Effect of sodium nitroprusside on the mediator release and functional properties of the postsynaptic membrane at the neuromuscular junction]

The effect of nitric oxide donor sodium nitroprusside on the end-plate currents was studied under two-electrode voltage-clamp condition at frog neuro-muscular junction. Sodium nitroprusside (10(-4) M) reduced to the half the amplitude of end-plate currents while did not change miniature end-plate currents indicating the presynaptic nature of end-plate depression. In keeping with such suggestion sodium nitroprusside essentially (to 33%) suppressed the frequency of miniature end-plate currents but did not affect the decay time constant and voltage-dependence of miniature end-plate decay. In contrast to another presynaptic inhibitors sodium nitroprusside rather reduced than increased the presynaptic facilitation and did not change postsynaptic potentials. Thus, nitric oxide is the powerful inhibitor of both evoked and spontaneous transmitter release and did not change postsynaptic potential.     

Pre- and postsynaptic effects of the calcium channel blocker verapamil in the nerve-muscle preparation

Verapamil did not change the amplitude of the miniature and multiquantal end-plate currents, synchronicity of the transmitter release and repetitive firing at the motor nerve endings. Verapamil shortened the decay of multiquantal currents, the effect being enhanced after acetylcholinesterase inhibition. In muscles with inhibited acetylcholinesterase, verapamil promoted the depression of successive end-late currents in rhythmic nerve stimulation. The data suggest that in skeletal muscles verapamil-sensitive calcium channels do not take part in physiological transmitter release or in chemical potentiation of the secretion after treatment with potassium channels blocking agents.     

Mediator secretion in the nerve-muscle synapse in the frog following long-term effect of calcium-free solutions

The changes of spontaneous and evoked transmitter release in condition of long time (1-4 hours) incubation in Ca-free solution with EGTA adding, were investigated with extracellular recordings in experiments on the nerve-muscular junction of the frog cutaneous-pectoris muscle. Using the method of three extracellular microelectrodes recordings of the monoquantal postsynaptic signals, it was shown that during action of Ca-free solutions the topography of transmitter release changed, the specific spatial organization of points of transmitter release was disrupted. These changes remained after returning to the initial solution. The obtained data suggest that the Ca2+ free solution leads to disruption of active zones of nerve ending. In condition of low initial extracellular Ca2+ concentrations (0.15-0.4 mmol/l), the active zones disorganization led to decreasing of average amplitude of the end-plate currents (EPC) by decreasing their quantal content, increasing their time-course and decreasing the frequency of the miniature end-plate currents (MEPC). The sharp displacement of dependence of quantal contents of EPC in extracellular Ca2+ concentration to a higher Ca2+ concentration without significant changes of slope was revealed. In condition of high (1.8 mmol/l) concentration of Ca2+, the long action of Ca-free solutions leads to decreasing of amplitude of EPC too, but it was less obvious than in condition of initial low Ca2+ concentration. It is supposed that intra- and extracellular Ca concentration provides the support of the typical morpho-functional organization of the mechanisms of transmitter release at the nerve ending of the frog. The disorganization of active zones leads to separation of the elements, which take part at the transmitter release process and reduces the efficiency of secretion.     

Effects of Noradrenaline on End-Plate Currents and the Kinetics of Transmitter Release under Long-Lasting Repetitive Stimulation

Noradrenaline causes a significant increase in the amplitude of multiquantum end-plate currents (EPC) and also diminishes the EPC rising phase vs the rising phase of the miniature EPC ratio in the frog neuromuscular junction under conditions of low-frequency long-lasting stimulation of the motor nerve. Noradrenaline changes the kinetics of transmitter release due to synchronization of the quantum transmitter secretion. The synchronizing action of noradrenaline can underlie its de-fatiguing effect in the neuromuscular junction.     

Differences between Spontaneous and Evoked Monoquantum Signals in the Frog Neuromuscular Junction

In experiments on the frog cutaneous-pectoris muscle, the amplitude-temporal parameters of monoquantum end-plate currents (EPC) and miniature EPC (mEPC) were investigated using extracellular recording. A significant dependence of the risetime of the signals on their amplitude was found after analyzing mEPC; at the same time, such dependence was absent for EPC. Approaches leading to disorganization of the active zones (AZ) of the nerve ending (NE), prolonged action of a Ca-free solution, and denervation resulted in an increased dependence of the risetime of the monoquantum signals on their amplitude; moreover, these dependences were similar for both mEPC and monoquantum EPC. Mathematical simulation showed that the obtained data could be explained by the spatial heterogeneity of the sites of spontaneous and evoked transmitter release within the regions of the AZ. A new hypothesis interpreting spontaneous and evoked transmitter release is proposed.     

