Differential effects of methylmercuric chloride and mercuric chloride on oxidation and iodination reactions catalyzed by thyroid peroxidase

Thyroid peroxidase (TPO), the major enzyme in the thyroid hormone synthesis, multifunctionally catalyzes (1) iodide oxidation, (2) iodination of the precursor protein, and (3) a coupling reaction of iodotyrosyl residues. The present study was carried out to examine the mercurial effects on the iodination, the second step of TPO. Purified porcine thyroglobulin or bovine serum albumin as acceptor protein was iodinated with [125I]NaI and H2O2 by purified porcine TPO. Iodinated protein was separated by acid precipitation on membrane filter or paper chromatography. Both CH3HgCl and HgCl2 dose-dependently inhibited the iodination, but HgCl2 was more potent to inhibit the iodination than CH3HgCl. These mercurial effects on the second step resemble the effects on the third step which were already reported; but are in marked contrast to the effects on the first step, where TPO was inhibited by HgCl2 but never by CH3HgCl.     

Localization of thyroid peroxidase and the site of iodination in rat thyroid gland.

The iodinated protein was localized in thyroid tissue slices by using radioautography. In unfixed tissue, the labelled protein was localized in the colloid, whereas, in tissue that was fixed before the 125I addition, the label was within the follicular cell. This localizes thyroid peroxidase largely on the endoplasmic reticulum of the cell.     

Iodination and oxidation of thyroglobulin catalyzed by thyroid peroxidase

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.     

Regulation by thyroid hormone of the synthesis of a cytosolic thyroid hormone binding protein during liver regeneration.

To understand the regulation by thyroid hormone, 3,3',5-triiodo-L-thyronine (T3), of the synthesis of a cytosolic thyroid hormone binding protein (p58-M2) during liver regeneration, the synthesis of p58-M2 was evaluated. The synthesis of p58-M2 was measured by metabolic labeling of primary cultures derived from the regenerating liver of euthyroid, hypo- or hyperthyroid rats. During regeneration, the increase in the liver/body weight ratio is approximately 25% higher in hyper- than in hypothyroid rats. However, T3 has no effect on the rate of overall liver regeneration observed in four days. In mature liver, T3 increased the synthesis of p58-M2 by approximately 2.5-fold. During regeneration, however, the change in the synthesis of p58-M2 varied with the thyroid status. In euthyroid rats, the synthesis of p58-M2 continued to increase up to 2-fold during liver regeneration. In hyperthyroid rats, after an initial increase by 1.5-fold on day 1, the synthesis of p58-M2 subsequently declined during regeneration. In hypothyroid rats, the synthesis of p58-M2 remained virtually unchanged during regeneration. These results indicate that T3 regulates the synthesis of p58-M2 in mature and regenerating liver.     

Quantitative modulation of thyroid iodide peroxidase by thyroid stimulating hormone

The activity of rat thyroid iodide peroxidase fell to 8% of the normal value 48 hours after hypophysectomy. Rats given injections of thyroid stimulating hormone manifested an enzyme activity indistinguishable from that of the sham-operated animals. Cycloheximide prevented the thyroid stimulating hormone-induced restoration of the enzyme activity. The incorporation of ¹⁴C-leucine into the thyroid gland decreased gradually and reached two thirds of the sham-operated group by 48 hours after hypophysectomy. Thyroid stimulating hormone administration prevented this decrease, as observed for iodide peroxidase activity. Thyroidal RNA contents decreased also in hypophysectomized rats, thyroid stimulating hormone treatment prevented the reduction of RNA contents and no significant change was observed in thyroidal DNA contents. These data are consistent with the idea that protein biosynthesis is involved in thyroid stimulating hormone regulation of thyroidal iodide peroxidase and that the life span of the peroxidase is less than 48 hours.     

Efficient thyroid hormone formation by in vitro iodination of a segment of rat thyroglobulin fused to Staphylococcal protein A.

A polypeptide of 224 amino acids from the C terminus of rat thyroglobulin fused to Staphylococcal protein A (TgC 224), containing 3 tyrosines which have been shown to be hormonogenic in vivo (Tyr-2555, -2569 and -2748), forms thyroid hormones with relatively high efficiency upon in vitro enzymatic iodination using, most likely, the hormonogenic Tyr-2555 and Tyr-2569. Acetylcholinesterase, which has sequence and structural homology with the C terminus of the thyroglobulin molecule and bovine serum albumin, used as control proteins, formed thyroid hormones with lower efficiency. These results validate our experimental approach to define the structural requirements for thyroid hormone formation using thyroglobulin fragments.     

Propyl gallate inhibition of iodide and tetramethylbenzidine oxidation catalyzed by human thyroid peroxidase

The kinetic characteristics (kcat, Km, and their ratio) for oxidation of iodide (I-) at 25 degrees C in 0.2 M acetate buffer, pH 5.2, and tetramethylbenzidine (TMB) at 20 degrees C in 0.05 M phosphate buffer, pH 6.0, with 10% DMF catalyzed by human thyroid peroxidase (HTP) and horseradish peroxidase (HRP) were determined. The catalytic activity of HRP in I- oxidation was about 20-fold higher than that of HTP. The kcat/Km ratio reflecting HTP efficiency was 35-fold higher in TMB oxidation than that in I- oxidation. Propyl gallate (PG) effectively inhibited all four peroxidase processes and its effects were characterized in terms of inhibition constants Ki and the inhibitor stoichiometric coefficient f. For both peroxidases, inhibition of I- oxidation by PG was characterized by mixed-type inhibition; Ki for HTP was 0.93 microM at 25 degrees C. However, in the case of TMB oxidation the mixed-type inhibition by PG was observed only with HTP (Ki = 3.9 microM at 20 degrees C), whereas for HRP it acted as a competitive inhibitor (Ki = 42 microM at 20 degrees C). A general scheme of inhibition of iodide peroxidation containing both enzymatic and non-enzymatic stages is proposed and discussed.     

