Enhancing the fidelity of neurotransmission by activity-dependent facilitation of presynaptic potassium currents.

Neurons convey information in bursts of spikes across chemical synapses where the fidelity of information transfer critically depends on synaptic input-output relationship. With a limited number of synaptic vesicles (SVs) in the readily releasable pool (RRP), how nerve terminals sustain transmitter release during intense activity remains poorly understood. Here we report that presynaptic K(+) currents evoked by spikes facilitate in a Ca(2+)-independent but frequency- and voltage-dependent manner. Experimental evidence and computer simulations demonstrate that this facilitation originates from dynamic transition of intermediate gating states of voltage-gated K(+) channels (Kvs), and specifically attenuates spike amplitude and inter-spike potential during high-frequency firing. Single or paired recordings from a mammalian central synapse further reveal that facilitation of Kvs constrains presynaptic Ca(2+) influx, thereby efficiently allocating SVs in the RRP to drive postsynaptic spiking at high rates. We conclude that presynaptic Kv facilitation imparts neurons with a powerful control of transmitter release to dynamically support high-fidelity neurotransmission.

Septins regulate developmental switching from microdomain to nanodomain coupling of Ca(2+) influx to neurotransmitter release at a central synapse.

Neurotransmitter release depends critically on close spatial coupling of Ca(2+) entry to synaptic vesicles at the nerve terminal; however, the molecular substrates determining their physical proximity are unknown. Using the calyx of Held synapse, where "microdomain" coupling predominates at immature stages and developmentally switches to "nanodomain" coupling, we demonstrate that deletion of the filamentous protein Septin 5 imparts immature synapses with striking morphological and functional features reminiscent of mature synapses. This includes synaptic vesicles tightly localized to active zones, resistance to the slow Ca(2+) buffer EGTA and a reduced number of Ca(2+) channels required to trigger single fusion events. Disrupting Septin 5 organization acutely transforms microdomain to nanodomain coupling and potentiates quantal output in immature wild-type terminals. These observations suggest that Septin 5 is a core molecular substrate that differentiates distinct release modalities at the central synapse.

Action potential evoked transmitter release in central synapses: insights from the developing calyx of Held.

Chemical synapses are the fundamental units that mediate communication between neurons in the mammalian brain. In contrast to the enormous progress made in mapping out postsynaptic contributions of receptors, scaffolding structures and receptor trafficking to synaptic transmission and plasticity, the small size of nerve terminals has largely precluded direct analyses of presynaptic modulation of excitability and transmitter release in central synapses. Recent studies performed in accessible synapses such as the calyx of Held, a giant axosomatic synapse in the sound localization circuit of the auditory brainstem, have provided tremendous insights into how central synapses regulate the dynamic gain range of synaptic transmission. This review will highlight experimental evidence that resolves several long-standing issues with respect to intricate interplays between the waveform of action potentials, Ca2+ currents and transmitter release and further conceptualize their relationships in a physiological context with theoretical models of the spatial organization of voltage-gated Ca2+ channels and synaptic vesicles at release sites.

Superfluous role of mammalian septins 3 and 5 in neuronal development and synaptic transmission.

The septin family of GTPases, first identified for their roles in cell division, are also expressed in postmitotic tissues. SEPT3 (G-septin) and SEPT5 (CDCrel-1) are highly expressed in neurons, enriched in presynaptic terminals, and associated with synaptic vesicles. These characteristics suggest that SEPT3 or SEPT5 might be important for synapse formation, maturation, or synaptic vesicle traffic. Since Sept5(-/-) mice do not show any overt neurological phenotypes, we generated Sept3(-/-) and Sept3(-/-) Sept5(-/-) mice and found that SEPT3 and SEPT5 are not essential for development, fertility, or viability. Changes in the expression of septins were noted in the absence of SEPT3, SEPT5, and both septins. SEPT5 association with other septins in brain tissue was unaffected by the removal of SEPT3. No abnormalities were observed in the gross morphology and synapses of the hippocampus. Similarly, axon development and synapse formation were unaffected in vitro. In cultured hippocampal neurons, the size of the recycling synaptic vesicle pool was unaltered in the absence of SEPT3. Furthermore, synaptic transmission at two different central synapses was not significantly affected in Sept3(-/-) Sept5(-/-) mice. These results indicate that SEPT3 and SEPT5 are dispensable for neuronal development as well as for synaptic vesicle fusion and recycling.

