Aziza El Harchi

The hERG potassium channel and hERG screening for drug-induced torsades de pointes.

Drug-induced torsades de pointes (TdP) arrhythmia is a major safety concern in the process of drug design and development. The incidence of TdP tends to be low, so early pre-clinical screens rely on surrogate markers of TdP to highlight potential problems with new drugs. hERG (human ether-à-go-go-related gene, alternative nomenclature KCNH2) is responsible for channels mediating the rapid delayed rectifier K+ current (IKr) which plays an important role in ventricular repolarization. Pharmacological inhibition of native IKr and of recombinant hERG channels is a shared feature of diverse drugs associated with TdP. In vitro hERG assays therefore form a key element of an integrated assessment of TdP liability, with patch-clamp electrophysiology offering a gold standard. However, whilst clearly necessary, hERG assays cannot be assumed automatically to provide sufficient information, when considered in isolation, to differentiate safe from dangerous drugs. Other relevant factors include therapeutic plasma concentration, drug metabolism and active metabolites, severity of target condition and drug effects on other cardiac ion channels that may mitigate or exacerbate effects of hERG blockade. Increased understanding of the nature of drug-hERG channel interactions may ultimately help eliminate potential hERG blockade early in the design and development process. Currently, for promising drug candidates integration of data from hERG assays with information from other pre-clinical safety screens remains essential.

IKs response to protein kinase A-dependent KCNQ1 phosphorylation requires direct interaction with microtubules

AIMSnKCNQ1 (alias KvLQT1 or Kv7.1) and KCNE1 (alias IsK or minK) co-assemble to form the voltage-activated K(+) channel responsible for I(Ks)-a major repolarizing current in the human heart-and their dysfunction promotes cardiac arrhythmias. The channel is a component of larger macromolecular complexes containing known and undefined regulatory proteins. Thus, identification of proteins that modulate its biosynthesis, localization, activity, and/or degradation is of great interest from both a physiological and pathological point of view.nnnMETHODS AND RESULTSnUsing a yeast two-hybrid screening, we detected a direct interaction between beta-tubulin and the KCNQ1 N-terminus. The interaction was confirmed by co-immunoprecipitation of beta-tubulin and KCNQ1 in transfected COS-7 cells and in guinea pig cardiomyocytes. Using immunocytochemistry, we also found that they co-localized in cardiomyocytes. We tested the effects of microtubule-disrupting and -stabilizing agents (colchicine and taxol, respectively) on the KCNQ1-KCNE1 channel activity in COS-7 cells by means of the permeabilized-patch configuration of the patch-clamp technique. None of these agents altered I(Ks). In addition, colchicine did not modify the current response to osmotic challenge. On the other hand, the I(Ks) response to protein kinase A (PKA)-mediated stimulation depended on microtubule polymerization in COS-7 cells and in cardiomyocytes. Strikingly, KCNQ1 channel and Yotiao phosphorylation by PKA-detected by phospho-specific antibodies-was maintained, as was the association of the two partners.nnnCONCLUSIONnWe propose that the KCNQ1-KCNE1 channel directly interacts with microtubules and that this interaction plays a major role in coupling PKA-dependent phosphorylation of KCNQ1 with I(Ks) activation.

Long-Term Amiodarone Administration Remodels Expression of Ion Channel Transcripts in the Mouse Heart

Background—The basis for the unique effectiveness of long-term amiodarone treatment on cardiac arrhythmias is incompletely understood. The present study investigated the pharmacogenomic profile of amiodarone on genes encoding ion-channel subunits. Methods and Results—Adult male mice were treated for 6 weeks with vehicle or oral amiodarone at 30, 90, or 180 mg · kg−1 · d−1. Plasma and myocardial levels of amiodarone and N-desethylamiodarone increased dose-dependently, reaching therapeutic ranges observed in human. Plasma triiodothyronine levels decreased, whereas reverse triiodothyronine levels increased in amiodarone-treated animals. In ECG recordings, amiodarone dose-dependently prolonged the RR, PR, QRS, and corrected QT intervals. Specific microarrays containing probes for the complete ion-channel repertoire (IonChips) and real-time reverse transcription–polymerase chain reaction experiments demonstrated that amiodarone induced a dose-dependent remodeling in multiple ion-channel subunits. Genes encoding Na+ (SCN4A, SCN5A, SCN1B), connexin (GJA1), Ca2+ (CaCNA1C), and K+ channels (KCNA5, KCNB1, KCND2) were downregulated. In patch-clamp experiments, lower expression of K+ and Na+ channel genes was associated with decreased Ito,f, IK,slow, and INa currents. Inversely, other K+ channel &agr;- and &bgr;-subunits, such as KCNA4, KCNK1, KCNAB1, and KCNE3, were upregulated. Conclusions—Long-term amiodarone treatment induces a dose-dependent remodeling of ion-channel expression that is correlated with the cardiac electrophysiologic effects of the drug. This profile cannot be attributed solely to the amiodarone-induced cardiac hypothyroidism syndrome. Thus, in addition to the direct effect of the drug on membrane proteins, part of the therapeutic action of long-term amiodarone treatment is likely related to its effect on ion-channel transcripts.

