Blockade of the KATP channel Kir6.2 by memantine represents a novel mechanism relevant to Alzheimer's disease therapy.

Here, we report a novel target of the drug memantine, ATP-sensitive K+ (KATP) channels, potentially relevant to memory improvement. We confirmed that memantine antagonizes memory impairment in Alzheimer's model APP23 mice. Memantine increased CaMKII activity in the APP23 mouse hippocampus, and memantine-induced enhancement of hippocampal long-term potentiation (LTP) and CaMKII activity was totally abolished by treatment with pinacidil, a specific opener of KATP channels. Memantine also inhibited Kir6.1 and Kir6.2 KATP channels and elevated intracellular Ca2+ concentrations in neuro2A cells overexpressing Kir6.1 or Kir6.2. Kir6.2 was preferentially expressed at postsynaptic regions of hippocampal neurons, whereas Kir6.1 was predominant in dendrites and cell bodies of pyramidal neurons. Finally, we confirmed that Kir6.2 mutant mice exhibit severe memory deficits and impaired hippocampal LTP, impairments that cannot be rescued by memantine administration. Altogether, our studies show that memantine modulates Kir6.2 activity, and that the Kir6.2 channel is a novel target for therapeutics to improve memory impairment in Alzheimer disease patients.

How a nerve fiber repairs its cut end: involvement of phospholipase A2.

Following transection of a giant axon, the nerve membrane at the cut end is resealed within 5 to 30 minutes. This membrane resealing process is highly dependent upon temperature and extracellular calcium ions. The membrane resealing is triggered by excess calcium entering the axoplasm at the site of transection but is prevented by the application of phospholipase A2 inhibitors. We propose that calcium activated phospholipase A2 plays a central role in resealing of the ruptured nerve membrane.

Nerve terminal remodeling visualized in living mice by repeated examination of the same neuron.

The distribution of presynaptic endings on the surfaces of autonomic ganglion cells was mapped in living mice after intravenous administration of a styryl pyridinium dye. The staining and imaging techniques did not appear to damage the ganglion cells, or the synapses on them; these procedures could therefore be repeated after an arbitrary period. Observations of the same neurons at intervals of up to 3 weeks indicate that the pattern of preganglionic terminals on many of these nerve cells gradually changes.

Noradrenergic excitation of a subpopulation of GABAergic cells in the basolateral amygdala via both activation of nonselective cationic conductance and suppression of resting K+ conductance: a study using glutamate decarboxylase 67-green fluorescent protein knock-in mice.

GABAergic interneurons play central roles in the regulation of neuronal activity in the basolateral nucleus of the amygdala (BLA). They are also suggested to be the principal targets of the brainstem noradrenergic afferents which are involved in the enhancement of the BLA-related memory. In addition, behavioral stress has been shown to impair noradrenergic facilitation of GABAergic transmission. However, the noradrenaline (NA) effects in the BLA have not been differentiated among medium- to large-sized GABAergic neurons and principal cells, and remain to be elucidated in terms of their underlying mechanisms. Glutamate decarboxylase 67 (GAD67) is a biosynthetic enzyme of GABA and is specifically expressed in GABAergic neurons. To facilitate the study of the NA effects on GABAergic neurons in live preparations, we generated GAD67-green fluorescent protein (GFP) knock-in mice, in which GFP was expressed under the control of an endogenous GAD67 gene promoter. Here, we show that GFP was specifically expressed in GABAergic neurons in the BLA of this GAD67-GFP knock-in mouse. Under whole-cell patch-clamp recordings in vitro, we identified a certain subpopulation of GABAergic neurons in the BLA chiefly on the basis of the electrophysiological properties. When depolarized by a current injection, these neurons, which are referred to as type A, generated action potentials at relatively low frequency. We found that NA directly excited type-A cells via alpha1-adrenoceptors, whereas its effects on the other types of neurons were negligible. Two ionic mechanisms were involved in this excitability: the activation of nonselective cationic conductance and the suppression of the resting K+ conductance. NA also increased the frequency of spontaneous IPSCs in the principal cells of the BLA. It is suggested that the NA-dependent excitation of type-A cells attenuates the BLA output for a certain period.

Synapse-to-synapse variation of calcium channel subtype contributions in large mossy fiber terminals of mouse hippocampus.

