Methanogens: Principal Methylators of Mercury in Lake Periphyton

Hamelin, Stéphanie; Amyot, Marc; Barkay, Tamar; Wang, Yanping; Planas, Dolors

doi:10.1021/es2010072

Cited by 267 publications

(223 citation statements)

References 59 publications

(108 reference statements)

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“…There are several possible environmental sources of MeHg, but few studies have measured production rates from these various sources in Arctic environments, especially in marine settings. In temperate marine and fresh water environments, wetlands and benthic sediments are major MeHg sources and this is thought to be due to the activity of sulfate-and iron-reducing bacteria [140][141][142] and methanogens [143] in these anoxic environments. MeHg can also be produced during detrital remineralisation in oxic marine waters, associated with mid-depth nutrient maxima and oxygen utilisation.…”

Section: Controls On Arctic Food Chain Mercury Accumulation By Methylmentioning

confidence: 99%

The fate of mercury in Arctic terrestrial and aquatic ecosystems, a review

Douglas

Loseto²,

Macdonald³

et al. 2012

Environ. Chem.

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118

145

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Environmental context. Mercury, in its methylated form, is a neurotoxin that biomagnifies in marine and terrestrial foodwebs leading to elevated levels in fish and fish-eating mammals worldwide, including at numerous Arctic locations. Elevated mercury concentrations in Arctic country foods present a significant exposure risk to Arctic people. We present a detailed review of the fate of mercury in Arctic terrestrial and marine ecosystems, taking into account the extreme seasonality of Arctic ecosystems and the unique processes associated with sea ice and Arctic hydrology.Abstract. This review is the result of a series of multidisciplinary meetings organised by the Arctic Monitoring and Assessment Programme as part of their 2011 Assessment 'Mercury in the Arctic'. This paper presents the state-of-the-art knowledge on the environmental fate of mercury following its entry into the Arctic by oceanic, atmospheric and terrestrial pathways. Our focus is on the movement, transformation and bioaccumulation of Hg in aquatic (marine and fresh water) and terrestrial ecosystems. The processes most relevant to biological Hg uptake and the potential risk associated with Hg exposure in wildlife are emphasised. We present discussions of the chemical transformations of newly deposited or transported Hg in marine, fresh water and terrestrial environments and of the movement of Hg from air, soil and water environmental compartments into food webs. Methylation, a key process controlling the fate of Hg in most ecosystems, and the role of trophic processes in controlling Hg in higher order animals are also included. Case studies on Eastern Beaufort Sea beluga (Delphinapterus leucas) and landlocked Arctic char (Salvelinus alpinus) are presented as examples of the relationship between ecosystem trophic processes and biologic Hg levels. We examine whether atmospheric mercury depletion events (AMDEs) contribute to increased Hg levels in Arctic biota and provide information on the links between organic carbon and Hg speciation, dynamics and bioavailability. Long-term sequestration of Hg into non-biological archives is also addressed. The review concludes by identifying major knowledge gaps in our understanding, including:(1) the rates of Hg entry into marine and terrestrial ecosystems and the rates of inorganic and MeHg uptake by Arctic microbial and algal communities; (2) the bioavailable fraction of AMDE-related Hg and its rate of accumulation by biota and (3) the fresh water and marine MeHg cycle in the Arctic, especially the marine MeHg cycle.

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Section: Controls On Arctic Food Chain Mercury Accumulation By Methylmentioning

confidence: 99%

The fate of mercury in Arctic terrestrial and aquatic ecosystems, a review

Douglas

Loseto²,

Macdonald³

et al. 2012

Environ. Chem.