Proarrhythmia in KCNJ2-linked short QT syndrome: insights from modelling

AIMSnOne form of the short QT syndrome (SQT3) has been linked to the D172N gain-in-function mutation to Kir2.1, which preferentially increases outward current through channels responsible for inward rectifier K(+) current (I(K1)). This study investigated mechanisms by which the Kir2.1 D172N mutation facilitates and perpetuates ventricular arrhythmias.nnnMETHODS AND RESULTSnThe ten Tusscher et al. model for human ventricular action potentials (APs) was modified to incorporate changes to I(K1) based on experimentally observed changes to Kir2.1 function: both heterozygous (WT-D172N) and homozygous (D172N) mutant scenarios were studied. Cell models were incorporated into heterogeneous one-dimensional (1D), 2D tissue, and 3D models to compute the restitution curves of AP duration (APD-R), effective refractory period (ERP-R), and conduction velocity (CV). Temporal and spatial vulnerability of ventricular tissue to re-entry was measured and dynamic behaviour of re-entrant excitation waves (lifespan and dominant frequency) in 2D and 3D models of the human ventricle was characterized. D172N mutant I(K1) led to abbreviated APD and ERP, as well as steeper APD-R and ERP-R curves. It reduced tissue excitability at low excitation rates but increased it at high rates. It increased tissue temporal vulnerability for initiating re-entry, but reduced the minimal substrate size necessary to sustain re-entry. SQT3 mutant I(K1) also stabilized and accelerated re-entrant excitation waves, leading to sustained rapid re-entry.nnnCONCLUSIONnIncreased I(K1) due to the Kir2.1 D172N mutation increases arrhythmia risk due to increased tissue vulnerability, shortened ERP, and altered excitability, which in combination facilitate initiation and maintenance of re-entrant circuits.

hERG potassium channel blockade by the HCN channel inhibitor bradycardic agent ivabradine.

Background Ivabradine is a specific bradycardic agent used in coronary artery disease and heart failure, lowering heart rate through inhibition of sinoatrial nodal HCN‐channels. This study investigated the propensity of ivabradine to interact with KCNH2‐encoded human Ether‐à‐go‐go–Related Gene (hERG) potassium channels, which strongly influence ventricular repolarization and susceptibility to torsades de pointes arrhythmia. Methods and Results Patch clamp recordings of hERG current (IhERG) were made from hERG expressing cells at 37°C. IhERG was inhibited with an IC50 of 2.07 μmol/L for the hERG 1a isoform and 3.31 μmol/L for coexpressed hERG 1a/1b. The voltage and time‐dependent characteristics of IhERG block were consistent with preferential gated‐state‐dependent channel block. Inhibition was partially attenuated by the N588K inactivation‐mutant and the S624A pore‐helix mutant and was strongly reduced by the Y652A and F656A S6 helix mutants. In docking simulations to a MthK‐based homology model of hERG, the 2 aromatic rings of the drug could form multiple π‐π interactions with the aromatic side chains of both Y652 and F656. In monophasic action potential (MAP) recordings from guinea‐pig Langendorff‐perfused hearts, ivabradine delayed ventricular repolarization and produced a steepening of the MAPD90 restitution curve. Conclusions Ivabradine prolongs ventricular repolarization and alters electrical restitution properties at concentrations relevant to the upper therapeutic range. In absolute terms ivabradine does not discriminate between hERG and HCN channels: it inhibits IhERG with similar potency to that reported for native If and HCN channels, with S6 binding determinants resembling those observed for HCN4. These findings may have important implications both clinically and for future bradycardic drug design.

Action potential clamp and chloroquine sensitivity of mutant Kir2.1 channels responsible for variant 3 short QT syndrome.

Recently identified genetic forms of short QT syndrome (SQTS) are associated with an increased risk of arrhythmia and sudden death. The SQT3 variant is associated with an amino-acid substitution (D172N) in the KCNJ2-encoded Kir2.1 K+ channel. In this study, whole-cell action potential (AP) clamp recording from transiently transfected Chinese Hamster Ovary cells at 37 °C showed marked augmentation of outward Kir2.1 current through D172N channels, associated with right-ward voltage-shifts of peak repolarizing current during both ventricular and atrial AP commands. Peak outward current elicited by ventricular AP commands was inhibited by chloroquine with an IC50 of 2.45 μM for wild-type (WT) Kir2.1, of 3.30 μM for D172N-Kir2.1 alone and of 3.11 μM for co-expressed WT and D172N (P > 0.05 for all). These findings establish chloroquine as an effective inhibitor of SQT3 mutant Kir2.1 channels.

The short QT syndrome

Short QT syndrome is a condition that can cause a disruption of the hearts normal rhythm (arrhythmia). In people with this condition, the heart (cardiac) muscle takes less time than usual to recharge between beats. The term short QT refers to a specific pattern of heart activity that is detected with an electrocardiogram (EKG), which is a test used to measure the electrical activity of the heart. In people with this condition, the part of the heartbeat known as the QT interval is abnormally short.