Pre-synaptic and post-synaptic factors influencing the synchronism in the transmitter secretion and the amplitude and temporal parameters of a postsynaptic response in the neuromuscular junction: a model study

Using a model of the frog neuromuscular junction, we studied the influence of pre-synaptic and post-synaptic factors on the amplitude and temporal parameters of end-plate currents (EPC). A nerve terminal (NT) was supposed to include linearly distributed active zones (AZ) that are able to release a transmitter quantum with a definite temporal distribution of the release probability (AZ DRP) after successive activation of these zones by a spreading action potential (AP). An increase in the length of a terminal, distance between AZ, and time constant of the DRP decline, or a decrease in the AP conduction velocity along the NT determines a decrease in the EPS amplitude and prolongation of its rising phase. These effects result from an increased asynchronism in the transmitter release. An expansion of the temporal parameters of minature EPC leads to an increase in the EPC amplitude, i.e., provides minimization of its loss. Various EPC models are compared, and contributions of the examined pre-synaptic and post-synaptic factors in modifications of the amplitude and temporal EPC parameters are evaluated.Neirofiziologiya/Neurophysiology, Vol. 27, No. 3, pp. 163–179, May–June, 1995.     

Desensitisation of postsynaptic membrane in the neuro-muscular junction due to an increase in spontaneous quantal release of a mediator

Dependence of the amplitude of miniature end-plate currents on frequency of spontaneous quantal release modulated by the elevation of K+ concentration was studied in the frog voltage clamped neuromuscular junctions. A sharp increase of mEPC frequency (not less than approximately 50 per sec) was followed by an obvious fall in both their amplitude and acceleration of decay only in the presence of 3 microM prostigmine (acetylcholinesterase inhibitor) and 5 microM proadiphene, these agents promoting a desensitization of cholinergic postsynaptic membrane. Probable depletion of transmitter store is not involved in the phenomenon observed which is mainly due to the repetitive activation of the postsynaptic zones and the increase of the desensitized cholinoreceptor number.     

Statistical analysis of the structure of a train of miniature endplate potentials following different treatments of the process of transmitter secretion

The process of transmitter release has been statistically analysed with the use of a rat phrenic nerve-diaphragm preparation in which spontaneous transmitter secretion had been changed by ouabain, 4-aminopyridine and tetanus toxin. In all cases significant deviations of the statistics of miniature end-plate potentials (MEPP) impulse flows from Poisson process and amplitude distributions of MEPP from normal have been obtained. By the statistical characteristics two groups of processes have been distinguished: 1) normal and ouabain where certain consistency of the processes suggests the organization of transmitter release sites and 2) 4-aminopyridine and tetanus toxin where the temporary characteristics of the process in conjunction with the appropriate transformation of MEPP amplitude distribution apparently suggests breakdown of the mechanism of spontaneous synchronization of transmitter quanta release.     

Effects of pyrocatechol on neuromuscular transmission

Effects of pyrocatechol on neuromuscular transmission were studied both in the frog pectoral-cutaneous muscle and in the mouse phrenic-diaphragmatic preparation by means of extracellular microelectrode recording of synaptic signals. Pyrocatechol applied in a concentration of 0.05 mM increased the frequency of miniature end-plate currents (MEPC) and the amplitude of end-plate current (EPC) by increasing its quantum content. Pyrocatechol also increased the duration of presynaptic response. When voltage-dependent potassium channels had been blocked, pyrocatechol affected neither the EPC quantum content nor the duration of presynaptic response. It is suggested that the pyrocatechol-induced enhancement of transmitter release results from modulatory effects of pyrocatechol on voltage-dependent potassium current in the membrane of a nerve terminal.Neirofiziologiya/Neurophysiology, Vol. 25, No. 6, pp. 405–408, November–December, 1993.     

A voltage clamp study of the glutamate responsive neuromuscular junction in Drosophila melanogaster

The point and single electrode voltage clamp methods have been used to study the characteristics of junctional currents in Drosophila melanogaster larvae muscle fibers and the modulation of these currents by excitatory amino acids, short and long chain n-alkanols, and pentobarbital. The decay phase of junctional currents in Drosophila was found to be dominated by cooperativity in transmitter binding associated with reverberation, that is, repeated binding of transmitter with receptors as the transmitter molecules diffuse away from the active region. The current decay does not directly reflect the closure of ion channels and is qualitatively similar to the decay of miniature end-plate currents at the mouse neuromuscular junction after poisoning of acetylcholinesterase by paraoxon. In Drosophila an increase in membrane hyperpolarization both slows the time course of current decay and increases the degree of reverberation. The application of excitatory amino acids including glutamate, N-methyl-D-aspartate, quisqualate, and kainate causes a significant decrease in the amplitude of the junctional currents, a prolongation of the decay time course, and a reduction in reverberation of transmitter. The height of junctional currents is also diminished by the n-alkanols ethanol, pentanol, and octanol and by the barbiturate pentobarbital; ethanol also hastened the time course of decay of the currents.     

