Zebularine induces replication-dependent double-strand breaks which are preferentially repaired by homologous recombination

Zebularine is a second-generation, highly stable hydrophilic inhibitor of DNA methylation with oral bioavailability that preferentially target cancer cells. It acts primarily as a trap for DNA methyl transferases (DNMTs) protein by forming covalent complexes between DNMT protein and zebularine-substrate DNA. It’s well documented that replication-blocking DNA lesions can cause replication fork collapse and thereby to the formation of DNA double-strand breaks (DSB). DSB are dangerous lesions that can lead to potentially oncogenic genomic rearrangements or cell death. The two major pathways for repair of DSB are non-homologous end joining (NHEJ) and homologous recombination (HR). Recently, multiple functions for the HR machinery have been identified at arrested forks. Here we investigate in more detail the importance of the lesions induced by zebularine in terms of DNA damage and cytotoxicity as well as the role of HR in the repair of these lesions. When we examined the contribution of NHEJ and HR in the repair of DSB induced by zebularine we found that these breaks were preferentially repaired by HR. Also we show that the production of DSB is dependent on active replication. To test this, we determined chromosome damage by zebularine while transiently inhibiting DNA synthesis. Here we report that cells deficient in single-strand break (SSB) repair are hypersensitive to zebularine. We have observed more DSB induced by zebularine in XRCC1 deficient cells, likely to be the result of conversion of SSB into toxic DSB when encountered by a replication fork. Furthermore we demonstrate that HR is required for the repair of these breaks. Overall, our data suggest that zebularine induces replication-dependent DSB which are preferentially repaired by HR.     

Radiation chemical mechanisms of single- and double-strand break formation in irradiated SV40 DNA

Using an electrophoresis assay system developed in our laboratory, we have simultaneously measured single- and double-strand DNA breaks (SSBs and DSBs) induced by gamma radiation in small SV40 viral DNA molecules, under conditions of greatly varying radical scavenger concentration and DNA configuration. In our experiments with aqueous solutions of SV40 DNA, we observe that SSB induction is linear with dose (one-hit response), over the entire hydroxyl scavenger efficiency range examined, from approximately 0 to 5 x 10(9) s-1, while DSB induction shifts from having a major quadratic component (two-hit response) at very low scavenger efficiencies to nearly pure linear for efficiencies greater than 10(7) s-1. The mean ratio of SSBs to one-hit DSBs remains relatively constant with increasing scavenger efficiency, decreasing from about 100:1 to 40:1 as the scavenger efficiency increases from 2 x 10(5) s-1 to 5 x 10(9) s-1, and the absolute induction efficiencies for breaks decrease by three orders of magnitude. This decrease takes place primarily at scavenger efficiencies above 1 x 10(8) s-1. Irradiation of intranuclear SV40 minichromosomes induces SSBs and DSBs at nearly the same efficiencies as does irradiation of free DNA at the highest scavenger concentrations examined, and at only about twice the efficiencies observed at -75 degrees C, where direct effects are believed to predominate. Our observations that the linear-quadratic mix of the dose-response curve for DSBs depends critically on scavenger efficiency may help to clarify the considerable confusion in the literature on the shape of such curves. Our observations of a relatively constant ratio between one-hit SSBs and DSBs at low and moderate scavenger efficiencies are in agreement with the recent hypothesis of Siddiqi and Bothe (Radiat. Res. 112, 449-463 (1987)) that, contrary to widely and long-held beliefs, the formation by indirect effects of a one-hit DSB in DNA occurs under these conditions predominantly by a mechanism involving a single OH radical, with a presumed radical transfer between complementary DNA strands. In contrast, our results for strongly protective conditions are not consistent with this hypothesis, but are consistent with the predictions of Ward's hypothesis (Radiat. Res. 86, 185-195, (1981)) that one-hit DSBs from indirect effects are produced predominantly by local clusters of OH radicals from single energy deposition events (locally multiply damaged sites) rather than by single OH radicals.(ABSTRACT TRUNCATED AT 400 WORDS)     

Formation and rejoining of deoxyribonucleic acid double-strand breaks induced in isolated cell nuclei by antineoplastic intercalating agents

