UMLS:C0022716 - FACTA Search

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Query: UMLS:C0022716 (Menkes)
1,057 document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)

Wilson disease (WD) and Menkes disease (MNK) are inherited disorders of copper metabolism. The genes that mutate to give rise to these disorders encode highly homologous copper transporting ATPases. We use yeast and mammalian two-hybrid systems, along with an in vitro assay to demonstrate a specific, copper-dependent interaction between the six metal-binding domains of the WD and MNK ATPases and the cytoplasmic copper chaperone HAH1. We demonstrate that several metal-binding domains interact independently or in combination with HAH1p, although notably domains five and six of WDp do not. Alteration of either the Met or Thr residue of the HAH1p MTCXXC motif has no observable effect on the copper-dependent interaction, whereas alteration of either of the two Cys residues abolishes the interaction. Mutation of any one of the HAH1p C-terminal Lys residues (Lys(56), Lys(57), or Lys(60)) to Gly does not affect the interaction, although deletion of the 15 C-terminal residues abolishes the interaction. We show that apo-HAH1p can bind in vitro to copper-loaded WDp, suggesting reversibility of copper transfer from HAH1p to WD/MNKp. The in vitro HAH1/WDp interaction is metalospecific; HAH1 preincubated with Cu(2+) or Hg(+) but not with Zn(2+), Cd(2+), Co(2+), Ni(3+), Fe(3+), or Cr(3+) interacted with WDp. Finally, we model the protein-protein interaction and present a theoretical representation of the HAH1p.Cu.WD/MNKp complex.
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PMID:Characterization of the interaction between the Wilson and Menkes disease proteins and the cytoplasmic copper chaperone, HAH1p. 1049 13

Cation-transporting P-type ATPases comprise a major membrane protein family, the members of which are found in eukaryotes, eubacteria, and archaea. A phylogenetically old branch of the P-type ATPase family is involved in the transport of heavy-metal ions such as copper, silver, cadmium, and zinc. In humans, two homologous P-type ATPases transport copper. Mutations in the human proteins cause disorders of copper metabolism known as Wilson and Menkes diseases. E. coli possesses two genes for heavy-metal translocating P-type ATPases. We have constructed an expression system for one of them, ZntA, which encodes a 732 amino acid residue protein capable of transporting Zn(2+). A vanadate-sensitive, Zn(2+)-dependent ATPase activity is present in the membrane fraction of our expression strain. In addition to Zn(2+), the heavy-metal ions Cd(2+), Pb(2+), and Ag(+) activate the ATPase. Incubation of membranes from the expression strain with [gamma-(33)P]ATP in the presence of Zn(2+), Cd(2+), or Pb(2+) brings about phosphorylation of two membrane proteins with molecular masses of approximately 90 and 190 kDa, most likely representing the ZntA monomer and dimer, respectively. Although Cu(2+) can stimulate phosphorylation by [gamma-(33)P]ATP, it does not activate the ATPase. Cu(2+) also prevents the Zn(2+) activation of the ATPase when present in 2-fold excess over Zn(2+). Ag(+) and Cu(+) appear not to promote phosphorylation of the enzyme. To study the effects of Wilson disease mutations, we have constructed two site-directed mutants of ZntA, His475Gln and Glu470Ala, the human counterparts of which cause Wilson disease. Both mutants show a reduced metal ion stimulated ATPase activity (about 30-40% of the wild-type activity) and are phosphorylated much less efficiently by [gamma-(33)P]ATP than the wild type. In comparison to the wild type, the Glu470Ala mutant is phosphorylated more strongly by [(33)P]P(i), whereas the His475Gln mutant is phosphorylated more weakly. These results suggest that the mutation His475Gln affects the reaction with ATP and P(i) and stabilizes the enzyme in a dephosphorylated state. The Glu470Ala mutant seems to favor the E2 state. We conclude that His475 and Glu470 play important roles in the transport cycles of both the Wilson disease ATPase and ZntA.
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PMID:Expression and mutagenesis of ZntA, a zinc-transporting P-type ATPase from Escherichia coli. 1052 59

