Functional analysis of a frame-shift mutant of the dihydropyridine receptor pore subunit (α1S) expressing two complementary protein fragments

Background  

The L-type Ca²⁺ channel formed by the dihydropyridine receptor (DHPR) of skeletal muscle senses the membrane voltage and opens the ryanodine receptor (RyR1). This channel-to-channel coupling is essential for Ca²⁺ signaling but poorly understood. We characterized a single-base frame-shift mutant of α_1S, the pore subunit of the DHPR, that has the unusual ability to function voltage sensor for excitation-contraction (EC) coupling by virtue of expressing two complementary hemi-Ca²⁺ channel fragments.     

The Skeletal L-type Ca2+ Current Is a Major Contributor to Excitation-coupled Ca2+ entry

The term excitation-coupled Ca²⁺ entry (ECCE) designates the entry of extracellular Ca²⁺ into skeletal muscle cells, which occurs in response to prolonged depolarization or pulse trains and depends on the presence of both the 1,4-dihydropyridine receptor (DHPR) in the plasma membrane and the type 1 ryanodine receptor in the sarcoplasmic reticulum (SR) membrane. The ECCE pathway is blocked by pharmacological agents that also block store-operated Ca²⁺ entry, is inhibited by dantrolene, is relatively insensitive to the DHP antagonist nifedipine (1 μM), and is permeable to Mn²⁺. Here, we have examined the effects of these agents on the L-type Ca²⁺ current conducted via the DHPR. We found that the nonspecific cation channel antagonists (2-APB, SKF 96356, La³⁺, and Gd³⁺) and dantrolene all inhibited the L-type Ca²⁺ current. In addition, complete (>97%) block of the L-type current required concentrations of nifedipine >10 μM. Like ECCE, the L-type Ca²⁺ channel displays permeability to Mn²⁺ in the absence of external Ca²⁺ and produces a Ca²⁺ current that persists during prolonged (∼10-second) depolarization. This current appears to contribute to the Ca²⁺ transient observed during prolonged KCl depolarization of intact myotubes because (1) the transients in normal myotubes decayed more rapidly in the absence of external Ca²⁺; (2) the transients in dysgenic myotubes expressing SkEIIIK (a DHPR α_1S pore mutant thought to conduct only monovalent cations) had a time course like that of normal myotubes in Ca²⁺-free solution and were unaffected by Ca²⁺ removal; and (3) after block of SR Ca²⁺ release by 200 μM ryanodine, normal myotubes still displayed a large Ca²⁺ transient, whereas no transient was detectable in SkEIIIK-expressing dysgenic myotubes. Collectively, these results indicate that the skeletal muscle L-type channel is a major contributor to the Ca²⁺ entry attributed to ECCE.     

Divalent cations permeation in a Ca2+ non-conducting skeletal muscle dihydropyridine receptor mouse model

In response to excitation of skeletal muscle fibers, trains of action potentials induce changes in the configuration of the dihydropyridine receptor (DHPR) anchored in the tubular membrane which opens the Ca²⁺ release channel in the sarcoplasmic reticulum membrane. The DHPR also functions as a voltage-gated Ca²⁺ channel that conducts L-type Ca²⁺ currents routinely recorded in mammalian muscle fibers, which role was debated for more than four decades. Recently, to allow a closer look into the role of DHPR Ca²⁺ influx in mammalian muscle, a knock-in (ki) mouse model (ncDHPR) carrying mutation N617D (adjacent to domain II selectivity filter E) in the DHPRα_1S subunit abolishing Ca²⁺ permeation through the channel was generated [Dayal et al., 2017]. In the present study, the Mn²⁺ quenching technique was initially intended to be used on voltage-clamped muscle fibers from this mouse to determine whether Ca²⁺ influx through a pathway distinct from DHPR may occur to compensate for the absence of DHPR Ca²⁺ influx. Surprisingly, while N617D DHPR muscle fibers of the ki mouse do not conduct Ca²⁺, Mn²⁺ entry and subsequent quenching did occur because Mn²⁺ was able to permeate and produce L-type currents through N617D DHPR. N617D DHPR was also found to conduct Ba²⁺ and Ba²⁺ currents were strongly blocked by external Ca²⁺. Ba²⁺ permeation was smaller, current kinetics slower and Ca²⁺ block more potent than in wild-type DHPR. These results indicate that residue N617 when replaced by the negatively charged residue D is suitably located at entrance of the pore to trap external Ca²⁺ impeding in this way permeation. Because Ba²⁺ binds with lower affinity to D, Ba²⁺ currents occur, but with reduced amplitudes as compared to Ba²⁺ currents through wild-type channels. We conclude that mutations located outside the selectivity filter influence channel permeation and possibly channel gating in a fully differentiated skeletal muscle environment.     

