple eyes. The reduction of eyes is particularly striking in animal groups where eyes usually are present, e.g., in polychaetes.

4.1.4

Adaptations Related to Reproduction and Development

The minute body sizes of the meiobenthos largely determine their developmental modes, since they do not support the shedding of abundant gametes. Especially in the interstitial, specialized approaches to sperm transfer, fertilization and development have been developed. Due to their reduced sizes, many interstitial animals have only a single ovary. Most of them produce just one or only a few eggs (Table 4.2). In ostracods, where paired penes are common, the meiobenthically small species often develop just one penis. The formation of loose sperm bundles (spermatozeugmata) or more complicated spermatophores considerably enhances the chances of Table 4.2 Reduced egg number in some typical meiobenthos (from various authors) Taxon Egg number 1–4 Halammohydra (cnidarians) Kalyptorhynchia (turbellarians) 1–3 2–5 Trilobodrilus (polychaetes) Microdriline oligochaetes 1–4 1 Bathynella (syncarid crustaceans) Microparasellidae (isopods) 1–4 1–2 Angeliera (isopods) 1–2 Bogidiella (amphipods) 1–2 Uncinotarsus (amphipods) 2–3 Leptosynapta (holothurians)

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fertilization and reduces the risk of sperm loss in a world where spermatozoa released into the pore water would not be carried any great distance by water currents. Sometimes sperm bundles are deposited on the substratum, e.g., in the polychaete Nerilla, where they are subsequently taken up by the partner. More frequently they are transferred directly onto the skin of the partner, but the subsequent process of their transfer to the eggs often remains unknown (histolysis?): this occurs in some tardigrades, hesionid polychaetes, tubificid oligochaetes (Aktedrilus monospermathecus), and kinorhynchs. Hypodermal injection occurs in the polychaete Trilobodrilus, the snail Hedylopsis, in some gastrotrichs, and (particularly well studied) in many rotifers, where the initially produced sterile sperm histolytically “clears” a route towards the eggs for the subsequently released fertile sperm. The most direct way of sperm transfer ensuring fertilization is copulation, which frequently occurs in meiobenthic animals (e.g., in polychaetes, see 2efv Fig. 5.43). This not only entails the “construction” of organs that directly participate in sperm transmittance (cirrus, penis) and often sperm storage (vesicula seminalis, spermatheca), but it also necessitates sense organs to find the partner from a distance and behavioral cooperation in order to obtain the correct positioning needed to complete copulation successfully. In groups such as turbellarians or oligochaetes, the whole taxon is characterized by this most evolved approach to reproduction; however, meiobenthic representatives from taxa which normally simply shed their spermatozoa into the ambient water, like polychaetes, have also developed penislike organs, complicated modes of copulation (e.g., Questidae) and elaborate sexual behavior. The sexual foreplay that has developed in some turbellarians, gastrotrichs and polychaetes is astonishingly complex for these “lower invertebrates.” One important way to further enhance the chances of successful reproduction in a world with a limited individual range of distribution is hermaphroditism. Most macrodasyoid gastrotrichs (e.g., Turbanella) and small meiobenthic polychaetes are hermaphrodites, including Ophryotrocha, Microphthalmus, and some tardigrades (some Echiniscidae; many Eutradigrada), hydroids (Halammohydra, Otohydra), and even some meiobenthic crustaceans (some Tanaidacea) and holothurians (Leptosynapta). Groups such as gnathostomulids, turbellarians and oligochaetes exhibit hermaphroditism as a general feature of the taxon, and so are preadapted to a meiobenthic life. The low chances of survival of many meiobenthic species, aggravated by their reduced mobility and low number of embryos, are compensated for by direct development without any free-swimming larvae, by relatively short generation times, and frequently continuous reproductive periods. Like the sperm, the fertilized eggs do not freely float in the pore water. Instead, with their sticky surfaces they adhere to sediment particles or are ensheathed in a capsule (turbellarians) or cocoon (oligochaetes, some polychaetes), which becomes glued to the surface of a sand grain. Loss of offspring is further reduced by hatching well-developed and self-sufficient juveniles. Viviparity is not uncommon (e.g., the gastrotrich Urodasys viviparus, the rotifer Rotaria, the hydroids Armorhydra and Otohydra vagans). Parental brood protection of the embryos occurs frequently in special capsules or pouches of/on the body. Nerillid polychaetes attach their offspring to the posterior part of


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the body, and ovisacs (in harpacticoids) or “marsupia” (in peracarid crustaceans) provide protection to the developing embryos. Rapid asexual multiplication (budding or fissure) occurs in some turbellarians (Macrostomida), some polychaetes (Syllidae), in most Naididae (Oligochaeta), and in aeolosomatid annelids. Parthenogenetic reproduction is common in rotifers, chaetonotoid gastrotrichs, darwinuloid ostracods and in cladocerans. In meiobenthic animal groups, the tendency to abbreviate ontogeny has often led to neotenic or progenetic development (Westheide 1984, 1987a). Progenesis characterizes many polychaetes (e.g., Ophryotrocha, Dinophilus, Apodotrocha, Trilobodrilus), which have retained larval traits such as ciliary tufts and bands, and a lack of coelomic compartmentation. However, progenesis also occurs in meiobenthic opisthobranch molluscs, in many gastrotrichs and interstitial Cnidaria, and has also been found in some loriciferans. In some (freshwater) crustacean groups, neoteny has led to phylogenetically interesting new groups (see Chap. 6). Encystment and dormancy often help animals to survive periods of hostile life conditions and are particularly frequent in freshwater meiofauna (Alekseev et al. 2007). Turbellarians, cladocerans, rotifers and some harpacticoids have stages of “dormancy.” In freshwater biotopes, tardigrades, some ostracods and some nematodes are perfectly adapted to survival under extreme conditions such as dryness through the development of “cryptobiosis.” In the marine realm, encystment occurs in tardigrades, in many turbellarians from salt marshes, in Dinophilus taeniatus (Polychaeta), and in the harpacticoid Heteropsyllus nunni (Coull and Grant 1981; Williams-Howze and Coull 1992). Some antarctic harpacticoids seem to have a diapause stage during their copepodite phase (Dahms 1991). Interestingly, many resting eggs of planktonic copepods occur in sediment and hatch under more favorable conditions (e.g., increasing spring temperatures). Dormant copepod eggs were regularly found in sediment samples of anoxic mud from the Black Sea (Luth et al. 1999; Sergeeva and Gulin 2007). Larval stages of some deep-sea species of Rugiloricus (Loricifera) retard their hatching through encystation (Kristensen 1991b). In all of these developmental adaptations, the respiration is massively reduced and metabolism becomes deeply quiescent. Despite the diversity of the numerous animal groups found in the meiobenthos, and despite differences in organization, structure, taxonomic rank and phylogenetic age, they have all experienced the constraints and dynamics of the interstitial habitat. They have all have been subject to “integrating adaptations” (Remane 1952) which can form analogous specializations with often surprisingly uniform convergent traits in groups of different systematic position. Here, the meiofauna exhibits parallels with troglobitic fauna, edaphic assemblages, and partly also phytal communities (e.g., Remane 1952). More detailed reading: Ax (1966, 1969); Swedmark (1964); Schwoerbel (1967).

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Box 4.1 Adaptations of a Typical Meiobenthic Animal A small body size is the characteristic feature that overrides all other adaptations of a meiobenthic animal. It is indispensable when squeezing through the narrow crevices between sand grains or pushing through thickets of debris and mud. Distinctive adaptive features have evolved in sand meiofauna (interstitial fauna). Filiform or flattened bodies, often equipped with long tails, enable flexibility and contact with sediment particles, facilitating movement through the void system. Locomotion in sand is often achieved by body ciliation or by wriggling movements, while burrowing occurs mostly in soft muds and climbing in phytal habitats. When erosive disturbances occur in the mobile substrate, adhesion reduces the risk of being washed away. This is accomplished by utilizing complex glands on toes or spines that produce sticky mucus. Reinforcing external or internal body structures (armor, spicules, alveolar cushions) are conspicuous features of many meiofauna and are believed to physically protect the body in mobile habitats. Static organs frequently help animals to orientate in the dark, three-dimensional system where eyes and pigments are useless. The minute sizes of meiobenthos as well as their mazelike habitats have prompted parsimonious modes of reproduction: the production of only a few eggs, direct sperm transfer or internal fertilization, brood protection, abbreviated larval life, and restricted propagation complete the array of integrating adaptations common to many meiofauna.

Chapter 5

Meiofauna Taxa: A Systematic Account

Many of the zoological groups belonging to the meiobenthos are omitted in zoology textbooks, or they are commented upon as “small and isolated groups” in a few lines of small print. However, they often represent anatomically fascinating and phylogenetically important taxa. Particularly in the “new animal phylogeny” based on the analysis of gene sequences or whole genomes, small meiobenthic groups such as rotifers, gnathostomulids or tardigrades represent important and much disputed bridging taxa, whose links with larger phylogenetic groups are much disputed (see Jenner 2004; Philippe et al. 2005). In this account, the reader will find freshwater taxa more briefly presented than the marine groups (see Rundle et al. 2002 for more details on the freshwater taxa). In this ecologically oriented overview, phylogenetic discussions will be presented in general features only. My descriptions of meiobenthic taxa (including gross diagnostic aspects and omitting many anatomical details) cannot substitute for reading textbooks or the primary literature. The figures given herein depict only some selected forms and should not be used for more detailed identification. Each paragraph begins with taxonomic data, continues with biological, ecological and distributional comments, and ends with some aspects of relationships and phylogeny.

5.1

Protista (Protoctista)

Though often neglected by zoologists, the sizes and ecological relevances of many unicellular benthic heterotrophs mean that they merit consideration in meiobenthological studies. Since the natural classification of protists is undergoing a great deal of change, the traditional names and groupings are retained here.

5.1.1

Foraminifera (Rhizaria: Granuloreticulosa)

Most foraminiferans belong within the size range of the meiobenthos, although there are numerous species with larger, often solid shells that can attain sizes of up O. Giere, Meiobenthology, 2nd edition, doi: 10.1007/b106489, © Springer-Verlag Berlin Heidelberg 2009

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to 12 cm or more. In total about 34,000 species have been described, and about 4,000 of these recently (Lee 1980b). In both deep-sea bottoms and in shallow reaches, a single sampling campaign can collect 50–60 foraminiferan taxa (Hannah and Rogerson 1997). Some are small symmetrical or snail-shaped, some plait- or ribbon-shaped, and some are disk-like. Others are completely asymmetrical and are hardly recognizable as foraminiferans, and so they have often been overlooked. The multitude of shell shapes is bewildering (see Fig. 5.1). The original organic substance of the shell secreted by the cytoplasm will mostly be more or less completely substituted for calcareous material. The Gromiida and Allogromiida (“atestate foraminiferans”) have delicate or agglutinated soft shells of organic material that are often not recognized to house protists. One of the more conspicuous, filiform foraminiferans that crawls through sand is Marenda (Fig. 4.3), formerly assigned to the Amoebozoa. The affiliation of these groups to the traditional Foraminifera and the derivation of more detailed interspecific phylogenetic relationships are achieved through molecular methods rather than the structural characters of the shells (for a review see Pawlowski 2000). The large species often are heterokaryotic, similar to the Ciliophora (see below), i.e., they have a macro- and

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Fig. 5.1a–d “Morphogroups” of Foraminifera in their typical habitats (based on Jones and Charnock 1985). Morphogroup a (hyperbenthic suspension feeders): 1, Halyphysema; 2, Dendrophyra; 3,5,8, Pelosina; 4,7, Jaculella; 6, Bathysiphon; Morphogroup b (epibenthic, surface-dwelling herbivores, detritivores, omnivores): 1,2, Psammosphaera; 3, Hippocrepina; 4, Ammodiscus; 5, Saccamina; Morphogroup c (endobenthic herbivores and detritivores): 1, Ammobaculites; 2, Miliammina and Quinqueloculina; 3, Textularia; Morphogroup d (phytal herbivores): 1, Trochammina inflata; 2, T. labiosa

5.1 Protista (Protoctista)

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a micronucleus. Many of the disk-shaped epibenthic forms live symbiotically with unicellular algae (Symbiodinium group). They cover the bottoms of shallow waters, where they utilize the sunlight. The biology and ecology of benthic foraminiferans have been recently compiled and reviewed (Sen Gupta 2002). Since their eminent role in the deep-sea benthos (see below) was discovered, foraminiferans have received increasing research attention. Common planktonic drifters are far surpassed in terms of species number by epi- and endobenthic forms in soft sediments. Here they cling to the substratum using their long, often branching pseudopodia (reticulopodia, rhizopodia, see Fig. 5.1). The nonparasitic foraminiferans have been assigned to four “morphogroups” on the basis of life position and feeding habits (see Fig. 5.1; Jones and Charnock 1985). These include the tubular and branching suspension feeders that are semisessile and anchored in an erect position, preferably in more exposed sites of the sediment (Type A), the deposit feeding or (passively) herbivorous epibenthic Type B that occur on more lentic, detritus-rich sediments, the more vagile, endobenthic sand-based detritivores and herbivores (Type C), and the phytal forms that live on phytodetritus or plants (Type D). Foraminifera move slowly by contracting their amazingly large nets of cytoplasmatic appendages that they use to collect algal cells, phytodetritus, bacteria or even small animals for ingestion. Many species are bacterivorous or even ingest small animals (Goldstein and Corliss 1994). They are considered heavy grazers on bacteria and their biofilms (Bernhard and Bowser 1992). In some cases, animals as large as 2–3 cm in size, like cumaceans, caprellids and newly metamorphosed echinoderms, have been found in their cytoplasmic nets. Apparently the prey is immobilized (toxins?) before it is rapidly digested (digestion lasts only one day, even for large prey). The uptake of nutrition seems to be a rather selective process, with some species preferring only certain benthic microalgae (e.g., diatoms), while other epibenthic species are suspension feeders. Most benthic species live in the surface layers, especially the diatom eaters. However, most of them are versatile in microhabitat selection and react to food supply, current exposure or oxygen availability. Many foraminiferans can occur down to 30 cm depth in the sediment, even in oxygen-depleted sediments, where they cluster in the micro-oxic zones around animal burrows (Thomson and Altenbach 1993). They can also live facultatively anaerobic for extended periods of time (Bernhard 1996; Moodley1997 et al. 1997, 1998a,b; Bernhard and Sen Gupta 2002), which may become increasingly relevant as oxygen-depleted areas continue to expand. Both soft-shelled and hard-shelled foraminiferans have been found under permanent anoxia in the Black Sea. Under low-oxygen organic enrichment conditions, a few opportunistic species form a low-diversity, high-abundance community, often with tests that deviate from the common patterns. In near shore, organic-rich sediments the seasonally varying dissolution of the tests due to undersaturation of calcite might influence the population dynamics and impair ecological success of foraminiferans (Green et al. 1998). Many dominant species of foraminiferans are widely distributed and often cross biogeographical barriers. A few species are adapted to brackish water conditions.

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The considerable ecological role of foraminiferans was not assessed until recently because of the difficulties involved in counting them and particularly in reliably separating dead and live forms (see Chap. 3). In the tidal flats of the North Sea, they usually occur at densities of about 700 individuals per 10 cm2 (Ammonia beccari, Chandler 1989) or >1,000 ind. cm−3 sediment (Ellison 1984). Their significance was further underlined by 13C-uptake experiments with foraminiferans (mainly Ammonia) that were fed with diatoms in an intertidal flat (Moodley et al. 2000). They documented the rapid incorporation of algal carbon by foraminifera and their important contribution to the meiofauna. Sandy bottoms on the continental shelf harbored more than 400 individuals per cm3, and 150–200 ind. cm−3 sediment were even found in the deep-sea bottom (Gooday 1986). Gabel (1971) counted >1,000 ind. per g sediment (dry wt) in the northern North Sea, with a decreasing trend towards the south. Although Foraminifera with their net of pseudopodia can densely cover the sea bottom, their share of the productivity and benthic turnover has rarely been quantified. They can dominate the meiofauna, yet in most studies on meiobenthos, which usually only deal with Metazoa, they are neglected. Particularly in the deep-sea (see Sect. 8.3), the overall trophic and productive processes must be reconsidered, since 50–80% of the meiofaunal species and 30% of their biomass can consist of foraminiferans (see Fig. 8.3; Shirayama and Horikoshi 1989). They make a central contribution to the cycling of organic matter in the deep-sea bottom (Larkin et al. 2006). Especially in polar regions, allogromiid and gromiid Foraminifera seem to be common taxa, but their ecological roles are poorly known (Pawlowski et al. 2005). Another group of testate protists with filose pseudopodia that are grouped within Foraminifera or related to them are the Komokiacea (Gooday et al. 2007). They occur in relevant numbers and exhibit species richness on and in deep-sea bottoms, but are widely overlooked during benthos sampling because of their irregular shapes. Small komokiacean species may fall into the meiofauna category (Fig. 5.2), while in others the complex system of branching tubes often coagulates with the sediment such that they resemble larger pebbles or mud balls (“komochki” Russian for a stone or pebble). Their relationship to the Foraminifera is still to be uncovered by molecular methods, their general ecological importance in the deep-sea is probably much higher than acknowledged so far. Another group of strange rhizopod (?) protozoans, the Xenophyophorea of the deep-sea, are sometimes mentioned in context with meiofauna and drew attention due to the accumulation of radionuclides in

Fig. 5.2 Typical komokiacean protist (Edgertonia?) from the deep sea of the North Pacific (4,430 m). (Drawing from photograph, courtesy of T. Radziejewska)

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their cells (Swinbanks and Shirayama 1986). However, since in many species their multinuclear cells attain up to several centimeters in size, they are not detailed here. Foraminiferans may even play a key role in the production of manganese nodules, where they contribute 10% of the outer layer. Granules of manganese and iron are quite common in the cytoplasm of Foraminifera (Mullineaux 1987). Simple Foraminifera flourish even in the deepest oceanic troughs (Todo and Kitazato 2005). More detailed reading: tidal flats, Hofker (1977), Lee and Anderson (1991); North Sea, Rhumbler (1938), Gabel (1971), deep-sea, Gooday (1986), identification (North Sea), Murray (1979); reviews, Murray (1973); Lee (1980b); Sen Gupta (2002).

5.1.2

Heliozoa (Actinopodia)

The traditional taxon Heliozoa is still described in most textbooks as a planktonic group of protozoa. However, the majority of heliozoans (size range with axopodia: 0.1—1 mm) are now considered to be a component of the freshwater micro- and meiobenthos. The brackish and marine heliozoans are morphologically close to the limnetic ones (Mikryukov 2001). Especially in the warmer season, intermittent buoyant (planktonic) phases can be observed, often resulting in blooms—a good example of benthopelagic coupling. Heliozoans live as passive “contact predators,” especially in the unconsolidated surface layers of lentic sands, temporarily attached by their sticky axopodia or by stalks to detritus particles, surficial sand grains and often also to macrophytes. The heliozoan body shape is spherical with prey-capturing axopodia (pseudopodia stiffened by a central axis of microtubules) extending like sunrays from the spherical central body. Specialists consider the group polyphyletic and subdivide it into seven subtaxa with a similar appearance. 80% of all Heliozoa are assigned to the Centroheliozoa, while the other subtaxa are permanently or temporarily stalked. The number of species identified so far is low; many freshwater species seem morphologically identical to marine forms. There are around 15 in the White Sea and 27 in Australia (Mikryukov 2001). Micropredators, they feed on microphytobenthos, ciliates and rarely on small metazoans like gastrotrichs and rotifers. Their species composition seems to depend on the water depth and the presence of macrophytes. In contrast to the prevailing limnetic forms, our knowledge of the marine heliozoa is very limited and based mostly on studies from the White Sea, the Black Sea (Mikryukov 1994, 2001) and from Mediterranean shores (Golemansky 1976; Febvre-Chevalier 1985).

5.1.3

Amoebozoa (“Rhizopoda”): Gymnamoebea, Testacea

Many Amoebozoa fall within the meiobenthic size range and their shells (“testa”) exhibit considerable morphological diversity (15 morphospecies have been found in one sample). Marine species usually have a chitinous organic shell with only a few, fine particles embedded in it (see Golemansky and Todorov 2004), while more sand

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Fig. 5.3 A typical interstitial testate amoebae from upper marine littoral sands. (After Golemansky and Todorov 2004)

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and detritus particles are embedded in the shell in limnetic forms (e.g., Centropyxis). The psammobiotic species are usually particularly small (mostly around 50 µm), and the shell is often flattened. An anchoring device, the sac-shaped shell has a wide circular collar from which the pseudopodia extend. Some lateral or caudal spines (see Fig. 5.3) may help to reduce the risk of suspension. These characters are interpreted as adaptations to interstitial life (Golemansky 1986). About 120 benthic species in 16 genera are described (Todorov and Golemansky 2007). In the warmer season between 10 and 21 (on average) species with 70–175 individuals were encountered per cm3 of sand (maximum 32 spp with 242 ind. cm−3). In these dense populations, psammobiotic testate amoebas represent effective herbivores or passive carnivores. However, they are often disregarded in accounts of meiofauna due to inappropriate sample processing. Since they are mostly euryhaline species they occur preferably in the moist sand above the water line, but others can be encountered subtidally as well. Golemansky (1994) even reported rich populations with about 90 species of interstitial testate amoebae in the brackish shoreline (the “hygropsammal”) of the Black Sea, with some of them also occurring in suboxic sands. More detailed reading: Golemansky (1978, 1994).

5.1.4

Ciliophora (Ciliata)

These heterokaryotic protists (the genome is separated into micro- and macronucleus) are traditionally divided into Holotrichia, Heterotrichia, Hypotrichia etc. These artificial groupings have gradually been substituted for more phylogenetically natural taxa. However, many references still refer to the old classification, with the Karyorelictida being the most primitive ciliate group. However, their primitive position is in doubt (the fact that their 2 n macronucleus is not capable of division appears to be a derived feature). The identification of ciliates is initially based on the inspection of live animals. The diagnostic features of many forms, which are characteristic enough to allow relatively easy identification at the genus level (body shape, ciliation, position of mouth opening), disappear immediately after fixation. However, species determination usually requires that the nuclear apparatus and infraciliation are scrutinized via


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staining procedures. An illustrated key has been developed for the interstitial marine forms (Carey 1992). While estimates of the total number of ciliate species vary (between 3,000 and 8,000), it is assumed that about 1,000 belong to the meiobenthos. About 40 species have been found in 1 cm3 of sandy sediment (Wickham et al. 2000). Benthic habitats harbor more ciliate species than the open water. There are often clear structural correlations between general body shape and size of the pore volume (FauréFremiet 1950). While “euporal” ciliates are apparently rather independent of grain size and occur in both fine and in coarse sediments, “microporal” ciliates populate the interstitial system of fine to medium sands (120–400 µm). Their rather thin pellicles give them high flexibility and their slender, often thread-like or flattened bodies allow them to quickly glide forward despite considerable body length (>3,000 µm). The microporal species avoid sediment agitation. The Karyorelictida are characteristic of this microporal ciliate community with the common family Trachelocercidae (Fig. 5.4). The genera Trachelonema, Tracheloraphis, Geleia, and Remanella occur frequently in the fine-to-medium coastal sands (see Patterson et al. 1989). However, convergent adaptations to an interstitial life (body elongation, flattening, head-like anterior end, formation of a tail shaft, see Sect. 4.1.1) have also developed in the noncaryorelictid genera Condylostoma, Spirostomum, Blepharisma (Heterotrichia). “Mesoporal” species live in coarse sands with pore diameters of 400–1,800 µm, where a thick and sometimes armored pellicle (plates, spines) helps them to survive strong wave exposure. The wide void system allows the small-to-medium-sized, mostly oval-to-slightly-flattened forms (often Hypotrichia) to move in the interstitial water with

Prorodon Frontonia

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Fig. 5.4 Some benthic representatives of characteristic Ciliata. (Various authors)

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sudden jerks of their ventral cirri. They are also able to cling to the grains by adhesive cirri. These mostly hypotrichous ciliates are frequently represented by the genera Aspidisca, Frontonia, Diophrys, Prorodon, Euplotes, Coleps, etc. (Figs. 5.4, 5.5). In sandy sediments several improved enumeration methods (sonication, centrifugation after flotation with Percoll) have been developed which demonstrate that the abundance of ciliates has been greatly underestimated (Epstein 1995; Wickham et al. 2000). Most ciliates occur in medium to fine sands where they can numerically exceed all other animals, even in biomass: tens to hundreds are observed per ml sand (with 1–20 µg fresh weight) or 20 ind. per g sediment (dry weight). With modern methods and under favorable conditions, as many as 2,300–2,500 marine ciliate cells per ml of sand have been recorded in the upper sediment layers (McLachlan 1985; Wickham et al. 2000). Fenchel (1969, 1978) found up to 5,000 ind. under 1 cm2. Figures from Australian sites were clearly less: 12 ind. under 1 cm2 in mangrove mud, 240 ind. under 1 cm2 in fine beach sand, 100 ind. per ml coral reef sand (Moriarty et al. 1985; Alongi 1986). The highest abundance is usually found in sediments with 6,000 specimens of G. jenneri per liter! Gnathostomulids are mostly associated with detritus-rich, hypoxic or slightly sulfidic fine sand like that typically found in sheltered tidal flats, seagrass beds, mangroves, and lower coral reefs. Here they feed on bacteria, fungal hyphae and perhaps diatoms, which they rasp off with their jaws. They reach maximum occurrence in the subsurface horizon near the oxic/sulfidic interface or along the tubes of burrowing macrofauna. However, they have also been encountered in anoxic layers at greater depths. In the permanently sulfidic bottom beneath brine seeps in the Gulf of Mexico they even represented the dominant animal group (Powell and Bright 1981). They were also regular inhabitants of the reduced sand core in pebble-shaped stromatolithic nodules from Bermuda (Westphalen, 1993). As Riedl (1969) put it, in their main environment, fine sediments smelling of hydrogen sulfide, gnathostomulids can “dominate all the other groups of the biotope, even the nematodes.” A remarkable feature in gnathostomulids is the frequent co-occurence of several species in virtually the same patch of sediment. Reise (1981b) found three species along a gradient of a few mm around Arenicola tubes, while Sterrer (1971) counted 13 species in one small sample. The basis of this high syntopic diversity with strong niche partitioning is not known and is contrasted by the amphiatlantic distribution of some common species. The systematic relations of the Gnathostomulida are still disputed (see above). While the jaw apparatus might superficially remind us of some kalyptorhynch turbellarians, the monociliated epidermal cells and the structure of the pharynx musculature clearly set them apart from the plathyhelminths. In any case, Gnathostomulida seems to be a group with a long, phylogenetically isolated history, indicated by the occurrence of cosmopolitan species despite the lack of any effective mechanisms of dispersal, and combined with a high degree of sympatry and a preference for “exotic” biotope conditions. More detailed reading: Riedl (1969); Sterrer (1972); Sterrer et al. (1985); Reise (1981b); Ax (1985); Sørensen et al. (2003, 2006); Jenner (2004).

5.4.2

Rotifera, Rotatoria

With about 1,000 benthic species, Rotifera are a dominant group of the freshwater meiobenthos, whe reas the taxon has been less frequently documented in marine samples. Greatest species richness is in Notammidae (Cephalodella), Lecanidae (Lecane)

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and Dicranophoridae (Dicranophorus) with many mesopsammic species (Segers 2008). There are some 60 marine meiobenthic rotifer genera; most species belong to the genera Encentrum (about 50 spp.), Lecane (about 20 spp.) and Proales (about 15 spp.). Species richness (and sampling effort) seems highest in the Northern hemisphere, while diversity culminates in the warmer regions. The structural diversity of rotifers is remarkable and is used for identification of live samples, at least to the generic level. While they can reach 2 mm in length, the bulk of the group is of meiobenthic size. The smallest rotifers (about 50 µm) easily reach the protozoan size range and represent some of the smallest metazoans. The wheel organ is the distinguishing structure from which the scientific group name is derived. Originally a ciliated plate for creeping and possibly sweeping particles from the substratum, its function has been modified and complicated by the formation of two separate ciliary whirls (resembling a rotating wheel), which produce strong incurrent water eddies for food ingestion. There are two important benthic subgroups (Fig. 5.13): Bdelloidea: Rotatoria, Mniobia, Philodina. These live mostly between mosses; reproduction is a diploid parthenogenesis; there are no males. Monogononta, Ploimida: Trichocerca, Lepadella, Lecane, Proales, Notomma, Notholca, Ploima. Common marine species are members of the genera Encentrum, Trichocerca, Proales. Most meiobenthic forms belong to the Monogononta, which has developed a complex alternation of diploid and haploid stages (see below). The second characteristic of Rotifera (beside the wheel organ) is the pharynx, with its complex cuticularized jaws (trophi) that form a grasping and chewing apparatus, the mastax. The trophi and their muscles are important features for rotifer identification and phylogenetic affiliation (see below). The body is covered by a structurally and chemically specific, flexible, syncytial integument, which can be locally reinforced to form plates (e.g., in Notholca), but is not shed during growth. The animals do not develop collagen. The head with the wheel organ is retractable into the trunk, so that, in fixed samples, this diagnostically important organ is often not visible. The body cavity is not lined with a mesothelium. The saccate body usually tapers into a flexible and eversible foot, which usually ends in a pair of toes. Since it carries adhesive glands, the tail with its toes serves as anchoring organ, but in some species it also participates in a looping locomotion where body contractions and extensions alternate while the wheel organ or the foot is fixed. Rotifers are strictly eutelic. They have about 1,000 cells; their cell number is definite and remains constant after the first 5 h of life when mitosis terminates. The males are short-lived and dwarfed, without intestine. Reproduction in the Monogononta Ploimida is by heterogonous alternation of parthenogenetic summer generations and one bisexual winter generation. Sperm transfer is by injection into the females, and the few eggs are frequently brooded. These diploid winter eggs represent resting stages for overwintering. Convergent with tardigrades and some nematodes, many rotifer species can develop cryptobiotic stages that tolerate desiccation. Ecological aspects. Oligotrophic to mesotrophic lakes with a well developed phytal littoral are favourable habitats for benthic rotifers; they can harbour between

Proales Lindia

Fig. 5.13 Some benthic Rotifera, lengths 0.5–1 mm. (Various authors)

Encentrum

Triphylus

Rattulus Philodina

5.4 Gnathifera 131

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150 to 250 species with a maximum in tropical regions (Segers 2008). A speciose rotifer fauna is also found in slightly acidic, soft waters. Among limnetic meiofauna, rotifers can exceed in abundance not only nematodes, but all other meiofauna (Schmid-Araya 1998; Ricci and Balsamo 2000). Resting stages, together with parthenogenesis, contribute to their ability to quickly colonize and populate new or ephemeral habitats with often drastic population fluctuations. This makes quantitative data such as average rotifer population density (about 100 specimens per 10 cm3 sediment) problematic. In optimal zones, such as the well-oxygenated phytal or detritus-rich and water-saturated sandy shores of lakes, samples contained up to 11,500 ind. per 10 cm3 sediment (Pennak 1940). “Psammobiotic” (Wiszniewski 1934) rotifers have morphological adaptations to an interstitial life: flattened bodies, enlarged adhesive glands, long toes, no pigment and eyes (e.g., many Dicranophoridae). Species less strictly bound to the mesopsammon were termed “psammophilous.” Stygobiotic rotifers live preferably in the groundwater horizons, e.g., Encentrum subterraneum (=Wierzejskiella subterranea), Paradicranophorus (see Sect. 8.7.2). Gravel streams also harbor a rich and diverse rotifer assemblage. In marine habitats there is a marked reduction in rotifer diversity and abundance. About 100 marine species have been recorded, belonging mostly to the genera Lecane, Trichocerca, Lindia, Proales, Lepadella, Testudinella and Colurella. Turner (1993) described between 20 and 790 specimens per 100 cm3 belonging to fifteen species of psammobiotic forms from a marine beach in Florida. Lecane inermis and Colurella salina occurred in particularly high numbers at the high tide mark and in the surface layers (down to about 5 cm). Remane (1949) and Tzschaschel (1979, 1980) often found densities of between 30 and 60 specimens per 100 cm3 in sandy North Sea shores. Also in the marine realm, rotifers seems to occur only in shallow, well-oxygenated sediments (coarse sand, shell hash) and sublittorally down to 300 m water depth. In tidal flats, a reduced oxygen supply can limit their distribution and may explain their preference for the sandy upper subsurface horizons near the highwater mark while the lower reaches and the deeper strata are avoided. In winter, the populations from shallow reaches seem to perform temperature-dependent vertical migrations in somewhat deeper layers. In the void system of Arctic sea ice, close to its lower surface, rotifers seem to be fairly frequent and accounted for > 20% of the overall meiofauna (Gradinger et al. 1999; see Chap. 8.1.1). Other brackish water habitats with fluctuating conditions such as estuaries are also regularly populated by benthic Rotifera. Considering the oxygen demands of most rotifers, the colonization of anoxic and sulfidic deep-sea sediments around gas hydrates and between bacterial mats by new Lecane species is amazing (Sommer et al. 2003). Cyclomorphosis, the regular changes of body form and structure exhibited by some planktonic Rotifera, also occur in some meiobenthic forms (e.g., Mniobia). The adaptive significance of this interesting phenomenon, also described for tardigrades (see Sect. 5.7), remains unclear. Little is known about the nutrition of benthic rotifers. They probably feed on algal cells and protozoans, which they scrape off or grasp using their wheel organ and jaws. Their presence on sea ice suggests that the rich diatom populations are

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utilized. Carnivory has been observed in some planktonic forms. Rotifers are important members of the small food web, particularly as food items for cyclopoid copepods and juvenile fish. Derived, often extreme biological adaptations (cryptobiosis, parthenogenesis) have contributed to the ecological success of rotifers. A phylogenetic relationship to the newly discovered Micrognathozoa seems well founded on the basis of morphological characters (see below), and an affiliation with gnathostomulids is probable. Molecular analyses to scrutinize the validity of the resulting taxon Gnathifera are urgently required. More detailed reading: ecology, Remane (1949); Tzschaschel (1980); Pennak (1951); Ricci and Balsamo (2000) (freshwater); Wiszniewski (1934) (freshwater); taxonomy, Tzschaschel (1979); Voigt and Koste (1978); monograph, mainly anatomy, Clément and Wurdak (1991); phylogeny, Clément (1993); Rieger and Tyler (1995); Kristensen and Funch (2000); identification key, Fontaneto et al. (2008).

5.4.3

Micrognathozoa

Another meiobenthic animal group new to science, the monospecific Micrognathozoa comprising the species Limnognathia maerski was described in 2000 (Kristensen and Funch), although it had been found in Greenland in the late 1970s. The rich moss vegetation of some cold freshwater springs (frozen for most of the year) in a moor outflow harbored many of these tiny animals (about 150 µm long and 55 µm wide), which were initially thought to be rotifers. Some Limnognathia spp. have also been found on the subantarctic Crozet Islands (De Smet 2002). Another discovery of Limnognathia maerski in a cold spring in Wales (Kristensen, pers. comm.) confirms a relationship to cold springs as a preferred habitat. Their characteristic structure is the highly complicated cuticular jaw apparatus, which is ultrastructurally homologous to the jaws of gnathostomulids and rotifers (it consists of microtubular rods). The body is dorsally protected by a set of plates but is ventrally “naked.” The epidermis is cellular, not syncytial. A ventral ciliary field serves as a locomotor organ with which the animals can swim in slow spirals in the moss thicket. Limnognathia frequently adheres to the substrate with its posterior ventral side by means of a sticky pad of cilia that is different in fine structure from the “duo-gland pattern” found in the adhesive toes of rotifers and other adhesive organs. The bipartite head is studded with sensory cilia; long bristles are arranged along the length of the body. The animal bends its thorax like an accordion while moving, and the sack-like abdomen ends in a small tail. Only females have been found, even after long-term rearing in moss cultures, which points to possible parthenogenesis. The two eggs visible in mature specimens have different sizes and structures (winter and summer eggs, like in rotifers). Apart from the complex pharynx and jaw apparatus the digestive tract is rather simple, ending in a periodically opening dorsal anus. The food seems to consist of diatoms and probably also bacteria.

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Kristensen and Funch (2000) suggested from structural evaluation that the Micrognathozoa should be considered the sister group of the Gnathostomulida, an affiliation that was later confirmed by molecular analysis (Kristensen 2002). On the other hand, there are also some affinities with the Rotifera. Altogether Micrognathozoa have been considered a missing link between these groups; their discovery supports the monophyly of the taxon Gnathifera and rejects the assumed sister-group relationship of Gnathostomulida to Plathyhelminthes (Funch and Kristensen 2002; Kristensen 2002).

Box 5.4 Gnathifera: Elusive, Exotic, Extreme Two of the “youngest” animal groups, the Gnathostomulida and the Micrognathozoa, are meiobenthic and assigned to the Gnathifera. They eluded discovery for a long time because of their exotic biotopes: sulfidic sediments (Gnathostomulida) and moor springs in Greenland (Micrognathozoa). In contrast, the third taxon of the Gnathifera, the Rotifera, has been well known since the beginning of microscopy in the seventeenth century. Their extreme character is only revealed by life history studies. Desiccation? No problem, try resistant resting stages. Remote habitats without a sexual partner? Colonize them via air transport and reproduce parthenogenetically. The early cessation of cell cleavage with a defined number and fate of cells adds to these peculiarities. The prime character that unifies these three, rather diverse-looking phyla are their elaborate and conspicuous jaw apparatuses, which are probably homologous. Many questions about these structurally and biologically aberrant meiobenthic forms remain to be answered: Males in Micrognathozoa? Their survival during eight months of frost? Relation of Gnathostomulida to sulphide, their metabolism in sulphidic bottoms that are permanently under a thick brine seep? Complexity of reproductive cycles in Rotifera, triggers that induce meiosis and the change from the diploid to the haploid phase? Adaptive significance of cyclomorphosis in benthic rotifers? - We could therefore add the connotation “enigmatic” to the terms listed in the caption.

5.5

Nemertinea

The whole phylum Nemertinea seems perfectly preadapted to a life as meiobenthos when the size is reduced. This may be why the smallest, meiobenthic representatives among them (about 50 species) have essentially the same organizational pattern as the huge ribbon worms (Fig. 5.14). Many of the typical mesopsammic nemerteans are relatively long (up to several centimeters in length), but are extremely flexible and thin. They are totally ciliated, have a unique ectodermal proboscis that protrudes from a cavity that is involved in locomotion and is lined by mesoderm, a “rhynchocoel.” The proboscis is armed

5.5 Nemertinea

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Oerstedia dorsalis (8 mm) Protostomatella arenicola (8 mm)

Micrura fasciolata (15 mm)

Ototyphlonemertes sp. (8 mm)

Fig. 5.14 Some meiobenthic Nemertinea. (Various authors)

with viscid glands, and, in the order Hoplonemertinea, with stylets used to catch prey. It works independent of the oral opening to grasp prey, similar to kalyptorhynch turbellarians. In some species it is also used as a locomotor organ. In some heteronemertines the head is flanked by two deep lateral slits that form sensory organs. In many meiobenthic nemertines, the head has a pair of anterior statocysts associated with the brain. Nemerteans have a four-lobed cerebral center with a large ventral part. The blood vascular system is closed and numerous pseudosegmental protonephridia and gonads run in long rows along each side of the body. The complicated body musculature allows for extreme flexibility and ever-changing body form and width: nemerteans can contract their body to 1/12 of their length and squeeze through tiny voids. The majority of the meiobenthic species live interstitially in marine sand (30 species) and belong to the class Enopla (i.e., “armed nemerteans”), of which the

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Hoplonemertinea are the main subgroup; these carry stylets at the tip of the proboscis. Characteristic genera from sandy bottoms like Ototyphlonemertes and Arenonemertes clearly demonstrate the adaptations to their interstitial habitat: gliding ciliary movement, sticky areas achieved through numerous epidermal glands, sensory cirri, paired statocysts, formation of a tail (in some species), turgescent chordoid tissues (O. antipai), suppression of the planktonic “Pilidium” larva. There are reductive trends in the cerebral organs, in eye development, in the intestinal diverticula, and in the number of gonads and eggs. Ingole et al. (2005) reported nemertines ranking second after nematodes in muddy deep-sea bottoms with an amazing 11 ind. 10 cm−2. Some nemerteans, most of which belong to the Anopla, lack ocelli, statocysts and any proboscis armature. Their mouths are ventral and they all are of meiobenthic size (the most common genus is Cephalothrix, which has a mouth far posterior to the cephalic tip; other genera are Procephalothrix, Carinina). The rather small species of the Anopla often live epibenthically on/in muddy bottoms. While Ototyphlonemertes (see Fig. 5.14) has a worldwide distribution, other genera like Arenonemertes are only known from a few species of restricted occurrence. Members of Prostoma and Potamonemertes can be considered stygobiotic freshwater forms. Nemerteans are rather insensitive to factors like grain size, oxygen and even food supply. They are voracious predators and also eat carrion, but they can survive long phases of starvation while reducing their body size. Their sluggish, extremely delicate bodies must be handled with great care during investigation. Even the gentlest method, extraction through deterioration of the (oxic) environment when a sediment sample is kept for some time, is not quantitativily effective for this group. Nemertinea is an isolated animal group whose relationships are rather ambiguously discussed, especially its connection with Plathyhelminthes (Garey 2002). Independent molecular studies support a position near the annelids sensu lato (Trochozoa, Spiralia) (Turbeville 2002; Jenner 2004; Petrov and Vladychenskaya 2005). More detailed reading: interstitial species, Gerner (1969); taxonomy, key for interstitial species, Norenburg (1988); phylogeny, Riser 1985, 1989; Jenner (2004).

5.6

Nemathelminthes: A Valid Taxon?

The heterogeneous combination of various animal classes into the phylum Nemathelminthes is probably not a natural, monophyletic unit. Therefore, nemathelminths are often considered to comprise independent phyla, which are probably unified through a common evolutionary trend for dwarfism, but differ in terms of varying reductive phases of coelom formation. In some nematodes, priapulids and gastrotrichs, the body cavity is completely lined with a mesodermal coelothel, i.e., a coelom is present in the cases studied. In other forms this mesothelium is absent, incomplete or reduced. Subsequently, the body cavity has been characterized as a “pseudocoelom” and nemathelminths have also been termed “pseudocoelomates”

5.6 Nemathelminthes: A Valid Taxon?

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in some textbooks. In many groups, the body cavity is reduced and is more or less densely packed with the inner organs (numerous nematodes and gastrotrichs); in others it is spacious and filled only with body fluids and some mesenchymatous cells (kinorhynchs, priapulids). A new phylogenetic concept is to group together large taxa that have an acellular, often chitinous cuticle that is molted: The Arthropoda and some of the former nemathelminth phyla (nematodes, kinorhynchs, loriciferans, priapulids) represent the supertaxon “Ecdysozoa.” This grouping, which breaks up the traditional taxa Nemathelminthes and Articulata, is based on molecular analyses (18S rRNA and Hox gene studies) as well as chemical signatures. It has received increasing molecular support recently (Zrzavy 2001, Garey 2002, Giribet 2003, Philippe et al. 2005, Mallat and Giribet 2006, Petrov and Vladychenskaya 2006). Accordingly, the gastrotrichs, which lack chitin, would be separated from the Ecdysozoa, a position again supported by cladistic and DNA analyses. However, the Ecdysozoa hypothesis has been rejected by some zoologists, who contend that it lacks support from homologous morphological characters and paleontological evidence (see Wägele and Misof 2001). In other (morphologically based) concepts, nemathelminths are split with regard to the presence of a retractable anterior body part (introvert) or vestiges thereof (“Introverta:” Nematoda, Kinorhyncha, Loricifera, Priapulida), or with regard to the body armature of spiny plates or scales (“Scalidophora:” Priapulida, Kinorhyncha, Loricifera). The latter grouping has recently been shown to be doubtful on the basis of detailed molecular analyses of several loriciferan species (Sørensen et al. 2008). Since the positioning is so controversial and the molecular information is still ambiguous, “Nemathelminthes” is retained in this nonphylogenetic treatise, but the reader should be open for this exciting new phylogenetic debate in which the role of progenetic trends should be scrutinized. The free-living nemathelminths are nonsegmented, bilateral animals, mostly with a mouth and an anus, and often with a complex cuticular lining covering the epidermis. In the Scalidophora the cuticle contains chitin. Direct development after internal fertilization of the gonochoristic species prevails. There is a trend towards a defined and fixed cell number (eutelic development) with little regenerative potential. Asexual development is not known, but parthenogenesis occurs in some taxa (e.g., in Loricifera).

5.6.1

Nematoda (Free-Living)

The most frequent metazoans, nematodes usually dominate each meiofaunal sample both in abundance and biomass. Many free-living nematodes are of meiobenthic size; however, numerous undescribed nematodes in the deep-sea are macrobenthic reach the macrobenthic size range (Lambshead, pers. commun.). Most meiobenthic nematodes are 0.5–3 mm long, the smallest being 0.2 mm; their lengths are 20–40 times their width. In terms of their general body structure many features pre-adapt them to living in sands and muds. Nematodes occur in all substrates,

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sediments, climatic zones and water depths. 80–95% of the individuals and 50–90% of the biomass of meiobenthos usually consists of nematodes (Fig. 5.15a,b). Each square meter of sea floor is populated by 1–12 million nematodes (Heip et al. 1985a; Soetaert et al. 1995). Correspondingly high densities are found in freshwater biotopes, especially in the littorals of lakes (Traunspurger 2002). About 4,000–5,000 species of free-living marine and about 11,000–20,000 nematode species have been described in total so far. Records of nominal nematode species differ much; about 20,000 free-living species have been described, the vast majority (90%) living in marine habitats (Eyualem-Abebe et al. 2008). Some researchers consider nematodes a “hyperdiverse” taxon with > 1 million species, while others doubt this estimate (Lambshead and Boucher 2003). Even if about 100,000 species is assumed to be a realistic guess (Coomans 2000), completely

% others ⬙Turbellaria Harpacticoida Nematoda

80

60

40 20

Feb.

a

Jul. 1978

Dec.

% others Gastrotrichs Kinorhynchs Ostracods Polychaetes Nauplii Copepods Nematodes

80 60 40 20

Dec. Feb.

b

Jun. 1997

Dec.

Apr. 1998

Fig. 5.15 a–b Dominance of nematodes among meiofaunal groups, as indicated by their relative abundance. a From the shallow sublittoral of the Belgian North Sea coast; b from deep-sea mud. (a After Herman et al. 1985; b compiled from Shimanaga et al. 2000)


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describing them all would be an utopian task considering the number of specialists required. The marine biotopes around the British Isles alone harbor 41 nematode families with 450 species. Another estimate for the North Sea sediments is 800 species, and 1,625 species have been recorded in European seas (Costello et al. 2006). In meiofaunal samples, the number of species of nematodes often exceeds that of all the other groups put together by an order of magnitude. Therefore, 100 cm3 of shallow-water sand may contain 20 species. In deep-sea sediments, where the species richness is spectacularly high, this number can even be higher. “Contrary to popular opinion, marine nematodes do not all look the same and it is time that this myth was finally put to rest” (Platt and Warwick 1980). The eminent and diverse ecological importance of nematodes was only realized when their undifferentiated treatment as a huge but hardly identifiable bulk taxon was abandoned. The recent increase in meiofaunal studies with more detailed nematode analyses led to a more realistic assessment of their ecological role. This is in part the result of better identification media, techniques and training workshops. Today, valuable illustrated keys and databases are available (Platt and Warwick 1983, 1988, Warwick et al. 1998; Vandepitte et al. 2008). Several electronic keys have been designed specifically for nematodes (Tarjan and Keppner 1999; Deprez 2006. These demonstrate that it is not so much a lack of valid and conspicuous diagnostic features that deters meiobenthologists from dealing with nematodes, but rather their exorbitant species richness and often tiny sizes. Identification of meiobenthic nematodes is based mainly on characters that are visible without dissection, but this requires a good compound microscope (“Nomarski” interference contrast is very helpful). The general body and tail forms of nematodes are by no means uniform (which is often supposed; see Fig. 5.16). Together with marked buccal cavity differences (see below), this allows the spectacular species richness to be broken down into large groups as a first step towards taxonomic ordination.

5.6.1.1 Taxonomy and Systematics Taxonomically relevant external features are: tail shape and spicular apparatus, numbers and arrangements of sensory setae (particularly around the head), of caudal glands and of gonads, the positions and shapes of amphids (paired anterior chemical sense organs), and epicuticular structures (e.g., annulation). The most important internal features are the shape and cuticularization of the buccal cavity, the structure of the genital organs, and sperm morphology. In some taxa the general body shape and its external cuticle is of diagnostic value (e.g., some Chromadoridae, Desmoscolecida, Draconematidae and Epsilonematinae; see Fig. 5.16), while in most nematode groups the body is rather uniform, with the anterior end more truncated and the posterior end slender; in males this merges into an inflected tip. Thistle et al. (1995) assert that for deep-sea nematodes the tail shape in combination with the buccal armature yields a promising analytical tool for future work. The scope of this book only allows to mention a few more comprehensive higher taxa and some extraordinary species. For more details, perusal of the original

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50 µm

200 µm 500 µm

Eubostrichus 100 µm

Desmoscolex

50 µm Paramonohystera

50 µm

Eleutherolaimus (front end)

200 µm

Draconema Echinotheristus

Fig. 5.16

Metepsilonema

Various Nematoda of different appearance. (Various authors)

literature is recommended. An earlier taxonomic division into two subgroups, the Adenophorea and the Secernentea were confirmed in the system of Lorenzen (1994). Since most of the pertinent (ecological) meiobenthic literature is still based on this classification, these categories are used here too. While Kampfer et al. (1998) maintain that Adenophorea is monophyletic, other specialists reject the monophyly of this taxon and suggest a division of Nematoda into two classes, Enoplea and Chromadorea (Coomans 2000). With increasing molecular studies (> 200 taxa now analyzed) this general division was confirmed (De Ley and Blaxter 2004) and maintained after the addition of numerous marine species to the analysis (Meldal et al. 2007). This would suggest that the long-standing and widely adopted divison of nematodes into “Adenophorea” and “Secernentea” should be abandoned. Yet the systematics of the Nematoda have undergone further changes and even the major taxa are still not stable or generally recognized. Among the Chromadorea, a cluster termed the “Rhabditida” has been resolved (this was previously the “Secernentea”). At least Monhysterida, Chromadorida and Desmodorida seem monophyletic (Litvaitis et al. 2000). Recent overviews of


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the phylogenetic relationships of nematodes are given by De Ley et al. (2006) and Meldal et al. (2007). Since even nematode orders are far from stable, we need more genetic, morphological and ultrastructural details to further resolve the natural phylogenetic units in nematodes. Complete genomic deciphering of two Caenorhabditis species demonstrated the high variability of the genetic background, even in closely related nematodes. Only 35–70% of the genome is similar to other nematodes (Parkinson et al. 2004), underlining the exhaustive genetic diversity in this phylum. It also underlines the urgency with which further genetic analyses for use in the systematics of lower nematode taxa are required. As the work of Derycke et al. (2005, 2007a, 2008) has illustrated, there is high intraspecific allelic and genetic variance with considerable local differences. These may be valuable for ecological population studies but they are misleading in taxonomic research using molecular methods. As yet, there is a huge gap in this promising field that can hopefully be tackled using new fixation methods that yield morphological descriptions and genetic identification for the same specimen (Bhadury et al. 2005). Adenophorea: Setae and adhesive glands are present, amphids are conspicuous. Most meiobenthic nematodes belong to this subgroup. Mostly from marine and brackish water sites, but some 400 species of various families are also limnetic and even stygobiotic (mainly Dorylaimida, Tobrilidae, Monhysteridae, Desmoscolecidae, Xyalidae: Theristus). Important orders with numerous genera and species include the Monhysterida, Chromadorida, Enoplida and Trefusiida. The family Desmoscolecidae sometimes also takes ordinal rank as Desmoscolecina. Trichodorus, Tripyla and Onchulidae, with their soft cuticles and aberrant spicular apparatuses, are considered primitive taxa. Secernentea: No setae and adhesive glands, amphids are much reduced. Within the scope of this book, this taxon is of less relevance, since it contains the bulk of terrestrial, or parasitic and pathogenic forms. Among the meiobenthic forms there are those limnic groups that prefer a certain degree of organic pollution (Rhabditidae, Diplogasteridae). Only a few species of “halophilic” Secernentea occur in biotopes of marine shores, albeit often in large numbers (e.g., Pellioditis, Rhabditis marina).

5.6.1.2

Biological Aspects

Nematodes lie normally on their side and move, in the absence of circular muscles, in their natural environment by alternating contractions of their longitudinal musculature in a characteristic dorso-ventral bending action. In conjunction with the surrounding sediment this results in a somewhat snake-like, writhing motion performed at a relatively high speed (Cullen 1973). Despite the fact that they are mostly small in size, this motion pushes them along at some 15 cm per minute. The contractions increase the internal turgor and cause pressure waves to run along the body. In flocculent sediments biostabilization through mucus secretion may render wriggling movements more efficient (Riemann 1995). Some species

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can jerkily “jump” by rapidly bending their bodies with subsequent sudden relaxation (e.g., in Theristus). Only the structurally aberrant Epsilonematidae and Draconematidae move by “looping,” which involves alternatively adhering and detaching their mouths and tail regions (see Fig. 4.8). Desmoscolecidae move by “contractive waves.” Under artificial conditions, when performed in a drop of water under the microscope, nematode movement is rather awkward and helpless wriggling up and down. Although about 45% of all adenophoran nematodes are interstitial, there are not many morphological features that occur regularly in mesopsammic species and can be ascribed to the mesopsammic life, although their functions are often not clear (Lorenzen 1986): a strongly bent tail with adhesive glands, additional adhesive organs (e.g., in Epsilonematidae), a flexible, tapering “neck” region, extremely long setae (Thrichotheristus), aberrant positions of amphids (Epsilonematidae), flattened body (rare, e.g., Neochromadora angelica). Life history. Complete life tables of nematodes are known for just a few species. The following data refer mainly to the ecological review of Heip et al. (1985): Within a small sample, species with a generation cycle of a few days can co-occur with others that need an entire year to complete their generation cycle, making generalizations about “the typical nematode” problematic. For a realistic assessment of their production and ecological relevance, complete life history studies on more nematodes species (e.g., on Chromadorina germanica by Tietjen and Lee 1977; Chromadorita tenuis by Jensen 1983) are needed and can be expected with the increasing ability to cultivate nematode species (Moens and Vincx 1998). Adult females usually produce between 10 and 50 eggs, and after hatching the juveniles undergo four molts before reaching maturity. All cuticular structures (and the armature of the buccal cavity) are shed with each molt. Growth continues after the last molt. The average nematode has a fresh weight of 1 µg. Generation time is mostly between 13 and 60 days, resulting in 4–10 annual generations (however, there is also a species with a generation time of just 3 days—Pellioditis marina—and others with only one reproductive period per year!). The high production of nematodes contrasts with their rather low biomass; the annual P/B ratio is about 8–10 (see Sect. 9.3.2). While marine nematodes reproduce by bisexual amphimixis, in freshwater habitats obligate or facultative parthenogenetic or hermaphroditic development of nematodes has repeatedly been reported (for details see Nicholas 1984), with populations consisting either exclusively (e.g., Chronogaster spp.) or predominantly (e.g. Eumonhystera spp.) of females. For more detailed life history data on freshwater nematodes, see Traunspurger (2002) and Bergtold and Traunspurger (2006). For those who can read Russian, the monograph on the biology of marine nematodes by Chesunov (2006) is recommended.

5.6.1.3

Ecological Aspects

Wieser (1953, 1959), in his seminal papers on the ecology of nematodes from European and American littoral coasts, was the first who found a relation between community structure, sediment granulometry and trophic guilds expressed in the cuticular armatures of the nematode’s buccal cavity (Fig. 5.17).


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FINE SAND, RICH ORGANIC CONTENT

COARSE SAND, LOW ORGANIC CONTENT

Carnivores, omnivores, epistrate feeders

SHELTERED OR EXPOSED PHYTAL

Epistrate feeders, omnivores, selective deposit feeders

Selective and non-selective deposit feeders, carnivores

Deposit feeders, often non-selective MUD, SILTY SAND

Fig. 5.17 Trophic guilds of nematodes from various tidal habitats based on different mouth structures. (After Wieser 1953 and other authors)

1. In mostly homogeneous muds and fine sand, nonselective deposit feeders with a well developed but weakly cuticularized buccal cavity prevail. Food particles, often larger bacteria, detritus and diatom cells, are taken up using the lips and the anterior buccal cavity. 2. In more heterogeneous (fine) sandy substrates, selective or nonselective deposit feeders with a small or vestigial non-cuticularized buccal cavity are found. Their food particles (bacteria, small detritus) are soft and mostly obtained by suction of the muscular pharynx. 3. In sand with more microhabitats epigrowth feeders prevail. They scrape off the (algal) surfaces of grains or pierce single cells. Hard cuticular ridges for scooping or pointed tips for piercing are well developed in the narrow buccal cavity. Coarser sandy sediments contain mainly predators and omnivores with large and powerful pointed teeth and lancets as buccal armature; their buccal cavities are wide. 4. The exposed phytal is dominated by algivores and predators/omnivores. In more sheltered algal sites an increasing number of epigrowth feeders and selective deposit feeders scrape off and pick up particles (epigrowth and detritus) from the thalli of the plants.

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Given the huge number of nematode species, it is not surprising that all trophic resources are utilized, but it has become increasingly clear that many species originally considered generalists are actually specialized feeders with a high rate of trophic niche partitioning. Wieser’s (1953, 1959) allocation of (marine) nematodes into four trophic groups was developed under distributional aspects and was intended to serve as a practical way of defining communities. It is this simplification that makes Wieser’s classification applicable to nematode studies from many other areas (e.g., Ott 1972a; Kennedy 1994a). Of course, this grouping had to be refined to meet the requirements of local nematode populations (Joint et al. 1982; Jensen 1987a; Romeyn and Bouwman 1983). A modified classification with ciliate feeders as a separate group was introduced by Moens and Vincx (1997a) for the nematode fauna of estuarine tidal flats (Fig. 5.18). To complicate the situation, the variability of buccal structures also depends on ontogenetic age (Lorenzen 2000). Moreover, when assigning nematodes to feeding groups it is important to consider

Facultative predators

Microvores

Ciliate feeders

Predators

Deposit feeders

Epigrowth feeders

Fig. 5.18 A modified categorization of the nematode feeding groups from estuarine tidal flats. (After Moens and Vincx 1997a)


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that many opportunistic nematodes can switch their feeding mode in response to the food available. Today, there is substantial evidence that, due to their restricted capacity for proteolytic nutrient digestion, nematodes are mostly selective feeders. The high syntopic diversity of nematode species has been interpreted as being a consequence of this highly developed food partitioning. They can selectively differentiate between prey organisms, and even between bacteria (Moens et al. 1999b), which seem to be the main nutritive source for the group, especially in the deep-sea. The worms accelerate bacterial digestion, secreting bactericidal lysozymes (beta-glucoronidase) which dissolve the thick cell walls (Tietjen and Lee 1977). The bacterial symbiotic Stilbonematinae live exclusively on their own epicuticular “bacterial kitchengardens” (review: Ott et al. 2004). Aggregations of bacteria on decaying carrion or plant debris strongly attract nematodes. When (bacterivorous) nematodes were added to decomposing wrack, degradation times were significantly reduced. This detritus was then the preferred food of macrobenthic polychaetes (Tenore et al. 1977b; Rieper-Kirchner 1989). The mucus secretions that nematodes leave in their trails stimulate and/or modify bacterial growth (the gardening hypothesis, Riemann and Schrage 1978; Jensen 1996; Moens et al. 2005; freshwater: Traunspurger et al. 1997). The secretions seem to have enzymatic effects on refractory polysaccharides such as cellulose (Riemann and Helmke 2002). The mucus-lined fine nematode burrows modify the microtexture and thus the microclimate in the sediment (Cullen 1973; Fenchel 1996) and in biofilms (Mathieu et al. 2007). The rather stable tubes of Ptycholaimellus increased the aeration of the deeper layers, modified the depth of the oxic/anoxic interface, and influenced the occurrence of other meiofauna (Nehring et al. 1990). It has repeatedly been pointed out that nematodes take up considerable amounts of dissolved/lysed substances that are not discernible in the intestine (e.g., Adoncholaimus fuscus, Moens et al. 1999c; see also Moens et al. 2006). This mode of nutrition is of obvious relevance in the gutless genera Astomonema and Rhabtothyreus. Odor compounds produced by biofilms have also been shown to act attractively on nematodes (Höckelmann et al. 2004). For freshwater nematodes Traunspurger (1997b) developed a tropho-ecologically based classification which is probably also applicable to marine and terrestrial species. He discerned four categories: 1. Swallowers (deposit feeders) without teeth feeding on whole protists 2. Epistrate feeders that use a small tooth to tear and swallow protists and microalgae 3. Chewers with a wide and sclerotized buccal cavity (the traditional omnivores/ predators) 4. Suction feeders with a stylet apparatus that suck plants, fungi and animals Studying several trophically different lakes in Germany demonstrated the wide applicability of this classification (Moens et al. 2006, Fig. 5.19 ) In consumption experiments with tidal flat nematodes, microalgae were preferred over bacteria (Pascal et al. 2008). Especially in tidal flats, many diatom-eating nematodes

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graze on the rich stock of microphytobenthos (Montagna 1995; Santos and SouzaSantos; 1995; Riera et al. 1996; Moens and Vincx 1997a; Middelburg et al. 2000), crushing the silica shells of diatoms with specialized mouth parts (Fig. 5.20). Here, more than 30% of the nematodes represented microalgal grazers that actively migrated to their favorite food patches, creating a dynamic and irregular distribution pattern (Moens et al. 1999a) that is different from the small-scale distribution created by DOM users (Blome et al. 1999). Not only buccal structures, but also the general morphometrics of nematodes such as the width/length ratio and the general body mass, seem to be influenced by the availability and type of food and to be related to the feeding type. A granulometric influence on nematode morphometrics is also widely discussed, as are other factors such as hydrodynamics (erosion) or oxygen availability. Microvores tend to have a small width/length ratio (slender worms), while greater ratios defined predators and epigrowth feeders (Tita et al. 1999). The predatory taxa prevailing in medium-to-coarse sands are usually robust (e.g., Desmodoridae) and often have well-sculptured cuticles and long setae (Draconematidae, Epsilonematidae and Desmoscolecida, Fig. 5.16). Thus, stout, bulky nematodes seem to be characteristic of shallow sandy sites and the uppermost centimeters with good oxygen availability. However, on sand banks with high wave exposure Vanaverbecke et al. (2007) noticed a trend towards longer bodies, which perhaps prevents suspension. Similarly ambiguous are the trends in finer sediments. The nematodes generally become smaller and more slender in barely exposed finer sediments (Udalov et al. 2005).

