人与大鼠体内罗红霉素去甲基化代谢(英文)

目的:研究罗红霉素在人体和大鼠体内的去甲基化代谢途径,并研究去甲基罗红霉素的体外抗菌活性方法:采用LC-MS方法测定了罗红霉素在人体和大鼠体内的去甲基代谢产物;并用二倍稀释法,选择三种生物检测实验标准菌株,测定了罗红霉素、去甲基代谢产物以及其他几种主要代谢产物的体外抗菌活性。结果:罗红霉素在人体内主要经历O-去甲基化代谢,而在大鼠体内主要经历N-去甲基化代谢。代谢物O-去甲基罗红霉素具有与母体药相当的体外抗菌活性。结论:O-去甲基罗红霉素是罗红霉素在人体内的活性代谢产物,罗红霉素在人与大鼠体内的去甲基化产物具有种属差异。     

N-Demethylation of clomipramine in human liver microsomes in vitro1

采用人肝微粒体应用酶促动力学分析,观察特异性细胞色素P450(CYP450)抑制剂对氯米帕明(CIM) N-去甲基代谢的作用以及CIM去甲基代谢与S-美芬妥英4′-羟化代谢的相关性,以阐明参与CIM N-去甲基代谢的CYP450的种类, 性质及其在代谢中的作用. 酶促动力学分析结果表明有高亲和力酶及具有底物别构激活特性的低亲和力酶参与了CIM的N-去甲基代谢. 抑制实验结果表明CYP 1A2特异性抑制剂呋拉茶碱（Fur）主要抑制低浓度CIM的去甲基代谢,CYP 3A4特异性抑制剂醋竹桃霉素（TAO）主要抑制高浓度CIM去甲基代谢. 相关实验发现3 μmol     

地尔硫抑制大鼠肝脏药物代谢的机制

目的:研究地尔硫(艹卓)(DZ)抑制大鼠肝脏药物代谢的机制.方法:(1)SD大鼠未诱导或经地塞米松(DEX)、苯巴比妥(PB)、β萘黄酮(BNF)诱导,制备肝微粒体,于DZ体外37℃温孵25min,检测细胞色素P450-Fe(Ⅱ)-代谢物(MI)复合物.(2)未诱导大鼠ip DZ 100mg/kg 3d,或经DEX诱导再给予单剂量DZ 100mg/kg,制备肝微粒体并检测MI复合物.结果:DEX、PB诱导组在体外分别有30.62%和10.30%MI复合物形成.未诱导大鼠ip DZ 3d,体内检测到7.9%MI复合物;经DEX诱导再给予单剂量DZ的大鼠,体内有17.57%MI复合物形成.结论:DZ在大鼠肝脏中经细胞色素P450 3A催化,发生N-去甲基化,生成的活性代谢物可与P450 3A络合而形成MI复合物,使P450 3A丧失部分活性.     

去氢土莫酸在大鼠体外肝微粒体体系中的生物转化研究

目的:研究中药茯苓中主要化学成分之一的去氢土莫酸在大鼠肝微粒体中的生物转化.方法:用大鼠肝微粒体体外温孵法进行去氢土莫酸的生物转化,优化了温孵体系;高效液相色谱法检测和制备原形化合物去氢土莫酸及其生物转化产物,核磁共振波谱法和质谱法确定生物转化产物的结构.结果:去氢土莫酸在苯巴比妥诱导的大鼠肝微粒体药物代谢酶作用下,产生2个转化产物,分别为土莫酸和去氢茯苓酸.结论:去氢土莫酸可被苯巴比妥诱导的大鼠肝微粒体药物代谢酶转化为土莫酸和去氢茯苓酸.     

