Author:
Fauteux Myriam,Côté Nadia,Bergeron Sandra,Maréchal Alexandre,Gaudreau Luc
Abstract
AbstractAs modern agricultural practices increase their use of chemical pesticides, it is inevitable that we will find a number of these xenobiotics within drinking water supplies and disseminated throughout the food chain. A major problem that arises from this pollution is that the effects of most of these pesticides on cellular mechanisms in general, and how they interact with each other and affect human cells are still poorly understood. In this study we make use of cultured human cancer cells to measure by qRT-PCR how pesticides affect gene expression of stress pathways. Immunoblotting studies were performed to monitor protein expression levels and activation of signaling pathways. We make use of immunofluorescence and microscopy to visualize and quantify DNA damage events in those cells. In the current study, we evaluate the potential of a subset of widely used pesticides to activate the dioxin receptor pathway and affect its crosstalk with estrogen receptor signaling. We quantify the impact of these chemicals on the p53-dependent cellular stress response. We find that, not only can the different pesticides activate the dioxin receptor pathway, most of them have better than additive effects on this pathway when combined at low doses. We also show that different pesticides have the ability to trigger crosstalk events that may generate genotoxic estrogen metabolites. Finally, we show that some, but not all of the tested pesticides can induce a p53-dependent stress response. Taken together our results provide evidence that several xenobiotics found within the environment have the potential to interact together to elicit significant effects on cell systems. Our data warrants caution when the toxicity of substances that are assessed simply for individual chemicals, since important biological effects could be observed only in the presence of other compounds, and that even at very low concentrations.
Funder
Natural Sciences and Engineering Research Council of Canada
Publisher
Springer Science and Business Media LLC
Reference79 articles.
1. Abass, K. et al. Characterization of human cytochrome P450 induction by pesticides. Toxicology. 294(1), 17–26. https://doi.org/10.1016/j.tox.2012.01.010 (2012).
2. Otto, S., Loddo, D., Baldoin, C. & Zanin, G. Spray drift reduction techniques for vineyards in fragmented landscapes. J. Environ. Manag. 162, 290–298. https://doi.org/10.1016/j.jenvman.2015.07.060 (2015).
3. Ma, Q. et al. The pesticide module of the root zone water quality model (RZWQM): Testing and sensitivity analysis of selected algorithms for pesticide fate and surface runoff. Pest Manag. Sci. 60(3), 240–252. https://doi.org/10.1002/ps.790 (2004).
4. De Schampheleire, M., Nuyttens, D., De Keyser, D. & Spanoghe, P. Evaporation drift of pesticides active ingredients. Commun. Agric. Appl. Biol. Sci. 73(4), 739–742 (2008).
5. Fox, G. A., Malone, R., Sabbagh, G. J. & Rojas, K. Interrelationship of macropores and subsurface drainage for conservative tracer and pesticide transport. J. Environ. Qual. 33(6), 2281–2289 (2004).