Rapid Evolution of Plant-Bacterium Mutualism in the Rhizosphere
45 Pages Posted: 4 Aug 2020 Publication Status: Review Complete
More...Abstract
Plant roots are associated with a diverse microbial community that consists of antagonistic, commensal and mutualistic organisms. While beneficial plant-microbe interactions are important for plant performance, direct evidence for the evolution of rhizosphere mutualism remains elusive. Here we experimentally show that initially plant-antagonistic Pseudomonas protegens bacterium can rapidly evolve into a mutualist in the rhizosphere of Arabidopsis thaliana only within six plant growth cycles (6 months). Using an in vivo experimental evolution system, we observed that P. protegens rapidly diversified into distinct phenotypes, with some having clearly positive effects on the plant performance. Crucially, this evolution of plant facilitation was also accompanied with increased bacterial fitness indicative of a mutualistic interaction. At the genetic level, P. protegens mutualism was associated with mutations in the GacS/GacA two-component global regulator system, which is known to affect several aspects of bacterial physiology including carbon metabolism, host-microbe signalling, and downregulation of phytotoxic secondary metabolites. At the phenotypic level, the evolution of mutualism could be explained via two mechanisms: improved competition for root exudates and enhanced capacity for activating the root-specific transcription factor gene MYB72, which is essential for the production and excretion of the antimicrobial scopoletin for which the mutualists evolved enhanced tolerance. Together, these results show that plant-bacteria mutualism can rapidly evolve at an agriculturally relevant evolutionary timescale in the rhizosphere.
Keywords: mutualism, plant-microbe interaction, evolution, rhizosphere
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