Global DNA Damage Research Articles

The different genetic alterations between Western and Chinese prostate cancers and the underlying mechanisms.

184 Background: Prostate cancer shows a wide variation in the clinical incidence and mortality rates of different geographical regions. While it is the most common male cancer in Western countries, it is much less frequent in Asian countries. We investigated genomic changes in prostate cancers from UK and China using microarrays to determine the genetic similarities and differences as well as the underlying mechanisms. Methods: We determined genome-wide genomic alterations using Affymetrix SNP array 6.0, and evaluated data using fluorescence in situ hybridisation (FISH) and immunohistochemistry. In addition, we assess androgen induced TMPRSS2 and ERG co-localization and fusion. Microsatellite analysis was used for AR CAG repeat polymorphism in UK and Chinese population. Results: Genome-wide analysis of 32 UK and 39 Chinese samples revealed that losses of 21q22 (leading to TMPRSS2:ERG fusion) and 10q23.3 (PTEN) were at much higher frequency in Western than Chinese prostate cancers. Using FISH analysis of 160 UK and 143 Chinese samples, we showed that PTEN deletion and ERG rearrangements were at a significantly higher frequency in samples from UK than China (p<0.001 for both). We found that PTEN and ERG protein were also differentially expressed (p<0.001) in the two populations. Investigating this further, we induced TMPRSS2 and ERG gene proximity and TMPRSS2:ERG fusion in two immortalised prostate epithelial cell lines by exposure to high dose of androgen. This androgen treatment did not cause increased global DNA damage but was associated with low expression of PIWIL1, which is involved in repairing double-strand breaks. Overexpression of PIWIL1 by transfection inhibited androgen induced TMPRSS2:ERG fusion. We found that AR CAG repeat lengths, which associated with AR activity, are significantly shorter in the UK than Chinese patients (p<0.05). Conclusions: We revealed genomic differences in prostate cancer comparing the high-risk (Western) and low-risk (Chinese) populations. We further demonstrated that TMPRSS2:ERG fusion can be induced by androgen. The difference of CAG repeat length between the two populations are potentially associated with TMPRSS2:ERG fusion positive prostate cancers.

Evaluation of DNA Single and Double Strand Breaks in Women with Cervical Neoplasia Based on Alkaline and Neutral Comet Assay Techniques

A hospital-based unmatched case-control study was performed in order to determine the relation of DNA single (ssb) and double (dsb) strand breaks in women with and without cervical neoplasia. Cervical epithelial cells of 30 women: 10 with low grade squamous intraepithelial lesions (LG-SIL), 10 with high-grade SIL (HG-SIL), and 10 without cervical lesions were evaluated using alkaline and neutral comet assays. A significant increase in global DNA damage (ssb + dsb) and dsb was observed in patients with HG-SIL (48.90 ± 12.87 and 23.50 ± 13.91), patients with LG-SIL (33.60 ± 14.96 and 11.20 ± 5.71), and controls (21.70 ± 11.87 and 5.30 ± 5.38; resp.). Pearson correlation coefficient reveled a strong relation between the levels ssb and dsb (r2 = 0.99, P = 0.03, and r2 = 0.94, P = 0.16, resp.) and progression of neoplasia. The increase of dsb damage in patients with HG-SIL was confirmed by DNA breakage detection-FISH (DBD-FISH) on neutral comets. Our results argue in favor of a real genomic instability in women with cervical neoplasia, which was strengthened by our finding of a higher proportion of DNA dsb.

Regulation of nucleotide excision repair through ubiquitination

Nucleotide excision repair (NER) is the most versatile DNA-repair pathway in all organisms. While bacteria require only three proteins to complete the incision step of NER, eukaryotes employ about 30 proteins to complete the same step. Here we summarize recent studies demonstrating that ubiquitination, a post-translational modification, plays critical roles in regulating the NER activity either dependent on or independent of ubiquitin-proteolysis. Several NER components have been shown as targets of ubiquitination while others are actively involved in the ubiquitination process. We argue through this analysis that ubiquitination serves to coordinate various steps of NER and meanwhile connect NER with other related pathways to achieve the efficient global DNA-damage response.

