Specific strand loss in N-2-acetylaminofluorene-modified DNA

Replication fork collapse is a major cause of the high mutation frequency at three-base lesion clusters

Unresolved repair of clustered DNA lesions can lead to the formation of deleterious double strand breaks (DSB) or to mutation induction. Here, we investigated the outcome of clusters composed of base lesions for which base excision repair enzymes have different kinetics of excision/incision. We designed multiply damaged sites (MDS) composed of a rapidly excised uracil (U) and two oxidized bases, 5-hydroxyuracil (hU) and 8-oxoguanine (oG), excised more slowly. Plasmids harboring these U-oG/hU MDS-carrying duplexes were introduced into Escherichia coli cells either wild type or deficient for DNA n-glycosylases. Induction of DSB was estimated from plasmid survival and mutagenesis determined by sequencing of surviving clones. We show that a large majority of MDS is converted to DSB, whereas almost all surviving clones are mutated at hU. We demonstrate that mutagenesis at hU is correlated with excision of the U placed on the opposite strand. We propose that excision of U by Ung initiates the loss of U-oG-carrying strand, resulting in enhanced mutagenesis at the lesion present on the opposite strand. Our results highlight the importance of the kinetics of excision by base excision repair DNA n-glycosylases in the processing and fate of MDS and provide evidence for the role of strand loss/replication fork collapse during the processing of MDS on their mutational consequences.

RecA-mediated excision repair: a novel mechanism for repairing DNA lesions at sites of arrested DNA synthesis

In Escherichia coli, bulky DNA lesions are repaired primarily by nucleotide excision repair (NER). Unrepaired lesions encountered by DNA polymerase at the replication fork create a blockage which may be relieved through RecF-dependent recombination. We have designed an assay to monitor the different mechanisms through which a DNA polymerase blocked by a single AAF lesion may be rescued by homologous double-stranded DNA sequences. Monomodified single-stranded plasmids exhibit low survival in non-SOS induced E. coli cells; we show here that the presence of a homologous sequence enhances the survival of the damaged plasmid more than 10-fold in a RecA-dependent way. Remarkably, in an NER proficient strain, 80% of the surviving colonies result from the UvrA-dependent repair of the AAF lesion in a mechanism absolutely requiring RecA and RecF activity, while the remaining 20% of the surviving colonies result from homologous recombination mechanisms. These results uncover a novel mechanism - RecA-mediated excision repair - in which RecA-dependent pairing of the mono-modified single-stranded template with a complementary sequence allows its repair by the UvrABC excinuclease.

The roles of specific glycosylases in determining the mutagenic consequences of clustered DNA base damage

The potential for genetic change arising from specific single types of DNA lesion has been thoroughly explored, but much less is known about the mutagenic effects of DNA lesions present in clustered damage sites. Localized clustering of damage is a hallmark of certain DNA-damaging agents, particularly ionizing radiation. We have investigated the potential of a non-mutagenic DNA base lesion, 5,6-dihydrothymine (DHT), to influence the mutagenicity of 8-oxo-7,8-dihydroguanine (8-oxoG) when the two lesions are closely opposed. Using a bacterial plasmid-based assay we present the first report of a significantly higher mutation frequency for the clustered DHT and 8-oxoG lesions than for single 8-oxoG in wild-type and in glycosylase-deficient strains. We propose that endonuclease III has an important role in the initial stages of processing DHT/8-oxoG clusters, removing DHT to give an intermediate with an abasic site or single-strand break opposing 8-oxoG. We suggest that this mutagenic intermediate is common to several different combinations of base lesions forming clustered DNA damage sites. The MutY glycosylase, acting post-replication, is most important for reducing mutation formation. Recovered plasmids commonly gave rise to both wild-type and mutant progeny, suggesting that there is differential replication of the two DNA strands carrying specific forms of base damage.

Replication of N2-Ethyldeoxyguanosine DNA Adducts in the Human Embryonic Kidney Cell Line 293

N(2)-Ethyldeoxyguanosine (N(2)-ethyldGuo) is a DNA adduct formed by reaction of the exocyclic amine of dGuo with the ethanol metabolite acetaldehyde. Because ethanol is a human carcinogen, we assessed the biological consequences of replication of template N(2)-ethyldGuo, in comparison to the well-studied adduct O(6)-ethyldeoxyguanosine (O(6)-ethyldGuo). Single chemically synthesized N(2)-ethyldGuo or O(6)-ethyldGuo adducts were placed site specifically in the suppressor tRNA gene of the mutation reporting shuttle plasmid pLSX. N(2)-EthyldGuo and O(6)-ethyldGuo were both minimally mutagenic in double-stranded pLSX replicated in human 293 cells; however, the placement of deoxyuridines on the complementary strand at 5'- and 3'-positions flanking the adduct resulted in 5- and 22-fold enhancements of the N(2)-ethyldGuo- and O(6)-ethyldGuo-induced mutant fractions, respectively. The fold increase in the N(2)-ethyldGuo-induced mutant fraction in deoxyuridine-containing plasmids was similar after replication in 293T cells, a mismatch repair deficient variant of 293 cells, indicating that postreplication mismatch repair has little role in modulating N(2)-ethyldGuo-mediated mutagenesis. The mutation spectrum generated by N(2)-ethyldGuo consisted primarily of single base deletions and adduct site-targeted transversions, in contrast to the exclusive production of adduct site-targeted transitions by O(6)-ethyldGuo. The yield of progeny plasmids after replication in 293 cells was reduced by the presence of N(2)-ethyldGuo in parental plasmids with or without deoxyuridine to 39 or 19%, respectively. Taken together, these data indicate that N(2)-ethyldGuo in DNA exerts its principal biological activity by blocking translesion DNA synthesis in human cells, resulting in either failure of replication or frameshift deletion mutations.

Mutagenesis by exocyclic alkylamino purine adducts in Escherichia coli

Exocyclic alkylamino purine adducts, including N(2)-ethyldeoxyguanosine, N(2)-isopropyldeoxyguanosine, and N(6)-isopropyldeoxyadenosine, occur as a consequence of reactions of DNA with toxins such as the ethanol metabolite acetaldehyde, diisopropylnitrosamine, and diisopropyltriazene. However, there are few data addressing the biological consequences of these adducts when present in DNA. Therefore, we assessed the mutagenicities of these single, chemically synthesized exocyclic amino adducts when placed site-specifically in the supF gene in the reporter plasmid pLSX and replicated in Escherichia coli, comparing the mutagenic potential of these exocyclic amino adducts to that of O(6)-ethyldeoxyguanosine. Inclusion of deoxyuridines on the strand complementary to the adducts at 5' and 3' flanking positions resulted in mutant fractions of N(2)-ethyldeoxyguanosine and N(2)-isopropyldeoxyguanosine-containing plasmid of 1.4+/-0.5% and 5.7+/-2.5%, respectively, both of which were significantly greater than control plasmid containing deoxyuridines but no adduct (p=0.04 and 0.003, respectively). The mutagenicities of the three exocyclic alkylamino purine adducts tested were of smaller magnitude than O(6)-ethyldeoxyguanosine (mutant fraction=21.2+/-1.2%, p=0.00001) with the N(6)-isopropyldeoxyadenosine being the least mutagenic (mutant fraction=1.2+/-0.5%, p=0.13). The mutation spectrum generated by the N(2)-ethyl and -isopropyldeoxyguanosine adducts included adduct site-targeted G:C-->T:A transversions, adduct site single base deletions, and single base deletions three bases downstream from the adduct, which contrasted sharply with the mutation spectrum generated by the O(6)-ethyldeoxyguanosine lesion of 95% adduct site-targeted transitions. We conclude that N(2)-ethyl and -isopropyldeoxyguanosine are mutagenic adducts in E. coli whose mutation spectra differ markedly from that of O(6)-ethyldeoxyguanosine.

