发育增强子中人类特有的功能获得

Human-specific gain of function in a developmental enhancer.

作者信息

Prabhakar Shyam, Visel Axel, Akiyama Jennifer A, Shoukry Malak, Lewis Keith D, Holt Amy, Plajzer-Frick Ingrid, Morrison Harris, Fitzpatrick David R, Afzal Veena, Pennacchio Len A, Rubin Edward M, Noonan James P

机构信息

Genomics Division, Lawrence Berkeley National Laboratory, Berkeley, CA 94720, USA.

出版信息

Science. 2008 Sep 5;321(5894):1346-50. doi: 10.1126/science.1159974.

DOI:10.1126/science.1159974

PMID:18772437

原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC2658639/

Abstract

Changes in gene regulation are thought to have contributed to the evolution of human development. However, in vivo evidence for uniquely human developmental regulatory function has remained elusive. In transgenic mice, a conserved noncoding sequence (HACNS1) that evolved extremely rapidly in humans acted as an enhancer of gene expression that has gained a strong limb expression domain relative to the orthologous elements from chimpanzee and rhesus macaque. This gain of function was consistent across two developmental stages in the mouse and included the presumptive anterior wrist and proximal thumb. In vivo analyses with synthetic enhancers, in which human-specific substitutions were introduced into the chimpanzee enhancer sequence or reverted in the human enhancer to the ancestral state, indicated that 13 substitutions clustered in an 81-base pair module otherwise highly constrained among terrestrial vertebrates were sufficient to confer the human-specific limb expression domain.

摘要

基因调控的变化被认为对人类发育的进化起到了作用。然而，关于独特的人类发育调控功能的体内证据仍然难以捉摸。在转基因小鼠中，一个在人类中进化极快的保守非编码序列（HACNS1）充当了基因表达的增强子，相对于黑猩猩和恒河猴的直系同源元件，它获得了一个强大的肢体表达域。这种功能的获得在小鼠的两个发育阶段是一致的，包括假定的前腕和近端拇指。用合成增强子进行的体内分析表明，将人类特异性替换引入黑猩猩增强子序列或在人类增强子中恢复到祖先状态，在一个81个碱基对的模块中聚集的13个替换，在陆地脊椎动物中其他方面受到高度限制，足以赋予人类特异性的肢体表达域。

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