Delivery method, target gene structure, and growth properties of target cells impact mutagenic responses to reactive nitrogen and oxygen species

Dysregulated production of nitric oxide (NO?) and reactive oxygen species (ROS) by inflammatory cells in vivo may contribute to mutagenesis and carcinogenesis. Here, we compare cytotoxicity and mutagenicity induced by NO? and ROS in TK6 and AS52 cells, delivered by two methods: a well-characterized delivery system and a novel adaptation of a system for coculture. When exposed to preformed NO?, a cumulative dose of 620 μM min reduced the viability of TK6 cells at 24 h to 36% and increased mutation frequencies in the HPRT and TK1 genes to 7.7 × 10?? (p < 0.05) and 24.8 × 10?? (p < 0.01), 2.7- and 3.7-fold higher than background, respectively. In AS52 cells, cumulative doses of 1700 and 3700 μM min reduced viability to 49 and 22%, respectively, and increased the mutation frequency 10.2- and 14.6-fold higher than the argon control (132 × 10?? and 190 × 10??, respectively). These data show that TK6 cells were more sensitive than AS52 cells to killing by NO?. However, the two cell lines were very similar in relative susceptibility to mutagenesis; on the basis of fold increases in MF, average relative sensitivity values [(MF(exp)/MF(control))/cumulative NO? dose] were 5.16 × 10?3 and 4.97 × 10?3 μM?1 min?1 for TK6 cells and AS52 cells, respectively. When AS52 cells were exposed to reactive species generated by activated macrophages in the coculture system, cell killing was greatly reduced by the addition of NMA to the culture medium and was completely abrogated by combined additions of NMA and the superoxide scavenger Tiron, indicating the relative importance of NO? to loss of viability. Exposure in the coculture system for 48 h increased mutation frequency in the gpt gene by more than 9-fold, and NMA plus Tiron again completely prevented the response. Molecular analysis of gpt mutants induced by preformed NO? or by activated macrophages revealed that both doubled the frequency of gene inactivation (40% in induced vs 20% in spontaneous mutants). Sequencing showed that base-substitution mutations dominated the spectra, with transversions (30-40%) outnumbering transitions (10-20%). Virtually all mutations took place at guanine sites in the gene. G:C to T:A transversions accounted for about 30% of both spontaneous and induced mutations; G:C to A:T transitions amounted to 10-20% of mutants; insertions, small deletions, and multiple mutations were present at frequencies of 0-10%. Taken together, these results indicate that cell type and proximity to generator cells are critical determinants of cytotoxic and genotoxic responses induced by NO? and reactive species produced by activated macrophages.     

Analysis of HPRT and supF mutations caused by pierisin-1, a guanine specific ADP-ribosylating toxin derived from the cabbage butterfly

Pierisin-1, an ADP-ribosylating toxin derived from the cabbage butterfly, Pieris rapae, induces apoptosis in various mammalian cell lines. We recently reported that the target for ADP ribosylation by pierisin-1 is the 2'-deoxyguanosine residue in DNA. To examine whether pierisin-1 would induce mutations in mammalian cell genes, we conducted a mutational analysis for the hypoxanthine-guanine phosphoribosyltransferase (HPRT) locus in pierisin-1-treated Chinese hamster lung (CHL) cells. N(2)-(ADP-ribos-1-yl)-2'-deoxyguanosine was detected by the (32)P-postlabeling method in CHL cells after treatment with pierisin-1 at doses of 2-32 ng/mL; adduct levels were 1.1-12.0 per 10(6) nucleotides. Pierisin-1 induced mutations in the HPRT gene dose-dependently, and the frequency was 38 times higher than the control, at a dose of 32 ng/mL. To confirm that mono(ADP-ribosyl)ated dG itself leads to mutations, the pierisin-1-treated DNA of plasmid pMY189 bearing the supF gene was used for mutational analysis. The mutation frequency of the supF gene treated with 2-8 micro g/mL of pierisin-1 was 17-40-fold the control value. Mutation spectrum analysis showed that single base substitutions dominated in both HPRT and supF genes. Among these, transversions were predominant, and more than 70% of the base substitutions occurred at G:C base pairs in both genes. The most frequent mutations were G:C to C:G, followed by G:C to T:A in HPRT gene, whereas G:C to T:A transversions dominated in the supF gene. Our results indicate that pierisin-1 produced N(2)-(ADP-ribos-1-yl)-2'-deoxyguanosine and this guanine-adduct could lead to mutations in the HPRT and supF genes. These findings could provide very useful information for understanding the biological significance of pierisin-1.     

