真核生物中普遍存在的内源性基因重复和内含子产生。
Ubiquitous internal gene duplication and intron creation in eukaryotes.
机构信息
Department of Biology, Indiana University, 1001 East Third Street, Bloomington, IN 47405, USA.
出版信息
Proc Natl Acad Sci U S A. 2009 Dec 8;106(49):20818-23. doi: 10.1073/pnas.0911093106. Epub 2009 Nov 19.
Abstract
Duplication of genomic segments provides a primary resource for the origin of evolutionary novelties. However, most previous studies have focused on duplications of complete protein-coding genes, whereas little is known about the significance of duplication segments that are entirely internal to genes. Our examination of six fully sequenced genomes reveals that internal duplications of gene segments occur at a high frequency (0.001-0.013 duplications/gene per million years), similar to that of complete gene duplications, such that 8-17% of the genes in a genome carry duplicated intronic and/or exonic regions. At least 7-30% of such genes have acquired novel introns, either because a prior intron in the same gene has been duplicated, or more commonly, because a spatial change has activated a latent splice site. These results strongly suggest a major evolutionary role for internal gene duplications in the origin of genomic novelties, particularly as a mechanism for intron gain.
摘要
基因组片段的复制为进化新事物的起源提供了主要资源。然而,大多数先前的研究都集中在完整的蛋白质编码基因的复制上,而对于完全位于基因内部的复制片段的意义知之甚少。我们对六个完全测序的基因组的研究表明,基因片段的内部重复发生的频率很高(每百万年 0.001-0.013 个重复/基因),与完整基因重复的频率相似,因此基因组中 8-17%的基因携带重复的内含子和/或外显子区域。至少有 7-30%的这类基因获得了新的内含子,要么是因为同一基因中的先前内含子发生了重复,要么更常见的是,因为空间变化激活了潜伏的剪接位点。这些结果强烈表明内部基因重复在基因组新事物起源中具有主要的进化作用,特别是作为获得内含子的一种机制。
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