Evidence for Regulation of Monomethyl Mercury by Nitrate in a Seasonally Stratified, Eutrophic Lake

Todorova, Svetoslava; Driscoll, Charles T.; Matthews, David A.; Effler, Steven W.; Hines, Mark E.; Henry, E. A.

doi:10.1021/es900887b

Cited by 73 publications

(62 citation statements)

References 40 publications

Supporting

Mentioning

Contrasting

Order By: Relevance

“…In an eutrophic and hypolimnetic reservoir in Idaho sediments that were rich in organic matter, low in dissolved oxygen, under redox conditions, and with increased nutrient content were suggested to lead to elevated methylation rates compared with other systems (Gray and Hines 2009). This is in contrast to other recent studies that have observed negative correlations of nitrate and MeHg concentrations in the water column of (Todorova et al 2009). A mesocosm study of estuarine sediments that were amended with various levels of N and P loadings to surface water showed that increased nutrients led to increased phytoplankton biomass productivity with stimulated microbial activity in sediments with Hg tracers that were considered highly bioavailable.…”

Section: Salinity Ph and Trophic Statuscontrasting

confidence: 93%

“…In oligotrophic systems, nitrogen availability was positively correlated with MeHg concentration and %MeHg, suggesting that in some systems methylation may be stimulated by N availability (Braaten et al 2014). Eutrophic conditions are also believed to influence methylation (Todorova et al 2009), though this may be due to the enhancement of methylation in the presence of organic matter. In an eutrophic and hypolimnetic reservoir in Idaho sediments that were rich in organic matter, low in dissolved oxygen, under redox conditions, and with increased nutrient content were suggested to lead to elevated methylation rates compared with other systems (Gray and Hines 2009).…”

Section: Salinity Ph and Trophic Statusmentioning

confidence: 99%

See 1 more Smart Citation

Recent advances in the study of mercury methylation in aquatic systems

Paranjape

Hall

2017

FACETS

114

View full text Add to dashboard Cite

With increasing input of neurotoxic mercury to environments as a result of anthropogenic activity, it has become imperative to examine how mercury may enter biotic systems through its methylation to bioavailable forms in aquatic environments. Recent development of stable isotope-based methods in methylation studies has enabled a better understanding of the factors controlling methylation in aquatic systems. In addition, the identification and tracking of the hgcAB gene cluster, which is necessary for methylation, has broadened the range of known methylators and methylation-conducive environments. Study of abiotic factors in methylation with new molecular methods (the use of stable isotopes and genomic methods) has helped elucidate the confounding influences of many environmental factors, as these methods enable the examination of their direct effects instead of merely correlative observations. Such developments will be helpful in the finer characterization of mercury biogeochemical cycles, which will enable better predictions of the potential effects of climate change on mercury methylation in aquatic systems and, by extension, the threat this may pose to biota.

show abstract

Section: Salinity Ph and Trophic Statuscontrasting

confidence: 93%

Section: Salinity Ph and Trophic Statusmentioning

confidence: 99%

Recent advances in the study of mercury methylation in aquatic systems

Paranjape

Hall

2017

FACETS

114

View full text Add to dashboard Cite

show abstract

“…Most Hg in soil is detected as ionic Hg 2+ species and shows relatively low toxicity, however, it still poses some environmental risk due to potential for Hg methylation followed by bioamplification in soilplant systems (Meng et al 2010;Liu et al 2012). Earlier studies have examined microbial methylation of Hg in estuarine, wetland, and freshwater sediments (Gilmour et al 1992; Heyes et al 2006;Duran et al 2008;Todorova et al 2009), but little attention to date has been paid to the linkage between specific types of microorganism and Hg methylation in soil environments. Since some studies reported high MeHg contents in both of soil and rice in the Wanshan Hg mine area of Guizhou province in southwest China (Feng et al 2008;Zhang et al 2010), concerns have been raised about the fate of Hg and potential production of MeHg in the local soil-rice system.…”

Section: Introductionmentioning

confidence: 99%

Linkage between community diversity of sulfate-reducing microorganisms and methylmercury concentration in paddy soil

