Dependence of Secondary Mineral Formation on Fe(II) Production

Mar 6, 2018 - Iron is the most abundant redox-active metal in the Earth's crust, and ..... Hence, the order of formation rates of magnetite as the fin...
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Dependence of Secondary Mineral Formation on Fe(II) Production from Ferrihydrite Reduction by Shewanella oneidensis MR-1 Rui Han, Tongxu Liu, Fangbai Li, Xiaomin Li, Dandan Chen, and Yundang Wu ACS Earth Space Chem., Just Accepted Manuscript • DOI: 10.1021/ acsearthspacechem.7b00132 • Publication Date (Web): 06 Mar 2018 Downloaded from http://pubs.acs.org on March 6, 2018

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Dependence of Secondary Mineral Formation on Fe(II) Production from

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Ferrihydrite Reduction by Shewanella oneidensis MR-1

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Rui Han,a,b Tongxu Liu,a,* Fangbai Li,a Xiaomin Li,a,c Dandan Chena, and Yundang Wua

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a

Guangdong Institute of Eco-environmental Science & Technology, Guangdong Key Laboratory of Integrated Agro-environmental Pollution Control and Management, Guangzhou 510650, China

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b

College of Marine Technology and Environment, Dalian Ocean University, Dalian 116023, China

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The Environmental Research Institute, MOE Key Laboratory of Theoretical Chemistry of Environment,

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South China Normal University, Guangzhou 510006, China

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*

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E-mail address: [email protected] (T.X.Liu)

Corresponding author. Tel.: +86 20 37021396.

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ACS Earth and Space Chemistry

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(Re-submitted March, 2018)

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1

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ABSTRACT: Although dissimilatory iron reduction and secondary mineral formation by

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Shewanella oneidensis MR-1 have been widely recognized, questions remain about the effects

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of biogenic Fe(II) on the rate and extent of secondary mineral formation and the importance

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of biogenic Fe(II)-induced crystallization processes. In this study, we investigated the effects

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of different mutants of MR-1 on the bioreduction and mineralization of ferrihydrite. The

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results indicate that while the reduction rates of ferrihydrite by ∆mtrD, ∆mtrF, and ∆omcA are

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similar to that of the wild type (WT), the capacity to reduce ferrihydrite decreased

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dramatically in the mutants ∆cymA and ∆mtrA. The order for Fe(III) reduction by MR-1 WT

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and mutants was ranked as follows: WT ≈ ∆mtrD ≈ ∆mtrF >∆omcA > ∆mtrC > ∆cymA >

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∆mtrA. Secondary minerals of ferrihydrite were characterized using X-ray diffraction, Fourier

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transform infrared spectra, and scanning electron microscopy. The results show that goethite

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and hematite were the main secondary minerals formed during the first two days in all

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treatments, and then magnetite appeared in the WT, ∆mtrD, ∆mtrF and ∆omcA treatments,

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while magnetite began to appear from the sixth day onwards in the ∆mtrC treatment.

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However, no magnetite was observed during the six days in the ∆mtrA and ∆cymA incubation

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treatments. The plausible electron transfer pathways of bioreduction and phase transformation

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were also verified using thermodynamic calculations of elementary reactions. This study

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clarified the importance of Fe(II) production in secondary mineral formation processes and

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highlighted the significance of biogenic Fe(II)-catalyzed crystallization. This information may,

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in turn, help us to better understand natural microbe−mineral interaction processes.

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KEYWORDS: Biotransformation; ferrihydrite; mutant; Shewanella oneidensis MR-1;

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extracellular electron transfer.

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1. INTRODUCTION

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Iron is the most abundant redox-active metal in the Earth’s crust, and iron-bearing minerals

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are ubiquitous reactive constituents of aquifers, soils, and sediments. Dissimilatory Fe(III)

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reduction is widely observed in natural systems (aquatic sediments, soils, and subsurface

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environments) and has major impacts on iron geochemistry, the fate of trace metals and

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nutrients, and the degradation of organic matter.1 Dissimilatory iron-reducing bacteria (DIRB)

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can reduce Fe(III) to Fe(II) under anoxic conditions relying on hydrogen or the oxidation of

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organic matter to obtain energy for maintenance and cell growth.2,3 A wide phylogenetic

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diversity of microorganisms, including archaea and bacteria, are capable of dissimilatory

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Fe(III) reduction. Of all the identified strains of DIRB, Geobacter and Shewanella are by far

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the most extensively investigated.4

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Iron exists predominantly in an insoluble solid phase (e.g., ferrihydrite, goethite, and

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hematite) in the environment under circumneutral pH conditions.4 Shewanella oneidensis

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MR-1 (MR-1) has two main pathways of extracellular electron transfer (EET): (i) to directly

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transfer electrons from outer membrane (OM)-bound cytochromes and porin-cytochrome

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complexes toward iron oxides, or along organic appendages named “nanowires,” which are

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extensions of the outer membrane and periplasm produced by MR-1 5; (ii) to use endogenous

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organic molecules (e.g., flavin or riboflavin mononucleotides) as electron shuttles that diffuse

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in the medium and mediate EET; thus, DIRB must pump electrons from the internal

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cytoplasmic membrane to iron oxides located outside the cell.6 To overcome this physical

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barrier, MR-1 developed a pathway (i.e., Mtr) that requires multihaem c-type cytochromes

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(c-Cyts) for transferring electrons from the inner membrane via the periplasm and OM to

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external minerals.7,8 Electron transport proteins of the Mtr pathway include multihaem c-Cyts

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(CymA, MtrA, MtrC, OmcA, and a porin-like OM protein MtrB).7,8 The roles of these

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proteins in the electron transfer process have been documented as follows: CymA is an inner 3

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membrane-anchored quinol dehydrogenase that oxidizes quinol in the inner membrane and

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transfers the released electrons to the periplasmic MtrA; MtrA delivers electrons to the

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OM-anchored MtrC and OmcA, which can directly reduce solid metal (hydr)oxides.9-12 For

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most Shewanella members, the EET process is generally performed by an MtrCAB complex.

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Biochemical characterization of this complex indicates that MtrB functions as a

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trans-membrane sheath into which both MtrC and MtrA are partially inserted. 8,13,14 MtrF,

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MtrD, and MtrE are the homologues of MtrC, MtrA, and MtrB, respectively. MtrF, MtrD, and

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MtrE are thought to form an OM-spanning complex, namely MtrFDE, which has the same

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overall structure as MtrCAB but only makes a minor contribution to the process of iron

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reduction.15 Despite progress in understanding the key proteins in the Mtr pathway via

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mutants and purified proteins,10,15-18 there is a critical need to quantify the roles of these

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proteins in EET to iron minerals owing to their implications for biogeochemical redox

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processes. Therefore, it is necessary to further investigate the effects of key proteins and their

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homologues on the kinetics of iron reduction by wild type (WT) and mutants of MR-1.

