Substrate specificity of 3-methyladenine-DNA glycosylase from calf thymus

Dose and temporal evaluation of ethylene oxide-induced mutagenicity in the lungs of male big blue mice following inhalation exposure to carcinogenic concentrations

Ethylene oxide (EO) is a direct acting alkylating agent; in vitro and in vivo studies indicate that it is both a mutagen and a carcinogen. However, it remains unclear whether the mode of action (MOA) for cancer for EO is a mutagenic MOA, specifically via point mutation. To investigate the MOA for EO-induced mouse lung tumors, male Big Blue (BB) B6C3F1 mice (10/group) were exposed to EO by inhalation, 6 hr/day, 5 days/week for 4 (0, 10, 50, 100, or 200 ppm EO), 8, or 12 weeks (0, 100, or 200 ppm EO). Lung DNA samples were analyzed for cII mutant frequency (MF) at 4, 8 and 12 weeks of exposure; the mutation spectrum was analyzed for mutants from control and 200 ppm EO treatments. Although EO-induced cII MFs were 1.5- to 2.7-fold higher than the concurrent controls at 4 weeks, statistically significant increases in the cII MF were found only after 8 and 12 weeks of exposure and only at 200 ppm EO (P ≤ 0.05), which is twice the highest concentration used in the cancer bioassay. Consistent with the positive response, DNA sequencing of cII mutants showed a significant shift in the mutational spectra between control and 200 ppm EO following 8 and 12 week exposures (P ≤ 0.035), but not at 4 weeks. Thus, EO mutagenic activity in vivo was relatively weak and required higher than tumorigenic concentrations and longer than 4 weeks exposure durations. These data do not follow the classical patterns for a MOA mediated by point mutations. Environ. Mol. Mutagen. 58:122-134, 2017. © 2017 Wiley Periodicals, Inc.

Evaluation of cII gene mutation in the brains of Big Blue mice exposed to acrylamide and glycidamide in drinking water

Potential health risks for humans from dietary exposure to acrylamide (AA) and its reactive epoxide metabolite, glycidamide (GA), exist because substantial amounts of AA are found in a variety of fried and baked starchy foods. AA is tumorigenic in rodents, and a large number of studies indicate that AA is genotoxic in multiple organs of mice and rats. Although AA is neurotoxic, there are no reports on AA-induced gene mutations in the mouse brain. Therefore, to investigate if gene mutation can be induced by AA or its metabolite GA, we screened brains for cII mutant frequency (MF) and scored for mutation types in previously treated male and female Big Blue mice with 0, 1.4 mM, and 7.0 mM AA or GA in drinking water for up to 4 weeks. High doses of AA and GA induced similar cII MFs in males and females but only the induced cII MF in males was significantly higher than the corresponding male control MF (p < 0.05). Molecular analysis of the cII mutants from males showed that AA and GA each induced at least a 2.5-fold increase in the incidence of G:C → T:A, A:T → T:A, and A:T → C:G transversions compared to the vehicle controls, with similar mutational spectra observed when comparing AA with GA treatment. These results suggest that the MFs and types of mutations induced by AA and GA in the brain are consistent with AA exerting its genotoxicity via metabolism to GA.

Acrylamide-induced carcinogenicity in mouse lung involves mutagenicity: cII gene mutations in the lung of big blue mice exposed to acrylamide and glycidamide for up to 4 weeks

