A gene with a thousand alleles: The hyper-variable effectors of plant-parasitic nematodes.

IF 11.1 Q1 CELL BIOLOGY Cell genomics Pub Date : 2024-06-12 Epub Date: 2024-05-29 DOI:10.1016/j.xgen.2024.100580
Unnati Sonawala, Helen Beasley, Peter Thorpe, Kyriakos Varypatakis, Beatrice Senatori, John T Jones, Lida Derevnina, Sebastian Eves-van den Akker
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Abstract

Pathogens are engaged in a fierce evolutionary arms race with their host. The genes at the forefront of the engagement between kingdoms are often part of diverse and highly mutable gene families. Even in this context, we discovered unprecedented variation in the hyper-variable (HYP) effectors of plant-parasitic nematodes. HYP effectors are single-gene loci that potentially harbor thousands of alleles. Alleles vary in the organization, as well as the number, of motifs within a central hyper-variable domain (HVD). We dramatically expand the HYP repertoire of two plant-parasitic nematodes and define distinct species-specific "rules" underlying the apparently flawless genetic rearrangements. Finally, by analyzing the HYPs in 68 individual nematodes, we unexpectedly found that despite the huge number of alleles, most individuals are germline homozygous. These data support a mechanism of programmed genetic variation, termed HVD editing, where alterations are locus specific, strictly governed by rules, and theoretically produce thousands of variants without errors.

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千变万化的基因:植物寄生线虫的超变异效应因子。
病原体与其宿主进行着激烈的进化军备竞赛。处于王国间交战最前沿的基因往往是多样化和高度变异基因家族的一部分。即使在这种情况下,我们也在植物寄生线虫的超变异(HYP)效应因子中发现了前所未有的变异。HYP 效应子是单基因位点,可能包含数千个等位基因。等位基因在中心超变异结构域(HVD)内的基序组织和数量上各不相同。我们极大地扩展了两种植物寄生线虫的 HYP 基因库,并确定了表面上完美无瑕的基因重排所依据的不同物种特异性 "规则"。最后,通过分析 68 条线虫个体的 HYPs,我们意外地发现,尽管等位基因数量巨大,但大多数个体都是种系同源的。这些数据支持一种被称为 HVD 编辑的程序化基因变异机制,在这种机制下,基因改变是特定位点的,严格受规则约束,理论上可以无差错地产生成千上万个变体。
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7.10
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