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Query: EC:1.11.1.7 (
peroxidase
)
65,474
document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)
The activation of 14C-labeled estradiol by "true" and "pseudo" peroxidases to form conjugates and other products was compared in four model systems using H2O2, glutathione,
Mn2+
or irradiated riboflavin. Albumin was used as acceptor except in the glutathione system. The binding of estradiol to glutathione in the presence of the true peroxidases, lacto- or uterine
peroxidase
(no H2O2 added), was also examined and the conditions shown to differ from those required with the pseudoperoxidases, microperoxidase or trypsin-digested cytochrome c. The conjugates were purified by chromatography after elution from Amberlite XAD-2 and the relative amounts of these products assessed by autoradiography. The ratio of steroid to glutathione in the main water-soluble metabolite formed with
lactoperoxidase
was found to be approx 1:1 in a double label experiment with [14C]estradiol and [3H]glutathione. It was also shown, using estradiol labeled with 3H in different positions of the steroid molecule, that
lactoperoxidase
acts non-specifically in catalyzing the formation of glutathionyl conjugates as indicated by the release of 3H2O. The possible role of
peroxidase
and glutathione in the metabolism of estrogens and in the formation of artifactual products is discussed.
...
PMID:Metabolism of estradiol by true and pseudoperoxidases. 299 58
The purpose of this study was to elucidate the biochemical basis of the enhanced hydrogen peroxide (H2O2) production by guinea pig peritoneal macrophages (MP) cultured in lymphokine (LK)-containing medium. The markedly augmented H2O2 generation by these cells, demonstrable by the
horseradish peroxidase (HRP)
-catalyzed oxidation of phenol red, is distinguished by its lack of dependence on a second stimulus. We demonstrate that H2O2 production is truly spontaneous and is not caused by a stimulant present among the H2O2 assay reagents. The principal candidate for such a role was HRP type II (a mixture of five isoenzymes) that was reported to be capable of eliciting an oxidative burst in MP. Four distinct HRP isoenzymes that were found incapable of provoking an oxidative response were nevertheless adequate for demonstrating H2O2 production by LK-activated MP. Blocking the MP receptor for mannose by the addition of mannan to the assay system resulted in enhanced detection of H2O2 by low concentrations of HRP type II and by three out of four HRP isoenzymes. Treatment of MP with LK-containing medium for 72 hr did not result in a significant change in the activity of cellular superoxide dismutase (SOD) compared with MP cultured for the same length of time in control medium. By using the specific inhibitor of copper, zinc-containing SOD, sodium diethyldithiocarbamate (DDC), and the universal SOD inhibitor, sodium nitroprusside, we found that the predominant enzyme in guinea pig peritoneal MP is probably
manganese
-containing SOD. Incubation of LK-activated MP with nitroprusside resulted in almost total inhibition of H2O2 production and a simultaneous switch to superoxide (O2-) liberation. Similar exposure to DDC had no effect. These data indicate that H2O2 produced by LK-activated MP is derived exclusively by enzymatic dismutation of O2- mediated by a
manganese
-containing SOD. The increase in spontaneous H2O2 production induced by LK is therefore secondary to augmented O2- production that occurs at a cellular location where O2- is accessible to SOD. The enzymatic basis of the enhanced oxygen radical production was investigated by determining the kinetic parameters of the O2- -forming NADPH oxidase of resting LK-treated MP in a cellfree system in which O-2 production was induced by sodium dodecyl sulfate. The Km for NADPH and the Vmax of the enzyme of LK-treated MP were not different from those of the enzyme of MP incubated in control medium. We conclude that LK treatment of MP does not modulate the NADPH oxidase itself but, most likely, a process related to activation of the enzyme.
...
