Mercury concentrations in snapping turtles (Chelydra serpentina) correlate with environmental and landscape characteristics
Tóm tắt
Mercury (Hg) deposited onto the landscape can be transformed into methylmercury (MeHg), a neurotoxin that bioaccumulates up the aquatic food chain. Here, we report on Hg concentrations in snapping turtles (Chelydra serpentina) across New York State, USA. The objectives of this study were to: (1) test which landscape, water, and biometric characteristics correlate with total Hg (THg) concentrations in snapping turtles; and (2) determine whether soft tissue THg concentrations correlate with scute (shell) concentrations. Forty-eight turtles were sampled non-lethally from ten lakes and wetlands across New York to observe patterns under a range of ecosystem variables and water chemistry conditions. THg concentrations ranged from 0.041 to 1.50 μg/g and 0.47 to 7.43 μg/g wet weight of muscle tissue and shell, respectively. The vast majority of mercury (~94%) was in the MeHg form. Sixty-one percent of turtle muscle samples exceeded U.S. Environmental Protection Agency (U.S. EPA) consumption advisory limit of 0.3 μg Hg/g for fish. Muscle THg concentrations were significantly correlated with sulfate in water and the maximum elevation of the watershed. Shell THg concentrations were significantly correlated with the acid neutralizing capacity (ANC) of water, the maximum elevation of the watershed, the percent open water in the watershed, the lake to watershed size, and various forms of atmospheric Hg deposition. Thus, our results demonstrate that THg concentrations in snapping turtles are spatially variable, frequently exceed advisory limits, and are significantly correlated with several landscape and water characteristics.
Tài liệu tham khảo
Bank MS, Loftin CS, Jung RE (2005) Mercury bioaccumulation in two-lined salamanders from streams in the northeastern U.S. Ecotoxicology 14(1):181–191. doi:10.1007/s10646-004-6268-8
Bergeron CM, Husak JF, Unrine JM, Romanek CS, Hopkins WA (2007) Influence of feeding ecology on blood mercury concentrations in four species of turtles. Environ Toxicol Chem 26(8):1733–1741
Beyer HL (2004) Hawth’s analysis tools for ArcGIS. http://www.spatialecology.com/htools. Accessed 1 Oct 2010
Bloom NS (1992) On the chemical form of mercury in edible fish and marine invertebrate tissue. Can J Fish Aquat Sci 49(5):1010–1017
Burgess N, Evers DC, Kaplan J (2005) Mercury and other contaminants in common loons breeding in Atlantic Canada. Ecotoxicology 14(1):241–252. doi:10.1007/s10646-004-6271-0
Chen CY, Stemberger RS, Kamman NC, Mayes BM, Folt CL (2005) Patterns of Hg bioaccumulation and transfer in aquatic food webs across multi-lake studies in the northeast US. Ecotoxicology 14(1):135–147. doi:10.1007/s10646-004-6265-y
Chen CY, Driscoll CT, Kamman NC (in press) Mercury hotspots in freshwater ecosystems: drivers, processes, and patterns. In: Bank MS (ed) Mercury in the environment: pattern and process. University of California Press, Berkeley
Driscoll CT, Yan C, Schofield CL, Munson R, Holsapple J (1994) The mercury cycle and fish in the Adirondack lakes. Environ Sci Technol 28(3):136–143. doi:10.1021/es00052a003
Driscoll CT, Han YJ, Chen CY, Evers DC, Lambert KF, Holsen TM, Kamman NC, Munson RK (2007) Mercury contamination in forest and freshwater ecosystems in the northeastern United States. Bioscience 57(1):17–28. doi:10.1641/b570106
Ernst CH (1965) Bait preferences of some freshwater turtles. J Ohio Herpetol Soc 5(2):53
Ernst CH, Lovich JE, Barbour RW (1994) Turtles of the United States and Canada. Smithsonian Institution Press, Washington