The biochemical characteristics of the formation and disappearance of intercalator-induced DNA double-strand breaks (DSB) were studied in nuclei from mouse leukemia L1210 cells by using filter elution methodology [Bradley, M. O., & Kohn, K.W. (1979) Nucleic Acids Res. 7, 793-804]. The three intercalators used were 4'-(9-acridinylamino)-methanesulfon-m-anisidide (m-AMSA), 5-iminodaunorubicin (5-ID), and ellipticine. These compounds differ in that they produced predominantly DNA single-strand breaks (SSB) (m-AMSA) or predominantly DNA double-strand breaks (ellipticine) or a mixture of both SSB and DSB (5-ID) in whole cells. In isolated nuclei, each intercalator produced DSB at a frequency comparable to that which is produced in whole cells. Moreover, these DNA breaks reversed within 30 min after drug removal. It thus appeared that neither ATP nor other nucleotides were necessary for intercalator-dependent DNA nicking-closing reactions. The formation of the intercalator-induced DSB was reduced at ice temperature. Break formation was also reduced in the absence of magnesium, at a pH above 6.4 and at NaCl concentrations above 200 mM. In the presence of ATP and ATP analogues, the intercalator-induced cleavage was enhanced. These results suggest that the intercalator-induced DSB are enzymatically mediated and that the enzymes involved in these reactions can catalyze DNA double-strand cleavage and rejoining in the absence of ATP, although the occupancy of an ATP binding site might convert the enzyme to a form more reactive to intercalators. Three inhibitors of DNA topoisomerase II--novobiocin, nalidixic acid, and norfloxacin--reduced the formation of DNA strand breaks.(ABSTRACT TRUNCATED AT 250 WORDS)     

Parp-1 protects homologous recombination from interference by Ku and Ligase IV in vertebrate cells

Parp-1 and Parp-2 are activated by DNA breaks and have been implicated in the repair of DNA single-strand breaks (SSB). Their involvement in double-strand break (DSB) repair mediated by homologous recombination (HR) or nonhomologous end joining (NHEJ) remains unclear. We addressed this question using chicken DT40 cells, which have the advantage of carrying only a PARP-1 gene but not a PARP-2 gene. We found that PARP-1(-/-) DT40 mutants show reduced levels of HR and are sensitive to various DSB-inducing genotoxic agents. Surprisingly, this phenotype was strictly dependent on the presence of Ku, a DSB-binding factor that mediates NHEJ. PARP-1/KU70 double mutants were proficient in the execution of HR and displayed elevated resistance to DSB-inducing drugs. Moreover, we found deletion of Ligase IV, another NHEJ gene, suppressed the camptothecin of PARP-1(-/-) cells. Our results suggest a new critical function for Parp in minimizing the suppressive effects of Ku and the NHEJ pathway on HR.     

Rejoining of DNA strand breaks by T4 DNA ligase in mammalian cells

We have tested the ability of T4 DNA ligase to rejoin radiation-induced DNA strand breaks in living hamster cells (CHO-K1, EM9, xrs-5). T4 DNA ligase was introduced into cells by electroporation prior to x-irradiation. Single- and double-strand breaks were measured by the alkaline comet assay technique, and double-strand breaks (DSBs) were evaluated by the pulsed-field gel electrophoresis method. In the comet assay, the three cell lines showed reduced tail moments following pretreatment with T4 DNA ligase, both directly after irradiation and after repair incubation for 4 h. Similarly, the results obtained from pulsed-field gel electrophoresis showed reduced DSB frequencies after pretreatment with T4 DNA ligase. We conclude that exogeneous T4 ligase contributes to rejoining of radiation-induced strand breaks.     

Age and gender effects on DNA strand break repair in peripheral blood mononuclear cells

Exogenous and endogenous damage to DNA is constantly challenging the stability of our genome. This DNA damage increase the frequency of errors in DNA replication, thus causing point mutations or chromosomal rearrangements and has been implicated in aging, cancer, and neurodegenerative diseases. Therefore, efficient DNA repair is vital for the maintenance of genome stability. The general notion has been that DNA repair capacity decreases with age although there are conflicting results. Here, we focused on potential age‐associated changes in DNA damage response and the capacities of repairing DNA single‐strand breaks (SSBs) and double‐strand breaks (DSBs) in human peripheral blood mononuclear cells (PBMCs). Of these lesions, DSBs are the least frequent but the most dangerous for cells. We have measured the level of endogenous SSBs, SSB repair capacity, γ‐H2AX response, and DSB repair capacity in a study population consisting of 216 individuals from a population‐based sample of twins aged 40–77 years. Age in this range did not seem to have any effect on the SSB parameters. However, γ‐H2AX response and DSB repair capacity decreased with increasing age, although the associations did not reach statistical significance after adjustment for batch effect across multiple experiments. No gender differences were observed for any of the parameters analyzed. Our findings suggest that in PBMCs, the repair of SSBs is maintained until old age, whereas the response to and the repair of DSBs decrease.     

