The putative tumor suppressor Tsc-22 is downregulated early in chemically induced hepatocarcinogenesis and may be a suppressor of Gadd45b

Tsc-22 is a novel tumor suppressor gene that represents a new class of transcription factors that has transcriptional repressor activity. We found Tsc-22 downregulation in livers from B6C3F1 mice following treatment for 2 weeks with carcinogenic doses of the antianxiety drug oxazepam (2500 ppm) or the peroxisome proliferator Wyeth-14,643 (500 ppm) but not with two other carcinogens such as o-nitrotoluene or methyleugenol or three noncarcinogens including p-nitrotoluene, eugenol, or acetaminophen. The expression of Tsc-22 was also repressed in B6C3F1 mouse liver tumors that were induced by several chemicals from 2-year carcinogenicity studies as well as in spontaneous liver tumors. To identify potential Tsc-22 target genes in mouse liver, we transfected small interference RNA (SiRNA) designed to inhibit Tsc-22 into murine liver BNL-CL.2 cells. We selected two potential transcriptional targets of Tsc-22, growth arrest and DNA damage-inducible gene 45 beta (Gadd45b) and leucine zipper, putative tumor suppressor 2 (Lzts2) to test based on our previous complementary DNA microarray studies, showing that expression of these cancer-associated genes was increased when Tsc-22 was repressed. SiRNA treatment of BNL-CL.2 cells with Tsc-22 oligonucleotides but not nonspecific oligonucleotides decreased RNA and protein expression of Tsc-22 by 80-90%, while expression of Gadd45b gene, but not Lzts2, was increased over time after an initial decrease. Treatment of these cells with oxazepam for 48 h also resulted in decreased Tsc-22 and increased Gadd45b expression. These data provide evidence that Tsc-22 is a suppressor of Gadd45b expression, which may contribute to an early antiapoptotic response.

Unique patterns of gene expression changes in liver after treatment of mice for 2 weeks with different known carcinogens and non-carcinogens

Previously we demonstrated that the mouse liver tumor response to the non-genotoxic carcinogens oxazepam and Wyeth-14,643 involved more differences than similarities in changes in early gene expression. In this study we used quantitative real-time PCR and oligonucleotide microarray analysis to identify genes that were up- or down-regulated in mouse liver early after treatment with different known carcinogens, including oxazepam (125 and 2500 p.p.m.), o-nitrotoluene (1250 and 5000 p.p.m.) and methyleugenol (75 mg/kg/day), or the non-carcinogens p-nitrotoluene (5000 p.p.m.), eugenol (75 mg/kg/day) and acetaminophen (6000 p.p.m.). Starting at 6 weeks of age, mice were treated with the different compounds for 2 weeks in the diet, at which time the livers were collected. First, expression of 12 genes found previously to be altered in liver after 2 weeks treatment with oxazepam and/or Wyeth-14,643 was examined in livers from the various chemical treatment groups. These gene expression changes were confirmed for the livers from the oxazepam-treated mice in the present study, but were not good early markers for all the carcinogens in this study. In addition, expression of 20 842 genes was assessed by oligonucleotide microarray [n = 4 livers/group, 2 hybridizations/liver (with fluor reversals)] and the results were analyzed using the Rosetta Resolver System and GeneSpring software. The analyses revealed that several cancer-related genes, including Fhit, Wwox, Tsc-22 and Gadd45b, were induced or repressed in unique patterns for specific carcinogens and not altered by the non-carcinogens. The data indicate that even if the tumor response, including molecular alterations, is similar, such as for oxazepam and methyleugenol, early gene expression changes appear to be carcinogen specific and seem to involve apoptosis and cell cycle-related genes.

