The Effect of a Synthetic Estrogen, Ethinylestradiol, on the hERG Block by E-4031

Inhibition of K+-conductance through the human ether-a-go-go related gene (hERG) channel leads to QT prolongation and is associated with cardiac arrhythmias. We previously reported that physiological concentrations of some estrogens partially suppress the hERG channel currents by interacting with the S6 residue F656 and increase the sensitivity of hERG blockade by E-4031. Although these studies suggested that clinically used synthetic estrogens with similar structures have the marked potential to alter hERG functions, the hERG interactions with synthetic estrogens have not been assessed. We therefore examined whether ethinylestradiol (EE2), a synthetic estrogen used in oral contraceptives, affects hERG function and blockade by drugs. Supratherapeutic concentrations of EE2 did not alter amplitudes or kinetics of the hERG currents elicited by train pulses at 20 mV (0.1 Hz). On the other hand, EE2 at therapeutic concentrations reduced the degree of hERG current suppression by E-4031. The administration of EE2 followed by E-4031 blockade reversed the current suppression, suggesting that the interaction of EE2 and E-4031 alters hERG at the drug-binding site. The effects of EE2 on hERG blockade raised the possibility that other estrogens, including synthetic estrogens, can alter hERG blockade by drugs that cause QT prolongation and ventricular arrhythmias.

Electrophysiological characterization of the hERG R56Q LQTS variant and targeted rescue by the activator RPR260243

Human Ether-à-go-go (hERG) channels contribute to cardiac repolarization, and inherited variants or drug block are associated with long QT syndrome type 2 (LQTS2) and arrhythmia. Therefore, hERG activator compounds present a therapeutic opportunity for targeted treatment of LQTS. However, a limiting concern is over-activation of hERG resurgent current during the action potential and abbreviated repolarization. Activators that slow deactivation gating (type I), such as RPR260243, may enhance repolarizing hERG current during the refractory period, thus ameliorating arrhythmogenicity with reduced early repolarization risk. Here, we show that, at physiological temperature, RPR260243 enhances hERG channel repolarizing currents conducted in the refractory period in response to premature depolarizations. This occurs with little effect on the resurgent hERG current during the action potential. The effects of RPR260243 were particularly evident in LQTS2-associated R56Q mutant channels, whereby RPR260243 restored WT-like repolarizing drive in the early refractory period and diastolic interval, combating attenuated protective currents. In silico kinetic modeling of channel gating predicted little effect of the R56Q mutation on hERG current conducted during the action potential and a reduced repolarizing protection against afterdepolarizations in the refractory period and diastolic interval, particularly at higher pacing rates. These simulations predicted partial rescue from the arrhythmic effects of R56Q by RPR260243 without risk of early repolarization. Our findings demonstrate that the pathogenicity of some hERG variants may result from reduced repolarizing protection during the refractory period and diastolic interval with limited effect on action potential duration, and that the hERG channel activator RPR260243 may provide targeted antiarrhythmic potential in these cases.

Proton Pump Inhibitors Directly Block hERG-potassium Channel and Independently Increase the Risk of QTc Prolongation in a Large Cohort of US Veterans

Background - Worldwide, there are millions of chronic proton pump inhibitors (PPIs) users, often without a compelling indication. Evidence indicates that PPI treatment can increase mortality, in part due to a higher risk of QTc-related malignant arrhythmias. Drug-induced hypomagnesemia is currently believed to be the underlying mechanism, and therefore serum magnesium monitoring is recommended to minimize arrhythmic risk. However, recent data suggest that PPIs might also directly interfere with cardiac electrophysiology. To test this hypothesis, a translational study was performed using a combination of electrophysiology, molecular dynamics simulations, and population data. Methods - First, the effect of different PPIs on the ether-a-go-go -related-gene potassium channel (hERG) current was evaluated in HEK293-cells expressing hERG. Then, free energy calculations were performed to investigate the binding of these drugs to hERG. Finally, the impact of PPIs on the risk of QTc prolongation was assessed in a retrospective observational cohort of 3867 US Veterans, including 1289 PPI-treated subjects. Results - Clinically-relevant concentrations of different PPIs induced a significant inhibition of the hERG-current in-vitro , pantoprazole and lansoprazole being the most potent compounds. Atomic simulations demonstrated that such a blocking class-effect is likely due to direct PPIs binding to hERG-channel pore cavity. Accordingly, in a US Veterans cohort, PPI treatment was independently associated with a ~20-40% increased risk of QTc prolongation, also regardless of hypomagnesemia. Moreover, a synergistic interaction between PPIs and most of the traditional QT-prolonging risk factors was demonstrated. Conclusions - Altogether, this study provides, for the first time, strong evidence that PPIs can per se promote QTc prolongation, by directly inhibiting hERG function. A careful evaluation of the benefit/risk ratio is recommended whenever PPIs are administered in subjects with other QT-prolonging risk factors, even in the absence of hypomagnesemia.

