Mechanisms of spontaneous Ca2+ release-mediated arrhythmia in a novel 3D human atrial myocyte model: II. Ca2+-handling protein variation

Abstract

AbstractDisruption of the transverse-axial tubule system (TATS) in diseases such as heart failure and atrial fibrillation occurs in combination with changes in the expression and distribution of key Ca2+- handling proteins. Together this ultrastructural and ionic remodeling is associated with aberrant Ca2+ cycling and electrophysiological instabilities that underly arrhythmic activity. However, due to the concurrent changes in TATs and Ca2+-handling protein expression and localization that occur in disease it is difficult to distinguish their individual contributions to the arrhythmogenic state. To investigate this, we applied our novel 3D human atrial myocyte model with spatially detailed Ca2+ diffusion and TATS to investigate the isolated and interactive effects of changes in expression and localization of key Ca2+-handling proteins and variable TATS density on Ca2+- handling abnormality driven membrane instabilities. We show that modulating the expression and distribution of the sodium-calcium exchanger, ryanodine receptors, and the sarcoplasmic reticulum (SR) Ca2+ buffer calsequestrin have varying pro and anti-arrhythmic effects depending on the balance of opposing influences on SR Ca2+ leak-load and Ca2+-voltage relationships. Interestingly, the impact of protein remodeling on Ca2+-driven proarrhythmic behavior varied dramatically depending on TATS density, with intermediately tubulated cells being more severely affected compared to detubulated and densely tubulated myocytes. This work provides novel mechanistic insight into the distinct and interactive consequences of TATS and Ca2+-handling protein remodeling that underlies dysfunctional Ca2+ cycling and electrophysiological instability in disease.Key PointsIn our companion paper we developed a 3D human atrial myocyte model, coupling electrophysiology and Ca2+ handling with subcellular spatial details governed by the transverse-axial tubule system (TATS).Here we utilize this model to mechanistically examine the impact of TATS loss and changes in the expression and distribution of key Ca2+-handling proteins known to be remodeled in disease on Ca2+ homeostasis and electrophysiological stability.We demonstrate that varying the expression and localization of these proteins has variable pro- and anti-arrhythmic effects with outcomes displaying dependence on TATS density.Whereas detubulated myocytes typically appear unaffected and densely tubulated cells seem protected, the arrhythmogenic effects of Ca2+ handling protein remodeling are profound in intermediately tubulated cells.Our work shows the interaction between TATS and Ca2+-handling protein remodeling that underlies the Ca2+-driven proarrhythmic behavior observed in AF and may help to predict the effects of antiarrhythmic strategies at varying stages of ultrastructural remodeling.