EC:4.6.1.2 - FACTA Search

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)

Nitrovasodilators relax vascular smooth muscle by one common mechanism, the activation of soluble guanylate cyclase leading to increased formation of cGMP. The considerable differences in potency between various nitrovasodilators appear, at least in part, to be due to the different pathways of their transformation into activators of guanylate cyclase such as nitrous oxide or nitrosothiol. Major differences were also found in the ability of these compounds to induce tolerance in isolated bovine coronary artery strips. Although the mechanism of tolerance development is still not clarified, it appears likely that cysteine deficiency may be responsible for this phenomenon since this thiol appears to be required for the transformation of certain nitrovasodilators (e.g. nitroglycerin) into stimulators of guanylate cyclase and also in the final step of activation of this enzyme.
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PMID:Mode of action of nitrates with regard to vasodilatation and tolerance. 287 92

Nitrovasodilators relax vascular smooth muscle by stimulating soluble guanylate cyclase (GC). The resulting rise in cGMP probably initiates Ca extrusion from the smooth muscle cell which causes relaxation. Since repeated administration of organic nitrates, particularly nitroglycerin, leads to tolerance, i.e. a decrease in the vasodilator effect, it was studied whether (a) tolerance was a peripheral phenomenon occurring in the vascular smooth muscle, and (b) was due to an impairment of GC activation. In isolated circular strips of bovine coronary arteries, 90 min pretreatment with nitroglycerin greatly lowered the relaxing as well as the cGMP increasing response to nitroglycerin, indicating tolerance induction. Tolerance, although to a lesser extent, was also obtained with other organic nitrates under similar conditions, including IS 5-MN. Little (nitroprusside Na) to negligible tolerance was obtained with sodium nitrate and SIN-1, the active metabolite of molsidomine. The latter group of drugs stimulated soluble GC in vitro in the absence of cysteine whereas organic nitrates required the presence of this thiol. Preincubation with nitroglycerin almost completely inactivated GC whereas other organic nitrates had little effect. The results indicate that tolerance is caused by an impairment of GC function in the smooth muscle cell, particularly when elicited by nitroglycerin, and that differences in the degree of tolerance development by various nitrovasodilators are possibly due to different mechanisms of activation and inactivation of GC as well as differences in cysteine requirement.
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PMID:Mechanism of vasodilation by nitrates: role of cyclic GMP. 288 20

Organic nitrates develop their vasodilating potency by stimulating the enzyme guanylate cyclase. There are still several theories concerning the molecular mechanism of enzyme activation, the most likely of which sees nitric oxide (NO.) as the true modulator of the soluble guanylate cyclase. We therefore examined the release of nitric oxide from organic nitrates by means of a difference-spectrophotometric method and found that our results correlated well with the extent of enzyme activation. The more NO. was liberated from the compounds in question, the higher was the enzyme activation observed. When the examined nitrates were used in a concentration which caused a half-maximal enzyme stimulation, the result was a NO. liberation of striking uniformity. This correlation also applied to SIN-1 for which it has been assumed up to now that the intact molecule itself is able to stimulate the enzyme and not the nitric oxide released from it. We found the reaction between organic nitrates and cysteine to be highly dependent on temperature, while the extent of the observed enhancement increased with the number of nitrate groups per molecule. We also studied the potential effects of certain compounds on non-enzymatic NO. release and found that, in addition to methylene blue, thionine and brilliantcresyl blue, but not ferricyanide, were also effective inhibitors. So it seems likely that both an enzymatic and a non-enzymatic mode of inhibition of enzyme activity does exist. Since oxyhemoglobin is an effective scavenger of nitric oxide, its addition can inhibit enzyme activation by nitrovasodilators. Our results stress the important role of the non-enzymatic liberation of NO. from organic nitrates and related compounds as possible, perhaps even as the principal mode of activation of soluble guanylate cyclase by nitrovasodilators.
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PMID:Correlation between nitric oxide formation during degradation of organic nitrates and activation of guanylate cyclase. 288 63