Evers DC (2005) Mercury connections: the extent and effects of mercury pollution in northeastern North America. BioDiversity Research Institute, Gorham
Fitzgerald WF, Engstrom DR, Mason RP, Nater EA (1998) The case for atmospheric mercury contamination in remote areas. Environ Sci Technol 32(1):1–7
Gibbs JP, Breisch AR, Ducey PK, Johnson G, Behler JL, Bothner RC (2007) The amphibians and reptiles of New York State: identification, natural history, and conservation. Oxford University Press, New York
Golet WJ, Haines TA (2001) Snapping turtles (Chelydra serpentina) as monitors for mercury contamination of aquatic environments. Environ Monit Assess 71(3):211–220
Green AD, Buhlmann KA, Hagen C, Romanek C, Gibbons JW (2010) Mercury contamination in turtles and implications for human health. J Environ Health 72(10):14–22
Grieb TM, Bowie GL, Driscoll CT, Gloss SP, Schofield CL, Porcella DB (1990) Factors affecting mercury accumulation in fish in the upper Michigan peninsula. Environ Toxicol Chem 9(7):919–930. doi:10.1002/etc.5620090710
Grillitsch B, Schiesari L (2010) The ecotoxicology of metals in reptiles. In: Sparling DW, Linder G, Bishop CA, Krest SK (eds) Ecotoxicology of amphibians and reptiles, 2nd edn. CRC Press, Pensacola, pp 337–473
Hammer DA (1969) Parameters of marsh snapping turtle populations Lacreek Refuge, South Dakota. J Wildl Manag 33(4):995–1005
Harris RC, Bodaly RA (1998) Temperature, growth and dietary effects on fish mercury dynamics in two Ontario lakes. Biogeochemistry 40(2–3):175–187
Helwig DD, Hora ME (1983) Polychlorinated biphenyl, mercury, and cadmium concentrations in Minnesota snapping turtles. Bull Environ Contam Toxicol 30(2):186–190
Hintelmann H, Nguyen HT (2005) Extraction of methylmercury from tissue and plant samples by acid leaching. Anal Bioanal Chem 381:360–365
Lagler KF (1943) Methods of collecting freshwater turtles. Copeia 1943(1):21–25
Meyers-Schöne L, Walton BT (1994) Turtles as monitors of chemical contaminants in the environment. Rev Environ Contam Toxicol 135:93–153
Meyers-Schöne L, Shugart LR, Beauchamp JJ, Walton BT (1993) Comparison of two freshwater turtles species as monitors of radio nuclide and chemical contaminations: DNA damage and residue analysis. Environ Toxicol Chem 12(8):1487–1496
Miller EK, Vanarsdale A, Keeler GJ, Chalmers A, Poissant L, Kamman NC, Brulotte R (2005) Estimation and mapping of wet and dry mercury deposition across northeastern North America. Ecotoxicology 14(1):53–70. doi:10.1007/s10646-004-6259-9
Mosimann JE, Bider JR (1960) Variation, sexual dimorphism, and maturity in a Quebec population of the common snapping turtle, Chelydra serpentina. Can J Zool 38:19–38
National Wildlife Federation (2006) Poisoning wildlife: the reality of mercury pollution. National Wildlife Federation, Reston
New York State Department of Health (2009) Chemicals in sportfish and game: 2009–2010 health advisories. New York State Department of Health: Division of Environmental Health Assessment, Albany
NYS Adirondack Park Agency (2001) Shared Adirondack park geographic information CD-ROM Version 1.0. Adirondack Park Agency, Ray Brook
NYS Department of Environmental Conservation (1999) New York state regulatory freshwater wetlands for Oneida county outside the Adirondack Park. Cornell University Geospatial Information Repository (CUGIR). http://cugir.mannlib.cornell.edu/datatheme.jsp?id=111. Accessed 24 May 2010
Ohio Environmental Protection Agency (2010) 2010 Ohio snapping turtle consumption advisory. http://www.epa.state.oh.us/dsw/fishadvisory/turtles.aspx. Accessed 12 Oct 2010
