Functional expression and characterization of skeletal muscle dihydropyridine receptors in Xenopus oocytes

STAC proteins: The missing link in skeletal muscle EC coupling and new regulators of calcium channel function

Excitation-contraction coupling is the signaling process by which action potentials control calcium release and consequently the force of muscle contraction. Until recently, three triad proteins were known to be essential for skeletal muscle EC coupling: the voltage-gated calcium channel CaV1.1 acting as voltage sensor, the SR calcium release channel RyR1 representing the only relevant calcium source, and the auxiliary CaV β1a subunit. Whether CaV1.1 and RyR1 are directly coupled or whether their interaction is mediated by another triad protein is still unknown. The recent identification of the adaptor protein STAC3 as fourth essential component of skeletal muscle EC coupling prompted vigorous research to reveal its role in this signaling process. Accumulating evidence supports its possible involvement in linking CaV1.1 and RyR1 in skeletal muscle EC coupling, but also indicates a second, much broader role of STAC proteins in the regulation of calcium/calmodulin-dependent feedback regulation of L-type calcium channels.

Stac adaptor proteins regulate trafficking and function of muscle and neuronal L-type Ca2+ channels

Excitation-contraction (EC) coupling in skeletal muscle depends upon trafficking of CaV1.1, the principal subunit of the dihydropyridine receptor (DHPR) (L-type Ca(2+) channel), to plasma membrane regions at which the DHPRs interact with type 1 ryanodine receptors (RyR1) in the sarcoplasmic reticulum. A distinctive feature of this trafficking is that CaV1.1 expresses poorly or not at all in mammalian cells that are not of muscle origin (e.g., tsA201 cells), in which all of the other nine CaV isoforms have been successfully expressed. Here, we tested whether plasma membrane trafficking of CaV1.1 in tsA201 cells is promoted by the adapter protein Stac3, because recent work has shown that genetic deletion of Stac3 in skeletal muscle causes the loss of EC coupling. Using fluorescently tagged constructs, we found that Stac3 and CaV1.1 traffic together to the tsA201 plasma membrane, whereas CaV1.1 is retained intracellularly when Stac3 is absent. Moreover, L-type Ca(2+) channel function in tsA201 cells coexpressing Stac3 and CaV1.1 is quantitatively similar to that in myotubes, despite the absence of RyR1. Although Stac3 is not required for surface expression of CaV1.2, the principle subunit of the cardiac/brain L-type Ca(2+) channel, Stac3 does bind to CaV1.2 and, as a result, greatly slows the rate of current inactivation, with Stac2 acting similarly. Overall, these results indicate that Stac3 is an essential chaperone of CaV1.1 in skeletal muscle and that in the brain, Stac2 and Stac3 may significantly modulate CaV1.2 function.

Alternative splicing at C terminus of Ca(V)1.4 calcium channel modulates calcium-dependent inactivation, activation potential, and current density

The Ca(V)1.4 voltage-gated calcium channel is predominantly expressed in the retina, and mutations to this channel have been associated with human congenital stationary night blindness type-2. The L-type Ca(V)1.4 channel displays distinct properties such as absence of calcium-dependent inactivation (CDI) and slow voltage-dependent inactivation (VDI) due to the presence of an autoinhibitory domain (inhibitor of CDI) in the distal C terminus. We hypothesized that native Ca(V)1.4 is subjected to extensive alternative splicing, much like the other voltage-gated calcium channels, and employed the transcript scanning method to identify alternatively spliced exons within the Ca(V)1.4 transcripts isolated from the human retina. In total, we identified 19 alternative splice variations, of which 16 variations have not been previously reported. Characterization of the C terminus alternatively spliced exons using whole-cell patch clamp electrophysiology revealed a splice variant that exhibits robust CDI. This splice variant arose from the splicing of a novel alternate exon (43*) that can be found in 13.6% of the full-length transcripts screened. Inclusion of exon 43* inserts a stop codon that truncates half the C terminus. The Ca(V)1.4 43* channel exhibited robust CDI, a larger current density, a hyperpolarized shift in activation potential by ∼10 mV, and a slower VDI. Through deletional experiments, we showed that the inhibitor of CDI was responsible for modulating channel activation and VDI, in addition to CDI. Calcium currents in the photoreceptors were observed to exhibit CDI and are more negatively activated as compared with currents elicited from heterologously expressed full-length Ca(V)1.4. Naturally occurring alternative splice variants may in part contribute to the properties of the native Ca(V)1.4 channels.

