n.
A hormone secreted by glands in the mucous membrane of the stomach that stimulates the production of gastric juice.
gastrin
Dictionary:
gas·trin (găs'trĭn)  |
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Gastrin is a hormone produced in the stomach which stimulates gastric acid secretion after a meal. It was discovered in 1905 by John Sydney Edkins (1863-1940), working in St Bartholomew's Hospital, London. Edkins reasoned that gastric acid secretion might be regulated by a mechanism analogous to the control of pancreatic secretion by the intestinal hormone secretin which had been discovered by W. M. Bayliss and E. H. Starling three years earlier. He then showed that when extracts of the lowest part of the stomach were injected into the jugular vein they stimulated gastric acid secretion, and he called the active factor ‘gastrin’. Gastrin is a polypeptide. It occurs in several different molecular forms, the most important of which are molecules of 17 and 34 amino acid residues.
In 1919 the Russian physiologist L. Popielski showed that histamine was a powerful stimulant of gastric acid secretion and for some years thereafter it was widely thought that Edkins' ‘gastrin’ was in fact histamine. The issue was clarified by S. A. Komarov, who established that histamine-free extracts of gastric mucosa stimulated acid secretion when injected into the blood. However, the low concentrations of gastrin in stomach tissue frustrated early attempts to obtain the hormone in a pure form. Success was finally achieved by Rod Gregory and Hilda Tracy at the University of Liverpool, who in the early 1960s purified from pig stomach the 17 amino acid form of the hormone. Their work required the routine processing of many hundreds of pig stomachs obtained each week from a local abattoir. Together with their colleague, the chemist George Kenner, they established the structure of gastrin and noted that a sequence of 4 amino acid residues was sufficient to produce the full range of actions of the molecule they had purified. A synthetic compound based on this sequence, pentagastrin, is used clinically for tests of gastric acid secretion. A closely related sequence occurs in the brain-gut peptide cholecystokinin, and a similar peptide is also found in high concentrations in skin glands of certain amphibians, for example the South African clawed toad, Xenopus leavis.
Gastrin is released from specialized cells in the mucosa of the final part of the stomach. Secretion into the bloodstream is increased by the presence of food, particularly protein, in the stomach, and is also stimulated by neural reflexes. Gastrin is then carried by the blood throughout the body, but it exerts its action by virtue of specific receptors on cells of the acid-secreting (middle and upper) part of the stomach. Gastric acid, in turn, passes to the lower part of the stomach and there inhibits the release of gastrin, providing a mechanism to limit acid secretion during digestion. In the absence of acid due either to loss of the parietal cells that secrete it (pernicious anaemia) or to administration of drugs that block the proton pump in parietal cells, e.g. omeprazole, the concentration of gastrin in the blood becomes elevated. It also becomes elevated in the blood of patients with the rare condition of Zollinger-Ellison syndrome, due to a gastrin-producing tumour typically sited in the pancreas.
Gastrin increases acid secretion both by direct stimulation of the acid-producing parietal cells, and by increasing the release of histamine from specialized cells, known as enterochromaffin-like cells, in the mucosa adjacent to parietal cells. Histamine then diffuses through the mucosa to parietal cells, acting as a local regulator. Gastrin is also a stimulant of the growth of the gastric mucosa, and in particular of the enterochromaffin-like cells. In extreme cases, elevated concentrations of gastrin in blood may be associated with the development of nodules of enterochromaffin-like cells, known as gastric carcinoid tumours.
The actions of gastrin are mediated by receptors on the surface of parietal and enterochromaffin-like cells, activation of which leads to increased intracellular calcium. The same receptor responds to cholecystokinin, and is known as the gastrin/cholecystokinin-B receptor. Cholecystokinin is normally present in blood in concentrations about ten times lower than those of gastrin and so its actions on these receptors in the stomach are relatively unimportant. Cholecystokinin also acts at a different type of receptor (the cholecystokinin-A receptor) which responds weakly to gastrin. Actions at cholecystokinin-A receptors account for the capacity of gastrin to stimulate pancreatic enzyme secretion and gall bladder contraction when given in high doses. The gastrin/cholecystokinin-B receptor is abundant in the central nervous system. Gastrin is not normally present in the brain and does not normally penetrate from the circulation; however, cholecystokinin does occur in the brain and so is the natural stimulant of this receptor in the central nervous system.
