Rie Schultz Hansen

Inhibition of small-conductance Ca2+-activated K+ channels terminates and protects against atrial fibrillation.

Background—Recently, evidence has emerged that small-conductance Ca2+-activated K+ (SK) channels are predominantly expressed in the atria in a number of species including human. In rat, guinea pig, and rabbit ex vivo and in vivo models of atrial fibrillation (AF), we used 3 different SK channel inhibitors, UCL1684, N-(pyridin-2-yl)-4-(pyridin-2-yl)thiazol-2-amine (ICA), and NS8593, to assess the hypothesis that pharmacological inhibition of SK channels is antiarrhythmic. Methods and Results—In isolated, perfused guinea pig hearts, AF could be induced in all control hearts (n=7) with a combination of 1 &mgr;mol/L acetylcholine combined with electric stimulation. Pretreatment with 3 &mgr;mol/L NS8593, which had no effect on QT interval, prolonged the atrial effective refractory period by 37.1±7.7% (P<0.001) and prevented acetylcholine-induced AF (P<0.001, n=7). After AF induction, perfusion with NS8593 (10 &mgr;mol/L), UCL1684 (1 &mgr;mol/L), or ICA (1 &mgr;mol/L) terminated AF in all hearts, comparable to 10 &mgr;mol/L amiodarone. In isolated, perfused rat hearts, AF was induced with electric stimulation; 10 &mgr;mol/L NS8593 terminated AF and prevented reinduction of AF in all hearts (n=6, P<0.001). In all hearts, AF could be reinduced after washing. In isolated, perfused rabbit hearts, AF was induced with 10 &mgr;mol/L acetylcholine and burst pacing; 10 &mgr;mol/L NS8593 terminated AF and prevented reinduction of AF in all hearts (n=6, P<0.001). After washing, AF could be reinduced in 75% of the hearts (n=4, P=0.06). In an in vivo rat model of acute AF induced by burst pacing, injection of 5 mg/kg of either NS8593 or amiodarone shortened AF duration significantly to (23.2±20.0%, P<0.001, n=5, and 26.2±17.9%, P<0.001, n=5, respectively) as compared with injection of vehicle (96.3±33.2%, n=5). Conclusions—Inhibition of SK channels prolongs atrial effective refractory period without affecting QT interval and prevents and terminates AF ex vivo and in vivo, thus offering a promising new therapeutic opportunity in the treatment of AF.

A transient outward potassium current activator recapitulates the electrocardiographic manifestations of Brugada syndrome

AIMS Transient outward potassium current (I(to)) is thought to be central to the pathogenesis of the Brugada syndrome (BrS). However, an I((to)) activator has not been available with which to validate this hypothesis. Here, we provide a direct test of the hypothesis using a novel I(to) activator, NS5806. METHODS AND RESULTS Isolated canine ventricular myocytes and coronary-perfused wedge preparations were used. Whole-cell patch-clamp studies showed that NS5806 (10 microM) increased peak I(to) at +40 mV by 79 +/- 4% (24.5 +/- 2.2 to 43.6 +/- 3.4 pA/pF, n = 7) and slowed the time constant of inactivation from 12.6 +/- 3.2 to 20.3 +/- 2.9 ms (n = 7). The total charge carried by I(to) increased by 186% (from 363.9 +/- 40.0 to 1042.0 +/- 103.5 pA x ms/pF, n = 7). In ventricular wedge preparations, NS5806 increased phase 1 and notch amplitude of the action potential in the epicardium, but not in the endocardium, and accentuated the ECG J-wave, leading to the development of phase 2 re-entry and polymorphic ventricular tachycardia (n = 9). Although sodium and calcium channel blockers are capable of inducing BrS only in right ventricular (RV) wedge preparations, the I(to) activator was able to induce the phenotype in wedges from both ventricles. NS5806 induced BrS in 4/6 right and 2/10 left ventricular wedge preparations. CONCLUSION The I(to) activator NS5806 recapitulates the electrographic and arrhythmic manifestation of BrS, providing evidence in support of its pivotal role in the genesis of the disease. Our findings also suggest that a genetic defect leading to a gain of function of I(to) could explain variants of BrS, in which ST-segment elevation or J-waves are evident in both right and left ECG leads.

