Cytoskeleton-mediated forces regulate the assembly and function of integrin adhesions; however, the underlying mechanisms remain unclear. The tripartite IPP complex, comprising ILK, Parvin, and PINCH, mediates the integrin-actin link at Drosophila embryo muscle attachment sites (MASs). Here, we demonstrate a developmentally earlier function for the IPP complex: to reinforce integrin-extracellular matrix (ECM) adhesion in response to tension. In IPP-complex mutants, the integrin-ECM linkage at MASs breaks in response to intense muscle contractility. Mechanistically, the IPP complex is required to relay force-elicited signals that decelerate integrin turnover at the plasma membrane so that the integrin immobile fraction is adequate to withstand tension. Epistasis analysis shows that alleviation of muscle contractility, downregulation of endocytosis, and enhanced integrin binding to the ECM are sufficient to restore integrin-ECM adhesion and maintain integrin-adhesome organization in IPP-complex mutants. Our findings reveal a role for the IPP complex as an essential mechanosensitive regulatory switch of integrin turnover in vivo.
Keywords: endocytosis; integrin-linked kinase; mechanosensing; mechanotransduction.
Copyright © 2016 The Authors. Published by Elsevier Inc. All rights reserved.