Demonstration of the phosphorylation of dihydropyridine-sensitive calcium channels in chick skeletal muscle and the resultant activation of the channels after reconstitution.

We have examined the effects of cAMP elevating agents on the phosphorylation of dihydropyridine-sensitive Ca2+ channels in intact newborn chick skeletal muscle. In situ treatment with the beta-adrenergic receptor agonist isoproterenol resulted in the phosphorylation of the 170-kDa alpha 1 subunit in the intact cells, as evidenced by a marked decrease in the ability of the alpha 1 peptide to serve as a substrate in in vitro back phosphorylation reactions with [gamma-32P]ATP and the purified catalytic subunit of cAMP-dependent protein kinase. The phosphorylation of the 52-kDa beta subunit was not affected. The effects of isoproterenol were time- and concentration-dependent and were mimicked by other cAMP elevating agents but not by the Ca2+ ionophore A23187 or a protein kinase C activator. To test for functional effects of the observed phosphorylation, purified channels were reconstituted into liposomes containing entrapped fluo-3, and depolarization-sensitive and dihydropyridine-sensitive Ca2+ influx was measured. Channels from isoproterenol-treated muscle exhibited an increased rate and extent of Ca2+ influx compared to control preparations. The effects of isoproterenol pretreatment could be mimicked by phosphorylating the channels with cAMP-dependent protein kinase in vitro. These results demonstrate that the alpha 1 subunit of the dihydropyridine-sensitive Ca2(+)-channels is the primary target of cAMP-dependent phosphorylation in intact muscle and that the phosphorylation of this protein leads to activation of channel activity.     

Mechanism of voltage-dependent gating in skeletal muscle chloride channels.

Voltage-dependent gating was investigated in a recombinant human skeletal muscle Cl- channel, hCIC-1, heterologously expressed in human embryonic kidney (HEK-293) cells. Gating was found to be mediated by two qualitatively distinct processes. One gating step operates on a microsecond time scale and involves the rapid rearrangement of two identical intramembranous voltage sensors, each consisting of a single titratable residue. The second process occurs on a millisecond time scale and is due to a blocking-unblocking reaction mediated by a cytoplasmic gate that interacts with the ion pore of the channel. These results illustrate a rather simple structural basis for voltage sensing that has evolved in skeletal muscle Cl- channels and provides evidence for the existence of a cytoplasmic gating mechanism in an anion channel analogous to the "ball and chain" mechanism of voltage-gated cation channels.     

Dihydropyridine-sensitive calcium channels from skeletal muscle. I. Roles of subunits in channel activity.

Dihydropyridine-sensitive Ca2+ channels from skeletal muscle are hetero-oligomeric proteins. Little is known about the functional roles of the various subunits, except that the alpha 1 subunit is the essential channel unit. We have reconstituted both partially purified holomeric channels and the separated subunits into liposomes and measured their properties using an assay based on the Ca2+ indicator dye fluo-3. The holomeric channels exhibited Ca2+ influx that was sensitive to membrane potential achieved by the addition of valinomycin in the presence of a K+ gradient. Dissipation of the K+ gradient resulted in the loss of the valinomycin-sensitive Ca2+ flux. In addition, the reconstituted channels were: 1) activated by the dihydropyridine Ca2+ channel activator Bay K 8644 in a dose-dependent manner with a Kd of 20 nM; 2) inhibited by various types of Ca2+ channel inhibitors including the dihydropyridine (+)-PN 200-110, the phenylalkylamine verapamil, and the benzothiazepine d-cis-diltiazem; and 3) modulated in a stereoselective manner by the enantiomers of the dihydropyridine S-202-791. The purified channels used in this work possessed an alpha 1 subunit of 165 kDa and did not appear to contain a larger alpha 1 subunit of approximately 210 kDa, suggesting that channel activity with properties similar to those observed in intact cells can be supported with an alpha 1 subunit of 165 kDa. Reconstituted channels that were 85% depleted in the alpha 2/delta subunits showed a significant decrease in the initial rate of Ca2+ influx induced by valinomycin, but retained responsiveness to Bay K 8644 and (+)-PN 200-110. When the separated alpha 2 and delta subunits were added back to the alpha 1 subunit-containing preparation, the channels exhibited their normal rate of Ca2+ influx. These results demonstrated that the dihydropyridine-sensitive Ca2+ channels from skeletal muscle require the presence of the alpha 2.gamma complex in stoichiometric amounts to exhibit full activity.     

