Fast, precise, and sustained synaptic transmission at high frequency is thought to be crucial for the task of sound localization in the auditory brainstem. However, recordings from the calyx of Held synapse have revealed severe frequency-dependent synaptic depression, which tends to degrade the exact timing of postsynaptic spikes. Here we investigate the functional changes occurring throughout the critical period of synapse refinement from immature calyx terminal [postnatal day 5 (P5)] to after the onset of hearing (P12-P14). Surprisingly, for recordings near physiological temperature (35°C), we find that P14 synapses are already able to follow extremely high input rates of up to 800 Hz. This ability stems in part from a remarkable shortening of presynaptic action potentials, which may lead to a lowering of release probability and decrease in synaptic delays during development. In addition, AMPA receptor-mediated EPSCs as well as quantal synaptic currents acquired progressively faster kinetics, although their mean amplitudes did not change significantly. NMDA receptor-mediated EPSCs, however, diminished with age, as indicated by a 50% reduction in mean amplitude and faster decay kinetics. Finally, the degree of synaptic depression was greatly attenuated with age, presumably because of a 2.5-fold or larger increase in the releasable pool of vesicles, which together with a decreasing release probability produces a fairly constant EPSC amplitude. This finely tuned orchestra of developmental changes thus simultaneously promotes speed while preventing premature vesicle pool depletion during prolonged bouts of firing. A few critical days in postnatal development can thus have a large impact on synaptic function.
Bursts of neuronal activity are transmitted more effectively as synapses mature. However, the mechanisms that control synaptic efficiency during development are poorly understood. Here, we study postnatal changes in synaptic ultrastructure and exocytosis in a calyx-type nerve terminal. Vesicle pool size, exocytotic efficiency (amount of exocytosis per Ca influx), Ca current facilitation, and the number of active zones (AZs) increased with age, whereas AZ area, number of docked vesicles per AZ, and release probability decreased with age. These changes led to AZs that are less prone to multivesicular release, resulting in reduced AMPA receptor saturation and desensitization. A greater multiplicity of small AZs with few docked vesicles, a larger pool of releasable vesicles, and a higher efficiency of release thus promote prolonged high-frequency firing in mature synapses.
Neuroligins (NL1-NL4) are postsynaptic adhesion proteins that control the maturation and function of synapses in the central nervous system (CNS). Loss-of-function mutations in NL4 are linked to rare forms of monogenic heritable autism, but its localization and function are unknown. Using the retina as a model system, we show that NL4 is preferentially localized to glycinergic postsynapses and that the loss of NL4 is accompanied by a reduced number of glycine receptors mediating fast glycinergic transmission. Accordingly, NL4-deficient ganglion cells exhibit slower glycinergic miniature postsynaptic currents and subtle alterations in their stimuluscoding efficacy, and inhibition within the NL4-deficient retinal network is altered as assessed by electroretinogram recordings. These data indicate that NL4 shapes network activity and information processing in the retina by modulating glycinergic inhibition. Importantly, NL4 is also targeted to inhibitory synapses in other areas of the CNS, such as the thalamus, colliculi, brainstem, and spinal cord, and forms complexes with the inhibitory postsynapse proteins gephyrin and collybistin in vivo, indicating that NL4 is an important component of glycinergic postsynapses.synaptogenesis | inhibitory transmission | visual processing I n rodents, postsynaptic adhesion proteins of the neuroligin family (NL1-NL4) are expressed throughout the central nervous system (CNS) (1-3) and essential for synapse organization and function (2-5). In vivo, each NL isoform localizes to specific synapse subpopulations, with NL1, NL2, and NL3 predominantly associating with glutamatergic, GABAergic, or both types of postsynapses, respectively (1, 6-9).Thus far, the distribution and function of the fourth NL isoform has remained unclear, despite the wide interest triggered by the causal link of specific loss-of-function mutations in NL4 to cases of autism, which led to the notion that aberrant synaptic transmission may cause autism spectrum disorders (ASDs) (10).We examined the distribution of NL4 in the mouse retina, a well-characterized region of the CNS with distinct, topographically organized glutamatergic, GABAergic, and glycinergic synapses, which has recently allowed us to characterize crucial aspects of NL2 distribution and function (8). Additionally, we assessed NL4 function by studying synaptic activity and visual processing in the NL4-deficient (NL4-KO; ref.3) mouse retina. Finally, we studied NL4 localization in the rest of the CNS and identified some of its key binding partners at the synapse. Results NL4 Is Localized to Glycinergic Postsynapses in the Retina.We characterized the distribution of NL4 by immunohistochemistry by using an isoform-specific antibody (3) (Fig. 1). A punctate labeling was detected in the inner plexiform layer (IPL) of wildtype (WT) but not NL4-KO retinae (Fig. 1A). NL4-positive puncta were abundant in the outer IPL but sparse in the rest of the IPL (Fig. 1A), which is reminiscent of glycine receptor (GlyR) distribution in the retina (11,12). Indeed, upon co...
