Temporal analysis of the microbial communities in a nitrate-contaminated aquifer and the co-occurrence of anammox, n-damo and nitrous-oxide reducing bacteria

Groundwater-N pollution derives from agricultural and urban activities, and compromises water quality in shallow aquifers, putting human and environmental health at risk. Nonetheless, subsurface microbiota can transform dissolved inorganic nitrogen into N2. In this study, we surveyed the microbial c...

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Bibliographic Details
Published in:Journal of contaminant hydrology 2020-10, Vol.234, p.103657, Article 103657
Main Authors: Aguilar-Rangel, Eduardo J., Prado, Blanca L., Vásquez-Murrieta, María Soledad, los Santos, Paulina Estrada-de, Siebe, Christina, Falcón, Luisa I., Santillán, Jazmín, Alcántara-Hernández, Rocío J.
Format: Article
Language:English
Subjects:
Ammonium Compounds
Anaerobic ammonium oxidation
Anaerobiosis
Bacteria - genetics
Denitrification
Groundwater
Groundwater bacteria
Humans
Methane
Microbiota
Nitrates
Nitrite-dependent anaerobic methane oxidation
Nitrogen transformation
Nitrous Oxide
Nitrous oxide reduction
Oxidation-Reduction
RNA, Ribosomal, 16S - genetics
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Summary:Groundwater-N pollution derives from agricultural and urban activities, and compromises water quality in shallow aquifers, putting human and environmental health at risk. Nonetheless, subsurface microbiota can transform dissolved inorganic nitrogen into N2. In this study, we surveyed the microbial community of a shallow aquifer by sampling one well, one piezometer and a spring within an agricultural area that receives N-inputs of more than 700 kg/ha per year through irrigation with wastewater. The survey was conducted during a year with a 16S rRNA next-gen approach. In parallel, we quantified the number of gene copies and transcripts related to anaerobic ammonium oxidation (anammox, hzo), nitrite-dependent anaerobic methane oxidation (n-damo, nod and pmoA) and nitrous oxide reduction (last step of denitrification, nosZ), during the dry and rainy seasons. Our results showed that the groundwater samples had 17.7 to 22.5 mg/L of NO3−-N. The bacterial and archaeal community structure was distinctive at each site, and it remained relatively stable over time. We verified the co-occurrence of N-transforming bacteria, which was correlated with the concentration of NO2−/NO3− and ORP/DO values (DO: ~3.0 mg/L). Our analyses suggest that these conditions may allow the presence of nitrifying microorganisms which can couple with anammox, n-damo and denitrifying bacteria in interrelated biogeochemical pathways. Gene density (as the number of gene copies per litre) was lower in the rainy season than in the dry season, possibly due to dilution by rainwater infiltration. Yet, the numbers of hzo gene copies here found were similar to those reported in oceanic oxygen minimum zones and in a carbonate-rock aquifer. The transcript sequences showed that Candidatus Brocadia spp. (anammox), Candidatus Methylomirabilis spp. (n-damo) and autotrophic denitrifying Betaproteobacteria coexist in the groundwater environment, with the potential to attenuate the concentration of dissolved inorganic nitrogen by reducing it to N2 rather than N2O; delivering thus, an important ecosystem service to remove contaminants. [Display omitted] •Microbial communities in groundwater are relatively stable over time.•Anammox, n-damo and nitrous oxide-reducing bacteria can coexist in groundwater.•The presence of N-transforming bacteria is related to NO3− and ORP/DO conditions.•n-damo bacteria might be relevant in aquifers.
ISSN:0169-7722
1873-6009
DOI:10.1016/j.jconhyd.2020.103657