Abstract
The long-standing question in radiation and cancer biology is how principles of chromosome organization impact the formation of chromosomal aberrations (CAs). To address this issue, we developed a physical modeling approach and analyzed high-throughput genomic data from chromosome conformation capture (Hi-C) and translocation sequencing (HTGTS) methods. Combining modeling of chromosome structure and of chromosomal aberrations induced by ionizing radiation (IR) and nuclease we made predictions which quantitatively correlated with key experimental findings in mouse chromosomes: chromosome contact maps, high frequency of cis-translocation breakpoints far outside of the site of nuclease-induced DNA double-strand breaks (DSBs), the distinct shape of breakpoint distribution in chromosomes with different 3D organizations. These correlations support the heteropolymer globule principle of chromosome organization in G1-arrested pro-B mouse cells. The joint analysis of Hi-C, HTGTS and physical modeling data offers mechanistic insight into how chromosome structure heterogeneity, globular folding and lesion dynamics drive IR-recurrent CAs. The results provide the biophysical and computational basis for the analysis of chromosome aberration landscape under IR and nuclease-induced DSBs.
Highlights
The influence of spatial genome organization on chromosomal aberrations (CAs) is a problem attracting attention for many years
Combining modeling of chromosome structure and of chromosomal aberrations induced by ionizing radiation (IR) and nuclease we made predictions which quantitatively correlated with key experimental findings in mouse chromosomes: chromosome contact maps, high frequency of cis-translocation breakpoints far outside of the site of nuclease-induced DNA double-strand breaks (DSBs), the distinct shape of breakpoint distribution in chromosomes with different 3D organizations
We developed an approach to CA modeling which extracted information about 3D chromosome structure organization from high-throughput genomic data from chromosome conformation capture (Hi-C) data and applied it to the evaluation of CAs
Summary
The influence of spatial genome organization on chromosomal aberrations (CAs) is a problem attracting attention for many years. The experiments with knockdown of the DNA-end-binding protein Ku80 caused a loss of the positional stability of broken chromosome ends and allowed them to move in nuclear space [13]. In this way, the breakage-first mechanism may be activated. Regardless of whichever mechanism prevails, the spatial proximity of loci in the genome should increase the probability of inter- and intrachromosomal aberrations under the influence of various DNA-damaging factors, including ionizing radiation (IR) [7,14,15]
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