Evolution, child development and the thyroid: a phylogenetic and ontogenetic introduction to normal thyroid function.

Endocrine development Pub Date : 2014-01-01 Epub Date: 2014-08-29 DOI:10.1159/000363151
Heiko Krude
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引用次数: 4

Abstract

Congenital thyroid diseases can be explained in the context of the individual ontogenetic development; however, they can also be mirrored in the perspective of the phylogenetic evolution of the thyroid hormone system. The unique feature of the system, e.g., the generation of iodinated tyrosine derivatives by specialized enzymes that are frequently disrupted by mutations in congenital hypothyroidism, occurred very early in plant evolution and can still be demonstrated in algae today. All other components like the thyroid hormone receptors (TRs), the transporter molecules, the regulation by thyroid-stimulating hormone and thyrotropin-releasing hormone--and their respective receptors - as well as the structures that produce thyroid hormone with the human thyroid as the most recent development evolved in the animal kingdom. Already in the earliest animal species like Ciona intestinalis, specialized cells in the so-called endostyle not only iodinate tyrosine residues, but also secrete thyroid hormone itself, which activates TRs in target cells. During the following process of growing complexity of the thyroid system in higher species, pre-existing molecules and functions accumulated new variations, which enabled their assembly in new functional frames of the system and its central regulation. A deeper view into the range of evolutional variabilities and also flexibilities within the thyroid axis will most likely increase our understanding of the molecular defects and their potential treatment in the current human thyroid system.

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进化,儿童发育和甲状腺:正常甲状腺功能的系统发育和个体发育介绍。
先天性甲状腺疾病可以在个体个体发育的背景下解释;然而,它们也可以反映在甲状腺激素系统的系统发育进化的角度。该系统的独特特征,例如,由专门的酶产生的碘化酪氨酸衍生物经常被先天性甲状腺功能减退症的突变所破坏,在植物进化的早期就发生了,今天仍然可以在藻类中得到证明。所有其他成分,如甲状腺激素受体(TRs)、转运分子、促甲状腺激素和促甲状腺激素释放激素的调节——以及它们各自的受体——以及与人类甲状腺一起产生甲状腺激素的结构,都是动物王国中最新的发展。早在最早的动物物种中,如Ciona ntestinalis,所谓的内质层中的特化细胞不仅碘化酪氨酸残基,而且还分泌甲状腺激素,激活靶细胞中的TRs。在随后的高等物种甲状腺系统复杂性增长的过程中,先前存在的分子和功能积累了新的变异,这使得它们能够组装在系统的新功能框架及其中心调控中。更深入地了解甲状腺轴的进化变异性和灵活性,将最有可能增加我们对当前人类甲状腺系统中分子缺陷及其潜在治疗方法的理解。
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