Studies on the contracture of the mouse diaphragm induced by sodium selenite

In this study, we found that sodium selenite was potent in inducing contracture of the mouse diaphragm. The possible mechanism of action of selenite was investigated. Contracture was induced by a direct action of selenite on the muscle membrane rather than that selenite enhanced transmitter release from the motor nerve terminals, since denervation, d-tubocurarine and tetrodotoxin did not inhibit the selenite-induced contracture. Although selenite decreased both the membrane potential and the amplitude of the muscle action potential, neither high K+ nor glycerol treatment, which closed the transverse tubule, reduced the selenite-induced contracture, suggesting that depolarization of the muscle membrane was not essential for the induction of the contracture. EGTA (1-50 mM) inhibited the selenite-induced contracture in a concentration-dependent manner. In contrast, varying the external Ca2+ concentrations from 10(-3) to 10 mM or raising Mg2+ concentration to 10 mM did not affect the contracture. Similarly, the contracture induced by caffeine was not affected by lowering the external Ca2+ concentration to 10(-3) mM but was completely inhibited by 30 mM EGTA. Selenite pretreatment markedly potentiated the caffeine contracture and prolonged treatment with caffeine inhibited the selenite contracture. All of these findings suggest that the selenite contracture was not dependent on external Ca2+ but was induced by the release of Ca2+ from internal membranes such as the sarcoplasmic reticulum. Pretreatment with trypsin, glutathione or cyanide blocked the selenite-evoked contracture. Therefore, we postulate that the selenite-induced contracture was induced by the initial binding of selenite to the sulfhydryl groups of the muscle membrane, which then triggered the release of Ca2+ from internal membranes such as the sarcoplasmic reticulum.     

Effect of lignocaine on chick biventer cervicis skeletal muscle

The effect of lignocaine (0.01-100 micrograms.ml-1) on amplitude of indirectly and directly-elicited twitch contractions and on contractures produced by acetylcholine (ACh) (0.1-10 mM) and tetraethylammonium (TEA) (1.2-12 mM) was studied in isolated biventer cervicis skeletal muscle of the chick. Lignocaine (0.01-0.9 microgram.ml-1) increased the amplitude of the indirectly-elicited twitch contractions. At high concentrations (10-100 micrograms.ml-1), lignocaine decreased or blocked the twitch tension and produced a contracture in the chick skeletal muscle. Lignocaine also reduced or blocked the directly-elicited twitch contractions in a dose-dependent manner. Lignocaine (10 micrograms.ml-1) reduced the ACh-induced contracture whereas it increased that produced by TEA. Physostigmine (2 micrograms.ml-1) increased the stimulating effect of lignocaine, at low concentrations. However, repeated exposures to lignocaine followed by physostigmine resulted in both increase and decrease in the indirectly-elicited twitch contractions. It was concluded that lignocaine had a dual action at the neuromuscular junction. In low concentrations, lignocaine increases the twitch tension, possibly by an anticholinesterase action, and in high concentrations it reduces or blocks the twitch tension, produces a contracture in the muscle, and reduces the ACh-induced contractures, whereas it increases the TEA-induced responses. Some of these effects of lignocaine may be interpreted in terms of effects on excitation-contraction coupling in muscle.     

Effects of sodium selenite on neuromuscular junction of the mouse phrenic nerve-diaphragm preparation

