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

Circular muscle strips from opossum lower esophageal sphincter were suspended in organ baths for measurement of isometric tension. Nonadrenergic noncholinergic (NANC) inhibitory nerves were stimulated by means of transmural field stimulation. This induced frequency-dependent relaxations of the muscle strips. Methylene blue (3 x 10(-6) M; inhibits guanylate cyclase) and pyrogallol (10(-4) M; generates superoxide anions) had no influence on relaxations, whereas oxyhemoglobin [10(-5) M; binds nitric oxide (NO) and other nitroso compounds extracellularly] inhibited relaxations at all frequencies. NO concentration dependently relaxed the muscle strips. Pyrogallol (10(-4) M) and methylene blue (3 x 10(-6) M) inhibited and oxyhemoglobin (10(-5) M) nearly abolished relaxation induced by NO. S-nitroso-L-cysteine caused concentration-dependent relaxations of the muscle strips, which were inhibited by pyrogallol (10(-4) M), whereas methylene blue (3 x 10(-6) M) augmented the action of S-nitroso-L-cysteine. Methylene blue (3 x 10(-6) M) had no influence on the concentration-dependent relaxations caused by sodium nitroprusside (SNP). Oxyhemoglobin (10(-5) M), and to a lesser extent pyrogallol (10(-4) M), both inhibited the effects of SNP. The action profiles for S-nitroso-L-cysteine, NO, and SNP differed from the action profile for NANC nerve-mediated response. Although pyrogallol inhibited the effects of SNP, the action profile generally resembled the action profile for NANC responses more closely than did the profiles for S-nitroso-L-cysteine or NO. In conclusion, of the nitroso compounds studied, SNP most closely resembled the response to NANC nerve stimulation. Neither NO nor S-nitroso-L-cysteine individually mimicked the NANC response.
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PMID:Action profiles of nitric oxide, S-nitroso-L-cysteine, SNP, and NANC responses in opossum lower esophageal sphincter. 159 Mar 94

Nicorandil increases cyclic 3'5'-guanosine monophosphate (cGMP) in vascular smooth muscle. However, high concentrations are required to activate guanylate cyclase (GC). We examined the relationship between activation of GC, increases in cGMP and relaxation in canine mesenteric artery and vein, renal and coronary artery and thoracic aorta. Nicorandil (10-100 microM) relaxed in each of the blood vessels. Relaxation was associated with elevations of cGMP but independent of release of endothelium-derived relaxing factor, and inhibited by methylene blue and hemoglobin. The organic nitrate esters nitroglycerin, pentaerythritol tetranitrate, isosorbide dinitrate, 2-isosorbide mononitrate, and 5-isosorbide mononitrate each behaved in a similar manner. In each blood vessel pentaerythritol tetranitrate was the most potent and 5-isosorbide mononitrate the least potent relaxant and stimulant of cGMP. Each of the organic nitrate esters (1 microM to 1 mM) except nicorandil stimulated soluble GC activity in the presence of 10 mM cysteine. Nicorandil (EC50 38 mM) increased GC activity. Moreover, nicorandil (0.1 microM to 30 microM) did not inhibit cGMP phosphodiesterase. The EC50 for vascular relaxation was directly correlated with the EC50 for elevation of cGMP for each of the agonists in each blood vessel type. The EC50 for activation of GC was directly related to the reciprocal of the rate constant for nitric oxide formation for each of the organic nitrate esters. However, a direct correlation existed between the EC50 for activation of GC and the EC50 for 1) elevation of cGMP and 2) relaxation, for each of the organic nitrate esters except nicorandil. Thus, the high concentrations of nicorandil required to activate GC cannot account for the low concentrations required to elevate cGMP or relax smooth muscle. We postulate that nicorandil may interact with a membrane receptor or release a second messenger, distinct from nitric oxide or endothelium-derived relaxing factor, which then activates GC. This may represent a physiologic mechanism for regulation of GC activity in smooth muscle.
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PMID:Comparison of nicorandil-induced relaxation, elevations of cyclic guanosine monophosphate and stimulation of guanylate cyclase with organic nitrate esters. 167 47

