Litcius/Paper detail

Cell-substrate distance fluctuations of confluent cells enable fast and coherent collective migration

Marcel Jipp, Bente D. Wagner, Lisa Egbringhoff, Andreas Teichmann, Angela Rübeling, Paul Nieschwitz, Alf Honigmann, Alexey I. Chizhik, Tabea A. Oswald, Andreas Janshoff

2024Cell Reports12 citationsDOIOpen Access PDF

Abstract

Collective cell migration is an emergent phenomenon, with long-range cell-cell communication influenced by various factors, including transmission of forces, viscoelasticity of individual cells, substrate interactions, and mechanotransduction. We investigate how alterations in cell-substrate distance fluctuations, cell-substrate adhesion, and traction forces impact the average velocity and temporal-spatial correlation of confluent monolayers formed by either wild-type (WT) MDCKII cells or zonula occludens (ZO)-1/2-depleted MDCKII cells (double knockdown [dKD]) representing highly contractile cells. The data indicate that confluent dKD monolayers exhibit decreased average velocity compared to less contractile WT cells concomitant with increased substrate adhesion, reduced traction forces, a more compact shape, diminished cell-cell interactions, and reduced cell-substrate distance fluctuations. Depletion of basal actin and myosin further supports the notion that short-range cell-substrate interactions, particularly fluctuations driven by basal actomyosin, significantly influence the migration speed of the monolayer on a larger length scale.

Topics & Concepts

BiophysicsTractive forceMonolayerSubstrate (aquarium)IntracellularCellMechanotransductionActinCell biologyCell migrationTraction (geology)ChemistryBiologyPhysicsBiochemistryEcologyThermodynamicsPaleontologyCellular Mechanics and Interactions3D Printing in Biomedical ResearchMicrofluidic and Bio-sensing Technologies