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Arsenite Oxidation Using Biogenic Manganese Oxides Produced By A Deep-Sea Manganese-Oxidizing Bacterium, Marinobacter Sp. MnI7-9

S. Liao, J. Zhou, Hui Wang, X. Chen, H. Wang, G. Wang
Published 2013 · Chemistry

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Marinobacter sp. MnI7-9, a deep-sea manganese [Mn(II)]-oxidizing bacterium isolated from the Indian Ocean, showed a high resistance to Mn(II) and other metals or metalloids and high Mn(II) oxidation/removal abilities. This strain was able to grow well when the Mn(II) concentration reached up to 10 mM, and at that concentration, 76.4% of the added Mn(II) was oxidized and 23.4% of the Mn(II) was adsorbed by the generated biogenic Mn oxides (total 99.9% Mn removal). Scanning electron microscope observation and X-ray diffraction analysis showed that the biogenic Mn oxides were in stick shapes, adhered to the cell surface, and contained two typical crystal structures of γ-MnOOH and δ-MnO2. In addition, the biogenic Mn oxides generated by strain MnI7-9 showed abilities to oxidize the highly toxic As(III) to the less toxic As(V), in both co-culture and after-collection systems. In the co-culture system containing 10 mM Mn(II) and 55 μM As(III), the maximum percentage of As(III) oxidation was 83.5%. In the after-collection system using the generated biogenic Mn oxides, 90% of the As(III) was oxidized into As(V), and the concentration of As(III) decreased from 55.02 to 5.55 μM. This study demonstrates the effective bioremediation by a deep-sea Mn(II)-oxidizing bacterium for the treatment of As-containing water and increases the knowledge of deep-sea bacterial Mn(II) oxidation mechanisms. Supplemental materials are available for this article. Go to the publisher's online edition of Geomicrobiology Journal to view the supplemental file.
This paper references
Kinetics of Bacterial As(III) Oxidation and Subsequent As(V) Removal by Sorption onto Biogenic Manganese Oxides during Groundwater Treatment
I. Katsoyiannis (2004)
Cr(III) oxidation coupled with Mn(II) bacterial oxidation in the environment
Ji-Zheng He (2010)
Zinc sorption to biogenic hexagonal-birnessite particles within a hydrated bacterial biofilm
B. Toner (2006)
Microbial manganese oxide formation and interaction with toxic metal ions.
N. Miyata (2007)
Novel gene clusters involved in arsenite oxidation and resistance in two arsenite oxidizers: Achromobacter sp. SY8 and Pseudomonas sp. TS44
L. Cai (2009)
Interaction of inorganic arsenic with biogenic manganese oxide produced by a Mn-oxidizing fungus, strain KR21-2.
Y. Tani (2004)
Manganese oxide minerals: crystal structures and economic and environmental significance.
J. Post (1999)
Evidence for the presence of Mn(III) intermediates in the bacterial oxidation of Mn(II).
S. Webb (2005)
Concurrent transformation of Ce(III) and formation of biogenic manganese oxides
T. Ohnuki (2008)
Isolation and characterization of manganese resistant bacteria from deep sea sediments . ( in Chinese )
B Toner (2006)
MEGA 4: Molecular evolutionary genetics 277 analysis (MEGA) software version 4.0
K Tamura (2007)
Novel gene culsters involved in arsenite oxidation and resistance in two arsenite oxidizers: Achromobacter sp
L Cai (2009)
Novel gene culsters involved in arsenite oxidation and resistance in two arsenite oxidizers: Achromobacter sp. SY8 and Pseudomonas sp
L Cai (2009)
Adsorption of heavy metals by biogenic manganese oxides
Zhang Li-mei (2009)
Isolation and characterization of manganese resistant bacteria from deep sea sediments
M Tian (2006)
Removal of multi-heavy metals using biogenic manganese oxides generated by a deep-sea sedimentary bacterium - Brachybacterium sp. strain Mn32.
W. Wang (2009)
Mn ( | | ) Oxidation and removal by a manganese - oxidizing bacteriumBacillus sp . MK 3 – 1
YT Meng (2009)
HLA alleles determine human T-lymphotropic virus-I (HTLV-I) proviral load and the risk of HTLV-I-associated myelopathy.
K. Jeffery (1999)
Genome sequence of a deep-sea manganese-oxidizing bacterium
H Wang (2012)
Characterization of the Manganese Oxide Produced by Pseudomonas Putida Strain MnB1
I. Saratovsky (2004)
Biogenic manganese oxides: Properties and mechanisms of formation
B. Tebo (2004)
Indirect UO 2 oxidation by Mn ( II ) - oxidizing spores of Bacillus sp . strain SG - 1 and the effect of U andMn concentrations
S Chinni (2008)
Crystal structure of photosystem II from Synechococcus elongatus at 3.8 Å resolution
A. Zouni (2001)
Nanocrystalline todorokite-like manganese oxide produced by bacterial catalysis.
H. Kim (2003)
Sorption of Co(II), Ni(II), and Zn(II) on Biogenic Manganese Oxides Produced by a Mn-Oxidizing Fungus, Strain KR21-2
Y. Tani (2004)
Indirect UO2 oxidation by Mn(II)-oxidizing spores of Bacillus sp. strain SG-1 and the effect of U and Mn concentrations.
S. Chinni (2008)
Cr(III) is indirectly oxidized by the Mn(II)-oxidizing bacterium Bacillus sp. strain SG-1.
K. J. Murray (2007)
Oxidation of manganese by spores of a marine bacillus: Kinetic and thermodynamic considerations
David Hastings (1986)
Recent advances in the bioremediation of arsenic-contaminated groundwater.
A. Zouboulis (2005)
Mechanisms of Pb(II) sorption on a biogenic manganese oxide.
M. Villalobos (2005)
Determination of uranyl incorporation into biogenic manganese oxides using x-ray absorption spectroscopy and scattering.
S. Webb (2006)
Ni(II) and Zn(II) ions on biogenic manganese oxide produced by a Mn-oxidizing fungus, strain KR21-2
Y Tani (2004)
Mn(||) Oxidation and removal by a manganese-oxidizing bacterium Bacillus sp. MK3-1. Microbiology-CAS
Y Liu (2009)
Cobalt(II) Oxidation by the Marine Manganese(II)-Oxidizing Bacillus sp. Strain SG-1.
Y. Lee (1994)
Mn(||) Oxidation and removal by a manganese-oxidizing bacterium Bacillus sp
Y Liu (2009)
Enzymatic Manganese(II) Oxidation by Metabolically Dormant Spores of Diverse Bacillus Species
Chris A. Francis (2002)
Amplification of bacterial 16S ribosomal DNA with polymerase chain reaction.
K. Wilson (1990)
Production of Biogenic Mn Oxides by Leptothrix discophora SS-1 in a Chemically Defined Growth Medium and Evaluation of Their Pb Adsorption Characteristics
Yarrow M. Nelson (1999)
MEGA4: Molecular Evolutionary Genetics Analysis (MEGA) software version 4.0.
K. Tamura (2007)
A new method for the detection and enumeration of manganese oxidizing and reducing microorganisms
W. Krumbein (2005)
Genome sequence of deep-sea manganese-oxidizing bacterium Marinobacter manganoxydans MnI7-9.
H. Wang (2012)
The neighbor-joining method: a new method for reconstructing phylogenetic trees.
N. Saitou (1987)
Isolation and characterization of manganese resistant bacteria from deep sea sediments. (in Chinese)
M Tian (2006)
Novel gene culsters involved in arsenite oxidation and resistance in two arsenite oxidizers : Achro - mobacter sp . SY 8 and Pseudomonas sp . TS 44
L Cai (2009)
Biogenic Mn oxides for effective adsorption of Cd from aquatic environment.
Y. Meng (2009)