Measurement of radiation-induced DNA damage using gel electrophoresis or neutral filter elution shows an increased frequency of DNA strand breaks after exposure to pH 9.6

The filter elution technique using nondenaturing conditions is widely used to assay DNA double-strand break (DSB) induction and repair. It has been reported that in the measurement of strand breaks higher rates of elution and of initial rejoining are obtained at pH 9.6 compared to pH 7.2. In the present experiments neutral elution at pH 7.2 and 9.6 were compared in the assay of damage to DNA induced by X rays, 125I decay, and restriction enzyme digestion, in an effort to explain this discrepancy and to determine whether the higher rate of elution observed at pH 9.6 corresponds to a greater number of DSBs. X-ray damage to cellular DNA resulted in significantly different elution profiles at the two pH values. In contrast the elution profiles of the DSB induced by intragenomic 125I decays or restriction endonuclease were independent of the pH of the elution buffer. When gamma-irradiated SV40 DNA was exposed to pH 7.2 or 9.6 elution buffer prior to analysis by gel electrophoresis, a significantly greater number of DNA DSBs were detected in the DNA exposed to pH 9.6. We conclude that X and gamma radiation produce lesions (pH 9.6-labile lesions), in proportion to dose, that have the potential of becoming measurable DSBs following incubation under the mildly alkaline condition of pH 9.6. The data suggest that these lesions may result from single-hit events.     

SV40 Utilizes ATM Kinase Activity to Prevent Non-homologous End Joining of Broken Viral DNA Replication Products

Simian virus 40 (SV40) and cellular DNA replication rely on host ATM and ATR DNA damage signaling kinases to facilitate DNA repair and elicit cell cycle arrest following DNA damage. During SV40 DNA replication, ATM kinase activity prevents concatemerization of the viral genome whereas ATR activity prevents accumulation of aberrant genomes resulting from breakage of a moving replication fork as it converges with a stalled fork. However, the repair pathways that ATM and ATR orchestrate to prevent these aberrant SV40 DNA replication products are unclear. Using two-dimensional gel electrophoresis and Southern blotting, we show that ATR kinase activity, but not DNA-PK_cs kinase activity, facilitates some aspects of double strand break (DSB) repair when ATM is inhibited during SV40 infection. To clarify which repair factors associate with viral DNA replication centers, we examined the localization of DSB repair proteins in response to SV40 infection. Under normal conditions, viral replication centers exclusively associate with homology-directed repair (HDR) and do not colocalize with non-homologous end joining (NHEJ) factors. Following ATM inhibition, but not ATR inhibition, activated DNA-PK_cs and KU70/80 accumulate at the viral replication centers while CtIP and BLM, proteins that initiate 5′ to 3′ end resection during HDR, become undetectable. Similar to what has been observed during cellular DSB repair in S phase, these data suggest that ATM kinase influences DSB repair pathway choice by preventing the recruitment of NHEJ factors to replicating viral DNA. These data may explain how ATM prevents concatemerization of the viral genome and promotes viral propagation. We suggest that inhibitors of DNA damage signaling and DNA repair could be used during infection to disrupt productive viral DNA replication.     

Quantitation of the involvement of the recA, recB, recC, recF, recJ, recN, lexA, radA, radB, uvrD, and umuC genes in the repair of X-ray-induced DNA double-strand breaks in Escherichia coli

Isogenic Escherichia coli strains carrying single DNA-repair mutations were compared for their capacity for (i) the repair of X-ray-induced DNA double-strand breaks (DSB) as measured using neutral sucrose gradients; (ii) medium-dependent resistance, i.e., a recA-dependent X-ray survival phenomenon that correlates closely with the capacity for repairing DSB; and (iii) the growth medium-dependent, recA-dependent repair of X-ray-induced DNA single-strand breaks (SSB) as measured using alkaline sucrose gradients (about 80% of these SSB are actually parts of DSB). These three capacities were measured to quantitate more accurately the involvement of the various genes in the repair of DSB over a wide dose range. The mutations tested were grouped into five classes according to their effect on the repair of X-ray-induced DSB: (I) the recA, recB, recC, and lexA mutants were completely deficient; (II) the radB and recN mutants were about 90% deficient; (III) the recF and recJ mutants were about 70% deficient; (IV) the radA and uvrD mutants were about 30% deficient; and (V) the umuC mutant resembled the wild-type strains in its capacity for the repair of DSB.     

