The ecology of anaerobic degraders of BTEX hydrocarbons in aquifers

Lueders, Tillmann

doi:10.1093/femsec/fiw220

Cited by 91 publications

(65 citation statements)

References 119 publications

(196 reference statements)

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“…We can hypothesise that close to the reservoir of natural gas, dissolved hydrocarbons (i.e., short-chain alkanes, BTEX) may serve as exogenous nutrients and could be key factor shaping the composition of the communities. The literature on the topic is full of examples of the capacity of deltaproteobacteria and Firmicutes to grow on these organic molecules (Meckenstock et al, 2016;Lueders, 2017). Microbial communities populating subsurface environments have demonstrated such capacity for the biodegradation of hydrocarbons in the laboratory and in situ.…”

Section: Diversity Of Sulfate-reducing and Methanogenic Metacommunitiesmentioning

confidence: 99%

Geological gas‐storage shapes deep life

Ranchou-Peyruse

Auguet

Mazière

et al. 2019

Environmental Microbiology

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Summary Around the world, several dozen deep sedimentary aquifers are being used for storage of natural gas. Ad hoc studies of the microbial ecology of some of them have suggested that sulfate reducing and methanogenic microorganisms play a key role in how these aquifers' communities function. Here, we investigate the influence of gas storage on these two metabolic groups by using high‐throughput sequencing and show the importance of sulfate‐reducing Desulfotomaculum and a new monophyletic methanogenic group. Aquifer microbial diversity was significantly related to the geological level. The distance to the stored natural gas affects the ratio of sulfate‐reducing Firmicutes to deltaproteobacteria. In only one aquifer, the methanogenic archaea dominate the sulfate‐reducers. This aquifer was used to store town gas (containing at least 50% H2) around 50 years ago. The observed decrease of sulfates in this aquifer could be related to stimulation of subsurface sulfate‐reducers. These results suggest that the composition of the microbial communities is impacted by decades old transient gas storage activity. The tremendous stability of these gas‐impacted deep subsurface microbial ecosystems suggests that in situ biotic methanation projects in geological reservoirs may be sustainable over time.

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Section: Diversity Of Sulfate-reducing and Methanogenic Metacommunitiesmentioning

confidence: 99%

Geological gas‐storage shapes deep life

Ranchou-Peyruse

Auguet

Mazière

et al. 2019

Environmental Microbiology

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“…The electron acceptors were consumed in a certain order, with O 2 consumed first, followed by NO reduction, and methane production, respectively [16]. Samples MW3 and MW17 were associated with high Fe 2+ and low SO 4 2− , which indicated that the electron acceptors Fe 3+ and SO 4 2− had been consumed, these two samples probably were in the methanogenesis stage.…”

Section: The Influence Of Electron Acceptors On Bacterial Communitiesmentioning

confidence: 93%

“…Ai-xia Zhou researched the responses of microbial communities to seasonal fluctuations in groundwater level and found that groundwater-table fluctuations would affect the distribution, transport, and biodegradation of the contaminants [15]. Petroleum compounds can be transported from the source area in groundwater, with the result that the petroleum concentrations, redox conditions, biogeochemical processes, and bacterial communities would vary along the groundwater flow path [16]. This view can be supported by other related research, such as from Karolin Tischer, Etienne Yergeau and C.E.…”

Section: Introductionmentioning

confidence: 99%

Spatial Pattern of Bacterial Community Diversity Formed in Different Groundwater Field Corresponding to Electron Donors and Acceptors Distributions at a Petroleum-Contaminated Site

Ning

Zhang

et al. 2018

Water

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Abstract:The benefits of an electron-transfer mechanism for petroleum biodegrading have been widely acknowledged, but few have studied the spatial pattern of microbial community diversity in groundwater fields, and few discuss the bacterial community's diversity in relation to electron donors-acceptors distribution, which is largely determined by groundwater flow. Eleven samples in different groundwater fields are collected at a petroleum-contaminated site, and the microbial communities are investigated using 16S rRNA gene sequences with multivariate statistics. These are mainly linked to the chemical composition analysis of electron donor indexes COD, BTEX and electron acceptor indexes DO, NO 3 − , Fe 2+ , Mn 2+ , and SO 4 2− , HCO 3 − . The spatial pattern of the bacterial community's diversity is characterized and the effect of the electron redox reaction on bacterial community formation in different groundwater field zones is elucidated. It is found that a considerable percentage (>65%) of the bacterial communities related to petroleum degrading suggest that petroleum biodegrading is occurring in groundwater. The communities are subject to the redox reaction in different groundwater field zones: The side plume zone and the upstream of the source zone are under aerobic redox or denitrification redox, and the corresponding bacteria are Rhodoferax, Novosphingobium, Hydrogenophaga, and Comamonas; the source zone and downstream of the source zone are under Fe 3+ , Mn 4+ , and SO 4 2− reduction redox, and the corresponding bacteria are Rhodoferax, Treponema, Desulfosporosinus, Hydrogenophaga, and Acidovorax. These results imply that groundwater flow plays a definitive role in the bacterial community's diversity spatial pattern formation by influencing the distribution of electron donor and acceptor.

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“…A large variety of microorganisms (bacteria and archaea) have been identified with the capability to degrade hydrocarbon molecules anaerobically. These bacteria exploit anaerobic respiration via nitrate, nitrite, and metal ions or fermentation during substrate catabolism (Lueders, 2017;Portugal et al, 2017).…”

Section: Anaerobic Biodegradationmentioning

confidence: 99%

“…Likewise, this kind of biodegradation can happen beneath the surface of areas where aerobic biological activity has been ceased as all the oxygen is used. After oxygen exhaustion, there may be a consecutive employment of the electron acceptors (nitrate, ferric iron, sulphate, and hydrogen) to supply energy from the hydrocarbon mineralization (Aktas et al, 2017;Arulazhagan et al, 2017;Ghattas et al, 2017;Lueders, 2017).…”

Section: Anaerobic Biodegradationmentioning

confidence: 99%