Authors: Vos, Joseph G.¹; Dybing, Erik²; Greim, Helmut A.³; Ladefoged, Ole⁴; Lambré, Claude⁵; Tarazona, Jose V.⁶; Brandt, Ingvar⁷; Vethaak, A. Dick⁸

Source: Critical Reviews in Toxicology, Volume 30, Number 1, January-February 2000 , pp. 71-133(63)

Publisher: Informa Healthcare

Abstract:

Many wildlife species may be exposed to biologically active concentrations of endocrine-disrupting chemicals. There is strong evidence obtained from laboratory studies showing the potential of several environmental chemicals to cause endocrine disruption at environmentally realistic exposure levels. In wildlife populations, associations have been reported between reproductive and developmental effects and endocrine-disrupting chemicals. In the aquatic environment, effects have been observed in mammals, birds, reptiles, fish, and mollusks from Europe, North America, and other areas. The observed abnormalities vary from subtle changes to permanent alterations, including disturbed sex differentiation with feminized or masculinized sex organs, changed sexual behavior, and altered immune function. For most reported effects in wildlife, however, the evidence for a causal link with endocrine disruption is weak or nonexist-ing. Crucial in establishing causal evidence for chemical-induced wildlife effects appeared semifield or laboratory studies using the wildlife species of concern. Impaired reproduction and development causally linked to endocrine-disrupting chemicals are well documented in a number of species and have resulted in local or regional population changes. These include: • Masculinization (imposex) in female marine snails by tributyltin, a biocide used in antifouling paints, is probably the clearest case of endocrine disruption caused by an environmental chemical. The dogwhelk is particularly sensitive, and imposex has resulted in decline or extinction of local populations worldwide, including coastal areas all over Europe and the open North Sea. • DDE-induced egg-shell thinning in birds has caused severe population declines in a number of raptor species in Europe and North America. • Endocrine-disrupting chemicals have adversely affected a variety of fish species. In the vicinity of certain sources (e.g., effluents of water treatment plants) and in the most contami nated areas is this exposure causally linked with the effects on reproductive organs that could have implications for fish populations. However, there is also a more widespread occurrence of endocrine disruption in fish in the U.K., where estrogenic effects have been demonstrated in freshwater systems, in estuaries, and in coastal areas. • In mammals, the best evidence comes from the field studies on Baltic gray and ringed seals, and from the Dutch semifield studies on harbor seals, where both reproduction and immune functions have been impaired by PCBs in the food chain. Reproduction effects resulted in population declines, whereas impaired immune function has likely contributed to the mass mortalities due to morbillivirus infections. • Distorted sex organ development and function in alligators has been related to a major pesticide spill into a lake in Florida, U.S.A. The observed estrogenic/antiandrogenic effects in this reptile have been causally linked in experimental studies with alligator eggs to the DDT complex. Although most observed effects currently reported concern heavily polluted areas, endocrine disruption is a potential global problem. This is exemplified by the widespread occurrence of imposex in marine snails and the recent findings of high levels of persistent potential endocrine-disrupting chemicals in several marine mammalian species inhabiting oceanic waters.

Keywords: endocrine modulator; estrogenic effects; reproduction effects; immunotoxic effects; marine mammals; reptiles; fish; birds; invertebrates; chlorinated compounds; PCBs; PCDFs; PCDDs; DDT; TBT

Document Type: Research article

DOI: 10.1080/10408440091159176

Affiliations: 1: National Institute of Public Health and the Environment, Bilthoven, The Netherlands 2: National Institute of Public Health, Oslo, Norway 3: GSF National Research Center for Environment and Health, Institute of Toxicology, Neuherberg, Germany 4: Danish Veterinary and Food Administration, Copenhagen, Denmark 5: Institut National de l'Environnement Industriel et des Risques, INERIS, Verneuil-en-Halatte, France 6: Division of Environmental Toxicology, Instituto Nacional de Investigaciones Agrarias y Alimentarias, Madrid, Spain 7: Department of Environmental Toxicology, Uppsala University, Uppsala, Sweden 8: National Institute of Coastal and Marine Management, Middelburg, The Netherlands

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