Molecular basis of the facilitation of the heterooligomeric GIRK1/GIRK4 complex by cAMP dependent protein kinase

G-protein activated inwardly rectifying K+ channels (GIRKs) of the heterotetrameric GIRK1/GIRK4 composition mediate IK + ACh in atrium and are regulated by cAMP dependent protein kinase (PKA). Phosphorylation of GIRK1/GIRK4 complexes promotes the activation of the channel by the G-protein Gβγ-dimer (“heterologous facilitation”). Previously we reported that 3 serines/threonines (S/Ts) within the GIRK1 subunit are phosphorylated by the catalytic subunit of PKA (PKA-cs) in-vitro and are responsible for the acute functional effects exerted by PKA on the homooligomeric GIRK1F137S (GIRK1⁎) channel. Here we report that homooligomeric GIRK4WT and GIRK4S143T (GIRK4⁎) channels are clearly regulated by PKA phosphorylation. Heterooligomeric channels of the GIRK1S385CS401CT407C/GIRK4WT composition, where the GIRK1 subunit is devoid of PKA mediated phosphorylation, exhibited reduced but still significant acute effects (reduction during agonist application was ≈ 49% compared to GIRK1WT/GIRK4WT). Site directed mutagenesis of truncated cytosolic regions of GIRK4 revealed four serines/threonines (S/Ts) that were heavily phosphorylated by PKA-cs in vitro. Two of them were found to be responsible for the acute effects exerted by PKA in vivo, since the effect of cAMP injection was reduced by ≈ 99% in homooligomeric GIRK4⁎T199CS412C channels. Coexpression of GIRK1WT/GIRK4T199CS412C reduced the acute effect by ≈ 65%. Only channels of the GIRK1S385CS401CT407C/GIRK4T199CS412C composition were practically devoid of PKA mediated effects (reduction by ≈ 97%), indicating that both subunits contribute to the heterologous facilitation of IK + ACh.

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► Phosphorylation of GIRKs is the prerequisite for activation by G-proteins (=heterologous facilitation).
► Direct phosphorylation by PKA was found to be responsible for GIRK4 regulation.
► GIRK4 subunits contribute substantially to regulation of heterooligomeric GIRK1/GIRK4 channels by PKA in vivo.
► Mechanistic insight how G-protein/effector interaction is modulated by effector phosphorylation is provided.