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Related papers: Density-dependent flow generation in active cytosk…

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We present a novel flow instability that can arise in thin films of cytoskeletal fluids if the friction with the substrate on which the film lies is sufficiently strong. We consider a two dimensional, membrane-bound fragment containing…

Soft Condensed Matter · Physics 2009-11-13 A. C. Callan-Jones , J. -F. Joanny , J. Prost

Cell polarization relies on long-range cortical flows, which are driven by active stresses and resisted by the cytoskeletal network. While the general mechanisms that contribute to cortical flows are known, a quantitative understanding of…

Soft Condensed Matter · Physics 2023-10-18 Yuqing Qiu , Elizabeth D. White , Edwin M. Munro , Suriyanarayanan Vaikuntanathan , Aaron R. Dinner

The composite cytoskeleton, comprising interacting networks of semiflexible actin and rigid microtubules, actively generates forces and restructures using motor proteins such as myosins to enable key mechanical processes including cell…

Cortical actin networks are highly dynamic and play critical roles in shaping the mechanical properties of cells. The actin cytoskeleton undergoes significant reorganization over the course of the cell cycle, when cortical actin transitions…

Quantitative Methods · Quantitative Biology 2022-07-22 Maria-Veronica Ciocanel , Aravind Chandrasekaran , Carli Mager , Qin Ni , Garegin Papoian , Adriana Dawes

Mechanical forces generated by myosin II molecular motors drive diverse cellular processes, most notably shape change, division and locomotion. These forces may be transmitted over long range through the cytoskeletal medium - a disordered,…

Soft Condensed Matter · Physics 2023-02-28 Abhinav Kumar , David A. Quint , Kinjal Dasbiswas

Developing tissues need to pattern themselves in space and time. A prevalent mechanism to achieve this are pulsatile active stresses generated by the actin cytoskeleton. Active gel theory is a powerful tool to model the dynamics of…

Biological Physics · Physics 2023-02-21 Eloy Merlijn de Kinkelder , Elisabeth Fischer-Friedrich , Sebastian Aland

In this work, we study in detail the distribution of stochastic forces generated by the molecular motors activity, in the actin cortex of pre-muscular cells. By combining active and passive rheology experiments, performed on the same…

Biological Physics · Physics 2019-12-10 P. Bohec , J. Tailleur , F. van Wijland , A. Richert , F. Gallet

We present a combined numerical and analytical study of pattern formation in an active system where particles align, possess a density-dependent motility, and are subject to a logistic reaction. This is a model for suspensions of…

Soft Condensed Matter · Physics 2015-06-16 X. Yang , D. Marenduzzo , M. C. Marchetti

Understanding the role of non-equilibrium driving in self-organization is crucial for developing a predictive description of biological systems, yet it is impeded by their complexity. The actin cytoskeleton serves as a paradigm for how…

Soft Condensed Matter · Physics 2020-12-22 Yuqing Qiu , Michael Nguyen , Glen M. Hocky , Aaron R. Dinner , Suriyanarayanan Vaikuntanathan

The structural reorganization of the actin cytoskeleton is facilitated through the action of motor proteins that crosslink the actin filaments and transport them relative to each other. Here, we present a combined experimental-computational…

Biological Physics · Physics 2015-06-04 Daniel Gordon , Anne Bernheim-Groswasser , Chen Keasar , Oded Farago

Important cellular processes, such as cell motility and cell division, are coordinated by cell polarity, which is determined by the non-uniform distribution of certain proteins. Such protein patterns form via an interplay of protein…

Biological Physics · Physics 2020-05-20 Manon C Wigbers , Fridtjof Brauns , Ching Yee Leung , Erwin Frey

Cell motility and tissue morphogenesis depend crucially on the dynamic remodelling of actomyosin networks. An actomyosin network consists of an actin polymer network connected by crosslinker proteins and motor protein myosins that generate…

Soft Condensed Matter · Physics 2016-05-25 Chiu Fan Lee , Gunnar Pruessner

Cells control fluid flows with a spatial and temporal precision that far exceeds the capabilities of current microfluidic technologies. Cells achieve this superior spatio-temporal control by harnessing dynamic networks of cytoskeleton and…

Soft Condensed Matter · Physics 2025-05-26 Fan Yang , Shichen Liu , Heun Jin Lee , Rob Phillips , Matt Thomson

Active force generation by actin-myosin cortex coupled to the cell membrane allows the cell to deform, respond to the environment, and mediate cell motility and division. Several membrane-bound activator proteins move along it and couple to…

Soft Condensed Matter · Physics 2021-12-23 Subhadip Ghosh , Sashideep Gutti , Debasish Chaudhuri

Myosin II isoforms with varying mechanochemistry and filament size interact with filamentous actin (F-actin) networks to generate contractile forces in cells. How their properties control force production in environments with varying…

Subcellular Processes · Quantitative Biology 2014-07-09 Samantha Stam , Jon Alberts , Margaret L. Gardel , Edwin Munro

We aim to identify the control principles governing the adaptable formation of non-equilibrium structures in actomyosin networks. We build a phenomenological model and predict that biasing the energy dissipated by molecular motors should…

We propose a novel mechanism of cell motility, which relies on the coupling of actin polymerization at the cell membrane to geometric confinement. We consider a polymerizing viscoelastic cytoskeletal gel confined in a narrow channel, and…

Soft Condensed Matter · Physics 2009-02-13 R. J. Hawkins , M. Piel , G. Faure-Andre , A. M. Lennon-Dumenil , J. F. Joanny , J. Prost , R. Voituriez

We analyse a generic motility model, with the motility mechanism arising by contractile stress due to the interaction of myosin and actin. A hydrodynamic active polar gel theory is used to model the cytoplasm of a cell and is combined with…

Cell Behavior · Quantitative Biology 2015-07-06 Wieland Marth , Simon Praetorius , Axel Voigt

Centering and decentering of cellular components is essential for internal organization of cells and their ability to perform basic cellular functions such as division and motility. How cells achieve proper localization of their components…

Biological functions rely on ordered structures and intricately controlled collective dynamics. In contrast to systems in thermodynamic equilibrium, order is typically established and sustained in stationary states by continuous dissipation…