In vitro DNA replication implicates O2-ethyldeoxythymidine in transversion mutagenesis by ethylating agents

Adopting duplex sequencing technology for genetic toxicity testing: A proof-of-concept mutagenesis experiment with N-ethyl-N-nitrosourea (ENU)-exposed rats

Duplex sequencing (DS) is an error-corrected next-generation sequencing method in which molecular barcodes informatically link PCR-copies back to their source DNA strands, enabling computational removal of errors in consensus sequences. The resulting background of less than one artifactual mutation per 107 nucleotides allows for direct detection of somatic mutations. TwinStrand Biosciences, Inc. has developed a DS-based mutagenesis assay to sample the rat genome, which can be applied to genetic toxicity testing. To evaluate this assay for early detection of mutagenesis, a time-course study was conducted using male Hsd:Sprague Dawley SD rats (3 per group) administered a single dose of 40 mg/kg N-ethyl-N-nitrosourea (ENU) via gavage, with mutation frequency (MF) and spectrum analyzed in stomach, bone marrow, blood, and liver tissues at 3 h, 24 h, 7 d, and 28 d post-exposure. Significant increases in MF were observed in ENU-exposed rats as early as 24 h for stomach (site of contact) and bone marrow (a highly proliferative tissue) and at 7 d for liver and blood. The canonical, mutational signature of ENU was established by 7 d post-exposure in all four tissues. Interlaboratory analysis of a subset of samples from different tissues and time points demonstrated remarkable reproducibility for both MF and spectrum. These results demonstrate that MF and spectrum can be evaluated successfully by directly sequencing targeted regions of DNA obtained from various tissues⁠, a considerable advancement compared to currently used in vivo gene mutation assays.

Adopting Duplex Sequencing™ Technology for Genetic Toxicity Testing: A Proof-of-Concept Mutagenesis Experiment with N-Ethyl-N-Nitrosourea (ENU)-Exposed Rats

Duplex sequencing (DuplexSeq) is an error-corrected next-generation sequencing (ecNGS) method in which molecular barcodes informatically link PCR-copies back to their source DNA strands, enabling computational removal of errors by comparing grouped strand sequencing reads. The resulting background of less than one artifactual mutation per 10 7 nucleotides allows for direct detection of somatic mutations. TwinStrand Biosciences, Inc. has developed a DuplexSeq-based mutagenesis assay to sample the rat genome, which can be applied to genetic toxicity testing. To evaluate this assay for early detection of mutagenesis, a time-course study was conducted using male Hsd:Sprague Dawley SD rats (3 per group) administered a single dose of 40 mg/kg N-ethyl-N-nitrosourea (ENU) via gavage, with mutation frequency (MF) and spectrum analyzed in stomach, bone marrow, blood, and liver tissues at 3 h, 24 h, 7 d, and 28 d post-exposure. Significant increases in MF were observed in ENU-exposed rats as early as 24 h for stomach (site of contact) and bone marrow (a highly proliferative tissue) and at 7 d for liver and blood. The canonical, mutational signature of ENU was established by 7 d post-exposure in all four tissues. Interlaboratory analysis of a subset of samples from different tissues and time points demonstrated remarkable reproducibility for both MF and spectrum. These results demonstrate that MF and spectrum can be evaluated successfully by directly sequencing targeted regions of DNA obtained from various tissues, a considerable advancement compared to currently used in vivo gene mutation assays.

HIGHLIGHTS

DuplexSeq is an ultra-accurate NGS technology that directly quantifies mutationsENU-dependent mutagenesis was detected 24 h post-exposure in proliferative tissuesMultiple tissues exhibited the canonical ENU mutation spectrum 7 d after exposureResults obtained with DuplexSeq were highly concordant between laboratoriesThe Rat-50 Mutagenesis Assay is promising for applications in genetic toxicology.

Comparison of the frequencies of ENU-induced point mutations in male germ cells and inherited germline mutations in their offspring

Background

Gene mutations induced in germ cells may be transmitted to the next generation and cause adverse effects such as genetic diseases. Certain mutations may result in infertility or death in early development. Thus, the mutations may not be inheritable. However, the extent to which point mutations in male germ cells are transmitted to the next generation or eliminated during transmission is largely unknown. This study compared mutation frequencies (MFs) in sperm of N-ethyl-N-nitrosourea (ENU)-treated gpt delta mice and de novo MFs in the whole exome/genome of their offspring.

Results

Male gpt delta mice were treated with 10, 30, and 85 mg/kg of ENU (i.p., weekly × 2) and mated with untreated females to generate offspring. We previously reported a dose-dependent increase in de novo MFs in the offspring estimated by whole exome sequencing (WES) (Mutat. Res., 810, 30–39, 2016). In this study, gpt MFs in the sperm of ENU-treated mice were estimated, and the MFs per reporter gene were converted to MFs per base pair. The inherited de novo MFs in the offspring (9, 26 and 133 × 10^− 8/bp for 10, 30, and 85 mg/kg ENU-treated groups, respectively) were comparable to those of the converted gpt MFs in the sperm of ENU-treated fathers (6, 16, and 69 × 10^− 8/bp). It indicated that the gpt MFs in the ENU-treated father’s sperm were comparable to the inherited de novo MFs in the offspring as estimated by WES. In addition, de novo MFs in the offspring of 10 mg/kg ENU-treated and control fathers were estimated by whole genome sequencing (WGS), because WES was not sufficiently sensitive to detect low background MF. The de novo MF in the offspring of the ENU-treated fathers was 6 × 10^− 8/bp and significantly higher than that of the control (2 × 10^− 8/bp). There were no significant differences in de novo MFs between gene-coding and non-coding regions. WGS analysis was able to detect ENU-induced characteristic de novo base substitutions at a low dose group.

Conclusions

Despite a difference between exome/genome and exogenous reporter genes, the results indicated that ENU-induced point mutations in male germ cells could be transmitted to the next generation without severe selection.

Supplementary Information

The online version contains supplementary material available at 10.1186/s41021-021-00216-z.

New homozygous gpt delta transgenic rat strain improves an efficiency of the in vivo mutagenicity assay

Background

Gene mutation assays in transgenic rodents are useful tools to investigate in vivo mutagenicity in a target tissue. Using a lambda EG10 transgene containing reporter genes, gpt delta transgenic mice and rats have been developed to detect point mutations and deletions. The transgene is integrated in the genome and can be rescued through an in vitro packaging reaction. However, the packaging efficiency is lower in gpt delta rats than in mice, because of the transgene in gpt delta rats being heterozygous and in low copy number. To improve the packaging efficiency, we herein describe a newly developed homozygous gpt delta rat strain.

Results

The new gpt delta rat has a Wistar Hannover background and has been successfully maintained as homozygous for the transgene. The packaging efficiency in the liver was 4 to 8 times higher than that of existing heterozygous F344 gpt delta rats. The frequency of gpt point mutations significantly increased in the liver and bone marrow of N-nitroso-N-ethylurea (ENU)- and benzo[a]pyrene (BaP)-treated rats. Spi⁻ deletion frequencies significantly increased in the liver and bone marrow of BaP-treated rats but not in ENU-treated rats. Whole genome sequencing analysis identified ≥ 30 copies of lambda EG10 transgenes integrated in rat chromosome 1.

Conclusions

The new homozygous gpt delta rat strain showed a higher packaging efficiency, and could be useful for in vivo gene mutation assays in rats.

Supplementary Information

The online version contains supplementary material available at 10.1186/s41021-021-00195-1.

Tissue-specific and time-dependent clonal expansion of ENU-induced mutant cells in gpt delta mice

DNA mutations play a crucial role in the origins of cancer, and the clonal expansion of mutant cells is one of the fundamental steps in multistage carcinogenesis. In this study, we correlated tumor incidence in B6C3F1 mice during the period after exposure to N-ethyl-N-nitrosourea (ENU) with the persistence of ENU-induced mutant clones in transgenic gpt delta B6C3F1 mice. The induced gpt mutations afforded no selective advantage in the mouse cells and could be distinguished by a mutational spectrum that is characteristic of ENU treatment. The gpt mutations were passengers of the mutant cell of origin and its daughter cells and thus could be used as neutral markers of clones that arose and persisted in the tissues. Female B6C3F1 mice exposed for 1 month to 200 ppm ENU in the drinking water developed early thymic lymphomas and late liver and lung tumors. To assay gpt mutations, we sampled the thymus, liver, lung, and small intestine of female gpt delta mice at 3 days, 4 weeks, and 8 weeks after the end of ENU exposure. Our results reveal that, in all four tissues, the ENU-induced gpt mutations persisted for weeks after the end of mutagen exposure. Clonal expansion of mutant cells was observed in the thymus and small intestine, with the thymus showing larger clone sizes. These results indicate that the clearance of mutant cells and the potential for clonal expansion during normal tissue growth depends on tissue type and that these factors may affect the sensitivity of different tissues to carcinogenesis. Environ. Mol. Mutagen. 58:592-606, 2017. © 2017 Wiley Periodicals, Inc.

Braf Mutations Initiate the Development of Rat Gliomas Induced by Postnatal Exposure to N-Ethyl-N-Nitrosourea

A single dose of N-ethyl-N-nitrosourea (ENU) during late prenatal or early postnatal development induces a high incidence of malignant schwannomas and gliomas in rats. Although T->A mutations in the transmembrane domain of the Neu (c-ErbB-2) gene are the driver mutations in ENU-induced malignant schwannomas, the molecular basis of ENU-induced gliomas remains enigmatic. We performed whole-genome sequencing of gliomas that developed in three BDIV and two BDIX rats exposed to a single dose of 80 mg ENU/kg body weight on postnatal day one. T:A->A:T and T:A->C:G mutations, which are typical for ENU-induced mutagenesis, were predominant (41% to 55% of all somatic single nucleotide mutations). T->A mutations were identified in all five rat gliomas at Braf codon 545 (V545E), which corresponds to the human BRAF V600E. Additional screening revealed that 33 gliomas in BDIV rats and 12 gliomas in BDIX rats all carried a Braf V545E mutation, whereas peritumoral brain tissue of either strain had the wild-type sequence. The gliomas were immunoreactive to BRAF V600E antibody. These results indicate that Braf mutation is a frequent early event in the development of rat gliomas caused by a single dose of ENU.