Both N- and P/Q-type voltage-dependent calcium channels are involved in fast transmitter release in the hippocampus, but are differentially regulated. Although variable contributions of voltage-dependent calcium channel subtypes to presynaptic Ca2+ influx have been suggested to give a neural network of great diversity, their presence has only been demonstrated in a culture system and has remained unclear in the brain. Here, the individual large mossy fiber presynaptic terminal was labeled with Ca2+/Sr2+-sensitive fluorescent dextrans in the hippocampal slice of the mouse. The fractional contribution of voltage-dependent calcium channel subtypes to presynaptic Ca2+/Sr2+ influx was directly measured by the sensitivity of Ca2+/Sr2+-dependent fluorescent increment to subtype-selective neurotoxins, omega-conotoxin GVIA (an N-type selective blocker), omega-agatoxin IVA (a P/Q-type selective blocker) and SNX-482 (an R-type selective blocker). Synapse-to-synapse comparison of large mossy fiber terminals revealed that the contributions of N- and R-type voltage-dependent calcium channels varied more widely than that of P/Q-type. Even two large mossy fiber presynaptic terminals neighboring on the same axon differed in the fractional contributions of N- and R-type voltage-dependent calcium channels. On the other hand, these terminals were similar in the fractional contributions of P/Q-type voltage-dependent calcium channels. These results provide direct evidence that individual large mossy fiber synapses are differential in the contribution of N- and R-type voltage-dependent calcium channel subtypes to presynaptic Ca2+/Sr2+ influx. We suggest that the synapse-to-synapse variation of presynaptic voltage-dependent calcium channel subtype contributions may be one of the mechanisms amplifying diversity of the hippocampal network.

Immunohistochemical distribution and functional characterization of an organic anion transporting polypeptide 2 (oatp2).

The rabbit polyclonal antibody against rat organic anion transporting polypeptide 2 (oatp2) was raised and immunoaffinity-purified. Western blot analysis for oatp2 detected two bands ( 74 and 76 kDa) in rat brain and a single band (76 kDa) in the liver. By immunohistochemical analysis, the oatp2 immunoreactivity was specifically high at the basolateral membrane of rat hepatocytes. Functionally, the oatp2-expressing oocytes were found to transport dehydroepiandrosterone sulfate, delta1 opioid receptor agonist [D-Pen2,D-Pen5]enkephalin, Leuenkephalin, and biotin significantly, as well as the substrates previously reported. These data reveal the exact distribution of the rat oatp2 at the protein level in the liver, and that oatp2 appears to be involved in the multispecificity of the uptaking substrates in the liver and brain.

An improved method for perforated patch recordings using nystatin-fluorescein mixture.

This paper describes an improved method for solubilizing nystatin in an aqueous solution without the aid of organic solvents. The patch pipette was filled with a solution of nystatin and fluorescein sodium mixed in a molar ratio of 1:10. The success rate of perforated patch recordings was substantially improved, and the access resistance of 20-40 M omega was readily achieved.

Changes in the dendritic geometry of mouse superior cervical ganglion cells following postganglionic axotomy.

The dendritic geometry of mouse superior cervical ganglion cells was studied over periods of up to 3 months after postganglionic axotomy. Intracellular injection of HRP showed that total dendritic length and complexity were reduced by 60-70%, on average, among cells whose postganglionic axons had been crushed 2 weeks before. Both parameters gradually recovered in parallel with ganglion cell reinnervation of the periphery. These results indicate that neuronal interactions with peripheral targets influence the configuration of ganglion cell dendrites throughout life. The implications of this conclusion are discussed.

Noradrenaline modulates transmitter release by enhancing the Ca2+ sensitivity of exocytosis in the chick ciliary presynaptic terminal.

1. The giant presynaptic terminal of chick ciliary ganglion was used to examine how noradrenaline (NA) modulates neurotransmitter release. The cholinergic excitatory postsynaptic currents (EPSCs) were recorded under whole-cell voltage clamp of the postsynaptic neuron. 2. Although the EPSC was potentiated by NA, the current directly activated by acetylcholine (IACh) was unaffected. NA also increased the quantal contents without changing the quantal size. 3. The NA-dependent potentiation was antagonized by neither phentolamine nor propranolol. The EPSC was also potentiated by adrenaline and dopamine but not by normetanephrine, phenylephrine or isoprenaline. The EPSC was attenuated by clonidine. Therefore, NA potentiated the transmitter release through a receptor pharmacologically different from both alpha- and beta-adrenergic receptors. 4. The Ca2+ increment produced by an action potential (delta[Ca2+]pre) was reduced by NA through an alpha 2-adrenergic receptor. However, when alpha 2-adrenergic receptors were blocked, neither delta[Ca2+]pre nor resting Ca2+ were changed by NA. 5. The [Ca2+]o-EPSC relation was shifted by NA, decreasing the half-saturating [Ca2+]o, without changing the maximum. 6. It is concluded that NA-dependent potentiation of transmitter release was due to an increase in the Ca2+ sensitivity of the exocytotic process. The enhancement of the fusion probability is suggested.