Mutagenesis studies with four stereoisomeric N2-dG benzo[a]pyrene adducts in the identical 5′-CGC sequence used in NMR studies: G→T mutations dominate in each case

Benzo[a]pyrene (B[a]P) is a polycyclic aromatic hydrocarbon (PAH) and a potent mutagen/carcinogen found ubiquitously in the environment. B[a]P is primarily metabolized to diol epoxides, which react principally at N2-dG in DNA. B[a]P-N2-dG adducts have been shown to induce a variety of mutations, notably G-->T, G-->A, G-->C and -1 frameshifts. Four stereoisomers of B[a]P-N2-dG (designated: [+ta]-;, [+ca]-, [-ta] and [-ca]) were studied by NMR in duplex 11mers in a 5'-CGC sequence context, and each adopted a different adduct conformation (Geacintov, et al. (1997) Chem. Res. Toxicol., 10, 111). Herein these four identical B[a]P-containing 11mers are built into duplex plasmid genomes and mutagenesis studied in Escherichia coli following SOS-induction. In nucleotide excision repair (NER) proficient E.coli, no adduct-derived mutants are detected. In NER deficient E.coli, G-->T mutations dominate for all four stereoisomers [+ta]-, [+ca]-, [-ta] and [-ca]-B[a]P-N(2)-dG, and mutation frequency is similar. Thus, the mutagenic pattern for these four B[a]P-N2-dG stereoisomers is the same, in spite of the fact that they adopt dramatically different conformations in ds-oligonucleotides as determined by NMR. These findings suggest that adduct conformation must be fluid enough in the 5'-CGC sequence that the duplex DNA conformation can interconvert to mutagenic and non-mutagenic conformations during lesion-bypass. A comparison of all published studies with these four B[a]P-N2-dG stereoisomers in E.coli reveals that B[a]P-N2-dG adduct stereochemistry tends to have a lesser impact on mutagenic pattern (e.g. G-->T versus G-->A mutations) than does DNA sequence context, which is discussed.

Mutational consequences of replication of M13mp7L2 constructs containing cis-opened benzo[a]pyrene 7,8-diol 9, 10-epoxide-deoxyadenosine adducts

The four adducts that arise by cis ring opening of the four optically active benzo[a]pyrene diol epoxides by the exocyclic N6-amino group of deoxyadenosine were incorporated synthetically into each of two different oligonucleotide 16-mers, 5'-TTTXGAGTCTGCTCCC-3' [context I(A)] and 5'-CAGXTTTAGAGTCTGC-3' [context II(A)], at the X position. The eight resultant oligonucleotides were separately ligated into bacteriophage M13mp7L2 and replicated in Escherichia coli that had been SOS-induced, and the progeny were analyzed to evaluate the consequences of replication past these adducts. The presence of these adducts reduced plaque yields substantially. However, the progeny obtained exhibited high frequencies of base substitution mutation ranging from 9 to 68%, depending upon the individual adduct and the sequence context in which it was placed. For most of the adducts, A --> T transversion was the mutation found most frequently in either sequence context, and mutation frequencies in context I(A) were always substantially greater than those in context II(A). In context I(A), adducts with an R configuration at the site of nucleoside attachment were more mutagenic than those with an S configuration. In both sequence contexts that were studied, the cis adduct arising from the (7S,8R)-diol (9S,10R)-epoxide was the most mutagenic adduct. These findings clearly show that individual mutation frequencies are determined by the combined effects of both adduct structure and sequence context.

A slipped replication intermediate model is stabilized by the syn orientation of N-2-aminofluorene- and N-2-(acetyl)aminofluorene-modified guanine at a mutational hotspot

The Escherichia coli NarI restriction enzyme recognition site 5'G1G2C3G4C5C63' is a mutational hotspot for -2 deletions in E. coli plasmid pBR322, resulting in the sequence 5'GGCC3' when G4 is modified by the aromatic amine N-2-(acetyl)aminofluorene (AAF) [Burnouf, D., Koehl, P., and Fuchs, R. P. P. (1995) Proc. Natl. Acad. Sci. U.S.A. 86, 4147-4151] even though each G shows similar reactivity [Fuchs, R. P. P. (1984) J. Mol. Biol. 177, 173-180]. Modification at G4 by the related aromatic amine 2-aminofluorene (AF), which lacks the acetyl group of AAF, can also cause -2 deletions, but at a lower frequency [Bichara, M., and Fuchs, R. P. P. (1985) J. Mol. Biol. 183, 341-351]. A specific mechanism has been proposed to explain the double-base frameshifts in the NarI sequence in which the GC deletion results from a slipped mutagenic intermediate formed during replication [Schaaper, B. M., Koffel-Schwartz, N., and Fuchs, R. P. P. (1990) Carcinogenesis 11, 1087-1095]. We address the following key questions in this study. Why does AAF modification dramatically increase the mutagenicity at the NarI G4 position, and why does AAF enhance the mutagenicity more than AF? We studied two intermediates which model replication at one arm of a fork, using a fragment of DNA modified by AF or AAF at G4 in the NarI sequence: Intermediate I can be converted into intermediate II by misalignment. Elongation of intermediate I leads to error-free translesion synthesis, while elongation of intermediate II leads to a -2 frameshift mutation. Minimized potential energy calculations were carried out using the molecular mechanics program DUPLEX to investigate the conformations of the AF and AAF adducts at G4 in these two intermediates. We find that the slipped mutagenic intermediate is quite stable relative to its normally extended counterpart in the presence of AF and AAF in an abnormal syn orientation of the damaged base. An enhanced probability of elongation from a stable slipped structure rather than a properly aligned one would favor increased -2 frameshift mutations. Furthermore, AAF-modified DNA has a greater tendency to adopt the syn orientation than AF because of its greater bulk, which could explain its greater propensity to cause -2 deletions in the NarI sequence.

Analysis of damage tolerance pathways in Saccharomyces cerevisiae: a requirement for Rev3 DNA polymerase in translesion synthesis

The replication of double-stranded plasmids containing a single N-2-acetylaminofluorene (AAF) adduct located in a short, heteroduplex sequence was analyzed in Saccharomyces cerevisiae. The strains used were proficient or deficient for the activity of DNA polymerase zeta (REV3 and rev3delta, respectively) in a mismatch and nucleotide excision repair-defective background (msh2delta rad10delta). The plasmid design enabled the determination of the frequency with which translesion synthesis (TLS) and mechanisms avoiding the adduct by using the undamaged, complementary strand (damage avoidance mechanisms) are invoked to complete replication. To this end, a hybridization technique was implemented to probe plasmid DNA isolated from individual yeast transformants by using short, 32P-end-labeled oligonucleotides specific to each strand of the heteroduplex. In both the REV3 and rev3delta strains, the two strands of an unmodified heteroduplex plasmid were replicated in approximately 80% of the transformants, with the remaining 20% having possibly undergone prereplicative MSH2-independent mismatch repair. However, in the presence of the AAF adduct, TLS occurred in only 8% of the REV3 transformants, among which 97% was mostly error free and only 3% resulted in a mutation. All TLS observed in the REV3 strain was abolished in the rev3delta mutant, providing for the first time in vivo biochemical evidence of a requirement for the Rev3 protein in TLS.

