The choice of target site is crucial in artificial miRNA-mediated virus resistance in transgenic Nicotiana tabacum

MicroRNAs (miRNAs) are negative regulators of gene expression via mRNA degradation or translational repression. The potential of artificial miRNAs (amiRNAs) as antiviral agents has been used in plant biotechnology. In this study, we designed eight amiRNAs derived from Potato Virus Y (PVY) Coat Protein RNA sequences and generated transgenic tobacco plants to express these amiRNAs to confer virus resistance against PVY. Together with transient assays, the hairpin amiRcp precursors that mimic natural miRNA precursor molecules proved to be effective in expressing amiRcps and silencing the target gene. Virus resistance assay revealed that not all amiRcps targeting viral CP sequence are equally effective in preventing PVY infection. Plants with amiRcp-8 targeting the 3′ end (nt735–nt754) region exhibited high virus resistance up to 64.69%. The amiRcp-6 harboring RNA sequence (nt567–nt586) induced the lowest percentages with only 17.05%. Besides, northern blots showed that there was a correlation between the resistance level and the accumulation of amiRNA expression. Furthermore, we used bioinformatics approach to predict the mRNA structure and found that targeting sequences of loose structure benefit to improve the virus resistance level. Our results indicate that the selection of appropriate target sequence is crucial for transgenic plant against virus and provide useful guideline for the design of pathogen-derived amiRNAs.

► Expression of artificial miRNA targeting PVY-CP gene conferred plant high resistance. ► The 3′ end of target gene was more effective than 5′ end in mediating RNA silencing. ► Position of target sequence influence amiRNA-mediated virus resistance. ► The resistance level was well correlated to the miRNA expression level. ► Silencing efficacy depended on amiRNA characteristic and accessibility of target site.