BACKGROUND: Sudden cardiac death often involves arrhythmias triggered by metabolic stress. Loss of mitochondrial function is thought to contribute to the arrhythmogenic substrate, but how mitochondria contribute to uncoordinated electrical activity is poorly understood. It has been proposed that the formation of metabolic current sinks, caused by the nonuniform collapse of mitochondrial inner membrane potential (ΔΨm), contributes to re-entrant arrhythmias because ΔΨm depolarization is tightly coupled to the activation of sarcolemmal ATP-sensitive K(+) channels, hastening action potential repolarization and shortening the refractory period. METHODS AND RESULTS: Here, we use computational and experimental methods to investigate how ΔΨm instability can induce re-entrant arrhythmias. We develop the first tissue-level model of cardiac electrical propagation incorporating cellular electrophysiology, excitation-contraction coupling, mitochondrial energetics, and reactive oxygen species balance. Simulations show that re-entry and fibrillation can be initiated by regional ΔΨm loss because of the disparity of refractory periods inside and outside the metabolic sink. Computational results are compared with the effects of a metabolic sink generated experimentally by local perfusion of a mitochondrial uncoupler in a monolayer of cardiac myocytes. CONCLUSIONS: The results demonstrate that regional mitochondrial depolarization triggered by oxidative stress activates sarcolemmal ATP-sensitive K(+) currents to form a metabolic sink. Consequent shortening of the action potential inside, but not outside, the sink increases the propensity for re-entry. ΔΨm recovery during pacing can lead to novel mechanisms of ectopic activation. The findings highlight the importance of mitochondria as potential therapeutic targets for sudden death associated with cardiovascular disease.
BACKGROUND: Sudden cardiac death often involves arrhythmias triggered by metabolic stress. Loss of mitochondrial function is thought to contribute to the arrhythmogenic substrate, but how mitochondria contribute to uncoordinated electrical activity is poorly understood. It has been proposed that the formation of metabolic current sinks, caused by the nonuniform collapse of mitochondrial inner membrane potential (ΔΨm), contributes to re-entrant arrhythmias because ΔΨm depolarization is tightly coupled to the activation of sarcolemmal ATP-sensitive K(+) channels, hastening action potential repolarization and shortening the refractory period. METHODS AND RESULTS: Here, we use computational and experimental methods to investigate how ΔΨm instability can induce re-entrant arrhythmias. We develop the first tissue-level model of cardiac electrical propagation incorporating cellular electrophysiology, excitation-contraction coupling, mitochondrial energetics, and reactive oxygen species balance. Simulations show that re-entry and fibrillation can be initiated by regional ΔΨm loss because of the disparity of refractory periods inside and outside the metabolic sink. Computational results are compared with the effects of a metabolic sink generated experimentally by local perfusion of a mitochondrial uncoupler in a monolayer of cardiac myocytes. CONCLUSIONS: The results demonstrate that regional mitochondrial depolarization triggered by oxidative stress activates sarcolemmal ATP-sensitive K(+) currents to form a metabolic sink. Consequent shortening of the action potential inside, but not outside, the sink increases the propensity for re-entry. ΔΨm recovery during pacing can lead to novel mechanisms of ectopic activation. The findings highlight the importance of mitochondria as potential therapeutic targets for sudden death associated with cardiovascular disease.
Entities:
Keywords:
KATP channels; arrhythmias, cardiac; mitochondria; reactive oxygen species
Authors: Alexander R Lyon; Paul J Joudrey; Dongzhu Jin; Robert D Nass; Miguel A Aon; Brian O'Rourke; Fadi G Akar Journal: J Mol Cell Cardiol Date: 2010-07-16 Impact factor: 5.000
Authors: Argelia Medeiros-Domingo; Bi-Hua Tan; Lia Crotti; David J Tester; Lee Eckhardt; Alessandra Cuoretti; Stacie L Kroboth; Chunhua Song; Qing Zhou; Doug Kopp; Peter J Schwartz; Jonathan C Makielski; Michael J Ackerman Journal: Heart Rhythm Date: 2010-06-15 Impact factor: 6.343
Authors: David A Brown; Miguel A Aon; Chad R Frasier; Ruben C Sloan; Andrew H Maloney; Ethan J Anderson; Brian O'Rourke Journal: J Mol Cell Cardiol Date: 2009-12-03 Impact factor: 5.000
Authors: Matthew S Sulkin; Bas J Boukens; Megan Tetlow; Sarah R Gutbrod; Fu Siong Ng; Igor R Efimov Journal: Am J Physiol Heart Circ Physiol Date: 2014-08-15 Impact factor: 4.733
Authors: Jian Liu; Peipei Wang; Luyun Zou; Jing Qu; Silvio Litovsky; Patrick Umeda; Lufang Zhou; John Chatham; Susan A Marsh; Louis J Dell'Italia; Steven G Lloyd Journal: Am J Physiol Heart Circ Physiol Date: 2014-06-13 Impact factor: 4.733
Authors: Dai-Yin Lu; Hulya Yalçin; Fatih Yalçin; Min Zhao; Sanjay Sivalokanathan; Ines Valenta; Abdel Tahari; Martin G Pomper; Theodore P Abraham; Thomas H Schindler; M Roselle Abraham Journal: Am J Cardiol Date: 2018-02-06 Impact factor: 2.778
Authors: Colleen E Clancy; Ye Chen-Izu; Donald M Bers; Luiz Belardinelli; Penelope A Boyden; Laszlo Csernoch; Sanda Despa; Bernard Fermini; Livia C Hool; Leighton Izu; Robert S Kass; W Jonathan Lederer; William E Louch; Christoph Maack; Alicia Matiazzi; Zhilin Qu; Sridharan Rajamani; Crystal M Rippinger; Ole M Sejersted; Brian O'Rourke; James N Weiss; András Varró; Antonio Zaza Journal: J Physiol Date: 2015-03-15 Impact factor: 5.182
Authors: Yiyi Zhang; Eliseo Guallar; Foram N Ashar; Ryan J Longchamps; Christina A Castellani; John Lane; Megan L Grove; Josef Coresh; Nona Sotoodehnia; Leonard Ilkhanoff; Eric Boerwinkle; Nathan Pankratz; Dan E Arking Journal: Eur Heart J Date: 2017-12-07 Impact factor: 29.983