A umuDC-independent SOS pathway for frameshift mutagenesis

Interactions and Localization of Escherichia coli Error-Prone DNA Polymerase IV after DNA Damage

Escherichia coli's DNA polymerase IV (Pol IV/DinB), a member of the Y family of error-prone polymerases, is induced during the SOS response to DNA damage and is responsible for translesion bypass and adaptive (stress-induced) mutation. In this study, the localization of Pol IV after DNA damage was followed using fluorescent fusions. After exposure of E. coli to DNA-damaging agents, fluorescently tagged Pol IV localized to the nucleoid as foci. Stepwise photobleaching indicated ∼60% of the foci consisted of three Pol IV molecules, while ∼40% consisted of six Pol IV molecules. Fluorescently tagged Rep, a replication accessory DNA helicase, was recruited to the Pol IV foci after DNA damage, suggesting that the in vitro interaction between Rep and Pol IV reported previously also occurs in vivo. Fluorescently tagged RecA also formed foci after DNA damage, and Pol IV localized to them. To investigate if Pol IV localizes to double-strand breaks (DSBs), an I-SceI endonuclease-mediated DSB was introduced close to a fluorescently labeled LacO array on the chromosome. After DSB induction, Pol IV localized to the DSB site in ∼70% of SOS-induced cells. RecA also formed foci at the DSB sites, and Pol IV localized to the RecA foci. These results suggest that Pol IV interacts with RecA in vivo and is recruited to sites of DSBs to aid in the restoration of DNA replication.

IMPORTANCE

DNA polymerase IV (Pol IV/DinB) is an error-prone DNA polymerase capable of bypassing DNA lesions and aiding in the restart of stalled replication forks. In this work, we demonstrate in vivo localization of fluorescently tagged Pol IV to the nucleoid after DNA damage and to DNA double-strand breaks. We show colocalization of Pol IV with two proteins: Rep DNA helicase, which participates in replication, and RecA, which catalyzes recombinational repair of stalled replication forks. Time course experiments suggest that Pol IV recruits Rep and that RecA recruits Pol IV. These findings provide in vivo evidence that Pol IV aids in maintaining genomic stability not only by bypassing DNA lesions but also by participating in the restoration of stalled replication forks.

Physiology of the read-write genome

Discoveries in cytogenetics, molecular biology, and genomics have revealed that genome change is an active cell-mediated physiological process. This is distinctly at variance with the pre-DNA assumption that genetic changes arise accidentally and sporadically. The discovery that DNA changes arise as the result of regulated cell biochemistry means that the genome is best modelled as a read-write (RW) data storage system rather than a read-only memory (ROM). The evidence behind this change in thinking and a consideration of some of its implications are the subjects of this article. Specific points include the following: cells protect themselves from accidental genome change with proofreading and DNA damage repair systems; localized point mutations result from the action of specialized trans-lesion mutator DNA polymerases; cells can join broken chromosomes and generate genome rearrangements by non-homologous end-joining (NHEJ) processes in specialized subnuclear repair centres; cells have a broad variety of natural genetic engineering (NGE) functions for transporting, diversifying and reorganizing DNA sequences in ways that generate many classes of genomic novelties; natural genetic engineering functions are regulated and subject to activation by a range of challenging life history events; cells can target the action of natural genetic engineering functions to particular genome locations by a range of well-established molecular interactions, including protein binding with regulatory factors and linkage to transcription; and genome changes in cancer can usefully be considered as consequences of the loss of homeostatic control over natural genetic engineering functions.

Biochemical basis for the essential genetic requirements of RecA and the beta-clamp in Pol V activation

In Escherichia coli, it is genetically well established that the beta-clamp and RecA are essential cofactors that endow DNA polymerase (Pol) V with lesion bypass activity. However, the biochemical basis for these requirements is still largely unknown. Because the process of translesion synthesis (TLS) requires that the specialized DNA polymerase synthesize in a single binding event a TLS patch that is long enough to resist external proofreading, it is critical to monitor Pol V burst synthesis. Here, we dissect the distinct roles that RecA and the beta-clamp perform during the Pol V activation process using physiologically relevant long single-stranded template DNA, similar to those used in genetic assays. Our data show that the beta-clamp endows the complex between Pol V and the template DNA with increased stability. Also, the RecA filament formed in cis on the single-stranded DNA produced downstream from the lesion stretches the template DNA to allow smooth elongation of the nascent strand by Pol V. The concurrent action of both cofactors is required for achieving productive TLS events. The present article presents an integrated view of TLS under physiologically relevant conditions in E. coli that may represent a paradigm for lesion bypass in other organisms.

Interplay among replicative and specialized DNA polymerases determines failure or success of translesion synthesis pathways

Living cells possess a panel of specialized DNA polymerases that deal with the large diversity of DNA lesions that occur in their genomes. How specialized DNA polymerases gain access to the replication intermediate in the vicinity of the lesion is unknown. Using a model system in which a single replication blocking lesion can be bypassed concurrently by two pathways that leave distinct molecular signatures, we analyzed the complex interplay among replicative and specialized DNA polymerases. The system involves a single N-2-acetylaminofluorene guanine adduct within the NarI frameshift hot spot that can be bypassed concurrently by Pol II or Pol V, yielding a -2 frameshift or an error-free bypass product, respectively. Reconstitution of the two pathways using purified DNA polymerases Pol III, Pol II and Pol V and a set of essential accessory factors was achieved under conditions that recapitulate the known in vivo requirements. With this approach, we have identified the key replication intermediates that are used preferentially by Pol II and Pol V, respectively. Using single-hit conditions, we show that the beta-clamp is critical by increasing the processivity of Pol II during elongation of the slipped -2 frameshift intermediate by one nucleotide which, surprisingly, is enough to support subsequent elongation by Pol III rather than degradation. Finally, the proofreading activity of the replicative polymerase prevents the formation of a Pol II-mediated -1 frameshift product. In conclusion, failure or success of TLS pathways appears to be the net result of a complex interplay among DNA polymerases and accessory factors.

