Abstract
Fine root litter is a primary source of soil organic matter (SOM), which is a globally important pool of C that is responsive to climate change. We previously established that ~20 years of experimental nitrogen (N) deposition has slowed fine root decay and increased the storage of soil carbon (C; +18%) across a widespread northern hardwood forest ecosystem. However, the microbial mechanisms that have directly slowed fine root decay are unknown. Here, we show that experimental N deposition has decreased the relative abundance of Agaricales fungi (−31%) and increased that of partially ligninolytic Actinobacteria (+24%) on decaying fine roots. Moreover, experimental N deposition has increased the relative abundance of lignin-derived compounds residing in SOM (+53%), and this biochemical response is significantly related to shifts in both fungal and bacterial community composition. Specifically, the accumulation of lignin-derived compounds in SOM is negatively related to the relative abundance of ligninolytic Mycena and Kuehneromyces fungi, and positively related to Microbacteriaceae. Our findings suggest that by altering the composition of microbial communities on decaying fine roots such that their capacity for lignin degradation is reduced, experimental N deposition has slowed fine root litter decay, and increased the contribution of lignin-derived compounds from fine roots to SOM. The microbial responses we observed may explain widespread findings that anthropogenic N deposition increases soil C storage in terrestrial ecosystems. More broadly, our findings directly link composition to function in soil microbial communities, and implicate compositional shifts in mediating biogeochemical processes of global significance.
Original language | English |
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Pages (from-to) | 4369-4382 |
Number of pages | 14 |
Journal | Global Change Biology |
Volume | 25 |
Issue number | 12 |
DOIs | |
State | Published - Dec 1 2019 |
Externally published | Yes |
Funding
We sincerely thank Kimberly Martin, Remy Long, Kathryn Kelley, Allison Sharrar, Kerri Metz, and Sisimac Duchicela for their assistance with fine root processing and litter bag construction. We thank Zachary Freedman and Karl Romanowicz for their assistance with soil collection. We also thank Peter Pellitier, Deborah Goldberg, Inés Ibáñez, Timothy James, the James lab, and the plant ecology discussion group at the University of Michigan for their insightful comments on previous versions of this manuscript. This work was supported by funding from the United States Department of Energy Biological and Environmental Research program. The maintenance of our long-term N deposition project is supported by the National Science Foundation Long-Term Research in Environmental Biology Program.
Funders | Funder number |
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National Science Foundation Long-Term Research in Environmental Biology Program | |
United States Department of Energy Biological and Environmental Research program |
Keywords
- bacterial community
- biogeochemical feedback
- fungal community
- lignin
- microbial decomposition
- root decay
- soil carbon