Cell clusters adopt a collective amoeboid mode of migration in confined nonadhesive environments

Diane Laure Pagès; Emmanuel Dornier; Jean de Seze; Emilie Gontran; Ananyo Maitra; Aurore Maciejewski; Li Wang; Rui Luan; Jérôme Cartry; Canet Jourdan Charlotte; Joël Raingeaud; Grégoire Lemahieu; Marceline Lebel; Michel Ducreux; Maximiliano Gelli; Jean Yves Scoazec; Mathieu Coppey; Raphaël Voituriez; Matthieu Piel; Fanny Jaulin

doi:10.1126/sciadv.abp8416

Cell clusters adopt a collective amoeboid mode of migration in confined nonadhesive environments

Diane Laure Pagès, Emmanuel Dornier, Jean de Seze, Emilie Gontran, Ananyo Maitra, Aurore Maciejewski, Li Wang, Rui Luan, Jérôme Cartry, Canet Jourdan Charlotte, Joël Raingeaud, Grégoire Lemahieu, Marceline Lebel, Michel Ducreux, Maximiliano Gelli, Jean Yves Scoazec, Mathieu Coppey, Raphaël Voituriez, Matthieu Piel, Fanny Jaulin

Résultats de recherche: Contribution à un journal › Article › Revue par des pairs

25 Citations (Scopus)

Résumé

Cell migration is essential to living organisms and deregulated in cancer. Single cell’s migration ranges from traction-dependent mesenchymal motility to contractility-driven propulsive amoeboid locomotion, but collective cell migration has only been described as a focal adhesion–dependent and traction-dependent process. Here, we show that cancer cell clusters, from patients and cell lines, migrate without focal adhesions when confined into nonadhesive microfabricated channels. Clusters coordinate and behave like giant super cells, mobilizing their actomyosin contractility at the rear to power their migration. This polarized cortex does not sustain persistent retrograde flows, of cells or actin, like in the other modes of migration but rather harnesses fluctuating cell deformations, or jiggling. Theoretical physical modeling shows this is sufficient to create a gradient of friction forces and trigger directed cluster motion. This collective amoeboid mode of migration could foster metastatic spread by enabling cells to cross a wide spectrum of environments.

langue originale	Anglais
Numéro d'article	eabp8416
journal	Science Advances
Volume	8
Numéro de publication	39
Les DOIs	https://doi.org/10.1126/sciadv.abp8416
état	Publié - 30 sept. 2022

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10.1126/sciadv.abp8416

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Pagès, D. L., Dornier, E., Seze, J. D., Gontran, E., Maitra, A., Maciejewski, A., Wang, L., Luan, R., Cartry, J., Charlotte, C. J., Raingeaud, J., Lemahieu, G., Lebel, M., Ducreux, M., Gelli, M., Scoazec, J. Y., Coppey, M., Voituriez, R., Piel, M., & Jaulin, F. (2022). Cell clusters adopt a collective amoeboid mode of migration in confined nonadhesive environments. Science Advances, 8(39), Article eabp8416. https://doi.org/10.1126/sciadv.abp8416

@article{2aa49a6212a34dbe9f1b474233c46fad,

title = "Cell clusters adopt a collective amoeboid mode of migration in confined nonadhesive environments",

abstract = "Cell migration is essential to living organisms and deregulated in cancer. Single cell{\textquoteright}s migration ranges from traction-dependent mesenchymal motility to contractility-driven propulsive amoeboid locomotion, but collective cell migration has only been described as a focal adhesion–dependent and traction-dependent process. Here, we show that cancer cell clusters, from patients and cell lines, migrate without focal adhesions when confined into nonadhesive microfabricated channels. Clusters coordinate and behave like giant super cells, mobilizing their actomyosin contractility at the rear to power their migration. This polarized cortex does not sustain persistent retrograde flows, of cells or actin, like in the other modes of migration but rather harnesses fluctuating cell deformations, or jiggling. Theoretical physical modeling shows this is sufficient to create a gradient of friction forces and trigger directed cluster motion. This collective amoeboid mode of migration could foster metastatic spread by enabling cells to cross a wide spectrum of environments.",

