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)

The separate fourth intracellular microelectrode was used for controlling the conditions of cyclic nucleotide injection in neurons of Helix pomatia. Ionoforetic increase in intracellular cyclic AMP concentration elicits membrane depolarization in many neurons. Phosphodiesterase inhibitors 3-isobutyl-1-methylxantine and SQ-20009 prolong this depolarization and raise its level. In cell F-1 of helix brain sometimes cAMP induces weak hyperpolarization, but this response turns to usual depolarization after 3-isobutyl-1-methylxantine application. It is suggested that cell molecular computer has an analog input, where diffusion of cAMP, cGMP and Ca++ being a modelling process. Adenylate cyclase and guanylate cyclase and ionic channels of membrane are regulated sources. Phosphodiesterases with Ca2+-binding activator proteins are molecular out flowers and protein kinases--detectors that transform the data about the concentrations of cAMP and cGMP into codes for MCC. Protein kinases control over the activity of proteins directly. The depolarization effect on neuron membrane seems to be associated with protein kinase activation or with direct action of cAMP on phospholipase.
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PMID:[Neuron membrane depolarization under the influence of cyclic-3',5'-adenosine monophosphate and its possible role in the neuronal molecular computer (MC)]. 2 73

The cell membrane of vascular smooth muscle is lined with many receptor sensitive to signals emitted by the vessel wall or transported in the blood stream. Recent data on the mechanisms by which these receptors regulate vascular tone enable them to be classified into two main groups. The first group includes the receptors carried by the membrane proteins which are under their direct control; ATP-P2x receptors on Na+ and Ca2+ channels, pharmacological receptors (dihydropyridines, diltiazem, phenylalkylamines) situated on a voltage operated channel, receptors to cromakaline-like substances associated with a potassium channel, receptors to atriopeptines (ANF-B) with guanylate cyclase activity. The second group of receptors act through the intermediary of the G protein (which has a high affinity for guanylic nucleotides); it regulates the activity of an effector which may be an enzyme or an ionic channel. The receptors of this type which have been identified in vascular smooth muscle are: --positively (beta-adrenergic, DA1-dopaminergic, P1 purinergic or H2-histaminic) or negatively coupled (alpha 2-adrenergic) to adrenylate cyclase; --positively coupled to C phospholipase (angiotensin II, vasopressin V1, 5-H-T2, alpha 1-adrenergic, M1-cholinergic, H1-histaminic). In addition, the same receptor may act by different mechanisms (V1-vasopressin, alpha 2-adrenergic, for example). Whatever the initial mechanism of action, all these receptors influence the contraction by changing ionic permeability or by producing secondary relaxing (cyclic AMP, cyclic GMP) or contractility messengers (inositol phosphates, diacylglycerol).(ABSTRACT TRUNCATED AT 250 WORDS)
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PMID:[Current data of the membrane receptors of the vascular smooth muscle fibers]. 164 53

The present study, addressed to understand the mechanism behind the cholesterol-induced proliferative and collagen secretory activity of smooth muscle cells, revealed that cholesterol-induced smooth muscle cellular DNA synthesis and collagen secretion was mediated through its ability to amplify the intracellular cGMP signal because of the fact that Trifluoperazine (an anticalmodulin and blocker of phospholipase A2) and colchicine (an antitubulin and inhibitor of guanyl cyclase) inhibited DNA synthesis and collagen-secretory activity of smooth muscle cells by their ability to decrease the cGMP levels within smooth muscle cells. From these results we suggest that membrane cholesterol modulated phospholipase 'A2' activity may be the basic mechanism involved in cholesterol-induced proliferative and collagen-secretory activity of smooth muscle cells in vitro.
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PMID:Effect of trifluoperazine and colchicine on smooth muscle cellular proliferative and secretory activity induced by hypercholesterolemic medium in vitro. 216 85

