EC:1.16.3.1 - FACTA Search

Gene/Protein Disease Symptom Drug Enzyme Compound
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Query: EC:1.16.3.1 (ceruloplasmin)
5,074 document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)

A candidate gene (ATP7B) for Wilson's disease, an autosomal recessive disorder of copper transport, has recently been identified. We examined the ATP7B gene in two Japanese sisters with Wilson's disease presenting with fulminant hepatic failure but who did not exhibit Kayser-Fleischer rings or abnormal neurological findings. Genomic DNA was isolated from the whole blood of the patients and their family. Entire exons of ATP7B, and their associated splice junctions, were amplified by polymerase chain reaction. The sequencing of all exons was performed by a non-radioactive sequencing method. The sequencing of exon 12 of ATP7B revealed a 9-bp deletion. The mutation deleted 922Gly, 923Tyr, and 924Phe, and three residues conserved in the Menkes gene, ATP7A, located in the fifth transmembrane region. Of the 14 family members tested, 7 were normal and 7 were heterozygous for the deletion. Mean serum copper and cerulopasmin levels were significantly lower in the family members who were heterozygous for the deletion than in the normal family members, and two heterozygous family members showed abnormally low ceruloplasmin levels; however, there were no differences in mean aspartate aminotransferase or alanine aminotransferase levels between the two groups.
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PMID:A new variant deletion of a copper-transporting P-type ATPase gene found in patients with Wilson's disease presenting with fulminant hepatic failure. 1077 57

The interaction was studied of ceruloplasmin (Cp, EC 1.16.3.1), a copper-containing plasma protein, with two synthetic peptides P15 and P16 whose structures correlate with those of the noncytosolic regions of the copper transfer P1 type ATPase (ATP7A), apparently encoded by the Menkes disease gene (Atp7a). Pentadecapeptide P15 and hexadecapeptide P16 were synthesized using the solid phase method. They correspond to fragments of two extracellular loops ATP7A, of which one loop is apparently involved in the copper ion transfer (P16) whereas the other is not (P15). The protein footprinting showed that P16 binds to a fragment of the ceruloplasmin domain 6. Kinetics of the ceruloplasmin-P16 binding was studied by affinity chromatography on P16 immobilized on a macroporous disk, and the Kd value (1.5 x 10(-6) M) of this interaction was determined. The ATP7A involvement in the copper ion transfer to nonhepatocyte cells is discussed.
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PMID:[Identification of a fragment of ceruloplasmin, interacting with copper-transporting Menkes ATPase]. 1104 Sep 94

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

Genomic DNA of 17 unrelated Japanese males with Menkes disease and 2 Japanese males with occipital horn syndrome were studied for mutations in the ATP7A gene. Using SSCP analysis and direct sequencing of the exons and the 5'-upstream region of the gene amplified by PCR, we identified 16 mutations in 16 of 17 males with Menkes disease, including 4 deletions, 2 insertions, 6 nonsense mutations, 2 missense mutations, and 2 splice-site mutations. All these mutations were those that affect the function of the gene. Of the two males with occipital horn syndrome, one had a splice-site mutation in intron 6 that led to normal-size and smaller-size transcripts. The amount of the normal-size transcripts in his cultured skin fibroblasts was 19% of the normal level. His serum copper and ceruloplasmin levels were normal, whereas his cultured skin fibroblasts contained increased levels of copper. These findings indicate that his mild clinical manifestations were due to the presence of normal-size and presumably functional transcripts of the gene. DNA sequencing analysis of the exons and 5'-upstream region of the ATP7A gene in 20 normal individuals and the 19 affected males identified 25 polymorphisms.
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PMID:ATP7A gene mutations in 16 patients with Menkes disease and a patient with occipital horn syndrome. 1124 93

Using the immunoblotting method, the synthesis of two copper-transporting P1-type ATPases, ATP7A (a candidate for the product of the Menkes disease gene) and ATP7B (presumed product of the Wilson disease gene), in the yolk sac cells of rat embryos at days 11 and 20 of embryogenesis was demonstrated. Concomitantly, yolk sac cells produce ceruloplasmin, a soluble copper-transporting glycoprotein, a proportion of which in secreted proteins progressively diminishes, attaining 5.2% at day 11 and 3.1% at day 20 of development. At different stages of embryogenesis, yolk sac cells synthesize two molecular forms of [14]C-ceruloplasmin, one of which is secreted towards the embryo, whereas the other, towards the decidual membrane. Two forms of ceruloplasmin secreted in polar directions differ in the rate of secretion. The role of the yolk sac as a key organ controlling the delivery and secretion of copper in the embryo during the postimplantation period is discussed.
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PMID:[The role of the yolk sac in copper metabolism during rat embryogenesis]. 1154 10

Wilson disease is an autosomal recessive inherited disorder of copper metabolism, characterized by the accumulation of copper in the body due to defective biliary copper excretion from hepatocytes. Recently, novel components involved in copper metabolism, including Menkes disease protein (ATP7A), Wilson disease protein (ATP7B), and copper chaperones, have been identified. It has been demonstrated that ATP7B functions in copper secretion into the plasma, coupled with ceruloplasmin synthesis and biliary copper excretion. However, the precise intracellular localization of ATP7B has been disputed. Various mutations of ATP7B have been reported in patients with Wilson disease, and investigations of genotype-phenotype correlations are now being conducted in the patients. These recent findings provide us with information on the molecular pathogenesis of Wilson disease, as well as the biological mechanisms of copper homeostasis. In this review, recent advances in this field are briefly summarized.
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PMID:Wilson disease. 1218 46

