The effects of ethanol on pre-synaptic components of synaptic transmission in a model glutamatergic synapse: the crayfish neuromuscular junction

We have elucidated some of the mechanisms by which ethanol (EtOH) reduces synaptic efficacy at model glutamatergic synapses. The crayfish phasic and tonic neuromuscular junctions are superb models for directly assessing the effects of EtOH on pre-synaptic components of synaptic transmission. The ability to perform quantal analysis of synaptic transmission has allowed us to assess pre-synaptic alterations of release. Using this system, we report that the application of EtOH, within a range observed in intoxicated humans (44 and 88 mM), resulted in a diminution of excitatory post-synaptic potentials (EPSP) amplitudes. Additionally, using focal macro-patch recordings, quantal synaptic currents were recorded to assess the pre-synaptic component as potential target sites for EtOH's action. At the tonic neuromuscular junctions, EtOH (88 mM) reduced the probability of release (p), and in some cases, reduced the number of the release sites (n), but did not alter facilitation index nor did it affect the latency of vesicular release. At the phasic neuromuscular junction, a reduction in synaptic charge occurred during the presence of EtOH. Thus, the observed decrease in synaptic strength is at least partially attributable to a pre-synaptic alteration, specifically the release of fewer vesicles.     

Ca2+-dependent recycling of synaptic vesicles at the frog neuromuscular junction

Frog cutaneous pectoris muscles were treated with low doses of crude black widow spider venom (BWSV) or purified alpha-latrotoxin, and neuromuscular transmission, quantal secretion, changes in ultrastructure and uptake of horseradish peroxidase (HRP) were studied. When these agents were applied to muscles bathed in a Ca2+-free solution with 1 mM EGTA and 4 mM Mg2+, the rate of quantal secretion rose to high levels but quickly subsided; neuromuscular transmission was totally and irreversibly blocked within 1 h. The terminals became swollen and were depleted of vesicles; HRP was not taken up. When BWSV was applied to other muscles bathed in a solution with 1.8 mM Ca2+ and 4 mM Mg2+, the rate of secretion rose to high levels and then declined to intermediate levels that were sustained throughot the hour of exposure. Neuromuscular transmission was blocked in fewer than 50% of these fibers. The ultrastructure of these terminals was normal and they contained large numbers of synaptic vesicles. If HRP had been present, most of the synaptic vesicles were labeled with reaction product. These observations suggest that Ca2+ plays an important role in endocytosis at the frog neuromuscular junction.     

The effects of pentachlorophenol (PCP) at the toad neuromuscular junction

1. Effects of PCP at the frog neuromuscular junction were studied in vitro in sciatic nerve sartorius muscle of the toad Pleurodema-thaul. 2. Within the concentration 0.003-0.1 mM, PCP caused a dose-time-dependent block of evoked transmitter release acompanied by an increase in the rate of spontaneous quantal release. 3. PCP induced an increase in miniature endplate potential (MEPP) frequency and it was not antagonized in a Ca2(+)-free medium, indicating that it does not depend upon Ca2+ influx from the external medium, but may act by releasing Ca2+ from intraterminal stores. 4. The present data, together with previous results concerning PCP at eighth sympathetic ganglia indicate that 3,4-diaminopyridine (3,4-DAP) counteracts the effects of PCP on synaptic transmission. This result suggests that PCP interfering Ca2+ influx occurs during depolarization of motor nerve terminals.     

Down-regulation of quantal size at frog neuromuscular junctions: possible roles for elevated intracellular calcium and for protein kinase C

Previous work showed that quantal size can be at least doubled at the frog neuromuscular junction by pretreatment with hormones or hypertonic solutions, primarily by the release of more acetylcholine (ACh) per quantum. Once increased, quantal size slowly declined over hours. Quantal size was measured from miniature end-plate potentials (MEPPs) or currents (MEPCs). In the present experiments, preparations in which quantal size had been increased were exposed to 17-25 mM [K+], quantal size decreased within minutes. Release of comparable numbers of quanta by nerve stimulation did not decrease size. K(+)-solutions did not decrease size if Ca2+ was omitted or replaced with Sr2+. The phosphokinase C (PKC) activators phorbol 12,13-diacetate (PDA) and 1-oleoyl-2-acetyl-rac-glycerol (OAG) also decreased quantal size within minutes when applied in a hypertonic solution that increased the rate of spontaneous release. Phorbol 12,13-dideconate, which does not activate PKC, did not decrease quantal size. The size decrease triggered by K(+)-solutions or PKC activators was blocked by 100 microM 1-(5-isoquinolinyl-sulfonyl)-2-methyl-piperazine (H7), a protein kinase inhibitor. Apparently, increasing [K+] elevated intracellular [Ca2+], which activates PKC, and which leads to the down-regulation of quantal size. During the period in which size is decreasing, there appears to be large and normal subpopulations of MEPP sizes, with normal gradually replacing large. This suggests that large quanta are formed by adding additional ACh to preformed quanta shortly before they are available for release.     

