Belowground Biomass Response to Nutrient Enrichment Depends on Light Limitation Across Globally Distributed Grasslands

Anthropogenic activities are increasing nutrient inputs to ecosystems worldwide, with consequences for global carbon and nutrient cycles. Recent metaanalyses show that aboveground primary production is often co-limited by multiple nutrients; however, little is known about how root production respond...

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Bibliographic Details
Published in:Ecosystems (New York) 2019-11, Vol.22 (7), p.1466-1477
Main Authors: Cleland, Elsa E., Lind, Eric M., DeCrappeo, Nicole M., DeLorenze, Elizabeth, Wilkins, Rachel Abbott, Adler, Peter B., Bakker, Jonathan D., Brown, Cynthia S., Davies, Kendi F., Esch, Ellen, Firn, Jennifer, Gressard, Scott, Gruner, Daniel S., Hagenah, Nicole, Harpole, W. Stanley, Hautier, Yann, Hobbie, Sarah E., Hofmockel, Kirsten S., Kirkman, Kevin, Knops, Johannes, Kopp, Christopher W., La Pierre, Kimberly J., MacDougall, Andrew, McCulley, Rebecca L., Melbourne, Brett A., Moore, Joslin L., Prober, Suzanne M., Riggs, Charlotte, Risch, Anita C., Schuetz, Martin, Stevens, Carly, Wragg, Peter D., Wright, Justin, Borer, Elizabeth T., Seabloom, Eric W.
Format: Article
Language:English
Subjects:
Analysis
Anthropogenic factors
Biomass
Biomedical and Life Sciences
Canopies
Carbon cycle
Carbon sequestration
Dependence
Ecology
Ecosystems
Environmental gradient
Environmental Management
Geoecology/Natural Processes
Grasslands
Hydrology/Water Resources
Life Sciences
Light penetration
Nitrogen
Nutrient availability
Nutrient cycles
Nutrient enrichment
Nutrients
Original Articles
Phosphorus
Plant growth
Plant Sciences
Plants (botany)
Primary production
Soil surfaces
Zoology
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Summary:Anthropogenic activities are increasing nutrient inputs to ecosystems worldwide, with consequences for global carbon and nutrient cycles. Recent metaanalyses show that aboveground primary production is often co-limited by multiple nutrients; however, little is known about how root production responds to changes in nutrient availability. At twenty-nine grassland sites on four continents, we quantified shallow root biomass responses to nitrogen (N), phosphorus (P) and potassium plus micronutrient enrichment and compared below- and aboveground responses. We hypothesized that optimal allocation theory would predict context dependence in root biomass responses to nutrient enrichment, given variation among sites in the resources limiting to plant growth (specifically light versus nutrients). Consistent with the predictions of optimal allocation theory, the proportion of total biomass belowground declined with N or P addition, due to increased biomass aboveground (for N and P) and decreased biomass belowground (N, particularly in sites with low canopy light penetration). Absolute root biomass increased with N addition where light was abundant at the soil surface, but declined in sites where the grassland canopy intercepted a large proportion of incoming light. These results demonstrate that belowground responses to changes in resource supply can differ strongly from aboveground responses, which could significantly modify predictions of future rates of nutrient cycling and carbon sequestration. Our results also highlight how optimal allocation theory developed for individual plants may help predict belowground biomass responses to nutrient enrichment at the ecosystem scale across wide climatic and environmental gradients.
ISSN:1432-9840
1435-0629
DOI:10.1007/s10021-019-00350-4