Gene/Protein Disease Symptom Drug Enzyme Compound
Pivot Concepts:   Target Concepts:
Query: EC:4.6.1.1 (adenylate cyclase)
 19,190 document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)

An immunohistofluorescence procedure for detecting prostaglandin-forming cyclooxygenase has been used to localize the enzyme in the renal cortex of the cow, guinea pig, rabbit, rat, and sheep. Cyclooxygenase antigenicity was found in endothelial cells lining all arteries and arterioles and in cortical collecting tubules in each species examined. The enzyme was also detected in epithelial cells of Bowman's capsule in the rabbit and in mesangial cells in both ovine and bovine glomerular tufts. That prostaglandins can be formed in renal resistance vessels suggests that it is the synthesis occurring in these vessels which is responsible for the effects of prostaglandins on renal blood flow. Of further note is the correlation that exists between the location of the cyclooxygenase and that of the antidiuretic hormone-responsive adenyl cyclase in the distal nephron.
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PMID:Immunohistochemical localization of the prostaglandin-forming cyclooxygenase in renal cortex. 10 39

Thromboxane A2 plays an important role in arachidonic acid- and prostaglandin H2-induced platelet aggregation. Agents that stimulate platelet adenylate cyclase (prostaglandin I2, prostaglandin I1 and prostaglandin E1) and dibutyryl cyclic AMP inhibit both thromboxane A2 formation and arachidonate-induced aggregation in platelet-rich plasma. Despite complete suppression of aggregation with agents that elevate cyclic AMP, considerable thromboxane A2 is still formed. Prostaglandin H2-induced aggregations which bypass the cyclooxygenase regulatory step are also inhibited by agents that elevate cyclic AMP without any measurable effect on thromboxane A2 production. These data demonstrate that cyclic AMP can inhibit platelet aggregation by a mechanism independent of its ability to suppress the cyclooxygenase enzyme. Parallel experiments with washed platelet preparations suggest that they may be an inadequate model for studying the relationship between the platelet cyclooxygenase and platelet function.
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PMID:Regulatory role of cyclic adenosine 3',5'-monophosphate on the platelet cyclooxygenase and platelet function. 21 15

Platelets enzymatically convert prostaglandin H(3) (PGH(3)) into thromboxane A(3). Both PGH(2) and thromboxane A(2) aggregate human platelet-rich plasma. In contrast, PGH(3) and thromboxane A(3) do not. PGH(3) and thromboxane A(3) increase platelet cyclic AMP in platelet-rich plasma and thereby: (i) inhibit aggregation by other agonists, (ii) block the ADP-induced release reaction, and (iii) suppress platelet phospholipase-A(2) activity or events leading to its activation. PGI(3) (Delta(17)-prostacyclin; synthesized from PGH(3) by blood vessel enzyme) and PGI(2) (prostacyclin) exert similar effects. Both compounds are potent coronary relaxants that also inhibit aggregation in human platelet-rich plasma and increase platelet adenylate cyclase activity. Radioactive eicosapentaenoate and arachidonate are readily and comparably acylated into platelet phospholipids. In addition, stimulation of prelabeled platelets with thrombin releases comparable amounts of eicosapentaenoate and arachidonate, respectively. Although eicosapentaenoic acid is a relatively poor substrate for platelet cyclooxygenase, it appears to have a high binding affinity and thereby inhibits arachidonic acid conversion by platelet cyclooxygenase and lipoxygenase. It is therefore possible that the triene prostaglandins are potential antithrombotic agents because their precursor fatty acids, as well as their transformation products, PGH(3), thromboxane A(3), and PGI(3), are capable of interfering with aggregation of platelets in platelet-rich plasma.
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PMID:Triene prostaglandins: prostacyclin and thromboxane biosynthesis and unique biological properties. 21 23

