阿部鲻鰕鯱P450 1A1克隆与分析

细胞色素P450(Cytochrome P450,简称CYP)是生物体内广泛存在的一类重要的代谢酶,它参与包括内源性物质和多种外源性物质(包括药物)在内的各类物质的代谢和转化.     

细胞色素P450酶的结构、功能与应用研究进展

细胞色素P450 (cytochrome P450,CYP)酶是广泛存在于微生物、动植物及人体中与膜结合的血红蛋白类酶,具有氧化、环氧化、羟化、去甲基化等多种生物催化活性。CYP酶在药物、类固醇、脂溶性维生素和许多其他类型化学物质的代谢中具有重要作用,其在异源物质的解毒、药物相互作用和内分泌功能等领域的研究是热点问题。本综述对CYP的结构、功能、临床应用与开发前景进行了概述,并对其最新的研究现状和发展前景进行探讨。     

细胞色素P450的多样性与介导抗性的研究

细胞色素单加氧酶是一类广泛分布在生物体内的重要酶系,在生物体内广泛分布,CYP450参与多种外源性化合物的代谢,内源性物质的合成,在生物体起到十分重要的作用,对P450的研究已从最开始的功能与定位深入到了它的分子机制和多样性等的研究,就P450的多样性、介导抗性的机制和分离方法作一综述。     

细胞色素P450在植物三萜和甾醇骨架修饰中的功能研究进展

植物三萜类化合物在植物生长发育、抵御逆境胁迫与病虫害、生物间相互作用以及传递信息等方面发挥重要作用,植物甾醇具有重要的药用价值.细胞色素P450单加氧酶(CYP450)是参与植物代谢的最大酶家族,在三萜及甾醇骨架结构多样化及功能化修饰中具有关键作用.到目前为止,研究发现约有80个CYP450参与植物三萜代谢,包括亚家族CYP51H, CYP71A, D, CYP72A, CYP81Q, CYP87D, CYP88D, L, CYP93E, CYP705A, CYP708A和CYP716A, C, E, S, U, Y,它们参与包括特定病原体的化学防御功能和药理活性的三萜及其皂苷类化合物的代谢.亚家族CYP51G, CYP85A, CYP90B-D, CYP710A, CYP724B和CYP734A与甾醇和类固醇激素的生物合成有关.本文针对CYP450基因在三萜及甾醇化合物形成过程中不同位点的修饰功能进行概述,重点探讨了陆地植物CYP450基因11个家族的进化及在双子叶、单子叶植物中五环三萜物质合成过程中的功能.以期为充分利用具有重要价值的抗肿瘤、抗艾滋病的三萜物质的合成生物学的研究及其代谢调控提供进一步的理论依据.     

细胞色素P450介导的果蝇抗药性研究进展

细胞色素P450 (cytochrome P450, CYP450)超基因家族是由一些数量多而功能复杂的血红蛋白酶基因所组成,该代谢酶系作为一种几乎地球上所有需氧生物都存在的重要生存策略,可以调控多种内源物质及外源化合物的代谢,参与了众多重要的生命过程,代谢解毒作用是该酶系重要功能之一。细胞色素P450的代谢解毒作用受药物影响,机体通过改变基因表达量,实现增强代谢解毒,加快机体对于有害物质的代谢,从而使得机体对有害环境产生一定的适应性,进而使得机体产生耐药性或抗药性。本研究说明果蝇细胞色素P450介导的杀虫剂类药物代谢机制及代谢抗性的特点等方面的研究,对明确果蝇的抗药性机制研究具有参考意义。     

