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

Osteopontin is a secreted phosphoprotein that is expressed by normal kidney, and has been associated with a number of functions including cell adhesion, migration, signaling, and biomineralization. Although there is a vast literature detailing osteopontin localization in various rodent models of both development and disease, this article presents the first comprehensive description of osteopontin localization in human kidney. In this study, immunohistochemistry, immunoelectron microscopy, in situ hybridization, and Northern blotting are used to analyze osteopontin protein and mRNA expression in human fetal and normal mature renal tissue. Osteopontin is expressed in the human embryonic renal tubular epithelium beginning on approximately day 75 to 80 of gestation. In the fetal kidney, osteopontin can also be seen occasionally expressed in the ureteric buds and in some interstitial cells. As localized at the protein and mRNA level, the tubular expression of osteopontin increases with increasing gestational age and persists into adulthood. In the normal adult kidney, osteopontin is localized primarily to the distal nephron and is strongly expressed by the thick ascending limb of the loops of Henle. Osteopontin expression can also be observed in some collecting duct epithelium. In cases that exhibit foci of interstitial fibrosis and an associated influx of interstitial macrophages, osteopontin expression is significantly upregulated in all tubular segments, including proximal tubules.
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PMID:Osteopontin expression in fetal and mature human kidney. 1007 94

Complement homologous restriction factor CD59 and complement receptor CD35 are typically involved in the regulation of the host defense system. Recent observations in the human fetal kidney suggest a further role for complement cell surface regulators CD35 and CD59 in kidney development and maturation. We investigated this possible role by localizing CD35 and CD59 protein and mRNA in the developing and adult kidney. Adult tissue and fetal tissue ontogeny were analyzed using immunohistochemistry and in situ hybridization. CD35 protein and mRNA were localized to the podocyte of the glomerulus in the human fetal and adult kidney. Expression was initiated after vascularization of the early developing glomerulus. CD59 protein and mRNA were observed as early as 8 weeks' gestation and were localized primarily to the ureteric duct epithelium in the fetal kidney and predominantly to the collecting duct in the adult. Interestingly, CD59 expression was translocated from the basolateral surface in the fetal kidney to the apical surface in the adult kidney. The specific spatial and temporal expression of CD35 and CD59 suggests a possible role for these complement regulatory proteins in renal cell differentiation.
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PMID:Expression of complement regulatory proteins in the developing human kidney. 1109 9

A systematic effort to isolate kidney-specific genes was performed using recently described PCR-select methodology. Using this technique, a kidney-specific mini-gene library was generated and a number of kidney-specific genes that share significant homology to previously characterized kidney genes from rats and other species were isolated. These included three renal-specific transporters (an ADH water channel, the anion transporters RST and ROAT1), a cell adhesion molecule (K-cadherin) and a kidney-specific protein upregulated in renal carcinoma (DD96). In addition, we isolated two novel genes from a rat kidney. One of the genes shares limited homology to rat profilin-1 while the other did not share any similarity to genes in the Genbank. Northern blot analysis revealed that the mRNA for each of these genes is expressed in a highly kidney-restricted fashion. Our results suggested that tissue-specific genes can be rapidly isolated and characterized using PCR-select techniques and this methodology may be generally applicable to isolate specific genes from a variety of tissues.
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PMID:Rapid isolation of tissue-specific genes from rat kidney. 1115 Aug 65

Galectin-3 is a mammalian beta-galactoside-specific lectin with functions in cell growth, adhesion, and neoplastic transformation. On the basis of expression patterns in humans, it is proposed that galectin-3 modulates fetal collecting duct growth. This article provides evidence that galectin-3 can modulate branching morphogenesis of the mouse ureteric bud/collecting duct lineage. With the use of immunohistochemistry, galectin-3 was not detected in early metanephrogenesis but was upregulated later in fetal kidney maturation when the protein was prominent in basal domains of medullary collecting ducts. Addition of galectin-3 to embryonic days 11 and 12 whole metanephric cultures inhibited ureteric bud branching, whereas galectin-1 did not perturb morphogenesis, nor did a galectin-3 mutant lacking wild-type high-affinity binding to extended oligosaccharides. Exogenous galectin-3 retarded conversion of renal mesenchyme to nephrons in whole metanephric explants but did not affect nephron induction by spinal cord in isolated renal mesenchymes. Finally, addition of a blocking antiserum to galectin-3 caused dilation and distortion of developing epithelia in embryonic day 12 metanephroi cultured for 1 wk. The upregulation of galectin-3 protein during kidney maturation, predominantly at sites where it could mediate cell/matrix interactions, seems to modulate growth of the ureteric tree.
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PMID:Galectin-3 modulates ureteric bud branching in organ culture of the developing mouse kidney. 1118 99