Abstract 17074: Methadone Potently Blocks Cardiac IK1 Leading to Membrane Instability

Introduction: Methadone is the second most frequently reported cause of drug-induced cardiac arrest in pharmacovigilance databases, yet the mechanism of its pro-arrhythmia is unclear. Methadone-induced QTU wave prolongation has been repeatedly observed and attributed to inhibition of the delayed rectifier hERG current, but QTU fusion suggests the inwardly rectifying K + current (IK1) might also be affected by methadone. Hypothesis: Methadone pro-arrhythmia is associated with potent block of the IK1 current responsible for rapid terminal repolarization of the cardiac action potential (AP). Methods: Human Kir2.2, encoding the IK1 current, was transiently expressed in COS cells. hERG1a was stably expressed in CHO cells. Cardiac myocytes from swine were obtained by ventricular enzymatic dissociation. Ionic current and APs were measured using patch-clamp methods. Methadone HCl (R+S racemates) was dissolved in Tyrode solution. Results: Methadone suppressed IK1 current with an IC 50 of 1.47 uM (Fig 1A). Methadone also suppressed outward IK1 (-60 mV) measured in swine myocytes (Ba 2+ -sensitive current) with an IC 50 of 1.52 μM. Methadone suppressed hERG currents with an IC 50 of 2.1 μM. APs measured in swine myocytes exhibited significant prolongation (13 ± 4 % increase of APD 90 , p<0.029, n=7) as well as slowing of the rate of terminal repolarization (a specific marker of IK1 blockade) in the presence of 1 μM methadone (Fig. 1B). Fluctuations of diastolic voltage increased by 30 ± 12 and 151 ± 27 % (n=3; p<0.04) in 0.1 and 1 μM methadone, respectively, consistent with a reduction in membrane stability. Conclusions: Methadone is an equipotent blocker of IK1 and hERG. The effect of IK1 block coupled with modest hERG block has a synergistic effect on terminal repolarization that may partially explain the pro-arrhythmic impact of methadone. Moreover, this observation may be generalized to other drugs where unsuspected IK1 blockade may contribute to pro-arrhythmia and torsade de pointes.

The electrophysiological effect of cannabidiol on hERG current and in guinea-pig and rabbit cardiac preparations

Cannabis use is associated with cardiovascular adverse effects ranging from arrhythmias to sudden cardiac death. The exact mechanism of action behind these activities is unknown. The aim of our work was to study the effect of cannabidiol (CBD), tetrahydrocannabinol and 11-nor-9-carboxy-tetrahydrocannabinol on cellular cardiac electrophysiological properties including ECG parameters, action potentials, hERG and IKr ion channels in HEK cell line and in rabbit and guinea pig cardiac preparations. CBD increased action potential duration in rabbit and guinea pig right ventricular papillary muscle at lower concentrations (1 µM, 2.5 µM and 5 µM) but did not significantly change it at 10 µM. CBD at high concentration (10 µM) decreased inward late sodium and L-type calcium currents as well. CBD inhibited hERG potassium channels with an IC50 value of 2.07 µM at room temperature and delayed rectifier potassium current with 6.5 µM at 37 °C, respectively. The frequency corrected QT interval (QTc) was significantly lengthened in anaesthetized guinea pig without significantly changing other ECG parameters. Although the IC50 value of CBD was higher than literary Cmax values after CBD smoking and oral intake, our results raise the possibility that hERG and potassium channel inhibition might have a role in the possible proarrhythmic adverse effects of cannabinoids in situations where metabolism of CBD impaired and/or the repolarization reserve is weakened.

