State Key Laboratory of Maize Bio-breeding/College of Plant Protection/Ministry of Agriculture and Rural Affairs Key Laboratory of Surveillance and Management for Plant Quarantine Pests, China Agricultural University, Beijing 100193, P.R. China.
State Key Laboratory of Maize Bio-breeding/College of Plant Protection/Ministry of Agriculture and Rural Affairs Key Laboratory of Surveillance and Management for Plant Quarantine Pests, China Agricultural University, Beijing 100193, P.R. China; Institute of Plant Protection and Microbiology, Zhejiang Academy of Agricultural Sciences, Zhejiang 310021, P.R. China.
Mol Plant. 2024 Oct 7;17(10):1606-1623. doi: 10.1016/j.molp.2024.09.006. Epub 2024 Sep 19.
Maize (Zea mays) is one of the most important crops in the world, but its yield and quality are seriously affected by diverse diseases. Identifying broad-spectrum resistance genes is crucial for developing effective strategies to control the disease in maize. In a genome-wide study in maize, we identified a G-type lectin receptor kinase ZmLecRK1, as a new resistance protein against Pythium aphanidermatum, one of the causal pathogens of stalk rot in maize. Genetic analysis showed that the specific ZmLecRK1 allele can confer resistance to multiple pathogens in maize. The cell death and disease resistance phenotype mediated by the resistant variant of ZmLecRK1 requires the co-receptor ZmBAK1. A naturally occurring A404S variant in the extracellular domain of ZmLecRK1 determines the ZmLecRK1-ZmBAK1 interaction and the formation of ZmLecRK1-related protein complexes. Interestingly, the ZmLecRK1 susceptible variant was found to possess the amino acid S404 that is present in the ancestral variants of ZmLecRK1 and conserved among the majority of grass species, while the resistance variant of ZmLecRK1 with A404 is only present in a few maize inbred lines. Substitution of S by A at position 404 in ZmLecRK1-like proteins of sorghum and rice greatly enhances their ability to induce cell death. Further transcriptomic analysis reveals that ZmLecRK1 likely regulates gene expression related to the pathways in cell wall organization or biogenesis in response to pathogen infection. Taken together, these results suggest that the ZmLecRK1 resistance variant enhances its binding affinity to the co-receptor ZmBAK1, thereby enhancing the formation of active complexes for defense in maize. Our work highlights the biotechnological potential for generating disease-resistant crops by precisely modulating the activity of ZmLecRK1 and its homologs through targeted base editing.
玉米(Zea mays)是世界上最重要的作物之一,但它的产量和品质受到多种疾病的严重影响。鉴定广谱抗性基因对于开发有效的玉米病害防治策略至关重要。在玉米的全基因组研究中,我们鉴定了一个 G 型凝集素受体激酶 ZmLecRK1,它是一种新的抗腐霉病菌(Pythium aphanidermatum)的抗性蛋白,腐霉病菌是玉米茎腐病的一种致病病原体。遗传分析表明,该特定的 ZmLecRK1 等位基因可以赋予玉米对多种病原体的抗性。由抗性变异体 ZmLecRK1 介导的细胞死亡和抗病表型需要共受体 ZmBAK1。ZmLecRK1 胞外结构域中的天然发生的 A404S 变异决定了 ZmLecRK1-ZmBAK1 相互作用和 ZmLecRK1 相关蛋白复合物的形成。有趣的是,发现易感性 ZmLecRK1 变体具有氨基酸 S404,该氨基酸存在于 ZmLecRK1 的祖先变体中,并在大多数禾本科物种中保守,而具有 A404 的抗性 ZmLecRK1 变体仅存在于少数玉米自交系中。在高粱和水稻的 ZmLecRK1 样蛋白中,S 到 A 的位置 404 取代极大地增强了它们诱导细胞死亡的能力。进一步的转录组分析表明,ZmLecRK1 可能调节与细胞壁组织或生物发生途径相关的基因表达,以响应病原体感染。总之,这些结果表明,ZmLecRK1 抗性变体增强了其与共受体 ZmBAK1 的结合亲和力,从而增强了玉米防御活性复合物的形成。我们的工作强调了通过靶向碱基编辑精确调节 ZmLecRK1 及其同源物的活性,从而产生抗病作物的生物技术潜力。