Ca2+-induced Ca2+ Release in Chinese Hamster Ovary (CHO) Cells Co-expressing Dihydropyridine and Ryanodine Receptors

Combined patch-clamp and Fura-2 measurements were performed on chinese hamster ovary (CHO) cells co-expressing two channel proteins involved in skeletal muscle excitation-contraction (E-C) coupling, the ryanodine receptor (RyR)-Ca²⁺ release channel (in the membrane of internal Ca²⁺ stores) and the dihydropyridine receptor (DHPR)-Ca²⁺ channel (in the plasma membrane). To ensure expression of functional L-type Ca²⁺ channels, we expressed α₂, β, and γ DHPR subunits and a chimeric DHPR α₁ subunit in which the putative cytoplasmic loop between repeats II and III is of skeletal origin and the remainder is cardiac. There was no clear indication of skeletal-type coupling between the DHPR and the RyR; depolarization failed to induce a Ca²⁺ transient (CaT) in the absence of extracellular Ca²⁺ ([Ca²⁺]_o). However, in the presence of [Ca²⁺]_o, depolarization evoked CaTs with a bell-shaped voltage dependence. About 30% of the cells tested exhibited two kinetic components: a fast transient increase in intracellular Ca²⁺ concentration ([Ca²⁺]_i) (the first component; reaching 95% of its peak <0.6 s after depolarization) followed by a second increase in [Ca²⁺]_i which lasted for 5–10 s (the second component). Our results suggest that the first component primarily reflected Ca²⁺ influx through Ca²⁺ channels, whereas the second component resulted from Ca²⁺ release through the RyR expressed in the membrane of internal Ca²⁺ stores. However, the onset and the rate of Ca²⁺ release appeared to be much slower than in native cardiac myocytes, despite a similar activation rate of Ca²⁺ current. These results suggest that the skeletal muscle RyR isoform supports Ca²⁺-induced Ca²⁺ release but that the distance between the DHPRs and the RyRs is, on average, much larger in the cotransfected CHO cells than in cardiac myocytes. We conclude that morphological properties of T-tubules and/or proteins other than the DHPR and the RyR are required for functional “close coupling” like that observed in skeletal or cardiac muscle. Nevertheless, some of our results imply that these two channels are potentially able to directly interact with each other.     

The mammalian skeletal muscle DHPR has larger Ca2+ conductance and is phylogenetically ancient to the early ray-finned fish sterlet (Acipenser ruthenus)

The L-type Ca²⁺ channel or dihydropyridine receptor (DHPR) in vertebrate skeletal muscle is responsible for sensing sarcolemmal depolarizations and transducing this signal to the sarcoplasmic Ca²⁺ release channel RyR1 via conformational coupling to initiate muscle contraction. During this excitation-contraction (EC) coupling process there is a slow Ca²⁺ current through the mammalian DHPR which is fully missing in euteleost fishes. In contrast to ancestral evolutionary stages where skeletal muscle EC coupling is still depended on Ca²⁺-induced Ca²⁺-release (CICR), it is possible that the DHPR Ca²⁺ conductivity during mammalian (conformational) EC coupling was retained as an evolutionary remnant (vestigiality). Here, we wanted to test the hypothesis that due to the lack of evolutionary pressure in post-CICR species skeletal muscle DHPR Ca²⁺ conductivity gradually reduced as evolution progressed. Interestingly, we identified that the DHPR of the early ray-finned fish sterlet (Acipenser ruthenus) is phylogenetically positioned above the mammalian rabbit DHPR which retained robust Ca²⁺ conductivity, but below the euteleost zebrafish DHPR which completely lost Ca²⁺ conductivity. Remarkably, our results revealed that sterlet DHPR still retained the Ca²⁺ conductivity but currents are significantly reduced compared to rabbit. This decrease is due to lower DHPR membrane expression similar to zebrafish, as well as due to reduced channel open probability (P_o). In both these fish species the lower DHPR expression density is partially compensated by higher efficacy of DHPR-RyR1 coupling. The complete loss of P_o in zebrafish and other euteleost species was presumably based on the teleost specific 3rd round of genome duplication (Ts3R). Ts3R headed into the appearance of two skeletal muscle DHPR isoforms which finally, together with the radiation of the euteleost clade, fully lost the P_o.     