The effects of sodium selenite on the neuromuscular junction of the phrenic nerve-diaphragm of the mouse were studied. Nerve-evoked twitches of the diaphragm of the mouse, the frequency of miniature endplate potentials, the quantal content of endplate potentials and the compound action potentials of the axon were measured. Sodium selenite induced a slight increase of the amplitude of the twitch, followed by twitch depression. The amplitude of the twitch, increased by selenite, became more prominent after the suppression of the twitch induced by cadmium ions, d-tubocurarine or magnesium ions. It appeared that the increased amplitude of twitch was due to the facilitation of transmitter release, since selenite significantly increased the frequency of miniature endplate potentials, and the amplitude and quantal content of endplate potentials; the amplitude and half decay time of miniature endplate potentials were unaffected. Twitch depression induced by selenite was enhanced by ammonium ions, high potassium and low magnesium and attenuated by high calcium. During the period of gradual depression of the twitch, selenite decreased the amplitude of compound action potentials of the phrenic nerve axon and caused the disappearance of endplate potentials. Ammonium ions enhanced the blockade of axonal conduction induced by selenite. Moreover, the depolarizing agents, ammonium and high potassium also induced an initial increase of twitch amplitude followed by depression of the twitch. These findings indicate that selenite probably alters the release of the transmitter by depolarizing the nerve membrane. The effects of selenite were antagonized by glutathione and cyanide, suggesting that the binding of selenite to sulfhydryl groups of the membrane was essential for inducing its pharmacological actions.     

Sites of action of dihydropyridine drugs in the mouse hemidiaphragm muscle

The effects of nifedipine and BAY K8644 on directly evoked isometric twitch and potassium (K+)- and caffeine-induced contractures were investigated in mouse hemidiaphragm preparations in which neuromuscular transmission had been irreversibly blocked. Both drugs caused initial potentiation of twitch which at high concentrations (greater than 3 x 10(-5) M) was followed by blockade. A simultaneous slow contracture was seen with nifedipine but not BAY K8644. Control K+ contractures were triphasic. The initial fast and slow phases of this contracture were potentiated by BAY K8644 at all times and concentrations. Both phases were potentiated by nifedipine at low concentrations but, during prolonged exposure to high concentrations, potentiation was replaced by an inhibition. The time course of activation and inactivation of the slow phase was also accelerated by all concentrations of nifedipine. The initial phase of caffeine-induced contracture was potentiated and resolved into two components. From these results at least three sites of action were postulated. Conventional binding to t-tubular Ca2+ channels was linked to effects on the slow phase of K+ contracture. An effect on Ca2+ release from the sarcoplasmic reticulum and an inhibition of Ca2+ transfer from uptake to release compartments in the sarcoplasmic reticulum are also postulated.     

Prenylamine-induced contracture of frog skeletal muscle.

1. Experiments were performed to determine the influence of prenylamine on excitation-contraction coupling in frog sartorius muscle. 2. Prenylamine (0.2-1.0 mM) produced a biphasic contracture in skeletal muscle characterized by an initial phasic and subsequent tonic contracture. 3. Neither dantrolene nor procaine blocked the prenylamine-induced contracture. Pretreatment with 100 mM K+ blocked the phasic but not the tonic component of the prenylamine contracture. 4. Prenylamine produced a sustained increase in 45Ca efflux at all concentrations that produce contracture. These concentrations of prenylamine also depressed the action potential, muscle twitch and resting potential. 5. Low concentrations of prenylamine (0.05 mM) which produced neither contracture, 45Ca efflux nor 45Ca influx, depressed the action potential, muscle twitch and K+ contracture. 6. The results suggest that prenylamine not only alters calcium mobility but also membrane permeability to other ions.     

Ca antagonistic and non-specific effects of diltiazem on the rat phrenic nerve diaphragm preparation