Sodium channel gating currents in frog skeletal muscle

Charge movements similar to those attributed to the sodium channel gating mechanism in nerve have been measured in frog skeletal muscle using the vaseline-gap voltage-clamp technique. The time course of gating currents elicited by moderate to strong depolarizations could be well fitted by the sum of two exponentials. The gating charge exhibits immobilization: at a holding potential of -90 mV the proportion of charge that returns after a depolarizing prepulse (OFF charge) decreases with the duration of the prepulse with a time course similar to inactivation of sodium currents measured in the same fiber at the same potential. OFF charge movements elicited by a return to more negative holding potentials of -120 or -150 mV show distinct fast and slow phases. At these holding potentials the total charge moved during both phases of the gating current is equal to the ON charge moved during the preceding prepulse. It is suggested that the slow component of OFF charge movement represents the slower return of charge "immobilized" during the prepulse. A slow mechanism of charge immobilization is also evident: the maximum charge moved for a strong depolarization is approximately doubled by changing the holding potential from -90 to -150 mV. Although they are larger in magnitude for a -150-mV holding potential, the gating currents elicited by steps to a given potential have similar kinetics whether the holding potential is -90 or -150 mV.     

Multiple conductance levels of the dihydropyridine-sensitive calcium channel in GH3 cells

Summary Calcium channels in GH₃ cells exhibit at least five conductance levels when examined in cell-attached or outside-out patches. These channels resemble the high threshold Ca²⁺ current in their range of activation and inactivation, and in their sensitivity to dihydropyridines (DHP). Mean open times for the five levels were brief (<1 msec) in control solutions but increased in the presence of BAY K 8644. In 100mm Ba²⁺ and BAY K 8644, the five predominant slope conductances were 8–9, 12–13, 16–18, 23–24, and 28 pS. The present study is the first report of multiple levels of the DHP-sensitive Ca²⁺ channel occurring with high frequency in native membranes. The range of conductance levels that we observed encompasses the range of conductances found for two other different types of Ca²⁺ channels and indicates that unit conductance should be used with caution as a distinguishing characteristic for identification of different channel types.     

Membrane stretch affects gating modes of a skeletal muscle sodium channel.

The alpha subunit of the human skeletal muscle Na(+) channel recorded from cell-attached patches yielded, as expected for Xenopus oocytes, two current components that were stable for tens of minutes during 0.2 Hz stimulation. Within seconds of applying sustained stretch, however, the slower component began decreasing and, depending on stretch intensity, disappeared in 1-3 min. Simultaneously, the faster current increased. The resulting fast current kinetics and voltage sensitivity were indistinguishable from the fast components 1) left after 10 Hz depolarizations, and 2) that dominated when alpha subunit was co-expressed with human beta1 subunit. Although high frequency depolarization-induced loss of slow current was reversible, the stretch-induced slow-to-fast conversion was irreversible. The conclusion that stretch converted a single population of alpha subunits from an abnormal slow to a bona fide fast gating mode was confirmed by using gigaohm seals formed without suction, in which fast gating was originally absent. For brain Na(+) channels, co-expressing G proteins with the channel alpha subunit yields slow gating. Because both stretch and beta1 subunits induced the fast gating mode, perhaps they do so by minimizing alpha subunit interactions with G proteins or with other regulatory molecules available in oocyte membrane. Because of the possible involvement of oocyte molecules, it remains to be determined whether the Na(+) channel alpha subunit was directly or secondarily susceptible to bilayer tension.     

Dihydropyridine-sensitive calcium channels from skeletal muscle. II. Functional effects of differential phosphorylation of channel subunits.

