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: UMLS:C0027960 (mole)
21,279 document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)

In order to select the method of water regeneration from air moisture condensate in a manned enclosed environment, the procedure of water decontamination from ethylene glycol was investigated. The process developed at t 20-22 degrees C and the following concentrations of C2H6O2 = 0.0125-0.5 mole/l, H2O2 = 1-5 mole/l, and catalyst = 1.7-50% wt. In the presence of 6.67 g/l of homogeneous catalyst FeSO4.7H2O, destructive oxidation of ethylene glycol to yield CO2 in the system 0.1 M C2H6O2 + 1M H2O2 proceeded effectively. However, the iron concentration in the decontaminated water exceeded significantly the maximally allowable concentration of iron in potable water as well as in industrial and non-industrial sewage. Heterogeneous MnO- and PbO-based catalysts provided no more than 20% ethylene glycol oxidation. Siderite, a natural mineral containing 33% wt. Fe2+, proved a more effective catalyst of ethylene glycol oxidation. When ethylene glycol and hydrogen peroxide were used at ratios of 1:30 and 1:80 with 5% wt. siderite, the degree of C2H6O2 to CO2 conversion was 99.2% and 99.8, respectively.
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PMID:[Water purification from ethylene glycol by catalytic oxidation using hydrogen peroxide]. 168 10

The products of the reactions of ozone with aqueous emulsions of unsaturated fatty acids and with liposomes made from phosphatidylcholine esters were characterized. Ozonolysis of emulsions of methyl oleate yields approximately 1 mol of hydrogen peroxide and 2 mol of aldehydes per mole of ozone used and fatty acid reacted. That is, the net equation that occurs is RCH = CHR' + O3 + H2O----RCHO + R'CHO + H2O2 . Ozonolysis of emulsions of oleic, linoleic, linolenic, and arachidonic acids gives 1 mol of hydrogen peroxide per mole of ozone used. Only very low yields (less than 5%) of reducible materials other than hydrogen peroxide are observed, suggesting that the yields of organic peroxidic materials, including Criegee ozonides and lipid hydroperoxides, are small. Ozonolysis of rat erythrocyte ghost membranes and rat bronchoalveolar lavage also gives significant yields (about 50%) of hydrogen peroxide based on the moles of ozone consumed. Reactions of ozone with bovine serum albumin, glutathione, and glucose do not produce hydrogen peroxide, implying that the hydrogen peroxide formed during the ozonation of biological materials arises almost exclusively from ozone/olefin reactions. Hydrogen peroxide and aldehydes are suggested to be important mediators of the modifications observed in both the lung and extrapulmonary tissues when ozone is inhaled.
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PMID:The ozonation of unsaturated fatty acids: aldehydes and hydrogen peroxide as products and possible mediators of ozone toxicity. 191 18

The mechanism of NADPH oxidation catalyzed by horse-radish peroxidase (HRP) and 2,4-diacetyl-[2H]heme-substituted horse-radish peroxidase (DHRP) was studied. The roles of the different H2O2/peroxidase compounds were examined by spectral studies. The oxidized NADPH species were identified using the superoxide dismutase effect and by measuring the stoichiometry between NADPH oxidized and H2O2 used. In the presence of a mediating molecule, like scopoletin, both enzymes acted via a similar mechanism, producing only NADP degrees, which in turn reacted with O2 producing O2-. Consequently H2O2 was completely regenerated in the presence of superoxide dismutase and partially regenerated in its absence. In the absence of a mediating molecule, the H2O2 complex of both enzymes (compound I) catalysed NADPH oxidation by single-electron transfer, producing NADP degrees; compound II of these enzymes catalyzed NADPH oxidation more slowly by a direct two-electron transfer, producing NADPH+. There were difference between HRP and DHRP. HRP compound II was produced by the oxidation of 1 mol NADPH/mole compound I, while DHRP compound II was formed by the spontaneous conversion of compound I to compound II. The NADPH oxidation catalyzed by DHRP compound I did not lead to the formation of compound II. When H2O2 was produced slowly by the glucose/glucose-oxidase system, compound II was never formed and a pure O2- adduct of DHRP (compound III) accumulated.
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PMID:Mechanism of NADPH oxidation catalyzed by horse-radish peroxidase and 2,4-diacetyl-[2H]heme-substituted horse-radish peroxidase. 193 47

