Stoichiometry of Kir channels with phosphatidylinositol bisphosphate.

Phosphatidylinositol bisphosphate (PIP(2)) is the most abundant phosphoinositide in the plasma membrane of cells and its interaction with many ion channel proteins has proven to be a critical factor enabling ion channel gating. All members of the inwardly rectifying potassium (Kir) channel family depend on PIP(2) for their activity, displaying distinct affinities and stereospecificities of interaction with the phosphoinositide. Here, we explored the stoichiometry of Kir channels with PIP(2). We first showed that PIP(2) regulated the activity of Kir3.4 channels mainly by altering their bursting behavior. Detailed burst analysis indicates that the channels assumed up to four open states and a connectivity of four between open and closed states depending on the available PIP(2) levels. Moreover, by controlling the number of PIP(2)-sensitive subunits in the stoichiometry of a tetrameric Kir2.1 channel, we showed that characteristic channel activity was obtained when at least two wild-type subunits were present. Our studies support a kinetic model for gating of Kir channels by PIP(2), where each of the four open states corresponds to the channel activated by one to four PIP(2) molecules.

Characterizations of a loss-of-function mutation in the Kir3.4 channel subunit.

Kir3.4 and Kir3.1 potassium channel subunits mediate the acetylcholine induced inwardly rectifying current I(KACh) in the heart. We found a glycine to arginine substitution in codon 247 of Kir3.4 in a patient with a single episode of atrial fibrillation (AF). Expression in Xenopus laevis oocytes and two-electrode voltage-clamp revealed that Kir3.4-G247R basal current was reduced compared to wild-type Kir3.4 and co-expression with the muscarinic acetylcholine receptor type 2 showed that also the acetylcholine induced current was severely reduced in Kir3.4-G247R, indicating that the mutation interfered with activation by the stimulatory G betagamma-subunits. Co-expression of Kir3.4-G247R with wild-type Kir3.4 or Kir3.1 had a compensating effect on both basal current levels and the response to muscarinic stimulation suggesting the function of Kir3.4-G247R is compensated in vivo. This may explain the lack of clear clinical manifestations and further studies are necessary to elucidate if mutations in Kir3.4 are predisposing AF.

Protein kinase A modulates PLC-dependent regulation and PIP2-sensitivity of K+ channels.

Neurotransmitter and hormone regulation of cellular function can result from a concomitant stimulation of different signaling pathways. Signaling cascades are strongly regulated during disease and are often targeted by commonly used drugs. Crosstalk of different signaling pathways can have profound effects on the regulation of cell excitability. Members of all the three main structural families of potassium channels: inward-rectifiers, voltage-gated and 2-P domain, have been shown to be regulated by direct phosphorylation and Gq-coupled receptor activation. Here we test members of each of the three families, Kir3.1/Kir3.4, KCNQ1/KCNE1 and TREK-1 channels, all of which have been shown to be regulated directly by phosphatidylinositol bisphosphate (PIP2). The three channels are inhibited by activation of Gq-coupled receptors and are differentially regulated by protein kinase A (PKA). We show that Gq-coupled receptor regulation can be physiologically modulated directly through specific channel phosphorylation sites. Our results suggest that PKA phosphorylation of these channels affects Gq-coupled receptor inhibition through modulation of the channel sensitivity to PIP2.