Gene/Protein Disease Symptom Drug Enzyme Compound
Pivot Concepts: Gene/Protein Disease Symptom Drug Enzyme Compound   Target Concepts: Gene/Protein Disease Symptom Drug Enzyme Compound

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Query: UMLS:C0020438 (hypercalciuria)
2,502 document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)

Dent's disease and familial hypomagnesemia with hypercalciuria and nephrocalcinosis (FHHNC) are inherited diseases in which hypercalciuria, nephrocalcinosis, and renal failure are prominent features. Dent's disease resembles a Fanconi syndrome, with impaired reabsorption in the proximal tubule; FHHNC, with urinary loss of magnesium and calcium, is associated with impaired cation transport in the thick ascending limb of Henle's loop. Gene mapping in families and positional cloning led in both cases to identification of the responsible gene. Dent's disease is associated with mutations that disrupt function of a voltage-gated chloride channel, CLC-5, expressed in subapical endosomes of the proximal tubule and in other nephron segments. Impaired function of this channel disturbs reabsorption of filtered proteins, as well as other transport functions of the proximal tubule, and leads, apparently indirectly, to hypercalciuria and renal failure. FHHNC results from mutations in paracellin-1, a tight-junction protein that appears to be important in conducting or regulating paracellular cation transport. Impaired function of paracellin-1 leads specifically to urinary losses of magnesium and calcium, but because transcellular transport is intact these patients do not have hypokalemia or salt wasting. Identification of both genes represent triumphs of a genetic approach to solving problems of pathophysiology.
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PMID:Inherited hypercalciuric syndromes: Dent's disease (CLC-5) and familial hypomagnesemia with hypercalciuria (paracellin-1). 1473 May 10

Dent's disease, a X-linked hypercalciuric nephrolithiasis, is caused by mutations of the CLCN5 gene. The disease is characterised by low molecular weight proteinuria with variable presence of hypercalciuria, hyperphosphaturia, nephrocalcinosis, and kidney stones. CLCN5 encodes a chloride channel belonging to the voltage-gated chloride channel family, which is predominantly expressed in the endosomes of proximal tubular cells. By shunting the current of electrogenic H+-ATPase, ClC-5 is crucial for efficient acidification of renal endosomes. As shown in knock-out mouse models, the ClC-5 loss of function causes severe impairment of receptor-mediated endocytosis, as well as the endocytotic retrieval of plasma membrane proteins including megalin. In a minority of patients with classical Dent's disease, the analysis of CLCN5 coding sequences failed to identify causative mutations. It is conceivable that mutations in the 5' upstream regulatory regions could impair the correct processing and translation of CLCN5. The complexity of its promoter region seems to support this hypothesis. Molecular diagnosis of Dent's disease is now available; since the risk of developing renal insufficiency in adult life is elevated for this type of nephrolithiasis, the correct diagnosis could potentially modify the natural history of the disease by preventing the evolution towards uraemia.
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PMID:[Dent's disease: hereditary nephrolithiasis related to defective tubular endocytosis processes]. 1473 9

Dent's disease is an inherited tubulopathy caused by a mutation in the CLCN5 chloride channel gene. It is characterized by low-molecular weight proteinuria, hypercalciuria, nephrolithiasis or nephrocalcinosis, rickets and eventual-progressive renal failure. Onset of clinical symptoms show a great variability, making a diagnosis at an early stage of the disease often difficult. Given the variably clinical picture, genetic analysis can provide a reliable method to confirm the diagnosis. Here, we report on the case of a patient with progressive renal failure showing signs of a tubular lesion and symptoms of Dent's disease. Although this rare disease was suspected by means of the clinical features, it was genetic analysis that confirmed the diagnosis and revealed a novel mutation in the CLCN5 gene.
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PMID:Dent's disease: identification of a novel mutation in the renal chloride channel CLCN5. 1557 Nov 86

Dent's disease, a renal tubular disorder characterized by low-molecular-weight proteinuria (LMWP), hypercalciuria, and nephrolithiasis, is due to inactivating mutations in the x-linked renal specific chloride channel CLC-5. CLC-5 belongs to the family of voltage-gated chloride channels, which function as homodimeric proteins with each subunit consisting of 18 helices and a chloride selectivity filter, i.e. pore. None of the 15 CLC-5 missense mutations reported in patients with dent's disease involves the chloride selectivity filter, but 12 of these are clustered around the interface of the two subunits, thereby emphasising the important role for the interaction between the two subunits at the interface of the homodimeric CLC-5. In the kidney, CLC-5 forms part of the receptor-mediated endocytic pathway, and defects in this pathway due to a loss of CLC-5 function, may help to account for the LMWP, hyperphosphaturia, hypercalciuria and nephrolithiasis. The molecular studies and the generation of mouse models of the disease have increased our understanding of the renal tubular mechanisms that regulate mineral homeostasis.
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PMID:Dent's disease--a nephrolithiasis disorder associated with defective receptor-mediated endocytosis. 1561 94