A brief review is given of the vasodilators that require an intact vascular endothelium to exert their relaxing effect. Then some major issues of the phenomenon of endothelium-dependent smooth muscle relaxation are discussed in more detail: The chemical structure of the endothelium-derived relaxing factor (EDRF), which mediates this type of vasodilation, is still unclear. There is agreement that EDRF is chemically unstable, but determinations of its biological half-life have yielded discrepant values (6-50 s). Recent evidence suggests that oxygen and/or activated oxygen species accelerate the evanescence of the factor. The biochemical mechanisms involved in the production of EDRF are still largely unknown. Both stimulators of phospholipase A2 and inhibitors of lysolecithin acyltransferase were found to induce EDRF-mediated relaxation, while several phospholipase inhibitors block these relaxations. These findings suggest that cleavage of phospholipids (and formation of free fatty acids and lysophosphatides) play an important role in EDRF production. EDRF-mediated relaxations are associated with increased levels of cyclic GMP in vascular smooth muscle cells. Endothelial cells were found to produce a factor that directly stimulates the enzymatic activity of soluble guanylate cyclase. This stimulating factor is likely to be identical with EDRF. The significance of the endothelium-dependent relaxing mechanism in resistance vessels is still largely unclear. In the blood-perfused hind limb of the rabbit, two irreversible inhibitors of endothelium-dependent vasodilation (gossypol and p-bromophenacyl-bromide) blocked the vasodilation induced by the endothelium-dependent agent acetylcholine, but not the response to the endothelium-independent vasodilator prostaglandin E1.(ABSTRACT TRUNCATED AT 250 WORDS)
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PMID:Properties and mechanisms of production and action of endothelium-derived relaxing factor. 243 90

1. Depolarization of excitable cells of the central nervous system results in the formation of the second messengers cyclic AMP, cyclic GMP, inositol phosphates, and diacylglycerides. 2. Depolarization-evoked accumulation of cyclic AMP in brain preparations can be accounted for mainly by the release of adenosine, which subsequently interacts with stimulatory adenosine receptor linked to adenylate cyclase. 3. Depolarization-evoked formation of cyclic GMP in brain preparations is linked to activation of voltage-dependent calcium channels, presumably leading to activation of guanylate cyclase by calcium ions. 4. In brain slices depolarization-evoked stimulation of phosphoinositide breakdown and subsequent formation of inositol phosphates and diacylglycerides are linked to activation of voltage-dependent calcium channels, which are sensitive to dihydropyridines, presumably leading to activation of phospholipase(s) C by calcium ions. 5. In the synaptoneurosome preparation depolarization-evoked stimulation of phosphoinositide breakdown does not involve activation of dihydropyridine-sensitive calcium channels and, instead, appears to be regulated primarily by the intracellular concentration of sodium ions. Thus, agents that induce increases in intracellular sodium--such as toxins that open or delay inactivation of voltage-dependent sodium channels; ouabain, an inhibitor of Na+/K+ ATPase that transports sodium outward and a sodium ionophore--all stimulate phosphoinositide breakdown. Mechanistically, increases in intracellular sodium either might directly affect phospholipase(s) C or might lead to influx of calcium ions through Na+/Ca2+ transporters. 6. Depolarization-evoked stimulation of cyclic AMP formation and phosphoinositide breakdown can exhibit potentiative interactions with responses to receptor agonists, thereby providing mechanisms for modulation of receptor responses by neuronal activity. 7. Since all these second messengers can induce phosphorylation of ion channels through the activation of specific kinases, it is proposed that depolarization-evoked formation of second messengers represents a putative feedback mechanism to regulate ion fluxes in excitable cells.
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PMID:Formation of second messengers in response to activation of ion channels in excitable cells. 245 43

