Gene/Protein Disease Symptom Drug Enzyme Compound
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Query: EC:4.6.1.2 (guanylate cyclase)
 8,497 document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)

NADPH diaphorase histochemistry selectively labels a number of discrete populations of neurons throughout the nervous system. This simple and robust technique has been used in a great many experimental and neuropathological studies; however, the function of this enzyme has remained a matter of speculation. We, therefore, undertook to characterize this enzyme biochemically. With biochemical and immunochemical assays, NADPH diaphorase was purified to apparent homogeneity from rat brain by affinity chromatography and anion-exchange HPLC. Western (immunoblot) transfer and immunostaining with an antibody specific for NADPH diaphorase labeled a single protein of 150 kDa. Nitric oxide synthase was recently shown to be a 150-kDa, NADPH-dependent enzyme in brain. It is responsible for the calcium/calmodulin-dependent synthesis of the guanylyl cyclase activator nitric oxide from L-arginine. We have found that nitric oxide synthase activity and NADPH diaphorase copurify to homogeneity and that both activities could be immunoprecipitated with an antibody recognizing neuronal NADPH diaphorase. Furthermore, nitric oxide synthase was competitively inhibited by the NADPH diaphorase substrate, nitro blue tetrazolium. Thus, neuronal NADPH diaphorase is a nitric oxide synthase, and NADPH diaphorase histochemistry, therefore, provides a specific histochemical marker for neurons producing nitric oxide.
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PMID:Neuronal NADPH diaphorase is a nitric oxide synthase. 170 73

To evaluate an interaction between vasoconstrictive (Ang II) and vasodilating (ANP) peptides, we examined the effect of Ang II on ANP-induced accumulation of cGMP in cultured glomerular mesangial cells. ANP rapidly increased intracellular cGMP levels, with a peak stimulation at one minute in the absence of IBMX and at ten minutes in the presence of IBMX. The ANP-induced cGMP accumulation was significantly inhibited when the cells were treated with Ang II simultaneously with ANP for one minute in the absence of IBMX. This inhibitory effect of Ang II was completely abolished by IBMX and significantly reduced in calcium-free media or by W7, but not affected by H7. Similar inhibitory effect was observed when cells were treated with A23187 but not with TPA for one minute. In the presence of IBMX, Ang II inhibited ANP-induced cGMP accumulation when cells were treated with Ang II for 15 minutes prior to the stimulation by ANP. This inhibition by Ang II was blocked by H7. ANP-induced increase in particulate guanylate cyclase activity was significantly reduced in the cells treated with Ang II or TPA. This reduction of enzyme activity was also prevented by H7. These results indicate that Ang II inhibits ANP-induced cGMP accumulation in cultured glomerular mesangial cells through at least two mechanisms; one is the activation of calcium-dependent, calmodulin-stimulated cyclic nucleotide phosphodiesterase in the initial phase, and the other is the inhibition of guanylate cyclase resulting from protein kinase C activation in the maintenance phase.
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PMID:Dual mechanism of angiotensin II inhibits ANP-induced mesangial cGMP accumulation. 171 65

We investigated the molecular mechanisms whereby Ca2+ enters the endothelial cytosol and regulates endothelial nitric oxide synthesis L-arginine-dependent nitric oxide synthesis by isolated endothelial cytosol as quantified by activation of a purified soluble guanylate cyclase was concentration-dependently enhanced by free Ca2+ (EC50 0.3 microM). The Ca(2+)-dependent activation was inhibited by the calmodulin antagonists mastoparan, melittin, and calcineurin (IC50 450, 350, and 60 nM, respectively) in a calmodulin-reversible manner. After removal of endogenous calmodulin the Ca(2+)-dependency of endothelial NO synthase was lost, but could be reconstituted with exogenous calmodulin. The results indicate that Ca(2+)-calmodulin directly activates the endothelial nitric oxide synthase, thereby transducing agonist-induced increases in intracellular free Ca2+ concentration to nitric oxide formation from L-arginine, K(+)-induced depolarization of the endothelial cells markedly inhibited the sustained, but not initial phase of the intracellular Ca2+ response to bradykinin, indicating that K(+)-induced depolarization depresses the transmembrane Ca2+ influx. On the contrary, the K+ channel activator Hoe 234 which elicits hyperpolarization of the endothelial cell membrane, augmented the sustained phase of the agonist-induced intracellular Ca2+ signal, but not the resting intracellular Ca2+ level. The effects of K+ and Hoe 234 on the agonist-induced Ca(2+)-response were reflected by corresponding changes in agonist-induced EDRF/NO release. From these data, we suggest that the endothelial membrane potential may play an important role for the extent of agonist-induced Ca2+ influx and, thereby, the endothelial EDRF/NO synthesis.
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PMID:Cellular mechanisms controlling EDRF/NO formation in endothelial cells. 171 54

