雪貂肝细胞中 CYP450 探针底物的代谢稳定性和代谢物鉴定

IF 2.1 4区 医学 Q4 BIOCHEMISTRY & MOLECULAR BIOLOGY
Jiang Pu, Wanyong Feng
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After a 120-minute incubation period, 400 μL of the mixtures were extracted for metabolite identification using UHPLC-QExactive Plus. Results: The metabolic clearance was determined as follows: diclofenac > taxol > chlorzoxazone > dextromethorphan > midazolam > omeprazole > bupropion > phenacetin > testosterone. Seven metabolites were identified from phenacetin. Deethylation was found to be the major pathway, and the major metabolite was matched with acetaminophen as probed with the CYP1A2 enzyme. Six metabolites were identified from diclofenac. Glucuronidation was the primary pathway, and a metabolite was found to match 4-OH-diclofenac as probed with the CYP2C9 enzyme. Twenty-two metabolites were identified from omeprazole. The major metabolic pathways included mono-oxygenation and sulfoxide to thioether conversion. No metabolite was found to match with the 5-OH-omeprazole as probed with the CYP2C19 enzyme. Twenty-two metabolites were identified from dextromethorphan. Demethylation was found to be the major metabolic pathway, and one demethylation metabolite was matched with dextrorphan as probed with CYP2D6. Fourteen metabolites were identified from midazolam. Mono-oxygenation was found to be the primary metabolic pathway, and one of the mono-oxygenation metabolites was matched with 1-OH-midazolam as probed with the CYP3A4 enzyme. Eight metabolites were identified from testosterone. Mono-oxygenation and glucuronidation were identified as the major metabolic pathways. One mono-oxygenation was matched with 6-β-testosterone as probed with CYP3A4 enzyme. Six metabolites were identified from taxol. Hydrolysis and mono-oxygenation were the top two metabolic pathways. No metabolite was matched with 6-α-OH-taxol as probed with the CYP2C8 enzyme. Ten metabolites were identified from bupropion. Mono-oxygenation and hydrogenation were identified as the top two metabolic pathways. No mono-oxygenation metabolite was matched with hydroxy-bupropion as probed with the CYP2B6 enzyme. Nine metabolites were identified from chlorzoxazone. Monooxygenation and sulfation were the top two metabolic pathways. One mono-oxygenation metabolite was matched with 6-OH-chlorzoxazone as probed with the CYP2E1 enzyme. Conclusion: Nine human CYP probe substrates were clearly metabolized in ferret hepatocytes, demonstrating substrate-dependent metabolic rates in ferret hepatocytes and species-dependent metabolic rates in mouse, rat, dog, monkey, and human hepatocytes. Except for 6-a-5-OH-omeprazole, 6-α-OH-taxol, and hydroxy-bupropion, specific metabolites of other six probe substrates in ferret hepatocytes were detected and identified as probed with six human CYP enzymes, respectively. conclusion: In ferret hepatocytes, all nine substrates were metabolized, and the CYP450 enzyme activity was significant. Testosterone and phenacetin exhibited the highest clearance during metabolism, with the CYP450 1A2 and 3A4 isoforms being the primary enzymes involved. 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引用次数: 0

摘要

