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)

Metallothionein biosynthesis is not induced by extracellular copper in Menkes Kinky hair disease (MKHD) or in normal cultured fibroblasts under the conditions of these experiments. In the presence of copper, MKHD fibroblasts also incorporated less cysteine than did normal fibroblasts. Extracellular cadmium greatly enhanced the uptake of cysteine in both normal and MKHD cultures. By the technique of polyacrylamide gel electrophoresis, it was demonstrated that metallothionein is induced by cadmium in normal and MKHD-cultured fibroblasts.
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PMID:Inducibility of metallothionein biosynthesis in cultured normal and Menkes kinky hair disease fibroblasts: effects of copper and cadmium. 47 76

Metallothioneins are a family of ubiquitous, cysteine rich proteins, whose amino acidic and genomic sequences have been highly conserved during evolution. MT synthesis is induced by heavy metals, glucocorticoids and a bacterial lipopolysaccharide in vivo and in vitro. MT forms stable complexes with heavy metals. One MTIIA gene, four MTI class genes and five pseudogenes have been isolated in humans. The cluster of MT genes is located on chromosome 16. The cloned, transfected genes retain metal inducibility. The first 150 bp of the 5' flanking region of mouse and human MT genes are essential for transcription and metal regulation. Two control regions have been identified. The distal region, between -151 and -78 is essential for efficient transcription and binding of cellular factor(s) which regulates MT gene expression. In Menkes' disease, a lethal X-linked recessive disorder, copper accumulates intracellularly bound to MT. Low doses of copper induce MT synthesis in Menkes' fibroblasts, but not in normal controls. Transfection experiments using the mouse MTI promoter fused to CAT show that the effect of copper in MT transcription is in trans. Menkes' cells are more sensitive to copper than normal controls and respond to copper poisoning by synthesizing two heat-shock like proteins. A mutation affecting copper transport or metabolism is discussed.
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PMID:Metallothionein gene regulation in Menkes' disease. 353 Sep 53

Metallothionein is a cysteine-rich, low molecular weight protein that binds zinc, copper and cadmium. It is inducible in liver, kidney and intestine by glucocorticoids, changes in the dietary zinc supply, acute administration of various metals, food restriction, infection, stress and endotoxin treatment. Regulation of synthesis involves altered gene expression. The protein is fairly rapidly degraded when zinc is the primary metal species bound, but the degradation rate is diminished when cadmium or copper are bound as well. The net result of metallothionein production seems to be accumulation of bound metal and/or intracellular metal redistribution. The accumulation of copper in various tissues of individuals with Menkes' and Wilson's diseases may be related to altered metallothionein turnover. The physiological function is not clear, but the response of metallothionein to hormonal stimuli is suggestive of an important role in cellular metabolism.
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PMID:Metallothionein--aspects related to copper and zinc metabolism. 641 69

Menkes fibroblasts contain a significantly greater amount of cysteine-rich 10,000 dalton copper-binding protein(s) (metallotheionein) than normal cells. Mutant fibroblasts incorporated 30 to 40% more tritiated amino acids into 10,000 dalton protein(s) than normal cells. The protein(s) was deficient in aromatic amino acids The amount of 35S-cysteine incorporated by the same protein(s) in Menkes fibroblasts was twice that of normal fibroblasts. Comparison of the 35 S:3H isotopic ratios of chromatographic fractions of both normal and Menkes cell lysates showed that only the proteins eluted in the 10,000 dalton peak were enriched in 35S-cysteine, and this ratio was always greater than in Menkes than in normal cells. The 10,000 molecular weight 35S-cysteine- and 3H-amino acid-labeled peaks coincided with the 64Cu peak in both cell strains. The copper-labeled peak was always greater in Menkes than in normal cells. No difference in the 64Cu:35S isotopic ratio in the 10,000 dalton peak was observed between normal and Menkes fibroblast strains. This finding shows the direct relationship between the amount of cysteine-rich 10,000 dalton protein(s) and the amount of 64Cu bound by this protein(s) in both Menkes and normal fibroblasts. DEAE-cellulose ion-exchange chromatography resulted in a further two-fold enrichment of the 10,000 dalton, sulfur-rich proteins that were eluted from the Sephadex G-75 column. Most of the labeled proteins from both normal and Menkes fibroblasts were eluted from the ion-exchange column in a single peak at a chloride concentration of approximately 30 mM. Polyacrylamide disc gel electrophoresis of pooled fractions of the 10,000 dalton proteins eluted from the G-75 column and the DEAE-cellulose ion-exchange column showed no consistent differences in the staining pattern between normal and mutant fibroblast strains. When th acrylamide gels were sliced and subsequently counted for radioactive content, no band showed a further increase in the 35 S:3H isotopic ratio when compared to the electrophoresed samples that were eluted from the Sephadex G-75 or the ion-exchange columns. Also, no significant increase in the amount of radioactivity associated with a specific protein band could be demonstrated between the Menkes and the normal fibroblast strains.
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PMID:Increased copper metallothionein in Menkes cultured skin fibroblasts. 722 Jan 48

