Einkorn 小麦中心粒的进化是由两个 LTR 逆转录转座子的相互影响所驱动的。

IF 4.7 2区 生物学 Q1 GENETICS & HEREDITY
Matthias Heuberger, Dal-Hoe Koo, Hanin Ibrahim Ahmed, Vijay K Tiwari, Michael Abrouk, Jesse Poland, Simon G Krattinger, Thomas Wicker
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引用次数: 0

摘要

背景:真核生物的中心粒功能是高度保守的,但不同物种之间的基本中心粒 DNA 序列却有很大差异。中心粒通常含有高比例的重复 DNA,如串联重复和/或转座元件(TE)。近缘小麦的中心粒缺乏串联重复序列,而主要由两个长末端重复(LTR)反转座子家族 RLG_Cereba 和 RLG_Quinta 组成,它们特异性地插入中心粒。然而,人们对这两个TE家族之间的关系以及它们是否和如何对中心粒的功能和进化做出贡献还知之甚少:根据诊断图案(LTR、整合酶和引物结合位点以及多聚嘌呤提取物)的保守性,我们认为RLG_Cereba和RLG_Quinta是一对自主和非自主的伙伴,其中自主的RLG_Cereba贡献了转座所需的所有蛋白质,而非自主的RLG_Quinta贡献了GAG蛋白。对预测的 GAG 蛋白的系统发育分析表明,RLG_Cereba 系至少在单子叶植物中存在了 1 亿年。相比之下,RLG_Quinta 是在 2,800 万年前至 3,500 万年前燕麦和小麦的共同祖先中从 RLG_Cereba 演化而来的。有趣的是,RLG_Cereba的整合酶与所谓的CR-domain融合,据推测,CR-domain可引导整合酶到达功能性中心粒。事实上,ChIP-seq 数据和 TE 群体分析表明,只有最年轻的 RLG_Cereba 和 RLG_Quinta 亚家族存在于活跃的中心粒中。重要的是,RLG_Quinta 和 RLG_Cereba 的 LTR 与中心粒特异性 CENH3 组蛋白变体的存在密切相关。我们推测,RLG_Cereba 和 RLG_Quinta 的 LTR 通过分期和/或放置 CENH3 核小体来促进小麦中心粒的完整性,从而有利于它们在竞争性中心粒-龛中的持续存在:我们的数据表明,RLG_Cereba 交叉移动了非自主的 RLG_Quinta 逆转录子。可能是通过整合酶 CR 结构域与 CENH3 组蛋白变体的直接结合,这两个家族的新拷贝被特异性地整合到功能性中心粒中。反过来,新插入的 RLG_Cereba 和 RLG_Quinta 元件的 LTR 也会招募和/或分阶段沉积新的 CENH3。这两个 TE 家族与植物宿主之间的相互影响动态地维持着小麦的中心粒。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Evolution of Einkorn wheat centromeres is driven by the mutualistic interplay of two LTR retrotransposons.

Background: Centromere function is highly conserved across eukaryotes, but the underlying centromeric DNA sequences vary dramatically between species. Centromeres often contain a high proportion of repetitive DNA, such as tandem repeats and/or transposable elements (TEs). Einkorn wheat centromeres lack tandem repeat arrays and are instead composed mostly of the two long terminal repeat (LTR) retrotransposon families RLG_Cereba and RLG_Quinta which specifically insert in centromeres. However, it is poorly understood how these two TE families relate to each other and if and how they contribute to centromere function and evolution.

Results: Based on conservation of diagnostic motifs (LTRs, integrase and primer binding site and polypurine-tract), we propose that RLG_Cereba and RLG_Quinta are a pair of autonomous and non-autonomous partners, in which the autonomous RLG_Cereba contributes all the proteins required for transposition, while the non-autonomous RLG_Quinta contributes GAG protein. Phylogenetic analysis of predicted GAG proteins showed that the RLG_Cereba lineage was present for at least 100 million years in monocotyledon plants. In contrast, RLG_Quinta evolved from RLG_Cereba between 28 and 35 million years ago in the common ancestor of oat and wheat. Interestingly, the integrase of RLG_Cereba is fused to a so-called CR-domain, which is hypothesized to guide the integrase to the functional centromere. Indeed, ChIP-seq data and TE population analysis show only the youngest subfamilies of RLG_Cereba and RLG_Quinta are found in the active centromeres. Importantly, the LTRs of RLG_Quinta and RLG_Cereba are strongly associated with the presence of the centromere-specific CENH3 histone variant. We hypothesize that the LTRs of RLG_Cereba and RLG_Quinta contribute to wheat centromere integrity by phasing and/or placing CENH3 nucleosomes, thus favoring their persistence in the competitive centromere-niche.

Conclusion: Our data show that RLG_Cereba cross-mobilizes the non-autonomous RLG_Quinta retrotransposons. New copies of both families are specifically integrated into functional centromeres presumably through direct binding of the integrase CR domain to CENH3 histone variants. The LTRs of newly inserted RLG_Cereba and RLG_Quinta elements, in turn, recruit and/or phase new CENH3 deposition. This mutualistic interplay between the two TE families and the plant host dynamically maintains wheat centromeres.

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来源期刊
Mobile DNA
Mobile DNA GENETICS & HEREDITY-
CiteScore
8.20
自引率
6.10%
发文量
26
审稿时长
11 weeks
期刊介绍: Mobile DNA is an online, peer-reviewed, open access journal that publishes articles providing novel insights into DNA rearrangements in all organisms, ranging from transposition and other types of recombination mechanisms to patterns and processes of mobile element and host genome evolution. In addition, the journal will consider articles on the utility of mobile genetic elements in biotechnological methods and protocols.
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