Short fluorodeoxyuridine exposure of different human glioblastoma lines induces high-level accumulation of S-phase cells that avidly incorporate super(125)I-iododeoxyuridine

Purpose Radio-iododeoxyuridine (IdUrd) is a potential Auger radiation therapy agent incorporated into DNA during the synthesis phase. In this study we sought to optimise S-phase targeting by modulating cellular cycling and radio-ldUrd DNA incorporation using short non-toxic fluorodeoxyuridine (FdUrd) incubations. Methods Three human glioblastoma cell lines with different p53 expression were pre-treated with various FdUrd conditions. After different intervals, super(125)I-ldUrd DNA incorporation was measured. Fluorescence-activated cell sorter cell cycle analysis was performed after identical intervals post FdUrd pre-treatment Results The highest increase in super(125)I-ldUrd DNA incorporation was induced by 1-h incubation with 1 mu M FdUrd. Increase in radio-ldUrd DNA incorporation was greatest 16-24 h after FdUrd, reaching factors of greater than or equal to 7.5 over baseline incorporation in the three cell lines. Furthermore, cell synchronisation in S phase was observed with a peak of greater than or equal to 69.5% in the three cell lines at 16 and 24 h post FdUrd, corresponding to an increase of 2.5-4.1 over baseline. Conclusion FdUrd-incluced thymidine synthesis inhibition led to S-phase accumulation that was maximal after an interval of 16-24 h and time-correlated with the highest radio-ldUrd DNA incorporation. These observations might allow the rational design of an Auger radiation therapy targeting a maximal number of S-phase cells in single treatment cycles.