Cell divisions imprint long lasting elastic strain fields in epithelial tissues

TL;DR

This study models how cell divisions in epithelial tissues generate force dipoles that cause long-lasting elastic strains, enabling quantification of cellular forces and their impact on tissue mechanics.

Contribution

It introduces a method to infer force dipoles from strain fields, linking cellular events to tissue-scale mechanical forces in epithelial tissues.

Findings

Cell divisions produce transient isotropic force dipoles.

Force dipoles remain detectable for about 3.5 hours post-division.

The tissue behaves as a linearly elastic sheet allowing force inference.

Abstract

A hallmark of biological tissues, viewed as complex cellular materials, is the active generation of mechanical stresses by cellular processes, such as cell divisions. Each cellular event generates a force dipole that deforms the surrounding tissue. Therefore, a quantitative description of these force dipoles, and their consequences on tissue mechanics, is one of the central problems in understanding the overall tissue mechanics. In this work we analyze previously published experimental data on fruit fly \textit{D. melanogaster} wing epithelia to quantitatively describe the deformation fields induced by a cell-scale force dipole. We find that the measured deformation field can be explained by a simple model of fly epithelium as a linearly elastic sheet. This fact allows us to use measurements of the strain field around cellular events, such as cell divisions, to infer the magnitude and dynamics of the mechanical forces they generate. In particular, we find that cell divisions exert a transient isotropic force dipole field, corresponding to the temporary localisation of the cell nucleus to the tissue surface during the division, and traceless-symmetric force dipole field that remains detectable from the tissue strain field for up to about $3.5$ hours after the division. This is the timescale on which elastic strains are erased by other mechanical processes and therefore it corresponds to the tissue fluidization timescale. In summary, we have developed a method to infer force dipoles induced by cell divisions, by observing the strain field in the surrounding tissues. Using this method we quantitatively characterize mechanical forces generated during a cell division, and their effects on the tissue mechanics.