HIV-1蛋白酶抑制剂ABT-378的体外代谢：物种比较与代谢物鉴定

In vitro metabolism of the HIV-1 protease inhibitor ABT-378: species comparison and metabolite identification.

作者信息

Kumar G N, Jayanti V, Lee R D, Whittern D N, Uchic J, Thomas S, Johnson P, Grabowski B, Sham H, Betebenner D, Kempf D J, Denissen J F

机构信息

Pharmaceutical Products Division, Abbott Laboratories, Abbott Park, Illinois 60064-3500, USA.

出版信息

Drug Metab Dispos. 1999 Jan;27(1):86-91.

PMID:9884314

Abstract

HIV protease inhibitor ABT-378 (ABT-378) was metabolized very extensively and rapidly by liver microsomes from mouse, rat, dog, monkey, and humans. The rates of NADPH-dependent metabolism of ABT-378 ranged from 2.39 to 9.80 nmol.mg microsomal protein-1.min-1, with monkey liver microsomes exhibiting the highest rates of metabolism. ABT-378 was metabolized to 12 metabolites (M-1 to M-12), which were characterized by mass and NMR spectroscopy. The metabolite profile of ABT-378 in liver microsomes from all five species was similar, except that the mouse liver microsomes did not form M-9, a minor secondary metabolite. The predominant site of metabolism was the cyclic urea moiety of ABT-378. In all five species, the major metabolites were M-1 (4-oxo-ABT-378) and M-3 and M-4 (4-hydroxy-ABT-378). Metabolite M-2 (6-hydroxy-ABT-378) was formed by rodents at a faster rate than by dog, monkey, and human liver microsomes. Metabolites M-5 to M-8 were identified as monohydroxylated derivatives of ABT-378. Metabolites M-9 and M-10 were identified as hydroxylated products of M-1. Metabolites M-11 and M-12 were identified as dihydroxylated derivatives of ABT-378. The metabolite profile in human hepatocytes and liver slices was similar to that of human liver microsomes. The results of the current study indicate that ABT-378 is highly susceptible to oxidative metabolism in vitro, and possibly in vivo, in humans.

摘要

HIV蛋白酶抑制剂ABT - 378在小鼠、大鼠、狗、猴和人类的肝微粒体中代谢非常广泛且迅速。ABT - 378的NADPH依赖性代谢速率在2.39至9.80 nmol·mg微粒体蛋白⁻¹·min⁻¹之间，其中猴肝微粒体的代谢速率最高。ABT - 378被代谢为12种代谢产物（M - 1至M - 12），通过质谱和核磁共振光谱对其进行了表征。除小鼠肝微粒体不形成次要二级代谢产物M - 9外，ABT - 378在所有五个物种肝微粒体中的代谢产物谱相似。主要代谢位点是ABT - 378的环状脲部分。在所有五个物种中，主要代谢产物是M - 1（4 - 氧代 - ABT - 378）以及M - 3和M - 4（4 - 羟基 - ABT - 378）。啮齿动物形成代谢产物M - 2（6 - 羟基 - ABT - 378）的速率比狗、猴和人类肝微粒体更快。代谢产物M - 5至M - 8被鉴定为ABT - 378的单羟基化衍生物。代谢产物M - 9和M - 10被鉴定为M - 1的羟基化产物。代谢产物M - 11和M - 12被鉴定为ABT - 378的二羟基化衍生物。人肝细胞和肝切片中的代谢产物谱与人类肝微粒体的相似。当前研究结果表明，ABT - 378在体外以及可能在人体内对氧化代谢高度敏感。

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HIV-1蛋白酶抑制剂ABT-378的体外代谢：物种比较与代谢物鉴定

In vitro metabolism of the HIV-1 protease inhibitor ABT-378: species comparison and metabolite identification.

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