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:4.6.1.2 (guanylate cyclase)
8,497 document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)

Saccharomyces cerevisiae was inoculated into a yeast nitrogen base with either glycerol or glucose as carbon source. Cell proliferation was followed by colony counts on agar medium. Cells in the glycerol-supplemented medium divided less than once in 10 days. When glucose, 6-deoxy-glucose or protoporphyrin IX was added, the cells had doubling times of about 24 h and increased in number to about 0.5 x 10(6) cells ml-1. Addition of either of the protein kinase C activators oleoyl-acetyl-glycerol or phorbol-12-myristate-13-acetate did not activate cell proliferation in the glycerol medium. However, when (i) glucose was combined with either protoporphyrin IX or chlorophyllin, or (ii) either protoporphyrin IX or chlorophyllin was combined with either of the protein kinase C activators, the cells had doubling times of about 12 h. Hence, (i) glucose can act as both a carbon source and a signalling molecule for proliferation, and (ii) two systems are involved in activating cell proliferation in S. cerevisiae: one operating through a protein kinase C system and another through a guanylate cyclase system.
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PMID:Effects of glucose, tetrapyrroles and protein kinase C activators on cell proliferation in cultures of Saccharomyces cerevisiae. 759 Jan 58

Progression of diabetic nephropathy is now associated with intrarenal hemodynamic disorders (renal hyperperfusion, hyperfiltration, intraglomerular hypertension). The cause of these disorders is unclear. It is supposed that the relaxation factor which is produced by the vascular endothelium (endothelial relaxation factor-ERF) and an endogenous nitrogen oxide (NO) can cause the above intrarenal hemodynamic alterations in diabetes mellitus. The production of ERF/NO in 35 patients with insulin-dependent diabetes mellitus who had varying severities of diabetic nephropathies were examined. These included the following groups: 1) patients without diabetic nephropathy (n = 9); 2) those with incipient diabetes mellitus (n = 12), 3) those with severe diabetes mellitus (n = 14). From groups 1 and 2, 5 patients with hyperfiltration were identified, their glomerular filtration rate were more than 140 ml/ml. The ability of the cells to produce ERF/NO was indirectly estimated, by determining the levels of human platelet guanylate cyclase in the presence of L-arginine, a NO precursor, the accumulation of cGMP in the cells and plasma. When L-arginine was present, the activity of guanylate cyclase was virtually unchanged in Group 1, but it was substantially increased in Groups 2 and 3, by reaching its peak in patients with hyperfiltration (Group 4). The platelet and plasma levels of cGMP corresponded to the enhancement of guanylate cyclase activity in the presence of L-arginine and increased as diabetic nephropathy progressed. Thus, it is suggested that there is ERF/NO hyperproduction in patients at a high risk for diabetic nephropathy (those having hyperfiltration). ERF/NO is likely to promote the dilation of glomerular arterioles, which results in the development of hyperfiltration and intraglomerular hypertension, causing diabetic nephropathy progression.
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PMID:[Endothelial relaxation factor in the development of diabetic nephropathy]. 762 82

An L-arginine-dependent pathway, metabolising L-arginine to citrulline and nitrogen oxides, has been described in many cell types in different species, including man. Two subtypes of this nitric oxide synthase have been reported: a constitutive enzyme type, releasing nitric oxide after stimulation, is typically found in endothelial and neural cells; another subtype can be induced in macrophages after cytokine treatment. This review summarizes the literature on the known and proposed roles of this L-arginine-dependent nitric oxide production in different pulmonary processes. Nitric oxide has been reported to act as a neurotransmitter in the inhibitory nonadrenergic, noncholinergic nerves in the airways of guinea-pig and man. It is released in cytostatic processes by immune-stimulated alveolar macrophages. Recent data on the role of L-arginine-dependent processes in immune-complex-mediated lung injury, histamine-induced activation of guanylate cyclase or cytokine networks in the lung are also discussed. Finally, similarities and differences between tracheal epithelium-derived relaxing factor and nitric oxide are analysed. The details of the role and distribution of nitric oxide synthase in the (human) lung and airways are not yet completely understood. Nitric oxide is believed to play a role in various pulmonary physiological processes, such as bronchodilation and the cytotoxic action of certain cells. The modulation of nitric oxide release will therefore, most probably lead to application of novel therapies in diseases such as asthma and inflammatory pulmonary diseases.
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PMID:L-arginine-dependent nitric oxide synthase: a new metabolic pathway in the lung and airways. 768 Mar 23