The role of individual cyclic nucleotide phosphodiesterase (PDE) isozymes in regulating cAMP and cGMP content in intact canine trachealis was examined using isozyme-selective and nonselective PDE inhibitors. The inhibitors used in this study were characterized previously [Mol. Pharmacol. 37:206-214 (1990)] and included: 1) zaprinast, an inhibitor (Ki = 0.1 microM) of the cGMP-specific PDE (cAMP Km = 135 microM; cGMP Km = 4 microM); 2) SK&F 94120, an inhibitor (Ki = 7 microM) of the cGMP-inhibited PDE (cAMP Km = 0.3 microM; cGMP Km = 8 microM); 3) Ro 20-1724, an inhibitor (Ki = 5 microM) of the cAMP-specific PDE (cAMP Km = 4 microM; cGMP Km = 40 microM); and 4) 3-isobutyl-1-methylxanthine (IBMX), a nonselective PDE inhibitor (IC50 = 1-30 microM). In addition to the aforementioned isozymes, canine trachealis contains a Ca2+/calmodulin-stimulated PDE (cAMP Km = 1 microM; cGMP Km = 2 microM) and a GMP-stimulated PDE (cAMP Km = 93 microM; cGMP Km = 60 microM), for which selective inhibitors are not available. Isolated canine trachealis strips were contracted with methacholine and exposed to various concentrations of PDE inhibitors, before being relaxed by the cumulative addition of isoproterenol, an adenylate cyclase activator, or sodium nitroprusside, a guanylate cyclase activator. At the completion of the concentration-response studies, tissues were flash-frozen and assayed for cyclic nucleotide content. Neither isoproterenol-induced relaxation nor cAMP accumulation was altered by zaprinast, but both of these responses were potentiated by pretreatment of tissues with either SK&F 94120 or Ro 20-1724. The effects of SK&F 94120 and Ro 20-1724 were additive, and the combination of SK&F 94120, Ro-1724, and IBMX had no greater effect on the responses to isoproperenol than did either IBMX alone or the combination of SK&F 94120 plus Ro 20-1724. In contrast, zaprinast potentiated sodium nitroprusside-induced relaxation and cGMP accumulation, whereas neither SK&F 94120 nor Ro 20-1724 altered these responses. IBMX produced a greater potentiation than did zaprinast, and the combination of zaprinast and IBMX had a greater effect than either agent alone. The results of this study suggest that the cGMP-inhibited and cAMP-specific PDEs are responsible for cAMP hydrolysis in intact canine trachealis, whereas cGMP hydrolysis is mediated by the cGMP-specific PDE as well as the Ca2+/calmodulin-stimulated PDE and/or the cGMP-stimulated PDE.
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PMID:Role of cyclic nucleotide phosphodiesterase isozymes in intact canine trachealis. 184 59

In the present studies we sought to determine if cicletanine, which is an antihypertensive agent of unknown mechanism, could alter cGMP metabolism via inhibition of cGMP phosphodiesterases (PDE) in vascular smooth muscle. Cicletanine was determined to be a mixed (competitive, noncompetitive) inhibitor of both calmodulin-regulated and cGMP-specific PDEs from monkey aortic smooth muscle with Ki values of 450 to 700 microM. Cicletanine also potentiated vasorelaxation by the guanylate cyclase activators sodium nitroprusside and atrial natriuretic peptide in isolated rat aortas. Potentiation was not dependent upon the contractile agonists nor was it indomethacin-sensitive. Neither potentiation nor inhibition of cGMP PDEs was stereoselective. Methylene blue attenuated a component of cicletanine-induced vasorelaxation, but did not completely obviate relaxation. Both cicletanine and the cGMP-PDE inhibitor zaprinast potentiated sodium nitroprusside-mediated cGMP formation and relaxation, although the increase in cGMP content was markedly greater with zaprinast compared to cicletanine. In further studies, cicletanine did not potentiate cGMP activation of cGMP-dependent protein kinase, but did inhibit calmodulin-activated myosin light chain kinase and protein kinase C at relatively high concentrations (approximately 1 mM). In summary, these data demonstrate that cicletanine inhibits vascular cGMP PDEs, potentiates vasorelaxation, and to a limited extent, cGMP formation by guanylate cyclase activators in vascular smooth muscle. However, these relationships for cicletanine are dissimilar from the reference cGMP PDE inhibitor, zaprinast. Thus, other mechanisms may also contribute to the vasorelaxant action of cicletanine.
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PMID:Inhibition of low Km cGMP phosphodiesterases and Ca+(+)-regulated protein kinases and relationship to vasorelaxation by cicletanine. 185 Apr 74

