Cortical Flow-Driven Shapes of Nonadherent Cells

A. C. Callan-Jones; V. Ruprecht; S. Wieser; C. P. Heisenberg; R. Voituriez

doi:10.1103/PhysRevLett.116.028102

Cortical Flow-Driven Shapes of Nonadherent Cells

A. C. Callan-Jones, V. Ruprecht, S. Wieser, C. P. Heisenberg, R. Voituriez

Research output: Contribution to journal › Article › peer-review

Abstract

Nonadherent polarized cells have been observed to have a pearlike, elongated shape. Using a minimal model that describes the cell cortex as a thin layer of contractile active gel, we show that the anisotropy of active stresses, controlled by cortical viscosity and filament ordering, can account for this morphology. The predicted shapes can be determined from the flow pattern only; they prove to be independent of the mechanism at the origin of the cortical flow, and are only weakly sensitive to the cytoplasmic rheology. In the case of actin flows resulting from a contractile instability, we propose a phase diagram of three-dimensional cell shapes that encompasses nonpolarized spherical, elongated, as well as oblate shapes, all of which have been observed in experiment.

Original language	English
Article number	028102
Journal	Physical Review Letters
Volume	116
Issue number	2
DOIs	https://doi.org/10.1103/PhysRevLett.116.028102
Publication status	Published - 15 Jan 2016
Externally published	Yes

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title = "Cortical Flow-Driven Shapes of Nonadherent Cells",

abstract = "Nonadherent polarized cells have been observed to have a pearlike, elongated shape. Using a minimal model that describes the cell cortex as a thin layer of contractile active gel, we show that the anisotropy of active stresses, controlled by cortical viscosity and filament ordering, can account for this morphology. The predicted shapes can be determined from the flow pattern only; they prove to be independent of the mechanism at the origin of the cortical flow, and are only weakly sensitive to the cytoplasmic rheology. In the case of actin flows resulting from a contractile instability, we propose a phase diagram of three-dimensional cell shapes that encompasses nonpolarized spherical, elongated, as well as oblate shapes, all of which have been observed in experiment.",

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AU - Ruprecht, V.

AU - Wieser, S.

AU - Heisenberg, C. P.

AU - Voituriez, R.

PY - 2016/1/15

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N2 - Nonadherent polarized cells have been observed to have a pearlike, elongated shape. Using a minimal model that describes the cell cortex as a thin layer of contractile active gel, we show that the anisotropy of active stresses, controlled by cortical viscosity and filament ordering, can account for this morphology. The predicted shapes can be determined from the flow pattern only; they prove to be independent of the mechanism at the origin of the cortical flow, and are only weakly sensitive to the cytoplasmic rheology. In the case of actin flows resulting from a contractile instability, we propose a phase diagram of three-dimensional cell shapes that encompasses nonpolarized spherical, elongated, as well as oblate shapes, all of which have been observed in experiment.

AB - Nonadherent polarized cells have been observed to have a pearlike, elongated shape. Using a minimal model that describes the cell cortex as a thin layer of contractile active gel, we show that the anisotropy of active stresses, controlled by cortical viscosity and filament ordering, can account for this morphology. The predicted shapes can be determined from the flow pattern only; they prove to be independent of the mechanism at the origin of the cortical flow, and are only weakly sensitive to the cytoplasmic rheology. In the case of actin flows resulting from a contractile instability, we propose a phase diagram of three-dimensional cell shapes that encompasses nonpolarized spherical, elongated, as well as oblate shapes, all of which have been observed in experiment.

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DO - 10.1103/PhysRevLett.116.028102

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JO - Physical Review Letters

JF - Physical Review Letters

IS - 2

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ER -

Cortical Flow-Driven Shapes of Nonadherent Cells

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