Monoamine-induced diacylglycerol signaling rapidly accumulates Unc13 in nanoclusters for fast presynaptic potentiation

Neuromodulators control mood, arousal, and behavior by inducing synaptic plasticity via G-protein coupled receptors. Long-term potentiation of presynaptic neurotransmitter release requires structural changes, but how fast potentiation is achieved within minutes remains enigmatic. Using the Drosophila melanogaster neuromuscular junction, we show that on the timescale of one minute, octopamine, the invertebrate analog of nor-epinephrine, rapidly potentiates evoked neurotransmitter release by a G protein coupled pathway involving presynaptic OAMB receptors and phospholipase C. No changes of presynaptic calcium influx were seen, but confocal signals of the release factor Unc13A and the scaffolding protein Bruchpilot increased within one minute of octopamine treatment. On the same timescale, live, single-molecule imaging of endogenously tagged Unc13 revealed its instantly reduced motility and its increased concentration in synaptic nanoclusters with potentiation. Presynaptic knockdown of Unc13A fully blocked fast potentiation and removal of its N-terminal localization sequence delocalized the protein fragment to the cytosol, but it was rapidly recruited to the plasma membrane by DAG analog phorbol esters and octopamine, pointing to a role in C-terminal domains. Point mutation of endogenous Unc13 disrupting diacylglycerol-binding to its C1 domain blocked plasticity-induced nanoscopic enrichment and synaptic potentiation. The mutation increased basal neurotransmission but reduced Unc13 levels, revealing a gain of function and potential homeostatic compensation. The mutation also blocked phorbol ester-induced potentiation, decreased the calcium-sensitivity of neurotransmission and caused short-term synaptic depression. At the organismal level, the mutation reduced locomotion and survival while enhancing reproduction. Thus, the Unc13 C1 domain mediates acute subsynaptic compaction of Unc13 under monoamine-induced potentiation and influences short-term plasticity, locomotion, reproduction, and survival.