Dynamics in steady state in vitro acto-myosin networks

Adar Sonn-Segev; Anne Bernheim-Groswasser; Yael Roichman

doi:10.1088/1361-648X/aa62ca

Dynamics in steady state in vitro acto-myosin networks

Adar Sonn-Segev, Anne Bernheim-Groswasser, Yael Roichman

School of Chemistry

Research output: Contribution to journal › Review article › peer-review

13 Scopus citations

Abstract

It is well known that many biochemical processes in the cell such as gene regulation, growth signals and activation of ion channels, rely on mechanical stimuli. However, the mechanism by which mechanical signals propagate through cells is not as well understood. In this review we focus on stress propagation in a minimal model for cell elasticity, actomyosin networks, which are comprised of a sub-family of cytoskeleton proteins. After giving an overview of th actomyosin network components, structure and evolution we review stress propagation in these materials as measured through the correlated motion of tracer beads. We also discuss the possibility to extract structural features of these networks from the same experiments. We show that stress transmission through these networks has two pathways, a quickly dissipative one through the bulk, and a long ranged weakly dissipative one through the pre-stressed actin network.

Original language	English
Article number	163002
Journal	Journal of Physics Condensed Matter
Volume	29
Issue number	16
DOIs	https://doi.org/10.1088/1361-648X/aa62ca
State	Published - 21 Mar 2017

Keywords

active matter
complex fluids
cytoskeleton
microrheology
stress transmission

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10.1088/1361-648X/aa62ca

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abstract = "It is well known that many biochemical processes in the cell such as gene regulation, growth signals and activation of ion channels, rely on mechanical stimuli. However, the mechanism by which mechanical signals propagate through cells is not as well understood. In this review we focus on stress propagation in a minimal model for cell elasticity, actomyosin networks, which are comprised of a sub-family of cytoskeleton proteins. After giving an overview of th actomyosin network components, structure and evolution we review stress propagation in these materials as measured through the correlated motion of tracer beads. We also discuss the possibility to extract structural features of these networks from the same experiments. We show that stress transmission through these networks has two pathways, a quickly dissipative one through the bulk, and a long ranged weakly dissipative one through the pre-stressed actin network.",

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AB - It is well known that many biochemical processes in the cell such as gene regulation, growth signals and activation of ion channels, rely on mechanical stimuli. However, the mechanism by which mechanical signals propagate through cells is not as well understood. In this review we focus on stress propagation in a minimal model for cell elasticity, actomyosin networks, which are comprised of a sub-family of cytoskeleton proteins. After giving an overview of th actomyosin network components, structure and evolution we review stress propagation in these materials as measured through the correlated motion of tracer beads. We also discuss the possibility to extract structural features of these networks from the same experiments. We show that stress transmission through these networks has two pathways, a quickly dissipative one through the bulk, and a long ranged weakly dissipative one through the pre-stressed actin network.

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Dynamics in steady state in vitro acto-myosin networks

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