三种鲑科鱼类肝微粒体对苯酚的 I 期和 II 期生物转化比较研究:对苯二酚、儿茶酚和苯葡萄糖醛酸的形成

IF 2.1 3区 农林科学 Q2 FISHERIES Fishes Pub Date : 2024-07-17 DOI:10.3390/fishes9070284
R. Kolanczyk, Laura E. Solem, Patricia K. Schmieder, James M. McKim
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引用次数: 0

摘要

使用产卵前的成年虹鳟(Oncorhynchus mykiss)(RBT)、溪鳟(Salvelinus fontinalis)(BKT)和湖鳟(Salvelinus namaycush)(LKT)肝微粒体制备物研究了苯酚在 11 °C下的体外生物转化。对培养时间、辅助因子浓度、pH 值和微粒体蛋白浓度进行了优化。采用高效液相色谱法和双通道电化学及紫外检测法对第一阶段环羟化和第二阶段葡萄糖醛酸化代谢产物的形成进行定量。在一系列底物浓度(1 至 180 mM)范围内对苯酚的生物转化进行了量化,并计算了对苯二酚(HQ)、邻苯二酚(CAT)和苯葡萄糖醛酸(PG)形成的迈克尔斯-门顿动力学常数 Km 和 Vmax。注意到 HQ 和 CAT 第一阶段酶生成的 Km 值存在物种差异,酶对底物的亲和力排序如下:RBT > BKT = LKT。不过,苯酚转化为 PG 的第二阶段代谢 Km 值没有发现明显差异。相反,虽然不同物种形成 HQ 或 CAT 的 Vmax 没有明显差异,但 LKT 形成 PG 的表观最大能力明显低于 RBT 和 BKT。这些实验为量化鱼类体内异种生物的代谢活化和失活、比较不同物种的活化和失活反应提供了一种方法,并为今后预测鱼类体内新的化学生物转化途径和速率提供了指导。这些实验提供了必要的速率和容量(Km 和 Vmax)输入,这些输入是为苯酚等容易发生生物转化的活性化学物质的鱼类生理毒物动力学(PB-TK)模型设置参数所必需的。今后,需要针对选定的化学结构,建立一个重要鱼类物种的这些速率和容量参数的广泛数据库,以便在水生毒理学和环境风险评估中有效使用反应性生物转化化学品的预测模型。
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A Comparative Study of Phase I and II Hepatic Microsomal Biotransformation of Phenol in Three Species of Salmonidae: Hydroquinone, Catechol, and Phenylglucuronide Formation
The in vitro biotransformation of phenol at 11 °C was studied using pre-spawn adult rainbow (Oncorhynchus mykiss) (RBT), brook (Salvelinus fontinalis) (BKT), and lake trout (Salvelinus namaycush) (LKT) hepatic microsomal preparations. The incubations were optimized for time, cofactor concentration, pH, and microsomal protein concentration. Formation of Phase I ring-hydroxylation and Phase II glucuronidation metabolites was quantified using HPLC with dual-channel electrochemical and UV detection. The biotransformation of phenol over a range of substrate concentrations (1 to 180 mM) was quantified, and the Michaelis–Menten kinetics constants, Km and Vmax, for the formation of hydroquinone (HQ), catechol (CAT), and phenylglucuronide (PG) were calculated. Species differences were noted in the Km values for Phase I enzyme production of HQ and CAT, with the following rank order of apparent enzyme affinity for substrate: RBT > BKT = LKT. However, no apparent differences in the Km for Phase II metabolism of phenol to PG were detected. Conversely, while there were no apparent differences in Vmax between species for HQ or CAT formation, the apparent maximum capacity for PG formation was significantly less in LKT than that observed for RBT and BKT. These experiments provide a means to quantify metabolic activation and deactivation of xenobiotics in fish, to compare activation and deactivation reactions across species, and to act as a guide for future predictions of new chemical biotransformation pathways and rates in fish. These experiments provided the necessary rate and capacity (Km and Vmax) inputs that are required to parameterize a fish physiologically based toxicokinetic (PB-TK) model for a reactive chemical that is readily biotransformed, such as phenol. In the future, an extensive database of these rate and capacity parameters on important fish species for selected chemical structures will be needed to allow the effective use of predictive models for reactive, biotransformation chemicals in aquatic toxicology and environmental risk assessment.
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Fishes
Fishes Multiple-
CiteScore
1.90
自引率
8.70%
发文量
311
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