Replicative Bypass of O2-Alkylthymidine Lesions in Vitro

DNA alkylation represents a major type of DNA damage and is generally unavoidable due to ubiquitous exposure to various exogenous and endogenous sources of alkylating agents. Among the alkylated DNA lesions, O²-alkylthymidines (O²-alkyldT) are known to be persistent and poorly repaired in mammalian systems and have been shown to accumulate in the esophagus, lung, and liver tissue of rats treated with tobacco-specific N-nitrosamines, i.e., 4-(methylnitrosamino)-1-(3-pyridyl)-1-butanone (NNK) and N'-nitrosonornicotine (NNN). In this study, we assessed the replicative bypass of a comprehensive set of O²-alkyldT lesions, with the alkyl group being a Me, Et, nPr, iPr, nBu, iBu, or sBu, in template DNA by conducting primer extension assays with the use of major translesion synthesis DNA polymerases. The results showed that human Pol η and, to a lesser degree, human Pol κ, but not human polymerase ι or yeast polymerase ζ, were capable of bypassing all O²-alkyldT lesions and extending the primer to generate full-length replication products. Data from steady-state kinetic measurements showed that human Pol η exhibited high frequencies of misincorporation of dCMP opposite those O²-alkyldT lesions bearing a longer straight-chain alkyl group. However, the nucleotide misincorporation opposite branched-chain lesions was not selective, with dCMP, dGMP, and dTMP being inserted at similar efficiencies, though the total frequencies of nucleotide misincorporation opposite the branched-chain lesions differed and followed the order of O²-iPrdT > O²-iBudT > O²-sBudT. Together, the results from the present study provided important knowledge about the effects of the length and structure of the alkyl group in the O²-alkyldT lesions on the fidelity and efficiency of DNA replication mediated by human Pol η.

Improvement of ENU Mutagenesis Efficiency Using Serial Injection and Mismatch Repair Deficiency Mice

ENU mutagenesis is a powerful method for generating novel lines of mice that are informative with respect to both fundamental biological processes and human disease. Rapid developments in genomic technology have made the task of identifying causal mutations by positional cloning remarkably efficient. One limitation of this approach remains the mutation frequency achievable using standard treatment protocols, which currently generate approximately 1–2 sequence changes per megabase when optimized. In this study we used two strategies to attempt to increase the number of mutations induced by ENU treatment. One approach employed mice carrying a mutation in the DNA repair enzyme Msh6. The second strategy involved injection of ENU to successive generations of mice. To evaluate the number of ENU-induced mutations, single mice or pooled samples were analyzed using whole exome sequencing. The results showed that there is considerable variability in the induced mutation frequency using these approaches, but an overall increase in ENU-induced variants from one generation to another was observed. The analysis of the mice deficient for Msh6 also showed an increase in the ENU-induced variants compared to the wild-type ENU-treated mice. However, in both cases the increase in ENU-induced mutation frequency was modest.

Estimation of the frequency of inherited germline mutations by whole exome sequencing in ethyl nitrosourea-treated and untreated gpt delta mice

Background

Germline mutations are heritable and may cause health disadvantages in the next generation. To investigate trans-generational mutations, we treated male gpt delta mice with N-ethyl-N-nitrosourea (ENU) (85 mg/kg intraperitoneally, weekly on two occasions). The mice were mated with untreated female mice and offspring were obtained. Whole exome sequencing analyses were performed to identify de novo mutations in the offspring.

Results

At 20 weeks after the treatment, the gpt mutant frequencies in the sperm of ENU-treated mice were 21-fold higher than those in the untreated control. Liver DNA was extracted from six mice, including the father, mother, and four offspring from each family of the ENU-treated or untreated mice. In total, 12 DNA samples were subjected to whole exome sequencing analyses. We identified de novo mutations in the offspring by comparing single nucleotide variations in the parents and offspring. In the ENU-treated group, we detected 148 mutation candidates in four offspring and 123 (82 %) were confirmed as true mutations by Sanger sequencing. In the control group, we detected 12 candidate mutations, of which, three (25 %) were confirmed. The frequency of inherited mutations in the offspring from the ENU-treated family was 184 × 10⁻⁸ per base, which was 17-fold higher than that in the control family (11 × 10⁻⁸ per base). The de novo mutation spectrum in the next generation exhibited characteristic ENU-induced somatic mutations, such as base substitutions at A:T bp.

Conclusions

These results suggest that direct sequencing analyses can be a useful tool for investigating inherited germline mutations and that the germ cells could be a good endpoint for evaluating germline mutations, which are transmitted to offspring as inherited mutations.

Electronic supplementary material

The online version of this article (doi:10.1186/s41021-016-0035-y) contains supplementary material, which is available to authorized users.

DNA Polymerases η and ζ Combine to Bypass O(2)-[4-(3-Pyridyl)-4-oxobutyl]thymine, a DNA Adduct Formed from Tobacco Carcinogens

4-(Methylnitrosamino)-1-(3-pyridyl)-1-butanone (NNK) and N'-nitrosonornicotine (NNN) are important human carcinogens in tobacco products. They are metabolized to produce a variety 4-(3-pyridyl)-4-oxobutyl (POB) DNA adducts including O(2)-[4-(3-pyridyl)-4-oxobut-1-yl]thymidine (O(2)-POB-dT), the most abundant POB adduct in NNK- and NNN-treated rodents. To evaluate the mutagenic properties of O(2)-POB-dT, we measured the rate of insertion of dNTPs opposite and extension past O(2)-POB-dT and O(2)-Me-dT by purified human DNA polymerases η, κ, ι, and yeast polymerase ζ in vitro. Under conditions of polymerase in excess, polymerase η was most effective at the insertion of dNTPs opposite O(2)-alkyl-dTs. The time courses were biphasic suggesting the formation of inactive DNA-polymerase complexes. The kpol parameter was reduced approximately 100-fold in the presence of the adduct for pol η, κ, and ι. Pol η was the most reactive polymerase for the adducts due to a higher burst amplitude. For all three polymerases, the nucleotide preference was dATP > dTTP ≫ dGTP and dCTP. Yeast pol ζ was most effective in bypassing the adducts; the kcat/Km values were reduced only 3-fold in the presence of the adducts. The identity of the nucleotide opposite the O(2)-alkyl-dT did not significantly affect the ability of pol ζ to bypass the adducts. The data support a model in which pol η inserts ATP or dTTP opposite O(2)-POB-dT, and then, pol ζ extends past the adduct.

2-Thiouracil deprived of thiocarbonyl function preferentially base pairs with guanine rather than adenine in RNA and DNA duplexes

2-Thiouracil-containing nucleosides are essential modified units of natural and synthetic nucleic acids. In particular, the 5-substituted-2-thiouridines (S2Us) present in tRNA play an important role in tuning the translation process through codon-anticodon interactions. The enhanced thermodynamic stability of S2U-containing RNA duplexes and the preferred S2U-A versus S2U-G base pairing are appreciated characteristics of S2U-modified molecular probes. Recently, we have demonstrated that 2-thiouridine (alone or within an RNA chain) is predominantly transformed under oxidative stress conditions to 4-pyrimidinone riboside (H2U) and not to uridine. Due to the important biological functions and various biotechnological applications for sulfur-containing nucleic acids, we compared the thermodynamic stabilities of duplexes containing desulfured products with those of 2-thiouracil-modified RNA and DNA duplexes. Differential scanning calorimetry experiments and theoretical calculations demonstrate that upon 2-thiouracil desulfuration to 4-pyrimidinone, the preferred base pairing of S2U with adenosine is lost, with preferred base pairing with guanosine observed instead. Therefore, biological processes and in vitro assays in which oxidative desulfuration of 2-thiouracil-containing components occurs may be altered. Moreover, we propose that the H2U-G base pair is a suitable model for investigation of the preferred recognition of 3'-G-ending versus A-ending codons by tRNA wobble nucleosides, which may adopt a 4-pyrimidinone-type structural motif.

Replication across regioisomeric ethylated thymidine lesions by purified DNA polymerases

Causal links exist between smoking cigarettes and cancer development. Some genotoxic agents in cigarette smoke are capable of alkylating nucleobases in DNA, and higher levels of ethylated DNA lesions were observed in smokers than in nonsmokers. In this study, we examined comprehensively how the regioisomeric O(2)-, N3-, and O(4)-ethylthymidine (O(2)-, N3-, and O(4)-EtdT, respectively) perturb DNA replication mediated by purified human DNA polymerases (hPols) η, κ, and ι, yeast DNA polymerase ζ (yPol ζ), and the exonuclease-free Klenow fragment (Kf(-)) of Escherichia coli DNA polymerase I. Our results showed that hPol η and Kf(-) could bypass all three lesions and generate full-length replication products, whereas hPol ι stalled after inserting a single nucleotide opposite the lesions. Bypass conducted by hPol κ and yPol ζ differed markedly among the three lesions. Consistent with its known ability to efficiently bypass the minor groove N(2)-substituted 2'-deoxyguanosine lesions, hPol κ was able to bypass O(2)-EtdT, though it experienced great difficulty in bypassing N3-EtdT and O(4)-EtdT. yPol ζ was only modestly blocked by O(4)-EtdT, but the polymerase was strongly hindered by O(2)-EtdT and N3-EtdT. LC-MS/MS analysis of the replication products revealed that DNA synthesis opposite O(4)-EtdT was highly error-prone, with dGMP being preferentially inserted, while the presence of O(2)-EtdT and N3-EtdT in template DNA directed substantial frequencies of misincorporation of dGMP and, for hPol ι and Kf(-), dTMP. Thus, our results suggested that O(2)-EtdT and N3-EtdT may also contribute to the AT → TA and AT → GC mutations observed in cells and tissues of animals exposed to ethylating agents.