The calcium antagonist diltiazem (2.8 X 10(-4) M) blocked the twitches of a rat phrenic nerve diaphragm preparation after a period of twitch potentiation. Its ability to block twitches was greater during indirect than direct stimulation. Experiments on the isolated phrenic nerve indicated that the excitability of the nerve was blocked. Diltiazem (2.3-9.0 X 10(-5) M) caused a similar inhibition of indirectly and directly elicited tetanic contractions and EMG. Experiments with d-tubocurarine and lowered temperature disclosed a separate inhibition at the neuromuscular junction. High Ca2+ did not reverse the diltiazem-affected twitch or tetanic contractions, which suggests that they are non-specific effects. KCl (100 mM)-induced contractures were antagonized at low (2.3-4.5 X 10(-5) M) but not at high (1 mM) concentrations of diltiazem. Diltiazem depressed the initial phase of the two-phasic caffeine (10 mM) contracture and increased and accelerated the slow phase. Diltiazem greatly reduced the amplitude and duration of the caffeine-potentiated KCl contracture, and reduced and delayed the slow phase of the KCl-potentiated caffeine contracture. The effects on the combined contractures (caffeine-induced, KCl-potentiated) were partly antagonized by a high Ca2+ (2.2 X 10(-5) M) solution, which suggests that diltiazem has calcium antagonistic effects.     

Blocking effects of hypaconitine and aconitine on nerve action potentials in phrenic nerve-diaphragm muscles of mice

The mechanisms of neuromuscular blockade by hypaconitine and aconitine were investigated electrophysiologically in isolated phrenic nerve-diaphragm muscles of mice. Hypaconitine (0.08-2 microM) and aconitine (0.3-2 microM) depressed the nerve-evoked twitch tension, without affecting the contraction evoked by stimulation of the muscle. At the concentrations of hypaconitine (up to 5 microM) and aconitine (up to 2 microM) that depressed the nerve-evoked twitch tension, the resting membrane potential of the muscle cells was unchanged. Hypaconitine (0.1-2 microM) and aconitine (2 microM) blocked the end-plate potential (epp), without affecting the amplitude of the miniature epp (mepp). The quantal content of end-plate potentials was decreased by these agents in parallel with the decrement in amplitude. The nerve compound action potential was inhibited by hypaconitine (5 microM) and aconitine (2-10 microM), as well as by 1 microM tetrodotoxin (TTX). When the nerve compound action potential was completely blocked by 2 microM aconitine, the muscle action potential was unaffected, although 1 microM TTX suppressed both potentials to the same degree. These results indicate the neuromuscular blockade produced by hypaconitine and aconitine were caused by reducing the evoked quantal release. The mechanism of this effect was attributed mainly to blocking of the nerve compound action potential.     

A comparison between the effects of a tetanus and the effects of sympathomimetic amines on fast- and slow-contracting mammalian muscles

The effects of adrenaline and isoprenaline on the tension and time-course of the contractions of the tibialis anterior and soleus muscles of cats and rabbits have been compared with the effects of previous high-frequency stimulation. Like a tetanus, adrenaline possessed a facilitating action on neuromuscular transmission and an action exerted directly on the muscle fibres. Isoprenaline possessed only the second of these two actions. The effect of adrenaline and isoprenaline on the muscle fibres was blocked by dichloroisoprenaline and by 1-(2 naphthyl)-2-isopropylaminoethanol, whereas the effect of adrenaline on neuromuscular transmission was blocked by phentolamine and by phenoxybenzamine. In the soleus muscle, both the catechol amines and a previous tetanus caused similar decreases in maximal twitch tension and in the times to peak tension and to half-relaxation. The muscle action potentials were unaltered or slightly increased in amplitude. In the tibialis anterior muscle, a previous tetanus and the catechol amines caused an increase in twitch tension and an increase in the overall duration of the twitch. The muscle action potentials were either unchanged or were slightly decreased in amplitude. In this muscle the effect of a tetanus differed from that of the catechol amines in that the large post-tetanic change was associated with a marked increase in the rate of rise of twitch tension.     

Inhibition of neuromuscular transmission in isolated mouse phrenic nerve-diaphragm by the enterotoxin of Clostridium perfringens type A.

