Targeted deletion of three CYP51s in Fusarium fujikuroi and their different roles in determining sensitivity to 14α‐demethylase inhibitor fungicides

Abstract Background Fusarium fujikuroi is the pathogenic agent of rice bakanae disease and has developed serious resistance to prochloraz, a 14α‐demethylase inhibitor (DMI). Prochloraz resistance in F . fujikuroi is caused by cooperation between FfCyp51B with Cyp51A and shows cross‐resistance only to prothioconazole but not to tebuconazole, difenoconazole, propiconazole, metconazole, hexaconazole, and triadimefon. This study aimed to analyze the functions of the three Cyp51s in F . fujikuroi , especially their role in determining sensitivity to DMIs. Results The respective deletion of FfCyp51A , Cyp51B , and Cyp51C had no obvious effect on morphology, conidium germination, or pathogenicity. The involvement of growth, growth and ergosterol biosynthesis, and conidium production and ergosterol biosynthesis was observed for FfCyp51A , Cyp51B , and Cyp51C , respectively. Compared with the sensitive isolate of F. fujikuroi , the effect on sensitivity to the tested DMIs was divided into four groups: (i) both of Cyp51A and Cyp51B positively regulate the sensitivity to prochloraz and prothioconazole; (ii) Cyp51B positively regulate the sensitivity to tebuconazole and metconazole, but negatively regulate the sensitivity to difenoconazole; (iii) Cyp51A and Cyp51B play opposite roles in the sensitivity to triadimefon. Therefore, deletion of Cyp51A in F . fujikuroi confers a higher sensitivity to triadimefon, while deletion of Cyp51B results in a triadimefon‐resistant mutant isolate; (iv) deletion of Cyp51B yielded a mutant isolate that was more resistant to propiconazole and hexaconazole. Conclusion Sophisticated interactions exist within the three Cyp51 genes to DMIs fungicides sensitivity in F. fujikuroi , and Cyp51B probably plays a more critical role than Cyp51A and Cyp51C. © 2022 Society of Chemical Industry.