Controls on subsurface methane fluxes and shallow gas formation in Baltic Sea sediment (Aarhus Bay, Denmark)

Flury, Sabine; Røy, Hans; Dale, Andrew W.; Fossing, Henrik; Tóth, Zsuzsanna; Spieß, V.; Jensen, Jørn Bo; Jørgensen, Bo Barker

doi:10.1016/j.gca.2016.05.037

Cited by 57 publications

(116 citation statements)

References 35 publications

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“…1A and SI Appendix, Table S1). Although the depth distribution of sediment age and microbial carbon mineralization rates show little variation across stations in Aarhus Bay (19), the depth of the SMT zone varies between stations due to differences in the thickness of the Holocene mud layer forming the marine sediment (19). Across the sampled sediment depths (0-7 m) the microbial cell density decreased from 10 9 to 10 7 cells·g −1 wet weight (Fig.…”

Section: Resultsmentioning

confidence: 95%

“…Differences in the number of reads mapped on SAGs do explain some of the diversity differences observed, but genuine differences among lineages remain (P = 0.016). Our generation time estimate is based on empirically determined parameters (Material and Methods); of these, cellular carbon content varies twofold (27) and sediment age by 2% (4), whereas rates of carbon mineralization were modeled from experimental data with a SD of 5% (19,28). Finally, cellular growth yields likely vary by a factor of 2-3, according to pure culture studies and subsurface sediment modeling (3,6,8).…”

Section: Resultsmentioning

confidence: 99%

“…The cores were subsampled for DNA extraction by a protocol, which removes extracellular DNA (30), and for whole-cell extraction for single-cell sorting. The biogeochemistry of the studied cores is reported elsewhere (19).…”

Section: Methodsmentioning

confidence: 99%

“…Sulfate reduction rates therefore represent the metabolic activity of the entire anaerobic microbial food chain in this zone (6,8). In marine sediments, including Aarhus Bay, sulfate reduction rates decrease with sediment depth according to a power law function that can be extrapolated below the SMT zone to reflect carbon mineralization rates in the methanogenic zone (i.e., by methanogenesis) (19,32). We therefore used such a power law function determined for Aarhus Bay sediments (19) to calculate organic carbon oxidation rates.…”

Section: Methodsmentioning

confidence: 99%

“…In marine sediments, including Aarhus Bay, sulfate reduction rates decrease with sediment depth according to a power law function that can be extrapolated below the SMT zone to reflect carbon mineralization rates in the methanogenic zone (i.e., by methanogenesis) (19,32). We therefore used such a power law function determined for Aarhus Bay sediments (19) to calculate organic carbon oxidation rates. Cell-specific carbon oxidation rates were calculated from total cell abundances and were used to estimate biomass turnover of cells assuming a growth yield of 8% (8) and a cellular carbon content of 21.5 fg (27).…”

Section: Methodsmentioning

confidence: 99%

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Microbial community assembly and evolution in subseafloor sediment

Starnawski

Bataillon

Ettema

et al. 2017

Proc. Natl. Acad. Sci. U.S.A.

190

224

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Bacterial and archaeal communities inhabiting the subsurface seabed live under strong energy limitation and have growth rates that are orders of magnitude slower than laboratory-grown cultures. It is not understood how subsurface microbial communities are assembled and whether populations undergo adaptive evolution or accumulate mutations as a result of impaired DNA repair under such energy-limited conditions. Here we use amplicon sequencing to explore changes of microbial communities during burial and isolation from the surface to the >5,000-y-old subsurface of marine sediment and identify a small core set of mostly uncultured bacteria and archaea that is present throughout the sediment column. These persisting populations constitute a small fraction of the entire community at the surface but become predominant in the subsurface. We followed patterns of genome diversity with depth in four dominant lineages of the persisting populations by mapping metagenomic sequence reads onto single-cell genomes. Nucleotide sequence diversity was uniformly low and did not change with age and depth of the sediment. Likewise, there was no detectable change in mutation rates and efficacy of selection. Our results indicate that subsurface microbial communities predominantly assemble by selective survival of taxa able to persist under extreme energy limitation.acteria and archaea inhabiting the subsurface seabed account for more than half of all microbial cells in the oceans (1, 2). The subsurface communities are cut off from fresh detrital organic matter deposited on the sea floor. The energy available for cellular maintenance and growth decreases rapidly with depth and age of the sediment (3-5). As a consequence, the microbial abundance and cell-specific metabolic rates decrease by orders of magnitude already within the top few meters of sediment (3, 6-8). However, even hundreds of meters below the seafloor sediments are populated by microbes that actively turn over their biomass (3,8). The growth characteristics of these microbial populations are unlike anything studied in pure culture as estimates suggest that the generation times of subsurface cells are tens to hundreds of years (3,7,8). As a model for how these deep biosphere communities are assembled, it was suggested that the microbes found in the subsurface seabed represent descendants of surface communities that were buried in the past (9-12). So far this model has not been tested systematically. Furthermore, it is not known if subsurface microorganisms during the burial evolve unique genetic traits conferring adaptation to this environment (13). Studies of adaptation and evolution in freeliving microorganisms reported high genetic heterogeneity and rapid evolutionary change within natural populations. However, these studies have focused on dynamic or mixed environments with large population sizes and rapid growth, e.g., biofilms or planktonic communities (14-16) that are very different from the subsurface seabed environment.According to "Drake's rule" (17), DNA-based or...

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Section: Resultsmentioning

confidence: 95%

Section: Resultsmentioning

confidence: 99%

Section: Methodsmentioning

confidence: 99%

Section: Methodsmentioning

confidence: 99%

Section: Methodsmentioning

confidence: 99%

See 3 more Smart Citations

Microbial community assembly and evolution in subseafloor sediment

Starnawski

Bataillon

Ettema

et al. 2017

Proc. Natl. Acad. Sci. U.S.A.

190

224

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Methylotrophic methanogenesis fuels cryptic methane cycling in marine surface sediment

Xiao

Beulig

Røy

et al. 2018

Limnology & Oceanography

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Methylotrophic methanogenesis is often proposed to be responsible for methane production in sulfate‐rich environments, yet the magnitude of this process remains elusive. In this study, we incubated sediment from Aarhus Bay (Denmark) with 13C labeled CH4 to measure total methane turnover by isotope dilution, and with 14C‐radiotracers to measure specifically the gross hydrogenotrophic and acetoclastic methane production. Highest CH4 production rates (> 200 pmol cm−3 d−1) were found in the top 0–2 cm. Most of this production was via methylotrophic pathways. Methanogenesis via the hydrogenotrophic pathway accounted for less than 20 pmol cm−3 d−1 throughout the surface sediment (0–10 cm), and there was no apparent contribution from acetoclastic methanogenesis. To further assess potentials for methanogenesis from hydrogen, acetate, or trimethylamine (TMA), sediment slurry incuabtions with excess substrate addition were performed. A high and accelarating CH4 production was only detected in incubations amended with TMA. Our results show that methylotrophic methanogenesis dominated the CH4 production in these sulfate‐rich marine surface sediments.

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Sulfate-Methane Transition Depths and Its Implication for Gas Hydrate

Zhang

Gao

2020

J. Ocean Univ. China

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Controls on subsurface methane fluxes and shallow gas formation in Baltic Sea sediment (Aarhus Bay, Denmark)

Cited by 57 publications

References 35 publications

Microbial community assembly and evolution in subseafloor sediment

Microbial community assembly and evolution in subseafloor sediment

Methylotrophic methanogenesis fuels cryptic methane cycling in marine surface sediment

Sulfate-Methane Transition Depths and Its Implication for Gas Hydrate

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