Cellular dynamics emerging from turbulent flows steered by active filaments (2501.05971v1)

Abstract: We develop a continuum theory to describe the collective dynamics of deformable epithelial cells, using two tensor order parameters to distinguish the force-generating active filaments in the cells from their shape. The theory demonstrates how active flows create nematic domains of anisotropic cells, drive active turbulence, and create topological defects. We show that the filament flow-aligning parameter, $\lambda_{\tens{Q}}$, a rheological quantity that determines the response of the filaments to velocity gradients in the active flows, plays a significant, to date unappreciated, role in determining the pattern of extensional and compressional active flows. In a contractile cell layer, local flows are expected to align elongated cells perpendicular to the active filaments. However, with increasing $\lambda_{\tens{Q}}$, long-range correlations in the active turbulent flow field lead to extended regions where this alignment is parallel, as recently observed in experiments on confluent MDCK cell layers. Further, the two order parameter formalism allows us to distinguish defects in the filament director field, which contribute to the active driving, and those in the shape director field, measured in experiments, which are advected by the active flows. By considering the relative orientations of shape and filaments we are able to explain the surprising observation of defects moving towards their heads in contractile cell layers.