Involvement of cGMP-dependent protein kinase in adrenergic potentiation of transmitter release from the calyx-type presynaptic terminal.

I have previously reported that norepinephrine (NE) induces a sustained potentiation of transmitter release in the chick ciliary ganglion through a mechanism pharmacologically distinct from any known adrenergic receptors. Here I report that the adrenergic potentiation of transmitter release was enhanced by a phosphodiesterase inhibitor, 3-isobutyl-1-methylxanthine (IBMX) and by zaprinast, an inhibitor of cGMP-selective phosphodiesterase. Exogenous application of the membrane-permeable cGMP, 8-bromo-cGMP (8Br-cGMP), potentiated the quantal transmitter release, and after potentiation, the addition of NE was no longer effective. On the other hand, 8Br-cAMP neither potentiated the transmitter release nor occluded the NE-induced potentiation. The NE-induced potentiation was blocked by neither nitric oxide (NO) synthase inhibitor nor NO scavenger. The quantal transmitter release was not potentiated by NO donors, e.g., sodium nitroprusside. The NE-induced potentiation and its enhancement by IBMX was antagonized by two inhibitors of protein kinase G (PKG), Rp isomer of 8-(4-chlorophenylthio) guanosine-3', 5'-cyclic monophosphorothioate and KT5823. As with NE-induced potentiation, the effects of 8Br-cGMP on both the resting intraterminal [Ca2+] ([Ca2+]i) and the action potential-dependent increment of [Ca2+]i (DeltaCa) in the presynaptic terminal were negligible. The reduction of the paired pulse ratio of EPSC is consistent with the notion that the NE- and cGMP-dependent potentiation of transmitter release was attributable mainly to an increase of the exocytotic fusion probability. These results indicate that NE binds to a novel adrenergic receptor that activates guanylyl cyclase and that accumulation of cGMP activates PKG, which may phosphorylate a target protein involved in the exocytosis of synaptic vesicles.

Protein kinase C potentiates transmitter release from the chick ciliary presynaptic terminal by increasing the exocytotic fusion probability.

1. The giant presynaptic terminal of chick ciliary ganglion was used to examine how protein kinase C (PKC) modulates neurotransmitter release. Cholinergic excitatory postsynaptic currents (EPSCs) were recorded under whole-cell voltage clamp. 2. Although the EPSC was potentiated by phorbol ester (phorbol 12-myristate 13-acetate, PMA; 0.1 microM) in a sustained manner, the nicotine-induced current was unaffected. PMA increased the quantal content to 2.4 +/- 0.4 (n = 9) of control without changing the quantal size. 3. The inactive isoform of PMA, 4alpha-PMA, showed no significant effect on EPSCs. The PMA-induced potentiation was antagonized by two PKC inhibitors with different modes of action, sphingosine (20 microM) and bisindolylmaleimide I (10 microM). 4. When stimulated by twin pulses of short interval, the second EPSC was on average larger than the first EPSC (paired-pulse facilitation; PPF). PMA significantly decreased the PPF ratio with a time course similar to that of the potentiation of the first EPSC. 5. PMA did not affect resting [Ca2+]i or the action potential-induced [Ca2+]i increment in the giant presynaptic terminals. 6. The effect of PMA was less at 10 mM [Ca2+]o than at 1 mM [Ca2+]o. 7. When a train of action potentials was generated with a short interval, the EPSC was eventually depressed and reached a steady-state level. The recovery process followed a simple exponential relation with a rate constant of 0.132 +/- 0.029 s-1. PMA did not affect the recovery rate constant of EPSCs from tetanic depression. In addition, PMA did not affect the steady-state EPSC which should be proportional to the refilling rate of the readily releasable pool of vesicles. 8. These results conflict with the hypothesis that PKC upregulates the size of the readily releasable pool or the number of release sites. PKC appears to upregulate the Ca2+ sensitivity of the process that controls the exocytotic fusion probability.

Two components of transmitter release from the chick ciliary presynaptic terminal and their regulation by protein kinase C.

