Changes in the ionic currents sensitivity to inhibitors in twitch rat skeletal muscles following denervation

The lack of CuZnSOD leads to impaired neurotransmitter release, neuromuscular junction destabilization and reduced muscle strength in mice

Elevated reactive oxygen species (ROS) production and ROS-dependent protein damage is a common observation in the pathogenesis of many muscle wasting disorders, including sarcopenia. However, the contribution of elevated ROS levels to –a breakdown in neuromuscular communication and muscle atrophy remains unknown. In this study, we examined a copper zinc superoxide dismutase [CuZnSOD (Sod1)] knockout mouse (Sod1^−/−), a mouse model of elevated oxidative stress that exhibits accelerated loss of muscle mass, which recapitulates many phenotypes of sarcopenia as early as 5 months of age. We found that young adult Sod1^−/− mice display a considerable reduction in hind limb skeletal muscle mass and strength when compared to age-matched wild-type mice. These changes are accompanied by gross alterations in neuromuscular junction (NMJ) morphology, including reduced occupancy of the motor endplates by axons, terminal sprouting and axon thinning and irregular swelling. Surprisingly however, the average density of acetylcholine receptors in endplates is preserved. Using in vivo electromyography and ex vivo electrophysiological studies of hind limb muscles in Sod1^−/− mice, we found that motor axons innervating the extensor digitorum longus (EDL) and gastrocnemius muscles release fewer synaptic vesicles upon nerve stimulation. Recordings from individually identified EDL NMJs show that reductions in neurotransmitter release are apparent in the Sod1^−/− mice even when endplates are close to fully innervated. However, electrophysiological properties, such as input resistance, resting membrane potential and spontaneous neurotransmitter release kinetics (but not frequency) are similar between EDL muscles of Sod1^−/− and wild-type mice. Administration of the potassium channel blocker 3,4-diaminopyridine, which broadens the presynaptic action potential, improves both neurotransmitter release and muscle strength. Together, these results suggest that ROS-associated motor nerve terminal dysfunction is a contributor to the observed muscle changes in Sod1^−/− mice.

Effects of denervation on Ca2+ channels in slow skeletal muscle fibers of the frog

Effects of denervation on calcium channels in slow skeletal muscle fibers in the frog (Rana pipiens) were studied using the three-microelectrode voltage-clamp technique in intact fibers. Ca2+, Ba2+, and Sr2+ currents were all significantly reduced in amplitude during the first 2 weeks after denervation. After nerve section the selectivity sequence Ba congruent with Ca > Sr was changed to Ba > Sr > Ca and the values for relative ratio increased from 1.04 to 2.65 for Ba2+ and from 0.58 to 1.20 for Sr2+ (with respect to Ca2+). Barium current saturation was more obvious in denervated fibers than in non-denervated fibers. The values obtained with the Michaelis-Menten type expression, I = Imax/(1+Kd/[Ba]e) were Kd = 2.7 mM and Imax = 20 microA/cm2 in fibers 2 weeks after nerve section compared with the values Kd = 4.4 mM and Imax = 60 microA/cm2 obtained in non-denervated fibers. Additionally, the effects of two calcium channel blockers (cobalt and nifedipine) were greater by a factor of two in denervated fibers than in non-denervated fibers. Three weeks or so after nerve section, all the biophysical properties studied began to show a tendency to recover toward the values obtained in non-denervated muscles (controls). These results suggest that calcium channels are modified or that there is a change in the types of calcium channels present in frog slow skeletal muscle fibers after denervation.

Barium resistant potassium current in mammalian skeletal muscle following denervation

Inward rectifier potassium channels are thought to be related to resting membrane potential and in innervated skeletal muscle they are specially sensitive to the blocking action of Ba2+ ions. After denervation other channels are known to become resistant to their blockers. We study the effect of Ba2+ upon the inward rectifier potassium channels after denervation. Rat extensor digitorum longus fibers were equilibrated for 150 minutes in 150 mM KCl; when they were returned to 5 mM KCl the resting potential went back to its original level with a half time of 35 minutes. This repolarization was blocked by 5 mM BaCl2 in innervated muscles and in muscles denervated for 7 days, but failed to do so after 14 days of denervation. Voltage-clamp experiments performed in lumbricalis denervated muscle showed a lack of effect of Ba2+ upon potassium current after 18 days of denervation. This results suggest that the inward rectifier potassium channels become resistant to Ba2+ ions after denervation, indicating a neural influence.

