Geometric friction directs cell migration

M. Le Berre; Yan Jun Liu; J. Hu; Paolo Maiuri; O. Bénichou; R. Voituriez; Y. Chen; M. Piel

doi:10.1103/PhysRevLett.111.198101

Geometric friction directs cell migration

M. Le Berre
, Yan Jun Liu
, J. Hu
, Paolo Maiuri
, O. Bénichou
, R. Voituriez
, Y. Chen
, M. Piel

CNRS UMR144
PSL research University & IPSL
Université Pierre et Marie Curie
Laboratoire Jean Perrin

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

Abstract

In the absence of environmental cues, a migrating cell performs an isotropic random motion. Recently, the breaking of this isotropy has been observed when cells move in the presence of asymmetric adhesive patterns. However, up to now the mechanisms at work to direct cell migration in such environments remain unknown. Here, we show that a nonadhesive surface with asymmetric microgeometry consisting of dense arrays of tilted micropillars can direct cell motion. Our analysis reveals that most features of cell trajectories, including the bias, can be reproduced by a simple model of active Brownian particle in a ratchet potential, which we suggest originates from a generic elastic interaction of the cell body with the environment. The observed guiding effect, independent of adhesion, is therefore robust and could be used to direct cell migration both in vitro and in vivo.

Original language	English
Article number	198101
Journal	Physical Review Letters
Volume	111
Issue number	19
DOIs	https://doi.org/10.1103/PhysRevLett.111.198101
Publication status	Published - 7 Nov 2013
Externally published	Yes

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title = "Geometric friction directs cell migration",

abstract = "In the absence of environmental cues, a migrating cell performs an isotropic random motion. Recently, the breaking of this isotropy has been observed when cells move in the presence of asymmetric adhesive patterns. However, up to now the mechanisms at work to direct cell migration in such environments remain unknown. Here, we show that a nonadhesive surface with asymmetric microgeometry consisting of dense arrays of tilted micropillars can direct cell motion. Our analysis reveals that most features of cell trajectories, including the bias, can be reproduced by a simple model of active Brownian particle in a ratchet potential, which we suggest originates from a generic elastic interaction of the cell body with the environment. The observed guiding effect, independent of adhesion, is therefore robust and could be used to direct cell migration both in vitro and in vivo.",

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AU - Le Berre, M.

AU - Liu, Yan Jun

AU - Hu, J.

AU - Maiuri, Paolo

AU - Bénichou, O.

AU - Voituriez, R.

AU - Chen, Y.

AU - Piel, M.

PY - 2013/11/7

Y1 - 2013/11/7

N2 - In the absence of environmental cues, a migrating cell performs an isotropic random motion. Recently, the breaking of this isotropy has been observed when cells move in the presence of asymmetric adhesive patterns. However, up to now the mechanisms at work to direct cell migration in such environments remain unknown. Here, we show that a nonadhesive surface with asymmetric microgeometry consisting of dense arrays of tilted micropillars can direct cell motion. Our analysis reveals that most features of cell trajectories, including the bias, can be reproduced by a simple model of active Brownian particle in a ratchet potential, which we suggest originates from a generic elastic interaction of the cell body with the environment. The observed guiding effect, independent of adhesion, is therefore robust and could be used to direct cell migration both in vitro and in vivo.

AB - In the absence of environmental cues, a migrating cell performs an isotropic random motion. Recently, the breaking of this isotropy has been observed when cells move in the presence of asymmetric adhesive patterns. However, up to now the mechanisms at work to direct cell migration in such environments remain unknown. Here, we show that a nonadhesive surface with asymmetric microgeometry consisting of dense arrays of tilted micropillars can direct cell motion. Our analysis reveals that most features of cell trajectories, including the bias, can be reproduced by a simple model of active Brownian particle in a ratchet potential, which we suggest originates from a generic elastic interaction of the cell body with the environment. The observed guiding effect, independent of adhesion, is therefore robust and could be used to direct cell migration both in vitro and in vivo.

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DO - 10.1103/PhysRevLett.111.198101

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SN - 0031-9007

VL - 111

JO - Physical Review Letters

JF - Physical Review Letters

IS - 19

M1 - 198101

ER -

Geometric friction directs cell migration

Abstract

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