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Journal Articles Journal of Cell Biology Year : 2014

A contractile and counterbalancing adhesion system controls the 3D shape of crawling cells

Dylan Burnette
  • Function : Author
National Institute of Child Health and Human Development [Bethesda]
National Heart, Lung, and Blood Institute [Bethesda]
Lin Shao
  • Function : Author
Janelia Research Campus [Ashburn]
Carolyn Ott
  • Function : Author
National Institute of Child Health and Human Development [Bethesda]
National Heart, Lung, and Blood Institute [Bethesda]
Ana Pasapera
  • Function : Author
National Institute of Child Health and Human Development [Bethesda]
National Heart, Lung, and Blood Institute [Bethesda]
Robert Fischer
  • Function : Author
  • PersonId : 1010428
National Institute of Child Health and Human Development [Bethesda]
National Heart, Lung, and Blood Institute [Bethesda]
Michelle Baird
  • Function : Author
National High Magnetic Field Laboratory
Florida State University [Tallahassee]
Christelle C. Der Loughian
Institut Lumière Matière [Villeurbanne]
Hélène Delanoë-Ayari
Institut Lumière Matière [Villeurbanne]
Matthew Paszek
  • Function : Author
Cornell University [New York]
Michael Davidson
  • Function : Author
National High Magnetic Field Laboratory
Florida State University [Tallahassee]
Eric Betzig
Janelia Research Campus [Ashburn]
Jennifer Lippincott-Schwartz
  • Function : Author
National Institute of Child Health and Human Development [Bethesda]
National Heart, Lung, and Blood Institute [Bethesda]

Abstract

How adherent and contractile systems coordinate to promote cell shape changes is unclear. Here, we define a counterbalanced adhesion/contraction model for cell shape control. Live-cell microscopy data showed a crucial role for a contractile meshwork at the top of the cell, which is composed of actin arcs and myosin IIA filaments. The contractile actin meshwork is organized like muscle sarcomeres, with repeating myosin II filaments separated by the actin bundling protein α-actinin, and is mechanically coupled to noncontractile dorsal actin fibers that run from top to bottom in the cell. When the meshwork contracts, it pulls the dorsal fibers away from the substrate. This pulling force is counterbalanced by the dorsal fibers’ attachment to focal adhesions, causing the fibers to bend downward and flattening the cell. This model is likely to be relevant for understanding how cells configure themselves to complex surfaces, protrude into tight spaces, and generate three-dimensional forces on the growth substrate under both healthy and diseased conditions.

Domains

Physics [physics] Chemical Sciences Engineering Sciences [physics]
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https://univ-lyon1.hal.science/hal-02309211

Submitted on : Wednesday, January 20, 2021-9:28:15 AM

Last modification on : Wednesday, January 17, 2024-9:56:04 AM

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hal-02309211 , version 1 (20-01-2021)

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Dylan Burnette, Lin Shao, Carolyn Ott, Ana Pasapera, Robert Fischer, et al.. A contractile and counterbalancing adhesion system controls the 3D shape of crawling cells. Journal of Cell Biology, 2014, 205 (1), pp.83-96. ⟨10.1083/jcb.201311104⟩. ⟨hal-02309211⟩

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