Concentrations of seven iodothyronine metabolites in brain regions and the liver of the adult rat

The concentrations of the iodothyronine metabolites T(4), T(3), 3,5-diiodothyronine (3,5-T(2)), 3,3'-diiodothyronine (3,3'-T(2)), reverse T(3) (rT(3)), 3,3'-T(2) sulfate (3,3'T(2)S), and T(3) sulfate (T(3)S) were measured in 12 regions of the brain, the pituitary gland, and liver in adult male rats. Quantification of iodothyronine was performed by RIA following a newly developed method of purification and separation by HPLC. 3,5-T(2), 3,3'-T(2), rT(3) and T(2)S were detectable in the low femtomolar range (20-200 fmol/g) in most areas of the rat brain. T(3)S was detectable only in the hypothalamus. The concentrations of T(3) and T(4) were approximately 20- to 60-fold higher, ranging between 1 and 6 pmol/g. There was a significant negative correlation between the activities of inner-ring deiodinase and T(3) concentrations across brain areas. In the liver, 3,5-T(2), rT(3), and T(3)S were measurable in the low femtomolar range, whereas 3,3'-T(2) and 3,3'T(2)S were not detectable. 3,5-T(2) and 3,3'-T(2) were not detectable in mitochondrial fractions of the brain regions. Tissue concentrations of 3,5-T(2) exhibited a circadian variation closely parallel to those of T(3) in the brain regions and liver. T(3) was not a substrate for outer-ring deiodination under different experimental conditions; thus, it remains unclear which substrate(s) and enzyme(s) are involved in the production of 3,5-T(2). These results indicate that five iodothyronine metabolites other than T(3) and T(4) are detectable in the low femtomolar range in the rat brain and/or liver. The physiological implications of this finding are discussed.     

Deiodination of iodothyronine sulfamates by type I iodothyronine deiodinase of rat liver

The substrate behavior of synthetic N-sulfonated iodothyronines (iodothyronine sulfamates, TiNS) for the type I deiodinase was compared with that of the naturally occurring 4'-O-sulfonated iodothyronines (iodothyronine sulfates, TiS), which have been shown to be deiodinated 40-200 times more efficiently than the native iodothyronines. Deiodination was studied in incubations of rat liver microsomes with unlabeled or 3' (5')-125I-labeled T4NS, rT3NS, T3NS, and 3,3'-T2NS at 37 C and pH 7.2 in the presence of 5 mM dithiothreitol. Reaction products were analyzed by RIA or Sephadex LH-20 and HPLC. Kinetic studies were performed under initial reaction rate conditions to determine the apparent Michaelis Menten (Km) constants and maximum velocity values. In contrast to T4S, which is converted only by inner ring deiodination (IRD), T4NS underwent both IRD and outer ring deiodination (ORD), similar to T4, but more rapidly. At 10 nM T4NS substrate, T3NS was the major product observed, while no rT3NS accumulated due to its rapid conversion to 3,3'-T2NS. At least one third of the 3,3'-T2NS was converted by IRD, unlike 3,3'-T2 which is a pure ORD substrate. The type I deiodination efficiencies of T4NS IRD and ORD were 17-fold higher than with T4, mainly due to approximately 32-fold lower apparent Km values. Deiodination of rT3, the preferred type I substrate, was not improved by sulfamation. T3NS and 3,3'-T2NS were deiodinated 4-10 times more efficiently than T3 and 3,3'-T2, respectively, due to 2- to 4-fold decreases in apparent Km values with a concomitant doubling of maximum velocity values. N-Sulfonation stimulates type I deiodination to a similar extent as other side-chain modifications that eliminate the positive charge of the nitrogen (e.g. iodothyroacetic acids). However, the effects are less dramatic than those induced by 4'-sulfation with respect to both efficiency and specificity of the catalytic process.     

Metabolism of triiodothyronine in rat hepatocytes

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.     

