Mechanism of chromosome exchange formation in human fibroblasts: insights from "chromosome painting".

We have used the techniques of premature chromosome condensation (PCC) and fluorescence in situ hybridization (FISH) with a library for human chromosome 4 to analyze the rate of rejoining of chromosome breaks and development of exchange aberrations in AG1522 human fibroblasts. AG1522 cells were irradiated in plateau phase with 10 Gy and fused with mitotic HeLa cells either immediately after irradiation or at intervals up to eight days later. The slides were then hybridized with the chromosome 4 library and unrejoined breaks and exchange events (visualized as bicolor chromosomes) scored in these cells. At the earliest time point after irradiation, the number of exchange events in the irradiated cells was low, but increased with kinetics similar to that of the joining of the breaks. Furthermore, when we analyzed those cells which had exchange events for their distribution, almost all of the cells initially contained one exchange event (1 bicolor chromosome). As time progressed, the number of cells containing exchanges with two exchange events per cell increased as the number with one exchange event per cell decreased. Extrapolation of the number of exchange events to zero time (with an estimate of 20 min for the fusion and condensation times) gave a value consistent with zero exchanges at zero time after irradiation. In a separate experiment, we also scored AG 1522 cells at the first metaphase after a dose of 6 Gy and were able to show that as many as 50% of the complete exchanges were non-reciprocal in nature, that is, the two broken ends of a single break in chromosome 4 joined to two different chromosomes. These data support the classical breakage-and-reunion model rather than the Revell Exchange Theory of exchange formation.