Multiple actions of cadmium on transmitter release at the mouse neuromuscular junction

Resistance of delayed-rectifier K+ current to cadmium in Drosophila neurons

The delayed-rectifier potassium current (IKDR) is important in repolarizing the membrane potential and determining the level of neuronal excitability. We investigated the effect of cadmium on this potassium current. The whole-cell patch-clamp technique was used to measure IKDR from cultured Drosophila neurons derived from embryonic neuroblasts. The current was measured from neurons before and after the application of 0.1 mM cadmium to the external saline. IKDR was similar in the cadmium-containing saline (383 +/- 47 pA) and the control saline (401 +/- 60 pA). These results indicate that cadmium neurotoxicity does not specifically affect IKDR in Drosophila neurons.

Effects of ascorbic acid on lead induced alterations of synaptic transmission and contractile features in murine dorsiflexor muscle

Lead is a common environmental toxin that affects neuromuscular junction and potentially might cause muscle weakness. Antioxidants like ascorbic acid may protect against lead induced myopathy. The present study measured isometric twitch tensions (evoked either directly by muscle stimulation or indirectly by nerve stimulation) to study effects of ascorbic acid on lead induced alterations at murine dorsiflexor skeletal muscle. Resting membrane potentials (RMPs), endplate potentials (EPPs) and miniature endplate potentials (MEPPs) were also recorded. Forty animals were divided into four groups of n = 10 each. (10 control, 10 lead alone, 10 ascorbic acid alone, 10 lead treated plus ascorbic acid). Lead (1 mg/kg) i.p, was administered daily for 2 weeks before the recording day and ascorbic acid (200 mg/kg, i.p) was given daily for 3 weeks prior to the experiment day. Lead treatment reduced twitch tension significantly (from 4.3 +/- 0.5 g to 2.7 +/- 0.2 g) and delayed half time of decay compared to the control. Similarly MEPPs frequencies were reduced following lead treatment. Application of ascorbic acid prevented twitch tension reduction in lead treated mice (3.3 +/- 0.3 g) and reversed lead induced delay in half time of decay. The negative actions of lead treatment on MEPPs frequencies were also modified with ascorbic acid. It appears that ascorbic acid exerts a protective role against lead induced peripheral nerve and muscle dysfunction. This effect of ascorbic acid on lead induced neuromyopathy is probably mediated via a free radical scavenging mechanism or modification of Ca(2+) homeostasis.

Cadmium modulates diabetes-induced alterations in murine neuromuscular junction

Skeletal muscle function is compromised in diabetes mellitus and exposure to heavy metals may further complicate neuromuscular impairments. The present study investigated the effects of cadmium on diabetes induced dorsiflexor muscle dysfunction in C57 BL adult male mice. Forty mice were divided randomly into 2 groups (n=20 each). One group served as control and the other was injected once with i.p. streptozotocin (STZ) solution (60 mg/kg) to induce experimental diabetes. Each group was then divided into two sub-groups (n=10) of which one received 5 mM cadmium. Utilizing intracellular recording method, resting membrane potential (RMP) and miniature endplate potentials (MEPPs) were measured in dorsiflexor muscle obtained from urethane-anaesthetized (2 mg/g, i.p.) four weeks diabetic and matched control mice. Comparative analyses of isometric contractile characteristics of in situ dorsiflexor muscle were also conducted in both groups. In control mice, flexor muscle exposure to 5 mM cadmium for 10 min resulted in significant reduction in MEPPs frequencies and isometric twitch tensions without affecting RMP. In STZ-diabetic mice, the same exposure did not modify resting membrane potential and further decreased MEPPs frequencies and isometric twitch tensions. Current results indicated that cadmium probably via a Ca2+ antagonist and chelating activity at nerve terminals exacerbates diabetes complications.

