Environmental Genomics Reveals a Single-Species Ecosystem Deep Within Earth

Chivian, Dylan; Brodie, Eoin L.; Alm, Eric J.; Culley, David E.; Dehal, Paramvir; DeSantis, Todd Z.; Gihring, Thomas M.; Lapidus, Alla; Lin, Li; Lowry, Stephen R.; Moser, Duane P.; Richardson, Paul M.; Southam, Gordon; Wanger, Greg; Pratt, Lisa M.; Andersen, Gary L.; Hazen, Terry C.; Brockman, Fred J.; Arkin, Adam P.; Onstott, Tullis C.

doi:10.1126/science.1155495

Cited by 469 publications

(464 citation statements)

References 55 publications

(77 reference statements)

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“…In addition, besides Desulfohalobium and Desulfotomaculum, sequences affiliated to a Candidatus Desulforudis audaxviator were frequently detected in fluids produced from the cold well. Sequences of Candidatus Desulforudis audaxviator were also found in 60°C tempered fracture water collected from a South African gold mine at a depth of 2.8 km (Chivian et al 2008). Recently, a study by Alawi et al (2011) identified sequences similar to Candidatus Desulforudis audaxviator in 61°C tempered fluid samples taken after heat extraction in the topside facility of a geothermal plant in the Molasse Basin (Germany).…”

Section: Discussionmentioning

confidence: 98%

“…were detected in fluids cooled at the heat exchanger from 75°C to 46°C. Physiological characteristics of detected SRB and Halanaerobiaceae correspond to the subsurface environment with respect to optimum temperature, salt concentration, and pH, and are commonly found in similar anaerobic saline environments such as sediments from salt lakes (Cayol et al 1994;Jakobsen et al 2006), geothermal groundwater (Daumas et al 1988), fracture water (Chivian et al 2008), as well as in oil fields and petroleum hydrocarbon contaminated sites (Magot et al 2000;Cayol et al 2002;Denger et al 2002;Bonch-Osmolovskaya et al 2003). Halophilic Desulfohalobium utahense are known moderate halophilic and mesophilic sulfate and thiosulfate reducers that use a broad range of electron donors including various short-chain fatty acids and primary (C 1-5 ) alcohols, amino acids, H 2 /acetate and H 2 /yeast extract (Jakobsen et al 2006).…”

Section: Discussionmentioning

confidence: 99%

“…Recently, a study by Alawi et al (2011) identified sequences similar to Candidatus Desulforudis audaxviator in 61°C tempered fluid samples taken after heat extraction in the topside facility of a geothermal plant in the Molasse Basin (Germany). Candidatus Desulforudis audaxviator is a rarely detected microorganism so far, whereas it has the ability to subsist as a single species ecosystem that is based on hydrogen originating from radiochemical reactions in deep crustal rocks and sulfate reduction as the dominant electronaccepting process (Lin et al 2006;Chivian et al 2008). The repeated detection of sequences affiliated to this species in a saline aquifer of the NGB (TDS 130 g l -1 ) as well as in a low mineralized Malm aquifer of the Molasse Basin (TDS < 1 g l -1 ) indicates that this organism is much more distributed in the deep subsurface than previously assumed and co-existing with other SRB.…”

Section: Discussionmentioning

confidence: 99%

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Thermal effects on microbial composition and microbiologically induced corrosion and mineral precipitation affecting operation of a geothermal plant in a deep saline aquifer

et al. 2013

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The microbial diversity of a deep saline aquifer used for geothermal heat storage in the North German Basin was investigated. Genetic fingerprinting analyses revealed distinct microbial communities in fluids produced from the cold and warm side of the aquifer. Direct cell counting and quantification of 16S rRNA genes and dissimilatory sulfite reductase (dsrA) genes by real-time PCR proved different population sizes in fluids, showing higher abundance of bacteria and sulfate reducing bacteria (SRB) in cold fluids compared with warm fluids. The operation-dependent temperature increase at the warm well probably enhanced organic matter availability, favoring the growth of fermentative bacteria and SRB in the topside facility after the reduction of fluid temperature. In the cold well, SRB predominated and probably accounted for corrosion damage to the submersible well pump, and iron sulfide precipitates in the near wellbore area and topside facility filters. This corresponded to lower sulfate content in fluids produced from the cold well as well as higher content of hydrogen gas that was probably released from corrosion, and maybe favored growth of hydrogenotrophic SRB. This study reflects the high influence of microbial populations for geothermal plant operation, because microbiologically induced precipitative and corrosive processes adversely affect plant reliability.2

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Section: Discussionmentioning

confidence: 98%

Section: Discussionmentioning

confidence: 99%

Section: Discussionmentioning

confidence: 99%

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Thermal effects on microbial composition and microbiologically induced corrosion and mineral precipitation affecting operation of a geothermal plant in a deep saline aquifer

et al. 2013

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“…Recently, PCR primers for the specific amplification of the large subunit of the [FeFe]hydrogenase gene (hydA) were developed to examine the diversity of hydA as a proxy for fermentative bacteria in a H 2 -generating saline microbial-mat system (Boyd et al, 2009b) and in a H 2 -generating anaerobic bioreactor (Xing et al, 2008). The results of these studies, as well as those from a number of metagenomic investigations that include the deep subsurface (Chivian et al, 2008) and termite hindgut environments (Warnecke et al, 2007), collectively indicate a widespread distribution and diversity of [FeFe]-hydrogenase in nature. However, our understanding of the environmental constraints that control the distribution and diversity of [FeFe]hydrogenase-mediated H 2 production in natural systems is confounded by the tight coupling between H 2 production and consumption and by the abiological reactions that contribute to H 2 production and consumption in natural systems.…”

