Abstract
Synchronous coordination of calcium-induced calcium release (CICR) across thousands of calcium release units (CRUs) within the cardiomyocyte is critical for normal excitation-contraction coupling (ECC). Here we utilize a novel “local control” mathematical model of ECC, designed to simulate a mouse cardiomyocyte, to investigate physiological and pathophysiological calcium (Ca2+) signaling. The model contains 20,000 independent CRUs each composed of 6 stochastically gated L-type Ca2+ channels (LCCs) in the transverse tubule membrane that are positioned across a local “dyadic subspace” from a junctional sarcoplasmic reticulum (JSR) compartment containing a cluster of 50 stochastically gated ryanodine receptors (RyR2s). Action potential depolarization of the sarcolemmal membrane activates LCC openings which elevate subspace [Ca2+] ([Ca2+]ds) across each of the cell's 20,000 CRUs. This rise in [Ca2+]ds promotes RyR2 opening to initiate the fundamental element of triggered Ca2+ release, the Ca2+ spark. The mechanistic design and true SR Ca2+ pump/leak balance displayed by our model allows us to quantify ECC fidelity and Ca2+ spark fidelity (the probability that a LCC opening or RyR2 opening induces a Ca2+ spark, respectively). We study the effect of excess SR Ca2+ leak in the context of “catecholaminergic polymorphic ventricular tachycardia (CPVT)” caused by the R33Q mutation in calsequestrin (CASQ2). CPVT is simulated by increasing RyR2 sensitivity to [Ca2+]i and reducing JSR Ca2+ buffering capacity to levels identified by prior studies of the CASQ2-R33Q “knock-in” mice. Our model effectively reproduces both normal and arrhythmogenic CPVT RyR2 [Ca2+]i sensitivity, local Ca2+ spark activity, and global Ca2+ signals. Under CPVT conditions enhanced RyR2 open probability is critical for the development of “unstable”, quiescent Ca2+ sparks that fail to terminate robustly as well as asynchronous systolic Ca2+ spark activity and increased diastolic SR Ca2+ leak.
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