Henry Sackin

A conserved cytoplasmic region of ROMK modulates pH sensitivity, conductance, and gating

ROMK channels play a key role in overall K balance by controlling K secretion across the apical membrane of mammalian cortical collecting tubule. In contrast to the family of strong inward rectifiers (IRKs), ROMK channels are markedly sensitive to intracellular pH. Using Xenopus oocytes, we have confirmed this pH sensitivity at both the single-channel and whole cell level. Reduction of oocyte pH from 6.8 to 6.4 (using a permeant acetate buffer) reduced channel open probability from 0.76 +/- 0.02 to near zero (n = 8), without altering single-channel conductance. This was due to the appearance of a long-lived closed state at low internal pH. We have confirmed that a lysine residue (K61 on ROMK2; K80 on ROMK1), NH2 terminal to the first putative transmembrane segment (M1), is primarily responsible for conferring a steep pH sensitivity to ROMK (B. Fakler, J. Schultz, J. Yang, U. Schulte, U. Bråandle, H. P. Zenner, L. Y. Jan, and J. P. Ruppersberg. EMBO J. 15: 4093-4099, 1996). However, the apparent pKa of ROMK also depends on another residue in a highly conserved, mildly hydrophobic area: T51 on ROMK2 (T70 on ROMK1). Replacing this neutral threonine (T51) with a negatively charged glutamate shifted the apparent pKa for inward conductance from 6.5 +/- 0.01 (n = 8, wild type) to 7.0 +/- 0.02 (n = 5, T51E). On the other hand, replacing T51 with a positively charged lysine shifted the apparent pKa in the opposite direction, from 6.5 +/- 0.01 (n = 8, wild type) to 6.0 +/- 0.02 (n = 9, T51K). The opposite effects of the glutamate and lysine substitutions at position 51 (ROMK2) are consistent with a model in which T51 is physically close to K61 and alters either the local pH or the apparent pKa via an electrostatic mechanism. In addition to its effects on pH sensitivity, the mutation T51E also decreased single-channel conductance from 34.0 +/- 1.0 pS (n = 8, wild type) to 17.4 +/- 1 pS (n = 9, T51E), reversed the voltage gating of the channel, and significantly increased open-channel noise. These effects on single-channel currents suggest that the T51 residue, located in a mildly hydrophobic area of ROMK2, also interacts with the hydrophobic region of the permeation pathway.ROMK channels play a key role in overall K balance by controlling K secretion across the apical membrane of mammalian cortical collecting tubule. In contrast to the family of strong inward rectifiers (IRKs), ROMK channels are markedly sensitive to intracellular pH. Using Xenopus oocytes, we have confirmed this pH sensitivity at both the single-channel and whole cell level. Reduction of oocyte pH from 6.8 to 6.4 (using a permeant acetate buffer) reduced channel open probability from 0.76 ± 0.02 to near zero ( n = 8), without altering single-channel conductance. This was due to the appearance of a long-lived closed state at low internal pH. We have confirmed that a lysine residue (K61 on ROMK2; K80 on ROMK1), NH2 terminal to the first putative transmembrane segment (M1), is primarily responsible for conferring a steep pH sensitivity to ROMK (B. Fakler, J. Schultz, J. Yang, U. Schulte, U. Bråandle, H. P. Zenner, L. Y. Jan, and J. P. Ruppersberg. EMBO J. 15: 4093-4099, 1996). However, the apparent p K a of ROMK also depends on another residue in a highly conserved, mildly hydrophobic area: T51 on ROMK2 (T70 on ROMK1). Replacing this neutral threonine (T51) with a negatively charged glutamate shifted the apparent p K a for inward conductance from 6.5 ± 0.01 ( n = 8, wild type) to 7.0 ± 0.02 ( n = 5, T51E). On the other hand, replacing T51 with a positively charged lysine shifted the apparent p K a in the opposite direction, from 6.5 ± 0.01 ( n = 8, wild type) to 6.0 ± 0.02 ( n = 9, T51K). The opposite effects of the glutamate and lysine substitutions at position 51 (ROMK2) are consistent with a model in which T51 is physically close to K61 and alters either the local pH or the apparent p K a via an electrostatic mechanism. In addition to its effects on pH sensitivity, the mutation T51E also decreased single-channel conductance from 34.0 ± 1.0 pS ( n = 8, wild type) to 17.4 ± 1 pS ( n = 9, T51E), reversed the voltage gating of the channel, and significantly increased open-channel noise. These effects on single-channel currents suggest that the T51 residue, located in a mildly hydrophobic area of ROMK2, also interacts with the hydrophobic region of the permeation pathway.