Predominant K-ras codon 12 G --> A transition in chemically induced lung neoplasms in B6C3F1 mice

Based on long-term toxicity and carcinogenicity studies in B6C3F1 mice conducted by the National Toxicology Program, 2,2-Bis(bromomethyl)-1,3-propanediol (BMP) and tetranitromethane (TNM) have been identified as carcinogens. Following 2 yr of exposure to 312, 625, or 1,250 ppm BMP in feed, or exposure to 0.5 or 2 ppm TNM by inhalation, increased incidences of lung neoplasms were observed in B6C3F1 mice at all exposure concentrations compared to unexposed mice. The present study characterizes genetic alterations in the K-ras protooncogene in BMP- and TNM-induced lung neoplasms, respectively, and compares the findings to spontaneous lung neoplasms from corresponding control mice. The frequencies of the K-ras mutations were 57% (29/51) in BMP-induced lung neoplasms compared to 15% (3/20) in lung neoplasms from dosed feed control mice, and 54% (14/26) in TNM-induced lung neoplasms compared to 60% (3/5) in lung neoplasms from inhalation control mice. G --> A transitions at the second base of the K-ras codon 12 (GGT --> GAT) were the most frequent pattern of K-ras mutations identified in BMP-induced (20/29) and TNM-induced lung neoplasms (13/14), which differed from the mutational patterns identified in the lung neoplasms from unexposed control mice. These results indicate that mutations in the K-ras gene are involved in B6C3F1 lung carcinogenesis following BMP- and TNM-exposure, and the high frequency and specificity of the ras mutation profile in lung neoplasms (G --> A transition) may be due to in vivo genotoxicity by the parent compounds or their metabolites.

Expression of potential beta-catenin targets, cyclin D1, c-Jun, c-Myc, E-cadherin, and EGFR in chemically induced hepatocellular neoplasms from B6C3F1 mice

In this study we used liver neoplasms induced by several chemical carcinogens to investigate potential nuclear targets associated with beta-catenin/Wnt signaling and potential membrane-associated beta-catenin binding partners. Strong expression of cyclin D1, in a pattern similar to that observed previously for beta-catenin, was observed by Western analysis for all five hepatoblastomas examined regardless of treatment. Increased expression of cyclin D1 was also detected in 12 of 35 (34%) hepatocellular neoplasms. Ten of 15 tumors (67%) that had mutations in the Catnb gene had upregulation of cyclin D1, while only 2 of 20 tumors (10%) without Catnb mutations had increased cyclin D1 expression. Immunohistochemical analysis confirmed strong expression of cyclin D1 in most nuclei of hepatoblastomas and scattered nuclear staining in hepatocellular tumors that had Catnb mutations. Increased c-Jun expression was observed in 19 of 30 (63%) hepatocellular tumors and all hepatoblastomas, although upregulation was not completely correlated with Catnb mutation. C-Myc expression was not increased in the tumors. Reduced expression of E-cadherin, which interacts with beta-catenin at the membrane, was observed in some tumors, but this did not correlate with Catnb mutation. Expression of the epidermal growth factor receptor, which may have a role in beta-catenin tyrosine phosphorylation, was lower in some tumors than in normal tissue depending on chemical treatment. The results provide evidence that increased expression of cyclin D1 and c-Jun may provide an advantage during tumor progression and in the transition from hepatocellular neoplasms to hepatoblastomas. Moreover, it is likely increased cyclin D1 expression results at least in part from Catnb mutation, beta-catenin accumulation, and increased Wnt signaling.

Changes in global gene and protein expression during early mouse liver carcinogenesis induced by non-genotoxic model carcinogens oxazepam and Wyeth-14,643

