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.     

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.     

Evaluation of the tonic and phasic effects of endogenous adenosine on the transmitter secretion in the neuromuscular junction

Exogenous adenosine reduced the amplitude of multiquantal end-plate currents due to a depressant action on transmitter release. Theophylline did not change the amplitude of end-plate currents under low-rate motor nerve stimulation. The findings suggest a possibility of both tonic and phasic inhibitory actions of endogenous adenosine on transmitter release when utilization of this purine in synaptic cleft is inactivated.     

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.     

Calcium modulation of the release kinetics of the acetylcholine quanta generating multiquantal postsynaptic response

The effects of calcium on the quantal content of nerve-evoked endplate currents (EPC) and on the temporal parameters of quantal release were studied in the frog neuromuscular synapse using the method of "subtractions". It was shown that under physiological conditions quanta generating multiquantal postsynaptic responses were released nonsynchronously because of a considerable variability of latencies of the uniquantal responses forming multiquantal EPC. Different calcium dependences for EPCs quantal content and time course of the quantal release were revealed. The average quantal content grew exponentially with the increase in calcium concentration from 0.4 to 1.8 mmol/L, whereas the release synchronicity reached the maximum at 1 mmol/L calcium. It was suggested that the changes in the synchronicity of the evoked release were one of the mechanisms of the synaptic plasticity.     

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.     

End plate currents at the physiological level of quantal secretion and after potentiation of transmitter release by 4-aminopyridine

The role of postysynaptic potentiation (PSP) and asynchronous secretion of acetylcholine (ACh) in the generation of multiquantal currents and end plate currents (EPC) was investigated under voltage clamp conditions in transected sartorius muscle of the frog before and after 4-aminopyridine (4-AP) treatment. Compared with miniature EPC (MEPC), showing an average quantum content of 249, multiquantal EPC has a larger amplitude, longer rise-time, and longer decay-time (_epc). Magnesium ions (6–10 mM) reduce the amplitude and _spec of EPC without affecting its rise-time. Rhythmical stimulation (10 Hz for 60 sec) results in reduced amplitude and but increased rise-time of EPC. D-turbocurarine (5×10^–7 M) and -bungarotoxin (1×10^–5 gm/ml) diminishes the difference between _epc and _mepc. In the presence of 4-AP, all these effects are much more pronounced. It is proposed that asynchronous secretion of ACh from motor nerve teminals causes prolongation of the rise-time and reduction of the amplitude of EPC but has little or no effect upon the decay rate of EPC. The slow decay of multiquantal EPC, both in the absence and in the presence of 4-AP, is almost entirely due to postynaptic interaction of ACh quanta, i.e., PSP.Kurashov Meidcal Institute, Kazhan. Translated from Neirofiziologiya, Vol. 23, No. 1, pp. 48–56, January–February, 1991.     

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.     

Comparison of Pre- and postsynaptic process kinetics in neuro-muscular synapse using the end-plate current model

