Evidence of cryptic methane cycling and non-methanogenic methylamine consumption in the sulfate-reducing zone of sediment in the Santa Barbara Basin, California

Krause, Sebastian J. E.; Liu, Jiarui; Yousavich, David J.; Robinson, DeMarcus; Hoyt, David; Qin, Qianhui; Wenzhöfer, Frank; Janßen, Felix; Valentine, David L.; Treude, Tina

doi:10.5194/egusphere-2023-909

Cited by 2 publications

(1 citation statement)

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“…Evidence showed that aerobic methane-oxidizing bacteria could be adapted to a wide range of oxygen concentrations in seasonally hypoxic coastal waters (Steinle et al, 2017). A recent study demonstrated that seasonal deoxygenation could prompt the activity of the methanotroph community and methane consumption rates in a dynamic marine environment of the Santa Barbara Basin (Krause et al, 2023), but the effect of oxygen on methanotrophy at the ecosystem scale was likely indirect (Qin et al, 2022). However, the waters of the YS and ECS were fully oxygenated (oxygen concentrations >220 μM) so oxygen did not limit MOx and no correlation with methanotrophic activity was observed in these areas.…”

Section: Spatial Variability and Environmental Controls Of Mox In Ys ...mentioning

confidence: 99%

Dynamics and Controls of Methane Oxidation in the Aerobic Waters of Eastern China Marginal Seas

Liu,

Du,

et al. 2024

JGR Oceans

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Aerobic methane oxidation (MOx) mediated by methanotrophs is a crucial mechanism in controlling methane emissions from the surface ocean to the atmosphere. Coastal waters dominate global oceanic methane emissions, but the dynamics, controls and roles of MOx remain largely unconstrained in the marginal seas around China. Here, we conducted a variety of biogeochemical analyses to investigate the controls of methane cycling and the dynamics of methanotrophic activity in the East China Sea and Yellow Sea. Methane was supersaturated in the surface seawater and the concentrations ranged from 2.8 to 19.8 nM. The distribution of methane was regulated by the sources and sinks, which were influenced largely by hydrological and biogeochemical factors. Methane was turned over rapidly with high rates (k: 5 × 10−4–0.04 d−1), indicating the enzymatic capability of methanotrophic biomass to metabolize methane. Rates of MOx varied significantly between sites (1 × 10−3–0.60 nM d−1) and relatively high MOx rates were observed in shallow waters. MOx exhibited the Michaelis‐Menten kinetics with the Vmax of 0.30 nM d−1 and a Km of 78.3 nM. Methanotrophic activity was impacted by environmental factors such as methane availability, nutrient levels, bacterial production and temperature. Nutrient addition experiments demonstrated that phosphate elevated MOx rates, while the activity was largely inhibited by ammonium probably due to competitive inhibition of the methane monooxygenase by ammonia. Comparing the depth‐integrated MOx rates with the air‐sea fluxes at selected sites showed that methane consumed through microbial oxidation accounted for up to 78.1% of the total methane loss (=sum of MOx rates and air‐sea flux), highlighting the role of MOx as a microbial filter for methane emissions.

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Section: Spatial Variability and Environmental Controls Of Mox In Ys ...mentioning

confidence: 99%

Dynamics and Controls of Methane Oxidation in the Aerobic Waters of Eastern China Marginal Seas

Liu,

Du,

et al. 2024

JGR Oceans

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Biological methane production and accumulation under sulfate-rich conditions at Cape Lookout Bight, NC

Coon,

Duesing,

Paul

et al. 2023

Front. Microbiol.

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IntroductionAnaerobic oxidation of methane (AOM) is hypothesized to occur through reverse hydrogenotrophic methanogenesis in marine sediments because sulfate reducers pull hydrogen concentrations so low that reverse hydrogenotrophic methanogenesis is exergonic. If true, hydrogenotrophic methanogenesis can theoretically co-occur with sulfate reduction if the organic matter is so labile that fermenters produce more hydrogen than sulfate reducers can consume, causing hydrogen concentrations to rise. Finding accumulation of biologically-produced methane in sulfate-containing organic-rich sediments would therefore support the theory that AOM occurs through reverse hydrogenotrophic methanogenesis since it would signal the absence of net AOM in the presence of sulfate.Methods16S rRNA gene libraries were compared to geochemistry and incubations in high depth-resolution sediment cores collected from organic-rich Cape Lookout Bight, North Carolina.ResultsWe found that methane began to accumulate while sulfate is still abundant (6–8 mM). Methane-cycling archaea ANME-1, Methanosarciniales, and Methanomicrobiales also increased at these depths. Incubations showed that methane production in the upper 16 cm in sulfate-rich sediments was biotic since it could be inhibited by 2-bromoethanosulfonoic acid (BES).DiscussionWe conclude that methanogens mediate biological methane production in these organic-rich sediments at sulfate concentrations that inhibit methanogenesis in sediments with less labile organic matter, and that methane accumulation and growth of methanogens can occur under these conditions as well. Our data supports the theory that H2 concentrations, rather than the co-occurrence of sulfate and methane, control whether methanogenesis or AOM via reverse hydrogenotrophic methanogenesis occurs. We hypothesize that the high amount of labile organic matter at this site prevents AOM, allowing methane accumulation when sulfate is low but still present in mM concentrations.

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Evidence of cryptic methane cycling and non-methanogenic methylamine consumption in the sulfate-reducing zone of sediment in the Santa Barbara Basin, California

Cited by 2 publications

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Dynamics and Controls of Methane Oxidation in the Aerobic Waters of Eastern China Marginal Seas

Dynamics and Controls of Methane Oxidation in the Aerobic Waters of Eastern China Marginal Seas

Biological methane production and accumulation under sulfate-rich conditions at Cape Lookout Bight, NC

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