Unique phosphorylation site on the cardiac ryanodine receptor regulates calcium channel activity.

Ryanodine receptors have recently been shown to be the Ca2+ release channels of sarcoplasmic reticulum in both cardiac muscle and skeletal muscle. Several regulatory sites are postulated to exist on these receptors, but to date, none have been definitively identified. In the work described here, we localize one of these sites by showing that the cardiac isoform of the ryanodine receptor is a preferred substrate for multifunctional Ca2+/calmodulin-dependent protein kinase (CaM kinase). Phosphorylation by CaM kinase occurs at a single site encompassing serine 2809. Antibodies generated to this site react only with the cardiac isoform of the ryanodine receptor, and immunoprecipitate only cardiac [3H]ryanodine-binding sites. When cardiac junctional sarcoplasmic reticulum vesicles or partially purified ryanodine receptors are fused with planar bilayers, phosphorylation at this site activates the Ca2+ channel. In tissues expressing the cardiac isoform of the ryanodine receptor, such as heart and brain, phosphorylation of the Ca2+ release channel by CaM kinase may provide a unique mechanism for regulating intracellular Ca2+ release.     

Effects of azumolene on doxorubicin-induced Ca2+ release from skeletal and cardiac muscle sarcoplasmic reticulum

The mechanism of doxorubicin-induced Ca2+ release from skeletal and cardiac muscle sarcoplasmic reticulum (SR) was studied by examining the effects of azumolene (a water soluble dantrolene analog) on doxorubicin-mediated Ca2+ release and ryanodine binding. Doxorubicin induced a rapid Ca2+ release from both skeletal and cardiac SR in a similar concentration range (EC50 = 5-10 microM). Maximal doxorubicin-induced Ca2+ release was seen at 2 and 0.2 microM Ca2+ for skeletal and cardiac SR, respectively. Addition of 400 microM azumolene caused approx. 30% inhibition of doxorubicin-induced Ca2+ release from both skeletal and cardiac SR; skeletal SR had significantly higher sensitivity to azumolene than cardiac SR. In the presence of Ca2+, doxorubicin increased [3H]ryanodine binding to both skeletal and cardiac SR; whereas in the absence of Ca2+, doxorubicin led to significant ryanodine binding to skeletal SR, but not to cardiac SR. In both types of SR, doxorubicin-activated, but not Ca2+ activated ryanodine binding was inhibited by azumolene. Azumolene sensitivity for inhibition of doxorubicin-activated ryanodine binding was much higher in skeletal SR than cardiac SR, consistent with the results for effects of azumolene on Ca2+ release. Our results are consistent with the possibility that azumolene inhibits doxorubicin binding by direct competition for the drug receptor(s).     

Identification and characterization of the high affinity [3H]ryanodine receptor of the junctional sarcoplasmic reticulum Ca2+ release channel

The high affinity ryanodine receptor of the Ca2+ release channel from junctional sarcoplasmic reticulum of rabbit skeletal muscle has been identified and characterized using monoclonal antibodies. Anti-ryanodine receptor monoclonal antibody XA7 specifically immunoprecipitated [3H]ryanodine-labeled receptor from digitonin-solubilized triads in a dose-dependent manner. [3H]Ryanodine binding to the immunoprecipitated receptor from unlabeled digitonin-solubilized triads was specific, Ca2+-dependent, stimulated by millimolar ATP, and inhibited by micromolar ruthenium red. Indirect immunoperoxidase staining of nitrocellulose blots of various skeletal muscle membrane fractions has demonstrated that anti-ryanodine receptor monoclonal antibody XA7 recognizes a high molecular weight protein (approximately 350,000 Da) which is enriched in isolated triads but absent from light sarcoplasmic reticulum vesicles and transverse tubular membrane vesicles. Thus, our results demonstrate that monoclonal antibodies to the approximately 350,000-Da junctional sarcoplasmic reticulum protein immunoprecipitated the ryanodine receptor with properties identical to those expected for the ryanodine receptor of the Ca2+ release channel.     

Rose bengal activates the Ca2+ release channel from skeletal muscle sarcoplasmic reticulum.

