Assessment of 10 years of CO2 fumigation on soil microbial communities and function in a sweetgum plantation

Emily E. Austin; Hector F. Castro; Katherine E. Sides; Christopher W. Schadt; Aimée T. Classen

doi:10.1016/j.soilbio.2008.12.010

Assessment of 10 years of CO₂ fumigation on soil microbial communities and function in a sweetgum plantation

Emily E. Austin
, Hector F. Castro
, Katherine E. Sides
, Christopher W. Schadt
, Aimée T. Classen

Integrative Microbiomics

Research output: Contribution to journal › Article › peer-review

76 Scopus citations

Abstract

Increased vegetative growth and soil carbon (C) storage under elevated carbon dioxide concentration ([CO₂]) has been demonstrated in a number of experiments. However, the ability of ecosystems, either above- or belowground, to maintain increased C storage relies on the response of soil processes, such as those that control nitrogen (N) mineralization, to climatic change. These soil processes are mediated by microbial communities whose activity and structure may also respond to increasing atmospheric [CO₂]. We took advantage of a long-term (ca 10 y) CO₂ enrichment experiment in a sweetgum plantation located in the southeastern United States to test the hypothesis that observed increases in root production in elevated relative to ambient CO₂ plots would alter microbial community structure, increase microbial activity, and increase soil nutrient cycling. We found that elevated [CO₂] had no detectable effect on microbial community structure using 16S rRNA gene clone libraries, on microbial activity measured with extracellular enzyme activity, or on potential soil N mineralization and nitrification rates. These results support findings at other forested Free Air [CO₂] Enrichment (FACE) sites.

Original language	English
Pages (from-to)	514-520
Number of pages	7
Journal	Soil Biology and Biochemistry
Volume	41
Issue number	3
DOIs	https://doi.org/10.1016/j.soilbio.2008.12.010
State	Published - Mar 2009

Funding

We thank C. Engel, E. Felker-Quinn, S. Kortbein, and J. Ledford for assisting with field and laboratory work. C. Iversen and L. Souza for assistance with statistics. R. Norby for site support and helpful comments on this manuscript. The Ecosystem Ecology Lab group at ORNL and UT gave insightful comments on earlier manuscript versions. This research was funded by the U.S. Department of Energy, Office of Science, Biological and Environmental Research Program. ORNL is managed by UT-Battelle, LLC, for the U.S. Department of Energy.

Keywords

16S rRNA genes
Bacterial community structure
Climate change
Elevated carbon dioxide
Enzyme activity
Free Air CO Enrichment (FACE)
Potential nitrogen mineralization

Access to Document

10.1016/j.soilbio.2008.12.010

Cite this

@article{b13810d7f2e44f6b8b2ba1d58fb04ced,

title = "Assessment of 10 years of CO2 fumigation on soil microbial communities and function in a sweetgum plantation",

abstract = "Increased vegetative growth and soil carbon (C) storage under elevated carbon dioxide concentration ([CO2]) has been demonstrated in a number of experiments. However, the ability of ecosystems, either above- or belowground, to maintain increased C storage relies on the response of soil processes, such as those that control nitrogen (N) mineralization, to climatic change. These soil processes are mediated by microbial communities whose activity and structure may also respond to increasing atmospheric [CO2]. We took advantage of a long-term (ca 10 y) CO2 enrichment experiment in a sweetgum plantation located in the southeastern United States to test the hypothesis that observed increases in root production in elevated relative to ambient CO2 plots would alter microbial community structure, increase microbial activity, and increase soil nutrient cycling. We found that elevated [CO2] had no detectable effect on microbial community structure using 16S rRNA gene clone libraries, on microbial activity measured with extracellular enzyme activity, or on potential soil N mineralization and nitrification rates. These results support findings at other forested Free Air [CO2] Enrichment (FACE) sites.",

keywords = "16S rRNA genes, Bacterial community structure, Climate change, Elevated carbon dioxide, Enzyme activity, Free Air CO Enrichment (FACE), Potential nitrogen mineralization",

author = "Austin, \{Emily E.\} and Castro, \{Hector F.\} and Sides, \{Katherine E.\} and Schadt, \{Christopher W.\} and Classen, \{Aim{\'e}e T.\}",

year = "2009",

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doi = "10.1016/j.soilbio.2008.12.010",

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T1 - Assessment of 10 years of CO2 fumigation on soil microbial communities and function in a sweetgum plantation

AU - Austin, Emily E.

AU - Castro, Hector F.

AU - Sides, Katherine E.

AU - Schadt, Christopher W.

AU - Classen, Aimée T.

PY - 2009/3

Y1 - 2009/3

N2 - Increased vegetative growth and soil carbon (C) storage under elevated carbon dioxide concentration ([CO2]) has been demonstrated in a number of experiments. However, the ability of ecosystems, either above- or belowground, to maintain increased C storage relies on the response of soil processes, such as those that control nitrogen (N) mineralization, to climatic change. These soil processes are mediated by microbial communities whose activity and structure may also respond to increasing atmospheric [CO2]. We took advantage of a long-term (ca 10 y) CO2 enrichment experiment in a sweetgum plantation located in the southeastern United States to test the hypothesis that observed increases in root production in elevated relative to ambient CO2 plots would alter microbial community structure, increase microbial activity, and increase soil nutrient cycling. We found that elevated [CO2] had no detectable effect on microbial community structure using 16S rRNA gene clone libraries, on microbial activity measured with extracellular enzyme activity, or on potential soil N mineralization and nitrification rates. These results support findings at other forested Free Air [CO2] Enrichment (FACE) sites.

AB - Increased vegetative growth and soil carbon (C) storage under elevated carbon dioxide concentration ([CO2]) has been demonstrated in a number of experiments. However, the ability of ecosystems, either above- or belowground, to maintain increased C storage relies on the response of soil processes, such as those that control nitrogen (N) mineralization, to climatic change. These soil processes are mediated by microbial communities whose activity and structure may also respond to increasing atmospheric [CO2]. We took advantage of a long-term (ca 10 y) CO2 enrichment experiment in a sweetgum plantation located in the southeastern United States to test the hypothesis that observed increases in root production in elevated relative to ambient CO2 plots would alter microbial community structure, increase microbial activity, and increase soil nutrient cycling. We found that elevated [CO2] had no detectable effect on microbial community structure using 16S rRNA gene clone libraries, on microbial activity measured with extracellular enzyme activity, or on potential soil N mineralization and nitrification rates. These results support findings at other forested Free Air [CO2] Enrichment (FACE) sites.

KW - 16S rRNA genes

KW - Bacterial community structure

KW - Climate change

KW - Elevated carbon dioxide

KW - Enzyme activity

KW - Free Air CO Enrichment (FACE)

KW - Potential nitrogen mineralization

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