Assessment of radiation-induced DNA strand breaks and their repair in unlabeled cells.

Radiation induced damage, i.e., the induction of DNA strand breaks, was studied on the level of single, unlabeled cells. DNA strand breaks were determined by direct partial alkaline unwinding in intact cell nuclei followed by staining with acridine orange, a development of a proposal first described by B. Rydberg (Int J Radiat Biol 46:521-527, 1984). The ratio of green fluorescence (double-stranded DNA) to red fluorescence (single-stranded DNA) in single cells was taken as a measure of DNA strand breaks. CHO-K1 and M3-1 cells irradiated with X-rays show a dose dependent induction of DNA strand breaks. Incubation at 37 degrees C after irradiation leads to repair of breaks. A repair halflife of about 10-11 min can be determined. Cell cycle specific differences in the induction of DNA strand breaks or repair behavior are not detectable at the resolution achieved so far. This new method offers two major advantages: the resolution of DNA damage and repair on the level of single cells and no need for labeling, thereby allowing for DNA damage and repair to be assessed in biopsy material from tumor patients.     

MRN and the race to the break

In all living cells, DNA is constantly threatened by both endogenous and exogenous agents. In order to protect genetic information, all cells have developed a sophisticated network of proteins, which constantly monitor genomic integrity. This network, termed the DNA damage response, senses and signals the presence of DNA damage to effect numerous biological responses, including DNA repair, transient cell cycle arrests (“checkpoints”) and apoptosis. The MRN complex (MRX in yeast), composed of Mre11, Rad50 and Nbs1 (Xrs2), is a key component of the immediate early response to DNA damage, involved in a cross-talk between the repair and checkpoint machinery. Using its ability to bind DNA ends, it is ideally placed to sense and signal the presence of double strand breaks and plays an important role in DNA repair and cellular survival. Here, we summarise recent observation on MRN structure, function, regulation and emerging mechanisms by which the MRN nano-machinery protects genomic integrity. Finally, we discuss the biological significance of the unique MRN structure and summarise the emerging sequence of early events of the response to double strand breaks orchestrated by the MRN complex.     

Changes of 8-OH-dG levels in DNA and its base excision repair activity in rat lungs after inhalation exposure to hexavalent chromium

The co-genotoxic effects of cadmium are well recognized and it is assumed that most of these effects are due to the inhibition of DNA repair. We used the comet assay to analyze the effect of low, non-toxic concentrations of CdCl2 on DNA damage and repair-induced in Chinese hamster ovary (CHO) cells by UV-radiation, by methyl methanesulfonate (MMS) and by N-methyl-N-nitrosourea (MNU). The UV-induced DNA lesions revealed by the comet assay are single-strand breaks which are the intermediates formed during nucleotide excision repair (NER). In cells exposed to UV-irradiation alone the formation of DNA strand breaks was rapid, followed by a fast rejoining phase during the first 60 min after irradiation. In UV-irradiated cells pre-exposed to CdCl2, the formation of DNA strand breaks was significantly slower, indicating that cadmium inhibited DNA damage recognition and/or excision. Methyl methanesulfonate and N-methyl-N-nitrosourea directly alkylate nitrogen and oxygen atoms of DNA bases. The lesions revealed by the comet assay are mainly breaks at apurinic/apyrimidinic (AP) sites and breaks formed as intermediates during base excision repair (BER). In MMS treated cells the initial level of DNA strand breaks did not change during the first hour of recovery; thereafter repair was detected. In cells pre-exposed to CdCl2 the MMS-induced DNA strand breaks accumulated during the first 2h of recovery, indicating that AP sites and/or DNA strand breaks were formed but that further steps of BER were blocked. In MNU treated cells the maximal level of DNA strand breaks was detected immediately after the treatment and the breaks were repaired rapidly. In CdCl2 pre-treated cells the formation of MNU-induced DNA single-strand breaks was not affected, while the repair was slower, indicating inhibition of polymerization and/or the ligation step of BER. Cadmium thus affects the repair of UV-, MMS- and MNU-induced DNA damage, providing further evidence, that inhibition of DNA repair is an important mechanism of cadmium induced mutagenicity and carcinogenicity.     

