High efficiency detection of bi-stranded abasic clusters in gamma-irradiated DNA by putrescine

Bi-stranded abasic clusters, an abasic (AP) site on one DNA strand and another nearby AP site or strand break on the other, have been quantified using Nfo protein from Escherichia coli to produce a double-strand break at cluster sites. Since recent data suggest that Nfo protein cleaves inefficiently at some clusters, we tested whether polyamines, which also cut at AP sites, would cleave abasic clusters at higher efficiency. The data show that Nfo protein cleaves poorly at clusters containing immediately opposed AP sites and those separated by 1 or 3 bp. Putrescine (PUTR) cleaved more efficiently than spermidine or spermine, and did not cleave undamaged DNA. It cleaved abasic clusters in oligonucleotide duplexes more effectively than Nfo protein, including immediately opposed or closely spaced clusters. PUTR cleaved more efficiently than Nfo protein by a factor of ~1.7 or ~2 for DNA that had been γ-irradiated in moderate or non-radioquenching conditions, respectively. This suggests that the DNA environment during irradiation affects the spectrum of cluster configurations. Further comparison of PUTR and Nfo protein cleavage may provide useful information on abasic cluster levels and configurations induced by ionizing radiation.     

Are endogenous clustered DNA damages induced in human cells?

Although clustered DNA damages are induced in cells by ionizing radiation and can be induced artifactually during DNA isolation, it was not known if they are formed in unirradiated cells by normal oxidative metabolism. Using high-sensitivity methods of quantitative gel electrophoresis, electronic imaging, and number average length analysis, we found that two radiosensitive human cell lines (TK6 and WI-L2-NS) accumulated Fpg-oxidized purine clusters and Nth-oxidized pyrimidine clusters but not Nfo-abasic clusters. However, four repair-proficient human lines (MOLT 4, HL-60, WTK1, and 28SC) did not contain significant levels (<5/Gbp) of any cluster type. Cluster levels were independent of p53 status. Measurement of glycosylase levels in 28SC, TK6, and WI-L2-NS cells suggested that depressed hOGG1 and hNth activities in TK6 and WI-L2-NS could be related to oxybase cluster accumulation. Thus, individuals with DNA repair enzyme deficiencies could accumulate potentially cytotoxic and mutagenic clustered DNA damages. The absence of Nfo-detected endogenous clusters in any cells examined suggests that abasic clusters could be a signature of cellular ionizing radiation exposure.     

Clustered DNA damages induced by x rays in human cells

Although DNA DSBs are known to be important in producing the damaging effects of ionizing radiation in cells, bistranded clustered DNA damages-two or more oxidized bases, abasic sites or strand breaks on opposing DNA strands within a few helical turns-are postulated to be difficult to repair and thus to be critical radiation-induced lesions. Gamma rays can induce clustered damages in DNA in solution, and high-energy iron ions produce DSBs and oxidized pyrimidine clusters in human cells, but it was not known whether sparsely ionizing radiation can produce clustered damages in mammalian cells. We show here that X rays induce abasic clusters, oxidized pyrimidine clusters, and oxidized purine clusters in DNA in human cells. Non-DSB clustered damages comprise about 70% of the complex lesions produced in cells. The relative levels of specific cluster classes depend on the environment of the DNA.     

Human abasic endonuclease action on multilesion abasic clusters: implications for radiation-induced biological damage

Clustered damages—two or more closely opposed abasic sites, oxidized bases or strand breaks—are induced in DNA by ionizing radiation and by some radiomimetic drugs. They are potentially mutagenic or lethal. High complexity, multilesion clusters (three or more lesions) are hypothesized as repair-resistant and responsible for the greater biological damage induced by high linear energy transfer radiation (e.g. charged particles) than by low linear energy transfer X- or γ-rays. We tested this hypothesis by assessing human abasic endonuclease Ape1 activity on two- and multiple-lesion abasic clusters. We constructed cluster-containing oligonucleotides using a central variable cassette with abasic site(s) at specific locations, and 5′ and 3′ terminal segments tagged with visually distinctive fluorophores. The results indicate that in two- or multiple-lesion clusters, the spatial arrangement of uni-sided positive [in which the opposing strand lesion(s) is 3′ to the base opposite the reference lesion)] or negative polarity [opposing strand lesion(s) 5′ to the base opposite the reference lesion] abasic clusters is key in determining Ape1 cleavage efficiency. However, no bipolar clusters (minimally three-lesions) were good Ape1 substrates. The data suggest an underlying molecular mechanism for the higher levels of biological damage associated with agents producing complex clusters: the induction of highly repair-resistant bipolar clusters.     

