Heterologous expression of BI Ca2+ channels in dysgenic skeletal muscle

The alpha(1S) III-IV loop influences 1,4-dihydropyridine receptor gating but is not directly involved in excitation-contraction coupling interactions with the type 1 ryanodine receptor

In skeletal muscle, coupling between the 1,4-dihydropyridine receptor (DHPR) and the type 1 ryanodine receptor (RyR1) underlies excitation-contraction (EC) coupling. The III-IV loop of the DHPR alpha(1S) subunit binds to a segment of RyR1 in vitro, and mutations in the III-IV loop alter the voltage dependence of EC coupling, raising the possibility that this loop is directly involved in signal transmission from the DHPR to RyR1. To clarify the role of the alpha(1S) III-IV loop in EC coupling, we examined the functional properties of a chimera (GFP-alpha(1S)[III-IVa]) in which the III-IV loop of the divergent alpha(1A) isoform replaced that of alpha(1S). Dysgenic myotubes expressing GFP-alpha(1S)[III-IVa] yielded myoplasmic Ca(2+) transients that activated at approximately 10 mV more hyperpolarized potentials and that were approximately 65% smaller than those of GFP-alpha(1S). A similar reduction was observed in voltage-dependent charge movements for GFP-alpha(1S)[III-IVa], indicating that the chimeric channels trafficked less well to the membrane but that those that were in the membrane functioned as efficiently in EC coupling as GFP-alpha(1S). Relative to GFP-alpha(1S), L-type currents mediated by GFP-alpha(1S)[III-IVa] were approximately 40% smaller and activated at approximately 5 mV more hyperpolarized potentials. The altered gating of GFP-alpha(1S)[III-IVa] was accentuated by exposure to +/-Bay K 8644, which caused a much larger hyperpolarizing shift in activation compared with its effect on GFP-alpha(1S). Taken together, our observations indicate that the alpha(1S) III-IV loop is not directly involved in EC coupling but does influence DHPR gating transitions important both for EC coupling and activation of L-type conductance.

Functional interaction of CaV channel isoforms with ryanodine receptors studied in dysgenic myotubes

The L-type Ca(2+) channels Ca(V)1.1 (alpha(1S)) and Ca(V)1.2 (alpha(1C)) share properties of targeting but differ by their mode of coupling to ryanodine receptors in muscle cells. The brain isoform Ca(V)2.1 (alpha(1A)) lacks ryanodine receptor targeting. We studied these three isoforms in myotubes of the alpha(1S)-deficient skeletal muscle cell line GLT under voltage-clamp conditions and estimated the flux of Ca(2+) (Ca(2+) input flux) resulting from Ca(2+) entry and release. Surprisingly, amplitude and kinetics of the input flux were similar for alpha(1C) and alpha(1A) despite a previously reported strong difference in responsiveness to extracellular stimulation. The kinetic flux characteristics of alpha(1C) and alpha(1A) resembled those in alpha(1S)-expressing cells but the contribution of Ca(2+) entry was much larger. alpha(1C) but not alpha(1A)-expressing cells revealed a distinct transient flux component sensitive to sarcoplasmic reticulum depletion by 30 microM cyclopiazonic acid and 10 mM caffeine. This component likely results from synchronized Ca(2+)-induced Ca(2+) release that is absent in alpha(1A)-expressing myotubes. In cells expressing an alpha(1A)-derivative (alpha(1)Aas(1592-clip)) containing the putative targeting sequence of alpha(1S), a similar transient component was noticeable. Yet, it was considerably smaller than in alpha(1C), indicating that the local Ca(2+) entry produced by the chimera is less effective in triggering Ca(2+) release despite similar global Ca(2+) inward current density.

Cardiac-type EC-coupling in dysgenic myotubes restored with Ca2+ channel subunit isoforms alpha1C and alpha1D does not correlate with current density

