EC:4.6.1.1 - FACTA Search

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Query: EC:4.6.1.1 (adenylate cyclase)
19,190 document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)

Thyroid hormone formation requires the coincident presence of peroxidase, H2O2, iodide, and acceptor protein at one anatomic locus in the cell. The peroxidase enzyme appears to be a protoporphyrin lX containing heme protein, with binding sites for both iodide and tyrosine. It is probable that both iodide and tyrosine are oxidized to free radical forms which unite to form iodotyrosine. The peroxidase is also involved through an uncertain mechanism in iodotyrosine coupling and probably in oxidation of sulfhydryl bonds in thyroglobulin. H2O2 may be supplied by microsomal NADPH-cytochrome c reductase or NADH-cytochrome b5 reductase. Other possible intracellular H2OI generating systems include monoamine oxidase and xanthine oxidase. The usual acceptor for iodide is thyroglobulin, which is currently believed to be iodinated within apical secretory vesicles at the cell border just prior to liberation into the colloid, or possibly after liberation into the colloid. Other soluble an insoluble proteins are also iodinated within the gland. The peroxidase is present in numerous cellular structures, but iodination activity occurs primarily, if not only, at the apical cell border. The controls of iodination are imperfectly known. Thyrotrophin modulation of iodide uptake, H2O2 generation, thyroglobulin synthesis, and peroxidase enzyme level obviously are the main regulations. Many of these actions are thought to involve mediation of adenyl cyclase and subsequent activation of intracellular phosphokinases. Antithyroid drugs of the thiocarbamide group are competitive inhibitors of iodination under some circumstances, but if much iodide is present, they react with the oxidized iodine intermediate and are irreversibly inactivated themselves. Clinical problems involving defective peroxidase function are among the most frequent hereditary defects of thyroid hormone formation. Recognized abnormalities include deficient peroxidase, abnormality in binding of the peroxidase apoprotein to its prosthetic group, and other less well-identified abnormalities in peroxidase structure and function. Peroxidase is typically elevated in thyroid tissue from patients with hyperthyroidism sometimes deficient in cold thyroid nodules, and frequently diminished in tissue from patients with Hashimoto's thyroiditis.
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PMID:Biosynthesis of thyroid hormone: basic and clinical aspects. 6 47

As it was shown previoulsy by others, the membrane-bound phosphodiesterase (cyclic adenosine 3':5'-monophosphate phosphodiesterase) of rat epididymal fat cells was stimulated when intact cells were exposed to insulin. The levels of stimulation observed in the present study in the cell homogenate and microsomal fraction were approximately 2.0- to 2.5-fold and 2.5- to 3.0-fold, respectively, when the initial substrate level was 100 nM and insulin concentration was 1 to 3 nM. When the microsomal fraction was subjected to a sucrose density gradient centrifugation, most of the insulin-sensitive phosphodiesterase activity was fractionated into the "light" microsomal fraction which was rich in NADH2:potassium ferricyanide:oxidoreductase) and low in 5'-AMPase, adenylate cyclase, and insulin-binding activities. The latter three activities were mostly fractionated into the "heavy" microsomal fraction. Both basal and insulin-stimulated phosphodiesterase activities were low when cells were homogenized in the presence of N-ethylmaleimide or p-chloromercuribenzoate. The insulin-stimulated enzyme activity was also low when cells were homogenized in the presence of --SH compounds (e.g. dithiothreitol) or certain metal-chelating agents (e.g. ethylene glycol bis(beta-aminoethyl ehter)-N,N'-tetraacetate (EGTA)), or in a nitrogen atmosphere. The effect of EGTA was prevented by the addition of certain heavy metal ions but not by the addition of Ca2+ or Ca2+ plus Mg2+ ions. When cells were homogenized in the presence of certain oxidants (e.g. diamide, sodium tetrathionate, or air), a high plus-insulin activity was observed; this activity was not lowered by subsequent treatment of the enzyme with N-ethylmaleimede, EGTA, or fresh cell homogenate that was prepared in the presence of EGTA. However, the activity of an apparently oxidized enzyme could still be lowered by treatment woth dithiothreitol. A partially purified enzyme in the enzyme in the microsomal fraction was fairly stable both in basal and insulin-stimulated states (fully active after 35 days when kept at -20degrees). EGTA added to the homogenization buffer lowered the basal phosphodiesterase activity, but this effect was reversed by the addition of Ca2+ ions. EGTA also decreased the enzyme activity that was stimulated by norepinephrine. However, neither EGTA nor dithiothreitol had any effect on the activities of 5'-AMPase, NADH-dehydrogenase, and malate dehydrogenase of fat cells. The above data indicate that most of the insulin-sensitive phosphodiesterase and the so-called "cell membrane markers" are associated with different subcellular particles in the cell homogenate. In addition, the data seem to indicate that the insulin-stimulated phosphodiesterase has certain --SH groups and that the activity of the enzyme is stabilized when the --SH groups are oxidized by certain oxidants including molecular oxygen. It is suggested that the air oxidation of the enzyme is catalyzed by a trace of certain heavy metal ions and, therefore, can be blocked by a metal-chelating agent.
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PMID:Insulin-sensitive phosphodiesterase. Its localization, hormonal stimulation, and oxidative stabilization. 17 Feb 71