Dihydropyridine-sensitive Ca2+ channels from skeletal muscle are multisubunit proteins and are regulated by protein phosphorylation. The purpose of this study was to determine: 1) which subunits are the preferential targets of various protein kinases when the channels are phosphorylated in vitro in their native membrane-bound state and 2) the consequences of these phosphorylations in functional assays. Using as substrates channels present in purified transverse (T) tubule membranes, cAMP-dependent protein kinase (PKA), protein kinase C (PKC), and a multifunctional Ca2+/calmodulin-dependent protein kinase (CaM protein kinase) preferentially phosphorylated the 165-kDa alpha 1 subunit to an extent that was 2-5-fold greater than the 52-kDa beta subunit. A protein kinase endogenous to the skeletal muscle membranes preferentially phosphorylated the beta peptide and showed little activity toward the alpha 1 subunit; however, the extent of phosphorylation was low. Reconstitution of partially purified channels into liposomes was used to determine the functional consequences of phosphorylation by these kinases. Phosphorylation of channels by PKA or PKC resulted in an activation of the channels that was observed as increases in both the rate and extent of Ca2+ influx. However, phosphorylation of channels by either the CaM protein kinase or the endogenous kinase in T-tubule membranes was without effect. Phosphorylation did not affect the sensitivities of the channels toward the dihydropyridines. Taken together, the results demonstrate that the alpha 1 subunit is the preferred substrate of PKA, PKC, and CaM protein kinase when the channels are phosphorylated in the membrane-bound state and that phosphorylation of the channels by PKA and PKC, but not by CaM protein kinase or an endogenous T-tubule membrane protein kinase, results in activation of the dihydropyridine-sensitive Ca2+ channels from skeletal muscle.     

Identification of two distinct proteins that are immunologically related to the alpha 1 subunit of the skeletal muscle dihydropyridine-sensitive calcium channel.

The alpha 1 subunit of the dihydropyridine-sensitive calcium channel is a protein which is critical for excitation-contraction coupling and L-type calcium current in skeletal muscle. Using antibodies generated against peptides from three regions of the deduced amino acid sequence of the alpha 1 subunit, we have identified two distinct proteins in rabbit skeletal muscle. Both proteins appeared to be recognized by antibodies against the amino (N) terminus of the alpha 1 subunit sequence. One protein was also recognized by antibodies against an internal (I) region of the predicted sequence but not by antibodies against the carboxyl (C) terminus. In contrast, the other protein was recognized by antibodies against the carboxyl terminus but not by the antibodies against the internal region. We have designated these proteins pNI and pNC based on their patterns of antibody recognition. No protein was detected which was recognized by all three antibodies. pNI is the protein commonly identified as the alpha 1 subunit of the dihydropyridine-sensitive calcium channel. Of note is that pNI, which apparently lacks sequences from the predicted carboxyl tail, is the protein present in preparations which we have previously demonstrated contain dihydropyridine-sensitive calcium channel activity. pNC is herein identified as a skeletal muscle protein that is immunologically related to the alpha 1 subunit of the dihydropyridine-sensitive calcium channel. Its function is unknown. In addition to their distinct patterns of antibody recognition, pNI and pNC were also distinguishable by several other properties. pNC migrated as a protein of approximately 160 kDa in 5% sodium dodecyl sulfate-polyacrylamide gels versus approximately 165 kDa for pNI. pNI was enriched in transverse tubule membranes, whereas pNC was found to be enriched in triad and junctional sarcoplasmic reticulum membrane fractions and was not found in transverse tubule membranes. Under conditions in which pNI bound to wheat germ agglutinin-Sepharose, pNC did not bind. The results demonstrate that there are two proteins in skeletal muscle which are immunologically related to the alpha 1 subunit of the dihydropyridine-sensitive calcium channel but which are distinguishable by several biochemical and immunological characteristics.     

