EC:1.11.1.7 - FACTA Search

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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)

Glutathione (GSH) was oxidized to GSSG in the presence of H2O2, tyrosine, and peroxidase. During the GSH oxidation catalyzed by lactoperoxidase, O2 was consumed and the formation of glutathione free radical was confirmed by ESR of its 5,5'-dimethyl-1-pyrroline-N-oxide adduct. When lactoperoxidase was replaced by thyroid peroxidase in the reaction system, the consumption of O2 and the formation of the free radical became negligibly small. These results led us to conclude that, in the presence of H2O2 and tyrosine, lactoperoxidase and thyroid peroxidase caused the one-electron and two-electron oxidations of GSH, respectively. It was assumed that GSH is oxidized by primary oxidation products of tyrosine, which are phenoxyl free radicals in lactoperoxidase reactions and phenoxyl cations in thyroid peroxidase reactions. When tyrosine was replaced by diiodotyrosine or 2,6-dichlorophenol, the difference in the mechanism between lactoperoxidase and thyroid peroxidase disappeared and both caused the one-electron oxidation of GSH. Iodides also served as an effective mediator of GSH oxidation coupled with the peroxidase reactions. In this case the two peroxidases both caused the two-electron oxidation of GSH.
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PMID:Characterization of one- and two-electron oxidations of glutathione coupled with lactoperoxidase and thyroid peroxidase reactions. 302 21

3-Amino-1,2,4-triazole, a thyroid carcinogen and goitrogen, is negative in a wide variety of short-term mutagenicity assays. However, amitrole induces gene mutations and morphological transformation in Syrian hamster embryo fibroblasts, cells known to carry out the prostaglandin H synthase (PHS)-mediated peroxidative metabolism of other carcinogens. Therefore, we have investigated the peroxidase-mediated binding of [14C]amitrole to macromolecules in vitro. We report here the PHS- and lactoperoxidase-catalyzed binding of [14C]amitrole to protein and tRNA, as well as protein binding by rat and hog thyroid peroxidase. PHS was an order of magnitude more active than lactoperoxidase and two orders of magnitude more active than thyroid peroxidase. The low levels of binding observed with thyroid peroxidase could be explained by the rapid and potent inhibition of this enzyme by amitrole. Although the thyroid peroxidase-mediated binding of amitrole was quite low, it was not inhibitable by compounds that would be expected to be competing substrates in vivo (i.e. I-, monoiodotyrosine, diiodotyrosine). Neither catalase nor horseradish peroxidase catalyzed binding of [14C]amitrole. It was also observed that an interaction between amitrole and protein and/or nucleic acid resulted in the slow generation of hydrogen peroxide, which then served as a substrate to drive peroxidase-mediated binding of [14C]amitrole. These data suggest that PHS may be responsible for conversion of amitrole to a mutagenic intermediate in Syrian hamster embryo cells. Furthermore, the generation of reactive metabolites of amitrole by thyroid peroxidase and/or PHS may contribute to the complete carcinogenicity of this compound by adding a mutagenic response to its potent hormonal effects.
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PMID:Macromolecular binding of the thyroid carcinogen 3-amino-1,2,4-triazole (amitrole) catalyzed by prostaglandin H synthase, lactoperoxidase and thyroid peroxidase. 310 50

Methimazole, an irreversible, mechanism-based (suicide substrate) inhibitor of thyroid peroxidase and lactoperoxidase, also inhibits the oxidation of xenobiotics by prostaglandin hydroperoxidase. The mechanism(s) by which methimazole inhibits prostaglandin H synthase-catalyzed oxidations is not conclusively known. In studies reported here, methimazole inhibited the prostaglandin H synthase-catalyzed oxidation of benzidine, phenylbutazone, and aminopyrine in a concentration-dependent manner. Methimazole poorly supported the prostaglandin H synthase-catalyzed reduction of 5-phenyl-4-pentenyl hydroperoxide to the corresponding alcohol (5-phenyl-4-pentenyl alcohol), suggesting that methimazole is not serving as a competing reducing cosubstrate for the peroxidase. Methimazole is not a mechanism-based inhibitor of prostaglandin hydroperoxidase or horseradish peroxidase since methimazole did not inhibit the peroxidase-catalyzed, benzidine-supported reduction of 5-phenyl-4-pentenyl hydroperoxide. In contrast, methimazole inhibited the reduction of 5-phenyl-4-pentenyl hydroperoxide to 5-phenyl-4-pentenyl alcohol catalyzed by lactoperoxidase, confirming that methimazole is a mechanism-based inhibitor of that enzyme and that such inhibition can be detected by our assay. Glutathione reduces the aminopyrine cation free radical, the formation of which is catalyzed by the hydroperoxidase, back to the parent compound. Methimazole produced the same effect at concentrations equimolar to those required for glutathione. These data indicate that methimazole does not inhibit xenobiotic oxidations catalyzed by prostaglandin H synthase and horseradish peroxidase through direct interaction with the enzyme, but rather inhibits accumulation of oxidation products via reduction of a free radical-derived metabolite(s).
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PMID:The mechanism for the inhibition of prostaglandin H synthase-catalyzed xenobiotic oxidation by methimazole. Reaction with free radical oxidation products. 311 86

