Site-Specific Integration by Circular Donor Improves CRISPR/Cas9-Mediated Homologous Recombination in Human Cell Lines.

The technology for obtaining the high-efficiency expression of target proteins through site-specific recombination has made progress. However, using the CRISPR/Cas9 system for site-specific integration of long fragments and the expression of active proteins remains a challenge. This study optimized the linear DNA circularization system, eliminated the prokaryotic plasmid backbone on the traditional foreign gene vector, and generated a homologous arm-free circular donor template with a single guide RNA target site (sgRNA TS). This strategy significantly increased the co-transfection efficiency of the 1.6 kb template and Cas9 plasmid by 1.15-fold, and the average knock-in (KI) efficiency of the 4.7 kb long-fragment template for the two target gene sites increased by 1.3-fold. Subsequently, we used rhBCHE as a reporter gene to efficiently integrate the 5.4 kb fragment containing the gene of interest (GOI) into specific sites in the HEK293T cell line to detect the expression of the circular template at different target sites. Overall, this study further verifies that the length of the circular donor is more conducive to non-homologous integration, and more importantly, we provide a simple and optimized strategy for the construction of long-fragment site integration cell lines.