Synaptic ribbons are large proteinaceous scaffolds at the active zone of ribbon synapses that are specialized for rapid sustained synaptic vesicles exocytosis. A single ribbon-specific protein is known, RIBEYE, suggesting that ribbons may be constructed from RIBEYE protein. RIBEYE knockdown in zebrafish, however, only reduced but did not eliminate ribbons, indicating a more ancillary role. Here, we show in mice that full deletion of RIBEYE abolishes all presynaptic ribbons in retina synapses. Using paired recordings in acute retina slices, we demonstrate that deletion of RIBEYE severely impaired fast and sustained neurotransmitter release at bipolar neuron/AII amacrine cell synapses and rendered spontaneous miniature release sensitive to the slow Ca
2+-buffer EGTA, suggesting that synaptic ribbons mediate nano-domain coupling of Ca 2+ channels to synaptic vesicle exocytosis. Our results show that RIBEYE is essential for synaptic ribbons as such, and may organize presynaptic nano-domains that position release-ready synaptic vesicles adjacent to Ca 2+ channels.
How synaptic-vesicle release is controlled at the basic release structure, the active zone, is poorly understood. By performing cell-attached current and capacitance recordings predominantly at single active zones in rat calyces, we found that single active zones contained 5-218 (mean, 42) calcium channels and 1–10 (mean, 5) readily releasable vesicles (RRVs) and released 0–5 vesicles during a 2-ms depolarization. Large variation in the number of calcium channels caused wide variation in release strength (measured during a 2-ms depolarization) by regulating the RRV release probability (PRRV) and the RRV number. Consequently, an action potential opened ~1–35 (mean, ~7) channels, resulting in different release probabilities at different active zones. As the number of calcium-channels determined PRRV, it critically influenced whether subsequent release would be facilitated or depressed. Regulating calcium channel density at active zones may thus be a major mechanism to yield synapses with different release properties and plasticity. These findings may explain large differences reported at synapses regarding release strength (release of 0, 1 or multiple vesicles), PRRV, short-term plasticity, calcium transients and the requisite calcium-channel number for triggering release.
Synchronous release triggered by Ca binding to synaptotagmin-1, -2, or -9 is thought to drive fast synaptic transmission, whereas asynchronous release induced by Ca binding to synaptotagmin-7 is thought to produce delayed synaptic signaling, enabling prolonged synaptic computations. However, it is unknown whether synaptotagmin-7-dependent asynchronous release performs a physiological function at fast synapses lacking a prolonged signaling mode, such as the calyx of Held synapse. Here, we show at the calyx synapse that synaptotagmin-7-dependent asynchronous release indeed does not produce a prolonged synaptic signal after a stimulus train and does not contribute to short-term plasticity, but induces a steady-state, asynchronous postsynaptic current during stimulus trains. This steady-state postsynaptic current does not increase overall synaptic transmission but instead sustains reliable generation of postsynaptic spikes that are precisely time locked to presynaptic spikes. Thus, asynchronous release surprisingly functions, at least at some synapses, to sustain high-fidelity neurotransmission driven by synchronous release during high-frequency stimulus trains.
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