Recovery of Mercury-Contaminated Fisheries

Munthe, John; Bodaly, R. A.; Branfireun, Brian A.; Driscoll, Charles T.; Gilmour, Cynthia C.; Harris, R. O.; Horvat, Milena; Lucotte, Marc; Malm, Olaf

doi:10.1579/0044-7447(2007)36[33:romf]2.0.co;2

Cited by 266 publications

(246 citation statements)

References 117 publications

Supporting

Mentioning

238

Contrasting

Unclassified

Order By: Relevance

“…We do not know yet whether there will be a proportional response to the continuing increased loading to the lake in the longer term, as suggested by some regional studies (6). For example, if mercury demethylation switched on at some increased concentration of sediment methylmercury, the end response would not be directly proportional to the increase in inorganic mercury loading.…”

Section: Resultsmentioning

confidence: 91%

“…This issue has now approached a critical juncture because many nations (e.g., the United States and Canada) and organizations (e.g., United Nations Environment Program) are debating the implementation and extent of mercury emission controls. One of the reasons for this debate is that it has been notoriously difficult to establish how annual and regional patterns of mercury loading via deposition influence fish methylmercury concentrations (6). This is because the effects of mercury deposition alone are obscured by various factors [including climate change (7), lake acidification (8), and land use (9)(10)(11)] that act synergistically to influence fish methylmercury concentrations.…”

mentioning

confidence: 99%

See 1 more Smart Citation

Whole-ecosystem study shows rapid fish-mercury response to changes in mercury deposition

Harris

Rudd²,

Amyot

et al. 2007

Proc. Natl. Acad. Sci. U.S.A.

Self Cite

400

333

View full text Add to dashboard Cite

Methylmercury contamination of fisheries from centuries of industrial atmospheric emissions negatively impacts humans and wildlife worldwide. The response of fish methylmercury concentrations to changes in mercury deposition has been difficult to establish because sediments/soils contain large pools of historical contamination, and many factors in addition to deposition affect fish mercury. To test directly the response of fish contamination to changing mercury deposition, we conducted a whole-ecosystem experiment, increasing the mercury load to a lake and its watershed by the addition of enriched stable mercury isotopes. The isotopes allowed us to distinguish between experimentally applied mercury and mercury already present in the ecosystem and to examine bioaccumulation of mercury deposited to different parts of the watershed. Fish methylmercury concentrations responded rapidly to changes in mercury deposition over the first 3 years of study. Essentially all of the increase in fish methylmercury concentrations came from mercury deposited directly to the lake surface. In contrast, <1% of the mercury isotope deposited to the watershed was exported to the lake. Steady state was not reached within 3 years. Lake mercury isotope concentrations were still rising in lake biota, and watershed mercury isotope exports to the lake were increasing slowly. Therefore, we predict that mercury emissions reductions will yield rapid (years) reductions in fish methylmercury concentrations and will yield concomitant reductions in risk. However, a full response will be delayed by the gradual export of mercury stored in watersheds. The rate of response will vary among lakes depending on the relative surface areas of water and watershed.bioaccumulation ͉ mercury methylation ͉ stable isotopes ͉ whole-ecosystem experimentation ͉ methylmercury

show abstract

Section: Resultsmentioning

confidence: 91%

mentioning

confidence: 99%

Whole-ecosystem study shows rapid fish-mercury response to changes in mercury deposition

Harris

Rudd²,

Amyot

et al. 2007

Proc. Natl. Acad. Sci. U.S.A.

Self Cite

400

333

View full text Add to dashboard Cite

show abstract

“…Divalent Hg species are subject to rapid wet and dry deposition in terrestrial ecosystems. Some of the Hg 2ϩ deposited in aquatic systems and sediments is transformed into organic methylmercury (5). Although inorganic Hg species have severe health effects on humans, methylmercury is thought to be the highly toxic species involved in bioaccumulation in aquatic food chains.…”

mentioning

confidence: 99%

Polar firn air reveals large-scale impact of anthropogenic mercury emissions during the 1970s

Faïn

Ferrari

Dommergue

et al. 2009

Proc. Natl. Acad. Sci. U.S.A.

View full text Add to dashboard Cite

Mercury (Hg) is an extremely toxic pollutant, and its biogeochemical cycle has been perturbed by anthropogenic emissions during recent centuries. In the atmosphere, gaseous elemental mercury (GEM; Hg°) is the predominant form of mercury (up to 95%). Here we report the evolution of atmospheric levels of GEM in mid-to high-northern latitudes inferred from the interstitial air of firn (perennial snowpack) at Summit, Greenland. GEM concentrations increased rapidly after World War II from Ϸ1.5 ng m ؊3 reaching a maximum of Ϸ3 ng m ؊3 around 1970 and decreased until stabilizing at Ϸ1.7 ng m ؊3 around 1995. This reconstruction reproduces real-time measurements available from the Arctic since 1995 and exhibits the same general trend observed in Europe since 1990. Anthropogenic emissions caused a two-fold rise in boreal atmospheric GEM concentrations before the 1970s, which likely contributed to higher deposition of mercury in both industrialized and remotes areas. Once deposited, this toxin becomes available for methylation and, subsequently, the contamination of ecosystems. Implementation of air pollution regulations, however, enabled a large-scale decline in atmospheric mercury levels during the 1980s. The results shown here suggest that potential increases in emissions in the coming decades could have a similar large-scale impact on atmospheric Hg levels.atmosphere ͉ Greenland ͉ past century ͉ pollution

show abstract

“…Bacteria in aquatic systems convert a small proportion of the deposited Hg to MeHg, which bioaccumulates in fish (inorganic Hg does not bioaccumulate). Aquatic systems vary in the efficiency with which atmospherically deposited Hg is transformed to MeHg and bioaccumulate in fish (Munthe et al, 2007). For example, the Hg concentration of fish in neighbouring lakes can vary by as much as 10-fold, even when atmospheric Hg levels are similar (Wiener et al, 2006)).…”

Section: Figure 5: Major Ecosystem Inputs and Outputs (A) And Aquaticmentioning

confidence: 99%

“…For example, the Hg concentration of fish in neighbouring lakes can vary by as much as 10-fold, even when atmospheric Hg levels are similar (Wiener et al, 2006)). Nevertheless, in a given aquatic system, the production of MeHg is believed to be approximately proportional to atmospheric Hg deposition (but with variable response time and magnitude), so it is likely that historical increases in Hg emissions have increased MeHg concentrations in fish (Munthe et al, 2007).…”

Section: Figure 5: Major Ecosystem Inputs and Outputs (A) And Aquaticmentioning

confidence: 99%

Socio-economic costs of continuing the status-quo of mercury pollution

Pacyna¹,

Sundseth²,

Pacyna³

et al. 2008

TemaNord

Self Cite

View full text Add to dashboard Cite

Recovery of Mercury-Contaminated Fisheries

Cited by 266 publications

References 117 publications

Whole-ecosystem study shows rapid fish-mercury response to changes in mercury deposition

Whole-ecosystem study shows rapid fish-mercury response to changes in mercury deposition

Polar firn air reveals large-scale impact of anthropogenic mercury emissions during the 1970s

Socio-economic costs of continuing the status-quo of mercury pollution

Contact Info

Product

Resources

About