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: EC:4.6.1.1 (adenylate cyclase)
19,190 document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)

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

It was found that repeated transplantation of ACATOL strain cells resulted in a loss of their sensitivity to growth-stimulating effect of pentagastrin. The effect of gastrin receptor antagonist proglumide, on ACATOL cells growth was inconstant. ACATOL tumor was sensitive to VIP and glucagon in vitro (as shown by adenylate cyclase activity assay), that makes the model promising for selecting potent hormone drugs against colorectal cancer.
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PMID:[The hormonal sensitivity of a transplantable adenocarcinoma of the large intestine]. 222 62

Parietal cell secretory function may be inhibited by three mechanisms. (1) Receptors for gastrin, histamine and acetylcholine are present on the canine parietal cell, and parietal cell function may be directly inhibited by specific antagonists for each of these receptors. (2) Receptor activation of parietal cell function is mediated by cyclic AMP-dependent (histamine) and calcium-dependent (cholinergic agents and gastrin) mechanisms. The antisecretory action of prostaglandins reflect interference with histamine activation of adenylate cyclase. The current generations of calcium channel blockers have only weak antisecretory actions in vivo and are unlikely to be useful in clinical practice. (3) A third mechanism of inhibition is blockade of H+/K(+)-ATPase by substituted benzimidazoles, such as omeprazole. Each of these three mechanism provides modalities of potential clinical usefulness for treating acid-peptic disease. Gastrin and acetylcholine receptors are present on other fundic cells, in addition to the parietal cell. These other cells include the somatostatin cell in the dog fundic mucosa and the histamine-containing enterochromaffin-like (ECL) cell present in the fundic mucosa of several species. The relative impact of these receptors on different cell types on the regulation of acid secretion remains uncertain, and is probably variable among different species. One gastrin receptor of considerable importance is the gastrin receptor that exerts a trophic effect on the ECL cell in the fundic mucosa. Sustained hypergastrinaemia in response to profound hypochlorhydria is associated with hyperplasia of this cell type; the elucidation of the conditions that promote this hyperplasia and the clinical consequences of this association are pressing challenges.
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PMID:Review: antisecretory drugs: cellular mechanisms of action. 297 19

Venom from Gila monster (family Helodermatidae) contains a pancreatic secretagogue. In dispersed acini from guinea pig pancreas, the venom increased enzyme secretion to the same extent as did vasoactive intestinal peptide, secretin, or PHI. The abilities of vasoactive intestinal peptide and Gila monster venom to stimulate enzyme secretion were not altered by boiling but were abolished by incubation with trypsin or chymotrypsin. Like vasoactive intestinal peptide, secretin, and PHI, the venom caused a 50- to 60-fold increase in cellular cAMP and inhibited binding of 125I-vasoactive intestinal peptide to its membrane receptors on pancreatic acini. The action of venom on enzyme secretion was inhibited by [Gln9]secretin-(5-27), a vasoactive intestinal peptide receptor antagonist, but was not altered by atropine, a cholinergic receptor antagonist, or by dibutyryl cGMP, a cholecystokinin receptor antagonist. Gila monster venom contained no immunoreactive vasoactive intestinal peptide by radioimmunoassay. These results indicate that venom from Gila monster contains a peptide that can stimulate pancreatic enzyme secretion by interacting with vasoactive intestinal peptide receptors on pancreatic acinar cells and thereby activating adenylate cyclase and increasing cellular cAMP.
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PMID:Actions of Gila monster venom on dispersed acini from guinea pig pancreas. 617 52