Theoretical analysis of mutation hotspots and their DNA sequence context specificity

Mutation frequencies vary significantly along nucleotide sequences such that mutations often concentrate at certain positions called hotspots. Mutation hotspots in DNA reflect intrinsic properties of the mutation process, such as sequence specificity, that manifests itself at the level of interaction between mutagens, DNA, and the action of the repair and replication machineries. The hotspots might also reflect structural and functional features of the respective DNA sequences. When mutations in a gene are identified using a particular experimental system, resulting hotspots could reflect the properties of the gene product and the mutant selection scheme. Analysis of the nucleotide sequence context of hotspots can provide information on the molecular mechanisms of mutagenesis. However, the determinants of mutation frequency and specificity are complex, and there are many analytical methods for their study. Here we review computational approaches for analyzing mutation spectra (distribution of mutations along the target genes) that include many mutable (detectable) positions. The following methods are reviewed: derivation of a consensus sequence, application of regression approaches to correlate nucleotide sequence features with mutation frequency, mutation hotspot prediction, analysis of oligonucleotide composition of regions containing mutations, pairwise comparison of mutation spectra, analysis of multiple spectra, and analysis of "context-free" characteristics. The advantages and pitfalls of these methods are discussed and illustrated by examples from the literature. The most reliable analyses were obtained when several methods were combined and information from theoretical analysis and experimental observations was considered simultaneously. Simple, robust approaches should be used with small samples of mutations, whereas combinations of simple and complex approaches may be required for large samples. We discuss several well-documented studies where analysis of mutation spectra has substantially contributed to the current understanding of molecular mechanisms of mutagenesis. The nucleotide sequence context of mutational hotspots is a fingerprint of interactions between DNA and DNA repair, replication, and modification enzymes, and the analysis of hotspot context provides evidence of such interactions.

Frameshift mutations induced by three classes of acridines in the lacZ reversion assay in Escherichia coli: potency of responses and relationship to slipped mispairing models

The frameshift mutagenicity of 9-aminoacridine (9AA) was compared with that of quinacrine, the acridine mustards ICR-191 and quinacrine mustard (QM), and the nitroacridine Entozon in the lacZ reversion assay in Escherichia coli. As intercalating agents, 9AA and quinacrine cause mutations through noncovalent associations with DNA. Mustards and nitroacridines form covalent adducts in DNA and give rise to different spectra of mutations. Quinacrine and 9AA most effectively induced -1 frameshifts in a run of guanine residues, with 9AA being the more potent mutagen. They also induced +G frameshifts. The acridine mustard ICR-191 was a stronger mutagen than 9AA, owing largely to its potent induction of +G frameshifts. QM induced +G frameshifts more strongly than did its nonreactive counterpart quinacrine. The nitroacridine Entozon differed from the other acridines in being a potent inducer of -2 frameshifts, but it was less effective in inducing +/-1 frameshifts. Quinacrine, although a simple intercalator, induced all five kinds of frameshift mutations detected in the assay, as did the acridine mustards. Although +A and -A frameshifts were induced, adenine runs were less susceptible to acridine mutagenesis than guanine runs. The patterns of frameshift mutagenicity in the lacZ assay are similar to those in an assay based on the reversion of mutations in the tetracycline-resistance gene of the plasmid pBR322. The similarity suggests that the responses reflect the inherent bacterial mutagenicity of the compounds in the local sequence context and are not highly dependent on the broader sequence context. The results are interpreted with respect to slipped mispairing models of frameshift mutagenesis.

Genetics of mutagenesis in E. coli: various combinations of translesion polymerases (Pol II, IV and V) deal with lesion/sequence context diversity

The biochemistry and genetics of translesion synthesis (TLS) and, as a consequence, of mutagenesis has recently received much attention in view of the discovery of novel DNA polymerases, most of which belong to the Y family. These distributive and low fidelity enzymes assist the progression of the high fidelity replication complex in the bypass of DNA lesions that normally hinder its progression. The present paper extends our previous observation that in Escherichia coli all three SOS-inducible DNA polymerases (Pol II, IV and V) are involved in TLS and mutagenesis. The genetic control of frameshift mutation pathways induced by N-2-acetylaminofluorene (AAF) adducts or by oxidative lesions induced by methylene blue and visible light is investigated. The data show various examples of mutation pathways with an absolute requirement for a specific combination of DNA polymerases and, in contrast, other examples where two DNA polymerases exhibit functional redundancy within the same pathway. We suggest that cells respond to the challenge of replicating DNA templates potentially containing a large diversity of DNA lesions by using a pool of accessory DNA polymerases with relaxed specificities that assist the high fidelity replicase.