Characterization of human iodothyronine sulfotransferases

Sulfation is an important pathway of thyroid hormone metabolism that facilitates the degradation of the hormone by the type I iodothyronine deiodinase, but little is known about which human sulfotransferase isoenzymes are involved. We have investigated the sulfation of the prohormone T4, the active hormone T3, and the metabolites rT3 and 3,3'-diiodothyronine (3,3'-T2) by human liver and kidney cytosol as well as by recombinant human SULT1A1 and SULT1A3, previously known as phenol-preferring and monoamine-preferring phenol sulfotransferase, respectively. In all cases, the substrate preference was 3,3'-T2 > rT3 > T3 > T4. The apparent Km values of 3,3'-T2 and T3 [at 50 micromol/L 3'-phosphoadenosine-5'-phosphosulfate (PAPS)] were 1.02 and 54.9 micromol/L for liver cytosol, 0.64 and 27.8 micromol/L for kidney cytosol, 0.14 and 29.1 micromol/L for SULT1A1, and 33 and 112 micromol/L for SULT1A3, respectively. The apparent Km of PAPS (at 0.1 micromol/L 3,3'-T2) was 6.0 micromol/L for liver cytosol, 9.0 micromol/L for kidney cytosol, 0.65 micromol/L for SULT1A1, and 2.7 micromol/L for SULT1A3. The sulfation of 3,3'-T2 was inhibited by the other iodothyronines in a concentration-dependent manner. The inhibition profiles of the 3,3'-T2 sulfotransferase activities of liver and kidney cytosol obtained by addition of 10 micromol/L of the various analogs were better correlated with the inhibition profile of SULT1A1 than with that of SULT1A3. These results indicate similar substrate specificities for iodothyronine sulfation by native human liver and kidney sulfotransferases and recombinant SULT1A1 and SULT1A3. Of the latter, SULT1A1 clearly shows the highest affinity for both iodothyronines and PAPS, but it remains to be established whether it is the prominent isoenzyme for sulfation of thyroid hormone in human liver and kidney.     

Handling of iodothyronines by the liver and kidney in patients with chronic liver disease

Possible arterio-venous gradients of T4, T3, rT3 and 3,3'-diiodothyronine (3,3'-T2) across the liver and the kidneys were measured in 9 patients with varying degrees of liver failure undergoing diagnostic catheterization. Plasma iodothyronine levels were measured in peripheral, hepatic and renal veins before and at 10-min intervals until 60 min after iv injection of 400 micrograms of TRH. In 2 patients estimated hepatic plasma flow and effective renal plasma flow were determined as well. In these 2 patients, no significant differences between iodothyronine levels in arterial and peripheral venous plasma were found. T4 and T3 levels were not significantly different between peripheral, renal and hepatic veins. Hepatic vein rT3 and 3,3'-T2 concentrations were 10.7 +/- 8.3% (mean +/- SD, P less than 0.005) and 36 +/- 18% (P less than 0.001) lower than those in the peripheral vein (N = 9). Renal vein rT3 was just (6.2 +/- 7.5%, P less than 0.05) lower than rT3 in peripheral vein, whereas 3,3'-T2 was not different between the two veins. Estimates of hepatic and renal plasma flow were in agreement with values from the literature. On the basis of these data approximate hepatic clearance rates of 110 and 380 1/day for rT3 and 3,3'-T2 and a renal clearance rate of about 35 1/day for rT3 were calculated. Sixty min after TRH, plasma T3 was increased to 147 +/- 56% (P less than 0.05) and 3,3'-T2 in peripheral plasma was increased to 142 +/- 36% (P less than 0.025), whereas plasma T4 and rT3 did not change.(ABSTRACT TRUNCATED AT 250 WORDS)     

Organic anion transporter 1B1: an important factor in hepatic thyroid hormone and estrogen transport and metabolism

Sulfation is an important pathway in the metabolism of thyroid hormone and estrogens. Sulfation of estrogens is reversible by estrogen sulfatase, but sulfation of thyroid hormone accelerates its degradation by the type 1 deiodinase in liver. Organic anion transporters (OATPs) are capable of transporting iodothyronine sulfates such as T4 sulfate (T4S), T3S, and rT3S or estrogen sulfates like estrone sulfate (E1S), but the major hepatic transporter for these conjugates has not been identified. A possible candidate is OATP1B1 because model substrates for this transporter include the bilirubin mimic bromosulfophthalein (BSP) and E1S, and it is highly and specifically expressed in liver. Therefore, OATP1B1-transfected COS1 cells were studied by analysis of BSP, E1S, and iodothyronine sulfate uptake and metabolism. Two Caucasian populations (155 blood donors and 1012 participants of the Rotterdam Scan Study) were genotyped for the OATP1B1-Val174Ala polymorphism and associated with bilirubin, E1S, and T4S levels. OATP1B1-transfected cells strongly induced uptake of BSP, E1S, T4S, T3S, and rT3S compared with mock-transfected cells. Metabolism of iodothyronine sulfates by cotransfected type 1 deiodinase was greatly augmented in the presence of OATP1B1. OATP1B1-Val174 showed a 40% higher induction of transport and metabolism of these substrates than OATP1B1-Ala174. Carriers of the OATP1B1-Ala174 allele had higher serum bilirubin, E1S, and T4S levels. In conclusion, OATP1B1 is an important factor in hepatic transport and metabolism of bilirubin, E1S, and iodothyronine sulfates. OATP1B1-Ala174 displays decreased transport activity and thereby gives rise to higher bilirubin, E1S, and T4S levels in carriers of this polymorphism.     