Cardiac L-type calcium channel (Cav1.2) associates with gamma subunits

The cardiac voltage-gated Ca(2+) channel, Ca(v)1.2, mediates excitation-contraction coupling in the heart. The molecular composition of the channel includes the pore-forming α1 subunit and auxiliary α2/δ-1 and β subunits. Ca(2+) channel γ subunits, of which there are 8 isoforms, consist of 4 transmembrane domains with intracellular N- and C-terminal ends. The γ1 subunit was initially detected in the skeletal muscle Ca(v)1.1 channel complex, modulating current amplitude and activation and inactivation properties. The γ1 subunit also shifts the steady-state inactivation to more negative membrane potentials, accelerates current inactivation, and increases peak currents, when coexpressed with the cardiac α1c subunit in Xenopus oocytes and human embryonic kidney (HEK) 293 cells. The γ1 subunit is not expressed, however, in cardiac muscle. We sought to determine whether γ subunits that are expressed in cardiac tissue physically associate with and modulate Ca(v)1.2 function. We now demonstrate that γ4, γ6, γ7, and γ8 subunits physically interact with the Ca(v)1.2 complex. The γ subunits differentially modulate Ca(2+) channel function when coexpressed with the β1b and α2/δ-1 subunits in HEK cells, altering both activation and inactivation properties. The effects of γ on Ca(v)1.2 function are dependent on the subtype of β subunit. Our results identify new members of the cardiac Ca(v)1.2 macromolecular complex and identify a mechanism by which to increase the functional diversity of Ca(v)1.2 channels.

Short-term regulation of excitation-contraction coupling by the beta1a subunit in adult mouse skeletal muscle

The beta1a subunit of the skeletal muscle voltage-gated Ca2+ channel plays a fundamental role in the targeting of the channel to the tubular system as well as in channel function. To determine whether this cytosolic auxiliary subunit is also a regulatory protein of Ca2+ release from the sarcoplasmic reticulum in vivo, we pressure-injected the beta1a subunit into intact adult mouse muscle fibers and recorded, with Fluo-3 AM, the intracellular Ca2+ signal induced by the action potential. We found that the beta1a subunit significantly increased, within minutes, the amplitude of Ca2+ release without major changes in its time course. beta1a subunits with the carboxy-terminus region deleted did not show an effect on Ca2+ release. The possibility that potentiation of Ca2+ release is due to a direct interaction between the beta1a subunit and the ryanodine receptor was ruled out by bilayer experiments of RyR1 single-channel currents and also by Ca2+ flux experiments. Our data suggest that the beta1a subunit is capable of regulating E-C coupling in the short term and that the integrity of the carboxy-terminus region is essential for its modulatory effect.

The Ca2+ Channel α2δ-1 Subunit Determines Ca2+ Current Kinetics in Skeletal Muscle but Not Targeting of α1S or Excitation-Contraction Coupling

Auxiliary channel subunits regulate membrane expression and modulate current properties of voltage-activated Ca(2+) channels and thus are involved in numerous important cell functions, including muscle contraction. Whereas the importance of the alpha(1S), beta(1a), and gamma Ca(2+) channel subunits in skeletal muscle has been determined by using null-mutant mice, the role of the alpha(2)delta-1 subunit in skeletal muscle is still elusive. We addressed this question by small interfering RNA silencing of alpha(2)delta-1 in reconstituted dysgenic (alpha(1S)-null) myotubes and in BC3H1 skeletal muscle cells. Immunofluorescence labeling of the alpha(1S) and alpha(2)delta-1 subunits and whole cell patch clamp recordings demonstrated that triad targeting and functional expression of the skeletal muscle Ca(2+) channel were not compromised by the depletion of the alpha(2)delta-1 subunit. The amplitudes and voltage dependences of L-type Ca(2+) currents and of the depolarization-induced Ca(2+) transients were identical in control and in alpha(2)delta-1-depleted muscle cells. However, alpha(2)delta-1 depletion significantly accelerated the current kinetics, most likely by the conversion of slowly activating into fast activating Ca(2+) channels. Reverse transcription-PCR analysis indicated that alpha(2)delta-1 is the exclusive isoform expressed in differentiated BC3H1 cells and that depletion of alpha(2)delta-1 was not compensated by the up-regulation of any other alpha(2)delta isoform. Thus, in skeletal muscle the Ca(2+) channel alpha(2)delta-1 subunit functions as a major determinant of the characteristic slow L-type Ca(2+) current kinetics. However, this subunit is not essential for targeting of Ca(2+) channels or for their primary physiological role in activating skeletal muscle excitation-contraction coupling.