With improved techniques for isolation and identification of materials, thromboxane (TXA2) and prostacyclin (PGI2) derivatives are now recognized as more abundant in some tissues and more potent than PGE2 and PGF2alpha. The rapid appearance and disappearance of these autacoids can be regulated at many points along the enzymatic path. Two important features affecting the rate of overall prostaglandin formation are the availability of non-esterified substrate and the availability of hydroperoxide activator for the cyclooxygenase. The fate of the endoperoxide formed by this reaction then depends upon the different relative amounts of the synthases and dehydrogenases in each type of synthesizing cell. Important future developments will indicate ways in which the amounts of these enzyme activities are altered and the ways in which the prostaglandin receptors interact with cellular adenyl cyclase and adrenergic receptors.
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PMID:The biosynthesis and metabolism of prostaglandins. 21 68

Addition of the 3-series fatty acid precursor (icosapentaenoic acid, IPA), its endoperoxide [prostaglandin (PG)H(3)], or thromboxane A(3) to human platelet-rich plasma (PRP) does not result in aggregation of the platelets. In fact, preincubation of human PRP with exogenous PGH(3) actually inhibited aggregation by increasing platelet cyclic AMP concentrations. PGH(3) undergoes rapid spontaneous degradation to PGD(3) in human PRP. The PGD(3) so formed is adequate to account for the increase of platelet cAMP and inhibition of aggregation. Furthermore, addition of PGD-specific antisera to human PRP blocked the platelet inhibitory activity of exogenous PGH(3). PGD(3) has considerable potential as a circulating antithrombotic agent. Pretreatment of human PRP with the adenylate cyclase inhibitor 2',5'-dideoxyadenosine blocked the increase of platelet cyclic AMP and the inhibition of aggregation normally produced by PGI(2), PGE(1), PGD(2), PGH(3), and PGD(3). Furthermore, the dideoxyadenosine unmasked a direct but moderate reversible aggregatory effect in response to the subsequent addition of PGH(3). Similarly, the dideoxyadenosine markedly enhanced the aggregation produced by exogenous PGH(2). IPA is readily incorporated into tissue lipids but proved to be a poor substrate for kidney, blood vessel, or heart cyclooxygenase. IPA was previously shown to be a poor substrate for platelet cyclooxygenase. IPA is readily deacylated from the renal phospholipid pool in response to bradykinin, a substance that also stimulates the release of arachidonic acid. A diet that relies primarily on cold-water fish, as in the case of the Greenland Eskimos, lowers endogenous arachidonic acid and markedly increases the IPA content of tissue lipids. Thus, because IPA has the potential to act as an antagonist with arachidonic acid for platelet cyclooxygenase and lipoxygenase, the simultaneous release of IPA could suppress any residual arachidonic acid conversion to its aggregatory metabolites.
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PMID:Triene prostaglandins: prostaglandin D3 and icosapentaenoic acid as potential antithrombotic substances. 23 Apr 92

Nitric oxide (NO), formed by conversion of arginine to citrulline and NO by NO synthase, mediates relaxation of vascular smooth muscle. NO synthase has been demonstrated by immunocytochemical methods in neurons in various parts of the central nervous system including the hypothalamus. The latter finding suggested to us that NO might play a role in controlling the release of hypothalamic peptides. We have previously shown that norepinephrine mediates the release of luteinizing hormone-releasing hormone (LHRH) from LHRH terminals in the median eminence into the hypophyseal portal veins, which transport LHRH to the anterior pituitary gland to trigger release of luteinizing hormone from gonadotrophs. LHRH release from these terminals requires increased release of prostaglandin E2 (PGE2). PGE2 activates adenylate cyclase to produce cAMP, and then cAMP induces the exocytosis of LHRH secretory granules. In view of the evidence above and because of the developing evidence for the importance of NO in the central nervous system, it occurred to us that NO might be involved in this process. Consequently, we evaluated the role of NO in the release of PGE2 from medial basal hypothalamic fragments. As previously reported, norepinephrine (10 microM) increased PGE2 release from the hypothalamic fragments. The inhibitor of NO synthase NG-monomethyl-L-arginine (NMMA, 300 microM) blocked the stimulation of PGE2 release induced by norepinephrine but had no effect on the basal release of PGE2. Sodium nitroprusside (100 microM), which liberates NO, also elevated PGE2 release from the hypothalamic fragments. This elevation was not affected by NMMA, presumably because NMMA blocks enzymatic generation of NO but does not alter NO liberated by nitroprusside. When the NO liberated by nitroprusside was inactivated by hemoglobin (2 micrograms/ml), the effect of nitroprusside on PGE2 release was completely inhibited. Neither NMMA nor hemoglobin altered the basal release of PGE2, which indicates that NO is not responsible for basal PGE2 release. Addition of L-arginine (10 microM to 1 mM), the substrate for NO synthase, had no effect on basal PGE2 production. These results indicate that NO synthase is not activated in unstimulated hypothalamic fragments in vitro. The results suggest that norepinephrine activates NO synthase leading to the production of NO, which subsequently activates cyclooxygenase and results in the production of PGE2. PGE2 then activates adenylate cyclase leading to generation of increased cAMP, which induces exocytosis of secretory granules of LHRH and other neuropeptides released by PGE2. The indication that NO is essential to norepinephrine-induced release of PGE2 from hypothalamic fragments provides insight into the mechanism of LHRH release and the results open the possibility that the importance of NO to neuronal functions may be widespread in the nervous system.
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PMID:Nitric oxide mediates norepinephrine-induced prostaglandin E2 release from the hypothalamus. 128 Aug 29

