哺乳动物基因可变剪接编码区域的快速进化速率。

Fast rate of evolution in alternatively spliced coding regions of mammalian genes.

作者信息

Ermakova Ekaterina O, Nurtdinov Ramil N, Gelfand Mikhail S

机构信息

Department of Bioengineering and Bioinformatics, Moscow State University, Vorob'evy gory, 1-73, 119992, Moscow, Russia.

出版信息

BMC Genomics. 2006 Apr 18;7:84. doi: 10.1186/1471-2164-7-84.

DOI:10.1186/1471-2164-7-84

PMID:16620375

原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC1459143/

Abstract

BACKGROUND

At least half of mammalian genes are alternatively spliced. Alternative isoforms are often genome-specific and it has been suggested that alternative splicing is one of the major mechanisms for generating protein diversity in the course of evolution. Another way of looking at alternative splicing is to consider sequence evolution of constitutive and alternative regions of protein-coding genes. Indeed, it turns out that constitutive and alternative regions evolve in different ways.

RESULTS

A set of 3029 orthologous pairs of human and mouse alternatively spliced genes was considered. The rate of nonsynonymous substitutions (dN), the rate of synonymous substitutions (dS), and their ratio (omega = dN/dS) appear to be significantly higher in alternatively spliced coding regions compared to constitutive regions. When N-terminal, internal and C-terminal alternatives are analysed separately, C-terminal alternatives appear to make the main contribution to the observed difference. The effects become even more pronounced in a subset of fast evolving genes.

CONCLUSION

These results provide evidence of weaker purifying selection and/or stronger positive selection in alternative regions and thus one more confirmation of accelerated evolution in alternative regions. This study corroborates the theory that alternative splicing serves as a testing ground for molecular evolution.

摘要

背景

至少一半的哺乳动物基因存在可变剪接。可变剪接异构体通常具有基因组特异性，有人提出可变剪接是进化过程中产生蛋白质多样性的主要机制之一。看待可变剪接的另一种方式是考虑蛋白质编码基因的组成型区域和可变区域的序列进化。事实上，结果表明组成型区域和可变区域以不同的方式进化。

结果

研究了一组3029对人鼠可变剪接基因的直系同源对。与组成型区域相比，可变剪接编码区域中的非同义替换率（dN）、同义替换率（dS）及其比率（ω = dN/dS）似乎显著更高。当分别分析N端、内部和C端可变区时，C端可变区似乎对观察到的差异起主要作用。在快速进化基因的子集中，这种效应更加明显。

结论

这些结果提供了证据，表明可变区域的纯化选择较弱和/或正选择较强，从而再次证实了可变区域的加速进化。这项研究证实了可变剪接作为分子进化试验场的理论。

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哺乳动物基因可变剪接编码区域的快速进化速率。

Fast rate of evolution in alternatively spliced coding regions of mammalian genes.

作者信息

机构信息

出版信息

BACKGROUND

RESULTS

CONCLUSION

背景

结果

结论

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