It is generally agreed that unsaturated fatty acids (UFA) are an important class of target molecule for reaction with ozone when polluted air is inhaled. Most discussions have implicated the UFA in cell membranes, but lung lining fluids also contain fatty acids that are from 20 to 40% unsaturated. Since UFA in lung lining fluids exist in a highly aquated environment, ozonation would be expected to produce aldehydes and hydrogen peroxide, rather than the Criegee ozonide. In agreement with this expectation, we find that ozonations of emulsions of fatty acids containing from one to four double bonds give one mole of H2O2 for each mole of ozone reacted. Ozonation of oleic acid emulsions and dioleoyl phosphatidyl choline gives similar results. with two moles of aldehydes and one mole of H2O2 formed per mole of ozone reacted. The net reaction that occurs when ozone reacts with pulmonary lipids is suggested to be given by equation 1. [formula: see text]. From 5 to 10% yields of Criegee ozonides also appear to be formed. In addition, a direct reaction of unknown mechanism occurs between ozone and UFA in homogeneous organic solution, in homogeneous solutions in water, in aqueous emulsions, and in lipid bilayers to give organic radicals that can be spin trapped. These radicals are suggested to be responsible for initiating lipid peroxidation of polyunsaturated fatty acids. Thus, aldehydes, hydrogen peroxide, and directly produced organic radicals are suggested to be mediators of ozone-induced pathology.
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PMID:Aldehydes, hydrogen peroxide, and organic radicals as mediators of ozone toxicity. 193 28

A latent form of 'Ferrooxidase' exhibiting ferrocyanide-dependent O2 uptake was detected in the isolated spinach chloroplasts. Presence of a cationic detergent hexadecyl trimethyl ammonium bromide (CTAB) in the medium was essential to induce this activity. The association of this enzyme activity with photosystem II (PSII) particles as well as the ability of PSII particles to show oxidation of H2O2 (catalase like activity) indicated its possible relationship with water oxidation system. The protein catalysing this activity was purified to homogeneity and its molecular mass was found to be 34 kDa. The purified protein showed a complete dependence on an electron acceptor, namely ferricyanide, for the oxidation of H2O2. While with ferrocyanide in the presence of CTAB, the protein exhibits the ferrooxidase activity. For both activities, a sharp pH optima at 6.1 was observed. The km for H2O2 was 12.2 mM. The purified enzyme protein contained 4 atoms of calcium and 2 atoms of iron per mole of the enzyme. Unlike catalase, the enzyme reaction was insensitive to sodium azide even at 500 microM concentration. The enzyme was found to be sensitive to metal chelators like ethylene-glycol-bis-(beta-aminoethylether) N, N+ tetra acetic acid (EGTA) (2mM), alpha,alpha-dipyridyl (500 microM) and 1,10-orthophenanthroline (200 microM). The sensitivity of the reaction to alpha,alpha-dipyridyl and 1,10-orthophenanthroline suggested the involvement of Fe2+ in the reaction. Inhibition of enzyme activity by EGTA and restoration of activity by supplementation of CaCl2 to the EGTA-dialysed sample confirmed the absolute requirement for calcium for this activity. Calcium was absent in the EGTA-dialysed enzyme. Apart from these inhibitors, NaF and NH2OH were potent inhibitors of the enzyme reaction.(ABSTRACT TRUNCATED AT 250 WORDS)
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PMID:Isolation of 34 kDa protein from spinach chloroplasts having ferrooxidase and H2O2-dependent dark O2 evolution activities. 205 97

