UCSF

AbstractTMEM16F is activated by elevated intracellular Ca2+, and functions both as a small-conductance ion channel permeable to Ca2+ and as a phospholipid scramblase. It is important to hold this positive feedback in check to prevent prolonged Ca2+-overloading in cells. We hypothesize that TMEM16F shifts its ion selectivity so that it is more permeable to Cl− than cations at high intracellular Ca2+ concentration. We tested this hypothesis with the Q559K mutant that shows no current rundown in excised patch with prolonged Ca2+ elevation. Recorded in NaCl−based solution, the channel shifted its ion selectivity from Na+-selective to Cl−-selective when intracellular Ca2+ was increased. The ion selectivity switch did not correlate with changes of channel open state. Rather, it was indicative of an alteration of electrostatic field in the permeation pathway. Shifting ion-selectivity synergistically by intracellular divalent ions and membrane potential could work as a built-in mechanism that allows TMEM16F to brake the positive feedback.