Collective rotational motion of freely expanding T84 epithelial cell colonies

Research output: Contribution to journalJournal articleResearchpeer-review

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Collective rotational motion of freely expanding T84 epithelial cell colonies. / Ascione, Flora; Caserta, Sergio; Esposito, Speranza; Rachela, Valeria Villella; Maiuri, Luigi; Nejad, Mehrana R.; Doostmohammadi, Amin; Yeomans, Julia M.; Guido, Stefano.

In: Journal of the Royal Society Interface, Vol. 20, No. 199, 20220719, 22.02.2023.

Research output: Contribution to journalJournal articleResearchpeer-review

Harvard

Ascione, F, Caserta, S, Esposito, S, Rachela, VV, Maiuri, L, Nejad, MR, Doostmohammadi, A, Yeomans, JM & Guido, S 2023, 'Collective rotational motion of freely expanding T84 epithelial cell colonies', Journal of the Royal Society Interface, vol. 20, no. 199, 20220719. https://doi.org/10.1098/rsif.2022.0719

APA

Ascione, F., Caserta, S., Esposito, S., Rachela, V. V., Maiuri, L., Nejad, M. R., Doostmohammadi, A., Yeomans, J. M., & Guido, S. (2023). Collective rotational motion of freely expanding T84 epithelial cell colonies. Journal of the Royal Society Interface, 20(199), [20220719]. https://doi.org/10.1098/rsif.2022.0719

Vancouver

Ascione F, Caserta S, Esposito S, Rachela VV, Maiuri L, Nejad MR et al. Collective rotational motion of freely expanding T84 epithelial cell colonies. Journal of the Royal Society Interface. 2023 Feb 22;20(199). 20220719. https://doi.org/10.1098/rsif.2022.0719

Author

Ascione, Flora ; Caserta, Sergio ; Esposito, Speranza ; Rachela, Valeria Villella ; Maiuri, Luigi ; Nejad, Mehrana R. ; Doostmohammadi, Amin ; Yeomans, Julia M. ; Guido, Stefano. / Collective rotational motion of freely expanding T84 epithelial cell colonies. In: Journal of the Royal Society Interface. 2023 ; Vol. 20, No. 199.

Bibtex

@article{2955dbbea7ca46f99e21649477f2b606,
title = "Collective rotational motion of freely expanding T84 epithelial cell colonies",
abstract = "Coordinated rotational motion is an intriguing, yet still elusive mode of collective cell migration, which is relevant in pathological and morphogenetic processes. Most of the studies on this topic have been carried out on epithelial cells plated on micropatterned substrates, where cell motion is confined in regions of well-defined shapes coated with extracellular matrix adhesive proteins. The driver of collective rotation in such conditions has not been clearly elucidated, although it has been speculated that spatial confinement can play an essential role in triggering cell rotation. Here, we study the growth of epithelial cell colonies freely expanding (i.e. with no physical constraints) on the surface of cell culture plates and focus on collective cell rotation in such conditions, a case which has received scarce attention in the literature. One of the main findings of our work is that coordinated cell rotation spontaneously occurs in cell clusters in the free growth regime, thus implying that cell confinement is not necessary to elicit collective rotation as previously suggested. The extent of collective rotation was size and shape dependent: a highly coordinated disc-like rotation was found in small cell clusters with a round shape, while collective rotation was suppressed in large irregular cell clusters generated by merging of different clusters in the course of their growth. The angular motion was persistent in the same direction, although clockwise and anticlockwise rotations were equally likely to occur among different cell clusters. Radial cell velocity was quite low as compared to the angular velocity, in agreement with the free expansion regime where cluster growth is essentially governed by cell proliferation. A clear difference in morphology was observed between cells at the periphery and the ones in the core of the clusters, the former being more elongated and spread out as compared to the latter. Overall, our results, to our knowledge, provide the first quantitative and systematic evidence that coordinated cell rotation does not require a spatial confinement and occurs spontaneously in freely expanding epithelial cell colonies, possibly as a mechanism for the system.",
keywords = "epithelial cells, active matter, collective rotation, living matter, active nematics, COHERENT ANGULAR MOTION, MIGRATION, MONOLAYER, DIFFUSION, DYNAMICS, DIVISION, GUIDANCE, BEHAVIOR, FLOW",
author = "Flora Ascione and Sergio Caserta and Speranza Esposito and Rachela, {Valeria Villella} and Luigi Maiuri and Nejad, {Mehrana R.} and Amin Doostmohammadi and Yeomans, {Julia M.} and Stefano Guido",
year = "2023",
month = feb,
day = "22",
doi = "10.1098/rsif.2022.0719",
language = "English",
volume = "20",
journal = "Journal of the Royal Society Interface",
issn = "2042-8898",
publisher = "Royal Society, The",
number = "199",

}

RIS

TY - JOUR

T1 - Collective rotational motion of freely expanding T84 epithelial cell colonies

AU - Ascione, Flora

AU - Caserta, Sergio

AU - Esposito, Speranza

AU - Rachela, Valeria Villella

AU - Maiuri, Luigi

AU - Nejad, Mehrana R.