The photooxidizing xanthene dye rose bengal (10 nM to 1 microM) stimulates rapid Ca2+ release from skeletal muscle sarcoplasmic reticulum vesicles. Following fusion of sarcoplasmic reticulum (SR) vesicles to an artificial bilayer, reconstituted Ca2+ channel activity is stimulated by nanomolar concentrations of rose bengal in the presence of a broad-spectrum light source. Rose bengal does not appear to affect K+ channels present in the SR. Following reconstitution of the sulfhydryl-activated 106-kDa Ca2+ channel protein into a bilayer, rose bengal activates the isolated protein in a light-dependent manner. Ryanodine at a concentration of 10 nM is shown to lock the 106-kDa channel protein in a subconductance state which can be reversed by subsequent addition of 500 nM rose bengal. This apparent displacement of bound ryanodine by nanomolar concentrations of rose bengal is also directly observed upon measurement of [3H]ryanodine binding to JSR vesicles. These observations indicate that photooxidation of rose bengal causes a stimulation of the Ca2+ release protein from skeletal muscle sarcoplasmic reticulum by interacting with the ryanodine binding site. Furthermore, similar effects of rose bengal on isolated SR vesicles, on single channel measurements following fusion of SR vesicles, and following incorporation of the isolated 106-kDa protein strongly implicates the 106-kDa sulfhydryl-activated Ca2+ channel protein in the Ca2+ release process.     

Ryanodine binding to sarcoplasmic reticulum membrane; comparison between cardiac and skeletal muscle

[3H]Ryanodine binding to skeletal muscle and cardiac sarcoplasmic reticulum (SR) vesicles was compared under experimental conditions known to inhibit or stimulate Ca2+ release. In the skeletal muscle SR, ryanodine binds to a single class of high-affinity sites (Kd of 11.3 nM). In cardiac SR vesicles, more than one class of binding sites is observed (Kd values of 3.6 and 28.1 nM). Ryanodine binding to skeletal muscle SR vesicles requires high concentrations of NaCl, whereas binding of the drug to cardiac SR is only slightly influenced by ionic strength. In the presence of 5'-adenylyl imidodiphosphate (p[NH]ppA), increased pH, and micromolar concentration of Ca2+ (which all induce Ca2+ release from SR) binding of ryanodine to SR is significantly increased in skeletal muscle, while being unchanged in cardiac muscle. Ryanodine binding to skeletal but not to cardiac muscle SR is inhibited in the presence of high Ca2+ or Mg2+ concentrations (all known to inhibit Ca2+ release from skeletal muscle SR). Ruthenium red or dicyclohexylcarbodiimide modification of cardiac and skeletal muscle SR inhibit Ca2+ release and ryanodine binding in both skeletal and cardiac membranes. These results indicate that significant differences exist in the properties of ryanodine binding to skeletal or cardiac muscle SR. Our data suggest that ryanodine binds preferably to site(s) which are accessible only when the Ca2+ release channel is in the open state.     

Ryanodine-affinity chromatography purifies 106 kD Ca release channels from skeletal and cardiac sarcoplasmic reticulum

A 106 kD protein was isolated from skeletal sarcoplasmic reticulum (SR) vesicles and shown to have the properties of SR Ca2+ release channels, including blockade by 5 nM ryanodine. In view of extensive reports that the ryanodine-receptor complex consists of four 565 kD junctional feet proteins (JFPs) and is the 'physiological' Ca2+ release channel, we prepared ryanodine-affinity columns to isolate its receptor site(s). Conditions known to maximize the association and dissociation of ryanodine to SR proteins were respectively used to link, then elute, the receptor(s) from ryanodine-affinity columns. The method purified a protein at about 100 kD from both rabbit skeletal and canine cardiac SR vesicles. The skeletal and cardiac proteins isolated by ryanodine-affinity chromatography were identified as the low molecular weight Ca2+ release channel through their antigenic reaction with an anti-106 kD monoclonal antibody. Upon reconstitution in planar bilayers, both skeletal and cardiac proteins revealed the presence of functional SR Ca2+ release channels. Surprisingly, ryanodine-affinity columns did not retain JFPs but purified 106 kD Ca2+ release channels which are a minor component (0.1-0.3%) of SR proteins.     

