Intrinsic factor (IF), cobalamin binding intrinsic factor,[5] also known as gastric intrinsic factor (GIF), is a
glycoprotein produced by the
parietal cells (in humans) or chief cells (in rodents) of the
stomach. It is necessary for the absorption of
vitamin B12 later on in the distal
ileum of the
small intestine.[6] In humans, the gastric intrinsic factor
protein is encoded by the CBLIFgene.[5]Haptocorrin (
transcobalamin I) is another glycoprotein secreted by the
salivary glands which binds to vitamin B12. Vitamin B12 is acid-sensitive and in binding to haptocorrin it can safely pass through the acidic stomach to the duodenum.[7]
In the less acidic environment of the
small intestine, pancreatic enzymes digest the glycoprotein carrier and vitamin B12 can then bind to intrinsic factor.[7] This new complex is then absorbed by the epithelial cells (
enterocytes) of the
ileum.[7] Inside the cells, vitamin B12 dissociates once again and binds to another protein,
transcobalamin II; the new complex can then exit the epithelial cells to be carried to the liver.[8]
Site of secretion
Intrinsic factor is secreted by
parietal cells within the stomach, and so is present in the gastric juice as well as in the
gastric mucous membrane.[9] The optimum pH for its action is approximately 7.[10] Its concentration does not correlate with the amount of
HCl or
pepsin in the gastric juice, e.g., intrinsic factor may be present even when pepsin is largely absent.[11] The site of formation of the intrinsic factor varies in different species. In pigs it is obtained from the
pylorus and beginning of the
duodenum;[12] in human beings it is present in the
fundus and body of the
stomach.[13]
The limited amount of normal human gastric intrinsic factor limits normal efficient absorption of B12 to about 2 μg per meal, a nominally adequate intake of B12.[14]
Insufficiency
In
pernicious anemia, which is usually an
autoimmune disease,
autoantibodies directed against intrinsic factor or parietal cells themselves lead to an intrinsic factor deficiency,
malabsorption of vitamin B12, and subsequent
megaloblastic anemia.[15]Atrophic gastritis can also cause intrinsic factor deficiency and anemia through damage to the parietal cells of the stomach wall.[16]Pancreatic exocrine insufficiency can interfere with normal dissociation of vitamin B12 from its binding proteins in the small intestine, preventing its absorption via the intrinsic factor complex.[17] Other risk factors contributing to pernicious anemia are anything that damages or removes a portion of the stomach's parietal cells, including
bariatric surgery, gastric tumors, gastric ulcers, and excessive consumption of alcohol.[citation needed]
Mutations in the GIF gene are responsible for a rare inheritable disease called intrinsic factor deficiency[18] which results in malabsorption of vitamin B12.[19]
Treatment
In most countries,
intramuscular injections of vitamin B12 are used to treat
pernicious anemia.[20] Orally administered vitamin B12 is absorbed without intrinsic factor, but at levels of less than one percent than if intrinsic factor is present.[21] Despite the low amounts absorbed, oral vitamin B12 therapy is effective at reducing symptoms of pernicious anemia.[22]
Vitamin B12 can also be given
sublingually, but there is no evidence that this route of administration is superior to the oral route,[23] and only Canada and Sweden routinely prescribe this route of administration.[20]
Because vitamin B12 absorption is a multistep process that involves the stomach, pancreas and small intestine, and is mediated by two carriers:
Haptocorrin and intrinsic factor, and because
Haptocorrin (
transcobalamin I) binds to vitamin B12, and Vitamin B12 is acid-sensitive, when vitamin B12 binds to
Haptocorrin it can safely pass through the acidic stomach to the duodenum, given time in the mouth.[7]
^Alpers DH, Russell-Jones G (May 2013). "Gastric intrinsic factor: the gastric and small intestinal stages of cobalamin absorption. A personal journey". (review). Biochimie. 95 (5): 989–94.
doi:
10.1016/j.biochi.2012.12.006.
PMID23274574.
^Sharma K (2016).
"Gastrointestinal System". In Talwar G, Hasnain SE, Sarin SK (eds.). Textbook Of Biochemistry, Biotechnology, Allied And Molecular Medicine. (secondary) (4th ed.). PHI Learning Private Limited. p. 632.
ISBN978-81-203-5125-7.
^Poliner IJ, Spiro HM, Pask BA, Trocchio N (1958). "The independent secretion of acid, pepsin, and intrinsic factor by the human stomach". (primary). Gastroenterology. 34 (2): 196–209.
doi:
10.1016/S0016-5085(58)80102-X.
PMID13512593.
^Heatley NG, Florey H, Turnbull A, Jennings MA, Watson GM, Wakisaka G, Witts LJ (1954). "Intrinsic factor in the pyloric and duodenal secretions of the pig". (primary). Lancet. 267 (6838): 578–80.
doi:
10.1016/S0140-6736(54)90355-4.
PMID13193076.
^Neumann WL, Coss E, Rugge M, Genta RM (2013). "Autoimmune atrophic gastritis--pathogenesis, pathology and management". (review). Nature Reviews. Gastroenterology & Hepatology. 10 (9): 529–41.
doi:
10.1038/nrgastro.2013.101.
PMID23774773.
S2CID205487577.
^Guéant JL, Champigneulle B, Gaucher P, Nicolas JP (1990). "Malabsorption of vitamin B12 in pancreatic insufficiency of the adult and of the child". (review). Pancreas. 5 (5): 559–67.
doi:
10.1097/00006676-199009000-00011.
PMID2235967.
S2CID9077477.
Christensen EI, Nielsen R, Birn H (Feb 2013). "From bowel to kidneys: the role of cubilin in physiology and disease". (review). Nephrology, Dialysis, Transplantation. 28 (2): 274–81.
doi:
10.1093/ndt/gfs565.
PMID23291372.