Metabolism of triiodothyroacetic acid (TA3) in rat liver. I. Deiodination of TA3 and TA3 sulfate by microsomes

The deiodination of the acetic acid side-chain analogs of T3 as well as 3,3'-diiodothyronine (3,3'-T2) was investigated by incubating 125I-labeled 3,3',5-triiodothyroacetic acid (TA3) and 3,3'-diiodothyroacetic acid (3,3'-TA2) with rat liver microsomes at 37 C and pH 7.2 in the presence of 5 mM dithiothreitol. TA3 sulfate (TA3S) and 3,3'-TA2S were also tested as substrate since sulfation is known to accelerate T3 and 3,3'-T2 conversion. Reaction products were analyzed on Sephadex LH-20 and HPLC. TA3 underwent only inner ring deiodination (IRD), but 3,3'-TA2 was equally converted by IRD and outer ring deiodination (ORD). TA3S was metabolized very rapidly by IRD to 3,3'-TA2S which was only observed transiently due to its rapid deiodination predominantly in the outer ring. Kinetic studies under initial reaction rate conditions yielded apparent Michaelis-Menten (Km) values (micromolar) of 1.8 for TA3, 0.8 for 3,3'-TA2, and 0.004 for TA3S, and 0.02 for 3,3'-TA2S and Vmax values (picomoles per min/mg protein) of 174 for TA3, 49 for 3,3'-TA2, 21 for TA3S, and 63 for 3,3'-TA2S. The Vmax/Km ratios for the IRD of TA3 and TA3S were 16 and 930 times higher, respectively, relative to T3. Deiodinations were sensitive to propylthiouracil inhibition, indicating the involvement of the type I iodothyronine deiodinase. Furthermore, the iodothyroacetic acid derivatives competitively inhibited the ORD of rT3 with apparent inhibition constant (Ki) values (0.45 microM for TA3, 4 nM for TA3S, and 0.04 microM for 3,3'-TA2S) in agreement with corresponding Km values. We conclude that 1) TA3 and 3,3'-TA2 are better substrates than T3 and 3,3'-T2 for the type I deiodinase of rat liver; 2) the IRD of TA3 and ORD of 3,3'-TA2 are markedly enhanced by sulfation similar to the parent iodothyronines; and 3) TA3S in the best known substrate for IRD due to its very high affinity for the type I deiodinase.     

Metabolism of 3,3'-diiodothyronine in rat hepatocytes: interaction of sulfation with deiodination

Production of 3,3'-diiodothyronine (3,3'-T2) is an important step in the peripheral metabolism of thyroid hormone in man. The rapid clearance of 3,3'-T2 is accomplished to a large extent in the liver. We have studied in detail the mechanisms of this process using monolayers of freshly isolated rat hepatocytes. After incubation with 3,[3'-125I]T2, chromatographic analysis of the medium revealed two major metabolic routes: outer ring deiodination and sulfation. We recently demonstrated that sulfate conjugation precedes and in effect accelerates deiodination of 3,3'-T2. In media containing different serum concentrations the cellular clearance rate was determined by the nonprotein-bound fraction of 3,3'-T2. At substrate concentrations below 10(-8) M 125I- was the main product observed. At higher concentrations deiodination became saturated, and 3,3'-T2 sulfate (T2S) accumulated in the medium. Saturation of 3,3'-T2 clearance was found to occur only at very high (greater than 10(-6)M) substrate concentrations. The sulfating capacity of the cells exceeded that of deiodination by at least 20-fold. Deiodination was completely inhibited by 10(-4) M propylthiouracil or thiouracil, resulting in the accumulation of T2S while clearance of 3,3'-T2 was little affected. No effect was seen with methimazole. Hepatocytes from 72-h fasted rats showed a significant reduction of deiodination but unimpaired sulfation. Other iodothyronines interfered with 3,3'-T2 metabolism. Deiodination was strongly inhibited by 2 microM T4 and rT3 (80%) but little by T3 (15%), whereas the clearance of 3,3'-T2 was reduced by 27% (T4 and rT3) and 12% (T3). It is concluded that the rapid hepatic clearance of 3,3'-T2 is determined by the sulfate-transferring capacity of the liver cells. Subsequent outer ring deiodination of the intermediate T2S is inhibited by propylthiouracil and by fasting, essentially without an effect on overall 3,3'-T2 clearance.     