Ca(2+)-induced Ca(2+)-release (CICR)-the mechanism of cardiac excitation-contraction (EC) coupling-also contributes to skeletal muscle contraction; however, its properties are still poorly understood. CICR in skeletal muscle can be induced independently of direct, calcium-independent activation of sarcoplasmic reticulum Ca(2+) release, by reconstituting dysgenic myotubes with the cardiac Ca(2+) channel alpha(1C) (Ca(V)1.2) subunit. Ca(2+) influx through alpha(1C) provides the trigger for opening the sarcoplasmic reticulum Ca(2+) release channels. Here we show that also the Ca(2+) channel alpha(1D) isoform (Ca(V)1.3) can restore cardiac-type EC-coupling. GFP-alpha(1D) expressed in dysgenic myotubes is correctly targeted into the triad junctions and generates action potential-induced Ca(2+) transients with the same efficiency as GFP-alpha(1C) despite threefold smaller Ca(2+) currents. In contrast, GFP-alpha(1A), which generates large currents but is not targeted into triads, rarely restores action potential-induced Ca(2+) transients. Thus, cardiac-type EC-coupling in skeletal myotubes depends primarily on the correct targeting of the voltage-gated Ca(2+) channels and less on their current size. Combined patch-clamp/fluo-4 Ca(2+) recordings revealed that the induction of Ca(2+) transients and their maximal amplitudes are independent of the different current densities of GFP-alpha(1C) and GFP-alpha(1D). These properties of cardiac-type EC-coupling in dysgenic myotubes are consistent with a CICR mechanism under the control of local Ca(2+) gradients in the triad junctions.

Ca2+ current and charge movements in skeletal myotubes promoted by the beta-subunit of the dihydropyridine receptor in the absence of ryanodine receptor type 1

The beta-subunit of the dihydropyridine receptor (DHPR) enhances the Ca(2+) channel and voltage-sensing functions of the DHPR. In skeletal myotubes, there is additional modulation of DHPR functions imposed by the presence of ryanodine receptor type-1 (RyR1). Here, we examined the participation of the beta-subunit in the expression of L-type Ca(2+) current and charge movements in RyR1 knock-out (KO), beta1 KO, and double beta1/RyR1 KO myotubes generated by mating heterozygous beta1 KO and RyR1 KO mice. Primary myotube cultures of each genotype were transfected with various beta-isoforms and then whole-cell voltage-clamped for measurements of Ca(2+) and gating currents. Overexpression of the endogenous skeletal beta1a isoform resulted in a low-density Ca(2+) current either in RyR1 KO (36 +/- 9 pS/pF) or in beta1/RyR1 KO (34 +/- 7 pS/pF) myotubes. However, the heterologous beta2a variant with a double cysteine motif in the N-terminus (C3, C4), recovered a Ca(2+) current that was entirely wild-type in density in RyR1 KO (195 +/- 16 pS/pF) and was significantly enhanced in double beta1/RyR1 KO (115 +/- 18 pS/pF) myotubes. Other variants tested from the four beta gene families (beta1a, beta1b, beta1c, beta3, and beta4) were unable to enhance Ca(2+) current expression in RyR1 KO myotubes. In contrast, intramembrane charge movements in beta2a-expressing beta1a/RyR1 KO myotubes were significantly lower than in beta1a-expressing beta1a/RyR1 KO myotubes, and the same tendency was observed in the RyR1 KO myotube. Thus, beta2a had a preferential ability to recover Ca(2+) current, whereas beta1a had a preferential ability to rescue charge movements. Elimination of the double cysteine motif (beta2a C3,4S) eliminated the RyR1-independent Ca(2+) current expression. Furthermore, Ca(2+) current enhancement was observed with a beta2a variant lacking the double cysteine motif and fused to the surface membrane glycoprotein CD8. Thus, tethering the beta2a variant to the myotube surface activated the DHPR Ca(2+) current and bypassed the requirement for RyR1. The data suggest that the Ca(2+) current expressed by the native skeletal DHPR complex has an inherently low density due to inhibitory interactions within the DHPR and that the beta1a-subunit is critically involved in process.

Potentiation of the cardiac L-type Ca(2+) channel (alpha(1C)) by dihydropyridine agonist and strong depolarization occur via distinct mechanisms

A defining property of L-type Ca(2+) channels is their potentiation by both 1,4-dihydropyridine agonists and strong depolarization. In contrast, non-L-type channels are potentiated by neither agonist nor depolarization, suggesting that these two processes may by linked. In this study, we have tested whether the mechanisms of agonist- and depolarization-induced potentiation in the cardiac L-type channel (alpha(1C)) are linked. We found that the mutant L-type channel GFP-alpha(1C)(TQ-->YM), bearing the mutations T1066Y and Q1070M, was able to undergo depolarization-induced potentiation but not potentiation by agonist. Conversely, the chimeric channel GFP-CACC was potentiated by agonist but not by strong depolarization. These data indicate that the mechanisms of agonist- and depolarization-induced potentiation of alpha(1C) are distinct. Since neither GFP-CACC nor GFP-CCAA was potentiated significantly by depolarization, no single repeat of alpha(1C) appears to be responsible for depolarization-induced potentiation. Surprisingly, GFP-CACC displayed a low estimated open probability similar to that of the alpha(1C), but could not support depolarization-induced potentiation, demonstrating that a relatively low open probability alone is not sufficient for depolarization-induced potentiation to occur. Thus, depolarization-induced potentiation may be a global channel property requiring participation from all four homologous repeats.