Modulatory Role of Adenosine Receptors in Insect Motor Nerve Terminals

The effects of adenosine and ATP were studied on blowfly larvae Calliphora vicina neuromuscular preparation. Adenosine diminished (IC₅₀ = 40 ± 3 M) the amplitude of nerve-evoked postsynaptic currents (EPSCs) and slightly decreased the frequency of spontaneous currents without affecting their amplitude. EPSCs were slightly reduced by ATP, and this effect was prevented by concanavalin A. Presynaptic inhibition by adenosine was temperature-dependent and insensitive to pertussis toxin. A₁ agonists of vertebrate adenosine receptor CPA and NECA failed to reproduce the effect of adenosine, and 2-CADO enhanced the EPSCs. A₁ antagonist DPCPX competitively inhibited adenosine action. A₂ agonist DPMA potentiated EPSCs, and its effect was abolished by A₂ antagonist DMPX. Adenosine and ATP failed to affect the nonquantal release of glutamate. The results show for the first time the presence of presynaptic adenosine receptors regulating transmitter release at insect motor nerve terminals and point to differences in pharmacological properties of adenosine receptor subtypes in insects and vertebrates.     

Upper and lower bounds on the non-linearity of sommation of end-plate potentials

The amplitudes of end-plate potentials are non-linearly related to the number of transmitter packets eliciting the potentials. The form of the non-linearity depends on the time-course of the change in membrane conductance as compared with the membrane time-constant. Approximate solutions for very short and very long time-constants provide upper and lower bounds on the relationship between the peak amplitude of the end-plate potential and the relative number of transmitter packets.     

Analysis of factors restricting the use of binomial statistics for studying transmitter release in neuromuscular junctions

Binomial parameters of transmitter secretion were calculated on the basis of analysis of synaptic potentials in the frog sartorius muscle. Negative values of the parameter p were found in some synapses. This happened most often in low Ca²⁺ concentrations and with low amplitude of miniature end-plate potentials. The results were interpreted in terms of a model assuming spatial heterogeneity of probability of transmitter quantum release at different release points. Simulation of transmitter secretion by computer showed that the appearance of negative values of the parameter p and incorrect estimates of n experimentally are connected with the form of distribution of probability of transmitter quantum release in the synapse and with the amplitude of miniature potentials.S. V. Kurashov Kazan' Medical Institute, Ministry of Health of the RSFSR. Translated from Neirofiziologiya, Vol. 16, No. 2, pp. 182–189, March–April, 1984.     

Effect of noradrenaline on the amplitude and temporal parameters of multiquantal currents and on the kinetics of evoked quantal secretion of a transmitter]

Noradrenaline caused a significant increase of the multiquantal endplate currents (EPC) amplitude, the EPC rising phase/the rising phase of miniature EPC ratio diminishing, at that. Noradrenaline seems to synchronise the process of quanta secretion in the EPC generation. Thus when a single stimulation of motor nerve results in release of several tenths of a transmitter, noradrenaline may increase the multiquantal EPC amplitude through synchronising of the transmitter release involved in the generation.     

Influence of the Latency Fluctuations and the Quantal Process of Transmitter Release on the End-Plate Potentials' Amplitude Distribution

Spontaneous synaptic potentials and their relation to the end-plate potential (e.p.p.) are studied. It has been suggested earlier that the e.p.p. at a single nerve-muscle junction is built up statistically of small all-or-none units which are identical in size with the spontaneous miniature end-plate potentials (m.e.p.p.'s). In this paper, a more general theory is developed which takes into account latency fluctuations of the unit components. A general equation for e.p.p. amplitude probability distribution is derived. This probability distribution is a function of the latency distribution, m.e.p.p.'s pulse shape, m.e.p.p.'s amplitude distribution, and the mean quantal content. The time course of transmitter release, or latency distribution, is derived from a histogram of synaptic delays in a frog muscle, but obtained equations can be used for other distribution functions as well.     

On the effect of the ionophore X-537A on neuromuscular transmission in the rat

In the rat phrenic nerve-diaphragm muscle preparation, X-537A at 6×10^?6 to 3×10^?5 M (1) depolarized muscle fibre membranes, (2) caused an occasional transient increase in and ultimate block of spontaneous transmitter release, (3) did not increase the amplitude of the end-plate potential (epp) but abruptly blocked stimulus-evoked transmitter release, and (4) produced an increase in the occurrence of “giant” miniature epp's (mepp's). The possibility is discussed that the sporadically raised mepp frequency was due to an ionophore-induced depolarization of nerve terminals. The increased occurrence of “giant” mepp's apparently reflected a X-537A-induced spontaneous multiquantal release of acetylcholine. This was not dependent on extracellular calcium but appeared to be of presynaptic origin.     

