Non‐competitive Inhibition of ATP Binding to the Carboxyl Terminus of Kir6.2 by Epoxyeicosatrienoic Acids

Epoxyeicosatrienoic acids (EETs) potently and stereospecifically activate the cardiac ATP‐sensitive K + (Kir6.2) channels by reducing channel sensitivity to ATP. In this study, we determined the effects of EETs on the binding of ATP to Kir6.2 by using 2,4,6‐trinitrophenyl (TNP)‐ATP, which increases fluorescence emission >8‐fold with binding to protein, and by using GST fusion protein containing Kir6.2. TNP‐ATP binds to the GST fusion protein containing the Kir6.2C‐terminus but not to that with the Kir6.2N‐terminus. Binding of TNP‐ATP to GST‐Kir6.2C (K D 5.0 μ M) was unchanged by 5 μ M 11,12‐EET (K D 4.4 μ M) but B max was reduced by half, suggesting non‐competitive inhibition of ATP binding. The effect of 11,12‐EET was dose‐dependent and 8,9‐ and 14,15‐EETs were equipotent inhibitors of TNP‐ATP binding to GST‐Kir6.2C. Arachidonic acid and 11,12‐DHET were not effective inhibitors, whereas the methyl ester of 11,12‐EET was as effective as 11,12‐EET in inhibiting TNP‐ATP binding to GST‐Kir6.2C. R195A mutation in GST‐Kir6.2C abolished the EET effects on TNP‐ATP binding, while the K185A mutation, which reduced ATP binding to Kir6.2, had no effect. These findings are consistent with previous patch clamp results that showed the epoxide group in EET and R195 in Kir6.2 are critical for K ATP channel activation by EET. We conclude that EETs bind to the C‐terminus of the K ATP channel and allosterically alter the ATP binding site, reducing the channel sensitivity to ATP.