Activity-dependent changes in temporal components of neurotransmission at the juvenile mouse calyx of Held synapse.

The temporal fidelity of synaptic transmission is constrained by the reproducibility of time delays such as axonal conduction delay and synaptic delay, but very little is known about the modulation of these distinct components. In particular, synaptic delay is not generally considered to be modifiable under physiological conditions. Using simultaneous paired patch-clamp recordings from pre- and postsynaptic elements of the calyx of Held synapse, in juvenile mouse auditory brainstem slices, we show here that synaptic activity (20-200 Hz) leads to activity-dependent increases in synaptic delay and its variance as well as desynchronization of evoked responses. Such changes were most robust at 200 Hz in 2 mM extracellular Ca(2+) ([Ca(2+)](o)), and could be attenuated by lowering [Ca(2+)](o) to 1 mM, increasing temperature to 35 degrees C, or application of the GABA(B)R agonist baclofen, which inhibits presynaptic Ca(2+) currents (I(Ca)). Conduction delay also exhibited slight activity-dependent prolongation, but this prolongation was only sensitive to temperature, and not to [Ca(2+)](o) or baclofen. Direct voltage-clamp recordings of I(Ca) evoked by repeated action potential train template (200 Hz) revealed little jitter in the timing and kinetics of I(Ca) under various conditions, suggesting that increases in synaptic delay and its variance occur downstream of Ca(2+) entry. Loading the Ca(2+) chelator EGTA-AM into terminals reduced the progression rate, the extent of activity-dependent increases in various delay components, and their variance, implying that residual Ca(2+) accumulation in the presynaptic nerve terminal induces these changes. Finally, by applying a test pulse at different intervals following a 200 Hz train (150 ms), we demonstrated that prolongation in the various delay components reverses in parallel with recovery in synaptic strength. These observations suggest that a depletion of the readily releasable pool of SVs during high-frequency activity may downregulate not only synaptic strength but also decrease the temporal fidelity of neurotransmission at this and other central synapses.

Developmental transformation of the release modality at the calyx of Held synapse.

Ca(2+) influx through voltage-gated Ca(2+) channels (VGCCs) into nerve terminals triggers vesicular fusion and neurotransmitter release. However, it is unknown whether the coupling between VGCCs and synaptic vesicles (SVs) is developmentally regulated. By paired patch-clamp recordings from the mouse calyx of Held synapse, we show here that injection of a Ca(2+) buffer with slow binding kinetics (EGTA; 10 mm) potently attenuated transmitter release in young terminals [postnatal day 8 (P8)-P12] but produced little effect in older ones (P16-P18), suggesting that SVs in young synapses are loosely coupled to VGCCs, but the coupling tightens spatially during maturation. Using voltage paradigms that specifically recruit different numbers of VGCCs without changing the driving force for Ca(2+), we found that the Ca(2+) cooperativity (m), estimated from graded presynaptic Ca(2+) currents and transmitter release, was much higher in P8-P12 synapses (m = 4.8-5.5) than that in P16-P18 synapses (m = 2.8-3.0; 1 mm [Ca(2+)](o)), implying that the number of VGCCs or Ca(2+) domains required for release of single SVs decreases with maturation. The m value remained significantly different between two age groups at 35 degrees C or in 2 mm [Ca(2+)](o) and was independent of postsynaptic receptor desensitization. We demonstrated that release from P8-P12 terminals involved both N- and P/Q-type VGCCs, but P/Q-type-associated release sites specifically displayed low m values. These results suggest a developmental transformation of the release modality from "microdomain," involving cooperative action of many loosely coupled N- and P/Q-type VGCCs, to "nanodomain," in which opening of fewer tightly coupled P/Q-type VGCCs effectively induce a fusion event. Spatial tightening improves the release efficiency and is likely a critical step for the development of high-fidelity neurotransmission in this and other central synapses.