Hecht S S, Trushin N, Reid-Quinn C A, Burak E S, Jones A B, Southers J L, Gombar C T, Carmella S G, Anderson L M, Rice J M
Division of Chemical Carcinogenesis, American Health Foundation, Valhalla, NY 10595.
Carcinogenesis. 1993 Feb;14(2):229-36. doi: 10.1093/carcin/14.2.229.
The metabolism of the tobacco-specific nitrosamine 4-(methylnitrosamino)-1-(3-pyridyl)-1-butanone (NNK) was examined in the patas monkey, in order to provide further information about NNK metabolic pathways in primates. Female patas monkeys were given i.v. injections of [5-3H]NNK, and metabolites in serum and urine were analyzed by HPLC. Metabolism by alpha-hydroxylation of NNK was rapid and extensive, and the products of this pathway, 4-hydroxy-4-(3-pyridyl)butyric acid and 4-oxo-4-(3-pyridyl) butyric acid, accounted for a relatively large proportion of serum and urinary metabolites at all time points. This is significant because the formation of these products is associated with modification of DNA by NNK. The other major metabolic pathway was carbonyl reduction to 4-(methylnitrosamino)-1-(3-pyridyl)-1-butanol (NNAL), which detected both unconjugated and diastereomeric O-glucuronides. One of these glucuronides had been previously identified in rat urine, but the other diastereomer, which was the more prevalent of the two in serum and urine, had not been observed in studies of NNK metabolism in rodents. It was characterized by its spectral properties, by enzymatic hydrolysis to NNAL, and by derivatization of the released NNAL enantiomer with (R)-(+)-alpha-methylbenzylisocyanate. The two NNAL glucuronides accounted for 15-20% of the urinary metabolites in monkeys given 0.1 micrograms/kg NNK, which is similar to a smoker's dose, suggesting their use as dosimeters of NNK exposure in humans. Pharmacokinetic parameters were consistent with those observed in previous studies of nitrosamines, and varied predictably with body weight of five species. The results of this study have provided new insights relevant to assessing human metabolism of NNK.
为了获取更多关于灵长类动物中4-(甲基亚硝胺基)-1-(3-吡啶基)-1-丁酮(NNK)代谢途径的信息,研究人员对东非狒狒体内NNK的代谢情况进行了检测。给雌性东非狒狒静脉注射[5-³H]NNK,然后通过高效液相色谱法分析血清和尿液中的代谢产物。NNK的α-羟基化代谢迅速且广泛,该途径产生的产物4-羟基-4-(3-吡啶基)丁酸和4-氧代-4-(3-吡啶基)丁酸在所有时间点的血清和尿液代谢产物中都占相当大的比例。这一点很重要,因为这些产物的形成与NNK对DNA的修饰有关。另一条主要代谢途径是羰基还原生成4-(甲基亚硝胺基)-1-(3-吡啶基)-1-丁醇(NNAL),同时检测到了未结合的和非对映体的O-葡萄糖醛酸苷。其中一种葡萄糖醛酸苷先前已在大鼠尿液中鉴定出来,但另一种非对映体在血清和尿液中更为普遍,在啮齿动物的NNK代谢研究中尚未观察到。通过光谱特性、酶水解为NNAL以及用(R)-(+)-α-甲基苄基异氰酸酯对释放的NNAL对映体进行衍生化对其进行了表征。在给予0.1微克/千克NNK(类似于吸烟者的剂量)的猴子中,两种NNAL葡萄糖醛酸苷占尿液代谢产物的15%-20%,这表明它们可作为人类NNK暴露的剂量计。药代动力学参数与先前对亚硝胺的研究结果一致,并且在五个物种中随体重呈可预测的变化。这项研究的结果为评估人类NNK代谢提供了新的见解。