We hypothesized that the mouse liver tumor response to non-genotoxic carcinogens would involve some common early gene and protein expression changes that could ultimately be used to predict chemical hepatocarcinogenesis. In order to identify a panel of genes to test, we analyzed global differences in gene and protein expression in livers from B6C3F1 mice following dietary treatment with two rodent carcinogens, the benzodiazepine anti-anxiety drug oxazepam (2500 p.p.m.) and the hypolipidemic agent Wyeth (Wy)-14,643 (500 p.p.m.) compared with livers from untreated mice. Male mice were exposed for 2 weeks and 1, 3 or 6 months to oxazepam or Wy-14,643 in an age-matched study design. By histopathological evaluation, no liver preneoplastic foci or tumors were detected at 6 months in treated or control groups. By cDNA microarray analysis [NIEHS Mouse Chip (8700 genes); n = 3 individual livers/group, four hybridizations/sample], expression of 36 genes or 220 genes were changed relative to control livers following 6 months of oxazepam or Wy-14,643 treatment, respectively. To obtain a more comprehensive picture of gene/protein expression changes, we also conducted a proteomics study by 2D-gel electrophoresis followed by matrix assisted laser desorption/ionization-mass spectrometry on cytoplasmic, nuclear, and microsomal subcellular fractions of the same liver samples utilized for the cDNA microarray analysis. Real-time PCR, western blot analysis and immunohistochemistry were utilized for validation and to expand the results to other time points. Cyp2b20, growth arrest- and damage-inducible gene beta (Gadd45beta), tumor necrosis factor alpha-induced protein 2 and insulin-like growth factor binding protein 1 (Igfbp5) genes and proteins were upregulated by oxazepam, and Cyp2b20, Cyclin D1, proliferating cell nuclear antigen, Igfbp5, Gadd45beta and cell death-inducing DNA fragmentation factor alpha subunit-like effector A exhibited higher expression after Wy-14,643 treatment. Most of these genes/proteins were also deregulated at 2 weeks. There appeared to be more distinct than common changes in the expression of carcinogenesis-related genes/proteins between the two compounds, suggesting that the major carcinogenic pathways are different for these compounds and may be distinct for different chemical classes.

Hypermethylation of the p16 (Ink4a) promoter in B6C3F1 mouse primary lung adenocarcinomas and mouse lung cell lines

Primary lung tumors from B6C3F1 mice and mouse lung cell lines were examined to investigate the role of transcriptional silencing of the p16 (Ink4a) tumor suppressor gene by DNA hypermethylation during mouse lung carcinogenesis. Hypermethylation (>/=50% methylation at two or more of the CpG sites examined) of the p16 (Ink4a) promoter region was detected in DNA from 12 of 17 (70%) of the B6C3F1 primary mouse lung adenocarcinomas examined, whereas hypermethylation was not detected in normal B6C3F1, C57BL/6 and C3H/He mouse lung tissues. Immunohistochemistry performed on the B6C3F1 lung adenocarcinomas revealed heterogeneous expression of the p16 protein within and among the tumors. Laser capture microdissection was employed to collect cells from immunostained sections of four tumors displaying areas of relatively high and low p16 expression. The methylation status of the microdissected samples was assessed by sodium bisulfite genomic sequencing. The pattern of p16 expression correlated inversely with the DNA methylation pattern at promoter CpG sites in nine of 11 (82%) of the microdissected areas displaying variable p16 expression. To provide further evidence that hypermethylation is involved in the loss of p16 (Ink4a) gene expression, three mouse lung tumor cell lines (C10, sp6c and CMT64) displaying complete methylation at seven promoter CpG sites and no p16 (Ink4a) expression were treated with the demethylating agent, 5-aza-2'-deoxycytidine. Re-expression of p16 (Ink4a) and partial demethylation of the p16 (Ink4a) promoter were observed in two cell lines (C10 and sp6c) following treatment. These are the first reported studies to provide strong evidence that DNA methylation is a mechanism for p16 inactivation in mouse lung tumors.

