Base Editing of Somatic Cells Using CRISPR-Cas9 in .

Cas9 and a guide RNA (gRNA) function to target specific genomic loci for generation of a double-stranded break. Catalytic dead versions of Cas9 (dCas9) no longer cause double-stranded breaks and instead can serve as molecular scaffolds to target additional enzymatic proteins to specific genomic loci. To generate mutations in selected genomic residues, dCas9 can be used for genomic base editing by fusing a cytidine deaminase (CD) to induce C > T (or G>A) mutations at targeted sites. In this study, we test base editing in by expressing a transgenic base editor (based on the mammalian BE2) that consists of a fusion protein of CD, dCas9, and uracil glycosylase inhibitor. We utilized transgenic lines expressing gRNAs along with pan-tissue expression of the base editor () and found high rates of base editing at multiple targeted loci in the 20 bp target sequence. Highest rates of conversion of C > T were found in positions 3-9 of the gRNA-targeted site, with conversion reaching ∼100% of targeted DNA in somatic tissues. Surprisingly, the simultaneous use of two gRNAs targeting a genomic region spaced ∼50 bp apart led to mutations between the two gRNA targets, implicating a method to broaden the available sites accessible to targeting. These results indicate base editing is efficient in , and could be used to induce point mutations at select loci.