100

Königssee (oligotrophic)

80

Obersee (eutrophic) 60

40

20

0 %

Swallowers

Epistrate feeders

Chewers

Suction feeders

Fig. 5.19 Relative distributions of nematode feeding types (Traunspurger classification) in the littoral of two ecologically different lakes. (After Moens et al. 2006)


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Hypodontolaimus balticus Fig. 5.20 a–b Ingestion of benthic diatoms by specialized nematodes. a Mouthparts breaking the shells open; b Mouthparts piercing the shells and sucking the contents out. (After v. Thun 1968)

The few typical mud inhabitants are mostly small and have short setae (e.g., Sabatieria pulchra). On the other hand, Tita et al. (1999) recorded that the average body width and biomass of nematodes were higher in mud than in sand, resulting in a higher calculated respiration. Soetaert et al. (2002) contended that nematode body length increases when the sediments become little permeable and more cohesive. This is perhaps related to organic matter, but probably also to oxygen supply. The typical thiobiotic species from “sulfide layers” (see Sect. 8.4.2) has a long, slender and sluggish body with a thin cuticle (Linhomoeidae, Molgolaimidae). This longer and more slender shape has been interpreted as enabling higher mobility, facilitating effective vertical migrations; other advantages of a slender body may be the enhanced transepidermal uptake of oxygen and dissolved food. Referring to oxygen and hydrogen sulfide, Ott separated already in 1972 the nematode community of an American salt marsh into four associations. With increasing water depth, food limitation seems to become the decisive factor and causes a decrease in the size spectrum in deep-sea nematodes compared to shallow-water species (Thiel 1975; Udalov et al. 2005). In contrast, a shift towards larger sizes has been recorded in deep-sea nematode communities from Antarctic regions. The prevailing low temperatures have been put forward as the reason for this contradictory evidence, and so it may be only a local phenomenon (De Broyer

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et al. 2001, see Sect. 8.3). In the deep-sea, tail shape (rounded/conical/long, clavate) has been found to be another convenient parameter that significantly indicates differences between nematode communities from energetically different sites (Thistle et al. 1995a). Summarizing, a combination of feeding group with some additional morphometric and granulometric characteristics can probably be related to distinct nematode communities from different biotopes, depths and geographic ranges (Warwick and Gee 1984; Vanreusel 1990; Vincx et al. 1990; Gheskiere et al. 2005; Schratzberger et al. 2004). Schratzberger et al. (2007a) analyzed nematode community functions and combined a set of selected morphological features (body size, and shape, buccal structure, tail shape) with known biological traits. Assigning these functional groups is perhaps the most informative system used to connect the diverse biological requirements of nematodes with the functional dynamics of the community. Median grain size, silt content, and water depth were found to be attributes relevant to functional grouping. Nicholas et al. (1991) related the pattern of nutritive guilds of mangrove nematodes to the shore profile and the emersion gradient: epistrate and diatom feeders prevailed in the low tide zone, mostly selective microbial feeders were found in the higher mangrove zone, while the sediments above high water neap were dominated by omnivores, predators and plant root feeders. Kennedy (1994b) compared the relative roles of the four main nematode feeding types in a sandy and a muddy site respectively from the Exe Estuary in England (Fig. 5.21): omnivores/predators, although of subordinate abundance, dominated in biomass and production in the sandy site, while deposit feeders prevailed in density and in biomass or production in the muddy site. Focusing on the carbon production (Fig. 5.22, more than 50% was consumed by nonselective deposit feeders in the muddy site, while omnivores/predators assumed this prevailing role in the sandy site. There was even a clear differentiation among deposit feeders, with surface species preferring fresh organic matter while deeper dwelling species devoured older material.

5.6.1.4 Biodiversity The higher the degree of habitat microstructure, the richer the nematode community. Heterogeneous, fine sands in shallow sea bottoms with a rich food supply and an interstitial system that provides enough solute and oxygen transport harbor the highest number of species; about 100 species per investigation area are not unusual. As the amount of silt and organic content increases the occurrence of many stenotopic nematode species in the sediment is limited, and so the diversity tends to decrease. More eurytopic species show an affinity for silty or inhomogeneous sediments. As with other taxa, nematode biodiversity in the deep-sea is amazingly high and has not been satisfactorily explained (Packer et al. 2006; see Sect. 8.3). Extreme habitats such as wave-beaten beaches, hadal troughs or sulfidic muds with more homogeneous sediment structures and low organic contents are often popu-

5.6 Nemathelminthes: A Valid Taxon? 80 70 60 50 40 30 20 10 0 %

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Abundance Mud site Sand site

Deposit feeders

60

Epigrowth feeders Omnivores/Predators

Biomass

50 40 30 20 10 0 %

Deposit feeders


60

Production

50 40 30 20 10 0 %

Deposit feeders


Fig. 5.21 Relationship of nematode feeding type to mud and sand sites in the Exe Estuary. (After Kennedy 1994b)

lated by a rather monotonous community of characteristic specialists (Vincx et al. 1990). Strangely enough, some specialists from shallow sandy sediments (Epsilonematidae, Draconematidae) are often also characteristic of deep-sea sites. In a study from the sublittoral of subantarctic regions, deposit feeders prevailed while epistrate feeders were always frequent (Vanhove et al. 2000). As predicted by trophodynamic models, the diversity decreases upon nutrient depletion as a result of increased competition. Conversely, both density and diversity of selective deposit- and epistrate-feeding nematodes increased in the Belgian shelf area after phytoplankton blooms (Vanaverbeke et al. 2004). Boucher (1990) searched for factors determining the diversity patterns of sublittoral nematode assemblages, and concluded from a comprehensive evaluation of literature data that sediment

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MUD SITE

1.5 % Selective deposit feeders

1.1 %

SAND SITE

7.04 g C x m-2 yr-1

55.9 % Non-selective deposit feeders

16.1 %

14.8 %

27.8 %

Epigrowth feeders

Omnivores / Predators

25.1 %

57.4 %

5.42 g C x m-2 yr-1

Fig. 5.22 Partitioning of carbon consumption among nematode feeding groups in mud and sand sites of the Exe Estuary, England. (After Kennedy 1994b).

granulometry or trophic differences alone could not be the only factors responsible, since samples from muddy and sandy sediments did not differ significantly in their species richness and Shannon–Weaner index. It seems that local or large-scale biotopical factors, e.g., salinity gradients or pollution, are additionally modulating the distributional pattern (Vanreusel 1990, 1991; Bouchet and Lambshead 1995). Nematode abundance and biomass is largely correlated with food supply, and often with bacterial density. However, trophic studies in a tidal mudflat revealed that nematodes selectively preferred microalgae to bacterial food (Pascal et al. 2008). This would explain why shallow flats rich in organics seem to attain highest abundances. In North Sea flats among others, abundances of >15×106 m−2 have been found,


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decreasing towards the sublittoral to about 1 × 106 m−2. In the deep-sea, considerably lower values (around 1 × 104 m−2) have been recorded (Sect. 8.3). Densities in favorable freshwater habitats reach the highest values reported from marine habitats (see Traunspurger 2002; Michiels and Traunspurger 2005). In many limnetic ecosystems (e.g., in lakes), nematodes can contribute 50% or more to the total meiobenthic production, providing more evidence of their salient ecological role. The intensive taxonomic radiation and trophic differentiation of nematodes already indicates a distribution pattern with many local and seasonal variations. From the shallow sublittoral towards the deeper bottoms of the continental shelf, nematodes decrease only slightly in abundance. There is also only a slight reduction in nematode dominance towards the eulittoral. The same is true for the nematode occurrence along the salinity profile in estuarine waters (Soetaert et al. 1995). Apparently, among the high number of species there are enough generalists and specialists for each combination of factors to compensate for those nematodes that drop out (cf. Riemann 1966).

5.6.1.5 Vertical Distribution A community of “epibenthic” nematodes can be found on coral fragments or plant blades that consists of highly specialized and rare taxa. However, in sediments the majority of nematodes aggregate in the uppermost few centimeters, with diatom feeders (Spilophorella, Ptycholaimellus) at the very surface. The vertical decrease in abundance/diversity is highly dependent on the oxygen supply: well-oxygenated sands of exposed beaches can be populated by nematodes down to a depth of 1 m! In muds, which have steep oxygen gradients, the bulk of nematodes live in the uppermost few centimeters. However, specialized nematodes can be found even beneath a well-developed oxycline. In deeper shelf and canyon bottoms, more than 50% of all nematodes occurred in the anoxic layers (Soetaert et al. 2002). The presence of a distinct nematode community in these layers (Ott 1972), specialized in many ways to living under sulfide-dominated conditions, has been widely reported (see Sect. 8.4.2). Stilbonematinae (Chromadoridae) and the gutless Astomonema live in symbiosis with “sulfur bacteria” (Ott 1993; Musat et al. 2007); but the aposymbiotic Linhomoeidae, Siphonolaimus, Cyatholaimus, Terschellingia longicaudata, Monhystera disjuncta, Sabatieria pulchra and some deep-sea Epsilonematidae also have their highest abundances around or beneath this chemocline. Also, the bacterivorous limnetic taxa (Tobrilus spp., Chronogaster troglodytes, Poikilolaimus sp.) seem to thrive preferentially at the food-rich oxic/sulfidic interface. Paramonohystera wieseri from anoxic depths has been experimentally shown to survive extremes of temperature better under anoxia than in normoxic conditions, and is termed “obligate anaerobic” (Wieser et al. 1974). Various deep-sea epsilonematid species populate the muds of the suboxic upwelling zone off Peru (Decraemer et al. 2005). Eudorylaimus andrassy lives in oxygen-free zones of Lake Tiberias (Israel) for eight months each year and can survive being placed in a sealed jar

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with completely anoxic sediment for six months (Por and Masry 1968). Theristus anoxybioticus performs a unique biotopic change from the oxic surface to deep anoxic layers during its lifetime: adults live in the upper centimeters of muds of methanic seepage sediments in the Kattegatt (Denmark), while their juveniles migrate into the anoxic subsurface layers (Jensen 1995). Vertical distributions may vary, and many nematodes migrate diurnally or seasonally, often depending on the oxygen availability or tidal cycles (Hendelberg and Jensen 1993). Jensen (1984a) suggested that in Finnish waters low temperatures indirectly influence the vertical distribution of epigrowth-feeding phytal nematodes: the animals change to a bottom-dwelling lifestyle when their habitat, the algal canopy, is destroyed by ice. They leave the sea bottom again when the vegetation starts growing in spring. A substrate-mediated and food-influenced annual growth cycle was also found by Novak (1989) for the nematode fauna of a Mediterranean seagrass area, reflecting the growth cycle of the plants. Alongi (1990a) confirmed a food-mediated seasonal change in nematode dominance: deposit feeders and predators dominated during the cooler months of fall and winter, while epigrowth feeders were most frequent in spring and summer. Steyaert et al. (2001) found a species-specific and highly dynamic vertical migration pattern controlled by the tidal rhythm and requiring particular sampling methods and species analyses. Phytal nematodes living on macrophytes in the Black Sea demonstrated a diurnal vertical cycle: during the daytime they lived on the thalli, and they entered the bottom at night (Kolesnikova et al. 1995). Reports on the role of nematodes as a nutritional source for macrofauna are rare. In tidal flats, young Carcinus feed intensively on the larger nematodes, e.g., Enoploides and Adoncholaimus. The latter, in turn, is necrophagous and is attracted by decomposing macrofauna. Small crustaceans, fish and carnivorous polychaetes feed on nematodes; for some small fish they are even the dominant prey (Feller and Coull 1995; Colombini et al. 1996) (see Sect. 9.4.2). Typically, however, a good proportion of the nematode biomass does not seem to be transferred to macrofaunal levels. Nematodes are linked to other meiobenthos through the omnivore/predator group, but the bulk of the detritivores seem more integrated into the short trophic loops of decomposers (see Sect. 9.4.1). The high species number of nematodes, even within small samples, makes them good indicators of disturbance- and pollution-induced changes, provided that detailed identification is feasible. Heip and Decraemer (1974) could relate a local decrease in diversity with the efflux of polluted river water. Conversely, after recovery from years of pollution, abundance, particularly that of species indicating organic enrichment, decreased, while diversity increased (Essink and Romeyn 1994). However, natural changes like sediment structure, oxygen supply, temperature, etc., may interfere and thus complicate such an interpretation of diversity indices. To further scrutinize this interrelationship, Schratzberger and Warwick (1998a,b) performed microcosm experiments with whole meiofaunal communities, comparing the reactions of the nematode assemblage to physical and eutrophication. A thorough statistical evaluation discriminated the community reaction: that in exposed sands was more resilient to physical disturbance than that from sheltered


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muds. Following the “intermediate disturbance hypothesis” (Connell and Slatyer 1977), the nematodes from mobile sands were said to be more adapted to physical disturbances (of limited intensity) than those from muds. On the other hand, the nematode assemblage in muddy sediments reacted less sensitively to a sudden organic enrichment than that from the sandy sites. To assess community changes or functional ecosystem responses without the tedious species identification, summative parameters have been introduced. Bongers (1990) and Bongers et al. (1991) contend that a genus- or family-level relation between “colonizers” and “persisters,” the “maturity index,” is indicative of disturbance- or pollution-induced changes. Schratzberger et al. (2007b; Recife) used a combined analysis of some independent data sets arising from large-scale field surveys and small-scale laboratory experiments to investigate the effects of seabed disturbance on nematode communities. Disturbance response was documented as a function of disturbance type (coastal development, dredged material disposal, bottom trawling, glacial fjord), origin (man-made, natural) and intensity (low, medium, high). Natural and human-induced seabed disturbance could not be clearly differentiated. Both generated changes in the taxonomic and functional diversities of their assemblages. The magnitude and direction of effects depended on the origin and nature of the stress-generating factors. The application of multivariate statistics often helps to reveal changes in community structure, even above the species level, and facilitates discriminating the effects of frequently combined factors, e.g., disturbance/pollution (see Schratzberger and Warwick 1999a; Somerfield and Clarke 1995). Far more simple is the nematode–copepod index (Raffaeli and Mason 1981), which is based on the observation that in general the more robust nature of nematodes compared to harpacticoids, especially the interstitial ones, leads to superior persistence in gradients with increasing pollution. Refinements to correct for changes caused by factors others than pollution, such as mere physical perturbation, have since been made and have limited the general range of applicability as an indicator of pollution (see Sect. 8.8). Modern genetic methods provide a new approach to tackling the problem of mass identification of nematodes. A DNA barcoding technique, based on nematode-specific primers of the 18S rRNA gene, enabled Bhadury et al. (2006a,b) to correctly assign over 97% of the specimens present. Such a rapid genetic identification method may also prove valuable (perhaps indispensable) to future ecological and environmental studies. The perils of DNA barcoding based on just a few genes (Will et al. 2005) can be attenuated by supplementing this approach with traditional taxonomic work. A second aspect that lends nematode studies importance in future research is their physiological potential. Since they strongly react to endocrine disrupting (ED) chemicals known from vertebrates, nematodes might become promising organisms for biomonitoring (Höss and Weltje 2007). Among the often exotic physiological pathways mainly those concerning anoxia have been briefly addressed above. A regulative capacity for salinity tolerance exists in tidal species (Forster 1998). Some species can produce unusual substances and use metabolic processes whose adaptive value is seldom initially obvious, e.g., the production of potent neurotoxins

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(Kogure et al. 1996), the glyoxylate cycle, the synthesis of cellulases and polyunsaturated fatty acids, amino acid synthesis from acetate and glucose, and other metabolic pathways that are barely known from metazoans. Owing to their species richness, in the future and with the aid of modern (molecular) methods (Badhury et al. 2006a,b), nematodes may play a prominent role in addressing questions about the impacts of pollution or biodiversity changes resulting from the impacts of humans on ecosystem processes. A tool capable of coping with the enormous diversity of species considering the restricted capacity of the few experienced taxonomists might be a summative DNA barcode database that can be aligned with known barcode sequences of identified and video-captured species, as suggested by Lambshead and his group for the deep-sea (Cook et al. 2005; Bhadury et al. 2006a,b; Lambshead and Packer 2006). One problem with this approach might, however, be the high metapopulation diversity known for some nematodes (Derycke et al. 2007a). Of particular relevance for coupling taxonomy with genetic identification is the newly developed short-term formalin fixation method (Bhadury et al. 2005), which allows both approaches to be applied to the same individual. Accessibility to molecular genetic analyses, even those of archived nematode material achieved by a new hot-lysis method (Bhadury et al. 2006c), might gain considerable custodial relevance in the future. Some nematode species with short generation times and high reproductive rates allow for inexpensive axenic culture and mass breeding, making them a potentially powerful tool in environmental and toxicological studies (Williams and Dusenbery 1990; Moens and Vincx 1998; for freshwater: Traunspurger and Drews 1996; Höss et al. 2006). So far, about 30 free-living species can be cultivated in the laboratory. The fact that the freshwater nematode Caenorhabditis elegans (Rhabditidae) belongs to this group gives it far-reaching potential, since this is, so far, one of the few invertebrate metazoans for which not only the genome but also the entire cell lineage has been determined. The extreme nematode diversity between species, even among populations, would be grossly underestimated by classical taxonomy alone, but is revealed by genetic analyses or an integrative approach that combines molecular data with multivariate morphometric methods and, where possible, interbreeding experiments (Derycke et al. 2007a; Derycke et al. 2008). The high number of unique genes and the thousands of novel protein families present in nematodes (Parkinson et al. 2004) argue for further exploration of their complex genetic background. Considering their ecological success (pollution!) and their impact on human and agricultural ecosystems (parasites!), this search could bring meiobenthic animals to the forefront of general awareness and thus yield unprecedented success. The aspects addressed here bring a whole new meaning to the statement of Heip et al. (1982), which was originally related to field ecology: free-living “nematodes are …… the most important” taxon in all marine sediments. More detailed reading: taxonomy and systematics, Heip et al. (1982); Keppner and Tarjan (1989); Platt and Warwick (1983, 1988), Warwick et al. (1998); computer-assisted key, Diederich et al. (2000); anatomy, Chitwood and Chitwood


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(1974); Bird and Bird (1991); biology, life history, Wharton (1986); Hopper and Meyers (1966); Gerlach and Schrage (1971); Tietjen and Lee (1977); Herman and Vranken (1988); ecology, Wieser (1959); Alongi and Tietjen (1980) Platt and Warwick (1980); Heip et al. (1982, 1985a); Jensen (1987a); Warwick (1989); Moens and Vincx (1997a); books and general reviews, Ferris and Ferris (1979); Nicholas (1984); Heip et al. (1982, 1985a); Gal’tsova (1991); Wharton (1986); Malakhov (1994); Lee (2002); monographs on freshwater nematodes, EyualemAbebe et al. 2006; Traunspurger (2000, 2002).

Box 5.5 Nematodes: Exuberant, Exotic, Everywhere Meiobenthic nematodes, the animal taxon with the greatest species richness in the benthic zone, have exploited every biotope in the aquatic regions of the Earth, from polar ice to deep-sea mud, from mountain streams to jungle phytotelmata. Nematodes also represent the majority of the meiobenthos in suboxic muds and even in hydrothermal vents with their extreme conditions. In the seemingly deserted beach sand, many thousand nematodes belonging to numerous species can live under each footprint. Each of them occupies its own ecological niche with different trophic requirements, life histories and sediment preferences. This bewildering multitude of species, of which only about 10% may have been scientifically described, are systematically grouped into two large subtaxa. Ecological grouping is often related to substrate type (e.g., sand, mud) and feeding mode (e.g., microvores, predators). Nematodes are mostly sediment-bound and less dispersive than other meiofaunal groups. Most of them are bacterivores, but in tidal flats a large proportion of them graze on microalgae, and uptake of dissolved organic matter seems common. This high ecological differentiation and specialized physiological capacity of nematode species, which apparently corresponds to a hitherto unknown genetic diversity, makes any grouping of them into larger categories a problem. This becomes evident upon listing the life history or production details of nematodes. However, their relevance calls for generalizations in order to better assess their overall role. A P/B ratio of about 10–15 seems applicable to both the average marine and freshwater nematode. Their frequent and speciose occurrence in polluted environments and their often specific reactions to single pollutants make nematodes valuable tools for pollution studies, even when macrofauna have disappeared. Attempts have been made to define and possibly cultivate indicator species for experimental work. In order to overcome the problems of species identification (although competent literature does exist!), superficial parameters such as the nematode/copepod ratio have been developed. While simple to use, even by the nonspecialist, they are controversial. Considering the fact that in most biotopes >80% of all meiofauna are nematodes, findings for nematodes are often representative of the whole meiofaunal community.

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5.6.2


Kinorhyncha

The vermiform body covered with cuticular rings led Dujardin (1851), in the first description of a kinorhynch, to classify it as being intermediate “between worms and crustaceans.” The striking “in-and-out movement” of the eversible anterior end of their body is so characteristic that the scientific name “Kinorhyncha” (“animals with a motile proboscis”) was later derived from it. Today, their affiliation with Loricifera and Priapulida is considered, resulting in the “Scalidophora” or “Cephalorhyncha” (see Neuhaus 1994, Neuhaus and Higgins 2002). This morphologically based monophyly is supported by recent molecular studies (Petrov and Vladychenskaya 2005, Mallat and Giribet 2006, but see Sørensen et al. 2008). Some 170 kinorhynch species are grouped into 18 genera belonging to two orders distinguished by differences in the number of plates in the “neck” segment (the second of 13 segments) of the cuticular rings, sometimes referred to as “zonites” (Fig. 5.23). The head can be withdrawn in the trunk and the plates of the neck then serve as a closing apparatus. The zonites carry spines with different arrangements and shapes: an important taxonomic feature. Juveniles

100 µm

Echinoderes (lateral view)

a

Echinoderes (dorsal view)

b

Pycnophyes (dorsal view)

Fig. 5.23a–b Some characteristic Kinorhyncha. a Natural appearance; b schematic graph showing structure of body plates. (After Higgins 1981, 1986)


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hatch with a reduced number of trunk segments; two of them develop during the series of six molting stages. The hatching juveniles have a different spine arrangement and structure to that observed in adults, which has caused some confusion in their taxonomy. All cuticular structures are shed during the juvenile molting phases. Cyclorhagida, mainly represented by the genus Echinoderes with 60 species; second zonite is covered with 14–16 plates or “scalids” that are round-to-oval in cross-section. Semnoderes is another better-known genus from sandier sediments. Homalorhagida, mainly the genus Pycnophyes with about 35 species; second zonite with only 6–8 scalids that are triangular in cross-section. Kinorhynchus and Pycnophyes are well-known genera typical for very fine sediments. With a few exceptions (see below), kinorhynchs are infrequently recorded in meiofaunal samples, although their unique movements make them immediately noticeable. Their tiny size (120–1,100 µm) and the inadequacies of common extraction methods (decanting, elutriation, flotation, see Sect. 3.2.2 and below) contribute to their scarcity. The stiff body is made flexible through the articulation of the cuticle in 13 annular zonites, which additionally attain a certain degree of elasticity in lateral and medioventral furrows, subdividing them into separate plates. Rhythmical inversion of the first zonite into the neck and trunk region creates the typical kinorhynch movement in which the scalids serve as anchoring devices so that the body can be slowly dragged forward. When retracted, the anterior scalids can completely cover the front end; when fully extended, the nine long jointed oral styles of the first zonite point forward. They surround a small oral cone that often remains retracted in specimens from live samples. The subdivision of the body, externally evident in the zonites, is also internally documented in the epidermis, musculature and nerve system. The animals have separate sexes; spermatophores have been observed on the females of some homalorhagids. Ecological aspects. Kinorhynchs are purely marine animals that occur mostly in muddy-to-fine sandy sediments from the eulittoral (e.g., Echinoderes coulli) down to the deep-sea, where they seem to occur with the highest diversities, with many new species discovered. They are also found in the phytal, and occasionally in coarse clean sand (e.g., Cateria with a very slender body in intertidal high-energy beaches). Shallow water forms probably feed mainly on diatoms, which correlates with the marked population peak recorded in summer for some species. The diatom cells are taken up with the help of scalids and spines and protractor muscles that move a sucking pharynx. In deeper bottoms, bacteria and detritus are probably ingested. Kinorhynchs are mostly found in the oxygenated surface layers at abundances in the range of about 15 specimens per 10 cm2, with a decreasing tendency toward the deeper layers. Densities of Echinoderes coulli—one of only a few species that tolerate brackish salinities—reached as high as 72 per 10 cm2 (Higgins and Fleeger

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1980). Especially in polluted fine sediments, up to 200 kinorhynchs 10 cm−2 can represent a substantial part of the meiofauna. High densities (45 ind./10 cm2) have also been recorded in polar regions (Neuhaus and Higgins 2002). Pfannkuche and Thiel (1987) found that in Antarctic bottoms at 400 m depth kinorhynchs represent 5–6% of all meiofauna, exhibiting abundances of >250 specimens per 10 cm2. In some studies of the Pacific deep-sea and in Antarctic bottoms, kinorhynchs ranked third out of all meiofaunal groups. The kinorhynch body is covered by a strongly water-repelling cuticle, so the animals tend to adhere to the water surface once in contact with air. Hence, the best way to obtain kinorhynchs is to use the “bubble and blot method,” because, even when preserved, kinorhynchs adhere to the surface film, and they can be removed from this with blotting paper. Decantation with subsequent inspection of the water surface in the jar is only adequate in coarse sand. For quantitative purposes more sophisticated methods (Higgins 1988; Sørensen and Pardos 2008) must be used. More detailed reading: anatomy, Kristensen and Higgins (1991); Neuhaus (1994); monographs, Remane (1936a); Adrianov and Malakhov (1994); Neuhaus and Higgins (2002); biology and identification key, Sørensen and Pardos (2008).

5.6.3

Priapulida

Half of all known priapulids (some 20 species in total) are of meiobenthic size; however, these are rather heterogeneous in appearance and have wide distributions. Certainly the best known of these is Tubiluchus corallicola, which is relatively frequent in sublittoral coralline sands in the Caribbean. T. troglodytes from an Italian cave has been found at densities of up to 80 ind. 10 cm−2 (Todaro and Shirley 2003). Other meiobenthic forms are the interstitial Meiopriapulus fijiensis, found in the eulittoral of Pacific islands, and Maccabaeus (= Chaetostephanus), a tubicolous form from muds in the Mediterranean. The larva of the common macrobenthic Priapulus caudatus can be encountered in fine sediments as temporary meiobenthos. The body of a priapulid is covered with a chitinous cuticle, often bearing tegumental spines, setae and papillae. In its anterior part the body is structured as an eversible and retractable proboscis, the “introvert,” which is studded with various diagnostically relevant teeth and scales, the “scalids” (Fig. 5.24). A post-anal extension of the body can occur as a long tail, e.g., in the troglobitic (cave-dwelling) Tubiluchus troglodytes, which apparently serves as an anchoring organ. Besides the well-developed dermal-muscular layer, two strong retractor muscle strands traverse the body and insert into the proboscis. It has been argued that the body cavities of priapulids, for instance in Meiopriapulus, are coelomic with a mesodermal lining. In Tubiluchus spp., which are sexually dimorphic, the males have a stronger ventral setation. Except for Meiopriapulus, which may undergo direct development


159

0.5 mm

0.5 mm

Meiopriapulus fijiensis

Tubiluchus corallicola

Fig. 5.24 Characteristic meiobenthic Priapulida. (Various authors)

(Higgins and Storch 1991), priapulids have characteristic larvae that differ from the adults in that they have a fortified cuticle, the “lorica” (latin: “coat, case”) consisting of solid plates (dorsal, ventral, lateral) equipped with scalids (Fig. 5.24). The larvae of Tubiluchus spp. lack the tails characteristic of the adults. The chitinous cuticle of priapulids is periodically molted. The meiobenthic priapulids probably feed on bacterial films and other small organisms, which they scrape off or sieve out of the sediment with their relatively wide scoop- or comb-shaped anterior scalids. Priapulida is a very old group; fossilized members dating from the Cambrian have been found, and present-day members are often similar to fossils from the Burgess Shales. Their monophyletic character is not always plausible (Park et al. 2006), but their relations to the Kinorhyncha and especially to the Loricifera (see below) seem to be confirmed by molecular data and by the similarity of the priapulid larva to loriciferan adults (Warwick 2000). This is accentuated by the establishment of the taxon Scalidophora, which has strong morphological and molecular support (Garey 2002; Mallat and Giribet 2006; bus see Sørensen et al. 2008). More detailed reading: Maccabaeus, Por and Bromley (1974); Tubiluchus corallicola, Kirsteuer (1976); Meiopriapulus fijiensis, Morse (1981); ultrastructure, Higgins and Storch (1989); monograph, van der Land (1970)

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5.6.4


Loricifera

This nemathelminth phylum was first described by Kristensen (1983) on the basis of Nanaloricus mysticus found on the coast of Roscoff (France). In the meantime, these bizarre, minute animals have increased in the number of species described to about 25, grouped into several families, and at present about 300 species still await formal description (Gad, pers. comm.). While the first specimen described lived in shell gravel in only 25 m of water, today most species are found in the deep-sea (Gad 2004). Reasons for the late discovery of this group might be their minute size (250–300 µm), their similarity (when fixed) to contracted rotifers, and their rare occurrence, which, in turn, might be a methodological problem, since their viscid surface strongly adheres to sand grains. Loriciferans were first noted in 1974 by Higgins and in 1975 by Kristensen, and probably also by other meiobenthologists. However, it was not until fresh material became available that their unique structures separating them from other nemathelminths were recognized (Fig. 5.25). Despite their minute size, loriciferans have a considerable number of small cells (>10,000), in contrast with similarly small nematodes and rotifers. Today, sufficient specimens have been found to suggest a worldwide distribution for the taxon in both sandy and muddy sediments, not just in deep-sea bottoms. Shell hash and biogenic sands seem to be favorable habitats for loriciferans. Herman and Dahms (1992) even found loriciferans in the polar regions, and their occurrence has been reported in “Atalante,” an anoxic and sulfidic brine basin in the eastern Mediterranean. As undescribed new species are often found, the number of projected species will increase rapidly. The dorsoventrally flattened bodies of the Nanaloricidae are covered with a solid armor, the lorica, which is divided by longitudinal furrows into six plates. These are studded with about 230 spiny scalids which are often of bizarre shape and arranged in 9 transverse rows. The head region has a non-eversible but telescoping mouth cone, which can be retracted (e.g., when fixed) along a flexible neck into the trunk; this is reminiscent of certain rotifers. The anterior proboscis contains an internal stylet apparatus with a complicated triradiate muscular pharyngeal bulb. The Pliciloricidae (Pliciloricus) have a round body covered with a set of plates corresponding to lorica structures in the priapulid larva. The separate sexes of Loricifera differ in the structure of the scalids (Fig. 5.25). The complicated larva (“Higgins larva”) has numerous long spines around its head end, and, at least in Nanaloricus, a pair of toes at its hind end which serve as adhesive organs. Three leaf-shaped, locomotory flosculi may be present, which probably propel and push the animal forward through the sand. The larva passes through several molts, shedding the lorica. Deep-sea samples also harbored huge paedogenetic larvae (almost 850 mm; Gad 2005), other deep-sea species (e.g., Rugiloricus) have aberrant developmental cycles that include paedogenesis and parthenogenesis as well as gonochoristic development and internal fertilization of females.


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20 µm

50 µm

c

b a

40 µm

Fig. 5.25a–c The first described representative of Loricifera, Nanaloricus mysticus. a Female, ventral view; b female, front end with mouth opening; c larva with floscula. (After Kristensen 1984)

A systematic relationship of the Loricifera with the Kinorhyncha and Priapulida (“Scalidophora”) is well supported by morphological characters (Kristensen 2002; Mallat and Giribet 2006), and their positions within the Ecdysozoa were confirmed by analyses of 18S rRNA (Park et al. 2006). However, recent corresponding analyses with several loriciferan species (Sørensen et al. 2008) do not consistently support the close relationships mentioned above. The structural relationship, especially with the larva of priapulids, is striking (Warwick 2000), and a progenetic origin for loriciferans (from priapulids?) has found some molecular support. Fossil records also indicate a close connection between the scalidoporan taxa and emphasize that they were archaic nemathelmiths that existed already in the Lower Cambrian (Maas et al. 2007). Similarities with singular rotifers (lorica) or with tardigrades (stylet apparatus) are believed to be convergences; perhaps both are based of plesiomorphism (Ecdysozoa). With their extremely high cell numbers and numerous scalids, loriciferans can be considered to be the most morphologically complicated meiobenthic animals, despite their minute size. More detailed reading: first description of taxon, Kristensen (1983); taxonomy, anatomy, biology, Kristensen (1991a); phylogeny, Kristensen (2002).

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5.6.5


Gastrotricha

Gastrotrichs are all of meiobenthic size; indeed, they are among the smallest metazoans (some only 60 µm). However, the characteristic gliding that they perform on their ciliated ventral side (their scientific name means “gastric hairs”), their general body shape (head, thorax, tail, often biramous furca), and finally their armature of body spines and haptic tubes make most of them easy to recognize microscopically (Fig. 5.26). The haptic tubes are extensions of the body cuticle into stiff tubes that contain rich adhesive glands. With their steady gliding they differ from the more writhing gliding of turbellarians and gnathostomulids; another distinctive feature is their well-developed terminal mouth and anus. About 720 species have been described so far, which are classified into two orders genetically quite different orders with 15 families. From Northern Europe alone approximately 200 species are presently known. Identification is mostly based on the shape of the caudal furca, the arrangements and shapes of the scales, spines and hairs on the cuticular surface, the positions of the haptic tubes and the structure of the radial pharynx musculature. Macrodasyida (also Macrodasyoidea): discovered in the 1930s, this group contains about 250 relatively primitive but radiating marine species that exhibit hermaphroditic sexual reproduction. The numerous haptic tubes extend in a symmetric arrangement anteriorly, laterally and caudally. Macrodasys, Urodasys (with a tail), Turbanella, Cephalodasys (Fig. 5.26). Chaetonotida (also Chaetonotoidea): This mostly limnic group of approximately 450 species is more derived and exhibits less form variation; it contains only a few marine and brackish-water taxa such as Xenotrichula. The cuticle is covered by conspicuous spiny or shingle-shaped sculptures, often with a circumoral whirl of setae. There is only one pair of haptic glands on the furcate toes. Most species reproduce parthenogenetically, but hermaphroditism is also widespread (Weiss 2001). Chaetonotus, Neodasys, Lepidochaetus. In Xenotrichula and Neodasys, males have been found that inject their sperm in a complicated way into their female partners (similar to Rotatoria, see Sect. 5.4.2). Biological and ecological aspects. The cuticular hard structures (free of chitin) and the occasional development of vacuolized epidermal cells are often interpreted as providing protection against sediment agitation and pressure. With their very effective haptic tubes, glandular toes, and in some species haptic “girdles”, the animals can momentarily cling to sand grains (see Fig. 4.6). This reduces the success of extraction by decantation considerably unless anesthetization or a freshwater shock is applied. Besides the typical continuous gliding motion, locomotion by crawling and alternating adhesion using the front end and the haptic toes (looping) occurs in gastrotrichs as well as sinuous swimming. Characteristic for meiobenthic organisms, just a few, large eggs are produced, from which juveniles hatch without passing through a larval stage. The lifespan of gastrotrichs is only a few weeks. They are microphagous, feeding on bacteria, protozoans, etc.

Thaumastoderrma (Macrodasyoidea)

Fig. 5.26 Some representative Gastrotricha. (Various authors)

Turbanella

50 µm

50 µm

Diplodasys

50 µm

Chaetonotus (Chaetonotoidea)

50 µm

5.6 Nemathelminthes: A Valid Taxon? 163

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Gastrotrichs are occasionally abundant in meiofaunal samples. The marine species live preferably in the interstitial of fine sand enriched with detritus. Especially in the lower tidal to subtidal shore they can attain maximal densities of almost 7,000 per 10 cm2. On rare occasions, aggregations of more than 200 specimens per cm3 have been found in a beach on the west coast of the USA (Hummon 1972) and up to 400 specimens per cm3 in a tidal sand flat of the North Sea (Potel and Reise 1987). However, a rich gastrotrich fauna has also been recorded in areas of coarse sublittoral calcareous sand (shell hash) (Todaro 1998; Kristensen et al. 2007). In some habitats, including polar fine sand, gastrotrichs outnumbered many other meiofaunal groups (Huys et al. 1992). In tropical beaches, gastrotrichs were found to be particularly common after the decline of most meiofauna due to monsoon rains (Alongi 1990b). The first records from deep-sea hydrothermal vents (Desmodasys abyssalis) have been reported recently (Kieneke and Zekely 2007). Exposed beaches harbor just a few adapted species (e.g., Xenotrichula). In contrast to abundance, gastrotrich diversity can be remarkably high, particularly in coarse, calcareous sands. Up to 18 species have been stated to occur syntopically in a few square centimeters. Sea caves (anchihaline caves) have also been considered “hot spots” in gastrotrich diversity and endemism (Todaro et al. 2006). Differing ecological demands, even between some congeneric species, resulted in a typical vertical and horizontal distribution pattern along a beach (Ruppert 1977). Muds are seldom populated, since most gastrotrichs prefer oxygenated sediments. However, some species seem to possess adaptive metabolic pathways for a specialized thiobiotic life (Boaden 1974; Todaro et al. 2000). Some 40 specimens were found in samples from North Sea methane seeps (Giere, unpublished). The brackish-water and freshwater gastrotrichs prefer zones of submerged or decaying vegetation (periphyton), ephemeral pools and organic debris. Macrodasyida and Chaetonotida are commonly considered sister groups, but molecular analyses indicate that they are probably not monophyletic (Wirz et al. 1999; Zrzavy 2003). Within these subgroups, sperm ultrastructure seems to provide useful character sets for cladistic studies attempting to classify the species (Marotta et al. 2005). Gastrotrichs, with their multilayered cuticular fine structure, seem to be a monophyletic sister group of the Ecdysozoa Cycloneuralia (Schmidt-Rhaesa 2002; Zrzavy 2003), although other affiliations (e.g., with Plathyhelminthes) are also discussed. The trend for reducing body structures, concomitant with decreasing size, confuses conclusions about their phylogenetic position. Even the coelomate nature of their body cavities (mesothelial coelom present?) and the phylogenetic condition of the triradiate pharynx are disputed (Teuchert and Lappe 1980; Schmidt-Rhaesa 2002). In any case, the taxon Gastrotricha plays a key role in hypotheses regarding the deeper links between phyla. More detailed reading. taxonomy, Hummon (1971); Clausen 2000; structure, phylogeny, Rieger (1976); Teuchert (1977); Ruppert (1982), Schmidt-Rhaesa (2002); Zrzavy (2003); ecology, Schmidt and Teuchert (1969); physiology, Hummon (1974); zoogeography, Ruppert (1977); freshwater, Kisielewski (1990); Ricci and Balsamo (2000); monographs, Remane (1936a); D’Hondt (1971); electronic database, Hummon (2004); identification key, Todaro and Hummon (2008).

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165

Box 5.6 Bizarre, Spiny Dwarfs: The “Lesser-Known Taxa” A film producer asked to design an alien life form from outer space could do worse than to depict a scalid-armored loriciferan, a long-spined gastrotrich or a “mud dragon” (kinorhynch) plodding its way through the mud. It seems hard to imagine the evolutionary pathways that have led to these exotic forms. Unconventional and tiny (only a few priapulids belong to the macrobenthos), these rather unearthly groups have been termed “the lesserknown protostome taxa” (Garey 2002). The Loricifera, which were discovered only a few decades ago, are particularly complex in appearance and anatomical detail. The Scalidophora (Kinorhyncha, Priapulida, Loricifera) are armored with a chitinous cuticle (rings, plates, spines) that is regularly molted during growth. Especially in the loriciferans, this indirect development entails several bizarre larval stages and complex life cycles, often with progenesis. The anterior end of Scalidophora functions as a retractable “introvert” whose numerous scalids (in kinorhynchs and priapulids) scrape small food items, e.g., diatoms, bacteria, detritus while the animal digs through the mostly muddy sediment. In contrast, loriciferans, which tend to prefer sandy sediments, are equipped with a complex stylet apparatus suggesting the piercing and sucking of small cells, but, as yet, no live specimen has ever been observed. Discovered in the shallow sublittoral, the Scalidophora seem to attain the greatest diversity in deep-sea bottoms, with numerous species still awaiting description. The Gastrotricha are distinguished from the Scalidophora by their nonchitinous, flexible cuticles that allow continuous development without molts or larval stages. Their characteristic appearance, with numerous stiff spines and sticky tubes, makes them easily recognizable provided one is prepared to look for these tiny creatures that glide swiftly on their ventral ciliary soles across the substratum. In contrast to the Scalidophora, gastrotrichs can become quite abundant (e.g., in detritus-rich sands) if the right extraction technique (freshwater shock) is applied. They also exceed the other groups of spiny, bizarre dwarfs in species number.

5.7

Tardigrada

Tardigrada or “water bears” are another meiobenthic taxon that has gained considerable phylogenetic relevance in discussions about the link between the supertaxa Ecdysozoa and Arthropoda (Garey 2001; Nelson 2002; see below). The approximately 1,000 described species of tardigrades inhabit marine and freshwater habitats, sands and muds, the supralittoral and the deep-sea, and this wide ecological

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and geographical range indicates a distinct physiological diversification over a long phylogenetic period. The high group diversity (most genera have just a few species) also points to marked radiation. The first description of an interstitial tardigrade (Batillipes mirus) was provided in 1909, and new species are continuously being found and described today, especially those from marine habitats. The tiny sizes of all tardigrades (50–1,200 µm) often necessitate a double check at high magnification when sorting a sample. The five-segmented bodies of tardigrades are sometimes bizarre (Fig. 5.27). The head segment has numerous sense organs on cirri, and their arrangement is of diagnostic relevance. The following three thoracic segments and the caudal segment have flexible legs without arthropod joints, mostly ending in claws that sometimes come from long toes (subgroup Arthrotardigrada; Fig. 5.27). The telescopic extremities are retractable via muscles and eversible by the turgor pressure exerted by the mixocoelom; the last pair of legs often bears spectacular appendages (Fig. 5.27). The pharynx is equipped with a complicated, diagnostically important stylet apparatus for piercing. Its specific muscles act as a suction pump, similar to that seen in many nematodes. As in nematodes, circular musculature and ciliated epithelia are absent. Respiratory, circulatory and excretory (nephridial) systems are not developed. The phylum consists of two classes separated on the basis of morphological characters (the elusive Thermozodium is not considered here), each with representatives in marine and freshwater biotopes. Heterotardigrada: This more ancestral group, often considered the sister group for all other tardigrade taxa, consists of more than 300 species (all have head cirri) that are divided in two subgroups. In most heterotardigrade species the body is well segmented and often armored with plates. Most live in marine sediments, among algae and barnacle thickets. Arthrotardigrada: Usually have a median head cirrus, and the telescopic legs have toes from which claws and/or sucking discs arise. Stygarctus, Halechiniscus and Batillipes are common species from marine eulittoral sands; altogether there are presently 35 genera with 110 species. Echiniscoidea: The claws are positioned directly on the legs without toes. Most echiniscoid tardigrades are terrestrial forms, but Echiniscoides is a typical marine genus and the rather vermiform Carphania lives in hyporheic freshwater. Echiniscoid tardigrades survive periods of desiccation without any problems; there are presently 14 genera and 190 species in total. Eutardigrada: This more advanced group consists of 34 genera with more than 700 mostly limnetic and terrestrial species. They never have head cirri, their body is not armored, and the legs terminate directly in claws without toes. The mouth is surrounded by a whorl of lamellae. Macrobiotus, Hypsibius and Milnesium are characteristic representatives. Many occur in mosses and lichens, but they also live in mesopsammal habitats. Some have secondarily readapted to marine biotopes (e.g., Halobiotus).

5.7 Tardigrada

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A

B

30 µm

50 µm

Batillipes pennaki Stygarctus

50 µm

Echiniscus

50 µm

50 µm

Neostygarctus acanthophorus

Tanarctus bubulubus

Fig. 5.27a–b Some characteristic or spectacular Tardigrada. a Batillipes: piercing stylet apparatus. b Batillipes: viscid digital end plate. (Various authors)

Biological and ecological aspects. The aquatic heterotardigrades survive adverse periods via cyst formation, while terrestrial Eutardigrades have developed a remarkable capacity to survive as an almost metabolically inert “tun stage.” Extreme desiccation and freezing (30 K!) and high doses of radiation do not seem to affect the “tun,” and may even greatly extend the individual’s lifetime. This extreme cryptobiosis” or “anhydrobiosis” is not developed in the aquatic species,

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which only have less elaborate resting stages. The cryptobiotic stages are often in tune with propagatory phases, enabling tardigrades to colonize ephemeral or isolated biotopes (for an actual review of cryptobiosis, see Wright 2001; Crowe et al. 2002). The developmental biology of tardigrades is complicated by their diverse reproductive strategies, at least in eutardigrades (Bertolani 2001). The marine species usually have separate sexes that are sometimes dimorphous; the iteroparous females produce only one egg at a time; males of marine species, in contrast, are semelparous and have a shorter maturation period than females. Freshwater species are usually gonochoristic and iteroparous in both sexes. But hermaphrodities, with self-fertilization, parthenogenesis and polyploid cytotypes, occur. These mechanisms favor together with cryptobiosis dispersal to unstable and isolated environments. Bisexual reproduction in tardigrades is through copulation; eggs are often unusually shaped and ornate. Mitosis is limited to a few tissues and possible only during the juvenile phase; in the adult body, which consists of relatively few cells, the cell number remains constant (eutelic) in most organs. All hard structures (claws, stylet apparatus) consist of the chitinous material that covers the whole body as a cuticle, and so they have to be molted as the animal grows (which occurs continuously throughout its lifetime). Juvenile stages have fewer legs and claws than the adults. The developmental cycle of one of the most common interstitial tardigrades, Batillipes pennaki, is bivoltine with (in Italy) maxima in spring and fall, which are probably related to favorable food conditions; in boreal climates its population peaks in winter. During the life cycle of Halobiotus cyclomorphotic changes (i.e., regularly occurring alterations of certain body structures within a population) in the stylet apparatus have been noticed occasionally and in tune with the seasons (Kristensen 1982). The average lifespan is some months to a few years, but in the cryptobiotic stage they can survive for more than 100 years (Nelson and Higgins 1990). Tardigrades mostly feed on the contents of bacteria, fungi and algal cells (both macroalgae and diatoms), which they pierce with their stylet apparatus. A few species are carnivorous or detritivorous. Macrobiotus consumed in feeding experiments up to 100 nematodes in 4 h (Hohberg and Traunspurger 2005). However, feeding types related to specific mouth tube armatures, as in nematodes, could not be discerned. Many aquatic species are found in mosses, among algae, in seagrass meadows, and even in floating Sargassum. These phytal forms use their legs and claws to cling to the fine thalli. Another preferred habitat where tardigrades are regularly encountered is detritus-rich crevices among barnacle epigrowth. Sandy biotopes represent the other major habitat for (marine) tardigrades. Here, they characteristically and slowly crawl on sand grains (the group name is derived from the Latin for “slow walkers”). Batillipes, with its viscid digital sucker plates instead of claws, is fairly active, and “runs” busily up and down the grains. Halechiniscus, with its clumsy, barrel-shaped body, pushes its way through the finer sand. In the mud-inhabiting Coronarctus, found at greater depths and even in the deep-sea, the body is more worm-like and the legs are short.

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Similar to other meiobenthic groups, calcareous biogenic sands are populated by a highly diverse tardigrade fauna, often with particularly bizarre body appendages: 35 mostly new species were found in samples from the Faroe Bank (260 m water depth), i.e., 20% of all known marine species (Hansen et al. 2001). Recent data from the shallow calcareous Meloria Shoals in the Mediterranean underlined this trend. While in coarse sand most species live interstitially, the tardigrade community in fine sand with detritus tends to live epibenthically and it becomes less diverse. Apparently, sediment porosity and structure are relevant distributional factors. In sediments with a good oxygen supply (high-energy beaches), the vertical occurrence of tardigrades down to 150 cm and deeper is not unusual, but the food source at these depths remains unknown. The coastal zone of the sea is often considered the original habitat for primitive tardigrades, from which they entered both the freshwater and terrestrial biotopes as well as the deeper marine bottoms. Depressed forms with flat, extending body plates are considered particularly well adapted for passive transport by clinging to sand grains (Grimaldi de Zio et al. 1983). Despite the limited active distribution potential of tardigrades, many tardigrade genera and species are widely distributed, and some of them are cosmopolitans that occur in all climates. Their extreme survival capacities at various resting stages may have contributed to this ubiquity. A typical distributional profile along the sea bottom (Fig. 5.28) will have in the eulittoral the most eurytopic forms (Stygarctus, Batillipes) that are common in various types of sediment. Genera occurring in the sublittoral can be differentiated in mud- and sand dwellers, and rather specific tardigrade species of very limited distribution live in the deep-sea ooze. However, even genera that occur ubiquitously seem to have a well-developed potential to recognize subtle differences in habitat conditions, resulting in a remarkably heterogeneous colonization with distinct population centers in a beach (Pollock 1970). The overall abundance of tardigrades, even in favorable sites, is rarely very high. For marine forms, densities of >500 ind. per 100 cm3 of sand or 285 ind. per 10 cm2 must be considered unusually high. Patches with up to 3,500 B. pennaki per 100 cm3 (= 32,500 under 100 cm2) have been counted in the low water lines of a Portuguese beach (Thiermann, unpubl.), McGinty and Higgins (1968) decanted over 3,000 B. mirus from 100 cm3 of estuarine sand in Chesapeake Bay, USA. Especially in freshwater ecosystems, the presence of tardigrades in high quantities can reach ecological relevance. In the sandy shores of a freshwater lake in Brazil, Hypsibiidae were found to dominate the meiofauna with mean densities of 1,800 ind. 10 cm−2 (Flach et al. 2007)! Tardigrade abundance is often underestimated due to inadequate sorting procedures and methodological shortcomings. A good method for obtaining (interstitial) tardigrades fairly quantitatively is the “freshwater shock” decantation method, which causes them to release their grip on sand grains (see Sect. 3.2.2). Tardigrades are an old group; fossils attributed to their stem group date from the Middle Cambrian (Müller et al. 1995). The oldest true tardigrade was found embedded in amber that is 92 million years old. Earlier notions saw them affiliated

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5 Meiofauna Taxa: A Systematic Account Halechiniscus Batillipes

Florarctus

Parastygarctus 0m sand

200 m

coarse detritus

Coronarctus

4000 m mud

Fig. 5.28 A horizontal distributional pattern of tardigrades along the sea floor. (After Grimaldi de Zio et al. 1984)

with the spiralians (Eibye-Jacobsen 1997); their segmented bodies, chitinous cuticula, metameric nerve systems and characteristic legs indicating some linkage to the “annelid–arthropod line of development.” Today, the annelid linkage seems more and more untenable, since the concept of the supertaxon “Ecdysozoa” means that Tardigrada is linked as “Proarthropoda” to both the Nematoida and the Arthropoda, an affiliation repeatedly confirmed both in morphological and molecular studies (Garey 2002; Petrov and Vladychenskaya 2005; Mallat and Giribet 2006). This could explain some parallels with nematoid structures (pharyngeal pump, eutelic fixation of cell number, lack of ciliated epithelia and circular musculature), features that are also considered convergences. More detailed reading: Marine species, taxonomy, identification and faunistics, Kristensen and Higgins (1984) Guidetti and Bertolani 2005; phylogeny, Grimaldi de Zio et al. (1987); biology, ecology, De Zio and Grimaldi (1966); Grimaldi de Zio and D’Addabbo Gallo (1975); Grimaldi de Zio et al. (1983); Renaud-Mornant (1982); freshwater species, Iharos (1975); Schuster et al. (1980); cryptobiosis, Wright (2001); short review, Nelson (2002).

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Box 5.7 The Glamour of Clumsy Fellows: A Digression into the Psychology of Meiobenthos Any student course on meiofauna will prove that tardigrades are the stars in the wide world of meiobenthic animals. What is it that makes them so fascinating? Their tiny size? No—they are not any smaller than many rotifers or gastrotrichs! Their bizarre shapes, with floppy wings, decorative spines and baroque plates? No—kinorhynchs or priapulids have much more complex and ornamented scalid patterns! Their clumsy movements? Again, no—a kinorhynch’s method of pulling its body through the mud is more unusual! So, what makes “water bears” so different? Imagine: a spiny head, a flattened body, often armored with plates, strong claws on their four paired legs; all this would be repulsive to us if the creatures reacted quickly like a spider or an ant. However, these cuddly tardigrades set their stumped legs one after the other, as if pondering with each step where to go, they have to paddle hard to get a bit further. Many species have tiny eyes, useless for effective orientation. Altogether, they look touchingly helpless with their podgy bodies. Poor guys! In fact, tardigrades are real womanizers that primarily charm the female students. However, they have their male admirers too - they are record holders: They have resting stages to preserve their lives under most extreme conditions; their unusual modes of reproduction (progenesis, parthenogenesis) enable tardigrades to live in even the remotest of places. No wonder they have survived 500 million years—tough guys!

5.8

Crustacea

Nematodes aside, Crustacea is the meiobenthic group that dominates in abundance and species richness in most meiobenthic samples. There are, however, many taxonomic lines in crustaceans, with groups often consisting of just a few isolated species, and various species living in refuge habitats (e.g., groundwater, caves). Mainly because of their high phylogenetic and zoogeographic significance are these rarer forms included here too. Progenesis is of particular importance in the development of meiobenthic crustacean groups. They seem prone to this developmental abbreviation, which, on the evolutionary level, may have led to taxa such as Ostracoda and Anomopoda (Cladocera), which have a rapid generation turnover. In these groups as well as in the species-rich copepod suborder Harpacticoida, most are of meiobenthic size. However, there are other normally macrobenthic crustacean groups, e.g., isopods and amphipods, in which structural deviations and miniaturization have adapted a few aberrant taxa to the requirements of meiobenthic life. Many “microcrustaceans” are freshwater forms and are well reviewed in treatises by Dole-Olivier et al. (2000) and Galassi et al. (2002).

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Traditionally, the Crustacea as Arthropoda have been linked to the Annelida forming the supertaxon Articulata. With the advance of molecular methods, this unit has become controversial, while the concept of Ecdysozoa has gained increasing support (see Sect. 5.6; Giribet et al. 2005; Jenner and Scholz 2005). This concept would make Nematodes and Scalidophora related to Arthropoda, while the lophotrochozoan annelids are the sister group of Ecdysozoa and are thus only distant relatives to the crustaceans. The Crustacea seem to be a paraphyletic unit within the monophyletic Arthropoda (Garey 2001, Babbitt and Patel 2005; Mallett & Giribet 2006). Within the Crustracea the Malacostraca are apparently monophyletic while in other groups the relationships are inconsistent and debated.

5.8.1

Cephalocarida

This group, first described by Sanders (1955), presently consists of just five genera and a few species. Hutchinsoniella (Fig. 5.29), the first genus, was found in the

500 µm

Hutchinsoniella macracantha

Lightiella sp.

500 µm

Fig. 5.29 Some Cephalocarida. (Various authors)

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sublittoral down to 300 m depth off Long Island (East coast of America), and then Lightiella was discovered in sands off the American Pacific coast, in other Pacific areas, in the Caribbean, and off Venezuela. Sandersiella occurs in mud bottoms off Japan, Chiltoniella in New Zealand, and Hampsonellus off Brazil. These small animals (about 2–3 mm in body length) have a slender body with numerous, homogeneous segments (nine thoracic and ten abdominal metamers). They lack a carapace and a caudal furca. Cephalocarida have articulate legs (phyllopodia) and a maxilla that is morphologically identical to the thoracic legs; compound eyes have apparently been reduced. Representatives of the rare Hutchinsoniella genus are found in the superficial detrital layers of sea bottoms that are flocculent enough to allow the animals to filter food from them when they are moving (the rows of legs form suction chambers). Lightiella, although oxybiotic, regularly occurs in the Caribbean in the deeper sand layers below the RPD layer (De Troch et al. 2000; Schiemer and Ott 2001). Few other biological details are known: these simultaneous hermaphrodites produce just two large eggs from which metanauplii hatch. A disjunct geographical distribution, a long nerve cord and heart with serially arranged ostia, and the primitive structure of the maxilla characterize this order as being an early offshoot from archaic crustaceans, i.e., a “living fossil,” but one without a fossil record. More detailed reading: Sanders (1959).

5.8.2

Anostraca: Anomopoda (“Cladocera”; “Branchiopoda”)

“Cladocera” is actually an artificial, polyphyletic unit that should be separated into several natural taxa. The approximately 270 species of typically meiobenthic “water fleas” are today grouped under one subgroup “Anomopoda” within the Anostraca, but as with the term “turbellarians,” the ecological literature often still refers to them as “cladocerans.” Also the frequently used term “Branchiopoda” denotes a colloquial, not phylogenetically based taxon. Cladocerans live in all kinds of freshwaters, from puddles to lakes, with most of them belonging to the Chydoridae (Fig. 5.30). The phytal species climb and swim among macrophytes (Eurycercus, Chydorus), the epibenthic forms dig through the surfaces of muddy bottoms (Ilyocryptus, Macrothrix, Pleuroxus), and some few species even represent typical subterranean stygobiota (Alona spp.). Although some adult cladocerans exceed the meiobenthic size range, the bulk of the benthic forms do not surpass 1 mm in length or represent small pre-reproductive instars. Diagnostic features include the general shape and sculpture of the head (often in the shape of a helmet) and the wide bivalved carapace (the “shells”) which completely encloses the unsegmented and short thorax, certain pores on the headshield, and the setation and spines of the terminal claws which are usually bent ventrally. All cladocerans molt five times before reaching maturity, thereby shedding their carapace. The populations consist almost exclusively of females, which

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IIyocryptus sordidus

Pleuroxus

Alona

Chydorus

Fig. 5.30 Some representative meiobenthic Anomopoda; 0.5–1 mm in length (Wesenberg-Lund 1939)

predominantly reproduce parthenogenetically by diploid eggs. These are brooded underneath the carapace. Each egg deposition is preceeded by a molt, and the development of the juveniles hatching from these “summer eggs” is very rapid. As the living conditions deteriorate (e.g., the temperature drops) males are produced, and, after normal meiotic division, haploid eggs that require fertilization by the males. The resulting thick-shelled resting eggs are stored in a chamber in the carapace, the ephippium. Here they can survive extremes of temperature and salinity for periods as long as years. During this resting phase of embryonic development, the eggs can also dry out completely. Moreover, the ephippium is an excellent raft for distribution, since it drifts in the water or adheres to plants and birds’ legs. Depending on the physiographic situation, the production of fertilized eggs occurs in winter (“winter eggs”). However, in species typical of ephemeral pools, which repeatedly dry up and then fill up again after new rain falls, several sexual cycles occur independent of the season. This “heterogonous” generation cycle, resembling that of rotifers, ensures genetic mixis and survival (of eggs) during adverse life conditions on the one hand, and, through its parthenogenetic phase, a huge potential to rapidly populate new areas and isolated ponds on the other. As with many meiofauna, progenesis plays a major role in the phylogeny of this taxon. The meiobenthic cladocerans dig, rake and climb with their large and muscular locomotory antennae and thoracic appendages rather than using them as swimming and filtering legs. The number of filter chambers is correspondingly reduced to just one or two. The terminal claws can also be used to scrape the substrate. Benthic cladocerans feed on small algal and detrital particles.

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The highest diversity of meiobenthic cladocerans occurs in the phytal zone, where the habitat complexity is greatest. Due to their parthenogenetic development, they can develop dense populations in almost all types of freshwater (except streams). Abundances of 1 million per m2 substrate are not unusual (Whiteside et al. 1978). Considering their high consumption of bacteria, algae and detritus, Anomopoda represent members of the limnetic meiobenthos. They are also important as food for macrofauna. Anomopod-related fossils dating as far back as the mid-Cambrian have been found (Walossek 1996). One famous fossil related to the Anostraca is the Devonian Lepidocaris found in Scotland. More detailed reading (often still under the term “Cladocera”): taxonomy, Frey (1987); ecology, Goulden (1971); Whiteside et al. (1978); review, Rundle et al. (2002).

5.8.3

Ostracoda

Ostracoda are one of the most speciose crustacean groups. The bivalved carapace that characterizes them has been well documented in fossils that date from the Cambrian. Major taxonomic lineages seem to have diverged by then (Yamaguchi and Endo 2003). Today, > 60,000 extant and fossil species have been described, and the number of recent species is estimated to range between 5,000 and 15,000, with some authors even reporting 30,000, whereof about 2.000 species live in freshwater habitats. Important as stratigraphic and palaeoenvironmental indicators (De Deckker and Forester 1988), ostracods have been classified in a “geological system” based only on hard structures. In contrast, the zoological system of recent taxa is based on both hard structures and soft-body features; modern systematists try to integrate both systems (Hartmann and Puri 1974; Horne et al. 2005). For more detailed accounts on the limnetic ostracod groups, the reader is referred to the review on freshwater meiobenthos by Rundle et al. (2002) and references therein. Ostracods were first described in 1722 as “bivalved insects.” Their short bodies, consisting of only a few segments, are completely enclosed into the two valves of a carapace joined by a complicated hinge that is of taxonomic relevance (Fig. 5.31). Other diagnostic features used for identification are the shapes and sculptures of the shells, the structure of the single closing muscle and its scars on the shell, and the position of the spines on the short legs. The problems of basing the taxonomy on carapace structures become obvious when we consider that almost identical valve types have developed convergently in several independent lines, and that shell structures are subject to ontogenetic changes and sexual dimorphism. Moreover, shells can vary in their ornamentation and their patterns of lobes, depending on environmental conditions (e.g., salinity and chemical composition of the ambient water). The application of molecular studies has proven useful in this case, particularly because of the high degree of geographical and obligate parthenogenesis in many ostracods (Horne and Martens 1994).

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Candona candida

Cyprideis torosa

Cytherura sella Cypridopsis vidua

Iliocypris gibba Actinocythereis sp.

Polycope sp.

Psammocythere sp.

Fig. 5.31 Some representative meiobenthic Ostracoda; about 1 mm in length. (Various authors)

There are two relevant subgroups to mention here: Podocopa: Ord. Podocopida: Many marine (Cytheracea, Darwinuloidea), but also freshwater and brackish-water forms, prevailingly benthic. The ventral edge of the shell has a straight-to-concave contour; brackish water forms (Cypridacea) often have marked shell sculptures (Fig. 5.31) but no rostral incisure. The small species of meiobenthic size often show reduction phenomena like the lack of abdominal furca, heart and compound eyes. Progenesis is fairly common (e.g., Nannocandona). Representatives include Cyprideis, Paradoxostoma (interstitial; phytal), Bairdiidae (phytal), Microcythere (only 200 µm long),

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Leptocythere, Limnocythere, Cythere, Xestoleberis (both interstitial and phytal species, also in brackish and freshwater water), Cytherissa (limnetic). Ord. Platycopida: Exclusively marine, with unequal, ovate valves, small body, most live in deeper waters. Myodocopa: Exclusively marine, valves are weakly calcified and thus are poorly documented in the fossil record. The ventral edge of the shell has a convex contour; there is often (but not in Cladocopida) a rostral incisure in the anterior edge of the shell. The small and roundish Cladocopida live in the marine interstitial. Cladocopa; Polycope, Polycopsis (Fig. 5.31). Biological and ecological aspects. Ostracods are most successful crustaceans ecologically and from an evolutionary perspective. This success is probably related to their wide variety of reproductive models for studies on the evolution of sexuality. One species can have bisexual populations in some areas while other lineages in other areas are parthenogenetic (e.g., within Cyprididae). Members of the Darwinuloidea, which have been exclusively parthenogenetic since Mesozoic times apparently, have an amazingly low genetic diversity. The genetically homogenizing mechanism in this long unisexual sequence is unclear. In contrast, the Cytherididae and Candonidae are holomictic. These mictic freshwater species often have amazingly large spermatozoa that are transferred by large copulatory organs. Eggs can become fixed to the sediment by adhesive fibers. The nauplius already has a two-shelled carapace, and after 5–8 molts the adult stage is reached. The eggs and the first naupliar stage are sometimes brooded between the shells. Ostracods are quite long-lived; many live for several years. In the sea, ostracods regularly populate lower tidal flats and sublittoral sands, where they live in fine or coarse sands; fine-grained sediments seem to support the largest populations. They can be particularly diverse and abundant in calcareous or coralline sands. They vigorously burrow and push through the sediment with jerky motions of their strong legs, which are often armed with claw-like setae. Occasionally is there a clear adaptive correlation between the structural or biological features of ostracods and their habitat. There are only 60–70 species that appear to be structurally adapted for life in the interstitials of sands. These have small bodies (only 0.2 × 0.3 mm) possessing a smooth carapace with an elongated, almost cigar-like or conical shape (Fig. 5.31). The shell may be laterally compressed (Paradoxostoma) or ventrally flattened (Xestoleberidae), and the segment number may be reduced and the limbs simplified. While crawling on the grain surface or swimming in the interstitial system voids, they can immediately clutch the grains with adhesive fibers produced by a spinneret gland complex and released from openings in the setae of the antenna. The loss of eyes and pigments in the more endobenthic or interstitial Podocopa or the reduction in the number of segments (Polycopidae) can be interpreted as adaptations to the interstitial of coarse sands (Hartmann 1973). The phytal zone (see Sect. 8.5) is another preferred habitat that is densely populated by sediment dwellers and typically adapted phytal species, e.g., the Bairdiidae with their specialized mouth parts and hairy carapaces. The deep-sea harbors ostracods in silty sediments (Dinet at al. 1988) as well as in hydrothermal vents (Sect. 8.3; Fricke et al. 1989; Van Harten 1992). Various substrates in the Antarctic sublittoral harbored a rich and diverse ostracod fauna (Hartmann 1990).

