Pest Manag Sci 2013 May 01;695:642-51. doi: 10.1002/ps.3418.

Role of sterol 3-ketoreductase sensitivity in susceptibility to the fungicide fenhexamid in Botrytis cinerea and other phytopathogenic fungi.

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BACKGROUND: The narrow-spectrum fungicide fenhexamid was introduced into French vineyards in 2000 to control grey mould caused by a complex of two cryptic species: Botrytis cinerea, the predominant species sensitive to fenhexamid, and Botrytis pseudocinerea, naturally resistant. Fenhexamid was suggested to inhibit the 3-ketoreductase involved at C-4 demethylation steps during ergosterol biosynthesis, as revealed by its effects on the B. cinerea sterol profile. Resistance monitoring studies have hitherto identified two B. cinerea fenhexamid-resistant phenotypes, both resulting from mutations in the erg27 gene encoding 3-ketoreductase. RESULTS: The role of 3-ketoreductase sensitivity in fungal susceptibility to fenhexamid was investigated by studying sterol profiles and microsomal 3-ketoreductase in various fungal strains. Fenhexamid does inhibit B. cinerea 3-ketoreductase activity. Erg27 mutations causing amino acid substitutions in or near the transmembrane domain strongly decrease the affinity of fenhexamid for 3-ketoreductase. Fenhexamid has very low affinities for 3-ketoreductase in inherently resistant species, whether closely related to B. cinerea, like B. pseudocinerea, or more distantly related, like Nectria haematococca. CONCLUSION: erg27 mutation and erg27 polymorphism may therefore contribute to the unfavourable binding of fenhexamid to its target, 3-ketoreductase, explaining the acquisition of fenhexamid resistance in B. cinerea and the narrow spectrum of this fungicide.

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Genes referenced: LOC582915