Mechanism of carbachol and adenosine action on spontaneous quantal mediator release at frog neuromuscular junction

Experiments on the frog sartorius muscle showed that nonhydrolisable acetylcholine analog carbachol (CCh) depresses spontaneous quantal mediator release via muscarinic M2 receptors of nerve ending. Adenosine (Ade) acting via inhibitory A1 receptors is another strong spontaneous quantal release modulator. Inhibition of pertussis toxin (PTx)-sensitive G-proteins only partly eliminated CCh and Ade depressive action. It means metabotropic A1 and M2 receptors of the frog nerve ending regulate spontaneous quantal release via activating of both PTx-sensitive and PTx-insensitive inhibitory mechanisms.     

Trapping of an open-channel blocker at the frog neuromuscular acetylcholine channel.

At the ganglionic nicotinic acetylcholine channel (Gurney, A. M., and H. P. Rang, 1984, Br. J. Pharmacol., 82:623-642) and on some cholinergic neuromuscular synapses of Crustacea (Lingle, C., 1983a, J. Physiol. (Lond.), 339:395-417; Lingle, C., 1983b, J. Physiol. (Lond.), 339:419-437), some agents that block cholinergic currents by an open-channel block mechanism appear to become trapped within the channel when it subsequently closes. It is unknown whether trapping of some open-channel blockers might also occur at the neuromuscular nicotinic acetylcholine channel. Here we show that the long-lived cholinergic blocking action of chlorisondamine, a ganglionic nicotinic blocker, can in part be most simply explained by an open-channel block mechanism followed by a subsequent trapping of the blocking molecule within the closed ion channel. Unique structural characteristics of the chlorisondamine molecule place several provocative constraints on the mechanism by which trapping may be occurring.     

Desensitization and recovery at the frog neuromuscular junction

The time course of carbachol-induced desensitization onset and recovery of sensitivity after desenitization have been compared at the frog neuromuscular junction. The activation-desensitization sequence was determined from input conductance measurements using potassium-depolarized muscle preparations. Both desensitization onset and recovery from desensitization could be adequately described by single time constant expressions, with tauonset being considerably shorter than taurecovery. In nine experiments, tauonset was 13+/-1.3 s and taurecovery was 424+/-51 s with 1 mM carbachol. Elevating the external calcium or carbachol concentration accelerated desensitization onset without changing the recovery of sensitivity after equilibrium desensitization. Desensitization onset was accelerated by a prior activation-desensitization sequence to an extent determined by the recovery interval that followed the initial carbachol application. The time course of return of tauonset was closely parallel to, but slower than the time course of recovery of sensitivity. These results are consistent with a cyclic model in which intracellular calcium is a factor controlling the rate of development of desensitization.     

Interaction of glutamate- and adenosine-induced decrease of acetylcholine quantal release at frog neuromuscular junction

In a frog neuromuscular preparation of m. sartorius, glutamate had a reversible dose-dependent inhibitory effect on both spontaneous miniature endplate potentials (MEPP) and nerve stimulation-evoked endplate potentials (EPP). The effect of glutamate on MEPP and EPP is caused by the activation of metabotropic glutamate receptors, as it was eliminated by MCPG, an inhibitor of group I metabotropic glutamate receptors. The depression of evoked EPP, but not MEPP frequency was removed by inhibiting the NO production in the muscle by L-NAME and by ODQ that inhibits the soluble NO-sensitive guanylyl cyclase. The glutamate-induced depression of the frequency of spontaneous MEPP is apparently not caused by the stimulation of the NO cascade. The particular glutamate-stimulated NO cascade affecting the evoked EPP can be down-regulated also by adenosine receptors, as the glutamate and adenosine actions are not additive and application of adenosine partially prevents the further decrease of quantal content by glutamate. On the other hand, there is no obvious interaction between the glutamate-mediated inhibition of EPP and inhibitory pathways triggered by carbacholine and ATP. The effect of glutamate on the evoked EPP release might be due to NO-mediated modulation (phosphorylation) of the voltage-dependent Ca2+ channels at the presynaptic release zone that are necessary for evoked quantal release and open during EPP production.     

Synaptic vesicle pools at the frog neuromuscular junction

We have characterized the morphological and functional properties of the readily releasable pool (RRP) and the reserve pool of synaptic vesicles in frog motor nerve terminals using fluorescence microscopy, electron microscopy, and electrophysiology. At rest, about 20% of vesicles reside in the RRP, which is depleted in about 10 s by high-frequency nerve stimulation (30 Hz); the RRP refills in about 1 min, and surprisingly, refilling occurs almost entirely by recycling, not mobilization from the reserve pool. The reserve pool is depleted during 30 Hz stimulation with a time constant of about 40 s, and it refills slowly (half-time about 8 min) as nascent vesicles bud from randomly distributed cisternae and surface membrane infoldings and enter vesicle clusters spaced at regular intervals along the terminal. Transmitter output during low-frequency stimulation (2-5 Hz) is maintained entirely by RRP recycling; few if any vesicles are mobilized from the reserve pool.     

