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)

Previously, we showed that the transport of Cu by PC12 pheochromocytoma cells and C6 glioma cells correlated with the expression of a Cu-transporting ATPase (Atp7a) that has been linked to Menkes disease. Here, we show that cerebrovascular endothelial (CVE) cells that comprise the blood-brain barrier (BBB) also express the gene for the Cu-ATPase. By using reverse transcription-polymerase chain reaction (RT-PCR) and primers designed from mouse Atp7a cDNA, we amplified a 925-bp and a 760-bp cDNA fragment from two extreme regions of Atp7a mRNA from murine CVE cells; 777 bp of the 925-bp fragment and 677 bp of the 760-bp fragment had a 99.7 and 100% sequence homology, respectively, with mouse Atp7a cDNA. The 777-bp sequences covered the heavy metal binding (Hmb) domain and the 677-bp fragment coded for residues at the -COOH terminus of Atp7a. A functional analysis showed that Cu efflux was blocked by the sulfhydryl reagent p-chloromercuribenzoate (p-CMB), a potential inhibitor of Atp7a function. This study provides strong evidence that a Cu-ATPase in the BBB controls the penetration of Cu into the brain and that lesions to the Cu-ATPase in CVE cells are a primary cause of low brain Cu levels in Menkes disease.
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PMID:Copper efflux from murine microvascular cells requires expression of the menkes disease Cu-ATPase. 968 44

We isolated cDNA fragments from four human cell lines that had sequences for the Menkes Cu-transporting ATPase (ATP7A). Primers designed to generate a 4.8 kb cDNA with the complete open reading frame generated a 1.9 kb cDNA in addition to the expected 4.8 kb product. Sequence analysis revealed that the 1.9 kb cDNA encoded one of the six Cu-binding sites and two of the eight transmembrane domains of ATP7A. Stop and start codons were also present. More striking, however, was an unusual union between exons 2 and 16 that retained an in-frame reference to exon 23. The 1.9 kb cDNA thus appeared to be a truncated Menkes mRNA that coded for an ATP7A variant that lacked exons 3-15. A 530 bp probe specific for exon 23 that avoided sequences in the exon 3-15 region hybridized to a 5.5 kb band on Northern blot analysis. Western blotting provided immunochemical evidence for the presence of both a 170 kDa and a 57 kDa protein with ATP7A sequences in detergent extracts of Caco-2 and induced BeWo cells. Extracts from non-induced BeWo cells, which lack the capacity to express the Menkes gene (MNK), showed neither protein. In a cell-free reticulocyte lysate, a plasmid containing the 1.9 kb cDNA insert directed the synthesis of a 59 kDa protein with antigenic properties of ATP7A. These studies provide evidence that non-Menkes cells have the capacity to synthesize more than one MNK mRNA. The one characterized in this report codes for a 57-59 kDa protein that lacks the core structure of the ATP7A protein. The smaller variant could be an alternative spliced form of MNK mRNA.
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PMID:Multiple transcripts coding for the menkes gene: evidence for alternative splicing of Menkes mRNA. 969 4

Wilson disease is an autosomal recessive disorder of hepatic copper metabolism caused by mutations in a gene encoding a copper-transporting P-type ATPase. To elucidate the function of the Wilson protein, wild-type and mutant Wilson cDNAs were expressed in a Menkes copper transporter-deficient mottled fibroblast cell line defective in copper export. Expression of the wild-type cDNA demonstrated trans-Golgi network localization and copper-dependent trafficking of the Wilson protein identical to previous observations for the endogenously expressed protein in hepatocytes. Furthermore, expression of the Wilson cDNA rescued the mottled phenotype as evidenced by a reduction in copper accumulation and restoration of cell viability. In contrast, expression of an H1069Q mutant Wilson cDNA did not rescue the mottled phenotype, and immunofluorescence studies showed that this mutant Wilson protein was localized in the endoplasmic reticulum. Consistent with these findings, pulse-chase analysis demonstrated a 5-fold decrease in the half-life of the H1069Q mutant as compared with the wild-type protein. Maintenance of these transfected cell lines at 28 degreesC resulted in localization of the H1069Q protein in the trans-Golgi network, suggesting that a temperature-sensitive defect in protein folding followed by degradation constitutes the molecular basis of Wilson disease in patients harboring the H1069Q mutation. Taken together, these studies describe a tractable expression system for elucidating the function and localization of the copper-transporting ATPases in mammalian cells and provide compelling evidence that the Wilson protein can functionally substitute for the Menkes protein, supporting the concept that these proteins use common biochemical mechanisms to effect cellular copper homeostasis.
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PMID:Functional expression of the Wilson disease protein reveals mislocalization and impaired copper-dependent trafficking of the common H1069Q mutation. 972 94

