Membrane-associated polymerases deliver most of the actin subunits to a lamellipodial network

Actin filaments are two-stranded protein polymers that form the basic structural unit of the eukaryotic actin cytoskeleton. While filaments assembled from purified actin in vitro elongate when soluble monomers bind to free filament ends, in cells the mechanism of filament elongation is less clear. Most monomeric actin in the cytoplasm is bound to the accessory protein profilin, and many regulators of filament assembly recruit actin-profilin complexes to membrane surfaces where they locally accelerate filament elongation. Employing quantitative live-cell imaging of actin-profilin fusion proteins and biochemically defined mutants of the branched actin regulator, WAVE1, we find that only ∼25% of the actin in leading-edge lamellipodial networks enters directly from solution, while the majority enters via membrane-associated polymerases.