Modulation of hypersensitivity to oxidative DNA damage in ATM defective cells induced by potassium bromate by inhibition of the Poly (ADP-ribose) polymerase (PARP).

The ataxia telangiectasia mutated (ATM) protein is a pivotal multifunctional protein kinase predominantly involved in DNA damage response, as well as in maintaining overall functional integrity of the cells. Apart from playing its major role in regulating the cellular response to DNA damage, ATM, when mutated, can additionally determine oxidative stress, metabolic syndrome, mitochondrial dysfunction and neurodegeneration. In the present paper we aim to investigate the levels of oxidative stress potentially induced by the oxidizing rodent renal carcinogen KBrO3 in ATM-defective lymphoblastoid cell lines (LCLs) established from four classical AT patients (with different ATM mutations), one AT variant with reduced hypersensitivity to X rays, obligate AT heterozygotes and wild type intrafamilial control. A possible modulatory involvement of PARP in potentially induced oxidative stress is also evaluated following its inhibition with 3-aminobenzamide (3-AB). Treatments with KBrO3 clearly showed a marked hypersensitivity of the ATM-defective LCLs, including the AT variant. A marked and statistically significant reduction of KBrO3-induced chromosomal damage following inhibition of PARP by 3-AB, was observed in all AT LCLs, but not in those from the AT variant, AT heterozygotes and wild type intrafamilial control. This result is suggestive of a modulatory involvement of PARP in the hypersensitivity of ATM-defective cells to DNA oxidative damage.

Cytogenetic evidence that DNA topoisomerase II is not involved in radiation induced chromsome-type aberrations.

ICRF-187 (Cardioxane™, Chiron) is a catalytic inhibitor of DNA topoisomerase II (Topo II), proposed to act by blocking Topo II-mediated DNA cleavage without stabilizing DNA-Topo II-"cleavable complexes". In this study ICRF-187 was used to evaluate the potential involvement of DNA topoisomerase II in the formation of the radiation-induced chromosome-type aberrations in the G0 phase of the cell cycle in human lymphocytes from three healthy male donors. This is based on many evidences that DNA topoisomerases are involved in DNA recombination, mainly of illegitimate type (non-homologous) both in vitro and in vivo. The results obtained clearly indicated that ICRF-187 did not induce per se any chromosomal damage. When challenged with the non-catalytic Topo II poison VP-16 (etoposide), which acts by stabilizing the "cleavable complex" generating "protein concealed" DSB's and thus chromosomal aberrations, it completely abolished the significant induction of chromosome-type aberrations and formation of dicentric chromosomes. This indicates that ICRF-187 acts effectively as catalytic inhibitor of Topo II. On the other hand, when X-ray treatments were challenged with ICRF-187 using experimental conditions as for VP-16 treatments, no modification of the incidence of chromosome-type aberrations and dicentric chromosomes was observed. On this basis, we conclude that Topo II is not involved in the formation of X-ray-induced chromosome-type aberrations and dicentric chromosomes in human lymphocytes in the G0 phase of the cell cycle.

The novel human gene aprataxin is directly involved in DNA single-strand-break repair.

The cells of an ataxia-oculomotor apraxia type 1 (AOA1) patient, homozygous for a new aprataxin mutation (T739C), were treated with camptothecin, an inhibitor of DNA topoisomerase I which induces DNA single-strand breaks. DNA damage was evaluated by cytogenetic analysis of chromosomal aberrations. The results obtained showed marked and dose-related increases in induced chromosomal aberrations in the patient and her heterozygous mother compared to the intrafamilial wild-type control. The alkaline comet assay confirmed this pattern. Moreover, the AOA1 cells did not show hypersensitivity to ionizing radiation, i.e. X-rays. These findings clearly indicate the direct involvement of aprataxin in the DNA single-strand-break repair machinery.

Potassium bromate but not X-rays cause unexpectedly elevated levels of DNA breakage similar to those induced by ultraviolet light in Cockayne syndrome (CS-B) fibroblasts.

