CRISPR-mediated base editing can introduce single-nucleotide changes in the DNA of living cells. One intriguing application of base editing is to screen pivotal amino acids for protein function in vivo;… Click to show full abstract
CRISPR-mediated base editing can introduce single-nucleotide changes in the DNA of living cells. One intriguing application of base editing is to screen pivotal amino acids for protein function in vivo; however, it has not been achieved. Here, we report an enhanced third-generation base-editing system with extra nuclear localization sequences that can efficiently introduce a homozygous base mutation in embryonic stem cells. Meanwhile, we establish a strategy to generate base-mutant mice by injection of haploid embryonic stem cells carrying a constitutively expressed enhanced third-generation base-editing system (4B2N1) and single guide RNA into oocytes. Moreover, transfection of 4B2N1 cells with a single guide RNA library targeting the Dnd1 gene allows one-step generation of mutant mice with a base mutation. This enables the identification of four missense mutations that completely deplete primordial germ cells through disruption of DND1 protein stability and protein–protein interaction. Thus, our strategy provides an effective tool for in vivo screening of amino acids that are crucial for protein function.Li and colleagues develop a CRISPR–Cas9-based screen strategy that combines base editing and haploid embryonic stem cell technologies to identify amino acids critical for protein function in mice.
               
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