AU - Doostmohammadi, Amin

AU - Yeomans, Julia M.

AU - Guido, Stefano

PY - 2023/2/22

Y1 - 2023/2/22

N2 - Coordinated rotational motion is an intriguing, yet still elusive mode of collective cell migration, which is relevant in pathological and morphogenetic processes. Most of the studies on this topic have been carried out on epithelial cells plated on micropatterned substrates, where cell motion is confined in regions of well-defined shapes coated with extracellular matrix adhesive proteins. The driver of collective rotation in such conditions has not been clearly elucidated, although it has been speculated that spatial confinement can play an essential role in triggering cell rotation. Here, we study the growth of epithelial cell colonies freely expanding (i.e. with no physical constraints) on the surface of cell culture plates and focus on collective cell rotation in such conditions, a case which has received scarce attention in the literature. One of the main findings of our work is that coordinated cell rotation spontaneously occurs in cell clusters in the free growth regime, thus implying that cell confinement is not necessary to elicit collective rotation as previously suggested. The extent of collective rotation was size and shape dependent: a highly coordinated disc-like rotation was found in small cell clusters with a round shape, while collective rotation was suppressed in large irregular cell clusters generated by merging of different clusters in the course of their growth. The angular motion was persistent in the same direction, although clockwise and anticlockwise rotations were equally likely to occur among different cell clusters. Radial cell velocity was quite low as compared to the angular velocity, in agreement with the free expansion regime where cluster growth is essentially governed by cell proliferation. A clear difference in morphology was observed between cells at the periphery and the ones in the core of the clusters, the former being more elongated and spread out as compared to the latter. Overall, our results, to our knowledge, provide the first quantitative and systematic evidence that coordinated cell rotation does not require a spatial confinement and occurs spontaneously in freely expanding epithelial cell colonies, possibly as a mechanism for the system.

AB - Coordinated rotational motion is an intriguing, yet still elusive mode of collective cell migration, which is relevant in pathological and morphogenetic processes. Most of the studies on this topic have been carried out on epithelial cells plated on micropatterned substrates, where cell motion is confined in regions of well-defined shapes coated with extracellular matrix adhesive proteins. The driver of collective rotation in such conditions has not been clearly elucidated, although it has been speculated that spatial confinement can play an essential role in triggering cell rotation. Here, we study the growth of epithelial cell colonies freely expanding (i.e. with no physical constraints) on the surface of cell culture plates and focus on collective cell rotation in such conditions, a case which has received scarce attention in the literature. One of the main findings of our work is that coordinated cell rotation spontaneously occurs in cell clusters in the free growth regime, thus implying that cell confinement is not necessary to elicit collective rotation as previously suggested. The extent of collective rotation was size and shape dependent: a highly coordinated disc-like rotation was found in small cell clusters with a round shape, while collective rotation was suppressed in large irregular cell clusters generated by merging of different clusters in the course of their growth. The angular motion was persistent in the same direction, although clockwise and anticlockwise rotations were equally likely to occur among different cell clusters. Radial cell velocity was quite low as compared to the angular velocity, in agreement with the free expansion regime where cluster growth is essentially governed by cell proliferation. A clear difference in morphology was observed between cells at the periphery and the ones in the core of the clusters, the former being more elongated and spread out as compared to the latter. Overall, our results, to our knowledge, provide the first quantitative and systematic evidence that coordinated cell rotation does not require a spatial confinement and occurs spontaneously in freely expanding epithelial cell colonies, possibly as a mechanism for the system.

KW - epithelial cells

KW - active matter

KW - collective rotation

KW - living matter

KW - active nematics

KW - COHERENT ANGULAR MOTION

KW - MIGRATION

KW - MONOLAYER

KW - DIFFUSION

KW - DYNAMICS

KW - DIVISION

KW - GUIDANCE

KW - BEHAVIOR

KW - FLOW

U2 - 10.1098/rsif.2022.0719

DO - 10.1098/rsif.2022.0719

M3 - Journal article

C2 - 36872917

VL - 20

JO - Journal of the Royal Society Interface

JF - Journal of the Royal Society Interface

SN - 2042-8898

IS - 199

M1 - 20220719

ER -

ID: 340974205