Abstract

RNA interference (RNAi) shows significant effectiveness in conferring resistance to viral infections in various plants. The current study was conducted to develop transgenic tomato (Solanum lycopersicum cv. Rio Grande) lines expressing a 320 bp conserved inverted region of the integral 35S promoter region. The molecular cloning was done for the construction of expression vectors in a hairpin structure by the Tomato spotted wilt orthotospovirus (TSWV) species Orthotospovirus tomatomaculae, silencing suppressor (NSs) gene. It contains both sense and antisense orientation in a binary vector pFGC5941. Short hairpin RNA (shRNA) structures were employed to reduce the possibility of inducing endogenous non-specific antiviral responses, which usually target longer double-stranded RNAs (dsRNAs). To confirm the transgenic plants, molecular analysis was performed using TSWV gene-specific primers (TSWV-NSs). Based on the EHA105 Agrobacterium strain and the pFGC5941 vector carrying NSs and nptII genes in the T-DNA region, the results validate the insertion of kanamycin resistance into the regenerated transgenic plants. The virus source harboring TSWV was used to inoculate putative transgenic plants for evaluating the confirmation of successful transformation strategy for inducing virus resistance. Quantitative real-time polymerase chain reaction (qRT-PCR) assays were performed by using qRT-NSs primer pairs to determine the relative gene expression of all constructs (TSWV-NSs both sense and antisense orientation) after inoculations. In comparison to the control groups, which contained wild type control (non-transgenic tomato plant), empty pFGC5941 vector and the pFGC5941+sense construct, the expression of the NSs gene was noticeably reduced in the full clone (pFGC5941+sense + antisense) construct. For the validation of RNAi effectiveness, Nicotiana tabacum plants were also inoculated with viral constructs. Specifically, they displayed severe symptoms of TSWV in plants containing the pFGC5941+sense, pFGC5941 empty vector, and in wild-type tomato plants that are correlated with bioassay results. The lack of TSWV symptoms validated the hypothesis after careful observation of the expression of NSs genes in terms of pathogenicity. This research demonstrates the RNA interference effectiveness by targeting NSs gene as a reliable technique for achieving long lasting antiviral protection in tomatoes. The findings have practical relevance and the potential to be a tool for limiting tomato crop losses caused by TSWV worldwide.

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