Mutation spectrum induced by dihydropyrazines in Escherichia coli

Dihydropyrazine (DHP), which induces mutagenesis in E. coli, was investigated. From analyzing mutations in the chromosomal rpoB gene, the mutation spectrum in uvrB strain revealed the different behavior on exposure to two DHP derivatives 3-hydro-2,2,5,6-tetramethylpyrazine (HTMP), and 2,3-dihydro-5,6-dimethylpyrazine (DHDMP). A higher level of DHP-induced mutation was observed, with base substitutions at G : C pairs predominant. HTMP and DHDMP increased the frequency of G : C to T : A transversions. HTMP increased the frequency of G : C to A : T transitions, than did DHDMP. These findings suggest that DHPs prefer to attack the G : C pair and that different DHP derivatives may prefer distinct mutagenic base pairs; and further, that nucleotide excision repair may be involved in the repair of DHP-induced mutations.     

Effects of peroxynitrite dose and dose rate on DNA damage and mutation in the supF shuttle vector

Peroxynitrite (ONOO-) induces oxidative and nitrosative DNA damage, and previous studies by our group have shown that it is strongly mutagenic in the supF shuttle vector pSP189 replicated in Escherichia coli MBL50 cells. In those experiments, however, the pSP189 plasmid was exposed under unphysiological conditions to large single bolus doses of ONOO-, which limits extrapolation of the data to in vivo pathological states in which ONOO- may play a role. We have thus sought to define the effects of ONOO- dose and dose rate on the DNA damage and mutations induced in the supF gene by three different dosage mechanisms: (i) by infusion of ONOO- solution into suspensions of pSP189 at rates approximating those estimated to occur in inflamed tissues; (ii) by exposure to 3-morpholinosydnonimine (SIN-1), which generates ONOO- spontaneously during decomposition; and (iii) by bolus doses of ONOO- solution. In all cases, plasmid DNA was exposed in the presence of 25 mM bicarbonate, since the reaction of CO2 with ONOO- (to form nitrosoperoxycarbonate) has a major impact on mutagenic potency of ONOO- in this system. Nucleobase and deoxyribose damage were evaluated by a plasmid nicking assay immediately after ONOO- and SIN-1 exposures. Mutation frequency (MF) and mutational spectra in the supF gene were determined after plasmid pSP189 replicated in host E. coli cells. Bolus ONOO- addition caused the highest amount of DNA damage, including base and deoxyribose lesions, while infusion caused the least. SIN-1 was found to induce almost exclusively deoxyribose oxidation, while bolus addition generated a high percentage of base damage. MF increased in a dose-dependent manner following all treatments, but infused ONOO- and SIN-1 exposures were less mutagenic than bolus ONOO- exposure. MFs induced by infusion and by SIN-1 incubated for 100 min at the highest level (4 mM) were 63 and 43% less, respectively, than that induced by bolus. All mutational hot spots were located at G:C sites except for A121 and A177 induced by SIN-1 exposure. Hot spots at C108 and C168 were common to all exposures; G113, G115, and G116 were common to bolus and infused ONOO- exposures; and G129 was common to infused ONOO- and SIN-1 exposures. Almost all mutations were single base pair substitutions under all exposure conditions. Whereas those induced by infused or bolus ONOO- and SIN-1 consisted predominantly of G:C to T:A transversions (66, 65, and 51%, respectively), G:C to C:G mutations were much less frequent following infusion and SIN-1 (8 and 19%, respectively) than those induced by bolus exposure (29%). A:T to T:A mutations induced were detected only after ONOO- infusion and SIN-1 exposure (9 and 11%, respectively). In conclusion, both dose and dose rate at which a genetic target is exposed to ONOO- substantially influence the damage and mutational response, indicating that these parameters will need to be taken into account in assessing the potential effects of ONOO- in vivo. Furthermore, the results indicate that the chemistry of SIN-1-induced DNA damage differs substantially from native ONOO-, which suggests the need for caution in interpreting the biological relevance of SIN-1 as a surrogate for ONOO-.     

