In order to determine differences in repair after treatment with DNA damaging agents, normal and cancer cells were selected for analysis of single strand breaks and DNA crosslinks using the Comet assay. Normal human lymphocytes, human colorectal adenocarcinoma SW620 cells, lung carcinoma A549, and H460 cell lines were exposed to an ethylating agent (ethylmethane sulfonate [EMS]), and a cross-linking agent (mitomycin C [MMC]). Differences in repair profiles of DNA damage demonstrated using the comet assay were observed in human lymphocytes and tumour cell lines with both mutagens. Results were also indicative that MMC repair is concentration-dependent. It was also apparent that normal cells repair DNA damage more readily than tumour cells. Repair also varied between different cell lines. To investigate the mechanistic differences of these two chemicals, flow cytometry studies were undertaken in tumour cells, namely cell cycle analysis and frequency of micronuclei induction (FMN). A G2M phase block was clearly evident following treatment with EMS at all concentrations tested. With MMC, an initial arrest of cells in G2M was accompanied by a build-up in S-phase over longer exposure periods. Also, at the highest mutagen doses there were different patterns of micronuclei induction. Thus, using the mutagens with different mechanisms of action highlighted the differences in repair patterns between normal and tumour cells.
Telomerase-targeted strategies have aroused recent interest in anti-cancer chemotherapy, because DNA-binding drugs can interact with high-order tetraplex rather than double-stranded (duplex) DNA targets in tumour cells. However, the protracted cell-drug exposure times necessary for clinical application require that telomerase inhibitory efficacy must be accompanied by both low inherent cytotoxicity and the absence of mutagenicity/genotoxicity. For the first time, the genotoxicity of a number of structurally diverse DNA-interactive telomerase inhibitors is examined in the Ames test using six Salmonella typhimurium bacterial strains (TA1535, TA1537, TA1538, TA98, TA100, and TA102). DNA damage induced by each agent was also assessed using the Comet assay with human lymphocytes. The two assay procedures revealed markedly different genotoxicity profiles that are likely to reflect differences in metabolism and/or DNA repair between bacterial and mammalian cells. The mutational spectrum for a biologically active fluorenone derivative, shown to be mutagenic in the TA100 strain, was characterised using a novel and rapid assay method based upon PCR amplification of a fragment of the hisG46 allele, followed by RFLP analysis. Preliminary analysis indicates that the majority (84%) of mutations induced by this compound are C --> A transversions at position 2 of the missense proline codon of the hisG46 allele. However, despite its genotoxic bacterial profile, this fluorenone agent gave a negative response in the Comet assay, and demonstrates how unwanted systemic effects (e.g., cytotoxicity and genotoxicity) can be prevented or ameliorated through suitable molecular fine-tuning of a candidate drug in targeted human tumour cells.
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