Abstract
Plants traditionally used by farmers to manage livestock ailments could reduce reliance on synthetic antibiotics and anthelmintics but in many cases their chemical composition is unknown. As a case study, we analyzed the metabolite profiles of 17 plant species and 45 biomass samples from agricultural grasslands in England using targeted and untargeted metabolite profiling by liquid-chromatography mass spectrometry. We identified a range of plant secondary metabolites, including 32 compounds with known antimicrobial/anthelmintic properties which varied considerably across the different plant samples. These compounds have been shown previously to target multiple aspects of pathogen physiology and metabolism in vitro and in vivo, including inhibition of quorum sensing in bacteria and egg viability in nematodes. The most abundant bioactive compounds were benzoic acid, myricetin, p-coumaric acid, rhamnetin, and rosmarinic acid. Four wild plants (Filipendula ulmaria (L.) Maxim., Prunella vulgaris L., Centuarea nigra L., and Rhinanthus minor L.) and two forage legumes (Medicago sativa L., Trifolium hybridium L.) contained high levels of these compounds. Forage samples from native high-diversity grasslands had a greater abundance of medicinal compounds than samples from agriculturally improved grasslands. Incorporating plants with antibiotic/anthelmintic compounds into livestock feeds may reduce global drug-resistance and preserve the efficacy of last-resort drugs.
Highlights
Defense mechanisms[12,13,14]
We use liquid-chromatography mass spectrometry and metabolic network analysis to investigate variability in the antimicrobial and anthelmintic compounds found in 17 grassland plant species in Oxfordshire, England
We examined the availability of antimicrobial and anthelmintic compounds in 45 mixed-forage samples from current agricultural grasslands to determine how species-composition affects the overall chemical composition of grassland biomass
Summary
Defense mechanisms[12,13,14] These are temporary solutions and will not overcome resistance in the long term. Microbial and parasitic pathogens continually develop resistance to compounds from other bacteria and fungi and rapidly evolve defense mechanisms against treatments targeting specific genetic sequences and surface proteins. The chemical composition of many wild grassland plants and the biosynthesis of the antimicrobial and anthelmintic compounds they contain is unknown. To date it is uncertain whether adding a few species with medicinal compounds into agricultural grasslands can affect the overall chemical composition of the entire sward. We examined the availability of antimicrobial and anthelmintic compounds in 45 mixed-forage samples from current agricultural grasslands to determine how species-composition affects the overall chemical composition of grassland biomass
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