Genome scans for selection signatures identify candidate virulence genes for adaptation of the soybean cyst nematode to host resistance

IF 4.5 1区生物学 Q1 BIOCHEMISTRY & MOLECULAR BIOLOGY

Molecular Ecology Pub Date : 2024-08-12 DOI:10.1111/mec.17490

Khee Man Kwon, João P. G. Viana, Kimberly K. O. Walden, Mariola Usovsky, Andrew M. Scaboo, Matthew E. Hudson, Melissa G. Mitchum

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Abstract

Plant pathogens are constantly under selection pressure for host resistance adaptation. Soybean cyst nematode (SCN, Heterodera glycines) is a major pest of soybean primarily managed through resistant cultivars; however, SCN populations have evolved virulence in response to selection pressures driven by repeated monoculture of the same genetic resistance. Resistance to SCN is mediated by multiple epistatic interactions between Rhg (for resistance to H. glycines) genes. However, the identity of SCN virulence genes that confer the ability to overcome resistance remains unknown. To identify candidate genomic regions showing signatures of selection for increased virulence, we conducted whole genome resequencing of pooled individuals (Pool-Seq) from two pairs of SCN populations adapted on soybeans with Peking-type (rhg1-a, rhg2, and Rhg4) resistance. Population differentiation and principal component analysis-based approaches identified approximately 0.72–0.79 million SNPs, the frequency of which showed potential selection signatures across multiple genomic regions. Chromosomes 3 and 6 between population pairs showed the greatest density of outlier SNPs with high population differentiation. Conducting multiple outlier detection tests to identify overlapping SNPs resulted in a total of 966 significantly differentiated SNPs, of which 285 exon SNPs were mapped to 97 genes. Of these, six genes encoded members of known stylet-secreted effector protein families potentially involved in host defence modulation including venom-allergen-like, annexin, glutathione synthetase, SPRYSEC, chitinase, and CLE effector proteins. Further functional analysis of identified candidate genes will provide new insights into the genetic mechanisms by which SCN overcomes soybean resistance and inform the development of molecular markers for rapidly screening the virulence profile of an SCN-infested field.

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基因组扫描选择特征确定了大豆胞囊线虫适应宿主抗性的候选毒力基因。

植物病原体不断受到宿主抗性适应性的选择压力。大豆胞囊线虫（SCN，Heterodera glycines）是大豆的一种主要害虫，主要通过抗性栽培品种进行管理；然而，在重复单一栽培相同抗性基因的选择压力下，SCN 种群的毒力也发生了进化。对 SCN 的抗性是由 Rhg（抗甘氨酸瘤牛）基因之间的多种外显相互作用介导的。然而，赋予克服抗性能力的 SCN 毒力基因的身份仍然未知。为了确定显示毒力增强选择特征的候选基因组区域，我们对在具有北京型（rhg1-a、rhg2 和 Rhg4）抗性的大豆上适应的两对 SCN 群体的集合个体（Pool-Seq）进行了全基因组重测序。基于种群分化和主成分分析的方法确定了约 0.72-0.79 百万个 SNPs，其频率显示了多个基因组区域的潜在选择特征。种群对之间的第 3 和第 6 染色体显示出密度最大的离群 SNP，种群分化程度较高。通过多重离群点检测测试来识别重叠的SNPs，结果共发现了966个显著分化的SNPs，其中285个外显子SNPs被映射到97个基因上。其中，6 个基因编码可能参与宿主防御调节的已知stylet分泌效应蛋白家族成员，包括毒液-过敏原样蛋白、附件蛋白、谷胱甘肽合成酶、SPRYSEC、几丁质酶和CLE效应蛋白。对已确定候选基因的进一步功能分析将为了解 SCN 克服大豆抗性的遗传机制提供新的视角，并为开发分子标记提供信息，以便快速筛选 SCN 侵染田块的毒力特征。

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

Molecular Ecology 生物-进化生物学

CiteScore

8.40

自引率

10.20%

发文量

472

审稿时长

1 months

期刊介绍： Molecular Ecology publishes papers that utilize molecular genetic techniques to address consequential questions in ecology, evolution, behaviour and conservation. Studies may employ neutral markers for inference about ecological and evolutionary processes or examine ecologically important genes and their products directly. We discourage papers that are primarily descriptive and are relevant only to the taxon being studied. Papers reporting on molecular marker development, molecular diagnostics, barcoding, or DNA taxonomy, or technical methods should be re-directed to our sister journal, Molecular Ecology Resources. Likewise, papers with a strongly applied focus should be submitted to Evolutionary Applications. Research areas of interest to Molecular Ecology include: * population structure and phylogeography * reproductive strategies * relatedness and kin selection * sex allocation * population genetic theory * analytical methods development * conservation genetics * speciation genetics * microbial biodiversity * evolutionary dynamics of QTLs * ecological interactions * molecular adaptation and environmental genomics * impact of genetically modified organisms