PI3K/mTOR inhibitor omipalisib prolongs cardiac repolarization along with a mild proarrhythmic outcome in the AV block dog model.

Background: The phosphoinositide 3-kinase (PI3K) signaling pathway is an interesting target in cancer treatment. The awareness of the proarrhythmic risk of PI3K inhibitors was raised because PI3K is also involved in regulating signaling toward cardiac ion channels. Canine cardiomyocytes treated with PI3K inhibitors show an increased action potential duration and reduced cardiac repolarizing currents. Now, the potential proarrhythmic effect of chronic treatment of PI3K/mTOR inhibitor GSK2126458 (omipalisib) was investigated in the atrioventricular (AV) block dog model. Methods: Purpose-bred Mongrel dogs received complete AV block by ablation of the bundle of His and their hearts were paced in the right ventricular apex at VDD-mode (RVA-VDD). In this way, sinus rhythm was maintained for 15 ± 1 days and thereby bradycardia-induced cardiac remodeling was prevented. Dogs received 1 mg/kg omipalisib once (n = 3) or twice (n = 10) a day via oral administration for 7 days. Under standardized conditions (anesthesia, bradycardia at 60 beats/min, and a dofetilide challenge), potential proarrhythmic effects of omipalisib were investigated. Results: Twice daily dosing of omipalisib increased accumulative plasma levels compared to once daily dosing accompanied with adverse events. Omipalisib prolonged the QT interval at baseline and more strongly after the dofetilide challenge (490 ± 37 to 607 ± 48 ms). The arrhythmic outcome after omipalisib resulted in single ectopic beats in 30% of dogs perpetuating in multiple ectopic beats and TdP arrhythmia in 20% of dogs. Isolated ventricular cardiomyocytes from omipalisib-treated dogs showed a diminished IKs current density. Conclusion: Chronic treatment of PI3K/mTOR inhibitor omipalisib prolonged the QT interval in a preclinical model under standardized proarrhythmic conditions. Furthermore, this study showed that electrical remodeling induced by omipalisib had a mild proarrhythmic outcome.

Deleterious acute and chronic effects of bradycardic right ventricular apex pacing: consequences for arrhythmic outcome.

In the chronic complete atrioventricular (AV) block dog (CAVB) model, both bradycardia and altered ventricular activation due to the uncontrolled idioventricular rhythm contribute to ventricular remodeling and the enhanced susceptibility to Torsade de Pointes (TdP) arrhythmias. We investigated the effect of permanent bradycardic right ventricular apex (RVA) pacing on mechanical and electrical remodeling and TdP. In 23 anesthetized dogs, serial experiments were performed at sinus rhythm (SR), acutely after AV block (AAVB) and 3 weeks of remodeling CAVB at a fixed pacing rate of 60/min. ECG, and left (LV) and right ventricular (RV) monophasic action potentials durations (MAPD) were recorded; activation time (AT) and activation recovery interval (ARI) were determined from ten distinct LV electrograms; interventricular mechanical delay (IVMD) and time-to-peak strain (TTP) of the LV septal and lateral wall (ΔTTP: lateral wall minus septal wall) were obtained echocardiographically. Dofetilide (25 µg/kg/5 min) was infused to study TdP inducibility. In baseline AAVB, in comparison to SR, RVA bradypacing acutely increased QT interval, LV, and RVMAPD. Echocardiographic IVMD and ΔTTP were initially increased, which was partially corrected after 3 weeks of RVA pacing (IVMD: 22 ± 13 vs. 42 ± 11 vs. 31 ± 6 ms; ΔTTP: -2 ± 47 vs. -114 ± 38 vs. -36 ± 22 ms). QT interval (362 ± 23 vs. 373 ± 29 ms), LVMAPD (245 ± 18 vs. 253 ± 22 ms), RVMAPD (226 ± 26 vs. 238 ± 31 ms), and mean LV-ARI (268 ± 5 vs. 267 ± 6 ms) were not significantly changed after 3 weeks of RVA pacing. During AAVB, dofetilide increased mean LV-ARI (381 ± 11 ms) with largest increases in the later activated basal areas (slope AT-ARI: +0.96). In contrast with acute RVA pacing, 3 week pacing increased TdP inducibility (0/13 vs. 11/21) and mean LV-ARI (484 ± 18 ms), while the slope of AT-ARI responded differently on dofetilide (-2.37), with larger APD increases in the early region. The latter was supported at the molecular level: reduced RNA expressions of three repolarization-related ion channel genes in early (KCNQ1, KCNH2, and KCNJ2) versus two in late regions (KNCQ1 and KCNJ2). In conclusion, bradycardic RVA pacing acutely induced LV intra- and interventricular mechanical dyssynchrony, which was partially reversed after 3 weeks of pacing (remodeling). The latter occurred without apparent baseline electrical effects. However, dofetilide clearly unmasked (region-specific) arrhythmic consequences of remodeling.

