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)

Thyroid peroxidase was isolated from porcine thyroids by two methods. Limited trypsin proteolysis was employed to obtain a cleaved enzyme, and affinity chromatography was used to isolate intact thyroid peroxidase. Enzyme isolated by both methods was used in the examination of the heme site of native thyroid peroxidase and its complexes by EPR spectroscopy. Intact thyroid peroxidase showed a homogeneous high-spin EPR signal with axial symmetry, in contrast to the rhombic EPR signal of native lactoperoxidase. Reaction of cyanide or azide ion with native thyroid peroxidase resulted in the loss of the axial EPR signal within several hours. The EPR spectroscopy of the nitrosyl adduct of ferrous thyroid peroxidase exhibited a three-line hyperfine splitting pattern and indicated that the heme-ligand structure of thyroid peroxidase is significantly different from that of lactoperoxidase.
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PMID:Electron paramagnetic resonance spectroscopy of thyroid peroxidase. 283 83

Human myeloperoxidase and human thyroid peroxidase nucleotide and amino acid sequences were compared. The global similarities of the nucleotide and amino acid sequences are 46% and 44%, respectively. These similarities are most evident within the coding sequence, especially that encoding the myeloperoxidase functional subunits. These results clearly indicate that myeloperoxidase and thyroid peroxidase are members of the same gene family and diverged from a common ancestral gene. The residues at 416 in myeloperoxidase and 407 in thyroid peroxidase were estimated as possible candidates for the proximal histidine residues that link to the iron centers of the enzymes. The primary structures around these histidine residues were compared with those of other known peroxidases. The similarity in this region between the two animal peroxidases (amino acid 396-418 in thyroid peroxidase and 405-427 in myeloperoxidase) is 74%; however, those between the animal peroxidases and other yeast and plant peroxidases are not significantly high, although several conserved features have been observed. The possible location of the distal histidine residues in myeloperoxidase and thyroid peroxidase amino acid sequences are also discussed.
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PMID:Human myeloperoxidase and thyroid peroxidase, two enzymes with separate and distinct physiological functions, are evolutionarily related members of the same gene family. 284 Jun 55

In vitro production of antithyroid microsomal antibody (AMA) and antithyroid peroxidase antibody (APA) by peripheral blood lymphocytes from patients with autoimmune thyroid disease (AITD) has been studied and compared, in view of the evidence for identity of the two differently measured antibodies. Peripheral non-T cells (2 x 10(5)) and autologous CD4 (helper/inducer) cells (2 x 10(5)) from patients with positive serum AMA were cultured for 7 days with pokeweed mitogen (PWM). B cells secreting AMA or APA were detected by the enzyme-linked immunosorbent assay (ELISA) spot assay. AMA or APA in the culture supernatants of these cells was also measured by ELISA. There was a significant correlation between the number of AMA- (IgG class) secreting cells and APA- (IgG class) secreting cells (r = 0.89 p less than 0.001). There was also a significant correlation between AMA- and APA-ELISA indices (r = 0.86, p less than 0.001). Furthermore, the number of AMA- or APA-secreting cells significantly correlated with AMA or APA secreted in the culture supernatants (r = 0.91, r = 0.92), respectively. These data show that peripheral blood lymphocytes from patients with AITD were able to produce antibodies against thyroid peroxidase (TPO) in vitro, as well as antibodies against thyroid microsomal antigen, after PWM stimulation. The significant correlation between in vitro AMA versus APA production, or the number of AMA- versus APA-secreting cells, accords with the evidence that TPO is identical to, or at least the major antigenic protein component of, thyroid microsomal antigen.
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PMID:Comparison of measurements of in vitro production of antithyroid microsomal antibody versus antithyroid peroxidase antibody. 285 41

The ultrastructural appearance of colloid vacuoles, considered to be a typical sign of hyperactivity in the human thyroid gland, was studied in human thyroid tissue transplanted to nude mice and in human thyroid tissue fixed directly after surgical removal in patients with thyrotoxicosis. Transplanted normal thyroid tissue and toxic diffuse goiter (TDG) tissue was fixed by vascular perfusion with glutaraldehyde 5 or 12 weeks after transplantation. Light microscopic quantification showed that daily injections for 2 weeks of a gamma globulin fraction of patient sera containing thyroid-stimulating immunoglobulins (TSI) greatly increased the number of colloid vacuoles in both types of transplants. The vacuoles were mainly located in the periphery of the follicle lumen, giving the colloid a scalloped appearance. Electron microscopy of TSI-exposed tissue revealed, in addition to colloid vacuoles, the presence of large amounts of membrane material in the follicle lumen. Only sparse amounts of intraluminal membrane material were present in controls. The colloid vacuoles were almost invariably associated with such membrane material, which lined the border between the vacuole and the surrounding colloid. The intraluminal material consisted of spherical and elongated formations, each structure limited by a triple-layered membrane and often containing a dense interior. The elongated structures were often of the same dimensions as microvilli. The apical surface of follicle cells in TSI-exposed tissue expressed numerous microvilli, of which many showed a similar dense interior as the intraluminal membrane structures. The intraluminal membranes frequently showed, like the apical plasma membrane of the follicle cells, a positive reaction for peroxidase. Organelles, such as mitochondria, lysosomes or rough endoplasmic reticulum, were not encountered among the intraluminal membrane structures. These observations indicate that the intraluminal membrane material is derived from the apical plasma membrane of the follicle cells, presumably by shedding of microvilli. A similar association between colloid vacuoles and membrane material was also found in thyroid tissue from patients with thyrotoxicosis fixed directly at operation. It is suggested that the presence of membrane material in the follicle lumen precipitates the formation of colloid vacuoles in hyperactive thyroid tissue. The possible involvement of intraluminal membrane material in the development of microsomal autoantibodies in Graves' disease, i.e. exposure and presentation of thyroid microsomal antigen (identical to thyroperoxidase) to the immune system, is discussed.
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PMID:Plasma membrane shedding and colloid vacuoles in hyperactive human thyroid tissue. 290 7