Regulation of Na+ channels by luminal Na+ in rat cortical collecting tubule

1 The idea that luminal Na+ can regulate epithelial Na+ channels was tested in the cortical collecting tubule of the rat using whole‐cell and single‐channel recordings. Here we report results consistent with the idea of Na+ self‐inhibition. 2 Macroscopic amiloride‐sensitive currents (INa) were measured by conventional whole‐cell clamp. INa was a saturable function of external Na+ concentration ([Na+]o) with an apparent Km of 9 mm. Single channel currents (iNa) were measured in cell‐attached patches. iNa increased with pipette Na+ concentration with an apparent Km of 48 mm. Since INa= (iNa)NPo, the different Km values imply that the channel density (N) and/or open probability (Po) increase as [Na+]o decreases. Reduction of [Na+]o after increasing intracellular Na+ concentration also increased the outward amiloride‐sensitive conductance, consistent with activation of the Na+ channels. 3 The underlying mechanism was studied by changing pipette Na+ concentration while recording from cell‐attached patches. No increase in NPo was observed, suggesting that the effect is not a direct interaction between [Na+]o and the channel. 4 [Na+]o was varied outside the patch‐clamp pipette while recording from cell‐attached patches. When amiloride was in the bath to prevent Na+ entry, no change in NPo was observed. 5 Activation of the channels by hyperpolarization was observed with 140 mm Na+o but not with 14 mm Na+o. 6 The results are consistent with the concept of self‐inhibition of Na+ channels by luminal Na+. Activation of the channels by lowering [Na+]o is not additive with that achieved by hyperpolarization.

Selective Inhibition of the Kir2 Family of Inward Rectifier Potassium Channels by a Small Molecule Probe: The Discovery, SAR, and Pharmacological Characterization of ML133

The K(ir) inward rectifying potassium channels have a broad tissue distribution and are implicated in a variety of functional roles. At least seven classes (K(ir)1-K(ir)7) of structurally related inward rectifier potassium channels are known, and there are no selective small molecule tools to study their function. In an effort to develop selective K(ir)2.1 inhibitors, we performed a high-throughput screen (HTS) of more than 300,000 small molecules within the MLPCN for modulators of K(ir)2.1 function. Here we report one potent K(ir)2.1 inhibitor, ML133, which inhibits K(ir)2.1 with an IC(50) of 1.8 μM at pH 7.4 and 290 nM at pH 8.5 but exhibits little selectivity against other members of Kir2.x family channels. However, ML133 has no effect on K(ir)1.1 (IC(50) > 300 μM) and displays weak activity for K(ir)4.1 (76 μM) and K(ir)7.1 (33 μM), making ML133 the most selective small molecule inhibitor of the K(ir) family reported to date. Because of the high homology within the K(ir)2 family-the channels share a common design of a pore region flanked by two transmembrane domains-identification of site(s) critical for isoform specificity would be an important basis for future development of more specific and potent K(ir) inhibitors. Using chimeric channels between K(ir)2.1 and K(ir)1.1 and site-directed mutagenesis, we have identified D172 and I176 within M2 segment of K(ir)2.1 as molecular determinants critical for the potency of ML133 mediated inhibition. Double mutation of the corresponding residues of K(ir)1.1 to those of K(ir)2.1 (N171D and C175I) transplants ML133 inhibition to K(ir)1.1. Together, the combination of a potent, K(ir)2 family selective inhibitor and identification of molecular determinants for the specificity provides both a tool and a model system to enable further mechanistic studies of modulation of K(ir)2 inward rectifier potassium channels.

