| Background and Aims: Arbuscular mycorrhizal (AM) fungi may contribute to plant protection against pathogens. However, AM-fungal bioprotection may depend upon AM-fungal species identity and plant-pathosystem. Here, the aim is to determine if AM-fungal composition can alter Pseudomonas syringae pv. glycinia's (Psg) effect on soybean ( Glycine max).;Methods: Mycorrhizal composition and soil nutrients (nitrogen and phosphorous) were manipulated for Glycine max under growth chamber conditions. Mycorrhizal treatments included four single species of AM-fungi (Entrophospora infrequens, Funneliformis mosseae, Claroideoglomus claroideum, and Racocetra fulgida) and a mix of all four species. Three nutrient addition treatments included nitrogen (N), phosphorous (P), and nitrogen with phosphorous (NP). Pathogen (Psg) density was assessed at 40 and 120 hours post infection (HPI). An additional experiment examined soybean biomass in response to the interactive effect of Psg and soil environments (AM-fungal community, N, P, NP, control).;Results: AM-fungal species Entrophospora infrequens reduced Psg propagation, while three other fungal species did not (F. mosseae, C. claroideum, and R. fulgida ). Addition of supplemental nitrogen inhibited Psg propagation, suggesting a resource provisioning mechanism of AM-fungal bioprotection. Assessment of plant growth revealed that an AM-fungal inoculum mix increases soybean leaf mass over a four month growing period. Meanwhile, Psg markedly increased stem mass. An interaction between AM-fungi and Psg on plant growth was not detected. In mixed communities, AM-fungal sporulation was only detected for a single species (F. mosseae).;Conclusion: These findings provide insight into the role of AM-fungal identity in bioprotection against a foliar pathogen. Although additional work is needed to fully determine ecological processes that provide selective advantages to host plant, still these findings indicate that such ecological processes include nutrient provisioning and competition among AM-fungi. Together, these processes may have an underlying role in bioprotection. |
