Jonas Goldin Diness

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.

Role of small-conductance calcium-activated potassium channels in atrial electrophysiology and fibrillation in the dog.

Background— Recent evidence points to functional Ca2+-dependent K+ (SK) channels in the heart that may govern atrial fibrillation (AF) risk, but the underlying mechanisms are unclear. This study addressed the role of SK channels in atrial repolarization and AF persistence in a canine AF model. Methods and Results— Electrophysiological variables were assessed in dogs subjected to atrial remodeling by 7-day atrial tachypacing (AT-P), as well as controls. Ionic currents and single-channel properties were measured in isolated canine atrial cardiomyocytes by patch clamp. NS8593, a putative selective SK blocker, suppressed SK current with an IC50 of ≈5 &mgr;mol/L, without affecting Na+, Ca2+, or other K+ currents. Whole-cell SK current sensitive to NS8593 was significantly larger in pulmonary vein (PV) versus left atrial (LA) cells, without a difference in SK single-channel open probability (Po), whereas AT-P enhanced both whole-cell SK currents and single-channel Po. SK-current block increased action potential duration in both PV and LA cells after AT-P; but only in PV cells in absence of AT-P. SK2 expression was more abundant at both mRNA and protein levels for PV versus LA in control dogs, in both control and AT-P; AT-P upregulated only SK1 at the protein level. Intravenous administration of NS8593 (5 mg/kg) significantly prolonged atrial refractoriness and reduced AF duration without affecting the Wenckebach cycle length, left ventricular refractoriness, or blood pressure. Conclusions— SK currents play a role in canine atrial repolarization, are larger in PVs than LA, are enhanced by atrial-tachycardia remodeling, and appear to participate in promoting AF maintenance. These results are relevant to the potential mechanisms underlying the association between SK single-nucleotide polymorphisms and AF and suggest SK blockers as potentially interesting anti-AF drugs.

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.

Small-conductance calcium-activated potassium (SK) channels contribute to action potential repolarization in human atria

AIMS Small-conductance calcium-activated potassium (SK) channels are expressed in the heart of various species, including humans. The aim of the present study was to address whether SK channels play a functional role in human atria. METHODS AND RESULTS Quantitative real-time PCR analyses showed higher transcript levels of SK2 and SK3 than that of the SK1 subtype in human atrial tissue. SK2 and SK3 were reduced in chronic atrial fibrillation (AF) compared with sinus rhythm (SR) patients. Immunohistochemistry using confocal microscopy revealed widespread expression of SK2 in atrial myocytes. Two SK channel inhibitors (NS8593 and ICAGEN) were tested in heterologous expression systems revealing ICAGEN as being highly selective for SK channels, while NS8593 showed less selectivity for these channels. In isolated atrial myocytes from SR patients, both inhibitors decreased inwardly rectifying K(+) currents by ∼15% and prolonged action potential duration (APD), but no effect was observed in myocytes from AF patients. In trabeculae muscle strips from right atrial appendages of SR patients, both compounds increased APD and effective refractory period, and depolarized the resting membrane potential, while only NS8593 induced these effects in tissue from AF patients. SK channel inhibition did not alter any electrophysiological parameter in human interventricular septum tissue. CONCLUSIONS SK channels are present in human atria where they participate in repolarization. SK2 and SK3 were down-regulated and had reduced functional importance in chronic AF. As SK current was not found to contribute substantially to the ventricular AP, pharmacological inhibition of SK channels may be a putative atrial-selective target for future antiarrhythmic drug therapy.

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.

Pharmacologic inhibition of small-conductance calcium-activated potassium (SK) channels by NS8593 reveals atrial antiarrhythmic potential in horses

