Controls on Iron Reduction and Biomineralization over Broad Environmental Conditions as Suggested by the Firmicutes<i>Orenia metallireducens</i>Strain Z6

Dong, Yiran; Sanford, Robert A.; Boyanov, Maxim I.; Flynn, Theodore M.; O’Loughlin, Edward J.; Kemner, Kenneth M.; George, Samantha; Fouke, Kaitlyn E.; Li, Shuyi; Huang, Dongmei; Li, Shuzhen; Fouke, Bruce W.

doi:10.1021/acs.est.0c03853

Cited by 35 publications

(30 citation statements)

References 94 publications

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“…In addition to the presence/concentration of phosphate, other factors have been proposed to contribute to the formation of green rusts during Fe(III) oxide bioreduction, including the presence of other oxyanions (arsenate, silicate, molybdate, tungstate, etc.) [31,41]; the presence and nature of dissolved organic carbon (including humic substances and microbially produced extracellular polymeric materials) [31,33,38]; the species and population size of IRB [31][32][33]; the type and concentration of the electron donor [18,36,37]; the rate and extent of Fe(II) production [17,19,125]; the presence of electron shuttles [17]; the sorption of Fe(II) to the parent Fe(III) oxide [25]; the extent of aggregation of Fe(III) oxide particles [27]; Fe(III) oxide mineralogy (this study). Despite over 20 years of investigation, a definitive and comprehensive understanding of the key factor(s) and mechanisms of green rust formation during microbial Fe(III) oxide reduction remains elusive.…”

Section: Formation Of Green Rust As a Secondary Mineral During Fe(iii) Oxide Bioreductionmentioning

confidence: 99%

“…These phylogenetically diverse microorganisms couple the oxidation of an electron donor (organic compounds or molecular hydrogen, H 2 ) to the reduction of Fe(III) to Fe(II) [1][2][3][4][5][6][7][8][9][10][11][12][13][14][15]. The Fe(II), resulting from the microbial reduction of Fe(III) oxides, can be present as a broad range of Fe(II) species, including soluble and adsorbed Fe(II) and mineral phases containing structural Fe(II) (e.g., magnetite (Fe 3 O 4 ), siderite (FeCO 3 ), vivianite [Fe 3 (PO 4 ) 2 •8H 2 O], green rust, chukanovite [Fe 2 (OH) 2 CO 3 ], and Fe(II)-bearing clays) [16][17][18][19][20][21][22][23][24][25].…”

Section: Introductionmentioning

confidence: 99%

“…Many factors have been identified as contributing to the formation of specific Fe(II)bearing secondary minerals during the microbial reduction of Fe(III) oxides, including Fe(III) oxide mineralogy [19,25,26]; Fe(III) oxide particle aggregation [27]; the presence of electron shuttles [17]; the rate and extent of Fe(II) production [17,19,[28][29][30]; the extent of Fe(II) sorption on the parent Fe(III) oxide [25]; the species of IRB and the number of cells present [31][32][33]; the concentration and type of electron donor [34][35][36][37]; the type of organic matter present (including humic substances and microbially-produced extracellular polymeric materials) [31,33,38]; and the presence of phosphate and other oxyanions (silicate, molybdate, arsenate, etc.) [17,31,[39][40][41].…”

Section: Introductionmentioning

confidence: 99%

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Effects of Fe(III) Oxide Mineralogy and Phosphate on Fe(II) Secondary Mineral Formation during Microbial Iron Reduction

