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.     

Role of Potassium Channels in Facilitation of Transmitter Release from Frog Motor Nerve Ending (Electrophysiology and Mathematical Simulation)

In experiments on neuromuscular junctions in the frog m. thoraco-cutaneous, we studied changes in the transmitter release and shape of the nerve ending (NE) response related to high-frequency (10 or 50 sec^-1) rhythmic stimulation of the motor nerve; an extracellular recording technique was used. At a low extracellular Ca²⁺ concentration, rhythmic stimulation resulted in a gradual increase in the quantum content of end-plate currents, i.e., in facilitation. Simultaneously, the third (positive) phase of the NE response became smaller, the amplitude of the second (negative) phase of this response also decreased, while the duration of this phase increased. Modifications of the NE response upon stimulation with a 10 sec^-1 frequency were more clearly expressed than those at 50 sec^-1 stimulation. In Ca²⁺-free solutions, rhythmic stimulation was accompanied by analogous modifications of the shape of NE responses, and the dynamics of these changes were the same at both the above-mentioned stimulation frequencies. When 0.5-1.0 mM tetraethylammonium was applied, 10 sec^-1 stimulation was accompanied by no facilitation of transmitter release; at 50 sec^-1 stimulation, this phenomenon was observed but was weaker than in the control, and the shape of NE responses underwent only mild changes. Simulation of electrogenesis in the studied structure showed that modifications of the NE response shape related to rhythmic 10 sec^-1 stimulation can develop in the case of a gradual decrease in the voltage-dependent potassium membrane conductivity, which results in prolongation of the de- and repolarization phases of action potentials and increases in the amplitude and duration of the inward calcium current. At higher stimulation frequencies (50 sec^-1), this mechanism is accompanied by a gradual increase in the Ca²⁺-dependent potassium conductivity, due to an increase in the intracellular Ca²⁺ concentration. These data allow us to conclude that the intensity of facilitation of transmitter release from the frog motor NE is related not only to accumulation of residual calcium, but also to changes of presynaptic calcium current due to modification of the kinetics of functioning of the potassium channels.     

Transmitter release in proximal and distal parts of a nerve terminal of the frog sartorius muscle

Evoked synaptic potential were recorded extracellularly in experiments on a nervemuscle preparation of the frog sartorius muscle. A decrease in evoked transmitter release was found from the proximal to the distal parts of the nerve ending, due to a decrease in the probability of transmitter quantum release. The terminal portions of the synapse are less sensitive than the proximal parts to changes in Ca⁺⁺ concentration, they show less marked facilitation of transmitter release during paired and repetitive stimulation, and exhibit deeper and more rapidly developing depression. It is concluded that differences in transmitter release in the terminal parts of the synapse are due to the low reserves of transmitter and the lower premeability of the presynaptic membrane to Ca⁺⁺.     

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.     

Time course of transmitter release calculated from simulations of a calcium diffusion model.

A three-dimensional presynaptic calcium diffusion model developed to account for characteristics of transmitter release was modified to provide for binding of calcium to a receptor and subsequent triggering of exocytosis. When low affinity (20 microM) and rapid kinetics were assumed for the calcium receptor triggering exocytosis, and stimulus parameters were selected to match those of experiments, the simulations predicted a virtual invariance of the time course of transmitter release to paired stimulation, stimulation with pulses of different amplitude, and stimulation in different calcium solutions. The large temperature sensitivity of experimental release time course was explained by a temperature sensitivity of the model's final rate limiting exocytotic process. Inclusion of calcium tail currents and a saturable buffer with finite binding kinetics resulted in high peak calcium transients near release sites, exceeding 100 microM. Models with a single class of calcium binding site to the secretory trigger molecule failed to produce sufficient synaptic facilitation under this condition. When at least one calcium ion binds to a different site having higher affinity and slow kinetics, facilitation again reaches levels similar to those seen experimentally. It is possible that the neurosecretory trigger molecule reacts with calcium at more than one class of binding site.     

