药物代谢微粒体细胞色素 P450 的功能:蛋白质的硅学探测表明,远端血红素 "活性位点 "口袋在某些酶与底物的相互作用中扮演着相对 "被动 "的角色。

Avanthika Venkatachalam, Abhinav Parashar, Kelath Murali Manoj
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引用次数: 0

摘要

目的:目前对微粒体细胞色素 P450(CYPs)的机理认识是,各种药物分子在深层远端血红素袋中结合,然后在血红素中心发生反应。为了解释大量的实验观察和荟萃分析结果,我们提出了一个涉及 "可扩散自由基介导 "机制的假说。这一新的假说认为,许多底物也可以在酶上/酶内的其他位置结合,并在相关分子与所谓的催化 Fe-O 酶中间体不结合的情况下发生反应:方法:通过对微粒体 CYPs 的各种底物和非底物(不同大小、类别、拓扑结构等的药物分子)进行盲对接和血红素远端口袋中心对接,我们探讨了底物通过远端通道进入的可能性、其结合能、对接方向、反应分子(或分子本身)与血红素中心的距离等。我们研究了以下具体情况:(a)作为底物的大分子药物;(b)经典标记药物底物;(c)作为底物的药物类别(沙坦类、他汀类等);(d)底物偏好。(d) 相关和不相关 CYPs 之间的底物偏好,(e) 人工定点突变体和天然突变体的反应性和代谢处置,(f) 药物与药物之间的相互作用,(g) 药物底物与氧化产物的总体亲和力,(h) 硅与实验结合常数和反应/驻留时间的元分析等:结果:研究发现,底物/调节剂药物分子与现有 CYP 晶体结构的血红素中心对接给出了较差的对接几何图形和与铁血黄素中心的距离。结合其他一些论据,这些发现否定了以前的假说在许多 CYP 系统中的相关性。因此,新提出的假说被认为是一个可行的替代方案,因为它符合奥卡姆剃刀理论:新建议为解释 CYP 介导的药物代谢机制、动力学和整体现象提供了更广阔的空间。现在的理解是,CYPs 的血红素铁和疏水远端口袋主要起到稳定反应中间体(可扩散自由基)的作用,而载体蛋白的表面或隐窝则与异生物底物结合(在某些情况下,血红素远端口袋也可起到后一种作用)。因此,CYPs 可通过一种迄今尚未认识到的方式提高反应速率和选择性/特异性。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Functioning of drug-metabolizing microsomal cytochrome P450s: In silico probing of proteins suggests that the distal heme 'active site' pocket plays a relatively 'passive role' in some enzyme-substrate interactions.

Purpose: The currently held mechanistic understanding of microsomal cytochrome P450s (CYPs) seeks that diverse drug molecules bind within the deep-seated distal heme pocket and subsequently react at the heme centre. To explain a bevy of experimental observations and meta-analyses, we indulge a hypothesis that involves a "diffusible radical mediated" mechanism. This new hypothesis posits that many substrates could also bind at alternate loci on/within the enzyme and be reacted without the pertinent moiety accessing a bonding proximity to the purported catalytic Fe-O enzyme intermediate.

Methods: Through blind and heme-distal pocket centered dockings of various substrates and non-substrates (drug molecules of diverse sizes, classes, topographies etc.) of microsomal CYPs, we explored the possibility of access of substrates via the distal channels, its binding energies, docking orientations, distance of reactive moieties (or molecule per se) to/from the heme centre, etc. We investigated specific cases like- (a) large drug molecules as substrates, (b) classical marker drug substrates, (c) class of drugs as substrates (Sartans, Statins etc.), (d) substrate preferences between related and unrelated CYPs, (e) man-made site-directed mutants' and naturally occurring mutants' reactivity and metabolic disposition, (f) drug-drug interactions, (g) overall affinities of drug substrate versus oxidized product, (h) meta-analysis of in silico versus experimental binding constants and reaction/residence times etc.

Results: It was found that heme-centered dockings of the substrate/modulator drug molecules with the available CYP crystal structures gave poor docking geometries and distances from Fe-heme centre. In conjunction with several other arguments, the findings discount the relevance of erstwhile hypothesis in many CYP systems. Consequently, the newly proposed hypothesis is deemed a viable alternate, as it satisfies Occam's razor.

Conclusions: The new proposal affords expanded scope for explaining the mechanism, kinetics and overall phenomenology of CYP mediated drug metabolism. It is now understood that the heme-iron and the hydrophobic distal pocket of CYPs serve primarily to stabilize the reactive intermediate (diffusible radical) and the surface or crypts of the apoprotein bind to the xenobiotic substrate (and in some cases, the heme distal pocket could also serve the latter function). Thus, CYPs enhance reaction rates and selectivity/specificity via a hitherto unrecognized modality.

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