DNA strand breaks and base modifications induced by cholesterol hydroperoxides

Abstract

Cholesterol (Ch) can be oxidized by reactive oxygen species, forming oxidized products such as Ch hydroperoxides (ChOOH). These hydroperoxides can disseminate the peroxidative stress to other cell compartments. In this work, the ability of ChOOH to induce strand breaks and/or base modifications in a plasmid DNA model was evaluated. In addition, HPLC/MS/MS analyses were performed to investigate the formation of 8-oxo-7,8-dihydro-2′-deoxyguanosine (8-oxodGuo) after the incubation of 2′-deoxyguanosine (dGuo) with ChOOH and Cu²⁺. In the presence of copper ions, ChOOH induced DNA strand breaks in time and concentration-dependent manners. Purine and pyrimidine base modifications were also observed, as assessed respectively by the treatment with Fpg and Endo III repair enzymes. The detection of 8-oxodGuo by HPLC/MS/MS is in agreement with the dGuo oxidation in plasmid DNA. ChOOH-derived DNA damage adds further support to the role of lipid peroxidation in inducing DNA modifications and mutation.     

DNA strand breaks induced by low-energy heavy ions

The DNA unwinding method was used to estimate DNA breakage in Chinese hamster cells exposed to heavy ions with LET in the range of 750-5000 keV/micron. Comparison of the primary induced unwinding rate per dose unit for ions with various track diameters but similar LET showed a pronounced influence on the track diameter. Low-energy ions, producing thin tracks with diameters (penumbra) in the submicrometer region, were almost two orders of magnitude less efficient than more energetic ions producing tracks with diameters of several micrometers and about three orders of magnitude less efficient than X-rays. For the thin tracks, clustering of breaks was indicated by comparison of the DNA unwinding rates in two different alkaline solutions. The results indicate that the unwinding rate cannot be used as a good measurement for DNA breaks in this case. The residual unwinding remaining after 4 h of repair at 37 degrees C correlated well with the ability of the various ions to produce cell-killing.     

Chromosomal aberrations induced by double strand DNA breaks

It has been suggested that introduction of double strand DNA breaks (DSBs) into mammalian chromosomes can lead to gross chromosomal rearrangements through improper DNA repair. To study this phenomenon, we employed a model system in which a double strand DNA break can be produced in human cells in vivo at a predetermined location. The ensuing chromosomal changes flanking the breakage site can then be cloned and characterized. In this system, the recognition site for the I-SceI endonuclease, whose 18 bp recognition sequence is not normally found in the human genome, is placed between a strong constitutive promoter and the Herpes simplex virus thymidine kinase (HSV-tk) gene, which serves as a negative selectable marker. We found that the most common mutation following aberrant DSB repair was an interstitial deletion; these deletions typically showed features of non-homologous end joining (NHEJ), such as microhomologies and insertions of direct or inverted repeat sequences. We also detected more complex rearrangements, including large insertions from adjacent or distant genomic regions. The insertion events that involved distant genomic regions typically represented transcribed sequences, and included both L1 LINE elements and sequences known to be involved in genomic rearrangements. This type of aberrant repair could potentially lead to gene inactivation via deletion of coding or regulatory sequences, or production of oncogenic fusion genes via insertion of coding sequences.     

DNA strand breaks in mammalian tissues induced by methylarsenics

DNA damage induced by administration of dimethylarsinic acid (DMAA) to rats and mice was investigated. At 12 h after administration of DMAA, DNA single-strand breaks were induced markedly in lung. The majority of dimethylarsine, one of the main metabolites, in the expired air was excreted within 6–18 h after administration of DMAA to rats. In vitro experiments using nuclei isolated from lung of mice indicated that DNA strand breaks were caused by dimethylarsine. Furthermore, the strand breaks after exposure to dimethylarsine were reduced in the presence of catalase and/or superoxide dismutase. These results strongly suggest that the strand breaks are induced not by dimethylarsine itself but by active oxygen, e.g., O ₂ ^? and ·OH, produced both by dimethylarsine and molecular oxygen. When DNA was exposed to dimethylarsine, thiobarbituric acid (TBA)-reactive intermediates andcis-thymine glycol were produced. Dimethylarsine appears to induce DNA damage by the mechanism similar to the damage produced by ionizing radiation.     

