Electrical synapse formation disrupts calcium-dependent exocytosis, but not vesicle mobilization

Electrical coupling exists prior to the onset of chemical connectivity at many developing and regenerating synapses. At cholinergic synapses in vitro, trophic factors facilitated the formation of electrical synapses and interfered with functional neurotransmitter release in response to photolytic elevations of intracellular calcium. In contrast, neurons lacking trophic factor induction and electrical coupling possessed flash-evoked transmitter release. Changes in cytosolic calcium and postsynaptic responsiveness to acetylcholine were not affected by electrical coupling. These data indicate that transient electrical synapse formation delayed chemical synaptic transmission by imposing a functional block between the accumulation of presynaptic calcium and synchronized, vesicular release. Despite the inability to release neurotransmitter, neurons that had possessed strong electrical coupling recruited secretory vesicles to sites of synaptic contact. These results suggest that the mechanism by which neurotransmission is disrupted during electrical synapse formation is downstream of both calcium influx and synaptic vesicle mobilization. Therefore, electrical synaptogenesis may inhibit synaptic vesicles from acquiring a readily releasable state. We hypothesize that gap junctions might negatively interact with exocytotic processes, thereby diminishing chemical neurotransmission.     

An action potential-induced and ryanodine sensitive calcium transient dynamically regulates transmitter release at synapses between Lymnaea neurons

The notion that calcium released through ryanodine receptors effects presynaptic neurotransmitter release is gaining acceptance with the observation that this calcium does indeed contribute to both action potential-evoked and spontaneous transmitter release in a variety of preparations. However, the dynamics of this calcium release and its impact on transmitter release has not yet been fully elucidated. Moreover, in contrast to vertebrate synapses, much less is known about the involvement of ryanodine receptors in the regulation of transmitter release at invertebrate synapses. In this study, we reconstructed specific synapses between individually identifiable preand postsynaptic neurons from Lymnaea to demonstrate that although ryanodine reduces the amplitude of the action potential-induced calcium transient, it does not however, alter the resting calcium level. These data suggest that action potential-induced calcium release through ryanodine receptors is fast and highly dynamic and in turn regulates transmitter release at reconstructed synapses between Lymnaea neurons. This study thus provides direct evidence that a dynamic ryanodine receptor-mediated calcium transient occurs with the presynaptic action potential.     

Distinct Effects of Clostridial Toxins on Activity-dependent Modulation of Autaptic Responses in Cultured Hippocampal Neurons

Clostridial neurotoxins proteolyse specific proteins implicated in synaptic vesicle exocytosis, but their actions on the release machinery in functional synapses is not well understood. Here we examine the effects of botulinum toxin A (BoNT/A) and tetanus toxin (TeTx) on autaptic transmission in cultured rat hippocampal neurons using whole-cell voltage clamp recordings. The proportion of cells responding to stimulation with an excitatory postsynaptic current (EPSC) and the magnitude of the remaining responses decreased gradually with increasing concentration of either toxin. However, the activity-dependent modulation (5 Hz repetitive stimulation) of EPSCs remaining after toxin inhibition differed markedly between the two toxins. The TeTx inhibition was associated with a persistent activity-dependent depression similar to that in control cells. In contrast, the BoNT/A inhibition was accompanied by a reversal of the modulation into facilitation, resembling that induced by lowering of the calcium concentration. These results demonstrate a difference between BoNT/A and TeTx in their mode of inhibition of synaptic vesicle exocytosis, which suggests that they exert their preferential actions at distinct steps of the release process.     

Active zone structure‐function relationships at the neuromuscular junction

The impact of presynaptic transmitter release site organization on synaptic function has been a vibrant area of research for synaptic physiologists. Because there is a highly nonlinear relationship between presynaptic calcium influx and subsequent neurotransmitter release at synapses, the organization and density of calcium sources (voltage‐gated calcium channels [VGCCs]) relative to calcium sensors located on synaptic vesicles is predicted to play a major role in shaping the dynamics of neurotransmitter release at a synapse. Here we review the history of structure‐function studies within transmitter release sites at the neuromuscular junction across three model preparations in an effort to discern the relationship between VGCC organization and synaptic function, and whether that organizational structure imparts evolutionary advantages for each species.     

Presynaptic protein kinase activity supports long-term potentiation at synapses between individual hippocampal neurons.

