Curcumin damages DNA in human gastric mucosa cells and lymphocytes.

The naturally occurring pigment curcumin, a major component of the spice turmeric, is reported to be a potent inhibitor of the initiation and promotion of many cancers. Due to its presence in the diet, one of its primary targets is the human gastric mucosa (GM) cells. Using the sensitive single cell electrophoresis method (comet assay), we found that curcumin at of 15, 25, and 50 microM caused DNA damage in GM cells and human peripheral blood lymphocytes. There was no difference between the extent of the damage in both types of cells. Damaged cells were able to recover within a period of 120 minutes. Our results indicate that curcumin may play a dual role in carcinogenesis.     

DNA damage and repair in human lymphocytes exposed to three anticancer platinum drugs

Cisplatin is a widely used anticancer drug, but its application is limited due to severe side effects. To reduce these effects, many other platinum drugs have been synthesized. In the present work comparative analysis of the toxicity of cisplatin, oxoplatin, and a conjugate (NH(3))(2)Pt(SeO(3)) (Se-Pt) in terms of cell viability, DNA binding, and DNA damage and repair in human lymphocytes was performed using the Trypan blue exclusion test, atomic absorption spectroscopy, and the comet assay, respectively. Cisplatin and oxoplatin did not cause a significant change in the viability of the lymphocytes even at the highest used concentration (750 microM), but the conjugate dramatically diminished viability at 100 microM only about 60% of the lymphocytes were viable (P < 0.05), and at 750 microM, less than 20% (P < 0.001). Se-Pt bound to isolated DNA was about 100 times weaker than the remaining two compounds; the binding of cisplatin was about 30% stronger than oxoplatin. Cisplatin and oxoplatin formed crosslinks with DNA in lymphocytes, whereas the conjugate induced DNA strand breaks. The lesions evoked by cisplatin and oxoplatin were slowly removed, but damage induced by Se-Pt was not repaired after 5 h even at a drug concentration of 10 microM. Severe cytotoxic and genotoxic effects exerted by Se-Pt in normal human lymphocytes preclude its intravenous application in cancer therapy. Teratogenesis Carcinog. Mutagen. 20:119-131, 2000.     

DNA damage assessment by comet assay of human lymphocytes exposed to jet propulsion fuels

Exposure to jet fuel damages DNA and results in a number of physiological changes in liver, lung, immune, and neurological tissue. In this study the single-cell gel electrophoresis assay or comet assay was used to compare the DNA damage in human peripheral lymphocytes produced by three jet propulsion fuels: JP-8, JP-5, and JP-8+100. These fuels consist of complex mixtures of aliphatic, aromatic, and substituted naphthalene hydrocarbons. Two exposure times were investigated which correspond to estimated occupational exposure times and concentrations of fuels were used that were based on previous fuel toxicity studies. Analysis of samples for the extent of DNA damage as determined by tail moment and percent tail DNA was performed on exposed cells following a brief recovery time. All fuels produced significant increases in DNA damage; however, only JP-8+100 was genotoxic at the lowest exposure concentration (1:500). At the highest exposure concentration (1:75), the mean tail moments for JP-8 and JP-8+100 (32.041 +/- 2.599 and 45.774 +/- 4.743, respectively) were significantly greater than for JP-5 (1.314 +/- 0.474). These results indicate that JP-8+100 is the most potent inducer of DNA damage in human peripheral lymphocytes and that both JP-8+100 and JP-8 are capable of damaging lymphocyte DNA to a greater extent than JP-5.     

Distress and DNA repair in human lymphocytes

This research assessed differences in DNA repair in lymphocytes from high-and low-distressed individuals. A median split on Minnesota Multiphasic Personality Inventory (MMPI) Scale 2 divided 28 newly admitted nonpsychotic psychiatric inpatients into high- and low-distress subgroups. The high-distress subgroup had significantly poorer DNA repair in lymphocytes exposed to X-irradiation than low-distress subjects. We also found that lymphocytes obtained from this psychiatric sample had significantly poorer DNA repair than lymphocytes from nonpsychiatric control subjects when compared 5 hr after X-irradiation. A high level of distress therefore appears to be associated with significant dysfunctional differences at the molecular level which may have important implications for health. These data provide evidence for a direct pathway through which distress could influence the incidence of cancer.This research was funded in part by General Molecular Applications, Inc., the Bremer Foundation, the Samuel J. Roessler Fund, and Comprehensive Cancer Center Core Grant CA-16068-09.     