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Poorly crystalline hydrous ferric oxides (e.g., ferrihydrite), which commonly exist in soils

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and sediments, are thermodynamically unstable and, with time, transform to more crystalline

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Fe(III)-oxides, e.g., goethite and/or hematite,19 resulting in a loss of ability to scavenge other

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trace metals from solution.20 Ferrihydrite is considered the most (bio)available Fe(III)

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(hydr)oxide for DIRB, and electron transfer proteins from Shewanella play an important role

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in the extracellular reduction of ferrihydrite, followed by biomineralization. Previous studies

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have focused on the factors influencing secondary mineralization, such as iron reduction rates,

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electron donor/acceptor concentrations, cell density, pH, and redox potential.19,21,22

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Although the roles of some OM c-Cyts (MtrC and OmcA) have been documented with regard

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to biomineralization of ferrihydrite by MR-1,23 questions still remain about the relationship

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between the rate of iron bioreduction and the extent of secondary mineral formation, and the 4

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importance of Fe(II)-compounds as catalysts in these chemical processes.24

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In this study, MR-1 was selected because it is a DIRB that is well known for its abilities to

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use a variety of iron oxides and oxyhydroxides as terminal electron acceptors.25 The

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objectives of this study were to examine the rates of Fe(III) reduction and the concomitant

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secondary mineral formation by wild type and mutants of MR-1, with implications for

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quantifying the effects of biogenic Fe(II) production on the rates and extents of secondary

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mineral formation in the dissimilatory iron reduction processes of ferrihydrite.

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2. MATERIALS AND METHODS

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2.1. Materials. MR-1 wild type (WT) that had been isolated from anoxic sediments from

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Lake Oneida, NY26 was purchased from MCCC (Marine Culture Collection of China, China).

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All mutant-deletion strains ∆mtrA, ∆mtrC, ∆mtrD, ∆mtrF, ∆omcA, and ∆cymA were provided

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by Professor Gao Haichun from Zhejiang University, as documented in previous studies.

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8,15,27,28

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98%). Piperazine-N–N-bis-2-ethanesulfonic acid (PIPES) was purchased from J&K Chemical

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(Beijing, China). Lactate was purchased from Sinopharm Chemical Reagent Co., Ltd.

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(Shanghai, China). Other chemicals were purchased from Guangzhou Chemical Reagent

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Factory (Guangzhou, China). All solutions were prepared using Milli-Q deoxygenated

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ultrapure water (18 MΩ cm, EASYpure II RF/UV, USA).

All chemicals were of analytical reagent grade and the highest available purity (≥

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2.2. Preparation of ferrihydrite. Ferrihydrite was synthesized by neutralizing 0.4 mM

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FeCl3·6H2O with 1 mM NaOH in a high-density polyethylene container.29 Firstly, aqueous

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solutions of 0.4 mol L-1 FeCl3·6H2O and 1 mol L-1 NaOH were prepared. Then the FeCl3

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solution was stirred intensely and evenly while the NaOH solution was trickled steadily into it.

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As the circumneutral pH approached, the NaOH solution was added more slowly, and

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a thick red slurry of ferrihydrite formed. At pH 7.0, the slurry was allowed to ripen for 2–6 h, 5

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with a slight decrease in pH (usually < 1 pH unit). The slurry was adjusted back to pH 7.0 and

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centrifuged at 3 600 g for 20 min at 4 °C. After decanting the supernatant, the solid was

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re-suspended, washed with Milli-Q water, and centrifuged again. This procedure was repeated

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seven times to reduce the residual chloride content to less than 1 mM. The slurry was then

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kept in Milli-Q water prior to use.30

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2.3. Biotransformation of ferrihydrite by wild type and mutants of MR-1. MR-1 WT

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and various mutant cells (∆mtrA, ∆mtrC, ∆mtrD, ∆mtrF, ∆omcA, and ∆cymA) were grown

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aerobically in a Luria-Bertani medium (10 g L-1 NaCl, 5 g L-1 yeast extract, 10 g L-1 tryptone)

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at 30 °C with shaking at 180 rpm. When approaching the exponential phase, cells were

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harvested by centrifuging at 7 000 g at 4 °C for 10 min. The pellets were then washed three

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times and re-suspended in 30 mM PIPES buffer at pH 7.0 ± 0.2. The Fe(III) reduction

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medium contained 30 mM PIPES (pH 7.0 ± 0.2) as a buffer, 50 mM ferrihydrite as the sole

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electron acceptor, and 20 mM lactate as the sole electron donor. The bacterial concentration in

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each treatment was OD600nm = 1.0, and the number of bacterial cells (wild and mutants) for an

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OD600nm = 1.0 were measured using the DAPI staining method.31 Growth curves of the

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bacterial cells (wild and mutants) were plotted using the method outlined in Supporting

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Information, and the total protein contents of wild type and mutants at OD600nm = 1.0 were

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measured. An experimental group without bacteria was used as a control. The pH was also

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maintained at approximately 7.0 ± 0.2 using 30 mM PIPES. The medium was dispensed into

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100-mL serum bottles purged with O2-free N2 for at least 30 min, capped with butyl rubber

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closures, and crimp sealed. All anaerobic media were sterilized by autoclaving at 121 °C for

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20 min and then cooled to room temperature in a Bactron Anaerobic/Environmental Chamber

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II (Shellab, Sheldon Manufacturing Inc., Cornelius, OR, USA) before use. Inoculation and

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sampling were conducted using sterile syringes and needles. All experiments were incubated

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in an anaerobic chamber in the dark at 30 °C. Three reactor bottles per treatment were taken 6

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out for analysis at the sampling intervals of 0, 1, 2, 3, and 6 d. 2.4. Analytical methods. The total Fe(II) concentration was determined by extracting Fe(II)

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from the suspensions using 0.5 M HCl for 1.5 h32 and assaying the extract using the

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1,10-phenanthroline colorimetric method at 510 nm on a UV−Vis spectrophotometer

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(TU-1810PC, Beijing Purkinje General Instruments, China). Standard curves were made

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using ammonium ferrous sulfate dissolved in 0.5 M hydrochloric acid. The mineral samples

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were collected from the incubations by filtration inside the anaerobic chamber. Samples were

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filtered onto 0.22 µm filters (VCTP Millipore Isopore), washed twice with deoxygenated

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double deionized (DDI) water, and dried in the anaerobic chamber. The dry minerals were

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then characterized. The X-ray diffraction (XRD) patterns of powder samples before and after

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reactions were recorded on a Bruker Advance Diffractometer (Bruker Co., USA) at room

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temperature, operating at 40 kV and 40 mA, using Cu Kα radiation (λ = 0.15418 nm). Data

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were acquired in the range of 15° to 70°, using a step of 0.04°. The phases were identified by

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comparing diffraction patterns with those on standard powder XRD cards compiled by the

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Joint Committee on Powder Diffraction Standards (JCPDS).33 Fourier transform infrared

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spectroscopy (FTIR) was recorded using an FTIR spectrometer (Perkin−Elmer, model Vector

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33, Bruker Co., USA) at room temperature. The morphology was investigated by scanning

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electron microscopy, and the samples were dispersed onto carbon-coated Cu grids in the

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anaerobic chamber. SEM images were obtained using field-emission scanning electron

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microscopy (LEO1530VP, Zeiss, Germany).

