Biological effects and dose-response assessment of diesel exhaust particles on in vitro early embryo development in mice

Previous experiments conducted in our laboratory demonstrate that successful pregnancy is affected by air pollution. The aim of this study was to evaluate the biological effects associated with a dose-response curve of the diesel exhaust particles (DEP) on early embryonic development and implantation potential, using mice in vitro fertilization and culture embryo as model. In Experiment 1, we found a negative dose-dependent effect on the embryonic development, hatching process, cell allocation and morphology of inner cell mass (ICM) of blastocysts. A post-hoc analysis revealed that the early development of the embryo was not affected by concentrations of 0.2 g/cm2 or 2g/cm2, but was significantly affected by the concentration of 20 g/cm2 of DEP. The hatching process was impaired by concentrations of 2 g/cm2 and 20 g/cm2. Cell allocation of ICM and the ratio between cells of ICM and trophectoderm were significantly affected by all concentrations. Addicionaly, we observed a negative effect on ICM morphology was observed for the 2 µg/cm2 and the 20 µg/cm2 concentrations. Experiment 2, despite showing no significant effect on implantation potential, as evidenced by the adhesion ability and trophoblast outgrowth, revealed that ICM morphology on day 8 of culture, rates of cell viability and apoptosis, and expression of Oct4 and Cdx2 were significantly affected. The Tukey HSD test showed that presence of DEP (0.2 g/cm2 and 2 g/cm2) during embryonic development increased significantly the rate of apoptotic cells in embryos as on day 5 as on day 8 of culture, although the proportion of viable cells on day 8 was impaired by both concentrations, only exposure to 2 g/cm2 PED decreased cell viability on day 5. On the other hand, both the concentration of 0.2 g/cm2 such as 2 g/cm2 had a significant negative effect on the quality of ICM on the day 8 and the rate of expression of Oct4 on blastocysts, and increased the percentage of cells from these embryos expressing Cdx2, also, Oct4/Cdx2 ratio were significantly lower in the blastocysts derived from embryos exposed to 0.2 g/cm2 and 2 g/cm2¬ concentrations. Given these results, the suggestion is that DEP could be involved in the mechanisms that lead to decreased reproductive success observed in mice exposed to environmental pollution (AU)