Mutagenic Bypass of 8-Oxo-7,8-dihydroguanine (8-Hydroxyguanine) by DNA Polymerase κ in Human Cells

The formation of 8-oxo-7,8-dihydroguanine (G(O), 8-hydroxyguanine) in DNA and in the nucleotide pool results in G:C→T:A and A:T→C:G substitution mutations, respectively, since G(O) can pair with both C and A. In this study, the role of DNA polymerase κ in the mutagenicity of G(O) was investigated, using a supF shuttle plasmid propagated in human U2OS cells. This translesion synthesis DNA polymerase was knocked down by siRNA, and plasmid DNAs containing G(O):C and G(O):A pairs were transfected into the knock-down cells. The supF plasmid DNAs replicated in the cells were then introduced into Escherichia coli. Mutation analyses indicated that the knock-down of DNA polymerase κ by siRNA decreased the frequency of G:C→T:A mutation caused by G(O):C, although no effects of the DNA polymerase κ reduction were observed for the A:T→C:G substitution induced by G(O):A. These results suggested that DNA polymerase κ is involved in the mutagenic bypass of G(O) in living human cells, when the damaged base is generated by direct DNA oxidation.     

Mutagenic spectrum of butadiene-derived N1-deoxyinosine adducts and N6,N6-deoxyadenosine intrastrand cross-links in mammalian cells

Reactive metabolites of 1,3-butadiene, including 1,2-epoxy-3-butene (BDO), 1,2:3,4-diepoxybutane (BDO(2)), and 3,4-epoxy-1,2-butanediol (BDE), form both stable and unstable base adducts in DNA and have been implicated in producing genotoxic effects in rodents and human cells. N1 deoxyadenosine adducts are unstable and can undergo either hydrolytic deamination to yield N1 deoxyinosine adducts or Dimroth rearrangement to yield N(6) adducts. The dominant point mutation observed at AT sites in both in vivo and in vitro mutagenesis studies using BD and its epoxides has been A --> T transversions followed by A --> G transitions. To understand which of the butadiene adducts are responsible for mutations at AT sites, the present study focuses on the N1 deoxyinosine adduct at C2 of BDO and N(6),N(6)-deoxyadenosine intrastrand cross-links derived from BDO(2). These lesions were incorporated site-specifically and stereospecifically into oligodeoxynucleotides which were engineered into mammalian shuttle vectors for replication bypass and mutational analyses in COS-7 cells. Replication of DNAs containing the R,R-BDO(2) intrastrand cross-link between N(6) positions of deoxyadenosine yielded a high frequency (59%) of single base substitutions at the 3' adducted base, while 19% mutagenesis was detected using the S,S-diastereomer. Comparable studies using the R- and S-diastereomers of the N1 deoxyinosine adduct gave rise to approximately 50 and 80% A --> G transitions with overall mutagenic frequencies of 59 and 90%, respectively. Collectively, these data establish a molecular basis for A --> G transitions that are observed following in vivo and in vitro exposures to BD and its epoxides, but fail to reveal the source of the A --> T transversions that are the dominant point mutation.     

Mutagenesis of 8-oxoguanine adjacent to an abasic site in simian kidney cells: tandem mutations and enhancement of G-->T transversions

