Modulation of calcium current gating in frog skeletal muscle by conditioning depolarization

Ca2+/CaM-dependent inactivation of the skeletal muscle L-type Ca2+ channel (Cav1.1)

Ca2+-dependent modulation via calmodulin (CaM) has been documented for most high-voltage-activated Ca2+ channels, but whether the skeletal muscle L-type channel (Cav1.1) exhibits this property has been unknown. In this paper, whole-cell current and fluorescent resonance energy transfer (FRET) recordings were obtained from cultured mouse myotubes to test for potential involvement of CaM in function of Cav1.1. When prolonged depolarization (800 ms) was used to evoke Cav1.1 currents in normal myotubes, the fraction of current remaining at the end of the pulse displayed classic signs of Ca2+-dependent inactivation (CDI), including U-shaped voltage dependence, maximal inactivation (approximately 30%) at potentials eliciting maximal inward current, and virtual elimination of inactivation when Ba2+ replaced external Ca2+ or when 10 mM BAPTA was included in the pipette solution. Furthermore, CDI was virtually eliminated (from 30 to 8%) in normal myotubes overexpressing mutant CaM (CaM1234) that does not bind Ca2+, whereas CDI was unaltered in myotubes overexpressing wild-type CaM (CaMwt). In addition, a significant FRET signal (E=4.06%) was detected between fluorescently tagged Cav1.1 and CaMwt coexpressed in dysgenic myotubes, demonstrating for the first time that these two proteins associate in vivo. These findings show that CaM associates with and modulates Cav1.1.

Functional roles of the gamma subunit of the skeletal muscle DHP-receptor

In excitation-contraction coupling (EC coupling) of skeletal muscle, large and rapid changes of the myoplasmic Ca2+ concentration mediate the activation and termination of force. The L-type Ca2+ channel (dihydropyridine receptor, DHP receptor) is a central component of the EC coupling process. Its predominant role is to provide the Ca2+ release channels of the sarcoplasmic reticulum (SR) with the sensitivity to cell membrane voltage. The DHP receptor consists of five different proteins (alpha1S, beta1, gamma1, delta and alpha2) whose tasks and functional characteristics are still incompletely understood. This short review summarizes progress made in studying the physiology of the gamma1 subunit, a membrane polypeptide that is highly specific for skeletal muscle. The focus is on recent results obtained from muscle of gamma1-deficient mice.

Convergent regulation of skeletal muscle Ca2+ channels by dystrophin, the actin cytoskeleton, and cAMP-dependent protein kinase

The skeletal muscle L-type Ca2+ channel (Ca(V)1.1), which is responsible for initiating muscle contraction, is regulated by phosphorylation by cAMP-dependent protein kinase (PKA) in a voltage-dependent manner that requires direct physical association between the channel and the kinase mediated through A-kinase anchoring proteins (AKAPs). The role of the actin cytoskeleton in channel regulation was investigated in skeletal myocytes cultured from wild-type mice, mdx mice that lack the cytoskeletal linkage protein dystrophin, and a skeletal muscle cell line, 129 CB3. Voltage dependence of channel activation was shifted positively, and potentiation was greatly diminished in mdx myocytes and in 129 CB3 cells treated with the microfilament stabilizer phalloidin. Voltage-dependent potentiation by strong depolarizing prepulses was reduced in mdx myocytes but could be restored by positively shifting the stimulus potentials to compensate for the positive shift in the voltage dependence of gating. Inclusion of PKA in the pipette caused a negative shift in the voltage dependence of activation and restored voltage-dependent potentiation in mdx myocytes. These results show that skeletal muscle Ca2+ channel activity and voltage-dependent potentiation are controlled by PKA and microfilaments in a convergent manner. Regulation of Ca2+ channel activity by hormones and neurotransmitters that use the PKA signal transduction pathway may interact in a critical way with the cytoskeleton and may be impaired by deletion of dystrophin, contributing to abnormal regulation of intracellular calcium concentrations in dystrophic muscle.