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3. RESULTS AND DISCUSSION

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3.1. Effect of mutants on bioreduction of ferrihydrite. The kinetics of Fe(II) generation

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during ferrihydrite reduction by WT and mutants are shown in Figure 1a. While no Fe(II) was

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generated in the ferrihydrite control without MR-1, the presence of MR-1 WT and mutants 7

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obviously stimulated Fe(II) generation, indicating that the reduction of ferrihydrite to Fe(II)

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occurred via a biological reaction. Fe(II) generation by WT increased quickly to ~ 4 mM in

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the first two days and then decreased gradually to ~2.8 mM at the end of incubation (day 6).

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The Fe(II) generation by ∆mtrD and ∆mtrF was very close to that of WT. Fe(II) generation by

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∆omcA also increased at the beginning and then decreased, but the Fe(II) concentration was

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lower than that generated by WT, ∆mtrD, or ∆mtrF. Fe(II) generation by ∆mtrC, ∆cymA, and

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∆mtrA increased over time during the six days of incubation. To clearly illustrate Fe(II)

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generation rates of all the treatments, the zero-order reduction rates of Fe(II) generation

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during the increasing stage of the kinetic curves were calculated (Figure 1b). Because the

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concentration of Fe(II) in these systems decreases after two days due to the reaction between

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Fe(II) and ferrihydrite, production rates of Fe(II) in the WT and mutants without MtrD or

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MtrF were calculated using the data of the first two days. Compared to the Fe(II) production

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rate for WT (2.05 mM d-1), a slight decrease was observed for ∆mtrD (1.80 mM d-1) and

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∆mtrF (1.75 mM d-1); the rates for other mutants decreased substantially, by 64.9%, 77.1%,

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88.3%, and 93.7% for ∆omcA, ∆mtrC, ∆cymA, and ∆mtrA, respectively. Therefore, the order

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for the capacity of reducing ferrihydrite by MR-1 WT and mutants was ranked as follows: WT

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≈ ∆mtrD ≈ ∆mtrF > ∆omcA > ∆mtrC > ∆cymA > ∆mtrA, indicating their roles in controlling

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the electron transfer pathway. The initial cell number at OD600 nm = 1.0 added in all treatment

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groups (Figure 1c) was not identical for each strain of MR-1. WT had an initial cell number of

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2.35×109 which is 2.35 times and 4.7 times more than those of the ∆mtrA and ∆cymA

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treatments, respectively. The total protein contents of WT and mutants at OD600nm = 1.0

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(Figure S2) were consistent with the cell numbers in Figure 1c, thus the initial cell numbers

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were different. To clearly differentiate the effects of gene deletion and quantitative variation

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of cells used in Fe(III) oxide reduction, the cell numbers in Figure 1c were used to calibrate

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the rates in Figure 1b. The calibrated rates in Figure S3 for various treatments with WT and 8

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mutants are consistent with the original rates for Fe(II) production in Figure 1b. The above

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results indicated that the knock outs of different electron transfer proteins influenced the cell

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numbers of bacteria, and also affected the reduction rate of ferrihydrite and the secondary

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mineral formation.

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3.2. Effect of mutants on secondary mineral formation. The mineralogy of ferrihydrite

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changed along with ferrous release during the bioreduction processes, which was indicated by

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visible color changes of the incubated suspension (inserts of Figure 2). After six days of

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incubation, the color of the ferrihydrite suspension was dark red after reacting with ∆cymA,

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∆mtrA, and ∆mtrC, while those with WT, ∆mtrD, ∆mtrF and ∆omcA had turned black. The

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different colors of the reaction suspensions might be attributed to different secondary

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minerals.34

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Morphology. The samples were examined using SEM techniques to identify the changes in

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surface morphology of the solid phases during ferrihydrite reduction by WT and mutants. The

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ferrihydrite image showed a smooth flat surface (Figure 2a), which might be attributed to an

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aggregation of the tiny ferrihydrite particles after the drying processes. After incubation with

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MR-1 WT and mutants, large particles formed with a wide range of particle sizes between 20

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nm and 200 nm (Figure 2b-h). It was apparent that the particle sizes of minerals with WT,

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∆mtrD, ∆mtrF, and ∆omcA were much smaller than those with ∆mtrC, ∆cymA and ∆mtrA.

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The difference in particle sizes was similar to that of the iron reduction rates. Since the

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particle sizes during microbial mineralization might be determined by the mineral

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components, crystallization conditions, and the location relatively to the cells, the single SEM

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images did not provide crucial information for the secondary minerals except the surface

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morphology of the overall mixtures with cells and minerals. Therefore, specific differences of

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the secondary minerals were further characterized by FTIR and XRD as discussed below.

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Crystal structures. The solid samples of ferrihydrite before and after reduction by MR-1 9

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WT and mutants were further examined by FTIR. For the control treatment with ferrihydrite

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alone, the FTIR patterns of ferrihydrite remained unchanged, as no bioreduction or

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biomineralization occurred during the six-day incubation. The major peaks at 590 cm-1, 1040

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cm-1, 1120 cm-1, and 1175 cm-1 (Figure 3a) represent the characteristic peaks of ferrihydrite.34

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After reduction of ferrihydrite by MR-1 WT and mutants, the peaks for ferrihydrite changed

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by differing amounts (Figure 3b-h). Specifically, while the peaks for ferrihydrite at 1120 cm-1

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and 1175 cm-1 for WT, ∆mtrD, and ∆mtrF nearly disappeared after six days of incubation, the

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intensity of these peaks for the other mutants were only slightly lower. Two sharp peaks at

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797 cm-1 and 887 cm-1 appeared in all the treatments with MR-1 and were ascribed to the

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Fe–OH bond of goethite.35 It can also be seen that the peak at 590 cm-1 shifted to 564 cm-1 for

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the treatments with WT, ∆mtrD, ∆mtrF, and ∆omcA, which may be attributed to the Fe–O

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bond of magnetite.36 These results indicate that ferrihydrite was gradually reduced and

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transformed by WT and mutants over time, followed by the formation of goethite and

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magnetite.

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Microbial reduction of ferrihydrite was followed by recrystallization processes and

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formation of more crystalline iron (hydr)oxides.34 The XRD patterns of minerals in the

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control treatment of ferrihydrite showed no obvious diffraction peaks owing to its amorphous

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structure that remained unchanged over the six-day incubation (Figure 4a). For MR-1 WT or

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mutants, new diffraction peaks appeared, and their relative intensities changed over time

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(Figure 4b-h). After comparing those peaks with JCPDS cards, the newly formed crystal

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structures were found to include goethite (No. 29-0713), hematite (No. 33-0664), and

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magnetite (No. 19-0629). Goethite (2θ = 33.2°) and hematite (2θ = 35.7°, 54.1°, 62.4°, 64.0°)

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were the main forms of secondary minerals in the first two days for all the treatments with

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MR-1. For WT, ∆mtrD, ∆mtrF and ∆omcA, magnetite (2θ = 33.2°, 43.2°, 57.1°, 62.5°) began

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to appear on the third day, followed by a gradual disappearance of hematite, and then 10

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magnetite became the main form on the sixth day. For ∆omcA and ∆mtrC, magnetite began to

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appear on the fourth day and the sixth day, respectively. For ∆mtrA and ∆cymA, only hematite

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and goethite were observed, with no magnetite observed during the six-day incubation.

