High-efficiency and multiplex adenine base editing in plants using new TadA variants

Recently reported adenine base editors (ABEs) exhibit powerful potential for targeted gene correction as well as developing gain-of-function mutants and novel germplasms for both gene function studies and crop breeding. However, editing efficiency varies significantly among different target sites. Here, we investigated the activities of three evolved E. coli adenosine deaminase TadA variants (TadA8e, TadA8.17, and TadA8.20) side-by-side in transgenic rice. We found that TadA8e outperforms TadA8.17 and TadA8.20, and induces efficient A-to-G conversion at all tested sites in the rice genome, including those that were uneditable by ABE7.10 in our previous experiments. Furthermore, V82S/Q154R mutations were incorporated into TadA8e, resulting in a new variant that we named TadA9. Our data show that TadA9 is broadly compatible with CRISPR/SpCas9, CRISPR/SpCas9-NG, and CRISPR/SpRY, as well as CRISPR/ScCas9 nickase systems, achieving comparable or enhanced editing in a larger editing window at diverse PAM sites as compared with TadA8e. Finally, TadA9 was used to simultaneously install novel SNPs in four endogenous herbicide target genes in the commercial rice cultivar Nangeng 46 for potential field application in weed control. Collectively, we successfully generated a series of novel ABEs that can efficiently edit adenosines in the rice genome. Our findings suggest that TadA9 and TadA8e have great potentials in the development of plant base editors and crop molecular breeding. This study reveals that TadA8e outperforms TadA8.17 and TadA8.20 and achieves efficient adenine base editing in rice, whileTadA9 achieves comparable or enhanced editing in a larger editing window at tested sites as compared with TadA8e and can simultaneously edits four endogenous target genes at high efficiency. Both TadA9 and TadA8e are broadly compatible with CRISPR/SpCas9, CRISPR/SpCas9-NG, and CRISPR/SpRY, as well as CRISPR/ScCas9 nickase systems for efficient adenine base editing by targeting diverse PAM sequences in rice..