Abstract
Degeneration of neuromuscular synapses is a key pathological feature of spinal muscular atrophy (SMA), yet cellular mechanisms underlying synapse dysfunction remain elusive. Here, we show that pharmacological stimulation with Roscovitine triggers the assembly of Munc13-1 release sites that relies on its local translation. Our findings show that presynaptic mRNA levels and local synthesis of Munc13-1 are diminished in motoneurons from SMA mice and hiPSC-derived motoneurons from SMA patients. Replacement of the Munc13-1 3'UTR with that of Synaptophysin1 rescues Munc13-1 mRNA transport in SMA motoneurons and restores the nanoscale architecture of presynaptic Munc13-1 release sites. Restoration of Munc13-1 levels leads to functional synaptic recovery in cultured SMA motoneurons. Furthermore, SMA mice cross-bred with a conditional knock-in mouse expressing modified Munc13-1 with a heterologous 3'UTR display attenuated synapse and neurodegeneration and improved motor function. Identifying Munc13-1 as an SMA modifier underscores the potential of targeting synapses to mitigate neuromuscular dysfunction in SMA.