The enterotoxin of Clostridium perfringens type A, a channel forming protein toxin, inhibited neuromuscular transmission under conditions of low calcium. Twitch tension of isolated phrenic nerve-diaphragm preparations elicited by electrical stimulations to the phrenic nerve was recorded isometrically, and the preparations were exposed to the purified enterotoxin. In Krebs solution containing 0.5 mM calcium, the enterotoxin (20 micrograms/ml) reduced within 10 min the amplitude of the twitch tension to 34 +/- 7% (mean +/- S.D., n = 11) of that recorded before the treatment. The effects of the enterotoxin on the twitch tension were irreversible and proceeded independently of stimulation. The reduction of the twitch tension by the enterotoxin was apparent in Krebs solution containing less than 0.6 mM calcium and the degree of reduction was inversely related to the concentration of calcium. The reduction of the twitch tension by the enterotoxin was also dependent on temperature and concentration of the toxin. At temperatures below 20 degrees C, no obvious reduction of twitch tension was observed with 20 micrograms/ml of the enterotoxin. Enterotoxin at a concentration of 0.4 micrograms/ml caused 16 +/- 2% (mean +/- S.D., n = 4) reduction of twitch tension, and the degree of the reduction in twitch tension increased with toxin concentration, reaching a plateau of 65 +/- 4% (mean +/- S.D., n = 7) at 6.5 micrograms/ml of the enterotoxin. The effects of the enterotoxin were antagonized by 2 microM physostigmine. Unlike curare, pretreatment of the preparation with enterotoxin did not antagonize the neuromuscular block by decamethonium. Neither the tension of muscular twitch elicited by direct electrical stimulation to the muscle nor the resting membrane potentials of muscle fibers recorded intracellularly were affected by the enterotoxin. The enterotoxin (2.2 micrograms/ml) reduced the frequency, but not mean amplitude or amplitude distribution, of miniature end-plate potentials, from 0.91 +/- 0.07/sec to 0.72 +/- 0.07 (mean +/- S.E., n = 5). The results suggest that the enterotoxin will provide a novel tool for the studies on the mechanism of the neuromuscular transmission because of the unique characteristics of the inhibition and of the known mechanism of its action on the cell membrane.     

Modification by dantrolene, procaine and suxamethonium of caffeine-induced changes in aequorin luminescence transients and twitch tensions of directly-stimulated diaphragm muscle of mouse.

A convenient method is described for measuring simultaneously Ca2+-related aequorin luminescence and twitch tension in the isolated diaphragm muscle of the mouse. Forty to fifty fibres were injected intracellularly with aequorin solution and the mechanical and luminescence responses to direct stimulation were recorded. The replacement of Na+ by K+ (to obtain 59 or 143.4 mM K+) in the nutrient solution decreased both aequorin luminescence and twitch tensions, but after a time lag, it produced a contracture. Caffeine (5 or 10 mM) increased both aequorin luminescence and twitch tensions, and after a time lag, it also produced a contracture. Dantrolene (1 and 30 microM) and procaine (10 microM, 300 microM and 1 mM) decreased aequorin luminescence transients and twitch tension. In addition procaine inhibited the caffeine-induced increase of aequorin luminescence, but dantrolene did not have this effect. At concentrations causing neuromuscular block, suxamethonium (130 microM) decreased aequorin luminescence transients and twitch tension. By contrast, (+)-tubocurarine (6.5 microM) did not affect the aequorin luminescence in directly stimulated muscles. These results suggest that Ca+-related aequorin luminescence transients accompanied by twitch tensions reflect the intracellular fast mobilization of compartmentalized Ca2+ from plasma membrane or sarcoplasmic reticulum, and that the increase in resting luminescence caused by a K+- or caffeine-induced contracture may be produced by the slow mobilization of Ca2+ from sarcoplasmic reticulum.     

Blockade of acetylcholine release at the motor endplate by a polypeptide from the venom of Phoneutria nigriventer.