1. A study was made of the effects of phorbol ester (phorbol 12-myristate 13-acetate, PMA, 0.1 microM) on the two components of evoked transmitter release, namely the fast synchronous and the slow asynchronous components, from the giant presynaptic terminal of the chick ciliary ganglion. The excitatory postsynaptic currents (EPSCs) were recorded under whole-cell voltage clamp of the postsynaptic neuron. 2. The decay time constant of the slow component was prolonged by replacing Ca2+ with Sr2+. In 5 mM [Sr2+]o the fast component decayed with a time constant of 2.6 +/- 1.4 ms whereas the slow component decayed with a time constant of 19 +/- 7 ms. 3. When stimulated with twin pulses with a short interpulse interval, the fast component of the second EPSC was often depressed whereas the slow component was usually facilitated. Both components were positively dependent on [Sr2+]o in a saturable manner, but the fast component approached its maximum at a lower [Sr2+]o than the slow component. 4. PMA potentiated both the fast and slow components to a similar extent and with a similar time course. For each component, the effect of PMA was less potent at high [Sr2+]o than at low [Sr2+]o. For either the fast or the slow component the PMA-induced potentiation was accompanied by a reduction in the paired-pulse ratio (PPR). 5. Despite the different dissociation constant for dextran-conjugated fura-2, the fluorescent ratio for intraterminal [Sr2+] ([Sr2+]i) decayed to the baseline after the nerve-evoked increment with a time course similar to that for [Ca2+]i, suggesting that intraterminal Sr2+ is buffered less efficiently than Ca2+. PMA did not increase the [Sr2+]i transients produced by stimulation of the presynaptic oculomotor nerve. 6. It is suggested that protein kinase C (PKC) modulates both the fast and slow components through common molecular mechanisms that upregulate the Sr2+ sensitivity of the vesicle fusion probability.

Voltage-activated calcium currents in presynaptic nerve terminals of the chicken ciliary ganglion.

1. Calcium currents (ICa) were recorded from presynaptic calyces of ciliary ganglia of the chick embryo under whole-cell voltage clamp. 2. Only high-threshold ICa was recorded without any evidence for the presence of low-threshold Ca2+ channels. 3. High-threshold (high-voltage-activated, HVA) ICa could be classified into non-inactivating (HVAn) and inactivating (HVAi) components. The mean inactivation time constant of the HVAi component was 213 ms (at 0 mV). The threshold for activation by depolarizing pulses was more negative for the HVAn component than for the HVAi component. The HVAi component was inactivated by 19% at a holding potential of -60 mV, while the HVAn component was little affected under this condition. 4. The activation of HVAn component was faster than that of the HVAi component. 5. Both the HVAn and HVAi components were blocked by Cd2+ (50 microM) and La3+ (1 microM). Both components were only slightly affected by Ni2+ (100 microM). The order of potency in blocking was La3+ greater than Cd2+ greater than Ni2+ for both components. Both the HVAi and HVAn components were irreversibly blocked by omega-conotoxin GVIA(omega-CgTX, 10 microM). 6. The two components could pharmacologically be distinguished by selective blockade of the HVAn component with nifedipine (2 microM) and D600 (100-250 microM). 7. HVAn and HVAi components are suggested to represent two different subpopulations of Ca2+ channels. The HVAn subpopulation may be responsible for persistent Ca2+ influx during subthreshold depolarization of the nerve terminal.

Rectification of synaptic and acetylcholine currents in the mouse submandibular ganglion cells.

1. Synaptic currents and responses to acetylcholine (ACh) were recorded from mouse submandibular ganglion (SMG) cells under whole-cell voltage clamp. 2. The peak amplitude of excitatory synaptic currents (ESCs) as well as the currents evoked by the ionophoretic application of ACh followed a unique non-linear current-voltage (I-V) relation. The chord conductance of the whole-cell currents decreased with depolarization of the membrane potential and became virtually 0 at 50 mV. 3. The decay of ESCs was described by two exponential functions. Both the fast (tau f) and slow (tau s) time constants were sharply decreased at depolarizing potentials beyond -40 mV, being insensitive to hyperpolarizing potentials more than -50 mV. 4. Single ACh receptor channels were characterized by the whole-cell current noise analysis. The single-channel currents followed Ohm's law at negative membrane potentials but tended to reach a plateau at positive membrane potentials. The mean slope conductance measured between -40 and -20 mV was 28.5 pS. 5. The product of the number of functional channels (N) and the probability of a channel being open (p) showed a steep voltage dependence. The value of Np at 20 mV was only 31% of that at -20 mV. 6. The noise power spectrum was best fitted by a double-Lorentzian function. Both the fast (tau f) and slow (tau s) time constants were sharply decreased by depolarizations beyond -20 mV. being less sensitive to membrane potentials more negative than -30 mV. 7. The non-linear I-V relation of ESCs was attributed in part to the voltage dependence of p and in part to the voltage dependence of the single-channel conductance (gamma) of ACh receptor channels.