Effects of ethimizol on frog neuromuscular junction

The effects were studied of ethimizol, a substance activating memory processes, on features of synaptic transmission during experiments on frog cutaneous pectoris muscle. It was found that the presynaptic action of ethimizol consists of raising the frequency of miniature potentials, when used at a concentration of 0.5–10 mM, and modulating quantal content of synaptic transmission due to changes in binomial quantal release parameters p and n when 0.5–2 mM ethimizol was used. This substance facilitated transmission at synapses with a low initial level of transmitter release. This substance facilitated transmission at synapses with a low initial level of transmitter release. Ethimizol was also found to have a postsynaptic action, consisting of reducing amplitude at a concentration of 5–10 mM and prolonging synaptic currents and potentials when concentrations of 0.5–10 mM were used. The latter effect produced a considerable increase in the time integral of endplate potentials. The postsynaptic action of ethimizol is perhaps seen in its effects on features of postsynaptic ionic channels. The effects of ethimizol are discussed with a view to how it may act within the central nervous system as a nonspecific modulator.A. A. Zhdanov Leningrad State University. Translated from Neirofiziologiya, Vol. 17, No. 6, pp. 757–763, November–December, 1985.     

Physiological properties of developing frog tadpole nerve-muscle junctions during repetitive stimulation

Physiological properties of developing neuromuscular junctions were studied in Rana catesbeiana tadpoles at different developmental stages. Developing neurons formed functional synaptic connections with a section of tail muscle implanted in place of the hind limb bud. Low frequency repetitive stimulation at these developing junctions causes a progressive reduction in the Epp amplitude. This reduction is due to a decrease in the quantal content, is reversible, and is more apparent at the most immature developmental stages, becoming less noticeable with further development. These junctions are capable of facilitation at each developmental stage studied when the quantal content is reduced by magnesium. At normal calcium and magnesium concentrations there is little or no facilitation, and often depression of the second Epp occurs.     

Facilitation, augmentation, and potentiation of synaptic transmission at the superior cervical ganglion of the rabbit

The effect of repetitive stimulation on synaptic transmission was studied in the isolated superior cervical ganglion of the rabbit under conditions of reduced quantal content. Excitatory postsynaptic potentials (EPSP) were recorded with the sucrose gap technique to obtain estimates of transmitter release. Four components of increased transmitter release, with time constants of decay similar to those observed at the frog neuromuscular junction at 20 degrees C, were found in the ganglion at 34 degrees C: a first component of facilitation, which decayed with a time constant of 59 +/- 14 ms (mean +/- SD); a second component of facilitation, which decayed with a time constant of 388 +/- 97 ms; augmentation, which decayed with a time constant of 7.2 +/- 1 s; and potentiation, which decayed with a time constant of 88 +/- 25 s. The addition of 0.1-0.2 mM Ba2+ to the Locke solution increased the magnitude but not the time constant of decay of augmentation. Ba2+ had little effect on potentiation. The addition of 0.2-0.8 mM Sr2+ to the Locke solution appeared to increase the magnitude of the second component of facilitation. Sr2+ had little effect on augmentation or potentiation. These selective effects of Ba2+ and Sr2+ on the components of increased transmitter release in the rabbit ganglion are similar to the effects of these ions at the frog neuromuscular junction. Although the effects of Ba2+ and Sr2+ are similar in the two preparations, the magnitudes of augmentation and the second component of facilitation after a single impulse were about 6-10 times greater in the rabbit ganglion than at the frog neuromuscular junction. These results suggest that the underlying mechanisms in the nerve terminal that give rise to the components of increased transmitter release in the rabbit ganglion and frog neuromuscular junction are similar but not identical.     

金褐霉素（Aureofuscin）对神经末梢...

By means of the intracellular recording technique, the effect of aureofuscin (20 micrograms/ml, oversaturation solution) on the ACh release from motor nerve terminals and on muscle cell membrane potential were investigated in phrenic nerve diaphragm preparations of the mice. The results showed that (a) aureofuscin reduced the resting membrane potential of the muscle cell slightly; (b) the frequency of miniature end-plate potentials and the mean quantal content of end-plate potentials increased at first and then recovered approximately to the control level; (c) the depolarization produced by aureofuscin in the muscle cell membrane was reversible and the aureofuscin-invoked facilitation in miniature end-plate potential discharges was Ca(2+)-dependent; and (d) aureofuscin did not block neuromuscular transmission.     