AKAP79 increases the functional expression of skeletal muscle Ca2+ channels in Xenopus oocytes

The actions of the kinase A anchoring protein, AKAP79, a key element in the regulation of the cardiac L-type Ca2+ channel, were assessed on skeletal muscle Ca2+ channels expressed in Xenopus oocytes. The channels were reconstituted by expressing the pore forming alpha1s subunit and its accessory subunits, alpha2-delta, beta, and gamma. We report, for the first time, that peak Ca2+ channel currents are greatly increased (3.5-fold) by AKAP79 when co-expressed with the truncated form of the alpha1s subunit. Immunoblots revealed that the increase in current amplitude is not accompanied by a corresponding increase in the membrane levels of the alpha1s subunit. This suggests that AKAP79 does not increase the trafficking of the channel. In addition, we show that the transcript of AKAP150, the rat ortholog of the human AKAP79, is expressed in rat skeletal muscle and propose that AKAP79/150 modulates Ca2+ channel function.

Control of ion conduction in L-type Ca2+ channels by the concerted action of S5-6 regions

Voltage-gated L-type Ca(2+) channels from cardiac (alpha(1C)) and skeletal (alpha(1S)) muscle differ from one another in ion selectivity and permeation properties, including unitary conductance. In 110 mM Ba(2+), unitary conductance of alpha(1S) is approximately half that of alpha(1C). As a step toward understanding the mechanism of rapid ion flux through these highly selective ion channels, we used chimeras constructed between alpha(1C) and alpha(1S) to identify structural features responsible for the difference in conductance. Combined replacement of the four pore-lining P-loops in alpha(1C) with P-loops from alpha(1S) reduced unitary conductance to a value intermediate between those of the two parent channels. Combined replacement of four larger regions that include sequences flanking the P-loops (S5 and S6 segments along with the P-loop-containing linker between these segments (S5-6)) conferred alpha(1S)-like conductance on alpha(1C). Likewise, substitution of the four S5-6 regions of alpha(1C) into alpha(1S) conferred alpha(1C)-like conductance on alpha(1S). These results indicate that, comparing alpha(1C) with alpha(1S), the differences in structure that are responsible for the difference in ion conduction are housed within the S5-6 regions. Moreover, the pattern of unitary conductance values obtained for chimeras in which a single P-loop or single S5-6 region was replaced suggest a concerted action of pore-lining regions in the control of ion conduction.

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.

The beta1a subunit regulates the functional properties of adult frog and mouse L-type Ca2+ channels of skeletal muscle

The beta(1a) subunit, one of the auxiliary subunits of Ca(V)1.1 channels, was expressed in COS-1 cells, purified by electroelution and electrodialysis techniques and identified by Western blot using monoclonal antibodies. The purified beta(1a) subunit strongly interacted in vitro with the alpha interaction domain (AID) of Ca(V)1.1 channels. The actions of the purified beta(1a) subunit on Ca(V)1.1 channel currents were assessed in whole cell voltage clamp experiments performed in vesicles derived from frog and mouse adult skeletal muscle plasma membranes. L-type inward currents were recorded in solutions containing Ba(2+) (I(Ba)). Values of peak I(Ba) were doubled by the beta(1a) subunit in frog and mouse muscle vesicles and the amplitude of the slow component of tail currents was greatly increased. The actions of the beta(1a) subunit on Ca(V)1.1 channel currents reached a steady state within 20 min. The beta(1a) subunit had no effect on the time courses of activation or inactivation of I(Ba) or shifted the current-voltage relation. Non-linear capacitive currents were recorded in solutions that contained mostly impermeant ions. Charge movement depended on voltage with average Boltzmann parameters: Q(max) = 28.0 +/- 6.6 nC microF(-1), V = -58.0 +/- 2.0 mV and k = 15.3 +/- 1.1 mV (n = 24). In the presence of the beta(1a) subunit, these parameters remained unchanged: Q(max) = 29.8 +/- 3.5 nC microF(-1), V = -54.5 +/- 2.2 mV and k = 16.4 +/- 1.3 mV (n = 21). Overall, the work describes a novel preparation to explore in situ the role of the beta(1a) subunit on the function of adult Ca(V)1.1 channels.

