CYP2E1 in 1,4-dioxane metabolism and liver toxicity: insights from CYP2E1 knockout mice study

IF 4.8 2区 医学 Q1 TOXICOLOGY
Yewei Wang, Georgia Charkoftaki, David J. Orlicky, Emily Davidson, Reza Aalizadeh, Ning Sun, Gary Ginsberg, David C. Thompson, Vasilis Vasiliou, Ying Chen
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Abstract

1,4-Dioxane (DX), an emerging water contaminant, is classified as a Group 2B liver carcinogen based on animal studies. Understanding of the mechanisms of action of DX liver carcinogenicity is important for the risk assessment and control of this environmental pollution. Previous studies demonstrate that high-dose DX exposure in mice through drinking water for up to 3 months caused liver mild cytotoxicity and oxidative DNA damage, a process correlating with hepatic CYP2E1 induction and elevated oxidative stress. To access the role of CYP2E1 in DX metabolism and liver toxicity, in the current study, male and female Cyp2e1-null mice were exposed to DX in drinking water (5000 ppm) for 1 week or 3 months. DX metabolism, redox and molecular investigations were subsequently performed on male Cyp2e1-null mice for cross-study comparisons to similarly treated male wildtype (WT) and glutathione (GSH)-deficient Gclm-null mice. Our results show that Cyp2e1-null mice of both genders were resistant to DX-induced hepatocellular cytotoxicity. In male Cyp2e1-null mice exposed to DX for 3 months, firstly, DX metabolism to β-hydroxyethoxyacetic acid was reduced to ~ 36% of WT levels; secondly, DX-induced hepatic redox dysregulation (lipid peroxidation, GSH oxidation, and activation of NRF2 antioxidant response) was substantially attenuated; thirdly, liver oxidative DNA damage was at a comparable level to DX-exposed WT mice, accompanied by suppression of DNA damage repair response; lastly, no aberrant proliferative or preneoplastic lesions were noted in DX-exposed livers. Overall, this study reveals, for the first time, that CYP2E1 is the main enzyme for DX metabolism at high dose and a primary contributor to DX-induced liver oxidative stress and associated cytotoxicity. High dose DX-induced genotoxicity may occur via CYP2E1-independent pathway(s), potentially involving impaired DNA damage repair.

Abstract Image

CYP2E1在1,4-二恶烷代谢和肝脏毒性中的作用:CYP2E1基因敲除小鼠研究的启示。
1,4-二恶烷(DX)是一种新出现的水污染物,根据动物实验被列为 2B 类肝脏致癌物。了解 DX 肝致癌的作用机制对于风险评估和控制这种环境污染非常重要。先前的研究表明,小鼠通过饮用水接触长达 3 个月的高剂量 DX 会导致肝脏轻度细胞毒性和 DNA 氧化损伤,这一过程与肝脏 CYP2E1 诱导和氧化应激升高有关。为了了解 CYP2E1 在 DX 代谢和肝脏毒性中的作用,本研究将雌雄 Cyp2e1 基因缺失的小鼠暴露于饮用水中的 DX(5000 ppm)1 周或 3 个月。随后对雄性 Cyp2e1-null 小鼠进行了 DX 代谢、氧化还原和分子研究,并与处理类似的雄性野生型(WT)和谷胱甘肽(GSH)缺乏的 Gclm-null 小鼠进行了交叉研究比较。我们的研究结果表明,Cyp2e1-null 小鼠对 DX 诱导的肝细胞毒性均有抵抗力。在暴露于DX 3个月的雄性Cyp2e1-null小鼠中,首先,DX代谢成的β-羟乙氧乙酸降低到WT水平的约36%;其次,DX诱导的肝脏氧化还原失调(脂质过氧化、GSH氧化和NRF2抗氧化反应的激活)大大减弱;第三,肝脏氧化 DNA 损伤水平与暴露于 DX 的 WT 小鼠相当,同时 DNA 损伤修复反应受到抑制;最后,暴露于 DX 的肝脏未发现异常增殖或肿瘤前病变。总之,这项研究首次揭示了 CYP2E1 是高剂量 DX 代谢的主要酶,也是 DX 诱导肝脏氧化应激和相关细胞毒性的主要因素。高剂量 DX 诱导的基因毒性可能通过 CYP2E1 依赖性途径发生,可能涉及 DNA 损伤修复受损。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
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来源期刊
Archives of Toxicology
Archives of Toxicology 医学-毒理学
CiteScore
11.60
自引率
4.90%
发文量
218
审稿时长
1.5 months
期刊介绍: Archives of Toxicology provides up-to-date information on the latest advances in toxicology. The journal places particular emphasis on studies relating to defined effects of chemicals and mechanisms of toxicity, including toxic activities at the molecular level, in humans and experimental animals. Coverage includes new insights into analysis and toxicokinetics and into forensic toxicology. Review articles of general interest to toxicologists are an additional important feature of the journal.
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