van Bladeren P J, Vyas K P, Sayer J M, Ryan D E, Thomas P E, Levin W, Jerina D M
J Biol Chem. 1984 Jul 25;259(14):8966-73.
Absolute configurations of the arene 1,2-oxides formed from napththalene and anthracene by cytochrome P-450c, the predominant isozyme of cytochrome P-450 found in the livers of rats treated with 3-methylcholanthrene, were determined via two different approaches. The first consisted of trapping the arene oxides with N-acetyl-L-cysteine to form S-conjugates, methylation of the conjugates with diazomethane, and separation of the resulting diastereomeric esters by reversed phase high performance liquid chromatography. Analysis by this procedure of the arene oxides formed from radioactive naphthalene and anthracene by a highly purified and reconstituted monooxygenase system containing cytochrome P-450c indicated that 73 and greater than or equal to 95%, respectively, of the metabolically formed arene oxides consisted of the (+)-(1R,2S)-enantiomer. In the second approach, each hydrocarbon was incubated with a reconstituted system containing both cytochrome P-450c and epoxide hydrolase. Under these conditions, the predominant metabolites are trans-1,2-dihydrodiols formed by epoxide hydrolase catalyzed trans-addition of water to the arene oxide intermediates. In both cases, the (-)-(1R,2R)-dihydrodiols predominated; 92% for naphthalene and 99% for anthracene. Enzyme-catalyzed addition of water to (+)- and (-)-anthracene 1,2-oxide and (+)-napthalene 1,2-oxide occurred exclusively (greater than 99%) at the allylic 2-position. The (-)-(1S,2R)-naphthalene 1,2-oxide, however, is converted to a 40:60 mixture of the (-)-(1R,2R)- and (+)-(1S,2S)-dihydrodiols by benzylic and allylic attack, respectively, resulting in increased enantiomeric purity of the dihydrodiol relative to the oxide. Thus, qualitatively and quantitatively both approaches indicate that the (+)-arene (1R,2S)-oxides predominate. The results are discussed in terms of the steric constraints of a proposed model for the catalytic binding site of cytochrome P-450c.
由萘和蒽经细胞色素P - 450c形成的芳烃1,2 - 氧化物的绝对构型已通过两种不同方法确定。细胞色素P - 450c是在用3 - 甲基胆蒽处理的大鼠肝脏中发现的细胞色素P - 450的主要同工酶。第一种方法包括用N - 乙酰 - L - 半胱氨酸捕获芳烃氧化物以形成S - 结合物,用重氮甲烷对结合物进行甲基化,以及通过反相高效液相色谱法分离所得的非对映体酯。通过该程序对由放射性萘和蒽经含有细胞色素P - 450c的高度纯化和重组的单加氧酶系统形成的芳烃氧化物进行分析表明,代谢形成的芳烃氧化物分别有73%和大于或等于95%由( + )-(1R,2S)-对映体组成。在第二种方法中,将每种烃与含有细胞色素P - 450c和环氧水解酶的重组系统一起孵育。在这些条件下,主要代谢产物是由环氧水解酶催化水向芳烃氧化物中间体的反式加成形成的反式 - 1,2 - 二氢二醇。在这两种情况下,( - )-(1R,2R)-二氢二醇占主导;萘为92%,蒽为99%。酶催化水向( + )-和( - )-蒽1,2 - 氧化物以及( + )-萘1,2 - 氧化物的加成仅(大于99%)发生在烯丙基2 - 位。然而,( - )-(1S,2R)-萘1,2 - 氧化物分别通过苄基和烯丙基攻击转化为( - )-(1R,2R)-和( + )-(1S,2S)-二氢二醇的40:60混合物,导致二氢二醇相对于氧化物的对映体纯度增加。因此,定性和定量方面两种方法均表明( + )-芳烃(1R,2S)-氧化物占主导。根据所提出的细胞色素P - 450c催化结合位点模型的空间限制对结果进行了讨论。
