The renal K+ channel (ROMK2) was expressed in Xenopus oocytes, and the patch-clamp technique was used to assess its conducting and gating properties. In cell-attached patches with 110 mM K+ in the bath and pipette, the reversal potential was near zero and the inward conductance (36 pS) was larger than the outward conductance (17 pS). In excised inside-out patches the channels showed rectification in the presence of 5 mM Mg2+ on the cytoplasmic side but not in Mg(2+)-free solution. Inward currents were also observed when K+ was replaced in the pipette by Rb+, NH4+, or thallium (Tl+). The reversal potentials under these conditions yielded a selectivity sequence of Tl+ > K+ > Rb+ > NH4+. On the other hand, the slope conductances for inward current gave a selectivity sequence of K+ = NH4+ > Tl+ > Rb+. The differences in the two sequences can be explained by the presence of cation binding sites within the channel, which interact with Rb+ and Tl+ more strongly and with NH4+ less strongly than with K+. Two other ions, Ba2+ and Cs+, blocked the channel from the outside. The effect of Ba2+ (1 mM) was to reduce the open probability of the channels, whereas Cs+ (10 mM) reduced the apparent single-channel current. The effects of both blockers are enhanced by membrane hyperpolarization. The kinetics of the channel were also studied in cell-attached patches. With K+ in the pipette the distribution of open times could be described by a single exponential (tau 0 = 25 ms), whereas two exponentials (tau 1 = 1 ms, tau 2 = 30 ms) were required to describe the closed-time distribution. Hyperpolarization of the oocyte membrane decreased the open probability and tau 0, and increased tau 1, tau 2, and the number of long closures. The presence of Tl+ in the pipette significantly altered the kinetics, reducing tau 0 and eliminating the long-lived closures. These results suggest that the gating of the channel may depend on the nature of the ion in the pore.
The sequence of the hydrophobic "P" (pore) region of a K(+)-selective channel from the kidney (ROMK2) was altered to match that of the closely related inward rectifier (IRK1) channel by changing two amino acids, leucine (L) 117 and valine (V) 121, to isoleucine (I) and threonine (T), respectively. The mutant channel expressed in Xenopus laevis oocytes had an apparent inhibition constant at zero voltage [Ki(0)] in the presence of Ba2+ of 0.07 +/- 0.01 mM, which was more than 50 times lower than the Ki(0) of the wild-type channel (4.7 +/- 1.0 mM). The increased sensitivity to Ba2+ was accounted for by the point mutation V121T. Single-channel measurements indicated that the increased affinity involved an increase in the on-rate for Ba2+ block and a decrease in the off-rate. Block by Ca+ was also enhanced. The single-channel conductance of the L1171/ V121T mutant was increased by 50%, whereas the degree of inward rectification, ion selectivity, and apparent affinity for K+ were essentially unchanged. When the neutral asparagine residue within the second putative membrane-spanning domain of the ROMK channel was substituted with aspartic acid, the corresponding amino acid in IRK1, the degree of inward rectification was enhanced but Ba2+ block and single-channel inward conductance were unaffected. Thus the site of Ba2+ binding appears to be distinct from the locus of internal Mg2+ block and from at least one of the sites that determines K+ conjuctivity.
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