Highly efficient transgene-free genome editing in tobacco using an optimized CRISPR/Cas9 system, pOREU3TR

CRISPR/Cas9 genome-editing technology has revolutionized plant science and holds enormous promise for crop improvement. The exploration of this system received much attention regarding plant genome editing. Here, by editing the NtPDS gene in tobacco, we first verified that incorporating an OsU3-tRNA promoter combination into the CRISPR/Cas9 system contributed to the highest editing efficiency, as the sgRNA expression level was greater than that resulting from the AtU6-tRNA and AtU6 promoters. Then, we optimized the existing tobacco CRISPR/ Cas9 system, pORE-Cas9, by using the OsU3-tRNA promoter combination instead of AtU6 and by fusing an AtUb10-Ros1 expression cassette to the T-DNA to monitor the transgene events. The new system was named pOREU3TR. As expected, 49 transgene-free and homozygous gene-edited green plants were effectively screened in the T1 generation as a result of editing the NtLHT1 gene in tobacco, and the plant height and the contents of most free amino acids in the leaves of the T2 mutant plants were significantly different from those in the leaves of WT plants, demonstrating the high efficiency of the new editing system. This OsU3-tRNA-sgRNA/AtUb10-Ros1 system provides essential improvements for increasing the efficiency of plant genome editing.

Automated summary

CRISPR/Cas9 genome-editing technology has revolutionized plant science, showing great potential for crop improvement. By editing the NtPDS gene in tobacco, researchers have demonstrated that incorporating an OsU3-tRNA promoter combination into the CRISPR/Cas9 system can enhance editing efficiency. The optimized tobacco CRISPR/Cas9 system, named pOREU3TR, successfully produced transgene-free and homozygous gene-edited plants with significant differences in plant height and amino acid content. This OsU3-tRNA-sgRNA/AtUb10-Ros1 system provides essential improvements for increasing the efficiency of plant genome editing.