Beta-catenin mutations and protein accumulation in all hepatoblastomas examined from B6C3F1 mice treated with anthraquinone or oxazepam

The molecular pathogenesis of hepatoblastomas in the B6C3F1 mouse is unclear but may involve alterations in the beta-catenin/Wnt signaling pathway as was recently described for chemically induced hepatocellular neoplasms and human liver cancers. The objective of this study was to characterize the mutation frequency and spectrum of beta-catenin mutations and the intracellular localization of beta-catenin protein accumulation in chemically induced hepatoblastomas. In this study, beta-catenin mutations were identified in all 19 anthraquinone-induced hepatoblastomas and all 8 oxazepam-induced hepatoblastomas examined. Although several hepatoblastomas had multiple deletion and/or point mutations, the pattern of mutations in the hepatoblastomas did not differ from that identified in hepatocellular neoplasms. In a majority of the hepatoblastomas (six of seven) examined by immunohistochemical methods, both nuclear and cytoplasmic localization of beta-catenin protein were detected, whereas in hepatocellular adenomas, carcinomas, and normal liver only membrane staining was observed. Our data suggest that beta-catenin mutations and the subsequent translocation of beta-catenin protein from the cell membrane to the cytoplasm and nucleus may be critical steps in providing hepatocellular proliferative lesions with the growth advantage to progress to hepatoblastoma.

DNA methylation analysis of the promoter region of the human telomerase reverse transcriptase (hTERT) gene

The promoter of the hTERT gene encoding the catalytic subunit of telomerase was recently cloned and has a dense CG-rich CpG island, suggesting a role for methylation in regulation of hTERT expression. In this study, we have initiated the analysis of the regulation of hTERT expression by examining the methylation status of up to 72 CpG sites extending from 500 bases upstream of the transcriptional start site of the hTERT gene into the first exon in 37 cell lines. These cell lines represent a variety of cell and tissue types, including normal, immortalized, and cancer cell lines from lung, breast, and other tissues. Using bisulfite genomic sequencing, we did not find a generalized pattern of site-specific or region-specific methylation that correlated with expression of the hTERT gene: most of the hTERT-negative normal cells and about one-third of the hTERT-expressing cell lines had the unmethylated/hypomethylated promoter, whereas the other hTERT-expressing cell lines showed partial or total methylation of the promoter. The promoter of one hTERT-negative fibroblast cell line, SUSM-1, was methylated at all sites examined. Treatment of SUSM-1 cells with the demethylating agent 5-aza-2'-deoxycytidine and the histone deacetylase inhibitor trichostatin A induced the cells to express hTERT, suggesting a potential role for DNA methylation and/or histone deacetylation in negative regulation of hTERT. This study indicates that there are multiple levels of regulation of hTERT expression in CpG island methylation-dependent and -independent manners.

Mutation of beta-catenin is an early event in chemically induced mouse hepatocellular carcinogenesis

beta-catenin activation, and subsequent upregulation of Wnt-signaling, is an important event in the development of certain human and rodent cancers. Recently, mutations in the beta-catenin gene in the region of the serine-threonine glycogen kinase (GSK)-3beta phosphorylation target sites have been identified in hepatocellular neoplasms from humans and transgenic mice. In this study we examined 152 hepatocellular neoplasms from B6C3F1 mice included in five chemical treatment groups and controls for mutations in the beta-catenin gene. Twenty of 29 hepatocellular neoplasms from mice treated with methyleugenol had point mutations at codons 32, 33, 34 or 41, sites which are mutated in colon and other cancers. Likewise, nine of 24 methylene chloride-induced hepatocellular neoplasms and 18 of 42 oxazepam-induced neoplasms exhibited similar mutations. In contrast, only three of 18 vinyl carbamate-induced liver tumors, one of 18 TCDD-induced liver tumors, and two of 22 spontaneous liver neoplasms had mutations in beta-catenin. Thus, there appears to be a chemical specific involvement of beta-catenin activation in mouse hepatocellular carcinogenesis. Expression analyses using Western blot and immunohistochemistry indicate that beta-catenin protein accumulates along cell membranes following mutation. The finding of mutations in both adenomas and carcinomas from diverse chemical treatment groups and the immunostaining of beta-catenin protein in an altered hepatocellular focus suggest that these alterations are early events in mouse hepatocellular carcinogenesis.

