Paracetamol inhibits UV-induced DNA repair in resting human mononuclear blood cells in vitro

The effects of paracetamol on the repair of DNA damage in restinghuman peripheral mononuclear blood cells (MNC) in vitro wereinvestigated by means of the alkaline elution technique. Lowdoses of UV light (254 nm, 3 J/m²) caused a transient increasein the amount of DNA singlestrand breaks and alkali-labile sites(SSBs). Paracetamol (0.1–1.0 mM) present during post-irradiationincubation approximately doubled the maximum level of UV-induced(1–3 J/m²) SSBs and delayed the completion of repair.Although there were considerable variations between cells preparedfrom different donors, the level of UV-induced DNA SSBs wasalways higher with paracetamol. Hydroxyurea (0.3 mM), an inhibitorof ribonucleotide reductase, caused a similar increased accumulationand slow removal of SSBs, whereas cytosine-l-ß-D-arabinofuranoside(Ara C) (10 µM), an inhibitor of DNA polymerases, ledto a steady accumulation of DNA SSBs. The increased levels ofSSBs caused by paracetamol or hydroxyurea were both completelysuppressed by concomitant addition of deoxyribonucleosides;this supports the notion that paracetamol as well as hydroxyureainhibits ribonucleotide reductase. About the same rates of formationand removal of UV-induced SSBs were observed in T lymphocytes,B lymphocytes and monocytes. In both isolated T lymphocytesand B lymphocytes, paracetamol (0.3 mM) markedly increased thelevel of DNA SSBs induced by UV, whereas monocytes seemed tobe less sensitive to the effect of paracetamol. It is concludedthat the inhibition of DNA repair may contribute to the clastogeniceffects of paracetamol.     

Induction and repair of DNA strand breaks and oxidised bases in somatic and spermatogenic cells from the earthworm Eisenia fetida after exposure to ionising radiation

Methods for analysing oxidised DNA lesions [formamidopyrimidine glycosylase (Fpg)-sensitive sites] in coelomocytes and spermatogenic cells from the earthworm Eisenia fetida using the Fpg-modified comet assay were established. The DNA integrity (SSBs = strand breaks plus alkali labile sites and Fpg-sensitive sites) in cells from E. fetida continuously exposed to (60)Co gamma-radiation (dose rates 0.18-43 mGy/h) during two subsequent generations (F0 and F1) were measured and related to effects on reproduction end points which have already been reported. The data suggest a slight increase of Fpg-sensitive sites in spermatogenic cells from worms exposed at 11 mGy/h in the F0 generation but not in F1, whereas reduced reproduction had been observed at dose rates at or >4 mGy/h in F0 and at 11 mGy/h in F1. Using acute X-rays (41.9 Gy/h), dose-response relationships were established for SSBs in coelomocytes and spermatogenic cells exposed in vitro. In vivo DNA repair was studied by measuring the decrease in damage (SSBs and Fpg-sensitive sites) in coelomocytes and spermatogenic cells isolated from worms at different times (0-6 h) after acute X-ray exposure (4 Gy). SSBs were repaired in coelomocytes following biphasic kinetics, i.e. with a fast and a slow half-life (t(1/2)) of 36 min (95%) and 6.7 h (5%), respectively. Fpg-sensitive sites were repaired at considerably lower rates (t(1/2) = 4-5 h). In spermatogenic cells, SSB repair during the first hour was observed but a half-life could not be estimated. Repair of Fpg-sensitive sites could not be determined. In general, a reduced repair of Fpg-sensitive sites suggests a higher potential for accumulation of oxidised lesions, compared to SSBs, in earthworms exposed to radiation and other environmental contaminants. This is the first study comparing DNA damage with reproduction in earthworms exposed to ionising radiation.     

