Zearalenone (ZEN) is a common mycotoxin, for which only reductive metabolites have been identified so far. We now report that ZEN is extensively monohydroxylated by microsomes from human liver in vitro. Two of the major oxidative metabolites arise through aromatic hydroxylation and are catechols. Their chemical structures have been unambiguously determined by using deuterium-labeled ZEN and by comparison with authentic reference compounds. Moreover, both catechol metabolites of ZEN were substrates of the enzyme catechol-O-methyl transferase. One of the monomethyl ethers represented the major metabolite when ZEN was incubated with rat liver slices, thus demonstrating that catechol formation also takes place under in vivo-like conditions. Out of ten major human cytochrome P450 (hCYP) isoforms only hCYP1A2 was able to hydroxylate ZEN to its catechols with high activity. Catechol formation represents a novel pathway in the metabolism of ZEN and may be of toxicological relevance.
The nitrocellulose binding assay was used for quantitative studies on the cytochemical reactions for the three enzymes most frequently used in immunocytochemistry. The results show a linear relationship between the amount of enzyme immobilized on nitrocellulose and the amount of the enzyme reaction product. The similar course of the formation of the reaction product after DAB/H2O2 staining for peroxidase immobilized on nitrocellulose and for immunoperoxidase labeled cells indicates a linear relationship between the amount of enzyme-coupled antibodies bound to cells and the amount of enzyme reaction product. Furthermore, a mild acid treatment for the abolition of endogeneous peroxidase activity in tissues and cells applicable to immunoperoxidase staining procedures is proposed.
Zearalenone (ZEN) is a mycotoxin produced by Fusarium species and frequently found as a contaminant of food and feed. Earlier studies have disclosed that ZEN is biotransformed in microsomes from human and rat liver to multiple hydroxylated metabolites, two of which have recently been identified as products of aromatic hydroxylation. Here, we report for the first time on the structure elucidation of metabolites arising through hydroxylation of the aliphatic ring of ZEN at various positions. By using reference compounds and ZEN labeled with deuterium at specific positions, evidence was provided for the preferential hydroxylation of ZEN at C-8 and, to a lesser extent, at C-9, C-10, and C-5. In contrast, hydroxylation at C-6 could be ruled out, as could oxidation of the olefinic double bond. These results imply that the phase I metabolism of ZEN in the mammalian organism is more extensive than previously thought, and warrant further studies on the in vivo formation of the novel ZEN metabolites and their biological activities.
The mycotoxin zearalenone (ZEN) is produced by various Fusarium fungi and frequently found as a contaminant in food and feed. There are reports in the literature that several closely related analogues of ZEN are also formed in cultures of Fusarium species. We have therefore analyzed the organic extract from a 40 day culture of Fusarium graminearum by LC-DAD-MS and detected 15 compounds, which could be congeners of ZEN because of their ultraviolet, mass spectroscopy, and tandem mass spectroscopy spectra. In addition to confirming the previously reported α- and β-stereoisomers of 5-hydroxy-ZEN and 10-hydroxy-ZEN, we identified seven ZEN congeners for the first time. One of the major novel congeners was shown by nuclear magnetic resonance spectroscopy and chemical synthesis to have the structure of an aliphatic ZEN epoxide, whereas two minor products proved to be the corresponding dihydrodiols. In addition, three stereoisomers of a cyclization product of the dihydrodiols, carrying a spiro-acetal group, were identified as fungal products for the first time. The latter may be artifacts, because the ZEN epoxide and dihydrodiol are unstable under acidic conditions and rearrange easily to the spiro-acetal compounds.
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