Influence of cellular differentiation on repair of ultraviolet-induced DNA damage in murine proadipocytes

The effects of cellular differentiation on the repair of DNA damage induced by uv radiation were investigated in the murine 3T3-T proadipocyte cell culture system. Upon exposure to human plasma, actively cycling 3T3-T cells (stem cells) undergo growth arrest, which is followed by terminal differentiation into lipid-laden adipocytes. In response to uv irradiation, the level of unscheduled DNA synthesis is significantly lower in adipocytes as compared to stem cells. The alkaline elution assay was used to monitor the appearance of repair-induced strand breaks in 3T3-T cells after uv irradiation. DNA strand breaks were detected in stem cells by 4 min post-uv with essentially no further increase after 8 min. When terminally differentiated adipocytes were irradiated and allowed to repair, however, more strand breaks were present at 4 min and, in marked contrast to stem cells, continued to accumulate in adipocytes for at least 16 min post-uv. Inhibition of repair-replication with hydroxyurea and cytosine arabinoside significantly increased accumulation of repair-induced strand breaks in stem cells, yet had little effect on this accumulation in adipocytes. For stem cells and adipocytes, incision activity was linear out to at least 10 Jm-2 without saturation. These data suggested that 3T3-T cell differentiation is accompanied by a defect in some postincision process of the excision-repair pathway.     

A hydroxylapatite batch assay for quantitation of cellular DNA damage.

A batch elution procedure is described for quantitative measurement of DNA damage. The technique is based on alkaline unwinding of cellular DNA and separation of singlestranded from duplex forms by step elution from hydroxylapatite with phosphate formamide. The method is rapid, permits large numbers of samples to be handled simultaneously, and consistently yields recoveries of >95% of total chromatographed DNA. Because as many as 1 × 10⁷ cells per batch may be analyzed, quantitation of the eluted DNA by nonradioactive methods is feasible. The method is standardized with respect to the unwinding constant β, the alkaline DNA unwinding unit Mng, and the DNA-damaging efficiency of ionizing irradiation.     

Quantitative detection of DNA damage in cells after exposure to ionizing radiation by means of an improved immunochemical assay.

A simple, sensitive and fast immunochemical method has been developed to quantify the amount of DNA damage in cells of human blood after in vitro exposure to ionizing radiation. The technique is based on the enhancement of the radiation-induced single-strandedness, which occurs in DNA regions flanking strand breaks, by a controlled further unwinding of the DNA in an alkaline solution. Subsequently, the DNA is attached to the wall of polystryene cups by passive adsorption. DNA damage is then quantified by determining the extent of single-strandedness with a monoclonal antibody, D1B, directed against single-stranded DNA. D1B binding is assayed with a 'second' antibody, labelled with either an enzyme or europium. The latter gives slightly more reproducible results. No radioactive labelling of DNA is required and the assay takes only 3.5 h after the collection of blood. Damage can be detected after doses as low as 0.5 Gy. The potential broader application of the method is discussed.     

Assessment of oxidative base damage to isolated and cellular DNA by HPLC-MS/MS measurement

Oxidation reactions that involve several oxygen and nitrogen reactive species together with nucleobase radical cations give rise among various classes of lesions to modified bases. About 70 of oxidized nucleosides that include diastereomeric forms have been characterized in mechanistic studies involving isolated DNA and related model compounds. However, only eight modified bases have been accurately measured within cellular DNA upon exposure to either gamma or UVA radiations. Emphasis is placed in this survey on recent developments of HPLC associated with tandem mass spectrometry (MS/MS) operating in the mild electrospray ionization mode. Interestingly, the HPLC-MS/MS assay in the multiple reaction monitoring mode appears to be the more sensitive and accurate method currently available for singling out several oxidized nucleosides including 8-oxo-7,8-dihydro-2'-deoxyguanosine, 8-oxo-7,8-dihydro-2'-deoxyadenosine, 5-formyl-2'-deoxyuridine, 5-(hydroxymethyl-2'-deoxyuridine, 5-hydroxy-2'-deoxyuridine, and the four diastereomers of 5,6-dihydroxy-5,6-dihydrothymidine within isolated and cellular DNA. However, one limitation of the assay that also applied to all chromatographic methods is the slight side-oxidation of normal bases during DNA extraction and subsequent work-up. This explains why the combined use of DNA repair glycosylases with either the comet assay or the alkaline elution technique is a better alternative to monitor the formation of low levels of oxidized bases within cellular DNA.     