Naϩ channel recovery from inactivation limits the maximal rate of neuronal firing. However, the properties of presynaptic Na ϩ channels are not well established because of the small size of most CNS boutons. Here we study the Na ϩ currents of the rat calyx of Held terminal and compare them with those of postsynaptic cells. We find that presynaptic Na ϩ currents recover from inactivation with a fast, single-exponential time constant (24°C, of 1.4 -1.8 ms; 35°C, of 0.5 ms), and their inactivation rate accelerates twofold during development, which may contribute to the shortening of the action potential as the terminal matures. In contrast, recordings from postsynaptic cells in brainstem slices, and acutely dissociated, reveal that their Na ϩ currents recover from inactivation with a doubleexponential time course ( fast of 1.2-1.6 ms; slow of 80 -125 ms; 24°C). Surprisingly, confocal immunofluorescence revealed that Na ϩ channels are mostly absent from the calyx terminal but are instead highly concentrated in an unusually long (Ϸ20 -40 m) unmyelinated axonal heminode. Outside-out patch recordings confirmed this segregation. Expression of Na v 1.6 ␣-subunit increased during development, whereas the Na v 1.2 ␣-subunit was not present. Serial EM reconstructions also revealed a long pre-calyx heminode, and biophysical modeling showed that exclusion of Na ϩ channels from the calyx terminal produces an action potential waveform with a shorter halfwidth. We propose that the high density and polarized locus of Na ϩ channels on a long heminode are critical design features that allow the mature calyx of Held terminal to fire reliably at frequencies near 1 kHz.
Short-term synaptic plasticity, the dynamic alteration of synaptic strength during high-frequency activity, is a fundamental characteristic of all synapses. At the calyx of Held, repetitive activity eventually results in short-term synaptic depression, which is in part due to the gradual exhaustion of releasable synaptic vesicles. This is counterbalanced by Ca(2+)-dependent vesicle replenishment, but the molecular mechanisms of this replenishment are largely unknown. We studied calyces of Held in knockin mice that express a Ca(2+)-Calmodulin insensitive Munc13-1(W464R) variant of the synaptic vesicle priming protein Munc13-1. Calyces of these mice exhibit a slower rate of synaptic vesicle replenishment, aberrant short-term depression and reduced recovery from synaptic depression after high-frequency stimulation. Our data establish Munc13-1 as a major presynaptic target of Ca(2+)-Calmodulin signaling and show that the Ca(2+)-Calmodulin-Munc13-1 complex is a pivotal component of the molecular machinery that determines short-term synaptic plasticity characteristics.
