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Query: UNIPROT:P41181 (
collecting duct
)
5,183
document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)
The serine-threonine kinase WNK3 modulates Cl- transport into and out of cells through its regulation of SLC12A cation/Cl- cotransporters, implicating it as (one of) the long-sought Cl-/volume-sensitive kinase(s). Integrators in homeostatic systems regulate structurally diverse but functionally coupled elements. For example, the related kinase WNK4 regulates the Na-Cl co-transporter (NCC), paracellular Cl- flux, and the K+ channel ROMK1 (Kir1.1) to maintain renal NaCl and K+ homeostasis; mutations in PRKWNK4, encoding WNK4, cause a Mendelian disease featuring hypertension and hyperkalemia. It is known that WNK3 is expressed in the nephron's distal convoluted tubule (DCT) and stimulates NCC activity. Here, we show that WNK3 is also expressed in cortical and outer medullary
collecting duct
principal cells. Accordingly, we tested WNK3's effect on the mediators of NaCl and K+ handling in these nephron segments--the epithelial sodium channel (ENaC), paracellular Cl- flux, and ROMK1--using established model systems. WNK3 did not alter paracellular Cl- flux in tetracycline-responsive MDCK II cells, nor affect amiloride-sensitive currents when co-expressed with ENaC in Xenopus laevis oocytes. However, additional co-expression studies in oocytes revealed WNK3 inhibited the renal-specific K+ channel ROMK1 activity greater than 5.5-fold (p < .0001) by altering its plasmalemmal surface expression; WNK3 did not affect ROMK1's conductance or open/closed probability. In contrast, WNK3 had no effect on the activity of the cardiac long-QT syndrome K+ channel
KCNQ1
/KCNE1 when co-expressed in oocytes. Inhibition of ROMK1 is independent of WNK3's catalytic activity and is mediated by WNK3's carboxyl terminus--a mechanism distinct from its known kinase-dependent activation of NCC. A kinase-inactivating point mutation, or a missense mutation homologous to one in WNK4 that causes disease produced a gain-of-function effect, enhancing WNK3's inhibition of ROMK1 greater than 2.5-fold relative to wild type kinase (p < .0001). The magnitude and specificity of WNK3's effects at both NCC and ROMK1, its co-expression with its targets in the distal nephron, and the established in vivo effect of WNK4 at these same targets provide evidence that WNK3's action is physiologically relevant. WNK3 is likely a component of one of the mechanisms that determines the balance between renal NaCl reabsorption and K+ secretion.
...
PMID:WNK3, a kinase related to genes mutated in hereditary hypertension with hyperkalaemia, regulates the K+ channel ROMK1 (Kir1.1). 1635 11
Mechanisms of K(+) secretion and absorption along the
collecting duct
are not understood fully. Because
KCNQ1
participates in K(+) secretion within the inner ear and stomach, distribution of
KCNQ1
in mouse kidney was studied using Northern and Western analyses, RT-PCR of isolated tubules, and immunohistochemistry. Northern blots demonstrated
KCNQ1
transcripts in whole kidney. RT-PCR showed
KCNQ1
mRNA in isolated distal convoluted tubule (DCT), connecting segment (CNT), collecting ducts (CD), and glomeruli. Immunoblots of kidney and stomach revealed a approximately 75-kDa protein, the expected mobility for
KCNQ1
.
KCNQ1
was detected by immunohistochemistry throughout the distal nephron and CD. Thick ascending limbs exhibited weak basolateral immunolabel. In DCT and CNT cells, immunolabel was intense and basolateral, although
KCNQ1
label was stronger in late than in early DCT. Initial collecting tubule and cortical CD
KCNQ1
immunolabel was predominantly diffuse, but many cells exhibited discrete apical label. Double-labeling experiments demonstrated that principal cells, type B intercalated cells, and a few type A intercalated cells exhibited distinct apical
KCNQ1
immunolabel. In inner medullary CD, principal cells exhibited distinct basolateral
KCNQ1
immunolabel, whereas intercalated cells showed diffuse cytoplasmic staining. Thus
KCNQ1
protein is widely distributed in mouse distal nephron and CD, with significant axial and cellular heterogeneity in location and intensity. These findings suggest that
KCNQ1
has cell-specific roles in renal ion transport and may participate in K(+) secretion and/or absorption along the thick ascending limb, DCT, connecting tubule, and CD.
...
PMID:Cellular distribution of the potassium channel KCNQ1 in normal mouse kidney. 1689 89
The aim of this study was to evaluate
KCNQ1
K+ channel expression in the frog kidney of Rana esculenta.