Abnormal DNA repair activities in lymphocytes of workers exposed to 1,3-butadiene

Exposure to high concentrations of butadiene has been shown to cause cancer among exposed workers. We have conducted a biomarker study to elucidate whether current butadiene exposure conditions are hazardous to workers. Twenty-four workers exposed consistently to butadiene were matched with 19 co-workers who had much less contact with butadiene and who served as our controls. In the standard cytogenetic assay, there was no difference in chromosome aberration frequencies between the exposed and control groups. In the challenge assay, the exposed group shows a consistent, but non-significant, increase in chromosome aberrations indicating some abnormality in DNA repair response. The observed dicentric frequency in the challenge assay (indicative of abnormal repair of damaged chromosomes) is significantly correlated with a butadiene metabolite, 1,2-dihydroxy-4-(N-acetylcysteinyl)butane, in urine (r=0.52; p=0.04). Furthermore, cigarette smokers had consistently abnormal repair response compared with non-smokers for both the control and exposed groups. A small subset of the studied workers were evaluated for toxicant-induced DNA repair deficiency using an independent cat-host cell reactivation (CAT-HCR) assay. When cigarette smokers and non-smokers were combined in our analysis, we observed that the exposed group (n=9) had a significant reduction of DNA repair activities (p=0.009) compared with the control group (n=6). Cigarette smoking contributed significantly to the effect as exposed smokers (n=4) had a significant reduction in DNA repair activities (p=0.04) compared with exposed non-smokers. The results from the two independently conducted assays support each other and confirm the previously reported abnormal DNA repair response in another group of butadiene workers. In conclusion, our data indicates that exposure to environmental toxicants, such as butadiene, can cause DNA repair defects. Therefore, the current butadiene exposure conditions are still hazardous to workers. However, our data indicates that butadiene is not a potent genotoxic agent. Furthermore, the butadiene-induced effect is significantly enhanced by the cigarette smoking habit.     

The repair of DNA damage induced in human peripheral lymphocytes with styrene oxide

Isolated human peripheral lymphocytes were treated in vitro with styrene-7, 8-oxide (SO) and the kinetics of the repair of induced DNA damage was assessed by comet assay during further incubation of lymphocytes. Using a modified assay we measured simultaneously the number of single strand breaks in DNA (SSBs) and the sites sensitive to endonuclease III (endo III) that most probably represent abasic sites in DNA molecules. SO induced DNA damage in a dose-dependent manner and both SSBs and endo III sites were removed from the DNA by a repair process with a half time about 2-4 hours. The damage was repaired completely within 12 hours after the treatment.     

DNA damage in lymphocytes and buccal mucosa cells of children with malignant tumours undergoing chemotherapy

The aim of the present study was to evaluate DNA damage (micronucleus) in cytokinesis-blocked lymphocytes and exfoliated buccal mucosa cells from children with malignant tumours and under chemotherapy. Micronucleated cells (MNCs) were assessed from children before and during chemotherapy. A total of 21 healthy children (controls), matched for gender and age, were used as control. The results pointed out higher frequencies of micronucleated lymphocytes in children with malignant tumour before any therapy when compared to healthy probands. Furthermore an increase of micronucleated lymphocytes during chemotherapy was detected when compared to the data obtained before chemotherapy. No statistically significant increases of MNCs were noticed in buccal mucosa cells at any of the timepoints evaluated. Taken together, these data indicate that the presence of malignant tumours may increase the frequency of DNA damage in circulating lymphocytes, these cells being more sensitive for detecting chromosome aberrations caused by anti-cancer drugs.     

DNA repair and replication in lymphocytes from smokers exposed in vitro to UV light

In a sample of healthy subjects (23–59 years old), comprising49 non-smokers and 23 smokers, we studied the effects of smokingon DNA repair synthesis (UDS) in peripheral lymphocytes. DNArepair after UV-irradiation was measured by [³H]TdR incorporationinto DNA (semi-conservative synthesis was inhibited by hydroxyurea).Compared to lymphocytes from non-smokers, lymphocytes from smokersshowed significantly higher levels of UDS and higher incorporationof [³H]TdR in non-irradiated cells. We also determined the rateof DNA replication after 60 h in the presence of phytohaemoagglutinin(PHA) by measuring the incorporation of [³H]TdR during the last20 h of culture. By irradiating the lymphocytes with UV lightbefore setting up the cultures, we measured the inhibition ofDNA replication due to damage induced by UV light. This inhibition,determined by the ratio of DNA replication in irradiated overnon-irradiated lymphocytes, was less marked in smokers thanin non-smokers. In lymphocytes from a portion of the donors(18 non-smokers and 19 smokers) we also determined the rateof the [³H]TdR incorporation in the absence of PHA and comparedthe distribution of the radioactivity between the two groups.In unstimulated lymphocytes, more radioactivity was incorporatedby smokers compared to non-smokers in both conditions (UV-irradiatedor mock-irradiated), while in stimulated lymphocytes the distributionof radioactivity was significantly different only after UV-irradiation.     

