Chromatin structure and chromosome aberrations: modeling of damage induced by isotropic and localized irradiation

Abstract

Various models for the nuclear architecture in interphase cell nuclei have been presented, proposing a territorial or a non-territorial organization of chromosomes. To better understand the correlation between nuclear architecture and the formation of chromosomal aberrations, we applied computer simulations to model the extent of radiation induced chromosome damage under certain geometrical constraints. For this purpose, chromosomes were described by different models, which approximate the chromatin fiber by a polymer chain, folded in different ways. Corresponding to the different condensation levels, a territorial or a non-territorial organization of chromosomes was obtained. To determine the relative frequencies of radiation induced damage, the effects of isotropic ionizing radiation and of a focused laser UV-beam were studied. For isotropic ionizing radiation, the calculated translocation frequencies showed no differences between territorial and non-territorial models except for one special case. For localized irradiation, the results of both organizations were clearly different, with respect to the total number of damaged chromosomes per cell. The predictions agreed well with the experimental data available.