Induction of -2 frameshift mutations by 2-nitrofluorene, N-hydroxyacetylaminofluorene, and N-2-acetylaminofluorene in reversion assays in Escherichia coli strains differing in permeability and acetyltransferase activity

The mutagenicity of 2-nitrofluorene (NF), N-hydroxyacetylaminofluorene (N-OH-AAF), and N-2-acetylaminofluorene (AAF) was measured in strains of Escherichia coli that contain a lacZ allele that reverts by -2 frameshift mutations from CG(5) to CG(4). Mutagenesis was compared in a strain having wild-type permeability and metabolism, a strain with increased permeability caused by a lipopolysaccharide-defective (LPS(d)) mutation, a strain with N- and O-acetyltransferase (NAT/OAT) activity conferred by the Salmonella nat gene on plasmid pYG219, and a strain carrying both an LPS(d) mutation and pYG219. The LPS(d) mutation facilitated the measurement of mutagenicity but was not absolutely required, in that lower levels of mutagenicity were detected in LPS(+) strains. The NAT/OAT activity conferred by pYG219 strongly potentiated the mutagenicity of NF and N-OH-AAF. Surprisingly, AAF was mutagenic in the NAT/OAT LPS(d) strain without an exogenous P450 metabolic activation system. Its activity may be ascribable to the detection of a directly mutagenic impurity by the highly sensitive strain or to a low level of metabolic activation by the bacteria under the assay conditions. The findings add to the evidence that the lacZ allele derived from E. coli strain CC109 is an effective indicator of -2 frameshift mutagenesis and that strains expressing high levels of NAT/OAT activity are highly sensitive in monitoring the mutagenicity of nitroarenes and aromatic amides.

All three SOS-inducible DNA polymerases (Pol II, Pol IV and Pol V) are involved in induced mutagenesis

Most organisms contain several members of a recently discovered class of DNA polymerases (umuC/dinB superfamily) potentially involved in replication of damaged DNA. In Escherichia coli, only Pol V (umuDC) was known to be essential for base substitution mutagenesis induced by UV light or abasic sites. Here we show that, depending upon the nature of the DNA damage and its sequence context, the two additional SOS-inducible DNA polymerases, Pol II (polB) and Pol IV (dinB), are also involved in error-free and mutagenic translesion synthesis (TLS). For example, bypass of N:-2-acetylaminofluorene (AAF) guanine adducts located within the NAR:I mutation hot spot requires Pol II for -2 frameshifts but Pol V for error-free TLS. On the other hand, error-free and -1 frameshift TLS at a benzo(a)pyrene adduct requires both Pol IV and Pol V. Therefore, in response to the vast diversity of existing DNA damage, the cell uses a pool of 'translesional' DNA polymerases in order to bypass the various DNA lesions.

Escherichia coli DNA polymerase IV mutator activity: genetic requirements and mutational specificity

The dinB gene of Escherichia coli is known to be involved in the untargeted mutagenesis of lambda phage. Recently, we have demonstrated that this damage-inducible and SOS-controlled gene encodes a novel DNA polymerase, DNA Pol IV, which is able to dramatically increase the untargeted mutagenesis of F' plasmid. At the amino acid level, DNA Pol IV shares sequence homologies with E. coli UmuC (DNA Pol V), Rev1p, and Rad30p (DNA polymerase eta) of Saccharomyces cerevisiae and human Rad30A (XPV) proteins, all of which are involved in translesion DNA synthesis. To better characterize the Pol IV-dependent untargeted mutagenesis, i.e., the DNA Pol IV mutator activity, we analyzed the genetic requirements of this activity and determined the forward mutation spectrum generated by this protein within the cII gene of lambda phage. The results indicated that the DNA Pol IV mutator activity is independent of polA, polB, recA, umuDC, uvrA, and mutS functions. The analysis of more than 300 independent mutations obtained in the wild-type or mutS background revealed that the mutator activity clearly promotes single-nucleotide substitutions as well as one-base deletions in the ratio of about 1:2. The base changes were strikingly biased for substitutions toward G:C base pairs, and about 70% of them occurred in 5'-GX-3' sequences, where X represents the base (T, A, or C) that is mutated to G. These results are discussed with respect to the recently described biochemical characteristics of DNA Pol IV.

Lesions in DNA: hurdles for polymerases

Translesion synthesis (TLS) is one of the DNA damage tolerance strategies, which have evolved to enable organisms to replicate their genome despite the presence of unrepaired damage. The process of TLS has the propensity to produce mutations, a potential origin of cancer, and is therefore of medical interest. Significant progress in our understanding of TLS has come primarily from studies of the bacterium Escherichia coli, the budding yeast Saccharomyces cerevisiae and, more recently, human cells. Results from these analyses indicate that the fundamental mechanism of TLS and the proteins involved have been conserved throughout evolution from bacteria to humans.

