Recovery of structural integrity of epithelial monolayer in response to massive apoptosis-induced defects

Abstract

AbstractApoptosis exists ubiquitously in organisms and plays an essential role in maintaining the homeostasis of functional tissues. While the signaling pathway of cell apoptosis has been widely studied, the mechanism of how apoptotic cells regulate the structural homeostasis of a living tissue still remains largely elusive. Using a functional epithelial monolayer as a model system, we find that the integrity of the epithelium is interrupted by apoptosis-induced defects, with an increasing permeability to small molecules across the epithelium. The defects promote a structural reorganization through enhanced cell spreading and migratory dynamics, resulting in a quick recovery of epithelium integrity. Moreover, we show the epithelial monolayer remodeling is driven by local enhanced traction force after apoptosis, which triggers the process of fluidization and mesenchymal-like migration. Our results show the quick recovery of epithelial homeostasis when being interrupted by cell apoptosis, and indicate the importance of apoptosis-induced mechanical force in mediating cell behaviors to maintain the structural integrity of epithelium.