977 resultados para Distal nephron
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The mechanisms through which aldosterone promotes apparently opposite effects like salt reabsorption and K(+) secretion remain poorly understood. The identification, localization, and physiological analysis of ion transport systems in distal nephron have revealed an intricate network of interactions between several players, revealing the complex mechanism behind the aldosterone paradox. We review the mechanisms involved in differential regulation of ion transport that allow the fine tuning of salt and K(+) balance.
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In this review, we discuss genetic evidence supporting Guyton's hypothesis stating that blood pressure control is critically depending on fluid handling by the kidney. The review is focused on the genetic dissection of sodium and potassium transport in the distal nephron and the collecting duct that are the most important sites for the control of sodium and potassium balance by aldosterone and angiotensin II. Thanks to the study of Mendelian forms of hypertension and their corresponding transgenic mouse models, three main classes of diuretic receptors (furosemide, thiazide, amiloride) and the main components of the aldosterone- and angiotensin-dependent signaling pathways were molecularly identified over the past 20years. This will allow to design rational strategies for the treatment of hypertension and for the development of the next generation of diuretics.
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The functional versatility of the distal nephron is mainly due to the large cytological heterogeneity of the segment. Part of Na(+) uptake by distal tubules is dependent on Na(+)/H(+). exchanger 2 (NHE2), implicating a role of distal convoluted cells also in acid-base homeostasis. In addition, intercalated (IC) cells expressed in distal convoluted tubules, connecting tubules and collecting ducts are involved in the final regulation of acid-base excretion. IC cells regulate acid-base handling by 2 main transport proteins, a V-type H(+)-ATPase and a Cl/HCO(3)(-) exchanger, localized at different membrane domains. Type A IC cells are characterized by a luminal H(+)-ATPase in series with a basolateral Cl/HCO(3)(-) exchanger, the anion exchanger AE1. Type B IC cells mediate HCO(3)(-) secretion through the apical Cl(-)/HCO(3)(-) exchanger pendrin in series with a H(+)-ATPase at the basolateral membrane. Alternatively, H(+)/K(+)-ATPases have also been found in several distal tubule cells, particularly in type A and B IC cells. All of these mechanisms are finely regulated, and mutations of 1 or more proteins ultimately lead to expressive disorders of acid-base balance.
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Angiotensin II (Ang II), acting via the AT1 receptor, induces an increase in intracellular calcium [Ca(2+)]i that then interacts with calmodulin (CaM). The Ca(2+)/CaM complex directly or indirectly activates sodium hydrogen exchanger 1 (NHE1) and phosphorylates calmodulin kinase II (CaMKII), which then regulates sodium hydrogen exchanger 3 (NHE3) activity. In this study, we investigated the cellular signaling pathways responsible for Ang II-mediated regulation of NHE1 and NHE3 in Madin-Darby canine kidney (MDCK) cells. The NHE1- and NHE3-dependent pHi recovery rates were evaluated by fluorescence microscopy using the fluorescent probe BCECF/AM, messenger RNA was evaluated with the reverse transcription polymerase chain reaction (RT-PCR), and protein expression was evaluated by immunoblot. We demonstrated that treatment with Ang II (1pM or 1 nM) for 30 min induced, via the AT1 but not the AT2 receptor, an equal increase in NHE1 and NHE3 activity that was reduced by the specific inhibitors HOE 694 and S3226, respectively. Ang II (1 nM) did not change the total expression of NHE1, NHE3 or calmodulin, but it induced CaMKII, cRaf-1, Erk1/2 and p90(RSK) phosphorylation. The stimulatory effects of Ang II (1 nM) on NHE1 or NHE3 activity or protein abundance was reduced by ophiobolin-A (CaM inhibitor), KN93 (CaMKII inhibitor) or PD98059 (Mek inhibitor). These results indicate that after 30 min, Ang II treatment may activate G protein-dependent pathways, including the AT1/PLC/Ca(2+)/CaM pathway, which induces CaMKII phosphorylation to stimulate NHE3 and induces cRaf-1/Mek/Erk1/2/p90(RSK) activity to stimulate NHE1
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The distal parts of the renal tubule play a critical role in maintaining homeostasis of extracellular fluids. In this review, we present an in-depth analysis of microarray-based gene expression profiles available for microdissected mouse distal nephron segments, i.e., the distal convoluted tubule (DCT) and the connecting tubule (CNT), and for the cortical portion of the collecting duct (CCD; Zuber et al., Proc Natl Acad Sci USA 106:16523-16528, 2009). Classification of expressed transcripts in 14 major functional gene categories demonstrated that all principal proteins involved in maintaining the salt and water balance are represented by highly abundant transcripts. However, a significant number of transcripts belonging, for instance, to categories of G-protein-coupled receptors or serine/threonine kinases exhibit high expression levels but remain unassigned to a specific renal function. We also established a list of genes differentially expressed between the DCT/CNT and the CCD. This list is enriched by genes related to segment-specific transport functions and by transcription factors directing the development of the distal nephron or collecting ducts. Collectively, this in silico analysis provides comprehensive information about relative abundance and tissue specificity of the DCT/CNT and the CCD expressed transcripts and identifies new candidate genes for renal homeostasis.