The 30 S lobster skeletal muscle Ca2+ release channel (ryanodine receptor) has functional properties distinct from the mammalian channel proteins.

The 3-[(3-cholamidopropyl)dimethylammonio]-1-propanesulfonate (Chaps)-solubilized ryanodine receptor (RyR) of lobster skeletal muscle has been isolated by rate density centrifugation as a 30 S protein complex. Sodium dodecyl sulfate-polyacrylamide gel electrophoretic analysis of the purified 30 S receptor revealed a single high molecular weight protein band with a mobility intermediate between those of the mammalian skeletal and cardiac M(r) 565,000 RyR polypeptides. Immunoblot analysis showed no or only minimal cross-reactivity with the rabbit skeletal and canine cardiac RyR polypeptides. By immunofluorescence the lobster RyR was localized to the junctions of the A-I bands. Following planar lipid bilayer reconstitution of the purified 30 S lobster RyR, single channel K+ and Ca2+ currents were observed which were modified by ryanodine and optimally activated by millimolar concentrations of cis (cytoplasmic) Ca2+. Vesicle-45Ca2+ flux measurements also indicated an optimal activation of the lobster Ca2+ channel by millimolar Ca2+, whereas 45Ca2+ efflux from mammalian skeletal and cardiac muscle sarcoplasmic reticulum (SR) vesicles is optimally activated by micromolar Ca2+. Further, mammalian muscle SR Ca2+ release activity is modulated by Mg2+ and ATP, whereas neither ligand appreciably affected 45Ca2+ efflux from lobster SR vesicles. These results suggested that lobster and mammalian muscle express immunologically and functionally distinct SR Ca2+ release channel protein complexes.     

Purified ryanodine receptor from skeletal muscle sarcoplasmic reticulum is the Ca2+-permeable pore of the calcium release channel

The ryanodine receptor of rabbit skeletal muscle sarcoplasmic reticulum was purified by immunoaffinity chromatography as a single approximately 450,000-Da polypeptide and it was shown to mediate single channel activity identical to that of the ryanodine-treated Ca2+ release channel of the sarcoplasmic reticulum. The purified receptor had a [3H]ryanodine binding capacity (Bmax) of 280 pmol/mg and a binding affinity (Kd) of 9.0 nM. [3H]Ryanodine binding to the purified receptor was stimulated by ATP and Ca2+ with a half-maximal stimulation at 1 mM and 8-9 microM, respectively. [3H]Ryanodine binding to the purified receptor was inhibited by ruthenium red and high concentrations of Ca2+ with an IC50 of 2.5 microM and greater than 1 mM, respectively. Reconstitution of the purified receptor in planar lipid bilayers revealed the Ca2+ channel activity of the purified receptor. Like the native sarcoplasmic reticulum Ca2+ channels treated with ryanodine, the purified receptor channels were characterized by (i) the predominance of long open states insensitive to Mg2+ and ruthenium red, (ii) a main slope conductance of approximately 35 pS and a less frequent 22 pS substate in 54 mM trans-Ca2+ or Ba2+, and (iii) a permeability ratio PBa or PCa/PTris = 8.7. The approximately 450,000-Da ryanodine receptor channel thus represents the long-term open "ryanodine-altered" state of the Ca2+ release channel from sarcoplasmic reticulum. We propose that the ryanodine receptor constitutes the physical pore that mediates Ca2+ release from the sarcoplasmic reticulum of skeletal muscle.     

The calcium-ryanodine receptor complex of skeletal and cardiac muscle

[3H]Ryanodine binds with high affinity to saturable and Ca2+-dependent sites in heavy sarcoplasmic reticulum (SR) preparations from rabbit skeletal and cardiac muscle. Ruthenium red, known to interfere with Ca2+-induced Ca2+ release from SR vesicles, inhibits [3H]ryanodine specific binding in both skeletal and cardiac preparations whereas Mg2+, Ba2+, Cd2+ and La3+ selectively inhibit the skeletal preparation. The toxicological relevance of the [3H]ryanodine binding site is established by the correlation of binding inhibition with toxicity for seven ryanoids including two botanical insecticides. These findings provide direct evidence for Ca2+-ryanodine receptor complexes that may play a role in excitation-contraction coupling.     

