Ceruloplasmin (or caeruloplasmin) is a ferroxidase enzyme that in humans is encoded by the CP gene.[5][6][7]
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| Aliases | CP, CP-2, ceruloplasmin (ferroxidase), Ceruloplasmin, AB073614 | ||||||||||||||||||||||||||||||||||||||||||||||||||
| External IDs | OMIM: 117700; MGI: 88476; HomoloGene: 75; GeneCards: CP; OMA:CP - orthologs | ||||||||||||||||||||||||||||||||||||||||||||||||||
| EC number | 1.16.3.1 | ||||||||||||||||||||||||||||||||||||||||||||||||||
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Ceruloplasmin is the major copper-carrying protein in the blood, and in addition plays a role in iron metabolism. It was first described in 1948.[8] Another protein, hephaestin, is noted for its homology to ceruloplasmin, and also participates in iron and probably copper metabolism.
Function edit
Ceruloplasmin (CP) is an enzyme (EC 1.16.3.1) synthesized in the liver containing 6 atoms of copper in its structure.[9] Ceruloplasmin carries more than 95% of the total copper in healthy human plasma.[10] The rest is accounted for by macroglobulins. Ceruloplasmin exhibits a copper-dependent oxidase activity, which is associated with possible oxidation of Fe2+ (ferrous iron) into Fe3+ (ferric iron), therefore assisting in its transport in the plasma in association with transferrin, which can carry iron only in the ferric state.[11] The molecular weight of human ceruloplasmin is reported to be 151kDa.
Despite extensive research, much is still unknown about the exact functions of CP, most of the functions are attributed to CP focus on the presence of the Cu centers. These include copper transport to deliver the Cu to extrahepatic tissues, amine oxidase activity that controls the level of biogenic amines in intestinal fluids and plasma, removal of oxygen and other free radicals from plasma, and the export of iron from cells for transport through transferrin.[12]
Mutations have been known to disrupt the binding of copper to CP and will disrupt iron metabolism and cause an iron overload.
Ceruloplasmin is a relatively large enzyme (~10nm); the larger size prevents the bound copper from being lost in a person's urine during transport.
Active site structure edit
The multicopper active site of CP contains a type I (T1) mononuclear copper[12] site and a trinuclear copper center ~ 12-13 Å away (see figure 2). The tricopper center consists of two type III (T3) coppers and one type II (T2) copper ion. The two T3 copper ions are bridged by a hydroxide ligand while another hydroxide ligand links the T2 copper ion to the protein. The T1 center is bridged to the tricopper center by two histidine (His1020, His1022) residues and one Cys(1021) residue. The substrate binds near the T1 center and is oxidized by the T1 Cu2+ ion forming the reduced Cu+ oxidation state. The reduced T1 Cu+ then transfers the electron through the one Cys and two His bridging residues to the tricopper center. After four electrons have been transferred from the substrates to the copper centers, an O2 binds at the tricopper center and undergoes a four-electron reduction to form two molecules of water.[12]
Regulation edit
A cis-regulatory element called the GAIT element is involved in the selective translational silencing of the Ceruloplasmin transcript.[13]The silencing requires binding of a cytosolic inhibitor complex called IFN-gamma-activated inhibitor of translation (GAIT) to the GAIT element.[14]
Clinical significance edit
Like any other plasma protein, levels drop in patients with hepatic disease due to reduced synthesizing capabilities.
Mechanisms of low ceruloplasmin levels:
- Gene expression genetically low (aceruloplasminemia)
- Copper levels are low in general
- Malnutrition/trace metal deficiency in the food source
- Zinc toxicity, due to induced copper deficiency
- Copper does not cross the intestinal barrier due to ATP7A deficiency (Menkes disease and Occipital horn syndrome)
- Delivery of copper into the lumen of the ER-Golgi network is absent in hepatocytes due to absent ATP7B (Wilson's disease)
Copper availability doesn't affect the translation of the nascent protein. However, the apoenzyme without copper is unstable. Apoceruloplasmin is largely degraded intracellularly in the hepatocyte and the small amount that is released has a short circulation half life of 5 hours as compared to the 5.5 days for the holo-ceruloplasmin.
Ceruloplasmin can be measured by means of a blood test;[15] this can be done using immunoassays . The sample is spun and separated; it is stored around 4°C Celsius for three days. This test is to determine if there are signs of Wilson disease. Another test that can be done is a urine copper level test; this has been found to be less accurate than the blood test. A liver tissue test can be done as well.
Mutations in the ceruloplasmin gene (CP), which are very rare, can lead to the genetic disease aceruloplasminemia, characterized by hyperferritinemia with iron overload. In the brain, this iron overload may lead to characteristic neurologic signs and symptoms, such as cerebellar ataxia, progressive dementia, and extrapyramidal signs. Excess iron may also deposit in the liver, pancreas, and retina, leading to cirrhosis, endocrine abnormalities, and loss of vision, respectively.
Deficiency edit
Lower-than-normal ceruloplasmin levels may indicate the following:
- Wilson disease (a rare [UK incidence 2/100,000] copper storage disease).[16]
- Menkes disease (Menkes kinky hair syndrome) (rare – UK incidence 1/100,000)
- Copper deficiency
- Aceruloplasminemia[17]
- Zinc toxicity
Excess edit
Greater-than-normal ceruloplasmin levels may indicate or be noticed in:
- copper toxicity / zinc deficiency
- pregnancy
- oral contraceptive pill use[18]
- lymphoma
- acute and chronic inflammation (it is an acute-phase reactant)
- rheumatoid arthritis
- Angina[19]
- Alzheimer's disease[20]
- Schizophrenia[21]
- Obsessive-compulsive disorder[22]
Reference ranges edit
Normal blood concentration of ceruloplasmin in humans is 20–50 mg/dL.