How stereochemistry affects mutagenesis by N2-deoxyguanosine adducts of 7,8-dihydroxy-9,10-epoxy-7,8,9,10-tetrahydrobenzo[a]pyrene: configuration of the adduct bond is more important than those of the hydroxyl groups

Previous work has shown that the major adduct from the (+)-anti diol epoxide of benzo[a]pyrene (B[a]P), which forms at N2-deoxyguanosine [(+)-trans-anti-B[a]P-N2-dG], is capable of inducing either predominantely G --> T mutations ( approximately 95%) in a 5'-TGC-3 sequence context or predominantly G --> A mutations ( approximately 80%) in a 5'-CGT-3' sequence context. This is likely to be attributable to the major adduct being in a different mutagenic conformation in each case. In the next phase of this work, the questions to be addressed are what conformation is associated with what mutation and why? To help define what aspect of adduct structure is important to mutagenesis, the work herein reports on the mutations induced in a single sequence context by four stereoisomers of B[a]P-N2-dG: (+)-trans-, (+)-cis-, (-)-trans-, and (-)-cis-. The (+)-trans- and (-)-cis-adducts show a remarkably similar mutational pattern with G --> A mutations predominating ( approximately 80%). The (-)-trans- and (+)-cis-adducts also show a similar mutational pattern with a more even mixture of G --> T, G --> A, and G --> C mutations. Each of these adducts has an adduct bond and three hydroxyl groups at four consecutive saturated carbons in the B[a]P moiety of the adduct; the stereochemistry at these four positions differs in each of the adducts. The (+)-trans- and (-)-cis-adducts are a pair sharing the S configuration for the adduct bond, although they are a mirror image vis-a-vis the hydroxyl groups. The (-)-trans- and (+)-cis-adducts share the opposite adduct bond stereochemistry (R) but differ in the stereochemistry of their hydroxyl groups. Thus, there is a correlation suggesting that anti-B[a]P-N2-dG adduct mutagenesis is more dependent on the stereochemistry of the adduct bond than on the stereochemistry of the hydroxyl groups.

New strategy for the construction of single-stranded plasmids with single mutagenic lesions

Single-stranded DNA vectors containing single adducts offer a unique opportunity to study the biochemistry and genetics of trans lesion synthesis, a process during which a DNA polymerase synthesizes across a lesion. We describe a new and general strategy to produce high-quality single-stranded plasmids containing a single adduct within a predetermined sequence context starting with a short oligonucleotide containing the lesion of interest. These vectors are isolated from the corresponding double-stranded constructs by selective enzymatic degradation in vitro of the nonadducted uracil-containing strand. Efficient and complete removal of this strand was achieved using uracil DNA glycosilase to generate AP sites followed by the action of the AP endonuclease associated with exonuclease III and the robust 3'-->5' exonuclease activity associated with T7 DNA polymerase. We show the utility of these constructs for the study of trans lesion synthesis in vitro and in vivo in the case of the highly carcinogenic N-2-acetylaminofluorene adducts located within frameshift mutation hot spots. The possibility to construct both single-stranded and double-stranded plasmids, with the same origin of replication (i.e., ColE1), will allow a direct comparison between single-stranded and double-stranded DNA replication in site-specific mutagenesis studies.

Role of G-->T transversions in the mutagenicity of alkylperoxyl radicals: induction of alkali-labile sites in bacteriophage M13mp19

The mutagenicity of peroxyl radicals, ubiquitous products of lipid peroxidation, was assessed using an in vitro M13 forward mutational assay. Single-stranded M13mp19 plasmids were incubated with a range of concentrations of the azo initiator 2,2'-azobis(2-amidinopropane) hydrochloride, and then transfected into competent, SOS-induced Escherichia coli JM105 cells. Incubation with peroxyl radicals produced a concentration-dependent decrease in phage survival, with a 500 microM concentration of the azo initiator reducing the transfection efficiency by more than 90% while inducing a corresponding 6-fold increase in lacZ alpha mutation frequencies. Peroxyl radical-induced mutagenesis was completely prevented by the peroxyl radical scavenger Trolox. Automated DNA sequence analysis of the lacZ alpha gene of 100 peroxyl radical-induced mutants revealed that the most frequent sequence changes were base pair substitutions (92/95), with G-->T transversions predominating (73/92). Alkaline treatment prior to transfection diminished the mutagenicity of damaged plasmids to a level resembling that of unmodified DNA. While abasic sites might account for the sensitivity to alkaline cleavage, the possibility that unidentified nonabasic alkaline-labile lesions also contribute to peroxyl radical mutagenesis cannot be excluded. Collectively, these findings raise the possibility that DNA damage caused by a major class of endogenous radicals contributes to one of the most common spontaneous mutational events, the G-->T transversion.

Cellular strategies for accommodating replication-hindering adducts in DNA: control by the SOS response in Escherichia coli

The replication of double-stranded plasmids containing a single adduct was analyzed in vivo by means of a sequence heterology that marks the two DNA strands. The single adduct was located within the sequence heterology, making it possible to distinguish trans-lesion synthesis (TLS) events from damage avoidance events in which replication did not proceed through the lesion. When the SOS system of the host bacteria is not induced, the C8-guanine adduct formed by the carcinogen N-2-acetylaminofluorene (AAF) yields less than 1% of TLS events, showing that replication does not readily proceed through the lesion. In contrast, the deacetylated adduct N-(deoxyguanosin-8-yl)-2-aminofluorene yields approximately 70% of TLS events under both SOS-induced and uninduced conditions. These results for TLS in vivo are in good agreement with the observation that AAF blocks DNA replication in vitro, whereas aminofluorene does so only weakly. Induction of the SOS response causes an increase in TLS events through the AAF adduct (approximately 13%). The increase in TLS is accompanied by a proportional increase in the frequency of AAF-induced frameshift mutations. However, the polymerase frameshift error rate per TLS event was essentially constant throughout the SOS response. In an SOS-induced delta umuD/C strain, both US events and mutagenesis are totally abolished even though there is no decrease in plasmid survival. Error-free replication evidently proceeds efficiently by means of the damage avoidance pathway. We conclude that SOS mutagenesis results from increased TLS rather than from an increased frameshift error rate of the polymerase.

A viral genome containing an unstable aflatoxin B1-N7-guanine DNA adduct situated at a unique site

A problem that has hindered the study of the biological properties of certain DNA adducts, such as those that form at the N7 atoms of purines, is their extreme chemical lability. Conditions are described for the construction of a single-stranded genome containing the chemically and thermally labile 8,9-dihydro-8- (N7-guanyl)-9-hydroxyaflatoxin B1 (AFB1-N7-Gua) adduct, the major DNA adduct of the potent liver carcinogen aflatoxin B1 (AFB1). A 13mer oligonucleotide, d(CCTCTTCGAACTC), was allowed to react with the exo-8,9-epoxide of AFB1 to form an oligonucleotide containing a single AFB1-N7-Gua (at the underlined guanine). This modified 13mer was 5'-phosphorylated and ligated into a gap in an M13 bacteriophage genome generated by annealing a 53mer uracil-containing scaffold to M13mp7L2 linearized by EcoRI. Following ligation, the scaffold was enzymatically removed with uracil DNA glycosylase and exonuclease III. The entire genome construction was complete within 3 h and was carried out at 16 degrees C, pH 6.6, conditions determined to be optimal for AFB1-N7-Gua stability. Characterization procedures indicated that the AFB1-N7-Gua genome was approximately 95% pure with a small (5%) contamination by unmodified genome. This construction scheme should be applicable to other chemically or thermally unstable DNA adducts.

