Recurrent sequence evolution after independent gene duplication.

IF 3.4 Q1 Agricultural and Biological Sciences
Samuel H A von der Dunk, Berend Snel
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引用次数: 8

Abstract

Background: Convergent and parallel evolution provide unique insights into the mechanisms of natural selection. Some of the most striking convergent and parallel (collectively recurrent) amino acid substitutions in proteins are adaptive, but there are also many that are selectively neutral. Accordingly, genome-wide assessment has shown that recurrent sequence evolution in orthologs is chiefly explained by nearly neutral evolution. For paralogs, more frequent functional change is expected because additional copies are generally not retained if they do not acquire their own niche. Yet, it is unknown to what extent recurrent sequence differentiation is discernible after independent gene duplications in different eukaryotic taxa.

Results: We develop a framework that detects patterns of recurrent sequence evolution in duplicated genes. This is used to analyze the genomes of 90 diverse eukaryotes. We find a remarkable number of families with a potentially predictable functional differentiation following gene duplication. In some protein families, more than ten independent duplications show a similar sequence-level differentiation between paralogs. Based on further analysis, the sequence divergence is found to be generally asymmetric. Moreover, about 6% of the recurrent sequence evolution between paralog pairs can be attributed to recurrent differentiation of subcellular localization. Finally, we reveal the specific recurrent patterns for the gene families Hint1/Hint2, Sco1/Sco2 and vma11/vma3.

Conclusions: The presented methodology provides a means to study the biochemical underpinning of functional differentiation between paralogs. For instance, two abundantly repeated substitutions are identified between independently derived Sco1 and Sco2 paralogs. Such identified substitutions allow direct experimental testing of the biological role of these residues for the repeated functional differentiation. We also uncover a diverse set of families with recurrent sequence evolution and reveal trends in the functional and evolutionary trajectories of this hitherto understudied phenomenon.

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独立基因复制后的循环序列进化。
背景:趋同进化和平行进化为自然选择的机制提供了独特的见解。蛋白质中一些最引人注目的趋同和平行(集体循环)氨基酸取代是适应性的,但也有许多是选择性中性的。因此,全基因组评估表明,直系同源物的循环序列进化主要是由近中性进化来解释的。对于同类产品,更频繁的功能变化是预期的,因为如果它们没有获得自己的位置,通常不会保留额外的副本。然而,在不同的真核生物分类群中,在独立基因复制后,循环序列分化在多大程度上是可辨别的尚不清楚。结果:我们开发了一个框架,检测重复基因的循环序列进化模式。这被用来分析90种不同真核生物的基因组。我们发现大量的家族在基因复制后具有潜在可预测的功能分化。在一些蛋白质家族中,超过10个独立的重复显示出相似的序列水平差异。进一步分析发现,序列散度总体上是不对称的。此外,约6%的平行序列之间的循环序列进化可归因于亚细胞定位的循环分化。最后,我们揭示了基因家族Hint1/Hint2, Sco1/Sco2和vma11/vma3的特定复发模式。结论:提出的方法提供了一种方法来研究生物化学基础的功能分化之间的同类。例如,在独立衍生的Sco1和Sco2相似物之间发现了两个大量重复的替换。这样识别的取代允许对这些残基的重复功能分化的生物学作用进行直接实验测试。我们还发现了一系列具有重复序列进化的不同家族,并揭示了这种迄今尚未得到充分研究的现象的功能和进化轨迹的趋势。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
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来源期刊
BMC Evolutionary Biology
BMC Evolutionary Biology 生物-进化生物学
CiteScore
5.80
自引率
0.00%
发文量
0
审稿时长
6 months
期刊介绍: BMC Evolutionary Biology is an open access, peer-reviewed journal that considers articles on all aspects of molecular and non-molecular evolution of all organisms, as well as phylogenetics and palaeontology.
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