Prolonged depolarization promotes fast gating kinetics of L-type Ca2+ channels in mouse skeletal myotubes

The effects of prolonged conditioning depolarizations on the activation kinetics of skeletal L-type calcium currents (L-currents) were characterized in mouse myotubes using the whole-cell patch clamp technique. The sum of two exponentials was required to adequately fit L-current activation and enabled determination of both the amplitudes (A(fast) and A(slow)) and time constants (tau(fast) and tau(slow)) of each component comprising the macroscopic current. Prepulses sufficient to activate (200 ms) or inactivate (10 s) L-channels did not alter tau(fast), tau(slow), or the fractional contribution of either the fast (A(fast)/(A(fast) + A(slow)) or slow (A(slow)/(A(fast) + A(slow))) amplitudes of subsequently activated L-currents. Prolonged depolarizations (60 s to +40 mV) resulted in the conversion of skeletal L-current to a fast gating mode following brief repriming intervals (3-10 s at -80 mV). Longer repriming intervals (30-60 s at -80 mV) restored L-channels to a predominantly slow gating mode. Accelerated L-currents originated from L-type calcium channels since they were completely blocked by a dihydropyridine antagonist (3 microM nifedipine) and exhibited a voltage dependence of activation similar to that observed in the absence of conditioning prepulses. The degree of L-current acceleration produced following prolonged depolarization was voltage dependent. For test potentials between +10 and +50 mV, the fractional contribution of Afast to the total current decreased exponentially with the test voltage (e-fold approximately 38 mV). Thus, L-current acceleration was most significant at more negative test potentials (e.g. +10 mV). Prolonged depolarization also accelerated L-currents recorded from myotubes derived from RyR1-knockout (dyspedic) mice. These results indicate that L-channel acceleration occurs even in the absence of RyR1, and is therefore likely to represent an intrinsic property of skeletal L-channels. The results describe a novel experimental protocol used to demonstrate that slowly activating mammalian skeletal muscle L-channels are capable of undergoing rapid, voltage-dependent transitions during channel activation. The transitions underlying rapid L-channel activation may reflect rapid transitions of the voltage sensor used to trigger the release of calcium from the sarcoplasmic reticulum during excitation-contraction coupling.

Kinetics of inactivation and restoration from inactivation of the L-type calcium current in human myotubes

1. Inactivation and recovery kinetics of L-type calcium currents were measured in myotubes derived from satellite cells of human skeletal muscle using the whole cell patch clamp technique. 2. The time course of inactivation at potentials above the activation threshold was obtained from the decay of the current during 15 s depolarizing pulses. At subthreshold potentials, prepulses of different durations, followed by +20 mV test pulses, were used. The time course could be well described by single exponential functions of time. The time constant decreased from 17.8 +/- 7.5 s at -30 mV to 1.78 +/- 0.15 s at +50 mV. 3. Restoration from inactivation caused by 15 s depolarization to +20 mV was slowed by depolarization in the restoration interval. The time constant increased from 1.11 +/- 0.17 s at -90 mV to 7.57 +/- 2.54 s at -10 mV. 4. Restoration showed different kinetics depending on the duration of the conditioning depolarization. While the time constant was similar at restoration potentials of -90 and -50 mV after a 1 s conditioning prepulse, it increased with increasing prepulse duration at -50 mV and decreased at -90 mV. 5. The experiments showed that the rates of inactivation and restoration of the L-type calcium current in human myotubes were not identical when observed at the same potential. The results indicate the presence of more than one inactivated state and point to different voltage-dependent pathways for inactivation and restoration.

Effect of nifedipine on depolarization-induced force responses in skinned skeletal muscle fibres of rat and toad