The in vitro more efficiently repaired cisplatin adduct cis-Pt.GG is in vivo a more mutagenic lesion than the relative slowly repaired cis-Pt.GCG adduct

The toxic effect and the mutagenicity of two differentially repaired site-specific cis-diamminedichloroplatinum(II) (cis-DDP) lesions were investigated. Detailed analysis of the UvrABC-dependent repair of the two lesions in vitro showed a more efficient repair of the cis-Pt.GG adduct compared to that of the cis-Pt.GCG adduct (Visse et al., 1994). Furthermore, previously, a dependency of cis-DDP mutagenesis on UvrA and UvrB, but not on UvrC was found (Brouwer et al., 1988). To possibly relate survival and mutagenesis to repair, plasmids containing the same site-specific cis-DDP lesions as those that were used in the detailed repair studies were transformed into Escherichia coli. The results indicate that both lesions are very efficiently bypassed in vivo. Mutation analysis was performed using a denaturing gradient gel electrophoresis technique, which allows identification of mutations without previous selection. Although the cis-Pt.GG adduct is in vitro more efficiently repaired than the cis-Pt.GCG adduct, it appeared to be more mutagenic. We present a model in which this result is related to the previously observed dependency of the mutagenicity of cis-DDP lesions on the Uvr A and B proteins.

Frequency and fidelity of translesion synthesis of site-specific N-2-acetylaminofluorene adducts during DNA replication in a human cell extract

We have previously analyzed the effects of site-specific N-2-acetylaminofluorene (AAF) adducts on the efficiency and frameshift fidelity of SV40-based DNA replication in a human cell extract (Thomas, D. C., Veaute, X., Kunkel, T. A., and Fuchs, R. P. P. (1994) Proc. Natl. Acad. Sci. U.S.A. 91, 7752-7756). Here we use two sets of substrates to examine the probability of replication termination and error-free and error-prone bypass of AAF adducts. The substrates contained site-specific adducts at one of three guanines in a NarI sequence (5'-GGCGCC-3') placed within the lacZ alpha reporter gene and located on the template for either leading or lagging strand replication. The presence of the adduct at any position strongly reduces the efficiency of a single round of replication in a HeLa cell extract. Product analysis reveals preferential replication of the undamaged strand and termination of replication of the damaged strand occurring one nucleotide before incorporation opposite either a leading or lagging strand adduct. Products resistant to restriction endonuclease cleavage at the adducted site were generated in amounts consistent with 16-48% lesion bypass during replication. Most of this bypass was error-free. However, two-nucleotide deletion errors were detected in the replication products of DNA containing an AAF adduct in either the leading or lagging strand, but only when present at the third guanine position. Collectively, the data suggest that the replication apparatus in a HeLa cell extract generates a template-primer slippage error at an AAF adduct once for every 30-100 bypass events.

Genetic toxicity of 2-acetylaminofluorene, 2-aminofluorene and some of their metabolites and model metabolites

2-Acetylaminofluorene and 2-aminofluorene are among the most intensively studied of all chemical mutagens and carcinogens. Fundamental research findings concerning the metabolism of 2-acetylaminofluorene to electrophilic derivatives, the interaction of these derivatives with DNA, and the carcinogenic and mutagenic responses that are associated with the resulting DNA damage have formed the foundation upon which much of genetic toxicity testing is based. The parent compounds and their proximate and ultimate mutagenic and carcinogenic derivatives have been evaluated in a variety of prokaryotic and eukaryotic assays for mutagenesis and DNA damage. The reactive derivatives are active in virtually all systems, while 2-acetylaminofluorene and 2-aminofluorene are active in most systems that provide adequate metabolic activation. Knowledge of the structures of the DNA adducts formed by 2-acetylaminofluorene and 2-aminofluorene, the effects of the adducts on DNA conformation and synthesis, adduct distribution in tissues, cells and DNA, and adduct repair have been used to develop hypotheses to understand the genotoxic and carcinogenic effects of these compounds. Molecular analysis of mutations produced in cell-free, bacterial, in vitro mammalian, and intact animal systems have recently been used to extend these hypotheses.

Response of repair-competent and repair-deficient Escherichia coli to three O6-substituted guanines and involvement of methyl-directed mismatch repair in the processing of O6-methylguanine residues

Plasmids containing a site-specifically incorporated O6-methyl- (m6G), O6-ethyl- (e6G), or O6-benzylguanine (b6G) within the ATG initiation codon of the lacZ' gene were used to transform Escherichia coli that were repair proficient or deficient in one or both of the E. coli O6-alkylguanine-DNA alkyltransferases, the uvr(ABC) excision repair system, the recA-mediated recombination system, or the methylation-directed mismatch repair system. Colonies were scored phenotypically for adduct-induced mutations. With plasmids containing either e6G or b6G, the frequency of adduct-induced mutation was low and independent of the repair proficiency of the strain transformed. Plasmids containing an m6G residue elicited similar responses in all but the mismatch repair-deficient strain. The generally low mutagenicity of all the O6-substituted guanines was interpreted as reflecting an adduct-induced arrest of replication of the modified strand while the unmodified complementary strand was replicated normally. Studies of the involvement of mismatch repair in m6G mutagenesis showed that m6G:T base pairs were more readily processed than m6G:C base pairs, indicating that mismatch repair involving m6G residues occurs after replication. These data support a model in which the E. coli methylation-directed mismatch repair system diverts plasmids containing promutagenic m6G:T base pairs into replication-arrested complexes providing another line of defense against O6-methylguanine mutagenicity in addition to O6-alkylguanine-DNA alkyltransferase repair and excision repair mechanisms.

Mutagenic replication in human cell extracts of DNA containing site-specific N-2-acetylaminofluorene adducts

We have analyzed the effects of site-specific N-2-acetylaminofluorene (AAF) adducts on the efficiency and frameshift fidelity of bidirectional replication of double-stranded DNA in a human cell extract. Plasmid vectors were constructed containing the simian virus 40 origin of replication and single AAF adducts at one of three guanines in the Nar I sequence GGCGCC in a lacZ reporter gene. The presence of an AAF adduct diminishes replication efficiency in HeLa cell extracts by 70-80%. Replication product analyses reveal unique termination sites with each damaged vector, suggesting that when the replication fork encounters an AAF adduct, it often stops before incorporation opposite the adduct. We also observed a higher proportion of products representing replication of the undamaged strand compared to the damaged strand. This suggests that the undamaged strand is replicated more readily, either by uncoupling the first fork to encounter the lesion or by replication using the fork arriving from the other direction. Also included among replication products are covalently closed monomer-length molecules resistant to cleavage at the AAF-modified Nar I site. This resistance is characteristic of substrates containing the AAF adduct, suggesting that translesion bypass had occurred. Transformation of Escherichia coli cells with the replicated damaged DNA yielded lacZ alpha revertant frequencies significantly above values obtained with undamaged DNA or with damaged DNA not replicated in vitro. This increase was only seen with the substrate modified at the third guanine position. Analysis of mutant DNA demonstrated the loss of a GC dinucleotide at the Nar I sequence. Generation of this position-dependent AAF-induced frameshift error in a human replication system is consistent with previous observations in E. coli suggesting that, after incorporation of dCMP opposite modified guanine in the third position, realignment of the template-primer occurs to form an intermediate with two unpaired nucleotides in the template strand.