At least four loci and gender are associated with susceptibility to the chemical induction of lung adenomas in A/J x BALB/c mice

Four putative quantitative trait loci (QTLs) that influence susceptibility to the induction of lung adenomas by urethane in an F2 cross between A/J and BALB/cOlaHsd have been mapped. Following microsatellite typing of mice with resistant and susceptible phenotypes at 97 microsatellite marker loci, a major locus was identified on chromosome 18 with a lod score of 15. This was responsible for an 8- to 10-fold increase in tumor multiplicity in males and females, respectively, having the AA and CC genotypes at the D18Mit188 marker locus. It mapped close to Dcc (deleted in colorectal cancer). A locus on chromosome 4 (lod score 6.5) had the resistant allele in strain A/J and the susceptible allele in BALB/c, with a 14-fold difference in tumor multiplicity between mice of the AA and CC genotypes. This mapped close to the Cdkn2a (cyclin-dependent kinase inhibitor 2A) locus, which is commonly deleted in mouse lung tumors. Two loci with smaller effects (lod scores 3.03 and 3.25) were identified on chromosomes 1 and 11. There was also significant sexual dimorphism in tumor multiplicity both among 151 F2 hybrids and among 52 mice resulting from a backcross to strain A/J, with males having higher tumor counts than females.

Smad4 (homolog of human DPC4) and Smad2 (homolog of human JV18-1): candidates for murine lung tumor resistance and suppressor genes

In this study we investigated the mouse mad-related genes, Smad4/Dpc4 and Smad2 (homolog of JV18-1), as candidates for involvement in lung tumor resistance and suppression. These genes are located in a region of mouse chromosome 18 that is syntenic with human 18q21.1, where several genes that are mutated in various cancers have been mapped. A newly identified murine lung tumor resistance locus, Par2 has also been mapped to this region of chromosome 18. We found no mutations in the coding regions of either gene in 11 lung tumors from B6CF1 (C57BL/6 x BALB/c) mice by RT-PCR and SSCP/RFLP, suggesting that these genes are not mutated in lung carcinogenesis in this strain. Moreover, loss of heterozygosity in this region of chromosome 18 was not detected in 28 lung adenocarcinomas from B6CF1 mice, 17 lung adenocarcinomas from B6C3F1 mice or 18 lung adenocarcinomas from AB6F1 mice. These data provide evidence that a 'classical' tumor suppressor gene for mouse lung carcinogenesis in these strains does not reside in this region. In order to investigate Smad4/Dpc4 and Smad2 as candidates for the Par2 resistance locus mapped to this region, we also sequenced the coding regions of both genes in cDNA from normal lungs of A/J, BALB/c and C57BL/6 inbred strains of mice. No polymorphisms were detected in the coding region of Smad4. In Smad2, two sequence polymorphisms were identified that are not in the conserved regions of the gene. Northern blot analysis revealed no differential expression in normal lung tissue among the three strains for either gene. Thus, in this study we found no evidence that either Smad4 or Smad2 represents the Par2 lung tumor resistance locus or is a lung tumor suppressor gene in the B6CF1 mice.

Homozygous deletions but no sequence mutations in coding regions of p15 or p16 in human primary bladder tumors