Clustered DNA damages are well-established characteristics of ionizing radiation. As a model clustered lesion in the same strand of DNA, we have evaluated the mutagenic potential of 8-oxoguanine (8-oxoG) adjacent to a uracil in simian kidney cells using a phagemid vector. The uracil residue would be excised by the enzyme uracil DNA glycosylase in vivo generating an abasic site (AP site). A solitary uracil in either GUGTC or GTGUC sequence context provided >60% progeny containing GTGTC indicating that dAMP incorporation opposite the AP site or uracil occurred, but a >30% population showed replacement of U by A, C, or G, which suggests that dTMP, dGMP, or dCMP incorporation also occurred, respectively, opposite the AP site. While the preference for targeted base substitutions at the GUG site was T > C > A > G, the same at the GUC site was T > A > C > G. We conclude that base incorporation opposite an AP site is sequence-dependent. For 8-oxoG, as compared to 23-24% G-->T mutants from a single 8-oxoG in a TG(8-oxo)T sequence context, the tandem lesions UG(8-oxo)T and TG(8-oxo)U generated approximately 60 and >85% progeny, respectively, that did not contain the TGT sequence. A significant fraction of tandem mutations were detected when uracil was adjacent to 8-oxoG. What we found most interesting is that the total targeted G(8-oxo)-->T transversions that included both single and tandem mutations at the TG(8-oxo)U site was nearly 60% relative to about 30% at the UG(8-oxo)T site. A higher mutational frequency at the TG(8-oxo)U sequence may arise from a change in DNA polymerase that is more error prone. Thermal melting experiments showed that the Tm for the 8-oxoG:C pair in the TG(8-oxo)(AP*) sequence in a 12-mer was lower than the same in a (AP*)G(8-oxo)T 12-mer with deltadeltaG 0.8 kcal/mol (where AP* represents tetrahydrofuran, the model abasic site). When the 8-oxoG:C pair in each sequence was compared with a 8-oxoG:A pair, the former was found to be more stable than the latter. The preference for C over A opposite 8-oxoG for the (AP*)G(8-oxo)T 12-mer duplex with a deltadeltaG of 1.6 kcal/mol dropped to 0.4 kcal/mol in the TG(8-oxo)(AP*) 12-mer duplex. This suggests that the polymerase discrimination to incorporate dCMP over dAMP would be less efficient in the TG(8-oxo)(AP*) sequence relative to (AP*)G(8-oxo)T. Additionally, the efficiency of recognition and excision of A opposite 8-oxoG by a mismatch repair protein may be impaired in the TG(8-oxo)(AP*) sequence context.     

AlkB influences the chloroacetaldehyde-induced mutation spectra and toxicity in the pSP189 supF shuttle vector

2-Chloroacetaldehyde (CAA), a metabolite of the carcinogen vinyl chloride, reacts with DNA to form cyclic etheno ()-lesions. AlkB, an iron-/alpha-ketoglutarate-dependent dioxygenase, repairs 1, N (6)-ethenodeoxyadenosine (A) and 3, N (4)-ethenodeoxycytidine (C) in site-specifically modified single-stranded viral genomes in vivo and also protects the E. coli genome from the toxic effects of CAA. We examined the role of AlkB as a cellular defense against CAA by characterizing the frequencies, types, and distributions of mutations induced in the double-stranded supF gene of pSP189 damaged in vitro and replicated in AlkB-proficient (AlkB (+)) and AlkB-deficient (AlkB (-)) E. coli. AlkB reduced mutagenic potency and increased the survival of CAA-damaged plasmids. Toxicity and mutagenesis data were benchmarked to levels of -adducts and DNA strand breaks measured by LC-MS/MS and a plasmid nicking assay. CAA treatment caused dose-dependent increases in A, C, and 1, N (2)-ethenodeoxyguanosine (1, N (2)-G) and small increases in strand breaks and abasic sites. Mutation frequency increased in plasmids replicated in both AlkB (+) and AlkB (-) cells; however, at the maximum CAA dose, the mutation frequency was 5-fold lower in AlkB (+) than in AlkB (-) cells, indicating that AlkB protected the genome from CAA lesions. Most induced mutations in AlkB (-) cells were G:C to A:T transitions, with lesser numbers of G:C to T:A transversions and A:T to G:C transitions. G:C to A:T and A:T to G:C transitions were lower in AlkB (+) cells than in AlkB (-) cells. Mutational hotspots at G122, G123, and G160 were common to both cell types. Three additional hotspots were found in AlkB (-) cells (C133, T134, and G159), with a decrease in mutation frequency and change in mutational signature in AlkB (+) cells. These results suggest that the AlkB protein contributes to the elimination of exocyclic DNA base adducts, suppressing the toxic and mutagenic consequences induced by this damage and contributing to genetic stability.     

Mutagenesis of the supF gene by stereoisomers of 1,2,3,4-diepoxybutane

1,2,3,4-diepoxybutane (DEB) is a key metabolite of the important industrial chemical and environmental contaminant, 1,3-butadiene (BD). Although all three optical isomers of DEB, S,S-, R,R-, and meso-DEB, are produced by metabolic processing of BD, S,S-DEB exhibits the most potent genotoxicity and cytotoxicity, followed by R,R- and then meso-DEB. Our previous studies suggested that the observed differences between the biological effects of DEB optical isomers may be structural in their origin. Although S,S- and R,R-DEB produced mainly 1,3-interstrand 1,4-bis-(guan-7-yl)-2,3-butanediol (bis-N7G-BD) cross-links, meso-diepoxide induced equal numbers of intrastrand and interstrand bis-N7G-BD lesions. In the present study, the mutagenicity of the three DEB stereoisomers in the supF gene was investigated. We found that S,S-DEB was the most potent mutagen. Interestingly, mutation specificity and mutant spectra were strongly dependent on DEB stereochemistry. Although A:T to T:A transversions were the major form of mutation observed following treatment with each of the three stereoisomers (35-40%), S,S-DEB induced higher numbers of G:C to A:T transitions, whereas R,R-DEB treatment resulted in a greater frequency of G:C to T:A transversions. Our results are consistent with the stereospecific induction of promutagenic nucleobase adducts other than G-G cross-links by DEB stereoisomers.     

