Root-exuded secondary metabolites can alleviate negative plant-soil feedbacks

Abstract

AbstractPlants can suppress the growth of other plants by modifying soil properties. These negative plant-soil feedbacks are often species-specific, suggesting that some plants possess resistance strategies. However, the underlying mechanisms remain largely unknown. Here, we investigated if and how benzoxazinoids, a class of dominant secondary metabolites that are exuded into the soil by maize and other cereals, help plants to resist negative plant-soil feedbacks. We find that three out of five tested crop species suppress maize performance relative to the mean across species. This effect is partially alleviated by the plant’s capacity to produce benzoxazinoids. Soil complementation of benzoxazinoid-deficient mutants with purified benzoxazinoids is sufficient to restore the protective effect. Sterilization and reinoculation experiments suggest that benzoxazinoid-mediated protection acts via changes in soil microbes. Substantial variation of the protective effect between experiments and soil types illustrates that the magnitude of the protective effect of benzoxazinoids against negative plant-soil feedbacks is context dependent. In summary, our study demonstrates that plant secondary metabolites can confer resistance to negative plant-soil feedbacks. These findings expand the functional repertoire of plant secondary metabolites, reveal a mechanism by which plants can resist suppressive soils, and may represent a promising avenue to stabilize plant performance in crop rotations in the future.