Sesquiterpenyl epoxy-cyclohexenoids (SECs) that depend on a polyketide synthase-terpenoid synthase (PKS-TPS) pathway are widely distributed in plant pathogenic fungi. However, the biosynthesis and function of the acetylated SECs still remained cryptic. Here, we identified that AOL_s00215g 273 (273) was responsible for the acetylation of SECs in Arthrobotrys oligospora via the construction of Δ273, in which the acetylated SECs were absent and major antibacterial nonacetylated SECs accumulated. Mutant Δ273 displayed increased trap formation, and nematicidal and antibacterial activities but decreased fungal growth and soil colonization. Glutamine, a key precursor for NH3 as a trap inducer, was highly accumulated, and biologically active phenylpropanoids and antibiotics were highly enriched in Δ273. The decreased endocytosis and increased autophagosomes, with the most upregulated genes involved in maintaining DNA and transcriptional stability and pathways related to coronavirus disease and exosome, suggested that lack of 273 might result in increased virus infection and the acetylation of SECs played a key role in fungal diverse antagonistic ability.
Keywords: AOL_s00215g273; Arthrobotrys oligospora; acetylation; diverse antagonistic ability; function; polyketide synthase−terpenoid synthase (PKS−TPS) hybrid pathway; sesquiterpenyl epoxy-cyclohexenoids (SECs).