Thyroid Hormones and Methylmercury Toxicity

Thyroid hormones are essential for cellular metabolism, growth, and development. In particular, an adequate supply of thyroid hormones is critical for fetal neurodevelopment. Thyroid hormone tissue activation and inactivation in brain, liver, and other tissues is controlled by the deiodinases through the removal of iodine atoms. Selenium, an essential element critical for deiodinase activity, is sensitive to mercury and, therefore, when its availability is reduced, brain development might be altered. This review addresses the possibility that high exposures to the organometal, methylmercury (MeHg), may perturb neurodevelopmental processes by selectively affecting thyroid hormone homeostasis and function.     

Thyroid Hormones and Derivatives Inhibit Flunitrazepam Binding

Thyroid hormones and their derivatives were found to inhibit [3H]flunitrazepam binding stereospecifically and in a monophasic manner. Among the compounds tested, D-thyroxine was the most potent inhibitor (IC50 = 0.5 microM). The naturally occurring L-thyroxine was about 40-fold less potent (IC50 = 20 microM). The structure-activity relationships seem to imply that the thyronine base has the principal role in the inhibition of benzodiazepine receptor binding. The type of inhibition was examined with the most potent inhibitor, D-thyroxine, by Scatchard analysis. The apparent dissociation constant (KD) of the [3H]flunitrazepam binding increased and the receptor density (Bmax) decreased as a function of D-thyroxine concentration; this is characteristic of mixed-type inhibition.     

Thyroid Hormones Regulate Selenoprotein Expression and Selenium Status in Mice

Impaired expression of selenium-containing proteins leads to perturbed thyroid hormone (TH) levels, indicating the central importance of selenium for TH homeostasis. Moreover, critically ill patients with declining serum selenium develop a syndrome of low circulating TH and a central downregulation of the hypothalamus-pituitary-thyroid axis. This prompted us to test the reciprocal effect, i.e., if TH status would also regulate selenoprotein expression and selenium levels. To investigate the TH dependency of selenium metabolism, we analyzed mice expressing a mutant TH receptor α1 (TRα1+m) that confers a receptor-mediated hypothyroidism. Serum selenium was reduced in these animals, which was a direct consequence of the mutant TRα1 and not related to their metabolic alterations. Accordingly, hyperthyroidism, genetically caused by the inactivation of TRβ or by oral TH treatment of adult mice, increased serum selenium levels in TRα1+m and controls, thus demonstrating a novel and specific role for TRα1 in selenium metabolism. Furthermore, TH affected the mRNA levels for several enzymes involved in selenoprotein biosynthesis as well as serum selenoprotein P concentrations and the expression of other antioxidative selenoproteins. Taken together, our results show that TH positively affects the serum selenium status and regulates the expression of several selenoproteins. This demonstrates that selenium and TH metabolism are interconnected through a feed-forward regulation, which can in part explain the rapid parallel downregulation of both systems in critical illness.     

甲状腺激素对适应性免疫细胞的作用

摘要：甲状腺激素（Thyroid hormones,THs）参与免疫功能的调节,在固有免疫和适应性免疫中发挥着重要作用。THs异常分泌所致的免疫功能失调被认为参与了格雷夫斯病和桥本甲状腺炎等自身免疫性疾病的发生发展。目前,THs在固有免疫细胞（中性粒细胞、巨噬细胞、树突状细胞、自然杀伤细胞、肥大细胞）中的作用已得到了较好的阐明,但THs对适应性免疫细胞（T淋巴细胞与B淋巴细胞）的影响等方面的研究仍未引起足够的重视。因此,本研究从适应性免疫细胞的角度出发,重点讨论了THs对这些细胞的发育、分化及功能等方面的影响,为进一步理解THs调节免疫功能的作用提供新视角。     

Dietary Iodine Affected the GSH-Px to Regulate the Thyroid Hormones in Thyroid Gland of Rex Rabbits