Mutagenesis by O(6)-[4-oxo-4-(3-pyridyl)butyl]guanine in Escherichia coli and human cells

Site-specific mutagenesis by O(6)-[4-oxo-4-(3-pyridyl)butyl]guanine (O(6)-pobGua), a product of DNA pyridyloxobutylation by metabolites of the tobacco-specific nitrosamines N-nitrosonornicotine (NNN) and 4-(methylnitrosamino)-1-(3-pyridyl)-1-butanone (NNK), was studied in Escherichia coli strain DH10B and human kidney cells (293) when the modified base was incorporated in either a double-stranded or a gapped shuttle vector. In the repair-competent E. coli strain, less than 3% of the colonies produced by double-stranded vectors harboring the modified base were mutant whereas 96% were mutant when DH10B cells were transformed with modified gapped vectors. By contrast, transformation of DH10B cells with plasmids derived from O(6)-pobGua-containing double-stranded and gapped vectors previously replicated in 293 cells produced 7 and 16% mutant colonies, respectively. These percentages increased to 42 and 82%, respectively, when the 293 cells were pretreated with O(6)-benzylguanine to inactivate the O(6)-alkylguanine-DNA alkyltransferase protein. These findings confirm that the adduct is readily repaired by the human O(6)-alkylguanine-DNA alkyltransferase in both double-stranded and gapped vectors and suggest that it is also highly mutagenic in both human cells and E. coli. In the E. coli strain, the adduct produced exclusively G --> A transition mutations although in human 293 cells it also produced G --> T transversions and more complex mutations in addition to G --> A transitions. These data suggest that O(6)-[4-oxo-4-(3-pyridyl)butyl]guanine can contribute significantly to the mutagenic risk posed by exposure to both NNN and NNK in tobacco smoke.     

Pharmacological Coal Tar Induces G:C to T:A Transversion Mutations in the Skin of MutaTM Mouse

Abstract: Coal tar is a by‐product of the distillation of coal. It consists of a complex chemical mixture of aromatic and aliphatic hydrocabons, with high concentrations of polycyclic aromatic hydrocarbons such as benzo[a]pyrene. We have previously shown that single painting on skin of mice increases the mutation frequency 16 times in murine epidermis cells (Thein et al. 2000). Here, we have determined the mutations by DNA sequencing. Coal tar was found to primarily induce G:C to T:A transversions and one‐base pair deletions of G:C base pairs. More than half of the mutations were at CpG sites. The mutational spectrum is in agreement with that of benzo[a]pyrene and other polycyclic aromatic hydrocarbon mixtures.     

Mutagenicity of the 1-nitropyrene-DNA adduct N-(deoxyguanosin-8-yl)-1-aminopyrene in Escherichia coli located in a nonrepetitive CGC sequence

1-Nitropyrene, a common environmental pollutant, forms a major DNA adduct, N-(deoxyguanosin-8-yl)-1-aminopyrene (dG(AP)). Mutational spectra of randomly introduced dG(AP) in Escherichia coli included many different types of mutations. However, a prior site-specific study in a CGCG(AP)CG sequence showed only CpG deletions and +1 frame shifts. To further explore the context effects of dG(AP) in mutagenesis, in this work this adduct was incorporated into a nonrepetitive CGC sequence in single-stranded M13mp7L2 DNA. Upon replication of this construct in repair-competent E. coli, one-base deletions and base substitutions were detected. The -1 frame shifts, whose frequency increased 3-6-fold with SOS (to an average frequency of 1.5%), involved deletion of the adjacent C residues. The base substitutions ( approximately 2.2%) included targeted G-to-T and G-to-C transversions, whose frequencies did not increase with SOS. This suggests that dG(AP) mutagenesis is highly dependent on the local DNA sequence.     

