Oxygen-coupled Redox Regulation of the Skeletal Muscle Ryanodine Receptor/Ca2+ Release Channel (RyR1): SITES AND NATURE OF OXIDATIVE MODIFICATION*

In mammalian skeletal muscle, Ca²⁺ release from the sarcoplasmic reticulum (SR) through the ryanodine receptor/Ca²⁺-release channel RyR1 can be enhanced by S-oxidation or S-nitrosylation of separate Cys residues, which are allosterically linked. S-Oxidation of RyR1 is coupled to muscle oxygen tension (pO₂) through O₂-dependent production of hydrogen peroxide by SR-resident NADPH oxidase 4. In isolated SR (SR vesicles), an average of six to eight Cys thiols/RyR1 monomer are reversibly oxidized at high (21% O₂) versus low pO₂ (1% O₂), but their identity among the 100 Cys residues/RyR1 monomer is unknown. Here we use isotope-coded affinity tag labeling and mass spectrometry (yielding 93% coverage of RyR1 Cys residues) to identify 13 Cys residues subject to pO₂-coupled S-oxidation in SR vesicles. Eight additional Cys residues are oxidized at high versus low pO₂ only when NADPH levels are supplemented to enhance NADPH oxidase 4 activity. pO₂-sensitive Cys residues were largely non-overlapping with those identified previously as hyperreactive by administration of exogenous reagents (three of 21) or as S-nitrosylated. Cys residues subject to pO₂-coupled oxidation are distributed widely within the cytoplasmic domain of RyR1 in multiple functional domains implicated in RyR1 activity-regulating interactions with the L-type Ca²⁺ channel (dihydropyridine receptor) and FK506-binding protein 12 as well as in “hot spot” regions containing sites of mutation implicated in malignant hyperthermia and central core disease. pO₂-coupled disulfide formation was identified, whereas neither S-glutathionylated nor sulfenamide-modified Cys residues were observed. Thus, physiological redox regulation of RyR1 by endogenously generated hydrogen peroxide is exerted through dynamic disulfide formation involving multiple Cys residues.     

Impaired S-Nitrosylation of the Ryanodine Receptor Caused by Xanthine Oxidase Activity Contributes to Calcium Leak in Heart Failure

S-Nitrosylation is a ubiquitous post-translational modification that regulates diverse biologic processes. In skeletal muscle, hypernitrosylation of the ryanodine receptor (RyR) causes sarcoplasmic reticulum (SR) calcium leak, but whether abnormalities of cardiac RyR nitrosylation contribute to dysfunction of cardiac excitation-contraction coupling remains controversial. In this study, we tested the hypothesis that cardiac RyR2 is hyponitrosylated in heart failure, because of nitroso-redox imbalance. We evaluated excitation-contraction coupling and nitroso-redox balance in spontaneously hypertensive heart failure rats with dilated cardiomyopathy and age-matched Wistar-Kyoto rats. Spontaneously hypertensive heart failure myocytes were characterized by depressed contractility, increased diastolic Ca²⁺ leak, hyponitrosylation of RyR2, and enhanced xanthine oxidase derived superoxide. Global S-nitrosylation was decreased in failing hearts compared with nonfailing. Xanthine oxidase inhibition restored global and RyR2 nitrosylation and reversed the diastolic SR Ca²⁺ leak, improving Ca²⁺ handling and contractility. Together these findings demonstrate that nitroso-redox imbalance causes RyR2 oxidation, hyponitrosylation, and SR Ca²⁺ leak, a hallmark of cardiac dysfunction. The reversal of this phenotype by inhibition of xanthine oxidase has important pathophysiologic and therapeutic implications.     