— G. J. Dockray
See also alimentary system.
| Food and Nutrition: gastrin |
Polypeptide hormone secreted by the stomach in response to food (especially meat) which stimulates gastric and pancreatic secretion.
| Veterinary Dictionary: gastrin |
A polypeptide hormone secreted by certain cells of the pylorus, which strongly stimulates secretion of gastric acid and pepsinogen, and weakly stimulates secretion of pancreatic enzymes and gallbladder contraction.
- g. assay — plasma levels are elevated in gastrointestinal disease and other systemic diseases.
| Wikipedia: Gastrin |
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| Gastrin | ||||||||||||||
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| Identifiers | ||||||||||||||
| Symbols | GAST; GAS | |||||||||||||
| External IDs | OMIM: 137250 MGI: 104768 HomoloGene: 628 | |||||||||||||
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| Species | Human | Mouse | ||||||||||||
| Entrez | 2520 | 14459 | ||||||||||||
| Ensembl | ENSG00000184502 | ENSMUSG00000017165 | ||||||||||||
| UniProt | P01350 | Q6GSF5 | ||||||||||||
| RefSeq | NM_000805 (mRNA) | NM_010257 (mRNA) | ||||||||||||
| NP_000796 (protein) | NP_034387 (protein) | |||||||||||||
| Location | Chr 17: 37.12 - 37.13 Mb |
Chr 11: 100.15 - 100.15 Mb |
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| PubMed search | [1] | [2] | ||||||||||||
In humans, gastrin is a hormone that stimulates secretion of gastric acid (HCl) by the parietal cells of the stomach and aids in gastric motility. It is released by G cells in the stomach, duodenum, and the pancreas. Its release is stimulated by gastric luminal peptides. Its existence was first suggested in 1905 by the British physiologist John Sydney Edkins,[1][2] and gastrins were isolated in 1964 by Gregory and Tracy in Liverpool.[3]
Contents |
Physiology
Genetics
The GAS gene is located on the long arm of the seventeenth chromosome (17q21).[4]
Synthesis
Gastrin is a linear peptide hormone produced by G cells of the duodenum and in the pyloric antrum of the stomach. It is secreted into the bloodstream. Gastrin is found primarily in three forms:
- gastrin-34 ("big gastrin")
- gastrin-17 ("little gastrin")
- gastrin-14 ("minigastrin")
Also, pentagastrin is an artificially synthesized, five amino acid sequence identical to the last five amino acid sequence at the C-terminus end of gastrin.
The numbers refer to the amino acid count.
Release
Gastrin is released in response to certain stimuli. These include:
- stomach distension
- vagal stimulation (mediated by the neurocrine bombesin, or GRP in humans)
- the presence of partially digested proteins especially amino acids
- hypercalcemia
Gastrin release is inhibited by:
- The presence of acid (primarily the secreted HCl) in the stomach (a case of negative feedback).
- Somatostatin also inhibits the release of gastrin, along with secretin, GIP (gastroinhibitory peptide), VIP, glucagon and calcitonin.
Function
The presence of gastrin stimulates parietal cells of the stomach to secrete hydrochloric acid (HCl)/gastric acid. This is done indirectly via binding onto CCK2/gastrin receptors on ECL cells in the stomach, which then responds by releasing histamine, which in turn acts in a paracrine manner on parietal cells stimulating them to secrete H+ ions. This is the major stimulus for acid secretion by parietal cells.
Along with the above mentioned function, gastrin has been show to have additional functions as well:
- Stimulates parietal cell maturation and fundal growth.
- Causes chief cells to secrete pepsinogen, the zymogen (inactive) form of the digestive enzyme pepsin.
- Increases antral muscle mobility and promotes stomach contractions.
- Strengthens antral contractions against the pylorus, and constricts the pyloric sphincter, which slows gastric emptying.
- Plays a role in the relaxation of the ileocecal valve.[5]
- Induces pancreatic secretions and gallbladder emptying.[6]
- Impacts lower esophageal sphincter (LES) tone, causing it to relax.[7] Taking this into consideration, high levels of gastrin may play a role in the development of some of the more common LES disorders such as acid reflux disease.