The effect of correlation between the kinetics of acetylcholine (ACh) quanta release and the kinetics of the postsynaptic membrane channel activity on end-plate currents (EPCs) was studied in model experiments. The presynaptic process was described by a transmitter secretion probability distribution (SPD), and the postsynaptic process by characteristicsof miniature EPC (MEPC) with standard amplitude and variable decay duration (_MEPC). The SPD was represented by a curve with an S-like rise and exponential decay. The main portion of the data was analyzed after being adjusted to 20°C. The effect of the EPC amplitude loss (the difference between the EPC amplitudes in cases of synchronous and non-synchronous release of the ACh quanta) due to temporal dispersion of the transmitter secretion process was 43% at _MEPC=1.0 msec and 20% at _MEPC=4–5 msec under conditions when acetylcholinesterase (AChE) was inhibited.When _MEPC varied over a wide range, the effect of the EPC amplitude loss could be described by a curve with steeply and gently sloping portions; the boundary between these two portions corresponded to approximately 1.0 msec _MEPC, which is nearly the channel lifetime at resting membrane potential. The rise time of the EPC only slightly related to changes in _MEPC. The rate of EPC decay exceeded that in MEPC only when the lifetimes of the ACh-activated ionic channels were lower than their physiological values. In this case, the kinetics of transmitter release became a factor determining the EPC decay time course.Three variants of an increase in temporal dispersion of the ACh quanta secretion were modeled for constant _MEPC: one resulting from an increase in the SPD rising phase; a second resulting from equal increases in the SPD rising and declining phases, and a third resulting from an increase in the SPD declining phase. The results of the first variant corresponded most closely to experimental data on changes in EPC during a short-term period of rhythmical activity. This was also characterized by minimal effect of EPC amplitude loss.It has been suggested that the interrelation between the parameters of SPD and _MEPC is an important factor regulating the amplitude and duration of the postsynaptic signal. The maintenance of this interrelation at a constant level ensures reliability of synaptic transmission.Translated from Neirofiziologiya, Vol. 25, No. 2, pp. 126–132, March–April, 1993.     

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.     

Simultaneous Release of Multiple Vesicles from Rods Involves Synaptic Ribbons and Syntaxin 3B

First proposed as a specialized mode of release at sensory neurons possessing ribbon synapses, multivesicular release has since been described throughout the central nervous system. Many aspects of multivesicular release remain poorly understood. We explored mechanisms underlying simultaneous multivesicular release at ribbon synapses in salamander retinal rod photoreceptors. We assessed spontaneous release presynaptically by recording glutamate transporter anion currents (I_A(glu)) in rods. Spontaneous I_A(glu) events were correlated in amplitude and kinetics with simultaneously measured miniature excitatory postsynaptic currents in horizontal cells. Both measures indicated that a significant fraction of events is multiquantal, with an analysis of I_A(glu) revealing that multivesicular release constitutes ∼30% of spontaneous release events. I_A(glu) charge transfer increased linearly with event amplitude showing that larger events involve greater glutamate release. The kinetics of large and small I_A(glu) events were identical as were rise times of large and small miniature excitatory postsynaptic currents, indicating that the release of multiple vesicles during large events is highly synchronized. Effects of exogenous Ca²⁺ buffers suggested that multiquantal, but not uniquantal, release occurs preferentially near Ca²⁺ channels clustered beneath synaptic ribbons. Photoinactivation of ribbons reduced the frequency of spontaneous multiquantal events without affecting uniquantal release frequency, showing that spontaneous multiquantal release requires functional ribbons. Although both occur at ribbon-style active zones, the absence of cross-depletion indicates that evoked and spontaneous multiquantal release from ribbons involve different vesicle pools. Introducing an inhibitory peptide into rods to interfere with the SNARE protein, syntaxin 3B, selectively reduced multiquantal event frequency. These results support the hypothesis that simultaneous multiquantal release from rods arises from homotypic fusion among neighboring vesicles on ribbons and involves syntaxin 3B.     

The time course of the evoked secretion of the mediator quanta in various regions of the frog motor nerve ending

Apart from the fact that the gradient of the velocity of the AP propagation along the nerve terminal and the intensity of secretion do exist, the kinetics of a quanta transmitter release may also be revealed in different parts of the terminal. The velocity of the propagation and the minimum sympatric delay tend to diminish along with moving away from the myelinated part of axon, whereas the synchronicity of the quanta release rises. The distinctions in the time course of secretion in different parts of the terminal were amplified when the calcium ion concentration in the medium was enhanced. The observed peculiarities of the secretion kinetics in different regions of nerve ending seem to compensate for diminishing of the amplitude of multiquantal endplate current.     

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.     

