Oxidation of RyR2 Has a Biphasic Effect on the Threshold for Store Overload-Induced Calcium Release.

At the single-channel level, oxidation of the cardiac ryanodine receptor (RyR2) is known to activate and inhibit the channel depending on the level of oxidation. However, the mechanisms through which these changes alter the activity of RyR2 in a cellular setting are poorly understood. In this study, we determined the effect of oxidation on a common form of RyR2 regulation; store overload-induced Ca(2+) release (SOICR). We found that oxidation resulted in concentration and time-dependent changes in the activation threshold for SOICR. Low concentrations of the oxidant H2O2 resulted in a decrease in the threshold for SOICR, which led to an increase in SOICR events. However, higher concentrations of H2O2, or prolonged exposure, reversed these changes and led to an increase in the threshold for SOICR. This increase in the threshold for SOICR in most cells was to such an extent that it led to the complete inhibition of SOICR. Acute exposure to high concentrations of H2O2 led to an initial decrease and then increase in the threshold for SOICR. In the majority of cells the increased threshold could not be reversed by the application of the reducing agent dithiothreitol. Therefore, our data suggest that low levels of RyR2 oxidation increase the channel activity by decreasing the threshold for SOICR, whereas high levels of RyR2 oxidation irreversibly increase the threshold for SOICR leading to an inhibition of RyR2. Combined, this indicates that oxidation regulates RyR2 by the same mechanism as phosphorylation, methylxanthines, and mutations, via changes in the threshold for SOICR.

FKBPs facilitate the termination of spontaneous Ca2+ release in wild-type RyR2 but not CPVT mutant RyR2.

FK506-binding proteins 12.6 (FKBP12.6) and 12 (FKBP12) tightly associate with the cardiac ryanodine receptor (RyR2). Studies suggest that dissociation of FKBP12.6 from mutant forms of RyR2 contributes to store overload-induced Ca(2+) release (SOICR) and Ca(2+)-triggered arrhythmias. However, these findings are controversial. Previous studies focused on the effect of FKBP12.6 on the initiation of SOICR and did not explore changes in the termination of Ca(2+) release. Less is known about FKBP12. We aimed to determine the effect of FKBP12.6 and FKBP12 on the termination of SOICR. Using single-cell imaging, in cells expressing wild-type RyR2, we found that FKBP12.6 and FKBP12 significantly increase the termination threshold of SOICR without changing the activation threshold of SOICR. This effect, dependent on the association of each FKBP with RyR2, reduced the magnitude of Ca(2+) release but had no effect on the propensity for SOICR. In contrast, neither FKBP12.6 nor FKBP12 was able to regulate an arrhythmogenic variant of RyR2, despite a conserved protein interaction. Our results suggest that both FKBP12.6 and FKBP12 play critical roles in regulating RyR2 function by facilitating the termination of SOICR. The inability of FKBPs to mediate a similar effect on the mutant RyR2 represents a novel mechanism by which mutations within RyR2 lead to arrhythmia.

The arrhythmogenic human HRC point mutation S96A leads to spontaneous Ca(2+) release due to an impaired ability to buffer store Ca(2+).

The Ser96Ala (S96A) mutation within the histidine rich Ca(2+) binding protein (HRC) has recently been linked to cardiac arrhythmias in idiopathic dilated cardiomyopathy patients, potentially attributable to an increase in spontaneous Ca(2+) release events. However, the molecular mechanism connecting the S96A mutation of HRC to increased Ca(2+) release events remains unclear. Previous findings by our group indicate that these spontaneous Ca(2+) release events may be linked to store overload induced Ca(2+) release (SOICR) via the cardiac ryanodine receptor (RyR2). Therefore, in the present study we sought to determine whether HRC wild type (HRC WT) and S96A mutant (HRC S96A) expression has a direct effect on SOICR. Using both cytosolic and intra-Ca(2+) store measurements in human embryonic kidney cells expressing RyR2, we found that HRC WT significantly inhibited the propensity for SOICR by buffering store free Ca(2+) and inhibiting store Ca(2+) uptake. In contrast, HRC S96A exhibited a markedly suppressed inhibitory effect on SOICR, which was attributed to an impaired ability to buffer store Ca(2+) and reduce store Ca(2+) uptake. In addition to impairing the ability of HRC to regulate bulk store Ca(2+), a proximity ligation assay demonstrated that the S96A mutation also disrupts the Ca(2+) microdomain around the RyR2, as it alters the Ca(2+) dependent association of RyR2 and HRC. Importantly, in contrast to previous reports, the absence of triadin in our experimental model illustrates that the S96A mutation in HRC can alter the propensity for SOICR without any interaction with triadin. Collectively, our results demonstrate that the human HRC mutation S96A leads to an increase in spontaneous Ca(2+) release and ultimately arrhythmias by disrupting the regulation of intra-store free Ca(2+). This is primarily due to an impaired ability to act as an effective bulk and local microdomain store Ca(2+) buffer.