Factors influencing secretion
Gastric lumen:
- Stimulatory factors: dietary protein and amino acids, hypercalcemia. (i.e. during the gastric phase)
- Inhibitory factor: acidity (pH below 3) - a negative feedback mechanism, exerted via the release of somatostatin from δ cells in the stomach, which inhibits gastrin and histamine release.
Paracrine:
- Stimulatory factor: bombesin
- Inhibitory factor: somatostatin - acts on somatostatin-2 receptors on G cells. in a paracrine manner via local diffusion in the intercellular spaces, but also systemically through its release into the local mucosal blood circulation; it inhibits acid secretion by acting on parietal cells.
Nervous:
- Stimulatory factors: Beta-adrenergic agents, cholinergic agents, gastrin-releasing peptide (GRP)
Circulation:
- Stimulatory factor: epinephrine
- Inhibitory factors:gastric inhibitory peptide (GIP), secretin, somatostatin, glucagon, calcitonin
Role in disease
In the Zollinger-Ellison syndrome, gastrin is produced at excessive levels, often by a gastrinoma (gastrin-producing tumor, mostly benign) of the duodenum or the pancreas. To investigate for hypergastrinemia (high blood levels of gastrin), a "pentagastrin test" can be performed.
In autoimmune gastritis, the immune system attacks the parietal cells leading to hypochlorhydria (low stomach acidity). This results in an elevated gastrin level in an attempt to compensate for low acidity. Eventually, all the parietal cells are lost and achlorhydria results leading to a loss of negative feedback on gastrin secretion. Plasma gastrin concentration is elevated in virtually all individuals with mucolipidosis type IV (mean 1507 pg/mL; range 400-4100 pg/mL) (normal 0-200 pg/mL) secondary to a constitutive achlorhydria. This finding facilitates the diagnosis of patients with this neurogenetic disorder.[8]
References
- ^ Edkins JS (13 Mar 1906). "The chemical mechanism of gastric secretion". J. Physiol. (Lond.) 34 (1-2): 133–44. PMID 16992839. PMC 1465807. http://jp.physoc.org/cgi/reprint/34/1-2/133.
- ^ Modlin IM, Kidd M, Marks IN, Tang LH (1997). "The pivotal role of John S. Edkins in the discovery of gastrin". World J Surg 21 (2): 226–34. doi:. PMID 8995084.
- ^ Gregory RA, Tracy HJ (1964). "The constitution and properties of two gastrins extracted from hog antral mucosa". Gut 5: 103–14. doi:. PMID 14159395. PMC 1552180. http://gut.bmj.com/cgi/reprint/5/2/103.
- ^ Lund T, Geurts van Kessel AH, Haun S, Dixon JE (1986). "The genes for human gastrin and cholecystokinin are located on different chromosomes". Hum. Genet. 73 (1): 77–80. doi:. PMID 3011648.
- ^ Vadokas B, Lüdtke FE, Lepsien G, Golenhofen K, Mandrek K (December 1997). "Effects of gastrin-releasing peptide (GRP) on the mechanical activity of the human ileocaecal region in vitro". Neurogastroenterol Motil. 9 (4): 265-270. PMID 9430795.
- ^ Valenzuela JE, Walsh JH, Isenberg JI (September 1976). "Effect of gastrin on pancreatic enzyme secretion and gallbladder emptying in man". Gastroenterology 71 (3): 409-411. PMID 950091.
- ^ Castell DO (February 1978). "Gastrin and lower esophageal sphincter tone". Arch. Intern. Med. 138 (2): 196. PMID 626547.
- ^ Schiffmann R, Dwyer NK, Lubensky IA, Tsokos M, Sutliff VE, Latimer JS, Frei KP, Brady RO, Barton NW, Blanchette-Mackie EJ, Goldin E (February 1998). "Constitutive achlorhydria in mucolipidosis type IV". Proc Natl Acad Sci U S A. 95 (3): 1207-12. PMID 9448310.
Further reading
- Rozengurt E, Walsh JH (2001). "Gastrin, CCK, signaling, and cancer". Annu. Rev. Physiol. 63: 49–76. doi:. PMID 11181948.
- Dockray GJ (2005). "Clinical endocrinology and metabolism. Gastrin". Best Pract. Res. Clin. Endocrinol. Metab. 18 (4): 555–68. doi:. PMID 15533775.