Simultaneous microelectrode recording from two individual synaptically connected neurons enables the direct analysis of synaptic transmission and plasticity at a minimal synaptic connection. We have recorded from pairs of CA3 pyramidal neurons in organotypic hippocampal slices to examine the properties of long-term potentiation (LTP) at such minimal connections. LTP in minimal connections was found to be identical to the NMDA-dependent LTP expressed by CA3-CA1 synapses, demonstrating this system provides a good model for the study of the mechanisms of LTP expression. The LTP at minimal synaptic connections does not behave as a simple increase in transmitter release probability, because the amplitude of unitary EPSCs can increase several-fold, unlike what is observed when release probability is increased by raising extracellular calcium. Taking advantage of the relatively short axon connecting neighboring CA3 neurons, we found it feasible to introduce pharmacological agents to the interior of presynaptic terminals by injection into the presynaptic soma and have used this technique to investigate presynaptic effects on basal transmission and LTP. Presynaptic injection of nicotinamide reduced basal transmission, but LTP in these pairs was essentially normal. In contrast, presynaptic injection of H-7 significantly depressed LTP but not basal transmission, indicating a specific role of presynaptic protein kinases in LTP. These results demonstrate that pharmacological agents can be directly introduced into the presynaptic cell and that a purely presynaptic perturbation can alter this plasticity.     

L-AP4 inhibits calcium currents and synaptic transmission via a G-protein-coupled glutamate receptor.

The AP4 (2-amino-4-phosphonobutyrate) receptor is a presynaptic glutamate receptor that inhibits transmitter release via an unknown mechanism. We examined the action of L-AP4 on voltage-dependent calcium currents and excitatory synaptic transmission on cultured olfactory bulb neurons using whole-cell voltage-clamp methods. In neurons dialyzed with GTP, L-AP4 inhibited high-threshold calcium currents evoked in barium solutions. The inhibition was irreversible in the presence of GTP-gamma-S and blocked by removing intracellular Mg2+ or by preincubation with pertussis toxin (PTX), consistent with the involvement of a PTX-sensitive G-protein. Dialysis with staurosporine or buffering of intracellular calcium to pCa less than 8 did not block the action of L-AP4, suggesting that protein phosphorylation or release of intracellular calcium stores was not involved in calcium current inhibition under these experimental conditions. PTX also blocked the L-AP4-induced inhibition of monosynaptic EPSPs evoked by intracellular stimulation of cultured mitral cells. These results suggest that the presynaptic AP4 receptor is a G-protein-coupled glutamate receptor, and that inhibition of calcium influx by a membrane-delimited action of a G-protein may account for L-AP4-induced presynaptic inhibition.     

Rab3A deletion selectively reduces spontaneous neurotransmitter release at the mouse neuromuscular synapse

Rab3A is a synaptic vesicle-associated GTP-binding protein thought to be involved in modulation of presynaptic transmitter release through regulation of vesicle trafficking and membrane fusion. Electrophysiological studies at central nervous system synapses of Rab3A null-mutant mice have indicated that nerve stimulation-evoked transmitter release and its short- and long-term modulation are partly dependent on Rab3A, whereas spontaneous uniquantal release is completely independent of it. Here, we studied the acetylcholine (ACh) release at the neuromuscular junction (NMJ) of diaphragm and soleus muscles from Rab3A-deficient mice with intracellular microelectrode methods. Surprisingly, we found 20-40% reduction of spontaneous ACh release but completely intact nerve action potential-evoked release at both high- and low-rate stimulation and during recovery from intense release. The ACh release induced by hypertonic medium was also unchanged, indicating that the pool of vesicles for immediate release is unaltered at the Rab3A-deficient NMJ. These results indicate a selective role of Rab3A in spontaneous transmitter release at the NMJ which cannot or only partly be taken over by the closely related Rab3B, Rab3C, or Rab3D isoforms when Rab3A is deleted. It has been hypothesized that Rab3A mutation underlies human presynaptic myasthenic syndromes, in which severely reduced nerve action potential-evoked ACh release at the NMJ causes paralysis. Our observation that Rab3A deletion does not reduce evoked ACh release at any stimulation rate at the mouse NMJ, argues against this hypothesis.     