AMNIOTIC FLUID CONCENTRATIONS OF 3,3'',5''-TRI-IODOTHYRONINE (REVERSE T3), 3,3''-DI-IODOTHYRONINE, 3,5,3''-TRI-IODOTHYRONINE (T3) AND THYROXINE (T4) IN NORMAL AND COMPLICATED PREGNANCY

Amniotic fluid concentrations of 3,3',5'-tri-iodothyronine (rT3), 3,3'-Di-iodothyronine (3,3'-T2), 3,5,3'-tri-iodothyronine (T3) and T4 were studied in 384 women during normal and complicated pregnancy. An inverse correlation was observed between decreasing rT3 and increasing 3,3'-T2 concentrations in amniotic fluid with gestational age. The mean rT3 level in normal pregnancy was 2.81 nmol/1 at 12-20 weeks and decreased significantly to 1.06 nmol/1 at 36-42 weeks of gestation. The mean 3,3'-T2 concentration was 49.1 pmol/1 at12-20 weeks increasing to 119 pmol/1 at 36-42 weeks. The mean T4 value of 3.83 nmol/1 at 12-20 weeks was about half that of later periods. The T3 concentration in a random sample of 45 amniotic fluids ranged from less than 28 to 370 pmol/1 (mean 102 pmol/1). The mean rT3, 3,3'-T2 and T4 values measured in patients with intra-uterine malnutrition, gestation diabetes, tocolysis, placental insufficiency and rhesus incompatibility at 31-40 weeks of gestation were not significantly different from those in uncomplicated pregnancy. Significantly decreased rT3 and T4 concentrations were found in toxaemia. From the results obtained in complicated pregnancy it may be concluded that measurements of iodothyronines, especially rT3, in amniotic fluid have insignificant diagnostic value in the recognition of intra-uterine lesions with the probable exception of fetal hypothyroidism. The analysis of the dependence of iodothyronine concentrations on the gestational age showed a maximum of rT3 and T4 levels between 20 and 30 weeks of pregnancy. This marked rise of iodothyronine concentrations in amniotic fluid at mid-gestation may be due to the onsetting maturation of the hypothalamic-pituitary-thyroid control system of the fetus.     

Rapid and selective inner ring deiodination of thyroxine sulfate by rat liver deiodinase

Previous studies have shown that the inner ring deiodination (IRD) of T3 and the outer ring deiodination (ORD) of 3,3'-diiodothyronine are greatly enhanced by sulfate conjugation. This study was undertaken to evaluate the effect of sulfation on T4 and rT3 deiodination. Iodothyronine sulfate conjugates were chemically synthetized. Deiodination was studied by reaction of rat liver microsomes with unlabeled or outer ring 125I-labeled sulfate conjugate at 37 C and pH 7.2 in the presence of 5 mM dithiothreitol. Products were analyzed by HPLC or after hydrolysis by specific RIAs. T4 sulfate (T4S) was rapidly degraded by IRD to rT3S, with an apparent Km of 0.3 microM and a maximum velocity (Vmax) of 530 pmol/min X mg protein. The Vmax to Km ratio of T4S IRD was increased 200-fold compared with that of T4 IRD. However, formation of T3S by ORD of T4S could not be observed. The rT3S formed was rapidly converted by ORD to 3,3'-T2 sulfate, with an apparent Km of 0.06 microM and a Vmax of 516 pmol/min X mg protein. The enzymic mechanism of the IRD of T4S was the same as that of the deiodination of nonsulfated iodothyronines, as shown by the kinetics of stimulation by dithiothreitol or inhibition by propylthiouracil. The IRD of T4S and the ORD of rT3 were equally affected by a number of competitive inhibitors, suggesting a single enzyme for the deiodination of native and sulfated iodothyronines. In conjunction with previous findings on the deiodination of T3S, these results suggest that sulfation leads to a rapid and irreversible inactivation of thyroid hormone.     