EDRF is a potent, endogenous vasodilator that is produced and released from endothelial cells and subsequently causes the relaxation of VSM through the activation of soluble guanylate cyclase and an increase in VSM cyclic GMP. Structurally, EDRF is likely to be NO or a related nitrogen oxide-containing compound. It is synthesized in endothelial and other cell types from L-arginine by a calcium-calmodulin and NADPH-dependent enzyme. Its action is very similar to the nitrovasodilators that act directly on VSM. EDRF is present in all vascular beds, large and small vessels, and in a wide range of species. Its role in human vascular physiology and pathophysiology is just beginning to be understood. EDRF is a potent endogenous vasodilator and inhibitor of platelet aggregation and adhesion. Its activity is impaired in hypertension and atherosclerosis, and its absence due to endothelial damage may play a role in cerebral and coronary vasospasm. It is a mediator of flow-dependent vasodilation, and its inhibition by hypoxia may contribute to the hypoxic pulmonary vasoconstrictor response. Endothelial cell damage and impairment of EDRF production may also contribute to acute and chronic pulmonary hypertension. A further understanding of the chemical nature and synthetic pathways of EDRF should lead to the production of analogs and antagonists, which may play an important role in future treatments for atherosclerosis, myocardial infarction, angina, hypertension, and other vascular diseases. The recent realization that EDRF serves as the second messenger for guanylate cyclase activation and cyclic GMP production in a variety of cell types outside of the cardiovascular system, including renal and respiratory epithelium, cerebellar neurons, macrophages, and adrenocytes, suggests even broader implications. The importance of EDRF to the anesthesiologist may go beyond an understanding of its role in cardiovascular physiological and pathophysiological states. Initial studies have shown that the endothelium may play a role in mediating the vascular actions of anesthetics, and that anesthetics can inhibit the production, release, or action of EDRF. How are these interactions mediated? Are there significant differences between anesthetics with regard to their effects on EDRF? Is there a clinically significant effect of anesthetics on basal activity of EDRF, or only in response to exogenous stimulation? Conversely, it is important to determine if alterations in endothelial cell function by various disease states such as hypertension, atherosclerosis, adult respiratory distress syndrome, cerebral vasospasm, and others cause changes in the vascular actions of anesthetics. The potential interactions of anesthetics with EDRF production and action in cell types other than the endothelium have not yet been explored.(ABSTRACT TRUNCATED AT 400 WORDS)
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PMID:Endothelium-derived relaxing factor: basic review and clinical implications. 186 89

Tetrahymena calmodulin (CaM) differs from mammalian CaM in its ability to activate Tetrahymena guanylate cyclase. Of 12 differences in amino acid sequence, two occur near the carboxyl terminus (Gln-143----Arg and Thr-146----deletion). To investigate the functional significance of the carboxyl-terminal region in activation of the guanylate cyclase, three mutated CaMs were engineered by using cassette mutagenesis of rat CaM cDNA: Gln-143----Arg (CaM.A), Thr-146----deletion (CaM.D), and Gln-143----Arg/Thr-146 deletion (CaM.AD). Recombinant wild type CaM (wCaM), CaM.A, CaM.D, and CaM.AD were indistinguishable in their ability to activate cyclic AMP phosphodiesterase. The two mutated CaMs (CaM.A and CaM.AD) with the Gln-143 replacement activated guanylate cyclase of Tetrahymena plasma membrane in the presence of Ca2+, with the maximal activation being half of that produced by Tetrahymena CaM. In contrast, neither CaM.D nor wCaM could stimulate the cyclase activity. A CaM antagonist, W-7 (N-(6-aminohexyl)-5-chloro-1-naphthalenesulfonamide), prevented the cyclase activation by either Tetrahymena CaM, CaM.A, or CaM.AD. Thus, we conclude that Arg-143 is in a region of the molecule involved in activation of Tetrahymena guanylate cyclase. The data also suggest that the cyclase activation by Tetrahymena CaM requires complex macromolecular interactions between the entire CaM molecule and the enzyme.
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PMID:Site-directed mutagenesis of glutamine residue of calmodulin. Activation of guanylate cyclase of Tetrahymena plasma membrane. 196 9

