Intermediate Filament Mechanics Across Scales – From Single Filaments to Single Interactions and Networks in Cells


Book Description

The mechanical properties of cells are largely determined by the cytoskeleton. The cytoskeleton is an intricate and complex structure formed by protein filaments, motor proteins, and crosslinkers. The three main types of protein filaments are microtubules, actin filaments, and intermediate filaments ( IFs ). Whereas the proteins that form microtubules and actin filaments are exceptionally conserved throughout cell types and organisms, the family of IFs is diverse. For example, the IF protein vimentin is expressed in relatively motile fibroblasts, and keratin IFs are found in epithelial cells. This variety of IF proteins might therefore be linked to the various mechanical properties of different cell types. In the scope of this thesis, I combine studies of IF mechanics on different time scales and in systems of increasing complexity, from single filaments to networks in cells. This multiscale approach allows for the simplification necessary to interpret observations while adding increasing physiological context in subsequent experiments. We especially focus on the tunability of the IF mechanics by environmental cues in these increasingly complex systems. In a series of experiments, including single filament elongation studies, single filament stretching measurements with optical tweezers, filament-filament interaction measurements with four optical tweezers, microrheology, and isotropic cell stretching, we characterize how electrostatic (pH and ion concentration) and hydrophobic interactions (detergent) provide various mechanisms by which the mechanics of the IF cytoskeleton can be tuned. These studies reveal how small changes, such as charge shifts, influence IF mechanics on multiple scales. In combination with simulations, we determine the mechanisms by which charge shifts alter single vimentin filament mechanics and we extract energy landscapes for interactions between single filaments. Such insights will provide a deeper understanding of the mechanisms by which cells can maintain their integrity and adapt to the mechanical requirements set by their environment.




Intermediate Filament Proteins


Book Description

Intermediate Filament Proteins, the latest volume in the Methods in Enzymology series covers all the intermediate filaments in vertebrates and invertebrates, providing a unique understanding of the multiple different tissue-specific intermediate filaments. This volume also covers the latest methods that are currently being used to study intermediate filament protein function and dynamics. It will be an important companion for any experimentalist interesting in studying this protein family in their cell or organism model system.







The Cytoskeleton


Book Description




Advances in Cell Mechanics


Book Description

"Advances in Cell Mechanics" presents the latest developments in cell mechanics and biophysics, mainly focusing on interdisciplinary research in cell biology and the biophysics of cells. Moreover, a unique feature of the book is its emphasis on the molecular and complex continuum modeling and simulations of the cells. It may be the first work that brings rigorous and quantitative scientific analysis and state-of-the-art simulation technology into cell biology research. The book is intended for researchers and graduate students working in the fields of molecular cell biology, bio-engineering and bio-mechanics, soft matter physics, computational mechanics, bio-chemistry and bio-medicine. All contributors are leading scholars in their respective fields. Dr. Shaofan Li is a professor and an expert for computational mechanics at the University of California-Berkeley, USA; Dr. Bohua Sun is a professor at Cape Peninsula University of Technology, South Africa.







Mechanobiology of Cell-Cell and Cell-Matrix Interactions


Book Description

Mechanobiology of Cell-Matrix Interactions focuses on characterization and modeling of interactions between cells and their local extracellular environment, exploring how these interactions may mediate cell behavior. Studies of cell-matrix interactions rely on integrating engineering, (molecular and cellular) biology, and imaging disciplines. Recent advances in the field have begun to unravel our understanding of how cells gather information from their surrounding environment, and how they interrogate such information during the cell fate decision making process. Topics include adhesive and integrin-ligand interactions; extracellular influences on cell biology and behavior; cooperative mechanisms of cell-cell and cell-matrix interactions; the mechanobiology of pathological processes; (multi-scale) modeling approaches to describe the complexity or cell-matrix interactions; and quantitative methods required for such experimental and modeling studies.




Cytoskeletal Mechanics


Book Description

This book presents a full spectrum of views on current approaches to modeling cell mechanics. The authors come from the biophysics, bioengineering and physical chemistry communities and each joins the discussion with a unique perspective on biological systems. Consequently, the approaches range from finite element methods commonly used in continuum mechanics to models of the cytoskeleton as a cross-linked polymer network to models of glassy materials and gels. Studies reflect both the static, instantaneous nature of the structure, as well as its dynamic nature due to polymerization and the full array of biological processes. While it is unlikely that a single unifying approach will evolve from this diversity, it is the hope that a better appreciation of the various perspectives will lead to a highly coordinated approach to exploring the essential problems and better discussions among investigators with differing views.




Intermediate Filament Cytoskeleton


Book Description

Intermediate filaments are a large family of proteins that are the cytoskeletal elements involved in a number of skin, liver, neuromuscular, cardiac, eye and hair diseases. Intermediate filament genes are regulated in a tissue-and cell type-specific manner and their polymerized protein products protects the cells and tissue they are part of against a variety of mechanical and nonmechanical stresses. This book provides a comprehensive resource of methodology essentials, describing a variety of essential tools and assays for studying intermediate filaments. The book provides user-friendly advice and protocols covering all aspects of intermediate filaments including protein isolation and structure, protein and gene regulation, relationship to disease and apoptosis, and associated proteins. Both mammalian and non-mammalian systems and animal models are covered, making this book a must-have for any investigator wishing to study IF genes or their protein products. * Covers intermediate filaments from crystallography, protein chemistry, cell and molecular biology, microrheology, gene regulation, to animal models and human disease * Practical and user-friendly with detailed "how-to-protocols and "tricks of the trade" * Includes detailed tables of useful reagents, vendors and web links




Cell Mechanics


Book Description

Ubiquitous and fundamental in cell mechanics, multiscale problems can arise in the growth of tumors, embryogenesis, tissue engineering, and more. Cell Mechanics: From Single Scale-Based Models to Multiscale Modeling brings together new insight and research on mechanical, mathematical, physical, and biological approaches for simulating the behavior




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