author = "Pag{\`e}s, {Diane Laure} and Emmanuel Dornier and Seze, {Jean de} and Emilie Gontran and Ananyo Maitra and Aurore Maciejewski and Li Wang and Rui Luan and J{\'e}r{\^o}me Cartry and Charlotte, {Canet Jourdan} and Jo{\"e}l Raingeaud and Gr{\'e}goire Lemahieu and Marceline Lebel and Michel Ducreux and Maximiliano Gelli and Scoazec, {Jean Yves} and Mathieu Coppey and Rapha{\"e}l Voituriez and Matthieu Piel and Fanny Jaulin",

note = "Publisher Copyright: Copyright {\textcopyright} 2022 The Authors, some rights reserved.",

year = "2022",

month = sep,

day = "30",

doi = "10.1126/sciadv.abp8416",

language = "English",

volume = "8",

journal = "Science Advances",

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Pagès, DL, Dornier, E, Seze, JD, Gontran, E, Maitra, A, Maciejewski, A, Wang, L, Luan, R, Cartry, J, Charlotte, CJ, Raingeaud, J, Lemahieu, G, Lebel, M, Ducreux, M, Gelli, M, Scoazec, JY, Coppey, M, Voituriez, R, Piel, M & Jaulin, F 2022, 'Cell clusters adopt a collective amoeboid mode of migration in confined nonadhesive environments', Science Advances, VOL. 8, Numéro 39, eabp8416. https://doi.org/10.1126/sciadv.abp8416

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T1 - Cell clusters adopt a collective amoeboid mode of migration in confined nonadhesive environments

AU - Pagès, Diane Laure

AU - Dornier, Emmanuel

AU - Seze, Jean de

AU - Gontran, Emilie

AU - Maitra, Ananyo

AU - Maciejewski, Aurore

AU - Wang, Li

AU - Luan, Rui

AU - Cartry, Jérôme

AU - Charlotte, Canet Jourdan

AU - Raingeaud, Joël

AU - Lemahieu, Grégoire

AU - Lebel, Marceline

AU - Ducreux, Michel

AU - Gelli, Maximiliano

AU - Scoazec, Jean Yves

AU - Coppey, Mathieu

AU - Voituriez, Raphaël

AU - Piel, Matthieu

AU - Jaulin, Fanny

PY - 2022/9/30

Y1 - 2022/9/30

N2 - Cell migration is essential to living organisms and deregulated in cancer. Single cell’s migration ranges from traction-dependent mesenchymal motility to contractility-driven propulsive amoeboid locomotion, but collective cell migration has only been described as a focal adhesion–dependent and traction-dependent process. Here, we show that cancer cell clusters, from patients and cell lines, migrate without focal adhesions when confined into nonadhesive microfabricated channels. Clusters coordinate and behave like giant super cells, mobilizing their actomyosin contractility at the rear to power their migration. This polarized cortex does not sustain persistent retrograde flows, of cells or actin, like in the other modes of migration but rather harnesses fluctuating cell deformations, or jiggling. Theoretical physical modeling shows this is sufficient to create a gradient of friction forces and trigger directed cluster motion. This collective amoeboid mode of migration could foster metastatic spread by enabling cells to cross a wide spectrum of environments.

AB - Cell migration is essential to living organisms and deregulated in cancer. Single cell’s migration ranges from traction-dependent mesenchymal motility to contractility-driven propulsive amoeboid locomotion, but collective cell migration has only been described as a focal adhesion–dependent and traction-dependent process. Here, we show that cancer cell clusters, from patients and cell lines, migrate without focal adhesions when confined into nonadhesive microfabricated channels. Clusters coordinate and behave like giant super cells, mobilizing their actomyosin contractility at the rear to power their migration. This polarized cortex does not sustain persistent retrograde flows, of cells or actin, like in the other modes of migration but rather harnesses fluctuating cell deformations, or jiggling. Theoretical physical modeling shows this is sufficient to create a gradient of friction forces and trigger directed cluster motion. This collective amoeboid mode of migration could foster metastatic spread by enabling cells to cross a wide spectrum of environments.

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