Bacterial plasmids contain specific genes for resistances to toxic heavy metal ions including Ag+, AsO2-, AsO4(3-), Cd2+, Co2+, CrO4(2-), Cu2+, Hg2+, Ni2+, Pb2+, Sb3+, and Zn2+. Recent progress with plasmid copper-resistance systems in Escherichia coli and Pseudomonas syringae show a system of four gene products, an inner membrane protein (PcoD), an outer membrane protein (PcoB), and two periplasmic Cu(2+)-binding proteins (PcoA and PcoC). Synthesis of this system is governed by two regulatory proteins (the membrane sensor PcoS and the soluble responder PcoR, probably a DNA-binding protein), homologous to other bacterial two-component regulatory systems. Chromosomally encoded Cu2+ P-type ATPases have recently been recognized in Enterococcus hirae and these are closely homologous to the bacterial cadmium efflux ATPase and the human copper-deficiency disease Menkes gene product. The Cd(2+)-efflux ATPase of gram-positive bacteria is a large P-type ATPase, homologous to the muscle Ca2+ ATPase and the Na+/K+ ATPases of animals. The arsenic-resistance system of gram-negative bacteria functions as an oxyanion efflux ATPase for arsenite and presumably antimonite. However, the structure of the arsenic ATPase is fundamentally different from that of P-type ATPases. The absence of the arsA gene (for the ATPase subunit) in gram-positive bacteria raises questions of energy-coupling for arsenite efflux. The ArsC protein product of the arsenic-resistance operons of both gram-positive and gram-negative bacteria is an intracellular enzyme that reduces arsenate [As(V)] to arsenite [As(III)], the substrate for the transport pump. Newly studied cation efflux systems for Cd2+, Zn2+, and Co2+ (Czc) or Co2+ and Ni2+ resistance (Cnr) lack ATPase motifs in their predicted polypeptide sequences. Therefore, not all plasmid-resistance systems that function through toxic ion efflux are ATPases. The first well-defined bacterial metallothionein was found in the cyanobacterium Synechococcus. Bacterial metallothionein is encoded by the smtA gene and contains 56 amino acids, including nine cysteine residues (fewer than animal metallothioneins). The synthesis of Synechococcus metallothionein is regulated by a repressor protein, the product of the adjacent but separately transcribed smtB gene. Regulation of metallothionein synthesis occurs at different levels; quickly by derepression of repressor activity, or over a longer time by deletion of the repressor gene at fixed positions and by amplification of the metallothionein DNA region leading to multiple copies of the gene.
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PMID:Newer systems for bacterial resistances to toxic heavy metals. 784 81