Distinct Components of Retrograde CaV1.1-RyR1 Coupling Revealed by a Lethal Mutation in RyR1

The molecular basis for excitation-contraction coupling in skeletal muscle is generally thought to involve conformational coupling between the L-type voltage-gated Ca²⁺ channel (Ca_V1.1) and the type 1 ryanodine receptor (RyR1). This coupling is bidirectional; in addition to the orthograde signal from Ca_V1.1 to RyR1 that triggers Ca²⁺ release from the sarcoplasmic reticulum, retrograde signaling from RyR1 to Ca_V1.1 results in increased amplitude and slowed activation kinetics of macroscopic L-type Ca²⁺ current. Orthograde coupling was previously shown to be ablated by a glycine for glutamate substitution at RyR1 position 4242. In this study, we investigated whether the RyR1-E4242G mutation affects retrograde coupling. L-type current in myotubes homozygous for RyR1-E4242G was substantially reduced in amplitude (∼80%) relative to that observed in myotubes from normal control (wild-type and/or heterozygous) myotubes. Analysis of intramembrane gating charge movements and ionic tail current amplitudes indicated that the reduction in current amplitude during step depolarizations was a consequence of both decreased Ca_V1.1 membrane expression (∼50%) and reduced channel P_o (∼55%). In contrast, activation kinetics of the L-type current in RyR1-E4242G myotubes resembled those of normal myotubes, unlike dyspedic (RyR1 null) myotubes in which the L-type currents have markedly accelerated activation kinetics. Exogenous expression of wild-type RyR1 partially restored L-type current density. From these observations, we conclude that mutating residue E4242 affects RyR1 structures critical for retrograde communication with Ca_V1.1. Moreover, we propose that retrograde coupling has two distinct and separable components that are dependent on different structural elements of RyR1.     

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 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.     

Calcium signaling in insulin action on striated muscle

Striated muscles (skeletal and cardiac) are major physiological targets of insulin and this hormone triggers complex signaling pathways regulating cell growth and energy metabolism. Insulin increases glucose uptake into muscle cells by stimulating glucose transporter (GLUT4) translocation from intracellular compartments to the cell surface. The canonical insulin-triggered signaling cascade controlling this process is constituted by well-mapped tyrosine, lipid and serine/threonine phosphorylation reactions. In parallel to these signals, recent findings reveal insulin-dependent Ca²⁺ mobilization in skeletal muscle cells and cardiomyocytes. Specifically, insulin activates the sarco-endoplasmic reticulum (SER) channels that release Ca²⁺ into the cytosol i.e., the Ryanodine Receptor (RyR) and the inositol 1,4,5-triphosphate receptor (IP₃R). In skeletal muscle cells, a rapid, insulin-triggered Ca²⁺ release occurs through RyR, that is brought about upon S-glutathionylation of cysteine residues in the channel by reactive oxygen species (ROS) produced by the early activation of the NADPH oxidase (NOX2). In cardiomyocytes insulin induces a fast and transient increase in cytoplasmic [Ca²⁺]_i trough L-type Ca²⁺ channels activation. In both cell types, a relatively slower Ca²⁺ release also occurs through IP₃R activation, and is required for GLUT4 translocation and glucose uptake. The insulin-dependent Ca²⁺ released from IP₃R of skeletal muscle also promotes mitochondrial Ca²⁺ uptake. We review here these actions of insulin on intracellular Ca²⁺ channel activation and their impact on GLUT4 traffic in muscle cells, as well as other implications of insulin-dependent Ca²⁺ release from the SER.     

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.     

A CaV1.1 Ca Channel Splice Variant with High Conductance and Voltage-Sensitivity Alters EC Coupling in Developing Skeletal Muscle

