Fibrous Proteins: Structures and Mechanisms

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This book provides a unique discussion of the exciting advances made in the field of fibrous proteins over the past decade. The authors are world experts in their respective fields and each has provided the reader with a state-of-the-art summary of current thinking. As such, the book is clearly written and liberally illustrated. Those fibrous proteins described in detail include the constituents of muscle, keratin, connective tissue, silk, fibrin and biomaterials.  The opening chapter by Wood discusses prediction of structure from sequence data and structural modelling, and in it he raises a very important topic that of artificial intelligence and the increasing role that it will play in future years in protein research. In chapters 2-4 Luther, Lehman and Maeda cover muscle and concentrate on thick and thin filament structure and function. These highlight the recent advances made in cryo-electron microscope technology and image processing which have enabled new insights to be gained into the structure and working of the sarcomere and the effects that drugs designed to tackle disease have on this important motile element. In chapters 5-7,  Parry considers the recent developments in the structures of the corneous alpha and beta proteins from the sauropsids (birds and reptiles), Medalia reveals the incredibly detailed structures of the intermediate filaments that can now be deduced from high-resolution cryo-electron microscopy, and Köster explains the mechanical properties of single intermediate filaments. Chapters 8-12 are devoted to important but diverse aspects of connective tissue. In particular, Bella reviews the marine collagens, a topic rarely discussed but one of increasing interest and relevance, and Norris reveals that the glycosylation of collagen plays an important role in fibril assembly. Ruberti discusses how collagen provides a tissue with its optimum mechanical attributes, and Fertala reviews collagen diseases and fibrosis. Canty-Laird completes this section with a fascinating chapter on collagen diseases. In Chapters 13 and 14 Weisel describes the important developments that have been made on the structure and function of fibrin, and Sutherland completes the exciting 60-year-old story of the coiled-coil structure of the silks of the bees, ants and wasps. The final two Chapters (15 and 16) are devoted to

List of contents

Chapter 1. Sequence Prediction, Structural Modelling and the Challenges of Plasticity in Coiled Coils.- Chapter 2. Structure of the Myosin Thick Filaments In Muscle.- Chapter 3. The Structural Role of Tropomyosin In Regulating Thin Filament Activation of Actin-Myosin Interaction.- Chapter 4. Structural Biology of Actin: Interplay Between Molecular Assembly, Conformational Polymorphism and ATPase.- Chapter 5. Structural and Functional Elements Of The Epidermal Appendages In Birds and Reptiles: Conformations And Modes of Assembly of the Constituent b-Filaments And Keratin Intermediate Filaments (IF).- Chapter 6. Insights into the Structure of Intermediate Filaments.- Chapter 7. Intermediate Filaments: structure-mechanics crosstalk.- Chapter 8. The Fibrillar Collagens of Bony Fish: Genes, Proteins And Biomedical Applications.- Chapter 9. Comparative Study of the Positions of Glycosylated Residues In The Chains Of Fibril-Forming Collagens And The Role That These Residues Play in Axial and Lateral Assembly.- Chapter 10. Collagen Mechanics.- Chapter 11. Collagen in Fibrotic Diseases.- Chapter 12. The Impact of Ageing on Fibrillar Collagen.

About the author

David Parry has been active in X-ray diffraction, electron microscopy and sequence analysis of fibrous proteins for nearly 60 years. His scientific contributions at Massey University have been recognised by the award of six medals, Companionship of the New Zealand Order of Merit and election to Fellowship of the Royal Society of New Zealand. He has been President of the International Union for Pure and Applied Biophysics (IUPAB) and Vice President of the International Council for Science (ICSU). He has contributed 246 scientific papers and has written and/or edited seven books and six special Journal issues.
Pradeep Luther is a structural biologist working on cardiac and skeletal muscle and has used electron tomography and cryo-electron tomography to study the structure of thick filaments, the Z-band and the M-band. His research has utilised the recent advances made in cryo-electron microscopy and image processing, and this has enabled new insights to be gained into the structure and working of the sarcomere and the effects that drugs designed to tackle disease have on this important motile element. Luther is at the National Heart and Lung Institute, Imperial College London.

Summary

This book provides a unique discussion of the exciting advances made in the field of fibrous proteins over the past decade. The authors are world experts in their respective fields and each has provided the reader with a “state-of-the-art” summary of current thinking. As such, the book is clearly written and liberally illustrated. Those fibrous proteins described in detail include the constituents of muscle, keratin, connective tissue, silk, fibrin and biomaterials.  The opening chapter by Wood discusses prediction of structure from sequence data and structural modelling, and in it he raises a very important topic – that of artificial intelligence and the increasing role that it will play in future years in protein research. In chapters 2-4 Luther, Lehman and Maeda cover muscle and concentrate on thick and thin filament structure and function. These highlight the recent advances made in cryo-electron microscope technology and image processing which have enabled new insights to be gained into the structure and working of the sarcomere and the effects that drugs designed to tackle disease have on this important motile element. In chapters 5-7,  Parry considers the recent developments in the structures of the corneous alpha and beta proteins from the sauropsids (birds and reptiles), Medalia reveals the incredibly detailed structures of the intermediate filaments that can now be deduced from high-resolution cryo-electron microscopy, and Köster explains the mechanical properties of single intermediate filaments. Chapters 8-12 are devoted to important but diverse aspects of connective tissue. In particular, Bella reviews the marine collagens, a topic rarely discussed but one of increasing interest and relevance, and Norris reveals that the glycosylation of collagen plays an important role in fibril assembly. Ruberti discusses how collagen provides a tissue with its optimum mechanical attributes, and Fertala reviews collagen diseases and fibrosis. Canty-Laird completes this section with a fascinating chapter on collagen diseases. In Chapters 13 and 14 Weisel describes the important developments that have been made on the structure and function of fibrin, and Sutherland completes the exciting 60-year-old story of the coiled-coil structure of the silks of the bees, ants and wasps. The final two Chapters (15 and 16) are devoted to the designability of a-helical protein filaments (Conticello) and functional plasticity through amyloid polymorphism (Landau). This second edition of what proved to be a highly influential book when it was first published in 2017 will be a valuable resource for senior scientists and postgraduate students in academic institutions as well as those working in the medical and industrial fields. It will also establish the basis for future activities in this area of research.