Jinqi Tang, Yan Li, Shun Gong, Tianzhong Li, Qiulei Zhang
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引用次数: 0
Abstract
Alternaria leaf spot, a fungal disease affecting apple production globally, incurs significant economic losses annually. The pathogenic fungus, A. alternata f. sp. mali (ALT), produces the host-specific AM-toxin and secretory proteins, which disrupt plant metabolism, leading to increased defoliation, fruit drop, compromised fruit quality, and reduced production. In this study, we isolated eight novel ALT strains from Fuji apple leaves exhibiting leaf spot. The most aggressive strain, ALT7, was identified. To determine ALT7 secretory proteins, LC-MS analysis was performed, which showed that three secreted proteins were detected: AaAO (alcohol oxidase), AaPDE (alkaline phosphatase), and AaABC (ATP-binding cassette transporter). Agrobacterium-mediated transgenesis confirmed the extracellular localization of GFP-fused AaAO, AaABC, and AaPDE. To investigate their function, we used fungal transgenesis. Overexpression of AaABC, AaAO, and AaPDE in ALT7 increased its pathogenicity. Conversely, knocking them down decreased ALT7 pathogenicity. Additionally, AaABC was found to facilitate the secretion of AaAO and AaPDE. And AaAO and AaPDE facilitate plant susceptibility by degrading plant cell walls, while AaABC plays a crucial role in their transport, thereby participating in the plant pathogenic process. In conclusion, our findings suggest that AaABC in A. alternata f. sp. mali mediates the secretion of toxic proteins AaAO and AaPDE.
稻瘟病是一种影响全球苹果生产的真菌病,每年造成重大的经济损失。致病真菌A. alternata f. sp. mali (ALT)产生宿主特异性am毒素和分泌蛋白,破坏植物代谢,导致落叶增加、果实掉落、果实质量受损和产量减少。本研究从富士苹果叶片中分离到了8株新的ALT菌株。鉴定出最具侵袭性的菌株为ALT7。为了确定ALT7分泌蛋白,采用LC-MS分析,检测到三种分泌蛋白:AaAO(酒精氧化酶)、AaPDE(碱性磷酸酶)和AaABC (atp结合盒转运蛋白)。农杆菌介导的转基因证实了gfp融合的AaAO、AaABC和AaPDE的细胞外定位。为了研究它们的功能,我们使用了真菌转基因。ALT7中AaABC、AaAO和AaPDE的过表达增加了其致病性。相反,敲除它们会降低ALT7的致病性。此外,我们还发现AaABC能够促进AaAO和AaPDE的分泌。AaAO和AaPDE通过降解植物细胞壁促进植物易感,而AaABC在它们的转运中起着至关重要的作用,从而参与植物的致病过程。综上所述,我们的研究结果表明,马利褐花拟南麻的AaABC介导了有毒蛋白AaAO和AaPDE的分泌。
期刊介绍:
Horticultural Plant Journal (HPJ) is an OPEN ACCESS international journal. HPJ publishes research related to all horticultural plants, including fruits, vegetables, ornamental plants, tea plants, and medicinal plants, etc. The journal covers all aspects of horticultural crop sciences, including germplasm resources, genetics and breeding, tillage and cultivation, physiology and biochemistry, ecology, genomics, biotechnology, plant protection, postharvest processing, etc. Article types include Original research papers, Reviews, and Short communications.
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