Attempted base excision repair of ionizing radiation damage in human lymphoblastoid cells produces lethal and mutagenic double strand breaks

A significant proportion of cellular DNA damages induced by ionizing radiation are produced in clusters, also called multiply damaged sites. It has been demonstrated by in vitro studies and in bacteria that clustered damage sites can be converted to lethal double strand breaks by oxidative DNA glycosylases during attempted base excision repair. To determine whether DNA glycosylases could produce double strand breaks at radiation-induced clustered damages in human cells, stably transformed human lymphoblastoid TK6 cells that inducibly overexpress the oxidative DNA glycosylases/AP lyases, hNTH1 and hOGG1, were assessed for their radiation responses, including survival, mutation induction and the enzymatic production of double strand breaks post-irradiation. We found that additional double strand breaks were generated during post-irradiation incubation in uninduced TK6 control cells. Moreover, overproduction of either DNA glycosylase resulted in significantly increased double strand break formation, which correlated with an elevated sensitivity to the cytotoxic and mutagenic effects of ionizing radiation. These data show that attempted repair of radiation damage, presumably at clustered damage sites, by the oxidative DNA glycosylases can lead to the formation of potentially lethal and mutagenic double strand breaks in human cells.     

Viral Interference with DNA Repair by Targeting of the Single-Stranded DNA Binding Protein RPA

Correct repair of damaged DNA is critical for genomic integrity. Deficiencies in DNA repair are linked with human cancer. Here we report a novel mechanism by which a virus manipulates DNA damage responses. Infection with murine polyomavirus sensitizes cells to DNA damage by UV and etoposide. Polyomavirus large T antigen (LT) alone is sufficient to sensitize cells 100 fold to UV and other kinds of DNA damage. This results in activated stress responses and apoptosis. Genetic analysis shows that LT sensitizes via the binding of its origin-binding domain (OBD) to the single-stranded DNA binding protein replication protein A (RPA). Overexpression of RPA protects cells expressing OBD from damage, and knockdown of RPA mimics the LT phenotype. LT prevents recruitment of RPA to nuclear foci after DNA damage. This leads to failure to recruit repair proteins such as Rad51 or Rad9, explaining why LT prevents repair of double strand DNA breaks by homologous recombination. A targeted intervention directed at RPA based on this viral mechanism could be useful in circumventing the resistance of cancer cells to therapy.     

Early nuclear events in lymphocyte proliferation : The role of DNA strand break repair and ADP ribosylation

The previously reported extensive DNA strand breakage in resting murine splenic lymphocytes is not an artifact of the extraction or assay procedure. The benzamide inhibitors of poly(ADP ribose) synthetase (pADPRS), such as 5-methoxybenzamide (MBA), had been shown to block the strand break repair occurring within 2 h of activation of splenic lymphocytes by the mitogen concanavalin A (conA); the inhibitors also blocked early events in proliferation, such as blast formation, as well as entry into S phase. Inhibitors of pADPRS blocked lymphocyte proliferation by inhibiting the activity of this enzyme, rather than by non-specific effects. Aphidicolin, an inhibitor of alpha-polymerase, also prevented DNA strand break repair in conA-stimulated cells but, unlike MBA, did not prevent blast formation. DNA strand breaks accumulated in the presence of MBA at the same linear rate (300-400/h) in both resting and conA-treated cells. We and others had hypothesized that this accumulation was due to a continuous production of strand breaks in lymphocytes, leading to their accumulation in presence of repair inhibitors. However, incubation of the cells with aphidicolin at concentrations that inhibited repair did not result in any increase in strand breaks. The hypothesis of continuous cycling of breaks is incorrect; accumulation of breaks was due to some indirect effect of MBA, such as a possible disinhibition of an ADP-ribosylation-sensitive endonuclease described in other cell types. All of the early stages of lymphocyte proliferation, including blast transformation (but not DNA synthesis) require ADP ribosylation. Repair of DNA strand breaks is not a precondition for blast formation, though experiments involving the combined effects of MBA and aphidicolin showed that repair of the breaks is essential in order for the cells to replicate their DNA. Our data are consistent with a model suggesting that DNA strand breaks introduced into differentiated cells act as an additional safety-catch mechanism that restrains them from replicating their genetic material but not from undergoing the early stages of proliferation.     

Repair of ionizing radiation damage in mammalian cells. Alternative pathways and their fidelity

Ionizing radiation causes a variety of types of damage to DNA in cells, requiring the concerted action of a number of DNA repair enzymes to restore genomic integrity. The DNA base-excision repair and DNA double-strand break repair pathways are particularly important. While single base damages are rapidly excised and repaired using the opposite (undamaged) strand as a template, the correct repair of DNA double-strand breaks may present more difficulties to cellular enzymes owing to the loss of template. In the last few years evidence in support of several enzymatic pathways for the repair of such double-stranded damage has been found. At present we may distinguish at least three pathways: homologous recombination repair, non-homologous (DNA-PK-dependent) end joining, and repeat-driven end joining. This paper focuses on evidence for the first and third of these pathways, and considers in particular their relative importance in mammalian cells and implications for the fidelity of repair.     