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In favorable shallow bottoms, ostracods can attain abundances of well over 200 specimens per 10 cm2 (when sorting, it is difficult to determine the live individuals from the empty shells). In the beaches of the Galápagos Islands, ostracods were found (Westheide 1991) to rank second after the nematodes and sometimes even to dominate (2,850 specimens 100 cm−3). In the Baltic Sea a few ostracod species represent most of the total meiobenthic biomass (Modig et al. 2000). Through their vigorous motions they are the main bioturbators among meiofauna, and have a considerable impact on the sediment’s fabric and geochemistry. While ostracods, like harpacticoids, are generally restricted to the well-oxidized surficial sediment layers, Cyprideis torosa survives highly sulfidic conditions (Jahn et al. 1996). Since the salinity is the dominant influence for most species, coastal areas with a brackish water gradient often have a marked pattern of species that are differently adapted to haline ranges. In typical brackish-water species (e.g., Elofsonia baltica), the shells are often rather thin. In freshwater, ostracods occur in almost every habitat, from high mountain lakes to ground and cave waters, and some species can also live in moist mosses and litter. Ostracods are typical dwellers of springs with elevated temperatures and ionic contents. Limnetic ostracods are often adapted to survive adverse conditions. Darwinuloidea can hibernate for months in a state of torpidity, and the Cytheroidea and Cypridoidea produce resting eggs that are resistant to desiccation and freezing. The water or air transport of these resting stages by other animals (e.g., birds) may have contributed to the wide distribution of some brackish-water and freshwater species. A rich endemic ostracod fauna with large species flocks evolved in ancient lakes (Cytherissa in Lake Baikal, Cyprideis in Lake Tanganyika). Among the ostracods there are scavengers that feed on debris and perhaps carrion, microphages that ingest silt containing bacteria and microalgae, and herbivores that devour diatoms; some of these have piercing mouth parts that suck plant (and animal?) tissues (Paradoxostoma spp). Candona neglecta is known to graze intensively on diatom phytodetritus in the Baltic, and it accounts for almost half of the total food uptake by meiofauna (Ólafsson et al. 1999). In many interstitial forms (e.g., Xestoleberidae), the second antennae are equipped with a complex of spinneret glands that release adhesive fibers from openings in long setae. In some species the detrital food material is fixed for ingestion by secreted fibers. Locally, Ostracoda feeding on settled planktonic diatoms seems to be an important benthopelagic link (Ólafsson et al. 1999). However, generally speaking, the role of ostracods in the marine food web is little understood. They seem to be the preferred prey mainly of small fish (Yozzo and Smith 1995), as well as halacarid mites and some polychaete worms. The lacustrine Cytherissa lacustris and Darwinula stevensoni are among the best-known ostracods and are often investigated in studies of the limnetic meiobenthos. The latter species is of particular interest for genetic studies on its evolutionary long-lasting parthenogenesis (Griffiths and Butlin 1994; Van Doninck et al. 2004). Ostracods are considered to have originated very early by progenesis from unknown crustacean ancestors. Loss of mictic reproduction and sexuality had already developed by the early Mesozoic (Martens et al. 2003). Interstitial ostracods

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from the Cretaceous that closely resemble extant species indicate that morphological stasis has occurred in some lineages, in interesting contrast to the flexibility of other taxa. In spite of their rich fossil record, it is uncertain whether Ostracoda are monophyletic (Horne et al. 2005), and the relations between major subgroups are unresolved; the position of ostracods in relation to other crustacean classes are also disputed. More detailed reading: taxonomy, Elofson (1941); Hartmann and Puri (1974); Athersuch et al. 1989; monograph, Hartmann (1966–1975); freshwater, Meisch (2000); Henderson (1990); Maddocks (1992); Rundle et al. (2002); reproduction, Horne and Martens (1994); Horne et al. 2005; review, De Deckker et al. 1988; Ikeya et al. (2005)

Box 5.8 Bivalved Crustaceans: Sheltered, Adapted, Proliferous Cladocerans (Anomopoda) and ostracods are unrelated crustacean groups, but they do have some traits in common. In both the “water fleas” and the “water shrimps,” a short body of only a few segments is enclosed in two protective shells. The biological and (in ostracods) the palaeontological and even economic consequences of this are considerable. The protection from shells enables brooding, shelter for the offspring, survival in dry periods, and air/water transport over long distances. Parthenogenetic reproduction allows for the exponential growth of populations without any mating partners, even in remote and pristine habitats. Calcification of the shells (in many limnetic ostracods) has resulted in long-term fossilization and paleoenvironmental documentation of geological strata, a feature that is intensively used by oil drilling companies. Thus, the meiobenthic ostracods are probably the only meiobenthic taxon in which more fossilized than recent species are known, and for which an industry employs specialists. These small crustacean groups provide a variety of interesting scientific problems, such as the susceptibility of their reproductive modes to environmental cues. For example, at the onset of adverse conditions (e.g., winter temperatures), the series of parthenogenetic generations is interrupted and bisexual reproduction kicks in. In cladocerans this leads to a complex, seasonally tuned heterogonic generation cycle. Discussions about the origins and adaptive advantages of sexuality vs. asexual/unisexual reproduction in animals cannot exclude the darwinuloid ostracods, in which parthenogenesis without the existence of males has occurred since the Mesozoic without any apparent lack of adaptive potential. In other ostracod groups, (meta)populations of the same species can follow either a sexual or a parthenogenetic lineage, depending on unknown cues. Can meiofauna provide models for understanding one of the fundamentals of biology—sexuality?

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5.8.4


Mystacocarida

This entirely interstitial, marine group consists of some 12 species in only two genera (Derocheilocaris and Ctenocheilocaris). Although they occur locally in considerable numbers in well-accessible beaches, the group is scientifically young. They were originally found on the New England coast of America (D. typicus, Pennak and Zinn 1943), and on the French Mediterranean beaches north of Banyuls-sur-Mer (D. remanei, Delamare-Deboutteville and Chappuis 1951). Despite the close structural relations that bind the animals to the interstitial system and the lack of any distributional stages, populations of D. typicus live on conspecifically on both sides of the Atlantic. Other species have also been discovered along the African Atlantic coast. Ctenocheilocaris has been found along both Atlantic sides and also on Pacific beaches of South America and Australia. Hence, an assumed amphiatlantic distribution pattern can no longer be maintained. All mystacocarids are small (max. 0.5 mm) crustaceans with 11 free body segments that give the vermiform body high flexibility (Fig. 5.32). Equipped with long antennae, a primitively branched mandible and conspicuous claw-like caudal rami, a certain degree of convergence with some interstitial harpacticoid copepods is only superficial.

Fig. 5.32 The mystacocarid Derocheilocaris. (Left) body structure; (right) two animals in their natural environment. (After Lombardi and Ruppert 1982)

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In a detailed study, Lombardi and Ruppert (1982) emphasized the high degree of specialization in the swift movements (fifty times their body length = 2.5 cm min−1) of these interstitial animals (Fig. 5.32). The long exopodites of the antenna and the mandible are held upwards, supporting and pushing the animal dorsally; their endopodite counterparts have the same function ventrally. All other appendages are non-locomotory; the antennules are merely tactile and the caudal claws are perhaps useful during copulation. Thus, locomotion is fully dependent upon an interstitial void system of a given width, while in other surroundings the animals move helplessly. Their occurrence is local and patchy, but in favorable beaches along the Portuguese Atlantic coast, they have been ranked third in overall meiofauna abundance (70 ind. 100 cm−3, Thiermann, unpubl.). They apparently prefer water-unsaturated median sand above the (high) water line that is poor in detritus. Here they are most common in the permanently moist subsurface layers above the groundwater horizon, often living under low-oxic conditions (see Villora-Moreno 1996a). Only rarely have they been found sublittorally. Their occurrence high up on the shore relates to their euryhaline and eurythermal nature (down to 10 PSU; 7–25 °C; Jansson 1966b; Kraus and Found 1975). The reduction of the vascular and respiratory organs, of egg numbers and eyes can be interpreted as consequences of the tiny body size. Secondary adaptations to life in the interstitial system seem to be (a) specialized locomotory organs, (b) development of antennules used as long tactile organs, and (c) abbreviated ontogenesis, omitting the naupliar stage. Conservative features reflecting a long and isolated phylogenesis are the biramous mandibles that are used for their original function, locomotion, as well as primitive traits in the nervous and cerebral system. These features justify the separation of Mystacocarida as a separate albeit small crustacean order, perhaps of progenetic origin. More detailed reading: bibliography, Zinn et al. 1982.

5.8.5

Copepoda: Harpacticoida

Aside from nematodes, harpacticoids are usually the most abundant meiobenthic animals in marine samples. In some tropical beaches they have been found to attain a higher relative share (35%) of the total meiofauna than nematodes (30%). Within the probably monophyletic suborder there are 55 families, of which approximately 17 are species-rich and relevant to this account (Boxshall and Halsey 2004; Wells 2007). 4,000–4,500 meiobenthic species have been described, but Huys et al. (1996) estimate that 30,000 more harpacticoid species exist. From the North Sea and around the British Isles, an area usually considered well investigated, Huys et al. (1996) listed 800 species, many of them only recently discovered. About 950 species belonging to 13 families have invaded freshwater biotopes, and the Parastenocaridae have evolved into typical groundwater forms. The slender, usually rather linear bodies of harpacticoids range in length from 0.2 to 2.5 mm; the thorax is set off only a little from the abdomen. Harpacticoid

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Calanoida Harpacticoida

Cyclopoida

Fig. 5.33 The general body structure of the three suborders of Copepoda (after Siewing 1985)

copepods are distinguished from calanoid and cyclopoid copepods by their short antennules (Fig. 5.33). They are distinguished from calanoids by the position of the articulation between the metasome and the urosome: in calanoids this lies between the last thoracic and the first abdominal segment, but in harpacticoids the last thoracic segment, i.e., the genital segment, is included in the urosome. Since the designation of body parts tends to vary in the literature, it is advisable to carefully review the pertinent definitions before performing identification.

5.8.5.1

Taxonomy and Systematics

The identification of copepod species mostly depends on examining individual appendages, which may be a difficult task for the beginner due to their minute sizes. The flattened pereiopod 5 is of particular taxonomic significance. The two-volume work of Boxshall and Halsey (2004) provides a basis for copepod identification. Dealing mainly with copepod taxonomy, anatomy and evolution, the book by Huys and Boxshall (1991) also has great importance. The marine harpacticoid species described through to 1996 are catalogued by Bodin, with the last update being published (also on diskette) in 1997. There are carefully prepared systematic keys for harpacticoids that provide a very good basis for taxonomic work (e.g., Lang 1988; Wells 2007, also on diskette). For description and identification of the ovoid naupliar stages (Fig. 5.34) of several species, see Dahms (1990, 1992, 1993). General features that are evident even to the nonspecialist and that are valid for entire families do exist in harpacticoids. Hence, the following short characterization of some more common harpacticoid families provides a rough orientation. The stated numbers of taxa are from Wells (2007).

Tachidius Parathalestris

Harpacticoides

typical nauplius

Ancorabolus

Fig. 5.34 Some harpacticoid copepods with different body shapes adapted to various biotopes; body lengths are between 0.2 and 2.0 mm. (Various authors)

Arenosetella

Leptastacus

Tisbe

Porcellidium

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Ameiridae: body shape similar to Miraciidae, but in contrast they have just one egg sac and a small or missing rostrum; primarily interstitial and burrowing species; about 325 species in 35 genera, some living in the phytal; Nitokra, Ameira, Ameiropsis. Ancorabolidae: body characterized by large dorsal spines and epimeral “wings” (chitinous extensions), apparently live covered with mud in deep-sea and polar bottoms, about 60 species in 22 genera; Laophontodes, Ancorabolus, Echinopsyllus. Canthocamptidae: largest harpacticoid family, with 50 genera and about 800 species; body elongate and cylindrical; segments are not distinctly set off from each other; cephalothorax without marked rostrum; one egg sac; primarily freshwater, benthic or phytal, and present in subterranean waters; a few brackish and marine species; Canthocamptus, Attheyelya, Mesochra. Cletodidae: body dorsoventrally depressed or a tube with a rostrum, segments very well separated by deep incisions. The roughly 115 benthic species in 24 genera prefer muddy sediments rich in detritus; especially common in tidal flats and salt marshes; also common in deep-sea muds; present worldwide; some species in freshwater; Cletodes, Enhydrosoma, Limnocletodes. Cylindropsyllidae (33 species) and Leptastacidae (74 species): mainly slender, interstitial forms of major importance in sandy habitats, about 100 species in total. Leptastacus excretes mucopolysaccharides from the caudal glands of its terminal segments, the mucus strands attract bacteria which are subsequently ingested (mucus trap feeding; see Sect. 2.2.3); Cylindropsyllus, Stenocaris. Ectinosomatidae: body spindle-shaped (e.g., torpedo-shaped or vermiform); no marked demarcation between thorax and abdomen; the fifth leg of each sex has a unique structure peculiar to the family; epi- and endobenthic ubiquists, typical opportunists; some 275 benthic and phytal species in 21 genera occurring worldwide from littoral to deep-sea bottoms; Ectinosoma, Arenosetella. Laophontidae: body has distinct segments and varies from being flattened to ovoid to slender and linear; flat forms particularly found in exposed sands; first leg unique and characteristic, with two segmented endopodite terminating in protruding claw which makes the family easily recognizable; one egg sac; common mostly in shallow (50 genera occurring worldwide from littoral to deep-sea bottoms; Amphiascus, Schizopera, Stenhelia. Paramesochridae: body elongate–cylindrical to vermiform, small species, well adapted to the marine interstitial; about 125 species; may be the dominant harpacticoids in sandy shores, Apodopsyllus, Paramesochra, Scottopsyllus. Peltidiidae: body short and broad, dorsoventrally depressed, with large epimeral (lateral) plates; about 90 species in 11 genera live mostly among algae; Alteutha.

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Tegastidae: body short, laterally compressed, like many amphipods (an unusual shape for harpacticoids); cephalothorax has conspicuous ventrolateral flanks; very small abdomen; some 75 species occur epiphytically on algae and in muddy sediments; Tegastes. Tisbidae: body shape cyclopoid (see below), more or less depressed; about 26 genera and about 220 mostly benthic and phytal species occurring worldwide from littoral to deep-sea bottoms; commonly found as epibionts; Tisbe, Scutellidium.

5.8.5.2

Biological and Ecological Aspects

The body size and shape of harpacticoids vary, often in accordance with the preferred biotope (Fig. 5.34). Typical interstitial species live in medium-to-fine sand and have thin, almost vermiform bodies with minute legs. Their uniformly metameric bodies with short, non-protruding appendages and setae give them high flexibility. They seem to swim rapidly through the interstices of the sand via a rapid writhing of the whole body, not just the legs (Arenosetella, Apodopsyllus, Hastigerella, Leptastacus, Parastenocaris). The term “interstitial fauna” was coined for the rich harpacticoid populations in a sample from a British sandy beach (Nicholls 1935). Species living in the phytal often have a stout, sometimes depressed, body with richly setose, often sturdy legs that are well adapted to clinging to plants as well as to swimming (e.g., Peltidiidae, Porcellidiidae, Tegastidae, with Thalestris, Porcellidium, Fig. 8.10). Other phytal forms squeeze their slender bodies through plant thickets (Laophontidae). Northern hemisphere estuaries, tidal flats and salt marshes are typically dominated by the genera Tachidius and Microarthridion, whereas in the southern hemisphere representatives of the Cletodidae and Cannuellidae commonly dominate shallow muddy substrates. A habitat correlation is less obvious in those harpacticoids that live in fine sands or muds. Their bodies are often spindle-shaped, sometimes almost cyclopoid-shaped (see below) or with distinctly set-off segments, and fairly large in size. Their stout legs help to dig in the mud; they prefer the surficial sediment and live mostly epibenthically (Ectinosoma, Cletodes, Tachidius, Paronychocamptus, Microarthridion). Some epibenthic deep-sea forms (e.g., Ancorabolidae) have developed bizarre dorsal spines to anchor mud balls stabilized by mucus as camouflage (Fig. 5.34; Thistle 1982). Species of Stenhelia and Pseudostenhelia are tube-builders living in tubes constructed from sediment (Chandler and Fleeger 1984). Harpacticoids have often been considered mainly “detritus feeders.” Other studies, however, revealed selective grazing on single food particles (bacteria, protozoans and particularly diatom cells) which the animals strip with their mouth parts from detritus, algae and sand grains (Marcotte 1983, 1984; Bouguenec and Giani 1989, Coull 1999; De Troch et al. 2005). Many harpacticoids also seem to devour fresh planktonic diatoms that sink to the sediment surface. Exudates of bacteria and plants (biofilms) are also included in the preferred trophic spectrum of these

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animals (Decho and Fleeger 1988b; Dahms et al. 2007). Bacteria are attracted and concentrated by the mucus that they produce. In some species a selective preference for chemo-autotrophic bacteria as food has been identified based on the very low isotopic signatures measured (Franco et al. 2008). On the other hand, phototrophic sulfur bacteria and cyanobacteria seem to be avoided, or are at least an inadequate food for many coastal species (Souza-Santos et al. 1996). Trophic specialization and a close relationship to the changing pattern of physicochemical conditions in the sediment favor a distinct distribution pattern for many species (Fig. 5.35). This zonation is especially well developed in the tidal soft bottoms (Coull et al. 1979; De Troch et al. 2002). In diatom-feeding species a close distributional correlation has been found with patches of microphytobenthos. Even within the “microalgal trophic niche,” harpacticoid species can exploit the various diatoms species-specifically with different preferences. This extreme partitioning can lead to a microdistribution that changes with food availability and seasonal growth phases (Pace and Carman 1996; Azovsky et al. 2005; De Troch et al. 2005).

Microarthridion littorale Halicyclops sp. Enhydrosoma propinquum Stenhelia bifida Nannopus palustris

Halectinosoma winonae

Schizopera knabeni

Paronychocamptus wilsoni Pseudobradya pulchella

Nitocra lacustris Diarthrodes aegideus

Pseudostenhelia wellsi Robertsonia propinqua

MHW High marsh Low marsh

MLW

Mud flat Subtidal

Creek bottom

Fig. 5.35 The horizontal distribution pattern of harpacticoids along the shore of a salt marsh in the southeastern United States. (After Coull et al. 1979)

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On the other hand, flexibility in nutritional demands enables a shift to a broader food spectrum. Harpacticoids switch from one preferred food source to the other not only at different developmental stages but also sometimes with seasonal or tidal changes (Microarthridion). This flexibility explains why the (mass) culture of many harpacticoid species (e.g., Tisbe spp., Nitokra sp., Tigriopus; Cletocamptus, and others) is a successful and important method in experimental work, pollution monitoring, and fish aquaculture (Sun and Fleeger 1995; Chandler et al. 2004a,b; Brown et al. 2005). Beside food supply, temperature is a prime determinant of harpacticoid occurrence and development. Hatching and growth of the six naupliar and the five copepodite stages are mostly linked to increasing annual temperatures (Nodot 1978). Developmental time in situ is about 2–3 months in many harpacticoid species (Fleeger 1979), but can last a year in cold-water inhabitants. A prolongation also frequently occurs in groundwater species. Many limnetic and, so far, one marine species have been noted to develop cysts that are resistant to adverse conditions. Environmentally induced modulation of the developmental time can be accomplished by retarding naupliar development or a diapause phase during the copepodite phase. Parthenogenesis has also been reported for a few freshwater copepods. Species in crevices of Antarctic ice had copepodite resting stages (Dahms et al. 1990). On the other hand, Drescheriella glacialis from Antarctic sea-ice seems to compensate for the extremely cold temperatures by having a rapid life cycle, similar to the r-strategists of more temperate habitats (Bergmans et al. 1991). Most harpacticoids are sensitive to oxygen depletion, which restricts their occurrence in many sediments to the upper layers and favors epibenthic life. Nevertheless, in winter, migration into deeper sediment layers has been observed, provided there is enough oxygen available. In polar regions, populations of Tisbe furcata migrated during the winter months into the sea-ice layers, where they fed on the rich supply of algae (Grainger 1991). The often epibenthic harpacticoids are less sediment-bound than nematodes. Hence, they become easily disturbed by (tidal) currents, agitation during storms, or by the burrowing activities of macrobenthos (see Sect. 7.2.1). However, harpacticoids are also the classical “emergers” among the meiobenthos. Their morphology and setation of swimming legs discriminates them from persistent species (Thistle and Sedlacek 2004). Active emergence linking the benthic with the suprademersal biomes and the subsequent drift in the nearbottom water layers is influenced by favorable light and hydrodynamic conditions and often follows a diurnal rhythm (Bell and Sherman 1980; Palmer 1988). This behavior (Armonies 1989b; Buffan-Dubau and Castel 1996) leads to intensive dispersal, redistribution and colonization of new or disturbed habitats (Walters and Bell 1994). Despite this periodic “hyperbenthic” lifestyle, fairly consistent small-scale distribution patterns can be observed, although their formation is not yet fully understood. Some biological and physical factors are probably responsible for active and selective re-entry into the sediment, leading to non-random aggregations and patches in harpacticoids. In a comprehensive literature analysis of the distribution patterns of shallow-water harpacticoids,

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Chertoprud et al. (2007) found a set of six “life forms” that retained their species composition and suggested that the structure of the sediment and salinity gradients were controlling factors. High harpacticoid abundances are mostly encountered in shallow flats and lagoons with muddy, detritus-rich sand (from several hundred to several 1,000 specimens per 10 cm2), where they can even be the dominant taxon (e.g., in some areas of the southern North Sea). A density-dependent distribution was suggested by Sach and van Bernem (1996) for tidal flat harpacticoids, with more random patterns at low population densities and a highly patchy distribution at high densities. While the species composition can be rather monotonous in the eulittoral (about 20 species per sampling area), similar bottom types in the deeper sublittoral tend to show increased diversity (60–70 spp.), although with decreasing abundance. In deep-sea sediments there are often only 1–10 specimens per 10 cm2, but high diversity is maintained. Life history studies of meiofauna are often based on harpacticoid copepods (see Sect. 9.3.2) because some taxa (e.g., Tisbe or Schizopera) are easily cultured or because populations can be followed in the field due to their morphologically distinct ontogenetic life stages (see compilation by Ferrari and Dahms 2007). Generation times can be as short as 10 and 18 days in the field and can be accelerated in the laboratory. Compared to nematodes, the generally greater sensitivity of harpacticoids make them good indicators of pollution (Coull and Chandler 1992; Brown et al. 2005). In an extensive survey of the North Sea meiofauna (Huys et al. 1992), five well-defined harpacticoid groups could be discerned, based mainly on sediment structure and the impact of pollution. The frequent epibenthic occurrence of harpacticoids makes them a preferred prey for many small, often juvenile demersal fishes, carnivorous crustaceans (e.g., shrimps and their larvae) and polychaetes. In sandy tidal flats, but also in coral reefs, harpacticoids play a decisive nutritional role for small fish such as gobiids (Sect. 9.4.2; Gee 1987; Coull, 1990, 1999; Zander 1993; McCall and Fleeger 1995; Aarnio and Bonsdorff 1997; Fujiwara and Highsmith 1997). Derived from their preferred diatom food, harpacticoids have high fatty acid contents, which, in turn, seem to determine their nutritional value to fish (Coull 1999). The great diversity of copepods with their numerous parasitic families has been grouped in many different ways; the comprehensive cladistic phylogeny by Huys and Boxshall (1991) classifies Harpacticoida as a monophyletic group that is distant from the Cyclopoida. However, within the Harpacticoida the phylogeny remains debated. According to Noodt (1971) and Marcotte (1986b), harpacticoids with a more roundish and stout body shape (e.g., Tachidius, Tisbe) represent the more primitive type, and the vermiform sand dwellers are considered secondarily derived. This notion certainly needs molecular confirmation. More detailed reading: systematic monographs and identification keys, Lang (1988); Wells (2007), Bodin (1997); anatomy and phylogeny, Huys and Boxshall (1991); development, Ferrari and Dahms (2007); ecological reviews, Hicks and Coull (1983); Gee (1989); dormancy, William-Howze (1997).

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Box 5.9 Harpacticoid Copepods: Bridging the Benthic Boundary In the multistory house of meiobenthos, harpacticoids usually live in the top stores and on the roof, so that they are always ready to make small excursions into the water layer above. In the near-bottom water layer, they prefer the phytal, the thickets of plants. Why do they favor this surfacelinked occurrence despite the associated enhanced risk of predation and physiographic extremes? At least in shallow reaches, it is probably the availability of the preferred food of many harpacticoids, diatoms, and freshly sedimented (phyto)detritus that compensates for these extra risks. As a result of this adaptive linkage, the developmental cycles of some species in tidal flats are concordant with the onset and distribution patterns of light-dependent diatom blooms. Life around the benthic boundary also has another advantage: it partitions the trophic niches of many harpacticoids from their most important, more sediment-bound competitors, the nematodes. However, the harpacticoid situation is not that easily understood. The populations of some species get regularly (and not only in shallow tidal waters) suspended in currents. Beside this suspension some harpacticoid species have been found to actively emerge into the water, especially at night and in calm weather. We cannot really perceive how the distributional advantages can compensate for the risk of drifting away in the water column, the risk of losing contact with adequate sediment and food, and the risk of being devoured by many plankton and nekton predators. Indeed, most harpacticoids are closely linked to the sediment conditions: despite their occasional excursions into the water body, we often find a clearly zoned distribution with defined local patterns and patches whereas resuspension would bring about rather homogeneous and accidental settlement. However, to gain a deeper understanding of their migrational and resettling phenomena we need to perform thorough autecological experiments: sequential drift and settlement studies; tests on the mobility behaviors and homing ranges of individual specimens; analyses of their sensing capacities. Ideally, we need to observe the functioning animals at eye level, not from above as a tiny mass of particles or portions of chemical energy. This holds true not only for harpacticoids. The drifters and emergers among them only serve to highlight our limited understanding of functioning processes in and among the meiobenthos.

5.8.6

Copepoda: Cyclopoida and Siphonostomatoida

This cyclopoid subgroup of copepods is widely believed to be restricted to planktonic life in freshwater. This is misleading since many cyclopoid copepods live on and in the sediment or the phytal. The Halicyclopinae and most Cyclopininae (about 30 genera in total) are marine taxa. They are quite common in the southern

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North Sea (Huys et al. 1992), but have also been found in eastern North America and in Brasilian beaches. While the stout bodies of most cyclopoids are adapted to living epibenthically or burrowing in muddy sediments, many of the smaller forms represent typical interstitial meiobenthos with vermiform bodies (e.g., Psammocyclopina) and reduced egg number (Halicyclops, Cyclopina, Metacyclopina). They are structurally well adapted to the mesopsammal and show some convergence with the interstitial harpacticoid family Paramesochridae. The genus Halicyclops can be abundant in brackish-water sediments, and in boreal estuaries it can be a dominant member of the meiobenthos. Most freshwater cyclopoids live epibenthically among macrophytes, with all transitions towards an endobenthic life. About 25% of all limnetic cyclopoids (i.e., about 160 species) can be considered endobenthic, subterranean or even troglobitic species. Aside from the reduction in body size, many of these species have also reduced their number of eggs (e.g., the troglobitic Eucyclops teras). The most specialized species have even lost their typical egg sacs, such that they carry their few eggs on long filaments (Speocyclops, Graeteriella). Some genera are restricted to the phreatic sediments of riverbeds and shores (Haplocyclops, Speocyclops racovitzai, Eucyclops subterraneus). In contrast with harpacticoid copepods, most Cyclopoida are predaceous carnivores that feed on meiofauna of an equal size or even larger. More detailed reading: Rundle et al. (2002). Copepoda Siphonostomatoida: Several species of one family, the Dirivultidae, are associated with hydrothermal vent biotopes (see Sect. 8.4.7). Here they live, probably as bacteria grazers, in the thickets of mussels, snails or polychaete tubes. Some even occur in the gill chambers of vent shrimps.

5.8.7

Malacostraca

This well-defined crustacean taxon emerges from morphological and molecular analyses as a monophyletic group, although the relationships within the malacostracan orders are not stable (Giribet et al. 2005). More commonly known by their macrobenthic representatives (Decapoda and Peracarida), there are also meiobenthic forms in almost all groups of malacostracan crustaceans. Some represent isolated, specialized miniatures of a speciose group of larger-sized animals (e.g., Isopoda, Amphipoda). Others represent the sole survivors of rare relict groups, often living in refuge biotopes (see Sects. 7.2, 8.7). The specialized miniatures mostly have typical convergent features that secondarily adapt them to a meiobenthic and particularly to an interstitial life. The relict forms, however, represent a composite of specializedderived and archaic-primitive features (e.g., Syncarida, Thermosbaenacea). Along with their often enigmatic zoogeography, this makes the few existing species a particularly rewarding study target for the phylogenetically interested zoologist. Among the malacostracan crustaceans mentioned in the following sections, many exceed the formal size limits that separate meio- from macrobenthos. However, they do live in habitats typical of meiobenthos, their ecology is typically

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meiobenthic in many respects, and they have adaptations that are characteristic of the meiobenthos. Therefore, they are considered an “ecological meiobenthos” here, justifying their inclusion in this book. Their zoological, geographical and phylogenetical relevance would have made this book incomplete had they been omitted.

5.8.7.1 Syncarida This little-known crustacean superorder contains two orders, the Bathynellacea and the Anaspidacea, which lead a mostly subterranean life. While they are currently largely restricted to freshwater habitats, their fossilized ancestors are known to have dwelled in the marine strata of the Carboniferous. It is believed that they emigrated via the coastal, brackish groundwater. While almost all Bathynellacea are stygobionts, some species of the Anaspidacea that live superficially and in moist plant thickets should be considered stygophiles. The distributions of many syncarid crustaceans, especially the anaspidaceans, mirror the extent of the old supercontinent of Gondwana, corresponding to the recent Southern Hemisphere. Here, they are apparently still radiating. Bathynellid species are found globally; many of them appear to have a worldwide distribution. The increase in species descriptions is considerable and the group amounts now to 235 species. While the Bathynellacea have been investigated more thoroughly and some ecological details beyond their morphology and zoogeography have been described, little is known about the Anaspidacea. Syncarid morphology (Fig. 5.36a) consists of both primitive and derived features. This makes them, on the one hand, living representatives of primitive malacostracans (similar to Palaeozoic fossils), while, on the other hand, they are adapted convergently to the freshwater interstitial by developing a small, cylindrical and flexible body with uniform segments and reducing the carapace. The original eye peduncle is often abandoned, resulting in sessile eyes; sometimes the eyes become rather rudimentary. Bathynellacea: Some Bathynellacea with a body size of 0.5 mm represent the smallest malacostracans (Fig. 5.36a). Eyes and statocysts are reduced. They have retained a furca and styliform uropods. Bathynellaceans occur worldwide in groundwater systems, in wells and in river sands, where they appear to feed on bacteria and fungi colonizing the sand grains and detritus particles. Schminke (1981) showed that the group has clear homologies to the zoea/protozoea stages of the Eucarida (Penaeida) and thus suggested that it developed by progenesis from common ancestors of these other malacostracans. Like their penaeid relatives, bathynellids were originally larger in size (one species of length 50 mm still exists in Tasmania) and probably had free larval stages. Miniaturization and progenetic development enabled them to enter the mesopsammal of river mouths and from there the groundwater system, thus reducing competition from more “modern” crustaceans. Bathynellacea consist of two families, the Bathynellidae and Parabathynellidae, which have circum-mundane distributions with overlapping areas between the 10 and 20° longitude girdles (Schminke 1973).

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250 µm Syncarida: Bathynella

1 mm

a

Syncarida: Psammaspides

500 µm

b

Pancarida: Thermosbaena

Fig. 5.36a–b Representatives of the Syncarida (a) and Pancarida (Thermosbaenacea) (b) (a After Schminke 1986; b after Delamare-Deboutteville 1960)

Bathynella: 1–2 mm long, found in European and Californian groundwater; the first bathynellids, found in fountains. Allobathynella: mostly in Eastern Asia, includes many species formerly assigned to Parabathynella. Hexabathynella: cosmopolitan, mostly found in rivers; also found in brackish shore sand. Habrobathynella: India, Madagascar, in river sediments. Thermobathynella: Brasil, Central Africa, in thermal waters (55 °C) and river sand. Anaspidacea/Stygocaridacea: A relict group of about 20 known species grouped into five families restricted to the southern continents. Similar to some Palaeozoic fossils; several of them have archaic anatomical traits and give a picture of a primitive malacostracan. Psammaspides, Stygocarella: stygobiotic in New Zealand and Australia respectively. Micraspides (0.8 mm) and Koonunga (some species up to 8 mm): from crayfish burrows and moist mosses in Australia; furca reduced.

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Stygocaris Noodt: 1.5 mm long, found in the mesopsammal of South America and Tasmania; caudal furca only retained rudimentary. New reports of stygocarid crustaceans from Australia and New Zealand indicate that this group, originally established as a separate syncarid order, represents a family (“Stygocaridae”) within the Anaspidacea. More detailed reading: taxonomy, zoogeography, Noodt (1965); Pennak and Ward (1985); ontogeny, phylogeny, Schminke (1973, 1981, 1986).

5.8.7.2 Thermosbaenacea, Pancarida These rare, meiobenthic malacostracans (largest species 4 mm, Fig. 5.36b) are known from about 35 species within three families. They are related to the Peracarida (see following section). Monodella: about ten species, they have a “north amphiatlantic” distribution from the Caribbean to Italy and the near East. The vermiform species are very euryoecious, occurring in sands and muds of both marine and freshwater biotopes. Halosbaena (1.8 mm): the only marine form with a “south amphiatlantic” distribution, mostly found in coral rubble. Tethysbaena: first discovered in a brackish karst outlet in Southern France; now about 20 spp. of vicariant distribution along the Atlantic coasts, mostly in the Northern Hemisphere; some in the coastal groundwater. Thermosbaena mirabilis: a monotypic species found in the sediment of thermal springs (42 °C) in Tunisia; five pairs of pereiopods only. Instead of typical peracararid oostegites, Pancarida have developed a dorsal brood pouch or “marsupium” beneath the posterior part of the wide carapace which covers the dorsum up to the fourth free thoracic segment; the animals are blind. The distribution center of Pancarida currently consists of refuge biotopes such as marine caves and sometimes the groundwater system. Probably several independent lines emigrated from the Oligocene shorelines of the Tethys Sea via brackish groundwater and colonized the crevices of subterranean freshwater aquifers (some Tethysbaena species). Ontogenetically, in parallel with the Bathynellacea (see above), Pancarida are related to the mysis stage of penaeid shrimps (Decapoda), which indicates a progenetic origin too (Coineau 2000). More detailed reading: Monod (1940); Stock (1976); Wagner (1994).

5.8.7.3

Peracarida

In several phylogenetic lines, peracarid crustaceans have independently developed meiobenthic forms. The whole taxon (Mictacea), a good part of it (Tanaidacea), or just some specialized forms (like in Isopoda and Amphipoda) may be meiobenthic.

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Mictacea. First discovered in 1985, there are now two monotypic genera: Mictocaris halope Bowman and Iliffe 1985, 3–3.5 mm long, from marine caves of Bermuda (Fig. 5.37a); and Hirsutia bathyalis Sanders et al. 1985, from the deep-sea benthos. These homonomously segmented crustaceans have, like all true peracarids, a ventral marsupium for egg brooding. They have a combination of body features that do not fit with any other existing peracarid order; they are distinguished by one unique character, their eyestalks, which lack functioning visual elements. The isolated occurrence of Mictacea in disjunct biotopes points to a long, independent evolution. Mictocaris has been observed to live epibenthically, swimming with the exopodites of its pereiopods. Spelaeogriphacea. An isolated monotypic taxon; Spelaeogriphus lepidops, 6–8 mm long, blind, from a cave near Cape Town, South Africa, where it lives in pools and a stream (Fig. 5.37b). This troglobitic group is phylogenetically close to Tanaidacea (see below). It is distinguished by the well-developed exopodites on all but the last thoracopods. Females have a ventral marsupium.

0,5 mm Mictacea: Mictocaris halope

1 mm Spelaeogriphacea: Spelaeogriphus lepidops

1 mm Tanaidacea: Gollumudes botosaneanui

Fig. 5.37 Representatives of meiobenthic Peracarida: Mictacea, Spelaeogriphacea and Tanaidacea. (Various authors)

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Tanaidacea. A good part of this speciose and widespread marine group comprises numerous small species of meiobenthic size (a few mm in length, the smallest measuring only 0.8 mm) and with vermiform, narrow bodies. Distributed worldwide, they prefer muddy sediments (where they are tubicolous) and the phytal; only a few live in the interstitial of coarse sand. They occur frequently in deep-sea bottoms and can be among the most abundant crustaceans. Tanaissus lilljeborgi: 2.5 mm; Heterotanais oerstedti: 2 mm, occurs in muds of the North Sea; Anarthrura simplex: 1.5 mm, Atlantic Ocean; Psammokalliapseudes: from the mesopsammal off Brasil; Gollumudes botosaneanui: from beach sediment in Curacao (Fig. 5.37c). The tanaidacean carapace is highly reduced, allowing for high flexibility of the body, a trend enhanced by the numerous free and rather homonomous segments. This is important when digging U-shaped tubes in muddy sediments. In sandy bottoms and among algal mats the body is particularly vermiform; here they stabilize their tunnels by spinning silk from glands at the tips of peraeopods 1–3. All thoracopod exopodites are absent. The second thoracopod has a large distal chela. In some tanaidaceans, sex determination is phenotypic and complicated, sometimes with heteromorphic genders. In some families, different types of males and protogynous hermaphrodites have been described (a rare exception in malacostracans!). Most representatives are detritivores and scavengers, also feeding on diatoms; however, some predaceous species grasp nematodes and harpacticoids with their chelate legs. In shallow waters the tanaidacean abundance can reach densities of 100–1,000 individuals per 100 cm2, but their distribution is extremely patchy. In many areas tanaidaceans are common food for polychaetes, malacostracans and small fish. When numerous, they represent an important member of the marine benthic food chain. Isopoda. This large and diverse order has developed numerous meiobenthic forms through different adaptative lines known as the “micro-isopods” (Fig. 5.38). Structurally divergent, they belong to various suborders, superfamilies and families which have adapted to an epibenthic, interstitial–mesopsammic or endobenthic life. The groundwater species are often only 1 mm long (which is an unusually small size for the complex body organization of Malacostraca), but many species are 2–3 mm long, and yet they are well adapted to living in void systems, particularly those of river gravels (see Sect. 8.7.1), where they mostly feed on detritus. Large deep-sea isopods seem to selectively feed on Foraminifera. Many meiobenthic isopods belong to the superfamily Janiroidea; the genus Microcharon alone contains > 70 species. Microcerberoidea represent about 50–60 spp. of Microcerberus; all are meiobenthic in size and are probably of progenetic origin. Within the Cirolanidae (Flabellifera) there are about 45 stygobiotic freshwater species. The meiobenthic isopods from sand or gravel often have modified the typical dorso-ventral depression of the body into an almost round, vermiform shape with rather uniform segments. The resulting slender body is highly flexible. Reduction of eyes, pigments and long appendages occurs frequently in the numerous troglobitic and interstitial species, which all exhibit strongly thigmotactic behavior. In Stenasellus

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1 mm Cruregens frontanus

Angeliera phreaticola

300 µm

250 µm Microcerberus sp. Fig. 5.38 Characteristic representatives of meiobenthic Isopoda. (Various authors)

the lifespan and the intermolting periods appear to be unusually long. In Microcerberus, with reduced oostegites, eggs are deposited directly into the voids of the sand. Another developmental line is evident in the epibenthic forms. With their flattened bodies (large epimeres) and long legs they can easily move over soft surfaces. Microparasellidae: five genera with numerous species that are all only a few mm long. Their general distribution pattern corresponds to the region of the former Tethys Sea. Microparasellus lives in the shallow marine interstitial, as well as in freshwaters of European karstic regions; it is not present in America. Angeliera phreaticola occurs in the brackish coastal groundwater of Mediterranean beaches, as well as in surrounding freshwaters; it was also found off Madagascar. Microcharon is mostly known from the groundwater system, but some archaic forms are also marine and appear to be distributed worldwide: they have been found off Roscoff (coast of Brittany), along Mediterranean coasts, along the Gulf of Mexico coast off Belize, and on the Galapagos Islands. Microjaera lives sublittorally off Banyuls-sur-Mer (Mediterranean) and off Roscoff, France. Other taxa include the genera Protocharon and Paracharon.

5.8 Crustacea

197

Stenasellidae: with several genera that live in continental groundwater aquifers in all continents; Stenasellus spp. Microcerberoidea: the genus Microcerberus, containing species that are often just 1 mm long, occurs worldwide in continental groundwater systems, as well as in caves and aquifers of karstic bottoms. It also contains interstitial marine and coastal brackish species. This subterranean taxon is probably related to the epigean group Stenasellidae (Asellota). Phreaticoidea are restricted to subterranean freshwaters of the southern hemisphere; their bodies are strongly vermiform and attenuated. Neophreaticus, from New Zealand. Anthuridea: the center of this group seems to lie in the Caribbean and the IndoPacific. The species are mostly marine or live in freshwater in the vicinity of oceanic coastline. With their slender bodies they dig in the sediments, often occurring in tubes of polychaetes and in the culms of seagrasses, where they live as predators. The stygobiotic, often blind groundwater forms are sometimes only 1 mm long. Most-known genus: Cyathura. Flabellifera, Cirolanidae: these are mostly stygobiotic species with circumMediterranean and circum-Caribbean distributions. With their flattened bodies and reduced sizes (often only 2–3 mm long), they are typical of karstic habitats, where they live mostly as detritivores or scavengers. Cirolana, Speocirolana, Arubolana. Oniscoidea: Nannoniscus is a small (1–2 mm long), flattened deep-sea isopod living in the surface layer of the sea bottom. Most of the circum-Mediterranean meiobenthic isopods have been found in both marine and groundwater habitats, which led to discussions about whether they represent relict forms from the former Tethys Sea. Did they keep their old distributions, but, after the Tethys Sea had regressed, slowly adapt in several independent lines to brackish and finally to freshwater conditions? The alternative would be that the marine forms migrated independently and actively through crevices, often reaching deep down into the groundwater passing through the brackish mesopsammon of many beaches (see Chap. 7). More detailed reading: Faunistic and\ zoogeographic aspects, Delamare Deboutteville (1960); Botosaneanu (1986b). Amphipoda. Like isopods (see above), the dwarf forms of several amphipod orders appear to have developed independently. Even the morphological adaptations are fairly convergent with isopods, sometimes modifying the typical laterally compressed body shape of an amphipod into a roundish, slender body (Fig. 5.39). Some of the morphological species are extremely euryhaline, enabling them to live in marine as well as limnic habitats (different haline capacities in divergent physiological species or just different populations? See Kinne 1964). The data on the occurrence of meiobenthic Amphipoda do not yet allow us to draw a realistic picture of their geographical distribution. There seems to be a tendency for most marine meiobenthic amphipods to live in the southern hemisphere. Many freshwater forms are found in identical genera or even species in the Old and New Worlds, suggesting that these groups are very old, and originated on

198


500 µm Niphargellus sp.

250 µm Ingolfiella sp.

500 µm Bogidiella sp.

Fig. 5.39 Characteristic representatives of meiobenthic Amphipoda. (Various authors)

Gondwana or on the archaic Laurasian continent before they broke up, which formed the Atlantic Ocean. Meiofaunal amphipods live both in the sea and in freshwater, either interstitially in sands (rarely in mud), and often in rubble from encrusting algae and corals. Many also occur in the culms and holdfasts of seagrass and algae and belong to the phyton. Globally, many small amphipods live in subterranean biotopes like groundwater, springs, caves and river beds.

5.8 Crustacea

199

Although the sizes of small Amphipoda may exceed the traditional limits that separate meio- from macrobenthos, they beautifully exemplify typical adapatations for meiobenthic, and in particular interstitial, life (Fig. 5.39): minute sizes (for the group), vermiform bodies with reduced epimeres, 1–2 eggs, reduced eyes, no pigmentation, and high flexibility of the uniform body segments. Ecological studies on meiobenthic amphipods (as well as isopods) are scarce, but it can be inferred that most of them feed on small detritus particles and bacterial films on and in the sediment. Niphargidae: Mostly found in subterranean waters of the holarctis. Niphargus and related species. Within this large group, widely known from European groundwaters, most species have kept the typical amphipod morphology. However, there are some that are small in size (only 2–3 mm) and that live in the interstices of sand. These typically possess a modified body organization: the slender, vermiform type with short legs (e.g., Niphargellus), or the stout, short type that can roll up its body. Numerous species are adapted to brackish-water conditions. Microniphargus: 2 mm, from wells in western Germany and Belgium. Psammoniphargus: from the groundwater of the former Yugoslavia and Brazil. Crangonyctidae: Most representatives have a holarctic, particularly American arctic, distribution, and are often larger than the generally accepted meiobenthic size range, although some typical stygobionts have attenuated bodies only 1–2 mm in length. All species are cold stenothermal, photonegative and mostly lack eyes and pigments. They occur in springs and caves in karstic areas of the southern and central United States, but have also been found in India, Eurasia and recently in Africa. The stygobiotic forms are clearly derived from surface-living ancestors. Crangonyx spp.: Occur mostly in the United States, only a few are known from Eurasia. Synurella spp.: Hypogean as well as epigean forms, mostly from eastern Europe, some found in Asia; smallest species are 1.5 mm long; found in springs, subterranean waters, and in the mud in creeks. Stygobromus spp.: mostly subterranean and from the United States, but also found in (western) Asia. Bogidiellidae: currently more than 100 species in 35 genera with global distribution. Bogidiella spp. are typically subterranean animals. Their small sizes (often only 2.5 mm length) probably result from progenesis; they are found in caves, springs, river beds and groundwater, but occasionally also in the marine interstitial (B. chappuisi), mainly in Europe and South America but also in India. Ingolfiellidea: Ingolfiella: About 25 species of this strongly modified and progenetic group of amphipods are described. Many are only 1–3 mm long and have vermiform bodies that lack oostegites in the females. They are found in refuge biotopes like caves, continental and coastal groundwaters, but also in deep-sea bottoms. Their vermiform bodies best demonstrate typical adaptations to the lebensform of the mesopsammon. There are also species that are meiobenthic in size in other amphipod families living in both marine and freshwater habitats, e.g., Uncinotarsus pellucidus (Aoridae), which is 1.5 mm long. Found in the shallow sublittoral off Roscoff, it is a typical interstitial form with characteristic adaptations to the mesopsammal. Salentinella (1.6 mm) is a characteristic element of the Pyrenean groundwater fauna.

200


More detailed reading: faunistic and zoogeographic aspects, Delamare Deboutteville (1960); Botosaneanu (1986a); monographs, Barnard (1969, marine species), Barnard and Barnard (1983, freshwater species).

Box 5.10 Interstitial Malacostracans: Paradigms for Evolutionary Tales Upon hearing about Malacostraca we often envision lobsters, shrimps or perhaps gammarid amphipods. It is hard to believe that millimeter-small, vermiform, blind creatures that live deep in the groundwater, in karstic caves, in thermal springs or in sands of remote oceanic islands are also Malacostraca. Descendants of various classes with very different body structures and appearances, they all have to deal with the same constraints when adapting to the world of narrow voids in sand or gravel. The evolutionary outcome was a rather uniform, narrow and flexible body; not an easy task considering the normal sizes and body structures of the “higher” crustaceans with their heteronomous sections (tagmatization), bulky carapaces, long antennae and protruding walking legs. So how did they become small? They remained at an early and tiny ontogenetic stage but became mature: neoteny is fairly frequent in mesopsammic malacostracans. Eyes and colors were useless in the dark and so were reduced; eye stalks as well as protruding epimeres or oostegites were hindrances and were often reduced; the result was “smoothened,” wormlike, whitish and minute crustaceans with short legs. Although affiliated to groups as different as isopods, amphipods or tanaids, the student might easily lump them into one taxon—convergence par excellence! Another interesting feature of these micromalacostracans is their physiological evolution: within one genus, even within the same (morpho)species, both marine and freshwater forms exist (Ingolfiella, Microparasellus, Bogidiella chappuisi). This haline versatility, which is rare among other groups, may have opened up archaic pathways along which many of these originally marine interstitial malacostracans invaded the subterranean aquifers of the continents via (tropical?) coastal groundwaters. In many cases these evolutionary steps must have been taken in pre-Jurassic times when the uniform southern supercontinent Gondwana still existed, when Africa was still connected with Madagascar, when Australia and New Zealand were still parts of Laurasia (many bathynellids, anaspidaceans, e.g., Stygocaris, or amphipods, e.g., Bogidiella spp.). In the Tertiary the coastal groundwater system of the tropical Tethys Sea served as a bridge between shores that are today separated by a deep ocean (meiobenthic isopods). Thus, the present distributions of many subterranean freshwater malacostracans represent prehistoric patterns and mirror ancient zoogeographical connections. Migrations from the shallow marine interstitial into the continental groundwater, and often into caves, are interpreted as refuge routes for those taxa that are no longer competitive in the evolutionary “hot spots” of shallow coastal seas. Therefore, the study of stygobiotic and cavernicolous micromalacostracan groups in comparison with their radiating, usually larger, relatives from the surface often provides a way of investigating evolution (particularly regressive evolution) at work.

5.9 Chelicerata: Acari

5.9

201

Chelicerata: Acari

The small body size of mites has enabled them to contribute several independent subgroups to the meiobenthos (Fig. 5.40). The most successful is the superfamily Halacaroidea, with the family Halacaridae. In several independent lines, some 50 genera and more than 1,000 species from this family have invaded marine and brackish habitats since the Mesozoic (Bartsch 1996, 2004, 2006) and live preferably among plants and hard substrates. They even colonized with some 60 species freshwater biotopes (Limnohalacaridae). Other suborders of mites live mainly in the bottom substrates of lakes and rivers; most of them belong to the Hydrachnidia (for details see Di Sabatino et al. 2000). Representatives of some other mite groups can be encountered in marine sands and algal epigrowth. The Oribatei, with their uniform brownish color and heavily sclerotized dorsal shield represent a suborder that normally lives in terrestrial soils. The famous vermiform Nematalycus nematoides (Trombidiformes) was found in a beach near Algiers (Coineau et al. 1978, Fig. 5.40); its structural convergences with other insterstial groups are remarkable. Within the Rhodacaridae (Mesostigmata) there are two genera containing species that are regularly found in marine intertidal sand (e.g., Rhodacarellus). The slender bodies of some of these interstitial species seem well adapted to moving through the interstices of the sediment. Pontarachnidae, related to freshwater mites, are characteristic representatives in marine sediments and dense epigrowth in warm water areas.

5.9.1

Halacaroidea: Halacaridae

More than 1,000 species of halacaroids are known, most of which are meiobenthic in size and are inhabitants of marine sediments, the marine phytal and barnacle epigrowth. The family Halacaridae alone harbors >200 known species, and there is reason to assume that this represents only a small percentage of the real number. Some halacaraid species are specialized inhabitants of subterranean groundwater with wide distributions. Halacaroid mites are easily recognized by the division of their body into the “gnathosoma” carrying the chelicerae and pedipalps and the “idiosoma,” with the two first pairs of legs directed forwards and two pairs of posterior legs directed backwards. The distance between these laterally attached legs can become rather wide and the body can attain an elongated shape, thus adapting the species to a life in the interstices of sand (e.g., Anomalohalacarus, Fig. 5.40). The chitinous body cuticle can develop a pattern of sclerotized plates ornamented with numerous setae. The positions of the setae on the idiosoma and the legs and the shape of the plates are reliable diagnostic features, as is the articulate structure of the legs and the shape of the claws. Interstitial forms are either soft-bodied and slender with reduced body plates (Anomalohalacarus), enabling them to squeeze through the narrow voids, or stout, cylindrical and strongly armored with heavily scIerotized plates and legs (for interstitial forms), providing protection against sediment pressures (Acaromantis). In unfixed specimens, the remains of plants in the gut, visible

HALACARIDAE

100 µm

Halacarellus

Anomalohalacarus

100 µm

Ameronothrus ORIBATIDAE

200 µm

Fig. 5.40 Some typical representatives of different families of Acari. (Various authors)

Acaromantis

100 µm

300 µm

RHODACARIDA

Rhodacarus roseus

NEMATALYCIDAE

Nematalycus

100 µm

202 5 Meiofauna Taxa: A Systematic Account


203

through the more or less transparent bodies of many halacaroids, make the idiosoma a characteristic color (dark green, reddish, brownish–black). Despite their relatively clear-cut diagnostic characters, halacaroids are rarely investigated, even though they represent common members of the meiofauna that regularly occur in samples from almost all biotopes, whether littoral or deep-sea (see below). The genus Copidognathus alone comprises about one third (> 300) of all halacaroid species. Other genera which are frequently encountered in boreal shores (tidal flats) are Halacarellus, Lohmannella, Acarochelopodia, Actacarus, and Rhombognathus (Fig. 5.40). Biological and ecological aspects. Most halacaroids reproduce only once (semelparous). The female takes up a spermatophore deposited by the male. They have 10–20 eggs (the mesopsammic species have only one to a few eggs); after a relatively long developmental time one egg reaches maturity at a time. There is one larval stage, which has only the first three pairs of legs, followed by 1–3 nymph stages in which the last pair of legs develops. In summer, samples often contain only juveniles; adult halacarids predominate in winter. This sometimes makes identification difficult. Average life span is 5–9 months. Their low reproductive potential and their very limited mobility make halacarids slow colonizers after events that destroy the population. Halacarids are hardy creatures, able to live in a wide range of biotopes without too many morphological variations of their general body organization. Although they seem to prefer defined conditions of moisture, pH or salinity (Bartsch 1974), they can withstand a range of salinities, from freshwater to 30% S, while maintaining full activity. This capacity enhances the overall abundance of halacarid mites in brackish biotopes. One requirement for this amazing ecological resistance, however, is good oxygen supply, since most mites are sensitive to hypoxic conditions and do not occur in hypoxic and sulfidic muds. Mites can also survive extremes of temperature, desiccation and (hyper)salinity via an inactive stage during which they reduce their respiration significantly. After the fixation of meiofauna samples halacarids tend to move their legs for a wearily long time! Halacarid mites occur in all kinds of interstices. Aside from the mesopsammal, they prefer the thickets of mussel beds and kelp holdfasts, and thrive among cirripede aufwuchs or colonies of hydrozoans or bryozoans. Halacaroid community composition seems to be mainly determined by micro-environmental factors and not so much by wave exposure or the nature of the aufwuchs substrate (Somerfield and Jeal 1995). Mites crawl characteristically slowly and somewhat awkwardly. The abundant phytal forms climb with particularly strong clinging appendages, while the often very small (200 µm) and slender mesopsammic forms have a rather flexible, concave body shape that attaches better to the sand grains (e.g., Anomalohalacarus). Those species living in exposed and agitated coarse sand protect their roundish bodies with armored, solid plates and keep their legs tightly pressed to the body in cuticle depressions. 90% of all halacarids live in shallow shelf biotopes: the phytal of boreal and temperate regions is preferred by some (e.g., Rhombognathinae). In algal mats and Enteromorpha canopies halacarids can make up 90% of all meiofauna, in the

204


mesopsammal of medium sand they still comprise 15%, while in fine sand with a limited supply of oxygen this figure reduces to about 5% (Fig. 5.41). In this case, they never enter the deeper horizons and tend to live epibenthically. Silty muds are devoid of halacarids. In the epigrowth of larger animals (crustaceans, gastropods), mites are regular phoretic guests. The set of preference reactions (see above) allows certain species of marine mites to be distributed differentially along the shoreline. However, halacarids are well known to stay in a site even when it provides harsh conditions. A few stress-resistant taxa are associated with algae above the midwater line (e.g., Isobactrus), while most mites live in the lower tidal to subtidal range (Somerfield and Jeal 1995). Distribution with depth seems less defined; deep-sea samples sometimes harbor the same genera as from the shore. Their euryecious nature along with their long evolutionary lines and an often parthenogenetic mode of reproduction contribute to the wide distribution areas and limited endemism of many halacarids. No halacarid genus is restricted to just one zoogeographical province. This explains why the halacaroid fauna of the Baltic Sea and the North Sea are more or less identical and the inter-province fidelity of amphi-North Atlantic species is still 45% (Bartsch 2004). Like many other chelicerates, halacarids have piercing and sucking mouth parts and an extra-oral digestion. Most of them are carnivorous, feeding for instance on crustaceans and oligochaetes; the phytal forms (see below) feed on the soft parts of hydrozoan and bryozoan colonies. Rhombognathus is phytophagous, piercing algal

Halacaroidea other Acari

Upper slope, sand

Nematoda Oligochaeta Harpacticoida

Middle slope

Ostracoda Others

Enteromorpha Tidal flat

Fig. 5.41 Proportion of halacarids in the meiofaunal spectrum along a beach profile. (After Bartsch 1982)


205

cells. In some biotopes a certain degree of competition with oribatid mites can be expected. In turn, marine mites have been observed to serve as prey for some small fish, as well as for hydrozoan polyps, but there is generally not much predation pressure on them. Halacaroid mites can best be retrieved by decantation, perhaps along with a hot freshwater (60 °C) shock. Fixation with formalin should be avoided. For further preparation, clarification of the body plates in lactic acid is required. An identification key for the marine genera of halacarids (Bartsch 2006) can be downloaded from the net in the PDF format; a key to the species around the British Isles has been developed by Green and MacQuitty (1987).

5.9.2

Freshwater Mites: “Hydrachnidia,” Stygothrombiidae, and Others

Aquatic mites from many orders and families are combined in the group “Hydrachnidia” or formerly “Hydrachnellae” (more than 6,000 spp). They live among the phytal, in the sands of river beds (hyporheos) and lotic streams, as well as on mud of stagnant freshwater biotopes. One of the dominant hyporheic genera is Atractides; the larvae of this genus are parasites on chironomid midges. In many hydrachnellid groups, these biological ties to insects seem to have prevented successful colonization of the stygobial. The inhabitants of the hyporheic interstitial often show analogous specializations that are typical of the habitat: reduction of eyes, elongation of the body (Wandesiidae, Stygothrombiidae). The interstitial forms are clearly smaller than the epigean ones, exhibit strongly positive thigmotactic responses and have more or less reduced eyes. They never swim but prefer to crawl on sand grains. For further ecological details on freshwater mites see Sect. 8.2. More detailed reading (Acari): taxonomy, Viets (1927); Bartsch (1979); faunistics and zoogeography, Bartsch (1989, 1996, 2004); ecology, Bartsch (1974, 1989); Pugh and King (1985a,b); freshwater groups, Schwoerbel (1961b); Di Sabatino et al. (2000, 2002).

5.9.3

Palpigradi (Arachnida)

It is with hesitation that representatives of this primitive and rare group of Arachnida are included here. While most Palpigradi live in moist terrestrial soil and caves, a few species from three genera have been found in the eulittorals of tropical beaches and shallow coral sand. Considering their small sizes (less than 2 mm), slender shapes, long flagella and their fairly thin and flexible appendages, they seem well matching to the requirements of an interstitial life. The most interesting features that provide convincing arguments for life in the marine meiobenthos are of an ecological nature: specimens of Leptokoenenia scurra, the best-studied species, normally

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crawl on and clutch sand grains. When extracted, they can successfully move back into seawater. While all terrestrial palpigrades have a hydrophobic cuticle, which would trap them at the water surface, these marine forms can easily pass through the surface film. The occurrence of marine palpigrades has been considered supporting a new suggestion of a possible marine origin for Arachnida and the colonization of terrestrial habitats from the seashore. More detailed reading: Condé (1965); Monniot (1966).

Box 5.11 Halacarid Mites: A Story of Invasion and Re-Invasion It is not true that there are no arachnids in the sea. More than 1,000 species of halacarid mites refute this popular but erroneous opinion. Their amazing tolerance to harsh environmental conditions, especially to salinity fluctuations, underline the invasive potential of the ancestral mites that made their way into the sea and radiated there. Steadily climbing in algal aufwuchs on rocks, hiding in the crevices of barnacle, bryozoan or hydroid colonies, and even squeezing through the voids of beach sand, they conquered the shallow sites and, from there, even reached the deep-sea. Some 60 species have reinvaded freshwater regions as descendents of marine genera and populate, together with other meiobenthic mites, limnetic biotopes. Their euryoecious nature might be the reason for another characteristic: although they are widely distributed and live under different habitat conditions, halacarids did not much alter their typical body structure, having a bipartite body and four pairs of walking legs: two forwards and two backwards pairs. When they invaded the mesopsammal they did so with little more than elongation and body flexibility. Therefore, halacarid mites, especially when alive, are easily recognized between algal fronds or on sand grains. What a different evolutionary strategy compared to the meiobenthic malacostracans or polychaetes, which often changed their body structure beyond recognition! Since they play a minor ecological or phylogenetic role, the Halacaroida remain a niche taxon, although they can dominate the meiofauna of suitable phytal habitats.

5.9.4

Pycnogonida, Pantopoda

Among the meiobenthos extracted from sublittoral marine sand samples, there are occasionally also some minute representatives of the usually macrobenthic Pycnogonida or Pantopoda. These are about ten species of Anoplodactylus, Nymphonella and Rhynchothorax. Except for their small sizes (the smallest is about 1 mm in body length) and, in some species, reduced ocular tubercles and eyes, there are no characters that strongly differ from the general body organization of this strange animal group, which is associated with the chelicerates. More detailed reading: Child (1988).

5.11 Annelida

5.10

207

Terrigenous Arthropoda (Thalassobionts)

There is a heterogeneous assembly of normally terrestrial arthropods that are meiobenthic in size and occur so regularly in marine biotopes that they should be briefly mentioned here. These animals are characterized not so much by morphological idioadaptations (perhaps their normally well-developed clinging legs are important), but by highly interesting and genuine physiological and ecological features. The strong affinity of these arthropods to the marine realm seems to be based on an ecological niche realized in marine (temporarily) moist sand and in the algal cover of supra- and eulittoral hard bottoms. The typical and highly specialized forms, although mostly widespread, are rarely investigated. Most of them belong to chelicerate groups, followed by Tracheata: 1. 2. 3. 4. 5.

Mites: Hydracarida, Gamasida (Hydrogamasus ), Oribatei, Uropodidae Pseudoscorpiones Aranea Chilopoda (centipedes) Insects: Collembola (Anurida, Archisotoma), Diptera (larvae of Ephydridae), Coleoptera (Staphylinidae)

Compared to the normal meiobenthos, the problem for thalassobiotic terrigenous arthropods is not a lack of moisture in the environment, but rather inundation by the sea, which may last too long. On the other hand, since they are adapted to living in genuinely marine habitats, like regularly flooded cliffs and islets, their ability to survive flooding by the sea is amazing, and they can sometimes survive such situations for up to several months. During this time they of course remain air-breathing, often adopting the principles of “physical lungs” (plastron respiration). Moreover, many of the thalassobiotic arthropods have a resting stage with only minimal oxygen requirements. Osmoregulation remains effective through their coxal glands. The adaptations are so specific that survival after inundation is only possible in sea water, not freshwater. As an indication of their terrestrial descent, the foods of this ecologically defined assembly of animals are not of marine origin. Terrestrial detritus, fungi, lichens and carrion washed ashore on even the most isolated islands is sufficient to sustain a small outpost of strange terrestrial life in the marine biome. More detailed reading: Schuster (1965, 1979).

5.11

Annelida

The traditional Articulata concept, which unites Annelida and Arthropoda, is largely based on the monophyly of segmentation. It contrasts with a growing set of morphological and molecular (including Hox genes) studies (Peterson and Eernisse 2001; DeRosa et al. 1999) in which molluscs, annelids and sipunculids are combined into a taxon termed “Lophotrochozoa,” thus separating Annelida

208


from Arthropoda. The implication of this is that serial segmentation is more plastic than originally thought during evolution, and so it cannot serve as the pivotal character that bonds large groups of phyla together. Acccordingly, we arrange the Annelida in context with Sipunculida and Mollusca here. Although there is now a consensus among specialists that Annelida is a rather diverse group, with the “polychaetes” and “oligochaetes” being paraphyletic (McHugh 2000, 2005; Rouse and Pleijel 2006; Erséus et al. 2008), we retain these colloquial terms in this ecologically oriented book in order to enable a broader understanding. The actual morphological and phylogenetic status of the Annelida and especially the Polychaeta is summarized in Bartolomaeus and Purschke (2005) and Rousset et al. (2007).