SOS mutagenesis results from up-regulation of translesion synthesis

Irradiation of DNA with ultraviolet light generates a variety of photolesions. Among them, are cyclobutane pyrimidine dimers (CPD) and (6-4) photoproducts blocking lesions that interfere with DNA replication if left unrepaired. In addition to efficient pre-replicative excision repair mechanisms, cells have evolved damage tolerance pathways enabling them to replicate lesion-containing DNA molecules either by directly replicating through the damaged base (translesion synthesis, TLS) or by employing the locally undamaged complementary strand thus avoiding the lesion (damage avoidance pathways, DA). Using double-stranded vectors with a single T(6-4)T UV lesion and a strand segregation analysis (SSA), we have measured the relative utilization of the two tolerance pathways (TLS and DA) in Escherichia coli. During the SOS response the error-prone TLS pathway is strongly stimulated ( approximately 20-fold) at the expense of the error-free DA pathways. Thus, up-regulation of TLS may turn out to be a general property of the SOS response; a similar conclusion was previously reached with the frameshift-inducing N-2-acetylaminofluorene adduct. Therefore, as far as its contribution to damaged DNA replication is concerned, the SOS response appears to be an induced mutator state rather than a survival strategy. Depending on the base inserted opposite the lesion, TLS can be error-free or mutagenic. In a wild-type strain, both forms of TLS are increased to a similar extent during the SOS response. In contrast, in a DeltaumuDC strain induction of TLS is totally abolished, demonstrating that the UmuDC proteins usually thought to be specifically involved in mutagenesis facilitate the recovery of both error-free and mutagenic replication intermediates in vivo.

Replication of damaged DNA: molecular defect in xeroderma pigmentosum variant cells

Individuals with Xeroderma pigmentosum (XP) syndrome have a genetic predisposition to sunlight-induced skin cancer. Genetically different forms of XP have been identified by cell fusion. Cells of individuals expressing the classical form of XP (complementation groups A through G) are deficient in the nucleotide excision repair (NER) pathway. In contrast, the cells belonging to the variant class of XP (XPV) are NER-proficient and are only slightly more sensitive than normal cells to the killing action of UV light radiation. The XPV fibroblasts replicate damaged DNA generating abnormally short fragments either in vivo [A.R. Lehmann, The relationship between pyramidine dimers and replicating DNA in UV-irradiated human fibroblasts, Nucleic Acids Res. 7 (1979) 1901-1912; S.D. Park, J.E. Cleaver, Postreplication repair: question of its definition and possible alteration in Xeroderma pigmentosum cell strains, Proc. Natl. Acad. Sci. U.S.A. 76 (1979) 3927-3931.] or in vitro [S.M. Cordeiro, L.S. Zaritskaya, L.K. Price, W.K. Kaufmann, Replication fork bypass of a pyramidine dimer blocking leading strand DNA synthesis, J. Biol. Chem. 272 (1997) 13945-13954; D.L. Svoboda, L.P. Briley, J.M. Vos, Defective bypass replication of a leading strand cyclobutane thymine dimer in Xeroderma pigmentosum variant cell extracts, Cancer Res. 58 (1998) 2445-2448; I. Ensch-Simon, P.M. Burgers, J.S. Taylor, Bypass of a site-specific cis-syn thymine dimer in an SV40 vector during in vitro replication by HeLa and XPV cell-free extracts, Biochemistry 37 (1998) 8218-8226.], suggesting that in XPV cells, replication has an increased probability of being blocked at a lesion. Furthermore, extracts from XPV cells were found to be defective in translesion synthesis [A. Cordonnier, A.R. Lehmann, R.P.P. Fuchs, Impaired translesion synthesis in Xeroderma pigmentosum variant extracts, Mol. Cell. Biol. 19 (1999) 2206-2211.]. Recently, Masutani et al. [C. Masutani, M. Araki, A. Yamada, R. Kusomoto, T. Nogimori, T. Maekawa, S. Iwai, F. Hanaoka, Xeroderma pigmentosum variant (XP-V) correcting protein from HeLa cells has a thymine dimer bypass DNA polymerase activity, EMBO J. 18 (1999) 3491-3501.] have shown that the XPV defect can be corrected by a novel human DNA polymerase, homologue to the yeast DNA polymerase eta, which is able to replicate past cyclobutane pyrimidine dimers in DNA templates. This review focuses on our current understanding of translesion synthesis in mammalian cells whose defect, unexpectedly, is responsible for the hypermutability of XPV cells and for the XPV pathology.

Distinct roles for Rev1p and Rev7p during translesion synthesis in Saccharomyces cerevisiae

Translesion synthesis (TLS) in Saccharomyces cerevisiae requires at least Rev1p and polymerase zeta (Pol zeta), a complex of the Rev3 polymerase and its accessory factor Rev7p. Although their precise role(s) are poorly characterized, in vitro studies suggest that each protein contributes to TLS in a manner dependent on the particular lesion and surrounding DNA sequence. In the present study, strand segregation analysis is used to attempt to identify the role(s) of the Rev1 and Rev7 proteins during TLS. This assay uses double-stranded plasmids containing a genetic marker opposite to a replication blocking lesion (N-2-acetylaminofluorene; AAF) to measure TLS quantitatively and qualitatively in vivo. The AAF adduct is localized within a repetitive sequence in a manner that allows the formation of misaligned primer-template replication intermediates. Elongation from a misaligned intermediate fixes a frameshift mutation (slipped TLS), while extension of the correctly aligned lesion terminus yields error-free (non-slipped) TLS. The results indicate that there is a strong requirement for Rev7p during Pol zeta-mediated TLS measured in vivo. Furthermore, Rev1p is needed only for non-slipped TLS; slipped TLS remains efficient in its absence, revealing a previously uncharacterized Rev1p activity similar to Escherichia coli UmuDC function. Specifically, this activity is required for elongation from a correctly aligned lesion terminus.