Interstitial telomeric DNA sequences of Chinese hamster cells are hypersensitive to nitric oxide damage, and DNA-PKcs has a specific local role in its repair

The DNA breakage detection-fluorescence in situ hybridization (DBD-FISH) procedure was used to analyze DNA single-strand breaks (SSBs) and alkali-labile sites induced by exposure to the nitric oxide (NO) donors sodium nitroprusside (SNP) and 3-morpholinosydnomine hydrochloride (SIN-1) in the whole genome and in long interstitial telomeric repeat sequence (ITRS) blocks from Chinese hamster cells. The relative density of DNA damage generated in the ITRS by X-rays was similar to that induced in the genome overall, whereas it was 1.7 times higher when the alkylating agent MNNG was assayed. Nevertheless, after SNP or SIN-1 treatment, ITRSs proved to be 2.8 and 2.7 times relatively more damaged, respectively, than the whole genome. When the DNA-dependent protein kinase catalytic subunit (DNA-PKcs) was not active, as in XR-C1 mutant cells, the repair kinetics in the whole genome did not differ from that in the parental cell line with X-ray or SNP exposure. However, whereas the SSBs and alkali-labile sites induced in the ITRS by X-rays exhibited rejoining kinetics similar to that of the parental cell line, the damage induced by SNP was more slowly rejoined. This implies a role for DNA-PKcs in the repair of DNA damage induced by NO, especially in ITRSs. The results demonstrated intragenomic heterogeneity of NO-induced DNA damage and repair; there was a higher density of DNA damage in the ITRS blocks, possibly because of their guanine richness. This suggests that a parallel process may occur in the terminal telomeres, which has implications for premature aging and neoplastic development by chronic NO exposure in vivo.     

Effects of air pollution and smoking on DNA damage of human lymphocytes

The comet assay is a useful technique for the study of genetic damage in humans exposed to environmental mutagens and carcinogens. In this study the effects of hydrogen peroxide (H(2)O(2)) and ultraviolet (UV) irradiation on 80 healthy individuals living in urban and rural areas with different smoking habits were investigated. Endonuclease III (endo III) treatment was also used to reveal the level of oxidized pyrimidine formation in these groups. The extent of damage and subsequent repair appear to be influenced by the living conditions (urban or rural areas). Smoking, however, was shown to have the most significant effect on DNA damage on all groups studied.     

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.     

Induction of DNA strand breaks by ethylene oxide in human diploid fibroblasts

In vitro exposure of normal human diploid fibro-blasts (strain VH-10) to ethylene oxide (EtO) induced DNA strand breaks in the dose range of 2.5–30 mMh of EtO. Alkaline DNA unwinding (ADU), neutral filter elution (NFE), pulsed field gel electrophoresis (PFGE), and the comet assay were used to measure DNA single (SSBs) and double strand breaks (DSBs). Different induction rates of SSBs and DSBs, depending on applied method and also on treatment conditions (cells in monolayer or in suspension were used), were found. A dose-dependent increase of DNA strand breaks was found by the ADU method in the dose range of 2.5–20 mMh of EtO when treatment was performed in monolayer and in suspension. DSBs were detected by NFE only when the cells were treated with EtO in suspension (doses 10–30 mMh). The highest induction rate of DSBs (about 4 DSBs per 100 Mbp per 1 mMh of EtO) was detected in suspension with PFGE applied. We have shown that heat-labile sites are formed by EtO. Presumably, the different DSB levels detected by PFGE and NFE result from the conversion of these sites to DSBs during cell lysis at elevated temperature in the PFGE method. The results of the comet assay confirmed that apoptotic processes are not involved in the formation of DSBs in our experimental conditions (less than 1% of apoptotic cells were observed at all doses studied). Possible mechanisms for the induction of DNA strand breaks by EtO-treatment are discussed. The capacity to repair DSBs in EtO-exposed (5–7.5 mMh) cells was studied, and it was found that a considerable part of the damage (about 50%) could be repaired during 18 hr of incubation. © 1994 Wiley-Liss, Inc.     

