Orfamide production in Pseudomonas protegens CHA0T promotes rhizospheric colonization and influences assemblage of the bacterial community of wheat roots in soil.

Abstract

Orfamides (Ofa) are a family of closely related cyclic lipopeptides (cLPs) produced by different soil-inhabiting and plant beneficial strains of the Pseudomonas protegens subgroup. Orfamides are required for swarming motility, they mediate toxicity on oomycetes, algae, and insects, and they can act as ISR elicitors. Ofa biosynthesis depends on a non-ribosomal peptide synthetase gene cluster whose expression is tightly controlled by the post-transcriptional regulatory cascade Gac-Rsm. Although the biological properties and physiological role of Ofa have been well characterized in vitro, the role of Ofa in the fitness of the producing bacterium in its niche has not been studied so far. Here, we used an Ofa biosynthesis-deficient mutant (ΔofaABC) derived from the biocontrol model strain P. protegens CHA0T to explore the relevance of this cLP in soil for the survival of strain CHA0T, its contribution to the bacterial competitiveness for colonization of wheat roots, and its impact on the corresponding rhizobacterial community structure. To facilitate CFU counts in non-sterile soil and root samples we used chromosomally tagged versions of CHA0T and its ΔofaABC mutant with mini-Tn7 constructs carrying antibiotic resistance markers. We confirmed that the tagged Ofa− mutant does not show drop-collapse activity neither it can swarm in semi-solid medium. We also confirmed that Ofa can be exploited in vitro as a social good by the Ofa− mutant to resume swarming in the presence of CHA0T cells. We found that Ofa production did not confer any advantage for bacterial survival along a period of 5 weeks after soil inoculation. However, we observed that Ofa production was associated with a higher competitiveness for colonization of the wheat rhizosphere. Expression of the ofa biosynthetic operon, by means of a transcriptional Pofa-gfp reporter fusion, was detected in the rhizoplane of colonized wheat roots, suggesting that Ofa is produced in situ on the surface of colonized wheat roots. Finally, we observed that seed inoculation with the wild type Ofa producer strain CHA0T resulted in a differential assemblage of the bacterial community of the wheat rhizosphere with respect to that of seeds bacterized with the Ofa deficient mutant. Overall, we provide evidence that Ofa is important for the competitiveness of P. protegens CHA0T cells to colonize the surface of wheat roots and that Ofa production in the rhizosphere can impact the structure of the assembled bacterial microbiome.