Abstract

Flavine adenine dinucleotide (FAD) dependent glucose methanol choline oxidoreductase (GMC oxidoreductase) is the terminal key enzyme of the patulin biosynthetic pathway. GMC oxidoreductase catalyzes the oxidative ring closure of (<i>E</i>)-ascladiol to patulin. Currently, no protein involved in the patulin biosynthesis in <i>Penicillium expansum</i> has been experimentally characterized or solved by X-ray diffraction. Consequently, nothing is known about <i>P. expansum</i> GMC oxidoreductase substrate-binding site and mode of action. In the present investigation, a 3D comparative model for <i>P. expansum</i> GMC oxidoreductase has been described. Furthermore, a multistep computational approach was used to identify <i>P. expansum</i> GMC oxidoreductase residues involved in the FAD binding and in substrate recognition. Notably, the obtained 3D comparative model of <i>P. expansum</i> GMC oxidoreductase was used for performing a virtual screening of a chemical/drug library, which allowed to predict new GMC oxidoreductase high affinity ligands to be tested in in vitro/in vivo assays. In vitro assays performed in presence of 6-hydroxycoumarin and meticrane, among the highly affinity predicted binders, confirmed a dose-dependent inhibition (17-81%) of patulin production by 6-hydroxycoumarin (10 µM-1 mM concentration range), whereas the approved drug meticrane inhibited patulin production by 43% already at 10 µM. Furthermore, 6-hydroxycoumarin and meticrane caused a 60 and 41% reduction of patulin production, respectively, in vivo on apples at 100 µg/wound.