Mechanism of toxicity of 3-methyladenine for bacteriophage T7

Treatment of bacteriophage T7 with methyl methanesulfonate perturbed phage-specific genetic expression in both repair-proficient and repair-deficient Escherichia coli cells. In wild-type cells (AB1157), the time course of protein synthesis was slowed down but an entire complement of phage proteins was synthesized. In cells (BK2114, tag-) unable to repair 3-methyladenine, the toxic lesion produced by methyl methanesulfonate, alkylated phage produced only early (class I) proteins. These results suggested that late transcription was inhibited in infected tag- cells. These cells were shown to contain a significant amount of active T7 RNA polymerase, a class I protein. Thus, the cause of inhibition appeared to be the inability of T7 RNA polymerase to use unrepaired DNA as template. In vitro transcription assays with alkylated T7 DNA as template supported this proposal. T7 RNA polymerase proved to be very sensitive to the presence of alkylation lesions. In addition, the phage enzyme was much more sensitive to these lesions than was its bacterial counterpart, E. coli RNA polymerase. These results suggest that 3-methyladenine exerts its toxic action, in the T7 system, at the level of transcription by T7 RNA polymerase. To further characterize the reduced activity of the T7 enzyme, an in vitro transcription assay using linearized plasmid DNA with one T7 promoter was devised. Gel electrophoresis revealed that only one transcript of well-defined length was synthesized by T7 RNA polymerase on this template. Alkylation of the template did not alter the size of the transcript produced. Simultaneous measurement of chain initiation and chain elongation confirmed this result by showing that both steps were reduced to the same extent by alkylation of template DNA. Thus T7 RNA polymerase does not appear to be blocked by 3-methyladenine. Rather the lesion must hinder translocation of T7 RNA polymerase along the DNA template during chain elongation.

Mutagenicity and genotoxicity of the major DNA adduct of the antitumor drug cis-diamminedichloroplatinum(II)

The mutagenicity and genotoxicity of cis-[Pt(NH3)2[d(GpG)-N7(1),-N7(2)]] (G*G*), the major DNA adduct of the antitumor drug cisplatin, has been investigated in Escherichia coli. A duplex bacteriophage M13 genome was constructed to contain the G*G* adduct at a specific site in the (-) strand. The singly platinated duplex genome exhibited a survival of 22% relative to that of the unplatinated control genomes, and this value rose to 38% in cells treated with ultraviolet light to induce the SOS response. Singly platinated single-stranded genomes were also produced. Replication of the single- and double-stranded genomes in vivo yielded SOS-dependent, targeted mutations at frequencies of 1.3% and 0.16%, respectively. The mutagenic specificity of G*G* in both single- and double-stranded DNA was striking in that 80-90% of the mutations occurred at the 5'-platinated G. Approximately 80% of the mutations were G-->T transversions at that site. A model of mutagenesis is presented to explain this mutational specificity with respect to current understanding of platinum-DNA adduct structure.

In vivo evidence that UV-induced C-->T mutations at dipyrimidine sites could result from the replicative bypass of cis-syn cyclobutane dimers or their deamination products

The major mutations induced by UV light are C-->T transitions at dipyrimidines and arise from the incorporation of A opposite the C of dipyrimidine photoproducts. The incorporation of A has most often been explained by the known preference of a polymerase to do so opposite noninstructional DNA damage such as an abasic site (A rule). There are also mechanisms that suppose, however, that cis-syn dipyrimidine photodimers are instructional. In one such mechanism (tautomer bypass), the incorporation of A is directed by the tautomer of a C of a dimer that is equivalent in base-pairing properties to U [Person et al. (1974) Genetics 78, 1035-1049]. In another mechanism (deamination bypass), the incorporation of A is directed by a U of a dimer that results from the deamination of the C of a dimer [Taylor & O'Day (1990) Biochemistry 29, 1624-1632]. The viability of these mechanisms was tested by obtaining the mutation spectrum of a TU dimer in Escherichia coli by application of a standard method for site-directed mutagenesis. To this end, a 41-mer containing a site-specific TU dimer was constructed via ligation of a dimer-containing decamer that was produced by triplet-sensitized irradiation and used to prime DNA synthesis on a uracil-containing (+) strand of an M13 clone containing a double mismatch opposite the dimer. The reaction mixture was used to transfect a uracil glycosylase proficient, photoproduct repair deficient E. coli host, and all progeny phage weakly hybridizing to the parental (+) or (-) strands were sequenced. Under non-SOS conditions the TU dimer almost completely blocked replication, while under SOS conditions it directed the incorporation of two As with much higher specificity (96%) than would an abasic site. The implications of these results to the mechanism of the UV-induced TC-->TT mutation, and by extension to the CT-->TT, CC-->TC, CC-->CT, and the tandem CC-->TT mutations, are discussed.

An intrastrand d(GpG) platinum crosslink in duplex M13 DNA is refractory to repair by human cell extracts

We have examined the ability of human cell extracts to repair the most frequent DNA adduct caused by the cancer chemotherapeutic agent cis-diamminedichloroplatinum(II). A circular DNA duplex with an intrastrand d(GpG) crosslink positioned at a specific site was synthesized. Human cell extracts were unable to induce repair synthesis in a 29-base-pair region encompassing the adduct or in adjacent regions. The same extracts could repair a single defined 2-acetylaminofluorene lesion in a similar location. When molecules containing the platinum adduct were cleaved by Escherichia coli UvrABC enzyme, human cell extracts could perform repair synthesis at the damaged site, suggesting that human enzymes fail to make incisions near the d(GpG) crosslink but can complete repair once incisions are made. This result indicates that most repair synthesis in DNA damaged with multiple cis-diamminedichloroplatinum(II) adducts takes place at lesions other than the predominant d(GpG) crosslink. These data support the idea that the clinical effectiveness of cis-diamminedichloroplatinum(II) may be explained by the inefficient repair of the major DNA adduct caused by this drug.

Mutations induced by methylene blue plus light in single-stranded M13mp2

Reactive oxygen species are generated by a variety of cellular processes. These endogenously generated, reactive intermediates produce a multiplicity of DNA alterations and mutations and have been implicated in the pathogenesis of several human diseases. We report here that treatment of single-stranded M13mp2 bacteriophage DNA with methylene blue and white light generates increased levels of 8-hydroxydeoxyguanosine and that mutagenesis is both highly specific and dependent on the SOS response. Lesions produced block the progression of DNA synthesis one base preceding template guanines. In SOS-induced Escherichia coli, 97% of all methylene blue-induced mutations in the lacZ alpha gene of M13mp2 DNA are single-base substitutions opposite template guanines. The most frequent mutations are G----C transversions. The G----T transversions expected from the presence of 8-hydroxydeoxyguanosine in the template strand occur, but at a lower frequency. Sequence data together with SOS dependency and the presence of replication blockage demonstrate that while 8-hydroxydeoxyguanosine may serve as an important marker to monitor oxygen-induced DNA damage in humans, it does not account for either the observed blockage to replication or the mutagenesis by methylene blue plus light in SOS-induced E. coli. Instead, an as yet unidentified lesion generated by active oxygen species is a more potent mutagenic event.

Survival of phage M13 with uracils on one or both DNA strands

The survival of M13 DNA was studied after partial replacement of thymine by uracil in the bacteriophage. Uracils carry the same genetic information as the thymines. Nevertheless in Escherichia coli wild-type cells, uracils in DNA are replaced by thymines by excision repair initiated by uracil-DNA glycosylase (UDG). Thus inactivation of uracil-containing phage DNA is solely due to repair initiated by UDG. Incorporation of uracils was achieved in one or in both strands, either randomly or site-specifically using differently uracylated oligonucleotides. The results show that up to 580 uracils can be repaired without a significant decrease in survival if the uracils are localized in the (-) strand only. Incorporation of 246 uracils into the (+) strand leads to approximately 30% or approximately 10% survival when expressed in Escherichia coli strains CMK and JM103, respectively. However, when uracils are distributed over both strands a sharp decrease in survival occurs. This shows that the repair of two uracils localized in close proximity on opposite strands of the DNA by the excision repair mechanism is difficult, whereas uracils occurring in one strand are repaired more efficiently, irrespective of their number.