CYP2C19基因型和CYP2C9对人肝微粒体中氟西汀N-去甲基代谢的影响(英文)

目的:本实验旨在研究CYP2C19基因型人肝微粒体中氟西汀N-去甲基代谢的酶促动力学特点并鉴定参与此代谢途径的细胞色素P-450酶。方法:测定基因型CYP2C19肝微粒体中去甲氟西汀形成的酶促动力学。鉴定氟西汀N-去甲基酶活性与细胞色素P-450 2C9,2C19,1A2和2D6酶活性的相关性,同时应用各种细胞色素P-450酶的选择性抑制剂和化学探针进行抑制实验,从而确定参与氟西汀N-去甲基代谢的细胞色素P-450酶。结果:去甲氟西汀生成的酶促动力学数据符合单酶模型,并具有Michaelis-Menten动力学特征。当底物浓度为氟西汀25μmol/L和100μmol/L时,去甲氟西汀(N-FLU)的生成率分别与甲磺丁脲3-羟化酶活性显著相关(r_1=0.821,P_1=0.001;r_2=0.668,P_2=0.013),当底物浓度为氟西汀100μmol/L时,N-FLU的生成率与S-美芬妥因4’-羟化酶活性显著相关(r=0.717,P=0.006)。PM肝微粒中磺胺苯吡唑和醋竹桃霉素对氟西汀N-去甲基代谢的抑制作用显著大于EM(73％vs 45％,P<0.01)。结论:在生理底物浓度下,CYP2C9是催化人肝微粒体中氟西汀N-去甲基代谢的主要CYP-450酶;而高底物浓度时,以CYP2C19的作用为主。     

镉、铅、汞对苯巴比妥诱导肝微粒体药物代谢酶的影响

一次ip醋酸镉2.4mg/kg、醋酸铅100mg/kg或氯化汞 2.0 mg/kg均可抑制大鼠肝微粒体药物代谢酶。上述处理还可明显降低苯巴比妥对肝微粒’乙基吗啡N-脱甲基化酶、氨基比林N-脱甲基化酶、苯胺羟化酶和环己巴比妥羟化酶活力的诱导作用,降低苯巴比妥对细胞色素P450和细胞色素 b_5以及微粒体蛋白合成的诱导作用。结果提示镉、铅、汞可能通过降低微粒体酶的新生合成,抑制肝微粒体药物代谢酶。     

西格列他钠的体外代谢

目的研究拟治疗2型糖尿病的创新化合物西格列他钠(chiglitazar)的体外代谢速率、代谢酶和代谢转化,为临床应用提供参考。方法采用高效液相-紫外检测(HPLC-UV)的方法测定肝微粒体孵育液中西格列他钠的浓度,用特异性抑制剂的方法分析化合物的代谢酶,用大鼠肝微粒体体外研究西格列他钠可能的代谢产物和代谢途径。结果建立了可靠的测定大鼠肝微粒体中西格列他钠的HPLC分析方法;体外半衰期方法求得西格列他钠的t1/2为27.2min,固有清除率(Clint)为50.9mL.min-1.g-1蛋白;代谢酶研究表明,西格列他钠主要被P450酶中的CYP3A亚型代谢;西格列他钠在大鼠肝微粒体中的代谢主要为羟基化和O-脱烷基化,采用LC/MSn分析共发现了8个代谢物。结论西格列他钠是代谢活跃的化合物,有必要研究代谢产物的活性及临床注意药物相互作用。     

细胞色素P450 3A在胎肾上腺和胎肝中的表达

采用酶学和逆转录聚合酶链式反应 ( RT-PCR)技术 ,研究与药物代谢密切相关的细胞色素P450 3A( CYP3A)在胎肾上腺和胎肝中的表达 .结果表明 ,胎肾上腺微粒体中苄非他明 ,氨基比林 ,红霉素 N-脱甲基酶和睾酮 6β-羟化酶活性分别为胎肝微粒体的 2 1 % ,2 60 % ,1 0 5%和 33% .CYP诱导剂苯巴比妥能显著增加体外培养胎肾上腺细胞中苄非他明和氨基比林 N-脱甲基酶活性 ,诱导剂地塞米松也能明显诱导红霉素 N-脱甲基酶活性 .RT- PCR表明胎肾上腺和胎肝中存在 CYP3A7m RNA表达 .说明胎肾上腺和胎肝中存在 CYP3A亚族 .上述结果提示处于发育时期的肾上腺具有与胎肝能力相当的药物代谢功能 .     