The delivery of copper to specific sites within the cell is mediated by distinct intracellular carrier proteins termed copper chaperones. Previous studies in Saccharomyces cerevisiae suggested that the human copper chaperone HAH1 may play a role in copper trafficking to the secretory pathway of the cell. In this current study, HAH1 was detected in lysates from multiple human cell lines and tissues as a single-chain protein distributed throughout the cytoplasm and nucleus. Studies with a glutathione S-transferase-HAH1 fusion protein demonstrated direct protein-protein interaction between HAH1 and the Wilson disease protein, which required the cysteine copper ligands in the amino terminus of HAH1. Consistent with these in vitro observations, coimmunoprecipitation experiments revealed that HAH1 interacts with both the Wilson and Menkes proteins in vivo and that this interaction depends on available copper. When these studies were repeated utilizing three disease-associated mutations in the amino terminus of the Wilson protein, a marked diminution in HAH1 interaction was observed, suggesting that impaired copper delivery by HAH1 constitutes the molecular basis of Wilson disease in patients harboring these mutations. Taken together, these data provide a mechanism for the function of HAH1 as a copper chaperone in mammalian cells and demonstrate that this protein is essential for copper homeostasis.
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PMID:Interaction of the copper chaperone HAH1 with the Wilson disease protein is essential for copper homeostasis. 1055 26

Menkes disease is a rare X-linked recessive disorder of copper metabolism, characterised by progressive neurological degeneration, abnormal hair and connective tissue manifestations. We report on a girl with classic Menkes disease, carrying a de novo balanced translocation 46,X,t(X;13)(q13.3; q14.3). The translocation breakpoints at Xq13.3 and 13q14.3 coincide with the Menkes disease and Wilson disease loci, respectively.
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PMID:Clinical expression of Menkes disease in a girl with X;13 translocation. 1058 44

Copper is an essential component of a number of important enzymes. Efficient systems have developed for providing sufficient copper for essential functions, while eliminating excess to avoid tissue toxicity. Copper transport is disrupted in two human diseases: Wilson disease and Menkes disease. Both have defects in copper transporting membrane proteins. Many other proteins are involved in copper transport. Some of these proteins have been identified through a study of the similar copper pathway in yeast. This suggests other copper transport diseases are yet to be discovered. Molecular diagnosis holds promise for reliable diagnosis of patients. Testing of flanking markers is a reliable way to detect presymptomatic sibs of a definite patient.
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PMID:Disorders of copper transport. 1074 45

Copper ion homeostasis is complicated in that copper is an essential element needed for a variety of cellular processes but is toxic at excess levels. To identify Candida albicans genes that are involved in resistance to copper ion toxicity, a library containing inserts of C. albicans genomic DNA was used to complement the copper sensitivity phenotype of a Saccharomyces cerevisiae cup1Delta strain that is unable to produce Cup1p, a metallothionein (MT) responsible for high-level copper ion resistance. A P1-type ATPase (CPx type) that is closely related to the human Menkes and Wilson disease proteins was cloned. The gene encoding this pump was termed CRD1 (for copper resistance determinant). A gene encoding a 76-amino-acid MT similar to higher eukaryotic MTs in structure was also cloned, and the gene was termed CRD2. Transcription of the CRD1 gene was found to increase upon growth with increasing copper levels, while the CRD2 mRNA was expressed at a constant level. Strains with the CRD1 gene disrupted were extremely sensitive to exogenous copper and failed to grow in medium containing 100 microM CuSO(4). These crd1 strains also exhibited increased sensitivity to silver and cadmium, indicating that Crd1p is somewhat promiscuous with respect to metal ion transport. Although strains with the CRD2 gene disrupted showed reduced growth rate with increasing copper concentration, the crd2 mutants eventually attained wild-type levels of growth, demonstrating that CRD2 is less important for resistance to copper ion toxicity. Crd1p is the first example of a eukaryotic copper pump that provides the primary source of cellular copper resistance, and its ability to confer silver resistance may enhance the prevalence of C. albicans as a nosocomial pathogen.
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PMID:Role of a Candida albicans P1-type ATPase in resistance to copper and silver ion toxicity. 1094 34

The transport and cellular metabolism of Cu depends on a series of membrane proteins and smaller soluble peptides that comprise a functionally integrated system for maintaining cellular Cu homeostasis. Inward transport across the plasma membrane appears to be a function of integral membrane proteins that form the channels that select Cu ions for passage. Two membrane-bound Cu-transporting ATPase enzymes, ATP7A and ATP7B, the products of the Menkes and Wilson disease genes, respectively, catalyze an ATP-dependent transfer of Cu to intracellular compartments or expel Cu from the cell. ATP7A and ATP7B work in concert with a series of smaller peptides, the copper chaperones, that exchange Cu at the ATPase sites or incorporate the Cu directly into the structure of Cu-dependent enzymes such as cytochrome c oxidase and Cu, Zn superoxide dismutase. These mechanisms come into play in response to a high influx of Cu or during the course of normal Cu metabolism.
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PMID:Cellular copper transport and metabolism. 1094 Mar 36