Both lesion (L) and adjacent normal (N) thyroid tissue from 48 patients with non-functioning adenomas and adenomatous goitres were assayed for peroxidase activity by the 'mini' assay method employing guaiacol or iodide as the second substrate. A considerable proportion of thyroids (46% of adenomas and 22% of adenomatous goitres) demonstrated no iodide oxidation activity in L although they had guaiacol oxidation activity, and these were grouped as subgroups A. The rest of these non-functioning tumours, termed subgroups B, had both guaiacol and iodide oxidation activity which was higher (3.0-4.6 times in guaiacol assay and 7.3-14.1 times in iodide assay) in L than in N. These data indicate that the non-functioning in subgroups A may be due to a lack of iodide oxidation activity and that some other defects such as an iodide transport defect may be involved in subgroups B. Furthermore, a precise and rapid assay method for thyroglobulin iodination activity of thyroid peroxidase was developed, with modifications of previous methods. On the basis of this method, we found that there is a good correlation (r = 0.94) between iodide oxidation assay and thyroglobulin iodination assay, leading to the conclusion that thyroglobulin iodination assay can be replaced by iodide oxidation assay.
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PMID:Peroxidase activity and thyroglobulin iodination activity of thyroid peroxidase in non-functioning thyroid tumours. 338 46

Spectral scans in both the visible (650-450 nm) and the Soret (450-380 nm) regions were recorded for the native enzyme, Compound II, and Compound III of lactoperoxidase and thyroid peroxidase. Compound II for each enzyme (1.7 microM) was prepared by adding a slight excess of H2O2 (6 microM), whereas Compound III was prepared by adding a large excess of H2O2 (200 microM). After these compounds had been formed it was observed that they were slowly reconverted to the native enzyme in the absence of exogenous donors. The pathway of Compound III back to the native enzyme involved Compound II as an intermediate. Reconversion of Compound III to native enzyme was accompanied by the disappearance of H2O2 and generation of O2, with approximately 1 mol of O2 formed for each 2 mol of H2O2 that disappeared. A scheme is proposed to explain these observations, involving intermediate formation of the ferrous enzyme. According to the scheme, Compound III participates in a reaction cycle that effectively converts H2O2 to O2. Iodide markedly affected the interconversions between native enzyme, Compound II, and Compound III for lactoperoxidase and thyroid peroxidase. A low concentration of iodide (4 microM) completely blocked the formation of Compound II when lactoperoxidase or thyroid peroxidase was treated with 6 microM H2O2. When the enzymes were treated with 200 microM H2O2, the same low concentration of iodide completely blocked the formation of Compound III and largely prevented the enzyme degradation that otherwise occurred in the absence of iodide. These effects of iodide are readily explained by (i) the two-electron oxidation of iodide to hypoiodite by Compound I, which bypasses Compound II as an intermediate, and (ii) the rapid oxidation of H2O2 to O2 by the hypoiodite formed in the reaction between Compound I and iodide.
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PMID:Spectral studies with lactoperoxidase and thyroid peroxidase: interconversions between native enzyme, compound II, and compound III. 340 Oct 9

Two forms of human thyroid peroxidase cDNAs were isolated from a lambda gt11 cDNA library, prepared from Graves disease thyroid tissue mRNA, by use of oligonucleotides. The longest complete cDNA, designated phTPO-1, has 3048 nucleotides and an open reading frame consisting of 933 amino acids, which would encode a protein with a molecular weight of 103,026. Five potential asparagine-linked glycosylation sites are found in the deduced amino acid sequence. The second peroxidase cDNA, designated phTPO-2, is almost identical to phTPO-1 beginning 605 base pairs downstream except that it contains 1-base-pair difference and lacks 171 base pairs in the middle of the sequence. This results in a loss of 57 amino acids corresponding to a molecular weight of 6282. Interestingly, this 171-nucleotide sequence has GT and AG at its 5' and 3' boundaries, respectively, that are in good agreement with donor and acceptor splice site consensus sequences. Using specific oligonucleotide probes for the mRNAs derived from the cDNA sequences hTPO-1 and hTPO-2, we show that both are expressed in all thyroid tissues examined and the relative level of two mRNAs is different in each sample. These results suggest that two thyroid peroxidase proteins might be generated through alternate splicing of the same gene. By using somatic cell hybrid lines, the thyroid peroxidase gene was mapped to the short arm of human chromosome 2.
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PMID:Human thyroid peroxidase: complete cDNA and protein sequence, chromosome mapping, and identification of two alternately spliced mRNAs. 347 93