The Menkes (MNK) protein is a vital component of copper homeostasis in mammalian cells. In this paper we provide the first biochemical evidence that the MNK protein functions as a copper-translocating P-type ATPase in mammalian cells. The enzyme activity in membrane vesicles prepared from Chinese hamster ovary cells overexpressing MNK was ATP-dependent, correlated with the amount of MNK and followed Michaelis-Menten kinetics with respect to copper. The copper transport was observed only under reducing conditions suggesting MNK transports Cu(I). This study opens the way to detailed structure-function studies and assessment of functional MNK derived from patients with Menkes disease.
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PMID:ATP-dependent copper transport by the Menkes protein in membrane vesicles isolated from cultured Chinese hamster ovary cells. 976 3

Menkes' disease is a fatal, X-linked, copper deficiency disorder that results from defective copper efflux from intestinal cells and inadequate copper delivery to other tissues, leading to deficiencies of critical copper-dependent enzymes. Wilson's disease is an autosomally inherited, copper toxicosis disorder resulting from defective biliary excretion of copper, which leads to copper accumulation in the liver. The ATP7A and ATP7B genes that are defective in patients with Menkes' and Wilson's diseases, respectively, encode transmembrane, P-type ATPase proteins (ATP7A or MNK and ATP7B or WND, respectively) that function to translocate copper across cellular membranes. In this study, the cDNAs derived from a normal human ATP7A gene and the murine ATP7B homologue, Atp7b, were separately transfected into an immortalized fibroblast cell line obtained from a Menkes' disease patient. Both MNK and WND expressed from plasmid constructs were able to correct the copper accumulation and copper retention phenotype of these cells. However, the two proteins responded differently to elevated extracellular copper levels. Although MNK showed copper-induced trafficking from the trans-Golgi network to the plasma membrane, in the same cell line the intracellular location of WND did not appear to be affected by elevated copper.
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PMID:Correction of the copper transport defect of Menkes patient fibroblasts by expression of the Menkes and Wilson ATPases. 981 47

The human X-linked recessive disorder of copper metabolism, Menkes disease, is caused by a defect in the MNK ( ATP7A ) gene which encodes a transmembrane copper-transporting P-type ATPase (MNK). MNK is an important component of the mammalian copper transport pathway, and previous studies in cultured cells have localized MNK to the final compartment of the Golgi apparatus, the trans -Golgi network (TGN). At this location, MNK is predicted to supply copper to copper-dependent enzymes as they migrate through the secretory pathway. However, under conditions of elevated extracellular copper, the MNK protein undergoes a rapid relocalization to the plasma membrane where it functions in the efflux of copper from cells. In this study, three di-leucine motifs and a cluster of four acidic amino acids within the C-terminal region of MNK were investigated as candidate signals necessary for steady-state TGN localization. In vitro mutagenesis of the human MNK cDNA and immunofluorescence detection of mutant forms of MNK expressed in cultured cells demonstrated that the di-leucine, L1487L1488, was essential for localization of MNK within the TGN, but not for copper efflux. We suggest that this di-leucine motif is a putative endocytic targeting motif necessary for the retrieval of MNK from the plasma membrane to the TGN. Our data, along with the recent demonstration that the third transmembrane region of MNK functions as a TGN targeting signal, suggests that MNK localization to the TGN may be a two-step process involving TGN retention via the transmembrane region, and recycling to this compartment from the plasma membrane via the L1487L1488 motif.
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PMID:A C-terminal di-leucine is required for localization of the Menkes protein in the trans-Golgi network. 981 23

