Abstract
The CRISPR/Cas9 gene-editing system is a powerful tool in plant genetic engineering; however, screening for Cas9-free edited plants remains complex and time-consuming. To address this limitation, we developed an RNA aptamer-assisted CRISPR/Cas9 system, termed 3WJ-4 × Bro/Cas9. In this system, the engineered RNA aptamer 3WJ-4 × Bro functions as a transcriptional reporter, serving as an alternative to traditional fluorescent proteins and thus avoiding their potential interference with Cas9 activity. Compared to the conventional GFP/Cas9 system, 3WJ-4 × Bro/Cas9 showed more efficient transformation and higher accuracy in fluorescence-based selection of positive T1 transformants, without significantly affecting plant growth. Furthermore, 3WJ-4 × Bro/Cas9 achieved a 78.6% increase in the T1 mutation rate compared to GFP/Cas9, with the homozygous mutation rate reaching 1.78%. In addition, 3WJ-4 × Bro/Cas9 enabled fluorescence-based visual screening in the T2 generation for rapid identification of Cas9-free mutants, improving sorting efficiency by 30.2% over the GFP-based method. Moreover, 3WJ-4 × Bro/Cas9 enabled more efficient generation of homozygous double-target mutants compared to GFP/Cas9. These results demonstrate that the 3WJ-4 × Bro/Cas9 system provides a non-transgenic, efficient, and broadly applicable strategy for plant genome editing and selection.