The Ca²⁺ channel α_1S subunit (Ca_V1.1) is the voltage sensor in skeletal muscle excitation-contraction (EC) coupling. Upon membrane depolarization, this sensor rapidly triggers Ca²⁺ release from internal stores and conducts a slowly activating Ca²⁺ current. However, this Ca²⁺ current is not essential for skeletal muscle EC coupling. Here, we identified a Ca_V1.1 splice variant with greatly distinct current properties. The variant of the CACNA1S gene lacking exon 29 was expressed at low levels in differentiated human and mouse muscle, and up to 80% in myotubes. To test its biophysical properties, we deleted exon 29 in a green fluorescent protein (GFP)-tagged α_1S subunit and expressed it in dysgenic (α_1S-null) myotubes. GFP-α_1SΔ29 was correctly targeted into triads and supported skeletal muscle EC coupling. However, the Ca²⁺ currents through GFP-α_1SΔ29 showed a 30-mV left-shifted voltage dependence of activation and a substantially increased open probability, giving rise to an eightfold increased current density. This robust Ca²⁺ influx contributed substantially to the depolarization-induced Ca²⁺ transient that triggers contraction. Moreover, deletion of exon 29 accelerated current kinetics independent of the auxiliary α₂δ-1 subunit. Thus, characterizing the Ca_V1.1Δ29 splice variant revealed the structural bases underlying the specific gating properties of skeletal muscle Ca²⁺ channels, and it suggests the existence of a distinct mode of EC coupling in developing muscle.     

Regulation of the RyR channel gating by Ca<Superscript>2+</Superscript> and Mg<Superscript>2+</Superscript>

Ryanodine receptors (RyRs) are the Ca²⁺ release channels in the sarcoplasmic reticulum in striated muscle which play an important role in excitation-contraction coupling and cardiac pacemaking. Single channel recordings have revealed a wealth of information about ligand regulation of RyRs from mammalian skeletal and cardiac muscle (RyR1 and RyR2, respectively). RyR subunit has a Ca²⁺ activation site located in the luminal and cytoplasmic domains of the RyR. These sites synergistically feed into a common gating mechanism for channel activation by luminal and cytoplasmic Ca²⁺. RyRs also possess two inhibitory sites in their cytoplasmic domains with Ca²⁺ affinities of the order of 1 μM and 1 mM. Magnesium competes with Ca²⁺ at these sites to inhibit RyRs and this plays an important role in modulating their Ca²⁺-dependent activity in muscle. This review focuses on how these sites lead to RyR modulation by Ca²⁺ and Mg²⁺ and how these mechanisms control Ca²⁺ release in excitation-contraction coupling and cardiac pacemaking.     

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.     

β1a490–508, a 19-Residue Peptide from C-Terminal Tail of Cav1.1 β1a Subunit,Potentiates Voltage-Dependent Calcium Release in Adult Skeletal Muscle Fibers

The α1 and β1a subunits of the skeletal muscle calcium channel, Cav1.1, as well as the Ca²⁺ release channel, ryanodine receptor (RyR1), are essential for excitation-contraction coupling. RyR1 channel activity is modulated by the β1a subunit and this effect can be mimicked by a peptide (β1a490–524) corresponding to the 35-residue C-terminal tail of the β1a subunit. Protein-protein interaction assays confirmed a high-affinity interaction between the C-terminal tail of the β1a and RyR1. Based on previous results using overlapping peptides tested on isolated RyR1, we hypothesized that a 19-amino-acid residue peptide (β1a490–508) is sufficient to reproduce activating effects of β1a490–524. Here we examined the effects of β1a490–508 on Ca²⁺ release and Ca²⁺ currents in adult skeletal muscle fibers subjected to voltage-clamp and on RyR1 channel activity after incorporating sarcoplasmic reticulum vesicles into lipid bilayers. β1a490–508 (25 nM) increased the peak Ca²⁺ release flux by 49% in muscle fibers. Considerably fewer activating effects were observed using 6.25, 100, and 400 nM of β1a490–508 in fibers. β1a490–508 also increased RyR1 channel activity in bilayers and Cav1.1 currents in fibers. A scrambled form of β1a490–508 peptide was used as negative control and produced negligible effects on Ca²⁺ release flux and RyR1 activity. Our results show that the β1a490–508 peptide contains molecular components sufficient to modulate excitation-contraction coupling in adult muscle fibers.     

