Glycobiology is the study of the structure, biosynthesis, biology, and evolution of saccharides (sugar chains or glycans) that are widely distributed in nature, in all life-forms. Glycobiology is a rapidly growing field in the natural sciences, with broad relevance to many areas of basic research, biomedicine, and biotechnology. The field includes the chemistry of carbohydrates, the enzymology of glycan formation and degradation, the recognition of glycans by specific proteins, roles of glycans in complex biological systems, and glycan analysis or manipulation by various techniques. The fourth edition of this primary textbook in the field continues in the prior tradition to provide a basic overview of Glycobiology, directed toward the advanced undergraduate or the beginning graduate-level student of molecular and cellular biology and biomedicine. This edition includes a broader focus on all lineages of life-forms; a wider range of topics, from biology and medicine to chemistry, bioenergy, and materials science; a more diverse and international group of contributing authors with expertise in specific areas; further expansion of the monosaccharide symbol nomenclature for representation of glycans; and a greater attention to informatics, with relevance to exploring the glycome in relation to the genome, transcriptome, proteome, lipidome, and metabolome.

Contents

• Foreword
• Preface
• Praise for the Previous Editions of Essentials of Glycobiology
• Contributors
• Editors of Earlier Editions
• Consultant Reviewers
• Classic Books and Monographs
• Abbreviations
• General Principles
  • 1. Historical Background and Overview
    Ajit Varki and Stuart Kornfeld.
  • 2. Monosaccharide Diversity
    Peter H. Seeberger.
  • 3. Oligosaccharides and Polysaccharides
    Carlito B. Lebrilla, Jian Liu, Göran Widmalm, and James H. Prestegard.
  • 4. Cellular Organization of Glycosylation
    Karen J. Colley, Ajit Varki, Robert S. Haltiwanger, and Taroh Kinoshita.
  • 5. Glycosylation Precursors
    Hudson H. Freeze, Michael Boyce, Natasha E. Zachara, Gerald W. Hart, and Ronald L. Schnaar.
  • 6. Glycosyltransferases and Glycan-Processing Enzymes
    James M. Rini, Kelley W. Moremen, Benjamin G. Davis, and Jeffrey D. Esko.
  • 7. Biological Functions of Glycans
    Pascal Gagneux, Thierry Hennet, and Ajit Varki.
  • 8. A Genomic View of Glycobiology
    Nicolas Terrapon, Bernard Henrissat, Kiyoko F. Aoki-Kinoshita, Avadhesha Surolia, and Pamela Stanley.
• Structure and Biosynthesis
  • 9. N-Glycans
    Pamela Stanley, Kelley W. Moremen, Nathan E. Lewis, Naoyuki Taniguchi, and Markus Aebi.
  • 10. O-GalNAc Glycans
    Inka Brockhausen, Hans H. Wandall, Kelly G. Ten Hagen, and Pamela Stanley.
  • 11. Glycosphingolipids
    Ronald L. Schnaar, Roger Sandhoff, Michael Tiemeyer, and Taroh Kinoshita.
  • 12. Glycosylphosphatidylinositol Anchors
    Sneha Sudha Komath, Morihisa Fujita, Gerald W. Hart, Michael A.J. Ferguson, and Taroh Kinoshita.
  • 13. Other Classes of Eukaryotic Glycans
    Robert S. Haltiwanger, Lance Wells, Hudson H. Freeze, Hamed Jafar-Nejad, Tetsuya Okajima, and Pamela Stanley.
  • 14. Structures Common to Different Glycans
    Pamela Stanley, Manfred Wuhrer, Gordon Lauc, Sean R. Stowell, and Richard D. Cummings.
  • 15. Sialic Acids and Other Nonulosonic Acids
    Amanda L. Lewis, Xi Chen, Ronald L. Schnaar, and Ajit Varki.
  • 16. Hyaluronan
    Melanie Simpson, Liliana Schaefer, Vincent Hascall, and Jeffrey D. Esko.
  • 17. Proteoglycans and Sulfated Glycosaminoglycans
    Catherine L.R. Merry, Ulf Lindahl, John Couchman, and Jeffrey D. Esko.
  • 18. Nucleocytoplasmic Glycosylation
    Christopher M. West, Chad Slawson, Natasha E. Zachara, and Gerald W. Hart.
  • 19. The O-GlcNAc Modification
    Natasha E. Zachara, Yoshihiro Akimoto, Michael Boyce, and Gerald W. Hart.
