Distribution of calcium during contraction and relaxation of crayfish skeletal muscle fibre.

A model of activation of muscle contraction has been applied to the crayfish isolated skeletal muscle fibre. The model is based on calcium diffusion and binding to specific regulatory sites in a sarcomere. Calcium ions activate interactions of contractile proteins and thus the generation of force. The model quantifies the relation between calcium released from intracellular stores and force elicited. Experimental tension records from isolated crayfish skeletal muscle fibres under voltage clamp conditions are analyzed. Model parameters were determined either via approximation of the onset of tension by the model solution or from the model based relations between the tension maximum, and depolarizing pulse length and amplitude. This allowed to determine time changes of free and bound calcium distribution in the sarcomere and the calcium release from terminal cisternae. The steady state calcium concentration at terminal cisternae showed S-shaped voltage dependence with saturation below approx. 10 mumol/l at positive membrane potentials.     

The effect of diazepam on potassium contractures, contraction threshold, and resting tension in rat skeletal muscles

The effects of diazepam on potassium contractures, contraction threshold, and resting tension have been examined in rat soleus muscle fibres. Two actions of the drug were defined that could not be attributed to changes in the resting membrane potential or depolarization in high potassium solutions. The major effect was an increase in the amplitude of submaximal tension during either twitches or potassium contractures and an increase in resting tension. At 400 microM diazepam, there was (a) a fourfold increase in 40 mM potassium contracture tension, (b) a negative shift of 8 mV in the membrane potential for half maximum tension estimated from the best fit of a Boltzmann-type equation to average potassium contracture data, (c) a negative shift of 8 mV in the threshold for contraction measured under voltage clamp conditions, and (d) a contracture of variable amplitude to a level that was occasionally equivalent to maximum tetanic tension. These potentiating actions of diazepam depended on drug concentration within the range of 100-800 microM. In contrast, the second effect of diazepam, depression of maximum tension by 10-15%, was independent of drug concentration between 100 and 400 microM. The results support the idea that diazepam produces an increase in resting myoplasmic calcium concentrations.     

Effects of isoprenaline on tonic tension and Na-Ca exchange in frog atrial fibres

The action of isoprenaline, a purely beta-agonist, was investigated on frog atrial fibres under voltage clamp conditions; tonic tension was induced by long depolarizing pulses and the outward delayed current simultaneously developed. The cumulative dose-response curves showed that isoprenaline increased the peak of tonic tension in the concentration range 10(-8) to 3. 10(-6) mol.l-1, with a maximum effect for 10(-6) mol.l-1. The positive inotropic action of isoprenaline was associated with an increase in the rates of tension rise and of relaxation. Isoprenaline also increased the amplitude of the outward delayed current in a dose-dependent manner. The effects of isoprenaline (10(-6) mol.l-1) on tonic tension and outward delayed current were not observed in the presence of propranolol (10(-7) mol.l-1). Experiments carried out in low-sodium solution demonstrated that the action of isoprenaline on tonic tension can be explained by activation of Na-Ca exchange; the enhanced relaxation might result from the same process. These results suggested that the positive inotropic action of isoprenaline is mediated not only by the well-known increase in the slow inward current but also by activation of the Na-Ca exchange mechanism.     

Patch clamp recording of the responses to three bitter stimuli in mouse taste cells.

Although several pathways of bitter taste signal transduction have been proposed in taste cells, these mechanisms have not been elucidated in detail. To investigate the diversity of responses to bitter stimuli, we recorded the electrophysiological responses to quinine, denatonium and naringin using whole-cell patch clamp technique in isolated taste cells of C57BL/6J mice. Ten mM quinine induced depolarizing response under the current clamp mode, and inward current response under the voltage-clamp mode (holding potential -80 mV) using both K+ (with pseudo intracellular solution) and Cs+ (K+ was substituted by Cs+ in the pseudo intracellular solution) pipettes. However, when the K+ pipette was used, the membrane conductance was suppressed and activated in succession. On the other hand, the membrane conductance was only activated when the Cs+ pipette was used. Half to one mM denatonium induced depolarizing response under the current clamp mode, and outward current response under the voltage clamp mode with both pipettes. Using these pipettes, the membrane conductance was activated or suppressed in the individual case. Naringin-induced responses were not detected in these measurements. These electrophysiological recordings suggest that multiple transduction mechanisms are involved in bitter taste perception in mouse taste cells.     

