Sequeira, C.; Di Francescantonio, S.; Motta, G.; Kogata, N.; Way, M.; Gomes, E. R.

Skeletal muscle postnatal growth depends on myoblast fusion with pre-existing myofibers, but whether myofibers actively regulate this process remains unclear. The Arp2/3 complex, which nucleates branched actin networks, is required for myoblast fusion during embryogenesis, but its role in postnatal myofibers is unknown. Here, we investigated the role of the Arp2/3 complex in myofibers using an inducible skeletal muscle - specific Arpc4 knockout model. We find that loss of Arp2/3 in myofibers impairs myonuclear accretion, resulting in smaller myofibers and reduced muscle strength. Satellite cells are still activated and able to differentiate but accumulate around Arpc4-deficient myofibers rather than fusing, pointing to a myofiber-intrinsic defect. In co-culture, myofibers form long-lived membrane protrusions enriched in Arp2/3 at myoblast contact sites, and optogenetic activation of protrusion in myofibers induced myoblast fusion. Genetic depletion of Arpc4 in myofibers markedly reduces membrane protrusions both in vitro and in vivo. These findings unveil a fundamental role for the Arp2/3 complex in postnatal muscle growth and reveal a mechanism by which myofibers actively extend membrane protrusions to drive myoblast fusion. This repositions myofibers as active fusogenic partners and cell-autonomous drivers of their own nuclear accretion.