Identification and functional characterization of UDP-glucuronosyltransferases UGT1A8*1, UGT1A8*2 and UGT1A8*3

UDP-glucuronosyltransferase (UGT) 1A8 is part of the UGT1 locus and is expressed exclusively in extrahepatic tissues. Analysis of UGT1A8 exon 1 sequence has identified four genotypes from a population of 69 individuals. While there are four alleles, one of the single base pair changes leads to a silent mutation at T255, while the other mutations lead to amino acid substitutions at positions 173 and 277, creating three allelic variants. UGT1A8*1 (A173C277), UGT1A8*1a (T255A>G), UGT1A8*2 (G173C277) and UGT1A8*3 (A173Y277). The allelic frequencies of UGT1A8*1, UGT1A8*1a, UGT1A8*2 and UGT1A8*3 are 0.551, 0.282, 0.145 and 0.022, respectively. To examine the properties of the UGT1A8 proteins, UGT1A8*1 and UGT1A8*2 were cloned from a human colon cDNA library and UGT1A8*3 generated by mutagenesis using UGT1A8*1 as template. The cDNAs were expressed in HK293 cells to examine catalytic function as well as abundance as observed by analysis of UGT1A8-GFP (green fluorescent protein) expression. The single amino acid change that identifies UGT1A8*1 (A173) and UGT1A8*2 (G173) has little impact on function, while the UGT1A8*3 (Y277) is a conserved amino acid alteration represented by a dramatic reduction in catalytic activity. Protein abundance, as determined by Western blot analysis following transient transfection, is not altered. In addition, functional UGT1A8-GFP variants displayed staining in the cytoplasmic region, indicating that each protein is expressed in similar cellular compartments. Together, these data suggest that the null UGT1A8*3 results from structural changes and not a lack of protein expression. Allelic variation leading to singular codon changes could potentially alter drug metabolism in extrahepatic tissues.     

Mutations induced by the carcinogenic pyrrolizidine alkaloid riddelliine in the liver cII gene of transgenic big blue rats

Riddelliine is a naturally occurring pyrrolizidine alkaloid that forms a number of different mononucleotide and dinucleotide adducts in DNA. It is a rodent carcinogen and a potential human hazard via food contamination. To examine the mutagenicity of riddelliine, groups of six female transgenic Big Blue rats were gavaged with 0.1, 0.3, and 1.0 mg riddelliine per kg body weight. The middle and high doses resulted in liver tumors in a previous carcinogenesis bioassay. The animals were treated 5 days a week for 12 weeks and sacrificed 1 day after the last treatment. The liver DNA was isolated for analysis of the mutant frequency (MF) in the transgenic cII gene, and the types of mutations were characterized by sequencing the mutants. A significant dose-dependent increase in MF was found, increasing from 30 x 10(-)(6) in the control animals to 47, 55, and 103 x 10(-)(6) in the low, middle, and high dose groups, respectively. Molecular analysis of the mutants indicated that there was a statistically significant difference between the mutational spectra from the riddelliine-treated and the control rats. A G:C --> T:A transversion (35%) was the major type of mutation in rats treated with riddelliine, whereas a G:C --> A:T transition (55%) was the predominant mutation in the controls. In addition, mutations from the riddelliine-treated rats included an unusually high frequency (8%) of tandem base substitutions of GG --> TT and GG --> AT. These results indicate that riddelliine is a genotoxic carcinogen in rat liver and that the types of mutations induced by riddelliine are consistent with riddelliine adducts involving G:C base pairs.     

Pharmacological coal tar induces G:C to T:A transversion mutations in the skin of muta mouse

Coal tar is a by-product of the distillation of coal. It consists of a complex chemical mixture of aromatic and aliphatic hydrocabons, with high concentrations of polycyclic aromatic hydrocarbons such as benzo[a]pyrene. We have previously shown that single painting on skin of mice increases the mutation frequency 16 times in murine epidermis cells (Thein et al. 2000). Here, we have determined the mutations by DNA sequencing. Coal tar was found to primarily induce G:C to T:A transversions and one-base pair deletions of G:C base pairs. More than half of the mutations were at CpG sites. The mutational spectrum is in agreement with that of benzo[a]pyrene and other polycyclic aromatic hydrocarbon mixtures.     