Ultrastructural distribution of synaptophysin and synaptic vesicle recycling at the frog neuromuscular junction

Synaptic vesicle recycling after intense acetylcholine (ACh) release was studied at the frog neuromuscular junction (NMJ) using the synaptic vesicle transmembrane protein synaptophysin as immunocytochemical marker of the synaptic vesicle membrane during the process of exo-endocytosis. ACh release in cutaneous pectoris nerve-muscle preparations was stimulated by three different means: K+, Cd2+ in Ca(2+)-free medium, and electrical stimulation in the presence of 4-aminopyridine (4-AP). Cd2+ stimulation produced synaptic vesicle depletion and nerve terminal swelling. Electrical stimulation in the presence of 4-AP produced a reduction in the number of synaptic vesicles, deep axolemmal infoldings, coated pits, and coated vesicles. K+ stimulation did not produce any observable ultrastructural changes. Synaptophysin was labeled using silver-intensified immunogold in dissociated muscle fibers. Unstimulated and K(+)-stimulated preparations showed synaptophysin immunolabeling associated only with synaptic vesicles. In contrast, in Cd(2+)-stimulated preparations, synaptophysin appeared along the axolemma, mainly at the active zones, and after electrical stimulation it appeared in both axolemmal infoldings and the remaining synaptic vesicles. The results show that when synaptic vesicle recycling is inhibited by Cd2+ in Ca(2+)-free medium, or when 4-AP is present during electrical stimulation, synaptic vesicle fusion is accompanied by translocation and incorporation of synaptic vesicle membrane proteins into the axolemma. However, during the latter condition, synaptic vesicles are recycled through coated vesicles arising from the axolemmal infoldings. Conversely, during physiological-like stimulation of ACh release by K+ the synaptic vesicles are rapidly recycled at the active zones, by a double and rapid process of exo-endocytosis, without collapse into the axolemma.

Relative potencies of metal ions on transmitter release at mouse motor nerve terminals

1. The effects of a range of metal ions were systematically studied at the mouse neuromuscular junction in order to investigate the type of calcium channel present at the nerve terminal. 2. Endplate potentials and miniature endplate potentials were recorded from the phrenic nerve diaphragm muscle preparation with glass microelectrodes. 3. Endplate potential amplitudes and quantal contents were reduced by manganese (IC50 220 microM), cadmium (IC50 11 microM), cobalt (IC50 350 microM), and nickel (IC50 420 microM). Miniature endplate potentials were not affected by these ions at concentrations equal to the IC50s. Gadolinium did not reduce endplate potentials up to 100 microM. 4. Comparisons made with known channel types in neuroblastoma cell lines suggest that the calcium channels at the motor nerve terminal are different from those types studied in the cell lines, although most similarity is shown to the high-voltage activated calcium channel types.

Role of intracellular Cd2+ in catecholamine release and lethality in PC12 cells

To evaluate the role of intracellular Cd2+ in catecholamine release and lethality in rat pheochromocytoma (PC12) cells the following results were obtained: [1] the presence of Cd2+ intracellularly was demonstrated with the Cd(2+)-sensitive fluorescent dye BTC-5N, [2] Cd2+ entry through Ca(2+)-channels was either blocked with nifedipine or diltiazem or increased with Bay K8644, [3] Cd2+ entry through voltage sensitive Ca2+ channels was related to dopamine release and cell lethality, [4] a calmodulin inhibitor protected against Cd2+ toxicity, and [5] extracellular Ca2+ concentration, altered prior to Cd2+ exposure, was inversely related to dopamine release by Cd2+. The data indicate intracellular effects of Cd2+ rather than cell surface actions are primarily involved in neurotransmitter release and lethality by toxic levels of Cd2+ in adrenomedullary cells. To evaluate the role of intracellular Cd2+ in catecholamine release and lethality in rat pheochromocytoma (PC12) cells the following results were obtained: [1] the presence of Cd2+ intracellularly was demonstrated with the Cd(2+)-sensitive fluorescent dye BTC-5N, [2] Cd2+ entry through Ca(2+)-channels was either blocked with nifedipine or diltiazem or increased with Bay K8644, [3] Cd2+ entry through voltage sensitive Ca2+ channels was related to dopamine release and cell lethality, [4] a calmodulin inhibitor protected against Cd2+ toxicity, and [5] extracellular Ca2+ concentration, altered prior to Cd2+ exposure, was inversely related to dopamine release by Cd2+. The data indicate intracellular effects of Cd2+ rather than cell surface actions are primarily involved in neurotransmitter release and lethality by toxic levels of Cd2+ in adrenomedullary cells.

