Establishing an Immune System Conferring DNA and RNA Virus Resistance in Plants Using CRISPR/Cas12a Multiplex Gene Editing.

Abstract

Two types of CRISPR/Cas systems (Cas9 and Cas13) have been used to combat eukaryotic viruses successfully. In this study, we established resistance to the DNA virus BSCTV and RNA virus TMV in Nicotiana benthamiana using the CRISPR-Cas12a multiplex gene editing system. We employed two effector proteins LbCas12a and FnCas12a coupled with six guide RNAs targeting virus genome and a novel mRNA-gRNA nucleic acid complex to transport gRNA efficiently. Compared with the BSCTV accumulation in the wild-type N. benthamiana, it was reduced by more than 90% by most transgenic events derived at 7 days post-inoculation. Additionally, the shoot-tip leaves were normal in the transgenic plants, whereas they appeared severely curled and stunted in wild-type N. benthamiana at 15 days post-infection. Target sites evaluation revealed that the editing system can directly destroy the structure of BSCTV viral genomes via large fragment deletions. We quantified TMV virus accumulation in the transgenic N. benthamiana lines by monitoring dynamic changes in GFP fluorescence and quantitative analysis by qPCR showed that the CRISPR-Cas12a system can introduce TMV virus resistance to N. benthamiana by preventing its systemic spread. Our study provides an innovative strategy-an mRNA-gRNA nucleic acid complex-which has proven to be highly effective in the gene-editing system and offers an efficient antiviral approach for generating virus-resistant plants.