Collective rotational motion of freely-expanding T84 epithelial cell colonies

TL;DR

This study demonstrates that collective rotational motion in epithelial cell colonies can spontaneously occur without physical confinement, depending on size and shape, challenging previous assumptions about the necessity of spatial constraints.

Contribution

It provides the first systematic evidence that cell confinement is not required for collective rotation, highlighting the role of colony size and shape in this process.

Findings

Spontaneous collective rotation occurs in freely expanding colonies.

Rotation depends on colony size and shape, with smaller, round colonies rotating more.

No spatial confinement is necessary for collective rotation.

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 confined epithelial cells. 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, a case which has received scarce attention in the literature. We find 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 collective rotation was size and shape dependent: a highly coordinated disk-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 low as compared to the angular velocity. 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 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.