Profile and kinetics of L-type calcium current during the cardiac ventricular action potential compared in guinea-pigs, rats and rabbits

Abstract. The substantial interspecies differences in mammalian cardiac action potentials (APs) are attributed primarily to variations in K+ currents. In a comparative study on isolated ventricular myocytes from guinea-pigs, rabbits and rats, we investigated the influence of the species-based AP differences on the time course of the L-type Ca2+ current (ICa,L). In addition, we tested whether also species-dependent properties of the ICa,L contribute to its time course during the AP. In patch-clamp measurements, ICa,L was characterised using conventional square pulses and digitised APs as command voltages. Special interest was directed to the analysis of the actual time courses of ICa,L, and L-type channel activation and inactivation during APs. Although species-specific differences in AP shape strongly influence the amplitude and the time course of ICa,L, divergence in L-type channel inactivation was found as well. In each species ICa,L inactivation was related to Ca2+ influx via L-type channels. However, while L-type channels showed similar Ca2+ dependency in the rabbit and the rat, a 2-times higher Ca2+ influx was necessary to achieve a given degree of inactivation in the guinea-pig. Thus, inactivation of ICa,L is delayed in the guinea-pig, thereby contributing to the prolonged AP plateau in this species. Comparing the actual time course of ICa,L, and L-type channel activation and inactivation revealed that, in each species, fading of ICa,L during final repolarisation was caused by deactivation (i.e. closure of the channel's d-gate) rather than inactivation.

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