Activation of two types of fibres in ferret, Mustela putorius furo, cremaster muscle

Some contractile, histochemical, morphological and electrophysiological properties of ferret, Mustela putorius furo, cremaster muscle have been estimated. Histochemical fibre typing revealed the presence of two types of fibres (type I 66.2%, type II 33.8%). Morphometry performed on ATPase-stained transverse sections showed that type I was composed of a large amount (40%) of small (less than 1400 microns2) cells. In mammalian Ringer two groups of fibres could be recognized on the basis of the values of resting potential (-69.7 mV and -59.1 mV) intracellular sodium activity (8.3 mmol.l-1 and 14.1 mmol.l-1, respectively). In experiments on fibre bundles, the elevation of extracellular potassium concentration to 15-200 mmol.l-1 produced contractures that consisted of a well-defined transient or phasic tension followed by a sustained or tonic tension. Properties of activation and inactivation of the tension analysed in small bundles of cut fibres (lengths 0.5-1.0 cm) were of fast- and slow-twitch type for phasic and tonic phase, respectively. In contrast to the phasic component of K contractures, the tonic phase was abolished by Ca2+ withdrawal and inhibited by Ni2+, Cd2+, Co2+, Gd3+ and gallopamil (D600). In Ca(2+)-free medium the sustained tension was restored by adding Sr2+. It is concluded that in ferret cremaster muscle the presence of slow-twitch fibres would give rise to the tonic component of the K contracture in which an extracellular source of activator Ca2+ is involved. The ability of these fibres to contract with a maintained tension for prolonged periods of time might participate in the temperature regulation of the testes.

Calcium current activation and charge movement in denervated mammalian skeletal muscle fibres

1. Calcium current (ICa) activation was studied in denervated extensor digitorum longus muscle fibres of the rat. Denervation was performed by surgically removing 6-8 mm of the sciatic nerve at the sciatic notch. Controls were normal fibres from non-operated rats. Electrical recordings were carried out using the double Vaseline-gap technique. 2. Current-voltage (I-V) curves showed that the ICa amplitude increased during the first 4-6 days after denervation and subsequently decreased during the second week. Between days 4 and 6 after denervation, the peak ICa amplitude (at 0 mV) was -5.9 +/- 0.5 microA/microF (mean +/- S.E.M.) as compared with -4.8 +/- 0.3 microA/microF in normal fibres. Between days 14 and 15 after denervation, the ICa amplitude was -2.9 +/- 0.4 microA/microF. 3. The time constant of ICa activation (tau a) was significantly increased by denervation. At 0 mV, tau a in normal fibres was 44.8 +/- 1.4 ms. Between 4 and 6 days after denervation tau a was 58.1 +/- 4.8 ms, and between 14 and 15 days after denervation, 55.8 +/- 3.8 ms. 4. The time constant of deactivation (tau d) decreased after denervation. At -10 mV, the tau d in normal fibres was 103.4 +/- 14 ms. The value decreased to 74.5 +/- 8.6 and 74.0 +/- 17 ms between days 4 and 6 and days 14 and 15 of denervation respectively. 5. Charge movement (Qon) was reduced progressively without major changes in the steepness (k) and position on the voltage axis of the Qon-Vm relationship. The fitted parameters under control were Qmax = 15.4 nC/microF, mid-point potential Vq1/2 = -25.2 mV and k = 11.9 mV. Between days 14 and 15 of denervation, the values for Qmax, Vq1/2 and k were 6.7 nC/microF, -36.8 mV and 11.3 mV respectively. 6. Calcium permeability (PCa) in normal and denervated fibres at stages during denervation was calculated according to the Hodgkin-Huxley model. At 0 mV PCa was 1.24 x 10(-5) cm/s in normal fibres, and 7.43 x 10(-6) cm/s after 2 weeks of denervation. 7. The m infinity-Vm relationship was shifted to more positive potentials after denervation without significant changes in the steepness factor k. The V1/2 value in normal fibres was -4.4 mV, and 5.8 mV after two weeks of denervation. 8. The ICa sensitivity to nifedipine was not modified in the different groups of denervated fibres studied. With 10 microM-nifedipine, the 1-(ICa in nifedipine/ICa control) relationships were 0.74 +/- 0.03 in normal fibres and 0.76 +/- 0.12, 14 days after denervation.

