Thyronine

Abstract: T4 and T3 have been measured by RIA in 10-12-day-old rat embryo-trophoblasts, and in 13-20-day-old embryos and placentas, as well as in a few samples of amniotic fluid. Both T4 and T3 were measured after extraction of the samples with ethanol, purification by paper chromatography, anion exchange resin, or both. T4 and T3 could be shown in all samples studied. The amounts of T4 and T3 per conceptus and their concentrations were higher in embryo-trophoblasts and placentas than in 13-18-day-old embryos. The concentrations of T4 and T3 remained fairly constant in the embryos until day 19, when they appeared to increase. The molar ratios of T4 to T3 were 1.4, 8.5 and 103 for embryos, placentas and maternal plasma, respectively. These data show that, for at least one mammalian species, embryonic tissues are provided with T4 and T3 from the earliest date studied, namely 4 days after uterine implantation, and well before onset of thyroid function, which in the rat starts after 17 days gestational age. Such a result suggests that statements denying a possible role of thyroid hormones in early embryogenesis ought to be reconsidered.

Abstract: Cells from a rat pituitary tumor cell line will respond in vitro to physiological concentrations of L-thyroxine and L-triiodothyronine. The cells are grown in a cultutre medium that contains serum from a hypothyroid calf. Dose-response relationships of a vacriety of thyronine derivatives indicate that this system has a specificity of response which is similar to that observed in vitro.

Abstract: Mutations of the gene expressing plasma membrane transporter for thyroid hormones MCT8 (SLC16A2) in humans lead to altered thyroid hormone levels and a severe neurodevelopmental disorder. Genetically engineered defect of the Mct8 gene in mice leads to similar thyroid hormone abnormalities but no obvious impairment of brain development or function. In this work we studied the relative role of the blood-brain barrier and the neuronal plasma cell membrane in the restricted access of T(3) to the target neurons. To this end we compared the effects of low doses of T(4) and T(3) on cerebellar structure and gene expression in wild-type (Wt) and Mct8 null male mice [Mct8-/y, knockout (KO)] made hypothyroid during the neonatal period. We found that compared with Wt animals, T(4) was considerably more potent than T(3) in the Mct8KO mice, indicating a restricted access of T(3), but not T(4), to neurons after systemic administration in vivo. In contrast, T(3) action in cultured cerebellar neurons was similar in Wt cells as in Mct8KO cells. The results suggest that the main restriction for T(3) entry into the neural target cells of the mouse deficient in Mct8 is at the blood-brain barrier.

Abstract: To evaluate the effect of starvation, oral and i.v. nutriments, and hypothyroidism on the peripheral conversion of thyroxine (T4) to 3,3', 5-triiodothyronine (T3) in the rat and mouse, an in vitro system for assessing T4 conversion to T3 by fresh liver homogenates was used. A 2-day starvation in the rat reduced hepatic T3 generation from T4 by 47% +/- 3.5% (mean +/- SE) in six separate experiments and also impaired the metabolism of 125I-r-T3. Administration of carbohydrate (CHO) and amino acids (P), but not lipid (L), significantly increased T3 generation above values observed in the starved rat. The mean serum glucose concentration was similar in all nutriment-infused groups, but serum insulin was significantly greater in the CHO- and P-infused as compared to the L-infused rats. These findings suggest that CHO and P, but not L, are important modulators of hepatic outer ring thyronine deiodination in the rat, perhaps due to increased intracellular glucose. Hypothyroidism in the rat induced by thyroidectomy and congenital secondary hypothyroidism in the dwarf mouse resulted in a striking decrease in hepatic conversion of T4 to T3. This decrease was restored to normal by the daily s.c. administration of physiologic doses of T4 (1.5 microgram/100 g) or T3 (0.5 microgram/100 g) for 14 days, and was increased above normal following treatment of normal rate with greater than physiologic doses of T4 (3microgram/100 g) or T3 (1 microgram/100g). In vitro hepatic conversion of T4 to T3 is, therefore, dependent upon thyroid function. Since 2-days starvation in the rat was associated with decreased serum concentrations of T4, T3, and TSH, and hypothyroidism resulted in decreased conversion of T4 to T3, the effect of a constant 2-day infusion of physiologic doses of T4 or T3 in the starved rat on the in vitro deiodination of T4 was assessed. Thyroid hormone replacement did not enhance the conversion of T4 to T3 in the starved rat. These observations suggest that the starvation-induced decrease in hepatic generation of T3 from T4 is not due to hypothyroidism and that the mechanism(s) of the decreased T3 production observed in starvation and hypothyroidism is different.