Modification of the Radiation Sensitivity of Human Tumour Cells by a Bis-benzimidazole Derivative

Abstract

A comparison was made of the ability of either X-radiation or a DNA-specific ligand (the vital bis-benzimidazole dye; Hoechst 33342) to induce: cell killing, inhibition of de novo DNA synthesis, DNA strand breakage and the delay of cell division in human colon adenocarcinoma cells in vitro. Unlike radiation-induced cell killing, ligand-induced cytotoxicity appeared to be positively correlated with the extent of inhibition of de novo DNA synthesis—a feature consistent with the persistent binding of ligand molecules to nuclear DNA. Ligand-induced DNA strand-breaks disappeared slowly although ligand-treated cells retained apparently normal capacities to repair discrete radiogenic DNA strand-breaks. Pre-treatment of cells with Hoechst 33342 resulted in a dose-modifying enhancement of radiation resistance not associated with altered dosimetry for strand-break induction. However, radioresistance was accompanied by the protracted retention of cells in the G₂ phase of the cell cycle. We suggest that the results provide direct evidence that the retention of cells in G₂ phase is a sparing phenomenon and is triggered by the responses of chromatin domains to the presence of DNA damage. Our results have implications for the use of DNA-interactive agents in combined modalities for tumour therapy, and indicate a possible basis for the sparing of some tumour cells in dividing populations.