Zbaida S
Department of Drug Metabolism and Pharmacokinetics, Schering-Plough Research Institute, Kenilworth, New Jersey 07033-0539, USA.
Drug Metab Rev. 1995;27(3):497-516. doi: 10.3109/03602539508998333.
The mechanism of microsomal azoreductase is regulated by the overall Hammett sigma substituent values on each ring. A substrate dye must exhibit an overall Hammett sigma substituent value either equal or more negative than -0.37 on either ring. Dyes with Hammett sigma substituent constants less negative than -0.37 will not be reduced by microsomal cytochrome P450. Microsomal reduction of azo dyes containing only electron-donating substituents on either ring is insensitive to both oxygen and carbon monoxide. The required Hammett sigma substituent value on the opposite benzene (prime) ring for I-substrates is therefore, sigma' P < or = 0. Reduction of azo dyes containing electron-withdrawing group on opposite (prime) is sensitive to both oxygen and carbon monoxide. The required Hammett sigma substituent value on the opposite benzene (prime) ring for S-substrates is, consequently, sigma' P > 0 (Table 3). Redox Potentials. Anaerobic cyclic voltammograms of azobenzene derivatives verify the following points: A nonsubstrate azo dye will not exhibit a positive potential. (Several nonsubstrate hydrazobenzenes exhibited positive potentials, but in a low range 0.41-0.48 V. Consequently, cyclic voltammetry can distinguish between nonsubstrate azobenzenes and their nonsubstrate half-reduced hydrazo analogs.) A substrate azo dye will exhibit a positive potential in the range +1.00 to +1.50 V. I-substrate: Both negative potentials are stable in air. S-substrate: The first negative potential will immediately quench upon exposure to air. I-substrates exhibit on average potentials which are approximately 0.6 V more negative than those for S-substrates. A comparison between the oxidative and the reductive pathway of microsomal cytochrome P450 indicates a similarity in the first two steps in the reaction cycle, for example, substrate binding and uptake of the first electron by the cytochrome [76, 109, 110]. Upon reduction of the iron, ferrous cytochrome P450 may bind oxygen or carbon monoxide in a competitive manner in the oxidative cycle or may directly transfer the electrons to the substrate in a stepwise fashion in the reductive cycle [76]. Estabrook et al. [111] suggested that carbon monoxide insensitivity can occur when the formation of ferrous cytochrome P450 substrate complex is rate limiting for the overall reaction. Structure-activity relationships of azo compounds depend on (1) the electron transport component and (2) the oxidation-reduction potential of the dye, which determines its ability to accept electrons from cytochrome P-450. Nesnow et al. examined a group of 36 aryl azo dyes for their ability to be reduced by rat liver microsomal azoreductase.(ABSTRACT TRUNCATED AT 400 WORDS)
微粒体偶氮还原酶的机制受每个环上总的哈米特σ取代基值调控。底物染料在任何一个环上的总的哈米特σ取代基值必须等于或比-0.37更负。哈米特σ取代基常数比-0.37负性小的染料不会被微粒体细胞色素P450还原。仅在一个环上含有供电子取代基的偶氮染料的微粒体还原对氧气和一氧化碳均不敏感。因此,I底物在相对的苯(主)环上所需的哈米特σ取代基值为σ' P≤0。在相对(主)环上含有吸电子基团的偶氮染料的还原对氧气和一氧化碳均敏感。因此,S底物在相对的苯(主)环上所需的哈米特σ取代基值为σ' P>0(表3)。氧化还原电位。偶氮苯衍生物的厌氧循环伏安图证实了以下几点:非底物偶氮染料不会呈现正电位。(几种非底物氢化偶氮苯呈现正电位,但在0.41 - 0.48 V的低范围内。因此,循环伏安法可以区分非底物偶氮苯及其非底物半还原氢化偶氮类似物。)底物偶氮染料将在+1.00至+1.50 V范围内呈现正电位。I底物:两个负电位在空气中均稳定。S底物:第一个负电位在暴露于空气时会立即淬灭。I底物的平均电位比S底物的电位大约负0.6 V。微粒体细胞色素P450的氧化和还原途径之间的比较表明,反应循环的前两步具有相似性,例如底物结合以及细胞色素对第一个电子的摄取[76, 109, 110]。铁还原后,亚铁细胞色素P450在氧化循环中可能以竞争方式结合氧气或一氧化碳,或者在还原循环中可能以逐步方式将电子直接转移到底物[76]。埃斯特布鲁克等人[111]提出,当亚铁细胞色素P450底物复合物的形成是整个反应的限速步骤时,可能会出现对一氧化碳不敏感的情况。偶氮化合物的构效关系取决于(1)电子传递成分和(2)染料的氧化还原电位,这决定了其从细胞色素P - 450接受电子的能力。内斯诺等人研究了一组36种芳基偶氮染料被大鼠肝脏微粒体偶氮还原酶还原的能力。(摘要截断于400字)
