The consequences of disrupting cardiac inwardly rectifying K+current (IK1)as revealed by the targeted deletion of the murineKir2.1andKir2.2genes

A complementary DNA encoding an inward rectifier K+ channel (IRK1) was isolated from a mouse macrophage cell line by expression cloning. This channel conducts inward K+ current below the K+ equilibrium potential but passes little outward K+ current. The IRK1 channel contains only two putative transmembrane segments per subunit and corresponds to the inner core structure of voltage-gated K+ channels. The IRK1 channel and an ATP-regulated K+ channel show extensive sequence similarity and constitute a new superfamily.

The inwardly rectifying K channel provides the resting K conductance in a variety of cells. This channel acts as a valve or diode, permitting entry of K+ under hyperpolarization, but not its exit under depolarization. This behaviour, termed inward rectification, permits long depolarizing responses which are of physiological significance for the pumping function of the heart and for fertilization of egg cells. Little is known about the outward currents through the inwardly rectifying K channel, despite their great physiological importance, and the mechanism of inward rectification itself is unknown. We have used improved patch clamp techniques to control the intracellular media, and have recorded the outward whole-cell and single-channel currents. We report here that the channel conductance is ohmic and that the well-known inward rectification of the resting K conductance is caused by rapid closure of the channel accompanied by a voltage-dependent block by intracellular Mg2+ ions at physiological concentrations.

Inward rectifier K+ channels pass prominent inward currents, while outward currents are largely blocked. The inward rectification is due to block by intracellular Mg2+ and a Mg(2+)-independent process described as intrinsic gating. The rapid loss of gating upon patch excision suggests that cytoplasmic factors participate in gating. "Intrinsic" gating can be restored in excised patches by nanomolar concentrations of two naturally occurring polyamines, spermine and spermidine. Spermine and spermidine may function as physiological blockers of inward rectifier K+ channels and "intrinsic" gating may largely reflect voltage-dependent block by these cations.