It has been previously reported that the elevated accumulation of repair incision intermediates in cells from patients with combined characteristics of xeroderma pigmentosum complementation group D (XP-D) and Cockayne syndrome (CS) XP-D/CS fibroblasts following UV irradiation is caused by an "uncontrolled" incision of undamaged genomic DNA induced by UV-DNA-lesions which apparently are not removed. This could be an explanation for the extreme sensitivity of these cells to UV light. In the present study, we confirm the immediate DNA breakage following UV irradiation also for CS group B (CS-B) fibroblasts by DNA migration in the "comet assay" and extend these findings to other lesions such as 8-oxodeoxyguanosine (8-oxodG), selectively induced by KBrO3 treatment. In contrast, X-ray exposure does not induce differential DNA breakage. This indicates that additional lesions other than the UV-induced photoproducts (cyclobutane pyrimidine dimers, CPD, and 6-pyrimidine-4-pyrimidone products, 6-4 PP), such as 8-oxodG, specifically induced by KBrO3, are likely to trigger "uncontrolled" DNA breakage in the undamaged genomic DNA in the CS-B fibroblasts, thus accounting for some of the clinical features of these patients.

Werner's syndrome protein is required for correct recovery after replication arrest and DNA damage induced in S-phase of cell cycle.

Werner's syndrome (WS) is a rare autosomal recessive disorder that arises as a consequence of mutations in a gene coding for a protein that is a member of RecQ family of DNA helicases, WRN. The cellular function of WRN is still unclear, but on the basis of the cellular phenotypes of WS and of RecQ yeast mutants, its possible role in controlling recombination and/or in maintenance of genomic integrity during S-phase has been envisaged. With the use of two drugs, camptothecin and hydroxyurea, which produce replication-associated DNA damage and/or inhibit replication fork progression, we find that WS cells have a slower rate of repair associated with DNA damage induced in the S-phase and a reduced induction of RAD51 foci. As a consequence, WS cells undergo apoptotic cell death more than normal cells, even if they arrest and resume DNA synthesis at an apparently normal rate. Furthermore, we report that WS cells show a higher background level of DNA strand breaks and an elevated spontaneous induction of RAD51 foci. Our findings support the hypothesis that WRN could be involved in the correct resolution of recombinational intermediates that arise from replication arrest due to either DNA damage or replication fork collapse.

Enhancement of genetic instability in human B cells by Epstein-Barr virus latent infection.

The level of genetic instability, as assessed by micronucleus (MN) formation, was higher in Epstein-Barr virus (EBV)-converted B-cell lines with one copy of the EBV genome integrated in each cell than in the parental, EBV-negative, B lymphoma cells. MN induced by EBV latency, as analysed by in situ hybridization, contained mainly centromeric regions, indicating that the presence of EBV affects the segregation of entire chromosomes. The instability was inhibited by treatment with antioxidants. Flow cytometric analysis indicated that there was a higher basal level of peroxides in EBV(+) cells. Direct oxidative stress caused by hydrogen peroxide (which is known to be both apoptogenic and mutagenic) enhanced the number of MN only in an EBV-converted clone. These cells were also resistant to apoptosis, as expected, suggesting that in the parental EBV cells apoptosis may efficiently eliminate cells with genetic damage. These results show for the first time a direct involvement of EBV in the induction of genetic instability, suggesting that it could contribute to tumour progression.

HUman MicroNucleus project: international database comparison for results with the cytokinesis-block micronucleus assay in human lymphocytes: I. Effect of laboratory protocol, scoring criteria, and host factors on the frequency of micronuclei.

Micronucleus (MN) expression in peripheral blood lymphocytes is well established as a standard method for monitoring chromosome damage in human populations. The first results of an analysis of pooled data from laboratories using the cytokinesis-block micronucleus (CBMN) assay and participating in the HUMN (HUman MicroNucleus project) international collaborative study are presented. The effects of laboratory protocol, scoring criteria, and host factors on baseline micronucleated binucleate cell (MNC) frequency are evaluated, and a reference range of "normal" values against which future studies may be compared is provided. Primary data from historical records were submitted by 25 laboratories distributed in 16 countries. This resulted in a database of nearly 7000 subjects. Potentially significant differences were present in the methods used by participating laboratories, such as in the type of culture medium, the concentration of cytochalasin-B, the percentage of fetal calf serum, and in the culture method. Differences in criteria for scoring micronuclei were also evident. The overall median MNC frequency in nonexposed (i.e., normal) subjects was 6.5 per thousand and the interquartile range was between 3 and 12 per thousand. An increase in MNC frequency with age was evident in all but two laboratories. The effect of gender, although not so evident in all databases, was also present, with females having a 19% higher level of MNC frequency (95% confidence interval: 14-24%). Statistical analyses were performed using random-effects models for correlated data. Our best model, which included exposure to genotoxic factors, host factors, methods, and scoring criteria, explained 75% of the total variance, with the largest contribution attributable to laboratory methods.