Bacterial plasmids encode resistance systems for toxic metal ions including Ag+, AsO2-, AsO4(3-), Cd2+, CO2+, CrO4(2-), Cu2+, Hg2+, Ni2+, Pb2+, Sb3+, TeO3(2-), Tl+, and Zn2+. In addition to understanding of the molecular genetics and environmental roles of these resistances, studies during the last few years have provided surprises and new biochemical mechanisms. Chromosomal determinants of toxic metal resistances are known, and the distinction between plasmid resistances and those from chromosomal genes has blurred, because for some metals (notably mercury and arsenic), the plasmid and chromosomal determinants are basically the same. Other systems, such as copper transport ATPases and metallothionein cation-binding proteins, are only known from chromosomal genes. The largest group of metal resistance systems function by energy-dependent efflux of toxic ions. Some of the efflux systems are ATPases and others are chemiosmotic cation/proton antiporters. The CadA cadmium resistance ATPase of gram-positive bacteria and the CopB copper efflux system of Enterococcus hirae are homologous to P-type ATPases of animals and plants. The CadA ATPase protein has been labeled with 32P from gamma-32P-ATP and drives ATP-dependent Cd2+ uptake by inside-out membrane vesicles. Recently isolated genes defective in the human hereditary diseases of copper metabolism, Menkes syndrome and Wilson's disease, encode P-type ATPases that are more similar to the bacterial CadA and CopB ATPases than to eukaryote ATPases that pump different cations. The arsenic resistance efflux system transports arsenite, using alternatively either a two-component (ArsA and ArsB) ATPase or a single polypeptide (ArsB) functioning as a chemiosmotic transporter. The third gene in the arsenic resistance system, arsC, encodes an enzyme that converts intracellular arsenate [As (V)] to arsenite [As (III)], the substrate of the efflux system. The three-component Czc (Cd2+, Zn2+, and CO2+) chemiosmotic efflux pump of soil microbes consists of inner membrane (CzcA), outer membrane (CzcC), and membrane-spanning (CzcB) proteins that together transport cations from the cytoplasm across the periplasmic space to the outside of the cell. Finally, the first bacterial metallothionein (which by definition is a small protein that binds metal cations by means of numerous cysteine thiolates) has been characterized in cyanobacteria.
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PMID:Bacterial heavy metal resistance: new surprises. 890 98

N-terminal domains of the Wilson's and Menkes disease proteins (N-WND and N-MNK) were overexpressed in a soluble form in Escherichia coli as fusions with maltose-binding protein, purified, and their metal-binding properties were characterized. Both N-MNK and N-WND bind copper specifically as indicated by the results of metal-chelate chromatography, direct copper-binding measurements, and chemical modification of Cys residues in the presence of different heavy metals. When E. coli cells are grown in the presence of copper, N-MNK and N-WND bind copper in vivo with stoichiometry of 5-6 nmol of copper/nmol of protein. Copper released from the copper-N-MNK and copper-N-WND complexes reacts with the Cu(I)-selective chelator bicinchoninic acid in the absence of reducing agents. This suggests that in proteins, it is bound in reduced Cu(I) form, in agreement with the spectroscopic properties of the copper-bound domains. Copper bound to the domains in vivo or in vitro specifically protects the N-MNK and N-WND against labeling with the cysteine-directed probe; this indicates that Cys residues in the repetitive motifs GMTCXXCXXXIE are involved in coordination of copper. Direct involvement of the N-terminal domains in the binding of copper suggests their important role in copper-dependent functions of human copper-transporting adenosine triphosphatases (Wilson's and Menkes disease proteins).
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PMID:N-terminal domains of human copper-transporting adenosine triphosphatases (the Wilson's and Menkes disease proteins) bind copper selectively in vivo and in vitro with stoichiometry of one copper per metal-binding repeat. 922 74

Menkes disease is a fatal neurodegenerative disorder of childhood caused by the absence or dysfunction of a putative P-type ATPase encoded on the X chromosome. To elucidate the function of the Menkes disease protein, a plasmid containing the open reading frame of the human Menkes disease gene was constructed and used to transform a strain of Saccharomyces cerevisiae deficient in CCC2, the yeast Menkes/Wilson disease gene homologue. ccc2Delta yeast are deficient in copper transport into the secretory pathway, and expression of a wild type human Menkes cDNA complemented this defect, as evidenced by the restoration of copper incorporation into the multicopper oxidase Fet3p. Site-directed mutagenesis demonstrated the essential role of four specific amino acids in this process, including a conserved histidine, which is the site of the most common disease mutation in the homologous Wilson disease protein. The expression of Menkes cDNAs with successive mutations of the conserved cysteine residues in the six amino-terminal MXCXXC metal binding domains confirmed the essential role of these cysteine residues in copper transport but revealed that each of these domains is not functionally equivalent. These data demonstrate that the Menkes disease protein functions to deliver copper into the secretory pathway of the cell and that this process involves biochemical mechanisms common to previously characterized members of this P-type ATPase family.
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PMID:Functional expression of the menkes disease protein reveals common biochemical mechanisms among the copper-transporting P-type ATPases. 945 9