Direct in vivo comparison of two mechanisms releasing dopamine in the rat striatum

A push-pull cannula supplied with artificial CSF was implanted in the striatum of anaesthetized rats, and the basal extracellular DA and DOPAC was assayed in the superfusates using HPLC and electrochemical detection. Simultaneously, a carbon fibre electrode was implanted in close proximity of the cannula and the evoked DA release was detected by differential pulse amperometry during stimulation of the DA axons. Local treatments with cadmium (100 microM) blocked the evoked DA release (-90%), but substantially increased the basal extracellular DA (+125%). The effects of glutamate agonists NMDA (1 mM) and kainate (0.1 mM), known to increase basal extracellular DA were confirmed (+150% and +60% respectively). It was, however, simultaneously observed that the evoked DA release was inhibited (-80% and -50%, respectively). Amphetamine (1 microM) released DA (+150%) and produced also an increase (+100%) of the evoked DA release. These results, apparently conflicting, show that the two mechanisms releasing dopamine (firing-dependent and not) can be directly and simultaneously observed. These two releasing processes appear to be not strictly antagonist. They are also differently and independently modulated by calcium and by local influences such those conveyed by glutamate.

Cd(2+)-and K(+)-evoked ACh release induce different synaptophysin and synaptobrevin immunolabelling at the frog neuromuscular junction

Synaptophysin and synaptobrevin, two integral proteins of synaptic vesicles, have been used as immunocytochemical markers of the synaptic vesicle membrane during Cd(2+)- or K(+)-induced ACH release at the frog neuromuscular junction. ACh release was stimulated in cutaneous pectoris nerve-muscle preparations by: (1) 1 mM Cd2+ in Ca(2+)-free medium for a period of 3 h, (2) 25 or 40 mM K+ in normal Ringer's solution. Synaptophysin and synaptobrevin were immunolabelled in single fibres teased from fixed muscles using rabbit antisera raised against synaptophysin and synaptobrevin revealed with fluorescein-conjugated IgG. The postsynaptic ACh receptors were simultaneously labelled with rhodaminated alpha-bungarotoxin. Unstimulated and K(+)-stimulated preparations showed synaptophysin and synaptobrevin immunolabelling only after membrane permeabilization with 0.1% Triton X-100. In preparations stimulated with Cd2+ in Ca(2+)-free medium, the immunofluorescence was also observed in non Triton X-100 treated muscle fibres. Confocal laser scanning microscopy analysis revealed that in unstimulated and K(+)-stimulated preparations, synaptophysin and synaptobrevin immunofluorescence appears as bands regularly spaced along the permeabilized nerve terminals and that their distribution corresponds to clusters of synaptic vesicles. After Cd2+ stimulation in Ca(2+)-free medium, labelling for both proteins is irregularly distributed, being more intense at the lateral margins of swollen nerve terminals, suggesting a translocation of synaptic vesicle proteins to the axolemma. At the electron microscopic level, Cd2+ stimulation in Ca(2+)-free medium produces nerve terminal swelling and synaptic vesicle depletion. The results show that when ACh release is stimulated under an impairment of synaptic vesicle recycling, which leads to synaptic vesicle depletion, synaptophysin and synaptobrevin translocation occurs. These findings are in favour of a permanent incorporation of synaptic vesicle membrane into the axolemma. In contrast, after K+ stimulation, the immunofluorescence and the normal synaptic vesicle population observed, suggest that a double process of synaptic vesicle exo-endocytosis rapidly occurs, without incorporation of synaptic vesicle components into the axolemma.

The pharmacological effects of cadmium on skeletal neuromuscular transmission

1. Cadmium (100 microM) blocks neuromuscular transmission by blocking prejunctional voltage dependent calcium channels in a competitive manner. 2. Prolonged exposure to cadmium leads to a block of neuromuscular transmission that is not competitive. 3. Cadmium can increase the spontaneous release of acetylcholine, this release is modified by the cation composition of the bathing solution. 4. Cadmium may enter the nerve terminal via the voltage dependent calcium channels (the L-type calcium channel has been implicated) and exert some of its actions intracellularly. 5. All of the extracellular effects of cadmium can be reversed by cysteine.

