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)

Duodenal gastrin release in the dog was studied after mucosal antrectomy with intact duodenal innervation, following which basal gastrin levels fell. Acetylcholine at pH 7 but not at pH 1.5 and insulin hypoglycemia but not 2-deoxyglucose release duodenal gastrin. Glycine (pH7), physiologic saline (pH 7), and balloon distention failed to release duodenal gastrin. These findings suggest differences in release characteristics between canine antral and duodenal gastrin, and point out species differences between man and dog in respect to release of duodenal gastrin.
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PMID:Characteristics of release of duodenal gastrin. 1 64

Biochemical assays on microdissected samples, denervation studies, subcellular fractionation, and light and electron microscopic autoradiography of high affinity uptake have been performed to study the cellular localization of transmitter candidates in the rat hippocampal formation. High affinity uptake of glutamate and aspartate is localized in the terminals of several excitatory systems, such as the entorhino-dentate fibres (perforant path), mossy fibres (from granular cells) and pyramidal cell axons. Thus, in stratum radiatum and oriens of CA1, 85% of glutamate and asparate uptake and 40% of glutamate and aspartate content are lost after lesions of ipsilateral plus commissural fibres from CA3/CA4. Hippocampal efferents also take up aspartate and glutamate, since these activities are heavily reduced in the lateral septum and mamillary bodies after transection of fimbria and the dorsal fornix. The synthesis (by glutamic acid decarboxylase), content and high affinity uptake of gamma-aminobutyrate (GABA) are not reduced after lesions of these or other projection fibre systems. A localization in intrinsic neurons is confirmed by a selective loss of glutamic acid decarboxylase after local injections of kainic acid. Peak concentrations of the enzyme occur near the pyramidal and granular cell bodies, corresponding to the site of the inhibitory basket cell terminals, and in the outer parts of the molecular layers. Some 85% of glutamic acid decarboxylase is situated in 'nerve ending particles'. Acetylcholine synthesis (by choline acetyltransferase) disappears after lesions of septo-hippocampal fibres. Since 80% of the hippocampal choline acetyltransferase is in 'nerve ending particles', the characteristic topographical distribution of this enzyme should reflect the distribution of cholinergic septo-hippocampal afferents. Serotonin, noradrenaline, dopamine and histamine are located/synthesized in afferent fibre systems. Some monoamine-containing afferents to the hippocampal formation pass via the septal area, others via the amygdala. The hippocampal formation also contains nerve elements reacting with antibodies against neuroactive peptides, such as enkephalin, substance P, somatostatin and gastrin/cholecystokinin.
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PMID:Localization of putative transmitters in the hippocampal formation: with a note on the connections to septum and hypothalamus. 3 19

The three stimulants of gastric acid secretion likely to have physiological roles in regulation of secretion are acetylcholine, gastrin, and histamine. Acetylcholine is released by vagal and intramucosal reflex stimulation, acting directly on the parietal cell. Gastrin is released by peptides and free amino acids in the stomach and is the only known hormonal stimulant of acid secretion. Release of gastrin by acetylcholine may occur. However, cholinergic control of gastrin release is complex since under certain conditions anticholinergic drugs may actually enhance gastrin release. Factors regulating histamine release have not been defined, but studies with H2-receptor antagonists leave little doubt that histamine has an important role in acid secretion. Studies with isolated parietal cells indicate that histamine, gastrin, and acetylcholine each appear to act at separate receptors on the parietal cell. Anticholinergic agents specifically prevent the cellular actions of acetylcholine, cimetidine specifically inhibits stimulation by histamine, and neither inhibitor blocks the small direct response to gastrin. Furthermore potentiating interactions occur between histamine, gastrin, and cholinergic agents which may account for the interdependence of secretagogue action observed in vivo. Direct potentiating interactions occur between histamine and gastrin and histamine and carbachol but not between carbachol and gastrin. However, in the presence of histamine, carbachol, and gastrin, a three-way potentiation does occur. By interfering with the potentiating interactions between stimulants, anticholinergic agents and cimetidine display an apparent cross-specificity in vitro that resembles the effects of these agents in intact mucosa. The mechanisms underlying these interactions are unknown, but the actions of histamine appear to be mediated through increased production of cyclic AMP and cyclic AMP analogs, which mimic the interactions involving histamine itself. The secondary effectors for acetylcholine and gastrin and the mechanisms for amplification of the response to combinations of stimulants remain to be elucidated.
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PMID:Regulation of gastric acid secretion. 21 62