Possible involvement of XPA in repair of oxidative DNA damage deduced from analysis of damage, repair and genotype in a human population study

Participants in a study of occupational exposure to mineral fibres in Slovakia were analysed for the polymorphism 23A-->G in the DNA repair gene XPA. Of the 388 subjects, 239 were exposed to asbestos, stonewool or glass fibre; the rest were unexposed controls. Levels of DNA base alterations (oxidation and alkylation) in lymphocytes were measured using the comet assay with lesion-specific endonucleases. 8-oxoguanine DNA glycosylase (OGG1) DNA repair activity was measured, as incision activity of a lymphocyte extract on DNA containing the OGG1 substrate 8-oxoguanine. Presence of the A allele was associated with higher levels of DNA damage (sites sensitive to formamidopyrimidine DNA glycosylase, endonuclease III or 3-methyladenine DNA glycosylase II) as well as with higher activity of OGG1 repair enzyme. DNA base damage increased with age, showing highly significant correlations when the whole population or subgroups of the population were analysed. OGG1 repair activity also increased with age, but when analysed according to XPA genotype, the increase was observed only in those individuals with an A allele. Although XPA is known as a protein involved in nucleotide excision repair of UV-induced damage and bulky DNA adducts, it may also have a role in the repair of oxidized bases.     

Rejoining of DNA strand breaks induced by propylene oxide and epichlorohydrin in human diploid fibroblasts

The repair kinetics of DNA single- and double-strand breaks (SSBs, DSBs) induced with two carcinogenic epoxides, propylene oxide (PO) and epichlorohydrin (ECH), was studied in human diploid fibroblasts. The methods used were: alkaline DNA unwinding (ADU), the comet assay, and pulsed field gel electrophoresis (PFGE). About 70% of SSBs, measured by ADU, were rejoined after the treatment with 5 mMh and 10 mMh of PO within 20 hr, and the half-life was estimated to be ∼15 hr. On the other hand, effective rejoining of SSBs after ECH treatment was observed only at a dose of 1 mMh (a half-life of ∼15 hr), whereas after 2 mMh treatment, only 26% of SSBs could be rejoined within 20 hr. Furthermore, the use of the comet assay demonstrated that DNA strand breaks were effectively rejoined after PO and ECH treatment at doses of 5–10 mMh and 0.5–1 mMh, respectively. About 76% and 83% of DSBs induced by 5 and 10 mMh of PO, respectively, were rejoined within 4 hr after the treatment (a half-life of ∼2.5 hr), with little further repair thereafter. At lower dose of ECH (1 mMh) a half-life for DSBs rejoining was estimated to be ∼2 hr; however, only 29% of DSBs were rejoined within 2 hr at the higher dose of 2 mMh. After 18 hr, the rejoining following treatment with a lower dose was negligible. At a higher dose, a rapid accumulation of DSBs was observed, probably as the result of cell death and DNA degradation. The results demonstrate the capability of human diploid fibroblasts to repair DNA SSBs and DSBs at low-to-moderate doses of the epoxides. A weak capacity to rejoin DNA strand breaks induced by higher doses of ECH may be a consequence of its higher DNA alkylation activity and approximately 10 times higher toxicity compared to PO. Environ. Mol. Mutagen. 32:223–228, 1998 © 1998 Wiley-Liss, Inc.     

Analysis of DNA alkylation damage and repair in mammalian cells by the comet assay

The single cell gel electrophoresis (SCGE) or comet assay, whichmeasures DNA strand breaks in individual cells, was used toanalyse DNA damage and repair induced by the SN₁-type alkylatingcarcinogens N-ethyl-N'-nitro-N-nitrosoguanidine and N-ethyl-N-nitrosoureain CHO cells. The comet assay was comparable in sensitivityto the alkaline elution assay. The alkyl-adducts detected asDNA single-strand breaks (ssb) by this technique were completelyrepaired within 24 h after treatment. These data indicate thatlong-lived lesions, such as alkylphosphotriesters, are not convertedinto ssb under the standard SCGE alkaline conditions (pH 13.5).The lesions revealed by the comet assay are mainly apurinic/apyrimidinic(AP) sites and breaks formed as intermediates in the base excisionrepair process of N-alkylpurines. When SCGE was performed atpH 12.5 instead of pH 13.5 a lower level of ssb was detectedand these breaks were completely resealed within 2 h after treatmentThese data suggest that different subsets of lesions are detectedunder different pH conditions. The SCGE combined with inclusionwithin the cells of endo-nuclease III revealed that a high portionof AP sites induced by alkylation damage were not convertedinto ssb by alkali. The level of endonuclease III-sensitivesites decreased as a function of the repair time and by 24 hafter treatment no sites were left on the DNA. The use of thismodified SCGE assay allows the estimation of the total amountof unrepaired AP sites present on DNA. Alkylation-induced ssbas detected by the comet assay should be regarded as an indicatorof repair rate and balance more than a measure of actual DNAdamage. ³To whom correspondence should be addressed     

