CRISPR-induced indels and base editing using the Staphylococcus aureus Cas9 in potato

Genome editing is now widely used in plant science for both fundamental research and molecular crop breeding. The clustered regularly interspaced short palindromic repeats (CRISPR) technology, through its precision, high efficiency and versatility, allows to edit many sites in plant genomes. This system has been highly successful to produce of knock-out mutants through the introduction of frameshift mutations due to error-prone repair pathways. Nevertheless, recent new CRISPR-based technologies such as base editing and prime editing can generate precise and on request nucleotide conversion, allowing to fine-tune protein function and generate gain-of-function mutants. However, genome editing through CRISPR systems still have some drawbacks and limitations, such as the PAM restriction and the need for more diversity in CRISPR tools to simultaneously mediate different catalytic activities. In this study, we successfully used the CRISPR-Cas9 system from Staphylococcus aureus (SaCas9) for the introduction of frameshift mutations in the tetraploid genome of the cultivated potato ( Solanum tuberosum ). We also developed a S. aureus -cytosine base editor that mediate nucleotide conversions, allowing to precisely modify specific residues or regulatory elements in potato. Our proof-of-concept results in potato expand the plant dicot CRISPR toolbox for biotechnology and precision breeding applications.