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The effect of 2,4-D on gene expression in cultured cellsGunness, Patrina 16 October 2007
The cytotoxic effects of exposure to low concentrations of the herbicide, 2,4-dichlorophenoxyacetic acid (2,4-D) that are typically found in groundwater were investigated, in vitro. Most 2,4-D toxicology studies use high concentrations of the herbicide that are above those typically found in groundwater and measure overt biological endpoints. In contrast, this thesis examines the effects of low concentrations of 2,4-D and measures more subtle and sensitive endpoints such as gene expression and the generation of reactive oxygen species. This work derives from recent cDNA microarray analysis conducted in our laboratory that revealed significant alterations in the expression of 238 genes in cells exposed to nanomolar (nM) concentrations of a commercial formulation of 2,4-D. These findings are extended in this thesis to include the in vitro cytotoxic effects of low concentrations of both technical and commercial 2,4-D on two cell lines. Cells derived from liver (HepG2) and kidney (HEK293) respectively, were chosen, since liver and kidney are known to metabolize 2,4-D in vivo. Cell viability was measured using the Resazurin assay, reactive oxygen species (ROS) were measured with 2,7-dichlorofluorescin diacetate (2,7-DCFH-DA), and real timepolymerase chain reaction (RT-PCR) was used to assess changes in mRNA expression while protein expression was examined by Western blot.<p>Cell viability studies revealed that low environmental concentrations (0.1 to 100 nM) of 2,4-D induced small, but statistically significant decreases in cell viability. No concentration or time-dependent decreases in cell viability were observed in cells exposed to either forms of low environmental 2,4-D concentrations. HEK293 cells were more susceptible than HepG2 cells to the toxic effects of both forms of 2,4-D, having statistically significant lower viability at all exposure concentrations and durations. Both forms of 2,4-D reduced cell viability in both cell lines, suggesting that cytotoxicity was induced directly by 2,4-D, and not by the inert ingredients in the commercial formulation.<p>The ROS assays illustrated that 2,4-D induced statistically significant ROS production in HepG2 and HEK293 cell cultures at concentrations greater than 10 µM and 100 nM respectively. This was both a concentration and time-dependent effect in both cell lines. Although HEK293 cells were more susceptible to 2,4-D, they had 50 to 70% less ROS production than HepG2 cells, at all exposure concentrations and times.<p>The RT-PCR and Western blot analyses showed that exposure of HepG2 and HEK293 cells to low 2,4-D concentrations induced (< 2 fold) alterations in mRNA and protein levels of FTL, FTH1 and PCNA however these changes did not consistently vary with concentration.<p>Taken together, cell viability, ROS and gene expression studies show that low environmental 2,4-D concentrations induced subtle in vitro cytotoxic effects. However we have no evidence that these subtle changes pose a serious health threat to exposed humans.
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The effect of 2,4-D on gene expression in cultured cellsGunness, Patrina 16 October 2007 (has links)
The cytotoxic effects of exposure to low concentrations of the herbicide, 2,4-dichlorophenoxyacetic acid (2,4-D) that are typically found in groundwater were investigated, in vitro. Most 2,4-D toxicology studies use high concentrations of the herbicide that are above those typically found in groundwater and measure overt biological endpoints. In contrast, this thesis examines the effects of low concentrations of 2,4-D and measures more subtle and sensitive endpoints such as gene expression and the generation of reactive oxygen species. This work derives from recent cDNA microarray analysis conducted in our laboratory that revealed significant alterations in the expression of 238 genes in cells exposed to nanomolar (nM) concentrations of a commercial formulation of 2,4-D. These findings are extended in this thesis to include the in vitro cytotoxic effects of low concentrations of both technical and commercial 2,4-D on two cell lines. Cells derived from liver (HepG2) and kidney (HEK293) respectively, were chosen, since liver and kidney are known to metabolize 2,4-D in vivo. Cell viability was measured using the Resazurin assay, reactive oxygen species (ROS) were measured with 2,7-dichlorofluorescin diacetate (2,7-DCFH-DA), and real timepolymerase chain reaction (RT-PCR) was used to assess changes in mRNA expression while protein expression was examined by Western blot.<p>Cell viability studies revealed that low environmental concentrations (0.1 to 100 nM) of 2,4-D induced small, but statistically significant decreases in cell viability. No concentration or time-dependent decreases in cell viability were observed in cells exposed to either forms of low environmental 2,4-D concentrations. HEK293 cells were more susceptible than HepG2 cells to the toxic effects of both forms of 2,4-D, having statistically significant lower viability at all exposure concentrations and durations. Both forms of 2,4-D reduced cell viability in both cell lines, suggesting that cytotoxicity was induced directly by 2,4-D, and not by the inert ingredients in the commercial formulation.<p>The ROS assays illustrated that 2,4-D induced statistically significant ROS production in HepG2 and HEK293 cell cultures at concentrations greater than 10 µM and 100 nM respectively. This was both a concentration and time-dependent effect in both cell lines. Although HEK293 cells were more susceptible to 2,4-D, they had 50 to 70% less ROS production than HepG2 cells, at all exposure concentrations and times.<p>The RT-PCR and Western blot analyses showed that exposure of HepG2 and HEK293 cells to low 2,4-D concentrations induced (< 2 fold) alterations in mRNA and protein levels of FTL, FTH1 and PCNA however these changes did not consistently vary with concentration.<p>Taken together, cell viability, ROS and gene expression studies show that low environmental 2,4-D concentrations induced subtle in vitro cytotoxic effects. However we have no evidence that these subtle changes pose a serious health threat to exposed humans.