The effects of glucose, a series of glucose metabolites, nicotinamide nucleotides, Ca2+ and p-chloromercuribenzenesulphonate on adenylate cyclase activity in homogenates of mouse pancreatic islets were studied. The basal activity of the adenylate cyclase was approx. 6 pmol of cyclic AMP formed/30 min per microng of DNA at 30 degrees C. The enzyme activity was stimulated by some 150% by fluoride. Starvation of the animals for 48h had no effect on either the basal or the fluoride-stimulated activity. The adenylate cyclase activity was increased by 40-50% when 17 mM-glucose, 10 micronM-phosphoenolpyruvate or 10 micronM-pyruvate was added to the assay medium. The effect of glucose was unchanged in the presence of 17 mM-mannoheptulose, and mannoheptulose alone had no effect. The other glycolytic intermediates, and the coenzymes NAD+, NADH and NADPH, at concentrations up to 1 mM were without any detectable effect on the rate of formation of cyclic AMP. The insulin secretagogue p-chloromercuribenzenesulphonate inhibited the adenylate cyclase markedly even at a concentration of 10 micronM. Calculated concentrations of free Ca2+ of 10 micronM and 0.1 mM inhibited adenylate cyclase by 29 and 71% respectively. It is concluded that both glucose itself and phosphoenolpyruvate and/or pyruvate are true activating ligands for islet and adenylate cyclase and that inhibition of the cyclase by Ca2+ may be of physiological significance.
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PMID:Effects of glucose, glucose metabolites and calcium ions on adenylate cyclase activity in homogenates of mouse pancreatic islets. 19 80

From a homogenate of rabbit colon muscle subcellular fractions were isolated by differential centrifugation. The crude microsomal fraction could be separated into subfractions, a fraction of vesicular microsomes at 35% sucrose, a fraction containing sarcolemma, mitochondrial fragments and microsomal vesicles at 35--45% sucrose and a small protein fraction at 45--55% sucrose. Their biochemical properties and their morphological characterization were investigated. The cholesterol and the phospholipid content was equally distributed between the microsomal fractions 35% and 35--45% while the RNA was localized to the mitochondria and the microsomal fraction 35%. The enzyme cytochrome c oxidase was found to be concentrated in the mitochondria while a high contamination was found in the microsomal fractions 35--45%. The NADH-oxidase activity was highest in the 35% fraction and the 5'-nucleotidase activity in the 40,000 X g supernatant. The microsomal subfractions contained the enzymes ATPase, adenylate cyclase and phosphodiesterase. In the 35% fraction Ca stimulated the hydrolysis of ATP. The binding of [3H]-ouabain and the incorporation of [3H]-leucine was most pronounced in the 35% fraction. In a K+-free Krebs Ringer medium the binding of the glucoside was stimulated in all the fractions. From these results we concluded that the fraction 35% sucrose may be mainly derived from the endoplasmic reticulum and the plasma membrane while the 35--45% originates from the plasma membrane, mitochondria and to a lesser extent the endoplasmic reticulum.
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PMID:Biochemical and morphological characterization of subcellular fractions isolated from rabbit colon muscle. 20 90

