将爱好转变为工作：重复基因如何找到新功能。

Turning a hobby into a job: how duplicated genes find new functions.

作者信息

Conant Gavin C, Wolfe Kenneth H

机构信息

Division of Animal Sciences, University of Missouri-Columbia, 163B Animal Sciences Center, 920 East Campus Drive, Columbia, Missouri 65211-5300, USA.

出版信息

Nat Rev Genet. 2008 Dec;9(12):938-50. doi: 10.1038/nrg2482.

DOI:10.1038/nrg2482

PMID:19015656

Abstract

Gene duplication provides raw material for functional innovation. Recent advances have shed light on two fundamental questions regarding gene duplication: which genes tend to undergo duplication? And how does natural selection subsequently act on them? Genomic data suggest that different gene classes tend to be retained after single-gene and whole-genome duplications. We also know that functional differences between duplicate genes can originate in several different ways, including mutations that directly impart new functions, subdivision of ancestral functions and selection for changes in gene dosage. Interestingly, in many cases the 'new' function of one copy is a secondary property that was always present, but that has been co-opted to a primary role after the duplication.

摘要

基因复制为功能创新提供了原材料。最近的进展揭示了有关基因复制的两个基本问题：哪些基因倾向于发生复制？以及自然选择随后如何作用于它们？基因组数据表明，在单基因和全基因组复制后，不同的基因类别倾向于被保留。我们也知道，复制基因之间的功能差异可以通过几种不同的方式产生，包括直接赋予新功能的突变、祖先功能的细分以及对基因剂量变化的选择。有趣的是，在许多情况下，一个拷贝的“新”功能是一种一直存在的次要特性，但在复制后被用于主要功能。

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将爱好转变为工作：重复基因如何找到新功能。

Turning a hobby into a job: how duplicated genes find new functions.

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