Department of Biomedical Physiology and Kinesiology, Simon Fraser University, British Columbia, Canada.
Am J Physiol Heart Circ Physiol. 2020 Aug 1;319(2):H251-H261. doi: 10.1152/ajpheart.00038.2020. Epub 2020 Jun 19.
Human ether-à-go-go related gene (hERG) K channels are important in cardiac repolarization, and their dysfunction causes prolongation of the ventricular action potential, long QT syndrome, and arrhythmia. As such, approaches to augment hERG channel function, such as activator compounds, have been of significant interest due to their marked therapeutic potential. Activator compounds that hinder channel inactivation abbreviate action potential duration (APD) but carry risk of overcorrection leading to short QT syndrome. Enhanced risk by overcorrection of the APD may be tempered by activator-induced increased refractoriness; however, investigation of the cumulative effect of hERG activator compounds on the balance of these effects in whole organ systems is lacking. Here, we have investigated the antiarrhythmic capability of a hERG activator, RPR260243, which primarily augments channel function by slowing deactivation kinetics in ex vivo zebrafish whole hearts. We show that RPR260243 abbreviates the ventricular APD, reduces triangulation, and steepens the slope of the electrical restitution curve. In addition, RPR260243 increases the post-repolarization refractory period. We provide evidence that this latter effect arises from RPR260243-induced enhancement of hERG channel-protective currents flowing early in the refractory period. Finally, the cumulative effect of RPR260243 on arrhythmogenicity in whole organ zebrafish hearts is demonstrated by the restoration of normal rhythm in hearts presenting dofetilide-induced arrhythmia. These findings in a whole organ model demonstrate the antiarrhythmic benefit of hERG activator compounds that modify both APD and refractoriness. Furthermore, our results demonstrate that targeted slowing of hERG channel deactivation and enhancement of protective currents may provide an effective antiarrhythmic approach. hERG channel dysfunction causes long QT syndrome and arrhythmia. Activator compounds have been of significant interest due to their therapeutic potential. We used the whole organ zebrafish heart model to demonstrate the antiarrhythmic benefit of the hERG activator, RPR260243. The activator abbreviated APD and increased refractoriness, the combined effect of which rescued induced ventricular arrhythmia. Our findings show that the targeted slowing of hERG channel deactivation and enhancement of protective currents caused by the RPR260243 activator may provide an effective antiarrhythmic approach.
人类 ether-à-go-go 相关基因 (hERG) K 通道在心脏复极中起重要作用,其功能障碍导致心室动作电位延长、长 QT 综合征和心律失常。因此,增强 hERG 通道功能的方法,如激活剂化合物,因其具有显著的治疗潜力而受到极大关注。阻碍通道失活的激活剂化合物会缩短动作电位时程 (APD),但存在过度矫正导致短 QT 综合征的风险。APD 过度矫正增加的风险可能会因激活剂诱导的不应期延长而缓和;然而,在整个器官系统中,关于 hERG 激活剂化合物对这些效应平衡的累积效应的研究尚缺乏。在这里,我们研究了一种 hERG 激活剂 RPR260243 的抗心律失常能力,该激活剂主要通过减慢离体斑马鱼心脏整体 ex vivo 中的失活动力学来增强通道功能。我们表明,RPR260243 缩短心室 APD、减少三角化并使电复极化曲线斜率变陡。此外,RPR260243 增加复极化后不应期。我们提供的证据表明,这种效应是由于 RPR260243 诱导的 hERG 通道保护性电流增强而引起的,该电流在复极化早期流动。最后,通过恢复多非利特诱导心律失常的心脏的正常节律,证明了 RPR260243 在整个器官斑马鱼心脏中的累积效应对心律失常的影响。这些在整体器官模型中的发现证明了既能改变 APD 又能改变不应期的 hERG 激活剂化合物的抗心律失常益处。此外,我们的结果表明,靶向减缓 hERG 通道失活和增强保护性电流可能提供一种有效的抗心律失常方法。hERG 通道功能障碍导致长 QT 综合征和心律失常。激活剂化合物因其治疗潜力而受到极大关注。我们使用整个器官斑马鱼心脏模型来证明 hERG 激活剂 RPR260243 的抗心律失常益处。该激活剂缩短了 APD 并增加了不应期,这两者的综合作用挽救了诱导的心室心律失常。我们的发现表明,RPR260243 激活剂引起的 hERG 通道失活的靶向减缓和保护性电流的增强可能提供一种有效的抗心律失常方法。
