Intersubunit cross-linking is the key mechanism of cardiac ryanodine receptor dysfunction during oxidative stress: The role of cysteines 1078 and 2991

The type 2 ryanodine receptor (RyR2) plays a key role in regulating cardiac intracellular Ca2+. We have previously shown that oxidative stress can regulate RyR2 by promoting the formation of disulfide bonds between neighboring RyR2 subunits (intersubunit cross-linking). However, the functional significance of this redox modification and cysteines involved in cross-linking remain unknown. Here, we used site-directed mutagenesis to replace cysteines 1078 and 2991 with serines in human RyR2 (hRyR2). Obtained constructs were expressed in HEK293 cells and treated with diamide to induce oxidative stress. Western blot analysis revealed that both mutations substantially protected against hRyR2 cross-linking. Analysis of the ER lumen [Ca2+] ([Ca2+]ER) dynamics with the ER Ca2+ sensor R-CEPIA1er in HEK293 cells expressing hRyR2 revealed that the mutation of either 1078 or 2991 cysteines prevented the depletion of ER Ca2+ load caused by RyR2 oxidation (by >40%). The simultaneous mutation of both cysteines produced the similar protection against hRyR2 cross-linking and [Ca2+]ER depletion, indicating a common mechanism of redox regulation involving both residues. Given the structural localization of both cysteines at the neighboring RyR2 subunits, we suggest that they form an intersubunit disulfide bond during channel oxidation, followed by the formation of the pathologically “leaky” channel. Although the N-terminal region (NTR) of RyR2 plays an important role in the channel's tetramer formation and functional regulation, the individual cysteines in this region are not directly involved in hRyR2 cross-linking. However, the structural integrity of the NTR has an allosteric effect on hRyR2 complex re-arrangements required for the channel's cross-linking. In conclusion, the results of this study revealed two critical cysteines within hRyR2 that are involved in the intersubunit disulfide cross-linking and the channel's functional response to oxidative stress.