Preferential inhibition of omega-conotoxin-sensitive presynaptic Ca2+ channels by adenosine autoreceptors.

Adenosine is a potent modulator of transmitter release at a variety of synapses. The adenosine A1 receptor is assumed to reside in presynaptic terminals and to function as a negative autoreceptor. How adenosine reduces transmitter release is uncertain; it may reduce the calcium influx during nerve terminal depolarization by either activating K+ currents or inhibiting Ca2+ currents, although other mechanisms have been proposed. We have directly measured intracellular Ca2+ concentrations of giant pre-synaptic terminals in the chick ciliary ganglion. We report here that adenosine inhibited the nerve-evoked Ca2+ influx in the terminal by activating A1 receptors. Reduced Ca2+ influx was due largely to inhibition of omega-conotoxin GVIA-sensitive Ca2+ channels in the presynaptic terminal.

Re-evaluation of calcium currents in pre- and postsynaptic neurones of the chick ciliary ganglion.

1. Presynaptic nerve terminals of ciliary ganglia of the chick embryo were identified by the accumulation of dextran-tetramethylrhodamine applied to the cut end of the oculomotor nerve. Ca2+ currents were then recorded from the identified nerve terminals. 2. Whole-cell recordings were carried out simultaneously from a presynaptic terminal and its postsynaptic cell. The generation of presynaptic Ca2+ currents induced a postsynaptic response with a short delay. Electrical coupling was present in eight of fifteen pairs. The coupling ratio did not exceed 5%. 3. High-threshold Ba2+ currents were observed in presynaptic terminals without any evidence for the presence of low-threshold Ca2+ channels. The Ba2+ current was completely blocked by 50 microM Cd2+. 4. The presynaptic Ca2+ current induced by a long depolarizing pulse showed inactivation, but this inactivation was diminished when Ca2+ was replaced with Ba2+. 5. The presynaptic Ba2+ current was insensitive to dihydropyridines (DHPs). omega-Conotoxin GVIA (omega CgTX) suppressed a large fraction of the Ba2+ current irreversibly. About 10% of the Ba2+ current was resistant to both DHPs and omega CgTX. 6. The omega CgTX-sensitive component was not sensitive to changes in the holding potential between -120 and -50 mV. The omega CgTX-resistant component tended to be inactivated at depolarized holding potentials. 7. In some perisynaptic Schwann cells, small Ca2+ currents were observed. These Ca2+ currents increased monotonically with depolarization. 8. Only high-threshold Ca2+ channel currents were observed in postsynaptic ciliary cells. Exposure to 50 microM Cd2+ completely abolished the Ca2+ current. 9. About 25% of the Ba2+ currents were blocked by nifedipine (10 microM) in ciliary cells. The nifedipine-resistant component was partly blocked by omega CdTX (10 microM) leaving a small component (about 20%) which was resistant to both nifedipine and omega CgTX. 10. In ciliary cells, the fraction of Ba2+ currents blocked by omega CgTX was not affected by the presence or absence of nifedipine. Similarly, nifedipine blocked the Ba2+ currents to the same extent whether omega CgTX was present or not. The Ba2+ currents potentiated by Bay K 8644 were eliminated by nifedipine. 11. It is concluded that the presynaptic terminal of chick ciliary ganglion did not possess DHP-sensitive Ca2+ channels in contrast with the postsynaptic cell. Two subpopulations of presynaptic Ca2+ channels were distinguishable by their sensitivity to omega CgTX and membrane potential.

mu-Opioid receptor inhibits N-type Ca2+ channels in the calyx presynaptic terminal of the embryonic chick ciliary ganglion.

