PI(3)P signaling regulates endosomal flux underlying developmental synaptic remodeling via Rab4
Rab4 GTPase, essential for endosomal sorting and trafficking, is implicated in synaptic atrophy and dementia. To uncover the underlying mechanism, we studied the correlation between Rab4 vesicle transport in axons and episodic remodeling of synapses in the central nervous system (CNS) of Drosophila larvae. We found that synapse-bound traffic and presynaptic enrichment of Rab4 vesicles increase during the programmed, transient contraction of synapses in the ventral neuropil region at a specific larval stage. This coincides with the episodic activation of insulin and Vps34-mediated signaling, which elevates phosphatidylinositol-3-phosphate levels on Rab4 vesicles. The presence of this phospholipid on Rab4-associated vesicles recruit a PX-domain-containing motor protein, Klp98A, accelerating synapse-directed traffic. This, in turn, increases presynaptic enrichment of Rab4 during the developmentally programmed synapse contraction phase. Our findings elucidate the molecular mechanism that regulates developmental synaptic plasticity in the CNS via insulin signaling and directed axonal transport of endosomes.