Cardiac IK1 underlies early action potential shortening during hypoxia in the mouse heart

It is established that prolonged hypoxia leads to activation of KATP channels and action potential (AP) shortening, but the mechanisms behind the early phase of metabolic stress remain controversial. Under normal conditions IK1 channels are constitutively active while KATP channels are closed. Therefore, early changes in IK1 may underlie early AP shortening. This hypothesis was tested using transgenic mice with suppressed IK1 (AAA-TG). In isolated AAA-TG hearts AP shortening was delayed by not, vert, similar 24 s compared to WT hearts. In WT ventricular myocytes, blocking oxidative phosphorylation with 1 mM cyanide (CN; 28 °C) led to a 29% decrease in APD90 within not, vert, similar 3–5 min. The effect of CN was reversed by application of 100 μM Ba2+, a selective blocker of IK1, but not by 10 μM glybenclamide, a selective blocker of KATP channels. Accordingly, voltage-clamp experiments revealed that both CN and true hypoxia lead to early activation of IK1. In AAA-TG myocytes, neither CN nor glybenclamide or Ba2+ had any effect on AP. Further experiments showed that buffering of intracellular Ca2+ with 20 mM BAPTA prevented IK1 activation by CN, although CN still caused a 54% increase in IK1 in a Ca2+-free bath solution. Importantly, both (i) 20 μM ruthenium red, a selective inhibitor of SR Ca2+-release, and (ii) depleting SR by application of 10 μM ryanodine + 1 mM caffeine, abolished the activation of IK1 by CN. The above data strongly argue that in the mouse heart IK1, not KATP, channels are responsible for the early AP shortening during hypoxia.