Repair of DNA single-strand breaks in X-irradiated yeast. II. Kinetics of repair as measured by the DNA-unwinding method

The kinetics of disappearance of single-strand breaks (SSB) from the DNA of X-irradiated stationary yeast cells under liquid-holding conditions was found to proceed in a dose-independent manner up to a dose of at least 2400 Gy, and was found to be complete after incubation of cells for 1 h. This was deduced from data for a yeast wild-type (WT) haploid and diploid strain as well as for rad52 haploid cells defective in DNA double-strand break (DSB) repair. In all cases an initial fast repair component assumed to correspond to SSB repair was observed whereby about 80% of the induced 'unwinding points' disappeared from the DNA with a time constant of about 3 min. Following this fast component, a slower component of removal of 'unwinding points' occurred with a time constant estimated to be 20 min. The molecular nature of these two components of repair is not known. We could find no evidence for the induction of secondary (enzymatic) breaks in the DNA during post-irradiation incubation. Incubation of cells in growth medium after irradiation resulted in similar kinetics as those under liquid-holding conditions. In the absence of an energy source in the medium (i.e. when cells were incubated in buffer or distilled water after irradiation) only 60-80% of the SSB were removed from yeast DNA. Residual SSB disappeared from the DNA only when cells were transferred to a medium containing glucose. The relative mass of DNA unwound per induced strand break (i.e. represented by the slope of the dose-effect curve immediately after irradiation) was found to change slowly with the age of the cell culture under liquid-holding conditions. This effect had to be corrected for in the measurements of strand break repair under these conditions.     

Damage clusters after gamma irradiation of a nanoparticulate plasmid DNA peptide condensate

We have gamma-irradiated plasmid DNA in aqueous solution in the presence of submillimolar concentrations of the ligand tetra-arginine. Depending upon the ionic strength, under these conditions, the plasmid can adopt a highly compacted and aggregated form which attenuates by some two orders of magnitude the yield of damage produced by the indirect effect. The yields of DNA single- and double-strand breaks (SSB and DSB) which result are closely comparable with those produced in living cells. The radical lifetimes, diffusion distances, and track structure are expected to be similarly well reproduced. After irradiation, the aggregation was reversed by adjusting the ionic conditions. The approximate spatial distribution of the resulting DNA damage was then assayed by comparing the increases in the SSB and DSB yields produced by a subsequent incubation with limiting concentrations of the eukaryotic base excision repair enzymes formamidopyrimidine-DNA N-glycosylase (the FPG protein) and endonuclease III. Smaller increases in DSB yields were observed in the plasmid target that was irradiated in the condensed form. By modeling the spatial distribution of DNA damage, this result can be interpreted in terms of a greater extent of damage clustering.     

DNA single-strand breaks,double-strand breaks,and crosslinks in rat testicular germ cells: Measurements of their formation and repair by alkaline and neutral filter elution

This work describes a neutral and alkaline elution method for measuring DNA single-strand breaks (SSBs), DNA double-strand breaks (DSBs), and DNA-DNA crosslinks in rat testicular germ cells after treatments in vivo or in vitro with both chemical mutagens and gamma-irradiation. The methods depend upon the isolation of testicular germ cells by collagenase and trypsin digestion, followed by filtration and centrifugation. ¹³⁷Cs irradiation induced both DNA SSBs and DSBs in germ cells held on ice in vitro. Irradiation of the whole animal indicated that both types of DNA breaks are induced in vivo and can be repaired. A number of germ cell mutagens induced either DNA SSBs, DSBs, or cross-links after in vivo and in vitro dosing. These chemicals included methyl methane sulfonate, ethyl methane sulfonate, ethyl nitrosurea, dibromochlorpropane, ethylene dibromide, triethylene melamine, and mitomycin C. These results suggest that the blood-testes barrier is relatively ineffective for these mutagens, which may explain in part their in vivo mutagenic potency.This assay should be a useful screen for detecting chemical attack upon male germ-cell DNA and thus, it should help in the assessment of the mutagenic risk of chemicals. In addition, this approach can be used to study the processes of SSB, DSB, and crosslink repair in DNA of male germ cells, either from all stages or specific stages of development.Abbreviations DBCP dibromochlorpropane - DSB(s) DNA double-strand break(s) - EDB ethylene dibromide - EMS ethyl methane sulfonate - ENU ethyl nitrosurea - MC mitomycin C - MMS methyl methane sulfonate - SDS sodium dodecyl sulfate - SSB (s) DNA single-strand break(s) - TEM triethylene melamine - UDS unscheduled DNA synthesis     

