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钠电流的非平衡复活驱动小鼠心室早期后去极化。

Nonequilibrium reactivation of Na+ current drives early afterdepolarizations in mouse ventricle.

作者信息

Edwards Andrew G, Grandi Eleonora, Hake Johan E, Patel Sonia, Li Pan, Miyamoto Shigeki, Omens Jeffrey H, Heller Brown Joan, Bers Donald M, McCulloch Andrew D

机构信息

From the Department of Bioengineering (A.G.E., S.P., J.H.O., A.D.M.), Department of Pharmacology (S.M., J.H.B.), University of California, San Diego, La Jolla; Department of Pharmacology, University of California, Davis (E.G., D.M.B.); and Simula Research Laboratory, Center for Biomedical Computing, Lysaker, Oslo, Norway (J.E.H., P.L.).

出版信息

Circ Arrhythm Electrophysiol. 2014 Dec;7(6):1205-13. doi: 10.1161/CIRCEP.113.001666. Epub 2014 Sep 18.

DOI:10.1161/CIRCEP.113.001666

原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC4301603/

Abstract

BACKGROUND

Early afterdepolarizations (EADs) are triggers of cardiac arrhythmia driven by L-type Ca(2+) current (ICaL) reactivation or sarcoplasmic reticulum Ca(2+) release and Na(+)/Ca(2+) exchange. In large mammals the positive action potential plateau promotes ICaL reactivation, and the current paradigm holds that cardiac EAD dynamics are dominated by interaction between ICaL and the repolarizing K(+) currents. However, EADs are also frequent in the rapidly repolarizing mouse action potential, which should not readily permit ICaL reactivation. This suggests that murine EADs exhibit unique dynamics, which are key for interpreting arrhythmia mechanisms in this ubiquitous model organism. We investigated these dynamics in myocytes from arrhythmia-susceptible calcium calmodulin-dependent protein kinase II delta C (CaMKIIδC)-overexpressing mice (Tg), and via computational simulations.

METHODS AND RESULTS

In Tg myocytes, β-adrenergic challenge slowed late repolarization, potentiated sarcoplasmic reticulum Ca(2+) release, and initiated EADs below the ICaL activation range (-47 ± 0.7 mV). These EADs were abolished by caffeine and tetrodotoxin (but not ranolazine), suggesting that sarcoplasmic reticulum Ca(2+) release and Na(+) current (INa), but not late INa, are required for EAD initiation. Simulations suggest that potentiated sarcoplasmic reticulum Ca(2+) release and Na(+)/Ca(2+) exchange shape late action potential repolarization to favor nonequilibrium reactivation of INa and thereby drive the EAD upstroke. Action potential clamp experiments suggest that lidocaine eliminates virtually all inward current elicited by EADs, and that this effect occurs at concentrations (40-60 μmol/L) for which lidocaine remains specific for inactivated Na(+) channels. This strongly suggests that previously inactive channels are recruited during the EAD upstroke, and that nonequilibrium INa dynamics underlie murine EADs.

CONCLUSIONS

Nonequilibrium reactivation of INa drives murine EADs.

摘要

背景

早期后除极（EADs）是由L型钙电流（ICaL）再激活或肌浆网钙释放及钠/钙交换所驱动的心律失常触发因素。在大型哺乳动物中，正向动作电位平台期促进ICaL再激活，当前的范例认为心脏EAD动力学主要由ICaL与复极化钾电流之间的相互作用主导。然而，EADs在快速复极化的小鼠动作电位中也很常见，而这不应轻易允许ICaL再激活。这表明小鼠EADs表现出独特的动力学，这对于解释这种普遍存在的模式生物中的心律失常机制至关重要。我们在易患心律失常的钙调蛋白依赖性蛋白激酶IIδC（CaMKIIδC）过表达小鼠（Tg）的心肌细胞中以及通过计算模拟研究了这些动力学。

方法与结果

在Tg心肌细胞中，β肾上腺素能刺激减慢了晚期复极化，增强了肌浆网钙释放，并在ICaL激活范围以下（-47±0.7 mV）引发了EADs。这些EADs被咖啡因和河豚毒素（但不是雷诺嗪）消除，表明EAD起始需要肌浆网钙释放和钠电流（INa），而不是晚期INa。模拟表明，增强的肌浆网钙释放和钠/钙交换塑造了晚期动作电位复极化，有利于INa的非平衡再激活，从而驱动EAD的上升支。动作电位钳实验表明，利多卡因几乎消除了EADs引发的所有内向电流，并且这种效应发生在利多卡因对失活钠通道仍具有特异性的浓度（40 - 60 μmol/L）下。这强烈表明先前未激活的通道在EAD上升支期间被募集，并且非平衡INa动力学是小鼠EADs的基础。

结论

INa的非平衡再激活驱动小鼠EADs。