Identification of anti-fungal bioactive terpenoids from the bioenergy crop switchgrass (Panicum virgatum)

Abstract

AbstractPlant derived bioactive small molecules have attracted attention of scientists across fundamental and applied scientific disciplines. We seek to understand the influence of these phytochemicals on functional phytobiomes. Increased knowledge of specialized metabolite bioactivities could inform strategies for sustainable crop production. Our recent investigations of metabolomes of the upland and lowland ecotypes of the bioenergy crop switchgrass (Panicum virgatum) revealed large differences in types and abundances of terpenoid specialized metabolites. We hypothesized that – consistent with accumulating evidence that switchgrass genotype impacts microbiome assembly – differential terpenoid accumulation contributes to switchgrass ecotype-specific microbiome composition. An initialin vitroplate-based disc diffusion screen of 18 switchgrass root derived fungal isolates revealed differential responses to upland- and lowland-isolated metabolites. To identify specific fungal growth-modulating metabolites, we tested fractions from root extracts on three ecologically important fungal isolates –Linnemania elongata, Trichodermasp. andFusariumsp. Saponins and diterpenoids were identified as the most prominent antifungal metabolites. Finally, analysis of liquid chromatography-purified terpenoids revealed fungal inhibition structure – activity relationships (SAR). Saponin antifungal activity was primarily determined by the number of sugar moieties – saponins glycosylated at a single core position were inhibitory whereas saponins glycosylated at two core positions were inactive. Saponin core hydroxylation and acetylation were also associated with reduced activity. Diterpenoid activity required the presence of an intact furan ring for strong fungal growth inhibition. This study demonstrates that switchgrass genotype-specific metabolites differentially inhibit fungal isolates from the root and rhizosphere, supporting the hypothesis that these small molecules contribute to microbiome assembly and function.