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Equal amounts of ferrihydrite were used as the starting materials and all the samples were

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characterized at the same time. Thus, the relative contents of all the minerals can be compared

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according to the diffraction peaks and the kinetics of each mineral can be estimated from the

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changes of the peak intensities over time. The relative peak areas of goethite (2θ = 33.2o),

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magnetite (2θ = 62.5o) and hematite (2θ = 35.7o) were plotted as a function of incubation time

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(Figure 5). For goethite, the peak areas of all treatments with MR-1 WT and mutants

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increased with incubation time (Figure 5a). During the first day, the order of goethite

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formation amounts was similar to that for Fe(II) production in Figure 1b. The peak areas for

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∆mtrA, ∆mtrC and ∆cymA on the sixth day were slightly higher than those of WT, ∆mtrD,

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∆mtrF and ∆omcA. The changing trend for hematite was opposite to that for goethite with all

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the treatments. The peak intensities of hematite (2θ = 35.7°) in the treatments of WT, ∆mtrD,

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∆mtrF and ∆omcA on the sixth day were slightly higher than those of ∆mtrA, ∆mtrC and

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∆cymA (Figure 5b). Meanwhile, the peak of magnetite (2θ = 57.1°) appeared and increased as

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the reaction proceeded, indicating that the minerals were transformed into magnetite from the

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third day of reaction. Since goethite are just intermediate mineral products, the order of

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formation of goethite in the following days was not well matched with that of Fe(II)

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production. For magnetite (Figure 5c), diffraction peaks began to appear on the second day

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for WT, ∆mtrD, and ∆mtrF; the third day for ∆omcA; and the fourth day for ∆mtrC. No

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magnetite peaks were observed for ∆mtrA and ∆cymA over the six days of incubation. Hence,

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the order of formation rates of magnetite as the final mineral product was consistent with

269

Fe(II) production.

270

3.3. Thermodynamics of bioreduction and biomineralization. The above experimental 11

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results clearly indicate that Fe(II) generation can occur via bioreduction processes and iron

272

(oxyhdr)oxides formation via re-crystallization. These bioreduction processes were identified

273

as enzymatic reactions between outer membrane c-type cytochromes (OM c-Cyts) and iron

274

(oxyhdr)oxides; the re-crystallization processes may be induced by biogenic Fe(II) or direct

275

enzymatic reactions. To examine the specific reactions occurring during the bioreduction and

276

biomineralization processes, the thermodynamics of all possible reactions were calculated

277

according to the reported values of various species and minerals involved in the

278

biotransformation processes (Table 1).

279

The starting mineral, ferrihydrite, can be reduced by MR-1, as may the secondary minerals.

280

The reduced product was usually free ferrous (Fe2+); the Fe(II)-containing mineral (Fe3O4)

281

was also observed via XRD and FITR characterization. Hence, the half reactions for all

282

possible bioreduction processes with Fe2+ and Fe3O4 as reduced products are summarized as

283

Rxns. 1 – 4 in Table 2. As free energy or chemical potential is the driving force of the

284

reactions, the standard free energy change ( ∆G 0r ) of the half reaction for iron reduction was

285

calculated with Eq. 1 based on the total free energies of formation of the products ( ∆G 0f products )

286

and reactants ( ∆G 0f reactants ) in Table 1,

287

∆G 0r = ∑ ∆G f0 products − ∑ ∆G 0f reactants

(1)

288

where ∆G 0r for the hydrogen half-cell is zero, ∆G 0r for the electrons cancels out, and the

289

unit is KJ mol-1.

290

The results in Table 2 indicate that the ∆G 0r values for all the reactions with Fe2+ as

291

reduced products are ranked as α-FeOOH > am-FeOOH > α-Fe2O3 > Fe3O4. In the

292

bioreduction system, more negative ∆G 0r values may reflect greater difficulty in iron

293

reduction reactions with MR-1. Regarding the formation processes of secondary minerals, it

294

was noted that am-FeOOH, α-FeOOH, and α-Fe2O3 were all Fe(III) minerals, implying that 12

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non-redox reactions among them may directly induce phase transformation. In addition, the

296

biogenic Fe(II) and Fe(III) minerals (am-FeOOH, α-FeOOH, and α-Fe2O3) may also combine

297

with each other via non-redox reactions by forming Fe(III)−Fe(II) mixed minerals (Fe3O4).

298

These reactions are written according to the mass balance law as Rxns. 5 – 10 in Table 3. It

299

has been reported that ferrihydrite is thermodynamically metastable and transforms into the

300

more-crystalline products goethite and hematite via a long-term aging process.42 Therefore, it

301

is essential to clarify whether the aging processes of iron (oxyhydr)oxides plays a role in

302

biomineralization processes. The ∆G 0r values of the non-redox reactions for phase

303

transformation were calculated based on Eq. 1. The ∆G 0r values for Rxns. 5 and 6

304

(am-FeOOH and α-FeOOH) in Table 4 were lower than zero, indicating that the reactions of

305

am-FeOOH → α-FeOOH and am-FeOOH→ α-Fe2O3 may spontaneously occur, though they

306

may be very slow.42 The reaction α-FeOOH→ α-Fe2O3 (Rxn. 7), and all three reactions

307

between Fe2+ and iron (oxyhydr)oxides (Rxns. 8 – 10) are not thermodynamically favorable

308

via non-redox reactions, and it was supported that the transformation from goethite to

309

hematite only occurred under heating at about 250 oC.43,44

310

Recently, the Fe(II)-catalyzed phase transformation of iron (oxyhydr)oxides to more

311

crystalline forms has attracted much attention from geochemists owing to the wide

312

implications for both geochemistry and contaminant mobilization.45 Fe(II) is generated from

313

bioreduction processes, and biogenic Fe(II) may also induce the phase transformation of iron

314

(oxyhydr)oxides. Based on thermodynamic calculations (Rxns. 7 – 10), direct transformation

315

via non-redox reactions should be unfeasible, but recent observations45 imply that an

316

“induction period” is associated with the reorganization of highly disordered surfaces, and

317

reactive intermediates were responsible for atom-exchange and feasible electron transfer,

318

finally resulting in the phase transformation of iron (oxyhydr)oxides. Based on this

319

mechanism, reactions involving reactive intermediates are listed in Table 4. The elementary 13

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320

reaction can be written as Rxns. 11 – 13. The first step (Rxn. 11) is surface complexation with

321

the formation of the reactive intermediate (≡Fe(III)OFe(II)+). The second step (Rxn. 12) is the

322

internal electron transfer to another Fe(III) atom in the structure, forming ≡Fe(II)OFe(III)+. In

323

the third step (Rxn. 13), the “new” Fe(II) is eventually released into solution via desorption,

324

and the “new” Fe(III) in the structure becomes a more-crystalline (oxyhydr)oxide. In a similar

325

way, phase transformations to goethite, hematite, and magnetite can be proposed as Rxns. 14

326

– 17.

