Abstract
hERG (human Ether-à-go-go Related Gene) is responsible for ion channels mediating rapid delayed rectifier potassium current, I(Kr), which is key to cardiac action potential repolarization. Gain-of-function hERG mutations give rise to the SQT1 variant of the Short QT Syndrome (SQTS). Reggae mutant zebrafish, with a S4 zERG mutation (Leucine499Proline; L499P), display arrhythmic features analogous to those seen in the SQTS. The affected S4 domain ERG residue is highly conserved. This study was executed to determine how the homologous hERG mutation (L532P) influences channel function at 37°C. Whole-cell measurements of current (I(hERG)) were made from HEK 293 cells expressing WT or L532P hERG. The half maximal activation voltage (V(0.5)) of L532P I(hERG) was positively shifted by ~+36mV compared to WT I(hERG); however at negative voltages a pronounced L532P I(hERG) was observed. Both activation and deactivation time-courses were accelerated for L532P I(hERG). The inactivation V(0.5) for L532P I(hERG) was shifted by ~+32mV. Under action potential (AP) voltage-clamp, L532P I(hERG) exhibited a dome-shaped current peaking at ~+16mV, compared to ~-31mV for WT-I(hERG). The L532P mutation produced an ~5-fold increase in the IC(50) for dronedarone inhibition of I(hERG). Homology modeling indicated that the L532 residue within the S4 helix lies closely apposed to the S5 region of an adjacent hERG subunit. Alterations to the S4 domain structure and, potentially, to interactions between adjacent hERG subunits are likely to account for the functional effects of this mutation.