Influence of substrate type on microbial community structure in vertical-flow constructed wetland treating polluted river water

Guan, Wei; Yin, Min; He, Tao; Xie, Shuguang

doi:10.1007/s11356-015-5160-9

Cited by 94 publications

(36 citation statements)

References 63 publications

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“…In a VF wetland operated under OLR of 27 g COD m -2 d -1 was identified that Nitrosomonas europaea, N. mobilis and Nitrosospira were dominant AOBs in the filter media (Tietz et al, 2007). Guan et al (2015) evaluated in three VF wetlands (1.2 m²) the influence of different substrates (sand, zeolite and gravel) and showed that the bacterial community was significantly influenced by substrate type. However, Nitrospira one of the NOB, was abundant in all units showing no influence of substrate type.…”

Section: Introductionmentioning

confidence: 99%

Unraveling the active microbial populations involved in nitrogen utilization in a vertical subsurface flow constructed wetland treating urban wastewater

Pelissari

Guivernau

Viñas

et al. 2017

Science of The Total Environment

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The dynamics of the active microbial populations involved in nitrogen transformation in a vertical subsurface flow constructed wetland (VF) treating urban wastewater was assessed. The wetland (1.5m) operated under average loads of 130gCODmd and 17gTNmd in Period I, and 80gCODmd and 19gTNmd in Period II. The hydraulic loading rate (HLR) was 375mmd and C/N ratio was 2 in both periods. Samples for microbial characterization were collected from the filter medium (top and bottom layers) of the wetland, water influent and effluent at the end of Periods I (Jun-Oct) and II (Nov-Jan). The combination of qPCR and high-throughput sequencing (NGS, MiSeq) assessment at DNA and RNA level of 16S rRNA genes and nitrogen-based functional genes (amoA and nosZ-clade I) revealed that nitrification was associated both with ammonia-oxidizing bacteria (AOB) (Nitrosospira) and ammonia-oxidizing archaea (AOA) (Nitrososphaeraceae), and nitrite-oxidizing bacteria (NOB) such as Nitrobacter. Considering the active abundance (based in amoA transcripts), the AOA population revealed to be more stable than AOB in both periods and depths of the wetland, being less affected by the organic loading rate (OLR). Although denitrifying bacteria (nosZ copies and transcripts) were actively detected in all depths, the denitrification process was low (removal of 2gTNmd for both periods) concomitant with NO-N accumulation in the effluent. Overall, AOA, AOB and denitrifying bacteria (nosZ) were observed to be more active in bottom than in top layer at lower OLR (Period II). A proper design of OLR and HLR seems to be crucial to control the activity of microbial biofilms in VF wetlands on the basis of oxygen, organic-carbon and NO-N forms, to improve their capacity for total nitrogen removal.

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Section: Introductionmentioning

confidence: 99%

Unraveling the active microbial populations involved in nitrogen utilization in a vertical subsurface flow constructed wetland treating urban wastewater

Pelissari

Guivernau

Viñas

et al. 2017

Science of The Total Environment

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“…Proteobacteria was the most dominant phylum in almost all samples, accounting for more than 50% of the total detected reads (except Day1 and SF), followed by Bacteroidetes, Actinobacteria, Verrucomicrobia, Planctomycetes, Patescibacteria and Cyanobacteria. These phyla were also reported as dominant phylum in other CW systems [50,51]. Besides, more than half of the Proteobacteria were from class of Gammaproteobacteria.…”

Section: Microbial Community Structural Changes During Test Operationmentioning

confidence: 69%

“…Proteobacterial microorganisms were commonly found in CW and sand filtration systems [50,[58][59][60] and considered playing important roles in the biodegradation or biotransformation of organic compounds in surface water CW systems or filtration systems [59,61]. Therefore, Proteobacteria might have helped to biodegrade the target PPCP compounds and some microorganisms e.g.…”

Section: Dynamic Otus Changes Of Proteobacteriamentioning

confidence: 99%

Physico-chemical and biological aspects of a serially connected lab-scale constructed wetland-stabilization tank-GAC slow sand filtration system during removal of selected PPCPs

