A Thyroid Hormone-Independent Molecular Fingerprint of 3,5-Diiodothyronine Suggests a Strong Relationship with Coffee Metabolism in Humans.

Background: In numerous studies based predominantly on rodent models, administration of 3,5-diiodo-L-thyronine (3,5-T2), a metabolite of the thyroid hormones (TH) thyroxine (T4) and triiodo-L-thyronine (T3), was reported to cause beneficial health effects, including reversal of steatohepatosis and prevention of insulin resistance, in most instances without adverse thyrotoxic side effects. However, the empirical evidence concerning the physiological relevance of endogenously produced 3,5-T2 in humans is comparatively poor. Therefore, to improve the understanding of 3,5-T2-related metabolic processes, we performed a comprehensive metabolomic study relating serum 3,5-T2 concentrations to plasma and urine metabolite levels within a large general population sample. Methods: Serum 3,5-T2 concentrations were determined for 856 participants of the population-based Study of Health in Pomerania-TREND (SHIP-TREND). Plasma and urine metabolome data were generated using mass spectrometry and nuclear magnetic resonance spectroscopy, allowing quantification of 613 and 578 metabolites in plasma and urine, respectively. To detect thyroid function-independent significant 3,5-T2-metabolite associations, linear regression analyses controlling for major confounders, including thyrotropin and free T4, were performed. The same analyses were carried out using a sample of 16 male healthy volunteers treated for 8 weeks with 250 µg/day levothyroxine to induce thyrotoxicosis. Results: The specific molecular fingerprint of 3,5-T2 comprised 15 and 73 significantly associated metabolites in plasma and urine, respectively. Serum 3,5-T2 concentrations were neither associated with classical thyroid function parameters nor altered during experimental thyrotoxicosis. Strikingly, many metabolites related to coffee metabolism, including caffeine and paraxanthine, formed the clearest positively associated molecular signature. Importantly, these associations were replicated in the experimental human thyrotoxicosis model. Conclusion: The molecular fingerprint of 3,5-T2 demonstrates a clear and strong positive association of the serum levels of this TH metabolite with plasma levels of compounds indicating coffee consumption, therefore pointing to the liver as an organ, the metabolism of which is strongly affected by coffee. Furthermore, 3,5-T2 serum concentrations were found not to be directly TH dependent. Considering the beneficial health effects of 3,5-T2 administration observed in animal models and those of coffee consumption demonstrated in large epidemiological studies, one might speculate that coffee-stimulated hepatic 3,5-T2 production or accumulation represents an important molecular link in this connection.

Fetal-to-maternal transfer of thyroid hormone metabolites in late gestation in sheep.

3,3'-Diiodothyronine sulfate (T2S) derived from T3 of fetal origin is transferred to the maternal circulation and contributes significantly to the maternal urinary pool. The present study quantitatively assesses the fetal to maternal transfer of T4 metabolites compared with those of T3. Labeled T4 or T3 was infused intravenously to four singleton fetuses in utero in each group at gestational age 138 +/- 3 d. Maternal and fetal serum and maternal urine samples were collected hourly for 4 h and at 24 h (serum) or in pooled 4-24 h samples (urine). Radioactive metabolites were identified by HPLC and by specific antibody in serum and urine extracts and expressed as percentage infusion dose per liter. The results demonstrate a rapid clearance of labeled T3 from fetal serum (disappearance T(1/2) of 0.7 h versus 2.4 h for T4 in the first 4 h). The metabolites found in fetal serum after labeled T3 infusion were T2S > T3 > T3S; in maternal urine, T2S > unconjugated iodothyronines (UI) > T3S > unknown metabolite (UM). After labeled T4 infusion, the metabolites in fetal serum were rT3 > T3 > T2S > T4S in the first 4 h, and rT3 = T3 = T4S = T2S > T3S at 24 h; in maternal urine we found T2S > UM > UI > T4S > T3S in the first 4 h and UM > T2S > UI in 4-24 h pooled sample. In conclusion, the conversion of T3 to T2S followed by fetal to maternal transfer of T2S and other iodothyronines appears to contribute importantly to maintaining low fetal T3 levels in late gestation.