Activity‐induced large amplitude postsynaptic mPSPs at soma–soma synapses between Lymnaea neurons

Spontaneous transmitter release has been observed at various synapses that permit analysis at a sufficient resolution as a miniature postsynaptic potential (mPSP). However, the precise mechanisms that regulate spontaneous transmitter release have not yet been fully defined. Activity and ligand‐mediated modulation of large amplitude, spontaneous events significantly enhances postsynaptic excitation in the absence of action potential activity suggesting a more complicated role for this mode of transmitter release, and thus warrants further analysis. Here, we used Lymnaea soma–soma synaptic connections to demonstrate that a transient increase in both the frequency and amplitude of spontaneous events (mPSPs) occurs following a short burst of action potentials in the presynaptic cell. These events were of presynaptic origin and the increase in mPSP amplitude could also be achieved with a stimulatory concentration of ryanodine. Ryanodine also occluded the activity‐induced increase in mPSP amplitude implicating calcium release from these channels in the production of large amplitude spontaneous transmitter release events. This suggests that presynaptic activity triggers ryanodine receptor‐mediated large amplitude minis, indicating that although these events are action potential‐independent, they are nevertheless responsive to the prior activity of the synapse. Synapse 63:117–125, 2009. ©2008 Wiley‐Liss, Inc.     

Rapid activation of presynaptic nicotinic acetylcholine receptors by nerve-released transmitter

Nicotine's ability to enhance neurotransmitter release has implicated presynaptic nicotinic acetylcholine receptors (nAChRs) in synaptic modulation, but there aze few examples where presynaptic nAChRs are known to be activated by nerve-released transmitter. We searched for endogenous activation of presynaptic nAChRs in the calyceal nerve terminals of the chick ciliary ganglion by imaging presynaptic calcium transients using dextran-coupled indicator dyes. The amplitude of Ca(+)signals recorded in individual nerve terminals was frequency dependent over 2-50 Hz. Calcium transients evoked by stimulation of the preganglionic nerve were significantly reduced (approximately 10-15%) by the nonspecific nAChR antagonist d-tubocurarine (d-TC; 100 microM) and the alpha7-specific antagonist methyllycaconitine (20-50 nM) but were not affected by 10 microM dihydro-beta-erythroidine, which should inhibit several non-alpha7 nAChRs. Feedback was rapid and did not require a stimulation-dependent build-up of transmitter, as d-TC and MLA reduced the amplitude of the first calcium transient in a 2-Hz train. Choline is an agonist at alpha7 nAChRs but is not the sole agonist in this system, as inhibition of acetylcholinesterase by echothiophate failed to reduce calcium transients. These results show that nerve-released acetylcholine (ACh) feeds back onto presynaptic alpha7 nAChRs to enhance calcium signals within the terminal. This feedback may help maintain the high rate of transmission at this cholinergic synapse.     

The effects of volatile anesthetics on synaptic and extrasynaptic GABA-induced neurotransmission

Examination of volatile anesthetic actions at single synapses provides more direct information by reducing interference by surrounding tissue and extrasynaptic modulation. We examined how volatile anesthetics modulate GABA release by measuring spontaneous or miniature GABA-induced inhibitory postsynaptic currents (mIPSCs, sIPSCs) or by measuring action potential-evoked IPSCs (eIPSCs) at individual synapses. Halothane increased both the amplitude and frequency of sIPSCs. Isoflurane and enflurane increased mIPSC frequency while sevoflurane had no effect. These anesthetics did not alter mIPSC amplitudes. Halothane increased the amplitude of eIPSCs, with a decrease in failure rate (Rf) and paired-pulse ratio. In contrast, isoflurane and enflurane decreased the eIPSC amplitude and increased Rf, while sevoflurane decreased the eIPSC amplitude without affecting Rf. Volatile anesthetics did not change kinetics except for sevoflurane, suggesting that presynaptic mechanisms dominate changes in neurotransmission. Each anesthetic showed somewhat different GABA-induced response and these results suggest that GABA-induced synaptic transmission cannot have a uniformly common site of action as suggested for volatile anesthetics. In contrast, all volatile anesthetics concentration-dependently enhanced the GABA-induced extrasynaptic currents. Extrasynaptic receptors containing α4 and α5 subunits are reported to have high sensitivities to volatile anesthetics. Also, inhibition of GABA uptake by volatile anesthetics results in higher extracellular GABA concentration, which may lead to prolonged activation of extrasynaptic GABA_A receptors. The extrasynaptic GABA-induced receptors may be major site of volatile anesthetic-induced neurotransmission.This article is part of a Special Issue entitled ‘Extrasynaptic ionotropic receptors’.     