Dissociation of K channel density and ROMK mRNA in rat cortical collecting tubule during K adaptation

The density of conducting K channels in the apical membrane of the rat cortical collecting tubule (CCT) is increased by a high-K diet. To see whether this involved increased abundance of mRNA coding for K channel protein, we measured the relative amounts of mRNA for ROMK, the clone of the gene thought to encode the secretory K channel in the CCT. Tubules were isolated and fixed for in situ hybridization with a probe based on the ROMK sequence. Radiolabeled probe associated with the tubule was quantified using densitometric analysis of the autoradiographic images of the tubules. The densitometry signal was shown to be proportional to the amount of radioactive probe in the sample and to the time of exposure of the film. The technique was able to detect an approximately twofold increase in the abundance of mRNA coding for the water channel aquaporin 3 (AQP3), in response to a 30-h dehydration period. Tubules from rats fed a normal diet or a high-K (10% KCl) diet had equal amounts of ROMK mRNA. This suggests that an increase in the abundance of mRNA does not underlie the increase in channel density observed under these conditions.

Gating properties of inward-rectifier potassium channels: effects of permeant ions.

Abstract. 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.

Permeant cations and blockers modulate pH gating of ROMK channels.

External potassium (K) activates the inward rectifier ROMK (K(ir)1.1) by altering the pH gating of the channel. The present study examines this link between external K and internal pH sensitivity using both the two-electrode voltage clamp and the perfused, cut-open Xenopus oocyte preparation. Elevating extracellular K from 1 mM to 10 mM to 100 mM activated ROMK channels by shifting their apparent pK(a) from 7.2 +/- 0.1 (n = 6) in 1 mM K, to 6.9 +/- 0.02 (n = 5) in 10 mM K, and to 6.6 +/- 0.03 (n = 5) in 100 mM K. At any given internal pH, the number of active ROMK channels is a saturating function of external [K]. Extracellular Cs (which blocks almost all inward K current) also stimulated outward ROMK conductance (at constant 1 mM external K) by shifting the apparent pK(a) of ROMK from 7.2 +/- 0.1 (n = 6) in 1 mM K to 6.8 +/- 0.01 (n = 4) in 1 mM K + 104 mM Cs. Surprisingly, the binding and washout of the specific blocker, Tertiapin-Q, also activated ROMK in 1 mM K and caused a comparable shift in apparent pK(a). These results are interpreted in terms of both a three-state kinetic model and a two-gate structural model that is based on results with KcsA in which the selectivity filter can assume either a high or low K conformation. In this context, external K, Cs, and Tertiapin-Q activate ROMK by destabilizing the low-K (collapsed) configuration of the selectivity filter.

Regulation of ROMK by Extracellular Cations

The effect of external potassium (K) and cesium (Cs) on the inwardly rectifying K channel ROMK2 (K(ir)1.1b) was studied in Xenopus oocytes. Elevating external K from 1 to 10 mM increased whole-cell outward conductance by a factor of 3.4 +/- 0.4 in 15 min and by a factor of 5.7 +/- 0.9 in 30 min (n = 22). Replacing external Na by Cs blocked inward conductance but increased whole-cell conductance by a factor of 4.5 +/- 0.5 over a period of 40 min (n = 15). In addition to this slow increase in conductance, there was also a small, rapid increase in conductance that occurred as soon as ROMK was exposed to external cesium or 10 mM K. This rapid increase could be explained by the observed increase in ROMK single-channel conductance from 6.4 +/- 0.8 pS to 11.1 +/- 0.8 pS (10 mM K, n = 8) or 11.7 +/- 1.2 pS (Cs, n = 8). There was no effect of either 10 mM K or cesium on the high open probability (P(o) = 0.97 +/- 0.01; n = 12) of ROMK outward currents. In patch-clamp recordings, the number of active channels increased when the K concentration at the outside surface was raised from 1 to 50 mM K. In cell-attached patches, exposure to 50 mM external K produced one or more additional channels in 9/16 patches. No change in channel number was observed in patches continuously exposed to 50 mM external K. Hence, the slow increase in whole-cell conductance is interpreted as activation of pre-existing ROMK channels that had been inactivated by low external K. This type of time-dependent channel activation was not seen with IRK1 (K(ir)2.1) or in ROMK2 mutants in which any one of 6 residues, F129, Q133, E132, V121, L117, or K61, were replaced by their respective IRK1 homologs. These results are consistent with a model in which ROMK can exist in either an activated mode or an inactivated mode. Within the activated mode, individual channels undergo rapid transitions between open and closed states. High (10 mM) external K or Cs stabilizes the activated mode, and low external K stabilizes the inactivated mode. Mutation of a pH-sensing site (ROMK2-K61) prevents transitions from activated to inactivated modes. This is consistent with a direct effect of external K or Cs on the gating of ROMK by internal pH.