PMID:The mechanism of action of lymphokines. IX. The enzymatic basis of hydrogen peroxide production by lymphokine-activated macrophages. 301 93
We have isolated a heme protein from canine midbrains that possesses potent
peroxidase
activity. This enzyme catalyzes the oxidation of dopamine to neuromelanin in the presence of H2O2. We have further shown that the isolated
peroxidase
possesses potent cytotoxic activity in the presence of superoxide or H2O2 and Cl-. The enzyme possesses an endogenous NAD(P)H oxidase activity that can promote the cytotoxic activity by virtue of its production of superoxide. Other enzymes such as dihydroorotate dehydrogenase and galactose oxidase, which produce O2- and H2O2, respectively, are also effective in promoting the cytotoxic activity of the brainstem
peroxidase
. Although rat erythrocytes were routinely used as the target cell, other cell types, including rat hepatoma and mouse neuroblastoma cells, are also susceptible to the toxic action of the
peroxidase
. The cytotoxic action of the brainstem
peroxidase
is dramatically enhanced by kainic acid and is significantly enhanced by
Mn2+
, whereas dopamine was found to be a potent inhibitor of the cytotoxic activity. Based on these findings, we postulate a central role for the brainstem
peroxidase
in dopamine metabolism as well as in the biochemical and anatomical changes associated with Parkinson's disease.
...
PMID:Neuromelanogenic and cytotoxic properties of canine brainstem peroxidase. 302 61
Peroxide compounds of
manganese
protoporphyrin IX and its complexes with apo-horseradish
peroxidase
and apocytochrome-c
peroxidase
were characterized by electronic absorption and electron paramagnetic resonance spectroscopies. An intermediate formed upon titration of
Mn(III)
-horseradish
peroxidase
with hydrogen peroxide exhibited a new electron paramagnetic resonance absorption at g = 5.23 with a definite six-lined 55Mn hyperfine (AMn = 8.2 mT). Neither a porphyrin pi-cation radical nor any other radical in the apoprotein moiety could be observed. The reduced form of Mn-horseradish
peroxidase
,
Mn(II)
-horseradish
peroxidase
, reacted with a stoichiometric amount of hydrogen peroxide to form a peroxide compound whose electronic absorption spectrum was identical with that formed from
Mn(III)
-horseradish
peroxidase
. The electronic state of the peroxide compound of
manganese
horseradish
peroxidase
was thus concluded to be Mn(IV), S = 3/2.
Mn(III)
-cytochrome-c peroxidase reacted with stoichiometry quantities of hydrogen peroxide to form a catalytically active intermediate. The electronic absorption spectrum was very similar to that of a higher oxidation state of
manganese
porphyrin, Mn(V). Since the peroxide compound of
manganese
cytochrome-c peroxidase retained two oxidizing equivalents per mol of the enzyme (Yonetani, T. and Asakura, T. (1969) J. Biol. Chem. 244, 4580-4588), this peroxide compound might contain an Mn(V) center.
...
PMID:Electron paramagnetic resonance and spectrophotometric studies of the peroxide compounds of manganese-substituted horseradish peroxidase, cytochrome-c peroxidase and manganese-porphyrin model complexes. 303 Apr 31
Ligninase-I (Mr 42,000-43,000; carbohydrate, 21%) and peroxidase-M2 (Mr 45,000-47,000; carbohydrate, 17%), two representative, hydrogen peroxide-dependent extracellular enzymes produced by ligninolytic cultures of the white-rot fungus Phanerochaete chrysosporium BKM-F-1767, were purified and their properties compared. Spectroscopic studies showed that both native enzymes are heme proteins containing protoporphyrin IX. EPR spectroscopy indicated that iron ions are coordinated with the enzymes' prosthetic groups as high-spin ferriheme complexes. We confirmed reports of others that the ligninase-hydrogen peroxide complex (activated enzyme) reverts to its native state on addition of dithionite or one of the enzyme's substrates (e.g., veratryl alcohol); however, we found that the peroxidase-M2-hydrogen peroxide complex required
Mn2+
ions to accomplish a similar cycle. The
peroxidase
oxidized
Mn2+
to a higher oxidation state, and the oxidized Mn acted as a diffusible catalyst able to oxidize numerous organic substrates. Unlike ligninase-I which is found free extracellularly, peroxidase-M2 appears to be associated closely with the fungal mycelium. In its peroxidatic reactions, ligninase-I oxidizes a variety of nonphenolic and phenolic lignin model compounds. In the presence of
Mn2+
, peroxidase-M2 oxidizes numerous phenolic compounds, especially syringyl (3,5-dimethoxy-4-hydroxyphenyl) and vinyl side-chain substituted substrates. Also, the
peroxidase
-
Mn2+
system (without hydrogen peroxide) expresses oxidase activity against NADPH, GSH, dithiothreitol, and dihydroxymaleic acid, forming hydrogen peroxide at the expense of oxygen. Both enzymes were believed to play roles in lignin degradation, and these are discussed.
