Obregon M J, Larsen P R, Silva J E
Endocrinology. 1986 Nov;119(5):2186-92. doi: 10.1210/endo-119-5-2186.
Type II iodothyronine 5'-deiodinase (5'D-II) activity is the source of 75-80% of the cerebral cortex T3 content in euthyroid rats. The activity of this enzyme is increased in hypothyroidism and can be quickly suppressed by T4 and rT3 by mechanisms involving neither protein synthesis nor nuclear T3 receptors. We have examined the possibility that endogenous cerebrocortical rT3 levels play a physiological role in the regulation of this enzyme. Thyroidectomized rats were injected with graded doses of [125I]rT3, and cortex 5'D-II activity and rT3 content were determined at various times thereafter. Enzyme activity was reduced as early as 10 min after the injection of 0.75 microgram rT3/100 g BW, and 18 h after 25 micrograms/100 g BW remained 60% suppressed. Regardless of the time after the injection, 5'D-II activity was inversely related to the rT3 content in the cortex; nearly complete suppression was observed at 0.5 ng rT3/g tissue, 50% at 80 pg/g, and 20-30% at 30 pg/g, the euthyroid level. After the infusion of 0.75 microgram rT3/100 g, maximal inhibition occurred at 10 min, before the rT3 content reached maximum levels, and the 5'D-II activity started to recover after the rT3 level fell below 300 pg/g tissue. After increasing doses of T4 administered to thyroidectomized rats, serum and cerebrocortical T4 concentrations increased in a dose-dependent manner, but the increment in the latter was steeper than that in the former. Serum rT3 increments were also proportional to the dose of T4, but cerebrocortical rT3 increased to a greater extent, as evidenced by a 3-fold increment in the cerebrocortical rT3 to T4 ratio. With 1.6 microgram T4/100 g BW, cerebrocortical rT3 reached approximately 100 pg/g, about 3 times the euthyroid level, suggesting that at this T4 dose, the rT3 formed from T4 accounts for part of the inhibition of 5'D-II. With the half-maximal suppressive dose of T4, cortex T4 was about 400 pg/g, but rT3 was negligible. We conclude that: suppression of cortex 5'D-II by rT3 is rapid and requires the presence of rT3 in the tissue (i.e. no long-lived mediators); intracortical rT3 is about 5 times more potent than T4 in suppressing this enzyme; the cortex of rT3-5'D-II suppression relationships suggest that the euthyroid levels of cortex rT3 may be significant in the modulation of 5'D-II.(ABSTRACT TRUNCATED AT 400 WORDS)
II型碘甲腺原氨酸5'-脱碘酶(5'D-II)活性是正常甲状腺功能大鼠大脑皮质中75%-80%的T3含量的来源。该酶的活性在甲状腺功能减退时增加,并且可被T4和反T3通过既不涉及蛋白质合成也不涉及核T3受体的机制迅速抑制。我们研究了内源性大脑皮质反T3水平在该酶调节中发挥生理作用的可能性。给甲状腺切除的大鼠注射不同剂量的[125I]反T3,然后在不同时间测定皮质5'D-II活性和反T3含量。在注射0.75微克反T3/100克体重后10分钟,酶活性就开始降低,在注射25微克/100克体重后18小时仍被抑制60%。无论注射后时间如何,5'D-II活性与皮质中的反T3含量呈负相关;在0.5纳克反T3/克组织时观察到几乎完全抑制,在80皮克/克时为50%,在30皮克/克(正常甲状腺水平)时为20%-30%。在输注0.75微克反T3/100克后,最大抑制在10分钟时出现,此时反T3含量尚未达到最高水平,并且当反T3水平降至300皮克/克组织以下时,5'D-II活性开始恢复。给甲状腺切除的大鼠增加T4剂量后,血清和大脑皮质T4浓度呈剂量依赖性增加,但后者的增加比前者更陡峭。血清反T3增加也与T4剂量成比例,但大脑皮质反T3增加程度更大,大脑皮质反T3与T4的比值增加了3倍就证明了这一点。给予1.6微克T4/100克体重时,大脑皮质反T3达到约100皮克/克,约为正常甲状腺水平的3倍,表明在这个T4剂量下,由T4形成的反T3占5'D-II抑制的一部分。在T4的半数最大抑制剂量时,皮质T4约为400皮克/克,但反T3可忽略不计。我们得出结论:反T3对皮质5'D-II的抑制迅速,并且需要组织中存在反T3(即没有长寿命介质);皮质内反T3在抑制该酶方面比T4强约5倍;反T3-5'D-II抑制关系的皮质情况表明,皮质反T3的正常甲状腺水平在5'D-II的调节中可能很重要。(摘要截断于400字)