1. The mechanisms underlying the muscle relaxation effect of a fraction (PF3) isolated from the Phoneutria nigriventer spider venom were assessed on mouse diaphragm and chick biventer cervicis muscle preparations. 2. PF3 (0.25-4 micrograms ml-1) produced a concentration-dependent blockade of the nerve-elicited muscle twitch of the mouse diaphragm (IC50 = 0.8 micrograms ml-1) without affecting the directly induced muscle twitch. In similar preparations, the crude venom (1-10 micrograms ml-1) produced muscle contracture and blocked both the direct and indirectly induced muscle twitches. 3. In the chick biventer cervicis muscle, PF3 (1-5 micrograms ml-1) blocked the nerve stimulated muscle twitch (IC50 = 1.26 micrograms ml-1), but did not alter the postjunctional response to exogenous acetylcholine (ACh, 10 microM-10 mM). 4. PF3 (2-8 micrograms ml-1) reduced the frequency of miniature endplate potentials (m.e.p.ps) recorded intracellularly from the mouse diaphragm muscle fibers by 58 to 64%, and diminished the amplitude of m.e.p.ps by 20 to 40% of control. The relationship between log m.e.p.p. frequency and log [Ca2+]o was shifted rightwards in the presence of 4 micrograms ml-1 PF3. 5. Raising the frequency of m.e.p.ps with high K+ medium or theophylline (3 mM) did not prevent the toxin-induced depression of spontaneous ACh release. 6. The quantal content of e.p.ps (m), determined in cut-diaphragm muscle fibres, was reduced by 53% and 77% of control by 1 and 4 micrograms ml-1 PF3, respectively. At 1 microgram ml-1 the toxin shifted the relationship between log m and log [Ca2+]o towards higher values without apparent change of the slope. 7. E.p.p. trains elicited at 10 to 50 Hz in the presence of PF3 (1 microgram ml-1) exhibited irregular amplitudes and facilitation related to the frequency of nerve stimulation. 8. It is concluded that PF3 blocks neuromuscular transmission by acting prejunctionally and reducing the nerve-evoked transmitter release. The effect was related to a diminished Ca2+ entry into the nerve terminal associated with inhibition of exocytosis.     

Effects induced by bothropstoxin, a component from Bothrops jararacussu snake venom, on mouse and chick muscle preparations.

Bothropstoxin, a 13,700 mol. wt myotoxic phospholipase homologue isolated from the venom of Bothrops jararacussu and devoid of PLA2, proteolytic or hemolytic activities, inhibited muscle twitch tension, evoked either directly or indirectly through stimulation of the motor nerve in the mouse phrenic-diaphragm preparations. The compound action potential of the muscle was also abolished with a similar time course. In addition, the toxin (0.7 mM) evoked membrane depolarization which was inhibited in the presence of 10 mM Ca2+. In chick biventer cervicis muscle, the toxin (2 mM) induced a contracture that reached its maximum amplitude in 44.8 +/- 15.6 min (n = 6) and was not blocked by either d-tubocurarine or tetrodotoxin. The time to maximum amplitude was reduced to 5.5 +/- 1.0 min (n = 4) in nominally Ca(2+)-free Krebs solution and was completely abolished in Ca(2+)-free Krebs solution containing 1 mM EGTA.     

Depolarizing neuromuscular blocking action induced by electropharmacological coupling in the combined effect of paeoniflorin and glycyrrhizin

Twitch tensions of indirectly stimulated diaphragm muscles of mice were blocked by a combination of paeoniflorin (PF) and glycyrrhizin (GLR). The mechanism of this effect was studied electropharmacologically. When twitch responses were completely prevented, miniature end-plate, end-plate, and muscle action potentials were still observed when PF and GLR were combined, suggesting that the mechanism is postsynaptic. Potential amplitudes induced by acetylcholine (ACh), which was injected iontophoretically, were inhibited by about 70% by PF (25 micrograms/ml) plus GLR (75 micrograms/ml), although neither agent alone caused an inhibition. The combined ratio (PF:GLR = 1:3) by concentrations (g/ml) potentiated both the inhibition of ACh potential amplitudes and the depolarization of resting membrane potentials. These results indicate that the effect of combined PF and GLR is to depolarize the muscle membrane and to block ACh-receptor-linked processes. In chemically skinned (saponin-treated) muscles, the tension induced by 0.39 microM of free calcium was inhibited by PF (300 micrograms/ml), but it tended to be increased by GLR (300 micrograms/ml). Caffeine-induced contractures in the skinned muscles was not influenced by PF, and they tended to be decreased with GLR treatment. Thus, in muscles with sustained depolarization, these combined compounds seem to block intracellular Ca2+ movement.     