Differential regulation of skeletal muscle L-type Ca2+ current and excitation-contraction coupling by the dihydropyridine receptor beta subunit

The dihydropyridine receptor (DHPR) of skeletal muscle functions as a Ca2+ channel and is required for excitation-contraction (EC) coupling. Here we show that the DHPR beta subunit is involved in the regulation of these two functions. Experiments were performed in skeletal mouse myotubes selectively lacking a functional DHPR beta subunit. These beta-null cells have a low-density L-type current, a low density of charge movements, and lack EC coupling. Transfection of beta-null cells with cDNAs encoding for either the homologous beta1a subunit or the cardiac- and brain-specific beta2a subunit fully restored the L-type Ca2+ current (161 +/- 17 pS/pF and 139 +/- 9 pS/pF, respectively, in 10 mM Ca2+). We compared the Boltzmann parameters of the Ca2+ conductance restored by beta1a and beta2a, the kinetics of activation of the Ca2+ current, and the single channel parameters estimated by ensemble variance analysis and found them to be indistinguishable. In contrast, the maximum density of charge movements in cells expressing beta2a was significantly lower than in cells expressing beta1a (2.7 +/- 0.2 nC/microF and 6.7 +/- 0. 4 nC/microF, respectively). Furthermore, the amplitude of Ca2+ transient measured by confocal line-scans of fluo-3 fluorescence in voltage-clamped cells were 3- to 5-fold lower in myotubes expressing beta2a. In summary, DHPR complexes that included beta2a or beta1a restored L-type Ca2+ channels. However, a DHPR complex with beta1a was required for complete restoration of charge movements and skeletal-type EC coupling. These results suggest that the beta1a subunit participates in key regulatory events required for the EC coupling function of the DHPR.     

The cardiac α1C subunit can support excitation-triggered Ca2+ entry in dysgenic and dyspedic myotubes

Depolarization-induced entry of divalent ions into skeletal muscle has been attributed to a process termed Excitation-Coupled Ca²⁺ Entry (ECCE), which is hypothesized to require the interaction of the ryanodine receptor (RyR1), the L-type Ca²⁺ channel (DHPR) and another unidentified cation channel. Thus, ECCE is absent in myotubes lacking either the DHPR (dysgenic) or RyR1 (dyspedic). Furthermore, ECCE, as measured by Mn²⁺ quench of Fura-2, is reconstituted by expression of a mutant DHPR α_1S subunit (SkEIIIK) thought to be impermeable to divalent cations. Previously, we showed that the bulk of depolarization-induced Ca²⁺ entry could be explained by the skeletal L-type current. Accordingly, one would predict that any Ca²⁺ current similar to the endogenous current would restore such entry and that this entry would not require coupling to either the DHPR or RyR1. Here, we show that expression of the cardiac α_1C subunit in either dysgenic or dyspedic myotubes does result in Ca²⁺ entry similar to that ascribed to ECCE. We also demonstrate that, when potentiated by strong depolarization and Bay K 8644, SkEIIIK supports entry of Mn²⁺. These results strongly support the idea that the L-type channel is the major route of Ca²⁺ entry in response to repetitive or prolonged depolarization of skeletal muscle.     

Ca2+ influx through {alpha}1S DHPR may play a role in regulating Ca2+ release from RyR1 in skeletal muscle

Differentiated primary myotubes isolated from wild-type mice exhibit ryanodine-sensitive, spontaneous global Ca²⁺ oscillations as well as spontaneous depolarizations in the plasma membrane. Immunolabeling of these myotubes showed expression of both _1S dihydropyridine receptors (DHPRs) and ryanodine-sensitive Ca²⁺-release channel 1 (RyR1), the two key proteins in skeletal excitation-contraction (E-C) coupling. Spontaneous global Ca²⁺ oscillations could be inhibited by addition of 0.1 mM CdCl₂/0.5 mM LaCl₃ or 5 µM nifedipine to the extracellular bathing solution. After either treatment, Ca²⁺ oscillations could be restored upon extensive washing. Although exposure to DHPR antagonists completely blocked Ca²⁺ oscillations, normal orthograde signaling between DHPRs and RyRs, such as that elicited by 80 mM KCl depolarization, was still observed. In addition, we showed that spontaneous Ca²⁺ oscillations were never present in cultured mdg myotubes, which lack the expression of _1SDHPRs. These results suggest that under physiological conditions in conjunction with the mechanical coupling between the _1SDHPRs and RyR1, the initiation of Ca²⁺ oscillations in myotubes may be facilitated, in part, by the Ca²⁺ influx through the _1s-subunit of the DHPR. calcium-induced calcium release; dihydropyridine receptors; excitation-contraction coupling; ryanodine receptors; skeletal muscle     