Acetylcholine Synthesis and Release by a Sympathetic Ganglion in the Presence of 2-(4-Phenylpiperidino) Cyclohexanol (AH5183)

These experiments measured the release and the synthesis of acetylcholine (ACh) by cat sympathetic ganglia in the presence of 2-(4-phenylpiperidino) cyclohexanol (AH5183), an agent that blocks the uptake of ACh into synaptic vesicles. Evoked transmitter release during short periods of preganglionic nerve stimulation was not affected by AH5183, but release during prolonged stimulation was not maintained in the drug's presence, whereas it was in the drug's absence. The amount of ACh releasable by nerve impulses in the presence of AH5183 was 194 +/- 10 pmol, which represented 14 +/- 1% of the tissue ACh store. The effect of AH5183 on ACh release was not well antagonized by 4-aminopyridine (4-AP), and not associated with inhibition of stimulation-induced calcium accumulation by nerve terminals. It is concluded that AH5183 blocks ACh release indirectly, and that the proportion of stored ACh releasable in the compound's presence represents transmitter in synaptic vesicles available to the release mechanism. The synthesis of ACh during 30 min preganglionic stimulation in the presence of AH5183 was 2,448 +/- 51 pmol and in its absence it was 2,547 +/- 273 pmol. Thus, as the drug decreased ACh release it increased tissue content. The increase in tissue content of ACh in the presence of AH5183 was not evident in resting ganglia; it was evident in stimulated ganglia whether or not tissue cholinesterase was inhibited; it was increased by 4-AP and reduced by divalent cation changes expected to decrease calcium influx during nerve terminal depolarization.(ABSTRACT TRUNCATED AT 250 WORDS)     

Calcium stores in hippocampal synaptic boutons mediate short-term plasticity, store-operated Ca2+ entry, and spontaneous transmitter release

Evoked transmitter release depends upon calcium influx into synaptic boutons, but mechanisms regulating bouton calcium levels and spontaneous transmitter release are obscure. To understand these processes better, we monitored calcium transients in axons and presynaptic terminals of pyramidal neurons in hippocampal slice cultures. Action potentials reliably evoke calcium transients in axons and boutons. Calcium-induced calcium release (CICR) from internal stores contributes to the transients in boutons and to paired-pulse facilitation of EPSPs. Store depletion activates store-operated calcium channels, influencing the frequency of spontaneous transmitter release. Boutons display spontaneous Ca2+ transients; blocking CICR reduces the frequency of these transients and of spontaneous miniature synaptic events. Thus, spontaneous transmitter release is largely calcium mediated, driven by Ca2+ release from internal stores. Bouton store release is important for short-term synaptic plasticity and may also contribute to long-term plasticity.     

Presynaptic calcium diffusion from various arrays of single channels. Implications for transmitter release and synaptic facilitation.

A one-dimensional model of presynaptic calcium diffusion away from the membrane, with cytoplasmic binding, extrusion by a surface pump, and influx during action potentials, can account for the rapid decay of phasic transmitter release and the slower decay of synaptic facilitation following one spike, as well as the very slow decline in total free calcium observed experimentally. However, simulations using this model, and alternative versions in which calcium uptake into organelles and saturable binding are included, fail to preserve phasic transmitter release to spikes in a long tetanus. A three-dimensional diffusion model was developed, in which calcium enters through discrete membrane channels and acts to release transmitter within 50 nm of entry points. Analytic solutions of the equations of this model, in which calcium channels were distributed in active zone patches based on ultrastructural observations, were successful in predicting synaptic facilitation, phasic release to tetanic spikes, and the accumulation of total free calcium. The effects of varying calcium buffering, pump rate, and channel number and distribution were explored. Versions appropriate to squid giant synapses and frog neuromuscular junctions were simulated. Limitations of key assumptions, particularly rapid nonsaturable binding, are discussed.     