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BACKGROUND: Segmental handling of sodium along the proximal and distal nephron might be heritable and different between black and white participants. METHODS: We randomly recruited 95 nuclear families of black South African ancestry and 103 nuclear families of white Belgian ancestry. We measured the (FENa) and estimated the fractional renal sodium reabsorption in the proximal (RNaprox) and distal (RNadist) tubules from the clearances of endogenous lithium and creatinine. In multivariable analyses, we studied the relation of RNaprox and RNadist with FENa and estimated the heritability (h) of RNaprox and RNadist. RESULTS: Independent of urinary sodium excretion, South Africans (n = 240) had higher RNaprox (unadjusted median, 93.9% vs. 81.0%; P < 0.001) than Belgians (n = 737), but lower RNadist (91.2% vs. 95.1%; P < 0.001). The slope of RNaprox on FENa was steeper in Belgians than in South Africans (-5.40 +/- 0.58 vs. -0.78 +/- 0.58 units; P < 0.001), whereas the opposite was true for the slope of RNadist on FENa (-3.84 +/- 0.19 vs. -13.71 +/- 1.30 units; P < 0.001). h of RNaprox and RNadist was high and significant (P < 0.001) in both countries. h was higher in South Africans than in Belgians for RNaprox (0.82 vs. 0.56; P < 0.001), but was similar for RNadist (0.68 vs. 0.50; P = 0.17). Of the filtered sodium load, black participants reabsorb more than white participants in the proximal nephron and less postproximally. CONCLUSION: Segmental sodium reabsorption along the nephron is highly heritable, but the capacity for regulation in the proximal and postproximal tubules differs between whites and blacks.
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Aldosterone and corticosterone bind to mineralocorticoid (MR) and glucocorticoid receptors (GR), which, upon ligand binding, are thought to translocate to the cell nucleus to act as transcription factors. Mineralocorticoid selectivity is achieved by the 11β-hydroxysteroid dehydrogenase type 2 (11β-HSD2) that inactivates 11β-hydroxy glucocorticoids. High expression levels of 11β-HSD2 characterize the aldosterone-sensitive distal nephron (ASDN), which comprises the segment-specific cells of late distal convoluted tubule (DCT2), connecting tubule (CNT), and collecting duct (CD). We used MR- and GR-specific antibodies to study localization and regulation of MR and GR in kidneys of rats with altered plasma aldosterone and corticosterone levels. In control rats, MR and GR were found in cell nuclei of thick ascending limb (TAL), DCT, CNT, CD cells, and intercalated cells (IC). GR was also abundant in cell nuclei and the subapical compartment of proximal tubule (PT) cells. Dietary NaCl loading, which lowers plasma aldosterone, caused a selective removal of GR from cell nuclei of 11β-HSD2-positive ASDN. The nuclear localization of MR was unaffected. Adrenalectomy (ADX) resulted in removal of MR and GR from the cell nuclei of all epithelial cells. Aldosterone replacement rapidly relocated the receptors in the cell nuclei. In ASDN cells, low-dose corticosterone replacement caused nuclear localization of MR, but not of GR. The GR was redistributed to the nucleus only in PT, TAL, early DCT, and IC that express no or very little 11β-HSD2. In ASDN cells, nuclear GR localization was only achieved when corticosterone was replaced at high doses. Thus ligand-induced nuclear translocation of MR and GR are part of MR and GR regulation in the kidney and show remarkable segment- and cell type-specific characteristics. Differential regulation of MR and GR may alter the level of heterodimerization of the receptors and hence may contribute to the complexity of corticosteroid effects on ASDN function.
