Department of Plant Pathology, Nanjing Agricultural University, Nanjing, 210095, China.
Zhongshan Biological Breeding Laboratory (ZBBL), Nanjing Agricultural University, Nanjing, 210095, China.
J Integr Plant Biol. 2024 Nov;66(11):2543-2560. doi: 10.1111/jipb.13772. Epub 2024 Sep 3.
Soybean rust (SBR), caused by an obligate biotrophic pathogen Phakopsora pachyrhizi, is a devastating disease of soybean worldwide. However, the mechanisms underlying plant invasion by P. pachyrhizi are poorly understood, which hinders the development of effective control strategies for SBR. Here we performed detailed histological characterization on the infection cycle of P. pachyrhizi in soybean and conducted a high-resolution transcriptional dissection of P. pachyrhizi during infection. This revealed P. pachyrhizi infection leads to significant changes in gene expression with 10 co-expressed gene modules, representing dramatic transcriptional shifts in metabolism and signal transduction during different stages throughout the infection cycle. Numerous genes encoding secreted protein are biphasic expressed, and are capable of inhibiting programmed cell death triggered by microbial effectors. Notably, three co-expressed P. pachyrhizi apoplastic effectors (PpAE1, PpAE2, and PpAE3) were found to suppress plant immune responses and were essential for P. pachyrhizi infection. Double-stranded RNA coupled with nanomaterials significantly inhibited SBR infection by targeting PpAE1, PpAE2, and PpAE3, and provided long-lasting protection to soybean against P. pachyrhizi. Together, this study revealed prominent changes in gene expression associated with SBR and identified P. pachyrhizi virulence effectors as promising targets of RNA interference-based soybean protection strategy against SBR.
大豆锈病(SBR)由专性活体营养病原菌 Phakopsora pachyrhizi 引起,是一种世界性的大豆毁灭性疾病。然而,P. pachyrhizi 入侵植物的机制尚不清楚,这阻碍了 SBR 的有效防治策略的发展。在这里,我们对 P. pachyrhizi 在大豆中的感染周期进行了详细的组织学描述,并对 P. pachyrhizi 的感染进行了高分辨率转录组解析。这表明 P. pachyrhizi 的感染导致基因表达发生显著变化,有 10 个共表达基因模块,代表了在感染周期不同阶段代谢和信号转导的剧烈转录变化。许多编码分泌蛋白的基因呈双相表达,并能够抑制由微生物效应物触发的程序性细胞死亡。值得注意的是,发现三个共表达的 P. pachyrhizi 质外体效应物(PpAE1、PpAE2 和 PpAE3)能够抑制植物的免疫反应,是 P. pachyrhizi 感染所必需的。双链 RNA 与纳米材料相结合,通过靶向 PpAE1、PpAE2 和 PpAE3 显著抑制了 SBR 的感染,并为大豆提供了对 P. pachyrhizi 的持久保护。总之,本研究揭示了与 SBR 相关的基因表达的显著变化,并确定了 P. pachyrhizi 毒力效应物是基于 RNA 干扰的大豆 SBR 防治策略的有前途的靶标。