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Application of heterogeneous catalysts in ozonation of model compounds in waterGuzman Perez, Carlos Alberto 18 January 2011
The presence of micropollutants, particularly pesticides, in surface waters across Canada has been of concern not only for their environmental impact, but also for their potential effects on human health and recalcitrant nature to conventional water treatment methods. Although ozone has been mainly applied for disinfection of drinking water, oxidation of trace organics by ozonation has been considered potentially effective. In an effort to meet increasingly stringent drinking water regulations, different solid catalysts have been used to enhance the removal of water contaminants by ozonation. In spite of the increasing number of data demonstrating the effectiveness of heterogeneous catalytic ozonation, the influence of different factors on the efficiency of micropollutants oxidation is still unclear.<p>
In the present work, application of three solid catalysts in ozonation of two model micropollutants in pure water was examined using a laboratory-scale reaction system over a range of operating conditions. The three catalysts investigated were activated carbon, alumina, and perfluorooctyl alumina, and the two model micropollutants were the pesticides atrazine and 2,4-dichlorophenoxyactic acid. The effects of solution pH, presence of a radical scavenger, pesticide adsorption on catalyst, and catalyst dose on micropollutant removal were investigated. Solution pH was found to significantly influence the catalyst ability to decompose ozone into free hydroxyl radicals. The effect of these free radicals was markedly inhibited by the radical scavenger resulting in a negative impact on pesticides degradation. In general, the removal rate of pesticides was found to increase with increasing doses of catalyst.<p>
In the ozonation process in the presence of activated carbon, atrazine removal rates increased four and two times when using a catalyst dose of 0.5 g L-1 at pH 3 and 7, respectively, whereas observed reaction rates for 2,4-D increased over 5 times in the presence of 1 × 10-4 M tert-butyl alcohol at pH 3. In the ozonation system catalyzed by 8 g L-1 alumina, the observed reaction rate constant of atrazine removal notably improved at neutral pH by doubling the micropollutant removal rate. For the pesticide 2,4-D in the presence of 1 × 10-4 M tert-butyl alcohol at pH 5, the observed removal rate was over ten times higher than that for the non-catalytic ozonation process using also using a catalyst dose of 8 g L-1. Modification of alumina to produce perfluorooctyl alumina resulted in a material able to significantly adsorb atrazine, while not exhibiting affinity for adsorption of 2,4-D. In spite of its adsorptive properties, perfluorooctyl alumina was found to enhance neither molecular ozone reactions nor ozone decomposition into hydroxyl radicals. Thus, the observed removal rates for atrazine and 2,4-D by ozonation in the presence of perfluorooctyl alumina did not increase significantly.
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Application of heterogeneous catalysts in ozonation of model compounds in waterGuzman Perez, Carlos Alberto 18 January 2011 (has links)
The presence of micropollutants, particularly pesticides, in surface waters across Canada has been of concern not only for their environmental impact, but also for their potential effects on human health and recalcitrant nature to conventional water treatment methods. Although ozone has been mainly applied for disinfection of drinking water, oxidation of trace organics by ozonation has been considered potentially effective. In an effort to meet increasingly stringent drinking water regulations, different solid catalysts have been used to enhance the removal of water contaminants by ozonation. In spite of the increasing number of data demonstrating the effectiveness of heterogeneous catalytic ozonation, the influence of different factors on the efficiency of micropollutants oxidation is still unclear.<p>
In the present work, application of three solid catalysts in ozonation of two model micropollutants in pure water was examined using a laboratory-scale reaction system over a range of operating conditions. The three catalysts investigated were activated carbon, alumina, and perfluorooctyl alumina, and the two model micropollutants were the pesticides atrazine and 2,4-dichlorophenoxyactic acid. The effects of solution pH, presence of a radical scavenger, pesticide adsorption on catalyst, and catalyst dose on micropollutant removal were investigated. Solution pH was found to significantly influence the catalyst ability to decompose ozone into free hydroxyl radicals. The effect of these free radicals was markedly inhibited by the radical scavenger resulting in a negative impact on pesticides degradation. In general, the removal rate of pesticides was found to increase with increasing doses of catalyst.<p>
In the ozonation process in the presence of activated carbon, atrazine removal rates increased four and two times when using a catalyst dose of 0.5 g L-1 at pH 3 and 7, respectively, whereas observed reaction rates for 2,4-D increased over 5 times in the presence of 1 × 10-4 M tert-butyl alcohol at pH 3. In the ozonation system catalyzed by 8 g L-1 alumina, the observed reaction rate constant of atrazine removal notably improved at neutral pH by doubling the micropollutant removal rate. For the pesticide 2,4-D in the presence of 1 × 10-4 M tert-butyl alcohol at pH 5, the observed removal rate was over ten times higher than that for the non-catalytic ozonation process using also using a catalyst dose of 8 g L-1. Modification of alumina to produce perfluorooctyl alumina resulted in a material able to significantly adsorb atrazine, while not exhibiting affinity for adsorption of 2,4-D. In spite of its adsorptive properties, perfluorooctyl alumina was found to enhance neither molecular ozone reactions nor ozone decomposition into hydroxyl radicals. Thus, the observed removal rates for atrazine and 2,4-D by ozonation in the presence of perfluorooctyl alumina did not increase significantly.
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