PS 18-42 - The carbon cost of plant nitrogen uptake: Does mycorrhizal association predict rhizosphere carbon and nitrogen dynamics?

Wednesday, August 10, 2016
ESA Exhibit Hall, Ft Lauderdale Convention Center
Adrienne B. Keller, Department of Biology, Indiana University, Bloomington, IN and Richard P. Phillips, Biology, Indiana University, Bloomington, IN
Background/Question/Methods

Understanding how plant communities affect microbially-mediated soil biogeochemical cycling is critical to predicting the consequence of shifts in plant communities for global carbon (C) and nutrient cycles. Root exudation is a primary mechanism by which plants directly influence belowground C and nutrient cycling by priming the soil microbial community to accelerate soil organic matter decomposition and increase plant-available nitrogen (N). Recent evidence suggests a plant’s mycorrhizal status – for example, whether it associates with arbuscular (AM) or ectomycorrhizae (ECM) fungi – may affect root exudate rates and more broadly reflect (and determine) its impacts on biogeochemical processes. Specifically, it has been suggested that ECM-associated plants may have higher rates of exudation as a means to access N pools that are predominately tied up in organic matter, whereas AM-associated plants operate within a more inorganic nutrient economy and rely less on microbial priming for N acquisition. However, there are few experimental data to support this hypothesis. Here, we combine mesocosm and field experiments to quantify the degree to which AM- and ECM-associated tree species vary in their exudation rates, and the consequences of such differences in root exudation for plant N uptake. 

Results/Conclusions

Preliminary results from our dual-label 13C/15N mesocosm experiment show evidence of rapid transfer of C from the leaves to the soil in both AM and ECM trees, with soil δ13C peaking within 72 hours after labeling. Plant acquisition of organically bound N from the soil also appears to be rapid, with increased foliar δ15N observed within one month following the addition of 15N-labeled organic matter. In both our mesocosm and field studies, ECM trees showed significantly greater exudation rates compared to AM trees but only slightly greater organic N uptake from the soil, likely owing to the greater cost of mining N out of the soil organic matter. Taken together, these results suggest plant-microbe interactions are highly dynamic within the rhizosphere and are central to regulating C and N availability belowground. Considering the unique biogeochemical syndromes of these two plant functional types is thus critical to predicting how future shifts in vegetation will affect fundamental ecosystem processes.