Methoxyamine potentiates DNA single strand breaks and double strand breaks induced by temozolomide in colon cancer cells

We have previously shown that human cancer cells deficient in DNA mismatch repair (MMR) are resistant to the chemotherapeutic methylating agent temozolomide (TMZ) and can be sensitized by the base excision repair (BER) blocking agent methoxyamine (MX) [21]. To further characterize BER-mediated repair responses to methylating agent-induced DNA damage, we have now evaluated the effect of MX on TMZ-induced DNA single strand breaks (SSB) by alkaline elution and DNA double strand breaks (DSB) by pulsed field gel electrophoresis in SW480 (O6-alkylguanine-DNA-alkyltransferase [AGT]+, MMR wild type) and HCT116 (AGT+, MMR deficient) colon cancer cells. SSB were evident in both cell lines after a 2-h exposure to equitoxic doses of temozolomide. MX significantly increased the number of TMZ-induced DNA-SSB in both cell lines. In contrast to SSB, TMZ-induced DNA-DSB were dependent on MMR status and were time-dependent. Levels of 50 kb double stranded DNA fragments in MMR proficient cells were increased after TMZ alone or in combination with O6-benzylguanine or MX, whereas, in MMR deficient HCT116 cells, only TMZ plus MX produced significant levels of DNA-DSB. Levels of AP endonuclease, XRCC1 and polymerase beta were present in both cell lines and were not significantly altered after MX and TMZ. However, cleavage of a 30-mer double strand substrate by SW480 and HCT116 crude cell extracts was inhibited by MX plus TMZ. Thus, MX potentiation of TMZ cytotoxicity may be explained by the persistence of apurinic/apyrimidinic (AP) sites not further processed due to the presence of MX. Furthermore, in MMR-deficient, TMZ-resistant HCT116 colon cancer cells, MX potentiates TMZ cytotoxicity through formation of large DS-DNA fragmentation and subsequent apoptotic signalling.     

Protection of DNA from gamma-radiation induced strand breaks by Epicatechin

Epicatechin (EC), a polyphenolic antioxidant compound found in tea, apples and chocolate offered protection to DNA against ionizing radiation induced damages. Under in vitro conditions of radiation exposure, plasmid pBR322 DNA was protected by EC in a concentration dependent manner. The dose modifying factor for 0.2 mM EC for 50% protection of the plasmid DNA was found to be 6.0. EC when administered to mice 1 h prior to exposure to 4 Gy gamma-radiation protected cellular DNA against radiation-induced strand breaks in peripheral blood leukocytes, as revealed in alkaline comet assay studies. Thus, EC was found to protect DNA from gamma-radiation indiced strand breaks under in vitro as well as in vivo conditions of radiation exposure.     

Yield of DNA strand breaks after base oxidation of plasmid DNA

We have irradiated aerobic aqueous solutions of plasmid DNA with 137Cs gamma rays in the presence of inorganic radical scavengers including nitrite, iodide, azide, thiocyanate and bromide. These scavengers react with the strongly oxidizing hydroxyl radical (*OH) to produce less powerful oxidants. Of these scavengers, only thiocyanate and bromide result in the formation of oxidizing species [(SCN)2*- and Br2*-, respectively] which are capable of reacting with the bases in DNA. The oxidized bases were detected after incubation of the irradiated plasmid with the two E. coli DNA base excision repair endonucleases, formamidopyrimidine-DNA N-glycosylase and endonuclease III. Depending on the experimental conditions, the intermediate base radicals may ultimately form stable oxidized bases in very high yields (within an order of magnitude of the *OH yield), and possibly also single-strand breaks (SSBs) in much lower yield (between 0.1 and 1% of the total yield of base damage). By competing for (SCN)2*- with an additional species (nitrite), it was possible to estimate the second-order rate constant for the reaction of (SCN)2*- with DNA as 1.6 x 10(4) dm3 mol(-1) s(-1), and also to demonstrate a correlation between the large yield of damaged bases and the much smaller increase in the yield of SSBs over background levels due to *OH. The efficiency of transfer of damage from oxidized base to sugar is estimated as about 0.5% or 5%, depending on whether purine or pyrimidine base radicals are responsible for the base to sugar damage transfer.     