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(ANP, 1 µM) on the kinetics of bicarbonate reabsorption in the rat middle proximal tubule, we performed in vivo experiments using a stopped-flow microperfusion technique with the determination of lumen pH by Sb microelectrodes. These studies confirmed that ANG II added to the luminal or peritubular capillary perfusion fluid stimulates proximal bicarbonate reabsorption and showed that ANP alone does not affect this process, but impairs the stimulation caused by ANG II. We also studied the effects and the interaction of these hormones in cortical distal nephron acidification. Bicarbonate reabsorption was evaluated by the acidification kinetic technique in early (ED) and late (LD) distal tubules in rats during in vivo stopped-flow microperfusion experiments. The intratubular pH was measured with a double-barreled microelectrode with H+-sensitive resin. The results indicate that ANG II acted by stimulating Na+/H+ exchange in ED (81%) and LD (54%) segments via activation of AT1 receptors, as well as vacuolar H+-ATPase in LD segments (33%). ANP did not affect bicarbonate reabsorption in either segment and, as opposed to what was seen in the proximal tubule, did not impair the stimulation caused by ANG II. To investigate the mechanism of action of these hormones in more detail, we studied cell pH dependence on ANG II and ANP in MDCK cells using the fluorescent probe BCECF. We showed that the velocity of cell pH recovery was almost abolished in the absence of Na+, indicating that it is dependent on Na+/H+ exchange. ANP (1 µM) alone had no effect on this recovery but reversed both the acceleration of H+ extrusion at low ANG II levels (1 pM and 1 nM), and inhibition of H+ extrusion at higher ANG II levels (100 nM). To obtain more information on the mechanism of interaction of these hormones, we also studied their effects on the regulation of intracellular free calcium concentration, [Ca2+]i, monitored with the fluorescent probe Fura-2 in MDCK cells in suspension. The data indicate that the addition of increasing concentrations of ANG II (1 pM to 1 µM) to the cell suspension led to a progressive increase in [Ca2+]i to 2-3 times the basal level. In contrast, the addition of ANP (1 µM) to the cell suspension led to a very rapid 60% decrease in [Ca2+]i and reduced the increase elicited by ANG II, thus modulating the effect of ANG II on [Ca2+]i. These results may indicate a role of [Ca2+]i in the regulation of the H+ extrusion process mediated by Na+/H+ exchange and stimulated/impaired by ANG II. The data are compatible with stimulation of Na+/H+ exchange by increases of [Ca2+]i in the lower range, and inhibition at high [Ca2+]i levels
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The present paper reviews work from our laboratories evaluating the importance of adrenal cortical hormones in acidification by proximal and cortical distal tubules. Proximal acidification was determined by stationary microperfusion, and measurement of bicarbonate reabsorption using luminal pH determination was performed with H+-ion-sensitive microelectrodes. Rats were adrenalectomized (ADX) 48 h before the experiments, and corticosteroids (aldosterone (A), corticosterone (B), and 18-OH corticosterone (18-OH-B)) were injected intramuscularly 100 and 40 min before the experiments. In ADX rats stationary pH increased significantly to 7.03 as compared to sham-operated rats (6.78). Bicarbonate reabsorption decreased from 2.65 ± 0.18 in sham-operated rats to 0.50 ± 0.07 nmol cm-2 s-1 after ADX. The administration of the three hormones stimulated proximal tubule acidification, reaching, however, only 47.2% of the sham values in aldosterone-treated rats. Distal nephron acidification was studied by measuring urine minus blood pCO2 differences (U-B pCO2) in bicarbonate-loaded rats treated as above. This pCO2 difference is used as a measure of the distal nephron ability to secrete H+ ions into an alkaline urine. U-B pCO2 decreased significantly from 39.9 ± 1.26 to 11.9 ± 1.99 mmHg in ADX rats. When corticosteroids were given to ADX rats before the experiment, U-B pCO2 increased significantly, but reached control levels only