Gene/Protein Disease Symptom Drug Enzyme Compound
Pivot Concepts:   Target Concepts:
Query: UNIPROT:P41181 (collecting duct)
 5,183 document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)

E-cadherin, a member of the cadherin family, plays a major role in cell-cell adhesion of normal epithelium. Recent studies have demonstrated that heterogeneous expression, reduction or loss of E-cadherin is involved in invasion and metastasis of cancer cells. In this study, the localization of E-cadherin in the normal human kidney and the relationship between E-cadherin expression and histopathological features in renal cell carcinomas was examined immunohistochemically. Renal cell carcinoma tissues and normal kidney counterparts were obtained from 20 patients. E-cadherin in the normal kidney was detected in the cell-cell border of the distal tubules, collecting duct and Bowman's capsule but not in the proximal tubules. E-cadherin expression was reduced in all the clear cell type renal cell carcinomas with compact or cystic configuration (n = 15), while it was well preserved in all the papillary type (n = 3) and chromophobe cell type (n = 1) renal cell carcinomas. Different expression patterns between primary site and metastasis, i.e., homogeneously weak in primary tumor and heterogeneously positive in metastatis, was observed in a case of clear cell type renal cell carcinoma. Different patterns of expression between clear and non-clear cell type, or between papillary and non-papillary type, together with strong expression in chromophobe type might reflect the origin of each type of renal cell carcinoma. Further studies will clarify whether the change in expression of E-cadherin is associated with the prognosis of renal cell carcinoma.
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PMID:[E-cadherin expression and histopathological features in renal cell carcinomas]. 748 27

To evaluate the effect of cyclosporine A (CyA) at high concentrations (10(-4) and 10(-5) M) and the influence of endothelin-1 (ET-1) at physiological and pharmacological concentrations (10(-14) to 10(-6) M) on epithelial cell function, LLC-PK1 cells were studied as a model of the proximal tubule and MDCK cells as a model of the distal tubule/collecting duct. CyA caused time- and concentration-dependent acute toxicity. In LLC-PK1 cells, CyA caused a decrease in transepithelial resistance, indicating a loss of cell contacts, a release of lactate dehydrogenase (LDH) and villin into the supernatant, suggesting destruction of the apical membrane with loss of brush border, and finally release of uvomorulin, suggesting a disruption of the cell-cell adhesion, the zonula adherens. DNA synthesis, as evaluated by bromodeoxyuridine (BrdU) incorporation, was significantly affected at > or = 10(-5) M CyA. The toxicity of CyA was higher when given from the apical rather than the basolateral compartment. ET-1 alone was without effect, but in combination with CyA, ET-1 significantly enhanced toxicity. The ET-1 effect was partially inhibitable by an ET(B), but not an ET(A), antagonist. Immunofluorescence for alpha-catenin, another protein of the zonula adherens, demonstrated no change in polarity for this protein, and immunoprecipitation of the complex indicated relative stability of the zonula adherens despite loss of cadherin into the supernatant. In MDCK cells the effects were different. CyA was not associated with LDH release, but with an increase in transepithelial resistance, indicating increased paracellular resistance. Morphological alterations were significantly less, but BrdU incorporation was decreased. This pattern of toxicity is compatible with a direct toxic effect of CyA on cells of the proximal tubule, with predominant morphological destruction of the cells, with concomitant proximal tubular dysfunction, and a functional alteration in cells of the distal tubule associated with increased paracellular resistance, which may lead to solute and water loss.
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PMID:Tubular toxicity of cyclosporine A and the influence of endothelin-1 in renal cell culture models (LLC-PK1 and MDCK). 943 65

Cadmium toxicity to renal cells was investigated in Madin-Darby canine kidney (MDCK) and LLC-PK1 cells as models of the distal tubule/collecting duct and proximal tubule, respectively. Cells were grown on two-compartment filters and exposed to 0.1-50 microM Cd2+. In MDCK cells, Cd2+ was more toxic from the basolateral than from the apical side and dependent on the extracellular Ca2+ concentration. Toxicity was evident within 24 h, as shown by a decrease in transepithelial resistance (TER), reduced proliferation (bromodeoxyuridine incorporation), reduction in ATP concentration, and morphological changes. On confocal microscopy, E-cadherin and alpha-catenin staining patterns indicated interference with the cadherin-catenin complex. LLC-PK1 cells showed a similar toxicity pattern, which was evident at lower Cd2+ concentrations. An increase of E-cadherin and alpha-catenin molecules in the Triton X-100-insoluble fraction was detectable at high Cd2+ concentrations in LLC-PK1 cells but not in MDCK cells. Lactate dehydrogenase release indicated membrane leakage in LLC-PK1 cells. Rhodamine-phalloidin staining, a probe for F-actin filaments, demonstrated alterations of the actin cytoskeleton in both cell lines. In conclusion, cadmium caused ATP depletion and interfered with the cadherin-catenin complex and probably the tight junctions changing renal cell morphology and function.
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PMID:Cadmium is more toxic to LLC-PK1 cells than to MDCK cells acting on the cadherin-catenin complex. 968 16

