Litcius/Paper detail

Elucidating Plant-Microbe-Environment Interactions Through Omics-Enabled Metabolic Modelling Using Synthetic Communities

Ashley E. Beck, Manuel Kleiner, Anna-Katharina Garrell

2022Frontiers in Plant Science28 citationsDOIOpen Access PDF

Abstract

With a growing world population and increasing frequency of climate disturbance events, we are in dire need of methods to improve plant productivity, resilience, and resistance to both abiotic and biotic stressors, both for agriculture and conservation efforts. Microorganisms play an essential role in supporting plant growth, environmental response, and susceptibility to disease. However, understanding the specific mechanisms by which microbes interact with each other and with plants to influence plant phenotypes is a major challenge due to the complexity of natural communities, simultaneous competition and cooperation effects, signalling interactions, and environmental impacts. Synthetic communities are a major asset in reducing the complexity of these systems by simplifying to dominant components and isolating specific variables for controlled experiments, yet there still remains a large gap in our understanding of plant microbiome interactions. This perspectives article presents a brief review discussing ways in which metabolic modelling can be used in combination with synthetic communities to continue progress toward understanding the complexity of plant-microbe-environment interactions. We highlight the utility of metabolic models as applied to a community setting, identify different applications for both flux balance and elementary flux mode simulation approaches, emphasize the importance of ecological theory in guiding data interpretation, and provide ideas for how the integration of metabolic modelling techniques with big data may bridge the gap between simplified synthetic communities and the complexity of natural plant-microbe systems.

Topics & Concepts

BiologyPsychological resilienceEcologyBiochemical engineeringMicrobiomeAsset (computer security)Flux balance analysisResilience (materials science)Computer scienceData scienceComputational biologyEngineeringBioinformaticsComputer securityPhysicsThermodynamicsPsychologyPsychotherapistMicrobial Metabolic Engineering and BioproductionBiofuel production and bioconversionGene Regulatory Network Analysis