The effect of intragastric administration of acetylcholine on serum and antral gastrin concentrations of rats has been examined using a radioimmunoassay and quantitative electron microscopy. Exposure of the stomach of rats, previously fasted for 24h, to 2% acetylcholine for either 0.5 or 2h resulted in a significant 4--5 fold increase in serum gastrin concentrations to levels similar to those found in fed animals. Such treatment produced no detectable change in antral gastrin concentration or in the number or electron density of secretory granules in the G cells. This lack of detectable change in the G cells was not unexpected since our calculations suggest that less than 10% of the total gastrin stored in the antrum is released over 2h as a result of the stimulation with acetylcholine. The proportion of electron-lucent secretory granules was, however, markedly increased by prolonged fixation in aldehydes. The increase was similar in both ACh stimulated and control animals. These results indicate that the ultrastructural appearance of G cell secretory granules in influenced far more by the conditions of fixation than by the release of gastrin. They therefore cast considerable doubt on the hypothesis that gastrin is released by molecular dispersion from the granules.
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PMID:Gastrin and the ultrastructure of G cells after stimulation with acetylcholine. 35 63

The anaesthetised rat stomach preparation was adapted to assay intraluminally administered stimulants and inhibitors of acid secretion by continuously recirculating the perfusate (15 ml of 5% glucose) and measuring acid by the pH-stat technique. The responses obtained were linear. Continuous artificial neutralisation of the stomach to pH 5.5 as well as variation of the pH between 6.5 and 4.0 did not significantly alter the sensitivity of the preparation to intravenously administered human gastrin-heptadecapeptide I (HG I). Basal acid secretion however significantly declined following stepwise lowering of the intragastric pH between 6.5 and 4.0. The threshold values for responses to i.v. HG I were below 16 ng. 6 doses could be given per rat without tachyphylaxis. Acetylcholine, 1.3, 2.5, 5.2 and 10.4 micron g/ml in the perfusate, induced a dose-dependent linear (r=0.902) acid secretion. Metiamide 1.66 mg/ml in the perfusate, produced a parallel shift to the right of the HG I dose--response curve producing an agonist dose ratio of 3.66. The data suggest that intragastrically applied stimulants and inhibitors of acid secretion can be studied precisely in this relatively simple preparation.
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PMID:Intragastric titration of acid in the perfused rat stomach preparation following parenteral and intraluminal stimulation. 87 79