Induction of DNA double strand breaks by arsenite: comparative studies with DNA breaks induced by X-rays

Chinese hamster ovary (CHO-K1) cell line and two of its DNA double strand break (DSB) repair deficient mutant cell lines, xrs-5 (Ku80 mutant) and irs-20 (DNA-PKcs mutant), were treated with various concentrations of sodium arsenite for 2.5h, and the colony forming abilities were studied. The wild type cells showed the highest cell survival, while xrs-5 cells showed the lowest survival, and irs-20 cells had an intermediate survival. These results are very similar to the cell survival curves induced by X-rays in these three cell lines. Our data also show the dose dependent induction of DNA-DSBs in these cell lines exposed to arsenite. However, in order to obtain a similar cell survival in wild type cells, twice as many DNA-DSBs are necessary with arsenite exposure when compared with X-rays, suggesting that the types of DNA lesions leading to DSB induced by arsenite are different from those by X-rays. Based on these data, further mechanistic investigations including the involvement of DNA-DSB repair proteins are warranted in the recovery process from arsenic (As) exposure.     

DNA strand breaks induced by the anti-topoisomerase II bis-dioxopiperazine ICRF-193

The bis-dioxopiperazine ICRF-193 has long time been considered as a pure topoisomerase II catalytic inhibitor able to exert its inhibitory effect on the enzyme without stabilization of the so-called cleavable complex formed by DNA covalently bound to topoisomerase II. In recent years, however, this concept has been challenged, as a number of reports have shown that ICRF-193 really "poisons" the enzyme, most likely through a different mechanism from that shown by the classical topoisomerase II poisons used in cancer chemotherapy. In the present investigation, we have carried out a study of the capacity of ICRF-193 to induce DNA strand breaks, as classical poisons do, in cultured V79 and irs-2 Chinese hamster lung fibroblasts using the comet assay and pulsed-field gel electrophoresis (PFGE). Our results clearly show that ICRF-193 readily induces breakage in DNA through a mechanism as yet poorly understood.     

Three classes of DNA strand breaks induced by X-irradiation and internal beta-rays

Repair kinetics of DNA strand breaks were investigated after exposing exponentially growing CHO cells to X-radiation or to internal beta-rays from incorporated tritium, respectively. DNA strand breaks were analysed by the alkaline unwinding technique followed by chromatography on hydroxyapatite. For either type of radiation, the repair kinetics are statistically best described by a sum of three exponential components. The half-times determined are tau I approximately 2 min, tau II approximately 20 min and tau III approximately 170 min; they are identical for both types of radiation. But the initial fractions of the components are different for X- and internal beta-rays; X-rays; fI = 0.70, fII = 0.25, fIII = 0.05; internal beta-rays: fI = 0.40, fII = 0.40, fIII = 0.20. Components I and II are considered to represent the repair of two different classes of single-strand breaks and component III the repair of double-strand breaks. Two alternative interpretations for the occurrence of the two classes of single-strand breaks are discussed.     

Elaboration of cellular DNA breaks by hydroperoxides.

Cellular damage produced by ionizing radiation and peroxides, hydrogen peroxide (HOOH) and the organic peroxides tert-butyl (tBuOOH) or cumene hydroperoxide (CuOOH) were compared. DNA breaks, toxicity, malondialdehyde production, and the rate of peroxide disappearance were measured in a human adenocarcinoma cell line (A549). The alkaline and neutral filter elution assays were used to quantitate the kinetics of single and double strand break formation and repair (SSB and DSB), respectively. Peroxides, at 0.01-1.0 mM, produce multiphasic dose response curves for both toxicity and DNA SSBs. Radiation, 1-6 Gy, produced a shouldered survival curve, and both DNA SSB and DSBs produced in cells x-rayed on ice were nearly linear with dose. The peroxides produced more SSBs than radiation at equitoxic doses. X-ray induced DNA single strand breaks were rejoined rapidly by cells at 37 degrees C with approximately 80% of initial damage repaired in 20 min. Peroxide induced SSBs were maximal after 15 min at 37 degrees C. Rejoining proceeded thereafter, but at a rate less than for x-ray induced strand breaks. Significant DNA DSBs could not be achieved by peroxides even at concentrations 50-fold higher than required to produce SSBs. HOOH treatment of DNA on filters following cell lysis and proteolysis produced SSBs. CuOOH and tBuOOH produced no SSBs in lysed cell DNA. None of the peroxides produced DSBs when incubated with lysed cell DNA. Malondialdehyde was released from cells incubated with organic hydroperoxides, but not HOOH, nor up to 40 Gy of x-rays. HOOH was metabolized three times faster than the organic peroxides. The overall results demonstrate the necessity for a metabolically active cell environment to elaborate maximal DNA strand breaks and cell death at hydroperoxide concentrations of 10(-4) or greater, but prevent strand breaks and stimulate cell growth at 10(-5) M.     

