A umuDC-independent SOS pathway for frameshift mutagenesis.

Summary The chemical carcinogen N-acetoxy-N-2-acetylaminofluorene induces mainly frameshift mutations, which occur within two types of sequences (mutation hot spots): –1 frameshift mutations within contiguous guanine sequences and –2 frameshift mutations within alternating GC sequences such as the NarI and BssHII restriction site sequences. We have investigated the genetic control of mutagenesis at these sequences by means of a reversion assay using plasmids pW17 and pX2, which contain specific targets for contiguous guanine and alternating GC sequences, respectively. Our results suggest that mutations at these hot spot sequences are generated by two different genetic pathways, both involving induction of SOS functions. The two pathways differ both in their LexA-controlled gene and RecA protein requirements. In the mutation pathway that acts at contiguous guanine sequences, the RecA protein participates together with the umuDC gene products. In contrast, RecA is not essential for mutagenesis at alternating GC sequences, except to cleave the LexA repressor. The LexA-regulated gene product(s), which participate in this latter mutational pathway, do not involve umuDC but another as yet uncharacterized inducible function. We also show that wild-type RecA and RecA430 proteins exert an antagonistic effect on mutagenesis at alternating GC sequences, which is not observed either in the presence of activated RecA (RecA^*), RecA730 or RecA495 proteins, or in the complete absence of RecA as in recA99. It is concluded that the –1 mutation pathway presents the same genetic requirements as the pathway for UV light mutagenesis, while the –2 mutation pathway defines a distinct SOS pathway for frameshift mutagenesis.     

Roles of recA mutant allele (recA495) in frameshift mutagenesis

The chemical carcinogen N-acetoxy-N-2-acetylaminofluorene (N-AcO-AAF) induces frameshift mutations located within two types of specific sequences (mutation hot spots): i) contiguous guanine sequences and ii) alternating GC sequences. The genetic requirements of these frameshift events were investigated using specific reversion assays. AAF-induced -2 frameshift mutagenesis at alternating GC sequences is peculiar in that it requires a LexA- controlled function which is not UmuDC and occurs in the absence of RecA protein, provided the SOS regulon is derepressed. Moreover, the non-activated form of the RecA protein was shown to act as an inhibitor in this mutation pathway. As we were interested in elucidating this mutation pathway, we have developed a convenient spot reversion assay specific for the detection of this class of mutations. This assay allowed us to isolate E coli mutants affected either in repair or mutagenesis functions. One particular mutant, recA495, is very sensitive to UV and N-AcO-AAF, and is defective in recombination and UV mutagenesis. The RecA495 protein exhibits very low binding to both single- and double-stranded DNA. We show that when the SOS regulon is derepressed, the recA495 allele has two contrasting roles in frameshift mutagenesis: i) it prevents the induction of -1 frameshift mutations at repetitive sequences and ii) it is permissive for the induction of -2 frameshift mutations within alternating GC sequences.     

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. GGGGG). 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. GGCGCCGGCC). 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.     

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.     

Adducts formed by the food mutagen 2-amino-3-methylimidazo(4, 5-f ) quinoline induce frameshift mutations at hot spots through an SOS-independent pathway

The potency of 2-amino-3-methylimidazo(4, 5-f)quinoline (IQ) adducts to induce ?2, ?1 and +1 frameshift mutations has been determined on specific target DNA sequences, namely short runs of alternating GpC sequences and short runs of guanines. The genetic control of the mutational processes has been analyzed using different Escherichia coli mutants, affected either in the control or in the mutagenesis pathway of the SOS system. We have shown that IQ adducts induce very efficiently both ?1 and ?2 frameshift mutations in E. coli. Both types of deletion mutations are induced in bacteria without the need of SOS induction, indicating that no LexA-controlled functions, in particular the UmuDC proteins, are required for mutation fixation. We have also shown that the frequency of IQ-induced ?2 frameshift mutations in alternating GC sequences increases with the length of the repetition. The efficiency of IQ adducts to induce ?1 and ?2 frameshift mutations is similar to that of N‐2-acetylaminofluorene (AAF) adducts. Both chemicals are potent carcinogens which form covalent adducts at the C8 position of guanines. We suggest that in both cases the adduct-induced DNA structure allows the replication complex to perform a mutagenic bypass of the lesion by a slippage mechanism. However, in contrast to AAF-induced frameshift mutagenesis, IQ-induced frameshift mutagenesis is SOS-independent.     