Receptors for the main neural (acetylcholine), hormonal (gastrin) and paracrine (histamine) secretory stimulants and the signal transduction pathways to which these receptors are coupled have been identified on the parietal cell. The stimulatory effect of histamine is mediated via an increase in adenylate cyclase activity, whereas the effect of acetylcholine and gastrin are mediated via an increase in cytosolic levels of calcium. Strong synergism between histamine and either gastrin or acetylcholine may reflect postreceptor interaction between the distinct pathways. Acetylcholine and gastrin are also capable of releasing histamine from the gastric mucosa, probably from ECL cells. The inhibitory effects of somatostatin and prostaglandin E on acid secretion are mediated by receptors coupled via guanine nucleotide binding proteins to inhibition of adenylate cyclase activity. All the pathways converge on and modulate the activity of the luminal enzyme, H+K(+)-ATPase, ultimately responsible for acid secretion. The intramural neural and paracrine pathways involved in the regulation of gastrin secretion in the antrum and acid secretion in the fundus have also been identified. Of prime importance is the somatostatin cell, which exerts a paracrine restraint on gastrin secretion and acid secretion. Elimination of this restraint or disinhibition is one of the mechanisms by which the stimulatory influence of cholinergic neurons is exerted on gastrin and parietal cells. Gastrin secretion is regulated by a cholinergic neuron that causes inhibition of somatostatin secretion and thus stimulation of gastrin secretion (disinhibition) and a noncholinergic neuron that causes direct stimulation of gastrin secretion by releasing the neurotransmitter, bombesin (or gastrin-releasing peptide). Acid secretion is regulated by a cholinergic neuron that causes direct stimulation of the parietal cell and indirect stimulation by decreasing somatostatin secretion, thus eliminating its inhibitory effect on the parietal cell (disinhibition). In addition, a regulatory feedback mechanism exists whereby intraluminal acidification stimulates somatostatin secretion, which in turn attenuates acid secretion. Gastric acid secretion may also be regulated by one or more intestinal inhibitory hormones, the most likely candidates being secretin, intestinal somatostatin, and neurotensin. Enterogastrone activity probably reflects the combined effect of all these hormones. Precise information on receptors and signal transduction mechanisms as well as on intramural neural and paracrine regulatory pathways has led to the development of new drugs capable of inhibiting acid secretion. These include antagonists that interact with stimulatory receptors (histamine H2-receptor antagonists, muscarinic receptor antagonists, and gastrin receptor antagonists), agonists that interact with inhibitory receptors (somatostatin and prostaglandin E analogues), and irreversible inhibitors of the luminal enzyme, H+K(+)-ATPase.
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PMID:Control of acid secretion. 169 38

To study the role of somatostatin in the regulation of pancreatic and gastric functions, a combined isolated rat stomach and pancreas preparation was developed. This model allowed simultaneous measurements of exocrine and endocrine secretion from the pancreas and gastrin secretion from the stomach. Somatostatin was applied either by a linear gradient or by constant infusion with one concentration in the presence of cerulein, secretin, electric vagal activity, or acetylcholine. Somatostatin did not influence exocrine pancreatic secretion irrespective of what substance was stimulated. In contrast, somatostatin significantly inhibited glucose-dependent insulin and gastrin secretion, either basal or stimulated by vagal activity or acetylcholine. Acetylcholine-induced gastrin secretion was more sensitive to inhibition by somatostatin than insulin. We conclude that in an isolated perfused organ system somatostatin has potent inhibitory effects on endocrine pancreas and stomach but has no effect on exocrine pancreatic volume and enzyme secretion.
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PMID:Effects of somatostatin-14 on gastric and pancreatic responses to hormonal and neural stimulation using an isolated perfused rat stomach and pancreas preparation. 245 92