5.11.1

Polychaeta

In any meiofaunal sample, polychaetes are among the most striking and beautiful animals due to their multitude of structures, sizes and movements. Although there are only about 250 polychaete species of meiobenthic size, belonging to approximately 25 families, their abundance is fairly high, usually ranking fourth in meiofaunal samples. Besides the typical polychaetes that belong to the meiobenthic size spectrum as adults (permanent meiofauna, see below), many polychaetes pass through a juvenile phase in the meiobenthic size range (temporary meiofauna). In particular, juvenile Hesionidae, Syllidae and Capitellidae are often found in meiobenthic samples. Many of the meiobenthic forms were previously classified as a separate group, the “Archiannelida.” This group was characterized by rather aberrant features (e.g., irregular or absent segmentation, reduced parapodia, ciliary rings), which were held to be archaic. The structure that was often regarded as the most valid one for unifying the archiannelids was the ventral pharyngeal bulb, which is everted by a complicated musculature used to dab up bacterial and diatom epigrowth from sand grains. It has been shown, however, that the structures that form the ventral pharyngeal bulb are not homologous, that the similarities are convergences, and so they defy a synapomorphy for all the archiannelids (Purschke 1988). Today, it is well established that no single synapomorphic character can unify the “Archiannelida,” a fact documenting that this taxon is artificial. Rather, archiannelids are a convergent assembly of about 60–100 meiobenthic species of aberrant polychaetes belonging to approximately 12 families with numerous reductive, neotenic or highly modified features (Worsaae and Kristensen 2005; see below). It is, however, problematic to group them within the polychaetes, since polychaetes themselves cannot to be defined by clear synapomorphies (McHugh 2000). There are segmented worms that are so aberrant that classifying them as “Annelida incertae sedis ” (e.g., Aeolosomatida, Lobatocerebrum, see Sect. 5.11.3) would be more appropriate than forcing their classification within the traditional annelid subgroups, polychaetes and oligochaetes. With the absence of any segmentation in the Diurodrilidae, even their assignment to annelids is

5.11 Annelida

209

questionable. Some of these strange forms play a central role in phylogenetic discussions. Many characteristic convergent adaptations typical of meiobenthic and particularly interstitial life are beautifully realized among polychaetes (Fig. 5.42): – mostly very small (mature Nerillidium are only 250 µm long!), with only a few segments, – parapodia often reduced and not protruding (Protodrilus); sometimes even chaetae are reduced (Polygordius), – often ciliated, with ciliary rings or a ciliated “creeping sole” (with gliding locomotion; e.g., Dinophilus, Trilobodrilus, Ophryotrocha), – no circular musculature, no peristaltic movements. Some of the features mentioned above clearly relate to the progenetic nature of many interstitial annelids (Westheide 1987a; Worsaae and Kristensen 2005; Struck 2006), which is supported by other structures: the epithelial nerve system, the simplification of the dermal ultrastructure, no circular musculature of the vascular system, no coelomic cavities. Other morphological features seem to be secondary adaptations to the void system of the sediments: – Threadlike form with many segments (Polygordius is up to 10 cm long with up to 185 segments!) – Flattened body with a ventral “creeping sole” (Protodrilus) – Numerous adhesive glands on parapodia and caudal appendages (Hesionides, Sinohesione) – Eyes and pigments reduced – No planktonic trochophore larva – Complicated genital organs, often hermaphroditic (Ophryotrocha); with copulatory structures (Hesionides, Microphthalmus, Questa, Sinohesione)

5.11.1.1 Taxonomy and Classification The wealth of structural details useful as diagnostic features makes it possible to identify meiobenthic polychaetes to the generic level in most cases; often even the species can be identified without further dissection (Westheide 1990). Below, some of the more frequent and interesting genera are introduced and commented upon; their classification into families follows Westheide (1988, 1990a). Polygordiidae: Polygordius (with 15 species) occurs worldwide in the lowest tidal and subtidal of sandy shores (Nordheim1984; Villora-Moreno 1997). Together with Nerilla (see below) the genus was one of the first “archiannelids,” discovered in 1848 in sublittoral sand near the Island of Helgoland, Germany. The long, threadlike body with its smooth surface that is devoid of any appendages or setae and lacks circular musculature seems rather nematoid and makes the

Saccocirrus

Fig. 5.42 Some typical meiobenthic Polychaeta. (Various authors)

Polygordius appendiculatus

Protodrilus sp.

500 µm

1 mm

2 mm

Trilobodrilus axi

Nerillidium troglochaetoides

100 µm

Hesionides arenaria

100 µm

Stygocapitella subterranea

100 µm

200 µm

210 5 Meiofauna Taxa: A Systematic Account

5.11 Annelida

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genus easily recognizable. The numerous segments are not visible externally. The two prostomial tentacles are short and stiff; the pygidium with adhesive glands is set off. Protodrilidae: A family that may not be monophyletic, with two genera among which Protodrilus has about 30 species. They are distributed worldwide (Nordheim 1989), occurring mainly in the sublittoral but also in sandy tidal flats. The slender body consists of many discernible segments without parapodia but with setae visible. A continuous ventral band of cilia serves for gliding locomotion. Circular musculature is lacking. In contrast to Polygordius, the two head tentacles (palps), which easily break off, are flexible and longer. The pygidium has 2–3 lobes, which are of diagnostic relevance. The animals are hermaphrodites; some species have larval dwarf males which attach to the partner. They produce spermatophores and fertilization of the eggs is internal. The larva is known to metamorphose only in “natural” sand from its habitat, probably due to a certain bacterial composition (Gray 1966a). The two species of Protodriloides, characterized by numerous refringent epidermal glands, lay their eggs in cocoons; fertilization is external, possibly within the cocoons. Parenterodrilus is a gutless protodrilid from coral sand in the Pacific Ocean (Jouin 1992). Saccocirridae: Saccocirrus has 18 species distributed worldwide in eulittoral and sublittoral coarse sand. They are thin and very active worms with short parapodia and setae, one pair of eyes and two sticky pygidial appendages. The long and flexible tentacles are used as tactile probes. In some species, the males use eversible papillae in their genital segments as copulatory organs; the females have corresponding spermathecae. In other species of Saccocirrus, spermatophores are attached to the female partner. Saccocirrus is probably predaceous. Nerillidae: Most of the >50 species (classified into 17 genera of which Nerilla and Nerillidium are the best known) are small polychaetes ( 500 µm), which have been sampled

256

7 Patterns of Meiofauna Distribution

in traps and filters but can also be created experimentally. The meiofauna clinging to these particles not only take advantage of a nutritious substrate (many polysaccharides and diverse bacteria), but their movements also appear to support the coagulation, compaction and growth of the aggregations (Walters and Shanks 1996; Shanks and Walters 1997). The meiofauna of marine snow consists mainly of nematodes and foraminiferans as well as harpacticoids. Equipped with various adaptations for adhesion and clinging, suspended meiofauna are well adapted to drifting in and feeding on this substrate, thus allowing them to survive even longer-term excursions in the open water. In collections from oceanic sediment traps high above the sea bottom, 80% of all trapped nematodes, polychaetes and larvae plus 20% of the harpacticoids were observed to cling firmly to marine snow particles (Shanks and Edmonson 1990). Based on microbiological studies, Simon et al. (2002) point to the need to include aggregate-associated processes in ecosystem analyses. In the context of meiobenthology, it is proposed, though it has been insufficiently studied, that micro-aggregates are also of the great significance for production, nutrition and dispersal of meiobenthos and for bentho-pelagic coupling processes. The permanence and natural dimensions of marine snow could make this phenomenon of great evolutionary relevance, even beyond those of classical geotectonic processes (see the following section).

7.2.2

Geological Structures and Processes

Similar or identical meiofaunal taxa, both marine and limnetic, are often reported from distant and isolated habitats. Vicariant occurrence of the same taxon on both sides of the Atlantic has been postulated, although we often lack knowledge of the intermediate deep-sea fauna (Sterrer 1973; Stock 1994). This similarity between many species or genera of meiofauna separated by vast global distances could imply a relatively recent genetic exchange (Fig. 7.1). This would exclude the drifting of continental plates as a mechanism of dispersal unless the speciation rates were extremely slow or zero after the continents had drifted apart. In the case of uniform amphi-Atlantic gnathostomulid species (Sterrer 1973), this would be through 120–150 million years. Conservative biological characters (low number of offspring and restricted means of dispersal) combined with constant habitat and climatic conditions, especially in anchihaline or troglobitic biotopes (see Sect. 8.7.2), serve as a basis for the “relict refuge model” that is used to explain the similarities between many continental groundwater fauna. The frequent relict characters of some meiofauna require as an explanation minimal speciation rates or evolutionary stasis over long geological periods. However, this extremely slow speed of speciation contradicts the paleontological experience that few recent species branched off before the Eocene period, i.e., date back more than 55 million years. Calculations based on molecular clocks of genetic change also point in the same direction, confirming a shorter existence of many species. This scenario of a rapid radiation is also postulated by paleontologists. At the

7.2 Zoogeographic Aspects

257

species level, this would refute hypotheses that plate tectonics and a Gondwandabased common origin are responsible for similarities between Europe and America (see above; Hartmann 1986). Recent findings on the rich meiofauna of the Galápagos Islands also contradict the idea of a particularly slow speciation in the meiobenthos, because in just 3 million years (the age of the islands) the pristine beaches of the Galápagos archipelago have been colonized by a rich and radiating meiofauna (Westheide 1991). In turn, genetic analyses of many seemingly identical, disjunct species have yielded molecular differences that are large enough to dispense with the dogma of evolutionary stasis. However, aside from plate tectonics, other geological/geographical pathways should also be considered. Brackish water species may have taken the circumpolar route along the Iceland–Greenland–Northern Canada path (Ax and Armonies 1990). A more detailed knowledge of shallow shelf connections, extinct landbridges (e.g., the legendary “Thule Landbridge” along the Scotland–Iceland Ridge) or island belts used as stepping stones during periods with low sea levels would reveal potential distributional pathways that have not been adequately considered previously. In the scenario of extinct geographical patterns, the impacts of the ice ages and the concomitant massive lowering of the sea level must be included. In freshwater meiobenthos, a clear link between the distribution of harpacticoids and glaciation has been shown, such that the unglaciated South European and North American areas without such habitat disruptions maintain a higher species richness (Strayer et al. 1995; Rundle et al. 2000). In recent studies, the numerous sea mounts (about 100,000 worldwide!), with their summits of highly complex, biogenic sediments, have attracted special meiobenthological studies (George and Schminke 2002). Do sea mounts support similarly high levels of meiobenthic biodiversity as known for macrofauna and fishes? Are sea mounts “trapping stones” for the dispersal of meiofauna, with a long history of isolated speciation and disjunct fauna that are separate from those of the surrounding deep-sea mud? Or are they instead in distributive contact with the deep-sea and serve as “stepping stones” for dispersal across the oceans? Relationships to meiofauna from neighboring continental coasts would resolve the potential stepping stone function. The occurrence of taxa that were identical at the genus or even species level (e.g., the harpacticoid Laophonte bicornis) on various sea mounts (stepping stones). Recent harpacticoid studies from some Atlantic sea mounts have indicated an absence of a typical sea mount meiofauna and a low degree of endemism. On the other hand, the fact that the sea mount meiofauna is very different from that of the surrounding deep-sea would support the isolation aspect. Among the 56 species of harpacticoid copepod species found on the Great Meteor Sea Mount, only two species were known from other regions, and so a faunistic connection between the deep-sea and the sea mount summit was not evident (George and Schminke 2002). This high biodiversity was combined with low dominance values; each species was represented by only a few individuals. These results favor a long-lasting geological isolation with independent radiation (trapping stones). The apparent variability in the harpacticoid situation between seamounts probably depends on the degree of faunistic separation by local geological and hydrodynamic

258


conditions, which are difficult to generalize. Perhaps an assessment of the taxonomic distinctiveness (sensu Warwick and Clarke 1995, see Sect. 8.8.1) would better reflect the degree of isolation rather than counting species? Ascertaining the degree of genealogical concordance by employing (several) genetic markers would also be an appropriate way to determine the zoogeographical role of sea mounts in relation to meiofauna. Which factors drive the dispersal of meiofauna? Not, it seems, the “geological vehicle” of plate tectonics, nor stagnant speciation, nor anthropogenic transport. So what could be responsible for so many closely related yet disjunct meiofauna taxa; for the high amphi-oceanic similarity in meiofauna? What means of dispersal could explain present day distribution patterns of meiofauna on isolated islands or in anchihaline coastal refuges? Did natural rafts drifting across the oceans provide regular transport to suitably adapted micro- and meiofauna? All of these factors combined will account for some exchange of meiofauna across all oceans. This permanent exchange is more intensive in some areas and taxa, and more limited in others. Ubiquitous or large-scale distributions will characterize species predisposed to colonization by their ecological flexibility, eurytopic occurrence and high invasive capacities. Candidates for short-distance transport along coastlines by tidal and bottom currents will be shallow-water and epibenthic species. They exemplify a pattern of dynamic bentho-pelagic coupling within a diffuse boundary layer (Boudreau and Jørgensen 2001). Natural rafts, whether marine snow, sea ice or drifting islands, could have been responsible for repeated transoceanic long distance transport, especially at geological time scales. Such transportation events could support the colonization of remote or pristine islands by meiofauna without any previous contact with continents, as in the cases of the islands of Galápagos or New Zealand. A single contact event would then initiate the evolution of separate phyletic lines, i.e., radiating species from one founder population. The high numbers of monospecific genera among the nematode or gastrotrich fauna of some Pacific atolls (54 nematode species belonging to 47 genera) have been explained by isolated, discontinuous genetic importation from different original faunas and a low speciation rate (Gourbault and Renaud-Mornant 1990). In contrast, a regular gene flow between different areas would be accomplished by repeated genetic exchange and result in a high level of meiofaunal similarity. Natural long-distance dispersal could have provided this regular gene flow, causing little differentiation between, for example, foraminiferan species from the Arctic and Antarctic regions (Pawlowski et al. 2007). As anthropogenic activities and objects in the marine environment continue to increase (ship traffic, floating debris, shore maintenance works, large wide-range bottom dredging), additional potential means of meiofauna transport gain in importance. Both molecular analyses and experimental work offer us tools for specifying “similarity,” and estimating the relative impacts of and the timescales associated with the various distributional pathways for the dispersal of meiofauna. More detailed reading: Sterrer (1973); Palmer (1988); Hicks (1988a); Butman (1986); Armonies (1990, 1994); Eckman (1990); Shanks and Walters (1997); Simon et al. (2002).

7.3 Ecological Aspects of Distributional Importance: Horizontal Patterns

259

Box 7.1 Wide Taxonomic Occurrence vs. Local Individual Range: The Enigma of Meiofaunal Geographic Distribution What are the underlying processes, the distributional pathways that lead to identical taxa with restricted individual mobilities in amphi-oceanic shores or in the groundwaters of different continents? Avoiding the competitive marine shore conditions, many meiofauna evolved in the deeper regions of the sea, but were also displaced into continental aquifers after crossing the brackish transition zone. Relict taxa among the meiobenthos could survive in these refugial biotopes and retain archaic structures. A high degree of specialization (food, reproductive patterns) would support the trend towards isolation and enable sympatric speciation. Other taxa adapted by undergoing slight, initially cryptic mutations to the changing environment. They often formed morphologically closely related sister species or species flocks whose diversity has only been revealed by molecular analyses. And yet, the continental, even cosmopolitan, distributions of many taxa appear to result from a variety of dispersive mechanisms. Passive erosive suspension combined with active emergence may account for the fairly homogeneous meiofaunal distribution along continental shorelines; in freshwater habitats frequent flooding events will distribute many meiofauna. Similarity over transoceanic distances requires repeated contact, which is potentially accomplished by rafting. Natural rafts (floating islands, plants, sea ice) and anthropogenic rafts (vehicles, debris) may be of more local relevance, while the ubiquitous and natural flakes of “marine snow” are considered of global and continuous distributional relevance. Continental plate drift rarely explains genetic cohesiveness at low taxonomic levels. Many enigmatic relations require detailed analyses of genetic similarity in order to reveal the degrees of similarity, the routes and the timescales of dispersal.

7.3

Ecological Aspects of Distributional Importance: Horizontal Patterns

Are there any general patterns of meiofaunal distribution aside from those reflected by geographical and geological conditions? General patterns are difficult to conceive; the characteristic problems involved in assessing meiofaunal distribution have been outlined (for sandy sediments) by Fleeger and Decho (1987). The spatial distribution of meiofauna is notoriously patchy and unpredictably variable. Which factors control these patterns? It appears that we must discriminate again between abiotic and biotic factors. Large-scale meiobenthic distribution seems to be mainly related to physical and chemical parameters with sedimentary and hydrographic heterogeneities as modifying factors. The tidal zones of the oceans provide a good example. Along the slopes of shores, tides account for the large-scale zonation of meiobenthos (Hulings

260


and Gray 1976), since they control grain size composition, water content, salinity and permeability, which factors such as oxygen supply secondarily depend upon. A factor for which it is more difficult to differentiate the various ecological consequences is the general instability of environmental parameters. In sandy shores of the North Sea, with their rigorous physiographic regimes, the meiofaunal abundance is highest close to the mid-tidal line, while in the less exposed muddy sediments the greatest meiofauna abundance and species richness is recorded near the low tide level. The swash zone, with its marked physical and biological variations, displays low meiofaunal densities under strong tidal oscillations. However, it is a preferred zone in microtidal shores (e.g., Mediterranean, Moreno et al. 2006). In the most extreme upper areas of the eulittoral and supralittoral, meiofaunal abundance and diversity decreases. Only some annelids have their preferred habitat in this zone (Fig. 5.46). Perpendicular to the water line of these rather homogeneous shores, the deviations in meiofaunal abundance and composition are small. Small-scale distribution at the centimeter scale appears to be mostly due to biotic interrelations (Li et al. 1997; Snelgrove and Butman 1994; Somerfield et al. 2007), so that it is influenced by a complex factorial combination of attraction (e.g., as a result of reproductive activities) or avoidance reactions (e.g., predation). Aggregations a few centimeters in size are common in meiofauna and often even persist through tidal cycles. Many studies support the view that most of this patchy distribution is determined by aggregations of microorganisms (see Sect. 2.2), selective feeding preferences and direct or indirect trophic interactions (Findlay 1981; Fleeger et al. 1990; Blanchard 1991). However, larger patches of food such as decaying macrofauna can also structure the distribution of many meiofauna through selective attraction (Ólafsson et al. 1999). Small-scale heterogeneities of the sediment, as a biogenic bulk parameter, is generated by animal activities (e.g., bioturbation), become especially important for meiofaunal aggregation in non-tidal shores and in deeper, less disturbed areas (deep-sea) (Thistle et al. 1993). In any case, direct comparisons demonstrate that the horizontal distribution pattern of meiobenthos markedly differs from that of macrobenthos (Fig. 7.4). The divergent size scales of the various components of the benthos appear to be controlled by systems of factors that act differently in each case (see Sect. 9.2). The organic content of the sediments, as a biogenic bulk parameter, is another decisive factor and seems to play a key role in meiofaunal density and distribution. Along the coasts of South Africa, meiofaunal abundance was positively correlated with the detritus content of the sediment (McLachlan et al. 1981). A similar correlation was found in a Mediterranean beach, but the generally lower content of organic matter supported only a relatively poor meiofauna (between 14 × 103 and 715 × 103 ind. m−2) (Moreno et al. 2006). In contrast, the eulittoral of the North Sea, with its high amount of organic matter, especially in the finer sediments, is more densely populated: up to 16 × 106 ind. m−2 (McIntyre 1969) is not an unrealistic level of abundance. Other meiofauna data from a North Sea survey indicate, however, that the general decrease in both density and diversity of meiofauna from the south to the north cannot be simply attributed to grain size conditions and/or organic content alone (Huys et al. 1992). In many cases food overrides the abiotic parameters in distributional importance. In sublittoral and deep-sea bottoms, the reduced concentration of food accounts for the

7.4 Vertical Zonation of Meiobenthos

a

c

Macrobenthos

Ciliates

261

b

d

Nematodes

Ciliates after 14 days

Fig. 7.4 Different distribution patterns of three faunal size groups in the same area (40 × 80 m) of a mid-tide bay (fine sand) of the White Sea (after Burkovsky et al. 1994). Group clusters according to similar species composition.

reduced meiofaunal abundance (see Sect. 8.3). Despite the rather stable physiographic conditions, meiofauna in the subtidal zone are generally 3–4 times scarcer than in tidal bottoms. Towards greater depths, the general decrease in abundance and biomass is clearly attributable mainly to food scarcity: the rain of organic particles resulting from the primary production in the surface layers often controls meiofaunal numbers (Vanreusel et al. 1995a) which often show a clear seasonal fluctuation, with peaks in summer periods (Grove et al. 2006). Since the macrobenthos is even more hampered by food scarcity in deep-water sediments, the meiobenthos often gains in relative importance with respect to both abundance and biomass. Locally, for example in the deep-sea and in muddy fjords, the quantity of the meiobenthos can equal that of the macrobenthos, even attaining a competitive significance. However, even here there is still a close coupling of meiobenthic dynamics with food supply (Pfannkuche 1992).

7.4

Vertical Zonation of Meiobenthos

Demonstrating the parameters that control the general vertical distribution patterns of meiofauna is intricate because of the huge variety of sediments, from sandy beaches to deep-sea muds, that are inhabited by meiofauna. In all vertical sediment

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profiles, the upper few centimeters have a richer supply of oxygen and food particles and so usually harbor more meiofauna than the deeper horizons. In sandy beaches, Kotwicki et al. (2005a) found that about 70% of the meiofauna was concentrated in the uppermost 5 cm. In finer sediments, with their steeper physiographic gradients, this general pattern is particularly apparent (e.g., Vanreusel et al. 1995a). In a core of silty sediment, Yingst (1978) found that the uppermost two centimeters contained 71% of all the meiofauna present. Mud flats, because of their rich food supply (organic matter), contained about as much meiofauna in the uppermost centimeter as were present in a 10-cm column from a sandy bottom, making the more exposed meiofauna in muds the preferred prey for macrobenthos (Smith and Coull 1987). A general preference of the surficial layers is apparently also valid for protists, which are 2–3 times more abundant in the surface layer than at a depth of 5 cm (Bak and Nieuwland 1989); an exception being Foraminifera, which seem to occur at dysoxic and even anoxic depths (Bernhard 1996). However, there are other, more marked, exceptions to this general pattern. Thiobiotic meiofauna prefer the chemocline at the oxic/sulfidic interface and are only exceptionally encountered in the surficial layer (Giere et al. 1991; Ott et al. 1991; see Sect. 8.4). In mangrove muds and salt marshes, specialized nematodes and harpacticoids have been found down to depths of 15 or 20 cm in layers with reducing Eh values. Macrofaunal burrows and plant roots seem to be major reasons for this deep vertical distribution, although the physiological background of this occurrence remains largely unclear. Detailed distribution studies have also uncovered vertical migrations along a gradient system, with preference and avoidance reactions to tidal change. Tidal currents, with their powerful “tidal pumps,” have a massive influence on fluctuations in the vertical distribution (Joint et al. 1982). In tidal flats, when the sediment is exposed at ebb tide, most meiofauna move closer to the surface, but they migrate rapidly downwards as soon as the tide water reaches the surface (Boaden and Platt 1971). In tidal beaches, the nematode and harpacticoid populations have been shown to change positions by up to 25 cm during one tidal cycle (Harris 1972). In sandy beaches at ebb tide, where fluctuations in water content, temperature and salinity are unfavorably high at the surface, meiofauna react by migrating downward (Figs. 2.4 and 7.5). These vertical migrations of meiofauna into the sediment column suggest an active reaction to the hydrodynamic conditions and vibrational stimuli (Boaden 1968; De Bovée and Soyer 1974; Meineke and Westheide 1979; Foy and Thistle 1991). A preference for deeper layers is especially pronounced in the erosive swash zone. However, any avoidance reaction must “compromise” with the oxygen-related disadvantages of living at a greater sediment depth. The temperature regime can also influence diurnal and particularly seasonal variations in the vertical occurrence of meiofauna. In the summer, most animals of boreal shores live closer to the surface, and in winter they migrate further down and tend to live in closer aggregates (Fig. 7.6). Differentiated by taxon, the more phytobenthos- and phytodetritus-linked harpacticoids are usually more closely associated with the surface layers, where they sometimes even dominate in number, while the more detritus-linked nematodes occur in high numbers further down. This is valid in both littoral and deep-sea sediments from

50

40

30

20

10

1

= 25 ind. 2

High Water

3

Low Water

4

73

Experimental Column

Fig. 7.5 Migratory reaction of meiofauna to a tidal wave. Graphs 1–3 are field samples taken during one 18-h tidal cycle beginning with low water; graph 4 is for an experimental core that simulates high water conditions without wave action. (After Meineke and Westheide 1979)

Depth (cm)

0

Low Water

7.4 Vertical Zonation of Meiobenthos 263

264 cm 0

7 Patterns of Meiofauna Distribution Total Meiofauna

Turbellaria

Nematoda

Copepoda

10 20 Summer

30 40 0 10 20

Winter 30 40 50 0 20 40 60 80100 %

Fig. 7.6 Vertical occurrence of eulittoral meiofauna under summer and winter conditions (After Harris 1972)

polar and tropical regions. However, there are exceptions: In the sediment column of tropical Brazilian beaches, harpacticoids (about 35% of the total meiofauna abundance) outnumbered nematodes (up to 30% of the total meiofaunal abundance). This distinct exception in abundance of the two dominating meiofauna groups was also obvious in North Sea shores, according to the comprehensive study by Huys et al. (1992). Again, in the vertical distribution pattern harpacticoids contrasted with nematodes. The schematic outline of meiofaunal occurrence described above may vary considerably when local distributional patterns are considered. For instance, in eroded shelf sediments, the surface-linked harpacticoid copepods did not show any avoidance reactions to the hydrodynamic forces involving vertical migration into the deeper layers. They tended to prefer suspension rather than living deeper in the sediment (Thistle et al. 1995b). Taking into account the patchiness, variability and frequent water-column transport of meiofauna, the existence of meiobenthic “communities” or consistent “associations” that characterize a particular zone or habitat has only been rarely confirmed, at least in shallow marine sites. When Remane (1933, 1952a) proposed the establishment of interstitial coenoses as a basis for an ecological grouping, this was influenced by corresponding ideas in early benthology, where depth and sediment type were thought to define stable communities. A “Halammohydra coenosis” was defined for coarse sublittoral sands (H. octopodites, some stenoecious archiannelids, turbellarians and harpacticoids), a “Turbanella hyalina coenosis” in sublittoral fine sediment, an “Otoplana coenosis” in exposed eulittoral beaches (otoplanids, some gastrotrichs) or, under rather constant groundwater conditions, a “Bathynella–Parastenocaris coenosis.” Today, with our more dynamic conception of the sediment realm in which many biotic and abiotic factors interact (see Chap. 2,

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Box 2.8; Snelgrove and Butman 1994), the occurrence of some characteristic species denotes temporary aggregations rather than stable communities. In some studies, nematodes, their more stable numerical and spatial distribution (compare also Armonies 1990), enable relatively significant communities characteristic of a particular sediment structure or organic content to be denominated (see Sect. 5.61; Bongers and Haar 1990; Vanreusel 1990; Vincx et al. 1990). Similarities between the nematode faunas in fine shelf and coastal sediments also led Heip et al. (1985a) to establish “parallel nematode communities.” Another example of the formation of distinct assemblages that can be statistically discriminated (by relative abundance of species) is the ostracods in a specifically structured Californian intertidal phytal habitat (Frame et al. 2008). For littoral harpacticoids from various European sites, Chertoprud et al. (2007) suggested six assemblages with fairly consistent species composition regardless of the geographic area. More detailed reading: McIntyre (1969); Heip et al. (1985a); Alongi (1990a)

Box 7.2 Patterns of Meiofauna Distribution and Their Determinants Examining patterns is always a matter of scale. Large-scale distribution of meiofauna seems to be mainly related to physical and chemical parameters, especially under unstable, extreme conditions. Hence, in coastal areas subjected to tidal fluctuations, the physiographic regime—primarily fluctuations of salinity, water permeability and water supply—are good determinants of the zonation patterns of meiofauna. When we leave the tidal zone and move towards the more stable subtidal reaches, biogenic factors—such as food supply or animal interactions— gain in importance. Factors such as predation, bioturbation or competitive interactions form an interconnected complex of high relevance, especially in minimally exposed environments. However, the most relevant and ubiquitous biogenic factor that determines meiofaunal microdistribution is the supply of organic matter: detritus, bacteria and protists. This becomes particularly evident when comparing exposed with sheltered sediments or shallow with deeper sites. Despite the rather uniform physiographic milieu, meiofaunal distribution is typically patchy. The effective food partitioning of most species differentiates life conditions and determines small-scale (a few centimeters or meters) patterns. The interdependent balance between “organic matter supply” and “oxygen depletion” is the major determinant of most vertical distribution patterns of meiofauna. It demonstrates how closely the biotic and abiotic factors are interlinked: Low organic content keeps oxygen consumption low and even allows meiofauna to live in subsurface layers; rich organic content will attract many meiobenthic organisms to the upper centimeters of the sediment, but increases the risk of oxygen depletion. The consequence are marked preference/avoidance migrations of the meiofauna. Since the structure of the sediment often reflects the oxidative and trophic conditions, certain assemblages of meiofauna (especially of nematodes) can be associated to granulometry.

Chapter 8

Meiofauna from Selected Biotopes and Regions

The ongoing rapid global decline in species number tells us that assessments of natural diversity (“species richness” or “biodiversity”) are necessary not only for scientific reasons, but also to substantiate conservation or sustainable regulation. Thus, studies have been initiated to file our knowledge of meiofauna diversity in numerous marine and freshwater biotopes (see international programmes and projects such as the Global Biodiversity Assessment, UNEP 1995; Convention of Biological Diversity, UNEP 2001–2005; BIOMARE, MarBEF, CenSeam; overview in Costello et al. 2006). Due to methodological problems, estimates of marine biodiversity lag behind the numerous terrestrial census studies. The book by Queirago et al. (2006) provides general information about marine biodiversity, and recently a comprehensive assessment of freshwater species has been published, edited by Balian et al. (2008; see also the earlier compilation by Segers and Martens 2005). Meiofauna were initially not included when comparing marine with terrestrial species richness. About 10 million macrobenthic marine species and between 10 and 100 million meiobenthic species are assumed to exist (Lambshead, pers. comm.). For assesment of the biodiversity of (marine) meiobenthos (both species richness = alpha diversity, and assemblage richness between habitats = beta diversity), many previously neglected regions such as the polar seas, tropical beaches and deep-sea bottoms have been studied in greater detail over the last decade. These have increased our knowledge considerably and some of these sites have turned out to be “hot spots” of meiofaunal diversity. The following chapters will characterize the ecological conditions and diversity of meiofauna in some relevant biotopes from different latitudes. The resulting questions regarding the latitudinal gradient concept (Pianka 1989) and its validity for marine meiofauna will be discussed in Box 8.3. More detailed reading: Lambshead (1993); Gaston (2000); Gray (2000); McCann (2000); Warwick and Clarke (2001).


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8.1

8 Meiofauna from Selected Biotopes and Regions

Polar Regions

Since the 1990s research activity in the polar regions has greatly increased and ecologically oriented meiobenthic long-term studies have been performed in Antarctica (compiled in Vanhove et al. 1998, 2003), and in the Arctic (mainly by Szymelfenig et al. 1995). There are also numerous Russian papers on polar meiofauna of the White Sea shores based on long-term collections, but these papers are not readily available. The more accessible arctic coasts of Svalbard (Spitsbergen) are relatively well studied (see below). Interestingly, the deeper sediments are often better covered by sampling campaigns than the eulittoral (e.g., Hoste et al. 2007; Fonseca and Soltwedel 2007). The increase in the number of taxonomic papers is demonstrated by the monograph of Scott and Marchant (2005) on Antarctic protists, and by numerous descriptions of nematodes provided by Tchesunov (e.g., Tchesunov and Portnova 2005). Therefore, a more detailed picture of the meiofauna in these remote areas can now be provided. The polar and subpolar meiobenthos do not seem, in both abundance and composition, to be essentially different from those found at boreal (resp. southern boreal) latitudes from corresponding depths and sediments. Kendall et al. (1997) ascribe the low endemism of (shallow) Arctic meiobenthos to the fact that they originated at lower latitudes. The similarities of the vertical temperature ranges of Arctic shallow and deep-sea sites may explain the fairly similar abundances of polar meiofauna found at different depths. The eulittoral is characterized by strong seasonal oscillations of two rigid factors to which the meiofauna is apparently well adapted: (1) temperature (an ice cover is present for many months, which is aggravated by destructive ice scouring), and (2) food input (there is a rich microphytobenthos in spring and summer and short pulses of phytodetritus from dense plankton blooms). Due to the strong impact of physical factors, eulittoral meiofaunal populations are relatively scarce, and show high seasonal and inter-annual fluctuations (Table 8.1). In less exposed or deeper muddy bottoms with their rich organic matter, the density of meiofauna is one or two orders of magnitude higher. The sediments under marginal ice zones harbor especially rich meiofauna communities, which feed on the rich sedimented phytodetritus (Fonseca and Soltwedel 2007; Hoste et al. 2007), indicating a close bentho-pelagic coupling (see below). Even the polar deep-sea beneath the ice margins is governed by a rich amount of surficial phytodetritus which provides the basis for a diverse and rich meiofauna. The transition is smooth from this ice margin towards the typical deep-sea basins (Sect. 8.3). Towards the deep-sea and in sediments containing less organic matter, the meiofauna decreases in abundance, despite a physiographically less aggravating milieu. A general difference between the meiofauna densities of Arctic and Antarctic sites does not seem to exist. However, the considerable local variations only permit gross generalizations. Regarding community composition, the polar and subpolar meiofauna correspond to those from boreal latitudes, with nematodes clearly dominating (> 60%,

Sand and gravel Medium-to-fine sand Fine sand Coarse sand Sheltered beach sand Exposed beach sand Muddy sand flat

*Includes Foraminifera; **without Foraminifera

Alaska Muddy sand flat King George Island, Coarse sand and gravel Antarctica Shallow sublittoral South Orkney Islands Fine sand Magellan Strait, Beagle Mud with some sand Channel Admiralty Bay, King George Fine sand Island, Antarctica Brazilian Station, Martel Inlet, Sand, org. enriched King-George Island Deeper shelf, cont. margin Off Spitsbergen Mud? Arctic Laptev Sea Mud Deep-sea Central Arctic Ocean Mud Central Arctic Ocean Mud

Barents Sea

Mid-tidal Low-tidal Bear Island

Spitsbergen (Svalbard)

Eulittoral

Prevailing sediment

Nematodes Nematodes

Nematodes Nematodes Nematodes Nematodes

Nematodes Nematodes Nematodes** Nematodes

6,200 >3,000 3,500–4,000 10,000–15,000

1,150–3,450 500–1,000 70–250* 150–3,400

Nematodes Nematodes Oligochaetes Nematodes Turbellarians Turbellarians Nematodes

Main taxon

500–5,000 400 per 10 cm3

10–110 0–10,000; mostly 200 PSU, with steep gradients in the mm range. The authochthonous ice species Drescheriella glacialis (Harpacticoida) and Cyclopina gracilis (Cyclopoida) tolerate salinities of up to 80 PSU. For the fauna in the brine of the deeper channel system the constraints must be intense, while the peripheral ice portions, which have temperatures and salinities similar to the open water, offer more benign conditions. Is the relatively high proportion of rotifers in Arctic sea ice (22%, Gradinger et al. 1993), normally a group that is common in brackish and freshwaters, related to the occasionally low brackish salinity? Rotifers also have a physical advantage here: their flexible bodies favor life in the narrow ice channels, and they can squeeze through passages 50% smaller than the diameters of their bodies. Turbellarians also match their body dimensions to the varying channel widths by adjusting their osmotic pressures (Krembs et al. 2000). Further physiological and experimental studies that analyze the living conditions in the intricate web of ice channels are needed. Within a single ice core the meiofauna are mostly concentrated in the bottom layers, but even the upper layers harbor a few meiofauna (Dahms et al. 1990; Schnack-Schiel et al. 2001). Terrestrial meiofauna have also found access to polar ice: rich numbers of the enchytraeid Mesenchytraeus solifugus (Oligochaeta) live as “ice worms” or “glacier worms” in the fissures of glacier ice, mainly on the Alaskan coast. They feed on microalgae and pollen, and their strikingly blackish coloration can stain the ice dark (Shain et al. 2001). The changes in the abundance and production of sympagic meiofauna are as irregular as the changes in composition. Table 8.2 demonstrates these variations by region, season, and even in replicate samples. When appropriately processed (salinity-buffered melting of the sample), one core of 1,000 cm3 sea ice can contain 9,000 specimens. Densities from a few thousand up to several hundred thousand per m2 have been recorded (Carey Jr. 1992; Gradinger 2001); nematodes alone accounted for 24,000/m2 (Canadian sea ice, Riemann and Sime-Ngando 1997). However, comparisons are problematic: sympagic fauna in land ice are completely different from those in adjacent pack ice. Drastic changes in meiofauna abundance and composition may occur at the same station from month to month, with abrupt quantitative fluctuations ranging from more than 100 × 103 m−2 to less than 20 × 103 m−2. Rotifera, usually a rare group, can locally dominate; acoel turbellarians can comprise > 60% of the total sea ice fauna (Gradinger et al. 1993), and sometimes even

8.1 Polar Regions

273

Table 8.2 Abundance and main composition of “sympagic” meiofauna in sea ice from various locations (ciliates and foraminiferans are not considered) Area

Abundance (ind. 103 m−2)

Arctic regions Baffin Bay (both Apr–May 98): Pack ice

1.5

Land-fast ice

18.0

Greenland Sea, pack ice, summer 94, 95 Barents Sea, Aug 93 Frobisher Bay: Feb 81

31.7 68.7 17.3–110.3 105.0

May 81 June 81

110.3 17.4

Beaufort Sea: Apr 80 June 80

11.1–48.2 11.1 48.2

Stefansson Sound:

4.5–8.0

Mar 79

8.0

May 79

4.5

Composition (% ranked)

Nozais et al. (2001) 90 cop + naup/8 nem/ 1.1 pol 97 nem/3.3 cop + naup/ 0.1 pol 68.1 nem/5.5 turb/2.4 cop/6.9 rot 25 rot/25 nem/4 turb

Gradinger et al. (1999) Friedrich (1997) Grainger et al. (1985)

88.9 cop + naup/10.1 nem/0.4 pol 98.6 nem/1 cop + naup 92.3 nem/4.7 cop + naup/ 2.7 rot Kern and Carey (1983) 45.9 pol/45.7 cop/3.2 nem 51.9 nem/31.4 turb/ 14.5 cop Carey and Montagna (1982) 67.3 pol/32.2 cop. + naup/0.7 nem 76.9 nem/23.1 cop + naup/0 pol

Central Arctic Ocean: Aug–Sept 91

Reference

Recalculated from Gradinger (1999) ca. 15

46.9 nem/28.5 rot/15.4 cop. + naup/15.4 turb

Northern Fram Strait:

Schünemann and Werner (2005)

Summer

0.6–34.1

Winter

3.7–24.8

45% cop/33% rot/16 nem/3 turb 93% naup/4 rot/2 cop/ 0.5 turb/0.1 nem

Antarctic regions Weddell Sea:

Recalculated from Gradinger (1999)

Sept 89

1.5

Apr–May 92

78.1

34.4 cop + naup/31.2 turb/7.3 others 51.8 cop + naup/48.3 turb/5 others

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temporary meiofauna can form the bulk of the sea ice fauna. Arctic sea-ice fauna differs profoundly from its Antarctic equivalent. Compared to the biomass of flagellates and diatoms (100 mg C m−2), meiofauna (5–7 mg C m−2 sea ice) represent only a few percent (Friedrich et al. 1996), while the ciliate contribution is 20% (macrofaunal amphipods represent less than 1 mg C). In terms of biomass, the intensive primary production performed by microalgae (although varying with season, region and texture of the ice) exceeds that of the sea ice meiofauna more than tenfold. This is higher than required by the meiofauna, so rates of diatom ingestion by the sympagic meiofauna are only between 3–4% (Arctic) and 16% (Antarctic) (Gradinger et al. 1999; SchnackSchiel et al. 2001), even during the dark winter season even included. For Arctic sea ice in Baffin Bay, Nozais et al. (2001) noted a similar rate of consumption of the primary production (6%). These low values correspond to daily grazing rates of only 1% of the algal production. These calculations suggest unlimited feeding conditions for the sympagic meiofauna in most areas (Gradinger 1999; Nozais et al. 2001; Gradinger et al. 2005). Within meiofauna, turbellarians, which are often the dominant taxon by biomass, are the main predators and have considerable grazing rates (Gradinger et al. 1993). Sea ice meiofauna is not an isolated and stable biota. It closely interacts with the benthic and pelagic environments depending on the water depth, its proximity to land and its age (Werner 2005). Shallow water ice (water less than 10 m deep) predominantly contains a selection of meiofauna from the underlying benthos, whose populations are much larger than those in the overlying ice (Carey 1992). The frequently suspended harpacticoids and cyclopoid copepods and turbellarians (see Sect. 7.2.1) easily colonize the ice habitats. Each bottom contact of an ice floe, of which 80% is below the surface, provides benthic meiofauna with the chance to access the ice interstitial. With each melting or freezing period, seasonal ice floes release and take up meiofauna and thus contribute not only to the coupling of bottom fauna and ice fauna, but also by long drift passages to the distribution of the meiobenthos via long drift passages (Carey 1992; Schnack-Schiel et al. 2001). During ice-free periods, land ice represents a retention habitat and provides a “stepping stone” that enables recolonization when new ice is formed in winter. Figure 8.1 illustrates some seasonal processes in sea ice colonization. Additionally, during freezing periods ice platelets are formed and lifted from the bottom, with some sediment underneath. This may contain meiofauna which are then incorporated into the ice system, and this would explain why coastal fast ice usually harbors more meiofauna than remote sea ice (Gradinger et al. 2005). The “benthic-oriented” Arctic sea ice in particular permits an intensive interaction between the benthic and sympagic meiofauna (Carey 1992). However, only about one-third of all sympagic meiofauna seem to be of benthic origin. Oceanic sea ice contains a blend of autochthonous meiofauna, meroplanktonic larvae and true plankton organisms. It is not clear whether they are enclosed while the floe is freezing or they actively colonize the channel system.

8.1 Polar Regions

Winter

275

Spring

Summer

Autumn

ICE ???

Ice algae & phytoplankton Naupliar larvae Sympagic amphipods

Sympagic meiofauna (copepods, turbellarians, nematodes, rotifers) Pelagic copepods

Fig. 8.1 Seasonal pattern of sea ice colonization by meiofauna, emphasizing the intensive cryo-pelagic coupling (After Werner 2005)

In any case, freezing and melting processes contribute to their uptake and their release to and from the ambient sub-ice plankton (Fig. 8.1). During seasonal ice-free periods in the open water, the remaining areas of fast ice in coastal areas serve as refugia for ice fauna and as seeding grounds for the colonization of newly formed ice floes. The origin and fate of meiofauna in old ice floes drifting across the open polar seas and their pathways of colonization are often unclear. The various endemic species (e.g., the harpacticoid Dreschierella glacialis, the cyclopoid copepod Cyclopina gracilis, perhaps also the nematodes Cryonema and Hieminema) must have had long evolutionary lines with authochthonous, ice-bound life histories. Chunks of ice originating from multiyear ice floes may have provided appropriate rafts for (long-distance?) transport and further distribution. In all polar regions, sea ice acts as an important retention substrate and transport vehicle that contributes to meiofauna distribution. The extent to which the sea ice meiofauna represent truly benthic or sympagic fauna may vary with the texture of the ice, and with region, season and climate; quantitative data remain to be assessed. However, the ecological role of meiofauna in/on sea ice is certainly important. A universal ice melt resulting from global warming would point to a bleak future for polar ecosystems and their fauna, including their meiofauna. More detailed reading: Carey (1985); Spindler (1994); Gradinger et al. (1999); Gradinger (2001); Nozais et al. (2001).

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Box 8.1 Life Under Icy Conditions: Meiofauna in Polar Regions Despite the harsh conditions, meiofauna seem to thrive in Arctic and Antarctic regions. Their abundance and diversity are often no lower than those in temperate climates, and many boreal species also populate polar bottoms. Polar meiobenthic life depends on pulses of phytodetritus from the blooms of microalgae during the polar light season and is characterized, as in other extreme biotopes, by strong seasonal, interannual and local fluctuations. In the shallow bottoms mechanical disturbance by ice scouring adds to the physical stress, but under more favorable conditions densities of several 1,000 meiofaunal individuals per 10 cm2 are common. Nematodes and harpacticoids are normally the dominant taxa. In eulittoral sediments oligochaetes are common, while towards greater depths foraminiferans become increasingly dominant. Here diversity is often highest and many endemic species are found. A particular compartment of polar meiofauna lives in the channel system of sea ice. On the walls of this interstitial web filled with water of changing salinity thrive masses of microalgae, the food basis of a rich “sympagic” meiofauna, dominated by ciliates, foraminiferans and copepods, turbellarians and rotifers are unusually frequent. Nematodes are common in the Arctic ice but they, as well as rotifers, have not yet been found in Antarctic sea ice. Sea ice meiofauna are patchily distributed and show strong temporal fluctuations. This depends, apparently, on the processes forming the channel system, on the position and size of the ice floe, its distance from land, and on changing light conditions. Donor populations are from the bottom or from suspended meiofauna. A few species live their whole life cycles in the ice. They are often endemic and highly adapted to the special conditions in this exotic biotope, e.g., extreme salinities and temperatures. The meiofauna of sea ice is a food-unlimited community of specialists with reduced predation pressure. Only the rich meiofauna populations on the underside of sea ice are accessible and grazed upon by various macrofauna (particularly amphipods). Sea ice is a nutritious sheltered biotope for many meiofauna and a nursery ground for macrofauna. Linking the benthic and planktonic polar food webs, sea ice is of considerable ecological relevance. The consequences of its accelerated melting in the global warming process for oceanic life are by no means understood.

8.2

Marine Subtropical and Tropical Regions

In the last decade, studies of the meiofauna from subtropical and tropical regions have greatly increased following the pioneering studies on Indian beaches (McIntyre 1968), various Pacific islands (French researchers around Salvat and RenaudMornant) and the Bermuda Platform (Coull 1970). In a review of tropical meiofauna,

8.2 Marine Subtropical and Tropical Regions

277

Alongi (1990a) outlined a picture with large geographical, biotopical and seasonal variations. The tropics have a great range of habitat types for meiofauna, with carbonate sands on beaches and shelf regions of carbonate sand, estuarine muds, mangrove thickets, and enclosed lagoons. The present account will first focus on some general data and then present the meiofauna of some characteristics tropical biotopes. Despite the usually oligotrophic tropical seas, the abundance of littoral meiofauna in the tropics is very similar to that in temperate coastal areas: from several hundred to several thousand specimens per 10 cm2 (McIntyre 1968; Gourbault and Renaud-Mornant 1990; Alongi 1990b; Vanhove 1993). Dense populations beyond this range (e.g., >10,000 per 10 cm2 on the Malaysian coast; 17,000 nematodes per 10 cm2 in an Indian salt marsh) represent probably local aggregations and should perhaps not be generalized. In samples from the subtidal and the continental shelf, mean densities gradually decrease. Even the large local variations correspond to conditions in temperate regions and do not allow generalization. Unexpectedly, under tropical conditions the density fluctuations often also exhibit a seasonal pattern (Bermuda: Coull 1970; Galápagos: Westheide1981; Philippines: Faubel 1984; Red Sea: Arlt 1993). However, in contrast to temperate climates, the richest populations often develop in the cooler parts of the year (at least in habitats in the “dry tropics,” see Alongi 1990b). Breeding and reproduction are also mostly seasonal, and are often adjusted to avoid climatic extremes such as torrential rainfalls in the monsoon season. During their reproductive phases, even those meiofaunal species adapted to tropical conditions are limited in their tolerance to changing physical conditions (see Sect. 8.6). Monsoonal floods, with their high mud loads of river run-off, hurricanes (typhoons) and cyclones, which are characteristic of the tropical girdle, can cause a sudden and sometimes complete turmoil of the ecosystem, with severe destruction of meiofaunal assemblages, especially in the eulittoral (Suresh et al. 1992). A similarly negative effect has been recorded in South Africa after the seasonal flooding of estuaries (Nozais et al. 2005). However, these are natural disturbances to which meiofauna seem adapted, since the populations normally recover fairly rapidly, albeit often with an altered community composition (Alongi 1990a; Ansari and Parulekar 1993). Typical of certain tropical areas are oscillations such as “El Nino” or seasonal upwellings. These hydrographic events also have a marked impact on coastal meiofauna. By enriching the nutrient supply they augment meiofauna populations. Where river inputs provide rich organic matter, meiofauna will develop into particularly dense populations, so long as the load of fine sediment does not lead to anoxic events. In estuaries and coastal lagoons the great salinity and temperature stress reduce meiofauna to densities of around or less than 100 ind 10 cm−2 (Alongi 1990b); this is lower than observed in corresponding temperate or boreal brackish waters. As seen in non-tropical meiofauna, grain size composition, the complex indicator of abiotic factors (see Sect. 2.1), seems to influence meiofauna composition: community structure in tropical sediments mostly corresponds to the typical pattern, with nematodes as the most abundant and diverse group. However, in coarse sands with a low silt content harpacticoids may prevail. This relation to grain size and silt content has been found in both tropical quartz and biogenic coralline sands. In contrast with most studies from temperate regions, polychaetes and oligochaetes play a substantial

278


role in the tropics and can represent important taxa (Ansari and Ingole 1983; Faubel 1984; Ingole et al. 1997; Westheide 1991; Sasekumar 1994; Villora-Moreno 1997; Netto et al. 1999). On the other hand, a local scarcity of annelids may suggest the presence of turbellarians, their main predators, which occasionally exhibit considerable abundance in tropical studies.

8.2.1

Tropical Sands

The littoral fringes of many tropical seas, atolls and islets consist of calcareous biogenic sands. These splintery biogenic sediments are structurally complex, relatively little sorted and of high porosity. In experimental sediment columns, permeability of calcareous sand was often markedly higher than in corresponding siliceous sand. The “open” grain surfaces of calcareous particles favor adsorption of nutrients that are the basis for rich organic matter and large stocks of microorganisms (Suess 1973; Rasheed et al. 2003a,b; Wild et al. 2005). This means an attractively rich food supply for meiofauna (Dahms et al. 2007). Their assemblies consist of many different taxa, albeit with just a few individuals each, they have an unusually high biodiversity. This richness contrasts with the often low number of individuals per taxon (RenaudMornant & Serène 1967; Coull 1970; Gúzman et al. 1987). Gourbault et al. (1998) identified in their study on the beaches of Guadeloupe 122 spp of nematodes belonging to 112 genera, and the 42 spp of harpacticoids found by Villiers and Bodiou (1996) in Polynesia belonged to 21 genera! In somewhat coarser sediments (unprotected beaches and reef slopes), the dominant group is often the harpacticoid copepods; the nematodes here are relatively large, epigrowth-feeding or predacious types. Many other, often rare, taxa (foraminifera, interstitial ostracods, polychaetes, molluscs, priapulids, and tardigrades) also occur. Overall, in the coarse, exposed sites meiofauna densities are relatively low (< 500 ind. 10 cm−2; see Guzmán et al. 1987). In contrast, the finer sands and muds of more sheltered sites (lagoons, pools) harbor a more monotonous meiofauna with numerous small, deposit-feeding nematodes dominating (Coull 1970; Vanhove 1993; but see contrasting conditions in Gourbault and Renaud-Mornant 1990), (e.g., 30–540 × 10 cm−2: Grelet et al. 1987 (80–90% nematodes); about 1000 inds × 10 cm−2: Netto et al. 1999; several thousand × 10 cm−2: Guzmán et al. 1987); the turbellarian fauna is also rich here. Biomass at the surface was almost 4 g m−2 (wwt, 0–5 cm), twice that of corresponding records from North Sea sands (Grelet 1985). This increase in meiobenthic abundance with the reduction in the permeability of the interstitial system occurs mostly at the expense of taxonomic diversity. The switch from copepod to nematode dominance can occur within short periods of time (5 in the Great Barrier Reef or even up to 11 for the Red Sea coast have been reported.

8.2 Marine Subtropical and Tropical Regions Nematodes

Harpacticoids

Jacc. 1.0

0.5

279 Polychaetes

Others

Renk. % 20

1 0

Jaccard Index Renkkonen Number

Fig. 8.2 Comparison of similarity (Jaccard index) and dominance (Renkonen index) in meiofaunal samples from calcareous and siliceous sands in two adjacent Mediterranean sites. Low Jaccard values indicate marked differences between the species at the sites, while Renkonen percentages indicate the degree of similar dominance relations in the compared sediments (Giere et al., unpubl.)

More sheltered lagoonal ecosystems in the Pacific had a lower diversity of >3 (Gourbault and Renaud-Mornant 1990). On the other hand, Coull (1970) reported that the highest species diversity of Bermudian copepods occurred in the muddy, not the sandy, substrates. Hence, a simple relationship between granulometry and species richness does not seem to exist (Boucher 1990). In a direct comparison between the meiofauna of calcareous and siliceous sands from Italian shallow sites (Giere et al. unpubl.), indices of similarity and dominance differed profoundly, while the abundance, taxonomic richness and H’diversity remained comparable (Fig. 8.2). These differences in meiofaunal community structure despite similar granulometry became most evident at the species level, not when higher taxa were compared. Many calcareous tropical sediments harbor a typical thiobiotic and sulfidedependent meiofauna at depths below 10 cm (Ott et al. 2003; Bright and Giere 2005; Van Gaever et al. 2004; see Sect. 8.4.2). How can anoxia/sulfide develop beneath the upper few oxic centimeters in sediments of high porosity and in hydrodynamically exposed areas? As evidenced by the mostly low degree of sorting, between the calcareous fragments of shells and skeletons, a large amount of fine, powdery abrasion accumulates which tends to clog the pores, causing low permeability in the deeper strata. In addition, mucilage sheaths, which are not present to such a large extent on silicate grains, coat the particles (Suess 1969, 1973; Rasheed 2003a,b). These biogenic films and the rich organic content of the sediments may cause the rapid oxygen depletion in the deeper layers. The zonation of meiofauna on tropical shores corresponds to that in temperate climates: the highest diversity but not necessarily abundance occurs near the lowwater mark, a lower diversity is found in the higher shore. The intermediate zone often harbors fairly high meiofauna abundances. In the shelter of tropical algal assemblages, rich in habitat structure and food supply, a particularly abundant and taxonomically diverse epiphytic meiofauna is commonly observed (Faubel 1984; Arlt 1993; De Troch et al. 2001). Microhabitat complexity, exposure and sediment transport are major determinants of meiofauna abundance and composition in these phytal communities (Muralikrishnamurty 1993).

280


Box 8.2 Calcareous Sands: A Bonanza of Fascinating Meiofauna The rubble in tropical coral reefs, the sediments in many marine caves, the tops of many sea mounts, the beaches of atolls, the shoals along limestone shores: these all are of biogenic origin, and their sands have fascinating structural complexity. A look through a microscope shows a colorful sedimentary world: white coral rubble, fancy foraminiferan tests, reddish pieces of calcifying algae, crenulated fragments of echinoderm spines and sculptured parts of mollusc shells—and it shows a wonderful meiofauna, often with marked body structures and color patterns in white and red. Rare taxa like tiny holothurians and bryozoans, bizarre tardigrades and loriciferans, agile isopods, reddish harpacticoids or white bacterial symbiotic annelids and nematodes occur here. What causes this high meiofaunal diversity and endemism? Is it just the irregular, often splintery particle shapes? Are the porous surfaces of calcareous particles the clue to their high absorptive capacities? They bind many organic substances; their surfaces are coated with biofilms. Are specific biofilms the reason for the rich colonization with microorganisms and meiofauna? Whatever the case, their specific attractiveness to a diverse, often unusual meiofauna has been shown in direct comparisons. Contrasting in their origin, texture and probably also microbial composition, calcareous sands differ profoundly from their siliceous counterparts in their meiofaunal content. Irrespective of latitude, water depth and biotope, to the zoologist they represent a bonanza of new and interesting animals. The characteristic nature of these attractive habitats requires more comprehensive research.

8.2.2

Mangroves

One of the most characteristic, biologically rich and ecologically important habitats of the tropics, the mangrove girdle, has also attracted studies on its meiofauna. As in other tidal shores, differences in exposure generate various zones. The high shore with the most rigid fluctuations is usually the least populated, while the mid-tide or low shore harbor the densest populations of mangrove meiofauna. Although the sediment compositions in these zones vary slightly (the low shore has somewhat coarser particle fractions), in general mangrove sediment consists of fine mud that is rich in organic matter. With their low porosity and water percolation, mostly brackish and fluctuating salinities and limited oxygen supply, mangrove sediments are comparable to the tidal flats of temperate regions. In contrast, though, mangroves are characterized by different highly adapted and partly submerged mangrove trees. Their dense prop roots, the pneumatophores and the leaf litter create a much higher structural diversity than seen in temperate tidal flats. The horizontal distribution of meiofauna is determined by tidal changes in inundation, salinity and temperature. Tropical seasonal monsoons cause extreme salinity fluctuations and, along river mouths, flooding by riverine silt loads. Intense microbial degradation restricts the


281

oxygen supply in the sediment to the uppermost millimeters, aggravating meiobenthic life. In addition, the tidal currents and torrential rainfalls can erode the silt, creating patches of somewhat coarser sediment, at least in the lower reaches. A specific chemical factor for mangroves seems to be the high tannin content in the mangrove litter and pore water (Alongi 1987a,b). This habitat variability plus seasonal fluctuations (pre-monsoon vs. post-monsoon) may contribute to the extreme differences in meiofauna associations. Population densities and depth of vertical zonations differ in many studies (Alongi and Sasekumar 1992; Castel 1992). Thus, the mangrove meiofauna, like that found in silty tidal mud flats, must not only be adapted to temporary oxygen depletion and changing salinities, but it must also tolerate the adverse effects of tannin. It is thought that the low ability of meiofauna to break up mangrove litter may reduce meiofauna abundance (Coull 1999). Records on the vertical distribution of meiofauna in mangrove sediments are contrasting. Some authors have encountered meiofauna, mainly nematodes, way beyond the oxic/anoxic interface in the reducing layers, down to 15 or even 20 cm depth (Nicholas et al. 1991; Vanhove et al. 1992; Ansari et al. 1993); others claim that the presence of meiofauna at depths below a few centimetres is negligible (Sasekumar 1994). For an account of the problems associated with meiobenthic life under conditions of low/no oxygen, see Sect. 8.4 on thiobios. In almost all mangrove studies, nematodes, especially Daptonema and Microlaimus, represent 80–90% of the meiofauna. However, they do not form a biologically uniform group. In the different mangrove zones the variations in the silt content of the sediment relate to the nematode feeding type (Schrijvers and Vincx 1997). In the coarser sediments of the low shore and on roots and leaf litter, epistrate feeders (e.g., Spilophorella, Ptycholaimellus in a Kenyan mangrove) are more common (Nicholas et al. 1991; Ólafsson 1995; Chinnadurai and Fernando 2007). Their occurrence coincides with the increase in benthic microalgae and phytodetritus (Alongi 1990b). In Australian mangroves, the mid-level, particularly the silty zone, harbored numerous deposit-feeding nematodes, while omnivores and predators prevailed in the high water zone (Alongi 1987a; Nicholas et al. 1991), resulting in proportions of 50, 28 and 22%, respectively. In the deeper layers, the typical “sulfide nematodes” (Metalinhomoeus, Astomonema or Catanema) can prevail (see Sect. 8.4.2). However, the proportions of feeding guilds are not static. They can change rapidly depending on the seasonal input of microalgae and phytodetritus and on the silt loads that are often flushed in by monsoonal rains. A clearer relation to sediments was evident in harpacticoid copepods. Low species numbers are typical of muds, and much higher ones of sand. Harpacticoids are usually second in abundance (around 5–10%) after the nematodes. The lower, more sandy mangrove girdle not only harbors richer populations of these copepods than the higher shore, but it has also the highest taxonomic diversity (Alongi and Sasekumar 1992; Ólafsson 1995). In very soft mangrove mud, members of the Canuellidae, Ectinosomatidae and the genus Stenhelia were the dominant harpacticoids in Queensland, Australia (Coull et al. 1995). Favored by detritus-rich silty bottoms and often brackish water, burrowing macro- and meiobenthic tubificid and naidid oligochaetes are common in mangroves (5–19% in African mangroves). Although not often

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included in studies of meiofauna, ciliates can be quite common among mangrove meiofauna. In a South African mangrove they were the second most abundant (6.4%) after nematodes (80%) but before oligochaetes (4.5%, Dye 1983). In the more seaward Avicennia muds, kinorhynchs also attained considerable densities (up to 5%). Although both northern tidal flats and mangroves are detritus-based decompositional ecosystems, in mangroves the overall densities and diversities of meiofauna are often lower than those found in corresponding intertidal mud flats of temperate/boreal shores. Particularly because of their higher structural complexity (vegetation) is the epibenthic meiobenthos in mangroves more abundant (and more diverse) than that in northern tidal flats. About 1,000–7,000 individuals (mostly nematodes) per 10 cm2 have been documented in mangrove samples from different areas and continents (Dye 1983; Nicholas et al. 1991; Castel 1992; Vanhove et al. 1992; Vanhove 1993; Ólafsson 1995). Structural complexity would also explain why American salt marshes, that lack the extreme aggravations of mangroves, can harbor enormous meiofaunal densities (Wieser and Kanwisher 1961; Teal and Wieser 1966; Bell 1979). However, there are also records of much lower densities from non-estuarine and unpolluted mangrove forests (Alongi 1987a; Alongi and Sasekumar 1992; Chinnadurai and Fernando 2007), reflecting the high variability of local conditions and climates. The seasonal impact varies depending on the geographical location (the distance from the equator). In the dry tropics, the hot temperatures in spring and summer seem to reduce meiofauna, while in subtropical areas, (late) summer produces the highest densities. In general, the torrential rainfalls of monsoons have a negative impact on meiofauna, so that lowest densities were found in the post flood period (India). Biomass values from mangrove meiofauna are rare. Varying seasonally and locally, they may range (mean biomass) between 0.2 and 2.3 g C m−2, which, on the basis of an assumed turnover rate of 8 or 9, would give an annual production of as high as 1.5–8.4 g C m−2 (Dye 1983; Vanhove 1993). Similar to temperate tidal flats, in mangroves the dynamics of bacteria/microalgae communities and protozoan/meiobenthos assemblages are tightly linked (Schrijvers et al. 1995; Schrijvers and Vincx 1997): In the African mangroves, exclusion experiments on epibenthic grazers (gastropods) increased the stock of microalgae (chlorophyll a concentration) as well as the prevalence of epistrate-feeding nematodes. Exclusion of macro-epibenthic detritivores resulted in an increase in silty debris as well as a parallel increase in the population of detritivorous meiofauna (deposit-feeding nematodes and oligochaetes). Hence, a link between two different decompositional chains was revealed in the meiobenthos, one based on microalgae, the other based on detritus. Stable-isotope analyses (13C) showed that phytoplankton-derived seston was also an important food source in the upper centimeters of the sediment, which calls into question the prevailing trophic role of autochthonous mangrove litter. The rich epibiota in the thickets of prop roots and trees is another assemblage in mangrove shores that influences the mangrove meiobenthos by their structural diversity. Areas densely overgrown with mangrove vegetation often embody higher meiofauna densities. On the other hand, areas with many burrowing crabs have been found to be less densely populated (Dye and Lasiak 1986). This decline was interpreted as being more caused by disturbance and competition than by predation. Conversely, dense populations of epibenthic gastropods in a tropical mud flat led to the destabilization of the sediment surface and increased meiofaunal fluctuations


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(Carlén and Ólafsson 2002). Whether this negative effect was caused by competition for food or by physical disturbance is hard to discriminate in the field. However, in mangroves, with their abundant natural food supplies, why would competition among deposit-feeding snails and the much smaller nematodes exist at all? In all probability, the continuous fluctuations that characterize this habitat would rapidly reduce any long phases of resource limitation. Before we can generalize about interactive contacts between meiobenthos and other live compartments (Alongi and Sasekumar 1992; Schrijvers et al. 1995; Schrijvers and Vincx 1997), further experimental scrutiny is needed to gain a better understanding of the unique ecosystem of mangroves. More detailed reading: Alongi (1990a); Alongi and Sasekumar (1992); monograph, Alongi (2008).