Slow inward current and contraction of sheep cardiac Purkinje fibers

A "slow" inward current (Is) has been identified in ventricular muscle and Purkinje fibers of several mammalian species. The two- microelectrode voltage clamp technique is used to examine some of the relationships between Is and contraction of the sheep cardiac Purkinje fiber. "Tails" of inward current occurring on repolarization and extrapolation of Is recovery each show that the Is system may not inactivate completely during prolonged depolarization. The rate of recovery of Is after a depolarization is slow, and when a train of 300- ms clamps (frequency 1 s-1) is begun after a rest, Is is larger for the first clamp than it is for succeedings clamps. For the first clamp after a rest, the thresholds for Is and tension are the same and there is a direct correlation between peak tension and peak Is for clamp voltages between threshold and minus 40 mV. After a clamp, however, the ability to contract recovers much more slowly than does Is. Therefore, since Is may occur under certain conditions without tension, the realtionship between Is and tension must be indirect. Calcium entering the cell via this current may replenish or augment an intracellular calcium pool.     

External calcium and contractility in single giant muscle fibres

Isometric tension and intracellular calcium movements detected using the calcium sensitive photoprotein aequorin have been studied on single striated fibres. The decrease of tension and light response upon deprivation of external calcium would support the notion that calcium ions are involved in the transmission of the electrical potential change from the tubular system to the sarcoplasmic reticulum, by occupying sites on the external (extracellular) surface of tubular system in direct correspondence with the terminal sacs of the sarcoplasmic reticulum.     

Action potential-like responses due to the inward rectifying potassium channel

Summary This paper describes experiments carried out in the absence of sodium and calcium in the external solution. Frog atrial trabeculae were stimulated in current clamp with the double sucrose gap technique. The voltage responses looked like slow action potentials with a clear threshold. These responses were not suppressed in the presence of EGTA, in the presence of sodium or calcium channel blockers, or when sulfate ions replaced chloride. Guinea pig isolated ventricular myocytes were studied in whole cell clamp mode with a pathch pipette. Under current clamp, they displayed also voltage responses with a threshold. These responses were resistant to cadmium (5mm), and were suppressed by barium (0.5mm). A negative slope conductance is required to take into account these results. The membrane current in current clamp can be estimated by plotting the response in the phase plane. This analysis shows that on both types of preparations, the current responsible for the negative slope is not time dependent. This current is suppressed by barium. It can be concluded that it is the outward current flowing through the inward rectifying potassium channels. To confirm this hypothesis, data obtained in voltage clamp on the same preparations were introduced into a computer model to predict the response in current clamp. The results were in agreement with the experiments. Similar responses could be recorded and analyzed on skeletal muscle in isotonic potassium solution. These results show that the inward rectifier can induce by itself properties looking like excitability on different preparations. The physiological significance of this effect in normal conditions is discussed. The voltage responses described in this paper look similar to the slow action potentials on heart, which are sensitive to modifications of the calcium channels, but also of the potassium channels. Some implications in cardiac pharmacology are discussed.     

Effects of cortisone on mechanical activity and membrane ionic currents in frog auricular fibres.

The influence of cortisone on the mechanical and electrical activity of frog auricular fibres was investigated under voltage clamp conditions. 1. Cortisone exerted in vitro an inotropic action depending on concentration; a maximal positive inotropic effect was observed with 2 x 10(-4) g/ml of cortisone. 2. The positive inotropic effect of cortisone might be either an indirect sympathomimetic effect or an adrenaline-like effect. 3. The positive inotropic action of cortisone was correlated with modifications of the cardiac action potential: the amplitude of the action potential was enhanced while the resting membrane potential was unchanged; the amplitude and duration of the plateau were increased and the duration of the action potential was lengthened. 4. The electrical changes were related to an increase in the slow calcium current intensity resulting from an increase in the slow calcium conductance.     

Voltage clamp methods for the study of membrane currents and SR Ca(2+) release in adult skeletal muscle fibres

Skeletal muscle excitation-contraction (E-C)(1) coupling is a process composed of multiple sequential stages, by which an action potential triggers sarcoplasmic reticulum (SR)(2) Ca(2+) release and subsequent contractile activation. The various steps in the E-C coupling process in skeletal muscle can be studied using different techniques. The simultaneous recordings of sarcolemmal electrical signals and the accompanying elevation in myoplasmic Ca(2+), due to depolarization-initiated SR Ca(2+) release in skeletal muscle fibres, have been useful to obtain a better understanding of muscle function. In studying the origin and mechanism of voltage dependency of E-C coupling a variety of different techniques have been used to control the voltage in adult skeletal fibres. Pioneering work in muscles isolated from amphibians or crustaceans used microelectrodes or 'high resistance gap' techniques to manipulate the voltage in the muscle fibres. The development of the patch clamp technique and its variant, the whole-cell clamp configuration that facilitates the manipulation of the intracellular environment, allowed the use of the voltage clamp techniques in different cell types, including skeletal muscle fibres. The aim of this article is to present an historical perspective of the voltage clamp methods used to study skeletal muscle E-C coupling as well as to describe the current status of using the whole-cell patch clamp technique in studies in which the electrical and Ca(2+) signalling properties of mouse skeletal muscle membranes are being investigated.     