Abstract C82: Identification and preclinical characterization of inhibitors of the ubiquitin-activating enzymes UBA1 and UBA6.

Abstract Millennium Pharmaceuticals, Inc. is dedicated to the discovery and development of novel oncology therapeutics in the area of protein homeostasis. Here we report the identification and characterization of compounds that target the ubiquitin activating enzymes, UBA1 and UBA6. These compounds are mechanism based inhibitors that inactivate the ubiquitin E1 enzymes by forming a ubiquitin compound adduct that remains tightly associated with the E1 adenylate binding site. Treatment of cells with these inhibitors results in cellular effects consistent with known Uba1 biology including rapid loss of E2 ubiquitin thioesters, loss of total ubiquitin conjugates, and accumulation of many ubiquitin proteasome system substrates. Following prolonged treatment, cells primarily arrest in the G2 phase of the cell cycle and ultimately undergo apoptosis. Reflecting the extensive cellular roles of ubiquitin, the compounds also impact global protein turnover, ER stress and DNA damage repair. UBA1 inhibition impairs ubiquitination of PCNA and the Fanconia Anemia protein FANCD2 leading to defective repair of UV induced DNA damage. UBA1 inhibition impacts numerous biological pathways relevant to cancer, results in apoptosis in vitro and is capable of inhibiting tumor growth in mouse xenografts in vivo. These data implicate UBA1 as a target for the treatment of cancer. Citation Format: {Authors}. {Abstract title} [abstract]. In: Proceedings of the AACR-NCI-EORTC International Conference: Molecular Targets and Cancer Therapeutics; 2011 Nov 12-16; San Francisco, CA. Philadelphia (PA): AACR; Mol Cancer Ther 2011;10(11 Suppl):Abstract nr C82.

Characterization of the Human Artemis Promoter by Heterologous Gene Expression In Vitro and In Vivo

Artemis is an endonucleolytic enzyme involved in nonhomologous double-strand break repair and V(D)J recombination. Deficiency of Artemis results in a B- T- radiosensitive severe combined immunodeficiency, which may potentially be treatable by Artemis gene transfer into hematopoietic stem cells. However, we recently found that overexpression of Artemis after lentiviral transduction resulted in global DNA damage and increased apoptosis. These results imply the necessity of effecting natural levels of Artemis expression, so we isolated a 1 kilobase DNA sequence upstream of the human Artemis gene to recover and characterize the Artemis promoter (APro). The sequence includes numerous potential transcription factor-binding sites, and several transcriptional start sites were mapped by 5' rapid amplification of cDNA ends. APro and deletion constructs conferred significant reporter gene expression in vitro that was markedly reduced in comparison to expression regulated by the human elongation factor 1-α promoter. Ex vivo lentiviral transduction of an APro-regulated green fluorescent protein (GFP) construct in mouse marrow supported GFP expression throughout hematopoeitic lineages in primary transplant recipients and was sustained in secondary recipients. The human Artemis promoter thus provides sustained and moderate levels of gene expression that will be of significant utility for therapeutic gene transfer into hematopoeitic stem cells.

The dynamics of E1A in regulating networks and canonical pathways in quiescent cells