Reduction in free-radical-induced DNA strand breaks and base damage through fast chemical repair by flavonoids

This paper provides evidence that dietary flavonoids can repair a range of oxidative radical damages on DNA, and thus give protection against radical-induced strand breaks and base alterations. We have irradiated dilute aqueous solutions of plasmid DNA in the absence and presence of flavonoids (F) in a "constant *OH radical scavenging environment", k of 1.5 x 10(7) s(-1) by decreasing the concentration of TRIS buffer in relation to the concentration of added flavonoids. We have shown that the flavonoids can reduce the incidence of single-strand breaks in double-stranded DNA as well as residual base damage (assayed as additional single-strand breaks upon post-irradiation incubation with endonucleases) with dose modification factors of up to 2.0+/-0.2 at [F] < 100 microM by a mechanism other than through direct scavenging of *OH radicals. Pulse radiolysis measurements support the mechanism of electron transfer or H* atom transfer from the flavonoids to free radical sites on DNA which result in the fast chemical repair of some of the oxidative damage on DNA resulting from *OH radical attack. These in vitro assays point to a possible additional role for antioxidants in reducing DNA damage.     

Reduction in free-radical-induced DNA strand breaks and base damage through fast chemical repair by flavonoids

This paper provides evidence that dietary flavonoids can repair a range of oxidative radical damages on DNA, and thus give protection against radical-induced strand breaks and base alterations. We have irradiated dilute aqueous solutions of plasmid DNA in the absence and presence of flavonoids (F) in a “constant ^·OH radical scavenging environment”, k of 1.5 × 10⁷ s^-1 by decreasing the concentration of TRIS buffer in relation to the concentration of added flavonoids. We have shown that the flavonoids can reduce the incidence of single-strand breaks in double-stranded DNA as well as residual base damage (assayed as additional single-strand breaks upon post-irradiation incubation with endonucleases) with dose modification factors of up to 2.0 ± 0.2 at [F] < 100 μM by a mechanism other than through direct scavenging of ^·OH radicals. Pulse radiolysis measurements support the mechanism of electron transfer or H^· atom transfer from the flavonoids to free radical sites on DNA which result in the fast chemical repair of some of the oxidative damage on DNA resulting from ^·OH radical attack. These in vitro assays point to a possible additional role for antioxidants in reducing DNA damage.     

Deciphering the chromatin landscape induced around DNA double strand breaks

DNA double strand breaks (DSBs) are among the most deleterious forms of lesions and deciphering the details of the chromatin landscape induced around DSBs represents a great challenge for molecular biologists.

Chromatin Immunoprecipitation, followed by microarray hybridisation (ChIP-chip) or high-throughput sequencing (ChIP-seq), are powerful techniques that provide high-resolution maps of protein-genome interactions. However, applying these techniques to study chromatin changes induced around DSBs was previously hindered due to a lack of suitable DSB induction techniques.

We have recently developed an experimental system utilizing a restriction enzyme fused to a modified oestrogen receptor ligand binding domain (AsiSI-ER), which generates multiple, sequence-specific and unambiguously positioned DSBs across the genome upon induction with 4-hydroxytamoxifen (4OHT) ¹. Cell lines expressing this construct represent a powerful tool to study specific chromatin changes during DSB repair, enabling high-resolution profiling of DNA repair complexes and chromatin modifications induced around DSBs. Using this system, we have recently produced the first map of gH2AX, a DSB-induced chromatin modification, on two human chromosomes and have investigated its spreading properties ¹. Here we provide additional data characterizing the cell lines, present a genome-wide profile of gH2AX obtained by ChIP-seq, and discuss the potential of our system towards investigations of previously uncharacterized aspects of DSB repair.     

