EC:1.11.1.8 - FACTA Search

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Query: EC:1.11.1.8 (thyroid peroxidase)
3,116 document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)

In thyroid gland, iodination takes place on the apical plasma membrane and requires the presence of the thyroid peroxidase and H2O2 generating system. H2O2 generation and NBT (nitro blue tetrazolium) reductase activity (both of which are NADPH-dependent) as well as peroxidase activity were compared for their respective orientations in membrane vesicles. The possible role of NADPH-NBT reductase activity in H2O2 generation was also examined. Results favor the conclusion that thyroid peroxidase is oriented towards the luminal side of the vesicles, whereas the NADPH site of NADPH oxidase-dependent H2O2 generation is located on the external side of the same or of different vesicles. Furthermore, it is shown that different NADPH-NBT reductase activities are present on both the outer and inner surfaces of the membrane vesicles, and that none of these activities is able to produce either H2O2 or O-2. The idea that a multi-component complex is involved in H2O2 generation is discussed, and a model is proposed which takes into account the possible spatial separation of the thyroid peroxidase site from the NADPH site of this H2O2 generation system on the apical membrane of the thyrocyte.
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PMID:Relation between thyroid peroxidase, H2O2 generating system and NADPH-dependent reductase activities in thyroid particulate fractions. 401 97

The peroxidase activity in rat gastric mucosa is inhibited after administration of glucocorticoids. The synthetic steroid dexamethasone is more potent than the naturally occurring steroids, such as cortisone or corticosterone. Almost complete inhibition of the enzyme occurs after 24 h with a single dose of 100 micrograms dexamethasone/120 g body weight. Other mitochondrial enzyme activities, like monoamine oxidase, succinic dehydrogenase and Mg2+-ATPase, remain unaltered under the same experimental condition. Submaxillary peroxidase and thyroid peroxidase activity are not inhibited by dexamethasone. Gastric peroxidase activity is increased 200-250% on the 6th day after adrenalectomy. This effect is blocked by the administration of dexamethasone. In fact, the enzyme becomes more sensitive to dexamethasone after adrenalectomy, since it is inhibited by more than 90% at the dose of 25 micrograms/120 g body weight. The inhibition by dexamethasone in normal animals is reversible. The enzyme is also inhibited after the administration of a single dose of ACTH. The apparent Km of the enzyme for H2O2 is not altered after dexamethasone treatment or after adrenalectomy. The increase in enzyme activity following adrenalectomy is not blocked by actinomycin D or by alpha-amanitin, but is prevented by puromycin or cycloheximide. After administration of dexamethasone, the iodide concentration process in the gastric mucosa is not affected, but the organification of iodide is significantly diminished.
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PMID:Glucocorticoid effects on gastric peroxidase activity. 608 14

In a previous communication we proposed a reaction scheme to explain our observation that thyroid peroxidase and lactoperoxidase degrade H2O2 catalatically in the presence of low concentrations of iodide. An essential feature of the scheme was the proposal that enzyme-bound hypoiodite, designated [EOI]-, is a common intermediate in various peroxidase-catalyzed reactions involving iodide. In the present investigation, we tested the validity of this scheme by studying the predictions that it makes concerning the formation of OH-, O2, I2, and organically bound iodine. Stoichiometric and kinetic measurements were made to correlate formation of these various products. Three different peroxidase-catalyzed reactions were studied: 1) oxidation of I- to I2; 2) iodide-dependent catalytic degradation of H2O2 to O2; and 3) iodination of tyrosine or thyroglobulin. Reaction 2 was also studied nonenzymatically using I2, for comparison with the enzyme-catalyzed reaction. In all three reactions, both the stoichiometric and kinetic results with thyroid peroxidase agreed closely with the predictions made by the proposed scheme. This was largely the case with lactoperoxidase also. However, in the case of lactoperoxidase-catalyzed iodination of tyrosine or thyroglobulin, we observed a marked discrepancy between initial rates of OH- release and iodination, inconsistent with the mechanism originally proposed for the iodination reaction. As a possible explanation for this kinetic discrepancy, we postulate that lactoperoxidase generates hypoiodous acid and that the latter is the active intermediate in the various reactions involving iodide.
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PMID:Mechanisms of thyroid peroxidase- and lactoperoxidase-catalyzed reactions involving iodide. 609 29

Stopped flow experiments were carried out with purified hog thyroid peroxidase (A413 nm/A280 nm = 0.42). It reacted with H2O2 to form Compound I with a rate constant of 7.8 X 10(6) M-1 s-1. Compound I was reduced to Compound II by endogeneous donor with a half-life of 0.36 s. Compound I was reduced by tyrosine directly to the ferric enzyme with a rate constant of 7.5 X 10(4) M-1 s-1. Tyrosine could also reduce Compound II to the ferric enzyme with a rate constant of 4.3 X 10(2) M-1 s-1. Methylmercaptoimidazole accelerated the conversion of Compound I to Compound II and reacted with Compound II to form an inactivated form, which was discernible spectrophotometrically. The reactions of thyroid peroxidase with methylmercaptoimidazole quite resembled those of lactoperoxidase, but occurred at higher speeds. The absorption spectra of thyroid peroxidase were similar to those of lactoperoxidase and intestinal peroxidase, but obviously different from those of metmyoglobin, horseradish peroxidase, and chloroperoxidase. Similarity and dissimilarity between thyroid peroxidase and lactoperoxidase are discussed.
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PMID:Reactions of purified hog thyroid peroxidase with H2O2, tyrosine, and methylmercaptoimidazole (goitrogen) in comparison with bovine lactoperoxidase. 617 24