Autoantibodies (aAb) in serum of patients with autoimmune thyroid diseases (AITD) are directed to an antigen associated with thyroid microsomes. Although it has been investigated over almost three decades, the nature of this autoantigen remained unknown. Taking advantage of monoclonal antibodies (mAb) produced in our laboratory, we have demonstrated that thyroid peroxidase (TPO) is the 'microsomal' antigen. Sera of patients with AITD strongly inhibited the binding of only one of 19 mAb raised against human thyroid plasma membranes. This mAb did not react with thyroglobulin but achieved significant binding to preparations of human, bovine and porcine TPO, bovine lactoperoxidase and human myeloperoxidase without altering the enzyme activity. The mAb has been used to immunopurify the human TPO from solubilized thyroid microsomes. The procedure allowed high purification (approximately 3500-fold) of the native enzyme with a reasonable yield (approximately 10 mg TPO/kg thyroid tissue). Human TPO exhibited a specific activity of 350-400 guaiacol U/mg, a peak in the Soret region and a ratio of A411 nm to A280 nm of 0.20-0.25. Upon SDS-polyacrylamide gel electrophoresis, the purified enzyme gave two contiguous bands in the 100 kDa region. Performed in non-reducing conditions, electrophoresis of TPO showed one band in the same 100 kDa region. Sera with aAb to the microsomal antigen immunoprecipitated purified TPO to an extent ranging from 80 to 100% of the initial enzyme amount while sera from normal subjects or from patients with undectable level of anti-microsomal aAb elicit a decrease of less than 30% of the total TPO activity.(ABSTRACT TRUNCATED AT 250 WORDS)
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PMID:Thyroid peroxidase is the organ-specific 'microsomal' autoantigen involved in thyroid autoimmunity. 347 21

Peroxidases are known to be involved in the intracellular metabolism of H2O2 coupled with various physiological functions. Apart from the thyroid gland, the enzyme has been isolated from various extrathyroidal sources of which salivary gland is one of the richest sources of the enzyme. The enzyme from bovine and goat submaxillary gland has been extensively studied in terms of their molecular, spectral, kinetic, catalytic and immunological properties and compared with the lactoperoxidase which is similar to the salivary peroxidase. The modulation of the salivary peroxidase by various factors and the probable mechanism of the modulation has been described. The enzyme has also been compared with the thyroid peroxidase as regards their physicochemical properties as well as on the immunological and functional aspects. The similarities and dissimilarities have been incorporated. The possible function of the enzyme in iodine metabolism and in bactericidal action has been discussed.
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PMID:Salivary peroxidases. 352 Feb 91

Ultrastructural localization of endogenous thyroid peroxidase under benign pathological conditions such as toxic diffuse goiter, non-toxic multinodular goiter, and adenoma, and in normal tissue was studied. Peroxidase activity was visualized by a cytochemical reaction for electron microscopy. In toxic diffuse goiters and most non-toxic multinodular goiters, reaction product for peroxidase was observed not only in the cytoplasm but also at the external surface of microvilli of follicular cells. In normal thyroid tissues and adenomas, peroxidase was visualized only in the cytoplasm. Peroxidase activity at the external surface of microvilli of the follicular cells was found in the tissues obtained from the goiters which showed "hot" radioiodine scintigram. These findings suggest that follicles with peroxidase activity at the external surface of microvilli in non-toxic multinodular goiter are "autonomous follicles" and that peroxidase at the external surface of microvilli plays some role in active iodine uptake.
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PMID:Ultrastructural localization of endogenous peroxidase activity in benign thyroid diseases. 363 Jun 96

The interaction between thyroid microsomal autoantibodies and thyroid microsomal antigen/thyroid peroxidase (TPO) has been studied using both intact antigen preparations and their water-soluble trypsin fragments. In an analysis of sera from 30 patients with Graves' or Hashimoto's diseases, microsomal antibodies showed similar reactivity towards trypsin fragments (with TPO activity) and intact detergent (sodium deoxycholate, DOC)-solubilized human microsomal antigen preparations (r = 0.96). This raised the possibility that both the peroxidase-active site and the major autoantigenic site(s) of microsomal antigen were present on the same trypsin fragments. Studies with porcine TPO showed that only a few sera contained microsomal antibodies which cross-reacted strongly with the porcine preparations. Further analysis was carried out by immunoprecipitation of 125I-labelled microsomal antigen followed by SDS-PAGE and autoradiography. These studies suggest that intact human microsomal antigen (a single-chain protein with Mr = 110,000) contains an intrachain loop of amino acids formed by a disulphide bridge. Trypsin treatment cleaves the antigen close to its transmembrane section and releases a water-soluble fragment (Mr = 100,000), containing the intact disulphide-linked loop of amino acids. Further trypsin action causes cleavage of the peptide bonds within the loop in some preparations. Consequently, three major water-soluble trypsin fragments (Mr = 100,000, 73,000 and 68,000) are formed all of which contain an intact disulphide bridge and have microsomal antibody binding activities. The integrity of the disulphide bridge in intact antigen/TPO preparations and their trypsin fragments is essential for autoantibody binding activity.
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PMID:Structure-activity analysis of microsomal antigen/thyroid peroxidase. 366 90

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