BackgroundAdenoviruses force quiescent cells to re-enter the cell cycle to replicate their DNA, and for the most part, this is accomplished after they express the E1A protein immediately after infection. In this context, E1A is believed to inactivate cellular proteins (e.g., p130) that are known to be involved in the silencing of E2F-dependent genes that are required for cell cycle entry. However, the potential perturbation of these types of genes by E1A relative to their functions in regulatory networks and canonical pathways remains poorly understood.FindingsWe have used DNA microarrays analyzed with Bayesian ANOVA for microarray (BAM) to assess changes in gene expression after E1A alone was introduced into quiescent cells from a regulated promoter. Approximately 2,401 genes were significantly modulated by E1A, and of these, 385 and 1033 met the criteria for generating networks and functional and canonical pathway analysis respectively, as determined by using Ingenuity Pathway Analysis software. After focusing on the highest-ranking cellular processes and regulatory networks that were responsive to E1A in quiescent cells, we observed that many of the up-regulated genes were associated with DNA replication, the cell cycle and cellular compromise. We also identified a cadre of up regulated genes with no previous connection to E1A; including genes that encode components of global DNA repair systems and DNA damage checkpoints. Among the down-regulated genes, we found that many were involved in cell signalling, cell movement, and cellular proliferation. Remarkably, a subset of these was also associated with p53-independent apoptosis, and the putative suppression of this pathway may be necessary in the viral life cycle until sufficient progeny have been produced.ConclusionsThese studies have identified for the first time a large number of genes that are relevant to E1A's activities in promoting quiescent cells to re-enter the cell cycle in order to create an optimum environment for adenoviral replication.

Dyskeratosis congenita and the DNA damage response

Dyskeratosis congenita (DC) is a heterogeneous bone marrow failure disorder with known mutations in components of telomerase and telomere shelterin. Recent work in a mouse model with a dyskerin mutation has implicated an increased DNA damage response as part of the cellular pathology, while mouse models with Terc and Tert mutations displayed a normal response. To clarify how these contradictory results might apply to DC pathology in humans, we studied the cellular phenotype in primary cells from DC patients of several genetic subtypes, focussing on T lymphocytes to remain close to the haematopoietic system. We observed novel cell cycle abnormalities in conjunction with impaired growth and an increase in apoptosis. Using flow cytometry and confocal microscopy we examined induction of the DNA damage proteins γ-H2AX and 53BP1 and the cell cycle protein TP53 (p53). We found an increase in damage foci at telomeres in lymphocytes and an increase in the basal level of DNA damage in fibroblasts, but crucially no increased response to DNA damaging agents in either cell type. As the response to induced DNA damage was normal and levels of global DNA damage were inconsistent between cell types, DNA damage may contribute differently to the pathology in different tissues.

Nucleotide Excision Repair Proteins Rapidly Accumulate but Fail to Persist in Human XP‐E (DDB2 Mutant) Cells

The xeroderma pigmentosum (XP-E) DNA damage binding protein (DDB2) is involved in early recognition of global genome DNA damage during DNA nucleotide excision repair (NER). We found that skin fibroblasts from four newly reported XP-E patients with numerous skin cancers and DDB2 mutations had slow repair of 6-4 photoproducts (6-4PP) and markedly reduced repair of cyclobutane pyrimidine dimers (CPD). NER proteins (XPC, XPB, XPG, XPA and XPF) colocalized to CPD and 6-4PP positive regions immediately (<0.1 h) after localized UV irradiation in cells from the XP-E patients and normal controls. While these proteins persist in normal cells, surprisingly, within 0.5 h these repair proteins were no longer detectable at the sites of DNA damage in XP-E cells. Our results indicate that DDB2 is not required for the rapid recruitment of NER proteins to sites of UV photoproducts or for partial repair of 6-4PP but is essential for normal persistence of these proteins for CPD photoproduct removal.