Sequence-dependent modulation of frameshift mutagenesis at NarI-derived mutation hot spots

The NarI sequence is known to be the strongest mutation hot spot for induced frameshift mutagenesis. Indeed, a single N-2-acetylaminofluorene (AAF) adduct induces -2 frameshift mutations (5'-GGCGAAFCC--> 5'-GGCC) more than 10(7)-fold over background mutagenesis in Escherichia coli. The mechanism of induction of the frameshift mutation involves a two nucleotide primer-template misalignment event during replication of the adduct-containing sequence. The slipped mutagenic intermediate (SMI) that is thus formed is strongly stabilised by the AAF residue. In order to understand the origin of the extreme susceptibility of this sequence to frameshift mutagenesis, we analysed AAF-induced mutagenesis at sequences 5'-NaGCGAAFCNb-3' containing the core dinucleotide GCGC repeat present in the NarI sequence flanked by variable nucleotides Na and Nb. The nature of nucleotide Nb was found to strongly modulate the frequency of induced -2 frameshift mutagenesis (up to 30 to 50-fold), while little if any effect could be attributed to nucleotide Na. The induction of -2 frameshifts, regardless of nucleotides Na and Nb, was found to be SOS-inducible but umuDC-independent as previously found for the authentic NarI sequence. The NarI sequence (GGCGCC) and sequence TGCGCA (Na=T, Nb=A) were found to be equally "hot" for -2 frameshift mutation induction compared to the sequence AGCGCT where induced mutagenesis was 30 to 50-fold lower.The analysis of replication events using constructions containing a strand marker across from the adduct site allowed us to demonstrate that the large difference in -2 frameshift mutagenesis is due to an intrinsic difference in the propensity of these sequences to slip during replication. How the nature of the nucleotide flanking the adduct on its 3'-side (Nb) differentially stabilises the SMI will be discussed in the light of recent structural data and theoretical models.

Inactivation of DNA proofreading obviates the need for SOS induction in frameshift mutagenesis

Translesion synthesis at replication-blocking lesions requires the induction of proteins that are controlled by the SOS system in Escherichia coli. Of the proteins identified so far, UmuD', UmuC, and RecA* were shown to facilitate replication across UV-light-induced lesions, yielding both error-free and mutagenic translesion-synthesis products. Similar to UV lesions, N-2-acetylaminofluorene (AAF), a chemical carcinogen that forms covalent adducts at the C8 position of guanine residues, is a strong replication-blocking lesion. Frameshift mutations are induced efficiently by AAF adducts when located within short repetitive sequences in a two-step mechanism; AAF adducts incorporate a cytosine across from the lesion and then form a primer-template misaligned intermediate that, upon elongation, yields frameshift mutations. Recently, we have shown that although elongation from the nonslipped intermediate depends on functional umuDC+ gene products, elongation from the slipped intermediate is umuDC+-independent but requires another, as yet biochemically uncharacterized, SOS function. We now show that in DNA Polymerase III-proofreading mutant strains (dnaQ49 and mutD5 strains), elongation from the slipped intermediate is highly efficient in the absence of SOS induction-in contrast to elongation from the nonslipped intermediate, which still requires UmuDC functions.

Single-strand DNA-specific exonucleases in Escherichia coli. Roles in repair and mutation avoidance

Mutations in the genes encoding single-strand DNA-specific exonucleases (ssExos) of Escherichia coli were examined for effects on mutation avoidance, UV repair, and conjugational recombination. Our results indicate complex and partially redundant roles for ssExos in these processes. Although biochemical experiments have implicated RecJ exonuclease, Exonuclease I (ExoI), and Exonuclease VII (ExoVII) in the methyl-directed mismatch repair pathway, the RecJ- ExoI- ExoVII- mutant did not exhibit a mutator phenotype in several assays for base substitution mutations. If these exonucleases do participate in mismatch excision, other exonucleases in E. coli can compensate for their loss. Frameshift mutations, however, were stimulated in the RecJ- ExoI- ExoVII- mutant. For acridine-induced frameshifts, this mutator effect was due to a synergistic effect of ExoI- and ExoVII- mutations, implicating both ExoI and ExoVII in avoidance of frameshift mutations. Although no single exonuclease mutant was especially sensitive to UV irradiation, the RecJ- ExoVII- double mutant was extremely sensitive. The addition of an ExoI- mutation augmented this sensitivity, suggesting that all three exonucleases play partially redundant roles in DNA repair. The ability to inherit genetic markers by conjugation was reduced modestly in the ExoI- RecJ- mutant, implying that the function of either ExoI or RecJ exonucleases enhances RecBCD-dependent homologous recombination.

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.

Multiple pathways for SOS-induced mutagenesis in Escherichia coli: an overexpression of dinB/dinP results in strongly enhancing mutagenesis in the absence of any exogenous treatment to damage DNA

dinP is an Escherichia coli gene recently identified at 5.5 min of the genetic map, whose product shows a similarity in amino acid sequence to the E. coli UmuC protein involved in DNA damage-induced mutagenesis. In this paper we show that the gene is identical to dinB, an SOS gene previously localized near the lac locus at 8 min, the function of which was shown to be required for mutagenesis of nonirradiated lambda phage infecting UV-preirradiated bacterial cells (termed lambdaUTM for lambda untargeted mutagenesis). A newly constructed dinP null mutant exhibited the same defect for lambdaUTM as observed previously with a dinB::Mu mutant, and the defect was complemented by plasmids carrying dinP as the only intact bacterial gene. Furthermore, merely increasing the dinP gene expression, without UV irradiation or any other DNA-damaging treatment, resulted in a strong enhancement of mutagenesis in F'lac plasmids; at most, 800-fold increase in the G6-to-G5 change. The enhanced mutagenesis did not depend on recA, uvrA, or umuDC. Thus, our results establish that E. coli has at least two distinct pathways for SOS-induced mutagenesis: one dependent on umuDC and the other on dinB/P.

