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脊椎动物进化过程中 SCL 基因座的顺式调控重塑。

cis-Regulatory remodeling of the SCL locus during vertebrate evolution.

机构信息

Department of Haematology, Cambridge Institute for Medical Research, University of Cambridge, Cambridge, United Kingdom.

出版信息

Mol Cell Biol. 2010 Dec;30(24):5741-51. doi: 10.1128/MCB.00870-10. Epub 2010 Oct 18.

DOI:10.1128/MCB.00870-10
PMID:20956563
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC3004278/
Abstract

Development progresses through a sequence of cellular identities which are determined by the activities of networks of transcription factor genes. Alterations in cis-regulatory elements of these genes play a major role in evolutionary change, but little is known about the mechanisms responsible for maintaining conserved patterns of gene expression. We have studied the evolution of cis-regulatory mechanisms controlling the SCL gene, which encodes a key transcriptional regulator of blood, vasculature, and brain development and exhibits conserved function and pattern of expression throughout vertebrate evolution. SCL cis-regulatory elements are conserved between frog and chicken but accrued alterations at an accelerated rate between 310 and 200 million years ago, with subsequent fixation of a new cis-regulatory pattern at the beginning of the mammalian radiation. As a consequence, orthologous elements shared by mammals and lower vertebrates exhibit functional differences and binding site turnover between widely separated cis-regulatory modules. However, the net effect of these alterations is constancy of overall regulatory inputs and of expression pattern. Our data demonstrate remarkable cis-regulatory remodelling across the SCL locus and indicate that stable patterns of expression can mask extensive regulatory change. These insights illuminate our understanding of vertebrate evolution.

摘要

发育是通过一系列细胞身份的顺序进行的,这些身份是由转录因子基因网络的活性决定的。这些基因的顺式调控元件的改变在进化变化中起着重要作用,但对于负责维持基因表达保守模式的机制知之甚少。我们研究了控制 SCL 基因的顺式调控机制的进化,SCL 基因编码血液、血管和大脑发育的关键转录调节剂,在整个脊椎动物进化中表现出保守的功能和表达模式。SCL 顺式调控元件在青蛙和鸡之间是保守的,但在 3.1 亿至 2 亿年前以加速的速度积累了改变,随后在哺乳动物辐射的开始固定了新的顺式调控模式。因此,哺乳动物和低等脊椎动物共享的同源元件在广泛分离的顺式调控模块之间表现出功能差异和结合位点更替。然而,这些改变的净效应是整体调控输入和表达模式的恒定性。我们的数据表明 SCL 基因座发生了显著的顺式调控重塑,并表明稳定的表达模式可以掩盖广泛的调控变化。这些见解阐明了我们对脊椎动物进化的理解。

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