Taj Mehwish, Sajjad Muhammad, Li Mingju, Yasmeen Arooj, Mubarik Muhammad Salman, Kaniganti Sirisha, He Chi
Department of Biosciences, COMSATS University, Islamabad, Pakistan.
Yunnan Key Laboratory of Green Prevention and Control of Agricultural Transboundary Pests, Agricultural Environment and Resource Institute, Yunnan Academy of Agricultural Sciences, Kunming, China.
Front Genet. 2022 Jun 16;13:926955. doi: 10.3389/fgene.2022.926955. eCollection 2022.
Wheat is one of the most important food crops worldwide. Even though wheat yields have increased considerably in recent years, future wheat production is predicted to face enormous challenges due to global climate change and new versions of diseases. CRISPR/Cas technology is a clean gene technology and can be efficiently used to target genes prone to biotic stress in wheat genome. Herein, the published research papers reporting the genetic factors corresponding to stripe rust, leaf rust, stem rust, powdery mildew, fusarium head blight and some insect pests were critically reviewed to identify negative genetic factors (Susceptible, S genes) in bread wheat. Out of all reported genetic factors related to these disease, 33 genetic factors (S genes) were found as negative regulators implying that their down-regulation, deletion or silencing improved disease tolerance/resistance. The results of the published studies provided the concept of proof that these 33 genetic factors are potential targets for CRISPR/Cas knockdowns to improve genetic tolerance/resistance against these diseases in wheat. The sequences of the 33 genes were retrieved and re-mapped on the latest wheat reference genome IWGSC RefSeq v2.1. Phylogenetic analysis revealed that pathogens causing the same type of disease had some common conserved motifs and were closely related. Considering the significance of these disease on wheat yield, the S genes identified in this study are suggested to be disrupted using CRISPR/Cas system in wheat. The knockdown mutants of these S genes will add to genetic resources for improving biotic stress resistance in wheat crop.
小麦是全球最重要的粮食作物之一。尽管近年来小麦产量大幅增加,但由于全球气候变化和新型病害,预计未来小麦生产将面临巨大挑战。CRISPR/Cas技术是一种基因编辑技术,可有效用于靶向小麦基因组中易受生物胁迫的基因。本文对已发表的关于条锈病、叶锈病、秆锈病、白粉病、赤霉病和一些害虫的遗传因子的研究论文进行了批判性综述,以确定普通小麦中的负向遗传因子(感病基因,S基因)。在所有报道的与这些病害相关的遗传因子中,发现33个遗传因子(S基因)为负调控因子,这意味着对它们的下调、缺失或沉默可提高抗病性。已发表研究的结果提供了证据,证明这33个遗传因子是CRISPR/Cas敲除的潜在靶点,可提高小麦对这些病害的遗传抗性。检索了这33个基因的序列,并在最新的小麦参考基因组IWGSC RefSeq v2.1上重新定位。系统发育分析表明,引起同类型病害的病原体具有一些共同的保守基序,且亲缘关系密切。考虑到这些病害对小麦产量的重要性,建议利用CRISPR/Cas系统在小麦中破坏本研究中鉴定的S基因。这些S基因的敲除突变体将增加小麦作物提高生物胁迫抗性的遗传资源。