In this study, the role of adenosine 3',5'-cyclic monophosphate (cAMP)-dependent protein kinase A (PKA) in cAMP-dependent relaxation was assessed in the isolated-perfused rat lung using a PKA inhibitor, Rp-cAMPS, 8-bromo-cAMP (8-BrcAMP), and the diterpene activator of adenylate cyclase (AC), forskolin (FSK). A role for K+ channels was also assessed with the nonselective K+ channel blocker, tetraethylammonium (TEA, 10 mM), and an ATP-sensitive K+ channel inhibitor, glibenclamide (GLI, 100 microM). Both 8-BrcAMP (0.1-1.0 mM) and RSK (0.1-10 microM) dose-dependently attenuated the peak pressor response to alveolar hypoxia (HPR). Rp-cAMPS potentiated the HPR and attenuated 8-BrcAMP-mediated vasodilation but had no effect on FSK-mediated vasodilation. FSK-mediated vasodilation was not mimicked by 1,9-dideoxy-FSK, which is biologically inactive on AC but alters K+ channels identically to FSK, nor was it attenuated by the platelet-activating factor antagonist SRI 63-441 or the cyclooxygenase inhibitor indomethacin. TEA, but not GLI, attenuated FSK-mediated vasodilation. Similarly, TEA attenuated 8-BrcAMP-mediated vasodilation. These results support roles for PKA and indirect gating of a non-ATP-sensitive K+ channel in mediating cAMP-dependent pulmonary vasodilation.
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PMID:Role of cAMP-dependent protein kinase in cAMP-mediated vasodilation. 131 30

The signal transduction of prostaglandin E2 (PGE2) and thromboxane A2 (TXA2), cyclooxygenase products of arachidonic acid, was investigated in smooth muscle preparations and 1321N1 human astrocytoma cells. While PGE2 has been known to stimulate (via EP2 receptor) or inhibit (via EP3 receptor) adenylate cyclase, PGE2 activated phosphatidylinositol 4,5-bisphosphate (PIP2)-specific phospholipase C (PLase C) in non-vascular smooth muscles (via EP1 receptor), resulting in accumulations of inositol trisphosphate (IP3) and diacylglycerol to elicit intracellular Ca2+ mobilization. On the other hand, STA2, a TXA2 receptor analogue, also accumulated IP3 in human astrocytoma cells. [3H]SQ 29548, a TXA2 receptor antagonist, specifically bound to astrocytoma membranes. TXA2-receptor antagonists (ONO NT-126, S-145, SQ29548 and ONO3708) concentration-dependently inhibited PIP2-specific PLase C activation by STA2, and they also inhibited [3H]SQ 29548 binding in human astrocytoma cells. The Ki value of each antagonist in PIP2-specific PLase C inhibition was similar to that in [3H]SQ29548 binding inhibition. In membrane preparations, STA2 activated PIP2-specific PLase C in the presence of GTP gamma S. Pertussis toxin (IAP) did not affect STA2-induced PLase C activation. The results suggest that stimulation of TXA2 receptors activates PIP2-specific PLase C via an IAP-insensitive G-protein.
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PMID:[Signal transduction of prostaglandin E2 and thromboxane A2]. 131 76

