Shifts in mercury methylation across a peatland chronosequence: From sulfate reduction to methanogenesis and syntrophy

[Display omitted] •Mercury methylation rates are higher in younger peatlands.•Mercury methylation was fueled mainly by sulfate reduction in young peatlands.•Methanogensis and syntrophic metabolism get more important for mercury methylation as peatlands age.•Methylmercury degradation shifts from biot...

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Bibliographic Details
Published in:Journal of hazardous materials 2020-04, Vol.387, p.121967, Article 121967
Main Authors: Hu, Haiyan, Wang, Baolin, Bravo, Andrea G., Björn, Erik, Skyllberg, Ulf, Amouroux, David, Tessier, Emmanuel, Zopfi, Jakob, Feng, Xinbin, Bishop, Kevin, Nilsson, Mats B., Bertilsson, Stefan
Format: Article
Language:English
Subjects:
Biodiversity and Ecology
Chemical Sciences
Chronology as Topic
Chronosequence
Demethylation
Environmental Pollutants - chemistry
Environmental Pollutants - metabolism
Environmental Sciences
Mercury
Mercury - chemistry
Mercury - metabolism
Methylation
Methylmercury Compounds - metabolism
Miljövetenskap
Other
Oxidation-Reduction
Peatland
Soil - chemistry
Soil Microbiology
Sulfates - chemistry
Sulfates - metabolism
Wetlands
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Summary:[Display omitted] •Mercury methylation rates are higher in younger peatlands.•Mercury methylation was fueled mainly by sulfate reduction in young peatlands.•Methanogensis and syntrophic metabolism get more important for mercury methylation as peatlands age.•Methylmercury degradation shifts from biotic to abiotic processes along the peatland chronosequence. Peatlands are globally important ecosystems where inorganic mercury is converted to bioaccumulating and highly toxic methylmercury, resulting in high risks of methylmercury exposure in adjacent aquatic ecosystems. Although biological mercury methylation has been known for decades, there is still a lack of knowledge about the organisms involved in mercury methylation and the drivers controlling their methylating capacity. In order to investigate the metabolisms responsible for mercury methylation and methylmercury degradation as well as the controls of both processes, we studied a chronosequence of boreal peatlands covering fundamentally different biogeochemical conditions. Potential mercury methylation rates decreased with peatland age, being up to 53 times higher in the youngest peatland compared to the oldest. Methylation in young mires was driven by sulfate reduction, while methanogenic and syntrophic metabolisms became more important in older systems. Demethylation rates were also highest in young wetlands, with a gradual shift from biotic to abiotic methylmercury degradation along the chronosequence. Our findings reveal how metabolic shifts drive mercury methylation and its ratio to demethylation as peatlands age.
ISSN:0304-3894
1873-3336
1873-3336
DOI:10.1016/j.jhazmat.2019.121967