Mechanosensitive calcium signaling in response to cell shape changes promotes epithelial tight junction remodeling by activating RhoA

Epithelia maintain an effective barrier by remodeling cell-cell junctions in response to mechanical stimuli. Cells often respond to mechanical stress through activating RhoA and remodeling actomyosin. Previously, we found that local leaks in the barrier are rapidly repaired by localized, transient activation of RhoA – ″Rho flares″ – but how Rho flares are initiated remains unknown. Here, we discovered that intracellular calcium flashes occur in Xenopus laevis epithelial cells undergoing Rho flare-mediated remodeling of tight junctions. Calcium flashes originate at the site of barrier leaks and propagate into the cell. Depletion of intracellular calcium or inhibition of mechanosensitive calcium channels (MSC) reduced the amplitude of calcium flashes and diminished the activation of Rho flares. Furthermore, MSC-dependent calcium influx was necessary to maintain global barrier function by regulating local repair of tight junctions through efficient junction contraction. We propose that MSC-dependent calcium flashes are an important mechanism allowing epithelial cells to sense and respond to local leaks induced by mechanical stimuli.