Inhibition by hyperthermia of repair synthesis and chromatin reassembly of ultraviolet-induced damage to DNA

We have investigated the effects of hyperthermia treatment on sequential steps of the repair of UV-induced DNA damage in HeLa cells. DNA repair synthesis was inhibited by 40% after 15 min of hyperthermia treatment at 45 degrees C; greater inhibition of repair synthesis occurred with prolonged incubation at 45 degrees C. Enzymatic digestion of repair-labeled DNA with Exonuclease III indicated that once DNA repair was initiated, the DNA repair patch was synthesized to completion and that ligation of the DNA repair patch occurred. Thus the observed inhibition of UV-induced DNA repair synthesis by hyperthermia treatment may be the result of inhibition of enzymes involved in the initiating step(s) of DNA repair. DNA repair patches synthesized in UV-irradiated cells labeled at 37 degrees C with [3H]Thd were 2.2-fold more sensitive to micrococcal nuclease digestion than was parental DNA; if the length of the labeling period was prolonged, the nuclease sensitivity of the repair patch synthesized approached that of the parental DNA. DNA repair patches synthesized at 45 degrees C, however, remained sensitive to micrococcal nuclease digestion even after long labeling periods, indicating that heat treatment inhibits the reassembly of the DNA repair patch into nucleosomal structures.     

Quantitative measurement of sphingosine 1-phosphate by radioreceptor-binding assay

In Chinese hamster ovary cells overexpressing Edg-1, one of the sphingosine 1-phosphate (S1P) receptor subtypes, [(3)H]S1P binding was displaced by unlabeled S1P with IC(50), a half-maximal concentration to inhibit the binding, of about 20 nM. This radioreceptor binding was used for quantitative measurement of S1P. Among the various lipids employed, only sphingosylphosphorylcholine (SPC), other than S1P, practically displaced the binding; however, the potency of SPC was about 100 to 1000 times less than that of S1P. Thus, SPC bound to the S1P receptors inefficiently. Furthermore, before the application of test samples to this assay, S1P was partially purified: the lipid was extracted first into the aqueous phase and separated from other lipids under alkaline conditions, and then reextracted into the chloroform phase under acidic conditions. With this assay, we could specifically and quantitatively measure S1P from 2 to 40 pmol per assay well in biological samples including serum samples and various tissues. This assay also allowed us to measure the change in cellular S1P content in U937 cells after treatment with exogenous sphingosine.     

Repair of ultraviolet-induced DNA damage in the subcellular systems of Bacillus subtilis

Repair of UV-induced lesions in DNA was studied with various kinds of subcellular system prepared from Bacillus subtilis. The degree of repair during the post-irradiation incubation period was calculated from marker survivals in transforming DNA. Systems consisting mainly of non-viable spherical cells and subcellular fragments, as well as systems consisting of colony-forming protoplasts, were able to repair UV-induced lesions as efficiently as intact cell systems. A Teflon homogenate, a freeze-and-thawed product and an osmotic shockate were also examined. The former two systems showed high repair activity, but the last did not. Attempts to repair the lesions with a supernatant fraction of Teflon homogenate were unsuccessful. In contrast with the active protoplast derivatives, toluene-treated cells were inert with respect to repair even when supplemented with substrates and cofactors although they retained DNA-synthesizing activity under similar conditions.     