The marine polyether gambierol enhances muscle contraction and blocks a transient K current in skeletal muscle cells

Gambierol is a complex marine toxin first isolated with ciguatoxins from cell cultures of the toxic dinoflagellate Gambierdiscus toxicus. Despite the chemical complexity of the polycyclic ether toxin, the total successful synthesis of gambierol has been achieved by different chemical strategies. In the present work the effects of synthetic gambierol on mouse and frog skeletal neuromuscular preparations and Xenopus skeletal myocytes have been studied. Gambierol (0.1-5 μM) significantly increased isometric twitch tension in neuromuscular preparations stimulated through the motor nerve. Less twitch augmentation was observed in directly stimulated muscles when comparing twitch tension-time integrals obtained by nerve stimulation. Also, gambierol induced small spontaneous muscle contraction originating from presynaptic activity that was completely inhibited by d-tubocurarine. Gambierol slowed the rate of muscle action potential repolarization, triggered spontaneous and/or repetitive action potentials, and neither affected action potential amplitude nor overshoot in skeletal muscle fibers. These results suggest that gambierol through an action on voltage-gated K⁺ channels prolongs the duration of action potentials, enhances the extent and time course of Ca²⁺ release from the sarcoplasmic reticulum, and increases twitch tension generation. Further evidence is provided that gambierol at sub-micromolar concentrations blocks a fast inactivating outward K⁺ current that is responsible for action potential prolongation in Xenopus skeletal myocytes.     

Transmitter-mediated local contracture of the endplate region of the focally innervated mouse diaphragm treated with anticholinesterase.

1. Local contraction of the endplate region in response to nerve stimulation was studied in isolated mouse diaphragms. In normal preparations, muscle contractions involved the whole length of the muscle fibre with rise and decay times in the order of tens of ms whether evoked with a single or train of pulses. 2. When acetylcholinesterase was inhibited with neostigmine, tetanic stimulation produced a twitch-like phasic contraction and a delayed tonic contracture. A brief train of pulse (10 ms, 300 Hz) was enough to trigger a full size tonic contracture which reached an amplitude about one tenth that of control tetanus and had a duration of about 4 s. 3. Tetanic stimulation evoked a non-propagating prolonged depolarization at the endplate region lasting for about 1 s following a few muscle action potentials. 4. mu-Conotoxin, a specific inhibitor of muscle Na+ channel, selectively abolished the phasic contraction and the muscle action potentials leaving the tonic contracture and the prolonged depolarization unaffected. 5. Both the tonic contracture and the prolonged depolarization were highly sensitive to blockade by tubocurarine (IC50 0.05-0.1 microM) and vesamicol (1 microM, an inhibitor of packaging acetylcholine into synaptic vesicles), were attenuated by increasing Ca2+ concentration and were prolonged by decreasing Ca2+. 6. The results suggest that prolonged activation of endplate nicotinic receptors by endogenously released transmitter can produce substantial contractions of the endplate region when acetylcholinesterase are inhibited. The source of Ca2+ for the contraction seems to come mainly from intracellular stores.     

Enhancement by calcitonin gene-related peptide of nicotinic receptor-operated noncontractile Ca2+ mobilization at the mouse neuromuscular junction.

