Haptocorrin also known as transcobalamin-1 (TC-1) or cobalophilin is a transcobalamin protein that in humans is encoded by the TCN1 gene.[2] The essential function of haptocorrin is protection of the acid-sensitive vitamin B12 while it moves through the stomach.
Function
Haptocorrin (HC), also commonly known as the R-protein, or the R-factor, or previously referred to as transcobalamin I, is a unique glycoprotein produced by the salivary glands of the oral cavity, in response to ingestion of food. This protein binds strongly to vitamin B12 in what is an intricate and necessary mechanism to protect this vitamin from the acidic environment of the stomach.[3]:44 Vitamin B12 is an essential water-soluble vitamin, the deficiency of which creates anemia (macrocytic anemia), decreased bone marrow cell production (anemia, pancytopenia), neurological problems, as well as metabolic issues (methylmalonyl-CoA acidosis).[3]:50–51
Vitamin B12 is therefore an important vitamin for the body to absorb. Despite its vital role however, vitamin B12 is structurally very sensitive to the hydrochloric acid found in the stomach secretions, and easily denatures in that environment before it has a chance to be absorbed by the small intestine. Found in fresh animal products (such as liver), vitamin B12 attaches haptocorrin, which has a high affinity for its molecular structure.[4] Coupled together vitamin B12 and haptocorrin create a complex. This Haptocorrin-B12 complex is impervious to the insult of the stomach acid, and passes on via the pylorus to the duodenum. In the duodenum pancreatic proteases (a component of pancreatic juice) cleave haptocorrin, releasing vitamin B12 in its free form.
The same cells in the stomach that produce gastric hydrochloric acid, the parietal cells, also produce a molecule called the intrinsic factor (IF), which binds the B12 after its release from haptocorrin by digestion, and without which vitamin B12 can not be absorbed. Intrinsic factor (IF) is a glycoprotein, with a molecular weight of 45 kDa. In the duodenum, the free vitamin B12 attaches to the intrinsic factor (IF) to create a vitamin B12-IF complex. This complex then travels through the small bowel and reaches the terminal tertiary portion of the small intestine, called the ileum. The ileum is the longest of all portions of the small intestine, and has on its surface specialized receptors called cubilin receptors, that identify the B12-IF complexes and take them up into the circulation via endocytosis mediated absorption.[5]
In short, the essential function of haptocorrin is protection of the acid-sensitive vitamin B12 while it moves through the stomach.
Haptocorrin also circulates and binds approximately 80% of circulating B12, rendering it unavailable for cellular delivery by transcobalamin II [6]
References
Further reading
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- Matteini AM, Walston JD, Bandeen-Roche K, Arking DE, Allen RH, Fried LP, Chakravarti A, Stabler SP, Fallin MD (Jan 2010). "Transcobalamin-II variants, decreased vitamin B12 availability and increased risk of frailty". The Journal of Nutrition, Health & Aging. 14 (1): 73–7. doi:10.1007/s12603-010-0013-1. PMC 3042247. PMID 20082058.
- Lee KM, Lan Q, Kricker A, Purdue MP, Grulich AE, Vajdic CM, Turner J, Whitby D, Kang D, Chanock S, Rothman N, Armstrong BK (Dec 2007). "One-carbon metabolism gene polymorphisms and risk of non-Hodgkin lymphoma in Australia". Human Genetics. 122 (5): 525–33. doi:10.1007/s00439-007-0431-2. PMID 17891500.
- Liu T, Qian WJ, Gritsenko MA, Camp DG, Monroe ME, Moore RJ, Smith RD. "Human plasma N-glycoproteome analysis by immunoaffinity subtraction, hydrazide chemistry, and mass spectrometry". Journal of Proteome Research. 4 (6): 2070–80. doi:10.1021/pr0502065. PMC 1850943. PMID 16335952.
- Fintelman-Rodrigues N, Corrêa JC, Santos JM, Pimentel MM, Santos-Rebouças CB (2009). "Investigation of CBS, MTR, RFC-1 and TC polymorphisms as maternal risk factors for Down syndrome". Disease Markers. 26 (4): 155–61. doi:10.3233/DMA-2009-0626. PMID 19729796.
- Wang SS, Maurer MJ, Morton LM, Habermann TM, Davis S, Cozen W, Lynch CF, Severson RK, Rothman N, Chanock SJ, Hartge P, Cerhan JR (Mar 2009). "Polymorphisms in DNA repair and one-carbon metabolism genes and overall survival in diffuse large B-cell lymphoma and follicular lymphoma". Leukemia. 23 (3): 596–602. doi:10.1038/leu.2008.240. PMC 3066015. PMID 18830263.
- Fedosov SN, Fedosova NU, Kräutler B, Nexø E, Petersen TE (May 2007). "Mechanisms of discrimination between cobalamins and their natural analogues during their binding to the specific B12-transporting proteins". Biochemistry. 46 (21): 6446–58. doi:10.1021/bi062063l. PMID 17487979.
- Carmel R, Parker J, Kelman Z (Nov 2009). "Genomic mutations associated with mild and severe deficiencies of transcobalamin I (haptocorrin) that cause mildly and severely low serum cobalamin levels". British Journal of Haematology. 147 (3): 386–91. doi:10.1111/j.1365-2141.2009.07855.x. PMID 19686235.
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- Haggarty P, Campbell DM, Duthie S, Andrews K, Hoad G, Piyathilake C, Fraser I, McNeill G (Jun 2008). "Folic acid use in pregnancy and embryo selection". Bjog. 115 (7): 851–6. doi:10.1111/j.1471-0528.2008.01737.x. PMID 18485163.
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- von Castel-Dunwoody KM, Kauwell GP, Shelnutt KP, Vaughn JD, Griffin ER, Maneval DR, Theriaque DW, Bailey LB (Jun 2005). "Transcobalamin 776C->G polymorphism negatively affects vitamin B-12 metabolism". The American Journal of Clinical Nutrition. 81 (6): 1436–41. PMID 15941899.
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