Effect of the spin-labelled 1-ethyl-1-nitrosourea on CCNU-induced oxidative liver injury

This study was carried out to determine the effects of 1-ethyl-3-[4-(2,2,6,6-tetramethylpiperidine-1-oxyl)]-l-nitrosourea (SLENU), recently synthesised in our laboratory, and vitamin E as positive control on 1-(2-chloroethyl)-3-cyclohexyl-1-nitrosourea (CCNU) - free radical induced oxidative injuries in the liver of mice. Specifically, alterations in malonyl dialdehyde (MDA) level and activities of some antioxidant enzymes, superoxide dismutase (SOD) and catalase (CAT), were measured in liver homogenates from tumour-bearing C57 black mice after treatment with solutions of CCNU (30 mg/kg) and SLENU (100 mg/kg), both administered intraperitoneally. CCNU-induced increase in MDA level, SOD and CAT activities were suppressed by SLENU. The present results and those from a previous report demonstrated superoxide scavenging activities (SSA) of the nitrosourea SLENU and enabled us explain the protective effect of the spin-labelled nitrosourea on CCNU-induced oxidative stress in the liver of mice. This protective effect is through the scavenging of *O2- and by an increased production of *NO. Thus, a potential for developing new combination chemotherapy in cancer is seen.     

线粒体基因突变型糖尿病患者氧化应激状态的临床研究

目的:观察线粒体基因突变型糖尿病(mitochodrial diabetes mellitus,mtDM)患者体内氧化应激状态,探讨线粒体基因突变与氧化应激的关系。方法:应用聚合酶链反应-限制性片段长度多态性法(PCR-RFLP)筛查2型糖尿病患者(T2DM组)和健康对照组(C组)mtDNA tRNALE(UUUR)3243A→G(A3243G)和mtDNAND412026A→G(A12026G)突变位点发生情况,用酶反应化学比色法测定线粒体基因突变型糖尿病组(mtDM组)、T2DM组及健康对照组外周血中超氧化物歧化酶(SOD)、谷胱甘肽过氧化物酶(GSH-Px)、过氧化氢酶(CAT)、抗活性氧活力(Anti-ROS)和丙二醛(MDA)等氧化应激指标。结果:(1)与C组相比,mtDM组和T2DM组Anti-ROS、SOD、GSH-Px、CAT活性及SOD/MDA均下降(P<0.05),MDA含量升高(P<0.05或P<0.01)。(2)mtDM组与T2DM组相比,CAT活性下降(P<0.05),MDA含量升高(P<0.05或P<0.01)。(3)A3243G突变组和A12026G突变组之间SOD、GSH-Px、CAT、Anti-ROS活性和MDA差异无统计学意义(P>0.05)。结论:线粒体基因突变型糖尿病较无突变2型糖尿病患者及健康对照组氧化应激损伤更严重,可能与线粒体基因突变有关。     

Long-term effects of ozone and nitrogen dioxide on the metabolism and population of alveolar macrophages.

To investigate how alveolar macrophages adapt themselves to oxidative pollutants in the long term, rats were exposed to a strong oxidant, ozone (O3), or a weak oxidant, nitrogen dioxide (NO2), for a maximum duration of 12 wk. After exposures, alveolar macrophages were collected by pulmonary lavage. Throughout 11 wk of exposure to 0.2 ppm O3, the specific activities of glucose-6-phosphate dehydrogenase (G6PDH) and glutathione peroxidase of the peroxidative metabolic pathway and pyruvate kinase and hexokinase of the glycolytic pathway were 40-70% elevated over the controls in alveolar macrophages. The population of alveolar macrophages was consistently 60% higher than the controls. The small-sized macrophages, immature macrophages, preferentially increased. To the contrary, the thymidine incorporation per cell was always 20-30% lower than in the controls, although the total incorporation remained unchanged. No infiltration of polymorphonuclear leukocytes occurred. By 12 wk of exposures to 1.2 and 4.0 ppm NO2, the population of alveolar macrophages increased 30% over the control. Among the enzymes examined, however, only the G6PDH activity increased 10% for 4.0 ppm NO2. No increase in the enzyme activities occurred for 1.2 ppm NO2. Based on these results, alveolar macrophages adapt themselves to the long-term exposure of O3 or NO2 by recruiting immature macrophages through an apparent influx of monocytes. During the exposure to O3, the peroxidative metabolic and glycolytic pathways are enhanced persistently in alveolar macrophages, whereas both pathways were not enhanced by the exposures to NO2.     