The effect of the dihydropyridine, nifedipine, on excitation-contraction coupling was compared in toad and rat skeletal muscle, using the mechanically skinned fibre technique, in order to understand better the apparently disparate results of previous studies and to examine recent proposals on the importance of certain intracellular factors in determining the efficacy of dihydropyridines. In twitch fibres from the iliofibularis muscle of the toad, 10 microM nifedipine completely inhibited depolarization-induced force responses within 30 s, without interfering with direct activation of the Ca(2+)-release channels by caffeine application or reduction of myoplasmic [Mg2+]. At low concentrations of nifedipine, inhibition was considerably augmented by repeated depolarizations, with half-maximal inhibition occurring at < 0.1 microM nifedipine. In contrast, in rat extensor digitorum longus (EDL) fibres 1 microM nifedipine had virtually no effect on depolarization-induced force responses, and 10 microM nifedipine caused only approximately 25% reduction in the responses, even upon repeated depolarizations. In rat fibres, 10 microM nifedipine shifted the steady-state force inactivation curve to more negative potentials by < 11 mV, whereas in toad fibres the potent inhibitory effect of nifedipine indicated a much larger shift. The inhibitory effect of nifedipine in rat fibres was little, if at all, increased by the absence of Ca2+ in the transverse tubular (t-) system, provided that the Ca2+ was replaced with sufficient Mg2+. The presence of the reducing agents dithiothreitol (10 mM) or glutathione (10 mM) in the solution bathing a toad skinned fibre did not reduce the inhibitory effect of nifedipine, suggesting that the potency of nifedipine in toad skinned fibres was not due to the washout of intracellular reducing agents. The results are considered in terms of a model that can account for the markedly different effects of nifedipine on the two putative functions of the dihydropyridine receptor, as both t-system calcium channel and a voltage-sensor controlling Ca2+ release.

Depolarization-induced facilitation of a plateau-generating current in ventral horn neurons in the turtle spinal cord

Plasticity at the neuronal level commonly involves use-dependent changes in strength of particular synaptic pathways or regulation of postsynaptic properties by modulatory transmitters. Here we analyze a novel form of short-term plasticity mediated by use-dependent facilitation of postsynaptic responsiveness. Using current- and voltage-clamp recordings, we found that all spinal ventral horn neurons able to generate plateau potentials showed depolarization-induced facilitation of the underlying inward current. Facilitation was noticeable when the neurons were depolarized to more than -50 mV at intervals <4 s. When stimulation with fast triangular voltage ramps was used, the inward current activated at a less depolarized potential during the second ramp. The inward current and facilitation was eliminated by nifedipine, a selective antagonist of L-type calcium channels. Depolarization-induced facilitation of low-voltage-activated L-type calcium channels is suggested to be the underlying mechanism. It is noted that facilitation occurs on a time scale compatible with a role in phasic motor activity.

L-type calcium current activation in cultured human myotubes

The time course of activation of the skeletal muscle L-type calcium channel was studied in voltage-clamped myotubes derived from human satellite cells. The slow L-type current was isolated by inactivating faster calcium current components using appropriate prepulses or by subtracting the currents not blocked by 5 microM nifedipine. The L-type current exhibited a single exponential activation and time constants which showed little voltage dependence in the range +10 to +50mV. Currents blocked by nifedipine could be partially restored by UV-light flash photolysis. When a flash of light was applied during a depolarizing step, the activation time course of the resulting inward current contained a rapid, almost instantaneous component followed by a slower component. The amplitude of the rapid component was different when the flash was applied at different times during the depolarizing step: depolarization first increased and then decreased the fraction of channels which could rapidly be restored from the block by photolysis. Plotted versus time after the onset of the depolarization this fraction closely matched the time course of the L-type current obtained before the block by nifedipine. This indicates that the slow gating recations of the Ca2+ channel remain functional in the nifedipine-blocked state. Large conditioning depolarizations which had been shown to enhance the speed of L-type current activation in frog muscle fibres showed no effect in human myotubes. Numerical simulations using a gating scheme proposed for frog muscle demonstrate that such differences can be caused by changing just a single kinetic parameter.

Voltage-dependent modulation of T-type calcium channels by protein tyrosine phosphorylation

A T-type Ca2+ channel is expressed during differentiation of the male germ lineage in the mouse and is retained in sperm, where is it activated by contact with the the egg's extracellular matrix and controls sperm acrosomal exocytosis. Here, we examine the regulation of this Ca2+ channel in dissociated spermatogenic cells from the mouse using the whole-cell patch-clamp technique. T currents were enhanced, or facilitated, after strong depolarizations or high frequency stimulation. Voltage-dependent facilitation increased the Ca2+ current by an average of 50%. The same facilitation is produced by antagonists of protein tyrosine kinase activity. Conversely, antagonists of tyrosine phosphatase activity block voltage-dependent facilitation of the current. These data are consistent with the presence of a two-state model, in which T channels are maintained in a low (or zero) conductance state by tonic tyrosine phosphorylation and can be activated to a high conductance state by a tyrosine phosphatase activity. The positive and negative modulation of this channel by the tyrosine phosphorylation state provides a plausible mechanism for the control of sperm activity during the early stages of mammalian fertilization.