Box 8.3 Tropical Plethora vs. Polar Purity: A Latitudinal Diversity Gradient in the Meiobenthos? The latitudinal gradient, derived from terrestrial studies, is one of the bestknown large-scale biodiversity patterns. The mechanisms governing this pattern, which have been disputed since the review of Pianka (1966), remain a challenge for the marine realm. But is the “classical” decline in species diversity from the tropics to the polar seas globally valid, and does it also apply to meiofauna? Has it only developed in the deep-sea or in shallow sites too? Many questions, but they have different answers. Recent and fossil Foraminifera seem to globally decline in species richness from the Equator to the North (Culver and Buzas 2000), However, nematodes in various deep-sea areas show a converse decline with increasing numbers of species towards the Arctic. This pattern was found to be linked to increased surface productivity and supply of organic matter (“food-driven gradient”), and is not related to a latitude gradient per se (Lambshead et al. 2000, 2002). In the southern oceans and the Antarctic deepsea, the highly diverse assemblages of meiofauna challenge the contention of a depressed diversity at higher latitudes (Brandt et al. 2007). Other studies and taxa did not demonstrate a latitudinal gradient, whether in nematodes or in harpacticoids. At shallow sites, meiobenthic species richness and diversity were as high as or even higher in temperate and boreal habitats than in the tropics (see Kotwicki et al. 2005b). An absence of any gradient between shallow tropical and temperate sites was also experimentally confirmed for nematodes (the main representative of meiofauna) using artificial collectors (Gobin and Warwick 2006). Also, in studies of freshwater meiofauna, a relationship between species number (mainly harpacticoid copepods) and latitude could not be discerned (Reid 1994; Rundle et al. 2000). A product of several interacting mechanisms, the latitudinal diversity index is often blurred by local geographic, historical and ecological variables. The lack of convincing evidence for a latitudinal diversity cline in the meiobenthos also may be partly due to our insufficient knowledge of regional diversification and the confounding effects of production and circulation patterns, but also due to differently sized samples, taken and evaluated by different researchers with different methods.

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The Deep-Sea

Deep-sea research is largely instrument-limited. Since the first study of the deep-sea meiobenthos (Wigley and McIntyre 1964), the development of suitable corers (e.g., the multiple Aberdeen corer, Barnett et al. 1984) has enabled quantitative evaluations. Today, scientists on numerous research cruises are equipped with sophisticated remotely controlled instrumentation, and can even perform experiments on the deepsea bottom, deploy and retrieve automatic devices such as “bottom landers,” and record environmental variables on-line. The application of new analytical methods (e.g., analysis of proteins, chloroplastic pigments, adenosine nucleotide content, and electron transport system activity) has refined our knowledge of the deep-sea meiofauna. These biochemical parameters that are related to biomass often render more reliable results than those obtained by direct counting and weighing.

8.3.1

The Habitat

Compared to the shallow benthic zones, the bathyal and abyssal bottoms are rather static and monotonous; wide regions of the muddy bathyal and abyssal plains represent a fairly uniform “desert environment.” However, interspersed with the widely prevailing mud plains are hydrodynamically complex areas where water currents are strong enough (5–10 cm s−1) to suspend the silty deep-sea sediment and form sandy patches (Thistle 1988). Upwelling regions can create oxygen minimum zones (OMZ), while mountainous ridges cause complex and little-explored smallscale near-bottom currents. We know of big river outflows, steep canyons and disastrous turbidites that influence the assemblages of deep-sea fauna. In addition to these hydrodynamic and geological patterns, manganese nodule fields, cold-water reefs and aggregations of sessile macrofauna result in a benthic structural heterogeneity that is greater than previously assumed and is important for the diversity and distribution of meiofauna. However, perhaps the most biologically important and unexpected factor is the seasonality of deep-sea processes (Gooday 2002), because this vast depth is coupled to the phototrophic surface, inferring that the ocean is one interactive biome that is under continuous change. While the temperature of the deep bottom is usually 1–2 °C, it is considerably elevated in the Red Sea (21 °C), the Mediterranean (about 10–14 °C), and in sediments associated with volcanic and hydrothermal activity (5–35 °C). Oxygen content is one of the most important abiotic factors in shallow sites, but wide areas of the deep-sea bottom are well oxygenated, often down to 10 cm depth. This results from the small amount of degradable organic carbon present in most deep-sea sediments. Conversely, in upwelling areas, which have a rich input of sedimenting debris after plankton blooms, oxygen can become limiting for many meiofauna, at least in the subsurface sediment layers. Low oxygen contents also occur in warm deep-sea regions (Red Sea, Sulu Sea in the Pacific Ocean) and

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remind us that complete anoxia prevailed in the deeper oceans for millions of years (e.g., during the oxygen crisis at the Permo–Triassic transition or the Mid-Cretaceous). Decaying plankton blooms cause seasonal pulses of organic matter that largely sustain the deep-sea ecosystems. Fluffy masses of phytodetritus reach the bottom after weeks and settle there as a greenish (from chloroplastic pigments) unconsolidated surface layer of high nutritive value (Pfannkuche and Thiel 1987). Since most meiofauna prefer this layer, it is imperative to prevent the “green fluff” from being flushed away by inadequate sampling if reliable results are to be obtained (Bett et al. 1994). Thus, variable deep-sea meiofauna recordings do not necessarily reflect merely local and seasonal fluctuations in sediment structure; it may be that they are attributable to inadequacies in sampling methods. There are three main factors that control the structure of meiofauna assemblages in the deep-sea. 1. Sediment characteristics (mud vs. sand). Changes from muddy to sandy areas caused by hydrographical properties and different sedimentation rates are paralleled by a change in community structure. In sediments with a high content of fine particles (silt), the meiofaunal abundance is usually relatively high and dominated by the large community of nematodes that can even live in deeper, often anoxic layers. Especially in cores with calcareous ooze, meiofauna can attain high densities (Shirayama 1984). In sandy areas a relatively diverse meiofauna is dominated by harpac ticoids in the upper few centimeters. These typical changes in community composition can be best demonstrated on neighboring flanks of ridges with different exposures and sedimentation rates (Jensen et al. 1992a). 2. The supply of organic matter (measured as chloroplastic pigments or adenylates), which is usually reflected by the silt content of the sediment, regulates the abundance of deep-sea meiofauna in all oceans. Every degradable organic particle added, whether it comes from seasonal phytodetritus or from horizontal advection by currents, influences the composition and abundance of the meiobenthos in this precarious nutritive environment (Thiel et al. 1988/89; Gooday and Turley 1990). However, the effect largely depends on the quality of the settling particles (larger, fast-sinking, fresh aggregates compared to lighter, more degraded ones that have drifted for longer; see Soltwedel 1997). About 3% (in other estimates 5–10%) of the surficial primary production reaches the deep-sea bottom despite the biological degradation that the particles undergo when they sink down through the water column at a speed of about 100 m per day. The response to the addition of phytodetritus is most obvious in the temperate and northern oceans, especially underneath the ice margin, but the reasons for these regional differences are not always clear (Pfannkuche and Thiel 1987; Lambshead and Gooday 1990; Tietjen 1992; Vincx et al. 1994; Gooday 2002; Witte et al. 2003). A lesser food source of the deep-sea is terrigenous detritus, which often accumulates near big river mouths and at the foot of the continental slopes. Remains of dead large animals and plants (“food falls”) provide large food packages that contribute about 10% of the energy input into the deep-sea.

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These are particularly used by nematodes, which aggregate despite often high oxygen deficiencies around sunken carcasses (Debenham et al. 2004). The last food source to be mentioned here are the bacterial films that colonize the mucus strands and excretions of the ubiquitous benthic foraminiferans. Bacteria and protozoa react rapidly to the periodic pulses of phytodetritus and fecal pellets and, thereby, can increase their production by an order of magnitude. In contrast, the metazoan meiofauna exhibit a delayed reaction (by some weeks to months). 3. Habitat heterogeneity on a small scale plays an important role in both species richness and diversity of deep-sea meiofauna. Sessile macrofauna protruding from the surface (sponges, coelenterates), worm tubes, agglutinated foraminiferan shells, komokiacean “mud balls” and “manganese nodules” (see Bussau et al. 1995) represent small-scale structures that increase the habitat complexity and also the species richness and functional diversity of meiofauna. These favorable structures persist for long periods in the quiescent deep-sea conditions (Thistle et al. 1993). A structuring effect is also ascribed to the bioturbative activities of megafauna (e.g., holothurians and enteropneusts; see Meadows and Meadows 1994) or to fragments of cold-water corals and sponges that accumulate on the deep-sea bottom (Raes and Vanreusel 2006). Increase in sediment complexity attracts a community of specialized meiobenthic epistrate feeders and contributes to local variations. The ameliorating effect of protruding tubes can be attributed to a complex interaction of favorable factors, such as establishment of hydrodynamically favorable sheltered zones with the accumulation of debris, increased downward transport of solutes, enhanced growth of bacterial stocks and better protection from predators (Thistle and Eckmann 1990, Eckman and Thistle 1991). Bioturbation by macro-epifauna can interact adversely with meiofauna, particularly with harpacticoid copepods (Thistle et al. 2008). Moreover, when macrofauna is experimentally excluded, the concentration of chloroplastic pigments increases and subsequently the meiofaunal densities increased too. Increased structural heterogeneity with strong hydrodynamic variability and the downward transport of large amounts of food material are also thought to be the reason why steep submarine canyons that cut into the continental margin represent “hot spots” of diversity (Ingels and Vanreusel 2006). The geological heterogeneity of the bottom (sheltered and exposed sides of submarine mountains, slopes and faults) may also contribute to variations and increased diversity in the pattern of meiobenthos colonization (Alongi 1990b; Grove et al. 2006). Recently, another geological phenomenon has received particular attention in meiofauna studies: hydrothermal vent areas. Here, an enhanced abundance of the meiobenthos—compared to the non-vent surroundings—results more or less directly from the enormous biomass and production of “sulfur and methane bacteria” (van Harten 1992). On the other hand, the species spectrum is restricted to the few forms that can tolerate the temporarily hostile sulfidic conditions (see Sect. 8.4). On the negative side, collapsing sediments of turbidites represent huge physical disturbances that have long-lasting and highly adverse effects on natural communities (Lambshead et al. 2001).

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8.3.2

287

The Meiofauna

The typical deep-sea meiobenthic organism is highly adapted in biological and ecological terms to the scarcity of food. Favored by the prevailing low temperatures, it grows slowly and has a long life span with low maintenance expenditure. Its metabolically costly reproduction is also affected by the need for energy conservation, resulting in a low number of eggs, often combined with brooding and asexual multiplication (protozoans). Hermaphroditism is frequent and reduces the energetic costs of finding a partner. Sometimes, especially at lower latitudes, reproductive activity in the depth changes in tune with the seasonal supply of surface-derived organic matter. Additionally, the predominant mode of nutrition in the deep-sea, passive deposit feeding, is energetically more favorable than the more active selection of food particles. All of these features characterize deep-sea meiofauna as specialized K-strategists, with a remarkable degree of trophic partitioning and evolutionary diversification. The structuring influence of a scarce food supply is also evident in analyses of size spectra, which have been best studied in the dominant deep-sea taxon, the nematodes. Thiel’s (1975) general rule for deep-sea fauna is valid for various deep-sea regions: with decreasing food supply (chlorophyll content) and mostly parallel with increasing depth, the average body size of nematodes decreases (Soetaert and Heip 1989; Tietjen 1992; Schewe and Soltwedel 2000; Kaariainen and Bett 2006; Rex et al. 2006). Only in the nematode fauna inhabiting the deeper sediment layers with hypoxic or sulfidic conditions has another trend evolved. Here, a long, filiform body size seems to be more favored, perhaps because it is better adapted to the uptake of dissolved organics or to higher mobility in the semi-liquid mud (Jensen et al. 1992a; Soetaert et al. 2002). The trend towards small body size also seems to hold for harpacticoids: in a deep-sea area of the South Pacific, more than 50% of the copepod specimens were less than 200 µm in length (Schriever, personal communication). Gigantism relative to the average representatives of a taxon also occurs in the deep-sea among meiofauna, e.g., in Loriciferans, but it is probably ecologically irrelevant. High specialization and slow biological processes in the deep-sea make meiofauna, especially the rarer species, sensitive to disturbances and much more vulnerable than their relatives in shallow sediments. Processes of recovery from a major disturbance have been found to last for years, a fact that should be considered when planning the economic exploitation of deep-sea bottoms (Ingole et al. 2005), e.g., the mining of manganese nodules (Radziejewska 2002) or the deposition of CO2 (Carman et al. 2004). In this context, the possible role of meiobenthos in the formation of polymetallic (manganese) nodules in the Pacific Ocean should be mentioned briefly. Although the chemical processes involved in the massive accretion of valuable heavy metals are not yet understood, each nodule is densely covered with and colonized in its internal interstices by a diverse meiobenthic community of protozoans and also meiofauna. It may be of relevance that Foraminifera are known to selectively excrete manganese, iron and other metals as xenobiotic particles (xanthosomes). Perhaps these excretions serve as the initial granules for the formation of new nodules, since mineral centers

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have been found in all of them (Riemann 1985)? Thus, it is conceivable that meiobenthic organisms influence the growth of these structures of high economic potential in one way or another (Shirayama and Swinbanks 1986). However, the expected largescale exploitation of polymetallic nodules by deep-sea mining would certainly massively threaten the slow-growing deep-sea meiobenthos. Meiofauna community composition. The ubiquitous Foraminifera (Protozoa) play the dominant ecological role in the shelves, the slopes and the plains of abyssal deep-sea bottoms (Fig. 8.3). Usually 50% of all individuals (maximally 90%) and

3m

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> 2000 m

Foraminifera Nematoda other meiofauna Polychaeta (macrofauna) other macrofauna

Fig. 8.3 The relative increase in Foraminifera with ocean depth among the benthos. (After Shirayama and Horikoshi 1989)

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about 30% of the meiofaunal biomass consists of foraminiferans (Shirayama and Horikoshi 1989; Moodley et al. 2002). This group alone is as abundant as all remaining metazoan meiofauna. Aside from the foraminiferans, other rhizopods such as Amoebina and the large Xenophyophoria have also been found to richly populate the deep-sea bottoms (Levin 1991). It seems that there is no square centimeter of the deep-sea bottom that is not interwoven with rhizopod pseudopodia. While many predator species among foraminiferans directly affect the metazoan populations by predation, Foraminifera also have a considerable indirect impact on the metazoan meiofauna, consuming about 50% of the incoming phytodetritus. Among the metazoans, nematodes dominate in almost all deep-sea studies, with a share of between 80 and 90%—an even higher value than in shallow reaches. In the muddy abyssal plains and often in the deeper layers below the sediment surface, the meiobenthos is essentially a community consisting primarily of Desmodoridae and Microlaimidae. In a Mediterranean deep-sea canyon, Comesomatidae (with Sabatieria) were the prevailing (up to 40%) nematode family (De Bovée and Labat 1993). Other typical deep-sea nematodes are Acantholaimus, Molgolaimus, Microlaimus, Thalassomonhystera and Halalaimus. Bacterivorous deposit feeders seem to prevail, followed by predators and omnivores, e.g., Sphaerolaimidae, while epistrate feeders usually only represent a low percentage. A 7% share was assigned to gutless nematodes by De Bovée and Labat (1993). Occurring in much lower numbers and particularly in the surficial layers of somewhat coarser sediments are harpacticoids (e.g., Pseudomesochra, Zosime, Malacopsyllus) and polychaetes. Juvenile bivalves and some kinorhynchs are encountered in muddy samples. In studies from the northern Atlantic, polychaetes ranked second after nematodes. The meiofauna of sea mount sediments differs from that of general deep-sea bottoms (see Sect. 7.2.2). Meiofauna (e.g., harpacticoids) even exists in the hadal troughs at depths beyond 10,000 m, although in reduced abundance. Interestingly enough, even representatives of oligochaetes, a group purportedly of limnogenous/terrigenous descent and lacking propagatory stages, have been found at > 7,000 m depth. Nemertines, reported by Ingole et al. (2005) to rank second after nematodes in greater depths of the Indian Ocean, certainly represent a local exception. Diversity. The deep-sea is renowned as a “hot spot of biodiversity.” Based on their high patch dynamics, meiofauna confirm this general rule. The alpha-diversity, “weighted” or “expected species richness” or “Shannon diversity” are unexpectedly high, especially in the bathyal and abyssal depths and around Antarctica. Foraminifera alone can exist at an abundance of 40 different species per cm2. On average 25–50 distinct species of nematodes or harpacticoids can be discriminated per 100 individuals of meiofauna sampled; the equatorial and southern Pacific seems to have a particularly speciose nematode community (Snelgrove and Smith 2002). Based on nematode data, the average taxonomic diversity increases with water depth, although the number of genera may decline approaching deep-water sediments. In samples from the deep-sea bottom under the Arctic ice margin, 300 species of nematodes were discriminated, most of them new to science (Hoste et al. 2007). In a manganese nodule field, an assemblage of 2,022 nematodes consisted of 250 distinct species belonging to 110 genera (Miljutina et al. 2006). Also, Arctic

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deep-sea bottoms structured by a rich sponge assemblage exhibited a correspondingly high alpha-diversity (Hasemann and Soltwedel 2006). On a small scale, the diversity of species is extremely high in the deep-sea while comparisons of diversity between large biogeographic regions (gamma-diversity), especially at the genus level, often yield low values. A comparison of nematodes on the generic level between southern and northern abyssal sites revealed minor differences only (Sebastian et al. 2007). Compared to abundance, biodiversity (alpha-diversity) seems to be more intricately influenced by food supply and habitat heterogeneity. Whereas in some studies both diversity and abundance decreased with the depth-related losses in particulate organic matter (POM), many other reports, especially those from bathyal and abyssal sites, measured an inverse relation between POM flux and diversity, i.e., diversity was higher in bathyal and abyssal depths than along the shelf slopes (Rex et al. 1993; Boucher and Lambshead 1995). A comprehensive literature evaluation (Mokievskiy et al. 2007) confirmed, regardless of the methodology applied, an increasing dominance of nematodes, with a maximum at depths of below 1,000 m. Again, this pattern appeared to be controlled by the habitat heterogeneity and the food supply. Only in the hadal regions did both of these parameters decline in parallel. Here a rich meiobenthic life apparently cannot be sustained. The resulting hyperbolic (“hump-shaped”) bathymetric gradient of biodiversity recorded from shallow reaches to the deepest parts of the ocean, with a maximum occurring around 2,000 m, has been corroborated for (nematode) meiofauna in the North Atlantic (Lambshead 1993). A multiple regression re-analysis of numerous nematode data sets using latitude, areas scale, sampling effort and depth as independent parameters (Mokievskiy and Azovsky 2002) also resulted in a hyperbolic diversity curve for depths >100 m, with the highest values obtained at latitudes of between 30 and 60°N. However, the evaluation of another comprehensive data set of nematode genera from numerous sites at depths of between 200 and >8,000 m from a wide spectrum of regions did not show the expected hyperbolic curve of species richness (Gambi et al. 2007). The critical point when looking at diversity patterns seems to be the choice of an appropriate scale that separates local from regional data sets. This would perhaps explain the problematic and partly contradictory results (Lambshead et al. 2000). Why is the deep-sea meiofauna (and macrofauna) so diverse? Depth per se is probably not the causative factor involved per se. The limited food supply promotes niche partitioning, which results in strong functional and morphological specialization and spurs the process of evolutionary diversification. Additonally, structural heterogeneities influence the trophic interrelationships and contribute to biodiversity. This is demonstrated in studies of meiofauna from submarine canyons and from sea mounts. Both of these regions are increasingly recognized as being “hot spots” of meiofaunal diversity. Their variable and complex hydrodynamic patterns create sediment heterogeneity, sometimes combined with a favorably rich flux of organic particles. This scenario differs considerably from the uniform deep-sea plains and enhances meiobenthic diversity. The coral and sponge rubble in cold-water coral reefs enhance the habitat complexity as well and create islets of high diversity in the deep-sea bottom. They are preferred by

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robust nematode taxa that mostly act as epistrate feeders on microbial films (Epsilonematidae, Draconematidae). Epsilonema multispiralum is particularly common in North Atlantic deep coral sediments (Raes and Vanreusel 2006).

Box 8.4 Meiofauna in the Deep-sea: Diversity in Scarcity Scarcity of food and low temperatures are the key factors that determine the life of meiobenthos in the deep-sea. The most distinctive aspect is the high biodiversity, which exceeds that at shallow sites. Hydrodynamic patterns and macrofaunal activities structure the bottom and provide heterogeneity; sufficient oxygen and pulses of phytodetritus as food are usually available. This combination results in a deep-sea ecosystem that is far from monotonous, sustaining a meiofauna of particular composition, low abundance and biomass, but high diversity. Foraminiferan protists dominate, and the sediment is interwoven with their pseudopodia. The other main component is nematodes, while harpacticoids remain relatively rare. The number of specimens per species/taxon is extremely low: any random selection of 100 meiofaunal individuals would usually include 25–50 distinct species of nematodes and harpacticoids. What causes such a high diversity? Scarce and patchy food pulses support energy-efficient K-selection in most deep-sea animals. Reduction in average body size reduces consumption and trophic specialization avoids competitive displacement. Moderate fluctuations in the hydrodynamic and oxygen regimes, small disturbance effects in a mosaic of variables, and narrow niches create a factorial complex that maintains subtle ecological disequilibrium processes. Today, these together with the classical time-stability effects are considered the main promoters of deep-sea biodiversity. With electronically controlled instruments, robots and submarines, deep-sea research is providing fascinating contributions to meiobenthic research, and many future discoveries remain to be made in this vast biotope.

Distribution pattern. At a large geographic scale, the horizontal distribution pattern of deep-sea meiobenthos is rather monotonous (see Box 8.1 for an assay of the “latitudinal diversity gradient”). In areas of little sedimentation, the ubiquitous muds harbor a rather evenly distributed association of deposit feeders of high conformity at the genus level. However, changes in sediment structure, e.g., local accumulations of phytodetritus, seem to correspond with a non-random meiofauna distribution and differing composition. The Northeast Atlantic, with its high primary production, harbors a particularly rich deep-sea meiobenthos compared to other large ocean basins and the Mediterranean. In the hydrodynamically more complex sandy areas of the deep-sea, suspension feeders with mucus filtration become more frequent.

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Vertical core profiles also demonstrate that deep-sea meiofauna is mainly controlled by the restricted food supply. About 90% of all meiofauna are concentrated in the upper 2–5 cm, where the nutritive detritus accumulates. Especially foraminiferans, harpacticoids and polychaetes aggregate near the surface, while the deeper strata are the domain of nematodes. In contrast to shallow sediments, this concentration at the surface does not result from decreasing oxygen levels at greater depths. As a result of the extremely low input of organic matter, the biological oxygen demand is reduced so much that the upper 5–10 cm of the deep-sea bottom remain oxic. Only areas with richer organic input suffer from low oxygenation, which then becomes an additional key factor. In regions intensively bioturbated by macrobenthos, meiofauna (mainly nematodes) also occur in deeper layers beyond the usual 5–10 cm threshold, since the oxygen penetration is enhanced in this case and the detritus is buried deep down. In the deep-sea of the Indian Ocean, Ingole et al. (2005) reported that only 16% of the meiofauna was present in the upper 2 cm, while meiofauna was recorded down to a sediment depth of 35 cm. The density of deep-sea meiofauna is largely determined by three sediment factors (Shirayama 1984): calcium carbonate content; heterogeneity of the substrate (low sorting coefficient); and organic matter, indicating food availability. Abundances of 100–1,000 meiobenthic organisms per 10 cm2 (without foraminiferans) are quite typical (Table 8.3; Tietjen 1992). At greater depths, meiofaunal density often declines to 10–100 per cm2 (Shimanaga et al. 2007). Sediments with a high abundance of shell remains (calcareous ooze) harbored up to 1,300 ind. ml−1 of metazoan meiofauna (Shirayama 1984). Even Protozoa (Foraminifera) do not markedly exceed this range (maximally 2,000 ind 10 cm−2 or 150–200 ind. ml−1 sediment). Compared to surface values, these figures document the often limiting effect of the organic particle flux on the existence of a deep-sea meiobenthos (Tietjen 1989). Since the amount and the nutritive value of this flux decrease with increasing depth, the meiofauna in most deep-sea regions follow a negative hyperbolic abundance/depth relation (Fig. 8.4; Pfannkuche and Thiel 1987; Tietjen 1992). Only where adverse hydrodynamic patterns dominate shallow sites, will meiofauna abundance and diversity be greater at deep-sea sites. This can cause an exceptional increase in the vertical density curve. Even deeper down, the usual decrease towards hadal depths begins, so that the resulting abundance/depth curve here is parabolic (Rex et al. 2006).

Table 8.3 Meiofaunal composition (%) and abundance in samples from increasingly deep marine sites (Coull et al. 1977) Taxon 400 m 800 m 4000 m Foraminifera Nematoda Harpacticoida Unidentified Polychaeta Organisms per 10 cm2 (average values)

30.8 45.1 10.7 5.1 2.8 442

33.1 59.7 2.4 1.5 1.6 892

65.2 30.2 2.0 1.1 0.5 74

8.3 Deep-Sea

293

Metazoan meiofauna (number x 103 x m−2) 2800

2000

1000

200

0

Depth (m)

1000

5000

9000

Fig. 8.4 The decrease in meiofaunal abundance with ocean depth. (Tietjen 1992)

Population densities of more than 1,000 ind. 10 cm−2 have been recorded in deep-sea areas with a high input of food particles. In the deep-sea of polar regions, especially beneath the ice margins with their rich supply of phytodetritus, meiofaunal abundance can even exceed these values (up to 5,000 ind. 10 cm−2 have been sampled) (Pfannkuche 1992; Soltwedel et al. 2003; Vanhove et al. 1995). Also, in upwelling areas, along the foot of the continental slope or in sites where currents accumulate debris, the richer nutrient supply gives rise to a generally higher meiofauna density (Alongi 1990b). Whereas in temperate and boreal waters phytodetritus from plankton blooms drives seasonal variations in deep-sea meiofauna, in some tropical areas, monsoon-driven fluxes in surface production seem to cause seasonal variations in the deep-sea. In Indian Ocean samples, the deep-sea meiofaunal density at 5,000 m depth was unusually high, about 45 × 103 m−2 (Ingole et al. 2005). Compared with the macrobenthos, the deep-sea micro- and meiofauna are generally more responsive to nutritional changes arising from the surface (Vincx et al. 1994; Gooday 2002). However, this close correlation between food supply (measured as chloroplastic pigments) and meiofaunal abundance was not found in the warm deep-sea of the Sulu Sea, where (corresponding to the conditions at the bottom of the Red Sea) low rates of degradable organic matter and low-oxygen conditions act as stressors (Shimanaga et al. 2007). Biomass and production. Towards the deep-sea, all animal groups experience significant exponential decreases in both abundance and biomass. Smaller size classes replace larger size classes. Since the general decline with depth is particularly rapid for macrofauna, larger animals, their fraction of the total community biomass compared to the fraction represented by the meiofauna shows a steeper

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decline towards the deep-sea and favors the meiobenthos. This can result in a biomass ratio between the macro- and meiobenthos of 1:1 (Tietjen 1992). With the benthic protozoans included, the preponderance of the macrobenthos is even more attenuated (see Sect. 9.3.3). The strong relationship between the meiofaunal abundance and biomass and the supply of organic matter, which in turn depends on depth, allowed De Bovée and Labat (1993) to suggest a linear regression with sample depth as the main variable. Meiofaunal biomass from the abyssal plains is often only 50–100 mg fresh wt m−2 (equalling approximately 4–8 mg C m−2). These low values underline the oligotrophic character of wide abyssal regions, although in the areas that receive a high flux of organic matter, values of around 1 g fresh wt × m−2 or more have been recorded. The meiobenthic biomass in Arctic regions was 3–10 times lower than that in richer East Atlantic bottoms (Pfannkuche and Thiel 1987). Canyons and the foot of the continental slopes, with their larger influxes of organic matter from the shelf, are usually more productive. 37 mg C m−2 were measured for the meiofauna of a Mediterranean canyon (De Bovée and Labat 1993). At various Pacific stations, Shirayama (1984) found unusually high biomasses (calculated from ash-free dry weight): metazoan meiofauna was between 103 and 4,120 mg wwt m−2, depending on depth and sediment type (corresponding values for foraminiferans were 130 and 3,414 mg wwt m−2). The few biomass data from the Indian Ocean are not sufficient to provide a consistent picture. In general, productivity rates in deep-sea bottoms are 2–3 orders of magnitude lower than in shallow-water sediments. Shirayama (1995) calculated that a generalized deep-sea meiofauna specimen will ingest about 10 ng C per day, while the same value can be ingested per hour in shallow sediments (Tietjen 1980a). Nevertheless, 80% of all metabolic processes in the deep-sea refer to meiobenthic organisms (Shirayama and Horikoshi 1989). An annual mean consumption rate for the meiobenthos of about 10 g C m−2 has been calculated (De Bovée and Labat 1993). Locally (e.g., in the Mediterranean) this rate can be lower (about 2.9 g C m−2). This demand is largely supplied by seasonal pulses of organic matter from the surface and by horizontal advective currents, sometimes influenced by the tides. The specific role of the meiobenthos in the biological productivity of the deep-sea is still rather difficult to assess, since the problems involved in measuring production (see Sect. 9.3.2) are aggravated in the deep-sea. The following promising methods have been suggested: - Recording community respiration in a limited sediment area under a bell jar (Pfannkuche and Lochte 1990). - Quantitative analysis of the most important nutrient input, the chloroplastic pigments. This parameter, which depends directly on the production of phytoplankton in the euphotic zone, couples the meiobenthos in the deep-sea with the ocean surface (Thiel et al. 1988/89; Fig. 8.5). However, there may be disadvantages to this approach, since the nutritive value (palatability) of phytodetritus can vary (fresh vs. aged detritus: Soltwedel 1997; Witte 2005).

8.3 The Deep-Sea

295

No. x 10 cm−2

2000

1000

0 0

5

10

15

AFDW mg x 10 cm−2

25

CPE (ng x cm−2)

a 1.0

0.5

0 0

b

20

5

10

15

20

25

CPE (ng x cm−2)

Fig. 8.5a–b The correlation between phytodetritus (chloroplastic pigments) and meiofaunal abundance (a) and biomass (b) in the deep-sea. (Pfannkuche 1985)

- Measuring the ATP content as well as the activity of the electron transport system (ETS), both of which reflect the (meio)benthic metabolic rate. The deep-sea is the largest biotope but the one that is least explored biologically. We do not yet have a reliable picture of the composition, diversity, distribution and ecological role of the deep-sea meiobenthos. Why were the composition and the abundance of the deep-sea meiobenthos, with its dominance of protozoans, not recognized earlier? Apart from problems with accessibility and inadequate equipment, the dominant taxon—the benthic foraminiferans with their irregular shells that are covered by agglutinated detritus—has often been overlooked. Considering the global extent of the deep-sea, a representative exploration seems impractical. Large parts of the southern oceans in particular must still be considered “terra incognita” in terms of their meiobenthos. More detailed reading: Thiel et al. (1988/89); Tietjen (1992); Vincx et al. (1994); Gooday (2002a); manganese nodules, Mullineaux 1987; Foraminifera, Gooday et al. 1992; Snelgrove and Smith (2002); latitudinal gradient, Clarke (1992); Rohde (1992); Rosenzweig (1995); Gaston (2000); Lambshead et al. (2000); monograph on the deep-sea, Gage and Tyler (1991).

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8.4


Dysoxic, Anoxic, and Sulfidic Environments: Discussing the Thiobios

Life began in an anoxic and sulfidic world. Even in today’s oxic world there are large environments where suboxic (dysoxic) or even anoxic conditions prevail. They originate under the influence of bacterial degradation wherever low oxygen supply meets high organic enrichment. The bacterial consumption of oxygen is often accompanied by the formation of toxic hydrogen sulfide. Hence, hypoxic/anoxic sediments develop naturally and worldwide, although human activities also continuously increase the number and persistence of anoxic/sulfidic sites. Anthropogenic eutrophication and deposition of organic matter accompanied by rising temperatures often create anoxic and sulfidic conditions, as evidenced by the frequent appearance of (black) sediment patches in the summer months. Sheltered hydrographic conditions are most affected, while the oxygen depletion is less severe in places with rich plant growth and intensive bioturbation. As general interest in ecology has increased, the fauna adapted to sulfidic conditions have also attracted more attention. This living system of the sulfide biome (Fenchel and Riedl 1970) was named “thiobios” by Boaden and Platt (1971). The fauna consisted mostly of ciliate protozoans along with some meiobenthic metazoans. Fenchel and Riedl (1970) had realized that there is a distinct, definable community of eukaryotic life that is specifically adapted to reducing conditions. Referring to nematodes, Ott (1972) had also emphasized that “the sulfide system has a homogeneous and stable … fauna of its own right”. Since complete anoxia had not been considered a prerequisite for the existence of a thiobios, it was an unfortunate and ecologically unrealistic approach to link the existence of a thiobios to the absence of oxygen. Reise and Ax (1979) questioned the term “thiobios,” since they could not find “a specific meiofauna confined to oxygen-deficient horizons of the sediment,” regrettably without measuring the microgradients of oxygen or hydrogen sulfide. In the modern understanding of “thiobios,” it seems adequate to base the definition on an etymological root (ϑηιon, theion, Greek for “sulfur”), emphasizing hydrogen sulfide (and/or other reduced substances) as the controlling factor: “Thiobios represents a diverse community of organisms characteristic for biotopes where hydrogen sulfide and other reduced substances are regularly dominating ecofactors. The thiobios is directly or indirectly linked to sulfidic habitats.” The existence of a meiobenthic thiobios is neither questionable nor ecologically irrelevant considering the trend towards more hypoxic/sulfidic environments. Among the thiobios, soft-bottom meiobenthic forms play a substantial role.

8.4.1

Reducing Habitats of the Thiobios

Oxygen depletion is often connected with the development of hydrogen sulfide. The distribution of this important ecofactor is mostly antagonistic to that of oxygen (see Fig. 2.11), and part of a complicated and changing system with intermingled

8.4 Dysoxic, Anoxic, and Sulfidic Environments

297

processes and differentiated gradients of O2 and H2S. The few general features that exist in this dynamic web are (a) ubiquitous transitions between oxic/anoxic and anoxic/sulfidic microenvironments, often in the range of micrometers or even just cell diameters (see Fig. 2.8; Revsbech et al. 1980; Bock et al. 1988; Fenchel 1996), and (b) their continuously changing dynamics based on microbial metabolism (Reichardt 1989). Since these transitions are often suboxic (also termed “dysoxic”), from an ecological perspective they belong to the reducing habitats, and so will be considered here too. Areas where sulfidic biotopes can be encountered are as numerous as the processes associated with them, and include deep-sea hydrothermal vents, gas and oil seeps, and silled marine basins such as the Baltic and the Black Sea. Large suboxic to anoxic and highly sulphidic areas also prevail in upwelling zones off the coasts of Peru and Chile, where organically rich muds are blocked from taking up oxygen by upwelling currents. Oxygen minimum zones (OMZ) are widespread at the continental margins of the oceans (Levin 2003). Basins filled with anoxic brine that has elevated levels of hydrogen sulfide and methane occur in the Mediterranean and in seep areas in the Gulf of Mexico. The subsurface layers of tidal mudflats and mangroves and coastal sites polluted by sewage represent large sulfidic habitats. Stratified deep lakes develop completely anoxic, often sulfidic, layers in their profundal depths. Reduced sediments develop dissolved hydrogen sulfide in two general ways: (a) The deeper layers of organically rich marine shore sediments (tidal flats, mangroves, estuaries, enclosed seas) become oxygen-depleted. Then, through the microbial reduction of oxidized sulfur species (mainly sulfates), sulfide develops. If produced in excess, not all sulfide becomes bound chemically, so that free sulfide will accumulate as toxic hydrogen sulfide. Because of the rich concentrations of sulfate in seawater, marine habitats reach higher (up to millimolar) concentrations of dissolved hydrogen sulfide than limnetic ones, where the sulfide mainly originates from the degradation of the proteins contained in organic matter. (b) Tectonic activities often lead to the venting of anoxic, volcanic, geothermal waters and gases rich in hydrogen sulfide, often combined with rich amounts of methane and ammonium (geothermal reduction). Particularly frequent in the deep-sea, hot smokers or diffuse venting sites characterize these hydrothermal activities (see Sect. 8.4.7). The structures of the ubiquitous reducing/sulfidic areas and their relevance as biotopes for animals can only be understood by considering microbiological and geochemical aspects, which, in turn, leads to a more dynamic understanding of their biota (e.g., Jørgensen and Bak 1991; Watling 1991; Diaz and Rosenberg 1995; Levin 2003). Some important aspects to be considered in this scenario are: - Microbial sulfate reduction, which produces sulfide, is possible under both anoxic and low-oxic conditions (see Jørgensen 1977a; Jørgensen and Bak 1991). - In natural marine sediments, thiosulfate is the predominant sulfur species, and it breaks down to a large extent into sulfide and sulfate (Jørgensen 1990; Fossing and Jørgensen 1990).

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- Microchambers (often only 50–200 µm ø) with reduced conditions amid oxic sediment can form a three-dimensional network of oxic and sulfidic microgradients (Jørgensen 1977a; Wilson 1978; Gowing and Silver 1983; Ramsing et al. 1993; Fenchel 1996; Förster 1996). Bioturbation and plant growth complicate their continuous dynamics and alteration (Fenchel 1996; Wetzel et al. 1995; Lee 2003). - The narrow light-colored haloes around tube structures in the sulfidic depths contain oxygen that is mostly in a chemically fixed form; free oxygen is available only temporarily (Jørgensen and Revsbech 1985; Watling 1991; Wetzel et al. 1995; De Beer et al. 2005a). - Oxidized sediment layers can lack free oxygen, but they can still have positive redox values, see Sect. 2.1.4). Oxygen respiration by most animals requires dissolved free oxygen (Sikora and Sikora 1982; Jørgensen and Revsbech 1985; Watling 1991). The following chapter will show that all of these diverse sulfidic biotopes are, at least temporarily, habitats for a characteristic, specialized meiobenthos, and it will challenge their alleged azoic nature.

8.4.2

Thiobiotic Meiobenthos

What is the composition of the typical meiofauna thiobios? Which groups are regularly encountered in the sulfide biome? Foraminifera: In temporarily oxygen-depleted and sulfidic sediments, Foraminifera prevail in abundance. Numerous species have been found in dysoxic or even completely anoxic sediments (Bernhard 1996; Bernhard et al. 2000; Moodley et al. 1997). Their quantitative prevalence under temporarily anoxic conditions has been tested experimentally and is not restricted to the deep-sea (see Sergeeva and Gulin 2007). Especially under conditions of high organic enrichment, they can form high-abundance but low-diversity communities. Ciliata: In many beaches, most of the ciliates are probably migrating between anoxic and oxic strata (Fig. 5.6; see Berninger and Epstein 1995). A rich ciliate fauna can be found mainly around the RPD layer (e.g., Kentrophoros), and many of these thiobiotic ciliates maintain a veritable “kitchen garden” of prokaryotic symbionts (Fenchel and Finlay 1989). Other ciliate species (Metopus, Plagiopyla) harboring methanogenic bacteria as symbionts live as true anoxybionts deep in the black layers (Fenchel et al. 1977; Fenchel and Finlay 1991). They lack normal mitochondria but possess hydrogenosomes (Hackstein et al. 1999). The hydrogen excreted by the ciliates is coupled by methanogenic bacteria to the reduction of CO2 and the resulting methane is released. Platyhelminthes: Among the turbellarians, numerous representatives of the Acoela (e.g., Solenofilomorpha, Oligofilomorpha, Parahaploposthia) and Catenulida (Retronectidae, Paracatenula) are found in the deeper horizons around or underneath the oxic/sulfidic interface (see Figs. 8.7, 8.8; Sterrer and Rieger 1974;


299

1

2

3

4

ind.x 10 cm3 2000

1500

1000

500

1

June

May

3 April

Feb.

Jan.

Dec.

Nov.

Oct.

Sept.

Aug.

July

June

0

March

2 4

Fig. 8.6 The preferred occurrence of meiofauna (here mainly turbellarians) along the tube walls of biogenic structures. Diagram showing the distribution and annual fluctuation around the tube of the lugworm, Arenicola marina. Numerals in the sediment block stand for subsamples equidistant from the tube into the surrounding sediment. They correspond to those indicated in the lower distributional graph. (After Scherer 1984)

Boaden 1975; Crezée 1976; Powell 1989). Their preference for hypoxia has been known for quite a while, and has been experimentally documented by Meyers et al. (1987, 1988). Scherer (1985) found most thiobiotic turbellarians in the close vicinity of macrofauna burrows, where they probably take advantage of an enriched food supply (Fig. 8.6). Gnathostomulida: While in most meiobenthic groups the thiobiotic species are exceptional specialists, it seems that all of the gnathostomulids prefer low oxic to anoxic or mildly sulfidic biotopes (Müller and Ax 1971). They are regularly encountered along the tube walls of endobenthic burrowers and they have been

300

8 Meiofauna from Selected Biotopes and Regions 0

Ptycholaimellus sp.

1 2 Daptonema fallax Theristus roscoffiensis

Neochromadora trichophora

Viscosia franzii

Rhinema sp.

Sabatieria celtica

Cyartonema sp.

000

Karkinochromadora lorenzeni

425

Monoposthia sp.

0 1 2

25 000 ind. x m−2

10

Paralinhomoeus sp.

Rhabdocoma riemanni

Pomponema sp.

Daptonema sp.

Scraptella tenuicaudata

Prochromadorella paramucrodonta

Nannolaimus fusus

Leptonemella aphanothecae

Sabatieria longispinosa

Spirinia sp.

20 cm

Pomponema tautraense

Odontophora rectangula

10

20 cm

Fig. 8.7 The vertical distributions of various nematodes in sediments of the Kattegat (Baltic Sea). Separate oxibiotic and thiobiotic faunal assemblages are apparent. (After Jensen 1987b)

found confined (and present with considerable diversity) to the reduced fine sand underneath cyanobacterial mats or the roots of surf grass (Westphalen 1993). They even dominate all other meiofauna in the permanently anoxic sediments underneath deep-sea brine seeps (Powell and Bright 1981; Powell et al. 1983). This phylum of primitive Bilateria is a typical component of thiobiotic meiofauna. Gastrotricha: The close relation of some gastrotrich genera to the reduced milieu of the thiobiota is documented by their scientific names: Thiodasys, Turbanella thiophila, T. reducta (Boaden 1974, 1975). Frequently, these and other gastrotrichs can be found in the black layers of sand underneath the chemocline. Urodasys is represented by several species in the anoxic Santa Barbara Basin (Balsamo et al. 2007). Kinoryncha (indet.) have been reported from the permanently anoxic bottom of the Black Sea (Sergeeva 2003). Nematoda: The most abundant animals in suboxic and reduced sediments are particular groups of nematodes (Moodley et al. 1997; Gooday et al. 2000; see Fig. 8.7). Most of them are unusually slender or threadlike (Jensen 1987b), and belong to Siphonolaimidae and Linhomoeidae (Monhysterida), but typical inhabitants of sulfidic biotopes also occur in the enoplid family Oncholaimidae (Pontonema), the chromadorid families Comesomatidae (Sabatieria), Xyalidae (Daptonema),


301

Macrostomum Turbanella

Solenofilomorpha

Preapha nostoma

Kuma

Parahaploposthia

OXIBIOS

THIOBIOS

normoxic

anoxic, no sulphide

microoxic

low sulphidic

zero-oxygen line

high sulphidic

Fig. 8.8 The occurrence of various oxibiotic and thiobiotic turbellarians in a depth profile of a tidal flat and around a worm burrow. (After Powell 1989)

the Desmodoridae (subfamily Stilbonematinae: Leptonemella, Eubostrichus), and in some Epsilonematidae (Glochinema). Desmodora masira regularly carries bacteria of unknown function in its cuticular furrows (Bernhard et al. 2000). Sabatieria pulchra tends to increase in abundance under hypoxic conditions (Modig and Ólafsson 1998). For faunistic details of the nematodes from the anoxic depths of the Black Sea, see Zajcev et al. (1987), Sergeeva (2003) and Sergeeva and Gulin (2007). Their counterparts in the limnic thiobios are members of the genus Tobrilus and some dorylaimids such as Eudorylaimus andrassy. Corresponding to their taxonomic divergence, they exhibit a wealth of structural peculiarities, of which only a few have been closely investigated: reduction or absence of the gut (Astomonema, Parastomonema, Rhabtothyreus with a “trophosome,” Miljutin et al. 2006); accumulation of large globular granules in the

302


intestinal cells (Siphonolaimus, Sphaerolaimus, Sabatieria, Terschellingia); inclusion of crystals in the muscle cells (Tobrilus, Sabatieria). It has been assumed by various authors that the furry covers exhibited by the Stilbonematinae, which consist of symbiotic sulfur-oxidizing epibacteria, are related to a thiobiotic lifestyle (Ott et al. 1991, 2004). Oncholaimus campylocercoides from shallow hydrothermal vents has been experimentally found to accumulate globules of polysulfur underneath the cuticle if exposed to hydrogen sulfide. This metabolic capacity is considered rare among aposymbiotic metazoans (Thiermann et al. 2000). Chemoautotrophic bacterial mats on the surface of a freshwater pool in Movile Cave (Romania) are inhabited by several nematode genera, among them the endemic Chronogaster troglodytes. These species have been experimentally shown to be well adapted to the methanic and sulfidic water and the extremely low oxygen concentrations in the mats (Riess et al. 1999; Muschiol and Traunspurger 2007). Oligochaeta: There are two marine genera, Inanidrilus and Olavius (Tubificidae), with numerous species that all are typically thiobiotic (Giere 1981; Giere and Langheld 1987; Erséus 1984, 1990b; see below). Polychaeta: A few adapted species occur in anoxic bottoms of the Black Sea (Nerilla, Protodrilus, Victorniella). In some nerillids, endo- and ectosymbioses with bacteria of unknown function are established (Tzetlin and Saphonov 1995; Bernhard et al. 2000). Crustacea: A few specialists among the normally oxygen-demanding ostracods and harpacticoid copepods (e.g., Cletocamptus confluens) were experimentally found to not only tolerate low oxygen concentrations but also unusually high rates of hydrogen sulfide (e.g., Cyprideis torosa). Among copepods, the Dirivultidae (Siphonostomatoida) dominate around hydrothermal vents (see Sect. 8.4.7). The harpacticoids Ectinosoma melaniceps, Parastenhelia spinosa and some others are regularly encountered in anoxic muds of the Black Sea; here copepod resting eggs were also quite common (Sergeeva 2003). The same study also reports that malacostracan crustaceans, widely held to be sensitive to any oxygen deprivation, occur under complete anoxia in the depths of the Black Sea (tanaids, amphipods). Various crustaceans such as the cephalocarid Lightiella live regularly under lowoxic conditions in marine caves (Schiemer and Ott 2001).

8.4.3

Survival of Thiobios Under Anoxia and Sulphide – Mechanisms and Adaptations

Survival and even persistence for months and years under anoxic/sulfidic conditions have been recorded in various meiofauna, but the underlying physiological pathways are yet to be elucidated. In protozoans, a broad spectrum of Foraminifera are tolerant to complete anoxia, even in combination with the presence of hydrogen sulfide (Bernhard 1996; Bernhard et al. 2000; Bernhard and Sen Gupta 2002; Moodley et al. 1998a,b; 1997; Moodley et al. 2008). A subset of hard-shelled


303

foraminiferans was viable for three months under anoxic conditions, surviving even longer than the nematodes species in the same sample, which lived for up to two months in complete anoxia (Moodley et al. 1997). The authors therefore suggested a foraminiferan/nematode ratio as a bioindicator of prolonged anoxia. The capacity of many ciliate species to live under suboxic to anoxic conditions formed the basis of Fenchel’s conception of a sulfide biome (see above, Fenchel et al. 1977). Among the metazoa, nematodes almost always prevail in suboxic to sulfidic biotopes (Cook et al. 2000). Some sampling sites in Kenyan mangrove muds were dominated by the bacterial symbiotic Astomonema sp. The nematode Eudorylaimus andrassyi and the tubificid Euilyodrilus heuscheri were retrieved from the permanently anoxic Lake Tiberias (Por and Masry 1968) and subsequently kept for several months in a sealed jar under complete anoxia. Even the symbiotic oligochaete Inanidrilus leukodermatus could survive in a sealed jar with its original sediment and in the presence of H2S (notable for its smell) for five months. Gnathostomulids and nematodes occurred in reduced sediments cut off from oxic seawater by a thick-layered seep of brine (Powell and Bright 1981; Jensen 1986a). Various other species of nematodes, turbellarians and gastrotrichs have been reported from the black depths of various tidal flats. In the oxygen minimum zone (OMZ) off the coast of Peru and Chile the anoxic/suboxic sediment interface is covered with large bacterial mats (mainly Thioploca) and harbors, besides the dominating nematodes, considerable numbers of rotifers, annelids and nemertines (Aramayo et al. 2007). Compared to these rather isolated reports of survival under anoxia, the meiofauna found in the world’s largest anoxic basin, the bottom layer of the Black Sea, undoubtedly proves the existence of a fairly diverse and rich benthos that lives under anoxia and in relatively high methane/sulfide concentrations. Nematodes of the genera Desmoscolex, Tricoma and Cobbionema and some tubificid oligochaetes (?Tubificoides sp.) have been reported from the permanently anoxic depths (> 300 m) of the Black Sea (Zajcev et al. 1987). Confirming these reports, Luth et al. (1999), Sergeeva (2003), and Sergeeva and Gulin (2007) found a meiofauna with an abundance of 50–75 ind 10 cm−2 (dominated by nematodes and foraminiferans) living below the oxycline in permanently anoxic and highly methanic/sulfidic conditions. They also found crustaceans (harpacticoids, tanaids and ampipods), kinorhynchs, and acarids. Even polychaetes (Nerilla, Protodrilus, Victorniella), mites, and juvenile molluscs were encountered. In addition, the muddy sediment contained numerous (> 200 10 cm−2) dormant eggs of copepods and cladocerans. A considerable portion of this peculiar anoxic fauna was not attributable to known taxa, even to phylum (Sergeeva 2003). The sea floor beneath brine basins in the Gulf of Mexico harbored an aberrant meiofauna dominated by gnathostomulids (Powell and Bright 1981; Powell et al. 1983); also in anoxic and sulfidic brine basins of the Mediterranean lived a remarkable meiofauna that was not dominated by nematodes (Lampadariou et al. 2003). As yet, we cannot conceive the physiological pathways that lead to this survival capacity, since most physiological methods are still inappropriate for animals of such minute size. In contrast to macrofauna, the small body diameter of meiofauna

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(below 1–2 mm), would allow maintaining an oxygen supply even under low oxygen concentrations by diffusive gradients alone (Powell 1989; Fenchel and Finlay 1995; Fortey et al. 1996). Theoretical considerations and recorded oxygen consumption rates of different meiobenthic groups led Powell (1989) to infer that meiofauna can use an aerobic metabolism at oxygen concentrations as low as 0.1 µmol l−1, which is below the detection levels of many oxygen electrodes. Even when physiologically adapted to low-oxygen conditions, meiofauna must nevertheless be protected from toxic and highly permeable hydrogen sulfide in order to exploit the ecological potential of sulfide-exposed habitats (Giere and Langheld 1987; Ott and Novak 1989; Powell 1989; Schiemer et al.1990; Vopel et al. 1996; Grieshaber and Völkel 1998; Bernhard et al. 2000). The underlying physiological pathways remain largely unexplored. Extreme metabolic specialization of whole communities was demonstrated by studies in the oxygen minimum zone (OMZ) off Chile. Here, sites with very low oxygen concentrations (0.8 ml l−1) harbored even higher meiofauna abundances than more oxygenated sites (Veit-Köhler et al. 2009). The toxicity of H2S is believed to be the main factor that controls the occurrence of thiobiotic meiofauna, since it (reversibly) blocks cytochrome c oxidase and thus the oxygen uptake required for “normal” ATP production. However, the physiology of the lugworm (Arenicola) demonstrates that organisms can develop other energy production pathways, e.g., gaining energy from the oxidation of sulfide using sulfide-insensitive cytochrome complexes (Grieshaber and Völkel 1998). “An ecological compromise between the food requirements of these organisms and their adaptations to the toxic influence of HS” (Sergeeva and Gulin 2007) describes the situation in the Black Sea, but does not reveal the underlying cellular physiology. Ecophysiological experiments by Wieser et al. (1974) not only confirmed the long-term survival of nematodes in anoxic sediment; for Paramonhystera wieseri, they even documented that the presence of oxygen impaired the ecophysiological capacity and viability of this nematode, which exists solely in deep, black sediments. The long persistence and even growth of nematodes under anoxia remains enigmatic, since the formation of cuticular and collagenous material requires oxygen. Jensen (1995) reported that juvenile Theristus anoxybioticus (Nematoda) from sublittoral muds died in oxic water while adults survived well, which corresponds to their field behavior where the long-lived juveniles preferred the deep, anoxic sediments. Schiemer and Duncan (1974) showed experimentally that the nematode Tobrilus gracilis stayed, metabolically, largely anaerobic, even in the presence of oxygen. In experiments performed under anoxia and slightly sulfidic conditions, Metachromadora vivipara even increased in abundance (Steyaert et al. 2007), while other nematode species in these experiments decreased in number and showed reduced activity. Many animals with a high tolerance for anoxia still try to maintain an oxic metabolism at extremely low residual oxygen concentrations (Powell 1989; Gnaiger 1991; Giere et al. 1999). Long-term survival under anoxic conditions was also reported for the turbellarian Parahaploposthia, which was found to be CN- and H2S-insensitive (Fox and Powell 1986, 1987). Thiobiotic animals are usually sluggish animals of low activity. They can considerably reduce their oxygen uptake rates compared to typical aerobic species


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(Fox and Powell 1987; Schiemer et al. 1990). Many nematodes and gnathostomulids living below the chemocline can regulate their metabolic levels down to low rates (Schiemer and Ott 2001), and often fall into quiescence when exposed to prolonged anoxia and sulfide concentrations (Vopel et al. 1996). In many species the role of mitochondria seems to be important. In macrobenthic species, the mitochondria have been identified as the site of sulfide oxidation (Powell and Somero 1986; Völkel and Grieshaber 1996). Perhaps are unusually high numbers of these organelles in the tissues of many thiobiotic meiofauna or significant modifications of their structure compared to the normal appearance of adaptive relevance (Duffy and Tyler 1984; Giere et al. 1988a; Jennings and Hick 1990)? Balsamo et al. (2007) speculated that the absence of mitochondria in the sperm of some gastrotrichs might be related to the occurrence of suboxic/anoxic muds in the Santa Barbara Basin. Parallel to conditions in the macrobenthos (Powell and Arp 1989), in some specialized meiobenthos the properties of hemoglobin also seem adapted to scavenging the slightest traces of oxygen (e.g., Colacino and Kraus 1984 for the gastrotrich Neodasys). Boaden (1975, 1977) discussed the role of heme proteins as efficient oxygen scavengers in various red-colored species of Gnathostomulida and Turbellaria; without further explanation Tsurumi et al. (2003) related the presence of hemoglobin in dirivultid copepods of hydrothermal vents to their tolerance of reduced oxygen levels. Unusual organelles possessing sulfide-oxidizing activity (“sulfideoxidizing bodies”) have also been suggested for meiofauna, but have never been documented. Anoxia in nature is mostly accompanied by hydrogen sulfide, one of the most toxic natural agents. However, there are almost no studies that examine the combined effects of these often co-occurring ecofactors. This may be due to the complex instrumentation required to reliably work with defined concentrations of volatile solutions (Visman 1996). Despite some inconsistencies, there is usually a negative synergism for hydrogen sulfide and anoxia. The presence of sulfide triggers a switch to a fermentative metabolism at an earlier phase than would be induced under anoxia alone (Cyprideis torosa, Ostracoda: Jahn et al. 1996; Cletocamptus confluens, Harpacticoida: Vopel et al. 1996). In some typical thiobiotic meiobenthos the activities of oxygen-metabolizing, sulfide-insensitive enzymes were found to be higher than in oxybiotic and macrobenthic fauna, indicating a specialization to cope with the toxicity of oxygen radicals (Morill et al. 1988). It is conceivable that in an environment free of dissolved oxygen, oxidized substances such as nitrate or thiophosphate can become enzymatically activated to serve as oxygen donors. This pathway is known from prokaryotes, from the ciliate Loxodes (Finlay et al. 1983), from representatives of the bacterial symbiotic Stilbonematinae (Nematoda), and gutless interstitial oligochaetes (Hentschel et al 1999; Woyke et al. 2006). An increasing number of meiobenthic species from dysoxic or sulfidic habitats have been found to depend on the symbiotic association with sulfide- or methaneoxidizing bacteria (for reviews see Giere 1996; Ott et al. 2003). A large group of gutless interstitial oligochaetes completely depend on their subcuticular extracellular symbionts and rely on the integrated cooperation of a bacterial consortium, each

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with a complicated and highly adapted metabolism (for an overview see Bright and Giere 2005; Dubilier et al. 2006). All of these oligochaete species have incorporated beneath their cuticles a thick layer of sulfide- or methane-oxidizing bacteria which continuously remove the toxic sulfide as they metabolize. This active protection enables the hosts to live in the subsurface layers of shallow sands. Obligate endosymbiosis with bacteria, combined with a reduction of a functional gut, has also developed in nematodes such as Astomonema that occur in sulfide-enriched sediments (Musat et al. 2007), and in Rhaptothyreus (Miljutin et al. 2006). The symbiosis of numerous stilbonematine nematodes (Leptonemella, Catanema) with sulfur-oxidizing ectobacteria, which decoratively ornament their cuticles, enables these worms to live in deeper layers of sand beneath the chemocline (Ott et al. 2003). There are several other meiofauna species within the turbellarians and the polychaetes that live in symbiosis with bacteria, but details about their symbionts’ nature and function are lacking. While further analysis of symbiotic bacteria is required, it should be noted that many thiobiotic animals can survive in extreme sulfidic environments without “bacterial metabolic help.” Beyond certain specific threshold values, they will switch over to an anaerobic metabolism that can sustain them for long periods of time. However, severely sulfidic habitats are avoided, a reaction that corresponds to those of numerous macrobenthic animals (for reviews see Somero et al. 1989; Fisher 1990; Vismann 1991; Bagarinao 1992; Grieshaber and Völkel 1998). The production of sulfur-containing granules or crystals and protection from sulfide by external precipitation (Giere et al. 1988b for Tubificoides benedii) is probably of limited importance, although the quantitative roles of these processes are still to be assessed. Iron has been found in various tissues of sulfide nematodes, and it has been suggested that it binds reduced sulfur (Nuß and Trimkowski 1984; Nicholas et al. 1987; Giere 1992). However, the exportation of the resulting precipitates needs to be demonstrated before this pathway can be verified as a means of detoxification. A more efficient option is the oxidation of sulfides into long-chained polysulfur, which can be stored as an inert but easily activated product in the tissues. This pathway is known from “sulfur bacteria,” but apparently also occurs in a thiobiotic nematode, Oncholaimus campylocercoides (Thiermann et al. 1994, 2000). However, considering the high diffusion rate of hydrogen sulfide through the minute bodies of meiobenthos, the efficiency of any protective method remains doubtful (Powell 1989). A pathway using accumulated carotenoids, common accessory pigments in photosynthesis, as energy-rich substances and oxygen reserves, has been suggested by Zajcev et al. (1987), but has not been demonstrated in physiological detail for invertebrates. Nonetheless, the multiple ecophysiological approaches that have evolved in meiobenthic animals to cope with life under anoxic and sulfidic conditions indicate the complexity of the ecological and physiological processes involved. The sulfidic ecosystem, which is dominated by the presence of reduced substances such as dissolved sulfide, methane and ammonium, is much too complex to allow for simple right-or-wrong opinions that arose in the early debate about the existence of a thiobios. It is the regular exposure to hydrogen sulfide in a spatially


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and temporally changing combination of micro-oxic and microsulfidic niches that characterizes the world of the thiobios, and not an either/or situation. With today’s deeper knowledge, we have a better understanding of “sulfide habitats,” their ecological conditions, and their physiological demands on the “sulfide fauna.” Future discussions about the possibility of animal life under anoxic conditions would be substantiated if studies were always accompanied by careful microelectrometric oxygen and sulfide measurements (see Sect. 2.1.4), and where possible combined with physiological analyses.

8.4.4

Food Spectrum of the Thiobios

Areas of steep gradients between anoxic/oxic and sulfidic layers are the preferred habitats of rich bacterial stocks with densities of 109–1010 cells cm−3 (Jørgensen 1977b; Aller and Yingst 1978; Ramsing et al. 1993). The sea bottom beneath the upwelling area off Peru and Chile is covered so densely with mats of the sulfur bacterium Thioploca that the sediment has been termed “Thioploca mud.” It has frequently been pointed out that thiobiotic meiofauna graze on the rich stock of sulfur bacteria (Fenchel 1969; Fenchel et al. 1977; Yingst and Rhoads 1980; Grossmann and Reichardt 1991). This attractivity influences the microdistribution of the thiobiotic meiofauna. For some freshwater nematodes in an isolated thermomineral cave (Romania) bacterial mats provide the habitat and apparently the sole food source (Muschiol and Traunspurger 2007). Animal/bacterial symbioses are another means of utilizing the thiobiotic environment (see above). Many symbiotic animals take advantage of the ability of microbes to metabolize reduced substances such as sulfide, thiosulfate and possibly methane. Studies on the gutless Inanidrilus and Olavius (Oligochaeta), on Kentrophoros (Ciliata) and on Stilbonematinae (Nematoda) indicate that these species use their bacteria as a convenient food source. The mostly used pathway is controlled phagocytosis by the host (Giere and Langheld 1987; Fenchel and Finlay 1989). The stilbonematine nematodes feed by grazing on their symbiotic epibacterial fur (Ott and Novak 1989; Ott et al. 1991). The most complicated symbiosis that has been functionally examined so far is a complex syntrophic web of five different bacterial taxa that cooperate in their host, the oligochaete Olavius algarvensis from the Mediterranean (Woyke et al. 2006). Here, some of its bacteria serve the host as food, but others also remove its wastes by reducing nitrate. The food spectra of the thiobiotic turbellarians Solenofilomorphidae and Kalyptorhynchia as well as those of the specialists among the crustaceans and polychaetes have not yet been ascertained. Dissolved organic matter. Dissolved organics are present in considerable amounts in anoxic sediment horizons (Liebezeit et al. 1983; Sect. 2.2.2). Acetate, an important substrate for sulfate-reducing bacteria (Jørgensen 1977a; Gibson et al. 1989; Michelson et al.1989), is utilized by nematodes (Riemann et al. 1990) and is probably an important organic food source for the thiobios. Boaden (1977) even postulated that absorptive feeding on dissolved organics was a general feature of

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the (primeval) thiobios. The thread-like body of many thiobiotic animals with a high length/width ratio and a large surface is believed to support the transepidermal uptake of dissolved organic substances (Boaden and Platt 1971; Giere 1981; Jensen 1986b; Wetzel et al. 1995). Combined with endosymbiosis, this nutritional pathway favors the repeated reduction or transformation of the intestinal tract in the thiobiotic (meio)benthos. The absence of mouth and anus has generated names like Astomonema (Nematoda), Inanidrilus (Oligochaeta) and Astomus (Polychaeta).

