Structural motifs for subtype-specific pH-sensitive gating of vertebrate otopetrin proton channels

Otopetrin (OTOP) channels are proton-selective ion channels conserved among vertebrates and invertebrates and with no structural similarity to other ion channels. There are three vertebrate OTOP channels (OTOP1, OTOP2, and OTOP3), of which one (OTOP1), functions as a sour taste receptor. Whether OTOP channels are gated by, as well as permeating, protons was not known. Here, by comparing functional properties of the three vertebrate proton channels with patch-clamp recording and cytosolic pH microfluorimetry, we provide evidence that each is gated by external protons. OTOP1 and OTOP3 are both activated by extracellular protons, with a sharp threshold of pHe <6.0 and 5.5 respectively, while OTOP2 is negatively gated by protons, and more conductive at alkaline extracellular pH (>pH 9.0). Strikingly, we found that we could change pH-sensitive gating of OTOP2 and OTOP3 channels by swapping extracellular linkers that connect transmembrane domains. Swaps of linkers within the N domain changed the relative conductance at alkaline pH, while swaps within the C domain tended to change the rates of OTOP3 current activation. We conclude that members of the OTOP channel family are proton-gated (acid-sensitive) proton channels and that the gating apparatus is distributed across multiple extracellular regions within both the N and C domains of the channels. In addition to the taste system, OTOP channels are found in the vestibular and digestive systems, where pH sensitivity may be tuned to specific functions.