Gene/Protein Disease Symptom Drug Enzyme Compound
Pivot Concepts:   Target Concepts:
Query: EC:1.11.1.7 (peroxidase)
 65,474 document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)

Neurological endemic cretinism is highly prevalent in severe endemic goiter areas. Often associated to euthyroid goiter, it is probably related to iodine deficiency. However the exact pathogenetic mechanism is yet unclear. We report the biochemical study of thyroid tissue obtained from a 26 year-old female cretin with a grade III multinodular goiter, neurological signs and euthyroidism. After surgery, thyroid tissue was analysed: iodoproteins where characterized by gel filtration, electrophoresis, sedimentation coefficient and antigenicity. Iodoalbumin was predominant while thyroglobulin was quantitatively reduced and poorly iodinated. In vitro, iodination with hog thyroid peroxidase was normal. There was no difference in peroxidase affinity for iodide in the oxidation reaction but a significantly reduced ability to iodinate in vitro thyroglobulin and free tyrosine. Oxidation of acetyltyrosilamide into bityrosine was also markedly reduced. These abnormal findings are known to occur in sporadic cases with or without hypothyroidism. The neurological defects could be linked to transient hypothyroidism during the critical period of nervous system maturation, however a role of iodine deficiency per se cannot be ruled out.
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PMID:Association of peroxidase enzyme defect and low thyroglobulin content in a case of endemic cretinism. 403 89

Endogenous peroxidase activity in rat thyroid follicular cells is demonstrated cytochemically. Following perfusion fixation of the thyroid gland, small blocks of tissue are incubated in a medium containing substrate for peroxidase, before being postfixed in osmium tetroxide, and processed for electron microscopy. Peroxidase activity is found in thyroid follicular cells in the following sites: (a) the perinuclear cisternae, (b) the cisternae of the endoplasmic reticulum, (c) the inner few lamellae of the Golgi complex, (d) within vesicles, particularly those found apically, and (e) associated with the external surfaces of the microvilli that project apically from the cell into the colloid. In keeping with the radioautographic evidence of others and the postulated role of thyroid peroxidase in iodination, it is suggested that the microvillous apical cell border is the major site where iodination occurs. However, that apical vesicles also play a role in iodination cannot be excluded. The in vitro effect of cyanide, aminotriazole, and thiourea is also discussed.
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PMID:Cytochemical localization of endogenous peroxidase in thyroid follicular cells. 419 69

Iodination within the thyroid follicle is intimately associated with a thyroid peroxidase. In order to locate the in vivo site of iodination, the initial cytochemical appearance of this enzyme has been determined in fetal rat thyroid and its presence correlated with the onset of iodinated thyroglobulin synthesis. Peroxidase first appears in follicular cells during the 18th day of gestation. It is seen first in the perinuclear cisternae, the cisternae of the endoplasmic reticulum, and within the inner few Golgi lamellae. These organelles presumably represent sites of peroxidase synthesis. During the 19th and 20th days of gestation, there is a tremendous increase in peroxidase activity. In addition to the stained sites described, there are now many peroxidase-positive apical vesicles in the follicular cells. Newly forming follicles stain most conspicuously for peroxidase, the reaction product being heavily concentrated at the external surfaces of apical microvilli and in the adjacent colloid. Iodinated thyroglobulin becomes biochemically detectable in thyroids during the 19th day of gestation and increases greatly during the 20th day. The parallel rise in peroxidase staining that just precedes, and overlaps, the rise in iodinated thyroglobulin, suggests that apical vesicles and the apical cell membrane are the major sites of iodination within the thyroid follicle.
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PMID:Appearance and function of endogenous peroxidase in fetal rat thyroid. 432 19

The enzyme lactoperoxidase (iodide:hydrogen-peroxide oxidoreductase, EC 1.11.1.8) was used to iodinate ((125)I) accessible proteins on membranes of intact virally transformed and untransformed cells. A number of labeled bands of proteins were detected by acrylamide gel electrophoresis. A heavily labeled band with a molecular weight of approximately 250,000 daltons was found in all untransformed cells but was absent from transformed cells. When Coomassie-blue-stained membrane preparations were compared, a band was seen in normal cells which co-migrated with the lactoperoxidase-labeled band. In transformed cell membranes, three discrete bands were present in the same position. Thus, the expression of this protein may be altered when cells are in the transformed state.
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PMID:A comparison of membrane proteins of normal and transformed cells by lactoperoxidase labeling. 436 Sep 46

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

In the presence of iodide, hydrogen peroxide and lactoperoxidase, docosahexaenoic acid (22:6 omega 3) was converted into iodinated compounds. The major product was identified as 5-iodo-4-hydroxy-7, 10, 13, 16, 19-docosapentaenoic acid, gamma-lactone, on the basis of 125 I incorporation, mass spectrometry, chemical modifications and proton nuclear magnetic resonance spectroscopy. Iodolactonization of docosahexaenoic acid occurred in the rat thyroid in vitro and was inhibited by the peroxidase inhibit or methimazole. These data indicate that formation of an idolactone constitutes one pathway of docosahexaenoic acid metabolism which could be expressed in tissues containing an iodide peroxidase.
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PMID:Iodination of docosahexaenoic acid by lactoperoxidase and thyroid gland in vitro: formation of an lodolactone. 615 54

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

The antithyroid drugs propylthiouracil and methimazole exert their effects on the thyroid gland by inhibiting thyroid peroxidase. In addition to this effect, these drugs have been reported to inhibit prostaglandin production in both the thyroid gland and the kidney. The purpose of our studies was to evaluate the mechanism of the effects of these drugs on prostaglandin production. Both propylthiouracil and methimazole reversibly inhibited prostaglandin E2 production in both inner medullary slices and isolated renal papillary collecting tubule cells. The inhibition of arachidonic acid-induced increases in PGE2 production indicated that the effects of methimazole and propylthiouracil were on the enzyme complex prostaglandin H synthase, and not on the phospholipase mechanisms responsible for the release of arachidonic acid from tissue phospholipids. Propylthiouracil inhibited both arachidonic acid and hydrogen peroxide-dependent binding of 14C-N-[4-(5-nitro-2-furyl)-2-thiazolyl]formamide to protein, indicating that the effect of propylthiouracil is on the hydroperoxidase and not on the cyclooxygenase component of prostaglandin H synthase. Our data also indicate the potential of the antithyroid drugs for inhibition of metabolism of drugs and xenobiotics by prostaglandin H synthase. Metabolism of both methimazole and propylthiouracil by the hydroperoxidase component of prostaglandin H synthase was demonstrated. It is proposed that this interaction with the hydroperoxidase component of prostaglandin H synthase is at least in part the mechanism by which propylthiouracil and methimazole inhibit prostaglandin production. The inhibition of tissue peroxidase provides these agents with the capability to prevent the peroxidatic metabolism of drugs and xenobiotics.
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PMID:Antithyroid drugs interact with renal medullary prostaglandin H synthase. 620 11

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


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