Pan S S, Iracki T, Bachur N R
Mol Pharmacol. 1986 Jun;29(6):622-8.
After anaerobic reductive activation by either NADPH cytochrome P-450 reductase (EC 1.6.2.4) or xanthine oxidase (EC 1.2.3.2), mitomycin C readily alkylated DNA. When the mitomycin C-alkylated DNA is digested by DNase, snake venom phosphodiasterase, and alkaline phosphatase, only partial release of the monofunctionally linked mitomycin C nucleotide adduct occurs. Cross-linked adducts are not released into dinucleotides but resist nuclease digestion and remain in oligonucleotides and insoluble precipitates. Kinetic analyses show that the nuclease-resistant fraction which is indicative of DNA cross-linking by mitomycin C takes place quite readily. This nuclease-resistant fraction is particularly significant when the amount of total bound mitomycin C is less than 15 mumol/mmol of DNA. The cross-linked mitomycin C product accounts for more than half of the total alkylation under all pH conditions tested. Our data suggest that particular DNA sites are available for DNA cross-linking by mitomycin C, and these sites are probably the preferred and immediate alkylating targets. Furthermore, DNA cross-links by mitomycin C are not the secondary product of monofunctional adducts. Activity of both flavoenzymes is pH dependent, hence, mitomycin C activation and the rate of DNA alkylation are pH dependent. At elevated mitomycin C alkylation of DNA, the highest amount of cross-linking occurs at neutral pH. High pressure liquid chromatographic separation of the nuclease-digested DNA detected one major and two less prominent mitomycin C adducts. These were verified to be mononucleotide mitosene types by UV spectra showing maximum absorbance at 312 and 250 nm. The major adduct was purified and identified as O6-(2'-deoxyguanosyl)-2,7-diaminomitosene by NMR, indicating that the O6 position of guanine is a preferred site in DNA for at least monofunctional linkage formation.
经NADPH细胞色素P - 450还原酶(EC 1.6.2.4)或黄嘌呤氧化酶(EC 1.2.3.2)进行厌氧还原活化后,丝裂霉素C很容易使DNA烷基化。当用DNase、蛇毒磷酸二酯酶和碱性磷酸酶消化丝裂霉素C烷基化的DNA时,单功能连接的丝裂霉素C核苷酸加合物仅部分释放。交联加合物不会释放为二核苷酸,而是抵抗核酸酶消化,保留在寡核苷酸和不溶性沉淀物中。动力学分析表明,指示丝裂霉素C引起DNA交联的核酸酶抗性部分很容易形成。当总结合的丝裂霉素C量小于15 μmol/mmol DNA时,这种核酸酶抗性部分尤为显著。在所有测试的pH条件下,交联的丝裂霉素C产物占总烷基化的一半以上。我们的数据表明,特定的DNA位点可用于丝裂霉素C引起的DNA交联,这些位点可能是优先且直接的烷基化靶点。此外,丝裂霉素C引起的DNA交联不是单功能加合物的次级产物。两种黄素酶的活性均依赖于pH,因此,丝裂霉素C的活化和DNA烷基化速率也依赖于pH。在DNA的丝裂霉素C烷基化升高时,最高量的交联发生在中性pH。对核酸酶消化的DNA进行高压液相色谱分离,检测到一种主要的和两种不太明显的丝裂霉素C加合物。通过紫外光谱在312和250 nm处显示最大吸光度,证实这些是单核苷酸丝裂霉素类型。主要加合物经纯化并通过核磁共振鉴定为O6 -(2'-脱氧鸟苷基)- 2,7 -二氨基丝裂霉素,表明鸟嘌呤的O6位置是DNA中至少用于单功能连接形成的优先位点。