The paper gives data on the role of heme in the functioning soluble forms of guanylate cyclase (of human platelets, rat heart and platelets), on the mechanism of nitrogen oxide-induced heme-dependent activation of enzymes, on the role of platelet guanylate cyclase in the regulation of human platelet aggregation/disaggregation and on the mechanism of antihypertensive and antiaggregatory action of enzyme activators. The instability of relationships of the protein molecule of human platelet guanylate cyclase and heme (regarded as a prosthetic group of the enzyme) results in heme loss during purification of the enzyme and preparation of a heme-deficient agent having a drastically reduced ability to sodium nitroprusside activation. Soluble rat platelet guanylate cyclase was found to be present in these cell originally in a heme-deficient form, it was not activated by sodium nitroprusside and, unlike the routine concepts, heme is not a moiety of this enzyme molecule. The water soluble antioxidant carnosine (beta-alanyl-L-histidine) inhibits sodium nitroprusside activation of guanylate cyclase by interacting with the heme of enzyme of the NO group of nitroprusside and may be useful to reveal the degree of htmt saturation of guanylate cyclase. The study of the mechanism of activation of guanylate cyclase by nitroso complexes of transition metals (Fe, Cr, Co) showed that their realization of antihypertensive effects required only heme-dependent activation of the enzyme. ADF-induced aggregation of human (donor) platelets is followed by stimulation of guanylate cyclase by various activators (despite heme involvement in the mechanism of activation) with concurrent elevations of platelet cGMP levels.(ABSTRACT TRUNCATED AT 250 WORDS)
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PMID:[Soluble forms of guanylate cyclases: mechanism of activation by nitrogen oxide and role in platelet aggregation]. 775 30

All-trans retinoic acid (tretinoin) is a known inducer of differentiation of the human monoblastic cell line, U-937. We now report that the ability of retinoic acid (RA) to induce differentiation of U-937 cells into cells possessing respiratory burst activity is enhanced by the known nitric oxide-donating drugs glyceryl trinitrate, molsidomine and CAS 936, and by tetranitromethane in combination with cysteine. RA alone was a strong inducer of U-937 differentiation as indicated by the following responses to 12-O-tetradecanoylphorbol-13-acetate (TPA) stimulation: (1) increase in the percentage of cells staining with nitroblue tetrazolium (NBT); (2) increase in the total amount of formazan (the product of NBT reduction by O2-.) as determined spectrophotometrically; (3) increase in hexose monophosphate shunt (HMPS) activity as assessed by [14C]CO2 released from D-[1-14C]glucose. RA was also able to increase mRNA levels for two respiratory burst-related genes and for glucose-6-phosphate dehydrogenase (G6PD), an HMPS enzyme. Other indications of differentiation were reduced cell proliferation, increased adherence and altered nuclear morphology. The observed increase in formazan production and HMPS activity and the reduction of cell proliferation due to RA were augmented by co-treatment with either glyceryl trinitrate, molsidomine, CAS 936 or tetranitromethane plus cysteine. Glyceryl trinitrate alone increased HMPS activity and G6PD mRNA levels and also reduced cell proliferation. Glyceryl trinitrate, molsidomine and CAS 936 are presumed to release nitric oxide and increase intracellular cGMP levels by stimulation of soluble guanylate cyclase. The mechanism of action of tetranitromethane is less certain, although it may also generate reactive nitrogen intermediates. These data suggest that a NO./cGMP pathway may augment a retinoic acid-mediated pathway to enhance maturation of U-937 cells with respect to the respiratory burst. Glyceryl trinitrate may act additionally by another pathway.
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PMID:Potentiation of retinoic acid-induced U-937 differentiation into respiratory burst-competent cells by nitric oxide donors. 776 33