Previous studies have shown that phenylbutazone, another pyrazolone, inhibits thyroid peroxidase activity and interferes with iodide organification. We have developed "in vitro" studies with rat particulated peroxidase and lactoperoxidase (LPO) to study the effects of dipyrone upon thyroid peroxidase and to determine the type of inhibition. The 3-monoiodothyrosine (MIT) and 3,5-diiodothyrosine (DIT) synthesis was markedly affected by 6 X 10(-4) M dipyrone with inhibitions of 59% and 30% respectively. No difference was observed with lower concentrations. Inhibition of peroxidase activity (Triiodide assay) was found when crude rat peroxidase preparations and LPO were incubated with dipyrone in concentrations ranging from 10(-3) M to 10(-8) M, with a Ki of 2.5 X 10(-5) M and 4 X 10(-5) M respectively. Guaiacol peroxidation was scarcely affected by the action of the drug; 10(-3) M produced inhibition of 50%. Line weaver-Burk: plots were used to investigate the inhibition of LPO activity by dipyrone. The inhibition by the drug was competitive with the iodide. We may conclude that dipyrone and other drugs of the pyrazolone group act upon peroxidase activity "in vitro", by an inhibition of competitive type and in presence of iodide.
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PMID:Inhibitory action of dipyrone on rat thyroid peroxidase and lactoperoxidase activities. 293 10

Thyroid microsomal antigen and peroxidase (TPO) have a close intracellular anatomical relationship, especially in exocytotic vesicles. We considered that antibodies to microsomal antigen might react with TPO and therefore looked for the presence of antibodies against TPO in the serum of patients with autoimmune thyroid disease (AITD). TPO was prepared from Graves' thyroid glands, solubilized by n-octyl glucoside, and its activity was assayed by the guaiacol method. Control sera and sera with a positive microsomal hemagglutination test (MCHA(+) ) were assayed for their ability to precipitate TPO activity by incubation of sera with TPO and protein A. We identified MCHA(+) sera which caused precipitation of TPO activity, and the extent of precipitation was related to the amount of serum added. A significant correlation was present between this anti-peroxidase activity and microsomal antibodies titers, measured by a micro-ELISA method. Affinity columns prepared from immunoglobulins of MCHA(+) sera, coupled to Reacti-Gel (6X), bound TPO activity, whereas using control IgG the recovery in the unbound fraction was high. These data provide evidence of antibodies against thyroid peroxidase in the serum of patients with AITD and suggest a close link between microsomal antigen and thyroid peroxidase.
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PMID:Anti-thyroid peroxidase antibody in patients with autoimmune thyroid disease: possible identity with anti-microsomal antibody. 299 29

A catalytic intermediate, Compound II of peroxidase was detected spectrophotometrically in thyroid microsomes. From comparison with the spectral data on purified thyroid peroxidase, the content of the peroxidase was estimated to be 0.019 nmol per mg of the microsomal protein, being about one-eighth of the amount of cytochrome b5. It was concluded that thyroid peroxidase exhibits the same peroxidase activity for guaiacol or ascorbate in the free and the microsome-bound forms.
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PMID:Detection of a catalytic intermediate of peroxidase in hog thyroid microsomes. 299 22

Unlike lactoperoxidase and horseradish peroxidase, thyroid peroxidase catalyzed the oxidation of hydroquinone mostly by way of 2-electron transfer. This conclusion could be derived from three independent experiments: ESR measurements of p-benzosemiquinone, trapping the unpaired electron by cytochrome c, and spectrophotometric analysis of catalytic intermediates of the enzymes. The 1-electron flux for hydroquinone oxidation was found to be 15-19% in the reaction of thyroid peroxidase, while it was nearly 100% in the reactions of lactoperoxidase and horseradish peroxidase. From the spectrophotometric analysis of the catalytic intermediates of enzyme, it was suggested that the mechanism of oxidation catalyzed by thyroid peroxidase changes from a 2-electron to a 1-electron type as the substituents at 2- and 6-positions of phenol become bulky or heavy. On the other hand, the mechanism was invariably a 1-electron type when the oxidation of phenols was catalyzed by lactoperoxidase or horseradish peroxidase. These three peroxidases all catalyzed 1-electron oxidation of ascorbate.
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PMID:Thyroid peroxidase selects the mechanism of either 1- or 2-electron oxidation of phenols, depending on their substituents. 299 69

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

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


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