when aldosterone (two 3-µg doses per rat) plus corticosterone (220 µg) were given together. In order to control for the effect of aldosterone on distal transepithelial potential difference one group of rats was treated with amiloride, which blocks distal sodium channels. Amiloride-treated rats still showed a significant reduction in U-B pCO2 after ADX. Only corticosterone and 18-OH-B but not aldosterone increased U-B pCO2 back to the levels of sham-operated rats. These results show that corticosteroids stimulate renal tubule acidification both in proximal and distal nephrons and provide some clues about the mechanism of action of these steroids
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Aldosterone and corticosterone bind to mineralocorticoid (MR) and glucocorticoid receptors (GR), which, upon ligand binding, are thought to translocate to the cell nucleus to act as transcription factors. Mineralocorticoid selectivity is achieved by the 11β-hydroxysteroid dehydrogenase type 2 (11β-HSD2) that inactivates 11β-hydroxy glucocorticoids. High expression levels of 11β-HSD2 characterize the aldosterone-sensitive distal nephron (ASDN), which comprises the segment-specific cells of late distal convoluted tubule (DCT2), connecting tubule (CNT), and collecting duct (CD). We used MR- and GR-specific antibodies to study localization and regulation of MR and GR in kidneys of rats with altered plasma aldosterone and corticosterone levels. In control rats, MR and GR were found in cell nuclei of thick ascending limb (TAL), DCT, CNT, CD cells, and intercalated cells (IC). GR was also abundant in cell nuclei and the subapical compartment of proximal tubule (PT) cells. Dietary NaCl loading, which lowers plasma aldosterone, caused a selective removal of GR from cell nuclei of 11β-HSD2-positive ASDN. The nuclear localization of MR was unaffected. Adrenalectomy (ADX) resulted in removal of MR and GR from the cell nuclei of all epithelial cells. Aldosterone replacement rapidly relocated the receptors in the cell nuclei. In ASDN cells, low-dose corticosterone replacement caused nuclear localization of MR, but not of GR. The GR was redistributed to the nucleus only in PT, TAL, early DCT, and IC that express no or very little 11β-HSD2. In ASDN cells, nuclear GR localization was only achieved when corticosterone was replaced at high doses. Thus ligand-induced nuclear translocation of MR and GR are part of MR and GR regulation in the kidney and show remarkable segment- and cell type-specific characteristics. Differential regulation of MR and GR may alter the level of heterodimerization of the receptors and hence may contribute to the complexity of corticosteroid effects on ASDN function.
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Autosomal recessive polycystic kidney disease is a hereditary fibrocystic disease that involves the kidneys and the biliary tract. Mutations in the PKHD1 gene are responsible for typical forms of autosomal recessive polycystic kidney disease. We have generated a mouse model with targeted mutation of Pkbd1 by disrupting exon 4, resulting in a mutant transcript with deletion of 66 codons and expression at similar to 30% of wild-type levels. Pkhd1(del4/d3l4) mice develop intrahepatic bile duct proliferation with progressive cyst formation and associated periportal fibrosis. In addition, these mice exhibit extrahepatic manifestations, including pancreatic cysts, splenomegaly, and common bile duct dilation. The kidneys are unaffected both histologically and functionally. Fibrocystin is expressed in the apical membranes and cilia of bile ducts and distal nephron segments but is absent from the proximal tubule. This pattern is unchanged in orthologous models of autosomal dominant polycystic kidney disease due to mutation in Pkd1 or Pkd2. Mutant fibrocystin in Pkhd1(del4/d3l4) mice also retains this expression pattern. The hypomorphic Pkhd1(del4/d3l4) mouse model provides evidence that reduced functional levels of fibrocystin are sufficient for cystogenesis and fibrosis in the liver and pancreas, but not the kidney, and supports the hypothesis of species-dependent differences in susceptibility of tissues to Pkbdl mutations.