A radioimmunoassay for measurement of 3,3'-diiodothyronine sulfate: Studies in thyroidal and nonthyroidal diseases, pregnancy, and fetal/neonatal life.

Data suggesting that (1) sulfation of the phenolic hydroxyl of iodothyronines plays an important role in thyroid hormone metabolism and (2) maternal serum 3,3'-diiodothyronone sulfate (3,3'-T(2)S) may reflect on the status of fetal thyroid function stimulated us to develop a radioimmunoassay (RIA) for measurement of T(2)S. Our T(2)S RIA is highly sensitive, practical, and reproducible. T(4)S, T(3)S, and T(1)S crossreacted 3.1%, 0.81%, and 5.3%, respectively; thyroxine (T(4)), triiodothyronine (T(3)), and reverse (r)T(3), 3,3'-T(2) and 3'-T(1) crossreacted <0.1%. Although rT(3) sulfate (rT(3)S) crossreacted 55% in 3,3'-T(2)S RIA, its serum levels are very low and have little influence on serum T(2)S values reported here. T(2)S was measured in ethanol extracts of serum, amniotic fluid, and urine. Recovery of nonradioactive T(2)S added to serum was 96%. The dose-response curves of inhibition of binding of (125)I-T(2)S to anti-T(2)S by serial dilutions of ethanol extracts of serum or urine were essentially parallel to the standard curve. The detection threshold of the RIA varied between 0.17 and 0.50 nmol/L (or 10 and 30 ng/dL). The coefficient of variation (CV) averaged 9% within an assay and 13% between assays. The serum concentration of T(2)S was [mean +/- SE, nmol/L] 0.86 +/- 0.59 in 36 normal subjects, 2.2 +/- 0.06 in 10 hyperthyroid patients (P <.05), 0.73 +/- 0.10 in 11 hypothyroid patients (not significant [NS]), 6.0 +/- 1.5 in 16 patients with systemic nonthyroidal illness (P <.001), 18 +/- 2.5 in 16 newborn cord blood sera (P <.02), 2.7 +/- 0.32 in 25 pregnant women [15 to 40 weeks gestation, P <.001], 0.94 +/- 0.10 in 10 hypothyroid women receiving T(4) replacement therapy (NS), and 2.0 +/- 0.38 in 11 hypothyroid women treated with T(4) replacement and oral contraceptives (P <.02); serum T(2)S levels in the third trimester of pregnancy were similar to those in the second trimester of pregnancy. T(2)S concentration in amniotic fluid was 12.5 +/- 2.7 nmol/L (n = 7) at 15 to 20 weeks gestation, and it decreased markedly to 3.3 +/- 1.3 nmol/L (n = 3) at 35 to 38 weeks gestation. Urinary excretion of T(2)S in random urine samples of 19 normal subjects was 10.9 +/- 1.3 nmol/g creatinine. (1) T(2)S is a normal component of human serum, urine, and amniotic fluid, and serum T(2)S levels change substantially in several physiologic and pathologic conditions; (2) high serum T(2)S in pregnancy may signify increased transfer of T(2)S from fetal to maternal compartment, estrogen-induced increase in T(2)S production, decreased clearance, or a combination of these factors. The data do not support the notion that fetal thyroid function is the only or the predominant factor responsible for high serum T(2)S in pregnant women.

3,3'-Diiodothyronine sulfate excretion in maternal urine reflects fetal thyroid function in sheep.

