细胞色素p450的结构与催化机理

细胞色素P450酶是广泛存在的含亚铁血红素单加氧酶, 参与甾类激素的合成、脂溶性维生素代谢、多不饱和脂肪酸转换为生物活性分子, 以及致癌作用和药物代谢. 综述了细胞色素p450结构与功能的关系, 特别是细胞色素P450活性位点经历大幅度开/关运动结合底物和释放产物以及电子迁移途径.     

细胞色素P-450酶模型的研究:过氧化物的化学反应机理

含有铁卟啉化合物活性中心的细胞色素P-450和其它过氧化物酶具有重要的生物化学功能. 本文讨论了铁卟啉模型物模拟这些酶功能的反应机理. 通过与已知的过氧化物中氧氧键均裂机理的比较, 以及对大部分溶液反应的研究, 表明在过氧化物(包括过氧酸)与铁卟啉生成活性中间体( Fe=O^+.)的过程中, 氧氧键的异裂机理占主导地位. 过氧化物如同其它氧化剂受物(如烯烃)一样, 能快速地直接与 FeO^+反应. 以铁卟啉为催化剂的过氧化物反应体系为我们提供了研究模拟催化酶的人工模型体系.     

Immobilization of Cytochrome P-450 and its Application in Ehzikb Electrodes

Abstract

For application in enzyme electrodes liver microsomal cytochrome P-450 was immobilized in a membraneous form. The immobilization yielded 60% of activity and did not impair the functional stability of the enzyme. By coimmobilization of glucose oxidase with P-450 the cofactor NADPH could be replaced by H₂O₂ formed from the enzymatic glucose oxidation. Fixed to a graphite electrode the obtained preparations were employed for quantitative substrate analysis. The P-450 substrate aniline was measured by anodic oxidation of its hydroqlation product at +250mV. A linear dependence of: the current on aniline concentration up to 0.5mM was obtained.     

Catalytic Cyclophanes. Part XI. A flavo-thiazolio-cyclophane as a biomimetic catalyst for the preparative-scale electro-oxidation of aromatic aldehydes to methyl esters

Flavo-thiazolio-cyclophane 6 was prepared on a gram scale by an 18-step synthesis (Schemes 3 and 4). This pathway involved the very efficient preparation of bromo-cyclophane 32 (37% yield over 13-steps), which can be readily modified to create various multiply functionalized receptors. This bromide 32 was subsequently converted into the corresponding boronic acid and connected to the 7-bromoflavin 10 (Scheme 2) via Suzuki coupling to give flavo-cyclophane 36 . The thiazolium unit was then introduced after quaternization of the tertiary amino groups of 36 . Flavo-thiazolio-cyclophane 6 , with both prosthetic groups attached in proximity to the well-defined cyclophane binding site, is a functional model for the enzyme pyruvate oxidase. In basic methanolic solution, 6 catalyzes the oxidation of aromatic aldehydes to their corresponding methyl esters. Cyclophane 6 shows saturation kinetics, and the turnover number calculated for the oxidation of naphthalene-2-carbaldehyde to methyl naphthalene-2-carboxylate (k_cat = 0.22 s⁻¹) is one of the highest reported for an artificial enzyme. Control experiments showed that the catalytic advantages of 6 result from the macrocyclic binding and reaction site as well as from the covalent attachment of both cofactors to this site. The catalytic cycle is completed by electrochemical re-oxidation of the reduced flavin moiety at a low working electrode potential (- 0.3 V vs. Ag/AgCl), and up to ca. 100 catalytic cycles can be performed on a preparative scale, The intramolecular nature of the electron transfer from the active aldehyde intermediate to the flavin is particularly conducive to the oxidation of unreactive aldehydes.     

Association of Cytochrome P450 Enzymes is a Determining Factor in their Catalytic Activity