Effects of calcium channel blockers on stimulation-induced changes in transmitter release at the frog neuromuscular junction

We have examined the effects of various calcium channel blockers on stimulation-induced changes in end-plate potential (EPP) amplitude at the frog neuromuscular junction. We found that the addition of small concentrations (1-10 microM) of Cd2+ to the low calcium bathing Ringer reduced both the control EPP amplitude and the increase in EPP amplitude that normally occurs during repetitive stimulation under low quantal conditions. These effects of Cd2+, which developed rapidly following its addition to the bathing solution and were equally rapidly reversed, resulted from changes in the amount of transmitter released from the nerve terminal. The major effect of Cd2+ appeared to be on the facilitation and augmentation components of increased release. Cd2+ had little or no effect on potentiation of release. The other divalent cations tested, Zn2+, Co2+, and Ni2+, also decreased both control EPP amplitude and the stimulation-induced increase in EPP amplitude, but higher concentrations (> 100 microM) of these cations were required. The order of effectiveness in reducing stimulation-induced increases in EPP amplitude was: Cd2+ >>> Co2+,Zn2+ > Ni2+. The organic calcium channel blockers verapamil (20-100 microM) and nimodipine (20-50 microM) had little effect on stimulation-induced increases in EPP amplitude. The results of this study are consistent with previous suggestions that the different components of increased release represent different mechanisms. Furthermore, if Cd2+ is acting by reducing Ca2+ entry into the nerve terminal, then these results suggest that facilitation and augmentation are dependent in some way on Ca2+ entry.

Contribution of Ca2+ inflow to quantal, phasic transmitter release from nerve terminals of frog muscle

Evoked quantal release from sections of frog endplates contained in an extracellular electrode has been investigated with Ca2+ inflow prevented by superfusing the extracellular space with a Ringer's solution containing Cd2+e or with an "intracellular", EGTA-buffered solution containing less than 0.1 microM Ca2+e. Pulse application and recording were by a perfused macro-patch-clamp electrode. The muscle outside the electrode (bath) was superfused with Ringer's solutions containing Cd2+b to block Ca2+ inflow and normal (1.8 mM) or elevated (10 mM) Ca2+b. The depolarization level of the terminal during current pulses that generated maximal Ca2+ inflow was used as unit relative depolarization. Starting from a threshold above 0.5 relative depolarization, the average release increased by a factor of about 1000 with increasing depolarization, reaching a plateau above 1.2 relative depolarization. The high level of plateau release extended to at least a relative depolarization of 4, i.e. to about +200 mV. When Ca2+ inflow was prevented in the section of the terminal within the electrode, release was depressed strongly for relative depolarizations around 1, i.e. at potentials at which Ca2+ inflow is high. However, for large depolarizations (> 1.5 relative units), the depression of release by block of Ca2+ inflow was weak or absent. The time course of release, measured in distributions of the delays of quanta after the depolarizing pulse, was unaffected by block of Ca2+ inflow. If the extra-electrode superfusion of Ca2+b of the muscle was elevated to 10 mM and Cd2+b was 0.1 mM or 0.5 mM, perfusion of the electrode with solutions below 0.1 microM Ca2+e raised the average release paradoxically. With 0.5 mM Cd2+b this paradoxical increase of release was, on average, 4-fold at 6 degrees C, and 19-fold at 16 degrees C. Quantal endplate currents recorded in less than 0.1 microM Ca2+e had slightly increased amplitudes, and decay time constants were prolonged by about 50%. The results are interpreted to support the Ca2+/voltage theory of release, which proposes that evoked, phasic release is controlled by both intracellular Ca2+ concentration and another membrane-depolarization-related factor. If the resting intracellular Ca2+ concentration is sufficiently high, large depolarizations can elicit release independent of the presence or absence of Ca2+ inflow.