Multiple phosphorylation sites in the 165-kilodalton peptide associated with dihydropyridine-sensitive calcium channels

Evidence from electrophysiological and ion flux studies has established that dihydropyridine-sensitive calcium channels are subject to regulation by neurotransmitter-mediated phosphorylation and dephosphorylation reactions. In the present study, we have further characterized the phosphorylation by cAMP-dependent protein kinase and a multifunctional Ca/calmodulin-dependent protein kinase of the membrane-associated form of the 165-kDa polypeptide identified as the skeletal muscle dihydropyridine receptor. The initial rates of phosphorylation of the 165-kDa peptide by both protein kinases were found to be relatively good compared to the rates of phosphorylation of established substrates of the enzymes. Phosphorylation of the 165-kDa peptide by both protein kinases was additive. Prior phosphorylation by either one of the kinases alone did not preclude phosphorylation by the second kinase. The cAMP-dependent protein kinase phosphorylated the 165-kDa peptide preferentially at serine residues, although a small amount of phosphothreonine was also formed. In contrast, after phosphorylation of the 165-kDa peptide by the Ca/calmodulin-dependent protein kinase, slightly more phosphothreonine than phosphoserine was recovered. Phosphopeptide mapping indicated that the two kinases phosphorylated the peptide at distinct as well as similar sites. Notably, one major site phosphorylated by the cAMP-dependent protein kinase was not phosphorylated by the Ca/calmodulin-dependent protein kinase, while other sites were phosphorylated to a high degree by the Ca/calmodulin-dependent protein kinase, but to a much lesser degree by the cAMP-dependent protein kinase. The results show that the 165-kDa dihydropyridine receptor from skeletal muscle can be multiply phosphorylated at distinct sites by the cAMP- and Ca/calmodulin-dependent protein kinases. As the 165-kDa peptide may be the major functional unit of the dihydropyridine-sensitive Ca channel, the results suggest that the phosphorylation-dependent modulation of Ca channel activity by neurotransmitters may involve phosphorylation of the 165-kDa peptide at multiple sites.     

The dihydropyridine-sensitive calcium channel subtype in cone photoreceptors

High-voltage activated Ca channels in tiger salamander cone photoreceptors were studied with nystatin-permeabilized patch recordings in 3 mM Ca2+ and 10 mM Ba2+. The majority of Ca channel current was dihydropyridine sensitive, suggesting a preponderance of L- type Ca channels. However, voltage-dependent, incomplete block (maximum 60%) by nifedipine (0.1-100 microM) was evident in recordings of cones in tissue slice. In isolated cones, where the block was more potent, nifedipine (0.1-10 microM) or nisoldipine (0.5-5 microM) still failed to eliminate completely the Ca channel current. Nisoldipine was equally effective in blocking Ca channel current elicited in the presence of 10 mM Ba2+ (76% block) or 3 mM Ca2+ (88% block). 15% of the Ba2+ current was reversibly blocked by omega-conotoxin GVIA (1 microM). After enhancement with 1 microM Bay K 8644, omega-conotoxin GVIA blocked a greater proportion (22%) of Ba2+ current than in control. After achieving partial block of the Ba2+ current with nifedipine, concomitant application of omega-conotoxin GVIA produced no further block. The P-type Ca channel blocker, omega-agatoxin IVA (200 nM), had variable and insignificant effects. The current persisting in the presence of these blockers could be eliminated with Cd2+ (100 microM). These results indicate that photoreceptors express an L-type Ca channel having a distinguishing pharmacological profile similar to the alpha 1D Ca channel subtype. The presence of additional Ca channel subtypes, resistant to the widely used L-, N-, and P-type Ca channel blockers, cannot, however, be ruled out.     

Cytoplasmic ATP-sensing domains regulate gating of skeletal muscle ClC-1 chloride channels