Protective effect of magnesium on DNA strand breaks induced by nickel or cadmium

Magnesium, an essential metal that is important in the normal functioning of DNA, has been shown to interact with some of the toxic heavy metals in respect to biochemical and molecular mechanisms and in altering the tumorigenic process. This study examined the influence of magnesium in combination with nickel and cadmium in respect to damage of the DNA molecule. The purpose of this study was to evaluate the influence of magnesium on the amelioration of the toxic metals nickel and cadmium in respect to sustaining DNA damage. Two types of lymphocytes were used, i.e., primary Fischer 344 rat splenocytes and AHH-1 TK+/-, a human B-lymphoblastoid cell line that has been spontaneously transformed. These cells were grown in either a magnesium-free or magnesium-supplemented RPMI 1640 medium that was specifically formulated for this study. A 2x2 factorial design was employed with magnesium and either nickel or cadmium serving as the two factors. The experimental groups were as follows: +Mg+Ni, +Mg–Ni, –Mg+Ni, –Mg–Ni, with cadmium alternating for the nickel in the subsequent studies. The nickel or cadmium was added at a concentration of 50 mol/L. The presence of double-stranded DNA was determined in each of the respective treatment groups with the two types of cell lines. Based on the results of this study, nickel is not directly toxic to DNA, whereas cadmium produces damage directly on the DNA molecule. The magnesium has little or no direct influence on the occurrence of DNA damage from nickel since the toxicity of nickel appears to be manifested in areas other than the DNA molecule, such as in the heterochromatin. The presence of cadmium in the treatment group resulted in DNA damage, which in turn was reduced significantly by the presence of magnesium.Abbreviations ds DNA double-stranded DNA - i.p. intraperitoneally     

Radiation induced DNA double strand breaks are rejoined by ligation and recombination processes.

Using the method of filter elution of double stranded DNA under neutral conditions we have shown that most of gamma-ray induced double strand breaks (DSB) are rejoined in both mammalian and bacterial cells. Rejoining also occurs in the G1 phase in V79 Chinese hamster cells and under different growth conditions. Within 8 minutes at 37 C, half the breaks are rejoined. The rejoining in E. coli is equally fast and depends on the presence of DNA ligase. Some of the breaks in E. coli rejoin slowly, and these require rec+. The non-rejoined DSB are distributed over the DNA without any preference for the nucleosomal or the linker structure in the chromosome. Two kinds of DSB rejoining are discriminated, a fast process of DNA ligation and a slower process involving rec functions.     

Lethal and mutagenic lesions induced by ionizing radiations inE. coli and DNA strand breaks

Summary The inactivation doses forE. coli exposed to alpha particles and protons of different LETs and to gamma rays have been measured. Strains derived fromE. coli B/r showed a maximum sensitivity at LETs of 30 keV/ whilst B_s–1 and other strains known to be deficient in repair capacity had sensitivities which decreased monotonically with increasing LET. These results can be interpreted in terms of two types of lethal damage to the bacterial genome. Damage of type 1 affects only one strand of the DNA macromolecule and is partially reparablein vivo whilst damage of type 2, inflicted by one track intersection of the DNA, is irreparable. The identity of both types of damage is uncertain but type 1 probably gives rise to a lesion recognizablein vitro as a single strand break. Type 2 damage probably corresponds to double strand scission of DNA as observedin vitro.Mutations to prototrophy of three auxotrophic strains ofE. coli are induced with an effectiveness which decreases steadily with increasing LET. This form of LET dependence implies that these mutations involve damage to one target only, probably one strand of the DNA duplex.Paper read at the 6th Annual Meeting of the European Society for Radiobiology, Interlaken, 5.–8. June, 1968. Round Table: Radiation Effectsin vitro andin vivo. Correlations and Discrepancies.     

Characterization of intracellular DNA strand breaks induced by neocarzinostatin in Escherichia coli cells.

DNA strand breaks induced by Neocarzinostatin in Escherichia coli cells have been characterized. Radioactively labeled phage lambda DNA was introduced into lysogenic host bacteria allowing the phage DNA to circularize into superhelical molecules. After drug treatment DNA single- and double-strand breaks were measured independently after neutral sucrose gradient sedimentation. The presence of alkali-labile lesions was measured in parallel in alkaline sucrose gradients. The cell envelope provided an efficient protection towards the drug, since no strand breaks were detected unless the cells were made permeable with toluene or with hypotonic Tris buffer. In permeable cells, no double strand breaks could be detected, even at high NCS concentration (100 micrograms/ml). Induction of single-strand breaks leveled off after 15 min at 20 degrees C in the presence of 2 mM mercaptoethanol. Exposure to 0.3N NaOH doubled the number of strand breaks. No enzymatic repair of the breaks could be observed.