Carcinogen-induced frameshift mutagenesis in repetitive sequences

We have constructed plasmids pS3G-1 and pSG4 that contain single acetylaminofluorene adducts within contiguous runs of three (5'-CCCG1G2G3-3') and four (5'-CG1GGG4T-3') guanine residues, respectively. In Escherichia coli, the frequency of induced -1 frameshift mutations was strongly dependent on the position of modification: pS3G-G3 was approximately 100-fold and 10-fold more mutagenic than pS3G-G1 and pS3G-G2, respectively; pSG4-G4 was approximately 600-fold more mutagenic than pSG4-G1. Mutagenesis was SOS-dependent and was markedly reduced in bacteria that were proficient in nucleotide excision repair as compared to a repair-deficient uvrA6 mutant. DNA sequencing showed that -1 frameshift events in pS3G-1 consisted of either targeted mutations (greater than 90% of induced mutations) within the guanine sequence or semitargeted mutations (greater than 10%) in the 5' flanking repetitive cytosine sequence. Semitargeted events, which were observed when acetylaminofluorene modification was at G1 and G2, show that a lesion can reduce the fidelity of replication at positions 5' to its location on the template strand. No semitargeted frameshifts were observed in plasmid pSG4, which lacks a repetitive sequence 5' to the adduct. Our results are consistent with a model for frameshift mutagenesis in which the acetylaminofluorene adduct (i) allows accurate incorporation of cytosine opposite the bulky lesion during DNA synthesis and (ii) impedes elongation of primer/template termini formed opposite the adduct or 5' to the adduct on the template strand, providing increased opportunity for the formation of slipped frameshift intermediates.

The vinyl chloride DNA derivative N2,3-ethenoguanine produces G----A transitions in Escherichia coli

Vinyl chloride is a known human and rodent carcinogen that forms several cyclic base derivatives in DNA. The mutagenic potential of these derivatives has been examined in vitro but not in vivo. One of these derivatives, N2,3-ethenoguanine (epsilon G), is known to base pair with both cytosine and thymine during in vitro DNA synthesis, which would result in G----A transitions. To determine the base pairing specificity of this labile guanine derivative in Escherichia coli, we have developed a genetic reversion assay for guanine derivatives. The assay utilizes DNA polymerase-mediated analogue insertion into a bacteriophage vector, M13G*1, which detects all single-base substitutions at position 141 of the lacZ alpha gene by change in plaque color. After the insertion of a single epsilon G opposite the template cytosine at position 141 by use of epsilon dGTP and DNA polymerase and further extension with all four normal dNTPs, the DNA was transfected into E. coli. Transfection of M13G*1 containing epsilon G at the target site yielded 135 mutants among 26,500 plaques, 134 of which represented G----A transitions. The uncorrected mutation frequency was 0.5%, as compared with the control value, approximately 0.02%; when corrected for epsilon G content and penetrance, the calculated mutagenic potential of epsilon G (mutations/analogue) was about 13%. We thus conclude that epsilon G specifically induces G----A transitions during DNA replication in E. coli. The M13G*1 assay may permit the testing of other labile guanine derivatives not otherwise amenable to mutagenesis studies.

RecA-dependent incision of psoralen-crosslinked DNA by (A)BC excinuclease

Previous work to elucidate the mechanism of crosslink repair by (A)BC excinuclease has shown that a psoralen-crosslinked duplex is selectively incised in the furan-side strand, while a three-stranded structure is incised in the pyrone-side strand of the crosslink. These observations support a sequential incision and recombination model for the complete error-free repair of a psoralen crosslink. The work presented here extends these findings by demonstrating that in the presence of RecA protein and a homologous DNA oligonucleotide, (A)BC excinuclease is induced to incise the pyrone-side strand of a crosslinked double-stranded plasmid molecule. This finding adds further support to the current model for error-free crosslink repair.

The 'A rule' of mutagen specificity: a consequence of DNA polymerase bypass of non-instructional lesions?

The replicative bypass of lesions in DNA and the induction of mutations by agents which react with DNA to produce damaged bases can be understood on the basis of a simple kinetic model. Bypass can be analyzed by separately considering three processes: a) addition of a base opposite a lesion, b) a proofreading excision process, and c) a rate limiting elongation step. Adenine nucleotides are preferentially added opposite many lesions making it possible to predict mutational specificity. Replicative bypass (translesion synthesis) is dependent on modulation of proofreading exonuclease activity but loss of exonuclease activity alone is not sufficient to ensure bypass. Frameshift mutation is the result of the failure of translesion synthesis accompanied by rearrangement of the template, particularly at repetitive sites.

Mutagenic properties of a unique abasic site in mammalian cells

The mutagenic properties of a true unique abasic site located opposite a guanine residue were studied. An oligonucleotide containing a chemically-produced abasic site was inserted into a shuttle vector able to replicate both in simian cells and in bacteria. Plasmid DNA was rescued from simian cells and screened in bacteria by differential hybridization with a labelled oligonucleotide probe. Mutations were easily detected and sequenced. Results showed that opposite a guanine the abasic site was error free repaired or replicated by mammalian cells with an efficiency of 99%. Point mutations occurred at a frequency of approximately 1% in control host cells and at more than 3% in UV-pre-irradiated host cells. Adenine, cytosine or thymine were found to have been inserted opposite the abasic site. No preferential insertion for a particular base was observed in contrast to that reported in bacteria.

Mammalian cell processing of a unique uracil residue in simian virus 40 DNA

The processing of a unique uracil in DNA has been studied in mammalian cells. A synthetic oligodeoxyribonucleotide carrying a potential Bgl II restriction site, where one base has been substituted with a uracil, was inserted in the early intron of SV40 genome. Various heteroduplexes were constructed in such a manner that the restitution of an active Bgl II restriction site corresponds in each case to the specific substitution of the uracil by one of the four bases normally present in the DNA. DNA cuts by this restriction enzyme in one or several constructed heteroduplexes immediately determine the type of base pair substitution produced at the site of the U residue. When the uracil is inserted opposite a purine it is fully repaired; when facing a guanine it is replaced by a cytosine and opposite an adenine it is replaced by a thymine. These results indicate the error-free repair of uracil when it appears in the cell with the usual mechanisms such as cytosine deamination or incorporation of dUTP in place of dTTP during replication. When the uracil is inserted opposite a pyrimidine no error free repair at all is detected for U:C or U:T mismatches. It appears, moreover, that in approximately 18% of the cases U:T mismatch leads to a C:G base pairing. In the majority of the U:pyrimidine mismatches, mutations occur in the vicinity of the uracil, including base substitutions and frameshifts by addition of one or several bases.

Single d(ApG)/cis-diamminedichloroplatinum(II) adduct-induced mutagenesis in Escherichia coli

The mutation spectrum induced by the widely used antitumor drug cis-diamminedichloroplatinum(II) (cis-DDP) showed that cisDDP[d(ApG)] adducts, although they account for only 25% of the lesions formed, are approximately 5 times more mutagenic than the major GG adduct. We report the construction of vectors bearing a single cisDDP[d(ApG)] lesion and their use in mutagenesis experiments in Escherichia coli. The mutagenic processing of the lesion is found to depend strictly on induction of the SOS system of the bacterial host cells. In SOS-induced cells, mutation frequencies of 1-2% were detected. All these mutations are targeted to the 5' base of the adduct. Single A----T transversions are mainly observed (80%), whereas A----G transitions account for 10% of the total mutations. Tandem base-pair substitutions involving the adenine residue and the thymine residue immediately 5' to the adduct occur at a comparable frequency (10%). No selective loss of the strand bearing the platinum adduct was seen, suggesting that, in vivo, cisDDP[d(ApG)] adducts are not blocking lesions. The high mutation specificity of cisDDP[d(ApG)]-induced mutagenesis is discussed in relation to structural data.

