18 research outputs found

    Epithelial sodium channel in human epidermal keratinocytes: expression of its subunits and relation to sodium transport and differentiation

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    The amiloride-sensitive epithelial sodium channel (ENaC) is a main determinant of sodium absorption in renal and colonic epithelial cells. Surprisingly, it is also expressed in non-transporting epithelia such as the epidermis. To gain insight into the putative role of ENaC in keratinocytes, we have evaluated its expression in human skin and in cultured human keratinocytes. Our results indicate that (1) ENaC is expressed in the epidermis and in cultured keratinocytes, at the mRNA and at the protein levels, (2) the ratio of expression of the different ENaC subunits is drastically modified at the protein level during cell growth and differentiation, with a selective upregulation of the &bgr; subunit, (3) no transepithelial sodium transport function is apparent in cultured keratinocytes, but patch-clamp recordings indicate the existence of functional sodium channels with properties similar to those of the cloned ENaC and (4) ENaC inhibition does not alter keratinocyte proliferation, but it significantly decreases the frequency of dome formation in confluent keratinocyte cultures. These results document for the first time the characteristics of ENaC subunit expression in human keratinocytes, and suggest that ENaC may be important during differentiation

    Activation of D 2

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    Coordinate control of Na,K-atpase mRNA expression by aldosterone, vasopressin and cell sodium delivery in the cortical collecting duct

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    We have examined the respective influence of aldosterone, vasopressin and cell sodium delivery on Na+,K+-ATPase expression. The level of expression of the mRNA encoding for the alpha1- and beta1-subunits of Na+,K+-ATPase was evaluated in cortical collecting duct (CCD) cells from rats under different aldosterone status, in cells from the rat CCD cell line RCCD1 treated or not with vasopressin and in CCD cells from mice inactivated or not for the a-subunit of the epithelial sodium channel. The amount of mRNA was determined by in situ hybridization. Both aldosterone and vasopressin up-regulate transcripts encoding for the alpha1-subunit of Na+,K+-ATPase while beta1 is unaltered. Interestingly, when cell sodium entry was largely reduced (alphaENaC knock-out mice), the amount of transcripts encoding for the alpha1-subunit of Na+,K+-ATPase was significantly decreased in spite of high plasma aldosterone concentrations. No effect was observed on beta1-subunit. Altogether, these results suggest a coordinated hormonal and ionic control of Na+,K+-ATPase expression by different transcriptional pathways (steroid-receptor, cAMP-dependent and Na+dependent) in CCD cells. These regulations affect only alpha1-subunit of Na,K+-ATPase but not beta1

    A novel vasopressin-induced transcript promotes MAP kinase activation and ENaC downregulation

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    In the principal cell of the renal collecting duct, vasopressin regulates the expression of a gene network responsible for sodium and water reabsorption through the regulation of the water channel and the epithelial sodium channel (ENaC). We have recently identified a novel vasopressin-induced transcript (VIT32) that encodes for a 142 amino acid vasopressin-induced protein (VIP32), which has no homology with any protein of known function. The Xenopus oocyte expression system revealed two functions: (i) when injected alone, VIT32 cRNA rapidly induces oocyte meiotic maturation through the activation of the maturation promoting factor, the amphibian homolog of the universal M phase trigger Cdc2/cyclin; and (ii) when co-injected with the ENaC, VIT32 cRNA selectively downregulates channel activity, but not channel cell surface expression. In the kidney principal cell, VIP32 may be involved in the downregulation of transepithelial sodium transport observed within a few hours after vasopressin treatment. VIP32 belongs to a novel gene family ubiquitously expressed in oocyte and somatic cells that may be involved in G to M transition and cell cycling
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