Rhythmic Activity of Murine Neuromuscular Junctions upon Activation of Release of Stored Calcium in the Presence of a Calcium Buffer

Using a two-electrode voltage-clamp technique, we recorded end-plate currents (EPCs) in neuromuscular synaptic junctions of the murine diaphragm upon rhythmic stimulation of the n. phrenicus with frequencies of 7, 20, 50, 70, and 100 sec⁻¹. Parameters of EPC series were analyzed against the background of the action of a mobilizer of intracellular calcium, ryanodine (0.5 μM), after the loading of terminals by 1.2 mM BAPTA (calcium buffer with rapid dynamics of binding of calcium), and upon the action of ryanodine in the presence of BAPTA. Under the action of ryanodine, the amplitude and quantum content of EPC within the plateau phase increased by 100 to 150% (P < 0.05). Loading with BAPTA evoked sharp decreases in the quantum content of unitary EPCs, the intensity of the initial facilitation, and the level of the EPC plateau in series within the entire range of stimulation frequencies used. Against the background of the action of BAPTA, the facilitatory effect of ryanodine increased; inhibitory effects of BAPTA with respect to the amplitude of unitary EPC and the level of the initial facilitation were completely compensated, whereas the level of EPC at the plateau stage increased to levels exceeding the control values by 50 to 70%. The ability of ryanodine to facilitate the transmitter (acetylcholine) release, which was enhanced in the presence of BAPTA, was completely neutralized by a blocker of L-type calcium channels, verapamil (5 μM). In the absence of BAPTA, verapamil did not influence the effects of ryanodine. We hypothesize that in the presence of BAPTA calcium channels of L type whose activity is resistive to the buffer action of BAPTA are disinhibited. The calcium current through L-type channels, perhaps, is capable of stimulating calcium release from the stores of nerve terminals and, as a consequence, of intensifying the facilitatory effect of ryanodine on the release of acetylcholine. After verapamil-induced blockade of this current, BAPTA demonstrates the ability to prevent the facilitatory effect of ryanodine on the transmitter release. Neirofiziologiya/Neurophysiology, Vol. 37, No. 4, pp. 330–338, July–August, 2005.     

Effects of voltage and temperature changes on postsynaptic potentiation at the frog neuromuscular junction

The difference in the decay time constants of multiquantal endplate currents (EPC) produced by presenting paired stimuli 100 msec apart was measured during experiments on transversely cut neuromuscular preparations of the frog sartorius muscle. When acetylcholinesterase was inhibited by 3×10^–6 M prostigmine, decay time of the 2nd EPC (₂) was 39±8% longer than that of the first (₁) due to postsynaptic potentiation. It was found that degree of potentiation was not affected by membrane potential level within the –30 to –120 mV range. Several effects were produced by a drop in temperature: an increase in EPC decay time constant and in that of miniature endplate currents (MEPC) in particular, a slight drop in MEPC amplitude, and a reduction in EPC quantal content. By comparing paired EPC of equal quantal content at different temperatures it was found that potentiation was more pronounced at 12°C than at 22°C and the temperature coefficient Q₁₀ at which ₂ exceeds ₁ was 2.0±0.2 (n=7). The processes determining postsynaptic potential are clearly not voltage-dependent but have a complex dependence on temperature. Quantal content of EPC falls with reduced temperature, thereby restraining potentiation, while helping to retain residual transmitter activity.I. M. Sechenov Institute of Evolutionary Physiology and Biochemistry, Academy of Sciences of the USSR, Leningrad. Kurashov Medical Institute, Kazan'. Translated from Neirofiziologiya, Vol. 18, No. 4, pp. 512–518, July–August, 1986.     

Effect of dimedrol on the function of the neuromuscular synapse and the generation of action potentials by motor nerve fibers

Microelectrode registration of synaptic potentials in the frog cutaneous-pectoris muscle has shown dimedrol (7.9 X 10(-5) M) to act on synaptic transmission decreasing the quantal content, estimated by mean EPP amplitude to mean miniature EPP amplitude ratio, the quantal content calculated by variation coefficient of EPP amplitude being unaffected. The data suggest possible transmitter release and depletion of mediator stock. The experiments on isolated motor nerve fibers have demonstrated dimedrol to cause the increase in transmitter release probability by widening the action potentials in the terminals and thus enhancing Ca2+ influx.     

