Filament transport supports contractile steady states of actin networks.

Unlabelled: In all eukaryotic cells, the actin cytoskeleton is maintained in a dynamic steady-state. Actin filaments are continuously displaced from cell periphery, where they assemble, towards the cell's center, where they disassemble. Despite this constant flow and turnover, cellular networks maintain their overall architecture constant. How such a flow of material can support dynamic yet steady cellular architectures remains an open question. To investigate the role of myosin-based forces in contractile steady-states of actin networks, we used a reconstituted system based on a minimal set of purified proteins, namely actin, myosin and actin regulators. We found that, contrary to previous bulk experiments, when confined in microwells, the actin network could self-organize into ordered arrangements of contractile bundles, flowing continuously without collapsing. This was supported by three-dimensional fluxes of actin filaments, spatially separated yet balancing each other. Unexpectedly, maintaining these fluxes did not depend on filament nucleation or elongation, but solely on filament transport. Ablation of the contractile bundles abolished the flux balance and led to network collapse. These findings demonstrate that the dynamic steady state of actin networks can be sustained by filament displacement and recirculation, independently of filament assembly and disassembly.

Significance Statement: Cellular structures continuously self-renew, with new material constantly being added and removed while maintaining overall structural stability. This is particularly true for the actin cytoskeleton, whose components are continuously assembled, displaced, and reassembled. Understanding this process is fundamental to uncovering how cells regulate their architecture and adapt to stimuli.Here, we reconstitute an in vitro actomyosin network capable of contracting steadily over time without collapsing, relying solely on myosin-based transport. These findings demonstrate that a minimal system consisting of actin and molecular motors can effectively recapitulate the ability of actin networks to self-organize into stable yet dynamic architectures.