• Glycans in Evolution and Development
  • 20. Evolution of Glycan Diversity
    Pascal Gagneux, Vladislav Panin, Thierry Hennet, Markus Aebi, and Ajit Varki.
  • 21. Eubacteria
    Chris Whitfield, Christine M. Szymanski, Amanda L. Lewis, and Markus Aebi.
  • 22. Archaea
    Benjamin H. Meyer, Sonja-Verena Albers, Jerry Eichler, and Markus Aebi.
  • 23. Fungi
    Françoise H. Routier, Tamara L. Doering, Richard D. Cummings, and Markus Aebi.
  • 24. Viridiplantae and Algae
    Malcolm A. O'Neill, Alan G. Darvill, Marilynn E. Etzler, Debra Mohnen, Serge Perez, Jenny C. Mortimer, and Markus Pauly.
  • 25. Nematoda
    Iain B.H. Wilson, Katharina Paschinger, Richard D. Cummings, and Markus Aebi.
  • 26. Arthropoda
    Kelly G. Ten Hagen, Hiroshi Nakato, Michael Tiemeyer, and Jeffrey D. Esko.
  • 27. Deuterostomes
    Michael Pierce, Iain B.H. Wilson, Katharina Paschinger, and Pamela Stanley.
• Glycan-Binding Proteins
  • 28. Discovery and Classification of Glycan-Binding Proteins
    Maureen E. Taylor, Kurt Drickamer, Anne Imberty, Yvette van Kooyk, Ronald L. Schnaar, Marilynn E. Etzler, and Ajit Varki.
  • 29. Principles of Glycan Recognition
    Richard D. Cummings, Ronald L. Schnaar, Jeffrey D. Esko, Robert J. Woods, Kurt Drickamer, and Maureen E. Taylor.
  • 30. Structural Biology of Glycan Recognition
    Jesús Angulo, Jochen Zimmer, Anne Imberty, and James H. Prestegard.
  • 31. R-Type Lectins
    Richard D. Cummings, Ronald L. Schnaar, and Yasuhiro Ozeki.
  • 32. L-Type Lectins
    Richard D. Cummings, Marilynn E. Etzler, T.N.C. Ramya, Koichi Kato, Gabriel A. Rabinovich, and Avadhesha Surolia.
  • 33. P-Type Lectins
    Nancy Dahms, Thomas Braulke, and Ajit Varki.
  • 34. C-Type Lectins
    Richard D. Cummings, Elise Chiffoleau, Yvette van Kooyk, and Rodger P. McEver.
  • 35. I-Type Lectins
    Takashi Angata, Stephan von Gunten, Ronald L. Schnaar, and Ajit Varki.
  • 36. Galectins
    Richard D. Cummings, Fu-Tong Liu, Gabriel A. Rabinovich, Sean R. Stowell, and Gerardo R. Vasta.
  • 37. Microbial Lectins: Hemagglutinins, Adhesins, and Toxins
    Amanda L. Lewis, Jennifer J. Kohler, and Markus Aebi.
  • 38. Proteins That Bind Sulfated Glycosaminoglycans
    Ding Xu, James H. Prestegard, Robert J. Linhardt, and Jeffrey D. Esko.
• Glycans in Physiology and Disease
  • 39. Glycans in Glycoprotein Quality Control
    Tadashi Suzuki, Richard D. Cummings, Markus Aebi, and Armando Parodi.
  • 40. Free Glycans as Bioactive Molecules
    Antonio Molina, Malcolm A. O'Neill, Alan G. Darvill, Marilynn E. Etzler, Debra Mohnen, Michael G. Hahn, and Jeffrey D. Esko.
  • 41. Glycans in Systemic Physiology
    Robert Sackstein, Sean R. Stowell, Karin M. Hoffmeister, Hudson H. Freeze, and Ajit Varki.
  • 42. Bacterial and Viral Infections
    Amanda L. Lewis, Christine M. Szymanski, Ronald L. Schnaar, and Markus Aebi.
  • 43. Parasitic Infections
    Richard D. Cummings, Cornelis H. Hokke, and Stuart M. Haslam.
  • 44. Genetic Disorders of Glycan Degradation
    Hudson H. Freeze, Richard Steet, Tadashi Suzuki, Taroh Kinoshita, and Ronald L. Schnaar.
  • 45. Congenital Disorders of Glycosylation
    Dirk J. Lefeber, Hudson H. Freeze, Richard Steet, and Taroh Kinoshita.
  • 46. Glycans in Acquired Human Diseases
    Robert Sackstein, Karin M. Hoffmeister, Sean R. Stowell, Taroh Kinoshita, Ajit Varki, and Hudson H. Freeze.
  • 47. Glycosylation Changes in Cancer
    Susan L. Bellis, Celso A. Reis, Ajit Varki, Reiji Kannagi, and Pamela Stanley.
• Methods and Applications
  • 48. Glycan-Recognizing Probes as Tools
    Richard D. Cummings, Marilyn Etzler, Michael G. Hahn, Alan Darvill, Kamil Godula, Robert J. Woods, and Lara K. Mahal.
  • 49. Glycosylation Mutants of Cultured Mammalian Cells
    Jeffrey D. Esko, Hans H. Wandall, and Pamela Stanley.