SOS factors involved in translesion synthesis

Mutations are permanent DNA sequence changes that can be induced when replication occurs on a damaged DNA template. In Escherichia coli, the process of translesion synthesis past a lesion that hinders replication requires the induction of SOS-controlled gene products, among which are those of the umuDC operon. To study translesion synthesis in vivo, we have constructed single-stranded vectors containing single 2-acetylaminofluorene adducts located within -1 and -2 frameshift mutation hot spots formed by short repetitive sequences. These adducts strongly hinder DNA replication as only 2-5% of the molecules give rise to progeny under non-SOS-induced conditions. Induction of the SOS response lead to a 10-fold increase in survival. Adducts present within repetitive sequences trigger the formation of misaligned primer/template replication intermediates which, upon elongation, will result in the fixation of frameshift errors (mutagenic translesion synthesis). Surprisingly we find that elongation from the nonslipped intermediate depends upon functional umuDC+ gene products, whereas elongation from the slipped intermediate is umuDC+ independent but requires another, as yet biochemically uncharacterized, SOS function. These data are discussed in terms of the different steps involved during translesion synthesis through a replication-blocking lesion.

Replication bypass and mutagenic effect of alpha-deoxyadenosine site-specifically incorporated into single-stranded vectors

alpha-2'-Deoxyadenosine (alpha) is a major adenine lesion produced by gamma-ray irradiation of DNA under anoxic conditions. In this study, single-stranded recombinant M13 vectors containing alpha were constructed and transfected into Escherichia coli to assess lethal and mutagenic effects of this lesion. The data for alpha were further compared with those obtained with M13 vectors containing normal A or a model abasic site (F) at the same site. The transfection assay revealed that alpha constituted a moderate block to DNA replication. The in vivo replication capacity to pass through alpha was approximately 20% relative to normal A, but 20-fold higher than that of F constituting an almost absolute replication block. Similar data were obtained by in vitro replication of oligonucleotide templates containing alpha or F by E.coli DNA polymerase I. The mutagenic consequence of replicating M13 DNA containing alpha was analyzed by direct DNA sequencing of progeny phage. Mutagenesis was totally targeted at the site of alpha introduced into the vector. Mutation was exclusively a single nucleotide deletion and no base substitutions were detected. The deletion frequency associated alpha was dependent on the 3'-nearest neighbor base: with the 3'-nearest neighbor base T mutation (deletion) frequency was 26%, whereas 1% with the 3'-nearest neighbor base G. A possible mechanism of the single nucleotide deletion associated with alpha is discussed on the basis of the misinsertion-strand slippage model.

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.

Mutagenicity of acridines in a reversion assay based on tetracycline resistance in plasmid pBR322 in Escherichia coli

The mutagenicity of a series of acridine compounds was studied in an assay based on the reversion of mutations in the tetracycline-resistance gene (tet) of plasmid pBR322 in Escherichia coli. Mutations that restore the tetracycline-resistant phenotype were detected in tetracycline-sensitive strains carrying mutant plasmids. Mutations that revert by +2, +1, -1 and -2 frameshift mutations and by base-pair substitutions were used to analyze the mutagenicity of two simple acridines, two acridine mustards, and a nitroacridine. The simple acridines (9-aminoacridine and quinacrine) effectively induced -1 frameshifts and weakly induced +1 frameshifts. The acridine mustards (quinacrine mustard and ICR-191) were more potent inducers of -1 and +1 frameshifts than the simple acridines. Reactive acridines, including both the mustards and the nitroacridine Entozon, were effective inducers of -2 frameshifts but the simple acridines were not. The two classes of reactive acridines differed from one another, in that the mustards were better inducers of +1 frameshifts than Entozon, whereas Entozon was a particularly potent inducer of -2 frameshifts. None of the compounds induced +2 frameshifts, and the induction of base-pair substitutions was negligible. These results confirm and extend studies showing that adduct-forming acridines are stronger frameshift mutagens than simple intercalating acridines and that the acridines differ from one another not only in overall mutagenic potency but also in the prevalence of different classes of frameshift mutations.

NMR data show that the carcinogen N-2-acetylaminofluorene stabilises an intermediate of -2 frameshift mutagenesis in a region of high mutation frequency

The heteroduplex, D(ACCGGCGCCACA) . d(TGTGG-CCGGT), containing two bulged bases, a cytosine and the guanine G7, either unmodified or modified with the carcinogen N-2-acetylaminofluorene, have been studied by NMR as models of slipped-mutagenic intermediates (SMI). The melting temperature of the modified heteroduplex is strongly increased compared with that of the unmodified heteroduplex. NMR studies have shown that all the bases of the unmodified heteroduplex are stacked within the helix, without any disruption of the sequential connectivities. The two strands are in a B-like conformation. Nevertheless, exchangeable-proton studies have revealed that base pairing is very weak, or even lacking, over two base pairs apart from the bulge. Concerning the modified heteroduplex, no B-like connectivity is observed in the G5-C9 segment. Moreover, the cytosine C8 is rejected outside the helix, whereas the N-2-acetylaminofluorene moiety is inserted within the helix. The G5.C18, C6.G17 and C9.G16 bases are remarkably stable when the temperature is increased, in agreement with the high melting temperature. Some small unassigned peaks reveal the presence of the minor conformation in equilibrium. The strong stabilisation of the N-2-acetylaminofluorene-modified heteroduplex compared with the unmodified duplex is in agreement with the high N-2-acetylaminofluorene-induced mutation frequency compared with the spontaneous frequency and with the hypothesis of mutagenesis occurring during replication.

