In several independent studies, it was demonstrated that reactive oxygen species such as H2O2 are key players and crucial in the regulation of cell differentiation in microbial eukaryotes [32, 33]. In accordance with this, it was demonstrated that NADPH oxidases which generate reactive oxygen are decisive in fungal cell differentiation and growth in a model system using Neurospora crassa [34]. Taken together, these results not only reinforce the hypothesis that H2O2 can induce DON biosynthesis but also suggest that DON accumulation induced by sub lethal triazole application click here is mediated through
an increased production or release of H2O2 into the medium rendering a physiological
interface of H2O2 influencing DON production. It is tempting to speculate on the mechanistics behind these observations. We hypothesize that due to the inhibition of ergosterol biosynthesis by the application of triazole fungicides, an increased cell permeability results in the CHIR98014 chemical structure increased release of H2O2 in the medium which in turns activates the trichothecene biosynthesis machinery. Indeed, although H2O2 is a very reactive molecule which can diffuse freely across bio membranes, it has been shown in a Sacharomyces model system that organisms prevent H2O2 diffusion [35, 36]. This hypothesis is subscribed by accumulating indirect evidence in many other fungi. As such in Candida ergosterol depletion increases vulnerability to phagocytic oxidative damage [37]. In Sacharomyces it was demonstrated using ergosterol knock out mutants that ergosterol depletion results in a changed biophysical property of the plasma membrane leading to an increased permeability towards H2O2[38]. Although beyond the scope of the present paper it is important to notice that triazole fungicides on their own can generate H2O2 in planta as an intermediate
metabolite in plants through Adriamycin cell line activation of antioxidant systems [39] generating as such a greening effect which results in a retardation of the senescence [40]. why The effect of this physiological induced H2O2 in planta on DON production by an invading F. graminearum is till now not studied and certainly needs more attention in the future. Conclusions In the present work it was shown that sub lethal prothioconazole concentrations resulted in a significant increase in DON production by F. graminearum in a combined approach of an in vitro assay and an artificial infection trial. In the in vitro assay, the stimulated DON production was preceded by a prompt induction of H2O2 suggesting that the proliferated DON production was induced by an oxidative stress response in the fungus.