Multiple structural elements contribute to voltage-dependent facilitation of neuronal alpha 1C (CaV1.2) L-type calcium channels

Voltage- and frequency-dependent facilitation of calcium channel activity has been implicated in a number of key physiological processes. Various mechanisms have been proposed to mediate these regulations, including a switch between channel gating modes, voltage-dependent phosphorylation, and a voltage-dependent deinhibition of G-protein block. Studying such modulation on recombinant Ca channels expressed in oocytes, we previously reported that alpha(1C) L-type calcium channel contrast with non-L type Ca channels by its ability to exhibit facilitation by pre-depolarization (Voltage-dependent facilitation of a neuronal alpha(IC) L-type calcium channel, E. Bourinet et al., EMBO Journal, 1994; 13, 5032-5039). To further analyze this effect, we have investigated the molecular determinants which mediate the differences in voltage-dependent facilitation between "facilitable" alpha(1C) and "non facilitable" alpha(1E) calcium channels. We used a series of chimeras which combine the four transmembrane domains of the two channels. Results show that the four domains of alpha(1C) contribute to facilitation, with domain I being most critical. This domain is required but not sufficient alone to generate facilitation. The minimal requirement to observe the effect is the presence of domain I plus one of the three others. We conclude that similarly to activation gating, voltage-dependent facilitation of alpha(1C) is a complex process which involves multiple structural elements were domains I and III play the major role.

The triad targeting signal of the skeletal muscle calcium channel is localized in the COOH terminus of the alpha(1S) subunit

The specific localization of L-type Ca(2+) channels in skeletal muscle triads is critical for their normal function in excitation-contraction (EC) coupling. Reconstitution of dysgenic myotubes with the skeletal muscle Ca(2+) channel alpha(1S) subunit restores Ca(2+) currents, EC coupling, and the normal localization of alpha(1S) in the triads. In contrast, expression of the neuronal alpha(1A) subunit gives rise to robust Ca(2+) currents but not to triad localization. To identify regions in the primary structure of alpha(1S) involved in the targeting of the Ca(2+) channel into the triads, chimeras of alpha(1S) and alpha(1A) were constructed, expressed in dysgenic myotubes, and their subcellular distribution was analyzed with double immunofluorescence labeling of the alpha(1S)/alpha(1A) chimeras and the ryanodine receptor. Whereas chimeras containing the COOH terminus of alpha(1A) were not incorporated into triads, chimeras containing the COOH terminus of alpha(1S) were correctly targeted. Mapping of the COOH terminus revealed a triad-targeting signal contained in the 55 amino-acid sequence (1607-1661) proximal to the putative clipping site of alpha(1S). Transferring this triad targeting signal to alpha(1A) was sufficient for targeting and clustering the neuronal isoform into skeletal muscle triads and caused a marked restoration of Ca(2+)-dependent EC coupling.

The II-III loop of the skeletal muscle dihydropyridine receptor is responsible for the Bi-directional coupling with the ryanodine receptor

The dihydropyridine receptor (DHPR) in the skeletal muscle plasmalemma functions as both voltage-gated Ca(2+) channel and voltage sensor for excitation-contraction (EC) coupling. As voltage sensor, the DHPR regulates intracellular Ca(2+) release via the skeletal isoform of the ryanodine receptor (RyR-1). Interaction with RyR-1 also feeds back to increase the Ca(2+) current mediated by the DHPR. To identify regions of the DHPR important for receiving this signal from RyR-1, we expressed in dysgenic myotubes a chimera (SkLC) having skeletal (Sk) DHPR sequence except for a cardiac (C) II-III loop (L). Tagging with green fluorescent protein (GFP) enabled identification of expressing myotubes. Dysgenic myotubes expressing GFP-SkLC or SkLC lacked EC coupling and had very small Ca(2+) currents. Introducing a short skeletal segment (alpha(1S) residues 720-765) into the cardiac II-III loop (replacing alpha(1C) residues 851-896) of GFP-SkLC restored both EC coupling and Ca(2+) current densities like those of the wild type skeletal DHPR. This 46-amino acid stretch of skeletal sequence was recently shown to be capable of transferring strong, skeletal-type EC coupling to an otherwise cardiac DHPR (Nakai, J., Tanabe, T., Konno, T., Adams, B., and Beam, K.G. (1998) J. Biol. Chem. 273, 24983-24986). Thus, this segment of the skeletal II-III loop contains a motif required for both skeletal-type EC coupling and RyR-1-mediated enhancement of Ca(2+) current.