There is a positive correlation between lactate output and insulin secretion but there is no correlation between total islet PEP content and insulin secretion and no correlation between cAMP production and insulin release. Neither PEP or cAMP seem to be primary triggers to insulin release but may rather act as positive modulators of insulin secretion. Potentially, PEP can maintain an elevated cytoplasmic Ca++ concentration by inhibiting Ca++ uptake in the mitochondria, increase the concentration of cAMP in the beta-cells by activating the adenylate cyclase (11) and change the phosphorylation state of the plasma membrane (12). The possible trigger effect of an increased glycolytic flux on insulin secretion may be mediated perhaps via changes in the NADH/NAD+ ratio (13). As regards the mechanism of potentiation of insulin release: in the fed state potentiation may be related to an increased glycolytic flux whereas this is not the case during starvation. Here enhancement of cAMP may play a role.
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PMID:The role of phosphoenolpyruvate and lactate production in insulin secretion. 22 40

Treatment of cultured normal rat kidney cells with the nitrosourea-containing compounds streptozotocin, chlorozotocin, or 1-(2-chloroethyl)-3-(4-methylcyclohexyl)-1-nitrosourea resulted in a time-dependent potentiation in the ability of prostaglandin E1 and (-)-isoproterenol to elevate intracellular cAMP levels. This hormone response increased at 4 hours and reached a maximum at 15--25 hours after addition of the nitrosoureas. Basal cAMP levels were not affected. The greater response was apparently due to an increase in the GTP-dependent step in hormonal activation of adenylate cyclase, inasmuch as GTP- and GTP plus hormone-stimulated adenylate cyclase activities were enhanced twofold to threefold in crude membranes prepared from nitrosourea-treated cells. Fluoride-stimulated adenylate cyclase activity was increased only 10--25%. Nicotinamide did not prevent the elevated response, and NAD+ plus NADH levels were not appreciably altered after 42 hours; treatment with streptozotocin. The results suggest a possible involvement of cAMP in the biologic actions of nitrosoureas.
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PMID:Increase in hormonal activation of adenylate cyclase by treatment of cultured cells with N-alkyl,N-nitrosourea. 22 93

Activation of adenylate [ATP pyrophosphate-lyase (cyclizing), EC 4.6.1.1] by cholera toxin (84,000 daltons, 5.5 S) is demonstrated in plasma membrane fragments of mouse ascites cancer cells. The activation of adenylate cyclase is mediated by a macromolecular cyclase activating factor (MCAF), which has a sedimentation constant of 2.7 S and a molecular weight of about 26,000. MCAF is derived from, and may be identical to the "A fragment" of cholera toxin. Generation of MCAF depends on prior interaction of cholera toxin with either dithiothreitol, NADH, NAD, or a low-molecular-weight component (less than 700 daltons) present in cytoplasm. Subsequent exposure of this pretreated cholera toxin to cell membranes from a variety of mouse ascites cancer cells is followed rapidly by the appearance of MCAF, which no longer requires dithiothreitol, NADH, or NAD for the activation of adenylate cyclase. Activation of adenylate cyclase by MCAF in ascites cancer cell membrane fragments is not reversed by repeated washing of these membrane fragments. Adenylate cyclase in normal cell membrane fragments fails to respond either to cholera toxin or MCAF in the presence of dithiothreitol. In striking contrast, the adenylate cyclase in membrane fragments from five ascites cancer cells responds to either MCAF or native cholera toxin preincubated with dithiothreitol, NADH, or NAD.
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PMID:Cholera toxin activation of adenylate cyclase in cancer cell membrane fragments. 105 74

