Fe-oxide grain coatings support bacterial Fe-reducing metabolisms in 1.7-2.0 km-deep subsurface quartz arenite sandstone reservoirs of the Illinois Basin (USA)

The Cambrian-age Mt. Simon Sandstone, deeply buried within the Illinois Basin of the midcontinent of North America, contains quartz sand grains ubiquitously encrusted with iron-oxide cements and dissolved ferrous iron in pore-water. Although microbial iron reduction has previously been documented in... Full description

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doi: 10.3389/fmicb.2014.00511
Authors:Dong, Y.; Sanford, R.A.; Locke, R.A.; Cann, I.K.; Mackie, R.I.; Fouke, B.W.
Volume Title:Frontiers in Microbiology
Source:Frontiers in Microbiology, Vol.5. Publisher: Frontiers Research Foundation, Lausanne, Switzerland. ISSN: 1664-302X
Publication Date:2014
Note:In English. 50 refs.; illus., incl. 1 table
Subjects:Arenite; Bacteria; Cambrian; Carbon dioxide; Carbon sequestration; Clastic rocks; Gas injection; Iron oxides; Metabolism; Microorganisms; Mount Simon Sandstone; Oxides; Paleozoic; Quartz arenite; Reservoir rocks; Sandstone; Sedimentary rocks; Site exploration; Upper Cambrian; Illinois; Illinois Basin; Macon County Illinois; United States; Decatur Illinois; Firmicutes; Halanaerobiales; Vulcanibacillus
Coordinates:N393600 N400400 W0884500 W0891200
Record ID:2020024172
Copyright Information:GeoRef, Copyright 2020 American Geosciences Institute.
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100 1 |a Dong, Y.  |u University of Illinois at Urbana-Champaign, Institute for Genomic Biology, Urbana, IL 
245 1 0 |a Fe-oxide grain coatings support bacterial Fe-reducing metabolisms in 1.7-2.0 km-deep subsurface quartz arenite sandstone reservoirs of the Illinois Basin (USA) 
300 |a Article no. 511 
500 |a In English. 50 refs. 
500 |a Key title: Frontiers in Microbiology 
500 |a Source note: Frontiers in Microbiology, Vol.5. Publisher: Frontiers Research Foundation, Lausanne, Switzerland. ISSN: 1664-302X 
500 |a Publication type: journal article 
504 |b 50 refs. 
510 3 |a GeoRef, Copyright 2020 American Geosciences Institute. 
520 |a The Cambrian-age Mt. Simon Sandstone, deeply buried within the Illinois Basin of the midcontinent of North America, contains quartz sand grains ubiquitously encrusted with iron-oxide cements and dissolved ferrous iron in pore-water. Although microbial iron reduction has previously been documented in the deep terrestrial subsurface, the potential for diagenetic mineral cementation to drive microbial activity has not been well studied. In this study, two subsurface formation water samples were collected at 1.72 and 2.02 km, respectively, from the Mt. Simon Sandstone in Decatur, Illinois. Low-diversity microbial communities were detected from both horizons and were dominated by Halanaerobiales of Phylum Firmicutes. Iron-reducing enrichment cultures fed with ferric citrate were successfully established using the formation water. Phylogenetic classification identified the enriched species to be related to Vulcanibacillus from the 1.72 km depth sample, while Orenia dominated the communities at 2.02 km of burial depth. Species-specific quantitative analyses of the enriched organisms in the microbial communities suggest that they are indigenous to the Mt. Simon Sandstone. Optimal iron reduction by the 1.72 km enrichment culture occurred at a temperature of 40°C (range 20-60°C) and a salinity of 25 parts per thousand (range 25-75 ppt). This culture also mediated fermentation and nitrate reduction. In contrast, the 2.02 km enrichment culture exclusively utilized hydrogen and pyruvate as the electron donors for iron reduction, tolerated a wider range of salinities (25-200 ppt), and exhibited only minimal nitrate- and sulfate-reduction. In addition, the 2.02 km depth community actively reduces the more crystalline ferric iron minerals goethite and hematite. The results suggest evolutionary adaptation of the autochthonous microbial communities to the Mt. Simon Sandstone and carries potentially important implications for future utilization of this reservoir for CO<2` injection. 
650 7 |a Arenite  |2 georeft 
650 7 |a Bacteria  |2 georeft 
650 7 |a Cambrian  |2 georeft 
650 7 |a Carbon dioxide  |2 georeft 
650 7 |a Carbon sequestration  |2 georeft 
650 7 |a Clastic rocks  |2 georeft 
650 7 |a Gas injection  |2 georeft 
650 7 |a Iron oxides  |2 georeft 
650 7 |a Metabolism  |2 georeft 
650 7 |a Microorganisms  |2 georeft 
650 7 |a Mount Simon Sandstone  |2 georeft 
650 7 |a Oxides  |2 georeft 
650 7 |a Paleozoic  |2 georeft 
650 7 |a Quartz arenite  |2 georeft 
650 7 |a Reservoir rocks  |2 georeft 
650 7 |a Sandstone  |2 georeft 
650 7 |a Sedimentary rocks  |2 georeft 
650 7 |a Site exploration  |2 georeft 
650 7 |a Upper Cambrian  |2 georeft 
651 7 |a Illinois  |2 georeft 
651 7 |a Illinois Basin  |2 georeft 
651 7 |a Macon County Illinois  |2 georeft 
651 7 |a United States  |2 georeft 
653 |a Decatur Illinois 
653 |a Firmicutes 
653 |a Halanaerobiales 
653 |a Vulcanibacillus 
700 1 |a Sanford, R.A. 
700 1 |a Locke, R.A. 
700 1 |a Cann, I.K. 
700 1 |a Mackie, R.I. 
700 1 |a Fouke, B.W. 
773 0 |t Frontiers in Microbiology  |d Lausanne : Frontiers Research Foundation, Sep. 2014  |x 1664-302X  |n Frontiers in Microbiology, Vol.5. Publisher: Frontiers Research Foundation, Lausanne, Switzerland. ISSN: 1664-302X  |g Vol. 5  |h illus., incl. 1 table 
856 |u urn:doi: 10.3389/fmicb.2014.00511