Literature DB >> 20436784

Rapid, efficient growth reduces mercury concentrations in stream-dwelling Atlantic salmon.

Darren M Ward1, Keith H Nislow, Celia Y Chen, Carol L Folt.   

Abstract

Mercury (Hg) is a potent toxin that biomagnifies in aquatic food webs. Large fish generally have higher Hg concentrations than small fish of the same species. However, models predict that fish that grow large faster should have lower Hg concentrations than small, slow-growing fish due to somatic growth dilution (SGD). We examined the relationship between Hg concentrations and growth rate in fish using a large-scale field experiment. Atlantic salmon (Salmo salar) fry hatched under uniform initial conditions were released at eighteen sites in natural streams, collected after one growing season, and Hg concentration and growth measured. As expected for Hg accumulation from food, mercury concentrations in salmon tracked Hg concentrations in their prey. Nonetheless, large, fast-growing salmon had lower Hg concentrations than small, slow-growing salmon, consistent with SGD. While prey Hg concentration accounted for 59% of the explained variation in salmon Hg concentration across sites, salmon growth rate accounted for 38% of the explained variation independent of prey Hg concentration. A mass-balance Hg accumulation model shows that such SGD occurs when fast growth is associated with high growth efficiency. Fish growth is tremendously variable and sensitive to anthropogenic impacts, so SGD of Hg has important implications for fisheries management.

Entities:  

Year:  2010        PMID: 20436784      PMCID: PMC2861578          DOI: 10.1577/T09-032.1

Source DB:  PubMed          Journal:  Trans Am Fish Soc        ISSN: 0002-8487            Impact factor:   1.861


  26 in total

1.  Patterns of Hg bioaccumulation and transfer in aquatic food webs across multi-lake studies in the northeast US.

Authors:  Celia Y Chen; Richard S Stemberger; Neil C Kamman; Brandon M Mayes; Carol L Folt
Journal:  Ecotoxicology       Date:  2005-03       Impact factor: 2.823

Review 2.  Recovery of mercury-contaminated fisheries.

Authors:  John Munthe; R A Drew Bodaly; Brian A Branfireun; Charles T Driscoll; Cynthia C Gilmour; Reed Harris; Milena Horvat; Marc Lucotte; Olaf Malm
Journal:  Ambio       Date:  2007-02       Impact factor: 5.129

3.  Effects of food availability on temporal activity patterns and growth of Atlantic salmon.

Authors:  James E Orpwood; Siân W Griffiths; John D Armstrong
Journal:  J Anim Ecol       Date:  2006-05       Impact factor: 5.091

4.  Fish growth rates modulate mercury concentrations in walleye (Sander vitreus) from eastern Canadian lakes.

Authors:  Michel Simoneau; Marc Lucotte; Steve Garceau; Denis Laliberté
Journal:  Environ Res       Date:  2005-05       Impact factor: 6.498

5.  Relationship between wetlands and mercury in brook trout.

Authors:  Mark S Castro; Robert H Hilderbrand; Joe Thompson; A Heft; S E Rivers
Journal:  Arch Environ Contam Toxicol       Date:  2006-10-23       Impact factor: 2.804

6.  Factors controlling the bioaccumulation of mercury, methylmercury, arsenic, selenium, and cadmium by freshwater invertebrates and fish.

Authors:  R P Mason; J Laporte; S Andres
Journal:  Arch Environ Contam Toxicol       Date:  2000-04       Impact factor: 2.804

7.  Mercury in soils, lakes, and fish in Voyageurs National Park (Minnesota): importance of atmospheric deposition and ecosystem factors.