We have shown that there is significant fetal-to-maternal transfer of sulfated metabolites of thyroid hormone after fetal infusion of a pharmacologic amount of 3,3',5-triiodothyronine (T(3)) or sulfated T(3) in late pregnancy in sheep (Am J Physiol 277:E915, 1999). The transferred iodothyronine sulfoconjugate, i.e. 3,3'-diiodothyronine sulfate (T(2)S), of fetal origin appears in maternal sheep urine. The present study was carried out to assess the contribution of T(2)S of fetal origin to the urinary pool in ewes. Eighteen date-bred ewes (mean gestational age of 115 d) and their twin fetuses were divided into four groups. In group I (control, n = 5), both ewes (M) and their fetuses (F) were sham operated for thyroidectomy (Tx). In group II, the ewes (MTx, n = 4) and, in group III, the fetuses (FTx, n = 4) were subjected to Tx. In group IV (MTx.FTx, n = 5), both the ewe and fetus had Tx. After 10-12 d, fetal and/or maternal hypothyroidism were confirmed by serum thyroxine (<15 nmol/L) measurements. In addition, we infused radioactive T(3) without disturbing the T(3) pool in three singleton near-term fetuses and assessed the amount of radioactive iodothyronine that appeared in maternal urine (MU). After infusing [(125)I-3'],3,5-T(3) via fetal vein to the near-term normal fetuses, radioactive T(2)S was identified as the major metabolite in MU by HPLC and T(2)S-specific antibody. MU T(2)S excretion (pmol/mmol creatinine) was significantly reduced by FTx and MTx.FTx but not by MTx. In addition, positive correlations (p < 0.01) were found between MU T(2)S excretion and fetal serum thyroxine and T(3) concentrations but not with maternal serum thyroxine or T(3) levels. T(2)S of fetal origin contributes significantly to the MU pool.

Maternal compound W serial measurements for the management of fetal hypothyroidsm.

OBJECTIVE: The diagnosis of fetal hypothyroidism is based at present on measurements of TSH and free thyroxine (FT4) in fetal blood samples obtained by cordocentesis. The measurement of maternal serum and urinary concentrations of compound W, immunologically similar to but chromatographically distinct from diiodothyronine sulfate (T2S), has been advocated as a new possible marker for fetal hypothyroidism. DESIGN: In this paper, we measured serum compound W levels in 84 pregnant women, 20 with and 64 without thyroid disorders before and during specific treatment. Compound W was also assessed in fetal blood obtained by cordocentesis from 49 normal fetuses and 4 fetuses with suspected hypothyroidism due to transplacental passage of propylthiouracil (PTU). Compound W levels were measured by T2S RIA in maternal and fetal serum. To assess the possible usefulness of 3, 5,3'-triiodothyroacetic acid (TRIAC) for therapy of fetal hypothyroidism we evaluated the transplacental passage of TRIAC by administering the drug to four pregnant women before therapeutic abortion. RESULTS: In normal pregnancies, both maternal and fetal compound W levels increased progressively during gestation with a significant direct correlation (P<0.001, in both mothers and fetuses). Moreover, a significant positive correlation was observed between fetal compound W and fetal FT4 values (P<0.005), whereas no correlation was observed between maternal serum compound W and maternal FT4 in either euthyroid or hyperthyroid women, suggesting the fetal origin of compound W. The hypothyroid fetuses of PTU-treated mothers showed low compound W levels, and maternal compound W values were in the low normal range and did not show the typical increase during progression of gestation. A significant increase of maternal compound W was observed when the PTU dose was reduced. TRIAC was documented to cross the placental barrier and the treatment of a hyperthyroid pregnant woman on PTU caused the high fetal TSH levels and goiter to normalize. CONCLUSIONS: Serial measurements of 3,3'-T2S crossreactive materials (compound W and 3, 3'-diiodothyroacetic acid sulfate) in maternal blood and the administration of TRIAC to the mother may represent a useful and safe alternative to invasive techniques for the diagnosis and therapy of fetal hypothyroidism.

Fetal-to-maternal transfer of 3,3',5-triiodothyronine sulfate and its metabolite in sheep.

Earlier studies have shown that sulfoconjugation is a major pathway of thyroid hormone metabolism in fetal mammals. To assess the placental transfer of sulfoconjugates in the pregnant sheep model, we measured 3,3',5-triiodothyronine (T(3)) sulfate (T(3)S), 3, 3'-diiodothyronine sulfate (T(2)S), and T(3) concentrations in fetal serum and in maternal serum and urine after T(3)S infusion to the fetus (n = 5) or the ewe (n = 6). Maternal infusion of T(3)S did not increase fetal serum T(2)S, T(3)S, or T(3) concentrations. In contrast, fetal infusion of T(3)S produced significant increases in maternal serum T(2)S and T(3)S but not T(3) concentrations. Fetal T(3)S infusion also increased maternal urine excretion of T(3)S. However, the 4-h cumulative maternal urinary excretion of T(2)S and T(3)S after fetal T(3)S infusion was less than the excretion observed after fetal infusion of equimolar amounts of T(3) in our previous study. It is concluded that fetal serum T(2)S and T(3)S can be transferred to maternal compartments. However, compared with T(3), these sulfoconjugates may be less readily transferred.