The role of poly(ADP-ribose) in the DNA damage signaling network.

DNA damage signaling is crucial for the maintenance of genome integrity. In higher eukaryotes a NAD+-dependent signal transduction mechanism has evolved to protect cells against the genome destabilizing effects of DNA strand breaks. The mechanism involves 2 nuclear enzymes that sense DNA strand breaks, poly(ADP-ribose) polymerase-1 and -2 (PARP-1 and PARP-2). When activated by DNA breaks, these PARPs use NAD+ to catalyze their automodification with negatively charged, long and branched ADP-ribose polymers. Through recruitment of specific proteins at the site of damage and regulation of their activities, these polymers may either directly participate in the repair process or coordinate repair through chromatin unfolding, cell cycle progression, and cell survival-cell death pathways. A number of proteins, including histones, DNA topoisomerases, DNA methyltransferase-1 as well as DNA damage repair and checkpoint proteins (p23, p21, DNA-PK, NF-kB, XRCC1, and others) can be targeted in this manner; the interaction involves a specific poly(ADP-ribose)-binding sequence motif of 20-26 amino acids in the target domains.     

Alkali lability and rapid initiation of excision repair following photoaffinity damage by ethidium azide

DNA damage and repair provoked by ethidium azide (EA) photoaffinity labeling in mouse leukemia cells was studied by measuring sedimentation properties of nucleoids in neutral sucrose gradients, and it was found that the strand opening step was faster than that which followed damage of cells by ultraviolet (UV) light. The two insults were compared at levels of damage which gave the same overall rates of repair synthesis in intact cells and which required the same length of time to complete repair, as judged by the restoration of supercoiling of the isolated nucleoids. In the case of UV, single-strand breaks in DNA were detectable at 30 min, maximum at 2 h, and the superhelical properties restored at 21 h. With photoaffinity labeling, single-strand breaks were prominent immediately, even when photolabeling of cells was done on ice, but restoration of DNA supercoiling still required 21 h. Photolabeling of isolated nucleoids or isolated viral DNA with EA failed to introduce DNA strand breaks. However, it was discovered that photoaffinity labeling of DNA with EA resulted in alkali labile sites shown by single strand breaks produced on alkaline sucrose sedimentation or by alkali exposure followed by sedimentation on neutral formamide gradients. These results suggest that the drug attachment sites should be identifiable by the location of such single strand breaks.     

Effect of age on endogenous DNA single-strand breakage, strand break induction and repair in the adult housefly, Musca domestica

It has been suggested that genomic alterations involving DNA damage and the ability to repair such damage play an important role in cellular senescence. In this study, endogenous DNA single-strand breaks, the susceptibility of DNA to induced strand breakage and the capacity to repair these breaks were compared in postmitotic cells from young (3-day-old) and old (23-day-old) houseflies. DNA single-strand breaks did not accumulate during normal aging in the housefly. However, cells of the old flies exhibited a greater sensitivity to single-strand breakage induced by gamma-radiation and UV light. The capacity to repair these exogenously induced single-strand breaks declined with age. Results do not support the view that DNA single-strand breaks are a causal factor in aging in the housefly. An age-related increase in the susceptibility to undergo single-strand breakage suggests alterations in chromatin during the aging process.     

Interaction between radiation and drug damage in mammalian cells. V. DNA damage and repair induced in LZ cells by adriamycin and/or radiation

A multi-drug-resistant cell line selected in increasing concentrations of Adriamycin and designated LZ (J. A. Belli, Radiat. Res. 119, 88-100, 1989) is shown to exhibit a survival response characterized by radiation sensitivity and Adriamycin resistance. To determine if this response is due to alterations in either the initial levels of damage induced or the repair of DNA damage, LZ cells and the parental V79 cells were exposed to either radiation or Adriamycin and the damage and repair were measured with alkaline or nondenaturing filter elution. After exposure to radiation, induction and repair of both single-strand and double-strand breaks were equivalent. LZ cells exposed to 100 micrograms/ml Adriamycin for 1 h contained no measurable damage while the same treatment induced breaks and crosslinks in V79 cells. Pretreatment of LZ cells for 1 h with Adriamycin before irradiation did not alter either the initial levels of induced damage or the repair of strand breakage. These results suggest that (1) mechanisms other than differential induction and repair of strand breaks are responsible for the increased radiation sensitivity in LZ, and (2) the lack of Adriamycin-induced DNA damage in LZ is at least partially responsible for the increased cell survival after treatment.     

