CRISPR-mediated chromosome deletion facilitates genetic mapping of Vip3Aa resistance gene within complex genomic region in an invasive global pest

Minghui Jin, Yinxue Shan, Yan Peng, Shenlin Chen, Xuanhe Zhou, Kaiyu Liu, Yutao Xiao
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Abstract

Connecting genetic variation to phenotypes and understanding the underlying biological mechanisms has been a fundamental goal of biological genetics. Here, we used the association analysis to identify a Vip3Aa resistance-associated genomic region in a strain of fall armyworm, JC-R, which exhibits >5000-fold resistance to the Bt toxin Vip3Aa. However, through various analytical approaches and fine-scale mapping across different populations, we demonstrated that this genomic region exhibits strong genetic linkage. The chromosome-level genome of JC-R and its parent strain JC-S were assembled, and extensive structural variations in the linkage regions were identified, which could be responsible for maintaining the linkage. To identify the causal variation within this linked region, a chromosome fragment stepwise knockout strategy based on CRISPR/Cas9 was developed. By crossing with the resistant strain and phenotyping segregating offspring on Vip3Aa-containing diet, we identified a chromosomal segment, KO8, containing the resistant gene. Subsequently, we conducted a comprehensive analysis of the variations in the KO8 region using multi-omics approaches, including genomic data, RNA-seq, proteomic, PacBio long read Iso-seq, and phosphoproteomic data. This analysis identified multiple variations in the chitin synthase gene CHS2, including amino acid substitution, alternative splicing, and changes in phosphorylation sites. After knocking out the CHS2, larvae exhibited over 6777-fold resistance to Vip3Aa. These results demonstrate that the chromosome fragment stepwise knockout strategy is a viable approach for studying complex genomic regions, and highlight the value of comprehensive analysis of genetic variations using multi-omics data. The identified candidate gene could potentially advance monitoring and management of pest resistance to Vip3Aa.
CRISPR-mediated chromosome deletion facilitates genetic mapping of Vip3Aa resistance gene within complex genomic region in an invasive global pest
将遗传变异与表型联系起来并理解其背后的生物学机制一直是生物遗传学的基本目标。在这里,我们利用关联分析鉴定了秋刺吸虫品系 JC-R 的 Vip3Aa 抗性相关基因组区域,该品系对 Bt 毒素 Vip3Aa 的抗性高达 >5000倍。然而,通过各种分析方法和不同种群间的精细图谱绘制,我们证明了该基因组区域具有很强的遗传连锁性。我们组装了 JC-R 及其亲本菌株 JC-S 的染色体级基因组,并确定了连接区的广泛结构变异,这些变异可能是维持连接的原因。为了确定该连接区的致病变异,研究人员开发了一种基于 CRISPR/Cas9 的染色体片段逐步敲除策略。通过与抗性品系杂交,并在含有 Vip3Aa 的饮食中对分离后代进行表型分析,我们确定了含有抗性基因的染色体片段 KO8。随后,我们采用多组学方法对 KO8 区域的变异进行了全面分析,包括基因组数据、RNA-seq、蛋白质组、PacBio long read Iso-seq 和磷酸化蛋白质组数据。这项分析确定了几丁质合成酶基因 CHS2 的多种变异,包括氨基酸替换、替代剪接和磷酸化位点的变化。敲除 CHS2 基因后,幼虫对 Vip3Aa 的抗性提高了 6777 倍。这些结果表明,染色体片段逐步敲除策略是研究复杂基因组区域的一种可行方法,并凸显了利用多组学数据对遗传变异进行综合分析的价值。所确定的候选基因有可能推进害虫对 Vip3Aa 抗性的监测和管理。
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