Glutamatergic synapses show large variations in strength and shortterm plasticity (STP). We show here that synapses displaying an increased strength either after posttetanic potentiation (PTP) or through activation of the phospholipase-C-diacylglycerol pathway share characteristic properties with intrinsically strong synapses, such as (i) pronounced short-term depression (STD) during high-frequency stimulation; (ii) a conversion of that STD into a sequence of facilitation followed by STD after a few conditioning stimuli at low frequency; (iii) an equalizing effect of such conditioning stimulation, which reduces differences among synapses and abolishes potentiation; and (iv) a requirement of long periods of rest for reconstitution of the original STP pattern. These phenomena are quantitatively described by assuming that a small fraction of "superprimed" synaptic vesicles are in a state of elevated release probability (p ∼ 0.5). This fraction is variable in size among synapses (typically about 30%), but increases after application of phorbol ester or during PTP. The majority of vesicles, released during repetitive stimulation, have low release probability (p ∼ 0.1), are relatively uniform in number across synapses, and are rapidly recruited. In contrast, superprimed vesicles need several seconds to be regenerated. They mediate enhanced synaptic strength at the onset of burst-like activity, the impact of which is subject to modulation by slow modulatory transmitter systems.posttetanic potentiation | short-term plasticity | calyx of Held | Munc13 | phorbol ester G lutamatergic synapses display a variety of dynamic changes in response to stimulation with action potential (AP) trains, ranging from immediate short-term depression to facilitation followed by depression (1). Both pharmacological (2-6) and molecular (7-9) perturbations have been described, which change such patterns from one to the other in a given synapse. Short-term plasticity (STP) has been shown to underlie many basic signal processing tasks of circuits in the central nervous system (10-13) and rapid changes of STP have been considered "... to be an almost necessary condition for the existence of (short-lived) activity states in the central nervous system" (ref. 14, p. 247). The balance between facilitation and depression is shifted during posttetanic potentiation (PTP) (15) and behavioral states are dynamically regulated by STP (16). Regulation occurs through slow, modulatory transmitter systems (17, 18). However, many open questions regarding the mechanisms underlying such changes remain. Modulation of presynaptic voltage-gated Ca 2+ channels by slow transmitter systems is probably the most powerful mechanism of changing release probability (p) of synaptic vesicles (SVs) (19)(20)(21). Changes in intrinsic [Ca 2+ ] i sensitivity of the release apparatus also contribute and have been investigated in the context of the phospholipase-C-diacylglycerol (PLC-DAG) signaling pathway (22-26) and posttetanic potentiation (15,(27)(28)(29)(30), but the infl...
We have characterized developmental changes in the kinetics and quantal parameters of action potential (AP)-evoked neurotransmitter release during maturation of the calyx of Held synapse. Quantal size (q) and peak amplitudes of evoked EPSCs increased moderately, whereas the fraction of vesicles released by single APs decreased. During synaptic depression induced in postnatal day (P) 5-7 synapses by 10-100 Hz stimulation, q declined rapidly to 40-12% of its initial value. The decrease in q was generally smaller in more mature synapses (P12-14), but quite severe for frequencies ≥ 300 Hz. The stronger decline of q in immature synapses resulted from a slower recovery from desensitization, presumably due to delayed glutamate clearance. Recovery from this desensitization followed an exponential time course with a time constant of ∼480 ms in P5-7 synapses, and sped up > 20-fold during maturation. Deconvolution analysis of EPSCs revealed a significant acceleration of the release time course during development, which was accompanied by a 2-fold increase of the peak release rate. During long 100 Hz trains, more mature synapses were able to sustain average rates of 8-10 quanta s −1 per active zone for phasic release. The rates of asynchronous vesicle release increased transiently > 35-fold immediately after such stimuli and decayed rapidly with an exponential time constant of ∼50 ms to low resting levels of spontaneous release. However, even following extended periods of 100 Hz stimulation, the amount of asynchronous release was relatively minor with peak rates of less than 5% of the average rate of synchronous release measured at steady state during the tetani. Therefore, a multitude of mechanisms seems to converge on the generation of fast, temporally precise and reliable high-frequency transmission at the mature calyx of Held synapse.
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