Downregulation of Kv7.4 Channel Activity in Primary and Secondary Hypertension

BACKGROUND Voltage-gated potassium (K(+)) channels encoded by KCNQ genes (Kv7 channels) have been identified in various rodent and human blood vessels as key regulators of vascular tone; however, nothing is known about the functional impact of these channels in vascular disease. We ascertained the effect of 3 structurally different activators of Kv7.2 through Kv7.5 channels (BMS-204352, S-1, and retigabine) on blood vessels from normotensive and hypertensive animals. METHODS AND RESULTS Precontracted thoracic aorta and mesenteric artery segments from normotensive rats were relaxed by all 3 Kv7 activators, with potencies of BMS-204352=S-1>retigabine. We also tested these agents in the coronary circulation using the Langendorff heart preparation. BMS-204352 and S-1 dose dependently increased coronary perfusion at concentrations between 0.1 and 10 μmol/L, whereas retigabine was effective at 1 to 10 μmol/L. In addition, S-1 increased K(+) currents in isolated mesenteric artery myocytes. The ability of these agents to relax precontracted vessels, increase coronary flow, or augment K(+) currents was impaired considerably in tissues isolated from spontaneously hypertensive rats (SHRs). Of the 5 KCNQ genes, only the expression of KCNQ4 was reduced (≈3.7 fold) in SHRs aorta. Kv7.4 protein levels were ≈50% lower in aortas and mesenteric arteries from spontaneously hypertensive rats compared with normotensive vessels. A similar attenuated response to S-1 and decreased Kv7.4 were observed in mesenteric arteries from mice made hypertensive by angiotensin II infusion compared with normotensive controls. CONCLUSIONS In 2 different rat and mouse models of hypertension, the functional impact of Kv7 channels was dramatically downregulated.

Effects on Atrial Fibrillation in Aged Hypertensive Rats by Ca2+-Activated K+ Channel Inhibition

We have shown previously that inhibition of small conductance Ca2+-activated K+ (SK) channels is antiarrhythmic in models of acutely induced atrial fibrillation (AF). These models, however, do not take into account that AF derives from a wide range of predisposing factors, the most prevalent being hypertension. In this study we assessed the effects of two different SK channel inhibitors, NS8593 and UCL1684, in aging, spontaneously hypertensive rats to examine their antiarrhythmic properties in a setting of hypertension-induced atrial remodeling. Male spontaneously hypertensive rats and the normotensive Wistar-Kyoto rat strain were divided in 2×3 groups of animals aged 3, 8, and 11 months, respectively. The animals were randomly assigned to treatment with NS8593, UCL1684, or vehicle, and open chest in vivo experiments including burst pacing–induced AF were performed. The aging spontaneously hypertensive rats were more vulnerable to AF induction both by S2 stimulation and burst pacing. Vehicle affected neither the atrial effective refractory period nor AF duration. SK channel inhibition with NS8593 and UCL1684 significantly increased the atrial effective refractory period and decreased AF duration in both the normotensive and hypertensive strains with no decline in efficacy as age increased. In conclusion, SK channel inhibition with NS8593 and UCL1684 possesses antiarrhythmic properties in a rat in vivo model of paroxysmal AF with hypertension-induced atrial remodeling. The present results support the notion that SK channels may offer a promising new therapeutic target in the treatment of AF.

The Duration of Pacing-induced Atrial Fibrillation Is Reduced in Vivo by Inhibition of Small Conductance Ca2+-activated K+ Channels

