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)

Despite their importance, little is known about the mechanism of idiosyncratic reactions, many such reactions have characteristics that suggest an immune-mediated mechanism. This is particularly true of drug-induced lupus which is an autoimmune syndrome. Certain functional groups are associated with a high incidence of idiosyncratic reactions, probably reflecting the ease with which they are metabolized to reactive metabolites. Although the liver is the principal organ of drug metabolism, most reactive metabolites generated in the liver would not reach other organs in significant concentrations. Because of the function of leukocytes, especially monocytes, in the induction of an immune response, the generation of reactive metabolites by monocytes would seem likely to lead to an immune-mediated adverse reaction. We have found that drugs that are associated with drug-induced lupus are oxidized to reactive metabolites by the myeloperoxidase system of monocytes. The initial step in drug-induced lupus could be haptenization of a protein on the surface of monocytes by these reactive metabolites. Other types of idiosyncratic drug reactions may involve a similar mechanism and the same drugs that induce lupus are usually associated with a high incidence of other types of idiosyncratic reactions. for example, procainamide, which causes the highest incidence of drug-induced lupus, also causes a relatively high incidence of agranulocytosis. Even some of the therapeutic effects of drugs may involve the production of reactive metabolites by myeloperoxidase or thyroid peroxidase.
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PMID:Metabolism of drugs by activated leukocytes: implications for drug-induced lupus and other drug hypersensitivity reactions. 206 78

Iodothyronines induced catalatic (H2O2-decomposing) activity of thyroid peroxidase and lactoperoxidase, the effect increasing in the order of thyroxine (T4) greater than triiodothyronine (T3) greater than diiodothyronine (T2). The iodothyronines served as electron donors in the peroxidase reactions, and during the reactions the catalytic intermediate of thyroid peroxidase was confirmed to be Compound II for T4 and Compound I for T3 and T2 and from the Soret absorption spectra obtained by stopped-flow measurements. Rate constants for the reactions between T4 and Compound II, T3 and Compound I, and T2 and Compound I were estimated at 1.9 x 10(5), 1.3 x 10(6), and 7.1 x 10(5) M-1.s-1, respectively. Unlike the case of thyroid peroxidase, the catalytic intermediate of lactoperoxidase observed during the oxidation of iodothyronines was invariably Compound II. From these and other data it was concluded that thyroid peroxidase catalyzed one-electron oxidation of T4 and two-electron oxidations of T2 and T3 while lactoperoxidase catalyzed exclusively one-electron oxidation of the iodothyronines. Iodide was released during the enzymatic oxidation of iodothyronines, irrespective of the mechanism of one-electron and two-electron oxidations. The amount of released iodide increased in the order of T4 greater than T3 greater than T2. The iodothyronines-induced catalatic activity of these peroxidases was ascribable to the release of iodide, but it was also found that the iodide-enhanced catalatic activity was stimulated by iodothyronines. In this case the effect of iodothyronines was greater in the order of T2 greater than T3 greater than T4, which was consistent with the order of iodothyronine activation for the iodinium cation transfer from enzyme to acceptor.
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PMID:Iodothyronine-induced catalatic activity of thyroid peroxidase. 208 35

Acetylation of Ser-530 of sheep prostaglandin endoperoxide (PGG/H) synthase by aspirin causes irreversible inactivation of the cyclooxygenase activity of the enzyme. To determine the catalytic function of the hydroxyl group of Ser-530, we used site-directed mutagenesis to replace Ser-530 with an alanine. Cos-1 cells transfected with expression vectors containing the native (Ser-530) or mutant (Ala-530) cDNAs for sheep PGG/H synthase expressed comparable cyclooxygenase and hydroperoxidase activities. Km values for arachidonate (8 microM) and ID50 values for reversible inhibition by the cyclooxygenase inhibitors, flurbiprofen (5 microM), flufenamate (20 microM), and aspirin (20 mM), were also the same for both native and mutant PGG/H synthases; however, only the native enzyme was irreversibly inactivated by aspirin. Thus, the "active site" Ser-530 of PGG/H synthase is not essential for catalysis or substrate binding. Apparently, acetylation of native PGG/H synthase by aspirin introduces a bulky sidechain at position 530 which interferes with arachidonate binding. In related studies, a cDNA for mouse PGG/H synthase was cloned and sequenced. A sequence of 35 residues with Ser-530 at the midpoint was identical in the two proteins. Thus, Ser-530 does lie in a highly conserved region, probably involved in cyclooxygenase catalysis. Sequence comparisons of mouse and sheep PGG/H synthase also provided information about the heme-binding site of the enzyme. The sheep HYPR sequence (residues 274-277), which had been proposed to form a portion of the distal heme-binding site, is not conserved in the mouse PGG/H synthase, suggesting that this region is not the distal heme-binding site. One sequence, TIWLREHNRV (residues 303-312 of the sheep enzyme), is very closely related to the sequence TLW(L)LREHNRL common to thyroid peroxidase and myeloperoxidase. The histidine in this latter sequence is the putative axial heme ligand of these peroxidases. We suggest that the histidine (His-309) of sheep PGG/H synthase sequence is the axial heme ligand of this enzyme.
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PMID:The aspirin and heme-binding sites of ovine and murine prostaglandin endoperoxide synthases. 210 69

