posted on 2022-07-25, 19:12authored byKun Gao, Yukun Qin, Linsong Wang, Xin Li, Song Liu, Ronge Xing, HuaHua Yu, Xiaolin Chen, Pengcheng Li
Hymexazol (HYM) is irreplaceable for treating soil-borne
diseases
due to its high efficiency and low cost, as a broad-spectrum fungicide.
However, when HYM is absorbed by plants, it is rapidly converted into
two glycoside metabolites, and the antifungal activities of these
glycosides are inferior to that of HYM. Therefore, in this study,
to maintain strong antifungal activity in vitro and in vivo, HYM was
glycosylated with amino sugars that have diverse biological activities
to simulate plant glycosylation. The antifungal experiment proved
that glycoside 15 has the highest antifungal activity,
and N-acetyl glucosamine and HYM had obvious synergistic
effects. According to the structure–activity relationship studies,
glycoside 15 had greater numbers of active electron-rich
regions and front-line orbital electrons due to the introduction of N-acetyl glucosamine. Moreover, glycoside 15 can significantly promote plant growth and induce an increase in
plant defense enzyme activity. Additionally, compared to HYM, the
results of electron microscopy and proteomics revealed that glycoside 15 has a unique antifungal mechanism. The promising antifungal
activity and interactions with plants mean that glycoside 15 is a potential green fungicide candidate. Furthermore, this research
conducted an interesting exploration of the agricultural applications
of amino sugars.