We have investigated the mechanism by which the thioureylene drugs, 1-methyl-2-mercaptoimidazole (MMI) and 6-n-propylthiouracil (PTU), inactivate thyroid peroxidase (TPO). Our results indicate that inactivation of TPO by MMI and PTU involves a reaction between the drugs and the oxidized heme group produced by interaction between TPO and H2O2. This conclusion is supported by the following observations. First, addition of a low concentration of H2O2 to a solution of TPO shifted lambda max of the Soret band from 411 to 420 nm, reflecting the formation of an oxidized form of TPO (TPOox). Addition of MMI or PTU to TPOox produced a Soret spectrum that was significantly different from the spectrum of native TPO or TPOox, whereas addition of MMI or PTU to native TPO produced no significant change in the heme spectrum. Second, studies with radiolabeled MMI and PTU combined with simultaneous assays of enzyme activity (guaiacol assay) showed that firm binding of the drugs to TPO and inactivation of the enzyme occurred on addition of the drugs to TPOox. However, neither binding nor inactivation occurred on addition of the drugs to native TPO. Third, the presence of a low concentration of iodide prevented the shift in the Soret spectrum, the binding of labeled drug, and the loss of enzyme activity associated with the addition of thioureylene drugs to TPO + H2O2. Under these conditions we assume that the enzyme was present as TPO X Iox, a form in which the heme is present in the same reduced state as in native TPO. This would explain the protective action of iodide on the inactivation of TPOox by MMI and PTU.
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PMID:Mechanism of inactivation of thyroid peroxidase by thioureylene drugs. 618 57

It has been demonstrated that the H2O2/l ratio is a critical factor in the control of iodination and de-iodination of covalently bound tyrosyl residues in proteins and free iodotyrosines by peroxidase enzymes. This has been shown for myeloperoxidase (MPO) isolated from normal human polymorphonuclear lymphocytes in particular, and also for peroxidase of animal origin such as thyroid peroxidase (TPO) and lactoperoxidase (LPO). It has been shown that the H2O2/l ratio exerts a controlling influence on MPO-catalysed reactions of fully iodinated tyrosines, e.g. di-iodotyrosine, and of partially and completely iodinated thyronines such as thyroxine and tri-iodothyronine. Using an in vivo model system it has been shown that MPO catalyses the sequential events of iodination, iodine exchange and de-iodination of tyrosines and, furthermore, that all three reactions are influenced by the rate of H2O2 generation and the iodide concentration of the reaction medium. The action of MPO on iodothyronine substrates only affects de-iodination irrespective of whether the iodothyronine is partially iodinated, as in tri-iodothyronine, or completely iodinated, as in thyroxine. This MPO-catalysed de-iodination of thyroxine and tri-iodothyronine can also be regulated by the H2O2/l ratio. Moreover, the results show that MPO-catalysed iodine exchange can only occur in completely iodinated tyrosines such as di-iodotyrosine (DIT). Iodine exchange in partially iodinated tyrosines such as mono-iodotyrosine (MIT) or in iodothyronines (T3 and T4) cannot be catalysed by MPO irrespective of the H2O2/l ratio. These results introduce a new concept which may be important in understanding the control of thyroid activity in thyroid disease and the control of MPO activity in biological defence mechanisms in man.
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PMID:The control of peroxidase-catalysed iodination and de-iodination. 626 56

Thyroid peroxidase in involved in several steps of the biosynthesis of thyroid hormone utilizing H2O2: peroxidation of iodide to iodine, iodination of thyroglobulin (Tg) and coupling reaction leading to T4 and T3 formation. The peroxidase enzyme appears to be an heme protein containing a protoporphyrin IX, with binding sites for both iodide and tyrosine. Although the peroxidase is present in numerous cellular structure, iodination activity occurs primarily if not only at all, at the apical cell border. Lack of peroxidase activity or abnormal peroxidase has been described in isolated cases of congenital goiter with organification defect and a positive perchlorate test. However no change in enzymatic activity has been found in patients with Pendred's syndrome as compared to normal tissue. The deficiency of hormone synthesis observed in various benign diffuse thyroid disorders in certainly not due to a lack of peroxidase activity. In treated hyperthyroid patients, a high cellular activity is observed, especially at the apical cell border. In euthyroid patients with diffuse sporadic goiter, an increase of peroxidase activity is also observed. However, the cytochemical localization of the enzyme in goitrous thyroid gland shows that the peroxidase activity is mostly visualized around numerous lipoid structures; being concentrated in this particular site, the enzyme might preferentially oxidize lipids and consequently be less available for hormone synthesis. In euthyroid hot nodule, the peroxidase activity is normal. In cold nodule, a discrepancy between iodide oxidation and protein iodination has been found, suggesting that iodide peroxidation and iodination of tyrosine residues of Tg are two relatively independent processes although thyroid peroxidase catalyses both reactions. In contrast with the benign pathological conditions, the peroxidase activity is lower than normal in thyroid cancerous tissue.
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PMID:[Peroxidase and human thyroid hormone synthesis disorders (author's transl)]. 626 13