The mechanism whereby somatostatin (SS) produces beneficial effects in established pancreatitis induced by pancreaticobiliary duct ligation (PBDL) is still not clear. The aim of the work was to evaluate the possibility of a direct action of SS on pancreatic acinar cells from rats with acute pancreatitis. For this purpose, we studied the SS-receptor-adenylate cyclase system in pancreatic acinar membranes from both, control rats and rats with experimentally induced acute pancreatitis. On the other hand, it has been reported that cholecystokinin (CCK) diminishes the number of SS receptors in pancreatic acinar cells. Proglumide, a CCK receptor antagonist reduces the severity of acute pancreatitis in the rat. Therefore, we have also examined the effect of proglumide on the somatostatinergic system in controls and rats with acute pancreatitis. Fourteen hours after PBDL, the SS receptors, the capacity of the SS analogue SMS 201-995 to inhibit forskolin-stimulated adenylate cyclase activity and PTX-catalyzed [32P] ADP-ribosylation of the alpha1 subunits of Gi proteins could not be detected in pancreatic acinar membranes. One month after reopening the closed pancreaticobiliary duct (PBD), the pancreas showed regeneration of acinar cells, and the above-mentioned parameters were significantly lower than in the control group. Two months after reopening the closed PBD, all these parameters had returned to control values. The administration of proglumide (20 mg/kg i.p.), a cholecystokinin receptor antagonist, accelerated pancreatic regeneration and approached all these parameters to control values one month after reopening the closed PBD. The present study suggests that the beneficial effects of SS on established pancreatitis induced by PBDL may not be due to a direct action of the peptide on pancreatic acinar cells at least at 14 hours after PBDL. In addition, these findings suggest that in established pancreatitis the effect of proglumide on the SS receptor-adenylate cyclase system could be due to its action on pancreatic regeneration.
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PMID:The somatostatin receptor-adenylate cyclase system in rat pancreatic acinar membranes after temporary pancreaticobiliary duct ligation. 940 49

Gastric acid secretion is under nervous and hormonal control. Gastrin, the major circulating stimulus of acid secretion, probably does not stimulate the parietal cells directly but acts to mobilize histamine from the ECL cells in the oxyntic mucosa. Histamine stimulates the parietal cells to secrete HCl. The gastrin-ECL cell pathway has been investigated extensively in situ (gastric submucosal microdialysis), in vitro (isolated ECL cells) and in vivo (intact animals). Gastrin acts on CCK2 receptors to control the synthesis of ECL-cell histamine, accelerating the expression of the histamine-forming enzyme histidine decarboxylase (HDC) at both the transcription and the translation/posttranslation levels. Depletion of histamine by alpha-fluoromethylhistidine (an irreversible inhibitor of HDC) prevents gastrin-induced but not histamine-induced gastric acid secretion. Acute CCK2 receptor blockade inhibits gastrin-evoked but not histamine-induced acid secretion. Studies both in vivo/in situ and in vitro have suggested that while acetylcholine seems capable of activating parietal cells, it does not affect histamine secretion from ECL cells. Unlike acetylcholine, the neuropeptides pituitary adenylate cyclase-activating peptide and vasoactive intestinal peptide mobilize ECL-cell histamine. Whether vagally stimulated acid secretion reflects an effect of the enteric nervous system on the ECL cells (neuropeptides) and/or a direct one on the parietal cells needs to be further investigated.
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PMID:Control of gastric acid secretion:the gastrin-ECL cell-parietal cell axis. 1124 41

Cholecystokinin is a regulatory peptide, that acts through two subtypes of receptors, 1 and 2. RT-PCR demonstrated the expression of both cholecystokinin receptors 1 and 2 genes in the zona glomerulosa, but not the zona fasciculata-reticularis, of rat adrenals. Autoradiography demonstrated the presence of abundant [(125)I]cholecystokinin-binding sites in the zona glomerulosa, but not the zona fasciculata-reticularis, which were displaced by both cholecystokinin receptor 1- and 2-selective antagonists (cholecystokinin 1-A and 2-A). Cholecystokinin increased basal aldosterone secretion from dispersed zona glomerulosa cells without affecting corticosterone secretion from zona fasciculata-reticularis cells. The aldosterone response to cholecystokinin was blunted by cholecystokinin 1-A and 2-A, which when added together abolished it. ACTH-stimulated aldosterone production was not affected by cholecystokinin; in contrast, cholecystokinin potentiated aldosterone response to both angiotensin II and K(+). Cholecystokinin enhanced cAMP, but not IP(3), release by dispersed zona glomerulosa cells. The aldosterone response to cholecystokinin was abolished by the adenylate cyclase inhibitor SQ-22536 and the PKA inhibitor H-89, but not by either the PLC inhibitor U-73122 or the PKC inhibitor calphostin C. In conclusion, our study provides evidence that cholecystokinin, acting through cholecystokinin receptors 1 and 2 coupled with the adenylate cyclase/PKA cascade, exerts a sizeable secretagogue action on rat zona glomerulosa cells.
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PMID:Cholecystokinin stimulates aldosterone secretion from dispersed rat zona glomerulosa cells, acting through cholecystokinin receptors 1 and 2 coupled with the adenylate cyclase-dependent cascade. 1156 81

