Force-dependent activation of actin elongation factor mDia1 protects the cytoskeleton from mechanical damage and promotes stress fiber repair.

Plasticity of cell mechanics underlies a wide range of cell and tissue behaviors allowing cells to migrate through narrow spaces, resist shear forces, and safeguard against mechanical damage. Such plasticity depends on spatiotemporal regulation of the actomyosin cytoskeleton, but mechanisms of adaptive change in cell mechanics remain elusive. Here, we report a mechanism of mechanically activated actin polymerization at focal adhesions (FAs), specifically requiring the actin elongation factor mDia1. By combining live-cell imaging with mathematical modeling, we show that actin polymerization at FAs exhibits pulsatile dynamics where spikes of mDia1 activity are triggered by contractile forces. The suppression of mDia1-mediated actin polymerization increases tension on stress fibers (SFs) leading to an increased frequency of spontaneous SF damage and decreased efficiency of zyxin-mediated SF repair. We conclude that tension-controlled actin polymerization acts as a safety valve dampening excessive tension on the actin cytoskeleton and safeguarding SFs against mechanical damage.

Quantitative Analysis of Myofibroblast Contraction by Traction Force Microscopy.

Myofibroblasts play important roles in physiological processes such as wound healing and tissue repair. While high contractile forces generated by the actomyosin network enable myofibroblasts to physically contract the wound and bring together injured tissue, prolonged and elevated levels of contraction also drive the progression of fibrosis and cancer. However, quantitative mapping of these forces has been difficult due to their extremely low magnitude ranging from 100 pN/µm2 to 2 nN/µm2. Here, we provide a protocol to measure cellular forces exerted on two-dimensional compliant elastic hydrogels. We describe the fabrication of polyacrylamide hydrogels labeled with fluorescent fiducial markers, functionalization of substrates with ECM proteins, setting up the experiment, and imaging procedures. We demonstrate the application of this technique for quantitative analysis of traction forces exerted by myofibroblasts.