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)

Various inherited disorders of copper metabolism in man and animals are reviewed. Emphasis is placed on the use of cultured cells from mutants to determine the primary molecular defects and to acquire basic knowledge of normal copper metabolism. This allows better diagnostic tests and possible treatment of the disorders. Menkes' disease in humans and mottled mouse mutants are discussed in detail, as they illustrate these approaches.
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PMID:Mutations in humans and animals which affect copper metabolism. 613 94

Menkes disease and Wilson disease are human disorders of copper metabolism. It has recently been shown that both are due to mutations in P-type ATPase copper transport molecules. Related heavy metal transporting ATPases have been described in several strains of bacteria. In an effort to isolate other mammalian metal transporters, we screened a human small intestine library with probes homologous to conserved sequences in the known proteins. Two novel cDNAs were isolated, which encode new members of this family. Surprisingly, they were both of bacterial origin, most likely derived from E. coli sequences transduced during library construction.
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PMID:Novel bacterial P-type ATPases with histidine-rich heavy-metal-associated sequences. 781 Dec 48

In this review we discuss four genetic disorders of copper metabolism. Wilson's disease and Indian childhood cirrhosis result from the toxic effects of copper accumulation in the liver. Menkes' disease and, most likely, occipital horn syndrome result from copper deficiency secondary to disturbances in copper transport. The recent cloning and sequencing of the genes defective in Wilson's disease and Menkes' disease provide the molecular basis for understanding the causes of the two major disorders of copper transport in humans. Mutations that result in Wilson's and Menkes' diseases were shown to disrupt the function of two related P-type copper transporting ATPases. Genetic analysis demonstrates that Wilson's disease and, probably, Menkes' disease are caused by a number of different mutations within a single gene (allelic heterogeneity), and that this occurrence likely explains the clinical heterogeneity of both diseases. The possibility that different mutations within the same gene account for the similar phenotypes of Wilson's disease and Indian childhood cirrhosis on the one hand and for Menkes' disease and occipital horn syndrome on the other are discussed.
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PMID:Genetic disorders of copper metabolism. 784 17

The Menkes ATPase is the product of the MNK gene, defective in some inherited human disorders of copper metabolism. We here show the formation of an acylphosphate intermediate by the murine MNK homologue in membranes from normal and copper resistant Chinese hamster ovary cells. In the latter, fivefold higher levels of acylphosphate were formed. Challenging these cells with copper, which induces relocation of the MNK ATPase from the trans-Golgi network to the plasma membrane, did not influence acylphosphate formation. The kinetics of phosphorylation, metal dependence, and sensitivity to inhibitors were investigated. The results show that the MNK ATPase is an active P-type ATPase and provide a direct functional test for this enzyme.
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PMID:Acylphosphate formation by the Menkes copper ATPase. 925 13

Cloning of the gene defective in the X-linked neurodegenerative disorder Menkes disease led to a cascade of new findings. Besides giving a better understanding of the intracellular copper homeostasis, these findings had important consequences from a clinical point of view. Today the underlying genetic defect has been described in several patients affected by one of the three hereditary disorders of copper metabolism: Menkes disease, occipital horn syndrome and wilson disease. In this review we discuss mainly Menkes disease and the impact of the recent findings on the diagnosis of this disorder.
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PMID:Menkes disease: underlying genetic defect and new diagnostic possibilities. 972 40

Copper is an essential transition metal that permits the facile transfer of electrons in a series of critical biochemical pathways. Menkes disease and Wilson's disease are inherited disorders of copper metabolism resulting from the absence or dysfunction of homologous copper-transporting ATPases that reside in the trans-Golgi network of all cells. Despite striking differences in the clinical presentation of these two diseases, the respective ATPases function in precisely the same manner within the cell and the unique clinical features of each disease are entirely the result of the tissue-specific expression of each protein. Elucidation of the basic defect in these rare genetic disorders has provided a valuable heuristic paradigm for understanding the mechanisms of cellular copper homeostasis.
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PMID:Genetic disorders of membrane transport. IV. Wilson's disease and Menkes disease. 995 Aug 3

Copper is an essential trace metal which plays a fundamental role in the biochemistry of the human nervous system. Menkes disease and Wilson disease are inherited disorders of copper metabolism and the dramatic neurodegenerative phenotypes of these two diseases underscore the essential nature of copper in nervous system development as well as the toxicity of this metal when neuronal copper homeostasis is perturbed. Ceruloplasmin contains 95% of the copper found in human plasma and inherited loss of this essential ferroxidase is associated with progressive neurodegeneration of the retina and basal ganglia. Gain-of-function mutations in the cytosolic copper enzyme superoxide dismutase result in the motor neuron degeneration of amyotrophic lateral sclerosis and current evidence suggests a direct pathogenic role for copper in this process. Recent studies have also implicated copper in the pathogenesis of neuronal injury in Alzheimer's disease and the prion-mediated encephalopathies, suggesting that further elucidation of the mechanisms of copper trafficking and metabolism within the nervous system will be of direct relevance to our understanding of the pathophysiology and treatment of neurodegenerative disease.
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PMID:The role of copper in neurodegenerative disease. 1044 50

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

Copper is an essential trace element, but its redox reactivity leads to risks of damage to cell and tissues. These are well exemplified by several forms of neurodegenerative diseases, either arising as inherited disorders of copper metabolism, such as Menkes' and Wilson's disease, or as conformational diseases such as Alzheimer's disease and prion diseases. This review will cover some aspects of the involvement of copper-mediated oxidative stress in degenerative processes in the central nervous system, with special focus on the familial form of amyotrophic lateral sclerosis (FALS). Furthermore, a possible role of copper reactivity in inducing critical steps in the apoptotic pathways leading to neurodegeneration is envisaged.
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PMID:Copper-dependent oxidative stress and neurodegeneration. 1132 25

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