Transmission in the squid giant synapse: a model based on voltage clamp studies

1. Voltage clamp studies were performed in squid giant synapse after blockage of the voltage-dependent sodium and potassium conductances. 2. Presynaptic depolarization under these conditions demonstrates the presence of voltage-dependent calcium conductance change for the duration of the voltage step, and a tail current at the break of the pulse. 2. This calcium current triggers a postsynaptic response which can be measured directly at the postsynaptic fiber. 4. These voltage clamp experiments have allowed the development of a mathematical model that describes the kinetics of the calcium current and the relationship between calcium current and transmitter release.     

Effect of forskolin on action potential, slow inward current and tension of frog atrial fibers

The new nonhormonal activator of adenylate cyclase forskolin was studied on frog atrial trabeculae by current clamp and voltage clamp methods using a double sucrose gap technique. Forskolin (5 X 10(-6) M to 2 X 10(-5) M) dose-dependently increased action potential duration, the height of the plateau and twitch tension. The time constant for inactivation of the slow inward current and the steady state kinetic variables of calcium channels d infinity and f infinity remained uneffected. Forskolin increased the amplitude of slow inward calcium current isi and of the phasic tension related to it. The maximal conductance gsi increased. These effects were indistinguishable from those obtained earlier on cardiac fibers with hormonal and nonhormonal activators of cyclic AMP-dependent phosphorylation. The beta-adrenoreceptor antagonist propranolol 10(-6)M did not decrease the effect of forskolin. Forskolin had no effect when slow inward current was previously increased by saturating concentrations of the beta-adrenergic agonist isoproterenol (10(-4)M). Our results are in favour of the hypothesis that cyclic AMP-dependent phosphorylation of membrane proteins modulates the Ca-entry in the heart cells through the membrane slow calcium channels.     

Relationships between voltage and tension in sheep cardiac Purkinje fibers

The two-microelectrode technique of voltage clamping sheep cardiac Purkinje fibers was used to examine the changes in contraction which occur during trains of voltage clamps. (A "train" is defined as a series of voltage clamps delivered at a particular rate, beginning after a rest long enough that the effects of previous stimulation have died away.) Contractions showed striking staircases, or progressive changes in peak isometric tension, during trains. Short clamps, clamps to voltages more negative than --20 or --30 mV, or holding potentials less negative than the resting potential favored negative staircases, while long clamps, clamps to positive voltages, and holding potentials near the resting potential each favored positive staircases. The staircase behavior appeared to be due to changes in the initial rate of recovery of the ability to contract. The changes in staircase behavior as a function of clamp voltage suggested that the relationship between peak tension and clamp voltage should depend on the experimental design. When the steady-state contraction was plotted as a function of clamp voltage, voltage-tension relations like those recently reported for working ventricle were obtained, with a threshold between --30 and - -40 mV and a steep relation between tension and voltage. When the first contraction after a rest was plotted, the threshold voltage was more negative, the curve was flatter, and the peak tensions at inside positive voltages were reduced.     

Effects of quinidine and lidocaine on action potential and membrane currents of frog ventricles

The effects of quinidine and lidocaine on frog ventricle were studied by using a single sucrose gap voltage clamp technique. In Ca2+-Ringer, quinidine (80 microM) caused slight prolongation of action potential duration (APD50) and significant inhibition of twitch tension. Lidocaine (40 microM) shortened APD50 without significant effect on twitch tension. In tetrodotoxin (TTX)-treated preparations, quinidine caused significant prolongation of APD50 from 529 +/- 19 msec to 597 +/- 11 msec, (n = 9) and inhibition of twitch tension, but lidocaine did not affect APD50 and twitch tension. Under voltage clamp condition, quinidine reduced peak inward current in the absence of TTX, but enhanced peak inward current in the presence of TTX. The steady state outward current was increased by quinidine. Lidocaine didn't affect peak inward current in the absence or in the presence of TTX. Membrane current through the inward rectifier (IK1) was slightly increased by lidocaine, but significantly inhibited by quinidine. The enhancement of peak inward current by quinidine was retarded or reversed in preparation bathed with Sr2+-Ringer. When Ni2+ was added to a preparation bathed in Ca2+-Ringer, an inhibition of calcium inward current and action potential plateau was observed. The spike amplitude of the action potential was, however, unaffected by Ni2+. In this Ni2+-treated preparation, lidocaine (20 microM) caused significant shortening of APD50 without significant effect on action potential amplitude. The shortening of APD50 was associated with a slight increase of steady state outward current. The increase of steady state outward current by lidocaine was absent in the TTX-treated preparation.(ABSTRACT TRUNCATED AT 250 WORDS)     