Calcium action potentials in innervated and denervated rat muscle fibres

We studied the generation of calcium action potentials (Ca APs) in innervated and denervated fibres of the extensor digitorum longus of the rat in a tetraethylammonium (TEA) sulphate solution plus 3-4 diaminopiridine (3-4 DAP). The main results are the following: (1) more than 90% of the innervated fibres were capable of developing well-sustained Ca APs that were blocked by Cd or nifedipine; (2) the incidence of Ca APs obtained from the denervated fibres was substantially lower than in the control preparations; (3) no relation was found between the appearance of Ca APs in the denervated fibres and the resting membrane potential (Vm), stimulus duration (500-2000 ms) or holding potential (-80, -100 mV); (4) The percentage of denervated fibres that exhibited Ca APs was increased significantly with the following procedures. First, by raising the external Ca concentration to 14 mM; second, by depleting the intracellular K concentration by overnight exposure of the muscles to a free K-Cs solution; (c) and third, by incubating the muscles in 500 nM apamin, a venom that inhibits the K conductance activated by Ca. Several factors may be involved in the lower incidence of Ca APs obtained in denervated fibres: (1) a diminished Ca current due to a reduction in the driving force as a result of an increment in the intracellular Ca concentration; (2) a persistence of a shunting K conductance that is not inhibited by TEA and 3-4 DAP; (3) a shift in the voltage dependence of the activation and inactivation parameters of the Ca current or the appearance of a new type of Ca channel with a different kinetics.

Sodium current block caused by group IIb cations in calf Purkinje fibres and in guinea-pig ventricular myocytes

The action of group IIb cations [Cadmium (Cd2+), Zinc (Zn2+), Mercury (Hg2+)] on the cardiac fast sodium current (INa) was investigated in calf Purkinje fibres and in ventricular cells isolated from guinea-pig hearts. In calf Purkinje fibres, INa was depressed by submillimolar concentrations of Zn2+ and Hg2+. With both cations, the current reduction occurred at all voltages in the range of current activation and the voltage dependence of peak current was unchanged. The degree of peak current inhibition depended on the cation concentration but not on voltage. The position of the inactivation curve on the voltage axis was unaltered at cation concentrations giving substantial current inhibition, and moved to the right only with concentration exceeding 1-1.5 mM. These effects can be interpreted as due to INa channel blockade. The action of Zn2+ and Hg2+ was similar to that described earlier of Cd2+ on Purkinje fibres (DiFrancesco et al. 1985b). INa was also inhibited by group IIb cations in isolated guinea-pig ventricular cells. Depression of INa by Cd2+, Zn2+ and Hg2+ was essentially voltage-independent, in agreement with its being caused by channel block. The dependence of INa block by Cd2+ upon external Na concentration [Na+0] was investigated in ventricular myocytes. The fraction of INa block by 0.1 mM CdCl2 was 0.50 at 140 mM, 0.81 at 70 mM and 0.83 at 35 mM [Na+]0. A similar increase of block efficiency at low [Na+0] was observed with 0.05 mM CdCl2. In both the Purkinje fibre and the ventricular cell, the order of potency of INa block by group IIb cations was Hg2+ greater than Zn2+ greater than Cd2+. Manganese (Mn2+, 2-5 mM), an ion of group VIIa, also depressed the INa in Purkinje fibres and ventricular myocytes. This effect was however due mainly to a positive shift on the voltage dependence of current kinetics rather than to a reduction of the conductance of the channel (GNa), and can be accounted for by an ion-screening action of Mn2+ on the external membrane surface. The block by group IIb cations is a typical property of cardiac Na+ channels and characterizes the cardiac as opposed to other types of Na+ channel.