X-ray-induced chromosome aberrations in human lymphocytes in vitro are potentiated under simulated microgravity conditions (Clinostat).

The influence of simulated microgravity weightlessness on the outcome of radiation-induced chromosomal aberrations was investigated using the clinostat as a tool to simulate weightlessness conditions. Treatments were performed in the G0 phase of human lymphocytes with 1.5 Gy of X-rays alone or in combination with the DNA synthesis inhibitor of 1-beta-D-arabinofuranosylcytosine (ara-C) to check also for possible specific radiation-induced DNA repair processes impairment (excision repair caused by base damage) under microgravity conditions. The results obtained, which confirmed previous findings, showed significantly higher increases of aberrant cells and hence total number of aberrations compared to the parallel treatments performed 'on ground'. For what concern ara-C its contribution in terms of potentiation in the induction of aberrant cells was equivalent in absolute terms under simulated microgravity conditions and 'on ground' indicating that excision repair caused by base damage and inhibited by ara-C is not affected by simulated microgravity. A possible explanation for this outcome could quote two major factors: i) Enhanced probability that under simulated microgravity conditions the reactive DSB are spatially brought together to better interact, hence increasing the probability of mis-rejoining. ii) Alternatively chromatin structure could be modified under simulated microgravity conditions generating different quality and quantities of DNA lesions compared to treatments performed 'on ground'.

Werner's syndrome cell lines are hypersensitive to camptothecin-induced chromosomal damage.

Werner's syndrome (WS) is a recessive human genetic disorder associated with an elevated incidence of many types of cancer. The WS gene product, WRNp, belongs to the RecQ family of DNA helicases and is required for the maintenance of genomic stability in human cells. A possible interaction between helicases and topoisomerases that could co-operate in many aspects of DNA metabolism such as progression of the replication forks, recombination and repair has been recently suggested. In addition, sgs1 gene product in yeast, homologous to WS gene, has been shown to physically interact with topoisomerase types I and II. Earlier data from our laboratory suggested that WRN helicase might play a role in a G2 recombinational pathway of double strand breaks (DSBs) repair, co-operating with topoisomerase II. In this work, the effect of the topoisomerase I inhibitor camptothecin in WS cells has been investigated at the chromosomal level. The data from the present work suggest that the inhibition of topoisomerase I activity by camptothecin results in a higher induction of chromosomal damage in WS cell lines in the G2-phase and in the S-phase of the cell cycle compared to normal cells, perhaps associated with the defects in DNA replication synthesis.

Evidence that camptothecin-induced aberrations in the G(2) phase of cell cycle of Chinese hamster ovary (CHO) cell lines is associated with transcription.

It is widely accepted that camptothecin (CPT) is an S-dependent genotoxin. In this study, we aimed to elucidate the 'puzzling' induction of chromosomal damage by CPT in the G(2) phase of CHO cells, where no DNA synthesis is expected, focusing the attention on the possible role of the ongoing RNA synthesis, supposed to cause the conversion of CPT-single stranded cleavage complexes spaced closely on opposite DNA strands into DNA double strand breaks (DSB's) by the action of traversing RNA polymerase.CHO AA8 and its parental mutant EM9 cell lines were pre-treated with alpha-amanitin, which prevents transcription to pre-m-RNA and challenged cells with CPT for the last hour in culture to evaluate whether G(2)-CPT-induced aberrations would have been reduced or abolished in the absence of RNA synthesis compared with G(2)-CPT treatment alone. The results obtained indicated a marked and significant reduction of aberration yields, to almost the control values (alpha-amanitin alone) when inhibition of RNA synthesis was substantial (3h total alpha-amanitin). Partial inhibition of RNA synthesis (2h total alpha-amanitin) slightly reduced the CPT-induced aberrations yield only at the high dose-level employed of CPT (20mM). This finding strongly supports the hypothesis that CPT-single stranded cleavages complexes spaced closely on opposite DNA strands are converted into DNA double strand breaks by the action of traversing RNA polymerase.

