Redox and temperature-sensitive changes in microbial communities and soil chemistry dictate greenhouse gas loss from thawed permafrost

Autor:	Francisco J. Calderón, Matthew D. Wallenstein, Laurel M. Lynch, Jessica G. Ernakovich, Paul E. Brewer
Rok vydání:	2017
Předmět:	Anaerobic respiration 010504 meteorology & atmospheric sciences Methanogenesis Soil chemistry 04 agricultural and veterinary sciences Permafrost 01 natural sciences Methane chemistry.chemical_compound chemistry Environmental chemistry Greenhouse gas Dissolved organic carbon 040103 agronomy & agriculture 0401 agriculture forestry and fisheries Environmental Chemistry Environmental science Permafrost carbon cycle 0105 earth and related environmental sciences Earth-Surface Processes Water Science and Technology
Zdroj:	Biogeochemistry. 134:183-200
ISSN:	1573-515X 0168-2563
DOI:	10.1007/s10533-017-0354-5
Popis:	Greenhouse gas (GHG) emissions from thawed permafrost are difficult to predict because they result from complex interactions between abiotic drivers and multiple, often competing, microbial metabolic processes. Our objective was to characterize mechanisms controlling methane (CH4) and carbon dioxide (CO2) production from permafrost. We simulated permafrost thaw for the length of one growing season (90 days) in oxic and anoxic treatments at 1 and 15 °C to stimulate aerobic and anaerobic respiration. We measured headspace CH4 and CO2 concentrations, as well as soil chemical and biological parameters (e.g. dissolved organic carbon (DOC) chemistry, microbial enzyme activity, N2O production, bacterial community structure), and applied an information theoretic approach and the Akaike information criterion to find the best explanation for mechanisms controlling GHG flux. In addition to temperature and redox status, CH4 production was explained by the relative abundance of methanogens, activity of non-methanogenic anaerobes, and substrate chemistry. Carbon dioxide production was explained by microbial community structure and chemistry of the DOC pool. We suggest that models of permafrost CO2 production are refined by a holistic view of the system, where the prokaryote community structure and detailed chemistry are considered. In contrast, although CH4 production is the result of many syntrophic interactions, these actions can be aggregated into a linear approach, where there is a single path of organic matter degradation and multiple conditions must be satisfied in order for methanogenesis to occur. This concept advances our mechanistic understanding of the processes governing anaerobic GHG flux, which is critical to understanding the impact the release of permafrost C will have on the global C cycle.
Databáze:	OpenAIRE
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