In spite of its pivotal role in visual transduction, very little is known about guanylate cyclase of retinal photoreceptor cells. The enzyme has not yet been purified principally because of the difficulty in solubilizing it. We report here a simple method for solubilization of 67% of the cyclase activity from the retinal rod disk membranes (RDM). With Nonidet P-40 as detergent, the solubilization of cyclase is favored by a high concentration of KCl and exclusion of manganese. The solubilized and the residual insoluble enzymes are both highly unstable but could be partially stabilized by dithiothreitol. They were both insensitive to calcium, calmodulin, and atrial natriuretic factor. They also responded similarly to varying the manganese concentration in the assay. For the activity in both fractions, the Km for GTP was about 230 microM, Line-weaver-Burk plots showed that substrate binding was cooperative, and Hill plots suggested that there are two substrate binding sites. Cumulatively, these observations showed that while the entire activity could not be solubilized, the solubilized and the residual insoluble activities probably belonged to the same enzyme. Partial purification resolved the solubilized enzyme into two activities refered to as enzymes 1 and 2. Both had substrate saturation kinetics similar to the solubilized enzyme and were inhibited competitively by inorganic pyrophosphate, one of the products of the cyclase reaction. The Ki for PPi for enzyme 1 was 70-100 microM and 150-200 microM for enzyme 2. cGMP at concentrations up to 800 microM had no influence on the activity of either enzyme.(ABSTRACT TRUNCATED AT 250 WORDS)
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PMID:Guanylate cyclase from bovine rod outer segments: solubilization, partial purification, and regulation by inorganic pyrophosphate. 197 Nov 84

Two subclasses of cyclic guanosine monophosphate (GMP)-specific phosphodiesterases were identified in vascular tissue from several beds. The activity of one subclass (phosphodiesterase IB) was stimulated severalfold by calmodulin and selectively inhibited by the phosphodiesterase inhibitor TCV-3B. The activity of the other subclass (phosphodiesterase IC) was not stimulated by calmodulin and was selectively inhibited by the phosphodiesterase inhibitor M&B 22,948. To assess the involvement of both subclasses in regulating cyclic GMP-dependent responses, the ability of TCV-3B and M&B 22,948 to potentiate the in vitro and in vivo responses to the endogenous guanylate cyclase stimulator atrial natriuretic factor (ANF) was evaluated. Both TCV-3B and M&B 22,948 relaxed isolated rabbit aortic and pulmonary artery rings and also potentiated the relaxant effect of ANF. In addition, both inhibitors produced small increases in urine flow and sodium excretion in anesthetized rats and potentiated the diuretic and natriuretic responses to exogenous ANF. M&B 22,948 (30 micrograms/kg/min) produced a threefold increase in the natriuretic response to simultaneously administered ANF, and TCV-3B (10 micrograms/kg/min) produced a twofold increase in the response to ANF. The results of the present experiments suggest that both the calmodulin-sensitive and calmodulin-insensitive subclasses of cyclic GMP-specific phosphodiesterase play a role in regulating the in vitro and in vivo response to ANF.
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PMID:Subclasses of cyclic GMP-specific phosphodiesterase and their role in regulating the effects of atrial natriuretic factor. 215 39

The roles of Ca2+ and cyclic nucleotides as secondary, intracellular messengers for exflagellation of Plasmodium berghei and Plasmodium falciparum were investigated. Treatment with Ca2+ antagonists such as TMB-8 (an inhibitor of intracellular Ca2+ release) or W-7 (a calmodulin inhibitor) strongly inhibited exflagellation induced by alkaline medium at pH 8.0 whereas EGTA (a Ca2+ chelator) or nicardipine and nifedipine (Ca2+ channel inhibitors) had no effect. These results may indicate that mobilization of parasites' internal resources of Ca2+ is a prerequisite for exflagellation. Agents which increase cAMP levels did not induce exflagellation at the non-permissive pH of 7.3, and had no significant inhibitory effect at the permissive pH of 8.0. IBMX (cAMP/cGMP-phosphodiesterase inhibitor), however, enhanced exflagellation at pH 7.3, indicating the possibility that cGMP, but not cAMP, may be involved in the induction of exflagellation. Furthermore, cGMP or agents which increase cGMP levels such as nitroprusside (a potent activator of guanylate cyclase), enhanced exflagellation at pH 7.3, whereas N-methyl-hydroxylamine (guanylate cyclase inhibitor) inhibited the exflagellation at pH 8.0. From these results, it may be concluded that the induction of exflagellation requires both Ca2+ mobilization and an increase in cGMP levels.
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PMID:Possible roles of Ca2+ and cGMP as mediators of the exflagellation of Plasmodium berghei and Plasmodium falciparum. 217 16


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