Abstract
To obtain an overall picture of the repair of DNA single and double strand breaks in a defined region of chromatin in vivo, we studied their repair in a ∼170 kb circular minichromosome whose length and topology are analogous to those of the closed loops in genomic chromatin. The rate of repair of single strand breaks in cells irradiated with γ photons was quantitated by determining the sensitivity of the minichromosome DNA to nuclease S1, and that of double strand breaks by assaying the reformation of supercoiled DNA using pulsed field electrophoresis. Reformation of supercoiled DNA, which requires that all single strand breaks have been repaired, was not slowed detectably by the inhibitors of poly(ADP-ribose) polymerase-1 NU1025 or 1,5-IQD. Repair of double strand breaks was slowed by 20–30% when homologous recombination was supressed by KU55933, caffeine, or siRNA-mediated depletion of Rad51 but was completely arrested by the inhibitors of nonhomologous end-joining wortmannin or NU7441, responses interpreted as reflecting competition between these repair pathways similar to that seen in genomic DNA. The reformation of supercoiled DNA was unaffected when topoisomerases I or II, whose participation in repair of strand breaks has been controversial, were inhibited by the catalytic inhibitors ICRF-193 or F11782. Modeling of the kinetics of repair provided rate constants and showed that repair of single strand breaks in minichromosome DNA proceeded independently of repair of double strand breaks. The simplicity of quantitating strand breaks in this minichromosome provides a usefull system for testing the efficiency of new inhibitors of their repair, and since the sequence and structural features of its DNA and its transcription pattern have been studied extensively it offers a good model for examining other aspects of DNA breakage and repair.
Highlights
The molecular events implicated in repair of strand breaks in DNA are becoming more clear, but an overall and quantitative picture of their repair in vivo which would contribute to understanding the systems biology of repair and the effects of inhibitors is not yet available
As a model system to approach this question we are studying the repair of strand breaks in vivo in a,170 kb circular minichromosome, the Epstein-Barr virus (EBV) episome, which is maintained in the nuclei of Raji cells at 50–100 copies localised at the periphery of interphase chromosomes [12,13,14,15,16,17]
Strand Breaks in the Minichromosome in Irradiated Cells The supercoiled minichromosome DNA [12] and the forms which were expected to be produced in irradiated cells were quantitated by hybridising pulsed-field gel electrophoresis (PFGE) gels of total cell DNA with a probe of EBV DNA, the linear form of the minichromosome DNA [14] (Figure 1B)
Summary
The molecular events implicated in repair of strand breaks in DNA are becoming more clear (reviewed in [1,2,3,4,5,6]), but an overall and quantitative picture of their repair in vivo which would contribute to understanding the systems biology of repair and the effects of inhibitors is not yet available. As a model system to approach this question we are studying the repair of strand breaks in vivo in a ,170 kb circular minichromosome, the Epstein-Barr virus (EBV) episome, which is maintained in the nuclei of Raji cells at 50–100 copies localised at the periphery of interphase chromosomes [12,13,14,15,16,17]. New features of the repair of strand breaks in vivo and of their kinetics were revealed by mathematical modeling
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