Atrial natriuretic peptide (ANP) contains a disulfide which is generally considered to be required for biological activity. A truncated linear ANP analog, des-Cys105,Cys121-ANP-(104-126) (referred to as analog I), that lacks the 2 cysteine residues of the parent peptide was synthesized. In competition binding studies using rabbit lung membranes, ANP-(103-126) and analog I displaced bound 125I-ANP-(103-126) from specific ANP binding sites 100 and 73%, respectively. The concentrations of ANP-(103-126) and analog I that produced 50% inhibition of radioligand binding to the membranes were 0.26 +/- 0.07 and 0.31 +/- 0.09 nM, respectively. Radioiodinated ANP-(103-126) and analog I were chemically cross-linked to binding sites on rabbit lung membranes, and the labeled membrane proteins were analyzed by sodium dodecyl sulfate-polyacrylamide gel electrophoresis and autoradiography. 125I-Analog I specifically labeled a 65,000-dalton protein and a 135,000-dalton protein which, under reducing conditions, dissociated into 65,000-dalton subunits. In contrast, 125I-ANP-(103-126) labeled specifically a nonreducible 135,000-dalton protein, in addition to the 65,000-dalton species and the reducible 135,000-dalton species. ANP-(103-126) (100 nM) stimulated rabbit lung particulate guanylate cyclase activity, whereas analog I, at the same concentration, had no effect on cyclic GMP production and did not antagonize the effect of ANP-(103-126). From these observations, we conclude that analog I is a selective ligand which binds to approximately 73% of the total ANP binding sites present in rabbit lung membranes. Unlike ANP-(103-126), analog I does not bind to the remaining 27% of the binding sites and does not activate guanylate cyclase. Binding to the cyclase-linked ANP receptor correlates with the specific labeling by 125I-ANP-(103-126) of the nonreducible 135,000-dalton membrane protein.
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PMID:A linear analog of atrial natriuretic peptide (ANP) discriminates guanylate cyclase-coupled ANP receptors from non-coupled receptors. 289 82

We continuously studied the quantitative formation of nitric oxide (NO), nitrite and nitrate ions from several organic nitrate esters in the presence of various thiol-containing compounds by spectroscopy and HPLC. The results indicate that there are different pathways of decomposition depending on the chemical nature of the mercaptan tested. The amino acid cysteine is known to function as an essential cofactor for guanylate cyclase activation by organic nitrates in vitro. For comparison we investigated several structural analogues with respect to their nitric oxide or nitrite ion releasing potency. Both were found to represent the main products resulting from nitrate ester breakdown besides the respective alcohols. We found that only those compounds were able to activate the enzyme in the presence of nitroglycerin (GTN) which induce the release of NO as well. On the other hand, nearly all other thiols tested caused an in vitro decomposition of organic nitrates by producing excess nitrite and the corresponding disulfide without the formation of NO. Thus, the decomposition of organic nitrates to nitrite ions does not contribute at all to activation of guanylate cyclase. Our results confirm that the liberation of nitric oxide is the common principle of action for all nitrovasodilators. In addition, our results suggest that the thiol consuming transformation of organic nitrates into nitrite ions (ratio NO/nitrite 1:10) may lead to a depletion of cysteine stores, resulting in a decreased formation of NO and, consequently, in a decrease of guanylate cyclase activation, clinically arising as nitrate tolerance.
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PMID:Explanation of the discrepancy between the degree of organic nitrate decomposition, nitrite formation and guanylate cyclase stimulation. 290 Jul 66

We have directly compared the effects of the nitrates isosorbide-5-mononitrate, nitroglycerin and isosorbide dinitrate and of the nitric oxide-containing sodium nitroprusside and 3-morpholino-sydnonimine (SIN 1) as well as of the bioinactive precursor of SIN 1, molsidomine, on platelet activating factor-induced platelet aggregation and activation of soluble guanylate cyclase. The effects of these agents on the aggregation and on soluble guanylate cyclase activity of human platelets were closely correlated. Whereas nitroprusside and SIN 1 were very potent inhibitors of aggregation and activators of soluble guanylate cyclase in micromolar concentrations, the other drugs were effective only at millimolar concentrations. Preincubation of platelets with cysteine did not or only slightly increase the ability of isosorbide-5'-mononitrate and isosorbide dinitrate to inhibit aggregation, but a clear increase was observed after preincubation with nitroglycerin. These data support the concept that cyclic GMP is the mediator of nitric oxide-induced inhibition of platelet aggregation and indicate that nitrates cannot directly inhibit aggregation or be converted to nitric oxide-containing agents by a specific mechanism in platelets. The data also suggest that SIN 1 and nitroprusside, but not or only to a certain degree the nitrates, can be considered as exogenous endothelium-derived relaxing factors.
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PMID:Direct comparison of the effects of nitroprusside, SIN 1, and various nitrates on platelet aggregation and soluble guanylate cyclase activity. 290 6

Nitrovasodilators relax vascular smooth muscle by stimulating guanylate cyclase. Ignarro et al. (1981) proposed a mechanistic scheme according to which organic nitrates release nitrite in the presence of thiols. The corresponding nitrous acid would decay leading to nitric oxide, which then would react with another thiol to nitrosothiol. Dose-response relations with regard to guanylate cyclase stimulation of organic nitrates and sodium nitrite were compared in the presence of cysteine and its closely related methylester. Nitrite formation from ED95 concentrations of organic nitrates was also measured and compared with that present under an equi-effective concentration of sodium nitrite. In addition, the proposed formation of nitrosothiol from nitric oxide was re-examined. In the presence of cysteine, organic nitrates as well as sodium nitrite stimulated guanylate cyclase, but nitrite formation under ED95 concentrations of organic nitrates was 1000-fold smaller than that present under an equi-effective concentration of sodium nitrite. In the presence of cysteinemethylester, liberation of nitrite from organic nitrates was similar but no stimulation of guanylate cyclase was obtained. Sodium nitrite, however, showed a stimulating activity similar to that in the presence of cysteine. These results clearly demonstrate that guanylate cyclase stimulation by organic nitrates is not mediated by nitrite and subsequent formation of nitrosothiol. Since nitrous acid did not decay to nitric oxide in the pH range studied, the formation of nitrosothiol is apparently due to a direct reaction of nitrous acid with thiol.
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PMID:Guanylate cyclase activation by organic nitrates is not mediated via nitrite. 290 90