All nitrovasodilators act intracellularly by a common molecular mechanism. This is characterized by the release of nitric oxide (NO). They are, thus, prodrugs or carriers of the active principle NO, responsible for endothelial controlled vasodilation. The rate of NO-formation strongly correlates with the activation of the soluble guanylate cyclase in vitro, resulting in a stimulation of cGMP synthesis. Nitrovasodilators thus are therapeutic substitutes for endogenous EDRF/NO. The pathways of bioactivation, nevertheless, differ substantially, depending on the individual chemistry of the nitrovasodilator. Besides NO, numerous other reaction products such as nitrite and nitrate anions are formed. The guanylate cyclase is only activated if NO is liberated. In the case of organic nitrates such as GTN, NO is only formed if certain thiol compounds are present as an essential cofactor. The rate of NO-formation correlates with the number of nitrate ester groups and proceeds with a simultaneous nitrite formation (with a ratio of 1:14 in the presence of cysteine). Nitrosamines such as molsidomine do not need thiol compounds for bioactivation. They directly liberate NO from the ring-open A-forms. This process basically depends on the presence of oxygen as electron acceptor from the sydnonimine molecule. Therefore, besides NO also superoxide radicals are formed, which may react with the generated NO under formation of nitrate ions. Organic nitrites (such as amyl nitrite) require the preceding interaction with a mercapto group to form a S-nitrosothiol intermediate, from which finally NO radicals are liberated. Nitrosothiols (like S-nitroso-acetyl-penicillamine) and sodium nitroprusside spontaneously release NO. The molecules themselves do not possess a direct enzyme activating potency. In the presence of thiol compounds organic nitrites (e.g., amyl nitrite) and nitrosothiols may act as intermediary products of NO generation.
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PMID:Molecular mechanisms of nitrovasodilator bioactivation. 168 27

We studied the biological activity, stability and interaction of dinitrosyl-iron(II)-L-cysteine with vascular tissue. Dinitrosyl-iron(II)-L-cysteine was a potent activator of purified soluble guanylyl cyclase (EC50 10 nM with and 100 nM without superoxide dismutase) and relaxed noradrenaline-precontracted segments of endothelium-denuded rabbit femoral artery (EC50 10 nM superoxide dismutase). Pre-incubation (5 min; 310 K) of endothelium-denuded rabbit aortic segments with dinitrosyl-iron(II)-L-cysteine (0.036-3.6 mM) resulted in a concentration-dependent formation of a dinitrosyl-iron(II) complex with protein thiol groups, as detected by ESR spectroscopy. While the complex with proteins was stable for 2 h at 310 K, dinitrosyl-iron(II)-L-cysteine in aqueous solution (36-360 microM) decomposed completely within 15 min, as indicated by disappearance of its isotropic ESR signal at gav = 2.03 (293 K). Aortic segments pre-incubated with dinitrosyl-iron(II)-L-cysteine released a labile vasodilating and guanylyl cyclase activating factor. Perfusion of these segments with N-acetyl-L-cysteine resulted in the generation of a low molecular weight dinitrosyl-iron(II)-dithiolate from the dinitrosyl-iron(II) complex with proteins, as revealed by the shape change of the ESR signal at 293 K. The low molecular weight dinitrosyl-iron(II)-dithiolate accounted for an enhanced guanylyl cyclase activation and vasodilation induced by the aortic effluent. We conclude that nitric oxide (NO) produced by, or acting on vascular cells can be stabilized and stored as a dinitrosyl-iron(II) complex with protein thiols, and can be released from cells in the form of a low molecular weight dinitrosyl-iron(II)-dithiolate by intra- and extracellular thiols.
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PMID:The potent vasodilating and guanylyl cyclase activating dinitrosyl-iron(II) complex is stored in a protein-bound form in vascular tissue and is released by thiols. 168 53

Nitrates are among the most widely prescribed drugs in cardiovascular disease. They are able to prevent and to interrupt episodes of myocardial ischaemia, alleviate anginal symptoms, and exert favourable effects in acute myocardial infarction and in congestive heart failure. Most of these effects can be explained by their ability to relax smooth muscle cells: peripheral vasodilation, in veins and in arteries, reduces cardiac workload, thereby decreasing oxygen consumption; furthermore, nitrates dilate coronary arteries directly, thereby increasing myocardial oxygen supply. However, nitrates also exert effects on blood platelets. These occur by the same mechanisms operating on blood vessels, a stimulation of soluble guanylate cyclase and a consequent increase in cytosolic levels of cyclic GMP. When added to platelet suspensions nitrates inhibit platelet aggregation by almost all known stimuli. Such effects in vitro generally require high concentrations of drugs; evidence has been obtained, however, that nitrates may inhibit platelet function also in vivo. Such evidence derives from ex vivo studies with platelet aggregometry, from experiments showing the synergism of nitrates and prostacyclin and the requirement for nitrate action of sulphydryl group donors such as N-acetyl-cysteine, and from studies on bleeding time. Antiplatelet effects of nitrates may be an explanation for the protection from death and reinfarction, inferred on the basis of meta-analysis of several studies in acute myocardial infarction.
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PMID:[Antiplatelet effects of nitrate derivatives]. 193 57

