Project description:Sarcoplasmic reticulum (SR) Ca(2+) release in striated muscle is mediated by a multiprotein complex that includes the ryanodine receptor (RyR) Ca(2+) channel and the intra-SR Ca(2+) buffering protein calsequestrin (CSQ). Besides its buffering role, CSQ is thought to regulate RyR channel function. Here, CSQ-dependent luminal Ca(2+) regulation of skeletal (RyR1) and cardiac (RyR2) channels is explored. Skeletal (CSQ1) or cardiac (CSQ2) calsequestrin were systematically added to the luminal side of single RyR1 or RyR2 channels. The luminal Ca(2+) dependence of open probability (Po) over the physiologically relevant range (0.05-1 mM Ca(2+)) was defined for each of the four RyR/CSQ isoform pairings. We found that the luminal Ca(2+) sensitivity of single RyR2 channels was substantial when either CSQ isoform was present. In contrast, no significant luminal Ca(2+) sensitivity of single RyR1 channels was detected in the presence of either CSQ isoform. We conclude that CSQ-dependent luminal Ca(2+) regulation of single RyR2 channels lacks CSQ isoform specificity, and that CSQ-dependent luminal Ca(2+) regulation in skeletal muscle likely plays a relatively minor (if any) role in regulating the RyR1 channel activity, indicating that the chief role of CSQ1 in this tissue is as an intra-SR Ca(2+) buffer.

Project description:The synergic effect of luminal Ca(2+), cytosolic Ca(2+), and cytosolic adenosine triphosphate (ATP) on activation of cardiac ryanodine receptor (RYR2) channels was examined in planar lipid bilayers. The dose-response of RYR2 gating activity to ATP was characterized at a diastolic cytosolic Ca(2+) concentration of 100 nM over a range of luminal Ca(2+) concentrations and, vice versa, at a diastolic luminal Ca(2+) concentration of 1 mM over a range of cytosolic Ca(2+) concentrations. Low level of luminal Ca(2+) (1 mM) significantly increased the affinity of the RYR2 channel for ATP but without substantial activation of the channel. Higher levels of luminal Ca(2+) (8-53 mM) markedly amplified the effects of ATP on the RYR2 activity by selectively increasing the maximal RYR2 activation by ATP, without affecting the affinity of the channel to ATP. Near-diastolic cytosolic Ca(2+) levels (<500 nM) greatly amplified the effects of luminal Ca(2+). Fractional inhibition by cytosolic Mg(2+) was not affected by luminal Ca(2+). In models, the effects of luminal and cytosolic Ca(2+) could be explained by modulation of the allosteric effect of ATP on the RYR2 channel. Our results suggest that luminal Ca(2+) ions potentiate the RYR2 gating activity in the presence of ATP predominantly by binding to a luminal site with an apparent affinity in the millimolar range, over which local luminal Ca(2+) likely varies in cardiac myocytes.

Project description:During physical exercise and stress, the sympathetic system stimulates cardiac contractility via β-adrenergic receptor activation, resulting in protein kinase A (PKA)-mediated phosphorylation of the cardiac ryanodine receptor, RyR2, at Ser2808. Hyperphosphorylation of RyR2-S2808 has been proposed as a mechanism contributing to arrhythmogenesis and heart failure. However, the role of RyR2 phosphorylation during β-adrenergic stimulation remains controversial. We examined the contribution of RyR2-S2808 phosphorylation to altered excitation-contraction coupling and Ca(2+) signaling using an experimental approach at the interface of molecular and cellular levels and a transgenic mouse with ablation of the RyR2-S2808 phosphorylation site (RyR2-S2808A). Experimentally challenging the communication between L-type Ca(2+) channels and RyR2 led to a spatiotemporal de-synchronization of RyR2 openings, as visualized using confocal Ca(2+) imaging. β-Adrenergic stimulation re-synchronized RyR2s, but less efficiently in RyR2-S2808A than in control cardiomyocytes, as indicated by comprehensive analysis of RyR2 activation. In addition, spontaneous Ca(2+) waves in RyR2-S2808A myocytes showed significantly slowed propagation and complete absence of acceleration during β-adrenergic stress, unlike wild type cells. Single channel recordings revealed an attenuation of luminal Ca(2+) sensitivity in RyR2-S2808A channels upon addition of PKA. This suggests that phosphorylation of RyR2-S2808 may be involved in RyR2 modulation by luminal (intra-SR) Ca(2+) ([Ca(2+)](SR)). We show here by three independent experimental approaches that PKA-dependent RyR2-S2808 phosphorylation plays significant functional roles at the subcellular level, namely, Ca(2+) release synchronization, Ca(2+) wave propagation and functional adaptation of RyR2 to variable [Ca(2+)](SR). These results indicate a direct mechanistic link between RyR2 phosphorylation and SR luminal Ca(2+) sensing.

