Sebo Jan Eelkman Rooda scite author profile

The type 1 iodothyronine deiodinase (1D-I) in liver and kidney converts the prohormone thyroxine ('1"4) by outer ring deiodination (ORD) to bioactive 3,3',5-triiodothyronine (T3) or by inner ring deiodination (IRD) to inactive 3,3',5-"triiodothronine (rT3), while it also catalyzes the IRD of T3 and the ORD of rT 3, with the latter as the preferred substrate. Sulfation of the phenolic hydroxyl group blocks the ORD of T 4, while it strongly stimulates the IRD of both T 4 and T3, indicating that sulfation is an important step in the irreversible inactivation of thyroid hormone. This review summarizes recent studies concerning this interaction between sulfation and deiodination of iodothyronines, the characterization of iodothyronine sulfotransferase activities, the measurement of iodothyronine sulfates in humans and animals, and the possible physiological importance of iodothyronine sulfation.

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Metabolism of Thyroid Hormone in Liver

Rutgers

Herder

et al. 1989

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Metabolism of reverse triiodothyronine by isolated rat hepatocytes.

Rooda¹,

Loon²,

Tj³

1987

J. Clin. Invest.

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Reverse triiodothyronine (rT3) is metabolized predominantly by outer ring deiodination to 3,3'-diiodothyronine (3,3'-T2) in the liver. Metabolism of rT3 and 3,3'-T2 by isolated rat hepatocytes was analyzed by Sephadex LH-20 chromatography, high performance liquid chromatography, and radioimmunoassay, with closely agreeing results. Deiodinase activity was inhibited with propylthiouracil (PTU) and sulfotransferase activity by sulfate depletion or addition of salicylamide or dichloronitrophenol. Normally, little 3,3'-T2 production from rT3 was observed, and 1251 was the main product of both 3,13'-'25iT2 and 13',5'-25IlrT3. PTU inhibited rT3 metabolism but did not affect 3,3'-T2 clearance as explained by accumulation of 3,3'-T2 sulfate. Inhibition of sulfation did not affect rT3 clearance but 3,3'-T2 metabolism was greatly diminished. The decrease in I formation from rT3 was compensated by an increased recovery of 3,3'-T2 up to 70% of rT3 metabolized. In conclusion, significant production of 3,3'-T2 from rT3 by rat hepatocytes is only observed if further sulfation is inhibited.

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Metabolism of Triiodothyronine in Rat Hepatocytes*

Rooda¹,

Otten²,

Loon³

et al. 1989

Endocrinology

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The metabolism of T3 by isolated rat hepatocytes was analyzed by Sephadex LH-20 chromatography, HPLC, and RIA for T3 sulfate (T3S) and 3,3'-diiodothyronine (3,3'-T2). Type I iodothyronine deiodinase activity was inhibited with propylthiouracil (PTU), and phenol sulfotransferase activity by SO4(2-) depletion or with competitive substrates or inhibitors. Under normal conditions, labeled T3 glucuronide and I- were the main products of [3'-125I]T3 metabolism. Iodide production was decreased by inhibition (PTU) or saturation (greater than 100 nM T3) of type I deiodinase, which was accompanied by the accumulation of T3S and 3,3'-T2S. Inhibition of phenol sulfotransferase resulted in decreased iodide production, which was associated with an accumulation of 3,3'-T2 and 3,3'-T2 glucuronide, independent of PTU. Formation of 3,3'-T2 and its conjugates was only observed at T3 substrate concentrations below 10 nM. Thus, T3 is metabolized in rat liver cells by three quantitatively important pathways: glucuronidation, sulfation, and direct inner ring deiodination. Whereas T3 glucuronide is not further metabolized in the cultures, T3S is rapidly deiodinated by the type I enzyme. As confirmed by incubations with isolated rat liver microsomes, direct inner ring deiodination of T3 is largely mediated by a low Km, PTU-insensitive, type III-like iodothyronine deiodinase, and production of 3,3'-T2 is only observed if its rapid sulfation is prevented.

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Serum Triiodothyronine Sulfate in Man Measured by Radioimmunoassay

Rooda

Kaptein

Visser

1989

The Journal of Clinical Endocrinology & Metabolism

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In humans deiodination and perhaps glucuronidation are important pathways of thyroid hormone metabolism. In animals, sulfation plays an important role in T4 and especially in T3 metabolism, but little is known about sulfate conjugation of thyroid hormone in humans. In this study we used a specific T3 sulfate (T3S) RIA to address this question. Eight normal subjects were given oral T3 (1 microgram/day.kg BW) for 7 weeks. During the fifth week they also received propylthiouracil (PTU; four doses of 250 mg/day) for 2 days and during the seventh week iopanoic acid (IOP; 1 g/day) for 3 days. The mean pre-T3 serum iodothyronine values were: T4, 92 +/- 6 (+/- SE) nmol/L; rT3, 0.24 +/- 0.02 nmol/L; T3, 2.30 +/- 0.10 nmol/L; and T3S, less than 0.1 nmol/L (at or below the detection limit of the RIA). After 4 weeks of T3 administration the mean serum values were: T4, 39 +/- 6; rT3, 0.11 +/- 0.01; T3, 5.31 +/- 0.39; and T3S, 0.10 +/- 0.01 nmol/L. After 2 days of PTU administration, mean serum T4 increased to 48 +/- 7 (P less than 0.005), rT3 to 0.20 +/- 0.03 (P less than 0.025), and T3S to 0.13 +/- 0.01 nmol/L (P = NS), but serum T3 did not change (4.91 +/- 0.35 nmol/L). The effect of IOP was more pronounced; after its administration for 3 days the mean serum T4 was 49 +/- 8 (P less than 0.001), rT3 was 0.48 +/- 0.09 (P less than 0.005), and T3S was 0.29 +/- 0.04 nmol/L (P less than 0.005), and serum T3 decreased to 3.95 +/- 0.25 nmol/L (P less than 0.005). The T3S/T3 ratio was increased by PTU from 0.018 +/- 0.003 to 0.024 +/- 0.004 (P less than = NS) and by IOP to 0.055 +/- 0.007 (P less than 0.005). In conclusion, 1) serum T3S is virtually undetectable (less than 0.1 nmol/L) in normal subjects; 2) low serum T3S concentrations are detected in humans given T3; 3) serum T3S in T3-treated subjects is increased by inhibition of type I deiodinase activity with PTU and especially IOP; and 4) in comparison with previous estimates of the serum T3S/T3 ratio in rats, the low ratio in humans may indicate that sulfation is not an important mechanism of T3 metabolism in humans and/or the kinetics of plasma T3 and T3S differ in humans and rats.

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