K-ras gene sequence effects on the formation of 4-(methylnitrosamino)-1-(3-pyridyl)-1-butanone (NNK)-DNA adducts

The tobacco specific pulmonary carcinogen 4-(methylnitrosamino)-1-(3-pyridyl)-1-butanone (NNK) is metabolically activated to electrophilic species that form methyl and pyridyloxobutyl adducts with genomic DNA, including O(6)-methylguanine, N7-methylguanine, and O(6)-[4-oxo-4-(3-pyridyl)butyl]guanine. If not repaired, these lesions could lead to mutations and the initiation of cancer. Previous studies used ligation-mediated polymerase chain reaction (LMPCR) in combination with PAGE to examine the distribution of NNK-induced strand breaks and alkali labile lesions (e.g., N7-methylguanine) within gene sequences. However, LMPCR cannot be used to establish the distribution patterns of highly promutagenic O(6)-methylguanine and O(6)-[4-oxo-4-(3-pyridyl)butyl]guanine adducts of NNK. We have developed methods based on stable isotope labeling HPLC-electrospray ionization tandem mass spectrometry (HPLC-ESI MS/MS) that enable us to accurately quantify NNK-induced adducts at defined sites within DNA sequences. In the present study, the formation of N7-methylguanine, O(6)-methylguanine, and O(6)-[4-oxo-4-(3-pyridyl)butyl]guanine adducts at specific positions within a K-ras gene-derived double-stranded DNA sequence (5'-G(1)G(2)AG(3)CTG(4)G(5)TG(6)G(7)CG(8)TA G(9)G(10)C-3') was investigated following treatment with activated NNK metabolites. All three lesions preferentially formed at the second position of codon 12 (GGT), the major mutational hotspot for G-->A and G-->T base substitutions observed in smoking-induced lung tumors. Therefore, our data support the involvement of NNK and other tobacco specific nitrosamines in mutagenesis and carcinogenesis.     

Reactive oxygen species generated by PAH o-quinones cause change-in-function mutations in p53

Polycyclic aromatic hydrocarbons (PAHs) in tobacco smoke may cause human lung cancer via metabolic activation to ultimate carcinogens. p53 is one of the most commonly mutated tumor suppressor genes in this disease. An analysis of the p53 mutational database shows that G to T transversions are a signature mutation of lung cancer. Aldo-keto reductases (AKRs) activate PAH trans-dihydrodiol proximate carcinogens to yield their corresponding reactive and redox-active o-quinones, e.g., benzo[a]pyrene-7,8-dione (BP-7,8-dione). We employed a yeast reporter system to determine whether PAH o-quinones or the ROS they generate cause change-in-function mutations in p53. N-Methyl-N-nitroso-N'-nitro-guanidine, a standard alkylating mutagen was used as a positive control. MNNG caused a dose-dependent increase in mutant yeast colonies and at the highest concentrations 8-14% of the yeast colonies were mutated and were characterized by G:C to A:T transitions in the p53 DNA binding domain. Treatment of p53 cDNA with micromolar concentrations of (+/-)-anti-7,8-dihydroxy-9alpha,10alpha-epoxy-7,8,9,10-tetrahydro-benzo[a]pyrene, (anti-BPDE, an ultimate carcinogen) or sub-micromolar concentrations of BP-7,8-dione in the presence of redox-cycling conditions (NADPH and CuCl(2)) also caused p53 mutations in a dose-dependent manner. We found that no mutants were observed with PAH o-quinones or NADPH alone. p53 mutagenesis by BP-7,8-dione was attenuated by ROS scavengers and completely abrogated by a combination of superoxide dismutase and catalase, indicating that both superoxide anion and hydroxyl radicals were the responsible mutagens. The bulk of the mutations detected were single-point mutations and were not random in occurrence. Over 46% of BP-7,8-dione-induced mutations were G:C to T:A transversions, consistent with the formation of 8-oxo-dGuo or its secondary oxidation products. In addition, 25% of these mutations were at hotspots in p53 which are known to be mutated in lung cancer. Together these data suggest that PAH o-quinones generate an endogenous mutagen (ROS) which leads to p53 inactivation. These observations provide an alternative route to G to T transversions that dominate in p53 in lung cancer.