Dynamic nanoscale architecture of synaptic vesicle fusion in mouse hippocampal neurons

During neurotransmission, presynaptic action potentials trigger synaptic vesicle fusion with the plasma membrane within milliseconds. To visualize membrane dynamics before, during, and right after vesicle fusion at central synapses under near-native conditions, we developed an experimental strategy for time-resolved in situ cryo-electron tomography with millisecond temporal resolution. We coupled optogenetic stimulation with cryofixation and confirmed the stimulation-induced release of neurotransmitters via cryo-confocal microscopy of a fluorescent glutamate sensor. Our morphometric analysis of tomograms from stimulated and control synapses allowed us to characterize five states of vesicle fusion intermediates ranging from stalk formation to the formation, opening, and collapsing of a fusion pore. Based on these measurements, we generated a coarse-grained simulation of a synaptic vesicle approaching the active zone membrane. Both, our morphofunctional and computational analyses, support a model in which calcium-triggered fusion is initiated from synaptic vesicles in close proximity to the active zone membrane, whereby neither tight docking nor an induction of membrane curvature at the active zone are favorable. Numbers of filamentous tethers closely correlated to the distance between vesicle and membrane, but not to their respective fusion readiness, indicating that the formation of multiple tethers is required for synaptic vesicle recruitment preceding fusion.