- Welf, Erik S;
- Miles, Christopher E;
- Huh, Jaewon;
- Sapoznik, Etai;
- Chi, Joseph;
- Driscoll, Meghan K;
- Isogai, Tadamoto;
- Noh, Jungsik;
- Weems, Andrew D;
- Pohlkamp, Theresa;
- Dean, Kevin;
- Fiolka, Reto;
- Mogilner, Alex;
- Danuser, Gaudenz
Despite the well-established role of actin polymerization as a driving mechanism for cell protrusion, upregulated actin polymerization alone does not initiate protrusions. Using a combination of theoretical modeling and quantitative live-cell imaging experiments, we show that local depletion of actin-membrane links is needed for protrusion initiation. Specifically, we show that the actin-membrane linker ezrin is depleted prior to protrusion onset and that perturbation of ezrin's affinity for actin modulates protrusion frequency and efficiency. We also show how actin-membrane release works in concert with actin polymerization, leading to a comprehensive model for actin-driven shape changes. Actin-membrane release plays a similar role in protrusions driven by intracellular pressure. Thus, our findings suggest that protrusion initiation might be governed by a universal regulatory mechanism, whereas the mechanism of force generation determines the shape and expansion properties of the protrusion.