SUMMARY Dietary potassium deficiency, common in Western diets, raises blood pressure and enhances salt sensitivity. Potassium homeostasis requires a molecular switch in the distal convoluted tubule (DCT), which fails in familial hyperkalemic hypertension (pseudohypoaldosteronism type 2), activating the thiazide-sensitive NaCl cotransporter, NCC. Here, we show that dietary potassium deficiency activates NCC, even in the setting of high salt intake, thereby causing sodium retention and a rise in blood pressure. The effect is dependent on plasma potassium, which modulates DCT cell membrane voltage and, in turn, intracellular chloride. Low intracellular chloride stimulates WNK kinases to activate NCC, limiting potassium losses, even at the expense of increased blood pressure. These data show that DCT cells, like adrenal cells, sense potassium via membrane voltage. In the DCT, hyperpolarization activates NCC via WNK kinases, whereas in the adrenal gland, it inhibits aldosterone secretion. These effects work in concert to maintain potassium homeostasis.
The renal phenotype induced by loss-of-function mutations of inwardly rectifying potassium channel (Kir), Kcnj10 (Kir4.1), includes salt wasting, hypomagnesemia, metabolic alkalosis and hypokalemia. However, the mechanism by which Kir.4.1 mutations cause the tubulopathy is not completely understood. Here we demonstrate that Kcnj10 is a main contributor to the basolateral K conductance in the early distal convoluted tubule (DCT1) and determines the expression of the apical Na-Cl cotransporter (NCC) in the DCT. Immunostaining demonstrated Kcnj10 and Kcnj16 were expressed in the basolateral membrane of DCT, and patch-clamp studies detected a 40-pS K channel in the basolateral membrane of the DCT1 of p8/p10 wild-type Kcnj10 +/+ mice (WT). This 40-pS K channel is absent in homozygous Kcnj10 −/− (knockout) mice. The disruption of Kcnj10 almost completely eliminated the basolateral K conductance and decreased the negativity of the cell membrane potential in DCT1. Moreover, the lack of Kcnj10 decreased the basolateral Cl conductance, inhibited the expression of Ste20-related proline-alanine-rich kinase and diminished the apical NCC expression in DCT. We conclude that Kcnj10 plays a dominant role in determining the basolateral K conductance and membrane potential of DCT1 and that the basolateral K channel activity in the DCT determines the apical NCC expression possibly through a Ste20-related proline-alanine-rich kinasedependent mechanism. SeSAME/EAST syndrome | Kir.5.1 | SPAK | WNK T he distal convoluted tubule (DCT) of the kidney is responsible for the absorption of 5% of the filtered NaCl load and plays an important role in the reabsorption of Ca 2+ and Mg 2+
Background: KCNJ10 is a key component of the basolateral K channels in DCT. Results: SFK phosphorylates KCNJ10 at Tyr
The aim of the present study is to examine the role of Kcnj10 (Kir.4.1) in contributing to the basolateral K conductance in the cortical thick ascending limb (cTAL) using Kcnj10+/+ wild-type (WT) and Kcnj10−/− knockout (KO) mice. The patch-clamp experiments detected a 40- and an 80-pS K channel in the basolateral membrane of the cTAL. Moreover, the probability of finding the 40-pS K was significantly higher in the late part of the cTAL close to the distal convoluted tubule than those in the initial part. Immunostaining showed that Kcnj10 staining was detected in the basolateral membrane of the cTAL but the expression was not uniformly distributed. The disruption of Kcnj10 completely eliminated the 40-pS K channel but not the 80-pS K channel, suggesting the role of Kcnj10 in forming the 40-pS K channel of the cTAL. Also, the disruption of Kcnj10 increased the probability of finding the 80-pS K channel in the cTAL, especially in the late part of the cTAL. Because the channel open probability of the 80-pS K channel in KO was similar to those of WT mice, the increase in the 80-pS K channel may be achieved by increasing K channel number. The whole cell recording further showed that K reversal potential measured with 5 mM K in the bath and 140 mM K in the pipette was the same in the WT and KO mice. Moreover, Western blot and immunostaining showed that the disruption of Kcnj10 did not affect the expression of Na-K-Cl cotransporter 2 (NKCC2). We conclude that Kir.4.1 is expressed in the basolateral membrane of cTAL and that the disruption of Kir.4.1 has no significant effect on the membrane potential of the cTAL and NKCC2 expression.
tributed to cell maintenance. LA, UIS, and JSM designed and performed high-throughput screening assays. MP synthesized compounds. CZ and WW performed and analyzed electrophysiology. ENR performed qPCR analysis and ELISAs. UIS and BIK performed Kirby-Bauer disk-diffusion assays. UIS prepared figures and tables. UIS and RPL wrote and edited the main text and supplemental data. UIS, DH, JSM, WW, and RPL oversaw parts of the project or had advisory roles.
