Stereoselective block of the hERG potassium channel by the Class Ia antiarrhythmic drug disopyramide

Potassium channels encoded by human Ether-à-go-go-Related Gene (hERG) are inhibited by diverse cardiac and non-cardiac drugs. Disopyramide is a chiral Class Ia antiarrhythmic that inhibits hERG at clinical concentrations. This study evaluated effects of disopyramide enantiomers on hERG current (I_hERG) from hERG expressing HEK 293 cells at 37 °C. S(+) and R(−) disopyramide inhibited wild-type (WT) I_hERG with IC₅₀ values of 3.9 µM and 12.9 µM respectively. The attenuated-inactivation mutant N588K had little effect on the action of S(+) disopyramide but the IC₅₀ for the R(−) enantiomer was ~ 15-fold that for S(+) disopyramide. The enhanced inactivation mutant N588E only slightly increased the potency of R(−) disopyramide. S6 mutation Y652A reduced S(+) disopyramide potency more than that of R(−) disopyramide (respective IC₅₀ values ~ 49-fold and 11-fold their WT controls). The F656A mutation also exerted a stronger effect on S(+) than R(−) disopyramide, albeit with less IC₅₀ elevation. A WT-Y652A tandem dimer exhibited a sensitivity to the enantiomers that was intermediate between that of WT and Y652A, suggesting Y652 groups on adjacent subunits contribute to the binding. Moving the Y (normally at site 652) one residue in the N- terminal (up) direction in N588K hERG markedly increased the blocking potency of R(−) disopyramide. Molecular dynamics simulations using a hERG pore model produced different binding modes for S(+) and R(−) disopyramide consistent with the experimental observations. In conclusion, S(+) disopyramide interacts more strongly with S6 aromatic binding residues on hERG than does R(−) disopyramide, whilst optimal binding of the latter is more reliant on intact inactivation.