Recent advances in the study of mercury methylation in aquatic systems

Paranjape, Avnee R.; Hall, Britt D.

doi:10.1139/facets-2016-0027

Cited by 121 publications

(98 citation statements)

References 210 publications

(282 reference statements)

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“…The relatively large increase in surface water MeHg in response to increased (SO 4 ) Depl in this experiment supports the assumption that MSR was responsible for most of the observed production of MeHg. It is likely that increased SO 4 loading to low‐SO 4 aquatic systems with organic sediment will result in increased Hg methylation even though the relative importance of Hg methylation in the environment by different groups of bacteria is still a subject of debate (Paranjape & Hall, ).…”

Section: Resultsmentioning

confidence: 99%

Increase in Nutrients, Mercury, and Methylmercury as a Consequence of Elevated Sulfate Reduction to Sulfide in Experimental Wetland Mesocosms

et al. 2017

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Microbial sulfate reduction (MSR) in both freshwater and marine ecosystems is a pathway for the decomposition of sedimentary organic matter (OM) after oxygen has been consumed. In experimental freshwater wetland mesocosms, sulfate additions allowed MSR to mineralize OM that would not otherwise have been decomposed. The mineralization of OM by MSR increased surface water concentrations of ecologically important constituents of OM: dissolved inorganic carbon, dissolved organic carbon, phosphorus, nitrogen, total mercury, and methylmercury. Increases in surface water concentrations, except for methylmercury, were in proportion to cumulative sulfate reduction, which was estimated by sulfate loss from the surface water into the sediments. Stoichiometric analysis shows that the increases were less than would be predicted from ratios with carbon in sediment, indicating that there are processes that limit P, N, and Hg mobilization to, or retention in, surface water. The highest sulfate treatment produced high levels of sulfide that retarded the methylation of mercury but simultaneously mobilized sedimentary inorganic mercury into surface water. As a result, the proportion of mercury in the surface water as methylmercury peaked at intermediate pore water sulfide concentrations. The mesocosms have a relatively high ratio of wall and sediment surfaces to the volume of overlying water, perhaps enhancing the removal of nutrients and mercury to periphyton. The presence of wild rice decreased sediment sulfide concentrations by 30%, which was most likely a result of oxygen release from the wild rice roots. An additional consequence of the enhanced MSR was that sulfate additions produced phytotoxic levels of sulfide in sediment pore water.

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Section: Resultsmentioning

confidence: 99%

Increase in Nutrients, Mercury, and Methylmercury as a Consequence of Elevated Sulfate Reduction to Sulfide in Experimental Wetland Mesocosms

et al. 2017

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“…Comprehensive evaluations of the chemical and physical processes that govern Hg distribution and fate among the major environmental compartments can be found in the literature (Chételat et al ; Sundseth et al ; Kim et al ; Bjørklund et al ; Dranguet et al ; Paranjape and Hall ; Klapstein and Driscoll ). Briefly, in the water column Hg II can (1) be reduced to Hg 0 and reemitted back to the atmosphere, (2) methylated to the organic form MMHg, or (3) bind to organic matter (OM) as well as inorganic particles and directly deposit to bottom sediments.…”

Section: The Mercury Problemmentioning

confidence: 99%

“…Besides the presence and diversity of Hg II methylating microbes, Hg II methylation depends on the amount of Hg II bioavailable for methylation (Schaefer et al ; Jonsson et al ), which is determined by chemical speciation of Hg II , solubility of the Hg‐S particles (Hsu‐Kim et al ; Liem‐Nguyen et al ) as well as the availability of electron donors and acceptors for Hg II methylating microorganisms (Desrochers et al ). Hg II methylation is a bio‐physico‐chemical conundrum because both the amount of Hg II available for methylation and the activity of microorganisms involved in the process are determined by multiple physico‐chemical variables such as sulfur (Skyllberg et al ; Drott et al ), iron (Bravo et al ) and OM concentration and speciation (Schartup et al ; Bravo et al ) as well as Eh, pH, nutrient availability, and temperature (Ullrich et al ; Paranjape and Hall ) (Fig. ).…”

