Scientists coupled the concepts of energy flow through food webs with measurements of mercury in organic matter and animals to estimate mercury fluxes and fate during an experimental flood in the Colorado River. The flood redistributed mercury in simple, upstream food webs but not in more complex, downstream food webs.

Mercury in its organic form, methylmercury, is a neurotoxin that can biomagnify in food chains. Mercury is present in food webs throughout the world, even in seemingly remote locations such as Grand Canyon National Park, where aquatic animals in the Colorado River accumulate mercury at levels posing risks to fish and wildlife.
Floods are a regular feature of many ecosystems including the Colorado River, and contaminant fluxes during flooding events are poorly understood. It also is unclear how floods and their associated changes in community dynamics might alter pathways of mercury transfer among aquatic species.
Therefore, U.S. Geological Survey scientists and university partners conducted a study that provided an understanding of factors that drive mercury transfers in food webs and govern exposure before and after an experimental flood on the Colorado River. They were able to take advantage of periodic high-flow releases from the Glen Canyon Dam that simulate floods and supply sand for sand bar rebuilding in the Colorado River.
Invertebrates, organic matter, and fish were collected at six sites spanning 370 kilometers of the Colorado River in the year before and after the experimental flood. Scientists collected 18–20 benthic invertebrate samples per season and site and sampled the predominant habitats using multiple approaches. Organic matter collected included fine benthic organic matter, seston (suspended organic matter), epilithon (benthic biofilm), attached algae (Cladophora sp.), and epiphyton (diatoms attached to Cladophora). Scientists collected fish with various approaches, including angling, electrofishing, and seining.
Only a few pathways dominated mercury flux in the Colorado River despite large spatial differences in food web complexity, and these fluxes were largely mediated by one critical invertebrate trait—resistance to predation.

For example, invasive New Zealand mudsnails (Potamopyrgus antipodarumare) accumulated available mercury because they are resistant to predation and created a trophic dead end for a substantial proportion of mercury moving through the food web; mudsnails in the habitat immediately below the dam (tailwater) decreased after flooding. Conversely, blackflies (Simulium spp.) increased after flooding and are preferred prey; consumption of blackflies accounted for 56–80 percent of the total mercury flux to fishes, even at sites where they constituted only a fraction of total invertebrate production.
The scientists concluded that the experimental flood redistributed mercury fluxes in the relatively simple, tailwater food web but not in more complex, downstream food webs. Recognizing that species traits, ecological interactions, and disturbance regimes mediate contaminant exposure can improve management of linked aquatic-terrestrial ecosystems.
This research provided a unique opportunity to explore how differences in food webs affect contaminant transfer, which ultimately governs exposure to fish, wildlife, and humans. This study was funded in part by the U.S. Geological Survey Environmental Health Program (Toxic Substances Hydrology and Contaminant Biology), which is part of the Ecosystems Mission Area.
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Food web controls on mercury fluxes and fate in the Colorado River, Grand Canyon
- Overview
Scientists coupled the concepts of energy flow through food webs with measurements of mercury in organic matter and animals to estimate mercury fluxes and fate during an experimental flood in the Colorado River. The flood redistributed mercury in simple, upstream food webs but not in more complex, downstream food webs.
Sources/Usage: Some content may have restrictions. Visit Media to see details.USGS scientists Kyle Hanus, Cheyenne Szydlo and Ted Kennedy collect and analyze algae, invertebrates and fish on the Colorado River. This is part of a study to learn more about how food web dynamics influence the movement of mercury throughout the Colorado River in the Grand Canyon. Mercury in its organic form, methylmercury, is a neurotoxin that can biomagnify in food chains. Mercury is present in food webs throughout the world, even in seemingly remote locations such as Grand Canyon National Park, where aquatic animals in the Colorado River accumulate mercury at levels posing risks to fish and wildlife.
Floods are a regular feature of many ecosystems including the Colorado River, and contaminant fluxes during flooding events are poorly understood. It also is unclear how floods and their associated changes in community dynamics might alter pathways of mercury transfer among aquatic species.
