Molecular dissection of cardiac repolarization by in vivo Kv4.3 gene transfer

Heart failure leads to marked suppression of the Ca2+-independent transient outward current (I-tol), but it is not clear whether I-tol downregulation suffices to explain the concomitant action potential prolongation. To inves tigate the role of I-tol in cardiac repolarization while circumventing cult ure-related action potential alterations, we injected adenovirus vectors in vivo to overexpress or to suppress I-to1 in guinea pigs and rats, respecti vely. Myocytes were isolated 72 hours after intramyocardial injection and s timulation of the ecdysone-inducible vectors with intraperitoneal injection of an ecdysone analog. Kv4.3-infected guinea pig myocytes exhibited robust transient outward currents. Increasing density of I-tol progressively depr essed the plateau potential in Kv4.3-infected guinea pig myocytes and abbre viated action potential duration (APD). In vivo infection with a dominant-n egative Kv4.3-W362F construct suppressed peak I-tol in rat ventriculocytes, elevated the plateau height, significantly prolonged the APD, and resulted in a prolongation by about 30% of the QT interval in surface electrocardio gram recordings. These results indicate that I-tol plays a crucial role in setting the plateau potential and overall APD, supporting a causative role for suppression of this current in the electrophysiological alterations of heart failure. The electrocardiographic findings indicate that somatic gene transfer can be used to create gene-specific animal models of the long QT syndrome.