Caveolae are small membrane pits with fundamental roles in mechanotransduction. Several studies have shown that caveolae flatten out in response to an increase in membrane tension, thereby acting as a mechanosensitive membrane reservoir that buffers acute mechanical stress. The dynamic assembly and disassembly of caveolae has also been implicated in the control of RhoA/ROCK-mediated actomyosin contractility at the rear of migrating cells. However, how membrane tension controls the organisation of caveolae and caveolae-mediated mechanotransduction is poorly understood. To address this, we systematically quantified protein-protein interactions of caveolin-1 in migrating RPE1 cells at steady state and in response to an acute increase in membrane tension using biotin-based proximity labelling and quantitative mass spectrometry. Our data show that caveolae are highly enriched at the rear of migrating RPE1 cells and that membrane tension rapidly and reversibly disassembles the caveolar protein coat. Membrane tension also dislodges caveolin-1 from focal adhesion proteins and several mechanosensitive cortical actin regulators including filamins and cortactin. In addition, we present evidence that ROCK and the RhoGAP ARHGAP29 are associated with caveolin-1 in a membrane tension-dependent manner, and that ARHGAP29 regulates caveolin-1 Y14 phosphorylation, caveolae rear localisation, and RPE1 cell migration. Taken together, our work uncovers a membrane tension-sensitive coupling between caveolae and the rear-localised F-actin cytoskeleton. This provides a framework for dissecting the molecular mechanisms underlying caveolae-regulated mechanotransduction pathways.
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