Regulation of Fe3+-oxide Formation Among Fe2+-oxidizing Bacteria |
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Authors: | Rachel E James Steven D Scott Danielle Fortin Ian D Clark F Grant Ferris |
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Institution: | 1. Department of Geology , University of Toronto , Toronto , Ontario , Canada;2. Department of Earth Sciences , University of Ottawa , Ottawa , Ontario , Canada |
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Abstract: | Helical stalks (resembling Gallionella ferruginea, Mariprofundus ferrooxydans) and filamentous sheaths (resembling Leptothrix ochracea) of Fe2+-oxidizing bacteria (FeOB) are mineralized by hydrous ferric oxides (HFO). To perform both inter-species and inter-site size comparisons of HFO particles on stalks and sheaths we measured HFO particles in samples of natural bacteriogenic iron oxides (BIOS) from 3 contrasting field sites: the Loihi Seamount (southern Hawaii); Äspö Hard Rock Laboratory (eastern Sweden); and Chalk River Laboratories (northern Canada) representing seafloor saline, underground brackish, and surface freshwater aqueous conditions. Ambient temperatures were in the psychrophilic range and pHs measured for Loihi, CRL, and Äspö were 5.6, 6.9 and 7.4, respectively. Dissolved Fe was lowest for CRL (0.2 mg · L?1) followed by Äspö (1.5 mg · L?1), then Loihi (4.5–14.9 mg · L?1). L. ochraceasheaths appear to have surface properties that restrict HFO particle growth in comparison to G.ferruginea-M.ferrooxydans stalks in the same environment, which we attribute to interfacial surface energy (γ). An inverse relationship between particle size and stalk/sheath length due to restrictions in reactive surface area was also observed, which may provide insight into FeOB survival strategies to alleviate oxidative stress arising from Fe3+ production. |
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Keywords: | Interfacial energy biomineralization groundwater iron-oxidizing bacteria subsurface microbiology |
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