Allosteric Regulation of Human Plastins
Plastins/fimbrins are conserved actin-bundling proteins contributing to motility, cytokinesis, and other cellular processes by organizing actin assemblies of strikingly different geometries as in aligned bundles and branched networks. We propose that this unique ability stems from an allosteric communication between the two actin-binding domains (ABD1/2) engaged in a tight spatial association. We found that although ABD1 binds actin first, ABD2 can bind to actin three orders of magnitude stronger if not inhibited by an equally strong allosteric engagement with ABD1. Binding of ABD1 to actin lessened the inhibition, enabling weak bundling within aligned bundles. A mutation mimicking physiologically relevant phosphorylation at the ABD1-ABD2 interface strongly reduced their association, dramatically potentiating actin cross-linking. Cryo-EM reconstruction revealed the ABD1-actin interface and enabled modeling of the plastin bridge to confirm domain separation in parallel bundles. The characteristic domain organization with a strong allosteric inhibition imposed by ABD1 on ABD2 allows plastins to tune cross-linking, contributing to the assembly and remodeling of actin assemblies with different morphological and functional properties defining the unique place of plastins in actin organization.