327

3.4 Roles of proteins in ferrihydrite reduction. Based on experimental results and the

328

thermodynamics of iron reduction and mineralization, the roles of all proteins in the Mtr

329

pathway for bioreduction and biomineralization of ferrihydrite are proposed in Figure 6.

330

Because CymA is an inner-membrane quinol dehydrogenase that transfers electrons to

331

MtrA,8,16,46 the deletion of cymA may significantly lower electron output from the menaquinol

332

pool to the periplasm,9 resulting in a substantial decrease (88.3%) of ferrihydrite reduction

333

activity (Figure 1b). MtrA is a soluble decaheme c-Cyts localized in the periplasm and

334

associated with the outer membrane that accepts electrons from CymA and donates electrons

335

to OmcA, MtrC, or MtrF.47-49 Thus, a lack of MtrA could lead to a deficiency in electron

336

transfer from CymA to OM c-Cyts, resulting in the observed decrease (93.7%) in ferrihydrite

337

reduction activity (Figure 1b). These results also imply that the presence of inner-membrane

338

CymA and periplasmic MtrA is essential for electron transfer to ferrihydrite reduction by

339

MR-1.

340

Both MtrC and OmcA are lipoproteins inserted in the OM that are partially exposed to the

341

extracellular environment.50-52 They accept electrons from MtrA and donate electrons to the

342

extracellular terminal electron acceptors including iron oxides.13,47 The deletion of mtrC or

343

omcA only partially inhibited the ferrihydrite reduction, indicating that MtrA could donate

344

electrons to alternative functional proteins to complete the electron transfer to ferrihydrite,27 14

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345

so it is reasonable to infer that the lack of OmcA retards, but does not completely inhibit,

346

biotransformation processes. The reduction rate by ∆mtrC was lower than that by ∆omcA

347

(Figure 1b), suggesting that MtrC is more efficient in the electron transfer pathways for

348

ferrihydrite reduction by MR-1, which may be because the level of OmcA in a whole cell of

349

MR-1 (8×10-20 moles) is lower than that of MtrC (1.2×10-19 moles).17 However, the Fe(II)

350

concentration in the ∆omcA treatment during the bioreduction of ferrihydrite may be

351

underestimated (Figure 1a and Figure 5c) since increased production of magnetite may fix

352

more Fe(II) ions during the ∆omcA treatment than the ∆mtrC treatment.

353

MtrF and MtrD are homologous components of MtrC and MtrA, respectively, and the rates

354

of iron reduction and final product (magnetite) generation for ∆mtrD and ∆mtrF were close to

355

that for WT, so the deletion of mtrF and mtrD only had a minor influence on the bioreduction

356

and biomineralization processes of ferrihydrite. Similar results were also found in the

357

reduction of Fe(III) minerals by Geobacter sulfurreducens.53 Although MtrD and MtrF have

358

structures that are similar to those of MtrA and MtrC, respectively,54,55 MtrD and MtrF did

359

not play a key role in ferrihydrite reduction in the presence of MtrA and MtrC.27

360

3.5 Importance of Fe(II) production to secondary mineral formation. Regarding

361

secondary mineral formation from ferrihydrite, two processes might influence this pathway.

362

Firstly, Fe(II) generated and released through dissimilatory iron reduction of ferrihydrite

363

might be adsorbed to the surface of ferrihydrite, leading to precipitation and re-crystallization

364

and resultant changes in mineral structures.36 Secondly, microorganisms can be directly

365

involved in the transformation of minerals via enzymatic iron reduction and re-crystallization

366

processes.34,56 From the current results of mineral characterization, goethite was generated

367

very quickly in the first two days as the primary mineral, which is consistent with a report

368

stating that goethite was the solid-phase product formed during the first day of dissimilatory

369

iron reduction of ferrihydrite by Shewanella putrefaciens strain CN32.21 As the reaction 15

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proceeded over time, magnetite became the primary biomineralization product. A similar

371

report investigating bioreduction of ferrihydrite by Shewanella putrefaciens strain CN32

372

demonstrated that magnetite was a stable end-product in PIPES-buffered media,57 whereas

373

hematite formed through internal-dehydration and rearrangement within the ferrihydrite

374

aggregates58; thus, hematite was found in all the treatments. The formation of hematite and

375

the transformation of hematite to magnetite may be due to direct effects of microorganisms on

376

minerals. The high efficiency of electron transfer from microorganism to the mineral surface

377

favored the transformation of hematite to magnetite. For ∆mtrA, ∆mtrC and ∆cymA with slow

378

iron reduction rates, goethite and hematite were the dominant secondary minerals. MtrA,

379

MtrC and CymA are key components of the Mtr pathway, and the combination complex

380

(CymA-MtrCAB) was found to be the most significant electron conduit in ferrihydrite

381

reduction by biomineralization with MR-1,8,16,46. Thus, knocking out either cymA or mtrA

382

leads to serious interruption of the overall electron transport chain,9 resulting in low levels of

383

electron transfer to ferrihydrite. MtrC plays a critical role in iron reduction through either a

384

direct mechanism involving electron transport or in conjunction with OmcA.50 Knocking out

385

mtrC caused the loss of the most effective pathway for electron transmission to the outside,

386

which greatly weakened the electron transport ability. Therefore, highly efficient electron

387

transport ability is the key factor controlling the bioreduction of ferrihydrite. The results of

388

Fe(II) production presented in Figure 1 and the results of secondary mineral formation shown

389

in Figure 5 indicate that the higher Fe(II) production with WT, ∆mtrF and ∆mtrD led to

390

higher formation rates of secondary minerals (goethite, hematite, and magnetite), while those

391

treatments with lower Fe(II) production showed lower formation rates of secondary minerals.

392

Therefore, the rates and extents of secondary mineral formation appear to be strongly

393

dependent on the amounts of Fe(II) produced from the bioreduction of ferrihydrite.

394

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4. CONCLUSION

396

Various MR-1 mutants were investigated regarding ferrihydrite reduction and secondary

397

mineral formation. High reduction rates were well-correlated with the rate and extent of

398

secondary mineral formation. CymA-MtrCAB-ferrihydrite is the dominant electron transfer

399

pathway of ferrihydrite reduction and Fe(II) production, resulting in higher rates and extents

400

of secondary mineral formation. After knocking out the three key electron transfer proteins,

401

electron output capacity was weakened, resulting in a retardation of the ferrihydrite reduction

402

rate and the rate and extent of secondary mineral formation. Other proteins (i.e., MtrDEF) had

403

little contribution to the overall processes of ferrihydrite reduction and secondary mineral

404

formation. The thermodynamic feasibility of bioreduction and phase transformation was

405

calculated based upon the free energies and chemical potentials of elementary reactions and

406

redox couples. This study provides a systematic and quantitative understanding of the roles of

407

biogenic Fe(II) production in the crystal transformation of ferrihydrite during dissimilatory

408

iron reduction processes.