A NADPH-dependent H2O2 generating system associated with a thyroid particular fraction is described. H2O2 is measured by two different methods: iodination of NADPH itself when the system is supplemented with lactoperoxidase and [125I]iodide, and by the scopoletin method. It is shown that: H2O2 generation is inhibited by catalase and is dependent on NADPH or particulate protein concentration; radical scavengers of OH and of singlet oxygen have no effect while superoxide dismutase has only a marginal effect; disruption of the particular fraction by phospholipase A2 or digitonin treatment completely abolished H2O2 generation activity while thyroid peroxidase activity appears, suggesting different sites for the two activities in the membrane vesicles.
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PMID:NADPH-dependent H2O2 generation and peroxidase activity in thyroid particular fraction. 643 Jul 33

Ascaridole, an asymmetric monoterpene endoperoxide with anthelmintic properties, occurs as a major constituent (60-80%) in the volatile oil of American wormseed fruit (Chenopodium ambrosioides: Chenopodiaceae), and as a lesser component in the leaf pocket oil of the boldo tree (Peumus boldus: Monimiaceae). Determination of optical activity and chromatographic resolution of naturally occurring ascaridole, and several synthetic derivatives, showed that both wormseed and boldo produce ascaridole in racemic form. The biosynthesis of ascaridole from the conjugated, symmetrical diene alpha-terpinene (a major component of the oil from wormseed) was shown to be catalyzed by a soluble iodide peroxidase isolated from homogenates of C. ambrosioides fruit and leaves. The enzymatic synthesis of ascaridole was confirmed by capillary gas-liquid chromatography and mass spectrometry of the product, which was also shown to be racemic. Optimal enzymatic activity occurred at pH 4.0 in the presence of 2.5 mM H2O2 and 1 mM NaI. Soluble enzyme extracts were fractionated by gel filtration on both Sephacryl S-300 and Sephadex G-100, and were shown to consist of a high-molecular-weight peroxidase component (Mr greater than 1,000,000, 30% of total activity) and two other peroxidase species having apparent molecular weights of 62,000 and 45,000 (major component). Peroxidase activity was susceptible to proteolytic destruction only after periodate treatment, suggesting an association of the enzyme(s) with polysaccharide material. Ascaridole biosynthesis from alpha-terpinene was inhibited by cyanide, catalase, and reducing agents, but not by compounds that trap superoxide or quench singlet oxygen. A peroxide transfer reaction initiated by peroxidase-generated I+ is proposed for the conversion of alpha-terpinene to ascaridole.
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PMID:Biosynthesis of ascaridole: iodide peroxidase-catalyzed synthesis of a monoterpene endoperoxide in soluble extracts of Chenopodium ambrosioides fruit. 649 93

Mechanisms that have been proposed for peroxidase-catalyzed iodination require the utilization of 1 mol of H2O2 for organic binding of 1 mol of iodide. When we measured the stoichiometry of this reaction using thyroid peroxidase or lactoperoxidase at pH 7.0, we consistently obtained a ratio less than 1.0. This was shown to be attributable to catalase-like activity of these enzymes, resulting in unproductive cleavage of H2O2. This catalatic activity was completely iodide-dependent. To elucidate the mechanism of the iodide-dependent catalatic activity, the effects of various agents were investigated. The major observations may be summarized as follows: 1) The catalatic activity was inhibited in the presence of an iodine acceptor such as tyrosine. 2) The pseudohalide, SCN-, could not replace I- as a promoter of catalatic activity. 3) The inhibitory effects of the thioureylene drugs, methimazole and carbimazole, on the iodide-dependent catalatic activity were very similar to those reported previously for thyroid peroxidase-catalyzed iodination. 4) High concentrations of I- inhibited the catalatic activity of thyroid peroxidase and lactoperoxidase in a manner similar to that described previously for peroxidase-catalyzed iodination. On the basis of these observations and other findings, we have proposed a scheme which offers a possible explanation for iodide-dependent catalatic activity of thyroid peroxidase and lactoperoxidase. Compound I of the peroxidases is represented as EO, and oxidation of I- by EO is postulated to form enzyme-bound hypoiodite, represented in our scheme as [EOI]-. We suggest that the latter can react with H2O2 in a catalase-like reaction, with evolution of O2. We postulate further that the same form of oxidized iodine is also involved in iodination of tyrosine, oxidation of thioureylene drugs, and oxidation of I-, and that inhibition of catalatic activity by these agents occurs through competition with H2O2 for oxidized iodine.
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PMID:Mechanism of iodide-dependent catalatic activity of thyroid peroxidase and lactoperoxidase. 670 30

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