Dioleoyl phosphatidylcholine (PC) liposomes were ozonized and the ozonized liposomes were tested for their lytic potency on human red blood cells (RBC). Ozonation of PC liposomes generated approximately 1 mole equivalent of hydrogen peroxide (H2O2) and 2 mole equivalents of aldehydes, based on the moles of ozone consumed. The time necessary for 50% hemolysis induced by ozonized liposomes (a convenient measure of hemolytic activity) was found to depend on the extent of ozonation of the PC liposomes, indicating the formation and accumulation of hemolytic agents during ozonation. Hemolysis was also observed when RBC were incubated with nonanal, the expected product of the ozonation of oleic acid, the principle unsaturated fatty acid in the liposomes. Hydrogen peroxide, another product of PC ozonation, did not induce hemolysis; however, a combination of H2O2 and nonanal was significantly more hemolytic than nonanal alone. A ratio of 1:2 H2O2/nonanal (the ratio observed in the ozonized liposomes) provided hemolytic activity comparable to that observed with ozonized dioleoyl PC. Among different antioxidants tested, ascorbate, catalase, and glutathione peroxidase partially inhibited hemolysis induced by ozonized liposomes and by H2O2/nonanal mixtures, but they were not protective against the nonanal-induced hemolysis. Identification of H2O2 and aldehydes as cytotoxic chemical species generated from the ozonation of unsaturated fatty acids may have an important bearing on the in vivo toxicity of ozone on the lung as well as on extrapulmonary tissues.
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PMID:The mixture of aldehydes and hydrogen peroxide produced in the ozonation of dioleoyl phosphatidylcholine causes hemolysis of human red blood cells. 206 37

Superoxide dismutase was isolated from each of the anaerobically grown organisms Actinomyces naeslundii, Actinomyces strain E1S.25D, and Actinomyces odontolyticus. The enzymes were 100,000-110,000 mol wt acidic proteins (pI 4.3-4.6) and contained Mn and Zn, but no detectable Fe. The Mn and Zn content varied with the enzyme source. A. naeslundii superoxide dismutase, specific activity 2200 U/mg, contained 2.3 g atoms Mn and 1.4 g atoms Zn per mole tetramer whereas A. odontolyticus SOD, specific activity 700 U/mg, contained 1.4 g atoms Mn and 1.8 g atoms Zn per mole tetramer. Actinomyces strain E1S.25D, specific activity 1300 U/mg, contained 1.8 g atoms Mn and 1.2 g atoms Zn per mole tetramer. The amino acid compositions of the enzymes were comparable except for arginine, lysine, and tryptophan content. The enzymatic activity of each enzyme was stable in 5 mM H2O2 at 23 degrees C for 2 h. The enzymes were only modestly inhibited by 20 mM NaN3. The enzymatic activity was increased at low ionic strength but was markedly decreased at increased ionic strength with each salt tested except sodium perchlorate, which caused marked inhibition even at low ionic strength. Polyclonal antibodies to A. naeslundii and Actinomyces strain E1S.25D precipitated and inactivated their respective antigens whereas the precipitated A. odontolyticus superoxide dismutase-antibody complex retained virtually full catalytic activity. Immunological studies revealed that the native A. naeslundii and Actinomyces strain E1S.25D MnSODs share common epitopes and cross-reacted with precipitin lines of complete identity in Ouchterlony double diffusion gels. Antibody to the A. odontolyticus enzyme displayed only partial cross-reactivity with superoxide dismutase from the two other Actinomyces. Western blotting of the denatured antigens revealed reactivities of the antibodies that differed only slightly from the results of the Ouchterlony gels.
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PMID:Tetrameric manganese superoxide dismutases from anaerobic Actinomyces. 211 98