Dual effects of charged amphiphiles on depolarization-contraction coupling in denervated rat soleus muscle

Ionic currents and contraction were recorded under voltage clamp conditions in single fibres isolated from rat soleus muscles denervated for more than 20 days. The effects of amphiphiles on depolarization-contraction (d.c.) coupling in Na-free TEA-containing solutions were analyzed. An anionic amphiphile, sodium dodecyl sulfate (1-10 microM), caused a dose-dependent reduction of the contractile response at all amplitudes of depolarization while a cationic amphiphile, dodecyltrimethylamine (1-10 microM), increased the maximum developed tension with a shift in the contractile threshold. A neutral amphiphile, lauryl acetate (20 microM), induced no significant variation. The effects of charged amphiphiles were found to be strongly dependent on the external calcium concentration and on membrane potential. The effect of sodium dodecyl sulfate to decrease tension was reduced or changed to positive inotropy following hyperpolarization of the membrane by, respectively, +10 and +20 mV. In hyperpolarized (+20 mV) cells, dodecyltrimethylamine reduced the amplitude of the contraction. The results demonstrated that changes in Ca-binding properties of surface membrane modified d.c. coupling in denervated slow twitch skeletal muscle.

Changes in Na channel properties of frog and rat skeletal muscles induced by the AaH II toxin from the scorpion Androctonus australis

The effects of the mammal toxin II isolated from the venom of the scorpion Androctonus australis Hector (AaH II) were studied under current and voltage clamp conditions in frog (semitendinosus) and rat (fast e.d.l. and slow soleus) skeletal twitch muscle fibres. In both species, AaH II induced a dose-dependent prolongation of the action potential (AP) leading at saturating concentration to APs with long plateaus of about 1.5 s in frog and 5 s in rat e.d.l. and soleus fibres. The concentrations to induce 50% of the maximal effect (K0.5) were 9.1 x 10(-9) M in the frog and 1.4 x 10(-9) M in the rat. AaH II increased the time constants of inactivation of the peak Na current and induced a maintained Na current that was greater in rat e.d.l. and soleus (31.6% of peak current amplitude at -30 mV; K0.5 = 0.8 x 10(-9) M) than in frog (16.5%; K0.5 = 15.5 x 10(-9) M) muscles. Peak and maintained Na currents were TTX-sensitive and had identical threshold and reversal potentials. The half-maximum maintained permeability occurred at a potential 20 mV more positive than the peak permeability. Recovery from inactivation and steady-state inactivation of the inactivating Na current remained unchanged. The maintained current deactivated with normal fast kinetics. The action of the toxin reversed poorly on washout but could be largely removed by conditioning depolarizations more positive than the reversal potential of the Na current. Our results suggest that, in vertebrate skeletal muscle fibres, AaH II affects all the Na channels and are consistent with the hypothesis that the maintained current originates from a reopening of previously inactivated Na channels.

Changes in tetrodotoxin-resistant action potentials after passive transfer of myasthenia gravis patient sera

Muscle electrical activity has been studied in mice after intraperitoneal injection of sera from myasthenia gravis (MG) patients. Myasthenic serum did not modify the electrical properties of innervated muscle fibres. The resting membrane potential and the action potential parameters remained unchanged. However, tetrodotoxin (TTX)-resistant action potentials of denervated muscles were reduced by myasthenic serum, possibly in association with receptor endocytosis induced by the immunoglobulin. However, a direct effect of MG serum on TTX-resistant sodium channels cannot be ruled out.

Mechanical and electrical properties of denervated rat skeletal muscles

Mechanical activity (twitch and tetanus) and electrical activity (single and repetitive action potentials) were recorded in vitro (34 degrees C) in control and denervated (3 to 14 days) soleus and extensor digitorum longus muscles of the rat. After denervation tetanic tension (100 to 200 Hz, 500 ms duration) was decreased in both types of muscles. Denervation reduced significantly the rates of rise and fall and the amplitude of the action potential in both types of muscle fibers. In denervated fibers with very low resting membrane potential no action potentials could be recorded: in these fibers only a slow response without overshoot was detected. Hyperpolarization of denervated fibers to -90 mV prior to application of the depolarizing pulse increased their excitability. Action potential amplitudes were well maintained during tetanic stimulation (200 Hz, 40 to 90 ms) in innervated fibers. Depolarization of the innervated fibers with cathodic current before the tetanic pulse hindered the generation of repetitive action potentials at 200 Hz. A proportion of denervated fibers stimulated at 100 to 200 Hz generated only one action potential or gave rise to an incomplete train. Hyperpolarization of the denervated fibers resulted in an improvement in the ability to generate a train of action potentials at 100 to 200 Hz. A group of denervated fibers exhibited well maintained action potentials during tetanus. We suggest that failure in the repetitive electrical activity of denervated fibers could be the reason for the reduced tension of tetanus. Depolarization of the fibers and/or the increment in the electrical time constant of the sarcolemma are suggested for the decrease in the electrical excitability of denervated fibers.

