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Bacteria responsible for antimonite oxidation in antimony-contaminated soil revealed by DNA-SIP coupled to metagenomics

Zhang, Miaomiao ; Kolton, Max ; Li, Zhe ; [et al.]

Oxford University Press (OUP) ; 2021

In: FEMS Microbiology Ecology Vol. 97, No. 5 ( 2021-04-13)

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In: FEMS Microbiology Ecology, Oxford University Press (OUP), Vol. 97, No. 5 ( 2021-04-13)

Abstract: Antimony (Sb), the analog of arsenic (As), is a toxic metalloid that poses risks to the environment and human health. Antimonite (Sb(III)) oxidation can decrease Sb toxicity, which contributes to the bioremediation of Sb contamination. Bacteria can oxidize Sb(III), but the current knowledge regarding Sb(III)-oxidizing bacteria (SbOB) is limited to pure culture studies, thus underestimating the diversity of SbOB. In this study, Sb(III)-oxidizing microcosms were set up using Sb-contaminated rice paddies as inocula. Sb(III) oxidation driven by microorganisms was observed in the microcosms. The increasing copies and transcription of the arsenate-oxidizing gene, aioA, in the microcosms during biotic Sb(III) oxidation indicated that microorganisms mediated Sb(III) oxidation via the aioA genes. Furthermore, a novel combination of DNA-SIP and shotgun metagenomic was applied to identify the SbOB and predict their metabolic potential. Several putative SbOB were identified, including Paracoccus, Rhizobium, Achromobacter and Hydrogenophaga. Furthermore, the metagenomic analysis indicated that all of these putative SbOB contained aioA genes, confirming their roles in Sb(III) oxidation. These results suggested the concept of proof of combining DNA-SIP and shotgun metagenomics directly. In addition, the identification of the novel putative SbOB expands the current knowledge regarding the diversity of SbOB.

Type of Medium: Online Resource

ISSN: 0168-6496 , 1574-6941

URL: Article

DOI: 10.1093/femsec/fiab057

RVK:

WA 15000

Language: English

Publisher: Oxford University Press (OUP)

Publication Date: 2021

detail.hit.zdb_id: 1501712-6

SSG: 12

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Rhizosphere Microbial Response to Multiple Metal(loid)s in Different Contaminated Arable Soils Indicates Crop-Specific Metal-Microbe Interactions

Sun, Weimin ; Xiao, Enzong ; Krumins, Valdis ; [et al.]

American Society for Microbiology ; 2018

In: Applied and Environmental Microbiology Vol. 84, No. 24 ( 2018-12-15)

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In: Applied and Environmental Microbiology, American Society for Microbiology, Vol. 84, No. 24 ( 2018-12-15)

Abstract: In this study, we sampled rhizosphere soils from seven different agricultural fields adjacent to mining areas and cultivated with different crops (corn, rice, or soybean), to study the interactions among the innate microbiota, soil chemical properties, plants, and metal contamination. The rhizosphere bacterial communities were characterized by Illumina sequencing of the 16S rRNA genes, and their interactions with the local environments, including biotic and abiotic factors, were analyzed. Overall, these soils were heavily contaminated with multiple metal(loid)s, including V, Cr, Cu, Sb, Pb, Cd, and As. The interactions between environmental parameters and microbial communities were identified using multivariate regression tree analysis, canonical correspondence analysis, and network analysis. Notably, metal-microbe interactions were observed to be crop specific. The rhizosphere communities were strongly correlated with V and Cr levels, although these sites were contaminated from Sb and Zn/Pb mining, suggesting that these two less-addressed metals may play important roles in shaping the rhizosphere microbiota. Members of Gaiellaceae cooccurred with other bacterial taxa (biotic interactions) and several metal(loid)s, suggesting potential metal(loid) resistance or cycling involving this less-well-known taxon. IMPORTANCE The rhizosphere is the “hub” for plant-microbe interactions and an active region for exchange of nutrients and energy between soil and plants. In arable soils contaminated by mining activities, the rhizosphere may be an important barrier resisting metal uptake. Therefore, the responses of the rhizosphere microbiota to metal contamination involve important biogeochemical processes, which can affect metal bioavailability and thus impact food safety. However, understanding these processes remains a challenge. The current study illustrates that metal-microbe interactions may be crop specific and some less-addressed metals, such as V and Cr, may play important roles in shaping bacterial communities. The current study provides new insights into metal-microbe interactions and contributes to future implementation and monitoring efforts in contaminated arable soils.

Type of Medium: Online Resource

ISSN: 0099-2240 , 1098-5336

URL: Article

DOI: 10.1128/AEM.00701-18

RVK:

WA 15000

Language: English

Publisher: American Society for Microbiology

Publication Date: 2018

detail.hit.zdb_id: 223011-2

detail.hit.zdb_id: 1478346-0

SSG: 12

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