Joseph-Bravo Patricia, Jaimes-Hoy Lorraine, Uribe Rosa-María, Charli Jean-Louis
Departamento de Genética del Desarrollo y Fisiología MolecularInstituto de Biotecnología, Universidad Nacional Autónoma de México (UNAM), A.P. 510-3, Cuernavaca, Morelos 62250, Mexico
Departamento de Genética del Desarrollo y Fisiología MolecularInstituto de Biotecnología, Universidad Nacional Autónoma de México (UNAM), A.P. 510-3, Cuernavaca, Morelos 62250, Mexico.
J Endocrinol. 2015 Aug;226(2):T85-T100. doi: 10.1530/JOE-15-0124. Epub 2015 Jun 22.
This review presents the findings that led to the discovery of TRH and the understanding of the central mechanisms which control hypothalamus-pituitary-thyroid axis (HPT) activity. The earliest studies on thyroid physiology are now dated a century ago when basal metabolic rate was associated with thyroid status. It took over 50 years to identify the key elements involved in the HPT axis. Thyroid hormones (TH: T4 and T3) were characterized first, followed by the semi-purification of TSH whose later characterization paralleled that of TRH. Studies on the effects of TH became possible with the availability of synthetic hormones. DNA recombinant techniques facilitated the identification of all the elements involved in the HPT axis, including their mode of regulation. Hypophysiotropic TRH neurons, which control the pituitary-thyroid axis, were identified among other hypothalamic neurons which express TRH. Three different deiodinases were recognized in various tissues, as well as their involvement in cell-specific modulation of T3 concentration. The role of tanycytes in setting TRH levels due to the activity of deiodinase type 2 and the TRH-degrading ectoenzyme was unraveled. TH-feedback effects occur at different levels, including TRH and TSH synthesis and release, deiodinase activity, pituitary TRH-receptor and TRH degradation. The activity of TRH neurons is regulated by nutritional status through neurons of the arcuate nucleus, which sense metabolic signals such as circulating leptin levels. Trh expression and the HPT axis are activated by energy demanding situations, such as cold and exercise, whereas it is inhibited by negative energy balance situations such as fasting, inflammation or chronic stress. New approaches are being used to understand the activity of TRHergic neurons within metabolic circuits.
本综述介绍了导致促甲状腺激素释放激素(TRH)发现以及对控制下丘脑 - 垂体 - 甲状腺轴(HPT轴)活动的中枢机制理解的研究结果。关于甲状腺生理学的最早研究可追溯到一个世纪前,当时基础代谢率与甲状腺状态相关。确定HPT轴涉及的关键要素花费了50多年时间。甲状腺激素(TH:T4和T3)首先被表征,随后促甲状腺激素(TSH)被半纯化,其后来的表征与TRH平行。随着合成激素的可得性,对TH作用的研究成为可能。DNA重组技术有助于识别HPT轴涉及的所有要素,包括它们的调节方式。控制垂体 - 甲状腺轴的促垂体TRH神经元在表达TRH的其他下丘脑神经元中被识别出来。在各种组织中识别出三种不同的脱碘酶,以及它们在细胞特异性调节T3浓度中的作用。由于2型脱碘酶和TRH降解外切酶的活性,发现了伸展细胞在设定TRH水平中的作用。TH的反馈作用发生在不同水平,包括TRH和TSH的合成与释放、脱碘酶活性、垂体TRH受体和TRH降解。TRH神经元的活动通过弓状核的神经元受营养状态调节,弓状核神经元感知诸如循环瘦素水平等代谢信号。TRH表达和HPT轴在诸如寒冷和运动等能量需求情况下被激活,而在诸如禁食、炎症或慢性应激等负能量平衡情况下则受到抑制。正在采用新方法来理解代谢回路中TRH能神经元的活动。