Reversal by cysteine of the cadmium-induced block of skeletal neuromuscular transmission in vitro

1. Neuromuscular transmission in isolated nerve-muscle preparations was blocked by exposure to Cd2+ for less than 30 min or more than 2 h. The abilities of cysteine, Ca2+ or 3,4-diaminopyridine (3,4-DAP) to reverse the blockade induced by Cd2+ were studied. 2. On the mouse hemidiaphragm preparation, exposure to Cd2+ (10 microM) for 10 to 20 min induced a blockade which was easily reversed by increasing the extracellular Ca2+ concentration (5-10 mM) or by 3,4-DAP (100 microM). Exposure to Cd2+ (3-10 microM) for over 2 h led to a blockade which was not reversed by Ca2+ (5-15 mM) or 3,4-DAP (100 microM). Cysteine (1 mM) was able to reverse completely the blockade induced by both brief and prolonged exposures to Cd2+. 3. In chick biventer cervicis preparations, Cd2+ (100 microM) decreased the twitch height of indirectly stimulated preparations without affecting responses to exogenously applied acetylcholine, carbachol or KCl. Cysteine (1-3 mM) had no appreciable effect on twitch responses to indirect stimulation or to exogenously applied agonists but fully reversed the blockade induced by Cd2+ (100 microM). 4. In mouse triangularis sterni preparations, Cd2+ (1-30 microM) depressed the evoked quantal release of acetylcholine. Concentrations of Cd2+ which completely blocked endplate potentials (e.p.ps) were without significant effect on miniature endplate potential (m.e.p.p.) amplitude and frequency or time constant of decay. Cysteine (1-10 mM) alone had no effect on e.p.ps or m.e.p.ps, but completely reversed the blockade induced by Cd2+.6. In addition to the competitive blocking action of Cd2+ at the prejunctional Ca2+ channels, long exposure to Cd2+ leads to a blockade that is not competitive. This probably involves binding of Cd2+" at an extracellular thiol site on, or close to, voltage-operated Ca2+' channels.

Cadmium inhibits stimulus-response coupling in skate (Raja erinacea) electric organ

1. The effects of cadmium on stimulus-response coupling in the skate (Raja erinacea) electric organ were examined. 2. Cadmium decreased the evoked electrical discharge and the evoked release of 3H-ACh in a concentration-related fashion. 3. Cadmium (100 microM) also blocked voltage-dependent 45Ca uptake. 4. Both d-tubocurarine and nifedipine blocked Ca uptake and evoked potential, but not 3H-ACh release, thus most of the 45Ca uptake measured was post-synaptic through L Ca channels. 5. Nickel, cadmium, and verapamil inhibited 3H-ACh release and evoked potential, indicating a block of pre-synaptic T Ca channels.

Actions of lead on transmitter release at mouse motor nerve terminals

The actions of lead (Pb2+) on transmitter release were studied at neuromuscular junctions in mouse diaphragm in vitro. The quantal content of end-plate potentials (EPPs) was reduced by Pb2+ in a dose-related manner consistent with inhibition of Ca2+ entry into nerve terminals, with a half-maximal effect at 1.4 microM (in 0.5 mM Ca2+ and 2 mM Mg2+). Pb2+ also inhibited the increased frequency of MEPPs (fMEPP where MEPPs denotes miniature EPPs) produced by Ba2+ in the presence of raised K+, blocking the calculated Ba2+ entry half-maximally at 170 microM. However, at concentrations of 50-200 nM, Pb2+ often increased fMEPP in 20 mM K+ in the presence of Ca2+ and acted to promote the irreversible effect of lanthanum (La3+) to raise fMEPP. In nominally Ca(2+)-free solution with 20 mM K+, brief (1 min) application of Pb2+ (20-320 microM) caused rapid dose-dependent reversible rises in fMEPP. With prolonged exposure to Pb2+, fMEPP rose and then slowly declined; after removal of Pb2+, once fMEPP had fallen to low levels, fMEPP responded nearly normally to Ca2+ or ethanol, but not to Pb2+ itself. In 5 mM K+, 0 mM Ca2+ and varied [Pb2+] (where [] denotes concentration), nerve stimulation caused no EPPs, but prolonged tetanic stimulation produced increases in fMEPP graded with [Pb2+] that persisted as a "tail"; results were consistent with growth of fMEPP with the 4th power of intracellular Pb2+ and removal of intracellular Pb2+ with a time constant of about 30 s.(ABSTRACT TRUNCATED AT 250 WORDS)