Prolyl 4-hydroxylase plays a central role in the synthesis of all collagens. We have previously reported that the recently identified Type II isoenzyme is its main form in chondrocytes and possibly in capillary endothelial cells, while Type I is the main form in many other cell types. We report here that the Type II isoenzyme is clearly the main form in capillary endothelial cells and also in cultured umbilical vein endothelial cells, whereas no Type I isoenzyme could be detected in these cells by immunostaining or Western blotting. The Type II isoenzyme was also the main form in cells of the developing glomeruli in the fetal kidney and tubular structures of collecting duct caliber in both fetal and adult kidney, in occasional sinusoidal structures and epithelia of the bile ducts in the liver, and in some cells of the decidual membrane that probably represented invasive cytotrophoblasts in the placenta. Osteoblasts in a fetal calvaria, i.e., a bone developing by intramembranous ossification, stained strongly for both types of isoenzyme. The Type I isoenzyme was the main form in undifferentiated interstitial mesenchymal cells of the developing kidney, for example, and in fibroblasts and fibroblastic cells in many tissues. Skeletal myocytes and smooth muscle cells appeared to have the Type I isoenzyme as their only prolyl 4-hydroxylase form. Hepatocytes expressed small amounts of the Type I enzyme and very little if any Type II, the Type I expression being increased in malignant hepatocytes and cultured hepatoblastoma cells. The data suggest that the Type I isoenzyme is expressed especially by cells of mesenchymal origin and in developing and malignant tissues, whereas the Type II isoenzyme is expressed, in addition to chondrocytes and osteoblasts, by more differentiated cells, such as endothelial cells and cells of epithelial structures. (J Histochem Cytochem 49:1143-1153, 2001)
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PMID:Prolyl 4-hydroxylase isoenzymes I and II have different expression patterns in several human tissues. 1151 83

Urea transport in the kidney is mediated by a family of transporter proteins that includes renal urea transporters (UT-A) and erythrocyte urea transporters (UT-B). Because newborn rats are not capable of producing concentrated urine, we examined the time of expression and the distribution of UT-A and UT-B in the developing rat kidney by light and electron microscopic immunocytochemistry. Kidneys from 16-, 18-, and 20-day-old fetuses, 1-, 4-, 7-, 14-, and 21-day-old pups, and adult animals were studied. In the adult kidney, UT-A was expressed intensely in the inner medullary collecting duct (IMCD) and terminal portion of the short-loop descending thin limb (DTL) and weakly in long-loop DTL in the outer part of the inner medulla. UT-A immunoreactivity was not present in the fetal kidney but was observed in the IMCD and DTL in 1-day-old pups. The intensity of UT-A immunostaining in the IMCD gradually increased during postnatal development. In 4- and 7-day-old pups, UT-A immunoreactivity was present in the DTL at the border between the outer and inner medulla. In 14- and 21-day-old pups, strong UT-A immunostaining was observed in the terminal part of short-loop DTL in the outer medulla, and weak labeling remained in long-loop DTL descending into the outer part of the inner medulla. In the adult kidney, there was intense staining for UT-B in descending vasa recta (DVR) and weak labeling of glomeruli. In the developing kidney, UT-B was first observed in the DVR of a 20-day-old fetus. After birth there was a striking increase in the number of UT-B-positive DVR, in association with the formation of vascular bundles. The intensity of immunostaining remained strong in the outer medulla but gradually decreased in the inner medulla. We conclude that the expression of urea transporters in short-loop DTL and DVR coincides with the development of the ability to produce a concentrated urine.
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PMID:Expression of urea transporters in the developing rat kidney. 1183 36

In a young Wistar rat a bilateral renal malformation was observed microscopically. Clinical chemistry gave no evidence of impaired kidney function. The kidney weight was slightly elevated and the kidneys showed no gross pathological changes. The lesion was located in the inner cortex of both kidneys and consisted of multiple foci of abnormal renal parenchyma similar to fetal kidney. Three components could be distinguished in the foci: primitive glomerular/tubular structures, tubules resembling collecting ducts and mesenchyme. For further characterisation, histological stains (H&E, PAS, Novotny) and immunohistochemistry (vimentin, pan-cytokeratin, S 100, proliferating cell nuclear antigen, and terminal desoxyribosyl-transferase mediated dUTP nick end labelling) were applied. The glomerular and tubular structures were hyperplastic and positive for proliferating cell nuclear antigen and vimentin. The collecting duct-like tubules were positive for pan-cytokeratin and gave no evidence of proliferation. The two epithelial components of the foci were surrounded by mesenchymal cells which extended also between the normal cortical tubules so that no clear demarcation was discernible. The mesenchymal cells were uniformly spindle-shaped and associated with reticulin fibers. Immunohistochemically they were vimentin-positive and non-proliferative. With terminal desoxyribosyl-transferase mediated dUTP nick end labelling (TUNEL) and S 100 all components were nearly negative. Based on morphology and immunohistochemistry this malformation containing structures derived from the ureteric bud and from the metanephric blastema associated with oligonephronia probably represents a noncystic renal dysplasia. Transition to neoplasia was not observed. A specific cause of this unusual developmental anomaly which was not previously reported in rats could not be determined.
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PMID:Bilateral noncystic renal dysplasia in a Wistar-rat. 1271 Jul 12

