Interseeding cover crops into corn has been proposed as a technique to extend the cover crop growing window, but interseeded cover crops may reduce N availability and compete with corn for available nutrients. To assess N-cycling dynamics in soils where cover crops have been interseeded into corn for one or two years, plots were established in duplicate at two sites in Michigan with differing edaphic properties. Annual ryegrass (Lolium multiflorum Lam.), crimson clover (Trifolium incarnatum L.), oilseed radish (Raphanus sativus L.), or a mixture of ryegrass and clover were interseeded into corn at the V3 or V6 stages of corn growth and compared to control plots that did not receive cover crops. We measured active C and N pools during the growing season and after harvest as well as potential activities of microbially mediated nutrient-cycling processes via extracellular enzymes, nitrification, and denitrification. We found that after two years, interseeded cover crops had little to no effect on active pools of C and N or on microbial nutrient-cycling activities. However, we observed major differences in these parameters between sites, with finer-textured soils exhibiting increased dissolved organic C availability and greater peptidase activity compared to coarser-textured soils. Our results reveal important spatial and temporal trends that suggest greater C availability can lower the potential for N loss while maintaining a rapid flux of N through the N cycle.

Root and soil microbial communities constitute the below-ground plant microbiome, are drivers of nutrient cycling, and affect plant productivity. However, our understanding of their spatiotemporal patterns is confounded by exogenous factors that covary spatially, such as changes in host plant species, climate, and edaphic factors. These spatiotemporal patterns likely differ across microbiome domains (bacteria and fungi) and niches (root vs. soil). To capture spatial patterns at a regional scale, we sampled the below-ground microbiome of switchgrass monocultures of five sites spanning >3 degrees of latitude within the Great Lakes region. To capture temporal patterns, we sampled the below-ground microbiome across the growing season within a single site. We compared the strength of spatiotemporal factors to nitrogen addition determining the major drivers in our perennial cropping system. All microbial communities were most strongly structured by sampling site, though collection date also had strong effects; in contrast, nitrogen addition had little to no effect on communities. Though all microbial communities were found to have significant spatiotemporal patterns, the structure of bacterial communities was better explained by spatiotemporal factors than fungal communities, which appeared more structured by stochastic processes. Root communities, especially bacterial, were more temporally structured than soil communities which were more spatially structured, both across and within sampling sites. These differential responses of bacterial and fungal communities to spatiotemporal factors likely alter interactions and assembly of the plant microbiome.