In Swiss 3T3 murine fibroblasts, interleukin 1 (IL-1) and bradykinin stimulate prostaglandin E2 (PGE2) synthesis. However, in the present study, we found that neither agonist stimulated PGE2 synthesis in BALB/c 3T3 murine fibroblasts, this in spite of expression of similar numbers of receptors for each agonist compared to Swiss 3T3 cells. When BALB/c 3T3 cells were preincubated with cAMP analogs, both IL-1 and bradykinin stimulated PGE2 synthesis to levels similar to those observed in Swiss 3T3 cells. Similarly, when the cells were preincubated with forskolin, which activates the catalytic subunit of adenylate cyclase directly, or NECA, which stimulates cellular cAMP accumulation by activating adenosine receptors, IL-1 and bradykinin stimulated PGE2 synthesis. Rp-cAMPS, an inhibitor of cAMP-dependent protein kinase, blocked the ability of cAMP or NECA to render cells responsive to IL-1 and bradykinin. In basal BALB/c 3T3 cells, bradykinin and IL-1 stimulated arachidonate release in the absence of cAMP, but little conversion of released arachidonate to PGE2 occurred. cAMP, forskolin, and NECA all increased cyclooxygenase activity in the cells. SV-T2 is a clonal line originating from BALB/c 3T3 transformed with SV-40. In these cells, IL-1 and bradykinin stimulated PGE2 synthesis despite basal intracellular cAMP concentrations similar to BALB/c, and cAMP only modestly potentiated the response. In summary, cyclooxygenase expression appears to be regulated by cAMP in BALB/c 3T3 cells, and SV-40 transformation results in increased cyclooxygenase expression, apparently independent of cAMP.
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PMID:Elevated cAMP is required for stimulation of eicosanoid synthesis by interleukin 1 and bradykinin in BALB/c 3T3 fibroblasts. 133 33

The effect of azelastine on intracellular cyclic AMP concentration and on various indexes of cell activation was evaluated in guinea-pig alveolar macrophages and in human platelets. The effect of azelastine was further investigated on adenylate cyclase activity using membranes and homogenates from guinea-pig alveolar macrophages. Pretreatment of alveolar macrophages with azelastine prevented the activation induced by PAF-acether and by the chemotactic peptide fMLP as estimated by the reduced liberation of arachidonic acid metabolites formed by the cyclooxygenase and the lipoxygenase pathways. The effect of azelastine was concentration-dependent (50 to 500 microM) and reversible. Similarly, a short pretreatment with azelastine (100 microM) prevented arachidonic acid-induced platelet aggregation. This effect was also reversible after washing the platelets. In guinea-pig alveolar macrophages, azelastine induced a concentration-dependent (10 to 500 microM) increase in intracellular cyclic AMP and markedly potentiated the increase induced by PGE2. In human platelets, azelastine alone increased intracellular cyclic AMP concentration marginally only but, as in the case of macrophages, synergized with PGI2. Azelastine did not activate significantly adenylate cyclase unless a cytosolic factor was included within the membrane fraction. This effect of azelastine was not due to Ca2+ movements and was not modified by GTP. Our findings show that azelastine interferes with cell activation through a mechanism related to an increase in intracellular cyclic AMP concentration. The increase in cyclic AMP was induced by azelastine in intact cells and in homogenates but not in a crude membrane fraction. Those results indicate that azelastine modifies a cytosolic factor that may be phosphodiesterase. In addition, similarities between the effects of azelastine and those of reference phosphodiesterase inhibitors (theophylline, isobutyl-methyl-xanthine) are shown in this study, suggesting that azelastine might behave as a phosphodiesterase inhibitor.
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PMID:Azelastine potentiates the prostaglandin-induced increase of cyclic AMP content in human platelets and in guinea-pig alveolar macrophages. 137 22


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