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Intracellular pressure controls the propagation of tension in crumpled cell membranes

Author

Listed:
  • Raviv Dharan

    (Tel Aviv University
    Tel Aviv University)

  • Avishai Barnoy

    (Tel Aviv University
    Tel Aviv University)

  • Andrey K. Tsaturyan

    (Tel Aviv University
    Tel Aviv University)

  • Alon Grossman

    (Tel Aviv University
    Tel Aviv University)

  • Shahar Goren

    (Tel Aviv University
    Tel Aviv University)

  • Inbar Yosibash

    (Tel Aviv University
    Tel Aviv University)

  • Dikla Nachmias

    (Ben-Gurion University of the Negev)

  • Natalie Elia

    (Ben-Gurion University of the Negev)

  • Raya Sorkin

    (Tel Aviv University
    Tel Aviv University)

  • Michael M. Kozlov

    (Tel Aviv University
    Tel Aviv University)

Abstract

Propagation of membrane tension mediates mechanical signal transduction along surfaces of live cells and sets the time scale of mechanical equilibration of cell membranes. Recent studies in several cell types and under different conditions revealed a strikingly wide variation range of the tension propagation speeds including extremely low ones. The latter suggests a possibility of long-living inhomogeneities of membrane tension crucially affecting mechano-sensitive membrane processes. Here, we propose, analyze theoretically, and support experimentally a mechanism of tension propagation in membranes crumpled by the contractile cortical cytoskeleton. The tension spreading is mediated by the membrane flow between the crumples. We predict the pace of the tension propagation to be controlled by the intra-cellular pressure and the degree of the membrane crumpling. We provide experimental support for the suggested mechanism by monitoring the rate of tension propagation in cells exposed to external media of different osmolarities.

Suggested Citation

  • Raviv Dharan & Avishai Barnoy & Andrey K. Tsaturyan & Alon Grossman & Shahar Goren & Inbar Yosibash & Dikla Nachmias & Natalie Elia & Raya Sorkin & Michael M. Kozlov, 2025. "Intracellular pressure controls the propagation of tension in crumpled cell membranes," Nature Communications, Nature, vol. 16(1), pages 1-13, December.
    • Handle: RePEc:nat:natcom:v:16:y:2025:i:1:d:10.1038_s41467-024-55398-1
    DOI: 10.1038/s41467-024-55398-1
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    References listed on IDEAS

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    1. Martin P. Stewart & Jonne Helenius & Yusuke Toyoda & Subramanian P. Ramanathan & Daniel J. Muller & Anthony A. Hyman, 2011. "Hydrostatic pressure and the actomyosin cortex drive mitotic cell rounding," Nature, Nature, vol. 469(7329), pages 226-230, January.
    2. Kinneret Keren & Zachary Pincus & Greg M. Allen & Erin L. Barnhart & Gerard Marriott & Alex Mogilner & Julie A. Theriot, 2008. "Mechanism of shape determination in motile cells," Nature, Nature, vol. 453(7194), pages 475-480, May.
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