Responses of excitatory hippocampal synapses to natural stimulus patterns reveal a decrease in short-term facilitation and increase in short-term depression during postnatal development

Schaffer collateral excitatory synapses onto CA1 pyramidal cells are subject to significant modulation by short-term plasticity. This presynaptic, history-dependent modulation of neurotransmitter release causes synaptic transmission to be sensitive to the frequency of the input. As a result, temporally irregular input patterns, such as those observed in vivo, produce synaptic responses over a very wide dynamic range that reflect a balance of short-term facilitation and short-term depression. The neonatal period is an important developmental period in the hippocampus, when functional representations of an animal's environment are being established through exploratory behavior. The strength of excitatory synapses and their modulation by short-term plasticity are critical to this process. One form of short-term plasticity, paired-pulse facilitation, has been shown to decrease as juvenile rats mature into young adults. However, little is known about the neonatal modulation of other forms of short-term plasticity, including the responses to temporally complex stimuli. We examined developmental modulation of the short-term dynamics of Schaffer collateral excitatory synapses onto CA1 pyramidal cells in acute hippocampal slices, using both constant frequency stimuli and natural stimulus patterns that were taken from in vivo recording of spike patterns of hippocampal cells. In response to constant frequency stimulation, synapses in slices from young adult rats (P28-P35) showed less short-term depression than did those in slices from juveniles (P12-P18). However, when the natural stimulus pattern (containing a wide mix of frequencies) was used, synapses from young adults instead showed more short-term depression and less short-term facilitation than did juveniles. Comparing the natural stimulus pattern responses with constant frequency stimulation of a similar frequency, we found that the average responses were similar in young adults (both showed modest depression). However, in juveniles, the natural pattern produced robust facilitation while constant frequency stimulation caused a large short-term depression. Our results reveal that there are developmental changes both in individual forms of short-term plasticity and in the relative balance between short-term facilitation and short-term depression that will alter the signal transfer characteristics of these synapses.     

Modulation of GABAergic transmission by endogenous glutamate in the rat supraoptic nucleus

The presence of group III metabotropic glutamate receptors on GABAergic terminals in the supraoptic nucleus suggests that the level of glutamate in the extracellular space may regulate synaptic strength at inhibitory synapses. To test this hypothesis we examined the consequences of increasing ambient glutamate on GABA-mediated synaptic activity in supraoptic neurons. The concentration of the excitatory amino acid in the extracellular space was increased pharmacologically by blocking glutamate transporters. Inhibition of the astrocyte-specific GLT-1 glutamate transporter led to a reversible decrease in evoked inhibitory postsynaptic current amplitude. This modulation had a presynaptic origin as revealed by analysis of paired-pulse ratio and miniature inhibitory currents. Furthermore, blocking group III metabotropic glutamate receptors with the specific antagonist MAP4 prevented the depression of GABAergic transmission induced by glutamate transporter blockade. Thus, presynaptic metabotropic glutamate receptors located on inhibitory terminals in the supraoptic nucleus appear to sense changes in ambient glutamate and modify GABA release accordingly. However, it seems that such changes need to reach a certain magnitude because the discrete deficit in glutamate clearance which occurs in the supraoptic nucleus of lactating rats is not sufficient to modulate GABA-mediated transmission. These results suggest that ambient glutamate contributes to the modulation of synaptic efficacy not only at glutamatergic synapses but also at inhibitory GABAergic synapses.     

Somatic membrane potential and Kv1 channels control spike repolarization in cortical axon collaterals and presynaptic boutons

The shape of action potentials invading presynaptic terminals, which can vary significantly from spike waveforms recorded at the soma, may critically influence the probability of synaptic neurotransmitter release. Revealing the conductances that determine spike shape in presynaptic boutons is important for understanding how changes in the electrochemical context in which a spike is generated, such as subthreshold depolarization spreading from the soma, can modulate synaptic strength. Utilizing recent improvements in the signal-to-noise ratio of voltage-sensitive dye imaging in mouse brain slices, we demonstrate that intracortical axon collaterals and en passant presynaptic terminals of layer 5 pyramidal cells exhibit a high density of Kv1 subunit-containing ion channels, which generate a slowly inactivating K(+) current critically important for spike repolarization in these compartments. Blockade of the current by low doses of 4-aminopyridine or α-dendrotoxin dramatically slows the falling phase of action potentials in axon collaterals and presynaptic boutons. Furthermore, subthreshold depolarization of the soma broadened action potentials in collaterals bearing presynaptic boutons, an effect abolished by blocking Kv1 channels with α-dendrotoxin. These results indicate that action potential-induced synaptic transmission may operate through a mix of analog-digital transmission owing to the properties of Kv1 channels in axon collaterals and presynaptic boutons.     