- Anlauf M, Garbrecht N, Henopp T, et al. (2006). "Sporadic versus hereditary gastrinomas of the duodenum and pancreas: distinct clinico-pathological and epidemiological features". World J. Gastroenterol. 12 (34): 5440–6. PMID 17006979.
- Polosatov MV, Klimov PK, Masevich CG, et al. (1979). "Interaction of synthetic human big gastrin with blood proteins of man and animals". Acta hepato-gastroenterologica 26 (2): 154–9. PMID 463490.
- Fritsch WP, Hausamen TU, Scholten T (1977). "[Gastrointestinal hormones. I. Hormones of the gastrin group]". Zeitschrift für Gastroenterologie 15 (4): 264–76. PMID 871064.
- Higashimoto Y, Himeno S, Shinomura Y, et al. (1989). "Purification and structural determination of urinary NH2-terminal big gastrin fragments". Biochem. Biophys. Res. Commun. 160 (3): 1364–70. doi:. PMID 2730647.
- Pauwels S, Najdovski T, Dimaline R, et al. (1989). "Degradation of human gastrin and CCK by endopeptidase 24.11: differential behaviour of the sulphated and unsulphated peptides". Biochim. Biophys. Acta 996 (1-2): 82–8. PMID 2736261.
- Lund T, Geurts van Kessel AH, Haun S, Dixon JE (1986). "The genes for human gastrin and cholecystokinin are located on different chromosomes". Hum. Genet. 73 (1): 77–80. doi:. PMID 3011648.
- Kariya Y, Kato K, Hayashizaki Y, et al. (1987). "Expression of human gastrin gene in normal and gastrinoma tissues". Gene 50 (1-3): 345–52. doi:. PMID 3034736.
- Gregory RA, Tracy HJ, Agarwal KL, Grossman MI (1969). "Aminoacid constitution of two gastrins isolated from Zollinger-Ellison tumour tissue". Gut 10 (8): 603–8. doi:. PMID 5822140.
- Bentley PH, Kenner GW, Sheppard RC (1967). "Structures of human gastrins I and II". Nature 209 (5023): 583–5. doi:. PMID 5921183.
- Ito R, Sato K, Helmer T, et al. (1984). "Structural analysis of the gene encoding human gastrin: the large intron contains an Alu sequence". Proc. Natl. Acad. Sci. U.S.A. 81 (15): 4662–6. doi:. PMID 6087340.
- Wiborg O, Berglund L, Boel E, et al. (1984). "Structure of a human gastrin gene". Proc. Natl. Acad. Sci. U.S.A. 81 (4): 1067–9. doi:. PMID 6322186.
- Kato K, Hayashizaki Y, Takahashi Y, et al. (1984). "Molecular cloning of the human gastrin gene". Nucleic Acids Res. 11 (23): 8197–203. doi:. PMID 6324077.
- Boel E, Vuust J, Norris F, et al. (1983). "Molecular cloning of human gastrin cDNA: evidence for evolution of gastrin by gene duplication". Proc. Natl. Acad. Sci. U.S.A. 80 (10): 2866–9. doi:. PMID 6574456.
- Kato K, Himeno S, Takahashi Y, et al. (1984). "Molecular cloning of human gastrin precursor cDNA". Gene 26 (1): 53–7. doi:. PMID 6689486.
- Koh TJ, Wang TC (1995). "Molecular cloning and sequencing of the murine gastrin gene". Biochem. Biophys. Res. Commun. 216 (1): 34–41. doi:. PMID 7488110.
- Rehfeld JF, Hansen CP, Johnsen AH (1995). "Post-poly(Glu) cleavage and degradation modified by O-sulfated tyrosine: a novel post-translational processing mechanism". Embo J. 14 (2): 389–96. PMID 7530658.
- Rehfeld JF, Johnsen AH (1994). "Identification of gastrin component I as gastrin-71. The largest possible bioactive progastrin product". Eur. J. Biochem. 223 (3): 765–73. doi:. PMID 8055952.
- Varro A, Dockray GJ (1993). "Post-translational processing of progastrin: inhibition of cleavage, phosphorylation and sulphation by brefeldin A". Biochem. J. 295 ( Pt 3): 813–9. PMID 8240296.
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