Institute of Apicultural Research, Chinese Academy of Agricultural Sciences, Key Laboratory of Bee Products for Quality and Safety Control, Bee Product Quality Supervision and Testing Center, Ministry of Agriculture, Beijing, 100093, People's Republic of China.
College of Life Science, Yantai University, Yantai, Shandong 264005, People's Republic of China.
J Hazard Mater. 2020 Jul 5;393:121403. doi: 10.1016/j.jhazmat.2019.121403. Epub 2019 Oct 7.
Alpha-zearalenol (α-ZEL) and its masked form α-zearalenol-14 glucoside (α-ZEL-14G) have much higher oestrogenic activity than zearalenone. Owing to very limited toxicokinetic and metabolic data, no reference points could be established for risk assessment. To circumvent it, the toxicokinetic, metabolic profiles, and phenotyping of α-ZEL and α-ZEL-14G were comprehensively investigated in this study. As a result, the plasma concentrations of α-ZEL and α-ZEL-14G were all below LOQ after oral administration, while after iv injection, both could be significantly bio-transformed into various metabolites. A complete hydrolysis of α-ZEL-14G contributed to α-ZEL overall toxicity. Additionally, 31 phase I and 10 phase II metabolites of α-ZEL, and 9 phase I and 5 phase II metabolites were identified for α-ZEL-14G. For α-ZEL, hydroxylation, dehydrogenation, and glucuronidation were the major metabolic pathways, while for α-ZEL-14G, it was deglycosylation, reduction, hydroxylation, and glucuronidation. Significant metabolic differences were observed for α-ZEL and α-ZEL-14G in the liver microsomes of rats, chickens, swine, goats, cows and humans. Phenotyping studies indicated that α-ZEL and α-ZEL-14G were mediated by CYP 3A4, 2C8, and 1A2. Moreover, the deglycosylation of α-ZEL-14G was critically mediated by CES-I and CES-II. The acquired data would provide fundamental perspectives for risk evaluation of mycotoxins and their modified forms.
α-玉米赤霉醇(α-ZEL)及其掩蔽形式α-玉米赤霉醇-14-葡萄糖苷(α-ZEL-14G)比玉米赤霉烯酮具有更高的雌激素活性。由于毒代动力学和代谢数据非常有限,因此无法为风险评估建立参考点。为了克服这一问题,本研究全面研究了α-ZEL 和 α-ZEL-14G 的毒代动力学、代谢谱和表型。结果表明,口服后α-ZEL 和 α-ZEL-14G 的血浆浓度均低于 LOQ,而静脉注射后,两者均可显著转化为各种代谢物。α-ZEL-14G 的完全水解导致α-ZEL 整体毒性增加。此外,鉴定出了α-ZEL 的 31 种 I 相和 10 种 II 相代谢物,以及α-ZEL-14G 的 9 种 I 相和 5 种 II 相代谢物。对于α-ZEL,羟化、脱氢和葡萄糖醛酸化是主要的代谢途径,而对于α-ZEL-14G,则是去糖基化、还原、羟化和葡萄糖醛酸化。在大鼠、鸡、猪、山羊、牛和人肝微粒体中,α-ZEL 和α-ZEL-14G 表现出明显的代谢差异。表型研究表明,α-ZEL 和α-ZEL-14G 由 CYP3A4、2C8 和 1A2 介导。此外,α-ZEL-14G 的去糖基化过程受到 CES-I 和 CES-II 的严格调控。所获得的数据将为真菌毒素及其修饰形式的风险评估提供基础视角。