Ubiquitin-activating enzyme UBA1 is required for cellular response to DNA damage

The cellular DNA damage response (DDR) machinery that maintains genomic integrity and prevents severe pathologies, including cancer, is orchestrated by signaling through protein modifications. Protein ubiquitylation regulates repair of DNA double-strand breaks (DSBs), toxic lesions caused by various metabolic as well as environmental insults such as ionizing radiation (IR). Whereas several components of the DSB-evoked ubiquitylation cascade have been identified, including RNF168 and BRCA1 ubiquitin ligases, whose genetic defects predispose to a syndrome mimicking ataxia-telangiectasia and cancer, respectively, the identity of the apical E1 enzyme involved in DDR has not been established. Here, we identify ubiquitin-activating enzyme UBA1 as the E1 enzyme required for responses to IR and replication stress in human cells. We show that siRNA-mediated knockdown of UBA1, but not of another UBA family member UBA6, impaired formation of both ubiquitin conjugates at the sites of DNA damage and IR-induced foci (IRIF) by the downstream components of the DSB response pathway, 53BP1 and BRCA1. Furthermore, chemical inhibition of UBA1 prevented IRIF formation and severely impaired DSB repair and formation of 53BP1 bodies in G₁, a marker of response to replication stress. In contrast, the upstream steps of DSB response, such as phosphorylation of histone H2AX and recruitment of MDC1, remained unaffected by UBA1 depletion. Overall, our data establish UBA1 as the apical enzyme critical for ubiquitylation-dependent signaling of both DSBs and replication stress in human cells, with implications for maintenance of genomic integrity, disease pathogenesis and cancer treatment.     

Calibration of the comet assay for the measurement of DNA damage in mammalian cells

We used X-rays from a linear accelerator and from a low energy therapeutic source to calibrate the single cell gel electrophoresis (comet assay), a widely used method to measure DNA damage. γ-Rays from ⁶⁰Co, with known efficiency in inducing DNA breakage, were used as reference. Human lymphocytes and one murine tumour cell line, F10-M3 cells, were irradiated under different experimental conditions. A similar relationship between radiation dose and induced DNA damage was obtained with γ- and X-rays. A calibration curve was constructed to convert the comet assay raw data into break frequency. The median levels of DNA breaks and oxidative damage in circulating lymphocytes from healthy volunteers were calculated to be 0.76 and 0.80 breaks/10⁹ Da, respectively, (0.50 and 0.52 breaks/10⁶ bp). The values of oxidative DNA damage were in the same order of magnitude as those found by others with HPLC methods.     

Calibration of the comet assay for the measurement of DNA damage in mammalian cells

We used X-rays from a linear accelerator and from a low energy therapeutic source to calibrate the single cell gel electrophoresis (comet assay), a widely used method to measure DNA damage. γ-Rays from ⁶⁰Co, with known efficiency in inducing DNA breakage, were used as reference. Human lymphocytes and one murine tumour cell line, F10-M3 cells, were irradiated under different experimental conditions. A similar relationship between radiation dose and induced DNA damage was obtained with γ- and X-rays. A calibration curve was constructed to convert the comet assay raw data into break frequency. The median levels of DNA breaks and oxidative damage in circulating lymphocytes from healthy volunteers were calculated to be 0.76 and 0.80 breaks/10⁹ Da, respectively, (0.50 and 0.52 breaks/10⁶ bp). The values of oxidative DNA damage were in the same order of magnitude as those found by others with HPLC methods.     

Evaluation of DNA damage in flight personnel by Comet assay

There have been some suggestions that air-crew are at a higher-than-normal risk of developing cancer, since they are exposed to potential genotoxic factors. These include cosmic radiations, airborne pollutants such as the combustion products of jet propulsion, ozone, and electromagnetic fields. We used the Comet assay to investigate DNA damage in flight personnel with the aim of assessing potential health hazards in this occupational category. We studied 40 civil air-crew members who had been flying long-haul routes for at least 5 years, and compared them with a homogeneous control group of 40 healthy male ground staff. The Comet assay, or single-cell gel electrophoresis (SCGE), detects DNA single- and double-strand breaks (DSBs) and alkali-labile lesions in individual cells, and is a powerful and sensitive technique for detecting genetic damage induced by different genotoxic agents. Taking into consideration occupational risk and possible confounding factors, this assay showed a small increase, that did not reach statistical significance, of DNA damage in long-haul crew members compared to controls, indicating a lack of evident genotoxic effects. An association, although again not statistically significant, was found between reduced DNA damage and use of protective drugs (antioxidants).     