Mechanisms of neurotransmitter release facilitation in strontium solutions

Mechanisms of neurotransmitter release facilitation were studied using electrophysiological recording of end-plate currents (EPC) and nerve ending (NE) responses after substitution of extracellular Ca ions with Sr ions at the frog neuromuscular junction. The solutions with 0.5 mM concentration of Ca ions (calcium solution) or 1 mM concentration of Sr ions (strontium solution) were used where baseline neurotransmitter release (at low-frequency stimulation) is equal. Decay of paired-pulse facilitation of EPC at calcium solutions with increase of interpulse interval from 5 to 500 ms was well described by three-exponential function consisting of early, first and second components. Facilitation at strontium solutions was significantly diminished due mainly to decrease of early and first components. At the same time, EPC facilitation with rhythmic stimulation (10 or 50 imp/s) at strontium solutions was significantly increased. Also more pronounced decrease of NE response 3rd phase, reflecting potassium currents was detected under rhythmic stimulation of 50 imp/s at strontium solutions comparing to calcium solutions. It was concluded that facilitation sites underlying first and early components had lower affinity to Sr ions than to Ca ions. The enhancement of frequency facilitation at strontium solutions is mediated by two mechanisms: more pronounced broadening of NE action potential and increase of bivalent cation influx due to feebly marked activation of Ca(2+)-dependent potassium current by Sr ions, and slower dynamics of Sr(2+) removal from NE axoplasm comparing to Ca(2+).     

Glutamate uptake in synaptic plasticity: from mollusc to mammal

A great deal of research has been directed toward understanding the cellular mechanisms underlying synaptic plasticity and memory formation. To this point, most research has focused on the more "active" components of synaptic transmission: presynaptic transmitter release and postsynaptic transmitter receptors. Little work has been done characterizing the role neurotransmitter transporters might play during changes in synaptic efficacy. We review several new experiments that demonstrate glutamate transporters are regulated during changes in the efficacy of glutamatergic synapses. This regulation occurred during long-term facilitation of the sensorimotor synapse of Aplysia and long-term potentiation of the Schaffer-collateral synapse of the rat. We propose that glutamate transporters are "co-regulated" with other molecules/processes involved in synaptic plasticity, and that this process is phylogenetically conserved. These new findings indicate that glutamate transporters most likely play a more active role in neurotransmission than previously believed.     

Changes in miniature endplate potential frequency during repetitive nerve stimulation in the presence of Ca2+, Ba2+, and Sr2+ at the frog neuromuscular junction

Miniature endplate potentials (MEPPs) were recorded from frog sartorious neuromuscular junctions under conditions of reduced quantal contents to study the effect of repetitive nerve stimulation on asynchronous (tonic) quantal transmitter release. MEPP frequency increased during repetitive stimulation and then decayed back to the control level after the conditioning trains. The decay of the increased MEPP frequency after 100-to 200-impulse conditioning trains can be described by four components that decayed exponentially with time constants of about 50 ms, 500 ms, 7 s, and 80 s. These time constants are similar to those for the decay of stimulation-induced changes in synchronous (phasic) transmitter release, as measured by endplate potential (EPP) amplitudes, corresponding, respectively, to the first and second components of facilitation, augmentation, and potentiation. The addition of small amounts of Ca2+ or Ba2+ to the Ca2+-containing bathing solution, or the replacement of Ca2+ with Sr2+, led to a greater increase in the stimulation-induced increases in MEPP frequency. The Sr-induced increase in MEPP frequency was associated with an increase in the second component of facilitation of MEPP frequency; the Ba-induced increase with an increase in augmentation. These effects of Sr2+ and Ba2+ on stimulation-induced changes in MEPP frequency are similar to the effects of these ions on stimulation- induced changes in EPP amplitude. These ionic similarities and the similar kinetics of decay suggest that stimulation induced changes in MEPP frequency and EPP amplitude have some similar underlying mechanisms. Calculations are presented which show that a fourth power residual calcium model for stimulation-induced changes in transmitter release cannot readily account for the observation that stimulation- induced changes in MEPP frequency and EPP amplitude have similar time- courses.     