Project description:Various ryanodine receptor 2 (RyR2) point mutations cause catecholamine-induced polymorphic ventricular tachycardia (CPVT), a life-threatening arrhythmia evoked by diastolic intracellular Ca2+ release dysfunction. These mutations occur in essential regions of RyR2 that regulate Ca2+ release. The molecular dysfunction caused by CPVT-associated RyR2 mutations as well as the functional consequences remain unresolved. Here, we study the most severe CPVT-associated RyR2 mutation (K4750Q) known to date. We define the molecular and cellular dysfunction generated by this mutation and detail how it alters RyR2 function, using Ca2+ imaging, ryanodine binding, and single-channel recordings. HEK293 cells and cardiac HL-1 cells expressing RyR2-K4750Q show greatly enhanced spontaneous Ca2+ oscillations. An endoplasmic reticulum-targeted Ca2+ sensor, R-CEPIA1er, revealed that RyR2-K4750Q mediates excessive diastolic Ca2+ leak, which dramatically reduces luminal [Ca2+]. We further show that the K4750Q mutation causes three RyR2 defects: hypersensitization to activation by cytosolic Ca2+, loss of cytosolic Ca2+/Mg2+-mediated inactivation, and hypersensitization to luminal Ca2+ activation. These defects combine to kinetically stabilize RyR2-K4750Q openings, thus explaining the extensive diastolic Ca2+ leak from the sarcoplasmic reticulum, frequent Ca2+ waves, and severe CPVT phenotype. As the multiple concurrent defects are induced by a single point mutation, the K4750 residue likely resides at a critical structural point at which cytosolic and luminal RyR2 control input converge.

Project description:Spontaneous Ca(2+) release from intracellular stores is important for various physiological and pathological processes. In cardiac muscle cells, spontaneous store overload-induced Ca(2+) release (SOICR) can result in Ca(2+) waves, a major cause of ventricular tachyarrhythmias (VTs) and sudden death. The molecular mechanism underlying SOICR has been a mystery for decades. Here we show that a point mutation, E4872A, in the helix bundle crossing region (the proposed gate) of the cardiac ryanodine receptor (RyR2) completely abolishes luminal, but not cytosolic, Ca(2+) activation of RyR2. The introduction of metal-binding histidines at this site converts RyR2 into a luminal Ni(2+)-gated channel. Mouse hearts harboring a heterozygous RyR2 mutation at this site (E4872Q) are resistant to SOICR and are completely protected against Ca(2+)-triggered VTs. These data show that the RyR2 gate directly senses luminal (store) Ca(2+), explaining the regulation of RyR2 by luminal Ca(2+), the initiation of Ca(2+) waves and Ca(2+)-triggered arrhythmias. This newly identified store-sensing gate structure is conserved in all RyR and inositol 1,4,5-trisphosphate receptor isoforms.

Project description:Different forms of ventricular arrhythmias have been linked to mutations in the cardiac ryanodine receptor (RyR)2, but the molecular basis for this phenotypic heterogeneity is unknown. We have recently demonstrated that an enhanced sensitivity to luminal Ca(2+) and an increased propensity for spontaneous Ca(2+) release or store-overload-induced Ca(2+) release (SOICR) are common defects of RyR2 mutations associated with catecholaminergic polymorphic or bidirectional ventricular tachycardia. Here, we investigated the properties of a unique RyR2 mutation associated with catecholaminergic idiopathic ventricular fibrillation, A4860G. Single-channel analyses revealed that, unlike all other disease-linked RyR2 mutations characterized previously, the A4860G mutation diminished the response of RyR2 to activation by luminal Ca(2+), but had little effect on the sensitivity of the channel to activation by cytosolic Ca(2+). This specific impact of the A4860G mutation indicates that the luminal Ca(2+) activation of RyR2 is distinct from its cytosolic Ca(2+) activation. Stable, inducible HEK293 cells expressing the A4860G mutant showed caffeine-induced Ca(2+) release but exhibited no SOICR. Importantly, HL-1 cardiac cells transfected with the A4860G mutant displayed attenuated SOICR activity compared with cells transfected with RyR2 WT. These observations provide the first evidence that a loss of luminal Ca(2+) activation and SOICR activity can cause ventricular fibrillation and sudden death. These findings also indicate that although suppressing enhanced SOICR is a promising antiarrhythmic strategy, its oversuppression can also lead to arrhythmias.

Project description:Mitochondrial calcium handling and its relation with calcium released from sarcoplasmic reticulum (SR) in muscle tissue are subject of lively debate. In this study we aimed to clarify how the SR determines mitochondrial calcium handling using dCASQ-null mice which lack both isoforms of the major Ca(2+)-binding protein inside SR, calsequestrin. Mitochondrial free Ca(2+)-concentration ([Ca(2+)]mito) was determined by means of a genetically targeted ratiometric FRET-based probe. Electron microscopy revealed a highly significant increase in intermyofibrillar mitochondria (+55%) and augmented coupling (+12%) between Ca(2+) release units of the SR and mitochondria in dCASQ-null vs. WT fibers. Significant differences in the baseline [Ca(2+)]mito were observed between quiescent WT and dCASQ-null fibers, but not in the resting cytosolic Ca(2+) concentration. The rise in [Ca(2+)]mito during electrical stimulation occurred in 20-30 ms, while the decline during and after stimulation was governed by 4 rate constants of approximately 40, 1.6, 0.2 and 0.03 s(-1). Accordingly, frequency-dependent increase in [Ca(2+)]mito occurred during sustained contractions. In dCASQ-null fibers the increases in [Ca(2+)]mito were less pronounced than in WT fibers and even lower when extracellular calcium was removed. The amplitude and duration of [Ca(2+)]mito transients were increased by inhibition of mitochondrial Na(+)/Ca(2+) exchanger (mNCX). These results provide direct evidence for fast Ca(2+) accumulation inside the mitochondria, involvement of the mNCX in mitochondrial Ca(2+)-handling and a dependence of mitochondrial Ca(2+)-handling on intracellular (SR) and external Ca(2+) stores in fast skeletal muscle fibers. dCASQ-null mice represent a model for malignant hyperthermia. The differences in structure and in mitochondrial function observed relative to WT may represent compensatory mechanisms for the disease-related reduction of calcium storage capacity of the SR and/or SR Ca(2+)-leakage.