Regulation of Ca2+ release from internal stores in cardiac and skeletal muscles

It is widely accepted that Ca2+ is released from the sarcoplasmic reticulum by a specialized type of calcium channel, i.e., ryanodine receptor, by the process of Ca2+-induced Ca2+ release. This process is triggered mainly by dihydropyridine receptors, i.e., L-type (long lasting) calcium channels, directly or indirectly interacting with ryanodine receptor. In addition, multiple endogenous and exogenous compounds were found to modulate the activity of both types of calcium channels, ryanodine and dihydropyridine receptors. These compounds, by changing the Ca2+ transport activity of these channels, are able to influence intracellular Ca2+ homeostasis. As a result not only the overall Ca2+ concentration becomes affected but also spatial distribution of this ion in the cell. In cardiac and skeletal muscles the release of Ca2+ from internal stores is triggered by the same transport proteins, although by their specific isoforms. Concomitantly, heart and skeletal muscle specific regulatory mechanisms are different.     

Excitation-contraction coupling in cardiac muscle revisited.

According to the current views the direct and indispensable source of Ca2+ activating contraction is sarcoplasmic reticulum (SR). Ca2+ is released from the SR when its release channels (ryanodine receptors) are activated by Ca2+ influx through the L-type Ca2+ channels (dihydropyridine receptors). In contrast, ryanodine receptors of skeletal muscles are activated by conformational changes in dihydropyridine receptors induced by sarcolemmal voltage. Ca2+ influx is not necessary for their activation. In this review the papers not quite conforming with the current views are referred to and discussed. Their results suggest that SR is not an indispensable source of contractile Ca2+ at least in some mammalian species, and that cardiac ryanodine receptors may be activated by conformational changes in dihydropyridine receptors without Ca2+ influx (like in skeletal muscle). This may be a mechanism parallel to or accessory to the Ca2+ induced release of Ca2+ (CIRC).     

Reconstitution of purified cardiac muscle calcium release channel (ryanodine receptor) in planar bilayers

The purified ryanodine receptor of heart sarcoplasmic reticulum (SR) has been reconstituted into planar phospholipid bilayers and found to form Ca2+-specific channels. The channels are strongly activated by Ca2+ (10 nM) in the presence of ATP (1 mM) and ryanodine, and inactivated by Mg2+ (3 mM) or ruthenium red (30 microM). These characteristics are diagnostic of calcium release from heart SR. The cardiac ryanodine receptor, which has previously been identified as the foot structure, is now identified as the calcium release channel. A similar identity of the calcium release channel has recently been reported for skeletal muscle. The characteristics of the calcium release channel from skeletal muscle and heart are similar in that they: 1) consist of an oligomer of a single high molecular weight polypeptide (Mr 360,000 for skeletal muscle and 340,000 for heart); 2) exist morphologically as the foot structure; 3) are activated (ATP, Ca2+, ryanodine) and inhibited (ruthenium red and Mg2+) by a number of the same ligands. Important differences include: 1) Ca2+ activation at lower concentration of Ca2+ for the heart; 2) more dramatic stabilization by ryanodine of the open state for the skeletal muscle channel; and 3) different relative permeabilities (PCa/PK).     

Chloride-dependent sarcoplasmic reticulum Ca2+ release correlates with increased Ca2+ activation of ryanodine receptors.

