The activity of soil microbial taxa in the rhizosphere predicts the success of root colonization.

UNLABELLED

Plant-beneficial microbes have great potential to improve sustainability in agriculture. Still, managing beneficial microbes is challenging because the impact of microbial dormancy on community assembly across the soil, rhizosphere, and endosphere is poorly understood. We address this gap with the first documented use of Biorthogonal Non-Canonical Amino Acid Tagging (BONCAT) to probe active microbes in the soil-to-root gradient. Using nodule-forming legume we confirmed that BONCAT is suitable for labeling endospheric microbes with microscopy. Next, we coupled BONCAT to Flow Cytometer Activated Cell Sorting (FACS) and 16S rRNA amplicon sequencing to probe patterns of microbial activity and the structure of the active microbial community across the soil, rhizosphere, root, and nodule with a native soil microbial community. As expected, we found 10 times higher microbial activity in the endosphere than in the rhizosphere or bulk soil, likely due to increased plant resources. Finally, we revealed that microbial activity in the rhizosphere was significantly associated with successful endosphere colonization, more so than microbial abundance alone. This last finding has implications for the development of microbial inoculants, suggesting colonizing plant roots is linked to a microbe's ability to overcome dormancy once deployed in the soil.

IMPORTANCE

Most soil microbes are dormant, so they must exit dormancy to have the potential to carry out plant-beneficial functions. It is unclear if dormant microbes revive in proximity to plant-produced resources and if overcoming dormancy in the soil is important for successful plant colonization. We use a novel microbial activity probing technique for the first time on and in plant roots, and with it, we observe microbes increased in activity 10× inside plant tissues compared to the soil, likely in response to plant-produced resources. In complex, native microbial communities, we observe that microbes that are active and abundant are more likely to colonize plant roots successfully than just abundant microbes. Our research shows that plants could be leveraged to promote a distinct active microbial community from the native soil, a discovery that has the potential to improve sustainability in agriculture.