Voltage and calcium use the same molecular determinants to inactivate calcium channels

During sustained depolarization, voltage-gated Ca2+ channels progressively undergo a transition to a nonconducting, inactivated state, preventing Ca2+ overload of the cell. This transition can be triggered either by the membrane potential (voltage-dependent inactivation) or by the consecutive entry of Ca2+ (Ca2+-dependent inactivation), depending on the type of Ca2+ channel. These two types of inactivation are suspected to arise from distinct underlying mechanisms, relying on specific molecular sequences of the different pore-forming Ca2+ channel subunits. Here we report that the voltage-dependent inactivation (of the alpha1A Ca2+ channel) and the Ca2+-dependent inactivation (of the alpha1C Ca2+ channel) are similarly influenced by Ca2+ channel beta subunits. The same molecular determinants of the beta subunit, and therefore the same subunit interactions, influence both types of inactivation. These results strongly suggest that the voltage and the Ca2+-dependent transitions leading to channel inactivation use homologous structures of the different alpha1 subunits and occur through the same molecular process. A model of inactivation taking into account these new data is presented.

G-Protein-dependent facilitation of neuronal alpha1A, alpha1B, and alpha1E Ca channels

Modulation of neuronal voltage-gated Ca channels has important implications for synaptic function. To investigate the mechanisms of Ca channel modulation, we compared the G-protein-dependent facilitation of three neuronal Ca channels. alpha1A, alpha1B, or alpha1E subunits were transiently coexpressed with alpha2-deltab and beta3 subunits in HEK293 cells, and whole-cell currents were recorded. After intracellular dialysis with GTPgammaS, strongly depolarized conditioning pulses facilitated currents mediated by each Ca channel type. The magnitude of facilitation depended on current density, with low-density currents being most strongly facilitated and high-density currents often lacking facilitation. Facilitating depolarizations speeded channel activation approximately 1.7-fold for alpha1A and alpha1B and increased current amplitudes by the same proportion, demonstrating equivalent facilitation of G-protein-inhibited alpha1A and alpha1B channels. Inactivation typically obscured facilitation of alpha1E current amplitudes, but the activation kinetics of alpha1E currents showed consistent and pronounced G-protein-dependent facilitation. The onset and decay of facilitation had the same kinetics for alpha1A, alpha1B, and alpha1E, suggesting that Gbeta gamma dimers dissociate from and reassociate with these Ca channels at very similar rates. To investigate the structural basis for N-type Ca channel modulation, we expressed a mutant of alpha1B missing large segments of the II-III loop and C terminus. This deletion mutant exhibited undiminished G-protein-dependent facilitation, demonstrating that a Gbeta gamma interaction site recently identified within the C terminus of alpha1E is not required for modulation of alpha1B.

G-Protein-dependent facilitation of neuronal alpha1A, alpha1B, and alpha1E Ca channels

Modulation of neuronal voltage-gated Ca channels has important implications for synaptic function. To investigate the mechanisms of Ca channel modulation, we compared the G-protein-dependent facilitation of three neuronal Ca channels. alpha1A, alpha1B, or alpha1E subunits were transiently coexpressed with alpha2-deltab and beta3 subunits in HEK293 cells, and whole-cell currents were recorded. After intracellular dialysis with GTPgammaS, strongly depolarized conditioning pulses facilitated currents mediated by each Ca channel type. The magnitude of facilitation depended on current density, with low-density currents being most strongly facilitated and high-density currents often lacking facilitation. Facilitating depolarizations speeded channel activation approximately 1.7-fold for alpha1A and alpha1B and increased current amplitudes by the same proportion, demonstrating equivalent facilitation of G-protein-inhibited alpha1A and alpha1B channels. Inactivation typically obscured facilitation of alpha1E current amplitudes, but the activation kinetics of alpha1E currents showed consistent and pronounced G-protein-dependent facilitation. The onset and decay of facilitation had the same kinetics for alpha1A, alpha1B, and alpha1E, suggesting that Gbeta gamma dimers dissociate from and reassociate with these Ca channels at very similar rates. To investigate the structural basis for N-type Ca channel modulation, we expressed a mutant of alpha1B missing large segments of the II-III loop and C terminus. This deletion mutant exhibited undiminished G-protein-dependent facilitation, demonstrating that a Gbeta gamma interaction site recently identified within the C terminus of alpha1E is not required for modulation of alpha1B.

