Degradation and recycling of the substrate-binding subunit of type II iodothyronine 5'-deiodinase in astrocytes.

Thyroxine dynamically regulates levels of type II iodothyronine 5'-deiodinase (5'D-II) by modulating enzyme inactivation and targeting the enzyme to different pathways of internalization. 5'D-II is an approximately 200-kDa multimeric protein containing a 29-kDa substrate-binding subunit (p29) and an unknown number of other subunits. In the absence of thyroxine (T4), p29 is slowly endocytosed and transported to the lysosomes. T4 treatment rapidly activates an actin-mediated endocytotic pathway and targets the enzyme to the endosomes. In this study, we have characterized the influence of T4 on the intracellular trafficking of 5'D-II. We show that T4 accelerates the rate of 5'D-II inactivation by translocating the enzyme to the interior of the cell and by sequestering p29 in the endosomal pool without accelerating the rate of degradation of p29. This dichotomy between the rapid inactivation of catalytic activity and the much slower degradation of p29 is consistent with the reuse of p29 in the production of 5'D-II activity. Immunocytochemical analysis with a specific anti-p29 IgG shows that pulse affinity-labeled p29 reappears on the plasma membrane approximately 2 h after enzyme internalization in the presence of T4, indicating that p29 is recycled. Despite the ability of p29 to be recycled in the T4-treated cell, 5'D-II catalytic activity requires ongoing protein synthesis, presumably of another enzyme component(s) or an accessory enzyme-related protein. In the absence of T4, enzyme inactivation and p29 degradation are temporally linked, and pulse affinity-labeled p29 is internalized and sequestered in discrete intracellular pools. These data suggest that T4 regulates fundamental processes involved with the turnover of integral membrane proteins and participates in regulating the inter-relationships between the degradation, recycling, and synthetic pathways.

The thyroid gland is a major source of circulating T3 in the rat.

In rats, the respective contribution of the thyroid and peripheral tissues to the pool of T3 remains unclear. Most, if not all, of the circulating T3 produced by extrathyroidal sources is generated by 5'-deiodination of T4, catalyzed by the selenoenzyme, type I iodothyronine 5'-deiodinase (5'D-I). 5'D-I in the liver and kidney is almost completely lost in selenium deficiency, resulting in a marked decrease in T4 deiodination and an increase in circulating T4 levels. Surprisingly, circulating T3 levels are only marginally decreased by selenium deficiency. In this study, we used selenium deficiency and thyroidectomy to determine the relative contribution of thyroidal and extrathyroidal sources to the total body pool of T3. Despite maintaining normal serum T4 concentrations in thyroidectomized rats by T4 replacement, serum T3 concentrations remained 55% lower than those seen in intact rats. In intact rats, restricting selenium intake had no effect on circulating T3 concentrations. Decreasing 5'D-I activity in the liver and kidney by > 90% by restricting selenium intake resulted in a further 20% decrease in serum T3 concentrations in the thyroidectomized, T4 replaced rats, suggesting that peripheral T4 to T3 conversion in these tissues generates approximately 20% of the circulating T3 concentrations. While dietary selenium restriction markedly decreased intrahepatic selenium content (> 95%), intrathyroidal selenium content decreased by only 27%. Further, thyroid 5'D-I activity actually increased 25% in the selenium deficient rats, suggesting the continued synthesis of this selenoenzyme over selenoproteins in other tissues in selenium deficiency. These data demonstrate that the thyroid is the major source of T3 in the rat and suggest that intrathyroidal T4 to T3 conversion may account for most of the T3 released by the thyroid.

Effects of selenium deficiency on thyroid hormone economy in rats.

In selenium-deficient rats, peripheral T4 to T3 conversion is markedly decreased due to the loss of the selenoprotein, type I iodothyronine 5'-deiodinase (5'D-I). Despite the marked increase in circulating T4 that results from this loss of 5'D-I, serum T3 concentrations in selenium-deficient rats remain in the normal range. To determine the physiological mechanism(s) that maintains circulating T3 when peripheral T4 to T3 conversion is impaired, we examined the interrelationships between selenium intake and the metabolism of T3 and T4 in the rat. In euthyroid rats, selenium deficiency caused the expected loss of 5'D-I, with a 52% increase in serum T4, which paralleled an increase in the T4 biological half-life. Consistent with the prolonged t1/2 of T4, short term thyroidectomy (48 h) in selenium-deficient rats failed to decrease serum T4 concentrations to the levels observed in short term thyroidectomized, selenium-supplemented rats. Short term thyroidectomy also caused an expected 33% decrease in liver 5'D-I and a 44% increase in brain type II iodothyronine 5'-deiodinase (5'D-II) activities in selenium-supplemented rats. However, in selenium-deficient rats, short term thyroidectomy did not affect 5'D-I or 5'D-II activities. In contrast to the selenium-dependent changes in circulating T4 levels, little or no change in circulating T3 concentrations occurred. There was a 20% increase in the T3 half-life in selenium-deficient rats. The serum T3 sulfate concentration was increased, and T3 deiodination was reciprocally decreased in the selenium-deficient rats. These data suggest that increased T3 sulfate generation in selenium-deficient rats may lead to greater T3 availability through enterohepatic recycling of the iodothyronine and may explain why there are only minor changes in serum T3 concentrations in selenium-deficient rats.

Selenium deficiency and type II 5'-deiodinase regulation in the euthyroid and hypothyroid rat: evidence of a direct effect of thyroxine.

Selenium deficiency in rats is characterized by elevated serum T4 and decreased serum T3 concentrations, and low liver type I (5'D-I) and brain type II (5'D-II) iodothyronine 5'-deiodinase activities. These findings are partially explained by the demonstration that type I 5'D is a selenoprotein; however, 5'D-II does not contain selenium. Since 5'D-II varies inversely with serum T4 concentrations, and serum T4 is elevated in selenium deficiency, the decreased cerebrocortical 5'D-II activity may be secondary to the increased serum T4 levels. To determine the mechanism(s) by which selenium influences 5'D-II activity, we examined the effects of altered selenium intake on brain 5'D-II levels and enzyme turnover in euthyroid and thyroidectomized rats. Rats were fed a selenium-supplemented or selenium-deficient diet for 5 weeks from weaning; half of the animals were also thyroidectomized 3 weeks before death. Selenium deficiency was confirmed by decreased liver and brain glutathione peroxidase activities. In euthyroid rats, selenium deficiency caused a 38% increase in serum T4, and 91% and 39% decreases in 5'D-I and 5'D-II, respectively, compared to those in selenium-supplemented rats. In the thyroidectomized hypothyroid rats, selenium deficiency caused a 60% decrease in 5'D-I, but had no effect on 5'D-II activity, fractional turnover of the enzyme, or the calculated enzyme synthesis rate. The lack of effect of selenium deficiency on 5'D-II levels in hypothyroid rats is consistent with the finding that 5'D-II is not a seleno-enzyme. Thus, the decrease in brain and pituitary 5'D-II activity in selenium-deficient euthyroid rats is due to the T4-dependent increase in the turnover of the enzyme polypeptide.