Sevastyanova O, Binkova B, Topinka J, Sram R J, Kalina I, Popov T, Novakova Z, Farmer P B
Laboratory of Genetic Ecotoxicology, Institute of Experimental Medicine, Academy of Sciences of the Czech Republic, Vídenská 1083, 142 20 Prague 4, Czech Republic.
Mutat Res. 2007 Jul 1;620(1-2):123-34. doi: 10.1016/j.mrfmmm.2007.03.002. Epub 2007 Mar 12.
Principal aims of this study were at first, to find a relevant human derived cell line to investigate the genotoxic potential of PAH-containing complex mixtures and second, to use this cell system for the analysis of DNA adduct forming activity of organic compounds bound onto PM10 particles. Particles were collected by high volume air samplers during summer and winter periods in three European cities (Prague, Kosice, and Sofia), representing different levels of air pollution. The genotoxic potential of extractable organic matter (EOM) was compared with the genotoxic potential of individual carcinogenic polycyclic aromatic hydrocarbons (c-PAHs) as well as their artificial mixtures. Metabolically competent human hepatoma HepG2 cells, confluent cultures of human diploid lung fibroblasts (HEL), and the human monocytic leukemia cell line THP-1 were used as models. DNA adducts were analyzed by (32)P-postlabeling. The total DNA adduct levels induced in HepG2 cells after exposure to EOMs were higher than in HEL cells treated under the same conditions (15-190 versus 2-15adducts/10(8) nucleotides, in HepG2 and HEL cells, respectively). THP-1 cells exhibited the lowest DNA adduct forming activity induced by EOMs (1.5-3.7adducts/10(8) nucleotides). A direct correlation between total DNA adduct levels and c-PAH content in EOM was found for all EOMs in HepG2 cells incubated with 50microg EOM/ml (R=0.88; p=0.0192). This correlation was even slightly stronger when B[a]P content in EOMs and B[a]P-like adduct spots were analyzed (R=0.90; p=0.016). As THP-1 cells possess a limited metabolic capacity for most c-PAHs to form DNA reactive intermediates and are also more susceptible to toxic effects of PAHs and various EOM components, this cell line seemed to be an inappropriate system for genotoxicity studies of PAH-containing complex mixtures. The seasonal variability of genotoxic potential of extracts was stronger than variability among the three localities studied. In HepG2 cells, the highest DNA adduct levels were induced by EOM collected in Prague in the winter period, followed by Sofia and Kosice. However, in the summer sampling period, the order was quite opposite: Kosice>Sofia>Prague. When the EOM content per m(3) of air was taken into consideration in order to compare real exposures of humans to genotoxic compounds in all three localities, extracts from respirable dust particles collected in Sofia exhibited the highest genotoxicity regardless of the sampling period. The results indicate that most of DNA adducts detected in cells incubated with EOMs have their origin in low concentrations of c-PAHs representing 0.03-0.17% of EOM total mass. Finally, our results suggest that HepG2 cells have a metabolic capacity for PAHs similar to human hepatocytes and represent therefore the best in vitro model for investigating the genotoxic potential of complex mixtures containing PAHs among the three cell lines tested in this study.
本研究的主要目的,首先是找到一种合适的人源细胞系,以研究含多环芳烃(PAH)的复杂混合物的遗传毒性潜力;其次是利用该细胞系统分析结合在PM10颗粒上的有机化合物的DNA加合物形成活性。在欧洲三个代表不同空气污染水平的城市(布拉格、科希策和索非亚),于夏季和冬季通过大容量空气采样器采集颗粒。将可提取有机物(EOM)的遗传毒性潜力与单个致癌多环芳烃(c-PAHs)及其人工混合物的遗传毒性潜力进行比较。采用具有代谢活性的人肝癌HepG2细胞、人二倍体肺成纤维细胞(HEL)的汇合培养物以及人单核细胞白血病细胞系THP-1作为模型。通过³²P后标记法分析DNA加合物。暴露于EOMs后,HepG2细胞中诱导的总DNA加合物水平高于相同条件下处理的HEL细胞(分别为15 - 190个加合物/10⁸个核苷酸和HEL细胞中的2 - 15个加合物/10⁸个核苷酸)。THP-1细胞表现出由EOMs诱导的最低DNA加合物形成活性(1.5 - 3.7个加合物/10⁸个核苷酸)。对于用50μg EOM/ml培养的HepG2细胞中的所有EOMs,发现总DNA加合物水平与EOM中的c-PAH含量直接相关(R = 0.88;p = 0.0192)。当分析EOMs中的苯并[a]芘(B[a]P)含量和B[a]P样加合物斑点时,这种相关性甚至更强(R = 0.90;p = 0.016)。由于THP-1细胞对大多数c-PAHs形成DNA反应性中间体的代谢能力有限,并且对PAHs和各种EOM成分的毒性作用也更敏感,因此该细胞系似乎不是用于含PAH复杂混合物遗传毒性研究的合适系统。提取物遗传毒性潜力的季节变异性强于所研究的三个地点之间的变异性。在HepG2细胞中,冬季在布拉格采集的EOM诱导的DNA加合物水平最高,其次是索非亚和科希策。然而,在夏季采样期,顺序正好相反:科希策>索非亚>布拉格。为了比较所有三个地点人类对遗传毒性化合物的实际暴露情况,考虑每立方米空气中的EOM含量时,无论采样期如何,在索非亚采集的可吸入粉尘颗粒提取物表现出最高的遗传毒性。结果表明,在用EOMs培养的细胞中检测到的大多数DNA加合物源自低浓度的c-PAHs,其占EOM总质量的0.03 - 0.17%。最后,我们的结果表明,HepG2细胞对PAHs的代谢能力与人肝细胞相似,因此在本研究测试的三个细胞系中,它是用于研究含PAHs复杂混合物遗传毒性潜力的最佳体外模型。
