Fluoropyrimidine Toxicity: the Hidden Secrets of DPYD.

IF 2.1 4区 医学 Q4 BIOCHEMISTRY & MOLECULAR BIOLOGY
Vangelis G Manolopoulos, Georgia Ragia
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引用次数: 0

Abstract

Background: Fluoropyrimidine-induced toxicity is a main limitation of therapy. Currently, polymorphisms in the DPYD gene, which encodes the 5-FU activation enzyme dihydropyrimidine dehydrogenase (DPD), are used to adjust the dosage and prevent toxicity. Despite the predictive value of DPYD genotyping, a great proportion of fluoropyrimidine toxicity cannot be solely explained by DPYD variations.

Objective: We herein summarize additional sources of DPD enzyme activity variability, spanning from epigenetic regulation of DPYD expression, factors potentially inducing protein modifications, as well as drug-enzyme interactions that contribute to fluoropyrimidine toxicity.

Results: While seminal in vitro studies provided evidence that DPYD promoter methylation downregulates DPD expression, the association of DPYD methylation with fluoropyrimidine toxicity was not replicated in clinical studies. Different non-coding RNA molecules, such as microRNA, piwi-RNAs, circular-RNAs and long non-coding RNAs, are involved in post-transcriptional DPYD regulation. DPD protein modifications and environmental factors affecting enzyme activity may also add a proportion to the pooled variability of DPD enzyme activity. Lastly, DPD-drug interactions are common in therapeutics, with the most well-characterized paradigm the withdrawal of sorivudine due to fluoropyrimidine toxicity deaths in 5-FU treated cancer patients; a mechanism involving DPD severe inhibition.

Conclusions: DPYD polymorphisms are the main source of DPD variability. A study on DPYD epigenetics (both transcriptionally and post-transcriptionally) holds promise to provide insights into molecular pathways of fluoropyrimidine toxicity. Additional post-translational DPD modifications, as well as DPD inhibition by other drugs, may explain a proportion of enzyme activity variability. Therefore, there is still a lot we can learn about the DPYD/DPD fluoropyrimidine-induced toxicity machinery.

氟嘧啶的毒性:DPYD 的隐秘。
背景:氟嘧啶引起的毒性是治疗的主要限制因素。目前,编码 5-FU 活化酶二氢嘧啶脱氢酶(DPD)的 DPYD 基因的多态性被用于调整剂量和预防毒性。尽管 DPYD 基因分型具有预测价值,但很大一部分氟嘧啶类药物的毒性并不能完全由 DPYD 变异解释:我们在此总结了 DPD 酶活性变异的其他来源,包括 DPYD 表达的表观遗传调控、可能诱导蛋白质修饰的因素以及导致氟嘧啶毒性的药物-酶相互作用:尽管开创性的体外研究提供了 DPYD 启动子甲基化下调 DPD 表达的证据,但 DPYD 甲基化与氟嘧啶毒性的关联并未在临床研究中得到证实。不同的非编码 RNA 分子,如 microRNA、piwi-RNA、环状 RNA 和长非编码 RNA,参与了转录后 DPYD 的调控。影响酶活性的 DPD 蛋白质修饰和环境因素也可能增加 DPD 酶活性的总体变异性。最后,DPD与药物的相互作用在治疗中很常见,其中最典型的例子是,5-FU治疗的癌症患者因氟嘧啶中毒死亡而停用索立乌丁;其机制涉及DPD的严重抑制:结论:DPYD 多态性是 DPD 变异的主要来源。对 DPYD 表观遗传学(转录和转录后)的研究有望深入了解氟嘧啶毒性的分子途径。DPD翻译后的其他修饰以及其他药物对DPD的抑制可能会解释部分酶活性的变化。因此,关于 DPYD/DPD 氟嘧啶诱导毒性机制,我们还有很多东西可以学习。
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
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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