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)

A sibship of thirteen subjects whose parents were first cousins was studied for a defect in thyroid hormone synthesis. Five sibs were goitrous and had congenital hypothyroidism. All but one showed a positive perchlorate discharge test (PDT). Three other subjects were goitrous and euthyroid (one with a positive PDT), and the remaining five sibs were euthyroid with a presumably normal thyroid. However, an abnormally exaggerated TSH response to TRH was observed not only in the hypothyroid patients but also in six of the other subjects, indicating a decreased thyroid feedback at the pituitary level in the presence of a normal serum concentration of thyroid hormones. In two hypothyroid patients a normal serum T3, low serum T4 and a low reverse T3 were observed. Microscopic studies of thyroid tissue from three of the sibs disclosed marked cellular hyperplasia with no lymphocytic infiltration anywhere in the tissue. Peroxidase activity was determined on tissue from three sibs by three different assay procedures. It was within the normal range in one patient and was significantly elevated in the other two. There was no evidence for a qualitatively defective peroxidase. The defect in thyroid function in this family does not appear to involve a peroxidase deficiency. Thyroglobulin isolated from the thyroid glands of two of the goitrous, hypothyroid subjects was poorly iodinated but was judged to be normal by immunoreactive and ultracentrifugation procedures. Although the nature of the thyroid metabolic defect in this family was not elucidated, the evidence suggests a genetic defect, probably involving a recessive gene.
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PMID:Congenital goitre and hypothyroidism with impaired iodide organification and high thyroid peroxidase concentration. 48 12

Several steps of thyroid hormogenesis were studied on a subhyoid ectopic thyroid tissue in a case of compensated hypothyroidism with simultaneous sublingual and subhyoid ectopic thyroid. The patient, a 19-year-old girl, had normal values for serum T4, T3U and T3, and an elevated serum TSH level. The thyroidal 131I uptake was elevated both at 3 h and 24 h after oral 131I intake. No significant discharge of radioiodine was observed after perchlorate load. On the thyroid biopsy specimen, peroxidase activity was shown to be normal by both assays of guaiacol oxidizing and iodinating activity. Thyroglobulin was 19S and was normally iodinated in vitro with peroxidase. Iodine content of thyroglobulin was within the normal range. The mean percentage distribution of 131I administered 7 days prior to the biopsy showed no significant difference from the normal pattern. From these studies, no specific defects in thyroid hormogenesis could be detected in this case. It is suggested that abnormalities in thyroid function in this case are mainly due to insufficient functioning mass in the ectopic thyroid.
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PMID:Thyroid hormone formation in ectopic thyroid gland. A case study. 58 May 19

Thyroglobulin (TG) was localized in the endostyle of the anadromous sea lamprey, Petromyzon marinus L. by means of the unlabeled antibody peroxidase-antiperoxidase immunocytochemical method. TG was found localized on the apical surface and within the cytoplasm of type 2c and 3 cells and in some type 5 cells. By identifying the cells of the endostyle immunocytochemically it may be possible to study more readily the events of endostylar transformation during metamorphosis.
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PMID:Immunocytochemical localization of thyroglobulin in the endostyle of the anadromous sea lamprey, Petromyzon marinus L. 67 50