Impaired elimination of DNA double-strand break-containing lymphocytes in ataxia telangiectasia and Nijmegen breakage syndrome

The repair of DNA double-strand breaks is critical for genome integrity and tumor suppression. Here we show that following treatment with the DNA-intercalating agent actinomycin D (ActD), normal quiescent T cells accumulate double-strand breaks and die, whereas T cells from ataxia telangiectasia (AT) and Nijmegen breakage syndrome (NBS) patients are resistant to this death pathway despite a comparable amount of DNA damage. We demonstrate that the ActD-induced death pathway in quiescent T lymphocytes follows DNA damage and H2AX phosphorylation, is ATM- and NBS1-dependent and due to p53-mediated cellular apoptosis. In response to genotoxic 2-Gy gamma-irradiation, on the other hand, quiescent T cells from normal donors survive following complete resolution of the damage thus induced. T cells from AT and NBS patients also survive, but retain foci of phosphorylated H2AX due to a subtle double-strand break (DSB) repair defect. A common consequence of these two genetic defects in the DSB response is the apparent tolerance of cells containing DNA breaks. We suggest that this tolerance makes a major contribution to the oncogenic risk of patients with chromosome instability syndromes.     

DNA repair synthesis facilitates RAD52-mediated second-end capture during DSB repair

Homologous recombination (HR) is essential for the repair of DNA double-strand breaks (DSBs) in mitotic and meiotic cells. HR occurs through a series of steps involving DSB resection, invasion of single-stranded DNA into homologous duplex DNA to form a D loop, repair synthesis, and second-end capture. We show that DNA repair synthesis, catalyzed by human DNA polymerase eta (poleta) acting upon the priming strand of a D loop, leads to capture and annealing of the second end of a resected DSB in reactions mediated by RAD52 protein. Second-end capture products were not detected when poleta was replaced by other polymerases such as poldelta or poliota. RAD52 could not be replaced by RAD51. We also found that the RAD52-dependent reaction was stimulated by the single-strand binding protein RPA, but not by E. coli SSB. Following repair synthesis and second-end capture, de novo DNA synthesis was observed from the captured second DNA end.     

Enhancement of DNA damage and involvement of reactive oxygen species after exposure to bitumen with UVA irradiation.

This study was carried out to evaluate whether bitumen cytotoxicity is enhanced when bitumen treatment is combined with UVA exposure. We also evaluated the oxidative processes in bitumen-induced DNA damage, and attempted to identify the DNA damage caused by bitumen and UVA exposures, either alone or in combination. The effects of bitumen and UVA on cell proliferation were examined using HL 60 cells. DNA-protein crosslinks (DPCs) were assessed using a K-SDS assay, and reactive oxygen species formation was detected by 8-OH-dG formation. We evaluated the formations of double-strand breaks (DSB) using lambdaDNA/HindIII and single-strand breaks (SSB) using PM2 DNA. The cytotoxicity assay showed enhanced suppression of cell proliferation when bitumen exposure and UVA exposure were combined. Combined exposure caused significant increases in DPCs over either exposure alone. Incubation of deoxyguanosine (dG) with bitumen or UVA showed an increase in 8-hydroxy-2'-deoxyguanosine (8-OH-dG) levels when compared with controls, and combined exposure enhanced this effect. An evaluation of agarose gel bands showed that DSB and SSB were not formed following exposure to bitumen and UVA. This fact indicates that bitumen and UVA may be involved in genotoxic processes by producing oxygen free radicals and that combined exposure enhances these effects.     

BRCA2-dependent homologous recombination is required for repair of Arsenite-induced replication lesions in mammalian cells

Arsenic exposure constitutes one of the most widespread environmental carcinogens, and is associated with increased risk of many different types of cancers. Here we report that arsenite (As[III]) can induce both replication-dependent DNA double-strand breaks (DSB) and homologous recombination (HR) at doses as low as 5 µM (0.65 mg/l), which are within the typical doses often found in drinking water in contaminated areas. We show that the production of DSBs is dependent on active replication and is likely to be the result of conversion of a DNA single-strand break (SSB) into a toxic DSB when encountered by a replication fork. We demonstrate that HR is required for the repair of these breaks and show that a functional HR pathway protects against As[III]-induced cytotoxicity. In addition, BRCA2-deficient cells are sensitive to As[III] and we suggest that As[III] could be exploited as a therapy for HR-deficient tumours such as BRCA1 and BRCA2 mutated breast and ovarian cancers.     