KCNQ1
K+ channel, also known as KvLQT1, is the pore forming a-subunit of the IKs K+ channel, a delayed rectifier voltage-gated K+ channel, which has an important role in water and salt transport in the kidney and gastrointestinal tract. The expression of
KCNQ1
K+ channel along tubular epithelium differs from species to species. In the present study the expression of
KCNQ1
K+ channel in the frog kidney has been demonstrated by immunohistochemistry. The presence of
KCNQ1
K+ channel was demonstrated in the epithelial cells of distal convoluted tubule and
collecting duct
. However, the pattern of expression of
KCNQ1
K+ channel differs between distal convoluted tubules and
collecting duct
. All epithelial cells of distal convoluted tubules revealed basolateral expression of
KCNQ1
K+ channel. On the contrary, only the single cells of
collecting duct
, probably intercalated cells, showed diffuse cell surface staining with antibodies against
KCNQ1
K+ channel. These findings suggest that
KCNQ1
K+ channel has cell-specific roles in renal potassium ion transport.
...
PMID:Differential expression of KCNQ1 K+ channel in tubular cells of frog kidney. 2035 14
The
KCNQ1
K(+) channel plays a key role in the regulation of several physiological functions, including cardiac excitability, cardiovascular tone, and body electrolyte homeostasis. The metabolic sensor AMP-activated protein kinase (AMPK) has been shown to regulate a growing number of ion transport proteins. To determine whether AMPK regulates
KCNQ1
, we studied the effects of AMPK activation on
KCNQ1
currents in Xenopus laevis oocytes and
collecting duct
epithelial cells. AMPK activation decreased
KCNQ1
currents and channel surface expression in X. laevis oocytes, but AMPK did not phosphorylate
KCNQ1
in vitro, suggesting an indirect regulatory mechanism. As it has been recently shown that the ubiquitin-protein ligase Nedd4-2 inhibits
KCNQ1
plasma membrane expression and that AMPK regulates epithelial Na(+) channels via Nedd4-2, we examined the role of Nedd4-2 in the AMPK-dependent regulation of
KCNQ1
. Channel inhibition by AMPK was blocked in oocytes coexpressing either a dominant-negative or constitutively active Nedd4-2 mutant, or a Nedd4-2 interaction-deficient
KCNQ1
mutant, suggesting that Nedd4-2 participates in the regulation of
KCNQ1
by AMPK.
KCNQ1
is expressed at the basolateral membrane in mouse polarized kidney cortical
collecting duct
(mpkCCD(c14)) cells and in rat kidney. Treatment with the AMPK activators AICAR (2 mM) or metformin (1 mM) reduced basolateral
KCNQ1
currents in apically permeabilized polarized mpkCCD(c14) cells. Moreover, AICAR treatment of rat kidney slices ex vivo induced AMPK activation and intracellular redistribution of
KCNQ1
from the basolateral membrane in
collecting duct
principal cells. AICAR treatment also induced increased ubiquitination of
KCNQ1
immunoprecipitated from kidney slice homogenates. These results indicate that AMPK inhibits
KCNQ1
activity by promoting Nedd4-2-dependent channel ubiquitination and retrieval from the plasma membrane.
...
PMID:AMP-activated protein kinase inhibits KCNQ1 channels through regulation of the ubiquitin ligase Nedd4-2 in renal epithelial cells. 2086 Oct 72
To investigate the contribution of ion channels to ciliogenesis, we carried out a small interfering RNA (siRNA)-based reverse genetics screen of all ion channels in the mouse genome in murine inner medullary
collecting duct
kidney cells. This screen revealed four candidate ion channel genes: Kcnq1, Kcnj10, Kcnf1 and Clcn4. We show that these four ion channels localize to renal tubules, specifically to the base of primary cilia. We report that human
KCNQ1
Long QT syndrome disease alleles regulate renal ciliogenesis;
KCNQ1
-p.R518X, -p.A178T and -p.K362R could not rescue ciliogenesis after Kcnq1-siRNA-mediated depletion in contrast to wild-type
KCNQ1
and benign
KCNQ1
-p.R518Q, suggesting that the ion channel function of
KCNQ1
regulates ciliogenesis. In contrast, we demonstrate that the ion channel function of KCNJ10 is independent of its effect on ciliogenesis. Our data suggest that these four ion channels regulate renal ciliogenesis through the periciliary diffusion barrier or the ciliary pocket, with potential implication as genetic contributors to ciliopathy pathophysiology. The new functional roles of a subset of ion channels provide new insights into the disease pathogenesis of channelopathies, which might suggest future therapeutic approaches.
...
PMID:Screen-based identification and validation of four new ion channels as regulators of renal ciliogenesis. 2654 61