Therefore, U.S. Geological Survey scientists and university partners conducted a study that provided an understanding of factors that drive mercury transfers in food webs and govern exposure before and after an experimental flood on the Colorado River. They were able to take advantage of periodic high-flow releases from the Glen Canyon Dam that simulate floods and supply sand for sand bar rebuilding in the Colorado River.
Invertebrates, organic matter, and fish were collected at six sites spanning 370 kilometers of the Colorado River in the year before and after the experimental flood. Scientists collected 18–20 benthic invertebrate samples per season and site and sampled the predominant habitats using multiple approaches. Organic matter collected included fine benthic organic matter, seston (suspended organic matter), epilithon (benthic biofilm), attached algae (Cladophora sp.), and epiphyton (diatoms attached to Cladophora). Scientists collected fish with various approaches, including angling, electrofishing, and seining.
Only a few pathways dominated mercury flux in the Colorado River despite large spatial differences in food web complexity, and these fluxes were largely mediated by one critical invertebrate trait—resistance to predation.
Sources/Usage: Some content may have restrictions. Visit Media to see details.New Zealand mudsnails were analyzed as part of a study to evaluate how food web dynamics influence the movement of mercury throughout the Colorado River in the Grand Canyon. For example, invasive New Zealand mudsnails (Potamopyrgus antipodarumare) accumulated available mercury because they are resistant to predation and created a trophic dead end for a substantial proportion of mercury moving through the food web; mudsnails in the habitat immediately below the dam (tailwater) decreased after flooding. Conversely, blackflies (Simulium spp.) increased after flooding and are preferred prey; consumption of blackflies accounted for 56–80 percent of the total mercury flux to fishes, even at sites where they constituted only a fraction of total invertebrate production.
The scientists concluded that the experimental flood redistributed mercury fluxes in the relatively simple, tailwater food web but not in more complex, downstream food webs. Recognizing that species traits, ecological interactions, and disturbance regimes mediate contaminant exposure can improve management of linked aquatic-terrestrial ecosystems.
This research provided a unique opportunity to explore how differences in food webs affect contaminant transfer, which ultimately governs exposure to fish, wildlife, and humans. This study was funded in part by the U.S. Geological Survey Environmental Health Program (Toxic Substances Hydrology and Contaminant Biology), which is part of the Ecosystems Mission Area.
- Science
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Bioaccumulation of Mercury in Fish Varied by Species and Location in the Chesapeake Bay Watershed—Summary of Existing Data and a Roadmap for Integrated Monitoring
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Results from a 3-year study indicate there was support for the use of open- and deep-water treatment pools at the downstream end of seasonal wetlands to reduce methylmercury concentrations in water exported from the wetlands, but the treatment had no measurable effect on wetland fish. Questions remain about the long-term potential for mercury removal using this wetland management strategy.Mercury Accumulation in Waterbirds (Black Rails) Related to Sediment Chemistry in San Francisco Bay Wetlands
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Exposure and toxicity of environmental mercury to birds can be enhanced or lessened due to the available sources and forms of mercury and other species dependent factors such as life stage, migratory patterns, foraging and nesting behaviors, transfer of mercury from mothers to eggs, and sex. For example, mercury exposure can lead to sublethal toxicological effects that can influence parental...Roadmap to Understanding Factors Influencing Mercury Exposure and Adverse Health Effects
In a comprehensive overview, scientists explain that human and wildlife exposure and toxicological responses to mercury are dependent on factors that operate across global, individual, and molecular scales. They provide a roadmap for unified research to facilitate a better understanding of human and wildlife health risks from mercury exposure. - Publications
Related publications listed below.
Food web controls on mercury fluxes and fate in the Colorado River, Grand Canyon
Mercury (Hg) biomagnification in aquatic food webs is a global concern; yet, the ways species traits and interactions mediate these fluxes remain poorly understood. Few pathways dominated Hg flux in the Colorado River despite large spatial differences in food web complexity, and fluxes were mediated by one functional trait, predation resistance. New Zealand mudsnails are predator resistant and a tAuthorsDavid Walters, Wyatt F. Cross, Theodore Kennedy, Colden V. Baxter, R. O. Hall, Emma J. Rosi