Background-Antiarrhythmic management of atrial fibrillation (AF) remains a major clinical challenge. Mechanismbased approaches to AF therapy are sought to increase effectiveness and to provide individualized patient care. K 2P 3.1 (TASK-1 [tandem of P domains in a weak inward-rectifying K + channel-related acid-sensitive K + channel-1]) 2-poredomain K + (K 2P ) channels have been implicated in action potential regulation in animal models. However, their role in the pathophysiology and treatment of paroxysmal and chronic patients with AF is unknown. Methods and Results-Right and left atrial tissue was obtained from patients with paroxysmal or chronic AF and from control subjects in sinus rhythm. Ion channel expression was analyzed by quantitative real-time polymerase chain reaction and Western blot. Membrane currents and action potentials were recorded using voltage-and current-clamp techniques. K 2P 3.1 subunits exhibited predominantly atrial expression, and atrial K 2P 3.1 transcript levels were highest among functional K 2P channels. K 2P 3.1 mRNA and protein levels were increased in chronic AF. Enhancement of corresponding currents in the right atrium resulted in shortened action potential duration at 90% of repolarization (APD 90 ) compared with patients in sinus rhythm. In contrast, K 2P 3.1 expression was not significantly affected in subjects with paroxysmal AF. Pharmacological K 2P 3.1 inhibition prolonged APD 90 in atrial myocytes from patients with chronic AF to values observed among control subjects in sinus rhythm. Conclusions-Enhancement of atrium-selective K 2P 3.1 currents contributes to APD shortening in patients with chronic AF, and K 2P 3.1 channel inhibition reverses AF-related APD shortening. These results highlight the potential of K 2P 3.1 as a novel drug target for mechanism-based AF therapy.
TASK-1, a member of the recently identified K2P channel family, is mainly expressed in the heart and the nervous system. TASK-1 is regulated by several physiological and pathological conditions and functions as a background potassium channel. However, there are limited data concerning the significance of TASK-1 in cardiac physiology. We studied the functional role of TASK-1 in the heart by cardiac phenotyping the TASK-1-deficient mouse (TASK-1(-/-)). TASK-1 was predominantly expressed in the ventricles of control animals. Real-time PCR and immunoblot demonstrated that the expression of seven other K2P channels was unchanged in TASK-1(-/-) mice. No structural or functional abnormalities were found by histology and echocardiography. Electrophysiological studies recording monophasic action potentials (MAPs) showed a significant prolongation of action potential duration in spontaneously beating and atrially paced hearts, respectively. Surface ECGs of TASK-1(-/-) mice revealed a significant prolongation of the rate corrected QT interval. Telemetric ECG recordings for 24 h, during physical and pharmacological stress testing and after ischemia/reperfusion injury did not result in a higher incidence of arrhythmias. Infarct size was comparable in both genotypes. However, TASK-1(-/-) mice had a higher mean heart rate and significantly reduced heart rate variability (HRV). Time and frequency domain measurements as well as baroreceptor reflex testing revealed a sympathovagal imbalance with a shift to an increase in sympathetic influence in TASK-1(-/-) mice. In conclusion, TASK-1 plays a functional role in the repolarization of the cardiac action potential in vivo and contributes to the maintenance of HRV.
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