Dent's disease is an hereditary renal tubular disorder characterized by low-molecular-weight (LMW) proteinuria, hypercalciuria and nephrolithiasis. The disease is due to mutations of CLC-5, a member of the family of voltage-gated CLC chloride channels. CLC-5 is distributed in cells lining the proximal tubule (PT) of the kidney, where it co-localizes with albumin-containing endocytic vesicles that form part of the receptor-mediated endocytic pathway that mediates the reabsorption of low-molecular-weight (LMW) proteins filtered at the glomerular level. Since progression along the endocytic apparatus requires endosomal acidification, it has been suggested that dysfunction of CLC-5 in endosomes may lead to inefficient reabsorption of LMW proteins and dysfunction of PT cells. Investigations conducted in a CLC-5 knockout (KO) mouse model harbouring all the characteristic renal tubular defects of Dent's disease showed a severe impairment of endocytosis by PT cells, such that the endocytic tracer peroxidase was poorly transferred into early endocytic vesicles. These data demonstrated that an impairment of receptor-mediated endocytosis in PT cells is the basis for the defective uptake of LMW proteins in patients with Dent's disease. The endocytosis and processing of LMW proteins involves the multiligand tandem receptors, megalin and cubilin, that are abundantly expressed at the brush border of PT cells. The characterization of the endocytic defect in CLC-5 KO mice revealed that ligands of both megalin and cubilin were affected, whereas a decrease in total kidney content of megalin and cubilin at the protein level was detected. Using analytical subcellular fractionation and quantitative immunogold labelling, we demonstrated a selective disappearance of megalin and cubilin at the brush border of PT cells. These observations allowed us to conclude that defective protein endocytosis linked to CLC-5 inactivation is due to a major and selective loss of megalin and cubilin at the brush border, reflecting a trafficking defect in renal PT cells. These results improve our understanding of Dent's disease, taken as a paradigm for renal Fanconi syndrome and nephrolithiasis, and demonstrate multiple roles for CLC-5 in the kidney. These studies also provided insights in important functions such as apical endocytosis, handling of proteins by renal tubular cells, calcium metabolism, and urinary acidification.
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PMID:Chloride channels and endocytosis: new insights from Dent's disease and CLC-5 knockout mice. 1561 95

Dent's disease is a hereditary renal tubular disorder characterized by low-molecular weight (LMW) proteinuria, hypercalciuria and nephrolithiasis. The disease is due to mutations of ClC-5, a member of the family of voltage-gated CLC chloride channels. ClC-5 is expressed in part in cells lining the proximal tubule (PT) of the kidney, where it colocalizes with albumin-containing endocytic vesicles belonging to the receptor-mediated endocytic pathway that ensures efficient reabsorption of ultrafiltrated LMW proteins. Since progression along the endocytic apparatus requires endosomal acidification, it has been suggested that dysfunction of ClC-5 in endosomes may lead to inefficient reabsorption of LMW proteins and dysfunction of PT cells. Analysis of a ClC-5 knockout (KO) mouse model, displaying all the characteristic renal tubular defects of Dent's disease, showed evidence of a severe LMW proteinuria. Cytochemical studies with the endocytic tracer, peroxidase, showed poor transfer into early endocytic vesicles, suggesting that impairment of receptor-mediated endocytosis in PT cells is the basis for the defective uptake of LMW proteins in patients with Dent's disease. Endocytosis and processing of LMW proteins involve the multiligand tandem receptors, megalin and cubilin, that are abundantly expressed at the brush border of PT cells. Characterization of the endocytic defect in ClC-5 KO mice revealed that ligands of both megalin and cubilin were affected. The total kidney content of megalin and especially cubilin at the protein level was decreased but, more importantly, using analytical subcellular fractionation and quantitative immunogold labelling we demonstrated a selective disappearance of megalin and cubilin at the brush border of PT cells. These observations allowed us to conclude that defective protein endocytosis linked to ClC-5 inactivation is due at least in part to a major and selective loss of megalin and cubilin at the brush border, reflecting a trafficking defect in renal PT cells. These results improve our understanding of Dent's disease, taken as a paradigm for renal Fanconi syndrome and nephrolithiasis, and demonstrate multiple roles for ClC-5 in the kidney. These studies also provided insights into important functions such as apical endocytosis, handling of proteins by renal tubular cells, calcium metabolism, and urinary acidification.
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PMID:Chloride channels and endocytosis: new insights from Dent's disease and ClC-5 knockout mice. 1563 24