It is hoped that his review enables the reader to appreciate the complexities implicit in the interactions among Ca2+, cyclic nucleotides, and phospholipid-metabolizing pathways in cell signal transduction. The interactions are varied and intricate, often involving several levels of cell amplification mechanisms. Upsetting the balance of fatty acids in membrane phospholipids can have detrimental effects on adenylate cyclase. Thus, n - 3 fatty acid enrichment of phospholipids suppresses adenylate cyclase activity. The effects of significant alterations in dietary fatty acids, such as might occur with the current vogue for n - 3 eicosapentaenoic acid and docosahexaenoic acid (fish oil) dietary enrichment regimens, will need to be assessed more fully with regard to stimulus-induced changes in cyclic nucleotide production in various tissues. Since the n - 3 fatty acids have not been demonstrated to affect guanylate cyclase activity, dietary changes in certain of these fatty acids would not be expected to contribute to changes in cGMP generation as much as in cAMP production. Moreover, the ingestion of large quantities of these n - 3 fatty acids can alter the profile of cyclooxygenase and lipoxygenase products produced in cells. According to the paradigm developed in this article, changes in the metabolism of fatty acids are amplified by alterations in cyclic nucleotide production and phospholipase activities, with the eventual physiological impact predicated on the tissue type and the specific stimulus response. There appears to be a rather clear distinction between the regulatory properties of eicosanoids regarding adenylate and guanylate cyclase activities. Whereas prostaglandins often stimulate adenylate cyclase activity, they have little effect on guanylate cyclase activity. On the other hand, the HETE compounds seem to play an important role in guanylate cyclase regulation in certain cells. Moreover, arachidonic acid affects adenylate cyclase activity without prior peroxidation, whereas endoperoxides and hydroperoxides are more effective than arachidonic acid with regard to guanylate cyclase stimulation. However, in the intact cell there is a strong implication that the dual stimulation of guanylate cyclase by Ca2+ and fatty acid evokes optimal enzyme activity. An advantage of multidimensional response mechanisms in cells includes the ability to recognize different stimuli and to respond with specific, coordinated responses modulated in their intensity and/or duration by messenger interaction. Few cell types respond to receptor stimulation in an all-or-none fashion, and the "milieu interior" depends on specific, graded responses to the autonomic nervous system and endocrine stimuli.(ABSTRACT TRUNCATED AT 400 WORDS)
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PMID:Coordinate interactions of cyclic nucleotide and phospholipid metabolizing pathways in calcium-dependent cellular processes. 255 30

Various pure snake venom phospholipases A2 were used for studying their effect on guanylate cyclase activity. All the phospholipases A2 tested were found to activate guanylate cyclase from a rat brain homogenate. It was shown that particulate guanylate cyclase was especially affected. Intact glial cells incubated in presence of phospholipase A2 showed also an increased guanylate cyclase activity, demonstrating that the phospholipase effect, observed in disrupted cells, occurs also at the cellular level. These results suggest that in intact cells membrane-bound phospholipase A2 activity could be involved in the modulation of the cellular cyclic GMP content.
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PMID:Activation of brain guanylate cyclase by phospholipase A2. 612 Feb 16

Enterotoxigenic Escherichia coli may produce a heat-stable enterotoxin (ST) that causes diarrheal disease in humans and in animals ST activates particulate guanylate cyclase in intestinal mucosal cells and causes intestinal fluid secretion. In this study, we examined the effects of quinacrine on ST activation of guanylate cyclase and ST-mediated intestinal fluid secretion. Quinacrine significantly reduced ST activation of particulate guanylate cyclase in rat intestinal tissue. Additionally, quinacrine reduced ST-mediated fluid secretion in a rat intestinal loop assay (P less than 0.05). In the suckling mouse model, subcutaneous quinacrine (0.1 mumole/mouse) reduced ST-induced fluid secretion at a submaximally effective dose of the toxin, but it did not reduce ST-mediated fluid secretion at a near maximally effective dose. Quinacrine (0.1 mumole/mouse) did not significantly reduce intestinal fluid secretion induced by the analog of cyclic GMP, 8-bromo cyclic GMP. However, at a higher concentration of quinacrine (1 mumole/mouse), significant inhibition of 8-bromo cyclic GMP-induced secretion was observed. Inhibition by the antimalarial agent quinacrine of ST-induced fluid secretion, by a block prior to guanylate cyclase activation, suggests a possible role for a phospholipase early in the sequence of events of ST activation of guanylate cyclase. The results suggest that ST may activate membrane phospholipases prior to ST activation of guanylate cyclase.
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PMID:Inhibition of Escherichia coli heat-stable enterotoxin effects on intestinal guanylate cyclase and fluid secretion by quinacrine. 612 94