去氢厄弗酚在小鼠肝微粒体中代谢产物及CYP450酶亚型的鉴定

目的建立去氢厄弗酚(DHE)小鼠体外肝微粒体孵育方法,鉴定DHE在小鼠肝微粒体中的代谢产物及参与DHE代谢的CYP450酶亚型。方法采用UPLC-Q-TOF-MS/MS分析鉴定DHE在体外肝微粒体共温孵后的代谢产物,筛选7种CYP450酶亚型,并通过特异性化学抑制剂法,鉴别参与DHE代谢的主要CYP450酶亚型。结果在体外肝微粒体共温孵后,检测到4个代谢产物;所筛选的7种CYP450酶亚型中,CYP1A2、CYP2C8和CYP2D2对DHE体外肝微粒体代谢的参与度较高。结论在肝脏中,有多种代谢酶亚型参与DHE的代谢,表明DHE在临床上不易与其他药物产生相互作用。     

肉豆蔻木脂素的体外代谢初步研究

目的建立诱导的大鼠肝微粒体药物代谢酶体外转化模型,评价肉豆蔻木脂素的体外代谢情况,为规模化制备肉豆蔻木脂素的代谢产物提供方法.方法将肉豆蔻木脂素与苯巴比妥诱导的大鼠肝微粒体药物代谢酶共温孵,用高效液相色谱法检测肉豆蔻木脂素及其代谢产物.结果肉豆蔻木脂素在苯巴比妥诱导的大鼠肝微粒体药物代谢酶作用下,可以被代谢,并且发现了7个代谢产物.结论建立的肝微粒体药物代谢酶模型可靠有效,可用于肉豆蔻中肉豆蔻木脂素的体外代谢研究.     

Metabolism and metabolic inhibition of gambogic acid in rat liver microsomes

AIM: To study the metabolism of gambogic acid (GA) and the effects of selective cytochrome P-450 (CYP450) inhibitors on the metabolism of GA in rat liver microsomes in vitro. METHODS: Rat liver microsomes were used to perform metabolism studies. Various selective CYP450 inhibitors were used to investigate their effects on the metabolism of GA and the principal CYP450 isoform involved in the formation of major metabolite M(1) in rat liver microsomes. Types of inhibition in an enzyme kinetics model were used to model the interaction. RESULTS: GA was rapidly metabolized to two phase I metabolites, M(1) and M(2), in rat liver microsomes. M(1) and M(2) were tentatively presumed to be the hydration metabolite and epoxide metabolite of GA, respectively. alpha-Naphthoflavone uncompetitively inhibited the formation of M(1) while ketoconazole, sulfaphenazole, diethyl dithiocarbamate and quinidine had little or no inhibitory effects on the formation of M(1). CONCLUSION: GA is rapidly metabolized in rat liver microsomes and M(1) is crucial for the elimination of GA. Cytochrome P-450 1A2 is the major rat CYP involved in the metabolism of GA.     

CYP3A4 mediated in vitro metabolism of vinflunine in human liver microsomes

AIM: To study the metabolism of vinflunine and the effects of selective cytochrome P-450 (CYP450) inhibitors on the metabolism of vinflunine in human liver microsomes. METHODS: Individual selective CYP450 inhibitors were used to investigate their effects on the metabolism of vinflunine and the principal CYP450 isoform involved in the formation of metabolites M(1) and M(2) in human liver microsomes. RESULTS: Vinflunine was rapidly metabolized to 2 metabolites: M(1) and M(2) in human liver microsomes. M(1) and M(2) were tentatively presumed to be the N-oxide metabolite or hydroxylated metabolite and epoxide metabolite of vinflunine, respectively. Ketoconazole uncompetitively inhibited the formation of M(1), and competitively inhibited the formation of M(2), while alpha-naphthoflavone, sulfaphenazole, diethyl dithiocarbamate, tranylcypromine and quinidine had little or no inhibitory effect on the formation of M(1) and M(2). CONCLUSION: Vinflunine is rapidly metabolized in human liver microsomes, and CYP3A4 is the major human CYP450 involved in the metabolism of vinflunine.     

