Nonlinear microscale mechanics of actin networks governed by coupling of filament crosslinking and stabilization

Abstract

AbstractActin plays a vital role in maintaining the stability and rigidity of biological cells while allowing for cell motility and shape change. The semiflexible nature of actin filaments – along with the myriad actin-binding proteins (ABPs) that serve to crosslink, bundle, and stabilize filaments – are central to this multifunctionality. The effect of ABPs on the structural and mechanical properties of actin network mechanics has been the topic of fervent investigation over the past few decades, revealing diverse structures from isotropic percolated networks to heterogeneous bundles that depend on the crosslinker type and concentration. Yet, the impact of filament stabilization and stiffening via ABPs on the nonlinear response of crosslinked networks has yet to be explored. Here, we perform optical tweezers microheology measurements to characterize the nonlinear force response and relaxation dynamics of actin networks in the presence of varying concentrations ofα-actinin, which transiently crosslinks actin filaments, and phalloidin, which stabilizes filamentous actin and increases its persistence length. We show that crosslinking and stabilization can act both synergistically and antagonistically to tune the network resistance to nonlinear straining. For example, phalloidin-stabilization leads to enhanced elastic response and reduced dissipation at large strains and timescales, while the initial microscale force response is reduced compared to networks without phalloidin. Moreover, we find that stabilization switches this initial response from that of stress-stiffening to softening despite the increased filament stiffness that phalloidin confers. Finally, we show that both crosslinking and stabilization are necessary to elicit these emergent features, while the effect of stabilization on networks without crosslinkers is much more subdued. We suggest that these intriguing mechanical properties arise from the competition and cooperation between filament connectivity, bundling, and rigidification, shedding light on how ABPs with distinct roles can act in concert to mediate diverse mechanical properties of the cytoskeleton and bio-inspired polymeric materials.