Free diiosotyrosine exerts two opposite effects on the reactions catalyzed by thyroid peroxidase, thyroglobulin iodination and thyroid hormone formation. 1. Inhibition of thyroglobulin iodination catalyzed by thyroid peroxidase was observed when free diiodotyrosine concentration was higher than 5 muM. This inhibition was competitive, suggesting that free diiodotyrosine interacts with the substrate site(s) of thyroid peroxidase. Free diiodotyrosine also competively inhibited iodide peroxidation to I2. 2. Free diiodotyrosine, when incubated with thyroid peroxidase in the absence of iodide was recovered unmodified; in the presence of iodide an exchange reaction was observed between the iodine atoms present in the diiodotyrosine molecule and iodide present in the medium. Using 14C-labelled diiodotyrosine, 14C-labelled non-iodinated products were also observed, showing that deiodination occurred as a minor degradation pathway. However, no monoiodo[14C]tyrosine or E114C]tyrosine were observed. Exchange reaction between free diiototyrosine and iodide is therefore direct and does not imply deiodination-iodination intermediary steps. Thyroglobulin inhibits diiodotyrosine-iodide exchange and vice versa, again suggesting competition for both reactions. These results support, by a different experimental approach, the two-site model for peroxidase previously described by us in this journal. 3. Free diiodotyrosine when present at a very low concentration, 0.05 muM, exerts a stimulatory effect on throid hormones synthesis. The relationship between diiodotyrosine concentration and thyroid hormone synthesis give an S-shaped curve, suggesting that free diiodotyrosine acts as a regulatory ligand for thyroid peroxidase. Evidence is also presented that free diiodotyrosine is not incorporated into thyroid hormones. Therefore, thyroid peroxidase catalyzes only intra-molecular coupling between iodotyrosine hormonogenic residues. 4. Finally, although no direct proof exists that these free diiodotyrosine effects upon thyroglobulin iodination and thyroid hormone synthesis are physiologically significant, such a possibility deserves further investigation.
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PMID:Free diiodotyrosine effects on protein iodination and thyroid hormone synthesis catalyzed by thyroid peroxidase. 114 35

Two patients (G2, G3) with iodine organification defect were studied. The first patient (G2), a 25-year-old women with no clinical hypothyroidism, had had her goiter for 10 years; 62% of the thyroidal iodine was released by perchlorate indicating iodine organification defect. The thyroid tissue obtained at thyroidectomy contained a normal concentration of thyroid peroxidase (I2 formation from I-) when tested after solubilization of the enzyme by trypsin and digitonin treatment of the particulate material. 1. The enzymatic activity (G2-TPO) behaved on DEAE cellulose chromatography very differently from those of hog (P-TPO) or another human goiter peroxidase (G1-TPO) (Pommier, et al., J Clin Endocrinol Metab 39: 69, 1974): the molarity of elution was 2M NaCl instead of 0.15 mM. 2. Both P-TPO and G2-TPO catalyzed iodide peroxidation (I- leads to I2) but the Km (iodide) value for G2-TPO was much lower (2.3 x 10(-2) M) when compared with that of P-TPO (3.7 x 10(-3) M) or G1-TPO (3.5 x 10(-3) M). In addition, the optimum pH for this reaction differed markedly (pH 6.1 instead of 7.9). 3. G2-TPO was poorly efficient in catalyzing the oxidation of gaiacol to tetragaiacol. 4. G2-TPO was unable to perform the iodination of non-iodinated goiter thyroglobulin whatever the pH and the iodide concentration. 5. Thyroglobulin from this goiter (G2) was almost not iodinated (0.0014%), i.e., 0.07 atoms iodine/mole thyroglobulin), and its total content in the gland was very low (0.3-4 g/1000 g wet tissue instead of 25 g). A clear discrepancy was thus shown between the euthyroid state of this patient and the total lack of iodinating activity of the isolated peroxidase. The second patient (G3), a 17-year-old man with clinical hypothyroidism, had had his goiter for 5 years. 100% of the thyroidal iodine was released by perchlorate indicating a complete iodine organification defect. The thyroid tissue obtained at thyroidectomy contained no peroxidase activity when tested before and after treatment of the particulate material by trypsin and digitonin and even in the presence of hematin. Thyroglobulin from this goiter, which was almost non-iodinated (0.0014%), was present in normal amounts in the gland (congruent to 25 g/1000 g).
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PMID:Thyroid iodine organification defects: a case with lack of thyroglobulin iodination and a case without any peroxidase activity. 126 32