Seasonal variation of DNA damage and repair in patients with non-melanoma skin cancer and referents with and without psoriasis

Quadruples of skin cancer patients with and without psoriasis and referents with and without psoriasis (4×20 study persons) were identified and examined for DNA damage by single cell gel electrophoresis (comet-assay) and DNA-repair by UV-induced unscheduled DNA synthesis (UDS) in mononuclear blood cells (lymphocytes and monocytes). DNA damage (strand breaks and alkaline labile sites) as assessed by the comet assay and DNA repair as assessed by UDS were significantly associated with the season in which blood sampling took place. This variation might be explained by an increased exposure to solar radiation. When the comet tail moment data were stratified by sampling period, an interaction between psoriasis and skin cancer was detected, with patients with psoriasis and skin cancer exhibiting more DNA damage. Patients with psoriasis and skin cancer also had lower UDS compared to healthy study persons, suggesting that the more DNA damage may be caused by a lower rate of DNA repair. In all study persons, the extent of UDS correlated positively with the amount of DNA damage determined by the comet assay.     

Study of DNA damage via the comet assay and base excision repair activities in rat brain neurons and astrocytes during aging

Earlier we have used biochemical approach to assess the number of single (SSBs) and double (DSBs) strand breaks in brain cellular DNA. However, a quick method to obtain a reliable measure of DNA damage in cells was in need for population studies. Therefore, single cell gel electrophoresis technique (popularly known as "comet" assay) has been standardized using the Trevigen protocol. DNA damage was assessed in isolated neurons and astrocytes from the cortex of young (7 days), adult (6 months) and old (2 years). Marked increase is seen in DNA damage in terms SSBs and DSBs in both types of cells by 6 months of age, which increased further by 2 years of age. The number of 8-oxoguanine DNA glycosylase (OGG1) and uracil DNA glycosylase (UDG) sensitive sites also increased in DNA with age with the simultaneous decrease in OGG1, UDG and AP endonuclease (APE1) activities. Thus the comet assay adapted to our lab conditions has proven to be useful for a quick assessment of DNA damage in a large number of samples that constitute our future studies.     

Elevated levels of oxidative DNA damage in lymphocytes from patients with Alzheimer's disease.

Previous studies have provided evidence of the involvement of oxidative damage in the pathogenesis of Alzheimer's disease (AD). Although the role of oxidative stress in the aetiology of the disease is still not clear, the detection of an increased damage status in the cells of patients could have important therapeutic implications. The level of oxidative damage and repair capacity in peripheral lymphocytes of AD patients and of age-matched controls was determined by the Comet assay applied to freshly isolated blood samples with oxidative lesion-specific DNA repair endonucleases. This is less prone to errors arising from oxidative artifacts than chemical analytical methods; and is therefore a relatively reliable, as well as rapid method for assay of oxidative DNA damage in cells. Statistically significant elevations (P < 0.05) of oxidized purines were observed in nuclear DNA of peripheral lymphocytes from AD patients, compared to age matched control subjects, both at basal level and after oxidative stress induced by H(2)O(2.) AD patients also showed a diminished repair of H(2)O(2) -induced oxidized purines.     

