High-efficiency, transgene-free plant genome editing by viral delivery of an engineered TnpB

Abstract Genome editing has revolutionized plant biology research. However, efficient and straightforward delivery of editing reagents remains a major challenge. Viral delivery systems can address these issues, but CRISPR-Cas nucleases are often too large for viral vectors. Recently, smaller editors like TnpBs have been identified, but wild-type TnpBs are significantly less active than commonly used Cas9 nucleases. Here, we optimized a tobacco rattle virus (TRV)-based system to deliver newly discovered, highly active engineered ISDra2 TnpB variants. Our results demonstrate that the eTnpBc variant delivered via TRV enables effective somatic editing in systemic leaves and achieves up to 90% editing efficiency at target loci, significantly higher than that of wild-type ISDra2 TnpB. Additionally, up to 89% of offspring exhibit a mutant phenotype, with editing efficiencies reaching 100%. The design principles outlined here are expected to accelerate broader adoption of eTnpBc for transformation- and transgene-free genome editing in plants.