Your search keyword '"polymer physics"' showing total 7 results

1. Matrix Mechanosensing: From Scaling Concepts in ’Omics Data to Mechanisms in the Nucleus, Regeneration, and Cancer

Author

Discher, Dennis E, Smith, Lucas, Cho, Sangkyun, Colasurdo, Mark, García, Andrés J, and Safran, Sam

Subjects

Human Genome, Regenerative Medicine, Stem Cell Research, Genetics, Bioengineering, 1.1 Normal biological development and functioning, Underpinning research, Musculoskeletal, Animals, Biopolymers, Cell Nucleus, Collagen, Cytoskeleton, DNA Copy Number Variations, Epigenesis, Genetic, Gene Expression Regulation, Humans, Mechanotransduction, Cellular, Neoplasms, Proteome, Regeneration, Stem Cell Transplantation, Transcriptome, polymer physics, collagen, lamins, myosin, contractility, Medicinal and Biomolecular Chemistry, Biochemistry and Cell Biology, Chemical Engineering, Biophysics

Abstract

Many of the most important molecules of life are polymers. In animals, the most abundant of the proteinaceous polymers are the collagens, which constitute the fibrous matrix outside cells and which can also self-assemble into gels. The physically measurable stiffness of gels, as well as tissues, increases with the amount of collagen, and cells seem to sense this stiffness. An understanding of this mechanosensing process in complex tissues, including fibrotic disease states with high collagen, is now utilizing 'omics data sets and is revealing polymer physics-type, nonlinear scaling relationships between concentrations of seemingly unrelated biopolymers. The nuclear structure protein lamin A provides one example, with protein and transcript levels increasing with collagen 1 and tissue stiffness, and with mechanisms rooted in protein stabilization induced by cytoskeletal stress. Physics-based models of fibrous matrix, cytoskeletal force dipoles, and the lamin A gene circuit illustrate the wide range of testable predictions emerging for tissues, cell cultures, and even stem cell-based tissue regeneration. Beyond the epigenetics of mechanosensing, the scaling in cancer of chromosome copy number variations and other mutations with tissue stiffness suggests that genomic changes are occurring by mechanogenomic processes that now require elucidation.

Published

2017

2. Collapse Transitions of Proteins and the Interplay Among Backbone, Sidechain, and Solvent Interactions.

Author

Holehouse, Alex S. and Pappu, Rohit V.

Abstract

Proteins can collapse into compact globules or form expanded, solvent-accessible, coil-like conformations. Additionally, they can fold into well-defined three-dimensional structures or remain partially or entirely disordered. Recent discoveries have shown that the tendency for proteins to collapse or remain expanded is not intrinsically coupled to their ability to fold. These observations suggest that proteins do not have to form compact globules in aqueous solutions. They can be intrinsically disordered, collapsed, or expanded, and even form well-folded, elongated structures. This ability to decouple collapse from folding is determined by the sequence details of proteins. In this review, we highlight insights gleaned from studies over the past decade. Using a polymer physics framework, we explain how the interplay among sidechains, backbone units, and solvent determines the driving forces for collapsed versus expanded states in aqueous solvents. [ABSTRACT FROM AUTHOR]

Published

2018

3. Biophysics of Knotting.

Author

Meluzzi, Dario, Smith, Douglas E., and Arya, Gaurav

Subjects

*BIOPHYSICS, *DNA, *BIOMOLECULES, *BIOPOLYMERS, *STATISTICAL mechanics

Abstract

Knots appear in a wide variety of biophysical systems, ranging from biopolymers, such as DNA and proteins, to macroscopic objects, such as umbilical cords and catheters. Although significant advancements have been made in the mathematical theory of knots and some progress has been made in the statistical mechanics of knots in idealized chains, the mechanisms and dynamics of knotting in biophysical systems remain far from fully understood. We report on recent progress in the biophysics of knotting-the formation, characterization, and dynamics of knots in various biophysical contexts. [ABSTRACT FROM AUTHOR]

Published

2010

4. Matrix Mechanosensing: From Scaling Concepts in ’Omics Data to Mechanisms in the Nucleus, Regeneration, and Cancer

Author

Dennis E. Discher, Samuel A. Safran, Sangkyun Cho, Lucas R. Smith, Andrés J. García, and Mark Colasurdo

Subjects

collagen, 0301 basic medicine, Proteome, Mechanotransduction, myosin, Matrix (biology), Regenerative Medicine, Mechanotransduction, Cellular, Biochemistry, Epigenesis, Genetic, Biopolymers, Structural Biology, Neoplasms, Myosin, Cytoskeleton, Regulation of gene expression, Chemical Engineering, lamins, Collagen, Protein stabilization, DNA Copy Number Variations, 1.1 Normal biological development and functioning, Biophysics, Bioengineering, Nanotechnology, contractility, Article, Medicinal and Biomolecular Chemistry, 03 medical and health sciences, Genetic, Underpinning research, Genetics, Animals, Humans, Regeneration, Cell Nucleus, Regeneration (biology), Human Genome, Cell Biology, polymer physics, Stem Cell Research, Collagen, type I, alpha 1, 030104 developmental biology, Gene Expression Regulation, Musculoskeletal, Cellular, Biochemistry and Cell Biology, Transcriptome, Lamin, Stem Cell Transplantation, Epigenesis