Nitrovasodilators have been found to relax vascular smooth muscle by stimulating soluble guanylate cyclase and thus by increasing the formation of cyclic GMP (cGMP). This nucleotide is responsible for relaxation, most likely by decreasing cytosolic free Ca2+ by one or several mechanisms. Repeated administration of organic nitrates causes tolerance development characterized by a diminished relaxing effect and an attenuated rise in cGMP. Experiments in isolated circular strips from bovine coronary arteries were performed in order to study the mechanism of tolerance development. It was found that after nitroglycerin (NG) pretreatment the response of the coronary strips to NG was less sensitive with respect to relaxation and increases in cGMP. These strips were also cross-tolerant against isosorbide-5-mononitrate, which by itself caused only little tolerance. With NG, the degree of tolerance development depended on the time and the concentration of NG pre-exposure. NG was found to stimulate guanylate cyclase (GC) in coronary supernatant provided that cysteine was added to the incubation medium. As in the intact strips, activation of GC by NG was attenuated when supernatants were preincubated with NG. It was found that addition of cysteine during incubation lessened the degree of desensitization but did not prevent it completely. Similarly, in coronary strips, tolerance development was lower when N-acetylcysteine was present during pre-exposure of the strips with NG. Considerably more effective in preventing tolerance development by about 50% was L-2-oxothiazolidine-4-carboxylate (OTC), a substance that easily penetrates into the cell and is transformed into cysteine by 5-oxo-prolinase.(ABSTRACT TRUNCATED AT 250 WORDS)
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PMID:Mechanisms of nitrate-induced vasodilatation and tolerance. 197 61

Cultured rat lung fibroblasts were used to explore desensitization of guanylate cyclase to nitrovasodilators. The effect of pretreatment with glyceryl trinitrate (GTN) on the concentration-response curves of GTN and sodium nitroprusside (SNP) for cyclic GMP accumulation in intact cells and activation of guanylate cyclase in broken cell preparations was measured. Pretreatment of cells with 1 microM GTN for 3 h decreased cyclic GMP accumulation induced by GTN but had no effect on SNP-induced cyclic GMP accumulation. Pretreatment of cells with 100 microM GTN decreased the efficacy of GTN and SNP for cyclic GMP elevation by 89% and 40%, respectively. In contrast to results obtained with GTN, SNP slightly desensitized cyclic GMP accumulation induced by GTN and SNP. Pretreatment of cells with 100 nM atrial natriuretic peptide resulted in a 44% decrease in cyclic GMP accumulation induced by subsequent exposure to 10 nM atrial natriuretic peptide but had no effect on cyclic GMP elevation induced by nitrovasodilators. In experiments with crude preparations of soluble guanylate cyclase from cells pretreated with 1 mM GTN, activation of the enzyme by GTN and SNP was inhibited almost completely. Tolerance to GTN in intact cells could not be reversed by subsequent incubation with thiols such as cysteine, N-acetylcysteine or glutathione. However, overnight incubation of GTN-tolerant cells in media without added thiols resulted in complete recovery of responsiveness to GTN. Recovery of GTN-induced cyclic GMP accumulation was inhibited in a concentration-dependent manner by cycloheximide, suggesting that reversal of organic nitrate tolerance requires de novo synthesis of gyanylate cyclase.(ABSTRACT TRUNCATED AT 250 WORDS)
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PMID:Glyceryl trinitrate-induced desensitization of guanylate cyclase in cultured rat lung fibroblasts. 245 70

Using different techniques, we measured the kinetics of nitric oxide (NO) liberation from SIN-1, the metabolite of molsidomine, and some related sydnonimines like its thiomorpholinyl analog, compound C 78-0698, and compared it under identical experimental conditions with its biological action at the guanylate cyclase (GC) site, taking this target enzyme as a suitable bioassay. There was a close relationship between half-maximal activation of GC and the velocity of NO release. The thiomorpholinyl analog was slightly more active in NO liberation than SIN-1 and activated the enzyme more rapidly. The kinetics of SIN-1A and SIN-1C formation, determined by high-performance liquid chromatography, could be accurately described by a Bateman equation. Oxyhemoglobin shifted the concentration-response curve of SIN-1 at the isolated soluble GC concentration to the right, whereas methemoglobin was without any effect. The results of our chemical and biochemical studies suggest that velocity and amount of NO formation are the only rate-limiting factors of guanylate cyclase activation by sydnonimines like SIN-1. NO, therefore, exclusively is the mediator of their pharmacodynamic action. In remarkable contrast to nitrate esters like glyceryl trinitrate or isosorbide dinitrate, NO liberation is not dependent on the interaction with thiol-containing compounds like cysteine.
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PMID:Molecular aspects underlying the vasodilator action of molsidomine. 248 85