Evoked phasic release in frog nerve terminals obtained after block of Ca2+ entry by Cd2+

Cutaneous pectoris muscles of frogs were isolated, mounted in a chamber and superfused with Ringer's solution. With a macro-patch-clamp electrode placed on a section of a motor nerve terminal, quantal synaptic currents were elicited by depolarizing pulses and recorded. The electrode tip and the section of the terminal recorded from were perfused rapidly by Ringer's solution alone or containing 20-500 microM Cd2+ to block Ca2+ inflow. Separate superfusion of the muscle and the rest of the terminal with normal or elevated Ca2+ Ringer's solution provided a sufficiently high resting Ca2+ concentration in the terminal even when Ca2+ was blocked by Cd2+. The depolarization level of maximal Ca2+ inflow into the terminal was found by measuring maximal test pulse facilitation, Fc. In control solution as well as in the case of Cd2+ block, the rate of phasic release after depolarizing pulses rose further when depolarization was increased past the level of Fc, and reached a saturation level which was maintained at estimated depolarizations up to +200 mV. Block of Ca2+ inflow by Cd2+ decreased release substantially, but did not suppress it. The depression of release was greater in the range of large Ca2+ inflow (around Fc) than for very large depolarizations. The time course of phasic release was unaltered by blockage of Ca2+ inflow. It is concluded that Ca2+ inflow contributes to the promotion of evoked release only in the depolarization range in which Ca2+ inward current is large.(ABSTRACT TRUNCATED AT 250 WORDS)

PGF2 alpha synthesis in isolated cerebellar glomeruli: effects of membrane depolarization, calcium availability and phospholipase activity

The controlling factors for PGF2 alpha production were assessed in isolated cerebellar glomeruli, since this prostaglandin has been shown to stimulate the release of neurotransmitters from the mossy fiber terminals associated with this synaptic preparation. The metabolism of PGE2 was also examined, in order to determine the specificity of any treatment effects. It was observed that K(+)-dependent membrane depolarization or the activation of voltage-sensitive Na+ channels with veratradine stimulated the production of PGF2 alpha. The syntheses of both prostanoids were dependent on available calcium and were blocked by cyclooxygenase inhibitors. The lipoxygenase inhibitor NDGA also reduced the accumulation of PGE2 and PGF2 alpha. In addition, PGF2 alpha synthesis was stimulated by the phospholipase A2 activator melittin and was reduced due to phospholipase inhibition with dibucaine. These results are consistent with a role for PGF2 alpha in the evoked release of neurotransmitter from cerebellar mossy fiber terminals.

Involvement of dihydropyridine-sensitive calcium channels in nerve growth factor-dependent neurite outgrowth by sympathetic neurons

We have used a number of pharmacological manipulations of calcium influx to alter the nerve growth factor (NGF)-elicited neurite outgrowth response of SCG neurons. Our results indicate that influx of extracellular calcium is critical to sympathetic SCG neurite outgrowth. Effective blockade of this process was produced by the inorganic calcium channel blockers Cd2+ (with an IC50 of 48 microM), Co2+ (129 microM), and Ni2+ (180 microM). More specifically, there is a significant contribution from dihydropyridine-sensitive L-type calcium channels to NGF-activated neurite outgrowth, as evidenced by the significant inhibition of neurite outgrowth by diltiazem (IC50 of 17 microM) and nifedipine (3 microM). Further, increases in calcium influx can elicit an enhanced neurite outgrowth response, as shown by the calcium channel agonist Bay K 8644 which potentiated neurite outgrowth by up to 40%.