哺乳动物细胞色素P450酶中底物识别位点与功能的进化关系

细胞色素P450(cytochrome P450,CYP)酶存在于所有哺乳动物中,它们从共同的祖先通过基因倍增进化而来,以一种"爆炸性"的趋势形成了庞大的超家族。除代谢脂质等内源性物质外,部分CYP酶还在药物等外源性物质的代谢方面起到重要作用。通过收集和注释哺乳动物CYP酶的序列发现,家族规模发生显著变化的七个活跃亚家族均属于CYP1~4家族,相比之下,非CYP1~4家族的家族规模则基本保持稳定。基于二级结构的预测结果,六段底物识别位点(substrate recognition sites,SRSs)的进化速率在CYP1~4家族中,特别是活跃的亚家族中,也显著快于非CYP1~4家族。同时,SRS1~3的进化速率显著快于SRS4~6,说明SRS1-3在更大程度上决定了CYP酶在进化过程中所获得的新功能。     

甾醇14a-去甲基化酶(CYP51)的研究进展

甾醇14α-去甲基化酶(CYP51)是分布最广的细胞色素P450家族成员,是生物甾醇合成过程中的关键酶.故CYP51不仅是细胞色素P450蛋白结构、功能、结构与功能关系等研究的模板,而且是重要的降胆固醇药物、抗真菌药物和除草剂作用靶标,具有重要的经济价值.以下就CYP51家族的序列特征、功能(生理功能和生化特征)、结构、结构与功能的关系、CYP51活性的抑制等方面的研究进展进行了综述.并对CYP51抑制剂的研究局限方面进行了讨论,探讨了CYP51抑制剂设计开发的相关问题.     

细胞色素P450酶系与除草剂代谢

细胞色素P450是广泛存在于动物、植物和微生物体内的一类具有混合功能的血红素氧化酶系。它不但能够催化苯丙烷类、萜类化合物和脂肪酸等内源性物质的生物合成 ,而且参与许多外源性物质包括除草剂等的生物氧化。综述了代谢除草剂的细菌、哺乳动物和植物细胞色素P450酶系 ,概述了细胞色素P450酶系参与除草剂代谢的作用方式 :脱烷基化作用、环甲基化羟基化作用和芳环的羟基化作用等。这些细胞色素P450酶系在培育除草剂抗性作物、生物安全和生物修复方面表现出了巨大的潜能     

细胞色素P450：肿瘤研究中的新热点

细胞色素P450（CYP450）是体内重要的Ⅰ相代谢酶,与许多前致癌物和致癌物的活化有关。CYP450是目前肿瘤研究中新的热点之一。深入研究CYP450在肿瘤发生、发展过程中的作用机制及基因多态性与肿瘤易感性的关系,对肿瘤防治有积极作用。现就近年来CYP450在肿瘤领域的研究进展进行综述。     

植物细胞色素P450

对植物细胞色素P450(CYP450)基因的分离,植物CYP450在苯丙烷类物质、芥子油苷及IAA和萜类等物质的生物合成中的功能,以及对天然生物合成与人工合成物质的解毒功能等研究进展作了简要的综述。指出分离植物细胞色素P450基因,并对其生物学功能进行分析以及植物细胞色素P450降解除草剂的机制及其在环境生物修复等方面的应用是今后一段时间内植物CYP450领域的研究热点。     

Structural and biochemical characterization of Mycobacterium tuberculosis CYP142: evidence for multiple cholesterol 27-hydroxylase activities in a human pathogen

The Mycobacterium tuberculosis cytochrome P450 enzyme CYP142 is encoded in a large gene cluster involved in metabolism of host cholesterol. CYP142 was expressed and purified as a soluble, low spin P450 hemoprotein. CYP142 binds tightly to cholesterol and its oxidized derivative cholest-4-en-3-one, with extensive shift of the heme iron to the high spin state. High affinity for azole antibiotics was demonstrated, highlighting their therapeutic potential. CYP142 catalyzes either 27-hydroxylation of cholesterol/cholest-4-en-3-one or generates 5-cholestenoic acid/cholest-4-en-3-one-27-oic acid from these substrates by successive sterol oxidations, with the catalytic outcome dependent on the redox partner system used. The CYP142 crystal structure was solved to 1.6 Å, revealing a similar active site organization to the cholesterol-metabolizing M. tuberculosis CYP125, but having a near-identical organization of distal pocket residues to the branched fatty acid oxidizing M. tuberculosis CYP124. The cholesterol oxidizing activity of CYP142 provides an explanation for previous findings that ΔCYP125 strains of Mycobacterium bovis and M. bovis BCG cannot grow on cholesterol, because these strains have a defective CYP142 gene. CYP142 is revealed as a cholesterol 27-oxidase with likely roles in host response modulation and cholesterol metabolism.     