et al. 2021

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The bioreduction of Fe(III) oxides by dissimilatory iron-reducing bacteria may result in the formation of a suite of Fe(II)-bearing secondary minerals, including magnetite (a mixed Fe(II)/Fe(III) oxide), siderite (Fe(II) carbonate), vivianite (Fe(II) phosphate), chukanovite (ferrous hydroxy carbonate), and green rusts (mixed Fe(II)/Fe(III) hydroxides). In an effort to better understand the factors controlling the formation of specific Fe(II)-bearing secondary minerals, we examined the effects of Fe(III) oxide mineralogy, phosphate concentration, and the availability of an electron shuttle (9,10-anthraquinone-2,6-disulfonate, AQDS) on the bioreduction of a series of Fe(III) oxides (akaganeite, feroxyhyte, ferric green rust, ferrihydrite, goethite, hematite, and lepidocrocite) by Shewanella putrefaciens CN32, and the resulting formation of secondary minerals, as determined by X-ray diffraction, Mössbauer spectroscopy, and scanning electron microscopy. The overall extent of Fe(II) production was highly dependent on the type of Fe(III) oxide provided. With the exception of hematite, AQDS enhanced the rate of Fe(II) production; however, the presence of AQDS did not always lead to an increase in the overall extent of Fe(II) production and did not affect the types of Fe(II)-bearing secondary minerals that formed. The effects of the presence of phosphate on the rate and extent of Fe(II) production were variable among the Fe(III) oxides, but in general, the highest loadings of phosphate resulted in decreased rates of Fe(II) production, but ultimately higher levels of Fe(II) than in the absence of phosphate. In addition, phosphate concentration had a pronounced effect on the types of secondary minerals that formed; magnetite and chukanovite formed at phosphate concentrations of ≤1 mM (ferrihydrite), <~100 µM (lepidocrocite), 500 µM (feroxyhyte and ferric green rust), while green rust, or green rust and vivianite, formed at phosphate concentrations of 10 mM (ferrihydrite), ≥100 µM (lepidocrocite), and 5 mM (feroxyhyte and ferric green rust). These results further demonstrate that the bioreduction of Fe(III) oxides, and accompanying Fe(II)-bearing secondary mineral formation, is controlled by a complex interplay of mineralogical, geochemical, and microbiological factors.

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Section: Formation Of Green Rust As a Secondary Mineral During Fe(iii) Oxide Bioreductionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

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Effects of Fe(III) Oxide Mineralogy and Phosphate on Fe(II) Secondary Mineral Formation during Microbial Iron Reduction

et al. 2021

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“…Moreover, as absorption correction is not included in the STEM-EDS quantification, this analysis is likely to overestimate the Fe content, since higher energy Fe X-rays will be absorbed less strongly than the lower energy oxygen. Goethite and particularly lepidocrocite, can be susceptible to bioreduction 64, 65 , potentially remobilizing As. However, the crystalline “flakes” (developed after a longer incubation) were As deficient, in contrast to the amorphous spherical NPs, which retained more As, as shown by STEM-EDS analysis.…”

Section: Resultsmentioning

confidence: 99%

Elucidating Heterogeneous Iron Biomineralization Patterns in a Denitrifying As(III)-Oxidizing Bacterium: Implications for Arsenic Immobilization

Lopez-Adams¹,

Fairclough

Lyon³

et al. 2022

Preprint

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Anaerobic nitrate-dependent iron(II) oxidation is a process common to many bacterial species, which promotes the formation of Fe(III) minerals that can influence the fate of soil and groundwater pollutants, such as arsenic. Herein, we investigated simultaneous nitrate-dependent Fe(II) and As(III) oxidation by Acidovorax sp. strain ST3 with the aim of studying the Fe biominerals formed, their As immobilization capabilities and the metabolic effect on cells. X-ray powder diffraction (XRD) and scanning transmission electron microscopy (STEM) nanodiffraction were applied for biomineral characterization in bulk and at the nanoscale, respectively. NanoSIMS (nanoscale secondary ion mass spectrometry) was used to map the intra and extracellular As and Fe distribution at the single-cell level and to trace metabolically active cells, by incorporation of a 13C-labeled substrate (acetate). Metabolic heterogeneity among bacterial cells was detected, with periplasmic Fe mineral encrustation deleterious to cell metabolism. Interestingly, Fe and As were not co-localized in all cells, indicating delocalized sites of As(III) and Fe(II) oxidation. The Fe(III) minerals lepidocrocite and goethite were identified in XRD, although only lepidocrocite was identified via STEM nanodiffraction. Extracellular amorphous nanoparticles were formed earlier and retained more As(III/V) than crystalline flakes of lepidocrocite, indicating that longer incubation periods promote the formation of more crystalline minerals with lower As retention capabilities. Thus, the addition of nitrate promotes Fe(II) oxidation and formation of Fe(III) biominerals by ST3 cells which retain As(III/V), and although this process was metabolically detrimental to some cells, it warrants further examination as a viable mechanism for As removal in anoxic environments by biostimulation with nitrate.