Stimulation of the brain CCK2 receptor by the C-terminal octapeptide CCK8 of cholecystokinin (CCK) negatively modulates opioid responses. This suggests the existence of physiologically relevant interactions between endogenous CCK and opioid peptides, opening new perspectives particularly in the treatment of pain or drug addiction. CCK2 receptor-deficient mice were used to analyze the incidence of this gene invalidation on opioid system. Compared with wild-type mice, mutants exhibited the following: (1) a hypersensitivity to the locomotor activity induced by inhibitors of enkephalin catabolism or by morphine; (2) a spontaneous hyperalgesia to thermal nociceptive stimulus, which was reversed by previous administration of the NMDA antagonist MK-801 [(+)-5-methyl-10,11-dihydro-5H-dibenzo [a,d] cyclohepten-5,10-imine maleate], and a large reduction in analgesic effects of endogenous or exogenous opioids; and (3) a more severe withdrawal syndrome after chronic morphine treatment. As expected, stimulation of mu, delta, and D2 receptors on brain tissue of wild-type animals induced a dose-dependent decrease in adenylate cyclase activity, whereas a striking mirror effect was observed in mutants. All of these results suggest that the absence, in knock-out mice, of the negative feedback control on the opioid system, normally performed out by CCK2 receptor stimulation, results in an upregulation of this system. These biochemical and pharmacological results demonstrate the critical role played by CCK2 receptors in opioid-dependent responses.
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PMID:Deletion of CCK2 receptor in mice results in an upregulation of the endogenous opioid system. 1188 May 31

Cholecystokinin (CCK) IS a regulatory peptide that acts via two receptor subtypes, CCK1-R and CCK2-R. RT-PCR demonstrated the expression of both CCK1-R and CCK2-R in the zona glomerulosa (ZG), but not zona fasciculata-reticularis cells of the human adrenal cortex. CCK and the CCK2-R agonist pentagastrin enhanced basal aldosterone secretion from ZG cells without affecting cortisol production from zona fasciculata-reticularis cells. The aldosterone response to CCK and pentagastrin was suppressed by a CCK2-R antagonist, but not by a CCK1-R antagonist. Pentagastrin evoked a sizeable cAMP, but not inositol triphosphate, response from ZG cells, whereas CCK plus CCK2-R antagonist was ineffective. The cAMP response to pentagastrin was abrogated by CCK2-R antagonist or the adenylate cyclase inhibitor SQ-22536, and the aldosterone response was abolished by both SQ-22536 and the protein kinase A inhibitor H-89. Both CCK and pentagastrin increased steroidogenic acute regulatory protein mRNA expression in ZG cells; the effect was abrogated by CCK2-R antagonist. We conclude that CCK exerts secretagogue action on human ZG cells, acting through CCK2-Rs coupled to the adenylate cyclase/protein kinase A signaling cascade, which, in turn, stimulates the expression of steroidogenic acute regulatory protein, the rate-limiting step of steroidogenesis.
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PMID:Cholecystokinin (CCK) stimulates aldosterone secretion from human adrenocortical cells via CCK2 receptors coupled to the adenylate cyclase/protein kinase A signaling cascade. 1500 23

Cholecystokinin, or CCK, is a 33-amino acid peptide, originally considered a gut hormone, that acts via two subtypes of receptors, named CCK1-R and CCK2-R. CCK, along with its receptors, has been subsequently localized in the central nervous system, where it exerts, among other fuctions, antiorexinogenic actions. In this survey, we describe findings indicating that CCK, similar to other peptides modulating food intake (e.g., neuropeptide Y, leptin, and orexins), is also able to regulate the function of the hypothalamo-pituitary-adrenal axis, acting on both its central and peripheral branches. CCK stimulates aldosterone secretion via specific receptors (CCK1-Rs and CCK2-Rs in rats, and CCK2-Rs in humans) located in zona glomerulosa cells and coupled to the adenylate cyclase-dependent signaling cascade; and enhances glucocorticoid secretion from zona fasciculata-reticularis cells via an indirect mechanism mainly involving the CCK2-R-mediated stimulation of corticotropin-releasing hormone-dependent ACTH release.
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PMID:Cholecystokinin and adrenal-cortex secretion. 1611 77


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