Nitric oxide (NO) is important in many physiological, pharmacological, and pathological processes. According to current concepts, guanylyl cyclase is considered to be a receptor for NO in vascular and nonvascular smooth muscle and other tissues. Since there are no suitable radioisotopes of oxygen and nitrogen available for conventional radioligand-receptor binding studies for NO, a novel method was developed to identify NO binding site(s). A chemiluminescence-headspace gas assay was utilized to measure the sequestration of NO in biological systems, and this was used as an index of NO binding. In the present report, myoglobin (a hemoprotein, Mb) was used as a prototype macromolecule to develop the binding assay for subsequent application to studies of putative NO receptors. Solutions containing various concentrations of Mb were incubated with NO in sealed micro-Fernbach flasks at 37 degrees C in an argon atmosphere for 30 min; NO remaining in the headspace gas was analyzed by means of the chemiluminescence assay. The magnitude of NO sequestration was dependent on Mb concentration, and 5 nM Mb was the lowest Mb concentration for which NO sequestration was measurable. Application of the method to the measurement of NO sequestration by bovine serum albumin (BSA) and pulmonary artery medial layer homogenate (BPA-M) revealed that the lowest BSA concentration at which NO sequestration was measurable was 1.6 microM, which was 320 times greater than that for Mb. Applicability of the method to address the question of putative NO receptors was indicated by significant NO sequestration after incubation with 20% (w/v) homogenate of BPA-M, which is responsive to NO and putative NO prodrugs.
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PMID:A novel method for detection of nitric oxide binding sites by using a chemiluminescence-headspace gas technique. 812 3

Hypotension in septic shock is a reflection of unregulated nitric oxide (NO) production and vascular smooth muscle guanylyl cyclase activation. We examined the effect of methylene blue on lipopolysaccharide (LPS)-induced shock in anesthetized rabbits. Shock was induced with 150 micrograms/kg LPS after measurement of mean arterial pressure, platelet cGMP, and total plasma NO (nitrogen monoxide+S-nitrosothiol) content. Measurements were repeated before and after the intravenous administration of 1, 5, and 10 mg/kg methylene blue in response to a 55% reduction in mean arterial pressure. At baseline, mean +/- SEM arterial pressure was 88 +/- 3 mm Hg, which fell to 51 +/- 3 mm Hg after LPS (P < .05). Methylene blue at doses of 1, 5, and 10 mg/kg produced a prompt dose-dependent increase in mean arterial pressure to 69 +/- 2, 77 +/- 3, and 81 +/- 2 mm Hg, respectively (P < .05 versus mean arterial pressure after LPS) in association with normalization of plasma total NO content (P < .05); however, methylene blue did not significantly affect intraplatelet cGMP levels. Thus, methylene blue restores normal arterial pressure in rabbits with septic shock. This effect is associated with persistent elevation of intraplatelet cGMP levels and normalization of total plasma NO content. These data are consistent with methylene blue-mediated inhibition of NO synthase and/or degradation of NO in this model and suggest a novel therapeutic approach to the treatment of septic shock.
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PMID:Methylene blue reverses endotoxin-induced hypotension. 818 78

Nitric oxide (NO) is a small, gaseous, paramagnetic radical with a high affinity for interaction with ferrous hemoproteins such as soluble guanylate cyclase and hemoglobin. Interest in NO measurement increased exponentially with the discovery that NO or a related compound is the endothelium-derived relaxing factor (EDRF). In addition to being a potent endogenous vasodilator, NO has a role in inflammation, thrombosis, immunity, and neurotransmission. Measurement of NO is important as many of its effects (e.g., vasodilatation, inhibition of platelet aggregation) are similar to those of other substances produced by the endothelium, such as prostacyclin. NO is formed in small amounts in vivo and is rapidly destroyed by interaction with oxygen, making measurement difficult. A computerized search of the past five year's literature found NO measurements reported in fewer than 50 of 955 articles dealing with EDRF. Inhibitors of NO synthesis such as the arginine analogs or agents that inactivate NO, such as reduced hemoglobin, are commonly used as specific probes for NO, in vivo and in vitro; however, none of the NO inhibitors is completely specific. The most widely used assays use one of three strategies to detect NO: 1) NO is "trapped" by nitroso compounds, or reduced hemoglobin, forming a stable adduct that is detected by electron paramagnetic resonance (EPR) (detection threshold approximately 1 nmol); 2) NO oxidizes reduced hemoglobin to methemoglobin, which is detected by spectrophotometry (detection threshold approximately 1 nmol); 3) NO interacts with ozone producing light, "chemiluminescence" (detection threshold approximately 20 pmol). These assays can be performed to exclusively detect NO, or by adding acid and reducing agents to the sample, can measure NO and related oxides of nitrogen such as nitrite. Several new amperometric microelectrode assays offer the potential to measure smaller amounts of NO (10(-20) M), permitting NO measurement in intact issues and from single cells. This review describes the pharmacology and toxicology of NO and reviews the major techniques for measuring NO in biological models.
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PMID:Measurement of nitric oxide in biological models. 844 Apr 11