Three-Dimensional Localization of the α and β Subunits and of the II-III Loop in the Skeletal Muscle L-type Ca2+ Channel

The L-type Ca²⁺ channel (dihydropyridine receptor (DHPR) in skeletal muscle acts as the voltage sensor for excitation-contraction coupling. To better resolve the spatial organization of the DHPR subunits (α_1s or Ca_V1.1, α₂, β_1a, δ1, and γ), we created transgenic mice expressing a recombinant β_1a subunit with YFP and a biotin acceptor domain attached to its N- and C- termini, respectively. DHPR complexes were purified from skeletal muscle, negatively stained, imaged by electron microscopy, and subjected to single-particle image analysis. The resulting 19.1-Å resolution, three-dimensional reconstruction shows a main body of 17 × 11 × 8 nm with five corners along its perimeter. Two protrusions emerge from either face of the main body: the larger one attributed to the α₂-δ1 subunit that forms a flexible hook-shaped feature and a smaller protrusion on the opposite side that corresponds to the II-III loop of Ca_V1.1 as revealed by antibody labeling. Novel features discernible in the electron density accommodate the atomic coordinates of a voltage-gated sodium channel and of the β subunit in a single docking possibility that defines the α1-β interaction. The β subunit appears more closely associated to the membrane than expected, which may better account for both its role in localizing the α_1s subunit to the membrane and its suggested role in excitation-contraction coupling.     

RGK protein-mediated impairment of slow depolarization- dependent Ca2+ entry into developing myotubes

Three physiological functions have been described for the skeletal muscle 1,4-dihydropyridine receptor (Ca_V1.1): (1) voltage-sensor for excitation-contraction (EC) coupling, (2) L-type Ca²⁺ channel, and (3) voltage-sensor for slow depolarization-dependent Ca²⁺ entry. Members of the RGK (Rad, Rem, Rem2, Gem/Kir) family of monomeric GTP-binding proteins are potent inhibitors of the former two functions of Ca_V1.1. However, it is not known whether the latter function that has been attributed to Ca_V1.1 is subject to modulation by RGK proteins. Thus, the purpose of this study was to determine whether Rad, Gem and/or Rem inhibit the slowly developing, persistent Ca²⁺ entry that is dependent on the voltage-sensing capability of Ca_V1.1. As a means to investigate this question, Venus fluorescent protein-fused RGK proteins (V-Rad, V-Rem and V-Gem) were overexpressed in “normal” mouse myotubes. We observed that such overexpression of V-Rad, V-Rem or V-Gem in myotubes caused marked changes in morphology of the cells. As shown previously for YFP-Rem, both L-type current and EC coupling were also impaired greatly in myotubes expressing either V-Rad or V-Gem. The reductions in L-type current and EC coupling were paralleled by reductions in depolarization-induced Ca²⁺ entry. Our observations provide the first evidence of modulation of this enigmatic Ca²⁺ entry pathway peculiar to skeletal muscle.     

RGK protein-mediated impairment of slow depolarization- dependent Ca2+ entry into developing myotubes

Three physiological functions have been described for the skeletal muscle 1,4-dihydropyridine receptor (Ca_V1.1): (1) voltage-sensor for excitation-contraction (EC) coupling, (2) L-type Ca²⁺ channel, and (3) voltage-sensor for slow depolarization-dependent Ca²⁺ entry. Members of the RGK (Rad, Rem, Rem2, Gem/Kir) family of monomeric GTP-binding proteins are potent inhibitors of the former two functions of Ca_V1.1. However, it is not known whether the latter function that has been attributed to Ca_V1.1 is subject to modulation by RGK proteins. Thus, the purpose of this study was to determine whether Rad, Gem and/or Rem inhibit the slowly developing, persistent Ca²⁺ entry that is dependent on the voltage-sensing capability of Ca_V1.1. As a means to investigate this question, Venus fluorescent protein-fused RGK proteins (V-Rad, V-Rem and V-Gem) were overexpressed in “normal” mouse myotubes. We observed that such overexpression of V-Rad, V-Rem or V-Gem in myotubes caused marked changes in morphology of the cells. As shown previously for YFP-Rem, both L-type current and EC coupling were also impaired greatly in myotubes expressing either V-Rad or V-Gem. The reductions in L-type current and EC coupling were paralleled by reductions in depolarization-induced Ca²⁺ entry. Our observations provide the first evidence of modulation of this enigmatic Ca²⁺ entry pathway peculiar to skeletal muscle.     