Unlocking the bottleneck in forward genetics using whole-genome sequencing and identity by descent to isolate causative mutations

Forward genetics screens with N-ethyl-N-nitrosourea (ENU) provide a powerful way to illuminate gene function and generate mouse models of human disease; however, the identification of causative mutations remains a limiting step. Current strategies depend on conventional mapping, so the propagation of affected mice requires non-lethal screens; accurate tracking of phenotypes through pedigrees is complex and uncertain; out-crossing can introduce unexpected modifiers; and Sanger sequencing of candidate genes is inefficient. Here we show how these problems can be efficiently overcome using whole-genome sequencing (WGS) to detect the ENU mutations and then identify regions that are identical by descent (IBD) in multiple affected mice. In this strategy, we use a modification of the Lander-Green algorithm to isolate causative recessive and dominant mutations, even at low coverage, on a pure strain background. Analysis of the IBD regions also allows us to calculate the ENU mutation rate (1.54 mutations per Mb) and to model future strategies for genetic screens in mice. The introduction of this approach will accelerate the discovery of causal variants, permit broader and more informative lethal screens to be used, reduce animal costs, and herald a new era for ENU mutagenesis.

S-nitrosoglutathione reductase deficiency increases mutagenesis from alkylation in mouse liver

In human hepatocellular carcinoma (HCC) and many other cancers, somatic point mutations are highly prevalent, yet the mechanisms critical in their generation remain poorly understood. S-nitrosoglutathione reductase (GSNOR), a key regulator of protein S-nitrosylation, is frequently deficient in human HCC. Targeted deletion of the GSNOR gene in mice can reduce the activity of the DNA repair protein O (6)-alkylguanine-DNA alkyltransferase (AGT) and promote both carcinogen-induced and spontaneous HCC. In this study, we report that following exposure to the environmental carcinogen diethylnitrosamine, the mutation frequency of a transgenic reporter in the liver of GSNOR-deficient mice (GSNOR(-/-)) is significantly higher than that in wild-type control. In wild-type mice, diethylnitrosamine treatment does not significantly increase the frequency of the transition from G:C to A:T, a mutation deriving from diethylnitrosamine-induced O (6)-ethylguanines that are normally repaired by AGT. In contrast, the frequency of this transition from diethylnitrosamine is increased ~20 times in GSNOR(-/-) mice. GSNOR deficiency also significantly increases the frequency of the transversion from A:T to T:A, a mutation not affected by AGT. GSNOR deficiency in our experiments does not significantly affect either the frequencies of the other diethylnitrosamine-induced point mutations or hepatocyte proliferation. Thus, GSNOR deficiency, through both AGT-dependent and AGT-independent pathways, significantly raises the rates of specific types of DNA mutations. Our results demonstrate a critical role for GSNOR in maintaining genomic integrity in mice and support the hypothesis that GSNOR deficiency is an important cause of the widespread mutations in human HCC.

Low fidelity bypass of O(2)-(3-pyridyl)-4-oxobutylthymine, the most persistent bulky adduct produced by the tobacco specific nitrosamine 4-(methylnitrosamino)-1-(3-pyridyl)-1-butanone by model DNA polymerases

4-(Methylnitrosamino)-1-(3-pyridyl)-1-butanone (NNK) is one of the most important human carcinogens. It is metabolized to produce a variety of methyl and 4-(3-pyridyl)-4-oxo-butyl (POB) DNA adducts. A potentially important POB adduct is O(2)-[4-(3-pyridyl)-4-oxobut-1-yl]thymidine (O(2)-POB-dT) because it is the most abundant POB adduct in NNK-treated rodents. To evaluate the mutagenic properties of O(2)-POB-dT, we measured the rate of insertion of dNTPs opposite and extension past both O(2)-POB-dT and O(2)-methylthymidine (O(2)-Me-dT) by two model polymerases, E. coli DNA polymerase I (Klenow fragment) with the proofreading exonuclease activity inactivated (Kf) and Sulfolobus solfataricus DNA polymerase IV (Dpo4). We found that the size of the alkyl chain only marginally affected the reactivity and that the specificity of adduct bypass was very low. The k(cat)/K(m) for the Kf catalyzed incorporation opposite and extension past the adducts was reduced ∼10(6)-fold when compared to undamaged DNA. Dpo4 catalyzed the incorporation opposite and extension past the adducts approximately 10(3)-fold more slowly than undamaged DNA. The dNTP specificity was less for Dpo4 than for Kf. In general, dA was the preferred base pair partner for O(2)-Me-dT and dT the preferred base pair partner for O(2)-POB-dT. With enzyme in excess over DNA, the time courses of the reactions showed a biphasic kinetics that indicates the formation inactive binary and ternary complexes.

Tobacco-specific nitrosamine-derived O2-alkylthymidines are potent mutagenic lesions in SOS-induced Escherichia coli

To investigate the biological effects of the O(2)-alkylthymidines induced by the tobacco-specific nitrosamine 4-(methylnitrosamino)-1-(3-pyridyl)-1-butanone (NNK), we have replicated a plasmid containing O(2)-methylthymidine (O(2)-Me-dT) or O(2)-[4-(3-pyridyl-4-oxobut-1-yl]thymidine (O(2)-POB-dT) in Escherichia coli with specific DNA polymerase knockouts. High genotoxicity of the adducts was manifested in the low yield of transformants from the constructs, which was 2-5% in most strains but increased 2-4-fold with SOS. In the SOS-induced wild type E. coli, O(2)-Me-dT and O(2)-POB-dT induced 21% and 56% mutations, respectively. For O(2)-POB-dT, the major type of mutation was T → G followed by T → A, whereas for O(2)-Me-dT, T → G and T → A occurred in equal frequency. For both lesions, T → C also was detected in low frequency. The T → G mutation was reduced in strains with deficiency in any of the three SOS polymerases. By contrast, T → A was abolished in the pol V(-) strain, while its frequency in other strains remained unaltered. This suggests that pol V was responsible for the T → A mutations. The potent mutagenicity of these lesions may be related to NNK mutagenesis and carcinogenesis.

Analysis of mutations in the Pig-a gene of spleen T-cells from N-ethyl-N-nitrosourea-treated fisher 344 rats

A rapid in vivo somatic cell gene mutation assay is being developed that measures mutation in the endogenous X-linked phosphatidylinositol glycan, class A gene (Pig-a). The assay detects Pig-a mutants by flow cytometric identification of cells deficient in glycosylphosphatidyl inositol (GPI) anchor synthesis. GPI-deficient, presumed Pig-a mutant cells also can be detected in a cloning assay that uses proaerolysin (ProAER) selection. Previously, we demonstrated that ProAER-resistant (ProAER(r) ) rat spleen T-cells have mutations in the Pig-a gene. In the present study, we report on a more complete analysis of ProAER(r) rat spleen T-cell mutants and describe a mutation spectrum for mutants isolated from rats 4 weeks after treatment with three consecutive doses of 35.6 mg/kg N-ethyl-N-nitrosourea (ENU). We identified a total of 55 independent mutations, with the largest percentage (69%) involving basepair substitution at A:T. The overall spectrum of Pig-a gene mutations was consistent with the types of DNA adducts formed by ENU and was very similar to what has been described for in vivo ENU-induced mutation spectra in other rodent reporter genes (e.g., in the endogenous Hprt gene and transgenic shuttle vectors). These data are consistent with the rat Pig-a assay detecting test-agent-induced mutational responses.

Formation, repair, and genotoxic properties of bulky DNA adducts formed from tobacco-specific nitrosamines

4-(Methylnitrosamino)-1-(3-pyridyl)-1-butanone (NNK) and N′-nitrosonornicotine (NNN) are tobacco-specific nitrosamines present in tobacco products and smoke. Both compounds are carcinogenic in laboratory animals, generating tumors at sites comparable to those observed in smokers. These Group 1 human carcinogens are metabolized to reactive intermediates that alkylate DNA. This paper focuses on the DNA pyridyloxobutylation pathway which is common to both compounds. This DNA route generates 7-[4-(3-pyridyl)-4-oxobut-1-yl]-2′-deoxyguanosine, O²-[4-(3-pyridyl)-4-oxobut-1-yl]-2′-deoxycytosine, O²-[4-(3-pyridyl)-4-oxobut-1-yl]-2′-deoxythymidine, and O⁶-[4-(3-pyridyl)-4-oxobut-1-yl]-2′-deoxyguanosine as well as unstable adducts which dealkylate to release 4-hydroxy-1-{3-pyridyl)-1-butanone or depyriminidate/depurinate to generate abasic sites. There are multiple repair pathways responsible for protecting against the genotoxic effects of these adducts, including adduct reversal as well as base and nucleotide excision repair pathways. Data indicate that several DNA adducts contribute to the overall mutagenic properties of pyridyloxobutylating agents. Which adducts contribute to the carcinogenic properties of this pathway are likely to depend on the biochemistry of the target tissue.

The influence of repair pathways on the cytotoxicity and mutagenicity induced by the pyridyloxobutylation pathway of tobacco-specific nitrosamines

Tobacco-specific nitrosamines, 4-(methylnitrosamino)-1-(3-pyridyl)-1-butanone and N'-nitrosonornicotine, are considered to be human carcinogens. Both compounds are metabolized to pyridyloxobutylating intermediates that react with DNA to form adducts such as 7-[4-(3-pyridyl)-4-oxobut-1-yl]guanine, O(2)-[4-(3-pyridyl)-4-oxobut-1-yl]cytosine, O(2)-[4-(3-pyridyl)-4-oxobut-1-yl]-2'-deoxythymidine (O(2)-pobdT), O(6)-[4-(3-pyridyl)-4-oxobut-1-yl]-2'-deoxyguanosine (O(6)-pobdG), and 4-hydroxy-1-(3-pyridyl)-1-butanone-releasing adducts. The role of specific DNA adducts in the overall genotoxic activity of the pyridyloxobutylation pathway is not known. One adduct, O(6)-pobdG, is mutagenic. To characterize the mutagenic and cytotoxic properties of pyridyloxobutyl DNA adducts, the impact of DNA repair pathways on the cytotoxic and mutagenic properties of the model pyridyloxobutylating agent, 4-(acetoxymethylnitrosamino)-1-(3-pyridyl)-1-butanone (NNKOAc), was investigated in Chinese hamster ovary cell lines proficient or deficient in O(6)-alkylguanine DNA alkyltransferase (AGT), deficient in both AGT and base excision repair (BER), or deficient in both AGT and nucleotide excision repair (NER). The repair of the four pyridyloxobutyl DNA adducts was determined in the same cell lines via sensitive LC-MS/MS methods. NNKOAc was more cytotoxic in the cell lines lacking AGT, BER, and NER repair pathways. It also induced more mutations in the hprt gene in the BER- and NER-deficient cell lines. However, AGT expression did not influence NNKOAc's mutagenicity despite efficient repair of O(6)-pobdG. Analysis of the hprt mutational spectra indicated that NNKOAc primarily caused point mutations at AT base pairs. GC to AT transition mutations were a minor contributor to the overall mutation spectrum, providing a rationale for the observation that AGT does not protect against the overall mutagenic properties of NNKOAc in this model system. The only adduct affected by the absence of effective NER was O(2)-pobdT. Slower repair of O(2)-pobdT in NER-deficient cells was associated with increased AT to TA transversion mutations, supporting the hypothesis that these mutations are caused by O(2)-pobdT. Together, these data support a hypothesis that the pyridyloxobutylation pathway generates multiple mutagenic and toxic adducts.