Ten years ago, the term "oxidative stress" (sigma -O2) was created to define oxidative damage inflicted to the organism. This definition brings together processes involving reactive oxygen species production and action such as free radical production during univalent reduction of oxygen within mitochondria, activation of NADPH-dependent oxidase system on the membrane surface of neutrophils, flavoprotein-catalyzed redox cycling of xenobiotics and exposure to chemical and physical agents in the environment. Since the discovery of the nitric oxide biosynthetic pathway, the deleterious effects of uncontrolled nitric oxide generation are generally classified as oxidative stress. Indeed, products of the reaction of NO and superoxide lead to oxidants such as peroxinitrite, nitrogen dioxide and hydroxyl radical, which are involved in mechanisms of cell-mediated immune reactions and defence of the intracellular environment against microbiol invasion. However NO can also regulate many biological reactions and signal transduction pathways that lead to a variety of physiological responses such as blood pressure, neurotransmission, platelet aggregation, endothelin generation or smooth muscle cell proliferation. Then the uncontrolled NO production can lead to a variety of physiological and pathophysiological responses similar to a Nitric Oxide Stress: activation of guanylate cyclase and production of cGMP: overstimulation of the inducible L-arginine to L-citrulline and NO pathway by bactericidal endotoxins and cytokines has been shown to promote undesired increases in vasodilatation, which may account for hypotension in septic shock and cytokine therapy. stimulation of auto-ADP-ribosylation and modification of SH-groups of glyceraldehyde-3-phosphate dehydrogenase in a cGMP-independent mechanism: by this way, NO in excess can strongly inhibits this important glycolytic enzyme and reduce the cellular energy production. inhibition of ribonucleotide reductase: extensive inhibition of this key enzyme in DNA synthesis in the presence of large amounts of NO could lead to important antiproliferative effects; inhibition of cytochrome P450-dependent metabolism: in Kupffer cells and hepatocytes, LPS-induced overproduction of NO has been shown to inhibit cytochrome P450-dependent metabolism and to mediate the suppression of hepatic metabolism. Moreover, NO synthetized in the peripheral nervous system is known to mediate nonadrenergic noncholinergic (NANC) neurotransmission. Overstimulation of NO synthases might therefore contribute to pathophysiological states such as: gastrointestinal motility, reflux oesophagitis, asthma, adult respiratory distress syndrome (ARDS) and chronic pulmonary artery hypertension. To these NO-mediated biological functions, one could add the biological effects of NO-derivatives such as N-nitrosocompounds, which act as carcinogenic agents, or C-nitrosocompound which were recently used as "zinc-ejecting" agents to inhibit HIV-1 infectivity of human T-lymphocytes.(ABSTRACT TRUNCATED AT 400 WORDS)
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PMID:[Does nitric oxide stress exist?]. 852 Oct 87

This discussion of NO chemistry has addressed only certain aspects that may be of biological relevance. It is not meant to be a comprehensive in-depth treatment of general NO chemistry. For more information regarding the chemistry of NO and related nitrogen oxides, the reader is referred to a number of reviews (Ragsdale, 1973; Schwartz and White, 1983; Vosper, 1975; McCleverty, 1979; Gilbert and Thomas, 1972; Bonner and Hughes, 1988). Hopefully, it has become evident that an appreciation and knowledge of the chemistry of NO are key to understanding its physiological utility as well as its toxicology. It appears that Nature exploits a variety of the unique chemical aspects of NO in order to attain the needed physiological specificity. For example, the specific activation of guanylate cyclase by NO is most likely due to its unique binding properties to iron hemes. Also, the inherent lack of reactivity of NO makes it a fairly innocuous species unless it is coupled with other radical species, such as O2-. This chemical property thus allows NO to be utilized as a physiological messenger molecule and, under certain conditions, as a cytotoxic effector molecule as well.
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PMID:Chemistry of nitric oxide: biologically relevant aspects. 856 29


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