Great Lakes Environmental and Molecular Sciences Center, Department of Biological Sciences, Western Michigan University, Kalamazoo, MI 49008, USA.
Aquat Toxicol. 2011 Aug;104(3-4):254-62. doi: 10.1016/j.aquatox.2011.04.022. Epub 2011 May 6.
In our laboratory, Xenopus laevis tadpoles exposed throughout development to 200 or 400 μg/L atrazine, concentrations reported to periodically occur in puddles, vernal ponds and runoff soon after application, were smaller and had smaller fat bodies (the tadpole's lipid storage organ) than controls. It was hypothesized that these changes were due to atrazine-related perturbations of energy homeostasis. To investigate this hypothesis, selected metabolic responses to exposure at the transcriptional and biochemical levels in atrazine-exposed tadpoles were measured. DNA microarray technology was used to determine which metabolic pathways were affected after developmental exposure to 400 μg/L atrazine. From these data, genes representative of the affected pathways were selected for assay using quantitative real time polymerase chain reaction (qRT-PCR) to measure changes in expression during a 2-week exposure to 400 μg/L. Finally, ATP levels were measured from tadpoles both early in and at termination of exposure to 200 and 400 μg/L. Microarray analysis revealed significant differential gene expression in metabolic pathways involved with energy homeostasis. Pathways with increased transcription were associated with the conversion of lipids and proteins into energy. Pathways with decreased transcription were associated with carbohydrate metabolism, fat storage, and protein synthesis. Using qRT-PCR, changes in gene expression indicative of an early stress response to atrazine were noted. Exposed tadpoles had significant decreases in acyl-CoA dehydrogenase (AD) and glucocorticoid receptor protein (GR) mRNA after 24 h of exposure, and near-significant (p=0.07) increases in peroxisome proliferator-activated receptor β (PPAR-β) mRNA by 72 h. Decreases in AD suggested decreases in fatty acid β-oxidation while decreases in GR may have been a receptor desensitization response to a glucocorticoid surge. Involvement of PPAR-β, an energy homeostasis regulatory molecule, also suggested changes in energy status. Despite, or possibly because of, these early gene changes, there were no differences in either absolute ATP levels or ADP:ATP ratios early in the exposure. However, livers from animals exposed to 200 μg/L atrazine had near-significant (p=0.06) increases in ADP:ATP ratios at the end of exposure suggesting tadpoles may have had difficulty maintaining energy homeostasis. Perturbations in the expression of genes regulating energy metabolism by 24 h into exposure to 400 μg/L atrazine was noteworthy, especially since these tadpoles were significantly smaller than controls by 72 h of exposure.
在我们的实验室中,暴露于 200 或 400μg/L 莠去津的非洲爪蟾蝌蚪在整个发育过程中都比对照组更小,并且脂肪体更小(蝌蚪的脂质储存器官)。据报道,这些浓度周期性地出现在水坑、春池和施药后不久的径流中。有人假设这些变化是由于莠去津相关的能量稳态失调所致。为了验证这一假设,我们在暴露于莠去津的蝌蚪中测量了转录和生化水平的特定代谢反应,以研究其对能量稳态的影响。采用 DNA 微阵列技术来确定在发育过程中暴露于 400μg/L 莠去津后哪些代谢途径受到影响。根据这些数据,选择了代表受影响途径的基因,并用定量实时聚合酶链反应 (qRT-PCR) 来测量在暴露于 400μg/L 莠去津期间的 2 周内表达的变化。最后,我们还测量了暴露于 200 和 400μg/L 莠去津早期和结束时的蝌蚪中的 ATP 水平。微阵列分析显示,与能量稳态相关的代谢途径中的基因表达存在显著差异。转录增加的途径与将脂质和蛋白质转化为能量有关。转录减少的途径与碳水化合物代谢、脂肪储存和蛋白质合成有关。使用 qRT-PCR,我们注意到了暴露于莠去津后早期应激反应的基因表达变化。暴露的蝌蚪在暴露 24 小时后,酰基辅酶 A 脱氢酶 (AD) 和糖皮质激素受体蛋白 (GR) 的 mRNA 显著下降,72 小时后过氧化物酶体增殖物激活受体 β (PPAR-β) 的 mRNA 接近显著 (p=0.07) 增加。AD 的减少表明脂肪酸β-氧化减少,而 GR 的减少可能是糖皮质激素激增的受体脱敏反应。能量稳态调节分子 PPAR-β 的参与也表明能量状态发生了变化。尽管(或者可能是因为)这些早期的基因变化,在暴露的早期,绝对的 ATP 水平或 ADP:ATP 比值没有差异。然而,暴露于 200μg/L 莠去津的动物的肝脏在暴露结束时的 ADP:ATP 比值接近显著增加 (p=0.06),这表明蝌蚪可能难以维持能量稳态。暴露于 400μg/L 莠去津 24 小时后,调节能量代谢的基因表达受到干扰,这值得注意,尤其是这些蝌蚪在暴露 72 小时后比对照组明显更小。