Twenty medullary carcinomas of the thyroid gland were examined for the presence of immunoreactive calcitonin, thyroglobulin, glucagon, keratin, gastrin/CCK, carcinoembryonic antibody (CEA), insulin, serotonin, adreno-corticotropic hormone (ACTH), prostatic acid phosphatase, and somatostatin using the immunoperoxidase peroxidase-antiperoxidase technique. In addition, they were stained with mucicarmine, alcian blue/periodic acid-Schiff (PAS), Grimelius, Congo red, crystal violet, and Fontana-Masson stains. Calcitonin-immunoreactive cells were absent in one tumor and present in 19 tumors (95%). Thyroglobulin was present in seven tumors (35%). Twenty tumors contained CEA-immunoreactive cells (100%). Fourteen cases were immunoreactive to serotonin (70%) and 12 were positive for somatostatin (60%). Glucagon- and gastrin/CCK-immunoreactive cells were found in two cases each (10%). Four tumors (20%) contained ACTH-immunoreactive cells and three cases (15%) were positive for prostatic acid phosphatase. Five cases (25%) contained keratin-immunoreactive cells. One case was immunoreactive to insulin (5%). Grimelius-positive cells were present in 19 of the cases (95%). Mucin-containing cells were present in 65% of the cases. The validity of the immunocytochemical localizations was tested by specific absorption of each antibody with the corresponding antigen. The demonstration of immunoreactivity for multiple antigens in each of the 20 cases suggests that the origin of medullary thyroid carcinomas is from a neuroendocrine cell potentially capable of producing numerous hormone substances. In addition, as the neoplastic cells in 35% of the tumors contained hormonal substances as well as thyroglobulin, it is suggested that papillary or follicular tumors mixed with a neuroendocrine component exist more commonly than previously suspected. Finally, psammoma bodies might be present in pure medullary carcinoma of the thyroid gland.
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PMID:Medullary carcinoma of the thyroid gland. Clinical, pathological, and immunohistochemical features with review of the literature. 241 97

Thyroglobulin iodination and thyroxine synthesis in vitro require the presence of peroxidase, H2O2 and iodide. H2O2 is usually continuously generated by glucose oxidase (GO) and glucose. The aim of this study was to investigate whether the two enzymes could possibly be inactivated by a particular concentration of H2O2 or iodide present during incubation. The results revealed that both enzymes were indeed inactivated under two distinct conditions: Lactoperoxidase and thyroid peroxidase were inactivated by modest concentrations of H2O2 accumulating during incubation. Glucose oxidase was inactivated by an oxidized species of iodine or singlet oxygen produced in the catalytic cycle. The results may explain some hitherto unsolved discrepancies between different iodination procedures. Moreover they may have an impact on the regulation of in vivo thyroglobulin iodination and hormone synthesis.
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PMID:Inactivation of peroxidase and glucose oxidase by H2O2 and iodide during in vitro thyroglobulin iodination. 301 6