Section: Introductionmentioning

confidence: 99%

[FeFe]-hydrogenase in Yellowstone National Park: evidence for dispersal limitation and phylogenetic niche conservatism

et al. 2010

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Hydrogen (H 2 ) has an important role in the anaerobic degradation of organic carbon and is the basis for many syntrophic interactions that commonly occur in microbial communities. Little is known, however, with regard to the biotic and/or abiotic factors that control the distribution and phylogenetic diversity of organisms which produce H 2 in microbial communities. In this study, we examined the [FeFe]-hydrogenase gene (hydA) as a proxy for fermentative bacterial H 2 production along physical and chemical gradients in various geothermal springs in Yellowstone National Park (YNP), WY, USA. The distribution of hydA in YNP geothermal springs was constrained by pH to environments co-inhabited by oxygenic phototrophs and to environments predicted to have low inputs of abiotic H 2 . The individual HydA asssemblages from YNP springs were more closely related when compared with randomly assembled communities, which suggests ecological filtering. Model selection approaches revealed that geographic distance was the best explanatory variable to predict the phylogenetic relatedness of HydA communities. This evinces the dispersal limitation imposed by the geothermal spring environment on HydA phylogenetic diversity even at small spatial scales. pH differences between sites is the second highest ranked explanatory variable of HydA phylogenetic relatedness, which suggests that the ecology related to pH imposes strong phylogenetic niche conservatism. Collectively, these results indicate that pH has imposed strong niche conservatism on fermentative bacteria and that, within a narrow pH realm, YNP springs are dispersal limited with respect to fermentative bacterial communities.

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“…Lovley and Chapelle (1995) give a general summary of deep subsurface microbial processes. Chivian et al (2008) provide a schematic illustration of microbial processes in a deep single-species ecosystem, including mineralogic reactions and the radioactive and radiolytic processes that contribute energy and nutrients. Pedersen (1996) provided a review of investigations of bacteria in deep crystalline bedrock and their potential importance for nuclear-waste disposal in underground repositories.…”

Section: Microbial Activity In the Deep Subsurfacementioning

confidence: 99%

Disposal systems evaluations and tool development : Engineered Barrier System (EBS) evaluation.

Rutqvist¹,

Liu²,

Steefel³

et al. 2011

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Eric Sonnenthal (LBNL) Engineered Barrier System (EBS) Evaluation This page is intentionally left blank Engineered Barrier System (EBS) Evaluation 5 Executive SummaryKey components of the nuclear fuel cycle are short-term storage and long-term disposal of nuclear waste. The latter encompasses the immobilization of used nuclear fuel (UNF) and radioactive waste streams generated by various phases of the nuclear fuel cycle, and the safe and permanent disposition of these waste forms in geological repository environments. The engineered barrier system (EBS) plays a very important role in the long-term isolation of nuclear waste in geological repository environments. EBS concepts and their interactions with the natural barrier are inherently important to the long-term performance assessment of the safety case where nuclear waste disposition needs to be evaluated for time periods of up to one million years. Making the safety case needed in the decision-making process for the recommendation and the eventual embracement of a disposal system concept requires a multi-faceted integration of knowledge and evidence-gathering to demonstrate the required confidence level in a deep geological disposal site and to evaluate longterm repository performance.The focus of this report is the following:• Evaluation of EBS in long-term disposal systems in deep geologic environments with emphasis on the multi-barrier concept;• Evaluation of key parameters in the characterization of EBS performance;• Identification of key knowledge gaps and uncertainties;• Evaluation of tools and modeling approaches for EBS processes and performance.The above topics will be evaluated through the analysis of the following:• Overview of EBS concepts for various NW disposal systems;• Natural and man-made analogs, room chemistry, hydrochemistry of deep subsurface environments, and EBS material stability in near-field environments;• Reactive Transport and Coupled Thermal-Hydrological-Mechanical-Chemical (THMC) processes in EBS;• Thermal analysis toolkit, metallic barrier degradation mode survey, and development of a Disposal Systems Evaluation Framework (DSEF).This report will focus on the multi-barrier concept of EBS and variants of this type which in essence is the most adopted concept by various repository programs. Empasis is given mainly to the evaluation of EBS materials and processes through the analysis of published studies in the scientific literature of past and existing repository research programs. Tool evaluations are also emphasized, particularly on THCM processes and chemical equilibria. Although being an increasingly important aspect of NW disposition, short-term or interim storage of NW will be briefly discussed but not to the extent of the EBS issues relevant to disposal systems in deep geologic environments. Interim storage will be discussed in the report Evaluation of Storage Concepts FY10 Final Report (Weiner et al. 2010). Engineered Barrier System (EBS) Evaluation 6This page is intentionally left blank Engineered Barrier System (EBS) Eva...

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Environmental Genomics Reveals a Single-Species Ecosystem Deep Within Earth

Cited by 469 publications

References 55 publications

Thermal effects on microbial composition and microbiologically induced corrosion and mineral precipitation affecting operation of a geothermal plant in a deep saline aquifer

Thermal effects on microbial composition and microbiologically induced corrosion and mineral precipitation affecting operation of a geothermal plant in a deep saline aquifer

[FeFe]-hydrogenase in Yellowstone National Park: evidence for dispersal limitation and phylogenetic niche conservatism

Disposal systems evaluations and tool development : Engineered Barrier System (EBS) evaluation.

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