Gene/Protein Disease Symptom Drug Enzyme Compound
Pivot Concepts: Gene/Protein Disease Symptom Drug Enzyme Compound   Target Concepts: Gene/Protein Disease Symptom Drug Enzyme Compound

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Query: UNIPROT:P01350 (gastrin)
9,683 document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)

The neurotensin-cell is identified immunohistochemically and ultrastructurally by differential counting of endocrine cells in the gut of a primate (Tupaia belangeri). Utilizing light microscopy, the EC-cells are identified by the Masson-Fontana silver stain; with the same method the neurotensin cells are not stained. The other endocrine cells have been quantified in the small intestine using the peroxidase-antiperoxidase stain with antisera against glucagon, somatostatin, cholecystokinin, gastrin, secretin, pancreatic polypeptide, gastric inhibitory peptide and neurotensin. In the ileal mucosa of Tupaia, the most frequent endocrine cell is the EC-cell followed by the glucagonoid cell, (L-cell). The immunoreactive neurotensin cell represents the third most frequent endocrine cell in this region. On the ultrastructural level, this third most frequent endocrine cell is a heretofore undescribed cell, the N-cell, containing electron dense secretory granules measuring 335 +/- 87 nm in diameter.
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PMID:Ultrastructural identification of a new cell type--the N-cell as the source of neurotensin in the gut mucosa. 33 60

This is a review of current information concerning the role of hormones and the autonomic nervous system in the control of exocrine secretions of the pancreas. A greater emphasis has been placed on the role of hormones because of information accumulated during the last several years. With the development of radioimmunoassay techniques, it is now possible to correlate circulating hormone concentrations with biological function. The role of hormones has been discussed with the framework of the secretin-glucagon family, the cholecystokinin-gastrin family, and other proposed gastrointestinal hormones and related peptides. Gastrin, secretin and cholecystokinin-pancreozymin are three prime gut hormones that regulate pancreatic secretion. Other hormones that may have a role in pancreatic secretion include glucagon, vasoactive intestinal polypeptide, chymodenin, somatostatin, pancreatic polypeptide, motilin, and bombesin. Neural mechanisms play an important although not so succinct a role in the over-all control of exocrine secretion. A complex relationship exists between the parasympathetic nervous system and the release of the hormones and their effect on pancreatic acinar and duct cells.
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PMID:Neurohormonal control of pancreatic secretion. A review. 34 Mar 22

The chemistry, localisation, release and effects of gastrointestinal hormones and some related peptides are surveyed. Their main presumed physiologic actions are: gastric acid and pepsin secretion are stimulated by gastrin and to a less degree by secretin. Acid secretion is inhibited by bulbo-enterogastrone and GIP. Biliary water and electrolytes are augmented by gastrin, CCK-PZ, secretin and VIP and inhibited by Substance P. Pancreatic bicarbonate and enzyme secretions are stimulated by secretin and CCK-PZ, especially in combination. Lower oesophageal and antral motility and tonus are elevated following gastrin and motilin; the gallbladder and small intestine empty following CCK. Gastrin regulates gastrointestinal, and CCK pancreatic, tissue growth. Somatostatin inhibits all gut hormones. All peptides are vasoactive within the splanchnic area, each one in a specific manner.
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PMID:Gastrointestinal hormones. 35 98

Gastrin and cholecystokinin (CCH) cells of the rat gastrointestinal tract have been studied by immunocytochemistry and radioimmunoanalysis. With antisera directed against the COOH-terminal tetrapeptide sequence, which is common to gastrin and CCK, three distinct endocrine cell types are detected. One of the cell types predominates in the antrum, is scarce in the rest of the gut and corresponds to the gastrin cell. The second cell type is virtually confined to the duodenum and jejunum and corresponds to the CCK cell. The third cell type occurs disseminated in the small intestines, predominates in the ileum, and reacts with COOH-terminus-specific antisera only following diethylpyrocarbonate and not following formaldehyde fixation. It is possible that the third cell type stores a third member of the gastrin-CCK family of gut hormones.
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PMID:Distribution of gastrin and CCK cells in the rat gastrointestinal tract. Evidence for the occurrence of three distinct cell types storing COOH-terminal gastrin immunoreactivity. 36 36

To examine gut-islet interrelationships, we entirely separated the gastrointestinal tract from the rat. When we arterially perfused this preparation with an erythrocyte-free solution for 1 h, it remained histologically intact and took up oxygen and glucose. Feedings were given via a duodenal tube. The gut absorbed glucose when glucose in the feeding was high (9.2 g/dl), but not when glucose in the feeding was low (58 mg/dl). With feeding, the portal venous effluent (PVE) from this preparation (stomach to ileum) enhanced late-phase, glucose-induced insulin secretion from pancreas of another rat. This enhancement occurred when the gut was fed either glucose (9.2 g/dl) in electrolyte solution or electrolyte solution alone. PVE from glucose-fed upper gut (stomach, duodenum) was similarly insulinotropic. In contrast, PVE from unfed gut or from glucose-fed gut of old rats was not insulinotropic. PVE from all gut preparations except upper gut produced a glucagon "spike" during basal pancreatic perfusion. Effects of gastrointestinal peptides (gastric inhibitory polypeptide, cholecystokinin octapeptide, secretin, gastrin) and immunoassays of PVE suggested that the insulinotropic substance is not one of these peptides. Thus, an insulinotropic substance that is not dependent on feeding nutrient material is secreted from the intestine.
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PMID:Secretion of an insulinotropic factor from isolated, perfused rat intestine. 37 52