Processing of abasic DNA clusters in hApeI-silenced primary fibroblasts exposed to low doses of X-irradiation

Clustered damage in DNA includes two or more closely spaced oxidized bases, strand breaks or abasic sites that are induced by high- or low-linear-energy-transfer (LET) radiation, and these have been found to be repair-resistant and potentially mutagenic. In the present study we found that abasic clustered damages are also induced in primary human fibroblast cells by low-LET X-rays even at very low doses. In response to the induction of the abasic sites, primary fibroblasts irradiated by low doses of X-rays in the range 10–100 cGy showed dose-dependent up-regulation of the DNA repair enzyme, ApeI. We found that the abasic clusters in primary fibroblasts were more lethal to cells when hApeI enzyme expression was down-regulated by transfecting primary fibroblasts with hApeI siRNA as determined by clonogenic survival assay. Endonuclease activity of hApeI was found to be directly proportional to hApeI gene-silencing efficiency. The DNA repair profile showed that processing of abasic clusters was delayed in hApeI-siRNA-silenced fibroblasts, which challenges the survival of the cells even at very low doses of X-rays. Thus, the present study is the first to attempt to understand the induction of cluster DNA damage at very low doses of low-LET radiation in primary human fibroblasts and their processing by DNA repair enzyme ApeI and their relation with the survival of the cells.     

Bistranded oxidized purine damage clusters: induced in DNA by long-wavelength ultraviolet (290-400 nm) radiation?

Bistranded clustered DNA damages involving oxidized bases, abasic sites, and strand breaks are produced by ionizing radiation and radiomimetic drugs, but it was not known whether they can be formed by other agents, e.g., nonionizing radiation. UV radiation produces clusters of cyclobutyl pyrimidine dimers, photoproducts that occur individually in high yield. Since long-wavelength UV (290-400 nm) radiation induces oxidized bases, abasic sites, and strand breaks at low yields, we tested whether it also produces clusters containing these lesions. We exposed supercoiled pUC18 DNA to UV radiation with wavelengths of >290 nm (UVB plus UVA radiation), and assessed the induction of bistranded clustered oxidized purine and abasic clusters, as recognized by Escherichia coli Fpg protein and E. coli Nfo protein (endonuclease IV), respectively, as well as double-strand breaks. These three classes of bistranded clusters were detected, albeit at very low yields (37 Fpg-OxyPurine clusters Gbp(-1) kJ(-1) m(2), 8.1 double-strand breaks Gbp(-1) kJ(-1) m(2), and 3.4 Nfo-abasic clusters Gbp(-1) kJ(-1) m(2)). Thus, these bistranded OxyPurine clusters, abasic clusters, and double-strand breaks are not uniquely induced by ionizing radiation and radiomimetic drugs, but their level of production by UVB and UVA radiation is negligible compared to the levels of frequent photoproducts such as pyrimidine dimers.     

Clustered damages and total lesions induced in DNA by ionizing radiation: oxidized bases and strand breaks

Ionizing radiation induces both isolated DNA lesions and clustered damages-multiple closely spaced lesions (strand breaks, oxidized purines, oxidized pyrimidines, or abasic sites within a few helical turns). Such clusters are postulated to be difficult to repair and thus potentially lethal or mutagenic lesions. Using highly purified enzymes that cleave DNA at specific classes of damage and electrophoretic assays developed for quantifying isolated and clustered damages in high molecular length genomic DNAs, we determined the relative frequencies of total lesions and of clustered damages involving both strands, and the composition and origin of such clusters. The relative frequency of isolated vs clustered damages depends on the identity of the lesion, with approximately 15-18% of oxidized purines, pyrimidines, or abasic sites in clusters recognized by Fpg, Nth, or Nfo proteins, respectively, but only about half that level of frank single strand breaks in double strand breaks. Oxidized base clusters and abasic site clusters constitute about 80% of complex damages, while double strand breaks comprise only approximately 20% of the total. The data also show that each cluster results from a single radiation (track) event, and thus clusters will be formed at low as well as high radiation doses.     

