Background
Delayed afterdepolarizations (DADs) carried by Na+-Ca2+-exchange current (INCX) in response to sarcoplasmic reticulum (SR) Ca2+-leak can promote atrial fibrillation (AF). The mechanisms leading to DADs in AF-patients have not been defined.
Methods and Results
Protein levels (Western-blot), membrane-currents and action-potentials (patch-clamp), and [Ca2+]i (Fluo-3) were measured in right-atrial samples from 77 sinus-rhythm (Ctl) and 69 chronic-AF (cAF) patients. Diastolic [Ca2+]i and SR-Ca2+-content (integrated INCX during caffeine-induced-Ca2+-transient [cCaT]) were unchanged, whereas diastolic SR Ca2+-leak, estimated by blocking RyR2 with tetracaine, was ~50% higher in cAF vs. Ctl. Single-channel recordings from atrial RyR2 reconstituted into lipid-bilayers revealed enhanced open-probability in cAF-samples, providing a molecular basis for increased SR Ca2+-leak. Calmodulin-expression (+60%), CaMKII-autophosphorylation at Thr287 (+40%) and RyR2-phosphorylation at Ser2808 (PKA/CaMKII-site, +236%) and Ser2814 (CaMKII-site, +77%) were increased in cAF. The selective CaMKII-blocker KN-93 decreased SR Ca2+-leak, the frequency of spontaneous Ca2+-release events and RyR2 open-probability in cAF, whereas PKA-inhibition with H-89 was ineffective. Knock-in mice with constitutively-phosphorylated RyR2 at Ser2814 showed a higher incidence of Ca2+-sparks and increased susceptibility to pacing-induced AF vs. controls. The relationship between [Ca2+]i and INCX-density revealed INCX-upregulation in cAF. Spontaneous Ca2+-release events accompanied by inward INCX-currents and DADs/triggered-activity occurred more often and the sensitivity of resting membrane voltage to elevated [Ca2+]i (diastolic [Ca2+]i–voltage coupling gain) was higher in cAF vs. Ctl.
Conclusions
Enhanced SR Ca2+-leak through CaMKII-hyperphosphorylated RyR2, in combination with larger INCX for a given SR Ca2+-release and increased diastolic [Ca2+]i–voltage coupling gain, cause AF-promoting atrial DADs/triggered-activity in cAF patients.
Cardiac contractility is regulated by changes in intracellular Ca concentration ([Ca2+]i). Normal function requires that [Ca2+]i be sufficiently high in systole and low in diastole. Much of the Ca needed for contraction comes from the sarcoplasmic reticulum and is released by the process of calcium-induced calcium release. The factors that regulate and fine-tune the initiation and termination of release are reviewed. The precise control of intracellular Ca cycling depends on the relationships between the various channels and pumps that are involved. We consider 2 aspects: (1) structural coupling: the transporters are organized within the dyad, linking the transverse tubule and sarcoplasmic reticulum and ensuring close proximity of Ca entry to sites of release. (2) Functional coupling: where the fluxes across all membranes must be balanced such that, in the steady state, Ca influx equals Ca efflux on every beat. The remainder of the review considers specific aspects of Ca signaling, including the role of Ca buffers, mitochondria, Ca leak, and regulation of diastolic [Ca2+]i.
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