Adenylate cyclase activity in isolated rat liver plasma membranes was inhibited by NADH in a concentration-dependent manner. Half-maximal inhibition of adenylate cyclase was observed at 120 microM concentration of NADH. The effect of NADH was specific since adenylate cyclase activity was not altered by NAD+, NADP+, NADPH, and nicotinic acid. The ability of NADH to inhibit adenylate cyclase was not altered when the enzyme was stimulated by activating the cyclase was not altered when the enzyme was stimulated by activating the Gs regulatory element with either glucagon or cholera toxin. Similarly, inhibition of Gi function by pertussis toxin treatment of membranes did not attenuate the ability of NADH to inhibit adenylate cyclase activity. Inhibition of adenylate cyclase activity to the same extent in the presence and absence of the Gpp (NH) p suggested that NADH directly affects the catalytic subunit. This notion was confirmed by the finding that NADH also inhibited solubilized adenylate cyclase in the absence of Gpp (NH)p. Kinetic analysis of the NADH-mediated inhibition suggested that NADH competes with ATP to inhibit adenylate cyclase; in the presence of NADH (1 mM) the Km for ATP was increased from 0.24 +/- 0.02 mM to 0.44 +/- 0.08 mM with no change in Vmax. This observation and the inability of high NADH concentrations to completely inhibit the enzyme suggest that NADH interacts at a site(s) on the enzyme to increase the Km for ATP by 2-fold and this inhibitory effect is overcome at high ATP concentrations.
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PMID:Inhibition of hepatic adenylate cyclase by NADH. 187

A comprehensive model of cellular activation and proliferation is developed. The model has arachidonic acid (ARA) produced mainly from PLA2 on both sides of the membrane, and superoxide and other activated oxygen species (AOS) formed from O2 by electrons passing out through membrane NANPH and NADH oxidases, as the immediate stimulants of solute permeability. Both ARA and AOS interact with the various solute channel proteins especially their external thiols and disulfides, to increase influx of metabolic substrates, Na, Ca and O2. PLA2 and NADPH oxidase are turned on by growth factors at their receptors acting through tyrosine kinase phosphorylations of messenger proteins GP and ras p-21, stimulated proteases, and by Ca-calmodulin. The adenylate cyclase system has opposite, deactivating character as it increases efflux of Ca and desensitizes growth factor receptors by phosphorylation to shut down the increased solute permeability. Most cancer types are due to carcinogen binding to cell membrane channel and mitochondrial sites for increased solute influx with excessive AOS production inside the cell from mitochondria and other vesicles. High Ca, Na and AOS stimulate proliferation with extra high levels causing transformation to the autogenic, more embryonic-type cancer cell.
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PMID:Unitary model of cell activation, growth control, cancer and other diseases: 1. Activated oxygen species and arachidonic acid modulation of solute permeabilities, internal Ca, Na and AOS levels and DNA transcription and synthesis. 192 75

Plasma membranes were purified from deciduoma of pseudopregnant rats and rat liver. Preparations contained 80% plasma membrane-derived material as based on electron microscope morphometry and analysis of enzyme markers. Several plasma membrane enzymes were tested for direct response to hormones. NADH-ferricyanide reductase of plasma membranes from both tissues was stimulated by glucagon and inhibited by insulin but was unresponsive to steroids. For steroids, responsiveness was limited to a reduction in NaF-stimulated adenylate cyclase activity by the steroid R5020. Thus, interaction of steroid hormones with plasma membranes, unlike that of glucagon and insulin, is not reflected in an altered activity of plasma membrane-bound dehydrogenases but may be exerted directly on adenylate cyclase.
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PMID:Hormone regulated enzyme activities of plasma membrane of decidual endometrium of the rat. 220 37

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