Chromosome 9p21 appears to harbor a tumor suppressor gene, as evidenced by deletions in this region in a variety of human primary tumors and cell lines. To map the deletion at 9p21 in bladder tumors, we analyzed DNA from 28 tumor and normal pairs at five microsatellite markers that flank the region occupied by the putative tumor suppressor genes p16 and p15. Loss of heterozygosity (LOH) at the markers human interferon (HIFN) alpha and D9S171, which are adjacent to the p15 and p16 loci, was detected in 41% and 33%, respectively, of informative cases of bladder tumors. No sequence mutations were detected in exons 1 or 2 of either p15 or p16 in any of the bladder tumors. Three sequence-tagged site markers in the region bordered by HIFN alpha and D9S171 were used to further map the deleted region by multiplex polymerase chain reaction with the HIFN gamma maker (on chromosome 12) as a control for amplification. Six of 11 tumors with LOH at surrounding markers had homozygous deletions of the marker c5.1, which is located within the p16 gene; and two tumors appeared to have homozygous deletions within p15 (RN1.1) but not p16 (c5.1). A recently identified microsatellite marker, p16-CA-1, located 16 kb distal to p16, proved valuable in defining the minimal deletion involved in these bladder tumors. Five tumors exhibited homozygous deletions of this marker but not HIFN alpha and two tumors showed LOH at this marker and homozygous deletion of p16. Although these data could not be used to identify p16 or p15 as the definitive tumor suppressor gene in this region that is involved in bladder carcinogenesis, they suggest that homozygous deletion is a common mechanism of loss of tumor suppressor gene function in this region.

Homozygous deletions at chromosome 9p21 and mutation analysis of p16 and p15 in microdissected primary non-small cell lung cancers

Loss of heterozygosity on chromosome 9p has been detected in many primary human tumors and cell lines, suggesting that this chromosomal arm harbors one or more tumor suppressor genes. The recently cloned p16 and p15 genes, mapped to 9p21, are likely candidates for such tumor suppressors. To map the deletion at chromosome 9p21 in non-small cell lung tumors, we analyzed DNA from 25 tumors and matching normal DNAs at six microsatellite markers that flank the region occupied by the p16 and p15 genes. Loss of heterozygosity of at least one microsatellite marker on chromosome 9p21 was detected in 13 (52%) of 25 tumors, including one tumor that exhibited homozygous deletion of both human IFNalpha and D9S171. Six tumors analyzed by a comparative multiplex PCR technique showed homozygous deletions of the sequence tag site marker c5.1 (within p16). Screening for mutations in p16 and p15 revealed one tumor with a non-sense mutation in exon 2 of p16, but no mutations were detected in p15 in any of the tumors. Thus, in these analyses approximately one-half of the non-small cell lung tumors had loss of heterozygosity at chromosome 9p21, and of these tumors, one-half had homozygous deletions of the region that includes p16. This appears to confirm the importance of a locus in this region critical to growth control in lung. The apparent lack of other mutations in p16 and p15 in the tumors with loss of heterozygosity leaves open the possibility of an unidentified gene in this region that may function as a tumor suppressor.

Considerations concerning the murine hepatocarcinogenicity of selected chlorinated hydrocarbons

Of the chlorinated hydrocarbons discussed above, all six are associated with induction of hepatocellular neoplasia in mice. None of the six is considered to be potent mutagen and most are without any significant genotoxic activity as assessed by conventional in vitro testing schemes. Although some of the agents have biological effects in common (see Figure 4), there is no single biological response (mode of action) that they all share to provide a mechanistic basis for the observed murine hepatocarcinogenicity. Based upon the information currently available for each of the chlorinated hydrocarbons discussed above, it is probable that some modes of action may be more contributory to the rodent carcinogenic response than others; however, no mode of action, pathway, or mechanism should be considered to be mutually exclusive. The murine hepatocarcinogenic effect of TriCE is most probably contingent upon its species-specific metabolism to trichloroacetic acid and DCA. There is fairly consistent evidence that cytotoxicity and reparative hyperplasia are associated with doses of TriCE that cause induction of liver neoplasms. The possibility that peroxisome proliferation is playing a role in the induction of mouse hepatocellular neoplasia remains a tempting explanation, since higher intracellular steady states of H2O2 production would be consistent with observed enhanced cellular proliferation as well as the possibility of in vivo DNA damage. The mouse hepatocarcinogenicity associated with TetCE most probably is associated with species-specific metabolic production of trichloroacetic acid. As with TriCE, cytotoxicity and reparative hyperplasia may represent a potential mode of action for the observed hepatocarcinogenicity. Once again, the potential for enhanced peroxisome proliferation is consistent with enhanced cell proliferation and oxygen radical damage would help explain the random point mutations in ras proto-oncogenes documented in DNA from TetCE-induced mouse liver tumors. DCA-induced mouse hepatocellular neoplasia is probably influenced by cytotoxicity and reparative hyperplasia, but there is also recent evidence that DCA may directly damage DNA, implying an in vivo genotoxic mechanism may be operational. Likewise, altered expression of several genes suggests that subversion of signal transduction may play a role in the induction or progression of liver tumor development. As with TetCE and TriCE, a role for peroxisome proliferation is still a consideration, although the liver tumor response is obvious at doses too low to cause peroxisome proliferation.(ABSTRACT TRUNCATED AT 400 WORDS)