Recent studies have implicated protein kinase-C (PKC) in the regulation of guanylate cyclase in several cell types. In view of prior experiments by our laboratory which have demonstrated that 1 alpha,25-dihydroxyvitamin D3 [1 alpha,25-(OH)2D3] can activate PKC in CaCo-2 cells, it was of interest to determine whether this secosteroid influenced particulate guanylate cyclase and, if so, to determine which isoforms of PKC were involved. To address these issues, CaCo-2 cells were treated with 1 alpha,25-(OH)2D3 or other agents (see below), and crude membranes prepared from these cells were assayed for guanylate cyclase activity. In several experiments, agents were added directly to isolated membranes, and guanylate cyclase activity was then assayed. These studies demonstrated that 1) the addition of 1 alpha,25-(OH)2D3 or 12-O-tetradecanoyl phorbol 13-acetate (TPA), a known activator of PKC, to intact CaCo-2 cells stimulated particulate guanylate cyclase activity in a time- and concentration-dependent manner; 2) these agents induced the translocation of PKC alpha, but not PKC zeta, from the cytosolic to the membrane fraction of these cells; 3) preincubation of cells with staurosporine (50 nM), a PKC inhibitor, or U73122 (10 microM), an inhibitor of phospholipase-C-dependent processes, significantly reduced (P < 0.05) the stimulatory effect of 1 alpha,25-(OH)2D3 (3 nM) on guanylate cyclase; 4) preincubation of isolated membranes with TPA, calcium, and Mg(2+)-ATP increased guanylate cyclase activity, an affect that was augmented by purified rat brain PKC and inhibited by the PKC inhibitor peptide, PKC-(19-36); and 5) selective down-regulation of PKC alpha by treatment of cells with TPA (200 nM) for 24 h concomitantly abolished the activation of guanylate cyclase by 1 alpha,25-(OH)2D3. Taken together, these studies demonstrate that 1 alpha,25-(OH)2D3 activates particulate guanylate cyclase at least in part via a PKC alpha-dependent mechanism.
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PMID:The role of protein kinase-C alpha in the activation of particulate guanylate cyclase by 1 alpha,25-dihydroxyvitamin D3 in CaCo-2 cells. 791 83

Adrenergic stimulation of the adult pineal gland increases cAMP and cGMP production by over 100-fold. beta-Adrenergic stimulation results in Gs alpha-mediated cyclase activation; alpha 1-adrenergic activation potentiates the beta-adrenergic effects through mechanisms mediated by the intracellular Ca2+ concentration ([Ca2+]i) and Ca(2+)-phospholipid-dependent protein kinase. Development analysis of these responses has indicated that the adrenergic stimulation of cAMP is present several days after birth, but the cGMP response develops only after the second week of life. In the study presented here, the adrenergic-->cGMP response was analyzed in pineal glands from 10- and 25-day-old rats, with the intention of determining the basis of the developmental appearance of this response. Organ culture and tissue homogenate studies indicated that guanylate cyclase activity, cGMP phosphodiesterase activity, and adrenergic elevation of phospholipase-A2 were similar in pineal glands from 10- and 25-day-old rats. Norepinephrine stimulated an increase in [Ca2+]i in dispersed pinealocytes from 10-day-old rats, as has been previously demonstrated in adult pinealocytes. In contrast, several treatments that elevate [Ca2+]i had no effect on cGMP accumulation in forskolin-treated or beta-adrenergically activated glands from 10-day-old rats, but were fully effective in similarly treated glands from 25-day-old rats. However, glands from 10-day-old animals showed a 33-fold accumulation of cGMP when they were cultured together with glands from 25-day-old rats. These studies indicate that whereas many elements in the system that mediate adrenergic regulation of pineal cGMP are fully developed at 10 days of age, the developmental appearance of the cGMP response is triggered by the development of a process down-stream of the alpha 1-adrenergic stimulation of [Ca2+]i, and this process may involve a diffusible factor.
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PMID:Developmental appearance of pineal adrenergic-->guanosine 3',5'-monophosphate response is determined by a process down-stream from elevation of intracellular Ca2+: possible involvement of a diffusible factor. 809 11


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