Improved generation of rat gene knockouts by target-selected mutagenesis in mismatch repair-deficient animals

Background

The laboratory rat (Rattus norvegicus) is one of the preferred model organisms in physiological and pharmacological research, although the availability of specific genetic models, especially gene knockouts, is limited. N-ethyl-N-nitrosourea (ENU)-driven target-selected mutagenesis is currently the most successful method in rats, although it is still very laborious and expensive.

Results

As ENU-induced DNA damage is normally recognized by the mismatch repair (MMR) system, we hypothesized that the effectiveness of the target-selected mutagenesis approach could be improved by using a MMR-deficient genetic background. Indeed, Msh6 knockout rats were found to be more sensitive to ENU treatment and the germ line mutation rate was boosted more than two-fold to 1 mutation per 585 kb. In addition, the molecular mutation spectrum was found to be changed in favor of generating knockout-type alleles by ~20%, resulting in an overall increase in efficiency of ~2.5 fold. The improved effectiveness was demonstrated by high throughput mutation discovery in 70 Mb of sequence in a set of only 310 mutant F1 rats. This resulted in the identification of 89 mutations of which four introduced a premature stopcodon and 64 resulted in amino acid changes.

Conclusion

Taken together, we show that the use of a MMR-deficient background considerably improves ENU-driven target-selected mutagenesis in the rat, thereby reducing animal use as well as screening costs. The use of a mismatch repair-deficient genetic background for improving mutagenesis and target-selected knockout efficiency is in principle applicable to any organism of interest.

Differential effects of low- and high-dose X-rays on N-ethyl-N-nitrosourea-induced mutagenesis in thymocytes of B6C3F1 gpt-delta mice

Carcinogenesis in humans is thought to result from exposure to numerous environmental factors. Little is known, however, about how these different factors work in combination to cause cancer. Because thymic lymphoma is a good model of research for combined exposure, we examined the occurrence of mutations in thymic DNA following exposure of B6C3F1 gpt-delta mice to both ionizing radiation and N-ethyl-N-nitrosourea (ENU). Mice were exposed weekly to whole body X-irradiation (0.2 or 1.0 Gy), ENU (200 ppm) in the drinking water, or X-irradiation followed by ENU treatment. Thereafter, genomic DNA was prepared from the thymus and the number and types of mutations in the reporter transgene gpt was determined. ENU exposure alone increased mutant frequency by 10-fold compared to untreated controls and over 80% of mutants had expanded clonally. X-irradiation alone, at either low or high dose, unexpectedly, reduced mutant frequency. Combined exposure to 0.2 Gy X-rays with ENU dramatically decreased mutant frequency, specifically G:C to A:T and A:T to T:A mutations, compared to ENU treatment alone. In contrast, 1.0 Gy X-rays enhanced mutant frequency by about 30-fold and appeared to accelerate clonal expansion of mutated cells. In conclusion, repeated irradiation with 0.2 Gy X-rays not only reduced background mutation levels, but also suppressed ENU-induced mutations and clonal expansion. In contrast, 1.0 Gy irradiation in combination with ENU accelerated clonal expansion of mutated cells. These results indicate that the mode of the combined mutagenic effect is dose dependent.

Formation and accumulation of pyridyloxobutyl DNA adducts in F344 rats chronically treated with 4-(methylnitrosamino)-1-(3-pyridyl)-1-butanone and enantiomers of its metabolite, 4-(methylnitrosamino)-1-(3-pyridyl)-1-butanol

4-(Methylnitrosamino)-1-(3-pyridyl)-1-butanone (NNK, 1) and its metabolite, 4-(methylnitrosamino)-1-(3-pyridyl)-1-butanol (NNAL, 2) are both potent pulmonary carcinogens in rats. The metabolism of NNK to NNAL is stereoselective and reversible, with (S)-NNAL being the major enantiomer formed from NNK. In rats, (R)-NNAL undergoes facile glucuronidation and is rapidly excreted in urine, whereas (S)-NNAL is preferentially retained in tissues and converted to NNK. We hypothesized that the lung carcinogenicity of NNK in the rat is due in part to the preferential retention of (S)-NNAL in the lung, the reconversion to NNK, and then the metabolic activation of NNK to pyridyloxobutyl (POB)-DNA adducts. We tested this hypothesis by treating male F344 rats with 10 ppm of NNK, (R)-NNAL, or (S)-NNAL in drinking water. After 1, 2, 5, 10, 16, or 20 weeks of treatment, POB-DNA adducts in liver and lung DNA were quantified by HPLC-ESI-MS/MS. At each time point, total adduct levels were higher in the lung than in the liver. O2-[4-(3-pyridyl)-4-oxobut-1-yl]thymidine (O2-POB-dThd, 13) was the major adduct detected. Total adduct levels in the rats treated with (S)-NNAL were 0.6-1.3 times as great as those in the NNK group in the lung and 0.7-1.4 times in the liver, and 6-14 times higher than those in the (R)-NNAL group in the lung and 11-17 times in the liver. These results suggest that (S)-NNAL is stereoselectively retained in tissues. This study demonstrates for the first time the accumulation and persistence of specific POB-DNA adducts in the rat lung and liver during chronic treatment with NNK, (R)-NNAL, and (S)-NNAL and supports the hypothesis that the preferential retention of (S)-NNAL in the lung, followed by reconversion to NNK and then the metabolic activation of NNK is critical for lung carcinogenesis by NNK and NNAL.

Quantitation of pyridyloxobutyl DNA adducts of tobacco-specific nitrosamines in rat tissue DNA by high-performance liquid chromatography-electrospray ionization-tandem mass spectrometry

The tobacco-specific nitrosamines N'-nitrosonornicotine (NNN, 1) and 4-(methylnitrosamino)-1-(3-pyridyl)-1-butanone (NNK, 2) are potent carcinogens in rodents. Bioactivation of NNN and NNK by cytochrome P450 enzymes generates a pyridyloxobutylating agent 6, which alkylates DNA to produce pyridyloxobutyl (POB)-DNA adducts. POB-DNA adduct formation plays a critical role in NNN and NNK carcinogenicity in rodents. To further investigate the significance of this pathway, we developed a high-performance liquid chromatography-electrospray ionization-tandem mass spectrometry (HPLC-ESI-MS/MS) method for quantitative analysis of four POB-DNA adducts with known structures. The corresponding deuterated analogues were synthesized and used as internal standards. DNA samples, spiked with internal standards, were subjected to neutral thermal hydrolysis followed by enzymatic hydrolysis. The hydrolysates were partially purified by solid phase extraction prior to HPLC-ESI-MS/MS analysis. The method was accurate and precise. Excellent sensitivity was achieved, especially for O2-[4-(3-pyridyl)-4-oxobut-1-yl]thymidine (O2-POB-dThd, 11) with a detection limit of 100 amol per mg DNA. DNA samples treated with different concentrations of 4-(acetoxymethylnitrosamino)-1-(3-pyridyl)-1-butanone (NNKOAc, 3) were subjected to HPLC-ESI-MS/MS analysis. 7-[4-(3-Pyridyl)-4-oxobut-1-yl]guanine (7-POB-Gua, 12) was the most abundant adduct, followed by O6-[4-(3-pyridyl)-4-oxobut-1-yl]-2'-deoxyguanosine (O6-POB-dGuo, 8), O2-POB-dThd, and O2-[4-(3-pyridyl)-4-oxobut-1-yl]cytosine (O2-POB-Cyt, 13). Lung and liver DNA isolated from NNK-treated rats were analyzed. Consistent with the in vitro data, 7-POB-Gua was the major POB-DNA adduct formed in vivo. However, levels of O6-POB-dGuo were the lowest of the four adducts analyzed, suggesting efficient repair of this adduct in vivo. In contrast to the other three adducts, O6-POB-dGuo was more abundant in lung than in liver. O2-POB-dThd appeared to be poorly repaired in vivo, and its levels were comparable to those of 7-POB-Gua. The results of this study provide a sensitive HPLC-ESI-MS/MS method for comprehensive quantitation of four POB-DNA adducts, support an important role of O6-POB-dGuo in NNK lung tumorigenicity in rats, and suggest that O2-POB-dThd may be a useful tobacco-specific DNA biomarker for future tobacco carcinogenesis studies.

Mutations induced by 4-(methylnitrosamino)-1-(3-pyridyl)-1-butanone (NNK) in the lacZ and cII genes of Muta™ Mouse

4-(Methylnitrosamino)-1-(3-pyridyl)-1-butanone (NNK) found in chewing tobacco, snuff, cigarettes, and cigars is a tobacco-specific nitrosamine and classified as a possible human carcinogen (Class 2B) by the International Agency for Research on Cancer (IARC). NNK given intraperitoneally was seen to induce lung and liver adenomas. To evaluate the genotoxicity of NNK in vivo, NNK was intraperitoneally administered to Muta Mouse at two concentrations (125 and 250 mg/kg, once a week for 4 weeks) followed by the measurement of mutant frequencies in the lacZ and cII genes from lung and liver in the same mice. Characterization of the types of the mutation was determined by sequencing the cII genes from mutant plaques. The mutant frequencies in both target genes from both organs dose-dependently increased up to 10 times compared to those of the control group. For the types of mutations, the ratio of the G:C to A:T mutation in the total number of mutants was less than the ratio of A:T to T:A and A:T to C:G transversion, contrary to a previous report. The A:T to T:A transversion was the most highly induced mutation both in the lung and liver cII genes. The increasing rate of mutant frequencies in lung and liver over the vehicle control was 55 and 56 times, respectively, while the increasing rate of G:C to A:T transition was only 1.9 and 2.8 times, respectively. These observations show that NNK predominantly induces DNA adducts leading to A:T to T:A and/or A:T to C:G mutations in the transgene.

