The human ether-a'-go-go related gene (hERG) K+ channel blockade by the investigative selective-serotonin reuptake inhibitor CONA-437: limited dependence on S6 aromatic residues.

Diverse non-cardiac drugs adversely influence cardiac electrophysiology by inhibiting repolarising K(+) currents mediated by channels encoded by the human ether-a-go-go-related gene (hERG). In this study, pharmacological blockade of hERG K(+) channel current (I(hERG)) by a novel investigative serotonin-selective reuptake inhibitor (SSRI), CONA-437, was investigated. Whole-cell patch-clamp measurements of I(hERG) were made from human embryonic kidney (HEK 293) cells expressing wild-type (WT) or mutant forms of the hERG channel. With a step-ramp voltage-command, peak I(hERG) was inhibited with an IC(50) of 1.34 µM at 35 ±1°C; the IC(50) with the same protocol was not significantly different at room temperature. Voltage-command waveform selection had only a modest effect on the potency of I(hERG) block: the IC50 with a ventricular action potential command was 0.72 µM. I(hERG) blockade developed rapidly with time following membrane depolarisation and showed a weak dependence on voltage, accompanied by a shift of ≈ -5 mV in voltage-dependence of activation. There was no significant effect of CONA-437 on voltage-dependence of I(hERG) inactivation, though at some voltages an apparent acceleration of the time-course of inactivation was observed. Significantly, mutation of the S6 aromatic amino acid residues Y652 and F656 had only a modest effect on I(hERG) blockade by CONA-437 (a 3-4 fold shift in affinity). CONA-437 at up to 30 µM had no significant effect on either Nav1.5 sodium channels or L-type calcium channels. In conclusion, the novel SSRI CONA-437 is particularly notable as a gating-dependent hERG channel inhibitor for which neither S6 aromatic amino-acid constituent of the canonical drug binding site on the hERG channel appears obligatory for I(hERG) inhibition to occur.

Inhibition of HERG K+ current and prolongation of the guinea-pig ventricular action potential by 4-aminopyridine.

4-Aminopyridine (4-AP) has been used extensively to study transient outward K+ current (ITO,1) in cardiac cells and tissues. We report here inhibition by 4-AP of HERG (the human ether-à-go-go-related gene) K+ channels expressed in a mammalian cell line, at concentrations relevant to those used to study ITO,1. Under voltage clamp, whole cell HERG current (IHERG) tails following commands to +30 mV were blocked with an IC50 of 4.4 +/- 0.5 mM. Development of block was contingent upon HERG channel gating, with a preference for activated over inactivated channels. Treatment with 5 mM 4-AP inhibited peak IHERG during an applied action potential clamp waveform by ~59 %. It also significantly prolonged action potentials and inhibited resurgent IK tails from guinea-pig isolated ventricular myocytes, which lack an ITO,1. We conclude that by blocking the alpha-subunit of the IKr channel, millimolar concentrations of 4-AP can modulate ventricular repolarisation independently of any action on ITO,1.

Reduced ryanodine receptor to dihydropyridine receptor ratio may underlie slowed contraction in a rabbit model of left ventricular cardiac hypertrophy.

Cardiac hypertrophy is associated with contractile dysfunction, a feature of which is a slowing of the time to reach peak contraction. We have examined the main mechanisms involved in the initiation of contraction and investigated if their functions are changed during cardiac hypertrophy. Cardiac hypertrophy was induced by constriction of the ascending aorta in the rabbit. After 6 weeks left ventricular myocytes were isolated or left ventricular and septal mixed membrane preparations were produced for electrophysiological and radioligand binding studies, respectively. Aortic constriction resulted in a 24% and 23% increase in heart weight to body weight ratio and cell capacitance, respectively. Action potential duration and time-to-reach 50% and 90% peak contraction (TTP(50)and TTP(90), respectively) were significantly prolonged in myocytes from hypertrophied hearts. The prolongation of TTP(50)and TTP(90)could not be explained by altered peak calcium current density or SR calcium content which were unchanged in hypertrophy. Radioligand binding studies performed on tissue preparations from the same hearts, revealed a 34% reduction in ryanodine receptor (RYR) density with no change in dihydropyridine receptor (DHPR) density. This resulted in a reduction in the ratio of RYR to DHPR from 4.4:1 to 3.3:1 in hypertrophy. Ryanodine receptor Ca(2+)-sensitivity was unchanged between sham operated and hypertrophied groups. A reduction in the ratio of RYRs to DHPRs may result in a degree of "functional uncoupling" causing defective release of Ca(2+)from the SR. These findings may underlie the slowed TTP of myocyte contraction in hypertrophy.

The role of L-type calcium current in the generation of repolarization-induced contraction in cardiac myocytes.

OBJECTIVE: Early experiments into the arrhythmogenic transient inward current frequently showed apparent coupling of this current to repolarization from a depolarizing voltage clamp step. Calcium transients have subsequently been shown to couple to such repolarization and are the result of calcium release from the sarcoplasmic reticulum. We have investigated whether this phenomenon is due to calcium entry via non-inactivated calcium channels or to voltage-activated SR release. METHODS: Voltage clamp steps were imposed on isolated guinea pig and rabbit cardiac myocytes. Calcium release was monitored by tracking cell contraction. L-type calcium current at the moment of repolarization was manipulated by the rapid application of 2 mM cadmium or 10 mM calcium. RESULTS: Repolarization-induced contraction was abolished by the rapid application of 2 mM cadmium immediately prior to repolarization, and was augmented by the rapid change of extracellular calcium concentration from 2 mM to 10 mM immediately prior to repolarization. There is no evidence of coupling of drive train-induced aftercontractions to repolarization from the final action potential of the drive train and 2 mM cadmium does not alter the appearance or timing of these aftercontractions. Simulation of phase 1 repolarization in the mammalian cardiac action potential decreases rather than increases twitch amplitude. CONCLUSION: Repolarization-induced contraction results from calcium entry through non-inactivated calcium channels, not from voltage-activated release. It plays no physiological role in contributing to the stimulated twitch and no pathological role in generating drive train-induced aftercontractions.