Ca2+ entry-independent effects of L-type Ca2+ channel modulators on Ca2+ sparks in ventricular myocytes

During the cardiac action potential, Ca²⁺ entry through dyhidropyridine receptor L-type Ca²⁺ channels (DHPRs) activates ryanodine receptors (RyRs) Ca²⁺-release channels, resulting in massive Ca²⁺ mobilization from the sarcoplasmic reticulum (SR). This global Ca²⁺ release arises from spatiotemporal summation of many localized elementary Ca²⁺-release events, Ca²⁺ sparks. We tested whether DHPRs modulate Ca²⁺sparks in a Ca²⁺ entry-independent manner. Negative modulation by DHPR of RyRs via physical interactions is accepted in resting skeletal muscle but remains controversial in the heart. Ca²⁺ sparks were studied in cat cardiac myocytes permeabilized with saponin or internally perfused via a patch pipette. Bathing and pipette solutions contained low Ca²⁺ (100 nM). Under these conditions, Ca²⁺ sparks were detected with a stable frequency of 3–5 sparks·s^–1·100 µm^–1. The DHPR blockers nifedipine, nimodipine, FS-2, and calciseptine decreased spark frequency, whereas the DHPR agonists Bay-K8644 and FPL-64176 increased it. None of these agents altered the spatiotemporal characteristics of Ca²⁺ sparks. The DHPR modulators were also without effect on SR Ca²⁺ load (caffeine-induced Ca²⁺ transients) or sarco(endo)plasmic reticulum Ca²⁺-ATPase (SERCA) activity (Ca²⁺ loading rates of isolated SR microsomes) and did not change cardiac RyR channel gating (planar lipid bilayer experiments). In summary, DHPR modulators affected spark frequency in the absence of DHPR-mediated Ca²⁺ entry. This action could not be attributed to a direct action of DHPR modulators on SERCA or RyRs. Our results suggest that the activity of RyR Ca²⁺-release units in ventricular myocytes is modulated by Ca²⁺ entry-independent conformational changes in neighboring DHPRs. exitation-contraction coupling; ryanodine receptor; sarco(endo)plasmic reticulum Ca²⁺-ATPase; dihydropyridine receptor; sarcoplasmic reticulum     

Molecular origin of the L-type Ca2+ current of skeletal muscle myotubes selectively deficient in dihydropyridine receptor beta1a subunit.

The origin of Ibetanull, the Ca2+ current of myotubes from mice lacking the skeletal dihydropyridine receptor (DHPR) beta1a subunit, was investigated. The density of Ibetanull was similar to that of Idys, the Ca2+ current of myotubes from dysgenic mice lacking the skeletal DHPR alpha1S subunit (-0.6 +/- 0.1 and -0.7 +/- 0.1 pA/pF, respectively). However, Ibetanull activated at significantly more positive potentials. The midpoints of the GCa-V curves were 16.3 +/- 1.1 mV and 11.7 +/- 1.0 mV for Ibetanull and Idys, respectively. Ibetanull activated significantly more slowly than Idys. At +30 mV, the activation time constant for Ibetanull was 26 +/- 3 ms, and that for Idys was 7 +/- 1 ms. The unitary current of normal L-type and beta1-null Ca2+ channels estimated from the mean variance relationship at +20 mV in 10 mM external Ca2+ was 22 +/- 4 fA and 43 +/- 7 fA, respectively. Both values were significantly smaller than the single-channel current estimated for dysgenic Ca2+ channels, which was 84 +/- 9 fA under the same conditions. Ibetanull and Idys have different gating and permeation characteristics, suggesting that the bulk of the DHPR alpha1 subunits underlying these currents are different. Ibetanull is suggested to originate primarily from Ca2+ channels with a DHPR alpha1S subunit. Dysgenic Ca2+ channels may be a minor component of this current. The expression of DHPR alpha1S in beta1-null myotubes and its absence in dysgenic myotubes was confirmed by immunofluorescence labeling of cells.     