8.4.5

Distribution and Succession of the Thiobios

Thiobiotic species have a bacteria-controlled vertical distribution that is different from the usual, characteristic concentrations of oxybiotic meiofauna near the surface (Boaden 1977; Giere et al. 1982; Ott and Novak 1989). Benthic foraminiferans were found at or below the oxic/anoxic chemocline (Bernhard 1996), and ciliates from Scandinavian sites occured over a wide range of depths (Fenchel 1969; see Fig. 5.6). Berninger and Epstein (1995) even contended that most typical beach ciliates live under anoxic conditions, probably migrating up and down. An analysis of the nematode vertical distribution in the Kattegatt (Baltic Sea) revealed an assemblage of oxybiotic species that was clearly separated from the thiobiotic species (Jensen 1987b; Fig. 8.7). Jensen (1981) also demonstrated the presence of a very species-specific vertical pattern within the genus Sabatieria. S. pulchra, a typical thiobiotic species, lives deep in the anoxic sediment, while S. ornata occurs close to the surface. Among limnic nematodes, a similarly differentiated pattern occurs in the genus Tobrilus (Traunspurger 1997a). Powell (1989) summarized experimental studies on various turbellarians with different preference reactions to oxic and sulfidic layers (Fig. 8.8). In normal oxybionts, decreasing the oxygen content and increasing the sulfide content cause avoidance reactions in almost all meiobenthos, first through upward migrations and even emergence from the sediment into the bottom water layers. This avoidance behavior is barely developed in typical thiobios. A preference for layers around the oxic/sulfidic chemocline has been experimentally demonstrated in thiobiotic ciliates, turbellarians, gutless oligochaetes and stilbonematine nematodes (Fig. 8.9). However, this preference is combined with a dynamic positioning: thiobiotic animals typically migrate between oxic and sulfidic horizons, traversing the chemocline each time. They do not maintain a stable position at the chemocline. For the bacteria-symbiotic thiobios it appears that the bacteria recharge their energetically valuable reduced sulfur store while their host stays in the sulfidic layers and subsequently they gain energy from the oxidation of reduced sulfur when their host migrates into the oxic layers (Schiemer et al. 1990; Giere et al. 1991; Ott et al. 1991). Soon after the onset of dysoxic conditions, a marked succession of meiofauna community changes can be observed since the reaction to a hypoxic/sulfidic event differs depending on the meiofaunal taxon. Only when hydrogen sulfide rises to


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a 0

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Fig. 8.9a–b Migration experiments with thiobiotic oligochaetes (a) and nematodes (b) that prefer the chemocline (dark field in vertical bar). The more diffuse this transitional layer, the wider the migratory radius (a after Giere et al. 1991; b after Ott et al. 1991)

millimolar concentrations will most nematode and foraminiferan species disappear (Moodley et al. 1997). However, during periods of severe oxygen depletion even well adapted thiobiotic species such as Pontonema vulgare or Sabatieria pulchra (Nematoda) show avoidance reactions and are often found on the sediment surface (see Hendelberg and Jensen 1993; Wetzel et al. 2001). Some specialized thiobios can withstand up to millimolar levels of H2S in complete anoxia (Jahn et al. 1996; Vopel et al. 1996). Concentrations of H2S above 5 mM are usually lethal, even to the most tolerant thiobionts (but see Sommer et al. 2003). With the return of oxic conditions, the recolonization of the sediment by meiofauna proceeds rather rapidly, normally within a few weeks depending on the distance and status of the oxic donor assemblage. It is mainly the hydrographic regime that determines processes of recolonization, since drift through the water column is the main pathway for harpacticoids and also for nematodes. Usually the fauna is recruited by colonizers of the ambient oxic fauna, and in its first phases it is characterized by low diversity and high dominance indices (Wetzel et al. 2002).

8.4.6

Diversity and Evolution of the Thiobios

Compared to its oxic counterparts, the thiobiotic meiobenthos seems impoverished, at least in diversity, while abundance and biomass can be rather high. This is particularly evident in shallow sulfidic areas (Neira and Rackemann 1996).

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In the polluted Baltic Sea basins and bights, during anoxic and sulfidic periods the meiobenthos is mainly represented by dense masses of the nematode Pontonema vulgare, which feeds on dead macrofauna (Lorenzen et al. 1987). Under similar circumstances, the nematode Terschellingia communis can also develop huge populations. In meiofaunal samples from the oxygen minimum zone off Peru, Neira et al. (2001a,b) found the proportion of nematodes to be extremely high (99%), with a remarkable dominance of one epsilonematid species (Glochinema bathyperuvensis). The authors related the nematode maximum in the OMZ to the high and barely degraded organic content of the sediment. A 10-ml sample of Thioploca mud from the same upwelling area contained about 400 nematodes belonging to more than 20 species of numerous genera (Riemann, pers. comm.). Below the OMZ, where the oxygen content was restored, the abundance of nematodes decreased and that of harpacticoids increased. A change in relative dominance from nematodes to harpacticoids was also recorded by Levin et al. (1991) when sampling from the OMZ down to better oxygenated depths. Also from sediments on the shelf and in canyons with frequently anoxic conditions a prevalence of specialized nematode species that developed considerable abundances was noted (Soetaert et al. 2002). These studies confirm the generally higher sensitivities of harpacticoids compared to nematodes. In oxygen-depleted and sulfidic biotopes a decreasing diversity is observed along with an increasing dominance of single species, and the relative abundances of major taxa change markedly from oxic to suboxic/sulfidic depths (Gooday et al. 2000; Cook et al. 2000). Anoxic/sulfidic events exert a considerable selective pressure. Does this pressure become significant from an evolutionary perspective? Is it possible to characterize thiobios by particular anatomical features (bacterial symbioses, malformations or degenerative trends, see above)? The phylogenetic relevance of the thiobios is debated (see Fenchel and Finlay 1995). A fauna that has existed since archaic times should have considerable evolutionary relevance and should represent primitive life forms. However, suggestions “that the sulfide biome would contain at least some primary (faunal) elements… of the oldest biosystem on Earth” (Fenchel and Riedl 1970) were vehemently refused (Reise and Ax 1979). Today it is widely accepted that the extant thiobios is derived from oxybiotic predecessors. Even the evolution of complex bacterial symbioses in some meiofauna must be considered a relatively recent development, despite the profound anatomical reorganizations involved. This does not refute that the earliest metazoan fauna did indeed evolve under anoxic/sulfidic conditions. The various hypotheses about the environment of archaic metazoans center around the question of whether primitive, meiobenthic metazoan life had already evolved in the Proterozoic. The appearance of oxygen at the lowest concentrations probably predates the Ediacaran period (Jenkins 1991; Mangum 1991; Runnegar 1991; Thomas, 1997). During the late Proterozoic the ocean water may have contained low concentrations of free oxygen. However, at the sediment/water interface, with its rich organic matter, degradation will have caused intense oxygen consumption. Hence, according to modern insights into sedimentary ecology (see Sect. 2.1.4), during that geological


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period the sediment strata (the habitat of meiofauna) were probably largely anoxic (Revsbech et al. 1980a,b; Watling 1991; Giere 1992). If subsurface sediment layers in the late Proterozoic world were devoid of oxygen, but the water above the sediment was oxic, why should animals prefer the hostile conditions below the surface and live an endobenthic life? Compared to recent geological periods, organic particles serving as a nutritive basis were rare in the Proterozoic. This rare food would have accumulated at the surface and in the upper sediment layer, probably leading to a richer microbial life compared with the water column. These microbial aggregations plus the shelter from erosion and the elevated UV radiation would have favored the existence of small metazoans at the semisolid, fluffy sediment/water interface. Selective pressure to reduce predation might have been a later incentive to stay below the surface in the upper sediment layers. Only with the advent of bioturbation (early Cambrian) were oxic microniches formed, and additional migrations might have sustained a microaerophilic life. It is probably the parallel existence of adjacent oxic and sulfidic microniches in the sediment, especially in the fluffy surface layers, that enabled mobile microscopic animals to adapt to oxic environments. The small dimensions of the most primitive metazoans (see Fortey et al. 1996), today classified as meiofauna, were an important prerequisite for their utilization of the traces of oxygen present, via diffusion gradients (Powell 1989; Fenchel and Finlay 1995). Fenchel and Riedl (1970), in their initial paper on the thiobios, did not postulate the restriction of thiobiotic animals to complete anoxia. They included in their reasoning for an archaic thiobiotic fauna “the necessary assumption of a low-oxygen atmosphere in the Precambrian age.” Boaden (1977) also considered low oxygen concentrations to be important for the thiobios when he described a “metabolism adapted to very low levels of dissolved oxygen.” However, Boaden (1975, 1989b) also hypothesized an anaerobic, interstitial and holobenthic primitive “thiozoon.” Today, the possibility of the continuous existence of some “lower animal groups” belonging to the meiobenthic thiobios in a “plesiomorphic biotope” (Boaden 1975) is rejected by most authors (cf. Mangum 1991; Fenchel and Finlay 1995), although some of the animal clades that dominate among the thiobiotic fauna are considered primitive (Plathelminthes). On the other hand, Gastrotricha and Nematoda have attained a derived phylogenetic position and are not primitive descendants of an archaic low-oxic or anoxic biotope. Their thiobiotic representatives are instead metabolic specialists among the “normal,” oxic fauna. Hence, it remains speculative to link thiobios with an anaerobic metabolism and an evolutionary origin in the Proterozoic. As demonstrated above, there are many meiofauna that remain viable under anoxic/sulfidic conditions for extended periods of time or even permanently. The fact that aerobic respiration is much more frequent today than anaerobic fermentation reflects the dominance of present-day oxic environments. Among free-living benthos, one could consider strictly anaerobic life and completely aerobic life as extremes in the wide continuum of varying oxygen supply. Further research will discover many more highly interesting meiobenthic thiobios; perhaps more free-living metazoans from different biotopes (not only from the Black Sea and the OMZ

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sediments). The ability of free-ranging animals to thrive permanently in anoxia provides a relevance far beyond the meiobenthic scope. However, based on the aforementioned definitions and considering the necessary differentiations, this does not really affect the discussion about the existence of a meiobenthic thiobios. More detailed reading: evolutionary aspects, Fenchel and Riedl 1970; Boaden 1975, 1989b; physiological aspects, Powell 1989; Meyers et al. 1987; Grieshaber and Völkel 1998; ecological aspects, Ott et al. 1991, Giere 1992; geochemical aspects, Jørgensen and Bak 1991; anoxic ciliates, Fenchel and Finlay 1991; Hackstein et al. 1999; reviews, Bryant 1991; Diaz and Rosenberg (1995); Fenchel and Finlay 1995; Wetzel et al. 2001; Wu (2002).

Box 8.5 Thiobios: An Old Debate and Modern Data “Does a thiobios exist?” The debate about this question arose from several discrepancies: ecological field observations vs. geochemical microscale measurements, physiological understanding vs. palaeoclimatic reconstructions, classical taxonomic ordination vs. molecular positioning. Meiofauna of (sheltered) sediments have been known to harbor species typically encountered in the black, H2S-smelling mud layers which traditional methods record as being anoxic. So these species live under sulfide and anoxia; they are “living systems of a sulfide biome,” or “thiobios” (Fenchel and Riedl 1970; Boaden and Platt 1971). Provocatively, it was claimed that some thiobios were primitive representatives of a Proterozoic anoxic fauna. In the light of modern molecular methods this contention cannot be upheld. On the other hand, our traditional ecological picture was also erroneous. Detailed geochemical microrecordings disproved the concept of a rather static two-dimensional layer (oxic conditions at the surface and anoxic/sulfidic below). Today we know of a continuously changing three-dimensional web of oxic and anoxic/sulfidic microhabitats through which the tiny, often elongate, thiobiotic animals move. It is just this alternating exposure to oxic/anoxic spaces that is ecologically favorable and physiologically required. The thiobiotic taxa are adapted in various ways to cope with the challenges and chances of the hypoxic/sulfidic world. Today new fossil records have demonstrated that a meiofauna existed in the Proterozoic sediments. In this period, oxygen in the sediment was minimal or absent and reduced sulfur probably ubiquitous. Hence, a thiobios with a “metabolism adapted to very low levels of dissolved oxygen” was (and still is) present, as postulated by Boaden (1977). Also, the recent discoveries of a meiofauna at chemoautotrophic vents and the anoxic deep Black Sea contribute to a more differentiated and more comprehensive view of the thiobios: “Thiobios represents a diverse community of organisms characteristic of biotopes where hydrogen sulfide and other reduced substances are regularly dominating ecofactors. The thiobios is directly or indirectly linked to sulfidic habitats.”


8.4.7

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Chemoautotrophy-Based Ecosystems: Vents, Seeps, and Other Exotic Habitats

Life at the globally famous hot vents or seeps is based on chemoautotrophic processes and not on photoautotrophy. These unique ecosystems are characterized by a spectacular macrofauna. Mud volcanoes, oil seeps or decaying organic masses (large carcasses, sunken wood) also belong, from an ecological perspective, to these biotopes. What about their meiofauna? In contrast to the spectacular macrofauna observed at chemoautotrophic sites, their meiofauna are less exceptional and striking. Therefore, meiofauna have only recently been included in studies of chemoautotrophic ecosystems and detailed knowledge about them is still rare. Characteristic of an increased awareness is the “Meiovent” initiative (Bright and collaborators, Vienna). Meiofauna occur either in the thickets of mussel and tube worm colonies (Alvinella, Riftia, Bathymodiolus) or at the few sites where soft sediments accumulate. The higher the structural complexity of the epifauna thickets, the richer the meiobenthic life (Tsurumi and Tunnicliffe 2003): tightly interwoven tubes are more densely populated than bush-like structures; in mussel beds with young Bathymodiolus (small shells), copepods were more abundant than nematodes, but these prevailed in the older beds (Copley et al. 2007). Vents are characterized by irregular pulses of sulfide- and often methane-rich water alternating with influxes of ambient oxygen-rich seawater. Hence, the ecophysiological potential of the vent meiofauna is comparable to that of the typical thiobios in oxygen-deficient environments outlined above. Because of the accumulated detritus, meiofaunal abundances near vents can be elevated when compared to neighboring sediments. In the methane-dominated center of the Håkon Mosby mud-volcano, a mean density of 220 copepods per 10 cm2 (Tisbe sp.) is indicative of a rich but monotonous meiofauna (Van Gaever et al. 2006); cold seeps in Japanese waters harbored a total of around 400 meiobenthic individuals per 10 cm2 (Shirayama and Ohta 1990). Sediments from methane seeps off the Oregon coast (USA) often contained 1,000 or more individuals per 10 cm2 (Sommer et al. 2007). At one sampling site in the East Pacific Rise (EPR) up to 950 ind. 10 cm−2 were counted (Gollner et al. 2007). However, densities around 10,000 nematodes and more per 10 cm2 belonging to only a few species (Olu et al. 1997; Sommer et al. 2003; Van Gaever et al. 2006) may be exceptional. These figures make these deep-sea sites “chemosynthetic oases” for meiofauna (Soltwedel et al. 2005). However, at a hot-vent effluent in the South Atlantic, some samples (coarse sand) contained no meiofauna whatsoever (unpublished data)—a unique experience, without a readily apparent explanation (toxic composition of the effluents?). Surprisingly low densities and species richness (10–200 individuals per 10 cm2 belonging to 30 copepod species and 4 nematode species) were also recorded in evaluations of the hot-vent meiofauna among macrobenthic epigrowth from thickets of the tube worm Riftia in the East Pacific Rise (EPR), as well as from cold (oil) seeps in the Gulf of Mexico (Zekely et al. 2006a,b; Gollner et al. 2006, 2007). Also, the first compilation of hydrothermal meiofauna by Dinet et al. (1988) from the Guaymas mud seeps and West Pacific vents has reported relatively low mean densities.

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What are the compositions of vent and seep meiofauna assemblages? Worldwide, more than 80 meiobenthic species have been identified at vents so far: Pacific samples average 24 species; Atlantic samples 15 species. Nematodes usually represent the bulk of the meiofauna in chemoautotrophy-driven habitats, around deep-sea and shallow hot vents or in seeps (Kamenev et al. 1993; Buck and Barry 1998; Debenham et al. 2004; Flint et al. 2006; Sergeeva and Gulin 2007; Copley et al. 2007). Since many species belong to separate genera, often in a 1:1 ratio (Vanreusel et al. 1997; Zekely et al. 2006a), the generic diversity is rather high. In Mid-Atlantic Ridge sites nematodes prevailed (63%), and in various macrofauna substrates of the East Pacific Rise (EPR) the nematode Thalassomonhystera dominated, accompanied by other monhysterids and a few other families (Draconematidae, Cythalaimidae, Leptolaimidae, Microlaimidae, and Desmodoridae) (Flint et al. 2006; Zekely et al. 2006a,b). The monhysterid nematode Halomonhystera disjuncta was the only abundant species around a deep-sea mud volcano (Van Gaever et al. 2006). Shallow vent sites mainly harbored species of the common genera Oncholaimus, Sabatieria Desmodora and Chromadorina (Thiermann et al. 1997; Van Gaeuer et al. 2006, 2008; Zepilli and Danovaro 2007). The bacterial symbiotic stilbonematines, common around shallow gaseohydrothermal vents (Kamenev et al. 1993), seem to be lacking at deep-sea vents. The second most common taxon among many hydrothermal meiofauna is copepods. Their diverse taxa represent about 15% of the total vent fauna, with most of them belonging to the siphonostomatoid families Dirivultidae and Ecbathyriontidae, while harpacticoids are of a subordinate rank. A good example of the dominance of dirivultid copepods are the meiofauna in hydrothermally active areas on the East Pacific Rise, with Aphotopontius and Stygiopontius being the most typical genera endemic to hydrothermal vents (Heptner and Ivanenko 2002a,b; Martinez Arbizu et al. 2006; Gollner et al. 2006; Zekely et al. 2006a). Among the subdominant or rare meiofauna taxa are polychaetes (often dorvilleids), turbellarians, halacarid mites, ostracods, solenogastres, and recently kinorhynchs and gastrotrichs (Van Harten 1992; Scheltema 2000; Flint et al. 2006; Katz et al. 2006; Sergeeva and Gulin 2007; Copley et al. 2007). The roles of hydrothermal foraminiferans and ciliates, which are certainly of relevance to the chemoautotrophic biota, have not yet been duly assessed. At Japanese vents, 13% of the hydrothermal fauna consisted of Foraminifera (Shirayama and Ohta 1990). In methane seeps of the Black Sea, other taxa, including polychaetes, hydroid polyps and turbellarians, have been found under anoxic conditions. At oil seeps, some non-specialized harpacticoids with a wide occurrence were encountered. Large food falls in the ocean or thermomineral freshwater caves with high concentrations of methane and sulfide represent special cases of chemoautotrophic environments. Specialized nematodes also prevail in these unusual biotopes (Debenham et al. 2004). The isolated thermomineral Movile Cave (Romania) contains a simple meiofaunal food web. The bacterial mats are grazed upon by various ciliates and five nematode species, among them the endemic Chronogaster troglodytes. At least in experiments, the populations of Chronogaster were devoured and controlled by the copepod Eucyclops subterraneus (Muschiol et al. 2008a). Different meiofauna taxa have been found in other chemosynthetic habitats:


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sediments around methane hydrates with sulfide concentrations of up to 17 mmol harbored, besides the usual nematodes, two species of Lecane (Rotifera). As sulfide concentrations increased their populations became richer, such that they formed the dominant taxon (Sommer et al. 2003; Sommer et al. 2007). The adaptations that enable these specialists to survive under the toxic conditions of chemoautotrophic sites are not understood. They have this in common with the typical thiobiotic meiofauna (see above). Ovoviviparous reproduction, as found in Geomonhystera (Nematoda), might help to ensure the survival of the offspring (Van Gaever et al. 2006). Detoxification of hydrogen sulfide by oxidation into inert polysulfur might be another pathway that is realized in the dominant nematode around shallow gaseothermal fields in the Mediterranean Sea (Thiermann et al. 1994, 2000). Elemental sulfur was also shown to exist in thiobiotic turbellarians (Powell et al. 1980). Symbiosis with sulfide- or methane-oxidizing bacteria as a means of detoxification (as often found in other reducing environments) is rarely documented for meiofauna at vents and seeps. The significance of the biased sex ratios (clearly more females than males) found for both vent nematodes and copepods (Tsurumi et al. 2003; Gollner et al. 2006; Zekely et al. 2006a) is unclear; it is a phenomenon that is also common in “normal” deep-sea environments. A prevalence of slender filiform nematode species, interpreted as an adaptation enabling the effective uptake of dissolved organics in thiobiotic biotopes (see above), is not always seen at vent sites (Buck and Barry 1998). The significance of numerous dormant benthic eggs of copepods and cladocerans and also copepod nauplii in the permanently anoxic Black Sea mud remains unexplained. The absence of adults suggests long migrations (Sergeeva and Gulin 2007). The food web structure in hydrothermal and seep sites is relatively simple— another indication that this is an extreme habitat. Most of the dense meiofauna associated with chemoautotrophic sites are primary consumers that depend on the copious food supply from bacterial deposits condensed as mats or biofilms, resulting in a positive correlation between the abundances of the vent meiofauna and the (bacterial) debris (Limén et al. 2007). Hence, nematodes with weakly cuticularized buccal cavities, typical of deposit feeders (see Sect. 5.6.1), prevail (Dinet et al. 1988). Also, stable carbon isotope analyses suggest that bacteria provide a chemosynthetically derived food source (Van Gaever et al. 2006). Moreover, the considerably larger body sizes of hydrothermal nematodes (Vanreusel et al. 1997) may reflect an abundance of food compared to the normally food-depleted ambient deep-sea bottom. Because this trend is not generally observed at all sites (Buck and Barry 1998) its significance remains uncertain. The dirivultid copepods, frequent among mussel beds, crawl over the substrate and mostly graze on the rich bacterial films. They are also found associated with the tubes of polychaetes; some species of the genus Ceuthocetes may exist as parasites (Gollner et al. 2006), while some occur in the gill chambers of shrimp (Dinet et al. 1988; Heptner and Ivanenko 2002). Chemoautotrophic biotopes show highly variable fluctuations that are often associated with extreme environmental parameters. Judging from the macrobenthos, this should favor specific adaptations, resulting in an independent vent or seep community that is different from the neighboring “normal” fauna and rather isolated

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in its distribution. The entirely benthic larval stages of dirivultid copepods found by Gollner et al. (2006) would suggest distributional restriction (but in other studies vent nauplii were caught in the plankton above the vent; Ivanenko 1998). Comparisons of the meiobenthos in different regions emphasize its high endemism and independence from the ambient fauna. If analyzed at the species level, we find a patchy community controlled by local conditions with low correspondence to neighboring sites (Fricke et al. 1989; Shirayama and Ohta 1990). In a comparison of Pacific and Atlantic deep-sea mussel beds, the overlap between meiofaunal species was zero (Zekely et al. 2006a). This emphasizes the local and patchy character of most vent meiofauna, and would also explain why comparisons of hydrothermal vent and seep fauna with other sulfide/suboxic habitats display a low affinity. However, this isolation only refers to the species level (Shirayama and Ohta 1990; Vanreusel et al. 1997, Flint et al. 2006; Zekely et al. 2006b). The compositions on the genus level are often similar to those in the surrounding normoxic environment rather than to those of other disjunct chemoautotrophic sites. The reported absence of predatory meiofauna in hydrothermal vent sites would be surprising in habitats that are rich in deposit feeders, and so needs further assessment. From corresponding photoautotrophic ecosystems with rich bacterial stocks and organic deposits we know the presence of a variety of carnivorous species. Summarizing, hydrothermal vents and seeps with their copious supply of bacterial food can be perceived as extreme habitats harboring a specialized thiobiotic meiofauna with typically local characteristics. A high density with a low species richness would characterize the extreme nature of these biotopes. The low density and diversity of meiofauna at Pacific hydrothermal vents and seeps, as found in some reports, is perhaps not a general feature. Occasional aggregations of almost 1,000 ind. 10 cm−2 (Sommer et al. 2003; Zekely et al. 2006b) suggest a population patchiness that is typical of extreme habitats. The meiofaunal results from hot vents in the eastern Pacific published so far seem to support a gradient pattern from the hot and toxic smoker walls (Alvinella community) with hardly any sediment to the diffuse venting sites (Bathymodiolus community), where detritus accumulates on the shells and in the crevices. Meiofauna among the tubes of alvinellids represent a highly specialized association of low abundance and high dominance of some dirivultid copepods. Towards more diffuse venting fields with “milder” conditions and more available sediment, nematodes gain in importance and the communities become more diverse and speciose. The small-scale spatial pattern of meiofauna distribution at vents is probably shaped by the varying hydrothermal fluxes and needs further scrutiny. While it appears that the meiofauna at vents along the East Pacific Rise is poorer in terms of both biodiversity and abundance compared to the “non-vent” deep-sea surroundings, the abundance of meiofauna from other vent regions seems to support vents as favourable habitats. Anyway, with respect to meiofauna, vents cannot be considered “oases in the depth” (Dinet et al. 1988; Shirayama and Ohta 1990; van Gaever 2006; Vanreusel et al. 1997; Olu et al. 1997; Soltwedel et al. 2005). More detailed reading: Mokievsky and Kamenskaya (2002); Levin (2005); Van Gaever et al. (2006b); Zekely et al. (2006a).

8.5 Phytal Habitats and Hard Substrates

8.5

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Phytal Habitats and Hard Substrates

Remane (1933, 1940) characterized the phytal as a habitat populated by an abundant and diverse faunal community, which he termed the “phyton.” Wieser (1959b), in his comprehensive study of the phytal meiofauna from various shores, noted a relationship between the size, body structure and locomotion type of the inhabitants, the shape of the algae and the biotopical differentiation of the phytal. For example, on foliose, shrub-like algae of exposed sites, >50% of the often flattened harpacticoids have clawed clinging legs adapted for climbing (see below), while in tufted, fine-filamentous algae only 10% of the harpacticoids are armed with claws. The main reason why algal belts on hard bottoms are important habitats for vagile benthic animals is their structural complexity. This is modified by a set of (often local) abiotic and biotic conditions, such as water depth or exposure. This general conclusion about the phytal meiofauna emerged as early as the fundamental studies by Remane (1940) and Wieser (1959). In exposed phytal zones, the usual numerical dominance of nematodes and their productive role is reduced. Hence, unlike other meiobenthic habitats, the phytal is often characterized by a high percentage of harpacticoid copepods and ostracods. Compared with their low abundance in soft sediments (usually less than 10%), harpacticoids in phytal habitats regularly comprise more than 30% and often more than half of the total meiofaunal abundance and production (e.g. Danovaro et al. 2002; Hopper and Davenport 2006). A high percentage of copepods is also recorded from the blades of seagrass meadows, in strata under dense algal cover, and specifically on the fronds of algal thalli. In both tropical and boreal phytal areas, copepods seem to be the prevalent meiofaunal inhabitants (Wieser 1959; Jarvis and Seed 1996; Danovaro 1996; Danovaro and Fraschetti 2002), primarily represented by Tegastidae, Tisbidae (Tisbe, Scutellidium), Peltidiidae and Porcelliidae. Only in the deeper, hardly exposed phytal are the climbing meiofauna replaced by wriggling meiofauna (nematodes). The closer the phytal is to soft sediments and detritus, the higher the percentage of nematodes (very often oncholaimids). In addition to copepods and selected species of nematodes, other widespread members of the phytal meiofauna are ostracods, especially Xestoleberis spp., Paradoxostoma sp. and Loxoconcha sp. (Hull 1997; Frame et al. 2008) and halacarid mites, especially the plant suctorial Rhombognathinae (Pugh and King 1985b). These taxa are adapted to climbing in the thickets of densely branching algae. Commonly encountered taxa also include turbellarians, syllid polychaetes and tanaidaceans (peracarid crustaceans) (Arroyo et al. 2004). Which adaptive features characterize members of the phytal meiofauna? As we saw above, the fact that the plants are exposed to waves and tidal currents necessitates that the animals have highly developed attachment capabilities (Fig. 8.10): flattening of the body, development of “haptic” organs such as sucker-like structures, adhesion by mucus secretion. Most of the inhabitants of the upper strata are climbers. For this locomotory type, long, prehensile grasping legs and hairy spines are of high adaptive value (e.g., Porcellidium, Ectinosoma and Thalestris in harpacticoids, Paradoxostomatidae, Xestoleberidae, Bairdiidae in ostracods, Rhombognatidae in Halacaroidea).

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a

b Fig. 8.10a–b Structural adaptations of harpacticoids to a phytal environment. a The flattened harpacticoid Porcellidium in lateral view, and its “sucker disk” (mouth parts) in ventral view. b Some grasping legs from various phytal harpacticoids. (Combined from Tiemann 1975; Hicks 1985)

Exposure and tidal stress are the main factors influencing the composition and microdistribution of the littoral phytal meiofauna (Hopper and Davenport 2006). Turbellarians were found most commonly on the less exposed underside and inner parts of the thalli (Boaden 1996), where retained water better prevents desiccation. The harpacticoid Porcellidium (see Fig. 8.10a) avoids tidal stress by vertical migrations in the algal canopy (Gibbons 1991). Algal branches and thalli and seagrass plants offer numerous microhabitats, mitigate harsh hydrodynamic forces, and provide shelter from predators (Coull and Wells 1983; Webb and Parsons 1991; Muralikrishnamurti 1993). The thalli/blades also accumulate sediment and detritus, which adhere to the exudations and the biofilms on the plants. These sediments seem to increase the overall structural complexity and favor meiofauna colonization. Some colonizers have been found in both the organic layer covering the surrounding rocky substrate and in the detrital film on the surfaces of the fronds. In densely branching, turf-forming, tufted or fine filamentous algae meiofaunal abundance and diversity is enhanced; these microhabitats become more rapidly colonized than the foliose, blade-like thalli (Gibbons 1991; Frame et al. 2008). On the other hand, if accumulations of fine deposits become too rich, the habitable area and structural complexity are reduced, yielding


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a parallel decrease in phytal meiofaunal abundance and diversity. Less complex, shrub-like algae that do not retain the sediment and often grow in more exposed areas are populated by a less abundant and less diverse meiofauna. The epigrowth of small, often ephemeral, filamentous algae on the thalli or well-developed biofilms particularly enhance the species richness and density of meiofauna (Hall and Bell 1993; Peachey and Bell 1997). Along boreal shores, there are three general macroalgal types, which are distinguished by their decreasing structural complexity: the Laminaria–Delesseria zone, the Fucus zone, and the Zostera zone Remane 1940. Correspondingly, in warmwater areas the delicately branched Cladophora, Corallina and Delesseria harbored a much richer “meiophyton” than Laminaria, Fucus and seagrass blades (Hall and Bell 1988). The complex pelagic Sargassum rafts are also regularly inhabited by a rich meiobenthic fauna. Even the smooth laminose thalli of the green alga Caulerpa taxifolia, an invasive neophyte in the Mediterranean, are colonized by a rich and diverse community of meiofauna. Here, epiphytic macrofauna are yet to be found (Travizi and Zavodnik 2004). Macroalgae (e.g., kelp) provide three subhabitats for meiofauna (Hicks 1985): the surfaces of the thallus fronds, the interstices of holdfasts (rhizoids), and the deposited sediment and detritus that accumulates at the bases of the stems. Many phytal meiofauna differentiate between these microhabitats. Algal fronds are dominated by harpacticoid copepods, especially by rarer taxa, while the holdfasts harbor the highest abundance of more eurytopic meiofauna, primarily nematodes (Arroyo et al. 2004, 2007). The meiofauna of the algal holdfasts and the stems of seagrasses (see below), which are often rich in sediment and detritus, are frequently recruited from local softbottom sediments and are not tightly linked to the phytal fauna proper. This lowest phytal stratum seems to represent an ecotone that combines the structural complexity of the phytal with the rich food supply of the sediment below, which would explain the high meiofaunal densities and the similarity to the bottom fauna. Experiments with artificial substrates (standardized bottle brushes, blade mimics) confirmed the positive relation between structural complexity and meiofaunal density and between reduced water flow and meiofaunal colonization (Gibbons 1991, Attila et al. 2005; Mirto and Danovaro 2004). These authors conclude that structural density controls the species richness of copepods and nematodes, whereas the surface area of the plants controls the abundance of copepods. Apparently, the “realizable niche” of the phytal, which structures meiofaunal colonization and determines its “value,” depends on a multiple factorial complex, the nature and position of phytal elements, their protective potential, hydrodynamic exposure, surface area and amount of surface with sediment cover with (Attila et al. 2005; Hopper and Davenport 2006). The structural complexity can be numerically described and compared by plotting outlines of the phytal fronds and calculating the fractal dimensions. Multiple fractal scaling seems an appropriate approach to describe the complex physical environment of phytal meiofauna (Gee and Warwick 1994). Aside from spatial differentiation into various strata, meiofauna also display a structured temporal occurrence. A number of phytal meiofaunal species are known to periodically leave their substrate for (nightly) excursions into the overlying water

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column and can subsequently be caught in suspension traps (Kurdziel and Bell 1992). In the Black Sea phytal, Kolesnikova et al. (1995) found a differentiated diurnal behavior that varied depending on the meiofaunal taxon. While during the daytime harpacticoid copepods and nematodes both settled on macrophyte thalli, they separated at night, with harpacticoids ascending into the water column and nematodes heading for the bottom sediment. The authors interpret these migrations as avoidance reactions to fish predation. Because of the close structural and trophic ties of phytal meiofauna to the plants and their surface films, there is often a marked seasonal variation in the population dynamics of phytal meiofauna that depends on the cycles of growth and decay of the algal stocks. Even in the tropics, marked temporal variations were noted (Arlt 1993, Faubel 1984; Jarvis and Seed 1996). This seasonality becomes particularly apparent in seagrass beds with their decaying external blades in the winter (Novak 1992; Danovaro 1996). Growing in soft bottoms rich in detritus, seagrass beds usually develop in little-exposed subtidal zones with fairly stable conditions. They differ in their structural characteristics from algaecovered hard bottoms, i.e., the shape and the surface of the smooth sea grass blades are structurally rather simple. Here, the relevance of the biofilms, adhering detrital particles, and tiny algal epibionts on the blades becomes apparent. This epigrowth provides a microstructure of high protective and nutritive value, and has been found to control the density and diversity of phytal meiofauna (Hall and Bell 1993; Peachey and Bell 1997). Moreover, the fairly tall and rugged seagrass stems offer a wealth of microhabitats, especially when growing in dense stands. It is this density of plant patches per area that has been found to influence the meiofaunal abundance. In general, seagrass meiofauna are particularly rich in nematodes (often monhysterids and oncholaimids) and, hence, are more similar to the inhabitants of the ambient soft bottom than to those of algal belts. In Mediterranean Posidonia beds, the structurally complex and meiofaunally rich “stem stratum” has been distinguished from the more monotonous “upper leaf stratum” and “lower leaf stratum” (Novak 1989). The ease with which seagrass can be mimicked by artefacts allowed numerous manipulative studies of the impacts of structural complexity, biological aging of surfaces, protective effects and colonization potential on phytal meiofauna (Bell and Hicks 1991; Edgar 1999). In many cases the physical components are modified by the (micro)biological coating and the sedimentation of natural debris on the pristine artefacts. These components affect the rate, density and variety of meiofaunal colonization. Newly settled meiofauna came from the ambient sediment as well as from surrounding plants, thus demonstrating the high vagility of the phytal meiofauna (Bell and Hicks 1991). Comparable results have been reported for the meiofaunal colonization of artificial mangrove pneumatophors (see below; Gwyther and Fairweather 2002, 2005). One biotope typical of American tidal flats are the extensive Spartina salt marshes. The root system, the culms and the leaves of the plants provide the basis for a richly structured, well-protected habitat (Bell et al. 1978; Osenga and Coull 1983). With its abundant supply of organic matter, Spartina marshes harbor rich and genuinely adapted meiofaunal populations of ecological importance (Wieser and Kanwisher 1961; Rutledge and Fleeger 1993). In a complex, mutually regulating


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system, rich stocks of insect larvae, juvenile fish and shrimp seem to exert a severe predation pressure, acting as a top-down control for copepods in particular, but also for nematodes (Feller and Coull 1995). A peculiar subhabitat in salt marshes of the southern United States is the rich system of “gas passages” (aerenchyma) in the stems of Spartina alterniflora (Healy 1994; Walters et al. 1996). These are regularly inhabited by an amazingly rich and diverse meiofauna characterized mostly by specialized oligochaetes (Enchytraeidae) and epsilonematid nematodes. Together with the meiofauna found under the Spartina leaf sheaths, the inclusion of this stem biotope increased the overall abundance of salt marsh meiofauna by an order of magnitude! Another richly structured habitat of a particular character is provided by mangroves (see Sect. 8.2.1). The branched roots and the numerous pneumatophores, with their high degree of complexity, allow for comparisons with classical phytal habitats. Experiments with artificial mimics have demonstrated the relevance of natural surfaces, with their specific biofilms and mature epigrowth, for meiofaunal colonization, so that the degree of convergence and intrinsic patchiness remained rather low (Gwyther and Fairweather 2002, 2005). In their “taxo-ecological” structure, phytal habitats from tropical and south temperate shores correspond to those from temperate shores (Hicks 1985; Arlt 1993; Muralikrishnamurty 1993; De Troch et al. 2001). This underlines, despite climatic divergences, that comparable algal complexity and structural impact create meiobenthic “isocommunities” in geographically disjunct zones. An example of this is the dominance of enoploid nematodes in both the North Sea and Chilean phytal habitats. Also, many oncholaimid nematodes are trans-regional, characteristically inhabiting the phytal, and epsilonematids populate the stems of seagrasses in many areas. A similar trans-regional parallelism can be found in families of harpacticoids, ostracods and halacarid mites. The existence of isocommunities with far-reaching similarities in their fauna separated by continental distances with far-reaching similarities in their fauna (compare Wieser 1959; Arroyo et al. 2004) probably relates to the close adaptive parallels of the fauna to the phytal structure. This may also explain the similarity in phytal fauna between areas of varying exposure and water depth. Only a few members of the phytal meiofauna feed directly on their substratum, the plant’s tissue, by piercing the cells and sucking their cytoplasm. Some nematodes (Halenchus), tardigrades (Echiniscus), halacarids (Rhombognathidae), siphonostomatid cyclopoids and ostracods (some Xestoleberidae, Paradoxostomatidae) have adopted this specialized mode of living. Some phytal nematodes, harpacticoids and ostracods grasp and crack diatoms on the plants with specialized mouth parts. Other specialized phytal meiofauna may take up exudates secreted by the plants. However, the bulk of the meiofauna encountered in the phytal live on detritus and microorganisms that have accumulated on the plants. This organic film, and not the plant itself, is the grazing ground for the meiofauna and the basis of the phytal food chain. An example is decaying frond ends, which are densely populated by bacteria, and so attract a meiofaunal assemblage that grazes on the microbes. In seagrass beds, nematodes have been found to specialize on the brown, decaying parts of the blades (Moens and Vincx 2000a).

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The other trophic line in the phytal is, in fact, detritus-based. Lower current velocity within algal thickets causes an accumulation of plant debris and fine sediment. Experimental work with artificial substrates has shown a better correlation of meiofaunal colonization with debris accumulation on the plants rather than with an enhancement of the structural complexity (Edgar 1999). In seagrass beds, experimental results have also suggested a close relationship between meiofaunal settlement (harpacticoids) and the deposited detritus layer (Meyer and Bell 1989). It is largely the detrital food accumulating on the surface that controls the meiofauna and correlates with their density and diversity (Hall and Bell 1993). Dense, tufted filamentous algae retain more detritus particles and thereby harbor mostly detritus-feeding meiofauna, while epistrate feeders prevail in coarse, branching algal bushes (Wieser 1959). Conversely, the mobilization and reduction of the detrital layers on the blades and thalli by feeding meiofauna may also be advantageous for the plants and enhance their growth. More sessile members of the phytal meiofauna regularly utilize the outer parts of plants as prominent substrates for filter feeding (e.g., rotifers, cladocerans). Rotifers are particularly frequent in the phytal fringes of brackish waters. Some harpacticoids (Diarthrodes sp., Amphiascoides sp.) live on macroalgae, where they mine the fronds and ingest the medullary tissues, producing algal galls (Hicks and Coull 1983). In relation to the successive alteration of the surface coating, Gwyther and Fairweather (2002) noted a succession in nematodes from epigrowth-feeders to deposit-feeders, while omnivores and predators followed later. The abundance of meiofauna exploiting the complex habitats in rocky algal belts has been repeatedly emphasized (Crisp and Mwaiseje 1989; Danovaro and Fraschetti 2002; Frame et al. 2008). Seagrass beds also harbor twice as many meiofaunal species as the adjacent sediments (Hicks 1986), and are considered “hot spots of meiofaunal production,” producing around 10 g C m−2 y−1; a value equivalent to the world’s most productive sediment sites (Danovaro et al. 2002). A phytal meiofauna of a million individuals per m2 of macroalgae is not uncommon and, in terms of biomass, may correspond to 10% of the macrofauna. In addition, hard substrate communities comprising crusts of mussel beds, barnacle, bryozoan and hydrozoan colonies, or thickets of worm tubes represent habitats with a rich yet poorly studied meiofauna (Somerfield and Jeal 1995). They provide shelter even under exposed littoral conditions, and are, in many respects, comparable to the belts of crustose, twisted or upright algae. The phytal biotopes, with their highly productive meiofauna, represent an important food source for higher trophic levels. While meiofauna are usually scarce on bare rocky shores, valuable meiofaunal food is available in algal belts and among seagrass beds, mainly for small fish and shrimps. However, experiments demonstrated that the accessibility to this food source is reduced by the vegetation and stems. In experiments with grass shrimps (Palaemonetes), this shelter function of the phytal resulted in a 40% decline in the consumption rate compared to unvegetated cages (Gregg and Fleeger 1998). In a New Zealand rocky intertidal Coull and Wells (1983) demonstrated that more complex algal habitats exhibited less predation on meiofauna by tide pool fish. Thus, in many phytal ecosystems meiofauna provide an important link to higher trophic levels (see Sect. 9.4). Studying phytal meiofauna poses some problems of quantitative sampling. The plants have to be carefully placed in sampling bags underwater so that any loss of


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fauna is avoided. An open cylindrical jar with a thick and softly attached rim of flexible silicone sealant has proven to be a simple and useful tool (Gibbons and Griffiths 1988), but solid enclosures easily cause currents which may displace some of the meiofauna. After the injection of some formalin in order to release the attached meiofauna, the water volume of the sample is siphoned off. For better reproducibility this procedure should be repeated several times. Since a good proportion of the phytal meiofauna are linked to not only the plants themselves but to the ambient sedimentary meiofauna and the overlying water column, the meiofauna of phytal habitats have an important function coupling benthic and pelagic fauna. Considering the often small sizes of the vegetated areas, the phytal meiofauna exhibits high diversity and species richness, which it achieves by exploiting the structural complexity of the phytal and its numerous microhabitats and ecological niches. A recent study (Bracken et al. 2007) shows that there is also a “reversed” mutualistic link between meiofauna and the algal community. The excretions of meiofauna (ammonium) easily provide the nitrogen needed by the algae (Cladophora). More detailed reading: Posidonia meadows, Novak (1989); production, Danovaro et al. (2002); reviews, Hicks (1985a), Gibbons (1991); monographs, Remane (1940); Wieser (1959).

Box 8.6 The Phytal Meiofauna: A Haven Depending on Structural Complexity The meiophyton, which lives preferably on and among plants (algae on hard substrates; seagrass on sand or mud), wonderfully exemplifies the influences of habitat structure and heterogeneity on faunal diversity and abundance. On foliose thalli or blades lives a meiofauna that is different in composition and abundance from tufted or crustose algae. The colonizers of the fronds and blades, with their frequent excursions into the demersal water layer, differ from the inhabitants of lower stems and holdfasts that merge with the sediment fauna. Regularly migrating meiofauna further blur the limits of both biotopes—yet, the phyton is understood to be a meiofaunal unit with specific adaptations and with a faunal composition of its own. Harpacticoid copepods often dominate, while nematodes often rank second. Ostracods and halacarids are other frequent members of the phyton. Climbing among the plant thickets is supported by a flat body surface and clinging legs. The phytal habitat with its numerous retreats provides shelter against strong currents and larger predators such as small fish and shrimps, while the microbial biofilm on the surfaces and a well-developed layer of debris provides an ample food supply. There are many parallels to the meiofauna populating clumps of barnacles, mussels, bryozoans, or dense patches of hydrozoans or annelid tubes. This suggests an ecological incorporation of substrates formed by animal epigrowth into a wider definition of the phytal. Favorable ecological conditions are the basis for one of the highest production rates in benthic habitats and afford the meiophyton a considerable ecological role.

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8.6


Brackish Water Sites

Marine and limnetic sediments are connected by a brackish zone that is primarily characterized by its variable salinity. This is influenced by the tides, climatic, hydrodynamic and/or geographical factors. The future climatic change with increased salinity oscillations will globally affect the coastal soft-bottom zones with brackish conditions (Richmond et al. 2007). Coastal lagoons and tidal estuaries are typical brackish sites, as are large, semi-enclosed water bodies such as the Baltic Sea or the Black Sea. The salinity range between about 30 and 3 PSU can physiologically stress many fauna and can often limit their distributions. Another huge brackish water habitat, particularly for the meiobenthos, is the coastal subsurface zone where the marine and continental groundwater systems merge. The brackish coastal groundwater extends well above the supralittoral fringe of the seashore into the limnetic biome. Hence, it has always been pivotal for colonization and migration. Perhaps it was more shelter and less competition in this coastal groundwater system (see Sect. 8.7.2) that allowed meiofauna to adapt to brackish salinities. This long-term process, facilitated by biotopical stability, then led to a gradual transition from marine to limnetic conditions. Thus, this brackish zone has considerable relevance as an evolutionary pathway for the immigration of marine meiofauna into the continental groundwater system (see Chap. 7). This would also explain the relatively high percentage of genuine brackish water species among the meiobenthos (Fenchel 1978) and the high diversification of meiobenthic species adapted to all haline regimes. The weak separation of macrobenthic from meiobenthic biomass size spectra under brackish water conditions (see Sect. 9.2) may reflect this wide occurrence of meiofauna in various salinity zones (Drgas et al 1998; Duplisea and Drgas 1999). As a consequence, in contrast to the macrobenthos and the plankton, the meiobenthos is less constrained by a “brackish water species minimum” around salinities of 8–10% PSU (Remane 1940). Of course, in the most stressful intermediate range, between 5 and 10% PSU, even the number of meiobenthic species will decrease. However, the depletion of meiofaunal species in this critical range is relatively indistinct (Riemann 1966; Dauer et al. 1993; Yamamuro 2000; see Gerlach 1954 for nematodes). A significant size reduction, known from macrofauna in brackish areas, has also been found in marine nematodes from brackish lagoons compared to marine sites (Yamamuro 2000). Morphological aberrations, e.g., in the number, structure and position of amphids in populations of some Black Sea nematodes (e.g., Terschellingia longicaudata, Axonolaimus setosus, Sabatieria abyssalis), have also been interpreted as an indicator of extreme water conditions in combination with anthropogenic stress (Sergeeva 1999). In contrast with macrofauna, surprisingly many marine and freshwater meiofaunal species have developed a high tolerance capacity, usually to not only an unstable salinity but also to combined variations in temperature and oxygen supply. As a result, the distributional ranges of many marine and freshwater meiofauna in estuaries or in the Baltic Sea characteristically extend more widely into critical brackish zones than those of macrobenthos. Also in brackish water the influence of sediment characteristics as a controlling mechanism is apparent, evidenced by a comparison of meiofauna from various mesohaline regions in the Baltic Sea: Riga Bight, with its rich supply of

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organic matter, is populated mainly by deposit feeders, in contrast with sediments with a low organic load around the Swedish east coast, where epistrat feeders dominated (Pallo et al. 1998). Estuarine sediments harbor many euryhaline marine species of nematodes and turbellarians, which co-occur with freshwater and brackish water forms (Riemann 1966; Heip et al. 1985a; Sopott-Ehlers 1989; Alongi 1990a; Ax 2008). Euhaline meiofauna even populate olighohaline reaches with considerable densities. On the other hand, the meiobenthic rotifer species that colonize the brackish region are limnogenic; in this taxon the percentage of marine species is very low. Therefore, under brackish water conditions a relatively diverse and rich meiofauna gains in importance when compared with the less resistant macrobenthos. Despite this high tolerance, experiments have demonstrated that meiofauna in salinity gradients display the characteristic discrepancy between the range of survival and that of reproduction known from macrobenthos. Meiobenthic animals survived over a fairly wide salinity range, but they only reproduced over a rather narrow range (Ingole and Parulekar 1998). In nature this means that in a gradient of salinities, e.g., along an estuary, the area of successful reproduction will be distinctly smaller than the area of a mere persistence (see Ekman 1953). In recent years the meiofauna in the brackish Black Sea and Sea of Azov have been examined in more detail by the teams of Sergeeva (1996) and Vorobyova (1999). The pertinent publications deal not only with the meiofauna of anoxic and sulfidic depths in the Black Sea (see Sect. 8.4.1) but also with the littoral sediments, mussel beds and algal epigrowth of this strongly stratified brackish water body. Some of these studies also cover the adjacent Sea of Azov (Vorobyova 1999; Sergeeva and Burkatsky 2002). Meiobenthic communities of high abundance but low species richness characterize the shallow sites of these brackish seas (5–13% PSU in the Sea of Azov) as extreme habitats. In muddy sediments foraminiferans and nematodes (plus some kinorhynchs) prevailed, while sandy areas harbored relatively numerous harpacticoid copepods. Other important groups were ostracods, polychaetes, and oligochaetes. Meiofauna accounts for about 38% of the total invertebrate species identified so far in the Black Sea. As average densities almost 300 ind. 10 cm−2 in the Black Sea and about 500 ind. 10 cm−2 in the Sea of Azov (corresponding wet weight biomass of >10 mg) are reported (Vorobyova 1999; Sergeeva and Burkatsky 2002). Thus, meiofauna are important for the overall productivity of these brackish sites. The increase in meiofaunal density upon increasing anthropogenic impact is interpreted as a compensational effect of meiobenthos for the decreasing macrobenthos. In estuaries, the astatic tidal regime, the salinity and the sediment characteristics are the main determinants of the meiofauna distribution (Soetaert et al. 1995; Coull 1999). Fine estuarine sediments support a less species-rich meiofauna than coarser ones (Dye and Furstenberg 1981). Because of the typically rich content of organic matter, food is rarely a limiting factor that facilitates meiobenthic life in the harsh oligo- to mesohaline zone (Austen and Warwick 1995; Heip et al. 1995; Ingole and Parulekar 1998). In a South African temporarily open estuary, the meiofauna was likely not food-limited, because the main food source, the microphytobenthos, was abundant despite intensive grazing rates …(Nozais et al. (2005). Typically, salinity gradients seem to control meiofauna distribution in estuarine regions. In Dutch North Sea estuaries, the outer polyhaline regions harbored a meiofaunal community rich in non-detritus feeding nematodes

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(mainly deposit-feeding and predacious nematodes; annual average 3,200 ind. 10 cm−2), while in the mesohaline region the meiofauna were less numerous (average 2,300 ind. 10 cm−2) and more linked to a detritus food chain (Li and Vincx 1993). From South African estuaries, an average meiofaunal population density of 1,000 ind. 10 cm−2 was compiled (Dye and Furstenberg 1981), but locally up to 6,000 ind. 10 cm−2 were recorded. A seasonally varying meiofaunal abundance was noted by Coull (1999) in subtidal estuarine sites on the North Carolina coast of the US: during the first half of the year higher meiofaunal densities (max. 1,800 ind. 10 cm−2) were encountered in mud sites, and during the second half higher densities occurred in sand sites (max. 1,400 ind. 10 cm−2) (average values for a 22-year data set). A marked seasonality especially among harpacticoid populations was also observed in Belgian estuaries (Smol et al. 1994). Williams (2003) emphasized the aggravating role of a vertically increasing salinity gradient in the sediment of estuarine river mouths. Here, salinity and sediment characteristics appeared to be major factors influencing the distribution pattern, with a clearly negative relation to silt content observed. Since estuaries are often important traffic routes and are massively impacted by anthropogenic activities, Smol et al. (1994) calculated the influence of man-made hydrodynamic changes on the meiofauna. They predicted that increasing the tidal amplitude and current velocity due to shoreline regulations would decrease meiofaunal diversity but increase overall meiofaunal biomass. Since epibenthic species will replace interstitial species, the meiobenthos will be a more readily available and important food for the macrobenthos. The species composition of meiofaunal communities in brackish sites usually follows the general rule that nematodes are the main representatives. However, there are deviations from this rule that reflect locally varying conditions. In the Baltic Sea, the numerous nematode species, despite their high diversification, show a steady decline in species richness from the western Belt Sea to the eastern Bothnian Gulf (Arlt et al. 1982). Regarding taxon abundance, nematodes are not always followed by harpacticoids. In the rich meiofauna of an Indian estuary (average density 387 ind. 10 cm−2) turbellarians ranked second in abundance after nematodes (which contributed 60% of the total meiofaunal abundance); oligochaetes were third and harpacticoids fourth (Ingole and Parulekar 1998); ostracods are also fairly common inhabitants of estuaries. In some semi-enclosed brackish lagoons, the percentages were 50–85% nematodes, 8–33% turbellarians and only 7–25% harpacticoids (Escaravage et al. 1989). In the muds of Australian mangroves, turbellarians were the dominant taxon, followed by nematodes (Alongi 1987a; see Sect. 8.2.1). The high reproductive potential of many opportunistic turbellarians may explain this unusual prevalence. Among the Baltic Sea turbellarians, no endemic fauna were reported. All of the species also occurred in the supralittoral of the adjacent North Sea, where they represent a genuine brackish water fauna (Armonies 1988d). The surprising degree of faunal identity between Alaskan, Canadian and European coastal turbellarians has been ascribed to the well-developed brackish water tolerance capacity of meiofauna and the uniformity of brackish water biotopes. This results in a community of Platyhelminthes with a circumpolar distribution (Ax and Armonies 1990; Ax 2008). A lack of indigenous Baltic Sea representatives is also known for halacarids (Bartsch 1974), which are regular and frequent members of the brackish meiofauna. In a South African temporarily closed

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estuary, astigmatid mites (Tyrophagus) play a considerable role after nematodes (Nozais et al. 2005). Here, the extreme abundance varies between almost 0 and 888 ind. 10 cm−2, indicating the high temporal and spatial variations that occur in estuaries. Lagoons appear to be brackish water bodies that are particularly favorable to meiobenthos, although here the salinity extremes seem to limit species richness and abundance of meiofauna (Castel 1992; Yamamuro 2000). In his review paper on the meiofauna of brackish lagoons, Castel (1992) emphasized the role of the nutrient-rich sediments in the abundance of meiobenthos. Since high abundances (often ranging from 3,000 to >5,000 ind. 10 cm−2) are often linked to a low species richness, he categorized lagoons as extreme biotopes. Meiofauna other than the usual nematodes and harpacticoids can make up the relevant population stock also in lagoons: high proportions of turbellarian (see above), ostracod and oligochaete species, well adapted to brackish conditions, are often found. In these shallow brackish systems, meiofauna can represent a particularly important nutritional resource for higher trophic levels, especially for juvenile fish. With their open accessibilities and limited species richness, coastal lagoons appear highly suited to population studies and experimental work on meiofauna. Freshwater tidal flats, like their brackish counterparts, are highly productive and ecologically important feeding grounds for macrofauna and juvenile fish. Their rich meiofauna appears to be an important trophic link (Yozzo and Smith 1995; Coull 1999). More detailed reading: Dye and Furstenberg (1981); Heip et al. (1995); Coull (1999); Ax 2008.

Box 8.7 Brackish Sites: Instability as a Criterion Salinity gradients of high temporal and local variability are the prominent character of brackish sea basins, estuaries and coastal lagoons. Interactions with other unstable factors such as changing temperature, solute composition and oxygen depletion in this stressful physiological milieu control the viability and restrict the distribution of species. Whereas in the critical mesohaline “minimum zone” macrofaunal assemblages are typically reduced in diversity, meiofaunal species often have a higher tolerance. Here, the meiobenthos becomes more important in species number and abundance compared to macrobenthos. The extreme nature of many brackish biotopes is often exemplified by huge populations comprising just a few adapted and widespread species. Even in the hardy nematodes, species richness declines in the intermediate haline ranges. The resistant nature of many brackish water species is demonstrated by the rich meiofauna in enclosed seas such as the Baltic or the Black Sea. Numerous meiofauna are found even in the anoxic sediments of the Black Sea. Brackish shallow lagoons with their rich nutrient supply and often intense primary production are particularly favorable sites for rich stocks of meiofauna with an important role in the trophic web. The more stable brackish groundwater horizons probably acted as important invasion routes for some marine meiofauna that gradually adapted to brackish and ultimately freshwater conditions. Hence, many subterranean continental aquifers and cave waters are populated by meiobenthic species of marine origin.

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8.7


Freshwater Biotopes

When the first edition of this book was published, research on the small invertebrates of freshwater habitats was rarely considered in the context of “meiobenthology.” Links to the marine realm were rare and the terminology was different. The scattered literature was published in specialized journals not regularly read by the marine researcher. An early exception was the compendium Stygofauna Mundi (ed. Botosaneanu 1986a), a faunistic and zoogeographic compilation of the subterranean fauna: the stygofauna. Beside freshwater fauna, this volume also considered some marine taxa. Since that period, several comprehensive and competent reviews on the various freshwater biotopes have appeared (Allan and Castillo 2007; Gibert et al. 1994; Palmer et al. 2006; Hakenkamp and Palmer 2000; Robertson et al. 2000a; Wilkens et al. 2000), and improved methods have been developed in order to overcome sampling problems, especially in groundwater research (Mathieu et al. 1991; Malard et al. 1994). Detailed accounts of the various meiobenthic groups in sediments of running freshwater sites are given in the treatise on Freshwater Meiofauna edited by Rundle et al. (2002). The compiled knowledge of important taxa (e.g., nematodes: Traunspurger 2002; Eyualem-Abebe et al. 2006; ostracods: Horne and Martens 1994; turbellarians: Kolasa 2000; protists: Patterson 1996) now serves as a solid platform for further detailed studies. In groundwater research, the comprehensive publication by Hancock et al. (2005) and volumes on groundwater ecology (ed. Gibert et al. 1994; Wilkens et al. 2000) provided major progress. Supplementing the chapter on meiofauna in the second edition of Methods in Stream Ecology (Palmer et al. 2006), there is an electronic key to freshwater meiofauna (Strayer 2006) that can be downloaded to help the beginner in the field. Previously, various independent limnetic research lines had developed a diverging, specialized nomenclature and used different methods, originally with astoundingly little interconnection. Now, many of the new studies use a terminology that is similar to that in marine analogs, which had previously only been applied in the pioneering papers of Palmer (1990a,b). Bridging this traditional nomenclature gap indicates just how many aspects and trends freshwater and marine meiobenthos have in common, and fruitfully deepens our understanding of the structures and functions shared by both fields (e.g., Palmer et al. 1996). Groundwater research in particular demonstrates the numerous parallels and transitions between freshwater and marine meiobenthology. The recent emphasis on freshwater meiobenthology necessitates rewriting the pertaining section in this book. This section outlines the more general or summarized results without claiming complete coverage; for more details, the reader should consult the literature cited above. This increase in literature indicates that freshwater meiobenthology has gained considerable momentum. It is now apparent that: (a) much of the biodiversity in freshwaters is contributed by meiofauna …(Robertson et al. 2000b,c; Balian et al. 2008); (b) meiofauna are many times more abundant than the macrofauna, and; (c) their biomass could potentially be half that of the macrofauna, or may even exceed it (Poff et al. 1993; Stead et al. 2003). The biotopes of freshwater meiofauna are perhaps more heterogeneous than their marine counterparts, each harboring a

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specialized meiofauna. Groundwater aquifers, river shores, cave pools and lake bottoms, all are inhabited by a particular meiobenthos. Research on running waters was initially neglected, but recent research momentum (see above) has filled many ecological gaps and compensated for some of the previous lag in this field. The influential and early freshwater research on subterranean, mostly karstic fauna by Karaman and his school (e.g., Karaman 1935) as well as Chappuis (1942) and Rouch (1968) may have contributed to the notion that interstitial animals represented most of the freshwater meiofauna. Easier access and an apparent relevance also prompted early studies on the small bottom fauna of standing water bodies such as lakes and ponds (Wiszniewski 1934; Pennak 1940). Ecologically, the freshwater meiofauna often attains considerable importance, since together with bacteria and protozoa, meiobenthic animals are involved in the remediation of wastewater and the natural regeneration of our groundwater. The ecological constraints and the typical faunistic composition of the freshwater meiofauna differ much from those of its counterpart in the marine domain, although nematodes frequently dominate in abundance and biomass, just as in marine habitats. However, in many freshwater biotopes, rotifers are of equal importance, followed by copepods (cyclopoids and harpacticoids), tardigrades, “cladocerans” (Chydoridae), hydrachnid mites and oligochaetes. Insect larvae (mainly chironomids) are a specific temporary component of freshwater meiofauna without a counterpart in the marine world, but of considerable relevance in the limnetic food web (Pennak, 1940; Williams 1984; Schmid and Schmid-Araya 1997). However, variations from this generalized picture of freshwater meiofauna are often found when studying the different biotopes (Schwoerbel 1961a, 1967; Pennak 1988; Hakenkamp and Palmer 2000; Hakenkamp et al. 2002), and so they each require separate discussion. An artist’s view of the biotopes may help to illustrate the low concordance between marine and freshwater meiobenthic taxa (Figs. 8.11 and 8.12).

8.7.1

Running Waters: Stream and River Beds

The habitat. Although much of the biodiversity of the fauna populating stream beds is due to meiofauna, this faunal compartment is often neglected by freshwater ecologists (Stead et al. 2003). The first ecological studies on freshwater meiobenthos were performed in river beds, but this “hyporheic” and “phreatic” (in deeper sediment) meiobenthos is less well known than the meiobenthos in lakes (see Hakenkamp and Palmer 2000; Robertson et al. 2000b; Sect. 8.7.3). In many headwater habitats with coarse sand or gravel bottoms, this is probably due to problems with accessibility and sampling, making quantitative data scarce. The hyporheic habitat of the riverbed is mainly characterized by water flow, while the phreatic sediments continuously merge to the groundwater horizon (Fig. 8.13; Pennak and Ward 1986). In the groundwater aquifers underlying phreatic habitats, the fauna becomes more homogeneous with little or no altitudinal differentiation. Regarding the intense interactions between the epigean, hyporheic and groundwater zones of

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Fig. 8.11 Artist’s impression of the freshwater interstitial environment and its fauna

Fig. 8.12 Artist’s impression of the marine interstitial environment and its fauna


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zone of aeration

zone of aeration

hyporheic zone phreatic or groundwater zone (stygal) rock

Fig. 8.13 The habitat zonation of a river bed. (After Pennak and Ward 1986)

a river, Brunke and Gonser (1997) termed the hyporheic zone a “connecting ecotone”—a corridor used and inhabited by rich, diverse and interacting meiofaunal communities. These physiographic connections, which result in exchange rates that were higher than previously purported, make any strict delineation of the biotopical subunits (Fig. 8.13) rather arbitrary (Danielopol 1989, 1991; Lafont and Durbec 1990; Lafont et al. 1992; Dole-Olivier and Marmonier 1992). The dominant ecological factor in freshwater habitats is water flow. Water flow separates the torrential headwater streams with their beds of pebbles and barren cobbles from the slower lentic lowland rivers, with their fine sediments and rich macrophytes. The other characteristic of all hyporheic habitats is astatic and seasonal fluctuations. Hence, hyporheic meiofaunal assemblages differ in the various parts of a running-water system. Seasonal changes in temperature and water level together with a variable chemical milieu add to this instability. Especially at low water levels, the hyporheic fauna can become threatened by river pollution. Characteristic abiotic features of the hyporheic pore water system compared to the overlying river water are an increased CO2 content, which is reflected by a decrease in pH by 1–2 units. Strong adsorptive forces in the sediment often also cause an increase in the concentrations of silica, iron and manganese. In the coarser sediments of the riverine headwater region, the strong water currents maintain an open interstitial system with a good permeability, which compensates for the oxygen depletion caused by the supply of organic matter. In particular, crystalline sediments on primary rocks maintain an open pore system, acting as a filter bed for the few detritus particles. Detritus will accumulate in the more lentic lower river bed, clogging the interstices of the sand. Silt and mud particles compact the river bed in sheltered riverine side-arms and coves. Combined with intense bacterial growth, this accounts for typical decreases in oxygen and pH (Fig. 8.14) as well as nitrate and sulfate concentrations, while reduced substances and free hydrogen sulfide may develop locally and can act as major controls over hyporheic communities (Strayer et al. 1997).