The inhibitory effects of some adenosine analogues on transmitter release at the mammalian neuromuscular junction

An electrophysiological study was made of the effects of four adenosine analogues, 2-chloroadenosine (2-CIA), 5'-N-ethylcarboxamidoadenosine (NECA), L-N6-phenylisopropyladenosine (L-PIA), and 2-(p-methoxyphenyl)-adenosine (CV-1674) on neurotransmitter release in the mouse phrenic nerve - hemidiaphragm preparation. All four drugs decreased miniature end-plate potential frequency in a dose-dependent manner. Evoked transmitter release in the cut diaphragm preparation was depressed by 2-CIA and CV-1674 to a similar extent. The ability of theophylline to antagonize the inhibitory effect of CV-1674 on spontaneous transmitter release was also established. On the basis of these results, the rank order of potencies was: L-PIA greater than NECA greater than 2-CIA greater than CV-1674. A clear classification of receptor type could not be made, since the ratio of potencies of L-PIA and NECA was narrow. Different slopes of the concentration-effect curves for 2-CIA and CV-1674 compared with L-PIA and NECA suggest an additional component to simple agonist action in their overall effects.     

Transmitter release in botulinum-poisoned muscles

Examination of miniature end-plate potentials (m.e.p.ps) in rat skeletal muscle poisoned in vivo by botulinum toxin type A reveals the presence of two populations of potentials. One population which corresponds to m.e.p.ps in unpoisoned muscles and to quantal end-plate potentials. The frequency of these m.e.p.ps is greatly reduced by botulinum toxin. The second population of m.e.p.ps has quite different characteristics. These m.e.p.ps have a more variable, but generally much larger amplitude, and their time to peak is longer than normal m.e.p.ps. The frequency of these m.e.p.ps increases during poisoning and reaches 0.3-1 Hz after 10-14 days. In addition to the variability in amplitude and time-to-peak these m.e.p.ps differ from those at unpoisoned junctions by being unaffected by procedures which alter extra- or intracellular Ca2+ concentrations. The appearance of this Ca2+-insensitive spontaneous quantal secretion of acetylcholine is apparently not a direct effect of the toxin but secondary to blockade of impulse transmission since it also appears at unpoisoned end-plates when transmission is impaired for other reasons. Procedures which increase the intracellular Ca2+ concentration in nerve terminals restore transmitter release from botulinum toxin poisoned nerves. Furthermore, the block caused by the toxin is very temperature-dependent, a reduction in temperature relieving the block. Since presynaptic Ca2+ currents are unaltered by the toxin it is proposed that the block of transmission is due to a reduction in the calcium content of the nerve terminal to a level where the amount of Ca2+, which normally enters, is insufficient to activate transmitter release.     

Synchronization of secretion of the evoked transmitter quanta as mechanism of the facilitating action of sympathomimetics

Noradrenaline, isoproterenol, dobutamine were found to modulate kinetics of quanta secretion so as to synchronize the transmitter release. This effect could be prevented with blocking agents of beta-adrenoreceptor (atenolol, propranolol). Activators of beta-adrenoreceptors klonidine and phenylephrine did not change the kinetics of quanta secretion, whereas phentolamine did not affect the synchronizing effect of noradrenaline. The change in the time course of the secretion induced by noradrenaline increased the end-plate current amplitude. There seems to exist a specific presynaptic mechanism involving beta-adrenoreceptors for facilitation of effects of sympathomimetics.     

Monte Carlo Simulation of Release of Vesicular Content in Neuroendocrine Cells

The release of transmitter from the vesicle, its diffusion through the fusion pore, and the cleft and its interaction with the carbon electrode were simulated using the Monte Carlo method. According to the simulation the transmitter release is largely determined by geometric factors – the ratio of the fusion pore cross-sectional and vesicular areas, if the diffusion constant is as in the aqueous solution – but the speed of transmitter dissociation from the gel matrix plays an important role during the rise phase of release. Transmitter is not depleted near the entrance to the fusion pore and there is no cleft-to-vesicle feedback, but the depletion becomes evident if the diffusion constant is reduced, especially if the pore is wide. In general, the time course of amperometric currents closely resembles the time course of the simulated transmitter concentration in the cleft and the time course of release. Surprisingly, even a tenfold change of the electrode efficiency has only a marginal effect on the amplitude or the time course of amperometric currents. Greater electrode efficiency however lowers the cleft concentration, but only if the cleft is narrow. As the cleft widens the current amplitudes diminish and rise times lengthen, but the decay times are less affected. Moreover, the amplitude dependence of the rise and decay times becomes steeper as the cleft widens and/or as the release kinetics slows. Finally, lower diffusion constant of transmitter in the narrow cleft does not further prolong the amperometric currents, whose slow time course reflects slow release kinetics.