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Literature DB >> 35416768

A mechano-osmotic feedback couples cell volume to the rate of cell deformation.

Larisa Venkova^1,2, Amit Singh Vishen³, Sergio Lembo⁴, Nishit Srivastava^1,2, Baptiste Duchamp^1,2, Artur Ruppel⁵, Alice Williart^1,2, Stéphane Vassilopoulos⁶, Alexandre Deslys^1,2, Juan Manuel Garcia Arcos^1,2, Alba Diz-Muñoz⁴, Martial Balland⁵, Jean-François Joanny³, Damien Cuvelier^1,2,7, Pierre Sens³, Matthieu Piel^1,2.

Abstract

Mechanics has been a central focus of physical biology in the past decade. In comparison, how cells manage their size is less understood. Here, we show that a parameter central to both the physics and the physiology of the cell, its volume, depends on a mechano-osmotic coupling. We found that cells change their volume depending on the rate at which they change shape, when they spontaneously spread or when they are externally deformed. Cells undergo slow deformation at constant volume, while fast deformation leads to volume loss. We propose a mechanosensitive pump and leak model to explain this phenomenon. Our model and experiments suggest that volume modulation depends on the state of the actin cortex and the coupling of ion fluxes to membrane tension. This mechano-osmotic coupling defines a membrane tension homeostasis module constantly at work in cells, causing volume fluctuations associated with fast cell shape changes, with potential consequences on cellular physiology.

Entities: Chemical

Keywords: cell biology; cell shape; cell volume; human; membrane tension; mouse; physics of living systems

Mesh：

Substances：
Actins

Year: 2022 PMID： 35416768 PMCID： PMC9090331 DOI： 10.7554/eLife.72381

Source DB: PubMed Journal: Elife ISSN： 2050-084X Impact factor: 8.713

72 in total

1. Characterizing Cellular Biophysical Responses to Stress by Relating Density, Deformability, and Size.

Authors: Sangwon Byun; Vivian C Hecht; Scott R Manalis
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2. Living cell dry mass measurement using quantitative phase imaging with quadriwave lateral shearing interferometry: an accuracy and sensitivity discussion.

Authors: Sherazade Aknoun; Julien Savatier; Pierre Bon; Frédéric Galland; Lamiae Abdeladim; Benoit Wattellier; Serge Monneret
Journal: J Biomed Opt Date: 2015 Impact factor: 3.170

3. Protein-carbonhydrate interaction. 3. Agar gel-diffusion studies on the interaction of Concanavalin A, a lectin isolated from jack bean, with polysaccharides.

Authors: I J Goldstein; L L So
Journal: Arch Biochem Biophys Date: 1965-08 Impact factor: 4.013

4. Mechanics of cell spreading: role of myosin II.

Authors: Tetsuro Wakatsuki; Robert B Wysolmerski; Elliot L Elson
Journal: J Cell Sci Date: 2003-04-15 Impact factor: 5.285

5. Cell Mechanical and Physiological Behavior in the Regime of Rapid Mechanical Compressions that Lead to Cell Volume Change.

Authors: Anna Liu; Tong Yu; Katherine Young; Nicholas Stone; Srinivas Hanasoge; Tyler J Kirby; Vikram Varadarajan; Nicholas Colonna; Janet Liu; Abhishek Raj; Jan Lammerding; Alexander Alexeev; Todd Sulchek
Journal: Small Date: 2019-11-29 Impact factor: 13.281

6. Electromechanics and Volume Dynamics in Nonexcitable Tissue Cells.

Authors: Florence Yellin; Yizeng Li; Varun K A Sreenivasan; Brenda Farrell; Manu B Johny; David Yue; Sean X Sun
Journal: Biophys J Date: 2018-05-08 Impact factor: 4.033

7. The cytoplasm of living cells behaves as a poroelastic material.

Authors: Emad Moeendarbary; Léo Valon; Marco Fritzsche; Andrew R Harris; Dale A Moulding; Adrian J Thrasher; Eleanor Stride; L Mahadevan; Guillaume T Charras
Journal: Nat Mater Date: 2013-01-06 Impact factor: 43.841

Review 8. The actin cortex at a glance.

Authors: Priyamvada Chugh; Ewa K Paluch
Journal: J Cell Sci Date: 2018-07-19 Impact factor: 5.285