Biogeochemical Processes In Ethanol Stimulated Uranium-contaminated Subsurface Sediments

Mohanty, Santosh Ranjan; Kollah, Bharati; Hedrick, David B.; Peacock, Aaron D.; Kukkadapu, Ravi; Roden, Eric E.

doi:10.1021/es703082v

Cited by 52 publications

(40 citation statements)

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“…The 16S microarray data revealed qualitatively similar temporal patterns in microbial community structure compared to conventional 16S rRNA gene clone library data reported previously (29) for the slurry incubation experiment (Fig. 2).…”

supporting

confidence: 81%

“…Information on the status of microbial communities involved in U(VI) reduction and other electron-accepting pathways is important to understand the spatial/temporal dynamics and overall efficacy of in situ uranium bioremediation (1). Although 16S rRNA clone libraries and/or microarrays have been applied to various U(VI) reduction systems (2,4,7,17,28,29,40,41,44), knowledge remains scant of the quantitative coverage of these techniques, particularly in situations where multiple groups of organisms are active.…”

mentioning

confidence: 99%

“…The samples analyzed came from an experiment designed to document patterns of microbial redox metabolism and community structure in response to the addition of an electron donor (ethanol) to stimulate U(VI) reduction activity (29). As part of that study, six conventional 16S rRNA gene clone libraries (90-134 clones each) were constructed from reversetranscribed 16S rRNA extracted from subsamples obtained at different time points during the experiment.…”

mentioning

confidence: 99%

“…Although 16S microarrays have seen broad use in environmental microbiology, to date their ability to reveal changes in microbial community structure during redox transitions in space or time has not been established. A prior experiment (29) provided an ideal context for evaluating this question, as it was a controlled system for which both good supporting geochemical data on redox metabolism, and independent information on microbial community composition (i.e. clone libraries), were available.…”

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confidence: 99%

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16S rRNA Gene Microarray Analysis of Microbial Communities in Ethanol-Stimulated Subsurface Sediment

et al. 2011

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A high-density 16S rRNA gene microarray was used to analyze microbial communities in a slurry of ethanolamended, uranium-contaminated subsurface sediment. Of specific interest was the extent to which the microarray could detect temporal patterns in the relative abundance of major metabolic groups (nitrate-reducing, metal-reducing, sulfatereducing, and methanogenic taxa) that were stimulated by ethanol addition. The results show that the microarray, when used in conjunction with geochemical data and knowledge of the physiological properties of relevant taxa, provided accurate assessment of the response of key functional groups to biostimulation.

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confidence: 99%

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confidence: 99%

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16S rRNA Gene Microarray Analysis of Microbial Communities in Ethanol-Stimulated Subsurface Sediment

et al. 2011

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“…Aquatic chemistry and radiological analyses were performed by our LLNL collaborator. Briefly, activation products 14 C and 36 Cl were analyzed by accelerator mass spectrometry (AMS) and fission products Pumped or bailed water was obtained from subsurface radiological environments (Fig. 2).…”

Section: Field Sitementioning

confidence: 99%

Characterization of Microbial Communities in Subsurface Nuclear Blast Cavities of the Nevada Test Site

Moser¹,

Bruckner²,

Fisher³

et al. 2010

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This US Department of Energy (DOE) Environmental Remediation Sciences Project (ERSP) was designed to test fundamental hypotheses concerning the existence and nature of indigenous microbial populations of Nevada Test Site subsurface nuclear test/detonation cavities. Now called Subsurface Biogeochemical Research (SBR), this program's Exploratory Research (ER) element, which funded this research, is designed to support high risk, high potential reward projects. Here, five cavities (GASCON, CHANCELLOR, NASH, ALEMAN, and ALMENDRO) and one tunnel (U12N) were sampled using bailers or pumps. Molecular and cultivation-based techniques revealed bacterial signatures at five sites (CHANCELLOR may be lifeless). SSU rRNA gene libraries contained diverse and divergent microbial sequences affiliated with known metal-and sulfur-cycling microorganisms, organic compound degraders, microorganisms from deep mines, and bacteria involved in selenate reduction and arsenite oxidation. Close relatives of Desulforudis audaxviator, a microorganism thought to subsist in the terrestrial deep subsurface on H 2 and SO 4 2-produced by radiochemical reactions, was detected in the tunnel waters. NTS-specific media formulations were used to culture and quantify nitrate-, sulfate-, iron-reducing, fermentative, and methanogenic microorganisms. Given that redox manipulations mediated by microorganisms can impact the mobility of DOE contaminants, our results should have implications for management strategies at this and other DOE sites. CONTENTS