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8 Meiofauna from Selected Biotopes and Regions 20

16 CO2

O2

pH

12

8

4

0 overlying water

sediment surface

sediment sediment 50 cm 100 cm

Fig. 8.14 Gradients of chemical characteristics in a vertical profile of a typical lakeshore. Note the decrease in oxygen values (in ppm) as opposed to the increase in carbon dioxide values (in ppm). (After Pennak 1939)

Generally, the hydrological and geomorphological regimes seem to override all other factors in running water ecosystems and determine the interactions and roles of meiofauna (De Bovée et al. 1995; Strayer et al. 1997; Hakenkamp and Palmer 2000): at high flow rates the macrobenthos dominates and the meiobenthos attains a subordinate role despite its often considerable diversity. At intermediate flow rates the meiofauna gains importance, filtering detrital particles and breaking down organic matter. This intensifies bacterial processes and contributes greatly to total secondary production. At low flow rates patches of accumulating detritus develop, where the depletion of oxygen can cause a vertical upward migration of the hyporheic meiofauna and can increase losses by drift. These discontinuities in the interstitial water flow and local biotic factors may modify the general hydrological and geomorphological scenario and thus the hyporheic fauna (Dole-Olivier and Marmonier 1992, Ward and Palmer 1994). Overall, and in contrast to the aquatic epibenthos, the hyporheic fauna of running waters is structured by the site-specific physiography rather than the elevation (mountain river vs. lowland river). Among the biogenic factors, organic matter is the key component that influences attracts hyporheic meiofauna and controls their patchy distribution. The load of detritus, with its rich epigrowth of bacteria and microalgae, serves as the main food source. Sites in headwater streams with open access to both detritus and oxygen will support a diverse and quantitatively important meiofauna (Ward and Voelz 1990). In low-flow river beds suboxic reaches often develop. Here, the composition of the meiofauna changes; the diversity and abundance will decrease. As an


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adaptation, many of the hyporheic animals seem fairly resistant to a reduced oxygen content in the pore water. However, water velocity, sediment composition, oxygen and detritus supply may vary on small scales—around one boulder, within a stand of vegetation, or in a sand riffle. Depending on the bottom microstructure, downwelling and upwelling sites can form. For meiofauna, these local properties are often the real controls over the distribution pattern and community composition. For instance, cyclopoid copepods and cladocerans prefer areas with reduced flow, while harpacticoids are more common in coarser sediments with a high water flow and shear stress (Robertson 2002). Water flow also enhances the rate of faunal suspension. Although surface films of bacteria and diatoms tend to stabilize the sediment, sudden floods with subsequent heavy erosion and faunal suspension are common phenomena, and not only in montane rivers. Passive drift accounts for a repeated redistribution of meiofauna and is important for the dispersal and regeneration of communities after severe disturbances by flash floods (Palmer 1992; Palmer et al. 1996). The degree of community destruction apparently depends on the duration of the flood, but losses are usually compensated within a few weeks and only occasionally within several months (Hancock 2006). This swift recovery is largely made possible through transport from regions higher up the river. Transport in turbulent waters will increase the probability of hitting the bottom and resettling (McNair et al. 1997). Although only a small proportion of the fauna has been found to immigrate from the hyporheic strata (Palmer et al. 1992), the (deeper) hyporheic biotope can be considered a refuge area for fauna, allowing them to avoid currents and drift. With its transitional position between the exposed riverbed and the stygobiotic groundwater sediments, the hyporheos attains considerable importance as a sheltered recruitment zone, especially for insect larvae. Nematodes were encountered down to 50 cm depth in running water sediments. While the deep hyporheic zone as well as lentic “pockets” along the shore may be important as havens that are well supplied with accumulating debris, their role as centers of recolonization, supporting the “hyporheic refuge hypothesis,” is limited (Robertson 2000; Palmer et al. 1992; Olsen and Townsend 2005). Thus, dispersal by flooding, regeneration by incoming drift, a high potential for rapid colonization, as well as frequent redistribution of communities are regular features of running water biotopes. Combined with a high degree of resilience, the consequences of flood events are limited (Palmer et al. 1995, 1996; Robertson 2000). At reduced interstitial flow rates micropatches with favorable or unfavorable combinations of factors can develop and create a high spatial heterogeneity that changes temporally whenever flow conditions change. The previously fairly homogeneous spatial distribution of meiofauna in the hyporheic zone starts to become patchy. Hydrodynamics apparently also structure the temporal development and composition of riverine meiofauna. Seasonality in hyporheic abundance patterns is well developed, with minima in the spring following high waters in springtime. Under low-water conditions (which often occur during the summer months), the epibenthic fauna is confined to a thin surface horizon while the endobenthic fauna dominate throughout all the deeper layers. This situation reverses at times of high water

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discharge. During phases of low stream velocities, the fauna of deeper horizons often suffer from stagnant pore water conditions that favor, expecially in the summer, the development of hydrogen sulfide. In cold winters, the surface layers are easily exposed to frost and ice scraping, with its concomitant noxious impact on the inhabitants of these layers. They may survive frost by evading deeper down into the hyporheic interstitial (Schwoerbel 1967). In the cold season, nematodes, copepods and oligochaetes were found deeper down in the sediment (Palmer 1990a). Species composition. In the hyporheos, in great contrast to the marine meiofauna, rotifers, microcrustaceans (cyclopoids, harpacticoids, cladocerans, ostracods), microdriline oligochaetes and insect larvae often attain numerical dominance over nematodes. Usually, nematodes are favored in physically rigid sites, while other groups may prevail under less severe conditions. The headwaters of a river, with its bed of pebbles and gravel, its huge internal surface and its high structural complexity, harbors a more diverse hyporheic meiofauna than the sandy-to-muddy lower reaches. Cyclopoid and harpacticoid copepods, small isopods, tardigrades and smaller insect larvae prevail in the headwaters. With finer sediment and often increasing organic load, the riverine meiobenthos becomes dominated by oligochaetes and chironomid larvae, while the soft sediments of lowland streams are the domain of nematodes, chironomids and rotifers (Hakenkamp and Palmer 2000). In the bed of a low-gradient stream, Palmer (1990a) found 35–85% rotifers, followed by 20% juvenile oligochaetes, then chironomid larvae, and, to a lesser degree, nematodes and copepods. In field experiments with test tubes (Schwoerbel 1967), nematodes preferred the tubes filled with the finest sand (0.25 mm), while harpacticoids were most frequently found in tubes filled with gravel of size 4–6 mm; the third group of importance, chironomid larvae, dominated in sand of 1–4 mm grain size. Some rotifer genera (Notholca, Lecane) were found to be numerically dominant in alpine streams (Schmid-Araya 1995, 1998). In another stream, Ward and Voelz (1990) found that small ostracods and chironomid larvae accounted for 65% of all meiofauna. Another group characteristic of the hyporheos are chydorid cladocerans. Small isopods, which are rather frequent in European river beds, seem to be absent in North America (Williams 1989). In Scandinavian springs, oligochaetes and ostracods dominated the hyporheos (Särkkä et al. 1997). It is mostly at intermediate water velocities (~ 30 cm x s−1) that a relatively rich taxonomic diversity (nematodes, oligochaetes, microcrustaceans, flatworms, tardigrades and midge larvae) combined with high abundances can develop (Whitman and Clark 1984). In many lotic habitats the meiobenthos contribute far more than half of the total species richness (Robertson et al. 2000; Stead et al. 2003). Complete inventories often yield 150 species and can even exceed 300 species, of which nematodes contribute 30–50 spp (Hodda 2006). The sheer variety of microhabitats in lowland streams supports species richness. This is especially true for microcrustaceans, some of which are restricted to running waters (Rundle and Ramsay 1997). Still, our knowledge of the quantitative composition of hyporheic meiofauna is limited. Problems with quantitative sampling and detailed determination make calculations of species richness and population density per area or volume difficult (see below).


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Abundance, biomass, and production. In general, sediments of streams are not particularly densely populated by fauna. Coarse sand bottoms in the riverbed (less so in the shore sediments) harbor meiofauna with abundances of 20–30 ind. 10 cm−2. In an acidic stream the number of meiobenthic individuals was even less, although at >10 ind. 10 cm−2 (maximum 84 ind × 10 cm−2) it exceeded that of the macrofauna (Stead et al. 2003). Schwoerbel (1967) found a relatively high abundance of hyporheic meiofauna, 60–100 ind. 10 cm−2, in the sand of an alpine mountain stream; a range that is often similar to that of nematode communities (see compilation by Hodda 2006). Extremes of several thousands per 10 cm2 may represent patches, e.g., up to 6,000 meiobenthic organisms per 10 cm2 in the bed of a North American low-gradient stream with mostly rotifers (Palmer 1990a) or 4,100 nematodes 10 cm−2 in a small sandy river in Germany (see Hodda 2006). However, these figures do underline the taxonomic and numerical relevance of the hyporheic community of streams. Interestingly, Pennak and Ward (1986) found substantially more interstitial crustaceans in a mountain river than plankton in a nearby lake. Estimates of biomass and production rates for lotic meiofauna are rare. Depending on the substratum, between almost zero and 22% of the biomass (in sand) has been attributed to hyporheic meiofauna (Hakenkamp et al. 2002), with a higher contribution to the overall biomass in lentic than in lotic environments. Stead et al. (2003, 2005) published even higher meiobenthic biomass values: between 10 and 100 mg m−2 (dry wt), values close to the macrofaunal biomass. According to Kowarc (1990), the meiofaunal production in the gravel of mountain streams is rather low, with a P/B ratio of 3–6, which is probably caused by the low temperatures and generally oligotrophic conditions. A low-to-moderate (often less than 5%) contribution of meiofauna to the metazoan production has been adopted for lotic ecosystem productivity (Robertson et al. 2000; Hakenkamp and Morin 2000, Bergtold and Traunspurger 2006), but Hakenkamp et al. (2002) also report values of up to 50% in streams. Only exceptionally, especially in creeks with sandy bottoms, does this value increase considerably (Poff et al. 1993). However, regarding the rapid meiobenthic turnover, low biomass values can sustain a sizeable production (see Sects. 9.3.2 and 9.4). Stead et al. (2005) assessed the complete faunal spectrum of the benthos (retained in sieves down to 42 µm mesh size), evaluated over a period of more than a year, in an acidic English stream. They found that 15% of the total production (5.2 g dry wt. m−2 y−1) was due to the activity of permanent meiofauna, and together with the temporary meiofaunal taxa (oligochaetes, chironomids, plecopterans) more than half the production was contributed by meiobenthos. The authors argue that this result points to a “substantial underestimation” of meiobenthic productivity in many studies, arising from problems with appropriate assessment. Food relations. The predominance of bacterivores and detritivores among the meiofauna highlights the role these trophic components play, even in lotic freshwater habitats. Many chironomids, rotifers, ciliates and (to a lesser degree) nematodes graze extensively on bacteria. Particularly at times of high meiofaunal densities, the grazing pressure on bacteria and diatoms is significantly high (Borchardt and Bott 1955). Thus, meiofauna gain importance as a link between microbial grazing, reworking of the sediment and food for macrofauna. Numerous studies of various

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running-water habitats and experimental data conclude that the balance between macro- and meiofauna in terms of biomass and production as well as functional relevance will favor meiofauna in fine-grained sediments and a low interstitial flow regime (see also Hakenkamp and Morin 2000). At the predatory level of the food web, considerable activity from mites and the larvae of tanypodid chironomids and plecopterans has been reported (Schmid and Schmid-Araya 1997). Caging experiments demonstrated that predation on meiofauna is significant, particularly among young fish. Also, the biomass size spectra of meiofauna can be used to gauge the importance of differently sized organisms, indicating predator–prey interactions. However, for lotic freshwater habitats this approach is controversial: the results of some studies indicate well-separated biomass peaks for meio- and macrofauna (Poff et al. 1993), while in others the biomass distribution is more even and macrofauna only slightly prevail (see Sect. 9.2; Robertson et al. 2000c). When generalizing the data on the meiobenthos in running-water systems, the following aspects should be emphasized: - Much more information beyond local studies is required to provide a general, zoogeographically reliable overview. - While streams are relatively better understood ecologically, the meiofauna ecology of large rivers requires urgent investigation, especially since the meiofauna here are purportedly of higher ecological importance, but are being placed under much anthropogenic stress. - Life history data, estimates of turnover and the productions of key species are urgently needed. - The impacts of ecological parameters such as bioturbation or water drift still need to be assessed. - An appropriate methodology that catches epibenthic as well as interstitial fauna is a prerequisite for a total-component analysis. Methods. The scarcity of generalizable data on the hyporheic meiobenthos is often due to inherent technical and methodological problems. Only in the sandy bottoms is quantitative work with regular station profiles possible. Here, the standpipe corer (Williams and Hynes 1974) allows quantitative sampling into deeper strata too, enabling intact samples to be collected from defined depths. Battery-powered suction corers, constructed for quantitative sampling in marine bottoms (Taylor et al. 1995), might be applicable, as might the use of Scuba divers. In the pebbles and gravel of most riverbeds, sample holes can only be driven with massive corers, and the pore water that enters is pumped up for faunal analysis. The typical method used for lotic freshwater habitats as well as for groundwater research (see below) is pumping with the Bou–Rouch pump (Bou 1974; Fig. 8.15). A small pump is mounted on a perforated metal tube that has been hammered into the riverbed and remains in position for the repeated sampling of interstitial water. This pore water and its inhabitants can enter the tube through perforating holes. It is arguable whether this method will yield reliable reproducibility or area-related quantification, since most of the methods based on pumping do not allow exact reference to a distinct depth or area. These arguments also apply to trapping methods (Hahn 2003),


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Bou-Rouch pump

O2-analyzer air-pump

groundwater pipe with holes

O2-sensor groundwater

5 cm sampling chamber

filter

Fig. 8.15 A coring tube for fractionated sampling of groundwater fauna. For details see the text. (After Danielopol and Niederreiter 1987)

which have yielded comparatively satisfying results in test series. The corers designed by Danielopol and Niederreiter (1987) and Tabacchi (1990) provide more quantitative access. They allow for fractionated vertical subsampling of interstitial water and fauna by subdivision of the coring tube into small chambers, which are evaluated separately (Fig. 8.15). Quantitative results can be obtained with a more

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sophisticated but expensive method. A sediment core obtained in a metal tube is shock-frozen in situ by liquid nitrogen and then retrieved undisturbed after previous anesthetization of the fauna by electro-positioning (Bretschko and Klemens 1986). Limitations on quantitative sampling could perhaps mitigated by increasing experimental work (Palmer 1993). More detailed reading: general and ecology, Schwoerbel (1961a); Pennak and Ward (1986); Palmer (1990b, 1992); Ward and Palmer (1992); Brunke and Gonser (1997); Hakenkamp and Palmer (2000); Robertson et al. (2000c); Rundle et al. (2002); methods, Bretschko and Klemens (1986); Palmer et al. (2006).

8.7.2

The Groundwater System

Groundwater represents a freshwater reservoir of eminent importance. About 40% of all freshwater, ice included, is stored in the continental groundwater system (Danielopol 1989); the water masses in all lakes and rivers account for only about 4% of the global groundwater reservoir. An account of groundwater ecology (not specifically meiobenthos) has been edited by Gibert et al. (1994). An even wider topic is covered by Subterranean Ecosystems (ed. Wilkens et al. 2000). The importance of groundwater aquifers is based on the fact that they supply us with drinking water, an indispensable human resource. The contact with the surface waters, mediated by the hydraulic conductivity and the texture of the sediment, determines the typical abiotic characteristics of this biotope. With increasing depth, the homogeneity of its sediments, the constancy of its physiographic conditions and homeostasis over long geological periods are the main biotopical features of the groundwater system. Its abiotic milieu is characterized by fairly constant, low temperatures, a somewhat lowered pH, a slightly undersaturated oxygen content, a high amount of free CO2, and oligotrophic conditions (Fig. 8.14). However, groundwater systems are not separated from surface waters. They are progressively more “open” the closer they are to the surface and the coarser the sediment pores. The “stygobiotic” meiofauna of the groundwater aquifers and the “troglobitic” cave meiofauna are specifically adapted to the above ecofactors. They exhibit slow locomotion and thus a minimal migratory ability, low metabolic activity and growth, long generation times and lifetimes, late maturity and low fecundity (a few, large eggs), and hardly any diurnal rhythms. Progenesis seems to be a relevant evolutionary factor (e.g., in syncarid crustaceans, in some amphipods and isopods). All of these attributes characterize many meiofauna as K-selected specialists. Adaptations of the interstitial fauna to groundwater life are detailed in Coineau (2000). Typical stygobiotic species are mostly cold stenothermal but they are well adapted to the low oxic conditions of many groundwater habitats (see Fig. 8.16). A relatively welldeveloped tolerance to (low) salinity points to the evolutionary origin of many stygobionts from the coastal groundwater (see below). Energetic sources in the groundwater realm are scarce; the food web is rather simple with few trophic links (Gibert et al. 1994). The absence of primary producers and the scarcity of predators (cyclopoids) are why Gibert and Deharveng (2002) considered subterranean ecosystems


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Stygobionts

Other Animals

n /100 l

> 100

10

5

2 20

40

60

a

100

% O2

Saturation Stygobionts

% 100

n /100 l > 100

O2

80 O2 Saturation

80

60 10 40 6 20 2 20

b

40

60

80 100 120 Depth in Substrate (cm)

Fig. 8.16a–b Occurrence of stygobiont specimens in groundwater habitats of Caribbean islands. a Abundance of stygobionts vs. “normal” marine specimens in relation to oxygen saturation. b Occurrence related to depth in the substratum and oxygen saturation. (After Stock 1994)

“functionally truncated.” Depending entirely on heterotrophy and living on detritus entrained from the surface, the groundwater community shows ecological and sometimes even taxonomic parallels to that of the deep-sea (see below and Sect. 8.3). Altogether, the underground biocoenoses are less densely populated than the hyporheic riverbeds. In the ecotone layer, where hyporheic and groundwater meiofauna mix, biodiversity and density are concentrated. At a global scale the groundwater meiofauna can be considered almost unknown; our knowledge is mainly limited to a few areas in North America and Europe. They are characterized by a wealth of crustacean species (in Europe about 40% of all crustacean fauna are stygobites!) and an absence of the insect larvae that usually dominate in the riverine and lacustrine meiofauna (Danielopol et al. 2000). Figure 8.17 attempts to depict some characteristic inhabitants, the stygobites, of this “unseen ocean beneath our

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feet,” which extends worldwide and to a depth of several hundred meters. Stygobites are often continentally distributed and their compositions are consistent enough to form characteristic biocoenoses (e.g., the Bathynella–Parastenocaris community). In many ways these biocoenoses are related to the fauna of caves and springs, as exemplified by the freshwater polychaete Troglochaetus beranecki or the amphipod genera Niphargus and Bogidiella. Typical representatives of the groundwater fauna are minute malacostracan crustaceans: amphipods and isopods that are tiny enough to live in the interstices of the mostly karstic sediments (amphipods Niphargus spp, Salentinella spp., Stygobromus, the latter so far only found in North America; isopods: Microcerberidae, Cirolanidae, Microcharon, Proasellus, Microparasellus). The other characteristic group is the copepods; often cyclopoids (Diacyclops, Acanthocyclops) but also some harpacticoids (e.g., Nitocrella; Phyllognathopus spp.; Chappuisius spp.). In addition, stygobitic ostracods are well represented, especially members of the family Candonidae. A few representatives of the rare crustacean orders Thermosbaenacea (Pancarida) and Syncarida (Bathynellidae) supplement the suite of crustacean groundwater inhabitants. The microdriline oligochaetes frequently encountered in groundwater belong to the haplotaxids, rhyacodrilids, and tubificids. Some of them are descendants of marine lineages such as Phallodrilus sp. or Troglochaetus, while other annelids represent temporary meiofauna. Even minute gastropod molluscs are encountered in the subterranean aquifers (e.g., Paladilhia, Arganiella). Groundwater aquifers and caves have attracted the attention of zoologists, initially for evolutionary reasons, and later (and especially in the karstic regions of Europe

Fig. 8.17 The interstitial habitat of subterranean meiofauna in an Austrian aquifer. (After Danielopol et al. 1994a)


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and North America) as reservoirs of new species, “hot spots” of biodiversity. The abundance of species decreases sharply with increasing depth and isolation from the surface waters. Here, the number of endemics and relicts without a connection to surface fauna increases. This is especially evident among small crustaceans, such as thermosbanaceans, which are found in groundwater biotopes in seemingly complete isolation. There are both geological and ecological reasons for this interesting evolutionary diversity. A scarcity of predators and reduced competition have permitted the persistence of taxa with low mobility and little competitive strength in a biotope with numerous microhabitats characterized by ecological isolation. What were the pathways along which the groundwater was colonized by meiofauna? It is generally accepted that seashores were the most probable regions from which the colonization of the continental subterranean sediments started. Along this marine–groundwater route of meiobenthic dispersal and evolutionary change, river mouths, brackish lagoons and anchihaline caves may have served as “ports” and interconnecting pathways (see Chap. 7). Thus, some of the meiofauna populating wide areas of ancient seashores (e.g., the Tethys Sea) could have avoided the stressful dynamics of continuous geological change (marine transgressions or regressions, desiccation events, but also competition and predation by macrobenthos) by entering the more protected deeper sediment layers, especially the adjacent groundwater horizons, by gradually becoming “stygobites”. It was not just small size that adapted some meiobenthos to become colonizers of the groundwater system and caves. Pre-adapted by their frequent former exposure to brackish water conditions (see Sect. 8.6), the species could slowly adjust to freshwater conditions provided that they were exempted in their new localities from the stress factors characterizing surficial habitats. Their often euryoxic nature also supported their evolution in caves and groundwater systems, since these habitats are frequently dysoxic (Fig. 8.16; Stock 1986, 1994). In the fairly static refuges, relicts of primitive marine taxa with little adaptive potential could survive (“relict refuge model”; Botosaneanu and Holsinger 1991). They reflect the fauna in their old “plesiotopes” and cannot cope with the adaptive demands of the open marine littoral. A karstic surrounding supported the “stygobization” of meiofauna and their further subterranean distribution. These processes resulted in the separation of the originally large, cohesive shore stocks into small, isolated hypogean populations that became “founders” of radiating lines by allopatric speciation. Under the low selective pressure of the static groundwater world, speciation is slow. As a result, many stygobiotic animals from the continental groundwater are endemics and considered isolated relicts of a primitive marine fauna with formerly wider marine distribution. Morphologically primitive and often neotenic crustacean groups like Bathynellacea and Pancarida (see Fig. 5.36) are good examples of this process. Since the vagility of this evolutionary static fauna was limited, their present-day distributions often reflect the geological fate of their former habitats, they persist along the ancient sea shores: vicariant, e.g., amphi-Tethyan or amphi-Atlantic distributions. This “geological scenario,” mainly developed by Stock (1994; see also Strayer 1994) would also explain the rich and isolated groundwater fauna of the

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karstic Balkan, but also the astonishing insular groundwater fauna of the Caribbean and Middle American shores, where anchihaline caves are particularly frequent. Numerous fascinating meio- and macrobenthic animals have been retrieved from their shelter. Present-day islands, often ancient seamounts, also play a dominant role as stepping stones and centers of speciation (see Chap. 7). The “dispersionist school” of groundwater researchers is inclined to consider hypogean fauna as being mainly represented by animals that keep actively invading the stygobiotic freshwater milieu from other, often marine biotopes (Danielopol and Rouch 1991). Studying subterranean ostracods, Danielopol et al. (1994) state that dispersal by drift and active migration enable hypogean meiofauna to constantly proliferate into the surrounding habitats. The ostracod distribution is better explained by an ecological, dispersive scenario than a scenario of geological events. It is again mainly the degree of ecological flexibility and the capacity for tolerance that control the distribution of the species into the subterranean and epigean aquatic system. Another source of groundwater colonization may be the riverine meiofauna. There are, indeed, numerous connections between the groundwater and the hyporheic and epigean fauna of running waters. In downwelling areas of gravel bars, the epigean fauna from the surface becomes infiltrated into the interstitial of hypogean sediments. Contrastingly, in hyporheic areas with prevailing upwelling groundwater, the contribution of stygofauna from the deeper layers progressively increases in the interstitial system (from 8 to 47%, see Ward and Palmer 1994). A correspondingly varying influx of stygofauna into the riverbed was observed in studies of the floodplain of the River Rhone at sites with differing hydrological regimes (Dole-Olivier and Marmonier 1992). These studies emphasize the close connections of the groundwater assemblages to those of the surface waters. Boutin and Coineau (1991) point out that the colonization process represents a combination of dispersion and persistence. Their “two-phase model” is characterized by several successive steps. Initially there is active dispersion and vertical transition from surface waters to the interstitial. This is followed by passive persistence combined with gradual adaptations that further separate the interstitial fauna of the continental groundwater from that of the original marine habitats. Whichever mechanism, per se or in combination, was the driving evolutionary force, a confusing mosaic of archaic and derived characters is typical of the stygobios. Ecological stability and reduced competition in the simple subterranean ecosystem would explain the high biodiversity combined with the low abundance of the stygofauna. As examples, the karst regions in Europe and North America, and to a lesser extent the interstitial of alluvial aquifers, represent rich species reservoirs for some crustacean groups such as ostracods, harpacticoids, amphipods, and isopods. For these taxa and biotopes, the species richness can be equal or can even exceed those of surface freshwater habitats (Rouch and Danielopol 1997; Danielopol et al. 2000). In North America, the glacial boundary of the last ice age seems to represent an important distributional barrier for the hypogean fauna. A typical groundwater fauna that is speciose and rich in K-selected endemics, e.g., Bathynellacea, has only been found in formerly unglaciated areas. Both the upland plains (influenced by the ice cover) and the coastal plains (under the impact of the marine regime) are poorer


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in groundwater fauna (Strayer et al. 1995). Characteristic groundwater cyclopoids on the North American continent seem to follow the same distributional constraints. Once adapted to the physiological constraints of freshwater, stygobiotic species do not seem able to bridge the oceans (Schwoerbel 1967). Their continental distribution is linked to the large aquifers, for instance those of the Rhine and the Danube in Central Europe. Considering the limitations described above, the surprisingly frequent circummundane distributions of stygobiotic species cannot be conclusively explained. With the ongoing discovery of huge subterranean systems, it is likely that many more zoological “preciosa” will be discovered and that the distribution patterns of stygobiotic animals will become better understood. The ecological knowledge of groundwater meiofauna clearly lags behind that of rivers and lakes. This is especially true if we consider the scarcity of quantitative data on biomass (allowing for calculations of productivity), which is mostly due to methodological problems. Direct sampling of defined volumes in the aquifers deep beneath the surface is restricted. Even elaborate fractionated samplers (see Fig. 8.15), traps (Hahn 2003), and pumping systems that render access through narrow drill holes (Malard et al. 1994) do not allow us to draw quantitative conclusions about the sample volume collected. Notable exceptions are water accumulations in caves. If sufficiently isolated from the outside, the ponds and streams of caves harbor a “cavernicolous” (troglobotic or troglobiotic) meiofauna, which usually represents a typical groundwater fauna that shares the restrictive characters of stygobitic life but allows for quantitative evaluation. Ecological studies performed under these cave conditions, preferably experimental work, might allow conclusions on the biomass and production also of the ambient groundwater fauna. Usually, aquatic cave habitats are oligotrophic and carry little meiofauna. Exceptions include some thermomineral caves with effluents of methanic and sulfidic water, e.g., Movile Cave in a karstic area of Romania. Here the ponds are populated by a fauna completely based on a rich bacterial production which, in turn, supports a meiobenthic community dominated by bacterivores (mainly nematodes) and predators (cyclopoids). The rich supply of bacterial organic matter (and the high temperatures) enables high population growth and consumption rates (Muschiol and Traunspurger 2007; Muschiol et al. 2008a). The groundwater fauna inhabits a very delicate biotope that is of great importance to mankind’s water resources. Their high sensitivity to pollutants makes stygobiotic species valuable indicators of declining water quality. Changes in their populations should be used as early signals of the potential contamination of drinking water and the need for bioremediation. With regard to the slow speed of hypogean regenerative processes, the risk of pollution by anthropogenic chemicals requires a sustainable water management concept for groundwater habitats. Implementation of this concept is imperative in order to secure our future, considering the decrease and long-term deterioration of our groundwater reservoirs globally. Areas with a diverse or unique meiofauna possess a particularly high value beyond just the scope of scientific exploration: they demand protection (Hancock et al. 2005; Marmonier et al. 1993; Danielopol 1989, 2000b).

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More detailed reading: Delamare Deboutteville (1960); Danielopol (1990b, 2000a, b), Botosaneanu and Holsinger (1991); Gibert et al. (1994); Stock (1994); Brunke and Gonser (1997).

8.7.3

Standing Waters, Lakes

Lake sediments are more easily sampled quantitatively and thus have been more thoroughly investigated than other freshwater biotopes. However, only the meiofauna from a few lakes have been reported, in contrast to the numerous papers on the littoral parts of the sea. In particular, quantitative data on lake meiofauna (abundance, turnover and production) acquired over longer periods of time are scarce, although the ecological role of such meiobenthos is becoming increasingly apparent (see below). Modern lacustrine meiobenthic research is based on the classic book by Strayer (1985) on Lake Mirror, USA. In Europe, thorough investigations of northern lakes have increased our knowledge of the contribution of the meiobenthos to benthic biomass and productivity (Sarvala 1998, focusing on copepods; Kurashov 2002). Some oligotrophic lakes in Germany have been studied in quantitative detail by Traunspurger (2000) and his team (Bergtold and Traunspurger 2005). A chain of volcanic lakes in Ethiopia was the focus of an international project coordinated by Tudorancea and Taylor (2002). The latter study connects calculations on the production of bacteria and protozoa to meiobenthic production (mainly nematodes) and discusses their role in the total benthos, underlining the need for a holistic ecosystem approach. The need for comprehensive, interdisciplinary projects in lacustrine (meio)benthology was also the basis for the Cytherissa Project in the Austrian Mondsee (Danielopol 1990a). The permanently submerged sediments of most lowland lakes and ponds (the “hydropsammal” according to Wiszniewski 1934) usually consist of fine sand rich in organic particles and silt, often covered with plants. The concentration of dissolved inorganic and organic substances in this sediment is often 40–50% higher than in the overlying lake water. Here, burrowing macrofauna and epifauna largely prevail; the meiofauna is restricted to the uppermost centimeters. Nematodes usually dominate, followed by crustaceans (cyclopoid copepods, ostracods), often rotifers, (juvenile) oligochaetes, and chironomid larvae. Tardigrades occur irregularly, but can locally reach a high abundance (Neel 1948; Holopainen and Paasivirta 1977). All other taxa are considered insignificant. During aestival warm-water conditions, the fauna in the subsurface layers is frequently exposed to oxygen deficiency and the formation of hydrogen sulfide. In deeper oligotrophic lakes in both the mountains and lowlands the ecological situation is different. The amounts of organic matter in the profundal bottom sediments of these lakes are much less; oxygen is present even in the warm season while temperatures remain low. Further comparisons indicate that the ecosystems of very large and deep lakes (sensu Beeton 1984) often differ from those of smaller ones (Särkkä 1996b; Kurashov 2002). While in ponds and small lakes adverse


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factors such as pollution and/or oxygen deficiency can easily and rapidly affect the whole benthic ecosystem, in large lakes these remain local problems that are often compensated for due to mixing with other water bodies. The moist shore sediments above the water level (“hygropsammal,” Wiszniewski 1934) usually comprise a sandy belt of 1–3 m width with a grain size composition that depends on the exposure and the slope of the shore, with the more exposed sites having medium sand (Md > 250 µm). This zone, which is well supplied with oxygen and rich in detrital food because of the debris washed ashore, is richly populated by meiofauna. Pennak (1940) found that rotifers sometimes dominated the psammofauna with extreme densities (>10,000 ind. 10 cm−3). Next in abundance were a few species of harpacticoids (e.g., Parastenocaris; Phyllognathopus ), represented by numerous individuals. In addition, nematodes, oligochaetes (including aeolosomatid annelids) and tardigrades belonged to the ecologically dominant groups of these lacustrine shores; all others were considered less important. Meiofaunal compositions in lakes vary considerably, mostly depending on the trophic status, the profundal oxygen content, and the size and depth of the lake. Water depth and eutrophic conditions are negatively correlated with species richness and trophic group diversity. About 50 nematode species (but sometimes >100) can be expected in an oligo- or mesotrophic lake. Strayer (1985) reported from the shore sediments of Lake Mirror (USA) that 70% of all meiobenthic animals were nematodes, accompanied by turbellarians (often found only occasionally), gastrotrichs, cladocerans, copepods, just a few rotifers and tardigrades, and hardly any harpacticoids. A similar composition with a dominance of nematodes (between 70 and 189 ind. 10 cm−2 = 77%) but a relatively high share of rotifers (up to 21 ind. 10 cm−2) was recorded from oligotrophic lakes in Southern Germany (Bergtold and Traunspurger 2004, 2005; Peters et al. 2007). In a seasonal study of a lake receiving thermal effluents from a nuclear plant in South Carolina, USA, Oden (1979) recorded 400–3,047 nematodes and 88–740 rotifers 10 cm−2 in the control (cold) section; these densities were reduced in the effluent-affected (warm) areas of the lake. Oden found that rotifers, with 372 species from 19 families, were second in abundance to nematodes. In a eutrophic Chinese lake (total meiofaunal abundance between 15 and 400 ind. 10 cm−2) nematodes prevailed, followed by crustaceans and occasionally also rotifers or oligochaetes (Wu et al. 2004). Other eutrophic lakes contained 40–6,000 nematodes 10 cm−2. Upon compiling the various data on the predominance of nematodes in different lakes it would appear that, in sediments with a high organic load, nematodes can reach densities comparable to marine sites and dominate as long as the sediment is oxic. Copepoda, mainly Harpacticoida, are numerically and ecologically second in abundance in many lakes (around 50 ind. 10 cm−2 in Lake Brunnsee). In oligotrophic lakes at northern latitudes with a good oxygen supply and moderate organic input, their share was relatively high compared to nematodes (max. 250 ind. 10 cm−2; Sarvala 1998). Together with cyclopoids (20 ind. 10 cm−2) they were especially common in the periphyton and in shallow sediments. Towards the deeper profundal, harpacticoids decreased in abundance, while nematodes gained in importance. The total abundance of the meiobenthos in the meso-/eutrophic Upper

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Lake Constance (Germany/Switzerland), which has a typical, nematode-dominated meiofauna composition, was 550 ind. 10 cm−2 as a mean value, while the Lower Lake Constance contained 800 ind. 10 cm−2. Maximal meiofauna density in this large lake was almost 2,000 ind. 10 cm−2 (Kurashov, unpubl.). The rich ciliate fauna is not usually taken into account in assessments of meiofaunal abundance. Pennak (1939) counted about 10,000 protozoans compared to only about 500 metazoans per 10 cm2! Strayer (1985) quantified the whole spectrum of lacustrine meiofauna and related it to macrofauna. He found the lake bottom was on average inhabited by 1,200 ind. 10 cm−2, 60 times the number and one-third the biomass of the corresponding macrobenthos. Nutritionally, most of this fauna fed on diatoms, including the food-selective species like some rotifers. Diapausing resting eggs of planktonic copepods (“zooplankton egg banks”) have also been assumed to be a food source for meiobenthos, an interesting aspect of bentho-pelagic coupling (Hairston and Kearns 2002). The large majority (80%) of the meiobenthos was grazed down by the predaceous larvae of Tanypodida (Diptera) and other insects. In the oligotrophic Lake Brunnsee (Bergtold and Traunspurger 2005), meiofauna contributed only 0.1 g C m−2 or about 4% of the total biomass (for comparison, the proportion of macrobenthos was 40%). In Finnish oligotrophic lakes this low biomass of meiofauna was surpassed by the biomass of benthic littoral copepods alone (15–30%), and with increasing depth and diminishing macrofauna, the copepod biomass increased to up to 40% of the total meiofauna biomass (Sarvala 2002). This shift is in line with the general trend that meiofaunal biomass in food-limited freshwater environments may exceed that of macrobenthos (Strayer 1991; Kurashov 2002). On a general scale, this wide range is reflected in the biomass contributions of meiofauna to the total zoobenthos biomass vary greatly (7–6%, Morgan et al. 1980). Compared to streams, the meiofauna biomass in lakes is on average 25% higher, and in certain favorable lacustrine sites it is >50% (Hakenkamp et al. 2002). Since calculations of annual production and biomass/production (B/P) ratio are strongly dependent on fluctuating factors (individual body mass, temperature, nutrient supply; see Plante and Downing 1989), the production values for lake meiobenthos in relation to macrobenthos and total zoobenthos vary widely in the literature. While production figures will be given in Sect. 9.3.2, the contribution of the meiobenthos to the overall production of the lake and its comparison with the value for the macrobenthos are of interest here. In many oligotrophic lakes the meiobenthic production is 2–4× lower than the production of macrobenthos. If microorganisms are included in this calculation, the total benthic production exceeds 12× the production of meiofauna (Bergtold and Traunspurger 2005). Again, under food limitation, the relative importance of meiobenthos may increase considerably (Sarvala 1998). According to Kurashov (2002), in large lakes the contribution of meiobenthic to macrobenthic production is on average 50–60%, while in the profundal of smaller lakes with scarce macrobenthos the meiobenthic production increases considerably and can surpass that of macrobenthos by a factor of >10 (small lakes in Latvia). However, under the impact of eutrophication, the macrobenthos gained in abundance while the meiofauna lost


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its productive relevance and became negligible. Compiling data from various lakes, Hakenkamp et al. (2002) concluded that the biomass and production of lake meiofauna will be highest in fine sand containing a limited amount of detritus where the meiobenthos is exposed to a limited predation pressure and relatively frequent disturbances. Considering the divergence in generation time and metabolic needs between meio- and macrobenthos, the productive turnover, measured as the mean P/B ratio, perhaps better underlines the ecological role of lake meiofauna. P/B ratios > 10 are reported in Bergtold and Traunspurger (2005) for the oligotrophic Lake Brunnsee; in other lakes P/B ratios of up to 37 (Bergtold and Traunspurger 2006) suggest a high importance of meiobenthos in the ecosystem. However, in numerous less productive northern lakes with slower growth, the P/B ratios did not exceed five regardless of their trophic classifications (Kurashov 2002). Sarvala (1998) computed a ratio of only 1–7 for harpacticoids. These values are in the same range as those for marine meiobenthos (see Sect. 9.3.2). Using biomass as a basis, Strayer (1986) analyzed the size spectra of benthos from various limnetic biotopes, comparing it with corresponding figures by Schwinghamer (1981a) for the marine benthos. Regardless of biotope (lakes and streams) or sediment type, he could not group the limnobenthos into separate units of micro-, meio- and macrobenthos. This remarkable difference between marine and freshwater benthos was also confirmed by lotic freshwater studies (Traunspurger and Bergtold 2006; see Sect. 9.2 for explanations). Calculation of size spectra is now an accepted way of describing the holistic functioning of ecosystems and assessing the ecological relations of benthic groups and their metabolic roles (Hakenkamp et al. 2002). But, as Strayer (1991) cautioned, many factors other than grain size also have a potential influence on the size structure of the benthos, such as the degree of physical refuge or the predation pressure. These multifactor relations will cause considerable ambiguities in interpretation (see Sect. 9.2). Regarding nematode feeding groups, it seems that deposit feeders (mainly bacteria) dominate the littoral in all lake types. In oligo-/mesotrophic lakes, the range of chewers (predators and omnivores) increases considerably, especially at profundal depths. Suction feeders living mainly on plants and fungi are of (limited) importance and occur mostly in the littoral region (Traunspurger 2002; Moens et al. 2006). This corroborates the findings of Wu et al. (2002) that the greatest variety of feeding groups and nematode species (20 spp.) were found in the least nutrient-rich area of an otherwise eutrophic Chinese lake. Regarding copepods, oligotrophic northern lakes were inhabited by some 20 harpacticoid species and 30 cyclopoid species (Sarvala 1998). Data on lacustrine meiofauna are difficult to generalize, because each lake with its environment is a restricted biotope of its own. Its meiofaunal composition and ecological role in relation to other faunal compartments will differ, being subject to a variety of controlling influences. The conditions, and therefore meiofaunal functioning itself, depend much on seasonal fluctuations, which are influenced by the geographical location and the climatic situation of the body of water

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studied. In contrast to many marine habitats, the relatively small water bodies of lakes are directly subject to these factors. Thus, performing quantitative comparisons of different lakes and sampling periods, beyond considering different sampling methodologies, is a problem. More detailed reading: Wiszniewski (1934), Pennak (1940), Strayer (1985, 1991), Sarvala (1998); Traunspurger (2000); Kurashov (2002); Eyualem-Abebe et al. (2006).

Box 8.8 Freshwater Meiofauna—A Parallel World: Similarities, Dissimilarities and Transitions to the Marine Realm Hydrodynamics, hydrochemistry (particularly oxygen), disturbances, food supply, and competition: the same key factors control both freshwater and marine meiofauna. And yet there are far-reaching dissimilarities—differing methods, research histories and distributional pathways. Studies of community dynamics and functional structure suffer from impediments to adequate sampling, especially in streams and groundwater aquifers. The unique and barely accessible world of groundwater animals is sometimes visible in cave waters, where “troglobites” closely correspond to the “stygobites,” the groundwater fauna. Groundwater studies offer unique opportunities to reconstruct zoogeographical connections and evolutionary pathways. How can we explain the meiofaunal paradox: a wide distribution of animals with almost no dispersive capacity? For an adaptive fauna (oxygen, salinity), the coastal groundwater, river mouths or marine caves are believed to be ports to the continental groundwater aquifers. The reduced competitive pressure in the groundwater or cave habitats enables the survival of relict and often primitive taxa. Thus, groundwater studies can help us to understand evolutionary trends linking marine and freshwater meiofauna. The composition of the freshwater meiofauna is quite different from the marine world. Nematodes often lose their dominance while harpacticoids take the lead; insect larvae are important temporary meiofauna, both as detritivores and predators; also the predacious cyclopoid copepods have no equivalent in marine environments. Running freshwaters (streams, creeks, rivers) are favorable sites for (experimental) studies on meiofaunal drift, emergence, and recolonization. Parallels can be drawn from their unidirectional flow regimes to the more complex multidirectional hydrodynamic patterns in the sea. In lakes, the composition and ecology of the meiobenthos vary strongly with the physiography and chemistry. Aside from the nematodes that usually dominate, other groups such as rotifers, chironomid larvae or oligochaetes can locally and temporally become abundant. Copepods may prevail in the oligotrophic profundal of deep lakes. The lacustrine meiobenthos, despite its low biomass can be a highly important producer compared to the macrobenthos.

8.8 Polluted Habitats

8.8 8.8.1

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Polluted Habitats General Aspects and Method Survey

The assessment of ecosystem health using meiofauna was an innovative approach when the first edition of this book was written. This changed with the review by Coull and Chandler (1992). This major compilation of the field still provides an important foundation and will most likely serve this function in the future. Success in pollution research means convincing laymen and critical opponents, as well as obtaining research investment, for the sake of the health of the environment’s health. Impact studies using meiofauna have now been accepted by international governmental agencies because the advantage of using meiofauna is obvious. Today, the use of using meiofauna is a widely acknowledged method of assessing the environmental status of a biotope. What is the basis for this paradigm change? Monitoring programmes and case studies performed after both natural and manmade disturbances have shown that the resolution can be improved by studying meiobenthos because of its commonly higher sensitivity and turnover compared to those of macrobenthos. Meiofauna are speciose, abundant and ubiquitous; meiofauna are even represented in extreme areas where macrofauna become scarce; and meiofauna are relatively cost-effective to handle. The multitude of anthropogenic impacts and ecotoxicological agents and the diversity of meiofaunal investigations from polluted habitats is overwhelming and, in a treatise like this, forces reductive concentration. Hence, we will first discuss general aspects and problems. This will be followed by sections on the impact of petroleum hydrocarbons, metals and pesticides, three priority categories, as the almost 300 marine meiofaunal studies on the impact of pollution demonstrate (see Coull and Chandler 1992, plus more recent compilations). Oil obviously has a strong impact, but recovery is often surprisingly fast. Metals are persistent and recovery by metabolic degradation is limited, so long-term effects and subtle changes to community composition are common. Pesticides share both features: some are highly toxic but biodegradable and the meiofauna exposed have a substantial recovery potential. The more persistent and/or adsorptive pesticides cause long-lasting community effects that require special attention. Impact studies on freshwater meiofauna have been compiled by Traunspurger and Drews (1996), Särkkä (1996a) and Höss et al. (2006). The comprehensive body of information in these papers and their bibliographies allow one to focus here mainly on the marine realm. A well-structured survey of the advantages and problems associated with using meiobenthos in pollution studies is presented by Kennedy and Jacoby (1999). The underlying mathematical principles and details of calculation will not be covered here. The reader is referred to the competent accounts by Underwood and Chapman (2005) and to references cited below. The effects of pollution by anthropogenic organic enrichment on meiobenthos will not be detailed here, although they do occur universally, especially in coastal sites and freshwater bodies. The compilations mentioned above should be consulted

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here. The general effects in this field are rather uniform and well investigated: an initial enrichment in meiofaunal numbers in the eutrophicated area is linked to a decrease in diversity and an increase in the dominance of a few species, mainly rstrategists. Most harpacticoids disappear before nematodes. As oxygen concentrations decrease, all of the physiologically demanding species will drop out. Development of hydrogen sulfide will exterminate all but the thiobiotic species, which can persist by feeding on the rich supply of bacteria and decaying animals and plants (see Sect. 8.4). While pollution by organic anthropogenic wastes is today of minor relevance for most marine sites, it still devastates many freshwater habitats. An increasing threat to the marine coastal benthos, however, are side effects of the rapidly growing aquaculture industry. Especially in the early phase, aquaculture plants in many sheltered bights caused heavy depletions in the (meio-) benthic assemblages. Today, with better knowledge and sophisticated, controlled feeding methods, it is shown that the deterioration can be largely reduced and localized to small areas that will become recolonized relatively quickly (see Sutherland et al. 2007). As Heip (1980b), Hicks (1991) and Warwick (1993) point out, there are a suite of indisputable advantages to using meiofauna rather than macrofauna in pollution studies: -

Widespread occurrence, high availability Permanent and intimate contact with contaminated sediment Superior sensitivity and rapid reactions allow for short research periods High abundance, even in small sites or usually macrofauna-impoverished biotopes (estuaries, exposed beaches, high organic loads), allows for reliable statistical evaluation (e.g., Josefson and Widbom 1988, Austen and Widbom 1991) High species richness allows evaluations of changes in community structure Indicator species are widespread and present in various taxa Short generation cycles allow for tests of sensitive reproductive stages Cost-effective experimental and field work Low sensitivity to mechanical disturbance of the sediment enhances the possibility separating mechanically induced and pollutant-induced impairment (Austen et al. 1989, Warwick et al. 1990a).

These advantages of using meiobenthos for impact studies stand against some inherently “weak” arguments that seem to suggest the superiority of the macrobenthos as a pollution indicator: - Little previous information: Baseline studies and time-series observations on meiofauna prior to the pollution event are rare (e.g., Herman et al. 1985; Bodin 1988). Extrapolating from “similar” biotopes is a deceptive approach because of the inherent patchiness and variability of meiofauna. Long-term sampling and monitoring is needed. - Unimpressive size of the affected fauna: Pollution studies with inconspicuous microscopic animals pose a problem to the public (see Box 9.3)—they cannot see them! The choice of the relevant indicator species is crucial.


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- High sampling frequency: The high temporal and spatial heterogeneity of meiofauna requires detailed spatial and temporal coverage. - Difficult identification: Only instructive, easy-to-use and computer-based pictorial keys can help in the identification of fauna as diverse and small as meiofauna. Some additional achievements have recently promoted the use of meiofauna in impact studies: - Standardized bioassays acknowledged by national and international agencies for general use have been designed (Chandler 2004; ASTM 2004; Bejarano et al. 2006a). - Electronic identification keys exist for major meiobenthic groups (Diederich et al. 2000; Wells 2007). - Pollution-specific manuals facilitate evaluation (Somerfield and Warwick, 1996). - Computation is supported by reviews (e.g., Neher and Darby 2006) and software programs. - New indices using meiofauna have refined pollution analyses in both freshwater and marine habitats (Särkkä 1996a; Neher and Darby 2006; Vassalo et al. 2006). - Genetic-based ecotoxicological studies of meiofauna material have become a priority research field (Staton et al. 2001; Kammenga et al. 2007). Thorough research on the impact of pollutants should generally evaluate the intrinsic toxicity, as evidenced by the immediate responses, and the recovery potential of the community. This requires a combination of (1) chemical analyses, (2) field studies, and (3) laboratory experiments. This “triad” in general pollution research (Long and Chapman 1985; Chapman 1986) obviously also applies to impact studies performed with meiofauna. The main strategies (all of which require evaluation by careful statistical analyses) are: 1. Chemical analyses of the pollutant and its concentration 2. Field studies of the meiofaunal assemblage with time-series observations (case studies after incidents, large field experiments) 3. In-vitro laboratory assays of toxicity thresholds in the aqueous phase (unifactorial, multifactorial) using test animals (acute toxicity with representative species, long-term impact through generations with culturable test organisms) 4. Mesocosm studies in containers with sediment, agar (nematodes) or artificial substrates, either applied with a toxicant or transplanted into the polluted environment In addition to the traditional surveys performed after pollution incidents, largescale field experiments have recently been performed (Schratzberger and Warwick (1998 a,b). Furthermore, standardized experimental field approaches have been designed (Mirto and Danovaro 2004). Despite their complex interpretation, the results from these studies in the natural marine environment are probably more generalizable than single-factor tests performed in the laboratory.

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Many aquatic pollutants are sorbed to the sediment particles and so there are typically higher concentrations in the sediment than in the overlying water. This would suggest that sediment-associated tests yield more realistic information for meiofauna, considering their intimate contact with the sediment (Kovatch et al. 1999; Schratzberger et al. 2000; Chandler and Green 2001). However, toxicants in sediments have typically proven to be less toxic than their counterparts under “inwater conditions” (e.g., Austen and McEvoy 1997b; Green et al. 1993 for metals). In the “sediment situation,” many toxicants may not be bioavailable to meiofauna, their toxicities having been reduced by chelation or complexation, or by binding to organic ligands and colloidal aggregations on the sediment surface. Hence it is the bioavailability, not the absolute concentration of pollutants measured in water, that determines the noxious effects on the benthic environment. In nature, where single factors often act synergistically, the multifactorial impact of pollutants interacting with natural stressors (salinity, temperature, perturbation, high organic load) is usually more detrimental than the effect of adding the impacts of each individual toxicant (but there have been exceptions where the combined effect was less severe than the additive one). Hence, multiple stress experiments (e.g., low salinity plus elevated metal concentrations) will achieve more representative results. Another facet that illustrates the complexity of toxic interactions is that the pollutant toxicity can be modified by the addition of dissolved organic matter (DOM) (Höss et al. 2001; Bejanaro et al. 2005). One specific advantage of using meiofauna in pollution studies is their short generation times, since multigeneration tests are often needed to obtain reliable results on long-term community effects, which are cryptic at first sight. Sometimes, shortly after a pollution event, the overall abundance of meiofauna may increase (depending on the species, the nature and concentration of the pollutant, etc.), superficially suggesting a negligible impact. This could easily lead to erroneous rash conclusions about a non-detrimental effect. Often it is long-term parameters, such as lowered reproductive rates, decreased taxonomic diversity and a reduced ecological diversity, that provide the most severe consequences for the community. It is generally more informative to concentrate on the highly sensitive reproductive output parameters (clutch size, larval stages) than to focus on adult abundance and biomass (Giere and Hauschildt 1979; Bejarano et al. 2006a,b, for oil pollution; Chandler 1990; Bejarano et al. 2004, for pesticide contamination). Toxicity tests with developmental stages for pollution assessment require laboratory cultures, experiments and standardized bioassays with sensitive and preferably widespread and easily achievable common “indicator species.” But are there any easy-to-recognize species? And can we perform life cycle bioassays with them? So far, experiments with about 50 continuously lab-cultured meiobenthic species (among them about 15 harpacticoid copepods and some 30 nematodes) have been performed. The harpacticoids in particular combine sensitivity with frequency (mainly Amphiascus tenuiremis, Microarthridion littorale, Nitokra sp. and Robertsonia sp.). The culture of marine harpacticoid species as pollution indicators is most advanced in the USA (Chandler 1986; Chandler and Green 2001; Bejarano et al. 2006a,b). Tisbe sp. and Tigriopus japonicus are often used in Europe or in the Pacific area and new representatives are added regularly. Chandler’s working


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group succeeded in getting standardized bioassays officially licensed by the American Society for Testing and Materials (ASTM 2004), and (more recently) globally licensed by the OECD. Among the marine nematodes, Chromadora spp., Chromadorita tenuis, Pellioditis marina and Diplolaimella spp. are classical targets for culture (Tietjen and Lee 1984; Jensen 1983; see compilation by Moens and Vincx 1998); nematodes cultured for bioassays often belong to Monhysteridae. Meiobenthologists have also elaborated culture methods for freshwater nematode species (Panagrellus redivivus, Caenorhabditis elegans; see Traunspurger and Drews 1996; Heininger et al. 2006; Höss et al. 2006). Bioassays allowing to monitor the environmental impacts of noxious events on communities and their reestablishment integrated into the natural multifactorial network require standardized substrate conditions (e.g., bottle brushes, plastic sheets) (Mirto and Danovaro 2004). With the progress in technology, modern analytical procedures do not require large amounts of biomass, which was an obstacle that often disadvantaged meiofauna with respect to macrofauna. Bioaccumulation studies can be performed by analyzing tissue extracts in the microgram range (Wirth et al. 1994; Haitzer et al. 1998); changes in the genetic backgrounds of populations exposed to chemicals can be detected by “ecotoxicogenomic” screening (Watanabe and Iguchi 2006); the DNA barcoding of whole populations on a few slides (Bhadury et al. 2006a) offers the chance to exploit their biodiversity, which is often reduced as a response to pollution and environmental depletion (see below). Rapid in vivo effects of toxicants on meiofauna and their offspring can be documented and evaluated semiquantitatively under a confocal laser scanning microscope, thus linking the huge potential of fluorescence labeling to bioassay techniques (Chandler and Volz 2004). Ecophysiological parameters such as micro-respiration measurements can be used to derive the status of physiological resistance (Moens et al. 1996). Studies on meiofauna from many regions suggest that stress caused by disturbances, organic wastes or toxicant contamination causes a decrease in the various types of diversity (Warwick 1988b; see Sect. 9.1) and an increase in dissimilarity compared to reference communities. This deviation from “normal” is indicated by similarity indices that compare differences in the species compositions of two sites (Sørensen Index, Jaccard Index, Hill’s Index). Dominance indices (e.g., Simpson’s Index) relate the total abundance of species in samples (communities) to single species abundances. The Shannon diversity relates the observed species number to the (expected) species number, while the evenness considers aspects of how the individuals in the sample are apportitioned among species (distribution/aggregation). Biodiversity (taxonomic diversity in its various forms, such as weighted diversity) measures the number of taxa (species) per habitat/sample. All of these “classical” indices have a distinct information value and are used in pollution studies (see the good overview in Neher and Darby 2006). Their calculation is not detailed here, since such explanations can be found in numerous ecology textbooks and software programs; for comments and restrictions see Heip et al. (1988). Recent improvements of these indices also consider, in a probabilistic approach, those species present at the sites, but unseen in samples (“expected number of species-index” or “improved Shannon index”). Thus, they reduce a considerable bias in many indices.


Shannon-Wiener function (bits ind.−1)

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5

Copepod species Copepod genera

4

3

2

1

0 6 north

4

2 2 0 Distance from dump centre (km)

4 south

Fig. 8.18 The decrease in harpacticoid copepod diversity related to the distance from a polluted site in the Firth of Clyde, Scotland. Note the corresponding curves from evaluating species and genera. (Moore and Bett 1989)

Thus, they allow for more refined results than do the routine procedures (Chao and Shen 2003; Chao et al. 2006). Most meiofaunal studies have demonstrated that pollution results in causes marked changes in diversity (Fig. 8.18 ). Lambshead et al. (1983) introduced into ecology a method of assessing stress through pollution, the “k-dominance method.” An updated method, the “ABC method” (Warwick, 1986; Warwick et al. 1990a) relates abundance to biomass in two comparative curves. Both calculations are based on the assumption that in undisturbed biotopes the more K-selected specialist species (persisters) account for high individual biomass, even though they have low population densities and thus only a low numerical rank. In contrast, communities of r-selected generalists (colonizers), which dominate in disturbed areas, are typically characterized by just a few species that exhibit low individual biomass but large population density, thus attaining a high numerical rank (Fig. 8.19 ). (The general meanings of the character complexes r- and K-strategists are reviewed in Parry 1981.) Now, if the species are plotted on a log-scale-abscissa according to their rank, and on the ordinate according to their cumulative percentage dominance, the result can be highly indicative when comparing the curves for abundance and biomass. A disturbance (e.g., due to pollution) can be postulated if the abundance curve is elevated above that the biomass curve. If the biomass curve exceeds that of the abundance, the site can be considered undisturbed (Fig. 8.19). Essentially, this method is a graphical comparison of the two components of diversity, species richness and evenness (Platt et al. 1984). Although this convenient graphical method only allows a rather coarse discrimination of a few levels of pollution, it does not require control samples: the two curves represent an “internal control.” Warwick et al. (1990b) demonstrated that

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Cumulative %

ss ma

Bio

ce

n nda Abu

ce an nd u ss Ab ma Bio Moderately polluted

Unpolluted

Cumulative %

Cumulative %


e nc da n bu

A

s

as

m Bio

Grossly polluted

Species rank

Fig. 8.19 Hypothetical k-dominance curves for areas polluted to varying degrees. (Warwick 1993)

the k-dominance method can also be applied to meiofauna as a valuable indicator of disturbances despite the minute divergences in biomass between meiobenthic rand K-strategists. On the other hand, this study also revealed the inherent problem of interpretation: depending on the taxon, each kind of disturbance has a different impact and causes a different curve shape; e.g., nematodes are clearly affected by sediment disturbance (bioturbation), harpacticoids less so. Many of the characters listed above should make meiofauna an ideal tool for studying changes in benthic ecosystems. However, there is one major impediment: for optimal information value, many of the above indices require identification to a low and uniform taxonomic rank (species, genus). Even with the necessary instrumentation and literature, this thorough identification requires manpower, time and experience. To circumvent this problem, approaches based on “taxonomic minimalism” have been developed, which require bulk recognition to higher taxa only, and can be performed (with some guidance) by untrained personnel too. However, is too much informational value lost if we simply compare characteristic groups? Does the high ecological differentiation in meiofauna allow for a summative identification of higher meiobenthic taxa? Large-scale and comparative meiofaunal studies have shown that data based on taxonomic ranks as high as families still allowed a fairly clear separation of stations according to their degree of disturbance/pollution (Heip et al. 1988; Herman and Heip 1988; Warwick 1988a; Heininger et al. 2007). Especially in nematodes, data - aggregated to higher taxonomic ranks - yielded a fairly consistent discrimination between sites. The frequently used “maturity indices” (Bongers 1990; Bongers et al. 1991) characterize the relation between the “quality” and the stress situation of an environment. Based on species, genera or even families, they rank the taxa according

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to their life history characteristics into various degrees of “persisters” or “colonizers.” Members of these categories are known to be differently sensitive to stress or pollution. In disturbed sites the index is low; in areas with little or no disturbance the values are high. Upon applying this maturity index to various areas stressed by an oil spill, an overload of organic matter, heavy metal contamination, etc., it was shown that the index is widely applicable for the discrimination of stressed from unstressed biotopes in terrestrial, freshwater, marine, deep-sea and tidal flat habitats (see Essink and Romeyn 1994). With the increasing reliability of the allocation of taxa to stress classes, this method could provide a relatively simple means of assessing biotope disturbance. However, Heininger et al. (2007) showed that it can give results that conflict with the conclusions drawn from the chemical analysis of the same habitat. Modifications of the classical maturity index incorporate feeding groups, which, again, reflect environmental variables (see Neher and Darby 2006). Another approach that attempts to simplify working with meiofauna when investigating the effects of pollution is to focus on characteristics of the two most abundant taxa, nematodes and harpacticoids. In cases of organic enrichment, and often also chemical pollution, nematodes are on average more stress-enduring than harpacticoid copepods. This often observed ecological discrepancy is the basis for the “nematode/copepod ratio” (N/C index; Raffaeli and Mason 1981), proposed as easily applicable means of measuring the impact of pollution. The authors contended that this trend would be generally valid for sandy eulittoral coasts. However, the N/C ratio also turned out to be sensitive to natural environmental variables (grain size, water content), which brought its general reliability into question (Coull et al. 1981; Lee et al. 2001). Nevertheless, the ease of calculation made this ratio one of the most applied but also debated pollution indices in the field of marine meiobenthology. Raffaeli (1987) partly corrected his earlier oversimplified contention. What is the basis for the different ecological reactions of the two dominant meiofaunal taxa, and in which cases did the N/C ratio yield questionable results and thus require refinement? Harpacticoids comprise two major groups with different substrate-related life histories. The mesobenthic (interstitial) species live in sand, while their epibenthic or endobenthic counterparts instead prefer water-saturated fine sand and mud. Nematodes seem less dependent on sediment structure. This difference in substrate-relations is enhanced by the differences in the trophic niches of the two groups. Most nematodes are linked to a short, detritus/bacteria-based food chain. Hence, with organic enrichment of the site (generally typical of finer sediments), their abundance will usually increase even if the oxygen levels sometimes decrease (Fig. 8.20, compare Essink and Romeyn 1994). In contrast, harpacticoids are mainly microalgae-based and oxygen-sensitive members of the food web. The interstitial subgroup of copepods will react negatively to an increase in the organic load (compare Rudnick 1989; Vincx et al. 1990) with concomitant depletion in oxygen and clogging of the void system by debris. This scenario would explain the divergent N/C reactions of the taxa in many cases of organic pollution. Various studies (e.g., Sandulli and De Nicola 1991) that performed experimental work alluded to confirmed the different reactions of the two meiofaunal groups.


357 Nematodes

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Fig. 8.20 The divergent response of nematodes and copepods (harpacticoids) to a pollution gradient. For further explanation see text. (After Raffaeli 1987)

However, there are still interpretations that are not easily explained and that reduce the general applicability of the N/C ratio: the endo/epibenthic subgroup of harpacticoids is not greatly impaired by enrichment of organic matter. It may even initially increase in abundance with the increased food supply. This questions the indicative value of the N/C index if one generalized taxon “benthic copepoda” is used. Therefore, Shiells and Anderson (1985) suggested restricting the calculation of a refined N/C ratio to just the interstitial (mesobenthic) harpacticoids. Moreover, in cases of chemical pollution, the nematode populations can also decrease, so that the curves for both groups are similar and are not indicative. It appears that a refined version of N/C ratio is useful in cases where the effects of a pollution incident in a restricted area and the recovery phase are monitored over time without detailed identification (Raffaeli 1987).