Position of a single acetylaminofluorene adduct within a mutational hot spot is critical for the related mutagenic event

2-Acetylaminofluorene, a potent rat liver carcinogen, which binds primarily to C8 of guanines, has been shown to induce mainly frameshift mutations in the bacteria Escherichia coli. Mutations occur at specific sequences, known as mutation hot spots, of which two types may be considered. First, repetitive sequences, where deletions of a single unit occur (GGGGG----GGGG). Second, the so-called NarI site, 5'GGCGCC3', where only -2-bp deletions are observed (G1G2CG3CC----GGCC). Mutagenesis within repetitive sequences is dependent on the UmuCD+ gene functions, whereas mutagenesis in the NarI site is not. These differences in the genetic requirements of mutagenesis at these hot spots suggest that two different pathways operate. In order to precisely determine the actual involvement of each of the three premutagenic lesions that may form in the NarI site in the course of the mutational process, we designed a single adduct mutagenesis experiment, and found that AAF binding to the G3 induced only a -2 frameshift mutation event. This result will be discussed in terms of local DNA conformation.

Minor-groove binding models for acetylaminofluorene modified DNA

Minimized potential energy calculations have been employed to locate and evaluate energetically a number of different models for DNA modified at carbon-8 of guanine by acetylaminofluorene (AAF). Three different duplex nonamer sequences were investigated. In addition to syn guanine models which have some denaturation and a Z-DNA model, we have found two new types of structures in which guanine remains syn and the AAF is placed in the minor groove of a B-DNA helix. One type features Hoogsteen base pairing between the modified guanine and protonated cytosine, with a sharply bent helix. The other (here termed the "wedge" model because the aromatic amine is wedged into the minor groove) maintains a single hydrogen bond between O6 of the modified guanine and N3 of protonated cytosine, with much less deformation of the helix, and close Van der Waals contacts between the AAF and the walls of the minor groove. Both types of structures (as well as the related forms produced by deprotonation of cytosine) are energetically important in all three sequences examined. The wedge-type model, which is most favored except in alternating G-C sequences, has been previously observed in a combined NMR and computational characterization of an aminofluorene (AF) modified guanine opposite adenine in a DNA duplex undecamer (D. Norman, P. Abuaf, B.E. Hingerty, D. Live, D. Grunberger, S. Broyde and D.J. Patel, Biochemistry 28, 7462 (1989)).

Genetic effects of thymine glycol: site-specific mutagenesis and molecular modeling studies

The mutational specificity and genetic requirements for mutagenesis by 5,6-dihydroxy-5,6-dihydrothymine (thymine glycol), one of the principal DNA lesions induced by oxidation and ionizing radiation, has been investigated in Escherichia coli. Thymine glycol was positioned at a unique site in the single-stranded genome of a bacteriophage M13mp19 derivative. Replication of the genome in E. coli yielded targeted mutations at a frequency of 0.3%; the mutations were exclusively T----C. Mutagenesis was independent of SOS and nth (nth encodes endonuclease III, a thymine glycol repair enzyme). The adduct was not detectably mutagenic in duplex DNA. A chemical rationalization for the mutation observed for thymine glycol was developed by applying molecular modeling and molecular mechanical calculations to the same DNA sequence studied in vivo. Modeling suggested that the 5R,6S isomer of cis-thymine glycol, when not base paired, was displaced laterally by approximately 0.5 A toward the major groove in comparison to the position that thymine would otherwise occupy. This perturbation of DNA structure should increase the likelihood of a guanine.thymine glycol wobble base pair during replication, which would explain the mutational specificity of the base observed in the genetic experiments.

Translesion synthesis is the main component of SOS repair in bacteriophage lambda DNA

Agents that interfere with DNA replication in Escherichia coli induce physiological adaptations that increase the probability of survival after DNA damage and the frequency of mutants among the survivors (the SOS response). Such agents also increase the survival rate and mutation frequency of irradiated bacteriophage after infection of treated bacteria, a phenomenon known as Weigle reactivation. In UV-irradiated single-stranded DNA phage, Weigle reactivation is thought to occur via induced, error-prone replication through template lesions (translesion synthesis [P. Caillet-Fauquet, M: Defais, and M. Radman, J. Mol. Biol. 117:95-112, 1977]). Weigle reactivation occurs with higher efficiency in double-stranded DNA phages such as lambda, and we therefore asked if another process, recombination between partially replicated daughter molecules, plays a major role in this case. To distinguish between translesion synthesis and recombinational repair, we studied the early replication of UV-irradiated bacteriophage lambda in SOS-induced and uninduced bacteria. To avoid complications arising from excision of UV lesions, we used bacterial uvrA mutants, in which such excision does not occur. Our evidence suggests that translesion synthesis is the primary component of Weigle reactivation of lambda phage in the absence of excision repair. The greater efficiency in Weigle reactivation of double-stranded DNA phage could thus be attributed to some inducible excision repair unable to occur on single-stranded DNA. In addition, after irradiation, lambda phage replication seems to switch prematurely from the theta mode to the rolling circle mode.

DNA base changes and RNA levels in N-acetoxy-2-acetylaminofluorene-induced dihydrofolate reductase mutants of Chinese hamster ovary cells

Formerly, we isolated a series of dihydrofolate reductase-deficient Chinese hamster ovary cell mutants that were induced by N-acetoxy-2-acetylaminofluorene. Deletions and complex gene rearrangements were detected in 28% of these mutants; 72% contained putative point mutations. In the present study, we have localized the putative point mutations in the 25,000 base dhfr gene by RNase heteroduplex mapping. Assignment of a position for each mutation was successful in 16 of 19 mutants studied. We cloned DNA fragments containing the mapped mutations from nine mutants into a bacteriophage lambda vector. In the case of 11 other mutants, DNA was amplified by the polymerase chain reaction procedure. Sequence analysis of cloned and amplified DNA confirmed the presence of point mutations. Most mutants (90%) carried base substitutions; the rest contained frameshift mutations. Of the point mutations, 75% were G.C to T.A transversions in either the dhfr coding sequence or at splice sites; transition G.C to A.T mutations were found in two mutants (10%). In one of these transition mutants, the base substitution occurred at the fifth base of the third intron. Of the frameshift mutations, one was a deletion of G.C pair and the other was an insertion of an A.T pair. Of the mapped mutants, 38% exhibited greatly reduced (approximately 10-fold) steady-state levels of dhfr mRNA. All eight sequenced mutants displaying this phenotype contained premature chain termination codons. Normal levels of dhfr mRNA were observed in five missense mutants and in five mutants carrying nonsense codons in the translated portion of exon VI. Taken together with the results of other mutagens at this locus, we conclude that the low dhfr mRNA phenotype is correlated with the presence of nonsense codons in exons II to V but not in the last exon of the dhfr gene.