Molsidomine is enzymatically metabolized in the liver to SIN-1 and readily converted into the active metabolite SIN-1A, which carries a free nitroso group. Evidence obtained in isolated circular strips from bovine coronary arteries indicates that SIN-1 increases cyclic guanosine monophosphate in close association with its relaxant effects in coronary strips under various pharmacologic conditions, suggesting that cyclic guanosine monophosphate mediates relaxation. Various nitrovasodilators act by the same mechanism, which is stimulation of guanylate cyclase. In this study the effect of nitroglycerin depended on the presence of a special thiol, cysteine, whereas SIN-1 was active also in the absence of cysteine. Cysteine deficiency was found to be associated with tolerance. After prolonged exposure to the drug, tolerance toward nitroglycerin developed in coronary strips that was antagonized by cysteine. SIN-1 produced no significant tolerance and was also fully active in nitroglycerin-tolerant strips. We conclude that SIN-1 relaxes vascular smooth muscle by direct stimulation of guanylate cyclase, whereas nitroglycerin probably must be converted into a cyclase stimulator by a cysteine-dependent reaction.
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PMID:Mechanism of vasodilation by molsidomine. 298 23

The present study investigated possible involvement of cysteine (CSH) and reduced glutathione (GSH) as critical cellular sulfhydryls which mediate nitroglycerin (GTN)-induced cyclic GMP accumulation and relaxation in bovine coronary artery (BCA). Tolerance to the relaxant effects of GTN was induced in BCA in vitro by preincubation with 1 mM GTN for 2 h. GTN-tolerant BCA were at least 100-fold less sensitive than non-tolerant BCA to the relaxant effects of GTN. Consistent with a relationship between tolerance to both GTN-induced cyclic GMP accumulation and relaxation, cyclic GMP accumulation induced by 1 microM GTN was markedly reduced in GTN-tolerant BCA when compared with non-tolerant BCA. Incubation with 1 mM CSH for 1 h did not significantly alter GTN-induced cyclic GMP accumulation or relaxation in either GTN-tolerant or non-tolerant BCA. Levels of CSH, GSH and glutathione-disulfide (GSSG) were measured in non-tolerant BCA, GTN-tolerant BCA and GTN-tolerant BCA incubated with 1 mM CSH for 1 h. Levels of CSH and GSH were lower in GTN-tolerant BCA than in non-tolerant BCA, whereas GSSG levels were similar in both. In GTN-tolerant BCA incubated with 1 mM CSH, CSH levels were more than 10-fold above, and GSH levels were similar to corresponding values obtained in non-tolerant BCA. These data indicate that although incubation with CSH did not significantly reverse tolerance to GTN-induced cyclic GMP accumulation and relaxation in BCA, it did effectively raise the level of CSH and GSH in GTN-tolerant BCA, at least to corresponding levels found in non-tolerant BCA. These results indicate that the relaxant effects of GTN in BCA do not correlate with tissue levels of CSH and GSH. The findings do not support the hypothesis that CSH and GSH are the cellular sulfhydryls involved in mediating GTN-induced guanylate cyclase activation, cyclic GMP accumulation and relaxation in intact BCA.
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PMID:Dissociation of cysteine and glutathione levels from nitroglycerin-induced relaxation. 299 Sep 47

The dinitrosyl iron complexes (DNIC) with thiosulphate, cysteine or phosphate were shown to inhibit in vitro (in citrate plasma) the human platelet aggregation induced by ADP, collagen or adrenaline. This effect cannot be explained by the toxic action of DNIC on the platelet membrane, since DNIC-pretreated platelets are capable of aggregating under the action of 10(-8) M/ml of phorbol ester, which is known to cause direct activation of protein kinase C. The antiaggregatory activity of DNIC exceeds that of Na-nitroprusside and seems to be due to nitric oxide capable to activate guanylate cyclase of platelets. Using the EPR method, it was shown that addition of DNIC to platelet-enriched plasma results in a rapid transfer of Fe(NO)2 groups to the coupled RS(-)-groups proteins of plasma and, apparently, of platelet membrane proteins. These protein DNIC seem to be the source of NO which inhibits human platelet aggregation.
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PMID:[Inhibition of platelet aggregation by dinitrosyl iron complexes with low molecular weight ligands]. 302

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