Pell SM (1940) Notes on the food habits of the common snapping turtle. Copeia 1940:131
Rimmer CC, McFarland KP, Evers DC, Miller EK, Aubry Y, Busby D, Taylor RJ (2005) Mercury concentrations in Bicknell’s thrush and other insectivorous passerines in montane forests of northeastern North America. Ecotoxicology 14(1):223–240. doi:10.1007/s10646-004-6270-1
Roué-LeGall A, Lucotte M, Carreau J, Canuel R, Garcia E (2005) Development of an ecosystem sensitivity model regarding mercury levels in fish using a preference modeling methodology: application to the Canadian boreal system. Environ Sci Technol 39(24):9412–9423
Schneider L, Belger L, Burger J, Vogt RC (2009) Mercury bioaccumulation in four tissues of Podocnemis erythrocephala (Podocnemididae: Testudines) as a function of water parameters. Sci Total Environ 407(3):1048–1054. doi:10.1016/j.scitotenv.2008.09.049
Simonin HA, Loukmas JJ, Skinner LC, Roy KM (2008) Lake variability: key factors controlling mercury concentrations in New York State fish. Environ Pollut 154(1):107–115. doi:10.1016/j.envpol.2007.12.032
St. Louis VL, Rudd JWM, Kelly CA, Beaty KG, Flett RJ, Roulet NT (1996) Production and loss of methylmercury and loss of total mercury from boreal forest catchments containing different types of wetlands. Environ Sci Technol 30(9):2719–2729
United States Environmental Protection Agency (1998) Method 7473. USEPA, Office of Science and Technology, Office of Water, Engineering and Analysis Division (4303), Washington
United States Environmental Protection Agency (2001a) Water quality for the protection of human health: methylmercury. EPA-823-R-01-001, USEPA, Office of Science and Technology, Office of Water, Washington. http://water.epa.gov/scitech/swguidance/waterquality/standards/criteria/aqlife/pollutants/methylmercury/upload/2009_01_15_criteria_methylmercury_mercury-criterion.pdf. Accessed 25 Sep 2010
United States Environmental Protection Agency (2001b) Method 1630 methylmercury in water by distillation, aqueous ethylation, purge trap, and CVAFS. USEPA, Office of Water, Office of Science and Technology, Engineering and Analysis Division (4303), Washington
United States Fish and Wildlife Service (2009) FWS_wetlands_83. http://www.fws.gov/wetlands/Data/DataDownload.html. Accessed 1 Apr 2010
United States Geological Survey (1999) Hydrography features of New York State (shapefile). Cornell University Geospatial Information Repository (CUGIR). http://cugir.mannlib.cornell.edu/bucketinfo.jsp?id=7315. Accessed 25 Feb 2010
United States Geological Survey (2003) National land cover database: zone 13. Multi-Resolution Land Characteristics Consortium (MRLC). http://www.mrlc.gov/multizone_download.php?zone=13. Accessed 18 Oct 2009
United States Geological Survey (2009) 1-Arc second national elevation dataset. The National Map Seamless Server. http://seamless.usgs.gov/website/seamless/viewer.htm. Accessed 31 Mar 2010
White PS, Cogbill CV (1991) Spruce-fir forests of eastern North America. In: Eagar C, Adams MB (eds) Ecology and decline of red spruce in the eastern United States. Springer-Verlag, New York, pp 3–39
Wiener JG, Spry DJ (1996) Toxicology significance of mercury in freshwater fish. In: Beyer WN, Heinz GH, Redmon-Norwood AW (eds) Environmental contaminates in wildlife: interpreting tissue concentrations. Lewis, Boca Raton
Wiener JG, Knights BC, Sandheinrich MB, Jeremiason JD, Brigham ME, Engstrom DR, Woodruff LG, Cannon WF, Balogh SJ (2006) Mercury in soils, lakes, and fish in Voyageurs National Park (Minnesota): importance of atmospheric deposition and ecosystem factors. Environ Sci Technol 40(20):6261–6268