Abstract
Plant growth depends on a range of functions provided by their associated rhizosphere microbiome, including nutrient mineralization, hormone co-regulation and pathogen suppression. Improving the ability of plant-associated microbiomes to deliver these functions is thus important for developing robust and sustainable crop production. However, it is yet unclear how beneficial effects of probiotic microbial inoculants can be optimized and how their effects are mediated. Here, we sought to enhance tomato plant growth by targeted introduction of probiotic bacterial consortia consisting of up to eight plant-associated Pseudomonas strains. We found that the effect of probiotic consortium inoculation was richness-dependent: consortia that contained more Pseudomonas strains reached higher densities in the tomato rhizosphere and had clearer beneficial effects on multiple plant growth characteristics. Crucially, these effects were best explained by changes in the resident community diversity, composition and increase in the relative abundance of initially rare taxa, instead of introduction of plant-beneficial traits into the existing community along with probiotic consortia. Together, our results suggest that beneficial effects of microbial introductions can be driven indirectly through effects on the diversity and composition of the resident plant rhizosphere microbiome.
Highlights
Microorganisms associated with plant roots provide a range of services essential for plant growth
The background phlD gene abundances were below 0.001% in the noninoculated control treatments, confirming that Pseudomonas strains containing this gene were rare in the non-sterile agricultural soil plant growth characteristics royalsocietypublishing.org/journal/rspb Proc
In support for this, we found that rare taxa at phylum, family and operational taxonomic units (OTUs) levels were more likely to increase in abundance along with the richness of the inoculated consortia (x21,8607 1⁄4 22:45, p < 0.0001; figure 3c; electronic supplementary material, figure S5A–C)
Summary
Microorganisms associated with plant roots provide a range of services essential for plant growth. We employed a biodiversity-ecosystem functioning framework [25] to assess how the diverse probiotic bacterial inoculants affect rhizosphere microbiome and their impact on plant growth To this end, we assembled probiotic bacterial consortia consisting of one to eight different Pseudomonas spp. strains that all are well studied and have previously been shown to have beneficial effects on plants (electronic supplementary material, tables S1–S3) [26]. They express different traits that are important for several microbiome functions that improve plant growth (electronic supplementary material, table S3) All these strains contain functional gene phlD, which is involved in the production of antimicrobial polyketide 2,4-diacetylphloroglucinol (DAPG). To analyse the effect of richness and abundance of probiotic Pseudomonas consortia on the resident rhizosphere microbiome community composition, diversity and weighted mean of plant growth index, generalized linear models (GLMs) were used. We used SEM to examine direct and indirect effects linking consortium inoculants with plant growth by accounting for multiple potentially correlated effect pathways [41] (more detail is included in the electronic supplementary material)
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