Cell Reports (Aug 2024)

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 Chizhik,
  • Tabea A. Oswald,
  • Andreas Janshoff

Journal volume & issue
Vol. 43, no. 8
p. 114553

Abstract

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Summary: 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.

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