The novel gene LRP15 is regulated by DNA methylation and confers increased efficiency of DNA repair of ultraviolet-induced DNA damage

LRP15 is a novel gene cloned from lymphocytic cells, and its function is still unknown. Bioinformatic data showed that LRP15 might be regulated by DNA methylation and had an important role in DNA repair. In this study, we investigate whether the expression of LRP15 is regulated by DNA methylation, and whether overexpression of LRP15 increases efficiency of DNA repair of UV-induced DNA damage in HeLa cells. The results showed (1) the promoter of LRP15 was hypermethylated in HeLa cells, resulting a silence of its expression. Gene expression was restored by a demethylating agent, 5-aza-2'-deoxycytidine, but not by a histone deacetylase inhibitor, trichostatin A; (2) overexpression of LRP15 inhibited HeLa cell proliferation, and the numbers of cells in the G2/M phase of the cell cycle in cells transfected with LRP15 increased about 10% compared with controls; (3) cyclin B1 level was much lower in cells overexpressing LRP15 than in control cells; and (4) after exposure to UV radiation, the LRP15-positive cells showed shorter comet tails compared with the LRP15-negative cells. From these results we conclude that the expression of LRP15 is controlled by methylation in its promoter in HeLa cells, and LRP15 confers resistance to UV damage and accelerates the DNA repair rate.     

Recording cellular experiences of DNA damage

Comment on: Burrill DR, et al. Genes Dev 2011; 25:434-9.     

The cellular responses to DNA damage

The ability to survive spontaneous and induced DNA damage, and to minimize the number of heritable mutations that this causes, is essential to the maintenance of genome integrity for all organisms. Early studies on model eukaryotes focused on genes acting in defined DNA repair pathways. More recent work with the budding and fission yeasts and mammalian cells has started to integrate the DNA damage response with cell physiology and the cell cycle.     

Ultraviolet radiation-mediated damage to cellular DNA

Emphasis is placed in this review article on recent aspects of the photochemistry of cellular DNA in which both the UVB and UVA components of solar radiation are implicated individually or synergistically. Interestingly, further mechanistic insights into the UV-induced formation of DNA photoproducts were gained from the application of new accurate and sensitive chromatographic and enzymic assays aimed at measuring base damage. Thus, each of the twelve possible dimeric photoproducts that are produced at the four main bipyrimidine sites can now be singled out as dinucleoside monophosphates that are enzymatically released from UV-irradiated DNA. This was achieved using a recently developed high-performance liquid chromatography-tandem mass spectrometry assay (HPLC-MS/MS) assay after DNA extraction and appropriate enzymic digestion. Interestingly, a similar photoproduct distribution pattern is observed in both isolated and cellular DNA upon exposure to low doses of either UVC or UVB radiation. This applies more specifically to the DNA of rodent and human cells, the cis-syn cyclobutadithymine being predominant over the two other main photolesions, namely thymine-cytosine pyrimidine (6-4) pyrimidone adduct and the related cyclobutyl dimer. UVA-irradiation was found to generate cyclobutane dimers at TT and to a lower extent at TC sites as a likely result of energy transfer mechanism involving still unknown photoexcited chromophore(s). Oxidative damage to DNA is also induced although less efficiently by UVA-mediated photosensitization processes that mostly involved 1O2 together with a smaller contribution of hydroxyl radical-mediated reactions through initially generated superoxide radicals.     

Role of antioxidants in protecting cellular DNA from damage by oxidative stress

We have previously derived 2 V79 clones resistant to menadione (Md1 cells) and cadmium (Cd1 cells), respectively. They both were shown to be cross-resistant to hydrogen peroxide. There was a modification in the antioxidant repertoire in these cells as compared to the parental cells. Md1 presented an increase in catalase and glutathione peroxidase activities whereas Cd1 cells exhibited an increase in metallothionein and glutathione contents. The susceptibility of the DNA of these cells to the damaging effect of H₂O₂ was tested using the DNA precipitation assay. Both Md1 and Cd1 DNAs were more resistant to the peroxide action. In the case of Md1 cells it seems clear that the extra resistance is provided by the increase in the two H₂O₂ scavenger enzymes, catalase and glutathione peroxidase. In the case of Cd1 cells the activities of these enzymes as well as of superoxide dismutases (Cu/Zn and Mn) are unaltered as compared to the parental cells. The facts that parental cells exposed to 100 μM Zn²⁺ in the medium exhibit an increase in metallothionein but not in glutathione and that these cells become more resistant to the DNA-damaging effect of H₂O₂ suggest that this protein might play a protective role in vivo against the OH radical attack on DNA.     