409 410

ACKNOWLEDGEMENTS

411

This work was funded by the National Natural Science Foundation of China (grants

412

41571130052, 41522105, and 41471216), the Guangdong Natural Science Fund for

413

Distinguished Young Scholars (grant 2017A030306010), the Excellent Talent Fund of

414

Guangdong Academy of Sciences (GDAS) (grant 2017GDASCX-0408), the SPICC

415

(Scientific Platform and Innovation Capability Construction) program of GDAS, and an

416

Australian Research Council DECRA grant (DE150100500).

417 418

Supporting Information

419

Additional data can be found in the Supporting Information including additional descriptions 17

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of experiment method, Figures S1-S3 with illustrations. This material may be found in the

421

online version of this article.

422 423

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424

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Ecophysiology and Biochemistry, (Eds.) Dworkin, M., Falkow, S., Rosenberg, E., Schleifer, K.H.,

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Sediment. 2012, 12, 217–227. doi: 10.1007/s11368-011-0433-5.

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(35) Rong, X.; Chen, W.; Huang, Q.; Peng, C.; Wei, L. Pseudomonas putida adhesion to goethite: studied by

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equilibrium adsorption, SEM, FTIR and ITC. Colloids Surf. B Biointerfaces 2010,80, 79–85.

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(36) Yang, K.; Peng, H.; Wen, Y.; Ning, L. Re-examination of characteristic FTIR spectrum of secondary layer in

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bilayer

oleic

acid-coated

Fe3O4

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doi:10.1016/j.apsusc.2009.11.079.

nanoparticles.

Appl.

Surf.

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2010,

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3093–3097.

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(37) Mitsunobu, S.; Muramatsu, C.; Watanabe, K.; Sakata, M. Behavior of antimony(V) during the

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transformation of ferrihydrite and its environmental implications. Environ. Sci. Technol. 2013, 47,

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9660−9667. doi:10.1021/es4010398.

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(38) Boland, D.D.; Collins, R.N.; Miller, C.J.; Glover, C.J.; Waite, T.D. Effect of solution and solid-phase

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conditions on the Fe (II)-accelerated transformation of ferrihydrite to lepidocrocite and goethite.Environ.

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Sci. Technol. 2014, 48, 5477–5485. doi: 10.1021/es4043275.

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(39) Field, S.J., Dobbin, P.S., Cheesman, M.R., Watmough, N.J., Thomson, A.J. and Richardson, D. J.

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Purification and magneto-optical spectroscopic characterization of cytoplasmic membrane and outer

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membrane multiheme c-type cytochromes from Shewanella frigidimarina NCIMB400. J. Biol. Chem.

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2000, 275, 8515–8522. doi: 10.1074/jbc.275.12.8515.

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(40) Beliaev, A.S.; Saffarini, D.A.; Mclaughlin, J.L.; Hunnicutt, D. MtrC, An outer membrane decahaem c

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cytochrome required for metal reduction in Shewanella putrefaciens MR-1. Mol. Microbiol. 2001, 39, 21

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722–730. Doi: 10.1046/j.1365-2958.2001.02257.x.

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(41) Bretschger, O.; Obraztsova, A.; Sturm, C.A.; Chang, I.S.; Gorby, Y.A.; Reed, S.B.; Culley, D.E.; Reardon,

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C.L.; Barua, S.; Romine, M.F.; Zhou, J.; Beliaev, A.S.; Bouhenni, R.; Saffarini, D.; Mansfeld, F.; Kim,

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B.H.; Fredrickson, J.K.; Nealson, K.H. 2007. Current production and metal oxide reduction by

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Shewanella oneidensis MR-1 wild type and mutants. Appl. Environ. Microbiol. 2007, 73,

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7003–7012. doi: 10.1128/jb.00925-09.

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(42) Katrin, R.; Marcus, S.; Johannes, G. Dissimilatory reduction of extracellular electron acceptors in anaerobic respiration. Appl. Environ. Microbiol. 2012, 78, 913–921. doi: 10.1128/aem.06803-11. (43) Faria D. L. A. D., Lopes F. N. Heated goethite and natural hematite: Can Raman spectroscopy be used to differentiate them? Vib. Spectrosc., 2007, 45:117-121. doi:10.1016/j.vibspec.2007.07.003.

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(44) Gualtieri A .F, Venturelli P. In situ study of the goethite-hematite phase transformation by real time

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synchrotron powder diffraction. Am. Mineral., 1999, 84:895-904. doi:10.2138/am-1999-5-625.

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(45) Shi, L.; Chen, B.; Wang, Z.; Elias, D.A.; Mayer, M.U.; Gorby, Y.A.; Ni, S.; Lower, B.H.; Kennedy, D.W.;

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J.K.; Squier, T.C. Isolation of a high-affinity functional protein complex between OmcA and MtrC: Two

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outer membrane decaheme c-type cytochromes of Shewanella oneidensis MR-1. J. Bacteriol. 2006, 188,

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4705–4714. doi:10.1128/JB.01966-05.

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(46) Myers, C.R. and Myers, J.M. Cell surface exposure of the outer membrane cytochromes of Shewanella

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MR-1.

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lipoproteins. Lett. Appl. Microbiol. 2004, 39, 466–470. doi: 10.1111/j.1472-765X.2004.01611.x.

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(48) Cutting, R.S.; Coker, V.S.; Fellowes, J.W.; Lloyd, J.R.; Vaughan, D.J. Mineralogical and morphological

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constraints on the reduction of Fe(III) minerals by Geobacter sulfurreducens. Geochim.Cosmochimi.

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(49) Breuer M., Zarzycki P.; Shi L.; Clarke T.A.; Edwards M.J.; Butt J.N.; Richardson D.J.; Fredrickson

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J.K.;Zachara J.M.; Blumberger J.; Rosso K.M. Molecular structure and free energy landscape for

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electron transport in the decahaem cytochrome MtrF. Biochem. Soc. Trans. 2012, 40, 1198–1203. doi:

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MR-1: Structures, functions and opportunities. J. R. Soc. Interface 2015, 12, 1117. doi:

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(51) Liu, T.; Li, X.; Li, F.; Zhang, W.; Chen, M.; Zhou, S. Reduction of iron oxides by Klebsiella pneumoniae

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L17: Kinetics and surface properties. Colloids Surf. A Physicochem. Eng. Asp. 2011, 379, 143–150.

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(52) Fredrickson, J.K.; Zachara, J.M.; Kukkadapu, R.K.; Gorby, Y.A.; Smith, S.C.; Brown, C.F.

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Biotransformation of Ni-substituted hydrous ferric oxide by an Fe(III)-reducing bacterium. Environ. Sci.

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(53) Fischer, W.R. The formation of hematite from amorphous iron(III) hydroxide. Clays Clay Miner. 1975, 23, 33–37. doi:10.1346/ccmn.1975.0230105.

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R.L. The NBS tables of chemical thermodynamic properties: selected values for inorganic and C1 and

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C2 organic substances in SI units. J. Phys. Chem. 1982, 11, 1-392. doi:10.1063/1.555845.