The vasodilator and antiaggregatory properties of sydnonimines like SIN-1 are thought to be due to their marked stimulatory action on soluble guanylate cyclase. Enzyme activation and consecutive cyclic GMP accumulation is mediated by the liberation of nitric oxide (NO) from the open-ring A forms of sydnonimines. The purpose of the present study was to investigate the mechanism of NO release from sydnonimines in direct comparison to their stimulatory effect at the target enzyme, soluble guanylate cyclase. All sydnonimines tested were found to spontaneously liberate NO, the rate of which closely correlated with the extent of enzyme activation. NO release occurred nonlinearly with time and became maximal at high sydnonimine concentration. The in vitro stability of the A forms neither correlated with the measured rate of NO release nor with enzyme activation, indicating that a direct stimulation of guanylate cyclase by the A forms is rather unlikely. Besides NO, all sydnonimines generated NO2- and NO3- at a nearly equimolar rate. The addition of cysteine induced a marked shift from NO3- to NO2- with a small reduction in NO release, which is paralleled by a weak rightward shift of the EC50 at the guanylate cyclase. All tested sydnonimines were found to consume molecular oxygen at rates that closely corresponded to the measured rates of NO formation. By a molar comparison, the amounts of consumed oxygen are clearly higher, as would be expected for the oxidative conversion of NO to NO2- and NO3-. Oxygen seems to be additionally involved in the induction of NO formation while being converted to superoxide (O2-). In accordance with an autocatalytic process, O2- further enhances sydnonimine decomposition, since in the presence of superoxide dismutase (SOD) the rate of SIN-1C and NO2-/NO3- formation from SIN-1A was reduced, whereas the rate of NO liberation seemingly increased. O2- has, however, no influence on the rate of hydrolysis of SIN-1 to SIN-1A. At the level of guanylate cyclase, the presence of SOD induced a leftward shift of the concentration-response curve to SIN-1, in agreement with an enhancement of efficacy of NO by blocking the NO-scavenging effect of O2-. An additional O2- generation markedly enhanced SIN-1A decomposition to NO2-/NO3- and reduced the apparent rate of NO formation. We conclude from our results that oxygen plays a key role in the decomposition of sydnonimines and thus in the formation of NO as their pharmacodynamically active principle. Oxygen attack most probably occurs by one-electron abstraction from the A form of the respective sydnonimine compound.(ABSTRACT TRUNCATED AT 400 WORDS)
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PMID:On the mechanism of NO release from sydnonimines. 248 92

The molecular mechanism of tolerance development to nitrovasodilators, most prominent with nitroglycerin, associated with desensitization of guanylate cyclase is still unclear. Nitric oxide (NO) appears to be the common denominator of this group of drugs that leads to guanylate cyclase activation, followed by increases in levels of cyclic GMP and relaxation. It was therefore decided to study whether NO itself, which causes some tolerance, interferes with the actions of (a) SIN-1 and sodium nitroprusside, both of which are thought to act directly by NO formation, which explains why they cause little tolerance; and (b) with the actions of nitroglycerin, which stimulates cyclic GMP formation only in the presence of cysteine and causes pronounced (large) tolerance. Experiments were performed in circular strips of isolated de-endothelialized bovine coronary artery by measuring isotonic changes in length and cyclic GMP determined by radioimmunoassay. When the strips were treated with submaximal effective concentrations of NO, some tolerance was observed, as shown by moderate attenuation of the rises in cyclic GMP, and a rightward shift of the dose-response curve of the relaxing effects by a dose factor of 10 (DF = 10). Exposure to nitroglycerin, SIN-1, or sodium nitroprusside rendered the strips cross-tolerant to NO to a comparable extent as NO itself, suggesting that under these conditions the NO component of all of these drugs that caused similar tolerance is displayed. When the strips were treated with NO and subsequently challenged with nitroglycerin, SIN-1, or sodium nitroprusside, the NO cross-tolerance was uniformly lower than the tolerance to the challenging agent.(ABSTRACT TRUNCATED AT 250 WORDS)
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PMID:Tolerance and cross-tolerance between SIN-1 and nitric oxide in bovine coronary arteries. 248 98


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