Nature Communications (Jul 2023)

Allosteric activation of vinculin by talin

  • Florian Franz,
  • Rafael Tapia-Rojo,
  • Sabina Winograd-Katz,
  • Rajaa Boujemaa-Paterski,
  • Wenhong Li,
  • Tamar Unger,
  • Shira Albeck,
  • Camilo Aponte-Santamaria,
  • Sergi Garcia-Manyes,
  • Ohad Medalia,
  • Benjamin Geiger,
  • Frauke Gräter

DOI
https://doi.org/10.1038/s41467-023-39646-4
Journal volume & issue
Vol. 14, no. 1
pp. 1 – 16

Abstract

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Abstract The talin-vinculin axis is a key mechanosensing component of cellular focal adhesions. How talin and vinculin respond to forces and regulate one another remains unclear. By combining single-molecule magnetic tweezers experiments, Molecular Dynamics simulations, actin-bundling assays, and adhesion assembly experiments in live cells, we here describe a two-ways allosteric network within vinculin as a regulator of the talin-vinculin interaction. We directly observe a maturation process of vinculin upon talin binding, which reinforces the binding to talin at a rate of 0.03 s−1. This allosteric transition can compete with force-induced dissociation of vinculin from talin only at forces up to 10 pN. Mimicking the allosteric activation by mutation yields a vinculin molecule that bundles actin and localizes to focal adhesions in a force-independent manner. Hence, the allosteric switch confines talin-vinculin interactions and focal adhesion build-up to intermediate force levels. The ‘allosteric vinculin mutant’ is a valuable molecular tool to further dissect the mechanical and biochemical signalling circuits at focal adhesions and elsewhere.