Ca2+-dependent excitation-contraction coupling triggered by the heterologous cardiac/brain DHPR beta2a-subunit in skeletal myotubes

Molecular determinants essential for skeletal-type excitation-contraction (EC) coupling have been described in the cytosolic loops of the dihydropyridine receptor (DHPR) alpha1S pore subunit and in the carboxyl terminus of the skeletal-specific DHPR beta1a-subunit. It is unknown whether EC coupling domains present in the beta-subunit influence those present in the pore subunit or if they act independent of each other. To address this question, we investigated the EC coupling signal that is generated when the endogenous DHPR pore subunit alpha1S is paired with the heterologous heart/brain DHPR beta2a-subunit. Studies were conducted in primary cultured myotubes from beta1 knockout (KO), ryanodine receptor type 1 (RyR1) KO, ryanodine receptor type 3 (RyR3) KO, and double RyR1/RyR3 KO mice under voltage clamp with simultaneous monitoring of confocal fluo-4 fluorescence. The beta2a-mediated Ca2+ current recovered in beta1 KO myotubes lacking the endogenous DHPR beta1a-subunit verified formation of the alpha1S/beta1a pair. In myotube genotypes which express no or low-density L-type Ca2+ currents, namely beta1 KO and RyR1 KO, beta2a overexpression recovered a wild-type density of nifedipine-sensitive Ca2+ currents with a slow activation kinetics typical of skeletal myotubes. Concurrent with Ca2+ current recovery, there was a drastic reduction of voltage-dependent, skeletal-type EC coupling and emergence of Ca2+ transients triggered by the Ca2+ current. A comparison of beta2a overexpression in RyR3 KO, RyR1 KO, and double RyR1/RyR3 KO myotubes concluded that both RyR1 and RyR3 isoforms participated in Ca2+-dependent Ca2+ release triggered by the beta2a-subunit. In beta1 KO and RyR1 KO myotubes, the Ca2+-dependent EC coupling promoted by beta2a overexpression had the following characteristics: 1), L-type Ca2+ currents had a wild-type density; 2), Ca2+ transients activated much slower than controls overexpressing beta1a, and the rate of fluorescence increase was consistent with the activation kinetics of the Ca2+ current; 3), the voltage dependence of the Ca2+ transient was bell-shaped and the maximum was centered at approximately +30 mV, consistent with the voltage dependence of the Ca2+ current; and 4), Ca2+ currents and Ca2+ transients were fully blocked by nifedipine. The loss in voltage-dependent EC coupling promoted by beta2a was inferred by the drastic reduction in maximal Ca2+ fluorescence at large positive potentials (DeltaF/Fmax) in double dysgenic/beta1 KO myotubes overexpressing the pore mutant alpha1S (E1014K) and beta2a. The data indicate that beta2a, upon interaction with the skeletal pore subunit alpha1S, overrides critical EC coupling determinants present in alpha1S. We propose that the alpha1S/beta pair, and not the alpha1S-subunit alone, controls the EC coupling signal in skeletal muscle.     

Recovery of Ca2+ current, charge movements, and Ca2+ transients in myotubes deficient in dihydropyridine receptor beta 1 subunit transfected with beta 1 cDNA.

The Ca2+ currents, charge movements, and intracellular Ca2+ transients of mouse dihydropyridine receptor (DHPR) beta 1-null myotubes expressing a mouse DHPR beta 1 cDNA have been characterized. In beta 1-null myotubes maintained in culture for 10-15 days, the density of the L-type current was approximately 7-fold lower than in normal cells of the same age (Imax was 0.65 +/- 0.05 pA/pF in mutant versus 4.5 +/- 0.8 pA/pF in normal), activation of the L-type current was significantly faster (tau activation at +40 mV was 28 +/- 7 ms in mutant versus 57 +/- 8 ms in normal), charge movements were approximately 2.5-fold lower (Qmax was 2.5 +/- 0.2 nC/microF in mutant versus 6.3 +/- 0.7 nC/microF in normal), Ca2+ transients were not elicited by depolarization, and spontaneous or evoked contractions were absent. Transfection of beta 1-null cells by lipofection with beta 1 cDNA reestablished spontaneous or evoked contractions in approximately 10% of cells after 6 days and approximately 30% of cells after 13 days. In contracting beta 1-transfected myotubes there was a complete recovery of the L-type current density (Imax was 4 +/- 0.9 pA/pF), the kinetics of activation (tau activation at +40 mV was 64 +/- 5 ms), the magnitude of charge movements (Qmax was 6.7 +/- 0.4 nC/microF), and the amplitude and voltage dependence of Ca2+ transients evoked by depolarizations. Ca2+ transients of transfected cells were unaltered by the removal of external Ca2+ or by the block of the L-type Ca2+ current, demonstrating that a skeletal-type excitation-contraction coupling was restored. The recovery of the normal skeletal muscle phenotype in beta 1-transfected beta-null myotubes shows that the beta 1 subunit is essential for the functional expression of the DHPR complex.     