Human Xip1 (C2orf13) is a novel regulator of cellular responses to DNA strand breaks

DNA strand breaks arise continuously as the result of intracellular metabolism and in response to a multitude of genotoxic agents. To overcome such challenges to genomic stability, cells have evolved genome surveillance pathways that detect and repair damaged DNA in a coordinated fashion. Here we identify the previously uncharacterized human protein Xip1 (C2orf13) as a novel component of the checkpoint response to DNA strand breaks. Green fluorescent protein-tagged Xip1 was rapidly recruited to sites of DNA breaks, and this accumulation was dependent on a novel type of zinc finger motif located in the C terminus of Xip1. The initial recruitment kinetics of Xip1 closely paralleled that of XRCC1, a central organizer of single strand break (SSB) repair, and its accumulation was both delayed and sustained when the detection of SSBs was abrogated by inhibition of PARP-1. Xip1 and XRCC1 stably interacted through recognition of CK2 phosphorylation sites in XRCC1 by the Forkhead-associated (FHA) domain of Xip1, and XRCC1 was required to maintain steady-state levels of Xip1. Moreover, Xip1 was phosphorylated on Ser-116 by ataxia telangiectasia-mutated in response to ionizing radiation, further underscoring the potential importance of Xip1 in the DNA damage response. Finally, depletion of Xip1 significantly decreased the clonogenic survival of cells exposed to DNA SSB- or double strand break-inducing agents. Collectively, these findings implicate Xip1 as a new regulator of genome maintenance pathways, which may function to organize DNA strand break repair complexes at sites of DNA damage.     

Analysis of DNA damage and repair accompanying differentiation in the intestinal crypt.

The ability to process damaged DNA may vary between cells depending on their differentiated status. However, there is little in vivo data available and it is not intuitively obvious how the activity of specific repair pathways may vary between different subpopulations (e.g. stem cells and proliferative, committed and differentiated cells) of a particular tissue. To obtain such information for the intestinal epithelium, we have developed an assay that detects differences in the way different regions of the crypt (stem, proliferative and maturation zones) respond to DNA damage. The assay is a variant of the ''comet'' assay, which detects DNA strand breaks by measuring the proportion of DNA migrating from individual cells, or in this case intact isolated crypts, in an electrophoretic field. The method is quantitative, with the amount of migrating DNA being proportional to the number of strand breaks. Isolated crypts are repair competent and spatial differences are apparent with some agents. The assay has the potential to characterize the repair properties of cells at different stages of differentiation within the crypt, determine the characteristics that might predispose them to damage and may help in understanding the route of stem cell mutation.     

Defective repair of DNA single- and double-strand breaks in the bleomycin- and X-ray-sensitive Chinese hamster ovary cell mutant, BLM-2

Using filter elution techniques, we have measured the level of induced single- and double-strand DNA breaks and the rate of strand break rejoining following exposure of two Chinese hamster ovary (CHO) cell mutants to bleomycin or neocarzinostatin. These mutants, designated BLM-1 and BLM-2, were isolated on the basis of hypersensitivity to bleomycin and are cross-sensitive to a range of other free radical-generating agents, but exhibit enhanced resistance to neocarzinostatin. A 1-h exposure to equimolar doses of bleomycin induces a similar level of DNA strand breaks in parental CHO-K1 and mutant BLM-1 cells, but a consistently higher level is accumulated by BLM-2 cells. The rate of rejoining of bleomycin-induced single- and double-strand DNA breaks is slower in BLM-2 cells than in CHO-K1 cells. BLM-1 cells show normal strand break repair kinetics. The level of single- and double-strand breaks induced by neocarzinostatin is lower in both BLM-1 and BLM-2 cells than in CHO-K1 cells. The rate of repair of neocarzinostatin-induced strand breaks is normal in BLM-1 cells but retarded somewhat in BLM-2 cells. Thus, there is a correlation between the level of drug-induced DNA damage in BLM-2 cells and the bleomycin-sensitive, neocarzinostatin resistant phenotype of this mutant. Strand breaks induced by both of these agents are also repaired with reduced efficiency by BLM-2 cells. The neocarzinostatin resistance of BLM-1 cells appears to be a consequence of a reduced accumulation of DNA damage. However, the bleomycin-sensitive phenotype of BLM-1 cells does not apparently correlate with any alteration in DNA strand break induction or repair, as analysed by filter elution techniques, suggesting an alternative mechanism of cell killing.     