Potential health risks for humans from exposure to acrylamide (AA) and its epoxide metabolite glycidamide (GA) have garnered much attention lately because substantial amounts of AA are present in a variety of fried and baked starchy foods. AA is tumorigenic in rodents, and a large number of in vitro and in vivo studies indicate that AA is genotoxic. A recent cancer bioassay on AA demonstrated that the lung was one of the target organs for tumor induction in mice; however, the mutagenicity of AA in this tissue is unclear. Therefore, to investigate whether or not gene mutation is involved in the etiology of AA- or GA-induced mouse lung carcinogenicity, we screened for cII mutant frequency (MF) in lungs from male and female Big Blue (BB) mice administered 0, 1.4, and 7.0 mM AA or GA in drinking water for up to 4 weeks (19-111 mg/kg bw/days). Both doses of AA and GA produced significant increases in cII MFs, with the high doses producing responses 2.7-5.6-fold higher than the corresponding controls (P ≤ 0.05; control MFs = 17.2 ± 2.2 and 15.8 ± 3.5 × 10(-6) in males and females, respectively). Molecular analysis of the mutants from high doses indicated that AA and GA produced similar mutation spectra and that these spectra were significantly different from the spectra in control mice (P ≤ 0.01). The predominant types of mutations in the lung cII gene from AA- and GA-treated mice were A:T → T:A, and G:C → C:G transversions, and -1/+1 frameshifts at a homopolymeric run of Gs. The MFs and types of mutations induced by AA and GA in the lung are consistent with AA exerting its genotoxicity via metabolism to GA. These results suggest that AA is a mutagenic carcinogen in mouse lungs and therefore further studies on its potential health risk to humans are warranted. Environ. Mol. Mutagen. 56:446-456, 2015. © 2015 Wiley Periodicals, Inc.

Promoter structure and cell cycle dependent expression of the human methylpurine-DNA glycosylase gene

The methylpurine-DNA glycosylase (MPG) gene coding for human 3-methyladenine (3-meAde)-DNA glycosylase functions in the first step of base excision repair (BER) to remove numerous damaged bases including 3-meGua, ethenoadenine, and hypoxanthine (Hx) in addition to 3-meAde. In this report, we identify the length of the minimal MPG promoter region, demonstrate the involvement of several transcription factors in expression of the MPG gene, and determine the point at which transcription initiates. We also demonstrate that control of MPG expression is linked to MPG activity. To initiate studies on how the MPG functions with the ensemble of BER genes to effect repair, we have investigated the cell cycle control of MPG and other BER genes in normal human cells. Steady-state mRNA levels of MPG, human Nth homologue (NTH), and uracil-DNA glycosylase (UDG), DNA glycosylases, and human AP site-specific endonuclease (APE), an endonuclease incising DNA at abasic sites, are cell cycle dependent. In contrast, expression levels of genes coding for human 8-oxoguanine-DNA glycosylase (OGG1) and TDG DNA glycosylases, and omicron 6-methylguanine-DNA methyltransferase (MGMT) gene, and the RPA4 subunit gene do not vary with cell cycle. These observed cell cycle dependent differences might reflect distinct roles of individual BER proteins in mutation avoidance.

Heterogeneous repair of N-methylpurines at the nucleotide level in normal human cells

Base excision repair rates of dimethyl sulfate-induced 3-methyladenine and 7-methylguanine adducts were measured at nucleotide resolution along the PGK1 gene in normal human fibroblasts. Rates of 7-methylguanine repair showed a 30-fold dependence on nucleotide position, while position-dependent repair rates of 3-methyladenine varied only sixfold. Slow excision rates for 7-methylguanine bases afforded the opportunity to study their excision in vitro as a model for base excision repair. A two-component in vitro excision system, composed of human N-methylpurine-DNA glycosylase (MPG protein) and dimethyl sulfate-damaged DNA manifested sequence context-dependent rate differences for 7-methylguanine of up to 185-fold from position to position. This in vitro system reproduced both the global repair rate, and for the PGK1 coding region, the position-dependent repair patterns observed in cells. The equivalence of in vivo repair and in vitro excision data indicates that removal of 7-methylguanine by the MPG protein is the rate-limiting step in base excision repair of this lesion. DNA "repair rate footprints" associated with DNA glycosylase accessibility were observed only in a region with bound transcription factors. The "repair rate footprints" represent a rare chromatin component of 7-meG base excision repair otherwise dominated by sequence-context dependence. Comparison of in vivo repair rates to in vitro rates for 3-methyladenine, however, shows that the rate-limiting step determining position-dependent repair for this adduct is at one of the post-DNA glycosylase stages. In conclusion, this study demonstrates that a comparison of sequence context-dependent in vitro reaction rates to in vivo position-dependent repair rates permits the identification of steps responsible for position-dependent repair. Such analysis is now feasible for the different steps and adducts repaired via the base excision repair pathway.

