Tension sensing by FAK governs nuclear mechanotransduction, endothelial transcriptome and fate

Vascular endothelium forms a restrictive barrier to defend the underlying tissue against uncontrolled influx of circulating protein and immune cells. Mechanisms that mediate the transition from restrictive to leaky endothelium, a hallmark of tissue injury exemplified by acute lung injury (ALI), remain elusive. Using endothelial cell (EC)-Fak ^-/- mice, we show that FAK sensing and transmission of mechanical tension to the EC nucleus governs cell fate. In FAK- deleted EC, increased EC tension induced by Rho kinase caused tyrosine phosphorylation of nuclear envelope protein, emerin at Y74/Y95, and its localization in a nuclear cap. Activated emerin stimulated DNMT3a activity and methylation of the KLF2 promoter, impairing the restrictive EC transcriptome, including S1PR1 . Inhibiting emerin phosphorylation or DNMT3a activity enabled KLF2 transcription of S1PR1 , rescuing the restrictive EC phenotype in EC-Fak ^-/- lungs. Thus, FAK sensing of tension transmission to the nucleus is crucial for maintaining a restrictive EC fate and lung homeostasis.