Low levels of endogenous oxidative damage cluster levels in unirradiated viral and human DNAs

Ionizing radiation induces bistranded DNA damage clusters-two or more oxidized bases, abasic, sites or strand breaks on opposing strands within a few helical turns-but it is not known if clusters are also formed in unirradiated DNA in solution or in unirradiated cultured human cells. The frequencies of endogenous oxidized purine clusters (recognized by Escherichia coli Fpg protein), oxidized pyrimidine clusters (recognized by Nth protein), and abasic clusters (cleavage by Nfo protein) were determined using quantitative gel electrophoresis, electronic imaging, and number average length analysis. Methods of DNA isolation and storage were found to affect cluster levels significantly. In bacteriophage T7 DNA prepared using stringent conditions, the frequencies of these clusters were <1/Mbp. In DNA from unirradiated human 28SC monocytes, the levels of such clusters were, at most, a few per gigabase pair.     

Processing of thymine glycol in a clustered DNA damage site: mutagenic or cytotoxic

Localized clustering of damage is a hallmark of certain DNA-damaging agents, particularly ionizing radiation. The potential for genetic change arising from the effects of clustered damage sites containing combinations of AP sites, 8-oxo-7,8-dihydroguanine (8-oxoG) or 5,6-dihydrothymine is high. To date clusters containing a DNA base lesion that is a strong block to replicative polymerases, have not been explored. Since thymine glycol (Tg) is non-mutagenic but a strong block to replicative polymerases, we have investigated whether clusters containing Tg are highly mutagenic or lead to potentially cytotoxic lesions, when closely opposed to either 8-oxoG or an AP site. Using a bacterial plasmid-based assay and repair assays using cell extracts or purified proteins, we have shown that DNA double-strand breaks (DSBs) arise when Tg is opposite to an AP site, either through attempted base excision repair or at replication. In contrast, 8-oxoG opposite to Tg in a cluster ‘protects’ against DSB formation but does enhance the mutation frequency at the site of 8-oxoG relative to that at a single 8-oxoG, due to the decisive role of endonucleases in the initial stages of processing Tg/8-oxoG clusters, removing Tg to give an intermediate with an abasic site or single-strand break.     

The role of DNA polymerase beta in determining sensitivity to ionizing radiation in human tumor cells

Lethal lesions after ionizing radiation are thought to be mainly unrepaired or misrepaired DNA double-strand breaks, ultimately leading to lethal chromosome aberrations. However, studies with radioprotectors and repair inhibitors indicate that single-strand breaks, damaged nucleotides or abasic sites can also influence cell survival. This paper reports on studies to further define the role of base damage and base excision repair on the radiosensitivity of human cells. We retrovirally transduced human tumor cells with a dominant negative form of DNA polymerase β, comprising the 14 kDa DNA-binding domain of DNA polymerase β but lacking polymerase function. Radiosensitization of two human carcinoma cell lines, A549 and SQD9, was observed, achieving dose enhancement factors of 1.5–1.7. Sensitization was dependent on expression level of the dominant negative and was seen in both single cell clones and in unselected virally transduced populations. Sensitization was not due to changes in cell cycle distribution. Little or no sensitization was seen in G₁-enriched populations, indicating cell cycle specificity for the observed sensitization. These results contrast with the lack of effect seen in DNA polymerase β knockout cells, suggesting that polDN also inhibits the long patch, DNA polymerase β-independent repair pathway. These data demonstrate an important role for BER in determining sensitivity to ionizing radiation and might help identify targets for radiosensitizing tumor cells.     

