The biotransformation of nitrogen containing xenobiotics to lactams.

IF 1.8 4区医学 Q4 BIOCHEMISTRY & MOLECULAR BIOLOGY

Current drug metabolism Pub Date : 2000-11-30 DOI:10.2174/1389200003338929

S. Vickers, S. Polsky

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引用次数: 46

Abstract

The metabolism of nitrogen heterocyclics may lead to lactam formation. In early studies on xenobiotic metabolism lactams were identified as metabolites of nicotine, cyproheptadine, tremorine and prolintane. Now, because of the increasing availability of powerful analytical techniques, there are many instances of lactams being identified as metabolites. Lactam metabolites are formed from either iminium ions or carbinolamines. These two intermediates may have distinct mechanisms of formation but they can interconvert. There is evidence that the iminium ions are oxidized to lactams by aldehyde oxidases (cytosolic molybdenum hydroxylases). The tissue distribution and enzyme activities of aldehyde oxidase have been studied in several animal species. However, it is also known that iminium ions can undergo spontaneous hydrolysis to the corresponding carbinolamine. If the latter is stable it may undergo oxidation by cytochrome P-450 to form the lactam. Thus, species differences in lactam formation might be caused by differences in the concentrations of either cytochrome P450 isozymes or aldehyde oxidases. It appears that lactam formation is an end stage in the metabolism of N-heterocycles in that it is unlikely that the lactam will undergo hydrolysis to the corresponding amino acid. Such amino acids probably arise from the amino aldehydes that may be produced from ring opening of unstable carbinolamine intermediates. When microsomal preparations are incubated with the appropriate substrate in the presence of sodium cyanide the iminium ion may be trapped to produce a cyano compound. Such reactions have led to the proposal that iminium ions might react with nucleophilic sites of cellular macromolecules and so contribute to both the pharmacology and toxicology of N-heterocyclic compounds. Other pathways for the formation of lactam metabolites involve the internal cyclization of precursor metabolites, e.g. the self-condensation of an aldehyde group (formed during metabolism) with a neighboring amide group. However, spontaneous ring closures of amino acids to form lactams seem unlikely since it would be anticipated that the amino acid residue would exist as a stable zwitterion under physiological conditions. Thus, it is unlikely that lactams will undergo futile metabolism via hydrolytic ring opening followed by ring closure. Under extreme conditions such unanticipated ring closures may occur and the conditions of metabolite isolation may contribute to the occurrence of artifacts.

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含氮的异种生物转化为内酰胺。

氮杂环的代谢可能导致内酰胺的形成。在早期的外生代谢研究中，内酰胺被鉴定为尼古丁、赛戊乙胺、tremorine和脯氨酸的代谢物。现在，由于越来越强大的分析技术的可用性，有许多内酰胺被确定为代谢物的实例。内酰胺代谢物由亚胺离子或碳胺形成。这两种中间体可能有不同的形成机制，但它们可以相互转化。有证据表明，亚胺离子被醛氧化酶(胞质钼羟化酶)氧化成内酰胺。研究了几种动物体内醛氧化酶的组织分布和酶活性。然而，我们也知道，亚胺离子可以自发水解成相应的碳胺。如果后者是稳定的，它可能会被细胞色素P-450氧化形成内酰胺。因此，内酰胺形成的物种差异可能是由细胞色素P450同工酶或醛氧化酶浓度的差异引起的。内酰胺的形成似乎是n -杂环代谢的最后阶段，因为内酰胺不太可能水解成相应的氨基酸。这种氨基酸可能来自不稳定的碳胺中间体开环产生的氨基醛。当微粒体制剂与适当的底物在氰化钠存在下孵育时，可以捕获亚离子以产生氰化物。这些反应导致人们提出，亚胺离子可能与细胞大分子的亲核位点发生反应，从而对n -杂环化合物的药理学和毒理学都有贡献。内酰胺代谢物形成的其他途径包括前体代谢物的内部环化，例如醛基(在代谢过程中形成)与邻近酰胺基的自缩合。然而，氨基酸自发闭环形成内酰胺似乎不太可能，因为预计氨基酸残基在生理条件下会作为稳定的两性阴离子存在。因此，内酰胺不太可能通过水解打开环然后关闭环进行无用的代谢。在极端条件下，这种意想不到的环闭合可能发生，代谢物分离的条件可能导致伪影的发生。

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 医学-生化与分子生物学

CiteScore

4.30

自引率

4.30%

发文量

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.