Sulfation of thyroid hormone by estrogen sulfotransferase.

Sulfation is one of the pathways by which thyroid hormone is inactivated. Iodothyronine sulfate concentrations are very high in human fetal blood and amniotic fluid, suggesting important production of these conjugates in utero. Human estrogen sulfotransferase (SULT1E1) is expressed among other tissues in the uterus. Here we demonstrate for the first time that SULT1E1 catalyzes the facile sulfation of the prohormone T4, the active hormone T3 and the metabolites rT3 and 3,3'-diiodothyronine (3,3'-T2) with preference for rT3 approximately 3,3'-T2 > T3 approximately T4. Thus, a single enzyme is capable of sulfating two such different hormones as the female sex hormone and thyroid hormone. The potential role of SULT1E1 in fetal thyroid hormone metabolism needs to be considered.     

Synthesis and some properties of sulfate esters and sulfamates of iodothyronines

In the present study, convenient methods have been developed for the synthesis of sulfate derivatives of iodothyronines. Reaction with chlorosulfonic acid in dimethylformamide gave rise to formation of the sulfate ester with the phenolic hydroxyl group. Reaction with the sulfurtrioxide-trimethylamine complex in alkaline medium afforded the sulfamate with the alpha-amino group of the alanine side chain. The sulfated products were isolated by adsorption onto Sephadex LH-20 in acidic medium, followed by desorption with water. Iodide was not retarded on these columns, whereas elution of native iodothyronines required alkaline ethanol mixtures. The yield of both reactions varied between 70-90%. The sulfates and sulfamates of T4, T3, rT3, and 3,3'-diiodothyronine could be separated by reverse phase HPLC. The sulfamates exhibited high cross-reactivities with antibodies against free iodothyronines, in contrast to the low activities of the sulfates. Products were further characterized by proton nuclear magnetic resonance, TLC, and hydrolysis by acid or sulfatase activity. The availability of large quantities of pure iodothyronine sulfates and sulfamates should facilitate the study of the importance of sulfate conjugation in the metabolism of thyroid hormone.     

Altered serum levels of thyroxine, triiodothyronines and diiodothyronines in endogenous depression

Serum levels of thyroxine (T4), 3,3',5-triiodothyronine (T3), 3,3',5-triiodothyronine (rT3), 3,5-diiodothyronine (3,5-T2), 3,3'-diiodothyronine (3,3'-T2) and 3',5'-diiodothyronine (3',5'-T2) were studied in 80 patients with endogenous depression before and after electroconvulsive treatment (ECT). Compared to the values found after recovery, the patients when depressed had significant increased serum levels of T4, rT3, 3,3'-T2 and 3',5'-T2. Serum concentrations of T3 and 3,5-T2 were not significantly altered. Similarly the free T4 index (FT4I) was increased, while the free T3 index (FT3I) was unaffected. Previous studies have shown a reduced TSH response to TRH in patients with endogenous depression and that the long-term outcome after ECT is strongly related to changes in the TSH response. However, patients with increased TSH response to TRH (n = 23) had a pattern of serum iodothyronine concentrations similar to those (n = 57) with an unchanged TSH response. A similar pattern was also found in 7 patients with nonendogenous psychosis, in whom the TSH response to TRH was unchanged after recovery. It is concluded that the alterations of the TSH response to TRH found in endogenous depression cannot be explained by changes of FT4I or FT3I.     

Cloning and characterization of type III iodothyronine deiodinase from the fish Oreochromis niloticus.

