Potassium dependent structural changes in the selectivity filter of HERG potassium channels

The fine tuning of biological electrical signaling is mediated by variations in the rates of opening and closing of gates that control ion flux through different ion channels. Human ether-a-go-go related gene (HERG) potassium channels have uniquely rapid inactivation kinetics which are critical to the role they play in regulating cardiac electrical activity. Here, we have exploited the K+ sensitivity of HERG inactivation to determine structures of both a conductive and non-conductive selectivity filter structure of HERG. We propose that inactivation is the result of a high propensity for flipping of the selectivity filter valine carbonyl oxygens. Molecular dynamics simulations point to a low energy barrier, and hence rapid kinetics, for flipping of the valine 625 carbonyl oxygens facilitated by a previously unrecognized interaction between S620 and Y616 that stabilizes the transition state between conducting and non-conducting structures. Our model represents a new mechanism by which ion channels fine tune their activity that explains the uniquely rapid inactivation kinetics of HERG. Highlights Structures of a conductive and non-conductive HERG selectivity filter have been determined. Reduced potassium causes flipping of selectivity filter valine carbonyl oxygens. The sidechain of S620 on the pore helix coordinates distinct sets of interactions between conductive, non-conductive, and transition states. ### Competing Interest Statement The authors have declared no competing interest.