Permeation properties of inward-rectifier potassium channels and their molecular determinants

The structural domains contributing to ion permeation and selectivity in K channels were examined in inward-rectifier K(+) channels ROMK2 (Kir1.1b), IRK1 (Kir2.1), and their chimeras using heterologous expression in Xenopus oocytes. Patch-clamp recordings of single channels were obtained in the cell-attached mode with different permeant cations in the pipette. For inward K(+) conduction, replacing the extracellular loop of ROMK2 with that of IRK1 increased single-channel conductance by 25 pS (from 39 to 63 pS), whereas replacing the COOH terminus of ROMK2 with that of IRK1 decreased conductance by 16 pS (from 39 to 22 pS). These effects were additive and independent of the origin of the NH(2) terminus or transmembrane domains, suggesting that the two domains form two resistors in series. The larger conductance of the extracellular loop of IRK1 was attributable to a single amino acid difference (Thr versus Val) at the 3P position, three residues in front of the GYG motif. Permeability sequences for the conducted ions were similar for the two channels: Tl(+) > K(+) > Rb(+) > NH(4)(+). The ion selectivity sequence for ROMK2 based on conductance ratios was NH(4)(+) (1.6) > K(+) (1) > Tl(+) (0.5) > Rb(+) (0.4). For IRK1, the sequence was K(+) (1) > Tl(+) (0.8) > NH(4)(+) (0.6) > Rb(+) (0.1). The difference in the NH(4)(+)/ K(+) conductance (1.6) and permeability (0.09) ratios can be explained if NH(4)(+) binds with lower affinity than K(+) to sites within the pore. The relatively low conductances of NH(4)(+) and Rb(+) through IRK1 were again attributable to the 3P position within the P region. Site-directed mutagenesis showed that the IRK1 selectivity pattern required either Thr or Ser at this position. In contrast, the COOH-terminal domain conferred the relatively high Tl(+) conductance in IRK1. We propose that the P-region and the COOH terminus contribute independently to the conductance and selectivity properties of the pore.     

The acidic motif of WNK4 is crucial for its interaction with the K channel ROMK

WNK kinases have rapidly emerged as important regulators of Na⁺ and K⁺ homoeostasis in the mammalian kidney where they regulate the trafficking of proteins such as the NaCl-cotransporter (NCCT) and K⁺ channel, ROMK. However, an increasing number of WNK effects are kinase-independent, including their interaction with ROMK, and involve instead protein-protein interactions. Outside of their kinase domain all WNKs contain a unique run of predominantly negatively charged amino acids dubbed the acidic motif, where the WNK4 disease mutations causing Gordon’s syndrome also cluster. To look further at the role of this motif we studied the effects of WNK4 fragments, including one with a deleted acidic motif (ΔAM) and a 10-mer acidic motif peptide on ROMK expression in Xenopus oocytes. We found that an N-terminal fragment of WNK4 (1-620 WNK4) containing the acidic motif retains full activity in inhibiting ROMK currents. However, ΔAM WNK4 is completely inactive and the effect of WNK4 or 1-620 WNK4 can be completely blocked by co-injection of the 10-mer acidic motif peptide. The blocking action of the peptide was sequence specific as a peptide with a randomised sequence was inactive. These results on ROMK currents were paralleled by changes in membrane expression of fluorescent EGFP-ROMK. Finally, we show that 1-620 WNK4 can pull down ROMK and this interaction can be blocked with the acidic motif peptide. These results confirm the important role of the acidic motif of WNK4 in its protein-protein interaction with the ROMK channel.     

