Distinguishing Iron‐Reducing from Sulfate‐Reducing Conditions

Chapelle, Francis H.; Bradley, Paul M.; Thomas, Mary Ann; McMahon, Peter B.

doi:10.1111/j.1745-6584.2008.00536.x

Cited by 60 publications

(46 citation statements)

References 32 publications

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“…This substantiates the hypothesis that microbial iron reduction dominated in the group BCD mesocosms. The results are consistent with the fact that the organic carbon requirement for microbial sulphate reduction is substantially higher than that for microbial iron reduction [39].…”

Section: Carbohydrate Metabolismsupporting

confidence: 79%

Minor differences in sand physicochemistry lead to major differences in bacterial community structure and function after exposure to synthetic acid mine drainage

Welz

Ramond

Cowan

et al. 2014

Biotechnol Bioproc E

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The formation of environmentally toxic acidic waste from mining activities is a world-wide problem. Neutralization of this waste can be accomplished by physicochemical and/or biological means. In this short-term study, synthetic acid mine drainage was added to sandfilled mesocosms containing silica-dominated (quartz) sand. Glucose was added as a carbon source for microbial iron and/or sulphate reduction. Replicates contained two separate batches of sand obtained from the same quarry site. The investigations used to assess and compare the chemical and biological functioning of the replicates included system hydraulic conductivity measurements, sand chemistry, effluent chemistry and bacterial community fingerprinting. Minor differences in composition of the sand, including the levels of available nutrients and micronutrients, resulted in major differences in measured parameters. 2 Significant differences in effluent chemistry were found in systems containing different batches of sand. It was demonstrated that the characteristics of the sand and the presence of acid mine drainage impacted the bacterial community structure and function. The importance of the physical substrate on the selection of functional microbial communities in systems remediating AMD should not be under-estimated. The physical substrate should be carefully selected and it may be prudent to include small-scale comparative studies in each particular setting prior to full-scale implementation.

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Section: Carbohydrate Metabolismsupporting

confidence: 79%

Minor differences in sand physicochemistry lead to major differences in bacterial community structure and function after exposure to synthetic acid mine drainage

Welz

Ramond

Cowan

et al. 2014

Biotechnol Bioproc E

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“…So despite sulfate reducers and iron reducers competing for the same electron donors in the Mahomet aquifer, by working together they prevent product inhibition. Therefore, rather than being excluded due to thermodynamic constraints by iron reducers as is often suggested [19,20], sulfate reducers seem to be thriving alongside them in the Mahomet aquifer. The relative richness of iron-reducing bacteria as a proportion of total OTUs only exceeded that of sulfate reducers when sulfate concentrations were below 0.2 mM.…”

Section: Discussionmentioning

confidence: 95%

“…This aquifer contains a diverse community of iron-reducing and sulfate-reducing bacteria in which sulfate has been proposed as a key discriminant of bacterial community structure [18]. Specifically, in high sulfate wells, sulfate reducers have been shown to co-exist with iron reducers throughout the aquifer [18], contrary to previous notions that sulfate reduction is excluded under iron-reducing conditions [19-21]. Previous studies focused exclusively on bacterial populations, leaving the distribution of archaeal populations such as methanogens unexplored.…”

Section: Introductionmentioning

confidence: 99%

Functional microbial diversity explains groundwater chemistry in a pristine aquifer