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(55) Hiemstra T. Formation, stability, and solubility of metal oxide nanoparticles: Surface entropy, enthalpy, and

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energy

of

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584

10.1016/j.gca.2015.02.032.

Geochim.

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2015,

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179–198.

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(56) Diakonov, I.; Khodakovsky, I.; Schott, J.; Sergeeva, E. Thermodynamic properties of iron oxides and

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hydroxides. I. Surface and bulk thermodynamic properties of goethite (α-FeOOH) up to 500 K. Eur. J.

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Mineral. 1994, 6, 967–983. doi:10.1127/ejm/6/6/0967.

588 589 590 591

(57) Hemingway B.S. Thermodynamic properties for busenite, NiO, magnetite, Fe3O4, and hematite, Fe2O3, with comments on selected oxygen buffer reactions. Am. Mineral. 1990, 75, 781–790. (58) Helgeson, H.C. Thermodynamic of hydrothermal systems at elevated temperatures and pressures. Am. J. Sci. 1969, 267, 729-804. doi:10.1021/es9026248.

592

23

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Page 24 of 34

593 594 595

Table 1. Standard free energies of iron (oxyhydr)oxides, soluble ferrous and some other

596

species at 0.1 MPa and 298 K ∆G 0r (kJ mol-1) Source (Reference)

Ion/Solid

Fe2+ H+ H2O am-FeOOH α-FeOOH α-Fe2O3 Fe3O4

-78.8 0 -238.2 -472.8 -492.1 -744.3 -1016.1

597 598

24

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ACS Earth and Space Chemistry

599 600 601

Table 2. Calculated Gibbs free energies for half reactions of bioreduction processes of iron

602

(oxyhydr)oxides No

Reactions

1

C 3 H 5 O 3− + 4am -FeOOH + 7H + → C 2 H 3O −2 + HCO 3− + 6H 2 O + 4Fe 2+

∆G 0r (kJ mole-1)* -78.3

2

C 3 H 5 O 3− + 4α -FeOOH + 7H + → C 2 H 3O 2− + HCO 3− + 6H 2 O + 4Fe 2+

-59.0

3

C 3 H 5 O 3− + 2α -Fe 2 O 3 + 7H + → C 2 H 3O 2− + HCO 3− + 4H 2 O + 4Fe 2+

-59.8

− 3

+

− 2

− 3

C3 H 5 O + 2Fe3O 4 + 11H → C 2 H 3O + HCO + 6H 2 O + 6Fe

4 0 r

603

* ∆G

604

products ( ∆G 0f products ) and reactants ( ∆G 0f reactants ) in Table 1.

2+

-82.4

was calculated using Eq. 1 based on the total free energies of formation of the

605

25

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Page 26 of 34

606 607 608

Table 3. Calculated Gibbs free energies of non-redox mineralization processes of iron

609

(oxyhydr)oxides

No

Reactions

∆G 0r (kJ mol-1)*

5

-19.3

7

am-FeOOH → α -FeOOH 1 1 am-FeOOH → α -Fe2O3 + H 2O 2 2 2α -FeOOH → α -Fe2O3 + H 2O

8

Fe 2+ +2am-FeOOH → Fe 3O 4 + 2H +

8.3

6

9 10 0 r

2+

Fe +2α -FeOOH → Fe3O 4 + 2H 2+

-36.9 1.7

+

Fe +α -Fe 2 O 3 +H 2 O → Fe 3O 4 + 2H

46.9 +

610

* ∆G

611

products ( ∆G 0f products ) and reactants ( ∆G 0f reactants ) in Table 1.

45.2

was calculated using Eq. 1 based on the total free energies of formation of the

612

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ACS Earth and Space Chemistry

613 614 615

Table 4. List of reactions for biogenic Fe(II)-catalyzed mineralization processes of iron

616

(oxyhydr)oxides

617

No

Reactions of Biogenic Fe(II)-Catalyzed Mineralization

11

Elementary reaction* ≡ Fe(III)OH+Fe2+ →≡ Fe(III)OFe(II)+ +H+

12

≡ Fe(III)OFe(II)+ →≡ Fe(II)OFe(III)+

13

≡ Fe(II)OFe(III) + +H + →≡ Fe(III)OH new +Fe 2+

14

Goethite formation am -FeOOH+Fe → am -FeOOH • Fe 2+ → α -FeOOH + Fe 2+

15

Hematite formation 2 am-FeOOH+2Fe → 2( am-FeOOH • Fe 2+ ) → α -Fe 2 O 3 + H 2 O + 2Fe 2+

16

Magnetite formation 2 am-FeOOH+2Fe → 2( am-FeOOH • Fe 2+ ) → Fe 3O 4 + 2H + + Fe 2+

17

2α -FeOOH+2Fe 2+ → 2(α -FeOOH • Fe 2+ ) → Fe 3O 4 + 2H + + Fe 2+

2+

2+

2+

618 619

* ≡Fe(III)OFe(II)+ is the surface complex with Fe(II) adsorbing on the hydroxyl surface of

620

iron oxides. ≡Fe(II)OFe(III)+ is the surface complex after internal electron transfer.

621

≡Fe(II)OHnew is the “new” hydroxyl surface of more-crystalline (oxyhydr)oxides.

622

am-FeOOH•Fe2+, α-FeOOH•Fe2+, and α-Fe2O3•2Fe2+ represent the reactive surface complex

623

with Fe(II) adsorbing on hydroxyl surfaces of iron oxides.

624 625

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626

Figure captions

627

Figure 1. (a) Kinetics of Fe(II) generation during ferrihydrite reduction by MR-1 wild type

628

(WT) and the six types of mutant cells. Data are presented as means ± standard deviations

629

(SD) of triplicate replicates. (b) Zero-order reduction rates for Fe(II) generation. The

630

reduction of 50 mM ferrihydrite was determined for MR-1 WT and mutants (∆mtrA, ∆mtrC,

631

∆mtrD, ∆mtrF, ∆omcA, and ∆cymA) using lactate as an electron donor. Ferrihydrite without

632

bacteria was used as a negative control. (c) The number of bacterial cells (WT and mutants)

633

with the initial cell density (OD600nm = 1.0).

634

Figure 2. SEM of ferrihydrite after six days of microbial reductions by MR-1 WT and six

635

types of mutant cells. Ferrihydrite without bacteria was used as a negative control. Inset

636

pictures show photographs of the reaction suspensions after six days of incubation. (a) No cell,

637

(b) WT, (c) ∆mtrA, (d) ∆mtrC, (e) ∆mtrD, (f) ∆mtrF, (g) ∆omcA, (h) ∆cymA.

638

Figure 3. Fourier transform infrared spectra of ferrihydrite during the six-day reduction by

639

MR-1 WT and six types of mutant cells. (a) Ferrihydrite without bacteria, (b) WT, (c) ∆mtrA,

640

(d) ∆mtrC, (e) ∆mtrD, (f) ∆mtrF, (g) ∆omcA, (h) ∆cymA.

