Cells have many types of actin structures, which must assemble from a common monomer pool. Yet, it remains poorly understood how monomers are distributed to and shared between different filament networks. Simplified model systems suggest that monomers are limited and heterogeneous, which alters actin network assembly through biased polymerization and internetwork competition. However, less is known about how monomers influence complex actin structures, where different networks competing for monomers overlap and are functionally interdependent. One example is the leading edge of migrating cells, which contains filament networks generated by multiple assembly factors. The leading edge dynamically switches between the formation of different actin structures, such as lamellipodia or filopodia, by altering the balance of these assembly factors' activities. Here, we sought to determine how the monomer-binding protein profilin 1 (PFN1) controls the assembly and organization of actin in mammalian cells. Actin polymerization in PFN1 knockout cells was severely disrupted, particularly at the leading edge, where both Arp2/3 and Mena/VASP-based filament assembly was inhibited. Further studies showed that in the absence of PFN1, Arp2/3 no longer localizes to the leading edge and Mena/VASP is non-functional. Additionally, we discovered that discrete stages of internetwork competition and collaboration between Arp2/3 and Mena/VASP networks exist at different PFN1 concentrations. Low levels of PFN1 caused filopodia to form exclusively at the leading edge, while higher concentrations inhibited filopodia and favored lamellipodia and pre-filopodia bundles. These results demonstrate that dramatic changes to actin architecture can be made simply by modifying PFN1 availability.
ABD) preferentially engages actin in the presence of mechanical load across actin filaments (''mechanoaccumulation''), while vinculin's ABD does not. Simultaneous optical trapping and confocal microscopy experiments demonstrate that a load of 1pN across actin activates a-catenin ABD binding. Atomic-resolution cryo-EM structures of the metavinculin ABD-actin (2.9Å ) and a-catenin ABD-actin (3.2Å ) complexes demonstrate both ABDs undergo major conformational changes upon actin engagement, prominently at their N-and C-termini, and their C-terminal regions differentially refold to bind distinct sites on the filament surface. A C-terminal truncation of a-catenin's ABD constitutively binds actin regardless of force, and a chimeric protein of vinculin's ABD featuring a-catenin's flexible termini gains mechanoaccumulation activity, suggesting the a-catenin C-terminus-actin interaction is necessary and sufficient for mechanically regulated binding. This work, for the first time, establishes a force-regulated actin-binding mechanism in structural detail, and lays the groundwork for the rational design of therapeutics targeting cytoskeletal mechanotransduction pathways.
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