Amino Acid Residues 489–503 of Dihydropyridine Receptor (DHPR) β1a Subunit Are Critical for Structural Communication between the Skeletal Muscle DHPR Complex and Type 1 Ryanodine Receptor

The β_1a subunit is a cytoplasmic component of the dihydropyridine receptor (DHPR) complex that plays an essential role in skeletal muscle excitation-contraction (EC) coupling. Here we investigate the role of the C-terminal end of this auxiliary subunit in the functional and structural communication between the DHPR and the Ca²⁺ release channel (RyR1). Progressive truncation of the β_1a C terminus showed that deletion of amino acid residues Gln⁴⁸⁹ to Trp⁵⁰³ resulted in a loss of depolarization-induced Ca²⁺ release, a severe reduction of L-type Ca²⁺ currents, and a lack of tetrad formation as evaluated by freeze-fracture analysis. However, deletion of this domain did not affect expression/targeting or density (Q_max) of the DHPR-α_1S subunit to the plasma membrane. Within this motif, triple alanine substitution of residues Leu⁴⁹⁶, Leu⁵⁰⁰, and Trp⁵⁰³, which are thought to mediate direct β_1a-RyR1 interactions, weakened EC coupling but did not replicate the truncated phenotype. Therefore, these data demonstrate that an amino acid segment encompassing sequence ⁴⁸⁹QVQVLTSLRRNLSFW⁵⁰³ of β_1a contains critical determinant(s) for the physical link of DHPR and RyR1, further confirming a direct correspondence between DHPR positioning and DHPR/RyR functional interactions. In addition, our data strongly suggest that the motif Leu⁴⁹⁶-Leu⁵⁰⁰-Trp⁵⁰³ within the β_1a C-terminal tail plays a nonessential role in the bidirectional DHPR/RyR1 signaling that supports skeletal-type EC coupling.     

β1a490–508, a 19-Residue Peptide from C-Terminal Tail of Cav1.1 β1a Subunit,Potentiates Voltage-Dependent Calcium Release in Adult Skeletal Muscle Fibers

The α1 and β1a subunits of the skeletal muscle calcium channel, Cav1.1, as well as the Ca²⁺ release channel, ryanodine receptor (RyR1), are essential for excitation-contraction coupling. RyR1 channel activity is modulated by the β1a subunit and this effect can be mimicked by a peptide (β1a490–524) corresponding to the 35-residue C-terminal tail of the β1a subunit. Protein-protein interaction assays confirmed a high-affinity interaction between the C-terminal tail of the β1a and RyR1. Based on previous results using overlapping peptides tested on isolated RyR1, we hypothesized that a 19-amino-acid residue peptide (β1a490–508) is sufficient to reproduce activating effects of β1a490–524. Here we examined the effects of β1a490–508 on Ca²⁺ release and Ca²⁺ currents in adult skeletal muscle fibers subjected to voltage-clamp and on RyR1 channel activity after incorporating sarcoplasmic reticulum vesicles into lipid bilayers. β1a490–508 (25 nM) increased the peak Ca²⁺ release flux by 49% in muscle fibers. Considerably fewer activating effects were observed using 6.25, 100, and 400 nM of β1a490–508 in fibers. β1a490–508 also increased RyR1 channel activity in bilayers and Cav1.1 currents in fibers. A scrambled form of β1a490–508 peptide was used as negative control and produced negligible effects on Ca²⁺ release flux and RyR1 activity. Our results show that the β1a490–508 peptide contains molecular components sufficient to modulate excitation-contraction coupling in adult muscle fibers.     

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.     

A model of the physiological basis of a multivariate phenotype that is mediated by Ca(2+) signaling and controlled by ryanodine receptor composition

Calcium-signals occur in a wide variety of tissue types - from skeletal, smooth and cardiac muscle to pancreatic and brain tissues. Ca²⁺ signals regulate diverse processes including muscle contraction, hormone secretion, neural communication and gene expression. Together these different tissues and processes form the basis of a multivariate trait. Calcium signals are characterized by Ca²⁺ transients, which are sharp increases in Ca²⁺ concentration over a short period of time. In this paper we derive and analyze a model of Ca²⁺ transients for skeletal muscle, neurons and cardiac tissue based on underlying biophysical principles. Tissue differentiation in our model and in nature comes about by varying the ryanodine receptor (RyR) channel composition of tissues. In vertebrates, there are typically three types of RyR channels (labeled RyR1, RyR2 and RyR3 in mammals and α‐RyR, cardiac-RyR and β‐RyR in birds, amphibians and fish). Different compositions of these three RyR channels generate different Ca²⁺ transient properties. There are four Ca²⁺ transient properties that we measure: maximum amplitude, duration, half duration (D₅₀) and integrated concentration. In agreement with experimental work, our results find that the addition of RyR3 amplifies Ca²⁺ transients in skeletal muscle. An important consequence of shared molecular components between tissue types in a multivariate setting is that the shared components cause individual traits of a multivariate trait to be correlated in function. Here we show how correlations in Ca²⁺ transient properties between tissues can be predicted using an underlying biophysical model.     