Transgenic systems in studies on genotoxicity of alkylating agents: critical lesions, thresholds and defense mechanisms

Transgenic systems, both cell lines and mice with gain or loss of function, are being used in order to modulate the expression of DNA repair proteins, thus allowing to assess their contribution to the defense against genotoxic mutagens and carcinogens. In this review, questions have been addressed concerning the use of transgenic systems in elucidating critical primary DNA lesions, their conversion into genotoxic endpoints, low-dose effects, and the relative contribution of individual cellular functions in defense. It has been shown that the repair protein alkyltransferase (MGMT) is decisive for protection against methylating and chloroethylating compounds. Protection pertains also to tumor formation, as revealed by the response of MGMT transgenic and knockout mice. Overexpression of genes involved in base excision repair (N-methylpurine-DNA glycosylase, apurinic endonuclease, DNA polymerase beta) is in most cases not beneficial in increasing the protection level, whereas their down-modulation or inactivation increases cellular sensitivity. This indicates that non-repaired base N-alkylation lesions and/or repair intermediates possess genotoxic potential. Modulation of mismatch repair and poly(ADP)ribosyl transferase has also been shown to affect the cellular response to alkylating agents. Furthermore, the role of Fos, Jun and p53 in cellular defense against alkylating mutagens is discussed.

Specific interaction of wild-type and truncated mouse N-methylpurine-DNA glycosylase with ethenoadenine-containing DNA

N-Methylpurine-DNA glycosylase (MPG), a ubiquitous DNA repair enzyme, is responsible for the removal of a wide variety of alkylated base lesions in DNA, e.g., N-alkylpurines and cyclic ethenoadducts of adenine, guanine, and cytosine. These lesions, some of which are mutagenic and toxic, are generated endogenously or by genotoxic agents such as N-alkylnitrosamines and vinyl chloride. Wild-type mouse MPG, expressed from recombinant baculovirus, was purified to near homogeneity for studying its specific interaction with substrate, 1,N6-ethenoadenine- (epsilonA-) containing DNA. Electrophoretic mobility shift assays (EMSA) indicated that MPG formed a specific complex with a 50-mer epsilonA-containing duplex oligonucleotide. This complex was shown to be a transient reaction intermediate, because it could be formed only with the unreacted substrate and contained active enzyme molecules. DNA footprinting studies confirmed the specific binding of the protein to the epsilonA-containing duplex oligonucleotide; eight nucleotides on the epsilonA-containing strand and 16-17 nucleotides in the complementary strand spanning the base adduct were protected from DNase I digestion. A systematic deletion analysis of MPG was carried out in order to determine the minimally sized polypeptide capable of forming a stable substrate complex that is also suitable for characterization by NMR spectroscopy and X-ray crystallography. A truncated polypeptide (NDelta100CDelta18) lacking 100 and 18 amino acid residues from the amino and carboxyl termini, respectively, was found to be the minimal size that retained activity. The truncated and wild-type enzymes have similar kinetic properties. Moreover, both EMSA and DNase I footprinting studies indicated identical pattern of specific binding by the truncated and full-length polypeptides. Removal of five and nine additional residues from the amino- and carboxyl-termini of this polypeptide, respectively, resulted in a complete loss of activity. These results suggest that minimal structural change occured as a result of truncation in the NDelta100CDelta18 mutant, which may thus be suitable for elucidating the structure and mechanism of MPG.