Catalytic inhibition of topoisomerase II in Werner's syndrome cell lines enhances chromosomal damage induced by X-rays in the G2 phase of the cell cycle.

PURPOSE: To investigate whether catalytic topoisomerase II activity by ICRF187, a compound that interferes with the catalytic cycle of topoisomerase II without causing DNA damage, could result in a modulation of X-ray-induced chromosomal damage in Werner's syndrome (WS) cell lines. MATERIALS AND METHODS: Two WS (KO375, DJG) and one normal lymphoblastoid cell line (SNW646) were exposed to X-rays, post-treated with ICRF187 and harvested after various recovery times. Cell progression to mitosis was monitored by 5-bromo-2'-deoxyuridine (BrdUrd) and fluorescent immmunodetection to analyse chromosomal damage in homogeneous treated cell populations in the G1, S or G2 phase of the cell cycle. RESULTS: In WS cell lines, catalytic inhibition of topoisomerase II activity by ICRF187 resulted in potentiation of X-ray- induced chromosomal damage in the G2 phase of the cell cycle. This potentiation was not observed in the G1 or S phases of the cell cycle, neither in WS nor normal cells. CONCLUSION: These results point out the possibility that Werner's syndrome protein (WRNp) might play a role in a G2 recombinational pathway of double-strand break repair, cooperating with topoisomerase II and thus contributing to maintain genomic integrity.

Werner's syndrome lymphoblastoid cells are hypersensitive to topoisomerase II inhibitors in the G2 phase of the cell cycle.

Werner's syndrome (WS) is a rare autosomal recessive human disorder and the patients exhibit many symptoms of accelerated ageing in their early adulthood. The gene (WRN) responsible for WS has been biochemically characterised as a 3'-5' helicase and is homologous to a number of RecQ superfamily of helicases. The yeast SGS1 helicase is considered as a human WRN homologue and SGS1 physically interacts with topoisomerases II and III. In view of this, it has been hypothesised that the WRN gene may also interact with topoisomerases II and III. The purpose of this study is to determine whether the loss of function of WRN protein alters the sensitivity of WS cells to agents that block the action of topoisomerase II. This study deals with the comparison of the chromosomal damage induced by the two anti-topoisomerase II drugs, VP-16 and amsacrine, in both G1 and G2 phases of the cell cycle, in lymphoblastoid cells from WS patients and from a healthy donor. Our results show that the WS cell lines are hypersensitive to chromosome damage induced by VP-16 and amsacrine only in the G2 phase of the cell cycle. No difference either in the yield of the induced aberrations or SCEs was found after treatment of cells at G1 stage. These data might suggest that in WS cells, because of the mutation of the WRN protein, the inhibition of topoisomerase II activity results in a higher rate of misrepair, probably due to some compromised G2 phase processes involving the WRN protein.

Lack of effect of caffeine post-treatment on X-ray-induced chromosomal aberrations in Werner's syndrome lymphoblastoid cell lines: a preliminary report.

PURPOSE: To investigate whether in Werner's syndrome cells the G2 phase of the cell cycle has some abnormal response to post-treatment with agents such as caffeine and hydroxyurea known to interfere with cellular response to DNA damage. MATERIALS AND METHODS: Two Werner's syndrome lymphoblastoid cell lines (KO375 and DJG) and the normal cell line SNW646 were exposed to 50 cGy of X-rays or mitomycin-C and posttreated with caffeine or hydroxyurea in the G2 phase of the cell cycle. RESULTS: Hydroxyurea post-treatment potentiated the X-ray-induced aberration levels both in the normal and Werner's syndrome (KO375 and DJG) cell lines; in contrast caffeine was only effective in the normal cell line. Similar results were observed when Werner's syndrome cells were treated in the G1 phase with the S-dependent agent mitomycin-C and post-treated with caffeine in G2, extending the observation that Werner's syndrome cells are unaffected by caffeine G2 post-treatment. CONCLUSIONS: These results show a lack of caffeine effect in Werner's syndrome cells, suggesting an involvement of the Werner's syndrome protein in the signal transduction pathway by which caffeine could override the DNA damage induced G2 checkpoint.

The involvement of chromatin condensation in camptothecin-induced chromosome breaks in G0 human lymphocytes.