Atrial fibrillation (AF) is associated with increased morbidity and is in addition the most prevalent cardiac arrhythmia. Compounds used in pharmacological treatment has traditionally been divided into Na+ channel inhibitors, β-blockers, K+ channel inhibitors, and Ca2+ channel inhibitors, whereas newer multichannel blockers such as amiodarone and ranolazine have been introduced later. This study was devoted to the evaluation of an acute pacing-induced in vivo model of AF in rats. Antiarrhythmic effects of well-known compounds such as lidocaine, dofetilide, and ranolazine were confirmed in this model. In addition, antiarrhythmic effects of different inhibitors of Ca2+-activated small conductance K+ (SK) channels were demonstrated. Intravenous application of 5 mg/kg of the negative SK channel modulator NS8593 reduced AF duration by 64.5%, and the lowest significantly effective dose was 1.5 mg/kg. A dose-effect relationship was established based on 6 different dose groups. Furthermore, it was demonstrated that the antiarrhythmic effect of NS8593 and other tested drugs was associated with an increase in atrial effective refractory period. The functional role of SK channels was confirmed by 2 other SK channel inhibitors, UCL1684 and apamin, thereby confirming the hypothesis that these channels might constitute a new promising target for antiarrhythmic treatment.

Biophysical Characterization of the New Human Ether-A-Go-Go-Related Gene Channel Opener NS3623 [N-(4-Bromo-2-(1H-tetrazol-5-yl)-phenyl)-N′-(3′-trifluoromethylphenyl)urea]

Within the field of new antiarrhythmic compounds, the interesting idea of activating human ether-a-go-go-related gene (HERG1) potassium channels has recently been introduced. Potentially, drugs that increase HERG1 channel activity will augment the repolarizing current of the cardiac myocytes and stabilize the diastolic interval. This may make the myocardium more resistant to events that cause arrhythmias. We here present the compound N-(4-bromo-2-(1H-tetrazol-5-yl)-phenyl)-N′-(3′-trifluoromethylphenyl)urea (NS3623), which has the ability to activate HERG1 channels expressed in Xenopus laevis oocytes with an EC50 value of 79.4 μM. Exposure of HERG1 channels to NS3623 affects the voltage-dependent release from inactivation, resulting in a half-inactivation voltage that is rightward-shifted by 17.7 mV. Moreover, the compound affects the time constant of inactivation, leading to a slower onset of inactivation of the macroscopic HERG1 currents. We also characterized the ability of NS3623 to increase the activity of different mutated HERG1 channels. The mutants S620T and S631A are severely compromised in their ability to inactivate. Application of NS3623 to any of these two mutants did not result in increased HERG1 current. In contrast, application of NS3623 to the mutant F656M increased HERG1 current to a larger extent than what was observed with wild-type HERG1 channels. Because the amino acid F656 is essential for high-affinity inhibition of HERG1 channels, it is concluded that NS3623 has a dual mode of action, being both an activator and an inhibitor of HERG1 channels. Finally, we show that NS3623 has the ability to shorten action potential durations in guinea pig papillary muscle.

hERG1 channel activators : A new anti-arrhythmic principle

The cardiac action potential is the result of an orchestrated function of a number of different ion channels. Action potential repolarisation in humans relies on three potassium current components named I(Kr), I(Ks) and I(K1) with party overlapping functions. The ion channel alpha-subunits conducting these currents are hERG1 (Kv11.1), KCNQ1 (Kv7.1) and Kir2.1. Loss-of-function in any of these currents can result in long QT syndrome. Long QT is a pro-arrhythmic disease with increased risk of developing lethal ventricular arrhythmias such as Torsade de Pointes and ventricular fibrillation. In addition to congenital long QT, acquired long QT can also constitute a safety risk. Especially unintended inhibition of the hERG1 channel constitutes a major concern in the development of new drugs. Based on this knowledge is has been speculated whether activation of the hERG1 channel could be anti-arrhythmic and thereby constitute a new principle in treatment of cardiac arrhythmogenic disorders. The first hERG1 channel agonist was reported in 2005 and a limited number of such compounds are now available. In the present text we review results obtained by hERG1 channel activation in a number of cardiac relevant settings from in vitro to in vivo. It is demonstrated how the principle of hERG1 channel activation under certain circumstances can constitute a new anti-arrhythmogenic principle. Finally, important conceptual differences between the short QT syndrome and the hERG1 channel activation, are evaluated.

Pharmacological activation of rapid delayed rectifier potassium current suppresses bradycardia-induced triggered activity in the isolated guinea pig heart.