...
PMID:Comparison of ligninase-I and peroxidase-M2 from the white-rot fungus Phanerochaete chrysosporium. 308 Sep 53
An H2O2-generating fraction was prepared from porcine thyroid homogenate by differential and Percoll-density gradient centrifugations. The fraction consisted of mainly fragmented plasma membranes as judged by marker enzyme analysis and electron microscopy. The fraction produced H2O2 by reaction with NADPH only in the presence of Ca2+. The Ca2+ concentration for half-maximal activation (KCa) was about 0.1 microM and the Hill coefficient was 2. Sr2+ also activated the reaction whereas
Mn2+
, Zn2+, and Cd2+ inhibited it. The reaction was enhanced about twice by addition of ATP but not ADP, and inhibited by addition of hexokinase together with glucose to remove ATP. The Km value for NADPH was 35 microM and was less than 1/12 that for NADH. The NADPH oxidation rate was measured and the KCa and the Km were similar to those for the H2O2 production. The stoichiometry between the oxidation and the H2O2 formation was essentially 1. Superoxide dismutase (SOD) and KCN did not affect H2O2 production. The fraction catalyzed NADPH-cytochrome c reduction but the activity was SOD-insensitive. These results suggest that H2O2 was not generated through superoxide anion formation. NADPH-dichloroindophenol (DCIP) reductase activity was also observed and DCIP inhibited the production of H2O2. The cytochrome c and DCIP reductase activities were not influenced by Ca2+ or ATP. A unique electron transport system regulated by Ca2+ and ATP exists in the thyroid plasma membrane that produces H2O2. The concentrations of Ca2+ and ATP in thyroid cells may regulate hormone synthesis through activation of the production of H2O2, a substrate for
peroxidase
.
...
PMID:Activation by ATP of calcium-dependent NADPH-oxidase generating hydrogen peroxide in thyroid plasma membranes. 312 60
Manganese
peroxidase
(MnP), an extracellular heme enzyme from the lignin-degrading fungus Phanerochaete chrysosporium, catalyzes the
Mn(II)
-dependent oxidation of a variety of phenols. Herein, we spectroscopically characterize the oxidized states of MnP compounds I, II, and III and clarify the role of Mn in the catalytic cycle of the enzyme. Addition of 1 equiv of H2O2 to the native ferric enzyme yields compound I, characterized by absorption maxima at 407, 558, 605, and 650 nm. Addition of 2 or 250 equiv of H2O2 to the native enzyme yields compound II or III, respectively, identified by absorption maxima at 420, 528, and 555 nm or at 417, 545, and 579 nm, respectively. These characteristics are very similar to those of
horseradish peroxidase (HRP)
and lignin peroxidase (LiP) compounds I, II, and III. Addition of 1 equiv of either
Mn(II)
, ferrocyanide, or a variety of phenols to MnP compound I rapidly reduces it to MnP compound II. In contrast, only
Mn(II)
or ferrocyanide, added at a concentration of 1 equiv, reduces compound II. The
Mn(III)
produced by the enzymic oxidation of
Mn(II)
oxidizes the terminal phenolic substrates. This indicates that compounds I and II of MnP contain 2 and 1 oxidizing equiv, respectively, over the native ferric resting enzyme and that the catalytic cycle of the enzyme follows the path native enzyme----compound I----compound II----native enzyme. In addition, these results indicate that
Mn(II)
serves as an obligatory substrate for MnP compound II, allowing the enzyme to complete its catalytic cycle. Finally, the
Mn(II)
/
Mn(III)
redox couple enables the enzyme to rapidly oxidize the terminal phenolic substrates.
...