Copper transporting P-type ATPases, designated ATP7A and ATP7B, play an essential role in mammalian copper balance. Impaired intestinal transport of copper, resulting from mutations in the ATP7A gene, lead to Menkes disease in humans. Defects in a similar gene, the copper transporting ATPase ATP7B, result in Wilson disease. This ATP7B transporter has two functions: transport of copper into the plasma protein ceruloplasmin, and elimination of copper through the bile. Variants of ATP7B can be functionally assayed to identify defects in each of these functions. Tissue expression studies of the copper ATPases and their copper chaperone ATOX1 indicate that there is not complete overlap in expression. Other chaperones may be important for the transport of copper into ATP7A and ATP7B.
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PMID:Copper transporting P-type ATPases and human disease. 1253 60

Copper is an essential cofactor for approximately a dozen cuproenzymes in which copper is bound to specific amino acid residues in an active site. However, free cuprous ions react readily with hydrogen peroxide to yield the deleterious hydroxyl radical. Therefore, copper homeostasis is regulated very tightly, and unbound copper is extremely low in concentration. Copper imported by the plasma membrane transport protein Ctr1 rapidly binds to intracellular copper chaperone proteins. Atox1 delivers copper to the secretory pathway and docks with either copper-transporting ATPase ATP7B in the liver or ATP7A in other cells. ATP7B directs copper to plasma ceruloplasmin or to biliary excretion in concert with a newly discovered chaperone, Murr1, the protein missing in canine copper toxicosis. ATP7A directs copper within the transgolgi network to the proteins dopamine beta-monooxgenase, peptidylglycine alpha-amidating monooxygenase, lysyl oxidase, and tyrosinase, depending on the cell type. CCS is the copper chaperone for Cu,Zn-superoxide dismutase; it delivers copper in the cytoplasm and intermitochondrial space. Cox17 delivers copper to mitochondria to cytochrome c oxidase via the chaperones Cox11, Sco1, and Sco2. Other copper chaperones may exist and might include metallothionein and amyloid precursor protein (APP). Genetic and nutritional studies have illustrated the essential nature of these copper-binding proteins; alterations in their levels are associated with severe pathology.
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PMID:Intracellular copper transport in mammals. 1511 35

Iron deficiency during pregnancy causes problems both for the mother and fetus. Iron deficiency is known to have secondary effects on copper metabolism. In this study, we use a rat model to examine the effect of iron deficiency on copper levels in maternal and fetal tissue. We assess whether the effects of iron deficiency on copper metabolism are due to alterations in mRNA levels of proteins of copper transport. Rowett Hooded Lister rats were fed diets with four different iron contents before and during pregnancy. Maternal and fetal samples were collected on day 21 of gestation. Copper and iron levels of liver and placenta were analyzed, mRNA levels of genes involved in copper transport were studied, and copper oxidase activity measured. Reduced dietary iron was found to increase maternal liver copper, inversely correlating with iron levels. Correspondingly, copper and ceruloplasmin increased in maternal serum. The placenta showed the greatest increase in copper levels. As the iron content of the maternal diet decreased so did the iron and copper levels in the fetal liver. In all tissues examined, mRNA expression for CTR1, ATOX1, ATP7A, and ATP7B was unchanged by iron deficiency. However, copper oxidase activity in maternal serum and placenta was increased. Our study in a rat model demonstrates that iron deficiency during pregnancy has a differential effect on copper metabolism in the mother and fetus. It is clear from this study that the changes in copper levels that accompany iron deficiency are not mediated by changes in transcription of the genes involved in copper transport.
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PMID:Iron deficiency in the pregnant rat has differential effects on maternal and fetal copper levels. 1515 43

Copper is essential for brain metabolism, serving as a cofactor to superoxide dismutase, dopamine-beta-hydroxylase, amyloid precursor protein, ceruloplasmin, and other proteins required for normal brain function. The copper-transporting ATPases ATP7A and ATP7B play a central role in distribution of copper in the central nervous system; genetic mutations in ATP7A and ATP7B lead to severe neurodegenerative disorders, Menkes disease and Wilson disease, respectively. Although both ATP7A and ATP7B are required, their specific roles and regulation in the brain remain poorly understood. Using high-resolution imaging and functional assays, we demonstrate that ATP7A and ATP7B show cell-specific distribution in adult cerebellum, have distinct enzymatic characteristics, and are regulated differently during development. ATP7B is continuously expressed in Purkinje neurons (PN) where it delivers copper to the ferroxidase ceruloplasmin. ATP7A is a faster copper transporter than Wilson disease protein as evidenced by faster rates of catalytic reactions. The expression of ATP7A switches during development from PN to Bergmann glia, the cells supporting PN function in adult brain. Inactivation of ATP7B (Wilson disease protein) by gene knock-out induces a striking shift in the expression of the ATP7B target protein, ceruloplasmin, from PN to Bergmann glia, where ATP7A (Menkes disease protein) is present. The induced cell-specific change in expression restores copper delivery to ceruloplasmin via ATP7A. Overall, the results provide evidence for distinct functions of ATP7A and ATP7B in the cerebellum and illustrate a tight link between copper homeostasis in PN and Bergmann glia.
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PMID:The copper-transporting ATPases, menkes and wilson disease proteins, have distinct roles in adult and developing cerebellum. 1563 71

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