Membrane Ca2+ interactions and contraction in denervated rat soleus muscle

Under voltage clamp conditions contractile responses and ionic currents of single fibres isolated from rat soleus, denervated for more than 20 days, were recorded in Na-free TEA containing solutions. The relationship between membrane potential and contraction has been analysed under various conditions. The addition of trivalent cations (La3+, Gd3+) resulted in a dose dependent reduction of the contractile response and similar effects were produced by polymyxin B (0.05-0.5 mM). By contrast in the presence of phospholipase D (1-5 U/ml) contractions were significantly increased for all values of depolarization. The time course of the change of tension amplitude after the application of Ca-free medium, was dependent on the amplitude, the duration and the frequency of the depolarization. Upon depolarization glycerol-treated fibres generated contractile responses which were similar to those recorded in normal muscle and were also dependent on [Ca]o. It is proposed that in denervated soleus muscle the negatively charged phospholipids at the outside of the membrane were involved in the depolarization-contraction coupling by means of their Ca binding properties. The quantity of Ca binding sites would be dependent on [Ca]o and membrane potential and their binding properties modified during and/or following variation in membrane potential.

Effects of external cations and calcium-channel blockers on depolarization-contraction coupling in denervated rat twitch skeletal muscles

In the double mannitol gap arrangement the contraction was estimated in single fibres isolated from rat extensor digitorum longus (e.d.l.) muscles that had been denervated for 2-48 days. Denervation induced large changes in the characteristics of the action potential and of the twitch. Up to 15-20 days after denervation the contraction-depolarization curve was sigmoidal and the maximum amplitude of the contraction was not modified by variation of [Ca]o or [Na]o. After 15-20 days of denervation a bell-shaped curve described the relation between contraction and potential. The maximum amplitude was dependent upon the [Ca]o. In Ca-free solution no contractile response was obtained. In Na-free, Ca-containing solution the relationship between contraction and potential was not modified by the addition of divalent cations Co2+, Cd2+, Mn2+, Mg2+, Ni2+, or Ba2+. The contraction, which appeared in Ca-free solution, was restored by adding Sr2+. D600, verapamil and bepridil failed to change the amplitude of the contraction while a marked reduction was found with dihydropyridines. The reduction was overcome by increasing [Ca]o. The present results suggest that the slow calcium current is not involved in the generation of the contractile responses developed by denervated muscles in Na-free (TEA) solution.

Repetitive action potentials induced in chloride-free solution: effect of denervation

Isometric mechanical activity and action potentials registered with intracellular microelectrodes were studied in innervated and denervated fibers of the soleus muscle of the rat in normal and chloride-free solutions. The chloride-free solution promoted in both innervated and denervated fibers an increment in the resting membrane potential. The innervated muscles showed long mechanical relaxation and repetitive action potentials after a single depolarizing pulse. On the contrary, denervated muscles were resistant to show mechanical and electrical changes in the chloride-free medium. Spontaneous and evoked action potentials from innervated muscle fibers were abolished by tetrodotoxin. The evoked action potentials generated in denervated fibers had a slower time course and were resistant to tetrodotoxin. After 7 to 10 days of denervation the input resistance was increased by about 30%. Substitution of chloride with sulfate resulted in a 150% increase in input resistance of innervated muscle fibers and 80% in denervated preparations. Alterations in the ionic conductances, a decrease in the maximum rate of rise of the action potentials, and changes in the sodium current kinetics could be the main factors for the absence of repetitive action potentials in denervated fibers exposed to the chloride-free medium.