Probabilistic secretion of quanta and the synaptosecretosome hypothesis: evoked release at active zones of varicosities, boutons, and endplates.

A quantum of transmitter may be released upon the arrival of a nerve impulse if the influx of calcium ions through a nearby voltage-dependent calcium channel is sufficient to activate the vesicle-associated calcium sensor protein that triggers exocytosis. A synaptic vesicle, together with its calcium sensor protein, is often found complexed with the calcium channel in active zones to form what will be called a "synaptosecretosome." In the present work, a stochastic analysis is given of the conditions under which a quantum is released from the synaptosecretosome by a nerve impulse. The theoretical treatment considers the rise of calcium at the synaptosecretosome after the stochastic opening of a calcium channel at some time during the impulse, followed by the stochastic binding of calcium to the vesicle-associated protein and the probability of this leading to exocytosis. This allows determination of the probabilities that an impulse will release 0, 1, 2,... quanta from an active zone, whether this is in a varicosity, a bouton, or a motor endplate. A number of experimental observations of the release of transmitter at the active zones of sympathetic varicosities and boutons as well as somatic motor endplates are described by this analysis. These include the likelihood of the secretion of only one quantum at an active zone of endplates and of more than one quantum at an active zone of a sympathetic varicosity. The fourth-power relationship between the probability of transmitter release at the active zones of sympathetic varicosities and motor endplates and the external calcium concentration is also explained by this approach. So, too, is the fact that the time course of the increased rate of quantal secretion from a somatic active zone after an impulse is invariant with changes in the amount of calcium that enters through its calcium channel, whether due to changes consequent on the actions of autoreceptor agents such as adenosine or to facilitation. The increased probability of quantal release that occurs during F1 facilitation at the active zones of motor endplates and sympathetic boutons is predicted by the residual binding of calcium to a high-affinity site on the vesicle-associated protein. The concept of the stochastic operation of a synaptosecretosome can accommodate most phenomena involving the release of transmitter quanta at these synapses.     

Differential effects of Ba2+, Sr2+, and Ca2+ on stimulation-induced changes in transmitter release at the frog neuromuscular junction

Endplate potentials (EPP) were recorded from the frog sartorius neuromuscular junction under conditions of low quantal content to study the effect of Ba2+, Sr2+, and Ca2+ on the changes in evoked transmitter release that occur during and after repetitive stimulation. The addition of 0.1-1 mM Ba2+ or Sr2+ to the Ca2+-containing bathing solution, or the replacement of Ca2+ with 0.8-1.4 mM Sr2+, led to a greater increase in EPP amplitudes during and immediately after repetitive stimulation. These changes in release were analyzed in terms of the four apparent components of increased transmitter release that have previously been distinguished on the basis of their kinetic properties. The Ba2+-induced increase in EPP amplitudes was associated with an increase in the magnitude but not the time constant of decay of augmentation. Ba2+ had little effect on potentiation or the first and second components of facilitation. The Sr2+-induced increase in EPP amplitudes was associated with an increase in the magnitude and the time constant of decay of the second component of facilitation. Sr2+ had little effect on potentiation, augmentation, or the first component of facilitation. The selective effects of Ba2+ on augmentation and of Sr2+ on the second component of facilitation were reversible and could be obtained in the presence of the other ion. The addition of 0.1-0.3 mM Ca2+ to the bathing solution had little effect on potentiation, augmentation, or the two components of facilitation. These results provide pharmacological support for the proposal that there are four different components of increased transmitter release associated with repetitive stimulation and suggest that the underlying factors in the nerve terminal that give rise to these components can act somewhat independently of one another.     