DNA damage and repair capacity in workers exposed to low concentrations of benzene

DNA damage and cellular repair capacity were studied in 18 male fuel tanker drivers and 13 male filling‐station attendants exposed to low and very low concentrations of benzene, respectively, and compared to 20 males with no occupational exposure (controls). Exposure to airborne benzene was measured using passive personal samplers, and internal doses were assayed through the biomarkers t,t‐muconic acid, S‐phenylmercapturic acid and urinary benzene. DNA damage was evaluated using tail intensity (TI) determined by the comet assay in peripheral lymphocytes. Urinary 7‐hydro‐8‐oxo‐2’‐deoxyguanosine (8‐oxodG) was measured as a biomarker of oxidative damage. DNA repair kinetics were assessed using the comet assay in lymphocytes sampled 20 and 60 min post H₂O₂ exposure. Benzene exposure differed significantly between the drivers (median 246.3 µg/m³), attendants (median 13.8 µg/m³), and controls (median 4.1 µg/m³). There were no differences in TI and 8‐oxodG among the three groups, or between smokers and non‐smokers. DNA repair kinetics were similar among the drivers, attendants and controls, although the comet assay on H₂O₂‐damaged lymphocytes after 60 min revealed significantly lower levels of TI only in drivers. The DNA repair process in smokers was similar to that observed in drivers. In conclusion, this study found no relationship between low levels of benzene exposure and DNA damage, although there was evidence that exposure interferes with DNA repair kinetics. The biological impact of this finding on the onset of genotoxic effects in exposed workers has still to be ascertained. Environ. Mol. Mutagen. 57:151–158, 2016. © 2015 Wiley Periodicals, Inc.     

Hydrogen peroxide-induced DNA damage and DNA repair in lymphocytes from malnourished children

The aim of this study was to assess DNA repair capacity in lymphocytes of children with protein calorie malnutrition using the single-cell gel electrophoresis (comet) assay. Repair capacity was assessed by estimating the relative decrease of DNA migration length 5, 15, 30, and 60 min after hydrogen peroxide treatment, in three groups of children: well-nourished (WN), well-nourished infected (WN-I), and malnourished infected (MN-I). In addition, the DNA migration length was evaluated in all groups before and after peroxide treatment. Comparison of mean migration lengths observed in WN and WN-I children showed significant differences at all times tested; between WN-I and MN-I differences were also observed, except after hydrogen peroxide exposure. This implies that lymphocytes of WN-I and MN-I children were equally sensitive to hydrogen peroxide. Nevertheless, the MN-I group clearly shows the greatest overall percentage of damaged cells at all times tested. In relation to repair capacity, at 5 min it was approximately 30% in both groups of well-nourished children, but only 20% in MN-I; 15 min after exposure, repair capacity increased to 51% in well-nourished children but only to 31% in MN-I; and at 60 min this capacity increased to 82% in well-nourished but only to 55% in MN-I. These data indicate that lymphocytes of malnourished children show a decreased capacity to repair hydrogen peroxide-induced DNA damage compared to that of well-nourished controls. This reflects that only malnutrition is associated with decreased DNA repair capacity. Additionally, the data confirm that severe infection and malnutrition are two factors clearly associated with increased DNA damage.     

DNA repair in late-passage human cells.

Monolayer cultures of WI-38 cells from passages 18 to 60 were exposed to ultraviolet radiation, or to N-acetoxy-AAF, or to gamma-rays. The cultures were incubated in 3H-dThd, and unscheduled DNA synthesis--a measure of DNA repair--was measured radioautographically. Late passage cultures showed less repair, and many cells showed none. Double-label radioautographs indicated that there is an excellent correlation between cells that do scheduled synthesis and cells that do unscheduled synthesis. We interpret our results as indicating that failure of repair is not a causal event in the failure of late passage cells to divide, but that as cells age the ability to do the many coordinated steps in repair declines.     