Endogenous DNA damage clusters in human hematopoietic stem and progenitor cells

Clustered DNA damages-multiple oxidized bases, abasic sites, or strand breaks within a few helical turns-are potentially mutagenic and lethal alterations induced by ionizing radiation. Endogenous clusters are found at low frequencies in unirradiated normal human cells and tissues. Radiation-sensitive hematopoietic cells with low glycosylase levels (TK6 and WI-L2-NS) accumulate oxidized base clusters but not abasic clusters, indicating that cellular repair genotype affects endogenous cluster levels. We asked whether other factors, i.e., in the cellular microenvironment, affect endogenous cluster levels and composition in hematopoietic cells. TK6 and WI-L2-NS cells were grown in standard medium (RPMI 1640) alone or supplemented with folate and/or selenium; oxidized base cluster levels were highest in RPMI 1640 and reduced in selenium-supplemented medium. Abasic clusters were low under all conditions. In primary hematopoietic stem and progenitor cells from four non-tobacco-using donors, cluster levels were low. However, in cells from tobacco users, we observed high oxidized base clusters and also abasic clusters, previously observed only in irradiated cells. Protein levels and activity of the abasic endonuclease Ape1 were similar in the tobacco users and nonusers. These data suggest that in highly damaging environments, even normal DNA repair capacity can be overwhelmed, leaving highly repair-resistant clustered damages.     

Condensation of DNA—A putative obstruction for repair process in abasic clustered DNA damage

Clustered DNA damages are defined as two or more closely located DNA damage lesions that may be present within a few helical turns of the DNA double strand. These damages are potential signatures of ionizing radiation and are often found to be repair resistant. Types of damaged lesions frequently found inside clustered DNA damage sites include oxidized bases, abasic sites, nucleotide dimers, strand breaks or their complex combinations. In this study, we used a bistranded two-lesion abasic cluster DNA damage model to access the repair process of DNA in condensate form.Oligomer DNA duplexes (47 bp) were designed to have two deoxyuridine in the middle of the sequences, three bases apart in opposite strands. The deoxyuridine residues were converted into abasic sites by treatment with UDG enzyme creating an abasic clustered damage site in a precise position in each of the single strand of the DNA duplex. This oligomer duplex having compatible cohesive ends was ligated to pUC19 plasmid, linearized with HindIII restriction endonuclease. The plasmid–oligomer conjugate was transformed into condensates by treating them with spermidine. The efficiency of strand cleavage action of ApeI enzyme on the abasic sites was determined by denaturing PAGE after timed incubation of the oligomer duplex and the oligomer–plasmid conjugate in presence and absence of spermidine. The efficiency of double strand breaks was determined similarly by native PAGE. Quantitative gel analysis revealed that rate of abasic site cleavage is reduced in the DNA condensates as compared to the oligomer DNA duplex or the linear ligated oligomer–plasmid conjugates. Generation of double strand break is significantly reduced also, suggesting that their creation is not proportionate to the number of abasic sites cleaved in the condensate model. All these suggest that the ApeI enzyme have difficulty to access the abasic sites located deep into the condensates leading to repair refractivity of the damages. In addition, we found that presence of a polyamine such as spermidine has no notable effect in the incision activity of ApeI enzyme in linear oligomer DNA duplexes in our experimental concentration.     

Mechanism of cluster DNA damage repair in response to high-atomic number and energy particles radiation

Low-linear energy transfer (LET) radiation (i.e., γ- and X-rays) induces DNA double-strand breaks (DSBs) that are rapidly repaired (rejoined). In contrast, DNA damage induced by the dense ionizing track of high-atomic number and energy (HZE) particles is slowly repaired or is irreparable. These unrepaired and/or misrepaired DNA lesions may contribute to the observed higher relative biological effectiveness for cell killing, chromosomal aberrations, mutagenesis, and carcinogenesis in HZE particle irradiated cells compared to those treated with low-LET radiation. The types of DNA lesions induced by HZE particles have been characterized in vitro and usually consist of two or more closely spaced strand breaks, abasic sites, or oxidized bases on opposing strands. It is unclear why these lesions are difficult to repair. In this review, we highlight the potential of a new technology allowing direct visualization of different types of DNA lesions in human cells and document the emerging significance of live-cell imaging for elucidation of the spatio-temporal characterization of complex DNA damage. We focus on the recent insights into the molecular pathways that participate in the repair of HZE particle-induced DSBs. We also discuss recent advances in our understanding of how different end-processing nucleases aid in repair of DSBs with complicated ends generated by HZE particles. Understanding the mechanism underlying the repair of DNA damage induced by HZE particles will have important implications for estimating the risks to human health associated with HZE particle exposure.     