Type III iodothyronine deiodinase (D3) catalyzes the inner ring deiodination (IRD) of T4 and T3 to the inactive metabolites rT3 and 3,3'-diiodothyronine (3,3'-T2), respectively. Here we describe the cloning and characterization of complementary DNA (cDNA) coding for D3 in fish (Oreochromis niloticus, tilapia). This cDNA contains 1478 nucleotides and codes for a protein of 267 amino acids, including a putative selenocysteine (Sec) residue, encoded by a TGA triplet, at position 131. The deduced amino acid sequence shows 57-67% identity with frog, chicken, and mammalian D3, 33-39% identity with frog, fish (Fundulus heteroclitus) and mammalian D2, and 30-35% identity with fish (tilapia), chicken, and mammalian D1. The 3' UTR contains a putative Sec insertion sequence (SECIS) element. Recombinant tilapia D3 (tD3) expressed in COS-1 cells and native tD3 in tilapia brain microsomes show identical catalytic activities, with a strong preference for IRD of T3 (Km approximately 20 nM). IRD of [3,5-125I]T3 by native and recombinant tD3 are equally sensitive to inhibition by substrate analogs (T3 > T4 > rT3) and inhibitors (gold thioglucose > iodoacetate > propylthiouracil). Northern analysis using a tD3 riboprobe shows high expression of a 1.6-kb messenger RNA in gill and brain, although D3 activity is much higher in brain than in gill. The characterization of tD3 cDNA provides new information about the structure-activity relationship of iodothyronine deiodinases and an important tool to study the regulation of thyroid hormone bioactivity in fish.     

The effect of thyroid dysfunction and fasting on placenta inner ring deiodinase activity in the rat

The placenta contains iodothyronine 5-deiodinase activity (P5-Dase) that probably acts on iodothyronines in the fetal circulation to convert T4 to rT3 and T3 to 3,3'-T2. Since thyroid status and fasting have profound effects on iodothyronine deiodinases in other tissues, the present studies were performed to determine if these perturbations affected P5-Dase. Control and treated rats were mated and killed near term on the 20th day of gestation. P5-Dase was determined in placenta homogenates enriched with dithiothreitol by measuring the conversion of T4 to rT3. In four of five studies, P5-Dase was similar in dams that underwent thyroidectomy (Tx) on day 7 of gestation and sham Tx dams. P5-Dase was not altered in dams that were treated with methimazole (MMI) to induce maternal and fetal hypothyroidism. Treatment of dams with supraphysiological doses of T4, beginning on the seventh day of gestation, did not significantly affect P5-Dase. In three of four studies, P5-Dase was similar in fed dams to values in dams fasted for the last 5 days of pregnancy. Placenta iodothyronine 5'-deiodinase activity (P5'-Dase) was also measured in some studies. P5'-Dase was not decreased in Tx rats and was modestly decreased in MMI-treated rats. However, the effect of MMI was not reversed by the administration of supraphysiological doses of T4, Tx, MMI treatment, and fasting all decreased hepatic T4 5'-deiodinase activity in pregnant rats. These results strongly suggest that thyroid status and fasting do not alter P5-Dase activity.     

Renal handling of thyroxine, 3,5,3'- and 3,3',5'-triiodothyronine, 3,3'- and 3',5'-diiodothyronine in man

The 24-h urinary excretion and renal clearance of thyroxine (T4), 3,5,3'-triiodothyronine (T3), 3,3',5'-triiodothyronine (rT3), 3,3'-diiodothyronine (3,3'-T2), and 3',5'-diiodothyronine (3',5'-T2) were measured in 17 healthy subjects. The median urinary excretion was (pmol/24h) T4: 1242, T3: 828, rT3: 12.9, 3,3'-T2: 331, and 3',5'-T2: 5.8. The corresponding renal clearances were in median (ml/min) T4: 31, T3: 133, rT3: 15, 3,3'-T2: 683, and 3',5'-T2: 4.5. The clearances differed mutually (P less than 0.01) as well as from the creatinine clearance (P less than 0.01) which was in median 87 ml/min. Thus, all iodothyronines studied were subject to tubular transport mechanisms besides glomerular filtration. The 3 iodothyronines with 2 iodine atoms in the phenolic ring of the thyronine molecule, T4, rT3 and 3',5'-T2, were mainly tubularly reabsorbed, whereas those with only one iodine atom in the phenolic ring, T3 and 3,3'-T2, were mainly tubularly secreted. It might be hypothesized that the number of iodine atoms in the phenolic ring determines the direction of the tubular transport (presence of 2 iodine atoms is associated with tubular reabsorption, and of one iodine atom with secretion), whereas the rate of tubular transport decreases with decreasing number of iodine atoms in the tyrosylic ring.     

