Abstract
Plant-derived phase II metabolites of T-2 toxin (T2) and HT-2 toxin (HT2) were first described in 2011 and further characterized in the following years. Since then, some efforts have been made to understand their biosynthesis, occurrence, toxicity, toxicokinetics, and finally relevance for consumers. Thus, the probably most important question is whether and how these metabolites contribute to toxicity upon hydrolysis either during food processing or the gastrointestinal passage. To answer this question, firstly, knowledge on the correct stereochemistry of T2 and HT2 glucosides is important as this affects hydrolysis and chemical behavior. So far, contradictory results have been published concerning the number and anomericity of occurring glucosides. For this reason, we set up different strategies for the synthesis of mg-amounts of T2, HT2, and T2 triol glucosides in both α and ß configuration. All synthesized glucosides were fully characterized by NMR spectroscopy as well as mass spectrometry and used as references for the analysis of naturally contaminated food samples to validate or invalidate their natural occurrence. Generally, 3-O-glucosylation was observed with two anomers of HT2 glucoside being present in contaminated oats. In contrast, only one anomer of T2 glucoside was found. The second aspect of this study addresses the stability of the glucosides during thermal food processing. Oat flour was artificially contaminated with T2 and HT2 glucosides individually and extruded at varying initial moisture content and temperature. All four glucosides appear to be more stable during food extrusion than the parent compounds with the glucosidic bond not being hydrolyzed.
Highlights
The Fusarium-toxins T-2 toxin (3α-hydroxy-4ß,15diacetoxy-8α-(3-methylbutoxy)-12,13-epoxy-trichothec9-ene, T2, Fig. 1) and HT-2 toxin (3α,4ß-dihydroxy-15acetoxy-8α-(3-methylbutoxy)-12,13-epoxy-trichothec-9ene, HT2, Fig. 1) are both classified as type A trichothecenes
Modified forms of T2 and HT2, especially the in planta formed glucosides, are of increasing interest due to their possible health concern. They were discovered more than a half decade ago, the structures of the food-relevant glucosides of T2 and HT2 are not fully characterized and some of the reports in literature are conflicting
The full set of T2 and HT2 glucosides in α and ß configuration was prepared and characterized
Summary
The Fusarium-toxins T-2 toxin (3α-hydroxy-4ß,15diacetoxy-8α-(3-methylbutoxy)-12,13-epoxy-trichothec9-ene, T2, Fig. 1) and HT-2 toxin (3α,4ß-dihydroxy-15acetoxy-8α-(3-methylbutoxy)-12,13-epoxy-trichothec-9ene, HT2, Fig. 1) are both classified as type A trichothecenes. Neither the European Union nor the USA have established maximum levels for T2 and HT2 (Mazumeder and Sasmal 2001; European Commission 2006) This is attributed to an inchoate state of scientific knowledge regarding the year-toyear variations in toxin occurrence, the influence of agronomic and processing factors, and the presence of modified forms of both toxins in food and feed (European Commission 2013). Two studies analyzed the stability of T2 and HT2 glucosides during food processing (De Angelis et al 2013; Lattanzio et al 2015). SS-glucosides of HT2 could be obtained from experiments using recombinant UDP-glucosyltransferases (UGT) out of Arabidopsis thaliana (Poppenberger et al 2003), rice (Michlmayr et al 2015a), or barley (Schweiger et al 2010) expressed in yeast or Escherichia coli Another possible approach is based on exploiting bacterial induced transformations of mycotoxins. Flour samples artificially spiked with α and ß configured glucosides of T2 and HT2 were subjected to food extrusion to study the stability of the glucosidic bond
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