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RESEARCH PRODUCT
Human-Driven Microbiological Contamination of Benthic and Hyporheic Sediments of an Intermittent Peri-Urban River Assessed from MST and 16S rRNA Genetic Structure Analyses
Michèle GourmelonLaurence MarjoletBenoit CournoyerMarylise CottetSébastien RibunRomain MartiJean Baptiste AubinS PetitPascal BreilCéline ColinonLaurent Schmittsubject
0301 basic medicinePollutionMicrobiology (medical)benthic and hyporheic sedimentsmedia_common.quotation_subject[SDV]Life Sciences [q-bio]030106 microbiologyFECA CONTAMINATIONBiologyMicrobiologyarn ribosomal 16s03 medical and health sciencesperi-urban riverzone hyporhéique14. Life underwatermedia_commonOriginal ResearchEcologyBENTHIC AND HYPORHEIC SEDIMENTSMICROBIAL COMMUNITYHIGH THROUGH PUT SEQUENCING (HTS)zone benthiquebiology.organism_classification6. Clean waterFecal coliformAquabacteriumhigh throughput sequencing (HTS)Microbial population biology13. Climate actionBenthic zonefecal contaminationperi-urban river;benthic and hyporheic sediments;microbial community;high throughput sequencing (HTS);fecal contaminationcontamination biologiquePERI-URBAN RIVERCombined sewermicrobial communitySurface waterFlavobacteriumdescription
International audience; Rivers are often challenged by fecal contaminations. The barrier effect of sediments against fecal bacteria was investigated through the use of a microbial source tracking (MST) toolbox, and by Next Generation Sequencing (NGS) of V5-V6 16S rRNA gene (rrs) sequences. Non-metric multi-dimensional scaling analysis of V5-V6 16S rRNA gene sequences differentiated bacteriomes according to their compartment of origin i.e., surface water against benthic and hyporheic sediments. Classification of these reads showed the most prevalent operating taxonomic units (OTU) to be allocated to Flavobacterium and Aquabacterium. Relative numbers of Gaiella, Haliangium, and Thermoleophilum OTU matched the observed differentiation of bacteriomes according to river compartments. OTU patterns were found impacted by combined sewer overflows (CSO) through an observed increase in diversity from the sewer to the hyporheic sediments. These changes appeared driven by direct transfers of bacterial contaminants from wastewaters but also by organic inputs favoring previously undetectable bacterial groups among sediments. These NGS datasets appeared more sensitive at tracking community changes than MST markers. The human-specific MST marker HF183 was strictly detected among CSO-impacted surface waters and not river bed sediments. The ruminant-specific DNA marker was more broadly distributed but intense bovine pollution was required to detect transfers from surface water to benthic and hyporheic sediments. Some OTU showed distribution patterns in line with these MST datasets such as those allocated to the Aeromonas, Acinetobacter, and Pseudomonas. Fecal indicators (Escherichia coli and total thermotolerant coliforms) were detected all over the river course but their concentrations were not correlated with MST ones. Overall, MST and NGS datasets suggested a poor colonization of river sediments by bovine and sewer bacterial contaminants. No environmental outbreak of these bacterial contaminants was detected.
| year | journal | country | edition | language |
|---|---|---|---|---|
| 2017-01-24 |