Replication protein A and gamma-H2AX foci assembly is triggered by cellular response to DNA double-strand breaks

Human replication protein A (RPA p34), a crucial component of diverse DNA excision repair pathways, is implicated in DNA double-strand break (DSB) repair. To evaluate its role in DSB repair, the intranuclear dynamics of RPA was investigated after DNA damage and replication blockage in human cells. Using two different agents [ionizing radiation (IR) and hydroxyurea (HU)] to generate DSBs, we found that RPA relocated into distinct nuclear foci and colocalized with a well-known DSB binding factor, gamma-H2AX, at the sites of DNA damage in a time-dependent manner. Colocalization of RPA and gamma-H2AX foci peaked at 2 h after IR treatment and subsequently declined with increasing postrecovery times. The time course of RPA and gamma-H2AX foci association correlated well with the DSB repair activity detected by a neutral comet assay. A phosphatidylinositol-3 (PI-3) kinase inhibitor, wortmannin, completely abolished both RPA and gamma-H2AX foci formation triggered by IR. Additionally, radiosensitive ataxia telangiectasia (AT) cells harboring mutations in ATM gene product were found to be deficient in RPA and gamma-H2AX colocalization after IR. Transfection of AT cells with ATM cDNA fully restored the association of RPA foci with gamma-H2AX illustrating the requirement of ATM gene product for this process. The exact coincidence of RPA and gamma-H2AX in response to HU specifically in S-phase cells supports their role in DNA replication checkpoint control. Depletion of RPA by small interfering RNA (SiRNA) substantially elevated the frequencies of IR-induced micronuclei (MN) and apoptosis in human cells suggestive of a role for RPA in DSB repair. We propose that RPA in association with gamma-H2AX contributes to both DNA damage checkpoint control and repair in response to strand breaks and stalled replication forks in human cells.     

Relative contribution of homologous recombination and non-homologous end-joining to DNA double-strand break repair after oxidative stress in Saccharomyces cerevisiae

Oxidative damage to DNA seems to be an important factor in developing many human diseases including cancer. It involves base and sugar damage, base-free sites, DNA-protein cross-links and DNA single-strand (SSB) and double-strand (DSB) breaks. Oxidative DSB can be formed in various ways such as their direct induction by the drug or their generation either through attempted and aborted repair of primary DNA lesions or through DNA replication-dependent conversion of SSB. In general, two main pathways are responsible for repairing DSB, homologous recombination (HR) and non-homologous end-joining (NHEJ), with both of them being potential candidates for the repair of oxidative DSB. We have examined relative contribution of HR and NHEJ to cellular response after oxidative stress in Saccharomyces cerevisiae. Therefore, cell survival, mutagenesis and DSB induction and repair in the rad52, yku70 and rad52 yku70 mutants after hydrogen peroxide (H(2)O(2)), menadione (MD) or bleomycin (BLM) exposure were compared to those obtained for the corresponding wild type. We show that MD exposure does not lead to observable DSB induction in yeast, suggesting that the toxic effects of this agent are mediated by other types of DNA damage. Although H(2)O(2) treatment generates some DSB, their yield is relatively low and hence DSB may only partially be responsible for toxicity of H(2)O(2), particularly at high doses of the agent. On the other hand, the basis of the BLM toxicity resides primarily in DSB induction. Both HR and NHEJ act on BLM-induced DSB, although their relative participation in the process is not equal. Based on our results we suggest that the complexity and/or the quality of the BLM-induced DSB might represent an obstacle for the NHEJ pathway.     

Proliferative potential after DNA damage and non-homologous end joining are affected by loss of securin

The faithful repair of DNA damage, especially chromosomal double-strand breaks (DSBs), is crucial for genomic integrity. We have previously shown that securin interacts with the Ku70/80 heterodimer of the DSB non-homologous DNA end-joining (NHEJ) repair machinery. Here we demonstrate that securin deficiency compromises cell survival and proliferation, but only after genotoxic stress. Securin(-/-) cells show a significant increase in gross chromosomal rearrangements and chromatid breaks after DNA damage, and also reveal an altered pattern of end resection in an NHEJ assay in comparison with securin(+/+) cells. These data suggest that securin has a key role in the maintenance of genomic stability after DNA damage, thereby providing a previously unknown mechanism for regulating tumour progression.