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Lead accumulation rates in tissues of the estuarine teleost fish,Gillichthys mirabilis: Salinity and temperature effects

Archives of Environmental Contamination and Toxicology volume 6pages 337–348 (1977)Cite this article

Abstract

Tissue-specific lead accumulation rates were determined in the estuarine teleost fish,Gillichthys mirabilis, as a function of four variables; sea water lead concentration, duration of exposure to lead, salinity, and temperature. Distinct tissue-specific accumulation rates were found. Spleen, gills, fins, and intestine accumulated the greatest amounts of lead; liver and muscle accumulated the least lead.

Decay of lead from tissues of lead-exposed fish was observed only for gills, fins, and intestine, tissues which all possess an outer or inner covering of mucus. Our data suggest that the rapid turnover of lead in these mucus-covered tissues is a result of lead complexing with mucus and subsequent loss of lead when the mucus layer is sloughed off. In spleen and vertebrae, lead levels continued to rise in fish returned to natural (unspiked) sea water from lead-spiked sea water.

The rate of lead accumulation was dependent on both the holding salinity and the temperature. Fish held at high temperature accumulated lead more rapidly than fish held at low temperature. The rate of lead accumulation was inversely proportional to the salinity of the medium. Both of these environmental effects on lead accumulation rates could be significant in estuarine habitats where lead concentrations, salinity, and temperature are all apt to vary seasonally.

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Affiliations

  1. Scripps Institution of Oceanography, 92093, La Jolla, California, USA

    George N. Somero, Tsaihwa J. Chow, Paul H. Yancey & Carrie B. Snyder

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  1. George N. Somero
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  2. Tsaihwa J. Chow
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  3. Paul H. Yancey
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  4. Carrie B. Snyder
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Somero, G.N., Chow, T.J., Yancey, P.H. et al. Lead accumulation rates in tissues of the estuarine teleost fish,Gillichthys mirabilis: Salinity and temperature effects. Arch. Environ. Contam. Toxicol. 6, 337–348 (1977). https://doi.org/10.1007/BF02097774

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  • DOI: https://doi.org/10.1007/BF02097774

Keywords

  • Environmental Effect
  • Temperature Effect
  • Accumulation Rate
  • Lead Concentration
  • Lead Level