Previously, our laboratory demonstrated that one cytochrome P450 isoenzyme can influence the catalytic properties of another P450 isoenzyme when combined in a reconstituted system. Moreover, our data and that of other investigators indicate that P450 interaction is required for catalytic activity even when one isoenzyme is present. The goal of the current study was to examine the possible mechanism of these interactions in more detail. Analyzing recently published X-ray data of microsomal P450 enzymes and protein docking studies, four types of dimer formations of P450 enzymes were examined in more detail. In case of two dimer types, the aggregating partner was shown to contribute to NADPH cytochrome P450 reductase (CPR) binding-a flavoprotein whose interaction with P450 is required for expressing P450 functional activity of the neighboring P450 moiety. Thus, it was shown that dimerization of P450 enzymes might result in an altered affinity towards the CPR. Two dimer types were shown to exist only in the presence of a substrate, while the other two types exist also without a substrate present. The molecular basis was established for the fact that the presence of a substrate and other P450 enzymes simultaneously determine the catalytic activity. Furthermore, a kinetic model was improved describing the catalytic activity of P450 enzymes as a function of CPR concentration based on equilibrium between different supramolecular organizations of P450 enzymes. This model was successfully applied in order to explain our experimental data and that of other investigators.Eszter Hazai and Zsolt Bikádi contributed equally to this workDavid Kupfer-Deceased     

Fractionation by High Performance Liquid Chromatography of Microsomal Cytochrome P-450 Induced by Hexachlorobiphenyl Isomers

Abstract

High performance liquid chromatography has been employed to fractionate rat liver microsomes under nondenaturing conditions. Selective detection at 405 nm allowed resolution of microsomal heme proteins into three peaks (A, B, and C). Cytochromes in the peaks retain their native property of binding CO after HPLC. Peak-A, first eluting, contains P-450 and is rich in cytochrome P-420. Peak-B is largely hemoglobin and peak-C is a major cytochrome P-450. The ratio of peak-C to A is increased by treatment of rats with phenobarbitone, β-naphthoflavone, 2,3,5,2′,3′,5′-hexachlorobiphenyl and 3,4,5,3′,4′,5′-hexachlorobiphenyl as compared to controls. The highest increment in the ratio is observed on feeding 3,4,5,3′,4′,5′-hexachlorobiphenyl. NADPH cytochrome c reductase elutes earlier than peak-C but cytochrome b₅ is not separated from the major cytochrome P-450 peak. The separations obtained are highly reproducible and considerably faster than conventional gel permeation chromatography. The data presented here are very promising in establishing the role of HPLC in the studies of insoluble proteins and enzymes in general and cytochrome P-450 in particular.     

Cytochrome P-450 model compound catalyzed selective hydroxylation of C-H bonds: dramatic solvent effect

Selective hydroxylation of cyclohexane and cyclohexene by t-BuOOH in presence of F2oTPPFe(III)Cl as the catalyst has been achieved at room temparature in high yields.     

Immobilization of cytochrome P-450 and electrochemical control of its activity

P-450_cam (camphor-induced cytochrome P-450) was immobilized on an indium tin oxide (ITO) electrode by polypyrrole and its activity was controlled electrochemically. The results showed that P-450_cam was immobilized on the ITO electrode without denaturing and the amount of P-450_cam could be easily controlled. When, the electric potential was swept repeatedly between 0.4 and 0 V, the remarkable decrease of oxygen in the reaction mixture solution was observed only in the presence of camphor. In addition, hydroxycamphor was detected only in the same system by means of gas chromatography/mass spectroscopy. These results suggested that immobilized P-450_cam catalyzed the hydroxylation of camphor by the supply of electron from the electrode. The effect of pH and ionic strength on the activity was examined, and it was found that the high activity expressed at the pH of 6.0 – 7.0 and KCl concentration of 0.1 – 0.2 M . The paper is the first report that P-450 enzyme activity could be controlled artificially. © 1998 John Wiley & Sons, Ltd.     

Detection of the enzymatic activity of cytochrome P-450 enzymes by high-performance liquid chromatography.

The reactions catalysed by the various cytochrome P-450 enzymes are reviewed with respect to the analysis of products by high-performance liquid chromatography (HPLC). Especially biotransformation reactions of purified cytochrome P-450 enzymes in a reconstituted system and in microsomes mainly of rat liver origin are considered. Emphasis is put on the specificity of product formation due to the individual isozymes of cytochrome P-450. It is shown that the presence of eight cytochrome P-450 isozymes can be monitored and determined by specific product formation after HPLC analysis, which is an important parameter in toxicological studies.     

The Allylic Oxidation of Geraniol Catalyzed by Cytochrome P-450Cath., Proceeding with retention of configuration

Incubation of the geraniols (R)-(8-²H₁)[8-³H₁]- 1 and (S)-(8-²H₁)[8-³H₁]- 1 with microsomal cytochrome P-450_Cath. from the subtropical plant Catharanthus roseus (L.)G. DON resulted in the formation of the chiral 8-hydroxygeraniols (S)-(8-²H₁)[8-³H₁]- 2 and (R)-(8-²H₁)[8-³H₁]- 2 . Their absolute configuration was assigned on the basis of the ¹H-decoupled ³H-NMR Spectra of the corresponding dicamphanates (S)-(8-²H₁)[8-³H₁]- 9 and (R)-(8-²H₁)[8-³H₁]- 9 , of which the configurations are established in relation to the synthetic reference samples. The results clearly indicate retention of configuration during the allylic oxidation of 1 .     

