The potato RNA metabolism machinery is targeted by the cyst nematode effector RHA1B for successful parasitism

Li Huang, Yulin Yuan, Chloe Lewis, Chao Xia, Cankui Zhang, Joanna Kud, Joseph C Kuhl, Allan Caplan, Louise-Marie Dandurand, Fangming Xiao
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Abstract

The potato (Solanum tuberosum) cyst nematode Globodera pallida induces a multinucleate feeding site (syncytium) in potato roots as its sole source of nutrition. Here, we demonstrate that the G. pallida effector RING-H2 finger A1b (RHA1B), which is a functional ubiquitin ligase, interferes with the carbon catabolite repression 4 (CCR4)-negative on TATA-less (NOT) deadenylase-based RNA metabolism machinery that regulates syncytium development in G. pallida-infected potato. Specifically, RHA1B targets the CCR4-associated factor 1 (CAF1) and StNOT10 subunits of the CCR4-NOT complex for proteasome-mediated degradation, leading to upregulation of the cyclin gene StCycA2 involved in syncytium formation. The StCAF1 subunit of CCR4-NOT recruits the RNA binding protein StPUM5 to deadenylate StCycA2 mRNA, resulting in shortened poly-A tails of StCycA2 mRNA and subsequently reduced transcript levels. Knockdown of either subunit (StCAF1 or StNOT10) of the CCR4-NOT complex or StPUM5 in transgenic potato plants resulted in enlarged syncytia and enhanced susceptibility to G. pallida infection, which resembles the phenotypes of StCycA2 overexpression transgenic potato plants. Genetic analyses indicate that transgenic potato plants overexpressing RHA1B exhibit similar phenotypes as transgenic potato plants with knockdown of StNOT10, StCAF1, or StPUM5. Thus, our data suggest that G. pallida utilizes the RHA1B effector to manipulate RNA metabolism in host plants, thereby promoting syncytium development for parasitic success.
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马铃薯 RNA 代谢机制是孢囊线虫效应子 RHA1B 成功寄生的目标
马铃薯(Solanum tuberosum)胞囊线虫 Globodera pallida 在马铃薯根部诱导多核取食部位(合胞体),作为其唯一的营养来源。在这里,我们证明了 G. pallida 的效应物 RING-H2 finger A1b (RHA1B)(它是一种功能性泛素连接酶)干扰了碳代谢抑制 4 (CCR4)-Negative on TATA-less (NOT) 死氨酰化酶为基础的 RNA 代谢机制,该机制调控 G. pallida 感染马铃薯中合胞体的发育。具体来说,RHA1B 以 CCR4-NOT 复合物中的 CCR4-associated factor 1 (CAF1) 和 StNOT10 亚基为靶标,进行蛋白酶体介导的降解,导致参与合胞体形成的细胞周期蛋白基因 StCycA2 上调。CCR4-NOT 的 StCAF1 亚基会招募 RNA 结合蛋白 StPUM5,使 StCycA2 mRNA 死链,导致 StCycA2 mRNA 的 poly-A 尾缩短,转录水平随之降低。在转基因马铃薯植株中敲除 CCR4-NOT 复合物的任一亚基(StCAF1 或 StNOT10)或 StPUM5 会导致合胞体增大,并增强对 G. pallida 感染的敏感性,这与 StCycA2 过表达转基因马铃薯植株的表型相似。遗传分析表明,过表达 RHA1B 的转基因马铃薯植株与敲除 StNOT10、StCAF1 或 StPUM5 的转基因马铃薯植株表现出相似的表型。因此,我们的数据表明,G. pallida 利用 RHA1B 效应器来操纵寄主植物的 RNA 代谢,从而促进合胞体的发育,使寄生成功。
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