Liu

Zheng

Zhang

et al. 2013

Environ Sci Pollut Res

View full text Add to dashboard Cite

Sulfate-reducing microorganisms (SRM) have been thought to play a key role in mercury (Hg) methylation in anoxic environments. The current study examined the linkage between SRM abundance and diversity and contents of methylmercury (MeHg) in paddy soils collected from a historical Hg mining area in China. Soil profile samples were collected from four sites over a distance gradient downstream the Hg mining operation. Results showed that MeHg content in the soil of each site significantly decreased with the extending distance away from Hg mine. Soil MeHg content was correlated positively with abundance of SRM and the contents of organic matter (OM), NH 4 + , SO 4 2− , and Hg. The abundances of SRM based on dissimilatory (bi) sulfite reductase (dsrAB) gene at 0-40 cm depths were higher than those at 40-80 cm depth at all sites. The SRM community composition varied in the soils of different sampling sites following terminal restriction fragment length polymorphism (T-RFLP) and phylogenetic analyses, which appeared to be correlated with contents of MeHg, OM, NH 4 + , and SO 4 2− through canonical correspondence analysis. The dominant groups of SRM in the soils examined belonged to Deltaproteobacteria and some unknown SRM clusters that could have potential for Hg methylation. These results advance our understanding of the relationship between SRM and methylmercury concentration in paddy soil.

show abstract

“…Several small catchment studies suggest diverse catchmentscale response (loadings and/or concentrations) of total mercury (HgT), MeHg, and N r (as NO À 3 , NO 3 -N, or NO 2 -NO 3 ) to a variety of anthropogenically altered landscapes, for example, focusing on how NO À 3 and MeHg are processed in a lake [22], in standing water behind beaver dams [23], and in surface waters in catchments affected by forest fires [24,25]. Important questions remain, however, particularly in watersheds larger and with greater land cover diversity than that of the standard small catchment study, i.e., the spatial scale and land cover types at which most decision-making processes take place.…”

Section: Introductionmentioning

confidence: 99%

Simulated watershed mercury and nitrate flux responses to multiple land cover conversion scenarios

Golden

Knightes

2011

Enviro Toxic and Chemistry

View full text Add to dashboard Cite

Water quality and toxic exposure science is transitioning towards analysis of multiple stressors rather than one particular environmental concern (e.g., mercury) or a group of similarly reacting chemicals (e.g., nutrients). However, two of the most important water quality constituents affecting both human and ecosystem health today, reactive nitrogen (N(r) ) and methylmercury (MeHg), are often assessed separately for their independent effects on water quality. With the continued pressure of landscape modifications on water quality, a challenge remains in understanding the concurrent watershed flux response of both N(r) and MeHg to such physical stressors, particularly at the spatial scale (regional watersheds) and within the mixed land cover type systems that most decision-making processes are conducted. We simulate the annual average and monthly flux responses of Hg (MeHg and total mercury [HgT]), NO(3) -N, and runoff to four land cover change scenarios in the Haw River Watershed (NC, USA), a headwater system in the Cape Fear River Basin. Fluxes are simulated using a process-based, spatially explicit watershed Grid-Based Mercury Model (GBMM) and a NO(3) -N watershed flux model we developed to link to GBMM. Results suggest that annual NO(3) -N and Hg fluxes increase and decrease concomitantly to land cover change; however, the magnitude of the changes in NO(3) -N, MeHg, HgT, and water fluxes vary considerably between different land cover conversion scenarios. Converting pasture land to a suburbanized landscape elicited the greatest increase in runoff and MeHg, HgT, and NO(3) -N fluxes among all four conversion scenarios. Our findings provide insight for multi-stressor ecological exposure research and management of coastal eutrophication resulting from elevated N(r) loadings and exposure risk due to elevated concentrations of MeHg in fish tissue.

show abstract

Evidence for Regulation of Monomethyl Mercury by Nitrate in a Seasonally Stratified, Eutrophic Lake

Cited by 73 publications

References 40 publications

Recent advances in the study of mercury methylation in aquatic systems

Recent advances in the study of mercury methylation in aquatic systems

Linkage between community diversity of sulfate-reducing microorganisms and methylmercury concentration in paddy soil

Simulated watershed mercury and nitrate flux responses to multiple land cover conversion scenarios

Contact Info

Product

Resources

About