A study was made on the mechanisms by which enkephalins inhibit synaptic transmission at calyx-type presynaptic terminals in the ciliary ganglion of chick embryos at stages 39-40. Excitatory postsynaptic currents (EPSCs) were recorded by nystatin-perforated patch clamp at low [Ca2+]o and high [Mg2+]o. [Leu5]enkephalin (L-ENK, 1-10 microM) reduced the quantal content (m) without changing the quantal size (q). This effect was antagonized by naloxone (1 microM). Similar results were observed under conventional whole-cell clamp of the postsynaptic neuron. A specific agonist of the mu-opioid receptor, [D-Ala2, M-Me-Phe4,Gly5]enkephalin-ol (DAMGO) reduced m without changing q. A specific agonist of the delta-opioid receptor, [d-Pen2, d-Pen5]enkephalin (DPDPE) also reduced m without changing q. Both L-ENK and [Met5]enkephalin (M-ENK) reduced the stimulus-dependent increment of the intraterminal Ca2+ concentration (Delta[Ca2+]t) without affecting the decay time constant of the intraterminal Ca2+ concentration and basal Ca2+ level. This effect was antagonized by naloxone. DAMGO reduced Delta[Ca2+]t more effectively than DPDPE. When extracellular Ca2+ was replaced by Ba2+, the stimulus-dependent increment of the intraterminal Ba2+ concentration (Delta[Ba2+]t) was also reduced by L-ENK or DAMGO. L-ENK reduced Delta[Ca2+]t even in the presence of 4-aminopyridine (4-AP), which blocks the transient K+ conductance during the falling phase of the presynaptic action potential. When N-type Ca2+ channels were blocked by omega-conotoxin GVIA (omega-CgTxGVIA), the Delta[Ca2+]t was no longer sensitive to L-ENK and DAMGO. It is suggested that enkephalins reduce the transmitter release through presynaptic opioid receptors. The mu-opioid receptor may suppress presynaptic Ca2+ influx by selectively inhibiting N-type Ca2+ channels.

Omega-conotoxin-sensitive and -resistant transmitter release from the chick ciliary presynaptic terminal.

1. Synaptically evoked responses to stimulation of the oculomotor nerve were recorded from the ciliary nerve in chick embryos. The postsynaptic currents in response to presynaptic stimulation (EPSCs) were also recorded under whole-cell voltage clamp of the ciliary cell. 2. The ciliary nerve response was dependent on the extracellular Ca2+ concentration ([Ca2+]o). omega-Conotoxin GVIA (omega-CgTX, 100 nM) increased the [Ca2+]o necessary to evoke the half-maximal response by a factor of 1.7 without changing the slope of [Ca2+]o dependence. Dihydropyridine (DHP) derivatives, nifedipine or Bay K 8644, did not affect the [Ca2+]o sensitivity of ciliary nerve response. 3. The EPSC was usually preceded by the capacitive coupling response of the presynaptic action potential. In some records, the EPSCs were also preceded by the electrical coupling responses which were the mirror images of the presynaptic action potentials. The current-voltage relation of the EPSCs showed inward rectification. 4. The EPSC was potentiated by 4-aminopyridine (4-AP) as a result of prolongation of the falling phase of presynaptic action potential. In the presence of high [Ca2+]o and 4-AP, a small fraction of EPSC was resistant to omega-CgTX. 5. The resting potential of the presynaptic terminal was changed from -69 to -57 mV by increasing [K+]o from 1 to 10 mM. The same procedure decreased the omega-CgTX-resistant EPSC by 30%, whereas the omega-CgTX-untreated EPSC in low-Ca2+ saline was not affected by the change in [K+]o. 6. The nerve-evoked increase in intracellular Ca2+ was recorded from the presynaptic terminal (delta[Ca2+]pre). The delta[Ca2+]pre was larger in a solution containing 10 mM Ca2+ and 1 mM K+ after treating with omega-CgTX than in a solution containing 2 mM Ca2+ and 16 mM Mg2+ before treating with omega-CgTX. The EPSC was, in contrast, smaller in the 10 mM Ca(2+)-1 mM K+ solution after omega-CgTX treatment than in the 2 mM Ca(2+)-16 mM Mg2+ solution before omega-CgTX treatment. 7. Similarly, the EPSC was smaller in the 10 mM Ca(2+)-1 mM K+ solution containing 5 microM La3+ than in the 2 mM Ca(2+)-16 mM Mg2+ solution, whereas the delta [Ca2+]pre was larger in the 10 mM Ca(2+)-1 mM K+ solution containing 5 micrograms La3+ than in the 2 mM Ca(2+)-16 mM Mg2+ solution. 8. It is concluded that the omega-CgTX-sensitive Ca2+ conductance of the presynaptic terminal is the principal source of Ca2+ involved in transmitter release.(ABSTRACT TRUNCATED AT 400 WORDS)