Abstract

Many of the most important molecules of life are polymers. In animals, the most abundant of the proteinaceous polymers are the collagens, which constitute the fibrous matrix outside cells and which can also self-assemble into gels. The physically measurable stiffness of gels, as well as tissues, increases with the amount of collagen, and cells seem to sense this stiffness. An understanding of this mechanosensing process in complex tissues, including fibrotic disease states with high collagen, is now utilizing ’omics data sets and is revealing polymer physics–type, nonlinear scaling relationships between concentrations of seemingly unrelated biopolymers. The nuclear structure protein lamin A provides one example, with protein and transcript levels increasing with collagen 1 and tissue stiffness, and with mechanisms rooted in protein stabilization induced by cytoskeletal stress. Physics-based models of fibrous matrix, cytoskeletal force dipoles, and the lamin A gene circuit illustrate the wide range of testable predictions emerging for tissues, cell cultures, and even stem cell–based tissue regeneration. Beyond the epigenetics of mechanosensing, the scaling in cancer of chromosome copy number variations and other mutations with tissue stiffness suggests that genomic changes are occurring by mechanogenomic processes that now require elucidation.

Published

2017

5. Collapse Transitions of Proteins and the Interplay Among Backbone, Sidechain, and Solvent Interactions

Author

Rohit V. Pappu and Alex S. Holehouse

Subjects

0301 basic medicine, Aqueous solution, Chemistry, Biophysics, Bioengineering, Cell Biology, 010402 general chemistry, Intrinsically disordered proteins, 01 natural sciences, Biochemistry, 0104 chemical sciences, Solvent, 03 medical and health sciences, 030104 developmental biology, Structural Biology, Chemical physics, Polymer physics

Abstract

Proteins can collapse into compact globules or form expanded, solvent-accessible, coil-like conformations. Additionally, they can fold into well-defined three-dimensional structures or remain partially or entirely disordered. Recent discoveries have shown that the tendency for proteins to collapse or remain expanded is not intrinsically coupled to their ability to fold. These observations suggest that proteins do not have to form compact globules in aqueous solutions. They can be intrinsically disordered, collapsed, or expanded, and even form well-folded, elongated structures. This ability to decouple collapse from folding is determined by the sequence details of proteins. In this review, we highlight insights gleaned from studies over the past decade. Using a polymer physics framework, we explain how the interplay among sidechains, backbone units, and solvent determines the driving forces for collapsed versus expanded states in aqueous solvents.

Published

2018

6. Single-Molecule FRET Spectroscopy and the Polymer Physics of Unfolded and Intrinsically Disordered Proteins

Author

Daniel Nettels, Hagen Hofmann, Benjamin Schuler, Andrea Soranno, and University of Zurich

Subjects

0301 basic medicine, Protein Folding, 1303 Biochemistry, Polymers, Protein Conformation, Biophysics, Bioengineering, 610 Medicine & health, 010402 general chemistry, Intrinsically disordered proteins, 01 natural sciences, Biochemistry, 1307 Cell Biology, 03 medical and health sciences, Protein structure, 1315 Structural Biology, Structural Biology, 10019 Department of Biochemistry, Fluorescence Resonance Energy Transfer, 1502 Bioengineering, Chemistry, Protein dynamics, Physics, Proteins, Cell Biology, Single-molecule FRET, Single Molecule Imaging, 0104 chemical sciences, Folding (chemistry), Intrinsically Disordered Proteins, 030104 developmental biology, Structural biology, Polymer physics, 570 Life sciences, biology, Protein folding, 1304 Biophysics

Abstract

The properties of unfolded proteins have long been of interest because of their importance to the protein folding process. Recently, the surprising prevalence of unstructured regions or entirely disordered proteins under physiological conditions has led to the realization that such intrinsically disordered proteins can be functional even in the absence of a folded structure. However, owing to their broad conformational distributions, many of the properties of unstructured proteins are difficult to describe with the established concepts of structural biology. We have thus seen a reemergence of polymer physics as a versatile framework for understanding their structure and dynamics. An important driving force for these developments has been single-molecule spectroscopy, as it allows structural heterogeneity, intramolecular distance distributions, and dynamics to be quantified over a wide range of timescales and solution conditions. Polymer concepts provide an important basis for relating the physical properties of unstructured proteins to folding and function.

Published

2016

7. Particle-tracking microrheology of living cells: principles and applications

Author

Denis Wirtz

Subjects

Microrheology, Cytoplasm, Materials science, Microfluidics, Biophysics, Contrast Media, Bioengineering, Cell Biology, Tracking (particle physics), Image Enhancement, Biochemistry, Viscoelasticity, Microscopy, Fluorescence, Structural Biology, Particle, Polymer physics, Spatiotemporal resolution, Cell mechanics

Abstract

A multitude of cellular and subcellular processes depend critically on the mechanical deformability of the cytoplasm. We have recently introduced the method of particle-tracking microrheology, which measures the viscoelastic properties of the cytoplasm locally and with high spatiotemporal resolution. Here we establish the basic principles of particle-tracking microrheology, describing the advantages of this approach over more conventional approaches to cell mechanics. We present basic concepts of molecular mechanics and polymer physics relevant to the microrheological response of cells. Particle-tracking microrheology can probe the mechanical properties of live cells in experimentally difficult, yet more physiological, environments, including cells embedded inside a 3D matrix, adherent cells subjected to shear flows, and cells inside a developing embryo. Particle-tracking microrheology can readily reveal the lost ability of diseased cells to resist shear forces.

Published

2009