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:P01275 (glucagon)
26,492 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

From the mucosa of the gastrointestinal tract a number of peptides can be extracted, which are glucagon-like in their behavior towards antisera raised against the pancreatic hormone. The biochemistry and physiology of these peptides are critically reviewed. Although important advances have been made, facilitated by improved praparative and analytical techniques, many problems remain unresolved. It is, however, now well established that a peptide, which is indistinguishable from true, pancreatic glucagon (NW 3,485) is found in extrapancreatic gastrointestinal tissue from all species investigated. While abundant in dogs, especially in the gastric mucosa, much less is found in extra-pancreatic tissues of man and pig. Results from studies in dogs are therefore not necessarily relevant to other species. Human and porcine gut, however, contain other glucagon-like peptides (gut-type glucagon, enteroglucagon, gut GLI), one of which resembles true glucagon (MW 3,485) in its biological activity, but a definite physiological role for these peptides has not yet been established. The recent isolation and purification of one of the latter peptides undoubtedly will facilitate greatly future research in this field.
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PMID:Extrapancreatic glucagons. 34 23

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

The cellular and subcellular localization of one of the gut glucagon-like immunoreactants (GLI-1 or glicentin) and the relative distribution of glicentin- and glucagon-containing cells were investigated by immunocytochemistry. By immunofluorescence, the antiglicentin serum, which does not react with glucagon, revealed positive cells in the islets of Langerhans and in the gut mucosa, particularly in the terminal ileum and colon. In the intestinal mucosa, it was proven ultrastructurally that the glicentin immunoreactive cells correspond to the L cell and that the secretory granules represent the storage compartment of the immunoreactive material. In pancreatic islets, consecutive semithin sections treated with antiglicentin and specific antiglucagon sera showed that the same A cell population reacted with both sera, while immunoperoxidase staining on thin sections revealed that the immunoreactive material was confined to the secretory granules. The same results were obtained on dog oxyntic mucosa, where the glicentin- and glucagon-containing cells were identified as the gastric A cell. The immunocytochemical demonstration of a common glicentin-like material in the A and L cells together with the known presence of a common immunoreactant in glicentin and glucagon strongly support the idea that the A and L cells are ontogenetically related and synthesize their secretory product via a glicentin-like precursor which, by specific cleavage, could yield glucagon and gut glucagon-like immunoreactants.
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PMID:Glicentin immunoreactive cells: their relationship to glucagon-producing cells. 37 54

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

Nerve fibers reacting with antisera demonstrating gut-type glucagon were numerous in certain areas of hypothalamus and thalamus but absent from neocortex and hippocampus. They did not react with glucagon antisera specific for pancreatic type glucagon. Immunoreactive cell bodies were not observed.
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PMID:Gut-type glucagon immunoreactivity in nerves of the rat brain. 38 62

By using both immunofluorescence and peroxidase-anti-peroxidase procedures to detect cells producing the four islet hormones, supplemented by biochemical, biological, and radioimmunological assays of tissue extracts, it has been shown that insulin seems to be the most original hormone, apparently occurring already in invertebrates in cells of open type in the alimentary tract mucosa. Insulin cells also predominate in the first islet organ, namely that of the cyclostomes. The order of appearance in the endocrine pancreas during the subsequent evolution is: somatostatin; glucagon; and the pancreatic polypeptide. Even in lower vertebrates pancreatic polypeptide cells occur in those parts of the pancreas situated in close proximity to the gut.
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PMID:Immunocytochemical studies of the evolution of islet hormones. 38 30

The pancreatic endocrine cells of Barbus conchonius are concentrated in a large (principal) islet, located near the gall bladder, and in a number of smaller islets. Five types of endocrine cells can be distinguished in there pancreatic islets: B cells, A1 (or D cells), 2 types of A2 cells (A2r cells with round granules; and A2fl cells with flocculent granules) and a scarce 5th cell type. The hormones produced by B and A2fl cells are probably insulin and glucagon respectively. The A2r cell contains granules with the same diameter as the granules of the enteroendocrine type III cell of the gut. Both cell types may resemble the enteroglucagon-producing EG cell of mammals. The function of the A1 cells, which are frequently found without secretory granules, and of the 5th cell type, will be discussed. The pancreastic islets of B. conchonius are strongly innervated, which suggests thatpresence of a direct nervous control system. Some intermediate or mixed cells containing exocrine and endocrine A2r granules are found continguous with the principal islet. The origin of pancreatic endocrine cells is also the subject of discussion.
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PMID:Pancreatic endocrine cells of Barbus conchonius (Teleostei, Cyprinidae), and their relation to the enteroendocrine cells. 38 29


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