Abstract

<i>Ustilaginoidea virens</i> is the causal agent of rice false smut, one of the major fungal diseases of rice. However, there are only limited molecular studies with this important pathogen due to the lack of efficient approaches for generating targeted gene disruption mutants. In this study, we used the CRISPR-Cas9 system to efficiently generate mutants deleted of the <i>USTA</i> ustiloxin and <i>UvSLT2</i> MAP kinase genes. Three gRNA spacers of <i>USTA</i>, UA01, UA13, and UA21, were expressed with the RNAP III promoter of Gln-tRNA. For all of them, the homologous gene replacement frequency was higher when the Cas9 and gRNA constructs were transformed into <i>U. virens</i> on the same vector than sequentially. UA01, the spacer with the highest on-target score, had the highest knockout frequency of 90%, which was over 200 times higher than that of <i>Agrobacterium tumefaciens</i>-mediated transformation (ATMT) for generating <i>ustA</i> mutants. None of these <i>USTA</i> spacers had predicted off-targets with 1 or 2-nt variations. For predicted off-targets with 3 or 4-nt variations, mutations were not detected in 10 <i>ustA</i> mutants generated with spacer UA13 or UA21, indicating a relatively low frequency of off-target mutations in <i>U. virens</i>. For <i>UvSLT2</i>, the homologous gene replacement frequency was 50% with CRISPR-Cas9, which also was significantly higher than that of ATMT. Whereas <i>ustA</i> mutants had no detectable phenotypes, <i>Uvslt2</i> mutants were slightly reduced in growth rate and reduced over 70% in conidiation. Deletion of <i>UvSLT2</i> also increased sensitivity to cell wall stresses but tolerance to hyperosmotic or oxidative stresses. Taken together, our results showed that the CRISPR-Cas9 system can be used as an efficient gene replacement or editing approach in <i>U. virens</i> and the UvSlt2 MAP kinase pathway has a conserved role in cell wall integrity.