Bagriantsev SN , Clark KA , Minor DL .

R01-MH093603 NIMH NIH HHS, R01 MH093603 NIMH NIH HHS

	Figure 1. Extracellular potassium antagonizes regulation of K2P2.1 (TREK-1) by membrane potential. (A) Effect of membrane potential (EM) on K2P2.1 (TREK-1) activity in Xenopus laevis oocytes measured by two-electrode voltage clamp in 2 mM [K+]o pH 7.4. Current–voltage (I-V) curves show exemplar voltage-clamp recordings of K2P2.1 (TREK-1) activity after 4 min of holding at −100 and 0 mV, consecutively. (B) Cartoon diagram of a single K2P2.1 (TREK-1) subunit, transmembrane segments 1–4 (M1–M4), pore helix 1 and pore helix 2 (PH1, PH2), and the positions of key residues are indicated. (C) Exemplar I–V curves showing the effect of EM on K2P2.1 (TREK-1) S300A. (D) Channel activity from a representative cell in response to changes in EM. Channel activity was assayed every 15 s by a ramp from −150 to 50 mV. Following current stabilization at −100 mV, EM was changed to 0 mV, and channel activity was assayed by the ramp protocol until current reached minimal values (usually within 4–5 min). Channel activity was reversed by returning EM to −100 mV. Each point represents channel activity from the ramp curves at 0 or +50 mV for 2 mM and 90 [K+]o solutions, respectively. Data presented as fraction relative to activity after initial stabilization at −100 mV. (E) Quantification of maximal inhibition of WT or mutant K2P2.1 (TREK-1) by prolonged incubation at 0 mV (mean±s.e., n⩾6, N⩾2, where ‘n' is the number of oocytes and ‘N' in the number of independent oocyte batches). (F) I–V curves showing exemplar voltage-clamp recordings of K2P2.1 (TREK-1) in 90 mM [K+]o pH 7.4 after stabilization at, consecutively, −100 and 0 mV.
	Figure 2. PH1 is critical for K2P channels C-type gating. (A) Amino-acid alignment of the PH1 region of the indicated K2P channels. The GXG selectivity filter sequence is highlighted in grey. (B, C, E, F, H, I) Exemplar recordings of the response of the indicated K2P channels to the external pH (pHo) changes in 2 mM [K+]o solution. Currents were elicited by a voltage ramp from −150 to +50 mV, from a holding potential of −80 mV. (D, G, J) Quantitation of the response of the K2P channels to changes in pHo. Data (mean±s.e., n⩾6, N⩾2) was taken at 0 mV, normalized to activity at pH 9.0, and fitted to the Hill equation.
	Figure 3. Mutations that stabilize the C-type gate antagonize regulation of K2P2.1 (TREK-1) by membrane potential. (A, B) Exemplar recordings from oocytes expressing the indicated K2P2.1 (TREK-1) mutants after prolonged incubation at, consecutively, −100 and 0 mV in 2 mM [K+]o pH 7.4. After current stabilization at −100 mV, the membrane potential was changed to 0 mV, and the current was recorded every 15 s using a voltage ramp from −150 to +50 mV. (C) Exemplar time resolution of channel activity from a representative cell in response to fluctuating EM in 2 mM [K+]o pH 7.4. Each point represents channel activity from the ramp curves at 0 mV. Data presented as fraction relative to activity after initial stabilization at −100 mV. (D) Quantification of maximal K2P2.1 (TREK-1) inhibition by prolonged incubation at 0 mV (mean±s.e., n⩾6, N⩾2). (E) Ribbon diagram showing the location of Trp275 and Gly137 of K2P2.1 (TREK-1) on the crystal structure of K2P4.1 (TRAAK) (Brohawn et al, 2012)(PDB ID 3UM7). M4, transmembrane helix 4. PH1, pore helix 1. Blue spheres depict potassium ions.
	Figure 4. M4–Ct junction is critical for cross-talk between Ct and the C-type gate. (A) Amino-acid sequence of the M4–Ct junction region of K2P2.1 (TREK-1) showing the location of the 3G and 3A mutations. Dashed line indicates a predicted boundary between M4 and Ct. (B) Exemplar time resolution of channel activity from a representative cell in response to fluctuating EM in 2 mM [K+]o pHo 7.4. Each point represents channel activity from the ramp curves at 0 mV. Data presented as fraction relative to activity after initial stabilization at −100 mV. (C) Quantification of maximal K2P2.1 (TREK-1) inhibition by prolonged incubation at 0 mV (mean±s.e., n⩾6, N⩾2). (D–F) Normalized responses of the indicated channels to pHo changes in 2 mM [K+]o. Currents were elicited by a voltage ramp from −150 to +50 mV, from a holding potential of −80 mV. Data (mean±s.e., n⩾6, N⩾2) was taken at 0 mV, normalized to activity at pH 9.0 and fitted to the Hill equation.
	Figure 5. Ct domains act cooperatively to affect K2P2.1 (TREK-1) function. (A) Immunoblot analysis of lysates from oocytes expressing HA-tagged WT, HA-WT or tandem HA-WT-WT K2P2.1 (TREK-1) channels. Lysates were pre-incubated with or without EndoH for 1 h at 4oC or at room temperature (RT). Before electrophoresis, all samples were treated with 2% SDS and 2% β-mercaptoethanol for 15 min at 50oC to dissociate K2P2.1 (TREK-1) subunits. Asterisks denote deglycolyslated forms of WT and tandem channels. (B–D) Normalized responses of the indicated K2P2.1 (TREK-1) channels to pHo changes 2 mM [K+]o. Currents were elicited by a voltage ramp from −150 to +50 mV, from a holding potential of −80 mV. Data (mean±s.e., n⩾6, N⩾2) was taken at 0 mV, normalized to activity at pH 9.0 and fitted to the Hill equation.
	Figure 6. Both C-terminal domains are required for the K2P2.1 (TREK-1) temperature response. (A–C) Exemplar two-electrode voltage clamp recordings of K2P2.1 (TREK-1) (A), K2P2.1-3G (B), and K2P2.1-3A (C) responses to temperature in 2 mM [K+]o pH 7.4. Currents were elicited by a ramp from −150 to +50 mV, from a −80 mV holding potential. (D–F) Quantification of the temperature responses. Data (mean±s.e., n⩾6, N⩾2) was taken at 0 mV and normalized to channel activity at 14°C. (G) Cartoon model of how Ct couples to the C-type gate of K2P2.1 (TREK-1). M4, transmembrane segment 4. Channel elements come from a single subunit. Transmembrane segments M1–M3 and pore helix 2 are not depicted. Dashed regions indicate connections to parts of the subunit that are not shown. Green circles represent potassium ions in the selectivity filter.

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