ras proto-oncogene activation in dichloroacetic acid-, trichloroethylene- and tetrachloroethylene-induced liver tumors in B6C3F1 mice

The frequency and mutation spectra of proto-oncogene activation in hepatocellular neoplasms induced by tetrachloroethylene, trichloroethylene and dichloroacetic acid were examined to help define the molecular basis for their carcinogenicity. H-ras codon 61 activation was not significantly different among dichloroacetic acid- and trichloroethylene-induced and combined historical and concurrent control hepatocellular tumors (62%, 51% and 69% respectively). The mutation spectra of H-ras codon 61 mutations showed a significant decrease in AAA and increase in CTA mutations for dichloroacetic acid- and trichloroethylene-induced tumors when compared to combined controls. The H-ras codon 61 mutation frequency for tetrachloroethylene-induced tumors was significantly lower (24%) than that of combined controls and also that of the two other chemicals. Mutations at codons 13 and 117 plus a second exon insert contributed 4% to the total H-ras frequencies for trichloroethylene and tetrachloroethylene. There was also a higher incidence of K-ras activation (13%) in tetrachloroethylene-induced tumors than in the other chemically induced or control tumors. Four liver tumors were found to contain insertions of additional bases within the second exon of K- or H-ras. These findings suggest that exposure to dichloroacetic acid, trichloroethylene and tetrachloroethylene provides a selective growth advantage to spontaneously occurring mutations in codon 61 of H-ras and, at the same time, is responsible for a small number of unique molecular lesions suggestive of either a random genotoxic mode of action or a non-specific result of secondary DNA damage. However, the absence of ras activation in many of the liver neoplasms suggests that alternative mechanisms are also important in B6C3F1 mouse hepatocarcinogenesis.

Oxidative stress induces DNA damage and inhibits the repair of DNA lesions induced by N-acetoxy-2-acetylaminofluorene in human peripheral mononuclear leukocytes

Human mononuclear leukocytes were exposed to prooxidants such as H2O2, phorbol-12-myristate-13-acetate, and 4-nitroquinoline-N-oxide, and the effects on induction of DNA damage and repair were evaluated. ADP ribosylation was activated by prooxidant exposure and the response was bimodal with peaks of activation occurring at about 30 min and 4-5 h. Other evidence for prooxidant-induced DNA damage was provided by nucleoid sedimentation assays. Unscheduled DNA synthesis (UDS) was only slightly induced by prooxidant exposure which suggested that either the DNA lesions were repaired by a short patch mechanism involving little UDS, or the repair process was inhibited by prooxidant exposures, or some combination of both. This point was clarified by the fact that the repair of DNA lesions induced by N-acetoxy-2-acetylaminofluorene, an inducer of large patch DNA repair, was inhibited in a dose-dependent manner by exposure to H2O2 and the inhibition was dependent on ADP ribosylation. In contrast, the repair of DNA strand breaks induced by prooxidant exposures as identified above were complete within about 8 h and the repair was independent of ADP ribosylation. Both ADP ribosylation and N-acetoxy-2-acetylaminofluorene-induced UDS were shown to be up- and down-regulated by the redox state of human mononuclear leukocytes indicating a unique mechanism of cellular control over DNA repair.