Introduction, distribution, and removal of 7-methylguanine in different liver chromatin fractions of young and old mice

The distribution and elimination of 7-methylguanine (m7Gua) from different liver DNA chromatin fractions has been studied after treating young and old mice with N-methyl-N-nitrosourea (MNU). Guanine methylation kinetics was first studied in total liver DNA following intraperitoneal injections of 25 mg/kg and 50 mg/kg MNU does. MNU-induced DNA alkylation, as measured by m7Gua levels, was dose-dependent in liver tissues of young (9-11 month) and old mice (28-29 month). However, liver DNA in old mice incurred approximately 50% more damage than young mice for weight-normalized doses of MNU. The kinetics of adduct removal from total DNA was biphasic. A more rapid phase of m7Gua removal was observed during the first 24 h to 48 h following MNU administration; thereafter, the remaining m7Gua adducts were hydrolyzed much more slowly. Similar amounts of m7Gua were removed by 24 h at both the 25 mg/kg and 50 mg/kg MNU doses for a single age-group, but old liver tissue removed significantly more m7Gua than young liver tissue during this initial phase. Following a single injection of carcinogen (50 mg/kg), liver nuclei were isolated and chromatin was sheared by limited Micrococcal nuclease digestion. Chromatin was separated into nuclease-soluble, low-salt, high-salt and nuclear matrix fractions. All four fractions of young liver chromatin were methylated to the same degree. In contrast, there were differences in m7Gua levels between old liver chromatin fractions. DNA in the nuclease-sensitive fraction was most heavily alkylated, whereas nuclear matrix sequences were modified the least. Removal of m7Gua occurred at relatively uniform rates in all chromatin fractions regardless of age, indicating that m7Gua was not preferentially repaired in different nuclease-susceptible regions of chromatin. These results suggest that the N-methylpurine-DNA glycosylase responsible for eliminating m7Gua from the mammalian genome is not deficient in senescent liver tissue. However, there may be age-related changes in chromatin composition or structure that make some genomic sequences more accessible to alkylating agents in liver tissue of older animals.

Overexpression of N-methylpurine-DNA glycosylase in Chinese hamster ovary cells renders them more sensitive to the production of chromosomal aberrations by methylating agents--a case of imbalanced DNA repair

The main N-alkylation products induced in DNA by methylating mutagens (7-methylguanine, 3-methyladenine, 3-methylguanine) are removed by excision repair involving, in the first step of the repair pathway, N-methylpurine-DNA glycosylase (MPG). To elucidate the significance of excision repair of N-alkylpurines in the defense of cells against alkylating agents we have modulated the efficiency of removal of N-methylpurines in Chinese hamster cells by transfecting them with the human MPG cDNA cloned into a mammalian expression vector. Although the stably transfected cells had a significantly higher capacity for removal of N-methylpurines from DNA, they did not gain protection against the cytotoxic and mutagenic effect of alkylating agents. The cells even responded more sensitively with respect to SCE formation. Here we show that the frequency of chromosomal aberrations induced by methyl methanesulfonate and N-methyl-N'-nitro-N-nitrosoguanidine is significantly enhanced in the transfectants. Furthermore the transfectants showed a stronger inhibition of DNA replication and a higher yield of DNA breaks, as measured several hours after methylating agent exposure. The data suggest that overexpression of MPG causes an imbalance in the multi-step process of excision of N-methylpurines from DNA giving rise to a high yield of apurinic sites and/or gapped DNA that are intermediates in the formation of chromosomal aberrations, SCEs and the inhibition of replication in cells exposed to alkylating agents.

Purification and biochemical characterization of recombinant N-methylpurine-DNA glycosylase of the mouse

The mouse N-methylpurine-DNA glycosylase (MPG), responsible for the removal of most N-alkyladducts in DNA, was purified to homogeneity as a recombinant nonfusion protein from Escherichia coli. Only 10-15% of the protein was present in the soluble form in E. coli cells. The N-terminal amino acid sequence of the purified protein which lacks 48 residues from the amino terminus of the wild type protein was identical to that predicted from the nucleotide sequence. The glycosylase hydrolyzes 3-methyladenine (m3A), 7-methylguanine(m7G), and 3-methylguanine (m3G) from DNA, and the Km and kcat values were 130 nM and 0.8 min-1 for m3A, and 860 nM and 0.2 min-1 for m7G, respectively, when methylated calf thymus DNA was used as the substrate. A comparison of kcat/Km values for different bases indicates that the enzyme was more efficient in excising both m3A and m3G than m7G from methylated DNA. The enzyme showed moderate binding affinities (KA) for both methylated (5.8 x 10(7) M-1) and nonmethylated DNAs (4.2 x 10(7) M-1). The mouse protein has an extinction coefficient E280nm1% of 10.5 and a pI of 9.3. The enzyme activity was optimal in the presence of 100 mM NaCl, with a broad pH optimum of 8.5-9.5. The enzymatic release of both m3A and m7G was stimulated 50-75% by 0.5 mM MgCl2 and 0.02 mM spermine but inhibited by higher concentrations of these agents. Product inhibition by 40-50% of the reaction occurred in the presence of 10 mM m3A or m7G. However, 1.0 mM m3A stimulated release of m7G. The enzyme was inhibited by 60% in the presence of 0.9 mg/mL DNA which, at the same time, protected it from thermal inactivation.