BACKGROUND Small-conductance calcium-activated potassium (SK) channels have been found to play an important role in atrial repolarization and atrial fibrillation (AF). OBJECTIVE The purpose of this study was to investigate the existence and functional role of SK channels in the equine heart. METHODS Cardiac biopsies were analyzed to investigate the expression level of the most prominent cardiac ion channels, with special focus on SK channels, in the equine heart. Subcellular distribution of SK isoform 2 (SK2) was assessed by immunohistochemistry and confocal microscopy. The electrophysiologic and anti-AF effects of the relative selective SK channel inhibitor NS8593 (5 mg/kg IV) were evaluated in anesthetized horses, focusing on the potential of NS8593 to terminate acute pacing-induced AF, drug-induced changes in atrial effective refractory period, AF duration and vulnerability, and ventricular depolarization and repolarization times. RESULTS Analysis revealed equivalent mRNA transcript levels of the 3 SK channel isoforms in atria compared to ventricles. Immunohistochemistry and confocal microscopy displayed a widespread distribution of SK2 in both atrial and ventricular cardiomyocytes. NS8593 terminated all induced AF episodes (duration ≥15 minutes), caused pronounced prolongation of atrial effective refractory period, and reduced AF duration and vulnerability. QRS duration and QTc interval were not affected by treatment. CONCLUSION SK channels are widely distributed in atrial and ventricular cardiomyocytes and contribute to atrial repolarization. Inhibition by NS8593 terminates pacing-induced AF of short duration and decreases AF duration and vulnerability without affecting ventricular conduction and repolarization. Thus, inhibition by NS8593 demonstrates clear atrial antiarrhythmic properties in healthy horses.

Cardiac Ion Channels and Mechanisms for Protection Against Atrial Fibrillation

Atrial fibrillation (AF) is recognised as the most common sustained cardiac arrhythmia in clinical practice. Ongoing drug development is aiming at obtaining atrial specific effects in order to prevent pro-arrhythmic, devastating ventricular effects. In principle, this is possible due to a different ion channel composition in the atria and ventricles. The present text will review the aetiology of arrhythmias with focus on AF and include a description of cardiac ion channels. Channels that constitute potentially atria-selective targets will be described in details. Specific focus is addressed to the recent discovery that Ca(2+)-activated small conductance K(+) channels (SK channels) are important for the repolarisation of atrial action potentials. Finally, an overview of current pharmacological treatment of AF is included.

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.

Pharmacologically induced long QT type 2 can be rescued by activation of IKs with benzodiazepine R-L3 in isolated guinea pig cardiomyocytes.

The ionic current responsible for terminating the action potential (AP), and thereby in part determining the AP duration (APD), is the potassium current (IK), consisting of primarily two components: a rapidly (IKr) and a slowly (IKs) activating delayed rectifier potassium current. The aim of this study was to evaluate potential antiarrhythmic effects of compound induced IKs activation using the benzodiazepine L-364,373 (R-L3). Ventricular myocytes from guinea pigs were isolated and whole-cell current clamping was performed at 35°C. It was found that 1 μM R-L3 significantly reduced the APD90 at pacing frequencies of 1, 2, and 4 Hz when compared to control (40 ± 6%, 22 ± 2%, and 32 ± 2%, respectively). The reduction of APD90 was accompanied by a reduced triangulation (given as APD30-90) when compared to control at all pacing frequencies (62 ± 7 ms vs. 41 ± 3 ms, 55 ± 5 ms vs. 35 ± 6 ms, and 45 ± 4 ms vs. 32 ± 2 ms, at 1 Hz, 2 Hz, and 4 Hz, respectively). The abbreviated APDs also resulted in a reduction in the relative refractory period, and no direct protection against pacing induced early after-depolarizations (EAD) could be observed. However, an increase in repolarizing capacity was seen with 1 μM R-L3, as more complete repolarization of the AP was achieved before EADs could be elicited. Finally, a functional demonstration of the repolarization reserve revealed that increased IKs can counteract a pharmacologically reduced IKr. In conclusion, pharmacological activation of IKs possesses both pro- and antiarrhythmic characters. The most prominent antiarrhythmic propensity is the ability for IKs activation to rescue a cellular model of long QT type 2.

Role of Calcium-activated Potassium Channels in Atrial Fibrillation Pathophysiology and Therapy

Abstract: Small-conductance Ca2+-activated potassium (SK) channels are relative newcomers within the field of cardiac electrophysiology. In recent years, an increased focus has been given to these channels because they might constitute a relatively atrial-selective target. This review will give a general introduction to SK channels followed by their proposed function in the heart under normal and pathophysiological conditions. It is revealed how antiarrhythmic effects can be obtained by SK channel inhibition in a number of species in situations of atrial fibrillation. On the contrary, the beneficial effects of SK channel inhibition in situations of heart failure are questionable and still needs investigation. The understanding of cardiac SK channels is rapidly increasing these years, and it is hoped that this will clarify whether SK channel inhibition has potential as a new anti–atrial fibrillation principle.