Epithelial cell morphology and cytoskeletal organization are determined by interactions, with both adjacent cells and the extracellular matrix, which are mediated by integrins and cadherins. Little is known, however, of the relative contributions of integrins and cadherins to maintaining the sub-cortical cytoskeleton characteristic of epithelial cells. Since most studies that utilize integrin-blocking antibodies result in a loss of both cell-cell adhesion and sub-cortical cytoskeletal organization, it has been difficult to distinguish whether integrins and cadherins both mediate cytoskeletal assembly in epithelial cells. Therefore, cells derived from kidney collecting ducts of (alpha)3(beta)1 integrin-deficient mice were used to examine the role of integrins in epithelial cell morphology and cytoskeletal organization. In primary cell culture, (alpha)3(beta)1 integrin-deficient kidney collecting duct cells maintain cadherin-mediated cell-cell adhesions but fail to form the sub-cortical cytoskeleton that is characteristic of epithelial cells, and instead assemble actin stress fibers. Moreover, the cell-cell junctions in mutant cells were irregular, rather than being uniformly oriented perpendicular to the culture substrate. These results demonstrated that integrins have an primary and essential function in establishing and maintaining the sub-cortical cytoskeleton that is characteristic of epithelial cells. To further study the role of (alpha)3(beta)1 integrin in establishing and maintaining cytoskeletal organization in tubular epithelial cells, we derived immortalized cell lines from wild-type and (alpha)3(beta)1 integrin-deficient kidney collecting ducts that duplicated the cytoskeletal and cadherin organization observed in primary cells. E-cadherin and (alpha)- and (beta)-catenin were complexed together in equal amounts in membranes of wild-type and (alpha)3(beta)1 integrin-deficient cells. However, association of the cadherin:catenin complex with (alpha)-actinin was greatly decreased in mutant cells, indicating that integrin-mediated assembly of the sub-cortical cytoskeleton is essential for subsequent association of the cytoskeleton with the cadherin:catenin complex. These results present direct evidence for integrin:cadherin cross-regulation in which cadherin function is dependent on the presence of an integrin.
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PMID:(Alpha)3(beta)1 integrin regulates epithelial cytoskeletal organization. 1044 87

Kidney-specific cadherin (Ksp-cadherin, cadherin 16) is a tissue-specific member of the cadherin superfamily that is expressed exclusively in the basolateral membrane of tubular epithelial cells in the kidney. To determine the basis for tissue-specific expression of Ksp-cadherin in vivo, we evaluated the activity of the promoter in transgenic mice. Transgenic mice containing 3.3 kb of the mouse Ksp-cadherin promoter and an Escherichia coli lacZ reporter gene were generated by pronuclear microinjection. Assays of beta-galactosidase enzyme activity showed that the transgene was expressed exclusively in the kidney in both adult and developing mice. Within the kidney, the transgene was expressed in a subset of renal tubular epithelial cells that endogenously expressed Ksp-cadherin and that were identified as collecting ducts by colabeling with Dolichos biflorus agglutinin. In the developing metanephros, expression of the transgene in the branching ureteric bud correlated with the developmental expression of Ksp-cadherin. Identical patterns of expression were observed in multiple founder mice, indicating that kidney specificity was independent of transgene integration site. However, heterocellular expression was observed consistent with repeat-induced gene silencing. We conclude that the Ksp-cadherin gene promoter directs kidney-specific expression in vivo. Regulatory elements that are sufficient to recapitulate the tissue- and differentiation-specific expression of Ksp-cadherin in the renal collecting duct are located within 3.3 kb upstream to the transcriptional start site.
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PMID:Ksp-cadherin gene promoter. II. Kidney-specific activity in transgenic mice. 1051 85