Functional roles of gamma2, gamma3 and gamma4, three new Ca2+ channel subunits, in P/Q-type Ca2+ channel expressed in Xenopus oocytes

Stargazin or [gamma]2, the product of the gene mutated in the stargazer mouse, is a homologue of the [gamma]1 protein, an accessory subunit of the skeletal muscle L-type Ca2+ channel. [gamma]2 is selectively expressed in the brain, and considered to be a putative neuronal Ca2+ channel subunit based mainly on homology to [gamma]1. Two new members of the [gamma] family expressed in the brain have recently been identified: [gamma]3 and [gamma]4. We have co-expressed, in Xenopus oocytes, the human [gamma]2, [gamma]3 and [gamma]4 subunits with the P/Q-type (Ca(V)2.1) Ca2+ channel and different regulatory subunits ([alpha]2-[delta]; [beta]1, [beta]2, [beta]3 or [beta]4). Subcellular distribution of the [gamma] subunits confirmed their membrane localization. Ba2+ currents, recorded using two-electrode voltage clamp, showed that the effects of the [gamma] subunits on the electrophysiological properties of the channel are, most of the time, minor. However, a fraction of the oocytes expressing [beta] subunits displayed an unusual slow-inactivating Ba2+ current. Expression of both [beta] and [gamma] subunits increased the appearance of the slow-inactivating current. Our data support a role for the [gamma] subunit as a brain Ca2+ channel modulatory subunit and suggest that [beta] and [gamma] subunits are involved in a switch between two regulatory modes of the P/Q-type channel inactivation.

Asymmetric arrangement of auxiliary subunits of skeletal muscle voltage-gated l-type Ca(2+) channel

Highly purified L-type Ca(2+) channel complexes containing all five subunits (alpha(1), alpha(2), beta, gamma, and delta) and complexes of alpha(1)-beta subunits were obtained from skeletal muscle triad membranes by three-step purification and by 1% Triton X-100 treatment, respectively. Their structures and the subunit arrangements were analyzed by electron microscopy. Projection images of negatively stained Ca(2+) channels and alpha(1)-beta complexes were aligned, classified and averaged. The alpha(1)-beta complex showed a hollow trapezoid shape of 12 nm height. In top view, four asymmetric domains surrounded a central depression predicted to form the channel pore. The complete Ca(2+) channel complex exhibited the cylindrical shape of 20 nm in height binding a spherical domain on one edge. Further image analysis of higher complexes of the Ca(2+) channel using a monoclonal antibody against the beta subunit showed that the alpha(1)-beta complex forms the non-decorated side of the cylinder, which can traverse the membrane from outside the cell to the cytoplasm. Based on these results, we propose that the Ca(2+) channel exhibits an asymmetric arrangement of auxiliary subunits.

COOH-terminal truncated alpha(1S) subunits conduct current better than full-length dihydropyridine receptors

Skeletal muscle dihydropyridine (DHP) receptors function both as voltage-activated Ca(2+) channels and as voltage sensors for coupling membrane depolarization to release of Ca(2+) from the sarcoplasmic reticulum. In skeletal muscle, the principal or alpha(1S) subunit occurs in full-length ( approximately 10% of total) and post-transcriptionally truncated ( approximately 90%) forms, which has raised the possibility that the two functional roles are subserved by DHP receptors comprised of different sized alpha(1S) subunits. We tested the functional properties of each form by injecting oocytes with cRNAs coding for full-length (alpha(1S)) or truncated (alpha(1SDeltaC)) alpha subunits. Both translation products were expressed in the membrane, as evidenced by increases in the gating charge (Q(max) 80-150 pC). Thus, oocytes provide a robust expression system for the study of gating charge movement in alpha(1S), unencumbered by contributions from other voltage-gated channels or the complexities of the transverse tubules. As in recordings from skeletal muscle, for heterologously expressed channels the peak inward Ba(2+) currents were small relative to Q(max). The truncated alpha(1SDeltaC) protein, however, supported much larger ionic currents than the full-length product. These data raise the possibility that DHP receptors containing the more abundant, truncated form of the alpha(1S) subunit conduct the majority of the L-type Ca(2+) current in skeletal muscle. Our data also suggest that the carboxyl terminus of the alpha(1S) subunit modulates the coupling between charge movement and channel opening.