Purification and characterization of human 3-methyladenine-DNA glycosylase

A human cDNA coding sequence for a 3-methyladenine-DNA glycosylase was expressed in Escherichia coli. In addition to the full-length 3-methyladenine-DNA glycosylase coding sequence, two other sequences (resulting from differential RNA splicing and the truncated anpg cDNA) derived from that sequence were also expressed. All three proteins were purified to physical homogeneity and their N-terminal amino acid sequences are identical to those predicted by the nucleic acid sequences. The full-length protein has 293 amino acids coding for a protein with a molecular mass of 32 kDa. Polyclonal antibodies against one of the proteins react with the other two proteins, and a murine 3-methyladenine-DNA glycosylase, but not with several other E. coli DNA repair proteins. All three proteins excise 3-methyl-adenine, 7-methylguanine, and 3-methylguanine as well as ethylated bases from DNA. The activities of the proteins with respect to ionic strength (optimum 100 mM KCl), pH (optimum 7.6), and kinetics for 3-methyladenine and 7-methylguanine excision (average values: 3-methyladenine: Km 9 nM and kcat 10 min-1, 7-methylguanine: Km 29 nM and kcat 0.38 min-1) are comparable. In contrast to these results, however, the thermal stability of the full-length and splicing variant proteins at 50 degrees C is less than that of the truncated protein.

Detection of DNA adducts at the DNA sequence level by ligation-mediated PCR

Many carcinogens and mutagens interact with DNA to form specific adducts. Base-specificity and sequence-specificity of adduct formation has been analyzed previously with cloned, end-labelled DNA fragments. However, the distribution of adducts along a mammalian chromosome may be modulated by chromatin structure and could be different from that in naked plasmid DNA. Recently, a method has been developed that utilizes the sensitivity of the polymerase chain reaction (PCR) to detect DNA adducts at the DNA sequence level in mammalian cells. The sequence position of adducts can be mapped whenever it is possible to convert the adduct, either chemically or enzymatically, into a DNA strand break with a 5'-phosphate group. Fragments containing these ligatable breaks are amplified in a single-sided, ligation-mediated PCR reaction. We have used ligation-mediated PCR for detection of alkylguanine adducts and UV-induced cyclobutane pyrimidine dimers and (6-4) photoproducts. We discuss the sensitivity of the method, its limitations, and its potential for mapping other DNA adducts at the DNA sequence level in mammalian cells.

Contribution of O6-alkylguanine and N-alkylpurines to the formation of sister chromatid exchanges, chromosomal aberrations, and gene mutations: new insights gained from studies of genetically engineered mammalian cell lines