Differences in Phosphorylated Histone H2AX Foci Formation and Removal of Cells Exposed to Low and High Linear Energy Transfer Radiation

The use of particle ion beams in cancer radiotherapy has a long history. Today, beams of protons or heavy ions, predominantly carbon ions, can be accelerated to precisely calculated energies which can be accurately targeted to tumors. This particle therapy works by damaging the DNA of tissue cells, ultimately causing their death. Among the different types of DNA lesions, the formation of DNA double strand breaks is considered to be the most relevant of deleterious damages of ionizing radiation in cells. It is well-known that the extremely large localized energy deposition can lead to complex types of DNA double strand breaks. These effects can lead to cell death, mutations, genomic instability, or carcinogenesis. Complex double strand breaks can increase the probability of mis-rejoining by NHEJ. As a consequence differences in the repair kinetics following high and low LET irradiation qualities are attributed mainly to quantitative differences in their contributions of the fast and slow repair component. In general, there is a higher contribution of the slow component of DNA double strand repair after exposure to high LET radiation, which is thought to reflect the increased amount of complex DNA double strand breaks. These can be accurately measured by the γ-H2AX assay, because the number of phosphorylated H2AX foci correlates well with the number of double strand breaks induced by low or / and high LET radiation.     

Photodynamic effects of haematoporphyrin derivative on DNA repair in murine L929 fibroblasts.

Illumination with red light of murine L929 fibroblasts that had been sensitized with haematoporphyrin derivative caused DNA single-strand breaks after a lag time of about 20 min, as revealed by alkaline elution. The cells appeared not to be capable of recovering from this damage. The photodynamic effect of haematoporphyrin derivative on DNA repair was assessed by monitoring the repair kinetics of DNA damage induced by either X-rays, u.v. light (254 nm) or methyl methanesulphonate treatment subsequent to a non-DNA-damaging photodynamic treatment with haematoporphyrin derivative. On 'post-incubation', the normally rapid repair of X-ray-induced DNA strand breaks did not occur, whereas with u.v. light and methyl methanesulphonate treatment after photodynamic treatment prolonged post-incubation resulted in an increase in the number of strand breaks rather than the normally observed decrease. This clearly shows that, after a photodynamic treatment with haematoporphyrin derivative that itself did not cause strand breaks, excision repair in L929 cells is severely inhibited at a stage beyond the incision step.     

Poly(ADP-ribose) polymerase-1 modulates DNA repair capacity and prevents formation of DNA double strand breaks

Although poly(ADP-ribose) polymerase-1 (PARP-1) has no enzymatic activity involved in DNA damage processing by the base excision repair (BER) pathway, PARP-1 deficient cells are genetically unstable and sensitive to DNA-damaging agents. To explain this paradox, we investigated the impact of PARP-1 on BER in mammalian cells. We reduced cellular PARP-1 protein levels using siRNA, then introduced DNA damage by hydrogen peroxide treatment and examined the repair response. We find that PARP-1 is not involved in recruitment of the major BER proteins to sites of DNA damage. However, we find that PARP-1 protects excessive DNA single strand breaks (SSBs) from converting into DNA double strand breaks (DSBs) thus preserving them for subsequent repair by BER enzymes. This suggests that PARP-1 plays an important role in BER by extending the ability of BER enzymes to process DNA single strand breaks arising directly after mutagen stress or during processing of DNA lesions following extensive DNA damage.     

Telomeres and the DNA damage response: why the fox is guarding the henhouse

DNA double strand breaks (DSBs) are repaired by an extensive network of proteins that recognize damaged DNA and catalyze its repair. By virtue of their similarity, the normal ends of linear chromosomes and internal DNA DSBs are both potential substrates for DSB repair enzymes. Thus, telomeres, specialized nucleo-protein complexes that cap chromosomal ends, serve a critical function to differentiate themselves from internal DNA strand breaks, and as a result prevent genomic instability that can result from their inappropriate involvement in repair reactions. Telomeres that become critically short due to failure of telomere maintenance mechanisms, or which become dysfunctional by loss of telomere binding proteins, elicit extensive checkpoint responses that in normal cells blocks proliferation. In this situation, the DNA DSB repair machinery plays a major role in responding to these "damaged" telomeres - creating chromosome fusions or capturing telomeres from other chromosomes in an effort to rid the cell of the perceived damage. However, a surprising aspect of telomere maintenance is that many of the same proteins that facilitate this repair of damaged telomeres are also necessary for their proper integrity. Here, we review recent work defining the roles for DSB repair machinery in telomere maintenance and in response to telomere dysfunction.