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When not over-interpreted and not universally applied, the community indices outlined above, regardless of some criticism related to their insufficient consideration of ecosystem interactions, still appear to be useful and indicative tools for investigating many man-made changes in (meiofauna) community structure. The taxonomic distinctness of a community—the degree of relatedness of the taxa within a sample—has been transformed into an index, the TDI index (Warwick and Clarke 1995, 2001; Clarke and Warwick 1998). This index incorporates biological and ecological aspects as well as the distribution pattern. With increasing stress and decreasing habitat heterogeneity, the community will become more monotonous and the taxonomic distinctness will tend to decrease (Barbuto and Zullini 2005). For practical work it is important that the TDI is independent of the sampling success during data collection, while the other indices are strongly influenced by the number of sampled taxa. While many of the procedures outlined above also are applicable to freshwater field studies to evaluate anthropogenic impact, some specific and simple indices may help to avoid the need to evaluate all fauna. For northern lakes, Särkkä (1996a) contends that characteristics of the meiofauna such as easy access, large diversity and abundance, as well as its reduced seasonality, would support the use of meiofauna compared to macrofauna in assessing pollution. As easily recognizable indices, he proposed the numerical relation of permanent to total meiofauna, the ratio of aeolosomatid annelids to oligochaetes, and the percentage of naidid oligochaetes to total oligochaetes. For river-beds Zullini (1976) focused on nematodes and showed that the relation of the more tolerant Secernentea to Adenophorea might be a good pollution indicator. A valuable overview of the methods used in freshwater environmental science is given by Höss et al. (2006). Perhaps the biologically most meaningful method of linking community data to an environmental impact such as pollution is application of multivariate statistics. In many independent papers on meiofauna it has been shown that multivariate analyses (e.g., classification using the Bray–Curtis dissimilarity and multidimensional scaling ordination, MDS) are more sensitive approaches to reveal disturbances and impact events than the univariate indices (Gray et al. 1990; Austen and Somerfield 1997; Schratzberger and Warwick 1999b; Wetzel et al. 2002; Saunders and Moore 2004; Heiniger et al. 2007 for freshwater). Although the computational basis of multivariate statistics is fairly complex, especially in the case of the multidimensional scaling method (Field et al. 1982), the yields are an easy-to-conceive graphical document: a “map” of sample similarities influenced by environmental variables, e.g., pollution (Fig. 8.21). The superior sensitivity and the general applicability of MDS-method have proven valuable in numerous examples related to the macro- and meiobenthos, and for both abundance and biomass values (Warwick et al. 1993a; Somerfield et al. 1994). Moreover, MDS ordinations allow for a “taxonomic minimalism.” Calculations based on ranks above the species level (genera: Somerfield and Clarke 1995; families: Herman and Heip 1988; Warwick 1988a; Christie and Berge 1995) result in essentially similar patterns (Fig. 8.22), although a loss of discrimination/ information with coarser resolution is evident (Quijon and Snelgrove 2006; but see

Single indices (e.g. diversity, species richness, evenness

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Fig. 8.21 Schematic procedure for various statistic calculations including MDS scaling. (Courtesy M. Schratzberger)

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Fig. 8.22 Multidimensional scaling ordination (root-transformed abundance) for copepod data from the Firth of Clyde, Scotland. Samples from unpolluted sites are stippled, those from polluted sites are in bold black. The use of different taxonomic ranks results in largely the same sample configurations. (Warwick 1988)

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Carman and Todaro 1996). Nematodes seem especially robust to the grouping in higher taxa. Hence the MDS- method, often combined with additional analyses, represents a valuable tool for revealing the impact of an environmental variable (e.g., pollution), even in cases where mere diversity assessment could not give a significant answer (Warwick 1988a). Today the statistics in meiofaunal studies on disturbance and pollution are analyzed using convenient software programs (e.g., PRIMER in its various versions; Plymouth Marine Laboratory; http://www.pml.ac.uk/primer/index.htm). This classic in the field of ecological impact studies is available as a comprehensive package containing, among other methods, similarity profiles, Bray–Curtis dissimilarity calculations, cluster analyses in illustrative graphics, and various univariate indices. Training courses for the application of PRIMER are being offered. By using factorial correspondence analyses, interconnections between environmental parameters and meiofaunal community structure can be revealed (e.g., Villiers and Bodiou 1966). Their interpretation, though, requires a good biological understanding and is less easy than the computer-assisted calculation. An easier graphical interpretation is offered by the principal response calculation (PRC), a multivariate method that illustrates the relation between the sampling period and the first principal component responsible for the variance. In canonical correspondence analyses (CCA), the taxon data are compared with various environmental variables depicted as vectors on a biplot. The relative importance of the vector (variable) is then indicated by its length, and its correlation to other, neighboring variables by its angle. Canonical correspondence methods are embodied in the PRIMER package mentioned above, computer assistance facilitates their use considerably. Recent methods emphasizing the functional diversity and complexity of communities sometimes offer a useful option for indicating disturbance/pollutioninduced changes in ecosystem structure. In nematode studies especially, alterations of feeding group abundances are examples of such changes. However, the interdependence of trophic structure and substrate granulometry, which is especially well known for nematodes (see Figs. 5.21, 5.22; Kennedy et al. 1994; Schratzberger et al. 2007b), may hamper a simple interpretation (Höss et al. 2004). Regarding the rapid advance of simple-to-use and graphically attractive mathematical/statistical software, one caveat is appropriate: as easy as it may become to apply statistical programs, the user’s understanding of the underlying principles is also required. Presentations of sophisticated statistics/factor analyses/correlations often give the impression of an erratic trial-and-error-procedure without too much comprehension of the underlying biological processes. Easy application of statistical tests cannot substitute for a lack of understanding, an unclear conception, insufficient background knowledge and a thorough literature inquiry. The various methods used to assess changes in community structure (and community stress) are summarized by Warwick and Clarke (1991), Clarke (1993) and Warwick (1993): 1. Univariate methods, where the relative abundances of the various species are reduced to a single index. The appropriate statistical test is the classical ANOVA; the most frequently used univariate method is the Shannon Wiener


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diversity index H’ (Shannon and Weaver 1949), usually combined with calculations of evenness (equality of distribution). 2. Graphical/distributional methods, where the relative abundance (or biomass) of a species is plotted as a curve. The typical example is the k-dominance curve. This group of methods provides more information about the nature and distribution of the fauna than a diversity index. 3. Multivariate methods of classification and ordination, where faunal communities are compared with respect to their specific identities and (relative) quantitative importance. These methods are exemplified by techniques such as multidimensional scaling ordination (MDS). The two first types of methods have a disadvantage: they can yield identical results from communities with completely different taxonomic compositions. They are also less sensitive to detecting community changes than the multivariate methods. However, they can give a fairly clear assessment of the presence of detrimental (e.g., pollution) effects. On the other hand, the third group of analyses, multivariate statistics, document faunal changes with precision and are widely applicable, but they give few indications of the possible reasons. The option to compensate for the shortcomings of the different types of methods and to optimize their specific advantages is the combined use of several methods (Clarke 1993; Dauer et al. 1993).

8.8.2

Selected Cases of Pollution and Meiofauna

8.8.2.1 Oil Pollution Oil spills frequently devastate the environment, especially in coastal regions. Since environmental spilled oil in the environment is dreadfully spectacular, the effects of petroleum hydrocarbons on marine sites are frequently studied. Surprisingly, benthic fauna, including meiofauna, often appear only mildly affected. A long-lasting depletion of the fauna is only rarely reported, even after major oil spills. However, rash conclusions based on the behavior of some robust species only embody a potentially high political and societal risk that there are few effects of oil spills and recoveries from them occur quickly. But have the fauna really recovered? After a dramatic decline in abundance and diversity immediately after the impact, the return of the fauna is quite rapid (weeks, some months). Pioneered by some robust species, this return may misleadingly indicate an environmental recovery. The complex and sometimes controversial impact of hydrocarbon compounds on the environment can only be comprehended by detailed investigations involving field and experimental work, long-term monitoring and acute toxicity tests. Below I attempt to provide a clear picture of the multifactorial effects of oil pollution in the environment. Crude oil, consisting of thousands of chemical compounds with various toxicities and properties, is a natural product to which many meiofaunal species can partially adapt. During the “aging of oil,” the most toxic substances—the short-chained aromatics—evaporate and dissolve very quickly, so the oil remaining in the sediment

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is more persistent. Natural oil seeps in the sea are equivalent to organic enrichment (Montagna et al. 1989, 1995; Lee and Page 1997), and the stocks of nematodes are particularly rich here. Even negative impacts of oil platforms appear to be restricted to the direct vicinity of the outlet (Carr et al. 1996). Some of the negative results recorded from areas contaminated with oil were probably caused by the oxygen depletion induced by the degradation of excess organic matter rather than the toxicity of the oil itself (Bodin 1988). For the benthos in subtidal sediments, dissolution of many toxic substances in the water column further reduces the toxicity of natural crude oil; only a small part of spilled oil reaches the bottom (1–13% according to Lee and Page 1997). Boucher (1980) could not find a significant reduction in subtidal meiofauna, even after the huge Amoco Cadiz oil spill (see below). For shallow subtidal diatoms, Suderman and Thistle (2004) also confirmed a lack of significantly noxious effects of fuel oil. In subtidal samples from the Ligurian Sea (Mediterranean), meiofaunal populations after oil contamination returned to normal after only one month (Danovaro et al. 1995). The effects of oil spill accidents on shore life, specifically on meiobenthic communities, are divergent and difficult to summarize because of the different nature of the oil and the local physiographic and climatic conditions, e.g., wave exposure, sediment structure, season and temperature. This complexity makes reliable general predictions about the impact of oil spills almost impossible. In the large oil spill off La Coruña (Northern Spain) in 1976, all of the eulittoral meiofauna on beaches adjacent to the oil outflow were exterminated, and only a few opportunistic species had survived one year after the spill (Fig. 8.23). A similar massive destruction of meiofauna was reported from oil spills off Hong Kong and in brackish water of

Fig. 8.23 The impact of an oil spill on the abundance of nematodes in beaches off La Coruña, Northern Spain. Comparison of two data sets obtained six weeks and one year after the spill. (After Giere 1979)


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the Baltic Sea (Wormald 1976; Elmgren et al. 1983). Since spilled fuel oil can also drastically destroy the meiofauna (Ansari and Ingole 2002), the risk of massive destruction does not apply solely to oil tanker wreckages. In less destructive cases, the immediate meiofaunal response to oil spills is usually a strong reduction in harpacticoids, ostracods and turbellarians, and a less severe impact on annelids. The decrease in nematode populations is often only subordinate and difficult to separate from natural fluctuations. Correspondingly, the begin of the recovery phase after a spill is first indicated by nematodes which have a greater ability to survive oil compared to copepods (Christie and Berge 1995). Correspondingly, effects resulting from oil contamination and subsequent bioremediation are often indicated by subtle sublethal reactions of the communities, e.g., by changes of the dominance pattern, altered diversity and evenness (Warwick et al. 1988; Schratzberger et al. 2003). In microcosm experiments with differentially oiled salt marsh sediments and impact periods, Carman et al. (1997) found also changes in the nutrition. Grazing rates of most copepod species were reduced with increased exposure to and concentration of oil (see also Christie and Berge 1995). The Amoco Cadiz spill in 1978 represented a rare case in which the meiofauna (nematodes) had been monitored for years prior to the oil spill. However, at least for nematodes, univariate statistics did not reveal a significant negative impact that was discernible from the disequilibria caused by natural environmental variables. The complexity of the field conditions did not allow for a straightforward interpretation (Bodin and Boucher, 1983; Bodin 1988). Only the sensitive harpacticoids reacted with a decline in abundance and diversity right after the spill. Specifically, the more susceptible juvenile stages of harpacticoids were severely reduced and reproduction was delayed, which caused changes in the population dynamics due to depleted copepodite stages. Only MDS- and ABC-methods were sensitive enough to demonstrate the impact of the oil spill (Warwick and Clarke 1993). After two or three years, the “degradation phase” ended, but according to long-term studies it took almost six years for the meiofauna to recover and re-establish their status prior to the spill (Boucher 1985; Bodin 1988, 1991). Recovery after a spillage starts often with an unbalanced blooming of microalgae within a few months. This first sign is followed by rapid population outbursts of some robust nematodes (e.g., Sabatieria pulchra) and harpacticoids (e.g., Cletocamptus deitersi) accompanied by erratic fluctuations in the dominance pattern. Strong population growth in some species/groups is accompanied by the destruction decrease of more sensitive competitors and predators and supported by a rich supply of microalgae (Fleeger and Chandler 1983; Montagna et al. 1995). These outbursts are often followed by sudden population breakdowns. Especially in exposed, sandy shores, complete recovery of meiobenthic assemblages (measured in terms of diversity and evenness) may be achieved relatively rapidly, sometimes in less than one or two years (Rodriguez et al. 2007). The speed of recolonization depends much on the presence of neighboring donor assemblages (Gourbault 1987). However, in sheltered muddy bights and estuaries, depletion will last much longer due to the long persistence of undegraded toxic substances in

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the absence of oxygen in deeper layers. In the Amoco Cadiz spill, the depression of the meiofauna in the ecologically delicate muddy Bay de Morlaix was so pronounced that (based on abundance-related species-rank calculations) it took six years before the meiofauna had recovered (Gourbault 1987). After a smaller oil spill in the Ligurian Sea, Danovaro et al. (1995) could not determine any impact on the nematode populations using the N/C ratio (see also Carman and Todaro 1996; Ansari and Ingole 2002). However, a decreasing diversity is apparently a better indicator, as shown after the oil spill at the Hebridean shores (Moore and Stephenson 1997). Refined multivariate statistics may reveal that these seemingly mild cases of oil pollution might also have a clearly negative effect on meiofaunal communities (Warwick and Clarke 1993). What about cleaning up oil-polluted sites with dispersants? Does bioremediation with fertilizers help? While earlier oil dispersants often acted as additional stressors that enhanced the toxicity of the oil/dispersant mixture (Giere and Hauschildt 1979), modern products are fairly neutral if appropriately applied. Bioremediative additives might stimulate the growth of oil-degrading bacteria but they do not seem to enhance recolonization rates of meiofauna (Schratzberger et al. 2003). Experimental work on the impact of oil on meiofauna can be problematic considering the labile chemical processes and the multifactorial situation in the field. Small-scale laboratory experiments often result in extremely rapid recoveries, in the range of weeks or a month (Alongi et al. 1983; Fleeger et al. 1996). On the other hand, larger mesocosm experiments have produced drastic declines in meiofaunal populations, especially of harpacticoids, and indicated recovery times of about two months (Grassle et al. 1980–81). In field experiments three months were needed until the depressed diversity and increased evenness of meiofauna in artificially oiled sediments returned to the values of the corresponding reference samples (Schratzberger et al. 2003). Also, from a beach site treated with different dosages of crude oil, McLachlan and Harty (1982) recorded a recovery period of a few months (at least for the more robust nematodes) after an initial general decline was recorded (McLachlan and Harty 1982). In order to discover sensitive reactions that are not concealed by the survival of robust species, laboratory work often focuses on life cycle-based assessments of oil toxicity. Standardized and normative experiments on the impact of oil bioassays have been developed by Chandler and his team (see Bejarano et al. 2006 a,b), with the harpacticoid Amphiascus tenuiremis used as test species. As already shown with oligochaete offspring (Giere and Hauschild 1979), reproduction and development of these copepods is a sensitive indicator of pollution damages at concentrations that are indifferent to adults: for example, maturation time gets delayed, fertility is reduced, and larval stages (especially nauplii) become impaired or halted in their development. Palmer et al. (1988) summarized three main reactions of meiofauna after oil spills. (1) A “dramatic decline” in the abundance and diversity of the meiobenthos occurring in direct contact with the oil. (2) “No change,” probably only found in subtidal sites not immediately exposed to the most toxic, highly volatile/soluble oil compounds. (3) “Enhanced abundances” after contamination, momentary phases of


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the unbalanced, erratic fluctuations of some robust species. Typical of stressed communities (Warwick and Clarke 1993b), they indicate a severe disturbance in the early contamination phase. Twenty years after the summary by Palmer et al. (1988), additional compiled experiences on the reaction of meiofauna to oil impact allow a differentiation of the variable and partly controversial meiofauna reactions: (a) Depending on the extension of the spill and the nature of the oil, the initial losses in meiofaunal abundance and diversity will (at least in “high energy” sites) only persist for a relatively short time (months to a year) compared to more sheltered areas. Here the recovery will be retarded and take much longer (on the order of several years). Since the statuses of the intact neighboring sites are crucial to recolonization, small-scale contaminations, especially in exposed areas, will return to normal in the range of several weeks. (b) Juveniles are more sensitive to oil pollution than eggs or adults. Hence, bioassays analyzing reproductive success (fertility rates) and survival of first larval instars will better reveal sublethal damages after light contaminations (Bejarano et al. 2006a,b). (c) Only the most recent formulations of oil dispersants or bacterial fertilizers do not enhance the toxicity of the oil. In most cases, natural chemical and biological degradation processes and the natural supply of oil-degrading bacteria will be appropriate for effective oil-cleanup. Of course, these “invisible” and timeconsuming natural clean-up activities are often not enough spectacular for the media.

8.8.2.2 Effects of Pollution by Metal Compounds Invisible, highly persistent and ubiquitous, metal compounds are probably a greater threat to the environment than the spectacular but transient and local oil spills. Reflecting this notion is the increasing number of meiofaunal studies on the impact of (heavy) metals and their derived compounds, such as many antifouling agents. However, the majority of these studies are laboratory in vitro tests (Coull and Chandler 1992). In situ and sediment-bound, metal compounds, like other pollutants, are less toxic than in the aqueous phase. This is especially true in organic-rich muds (Austen and McEvoy 1997b; Austen et al. 1994). Chemical, physical and biological processes modify the toxicity: chelation, binding preferences (redoxdependent), pH, bioturbation, adhesion to biofilms and mucous secretions, metabolic uptake or selective storage. The synergism or even antagonism of several metals acting simultaneously in polluted areas confounds dosage effects of single metals (Mahmoudi et al. 2007). Hence, the toxicities of metals depend greatly on their bioavailability and barely relate to “total concentrations.” Therefore, the specification of actual threshold concentrations in sediments is probably not helpful, since interactions with ecological factors and different community patterns render them of local significance only.

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Metals vary in toxicity; according to the impact scale, mercury and copper seem to be particularly toxic, more so than zinc, cadmium or tin (see Van Damme et al. 1984; Austen et al. 1994, Austen and McEvoy 1997a,b; Austen and Somerfield 1997). Moreover, copper compounds are particularly relevant since they are present in numerous antifouling paints and are thus widespread in the aquatic world. This explains why many meiofaunal studies have been performed with this metal. Experiments by Alsterberg et al. (2007) showed that total meiofauna biomass decreased significantly with exposure to copper pyrithione. Freshwater harpacticoids with a high content of the food-derived carotinoid astaxanthin were better protected against toxic oxidants such as copper (Caramujo et al. 2008). Mixtures of several metals can have a different toxicity compared to that of the individual metals (Fig. 8.24). In solutions containing copper with mercury or with zinc, paired (synergistic) exposure was less toxic to the common marine nematode Monhystera disjuncta than exposure to each metal individually (Vranken et al. 1988a). However, in corresponding experiments with the harpacticoid Nitokra spinipes the combined effect of mercury and copper increased the mortality (synergistic effect) (Barnes and Stanbury 1948). Newly developed organo-metal compounds such as copper pyrithione are effective antifouling biocides that are added to paints. They seem to have little negative impact on meiofauna (nematodes), they tend to mainly affect prokaryotes and fungi more (Larson et al. 2007). On the other hand, exposure to metals in combination with the organic pesticide phenanthrene (see below) proved more toxic to meiofauna than any of the pollutants alone (Fleeger et al. 2007). The physiological mechanisms behind these different combined or 6

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singular effects differing in the various meiofauna groups are unclear. Toxicity even differs with the chemical form of the metal administered to the meiofauna; for example, methylmercury is more toxic than other mercury compounds. In contrast to the contention of Somerfield et al. (1994), the overall data suggest that harpacticoids are on average more sensitive than nematodes, just as they are to other pollutants. Females seem more severely affected than males, a conclusion derived from several studies and probably related to the better solubility of metal compounds in the richer lipid deposits of the (mature) female body. The overall flux of metals through the food web from meiofauna to macrofauna varies depending on the transfer rate, which is, apparently, greater in nematodes than in harpacticoids (Fichet et al. 1999). Ecological group parameters might suggest changes in community structure where single-species analyses fail. Parallel to increased levels of metal concentrations, the diversity, dominance pattern and evenness of meiofaunal nematodes decreased in the heavily polluted New York Bight (Tietjen 1980b). Conversely, an increasing species richness and abundance paralleled decreasing contamination in a North Sea estuary (Somerfield et al. 1994). In this study, the superiority of multivariate statistics again demonstrated concealed changes and suggested “that nematode community structure changes in a smooth and ordered fashion with increasing sediment metal concentration.” Among both harpacticoid copepods and nematodes, there are even adapted species (or local intraspecific strains?) with a high tolerance to heavy metal compounds (e.g., Tachidius discipes, Microarthridion fallax, Pseudobradya sp., Tisbe sp. among harpacticoids and Molgolaimus demani, Sabatieria pulchra, Axonolaimus, paraspinosus, Oncholaimus campylocercoides, Bathylaimus capacosus among nematodes, see Warwick et al. 1988; Somerfield et al. 1994; Hedfi et al. 2007). Species of the harpacticoid genera Cletodes, Laophonte and Stenhelia are also considered robust (Saunders and Moore 2004). Additionally, adaptive effects may expand the tolerance range within the same species: Enoplus brevis (Nematoda) from a polluted site was in experiments more tolerant than specimens from unpolluted sites (Somerfield et al. 1994). Only after longer periods of exposure to metals a certain selection for more tolerant species appears to influence the community composition: along a copperenriched estuary the number of Cu-tolerant nematode species increased when compared to uncontaminated reference sites (Millward and Grant 1995). The drastically depressed abundance of harpacticoids in the Westerschelde estuary (North Sea) was considered to be due to the increased levels of heavy metals, especially of copper (Van Damme et al. 1984). In Chilean beaches exposed for years to copper mine tailings, meiofauna was restricted to certain tolerant nematode species, while the number of harpacticoids, correlating with the copper concentration in the pore water, was negligible at many stations (Lee at al. 2001b; see also experiments by Lee and Correa 2006). These results suggest that harpacticoids, especially their larval stages, are sensitive indicator organisms for ecosystem deterioration due to exposure to metal pollution. A bizarre and hopefully unique experience regarding meiofauna and metal contamination is the report by Pogrebov et al. (1997) on the severe plutonium pollution in the bottom sediments of an Arctic inlet after several nuclear test explosions.

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While changes in the macro- and meiobenthic communities were not reported to be severe, in some areas the ciliate fauna was found to be massively impoverished or “eliminated,” while flagellates seemed unaffected. Moreover, the genus Euplotes showed clear morphological, anatomical and behavioral aberrances. There are a few publications on freshwater meiobenthos exposed to metal pollution. Most results correspond to those outlined for the marine realm (Burton et al. 2001), with copper being most directly correlated to reductions in the species richness of meiofauna. Again harpacticoid copepods seemed notably sensitive (exception: Bryocamptus spp.). Cyclopoid copepods (especially Diacyclops spp.) and semibenthic cladocerans (Chydorus sp.) as well as water mites (especially the halacarid Porohalacarus) were more tolerant. The authors ascribe the small changes in total species richness between contaminated and uncontaminated sites not to a small impact of heavy metals, but to a replacement of susceptible species by robust ones. Hence, metal contamination in freshwater (streams) also seems to massively alter the community composition of meiofauna. In sediments from various polluted and unpolluted German rivers, nematode community structure was related to metal pollution, but also to the hydromorphology of the sites (Heininger et al. 2007). Interestingly, predatory and omnivorous genera, such as Mononchus and Tobrilus, appeared more abundantly at sites with high rather than low metal pollution (perhaps a result of reduced competition?). Insect larvae, which in streams are a dominant taxon at the boundary of meiofauna and macrofauna, display a graded and fairly predictable response to metal pollution. Since chironomids appear to be rather resistant to heavy metal pollution, they dominated (80% of all insects) at the most grossly polluted stations (Winner et al. 1980). Hence, the authors suggest that the percentage of midge larvae in samples is a useful index for assessing this type of pollution. Studies on physiological processes in meiobenthic organisms impaired by toxic metals compounds are, thus far, rare. Binding of metals in mucus excretions might be interpreted as a defence mechanism and could play a major role, but detailed studies are lacking. In the Enoplus spp. (Nematoda) the metabolically active cuticle and hypodermis are the main organs that uptake and sequester metals (Howell 1983). Considering the situation in macrobenthos with significant physiological and ecological impacts of metals (e.g., tributyltin = TBT), also in meiobenthos detailed research on metal impacts using suitable indicator species is urgently required (see Schratzberger et al. 2002b). This would help to better understand the patterns and pathways of metal pollution in meiofauna and their physiological reactions. In streams and rivers, lead, a ubiquitously present metal of environmental relevance, should also be included in meiofaunal impact studies.

8.8.2.3

Toxicity of Pesticides

Similar to heavy metals, pesticides (herbicides, fungicides and insecticides) are ubiquitous in the environment, since they are often slow degrading and are longlived. By their intensive use, not only in agriculture, they tend to accumulate in


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freshwater runoffs and coastal marine sediments. Their adsorption into the biofilms of sediment surfaces means that meiofauna provide relevant test organisms not only for acute toxicity tests but also for life-cycle toxicity, including severalgeneration bioassays. The continuous development of function-designed pesticides contrasts sharply with the few studies on their effects on marine meiofauna, as noted by Coull and Chandler (1992, see their Table IV). Many of these few studies were performed in the aqueous phase, which usually results in a lower endpoint. As with heavy metals, the tests organisms appear less sensitive in the presence of sediment, so that threshold concentrations become rather problematic. Some general features from selected marine studies will be presented here without claiming any completeness. For details of the situation in freshwater meiobenthos, the reader should consult the review by Höss et al. (2006) and references therein. Pesticide toxicity is rarely found to directly limit survival. In tests with modern pesticides it is the exception rather than the rule that exposure to environmentally relevant or recommended concentrations induces direct mortality. Atrazine, a common herbicide, has been introduced into mesocosms with estuarine sediments at concentrations near the threshold proposed by environmental authorities. Rather exceptionally, this caused a 70% population decrease in several harpacticoid species, while nematodes were on average barely affected (Bejarano et al. 2005). Usually, the damage symptoms are more concealed, as shown in the lifecycle bioassay with Amphiascus tenuiremis (Harpacticoida) using Fipronil (Cary et al. 2004). A deceptive indication of this rather obscure pollution impact is that eggproducing females often seem less sensitive to the short-term impact of PCBs and other lipophilic toxicants than males (Carman and Todaro 1996; Bejarano et al. 2005). This is probably because the noxious substances are sequestered and deposited into the lipid-rich yolk of the eggs. Under realistic concentrations these widely used insecticides caused no significant lethality, but did cause sex-specific reproductive dysfunctions. In certain mating combinations there was an 80% decrease in successful reproduction, while in other combinations the reproductive success was not impaired, but the developmental time of the eggs was delayed. When these subtle, adverse effects act over several generations the ecological consequences become disastrous and massively change the population structure. Similarly adverse effects, be it a reduction in survival or in reproductive success, have also been recorded in other studies for Fipronil (Chandler et al. 2004a), and for Chlorpyrifos (Green and Chandler 1996; Green et al. 1996). Only a few experiments with licensed pesticides lacked direct toxic effects, at least through one generation: the sedimentassociated insecticide Fenvalerate seems to bind so tightly to sediment surfaces that its impact on A. tenuiremis was negligible, at least under the conditions applied (Strawbridge et al. 1992). Species react differently to the same pollutant, an obvious fact evidenced by experiments of Bejarano and Chandler (2003), and one that should caution us about making any rash generalizations. For example, Amphiascus tenuiremis, the model harpacticoid for many bioassays, was exposed to similar concentra-

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tions of Atrazine as were various other mesocosm harpacticoids tested by Bejarano et al. (2005). Through two generations neither survival nor developmental time of Amphiascus were massively affected. However, reproductive failures by the decreasing number of hatching nauplii were recorded. These life history effects, which often increase from one generation to the next, will, under natural conditions, obliterate the population as certainly as direct mortality. The incorporation of molecular genetics into pollution studies has revealed details of intrapopulation variability that might explain different adaptive capacities along pollution gradients. Toxicants have been shown to alter regular gene expression (Schizas et al. 2001; Staton et al. 2001). Genetically (mitochondrially) different lineages within an estuarine population of Microarthridion littorale (Harpacticoida) showed different survival in toxic concentrations of the organophosphate Chlorpyrifos (see above) in the laboratory (Schizas et al. 2001). This corresponded to their prevailing field occurrence in a pollution gradient in the field (Schizas et al. 2002). These interrelations between population genetics, distribution and ecotoxicology might be a field of extreme importance in the future. Since copepods are an important food source for juvenile fish (see Sect. 9.4.2), and many pesticides are not biodegradable, the problem of pesticide bioaccumulation through the food chain is of high relevance in polluted environments. Transfer of the insecticide Guthion, an organo-phosphate, to copepod-feeding juvenile spot (Leiostomus xanthurus) resulted in a twofold concentration in the fish over the amount in the sediments (DiPinto 1996). Also, from other studies it emerges that sediment-associated particulate organic carbon is a main transfer route of lipophilic pollutants to both sediment-screening meiofauna (e.g., the copepod A. tenuiremis) or sediment-ingesting macrobenthos and fish (Wirth et al. 1994). The question of whether the fish can modify the pesticide accumulation by their metabolism or excretion remains unanswered. Considering the metabolically highly active cuticles of nematodes, their notably sediment-associated biology, and their ubiquity and abundance, more representatives of this dominant taxon need to be included in future studies on pesticide toxicity. More detailed reading: Zullini (1976); Platt et al. (1984); Heip (1980b); Heip et al. (1988); Bouquegneau and Joiris (1988); Warwick et al. (1990a); Coull and Chandler (1992) Warwick (1993); Kennedy and Jacoby (1999); Chandler (2004); Austen and Widdicombe (2006); Neher and Darby (2006); for freshwater: Burton et al 2001; Höss et al. (2006); Heininger et al. (2007).


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Box 8.9 Tiny, But Powerful: Meiofauna as Pollution Indicators What are the main characteristics that make meiofauna superior to most macrofauna when assessing ecosystem health? - Ubiquitous occurrence - Rich populations and numerous species—even in small samples—allowing for reliable statistics - High turnover of generations permits control over several generations in a short time period - Saves handling time, space and money These inherent advantages of meiofauna can provide rapid and reproducible answers about the effects of pollution. Studies with meiofauna cover all typical procedures: (1) Field studies of the polluted sites, supported by computer-based multivariate analyses. Identification at a higher taxon level does not cause much information loss and can enable convincing and quick assessments of community changes after pollution incidents. (2) Toxicity bioassays with significant test organisms can explore and quantify uptake rates within short time periods, and determine sublethal reactions to deterioration or recovery over generations. (3) New analytical, histological and genetic methods can show pollution damage in single animals. (4) Mesocosm experiments combine the advantages of sediment-based field studies with those of laboratory assays in one system. They allow for a “realistic” testing of toxic effects including concomitant bacterial uptake and metabolism, accumulations in biofilms, and combined reactions to various chemicals.

Chapter 9

Synecological Perspectives in Meiobenthology

9.1

Community Structure and Diversity

Community structure. The habitats of benthic assemblages are structured, their species richness (biodiversity, alpha-diversity) and ecological diversity regulated by the interaction of ecological and physical processes. Therefore, some basic questions are: what are those structuring factors? Why is it that sandy bottoms tend to harbor more meiofauna species than muddy bottoms? There are no generally valid answers to these questions. Many scientists contend that biotic factors such as food supply, predation, competition, and reproductive strategies are decisive; others emphasize the impact of abiotic parameters such as exposure, temperature and salinity. Of course, there are good examples of both of these positions in the ecology of meiobenthos. The conclusions depend much on the area investigated (exposed vs. sheltered habitats), the taxonomic and ecological nature of the animals studied (opportunists vs. specialists), and the methods used (life vs. fixed; sieving vs. sorting). In stable environments such as sheltered flats, nontidal seas, groundwater systems and deep-sea bottoms, biotic factors will have the stronger structuring effect on meiofauna. In extremely stable ecosystems, competitive interactions may induce instabilities in conflicting populations and ultimately cause the displacement (“amensalism”) of the less competitive species. According to the time-stability hypothesis, this means that biotope stability would reduce diversity (Rhoads and Young 1970; Woodin and Jackson 1979a,b; Warwick et al. 1986b). However, in any natural ecosystem incessant small disturbances create subtle ecological disequilibria and interfere with complete stability. Minute habitat heterogeneities create mosaics of small patches with small temporal variations. Food web interactions (predation, succession, food supply) diversify the trophic situation. Strong trophic controls favor the dominance of highly discriminative feeding types, e.g., selective deposit feeders (Warwick et al. 1990b). These oscillations and differentiations reduce competition and create a scenario that sustains highly specialized species with small populations. Usually grouped as K-strategists, their representatives live in highly interactive, patchily distributed and hierarchically structured communities. A rich pattern of biotically constrained microniches is a characteristic of these species-rich assemblages (Gray 1978). O. Giere, Meiobenthology, 2nd edition, doi: 10.1007/b106489, © Springer-Verlag Berlin Heidelberg 2009

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9 Synecological Perspectives in Meiobenthology

While small oscillations reduce the intensity of competitive displacement and tend to enhance diversity, severe disturbances negatively affect diversity (Schratzberger et al. 2002a). This is typical of physically stressed habitats such as exposed shores with rigid hydrodynamic factors e.g., tidal and oxygen regimes. These habitats harbor a meiofaunal assemblage controlled by harsh and irregular abiotic fluctuations. Also, strong seasonal and tidal variations favor meiofaunal assemblages with more homogeneous species compositions and distributions (Hulings and Gray 1976). Dominated by a few species with large populations, these low-diversity meiofauna communities contain a high percentage of opportunistic r-strategists which co-occur under reduced hierarchical and biological interactions. Among nematodes, Sabatieria pulchra is a good example of such a species (e.g., Modig and Ólafsson 1988). Naturally, there are various transitional phases and “compromises” between these rather extreme structural patterns in meiofaunal assemblages. For instance, opportunistic meiobenthic populations can become regulated by biological interactions such as facilitation, inhibition or depletion (compare with macrobenthos: Whitlatch and Zajak 1985; Connell and Slatyer 1977). Even in eulittoral areas where abiotic disturbances dominate, considerable meiofaunal diversity can be maintained provided intensity of the disturbances is not too drastic. This could explain the high turbellarian diversity in beaches on the Island of Sylt in the North Sea (Armonies 1986; Reise 1988). Diversity. Assessing biological diversity in its various aspects, from species richness to evenness or taxonomic distinctness, in an ecologically meaningful way depends much on the method of measurement, since each aspect has its own justification and limitation. A comprehensive account of the development and use of diversity estimations in benthic communities is given by Carney (2007). The characteristics and the strong and weak points of the various diversity indices are used are also discussed in Heip et al. (1988). This treatise will not detail or reiterate them. Provided the taxa have been carefully identified to a low and homogeneous taxon level (see Sect. 8.8.1), it is simple to calculate diversity indices, especially using computer programs, but their adequate interpretation remains difficult. If not correctly applied, “diversity indices hide more than they reveal” (Platt et al. 1984). Following this line of reasoning, Crisp and Mwaiseje (1989) stated that a diversity index “is most frequently used to describe examples of impoverished data collecting.” Considering the more general aspects of diversity, the effects of various interactive factors such as intensity of disturbance, pattern of distribution and life history of the species on the diversity are of prime interest here. To what extent does grazing, organic enrichment and high production affect diversity? Answers to these basic questions would allow a deeper understanding of diversity. They should be acquired preferably through experimental approaches. In an analysis of numerous data sets, Hillebrand et al. (2007) showed that grazing reduced species richness in freshwater habitats, fertilization reduced evenness, while the assemblages reacted differently in terms of species richness depending on the degree of evenness. These data from microphytobenthic assemblages need to be repeated in corresponding analyses using meiobenthos.

9.1 Community Structure and Diversity

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Ecological diversity is a sensitive and highly reactive parameter that indicates the structural pattern of meiofaunal communities. It is the interdependence of numerous factors which makes the interpretation of diversity so difficult. Meiofaunal communities often have characteristically high taxonomic diversities compared with macrofauna and microfauna. “Up to now it has ultimately not conclusively been explained which factor or factorial combination is responsible for the high diversity of meiofauna” (Herman and Heip 1988). This is in contrast to microfauna, which have “a surprisingly modest global species richness” (Finlay et al. 1996), concurring with the wide, often global distributions of species. A species list, even if difficult to achieve, represents just an initial step in assessing diversity. What we need to know is not just “which species and how many individuals?” but rather “why, which pattern, and since when?” The list cannot explain the processes and changes that control the biodiversity; it cannot answer questions about uneven distributions, density variations, and the relationship to spatial and temporal seales. Moreover, there are major pitfalls in extrapolating the diversity of local patches to regional scales, which may lead to considerable miscalculations, especially when comparing deep-sea with shallow bottom data (Lambshead and Boucher 2003). The influence of different sample sizes must be statistically minimized in large-scale diversity assays (Boucher and Lambshead 1995). Perhaps the traditional diversity indices (e.g., the Shannon–Wiener diversity H’, or rarefaction calculations, with their inherent impairment by equitability, sample size and local features, are not appropriate (see Gray 2000)? Therefore, new methods have been developed to better compare values from various studies and regions (Rose et al. 2005). Margalef’s “species richness-weighted diversity index” has been suggested as a robust index of alpha-diversity by Boucher and Lambshead (1995) for large-scale comparisons of biotopes (Boucher and Lambshead 1995). For further statistical details the reader should consult the valuable compilations by Underwood (1989) and Underwood and Chapman (2005). For evolutionary aspects, a measure of diversity has been introduced, particularly for the assessment of wide-scale patterns and their changes in them: the “taxonomic distinctness index” (Clarke and Warwick 2001; Warwick and Clarke 2001). It is based on the taxonomic relatedness of the species and demonstrates that a community of distantly related species, each with a long and their independent evolutionary lineage, has evolved in a different ecological situation and has a higher level of diversity than a community of closely related species. The measure of distinctness highlights this difference, and thus weights the diversity of a sample comprising numerous genera as more diverse compared to a sample with the same number of species, but where species all belong to just one genus.

9.1.1

Processes of Recolonization

Disturbance and recolonization. Inherently linked to diversity, disturbances can enhance, impoverish or devastate meiofauna assemblages and their diversity (intermediate disturbance hypothesis, Huston 1979). Depending on their intensity and frequency,

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disturbances create a mosaic of differently composed faunal patches depending on the state of the previous fauna and its capacity to recover and recolonize (Sect. 2.2.7). The first phases of the recolonization process will proceed rapidly, as shown experimentally (Hockin 1982a; De Troch et al. 2005b). As the suite of ecological niches becomes increasingly occupied, this process will slow down. Since the widths of niches gradually become narrower, during later phases higher specialization is needed for successful colonization. Thus, the character of the meiobenthos assemblage will gradually change from a mainly r-selected to a more K-selected one. However, there is also a spatial aspect to the colonization process: the more isolated the “defaunated island” and the larger the devastated area, the slower the process of recolonization from the surrounding undisturbed biotopes. As a result, the recolonizing meiofaunal assemblage will initially be relatively poor and low in diversity. These general features corroborate the zoogeographical “island theory,” but recolonization also depends on the degree of maturity and the complexity of the neighboring “donor” assemblages; whether they are dominated by opportunistic generalists or highly adapted specialists (Azovsky 1988). The nature and life histories of the meiofaunal groups (of various dispersive competence) also play a dominant role. Because of their active emergence, harpacticoids recover most rapidly, in spite of their physiological sensitivity (De Troch et al. 2005b; see Sect. 7.2.1). In contrast, the (usually) more “sediment-bound” nematodes have a lower potential for recolonization. However, overall the recolonization of meiofauna proceeds rather rapidly. Sherman and Coull (1980) even noted that an experimentally disturbed intertidal mudflat returned to pre-disturbance levels of meiofaunal populations within one (12 h) tidal cycle. Both copepod and nematode species composition and diversity was back to pre-disturbance values within four tidal cycles. The authors attributed this rapid recolonization to the close availability of “source” populations and to suspension and transport by tidal currents (see also Sect. 8.8 for recolonization after pollution events). Colonization rates of a few weeks to two months have also been reported from experiments in the lacustrine phytal zone (periphyton), where after wide initial fluctuations a stable meiofauna assemblage established after two months dominated by ostracods, harpacticoids and rotifers (Peters et al. 2007). However, recolonization of a devastated area with meiofauna is, to a considerable degree, also a matter of chance, since it is influenced by unpredictable events such as storms, irregular exposure, the prevalence of specific reproductive patterns in the area, seasonal and trophic conditions. These stochastic factors make it difficult to pin down the timescale for recovery after a disturbance event. The composition of the establishing meiofauna will never be exactly the same as it was before, although the general structural traits may be predictable (Rhoads and Young 1970). Large-scale, man-made disturbances (e.g., erosive forces due to climatic extremes, intense trawl-fishing and ever-increasing shore constructions, dikes and waterways) have an increasingly drastic effect on meiofaunal habitats. Maintenance dredging and habitat (beach) enhancement have become regular “remedial actions” by which huge masses of sediment are mechanically distorted. Amazingly, the meiofauna seems to recover much more quickly from intensive disturbances than the macrofauna, as field studies, micro-/mesocosm experiments and large-scale field

9.2 Community Structure and Size Spectra

377

surveys have shown (Schratzberger and Thiel 1995; Schratzberger et al. 2006; Bolam et al. 2006). Supported by meticulous statistical analyses, these works have disclosed that the impact of this mechanical sediment distortion is mitigated by the concomitant rich seeding of meiofauna in the slush water and intensive migration activities. After relatively short periods (weeks), the meiofauna assemblage recovered from an initially reduced biodiversity, while the abundance was subdued for a longer period (> 1 year) compared to the reference areas. In sandy habitats the recovery was quicker than in mud, and nematodes proved less affected than harpacticoids. In the freshly consolidated sediments, recolonization not only depended on sediment structure but also on the random settling, water transport capabilities and reproductive potentials of the taxa (see Sect. 7.2.1). More detailed reading: Rhoads and Young (1970); Woodin and Jackson (1979b); Gray (1978, 2000); Heip et al. (1988); Herman and Heip (1988); Clarke and Warwick (2001); Lambshead and Bouchet (2003); Carney 2007.

9.2

Community Structure and Size Spectra

The members of an ecosystem have body size spectra which reflect biotopical, structural and functional aspects. Hence, size spectra (the density of the fauna, mostly in biomass units, logarithmically plotted against their size) can reveal complex underlying ecological processes. Schwinghamer (1981a, 1983) showed that the marine benthos is separated not only by our formal mesh size criteria, but has an intrinsic trimodal structure when analysing the size spectrum. Consistent “troughs” delineate three discrete size groups, with the meiobenthos between the micro- and the macrobenthos (Fig. 9.1). The scrutiny of data from other marine investigations and areas has confirmed the validity of this benthic grouping. Moreover, it has resulted not only from calculations of body size or biomass, but also from assimilation efficiencies and respiration rates (Gerlach et al. 1985; Warwick et al. 1986a). It also conforms to the conclusion that in a community numerous species can co-exist when animals are of different sizes, i.e., high species richness can correlate with high abundance in different size classes (Finlay et al. 1996). The differences in size and mass scales observed when comparing organisms from benthic and pelagic habitats suggest a formative impact of the substratum. Schwinghamer’s (1981a) interpretation of the separation of the meiobenthic group makes use of is along the following line of thought. The animals must either to be small enough to live interstitially between the particles (mesobenthic meiofauna) or large and strong enough to push aside the sediment particles (endobenthic macrofauna). However, this size-related grouping does not separate macro- from meiobenthos only. Even within the meiobenthos, different animals live in different sediment types and have evolved different lifestyles (interstitial, epibenthic, burrowing, etc.) which require divergent size ranges (Tita et al. 1999). In the interstitial of sandy sediments, slender nematode species (body width class around 20 mm) with smaller individual biomasses prevail, while in muddy sediments the burrowing/pushing

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9 Synecological Perspectives in Meiobenthology 103

Biovolume (cm3 x m −2)

102 101 100 10−1 10−2 10−3

0.5 µm

2

8

32

125

500 1

2

16

32

mm Equivalent Spherical Diameter

Fig. 9.1 Size spectra of benthic fauna. The values shown are from six sampling locations in a Canadian intertidal flat combined with data derived from eight other studies; weight data from the literature have been converted into volume data. (After Schwinghamer 1981a)

nematodes are broader (body width class around 35–45 mm) and heavier. Associated with these morphotypes are different feeding groups (microvores vs. epigrowth or predators) and metabolic types. The higher metabolic or respiratory ratios of the microvores in sands corresponds to their relatively long guts and indicate a different, lower-quality food spectrum. Conversely, the mud-dwelling larger species with shorter guts had lower metabolic ratios adapted to high-quality food (see also data from Kennedy 1994a for comparison; see Fig. 5.22). However, can a differentiation of meiobenthic size spectra by sediment type explain the trough towards the microbenthos? It has been argued that the underlying factors are of a more biological and evolutionary nature. Benthic assemblages are structured by various biological characteristics such as feeding behavior and life history modes. These, in turn, are affected by the spatial and temporal conditions of the environment. Following the principle of competitive displacement, Warwick (1989) and Warwick et al. (1986a) maintain that competition with the other benthic groups causes a delineation not only in size and biomass but probably also in a whole array of biological characteristics such as metabolic efficiency (see also Warwick et al. 2006). The demarcation towards the Protista (microbenthos) may be because the protists are mostly hapto-sessile organisms that adhere to sediment particles, while most meiobenthos are vagile. The numerous differentiating features are summarized in Table 9.1. It appears that the diverging size spectra result from mutually structuring effects that have evolved through biological interactions between larger and smaller


379

Table 9.1 A biological delineation of meiobenthos vs. macrobenthos (Warwick 1984) Animal weight

< 45 mg

> 45 mg

Development Dispersal Generation time Reproduction Growth Trophic type

Direct, all benthic Mainly as adults Less than one year Mostly semelparous Attain an asymptotic final size Often selective particle feeders

Mobility

Motile

With planktonic stages As planktonic larvae More than one year Mostly iteroparous Life-long permanent growth Often non-selective particle feeders Also sedentary

benthos. As a consequence, today, the different benthic groups occupy different ecological niches, thus avoiding competition. This principal becomes evident in larvae. As long as larvae of macrobenthic species are of meiofaunal size, most of them occur as meroplankton in the open water. They do not settle prior to reaching an average size beyond the main prey size of the meiobenthos. Thus, they avoid contact with the meiobenthos, with its direct competition and predation. According to Warwick this life history feature is mainly responsible for the size separation of the benthic fauna. Consequently, in a diagram of size structure, the size range of meroplanktonic larvae of the macrobenthos fits exactly in the trough between the benthic meio- and macrofauna (Fig. 9.2). However, there are counter-arguments. If evolutionary pressures caused an ecological differentiation into separate size groups, there would be little interaction and competition between meio- and macrobenthos today. But the evidence contradicts this notion (Coull and Bell 1979; Bell and Coull 1980; Reise 1985; Watzin 1986). There is, indeed, a high rate of interactive effects (see Sect. 9.4.2) between temporary and permanent meiofauna of the same size class, which probably has a strong structuring impact on the macro- and meiobenthos. Following the “planktonic larva hypothesis,” benthic size spectra from polar seas, where macrofauna rarely have planktonic larvae, should have an unimodal, continuous curve without separating troughs, because larval “escape” from the benthal (separating the size spectrum) does rarely occur. However, a study with Warwick as a coauthor (Kendall et al. 1997) on polar benthic communities (Spitsbergen and the Barents Sea) showed a well-developed bimodal curve of size spectra with a trough between the meio- and the macrobenthos. The low endemism in the Arctic, with many invasive non-Arctic species and their planktonic larvae, was believed to have modified the pattern of adult–larval interactions and altered the competitive control between the meiobenthos and macrobenthos. A parallel investigation including larval plankton is needed to qualify this interpretation by Kendall et al. (1997). Burkovsky et al. (1994) in their study on the Arctic benthos of the White Sea shores also confirmed the division into micro-, meio- and macrobenthos. These authors interpreted the size separation as being a result of fundamental biological parameters such as generation time and locomotory activity. These are believed to create a hierarchical habitat heterogeneity in which the different groups perceive


No of species

Proportion of species

380 0.1

Northumberland

adults

0.05

0 Polychaete larvae

3 0 4

Northumberland larvae

0 2

6

10

14

18

22

26 30 weight class

Fig. 9.2 The size spectrum of benthic fauna in relation to that of planktonic larvae in the Northumberland area (Great Britain). (Warwick 1989)

their environment at different grades of resolution: related to their own body volume, the relative density of microfauna or meiofauna in a given volume of substratum is much lower than that of macrofauna. Similarly, in a given astronomical time period (e.g., one year), a ciliate has many more generations than a nematode or a crab. Hence, the “organismic” space and time of meiofauna is much more extended than that of macrofauna (see Fig. 9.3). Each of the three size categories has its own environmental perception, with differing chorological and chronological scales. Correspondingly Stead et al. (2003) concluded from the different responses of stream benthos to environmental factors that freshwater meiofauna and macrofauna assemblages live at different spatial and temporal scales, thus perceiving the environment “with a different grain.” In the brackish Baltic Sea, several studies revealed a complex picture of partly contradictory size spectra. Clues are probably low endemism, changing impacts of stress factors such as hypoxia, and the regionally differing invasions of non-domestic species in different parts of the Baltic. In a study of benthic communities from the southern Baltic Sea (Gulf of Gdansk), two disparate size groups of meio- and macrobenthos emerged, separated by a (fairly low) trough (Drgas et al. 1998). Although the authors conclude that biomass size spectra represent a “unifying concept in community ecology,” various other sites in the Eastern Baltic (Swedish Askö area) did not display this bimodal benthic size spectrum (Duplisea and Drgas 1999). For the lacustrine zoobenthos of Mirror Lake (USA), Strayer (1986) calculated a unimodal curve without any separation between meio- and macrofauna. He attributed this to the numerous oligochaetes and chironomid larvae, characteristic members of the freshwater meiobenthos; their size spectra exactly fill the trough between the typical meio- and macrobenthos. This would corroborate Warwick’s (1989) arguments: while many factors in lakes are comparable to those in the


381

1024 512

CILIATES Year in generation periods

256 128 64 32 16 8

NEMATODES 4 2 1

MACROBENTHOS

10

102

103

104

105

106

Free space for each individual (related to body volume)

Fig. 9.3 “Organismic” time and space for various faunal size categories; for details see text. (After Burkovsky et al. 1994)

marine realm, the reproductive biology of the lacustrine benthos is essentially different, since planktonic larvae are largely lacking. Additionally, in freshwater much of the temporary meiofauna, such as many insect larvae, leave the aquatic biota after metamorphosis. Lack of direct competition prevented the evolution of disparate size spectra in lacustrine systems which resulted in a unimodal, continuous curve. Thus, the competitive situation between meiofauna and macrofauna in freshwater is fundamentally different from that in the marine sites studied by Schwinghamer (1981a, 1983) and Warwick (1984, 1989). However, size spectra analyses from other freshwater habitats do not conform to this idea. From a Piedmont stream (USA), Poff et al. (1993) revealed a clearly trimodal structure for metazoan size: oligochaetes and microcrustaceans provided the main meiobenthos, an introduced bivalve was the macrobenthic component, and fish represented a separate third group. The authors contend that this diverging structure, in contrast to the lacustrine studies by Strayer (1986), is because of their comprehensive sampling across all habitat types and faunal size ranges. However, the particular faunal composition of this stream, which is influenced by many local factors, may not be valid for all types of freshwater habitats. Woodward et al. (2005) interpreted marked size disparities in the benthos under trophic aspects. They suggested that different size groups represent fairly

382


independent “sub-webs” with a relatively low degree of trophic connection. Within these different compartments the larger size spectra are more severely affected by environmental perturbations, a notion confirmed by the different reactions of macro- and meiobenthos (Alongi 1985). Even though the factors governing the pattern of size spectra in benthic assemblages are, as yet, contradictory or unclear and apparently different in different ecosystems, the relatively straightforward parameter of “size” seems to have an ecological bearing beyond just the biological definition of meiobenthic size delineations. Size-spectral analyses, therefore, find increasing use in (meio)benthic studies on the energy flow through the system (see below). More detailed reading: Kennedy (1994a); Warwick et al. (1986a); Finlay et al. (1996b); Stead et al. (2003); Sheldon (2005); Woodward (2005).

Box 9.1 Diversity and Size Spectra: Indices of Community Structure The diversity and the size range of meiobenthic species are more than just abstract figures. They tell us about the life history, the nature of interactions with other organisms, and about the environmental stress status of the community-all of them parameters of high structural relevance. A biotope with high meiobenthic species richness will have a complex physical architecture, and favorable chemical and trophic conditions. The wealth of positive biotic interactions will counterbalance the impact of negative stress factors. Because of the minute sizes that define the meiobenthic world, our perception of these structural aspects is minimal; we need indicators to envisage, measure and compare them. These indicators can reveal that seemingly uniform sands or the monotonous deep-sea floor represent “havens” for meiobenthos, while exposed shores or organic-rich muds often are meiofaunal “deserts.” Diversity indices and size-related spectra reflect the complexity and hierarchy of community interactions, the ecological resilience and the colonization potential. However, the multitude of influencing factors makes them problematic. Their interpretation requires an assessment of the environmental situation, and they cannot substitute for good knowledge of the community composition. Characteristics of meiofaunal communities and their differentiation from other benthic communities are also reflected in the size spectra. Whether based on biomass, respiration or other size-related quantities, the meiobenthic range is often a clearly separated cluster in the benthic spectrum. As yet, the factors contributing to this pattern are not fully understood, but substrate and food interactions seem to play a major role. Despite numerous suggestions, why this pattern does not emerge from benthic studies of all ecosystems, marine and limnetic alike, is also unclear. However, the important message remains: there are biological and ecological characteristics differentiating meiofauna aside from their mesh size limits.

9.3 The Meiobenthos in the Benthic Energy Flow

9.3 9.3.1

383

The Meiobenthos in the Benthic Energy Flow General Considerations

The ecological role of meiofauna in the benthic ecosystem can only be assessed by measuring the flow of energy, from uptake to excretion and from reproduction to mortality. Static parameters such as abundance and biomass are only momentary reflections of this flow. Compared to the macrobenthos, assessments of production and energy flow in the meiobenthos are particularly important since the relevance of small animals lies in their high dynamics and turnover. In contrast to the macrobenthos, metabolic rates of single meiobenthic animals are difficult to measure. The energy budgets (Crisp 1984) are usually calculated using the summarizing parameters P = C − R − E (where P = production; C= consumption; R= respiration; E= excretion as feces or urine). The relations of meiobenthos to other faunal elements and its contribution to the energy flow through the benthic ecosystem can be assessed by measuring its population density (abundance, biomass), production and annual turnover. A description and critical evaluation of pertinent methods and their applicability, together with a detailed report on their inherent problems, is given by Feller and Warwick (1988) and Van der Meer et al. (2005). In addition, the accounts by Banse and Mosher (1980; mainly for macrofauna), Gray (1981), De Bovée (1987) and Warwick and Clarke (1993a) should be consulted. Compilations for freshwater meiobenthos in lakes can be found in Plante and Downing (1989) and Bergtold and Traunspurger (2005). The calculation of production in streams is discussed in Stead et al. (2005). A comprehensive compilation of benthic life history data, energy flow and pertinent literature can also be found in Brey (1990) and his Virtual Handbook (Brey 2001). With the focus on macrobenthos, this also presents numerous meiofaunal results, including conversion tables with search links to specific taxa. Therefore, except for some general aspects, methods will not be considered here in detail. The assessment of biomass from meiofaunal wet weight (wwt, or better “wet mass”) is difficult because of the inherently large range of error. Hence, biomass is mostly calculated from abundance using conversion factors (see Table 9.2). A nondestructive, semi-automatic method for calculating biomass applies digital microphotography and analytical computer graphics and allows fast and individual determinations of body volume from which mass values can be derived. The results, tested on thousands of nematodes and harpacticoids, did not differ much from tedious gravimetrical measurements (Baguley et al. 2004). However, biomass values at a given time and for a given area (“standing stock”) remain of limited ecological value if not connected with life history data which allow for extrapolations of the energy flow. Gerlach (1971) pointed out that meiofaunal biomass comprises just 3% of the overall biomass; however, the nutritional share of meiofauna within the food web is ~15%. The production, “the gain in organic substance per unit of time,” is a more relevant value when considering the ecological role of meiofauna. When calculating annual production, the P/B ratio

384


Table 9.2 Calculations of weight and derived parameters of meiofauna obtained by applying biometric conversion factors (compiled from Feller and Warwick 1988; Friedrich et al. 1996; Baguley et al. 2004; and other authors as indicated) Taxon Calculation Notes Reference A. Volume from length and widtha Nematodes Harpacticoids Nauplii Ostracods Turbellarians Polychaetes Oligochaetes Tardigrades Halacarids Kinorhynchs Gastrotrichs Isopods

L × W2 × C

Rachor (1975) (modified) C = 530 C = 230–560b C = 360 C = 450 C = 550 C = 530 C = 530 C = 614 C = 399 C = 295 C = 550 C = 230

B. Wet weight (wwt) from volume Meiofauna, most taxa V (nl) × 1.13* Nematodes + harpacticoids V (nl) × 1.064* Nematodes (p r2 L × 1.13*) − 10% Ciliates, alive p L W2 × 0.083 Ciliates, fixed p L W2 × 0.083 × 2.5 Rotifers 0.26 L W2 × 1.028* C. Dry weight (dwt) from wwt Nematodes Factor 0.25 Factor 0.20 Factor 0.15 Harpacticoids Factor 0.225 Factor 0.203 Nematodes + harpacticoids Factor 0.215 Nauplii Factor 0.225 Rotifers Factor 0.1 Meiofauna Factor 0.15

Wieser (1960) Baguley et al. (2004) Riemann et al. (1990) Friedrich et al. (1996) Friedrich et al. (1996)

Freshwater Mean value

D. Ash-free dry weight (adwt) or carbon content (C) from dwt Nematodes Factor 0.47 Factor 0.51 Harpacticoids Factor 0.46 Nauplii Factor 0.46 Rotifers Factor 0.1 E. Weight from length Nematodes

log10dwt = 2.47log10L −7.97

F. Carbon content from volume (V) Rotifers 0.26 L W2 × 0.08 G. Carbon content from wet weight Meiofauna Factor 0.116 Nematodes

Factor 0.124

Wieser (1960) Myers (1967) Schiemer (1982) Friedrich et al. (1996) Baguley et al. (2004) Banse (1982) De Bovée (1987) Baguley et al. (2004) Baguley et al. (2004) Friedrich et al. (1996) De Bovée (1987)

Friedrich et al. (1996) De Bovée and Labat (1993) Jensen (1984)

Note: L, length; W, width; r, radius; V, volume; C, factor. b Harpacticoid conversion factors depend on shape: pear-shaped, 400; semicylindrical, 560; depressed, 230 (Warwick and Gee 1984). *This value is the specific gravity a


385

becomes important, especially in the often short-lived meiofauna. This ratio expresses the rate of turnover in a given time, and thus integrates over the different biomass and lifetime data of the various taxa (Table 9.3). Production and P/B ratio are, however, difficult to calculate since they require life-table parameters such as fecundity, mortality, generation time, and other data on population dynamics. Especially for meiobenthos, life-table parameters must still be extrapolated from only a few species studied in the laboratory. Moreover, life history cannot be considered a static process. For individuals of the same species, these parameters vary with environmental conditions and food supply (see Vranken et al. 1988b, for nematodes), and between species this variability is greater. Even in common species, insufficient life history data present a serious barrier to accurate quantitative calculations. “A great deal more data is needed before it becomes possible to refine the relationships and to establish … equations according to taxonomical and ecological groups” (Ceccherelli and Mistri 1991). The more detailed the data we have on single species, the more reliable our compilations become, making them more useful for testable ecological hypotheses and predictions. Measuring the annual production requires knowledge of the annual number of generations. This varies considerably among taxa (Table 9.4), and in many populations, growth of distinct generations (= cohorts) is not identifiable since reproduction is

Table 9.3 Annual P/B ratios calculated for some common meiobenthic species (Heip et al. 1985b; Heip 1995) Taxon P/B ratio y−1 Harpacticoida Huntemannia jadensis Tachidius discipes Microarthridion litorale Paronychocamptus nanus Canuella perplexa

3.8 9.3 18.0 24.5 11

Nematoda Oncholaimus oxyuris Paracanthonchus caecus Monhystrella parelegantula Chromadora nudicapitata

3–6 10.4 18.2 31.4

Ostracoda Cyprideis torosa

2.7

Table 9.4 Annual number of generations for some common nematode species (Heip et al. 1985a) Taxon Generations 1.6 Oncholaimus oxyuris 5 Monhystrella parelegantula 10 Rhabidits marina 13 Chromadorina germanica 15 Monhystera denticulata 17 Diplolaimelloides brucei

386


continuous and the generations overlap. The high variability in life history parameters results in inaccurate data when generalized for a large taxon like nematodes, harpacticoids, or even meiofauna. So far, we have often been forced to extrapolate our calculations of production rates from the few meiofaunal species that have been successfully cultured through generations. Life history studies have concentrated on representatives of the two most important meiobenthic taxa ecologically, harpacticoids and nematodes. Life history data are often calculated in context with toxicity testing and food web analyses. The main problem in obtaining reliable life history data for different species is twofold: (1) laboratory conditions may differ from natural field conditions, so we need field-generated life tables; (2) assessing life history data is an extremely tedious task, but it is still rarely considered a “modern” science that would generate financial support. Among other harpacticoid copepods, detailed autecological analyses of growth and production exist for Canuella perplexa. Using this species, Ceccherelli and Mistri (1991) demonstrated that direct measurements yielded results that were considerably different from those obtained through indirect calculations, which greatly underestimated production. Other harpacticoid species whose production and population development have been followed over time are: a decade-long study on Parastenhelia megarostrum from New Zealand (Hicks 1985), and a 15-month study on Enhydrosoma propinquum, Microarthidion littorale and Stenhelia bifidia in South Carolina, USA (Fleeger 1979). Also, Fleeger and Palmer (1982) and Morris and Coull (1992) have focused on the common harpacticoid Microarthridion littorale. The latter authors found a remarkable dominance of the naupliar stock, whose large interannual variations (due to predation and natural mortality) determined the overall population fate of the species. Morphologically closely related Tisbe species have been studied in detail, revealing differences in growth and reproduction (Battaglia 1957; Gaudy and Guerin 1977; Abu Rezg et al. 1997). The extensive growth and short generation times of the remarkable harpacticoid Drescheriella glacialis from Antarctic sea ice documented specific traits that were interpreted as adaptations to the low ambient temperatures (Bergmans et al. 1991). Many harpacticoid life tables have revealed the high sensitivities of reproductive and larval stages to toxicants (Strawbridge et al. 1992; Chandler et al. 2004a,b). Corresponding work on nematodes includes detailed studies on Chromadorina germanica (Tietjen and Lee 1977), Chromadorita tenuis (Jensen 1983) and Monhystera disjuncta (Vranken et al. 1988b). The number of species capable of being cultivated through several generations is steadily increasing. Numerous freshwater species have been studied intensively for their life history data; again the driving force is the use of test species for the impact of pollution (see compilation by Bergtold and Traunspurger 2006). In order to elude the laborious direct measurements of life history data, more generalized approaches have been developed which summarize existing data. Based on abundance, the values for wet and dry weight, carbon and energy content can be calculated applying conversion factors (Brey 1987, 1990; Ricciardi and Bourget 1998). Another approach is to lump individual data and calculate mean values (De Bovée and Labat 1993). When measuring the rate of respiration (semi-automatically), the


387

energy consumption can be assessed (Baguley et al. 2004) or it can be calculated from body volume, which, in turn, can be derived from size or weight data (see Table 9.2). Regarding the different methodological approaches of the underlying studies and the different faunal properties that exist in the various sites, results and formulae obtained from these reductive and generalized compilations should not be overestimated. “Generalizations remain useful but also dangerous tools” (Vranken et al. 1988b). Most energy-flux diagrams which include meiobenthos and contain quantitative figures are not as accurate as the figures insinuate. Often calculated to the fourth digit after the decimal point, many of them are not mathematically meaningful and are probably best considered rough estimates with a rather loose relation to reality. Existing models are probably more useful for qualitative and comparative purposes than for retrieving realistic values of energy metabolized.

9.3.2

Assessing Production: Abundance, Biomass, P/B Ratio, Respiration

Following the general outlines above, we now provide some examples of how to assess the various parameters required to estimate production. They simultaneously illustrate the extreme variability involved and some of the inherent pitfalls. Since the (marine) meiofauna in almost all habitats is dominated by nematodes, the abundance values obtained for nematodes are often representative of the whole community and thus allow for some initial generalizations (see Figs. 5.15a,b; Sect. 5.6.1). This also applies to biomass: nematodes represent >90% of all living biomass in intertidal salt marshes, and even in the subtidal this figure reaches almost 80% (Sikora et al. 1977). 9.3.2.1 Abundance, density As shown in Table 9.5 the figures for meiofaunal density vary greatly, and authors that give average values should be aware of this difficulty. The review by McIntyre (1969) reports a range of between 30 and 30,000 ind. 10 cm−2. If 1,000–2,000 ind. 10 cm−2 can be assumed to be an average value integrated over all habitats (Coull and Bell 1979), the meiofauna would exceed the macrofauna in abundance by twoto threefold. Particularly high values for meiofauna (sometimes ten times greater than this range) have been recorded from silty mud and fine sand in tidal lagoons and flats (for harpacticoids, see the compilation in Table 25 of Heip et al. 1995). As sublittoral depths these extreme densities become reduced, and at greater depths they rarely exceed 2,000 ind. 10 cm−2. 9.3.2.2 Biomass With general values of about 1–2 g dwt m−2 and peaks at around 5 g (Coull and Bell 1979), the meiofauna of shallow littoral bottoms usually attain less than 10% of the

388

9 Synecological Perspectives in Meiobenthology Table 9.5 Meiofauna abundances from various habitats (compiled from McIntyre 1969 and some other authors) Habitat and locality Abundance (ind. 10 cm−2) Sandy beaches, tidal: West coast of Scotland West coast of Denmark North Sea shore in Germany Indian Ocean shores Australian east coast European beaches Arctic beach

1,000–4,000 750–1,900 200–800 1,000–10,000 ~470 360–4300 250–480

Sandy beaches, atidal: East coast of Sweden Kattegat (low tides)

200–1,000 ~500

Muddy to silty tidal sand, tidal flats: Sylt, North Sea Lynher Estuary, England Coast of Netherlands Vellar Estuary, India Swartkop Estuary, S. Africa Gironde Estuary, France European estuaries Mud, North Inlet, S. Carolina Sand, North Inlet, S. Carolina West coast of Canada Alaskan flat

Several thousand,

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