Modulation of the cloned skeletal muscle L-type Ca2+ channel by anchored cAMP-dependent protein kinase

Ca2+ influx through skeletal muscle Ca2+ channels and the force of contraction are increased in response to beta-adrenergic stimulation and high-frequency electrical stimulation. These effects are thought to be mediated by cAMP-dependent phosphorylation of the skeletal muscle Ca2+ channel. Modulation of the cloned skeletal muscle Ca2+ channel by cAMP-dependent phosphorylation and by depolarizing prepulses was reconstituted by transient expression in tsA-201 cells and compared to modulation of the native skeletal muscle Ca2+ channel as expressed in mouse 129CB3 skeletal muscle cells. The heterologously expressed Ca2+ channel consisting of alpha1, alpha2delta, and beta subunits gave currents that were similar in time course, current density, and dihydropyridine sensitivity to the native Ca2+ channel. cAMP-dependent protein kinase (PKA) stimulation by Sp-5,6-DCl-cBIMPS (cBIMPS) increased currents through both native and expressed channels two- to fourfold. Tail currents after depolarizations to potentials between -20 and +80 mV increased in amplitude and decayed more slowly as either the duration or potential of the depolarization was increased. The time- and voltage-dependent slowing of channel deactivation required the activity of PKA, because it was enhanced by cBIMPS and reduced or eliminated by the peptide PKA inhibitor PKI (5-24) amide. This voltage-dependent modulation of the cloned skeletal muscle Ca2+ channel by PKA also required anchoring of PKA by A-Kinase Anchoring Proteins because it was blocked by peptide Ht 31, which disrupts such anchoring. The results show that the skeletal muscle Ca2+ channel expressed in heterologous cells is modulated by PKA at rest and during depolarization and that this modulation requires anchored protein kinase, as it does in native skeletal muscle cells.

Modulation of the cloned skeletal muscle L-type Ca2+ channel by anchored cAMP-dependent protein kinase

Ca2+ influx through skeletal muscle Ca2+ channels and the force of contraction are increased in response to beta-adrenergic stimulation and high-frequency electrical stimulation. These effects are thought to be mediated by cAMP-dependent phosphorylation of the skeletal muscle Ca2+ channel. Modulation of the cloned skeletal muscle Ca2+ channel by cAMP-dependent phosphorylation and by depolarizing prepulses was reconstituted by transient expression in tsA-201 cells and compared to modulation of the native skeletal muscle Ca2+ channel as expressed in mouse 129CB3 skeletal muscle cells. The heterologously expressed Ca2+ channel consisting of alpha1, alpha2delta, and beta subunits gave currents that were similar in time course, current density, and dihydropyridine sensitivity to the native Ca2+ channel. cAMP-dependent protein kinase (PKA) stimulation by Sp-5,6-DCl-cBIMPS (cBIMPS) increased currents through both native and expressed channels two- to fourfold. Tail currents after depolarizations to potentials between -20 and +80 mV increased in amplitude and decayed more slowly as either the duration or potential of the depolarization was increased. The time- and voltage-dependent slowing of channel deactivation required the activity of PKA, because it was enhanced by cBIMPS and reduced or eliminated by the peptide PKA inhibitor PKI (5-24) amide. This voltage-dependent modulation of the cloned skeletal muscle Ca2+ channel by PKA also required anchoring of PKA by A-Kinase Anchoring Proteins because it was blocked by peptide Ht 31, which disrupts such anchoring. The results show that the skeletal muscle Ca2+ channel expressed in heterologous cells is modulated by PKA at rest and during depolarization and that this modulation requires anchored protein kinase, as it does in native skeletal muscle cells.

