Primordial germ cells (PGCs) that can differentiate into gametes are used to produce genome-edited chickens. However, the transfection efficiency into PGCs is low in chickens; therefore, the yield efficiency of PGCs modified via genome editing is problematic. In this study, we improved transfection efficiency and achieved highly efficient genome editing in chicken PGCs. For transfection, we used lipofection, which is convenient for gene transfer. Chicken PGC cultures require adding heparin to support growth; however, heparin significantly reduces lipofection efficiency (p<0.01). Heparin-induced lipofection efficiency was restored by adding protamine. Based on these results, we optimized gene transfer into chicken PGCs. Lipofectamine™ 2000 and our PGC medium was the most efficient transfection reagent and medium, respectively. Finally, based on established conditions, we compared the gene knock-out efficiencies of ovomucoid, a major egg allergen, and gene knock-in efficiencies at the ACTB locus. These results indicate that optimized lipofection is useful for CRISPR/Cas9-mediated knock-out and knock-in. Our findings may contribute to the generation of genome-edited chickens and stimulate research in various applications involving them.

Chicken eggs have gained attention as excellent bioreactors because of their genetic modifications. However, the development of chicken egg bioreactors requires a long time from the construction of the production system to the evaluation of the products. Therefore, in this study, we established a chicken cell line producing ovalbumin (OVA) and constructed a system for the rapid evaluation of the production system. First, we knocked in the EF1α promoter upstream of the OVA locus in chicken DF-1 cells for continuous OVA expression. Furthermore, we analyzed and identified an ideal position at the OVA locus for the insertion of useful protein genes to maximize recombinant protein yield. We found that knocking in the EF1α promoter upstream of exon1 yielded the maximum production of OVA protein. In addition, we found that production efficiency was higher with linking the recombinant gene hFGF2 to the 5′ side of the OVA gene and with the use of 2A peptide for linkage. Therefore, we established an OVA-expressing cell line and an evaluation system for proteins in chicken egg bioreactors. Our findings may improve the efficiency of chicken expression systems and expand their applications in protein production.