Effects of conformational peptide probe DP4 on bidirectional signaling between DHPR and RyR1 calcium channels in voltage-clamped skeletal muscle fibers

In skeletal muscle, excitation-contraction coupling involves the activation of dihydropyridine receptors (DHPR) and type-1 ryanodine receptors (RyR1) to produce depolarization-dependent sarcoplasmic reticulum Ca²⁺ release via orthograde signaling. Another form of DHPR-RyR1 communication is retrograde signaling, in which RyRs modulate the gating of DHPR. DP4 (domain peptide 4), is a peptide corresponding to residues Leu²⁴⁴²-Pro²⁴⁷⁷ of the central domain of the RyR1 that produces RyR1 channel destabilization. Here we explore the effects of DP4 on orthograde excitation-contraction coupling and retrograde RyR1-DHPR signaling in isolated murine muscle fibers. Intracellular dialysis of DP4 increased the peak amplitude of Ca²⁺ release during step depolarizations by 64% without affecting its voltage-dependence or kinetics, and also caused a similar increase in Ca²⁺ release during an action potential waveform. DP4 did not modify either the amplitude or the voltage-dependence of the intramembrane charge movement. However, DP4 augmented DHPR Ca²⁺ current density without affecting its voltage-dependence. Our results demonstrate that the conformational changes induced by DP4 regulate both orthograde E-C coupling and retrograde RyR1-DHPR signaling.     

Alternative splicing of RyR1 alters the efficacy of skeletal EC coupling

Alternative splicing of ASI residues (Ala³⁴⁸¹–Gln³⁴⁸⁵) in the skeletal muscle ryanodine receptor (RyR1) is developmentally regulated: the residues are present in adult ASI(+)RyR1, but absent in the juvenile ASI(?)RyR1 which is over-expressed in adult myotonic dystrophy type 1 (DM1). Although this splicing switch may influence RyR1 function in developing muscle and DM1, little is known about the properties of the splice variants. We examined excitation-contraction (EC) coupling and the structure and interactions of the ASI domain (Thr³⁴⁷¹–Gly³⁵⁰⁰) in the splice variants. Depolarisation-dependent Ca²⁺ release was enhanced by >50% in myotubes expressing ASI(?)RyR1 compared with ASI(+)RyR1, although DHPR L-type currents and SR Ca²⁺ content were unaltered, while ASI(?)RyR1 channel function was actually depressed. The effect on EC coupling did not depend on changes in ASI domain secondary structure. Probing RyR1 function with peptides possessing the ASI domain sequence indicated that the domain contributes to an inhibitory module in RyR1. The action of the peptide depended on a sequence of basic residues and their alignment in an α-helix adjacent to the ASI splice site. This is the first evidence that the ASI residues contribute to an inhibitory module in RyR1 that influences EC coupling. Implications for development and DM1 are discussed.     