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Hypertension is a serious medical problem affecting millions of people worldwide. A key protein regulating blood pressure is the Epithelial Na(+) Channel (ENaC). In accord, loss of function mutations in ENaC (PHA1) cause hypotension, whereas gain of function mutations (Liddle syndrome) result in hypertension. The region mutated in Liddle syndrome, called the PY motif (L/PPxY), serves as a binding site for the ubiquitin ligase Nedd4-2, a C2-WW-Hect E3 ubiquitin ligase. Nedd4-2 binds the ENaC-PY motif via it WW domains, ubiquitylates the channel and targets it for endocytosis, a process impaired in Liddle syndrome due to poor binding of the channel to Nedd4-2. This leads to accumulation of active channels at the cell surface and increased Na(+) (and fluid) absorption in the distal nephron, resulting in elevated blood volume and blood pressure. Compounds that destabilize cell surface ENaC, or enhance Nedd4-2 activity in the kidney, could potentially serve as drug targets for hypertension. In addition, recent discoveries of regulation of activation of ENaC by proteases such as furin, prostasin and elastase, which cleave the extracellular domain of this channel leading to it activation, as well as the identification of inhibitors that block the activity of these proteases, provide further avenues for drug targeting of ENaC and the control of blood pressure.
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Elevated plasma urate levels are associated with metabolic, cardiovascular, and renal diseases. Urate may also form crystals, which can be deposited in joints causing gout and in kidney tubules inducing nephrolithiasis. In mice, plasma urate levels are controlled by hepatic breakdown, as well as, by incompletely understood renal processes of reabsorption and secretion. Here, we investigated the role of the recently identified urate transporter, Glut9, in the physiological control of urate homeostasis using mice with systemic or liver-specific inactivation of the Glut9 gene. We show that Glut9 is expressed in the basolateral membrane of hepatocytes and in both apical and basolateral membranes of the distal nephron. Mice with systemic knockout of Glut9 display moderate hyperuricemia, massive hyperuricosuria, and an early-onset nephropathy, characterized by obstructive lithiasis, tubulointerstitial inflammation, and progressive inflammatory fibrosis of the cortex, as well as, mild renal insufficiency. In contrast, liver-specific inactivation of the Glut9 gene in adult mice leads to severe hyperuricemia and hyperuricosuria, in the absence of urate nephropathy or any structural abnormality of the kidney. Together, our data show that Glut9 plays a major role in urate homeostasis by its dual role in urate handling in the kidney and uptake in the liver.
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Liddle's syndrome is a genetic form of hypertension linked to Na(+) retention caused by activating mutations in the COOH terminus of the beta or gamma subunit of the epithelial sodium channel (ENaC). In this study, we used the short-circuit current (I(sc)) method to investigate the effects of deamino-8-d-arginine vasopressin (dDAVP) on Na(+) and Cl(-) fluxes in primary cultures of cortical collecting ducts (CCDs) microdissected from the kidneys of mice with Liddle's syndrome carrying a stop codon mutation, corresponding to the beta-ENaC R(566) stop mutation (L) found in the original pedigree. Compared to wild-type (+/+) CCD cells, untreated L/+ and L/L CCD cells exhibited 2.7- and 4.2-fold increases, respectively, in amiloride-sensitive (Ams) I(sc), reflecting ENaC-dependent Na(+) absorption. Short-term incubation with dDAVP caused a rapid and significant increase (approximately 2-fold) in Ams I(sc) in +/+, but not in L/+ or L/L CCD cells. In sharp contrast, dDAVP induced a greater increase in 5-nitro-2-(3-phenylpropamino)benzoate (NPPB)-inhibited apical Cl(-) currents in amiloride-treated L/L and L/+ cells than in their +/+ counterparts. I(sc) recordings performed under apical ion substituted conditions revealed that the dDAVP-stimulated apical secretion of Cl(-), which was absent in cultured CCDs lacking CFTR, was 1.8-fold greater in L/+ and 3.7-fold greater in L/L CCD cells than in their +/+ CCD counterparts. After the basal membrane had been permeabilized with nystatin and a basal-to-apical Cl(-) gradient had been imposed, dDAVP also stimulated larger Cl(-) currents across L/L and L/+ CCD layers than +/+ CCD layers. These findings demonstrate that vasopressin stimulates greater apical CFTR Cl(-) conductance in the renal CCD cells of mice with Liddle's syndrome than in wild-type mice. This effect could contribute to the enhanced NaCl reabsorption observed in the distal nephron of patients with Liddle's syndrome.