About insulin iodination: I. Monoidoination of insulin by horseradish peroxidase

Beef insulin has been iodinated according to an enzymic method. Labeled molecules have been separated quantitatively from the unlabeled ones on Ampholines. Results supplied by qualitative and quantitative studies of the distribution of iodine in the different tyrosyl residues showed that insulin was essentially iodinated on the tyrosyl residue A₁₉.     

Differences in iodinated peptides and thyroid hormone formation after chemical and thyroid peroxidase-catalyzed iodination of human thyroglobulin

The distribution of iodine among the polypeptides of human goiter thyroglobulin (Tg) was examined. Tg was iodinated in vitro with ¹³¹I to levels of 2 to 84 gram atoms (g.a.)/mol using thyroid peroxidase (TPO) or a chemical iodination system. The samples were reduced, alkylated, and subjected to sodium dodecyl sulfate-polyacrylamide gel electrophoresis. Two low-molecular-weight peptides appeared preferentially in radioautograms of the sodium dodecyl sulfate (SDS) gels of TPO-iodinated samples. Iodination of these peptides increased sharply in the TPO-treated Tg as the level of total iodine/ molecule rose. Radioiodine was incorporated into these same gel regions in the chemically treated Tg, but only after much higher levels of total iodination were reached. Differences in iodoamino acid distribution were also noted between the chemically and enzymatically iodinated thyroglobulins. In the chemically iodinated samples, little thyroxine (T₄) was synthesized, even at high iodine levels. In the TPO-treated samples only small amounts of T₄ were seen below 14 g.a. total I/mol, while at or above that level of iodination T₄ formation increased sharply. To examine the coupling process, Tg was chemically iodinated, excess I^? removed, and the samples treated with TPO and a H₂O₂-generating system in the absence of iodide. Radioautograms obtained from SDS-polyacrylamide gels of reduced and alkylated protein from such coupling assays showed an increase in the level of iodine in the low-molecular-weight peptides after TPO treatment. Thyroxine production also increased with TPO treatment. The addition of free DIT (a known coupling enhancer) to the [¹³¹I]Tg/TPO incubation increased both the production of T₄ and the amount of iodine in the smaller polypeptides. Two-dimensional maps prepared from CNBr-digested TG showed differences between the coupled and uncoupled samples. Our observations confirm the importance of the lowmolecular-weight peptides derived from Tg in thyroid hormone synthesis. At total iodine levels above 14 g.a./mol Tg in enzymatically treated samples there is selective incorporation of iodine into both the low-molecular-weight polypeptides and into thyroid hormone.     

Activation of protein kinase in thyroid slices by thyroid-stimulating hormone.

Protein kinase activity in homogenates of control thyroid slices and those incubated with thyroid-stimulating hormone (TSH) and prostaglandin EI was assayed and correlated with changes in cyclic adenosine 3':5'-monophosphate (cAMP) concentrations and binding of [3H]cAMP. Both TSH and prostaglandin E1 (25 mug/ml) increased protein kinase activity and the activity ratio (expressed as activity - cAMP to activity plus cAMP). It is unlikely that such activation reflects effects of the increased cAMP liberated at the time of homogenization. Hormone-induced activation of protein kinase persisted even after the homogenate had been diluted so that its cAMP concentration would be insufficient to achieve maximal activation of the enzyme. In contrast to the previous results of J. D. Corbin, T. R. Soderling, and C. R. Park ((1973 J. Biol. Chem. 248, 1813) using adipose tissue, homogenization of thyroid tissue in 0.5 M NaCl and chromatography using Sephadex G-100 did not seem to stabilize dissociation of protein kinase into its receptor and catalytic subunits. However, increasing amounts of NaCl in the homogenizing buffer were associated with an increase in the cAMP independence of enzyme activity. Dilution of the homogenate did not change the protein kinase activity ratio whether the homogenizing buffer contained NcCl or not. Increasing concentrations of NaF inhibited protein kinase activity. Within 1 to 3 min of incubation of thyroid slices with TSH, protein kinase activity and the activity ratio were increased significantly. This correlated quite well with increased cAMP concentrations in the slices and inhibition of [3H]cAMP binding to the homogenates. Maximal activation of the enzyme was achieved by 10 min which corresponds to the time of maximal effect on cAMP concentrations. Activation of protein kinase was achieved by 0.125 milliunit/ml of TSH and maximal effects with 0.5 to 1.25 milliunits/ml. These amounts agree well with those required for other effects of TSH. Although larger amounts of TSH produced even greater increases in cAMP concentrations this was not always associated with augmented inhibition of [3H]cAMP binding. These results are compatible with the concept that the TSH-mediated increase in cAMP is associated with activation of protein kinase in the intact cell. They also suggest that not all of the intracellular cAMP is available for activation of protein kinase.