Abstract
Gene editing is a promising alternative to traditional breeding for the generation of new mushroom strains. However, the current approach frequently uses Cas9-plasmid DNA to facilitate mushroom gene editing, which can leave residual foreign DNA in the chromosomal DNA raising concerns regarding genetically modified organisms. In this study, we successfully edited pyrG of Ganoderma lucidum using a preassembled Cas9-gRNA ribonucleoprotein complex, which primarily induced a double-strand break (DSB) at the fourth position prior to the protospacer adjacent motif. Of the 66 edited transformants, 42 had deletions ranging from a single base to large deletions of up to 796 bp, with 30 being a single base deletion. Interestingly, the remaining 24 contained inserted sequences with variable sizes at the DSB site that originated from the fragmented host mitochondrial DNA, E. coli chromosomal DNA, and the Cas9 expression vector DNA. The latter two were thought to be contaminated DNAs that were not removed during the purification process of the Cas9 protein. Despite this unexpected finding, the study demonstrated that editing G. lucidum genes using the Cas9-gRNA complex is achievable with comparable efficiency to the plasmid-mediated editing system.