Detection of DNA primary damage by premature chromosome condensation in human peripheral blood lymphocytes treated with methyl methanesulfonate

Methyl methanesulfonate (MMS) is a direct acting methylating agent which produces apurinic sites that are transformed into DNA single-strand breaks by base excision repair. MMS-induced DNA lesions have to be transformed by DNA synthesis in order to give rise to chromosomal damage. In this study the premature chromosome condensation (PCC) technique was used in G(1) human lymphocytes treated with MMS to investigate whether, with this technique, chromosomal damage could be detected without the cell needing to undergo DNA synthesis. A dose-dependent increase in chromosomal fragmentation was indeed observed in G(1) lymphocytes. MMS treatment at 1.3, 2.5 and 5 mM was characterized by the appearance of highly fragmented chromosomes. This observation induced us to further investigate whether this effect was more connected with triggering of apoptotic cell death than a consequence of the PCC technique. Data obtained by nuclear morphology analysis, by Trypan blue exclusion assay and pulsed field gel electrophoresis seem to suggest that the observed chromosome fragmentation could be due to the onset of apoptosis. Consequently, one should bear in mind that the PCC technique can overestimate chromosomal damage when apoptosis is also induced.     

In vitro mitigation of arsenic toxicity by tea polyphenols in human lymphocytes.

The groundwater arsenicals have brought dreadful misery for the people residing in the endemic regions of West Bengal, India. Arsenic-related anomalies include arsenicosis, hyperkera-tosis, gastric complications, liver fibrosis, peripheral neuropathy, and cancer. Some of these diseases have been frequently associated with overproduction of reactive oxygen species that cause DNA damage and improper functioning of body's antioxidant defense mechanism. Natural polyphenols present in tea serve as excellent antioxidants. In the present study, an attempt has been made to elucidate the role of representative polyphenols and extracts of green and black tea in modulating sodium arsenite (As III)-induced DNA damage in normal human lymphocytes. Comet assay was used to detect the DNA damage. Arsenic-induced oxidative stress was measured with generation of reactive oxygen species, lipid peroxidation, and activity of some antioxidant enzymes. Expression of some repair enzymes such as poly(ADP-ribose) polymerase and DNA polymerase beta was measured to assess the effect of tea on DNA repair. Tea afforded efficient reduction of As III-induced DNA damage in human lymphocytes. Tea also quenched the excessive production of reactive oxygen species by arsenic, reduced the elevated levels of lipid peroxidation, and increased the activity of antioxidant enzymes such as catalase, superoxide dismutase, and glutathione peroxidase. Furthermore, tea enhanced recovery of DNA damage, which was indicative of repair as confirmed by unscheduled DNA synthesis and pronounced expression of DNA repair enzyme poly(ADP-ribose) polymerase. It is speculated that the antioxidant potential and repair-inducing capacity of tea might help in combating the severe genotoxic effects induced by arsenic in the human population.     

The effect of mild hypothermia (34 degrees C) and mild hyperthermia (39 degrees C) on DNA damage, repair and aging of human diploid fibroblasts

We used mild hypothermia (34 degrees C) and mild hyperthermia (39 degrees C) to examine aging at the cellular level in relation to DNA damage and repair. With the filter elution technique we monitored spontaneous single-strand breaks (SSBs) and double-strand breaks (DSBs) in DNA during in vitro aging at 34 degrees C, 37 degrees C and 39 degrees C of normal human diploid fibroblasts (HDF). DNA repair was assessed after ionizing and non-ionizing (ultraviolet) radiation of HDF at different population doubling levels (PDLs): the former was assayed by filter elution and the latter by unscheduled DNA synthesis. Survival was assessed by trypan blue dye exclusion and colony formation. Cells at 37 degrees C achieve a higher cumulative PDL (67 +/- 6) than cells at 39 degrees C (60 +/- 5) or at 34 degrees C (55 +/- 6). The level of spontaneous SSBs and DSBs, and radiosensitivity of DNA to either 6 Gy or 100 Gy gamma rays, do not change with in vitro age at any of the three temperatures. Repair of SSBs (induced by 6 Gy) and DSBs (induced by 100 Gy) does not change with in vitro age: rejoining is 86-104% complete by 60 min repair and generally does not differ across temperatures. Response to non-ionizing radiation (254 nm, 75, 150, 300 ergs/mm2) does not change with in vitro age at 37 degrees C or 39 degrees C, whereas excision repair increases with age at 34 degrees C even though cell survival does not. The results do not support the rate of living theory of aging (Pearl, R., The Rate of Living, University of London Press, London, 1928) as applied to temperature effects on HDF aging in vitro (as measured by proliferative lifespan) and on their response to radiation-induced DNA damage.     