Effects of quantal content,membrane potential,and cholinoceptor density on the time course of end-plate currents in the rat under during acetylcholinesterase inhibition

The time-course of multiquantal end-plate currents (EPCs) was compared with monoquantal synaptic responses, i.e., miniature end-plate currents (MEPCs), in voltage-clamped rat diaphragm muscle fibers. In the presence of active acetylcholinesterase (AChE), the time constant of the decay of EPCs, that were composed of 25–140 quanta, was 1.2 times greater than that of MEPCs. After inhibition of AChE with armine or proserine the decay of the EPC was longer than the decay of the MEPC by 10–100 times, and unlike the MEPC, in the majority of synapses it could be described by the sum of two (n=34) or three (n=9) exponentials: monoexponential EPCs were noted in only three cases. The nature and duration of the EPC decay depended on its quantal content. After a reduction in the quantal content a three-exponential EPC decay could be successively reduced to a two- and a mono-exponential decay. A ,slow, component of the EPC decay, unlike the MEPC decay, was extremely sensitive to changes in the membrane potential, and extracellular magnesium ion concentration. When the cholinoceptors were irreversibly blocked by -bungarotoxin the MEPC decay accelerated, and the monoexponential EPC decay initially slowed down before accelerating, but even during a profound blockade the open-times of the ion channels were not affected. It therefore appears that during the generation of multiquantal EPCs when AChE is inhibited, not only does the synchronicity of the ion channel opening change, but so do their kinetics, possibly because of ion channel blockade by endogenous acetylcholine.S. V. Kurashov Institute of Medicine, Russian Ministry of Public Health, Kazan. Translated from Neirofiziologiya, Vol. 24, No. 3, pp. 269–279, May–June, 1992.     

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.     

Facilitation and Depression of Neuromuscular Transmission under Conditions of Blockade of Ryanodine Receptors

In our experiments on mice, end-plate currents (EPC) evoked by stimulation of the phrenic nerve were intracellularly recorded in neuromuscular synaptic junctions of the phrenic muscle. We studied the effects of a specific blocker of ryanodine receptors, ryanodine (10 to 20 M), on the amplitude and time parameters of EPC under conditions of tetanic facilitation and depression of synaptic transmission at frequencies of stimulation of 4 to 200 sec^-1. Ryanodine inhibited facilitation at stimulation frequencies of 7 to 70 sec^-1 (with maximum effect at 20 sec^-1) and accelerated depression. In the presence of ryanodine, an initial rundown of the EPC amplitude in the course of depression of transmission increased at high frequencies of stimulation (50 to 100 sec^-1), whereas the EPC amplitude at the plateau level decreased already at low frequencies (4 to 7 sec^-1). We concluded that the changes in facilitation and depression resulted from blocking of the presynaptic ryanodine receptors by ryanodine. It seems probable that calcium release from the calcium stores in murine motor terminals is a factor involved in the control of processes of transmitter secretion during short-term rhythmic activation of the junction.     

Changes in the Asynchronicity of Transmitter Release at the Neuromuscular Junction during Prolonged High-Frequency Stimulation

In experiments on neuromuscular junctions in the frog m. cutaneous-pectoris, changes in the intensity and asynchronicity of transmitter release during high-frequency (10 and 50 sec^-1) rhythmic stimulation of the motor nerve were investigated using extracellular recording. At low extracellular Ca²⁺ concentrations, rhythmic stimulation resulted in a gradual enlargement of the quantum content of end-plate currents (EPC), the so-called facilitation. The latter phenomenon was accompanied by an increase in the average value and variance of synaptic delays of single-quantum EPC, a shift of the main mode of their distribution towards greater values, and an increase in the latency of the nerve ending responses. The above-described changes reduce the magnitude of facilitation in the neuromuscular synapse.