641

Figure 4. X-ray diffraction patterns of ferrihydrite during the six-day reduction by MR-1 WT

642

and six types of mutants. (a) No cell, (b) WT, (c) ∆mtrA, (d) ∆mtrC, (e) ∆mtrD, (f) ∆mtrF, (g)

643

∆omcA, (h) ∆cymA, (i) the JCPDS cards of goethite, hematite and magnetite.

644

Figure 5. Secondary mineral generation kinetics of ferrihydrite by MR-1 WT and six types of

645

mutants based on the change in relative intensity over time (for goethite: 2θ = 33.2o, hematite:

646

2θ = 35.7o and magnetite: 2θ = 62.5o). (a) Goethite, (b) hematite, (c) magnetite.

647 648

28

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Page 29 of 34

Figure 1.

649 WT ∆mtrA

(a)

∆mtrC ∆mtrD

∆mtrF ∆omcA

3

2

1 0

1

2

650

3 Time (d)

∆mtrD

WT

(b)

2.0

4

5

6

∆omcA

1.5

No cell

0.5

∆cymA

∆mtrC

1.0

∆mtrA

r (mM d-1)

∆cymA No cell

∆mtrF

HCl-extractable Fe(II) (mmol-1)

4

0.0

651

652

∆cymA

1

∆mtrA

2

∆omcA

∆mtrC

WT

3

∆mtrF

∆mtrD

(c) Bacteria number (×109) (cells mL-1)

1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 16 17 18 19 20 21 22 23 24 25 26 27 28 29 30 31 32 33 34 35 36 37 38 39 40 41 42 43 44 45 46 47 48 49 50 51 52 53 54 55 56 57 58 59 60

ACS Earth and Space Chemistry

0

653 29

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654 655

Figure 2.

656 657 658

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Page 31 of 34

659

Figure 3.

660 (a)

1175 1120 1040

(b)

No cell

Transmittance

Transmittance

3d 2d 1d 0d

6d

WT

564

3d 2d 1d

0d

1200

(c)

590

797

4d

4d

661

887

1175 1120 1040

6d

590

6d

1000

1175 1120 1040

800 887

600

797

1200

400

590

(d)

∆mtrA

1000

1175 1120 1040

6d

887

800

600

797

590

800

600

400

∆mtrC

4d

Transmittance

Transmittance

4d 3d 2d 1d 0d

3d 2d 1d 0d

1200

1000

800

600

1200

400

1000

Wavenumber (cm-1)

662 (e)

887

1175 1120 1040

797

(f)

∆mtrD

Transmittance

Transmittance

∆mtrF

564

4d

3d 2d 1d

3d 2d 1d 0d

0d

1200

(g)

887 797 590

1175 1120 1040

6d

564

4d

663

400

Wavenumber (cm-1)

590

6d

1000

1175 1120 1040

887

800

600

797

590

6d

400

1200

(h)

∆omcA

1000

1175 1120 1040

887

6d

800

600

797

590

800

600

400

∆cymA

564

4d Transmittance

4d Transmittance

1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 16 17 18 19 20 21 22 23 24 25 26 27 28 29 30 31 32 33 34 35 36 37 38 39 40 41 42 43 44 45 46 47 48 49 50 51 52 53 54 55 56 57 58 59 60

ACS Earth and Space Chemistry

3d 2d 1d

3d 2d 1d 0d

0d

1200

664

1000

800

600

400

1200

1000

Wavenumber (cm-1)

Wavenumber (cm-1)

665 666

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ACS Earth and Space Chemistry

Figure 4.

667 (a)

(b)

No cell

H

WT

6d

Relative Intensity

M

Relative Intensity

4d 3d 2d

M

M

H

G

M

G

H

M

G

H

H

M

H

M

6d M

M

4d M

M

3d

G H

H

HH

2d

H

H H

1d

G H

1d

0d

0d 20

30

40

50

60

20

70

30

40

G G

H

H

H

H H

G

6d

H

G

H G

H

G

H

H

H

H H

H

H

4d 3d

H

2d

70

60

H

H

ΔmtrC

M G

H

G

H

H H G

H

H

H

H

H

H

H

H

H

H M H H

3d

H

2d 1d

1d

0d

0d 20

40

50

60

20

70

30

40

2 Theta ( )

a (e)

H

Relative Intensity

M

(f)

∆mtrD M

H

M

M G

6d

H M

G

M

G G

M

H

H

H

H

G H

M

M

4d M

M

3d

H

2d

H

1d

60

H

M

G

50

70

2 Theta (o)

o

∆mtrF

G

M

H

M

M

6d

H

Relative Intensity

669

30

M M

G

M

G

H

G H G H

H

M

H

M

M

4d

M

3d

H

2d

H

1d 0d

0d 20

30

40

50

60

70

20

30

40

2 Theta (o)

670 (g)

(h)

G

∆omcA G

G

M

H

6d

H

G

M

G G

H

H M

M

M

4d

H H

H G H

60

3d 2d

H

G H

H

H

M

M

Relative Intensity

M

50

G

H

G

H

H

G

H

G

H

ΔcymA

H

H

H

H

H

H

H

H

671

30

H H

6d

HH

4d

H

3d

H

2d

H

1d

1d 0d

0d 20

70

2 Theta (o)

H

G

6d 4d

H

G H

H

G

G

ΔmtrA

H

H

Relative Intensity

(d)

H

Relative Intensity

(c)

50

2 Theta (o)

2 Theta (o)

668

Relative Intensity

1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 16 17 18 19 20 21 22 23 24 25 26 27 28 29 30 31 32 33 34 35 36 37 38 39 40 41 42 43 44 45 46 47 48 49 50 51 52 53 54 55 56 57 58 59 60

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40

50

60

70

20

30

40

50

2 Theta (o)

2 Theta (o)

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70

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Figure 5.

672 12000

WT ∆mtrA ∆mtrC ∆mtrD ∆mtrF ∆omcA ∆cymA

(a)

Relative Intensity

9000

6000

Goethite

3000

0 0

1

2

3

4

5

6

Time (day)

673 30000

WT ∆mtrA ∆mtrC ∆mtrD ∆mtrF ∆omcA ∆cymA

(b)

Relative Intensity

25000

20000

Hematite

15000

10000

5000

0 0

1

2

3

4

5

6

Time (day)

674 (c)

Magnetite

WT ∆mtrA ∆mtrC ∆mtrD ∆mtrF ∆omcA ∆cymA

12000

Relative Intensity

1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 16 17 18 19 20 21 22 23 24 25 26 27 28 29 30 31 32 33 34 35 36 37 38 39 40 41 42 43 44 45 46 47 48 49 50 51 52 53 54 55 56 57 58 59 60

ACS Earth and Space Chemistry

9000

6000

3000

0

1

675 676

2

3

4

Time (day)

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6

ACS Earth and Space Chemistry

677 678 679

Table of Contents Fe(II) production

Secondary mineral formation

Fe2+

Goethite

Ferrihydrite

Hematite

eMagnetite

MtrCAB

680 681 682

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Fe2+

1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 16 17 18 19 20 21 22 23 24 25 26 27 28 29 30 31 32 33 34 35 36 37 38 39 40 41 42 43 44 45 46 47 48 49 50 51 52 53 54 55 56 57 58 59 60

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