In vivo mutation in gene A of splenic lymphocytes from phiX174 transgenic mice

Single-burst analysis was applied to a forward assay for gene A mutation in splenic lymphocytes of phiX174 transgenic mice for the purpose of optimizing analytical parameters for identifying in vivo mutations. The effect of varying the cutoff value for an in vivo burst on induced mutant frequency, fold increase, and the significance of the difference between control and N-ethyl-N-nitrosourea (ENU)-treated mice was calculated by two different methods. The plating density was reduced to an average of less than 10 background mutant plaques per aliquot in order to separate in vitro bursts. The spectrum of mutations contributing < 60 plaques per aliquot from control animals was not significantly different from the control spectra from E. coli or transgenic phiX174 cells in culture. The mutant spectra from ENU-treated animals was highly different between mutant bursts of > 80 plaques per aliquot compared to mutations contributing < 60 plaques per aliquot (P < 0.000001), the former fitting the spectrum expected for ENU-induced mutations. The latter spectrum was also different from control animals and E. coli (P < 0.000001), suggesting the difference was caused by ex vivo mutation. With the mutations found in this study, the total number of reported target sites for gene A is now 33. The results support the interpretation that, in contrast to results for the lacI transgene, 100% of mutants isolated in gene A from control animals and cells were fixed in E. coli. We attribute the difference between the two genes to hot-spot sites for mutation in gene A and to a testable hypothesis that the mosaic plaque assay for the lacI transgene underestimates the frequency of ex vivo mutants.

Effect of nucleotide excision repair on ENU-induced mutation in female germ cells of Drosophila melanogaster

The role of nucleotide excision repair (NER) in the repair of alkylation damage in the germ cells of higher eukaryotes has been studied mainly by treating postmeiotic male germ cells. Little is known about repair in actively repairing female germ cells. In this study, we treated NER-deficient (ner(-)) mus201(D1) Drosophila females with N-ethyl-N-nitrosourea (ENU) and determined both the mutant frequencies in the multiple locus recessive lethal (RL) test and in the single locus vermilion gene and determined the ENU mutation spectrum in the vermilion gene. The results show that ENU is mutagenic in all cell stages and that the induced frequencies increase with cell maturation, from oogonia to mature oocytes. In addition, the induced spectrum consists mainly of A:T-->T:A transversions (43.8%), A:T-->G:C transitions (21.9%), and A:T-->C:G transversions (15.6%). G:C-->A:T (3.1%) transitions, other transversions (9.4%), frameshifts (3.1%), and deletions (3.1%) were also found. Comparison of these results with those previously obtained for repair-proficient (ner(+)) female germ cells reveal: 1) Differences in the RL and vermilion mutation frequencies for ner(+) and ner(-) germ cells, indicating that NER is involved in the repair of ENU-induced damage to these cells. 2) At least 15.6% of mutations in ner(-) cells may be the consequence of N-ethylation damage and mutations of this type were not detected in ner(+) cells. 3) Although differences were found in transition frequencies between ENU-treated ner(+) and ner(-) germ cells (52.2% vs. 25%), suggesting that a functional NER is involved in processing O-ethylated damage, the role of NER in repairing O-ethylated adducts is uncertain.

Neighboring base identity affects N-ethyl-N-nitrosourea-induced mutagenesis in Escherichia coli

This study investigated the influence of different neighboring base contexts on the production of base substitutions generated by N-ethyl-N-nitrosourea (ENU). A set of bacterial strains having all possible bases neighboring an ochre (TAA) nonsense mutation in the tyrA gene of Escherichia coli were employed and true reversions of the nonsense mutation were induced by two separate doses of ENU. Base substitution mutations were investigated by direct sequencing methods. These studies revealed that 1) mutations occurring at 5'-purine-T sites were produced better, on average, than mutations involving 5'-pyrimidine-T sites, and 5'-TT sites contributed the least to the formation of mutations, 2) the order of preference for A:T to G:C transitions was 5'-GT>5'-AT, 5'-CT>5'-TT, and 3) A:T to C:G transversions at the first position of the codon (GAA mutations) were produced best at 5'-AT sites, while A:T to T:A transversions at the third position (TAT mutations) occurred more often at 5'-GT sites. These findings suggest that the occurrence of a specific mutation may reflect the sequence-dependent probability of DNA damage at a particular site as well as factors involving preferential DNA repair or differential base selection by DNA polymerase.

O-ethylthymidine adducts are the most relevant damages for mutation induced by N-ethyl-N-nitrosourea in female germ cells of Drosophila melanogaster

Responses to genotoxic agents vary not only among organisms, test systems, and cellular stages, but also between sexes; little, however, is known about the mutagenic consequences of chemical exposures to female germ cells. In this study, the mutagenicity of N-ethyl-N-nitrosourea (ENU) was analyzed in female germ cells of Drosophila melanogaster using the recessive-lethal test and the vermilion system, which simultaneously generates information on induced mutation frequency and mutation spectrum. ENU was mutagenic in all stages of oogenesis, although there were differences among the stages. In mature and immature oocytes, ENU-induced mutations in the vermilion locus were 43.5% A:T-->G:C transitions, 39.1% A:T-->T:A transversions, 8.7% G:C-->A:T transitions, and 8.7% A:T-->C:G transversions, indicating that the most important premutagenic lesions induced by this chemical are O(4)-ethylthymine and O(2)-ethylthymine. The low frequency of mutation involving O(6)-ethylguanine (i.e., G:C-->A:T transitions) could be a consequence of the repair of these lesions by O(6)-methylguanine DNA methyltransferase. Comparison of these results with those previously obtained in male germ cells stresses the importance of the repair activity of the analyzed cells, because the mutation spectrum in female germ cells was similar to the spectrum obtained with repair-proficient spermatogonial cells and different from repair-deficient postmeiotic cells. The results also indicate that studies with female germ cells could be an alternative to the use of premeiotic male germ cells, especially when the analysis of these cells is difficult or almost impossible and when studies of in vivo DNA repair in premeiotic germ cells are performed.

Characterization of mutant spectra generated by a forward mutational assay for gene A of Phi X174 from ENU-treated transgenic mouse embryonic cell line PX-2

The sensitivity of in vivo transgenic mutation assays benefits from the sequencing of mutations, although the large number of possible mutations hinders high throughput sequencing. A forward mutational assay exists for Phi X174 that requires an altered, functional Phi X174 protein and therefore should have fewer targets (sense, base-pair substitutions) than forward assays that inactivate a protein. We investigated this assay to determine the number of targets and their suitability for detecting a known mutagen, N-ethyl-N-nitrosourea (ENU). We identified 25 target sites and 33 different mutations in Phi X174 gene A after sequencing over 350 spontaneous and ENU-induced mutants, mostly from mouse embryonic cell line PX-2 isolated from mice transgenic for Phi X174 am3, cs70 (line 54). All six types of base-pair substitution were represented among both the spontaneous and ENU-treated mutant spectra. The mutant spectra from cells treated with 200 and 400 microg/ml ENU were both highly different from the spontaneous spectrum (P < 0.000001) but not from each other. The dose trend was significant (P < 0.0001) for a linear regression of mutant frequencies (R(2) = 0.79), with a ninefold increase in mutant frequency at the 400 microg/ml dose. The spontaneous mutant frequency was 1.9 x 10(-5) and the spontaneous spectrum occurred at 11 target base pairs with 15 different mutations. Thirteen mutations at 12 targets were identified only from ENU-treated cells. Seven mutations had highly significant increases with ENU treatment (P < 0.0001) and 15 showed significant increases. The results suggest that the Phi X174 forward assay might be developed into a sensitive, inexpensive in vivo mutagenicity assay.

Overexpression of Ogt reduces MNU and ENU induced transition, but not transversion, mutations in E. coli

Studies of alkylation-induced mutations in Escherichia coli FX-11 revealed that both N-ethyl-N-nitrosourea (ENU) and N-methyl-N-nitrosourea (MNU) produced tRNA suppressor mutations (G:C to A:T) but only ENU produced a significant number of backmutations (A:T to G:C, A:T to T:A and A:T to C:G). Further, the ENU-induced transversions were absent in a UmuC-defective strain. This suggested that transition mutations could result from alkylation of guanine or thymine at the O(6)- and O(4)-positions, respectively, but that transversions might result from alkylation of thymine at the O(2)-position. To test this idea, the gene encoding O(6)-alkylguanine-DNA methyltransferase (ogt) was recombined into a plasmid to overexpress the cellular levels of this enzyme. Ogt protein can de-alkylate O(6)-alkylguanine and O(4)-alkylthymine, but not O(2)-alkylthymine. Cells harboring the plasmid (or a control plasmid lacking the ogt gene) were exposed to different concentrations of MNU or ENU and the resulting mutations were analyzed. With either MNU or ENU, the frequency of GlnV(o) suppressors was reduced about 70-fold in the Ogt-overexpressing cells, suggesting that Ogt eliminated O(6)-alkylguanine. Similarly, GlnU(o) suppressor frequencies were substantially reduced. In contrast, the reduction in frequency for the backmutations was slight, only about 2.5-fold with MNU and less than two-fold for ENU. However, DNA sequence analysis of the backmutations showed that only A:T to G:C transitions were affected by overexpression of Ogt, suggesting repair of O(4)-alkylthymine. The frequency of transversions, in comparison, was essentially unaltered. These results implicate O(2)-alkylthymine as a likely candidate for transversion mutagenesis induced by ENU.