Multiple roles for MRE11 at uncapped telomeres

Progressive telomere attrition or uncapping of the shelterin complex elicits a DNA damage response (DDR) as a result of a cell’s inability to distinguish dysfunctional telomeric ends from DNA double-strand breaks (DSBs)1. Telomere deprotection activates both ataxia telangiectasia mutated (ATM) and telangiectasia and Rad3-related (ATR) kinase dependent DDR pathways and promotes efficient non-homologous end-joining (NHEJ) of dysfunctional telomeres2–5. The mammalian Mre11-Rad50-NBS1 (MRN) complex interacts with ATM to sense chromosomal DSBs and coordinate global DNA damage responses6, 7. While the MRN complex accumulates at dysfunctional telomeres, it is not known whether mammalian MRN promotes repair at these sites. Here we address this question by utilizing mouse alleles that either inactivate the entire MRN complex or eliminate only the nuclease activities of Mre118. Cells lacking MRN do not activate ATM when telomeric repeat binding factor 2 (TRF2) is removed from telomeres, and Ligase 4 (Lig4) dependent chromosome end-to-end fusions are markedly reduced. Residual chromatid fusions involve only telomeres generated by leading strand synthesis. Strikingly, while cells deficient for Mre11 nuclease activity efficiently activate ATM and recruit 53BP1 to deprotected telomeres, the 3’ telomeric overhang persists to prevent NHEJ-mediated chromosomal fusions. Removal of shelterin proteins that protect the 3’ overhang in the setting of Mre11 nuclease deficiency restores Lig4 dependent chromosome fusions. Our data suggest a critical role for the MRN complex in sensing dysfunctional telomeres, with Mre11 nuclease activity required to remove the 3’ telomeric overhang to promote chromosome fusion. Mre11 is also required to protect newly replicated leading strand telomeres from engaging the NHEJ pathway, likely by promoting 5’ strand resection to generate Pot1a-TPP1 bound 3’ overhangs that prevents NHEJ.

Transcript profiling and DNA damage in the European eel ( Anguilla anguilla L.) exposed to 7,12-dimethylbenz[a]anthracene

The molecular responses induced during and after an acute exposure to 7,12-dimethylbenz[a]anthracene (DMBA) were analysed in liver, gill and blood cells of juvenile Anguilla anguilla with the aim of developing molecular biomarkers of environmental PAH pollution. Changes in the mRNA expression levels of the cell cycle checkpoint-related rad1 gene and the mRNAs of differentially expressed genes by suppression subtractive hybridization (SSH) were analysed in the liver, and related to well-established biomarkers: cyp1A1 mRNA expression and assessment of the DNA integrity using the comet assay and flow cytometry. DMBA exposure resulted in increased cyp1A1 mRNA levels, suggesting that cyp1A1 might be involved in the metabolism of DMBA. Global DNA damage, detected by the comet assay, was observed in the three tissues analysed but only blood cells showed chromosomal lesions as analysed by flow cytometry. Although DNA damage was found in the liver, no induction in rad1 gene was observed in this organ. The global SSH approach revealed that mRNAs of genes related to xenobiotic metabolism, immune processes and cytoskeleton dynamics were differentially expressed in DMBA-exposed eel livers, highlighting the complexity in the response observed in fish exposed to a genotoxic agent and providing directions for new biomarker development.

Angiotensin II–Mediated Oxidative DNA Damage Accelerates Cellular Senescence in Cultured Human Vascular Smooth Muscle Cells via Telomere-Dependent and Independent Pathways

Angiotensin II (Ang II) induces reactive oxygen species (ROS) production by human vascular smooth muscle cells (hVSMCs). ROS have been implicated in the development of both acute stress-induced premature senescence (SIPS) and chronic replicative senescence. Global oxidative DNA damage triggers SIPS and telomere DNA damage accelerates replicative senescence, both mediated via p53. This study tests the hypothesis that DNA is an important target for Ang II-induced ROS leading to senescence via telomere-dependent and independent pathways. DNA damage was quantified using the Comet assay, telomere DNA length by Southern blotting and hVSMC senescence by senescence-associated beta-galactosidase staining. Exposure to Ang II increased DNA damage in hVSMCs within 4 hours. Inhibition by an AT1 receptor antagonist (losartan metabolite: E3174) or catalase, confirmed that Ang II-induced DNA damage was AT1 receptor-mediated, via the induction of ROS. Acute exposure to Ang II resulted in SIPS within 24 hours that was prevented by coincubation with E3174 or catalase. SIPS was associated with increased p53 expression but was not dependent on telomere attrition because overexpression of human telomerase did not prevent Ang II-induced SIPS. Exposure to Ang II over several population doublings accelerated the rate of telomere attrition (by >2-fold) and induced premature replicative senescence of hVSMCs--an effect that was also attenuated by E3174 or catalase. These data demonstrate that Ang II-induced ROS-mediated DNA damage results in accelerated biological aging of hVSMCs via 2 mechanisms: (1) Acute SIPS, which is telomere independent, and (2) accelerated replicative senescence which is associated with accelerated telomere attrition.