1. The involvement of calcitonin gene-related peptide (CGRP) in the mechanism of nicotinic acetylcholine receptor-operated noncontractile Ca2+ mobilization (not accompanied by twitch tension) was investigated by measuring Ca(2+)-aequorin luminescence at the neuromuscular junction of mouse diaphragm muscle treated with neostigmine. 2. Noncontractile Ca2+ transients were enhanced by 4-aminopyridine (100 microM), a K+ channel blocker, and inhibited by botulinum toxin (1-100 micrograms, i.p.) and hexamethonium (10-100 microM), a neuronal nicotinic receptor antagonist. 3. Noncontractile Ca2+ transients were diminished by CGRP8-37 (10-20 microM), a CGRP antagonist. CGRP (0.3-10 nM) prolonged the duration of noncontractile Ca2+ transients. The effect of CGRP was suppressed by CGRP8-37 (0.1 microM). 4. Noncontractile Ca2+ transients were inhibited by H-89 (0.1-1 microM), a protein kinase-A inhibitor. The catalytic subunit of protein kinase-A and AA373 (300 microM), a protein kinase-A activator, prolonged the duration of noncontractile transients. The prolongations either by CGRP or by AA373 were not observed in the presence of H-89 (0.1 microM). 5. Contractile (accompanied by twitch tension) but not noncontractile Ca2+ transients were decreased by 12-O-tetradecanoyl phorbol 13-acetate (TPA, 0.3-1 microM), a protein kinase-C activator. Phospholipase A2 increased only contractile Ca2+ transients. Calmodulin-related agents affected neither type of Ca2+ transients. 6. These results provide the first evidence that nicotinic acetylcholine receptor-operated noncontractile Ca2+ mobilization is promoted by nerve-released CGRP activating protein kinase-A, and is dependent on the accumulated amounts of acetylcholine at the neuromuscular junction where desensitization might readily develop.     

Mode of stimulatory actions of cadmium ion on the mouse diaphragm.

Effects of Cd2+ on the phrenic nerve-diaphragm preparation of the mouse varied markedly in media containing various Ca2+ concentrations. In normal 2.5 mM Ca2+ medium, Cd2+ inhibited acetylcholine release from nerve endings without appreciable effect on the muscle membrane. However, Cd2+ elicited stimulatory effects on the muscle membrane in low Ca2+ medium (10(-3)-1 mM). These stimulatory effects included the induction of spontaneous contractions, augmentation of twitch responses to direct electrical stimulation and potentiation of the muscle contracture induced by acetylcholine, carbachol and high K+. By contrast, caffeine contracture was not affected by Cd2+. Tetrodotoxin, procaine, cysteine and glycerol pretreatment abolished these stimulatory effects of Cd2+. Moreover, changing the ionic composition of the bathing medium to one containing low Na+, high K+, high Mg2+ or high Ca2+ also antagonized these effects of Cd2+. In contrast, low Mg2+ markedly potentiated the frequency of spontaneous contractions induced by Cd2+. (+)-Tubocurarine and beta-bungarotoxin had no effect on Cd2+-induced spontaneous contractions indicating that they may be myogenic rather than neurogenic in origin. By use of conventional microelectrodes, it was found that Cd2+ not only depolarized the muscle membrane but also induced spontaneous action potentials at a high frequency (173 +/- 17 Hz). It is concluded that increased Na+ permeability of the muscle membrane is the essential step bringing about spontaneous contractions. The binding of Cd2+ to -SH groups of the membrane is closely related to the induction of these effects.     

Inhibition of neuromuscular transmission in the myenteric plexus of guinea-pig ileum by omega-conotoxins GVIA, MVIIA, MVIIC and SVIB.

