Atrial effects of the novel K(+)-channel-blocker AVE0118 in anesthetized pigs.

OBJECTIVES: AVE0118 is a novel blocker of the K(+) channels K(v)1.5 and K(v)4.3 which are the molecular basis for the human cardiac ultrarapid delayed rectifier potassium current (I(Kur)) and the transient outward current (I(to)). The objective of this study was to investigate the effect of AVE0118 on atrial refractoriness (ERP), left atrial vulnerability (LAV) and on left atrial monophasic action potentials (MAP) in pentobarbital anesthetized pigs in comparison to the selective I(Kr) blocker dofetilide in order to assess the therapeutic potential of the novel K(+) channel blocker for atrial fibrillation. METHODS: Atrial ERP was determined with the S1-S2-stimulus method in the free walls of left and right atrium at 240, 300 and 400 ms basic cycle length (BCL). The inducibility of mostly nonsustained atrial tachyarrhythmias by the premature S2 extrastimulus, which is very high in the left pig atrium and referred to as LAV, was evaluated before and after drugs. Left atrial epicardial MAP was recorded to study the influence of the potassium channel blockers on the time course of repolarization. Left ventricular epicardial MAP, ERP and QT interval were measured to investigate a possible effect of AVE0118 on ventricular repolarization. RESULTS: ERPs determined at 240, 300 and 400 ms BCL were significantly shorter in the left vs. right atrium (99+/-3, 106+/-4 and 113+/-3 ms vs. 133+/-4 ms, 142+/-4 and 149+/-5, respectively; p<0.001; n=21). AVE0118 administered i.v. dose-dependently prolonged the atrial ERP independent from rate and inhibited LAV (100% at 0.5 and 1 mg/kg) while having no effect at all on the corrected QT (QTc) interval. At 1 mg/kg (n=5) AVE0118 prolonged left vs. right atrial ERP by 49.6+/-4.1 ms vs. 37.7+/-9.7 ms (means+/-SEM of changes at 240, 300, and 400 ms BCL), respectively, corresponding to a relative increase of 53.2+/-6.2% vs. 27.6+/-6.8% (p<0.05 for percent increase of left vs. right atrial ERP). In a separate group of pigs (n=5) AVE0118 had no effect on left ventricular ERP at 333, 400 and 500 ms BCL and no effect on MAP duration and QT at 600 ms BCL. After 1 mg/kg of AVE0118 the atrial MAP was significantly prolonged already at 10% repolarization (P<0.05; n=7) reaching the maximum at 40% repolarization. In contrast to AVE0118 the effect of dofetilide (10 microg/kg) on atrial MAP started to become significant only at 60% repolarization (n=6) with a maximum increase at 90%. Dofetilide, which prolonged the QTc interval by 16.9% (P<0.001), had a significantly stronger effect on right (34.7+/-5 ms) vs. left atrial ERP (23.5+/-7 ms) at 300 ms BCL, respectively, but did not significantly inhibit LAV (14%; n=6). CONCLUSION: The novel K(+) channel blocker AVE0118 prolonged atrial ERP and showed strong atrial antiarrhythmic efficacy with no apparent effect on ventricular repolarization in pigs in vivo.

Identification, synthesis, and activity of novel blockers of the voltage-gated potassium channel Kv1.5.

The voltage-gated potassium channel Kv1.5 is regarded as a promising target for the development of new atrial selective drugs with fewer side effects. In the present study the discovery of ortho,ortho-disubstituted bisaryl compounds as blockers of the Kv1.5 channel is presented. Several compounds of this new class were synthesized and screened for their ability to block Kv1.5 channels expressed in Xenopus oocytes. The observed structure-activity relationship (SAR) is described by a pharmacophore model that consists of three hydrophobic centers in a triangular arrangement. The hydrophobic centers are matched by a phenyl or pyridyl ring of the bisaryl core and both ends of the side chains. The most potent compounds (e.g., 17c and 17o) inhibited the Kv1.5 channel with sub-micromolar half-blocking concentrations and displayed 3-fold selectivity over Kv1.3 and no significant effect on the HERG channel and sodium currents. In addition, compounds 17c and 17m have already shown antiarrhythmic effects in a pig model.

Electrophysiological and antiarrhythmic effects of the novel I(Kur) channel blockers, S9947 and S20951, on left vs. right pig atrium in vivo in comparison with the I(Kr) blockers dofetilide, azimilide, d,l-sotalol and ibutilide.