Gating Properties of Inward-Rectifier Potassium Channels: Effects of Permeant Ions

Two inward-rectifier K⁺ channels, ROMK2 (Kir1.1b) and IRK1 (Kir2.1), were expressed in Xenopus oocytes and their gating properties were studied in cell-attached membrane patches. The gating properties depended strongly on the ion being conducted (K⁺, NH₄ ⁺, Rb⁺, or Tl⁺), suggesting tight coupling between permeation and gating. Mean open times were strongly dependent on the nature of the conducted ion. For ROMK2 the order from the longest to the shortest times was K⁺ > Rb⁺ > Tl⁺ > NH₄ ⁺. For IRK1 the sequence was K⁺ > NH₄ ⁺ > Tl⁺. In both cases the open times decreased monotonically as the membrane voltage was hyperpolarized. Both the absolute values and the voltage dependence of closed times were dependent on the conducted species. ROMK2 showed a single closed state whose mean lifetimes were biphasic functions of voltage. The maxima were at various voltages for different ions. IRK1 had at least two closed states whose lifetimes decreased monotonically with K⁺, increased monotonically with Tl⁺, and were relatively constant with NH₄ ⁺ as the conducted ion. We explain the ion-dependence of gating by assuming that the ions bind to a site within the permeation pathway, resulting in a stable, ion-dependent, closed state of the channel. The patterns of voltage-dependence of closed-state lifetimes, which are specific for different ions, can be explained by variations in the rate at which the bound ions leave the pore toward the inside or the outside of the cell. Received: 18 April 2001/Revised: 28 June 2001     

Concerted actions of NHERF2 and WNK4 in regulating TRPV5

With-no-lysine (K) kinase 4 (WNK4) is a protein serine/threonine kinase associated with a Mendelian form of hypertension. WNK4 is an integrative regulator of renal transport of Na⁺, K⁺, and Cl⁻ as shown in Xenopus oocyte system. In addition, WNK4 enhances the surface expression of epithelial Ca²⁺ channel TRPV5, which plays a key role in the fine tuning of renal Ca²⁺ reabsorption. Variations in the magnitude of WNK4-mediated regulation on TRPV5 in Xenopus oocytes suggest additional cellular components with limited expression are required for the regulation. In this study, we identified the Na⁺/H⁺ exchanger regulating factor 2 (NHERF2) as a critical component for the positive regulation of TRPV5 by WNK4. NHERF2 augmented the positive effect of WNK4 on TRPV5, whereas its homolog NHERF1 had no effect when tested in the Xenopus oocyte system. The C-terminal PDZ binding motif of TRPV5 was required for the regulation by NHERF2. While NHERF2 interacted with TRPV5, no association between NHERF2 and WNK4 was detected using a GST pull-down assay. WNK4 increased the forward trafficking of TRPV5; however, it also caused an accelerated decline of the functional TRPV5 channels at later stage of co-expression. NHERF2 stabilized TRPV5 at the plasma membrane without interrupting the forward trafficking of TRPV5, thus prevented the decline of functional TRPV5 channel caused by WNK4 at later stage. The complementary and orderly regulations of WNK4 and NHERF2 allow TRPV5 functions at higher level for a longer period to maximize Ca²⁺ influx.     

Regulation of Kir channels by intracellular pH and extracellular K(+): mechanisms of coupling

ROMK channels are regulated by internal pH (pH(i)) and extracellular K(+) (K(+)(o)). The mechanisms underlying this regulation were studied in these channels after expression in Xenopus oocytes. Replacement of the COOH-terminal portion of ROMK2 (Kir1.1b) with the corresponding region of the pH-insensitive channel IRK1 (Kir 2.1) produced a chimeric channel (termed C13) with enhanced sensitivity to inhibition by intracellular H(+), increasing the apparent pKa for inhibition by approximately 0.9 pH units. Three amino acid substitutions at the COOH-terminal end of the second transmembrane helix (I159V, L160M, and I163M) accounted for these effects. These substitutions also made the channels more sensitive to reduction in K(+)(o), consistent with coupling between the responses to pH(i) and K(+)(o). The ion selectivity sequence of the activation of the channel by cations was K(+) congruent with Rb(+) > NH(4)(+) > Na(+), similar to that for ion permeability, suggesting an interaction with the selectivity filter. We tested a model of coupling in which a pH-sensitive gate can close the pore from the inside, preventing access of K(+) from the cytoplasm and increasing sensitivity of the selectivity filter to removal of K(+)(o). We mimicked closure of this gate using positive membrane potentials to elicit block by intracellular cations. With K(+)(o) between 10 and 110 mM, this resulted in a slow, reversible decrease in conductance. However, additional channel constructs, in which inward rectification was maintained but the pH sensor was abolished, failed to respond to voltage under the same conditions. This indicates that blocking access of intracellular K(+) to the selectivity filter cannot account for coupling. The C13 chimera was 10 times more sensitive to extracellular Ba(2+) block than was ROMK2, indicating that changes in the COOH terminus affect ion binding to the outer part of the pore. This effect correlated with the sensitivity to inactivation by H(+). We conclude that decreasing pH(I) increases the sensitivity of ROMK2 channels to K(+)(o) by altering the properties of the selectivity filter.     