ClC proteins are a family of chloride channels and transporters that are found in a wide variety of prokaryotic and eukaryotic cell types. The mammalian voltage-gated chloride channel ClC-1 is important for controlling the electrical excitability of skeletal muscle. Reduced excitability of muscle cells during metabolic stress can protect cells from metabolic exhaustion and is thought to be a major factor in fatigue. Here we identify a novel mechanism linking excitability to metabolic state by showing that ClC-1 channels are modulated by ATP. The high concentration of ATP in resting muscle effectively inhibits ClC-1 activity by shifting the voltage gating to more positive potentials. ADP and AMP had similar effects to ATP, but IMP had no effect, indicating that the inhibition of ClC-1 would only be relieved under anaerobic conditions such as intense muscle activity or ischemia, when depleted ATP accumulates as IMP. The resulting increase in ClC-1 activity under these conditions would reduce muscle excitability, thus contributing to fatigue. We show further that the modulation by ATP is mediated by cystathionine beta-synthase-related domains in the cytoplasmic C terminus of ClC-1. This defines a function for these domains as gating-modulatory domains sensitive to intracellular ligands, such as nucleotides, a function that is likely to be conserved in other ClC proteins.     

Identification of putative calcium channels in skeletal muscle microsomes

Saturable binding sites for the labelled calcium antagonist (+/-)[3H]nimodipine were found in guinea-pig hind limb skeletal muscle homogenates. Binding sites were enriched in a microsomal pellet by differential centrifugation of the homogenate. [3H]Nimodipine binding (Kd = 1.5 +/- 0.03 nM, Bmax = 2.1 +/- 0.25 pmol/protein, at 37 degrees C) copurified (6-fold) in this fraction with [3H]ouabain binding (6.6-fold) and 125I-alpha-bungarotoxin binding (5-fold). d-cis-Diltiazem (but not 1-cis-diltiazem) stimulated (+/-) [3H]nimodipine binding (ED50 1 microM) by increasing the Bmax. Binding sites discriminated between the optical enantiomers of 1.4-dihydropyridine calcium antagonists and the optically pure enantiomers of D-600. The data confirm, with biochemical techniques, the presence of 1,4-dihydropyridine and (+/-) D-600 inhibitable calcium channels in skeletal muscle, previously found with electrophysiological techniques.     

Single calcium channel behavior in native skeletal muscle

The purpose of this study was to use whole-cell and cell-attached patches of cultured skeletal muscle myotubes to study the macroscopic and unitary behavior of voltage-dependent calcium channels under similar conditions. With 110 mM BaCl2 as the charge carrier, two types of calcium channels with markedly different single-channel and macroscopic properties were found. One class was DHP-insensitive, had a single-channel conductance of approximately 9 pS, yielded ensembles that displayed an activation threshold near -40 mV, and activated and inactivated rapidly in a voltage-dependent manner (T current). The second class could only be well resolved in the presence of the DHP agonist Bay K 8644 (5 microM) and had a single-channel conductance of approximately 14 pS (L current). The 14-pS channel produced ensembles exhibiting a threshold of approximately -10 mV that activated slowly (tau act approximately 20 ms) and displayed little inactivation. Moreover, the DHP antagonist, (+)-PN 200-110 (10 microM), greatly increased the percentage of null sweeps seen with the 14-pS channel. The open probability versus voltage relationship of the 14-pS channel was fitted by a Boltzmann distribution with a VP0.5 = 6.2 mV and kp = 5.3 mV. L current recorded from whole-cell experiments in the presence of 110 mM BaCl2 + 5 microM Bay K 8644 displayed similar time- and voltage-dependent properties as ensembles of the 14-pS channel. Thus, these data are the first comparison under similar conditions of the single-channel and macroscopic properties of T current and L current in native skeletal muscle, and identify the 9- and 14-pS channels as the single-channel correlates of T current and L current, respectively.     

Modulation of dihydropyridine-sensitive gastric mucosal calcium channels by GM1-ganglioside.

1. A dihydropyridine-sensitive calcium channel complex was solubilized from gastric mucosal cell membranes and purified by affinity chromatography on wheat germ agglutinin. 2. The calcium channel complex labeled with [3H]PN200-110, when reconstituted into phosphatidylcholine vesicles, exhibited active 45Ca2+ uptake into intravesicular space as evidenced by La3+ displacement and osmolarity studies. The channel complex responded in a dose-dependent manner to dihydropyridine calcium antagonist, PN200-110, which at 0.5 microM exerted maximal inhibitory effect of 66% in 45Ca2+ uptake. 3. The uptake of 45Ca2+ into vesicle-reconstituted gastric mucosal calcium channel complex was inhibited by GM1-ganglioside. Maximum inhibitory effect was achieved at 10-15 nM GM1, at which point a 74% decrease in 45Ca2+ uptake occurred. Furthermore, GM1 also inhibited dihydropyridine binding to gastric mucosal membranes, indicating the extracellular orientation of calcium channel domains for GM1. 4. The ability of GM1 to modulate the intracellular calcium levels may be an important feature in gastric mucosal protection by this ganglioside.     

