Microbial antibiotic resistance genes across an anthropogenic gradient in a Canadian High Arctic watershed

Antibiotic resistance is one of the biggest challenges to public health. While the disco v ery of antibiotics has decreased pathogen-caused mort alit y, the o v er use of these dr ugs has resulted in the increased transfer and e v olution of antibiotic resistance genes (AR Gs) in bacteria. AR Gs nat...

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Bibliographic Details
Published in:Sustainable Microbiology
Main Authors: Provencher, Juliette, George, Paul B. L., Thaler, Mary, Vincent, Warwick F., Duchaine, Caroline, Culley, Alexander, Girard, Catherine
Format: Other/Unknown Material
Language:English
Published: Oxford University Press 2025
Subjects:
Antimicrobial resistance (AMR)
Microbiology
Bioaerosols
Microbial mats
Lakes
Arctic
Anthropogenic contamination
Bactéries pathogènes > Résistance aux médicaments
Bassins hydrographiques
Aérosols > Microbiologie
Mattes microbiennes
Êtres humains > Influence sur la nature
Eaux usées > Microbiologie
Canada
Arctique*
Online Access:https://hdl.handle.net/20.500.11794/158463
https://doi.org/10.1093/sumbio/qvae021
Description
Summary:Antibiotic resistance is one of the biggest challenges to public health. While the disco v ery of antibiotics has decreased pathogen-caused mort alit y, the o v er use of these dr ugs has resulted in the increased transfer and e v olution of antibiotic resistance genes (AR Gs) in bacteria. AR Gs naturally occur in wild bacterial communities, but are also found in increased concentrations in environments contaminated by wastewater effluent. Although such ARGs are relatively well described in temperate environments, little is known about the distribution and dissemination of these genes in the Arctic. We characterized the ARGs in microbial communities from aerosols, lakes and microbial mats around a remote Arctic hamlet using metagenomic approaches. Specific objectives were to (i) compare ARGs across habitats, (ii) to characterize ARG populations along a continuum of anthropogenically influenced environments, and (iii) to identify ARGs of viral origin. We identified ARGs in all habitats throughout the watershed, and found that microbial mats in the most impacted area had the highest diversity of ARGs relative to uncontaminated sites, which may be a remnant signal of w aste w ater effluent inputs in the area during the 20th century. Although we identified ARGs predominantly in bacterial genomes, our data suggests that mimiviruses may also harbor ARGs.

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