DNA damage,photorepair, and survival in fish and human cells exposed to UV radiation

The effect of various wavelengths of UVB radiation on the induction of cyclobutane pyrimidine dimers in fish cells and human fibroblasts and the repair of these lesions were studied using an UV-endonuclease to measure dimers (endonuclease sensitive sites) by sedimentation of radioactive DNA, by gel electrophoresis of unlabeled DNA, and by cell survival. The data show that fish cells have an efficient photoreactivation system at wavelength > 304 nm that reverses cytotoxicity and dimer formation after exposure to filtered sunlamp irradiation of a shorter wave-length (λ > 290 nm). Shorter wavelengths in UVB (<304 nm) are more effective in photoreversal than longer ones (<320 nm). As a consequence, 50–85% of dimers induced by these wavelengths in fish are photoreactivated while they are being formed. A major cytotoxicological lesion is the cyclobutane pyrimidine dimers. Cultured human fibroblasts do not possess such a repair system. These results indicate that sun-lamp irradiation has wavelengths that both damage and repair DNA.     

Measurement of oxidative damage to DNA in nanomaterial exposed cells and animals

Increased levels of oxidatively damaged DNA have been documented in studies of metal, metal oxide, carbon‐based and ceramic engineered nanomaterials (ENMs). In particular, 8‐oxo‐7,8‐dihydroguanine‐2'‐deoxyguanosine (8‐oxodG) is widely assessed as a DNA nucleobase oxidation product, measured by chromatographic assays, antibody‐based methods or the comet assay with DNA repair enzymes. However, spurious oxidation of DNA has been a problem in certain studies applying chromatographic assays, yielding high baseline levels of 8‐oxodG. Antibody‐based assays detect high 8‐oxodG baseline levels, related to cross‐reactivity with other molecules in cells. This review provides an overview of efforts to reliably detect oxidatively damaged DNA and a critical assessment of the published studies on DNA damage levels. Animal studies with high baseline levels of oxidatively damaged DNA are more likely to show positive associations between exposure to ENMs and oxidized DNA in tissue than studies showing acceptable baseline levels (odds ratio = 12.1, 95% confidence interval: 1.2–124). Nevertheless, reliable studies indicate that intratracheal instillation of nanosized carbon black is associated with increased levels of oxidatively damaged DNA in lung tissue. Oral exposure to nanosized carbon black, TiO₂, carbon nanotubes and ZnO is associated with elevated levels of oxidatively damaged DNA in tissues. These observations are supported by cell culture studies showing concentration‐dependent associations between ENM exposure and oxidatively damaged DNA measured by the comet assay. Cell culture studies show relatively high variation in the ability of ENMs to oxidatively damage DNA; hence, it is currently impossible to group ENMs according to their DNA damaging potential. Environ. Mol. Mutagen. 56:97–110, 2015. © 2014 Wiley Periodicals, Inc.     

DNA damage and repair capacity in lymphocytes from obstructive sleep apnea patients

Obstructive sleep apnea (OSA) syndrome is a respiratory disease that is linked to heart attacks and high blood pressure. In the present study, we used the Comet assay to compare basal DNA damage and DNA damage induction by hydrogen peroxide, ethanol, and gamma-irradiation in lymphocytes from 35 OSA patients and 35 controls. We also measured the apoptosis and necrosis produced by these agents and the ability of the lymphocytes to repair the induced DNA damage. It was found that lymphocytes isolated from OSA patients had higher basal levels of DNA damage and were more sensitive to the effects of the DNA-damaging agents than lymphocytes from controls. OSA patients also had a reduced capacity to repair the DNA damage induced by the three agents, but apoptosis and necrosis were similar in OSA patients and the controls.     

Intra-epithelial lymphocytes and non-lymphoid cells in the human nasal mucosa

Immunohistochemical staining of biopsy specimens was used to investigate the occurrence of lymphocyte subsets and non-lymphoid cells within the epithelial layer of the human nasal mucosa. The CD19 (B cell) marker was not expressed on the intra-epithelial lymphocytes, whereas the pan T cell marker CD2 was varyingly detected. The HLA-Dr antigen was abundantly present on epithelial cells, lymphocytes, and non-lymphoid cells. The latter are probably dendritic or Langerhans' cells. The findings stated above were the same in patient and control samples. In biopsy sections of 9 ear, nose, and throat patients, many CD8-positive (T suppressor/cytotoxic) cells and very few weakly stained CD4-expressing (T helper/inducer) cells were present. Quantification on single-cell preparations showed an average of 67% of the lymphocytes to be CD2 positive, 73% to be CD8 positive, while only 12% of the lymphocytes expressed the CD4 antigen. In control sections CD8 was similarly present as in patient sections, and, in addition, some clearly stained CD4-positive cells were seen.     