Two ryanodine receptor isoforms in nonmammalian vertebrate skeletal muscle: possible roles in excitation-contraction coupling and other processes

The ryanodine receptor (RyR) is a Ca²⁺ release channel in the sarcoplasmic reticulum in vertebrate skeletal muscle and plays an important role in excitation–contraction (E–C) coupling. Whereas mammalian skeletal muscle predominantly expresses a single RyR isoform, RyR1, skeletal muscle of many nonmammalian vertebrates expresses equal amounts of two distinct isoforms, α-RyR and β-RyR, which are homologues of mammalian RyR1 and RyR3, respectively. In this review we describe our current understanding of the functions of these two RyR isoforms in nonmammalian vertebrate skeletal muscle. The Ca²⁺ release via the RyR channel can be gated by two distinct modes: depolarization-induced Ca²⁺ release (DICR) and Ca²⁺-induced Ca²⁺ release (CICR). In frog muscle, α-RyR acts as the DICR channel, whereas β-RyR as the CICR channel. However, several lines of evidence suggest that CICR by β-RyR may make only a minor contribution to Ca²⁺ release during E–C coupling. Comparison of frog and mammalian RyR isoforms highlights the marked differences in the patterns of Ca²⁺ release mediated by RyR1 and RyR3 homologues. Interestingly, common features in the Ca²⁺ release patterns are noticed between β-RyR and RyR1. We will discuss possible roles and significance of the two RyR isoforms in E–C coupling and other processes in nonmammalian vertebrate skeletal muscle.     

Molecular Basis of Regulating High Voltage-Activated Calcium Channels by S-Nitrosylation

Nitric oxide (NO) is involved in a variety of physiological processes, such as vasoregulation and neurotransmission, and has a complex role in the regulation of pain transduction and synaptic transmission. We have shown previously that NO inhibits high voltage-activated Ca²⁺ channels in primary sensory neurons and excitatory synaptic transmission in the spinal dorsal horn. However, the molecular mechanism involved in this inhibitory action remains unclear. In this study, we investigated the role of S-nitrosylation in the NO regulation of high voltage-activated Ca²⁺ channels. The NO donor S-nitroso-N-acetyl-dl-penicillamine (SNAP) rapidly reduced N-type currents when Cav2.2 was coexpressed with the Cavβ1 or Cavβ3 subunits in HEK293 cells. In contrast, SNAP only slightly inhibited P/Q-type and L-type currents reconstituted with various Cavβ subunits. SNAP caused a depolarizing shift in voltage-dependent N-type channel activation, but it had no effect on Cav2.2 protein levels on the membrane surface. The inhibitory effect of SNAP on N-type currents was blocked by the sulfhydryl-specific modifying reagent methanethiosulfonate ethylammonium. Furthermore, the consensus motifs of S-nitrosylation were much more abundant in Cav2.2 than in Cav1.2 and Cav2.1. Site-directed mutagenesis studies showed that Cys-805, Cys-930, and Cys-1045 in the II-III intracellular loop, Cys-1835 and Cys-2145 in the C terminus of Cav2.2, and Cys-346 in the Cavβ3 subunit were nitrosylation sites mediating NO sensitivity of N-type channels. Our findings demonstrate that the consensus motifs of S-nitrosylation in cytoplasmically accessible sites are critically involved in post-translational regulation of N-type Ca²⁺ channels by NO. S-Nitrosylation mediates the feedback regulation of N-type channels by NO.     

Dihydropyridine receptor-ryanodine receptor interactions in skeletal muscle excitation-contraction coupling

Much recent progress has been made in our understanding of the mechanism of sarcoplasmic reticulum Ca²⁺ release in skeletal muscle. Vertebrate skeletal muscle excitation-contraction (E-C) coupling is thought to occur by a mechanical coupling mechanism involving protein-protein interactions that lead to activation of the sarcoplasmic reticulum (SR) ryanodine receptor (RyR)/Ca²⁺ release channel by the voltage-sensing transverse (T–) tubule dihydropyridine receptor (DHPR)/Ca²⁺ channel. In a subsequent step, the released Ca²⁺ amplify SR Ca²⁺ release by activating release channels that are not linked to the DHPR. Experiments with mutant muscle cells have indicated that skeletal muscle specific DHPR and RyR isoforms are required for skeletal muscle E-C coupling. A direct functional and structural interaction between a DHPR-derived peptide and the RyR has been described. The interaction between the DHPR and RyR may be stabilized by other proteins such as triadin (a SR junctional protein) and modulated by phosphorylation of the DHPR.