Iodine (I) is an essential trace element that can influence animal health and productivity. In this study, we investigated the effects of dietary iodine on the antioxidant indices of organ (liver and thyroid gland) and messenger RNA (mRNA) expression of glutathione peroxidase (GSH-Px) in Rex rabbits. A total of 120 4-month-old Rex rabbits (2235.4 ± 13.04 g BW) were divided into four equal groups, and their diets were supplemented with iodine (0, 0.2, 2, or 4 mg/kg dry matter (DM)). The iodine concentration in basal diet (control group) was 0.36 mg/kg DM. In most of measured parameters, supplemental iodine exerted no significant effect. Growth and slaughter performance and organ weight were not influenced significantly by iodine supplementation. Serum T₃ was significantly lower in 2-mg I group than in 0.2 and 4-mg I groups (P < 0.05). Superoxide dismutase (SOD), GSH-Px, methane dicarboxylic aldehyde (MDA), and thyroperoxidase (TPO) in the serum and liver were not influenced (P > 0.05). Conversely, serum catalase (CAT) was significantly reduced (P < 0.05). In the thyroid, GSH-Px was higher in the 2-mg I group than in the 0.2- and 4-mg I groups (P < 0.05). RT-PCR results showed that the mRNA expression level of GSH-Px in the liver was not significantly influenced (P > 0.05). In the thyroid gland, the mRNA expression level of GSH-Px was higher in the 2-mg I group than in the 4-mg I group (P < 0.05), which agreed with the activity of GSH-Px. In conclusion, iodine supplementation exerted no effect on the performance and antioxidant capacity of the body, but dietary iodine influenced serum T₃ or GSH-Px in the thyroid gland. Thus, on the basis of serum T₃ and GSH-Px levels in the thyroid gland, we hypothesized that GSH-Px secretion was increased by adding dietary iodine in the thyroid, which may inhibit the H₂O₂ generation and further influence the thyroid hormone synthesis.     

Effect of Thyroid Hormones on Benzodiazepine Receptors in Neuron-Enriched Primary Cultures

The effect of administration of thyroid hormones on central benzodiazepine receptors was investigated using neuron-enriched primary cultures obtained from the neopallium of 16-day-old embryonic rats. Addition of L-triiodothyronine for 3 days decreased the maximal number of benzodiazepine receptor binding sites without any change in affinity at 10(-5) and 10(-6) M. L-Thyroxine administered for 3 days had the same effect at 10(-5) M. No significant change was observed over periods of less than 3 days, a finding indicating that this inhibition was not a direct in vitro effect. This down-regulation seems to be a direct modulatory effect of thyroid hormones on cerebral cortical neurons. Addition for 3 days of D-thyroxine and D-triiodothyronine, which are physiologically inactive isomers of the thyroid hormones, did not induce any significant alterations in benzodiazepine receptors. The decrease in number of cerebral cortical neuronal benzodiazepine receptors due to L-isomers of thyroid hormones may be related to the convulsions and anxiety observed in thyrotoxicosis in humans.     

Regulation by Thyroid Hormones of Glucose Transport in Cultured Rat Myotubes

Primary cultures of skeletal muscle obtained from neonatal rats possess a saturable process for active glucose uptake, the myotubes having a relatively high affinity for the substrate with a Km of 1 mM. The expression of the glucose transport system was most apparent after fusion of single myoblasts to multinucleated myotubes [3-4 days in vitro (DIV)], at which time glucose uptake increased sharply to reach plateau values at about 6-8 DIV. Treatment of the cells at age 6 DIV with triiodothyronine or thyroxine caused a marked increase in glucose uptake beginning 4 h after treatment and reaching a maximum at 24 h. Thyroid hormone-induced increase in glucose uptake was not reduced by either tetrodotoxin or verapamil, thus indicating that the effect was not secondary to the ability of the hormone to increase contractile activity. The effect of thyroid hormones was eliminated completely by inhibition of protein synthesis. The results indicate that thyroid hormones play an important role in regulation of glucose transport in skeletal muscle.     