Single adduct mutagenesis: strong effect of the position of a single acetylaminofluorene adduct within a mutation hot spot

2-Acetylaminofluorene (AAF), a potent rat liver carcinogen that binds covalently to the C-8 position of guanine residues in DNA, is an effective frameshift mutagen. The mutations are distributed nonrandomly, in that most are located at a few specific DNA sequences (i.e., mutation hot spots). Among these hot spots, the Nar I sequence (GGCGCC) is especially susceptible to the induction of -2 frameshift mutations (GGCGCC----GGCC). Due to the nature of the Nar I sequence, G1G2CG3CC, three different molecular events, each involving the deletion of two contiguous base pairs (i.e., G2C, CG3, G3C), can give rise to the observed end point (GGCC). To compare the potential role of each of the three possible guanine-AAF adducts in the Nar I site to induce the -2 frameshift mutation, we constructed double-stranded plasmid molecules containing a single-AAF adduct bound to one of the three guanine positions. Using these plasmids, we found that only the adduct in the G3 position induces the -2 frameshift mutation. This strong effect of the position of the -AAF adduct within the Nar I site is discussed in relation to the possible involvement of an unusual DNA conformation in the mutagenic processing.

Construction of plasmids containing a unique acetylaminofluorene adduct located within a mutation hot spot. A new probe for frameshift mutagenesis

N-2-acetylaminofluorene (AAF), a potent rat liver carcinogen, binds primarily to the C-8 position of guanine residues. In a bacterial forward mutation assay, more than 90% of the mutations induced by -AAF adducts are frameshift mutations located at specific sites: the so-called mutation hot spots. We are particularly interested in a class of -2 frameshift mutations occurring within a specific sequence, the NarI sequence. The NarI site, GGCGCC, contains three guanine residues that are approximately equally reactive toward -AAF substitution. To study further the mechanism by which mutations are induced by -AAF adducts at this site, we designed a new plasmid probe. In this paper we describe the construction and the effectiveness of this probe, pSM14, which provides a simple phenotypic test for detecting frameshift mutations within the NarI site. The construction and the characterization of plasmids with a single -AAF adduct in each of the three positions of the NarI site are also described. The strategy of construction that was used involves the ligation of oligonucleotides containing a single adduct in a NarI site into a gapped-duplex pSM14 plasmid. Plasmids that have successfully integrated the oligonucleotides by ligation at both the 5' and the 3' ends were purified by centrifugation on CsCl gradients. These constructs have been used in single adduct mutation studies.

Analysis of single-stranded DNA stability and damage-induced strand loss in mammalian cells using SV40-based shuttle vectors

The fate and stability of fully or partially single-stranded DNA molecules transfected into mammalian cells have been analysed. For this, we constructed a simian virus 40 (SV40)-based shuttle vector containing the f1 bacteriophage replication origin in the two possible orientations (pi SVF1-A and pi SVF1-B). This vector contains the SV40 origin of replication, the late viral genes and DNA sequences for replication and selection in Escherichia coli. It also carries the lacO sequence, which permits the analysis of plasmid stability. Single-stranded DNA from pi SVF1-A and pi SVF1-B were produced in bacteria and annealed in vitro to form a heteroduplex molecule. We showed that, in monkey kidney COS7 cells, single-stranded vectors replicate to form duplex molecules. After transfection of the three forms of molecules (single-stranded, heteroduplex or double-stranded), replicated DNA was rescued in E. coli. Vector stability was analysed by checking for plasmid rearrangements and screening for lacO mutants. The single-stranded pi SVF1 has a lower rearrangement level, while the spontaneous mutation frequency (on the lacO target) is in the same range as for the double-stranded vector. In contrast, the level of spontaneous mutagenesis is higher for the heteroduplex than for the single- and double-stranded forms. In addition, we found that replication of heteroduplex with one strand containing ultraviolet light-induced lesions yields progeny molecules in which the irradiated strand is mostly lost. This result indicates for the first time the specific loss of the damaged strand in mammalian cells.

Genetic control of AAF-induced mutagenesis at alternating GC sequences: an additional role for RecA

In a previous study, the forward mutation spectrum induced by the chemical carcinogen N-acetoxy-N-2-acetylaminofluorene was determined (Koffel-Schwartz et al. 1984). It was found that 90% of the induced mutations are frameshift mutations located within specific sequences (mutation hot spots). Two classes of mutation hot spots were found: (i) -1 frameshift mutations occurring within runs of guanines (i.e. GGGG----GGG; (ii) -2 frameshift mutations occurring within the NarI recognition sequence (GGCGCC----GGCC). In the present work, we further investigate the genetic requirements of these frameshift events by using specific reversion assays. Like UV-induced mutagenesis, frameshift mutations occurring within runs of G's (also referred to as the "slippage pathway") require the activated form of the RecA protein (RecA*). On the other hand, frameshift mutations occurring at the NarI site (the "NarI mutation pathway") require a LexA-controlled function(s) that is not UmuDC. The LexA-controlled gene(s) that is (are) involved in this pathway remain to be identified. Moreover, this pathway does not require RecA* for the proteolytic processing of a protein other than LexA (like the cleavage of UmuD in UV-induced mutagenesis). An "additional" role of RecA can be defined as follows: (i) The non-activated form of the RecA protein acts as an inhibitor in the NarI mutation pathway. (ii) This inhibition is relieved upon activation of RecA by UV irradiation of the bacteria. (iii) A recA deletion mutant is totally proficient in the NarI mutation pathway provided the SOS system is derepressed [lexA (Def) allele]. Therefore, RecA does not actively participate in the fixation of the mutation. A molecular model for this "additional" role of RecA is proposed.

Targeted mutations induced by a single acetylaminofluorene DNA adduct in mammalian cells and bacteria

Mutagenic specificity of 2-acetylaminofluorene (AAF) has been established in mammalian cells and several strains of bacteria by using a shuttle plasmid vector containing a single N-(deoxyguanosin-8-yl)acetylaminofluorene (C8-dG-AAF) adduct. The nucleotide sequence of the gene conferring tetracycline resistance was modified by conservative codon replacement so as to accommodate the sequence d(CCTTCGCTAC) flanked by two restriction sites, Bsm I and Xho I. The corresponding synthetic oligodeoxynucleotide underwent reaction with 2-(N-acetoxy-N-acetylamino)-fluorene (AAAF), forming a single dG-AAF adduct. This modified oligodeoxynucleotide was hybridized to its complementary strand and ligated between the Bsm I and Xho I sites of the vector. Plasmids containing the C8-dG-AAF adduct were used to transfect simian virus 40-transformed simian kidney (COS-1) cells and to transform several AB strains of Escherichia coli. Colonies containing mutant plasmids were detected by hybridization to 32P-labeled oligodeoxynucleotides. Presence of the single DNA adduct increased the mutation frequency by 8-fold in both COS cells and E. coli. Over 80% of mutations detected in both systems were targeted and represented G.C----C.G or G.C----T.A transversions or single nucleotide deletions. We conclude that modification of a deoxyguanosine residue with AAF preferentially induces mutations targeted at this site when a plasmid containing a single C8-dG-AAF adduct is introduced into mammalian cells or bacteria.

Spectrum of cisplatin-induced mutations in Escherichia coli

Using a forward-mutation assay based on the inactivation of the tetracycline-resistance gene located on plasmid pBR322, we have determined the mutation spectrum induced in Escherichia coli by cisplatin [cis-diamminedichloroplatinum(II)], a widely used antitumor drug. Cisplatin is known to form mainly intrastrand diadducts at ApG and GpG sites. We found that cisplatin efficiently induces mutations in an SOS-dependent way (i.e., dependent upon UV irradiation of the host bacteria). More than 90% of the mutations are single-base-pair substitutions occurring at the potential sites of cisplatin adducts (ApG and GpG). Taking into account the relative proportions of ApG and GpG adducts, we found that the ApG adducts are at least 5 times more mutagenic than the GpG adducts. Moreover, a strong mutation specificity was seen at the 5' side of the ApG adducts (A X T----T X A transversions). The observation that most mutations occur at the 5' end of the adduct at both ApG and GpG sites is discussed in relation to recent structural data.