Probucol-induced hERG Channel Reduction can be Rescued by Matrine and Oxymatrinein vitro

Background: The human ether-a-go-go-related gene (hERG) potassium channel is the rapidly activating component of cardiac delayed rectifier potassium current (IKr), which is a crucial determinant of cardiac repolarization. The reduction of hERG current is commonly believed to cause Long QT Syndrome (LQTs). Probucol, a cholesterol-lowering drug, induces LQTs by inhibiting the expression of the hERG channel. Unfortunately, there is currently no effective therapeutic method to rescue probucol-induced LQTs. Methods: Patch-clamp recording techniques were used to detect the action potential duration (APD) and current of hERG. Western blot was performed to measure the expression levels of proteins. Results: In this study, we demonstrated that 1 μM matrine and oxymatrine could rescue the hERG current and hERG surface expression inhibited by probucol. In addition, matrine and oxymatrine significantly shortened the prolonged action potential duration induced by probucol in neonatal cardiac myocytes. We proposed a novel mechanism underlying the probucol induced decrease in the expression of transcription factor Specificity protein 1 (Sp1), which is an established transactivator of the hERG gene. We also demonstrated that matrine and oxymatrine were able to upregulate Sp1 expression which may be one of the possible mechanisms by which matrine and oxymatrine rescued probucol-induced hERG channel deficiency. Conclusion: Our current results demonstrate that matrine and oxymatrine could rescue probucol-induced hERG deficiency in vitro, which may lead to potentially effective therapeutic drugs for treating acquired LQT2 by probucol in the future.

Development, calibration, and validation of a novel human ventricular myocyte model in health, disease, and drug block

Human-based modelling and simulations are becoming ubiquitous in biomedical science due to their ability to augment experimental and clinical investigations. Cardiac electrophysiology is one of the most advanced areas, with cardiac modelling and simulation being considered for virtual testing of pharmacological therapies and medical devices. Current models present inconsistencies with experimental data, which limit further progress. In this study, we present the design, development, calibration and independent validation of a human-based ventricular model (ToR-ORd) for simulations of electrophysiology and excitation-contraction coupling, from ionic to whole-organ dynamics, including the electrocardiogram. Validation based on substantial multiscale simulations supports the credibility of the ToR-ORd model under healthy and key disease conditions, as well as drug blockade. In addition, the process uncovers new theoretical insights into the biophysical properties of the L-type calcium current, which are critical for sodium and calcium dynamics. These insights enable the reformulation of L-type calcium current, as well as replacement of the hERG current model.

Identification of a proton sensor that regulates conductance and open time of single hERG channels

The hERG potassium channel influences ventricular action potential duration. Extracellular acidosis occurs in pathological states including cardiac ischaemia. It reduces the amplitude of hERG current and speeds up deactivation, which can alter cardiac excitability. This study aimed to identify the site of action by which extracellular protons regulate the amplitude of macroscopic hERG current. Recordings of macroscopic and single hERG1a and 1b channel activity, mutagenesis, and the recent cryoEM structure for hERG were employed. Single hERG1a and 1b channels displayed open times that decreased with membrane depolarization, suggestive of a blocking mechanism that senses approximately 20% of the membrane electric field. This mechanism was sensitive to pH; extracellular acidosis reduced both hERG1a and1b channel open time and conductance. The effects of acidosis on macroscopic current amplitude and deactivation displayed different sensitivities to protons. Point mutation of a pair of residues (E575/H578) in the pore turret abolished the acidosis-induced decrease of current amplitude, without affecting the change in current deactivation. In single hERG1a channel recordings, the conductance of the double-mutant channel was unaffected by extracellular acidosis. These findings identify residues in the outer turret of the hERG channel that act as a proton sensor to regulate open time and channel conductance.