In vivo evaluation of the potential protective effects of prolactin against damage caused by methylmercury.

Non-biodegradable metals such as mercury accumulate in living organisms during life (bioaccumulation) and also within trophic webs (biomagnification) and may reach high concentrations in humans. The contamination of humans by mercury in drinking water and food may be common, in particular in riverside communities that have a diet rich in fish. In vitro studies of human cell lines exposed to the cytotoxic and mutagenic effects of methylmercury have shown that prolactin has potential cytoprotective properties and may act as a co-mitogenic factor and inhibitor of apoptosis. The present in vivo study investigated the protective potential of prolactin against the toxic effects of methylmercury in the mammal Mus musculus. Histological and biochemical analyses, together with biomarker of genotoxicity, were used to verify the protective potential of prolactin in mice exposed to methylmercury. The reduction in kidney and liver tissue damage was not significant. However, results of biochemical and genotoxic analyses were excellent. After prolactin treatment, a significant reduction was observed in biochemical parameters and mutagenic effects of methylmercury. The study results therefore indicated that prolactin has protective effects against the toxicity of methylmercury and allowed us to suggest the continuation of research to propose prolactin in the future, as an alternative to prevent the damage caused by mercury, especially in populations that are more exposed.

In vivo evaluation of the potential protective effects of prolactin against damage caused by methylmercury

Non-biodegradable metals such as mercury accumulate in living organisms during life (bioaccumulation) and also within trophic webs (biomagnification) and may reach high concentrations in humans. The contamination of humans by mercury in drinking water and food may be common, in particular in riverside communities that have a diet rich in fish. In vitro studies of human cell lines exposed to the cytotoxic and mutagenic effects of methylmercury have shown that prolactin has potential cytoprotective properties and may act as a co-mitogenic factor and inhibitor of apoptosis. The present in vivo study investigated the protective potential of prolactin against the toxic effects of methylmercury in the mammal Mus musculus. Histological and biochemical analyses, together with biomarker of genotoxicity, were used to verify the protective potential of prolactin in mice exposed to methylmercury. The reduction in kidney and liver tissue damage was not significant. However, results of biochemical and genotoxic analyses were excellent. After prolactin treatment, a significant reduction was observed in biochemical parameters and mutagenic effects of methylmercury. The study results therefore indicated that prolactin has protective effects against the toxicity of methylmercury and allowed us to suggest the continuation of research to propose prolactin in the future, as an alternative to prevent the damage caused by mercury, especially in populations that are more exposed.

Inhibition of sea urchin fertilization by plant lectins.

Effects of plant lectins on sea urchin (Lytechinus variegatus) fertilization and a partial characterization of lectin-binding involved in the process were evaluated. IC50 doses for inhibition of fertilization varied from 4.1 to 135.5 microg/ml when the lectins were pre-incubated with sperms and from 0.7 to 33.4 microg/ml when pre-incubated with eggs. Such effects were reversed when the lectins were heat inactivated. FITC-labeled lectins bound egg surfaces while their denatured forms did not. Glucose/mannose specific lectins bound weaker to eggs when pre-incubated with the glycoprotein bovine lactotransferrin. None of the glycoproteins assayed diminished FITC patterns of the Gal/GalNAc binding lectins. Pre-incubation of Glucose/mannose binding lectins with eggs did not alter binding of Gal/GalNAc lectins. Lectins with distinct competencies for binding monosaccharide and glycoconjugates were able to inhibit sea urchin fertilization.