Nicardipine inhibits axon conduction but causes dual changes of acetylcholine release in the mouse motor nerve

The effects of nicardipine, a dihydropyridine Ca2(+)-channel antagonist, on neuromuscular transmission and impulse-evoked release of acetylcholine were compared with those of nifedipine. In the isolated mouse phrenic nerve diaphragm, nicardipine (50 microM), but not nifedipine (100 microM), induced neuromuscular block, fade of tetanic contraction, and dropout or all-or-none block of end-plate potentials. Nicardipine had no significant effect on the resting membrane potential and the amplitude of miniature end-plate potentials but increased the frequency and caused the appearance of large size miniature potentials. The quantal contents of evoked end-plate potentials were increased. In the presence of tubocurarine, however, nicardipine depressed the amplitude of end-plate potentials. The compound nerve action potential was also decreased. It is concluded that nicardipine blocks neuromuscular transmission by acting on Na+ channels and inhibits axonal conduction. Nicardipine appeared to affect the evoked release of acetylcholine by dual mechanisms, i.e., an enhancement presumably by an agonist action on Ca2+ channels, like Bay K 8644 and nifedipine, and inhibition by an effect on Na+ channels, like verapamil and diltiazem. In contrast with its inactivity on the amplitude of miniature end-plate potentials, depolarization of the end plate in response to succinylcholine was greatly depressed. The contractile response of baby chick biventer cervicis muscle to exogenous acetylcholine was noncompetitively antagonized by nicardipine (10 microM), but was unaffected by nifedipine (30 microM). These results may implicate that nicardipine blocks the postsynaptic acetylcholine receptor channel by enhancing receptor desensitization or by a use-dependent effect.     

Changes in synaptic transmission produced by hydrogen peroxide

The effect of hydrogen peroxide (H₂O₂) on excitatory and inhibitory synaptic transmission was studied at the lobster neuromuscular junction. H₂O₂ produced a dose dependent decrease in the amplitude of the junction potential (V_ejp). This decrease was due to changes in both presynaptic transmitter release and the postsynaptic response to the neurotransmitter. Observed presynaptic changes due to exposure to H₂O₂ were a decrease in the amount of transmitter released, that is, quantal content, as well as a decrease in the fast facilitation, that is, the amplitude increase of successive excitatory junction potentials at a rate of 3 Hz. To discern postsynaptic changes, glutamate, the putative excitatory neurotransmitter for this preparation was applied directly to the bathing medium in order to bypass the presynaptic release process. H₂O₂ produced a decreased response of the glutamate receptor/ ionophore. The action of H₂O₂ was not selective to excitatory (glutamate-mediated) transmission because inhibitory (GABA-mediated) transmission was also depressed by H₂O₂. This effect was primarily presynaptic since H₂O₂ produced no change in the postsynaptic response to applied GABA.     

Dual effect of potassium on transmitter exocytosis

The time course of exocytosis of quanta of acetylcholine induced by 20 mM K+ was studied at the frog neuromuscular junction. Images of vesicle fusion on freeze-fracture replicas were mostly localized at the active zones in resting preparations fixed in 20 mM K+. Fusions appeared also outside the active zones in preparations fixed after 1 min exposure to 20 mM K+ and were evenly distributed over the presynaptic membrane after 5 min in 20 mM K+ (even though secretion was prevented by withdrawing Ca2+ until 30 s before fixation). The mean densities of vesicle fusions were comparable in all conditions, as were the total number of quanta released during the fixation period. This indicates that fusions outside active zones represent ectopic exocytosis, slowly activated by potassium. Partial inactivation of K(+)-induced quantal release (time and concentration-dependent) was observed electrophysiologically; this may be related to the observed decrease in density of vesicle fusions along the active zones, with time. Consistently, after 5 min in 15 mM K+ fusion density at the active zones remained high. It is concluded that active zone-associated and ectopic fusions are two exocytotic processes activated with differential time courses and concentration-dependence by K+.     

Structural determinants of the reliability of synaptic transmission at the vertebrate neuromuscular junction

Brain Cell Biology - The reliability of neuromuscular transmission depends on the size and molecular organization of the neuromuscular junction. Comparative studies show that the quantal release...     