Genotoxicity, cytotoxicity and gene expression in patients undergoing elective surgery under isoflurane anaesthesia

There are numerous studies reporting on the effects of inhalation anaesthesia in cells of exposed individuals but not much is known about the ability of isoflurane (ISF) to induce oxidative DNA damage. However, surgery is often associated with a temporary perioperative immunological alteration, and some volatile anaesthetics seem to contribute to a transient lymphocytopenia after surgery. We conducted a study to evaluate a possible genotoxic effect, including oxidative DNA damage, and apoptosis in peripheral lymphocytes of 20 patients American Society of Anaesthesiologists physical status I undergoing minor elective surgery lasting at least 120 min, under anaesthesia with ISF. We also investigated the expression of several genes in blood cells. Blood samples were collected at three time points: before anaesthesia (T(1)), 2 h after the beginning of anaesthesia (T(2)) and on the first post-operative day (T(3)). General DNA damage and oxidised bases (Fpg and endo III-sites) in blood lymphocytes were evaluated using the comet assay. Lymphocytes were phenotyped and apoptosis was evaluated by flow cytometry. In addition, expressions of hOGG1 and XRCC1, genes involved in DNA repair, and BCL2, a gene related to apoptosis, were assessed by quantitative real-time polymerase chain reaction. Results showed no statistically significant difference in the level of DNA damage and oxidised bases among the three sampling times. Anaesthesia with ISF did not increase the percentage of cells in early or late apoptosis in cytotoxic or helper T lymphocytes. Lower hOGG1 and BCL2 expressions were detected at T(3) in comparison to the other two previous time points, and there was significantly lower expression of XRCC1 at T(3) in relation to T(2). In conclusion, the exposure to ISF did not result in genotoxicity and cytotoxicity in lymphocytes and in toxicogenomic effect in leukocytes, although DNA repair and apoptosis-related genes were down-regulated on the first post-operative day.     

Nick translation--a new assay for monitoring DNA damage and repair in cultured human fibroblasts

An in vitro assay has been developed to detect DNA damage and repair following chemical treatment of human diploid fibroblasts. DNA damage is measured by following the Escherichia coli DNA polymerase I-catalyzed incorporation of radiolabeled deoxycytidine triphosphate (dCTP) into the DNA of lysolecithin-permeabilized cells. DNA strand breaks with free 3' OH termini serve as template sites for incorporation, and decrease of this incorporation with time, following removal of the test chemical, indicates loss (repair) of initial damage. Inhibition of the DNA excision repair process by the addition of the repair inhibitors arabinofuranosyl cytosine (ara-C) and hydroxyurea (HU) during the incubation period gives rise to an increased number of template sites, manifesting itself in increased incorporation and indicating the induction of long-patch excision repair. This nick translation assay, originally proposed by Nose and Okamoto [1983], is very sensitive, allows detection and quantitation of both DNA damage and repair, distinguishes between various types of induced damage, does not require radioactive prelabeling of cells, and circumvents some of the problems inherent in unscheduled DNA synthesis (UDS) assays. The assay is also useful in detecting those agents that inhibit replicative DNA synthesis and/or the excision repair process. Results presented demonstrate that all 14 direct-acting carcinogens tested and 8 of 14 carcinogens requiring metabolic activation give positive indication of DNA damage, repair, or both. Eleven of 14 noncarcinogens tested were scored as negative, the other 3 having previously been shown to interact with cellular DNA. This assay is shown to have predictive capability at least equal to that of UDS assays but to allow a broader spectrum of genotoxic effects to be analyzed.     