Project description:Pressure overload-induced hypertrophy is a key step leading to heart failure. The Ca(2+)-induced Ca(2+) release (CICR) process that governs cardiac contractility is defective in hypertrophy/heart failure, but the molecular mechanisms remain elusive. To examine the intermolecular aspects of CICR during hypertrophy, we utilized loose-patch confocal imaging to visualize the signaling between a single L-type Ca(2+) channel (LCC) and ryanodine receptors (RyRs) in aortic stenosis rat models of compensated (CHT) and decompensated (DHT) hypertrophy. We found that the LCC-RyR intermolecular coupling showed a 49% prolongation in coupling latency, a 47% decrease in chance of hit, and a 72% increase in chance of miss in DHT, demonstrating a state of "intermolecular failure." Unexpectedly, these modifications also occurred robustly in CHT due at least partially to decreased expression of junctophilin, indicating that intermolecular failure occurs prior to cellular manifestations. As a result, cell-wide Ca(2+) release, visualized as "Ca(2+) spikes," became desynchronized, which contrasted sharply with unaltered spike integrals and whole-cell Ca(2+) transients in CHT. These data suggested that, within a certain limit, termed the "stability margin," mild intermolecular failure does not damage the cellular integrity of excitation-contraction coupling. Only when the modification steps beyond the stability margin does global failure occur. The discovery of "hidden" intermolecular failure in CHT has important clinical implications.

Project description:In striated muscle, the sarcoplasmic reticulum (SR) Ca2+ release/ryanodine receptor (RyR) channel provides the pathway through which stored Ca2+ is released into the myoplasm during excitation-contraction coupling. Various luminal Ca2+-binding proteins are responsible for maintaining the free [Ca2+] at 10(-3)-10(-4) M in the SR lumen; in skeletal-muscle SR, it is mainly calsequestrin. Here we show that, depending on its phosphorylation state, calsequestrin selectively controls the RyR channel activity at 1 mM free luminal [Ca2+]. Calsequestrin exclusively in the dephosphorylated state enhanced the open probability by approx. 5-fold with a Hill coefficient (h) of 3.3, and increased the mean open time by about 2-fold, i.e. solely dephosphorylated calsequestrin regulates Ca2+ release from the SR. Because calsequestrin has been found to occur mainly in the phosphorylated state in the skeletal-muscle SR for the regulation of RyR channel activity, the dephosphorylation of calsequestrin would appear to be a quintessential physiological event.

Project description:Catecholaminergic polymorphic ventricular tachycardia (CPVT) is linked to mutations in the cardiac ryanodine receptor (RyR2) or calsequestrin. We recently found that the drug flecainide inhibits RyR2 channels and prevents CPVT in mice and humans. Here we compared the effects of flecainide and tetracaine, a known RyR2 inhibitor ineffective in CPVT myocytes, on arrhythmogenic Ca(2+) waves and elementary sarcoplasmic reticulum (SR) Ca(2+) release events, Ca(2+) sparks. In ventricular myocytes isolated from a CPVT mouse model, flecainide significantly reduced spark amplitude and spark width, resulting in a 40% reduction in spark mass. Surprisingly, flecainide significantly increased spark frequency. As a result, flecainide had no significant effect on spark-mediated SR Ca(2+) leak or SR Ca(2+) content. In contrast, tetracaine decreased spark frequency and spark-mediated SR Ca(2+) leak, resulting in a significantly increased SR Ca(2+) content. Measurements in permeabilized rat ventricular myocytes confirmed the different effects of flecainide and tetracaine on spark frequency and Ca(2+) waves. In lipid bilayers, flecainide inhibited RyR2 channels by open state block, whereas tetracaine primarily prolonged RyR2 closed times. The differential effects of flecainide and tetracaine on sparks and RyR2 gating can explain why flecainide, unlike tetracaine, does not change the balance of SR Ca(2+) fluxes. We suggest that the smaller spark mass contributes to flecainide's antiarrhythmic action by reducing the probability of saltatory wave propagation between adjacent Ca(2+) release units. Our results indicate that inhibition of the RyR2 open state provides a new therapeutic strategy to prevent diastolic Ca(2+) waves resulting in triggered arrhythmias, such as CPVT.