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通过基因重复和功能驱动的基因复合体形成,在 Mus 精子 Adam 基因的黏附结构域中发生正选择。

Positive selection in the adhesion domain of Mus sperm Adam genes through gene duplications and function-driven gene complex formations.

机构信息

Department of Biology, University of Winnipeg, Winnipeg, Canada.

出版信息

BMC Evol Biol. 2013 Sep 30;13:217. doi: 10.1186/1471-2148-13-217.

DOI:10.1186/1471-2148-13-217
PMID:24079728
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC3849967/
Abstract

BACKGROUND

Sperm and testes-expressed Adam genes have been shown to undergo bouts of positive selection in mammals. Despite the pervasiveness of positive selection signals, it is unclear what has driven such selective bouts. The fact that only sperm surface Adam genes show signals of positive selection within their adhesion domain has led to speculation that selection might be driven by species-specific adaptations to fertilization or sperm competition. Alternatively, duplications and neofunctionalization of Adam sperm surface genes, particularly as it is now understood in rodents, might have contributed to an acceleration of evolutionary rates and possibly adaptive diversification.

RESULTS

Here we sequenced and conducted tests of selection within the adhesion domain of sixteen known sperm-surface Adam genes among five species of the Mus genus. We find evidence of positive selection associated with all six Adam genes known to interact to form functional complexes on Mus sperm. A subset of these complex-forming sperm genes also displayed accelerated branch evolution with Adam5 evolving under positive selection. In contrast to our previous findings in primates, selective bouts within Mus sperm Adams showed no associations to proxies of sperm competition. Expanded phylogenetic analysis including sequence data from other placental mammals allowed us to uncover ancient and recent episodes of adaptive evolution.

CONCLUSIONS

The prevailing signals of rapid divergence and positive selection detected within the adhesion domain of interacting sperm Adams is driven by duplications and potential neofunctionalizations that are in some cases ancient (Adams 2, 3 and 5) or more recent (Adams 1b, 4b and 6).

摘要

背景

已经证实,精子和睾丸表达的 Adam 基因在哺乳动物中经历了正选择的爆发。尽管正选择信号普遍存在,但尚不清楚是什么驱动了这些选择爆发。事实上,只有精子表面的 Adam 基因在其黏附结构域内显示出正选择的信号,这导致人们推测选择可能是由物种特异性的受精适应或精子竞争驱动的。或者,Adam 精子表面基因的复制和新功能化,特别是在啮齿动物中被理解的那样,可能加速了进化速度,并可能促进了适应性多样化。

结果

在这里,我们在五个 Mus 属物种的 16 个已知精子表面 Adam 基因的黏附结构域中进行了测序,并进行了选择测试。我们发现了与六种已知在 Mus 精子上形成功能复合物的 Adam 基因相关的正选择证据。这些形成复合物的精子基因中的一部分也显示出加速的分支进化,其中 Adam5 受到正选择的影响。与我们之前在灵长类动物中的发现相反,Mus 精子 Adam 中的选择爆发与精子竞争的代理指标没有关联。包括来自其他胎盘哺乳动物的序列数据的扩展系统发育分析使我们能够揭示古老和近期的适应性进化事件。

结论

在相互作用的精子 Adam 的黏附结构域中检测到的快速分歧和正选择的主导信号是由复制和潜在的新功能化驱动的,这些复制和新功能化在某些情况下是古老的(Adam2、3 和 5)或最近的(Adam1b、4b 和 6)。

https://cdn.ncbi.nlm.nih.gov/pmc/blobs/1a3b/3849967/8d98bd22b7e0/1471-2148-13-217-1.jpg
https://cdn.ncbi.nlm.nih.gov/pmc/blobs/1a3b/3849967/8d98bd22b7e0/1471-2148-13-217-1.jpg
https://cdn.ncbi.nlm.nih.gov/pmc/blobs/1a3b/3849967/8d98bd22b7e0/1471-2148-13-217-1.jpg

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