In the present study we evaluated campthotecin (CPT)-induced chromosomal damage in human lymphocytes in the G0 phase of the cell cycle as revealed by the premature chromosome condensation technique. The results obtained here indicate that CPT was able to induce chromosome fragments in the G0 phase of the cell cycle of human lymphocytes as detected in prematurely condensed chromosomes. This result appears to be rather surprising, since the DNA lesions produced by CPT (e.g. 'protein concealed' DNA single-strand breaks) should not produce any damage in G0. A possible explanation for this result could come from much evidence to suggest that chromatin condensation processes are significantly involved in the conversion of DNA lesions into chromosome breaks in prematurely condensed chromosomes. The unexpected clastogenic behaviour of CPT can be explained taking into account the chromosome condensation induced by mitosis promoting factors when human lymphocytes are fused in G0, thus converting the 'protein concealed' DNA single-strand breaks induced by CPT into chromosome breaks. The same perspective should be taken into consideration for breaks induced by CPT under normal physiological conditions in the G2 phase of the cell cycle.

Chromosome radiosensitivity in human G2 lymphocytes and cell-cycle progression.

PURPOSE: To investigate the possibility that the differential G2-phase radiosensitivity of human peripheral blood lymphocytes, found in normal individuals using the 'G2-phase chromosome radiosensitivity assay', could be attributed to heterogeneity in cellular progression to mitosis rather than differences in radiosensitivity. MATERIALS AND METHODS: Human peripheral blood lymphocytes, from four different donors, were exposed to 50 cGy X-rays and sampled at different times. The progression of cells into mitosis was monitored by 5-bromo 2'-deoxyuridine (BrdUrd) incorporation. RESULTS: The heterogeneous G2-phase chromosome radiosensitivity among different donors was abolished when homogeneous G2-phase cell populations were scored; they contained similar frequencies of cells in early or late G2-phase. CONCLUSIONS: The heterogeneous G2-phase chromosome radiosensitivity, usually found in different normal donors, is caused by the analysis of different cell populations rather than reflecting intrinsic differences in radiosensitivity.

Caffeine effect on the mitotic delay induced by G2 treatment with UVC or mitomycin C.

It is well established that DNA lesions trigger cell cycle check-points causing a mitotic delay that is required for their repair before cells enter the mitotic phase. Caffeine, in some cases, can remove this delay and consequently potentiates the yield of induced chromosome aberrations. The objective of this study was to test the effect of a G2 treatment with S-dependent agents (UV light and mitomycin C) on the cell kinetics of a G2 cell population and evaluate whether post-treatments with caffeine could modulate removal of the expected cell cycle delay. Cell kinetics were monitored by analysing the mitotic index (MI) values in combination with the 5-bromo-2'-deoxyuridine (BrdUrd) labelling technique. Chinese hamster fibroblast cultures (AA8) were treated in G2 phase of the cell cycle with 8 and 15 J/m2 UV light or 0.1 and 0.6 microgram/ml mitomycin C for 1.5 h. Post-treatments with caffeine were performed at dose levels and recovery times where the mitotic indices were substantially reduced. The results obtained showed that both UV light and mitomycin C induced a G2 arrest, as indicated by MI values and the absence of BrdUrd-labelled metaphases. For UV light the G2 block was observed at lower and higher dose levels after 1.5 h, while for mitomycin C it was observed only at the higher dose level after 1 h. However, in both cases the block lasted approximately 1 h, after which, even though slowed down, the cell population entered mitosis, as indicated by increased MI values. This block was not removed by caffeine post-treatment. In contrast, caffeine G2 post-treatment was able to remove G2 arrest induced by G1-S treatments. Accordingly, our results suggest that both UV light- and mitomycin C-induced damage must be processed during S phase to allow caffeine to remove induced G2 blocks.

Distribution of camptothecin-induced break points in Chinese hamster cells treated in late S and G2 phases of the cell cycle.