The design and synthesis of novel spirocyclic heterocyclic sulfone ROMK inhibitors as diuretics

A spirocyclic class of ROMK inhibitors was developed containing a structurally diverse heterocyclic sulfone moiety and spirocyclic core starting from lead 1. These compounds not only displayed exquisite ROMK potency but significantly improved selectivity over hERG. The lead compounds were found to have favorable pharmacokinetic properties and displayed robust diuretic, natriuretic and blood pressure lowering effects in spontaneously hypertensive rats.     

Permeation and Gating of an Inwardly Rectifying Potassium Channel : Evidence for a Variable Energy Well

Permeation, gating, and their interrelationship in an inwardly rectifying potassium (K⁺) channel, ROMK2, were studied using heterologous expression in Xenopus oocytes. Patch-clamp recordings of single channels were obtained in the cell-attached mode. The gating kinetics of ROMK2 were well described by a model having one open and two closed states. One closed state was short lived (∼1 ms) and the other was longer lived (∼40 ms) and less frequent (∼1%). The long closed state was abolished by EDTA, suggesting that it was due to block by divalent cations. These closures exhibit a biphasic voltage dependence, implying that the divalent blockers can permeate the channel. The short closures had a similar biphasic voltage dependence, suggesting that they could be due to block by monovalent, permeating cations. The rate of entering the short closed state varied with the K⁺ concentration and was proportional to current amplitude, suggesting that permeating K⁺ ions may be related to the short closures. To explain the results, we propose a variable intrapore energy well model in which a shallow well may change into a deep one, resulting in a normally permeant K⁺ ion becoming a blocker of its own channel.     

Expression of the potassium channel ROMK in adult and fetal human kidney

The renal potassium channel ROMK is a crucial element of K⁺ recycling and secretion in the distal tubule and the collecting duct system. Mutations in the ROMK gene (KCNJ1) lead to hyperprostaglandin E syndrome/antenatal Bartter syndrome, a life-threatening hypokalemic disorder of the newborn. The localization of ROMK channel protein, however, remains unknown in humans. We generated an affinity-purified specific polyclonal anti-ROMK antibody raised against a C-terminal peptide of human ROMK. Immunoblotting revealed a 45 kDa protein band in both rat and human kidney tissue. In human kidney sections, the antibody showed intense staining of epithelial cells in the cortical and medullary thick ascending limb (TAL), the connecting tubule, and the collecting duct. Moreover, a strong expression of ROMK protein was detected in cells of the macula densa. In epithelial cells of the TAL expression of ROMK protein was mainly restricted to the apical membrane. In human fetal kidney expression of ROMK protein was detected mainly in distal tubules of mature nephrons but not or only marginally in the collecting system. No expression was found in early developmental stages such as comma or S shapes, indicating a differentiation-dependent expression of ROMK protein. In summary, these findings support the proposed role of ROMK channels in potassium recycling and in the regulation of K⁺ secretion and present a rationale for the phenotype observed in patients with ROMK deficiency.