O6-methyl- and O6-ethylguanine are the major premutagenic and precarcinogenic lesions induced in DNA by monofunctional alkylating agents, albeit formed in minor amounts. The involvement of these lesions in SCE and aberration formation is less clear. We have analyzed the contribution of O6-alkylguanine to SCE and aberration formation, as well as its toxic and point mutation inducing effect in transgenic Chinese hamster ovary (CHO) cell lines that express variable amounts of human O6-methylguanine-DNA methyltransferase (MGMT). Cells that overexpress MGMT (or the bacterial Ada protein) gained resistance to the formation of alkylation-induced SCEs and aberrations, as compared to MGMT deficient cells. A correlation was apparent between the level of protection for SCEs and cell killing, indicating that both phenomena are interrelated. The protective effects were dependent on the level of MGMT expression, the agent used for alkylation, and cell cycle progression. Our data suggest that at least 2 kinds of lesions are responsible for SCE and aberration formation, namely, O6-alkylguanine and one or various N-alkylation products. The probability that O6-methylguanine is converted into cytogenetic effects has been estimated to be about 1:30 for SCEs, and 1:147,000 and 1:22,000 for chromosomal aberrations in the first and second post-treatment mitosis, respectively. The induction of SCEs and likely also of aberrations by O6-methylguanine requires two replication cycles and is supposed to involve the formation of secondary DNA lesions. Increased repair of 3-methyladenine and 7-methylguanine in CHO cells that overexpress the N-methylpurine-DNA glycosylase (MPG) after transfection with the human MPG-cDNA did not give rise to protection against methylation-induced SCEs and aberrations, probably because of incomplete excision repair. MPG overexpressing cells reacted even more sensitively to methylating agents, suggesting apurinic sites formed as a result of MPG action to be SCE and aberration-inducing lesions.

Action of spermidine, N1-acetylspermidine, and N8-acetylspermidine at apurinic sites in DNA

The cleavage efficiency of spermidine and its acetyl derivatives (N1-acetylspermidine and N8-acetylspermidine) at apurinic sites in DNA were examined by PAGE-urea analysis. The three polyamines induced different rates of cleavage when compared at 1 mM concentrations. The order of effectiveness were: spermidine greater than N8-acetylspermidine greater than N1-acetylspermidine. Thus a decrease in efficiency was observed when the first order amino-groups of spermidine were blocked. The N-8amino-group of spermidine was less effective in inducing cleavage at AP-sites than the N1-amino-group. Among several proposed models of polyamine-DNA interactions, our results can best be explained by the model postulated by Liquori et al.

Action of a mammalian AP-endonuclease on DNAs of defined sequences

An apurinic/apyrimidinic (AP) specific endonuclease from mouse plasmacytoma cells (line MPC-11), was observed to cleave apurinic sites in oligonucleotides 9, 11, 12, 39 and 40 nucleotides in length. However, the enzyme failed to cleave AP-sites in two oligonucleotides 7 nucleotides in length. The maximum rates of digestion observed on these short single-stranded DNA (ssDNA) fragments were approximately 1/30 of the rates observed on double-stranded DNA (dsDNA). In studies using the Maxam-Gilbert DNA sequencing analysis, apurinic sites in purine-rich regions were preferentially cleaved in dsDNA but not in ssDNA, indicating that the enzyme has a sequence preference on dsDNA. These results suggest that some sites on DNA might be more efficiently repaired than others.

Tissue-specific variation in repair activity for 3-methyladenine in DNA in two stocks of mice

Two stocks of mice, hybrid (C3H X 101)F1 and inbred SEC/R1, were compared for 3-methyladenine-DNA N-glycosylase activity which is involved in removal of 3-methyladenine, 7-methylguanine and some other N-methylpurines in DNA, in cell-free extracts of different tissues. Based on activity measured both per unit weight of tissue and per mass DNA, there is a significant organ-specific and stock-specific difference in N-glycosylase activity over a range of 0.5-8.7 fmoles of 3-methyladenine released per h at 37 degrees C per micrograms DNA of tissue extract. On a per cell basis, the repair activity for 3-methyladenine is the highest in stomach in both stocks. The tissue can be arranged in order of decreasing activity of glycolytic removal as stomach greater than kidney greater than lung greater than liver greater than spleen greater than brain greater than ovary for SEC/R1 mice and stomach greater than kidney greater than ovary greater than spleen, lung and brain greater than liver for the hybrid mice. For all tissues except ovary, SEC/R1 mice have 1.5-4-fold higher specific N-glycosylase activity than (C3H X 101)F1 mice. In contrast, the ovary of SEC/R1 stock has about half as much enzyme activity as that of the hybrid stock.