The distribution of camptothecin (CPT)-induced break points in late S or G2 phase of the cell cycle observed in Chinese hamster chromosomes was analysed in 400 metaphases. Contrary to expectation, they were not localized in the heterochromatic regions, suggesting that these chromatid-type aberrations arise by a mechanism which does not involve collision of the CPT-trapped 'cleavable complex' with the replication fork. Since many break points mapped more frequently to light bands (DAPI negative) than dark bands (DAPI positive) with a frequency of 73 and 15% respectively, it could be argued that the presence of the CPT-trapped 'cleavable complex' probably interferes with chromatin condensation. In fact, the euchromatic regions, which are expected to be more actively condensed in G2 phase, were more involved in chromosomal damage. These results do not completely confirm the idea that some residual DNA synthesis occurring in G2 is responsible for the G2 clastogenic effects of CPT as the heterochromatic regions should, in this case, be more involved.

Induction of chromosomal aberrations (unstable and stable) by inhibitors of topoisomerase II, m-AMSA and VP16, using conventional Giemsa staining and chromosome painting techniques.

Frequencies of symmetrical and asymmetrical exchange aberrations induced by two inhibitors of topoisomerase II, namely, 4'-(9-acridinylamino) methanesulfon-m-anisidide (m-AMSA) and etoposide (VP16), were estimated in human peripheral blood lymphocytes. The aberrations were scored using conventional Giemsa staining and fluorescence in situ hybridization (FISH) techniques, using chromosome-specific DNA libraries. Stable aberrations (translocations) were detected using two cocktails of DNA libraries specific for three chromosomes, namely 1, 3 and X and 2, 4 and 8, representing approximately 40% of the whole human genome. The frequencies of dicentrics and translocations increased in a dose-dependent manner, however, m-AMSA was found to be a more potent inducer of chromosomal aberrations in comparison with VP16 (at concentrations at which comparable frequencies of aberrations were induced) by 20- to 30-fold. When corrected for DNA content of chromosomes in each cocktail, a higher frequency of translocations with the cocktail consisting of chromosomes 2, 4 and 8 in comparison with 1, 3 and X was evident. The genomic translocation frequency calculated from chromosome painting analysis for m-AMSA exceeded that estimated for dicentrics by approximately 2-fold. However, for VP16 almost equal frequencies of both types of chromosome exchange were found.

Evaluation of bleomycin-induced chromosome aberrations under simulated microgravity conditions in human lymphocytes using "FISH" techniques.

In the present investigation we report the effects of simulated microgravity conditions (clinostat) on the induction of chromosomal aberrations in human lymphocytes in vitro by (R) Bleomycin. Chromosomal aberrations have been analysed by means of fluorescent in situ hybridisation (FISH) and chromosome-specific composite DNA probes (chromosome painting). The results obtained show that, under simulated microgravity conditions, the levels of both symmetrical and asymmetrical (dicentrics, rings), the number of cells bearing "complex" aberrations and hence the total numbers of aberrations were significantly elevated at any of the dose-levels assayed, compared to the parallel treatments performed as 1g control ("ground"). Furthermore, the ratio symmetrical:asymmetrical translocations was markedly elevated under simulated microgravity conditions, compared to the findings usually observed under "normal" 1g conditions. On these bases, we are much inclined to believe that simulated microgravity, rather than limiting the resealing of DNA double strand breaks (DSB's) induced by genotoxic agents is influencing in terms of enhancement the misrejoining of DSB's which is actually responsible for the fixation of the original lesions to DNA into chromosomal aberrations. In addition, the possible different misrepair processes leading to the formation of symmetrical and asymmetrical translocations might be differentially influenced by microgravity being the symmetrical translocations significantly more represented.

Evaluation of cytogenetic effects of a naturally occurring non-ice-nucleation Pseudomonas fluorescens strain in Chinese hamster ovary (CHO) cells.

One of the main methods for eliminating ice-nucleation-active (INA+) bacteria the micro-organisms responsible for frost injuries to plants at mild freezing temperatures, is the use, as competitors, of other naturally occurring non-nucleating strains (non-INA). In the present article we investigated the cytogenetic effects of a naturally occurring non-INA strain of Pseudomonas fluorescens (MS 1640 R3), evaluating the induction of chromosomal aberrations and sister chromatid exchanges (SCEs) in Chinese hamster ovary (CHO) cells in the absence and presence of rat S9 metabolism. The results obtained did not show any increase in either chromosomal aberrations or SCEs, both in the absence and presence of rat S9 metabolism when used as i) intact bacteria cells, ii) sonicated bacteria (i.e., potential endotoxins), or iii) metabolic bacterial products (i.e., potential exotoxins) released in the growth medium.