Department of Medicinal Chemistry, University of Florida, Gainesville, FL 32610-0485, United States.
Aquat Toxicol. 2012 Nov 15;124-125:72-82. doi: 10.1016/j.aquatox.2012.07.009. Epub 2012 Aug 4.
The antibacterial personal care product triclosan is discharged in municipal waste, and converted in part by bacteria in sewage sludge and soil to its more lipid-soluble methyl ether, methyl triclosan. Triclosan and methyl triclosan have been detected in water, sediment, fish and invertebrates near sewage treatment facilities. Understanding the biotransformation of methyl triclosan and triclosan in a model food fish, the channel catfish, will be of value in assessing the likelihood that these compounds will bioaccumulate in exposed fish, and therefore potentially pass up the food chain. We hypothesize that cytochrome P450 will catalyze the O-demethylation of methyl triclosan to yield triclosan, which is likely to undergo glucuronidation or sulfonation of the phenolic hydroxyl group. Conversion of methyl triclosan to triclosan was measured by LC/MS/MS following aerobic incubation of varying concentrations of methyl triclosan with NADPH and hepatic and intestinal microsomes from untreated, 3-methylcholanthrene-treated (10 mg/kg, i.p.) or PCB-126-treated (0.1 mg/kg, i.p.) channel catfish (n=4 per treatment group). The K(m) values for methyl triclosan were similar for untreated, 3-methylcholanthrene-treated and PCB-126-treated catfish liver microsomes, ranging from 80 to 250 μM. V(max) values for O-demethylation ranged from 30 to 150 pmol/min/mg protein, with no significant differences between controls, PCB-126-treated or 3-methylcholanthrene-treated fish, suggesting that methyl triclosan O-demethylation was not a CYP1-catalyzed reaction. Methyl triclosan O-demethylation activities in intestinal microsomes were similar to or lower than those found with liver microsomes. The calculated rate of O-demethylation of methyl triclosan in catfish liver at 1 μM, a concentration reported in exposed fish, and 21°C, an early summer water temperature, is 0.10 pmol/min/mg protein. This slow rate of metabolism suggests that upon continued exposure, methyl triclosan may bioaccumulate in the channel catfish. Triclosan itself, however, was readily glucuronidated by hepatic and intestinal microsomes and sulfonated by hepatic and intestinal cytosol. Triclosan glucuronidation followed Michaelis-Menten kinetics when rates were measured across a concentration range of 5-1000 μM, whereas triclosan sulfonation exhibited substrate inhibition at concentrations above 10-20 μM in both intestinal and hepatic cytosol. Based on the enzyme kinetic constants measured in hepatic and intestinal fractions at 21°C, triclosan at 1 μM could be glucuronidated at rates of 23 and 3.2 pmol/min/mg protein respectively in liver and intestine, and sulfonated at rates of 277 (liver) and 938 (intestine) pmol/min/mg protein. These rates are much higher than the rates of demethylation of methyl triclosan, and suggest that triclosan would be rapidly cleared and unlikely to bioaccumulate in catfish tissues.
抗菌个人护理产品三氯生被排放到城市废水中,并在污水污泥和土壤中的部分细菌的作用下转化为更具脂溶性的甲基醚,即甲基三氯生。三氯生和甲基三氯生已在污水处理设施附近的水、沉积物、鱼类和无脊椎动物中被检测到。了解模型食用鱼——斑点叉尾鮰中甲基三氯生和三氯生的生物转化情况,对于评估这些化合物是否会在暴露的鱼类中生物积累,从而有可能通过食物链传递,将具有重要意义。我们假设细胞色素 P450 将催化甲基三氯生的 O-去甲基化,生成三氯生,三氯生很可能会经历酚羟基的葡萄糖醛酸化或磺化。通过 LC/MS/MS 测量了不同浓度的甲基三氯生在有氧孵育下与 NADPH 和未经处理、3-甲基胆蒽(10mg/kg,ip)或 PCB-126(0.1mg/kg,ip)处理的斑点叉尾鮰的肝微粒体和肠微粒体中的转化,每组有 4 个样本。未处理、3-甲基胆蒽处理和 PCB-126 处理的斑点叉尾鮰肝微粒体中甲基三氯生的 K(m)值相似,范围为 80 至 250μM。O-去甲基化的 V(max)值范围为 30 至 150pmol/min/mg 蛋白,对照组、PCB-126 处理组和 3-甲基胆蒽处理组之间没有显著差异,表明甲基三氯生的 O-去甲基化不是 CYP1 催化的反应。肠微粒体中的甲基三氯生 O-去甲基化活性与肝微粒体相似或低于肝微粒体。在 1μM 的浓度下,即暴露鱼类中报告的浓度,以及 21°C 的初夏水温下,斑点叉尾鮰肝脏中甲基三氯生的 O-去甲基化速率计算为 0.10pmol/min/mg 蛋白。这种缓慢的代谢速度表明,在持续暴露的情况下,甲基三氯生可能会在斑点叉尾鮰体内生物积累。然而,三氯生本身很容易被肝微粒体和肠微粒体葡萄糖醛酸化,也很容易被肝和肠细胞质磺化。当以 5-1000μM 的浓度范围测量时,三氯生的葡萄糖醛酸化遵循米氏-门肯动力学,而三氯生的磺化在肠和肝细胞质中,当浓度高于 10-20μM 时,表现出底物抑制。基于 21°C 下肝和肠部分测量的酶动力学常数,1μM 的三氯生在肝脏和肠道中分别以 23 和 3.2pmol/min/mg 蛋白的速率进行葡萄糖醛酸化,以 277(肝脏)和 938(肠道)pmol/min/mg 蛋白的速率进行磺化。这些速率远高于甲基三氯生的去甲基化速率,表明三氯生将被迅速清除,不太可能在鱼类组织中生物积累。
