Generation of inheritable A-to-G transitions using adenine base editing and NG-PAM Cas9 in Arabidopsis thaliana

CRISPR/Cas9 technology is an important tool for functional genomics and crop improvement. It can be used to generate mutations at precise positions in the genome. Base editors consist of deaminase components and Cas9 to specify the type of mutation, such as C-to-T (cytosine base editors) or A-to-G (adenine base editors) transition. Available adenine base editor vectors usually make use of canonical Cas9, which limits their use to 5'-NGG-3' containing targets. We combined a relaxed variant of SpCas9 that uses 5'-NG-3' containing targets with the adenine base editor containing TadA7.10 or TadA8e to make a set of vectors. By using a phenotype-based screen, we found that our vectors efficiently induce A-to-G somatic mutations in a 5'-NGG-3' PAM context in Arabidopsis thaliana up to 81% efficiency. Such mutations are inheritable at the homozygous stage in T2. Among tested vectors, pECNUS4 (Addgene #184887), which carries TadA8e, showed highest efficiency at generating a stable A-to-G transition in a 5'-NGH-3' PAM context in the gene DM3. Using this vector, we were able to recreate a naturally occurring allele of DM3 in two generations without the transgene. pECNUS4 is a new component of the CRISPR toolbox to be used for introducing desired adenine base transitions with an expanded target window for functional genomic research and trait improvement.