Phenolic and tyrosyl ring iodothyronine deiodination by the Caco-2 human colon carcinoma cell line

Thyroid hormone metabolism was studied in the human Caco-2 colon carcinoma cell line, which at confluence exhibits several functions of differentiated enterocytes. Cells were harvested two to 17 days after reaching confluence. Intact cells and homogenates were tested for deiodination of [125I]-labeled substrates. Small amounts of thyroxine (T4) were converted by homogenates to 3,3',5'-triiodothyronine (rT3), 3,3'-diiodothyronine (3,3'-T2), and 1-, with no detectable production of 3,5,3'-triiodothyronine (T3) by homogenates or cells. rT3 was converted to 3,3'-T2 and 1- with an apparent Michaelis constant (Km) for rT3 of 24 nmol/L; 6-n-propyl-2-thiouracil (PTU) had a 50% inhibitory concentration of 30 nmol/L and abolished rT3 5'-deiodination at 1 mmol/L in the presence of 20 mmol/L dithiothreitol (DTT). T3 was deiodinated to 3,3'-T2 and 3'-monoiodothyronine (3'-T1) with an apparent Michaelis constant (Km) for T3 of 5.7 nmol/L; this reaction was not inhibited by 1 mmol/L PTU. Phenolic and tyrosyl ring deiodinating activities were maximal four and six days, respectively, after the cells reached confluence. Homogenates of cells grown in standard medium containing fetal calf serum had fivefold higher rT3 5'-deiodinating activity than cells grown in a serum-free defined culture medium, reflecting a fivefold difference in the apparent Vmax with no difference in the apparent Km for rT3. There was no difference in T3 5-deiodination rates in homogenates of Caco-2 cells grown in the two media until 12 days postconfluence, when cells grown in standard medium had higher activity.(ABSTRACT TRUNCATED AT 250 WORDS)     

Comparative aspects of the distribution, metabolism, and excretion of six iodothyronines in the rat

We have studied the kinetics of 3 iodothyronines, 3,3'-diiodothyronine (T2), 3',5'-T2, and 3'-monoiodothyronine (T1), in groups of young adult male rats maintained under normal steady state physiological conditions. We have also performed a comparative analysis of these results, combined with corresponding kinetic indices of T4, T3, and rT3, to obtain a more comprehensive understanding of normal thyroid hormone production, distribution, and metabolism. Tracer doses of 125I-labeled 3,3'-T2, 3',5'-T2, and 3'-T1 were separately injected iv, and blood samples were collected 6-12 times for each iodothyronine in optimized sequential kinetic studies designed to maximize the precision of kinetic parameters. Labeled iodothyronines were separated quantitatively from their metabolites in each plasma sample by Sephadex G-25 column chromatography. Conventional kinetic analysis of the resulting data generated distribution volume, clearance, turnover, and mean residence time indices for each iodothyronine, and concomitant compartmental analysis of the same data provided additional results useful for integration and comparative analysis of the 6 iodothyronines. Kinetic parameters for all but T4 and T3 were similar, suggesting that similar mechanisms are responsible for the transport, metabolism, and distribution of nonhormonal iodothyronines. All but T4 and T3 (and, to a much lesser extent, 3'-T1) were almost completely and irreversibly metabolized, whereas 24-30% of the hormones (and 6% of 3'-T1) were excreted as such in feces only. Three-pool models fitted individual plasma kinetic data sets best in all cases (for all 6 iodothyronines), each with a plasma, a slowly exchanging (slow), and a rapidly exchanging (fast) pool, and kinetic parameters of interest were quantified for each iodothyronine (Ti). Quantitative analysis of an integrated 18-pool model for all 6 Tis revealed several other features of physiological interest. The fractional transport rate of T3 into the fast pool (liver, at least) is about an order of magnitude larger than that for all other Tis, supporting the hypothesis that transport of T3 into fast tissues (e.g. liver cells) is selectively amplified relative to that of the 5 other iodothyronines studied. Simultaneous and direct comparison of the 6 plasma kinetic data sets also supports this result. In addition, composite slow tissue pools, which probably exclude liver and kidney, contained the largest whole body fractions of all Tis (greater than 50%), and these also appear to be major sites of whole body T4 monodeiodinations.(ABSTRACT TRUNCATED AT 400 WORDS)     