A(2A) adenosine receptor facilitation of neuromuscular transmission: influence of stimulus paradigm on calcium mobilization

The influence of stimulus pulse duration on calcium mobilization triggering facilitation of evoked [(3)H]acetylcholine ([(3)H]ACh) release by the A(2A) adenosine receptor agonist CGS 21680C was studied in the rat phrenic nerve-hemidiaphragm. The P-type calcium channel blocker omega-agatoxin IVA (100 nM) decreased [(3)H]ACh release evoked with pulses of 0.04-ms duration, whereas nifedipine (1 microM) inhibited transmitter release with pulses of 1-ms duration. Depletion of intracellular calcium stores by thapsigargin (2 microM) decreased [(3)H]ACh release evoked by pulses of 1 ms, an effect observed even in the absence of extracellular calcium. With short (0.04-ms) stimulation pulses, when P-type calcium influx triggered transmitter release, facilitation of [(3)H]ACh release by CGS 21680C (3 nM) was attenuated by both thapsigargin (2 microM) and nifedipine (1 microM). With longer stimuli (1 ms), a situation in which both thapsigargin-sensitive internal stores and L-type channels are involved in ACh release, pretreatment with either omega-agatoxin IVA (100 nM) or nifedipine (1 microM) reduced the facilitatory effect of CGS 21680C (3 nM). The results suggest that A(2A) receptor activation facilitates ACh release from motor nerve endings through alternatively mobilizing the available calcium pools (thapsigargin-sensitive internal stores and/or P- or L-type channels) that are not committed to the release process in each stimulation condition.     

Changes in Electrogenesis in the Motor Nerve Terminal with Long-Lasting High-Frequency Activation as a Factor of the Control of Transmitter Release

Using the technique of extracellular recording from the region of the neuromuscular junction in the cutaneous-sternal muscle in the frog under conditions of a reduced concentration of Ca²⁺ in the surrounding milieu, we demonstrated that long-lasting (10 min) rhythmic stimulation of the motor nerve with a frequency of 10 sec^{− 1} leads to a gradual increase in the evoked transmitter release. These changes are accompanied by a decrease in the amplitude of electrical responses of the nerve terminal (NT) and by a retardation of its second phase, as well as by a diminution of the third phase. Under conditions of long-lasting (5 min) stimulation with a frequency of 50 sec⁻¹, we observed a two-phase change in the intensity of transmitter release: on the 2nd min, the initial rise was replaced by inhibition. Modifications of the response of the NT with different stimulation frequencies were qualitatively similar, but with a frequency of 10 sec⁻¹ they were clearly expressed. Mathematical simulation of ion currents in the NT demonstrated that voltage-dependent potassium and sodium channels are inactivated in the course of long-lasting high-frequency excitation; the shape of the action potential is modified with changes in the rate of such inactivation. This leads to either an increase or a decrease of the inward calcium current. We conclude that the change in electrogenesis in the NT with long-lasting high-frequency activation of neuromuscular junctions exerts a significant influence on the dynamics of transmitter release. Neirofiziologiya/Neurophysiology, Vol. 37, No. 2, pp. 108–115, March–April, 2005.     

Critical role of intracellular calcium in plasticity mechanisms of defense behavior command neurons LPl1 and PPl1 of Helix lucorum during nociceptive sensitization