Sequence-specific oxidative base modifications in hypoxia-inducible genes

Reactive oxygen species associated with hypoxic signaling in pulmonary arterial endothelial cells (PAECs) oxidatively modify specific nucleotides in the hypoxic response element (HRE) of the VEGF gene ( FASEB J. 19:387–394; 2005). In this study, we determined in PAECs if hypoxia caused genome-wide oxidative modifications or if they were restricted to the promoters of genes differentially regulated by hypoxia. Comet assays indicated that there were no differences between normoxic and hypoxic PAECs in terms of global DNA damage. However, a simple PCR-based method involving DNA amplification before and after treatment with formamidopyrimidine DNA glycosylase (Fpg), a bacterial DNA repair enzyme that cleaves at sites of purine base oxidation, revealed that hypoxia caused modifications in the HREs of the hypoxia-inducible VEGF, HO-1, and ET-1 genes which coincided with accumulation of their respective mRNA transcripts. Promoter sequences not involved with hypoxic induction and coding regions of these genes failed to display Fpg-sensitive sites. Oxidative modifications also were not detected in sequences of the hypoxia down-regulated ornithine decarboxylase and TFAM genes or the constitutively expressed β-actin gene. These findings show that hypoxia-mediated oxidative DNA modifications cluster in functionally relevant promoter sequences in hypoxia-inducible genes and suggest that such oxidative modifications may be biologically significant.

Ataxia Telangiectasia-Mutated–Dependent DNA Damage Checkpoint Functions Regulate Gene Expression in Human Fibroblasts

The relationships between profiles of global gene expression and DNA damage checkpoint functions were studied in cells from patients with ataxia telangiectasia (AT). Three telomerase-expressing AT fibroblast lines displayed the expected hypersensitivity to ionizing radiation (IR) and defects in DNA damage checkpoints. Profiles of global gene expression in AT cells were determined at 2, 6, and 24 h after treatment with 1.5-Gy IR or sham treatment and were compared with those previously recognized in normal human fibroblasts. Under basal conditions, 160 genes or expressed sequence tags were differentially expressed in AT and normal fibroblasts, and these were associated by gene ontology with insulin-like growth factor binding and regulation of cell growth. On DNA damage, 1,091 gene mRNAs were changed in at least two of the three AT cell lines. When compared with the 1,811 genes changed in normal human fibroblasts after the same treatment, 715 were found in both AT and normal fibroblasts, including most genes categorized by gene ontology into cell cycle, cell growth, and DNA damage response pathways. However, the IR-induced changes in these 715 genes in AT cells usually were delayed or attenuated in comparison with normal cells. The reduced change in DNA damage response genes and the attenuated repression of cell cycle-regulated genes may account for the defects in cell cycle checkpoint function in AT cells.

Identification and characterization of the immunity repressor (ImmR) that controls the mobile genetic element ICEBs1 of Bacillus subtilis

ICEBs1 is a mobile genetic element found in the chromosome of Bacillus subtilis. Excision and transfer of ICEBs1 is regulated by the global DNA damage response and intercellular peptide signalling. We identified and characterized a repressor, ImmR (formerly YdcN), encoded by ICEBs1. ImmR represses transcription of genes required for excision and transfer, and both activates and represses its own transcription. ImmR regulates transcription within ICEBs1 by binding to several sites in the region of DNA that contains promoters for both immR and xis (encoding excisionase). In addition, we found that ImmR confers immunity from acquisition of additional copies of ICEBs1. ImmR-mediated regulation serves to keep a single copy of ICEBs1 stably maintained in the absence of induction, allows a rapid response to inducing signals, and helps limit acquisition of additional copies of ICEBs1.