The importance of distinct metabolites of N-nitrosodiethylamine for its in vivo mutagenic specificity

Although N-nitrosodiethylamine (NDEA) is a potent carcinogen in rodents and a probable human carcinogen, little attempts were made to characterize its mutation spectrum in higher eukaryotes. We have compared forward mutation frequencies at multiple (700) loci with the mutational spectrum induced at the vermilion gene of Drosophila, after exposure of post- and pre-meiotic male germ cells to NDEA. Among 30 vermilion mutants collected from post-meiotic stages were 12 G:C-->A:T transitions (40%), 8 A:T-->T:A transversions (27%), and 4 structural rearrangements (13%). The remainder were three A:T-->G:C transitions, two G:C-->C:G transversions and one G:C-->T:A transversion. The results show that although NDEA induces predominantly transitions (40% G:C-->A:T and 10% A:T-->G:C), the frequencies of transversions (37%, of which 27% of A:T-->T:A transversions) and especially of rearrangements (13%) are remarkably high. This mutation spectrum differs significantly from that produced by the direct-ethylating agent N-ethylnitrosourea (ENU), although the relative distribution of ethylated DNA adducts is similar for both carcinogens. These differences, in particular the occurrence of rearrangements, are most likely the result of the requirement of NDEA for bioactivation. Since all four rearrangements were collected from non-metabolizing spermatozoa (or late spermatids), it is hypothesized that they derived from acetaldehyde, a stable metabolite of NDEA. Due to its cytotoxicity, attempts to isolate vermilion mutants from NDEA-exposed pre-meiotic cells were largely unsuccessful, because only two mutants (one A:T-->G:C transition and one 1bp insertion) were collected from those stages. Our results show that NDEA is capable of generating carcinogenic lesions other than base pair substitutions.

Reduction of ENU-induced transversion mutations by the isoflavone genistein in Escherichia coli

In studies of mutagenesis induced by the carcinogen N-ethyl-N-nitrosourea (ENU) in the bacterium Escherichia coli FX-11, it was observed that G:C to A:T transitions did not require the inducible umuDC gene products, while a portion of the A:T to G:C transitions and all transversion mutations were dependent on a functional umuC gene. This observation suggested that the different base substitutions may result from differential processing of specific DNA adducts produced by ENU. To further understand these processes, we have investigated the effect of the soybean isoflavone genistein on the production of ENU-induced mutations. This compound, in particular, has been shown to exhibit numerous effects including the inhibition of the growth or proliferation of a variety of cancers, inhibition of angiogenesis, inhibition of tyrosine protein kinases and anti-oxidant properties. In our experiments, tyrosine defective (TyrA(-)) E. coli were exposed to ENU and a portion of the ENU-treated cells were exposed to genistein. The results showed a three-fold reduction in the overall mutation frequency when cells were treated with genistein subsequent to ENU-exposure and this anti-mutagenic effect was dependent on the dose of genistein employed. However, only certain types of base substitution mutagenesis were affected. In particular, transversion mutations were reduced an average of about 8.5-fold, while transitions were not greatly affected. In addition, UV-mutagenesis was reduced about three-fold and induction of the SOS response (as monitored with a sulA-lacZ fusion) was decreased. These results suggest that genistein may interfere with expression of the SOS response, including the UmuC-mediated lesion bypass mechanism that is necessary for UV-mutagenesis and the generation of transversions by ENU in E. coli.

Factors that influence the mutagenic patterns of DNA adducts from chemical carcinogens

Carcinogens are generally mutagens, which is understandable given that tumor cells grow uncontrollably because they have mutations in critical genes involved in growth control. Carcinogens often induce a complex pattern of mutations (e.g., GC-->TA, GC-->AT, etc.). These mutations are thought to be initiated when a DNA polymerase encounters a carcinogen-DNA adduct during replication. In principle, mutational complexity could be due to either a collection of different adducts each inducing a single kind of mutation (Hypothesis 1a), or a single adduct inducing different kinds of mutations (Hypothesis 1b). Examples of each are discussed. Regarding Hypothesis 1b, structural factors (e.g., DNA sequence context) and biological factors (e.g., differing DNA polymerases) that can affect the pattern of adduct mutagenesis are discussed. This raises the question: how do structural and biological factors influence the pattern of adduct mutagenesis. For structural factors, three possibilities are considered: (Hypothesis 2a) a single conformation of an adduct giving rise to multiple mutations -- dNTP insertion by DNA polymerase being influenced by (e.g.) the surrounding DNA sequence context; (Hypothesis 2b) a variation on this ("dislocation mutagenesis"); or (Hypothesis 2c) a single adduct adopting multiple conformations, each capable of giving a different pattern of mutations. Hypotheses 2a, 2b and 2c can each in principle rationalize many mutational results, including how the pattern of adduct mutagenesis might be influenced by factors, such as DNA sequence context. Five lines of evidence are discussed suggesting that Hypothesis 2c can be correct for base substitution mutagenesis. For example, previous work from our laboratory was interpreted to indicate that [+ta]-B[a]P-N(2)-dG in a 5'-CGG sequence context (G115) could be trapped in a conformation giving predominantly G-->T mutations, but heating caused the adduct to equilibrate to its thermodynamic mixture of conformations, leading to a decrease in the fraction of G-->T mutations. New work is described suggesting that [+ta]-B[a]P-N(2)-dG at G115 can also be trapped predominantly in the G-->A mutational conformation, from which equilibration can also occur, leading to an increase in the fraction of G-->T mutations. Evidence is also presented that the fraction of G-->T mutations is higher when [+ta]-B[a]P-N(2)-dG at G115 is in ss-DNA ( approximately 89%) vs. ds-DNA ( approximately 66%), a finding that can be rationalized if the mixture of adduct conformations is different in ss- and ds-DNA. In summary, the factors affecting adduct mutagenesis are reviewed and five lines of evidence that support one hypothesis (2c: adduct conformational complexity can cause adduct mutational complexity) are discussed.

The mutagenic spectrum of acridine-linked aniline nitrogen mustards in AS52 cells: implications of DNA targeting with high selectivity for adenine or guanine bases

The mutational spectra generated in AS52 cells at the gpt gene locus by aniline mustards were studied by the isolation of resistant clones and sequencing of the altered gene. A set of four aniline mustards (both mono- and bifunctional) linked to a DNA-affinic 9-aminoacridine (9-AA) carrier was used, together with the untargeted mustards chlorambucil (CHL) and its half-mustard, and the DNA binding carrier, 9-AA. Both 9-AA and CHL were weak cytotoxins, with the DNA-targeted mustards being markedly (10-40-fold) more dose potent, and the bifunctional ones somewhat more toxic than the monofunctional ones. 9-AA produced a different spectrum of mutations to the spontaneous background, with more minor addition events and less base pair substitutions, and showing for the first time that frameshift events so characteristic of 9-AA in bacteria or bacteriophage also occur in mammalian cells. The mutational spectra of the DNA-targeted mustards were quite different both from this and from the lesions caused by the untargeted mustards, which cause largely transition mutations at AT sites (despite a clear preference for formation of N(7)-guanine adducts). There were very few transition mutations, suggesting that the initial O(6)-alkylguanine/O(4)-alkylthymine lesions considered to give rise to these are relatively rare. There was also a lower incidence of complete deletions, usually attributed to DNA cross-links. For the short chain length targeted mustards, which form initial stable adducts largely (95%) at guanine N(7) sites, base pair substitution mutations, predominantly transversions, involved AT and GC base pairs equally. In contrast, the longer chain length targeted mustards, which form >90% of initial adducts at adenine N(1) sites, generated also formed transversion mutations, but these overwhelmingly (24/27) involved AT base pairs.

Role of DNA repair in carcinogen-induced ras mutation

In this contribution we discuss the gene- and cell type-specific repair of miscoding DNA alkylation products as a risk parameter in both mutation induction and malignant transformation by N-nitroso carcinogens. Upon exposure to N-nitroso compounds such as N-methyl-N-nitrosourea (MeNU) or N-ethyl-N-nitrosourea (EtNU), about a dozen different alkylation products are formed in cellular DNA. Among these are O(6)-methylguanine (O(6)-MeGua) and O(6)-ethylguanine (O(6)-EtGua), respectively, which differ only by one CH(2) group in their alkyl residue and, when unrepaired, cause G:C-->A:T transition mutations by anomalous base pairing during DNA replication. We have analyzed the global and gene-specific repair of O(6)-MeGua and O(6)-EtGua in target cell DNA, ras gene mutation frequencies, and tumor incidence, in the model of mammary carcinogenesis induced in 50-day-old female Sprague-Dawley rats by a single application of MeNU or EtNU. Both carcinogens induce histologically indistinguishable mammary adenocarcinomas at high yield. In the target mammary epithelia, O(6)-MeGua is repaired at similar slow rates in both transcriptionally active genes (Ha-ras, beta-actin), silent genes (lgE heavy chain), and in bulk DNA, by the one-step repair protein O(6)-alkylguanine-DNA alkyltransferase (MGMT; low level of expression in the target cells). The slow repair of O(6)-MeGua translates into a high frequency of mutations at the central position of Ha-ras codon 12 (GGA) in MeNU-induced tumors. O(6)-EtGua, however, is removed approximately 20 times faster than O(6)-MeGua selectively from transcribed genes via an MGMT independent, as yet uncharacterized excision mechanism. Accordingly, no Ha-ras codon 12 mutations are found in the EtNU-induced mammary tumors. Neither MeNU- nor EtNU-induced tumors exhibit mutations at codons 13 and 61 of Ha-ras or at codons 12, 13 and 61 of Ki-ras. While a moderate surplus MGMT activity of the target cells - contributed by a bacterial MGMT transgene (ada) - significantly counteracts mammary tumorigenesis in MeNU-exposed rats, this is not the case in the EtNU-treated animals. Differential repair of structurally distinct DNA lesions in transcribed or (temporarily) silent genes thus determines the probability of mutation and, together with cell type-specific and interindividual differences in DNA repair capacity, influences carcinogenic risk.