Activation of L-type calcium channel in twitch skeletal muscle fibres of the frog

1. The activation of the L-type calcium current (ICa) was studied in normally polarized (-100 mV) cut skeletal muscle fibres of the frog with the double Vaseline-gap voltage-clamp technique. Both external and internal solutions were Ca2+ buffered. Solutions were made in order to minimize all but the Ca2+ current. 2. The voltage-dependent components of the time course of activation were determined by two procedures: fast and slow components were evaluated by multiexponential fitting to current traces elicited by long voltage pulses (5 s) after removing inactivation; fast components were also determined by short voltage pulses having different duration (0.5-70 ms). 3. The components of deactivation were evaluated after removing the charge-movement current from the total tail current by the difference between two short (50 and 70 ms) voltage pulses to 10 mV, moving the same intramembrane charge. Two exponential components, fast and slow (time constants, 6 +/- 0.3 and 90 +/- 7 ms at -100 mV; n = 26), were found. 4. The time onset of ICa was evaluated either by multiexponential fitting to the ICa activation or by pulses of different duration to test the beginning of the 'on' and 'off' inequality. This was at about 2 ms, denoting that it was very early. 5. The time constant vs. voltage plots indicated the presence of four voltage-dependent components in the activation pathway. Various kinetic models are discussed. Models with independent transitions, like a Hodgkin-Huxley scheme, were excluded. Suitable models were a five-state sequential and a four-state cyclic with a branch scheme. The latter gave the best simulation of the data. 6. The steady-state activation curve saturated at high potentials. It had a half-voltage value of 1 +/- 0.2 mV and the opening probability was only 0.82 +/- 0.2 at 20 mV (n = 32). This result implies a larger number of functional calcium channels than was previously supposed and is in agreement with the number of dihydropyridine (DHP) receptors calculated for the tubular system.

Facilitation of Ca2+ current in excitable cells

Voltage-dependent Ca2+ channels are one of the main routes for the entry of Ca2+ into excitable cells. These channels are unique in cell-signalling terms in that they can transduce an electrical signal (membrane depolarization) via Ca2+ entry into a chemical signal, by virtue of the diverse range of intracellular Ca(2+)-dependent enzymes and processes. In a variety of cell types, currents through voltage-dependent Ca2+ channels can be increased in amplitude by a number of means. Although the term facilitation was originally defined as an increase of Ca2+ current resulting from one or a train of prepulses to depolarizing voltages, there is a great deal of overlap between facilitation by this means and enhancement by other routes, such as phosphorylation.

Calcium current reactivation after flash photolysis of nifedipine in skeletal muscle fibres of the frog

1. L-type calcium currents were activated by depolarization of cut muscle fibres of the frog. The current was blocked by the dihydropyridine compound nifedipine (5-10 microM) and reactivated by flash photolysis of the drug. 2. In the presence of nifedipine, increasing the time interval between the onset of depolarization and the flash resulted in progressively faster kinetics of the flash-induced current. This change developed with a slow time course similar to that of normal current activation. 3. A fast gating mode of the normally slow L-type channel was induced by conditioning activation (500 ms prepulses) applied 80 ms before a test step to the same potential. After block by nifedipine, flash-photolysis was carried out 40 ms before the end of the long conditioning pulse. The flash-induced current had the same rapid time course as the current activated by the subsequent test voltage step. 4. Similarly, the time course of current activation was comparable for the voltage-induced fast mode activation (flash applied 5 ms before the test step) and the flash-induced activation 40 ms after the onset of the test depolarization. 5. Our data suggest that in frog skeletal muscle nifedipine inhibits calcium current activation by blocking a rapid channel gating step while the slow conformational change that normally limits the rate of activation of the L-type calcium channel remains unaffected. UV flash illumination results in a fast reactivation indicating that the channels need not be inactivated to be blocked by nifedipine.