Our studies are designed to determine which amino acid residues are involved in catalyzing the cyclooxygenase and hydroperoxidase activities of prostaglandin endoperoxide (PGG/H) synthase. We have deduced from complementary (c)DNAs the amino acid sequences of the sheep and mouse PGG/H synthases, and a portion of the human PGG/H synthase. These enzymes have amino acid sequences which are about 90% identical. Sequence similarities with putative heme binding regions of myeloperoxidase and thyroid peroxidase suggest that the sequence TI(L)WLREHNRV of PGG/H synthase contains the histidine (His309) which is the proximal heme ligand; the distal heme ligand may be His226 which is found in the sequence 222-KALGH-226. Using site-directed mutagenesis, we have replaced Ser530, the serine residue which is acetylated by aspirin, with Ala530 and with Asn530; the Ala530 mutant has both cyclooxygenase and hydroperoxidase activity, while the Asn530 mutant lacks cyclooxygenase activity but retains hydroperoxidase activity. These results establish that the hydroxyl group of Ser530 is not essential for catalysis or substrate binding and suggest that a bulky group at position 530, such as that introduced by aspirin acetylation, prevents arachidonate binding to the cyclooxygenase active site. Finally, we have found that tetranitromethane causes irreversible inactivation of cyclooxygenase activity and that the enzyme is protected from inactivation when ibuprofen is included in the reaction mixture. These results suggest that there is an essential tyrosine at the active site of PGG/H synthase.
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PMID:Structure-function relationships in sheep, mouse, and human prostaglandin endoperoxide G/H synthases. 214 87

This review presents a unifying hypothesis that provides a connection between several types of hypersensitivity reactions associated with several types of drugs and explains some of the therapeutic effects (antiinflammatory activity and antithyroid effects) of these same drugs. This hypothesis centers on the oxidation of these drugs to chemically reactive metabolites by peroxidases. The drugs of interest have functional groups that are easily oxidized. The major peroxidase involved in this hypothesis is MPO because of its critical location in leukocytes which play a key role in the function of the immune system. However, thyroid peroxidase can probably also oxidize many of the same drugs to reactive metabolites, and this may be responsible for the thyroid autoimmunity observed in connection with some hypersensitivity reactions. Peroxidases have also been described in the skin and in platelets, and their presence may be responsible for the high incidence of skin reactions in the hypersensitivity response and the occurrence of immune-mediated thrombocytopenia, respectively. Involvement of other peroxidases, such as prostaglandin peroxidase, may also be important for antiinflammatory effects of drugs. In addition, leukocytes contain prostaglandin synthetase, and the activation of leukocytes leads to the release of arachidonic acid and the production of prostaglandins. This process may also lead to the metabolism of drugs to reactive metabolites. In studies of the metabolism of procainamide and dapsone, aspirin and indomethacin did not inhibit the formation of the hydroxylamine by neutrophils and mononuclear leukocytes. This is evidence against the involvement of prostaglandin synthetase in these oxidation; however, preliminary studies with other drugs suggest that prostaglandin synthetase may contribute to the metabolism of some drugs by leukocytes. Furthermore, the metabolism of phenylbutazone, phenytoin, and tenoxicam, as well as our preliminary work with other drugs such as carbamazepine, suggests that the range of drugs that are metabolized to reactive metabolites by peroxidases may be broader than initially suspected. There are several other drugs that do not fit into the functional group classes covered in this review but have similar properties. A good example is alpha-methyldopa, which is associated with drug-induced lupus, immune-mediated hemolytic anemia, and other hypersensitivity reactions. Such drugs may also be metabolized to reactive metabolites by peroxidases. Another aspect of the hypothesis is that an infection, or other inflammatory condition, may be an important risk factor for a hypersensitivity reaction because such a stimulus leads to activation of leukocytes which can lead to formation of reactive metabolites from certain drugs.(ABSTRACT TRUNCATED AT 400 WORDS)
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PMID:Drug metabolism by leukocytes and its role in drug-induced lupus and other idiosyncratic drug reactions. 217 25

Ultrastructural localization and intensity of endogenous thyroid peroxidase (TPO) in Hashimoto's thyroiditis were examined in relation to the serum thyroid hormone level, thyroid-stimulating hormone (TSH) concentration and anti-thyroid autoantibody titer. In Hashimoto's thyroiditis, TPO activity on the microvilli of follicular cells was more intense than that of normal thyroid tissue, but the intensity of the intracytoplasmic peroxidase reaction was generally weaker than that of Graves' or normal thyroid tissue. Microvillar TPO reaction products were positive in all thyroid follicular cells in patients with increased TSH levels, but no TPO activity was observed on the microvilli of patients with normal or low TSH levels, irrespective of their histological type or serum anti-microsomal antibody titer. It is suggested that TPO activity on the surface of microvilli of thyroid follicular cells in Hashimoto's thyroid gland is modulated by thyrotropin but is not affected by anti-thyroid autoantibodies.
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PMID:Ultrastructural localization of endogenous peroxidase activity in Hashimoto's thyroiditis. 233 Aug 43