  • 50. Structural Analysis of Glycans
    Stuart M. Haslam, Darón I. Freedberg, Barbara Mulloy, Anne Dell, Pamela Stanley, and James H. Prestegard.
  • 51. Glycomics and Glycoproteomics
    Pauline M. Rudd, Niclas G. Karlsson, Kay-Hooi Khoo, Morten Thaysen-Andersen, Lance Wells, and Nicolle H. Packer.
  • 52. Glycoinformatics
    Kiyoko F. Aoki-Kinoshita, Matthew P. Campbell, Frederique Lisacek, Sriram Neelamegham, William S. York, and Nicolle H. Packer.
  • 53. Chemical Synthesis of Glycans and Glycoconjugates
    Peter H. Seeberger and Hermen S. Overkleeft.
  • 54. Chemoenzymatic Synthesis of Glycans and Glycoconjugates
    Hermen S. Overkleeft and Peter H. Seeberger.
  • 55. Chemical Tools for Inhibiting Glycosylation
    David J. Vocadlo, Todd L. Lowary, Carolyn R. Bertozzi, Ronald L. Schnaar, and Jeffrey D. Esko.
  • 56. Glycosylation Engineering
    Henrik Clausen, Hans H. Wandall, Matthew P. DeLisa, Pamela Stanley, and Ronald L. Schnaar.
  • 57. Glycans in Biotechnology and the Pharmaceutical Industry
    Peter H. Seeberger, Darón I. Freedberg, and Richard D. Cummings.
  • 58. Glycans in Nanotechnology
    Martina Delbianco, Benjamin G. Davis, and Peter H. Seeberger.
  • 59. Glycans in Bioenergy and Materials Science
    Malcolm A. O'Neill, Robert J. Moon, William S. York, Alan G. Darvill, Kamil Godula, Breeanna Urbanowicz, and Debra Mohnen.
  • 60. Future Directions in Glycosciences
    Gerald W. Hart and Ajit Varki.
• Online Appendix 1A. Some Important Milestones in the History of Glycobiology
  Ajit Varki and Stuart Kornfeld.
• Online Appendix 1B. Symbol Nomenclature for Glycans (SNFG)
• Online Appendix 12A. Examples of GPI-Anchored Proteins
  Sneha Sudha Komath, Morihisa Fujita, Gerald W Hart, Michael AJ Ferguson, and Taroh Kinoshita.
• Online Appendix 12B-I. Complex and Varied Structures of Glycosylphosphatidylinositol (GPI) Anchors
  Sneha Sudha Komath, Morihisa Fujita, Gerald W Hart, Michael AJ Ferguson, and Taroh Kinoshita.
• Online Appendix 12B-II. Complex and Varied Structures of Glycosylphosphatidylinositol (GPI) Anchors
  Sneha Sudha Komath, Morihisa Fujita, Gerald W Hart, Michael AJ Ferguson, and Taroh Kinoshita.
• Online Appendix 12B-III. Complex and Varied Structures of Glycosylphosphatidylinositol (GPI) Anchors
  Sneha Sudha Komath, Morihisa Fujita, Gerald W Hart, Michael AJ Ferguson, and Taroh Kinoshita.
• Online Appendix 12B-IV. Complex and Varied Structures of Glycosylphosphatidylinositol (GPI) Anchors
  Sneha Sudha Komath, Morihisa Fujita, Gerald W Hart, Michael AJ Ferguson, and Taroh Kinoshita.
• Online Appendix 12B-V. Complex and Varied Structures of Glycosylphosphatidylinositol (GPI) Anchors
  Sneha Sudha Komath, Morihisa Fujita, Gerald W Hart, Michael AJ Ferguson, and Taroh Kinoshita.
• Online Appendix 12C updated. The Chemistry of GPI Anchors
  Sneha Sudha Komath, Morihisa Fujita, Gerald W Hart, Michael AJ Ferguson, and Taroh Kinoshita.
• Online Appendix 12D. Species-Specific Inhibitors of the GPI Biosynthetic Pathway
  Sneha Sudha Komath, Morihisa Fujita, Gerald W Hart, Michael AJ Ferguson, and Taroh Kinoshita.
• Online Appendix 27A. Glycosylation Genes Essential for Mouse Embryonic Development
  Michael Pierce, Pamela Stanley, and Morihisa Fujita.
• Online Appendix 28A. Comparison of Two Major Classes of Glycan-Binding Proteins
  Maureen E Taylor, Kurt Drickamer, Anne Imberty, Yvette van Kooyk, Ronald L Schnaar, Marilynn E Etzler, and Ajit Varki.
• Online Appendix 38A. Molecular Dynamic Simulations
  Ding Xu, Jeffrey D Esko, James H Prestegard, and Robert J Linhardt.
• Online Appendix 45A. Known Human Glycosylation Disorders
  Dirk Lefeber, Hudson H. Freeze, Richard Steet, and Taroh Kinoshita.
• Online Appendix 52A. Organizations and Publications Adopting SNFG
  Nicolle Packer.
• Glossary
• Study Guide
• Errata

