蛋白质中的简单序列重复及其对网络进化的意义。

Simple sequence repeats in proteins and their significance for network evolution.

作者信息

Hancock John M, Simon Michelle

机构信息

Bioinformatics Group, MRC Mammalian Genetics Unit, Harwell, Oxfordshire OX11 0RD, UK.

出版信息

Gene. 2005 Jan 17;345(1):113-8. doi: 10.1016/j.gene.2004.11.023. Epub 2004 Dec 15.

DOI:10.1016/j.gene.2004.11.023

PMID:15716087

Abstract

Only 5-6% of mammalian genomes are genes; the remainders are made up primarily of transposable elements and different types of simple sequence repeat (SSRs) (micro- and minisatellites and cryptic repeats), which tend to accumulate in organisms with larger genomes. SSRs are also found at the level of protein sequences and may or may not be encoded by SSRs at the DNA sequence level. Studies of proteins containing SSRs indicate that they tend to belong to particular functional classes, particularly transcription factors and protein kinases. Protein SSRs coded for by pure codon repeats evolve rapidly while those encoded by mixtures of codons evolve slowly. We outline a conceptualization of how protein SSRs may arise and become fixed in proteins during evolution, and suggest that emergence and change in length of protein SSRs may affect the topology of protein interaction networks.

摘要

只有5-6%的哺乳动物基因组是基因；其余部分主要由转座元件和不同类型的简单序列重复（SSRs）（微卫星和小卫星以及隐蔽重复序列）组成，这些序列往往在基因组较大的生物体中积累。在蛋白质序列水平也发现了SSRs，它们在DNA序列水平上可能由SSRs编码，也可能不由其编码。对含有SSRs的蛋白质的研究表明，它们往往属于特定的功能类别，特别是转录因子和蛋白激酶。由纯密码子重复编码的蛋白质SSRs进化迅速，而由密码子混合物编码的则进化缓慢。我们概述了蛋白质SSRs在进化过程中可能如何产生并在蛋白质中固定下来的概念，并表明蛋白质SSRs长度的出现和变化可能会影响蛋白质相互作用网络的拓扑结构。

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蛋白质中的简单序列重复及其对网络进化的意义。

Simple sequence repeats in proteins and their significance for network evolution.

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