Involvement of umuDCST genes in nitropyrene-induced -CG frameshift mutagenesis at the repetitive CG sequence in the hisD3052 allele of Salmonella typhimurium

Expression of the umuDC operon is required for UV and most chemical mutagenesis in Escherichia coli. The closely related species Salmonella typhimurium has two sets of umuDC-like operons, umuDCST on the chromosome and samAB on a 60-MDa cryptic plasmid. The roles of the umuDC-like operons in chemically induced frameshift mutagenesis of the hisD3052 allele of S. typhimurium were investigated. Introduction of a pBR322-derived plasmid carrying umuDCST increased the rate of reversion of hisD3052, following treatment with 1-nitropyrene (1-NP) or 1,8-dinitropyrene (1,8-DNP) tenfold and fivefold, respectively, whereas it did not substantially increase the rate of reversion induced by other frameshift mutagens, i.e. 2-nitrofluorene (2-NF) and 2-amino-3-methyldipyrido[1,2-a:3',2'-d]imidazole (Glu-P-1). Introduction of a pBR322-derived plasmid carrying samAB did not increase the incidence of reversion of hisD3052 observed with any of the mutagens examined. Deletion of umuDCST substantially lowered the reversion rate induced by 1-NP or 1,8-DNP, but it did not affect reversion induced by 2-NF, Glu-P-1 or N-hydroxyacetylaminofluorene (N-OH-AAF). Deletion of samAB had little impact on reversion incidence induced by any of the five frameshift mutagens. DNA amplification using the polymerase chain reaction technique followed by restriction enzyme analysis using BssHII, suggested that the mutations induced by the five frameshift mutagens were all CG deletions at the CGCGCGCG sequence in hisD3052. These results suggest that umuDCST, but not samAB, is involved in the -2 frameshift mutagenesis induced by 1-NP and 1,8-DNP at the repetitive CG sequence, whereas neither operon participates in induction of the same type of mutations by 2-NF, Glu-P-1 or N-OH-AAF.

DNA sequence analysis of spontaneous and gamma-radiation (anoxic)-induced lacId mutations in Escherichia coli umuC122::Tn5: differential requirement for umuC at G.C vs. A.T sites and for the production of transversions vs. transitions

Escherichia coli umuC122::Tn5 cells were gamma-irradiated (137Cs, 750 Gy, under N2), and lac-constitutive mutants were produced at 36% of the wild-type level (the umuC strain was not deficient in spontaneous mutagenesis, and the mutational spectrum determined by sequencing 263 spontaneous lacId mutations was very similar to that for the wild-type strain). The specific nature of the umuC strain's partial radiation mutability was determined by sequencing 325 radiation-induced lacId mutations. The yields of radiation-induced mutation classes in the umuC strain (as a percentage of the wild-type yield) were: 80% for A.T-->G.C transitions, 70% for multi-base additions, 60% for single-base deletions, 53% for A.T-->C.G transversions, 36% for G.C-->A.T transitions, 25% for multi-base deletions, 21% for A.T-->T.A transversions, 11% for G.C-->C.G transversions, 9% for G.C-->T.A transversions, and 0% for multiple mutations. Based on these deficiencies and other factors, it is concluded that the umuC strain is near-normal for A.T-->G.C. transitions, single-base deletions and possibly A.T-->C.G transversions; is generally deficient for mutagenesis at G.C sites and for transversions, and is grossly deficient in multiple mutations. Damage at G.C sites seems more difficult for translesion DNA synthesis to bypass than damage at A.T sites, and especially when trying to produce a transversion. The yield of G.C-->A.T transitions in the umuC strain (36% of the wild-type level) argues that abasic sites are involved in no more than 64% of gamma-radiation-induced base substitutions in the wild-type strain. Altogether, these data suggest that the UmuC and UmuD' proteins facilitate, rather than being absolutely required for, translesion DNA synthesis; with the degree of facilitation being dependent both on the nature of the noncoding DNA damage, i.e., at G.C vs. A.T sites, and on the nature of the misincorporated base, i.e., whether it induces transversions or transitions.

MucAB but not UmuDC proteins enhance -2 frameshift mutagenesis induced by N-2-acetylaminofluorene at alternating GC sequences

N-2-acetylaminofluorene has been shown efficiently to induce both -1 and -2 frameshift mutations in Escherichia coli as well as in mammalian cells. In E. coli, the genetic characteristics of -1 and -2 frameshift mutations were found to be distinct. The -1 frameshift mutation pathway occurs at monotonous runs of G residues (i.e. GGG-->GG). This pathway exhibits the same genetic requirements as UV light-induced base substitution mutagenesis. Indeed, optimal mutagenesis requires the expression of both UmuDC and the activated form of RecA. The -2 frameshift mutation pathway operates at short alternating GpC sequences, such as the NarI sequence (i.e. GGCGCC-->GGCC). In contrast to the -1 frameshift mutation pathway, optimal induction does not require the UmuDC and RecA proteins. This pathway involves a LexA-repressed function tentatively called Npf (for NarI processing factor). In this paper, we show that MucAB efficiently stimulates the -2 frameshift mutation pathway. However, unlike the Npf pathway, MucAB-mediated stimulation requires expression of the RecA protein.

