Plant-Beneficial Pseudomonas Spp. Suppress Local Root Immune Responses by Gluconic Acid-Mediated Lowering of Environmental pH

Abstract

The plant root microbiome consists of commensal, pathogenic and plant-beneficial microbes. Most members of the root microbiome possess microbe-associated molecular patterns (MAMPs) similar to those of plant pathogens. Their recognition by the cell surface-localized pattern recognition receptors can lead to the initiation of host immune signaling and suppression of plant growth due to growth-defense tradeoffs. We found that 42% of the tested root microbiota, including the plant growth-promoting rhizobacteria Pseudomonas capeferrum WCS358 (WCS358) and Pseudomonas simiae WCS417, are able to quench local Arabidopsis thaliana root immune responses that were triggered by the synthetic MAMP flg22, suggesting that this is an important function of the root microbiome. In a screen for WCS358 mutants that lost their capacity to suppress flg22-induced CYP71A12pro:GUS MAMP-reporter gene expression, we identified the bacterial genes pqqF and cyoB in WCS358. CyoB and pqqF are required for the production of gluconic acid and its derivative 2-keto gluconic acid. Both WCS358 mutants are impaired in the production of these organic acids and consequently lowered their extracellular pH to a lesser extent than wild-type WCS358. Acidification of the plant growth medium similarly suppressed flg22-induced CYP71A12pro:GUS and MYB51pro:GUS expression as well as the flg22-mediated oxidative burst, suggesting a role for rhizobacterial gluconic acid-mediated modulation of the extracellular pH in the suppression of local root immunity. Rhizosphere population densities of the mutants were significantly reduced compared to wild-type. Collectively, these findings show that suppression of local root immune responses is an important function of the root microbiome, as it facilitates colonization by beneficial root microbiota.