DNA damage and rpair with age in individual human lymphocytes

Previous biochemical studies on DNA repair competence and aging have been limited to techniques, such as alkaline elution or nucleoid sedimentation, involving mass cell populations. These techniques provide no information about the distribution of DNA damage and repair among individual cells and are unlikely to detect age-dependent changes affecting a minor fraction of the cell population. We have recently described a microgel electrophoretic assay (Singh et al., 1988) that measures, at the level of the individual cell, single-strand DNA breaks and alkali-sensitive sites. Here, we employ this method to analyze DNA damage and repair in lymphocytes isolated from the peripheral blood of 31 subjects (23 males and 8 females aged 25–91 years) and exposed in vitro to 200 rads of X-irradiation. While basal (pre-irradiation) levels of damage were independent of the age of the donor, an age-dependent increase in DNA damage was observed immediately following irradiation. For all subjects, the mean level of DNA damage was restored to pre-irradiation control levels within 2 h of incubation at 37°C. However, a distribution analysis of DNA damage among cells within each sample indicated the presence of a few highly damaged cells (4–16%) in the 2-h sample, the occurrence of which was significantly more common among aged individuals. These data indicate an age-related decline in DNA repair competence among a small subpopulation of lymphocytes.     

Analysis of cell damage and proliferation in Helicobacter pylori-infected human gastric mucosa from patients with gastric adenocarcinoma.

Helicobacter pylori (HP) infection, a cause of multifocal atrophic gastritis, is considered an important factor related to the evolution of the human gastric mucosa from normal to intestinal-type adenocarcinoma. We examined cell proliferation and both double and single strand DNA damage in situ in 35 patients undergoing gastrectomy for adenocarcinoma with HP-infected gastric mucosa by immunolocalization of Ki-67, terminal deoxynucleotidyl transferase-mediated dUTP-biotin nick end labeling, and in situ nick translation. We also studied the distribution of intraepithelial neutrophils by elastase immunolocalization. HP infection was confirmed in all cases by serum anti-HP antibodies, ureas testing, and histopathological examination. HP-infected gastric mucosa was classified according to the degree of inflammation and intestinal metaplasia. Ki-67, terminal deoxynucleotidyl transferase-mediated labeling, in situ nick translation, and intraepithelial neutrophil indices all increased with the progression of gastritis and were highest in glands with incomplete intestinal metaplasia. All indices were lowest in gastric glands with complete intestinal metaplasia. Significant positive correlations were observed among these markers. Increased proliferative activity in HP-associated chronic gastritis in response to cell damage or injury was clearly demonstrated, suggesting that both HP-associated toxins and intraepithelial neutrophils are important in HP-related gastric epithelial injury. Increased cell turnover associated with incomplete intestinal metaplasia may result in DNA instability and subsequent development of intestinal-type gastric adenocarcinoma in HP-infected mucosa.     

DNA damage and repair induced by bleomycin in mammalian and insect cells.

We assessed the response of mosquito (ATC-15) and mammalian (CHO) cells to bleomycin (BLM). Comparison of the data obtained in both cell lines indicates that DNA in the chromatin of mosquito cells is 10 to 20 times more resistant to BLM, and that the DNA damage induced by this antibiotic is better repaired in mosquito than in mammalian cells. Permeability of the cell membrane for BLM was found to be the same for both cell lines. Moreover, the time-kinetics of BLM damage to nuclear DNA was similar for ATC-15 and CHO cells. The low sensitivity of mosquito cells to BLM is reflected in better growth efficiency. These cells exhibit a satisfactory growth at BLM doses that produce a permanent arrest of growth in CHO cells. It is proposed that variations in the chromatin structure and in the intracellular free amino acid pool may play an important role in the differential response of insect and mammalian cells to BLM.     

Difference in the capacity to repair DNA damage in human cells chronically infected with the rubella virus

Centrifugation of cell lysates in alkaline sucrose gradients and chromatography on hydroxyapatite columns were used to demonstrate inhibition of reparation of mitomycin C-induced DNA damages at the stage of reunification of single-strand breaks of DNA in human HEp-2 cell cultures chronically infected with rubella virus. At the same time, reparation of single-strand breaks of DNA caused by bleomycin occurs with similar intensity both in chronically infected and noninfected HEp-2 cultures. The experimental results suggest that the chronic course of infection in human cells leads to disorders in reparative synthesis of cellular DNA and/or is due to disconnected effect of reparation enzymes in this system.