Progress in cytochrome P450 active site modeling

Models capable of predicting the possible involvement of cytochromes P450 in the metabolism of drugs or drug candidates are important tools in drug discovery and development. Ideally, functional information would be obtained from crystal structures of all the cytochromes P450 of interest. Initially, only crystal structures of distantly related bacterial cytochromes P450 were available-comparative modeling techniques were used to bridge the gap and produce structural models of human cytochromes P450, and thereby obtain some useful functional information. A significant step forward in the reliability of these models came four years ago with the first crystal structure of a mammalian cytochrome P450, rabbit CYP2C5, followed by the structures of two human enzymes, CYP2C8 and CYP2C9, and a second rabbit enzyme, CYP2B4. The evolution of a CYP2D6 model, leading to the validation of the model as an in silico tool for predicting binding and metabolism, is presented as a case study.     

The roles of different porcine cytochrome P450 enzymes and cytochrome b5A in skatole metabolism

Boar taint is the unfavourable odour and taste from pork fat, which results in part from the accumulation of skatole (3-methylindole, 3MI). The key enzymes in skatole metabolism are thought to be cytochrome P450 2E1 (CYP2E1) and cytochrome 2A (CYP2A); however, the cytochrome P450 (CYP450) isoform responsible for the production of the metabolite 6-hydroxy-3-methylindole (6-OH-3MI, 6-hydroxyskatole), which is thought to be involved in the clearance of skatole, has not been established conclusively. The aim of this study was to characterize the role of porcine CYP450s in skatole metabolism by expressing them individually in the human embryonic kidney HEK293-FT cell line. This system eliminates the problems of the lack of specificity of antibodies, inhibitors and substrates for CYP450 isoforms in the pig, and contributions of any other CYP450s that would be present. The results show that pig CYP1A1, CYP2A19, CYP2C33v4, CYP2C49, CYP2E1 and CYP3A and human CYP2E1 (hCYP2E1) are all capable of producing the major skatole metabolite 3-methyloxyindole (3MOI), as well as indole-3-carbinol (I3C), 5-hydroxy-3-methylindole (5-OH-3MI), 6-OH-3MI, 2-aminoacetophenone (2AAP) and 3-hydroxy-3-methyloxindole. CYP2A19 produced the highest amount of the physiologically important metabolite 6-OH-3MI, followed by porcine CYP2E1 and CYP2C49; CYP2A19 also produced more 6-OH-3MI than hCYP2E1. Co-transfection with CYB5A increased the production of skatole metabolites by some of the CYP450s, suggesting that CYB5A plays an important role in the metabolism of skatole. We also show the utility of this expression system to check the specificity of selected substrates and antibodies for porcine CYP450s. Further information regarding the abundance of different CYP450 isoforms is required to fully understand their contribution to skatole metabolism in vivo in the pig.     

Drug metabolism in human brain: high levels of cytochrome P4503A43 in brain and metabolism of anti-anxiety drug alprazolam to its active metabolite