The mechanism by which chloride increases sarcoplasmic reticulum (SR) Ca2+ permeability was investigated. In the presence of 3 microM Ca2+, Ca2+ release from 45Ca(2+)-loaded SR vesicles prepared from procine skeletal muscle was increased approximately 4-fold when the media contained 150 mM chloride versus 150 mM propionate, whereas in the presence of 30 nM Ca2+, Ca2+ release was similar in the chloride- and the propionate-containing media. Ca(2+)-activated [3H]ryanodine binding to skeletal muscle SR was also increased (2- to 10-fold) in media in which propionate or other organic anions were replaced with chloride; however, chloride had little or no effect on cardiac muscle SR 45Ca2+ release or [3H]ryanodine binding. Ca(2+)-activated [3H]ryanodine binding was increased approximately 4.5-fold after reconstitution of skeletal muscle RYR protein into liposomes, and [3H]ryanodine binding to reconstituted RYR protein was similar in chloride- and propionate-containing media, suggesting that the sensitivity of the RYR protein to changes in the anionic composition of the media may be diminished upon reconstitution. Together, our results demonstrate a close correlation between chloride-dependent increases in SR Ca2+ permeability and increased Ca2+ activation of skeletal muscle RYR channels. We postulate that media containing supraphysiological concentrations of chloride or other inorganic anions may enhance skeletal muscle RYR activity by favoring a conformational state of the channel that exhibits increased activation by Ca2+ in comparison to the Ca2+ activation exhibited by this channel in native membranes in the presence of physiological chloride (< or = 10 mM). Transitions to this putative Ca(2+)-activatable state may thus provide a mechanism for controlling the activation of RYR channels in skeletal muscle.     

Redox regulation of calcium release in skeletal and cardiac muscle

In skeletal and cardiac muscle cells, specific isoforms of the Ryanodine receptor channels mediate Ca2+ release from the sarcoplasmic reticulum. These channels are highly susceptible to redox modifications, which regulate channel activity. In this work, we studied the effects of Ca2+ (endogenous agonist) and Mg2+ (endogenous inhibitor) on the kinetics of Ca2+ release from sarcoplasmic reticulum vesicles isolated from skeletal or cardiac mammalian muscle. Native skeletal vesicles exhibited maximal stimulation of release kinetics by 10-20 microM [Ca2+], whereas in native cardiac vesicles, maximal stimulation of release required only 1 microM [Ca2+]. In 10 microM [Ca2+], free [Mg2+] < 0.1 mM produced marked inhibition of release from skeletal vesicles but free [Mg2+] < or = 0.8 mM did not affect release from cardiac vesicles. Incubation of skeletal or cardiac vesicles with the oxidant thimerosal increased their susceptibility to stimulation by Ca2+ and decreased the inhibitory effect of Mg2+ in skeletal vesicles. Sulfhydryl-reducing agents fully reversed the effects of thimerosal. The endogenous redox species, glutathione disulfide and S-nitrosoglutathione, also stimulated release from skeletal sarcoplasmic reticulum vesicles. In 10 microM [Ca2+], 35S-nitrosoglutathione labeled a protein fraction enriched in release channels through S-glutathiolation. Free [Mg2+] 1 mM or decreasing free [Ca2+] to the nM range prevented this reaction. Possible physiological and pathological consequences of redox modification of release channels on Ca2+ signaling in heart and muscle cells are discussed.     

Phosphorylation of the cardiac ryanodine receptor by cAMP-dependent protein kinase

The phosphorylation of canine cardiac and skeletal muscle ryanodine receptors by the catalytic subunit of cAMP-dependent protein kinase has been studied. A high-molecular-weight protein (Mr 400,000) in cardiac microsomes was phosphorylated by the catalytic subunit of cAMP-dependent protein kinase. A monoclonal antibody against the cardiac ryanodine receptor immunoprecipitated this phosphoprotein. In contrast, high-molecular-weight proteins (Mr 400,000-450,000) in canine skeletal microsomes isolated from extensor carpi radialis (fast) or superficial digitalis flexor (slow) muscle fibers were not significantly phosphorylated. In agreement with these findings, the ryanodine receptor purified from cardiac microsomes was also phosphorylated by cAMP-dependent protein kinase. Phosphorylation of the cardiac ryanodine receptor in microsomal and purified preparations occurred at the ratio of about one mol per mol of ryanodine-binding site. Upon phosphorylation of the cardiac ryanodine receptor, the levels of [3H]ryanodine binding at saturating concentrations of this ligand increased by up to 30% in the presence of Ca2+ concentrations above 1 microM in both cardiac microsomes and the purified cardiac ryanodine receptor preparation. In contrast, the Ca2+ concentration dependence of [3H]ryanodine binding did not change significantly. These results suggest that phosphorylation of the ryanodine receptor by cAMP-dependent protein kinase may be an important regulatory mechanism for the calcium release channel function in the cardiac sarcoplasmic reticulum.     

