Summary: | Bacteria from the genera <i>Paraburkholderia </i>and <i>Herbaspirillum</i> can promote the growth of <i>Sorghum bicolor</i>, but the underlying mechanisms are not yet known. In a pot experiment, sorghum plants grown on sterilized substrate were inoculated with <i>Paraburkholderia tropica</i> strain IAC/BECa 135 and <i>Herbaspirillum</i> <i>frisingense</i> strain IAC/BECa 152 under phosphate-deficient conditions. These strains significantly increased <i>Sorghum bicolor</i> cultivar SRN-39 root and shoot biomass. Shotgun metagenomic analysis of the rhizosphere revealed successful colonization by both strains; however, the incidence of colonization was higher in plants inoculated with <i>P. tropica </i>strain IAC/BECa 135 than in those inoculated with <i>H. frisingense </i>strain IAC/BECa 152. Conversely, plants inoculated with <i>H. frisingense </i>strain IAC/BECa 152 showed the highest increase in biomass. Genomic analysis of the two inoculants implied a high degree of rhizosphere fitness of <i>P. tropica </i>strain IAC/BECa 135 through environmental signal processing, biofilm formation, and nutrient acquisition. Both genomes contained genes related to plant growth-promoting bacterial (PGPB) traits, including genes related to indole-3-acetate (IAA) synthesis, nitrogen fixation, nodulation, siderophore production, and phosphate solubilization, although the <i>P. tropica </i>strain IAC/BECa 135 genome contained a slightly more extensive repertoire. This study provides evidence that complementary mechanisms of growth promotion in Sorghum might occur, i.e., that <i>P. tropica </i>strain IAC/BECa 135 acts in the rhizosphere and increases the availability of nutrients, while <i>H. frisingense </i>strain IAC/BECa 152 influences plant hormone signaling. While the functional and taxonomic profiles of the rhizobiomes were similar in all treatments, significant differences in plant biomass were observed, indicating that the rhizobiome and the endophytic microbial community may play equally important roles in the complicated plant-microbial interplay underlying increased host plant growth.
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