背景:雪貂的肺部生理结构与人类相似,感染流感后会出现类似的临床症状,因此是研究高易感性和感染模式的宝贵模型。然而,几种常见的人类 CYP450 探针底物在雪貂体中的代谢命运尚不清楚,也没有进行过研究。研究目的本研究旨在调查九种人类 CYP450 探针底物在雪貂肝细胞中的代谢情况,并探讨它们在雪貂和其他物种之间的代谢率差异。研究方法:将九种底物分别在雪貂肝细胞中培养 120 分钟。在每个时间点,提取 30 μL 混合物,使用 LC-MS/MS 方法进行稳定性分析。培养 120 分钟后,提取 400 μL 混合物,使用 UHPLC-QExactive Plus 进行代谢物鉴定。结果代谢清除率的测定结果如下:双氯芬酸;紫杉醇;氯唑沙宗;右美沙芬;咪达唑仑;奥美拉唑;安非他明;苯乙双胍;睾酮。从苯乙哌啶中鉴定出了七种代谢物。发现去乙基化是主要途径,主要代谢物与对乙酰氨基酚相匹配,通过 CYP1A2 酶进行探查。从双氯芬酸中鉴定出了六种代谢物。葡萄糖醛酸化是主要途径,发现一种代谢物与 CYP2C9 酶检测的 4-OH-diclofenac 相匹配。从奥美拉唑中鉴定出 22 种代谢物。主要代谢途径包括单氧化和亚砜到硫醚的转化。经 CYP2C19 酶检测,未发现与 5-OH-omeprazole 相符的代谢物。从右美沙芬中鉴定出 22 种代谢物。发现去甲基化是主要的代谢途径,其中一种去甲基化代谢物与右美沙芬的 CYP2D6 检测匹配。从咪达唑仑中鉴定出 14 种代谢物。发现单氧合作用是主要的代谢途径,其中一个单氧合作用代谢物与 CYP3A4 酶检测的 1-OH-midazolam 匹配。从睾酮中鉴定出了八种代谢物。单氧合和葡萄糖醛酸化被确定为主要的代谢途径。在 CYP3A4 酶的作用下,6-β-睾酮与一种单氧化作用相匹配。从紫杉醇中鉴定出六种代谢物。水解和单氧化是前两种代谢途径。经 CYP2C8 酶检测,没有代谢物与 6-α-OH-taxol 匹配。从安非他明中鉴定出了 10 种代谢物。单氧合作用和氢化作用被确定为最主要的两种代谢途径。经 CYP2B6 酶检测,羟基安非他酮没有与单氧代谢物匹配。从氯唑沙宗中鉴定出九种代谢物。单氧合作用和硫化作用是最主要的两种代谢途径。一种单氧代谢物与 6-OH-chlorzoxazone 相匹配,通过 CYP2E1 酶进行检测。结论九种人类 CYP 探针底物在雪貂肝细胞中被明确代谢,在雪貂肝细胞中显示出底物依赖性代谢率,在小鼠、大鼠、狗、猴和人类肝细胞中显示出物种依赖性代谢率。除 6-a-5-OH-奥美拉唑、6-α-OH-他克索和羟基安非他酮外,其他六种探针底物在雪貂肝细胞中的特异性代谢物均被检测到,并分别与六种人类 CYP 酶进行了探针鉴定:在雪貂肝细胞中,所有九种底物都被代谢,且 CYP450 酶活性显著。睾酮和苯乙酮在代谢过程中的清除率最高,CYP450 1A2 和 3A4 同工酶是参与代谢的主要酶。除了 6-a-5-OH-奥美拉唑、6-α-OH-他克索和 OH-安非他酮外,其余的独特探针都与特定 CYP450 底物的代谢物相匹配。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Metabolic Stability and Metabolite Identification of CYP450 Probe Substrates in Ferret Hepatocytes
Background: Ferrets exhibit similar lung physiology to humans and display similar clinical signs following influenza infection, making them a valuable model for studying high susceptibility and infection patterns. However, the metabolic fate of several common human CYP450 probe substrates in ferrets is still unknown and has not been studied. Objective: The purpose of this study was to investigate the metabolism of nine human CYP450 probe substrates in ferret hepatocytes and explore their metabolic rate differences between ferrets and other species. Method: Nine substrates were individually incubated in ferret hepatocytes for up to 120 min. At each time point, 30 μL mixtures were extracted for stability analysis using LC-MS/MS methods. After a 120-minute incubation period, 400 μL of the mixtures were extracted for metabolite identification using UHPLC-QExactive Plus. Results: The metabolic clearance was determined as follows: diclofenac > taxol > chlorzoxazone > dextromethorphan > midazolam > omeprazole > bupropion > phenacetin > testosterone. Seven metabolites were identified from phenacetin. Deethylation was found to be the major pathway, and the major metabolite was matched with acetaminophen as probed with the CYP1A2 enzyme. Six metabolites were identified from diclofenac. Glucuronidation was the primary pathway, and a metabolite was found to match 4-OH-diclofenac as probed with the CYP2C9 enzyme. Twenty-two metabolites were identified from omeprazole. The major metabolic pathways included mono-oxygenation and sulfoxide to thioether conversion. No metabolite was found to match with the 5-OH-omeprazole as probed with the CYP2C19 enzyme. Twenty-two metabolites were identified from dextromethorphan. Demethylation was found to be the major metabolic pathway, and one demethylation metabolite was matched with dextrorphan as probed with CYP2D6. Fourteen metabolites were identified from midazolam. Mono-oxygenation was found to be the primary metabolic pathway, and one of the mono-oxygenation metabolites was matched with 