PubMed 19522859
Referenced in: none
Automatically associated channels: Kv7.1
Title: Probing the mechanisms underlying modulation of quinidine sensitivity to cardiac I(Ks) block by protein kinase A-mediated I(Ks) phosphorylation.
Authors: Tao Yang, Hideaki Kanki, Wei Zhang, Dan M Roden
Journal, date & volume: Br. J. Pharmacol., 2009 Jul , 157, 952-61
PubMed link: http://www.ncbi.nlm.nih.gov/pubmed/19522859
Abstract
Cardiac I(Ks) is enhanced by protein kinase A (PKA) stimulation. And PKA-stimulated I(Ks) is about threefold less sensitive to quinidine block than basal current. In this study, we further tested two competing hypotheses: I(Ks) phosphorylation either (i) modulates access of blocking drugs to a binding site; or (ii) destabilizes the drug-channel interaction.To distinguish between these hypotheses, we studied quinidine block of I(Ks) channels in which three PKA site residues of the alpha-subunit KCNQ1 were mutated with a bulky negative charged aspartic acid (D). To study alleviation of I(Ks) block by quinidine, we compared activating current at +60 mV, either with or without 5 s hyperpolarizing prepulses to -120 mV.Without PKA stimulation, quinidine (100 microM) blocked wild-type current to a similar extent with and without the prepulse (93 +/- 2% of pre-drug current at +60 mV vs. 95 +/- 1%). With PKA-stimulated wild-type channels, however, there was less block with the hyperpolarization to -120 mV: at +60 mV, block was 71 +/- 2% (-prepulse) versus 58 +/- 3% (+prepulse). Individual D-mutations and the triple-D mutant were resistant to quinidine block similar to that seen with PKA-stimulated wild-type I(Ks).We conclude that phosphorylation-induced insertion of bulky negative charges alleviates quinidine block and that PKA-induced stimulation, by conferring negative charges to the channels, blunts I(Ks) block as the interaction between the channels and blockers becomes destabilized. These effects would be of clinical significance in providing protective mechanisms against pro-arrhythmias caused by drug-induced inhibition of I(Ks) and I(Kr).