In renal-coloboma syndrome (RCS), null mutations of the PAX2 gene cause renal hypoplasia due to a congenital deficit of nephrons; affected individuals may develop renal insufficiency in childhood. During normal kidney development, PAX2, is expressed at high levels throughout the arborizing ureteric bud (UB); recent observations suggest that one of its key roles is to suppress apoptosis in this collecting duct lineage. The authors hypothesized that increased UB cell apoptosis due to PAX2 haploinsufficiency must directly influence the rate of branching morphogenesis in developing kidney and the number of nephrons that can be formed before birth, when nephrogenesis in humans comes to an end. If so, the authors reasoned that caspase inhibitors might be used to suppress unwanted UB cell apoptosis during kidney development in Pax2(1Neu) mutant mice and rescue the genetic UB branching defect. E17.5 kidneys from Pax2(1Neu) mutant mice had smaller (-25%) longitudinal cross-sectional area and 3.5-fold increase in collecting duct cell apoptosis versus wild-type littermates; mutant E13.5 kidney explants allowed to arborize for 50 h in vitro had 18% fewer terminal branches than wild-types. However, exposure to the caspase inhibitor, Z-VAD-fmk (25 micro M), significantly increased terminal branch number in mutant explants (23%). It also increased branching in wild-type explants, apparently reflecting an effect of Z-VAD-fmk on basal apoptosis induced by ex vivo culture conditions. Similarly, when pregnant mice were injected daily with Z-VAD-fmk (10 micro g/g weight from E10.5 to E17.5), apoptosis of Pax2(1Neu) fetal collecting duct cells was suppressed to 40% of untreated mutants; by E14, terminal branch number was increased to 152% that of untreated litters. These studies support the hypothesis that PAX2 normally optimizes the rate of branching morphogenesis in fetal kidney by suppressing UB apoptosis. Furthermore, it suggests that caspase inhibitors can rescue the branching defect caused by PAX2 mutations.
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PMID:Rescue of defective branching nephrogenesis in renal-coloboma syndrome by the caspase inhibitor, Z-VAD-fmk. 1474 76

The renal potassium channel ROMK is a crucial element of K+ recycling and secretion in the distal tubule and the collecting duct system. Mutations in the ROMK gene (KCNJ1) lead to hyperprostaglandin E syndrome/antenatal Bartter syndrome, a life-threatening hypokalemic disorder of the newborn. The localization of ROMK channel protein, however, remains unknown in humans. We generated an affinity-purified specific polyclonal anti-ROMK antibody raised against a C-terminal peptide of human ROMK. Immunoblotting revealed a 45 kDa protein band in both rat and human kidney tissue. In human kidney sections, the antibody showed intense staining of epithelial cells in the cortical and medullary thick ascending limb (TAL), the connecting tubule, and the collecting duct. Moreover, a strong expression of ROMK protein was detected in cells of the macula densa. In epithelial cells of the TAL expression of ROMK protein was mainly restricted to the apical membrane. In human fetal kidney expression of ROMK protein was detected mainly in distal tubules of mature nephrons but not or only marginally in the collecting system. No expression was found in early developmental stages such as comma or S shapes, indicating a differentiation-dependent expression of ROMK protein. In summary, these findings support the proposed role of ROMK channels in potassium recycling and in the regulation of K+ secretion and present a rationale for the phenotype observed in patients with ROMK deficiency.
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PMID:Expression of the potassium channel ROMK in adult and fetal human kidney. 1589 41

The human protein kinase X (PRKX) gene was identified previously as a cAMP-dependent serine/threonine kinase that is aberrantly expressed in autosomal dominant polycystic disease kidneys and normally expressed in fetal kidneys. The PRKX kinase belongs to a serine/threonine kinase family that is phylogenetically and functionally distinct from classical protein kinase A kinases. Expression of PRKX activates cAMP-dependent renal epithelial cell migration and tubular morphogenesis in cell culture, suggesting that it might regulate branching growth of the collecting duct system in the fetal kidney. With the use of a mouse embryonic kidney organ culture system that recapitulates early kidney development in vitro, it is demonstrated that lentiviral vector-driven expression of a constitutively active, cAMP-independent PRKX in the ureteric bud epithelium stimulates branching morphogenesis and results in a 2.5-fold increase in glomerular number. These results suggest that PRKX stimulates epithelial branching morphogenesis by activating cell migration and support a role for this kinase in the regulation of nephrogenesis and of collecting system development in the fetal kidney.
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PMID:Protein kinase X activates ureteric bud branching morphogenesis in developing mouse metanephric kidney. 1623 8


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