Ca2+ Release in Muscle Fibers Expressing R4892W and G4896V Type 1 Ryanodine Receptor Disease Mutants

The large and rapidly increasing number of potentially pathological mutants in the type 1 ryanodine receptor (RyR1) prompts the need to characterize their effects on voltage-activated sarcoplasmic reticulum (SR) Ca²⁺ release in skeletal muscle. Here we evaluated the function of the R4892W and G4896V RyR1 mutants, both associated with central core disease (CCD) in humans, in myotubes and in adult muscle fibers. For both mutants expressed in RyR1-null (dyspedic) myotubes, voltage-gated Ca²⁺ release was absent following homotypic expression and only partially restored following heterotypic expression with wild-type (WT) RyR1. In muscle fibers from adult WT mice, both mutants were expressed in restricted regions of the fibers with a pattern consistent with triadic localization. Voltage-clamp-activated confocal Ca²⁺ signals showed that fiber regions endowed with G4896V-RyR1s exhibited an ∼30% reduction in the peak rate of SR Ca²⁺ release, with no significant change in SR Ca²⁺ content. Immunostaining revealed no associated change in the expression of either α1S subunit (Cav1.1) of the dihydropyridine receptor (DHPR) or type 1 sarco(endo)plasmic reticulum Ca²⁺ ATPase (SERCA1), indicating that the reduced Ca²⁺ release resulted from defective RyR1 function. Interestingly, in spite of robust localized junctional expression, the R4892W mutant did not affect SR Ca²⁺ release in adult muscle fibers, consistent with a low functional penetrance of this particular CCD-associated mutant.     

Properties of Na+ currents conducted by a skeletal muscle L-type Ca2+ channel pore mutant (SkEIIIK)

Four glutamate residues residing at corresponding positions within the four conserved membrane-spanning repeats of L-type Ca²⁺ channels are important structural determinants for the passage of Ca²⁺ across the selectivity filter. Mutation of the critical glutamate in Repeat III in the a_1S subunit of the skeletal L-type channel (Ca_v1.1) to lysine virtually eliminates passage of Ca²⁺ during step depolarizations. In this study, we examined the ability of this mutant Ca_v1.1 channel (SkEIIIK) to conduct inward Na⁺ current. When 150 mM Na⁺ was present as the sole monovalent cation in the bath solution, dysgenic (Ca_v1.1 null) myotubes expressing SkEIIIK displayed slowly-activating, non-inactivating, nifedipine-sensitive inward currents with a reversal potential (45.6 ± 2.5 mV) near that expected for Na⁺. Ca²⁺ block of SkEIIIK-mediated Na⁺ current was revealed by the substantial enhancement of Na⁺ current amplitude after reduction of Ca²⁺ in the external recording solution from 10 mM to near physiological 1 mM. Inward SkEIIIK-mediated currents were potentiated by either ±Bay K 8644 (10 mM) or 200-ms depolarizing prepulses to +90 mV. In contrast, outward monovalent currents were reduced by ±Bay K 8644 and were unaffected by strong depolarization, indicating a preferential potentiation of inward Na⁺ currents through the mutant Ca_v1.1 channel. Taken together, our results show that SkEIIIK functions as a non-inactivating, junctionally-targeted Na⁺ channel when Na⁺ is the sole monvalent cation present and urge caution when interpreting the impact of mutations designed to ablate Ca²⁺ permeability mediated by Ca_V channels on physiological processes that extend beyond channel gating and permeability.     

Rem inhibits skeletal muscle EC coupling by reducing the number of functional L-type Ca2+ channels

In skeletal muscle, the L-type voltage-gated Ca²⁺ channel (1,4-dihydropyridine receptor) serves as the voltage sensor for excitation-contraction (EC) coupling. In this study, we examined the effects of Rem, a member of the RGK family of Ras-related monomeric GTP-binding proteins, on the function of the skeletal muscle L-type Ca²⁺ channel. EC coupling was found to be weakened in myotubes expressing Rem tagged with enhanced yellow fluorescent protein (YFP-Rem), as assayed by electrically evoked contractions and myoplasmic Ca²⁺ transients. This impaired EC coupling was not a consequence of altered function of the type 1 ryanodine receptor, or of reduced Ca²⁺ stores, since the application of 4-chloro-m-cresol, a direct type 1 ryanodine receptor activator, elicited myoplasmic Ca²⁺ release in YFP-Rem-expressing myotubes that was not distinguishable from that in control myotubes. However, YFP-Rem reduced the magnitude of L-type Ca²⁺ current by ∼75% and produced a concomitant reduction in membrane-bound charge movements. Thus, our results indicate that Rem negatively regulates skeletal muscle EC coupling by reducing the number of functional L-type Ca²⁺ channels in the plasma membrane.     