et al. 2013

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BackgroundThe diverse microbial populations that inhabit pristine aquifers are known to catalyze critical in situ biogeochemical reactions, yet little is known about how the structure and diversity of this subsurface community correlates with and impacts upon groundwater chemistry. Herein we examine 8,786 bacterial and 8,166 archaeal 16S rRNA gene sequences from an array of monitoring wells in the Mahomet aquifer of east-central Illinois. Using multivariate statistical analyses we provide a comparative analysis of the relationship between groundwater chemistry and the microbial communities attached to aquifer sediment along with those suspended in groundwater.ResultsStatistical analyses of 16S rRNA gene sequences showed a clear distinction between attached and suspended communities; with iron-reducing bacteria far more abundant in attached samples than suspended, while archaeal clones related to groups associated with anaerobic methane oxidation and deep subsurface gold mines (ANME-2D and SAGMEG-1, respectively) distinguished the suspended community from the attached. Within the attached bacterial community, cloned sequences most closely related to the sulfate-reducing Desulfobacter and Desulfobulbus genera represented 20% of the bacterial community in wells where the concentration of sulfate in groundwater was high (> 0.2 mM), compared to only 3% in wells with less sulfate. Sequences related to the genus Geobacter, a genus containing ferric-iron reducers, were of nearly equal abundance (15%) to the sulfate reducers under high sulfate conditions, however their relative abundance increased to 34% when sulfate concentrations were < 0.03 mM. Also, in areas where sulfate concentrations were <0.03 mM, archaeal 16S rRNA gene sequences similar to those found in methanogens such as Methanosarcina and Methanosaeta comprised 73–80% of the community, and dissolved CH4 ranged between 220 and 1240 μM in these groundwaters. In contrast, methanogens (and their product, CH4) were nearly absent in samples collected from groundwater samples with > 0.2 mM sulfate. In the suspended fraction of wells where the concentration of sulfate was between 0.03 and 0.2 mM, the archaeal community was dominated by sequences most closely related to the ANME-2D, a group of archaea known for anaerobically oxidizing methane. Based on available energy (∆GA) estimations, results varied little for both sulfate reduction and methanogenesis throughout all wells studied, but could favor anaerobic oxidation of methane (AOM) in wells containing minimal sulfate and dihydrogen, suggesting AOM coupled with H2-oxidizing organisms such as sulfate or iron reducers could be an important pathway occurring in the Mahomet aquifer.ConclusionsOverall, the results show several distinct factors control the composition of microbial communities in the Mahomet aquifer. Bacteria that respire insoluble substrates such as iron oxides, i.e. Geobacter, comprise a greater abundance of the attached community than the suspended regardless of groundwater chemistry. Differences in co...

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“…This groundwater may be decades older and more depleted in bioavailable DOC than the runoff-derived groundwater in the losing section. The refractory DOC compounds in old groundwater are metabolized very slowly and do not strongly stimulate bacterial growth (Ladd et al 1982, Chapelle et al 2009). …”

Section: Relationships Among Doc Do and Bacteriamentioning

confidence: 99%

Ecological dynamics in the riverine aquifers of a gaining and losing river

2015

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The effects of river-flow fluctuations on groundwater ecosystems and differences in ecological conditions in aquifers connected to losing, gaining, and alternating river reaches are poorly known. We used monitoring wells at gaining and losing reaches along an alluvial river to identify associations between river and groundwater fluctuations and ecological conditions in riverine aquifers. Groundwater and surface-water pH, temperature, and dissolved O 2 (DO) were positively correlated at all sites, and groundwater and surface-water dissolved organic C (DOC) concentrations were positively correlated at 3 sites. Groundwater and surface water in the gaining section were more NO 3 --enriched and highly mineralized than in the losing section. These differences reflect the primary water source in each section. The gaining section is dominated by regional groundwater and the losing section by hillslope runoff. The groundwater-surface-water correlations and comparisons between sections indicate that physicochemical conditions in losing-reach aquifers are controlled by surface-water infiltration, and conditions in gaining-reach aquifers are controlled by groundwater inflow from up-gradient aquifers. At some sites, groundwater DOC concentrations were positively correlated with DO concentrations and heterotrophic bacterial densities. These correlations suggest that DOC and DO are depleted simultaneously by aerobic microbial processes and that bacterial populations are DOC-limited, which may in turn limit invertebrate abundance. DOC concentrations, bacterial densities, and invertebrate density and taxon richness varied in response to river flow, groundwater levels, and time since floods at some sites. Patterns of river-aquifer exchange and hydrology-groundwater-ecology relationships are prerequisites for identifying the river-flow requirements for healthy groundwater ecosystems.

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Distinguishing Iron‐Reducing from Sulfate‐Reducing Conditions

Cited by 60 publications

References 32 publications

Minor differences in sand physicochemistry lead to major differences in bacterial community structure and function after exposure to synthetic acid mine drainage

Minor differences in sand physicochemistry lead to major differences in bacterial community structure and function after exposure to synthetic acid mine drainage

Functional microbial diversity explains groundwater chemistry in a pristine aquifer

Ecological dynamics in the riverine aquifers of a gaining and losing river

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