Printed in the United States of America

Library of Congress Control Number: 2021950841

Publisher and Acquisition Editor   John Inglis

Senior Project Manager   Inez Sialiano

Permissions Coordinator   Carol Brown

Production Editor   Kathleen Bubbeo

Production Manager   Denise Weiss

Cover Designers   Lorenzo Casalino and Rommie Amaro

Illustrator and Illustrations Coordinator   Richard D. Cummings

Front cover artwork: Molecular representation of the full-length, fully glycosylated, all-atom model of the SARS-CoV-2 spike protein in the open state, embedded in the viral membrane. The model of the spike has been developed by Casalino et al. (ACS Cent Sci 6: 1722–1734 [2020]) based on the cryo-EM structure by Wrapp et al. (Science 367: 1260–1263 [2020]) (PDB ID: 6VSB). N-/O-glycans have been modeled according to Watanabe et al. (Science 369: 330–333 [2020]) and Shajahan et al. (Glycobiology 30: 981–988 [2020]).

On the left, the full-length SARS-CoV-2 spike in the open state—that is, with one receptor binding domain (RBD) in the “up” conformation—is shown with a cyan transparent surface overlaid on the cartoon representation of its secondary structure. The conformation of the spike was selected from molecular dynamics simulations performed by Casalino et al. (ACS Cent Sci 6: 1722–1734 [2020]). N-linked and O-linked glycans are depicted using the Symbol Nomenclature for Glycans (SNFG), in which blue filled squares are for N-acetyl-D-glucosamine (GlcNAc), green filled circles for D-mannose, yellow filled squares for N-acetyl-D-galactosamine (GalNAc), yellow filled circles for D-galactose (Gal), red filled triangles for L-fucose (Fuc), and purple filled diamonds for N-acetyl-D-neuraminic acid (Neu5Ac). The lipid bilayer of the viral membrane is depicted with a surface representation, in which the POPC (1-palmitoyl-2-oleoyl-sn-glycero-3-phosphocholine) are colored in pink, POPE (1-palmitoyl-2-oleoyl-sn-glycero-3-phosphoethanolamine) in purple, POPI (1-palmitoyl-2-oleoyl-sn-glycero-3-phosphoinositol) in orange, POPS (1-palmitoyl-2-oleoyl-sn-glycero-3-phosphoserine) in red, and cholesterol in yellow.

On the right, the glycan shield (dark-blue bush-like structures) in the SARS-CoV-2 spike protein (cyan transparent surface) is shown by overlaying multiple conformations of the N-linked and O-linked glycans obtained at multiple, interspersed frames along 1 μsec of molecular dynamics simulations (Casalino et al., ACS Cent Sci 6: 1722–1734 [2020]). For each glycan, each conformation sampled along the dynamics is shown with dark-blue sticks. When multiple conformations of each glycan are overlaid, they form a protective bush-like structure providing a visual representation of the extent of protein surface covered over a specific time frame. When the receptor-binding domain (RBD), located in the apical portion of the spike, is in the “up” conformation, it emerges from the glycan shield (as shown in the image with transparent cyan surface) and becomes available for binding to the angiotensin-converting enzyme 2 (ACE2) receptors located on the host cell. The binding event between the RBD and ACE2 initiates infection.

The cover artwork was designed and created by Dr. Lorenzo Casalino in the Amaro Laboratory (University of California San Diego), based on the all-atom model published in ACS Cent Sci 6: 1722–1734 (2020).

Library of Congress Cataloging-in-Publication Data

Identifiers: LCCN 2021950841 | ISBN 978-1-621824-21-3 (hardcover) | ISBN 978-1-621824-22-0 (ePub3)

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