Metabolism of nivalenol and nivalenol-3-glucoside in rats.

Plant-derived mycotoxin conjugates like deoxynivalenol-3-glucoside can be partly hydrolyzed to their aglycones in vivo, albeit to different extent depending on the mycotoxin conjugate and on the animal species. The aim of this work was to investigate the metabolization of the trichothecene mycotoxin nivalenol (NIV) and the fate of its modified form NIV-3-glucoside (NIV3G) in rats. To that end, 350 µg/kg body weight of NIV and the equimolar dose of NIV3G were administered to six rats by gavage in a 5 × 6 design and excreta were collected for 2 days after each treatment. For further analysis of NIV and NIV3G metabolites in rat urine and feces, seven novel NIV- and NIV3G metabolites including NIV sulfonates (NIVS) 1, 2 and 3, deepoxy-NIV (DNIV), DNIV sulfonate 2, NIV3G sulfonate (NIV3GS) 2 and NIV-3-glucuronide were produced, isolated and characterized. Subsequently, LC-MS/MS based methods for determination of NIV, NIV3G and their metabolites in excreta samples were developed, validated and applied. The biological recoveries of administered toxins in the form of their fecal and urinary metabolites were 57 ± 21% for NIV and 94 ± 36% for NIV3G. The majority of NIV and NIV3G metabolites was excreted into feces, with DNIV and NIVS 2 as major NIV metabolites and NIV3GS 2 and DNIV as major metabolites of NIV3G. Only 1.5% of the administered NIV3G was recovered in urine, with NIV3G itself as major urinary metabolite. The biological recovery of free NIV in urine was approximately 30 times lower after treatment with NIV3G than after administration of NIV, indicating that exposure of rats to NIV3G results in lower toxicity than exposure to NIV.

Metabolism of Zearalenone and Its Major Modified Forms in Pigs.

The Fusarium mycotoxin zearalenone (ZEN) can be conjugated with polar molecules, like sugars or sulfates, by plants and fungi. To date, the fate of these modified forms of ZEN has not yet been elucidated in animals. In order to investigate whether ZEN conjugates contribute to the total ZEN exposure of an individual, ZEN (10 µg/kg b.w.) and equimolar amounts of two of its plant metabolites (ZEN-14-O-ß-glucoside, ZEN-16-O-ß-glucoside) and of one fungal metabolite (ZEN-14-sulfate) were orally administered to four pigs as a single bolus using a repeated measures design. The concentrations of ZEN, its modified forms and its mammalian metabolites ZEN-14-glucuronide, α-zearalenol (α-ZEL) and α-ZEL-14-glucuronide in excreta were analyzed by high-performance liquid chromatography tandem mass spectrometry (HPLC-MS/MS) based methods. The biological recovery of ZEN in urine was 26% ± 10%, the total biological recovery in excreta was 40% ± 8%. Intact ZEN-14-sulfate, ZEN-14-O-ß-glucoside and ZEN-16-O-ß-glucoside were neither detected in urine nor in feces. After ZEN-14-sulfate application, 19% ± 5% of the administered dose was recovered in urine. In feces, no ZEN metabolites were detected. The total biological recoveries of ZEN-14-O-ß-glucoside and ZEN-16-O-ß-glucoside in the form of their metabolites in urine were 19% ± 11% and 13% ± 7%, respectively. The total biological recoveries in urine and feces amounted to 48% ± 7% and 34 ± 3%. An explanation for the low biological recoveries could be extensive metabolization by intestinal bacteria to yet unknown metabolites. In summary, ZEN-14-sulfate, ZEN-14-O-ß-glucoside, and ZEN-16-O-ß-glucoside were completely hydrolyzed in the gastrointestinal tract of swine, thus contributing to the overall toxicity of ZEN.