Role of rat liver cytochrome P450 3A and 2D in metabolism of imrecoxib

AIM: To investigate the in vitro metabolism of imrecoxib in rat liver microsomes and to identify the cytochrome P450 (CYP) forms involved in its metabolism. METHODS: Liver microsomes of Wistar rats were prepared using an ultracentrifuge. The in vitro metabolism of imrecoxib was studied by incubation with rat liver microsomes. To characterize the CYP forms involved in the 4 '-methyl hydroxylation of imrecoxib, the effects of typical CYP inducers (such as dexamethasone, isoniazid and beta-naphthoflavone) and of CYP inhibitors (such as ketoconazole, quinine, alpha-naphthoflavone, methylpyrazole, and cimetidine) on the formation rate of 4 '-hydroxymethyl imrecoxib were investigated. RESULTS: Imrecoxib was metabolized to 3 metabolites by rat liver microsomes: 4'-hydroxymethyl imrecoxib (M4), 4'-hydroxymethyl-5-hydoxyl imrecoxib (M3), and 4 '-hydroxymethyl-5-carbonyl imrecoxib (M5). Over the imrecoxib concentration range studied (5-600 micromol/L), the rate of 4'-methyl hydroxylation conformed to monophasic Michaelis-Menten kinetics. Dexamethasone significantly induced the formation of M4. Ketoconazole markedly lowered the metabolic rate of imrecoxib in a concentration-dependent manner. Moreover, a significant inhibitory effect of quinine on the formation of M4 was observed in microsomes obtained from control rats, isoniazid-induced rats, and b-naphthoflavone-induced rats. In contrast, a-naphthoflavone, cimetidine, and methylpyrazole had no inhibitory effects on this metabolic pathway. CONCLUSION: Imrecoxib is metabolized via 4'-methyl hydroxylation in rat liver microsomes. The reaction is mainly catalyzed by CYP 3A. CYP 2D also played a role in control rats, in isoniazid-induced rats and in beta-naphthoflavone-induced rats.     

Metabolism of pigment yellow 74 by rat and human microsomal proteins.

Pigment Yellow 74 (PY74) is a monoazo pigment that is used in yellow tattoo inks. The metabolism of PY74 was investigated using rat liver and human liver microsomes and expressed human cytochromes P450 (P450s). Two phase I metabolites were isolated and characterized by mass spectrometry and NMR techniques. One metabolite (PY74-M1) was a ring hydroxylation product of PY74, 2-((2-methoxy-4-nitrophenyl)azo)-N-(2-methoxy-4-hydroxyphenyl)-3-oxobutanamide. The second metabolite (PY74-M2) was identified as 2-((2-hydroxy-4-nitrophenyl)azo)-N-(2-methoxy-4-hydroxyphenyl)-3-oxobutanamide, which is the O-demethylation product of PY74-M1. These metabolites were formed by in vitro incubations of PY74 with 3-methylcholanthrene-induced rat liver microsomes and to a much lesser extent by liver microsomes from untreated or phenobarbital-induced rats. The role for CYP1A in the metabolism of PY74 was confirmed using expressed human P450s. The catalytic ability of the P450s for metabolism of PY74 was CYP 1A2 > CYP 1A1 > CYP 3A4 approximately CYP 1B1 (no activity with CYP 2B6, 2C9, 2D6 or 2E1). The metabolism of PY74-M1 to PY74-M2 was catalyzed only by CYP 1A2 and CYP 1A1 (no activity from CYP 1B1, 2B6, 2C9, 2D6, 2E1, or 3A4). These results demonstrate that the tattoo pigment PY74 is metabolized in vitro by P450 to metabolites that should be available for phase II metabolism and excretion.     