Endogenous DNA damage clusters in human skin, 3-D model, and cultured skin cells

Clustered damages-two or more oxidized bases, abasic sites, or strand breaks on opposing DNA strands within a few helical turns-are formed in DNA by ionizing radiation. Clusters are difficult for cells to repair and thus pose significant challenges to genomic integrity. Although endogenous clusters were found in some permanent human cell lines, it was not known if clusters accumulated in human tissues or primary cells. Using high-sensitivity gel electrophoresis, electronic imaging, and number average length analysis, we determined endogenous cluster levels in DNA from human skin, a 3-D skin model, and primary cultured skin cells. DNA from dermis and epidermis of human skin contained extremely low levels of endogenous clusters (a few per gigabase). However, cultured skin fibroblasts and keratinocytes-whether in monolayer cultures or in 3-D model skin cultures-accumulated oxidized pyrimidine, oxidized purine, and abasic clusters. The levels of endogenous clusters were decreased by growing cells in the presence of selenium or by increasing cellular levels of Fpg protein, presumably by increasing processing of clustered damages. These results imply that the levels of endogenous clusters can be affected by the cells' external environment and their ability to deal with DNA damage.     

Spectrum of complex DNA damages depends on the incident radiation

Ionizing radiation induces bistranded clustered damages--two or more abasic sites, oxidized bases and strand breaks on opposite DNA strands within a few helical turns. Since clusters are refractory to repair and are potential sources of double-strand breaks (DSBs), they are potentially lethal and mutagenic. Although induction of single-strand breaks (SSBs) and isolated lesions has been studied extensively, little is known about the factors affecting induction of clusters other than DSBs. To determine whether the type of incident radiation could affect the yields or spectra of specific clusters, we irradiated genomic T7 DNA, a simple 40-kbp linear, blunt-ended molecule, with ion beams [iron (970 MeV/nucleon), carbon (293 MeV/nucleon), titanium (980 MeV/nucleon), silicon (586 MeV/nucleon), protons (1 GeV/nucleon)] or 100 kVp X rays and then quantified DSBs, Fpg-oxypurine clusters and Nfo-abasic clusters using gel electrophoresis, electronic imaging and number average length analysis. The yields (damages/Mbp Gy(-1)) of all damages decreased with increasing linear energy transfer (LET) of the radiation. The relative frequencies of DSBs compared to abasic and oxybase clusters were higher for the charged particles-including the high-energy, low-LET protons-than for the ionizing photons.     

Securing genome stability by orchestrating DNA repair: removal of radiation-induced clustered lesions in DNA

In addition to double- and single-strand DNA breaks and isolated base modifications, ionizing radiation induces clustered DNA damage, which contains two or more lesions closely spaced within about two helical turns on opposite DNA strands. Post-irradiation repair of single-base lesions is routinely performed by base excision repair and a DNA strand break is involved as an intermediate. Simultaneous processing of lesions on opposite DNA strands may generate double-strand DNA breaks and enhance nonhomologous end joining, which frequently results in the formation of deletions. Recent studies support the possibility that the mechanism of base excision repair contributes to genome stability by diminishing the formation of double-strand DNA breaks during processing of clustered lesions.     

Double-strand DNA break formation mediated by flap endonuclease-1

Double-strand DNA breaks are the most lethal type of DNA damage induced by ionizing radiations. Previously, we reported that double-strand DNA breaks can be enzymatically produced from two DNA damages located on opposite DNA strands 18 or 30 base pairs apart in a cell-free double-strand DNA break formation assay (Vispé, S., and Satoh, M. S. (2000) J. Biol. Chem. 275, 27386-27392). In the assay that we developed, these two DNA damages are converted into single-strand interruptions by enzymes involved in base excision repair. We showed that these single-strand interruptions are converted into double-strand DNA breaks; however, it was not due to spontaneous denaturation of DNA. Thus, we proposed a model in which DNA polymerase delta/epsilon, by producing repair patches at single-strand interruptions, collide, resulting in double-strand DNA break formation. We tested the model and investigated whether other enzymes/factors are involved in double-strand DNA break formation. Here we report that, instead of DNA polymerase delta/epsilon, flap endonuclease-1 (FEN-1), an enzyme involved in base excision repair, is responsible for the formation of double-strand DNA break in the assay. Furthermore, by transfecting a flap endonuclease-1 expression construct into cells, thus altering their flap endonuclease-1 content, we found an increased number of double-strand DNA breaks after gamma-ray irradiation of these cells. These results suggest that flap endonuclease-1 acts as a double-strand DNA break formation factor. Because FEN-1 is an essential enzyme that plays its roles in DNA repair and DNA replication, DSBs may be produced in cells as by-products of the activity of FEN-1.     