The electromechanical window is no better than QT prolongation to assess risk of Torsade de Pointes in the complete atrioventricular block model in dogs.

BACKGROUND AND PURPOSE: The electromechanical window (EMW), the interval between the end of the T-wave and the end of the left ventricular pressure (LVP) curve, has recently been proposed as a predictor of risk of Torsade de Pointes (TdP) in healthy animals, whereby a negative EMW (mechanical relaxation earlier than repolarization) after drug administration indicates an increased TdP risk. The aims of this study were to assess (i) the effect of the ventricular remodelling in the canine chronic, complete atrioventricular block (CAVB) model on EMW; (ii) the effect of the I(Kr) -blocker dofetilide on EMW; and (iii) the correlation of EMW with TdP inducibility. EXPERIMENTAL APPROACH: Our 11 year database of experiments of CAVB in dogs under general anaesthesia was reviewed and experiments included if ECG and LVP were recorded simultaneously at spontaneous rhythm. In total, 89 experiments in 44 dogs were appropriate and were analysed. KEY RESULTS: During normally conducted sinus rhythm or acute atrioventricular block, EMW was positive. During CAVB, EMW was decreased to negative values. Dofetilide further reduced EMW before inducing repetitive TdP in 82% of the experiments. However, subclassification into inducible and non-inducible dogs revealed no difference in EMW. Analysis of the components of EMW revealed that the observed changes in EMW were solely caused by QT prolongation. CONCLUSIONS AND IMPLICATIONS: In the canine CAVB model, ventricular remodelling and I(Kr) block by dofetilide are associated with negative EMW values, but this reflects QT prolongation, and implies that the EMW lacks specificity to predict dofetilide-induced TdP.

Structure-activity relationships of pentamidine-affected ion channel trafficking and dofetilide mediated rescue.

BACKGROUND AND PURPOSE: Drug interference with normal hERG protein trafficking substantially reduces the channel density in the plasma membrane and thereby poses an arrhythmic threat. The chemical substructures important for hERG trafficking inhibition were investigated using pentamidine as a model drug. Furthermore, the relationship between acute ion channel block and correction of trafficking by dofetilide was studied. EXPERIMENTAL APPROACH: hERG and K(IR)2.1 trafficking in HEK293 cells was evaluated by Western blot and immunofluorescence microscopy after treatment with pentamidine and six pentamidine analogues, and correction with dofetilide and four dofetilide analogues that displayed different abilities to inhibit IKr . Molecular dynamics simulations were used to address mode, number and type of interactions between hERG and dofetilide analogues. KEY RESULTS: Structural modifications of pentamidine differentially affected plasma membrane levels of hERG and K(IR)2.1. Modification of the phenyl ring or substituents directly attached to it had the largest effect, affirming the importance of these chemical residues in ion channel binding. PA-4 had the mildest effects on both ion channels. Dofetilide corrected pentamidine-induced hERG, but not K(IR)2.1 trafficking defects. Dofetilide analogues that displayed high channel affinity, mediated by pi-pi stacks and hydrophobic interactions, also restored hERG protein levels, whereas analogues with low affinity were ineffective. CONCLUSIONS AND IMPLICATIONS: Drug-induced trafficking defects can be minimized if certain chemical features are avoided or 'synthesized out'; this could influence the design and development of future drugs. Further analysis of such features in hERG trafficking correctors may facilitate the design of a non-blocking corrector for trafficking defective hERG proteins in both congenital and acquired LQTS.