Structure-based virtual screening of hypothetical inhibitors of the enzyme longiborneol synthase—a potential target to reduce Fusarium head blight disease

Molecular insight into the mechanism of lipid regulating effect of Alisma orientalis based on ACAT

We studied the lipid-regulating effect and molecular mechanism of the medical components of Alisma orientalis: alisol A, alisol B, 23-acetyl alisol C (23C) and the 3 (alisol A): 1(alisol B):1(23C) and 2(alisol A):2(alisol B):1(23C) mixtures designed based on the ratio of them in Alisma orientalis from Fujian, Guangxi Province, China. The animal experiment and network pharmacology showed that ACAT was one of its lipid-regulating targets and alisols may reduce the level of TC by inhibiting ACAT activity. The molecular simulation and homologous modeling results suggested that the binding of alisol mixtures with ACAT was stronger than that of monomers because alisol monomers acted on different active regions of ACAT resulting in the superposition effect and caused the synergistic effect. The lipid-regulating effect of Fujian mixture was stronger than that of Guangxi mixture showing that 3:1:1 was a better ratio. The N-terminal lipid-regulating activity of ACAT was stronger than that of transmembrane domain 1.

Chemical synthesis of culmorin metabolites and their biologic role in culmorin and acetyl-culmorin treated wheat cells

The Fusarium metabolite culmorin (1) is receiving increased attention as an "emerging mycotoxin". It co-occurs with trichothecene mycotoxins and potentially influences their toxicity. Its ecological role and fate in plants is unknown. We synthesized sulfated and glucosylated culmorin conjugates as potential metabolites, which are expected to be formed in planta, and used them as reference compounds. An efficient procedure for the synthesis of culmorin sulfates was developed. Diastereo- and regioselective glucosylation of culmorin (1) was achieved by exploiting or preventing unexpected acyl transfer when using different glucosyl donors. The treatment of a wheat suspension culture with culmorin (1) revealed an in planta conversion of culmorin into culmorin-8-glucoside (6) and culmorin acetate, but no sulfates or culmorin-11-glucoside (7) was found. The treatment of wheat cells with the fungal metabolite 11-acetylculmorin (2) revealed its rapid deacetylation, but also showed the formation of 11-acetylculmorin-8-glucoside (8). These results show that plants are capable of extensively metabolizing culmorin.