Simultaneous turnover studies of thyroxine, 3,5,3' and 3,3',5'-triiodothyronine, 3,5-, 3,3'-, and 3',5'- diiodothyronine, and 3'-monoiodothyronine in chronic renal failure

The present study evaluates the sequential extra-thyroidal monodeiodination of thyroid hormones through tri-, di-, and monoiodothyronines in chronic renal failure (CRF) in man. Simultaneous turnover studies of T4, T3, rT3, 3,5-diiodothyronine (3,5-T2), 3,3'-T2, 3',5'-T2, 3'5'-T2, and 3'-monoiodothyronine (3--T1) were conducted in six patients with CRF (creatinine clearance, 9-18 ml/min) using the single-injection, noncompartmental approach. Serum levels of T4, T3, and 3,5-T2 were reduced to two thirds of control levels (P less than 0.05), whereas serum rT3 and 3,3'-T2 levels were reduced to a minor degree. Serum 3'-5'-T1 was doubled (p less than 0.05). The MCRs of T4, rT3, and 3',5'-T2 were enhanced to 168%, 127%, and 187% of normal (P less than 0.05), respectively, whereas those of T3, 3,5-T2, 3,3'-T2, and 3'-T1 were unaffected. The mean production rates (PRs) of the iodothyronines in CRF were as follows (CRF vs. control values, expressed as nanomoles per day/70 kg): T4, 119 vs. 125; T3, 26 vs. 44 (P less than 0.01); rT3, 49 vs, 48; 3,5-T2, 3.5 vs. 7.2 (P less than 0.001); 3,3'-T2, 25 vs. 35 (P less than 0.01); 3',5'-T2, 25 vs. 14 (P less than 0.01); and 3'-T1, 39 vs. 30. Previous studies have demonstrated reduced phenolic ring (5'-) deiodination of T4 in CRF, which is supported by the present finding of unaltered PR of T4 and reduced PR of T3. In contrast the 5'-deiodination of T3 leading to the formation of 3,5-T2 was found unaffected by CRF, since the conversion rate (CR) of T3 to 3,5-T2 (PR 3,5-T2/PR T3) was unaltered (16% vs. 15% in controls). The tyrosylic ring (5-) deiodination of T4 to rT3 was unaffected in patients with CRF, the CR being 42% vs. 40% in controls, in contrast to an enhanced CR of rT3 to 3',5'-T2 (53% vs. 29%, P less than 0.01), which also is a 5-deiodination step. In conclusion, our data show that CRF profoundly changes the kinetics of all iodothyronines studied. Furthermore, our data are compatible with the existence of more than one 5'-deiodinase as well as more than one 5-deiodinase in man.     

Deiodination of thyroid hormone by human liver

Liver is an important site for the peripheral production of T3 by outer ring deiodination (ORD) of T4 as well as for the clearance of plasma rT3, which is produced by inner ring deiodination (IRD) of T4 in other tissues. However, little is known about the underlying enzymatic reactions, and current concepts about thyroid hormone deiodination are largely based on studies in rat tissue. Here we describe the results of detailed studies of the catalytic properties of the iodothyronine deiodinase activity of human liver. The results demonstrated a high degree of similarity with the type I deiodinase of rat liver. The enzyme activity was found in the microsomal fraction. rT3 was the preferred substrate, since its ORD was catalyzed roughly 400 times more efficiently than the ORD or IRD of T4 or the IRD of T3. The deiodination of sulfated substrates was more rapid, as demonstrated by the roughly 30-fold increase in the IRD of T3 sulfate (T3S) compared with T3. The deiodinations exhibited ping-pong-type kinetics with dithiothreitol as the cofactor. Inhibition by propylthiouracil was uncompetitive with substrate and competitive with dithiothreitol, and PTU was an equally effective inhibitor of the ORD of rT3 and the IRD of T3S (Ki, 0.10-0.16 mumol/L). Various compounds with widely different inhibitory potencies had similar effects on ORD (rT3) and IRD (T3S). These results suggest that in human liver microsomes a single enzyme catalyzes the deiodination of the outer as well as the inner ring of iodothyronines by the same catalytic mechanism and with the same substrate specificity as the type I deiodinase of rat liver.