Peptides identical or related to mammalian gut hormones occur widely, not just in gut endocrine cells but also in central or peripheral nerves, amphibian skin glands, and a variety of invertebrate tissues. The dual distribution in brain and gut was probably already established early in the vertebrate line; representatives of the oldest vertebrate group, the cyclostomes, have cholecystokinin-like factors in gut endocrine cells and in brain. The related sequences of certain gut peptides, notably gastrin and cholecystokinin (CCK), and secretin, glucagon, vasoactive intestinal polypeptide (VIP), and gastric inhibitory peptide (GIP), indicate evolution from common ancestral molecules by gene duplication and divergence. Functionally important residues are conserved. Thus the COOH-terminal pentapeptide common to gastrin and CCK also contains their minimal active fragment. There are also evolutionary changes at the level of the target organ receptor mechanisms: these are also evolutionary changes at the level of the target organ receptor mechanisms; these are illustrated by evidence suggesting that secretin regulates the flow of pancreatic juice in mammals whereas the structurally related peptide VIP has a similar role in birds.
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PMID:Evolutionary relationships of the gut hormones. 37 11

The distribution of peptide hormone-like immunostaining in the gastrointestinal tract of 11 teleost species was investigated by immunofluorescence. Cells immunoreactive for somatostatin were found in the glandular epithelium of the stomach of four species and in the epithelium of the pyloric appendage of one species. The mid-gut epithelium contained cells reactive with antibodies to glucagon (three species), gastrin (five species), pancreatic polypeptide (five species), and substance P (two species). Cells immunoreactive for met-enkephalin were found in the epithelium of both the mid-gut and the stomach of six species. In six species in which the endocrine pancreas was investigated, insulin-, glucagon-, and somatostatin-like immunoreactivity was observed. Pancreatic polypeptide was definitely localised by immunostaining in cells of the endocrine pancreas of only one out of three species examined. Vasocative intestinal polypeptide-, neurotensin-, bombesin-, and enkephalin-like immunoreactivity was identified in the gastrointestinal nerve fibres in various species. In view of the considerable species variation found, caution should be exercised in generalising about the peptides present in the gastrointestinal tract of fish.
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PMID:Peptide hormone-like immunoreactivity in the gastrointestinal tract and endocrine pancreas of eleven teleost species. 38 3

Acid extracts of rat gut and brain contain substances that cross-react in a radioimmunoassay for the amphibian skin tetradecapeptide bombesin. Highest concentrations are present in the fundic part of the stomach, but there are significant amounts throughout the small and large intestine. Concentrations in the brain are highest in the hypothalamus. On gel filtration the rat bombesin-like immunoreactivity eluted as two major peaks. Fractionation of the second peak on cation exchange chromatography resolves this material into two further components. Intravenous infusions of partially purified preparations of the two components separated on gel filtration cause increases in serum gastrin in rats that are similar to those produced by immunochemically comparable amounts of synthetic bombesin.
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PMID:Bombesin-like peptides in mammals. 45 18

The release of pancreatic polypeptide (PP) by gut hormones, acetyl choline and adrenaline was investigated in an isolated perfused pancreas preparation. PP was potently released by 1 nmol/1 caerulein (186 +/- 12%, p is less than 0.001) and gastric inhibitory peptide (GIP) (211 +/- 31%, p is less than 0.005) as well as by 1 mumol/1 acetyl choline (1097 +/- 59%, p is less than 0.001). A significant two-fold release of PP was also evoked by 1 nmol/1 vasoactive intestinal peptide (VIP) (129 +/- 38%, p is less than 0.02 and gastrin (108 +/- 25% p is less than 0.01). Insulin release, induced by high glucose concentration was enhanced by both GIP (210 +/- 38%, p is less than (0.01) and VIP (48 +/- 5%, p is less than 0.001). In addition GIP enhanced the release of glucagon by 179 +/- 18% (p is less 0.001) at 1.4 mmol/1 glucose and by 127 +/- 24% (p is less than 0.005) at 8.3 mmol/1 glucose. Thus no simple inter-relationship appears to exist between the control of the three circulating islet hormones.
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PMID:Pancreatic polypeptide, glucagon and insulin secretion from the isolated perfused canine pancreas. 66 4

The duration of the disruption of the interdigestive migrating myoelectric complex (MMC) by various test meals in dogs was correlated with changes in serum gastrin and insulin levels. The test meals consisted of milk protein, sucrose, arachis oil and medium chain triglycerides (MCT). Intravenous infusions of glucose 20% were also used. Electrical activity of the small intestine was registered by means of electrodes implanted over the entire length of the gut. Hormones were assayed by radioimmunoassay techniques. The insulin level rose significantly after both the glucose infusion and the sucrose meal. The rise was small after the milk protein meal and nothing after arachis oil and MCT. Gastrin level was not changed by arachis oil or MCT and rose slightly after sucrose and milk protein. The MMC was not disrupted by glucose infusions, but was disrupted for 5--7 h by archis oil and for 6--12 h by MCT. We conclude that in dogs neither gastrin nor insulin have an important role in the mechanism of disruption of the MMC after feeding.
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PMID:Role of gastrin and insulin in postprandial disruption of migrating complex in dogs. 73 26


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