Release of Arsenic from Soil by a Novel Dissimilatory Arsenate-Reducing Bacterium, Anaeromyxobacter sp. Strain PSR-1

Kudo, Keitaro; Yamaguchi, Noriko; Makino, Tomoyuki; Ohtsuka, Toshihiko; Kimura, Kenta; Dong, Dian Tao; Amachi, Seigo

doi:10.1128/aem.00693-13

Cited by 108 publications

(54 citation statements)

References 42 publications

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“…PCC7120, and Anaeromyxobacter sp. strain PSR-1 can change the chemical species of As via oxidation/reduction and methylation/demethylation, and thereby influence the toxicity, mobilization, and availability of As in environment (Yin et al, 2011a;Kudo et al, 2013;Zhao et al, 2013). Other species such as Aspergillus clavatus and Aspergillus niger can sequestrate As into their cytoplasm or adsorb As onto their cell walls and thus transfer As from their surroundings to their own biomass (Č erň anský et al, 2007).…”

Section: Introductionmentioning

confidence: 97%

Arsenic speciation transformation and arsenite influx and efflux across the cell membrane of fungi investigated using HPLC–HG–AFS and in-situ XANES

Zeng

Feng

et al. 2015

Chemosphere

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Section: Introductionmentioning

confidence: 97%

Arsenic speciation transformation and arsenite influx and efflux across the cell membrane of fungi investigated using HPLC–HG–AFS and in-situ XANES

Zeng

Feng

et al. 2015

Chemosphere

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“…Some iron reducers can sometimes also reduce arsenate and possess the respiratory arsenate reductase gene arrA (Ohtsuka et al 2013;Kudo et al 2014;Osborne et al 2015). arrA genes closely related to those of Geobacter species have been detected frequently in arsenic rich sediments (Lear et al 2007;H ery et al 2015).…”

Section: Microbial Diversity In Iron-reducing Enrichmentsmentioning

confidence: 99%

Iron Cycling Potentials of Arsenic Contaminated Groundwater in Bangladesh as Revealed by Enrichment Cultivation

Hassan

Sultana

Westerhoff

et al. 2016

Geomicrobiology Journal

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The activities of iron-oxidizing and reducing microorganisms impact the fate of arsenic in groundwater. Phylogenetic information cannot exclusively be used to infer the potential for iron oxidation or reduction in aquifers. Therefore, we complemented a previous cultivation-independent microbial community survey covering 22 arsenic contaminated drinking water wells in Bangladesh, with the characterization of enrichments of microaerophilic iron oxidizers and anaerobic iron reducers, conducted on the same water samples. All investigated samples revealed a potential for microbial iron oxidation and reduction. Microbial communities were phylogenetically diverse within and between enrichments as was also observed in the previous cultivation-independent analysis of the water samples from which these enrichments were derived. Enrichment uncovered a larger diversity in iron-cycling microorganisms than previously indicated. The iron-reducing enrichments revealed the presence of several 16S ribosomal RNA (16S rRNA) gene sequences most closely related to Acetobacterium, Clostridium, Bacillus, Rhizobiales, Desulfovibrio, Bacteroides, and Spirochaetes, in addition to well-known dissimilatory iron-reducing Geobacter and Geothrix species. Although a large diversity of Geobacteraceae was observed, they comprised only a small part of the iron-reducing consortia. Iron-oxidizing gradient tube enrichments were dominated by Comamonadaceae and Rhodocyclaceae instead of Gallionellaceae. Forty-five percent of these enrichments also revealed the presence of the gene encoding arsenite oxidase, which converts arsenite to less toxic and less mobile arsenate. Their potential for ferric (oxyhydr)oxides precipitation and arsenic immobilization makes these iron-oxidizing enrichments of interest for rational bioaugmentation of arsenite contaminated groundwater.

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“…lactate, acetate, formate, and aromatic compounds) or inorganic (e.g., hydrogen and sulfide) electron donors [5,6]. In contrast to the detoxification pathway, dissimilatory As(V) reduction (DAsR) plays a major role in the release of As in anoxic environments [7,8]. Notably, dissimilatory As(V)-respiring bacteria (DARB) can reduce both sorbed and dissolved As(V) to As(III) because the enzymes responsible for As(V) reduction are membrane-bound and linked to electron transport chains involved in energy generation [9].…”

Section: Introductionmentioning

confidence: 99%

Dissimilatory Arsenate Reduction and In Situ Microbial Activities and Diversity in Arsenic-rich Groundwater of Chianan Plain, Southwestern Taiwan

et al. 2015

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Although dissimilatory arsenic reduction (DAsR) has been recognized as an important process for groundwater arsenic (As) enrichment, its characterization and association with in situ microbial activities and diversity in As-rich groundwater is barely studied. In this work, we collected As-rich groundwater at depths of 23, 300, and 313 m, respectively, from Yenshui-3, Budai-Shinwen, and Budai-4 of Chianan plain, southwestern Taiwan, and conducted incubation experiments using different electron donors, acceptors, and sulfate-reducing bacterial inhibitor (tungstate) to characterize DAsR. Moreover, bacterial diversity was evaluated using 454-pyrosequencing targeting bacterial 16S rRNAs. MPN technique was used to enumerate microorganisms with different in situ metabolic functions. The results revealed that DAsR in groundwater of Chianan plain was a biotic phenomenon (as DAsR was totally inhibited by filter sterilization), enhanced by the type of electron donor (in this case, lactate enhanced DAsR but acetate and succinate did not), and limited by the availability of arsenate. In addition to oxidative recycling of As(III), dissolution of As(V)-saturated manganese and iron minerals by indigenous dissimilatory Mn(IV)- and Fe(III)-reducing bacteria, and abiotic oxidation of As(III) with Mn(IV) regenerated As(V) in the groundwater. Sulfate-respiring bacteria contributed 7.4 and 28.2 % to the observed DAsR in groundwater of Yinshui-3 and Budai-Shinwen, respectively, whereas their contribution was negligible in groundwater of Budai-4. A noticeable variation in dominant genera Acinetobacter and Bacillus was observed within the groundwater. Firmicutes dominated in highly As-rich groundwater of Yenshui-3, whereas Proteobacteria dominated in comparatively less As-rich groundwater of Budai-Shinwen and Budai 4.

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Release of Arsenic from Soil by a Novel Dissimilatory Arsenate-Reducing Bacterium, Anaeromyxobacter sp. Strain PSR-1

Cited by 108 publications

References 42 publications

Arsenic speciation transformation and arsenite influx and efflux across the cell membrane of fungi investigated using HPLC–HG–AFS and in-situ XANES

Arsenic speciation transformation and arsenite influx and efflux across the cell membrane of fungi investigated using HPLC–HG–AFS and in-situ XANES

Iron Cycling Potentials of Arsenic Contaminated Groundwater in Bangladesh as Revealed by Enrichment Cultivation

Dissimilatory Arsenate Reduction and In Situ Microbial Activities and Diversity in Arsenic-rich Groundwater of Chianan Plain, Southwestern Taiwan

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