Genetic transformation of the fungal pathogen responsible for rice blast disease.

The analysis of complex genetic determinants that control the ability of a fungus to colonize its host has been impaired by the lack of sophisticated genetic tools for characterizing important pathogens. We have developed a system for the genetic transformation of Magnaporthe grisea, the causal agent of rice blast disease, to overcome this limitation. A M. grisea arginine auxotroph was shown to contain a mutation (arg3-12) that abolishes ornithine carbamoyltransferase activity. M. grisea strains that contain arg3-12 were used as recipients in transformation experiments with plasmid pMA2, which carries the ArgB(+) gene from Aspergillus nidulans. Stable prototrophic transformants arose at a frequency of about 35 per microgram of plasmid DNA. Integration of single or multiple plasmid copies occurred at a single site in the genome of each transformant; rearrangements were often created during integration. When M. grisea genomic segments were incorporated into pMA2, the presence of any one of five different M. grisea segments did not greatly affect the efficiency of transformation. Integration via homologous recombination occurred when the donor plasmid was linearized by cleaving at a unique restriction site within the M. grisea segment.