Campos-Barros A, Hoell T, Musa A, Sampaolo S, Stoltenburg G, Pinna G, Eravci M, Meinhold H, Baumgartner A
Department of Nuclear Medicine, Benjamin Franklin Hospital, Free University of Berlin, Germany.
J Clin Endocrinol Metab. 1996 Jun;81(6):2179-85. doi: 10.1210/jcem.81.6.8964848.
In the present study we investigated the biochemical properties of in vitro phenolic (5'D) and tyrosyl (5D) ring deiodination and the tissue concentrations of T4, T3, and rT3 in adult human central nervous system (CNS) tissue. All samples were obtained from nontumoral tissue at autopsy (n = 6) or neurosurgical operation (n = 5). Both phenolic and tyrosyl ring deiodinase activities were demonstrable in all samples obtained intraoperatively, whereas only tyrosyl ring deiodination was evident in the tissues obtained postmortem. The phenolic ring deiodination pathway corresponded to the type II 5'-deiodinase isoenzyme with regard to its high affinity for T4 and rT3 (Km = 2.2 and 2.4 nmol/L, respectively), its insensitivity to 6-propyl-n-2-thiouracil (PTU), and the sequential reaction mechanism. No PTU-sensitive 5'-deiodination of rT3 was demonstrable. Tyrosyl ring deiodination of both T4 and T3 showed typical type III 5D kinetics (Ka, 6.5 nmol/L for T4 and 3.4 nmol/L for T3) and was PTU insensitive. Nanomolar concentrations of tissue T4, T3, and rT3 were detected in samples obtained both intraoperatively and postmortem. They were very similar to the absolute values of the apparent Km for T4, T3, and rT3 in the phenolic and tyrosyl ring deiodination pathways. In conclusion, we have demonstrated the coexistence of both phenolic and tyrosyl ring deiodinase activities in the human CNS. Their kinetic characteristics, substrate specificity, and reaction mechanisms are very similar to the corresponding type II 5'- and type III 5-iodothyronine deiodinase activities in rat brain. In contrast to the findings in the rat CNS, no PTU-sensitive phenolic ring deiodinase (i.e. type I 5'D) activity was found in the human CNS. This may explain the relatively high tissue concentrations of rT3.
在本研究中,我们调查了体外酚环(5'D)和酪氨酰环(5D)脱碘的生化特性,以及成体人类中枢神经系统(CNS)组织中T4、T3和反T3(rT3)的组织浓度。所有样本均取自尸检时的非肿瘤组织(n = 6)或神经外科手术时的组织(n = 5)。术中获取的所有样本中均可检测到酚环和酪氨酰环脱碘酶活性,而在尸检获得的组织中仅酪氨酰环脱碘明显。酚环脱碘途径在对T4和rT3的高亲和力(Km分别为2.2和2.4 nmol/L)、对6-丙基-2-硫氧嘧啶(PTU)不敏感以及连续反应机制方面与II型5'-脱碘酶同工酶相对应。未检测到rT3的PTU敏感的5'-脱碘。T4和T3的酪氨酰环脱碘均显示典型的III型5D动力学(T4的Ka为6.5 nmol/L,T3的Ka为3.4 nmol/L)且对PTU不敏感。在术中及尸检获得的样本中均检测到纳摩尔浓度的组织T4、T3和rT3。它们与酚环和酪氨酰环脱碘途径中T4、T3和rT3的表观Km绝对值非常相似。总之,我们已证实在人类CNS中酚环和酪氨酰环脱碘酶活性共存。它们的动力学特征、底物特异性和反应机制与大鼠脑中相应的II型5'-和III型5-碘甲状腺原氨酸脱碘酶活性非常相似。与大鼠CNS中的发现相反,在人类CNS中未发现PTU敏感的酚环脱碘酶(即I型5'D)活性。这可能解释了rT3相对较高的组织浓度。