Selectivity of sodium channels in denervated tonic muscle fibre membrane of the frog

Ionic selectivity of sodium channels was examined under voltage clamp conditions in normal and denervated twitch fibres and denervated tonic fibres isolated from m. ileofibularis of the frog (R. temporaria). Membrane currents were recorded by means of the Hille-Campbell vaseline-gap voltage clamp method from muscle fibre segments exposed to a potassium-free artificial internal solution. Permeability ratio (PS/PNa) were determined from changes in the reversal potential after replacing all Na ions in the solution bathing the voltage clamped external membrane area with sodium substituting ions (S). The permeability sequence was: Na+ greater than Li+ greater than NH4+ greater than K+. No inward currents were observed for Ca2+. The permeability ratios were as follows. Denervated tonic fibres: 1:0.88:0.23:0.012; control twitch fibres: 1:0.94:0.22:0.076; denervated twitch fibres: 1:0.91:0.14:0.082. The permeability to Li+ ions deviates from independence to a greater extent in tonic than in phasic fibres. Our results are consistent with the Hille model of sodium channel selectivity, and they support the hypothesis that sodium channels formed in denervated tonic muscle fibres of the frog are of the same genetic origin as Na channels expressed under physiological conditions.     

Fast calcium transients translate the distribution and conduction of neural activity in different regions of a single sensory neuron

In the present study, cytosolic calcium concentration changes were recorded in response to various forms of excitations, using the fluorescent calcium indicator dye OG-BAPTA1 together with the current or voltage clamp methods in stretch receptor neurons of crayfish. A single action potential evoked a rise in the resting calcium level in the axon and axonal hillock, whereas an impulse train or a large saturating current injection would be required to evoke an equivalent response in the dendrite region. Under voltage clamp conditions, amplitude differences between axon and dendrite responses vanished completely. The fast activation time and the modulation of the response by extracellular calcium concentration changes indicated that the evoked calcium transients might be mediated by calcium entry into the cytosol through a voltage-gated calcium channel. The decay of the responses was slow and sensitive to extracellular sodium and calcium concentrations as well as exposure to 1–10 mM NiCl₂ and 10–500 µM lanthanum. Thus, a sodium calcium exchanger and a calcium ATPase might be responsible for calcium extrusion from the cytosol. Present results indicate that the calcium indicator OG-BAPTA1 might be an efficient but indirect way of monitoring regional membrane potential differences in a single neuron.     

Activation of ATP-dependent K+ currents in intact skeletal muscle fibres by reduced intracellular pH.

We have used three-microelectrode voltage clamp in conjunction with the ammonium prepulse method to investigate the effects of lowered intracellular pH (pHi) on resting potassium currents of frog skeletal muscle fibres. Potassium currents were recorded in 40 mM K+, Cl(-)-free solution in response either to voltage steps or ramps. An ammonium prepulse (2 h) reduced pHi to 6.45 from a control value of 7.19. The intracellular ATP concentration, measured with high-pressure liquid chromatography (HPLC), was unchanged by this procedure. Mean outward potassium currents were larger in low pHi than in control fibres, being about twice as large at +40 mV, whereas mean inward currents were very similar in control and low-pHi fibres. The sulphonylurea glibenclamide blocked single KATP channels in excised patches with a Kd of 3 microM. In intact fibres 50 microM glibenclamide had no effect on K+ currents in controls but reduced currents in low-pHi fibres. In the presence of glibenclamide, K+ currents in low-pHi fibres were not significantly different from those in control fibres. We suggest that reduced pHi in intact skeletal muscle fibres opens ATP-dependent potassium channels (KATP channels), as has been shown to occur in excised patches of membrane.     