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Field‐scale uranium (VI) bioimmobilization monitored by lipid biomarkers and ¹³C‐acetate incorporation

Peacock

Hedrick

Long

et al. 2011

Remediation Journal

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At the Old Rifle uranium mill-tailing site in eastern Colorado, a test of subsurface amendment with acetate to stimulate the reductive immobilization of uranium was monitored by using lipid biomarker analysis and incorporation of 13 C-labeled acetate into lipid biomarkers. Both sediment and groundwater samples were analyzed. Within 7 days of acetate addition, groundwater microbial biomass increased by a factor of 5, and remained higher than control values in most samples for the 28 days sampled. At 29 days after the beginning of acetate amendment, 4 of 12 sediment samples had microbial biomass greater than the 95 percent confidence interval of controls. The mole percents of the phospholipid fatty acids 16:1ω7c and 16:1ω5c increased over control values upon acetate amendment, and incorporated high levels of 13 C from labeled acetate in groundwater and sediment samples. 16:1ω7c is a biomarker for Geobacter, and evidence is provided that 16:1ω5crepresents an unidentified iron-reducing bacterium, probably a member of the Desulfobulbaceae.Biomarkers for organisms other than iron-reducing bacteria, iso-and anteiso-branched fatty acids and 18:1ω9c, decreased upon acetate amendment, and had their highest stable isotope incorporation at least 4 days after labeled acetate amendment ended, evidence for carbon-sharing between iron-reducers and other microorganisms. O c 2011 Wiley Periodicals, Inc. INTRODUCTIONGroundwater contamination by uranium is a localized but worldwide problem. While uranium contamination can derive from natural sources, most groundwaters are contaminated by uranium leaching from mining waste and mill tailings (Wall & Krumholtz, 2006). There is currently no proven cost-effective remediation strategy for uranium-contaminated aquifers. Strategies such as soil washing, solidification, chemical immobilization, chemical reduction, and phytoremediation are being explored (Abd El-Sabour, 2007). Uranium can be removed from potable waters by ion-exchange or reverse osmosis, but these technologies are too expensive to be scaled up to an aquifer. Bioimmobilization has emerged as an attractive approach to controlling uranium groundwater contamination. The soluble form of uranium is U(VI), usually complexed with carbonate (Wall & Krumholtz, 2006). Some metal-reducing bacteria, in particular Geobacter, can reduce U(VI) to U(IV), which forms insoluble uranite, UO 2 . There is also evidence that U(VI) is adsorbed by metal sulfides formed by sulfate-reducing bacteria. Acetate, ethanol, and glucose are the subsurface amendments most commonly used to drive bioimmobilization in situ. Issues to be resolved include the timing and amount of subsurface amendment to maximize bioimmobilization, and the long-term stability of bioimmobilized uranium. Bacterial reduction of iron (Lovley, 2000) and uranium (Wall & Krumholtz, 2006) have been reviewed. Phospholipid fatty acid (PLFA) analysis has been extensively applied to monitor subsurface bioremediation, including uranium bioimmobilization (Anderson et al., 2003;Chang et al., 20...

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Biogeochemical Processes In Ethanol Stimulated Uranium-contaminated Subsurface Sediments

Cited by 52 publications

References 42 publications

16S rRNA Gene Microarray Analysis of Microbial Communities in Ethanol-Stimulated Subsurface Sediment

16S rRNA Gene Microarray Analysis of Microbial Communities in Ethanol-Stimulated Subsurface Sediment

Characterization of Microbial Communities in Subsurface Nuclear Blast Cavities of the Nevada Test Site

Field‐scale uranium (VI) bioimmobilization monitored by lipid biomarkers and ¹³C‐acetate incorporation

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Biogeochemical Processes In Ethanol Stimulated Uranium-contaminated Subsurface Sediments

Cited by 52 publications

References 42 publications

16S rRNA Gene Microarray Analysis of Microbial Communities in Ethanol-Stimulated Subsurface Sediment

16S rRNA Gene Microarray Analysis of Microbial Communities in Ethanol-Stimulated Subsurface Sediment

Characterization of Microbial Communities in Subsurface Nuclear Blast Cavities of the Nevada Test Site

Field‐scale uranium (VI) bioimmobilization monitored by lipid biomarkers and 13C‐acetate incorporation

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Field‐scale uranium (VI) bioimmobilization monitored by lipid biomarkers and ¹³C‐acetate incorporation