Cytochrome P450 (P450) is a super-family of drug metabolizing enzymes. P450 enzymes have dual function; they can metabolize drugs to pharmacologically inactive metabolites facilitating their excretion or biotransform them to pharmacologically active metabolites which may have longer half-life than the parent drug. The variable pharmacological response to psychoactive drugs typically seen in population groups is often not accountable by considering dissimilarities in hepatic metabolism. Metabolism in brain specific nuclei may play a role in pharmacological modulation of drugs acting on the CNS and help explain some of the diverse response to these drugs seen in patient population. P450 enzymes are also present in brain where drug metabolism can take place and modify therapeutic action of drugs at the site of action. We have earlier demonstrated an intrinsic difference in the biotransformation of alprazolam (ALP) in brain and liver, relatively more alpha-hydroxy alprazolam (alpha-OHALP) is formed in brain as compared to liver. In the present study we show that recombinant CYP3A43 metabolizes ALP to both alpha-OHALP and 4-hydroxy alprazolam (4-OHALP) while CYP3A4 metabolizes ALP predominantly to its inactive metabolite, 4-OHALP. The expression of CYP3A43 mRNA in human brain samples correlates with formation of relatively higher levels of alpha-OH ALP indicating that individuals who express higher levels of CYP3A43 in the brain would generate larger amounts of alpha-OHALP. Further, the expression of CYP3A43 was relatively higher in brain as compared to liver across different ethnic populations. Since CYP3A enzymes play a prominent role in the metabolism of drugs, the higher expression of CYP3A43 would generate metabolite profile of drugs differentially in human brain and thus impact the pharmacodynamics of psychoactive drugs at the site of action.     

The neurosteroid pregnenolone is synthesized by a mitochondrial P450 enzyme other than CYP11A1 in human glial cells

Neurosteroids, modulators of neuronal and glial cell functions, are synthesized in the nervous system from cholesterol. In peripheral steroidogenic tissues, cholesterol is converted to the major steroid precursor pregnenolone by the CYP11A1 enzyme. Although pregnenolone is one of the most abundant neurosteroids in the brain, expression of CYP11A1 is difficult to detect. We found that human glial cells produced pregnenolone, detectable by mass spectrometry and ELISA, despite the absence of observable immunoreactive CYP11A1 protein. Unlike testicular and adrenal cortical cells, pregnenolone production in glial cells was not inhibited by CYP11A1 inhibitors DL-aminoglutethimide and ketoconazole. Furthermore, addition of hydroxycholesterols increased pregnenolone synthesis, suggesting desmolase activity that was not blocked by DL-aminoglutethimide or ketoconazole. We explored three different possibilities for an alternative pathway for glial cell pregnenolone synthesis: (1) regulation by reactive oxygen species, (2) metabolism via a different CYP11A1 isoform, and (3) metabolism via another CYP450 enzyme. First, we found oxidants and antioxidants had no significant effects on pregnenolone synthesis, suggesting it is not regulated by reactive oxygen species. Second, overexpression of CYP11A1 isoform b did not alter synthesis, indicating use of another CYP11A1 isoform is unlikely. Finally, we show nitric oxide and iron chelators deferoxamine and deferiprone significantly inhibited pregnenolone production, indicating involvement of another CYP450 enzyme. Ultimately, knockdown of endoplasmic reticulum cofactor NADPH-cytochrome P450 reductase had no effect, while knockdown of mitochondrial CYP450 cofactor ferredoxin reductase inhibited pregnenolone production. These data suggest that pregnenolone is synthesized by a mitochondrial cytochrome P450 enzyme other than CYP11A1 in human glial cells.     

Essential requirements for substrate binding affinity and selectivity toward human CYP2 family enzymes

A detailed analysis of substrate selectivity within the cytochrome P450 2 (CYP2) family is reported. From a consideration of specific interactions between drug substrates for human CYP2 family enzymes and the putative active sites of CYP2A6, CYP2B6, CYP2C8, CYP2C9, CYP2C19, CYP2D6, and CYP2E1, it is likely that the number and disposition of hydrogen bond donor/acceptors and aromatic rings within the various P450 substrate molecules determines their enzyme selectivity and binding affinity, together with directing their preferred routes of metabolism by the CYP2 enzymes concerned. Although many aliphatic residues are present in most P450 active sites, it would appear that their main contribution centers around hydrophobic interactions and desolvation processes accompanying substrate binding. Molecular modeling studies based on the recent CYP2C5 crystal structure appear to show close agreement with site-directed mutagenesis experiments and with information on substrate metabolism and selectivity within the CYP2 family.     