Urinary compound W in pregnant women is a potential marker for fetal thyroid function.

OBJECTIVE: Previously we reported 3,3'-diiodothyronine sulfate-like material (compound W) in maternal serum, and studies suggest that compound W is derived from thyroid hormones of fetal origin. In this study we characterized gestational changes of urinary compound W concentrations to correlate with changes in serum concentrations. STUDY DESIGN: Urinary samples were collected from 94 women at various gestational ages ranging from 3 to 40 weeks. Urinary compound W was first identified biochemically. The concentrations of compound W (adjusted for creatinine levels) were assessed by a 3,3'-diiodothyronine sulfate radioimmunoassay in ethanol extracts of urine samples. RESULTS: Compound W increased to 88 +/- 1.4 pmol (of 3,3'-diiodothyronine sulfate equivalent)/mmol creatinine in urinary samples obtained from 26 women in the first trimester of pregnancy compared with 40 +/- 6.9 pmol/mmol creatinine in 10 nonpregnant women. Excretion of compound W increased further during the second and third trimesters: 171 +/- 17 (n = 18) and 434 +/- 26 (n = 50) respectively. In contrast, urinary 3,3',5-triiodothyronine sulfate concentrations measured by radioimmunoassay were similar during pregnancy to values in nonpregnant women. CONCLUSIONS: Urinary compound W concentrations increase with the progression of normal pregnancy and correlate with the increase in serum levels. Random spot urine compound W concentrations, adjusted for creatinine levels, may be used in place of serum levels in conditions in which obtaining serum samples may be technically difficult, especially during population screening.

Identification of 3,3'-T2S as a fetal thyroid hormone derivative in maternal urine in sheep.

We measured 3,3'-diiodothyronine sulfate (T2S) in serum and urine (n = 5-6) obtained from euthyroid fetal (94-145 days of gestation, term = 150 days), newborn, and adult sheep and in serum and urine samples from ovine fetuses 13 days after total thyroidectomy conducted between 110 and 113 gestation days (n = 5). Sham-operated twin fetuses served as controls (n = 5). Mean serum T2S concentrations increased progressively from 94 days (74 ng/dl) to 130 days (420 ng/dl), decreasing thereafter to 145 days (197 ng/dl). T2S concentrations in fetal urine peaked at 110 days (117 ng/dl). In hypothyroid fetuses, mean serum and urine T2S were 60 and 53% of control values. To assess the possibility that the T2S in maternal serum/urine is derived from fetal serum 3,5,3'-triiodothyronine (T3), we measured T3, T3 sulfate (T3S), and T2S in fetal serum and in maternal serum and urine after bolus infusion of T3 to the fetus (n = 4). Additionally, T3, T3S, and T2S concentrations were measured in maternal serum and urine after T3 infusion to the maternal ewes (n = 4). Fetal T3 infusion rapidly increased fetal serum T3S and T2S. Maternal serum and urine T3S and T2S concentrations increased, whereas T3 concentrations remained unchanged. Maternal T3 infusion increased in serum and urine T3S and T2S levels, but the levels, relative to T3, were less than values measured after fetal T3 infusion. We conclude that T2S is a normal thyroid hormone metabolite in the ovine fetus and suggest that a major pathway of fetal T2S production is T3 to T3S to T2S.(ABSTRACT TRUNCATED AT 250 WORDS)

Renal handling of iodothyronines in acromegaly.

