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piRNA 通路组件 aubergine 的突变增强了果蝇减数分裂分离干扰器的驱动作用。

Mutations to the piRNA pathway component aubergine enhance meiotic drive of segregation distorter in Drosophila melanogaster.

机构信息

Department of Genetics, Harvard Medical School, Boston, Massachusetts 02115, USA.

出版信息

Genetics. 2013 Mar;193(3):771-84. doi: 10.1534/genetics.112.147561. Epub 2012 Dec 24.

Abstract

Diploid sexual reproduction involves segregation of allelic pairs, ensuring equal representation of genotypes in the gamete pool. Some genes, however, are able to "cheat" the system by promoting their own transmission. The Segregation distorter (Sd) locus in Drosophila melanogaster males is one of the best-studied examples of this type of phenomenon. In this system the presence of Sd on one copy of chromosome 2 results in dysfunction of the non-Sd-bearing (Sd(+)) sperm and almost exclusive transmission of Sd to the next generation. The mechanism by which Sd wreaks such selective havoc has remained elusive. However, its effect requires a target locus on chromosome 2 known as Responder (Rsp). The Rsp locus comprises repeated copies of a satellite DNA sequence and Rsp copy number correlates with sensitivity to Sd. Under distorting conditions during spermatogenesis, nuclei with chromosomes containing greater than several hundred Rsp repeats fail to condense chromatin and are eliminated. Recently, Rsp sequences were found as small RNAs in association with Argonaute family proteins Aubergine (Aub) and Argonaute3 (AGO3). These proteins are involved in a germline-specific RNAi mechanism known as the Piwi-interacting RNA (piRNA) pathway, which specifically suppresses transposon activation in the germline. Here, we evaluate the role of piRNAs in segregation distortion by testing the effects of mutations to piRNA pathway components on distortion. Further, we specifically targeted mutations to the aub locus of a Segregation Distorter (SD) chromosome, using ends-out homologous recombination. The data herein demonstrate that mutations to piRNA pathway components act as enhancers of SD.

摘要

二倍体有性生殖涉及等位基因对的分离,以确保基因型在配子库中得到平等的代表。然而,有些基因能够通过促进自身的传递来“欺骗”这个系统。黑腹果蝇雄性中的分离失真器(Sd)基因座就是这种现象的最佳研究实例之一。在这个系统中,Sd 存在于 2 号染色体的一个拷贝上,导致非 Sd 携带(Sd(+))精子功能失调,几乎将 Sd 完全传递给下一代。Sd 造成这种选择性破坏的机制仍然难以捉摸。然而,它的作用需要 2 号染色体上的一个靶基因座 Responder(Rsp)。Rsp 基因座包含重复的卫星 DNA 序列,Rsp 拷贝数与对 Sd 的敏感性相关。在精子发生过程中的失真条件下,包含数百个以上 Rsp 重复的染色体的核不能浓缩染色质并被消除。最近,Rsp 序列被发现与 Argonaute 家族蛋白 Aubergine(Aub)和 Argonaute3(AGO3)相关的小 RNA 结合。这些蛋白参与一种称为 Piwi 相互作用 RNA(piRNA)途径的生殖系特异性 RNAi 机制,该机制特异性抑制生殖系中转座子的激活。在这里,我们通过测试 piRNA 途径成分突变对失真的影响来评估 piRNA 在分离失真中的作用。此外,我们使用末端-out 同源重组,专门针对 Segregation Distorter(SD)染色体的 aub 基因座的突变。本文的数据表明,piRNA 途径成分的突变作为 SD 的增强剂起作用。

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