Recently, attention has been drawn to compounds that activate the human ether-a-go-go channel potassium channel (hERG), which is responsible for the repolarizing rapid delayed rectifier potassium current (IKr) in the mammalian myocardium. The compound NS3623 [N-(4-bromo-2-(1H-tetrazol-5-yl)-phenyl)-N′-(3′-trifluoromethylphenyl) urea] increases the macroscopic current conducted by the hERG channels by increasing the time constant for channel inactivation, which we have reported earlier. In vitro studies suggest that pharmacological activation is an attractive approach for the treatment of some arrhythmias. We present here data that support that NS3623 affects native IKr and report the effects that activating this potassium current have in the intact guinea pig heart. In Langendorff-perfused hearts, the compound showed a concentration-dependent shortening of action potential duration, which was also detected as concentration-dependent shorter QT intervals. There was no sign of action potential triangulation or reverse use dependence. NS3623 decreased QT variability and distinctly decreased the occurrence of extrasystoles in the acutely bradypaced hearts. Taken together, the present data strongly support the concept of using hERG activators as a treatment for certain kinds of arrhythmias and suggest further investigation of this new approach.

In vivo effects of the IKr agonist NS3623 on cardiac electrophysiology of the guinea pig.

The long QT syndrome is characterized by a prolongation of the QT interval measured on the surface electrocardiogram. Prolonging the QT interval increases the risk of dangerous ventricular fibrillations, eventually leading to sudden cardiac death. Pharmacologically induced QT interval prolongations are most often caused by antagonizing effects on the repolarizing cardiac current called IKr. In humans IKr is mediated by the human ether-a-go-go related gene (hERG) potassium channel. We recently presented NS3623, a compound that selectively activates this channel. The present study was dedicated to examining the in vivo effects of NS3623. Injection of 30 mg/kg NS3623 shortened the corrected QT interval by 25 ± 4% in anaesthetized guinea pigs. Accordingly, 50 mg/kg of NS3623 shortened the QT interval by 30 ± 6% in conscious guinea pigs. Finally, pharmacologically induced QT prolongation by a hERG channel antagonist (0.15 mg/kg E-4031) could be reverted by injection of NS3623 (50 mg/kg) in conscious guinea pigs. In conclusion, the present in vivo study demonstrates that injection of the hERG channel agonist NS3623 results in shortening of the QTc interval as well as reversal of a pharmacologically induced QT prolongation in both anaesthetized and conscious guinea pigs.

Antiarrhythmic effect of IKr activation in a cellular model of LQT3

BACKGROUND Long QT syndrome type 3 (LQT3) is an inherited cardiac disorder caused by gain-of-function mutations in the cardiac voltage-gated sodium channel, Na(v)1.5. LQT3 is associated with the polymorphic ventricular tachycardia torsades de pointes (TdP), which can lead to syncope and sudden cardiac death. The sea anemone toxin ATX-II has been shown to inhibit the inactivation of Na(v)1.5, thereby closely mimicking the underlying cause of LQT3 in patients. OBJECTIVE The hypothesis for this study was that activation of the I(Kr) current could counteract the proarrhythmic effects of ATX-II. METHODS Two different activators of I(Kr), NS3623 and mallotoxin (MTX), were used in patch clamp studies of ventricular cardiac myocytes acutely isolated from guinea pig to test the effects of selective I(Kr) activation alone and in the presence of ATX-II. Action potentials were elicited at 1 Hz by current injection and the cells were kept at 32 degrees C to 35 degrees C. RESULTS NS3623 significantly shortened action potential duration at 90% repolarization (APD(90)) compared with controls in a dose-dependent manner. Furthermore, it reduced triangulation, which is potentially antiarrhythmic. Application of ATX-II (10 nM) was proarrhythmic, causing a profound increase of APD(90) as well as early afterdepolarizations and increased beat-to-beat variability. Two independent I(Kr) activators attenuated the proarrhythmic effects of ATX-II. NS3623 did not affect the late sodium current (I(NaL)) in the presence of ATX-II. Thus, the antiarrhythmic effect of NS3623 is likely to be caused by selective I(Kr) activation. CONCLUSION The present data show the antiarrhythmic potential of selective I(Kr) activation in a cellular model of the LQT3 syndrome.