Spatial Pattern of Bacterial Community Diversity Formed in Different Groundwater Field Corresponding to Electron Donors and Acceptors Distributions at a Petroleum-Contaminated Site

Ning, Zhuo; Zhang, Min; He, Ze; Cai, Pingping; Guo, Caijuan; Wang, Ping

doi:10.3390/w10070842

Cited by 19 publications

(6 citation statements)

References 61 publications

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“…However, as in our study, the relationship between contaminates load (uranium) and functional genes richness was insignificant. In another study however, diversity in groundwater polluted with hydrocarbons in China, was lower than the downstream groundwater, likely due to the dominance of degrading bacteria [48].…”

Section: Pollution Extent Affects Community Diversitymentioning

confidence: 83%

The Spatial Distribution of the Microbial Community in a Contaminated Aquitard below an Industrial Zone

Balaban

Yankelzon

Adar

et al. 2019

Water

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The industrial complex Neot Hovav, in Israel, is situated above an anaerobic fractured chalk aquitard, which is polluted by a wide variety of hazardous organic compounds. These include volatile and non-volatile, halogenated, organic compounds. In this study, we characterized the indigenous bacterial population in 17 boreholes of the groundwater environment, while observing the spatial variations in the population and structure as a function of distance from the polluting source. In addition, the de-halogenating potential of the microbial groundwater population was tested through a series of lab microcosm experiments, thus exemplifying the potential and limitations for bioremediation of the site. In all samples, the dominant phylum was Proteobacteria. In the production plant area, the non-obligatory organo-halide respiring bacteria (OHRB) Firmicutes Phylum was also detected in the polluted water, in abundancies of up to 16 %. Non-metric multidimensional scaling (NMDS) analysis of the microbial community structure in the groundwater exhibited clusters of distinct populations following the location in the industrial complex and distance from the polluting source. Dehalogenation of halogenated ethylene was demonstrated in contrast to the persistence of brominated alcohols. Persistence is likely due to the chemical characteristics of brominated alcohols, and not because of the absence of active de-halogenating bacteria.

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Section: Pollution Extent Affects Community Diversitymentioning

confidence: 83%

The Spatial Distribution of the Microbial Community in a Contaminated Aquitard below an Industrial Zone

Balaban

Yankelzon

Adar

et al. 2019

Water

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“…The number of OTUs unique to RIC_S (713) was much higher than those in QSC_S and NFC_S (309 and 292). Other researchers have demonstrated that soil bacterial community diversity can gradually decrease with significant removal of soil organic C by leaching, dissolution, and aerobic transformation (Ning et al., 2018). This could explain the diversity differences between the vadose zone communities, but not the similar diversity in the oscillated zone communities or that the highest diversity in the saturated zone was exhibited by RIC.…”

Section: Resultsmentioning

confidence: 99%

Response of soil bacterial community and geochemical parameters to cyclic groundwater‐level oscillations in laboratory columns

Xia

Cheng

Zhu

et al. 2020

Vadose Zone Journal

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Groundwater-level oscillations change geochemical conditions, C cycling processes, and bacterial community composition, and these changes may vary vertically with depth in a soil. In this study, soil column experiments were conducted to explore variations in soil bacterial community composition and its associated geochemical parameters to rapid short-term cyclic groundwater-level oscillations driven by natural fluctuations (NF) and rainfall infiltration (RI), and the results are compared with a quasistatic (QS) column. Water saturation patterns in vadose and oscillated zones, and O 2 level patterns, soil total organic C (TOC) removal rates, and soil bacterial community composition in vadose, oscillated, and saturated zones were evaluated. Results showed that water saturation and O 2 level oscillated with groundwater level in NF and RI columns. Total organic C removal rates in RI column were the highest across vadose (∼38.4%), oscillated (∼35.8%), and saturated (∼35.2%) zones. Deltaproteobacteria, which were significantly correlated with TOC removal (p < .05), were found in higher abundance in the vadose and oscillated zones of the RI column than in the QS and NF columns. Soil bacterial community structure was dynamic at the class level due to water saturation, O 2 level, and TOC removal. Total organic C removal was the driver to separate the distribution of bacterial community structure in the vadose and oscillated zones of the RI column from those of the QS and NF columns. This study suggests that RI induced rapid, short-term, cyclic, groundwater-level oscillations could significantly influence both the soil C cycle and bacterial community structure in the vadose and oscillated zones.

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“…Most of the studies considered anthropogenic sources, with Beretta et al [7] and Haluska et al [6] addressing the industrial additive and known carcinogen hexavalent chromium, Plymale et al [8] focusing on the toxic salt ferrocyanide, Haluska et al [6] measuring the organic contaminants 1,4-dioxane and hexahydro-1,3,5-trinitro-s-triazine (RDX), Prieto-Amparán et al [9] studying sewage effluent, and Wells et al [10] tracking the fertilizer-derived anion nitrate. As a particular subset of anthropogenic contaminants, two studies discuss emerging contaminants, particularly related to hydrocarbon resources, as Hu et al [11] study oil shale development, while Ning et al [12] focus on petroleum contamination.…”

Section: Groundwater Contaminationmentioning

confidence: 99%

“…In parallel, Hu et al [11] discuss the potential impacts from emerging contaminants related to oil shale development. Three studies explore the central role of biology in groundwater remediation, reflecting our new understanding of subsurface processes through the interdisciplinary lens of biogeochemistry: Ning et al [12] study the spatial pattern of bacterial communities at a petroleum-contaminated site; Plymale et al [8] study bacterial communities at a nuclear waste-contaminated site; and Moradi et al [14] contribute a model describing thermally-enhanced bioremediation. Taken together, these studies demonstrate that our ability to remediate groundwater depends on knowing the contaminants, understanding the fluid mechanics, and interpreting processes in the context of hydrology, geochemistry, and microbiology.…”

Section: Subsurface Processesmentioning

confidence: 99%

Groundwater Contamination, Subsurface Processes, and Remediation Methods: Overview of the Special Issue of Water on Groundwater Contamination and Remediation

Mays

Scheibe

2018

Water

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Spatial Pattern of Bacterial Community Diversity Formed in Different Groundwater Field Corresponding to Electron Donors and Acceptors Distributions at a Petroleum-Contaminated Site

Cited by 19 publications

References 61 publications

The Spatial Distribution of the Microbial Community in a Contaminated Aquitard below an Industrial Zone

The Spatial Distribution of the Microbial Community in a Contaminated Aquitard below an Industrial Zone

Response of soil bacterial community and geochemical parameters to cyclic groundwater‐level oscillations in laboratory columns

Groundwater Contamination, Subsurface Processes, and Remediation Methods: Overview of the Special Issue of Water on Groundwater Contamination and Remediation

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