Potential for Mercury Reduction by Microbes in the High Arctic▿

The contamination of polar regions due to the global distribution of anthropogenic pollutants is of great concern because it leads to the bioaccumulation of toxic substances, methylmercury among them, in Arctic food chains. Here we present the first evidence that microbes in the high Arctic possess...

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Bibliographic Details
Published in:Applied and Environmental Microbiology
Main Authors: Poulain, Alexandre J., Ní Chadhain, Sinéad M., Ariya, Parisa A., Amyot, Marc, Garcia, Edenise, Campbell, Peter G. C., Zylstra, Gerben J., Barkay, Tamar
Format: Text
Language:English
Published: American Society for Microbiology 2007
Subjects:
Environmental Microbiology
Arctic
Arctic microbes
Online Access:http://www.ncbi.nlm.nih.gov/pmc/articles/PMC1855672
http://www.ncbi.nlm.nih.gov/pubmed/17293515
https://doi.org/10.1128/AEM.02701-06
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Summary:The contamination of polar regions due to the global distribution of anthropogenic pollutants is of great concern because it leads to the bioaccumulation of toxic substances, methylmercury among them, in Arctic food chains. Here we present the first evidence that microbes in the high Arctic possess and express diverse merA genes, which specify the reduction of ionic mercury [Hg(II)] to the volatile elemental form [Hg(0)]. The sampled microbial biomass, collected from microbial mats in a coastal lagoon and from the surface of marine macroalgae, was comprised of bacteria that were most closely related to psychrophiles that had previously been described in polar environments. We used a kinetic redox model, taking into consideration photoredox reactions as well as mer-mediated reduction, to assess if the potential for Hg(II) reduction by Arctic microbes can affect the toxicity and environmental mobility of mercury in the high Arctic. Results suggested that mer-mediated Hg(II) reduction could account for most of the Hg(0) that is produced in high Arctic waters. At the surface, with only 5% metabolically active cells, up to 68% of the mercury pool was resolved by the model as biogenic Hg(0). At a greater depth, because of incident light attenuation, the significance of photoredox transformations declined and merA-mediated activity could account for up to 90% of Hg(0) production. These findings highlight the importance of microbial redox transformations in the biogeochemical cycling, and thus the toxicity and mobility, of mercury in polar regions.

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