References edit
Further reading edit
- Hellman NE, Gitlin JD (2002). "Ceruloplasmin metabolism and function". Annual Review of Nutrition. 22: 439–58. doi:10.1146/annurev.nutr.22.012502.114457. PMID 12055353.
- Mazumder B, Seshadri V, Fox PL (Feb 2003). "Translational control by the 3'-UTR: the ends specify the means". Trends in Biochemical Sciences. 28 (2): 91–8. doi:10.1016/S0968-0004(03)00002-1. PMID 12575997.
- Giurgea N, Constantinescu MI, Stanciu R, Suciu S, Muresan A (Feb 2005). "Ceruloplasmin - acute-phase reactant or endogenous antioxidant? The case of cardiovascular disease". Medical Science Monitor. 11 (2): RA48-51. PMID 15668644.
- Kingston IB, Kingston BL, Putnam FW (Dec 1977). "Chemical evidence that proteolytic cleavage causes the heterogeneity present in human ceruloplasmin preparations". Proceedings of the National Academy of Sciences of the United States of America. 74 (12): 5377–81. Bibcode:1977PNAS...74.5377K. doi:10.1073/pnas.74.12.5377. PMC 431726. PMID 146197.
- Polosatov MV, Klimov PK, Masevich CG, Samartsev MA, Wünsch E (Apr 1979). "Interaction of synthetic human big gastrin with blood proteins of man and animals". Acta Hepato-Gastroenterologica. 26 (2): 154–9. PMID 463490.
- Schilsky ML, Stockert RJ, Pollard JW (Dec 1992). "Caeruloplasmin biosynthesis by the human uterus". The Biochemical Journal. 288 (2): 657–61. doi:10.1042/bj2880657. PMC 1132061. PMID 1463466.
- Walker FJ, Fay PJ (Feb 1990). "Characterization of an interaction between protein C and ceruloplasmin". The Journal of Biological Chemistry. 265 (4): 1834–6. doi:10.1016/S0021-9258(19)39903-X. PMID 2105310.
- Fleming RE, Gitlin JD (May 1990). "Primary structure of rat ceruloplasmin and analysis of tissue-specific gene expression during development". The Journal of Biological Chemistry. 265 (13): 7701–7. doi:10.1016/S0021-9258(19)39171-9. PMID 2332446.
- Yang FM, Friedrichs WE, Cupples RL, Bonifacio MJ, Sanford JA, Horton WA, Bowman BH (Jun 1990). "Human ceruloplasmin. Tissue-specific expression of transcripts produced by alternative splicing". The Journal of Biological Chemistry. 265 (18): 10780–5. doi:10.1016/S0021-9258(18)87015-6. PMID 2355023.
- Yang F, Naylor SL, Lum JB, Cutshaw S, McCombs JL, Naberhaus KH, McGill JR, Adrian GS, Moore CM, Barnett DR (May 1986). "Characterization, mapping, and expression of the human ceruloplasmin gene". Proceedings of the National Academy of Sciences of the United States of America. 83 (10): 3257–61. Bibcode:1986PNAS...83.3257Y. doi:10.1073/pnas.83.10.3257. PMC 323492. PMID 3486416.
- Mercer JF, Grimes A (Jul 1986). "Isolation of a human ceruloplasmin cDNA clone that includes the N-terminal leader sequence". FEBS Letters. 203 (2): 185–90. doi:10.1016/0014-5793(86)80739-6. PMID 3755405. S2CID 23472934.
- Rask L, Valtersson C, Anundi H, Kvist S, Eriksson U, Dallner G, Peterson PA (Jan 1983). "Subcellular localization in normal and vitamin A-deficient rat liver of vitamin A serum transport proteins, albumin, ceruloplasmin and class I major histocompatibility antigens". Experimental Cell Research. 143 (1): 91–102. doi:10.1016/0014-4827(83)90112-X. PMID 6337857.
- Kressner MS, Stockert RJ, Morell AG, Sternlieb I (1984). "Origins of biliary copper". Hepatology. 4 (5): 867–70. doi:10.1002/hep.1840040512. PMID 6479854. S2CID 43824397.
- Takahashi N, Bauman RA, Ortel TL, Dwulet FE, Wang CC, Putnam FW (Jan 1983). "Internal triplication in the structure of human ceruloplasmin". Proceedings of the National Academy of Sciences of the United States of America. 80 (1): 115–9. Bibcode:1983PNAS...80..115T. doi:10.1073/pnas.80.1.115. PMC 393320. PMID 6571985.
- Dwulet FE, Putnam FW (Feb 1981). "Complete amino acid sequence of a 50,000-dalton fragment of human ceruloplasmin". Proceedings of the National Academy of Sciences of the United States of America. 78 (2): 790–4. Bibcode:1981PNAS...78..790D. doi:10.1073/pnas.78.2.790. PMC 319888. PMID 6940148.
- Kingston IB, Kingston BL, Putnam FW (Apr 1980). "Primary structure of a histidine-rich proteolytic fragment of human ceruloplasmin. I. Amino acid sequence of the cyanogen bromide peptides". The Journal of Biological Chemistry. 255 (7): 2878–85. doi:10.1016/S0021-9258(19)85822-2. PMID 6987229.
External links edit
- GeneReviews/NCBI/NIH/UW entry on Aceruloplasminemia
- OMIM entries on Aceruloplasminemia
- Overview of all the structural information available in the PDB for UniProt: P00450 (Human Ceruloplasmin) at the PDBe-KB.