Cytochromes P450 involved with benzene metabolism in hepatic and pulmonary microsomes

Benzene is an occupational hazard and environmental toxicant found in cigarette smoke, gasoline, and the chemical industry. The major health concern associated with benzene exposure is leukemia. The toxic effects of benzene are dependent on its metabolism by the cytochrome P450 enzyme system. Previous research has identified CYP2E1 as the primary P450 isozyme responsible for benzene metabolism at low concentrations, whereas CYP2B1 is involved at higher concentrations. Our studies using microsomal preparations from human, mouse, and rat indicate that CYP2E1 is the P450 isozyme primarily responsible for benzene metabolism in lung and in liver. CYP2B isozymes have little involvement in benzene metabolism by either lung or liver. Our results also indicate that isozymes of the CYP2F subfamily may play a role in benzene metabolism by lung.     

Quantification of cholesterol-metabolizing P450s CYP27A1 and CYP46A1 in neural tissues reveals a lack of enzyme-product correlations in human retina but not human brain

Cytochrome P450 enzymes (CYP or P450) 46A1 and 27A1 play important roles in cholesterol elimination from the brain and retina, respectively, yet they have not been quantified in human organs because of their low abundance and association with membrane. On the basis of our previous development of a multiple reaction monitoring (MRM) workflow for measurements of low-abundance membrane proteins, we quantified CYP46A1 and CYP27A1 in human brain and retina samples from four donors. These enzymes were quantified in the total membrane pellet, a fraction of the whole tissue homogenate, using 1?N-labled recombinant P450s as internal standards. The average P450 concentrations/mg of total tissue protein were 345 fmol of CYP46A1 and 110 fmol of CYP27A1 in the temporal lobe, and 60 fmol of CYP46A1 and 490 fmol of CYP27A1 in the retina. The corresponding P450 metabolites were then measured in the same tissue samples and compared to the P450 enzyme concentrations. Investigation of the enzyme-product relationships and analysis of the P450 measurements based on different signature peptides revealed a possibility of retina-specific post-translational modification of CYP27A1. The data obtained provide important insights into the mechanisms of cholesterol elimination from different neural tissues.     

P450 gene induction by structurally diverse xenochemicals: central role of nuclear receptors CAR, PXR, and PPAR.

The biochemistry of foreign compound metabolism and the roles played by individual cytochrome P450 (CYP) enzymes in drug metabolism and in the toxification and detoxification of xenochemicals prevalent in the environment are important areas of molecular pharmacology and toxicology that have been widely studied over the past decade. Important advances in our understanding of the mechanisms through which foreign chemicals impact on these P450-dependent metabolic processes have been made during the past 2 years with several key discoveries relating to the mechanisms through which xenochemicals induce the expression of hepatic P450 enzymes. Roles for three "orphan" nuclear receptor superfamily members, designated CAR, PXR, and PPAR, in respectively mediating the induction of hepatic P450s belonging to families CYP2, CYP3, and CYP4 in response to the prototypical inducers phenobarbital (CAR), pregnenolone 16alpha-carbonitrile and rifampicin (PXR), and clofibric acid (PPAR) have now been established. Two other nuclear receptors, designated LXR and FXR, which are respectively activated by oxysterols and bile acids, also play a role in liver P450 expression, in this case regulation of P450 cholesterol 7alpha-hydroxylase, a key enzyme of bile acid biosynthesis. All five P450-regulatory nuclear receptors belong to the same nuclear receptor gene family (family NR1), share a common heterodimerization partner, retinoid X-receptor (RXR), and are subject to cross-talk interactions with other nuclear receptors and with a broad range of other intracellular signaling pathways, including those activated by certain cytokines and growth factors. Endogenous ligands of each of those nuclear receptors have been identified and physiological receptor functions are emerging, leading to the proposal that these receptors may primarily serve to modulate hepatic P450 activity in response to endogenous dietary or hormonal stimuli. Accordingly, P450 induction by xenobiotics may in some cases lead to a perturbation of endogenous regulatory circuits with associated pathophysiological consequences.