Wong J Y, Seah E S, Lee E J
Department of Pharmacology, National University of Singapore, Singapore.
Ann Acad Med Singap. 2000 May;29(3):401-6.
Genetic variation of drug metabolising enzymes has been recognised as one of the major causes of the inter-individual variability to drug response. The vast majority of drugs are degraded via a small number of metabolic pathways, mainly by microsomal P-450 enzymes localised in the liver and, to a minor extent, in the small intestine. Of these, CYP3A4 is the isozyme involved in the metabolism of most of the clinically useful drugs (50%). This is followed by CYP2D6 (20%), CYP2C9 and CYP2C19 (15%). In addition, minor pathways are catalysed by CYP2E1, CYP1A2, CYP2A6 and unidentified P-450s. Almost 40% of human P-450 dependent drug metabolism is carried out by genetically polymorphic enzymes. Polymorphisms generated by mutations in the genes for these enzymes cause quantitatively or qualitatively altered enzyme expression or activity through multiple molecular mechanisms. While CYP3A4 genetic polymorphisms are just beginning to be unraveled, extensive studies on the CYP2D6 gene over the last decade have identified at least 53 alleles. Of these, more than 20 of them are known to significantly alter the metabolism of CYP2D6 substrates.
This article reviews the information derived from various studies over the past decade and explains the molecular basis of functional differences in CYP2D6 variants, especially with respect to inter-ethnic differences and their clinical implications.
CYP2D6 activity ranges from complete absence to ultra-rapid metabolism. Large inter-individual and inter-ethnic variability exists in the activity of the enzyme, and consequently in the disposition of drugs undergoing oxidative metabolism.
Pharmacokinetic differences resulting from these polymorphisms show potentially important clinical consequences.
药物代谢酶的基因变异已被认为是个体对药物反应存在差异的主要原因之一。绝大多数药物通过少数代谢途径降解,主要由肝脏中的微粒体P-450酶介导,在较小程度上也由小肠中的微粒体P-450酶介导。其中,CYP3A4是参与大多数临床常用药物(50%)代谢的同工酶。其次是CYP2D6(20%)、CYP2C9和CYP2C19(15%)。此外,次要途径由CYP2E1、CYP1A2、CYP2A6和未明确的P-450酶催化。几乎40%的人类P-450依赖性药物代谢是由基因多态性酶进行的。这些酶基因中的突变产生的多态性通过多种分子机制导致酶表达或活性在数量或质量上发生改变。虽然CYP3A4基因多态性刚刚开始被揭示,但过去十年对CYP2D6基因的广泛研究已鉴定出至少53个等位基因。其中,已知有20多个等位基因会显著改变CYP2D6底物的代谢。
本文回顾了过去十年来自各种研究的信息,并解释了CYP2D6变体功能差异的分子基础,特别是关于种族间差异及其临床意义。
CYP2D6活性范围从完全缺失到超快速代谢。该酶的活性在个体间和种族间存在很大差异,因此在进行氧化代谢的药物处置方面也存在很大差异。
这些多态性导致的药代动力学差异显示出潜在的重要临床后果。