Absence of the gamma subunit of the skeletal muscle dihydropyridine receptor increases L-type Ca2+ currents and alters channel inactivation properties

In skeletal muscle the oligomeric alpha(1S), alpha(2)/delta-1 or alpha(2)/delta-2, beta1, and gamma1 L-type Ca(2+) channel or dihydropyridine receptor functions as a voltage sensor for excitation contraction coupling and is responsible for the L-type Ca(2+) current. The gamma1 subunit, which is tightly associated with this Ca(2+) channel, is a membrane-spanning protein exclusively expressed in skeletal muscle. Previously, heterologous expression studies revealed that gamma1 might modulate Ca(2+) currents expressed by the pore subunit found in heart, alpha(1C), shifting steady state inactivation, and increasing current amplitude. To determine the role of gamma1 assembled with the skeletal subunit composition in vivo, we used gene targeting to establish a mouse model, in which gamma1 expression is eliminated. Comparing litter-matched mice with control mice, we found that, in contrast to heterologous expression studies, the loss of gamma1 significantly increased the amplitude of peak dihydropyridine-sensitive I(Ca) in isolated myotubes. Whereas the activation kinetics of the current remained unchanged, inactivation of the current was slowed in gamma1-deficient myotubes and, correspondingly, steady state inactivation of I(Ca) was shifted to more positive membrane potentials. These results indicate that gamma1 decreases the amount of Ca(2+) entry during stimulation of skeletal muscle.

Involvement of the carboxy-terminus region of the dihydropyridine receptor beta1a subunit in excitation-contraction coupling of skeletal muscle

Skeletal muscle knockout cells lacking the beta subunit of the dihydropyridine receptor (DHPR) are devoid of slow L-type Ca(2+) current, charge movements, and excitation-contraction coupling, despite having a normal Ca(2+) storage capacity and Ca(2+) spark activity. In this study we identified a specific region of the missing beta1a subunit critical for the recovery of excitation-contraction. Experiments were performed in beta1-null myotubes expressing deletion mutants of the skeletal muscle-specific beta1a, the cardiac/brain-specific beta2a, or beta2a/beta1a chimeras. Immunostaining was used to determine that all beta constructs were expressed in these cells. We examined the Ca(2+) conductance, charge movements, and Ca(2+) transients measured by confocal fluo-3 fluorescence of transfected myotubes under whole-cell voltage-clamp. All constructs recovered an L-type Ca(2+) current with a density, voltage-dependence, and kinetics of activation similar to that recovered by full-length beta1a. In addition, all constructs except beta2a mutants recovered charge movements with a density similar to full-length beta1a. Thus, all beta constructs became integrated into a skeletal-type DHPR and, except for beta2a mutants, all restored functional DHPRs to the cell surface at a high density. The maximum amplitude of the Ca(2+) transient was not affected by separate deletions of the N-terminus of beta1a or the central linker region of beta1a connecting two highly conserved domains. Also, replacement of the N-terminus half of beta1a with that of beta2a had no effect. However, deletion of 35 residues of beta1a at the C-terminus produced a fivefold reduction in the maximum amplitude of the Ca(2+) transients. A similar observation was made by deletion of the C-terminus of a chimera in which the C-terminus half was from beta1a. The identified domain at the C-terminus of beta1a may be responsible for colocalization of DHPRs and ryanodine receptors (RyRs), or may be required for the signal that opens the RyRs during excitation-contraction coupling. This new role of DHPR beta in excitation-contraction coupling represents a cell-specific function that could not be predicted on the basis of functional expression studies in heterologous cells.