Functional studies of Ca2+ channels from plasmalemma and sarcoplasmic reticulum membranes in muscle cells

Physiological and biochemical studies (channel characteristics, intracellular Ca2+ determinations and, channel purification, cloning and expression) of the different components involved in the regulation of intercellular Ca2+ have provided new information about their specific role. Recent information favors a major role for plasmalemma Ca2+ channels in E-C coupling of cardiac muscle, while a major role for sarcoplasmic reticulum Ca2+ release channels (ryanodine receptors) is proposed for E-C coupling of skeletal muscle. In smooth muscle, both plasmalemma and sarcoplasmic reticulum (IP3 receptors) Ca2+ channels are involved in E-C coupling. These studies will be comparatively discussed for skeletal, cardiac and smooth muscle cells.     

Characterization of junctional and longitudinal sarcoplasmic reticulum from heart muscle

Longitudinal tubules and junctional sarcoplasmic reticulum (SR) were prepared from heart muscle microsomes by Ca2+-phosphate loading followed by sucrose density gradient centrifugation. The longitudinal SR had a high Ca2+ loading rate (0.93 +/- 0.08 mumol.mg-1.min) which was unchanged by addition of ruthenium red. Junctional SR had a low Ca2+ loading rate (0.16 +/- 0.02 mumol.mg-1.min) which was enhanced about 5-fold by ruthenium red. Junctional SR had feet structures observed by electron microscopy and a high molecular weight protein with Mr of 340,000, whereas longitudinal SR was essentially devoid of both. Thus, these subfractions have similar characteristics to longitudinal and junctional terminal cisternae of SR from fast twitch skeletal muscle. Ryanodine binding was localized to junctional cardiac SR as determined by [3H]ryanodine binding. Scatchard analysis of the binding data showed two types of binding (high affinity, Kd approximately 7.9 nM; low affinity, Kd approximately 1 microM), contrasting with skeletal junctional terminal cisternae where only one site with Kd of approximately 50 nM was observed. The ruthenium red enhancement of Ca2+ loading rate in junctional cardiac SR was blocked by pretreatment with low concentrations of ryanodine as reported for junctional terminal cisternae of skeletal muscle SR. The Ca2+ loading rate of junctional cardiac SR was enhanced by preincubation with high concentrations of ryanodine. The apparent inhibition constant (Ki approximately 7 nM) and stimulation constant (Km approximately 1.1 microM) for ryanodine on junctional SR corresponded to the Kd for high affinity binding (Kd approximately 7.9 nM) and low affinity binding (Kd approximately 1.1 microM), respectively. These results suggest that high affinity ryanodine binding locks the Ca2+ release channels in the open state and that low affinity binding closes the Ca2+ release channels of the junctional cardiac SR. The characteristics of the Ca2+ release channels of junctional cardiac SR appear to be similar to that of skeletal muscle SR, but the Ca2+ release channels of cardiac SR are more sensitive to ryanodine.     

Structural and functional characterization of the purified cardiac ryanodine receptor-Ca2+ release channel complex