1-OH-midazolam as probed with the CYP3A4 enzyme. Eight metabolites were identified from testosterone. Mono-oxygenation and glucuronidation were identified as the major metabolic pathways. One mono-oxygenation was matched with 6-β-testosterone as probed with CYP3A4 enzyme. Six metabolites were identified from taxol. Hydrolysis and mono-oxygenation were the top two metabolic pathways. No metabolite was matched with 6-α-OH-taxol as probed with the CYP2C8 enzyme. Ten metabolites were identified from bupropion. Mono-oxygenation and hydrogenation were identified as the top two metabolic pathways. No mono-oxygenation metabolite was matched with hydroxy-bupropion as probed with the CYP2B6 enzyme. Nine metabolites were identified from chlorzoxazone. Monooxygenation and sulfation were the top two metabolic pathways. One mono-oxygenation metabolite was matched with 6-OH-chlorzoxazone as probed with the CYP2E1 enzyme. Conclusion: Nine human CYP probe substrates were clearly metabolized in ferret hepatocytes, demonstrating substrate-dependent metabolic rates in ferret hepatocytes and species-dependent metabolic rates in mouse, rat, dog, monkey, and human hepatocytes. Except for 6-a-5-OH-omeprazole, 6-α-OH-taxol, and hydroxy-bupropion, specific metabolites of other six probe substrates in ferret hepatocytes were detected and identified as probed with six human CYP enzymes, respectively. conclusion: In ferret hepatocytes, all nine substrates were metabolized, and the CYP450 enzyme activity was significant. Testosterone and phenacetin exhibited the highest clearance during metabolism, with the CYP450 1A2 and 3A4 isoforms being the primary enzymes involved. Except for 6-a-5-OH-omeprazole, 6-α-OH-taxol, and OH-bupropion, the remaining unique probes were matched with the metabolites of specific CYP450 substrates.
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来源期刊
Current drug metabolism
Current drug metabolism 医学-生化与分子生物学
CiteScore
4.30
自引率
4.30%
发文量
81
审稿时长
4-8 weeks
期刊介绍: Current Drug Metabolism aims to cover all the latest and outstanding developments in drug metabolism, pharmacokinetics, and drug disposition. The journal serves as an international forum for the publication of full-length/mini review, research articles and guest edited issues in drug metabolism. Current Drug Metabolism is an essential journal for academic, clinical, government and pharmaceutical scientists who wish to be kept informed and up-to-date with the most important developments. The journal covers the following general topic areas: pharmaceutics, pharmacokinetics, toxicology, and most importantly drug metabolism. More specifically, in vitro and in vivo drug metabolism of phase I and phase II enzymes or metabolic pathways; drug-drug interactions and enzyme kinetics; pharmacokinetics, pharmacokinetic-pharmacodynamic modeling, and toxicokinetics; interspecies differences in metabolism or pharmacokinetics, species scaling and extrapolations; drug transporters; target organ toxicity and interindividual variability in drug exposure-response; extrahepatic metabolism; bioactivation, reactive metabolites, and developments for the identification of drug metabolites. Preclinical and clinical reviews describing the drug metabolism and pharmacokinetics of marketed drugs or drug classes.
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