Modulation of dihydropyridine-sensitive calcium channels in Drosophila by a cAMP-mediated pathway.

Drosophila has proved to be a valuable system for studying the structure and function of ion channels. However, relatively little is known about the regulation of ion channels, particularly that of Ca2+ channels, in Drosophila. Physiological and pharmacological differences between invertebrate and mammalian L-type Ca2+ channels raise questions on the extent of conservation of Ca2+ channel modulatory pathways. We have examined the role of cyclic adenosine monophosphate (cAMP) cascade in modulating the dihydropyridine (DHP)-sensitive Ca2+ channels in the larval muscles of Drosophila, using mutations and drugs that disrupt specific steps in this pathway. The L-type (DHP-sensitive) Ca2+ channel current was increased in the dunce mutants, which have high cAMP concentration owing to cAMP-specific phosphodiesterase (PDE) disruption. The current was decreased in the rutabaga mutants, where adenylyl cyclase (AC) activity is altered thereby decreasing the cAMP concentration. The dunce effect was mimicked by 8-Br-cAMP, a cAMP analog, and IBMX, a PDE inhibitor. The rutabaga effect was rescued by forskolin, an AC activator. H-89, an inhibitor of protein kinase-A (PKA), reduced the current and inhibited the effect of 8-Br-cAMP. The data suggest modulation of L-type Ca2+ channels of Drosophila via a cAMP-PKA mediated pathway. While there are differences in L-type channels, as well as in components of cAMP cascade, between Drosophila and vertebrates, main features of the modulatory pathway have been conserved. The data also raise questions on the likely role of DHP-sensitive Ca2+ channel modulation in synaptic plasticity, and learning and memory, processes disrupted by the dnc and the rut mutations.     

Multiple dilator pathways in skeletal muscle contraction-induced arteriolar dilations

To determine whether nitric oxide (NO), adenosine (Ado) receptors, or ATP-sensitive potassium (K(ATP)) channels play a role in arteriolar dilations induced by muscle contraction, we used a cremaster preparation in anesthetized hamsters in which we stimulated four to five muscle fibers lying perpendicular to a transverse arteriole (maximal diameter approximately 35-65 microm). The diameter of the arteriole at the site of overlap of the stimulated muscle fibers (the local site) and at a remote site approximately 1,000 microm upstream (the upstream site) was measured before, during, and after muscle contraction. Two minutes of 4-Hz muscle stimulation (5-15 V, 0.4 ms) produced local and upstream dilations of 19 +/- 1 and 10 +/- 1 microm, respectively. N(omega)-nitro-L-arginine (10(-4) M; NO synthase inhibitor), xanthine amine congener (XAC; 10(-6) M; Ado A(1), A(2A), and A(2B) receptor antagonist), or glibenclamide (Glib; 10(-5) M; K(ATP) channel inhibitor) superfused over the preparation attenuated the local dilation (by 29.7 +/- 12.7, 61.8 +/- 9.0, and 51.9 +/- 14.9%, respectively), but only XAC and Glib attenuated the upstream dilation (by 68.9 +/- 6.8 and 89.1 +/- 6.4%, respectively). Furthermore, only Glib, when applied to the upstream site directly, attenuated the upstream dilation (48.1 +/- 9.1%). Neither XAC nor Glib applied directly to the arteriole between the local and the upstream sites had an effect on the magnitude of the upstream dilation. We conclude that NO, Ado receptors, and K(ATP) channels are involved in the local dilation initiated by contracting muscle and that both K(ATP) channels and Ado receptor stimulation, but not NO, play a role in the manifestation of the dilation at the upstream site.