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	Fig. 2. Transport activation of DmHAK5. (A) Normalized current response recorded at −140 mV of Xenopus oocytes injected with H2O, cRNA of DmHAK5, or cRNA of DmHAK5 supplemented with CBL9/CIPK23. Macroscopic potassium currents were only detectable in DmHAK5/CBL9/CIPK23-coexpressing oocytes in solutions containing 2 mM potassium (n ≥ 6; mean ± SD). (B) Typical whole-oocyte currents recorded at −60 mV of an H2O-injected (black) and a DmHAK5/CBL9/CIPK23-expressing (red) Xenopus oocyte. Addition of 2 mM K+ resulted in macroscopic inward currents of ∼400 nA only with DmHAK5-expressing oocytes. The dotted line represents zero current.
	Fig. 3. Selectivity and pH dependency of DmKT1. (A) Currents recorded at −140 mV of DmKT1/CBL9/CIPK23-expressing oocytes in the presence of bath solutions containing various monovalent cations (each 100 mM). Large cation influx was only obtained with potassium in the external bath solution (n = 4; mean ± SD). (B) Inward K+ currents elicited by a DmKT1/CBL9/CIPK23-expressing Xenopus oocyte markedly increased on acidification of the external solution (Vm = −100 mV). Exchanging 100 mM external Li+ for 100 mM K+ at pH 6 resulted in potassium influx, which was enhanced by increasing the external H+ concentration. The dotted line represents zero currents. (C) Normalized currents of DmKT1/CBL9/CIPK23-expressing Xenopus oocytes at −140 mV. Stepwise acidification from pH 6 to 3 increased the potassium currents through DmKT1 (n = 6; mean ± SD). (D) The relative open probability (rel. PO) of DmKT1-expressing oocytes at the indicated H+ concentrations was plotted against the applied test voltage. Note the prominent positive shift of the half-maximal activation potential (V1/2) with increasing acidification. The data points were fitted with a Boltzmann function (solid lines; n = 6; mean ± SD).
	Fig. 4. Selectivity and pH dependency of DmHAK5. Xenopus oocytes were either injected with H2O (control) or cRNA of DmHAK5/CBL9/CIPK23 (DmHAK5). (A) Representative current recordings at −60 mV of a control (black) and a DmHAK5-expressing (red) Xenopus oocyte in response to 2 mM Li+, Na+, K+, Rb+, Cs+, NH4+, or NMDG+ (as indicated using sorbitol-based solutions). Both K+ and Rb+ resulted in macroscopic inward currents with DmHAK5-expressing oocytes. Application of NH4+ and Cs+ induced weaker DmHAK5-mediated inward currents. The dotted line represents zero current. (B) Average results from experiments as shown in A, except that the holding potential was −140 mV (n = 7; mean ± SD). (C) Normalized steady-state currents of Xenopus oocytes injected with DmHAK5 were recorded at −140 mV in response to sorbitol- or Na+-based solution (200 mOsm/kg). Addition of 2 mM K+ resulted in identical K+ influx irrespective from the presence or absence of sodium in the bath solution (n = 7; mean ± SD). (D) ISS recorded at −140 mV with oocytes injected with either H2O (gray bars) or DmHAK5 (red bars) in the presence of 100 mM K+ at different pH values (as indicated; n = 5; mean ± SD). Compared with control oocytes, K+ currents increased at pH values ≤5.
	Fig. 5. Biophysical analysis of DmKT1- and DmHAK5-mediated K+ currents at varying extracellular K+ concentrations. (A) Dose–response curve of DmKT1/CBL9/CIPK23-expressing Xenopus oocytes at −140 mV. The ionic strength of the solutions with varying K+ concentrations was adjusted to 100 mM with Li+. The saturation curve could be best fitted with a Michaelis–Menten equation (solid line), documenting a Km value of 108.29 ± 7.34 mM for DmKT1 (n = 5; mean ± SD). (B) Dose–response curve of DmHAK5/CBL9/CIPK23-expressing Xenopus oocytes clamped to a membrane potential of −140 mV. The Michaelis–Menten fit revealed a Km value of 127.38 ± 2.77 µM for DmHAK5 (n = 6; mean ± SD). (C) GK/V relationship of DmKT1-expressing oocytes in a K+ concentration range from 100 to 5 mM. Data points were normalized to GK at −140 mV in 100 mM K+ and fitted with a Boltzmann function. Decreasing the potassium concentration leads to a reduction in the cord conductance but not a change of the voltage dependence of the relative open probability (see also Fig. S5B) (n = 5; mean ± SD). (D) The relative maximal cord conductance was calculated with the equation: GK−max = GK−max(X mM)/GK−max (100 mM). Data points were plotted against the applied K+ concentration and fitted with a Michaelis–Menten equation. Note that GK−max increased with increasing potassium concentrations with a half-maximal activity (K0.5) of 34 mM (n = 5 ± SD).

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