Metabolic exchange and siderophore sharing underlie emergent biofilm synergism

Biofilm communities exhibit emergent properties that exceed the sum of contributions from individual members of the community. Here, we describe a multilayered metabolic interaction that drives enhanced biofilm formation among three bacterial species from the plant rhizosphere. Comparative metatranscriptomic and metabolomic analyses reveal that Bacillus velezensis-secreted 5-aminovaleric acid promotes the growth of the other community members, Burkholderia contaminans and Acinetobacter baumannii. In return, B. contaminans supplies branched-chain amino acids for B. velezensis. Branched-chain amino acids and cell–cell signaling acyl-homoserine lactones from B. contaminans induce biosynthesis of the siderophore bacillibactin in B. velezensis, that is further enhanced by A. baumannii. In exchange, the B. velezensis-secreted siderophore promotes the growth of B. contaminans in iron-limited conditions, which benefits the multispecies biofilm community in vitro and promotes plant growth performance in iron-depleted soil. Our study reveals the molecular mechanisms underlying an emergent rhizosphere biofilm community function and demonstrates its importance in plant–microbe interactions.