Blood mononucleocytes are sensitive to the DNA damaging effects of iron overload— In vitro and ex vivo results with human and rat cells

Iron exposure enhances colorectal carcinogeneis, by producing reactive oxygen species, which damage lipids, proteins and DNA. We recently demonstrated that ferric-nitrilotriacetate (Fe-NTA) damages DNA of human colon cells in different stages of malignant transformation. Opposed to this, little is known on systemic effects of iron and it is still difficult to determine the border between essential iron supplementation and iron overload in humans. The aim of this study was to determine whether Fe-NTA causes global and specific DNA damage in peripheral leucocytes. Human leucocytes were treated in vitro with Fe-NTA for 30 min at 37 °C. Male Sprague Dawley rats were fed (6 weeks) with an iron-overload diet (9.9 g Fe/kg DM) and whole blood was collected. DNA damage was measured in human and rat blood cells using the alkaline version of the Comet Assay with repair specific enzymes. In human cells the distribution of TP53 in the comet images was detected using fluorescence in situ hybridization (Comet FISH) to measure DNA damage in the region of the TP53 gene. Fe-NTA (10–500 μM) was clearly genotoxic in human leucocytes in vitro, and also in leucocytes of rats fed the iron overload diet. The induced damage in human leucocytes was approximately two-fold that observed previously in human colon cells. Oxidized bases were induced by iron in rat leucocytes in vivo, while they were not induced in human leucocytes in vitro. Fe-NTA enhanced the migration of TP53 signals into the comet tail of human leucocytes, indicating a high susceptibility of this tumour-relevant gene towards DNA damage induced by iron overload. In conclusion, iron markedly induced DNA damage in human and rat leucocytes, which shows that these white blood cells are sufficiently sensitive to assess exposure to iron. The measurement of DNA damage in human leucocytes could be used as a sensitive biomarker to study iron overload in vivo in humans and thus to determine whether supplementation results in genotoxic risk.

AP endonuclease deficiency results in extreme sensitivity to thymidine deprivation

Thymidine depletion is toxic to virtually all actively growing cells. The fundamental mechanism responsible for thymidineless death remains unknown. One event thought to be critical in causing the toxicity of thymidine depletion is a sharp rise in the ratio of dUTP to dTTP and subsequent incorporation of dUTP into DNA. Maneuvers to alter dUTP levels appear to alter the toxicity of thymidine depletion. However, loss of uracil-DNA-N-glycosylase activity does not appear to change the toxicity of thymidine deprivation significantly. This study proposes to define the role of uracil base excision repair (BER) in mediating thymidineless death. The toxicity of thymidine deprivation induced by the antifolate aminopterin was measured in a series of mutant Saccharomyces cerevisiae strains deficient in various steps in uracil-BER. Most mutants displayed modest changes in their sensitivity to aminopterin, with the exception of cells lacking the abasic endonuclease Apn1. apn1 mutants displayed a profound sensitivity to aminopterin that was relieved in an apn1 ung1 double mutant. Wild-type and apn1 mutants displayed similar levels of DNA damage and S-phase arrest during aminopterin treatment. A significant portion of cell killing occurred after removal of aminopterin in both wild-type and apn1 mutant cells. apn1 mutants showed a complete inability to re-initiate DNA replication following removal of aminopterin. These findings suggest recovery from arrest is a crucial step in determining the response to thymidine deprivation and that interruptions in uracil-BER increase the toxicity of thymidine deprivation by blocking re-initiation of replication rather than inciting global DNA damage. Inhibition of apurinic/apyrimidinic endonuclease may therefore be a reasonable approach to increase the efficacy of anticancer chemotherapies based on thymidine depletion.

A transcriptional response to replication status mediated by the conserved bacterial replication protein DnaA

Organisms respond to perturbations in DNA replication. We characterized the global transcriptional response to inhibition of DNA replication in Bacillus subtilis. We focused on changes that were independent of the known recA-dependent global DNA damage (SOS) response. We found that overlapping sets of genes are affected by perturbations in replication elongation or initiation and that this transcriptional response serves to inhibit cell division and maintain cell viability. Approximately 20 of the operons (>50 genes) affected have potential DnaA-binding sites and are probably regulated directly by DnaA, the highly conserved replication initiation protein and transcription factor. Many of these genes have homologues and recognizable DnaA-binding sites in other bacteria, indicating that a DnaA-mediated response, elicited by changes in DNA replication status, may be conserved.