Involvement of dihydropyridine receptors in terminating Ca2+ release in rat skeletal myotubes

1. Combined patch-clamp and fura-2 measurements were performed in order to investigate the effect of dihydropyridine (DHP) antagonists on termination of sarcoplasmic reticulum (SR) Ca2+ release in cultured rat skeletal myoballs. 2. Ca2+ transients induced by 10 mM caffeine were curtailed by depolarization (e.g. +20 mV for 1 s) and subsequent repolarization (-70 mV). This phenomenon is termed RISC (repolarization-induced stop of caffeine-induced Ca2+ release). 3. At 0.5 to 1 microM, DHP antagonists (nifedipine or (+)PN200-110) strongly inhibited RISC and also slowed the decay of intracellular Ca2+ concentration ([Ca2+]i) following repolarization after depolarization-induced Ca2+ release (-20 or -10 mV for 5 s). 4. The activation time course of the Ca2+ channel associated with the DHP receptor (DHPR) was investigated by measuring DHP-sensitive Ca2+ channel tail currents, while varying the duration of depolarizing pulses. The tail currents increased with pulse duration and peaked around 0.7, 0.9 and 1.1 s for depolarizations to +70, +40 and +20 mV, respectively. These values are compatible with the activation time course of RISC (0.5-1 s to maximally activate RISC at +20 to +60 mV). 5. These results suggest that the DHPR in T-tubular membranes regulates closing of the ryanodine receptor (RyR)-Ca2+ release channel complex through membrane potential change.

Skeletal muscle DHP receptor mutations alter calcium currents in human hypokalaemic periodic paralysis myotubes

1. Mutations in the gene encoding the alpha 1-subunit of the skeletal muscle dihydropyridine (DHP) receptor are responsible for familial hypokalaemic periodic paralysis (HypoPP), an autosomal dominant muscle disease. We investigated myotubes cultured from muscle of patients with arginine-to-histidine substitutions in putative voltage sensors, IIS4 (R528H) and IVS4 (R1239H), of the DHP receptor alpha 1-subunit. 2. Analysis of the messenger ribonucleic acid (mRNA) in the myotubes from such patients indicated transcription from both the normal and mutant genes. 3. In control myotubes, the existence of the slow L-type current and of two rapidly activating and inactivating calcium current components (T-type with a maximum at about -20 mV and 'third type' with a maximum at +10 to +20 mV) was confirmed. In the myotubes from patients with either mutation, the third-type current component was seen more frequently and, on average, with larger amplitude. 4. In myotubes with the IVS4 mutation (R1239H) the maximum L-type current density was smaller than control (-0.53 +/- 0.31 vs. -1.41 +/- 0.71 pA pF-1). The voltage dependence of activation was normal, and hyperpolarizing prepulses to -120 mV for 20 s did not increase the reduced current amplitude during test pulses. 5. In myotubes with the IIS4 mutation (R528H) the L-type current-voltage relation, determined at a holding potential of -90 mV, was normal. However, the voltage dependence of inactivation was shifted by about 40 mV to more negative potentials (voltage at half-maximum inactivation, V1/2 = -41.5 +/- 8.2 vs. -4.9 +/- 4.3 mV in normal controls).(ABSTRACT TRUNCATED AT 250 WORDS)

Simultaneous expression of cardiac and skeletal muscle isoforms of the L-type Ca2+ channel in a rat heart muscle cell line

1. We have investigated the identity of the L-type Ca2+ channels present in the H9c2 myoblast line derived from embryonic rat ventricle. To this end, we characterized macroscopic and unitary Ba2+ currents through Ca2+ channels, and looked for specific genetic messages encoding different L-type Ca2+ channel isoforms. 2. The macroscopic Ba2+ current (recorded in 10 mM BaCl2) revealed two components with different time courses of activation. The fast component (IBa,fast) activates with a time constant of 23 +/- 12 ms (at +10 mV), while the slow component activates with a time constant of 125 +/- 12 ms (at +10 mV). 3. Single-channel recordings revealed the presence of two independent channels with conductance values of 11 and 25 pS (in 70 mM Ba2+). These values are identical to those reported previously for skeletal muscle and cardiac Ca2+ channels, respectively. 4. The mean ensemble current from the 11 pS channel reproduced the time course of the slow component observed at the macroscopic level, while the 25 pS ensemble time course paralleled that of the fast component. 5. Reverse transcriptase polymerase chain reaction (PCR) with alpha 1-isoform-specific primers revealed the presence of two distinct transcripts in H9c2 cells. The sequences of the PCR products showed a high degree of homology with the corresponding segments of the rabbit cardiac and skeletal muscle L-type Ca2+ channel isoforms. Adult rat skeletal and cardiac muscle expressed only one type of transcript. 6. H9c2 cells appear to be unique in that they simultaneously express both skeletal muscle and cardiac isoforms of the L-type Ca2+ channel alpha 1-subunit. Thus, the H9c2 cell line may prove to be useful when studying the regulation of subtype-specific Ca2+ channel gene expression.

