RESUMO
The fast-rising CRISPR-derived gene editing technologies has been widely used in the fields of life science and biomedicine, as well as plant and animal breeding. However, the efficiency of homology-directed repair (HDR), an important strategy for gene knock-in and base editing, remains to be improved. In this study, we came up with the term Donor Adapting System (DAS) to summarize those CRISPR/Cas9 systems modified with adaptor for driving aptamer-fused donor DNA. A set of CRISPR/Cas9-Gal4BD DAS was designed in our study. In this system, Gal4 DNA binding domain (Gal4BD) is used as adaptor to fuse with Cas9 protein, and Gal4 binding sequence (Gal4BS) is used as aptamer to bind to the double-stranded DNA (dsDNA) donor, in order to improve the HDR efficiency. Preliminary results from the HEK293T-HDR.GFP reporter cell line show that the HDR editing efficiency could be improved up to 2-4 times when donor homologous arms under certain length (100-60 bp). Further optimization results showed that the choice of fusion port and fusion linker would affect the expression and activity of Cas9, while the Cas9-Gal4BD fusion with a GGS5 linker was the prior choice. In addition, the HDR efficiency was likely dependent on the aptamer-dsDNA donor design, and single Gal4BD binding sequence (BS) addition to the 5'-end of intent dsDNA template was suggested. Finally, we achieved enhanced HDR editing on the endogenous AAVS1 and EMX1 sites by using the CRISPR/Gal4BD-Cas9 DAS, which we believe can be applied to facilitate animal molecular design breeding in the future.