Measurement of the free serum concentration, the 24-h urinary excretion and the renal clearance of T4, T3, 3,3',5'-tri-iodothyronine (rT3), 3',5'-diiodothyronine (3',5'-T2) and 3,3'-di-iodothyronine (3,3'-T2) was performed in 13 patients with active acromegaly and in 18 healthy controls. The acromegalic patients had normal serum levels of the free iodothyronines, whereas the urinary excretion of T4 and T3 was increased approximately two-fold in the patients with acromegaly. The creatinine clearance, reflecting the glomerular filtration rate (GFR), was increased in the acromegalic patients, in median 133 ml/min versus 87 ml/min (p less than 0.01) in the controls. Compared to the creatinine clearance the clearance of T3 and 3,3'-T2 was higher (p less than 0.01) in acromegalics as well as in controls. The patients with acromegaly had higher renal clearance of T4 and T3 than controls, in median 81 ml/min versus 33 ml/min, and 269 ml/min versus 137 ml/min, respectively (p less than 0.01). These differences were not due to changes in creatinine clearance. The renal clearance of 3',5'-T2 tended to be enhanced in acromegalic patients (8.2 ml/min versus 3.9 ml/min, p less than 0.10), both before and after correction for creatinine clearance. The data suggest that in acromegaly, as in normal condition, iodothyronines are subject to both glomerular filtration and active tubular transport mechanisms. Further, active acromegaly results not only in increased GFR, but also in changes of the net tubular transport in favour of secretion of at least T4 and T3, and possibly also of 3',5'-T2.

Urinary excretion of unconjugated and conjugated 3,5-diiodothyronine.

A radioimmunoassay for the estimation of 3,5-diiodothyronine (3,5-T2) in human urine has been established. The urinary excretion of both glucuronide and sulfate conjugates of 3,5-T2 were estimated after enzymatic deconjugation. In 19 healthy controls the median excretion of unconjugated 3,5-T2 was 276 pmol/d, whereas the median excretion of glucuronidated and sulfated 3,5-T2 in 7 healthy subjects was 448 and 451 pmol/d, respectively. The median excretion of 154 pmol/d in 9 hypothyroid patients did not differ from that found in controls. In contrast 12 patients with hyperthyroidism had an enhanced excretion, 1312 pmol/d (P less than 0.01). Compared with previous data on the daily degradation of 3,5-T2, it is concluded that approximately one-sixth of degradated 3,5-T2 is excreted in the urine.

Urinary excretion of free and conjugated 3',5'-diiodothyronine and 3,3'-diiodothyronine.

RIAs for the estimation of 3',5'-diiodothyronine (3',5'-T2) and 3,3'-diiodothyronine (3,3'-T2) in human urine have been established. The urinary excretion of both glucuronide and sulfate conjugates of T2 and of T4, T3, and rT3 were estimated by means of enzymatic deconjugation. In healthy controls, the mean excretion (picomoles per 24 h) of free T4 was 1820, that of free T3 was 813, that of free rT3 was 77, that of free 3',5'-T2 was 13, and that of free 3,3'-T2 was 674. The total excretion of free and conjugated T4 was 2941, that of T3 was 1283, that of rT3 was 791, that of 3',5'-T2 was 709, and that of 3,3'-T2 was 2688. Significant amounts of sulfated T4 and T3 could not be demonstrated, amounts of sulfated T4 and T3 could not be demonstrated, whereas the excretion of sulfated rT3 was higher than that of glucuronidated rT3 (P less than 0.001). In contrast, glucuronidated and sulfated 3',5'-T2 as well as glucuronidated and sulfated 3,3'-T2 were found in the urine in equal amounts. In hyperthyroidism, the excretions of free and glucuronidated iodothyronines were increased, whereas the increase of the excretions of sulfated iodothyronines were less pronounced, only reaching statistical significance for 3,3'-T2 (P less than 0.02). In hypothyroidism, the excretions of both free, glucuronidated and sulfated iodothyronines were reduced. Significant amounts of sulfated T4 and T3 could not be demonstrated in urine from hyperthyroid or hypothyroid patients. Our data demonstrate that the amounts of free iodothyronines excreted in the urine vary considerably, suggesting active renal handling. The amounts of urinary glucuronidated and sulfated conjugates of the different iodothyronines studied vary considerably and are affected by thyroid function.