Exogenous RNA application is a promising transgene-free approach for crop protection and improvement. In almost all applications reported so far, exogenous RNA molecules (double stranded RNAs or small RNAs) are applied to plants in order to trigger degradation of a given mRNA (of plant, pest or pathogen origin), in a process termed post-transcriptional gene silencing (PTGS). However, whether exogenous RNAs can also trigger epigenetic modifications to plants such as RNA-directed DNA methylation (RdDM) and transcriptional gene silencing (TGS) remains largely unaddressed. Here, we provide evidence that high pressure spraying of a 24-nt short interfering RNA (siRNA) designed to target the CaMV 35S promoter that drives the expression of a GFP transgene, resulted in promoter RdDM in N. benthamiana. Moreover, the methylation at the target site spreads both up and downstream neighboring sites. Importantly, GFP expression was reduced in the sprayed leaf tissues. Small RNA sequencing excluded the presence siRNAs mapping to the GFP gene body and documented substantial amount of secondary RNAs in the promoter, suggesting that the GFP silencing was transcriptional rather than post-transcriptional. Our study provides a proof of principle for spray induced epigenetic modification (SPIEM) that could be used in modern crop breeding platforms.
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