Liu Xin, Hu Xiaochun, Tu Zhouyi, Sun Zhenbiao, Qin Peng, Liu Yikang, Chen Xinwei, Li Zhiqiang, Jiang Nan, Yang Yuanzhu
Key Laboratory of Southern Rice Innovation & Improvement, Ministry of Agriculture and Rural Affairs, Yuan Longping High-Tech Agriculture Co., Ltd., Changsha, China.
State Key Laboratory of Hybrid Rice, Hunan Hybrid Rice Research Center, Changsha, Hunan, China.
Front Plant Sci. 2024 Oct 9;15:1478159. doi: 10.3389/fpls.2024.1478159. eCollection 2024.
Phytopathogens represent an ongoing threat to crop production and a significant impediment to global food security. During the infection process, these pathogens spatiotemporally deploy a large array of effectors to sabotage host defense machinery and/or manipulate cellular pathways, thereby facilitating colonization and infection. However, besides their pivotal roles in pathogenesis, certain effectors, known as avirulence (AVR) effectors, can be directly or indirectly perceived by plant resistance (R) proteins, leading to race-specific resistance. An in-depth understanding of the intricate AVR-R interactions is instrumental for genetic improvement of crops and safeguarding them from diseases. (. ), the causative agent of rice blast disease, is an exceptionally virulent and devastating fungal pathogen that induces blast disease on over 50 monocot plant species, including economically important crops. Rice- pathosystem serves as a prime model for functional dissection of AVR effectors and their interactions with R proteins and other target proteins in rice due to its scientific advantages and economic importance. Significant progress has been made in elucidating the potential roles of AVR effectors in the interaction between rice and over the past two decades. This review comprehensively discusses recent advancements in the field of AVR effectors, with a specific focus on their multifaceted roles through interactions with corresponding R/target proteins in rice during infection. Furthermore, we deliberated on the emerging strategies for engineering R proteins by leveraging the structural insights gained from AVR effectors.
植物病原体对作物生产构成持续威胁,是全球粮食安全的重大障碍。在感染过程中,这些病原体在时空上部署大量效应子,以破坏宿主防御机制和/或操纵细胞途径,从而促进定殖和感染。然而,除了在致病过程中的关键作用外,某些效应子,即无毒(AVR)效应子,可被植物抗性(R)蛋白直接或间接识别,从而导致小种特异性抗性。深入了解复杂的AVR-R相互作用有助于作物的遗传改良并保护其免受病害侵害。稻瘟病菌是水稻稻瘟病的病原体,是一种极具毒性和破坏性的真菌病原体,可在包括经济上重要的作物在内的50多种单子叶植物物种上引发稻瘟病。由于其科学优势和经济重要性,水稻-稻瘟病菌系统是功能剖析AVR效应子及其与水稻中R蛋白和其他靶蛋白相互作用的主要模型。在过去二十年中,在阐明AVR效应子在水稻与稻瘟病菌相互作用中的潜在作用方面取得了重大进展。本综述全面讨论了AVR效应子领域的最新进展,特别关注它们在感染期间通过与水稻中相应的R/靶蛋白相互作用所发挥的多方面作用。此外,我们还探讨了利用从AVR效应子获得的结构见解来改造R蛋白的新兴策略。
