Stress-Strain Behavior of Single Vimentin Intermediate Filament


Book Description

Cells are the basic unit of living organisms and consist of a cytoplasm, which is enclosed by a membrane. As building blocks of life with a plethora of functions, cells have to be equipped with a high degree of mechanical resistance, durability, and variability. In eukaryotic cells three filamentous protein types – actin filaments, microtubules, and intermediate filaments (IFs) – form the so-called cytoskeleton, a network that is known to play a key role for the mechanical properties of cells. Among the three filament systems, IFs are special in terms of, for example, their hierarchical architecture, and their cell-type specific expression. In this thesis, vimentin, an IF mostly found in mesenchymal cells, is studied as a model system to learn more about the mechanical properties of IFs, and the underlying mechanisms that determine their robustness, stiffness, and flexibility. Using a combination of optical trapping and atomic force microcopy experiments and stochastic and numerical modelling, vimentin is found to possess impressive physical properties, such as an extendibility of about 3.6 times its initial length and a tensile memory that can be directly linked to the molecular architecture of the protein and the hierarchical construction of the filament. The experimental results show a clear loading-rate- and strain-dependent behavior of single vimentin IFs supporting the hypothesis that vimentin acts as a “safety belt” for cells, protecting them especially at large and fast deformations. The potential to dissipate a large amount of energy that is attributed to distinct non-equilibrium unfolding and refolding of the α-helices, which are the main structural feature of the vimentin monomer, enables vimentin to act as a shock absorber when exposed to large deformations. In case of cyclic deformations, such as in the cardiovascular system, the observed tensile memory could potentially help cells to be compliant with the repeated strain. In conclusion, vimentin is found to display highly interesting and diverse mechanical properties depending on the applied stress that could be linked to the molecular architecture of the filaments and enable vimentin to determine the mechanical properties of cells to a large extend.




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.




Intermediate Filaments


Book Description

Intermediate filaments (IFs), in concert with microfilaments (MFs) and microtubules (MTs), form the cytoskeleton, and each of these fibrillar networks exhibits rather unique structural and functional characteristics. Intermediate filaments were discovered in eukaryotic cells in the late 1960s, and their name comes from the fact that their diameter is intermediate between MFs and MTs. In contrast to the latter, IFs constitute a network that extends from the nuclear envelope throughout the cytoplasm, and in many cases, interact with cell surface domains involved in cell-cell and cell- matrix interactions. Several key features of their expression, assembly, structure and dynamics are highlighted in this eBook. For instance, IF proteins are encoded by several genes, which are classified into six types reflecting the tissues (cells) of origin. Moreover, IF proteins contain a conserved central α-helical (rod) domain flanked by N-terminal (head) and C-terminal (tail) globular domains that enables assembly of fibrous IFs exhibiting a tripartite structure. Although the rod domain is responsible for the formation of the coiled-coil framework and yields the main driving force during the IF protein assembly, the head and tail domains contribute to most of the structural heterogeneity of IF organization and undergo several types of post-translational modifications. Furthermore, the development of gene targeting methods to genetically knockout the expression of the IF genes in mice has uncovered the mechanical versus non-mechanical features of the IF networks, namely, their involvement in cell response to diverse forms of stress, growth stimulation, migration, or death insults. Finally, there is accumulating evidence revealing that the tissue and cell-type expression of IF genes reflects itself in the presence of causal or predisposition mutations responsible for numerous human tissue-specific diseases, known as IF-pathies. Table of Contents: List of Abbreviations / Introduction / IFs as a Multigene Family of Filamentous Proteins / Nuclear Lamina / IF Functional Interplay with Cell Surface Domains and Organelles / IFs and Cell Specialization / IF Relevance to Human Diseases / Conclusion / References / Author Biographies




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.




Atomic Force Microscopy in Nanobiology


Book Description

Recent developments in atomic force microscopy (AFM) have been accomplished through various technical and instrumental innovations, including high-resolution and recognition imaging technology under physiological conditions, fast-scanning AFM, and general methods for cantilever modification and force measurement. All these techniques are now highly




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.







Introductory Biomechanics


Book Description

Introductory Biomechanics is a new, integrated text written specifically for engineering students. It provides a broad overview of this important branch of the rapidly growing field of bioengineering. A wide selection of topics is presented, ranging from the mechanics of single cells to the dynamics of human movement. No prior biological knowledge is assumed and in each chapter, the relevant anatomy and physiology are first described. The biological system is then analyzed from a mechanical viewpoint by reducing it to its essential elements, using the laws of mechanics and then tying mechanical insights back to biological function. This integrated approach provides students with a deeper understanding of both the mechanics and the biology than from qualitative study alone. The text is supported by a wealth of illustrations, tables and examples, a large selection of suitable problems and hundreds of current references, making it an essential textbook for any biomechanics course.







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