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Résumé Les mécanismes de régulation de la réabsorption fine du sodium dans la partie distale (tube distal et tube collecteur) du néphron ont un rôle essentiel dans le maintien de l'homéostasie de la composition ionique et du volume des fluides extracellulaires. Ces mécanismes permettent le maintien de la pression sanguine. Dans la cellule principale du tube collecteur cortical (CCD), le taux de réabsorption de sodium dépend essentiellement de l'activité du canal épithélial à sodium (ENaC) à la membrane apicale et de la pompe sodium-potassium-adénosine-triphosphatase (Na+-K±ATPase) à la membrane basolatérale. L'activité de ces deux molécules de transport est en partie régulée par des hormones dont l'aldostérone, la vasopressine et l'insuline. Dans les cellules principales de CCD, la vasopressine régule le transport de sodium en deux étapes : une étape précoce dite « non-génomique » et une étape tardive dite « génotnique ». Durant l'étape précoce, la vasopressine régule l'expression de gènes, dont certains peuvent être impliqués dans le transport de sodium, comme ENaC et la Na+ -K+ATP ase. Le but de mon travail a été d'étudier l'implication d'une protéine appelée VIP32 (vasopressin induced protein : VIP) dans le transport de sodium. L'expression de VIP32 est augmentée par la vasopressine dans les cellules principales de CCD. Dans l'ovocyte de Xenopus laevis utilisé comme système d'expression hétérologue, nous avons montré que l'expression de VIP32 provoque la maturation méiotique de l'ovocyte par l'activation de la voie des MAPK (mitogen-activated protein kinase : MAPK) et du facteur de promotion méiotique (MPF). La co-expression d'ENaC et de VIP32 diminue l'activité d'ENaC de façon sélective, par l'activation de la voie des MAPK, sans affecter l'expression du canal à la surface membranaire. Nous avons également montré que la régulation de l'activité d'ENaC par la voie des MAPK est dépendante du mécanisme de régulation d'ENaC lié à un motif du canal appelé PY. Ce motif est impliqué dans le contrôle de la probabilité d'ouverture ainsi que l'expression à la surface membranaire d'ENaC. Dans les cellules principales, VIP32 par l'activation de la voie des MAPK peut être impliqué dans la régulation négative du transport transépithélial qui a lieu après plusieurs heures de traitement à la vasopressine. Le tube collecteur de reins normaux présente un taux basal significatif d'activité de la voie MAPK MEK1/2-ERK1/2. Dans la lignée mpkCCDc14 de cellules principales de CCD de souris, que nous avons utilisé pour cette partie du travail, nous avons montré la présence d'un taux basal d'activité d'ERK1/2 (pERK1/2). L'aldostérone et la vasopressine, connus pour stimuler le courant sodique transépithélial dans le CCD, ne changeaient pas le taux basal de pERK1/2. Le transport de sodium transépithélial basal, ou stimulé par l'aldostérone ou la vasopressine est diminué par l'effet de PD98059, un inhibiteur de MEK1/2 qui diminue parallèlement le taux de pERK1/2. Nous avons également montré dans des cellules non stimulées, ou stimulées par de l'aldostérone ou de la vasopressine, que l'activité de la Na+-K+ ATPase, mais pas celle d'ENaC est inhibée par des traitements avec différents inhibiteurs de MEK1/2. Par un marquage de la Na±-K+ATPase à la surface membranaire nous avons montré que la voie d'ERK1/2 contrôle l'activité intrinsèque de la Na+-K+ ATPase, plutôt que son expression à la surface membranaire. Ces données ont montré que l'activité de la Na+-K+ATPase et le transport transépithélial de sodium sont contrôlés par l'activité basal et constitutive de la voie d'ERK1/2. Summary The regulation of sodium reabsorption in the distal nephron (distal tubule and cortical collecting duct) in the kidney plays an essential role in the control of extracellular fluids composition and volume, and thereby blood pressure. In the principal cell of the collecting duct (CCD), the level of sodium reabsorption mainlly depends on the activity of both epithlial sodium channel (ENaC) and sodium-potassium-adenosine-triphosphatase (Na+-K+ATPase). The activity of these two transporters is regulated