Cancer Risk Factor Branch, Cancer Prevention and Research Institute, Florence, Italy.
Environ Mol Mutagen. 2013 Jul;54(6):375-83. doi: 10.1002/em.21788. Epub 2013 Jun 25.
Interindividual variation in DNA adduct levels in individuals exposed to similar amounts of environmental carcinogens may be due to genetic variability. We analysed the influence of genes involved in determining/modifying DNA damage, including microsomal epoxide hydrolase1 (EPHX1) His139Arg, N-acetyl-transferase, NAD(P)H:quinone oxidoreductase1 (NQO1) Pro187Ser, manganese superoxide dismutase2 (MnSOD2) Val16Ala, and apurinic/apyrimidinic endonuclease1 (APE1) Asp148Glu polymorphisms in blood of 120 smokers. Subsequently, we examined the effects of the combinations of the variant alleles of EPHX, NQO1 and MnSOD2 together with the wild type allele of APE1 on DNA damage by calculating the "sum of at-risk alleles." We reviewed the studies examining the relationships of DNA adducts with at-risk alleles in environmentally exposed subjects. Our findings showed that smokers carrying the EPHX1-139Arg and the NQO1-187Ser variants were significantly more likely to have higher adduct levels. Null associations were found with the other variants. Nevertheless, DNA adduct levels in smokers with ≥5 at-risk alleles were significantly different from those with fewer than two alleles. A similar picture emerged from studies of DNA adducts and at-risk alleles in environmentally exposed and smoking subjects. Certain at-risk allele combinations may confer a greater likelihood of increased levels of adducts after environmental insults. The increase in DNA adduct levels in susceptible subjects exposed to environmental carcinogens may reflect changes in the mechanisms that protect cells from the accumulation of genetic damage. Alterations of the physiological processes designed to maintain homeostasis may reduce the individual "genotoxic tolerance" to environmental challenges and result in phenotypes characterized by high levels of DNA adducts.
个体暴露于相似环境致癌物的情况下,DNA 加合物水平的个体差异可能归因于遗传变异性。我们分析了参与决定/修饰 DNA 损伤的基因的影响,包括细胞色素 P450 环氧化物水解酶 1(EPHX1)His139Arg、N-乙酰转移酶、NAD(P)H:醌氧化还原酶 1(NQO1)Pro187Ser、锰超氧化物歧化酶 2(MnSOD2)Val16Ala 和脱嘌呤/脱嘧啶内切核酸酶 1(APE1)Asp148Glu 多态性在 120 名吸烟者的血液中。随后,我们通过计算“风险等位基因总和”来研究 EPHX、NQO1 和 MnSOD2 的变异等位基因与野生型 APE1 等位基因的组合对 DNA 损伤的影响。我们回顾了研究环境暴露个体中 DNA 加合物与风险等位基因关系的研究。我们的研究结果表明,携带 EPHX1-139Arg 和 NQO1-187Ser 变异的吸烟者更有可能具有更高的加合物水平。其他变异与 DNA 加合物水平之间没有关联。然而,携带≥5 个风险等位基因的吸烟者的 DNA 加合物水平与携带少于两个等位基因的吸烟者明显不同。在环境暴露和吸烟个体的 DNA 加合物和风险等位基因研究中也出现了类似的情况。某些风险等位基因组合可能会增加环境刺激后加合物水平升高的可能性。易感性个体暴露于环境致癌物后 DNA 加合物水平的增加可能反映了保护细胞免受遗传损伤积累的机制的变化。旨在维持体内平衡的生理过程的改变可能会降低个体对环境挑战的“遗传毒性耐受”,并导致以高水平 DNA 加合物为特征的表型。