Ca2+ Uptake Through Voltage-gated L-type Ca2+ Channels by Polarized Enterocytes from Atlantic Cod Gadus morhua

The presence and localization of voltage-gated Ca²⁺ channels of L-type were investigated in intestinal cells of the Atlantic cod. Enterocytes were loaded with the fluorescent Ca²⁺ probe, fure-2/AM and changes in intracellular Ca²⁺ concentrations ([Ca²⁺] _i ) were measured, in cell suspensions, in the presence of high potassium levels (100 mm), BAY K-8644 (5 μm), nifedipine (5 μm) or ω-conotoxin (1 μm). L-type Ca²⁺ channels were visualized on intestinal sections using the fluorescent dihydropyridine (-)-STBodipy. Depolarization of the plasma membrane produced a rapid (within 5 sec) and transient (at basal levels after 21 sec) increase in [Ca²⁺] _i . BAY K-8644 increased the [Ca²⁺] _i by 7.2%. Cells in a Ca²⁺-free buffer increased [Ca²⁺] _i after addition of 10 mm Ca²⁺, and this increase was abolished by nifedipine in both depolarizing and normal medium but not by ω-conotoxin. Single cell experiments using video microscopy revealed that enterocytes remained polarized several hours after preparation and that the Ca²⁺ entry and extrusion occurred at specific and different regions of the enterocyte outer membrane. Fluorescent staining of L-type Ca²⁺ channels in the intestinal mucosa showed the most intense staining at the brushborder membrane. These results demonstrate the presence of voltage gated L-type Ca²⁺ channels in enterocytes from the Atlantic cod. The channels are mainly located at the apical side of the cells, and there is a polarized uptake of Ca²⁺ into the enterocytes. This suggests that the L-type Ca²⁺ channels are involved in the transcellular Ca²⁺ entry into the enterocytes. Received: 21 August 1997/Revised: 15 April 1998     

Trifluoperazine enhancement of Ca2+-dependent inactivation of L-type Ca2+ currents inHelix aspersa neurons

The effects of trifluoperazine hydrochloride (TFP), a calmodulin antagonist, on L-type Ca²⁺ currents (L-type ICa²⁺) and their Ca²⁺-dependent inactivation, were studied in identifiedHelix aspersa neurons, using two microelectrode voltage clamp. Changes in [Ca²⁺]_i were measured in unclamped fura-2 loaded neurons. Bath applied TFP produced a reversible and dose-dependent reduction in amplitude of L-type ICa²⁺ (IC₅₀=28 μM). Using a double-pulse protocol, we found that TFP enhances the efficacy of Ca²⁺-dependent inactivation of L-type ICa²⁺. Trifluoperazine sulfoxide (50 μM), a TFP derivative with low calmodulin-antagonist activity, did not have any effects on either amplitude or inactivation of L-type ICa²⁺. TFP (20 μM) increased basal [Ca²⁺]_i from 147±37 nM to 650±40nM (N=7). The increase in [Ca²⁺]_i was prevented by removal of external Ca²⁺ and curtailed by depletion of caffeine-sensitive intracellular Ca²⁺ stores. Since TFP may also block protein kinase C (PKC), we tested the effect of a PKC activator (12-O-tetradecanoyl-phorbol-13-acetate) on L-type Ca²⁺ currents. This compound produced an increase in L-type ICa²⁺ without enhancing Ca²⁺-dependent inactivation. The results show that 1) TFP reduces L-type ICa²⁺ while enhancing the efficacy of Ca²⁺-dependent inactivation. 2) TFP produces an increase in basal [Ca²⁺]_i which may contribute to the enhancement of Ca²⁺-dependent inactivation. 3) PKC up-regulates L-type ICa²⁺ without altering the efficacy of Ca²⁺ dependent inactivation. 4) The TFP effects cannot be attributed to its action as PKC blocker.