Asynchronous effect produced by neurotransmitter release at the frog neuromuscular junction

Hump-shaped distortion of motor nerve response, resembling spontaneous or single quanta in amplitude and time course were, observed at a temperature of 20°C, produced by stimulating this nerve during experiments on preparations of frog sartorius and cutaneous pectoral muscle involving focal extracellular recording. Having performed statistical analysis, the possibility could be excluded of this effect representing superposition of spontaneous over-evoked signals and the hypothesis could be put forward that it results from relatively unsynchronized release of separate quanta which go to make up a multiquantal response. This hypothesis would appear to be confirmed by clear-cut correlation between the distribution of synaptic delays in unitary response (when quantal content is low) and those observed in asynchronous response (when quantal content is high). Polymodal type distribution of synaptic delay is shown to be common to both cases. It is deduced that both asynchronous response and the discrete nature of variations in synaptic delay are standard features in the mechanisms of transmitter release.I. M. Sechenov Institute of Evolutionary Physiology and Biochemistry, Academy of Sciences of the USSR, Leningrad. Translated from Neirofiziologiya, Vol. 18, No. 3, pp. 346–354, May–June, 1986.     

The voltage-dependent sodium channel is co-localized with the acetylcholine receptor at the vertebrate neuromuscular junction

Isolated motor endplates from mouse intercostal muscles can be obtained after subcellular fractionation. On these motor endplates, localization of the nicotinic receptor and of the voltage-dependent Na+ channel coincides as demonstrated by double labeling with rhodamine alpha-bungarotoxin and a specific anti-Na+ channel monoclonal antibody. High density of Na+ channel at the motor endplate is confirmed by the enrichment in TTX binding sites as compared to the crude homogenate. In contrast isolated motor endplates are almost completely devoid of Ca2+ channel antagonist binding sites.     

The possible role of fixed membrane surface charges in acetylcholine release at the frog neuromuscular junction

Summary Bass and Moore [Proc. Nat. Acad. Sci. 55:1214 (1966)] proposed that the vesicles containing acetylcholine undergo Brownian motion in the nerve terminals. Acetylcholine is released whenever a vesicle touches the inner face of the axolemma of the nerve terminal. The frequency at which contact is made is limited by an energy barrier that must be overcome before the vesicle can touch the axolemma. The energy barrier has two components. (1) An electrostatic repulsion between positive, fixed charges on the vesicles and a relatively positive potential at the face of the axolemma that is generated by the resting potential. (2) A layer of water molecules held to the vesicle by the surface charge. This model is inconsistent with experimental data. A modification of the model is presented. Both the vesicle and the inner face of the axolemma are assumed to have fixed, negative surface charges that are responsible for the energy barrier. By a series of simplifications, the model leads to two predictions. (1) A plot of the ln (miniature end plate potentials/sec) as a function of the concentration of ions in the axoplasm)^–0.5 should give a straight line. (2) A plot of ln (end plate potential amplitudes) as a function of (extracellular Ca⁺⁺ concentration)^–0.5 should give a straight line. These predictions are shown to agree reasonably well with experimental data.     

The action of ionophores at the frog neuromuscular junction

The ionophores A23187 and X537A have markedly different actions on the MEPP frequency recorded at the frog neuromuscular junction. A23187 has no significant effect at 9–17°C, but causes a small increase in MEPP frequency at 6°C. At 25°C, on the other hand, A23187 causes a marked and progressive rise in MEPP rate. It is suggested that, in spite of increased Ca²⁺ influx associated with application of the ionophore, the presynaptic terminals can maintain [Ca²⁺]_i constant at 9–17°C, although [Ca²⁺]_i rises at higher and lower temperatures, causing an increase in frequency of MEPPs. As previously reported by Kita and Van der Kloot (5) X537A causes a dramatic increase in MEPP frequency, but it is suggested that its action is more complex and probably involves an increase in Na⁺ permeability.     

Reexamination of carbodiimide as a possible affinity label for the acetylcholine receptor at the frog neuromuscular junction

Summary The effects of a water-soluble carbodiimide were examined at the frog neuromuscular junction. Acetylcholine sensitivity was measured using a fluid electrode technique and intracellular recording of miniature end-plate potentials. The carbodiimide blocked synaptic sensitivity by a reversible, curare-like action. Irreversible blockade was also observed, probably due to covalent binding. The conditions of reaction and irreversibility suggest that several different residues may be attacked. The inability of cholinergic antagonists to protect the receptor from attack indicates that nonspecific sites, and not the acetylcholine binding site, are involved.     