Pools of sera from patients with Graves' disease or Hashimoto's thyroiditis highly inhibit the binding to human thyroid membranes of one of 19 monoclonal antibodies raised against preparations of human thyroid membranes. This monoclonal antibody reacts with human and bovine thyroid peroxidase and bovine lactoperoxidase but not with human hemoglobin, cytochrome c and other related molecules. These results indicate that the thyroid peroxidase and the microsomal antigen are antigenically related. These data taken together with those from other groups, highly suggest that thyroid peroxidase is the microsomal antigen involved in autoimmune thyroid diseases.
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PMID:[Antigenic relation between thyroid peroxidase and the microsomal antigen implicated in auto-immune diseases of the thyroid]. 241 85

We have characterized thyroid microsomal antigen (M-Ag) prepared from Graves' and normal thyroid tissues using 100,000 x g thyroid membrane fractions in enzyme-linked immunosorbent assays with pooled polyclonal human sera containing high titers of antibody to M-Ag. A ten-fold parallel increase in dose inhibition potencies occurred with M-Ag preparations from Graves' as compared to normal thyroid tissue. The M-Ag preparations were further evaluated by SDS-polyacrylamide gel electrophoresis and proteins visualized by Western blot using high titer microsomal antibody (M-Ab) sera (n = 2) devoid of thyroglobulin antibody activity. We found discrete 100 kD relative molecular mass bands in Graves' M-Ag preparations (n = 3) under nonreducing conditions which were only poorly resolved in normal thyroid M-Ag (n = 3) using up to 100 micrograms of protein per lane. The cellular localization of M-Ag was then investigated using the avidin-biotin-peroxidase technique on frozen sections of Graves' and normal human thyroid tissue with a murine monoclonal antibody reactive with human M-Ag and thyroid peroxidase. M-Ag reactivity was similar in both Graves' and normal thyroid tissues and localized to the entire follicular cell membrane with more intense staining occurring on the inner follicular cell membrane. This was in contrast to follicular cell staining for HLA-DR antigen which was present in 6 of 10 Graves' tissues examined and absent in normal thyroid tissue. Staining for HLA-DR antigen also occurred on the follicular cell surface membrane with occasional enhancement at the thyrocyte apical cell membrane. We conclude: a) M-Ag is induced approximately 10-fold in Graves' thyroid tissue and can be objectively quantified in ELISA systems, 2) There were no detectable qualitative differences between M-Ag from Graves' and normal thyroid tissue, and 3) HLA-DR antigen was detected on 60% Graves' tissues in a cell surface distribution similar to that observed for M-Ag in both Graves' and normal tissues.
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PMID:Induction of microsomal antigen and comparison with histologic localization of HLA-DR in Graves' thyroid tissue. 249 9

We studied the distribution of binding sites for anti-peroxidase monoclonal antibody and anti-microsomal antibodies on isolated human thyroid follicles and a human thyroid cell line. Both open follicles and cells were incubated first with antibodies at +4 degrees C, then with colloidal gold labelled protein A. The topography of the binding sites for monoclonal anti-peroxidase antibody corresponded closely to the expected cell surface distribution of endogenous thyroid peroxidase since labelling was observed at the apical cell surface of the follicles. Furthermore, labelling was restricted to the microvilli level; while smooth membrane territories were devoid of binding sites. In some cases, incubations at 4 degrees C were followed by warming the follicles and cells up to 37 degrees C for 20 minutes in order to study internalization of ligands. Ligands were then observed in intracellular organelles: endosomes and lysosomes. Essentially the same results were observed when human antibodies to the microsomal antigen were used. Controls with microsomal antibodies depleted in anti-peroxidase were negative. In conclusion these findings show that: 1) thyroid peroxidase is present in limited areas on the apical cell surface, 2) labelling of follicles and cells by the anti-microsomal antibodies had the same pattern of distribution as the monoclonal anti-peroxidase antibody, thus suggesting that they recognize the same apical antigens, and 3) TPO/MIC antigen traffics from the cell surface towards lysosomes when the cells are incubated at 37 degrees C.
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PMID:Immunocytochemical study of localization and traffic of thyroid peroxidase/microsomal antigen. 249 23

This study describes an assay for the detection of cytotoxicity for thyroid cells in serum of patients with autoimmune thyroiditis. Quantitative measurement may be performed by DNA or [3H] leucine incorporation determinations. The cytotoxic effect is localized in the gamma-globulin fraction, and is complement-mediated. It is thyroid specific i.e. it is not observed with fibroblasts and patients with other autoimmune diseases (patients with lupus erythematosis or glomerulonephritis) do not have cytotoxic antibodies directed against thyroid cells. The thyroid cytotoxicity is related to the presence of antimicrosomal antibodies and the effect of circulating antibodies is inhibited by human thyroid peroxidase. These results strengthen the possible implication of circulating antithyroid peroxidase antibodies in thyroid damage observed in autoimmune thyroiditis.
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PMID:Cytotoxic assay of circulating thyroid peroxidase antibodies. 249 49


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