The Ca2+/NADPH-dependent H2O2 generator in thyroid plasma membrane: inhibition by diphenyleneiodonium.

The thyroid plasma membrane contains a Ca(2+)-regulated NADPH-dependent H2O2-generating system which provides H2O2 for the peroxidase-catalysed biosynthesis of thyroid hormones. The electron transfer from NADPH to O2 catalysed by this system was studied by using diphenyleneiodonium (DPI), an inhibitor of flavo- and haemo-proteins. The prosthetic group of the H2O2 generator was removed by incubation with 5 mM CHAPS at 40 degrees C, and an active holoenzyme was reconstituted with FAD, but not with FMN. The H2O2-generating system also had an intrinsic Ca(2+)-dependent NADPH:ferricyanide reductase activity which is probably linked to its flavodehydrogenase component (or domain). Both activities, H2O2 production and ferricyanide reductase activity, were inhibited by DPI, with similar K1/2 (2.5 nmol/mg of protein). DPI only inhibited a system reduced with NADPH in the presence of Ca2+. NADPH could not be replaced by NADP+, NADH or sodium dithionite, suggesting the need for specific mild reduction of a redox centre in a particular conformation. Ferricyanide protected both activities against inhibition by DPI; the NADPH:ferricyanide reductase activity was completely protected at a ferricyanide concentration 20 times lower than that needed to protect the H2O2 formation, implying at least two target sites for DPI. One might be the flavodehydrogenase component; the other was beyond, on the entity which transfers the electrons to O2. This second site has not been identified.

A method for measuring H2O2 based on the potentiation of peroxidative NADPH oxidation by superoxide dismutase and scopoletin.

NADPH oxidation catalyzed by horseradish peroxidase is considerably increased by scopoletin and superoxide dismutase. These effects were used to develop a method for measuring H2O2 in a horseradish peroxidase, superoxide dismutase, and scopoletin system by measuring the NADPH oxidation rate. The optimal concentration of each reactant was determined. H2O2 could be detected and measured when it was present free in the medium or when it was produced by an H2O2-generating system, such as glucose-glucose oxidase or NADPH oxidase from thyroid plasma membranes. H2O2 was measured either by taking aliquots of the incubation medium or by placing NADPH directly in the medium and following the kinetics of NADPH oxidation. This latter approach required smaller amounts of biological material. In contrast to other methods, the H2O2 which is measured is regenerated. This method is 10 times more sensitive than the standard scopoletin method for H2O2 measurement and will detect a H2O2 production rate as low as 0.2 nmol per hour. The method is particularly suitable for biological systems in which small quantities of biological material are available.

Activation of the NADPH-dependent H2O2-generating system in pig thyroid particulate fraction by limited proteolysis and Zn2+ treatment.

The NADPH-dependent H2O2-generating system in a pig thyroid particulate fraction requires micromolar concentrations of Ca2+ for activity. The H2O2 generator could be Ca(2+)-desensitized (i.e. made fully active in the absence of Ca2+) by limited proteolysis with alpha-chymotrypsin or by treatment with ZnCl2. The Zn2+ effect was temperature- and dose-dependent with an apparent half-maximum concentration of 0.15 mM at 40 degrees C. Ca2+ desensitization was not reversed by adding the Zn2+ chelators, 1,10-phenanthroline and EGTA, but about one-third of the Ca(2+)-sensitivity was recovered after addition of 10 mM-dithiothreitol. The proteolysed enzyme and the Zn(2+)-treated enzyme had different Km values for NADPH. The Zn2+ effect did not seem to involve proteolysis or membrane fusion. These results indicate that Ca2+ regulation occurs via an autoinhibitory domain or inhibitory protein component of the H2O2-generator system. Its inhibitory effect may be removed by proteolysis or conformational changes, making the catalytic site accessible to the substrate NADPH and/or enabling electrons to be transferred from NADPH to O2.

Male rat hepatic UDP-glucuronosyltransferase activity toward thyroxine. Activation and induction properties--relation with thyroxine plasma disappearance rate.