Mutational spectrum induced in Saccharomyces cerevisiae by the carcinogen N-2-acetylaminofluorene

The spectrum of mutations induced by the carcinogen N-2-acetylaminofluorene (AAF) was analysed in Saccharomyces cerevisiae using a forward mutation assay, namely the inactivation of the URA3 gene. The URA3 gene, carried on a yeast/bacterial shuttle vector, was randomly modified in vitro using N-acetoxy-N-2-acetylaminofluorene (N-AcO-AAF) as a model reactive metabolite of the carcinogen AAF. The binding spectrum of AAF to the URA3 gene was determined and found to be essentially random, as all guanine residues reacted about equally well with N-AcO-AAF. Independent Ura- mutants were selected in vivo after transformation of the modified plasmid into a ura3 delta yeast strain. Plasmid survival decreased as a function of AAF modification, leading to one lethal hit (37% relative survival) for an average of approximately 50 AAF adducts per plasmid molecule. At this level of modification the mutation frequency was equal to approximately 70 x 10(-4), i.e. approximately 50-fold above the background mutation frequency. UV irradiation of the yeast cells did not further stimulate the mutagenic response, indicating the lack of an SOS-like mutagenic response in yeast. Sequence analysis of the URA3 mutants revealed approximately 48% frameshifts, approximately 44% base substitutions and approximately 8% complex events. While most base substitutions (74%) were found to be targeted at G residues where AAF is known to form covalent C8 adducts, frameshift mutations were observed at GC base pairs in only approximately 24% of cases.(ABSTRACT TRUNCATED AT 250 WORDS)

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.

Endonuclease VII of phage T4 nicks N-2-acetylaminofluorene-induced DNA structures in vitro

We have tested in vitro the activity of T4 endonuclease VII on three different double-stranded oligonucleotides bearing a single N-2-acetylaminofluorene (AAF) adduct covalently bound to each of the three guanine residues located within the NarI site (G1G2CG3CC), a strong frameshift mutation hot spot in E. coli. With the oligonucleotides modified at G2 and G3 a specific cleavage pattern with T4 endonuclease VII was observed in the complementary strand while no cleavage was found in the adduct-bearing strand. On the other hand, when G1 was modified, only a very faint cleavage band was observed (< 1%). These differences in nicking among the three AAF-modified DNA substrates are discussed in terms of the polymorphic nature in adduct-induced DNA structures as previously shown. This "non-physiological" activity of a DNA resolvase is discussed in terms of a potential role for such enzymes in the induction of frameshift mutations.

Greater susceptibility to mutations in lagging strand of DNA replication in Escherichia coli than in leading strand

Models of DNA replication in Escherichia coli involve an asymmetric DNA polymerase complex that replicates concurrently the leading and the lagging strands of double-stranded DNA. The effect of asymmetry on mutagenesis was tested with pairs of plasmids containing the unidirectional ColE1 origin of replication and a single lesion located in the leading or lagging strand. The lesion used was the covalent adduct that the chemical carcinogen N-2-acetylaminofluorene (AAF) forms with the C-8 position of guanine. Whether SOS was induced or not, mutations arose at about a 20-fold higher frequency when the AAF adduct was located in the lagging strand than when in the leading strand.

DNA adduct-induced stabilization of slipped frameshift intermediates within repetitive sequences: implications for mutagenesis

Chemical carcinogens such as the aromatic amide 2-acetylaminofluorene (AAF) are known to induce -1 frameshift mutation hotspots at repetitive sequences. This mutagenesis pathway was suggested to involve slipped intermediates formed during replication. To investigate the stability and structure of such intermediates we have constructed DNA duplexes containing single AAF adducts within a run of three guanine residues. The strand complementary to that bearing the AAF adducts contained either the wild-type sequence (homoduplexes) or lacked one cytosine directly opposite the run of guanines containing the AAF adduct and thus modeled the putative slipped mutagenic intermediates (SMIs). The melting temperature of AAF-modified homoduplexes or the unmodified SMI was reduced by approximately 10 degrees C relative to the unmodified homoduplex. Surprisingly, AAF adducts stabilized the SMIs as evidenced by an increase in melting temperature to a level approaching that of the unmodified homoduplex. The chemical probes hydroxylamine and bromoacetaldehyde were strongly reactive toward cytosine residues opposite the adduct in AAF-modified homoduplexes, indicating adduct-induced denaturation. In contrast, no cytosine reactivities were observed in the AAF-modified SMIs, suggesting that the two cytosines were paired with unmodified guanines. Use of diethyl pyrocarbonate to probe the guanine residues showed that all three guanines in the unmodified SMI adopted a transient single-stranded state which was delocalized along the repetitive sequence. However, when an AAF adduct was present, reduced diethyl pyrocarbonate reactivity at guanines adjacent to the adduct in AAF-modified SMIs reflected localization of the bulge to the adducted base. Our results suggest that AAF exerts a local denaturing and destabilizing effect within the homoduplex which is alleviated by the formation of a bulge. The stabilization by the AAF adduct of the SMIs may contribute to the dramatic increase in -1 frameshift mutation frequency induced by AAF adducts in repetitive sequences.