Benzodiazepine Receptor and Thyroid Hormones: In Vivo and In Vitro Modulation

In rats rendered hyperthyroid by chronic treatment with L-triiodothyronine (T3) hormone there was a 21 and 27% decrease, respectively, in the number of binding sites for [3H]flunitrazepam ([3H]FNZ) and [3H]ethyl-beta-carboline-3-carboxylate ([3H]beta-CCE) without changes in affinity for the two ligands. Two weeks after thyroidectomy there was a 44% increase in [3H]FNZ sites and a 17% increase in [3H]beta-CCE binding sites. In vitro we found that T3 produces a decrease in Bmax and an increase in KD, both changes being characteristic of a mixed type of inhibition. Thyroid status dramatically affected the Ki of T3 in displacing [3H]FNZ from sites on isolated membranes of the cerebral cortex: in hypothyroid rats the Ki value was 0.9 microM, whereas in hyperthyroid rats, it was 83 microM, a 92-fold difference. In control rats, the Ki was 11 microM. These findings are discussed in relation to a possible modulation of benzodiazepine receptors by thyroid hormones.     

Carrier-Mediated Transport of Thyroid Hormones into Rat Glial Cells in Primary Culture

The uptake of 3,3',5-[3'-125I]triiodo-L-thyronine ([125I]L-T3) and of L-[3',5'-125I]thyroxine ([125I]L-T4) by cultured rat glial cells was studied under initial velocity (Vi) conditions. Uptake of both hormones was carrier mediated and obeyed simple Michaelis-Menten kinetics. The following respective values of Km (microM) and Vmax (fmol/min/microgram of DNA) were obtained at 25 degrees C: 0.52 +/- 0.09 and 727 +/- 55 for L-T3 and 1.02 +/- 0.21 and 690 +/- 85 for L-T4. Ki values (microM) for the inhibition of [125I]L-T3 uptake by unlabeled analogues were as follows: L-T4, 0.88; 3,3',5'-triiodo-L-thyronine, 1.4; 3,3'-diiodo-L-thyronine, 2.9; 3,3',5-triiodo-D-thyronine, 4.8; and triiodothyroacetic acid, 5.3. These values indicate that the uptake system is stereospecific. Unlabeled L-T3 was a better competitor than unlabeled L-T4 for the uptake of [125I]L-T4, an observation suggesting that both hormones were taken up by a common carrier system. L-T3, and L-T4 uptake was pH dependent, a finding suggesting that the phenolic unionized form of the hormones was preferentially taken up. L-T3 uptake was studied in the presence of various inhibitors; the results suggest that uptake was independent of the transmembrane Na+ gradient and of the cellular energy. Compounds that inhibited cellular uptake but were without effect on L-T3 binding to isolated nuclei also inhibited L-T3 nuclear binding in intact cells, an observation suggesting that uptake could be rate limiting for the access of L-T3 to nuclear receptors when transport is severely inhibited.     

Weight Loss Through Gastric Banding: Effects on TSH and Thyroid Hormones in Obese Subjects With Normal Thyroid Function

Studies on thyroid function in obesity yielded inconsistent results; high thyroid‐stimulating hormone (TSH) levels were generally shown; high free triiodothyronine (fT)‐3 or fT4 levels were described in some, but not in other studies. After weight loss, TSH and thyroid hormones have been described to either increase or decrease. Our aim was to describe TSH, fT3, and fT4 in obese subjects with normal thyroid function before and after durable and significant weight loss, obtained through laparoscopic gastric banding (LAGB), in comparison with nonobese subjects. TSH, fT3, fT4, and fT3/fT4 ratio (an index of D1 and D2 deiodinase activity), were evaluated in 99 healthy controls and in 258 obese subjects, at baseline and 6 months, 1 year, and 2 years after LAGB, together with indexes of glucose (glucose, insulin, homeostasis model assessment of insulin resistance index) and lipid (triglycerides, total and high‐density lipoprotein–cholesterol) metabolism, and anthropometric measures (BMI and waist circumference). Under basal conditions, TSH, fT3, and fT4 were all in the normal range, but higher in obese than in nonobese subjects, and fT3/fT4 ratio was normal; with weight loss, fT3 and fT3/fT4 ratio decreased in obese subjects, while fT4 increased and TSH remained steady; all values were again within the normal range. Albumin and cholesterol levels remained steady, while triglycerides, insulin, and homeostasis model assessment of insulin resistance decreased, and high‐density lipoprotein–cholesterol increased. These changes, however, do not modify TSH, letting us to hypothesize that the changes are due to a decrease of D1 and D2 deiodinase activities.