DNA damage induced by copper deficiency in cattle assessed by the Comet assay

Cattle hypocuprosis is a well-known endemic disease in several parts of the world. In a previous paper, the clastogenic effect of copper deficiency in cattle has been described although the occurrence of DNA damage was not directly tested. For this reason, the relation between DNA damage assessed by the Comet assay and Cu plasma concentration was studied in Aberdeen Angus cattle.Blood samples were obtained in heparinized Vacutainer^® tubes from 28 female Aberdeen Angus cows during pregnancy or immediately after to give birth. Each sample was divided into two aliquots for Comet assay and Cu plasma determination, respectively. From the 28 cattle sampled, 17 were normocupremic and 11 were hypocupremic.Results obtained showed that whereas the average plasma Cu level in normocupremic cattle was 67.6 μg/dl, in hypocupremic cattle it was 32.1 μg/dl. The increase of DNA damage was mostly evidenced by the decrease of comet degree 1 cells and an increase of comet degree 2 cells. Correlation analysis comparing plasma Cu levels and degree 1 cells showed a correlation coefficient 0.72 (P<0.01). The comparison between plasma Cu levels and comet degree 2 cells was −0.65 (P<0.01). The comparison between plasma Cu levels and the comet length-head diameter medians determined in 23 out of 28 animals showed a correlation coefficient of −0.54 (P<0.01).The induction of DNA damage was clearly supported by the fact that the decrease of plasma Cu levels was correlated with the increase of comet length-head diameter. These findings could be considered as a contribution to the hypothesis that DNA and chromosome damage are a consequence of the higher oxidative stress suffered by hypocupremic animals.     

DNA polymerase POLQ and cellular defense against DNA damage

In mammalian cells, POLQ (pol θ) is an unusual specialized DNA polymerase whose in vivo function is under active investigation. POLQ has been implicated by different experiments to play a role in resistance to ionizing radiation and defense against genomic instability, in base excision repair, and in immunological diversification. The protein is formed by an N-terminal helicase-like domain, a C-terminal DNA polymerase domain, and a large central domain that spans between the two. This arrangement is also found in the Drosophila Mus308 protein, which functions in resistance to DNA interstrand crosslinking agents. Homologs of POLQ and Mus308 are found in multicellular eukaryotes, including plants, but a comparison of phenotypes suggests that not all of these genes are functional orthologs. Flies defective in Mus308 are sensitive to DNA interstrand crosslinking agents, while mammalian cells defective in POLQ are primarily sensitive to DNA double-strand breaking agents. Cells from Polq^?/? mice are hypersensitive to radiation and peripheral blood cells display increased spontaneous and ionizing radiation-induced levels of micronuclei (a hallmark of gross chromosomal aberrations), though mice apparently develop normally. Loss of POLQ in human and mouse cells causes sensitivity to ionizing radiation and other double strand breaking agents and increased DNA damage signaling. Retrospective studies of clinical samples show that higher levels of POLQ gene expression in breast and colorectal cancer are correlated with poorer outcomes for patients. A clear understanding of the mechanism of action and physiologic function of POLQ in the cell is likely to bear clinical relevance.     

Detection of oxidative base DNA damage by a new biochemical assay

Reactive oxygen species (ROS) damage DNA which appears to represent the major target involved in mutagenesis, carcinogenesis, and aging cell responses. Various DNA modifications are generated by ROS, but 8-hydroxy-2'-deoxyguanosine (8-oxoG) has retained a lot of attention in the last few years. Therefore, numerous methods have been developed to detect and quantify the extent of 8-oxoG in DNA, most of them requiring a significant amount of DNA that might be limiting in the case of biological samples. 8-oxoG is repaired in Escherichia coli by a specific glycosylase, the Fpg (formamidopyrimidine DNA glycosylase) protein, in a reaction that requires a covalent intermediate favored under reducing conditions. We set up a new assay based on the capture of plasmid DNA into sensitized microplate wells. DNA damaged by photoactivation of methylene blue was adsorbed on a polylysine-treated plastic well. Then the Fpg protein was added, allowed to fix on the damage by taking advantage of minimized glycosylase activity at low temperature and the reductive trapping of the covalent intermediate, yielding to a stable DNA-protein interaction. The trapped protein was subsequently recognized by a specific antibody. A secondary antibody coupled with horseradish peroxidase was used to detect the complex and the measurement was carried out by chemiluminescence. This new assay offers various potentialities, specifically in the field of technology of ROS producers.