Modulation of glutamatergic transmission by sulfated steroids: role in fetal alcohol spectrum disorder

It is well established that sulfated steroids regulate synaptic transmission by altering the function of postsynaptic neurotransmitter receptors. In recent years, evidence from several laboratories indicates that these agents also regulate glutamatergic synaptic transmission at the presynaptic level in an age-dependent manner. In developing neurons, pregnenolone sulfate (PREGS) increases the probability of glutamate release, as evidenced by an increase in the frequency of AMPA receptor-mediated miniature excitatory postsynaptic currents and a decrease in paired-pulse facilitation. In hippocampal slices from postnatal day 3–5 rats, this effect is mediated by an increase in Ca²⁺ levels in the axonal terminal that depends on presynaptic NMDA receptors. This is followed by delayed potentiation of postsynaptic AMPA receptor currents. Importantly, depolarization of postsynaptic neurons, inhibition of hydroxysteroid sulfatase activity and acute exposure to ethanol mimics the effect of exogenous PREGS application. This developmental form of synaptic plasticity cannot be observed in slices from rats older than postnatal day 6, when presynaptic NMDA receptors are no longer expressed in CA1 hippocampal region. Both in the CA1 hippocampal region and the dentate gyrus of more mature rats, PREGS, dehydroepiandrosterone sulfate and hydroxysteroid sulfatase inhibitors increase paired-pulse facilitation, without affecting basal glutamate release probability. This effect depends on activation of σ₁-like receptors and G_i/o and involves a target in the release machinery that is downstream of residual Ca²⁺. These presynaptic actions of sulfated steroids could play important roles in physiological processes ranging from synapse maturation to learning and memory, as well as pathophysiological conditions such as fetal alcohol spectrum disorder.     

Differential effects of serotonin, FMRFamide, and small cardioactive peptide on multiple, distributed processes modulating sensorimotor synaptic transmission in Aplysia.

At least two processes contribute to the modulation by 5-HT of the connections between sensory neurons and motor neurons in Aplysia. The first involves broadening of the presynaptic spike through modulation of 5-HT-sensitive K+ channels that leads to elevated levels of intracellular Ca2+ and increased release of transmitter. A second process (or set of processes) apparently accounts for the amount of facilitation not produced by presynaptic spike broadening. This spike duration-independent (SDI) process is particularly prominent in depressed synapses. We used a protocol in which spikes were prebroadened into a range of durations in which further spike broadening by itself has little or no effect on facilitation of the EPSP.5-HT produced pronounced facilitation in depressed synapses under these conditions. Another modulatory agent, small cardioactive peptide (SCPb), also broadened spikes in sensory neurons but did not produce facilitation comparable to that produced by 5-HT. These results indicate that 5-HT activates the SDI process whereas SCPb fails to do the same. A 5 min preexposure to the modulatory peptide FMRFamide inhibited 5-HT-induced activation of the SDI process, whereas a 1 min preexposure did not. Another process(es) that may modulate synaptic efficacy in sensorimotor synapses involves changes in the properties of the motor (follower) neuron, such as input resistance. FMRFamide decreased the input resistance of postsynaptic neurons. This action could contribute to the effects of FMRFamide when administered alone, but it did not appear to be responsible for the inhibitory action of FMRFamide on 5-HT-induced facilitation. Neither 5-HT nor SCPb had a clear effect on input resistance. The actions of these three agents, therefore, seem to be differentially distributed among various pre- and postsynaptic processes involved in the modulation of synaptic transmission.     

Frequency dependence of synaptic vesicle exocytosis in aortic baroreceptor neurons and the role of group III mGluRs

Synaptic transmission between baroreceptor afferents and the nucleus tractus solitarius (NTS) is essential for reflex regulation of blood pressure. High frequency stimulation of the afferents in vivo leads to a decrease in synaptic strength and is generally attributed to reduction in presynaptic neurotransmitter release. It has been hypothesized that during high frequency stimulation glutamate a major neurotransmitter at the baroreceptor afferent terminals inhibits its own release via presynaptic group III metabotropic glutamate receptors (mGluRs). A key player in modulation of presynaptic release is vesicle exocytosis. The present study utilized cultured aortic baroreceptor neurons and the styryl dye FM2-10 to characterize (1) the dependence of exocytosis at these afferent nerve terminals on the frequency of neuronal activation, (2) the effect of duration of stimulation on the rate of exocytosis and (3) the role of mGluRs in the frequency-dependent modulation of exocytosis. Destaining in the FM2-10 loaded boutons during 3 min of stimulation, a measure of exocytosis, progressively decreased with increasing frequency (0.5, 1.0 and 10 Hz). Blockade of group III mGluRs with 300 microM (RS)-cyclopropyl-4-phosphonophenylglycine (CPPG) facilitated exocytosis evoked by 10 Hz stimulation but not at 0.5 Hz. The data suggest that aortic baroreceptor terminals exhibit frequency-dependent depression of exocytosis and support a role for group III mGluRs in the frequency-dependent modulation of exocytosis.     

