Kellari L M, Dalakouras A, Tsiouri O, Vletsos P, Katsaouni A, Uslu V V, Papadopoulou K K
Department of Biochemistry and Biotechnology, Laboratory of Plant and Environmental Biotechnology, University of Thessaly, Larissa, Greece.
Averofeio Agri-Food Technological Park of Thessaly, University of Thessaly, Larissa, Greece.
Plant Biol (Stuttg). 2025 Jun;27(4):504-514. doi: 10.1111/plb.70026. Epub 2025 May 16.
Cross-kingdom transfer of small RNA (sRNA) molecules has been identified as a means of communication between plants and interacting microorganisms, but the mechanistic details of this sRNA-based interaction remain elusive. We have previously shown that the beneficial root-colonizing fungus Fusarium solani strain K (FsK) translocates sRNAs to its host, Nicotiana benthamiana (Nb), leading to systemic silencing of a reporter gene. Here, we investigated the mechanistic details of the endophyte-induced systemic silencing using an RNAi sensor system. We inoculated three Nb GFP expressing lines with conidia of an FsK transformant containing a transgene that targets host GFP (FsK-hpGF). The efficiency of silencing mediated by FsK-hpGF was monitored both phenotypically under ultraviolet light as well as quantitatively by RT-qPCR. sRNA sequencing was performed to evaluate the production of sRNAs targeting host GFP. Finally, bisulfite sequencing was used to assess plant GFP methylation levels. We show that the translocated fungal sRNAs induced production of secondary sRNAs, mainly of 22-24-nt in size, with the conspicuous absence of 21-nt sRNAs. Importantly, systemic silencing could not be induced in an RNA-DEPENDENT RNA POLYMERASE 6 (RDR6) CRISPR/Cas knockout background, nor in an intron-containing target gene. Overall, our data show that endophyte-induced silencing in the host requires RDR6-mediated transitivity and amplification of silencing signals. Despite being based on an artificial RNAi sensor system, our observations may reflect a more generalized and so far unexplored facet of cross-kingdom RNAi, with RDR6-based transitivity influencing the way symbionts and pathogens elicit systemic phenotypes in their host plants.
小RNA(sRNA)分子的跨界转移已被确认为植物与相互作用的微生物之间的一种通讯方式,但这种基于sRNA的相互作用的机制细节仍不清楚。我们之前已经表明,有益的根定殖真菌茄病镰刀菌菌株K(FsK)将sRNAs转运到其宿主本氏烟草(Nb)中,导致报告基因的系统性沉默。在这里,我们使用RNA干扰传感器系统研究了内生菌诱导的系统性沉默的机制细节。我们用含有靶向宿主绿色荧光蛋白(GFP)的转基因的FsK转化体的分生孢子接种了三个表达Nb GFP的品系。通过在紫外光下的表型观察以及通过RT-qPCR进行定量监测,来评估由FsK-hpGF介导的沉默效率。进行sRNA测序以评估靶向宿主GFP的sRNAs的产生。最后,使用亚硫酸氢盐测序来评估植物GFP的甲基化水平。我们表明,转运的真菌sRNAs诱导了次级sRNAs的产生,其大小主要为22 - 24个核苷酸,明显缺乏21个核苷酸的sRNAs。重要的是,在RNA依赖性RNA聚合酶6(RDR6)CRISPR/Cas敲除背景中,或者在含有内含子的靶基因中,都不能诱导系统性沉默。总体而言,我们的数据表明,宿主中内生菌诱导的沉默需要RDR6介导的传递性和沉默信号的放大。尽管基于人工RNA干扰传感器系统,但我们的观察结果可能反映了跨界RNA干扰中一个更普遍且迄今未被探索的方面,基于RDR6的传递性影响共生体和病原体在其宿主植物中引发系统性表型的方式。
