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ABSTRACT: Congenital long- or short-QT syndrome may lead to life-threatening ventricular tachycardia and sudden cardiac death. Apart from the rare disease-causing mutations, common genetic variants in CAPON, a neuronal nitric oxide synthase (NOS1) regulator, have recently been associated with QT interval variations in a human whole-genome association study. CAPON had been unsuspected of playing a role in cardiac repolarization; indeed, its physiological role in the heart (if any) is unknown. To define the biological effects of CAPON in the heart, we investigated endogenous CAPON protein expression and protein-protein interactions in the heart and performed electrophysiological studies in isolated ventricular myocytes with and without CAPON overexpression. We find that CAPON protein is expressed in the heart and interacts with NOS1 to accelerate cardiac repolarization by inhibition of L-type calcium channel. Our findings provide a rationale for the association of CAPON gene variants with extremes of the QT interval in human populations.
Proceedings of the National Academy of Sciences 04/2008; 105(11):4477-82. · 9.68 Impact Factor
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ABSTRACT: As an alternative to electronic pacemakers, we explored the feasibility of converting ventricular myocytes into pacemakers by somatic cell fusion. The idea is to create chemically induced fusion between myocytes and syngeneic fibroblasts engineered to express HCN1 pacemaker channels (HCN1-fibroblasts). HCN1-fibroblasts were fused with freshly isolated guinea pig ventricular myocytes using polyethylene-glycol 1500. In vivo fused myocyte-HCN1-fibroblast cells exhibited spontaneously oscillating action potentials; the firing frequency increased with beta-adrenergic stimulation. The heterokaryons created ectopic ventricular pacemaker activity in vivo at the site of cell injection. Coculture of nonfused HCN1-fibroblasts and myocytes without polyethylene-glycol 1500 revealed no evidence of dye transfer, demonstrating that the I(f)-mediated pacemaker activity arises from heterokaryons rather than electrotonic coupling. This nonviral, non-stem cell approach enables autologous, adult somatic cell therapy to create biopacemakers.
Circulation Research 04/2007; 100(8):1112-5. · 9.49 Impact Factor
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ABSTRACT: One key element of natural pacemakers is the pacemaker current encoded by the hyperpolarization-activated nucleotide-gated channel (HCN) gene family. Although HCN gene transfer has been used to engineer biological pacemakers, this strategy may be confounded by unpredictable consequences of heteromultimerization with endogenous HCN family members and limited flexibility with regard to frequency tuning of the engineered pacemaker.
To circumvent these limitations, we converted a depolarization-activated potassium-selective channel, Kv1.4, into a hyperpolarization-activated nonselective channel by site-directed mutagenesis (R447N, L448A, and R453I in S4 and G528S in the pore). Gene transfer into ventricular myocardium demonstrated the ability of this construct to induce pacemaker activity with spontaneous action potential oscillations in adult ventricular myocytes and idioventricular rhythms by in vivo electrocardiography.
Given the sparse expression of Kv1 family channels in the human ventricle, gene transfer of a synthetic pacemaker channel based on the Kv1 family has novel therapeutic potential as a biological alternative to electronic pacemakers.
Circulation 11/2006; 114(16):1682-6. · 14.74 Impact Factor
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