Methylmercury degradation by hot spring sulfur-linked microbial communities as a dominant pathway in regulating mercury speciation

Jin Ping Xue; Rosanna Margalef-Marti; Aubin Thibault De Chanvalon; Emmanuel Tessier; Rémy Guyoneaud; Zoyne Pedrero; Claire Gassie; Mathieu Sebilo; Michael S. Bank; David Amouroux

doi:10.1016/j.watres.2024.122652

Methylmercury degradation by hot spring sulfur-linked microbial communities as a dominant pathway in regulating mercury speciation

Jin Ping Xue
, Rosanna Margalef-Marti
, Aubin Thibault De Chanvalon
, Emmanuel Tessier
, Rémy Guyoneaud
, Zoyne Pedrero
, Claire Gassie
, Mathieu Sebilo
, Michael S. Bank
, David Amouroux

Research output: Contribution to journal › Article › peer-review

5 Scopus citations

Abstract

Sulfidic hot springs harbor unique microbial communities and are important in mercury (Hg) species transformations, although the fine scale drivers of these processes remain poorly understood. Here we studied Hg speciation in water, biofilms, and sediment across three sampling seasons in a French sulfidic hot spring with low Hg concentrations. Microbial Hg species methylation and demethylation potentials were evaluated using incubation experiments with species-specific Hg isotope tracers. Temporal variation in inorganic Hg (iHg) and methylmercury (MeHg) concentrations in water, biofilm, and sediment was observed. The incubation of microbial communities in biofilms and sediment under dark conditions exhibited low iHg methylation potentials, whereas a significant extent of biotic MeHg demethylation to oxidized iHg was found in relation to MeHg concentrations. Results from microbial diversity (16S rDNA) and the metabolic inhibition experiments suggest an important role of sulfur-linked bacterial metabolism dynamics. Specifically, sulfate-reducers and anoxygenic phototrophs were important factors in the regulation of MeHg concentrations in our study site. Overall, the observed dominance of microbial MeHg demethylation demonstrates a strong Hg detoxification capacity in sulfidic aquatic environments.

Original language	English
Article number	122652
Journal	Water Research
Volume	268
DOIs	https://doi.org/10.1016/j.watres.2024.122652
State	Published - Jan 1 2025
Externally published	Yes

Funding

This work has been supported by Université de Pau et de Pays de l'Adour (UPPA) in the framework of the Energy Environment Solutions (E2S-UPPA) initiative of excellence (I-SITES, PIA France) for the Scientific Hub ‘Metals in Environmental Systems Microbiology (MeSMic)’ and by the French National Programme EC2CO (Hybige) in the context of the Fe/N-ICS project. We extend our gratitude to Céline Lavergne for her valuable suggestions during the preparation of this manuscript. J. X. acknowledges the doctoral fellowship funded by I-site E2S UPPA . R.M.M. is grateful to the Spanish Government and University of Barcelona for the awarded Margarita Salas grant (Next Generation EU funds) .

Keywords

Mercury speciation
Methylmercury demethylation
Microbial communities
Stable isotope tracers
Sulfidic hot spring

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10.1016/j.watres.2024.122652

Cite this

Xue, J. P., Margalef-Marti, R., Thibault De Chanvalon, A., Tessier, E., Guyoneaud, R., Pedrero, Z., Gassie, C., Sebilo, M., Bank, M. S., & Amouroux, D. (2025). Methylmercury degradation by hot spring sulfur-linked microbial communities as a dominant pathway in regulating mercury speciation. Water Research, 268, Article 122652. https://doi.org/10.1016/j.watres.2024.122652

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title = "Methylmercury degradation by hot spring sulfur-linked microbial communities as a dominant pathway in regulating mercury speciation",

abstract = "Sulfidic hot springs harbor unique microbial communities and are important in mercury (Hg) species transformations, although the fine scale drivers of these processes remain poorly understood. Here we studied Hg speciation in water, biofilms, and sediment across three sampling seasons in a French sulfidic hot spring with low Hg concentrations. Microbial Hg species methylation and demethylation potentials were evaluated using incubation experiments with species-specific Hg isotope tracers. Temporal variation in inorganic Hg (iHg) and methylmercury (MeHg) concentrations in water, biofilm, and sediment was observed. The incubation of microbial communities in biofilms and sediment under dark conditions exhibited low iHg methylation potentials, whereas a significant extent of biotic MeHg demethylation to oxidized iHg was found in relation to MeHg concentrations. Results from microbial diversity (16S rDNA) and the metabolic inhibition experiments suggest an important role of sulfur-linked bacterial metabolism dynamics. Specifically, sulfate-reducers and anoxygenic phototrophs were important factors in the regulation of MeHg concentrations in our study site. Overall, the observed dominance of microbial MeHg demethylation demonstrates a strong Hg detoxification capacity in sulfidic aquatic environments.",

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AU - Margalef-Marti, Rosanna

AU - Thibault De Chanvalon, Aubin

AU - Tessier, Emmanuel

AU - Guyoneaud, Rémy

AU - Pedrero, Zoyne

AU - Gassie, Claire

AU - Sebilo, Mathieu

AU - Bank, Michael S.

AU - Amouroux, David

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N2 - Sulfidic hot springs harbor unique microbial communities and are important in mercury (Hg) species transformations, although the fine scale drivers of these processes remain poorly understood. Here we studied Hg speciation in water, biofilms, and sediment across three sampling seasons in a French sulfidic hot spring with low Hg concentrations. Microbial Hg species methylation and demethylation potentials were evaluated using incubation experiments with species-specific Hg isotope tracers. Temporal variation in inorganic Hg (iHg) and methylmercury (MeHg) concentrations in water, biofilm, and sediment was observed. The incubation of microbial communities in biofilms and sediment under dark conditions exhibited low iHg methylation potentials, whereas a significant extent of biotic MeHg demethylation to oxidized iHg was found in relation to MeHg concentrations. Results from microbial diversity (16S rDNA) and the metabolic inhibition experiments suggest an important role of sulfur-linked bacterial metabolism dynamics. Specifically, sulfate-reducers and anoxygenic phototrophs were important factors in the regulation of MeHg concentrations in our study site. Overall, the observed dominance of microbial MeHg demethylation demonstrates a strong Hg detoxification capacity in sulfidic aquatic environments.

AB - Sulfidic hot springs harbor unique microbial communities and are important in mercury (Hg) species transformations, although the fine scale drivers of these processes remain poorly understood. Here we studied Hg speciation in water, biofilms, and sediment across three sampling seasons in a French sulfidic hot spring with low Hg concentrations. Microbial Hg species methylation and demethylation potentials were evaluated using incubation experiments with species-specific Hg isotope tracers. Temporal variation in inorganic Hg (iHg) and methylmercury (MeHg) concentrations in water, biofilm, and sediment was observed. The incubation of microbial communities in biofilms and sediment under dark conditions exhibited low iHg methylation potentials, whereas a significant extent of biotic MeHg demethylation to oxidized iHg was found in relation to MeHg concentrations. Results from microbial diversity (16S rDNA) and the metabolic inhibition experiments suggest an important role of sulfur-linked bacterial metabolism dynamics. Specifically, sulfate-reducers and anoxygenic phototrophs were important factors in the regulation of MeHg concentrations in our study site. Overall, the observed dominance of microbial MeHg demethylation demonstrates a strong Hg detoxification capacity in sulfidic aquatic environments.

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KW - Methylmercury demethylation

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KW - Stable isotope tracers

KW - Sulfidic hot spring

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Methylmercury degradation by hot spring sulfur-linked microbial communities as a dominant pathway in regulating mercury speciation

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