Calcium-dependent phospholipid catabolism and arachidonic acid mobilization in cerebral minces

Cerebral minces were used to investigate the role of calcium influx on trauma-induced alterations of brain lipid metabolism. Cerebral phospholipids, nonpolar lipids, and free fatty acids were radiolabeled in vivo with [3H]arachidonic acid. Tissue incubation stimulated the time-dependent catabolism of choline and inositol glycerophospholipids, and resulted in the accumulation of [3H]free fatty acids. These effects were attenuated in Ca2(+)-free incubations, and when EGTA or verapamil were present. The inhibition of calcium influx also reduced the labeling of diglycerides, whereas ethanolamine and serine glycerophospholipids were not affected by incubation or treatments. Replacing Ca2+ with other cations also attenuated the incubation-dependent alterations in lipid metabolism. However, only cadmium was able to compete with calcium and reduce the accumulation of [3H]free fatty acids. It appeared that about half of the observed phospholipid catabolism was dependent on Ca2+ influx and that at least 80% of the [3H]free fatty acid accumulation required calcium.

Ciguatoxin enhances quantal transmitter release from frog motor nerve terminals

1. Ciguatoxin (CTX), a marine toxin produced by the benthic dinoflagellate Gambierdiscus toxicus, is responsible for a complex endemic disease in man known as ciguatera fish poisoning. In the present study we have investigated the effects of purified CTX extracted for Gymnothorax javanicus moray-eel liver on frog isolated neuromuscular preparations with conventional electrophysiological techniques. 2. CTX (1-2.5 nM) applied to cutaneous pectoris nerve-muscle preparations induced, after a short delay, spontaneous fibrillations of the muscle fibres that could be suppressed with 1 microM tetrodotoxin (TTX) or by formamide to uncouple excitation-contraction. 3. In preparations treated with formamide, CTX (1-2.5 nM) caused either spontaneous or repetitive muscle action potentials (up to frequencies of 60-100 Hz) in response to a single nerve stimulus. Recordings performed at extrajunctional regions of the muscle membrane revealed that during the repetitive firing a prolongation of the repolarizing phase of the action potential occurred. At junctional sites the repetitive action potentials were triggered by repetitive endplate potentials (e.p.ps). 4. CTX (2.5 nM) caused a TTX-sensitive depolarization of the muscle membrane. 5. In junctions equilibrated in solutions containing high Mg2+ + low Ca2+, addition of CTX (1.5 nM) first induced an average increase of 239 +/- 36% in the mean quantal content of e.p.ps. Subsequently CTX reduced and finally blocked nerve-evoked transmitter release irreversibly. 6. CTX (1.5-2.5 nM) increased the frequency of miniature endplate potentials (m.e.p.ps) in junctions bathed either in normal Ringer, low Ca2(+)-high Mg2+ medium or in a nominally Ca2(+)-free solution containing EGTA.2+ Extensive washing with toxin-free solutions did not reverse the effect. Furthermore, Cd2 + (0.1 mM), a potent calcium channel blocker, neither antagonized nor abolished the increase in transmitter release caused by CTX. 7. TTX (1 microM) completely prevented the effect of CTX (2.5nM) on m.e.p.p. frequency. This effect was independent of the presence of extracellular Ca2 +. TTX, when added after CTX (2.5 nM) exposure, antagonized the increase in m.e.p.p. frequency. The antagonism was complete in Ca2 +-free medium. These results strongly suggest that increased permeability of the nerve terminal to Na+ is responsible for the increase in m.e.p.p. frequency caused by CTX. It is likely that CTX may trigger calcium release from internal stores due to an increase of intraterminal Na+ concentration. 8. It is concluded that CTX exerts, in the nanomolar concentration range, a selective action on sodium channels of the neuromuscular junction causing both pre- and postsynaptic effects.

