Microbial Growth under Supercritical CO
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Peet, Kyle C.; Freedman, A. J.; Hernandez, Hector H.; Britto, Vanya; Boreham, Chris; Ajo‐Franklin, Jonathan; Thompson, Janelle R.

doi:10.1128/aem.03162-14

Cited by 49 publications

(96 citation statements)

References 61 publications

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“…In addition, microbes survive better in aquifers capable of rapid pH buffering (Wu et al, 2010). Numerous studies have documented microbes in environments of elevated CO 2 , even microbial growth in the presence of supercritical CO 2 (Yakimov et al, 2002; Inagaki et al, 2006; Videmsek et al, 2009; Oppermann et al, 2010; Emerson et al, 2016; Peet et al, 2015). …”

Section: Introductionmentioning

confidence: 99%

Thermodynamic and Kinetic Response of Microbial Reactions to High CO2

Jin

Kirk

2016

Front. Microbiol.

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Geological carbon sequestration captures CO2 from industrial sources and stores the CO2 in subsurface reservoirs, a viable strategy for mitigating global climate change. In assessing the environmental impact of the strategy, a key question is how microbial reactions respond to the elevated CO2 concentration. This study uses biogeochemical modeling to explore the influence of CO2 on the thermodynamics and kinetics of common microbial reactions in subsurface environments, including syntrophic oxidation, iron reduction, sulfate reduction, and methanogenesis. The results show that increasing CO2 levels decreases groundwater pH and modulates chemical speciation of weak acids in groundwater, which in turn affect microbial reactions in different ways and to different extents. Specifically, a thermodynamic analysis shows that increasing CO2 partial pressure lowers the energy available from syntrophic oxidation and acetoclastic methanogenesis, but raises the available energy of microbial iron reduction, hydrogenotrophic sulfate reduction and methanogenesis. Kinetic modeling suggests that high CO2 has the potential of inhibiting microbial sulfate reduction while promoting iron reduction. These results are consistent with the observations of previous laboratory and field studies, and highlight the complexity in microbiological responses to elevated CO2 abundance, and the potential power of biogeochemical modeling in evaluating and quantifying these responses.

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Section: Introductionmentioning

confidence: 99%

Thermodynamic and Kinetic Response of Microbial Reactions to High CO2

Jin

Kirk

2016

Front. Microbiol.

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“…This in turn, can complement existing genomic and metagenomic studies which can only confirm and infer the presence and activities of microbes based on sequence data. Previous culture-based approaches have also been performed utilizing samples from environmental sites (Mitchell et al, 2008;Kirk et al, 2013;Peet et al, 2015). Our approach was to work with a field site that had been under prolonged CO 2 perturbation (Burnside et al, 2013) to find out whether microbial communities under prolonged CO 2 exposure would still be viable.…”

Section: Introductionmentioning

confidence: 99%

Isolation and characterization of a CO2-tolerant Lactobacillus strain from Crystal Geyser, Utah, U.S.A.

et al. 2015

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When CO 2 is sequestered into the deep subsurface, changes to the subsurface microbial community will occur. Capnophiles, microorganisms that grow in CO 2 -rich environments, are some organisms that may be selected for under the new environmental conditions. To determine whether capnophiles comprise an important part of CO 2 -rich environments, an isolate from Crystal Geyser, Utah, U.S.A., a CO 2 -rich spring considered a carbon sequestration analog, was characterized. The isolate was cultured under varying CO 2 , pH, salinity, and temperature, as well as different carbon substrates and terminal electron acceptors (TEAs) to elucidate growth conditions and metabolic activity. Designated CG-1, the isolate is related (99%) to Lactobacillus casei in 16S rRNA gene identity, growing at PCO 2 between 0 and 1.0 MPa. Growth is inhibited at 2.5 MPa, but stationary phase cultures exposed to this pressure survive beyond 5 days. At 5.0 MPa, survival is at least 24 h. CG-1 grows in neutral pH, 0.25 M NaCl, and between 25 • and 45 • C and consumes glucose, lactose, sucrose, or crude oil, likely performing lactic acid fermentation. Fatty acid profiles between 0.1 and 1.0 MPa suggests decreases in cell size and increases in membrane rigidity. Transmission electron microscopy reveals rod shaped bacteria at 0.1 MPa. At 1.0 MPa, cells are smaller, amorphous, and produce abundant capsular material. Its ability to grow in environments regardless of the presence of CO 2 suggests we have isolated an organism that is more capnotolerant than capnophilic. Results also show that microorganisms are capable of surviving the stressful conditions created by the introduction of CO 2 for sequestration. Furthermore, our ability to culture an environmental isolate indicates that organisms found in CO 2 environments from previous genomic and metagenomics studies are viable, metabolizing, and potentially affecting the surrounding environment.