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“…Microbial reduction of V(V) typically leads to the formation of V(IV) species (i.e., soluble complexes and various precipitates); however, reduction to V(III) has been reported [18,22,28]. In addition to direct microbial reduction of V(V), microbes can indirectly impact V speciation/mobility by altering the geochemical conditions of their environment, particularly microbes involved in the biogeochemical cycling of Fe and S. Microbial reduction of ferric iron (Fe(III)) can result in the formation of a broad range of Fe(II) species including mineral phases containing structural Fe(II) (e.g., magnetite (Fe 3 O 4 ) , siderite (FeCO 3 ), vivianite [Fe 3 (PO 4 ) 2 •8H 2 0], green rust (a mixed Fe(II)/Fe(III) layered double hydroxide), and chukanovite [Fe 2 (OH) 2 CO 3 ]) [41][42][43][44][45][46][47][48][49][50][51]. Likewise, microbial reduction of oxidized S species such as sulfate, sulfite, and thiosulfate, and S(0), results in the production of sulfide, and its subsequent reaction with Fe(II) leads to the formation of insoluble ferrous sulfides such as mackinawite (FeS), greigite (Fe 3 S 4 ), pyrite (FeS 2 ), and pyrrhotite (Fe (1-x) S (x = 0 to 0.2)) [52][53][54][55][56][57][58].…”

Section: Introductionmentioning

confidence: 99%

Reduction of Vanadium(V) by Iron(II)-Bearing Minerals

2021

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Fe(II)-bearing minerals (magnetite, siderite, green rust, etc.) are common products of microbial Fe(III) reduction, and they provide a reservoir of reducing capacity in many subsurface environments that may contribute to the reduction of redox active elements such as vanadium; which can exist as V(V), V(IV), and V(III) under conditions typical of near-surface aquatic and terrestrial environments. To better understand the redox behavior of V under ferrugenic/sulfidogenic conditions, we examined the interactions of V(V) (1 mM) in aqueous suspensions containing 50 mM Fe(II) as magnetite, siderite, vivianite, green rust, or mackinawite, using X-ray absorption spectroscopy at the V K-edge to determine the valence state of V. Two additional systems of increased complexity were also examined, containing either 60 mM Fe(II) as biogenic green rust (BioGR) or 40 mM Fe(II) as a mixture of biogenic siderite, mackinawite, and magnetite (BioSMM). Within 48 h, total solution-phase V concentrations decreased to <20 µM in all but the vivianite and the biogenic BiSMM systems; however, >99.5% of V was removed from solution in the BioSMM and vivianite systems within 7 and 20 months, respectively. The most rapid reduction was observed in the mackinawite system, where V(V) was reduced to V(III) within 48 h. Complete reduction of V(V) to V(III) occurred within 4 months in the green rust system, 7 months in the siderite system, and 20 months in the BioGR system. Vanadium(V) was only partially reduced in the magnetite, vivianite, and BioSMM systems, where within 7 months the average V valence state stabilized at 3.7, 3.7, and 3.4, respectively. The reduction of V(V) in soils and sediments has been largely attributed to microbial activity, presumably involving direct enzymatic reduction of V(V); however the reduction of V(V) by Fe(II)-bearing minerals suggests that abiotic or coupled biotic–abiotic processes may also play a critical role in V redox chemistry, and thus need to be considered in modeling the global biogeochemical cycling of V.

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Controls on Iron Reduction and Biomineralization over Broad Environmental Conditions as Suggested by the FirmicutesOrenia metallireducensStrain Z6

Cited by 35 publications

References 94 publications

Effects of Fe(III) Oxide Mineralogy and Phosphate on Fe(II) Secondary Mineral Formation during Microbial Iron Reduction

Effects of Fe(III) Oxide Mineralogy and Phosphate on Fe(II) Secondary Mineral Formation during Microbial Iron Reduction

Elucidating Heterogeneous Iron Biomineralization Patterns in a Denitrifying As(III)-Oxidizing Bacterium: Implications for Arsenic Immobilization

Reduction of Vanadium(V) by Iron(II)-Bearing Minerals

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