Microbial interactions in the anaerobic oxidation of methane: model simulations constrained by process rates and activity patterns

He, Xiaojia; Chadwick, Grayson L.; Kempes, Christopher P.; Shi, Yan; McGlynn, Shawn E.; Orphan, Victoria J.; Meile, Christof

doi:10.1111/1462-2920.14507

Cited by 19 publications

(21 citation statements)

References 83 publications

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“…No flux conditions were imposed at the anode surface, where Cytred was converted to Cytox at a rate set by Jc, representing the offloading of electrons to electrode. 10 -14 -10 -16 (6×10 -15 ) Cell-specific acetate consumption rate constant Estimated from [6] μ d -1 varied Cell growth rate Calculated using Eq (1) ρ gdw cell -1 9.5×10 -14 Biomass density Estimated from [115] YAc gdw mol-Ac -1 4.32 Growth yield Calculated using Eq (3)…”

Section: Model Implementationmentioning

confidence: 99%

Spatially Resolved Electron Transport through Anode‐Respiring Geobacter sulfurreducens Biofilms: Controls and Constraints

Chadwick

Otero

et al. 2021

ChemElectroChem

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Section: Model Implementationmentioning

confidence: 99%

Spatially Resolved Electron Transport through Anode‐Respiring Geobacter sulfurreducens Biofilms: Controls and Constraints

Chadwick

Otero

et al. 2021

ChemElectroChem

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“…Not only do SO

_{4}^{2 -}

‐impacted environments have the most urgent need for clarifying the impact of S on overall wetland biogeochemistry, but they also provide the clearest test bed for examining S cycling in freshwater sediments. Previous reactive transport models have included AOM coupled to SO

_{4}^{2 -}

reduction for marine environments (see review by Regnier et al, , and He et al, ), but similar applications in freshwater ecosystems are minimal. Additionally, uncertainties about specific mechanisms and their rates have limited the incorporation of “cryptic” S cycling in any model applications.…”

Section: Introductionmentioning

confidence: 99%

Microbial and Reactive Transport Modeling Evidence for Hyporheic Flux‐Driven Cryptic Sulfur Cycling and Anaerobic Methane Oxidation in a Sulfate‐Impacted Wetland‐Stream System

Rosenfeld

Santelli

et al. 2020

JGR Biogeosciences

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This study reexamines the common expectations that in freshwater systems, sulfur plays a minor role in carbon cycling, and aerobic processes dominate methane oxidation. In anoxic sediments of a sulfate‐impacted wetland‐stream system in Minnesota (USA), a reactive transport model calibrated to geochemical observations predicted sulfate reduction to be the major terminal electron accepting process, and it showed that anaerobic oxidation of methane predominantly coupled with sulfate reduction attenuated methane concentrations near the sediment‐water interface. Consistent with model results, 16S rRNA microbiome analysis revealed a high relative abundance of taxa capable of dissimilatory sulfate reduction. It further supported the conclusion that high simulated sulfate reduction rates could be maintained by a “cryptic” sulfur cycle coupled to iron and methane. Low relative abundance of known iron reducing bacteria raised the possibility of abiotic ferric iron (Fe) reduction driving sulfide reoxidation to intermediate‐valence sulfur forms; widespread potential for microbially mediated disproportionation, oxidation, and reduction of sulfur intermediates provided mechanisms for completing redox cycles; and archaea comprising up to 25% of the microbial community could include consortia capable of anaerobic oxidation of methane. These biogeochemical processes were found to be controlled by hyporheic fluxes. Lower‐magnitude fluxes in wetland compared to channel sediments created sharper geochemical gradients that generated greater heterogeneity in microbial distributions and reaction rates. Changes in upward flux caused fluctuations in sulfate concentrations that led to alternating simulations of methane production and transport. Our work supports the importance of hyporheic flux‐driven iron‐sulfur‐methane cycling in sulfate‐impacted wetlands and prompts further investigations under freshwater conditions.