Self Cite

118

145

View full text Add to dashboard Cite

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“…The highest MeHg production occurs mostly in sediments at the oxic/anoxic transition zones during the anaerobic degradation of natural organic matter (Compeau and Bartha 1985;Gray et al 2004;Bravo et al 2014). Several guilds of bacteria are known to methylate IHg, notably iron-reducing bacteria (FeRB), sulfate-reducing bacteria (SRB), and methanogens (Fleming et al 2006;Kerin et al 2006;Gilmour et al 2011Gilmour et al , 2013Hamelin et al 2011;Yu et al 2013). The specific mechanisms and metabolic pathways involved in Hg methylation remains undefined, but two genes in particular (cluster hgcA and hgcB) have been shown to be required for Hg methylation (Gilmour et al 2013;Parks et al 2013).…”

Section: Introductionmentioning

confidence: 99%

Persistent Hg contamination and occurrence of Hg-methylating transcript (hgcA) downstream of a chlor-alkali plant in the Olt River (Romania)

Bravo

Loizeau

Dranguet

et al. 2015

Environ Sci Pollut Res

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Chlor-alkali plants using mercury (Hg) cell technology are acute point sources of Hg pollution in the aquatic environment. While there have been recent efforts to reduce the use of Hg cells, some of the emitted Hg can be transformed to neurotoxic methylmercury (MeHg). Here, we aimed (i) to study the dispersion of Hg in four reservoirs located downstream of a chlor-alkali plant along the Olt River (Romania) and (ii) to track the activity of bacterial functional genes involved in Hg methylation. Total Hg (THg) concentrations in water and sediments decreased successively from the initial reservoir to downstream reservoirs. Suspended fine size particles and seston appeared to be responsible for the transport of THg into downstream reservoirs, while macrophytes reflected the local bioavailability of Hg. The concentration and proportion of MeHg were correlated with THg, but were not correlated with bacterial activity in sediments, while the abundance of hgcA transcript correlated with organic matter and Cl− concentration, indicating the importance of Hg bioavailability in sediments for Hg methylation. Our data clearly highlights the importance of considering Hg contamination as a legacy pollutant since there is a high risk of continued Hg accumulation in food webs long after Hg-cell phase out

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“…La correlación positiva entre la producción de metilmercurio y la actividad de bacterias reductoras de SO 4 2-y Fe 3+ tiene una base molecular consistente en la presencia de los genes hgcA, que codifica una proteína con un grupo prostético corrinoide, y hgcB, que codifica una proteína con 2 centros 4Fe4S, necesarias para la metilación del mercurio en Desulfovibrio desulfuricans ND 132 y Geobacter sulfurreducens PCA (Parks et al, 2013). La metanogénesis también está relacionada con la producción de metilmercurio, ampliando la interconexión entre ciclos biogeoquímicos y los problemas de contaminación ambiental (Hamelin et al, 2011).…”

Section: El Ciclo Del Azufre/hierrounclassified

Acerca de la biotecnología ambiental

Blasco¹,

Rodríguez²

2014

Arbor

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RESUMEN: La Biotecnología ambiental trata de corregir los desequilibrios causados en el medio ambiente por actividades industriales que alteran los ecosistemas naturales mediante contaminación química o biológica y que también afectan a los grandes ciclos biogeoquímicos en la biosfera, mayoritariamente catalizados por seres vivos, entre los que los microrganismos juegan un papel esencial. Las desviaciones en los balances de compuestos carbonados, nitrogenados y azufrados atmosféricos pueden causar fenómenos de gran complejidad como el calentamiento global, la destrucción de la capa de ozono, la contaminación ambiental o la lluvia ácida. Por otra parte, las interacciones de los microorganismos entre sí y con el medio, desconocidas en su mayor parte, tiene importantes repercusiones en la generación y persistencia de especies químicas que, depositadas en las cadenas tróficas, son altamente tóxicas para los organismos vivos. Para atajar estos problemas es necesario avanzar en el conocimiento a nivel molecular de la ecología microbiana y del funcionamiento de los ciclos biogeoquímicos, aunque no es menos necesario desarrollar tecnologías para la eliminación de contaminantes industriales in situ y ex situ, evitar su producción y utilización incontroladas así como corregir las actuaciones desequilibrantes, actuales o futuras, de la biogeoquímica planetaria.

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Methanogens: Principal Methylators of Mercury in Lake Periphyton

Cited by 267 publications

References 59 publications

The fate of mercury in Arctic terrestrial and aquatic ecosystems, a review

The fate of mercury in Arctic terrestrial and aquatic ecosystems, a review

Persistent Hg contamination and occurrence of Hg-methylating transcript (hgcA) downstream of a chlor-alkali plant in the Olt River (Romania)

Acerca de la biotecnología ambiental

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