Slamenová Darina, Horváthová Eva, Bartková Miriam
Cancer Research Institute, Slovak Academy of Sciences, Laboratory of Mutagenesis and Carcinogenesis, Vlárska 7, 83391 Bratislava, Slovak Republic.
Mutat Res. 2006 Jan 29;593(1-2):97-107. doi: 10.1016/j.mrfmmm.2005.06.029. Epub 2005 Sep 13.
This study tried to clarify the question if nuclear genotoxicity played a role in 3'-azido-3'-deoxythymidine (AZT) toxicity. We investigated cytotoxic and DNA-damaging effects of AZT on human hepatoma HepG2 and human colonic CaCo-2 cells as well as on human diploid lung fibroblasts HEL. The amount of induced DNA damage was measured by standard alkaline single cell gel electrophoresis (SCGE). The nature of induced DNA lesions was evaluated (1) by modified SCGE, which includes treatment of lysed cells with DNA repair enzymes Endo III and Fpg and enables to recognize oxidized bases of DNA, and (2) by SCGE processed in parallel at pH 13.0 (standard technique) and pH 12.1, which enables to recognize alkali labile DNA lesions and direct DNA strand breaks. Cytotoxicity of AZT was evaluated by the trypan blue exclusion technique. Our findings showed that 3-h treatment of cells with AZT decreased the viability of all cell lines studied. SCGE performed in the presence of DNA repair enzymes proved that AZT induced oxidative lesions to DNA in all cell types. In hepatoma HepG2 cells and embryonic lung fibroblasts HEL the majority of AZT-induced DNA strand breaks were pH-independent, i.e. they were identified at both pH values (12.1 and 13.0). These DNA lesions represented direct DNA breaks. In colonic Caco-2 cells DNA lesions were converted to DNA strand breaks particularly under strong alkaline conditions (pH>13.0), which is characteristic for alkali-labile sites of DNA. DNA strand break rejoining was investigated by the standard comet assay technique during 48 h of post-AZT-treatment in HepG2 and Caco-2 cells. The kinetics of DNA rejoining, considered an indicator of DNA repair, revealed that AZT-induced DNA breaks were repaired in both cell types slowly, though HepG2 cells seemed to be more repair proficient with respect to AZT-induced DNA lesions.
本研究试图阐明核基因毒性是否在3'-叠氮-3'-脱氧胸苷(AZT)毒性中起作用。我们研究了AZT对人肝癌HepG2细胞、人结肠CaCo-2细胞以及人二倍体肺成纤维细胞HEL的细胞毒性和DNA损伤作用。通过标准碱性单细胞凝胶电泳(SCGE)测量诱导的DNA损伤量。通过以下方法评估诱导的DNA损伤的性质:(1)改良的SCGE,包括用DNA修复酶Endo III和Fpg处理裂解细胞,从而能够识别DNA的氧化碱基;(2)在pH 13.0(标准技术)和pH 12.1下并行处理的SCGE,其能够识别碱不稳定的DNA损伤和直接的DNA链断裂。通过台盼蓝排斥技术评估AZT的细胞毒性。我们的研究结果表明,用AZT处理细胞3小时会降低所有研究细胞系的活力。在DNA修复酶存在下进行的SCGE证明,AZT在所有细胞类型中均诱导DNA发生氧化损伤。在肝癌HepG2细胞和胚胎肺成纤维细胞HEL中,大多数AZT诱导的DNA链断裂与pH无关,即在两个pH值(12.1和13.0)下均可识别。这些DNA损伤代表直接的DNA断裂。在结肠CaCo-2细胞中,DNA损伤尤其在强碱性条件(pH>13.0)下转化为DNA链断裂,这是DNA碱不稳定位点的特征。在HepG2和CaCo-2细胞中,在AZT处理后48小时内,通过标准彗星试验技术研究了DNA链断裂的重新连接。DNA重新连接的动力学被视为DNA修复的指标,结果显示,两种细胞类型中AZT诱导的DNA断裂修复缓慢,不过就AZT诱导的DNA损伤而言,HepG2细胞似乎更善于修复。