The role of intracellular calcium in changes in excitability and responses of defense behavior command neurons LP11 and PP11 of Helix lucorum to sensory stimulation was investigated in semi-intact preparation of a snail during nociceptive sensitization. It was found that application of sensitizing stimuli onto the snail's head initiated membrane depolarization, increase in its excitability as well as depression of neural responses evoked by sensory stimuli in short-term period of sensitization and significant facilitation of neural responses in long-term period of sensitization. To elucidate the contribution of LP11 and PP11 neurons in plasticity rearrangements involved in the mechanisms of sensitization, we applied sensitizing stimuli during strong hyperpolarization of the neurons or after intracellular injection of calcium chelators. Application of sensitizing stimuli during hyperpolarization of the neurons suppressed the increase in membrane excitability and depressed the neural responses evoked by chemical stimulation of snail's head i.m. short- and long-term periods of sensitization. At the same time, synaptic facilitation of neural responses evoked by tactile stimulation of snail's head and foot was observed, which was similar to synaptic facilitation in the control sensitized snail. Intracellular injection of EGTA or BARTA (calcium chelators) before sensitization suppressed synaptic facilitation in neural responses evoked by sensory stimulation. Under these conditions, the increase in excitability was more pronounced then in the control snail neurons. The experimental results suggest the changes in neural responses evoked by sensory stimulation in sensitized snails involve postsynaptic calcium-dependent mechanisms of plasticity in LP11 and PP11 neurons.     

A nitric oxide/cyclic GMP-dependent protein kinase pathway alters transmitter release and inhibition by somatostatin at a site downstream of calcium entry

We have examined the somatostatin-mediated modulation of acetylcholine release from intact chick embryo choroid tissue and compared these data with those obtained using acutely dissociated neuronal cell bodies from the chick ciliary ganglion. Acetylcholine release, evoked in a calcium-dependent manner by a high potassium (55 mM KCI) stimulation in both preparations, was inhibited almost completely by 100 nM somatostatin. Measurement of intracellular calcium in these neurons revealed that somatostatin blocked the large calcium transient that was observed in control neurons following KCI exposure. The modulatory effect of somatostatin on transmitter release was significantly attenuated by pre-treatment with pharmacologic agents that selectively block cyclic GMP (cGMP)-dependent protein kinase (PKG) or nitric oxide (NO) synthase. It is interesting that this prevention of somatostatin-mediated acetylcholine release inhibition occurred without reversal of the somatostatin-mediated block of the KCl-evoked calcium transient. Furthermore, a NO donor or cGMP analogue could block KCI-evoked acetylcholine release, but only cGMP could reduce the KCI-evoked calcium transient. Although cGMP could reduce the KCI-evoked calcium transient, a cGMP analogue was shown to reduce calcium ionophore-evoked transmitter release. Thus, somatostatin reduces acetylcholine release by modulating calcium influx, but the NO-PKG pathway can inhibit acetylcholine release, and alter somatostatin-mediated inhibition, by affecting transmitter release at some point after calcium entry.     

Can presynaptic depolarization release transmitter without calcium influx?

Recent experimental evidence suggesting that presynaptic depolarization can evoke transmitter release without calcium influx has been re-examined. The presynaptic terminal of the squid giant synapse can be depolarized by variable amounts while recording presynaptic calcium current under voltage clamp and postsynaptic responses. Small depolarizations open few calcium channels with large single channel currents. Large depolarizations approaching the calcium equilibrium potential open many channels with small single channel currents. When responses to small and large depolarizations eliciting similar total macroscopic calcium currents are compared, the large pulses evoke more transmitter release. This apparent voltage-dependence of transmitter release may be explained by the greater overlap of calcium concentration domains surrounding single open calcium channels when many closely apposed channels open at large depolarizations. This channel domain overlap leads to higher calcium concentrations at transmitter release sites and more release for large depolarizations than for small depolarizations which open few widely dispersed channels. At neuromuscular junctions, a subthreshold depolarizing pulse to motor nerve terminals may release over a thousand times as much transmitter if it follows a brief train of presynaptic action potentials than if it occurs in isolation. This huge synaptic facilitation has been taken as indicative of a direct effect of voltage which is manifest only when prior activity raises presynaptic resting calcium levels. This large facilitation is actually due to a post-tetanic supernormal excitability in motor nerve terminals, causing the previously subthreshold test pulse to become suprathreshold and elicit a presynaptic action potential. When motor nerve terminals are depolarized by two pulses, as the first pulse increases above a certain level it evokes more transmitter release but less facilitation of the response to the second pulse.(ABSTRACT TRUNCATED AT 250 WORDS)