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“…At reservoir depths typically >1 km, CO 2 exists in the supercritical (sc) phase (31.18C, 72.9 atm). Although scCO 2 is regarded as a microbial sterilizing agent (White et al, 2006;Zhang et al, 2006;Mitchell et al, 2008;Ortuño et al, 2012), recent field and laboratory studies indicating resilience to stresses associated with supercritical (Mitchell et al, 2008;Mu et al, 2014;Peet et al, 2015) and near-critical CO 2 (de Beer et al, 2013;Emerson et al, 2015) suggest that scCO 2 -bearing reservoirs may support a stable microbial biosphere.…”

Section: Introductionmentioning

confidence: 99%

Microbial potential for carbon and nutrient cycling in a geogenic supercritical carbon dioxide reservoir

Freedman

Tan

Thompson

2017

Environmental Microbiology

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SummaryMicroorganisms catalyze carbon cycling and biogeochemical reactions in the deep subsurface and thus may be expected to influence the fate of injected supercritical (sc) CO2 following geological carbon sequestration (GCS). We hypothesized that natural subsurface scCO2 reservoirs, which serve as analogs for the long‐term fate of sequestered scCO2, harbor a ‘deep carbonated biosphere’ with carbon cycling potential. We sampled subsurface fluids from scCO2‐water separators at a natural scCO2 reservoir at McElmo Dome, Colorado for analysis of 16S rRNA gene diversity and metagenome content. Sequence annotations indicated dominance of Sulfurospirillum, Rhizobium, Desulfovibrio and four members of the Clostridiales family. Genomes extracted from metagenomes using homology and compositional approaches revealed diverse mechanisms for growth and nutrient cycling, including pathways for CO2 and N2 fixation, anaerobic respiration, sulfur oxidation, fermentation and potential for metabolic syntrophy. Differences in biogeochemical potential between two production well communities were consistent with differences in fluid chemical profiles, suggesting a potential link between microbial activity and geochemistry. The existence of a microbial ecosystem associated with the McElmo Dome scCO2 reservoir indicates that potential impacts of the deep biosphere on CO2 fate and transport should be taken into consideration as a component of GCS planning and modelling.

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Microbial Growth under Supercritical CO ₂

Cited by 49 publications

References 61 publications

Thermodynamic and Kinetic Response of Microbial Reactions to High CO2

Thermodynamic and Kinetic Response of Microbial Reactions to High CO2

Isolation and characterization of a CO2-tolerant Lactobacillus strain from Crystal Geyser, Utah, U.S.A.

Microbial potential for carbon and nutrient cycling in a geogenic supercritical carbon dioxide reservoir

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Microbial Growth under Supercritical CO 2

Cited by 49 publications

References 61 publications

Thermodynamic and Kinetic Response of Microbial Reactions to High CO2

Thermodynamic and Kinetic Response of Microbial Reactions to High CO2

Isolation and characterization of a CO2-tolerant Lactobacillus strain from Crystal Geyser, Utah, U.S.A.

Microbial potential for carbon and nutrient cycling in a geogenic supercritical carbon dioxide reservoir

Contact Info

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Microbial Growth under Supercritical CO ₂