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The Black-headed Gull's Adaptation to Polluted Environments: The Role of the Mixed-function Oxidase Detoxication System

Published online by Cambridge University Press:  24 August 2009

Cristina Fossi ,
Claudio Leonzio ,
Silvano Focardi  and
Aristeo Renzoni
Cristina Fossi
Affiliation:
Dipartimento di Biologia Ambientale, Università di Siena, Via delle Cerchia 3, 53100 Siena, Italy.
Claudio Leonzio
Affiliation:
Dipartimento di Biologia Ambientale, Università di Siena, Via delle Cerchia 3, 53100 Siena, Italy.
Silvano Focardi
Affiliation:
Dipartimento di Biologia Ambientale, Università di Siena, Via delle Cerchia 3, 53100 Siena, Italy.
Aristeo Renzoni
Affiliation:
Dipartimento di Biologia Ambientale, Università di Siena, Via delle Cerchia 3, 53100 Siena, Italy.
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Extract

This study was conducted to explore the role of the mixed-function oxidase (MFO) detoxication system in the ‘adaptation’ process of gulls to polluted environments. In two different populations of Black-headed Gull (Larus ridibundus), feeding in one case in a lagoon and in the other on an inland rubbish-dump, MFO hepatic activities (aldrin epoxidase, 7-ethoxyresorufin o-deethylase, NADPH-cytochrome c reductase, NADH-cytochrome c reductase, and NADH-ferrycianide reductase) and chlorinated hydrocarbon residues were determined. All the enzymatic activities detected, and the PCB residues, were higher in the Gulls feeding on the inland dump than in the gulls feeding in the lagoon.

The results obtained suggest that the development of a strong detoxication system constitutes an important ‘survival mechanism’ for these birds when feeding customarily in polluted environments.

Type
Main Papers
Information
Environmental Conservation , Volume 15 , Issue 3 , Autumn 1988 , pp. 221 - 224
Copyright
Copyright © Foundation for Environmental Conservation 1988