Metabolism of <Emphasis Type="Italic">dl</Emphasis>-praeruptorin a in rat liver microsomes using HPLC-electrospray ionization tandem mass spectrometry

dl-Praeruptorin A (Pd-Ia) is the major active constituent of the traditional Chinese medicine Peucedanum praeruptorum Dunn. Recently it has been identified as a novel agent in the treatment and prevention of cardiovascular diseases. Accordingly, we investigated the metabolism of Pd-Ia in rat liver microsomes. The involvement of cytochrome P450 (CYP) and CYP isoforms were identified using a CYP-specific inhibitor (SKF-525A), CYP-selective inhibitors (α-naphthoflavone, metyrapone, fluvastatin, quinidine, disulfiram, ketoconazole and ticlopidine) and CYP-selective inducers (phenobarbital, dexamethasone and β-naphthoflavone). Residual concentrations of the substrate and metabolites were determined by HPLC, and further identified by their mass spectra and chromatographic behavior. These experiments showed that CYP450 is involved in Pd-Ia metabolism, and that the major CYP isoform responsible is CYP3A1/2, which acts in a concentration-dependent manner. Four Pd-Ia metabolites (M1, M2, M3, and M4) were detected after incubation with rat liver microsomes. Hydroxylation was the primary metabolic pathway of Pd-Ia, and possible chemical structures of the metabolites were identified. Further research is now needed to link the metabolism of Pd-Ia to its drug-drug interactions.     

人肝CYP3A参与了山冈橐吾碱的代谢及其肝毒性代谢物的形成(英文)

目的　在体外研究山冈橐吾碱在人肝微粒体内的代谢及参与其代谢的主要的CYP4 5 0酶 ,探讨其代谢致毒机理。方法　采用人肝微粒体研究山冈橐吾碱的主要代谢方式和代谢物。在体外运用CYP4 5 0酶的选择性抑制剂和cDNA表达的人肝CYP4 5 0酶 ,探讨其对山冈橐吾碱的代谢及肝毒性的吡咯代谢物形成的影响及参与山冈橐吾碱代谢的主要的CYP4 5 0酶。结果　山冈橐吾碱在人肝微粒体内的主要代谢物为肝毒性的吡咯代谢物 :去氢倒千里光裂碱 ,7 谷胱甘肽基 去氢倒千里光裂碱 ,7,9 二谷胱甘肽基去氢倒千里光裂碱和山冈囊吾酸。CYP4 5 0特异性抑制剂α 萘黄酮 (抑制CYP1A2 )、黄胺苯吡唑 (抑制CYP2C)、奎尼丁 (抑制CYP2D6 )和二乙基二硫代氨基甲酸钠 (抑制CYP2E1)对山冈橐吾碱的代谢无明显的影响。但CYP3A的特异性抑制剂酮康唑和三乙酰竹桃霉素可以显著地抑制山冈橐吾碱的代谢及其吡咯代谢物和结合型吡咯物的形成。此外 ,在cDNA表达的人肝CYP3A4的温孵液中 ,山冈橐吾碱被代谢成相应的吡咯代谢物 ,而山冈橐吾碱在cDNA表达的人肝CYP1A2、CYP2C9、CYP2D6和CYP2E1温孵液中无代谢。结论　山冈橐吾碱在人肝微粒体内的主要代谢方式是形成肝毒性吡咯代谢物 ,CYP3A作为主要的CYP4 5 0酶参与了山冈橐吾碱的代谢及其肝毒性吡咯代谢?     