Dual Catalytic Activity of a Cytochrome P450 Controls Bifurcation at a Metabolic Branch Point of Alkaloid Biosynthesis in Rauwolfia serpentina

Plants create tremendous chemical diversity from a single biosynthetic intermediate. In plant‐derived ajmalan alkaloid pathways, the biosynthetic intermediate vomilenine can be transformed into the anti‐arrhythmic compound ajmaline, or alternatively, can isomerize to form perakine, an alkaloid with a structurally distinct scaffold. Here we report the discovery and characterization of vinorine hydroxylase, a cytochrome P450 enzyme that hydroxylates vinorine to form vomilenine, which was found to exist as a mixture of rapidly interconverting epimers. Surprisingly, this cytochrome P450 also catalyzes the non‐oxidative isomerization of the ajmaline precursor vomilenine to perakine. This unusual dual catalytic activity of vinorine hydroxylase thereby provides a control mechanism for the bifurcation of these alkaloid pathway branches. This discovery highlights the unusual catalytic functionality that has evolved in plant pathways.     

Electrochemical Activation of the Natural Catalytic Cycle of Cytochrome P450s in Human Liver Microsomes

The natural catalytic cycle of cytochrome (cyt) P450 enzymes in human liver microsome (HLM) films was activated electrochemically via the electron transfer sequence electrode→cyt P450 reductase (CPR)→cyt P450. Cyclic voltammograms for HLM films had midpoint potentials of ?0.50 V vs. SCE at pH 7.4 characteristic of CPR, not cyt P450s. HLM and CPR microsomes without cyt P450s did not electrocatalytically reduce H₂O₂, and did not shift midpoint potential when CO was added, also indicating that the peaks do not correspond to iron heme cyt P450 enzymes. Electrochemical activation of the natural cyt P450 cycle for substrate conversion via CPR in HLM films was confirmed by catalytic electrolysis in an electrochemical microfluidic array designed to generate and detect reactive metabolites by measuring their reactivity with DNA.     

杯[6]芳烃-双金属卟啉仿P-450酶模型的研究Ⅳ.对异丙苯氧化的催化行为

研究了杯[6]芳烃-双金属卟啉在氧化异丙苯中的催化行为，结果表明杯[6]芳烃-双金属卟啉比之相应的金属卟啉具有更高的催化活性，并表现同样的选择性，生成苯乙酮和醇组份。此一结果同通常酞菁或其它如西弗碱大分子金属络合物催化下生成丙酮和酚不同。还考察了温度、轴向配体、催化剂用量及金属离子种类等对反应的影响，仔细地通过测定反应速度比较了反应的活性。     

Catalytic hydroxylation on aromatic rings by use of an artificial P-450 system assisted by acid and acid anhydride.

Aromatic compounds are effectively monohydroxylated by the artificial P-450 type catalytic system, consisting of TPP · Mn, N-methylimidazole, colloidal Pt, O₂ and H₂. Addition of benzoic anhydride and/or hydrogen chloride favored o- and p-hydroxylation.     

A Minimal Functional Complex of Cytochrome P450 and FBD of Cytochrome P450 Reductase in Nanodiscs

Structural interactions that enable electron transfer to cytochrome‐P450 (CYP450) from its redox partner CYP450‐reductase (CPR) are a vital prerequisite for its catalytic mechanism. The first structural model for the membrane‐bound functional complex to reveal interactions between the full‐length CYP450 and a minimal domain of CPR is now reported. The results suggest that anchorage of the proteins in a lipid bilayer is a minimal requirement for CYP450 catalytic function. Akin to cytochrome‐b₅ (cyt‐b₅), Arg 125 on the C‐helix of CYP450s is found to be important for effective electron transfer, thus supporting the competitive behavior of redox partners for CYP450s. A general approach is presented to study protein–protein interactions combining the use of nanodiscs with NMR spectroscopy and SAXS. Linking structural details to the mechanism will help unravel the xenobiotic metabolism of diverse microsomal CYP450s in their native environment and facilitate the design of new drug entities.