Tagging with green fluorescent protein reveals a distinct subcellular distribution of L-type and non-L-type Ca2+ channels expressed in dysgenic myotubes

Expression of cardiac L-type Ca2+ channels in dysgenic myotubes results in large Ca2+ currents and electrically evoked contractions resulting from Ca2+-entry dependent release of Ca2+ from the sarcoplasmic reticulum. By contrast, expression of either P/Q-type or N-type Ca2+ channels in dysgenic myotubes does not result in electrically evoked contractions despite producing comparably large Ca2+ currents. In this work we examined the possibility that this discrepancy is caused by the preferential distribution of expressed L-type Ca2+ channels in close apposition to sarcoplasmic reticulum Ca2+ release channels. We tagged the N termini of different alpha1 subunits (classes A, B, C, and S) with a modified green fluorescent protein (GFP) and expressed each of the fusion channels in dysgenic myotubes. Each GFP-tagged alpha1 subunit exhibited Ca2+ channel activity that was indistinguishable from its wild-type counterpart. In addition, expression of GFP-alpha1S and GFP-alpha1C in dysgenic myotubes restored skeletal- and cardiac-type excitation-contraction (EC) coupling, respectively, whereas expression of GFP-alpha1A and GFP-alpha1B failed to restore EC coupling of any type. Laser-scanning confocal microscopy revealed a distinct expression pattern for L-type compared with non-L-type channels. After injection of cDNA into a single nucleus, GFP-alpha1S and GFP-alpha1C were present in the plasmalemma as small punctate foci along much of the longitudinal extent of the myotube. In contrast, GFP-alpha1A and GFP-alpha1B were not concentrated into punctate foci and primarily were found adjacent to the injected nucleus. Thus, L-type channels possess a targeting signal that directs their longitudinal transport and insertion into punctate regions of myotubes that presumably represent functional sites of EC coupling.

Modulation of the alpha 1A Ca2+ channel by beta subunits at physiological Ca2+ concentration

The class A Ca2+ channel alpha 1 subunit (alpha 1A) was expressed in Xenopus oocytes alone or in combination with the beta 1b, beta 2a, beta 3, or beta 4 subunit. Analysis of voltage-dependent activation and inactivation in the presence of 1.8 mM external Ca2+ showed an hyperpolarising shift of both relations when compared to similar recordings performed in the presence of 40 mM Ba2+. These shifts, which differed for activation and inactivation, were strongly modulated by the nature of the coexpressed beta subunit. On the other hand, for each combination, the kinetics of inactivation were similar in 1.8 mM Ca2+ and 40 mM Ba2+ (for example co-expression of the beta 2a subunit reduced inactivation using either 40 mM Ba2+ or 1.8 mM Ca2+). Thus, modulation of channel properties by the beta subunit is different in physiological Ca2+ or high Ba2+ concentrations. These results must be taken into consideration to extrapolate the role of the beta subunit in native cells.

Endogenous cardiac Ca2+ channels do not overcome the E-C coupling defect in immortalized dysgenic muscle cells: evidence for a missing link

The expression of subunit genes of the Ca2+ channel complex was studied in differentiating, immortalized mouse mdg cells. These cells expressed alpha 1 and alpha 2/delta transcripts of the skeletal muscle Ca2+ channel genes, a cardiac Ca2+ channel alpha 1 subunit gene and several known transcript variants of skeletal, cardiac and brain beta genes. The mdg mutation is retained in the 129DA3 cell line and occurs exclusively at nucleotide position 4010 in the skeletal alpha 1 transcript in which a cytosine residue is deleted. In early stages of differentiation and fusion, Ba2+ currents were detected in dysgenic myotubes the same as the cardiac L-type Ca2+ channel. These data provide specific structural evidence [Chaudhari, N. (1992) J. Biol. Chem. 267, 25636-25639] for the major genetic defect in mouse muscular dysgenesis and show a change in the expression levels of alpha 1S and alpha 1C. The upregulation of the expression of alpha 1C results in functional Ca2+ channel activity, however, presumably not sufficient for excitation-contraction coupling.