Identification of the Alcohol Activation Site in GIRK Channels

Abstract

In addition to G proteins, ethanol can activate G protein-gated inwardly rectifying K (GIRK) channels. The mechanism underlying GIRK channel activation by alcohol is not well understood. Based on a crystal structure of a related IRK1 channel which contains the alcohol (2-methyl,2-4-pentanediol- MPD) bound to a cytoplasmic hydrophobic pocket, we used structure-based mutagenesis and patch-clamp electrophysiology to investigate the role of the homologous alcohol pocket in GIRK2 channels. In HEK293T cells transfected with GIRK2 cDNA, both ethanol and MPD activated GIRK2 channels. Replacing a conserved Leucine (L257) in this pocket with a bulkier Tyrosine or Tryptophan led to significant attenuation or loss of alcohol-dependent activation of GIRK2 channels, suggesting these larger hydrophobic side-chains filled the pocket. Based on structure and functional evidence, we conclude that this hydrophobic pocket is the site for alcohol activation of GIRK channels. We hypothesized that tethering a hydrophobic group near the pocket might mimic alcohol mediated activation of the channel. To test this idea, we introduced a S246C mutation in a Cysteine-less GIRK2 channel and examined the effect of bath applied MTS-Benzene. Application of 10 micromolar MTS-Benzene dramatically increased the size of basal GIRK currents by 336+66% n=5. This rapid activation was reversed by application of reducing agent DTT (10 mM), indicating a disulfide bond had formed. In addition to the change in basal current, MTS modification of S246C channel altered the rank order for alcohol activation -with significantly less activation by the larger alcohol MPD. These results suggest that attachment of a bulky hydrophobic amino acid near the hydrophobic alcohol-binding pocket can produce sustained activation of the channel by associating with the activation site. These experiments provide a launching point to study molecular events at this hydrophobic pocket that lead to activation of GIRK channels.