PURPOSE. The aim of the study was to test the hypotheses that injury stimulates the expression of miR-205, which in turn inhibits KCNJ10 channels by targeting its 3 0 UTR, thereby facilitating the wound-healing process in human corneal epithelial cells (HCECs). METHODS.A stem-loop qRT-PCR was used to examine the miR-205 expression. BrdU cell proliferation assay and wound scratch assay were applied to measure the effect of miR-205 mimic or antagomer in HCECs. The patch-clamp technique, dual luciferase reporter assay, and Western blot analysis were employed to test whether miR-205 regulates KCNJ10, one of the target genes of miR-205. Both of the primary human and mouse corneal epithelial cells (pH/ MCECs) were employed to further confirm the observations obtained in HCECs. CONCLUSIONS. miR-205 stimulates wound healing by inhibiting its target gene KCNJ10.
Kcnj10 encodes the inwardly rectifying K(+) channel 4.1 (Kir4.1) and is expressed in the basolateral membrane of late thick ascending limb, distal convoluted tubule (DCT), connecting tubule (CNT), and cortical collecting duct (CCD). In the present study, we perform experiments in postneonatal day 9 Kcnj10(-/-) or wild-type mice to examine the role of Kir.4.1 in contributing to the basolateral K(+) conductance in the CNT and CCD, and to investigate whether the disruption of Kir4.1 upregulates the expression of the epithelial Na(+) channel (ENaC). Immunostaining shows that Kir4.1 is expressed in the basolateral membrane of CNT and CCD. Patch-clamp studies detect three types of K(+) channels (23, 40, and 60 pS) in the basolateral membrane of late CNT and initial CCD in wild-type (WT) mice. However, only 23- and 60-pS K(+) channels but not the 40-pS K(+) channel were detected in Kcnj10(-/-) mice, suggesting that Kir.4.1 is a key component of the 40-pS K(+) channel in the CNT/CCD. Moreover, the depletion of Kir.4.1 did not increase the probability of finding the 23- and 60-pS K(+) channel in the CNT/CCD. We next used the perforated whole cell recording to measure the K(+) reversal voltage in the CNT/CCD as an index of cell membrane potential. Under control conditions, the K(+) reversal potential was -69 mV in WT mice and -61 mV in Kcnj10(-/-) mice, suggesting that Kir4.1 partially participates in generating membrane potential in the CNT/CCD. Western blotting and immunostaining showed that the expression of ENaCβ and ENaCγ subunits from a renal medulla section of Kcnj10(-/-) mice was significantly increased compared with that of WT mice. Also, the disruption of Kir4.1 increased aquaporin 2 expression. We conclude that Kir4.1 is expressed in the CNT and CCD and partially participates in generating the cell membrane potential. Also, increased ENaC expression in medullary CD of Kcnj10(-/-) mice is a compensatory action in response to the impaired Na(+) transport in the DCT.
We used the perforated whole-cell recording technique to examine the effect of With-No-Lysine Kinase 4 (WNK4) on the Ca2+ activated big-conductance K channels (BK) in HEK293T cells transfected with BK–α subunit (BK-α). Expression of WNK4 inhibited BK channels and decreased the outward K currents. Coexpression of SGK1 abolished the inhibitory effect of WNK4 on BK channels and restored the outward K currents. Expression of WNK4S1169D//1196D, in which both SGK1-phosphorylation sites (serine 1169 and 1196) were mutated to aspartate, had no effect on BK channels. Moreover, coexpression of SGK1 had no additional effect on K currents in the cells transfected with BKα + WNK4 S1169D//1196D, suggesting that SGK1 reversed WNK4-induced inhibition of BK channels by stimulating WNK4 phosphorylation. Expression of WNK4 but not WNK4 S1169D//1196D increased the phosphorylation of ERK and p38 mitogen-activated protein kinase (MAPK); an effect was abolished by coexpression of SGK1. The role of ERK and p38 MAPK in mediating the effect of WNK4 on BK channels was further suggested by the finding that inhibition of ERK and P38 MAPK completely abolished the inhibitory effect of WNK4 on BK channels. In contrast, inhibition of MAPK failed to abolish the inhibitory effect of WNK4 on ROMK channels in both HEK cells and Xenopus oocytes. Expression of dominant negative dynaminK44A (DynK44A) or treatment of the cells with dynasore, a dynamin inhibitor, not only increased K currents but also largely abolished the inhibitory effect of WNK4 on BK channels. However, inhibition of MAPK still increased the outward K currents in the cells transfected with BKα+WNK4 and treated with dynasore. Similar results were obtained in experiments performed in the native tissue in which inhibition of ERK and p38 MAPK increased BK channel activity in the cortical collecting duct (CCD) treated with dynasore. We concluded that WNK4 inhibited BK channels by stimulating ERK and p38 MAPK and that activation of MAPK by WNK4 may inhibit BK channels partially via a mechanism other than stimulating endocytosis.
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