Inhibition of the cardiac Kv1.5 channel, the molecular base for the human cardiac ultrarapid delayed rectifier potassium current (I(Kur)), is considered a new promising atrial selective antiarrhythmic concept since this channel is presumed to contribute to atrial but not ventricular repolarization in the human heart. In a previous study in pigs we found clear baseline differences in refractoriness between left and right atrium with shorter effective refractory periods (ERPs) of the left atrium associated with a high left atrial vulnerability for tachyarrhythmias. In this newly established model we compared atrial and ventricular effects of two novel I(Kur) blockers, S9947 and S20951, with the I(Kr) blockers dofetilide, azimilide, ibutilide and d,l-sotalol. In pentobarbital anesthetized pigs (n=45) we determined ERPs in the free walls of both atria with the S1-S2-stimulus method at three basic cycle lengths (BCL 240/300/400 ms) and QTc-intervals. The incidence of atrial tachyarrhythmias triggered by the S2-extrastimulus of the left atrium was evaluated (referred to as left atrial vulnerability). In contrast to I(Kr) blockade, I(Kur) blockade had no effect on the QT-interval, but prolonged the atrial ERP. The I(Kur) blockers were significantly stronger on left atrial ERP, I(Kr) blockers on right atrial ERP (P<0.05 for all compounds tested). At 240 ms BCL the I(Kur) blocker S20951, 3 mg/kg, prolonged left vs. right atrial ERP by 28+/-5 ms vs. 12+/-3 ms and S9947, 3 mg/kg, by 45+/-7 ms vs. 19+/-6 ms. By contrast the effect of dofetilide, 10 microg/kg, was stronger on the right than left atrium (47+/-6 ms vs. 25+/-2 ms), a profile also found with azimilide (5 mg/kg, 43+/-3 ms vs. 17+/-3 ms), ibutilide (15 microg/kg, 70+/-10 ms vs. 29+/-4 ms) and d,l-sotalol (1.5 mg/kg, 57+/-6 ms vs. 36+/-4 ms). The I(Kur) blockers, S20951and S9947, significantly decreased left atrial vulnerability (-82% and -100%, respectively, P<0.01) in contrast to the selective I(Kr) blocker dofetilide (-14%; n.s.). In conclusion, I(Kur) and I(Kr) blockers showed substantial differences in their atrial and ventricular actions in pigs. I(Kr) blockers were stronger on right atrial ERP, I(Kur) blockers on left atrial ERP, suggesting interatrial differences in the expression of potassium channels. In contrast to selective I(Kr) blockade, I(Kur) blockade inhibited left atrial vulnerability and had no effect on the QT-interval. Thus, blockade of I(Kur) seems to be a promising atrial selective antiarrhythmic concept.

Effects of the chromanol HMR 1556 on potassium currents in atrial myocytes.

PURPOSE: The chromanol HMR 1556 is a potent blocker of KvLQT1/minK potassium channels expressed in Xenopus oocytes. The compound is therefore a new class III antiarrhythmic drug with a distinct mechanism of action. However, the effect of HMR 1556 on atrial ion channels and the selectivity of block in the human heart has not been investigated. We tested the effects of HMR 1556 on repolarizing potassium currents in human and guinea pig atrial myocytes. METHODS AND RESULTS: Single atrial myocytes were isolated by enzymatic dissociation. Atrial potassium currents (I(Ks), I(Kr), in guinea pig, I(to), I(Kur), I(K1) in humans) were recorded at 36 degrees C in the whole cell mode of the patch clamp technique. HMR 1556 produced a concentration-dependent and reversible block of I(Ks) with a half maximal concentration (EC(50)) of 6.8 nmol/l. 10 micromol/l HMR 1556 almost completely inhibited I(Ks) (97.2+/-3.2%, n=6). Steady-state activation as well as kinetic properties of the current were not altered by HMR 1556. I(Kr) currents were not affected up to concentrations of 10 micromol/l. HMR 1556 did not inhibit other potassium currents in human atrium: I(to), I(Kur) and the classical inward rectifier potassium current I(K1) were not significantly affected up to concentrations that completely blocked I(Ks) (10 micromol/l). CONCLUSIONS: HMR 1556 is a highly-potent blocker of I(Ks) channels without exerting effects on other potassium currents involved in atrial repolarization. Given the potential advantages of I(Ks) vs. I(Kr) blockade, the drug's new mechanism of action warrants further investigation to clarify its role as an antiarrhythmic agent.

Blockers of the Kv1.5 channel for the treatment of atrial arrhythmias.

Atrial arrhythmias are a common problem in cardiological practice. Despite the availability of several antiarrhythmic drugs, there is a medical need for safer and more efficient antiarrhythmic treatment. Compounds that act atrial selectively without prolonging the QTc-time and without negative inotropy to terminate and/or prevent atrial arrhythmias would be of high interest. In this context, the voltage-gated potassium channel Kv1.5 is regarded as a promising target to achieve atrial selectivity, which in turn would be associated with fewer side effects than classical antiarrhythmics. This review summarizes patents and other publications on compounds which show this novel mode of action. The chemistry, selectivity and structure-activity data disclosed in the literature are discussed in light of recent work demonstrating the antiarrhythmic efficacy of Kv1.5 blockers in vivo. Several studies in pig, dog or goat models have confirmed their proposed atrial selective antiarrhythmic effect in vivo. Most of the more intensively characterized Kv1.5 blockers have turned out not to be selective but also block other ion channels. Based on the currently available data it seems that additional inhibition of Kv4.3 and KACh is beneficial for the desired antiarrhythmic effect or at least does not hamper the atrial selectivity of a Kv1.5 blocker. Significant block of IK1, HERG or sodium channels, however, clearly leads to loss of atrial selectivity and increases the risk of lethal ventricular proarrhythmia.

