Abstract

Abstract Neurotransmitters are released by exocytosis from synaptic vesicles at the active zone in the presynaptic terminal. The scaffold of the active zone consists of only a few evolutionarily conserved proteins, including RIM, CAST/ELKS, and RIM-BP, and tethers Munc13 and Ca 2+ channels. The molecular principles that enable these proteins to mediate synaptic diversity have remained unclear. Here, we identified synapse type-specific molecular nanoconfigurations in the active zone by systematic quantification of active zone proteins using nanoscopy at two types of excitatory synapses and two types of inhibitory synapses in the rat hippocampal CA3 region. Quantitative analysis revealed that Munc13 content was particularly varied among the various synapse types and that the physical proximity of Ca 2+ channels to the active zone scaffolds correlated with the efficacy of neurotransmitter release. We propose that the active zone is a flexible supramolecular assembly that can tune its composition and spatial configuration to adjust neurotransmitter release.