Effects of mutations causing hypokalaemic periodic paralysis on the skeletal muscle L-type Ca2+ channel expressed in Xenopus laevis oocytes

1. A truncated form of the rabbit alpha1S Ca2+ channel subunit (alpha1SDeltaC) was expressed with the beta1b, alpha2delta and gamma auxiliary subunits in Xenopus laevis oocytes. After 5-7 days, skeletal muscle L-type currents were measured (469 +/- 48 nA in 10 mM Ba2+). All three of the auxiliary subunits were necessary to record significant L-type current. A rapidly inactivating, dihydropyridine-insensitive endogenous Ba2+ current was observed in oocytes expressing the auxiliary subunits without an exogenous alpha subunit. Expression of full-length alpha1S gave 10-fold smaller currents than the truncated form. 2. Three missense mutations causing hypokalaemic periodic paralysis (R528H in domain II S4 of the alpha1S subunit; R1239H and R1239G in domain IV S4) were introduced into alpha1SDeltaC and expressed in oocytes. L-type current was separated from the endogenous current by nimodipine subtraction. All three of the mutations reduced L-type current amplitude ( approximately 40 % for R528H, approximately 60-70 % for R1239H and R1239G). 3. The disease mutations altered the activation properties of L-type current. R528H shifted the G(V) curve approximately 5 mV to the left and modestly reduced the voltage dependence of the activation time constant, tauact. R1239H and R1239G shifted the G(V) curve approximately 5-10 mV to the right and dramatically slowed tauact at depolarized test potentials. 4. The voltage dependence of steady-state inactivation was not significantly altered by any of the disease mutations. 5. Wild-type and mutant L-type currents were also measured in the presence of (-)-Bay K8644, which boosted the amplitude approximately 5- to 7-fold. The effects of the mutations on the position of the G(V) curve and the voltage dependence of tauact were essentially the same as in the absence of agonist. Bay K-enhanced tail currents were slowed by R528H and accelerated by R1239H and R1239G. 6. We conclude that the domain IV mutations R1239H and R1239G have similar effects on the gating properties of the skeletal muscle L-type Ca2+ channel expressed in Xenopus oocytes, while the domain II mutation R528H has distinct effects. This result implies that the location of the substitutions is more important than their degree of conservation in determining their biophysical consequences.

The effect of alpha2-delta and other accessory subunits on expression and properties of the calcium channel alpha1G

1. The effect has been examined of the accessory alpha2-delta and beta subunits on the properties of alpha1G currents expressed in monkey COS-7 cells and Xenopus oocytes. 2. In immunocytochemical experiments, the co-expression of alpha2-delta increased plasma membrane localization of expressed alpha1G and conversely, the heterologous expression of alpha1G increased immunostaining for endogenous alpha2-delta, suggesting an interaction between the two subunits. 3. Heterologous expression of alpha2-delta together with alpha1G in COS-7 cells increased the amplitude of expressed alpha1G currents by about 2-fold. This finding was confirmed in the Xenopus oocyte expression system. The truncated delta construct did not increase alpha1G current amplitude, or increase its plasma membrane expression. This indicates that it is the exofacial alpha2 domain that is involved in the enhancement by alpha2-delta. 4. Beta1b also produced an increase of functional expression of alpha1G, either in the absence or the presence of heterologously expressed alpha2-delta, whereas the other beta subunits had much smaller effects. 5. None of the accessory subunits had any marked influence on the voltage dependence or kinetics of the expressed alpha1G currents. These results therefore suggest that alpha2-delta and beta1b interact with alpha1G to increase trafficking of, or stabilize, functional alpha1G channels expressed at the plasma membrane.

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.

Molecular cloning and functional expression of a skeletal muscle dihydropyridine receptor from Rana catesbeiana

In skeletal muscle the dihydropyridine receptor is the voltage sensor for excitation-contraction coupling and an L-type Ca2+ channel. We cloned a dihydropyridine receptor (named Fgalpha1S) from frog skeletal muscle, where excitation-contraction coupling has been studied most extensively. Fgalpha1S contains 5600 base pairs coding for 1688 amino acids. It is highly homologous with, and of the same length as, the C-truncated form predominant in rabbit muscle. The primary sequence has every feature needed to be an L-type Ca2+ channel and a skeletal-type voltage sensor. Currents expressed in tsA201 cells had rapid activation (5-10 ms half-time) and Ca2+-dependent inactivation. Although functional expression of the full Fgalpha1S was difficult, the chimera consisting of Fgalpha1S domain I in the rabbit cardiac Ca channel had high expression and a rapidly activating current. The slow native activation is therefore not determined solely by the alpha1 subunit sequence. Its Ca2+-dependent inactivation strengthens the notion that in rabbit skeletal muscle this capability is inhibited by a C-terminal stretch (Adams, B., and Tanabe, T. (1997) J. Gen. Physiol. 110, 379-389). This molecule constitutes a new tool for studies of excitation-contraction coupling, gating, modulation, and gene expression.