Downregulation of Centaurin gamma1A increases synaptic transmission at Drosophila larval neuromuscular junctions

Adequate regulation of synaptic transmission is critical for appropriate neural circuit functioning. Although a number of molecules involved in synaptic neurotransmission have been identified, the molecular mechanisms regulating neurotransmission are not fully understood. Here, we focused on Centaurin gamma1A (CenG1A) and examined its role in synaptic transmission regulation using Drosophila larval neuromuscular junctions. CenG1A is a member of the Centaurin family, which contains Pleckstrin homology, ADP ribosylation factor GTPase‐activating protein, and ankyrin repeat domains. Due to the existence of these functional domains, CenG1A is proposed to be involved in the process of synaptic release; however, no evidence for this has been found to date. In this study, we investigated the potential role for CenG1A in the process of synaptic release by performing intracellular recordings in larval muscle cells. We found that neurotransmitter release from presynaptic cells was enhanced in cenG1A mutants. This effect was also observed in larvae with reduced CenG1A function in either presynaptic or postsynaptic cells. In addition, we revealed that suppressing CenG1A function in postsynaptic muscle cells led to an increase in the probability of neurotransmitter release, whereas its suppression in presynaptic neurons led to an increase in neurotransmitter release probability and an increase in the number of synaptic vesicles. These results suggested that CenG1A functions at both presynaptic and postsynaptic sites as a negative regulator of neurotransmitter release. Our study provided evidence for a key role of CenG1A in proper synaptic transmission at neuromuscular junctions.     

The involvement of GABAB receptors and coupled G-proteins in spinal GABAergic presynaptic inhibition.

GABA acts as a presynaptic inhibitory transmitter in the spinal cord. In the lamprey, it has recently been shown that it acts in this way at both primary sensory and motor system synapses and is important in the generation of a locomotor rhythm. Both GABAA and GABAB receptors are activated at these sites by GABA released during physiological activity. In some systems, GABAB receptor activation has been shown to lead to modulation of ion channel function indirectly through the action of a pertussis toxin (PTX)-sensitive G-protein. Here we have studied the mechanism of action of the presynaptic GABAB receptor in this system. GABAB receptor activation leads to a decrease in axonal membrane impedance and also to a reduction in the axonal action potential duration. The ionic basis for this response remains unknown, though it is not, unlike the response to GABAA receptor activation, mediated by an increase in conductance to Cl-. The effects of GABAB receptor antagonism with phaclofen are mimicked by pretreatment of the spinal cord with PTX. Because this procedure inactivates certain classes of G-proteins, it seemed likely that the GABAB receptor-mediated effects are initiated via a presynaptic population of PTX-sensitive G-proteins. Experiments in which only presynaptic G-proteins were interfered with indicate that this is so. Stable analogs of GTP and GDP were used to activate permanently or to antagonize, respectively, the GTP binding site in the presynaptic component of these spinal synapses. We conclude that GABAB receptor-mediated synaptic suppression in the spinal cord is caused by GTP binding to presynaptic G-proteins linked to the GABAB receptor.(ABSTRACT TRUNCATED AT 250 WORDS)     

Probing fundamental aspects of synaptic transmission with strontium.

Strontium is capable of supporting synaptic transmission, but release is dramatically different from that evoked in calcium. By measuring presynaptic strontium levels, we gain insight into the actions of strontium, which has implications for the identification of molecules involved in different aspects of synaptic transmission. We examined presynaptic divalent levels and synaptic release at the granule cell to stellate cell synapse in mouse cerebellar slices. We find that the prolonged duration of release and paired-pulse facilitation in the presence of strontium can be accounted for by the slower removal of strontium from the presynaptic terminal. Phasic and delayed release are both driven by strontium less effectively than by calcium, indicating that a heightened sensitivity to strontium is not a feature of the binding sites involved in facilitation and delayed release. We also find that the cooperativity for phasic release is 1.7 for strontium compared with 3.2 for calcium, suggesting that differential binding may help to identify the calcium sensor involved in phasic release.