PMID:Manganese peroxidase from the basidiomycete Phanerochaete chrysosporium: spectral characterization of the oxidized states and the catalytic cycle. 316 51
The cytochemical reaction for surface-bound
horseradish peroxidase (HRP)
on cultured HeLa cells, GH3 cells, and isolated rat liver cells was suppressed by 30 microM monosialoganglioside, by 30 microM trisialoganglioside, or by 5 mM CMP-neuraminic acid. The reaction was also suppressed by 10 mM chitotriose or by 10 mM UDP-galactose, a galactose acceptor and donor, respectively, for galactosyl-transferase. The addition of 2 mM
Mn2+
to the incubation medium with HRP suppressed the reaction for surface-bound HRP, and the addition of 10-20 mM Ca2+ intensified the reaction. The addition of 2 mM Zn2+ caused less inhibition than that of 2 mM
Mn2+
, and the addition of 2 mM Co2+ caused either a slight inhibition, or no inhibition. These observations support the hypothesis that HRP may be bound to a glycosyltransferase at the cell surface.
...
PMID:Binding sites for horseradish peroxidase on the cell surface. Suppression of binding by gangliosides and effects of some bivalent cations. 358 19
Addition of vanadate, stimulated oxidation of NADH by rat liver microsomes. The products were NAD+ and H2O2. High rates of this reaction were obtained in the presence of phosphate buffer and at low pH values. The yellow-orange colored polymeric form of vanadate appears to be the active species and both ortho- and meta-vanadate gave poor activities even at mM concentrations. The activity as measured by oxygen uptake was inhibited by cyanide, EDTA, mannitol, histidine, ascorbate, noradrenaline, adriamycin, cytochrome c,
Mn2+
, superoxide dismutase, horseradish
peroxidase
and catalase. Mitochondrial outer membranes possess a similar activity of vanadate-stimulated NADH oxidation. But addition of mitochondria and some of its derivative particles abolished the microsomal activity. In the absence of oxygen, disappearance of NADH measured by decrease in absorbance at 340 nm continued at nearly the same rate since vanadate served as an electron acceptor in the microsomal system. Addition of excess catalase or SOD abolished the oxygen uptake while retaining significant rates of NADH disappearance indicating that the two activities are delinked. A mechanism is proposed wherein oxygen receives the first electron from NAD radical generated by oxidation of NADH by phosphovanadate and the consequent reduced species of vanadate (Viv) gives the second electron to superoxide to reduce it H2O2. This is applicable to all membranes whereas microsomes have the additional capability of reducing vanadate.
...
PMID:Vanadate-stimulated NADH oxidation in microsomes. 365 Jun 94
Nitridomanganese(V) protoporphyrin IX was prepared by hypochlorite oxidation of the corresponding
manganese
(III) protoporphyrin IX derivative in the presence of ammonium ion and by photolysis of the corresponding azidomanganese(III) complex. Myoglobin and horseradish
peroxidase
containing this novel protoporphyrin derivative were prepared for the first time. These remarkably stable species were examined by electronic absorption, electron paramagnetic resonance, and resonance Raman spectroscopies. The MnV-N stretching modes of the nitridomanganese(V)-substituted myoglobin and horseradish
peroxidase
were observed at 1010 and 1003 cm-1, respectively, by resonance Raman spectroscopy, while the MnV-N stretching frequency for nitridomanganese(V) protoporphyrin IX in 0.1 N aqueous NaOH was found at 1046 cm-1. The equilibrium dissociation energies of MnV-N bonds in these complexes were estimated from vibrational overtone spacings by introducing the Morse potential energy function, were found to be around 4.5 eV, and seemed independent of the surroundings of the
manganese
porphyrin, although its force constant decreased from 7.3 to 6.7 mdyn/A upon incorporation into apoprotein. The porphyrin ring modes of these nitridomanganese(V) derivatives were influenced greatly upon incorporation into apoproteins, suggestive of the occurrence of porphyrin core expansion. Upon this core expansion the MnV center moves into the mean plane of porphyrin plane, but the access of nitrido (N) toward MnV is restricted due to a steric hindrance from porphyrin pyrrole nitrogens. The resulting stretched MnV-N bond might cause lowering of the MnV-N stretching frequency upon incorporation into apoprotein.
...
PMID:Influence of heme-surrounding amino acid residues on the manganese (V)-nitrido bond in manganese-substituted hemoproteins: resonance Raman evidence for porphyrin core expansion and reduction of the manganese(V)-nitrido stretching force constant. 366 40
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