Authors:  J G Wiener; B C Knights; M B Sandheinrich; J D Jeremiason; M E Brigham; D R Engstrom; L G Woodruff; W F Cannon; S J Balogh
Journal:  Environ Sci Technol       Date:  2006-10-15       Impact factor: 9.028

8.  Changes in mercury bioaccumulation in an apex predator in response to removal of an introduced competitor.

Authors:  Jesse M Lepak; Jason M Robinson; Clifford E Kraft; Daniel C Josephson
Journal:  Ecotoxicology       Date:  2009-03-10       Impact factor: 2.823

9.  The movement of aquatic mercury through terrestrial food webs.

Authors:  Daniel A Cristol; Rebecka L Brasso; Anne M Condon; Rachel E Fovargue; Scott L Friedman; Kelly K Hallinger; Adrian P Monroe; Ariel E White
Journal:  Science       Date:  2008-04-18       Impact factor: 47.728

10.  Habitat-mediated foraging limitations drive survival bottlenecks for juvenile salmon.

Authors:  Brian P Kennedy; Keith H Nislow; Carol L Folt
Journal:  Ecology       Date:  2008-09       Impact factor: 5.499
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  18 in total

Review 1.  Bioaccumulation syndrome: identifying factors that make some stream food webs prone to elevated mercury bioaccumulation.

Authors:  Darren M Ward; Keith H Nislow; Carol L Folt
Journal:  Ann N Y Acad Sci       Date:  2010-05       Impact factor: 5.691

2.  Reduced trace element concentrations in fast-growing juvenile Atlantic salmon in natural streams.

Authors:  Darren M Ward; Keith H Nislow; Celia Y Chen; Carol L Folt
Journal:  Environ Sci Technol       Date:  2010-05-01       Impact factor: 9.028

3.  Mercury bioaccumulation increases with latitude in a coastal marine fish (Atlantic silverside, Menidia menidia).

Authors:  Zofia Baumann; Robert P Mason; David O Conover; Prentiss Balcom; Celia Y Chen; Kate L Buckman; Nicholas S Fisher; Hannes Baumann
Journal:  Can J Fish Aquat Sci       Date:  2016-11-30       Impact factor: 2.595

4.  Pathogenic microorganisms, heavy metals, and antibiotic residues in seven Korean freshwater aquaculture species.

Authors:  Jae-Suk Choi; Sun-Mee Park; Young Hun Kim; Sang Cheol Oh; Eun Seo Lim; Yong-Ki Hong; Mi-Ryung Kim
Journal:  Food Sci Biotechnol       Date:  2016-10-31       Impact factor: 2.391

5.  Chronic exposure to pollutants in Madín Reservoir (Mexico) alters oxidative stress status and flesh quality in the common carp Cyprinus carpio.

Authors:  Gabriela Morachis-Valdez; Octavio Dublán-García; Leticia Xochitl López-Martínez; Marcela Galar-Martínez; Karinne Saucedo-Vence; Leobardo Manuel Gómez-Oliván
Journal:  Environ Sci Pollut Res Int       Date:  2015-01-14       Impact factor: 4.223

6.  Foraging and fasting can influence contaminant concentrations in animals: an example with mercury contamination in a free-ranging marine mammal.

Authors:  Sarah H Peterson; Joshua T Ackerman; Daniel E Crocker; Daniel P Costa
Journal:  Proc Biol Sci       Date:  2018-02-14       Impact factor: 5.349

7.  Seasonal shift in the effect of predators on juvenile Atlantic salmon (Salmo salar) energetics.

Authors:  Darren M Ward; Keith H Nislow; Carol L Folt
Journal:  Can J Fish Aquat Sci       Date:  2011-11-29       Impact factor: 2.595

8.  Comparing nearshore benthic and pelagic prey as mercury sources to lake fish: the importance of prey quality and mercury content.

Authors:  Roxanne Karimi; Celia Y Chen; Carol L Folt
Journal:  Sci Total Environ       Date:  2016-05-09       Impact factor: 7.963

9.  Spatial and temporal variation in mercury bioaccumulation by zooplankton in Lake Champlain (North America).

Authors:  Celia Chen; Neil Kamman; Jason Williams; Deenie Bugge; Vivien Taylor; Brian Jackson; Eric Miller
Journal:  Environ Pollut       Date:  2011-10-11       Impact factor: 8.071

10.  Effects of habitat on mercury concentrations in fish: a case study of Nile perch (Lates niloticus) in Lake Nabugabo, Uganda.

Authors:  D E L Hanna; D G Buck; L J Chapman
Journal:  Ecotoxicology       Date:  2015-10-31       Impact factor: 2.823
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