HERG is believed to encode the major sub-unit of the cardiac 'rapid' delayed rectifier K channel (I(Kr)). Both I(Kr) and HERG exhibit marked inward rectification at positive membrane potentials due to rapid inactivation and this is thought to influence significantly the contribution of the current to cardiac action potential (AP) repolarisation. We investigated directly the role played by rapid inactivation, by measuring current activated by a ventricular AP waveform, from Chinese Hamster Ovary cells transfected with HERG cDNA with a point-mutation (S631A) in the pore region. Square command pulses elicited HERG-S631A current which increased progressively in magnitude with test potential up to +30/+40 mV (n=6). During test pulses to +40mV, HERG-S631A exhibited little inactivation compared to wildtype HERG. During an action potential command, WT-HERG current developed progressively during the AP plateau and slow repolarisation phase, showing maximal current between -30mV and -40 mV (n=10). In contrast, HERG-S631A current increased earlier during the AP plateau, with a maximal amplitude near +30mV (n=7). Current then declined as the AP proceeded, giving rise to a 'bow'- or 'inverted-U-' shaped current profile. A mathematical model with inactivation removed from the HERG current reproduced the I-V profile of HERG-S631A. These data provide a direct demonstration that rapid inactivation normally plays a critical role in determining both time-course and voltage dependence of HERG/I(Kr) -current during the cardiac ventricular AP.