Using the "Bi-Digital O-Ring Test Imaging Technique", the author has been able to accurately localize meridians and acupuncture points that correspond to specific internal organs and has found that most general patterns of meridians and the number of acupuncture points on each of the meridians of specific internal organs of the 12 main internal organs described in the literature of ancient Chinese medicine, are more or less correct, with the exception of some variations and inaccuracies. Each meridian of specific internal organs was found to be connected to the organ representation area in the cerebral cortex of specific internal organs. The acupuncture point has an area and occupies 3-dimensional space. It has a circular or slightly oval boundary with diameter in the range of 3 mm to 2.7 cm, although 6-12 mm are the most common diameters in human adults, with the exception of the area outside the corners of the nailbeds of the fingers and toes. Using the "Bi-Digital O-Ring Test Molecular Identification Method", the author also found that within the boundary of most acupuncture points and meridian lines (including Heart, Stomach, and Triple Burner) were high concentrations of neurotransmitters and hormones, including Acetylcholine, Methionine-Enkephalin, Beta-Endorphin, ACTH, Secretin, Cholecystokinin, Norepinephrine, Serotonin, and GABA. On all these meridian lines, in addition to the above neurotransmitters and hormones, Dopamine, Dynorphin 1-13, Prostaglandin E1 (PGE1) and VIP were found, but the latter do not usually exist within the boundary of the acupuncture point with the exception of the center midline of the acupuncture point where the meridian line is situated. Serotonin, Norepinephrine, and Cholecystokinin appeared in either one of the above 2 patterns, depending on the individual. Usually, no significant amounts of these neurotransmitters and hormones were found at the surrounding area outside of meridian and acupuncture points. However, the essential amino acid L-Tryptophan (which is a precursor of Serotonin), was usually found outside of the boundary of the acupuncture point and the meridian but not within the boundary of the acupuncture point and the meridian. Wherever Serotonin appeared, L-Tryptophan disappeared significantly and when the Serotonin disappeared, L-Tryptophan reappeared. In addition to the above common neurotransmitters and hormones, the Heart meridian had additional Atrial Natriuretic Peptide in both the meridian and its acupuncture points. Similarly, the Stomach meridian had additional Gastrin in both the meridian and its acupuncture points. Likewise,the Triple Burner meridian had additional Testosterone (in the male) and Estrogen (especially Estriol and Estradiol in the female.
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PMID:Connections found between each meridian (heart, stomach, triple burner, etc.) & organ representation area of corresponding internal organs in each side of the cerebral cortex; release of common neurotransmitters and hormones unique to each meridian and corresponding acupuncture point & internal organ after acupuncture, electrical stimulation, mechanical stimulation (including shiatsu), soft laser stimulation or QI Gong. 257 47

The etiology of peptic ulcer disease is completely unknown. However, gastric acid secretion plays an important role in the pathogenesis of the disease. Acetylcholine, gastrin and histamine are recognized as the main stimulators of the acid secretion. Extensive studies on blood gastrin have not incriminated this hormone in the pathogenesis of the disease. The present study was done to evaluate the role of circulating histamine in peptic ulcer disease using a sensitive and specific radioimmunoassay method. Since gastrin at least in some species seems to exert its stimulatory effect by releasing histamine, serum gastrin was also determined. There was no significant difference in plasma histamine between patients with duodenal or gastric ulcer, nonulcer dyspepsia or ulcer patients after proximal gastric vagotomy. However, patients taking a histamine-2 blocker (cimetidine or ranitidine) had significantly higher plasma histamine than those not taking these drugs. This effect was not due to interference in the histamine assay. There was no correlation between plasma histamine and plasma gastrin. Plasma gastrin was significantly increased in patients having been operated on with a proximal gastric vagotomy. In conclusion, plasma histamine is similar in patients with different upper gastrointestinal disorders. However, histamine-2 blockers may increase plasma histamine.
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PMID:Histamine and gastrin in plasma of patients with upper gastrointestinal diseases. 276 43

In vitro studies on the vascularly perfused rat stomach have shown that gastrin secretion is regulated by intramural cholinergic and noncholinergic neurons. We have postulated that bombesin (gastrin-releasing peptide), a known gastrin stimulant present in antral mucosal nerve fibers, is the most likely candidate for noncholinergic transmitter. Bombesin antiserum (final dilution, 1:150) but not control serum added to the vascular perfusate inhibited the gastrin response to 1,1-dimethyl-4-phenylpiperazinium by 59 +/- 17% (P less than 0.01) and to electrical field stimulation by 60 +/- 16% (P less than 0.01), and its effect was additive to that of 10(-7) M atropine (75-94%), thus accounting for the greater part of neurally induced gastrin secretion. The effects of atropine and bombesin antiserum on somatostatin secretion were consistent also with blockade of cholinergic and noncholinergic neurons, respectively. The results indicate that bombesin and acetylcholine are the main intramural neural regulators of gastrin and somatostatin secretion. Acetylcholine acts predominantly to decrease the paracrine secretion of somatostatin, thereby eliminating the continuous restraint of somatostatin on gastrin secretion and enabling bombesin to exert its potent stimulatory effect on gastrin secretion.
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PMID:Inhibition of neurally mediated gastrin secretion by bombesin antiserum. 285 81


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