1. The effects of a number of Ca2+ channel blockers on the transmural electrical stimulation or receptor agonist-elicited contractile responses of guinea-pig ileum were compared. 2. omega-Conotoxins (MVIIA, GVIA, SVIB and MVIIC), but not omega-agatoxin IVA, completely blocked the twitch responses evoked by low frequency (0.1 Hz) transmural stimulation without inhibition of the contractures evoked by exogenous acetylcholine. The concentration-inhibition curves were shifted by changes of external Ca2+. 3. The tetanic contractures produced by a high frequency (30 Hz) train of stimulation were inhibited by omega-conotoxins by only 25-30%, except for omega-conotoxin MVIIC, which produced about 55% inhibition, all significantly less than that produced by atropine (about 70%) or tetrodotoxin (about 85%). Combinations of omega-conotoxins did not produce additive inhibitory effects. 4. The four omega-conotoxins as well as atropine produced similar partial inhibition (53-62%) of the contractures evoked by dimethylphenylpiperazinium, while tetrodotoxin inhibited the contracture completely. 5. Nifedipine and Ni2+ depressed the nerve stimulation-evoked twitch response and tetanic contracture as well as acetylcholine contracture. 6. These observations suggest that, in the myenteric plexus, a subset of N-type Ca2+ channel dominates under low frequency stimulation, while high frequency stimulation may recruit additional channels and non-cholinergic pathways.     

Changes in intracellular Ca2+ produced in the mouse diaphragm by neuromuscular blocking drugs

Differences between the effects of depolarizing and competitive neuromuscular blocking drugs on Ca2(+)-aequorin luminescences (Ca2+ transients) emitted during twitches were compared in indirectly-stimulated diaphragm muscles of mice. Succinylcholine enhanced intracellular Ca2+ transients at concentrations of 1.3-2.5 microM and inhibited them at concentrations of 5.0-50 microM, demonstrating a biphasic response as in the case of twitch tensions. However, the response to Ca2+ transients was two to three times more sensitive than the response to twitch tension. Decamethonium 2.4-96 microM and carbachol 5.5-109 microM produced similar results. In contrast, pancuronium and (+)-tubocurarine inhibited them in the same concentration ranges. The relation between Ca2+ transients and twitch tensions was hyperbolic and was computer-simulated by the Hill equation in the case of succinylcholine, decamethonium and carbachol, whereas it was represented by a single exponential equation in the case of pancuronium, (+)-tubocurarine, and submaximal nerve-stimulation voltage. Spontaneous Ca2+ transients, on the other hand, were generated only in response to depolarizing drugs at concentrations having a neuromuscular blocking effect. These results suggest that depolarizing and competitive neuromuscular blocking drugs affect intracellular Ca2+ mobilization by different routes mediated by acetylcholine receptors.     

The influence of ouabain on twitch contractions in the presence of veratridine

1. Direct stimulation evoked twitches in mouse diaphragm muscles in presence of 10 microM D-tubocurarine in vitro. Effects of ouabain and their dependence on K+ were examined on the twitch responses and action potentials in the presence and absence of twitch potentiators. 2. Ouabain inhibited twitch contractions only in the presence of veratridine, aconitine and monensin while it had no inhibitory effect on control twitches. The interactions between ouabain and these twitch potentiators depended on the presence of external K+, except in the case of monensin. 3. Removal of Ca2+ from a bathing solution accelerated the potentiating effect of veratridine and the antagonizing effect of ouabain. 4. Caffeine further potentiated the twitches which had been attenuated by ouabain combined with veratridine. 5. Ouabain combined with veratridine consistently decreased resting membrane potentials, action potentials and overshoot potentials and prolonged time to peak of and duration of the muscle action potentials. 6. Tetraethylammonium, 4-aminopyridine, and caffeine produced twitch potentiation which was insensitive to ouabain or the removal of K+. 7. These results suggest that twitch contractions in the presence of activators of sodium channels link with activation of Na+-K+-ATPase. Accumulation of Na+ inside the muscle fibres may uncouple the excitation-contraction system. 8. This uncoupling may not include the caffeine-sensitive process that controls the release of Ca2+ from the sarcoplasmic reticulum. Na+ accumulation may decrease transmembraneous gradient of this ions, thereby causing a reduction in excitation coupled with twitch contraction.