The Ca(2+)-dependent membrane-spanning classical cadherins bind directly to cytosolic catenins. This cadherin-catenin interaction is known to be critical for the fundamental role of cadherins in cell-cell adhesion. The small subfamily of the 7D-cadherins, however, cannot interact with catenins due to their highly truncated cytoplasmic tail. Thus far, no cytoplasmic interaction partner for the 7D-cadherins has been described. With the use of the cytoplasmic domain of the Ksp (kidney-specific)-cadherin, which belongs to the family of 7D-cadherins, as bait in affinity chromatography with human kidney lysates, the small heat-shock protein alpha B-crystallin was identified by matrix-assisted laser desorption/ionization-time-of-flight analysis as a cytosolic binding partner of Ksp-cadherin. This interaction was verified by co-immunoprecipitation analysis. With the use of overlapping peptides representing the entire alpha B-crystallin molecule, the N-terminal part of alpha B-crystallin, which does not possess chaperone activity, was identified as responsible for the binding to Ksp-cadherin. This interaction was found to be specific since only the cytoplasmic domain of Ksp-cadherin, but not LI (liver-intestine)-cadherin (another member of the 7D-cadherin family), interacted with alpha B-crystallin. In the human kidney, both alpha B-crystallin and Ksp-cadherin co-localize to cells of the collecting duct. They also co-localize with the actin cytoskeleton and co-precipitate with the latter. These findings suggest that the interaction of Ksp-cadherin with alpha B-crystallin is important for the connection of Ksp-cadherin to the cytoskeleton and thus for maintaining tissue integrity in the kidney.
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PMID:alpha B-crystallin is a cytoplasmic interaction partner of the kidney-specific cadherin-16. 1834 7

Renal tubule epithelial cells express the insulin receptor (IR); however, their value has not been firmly established. We generated mice with renal epithelial cell-specific knockout of the IR by Cre-recombinase-loxP recombination using a kidney-specific (Ksp) cadherin promoter. KO mice expressed significantly lower levels of IR mRNA and protein in kidney cortex (49-56% of the WT) and medulla (32-47%) homogenates. Immunofluorescence showed the greatest relative reduction in the thick ascending limb and collecting duct cell types. Body weight, kidney weight, and food and water intakes were not different from WT littermates. However, KO mice had significantly increased basal systolic blood pressure (BP, 15 mm Hg higher) as measured by radiotelemetry. In response to a volume load by gavage (20 ml/kg of body weight, 0.9% NaCl, 15% dextrose), KO mice had impaired natriuresis (37 +/- 10 versus 99 +/- 9 mmol of Na(+) per 2 h in WT). Furthermore, volume load led to a sustained increase in BP in KO mice only. In contrast, insulin administration i.p. (0.5 units/kg of body weight) resulted in a significant fall in BP in WT, but not in KO mice. To test the role of reduced renal nitric oxide (NO) production in these responses, basal urinary nitrates plus nitrites excretion (UNOx) was measured and found to be 61% lower in KO vs. WT mice. Furthermore, acute insulin increased UNOx by 202% in the WT, relative to a significantly blunted rise (67%) in KO animals. These results illuminate a previously uncharacterized role for renal IR to reduce BP and facilitate sodium and water excretion, possibly via NO production.
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PMID:Impaired sodium excretion and increased blood pressure in mice with targeted deletion of renal epithelial insulin receptor. 1842 59

The mammalian kidney forms via cell-cell interactions between an epithelial outgrowth of the nephric duct and the surrounding nephrogenic mesenchyme. Initial morphogenetic events include ureteric bud branching to form the collecting duct (CD) tree and mesenchymal-to-epithelial transitions to form the nephrons, requiring reciprocal induction between adjacent mesenchyme and epithelial cells. Within the tips of the branching ureteric epithelium, cells respond to mesenchyme-derived trophic factors by proliferation, migration, and mitosis-associated cell dispersal. Self-inhibition signals from one tip to another play a role in branch patterning. The position, survival, and fate of the nephrogenic mesenchyme are regulated by ECM and secreted signals from adjacent tip and stroma. Signals from the ureteric tip promote mesenchyme self-renewal and trigger nephron formation. Subsequent fusion to the CDs, nephron segmentation and maturation, and formation of a patent glomerular basement membrane also require specialized cell-cell interactions. Differential cadherin, laminin, nectin, and integrin expression, as well as intracellular kinesin and actin-mediated regulation of cell shape and adhesion, underlies these cell-cell interactions. Indeed, the capacity for the kidney to form via self-organization has now been established both via the recapitulation of expected morphogenetic interactions after complete dissociation and reassociation of cellular components during development as well as the in vitro formation of 3D kidney organoids from human pluripotent stem cells. As we understand more about how the many cell-cell interactions required for kidney formation operate, this enables the prospect of bioengineering replacement structures based on these self-organizing properties.
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PMID:Cell-cell interactions driving kidney morphogenesis. 2573 49