In vitro and in vivo effects of the atrial selective antiarrhythmic compound AVE1231.

The novel compound AVE1231 was investigated in order to elucidate its potential against atrial fibrillation. In CHO cells, the current generated by hKv1.5 or hKv4.3 + KChIP2.2b channels was blocked with IC50 values of 3.6 microM and 5.9 microM, respectively. In pig left atrial myocytes, a voltage-dependent outward current was blocked with an IC50 of 1.1 microM, mainly by accelerating the time constant of decay. Carbachol-activated IKACh was blocked by AVE1231 with an IC50 of 8.4 microM. Other ionic currents, like the IKr, IKs, IKATP, ICa, and INa were only mildly affected by 10 microM AVE1231. In guinea pig papillary muscle the APD90 and the upstroke velocity were not significantly altered by 30 microM AVE1231. In anesthetized pigs, oral doses of 0.3, 1, and 3 mg/kg AVE1231 caused a dose-dependent increase in left atrial refractoriness (LAERP), associated by inhibition of left atrial vulnerability to arrhythmia. There were no effects on the ECG intervals, ventricular monophasic action potentials, or ventricular refractory periods at 3 mg/kg AVE1231 applied intravenously. In conscious goats, both AVE1231 (3 mg/kg/h iv) and dofetilide (10 microg/kg/h iv) significantly prolonged LAERP. After 72 hours of tachypacing, when LAERP was shortened significantly (electrical remodelling), the prolongation of LAERP induced by AVE1231 was even more pronounced than in sinus rhythm. In contrast, the effect of dofetilide was strongly decreased. The present data demonstrate that AVE1231 blocks early atrial K channels and prolongs atrial refractoriness with no effects on ECG intervals and ventricular repolarisation, suggesting that it is suited for the prevention of atrial fibrillation in patients.

The discovery of Kv1.5 blockers as a case study for the application of virtual screening approaches.

Different virtual screening techniques are available as alternatives to high throughput screening. These different techniques have been rarely used together on the same target. We had the opportunity to do so in order to discover novel blockers of the voltage-dependent potassium channel Kv1.5, a potential target for the treatment of atrial fibrillation. Our corporate database was searched, using a protein-based pharmacophore, derived from a homology model, as query. As a result, 244 molecules were screened in vitro, 19 of them (7.8%) were found to be active. Five of them, belonging to five different chemical classes, exhibited IC50 values under 10 microM. The performance of this structure-based virtual screening protocol has been compared with those of similarity and ligand-based pharmacophore searches. The analysis of the results supports the conventional wisdom of using as many virtual screening techniques as possible in order to maximize the chance of finding as many chemotypes as possible.

Atrial-selective antiarrhythmic actions of novel Ikur vs. Ikr, Iks, and IKAch class Ic drugs and beta blockers in pigs.

BACKGROUND: The Kv1.5 channel, underlying IKur, is supposed to be atrial selective in pigs and humans. We investigated the effects of different potassium channel blockers, i.e. the IKur blockers AVE 0118, S9947 and S20951, with amiodarone (AM), dofetilide (DO), azimilide (AZ), ibutilide (IB), the IKs blocker HMR 1556, atropine (ATR), flecainide (FL), propafenone (PR), d,l-sotalol (SO), atenolol (ATE), and esmolol (ES), on the left and right atrial and ventricular refractoriness and left atrial vulnerability (LAV) in vivo in pigs. MATERIAL/METHODS: In pentobarbital-anesthetized pigs (n=81), atrial and ventricular effective refractory periods (ERPs) were measured with the S1-S2-extrastimulus-method and QTc time from electrocardiograms. LAV was assessed after S2-extrastimulus to the left atrium. RESULTS: All IKur blockers prolonged left stronger than right atrial ERP and did not change QTc. All IKr blockers predominantly prolonged the right vs. left atria. AM prolonged both atria equally, and ATR the left only. Pure beta blockers acted predominantly on the left atrium, as did FL and PR, while d,l-sotalol acted predominantly on the right. AVE 0118, S9947, S20951, ibutilide, and d,l-sotalol significantly decreased LAV (-100%, -100%, -82%, -53%, -42%; p<0.05), in contrast to all other drugs. CONCLUSIONS: The IKur blockers exhibited stronger effects on the left atrium, which itself has shorter refractoriness, but strikingly with no effect on ventricular repolarization, while IKr blockers, IKs blockers, and d,l-sotalol exerted predominantly right atrial effects and known ventricular effects. IKur blockers inhibited atrial tachyarrhythmias stronger than all available drugs. Therefore, IKur blockers seem to be promising new atrial-selective antiarrhythmic drugs.

Pharmacophore-based search, synthesis, and biological evaluation of anthranilic amides as novel blockers of the Kv1.5 channel.

The search for novel, potent Kv1.5 blockers based on an anthranilic amide scaffold employing a pharmacophore-based virtual screening approach is described. The synthesis and structure-activity relationships (SAR) with respect to inhibition of the Kv1.5 channel are discussed. The most potent compounds display sub-micromolar inhibition of Kv1.5 and no significant effect on the HERG channel. In addition, good oral bioavailability is demonstrated for compound 3i in rats.