Section: Physico‐chemistry Plays a Pivotal Role In Hgii Methylationmentioning

confidence: 99%

Biotic formation of methylmercury: A bio–physico–chemical conundrum

Bravo

Cosio

2019

Limnology & Oceanography

115

102

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Mercury (Hg) is a natural and widespread trace metal, but is considered a priority pollutant, particularly its organic form methylmercury (MMHg), because of human's exposure to MMHg through fish consumption. Pioneering studies showed the methylation of divalent Hg (HgII) to MMHg to occur under oxygen‐limited conditions and to depend on the activity of anaerobic microorganisms. Recent studies identified the hgcAB gene cluster in microorganisms with the capacity to methylate HgII and unveiled a much wider range of species and environmental conditions producing MMHg than previously expected. Here, we review the recent knowledge and approaches used to understand HgII‐methylation, microbial biodiversity and activity involved in these processes, and we highlight the current limits for predicting MMHg concentrations in the environment. The available data unveil the fact that HgII methylation is a bio‐physico‐chemical conundrum in which the efficiency of biological HgII methylation appears to depend chiefly on HgII and nutrients availability, the abundance of electron acceptors such as sulfate or iron, the abundance and composition of organic matter as well as the activity and structure of the microbial community. An increased knowledge of the relationship between microbial community composition, physico‐chemical conditions, MMHg production, and demethylation is necessary to predict variability in MMHg concentrations across environments.

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“…Factors that influence HgII methylation and MeHg bioavailability are important controls in MeHg bioaccumulation in aquatic organisms (Wiener 2010;Li and Cai 2013;Hsu-Kim et al 2013;Paranjape and Hall 2017). We explored water chemistry and physical parameters that are often useful in explaining the variation of MeHg and THg in whole water (such as DOC, pH, total anion concentrations; see Methods section for complete list), and thus Hg in aquatic animals, using PCA (Fig.…”

Section: Differences In Thg In Tadpoles In Different Pondsmentioning

confidence: 99%

“…They are also important breeding and nesting habitats for avian wildlife in North America (Batt et al 1989). Atmospherically deposited Hg may be readily methylated (Hoggarth et al 2015) and accumulated (Sando et al 2007;Hall et al 2009) in these environments because prairie wetlands have potentially high dissolved organic carbon (DOC) concentration, a warm temperature in the summer months, and low dissolved oxygen; all variables which lead to anoxic conditions in which the main methylating organisms (sulfate and iron reducing bacteria and methanogens (Gilmour et al 2013;Parks et al 2013)) thrive (Paranjape and Hall 2017).…”

Section: Introductionmentioning

confidence: 99%

Survey of mercury in boreal chorus frog (Pseudacris maculata) and wood frog (Rana sylvatica) tadpoles from wetland ponds in the Prairie Pothole Region of Canada

Boczulak

Vanderwel

Hall

2017

FACETS

Self Cite

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Tadpoles are important prey items for many aquatic organisms and often represent the largest vertebrate biomass in many fishless wetland ecosystems. Neurotoxic mercury (Hg) can, at elevated levels, decrease growth, lower survival, and cause developmental instability in amphibians. We compared total Hg (THg) body burden and concentration in boreal chorus frog (Pseudacris maculata) and wood frog (Rana sylvatica) tadpoles. Overall, body burden and concentration were lower in boreal chorus frog tadpoles than wood frog tadpoles, as expected, because boreal chorus frog tadpoles consume at lower trophic levels. The variables species, stage, and mass explained 21% of total variation for body burden in our models but had negligible predictive ability for THg concentration. The vast majority of the remaining variation in both body burden and THg concentration was attributable to differences among ponds; tadpoles from ponds in three areas had considerably higher THg body burden and concentration. The pond-to-pond differences were not related to any water chemistry or physical parameter measured, and we assumed that differences in wetland geomorphology likely played an important role in determining Hg levels in tadpoles. This is the first report of Hg in frog tadpoles in the Prairie Pothole Region of North America.

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Recent advances in the study of mercury methylation in aquatic systems

Cited by 121 publications

References 210 publications

Increase in Nutrients, Mercury, and Methylmercury as a Consequence of Elevated Sulfate Reduction to Sulfide in Experimental Wetland Mesocosms

Increase in Nutrients, Mercury, and Methylmercury as a Consequence of Elevated Sulfate Reduction to Sulfide in Experimental Wetland Mesocosms

Biotic formation of methylmercury: A bio–physico–chemical conundrum

Survey of mercury in boreal chorus frog (Pseudacris maculata) and wood frog (Rana sylvatica) tadpoles from wetland ponds in the Prairie Pothole Region of Canada

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