G protein-activated (GIRK) current in rat ventricular myocytes is masked by constitutive inward rectifier current (I(K1)).

Inwardly-rectifying K+ channel subunits are not homogenously expressed in different cardiac tissues. In ventricular myocytes (VM) the background current-voltage relation is dominated by I(K1), carried by channels composed of Kir2.x subunits, which is less important in atrial myocytes (AM). On the other hand in AM a large G protein gated current carried by Kir3.1/3.4 complexes can be activated by stimulation of muscarinic M(2) receptors (I(K(ACh))), which is assumed to be marginal in VM. Recent evidence suggests that total current carried by cardiac inward-rectifiers (I(K(ATP)), I(K(ACh)), I(K1)) in both, AM and VM is limited, due to K+ accumulation/depletion. This lead us to hypothesize that in conventional whole celI recordings I(K(ACh)) in VM is underestimated as a consequence of constitutive I(K1). In that case a reduction in density of I(K1) should be paralleled by an increase in density of I(K(ACh)). Three different experimental strategies have been used to test for this hypothesis: (i) Adenovirus-driven expression of a dominant-negative mutant of Kir2.1, one of the subunits supposed to form I(K1) channels, in VM caused a reduction in I(K1)-density by about 80 %. In those cells I(K(ACh)) was increased about 4 fold. (ii) A comparable increase in I(K(ACh)) was observed upon reduction of I(K1) caused by adenovirus-mediated RNA interference.(iii) Ba2+ in a concentration of 2 microM blocks I(K1) in VM by about 60 % without affecting atrial I(K(ACh)). The reduction in I(K1) by 2 microM Ba2+ is paralleled by a reversible increase in I(K(ACh)) by about 100%. These data demonstrate that the increase in K+ conductance underlying ventricular I(K(ACh)) is largely underestimated, suggesting that it might be of greater physiological relevance than previously thought.

Generation of a constitutive Na+-dependent inward-rectifier current in rat adult atrial myocytes by overexpression of Kir3.4.

Apart from gating by interaction with betagamma subunits from heterotrimeric G proteins upon stimulation of appropriate receptors, Kir.3 channels have been shown to be gated by intracellular Na+. However, no information is available on how Na+-dependent gating affects endogenous Kir3.1/Kir3.4 channels in mammalian atrial myocytes. We therefore studied how loading of adult atrial myocytes from rat hearts via the patch pipette filling solution with different concentrations of Na+ ([Na+]pip) affects Kir3 current. Surprisingly, in a range between 0 and 60 mm, Na+ neither had an effect on basal inward-rectifier current nor on the current activated by acetylcholine. Overexpression of Kir3.4 in adult atrial myocytes forced by adenoviral gene transfer results in formation of functional homomeric channels that interact with betagamma subunits upon activation of endogenous muscarinic receptors. These channels are activated at [Na+]pip >or= 15 mm, resulting in a receptor-independent basal inward rectifier current (I bir). I bir was neither affected by pertussis toxin nor by GDP-beta-S, suggesting G-protein-independent activation. PIP(2) depletion via endogenous PLC-coupled alpha1 adrenergic receptors causes inhibition of endogenous Kir3.1/3.4 channel currents by about 75%. In contrast, inhibition of Na+-activated I bir amounts to < 20%. The effect of the Kir3 channel blocker tertiapin-Q can be described using an IC50 of 12 nm (endogenous I K(ACh)) and 0.61 nm (I bir). These data clearly identify I bir as a homotetrameric Kir3.4 channel current with novel properties of regulation and pharmacology. Ibir shares some properties with a basal current recently described in atrial myocytes from an animal model of atrial fibrillation (AF) and AF patients.