Fabiana S. Scornik scite author profile

Background-The Brugada syndrome displays an autosomal dominant mode of transmission with low penetrance. Despite equal genetic transmission of the disease, the clinical phenotype is 8 to 10 times more prevalent in males than in females. The basis for this intriguing sex-related distinction is unknown. The present study tests the hypothesis that the disparity in expression of the Brugada phenotype is a result of a more prominent I to -mediated action potential notch in the right ventricular (RV) epicardium of males versus females. Methods and Results-We studied epicardial tissue slices, arterially perfused wedge preparations, and dissociated epicardial myocytes isolated from male and female canine hearts. RV epicardium action potential phase 1 amplitude was 64.8Ϯ2.0% of that of phase 2 in males compared with 73.8Ϯ4.4% in females (PϽ0.05) at a cycle length of 2000 ms. I to density was 26% smaller and time constant for inactivation 17% smaller at ϩ40 mV in female versus male RV epicardial cells (PϽ0.05). The other functional characteristics of I to , including the voltage dependence of inactivation and time course of reactivation, were no different between the sexes. Pinacidil caused loss of action potential dome in male, but not female, RV epicardial tissue slices. Terfenadine (5 mol/L) induced phase 2 reentry in 6 of 7 male but only 2 of 7 female arterially perfused wedge preparations. Two of 6 male and 1 of 2 female preparations developed polymorphic ventricular tachycardia/ventricular fibrillation. Conclusions-Our results suggest that the predominance of the Brugada phenotype in males is a result of the presence of a more prominent I to in males versus females.

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Electrophysiologic Properties and Antiarrhythmic Actions of a Novel Antianginal Agent

Antzelevitch

Belardinelli²,

Wu³

et al. 2004

J Cardiovasc Pharmacol Ther

118

107

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Ranolazine is a novel antianginal agent capable of producing anti-ischemic effects at plasma concentrations of 2 to 6 microM without a significant reduction of heart rate or blood pressure. This review summarizes the electrophysiologic properties of ranolazine. Ranolazine significantly blocks I(Kr) (IC(50) = 12 microM), late I(Na), late I(Ca), peak I(Ca), I(Na-Ca) (IC(50) = 5.9, 50, 296, and 91 microM, respectively) and I(Ks) (17% at 30 microM), but causes little or no inhibition of I(to) or I(K1). In left ventricular tissue and wedge preparations, ranolazine produces a concentration-dependent prolongation of action potential duration (APD) in epicardium, but abbreviation of APD of M cells, leading to either no change or a reduction in transmural dispersion of repolarization (TDR). The result is a modest prolongation of the QT interval. Prolongation of APD and QT by ranolazine is fundamentally different from that of other drugs that block I(Kr) and induce torsade de pointes in that APD prolongation is rate-independent (ie, does not display reverse rate-dependent prolongation of APD) and is not associated with early after depolarizations, triggered activity, increased spatial dispersion of repolarization, or polymorphic ventricular tachycardia. Torsade de pointes arrhythmias were not observed spontaneously nor could they be induced with programmed electrical stimulation in the presence of ranolazine at concentrations as high as 100 microM. Indeed, ranolazine was found to possess significant antiarrhythmic activity, acting to suppress the arrhythmogenic effects of other QT-prolonging drugs. Ranolazine produces ion channel effects similar to those observed after chronic exposure to amiodarone (reduced late I(Na), I(Kr), I(Ks), and I(Ca)). Ranolazine's actions to reduce TDR and suppress early after depolarization suggest that in addition to its anti-anginal actions, the drug possesses antiarrhythmic activity.

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A Missense Mutation in the Sodium Channel β2 Subunit RevealsSCN2Bas a New Candidate Gene for Brugada Syndrome

et al. 2013

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Brugada Syndrome (BrS) is a familial disease associated with sudden cardiac death. A 20%-25% of BrS patients carry genetic defects that cause loss-of-function of the voltage-gated cardiac sodium channel. Thus, 70%-75% of patients remain without a genetic diagnosis. In this work, we identified a novel missense mutation (p.Asp211Gly) in the sodium β2 subunit encoded by SCN2B, in a woman diagnosed with BrS. We studied the sodium current (INa ) from cells coexpressing Nav 1.5 and wild-type (β2WT) or mutant (β2D211G) β2 subunits. Our electrophysiological analysis showed a 39.4% reduction in INa density when Nav 1.5 was coexpressed with the β2D211G. Single channel analysis showed that the mutation did not affect the Nav 1.5 unitary channel conductance. Instead, protein membrane detection experiments suggested that β2D211G decreases Nav 1.5 cell surface expression. The effect of the mutant β2 subunit on the INa strongly suggests that SCN2B is a new candidate gene associated with BrS.

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Modulation of coronary smooth muscle KCa channels by Gs alpha independent of phosphorylation by protein kinase A

Scornik

Codina

Birnbaumer

et al. 1993

American Journal of Physiology-Heart and Circulatory Physiology

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The occupancy of beta-receptors in the smooth muscle membrane of the coronary arteries produces vasodilation and a concomitant hyperpolarization. Large conductance calcium-activated K (KCa) channels are likely to be involved in such hyperpolarization, since they are densely distributed in coronary myocytes, and they are targets of beta-adrenergic stimulation in other smooth muscles. We sought to explore if coronary smooth muscle KCa channels are modulated by beta-agonists and we studied the mechanisms of their activation. We found that KCa channels reconstituted into lipid bilayers were activated in the presence of GTP by the beta-adrenergic receptor agonist isoproterenol. KCa channels were also stimulated on non-specific activation of an endogenous G protein(s) with guanosine 5'-O-(3-thiotriphosphate) (GTP gamma S), on addition of a purified activated stimulatory G protein (Gs alpha), and when the catalytic subunit of protein kinase A (PKA) was added. Inhibition of PKA activity prevented KCa channel stimulation by PKA, but not by endogenous G protein or by exogenous Gs alpha. These results indicate that beta-adrenoceptor activation of coronary smooth muscle KCa channels results from a dual control: 1) a membrane delimited, possibly direct action of Gs, independent of PKA-mediated phosphorylation; and 2) by PKA-dependent phosphorylation.

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