Han

Brandt

et al. 2019

Chemical Engineering Journal

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A serially connected lab-scale Greater duckweed constructed wetland (CW)stabilization tank (ST)-GAC sandwich slow sand filtration system was tested to remove four widely detected pharmaceuticals and personal care products (PPCPs) compounds from natural water with a spiked concentration of 25 μg/L. High removals were achieved rapidly (93.5~100%), being on average 95.9%, 99.1%, 98.1% and 97.4% for DEET, paracetamol, caffeine and triclosan (n=3), respectively. Except for DEET, no significant difference was observed between overall removals with and without artificial aeration in CW tank (p>0.05), showing good stability of the system. COD was considerably removed under aeration and final TOC removal was 64.7%. No nitrite, nitrate, ammonia and phosphate were detected at the test end (day 26). The microbial community structure in three connected units of the tested system showed differences and good stability after the aerators were removed. Proteobacteria was the most dominant phylum among the 47 phyla found. Microbes attaching to the Greater duckweed contributed more to the microbial community structure in CW and ST than *Revised Manuscript (clean for typesetting) Click here to view linked References original natural water. However, at the end of the run, the structural differences among three units decreased. After aeration stopped, phylum composition became more stable in ST tank while CW tank showed small structural variation throughout the test. Various correlations were found between detected phyla, among which Proteobacteria and Bacteroidetes showed a significant negative correlation (R=-0.73, p<0.001, FDR corrected). Good removal of target PPCPs and stability of the system show the potential applicability of this combined treatment process.

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“…Microorganisms belonging to the phyla Proteobacteria and Firmicutes are able to degrade a variety of organic compounds, which accounts for the effective removal of DOC [14]. For example, the genera Pseudomonas, Acinetobacter and Bacillus have been linked to the biological degradation of organic and natural compounds [57,58]; however, no significant correlations were observed between these genera and DOC in the LEW, except for the genus Acinetobacter. Wetlands play an important role in methane emissions, and the methanogenic microorganisms involved in this process are also assumed to play vital roles in degrading organic carbon [59].…”

Section: Potential Roles Of the Dominant Bacterial And Archaeal Taxa mentioning

confidence: 99%

Planktonic Bacterial and Archaeal Communities in an Artificially Irrigated Estuarine Wetland: Diversity, Distribution, and Responses to Environmental Parameters

et al. 2020

Microorganisms

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Bacterial and archaeal communities play important roles in wetland ecosystems. Although the microbial communities in the soils and sediments of wetlands have been studied extensively, the comprehensive distributions of planktonic bacterial and archaeal communities and their responses to environmental variables in wetlands remain poorly understood. The present study investigated the spatiotemporal characteristics of the bacterial and archaeal communities in the water of an artificially irrigated estuarine wetland of the Liaohe River, China, explored whether the wetland effluent changed the bacterial and archaeal communities in the Liaohe River, and evaluated the driving environmental factors. Within the study, 16S rRNA quantitative PCR methods and MiSeq high-throughput sequencing were used. The bacterial and archaeal 16S rRNA gene abundances showed significant temporal variation. Meanwhile, the bacterial and archaeal structures showed temporal but not spatial variation in the wetland and did not change in the Liaohe River after wetland drainage. Moreover, the bacterial communities tended to have higher diversity in the wetland water in summer and in the scarce zone, while a relatively higher diversity of archaeal communities was found in autumn and in the intensive zone. DO, pH and PO4-P were proven to be the essential environmental parameters shaping the planktonic bacterial and archaeal community structures in the Liaohe River estuarine wetland (LEW). The LEW had a high potential for methanogenesis, which could be reflected by the composition of the microbial communities.

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Influence of substrate type on microbial community structure in vertical-flow constructed wetland treating polluted river water

Cited by 94 publications

References 63 publications

Unraveling the active microbial populations involved in nitrogen utilization in a vertical subsurface flow constructed wetland treating urban wastewater

Unraveling the active microbial populations involved in nitrogen utilization in a vertical subsurface flow constructed wetland treating urban wastewater

Physico-chemical and biological aspects of a serially connected lab-scale constructed wetland-stabilization tank-GAC slow sand filtration system during removal of selected PPCPs

Planktonic Bacterial and Archaeal Communities in an Artificially Irrigated Estuarine Wetland: Diversity, Distribution, and Responses to Environmental Parameters

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