Concurrent Methane Production and Oxidation in Surface Sediment from Aarhus Bay, Denmark

Marine surface sediments, which are replete with sulfate, are typically considered to be devoid of endogenous methanogenesis. Yet, methanogenic archaea are present in those sediments, suggesting a potential for methanogenesis. We used an isotope dilution method based on sediment bag incubation and s...

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Bibliographic Details
Published in:Frontiers in microbiology 2017-06, Vol.8, p.1198-1198
Main Authors: Xiao, Ke-Qing, Beulig, Felix, Kjeldsen, Kasper U, Jørgensen, Bo B, Risgaard-Petersen, Nils
Format: Article
Language:English
Subjects:
isotope dilution
methane oxidation
methanogenesis
methanogenic archaea
Microbiology
surface sediment
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Summary:Marine surface sediments, which are replete with sulfate, are typically considered to be devoid of endogenous methanogenesis. Yet, methanogenic archaea are present in those sediments, suggesting a potential for methanogenesis. We used an isotope dilution method based on sediment bag incubation and spiking with C-CH to quantify CH turnover rates in sediment from Aarhus Bay, Denmark. In two independent experiments, highest CH production and oxidation rates (>200 pmol cm d ) were found in the top 0-2 cm, below which rates dropped below 100 pmol cm d in all other segments down to 16 cm. This drop in overall methane turnover with depth was accompanied by decreasing rates of organic matter mineralization with depth. Molecular analyses based on quantitative PCR and MiSeq sequencing of archaeal 16S rRNA genes showed that the abundance of methanogenic archaea also peaked in the top 0-2 cm segment. Based on the community profiling, hydrogenotrophic and methylotrophic methanogens dominated among the methanogenic archaea in general, suggesting that methanogenesis in surface sediment could be driven by both CO reduction and fermentation of methylated compounds. Our results show the existence of elevated methanogenic activity and a dynamic recycling of CH at low concentration in sulfate-rich marine surface sediment. Considering the common environmental conditions found in other coastal systems, we speculate that such a cryptic methane cycling can be ubiquitous.
ISSN:1664-302X
1664-302X
DOI:10.3389/fmicb.2017.01198