Regeneration of the active zone at the frog neuromuscular junction

The active zone is a unique specialization of the presynaptic membrane and is believed to be the site of transmitter release. The formation of the active zone and the relationship of this process to transmitter release were studied at reinnervated neuromuscular junctions in the frog. At different times after a nerve crush, the cutaneous pectoris muscles were examined with intracellular recording recording and freeze-fracture electron microscopy. The P face of a normal active zone typically consists of two double rows of particles lined up in a continuous segment located opposite a junctional fold. In the initial stage of reinnervation, clusters of large intramembrane particles surrounding membrane elevations appeared on the P face of nerve terminals. Like normal active zones, these clusters were aligned with junctional folds. Vesicle openings, which indicate transmitter release, were seen at these primitive active zones, even though intramembrane particles were not yet organized into the normal pattern of two double rows. The length of active zones at this stage was only approximately 15% of normal. During the secondary stage, every junction was reinnervated and most active zones had begun to organize into the normal pattern with normal orientation. Unlike normal, there were often two or more discontinuous short segments of active zone aligned with the same junctional fold. The total length of active zone per junctional fold increased to one-third of normal, mainly because of the greater number of segments. In the third stage, the number of active zone segments per junctional fold showed almost no change when compared with the secondary stage. However, individual segments elongated and increased the total length of all active zone segments per junctional fold to about two-thirds of the normal length. The dynamic process culminated in the final stage, during which elongating active zones appeared to join together and the number of active zone segments per junctional fold decreased to normal. Thus, in most regions, regeneration of the active zones was complete. These results suggest that the normal organization of two double rows is not necessary for the active zone to be functional. Furthermore, localization of regenerating active zones is related to junctional folds and/or their associated structures.     

Endocytosis of synaptic vesicle membrane at the frog neuromuscular junction

Frog nerve-muscle preparations were quick-frozen at various times after a single electrical stimulus in the presence of 4-aminopyridine (4-AP), after which motor nerve terminals were visualized by freeze-fracture. Previous studies have shown that such stimulation causes prompt discharge of 3,000-6,000 synaptic vesicles from each nerve terminal and, as a result, adds a large amount of synaptic vesicle membrane to its plasmalemma. In the current experiments, we sought to visualize the endocytic retrieval of this vesicle membrane back into the terminal, during the interval between 1 s and 2 min after stimulation. Two distinct types of endocytosis were observed. The first appeared to be rapid and nonselective. Within the first few seconds after stimulation, relatively large vacuoles (approximately 0.1 micron) pinched off from the plasma membrane, both near to and far away from the active zones. Previous thin-section studies have shown that such vacuoles are not coated with clathrin at any stage during their formation. The second endocytic process was slower and appeared to be selective, because it internalized large intramembrane particles. This process was manifest first by the formation of relatively small (approximately 0.05 micron) indentations in the plasma membrane, which occurred everywhere except at the active zones. These indentations first appeared at 1 s, reached a peak abundance of 5.5/micron2 by 30 s after the stimulus, and disappeared almost completely by 90 s. Previous thin-section studies indicate that these indentations correspond to clathrin-coated pits. Their total abundance is comparable with the number of vesicles that were discharged initially. These endocytic structures could be classified into four intermediate forms, whose relative abundance over time suggests that, at this type of nerve terminal, endocytosis of coated vesicles has the following characteristics: (a) the single endocytotic event is short lived relative to the time scale of two minutes; (b) earlier forms last longer than later forms; and (c) a single event spends a smaller portion of its lifetime in the flat configuration soon after the stimulus than it does later on.     

Structural changes after transmitter release at the frog neuromuscular junction

The sequence of structural changes that occur during synaptic vesicle exocytosis was studied by quick-freezing muscles at different intervals after stimulating their nerves, in the presence of 4-aminopyridine to increase the number of transmitter quanta released by each stimulus. Vesicle openings began to appear at the active zones of the intramuscular nerves within 3-4 ms after a single stimulus. The concentration of these openings peaked at 5-6 ms, and then declined to zero 50-100 ms late. At the later times, vesicle openings tended to be larger. Left behind at the active zones, after the vesicle openings disappeared, were clusters of large intramembrane particles. The larger particles in these clusters were the same size as intramembrane particles in undischarged vesicles, and were slightly larger than the particles which form the rows delineating active zones. Because previous tracer work had shown that new vesicles do not pinch off from the plasma membrane at these early times, we concluded that the particle clusters originate from membranes of discharged vesicles which collapse into the plasmalemma after exocytosis. The rate of vesicle collapse appeared to be variable because different stages occurred simultaneously at most times after stimulation; this asynchrony was taken to indicate that the collapse of each exocytotic vesicle is slowed by previous nearby collapses. The ultimate fate of synaptic vesicle membrane after collapse appeared to be coalescence with the plasma membrane, as the clusters of particles gradually dispersed into surrounding areas during the first second after a stimulus. The membrane retrieval and recycling that reverse this exocytotic sequence have a slower onset, as has been described in previous reports.     

Studies on the chemical properties of the acetylcholine receptor site of the frog neuromuscular junction

Summary The effect of a water-soluble carbodiimide has been used to study the nature of the presumed anionic part of the acetylcholine (ACh) receptor at the frog neuromuscular junction. The ACh sensitivity has been measured by the moving fluid electrode method and by recording end plate potentials with microelectrodes. The carbodiimide blocked ACh sensitivity without marked effect on the membrane resistance or potential difference. The conditions of reversibility of the block and the results obtained with phospholipids suggest that a carboxyl group is important in the combination of ACh with the receptor.