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References

Blondel, J. & Isenmann, P. (1973). L'évolution de la structure des peuplements de laro-limicoles nicheurs de Camargue. La Terre et la Vie, 1, pp. 6284, 6 figs.Google Scholar
Burger, J. & Gochfeld, M. (1983). Behavior of nine avian species at a Florida garbage dump. Colonial Waterbirds, 6, pp. 5463.Google Scholar
Burger, J. & Galli, J. (1987). Factors affecting distribution of gulls (Larus spp.) on two New Jersey coastal bays. Environmental Conservation, 14(1), pp. 5965, 8 figs.Google Scholar
Cramp, S. (1983). Handbook of the Birds of Europe, the Middle East and North Africa: The Birds of the Western Palearctic, Vol. III. Oxford University Press, Oxford, England, UK: 913 pp., illustr.Google Scholar
Ellenton, J.A., Brownlee, L.J. & Holleborne, B.R. (1985). Aryl hydrocarbon hydroxylase levels in Herring Gull embryos from different locations on the Great Lakes. Environ. Toxicol. Chem., 6, pp. 615–22, 3 figs.Google Scholar
Fossi, C., Leonzio, C. & Focardi, S. (1986). Mixed function oxidase activity and cytochrome P-450 forms in Black-headed Gulls feeding in different areas. Mar. Pollut. Bull, 17, pp. 546–8, 2 figs.Google Scholar
Hodgson, E., Kulkarni, A.P., Fabacher, D.L. & Robacker, K.M. (1980). Induction of hepatic drug-metabolizing enzymes in mammals by pesticides: A review. J. Environ. Sci. Health, B 15, pp. 723–54.Google Scholar
Isenmann, P., Johnson, A. & Walmsley, J. (1986). Fluctuations of the Laridae of the Rhone delta over the past 30 years (1956–1985). Pp. 285–91 in Mediterranean Marine Avifauna (Eds ‘Medmaravis’ & X. Monbailliu). Springer-Verlag, Berlin-Heidelberg: xx + 535 pp., illustr.Google Scholar
Knight, G.C. & Walker, C.H. (1982). A study of the hepatic microsomal monooxygenase of sea birds and its relationship to organochlorine pollutants. Comp. Biochem. Physiol., 73 C, pp. 211–21, 12 figs.Google Scholar
Knight, G.C., Walker, C.H., Cabot, D.C. & Harris, M.P. (1981). The activity of two hepatic microsomal enzymes in sea birds. Comp. Biochem. Physiol., 68 C, pp. 127–32, fig.Google Scholar
Krieger, R.L. & Wilkinson, C.F. (1969). Microsomal mixed function oxidases in insects, 1: Localisation and properties of an enzyme system affecting aldrin epoxidation in larvae of the Southern Armyworm (Prodenia eridania). Biochem. Pharmac., 19, pp. 1403–15.Google Scholar
Lambertini, M., Focardi, S., Fossi, C. & Leonzio, C. (in press). II Gabbiano Corso (Larus audouinii Payr.) nidificante nell'Arcipelago Toscano: Contaminazione da elementi in tracce e da idrocarburi clorurati. Atti del 11° Congresso Italiano di Ornitologia, Parma, Italy.Google Scholar
Leonzio, C., Fossi, C. & Focardi, S. (1986). Lead, Mercury, Cadmium and Selenium in two species of gull feeding on inland dumps, and in marine areas. Sci. Total Environ., 57, pp. 121–7, 2 figs.CrossRefGoogle ScholarPubMed
Livingstone, D.R. & Farrar, S.V. (1984). Tissue and subcellular distribution of enzyme activities of mixed-function oxidase and benzo(a)pyrene metabolism in the common mussel Mytilus edulis L. Sci. Total Environ., 39, pp. 209–35, 3 figs.CrossRefGoogle Scholar
Mineau, P., Fox, G.A., Norstrom, R.J., Weseloh, D.V., Hallett, D. J. & Ellenton, J.A. (1984). Using the Herring Gull to monitor levels and effects of organochlorine contamination in the Canadian Great Lakes. Pp. 426–52 in Toxic Contaminants in the Great Lakes (Eds Nriagu, Jerome O. & Simons, Milagros S.). J. Wiley and Sons, New York, NY, USA: illustr. [Not available for checking.]Google Scholar
Peakall, D.B., Norstrom, R.J., Rahimtula, A.D. & Butler, R.D. (1986). Characterization of mixed-function oxidase systems of the nestling Herring Gull and its implications for bioeffects monitoring. Environ. Toxicol. Chem., 5, pp. 379–85.Google Scholar
Pearce, P.A., Peakall, D.B. & Reynolds, L.M. (1979). Shell thinning and residues of organochlorines and mercury in seabird eggs, Eastern Canada, 1970–1976. Pestic. Monit. Journ., 13, pp. 61–8.Google Scholar
Pohl, R. J. & Foutus, J.R. (1980). A rapid method for assaying the metabolism of 7-ethoxyresorufin by microsomal subcellular fractions. Analytical Biochem., 107, pp. 150–6, 3 figs.CrossRefGoogle Scholar
Polunin, N. (1978). Gulls around a Swiss autoroute. Environmental Conservation, 5(4), p. 276.Google Scholar
Pyykko, K. (1983). Characterization and stability of rat liver microsomes isolated by rapid gel filtration method. Acta Pharmacol. Toxicol., 52, pp. 3946, 3 figs.Google Scholar
Safe, S., Bandiera, S., Sawyer, T., Robertson, L., Safe, L., Parkinson, T., Thomas, O.E., Ryan, D.E., Reik, L.M., Levin, W., Denomme, M.A. & Fujita, T. (1985). PCBs: structure-function relationship and mechanism of action. Environ. Health Perspect., 60, pp. 4756, 8 figs.Google ScholarPubMed
Walker, C.H. (1980). Species variations in some hepatic microsomal enzymes that metabolize xenobiotics. Prog. Drug Metabol., 5, pp. 113–64, 3 figs.Google Scholar