The polymerase inhibition assay: A methodology for the identification of DNA-damaging agents

We report here the development of the polymerase inhibition assay (PI assay), a methodology capable of simultaneously identifying multiple DNA-damaging agents. The PI assay was developed in order to fulfil a requirement for the screening of new pharmaceuticals for potential DNA-damaging effects. The assay has the potential to screen hundreds of new compounds per week because of the microtiter plate format employed. We review previous descriptions of the phenomenon and provide researchers with the necessary methodology to obtain optimum polymerase inhibition effects. The assay is based on the inhibition of DNA polymerases (including those used in the polymerase chain reaction (PCR)) encountering damaged DNA bases. Hence, DNA-damaging agents can be identified by a corresponding reduction in PCR amplification after exposure. We demonstrate the detection of polymerase inhibition induced by a range of model genotoxic agents (N-methyl-N-nitrosourea, N-ethyl-N-nitrosourea, and ultraviolet (UV) C radiation), illustrating the successful application of the methodology. In addition, the PI assay is shown to be capable of detecting DNA damaging agents of biological relevance, i.e., known human carcinogens. These were N-OH-PhIP (from cooked meat) and UV-B (from sunlight). In addition to its employment in the detection of putative DNA damaging agents, the PI assay may also be applied as a research tool in carcinogenicity studies.

Influence of nucleotide excision repair and of dose on the types of vermilion mutations induced by diethyl sulfate in postmeiotic male germ cells of Drosophila

The role of a defect for nucleotide excision repair (NER) in oocytes on the repair of DNA ethyl adducts induced by diethyl sulfate (DES) in male germ cells of Drosophila was analysed. Frequencies of mutations at multiple loci (recessive lethal mutations) and at the vermilion gene induced in NER+ conditions (cross NER+ x NER+) were compared with those fixed in a NER- background (NER- x NER+). The M(NER-)/M(NER+) mutability ratios for two DES concentrations, 10 mM and 15 mM, were 2.21 and 1.49, respectively, indicating that NER repairs part of the DES-induced damage. The majority of 28 fertile vermilion mutations produced by DES in NER- are transitions, both GC-AT (46.4%) and AT-GC (21.4%) transitions are found, the consequences of O6-ethylguanine and O4-ethylthymine, respectively. Transversions (21.5%), one +1 frameshift mutation (3.6%) and two deletions (7.1%) are most likely the result of N-alkylation damage. Furthermore, the DES-induced mutation spectra show interesting differences in relation to the exposure dose. All 10 mutants isolated in this and a previous [L.M. Sierra, A. Pastink, M.J.M. Nivard, E.W. Vogel, DNA base sequence changes induced by DES in postmeiotic male germ cells of Drosophila melanogaster, Mol. Gen. Genet. 237 (1993) 370-374] study from experiments with low DES-effectiveness are exclusively transitions, independent whether the females were of the NER+ or NER-genotype. This indicates that at lower DES effectiveness only O-alkylation damage is relevant, and that N-alkylation damage is repaired. In experiments revealing high DES-effectiveness, vermilion mutations representing N-alkylation damage reached 43% (9/21) with NER- and 26% (7/27) with NER+ females, suggesting (i) that NER becomes involved at high adduct levels because then the base excision repair (BER) may be saturated, and (ii) that this involvement of NER causes the relative decrease from 43% to 26% N-alkylation mediated sequence changes.

A functional and quantitative mutational analysis of p53 mutations in yeast indicates strand biases and different roles of mutations in DMBA- and BBN-induced tumors in rats

In order to analyze the mutational events and to understand the biological significance of the p53 gene in chemical carcinogenesis, we applied a new yeast-based p53 functional assay to ovarian tumors induced by 7, 12-dimethylbenz[a]anthracene (DMBA), as well as to transitional cell carcinomas of the urinary bladder induced by N-butyl-N-(4-hydroxybutyl) nitrosamine (BBN) in rats. The assay demonstrated that 15 of 19 DMBA induced tumors harbored clonal p53 mutations, which is consistent with the expectations of the "clonal expansion" hypothesis. The majority of the mutations were purine (AG) to pyrimidine (CT) transversions (12/19) on the non-transcribed (sense) strand (NTS), which is likely to be due to depurination created by DMBA adduct formation on the NTS. In contrast, we found no pyrimidine to purine [corrected] transversion on the NTS. After cessation of BBN treatment, BBN-induced multifocal lesions in the bladder contained heterogeneous p53 mutations at an early stage. In the later stage, however, clonal p53 mutations were identified in 4 out of 7 bladders analyzed, conforming with the concept of "field cancerization". The observed base substitutions were G-->A (1/6) or C -->T transitions (2/6), and mutations at T (3/6) on the NTS in clonal mutations, together with non-clonal mutations, showing a preference of C-->T to G-->A (17 vs. 0). Thus, preferential repair was found in the transcribed strand of the p53 gene, whether modified by DMBA or by BBN carcinogens. Very similar mutation patterns were observed between clonal and non-clonal mutations in the DMBA- and BBN-induced tumors, indicating that the rat yeast p53 functional assay can be a potential tool for the characterization of in vivo mutation patterns of p53, when modified by chemical carcinogens.

DNA polymerase mutagenic bypass and proofreading of endogenous DNA lesions

DNA polymerases differentiate between correct and incorrect substrates during synthesis on undamaged DNA templates through the biochemical steps of base incorporation, primer-template extension and proofreading excision. Recent research examining DNA polymerase processing of abasic, alkylation and oxidative lesions is reviewed in light of these discrimination mechanisms. Inhibition of DNA synthesis results from correct polymerase discrimination against utilization of geometrically incorrect template bases or 3' terminal basepairs. The efficiency of translesion synthesis is thus related to the physical structure of the lesion containing DNA. However, variations in enzyme structure and kinetics result in translesion synthesis efficiencies that are also dependent upon the DNA polymerase. With a low probability, polymerase misinsertion events create a 3' lesion terminus which is geometrically favored over the correct lesion basepair, resulting in mutagenic translesion synthesis. For example, both polymerase alpha and polymerase beta appear to require the formation of a stable 3' primer-template structure for efficient abasic site translesion synthesis. However, the enzymes differ as to the precise molecular make-up of the stable DNA structure, resulting in different mutational specificities. Similar mechanisms may be applicable to oxidative damage, where mutational specificities dependent upon the DNA polymerase also have been observed. In vitro reaction conditions also influence DNA polymerase processing of lesions. Using an in vitro herpes simplex virus thymidine kinase (HSV-tk) gene forward mutation assay, we demonstrate that high dNTP substrate concentrations affect the mutagenic specificity of translesion synthesis using alkylated templates. The exonuclease-deficient Klenow polymerase error frequency for G-->A transition mutations using templates modified by N-ethyl-N-nitrosourea (ENU) was four-fold higher at 1000 microM [dNTP], relative to 50 microM [dNTP], consistent with an increased efficiency of extension of the etO6G.T mispair. Moreover, the frequency of other ENU-induced polymerase errors was suppressed when polymerase reactions contained 50 microM dNTP, relative to 1000 microM dNTP. The efficiency of proofreading as a polymerase error discrimination mechanism reflects a balance between the competing processes of 3'-->5' exonuclease removal of mispairs and polymerization of the next correct nucleotide. Polymerases that are devoid of a proofreading exonuclease generally display enhanced abasic site translesion synthesis relative to proofreading-proficient enzymes. In addition, the proofreading exonucleases of Escherichia coli Pol I and T4 DNA polymerases have been found to remove mispairs caused by abasic sites and oxidative lesions, respectively, resulting in lowered polymerase error rates. However, the magnitude of the exonuclease effect is small (less than 10-fold), and highly dependent upon the DNA polymerase-exonuclease. We have studied proofreading exonuclease removal of alkylation damage in the HSV-tk forward assay. We observed no significant reduction in the magnitude of the mutant frequency vs. dose-response curves when N-methyl-N-nitrosourea or ENU-treated templates were used in exonuclease-proficient Klenow polymerase reactions, as compared to the exonuclease-deficient polymerase reactions. Thus, available data suggest that proofreading excision of endogenous lesion mispairs does occur, but the efficiency is dependent upon the lesion and the DNA polymerase-exonuclease studied.

Spectra of gpt mutations in ethylnitrosourea-treated and untreated transgenic mice

We have established a new transgenic mouse mutagenicity assay for the efficient detection of point mutations and deletions in vivo (Nohmi et al. [1996] Env. Mol. Mutagen. 28:465-470). In this assay, the gpt gene of Escherichia coli is used as a reporter for the detection of point mutations. Treatment of mice with ethylnitrosourea (ENU, 150 mg/kg) enhances by several-fold the mutant frequency of gpt in bone marrow. Here, we report the mutation spectra of the gpt gene recovered from bone marrow of ENU-treated and untreated transgenic mice. In the gpt mutants rescued from ENU-treated mice, more than 90% of the mutations were base change mutations; the predominant types were A:T to T:A transversions and G:C to A:T transitions. On the contrary, in the mutants rescued from untreated mice, 54% were base substitutions and the remainders were short deletions and insertions. Among untreated mice, the most frequently observed base substitution was G:C to A:T transitions (7/14 mutants). Three of these occurred at 5'-CpG-3' sites. Interestingly, the mutation spectra of the gpt gene were different from those of the gpt gene in ENU-treated and untreated E.coli, whereas they were similar to those of the lacZ and lacI genes in ENU-treated and untreated other transgenic mice or cultured mammalian cells. We also report the establishment of homozygous transgenic mice that have transgene lambdaEG10 DNA in both chromosome 17 of C57BL/6J mouse.

Alkylation-induced frameshift mutagenesis during in vitro DNA synthesis by DNA polymerases alpha and beta

We have analyzed the mutational spectra produced during in vitro DNA synthesis by DNA polymerase alpha-primase and DNA polymerase beta. The polymerase mutation frequency as measured in the in vitro herpes simplex virus thymidine kinase (HSV-tk) forward assay was increased when reactions utilized single-stranded DNA templates randomly modified by 20 mM N-ethyl-N-nitrosourea (ENU), relative to solvent-treated templates. A 20- to 50-fold increase in the frequency of G-->A transition mutations was observed for both polymerases, as expected due to mispairing by O6-ethylguanine lesions. Strikingly, ENU treatment of the template also resulted in a five- to 12-fold increased frequency of frameshift errors at heteropolymeric (non-repetitive) template sequences produced by polymerase beta and polymerase alpha-primase, respectively. The increased proportion of frameshift mutations at heteropolymeric sequences relative to homopolymeric (repetitive) sequences produced by each polymerase in response to ENU damage was statistically significant. For polymerase alpha-primase, one-base deletion errors at template guanine residues was the second most frequent mutational event, observed at a frequency only four-fold lower than the G-->A transition frequency. In the polymerase beta reactions, the frequency of insertion errors at homopolymeric (repetitive) sequences was increased six-fold using alkylated templates, relative to solvent controls. The frequency of such insertion errors was only three-fold lower than the frequency of G-->A transition errors by polymerase beta. Although ENU is generally regarded as a potent base substitution mutagen, these data show that monofunctional alkylating agents are capable of inducing frameshift mutations in vitro. Alkylation-induced frameshift mutations occur in both repetitive and non-repetitive DNA sequences; however, the mutational specificity is dependent upon the DNA polymerase.