Detergent-activation of UDP-glucuronosyltransferase (UGT) isoenzyme(s) involved in thyroxine (T4) glucuronidation in control, phenobarbital (PB)- and 3-methylcholanthrene (3-MC)-treated rats showed that between the four tested detergents, i.e. Triton X-100, Brij 58, Lubrol Px and 3-(3-cholamidopropyl)dimethylammonio-1-propanesulfonic acid (CHAPS), optimal activation of T4 UGT was displayed by the zwitterion CHAPS. "Native" versus optimal detergent-activated T4 UGT activity determination revealed that the latency of T4 UGT in microsomes from 3-MC-treated rats was decreased while the latency of T4 UGT in microsomes from PB-treated rats was increased compared to control, and suggest that the UGT isoenzyme(s) involved in the hepatic glucuronidation of T4 is (are) different in PB-treated rats than in 3-MC-treated rats. After a 7-day treatment with 20 mg/kg 3-MC, the activity of T4 UGT was increased 5-fold when determined in "native" and 4-fold when determined in optimal detergent-activated microsomes compared to controls. After a 7-day treatment with 75 mg/kg PB, T4 UGT was equivalent to the control when determined in "native", and increased 1.3-fold when determined in optimal detergent-activated microsomes. The results thus extend evidence that both 3-MC and PB induce the synthesis of UGT protein(s) involved in the glucuronidation of T4, 3-MC being a strong and PB a weak inducer. Hyperthyroid and hypothyroid status, achieved respectively by a 7-day treatment with 100 microns/kg T4 or a 7-day treatment with 10 mg/kg of one of the antithyroid drugs propylthiouracile or methymazole, did not modify T4 UGT activity, suggesting that the isoenzyme(s) conjugating T4 in microsomes from control rats is (are) unlikely to be either 4-nitrophenol or bilirubin UGT isoenzymes. After 14 days of treatment with 75 mg/kg PB, the hepatic glucuronidation rate of T4 was not different from the control when enzyme activity was expressed per mg microsomal protein but was significantly increased 1.4-fold when expressed per whole liver. A significant (1.5-fold) increase in the 125I-T4 plasma elimination rate was also observed in PB-treated rats compared to controls. A strong (3.6-fold) increase in the T4 glucuronidation rate was observed in rats treated with 5 mg/kg 3-MC for 14 days while the 125I-T4 plasma elimination rate was equivalent to the controls. These results demonstrate that there is no direct relation between T4 UGT activity (and subsequent biliary secretion of T4-glucuronides) and T4 plasma clearance and suggest an important contribution of the intestinal exchangeable thyroid hormone pool to the maintenance of blood thyroid hormone levels.

Optimal detergent activation of rat liver microsomal UDP-glucuronosyl transferases toward morphine and 1-naphthol: contribution to induction and latency studies.

The detergent-activation profiles of UDP-glucuronosyl transferases (UGTs, EC 2.4.1.17) toward 1-naphthol and toward morphine have been determined: three non-ionic detergents, Triton X-100, Brij 58 and Lubrol Px and one zwitterion detergent, 3-(3-cholamidopropyl)-dimethylammonio-1-propanesulfonic acid (CHAPS) were studied. The results showed that marked inhibition of 1-naphthol-UGT and morphine UGT activities occurred with high concentrations of Triton X-100. Lubrol Px, at high concentrations, inhibited 1-naphthol-UGT but not morphine-UGT. It appeared that the detergent/protein ratio suitable for optimal activation of both isoenzymes was limited to 0.2 for these detergents. In contrast, Brij 58 and CHAPS displayed optimal activation of the two enzymes for a large range of detergent/microsomal protein ratios (respectively from 0.2 to 1 and from 0.4 to 1), making them the most suitable for induction and/or latency studies of both isoenzymes. The influence of maximal activation status on the effect of 3-methylcholanthrene and phenobarbital treatment on morphine-UGT and 1-naphthol-UGT activity has also been evaluated. The findings provided evidence that detergent-activation profiles and optimal detergent-activated versus "native" UGT activity determination give crucial informations about the characteristics of a given isoenzymic form of UGT, i.e. its sensitivity to specific alterations of the phospholipid environment, its latency and its inducibility.

Comparison of the effects of propylthiouracil, amiodarone, diphenylhydantoin, phenobarbital, and 3-methylcholanthrene on hepatic and renal T4 metabolism and thyroid gland function in rats.