Involvement of DNA polymerase beta in repair of ionizing radiation damage as measured by in vitro plasmid assays

Characteristic of damage introduced in DNA by ionizing radiation is the induction of a wide range of lesions. Single-strand breaks (SSBs) and base damages outnumber double-strand breaks (DSBs). If unrepaired, these lesions can lead to DSBs and increased mutagenesis. XRCC1 and DNA polymerase beta (polbeta) are thought to be critical elements in the repair of these SSBs and base damages. XRCC1-deficient cells display a radiosensitive phenotype, while proliferating polbeta-deficient cells are not more radiosensitive. We have recently shown that cells deficient in polbeta display increased radiosensitivity when confluent. In addition, cells expressing a dominant negative to polbeta have been found to be radiosensitized. Here we show that repair of radiation-induced lesions is inhibited in extracts with altered polbeta or XRCC1 status, as measured by an in vitro repair assay employing irradiated plasmid DNA. Extracts from XRCC1-deficient cells showed a dramatically reduced capacity to repair ionizing radiation-induced DNA damage. Extracts deficient in polbeta or containing a dominant negative to polbeta also showed reduced repair of radiation-induced SSBs. Irradiated repaired plasmid DNA showed increased incorporation of radioactive nucleotides, indicating use of an alternative long-patch repair pathway. These data show a deficiency in repair of ionizing radiation damage in extracts from cells deficient or altered in polbeta activity, implying that increased radiosensitivity resulted from radiation damage repair deficiencies.     

Non-homologous end-joining defect in fanconi anemia hematopoietic cells exposed to ionizing radiation

Fanconi anemia is a genetically heterogeneous recessive disease characterized mainly by bone marrow failure and cancer predisposition. Although it is accepted that Fanconi cells are highly sensitive to DNA crosslinking agents, their response to ionizing radiation is still unclear. Using pulsed-field gel electrophoresis, we have observed that radiation generates a similar number of DNA double-strand breaks in normal and Fanconi cells from three (FA-A, FA-C and FA-F) of the 11 complementation groups identified. Nonsynchronized as well as nonproliferating Fanconi anemia cells showed an evident defect in rejoining the double-strand breaks generated by ionizing radiation, indicating defective non-homologous end-joining repair. At the cellular level, no difference in the radiosensitivity of normal and FA-A lymphoblast cells was noted, and a modest increase in the radiosensitivity of Fanca-/- hematopoietic progenitor cells was observed compared to Fanca+/+ cells. Finally, when animals were exposed to a fractionated total-body irradiation of 5 Gy, a similar hematopoietic syndrome was observed in wild-type and Fanca-/- mice. Taken together, our observations suggest that Fanconi cells, in particular those having nonfunctional Fanconi proteins upstream of FANCD2, have a defect in the non-homologous end-joining repair of double-strand breaks produced by ionizing radiation, and that compensatory mechanisms of DNA repair and/or stem cell regeneration should limit the impact of this defect in irradiated organisms.     

Processing of DNA damage clusters in human cells: current status of knowledge

Eukaryotic cells exposed to DNA damaging agents activate important defensive pathways by inducing multiple proteins involved in DNA repair, cell cycle checkpoint control and potentially apoptosis. After the acceptance of the hypothesis that oxidatively generated clustered DNA lesions (OCDL: closely spaced DNA lesions) can be induced even by low doses of ionizing radiation or even endogenously, and significant advances have been made in the understanding of the biochemistry underlying the repair of closely spaced DNA lesions, many questions still remain unanswered. The major questions that have to be answered in the near future are: 1) how human cells process these types of DNA damage if they repair them at all, 2) under what conditions a double strand break (DSB) may be created during the processing of two closely spaced DNA lesions and 3) what type of repair protein interactions govern the processing of complex DNA damage? The data existing so far on human cells and tissues are very limited and in some cases contradicting. All of them though agree however on the major importance of gaining mechanistic insights on the pathways used by the cell to confront and process complex DNA damage located in a small DNA volume and the need of more in depth analytical studies. We selectively review recently-obtained data on the processing of non-DSB DNA damage clusters in human cells and tissues and discuss the current status of knowledge in the field.