The Hah1 metallochaperone protein is implicated in copper delivery to the Menkes and Wilson disease proteins. Hah1 and the N-termini of its target proteins belong to a family of metal binding domains characterized by a conserved MT/HCXXC sequence motif. The crystal structure of Hah1 has been determined in the presence of Cu(I), Hg(II), and Cd(II). The 1.8 A resolution structure of CuHah1 reveals a copper ion coordinated by Cys residues from two adjacent Hah1 molecules. The CuHah1 crystal structure is the first of a copper chaperone bound to copper and provides structural support for direct metal ion exchange between conserved MT/HCXXC motifs in two domains. The structures of HgHah1 and CdHah1, determined to 1.75 A resolution, also reveal metal ion coordination by two MT/HCXXC motifs. An extended hydrogen bonding network, unique to the complex of two Hah1 molecules, stabilizes the metal binding sites and suggests specific roles for several conserved residues. Taken together, the structures provide models for intermediates in metal ion transfer and suggest a detailed molecular mechanism for protein recognition and metal ion exchange between MT/HCXXC containing domains.
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PMID:Structural basis for copper transfer by the metallochaperone for the Menkes/Wilson disease proteins. 1096 47

Copper (Cu) is an essential trace element and constitutes the active center of the redox Cu enzymes such as Cu, Zn-superoxide dismutase (Cu, Zn-SOD), ceruloplasmin and cytochrome c oxidase. Among hereditary diseases due to a defect in the metabolism of Cu, Menkes disease (caused by a Cu deficiency) and Wilson disease (caused by the excessive accumulation of Cu) have been shown to be caused by the mutation of genes encoding Cu-binding ATPase for the efflux of Cu, ATP7A and ATP7B, respectively. Following the identification of these causative genes, intracellular Cu transporters (Cu chaperones) specific for the Golgi apparatus, mitochondria and Cu, Zn-SOD were discovered, and these findings have facilitated the study of the underlying mechanisms of the biological regulation of Cu. Apart from these physiological and biochemical studies, toxicological studies have elucidated the underlying mechanisms of the occurrence of acute hepatitis caused by the accumulation of Cu accumulating in the liver of an animal model for Wilson disease, LEC rats. In these toxicological studies, two biological aspects of metallothionein (MT), i.e., antioxidant and prooxidant depending on the Cu/Zn ratio in Cu-containing MT have been proposed. The present article overviews the recent findings on the biological regulation of Cu and on the toxicological aspect of Cu. It is known that Cu forms a stable ternary complex with molybdenum and sulfur under reductive conditions in the body. On the basis of this observation, tetrathiomolybdate (TTM) has been applied to remove Cu from the liver of Long-Evans rats with a cinnamon-like coat color (LEC) rats. Precise mechanisms underlying the complex formation between Cu bound to MT and TTM were presented, and an appropriate protocol for the chelation therapy was also proposed together with the mechanisms underlying the occurrence of side-effects.
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PMID:[Biological regulation of copper and selective removal of copper: therapy for Wilson disease and its molecular mechanism]. 1108 2

Wilson disease is an autosomal recessive copper transport disorder resulting from defective biliary excretion of copper and subsequent hepatic copper accumulation and liver failure if not treated. The disease is caused by mutations in the ATP7B (WND) gene, which is expressed predominantly in the liver and encodes a copper-transporting P-type ATPase that is structurally and functionally similar to the Menkes protein (MNK), which is defective in the X-linked copper transport disorder Menkes disease. The toxic milk (tx) mouse has a clinical phenotype similar to Wilson disease patients and, recently, the tx mutation within the murine WND homologue (WND:) of this mouse was identified, establishing it as an animal model for Wilson disease. In this study, cDNA constructs encoding the wild-type (Wnd-wt) and mutant (Wnd-tx) Wilson proteins (Wnd) were generated and expressed in Chinese hamster ovary (CHO) cells. The tx mutation disrupted the copper-induced relocalization of Wnd in CHO cells and abrogated Wnd-mediated copper resistance of transfected CHO cells. In addition, co-localization experiments demonstrated that while Wnd and MNK are located in the trans-Golgi network in basal copper conditions, with elevated copper, these proteins are sorted to different destinations within the same cell. Ultrastructural studies showed that with elevated copper levels, Wnd accumulated in large multi-vesicular structures resembling late endosomes that may represent a novel compartment for copper transport. The data presented provide further support for a relationship between copper transport activity and the copper-induced relocalization response of mammalian copper ATPases, and an explanation at a molecular level for the observed phenotype of tx mice.
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PMID:Effect of the toxic milk mutation (tx) on the function and intracellular localization of Wnd, the murine homologue of the Wilson copper ATPase. 1115 99

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