The metabolism of Cu is intimately linked with its nutrition. From gut to enzymes, Cu bioavailability to key enzymes and other components operates through a complex mechanism that uses transport proteins as well as small molecular weight ligands. Steps in Cu transport through the blood, absorption by cells, and incorporation into enzymes are slowly being understood. Cloning and sequencing of the genes for Menkes disease and Wilson disease has shown that membrane-bound enzymes analogous to Cu-ATPases in prokaryotes are equally important to Cu transport and homeostasis in mammalian cells. The primary structure of the mammalian Cu-ATPases has been deduced from cDNAs from tissues and organs. It now appears that mammalian Cu-ATPase have tissue and developmental specificity. In this review, we will focus on the Cu-ATPase that has been identified with Menkes disease. An emphasis will be placed on the existence of multiple forms of the ATPase and some indication as to how the different isoforms befit their role in the normal physiology of copper, specifically transmembrane transport and maintenance of a favorable internal cellular environment.
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PMID:Genes regulating copper metabolism. 982 11

The group of X-linked mottled (Atp7aMo) mutations in mice is described. A normal gene encodes a copper-binding P-type ATPase. Mutant animals have the disturbance in copper metabolism, hemizygous males (Mo/y) die between 14-18 days of life, heterozygous females (Mo/+) are normal and fertile. This kind of copper metabolic defect is observed also in other animal and in human. In human Menkes disease caused by X-linked Atp7a mutant gene leads to death in early childhood. Because of is 89% of homology between Atp7aMo gene and Atp7a locus in human, mottled mutations are an excellent model for Menkes disease.
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PMID:[Mice with mottled mutation--a model for defective copper metabolism in humans]. 985 76

The Menkes ATPase (MNK) has an essential role in the translocation of copper across cellular membranes. In a complementary manner, the intracellular concentration of copper regulates the activity and cellular location of the ATPase through its six homologous amino-terminal domains. The roles of the six amino-terminal domains in the activation and cellular trafficking processes are unknown. Understanding the role of these domains relies on the development of an understanding of their metal-binding properties and structural properties. The second conserved sub-domain of MNK was over-expressed, purified and its copper-binding properties characterised. Reconstitution studies demonstrate that copper binds to MNKr2 as Cu(I) with a stoichiometry of one copper per domain. This is the first direct evidence of copper-binding to the MNK amino-terminal repeats. Circular dichroism studies suggest that the binding or loss of copper to MNKr2 does not cause substantial changes to the secondary structure of the protein.
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PMID:Characterisation of copper-binding to the second sub-domain of the Menkes protein ATPase (MNKr2). 1003 23

The 5' region of MNK cDNAs has a 45 bp insert terminating at the 5'end with an AGATG sequence. The ATG in the sequence is in-frame with the ATG downstream identified by Vulpe et al (1993) as a translation start site for MNK mRNA. Inserts of 192 bp and 45 bp have been found in the 5' region of MNK mRNAs from BeWo cells, Caco-2 cells and normal human fibroblasts. Extensions to the 5' end of these mRNAs could foretell a modified N-termini in certain forms of the Menkes Cu-ATPase. These modified H2N-terminal extensions are postulated to be targeting signals for post-translational processing and cellular localization. In this report, we provide evidence that the primary Menkes transcript in non-Menkes cells undergoes post-transcriptional splicing that gives rise to multiple transcripts. The data suggest that the Menkes gene is a copper locus that codes for more than one form of the Menkes Cu-ATPase and one of these forms could be a small Cu transport protein.
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PMID:Multiple forms of the Menkes Cu-ATPase. 1007 14

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