Regulation of Kir Channels by Intracellular pH and Extracellular K+: Mechanisms of Coupling

ROMK channels are regulated by internal pH (pHi) 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 ∼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 pHi and K+ o. The ion selectivity sequence of the activation of the channel by cations was K+ ≅ Rb+ > NH4 + >> 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 Ba2+ 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 pHI increases the sensitivity of ROMK2 channels to K+ o by altering the properties of the selectivity filter.

An intersubunit salt bridge near the selectivity filter stabilizes the active state of Kir1.1.

ROMK (Kir1.1) potassium channels are closed by internal acidification with a pKa of 6.7 +/- 0.01 in 100 mM external K and a pKa of 7.0 +/- 0.01 in 1 mM external K. Internal acidification in 1 mM K (but not 100 mM K) not only closed the pH gate but also inactivated Kir1.1, such that realkalization did not restore channel activity until high K was returned to the bath. We identified a new putative intersubunit salt bridge (R128-E132-Kir1.1b) in the P-loop of the channel near the selectivity filter that affected the K sensitivity of the inactivation process. Mutation of either R128-Kir1.1b or E132-Kir1.1b caused inactivation in both 1 mM and 100 mM external K during oocyte acidification. However, 300 mM external K (but not 200 mM Na + 100 mM K) protected both E132Q and R128Y from inactivation. External application of a modified honey-bee toxin, tertiapin Q (TPNQ), also protected Kir1.1 from inactivation in 1 mM K and protected E132Q and R128Y from inactivation in 100 mM K, which suggests that TPNQ binding to the outer mouth of the channel stabilizes the active state. Pretreatment of Kir1.1 with external Ba prevented Kir1.1 inactivation, similar to pretreatment with TPNQ. In addition, mutations that disrupted transmembrane helix H-bonding (K61M-Kir1.1b) or stabilized a selectivity filter to helix-pore linkage (V121T-Kir1.1b) also protected both E132Q and R128Y from inactivation in 1 mM K and 100 mM K. Our results are consistent with Kir inactivation arising from conformational changes near the selectivity filter, analogous to C-type inactivation.

Regulation of renal ion channels.

Ion channels in renal epithelia are involved in maintenance of the volume and ion composition of the epithelial cells themselves and of the entire organism. The latter function depends on transepithelial ion transport, a process that often involves ion channels at the apical (luminal) and/or the basolateral (contraluminal) cell membranes. Regulation of these channels is accomplished within many different time frames, each of which can involve different molecular mechanisms of regulation. Changes in membrane voltage, intracellular ion composition, or mechanical force on the membrane mediate short‐term regulation. Biosynthesis, degradation, and reversible transfer of channels to or from cytoplasmic stores are responsible for longer term regulation. Covalent modification of channel proteins can be involved in either short‐ or long‐term regulation. In this review we outline the different models of ion channel regulation in renal epithelia and give examples that emphasize the physiological roles of these channels in specific nephron segments.— Palmer, L. G.; Sackin, H. Regulation of renal ion channels. FASEB J. 2: 3061‐3065; 1988.