PLoS Computational Biology (Jul 2023)

Computational model of integrin adhesion elongation under an actin fiber.

  • Samuel Campbell,
  • Michelle C Mendoza,
  • Aravind Rammohan,
  • Matthew E McKenzie,
  • Tamara C Bidone

DOI
https://doi.org/10.1371/journal.pcbi.1011237
Journal volume & issue
Vol. 19, no. 7
p. e1011237

Abstract

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Cells create physical connections with the extracellular environment through adhesions. Nascent adhesions form at the leading edge of migrating cells and either undergo cycles of disassembly and reassembly, or elongate and stabilize at the end of actin fibers. How adhesions assemble has been addressed in several studies, but the exact role of actin fibers in the elongation and stabilization of nascent adhesions remains largely elusive. To address this question, here we extended our computational model of adhesion assembly by incorporating an actin fiber that locally promotes integrin activation. The model revealed that an actin fiber promotes adhesion stabilization and elongation. Actomyosin contractility from the fiber also promotes adhesion stabilization and elongation, by strengthening integrin-ligand interactions, but only up to a force threshold. Above this force threshold, most integrin-ligand bonds fail, and the adhesion disassembles. In the absence of contraction, actin fibers still support adhesions stabilization. Collectively, our results provide a picture in which myosin activity is dispensable for adhesion stabilization and elongation under an actin fiber, offering a framework for interpreting several previous experimental observations.