Regulation of a Bacillus subtilis mobile genetic element by intercellular signaling and the global DNA damage response

Horizontal gene transfer contributes to the evolution of bacterial species. Mobile genetic elements play an important role in horizontal gene transfer, and characterization of the regulation of these elements should provide insight into conditions that influence bacterial evolution. We characterized a mobile genetic element, ICEBs1, in the Gram-positive bacterium Bacillus subtilis and found that it is a functional integrative and conjugative element (ICE) capable of transferring to Bacillus and Listeria species. We identified two conditions that promote ICEBs1 transfer: conditions that induce the global DNA damage response and crowding by potential recipients that lack ICEBs1. Transfer of ICEBs1 into cells that already contain the element is inhibited by an intercellular signaling peptide encoded by ICEBs1. The dual regulation of ICEBs1 allows for passive propagation in the host cell until either the potential mating partners lacking ICEBs1 are present or the host cell is in distress.

Putative colon cancer risk factors damage global DNA and TP53 in primary human colon cells isolated from surgical samples

This study describes a novel in vitro method in genetic toxicology that is based on detection of chemical-induced DNA damage connected with altered migration of TP53 in primary human colonocytes. Techniques were developed to isolate high numbers of human epithelial colon cells from surgical tissues. High quantities of viable cells were obtained per donor. The primary cells were treated with the endogenous risk factors trans-2-hexenal, and hydrogen peroxide. Global DNA damage and repair were measured by single-cell gel electrophoresis (Comet assay). We compared responses of primary colon cells to HT29clone19A, a differentiated human colon tumour cell line, for which the karyotype was analysed with 24-colour FISH. Both compounds were genotoxic in both cell types and most of the induced DNA damage was repaired after 30 min. Specific migration of TP53 was determined by fluorescence in situ hybridization (Comet FISH). Using primary colon cells, we quantified the migration of TP53 signals into the comet tails. In these cells TP53 was more sensitive than global DNA for genotoxicity induced by trans-2-hexenal and H 2O 2. HT29clone19A cells cannot be used for Comet FISH because of their aberrant karyotype. The approach described allows us to obtain more knowledge of putative risk factors in colon carcinogenesis.

Role of reactive oxygen species in cupric 8-quinolinoxide-induced genotoxic effect

This study demonstrates that cupric 8-quinolinoxide (CuQ) has induced genetic toxicity in bacteria and mammalian cells through a mechanism of reactive oxygen species (ROS) generation. In the Ames test with rat liver S9, CuQ dose-dependently caused a point mutation in Salmonella typhimurium TA100. The effect of CuQ on DNA damage in HL60 and V79 cells identified in the comet assay is direct and enhanced by the addition of S9. Meanwhile, the tailing length of comet DNA is related to the increasing dosage of CuQ. The genotoxic effect of CuQ on either gene mutation in bacteria or DNA damage in culture cells can be generally blocked by several antioxidants, e.g. pyrrolidinedithiocarbamate, N-acetylcysteine, Vitamins C and E. Supportive of this observation, ROS generation induced by CuQ can be demonstrated both in vitro and in vivo by using the DCFH-DA fluoroprobe. The CuQ-induced intracellular ROS level is also dramatically inhibited by the above antioxidants. Above results imply that the CuQ-induced genotoxicity could be mediated by ROS generation. The nature of ferrous-dependent and S9-enhancing in CuQ-induced ROS generation hints a Fenton-like reaction or some specific enzymes activation could be involved in this process. Furthermore, a DNA damage- and oxidative stress-dependent protein, P53, could also been induced by CuQ treatments in a time-course and dose-dependent manners. Its expression level is recoverable by antioxidants too. In conclusion, our current study strongly suggests that CuQ induces gene mutation, global DNA damage, and P53 expression through a ROS-dependent mechanism.