Using density gradient centrifugation and [3H]ryanodine as a specific marker, the ryanodine receptor-Ca2+ release channel complex from Chaps-solubilized canine cardiac sarcoplasmic reticulum (SR) has been purified in the form of an approximately 30 S complex, comprised of Mr approximately 400,000 polypeptides. Purification resulted in a specific activity of approximately 450 pmol bound ryanodine/mg of protein, a 60-70% recovery of ryanodine binding activity, and retention of the high affinity ryanodine binding site (KD = 3 nM). Negative stain electron microscopy revealed a 4-fold symmetric, four-leaf clover structure, which could fill a box approximately 30 x 30 nm and was thus morphologically similar to the SR-transverse-tubule, junctionally associated foot structure. The structural, sedimentation, and ryanodine binding data strongly suggest there is one high affinity ryanodine binding site/30 S complex, comprised of four Mr approximately 400,000 subunits. Upon reconstitution into planar lipid bilayers, the purified complex exhibited a Ca2+ conductance (70 pS in 50 mM Ca2+) similar to that of the native cardiac Ca2+ release channel (75 pS). The reconstituted complex was also found to conduct Na+ (550 pS in 500 mM Na+) and often to display complex Na+ subconducting states. The purified channel could be activated by micromolar Ca2+ or millimolar ATP, inhibited by millimolar Mg2+ or micromolar ruthenium red, and modified to a long-lived open subconducting state by ryanodine. The sedimentation, subunit composition, morphological, and ryanodine binding characteristics of the purified cardiac ryanodine receptor-Ca2+ release channel complex were similar to those previously described for the purified ryanodine receptor-Ca2+ release channel complex from fast-twitch skeletal muscle.     

Functional interaction of the cytoplasmic domain of triadin with the skeletal ryanodine receptor

Triadin has been shown to co-localize with the ryanodine receptor in the sarcoplasmic reticulum membrane. We show that immunoprecipitation of solubilized sarcoplasmic reticulum membrane with antibodies directed against triadin or ryanodine receptor, leads to the co-immunoprecipitation of ryanodine receptor and triadin. We then investigated the functional importance of the cytoplasmic domain of triadin (residues 1-47) in the control of Ca2+ release from sarcoplasmic reticulum. We show that antibodies directed against a synthetic peptide encompassing residues 2-17, induce a decrease in the rate of Ca2+ release from sarcoplasmic reticulum vesicles as well as a decrease in the open probability of the ryanodine receptor Ca2+ channel incorporated in lipid bilayers. Using surface plasmon resonance spectroscopy, we defined a discrete domain (residues 18-46) of the cytoplasmic part of triadin interacting with the purified ryanodine receptor. This interaction is optimal at low Ca2+ concentration (up to pCa 5) and inhibited by increasing calcium concentration (IC50 of 300 microM). The direct molecular interaction of this triadin domain with the ryanodine receptor was confirmed by overlay assay and shown to induce the inhibition of the Ca2+ channel activity of purified RyR in bilayer. We propose that this interaction plays a critical role in the control, by triadin, of the Ca2+ channel behavior of the ryanodine receptor and therefore may represent an important step in the regulation process of excitation-contraction coupling in skeletal muscle.     

S100A1 binds to the calmodulin-binding site of ryanodine receptor and modulates skeletal muscle excitation-contraction coupling

S100A1, a 21-kDa dimeric Ca2+-binding protein, is an enhancer of cardiac Ca2+ release and contractility and a potential therapeutic agent for the treatment of cardiomyopathy. The role of S100A1 in skeletal muscle has been less well defined. Additionally, the precise molecular mechanism underlying S100A1 modulation of sarcoplasmic reticulum Ca2+ release in striated muscle has not been fully elucidated. Here, utilizing a genetic approach to knock out S100A1, we demonstrate a direct physiological role of S100A1 in excitation-contraction coupling in skeletal muscle. We show that the absence of S100A1 leads to decreased global myoplasmic Ca2+ transients following electrical excitation. Using high speed confocal microscopy, we demonstrate with high temporal resolution depressed activation of sarcoplasmic reticulum Ca2+ release in S100A1-/- muscle fibers. Through competition assays with sarcoplasmic reticulum vesicles and through tryptophan fluorescence experiments, we also identify a novel S100A1-binding site on the cytoplasmic face of the intact ryanodine receptor that is conserved throughout striated muscle and corresponds to a previously identified calmodulin-binding site. Using a 12-mer peptide of this putative binding domain, we demonstrate low micromolar binding affinity to S100A1. NMR spectroscopy reveals this peptide binds within the Ca2+-dependent hydrophobic pocket of S100A1. Taken together, these data suggest that S100A1 plays a significant role in skeletal muscle excitation-contraction coupling, primarily through specific interactions with a conserved binding domain of the ryanodine receptor. This warrants further investigation into the use of S100A1 as a therapeutic target for the treatment of both cardiac and skeletal myopathies.