Calcium dependence of uni-quantal release latencies and quantal content at mouse neuromuscular junction

Uni-quantal endplate currents (EPC) were recorded at mouse diaphragm neuromuscular synapse by extracellular microelectrode during motor nerve stimulation. The probability of release expressed as quantal content m(o), and variability of synaptic latencies expressed as P90 were estimated in the presence of extracellular calcium ([Ca2+]o) varying between 0.2 and 0.6 mM in the bathing solution. At 0.2 mM ([Ca2+]o), m(o) was low (0.10) and many of long-latency EPCs were present during the late phase of the release (P90 = 2.44 ms). No change in m(o) was found when ([Ca2+]o) was 0.3 mM, but P90 decreased by 39 %. For latency shortening, saturating concentration of ([Ca2+]o) was 0.4 mM, when P90 was 1.49 ms and latencies did not further change at 0.5 and 0.6 mM ([Ca2+]o). In the latter concentrations, however, an increase of m(o) was still observed. It can be concluded that the early phase of the secretion did not significantly change when ([Ca2+]o) was raised and that only the late phase of the release depends on extracellular calcium up to 0.4 mM.     

Presynaptic receptors regulating the time course of neurotransmitter release from vertebrate nerve endings

A number of different types of presynaptic receptors was revealed in central and peripheral chemical synapses activated both by main mediator and co-mediators released simultaneously. Physiological significance and mechanisms of functioning of these receptors are not clear yet. They are assumed to provide negative or positive feedback decreasing or increasing the number of neurotransmitter quanta released in response to nerve impulse and thus regulating synaptic transmission. At the same time, there is one more way of secretion process modulation associated with the changes of timing of transmitter release. This mechanism was shown to contribute to the efficiency of synaptic transmission. The role of presynaptic receptors in regulation of the kinetics of quanta release is one of the interesting questions of modern neurophysiology. This paper overviews the results obtained by the authors that demonstrate the contribution of presynaptic receptors of different types into the regulation of temporal parameters of quantal secretion at the vertebrates neuromuscular junction. It was shown that activation of the cholinergic nicotinic receptors leads to a decrease of the amplitude of postsynaptic response not only due to reduction of the quantity of released quanta but also due to increased the level of asynchronous release. On the contrary, the facilitating effect of catecholamines on the neuromuscular synapse is the result of activation of presynaptic β₁-adrenoreceptors which leads to greater synchronization of release process and, consequently, to the increase of the amplitude of the postsynaptic response. Presynaptic purine receptors, involved in the modulation the intensity of secretion, are also capable of alteration of the time course of secretion. Activation of ryanodine receptors results in the increase of the number of quanta released with prolonged latencies leading to appearance of the phase of delayed asynchronous neurotransmitter release.     

Cyclic nucleotides and neuromuscular transmission.

A review of the research on cyclic nucleotides and neuromuscular transmission suggests that cAMP is involved in the release of transmitter from motor nerve endings. Lipid-soluble derivations of cAMP cause depolarization of unstimulated nerve endings and prolong the after potentials of stimulated nerve endings. They also increase the frequency of miniature end plate potentials and increase the quantal content of stimulus evoked end plate potentials. Similar effects are produced by compounds that activate adenylate cyclase or inhibit phosphodiesterase. The responses to the derivatives of cAMP and activators of cyclase are enhanced by inhibitors of phosphodiesterase and prevented by compounds that block the flux of calcium into nerve endings. There is no evidence that suggests that cyclic nucleotides are involved in the postjunctional response to transmitter. Thus, it seems likely that cAMP is involved in the regulation of calcium in motor nerve endings and the exocytosis of transmitter. Additional study should expand our knowledge of neuromuscular transmission and contribute to an understanding of the functions of cyclic nucleotides in other synapses.     

Presynaptic effect of the aziridinium ion of acetylcholine mustard (methyl-2-acetoxyethyl-2'-chloroethylamine) on the phrenic nerve--rat diaphragm preparation.