Rabbit, a relevant model for the study of cardiac β3‐adrenoceptors

The β3‐adrenoceptors (β3‐ARs) have been identified and characterized in the human heart. Specific β3‐AR stimulation, unlike β1‐AR or β2‐AR stimulation, decreases cardiac contractility, partly via the Gi–NO pathway. However, the precise role of cardiac β3‐ARs is not yet completely understood. Indeed, under normal conditions, the β3‐AR response is present only to a very low degree in rats and mice. Therefore, we evaluated whether β3‐ARs were present and functional in rabbit ventricular cardiomyocytes, and whether the rabbit could serve as a relevant model for the study of cardiac β3‐ARs. We used RT‐PCR and Western blot to measure the β3‐AR transcripts and protein levels in rabbit ventricular cardiomyocytes. We also analysed the effect of β3‐AR stimulation using isoproterenol in combination with nadolol or SR 58611A on cardiomyocyte shortening, Ca2+ transient, L‐type Ca2+ current (ICa,L), delayed rectifier potassium current (IKs) and action potential duration (APD). For the first time, we show that β3‐ARs are expressed in rabbit ventricular cardiomyocytes. The mRNA and protein sequences present a high homology to those of rat and human β3‐ARs. Furthermore, β3‐AR stimulation decreases cardiomyocyte shortening, Ca2+ transient and ICa,L amplitudes, via a Gi–NO pathway. Importantly, β3‐AR stimulation enhances IKs amplitude and shortens the APD. Taken together, our results indicate that the rabbit provides a relevant model, easily used in laboratories, to study the roles of cardiac β3‐ARs in physiological conditions.

Molecular basis of hERG potassium channel blockade by the class Ic antiarrhythmic flecainide

The class Ic antiarrhythmic drug flecainide inhibits KCNH2-encoded “hERG” potassium channels at clinically relevant concentrations. The aim of this study was to elucidate the underlying molecular basis of this action. Patch clamp recordings of hERG current (IhERG) were made from hERG expressing cells at 37 °C. Wild-type (WT) IhERG was inhibited with an IC50 of 1.49 μM and this was not significantly altered by reversing the direction of K+ flux or raising external [K+]. The use of charged and uncharged flecainide analogues showed that the charged form of the drug accesses the channel from the cell interior to produce block. Promotion of WT IhERG inactivation slowed recovery from inhibition, whilst the N588K and S631A attenuated-inactivation mutants exhibited IC50 values 4–5 fold that of WT IhERG. The use of pore-helix/selectivity filter (T623A, S624A V625A) and S6 helix (G648A, Y652A, F656A) mutations showed < 10-fold shifts in IC50 for all but V625A and F656A, which respectively exhibited IC50s 27-fold and 142-fold their WT controls. Docking simulations using a MthK-based homology model suggested an allosteric effect of V625A, since in low energy conformations flecainide lay too low in the pore to interact directly with that residue. On the other hand, the molecule could readily form π–π stacking interactions with aromatic residues and particularly with F656. We conclude that flecainide accesses the hERG channel from the cell interior on channel gating, binding low in the inner cavity, with the S6 F656 residue acting as a principal binding determinant.

Ranolazine inhibition of hERG potassium channels: drug-pore interactions and reduced potency against inactivation mutants.

The antianginal drug ranolazine, which combines inhibitory actions on rapid and sustained sodium currents with inhibition of the hERG/IKr potassium channel, shows promise as an antiarrhythmic agent. This study investigated the structural basis of hERG block by ranolazine, with lidocaine used as a low potency, structurally similar comparator. Recordings of hERG current (IhERG) were made from cell lines expressing wild-type (WT) or mutant hERG channels. Docking simulations were performed using homology models built on MthK and KvAP templates. In conventional voltage clamp, ranolazine inhibited IhERG with an IC50 of 8.03 μM; peak IhERG during ventricular action potential clamp was inhibited ~ 62% at 10 μM. The IC50 values for ranolazine inhibition of the S620T inactivation deficient and N588K attenuated inactivation mutants were respectively ~ 73-fold and ~ 15-fold that for WT IhERG. Mutations near the bottom of the selectivity filter (V625A, S624A, T623A) exhibited IC50s between ~ 8 and 19-fold that for WT IhERG, whilst the Y652A and F656A S6 mutations had IC50s ~ 22-fold and 53-fold WT controls. Low potency lidocaine was comparatively insensitive to both pore helix and S6 mutations, but was sensitive to direction of K+ flux and particularly to loss of inactivation, with an IC50 for S620T-hERG ~ 49-fold that for WT IhERG. Docking simulations indicated that the larger size of ranolazine gives it potential for a greater range of interactions with hERG pore side chains compared to lidocaine, in particular enabling interaction of its two aromatic groups with side chains of both Y652 and F656. The N588K mutation is responsible for the SQT1 variant of short QT syndrome and our data suggest that ranolazine is unlikely to be effective against IKr/hERG in SQT1 patients.