Tetracycline fluorescence as calcium-probe for nerve membrane with some model studies using erythrocyte ghosts

Summary The tetracycline dyes, particularly chlorotetracycline, have been employed as probes of membrane-associated calcium during the excitation process of nerve. Both squid giant axons, stained internally, and lobster nerves, stained externally, show a small increase in fluorescent light during the action potential. Increasing the calcium concentration bathing a lobster nerve leads to a larger optical signal. Adding fluoride ion to the inside of a squid axon, which might be expected to influence the internal calcium-ion concentration, also leads to a larger optical signal. Squid axons have been studied under conditions of voltage clamp and the hyperpolarizing response. Model studies were done with erythrocyte ghosts to clarify the influence of membranes and calcium on the fluores-cence of the tetracyclines. Chlorotetracycline may be monitoring calcium concentration associated with the inner surface of the nerve membrane.     

The chloride conductance of intermediate fibres from frog muscles

Sheets of muscle fibres dissected from surface portions of frog ileofibularis and semitendinosus muscles were soaked in solutions with elevated K and Cl concentrations. The KCl-loaded muscles were then bathed in low [Cl-] solutions, whereby the membrane potential became transiently inside positive. The repolarization of the twitch fibres from the tonus bundle ("intermediate fibres") was faster than that of the fibres adjacent to it ("fast fibres") when the preceding exposure to high KCl was brief (7-15 min), and it was slower than that of the fast fibres when KCl was applied for 4 hours. Measurements of the voltage displacement at constant current and of the current in a point voltage clamp showed that inwardly rectifying K channels were present in the membranes of both types of fibres. The ionic conductance ratio, gK/gCl, was 191/523 in fast fibres and 335/230 in "intermediate" fibres. The different repolarization rates may thus be explained by differences in the chloride conductance of the fast and intermediate fibre membranes. The smaller diameter of the latter fibres may be another factor.     

An examination of the ability of inositol 1,4,5-trisphosphate to induce calcium release and tension development in skinned skeletal muscle fibres of frog and crustacea

We have examined the ability of inositol 1,4,5-trisphosphate (InsP3) to cause contractions of mechanically skinned muscle fibres of frog and barnacle. InsP3 (10-500 microM) did not cause any tension development in 25 frog skinned fibres and 26 barnacle myofibrillar bundles, although contractions could be readily evoked by caffeine and by replacement of an impermeant anion by Cl-, treatments known to release calcium from the sarcoplasmic reticulum (SR). Four barnacle bundles did give responses to InsP3. InsP3 did not modify responses to caffeine or calcium-induced calcium release. Free Mg2+ was lowered to 40 microM and 15 mM D-2,3-diphosphoglycerate was added in order to inhibit the possible breakdown of InsP3 by inositol trisphosphatase. Neither measure revealed a response to InsP3. Arsenazo III absorbance measurements failed to detect any binding of Mg2+ (0-0.5 mM) by 0.35 mM InsP3 in our solutions. Inhibitors of SR calcium uptake (cadium, quercetin, furosemide), omission of EGTA from the solution and varying the temperature from 4 degrees to 22 degrees C also failed to reveal a response of frog skinned fibres to InsP3. The nucleotide GTP, which has been reported to enhance InsP3-induced calcium release from rat liver microsomes, had no effect at 50 microM on the response of frog fibres to InsP3. It is concluded that under conditions in which other calcium release mechanisms operate well, InsP3 is relatively ineffective at releasing calcium from the SR in amounts sufficient to induce contraction. Although we have been unable to find evidence to support the proposed role of InsP3 as an essential link in excitation-contraction coupling of skeletal muscle, we cannot entirely reject its role if essential cofactors are lost in the skinned preparations.     

Length-dependent electromechanical coupling in single muscle fibers

In single muscle fibers from the giant barnacle, a small decrease in muscle length decreases both the calcium activation and the peak isometric tension produced by a constant current stimulus. The effect is most pronounced if the length change immediately precedes the stimulation. In some cases, the decrease in tension with shortening can be accounted for almost entirely by a decrease in calcium release rather than changes in mechanical factors such as filament geometry. During the constant current stimulation the muscle membrane becomes more depolarized at longer muscle lengths than at the shorter muscle lengths. Under voltage clamp conditions, when the membrane potential is kept constant during stimulation, there is little length dependence of calcium release. Thus, the effect of length on calcium release is mediated through a change in membrane properties, rather than an effect on a subsequent step in excitation-contraction coupling. Stretch causes the unstimulated fiber membrane to depolarize by about l mV while release causes the fiber membrane to hyperpolarize by about the same amount. The process causing this change in potential has an equilibrium potential nearly 10 mV hyperpolarized from the resting level. This change in resting membrane potential with length may account for the length dependence of calcium release.