The rat diaphragm has been used to investigate the neuromuscular blocking action of acetylcholine mustard which yields a potent nicotinic agonist, an aziridinium ion, in aqueous medium. Evidence was obtained that the acetylcholine mustard aziridinium ion impaired neuromuscular activity when the phrenic nerve was stimulated and that the ion did not directly inhibit muscle contraction. Impairment of neuromuscular activity was characterized by a latent period and depended both on the concentration of aziridinium ion and the frequency of stimulation of the phrenic nerve. Elevated concentrations of Ca-2+ and choline changed the response of the rat diaphragm to the aziridinium ion, the former increasing the rate of development of neuromuscular block and the latter protecting against neuromuscular block. These results indicated that the aziridinium ion may act either at the site of choline uptake or have an effect on acetylcholine synthesis in the nerve ending and that impairment of neuromuscular transmission in the rat diaphragm involved the availability of acetylcholine. Similar results were obtained with acetylcholine mustard aziridinium ion subjected to alkaline hydrolysis. This substance is thought to be choline mustard aziridinium ion. Although difficult to prove with the rat diaphragm it is possible that acetylcholinesterase of this preparation could hydrolyze acetylcholine mustard aziridinium ion at the neurotransmitter site and the resultant choline mustard aziridinium ion would interfere with the uptake of choline and eventually prevent neuromuscular transmission. This hemicholinium-like hypothesis for the mechanism of action of choline mustard aziridinium ion is compatible with reported date for toxicity of acetylcholine mustard aziridinium ion in the mouse.     

The sequence of events that underlie quantal transmission at central glutamatergic synapses

The properties of synaptic transmission were first elucidated at the neuromuscular junction. More recent work has examined transmission at synapses within the brain. Here we review the remarkable progress in understanding the biophysical and molecular basis of the sequential steps in this process. These steps include the elevation of Ca2+ in microdomains of the presynaptic terminal, the diffusion of transmitter through the fusion pore into the synaptic cleft and the activation of postsynaptic receptors. The results give insight into the factors that control the precision of quantal transmission and provide a framework for understanding synaptic plasticity.     

Cyclic AMP,Transmitter Release and the Effect of Adenosine on Neuromuscular Transmission

THE high activities of the enzymes in nervous tissue regulating the metabolism of 3',5' adenosine monophosphate (cyclic AMP) and its apparent involvement in secretion from glands have prompted considerable speculation about its possible role in the release of transmitters from nerve endings^1–4. There is some evidence that cyclic AMP is concerned in the release of acetylcholine from motor nerve endings^1,3. It has been found, for example, that neuromuscular transmission is facilitated by catecholamines^5,6 and methylxanthines^1,3; noradrenaline is known to increase both the quantal content of the endplate potential⁶ and the level of cyclic AMP in nervous tissue^7,8 and the increase in the quantal content is more marked in the presence of theophylline³. It was also found that increases in cyclic AMP concentration of up to thirty-fold occur in brain slices in the presence of 0.1-1 mM adenosine. We have therefore examined the effect of this substance on transmitter release.     

Quantal size is dependent on stimulation frequency and calcium entry in calf chromaffin cells

To what extent the quantal hypothesis of transmitter release applies to dense-core vesicle (DCV) secretion is unknown. We determined the characteristics of individual secretory events in calf chromaffin cells using catecholamine amperometry combined with different patterns of stimulation. Raising the frequency of action potential trains from 0.25-10 Hz in 2 mM [Ca(2+)]o or [Ca(2+)]o from 0.25-7 mM at 7 Hz elevated the amount released per event (quantal size). With increased stimulation, quantal size rose continuously, not abruptly, suggesting that release efficiency from a single population of DCVs rather than recruitment of different-sized vesicles contributed to the effect. These results suggest that catecholamine secretion does not conform to the quantal model. Inhibition of rapid endocytosis damped secretion in successive episodes, implying an essential role for this process in the recycling of vesicles needed for continuous secretion.     

Dehydration affects synaptic transmission at flexor muscle in acute lead-treated mice.

The effect of 24 hrs. water deprivation on spontaneous and evoked transmitter release was studied at flexor nerve terminals of control and lead-treated male C57BL mice. Miniature endplate potentials (MEPPs) and endplate potentials (EPPs) were recorded intracellularly from urethane-anesthetized (2 mg/g, i.p.) control and lead exposed mice in both hydrated and dehydrated conditions. Exposure to lead was made by i.p. injection of lead acetate (1.0 mg/kg) dissolved in a 5% glucose solution 24 hrs. prior to the experiment. Unimodal and bimodal MEPP frequencies decreased with dehydration, while small mode MEPPs remained unchanged and large mode MEPPs increased in frequency. EPP amplitude and quantal content were unchanged by dehydration. Lead treatment by itself reduced the frequency of unimodal and bimodal MEPPs but had no effect on the amplitude of EPPs or of quantal content. However a combination of dehydration and acute lead treatment reduced the frequency of unimodal, bimodal and large mode MEPPs and significantly reduced both EPP amplitude and quantal content. Dehydration apparently reveals an underlying neurotoxic action of lead at the neuromuscular junction. This raises a health concern that people subjected to both lead pollution and dehydration are at greater risk to lead poisoning of the neuromuscular junction.