The coupling of iodotyrosine (coupling reaction) is one of the least studied in the formation of thyroid hormone, particularly in human thyroid diseases. This paper describes a method of measuring iodotyrosine coupling catalyzed by human thyroid peroxidase (TPO) in vitro. There were two important requirements to demonstrate the coupling reaction: 1) thyroglobulin with a low thyroid hormone content, and 2) partially purified TPO. Thyroglobulin with low thyroid hormone content was obtained from Grave's and follicular adenoma tissues after propylthiouracil (PTU) therapy and L-T4 therapy, respectively. TPO was prepared from Graves' thyroid by solubilizing the 100,000 X g pellet of thyroid homogenate with sodium deoxycholate and trypsin, followed by Sephacryl S-300 gel filtration. Before the coupling reaction, thyroglobulin was iodinated with chloramine-T and potassium iodide, followed by dialysis. The coupling reaction was carried out by incubating newly iodinated thyroglobulin with TPO, diiodotyrosine, a coupling stimulator, and a H2O2-generating system (glucose and glucose oxidase) for 20 min at 37 C. After thyroglobulin was digested with Pronase, the thyroid hormone content of the thyroid digest was measured by RIA. Coupling activity was measured by the amount of newly formed T3 (nanograms of T3 per mg thyroglobulin). The time course of coupling reaction showed a progressive increase in coupling activity up to 30 min, and the reaction was temperature and pH dependent, with a pH optimum of 7.0. Coupling activity in the presence of H2O2 and TPO was 43 +/- 5.0 ng T3/mg thyroglobulin (mean +/- SD of triplicate samples), and addition of diiodotyrosine to the H2O2-TPO system caused a nearly 3-fold increase in coupling activity. This method has potential utilization for measurement of peroxidase coupling activity, since there was a linear relationship between the measured coupling activity and the amount of added TPO when the TPO concentration was over 3 micrograms/300 microliter. Methimazole (MMI) and PTU had similar potencies in inhibiting the TPO-catalyzed coupling reaction, whereas MMI was distinctly more potent than PTU as an inhibitor of TPO-mediated iodination in vitro. The different potencies of MMI in the two reactions suggest that different inhibitory mechanisms may be involved in iodination and coupling. The reducing agent, sodium metabisulfite, was also found to be a more potent inhibitor of the TPO-mediated coupling reaction than of the TPO-mediated iodination reaction. The method of iodotyrosine coupling described here may be useful to investigate the coupling step of thyroid hormone formation in human thyroid diseases.
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PMID:Coupling of iodotyrosine catalyzed by human thyroid peroxidase in vitro. 383 97

Primary cultures of ovine thyroid cells were induced to differentiate by addition of thyrotropin (TSH). This was demonstrated as an accumulation of 2 thyroid-specific proteins, thyroglobulin and thyroid peroxidase, using immunofluorescent staining methods and immunoprecipitation of biosynthetically labeled cultures. As an additional measure of differentiation, cells exhibited a morphological response to TSH and regained the ability to incorporate radioactive iodide. Epidermal growth factor (EGF) markedly inhibited differentiation when added together with TSH. Thyroglobulin synthesis was reduced to low levels and peroxidase synthesis was reduced to levels that were undetectable by the methods used. Morphological changes in response to TSH were also diminished by EGF. The antagonistic interaction between TSH and EGF in regulating differentiation in cultured thyroid cells may reflect the type of control that exists in vivo.
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PMID:Epidermal growth factor inhibits thyrotropin-mediated synthesis of tissue-specific proteins in cultured ovine thyroid cells. 387 50

The kinetics of iodination and oxidation of hog thyroglobulin were studied with purified hog thyroid peroxidase and the results were compared with the reactions of free tyrosine. From Lineweaver-Burk plots and on the basis of a value of 0.83 for delta epsilon mM at 289 nm/iodine atom incorporated, the rate constant for transfer of an assumed enzyme-bound iodinium cation to thyroglobulin was estimated to be 6.7 X 10(7) and 2.3 X 10(7) M-1 s-1 in native (iodine content = 1.0%) and more iodinated (iodine content = 1.2%) thyroglobulins, respectively. This iodine-transferring reaction was stimulated by iodothyronines, similarly as observed in the reaction with free tyrosine. The iodination of thyroglobulin was inhibited by GSH, the inhibition being competitive with thyroglobulin. Thyroglobulin was oxidized in the presence of a thyroid peroxidase system without giving any appreciable change in absorbance around 300 nm. From stopped flow data, the oxidation was concluded to occur by way of two-electron transfer and the rate constant for the reaction of thyroid peroxidase Compound I with thyroglobulin was estimated to be 1.0 X 10(7) M-1 s-1. The stopped flow kinetic pattern was similar to that observed on the reaction with free tyrosine and monoiodotyrosine. About 6 mol of hydrogen peroxide were consumed per mol of thyroglobulin. Thyroid peroxidase catalyzed thyroglobulin-mediated oxidation of GSH, but lactoperoxidase did not.
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PMID:Iodination and oxidation of thyroglobulin catalyzed by thyroid peroxidase. 670 40

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