We studied the effects of propylthiouracil (PTU), amiodarone (AMIO), diphenylhydantoin (DPH), phenobarbital (PB), and 3-methylcholanthrene (MC) on thyroid histomorphology, on the hepatic and renal enzymes involved in endogenous and exogenous metabolism, and on the plasma levels and pharmacokinetics of thyroid hormones after 7 and 14 days of treatment. PTU and PB, by decreasing both serum tetraiodothyronine (T4) and triiodothyronine (T3), induced a massive increase in serum thyrotropin (TSH) and thus induced thyroid hypertrophy. AMIO and MC, by decreasing respectively serum T3 and T4, also induced an increase of TSH, but to a lesser extent, not sufficient to induce thyroid hypertrophy. Hepatic 5'-deiodinase activity was decreased in all treated rats. Inhibition of this enzyme by PTU was demonstrated in vitro; AMIO also decreased the enzyme activity by a still unelucidated mechanism, which probably requires intact cell plasma membranes, whereas in PB- and MC-treated rats the decrease in enzyme activity certainly resulted from decreased serum concentrations of T4. In PTU-treated rats, and probably in MC-treated rats, decreases in circulating thyroid hormones were primarily due to impairment of synthesis and/or of secretion by the thyroid. In contrast, in PB-treated rats, the decrease in serum thyroid hormone levels seems to be due to increased excretion of these hormones, as T4 serum clearance was significantly increased. PB, a microsomal enzyme inducer, increased the cytochrome b5 and P450 content as well as the cytochrome P450-dependent O-depentylation of pentoxyresorufin. The other type of enzyme inducer, MC, did not affect cytochrome b5 and P450 levels, but did increase the cytochrome P450 dependent O-deethylation of ethoxyresorufin. PB increased the glucuronidation of morphine, whereas MC increased the glucuronidation of 1-naphthol. However, serum T4 clearance, mainly determined by its hepatic conjugation rate, was increased only in PB-treated rats. It appears from this study that the close metabolic relationship between the liver/kidney and the thyroid should be taken into consideration when the findings of chronic toxicology and carcinogenicity studies are interpreted.

Mechanism of NADPH oxidation catalyzed by horse-radish peroxidase and 2,4-diacetyl-[2H]heme-substituted horse-radish peroxidase.

The mechanism of NADPH oxidation catalyzed by horse-radish peroxidase (HRP) and 2,4-diacetyl-[2H]heme-substituted horse-radish peroxidase (DHRP) was studied. The roles of the different H2O2/peroxidase compounds were examined by spectral studies. The oxidized NADPH species were identified using the superoxide dismutase effect and by measuring the stoichiometry between NADPH oxidized and H2O2 used. In the presence of a mediating molecule, like scopoletin, both enzymes acted via a similar mechanism, producing only NADP degrees, which in turn reacted with O2 producing O2-. Consequently H2O2 was completely regenerated in the presence of superoxide dismutase and partially regenerated in its absence. In the absence of a mediating molecule, the H2O2 complex of both enzymes (compound I) catalysed NADPH oxidation by single-electron transfer, producing NADP degrees; compound II of these enzymes catalyzed NADPH oxidation more slowly by a direct two-electron transfer, producing NADPH+. There were difference between HRP and DHRP. HRP compound II was produced by the oxidation of 1 mol NADPH/mole compound I, while DHRP compound II was formed by the spontaneous conversion of compound I to compound II. The NADPH oxidation catalyzed by DHRP compound I did not lead to the formation of compound II. When H2O2 was produced slowly by the glucose/glucose-oxidase system, compound II was never formed and a pure O2- adduct of DHRP (compound III) accumulated.

Determination of 125I-labelled thyroxine glucuronide by reversed-phase high-performance liquid chromatography using on-line radiochemical detection to determine UDPglucuronosyltransferase activity.

A convenient, fast and highly sensitive high-performance liquid chromatographic method, using on-line radiochemical detection, is described for the determination of [125I]thyroxine glucuronide. The method involves direct injection of the supernatant, a total analysis time of 30 min and a detection limit of 1 pmol. The results demonstrate that the method is suitable for the determination of UDPglucuronosyltransferase activity with thyroxine as substrate in native hepatic microsomes. The rate of thyroxine glucuronidation in microsomes from rats treated with Arodor 1254 was ten times higher than in control microsomes, indicating that with this method, increases of UDPglucuronosyltransferase thyroxine activities, often associated with hepatic induction process involved in thyroid hypertrophy, can be easily detected. This method could also be applied to all experimental biological systems that involve the separation and quantification of [125I]thyroxine and [125I]thyroxine glucuronide.