Development and utilization of the rat lymphocyte hprt mutation assay

Much of the recent progress in the field of genetic toxicology has come from an increased understanding of the molecular and cellular biology of the mammalian organism. Most prominent has been the ability to detect and quantify somatic mutation and relate the nature of the mutation to the specific type of chemical damage. Building upon the foundation of the human lymphocyte hypoxanthine guanine phosphoribosyl transferase (hprt) system, and later, the mouse hprt system, methods for the detection and quantification of hprt mutations in rat lymphocytes were developed. These methods are described in this report as is the ongoing validation of the assay. Additionally, the characterization of the recovered mutants and a comparison of the mutation spectrum in the rat lymphocyte system to the spectrum in cancer genes, such as H-ras and p53, and the spectrum in transgenic systems, such as lacI, are included. The development of the rat lymphocyte hprt system and validation of the assay at the molecular level, provide an effective and reliable measure of genetic damage in an in vivo system which is readily comparable to measurement of genetic damage in the human.

Germ-cell mutagenesis in lambda lacZ transgenic mice treated with ethylating and methylating agents: comparison with specific-locus test

Germ-cell mutagenesis has been studied in male lambda lacZ transgenic mice in such a way that the data can be compared with literature data for germ-cell mutagenesis obtained with the specific-locus test (SLT). Mutagenesis induced by ethylnitrosourea (ENU), ethylmethanesulphonate (EMS), methylnitrosourea (MNU) and methylmethanesulphonate (MMS), has been studied in mature spermatozoa isolated from the epididymis and vas deferens. In order to investigate mutagenesis in different phases of spermatogenesis, animals were sacrificed at various time points after treatment. ENU at 150 mg/kg body weight significantly induced mutations in stem cells (analysis at 100 days post-treatment), but not in post-stem cells (7 days post-treatment). EMS (250 mg/kg) and MMS (60 mg/kg) induced mutations only in post-stem cells (7 days), but not in stem cells (100 days). MNU (70 mg/kg) resulted in an increase of mutations in both post-stem cells (14 and 37 days) and stem cells (100 days), although the latter, due to a limited number of data, was not statistically significant. All these data are in accordance with published SLT data. These results indicate that lambda lacZ transgenic mice are a suitable model to study gene mutations in different phases of spermatogenesis.

Functional nucleotide excision repair is required for the preferential removal of N-ethylpurines from the transcribed strand of the dihydrofolate reductase gene of Chinese hamster ovary cells

Transcription-coupled repair of DNA adducts is an essential factor that must be considered when one is elucidating biological endpoints resulting from exposure to genotoxic agents. Alkylating agents comprise one group of chemical compounds which modify DNA by reacting with oxygen and nitrogen atoms in the bases of the double helix. To discern the role of transcription-coupled DNA repair of N-ethylpurines present in discrete genetic domains, Chinese hamster ovary cells were exposed to N-ethyl-N-nitrosourea, and the clearance of the damage from the dihydrofolate reductase gene was investigated. The results indicate that N-ethylpurines were removed from the dihydrofolate reductase gene of nucleotide excision repair-proficient Chinese hamster ovary cells; furthermore, when repair rates in the individual strands were determined, a statistically significant bias in the removal of ethyl-induced, alkali-labile sites was observed, with clearance occurring 30% faster from the transcribed strand than from its nontranscribed counterpart at early times after exposure. In contrast, removal of N-ethylpurines was observed in the dihydrofolate reductase locus in cells that lacked nucleotide excision repair, but both strands were repaired at the same rate, indicating that transcription-coupled clearance of these lesions requires the presence of active nucleotide excision repair.

Spectrum of Bmp5 mutations from germline mutagenesis experiments in mice

Over 40 years of mutagenesis experiments using the mouse specific-locus test have produced a large number of induced germline mutations at seven loci, among them the short ear locus. We have previously shown that the short ear locus encodes bone morphogenetic protein 5 (BMP5), a member of a large family of secreted signaling molecules that play key roles in axis formation, tissue differentiation, mesenchymalepithelial interactions, and skeletal development. Here we examine 24 chemical- and radiation-induced mutations at the short ear locus. Sequence changes in the Bmp5 open reading frame confirm the importance of cysteine residues in the function of TGF beta superfamily members. The spectrum of N-ethyl-N-nitrosourea-induced mutations also provides new information about the basepair, sequence context, and strand specificity of germline mutations in mammals.

The influence of DNA repair by Ogt alkyltransferase on the distribution of alkylnitrosourea-induced mutations in Escherichia coli

To determine the influence of DNA repair by Ogt alkyltransferase on the distribution of alkylnitrosourea-induced mutations, we have analysed in Ogt-proficient and Ogt-deficient bacterial strains the DNA sequence changes of a total of 357 independent mutations occurring within the initial part of the lacl gene of Escherichia coli. The majority (>80%) of mutations induced by either N-ethyl-N nitrosourea (ENU) or N-methyl-N-nitrosourea (MNU) in the two genetic backgrounds were G:C --> A:T transitions, consistent with the predominant role of the O6-alkylguanine miscoding lesion in mutagenesis by alkylating agents. The analysis of the distribution of G:C --> A:T transitions induced by ENU in Ogt+ and Ogt bacteria reveals an influence of the 5'-flanking base at the level of repair by Ogt alkyltransferase. The Ogt protein appears more efficient at repairing O6-ethylguanine lesions, which are flanked 5' by a G or C, in agreement with previously reported data from our group for ethylmethane sulfonate. In contrast, no preference could be inferred for the repair of O6-methylguanine lesions by Ogt protein. These results seem to indicate that the preference of the Ogt alkyltransferase to repair certain DNA sequences might be a function of the size of the alkyl group. The importance of the alkyl group length has been described also at the level of the (A)BC excinuclease machinery that seems to have a DNA sequence specificity opposite to that of Ogt alkyltransferose.

DNA damage and repair in mutagenesis and carcinogenesis: implications of structure-activity relationships for cross-species extrapolation

Previous studies on structure-activity relationships (SARs) between types of DNA modifications and tumour incidence revealed linear positive relationships between the log TD50 estimates and s-values for a series of mostly monofunctional alkylating agents. The overall objective of this STEP project was to further elucidate the mechanistic principles underlying these correlations, because detailed knowledge on mechanisms underlying the formation of genotoxic damage is an absolute necessity for establishing guidance values for exposures to genotoxic agents. The analysis included: (1) the re-calculation and further extension of TD50 values in mmol/kg body weight for chemicals carcinogenic in rodents. This part further included the checking up data for Swain-Scott s-values and the use of the covalent binding index (CBI); (2) the elaboration of genetic toxicity including an analysis of induced mutation spectra in specific genes at the DNA level, i.e., the vermilion gene of Drosophila, a plasmid system (pX2 assay) and the HPRT gene in cultured mammalian cells (CHO-9); and (3) the measurement of specific DNA alkylation adducts in animal models (mouse, rat, hamster) and mammalian cells in culture. The analysis of mechanisms controlling the expression of mammalian DNA repair genes (alkyltransferases, glycosylases) as a function of the cell type, differentiation stage, and cellular microenvironment in mammalian cells. The 3 classes of genotoxic carcinogens selected for the project were: (1) chemicals forming monoalkyl adducts upon interaction with DNA; (2) genotoxins capable of forming DNA etheno-adducts; and (3) N-substituted aryl compounds forming covalent adducts at the C8 position of guanine in DNA. In general, clear SARs and AARs (activity-activity relationships) between physiochemical parameters (s-values, O6/N7-alkylguanine ratios, CBI), carcinogenic potency in rodents and several descriptors of genotoxic activity in germ cells (mouse, Drosophila) became apparent when the following descriptors were used: TD50 estimates (lifetime doses expressed in mg/kg b.wt. or mmol/kg b.wt.) from cancer bioassays in rodents; the degree of germ-cell specificity, i.e., the ability of a genotoxic agent to induce mutations in practically all cell stages of the male germ-cell cycle of Drosophila (this project) and the mouse (literature search), as opposed to a more specific response in postmeiotic stages of both species; the Mexr-/Mexr+ hypermutability ratio, determined in a repair assay utilizing Drosophila germ cells; mutation spectra induced at single loci (the 7 loci used in the specific-locus test of the mouse (published data), and the vermilion gene of Drosophila); and doubling doses (DD) in mg/kg (mmol/kg) for specific locus test results on mice. By and large, the TD50 values, the inverse of which can be considered as measures of carcinogenic potency, were shown to be predictable from knowledge of the in vivo doses associated with the absorbed amounts of the investigated alkylators and with the second-order constant, kc, reaction at a critical nucleophilic strength, nc. For alkylating agents kc can be expressed as the second-order rate constant for hydrolysis, kH2O, and the substrate constant s:kH2OTD50 is a function of a certain accumulated degree of alkylation, here given as the (average) daily increment, ac, for 2 years exposure of the rodents. The TD*50 in mmol/kg x day) could then be written: [formula: see text] This expression would be valid for monofunctional alkylators provided the reactive species are uncharged. This is the case for most SN2 reagents. Although it appears possible to predict carcinogenic potency from measured in vivo doses and from detailed knowledge of reaction-kinetic parameter values, it is at present not possible to quantify the uncertainty of such predictions. One main reason for this is the complication due to uneven distribution in the body, with effects on the dose in target tissues. The estimation can be impro