Dent's disease is a hereditary renal tubular disorder caused by mutations of the CLCN5 gene and is clinically characterized by low molecular weight proteinuria, hypercalciuria and nephrocalcinosis. This disease has been reported in several countries. However, there are some phenotypic differences between countries, such as hypophosphatemic rickets, progressive renal failure and hematuria. In this study, phenotypes were analyzed in three Korean boys with Dent's disease, and genetic diagnoses were performed using a new convenient method using peripheral blood RNA. Gene studies revealed two nonsense mutations, R637X in two patients and E609X in one patient. The phenotypes of the two patients with R637X were very similar to those of Japanese patients, i.e., they presented with asymptomatic proteinuria without rickets, renal failure or hematuria. The E609X patient was diagnosed genetically at 3 months of age before the onset of clinical symptoms because of superimposed furosemide-induced nephrolithiasis. This is the first report to characterize mutations in the CLCN5 gene in Korean patients with Dent's disease, and expands the spectrum of CLCN5 mutations by reporting a novel mutation, E609X. In addition, the mutational analysis using peripheral blood RNA can be easily applied in the clinical diagnosis.
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PMID:Phenotype and genotype of Dent's disease in three Korean boys. 1571 55

ClC-5 chloride channel deficiency causes proteinuria, hypercalciuria, and nephrolithiasis (Dent's disease). Impaired endosomal acidification in proximal tubule caused by reduced chloride conductance is a proposed mechanism; however, functional analysis of ClC-5 in oocytes predicts low ClC-5 chloride conductance in endosomes because of their acid interior pH and positive potential. Here, endosomal pH and chloride concentration were measured in proximal tubule cell cultures from wildtype vs. ClC-5 deficient mice using fluorescent sensors coupled to transferrin (early/recycling endosomes) or alpha(2)-macroglobulin (late endosomes). Initial pH in transferrin-labeled endosomes was approximately 7.2, decreasing at 15 min to 6.0 vs. 6.5 in wildtype vs. ClC-5 deficient cells, respectively; corresponding endosomal chloride concentration increased from approximately 16 mM to 47 vs. 36 mM. In contrast, acidification and chloride accumulation were not impaired in late endosomes or Golgi. Our results provide direct evidence for ClC-5 involvement in acidification of early endosomes in proximal tubule by a chloride shunt mechanism.
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PMID:Impaired acidification in early endosomes of ClC-5 deficient proximal tubule. 1575 47

Knockout mouse models and human inherited diseases have provided important new insights into the physiologic role of chloride transport by CLC Cl(-) channels and KCC K-Cl co-transporters. ClC-K/barrtin Cl(-) channels are important for renal salt reabsorption and possibly for acid secretion by intercalated cells. The endosomal ClC-5 protein is crucial for proximal tubular endocytosis. Its disruption in mice and patients with Dent's disease leads to hypercalciuria and kidney stones through a pathologic cascade that may be entirely explained by an impairment of endocytosis. KCC4 is important for recycling Cl(-) for the basolateral anion exchanger in intercalated cells, as is evident from the renal tubular acidosis resulting from its knockout. Finally, both KCC3 and KCC4 are crucial for proximal tubular cell volume regulation.
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PMID:Chloride transport in the kidney: lessons from human disease and knockout mice. 1582 7

ClC-5 is a member of the ClC family of voltage-gated chloride channels. Loss-of-function mutations of its corresponding gene (CLCN5) cause Dent's disease, an X-linked kidney disorder, characterized by low-molecular weight proteinuria, hypercalciuria, nephrocalcinosis/nephrolithiasis, and progressive renal failure. Here, we examined the effect of different mutations on function and cellular trafficking of the recombinant protein. Mutant CLCN5 cDNAs were generated by site directed mutagenesis for two premature stop codon variants (R347X and M517IfsX528), and several missense mutations (C221R, L324R, G462 V, and R516 W). We also tested L521R (instead of L521RfsX526 observed) and mutants G506E and R648X (previously reported by others). After heterologous expression in Xenopus oocytes, ClC-5 channel activity and surface expression were determined by two-electrode voltage-clamp analysis and ClC-5 surface ELISA, respectively. Except for the R516 W and R648X variants, none of the mutated proteins induced functional chloride currents or reached the plasma membrane. This is readily understandable for the truncation mutations. Yet, the tested missense mutations are distributed over different transmembrane regions, implying that correct channel structure and orientation in the membrane is not only a prerequisite for proper ClC-5 function but also for Golgi exit. Interestingly, the R648X mutant although functionally compromised, displayed a significant increase in surface expression. This finding might be explained by the deletion of a ClC-5 carboxy-terminal PY-like internalization signal, which in turn impairs channel removal from the membrane. Our observations further imply that recruitment of ClC-5 to alternative routes (plasma membrane or early endosomes) in the trans-Golgi network is mediated via different signal sequences.
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PMID:Functional evaluation of Dent's disease-causing mutations: implications for ClC-5 channel trafficking and internalization. 1589 57


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