by hormones especially aldosterone, vasopressin and insuline.In the principal cell of the CCD, vasopressin regulates sodium transport via a short-term effect and a late genomic effect. During the genomic effect vasopressin activates a complex network of vasopressin-dependent genes involved in the regulation of sodium transport as ENaC and Na+-K+ATPase. We were interested in the role of a recently identified vasopressin induced protein (VIP32) and its implication in the regulation of sodium transport in principal cell of the CCD. The Xenopus oocyte expression system revealed two functions : expressed alone VIP32 rapidly induces oocyte meiotic maturation through the activation of the mitogen-activated protein kinase (MAPK) pathway and the meiotic promoting factor and when co-expressed with ENaC, V1P32 selectively dowrn-egulates channel activity, but not channel cell surface expression. We have shown that the ENaC downregulation mediated by the activation of the MAPK pathway is related to the PY motif of ENaC. This motif is implicated in ENaC cell surface expression and open probability regulation. In the kidney principal cell, VIP32 through the activation of MAPK pathway may be involved in the downregulation of transepithelial sodium transport observed within a few hours after vasopressin treatment. The collecting duct of normal kidney exhibits significant activity of the MEK1/2-ERK1/2 MAPK pathway. Using in vitro cultured mpkCCDc14 principal cells we have shown a significant basal level of ERK1/2 activity (pERK1/2). Aldosterone and vasopressin, known to upregulate sodium reabsorption in CCDs, did not change ERK1/2 activity. Basal and aldosterone- or vasopressin-stimulated sodium transport were downregulated by the MEK1/2 inhibitor PD98059 in parallel with a decrease in pERK1/2 in vitro. The activity of Na+-K+ATPase but not that of ENaC was inhibited by MEK1/2 inhibitors in both, unstimulated and aldosterone- or vasopressin-stimulated CCDs in vitro. Cell surface labelling showed that intrinsic activity rather than cell surface expression of Na+-K+ATPase was controlled by pERK1/2. Our data demonstrate that basal constitutive activity of ERK1/2 pathway controls Na+-K+ATPase activity and transepithelial sodium transport in the principal cell. Résumé tout public Les mécanismes de régulation de la réabsorption fine du sodium dans la partie distale du néphron (l'unité fonctionnelle du rein) ont un rôle essentiel dans le maintien de l'homéostasie de la composition et du volume des fluides extracellulaires. Ces mécanismes permettent de maintenir une pression sanguine effective. Dans les cellules principales du tube collecteur, une région spécifique du néphron distal, le transport de sodium dépend essentiellement de l'activité de deux transporteurs de sodium : le canal épithélial à sodium (ENaC) et la pompe sodium-potassium-adénosine-triphosphatase (Na+-K+ATPase). Afin de répondre aux besoins de l'organisme, l'activité de ces deux molécules de transport est en partie régulée par des hormones dont l'aldostérone, la vasopressine et l'insuline. Dans les cellules principales du tube collecteur, la vasopressine régule le transport de sodium en deux étapes : une étape rapide et une étape lente dite « génomique ». Durant l'étape lente, la vasopressine régule l'expression de gènes pouvant être impliqués dans le transport de sodium, dont notamment ceux d'ENaC et de la Na+-K+ATPase. Parmi les gènes dont l'expression est augmentée par la vasopressine, celui de VIP32 (vasopressin induced protein : VIP) fait l'objet de cette étude. Le but de mon travail a été d'étudier, dans un système d'expression hétérologue (l'ovocyte de Xenopus leavis), l'implication de VIP32 dans le transport de sodium. Nous avons montré que VIP32 est capable d'activer un mécanisme moléculaire en cascade appelé MAPK (mitogen-activated protein kinase : MAPK) et est aussi capable de diminuer l'activité d'ENaC. Parallèlement, dans une lignée de cellules principales de tube collecteur les mpkCCDc14, nous avons montré que le taux basal d'activité de la cascade MAPK est capable de réguler l'activité de la Na+-K+ATPase, tandis qu'il n'influence pas l'activité d'ENaC.