In bicarbonate/CO2 buffer, Mn(II) and Fe(II) catalyze the oxidation of amino acids by H2O2 and the dismutation of H2O2. As the Mn(II)/Fe(II) ratio is increased, the yield of carbonyl compounds per mole of leucine oxidized is essentially constant, but the ratio of alpha-ketoisocaproate to isovaleraldehyde formed increases, and the fraction of H2O2 converted to O2 increases. In the absence of Fe(II), the rate of Mn(II)-catalyzed leucine oxidation is directly proportional to the H2O2, Mn(II), and amino acid concentrations and is proportional to the square of the HCO3- concentration. The rate of Mn(II)-catalyzed O2 production in the presence of 50 mM alanine or leucine is about 4-fold the rate observed in the absence of amino acids and accounts for about half of the H2O2 consumed; the other half of the H2O2 is consumed in the oxidation of the amino acids. In contrast, O2 production is increased nearly 18-fold by the presence of alpha-methylalanine and accounts for about 90% of the H2O2 consumed. The data are consistent with the view that H2O2 decomposition is an inner sphere (cage-like) process catalyzed by a Mn coordination complex of the composition Mn(II), amino acid, (HCO3-)2. Oxidation of the amino acid in this complex most likely proceeds by a free radical mechanism involving hydrogen abstraction from the alpha-carbon as a critical step. The results demonstrate that at physiological concentrations of HCO3- and CO2, Mn(II) is able to facilitate Fenton-type reactions.
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PMID:Manganese(II) catalyzes the bicarbonate-dependent oxidation of amino acids by hydrogen peroxide and the amino acid-facilitated dismutation of hydrogen peroxide. 229 94

Hypochlorous acid generated by myeloperoxidase reacts with histamine to produce chloramines. At pH 7, one mole of histamine monochloramine (HisCl) was generated per mole of H2O2 provided as substrate for myeloperoxidase. At pH 5, one mole of histamine dichloramine (HisCl2) was generated per two moles of H2O2. HisCl and HisCl2 had two and four oxidizing equivalents per molecule, respectively. In vitro, 30 microM HisCl and HisCl2 induced mepyramine-sensitive guinea pig lung parenchyma contraction with 89 and 56 percent of the response of an equivalent concentration of histamine. Pretreatment of lung strips with chloramines reduced the subsequent contractile response of the tissues to methacholine. These results suggest that H-1 histamine receptors provide for targeting of histamine chloramines to pulmonary tissue which may facilitate modification of tissue responses.
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PMID:Formation of chloramine derivatives of histamine: role of histamine chloramines in bronchoconstriction. 255 45

The extrinsic 33-kDa protein (P33) was cross-linked covalently to the binding site on P33-depleted PSII preparations which is responsible for reconstitution of photosynthetic water oxidation after PSII preparations have been washed with 1 M CaCl2. Conditions were found in which more than half of the cross-linked protein complexes formed in the PSII preparations retained the ability to catalyze the oxidation of water. The complex is composed of the P33 cross-linked to the D1 and D2 proteins and a 34-kDa protein, which is present in lower abundance than the other three proteins. After solubilization of the membranes with SDS and purification by preparative SDS-PAGE, the complex retains bound manganese and can catalyze the conversion of H2O2 to O2. Calcium and chloride increased the catalase activity of the purified cross-linked complex while lanthanum or hydroxylamine abolished the activity. By use of the specific activity of the H2O2-dependent reaction to follow the extent of purification of the cross-linked complex, the most highly purified complex was determined to contain 0.34 microgram of manganese/180 micrograms of protein. The mole ratio of Mn/protein was calculated to range from 3.6 to 4.5 depending on the assumed stoichiometry of the protein subunits. The results presented here provide direct evidence that one or more of the three proteins that have cross-linked to the P33 are responsible for binding the manganese of the oxygen-evolving complex.
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PMID:Manganese-binding proteins of the oxygen-evolving complex. 267 50


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