The Menkes protein (MNK or ATP7A) is a transmembrane, copper-transporting CPX-type ATPase, a subgroup of the extensive family of P-type ATPases. A striking feature of the protein is the presence of six metal binding sites (MBSs) in the N-terminal region with the highly conserved consensus sequence GMXCXXC. MNK is normally located in the trans-Golgi network (TGN) but has been shown to relocalize to the plasma membrane when cells are cultured in media containing high concentrations of copper. The experiments described in this report test the hypothesis that the six MBSs are required for this copper-induced trafficking of MNK. Site-directed mutagenesis was used to convert both cysteine residues in the conserved MBS motifs to serines. Mutation of MBS 1, MBS 6, and MBSs 1-3 resulted in a molecule that appeared to relocalize normally with copper, but when MBSs 4-6 or MBSs 1-6 were mutated, MNK remained in the TGN, even when cells were exposed to 300 microM copper. Furthermore, the ability of the MNK variants to relocalize corresponded well with their ability to confer copper resistance. To further define the critical motifs, MBS 5 and MBS 6 were mutated, and these changes abolished the response to copper. The region from amino acid 8 to amino acid 485 was deleted, resulting in mutant MNK that lacked 478 amino acids from the N-terminal region, including the first four MBSs. This truncated molecule responded normally to copper. Moreover, when either one of the remaining MBS 5 and MBS 6 was mutated to GMXSXXS, the resulting proteins were localized to the TGN in low copper and relocalized in response to elevated copper. These experiments demonstrated that the deleted N-terminal region from amino acid 8 to amino acid 485 was not essential for copper-induced trafficking and that one MBS close to the membrane channel of MNK was necessary and sufficient for the copper-induced redistribution.
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PMID:The role of GMXCXXC metal binding sites in the copper-induced redistribution of the Menkes protein. 1019 2

The cDNA, coding for the first metal-binding domain (MBD1) of Menkes protein, was cloned into the T7-system based vector, pCA. The T7 lysozyme-encoding plasmid, pLysS, is shown to be crucial for expression, suggesting that the protein is toxic to the cells. Adding copper to the growth medium did not affect the plasmid stability. MBD1 is purified in two steps with a typical yield of 12 mg.L-1. Menkes protein, a P-type ATPase, contains a sequence GMXCXSC that is repeated six times, at the N-terminus. The paired cysteine residues are involved in metal binding. MBD1 has only two cysteine residues, which can exist as free thiol groups (reduced), as a disulphide bond (oxidized) or bound to a metal ion [e.g. Cu(I)-MBD1]. These three MBD1 forms have been investigated using CD. No major spectral change was seen between the different MBD1 forms, indicating that the folding is not changed upon metal binding. A copper-bound MBD1 was also studied by EPR, and the lack of an EPR signal suggests that the oxidation state of copper bound to MBD1 is Cu(I). Cu(I) binding studies were performed by equilibrium dialysis and revealed a stoichiometry of 1 : 1 and an apparent Kd = 46 microM. Oxidized MBD1, however, is not able to bind copper. Different copper complexes were investigated for their ability to reconstitute apo-MBD1. Given the same total copper concentration CuCl43- was superior to Cu(I)-thiourea (structural analogue of metallothionein) and Cu(I)-glutathione (used at fivefold higher copper concentration) although the latter two were able to partially reconstitute apo-MBD1. Cu(II) was not able to reconstitute apo-MBD1, presumably due to Cu(II)-induced oxidation of the thiol groups. Based on our results, glutathione and/or metallothionein are likely candidates for the in vivo incorporation of copper to Menkes protein.
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PMID:Expression, purification and copper-binding studies of the first metal-binding domain of Menkes protein. 1049 Nov 37

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