Abstract
Zinc finger nucleases (ZFNs) have been successfully used for genome modification in various cell types and species. However, construction of an effective ZFN remained challenging. Previous studies all focused on obtaining specific zinc finger proteins (ZFPs) first via bacterial 2-hybrid approach, and then fusing selected ZFPs to FokI nuclease domain. These assembled ZFNs have high rate of failing to cleave target sites in vivo. In this study, we developed a simultaneous screening and validation system to obtain effective ZFNs directly in yeast AH109. This system is based on Gal4 reporter system carrying a unique intermediate reporter plasmid with two 30-bp Gal4 homology arms and a ZFN target site. DNA double strand breaks introduced on target sequence by ZFNs were repaired by single strand annealing (SSA) mechanism, and the restored Gal4 drove reporter genes expression. Taking the advantage of OPEN (Oligomerized Pool ENgineering) selection, we constructed 3 randomized ZFNs libraries and 9 reporter strains for each target gene. We tested this system by taking goat α s1-casein as target gene following three-step selection. Consequently, 3 efficient pairs of ZFNs were obtained from positive colonies on selective medium. The ZFNs achieved a 15.9% disruption frequency in goat mammary epithelial cells. In conclusion, we created a novel system to obtain effective ZFNs directly with simultaneous screening and validation.
Highlights
Zinc finger nucleases (ZFNs) as artificial enzymes exhibit extraordinary success in genome engineering
Key amino acids at position 21 to +6 relative to the start of the a-helix in one finger were altered by 7 degenerate codons (59-VNN-39), and the other two fingers were kept constant to breakpoint cluster region (BCR)-zinc finger proteins (ZFPs)
The reporter vector has three critical elements (Figure 1A): (1) target site located between two 30-bp homology arms, (2) KanMX4 expression cassette for G418 selection, (3) yeast-derived replicated centromere (CEN) element for a low copy number in yeast, which makes the copy of target site is similar with yeast genome
Summary
Zinc finger nucleases (ZFNs) as artificial enzymes exhibit extraordinary success in genome engineering. These enzymes are composed of a designed polymeric zinc finger protein (ZFP) and the nuclease domain of FokI restriction endonuclease [1,2]. ZFN-introduced DSBs can abrogate gene functions through imprecise repair of nonhomologous end joining (NHEJ) or introduce customized change by homologous recombination (HR) repair from a supplied donor DNA [4]. ZFNs-mediated genomic modification has been successfully demonstrated in a variety of plants and animals, including maize [5], C.elegans [6], Drosophila [7], Xenopus [8], zebrafish [9,10], mouse [11,12], rat [13] as well as human ES (embryonic stem) and iPS (induced pluripotent stem) cells [14]. ZFNs have shown potential in gene therapy: ZFN-modified human CD4+ T cells with permanent resistance to HIV infection are currently in phase 2 clinical trials for treatment of AIDS [15]
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