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Assessing the risks of plant pathogen resistance evolution for the success of microbe-mediated biocontrol

Project description

Microbial biocontrol solutions and resistance in plants

Biological control is an effective and sustainable alternative to conventional pesticides for managing plant diseases. Biocontrol bacteria produce antimicrobial compounds but it’s uncertain if pathogens can develop resistance. Funded by the Marie Skłodowska-Curie Actions programme, the RhizoEvo project will investigate tomato plant pathogen resistance using specific biocontrol bacteria. Researchers will develop a system for tracking bacterial adaptations across successive plant generations, combining various microbiological, genomics and metabolomics analyses. Project findings will provide fundamental insight into the long-term impact of biocontrol, assessing the risks of pathogen resistance and enhancing knowledge of microbial evolution in agriculture.

Objective

Microbe-mediated plant pathogen biocontrol has been suggested as an environmentally friendly alternative for agrochemicals to increase global food production. While biocontrol bacteria have been shown to suppress the growth of plant pathogenic bacteria via the production of antimicrobials, it remains unclear whether pathogens can escape this by evolving resistance. The main aim of this proposal is to experimentally test whether plant pathogenic Ralstonia solanacearum bacterium can evolve resistant to Pseudomonas protegens biocontrol bacterium in the tomato plant rhizosphere. I will also test if pathogen resistance evolution results in co-evolution and increased antimicrobial activity of the biocontrol bacterium, and if microbial adaptations will affect how both bacteria interact with the tomato plant, potentially shifting plant-microbe interactions along the parasitism-mutualism continuum (virulence vs. plant growth-promotion). To achieve this, I will learn to use a novel experimental-evolution system that allows direct tracking of bacterial adaptation in the rhizosphere of tomatoes over successive plant generations. Training will also be provided to quantify bacterial adaptation using a combination of microbiological assays, genomics, metabolomics and plant assays. The proposed work will help to assess the potential risks of plant pathogen resistance evolution for the long-term efficiency of microbe-mediated biocontrol. It will also improve fundamental understanding of the rapid microbial evolution in an agriculturally relevant model system and help identify potentially novel antimicrobial compounds for future crop protection.

Coordinator

HELSINGIN YLIOPISTO
Net EU contribution
€ 215 534,40
Address
YLIOPISTONKATU 3
00014 Helsingin Yliopisto
Finland

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Region
Manner-Suomi Helsinki-Uusimaa Helsinki-Uusimaa
Activity type
Higher or Secondary Education Establishments
Links
Total cost
No data