Mechanism of auxiliary subunit modulation of neuronal alpha1E calcium channels

Voltage-gated calcium channels are composed of a main pore-forming alpha1 moiety, and one or more auxiliary subunits (beta, alpha2 delta) that modulate channel properties. Because modulatory properties may vary greatly with different channels, expression systems, and protocols, it is advantageous to study subunit regulation with a uniform experimental strategy. Here, in HEK 293 cells, we examine the expression and activation gating of alpha1E calcium channels in combination with a beta (beta1-beta4) and/or the alpha2 delta subunit, exploiting both ionic- and gating-current measurements. Furthermore, to explore whether more than one auxiliary subunit can concomitantly specify gating properties, we investigate the effects of cotransfecting alpha2delta with beta subunits, of transfecting two different beta subunits simultaneously, and of COOH-terminal truncation of alpha1E to remove a second beta binding site. The main results are as follows. (a) The alpha2delta and beta subunits modulate alpha1E in fundamentally different ways. The sole effect of alpha2 delta is to increase current density by elevating channel density. By contrast, though beta subunits also increase functional channel number, they also enhance maximum open probability (Gmax/Qmax) and hyperpolarize the voltage dependence of ionic-current activation and gating-charge movement, all without discernible effect on activation kinetics. Different beta isoforms produce nearly indistinguishable effects on activation. However, beta subunits produced clear, isoform-specific effects on inactivation properties. (b) All the beta subunit effects can be explained by a gating model in which subunits act only on weakly voltage-dependent steps near the open state. (c) We find no clear evidence for simultaneous modulation by two different beta subunits. (d) The modulatory features found here for alpha1E do not generalize uniformly to other alpha1 channel types, as alpha1C activation gating shows marked beta isoform dependence that is absent for alpha1E. Together, these results help to establish a more comprehensive picture of auxiliary-subunit regulation of alpha1E calcium channels.

Regulation of ion channel expression by cytoplasmic subunits

Neuronal and cardiac voltage-gated ion channels contain auxiliary subunits that can profoundly affect the gating of the pore-forming and voltage-sensing alpha subunits. Recent studies on the structurally similar cytoplasmic beta subunits of Ca2+ and K+ channels reveal that these subunits can also exert profound effects on the expression of the integral membrane protein channel components. The mechanisms by which these effects occur are now being elucidated through a combined approach that employs biophysical, pharmacological, cell biological and biochemical techniques.

Differential effects of Ca2+ channel beta1a and beta2a subunits on complex formation with alpha1S and on current expression in tsA201 cells

To study the interactions of the alpha1S subunit of the skeletal muscle L-type Ca2+ channel with the skeletal beta1a and the cardiac beta2a, these subunits were expressed alone or in combination in tsA201 cells. Immunofluorescence- and green fluorescent protein-labeling showed that, when expressed alone, beta1a was diffusely distributed throughout the cytoplasm, beta2a was localized in the plasma membrane, and alpha1S was concentrated in a tubular/reticular membrane system, presumably the endoplasmic reticulum (ER). Upon coexpression with alpha1S, beta1a became colocalized with alpha1S in the ER. Upon coexpression with beta2a, alpha1S redistributed to the plasma membrane, where it aggregated in large clusters. Coexpression of alpha1S with beta1a but not with beta2a increased the frequency at which cells expressed L-type currents. A point mutation (alpha1S-Y366S) or deletion (alpha1S-Delta351-380) in the beta interaction domain of alpha1S blocked both translocation of beta1a to the ER and beta2a-induced translocation of the alpha1S mutants to the plasma membrane. However, the point mutation did not interfere with beta1a-induced current stimulation. Thus, beta1a and beta2a are differentially distributed in tsA201 cells and upon coexpression with alpha1S, form alpha1S. beta complexes in different cellular compartments. Complex formation but not current stimulation requires the intact beta interaction domain in the I-II cytoplasmic loop of alpha1S.