Relationship of calcium transients to calcium currents and charge movements in myotubes expressing skeletal and cardiac dihydropyridine receptors

In both skeletal and cardiac muscle, the dihydropyridine (DHP) receptor is a critical element in excitation-contraction (e-c) coupling. However, the mechanism for calcium release is completely different in these muscles. In cardiac muscle the DHP receptor functions as a rapidly-activated calcium channel and the influx of calcium through this channel induces calcium release from the sarcoplasmic reticulum (SR). In contrast, in skeletal muscle the DHP receptor functions as a voltage sensor and as a slowly-activating calcium channel; in this case, the voltage sensor controls SR calcium release. It has been previously demonstrated that injection of dysgenic myotubes with cDNA (pCAC6) encoding the skeletal muscle DHP receptor restores the slow calcium current and skeletal type e-c coupling that does not require entry of external calcium (Tanabe, Beam, Powell, and Numa. 1988. Nature. 336:134-139). Furthermore, injection of cDNA (pCARD1) encoding the cardiac DHP receptor produces rapidly activating calcium current and cardiac type e-c coupling that does require calcium entry (Tanabe, Mikami, Numa, and Beam. 1990. Nature. 344:451-453). In this paper, we have studied the voltage dependence of, and the relationship between, charge movement, calcium transients, and calcium current in normal skeletal muscle cells in culture. In addition, we injected pCAC6 or pCARD1 into the nuclei of dysgenic myotubes and studied the relationship between the restored events and compared them with those of the normal cells. Charge movement and calcium currents were recorded with the whole cell patch-clamp technique. Calcium transients were measured with Fluo-3 introduced through the patch pipette. The kinetics and voltage dependence of the charge movement, calcium transients, and calcium current in dysgenic myotubes expressing pCAC6 were qualitatively similar to the ones elicited in normal myotubes: the calcium transient displayed a sigmoidal dependence on voltage and was still present after the addition of 0.5 mM Cd2+ + 0.1 mM La3+. In contrast, the calcium transient in dysgenic myotubes expressing pCARD1 followed the amplitude of the calcium current and thus showed a bell shaped dependence on voltage. In addition, the transient had a slower rate of rise than in pCAC6-injected myotubes and was abolished completely by the addition of Cd2+ + La3+.

A possible role of sarcoplasmic Ca2+ release in modulating the slow Ca2+ current of skeletal muscle

Ca2+ channels are regulated in a variety of different ways, one of which is modulation by the Ca2+ ion itself. In skeletal muscle, Ca2+ release sites are presumably located in the vicinity of the dihydropyridine-sensitive Ca2+ channel. In this study, we have tried to investigate the effects of Ca2+ release from the sarcoplasmic reticulum on the L-type Ca2+ channel in frog skeletal muscle, using the double Vaseline gap technique. We found an increase in Ca2+ current amplitude on application of caffeine, a well-known potentiator of Ca2+ release. Addition of the fast Ca2+ buffer BAPTA to the intracellular solution led to a gradual decline in Ca2+ current amplitude and eventually caused complete inhibition. Similar observations were made when the muscle fibre was perfused internally with the Ca2+ release channel blocker ruthenium red. The time course of Ca2+ current decline followed closely the increase in ruthenium red concentration. This suggests that Ca2+ release from the sarcoplasmic reticulum is involved in the regulation of L-type Ca2+ channels in frog skeletal muscle.