Inhibition of Ca2+ inflow at nerve terminals of frog muscle blocks facilitation while phasic transmitter release is still considerable

Action potentials were triggered in the motor nerve by a suction electrode and calcium currents (iCa) in the nerve terminals were measured by means of a perfused macro-patch-clamp electrode on the distal portion of the end-plates. Postsynaptic currents were blocked by adding d-tubocurarine, whereas presynaptic Na+ (iNa) and K+ (iK) currents were blocked by adding tetrodotoxin (TTX), tetraethylammonium and 3,4-diaminopyridine, respectively, to the perfusate of the electrode. The current components which could be suppressed by addition of Cd2+ to the perfusate were taken as presynaptic iCa. The observed effects on the presynaptic current components were very similar to those reported previously. If the electrode was perfused with Ringer's solution containing the blockers for iNa and iK, the same, obviously complete block of iCa was obtained by 50 and 100 microM Cd2+, an average of 96% block by 20 microM Cd2+ and 50% block by about 5 microM Cd2+. Using the same type of electrode and similar locations on motor nerve terminals, postsynaptic quantal currents and twin-pulse facilitation (Fd) were elicited by variable-duration (0.5-3 ms) depolarizing pulses. When the electrode was perfused with Ringer's solution containing TTX, 20 microM Cd2+ added to the perfusate reduced the rate of phasic release of quanta insignificantly for short depolarizing pulses and by a factor of about 10 for longer pulses. Fd was blocked almost completely. Addition of 50 microM Cd2+ to the perfusate had a greater depressive effect on release after short depolarizing pulses and reduced release after longer pulses by a factor of about 100.(ABSTRACT TRUNCATED AT 250 WORDS)

Multiple actions of zinc on transmitter release at mouse end-plates

In mouse diaphragm, the increase in frequency of mini end-plate potentials (fmepp), by Ca2+ or Ba2+ in 20 mM K+, was reversibly inhibited by Zn2+ in a manner consistent with competition between Zn2+ and Ca2+ at a site which interacts with only one atom of Zn with an apparent dissociation constant (Ki) of about 0.015 mM. Between 0.5 mM and 2 mM, Zn2+ caused a rapid and reversible dose-dependent increase in fmepp in 20 mM K+/0 Ca2+. Prolonged or repeated exposure to Zn2+ produced a slow increase in fmepp followed by a decline, which once started, was not modified by of Zn2+. The time course was prolonged in raised Mg2+, bekanamycin, or in 5 mM K+ solution, and graded with Zn2+ concentration, but total numbers of MEPPs induced by 0.1 mM, 1 mM or 4 mM Zn2+ were not significantly different. When fmeppp fell it became insensitive to Ca2+, Ba2+, La3+ (in 20 mM K+), ethanol and raised osmotic pressure. Before complete block of responses to Ca2+, the Ca2+/fmepp dose/response curve in 20 mM K+ was shifted to the right. These results indicate that Zn2+ enters the terminal via voltage-gated Ca2+ channels that interact in a complex way with these ions and then acts (a) as a partial agonist at sites where Ca2+ normally governs transmitter release, and (b) to produce irreversible changes in the nerve terminal, associated with a rise and subsequent fall of fmepp and loss of sensitivity of the release mechanism to Ca2+ and other agents.

Effects of cadmium on quantal transmitter release and ultrastructure of frog motor nerve endings

Exposure of frog cutaneous pectoris nerve-muscle preparations to cadmium (0.1-1 mM) results in an increase in miniature end-plate potential (m.e.p.p.) frequency. The increase is dependent on the concentration, the time of exposure and the co-presence of other divalent cations in the extracellular fluid. The stimulatory effect of cadmium is most marked in a calcium-free medium. Increased levels of calcium (4-10 mM) or of magnesium (10 mM) reduce the stimulatory effect suggesting that those cations interfere with the entry of cadmium into nerve endings. Once the effect of cadmium on m.e.p.p. frequency is attained, washing with a cadmium-free solution fails to abolish its effect. The action of cadmium on m.e.p.p. frequency slowly declines towards zero after about 3 hrs. An ultrastructural study of nerve terminals exposed for one hr to 1 mM cadmium reveals that neither in calcium-containing nor in a nominally calcium-free medium are there any significant changes in the number of synaptic vesicles as compared to controls. However, after 3 hrs of cadmium action in a calcium-free medium there is about 65% depletion of synaptic vesicles, while in calcium-containing media there is only about 25% depletion. The results suggest that cadmium by itself can support transmitter release but not synaptic vesicle recycling which instead might depend upon calcium.