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胚胎学与分子生物学相遇:解读顶端外胚层嵴。

Embryology meets molecular biology: Deciphering the apical ectodermal ridge.

作者信息

Verheyden Jamie M, Sun Xin

机构信息

Laboratory of Genetics, University of Wisconsin, Madison, WI 53706, United States.

Laboratory of Genetics, University of Wisconsin, Madison, WI 53706, United States.

出版信息

Dev Biol. 2017 Sep 15;429(2):387-390. doi: 10.1016/j.ydbio.2017.01.017. Epub 2017 Jan 25.

Abstract

More than sixty years ago, while studying feather tracks on the shoulder of the chick embryo, Dr. John Saunders used Nile Blue dye to stain the tissue. There, he noticed a darkly stained line of cells that neatly rims the tip of the growing limb bud. Rather than ignoring this observation, he followed it up by removing this tissue and found that it led to a striking truncation of the limb skeletons. This landmark experiment marks the serendipitous discovery of the apical ectodermal ridge (AER), the quintessential embryonic structure that drives the outgrowth of the limb. Dr. Saunders continued to lead the limb field for the next fifty years, not just through his own work, but also by inspiring the next generation of researchers through his infectious love of science. Together, he and those who followed ushered in the discovery of fibroblast growth factor (FGF) as the AER molecule. The seamless marriage of embryology and molecular biology that led to the decoding of the AER serves as a shining example of how discoveries are made for the rest of the developmental biology field.

摘要

六十多年前,约翰·桑德斯博士在研究鸡胚肩部的羽毛痕迹时,用尼罗蓝染料对组织进行染色。在那里,他注意到一条深色染色的细胞线,整齐地环绕着正在生长的肢芽尖端。他没有忽视这一观察结果,而是通过切除这块组织进行了进一步研究,结果发现这导致了肢体骨骼的明显截断。这项具有里程碑意义的实验标志着意外发现了顶端外胚层嵴(AER),这是驱动肢体生长的典型胚胎结构。在接下来的五十年里,桑德斯博士一直引领着肢体领域的研究,不仅通过他自己的工作,还通过他对科学的热情感染了下一代研究人员。他和后来的研究者共同促成了成纤维细胞生长因子(FGF)作为AER分子的发现。胚胎学与分子生物学的完美结合,使得AER得以被解码,这为发育生物学领域的其他研究提供了一个发现是如何产生的光辉典范。

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