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“…These features suggest that DIET is the principal mechanism of sulfate-dependent AOM. While this hypothesis awaits direct experimental confirmation or indirect support through measurements that show the potential for conduction within the aggregates and is hampered by a lack of any pure cultures of microorganisms carrying out this metabolism, modeling efforts indicated that DIET can support cell-specific AOM rates and archaeal activity distributions that were consistent with observations from single-cell resolved fluorescent in situ hybridization-nanoscale secondary ion mass spectrometry (FISH-nanoSIMS) analyses (19).…”

mentioning

confidence: 78%

“…Furthermore, direct interspecies extracellular electron transfer (DIET) has been observed in cocultures (10,11) and microbial aggregates (12)(13)(14)(15)(16). There is also a growing body of evidence that DIET also takes place between methanotrophic archaea and syntrophic sulfate-reducing bacteria in AOM consortia (17)(18)(19), where it serves as an effective transport mechanism over long spatial distances (17). It overcomes limitations inherent in the diffusive exchange of dissolved electron-carrying molecules (mediated interspecies electron transfer, or MIET) that lead to the build-up of reaction products and the subsequent shutdown of metabolic activity (19,20).…”

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confidence: 99%

Controls on Interspecies Electron Transport and Size Limitation of Anaerobically Methane-Oxidizing Microbial Consortia

Chadwick

Kempes

et al. 2021

mBio

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About 382 Tg yr−1 of methane rising through the seafloor is oxidized anaerobically (W. S. Reeburgh, Chem Rev 107:486–513, 2007, https://doi.org/10.1021/cr050362v), preventing it from reaching the atmosphere, where it acts as a strong greenhouse gas. Microbial consortia composed of anaerobic methanotrophic archaea and sulfate-reducing bacteria couple the oxidation of methane to the reduction of sulfate under anaerobic conditions via a syntrophic process. Recent experimental studies and modeling efforts indicate that direct interspecies electron transfer (DIET) is involved in this syntrophy. Here, we explore a fluorescent in situ hybridization-nanoscale secondary ion mass spectrometry data set of large, segregated anaerobic oxidation of methane (AOM) consortia that reveal a decline in metabolic activity away from the archaeal-bacterial interface and use a process-based model to identify the physiological controls on rates of AOM. Simulations reproducing the observational data reveal that ohmic resistance and activation loss are the two main factors causing the declining metabolic activity, where activation loss dominated at a distance of <8 μm. These voltage losses limit the maximum spatial distance between syntrophic partners with model simulations, indicating that sulfate-reducing bacterial cells can remain metabolically active up to ∼30 μm away from the archaeal-bacterial interface. Model simulations further predict that a hybrid metabolism that combines DIET with a small contribution of diffusive exchange of electron donors can offer energetic advantages for syntrophic consortia. IMPORTANCE Anaerobic oxidation of methane is a globally important, microbially mediated process reducing the emission of methane, a potent greenhouse gas. In this study, we investigate the mechanism of how a microbial consortium consisting of archaea and bacteria carries out this process and how these organisms interact with each other through the sharing of electrons. We present a process-based model validated by novel experimental measurements of the metabolic activity of individual, phylogenetically identified cells in very large (>20-μm-diameter) microbial aggregates. Model simulations indicate that extracellular electron transfer between archaeal and bacterial cells within a consortium is limited by potential losses and suggest that a flexible use of electron donors can provide energetic advantages for syntrophic consortia.

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Microbial interactions in the anaerobic oxidation of methane: model simulations constrained by process rates and activity patterns

Cited by 19 publications

References 83 publications

Spatially Resolved Electron Transport through Anode‐Respiring Geobacter sulfurreducens Biofilms: Controls and Constraints

Spatially Resolved Electron Transport through Anode‐Respiring Geobacter sulfurreducens Biofilms: Controls and Constraints

Microbial and Reactive Transport Modeling Evidence for Hyporheic Flux‐Driven Cryptic Sulfur Cycling and Anaerobic Methane Oxidation in a Sulfate‐Impacted Wetland‐Stream System

Controls on Interspecies Electron Transport and Size Limitation of Anaerobically Methane-Oxidizing Microbial Consortia

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