Comparative studies on cytotoxic and genotoxic effects of two organic mercury compounds in lymphocytes and gastric mucosa cells of sprague-dawley rats

Human lymphocytes (HL) as well as lymphocytes (RL), hepatocytes (RH), and gastric mucosa cells (GM) of Sprague-Dawley rats were treated in vitro for 1 h with methylmercury chloride (MMC, 0.5–4 μg/ml) and dimethylmercury (DMM, 5–40 μg/ml). The cytotoxicity of the two organic mercury compounds was assessed by dye exclusion, and the extent of induced DNA fragmentation was measured with a single-cell microgel electrophoresis assay. Both MMC and DMM induced DNA damage and cytotoxicity in a dose-related manner in HL, RL, and GM. MMC was more effective in causing a significant increase in median DNA migration than DMM at doses yielding approximately the same degree of cytotoxicity. In rat hepatocytes the MMC-induced DNA damage was, however, lower than in the other cells. An analysis of repair kinetics following exposure to 2 μg/ml MMC was carried out in human lymphocytes obtained from an adult male donor. The bulk of DNA repair occurred 90 min after in vitro exposure, and it was about complete by 120 min following cessation of exposure. Finally, in order to have a basis for extrapolating to the human situation, in vivo studies were performed with Sprague-Dawley rats, also assessing the DNA damage and cytotoxicity in the lymphocytes and gastric mucosa cells. These in vivo results after oral exposure may be directly compared to the in vitro data obtained in the same cells. © 1993 Wiley-Liss, Inc.     

Nick translation—a new assay for monitoring dna damage and repair in cultured human fibroblasts

An in vitro assay has been developed to detect DNA damage and repair following chemical treatment of human diploid fibroblasts. DNA damage is measured by following the Escherichia coli DNA polymerase I-catalyzed incorporation of radiolabeled deoxycytidine triphosphate (dCTP) into the DNA of lysolecithin-permeabilized cells. DNA strand breaks with free 3′ OH termini serve as template sites for incorporation, and decrease of this incorporation with time, following removal of the test chemical, indicates loss (repair) of initial damage. Inhibition of the DNA excision repair process by the addition of the repair inhibitors arabinofuranosyl cytosine (ara-C) and hydroxyurea (HU) during the incubation period gives rise to an increased number of template sites, manifesting itself in increased incorporation and indicating the induction of long-patch excision repair. This nick translation assay, originally proposed by Nose and Okamoto [1983], is very sensitive, allows detection and quantitation of both DNA damage and repair, distinguishes between various types of induced damage, does not require radioactive prelabeling of cells, and circumvents some of the problems inherent in unscheduled DNA synthesis (UDS) assays. The assay is also useful in detecting those agents that inhibit replicative DNA synthesis and/or the excision repair process. Results presented demonstrate that all 14 direct-acting carcinogens tested and 8 of 14 carcinogens requiring metabolic activation give positive indication of DNA damage, repair, or both. Eleven of 14 noncarcinogens tested were scored as negative, the other 3 having previously been shown to interact with cellular DNA. This assay is shown to have predictive capability at least equal to that of UDS assays but to allow a broader spectrum of genotoxic effects to be analyzed.     

Proliferative potential and DNA repair in lymphocytes from short-lived and long-lived strains of mice, relation to aging

The replicative capacity and DNA repair ability of spleen lymphocytes of young and old mice from short-lived and long-lived strains were studied. DNA repair after both UV- and gamma-induced damage was investigated. Proliferation after Con A decreased as a function of age in both mouse strains and paralleled an age-associated decline in repair of DNA damage induced by either UV or gamma-irradiation. Compared to the long-lived, the short-lived strain displayed an earlier impairment of both proliferative and repair potentials. DNA repair after gamma-induced damage only occurred if lymphocytes were stimulated to proliferate. Resting lymphocytes appeared unable to repair strand breaks. By contrast, DNA repair of UV-induced damage showed two components: one was dependent on the cell proliferative state, the other was not. Both components were stimulated or induced by mitogen. Resting lymphocytes were able to perform an appreciable amount of repair after UV irradiation. Our results suggest that resting or post-mitotic cells possess a greater possibility to regulate repair of UV-induced than gamma-induced damage. We speculate that it may be the level of this proliferation-independent, but mitogen inducible form of repair which correlates with maximum life-spans between species, thereby explaining why repair of UV- but not gamma-induced damage reveals such a correlation.