Roles of human CYP2A6 and rat CYP2B1 in the oxidation of (+)-fenchol by liver microsomes

The metabolism of (+)-fenchol was investigated in vitro using liver microsomes of rats and humans and recombinant cytochrome P450 (P450 or CYP) enzymes in insect cells in which human/rat P450 and NADPH-P450 reductase cDNAs had been introduced. The biotransformation of (+)-fenchol was investigated by gas chromatography-mass spectrometry (GC-MS). (+)-Fenchol was oxidized to fenchone by human liver microsomal P450 enzymes. The formation of metabolites was determined by the relative abundance of mass fragments and retention times on GC. Several lines of evidence suggested that CYP2A6 is a major enzyme involved in the oxidation of (+)-fenchol by human liver microsomes. (+)-Fenchol oxidation activities by liver microsomes were very significantly inhibited by (+)-menthofuran, a CYP2A6 inhibitor, and anti-CYP2A6. There was a good correlation between CYP2A6 contents and (+)-fenchol oxidation activities in liver microsomes of ten human samples. Kinetic analysis showed that the Vmax/Km values for (+)-fenchol catalysed by liver microsomes of human sample HG03 were 7.25 nM-1 min-1. Human recombinant CYP2A6-catalyzed (+)-fenchol oxidation with a Vmax value of 6.96 nmol min-1 nmol-1 P450 and apparent Km value of 0.09 mM. In contrast, rat CYP2A1 did not catalyse (+)-fenchol oxidation. In the rat (+)-fenchol was oxidized to fenchone, 6-exo-hydroxyfenchol and 10-hydroxyfenchol by liver microsomes of phenobarbital-treated rats. Recombinant rat CYP2B1 catalysed (+)-fenchol oxidation. Kinetic analysis showed that the Km values for the formation of fenchone, 6-exo- hydroxyfenchol and 10-hydroxyfenchol in rats treated with phenobarbital were 0.06, 0.03 and 0.03 mM, and Vmax values were 2.94, 6.1 and 13.8 nmol min-1 nmol-1 P450, respectively. Taken collectively, the results suggest that human CYP2A6 and rat CYP2B1 are the major enzymes involved in the metabolism of (+)-fenchol by liver microsomes and that there are species-related differences in the human and rat CYP2A enzymes.     

Characterization of triptolide hydroxylation by cytochrome P450 in human and rat liver microsomes

Triptolide, the primary active component of a traditional Chinese medicine Tripterygium wilfordii Hook F, has a wide range of pharmacological activities. In the present study, the metabolism of triptolide by cytochrome P450s was investigated in human and rat liver microsomes. Triptolide was converted to four metabolites (M-1, M-2, M-3, and M-4) in rat liver microsomes and three (M-2, M-3, and M-4) in human liver microsomes. All the products were identified as mono-hydroxylated triptolides by liquid chromatography-mass spectrometry (LC-MS). The studies with chemical selective inhibitors, complementary DNA-expressed human cytochrome P450s, correlation analysis, and enzyme kinetics were also conducted. The results demonstrate that CYP3A4 and CYP2C19 could be involved in the metabolism of triptolide in human liver, and that CYP3A4 was the primary isoform responsible for its hydroxylation.     

Characterization of triptolide hydroxylation by cytochrome P450 in human and rat liver microsomes

Triptolide, the primary active component of a traditional Chinese medicine Tripterygium wilfordii Hook F, has a wide range of pharmacological activities. In the present study, the metabolism of triptolide by cytochrome P450s was investigated in human and rat liver microsomes. Triptolide was converted to four metabolites (M-1, M-2, M-3, and M-4) in rat liver microsomes and three (M-2, M-3, and M-4) in human liver microsomes. All the products were identified as mono-hydroxylated triptolides by liquid chromatography-mass spectrometry (LC-MS). The studies with chemical selective inhibitors, complementary DNA-expressed human cytochrome P450s, correlation analysis, and enzyme kinetics were also conducted. The results demonstrate that CYP3A4 and CYP2C19 could be involved in the metabolism of triptolide in human liver, and that CYP3A4 was the primary isoform responsible for its hydroxylation.