This paper is referenced by
Manganese-oxidizing microbes and biogenic manganese oxides: characterization, Mn(II) oxidation mechanism and environmental relevance
Hao Zhou (2020)
Arsenite oxidation regulator AioR regulates bacterial chemotaxis towards arsenite in Agrobacterium tumefaciens GW4
Kaixiang Shi (2017)
Correlation Models between Environmental Factors and Bacterial Resistance to Antimony and Copper
Z. Shi (2013)
Simultaneous 3-/4-Hydroxybenzoates Biodegradation and Arsenite Oxidation by Hydrogenophaga sp. H7
Xia Fan (2019)
The influence of particle size and structure on the sorption and oxidation behavior of birnessite: I. Adsorption of As(V) and oxidation of As(III)
M. Villalobos (2014)
Acclimation of a marine microbial consortium for efficient Mn(II) oxidation and manganese containing particle production.
H. Zhou (2016)
Removal of Indigo Carmine by Bacterial Biogenic Mn Oxides
X. Chen (2013)
Fate of arsenate following arsenite oxidation in Agrobacterium tumefaciens GW4.
Q. Wang (2015)
Genomic and physiological characterization of an antimony and arsenite-oxidizing bacterium Roseomonas rhizosphaerae.
Lina Sun (2020)
An Efficient Adsorption of Manganese Oxides/Activated Carbon Composite for Lead(II) Ions from Aqueous Solution
Zhiqiang Liu (2018)
Carbofuran Degradation by Biogenic Manganese Oxides
Z. Liu (2016)
Removal and Recovery of Toxic Silver Ion Using Deep-Sea Bacterial Generated Biogenic Manganese Oxides
Yuanjun Pei (2013)
Methanogenesis from wastewater stimulated by addition of elemental manganese
S. Qiao (2015)
Chromate Interaction with the Chromate Reducing Actinobacterium Intrasporangium chromatireducens Q5-1
H. Liu (2015)
Regulation of arsenite oxidation by the phosphate two-component system PhoBR in Halomonas sp. HAL1
F. Chen (2015)
Activated carbon doped with biogenic manganese oxides for the removal of indigo carmine.
Y. Hu (2016)
Paenibacillus selenitireducens sp. nov., a selenite-reducing bacterium isolated from a selenium mineral soil.
R. Yao (2014)
High-quality-draft genomic sequence of Paenibacillus ferrarius CY1T with the potential to bioremediate Cd, Cr and Se contamination
J. Li (2017)
Arsenite Oxidase Also Functions as an Antimonite Oxidase
Q. Wang (2015)
Discovery of a novel native bacterium of Providencia sp. with high biosorption and oxidation ability of manganese for bioleaching of heavy metal contaminated soils.
D. Li (2019)
Runella aurantiaca sp. nov., isolated from sludge of a manganese mine.
X. Yang (2019)
Impact of Microorganisms on Arsenic Biogeochemistry: A Review
Jen-How Huang (2014)
Novel Hyper Antimony-Oxidizing Bacteria Isolated from Contaminated Mine Soils in China
Jiaokun Li (2018)
Arsenic Toxicity and Its Remediation Strategies for Fighting the Environmental Threat
Vishvas Hare (2019)
Microbial Diversity of Emalahleni Mine Water in South Africa and Tolerance Ability of the Predominant Organism to Vanadium and Nickel
I. Kamika (2014)
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