Construction of frameshift mutation hot spots within the tetracycline resistance gene of pBR322

The chemical carcinogen, N-2-acetylaminofluorene (AAF) when bound covalently to DNA induces a majority (greater than 90%) of frameshift mutations. The mutations occur with high frequencies at defined sequences (i.e. mutation hot spots). Two classes of mutation hot spots were found: at repetitive sequences and at specific non-repetitive sequences. Mutations at the repetitive sequences depend upon a functional umuC gene whereas mutations at specific non-repetitive sequences are umuC-independent. The first discovered sequence of this class is the NarI restriction enzyme recognition sequence (5'GGCGCC3'). In an attempt to define a family of such sequences we constructed a related sequence 5'GCGCGC3' within the tetracycline resistance gene of pBR322. This sequence was also found to be an--AAF induced--2 frameshift mutation hot spot in both wild type and umuC strains.     

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.     

Adducts formed by the food mutagen 2-amino-3-methylimidazo(4, 5- f ) quinoline induce frameshift mutations at hot spots through an SOS-independent pathway

The potency of 2-amino-3-methylimidazo(4, 5-f)quinoline (IQ) adducts to induce −2, −1 and +1 frameshift mutations has been determined on specific target DNA sequences, namely short runs of alternating GpC sequences and short runs of guanines. The genetic control of the mutational processes has been analyzed using different Escherichia coli mutants, affected either in the control or in the mutagenesis pathway of the SOS system. We have shown that IQ adducts induce very efficiently both −1 and −2 frameshift mutations in E. coli. Both types of deletion mutations are induced in bacteria without the need of SOS induction, indicating that no LexA-controlled functions, in particular the UmuDC proteins, are required for mutation fixation. We have also shown that the frequency of IQ-induced −2 frameshift mutations in alternating GC sequences increases with the length of the repetition. The efficiency of IQ adducts to induce −1 and −2 frameshift mutations is similar to that of N‐2-acetylaminofluorene (AAF) adducts. Both chemicals are potent carcinogens which form covalent adducts at the C8 position of guanines. We suggest that in both cases the adduct-induced DNA structure allows the replication complex to perform a mutagenic bypass of the lesion by a slippage mechanism. However, in contrast to AAF-induced frameshift mutagenesis, IQ-induced frameshift mutagenesis is SOS-independent. Received: 13 June 1996 / Accepted: 24 September 1996     

Carcinogen-induced mutation spectrum in wild-type, uvrA and umuC strains of Escherichia coli. Strain specificity and mutation-prone sequences

Forward mutations induced by the ultimate carcinogen N-acetoxy-N-2-acetylaminofluorene (N-Aco-AAF) in the tetracycline resistance gene carried on plasmid pBR322 are shown to be dependent upon the induction of the host SOS functions in wild-type and umuC Escherichia coli cells. The mutation frequency in the umuC strain is equal to about 40% of the mutation frequency observed in the umu+ background. In the excision-repair-deficient uvrA mutant strain the mutagenic response is the same as in SOS-induced wild-type cells whether or not the uvrA bacteria are SOS-induced. Equal mutation frequencies are obtained in both the wild-type and the uvrA strains for equal modification levels although the survival of AAF-modified plasmid DNA is greatly reduced in the uvrA strain as compared to the wild-type strain. Sequence analysis of the mutations reveals that more than 90% of the N-Aco-AAF-induced mutations are frameshift mutations. Two types of mutational hotspots are observed occurring either at repetitive sequences or at non-repetitive sequences. Both types of mutants appear at similar locations and frequencies in both the wild-type and the uvrA strains. On the other hand, only the non-repetitive sequence mutants are obtained in the umuC background. These non-repetitive sequence mutants preferentially occur within the sequence 5' G-G-C-G-C-C 3' (the NarI restriction enzyme recognition sequence). The analysis of the -AAF binding spectrum to the same DNA fragment shows that there is no direct correlation between the modification spectrum and the mutation spectrum. We suggest that certain sequences are "mutation-prone" in the sense that only these sequences can be efficiently mutated as the result of an active processing mediated by specific proteins. When a sequence is said to be mutation-prone it probably corresponds to a particular structure that is induced within this sequence as a result of the binding to the DNA of the mutagen. This sequence-specific conformational change is the substrate for the protein(s) that fixes the mutation. The mutagenic processing pathway(s) is part of the cellular response to DNA-damaging agents (the so-called SOS response). Two pathways for frameshift mutagenesis are suggested by the data: an umuC-dependent pathway, which is involved in the mutagenic processing of lesions within repetitive sequences; an umuC-independent pathway responsible for the fixation of mutations within specific non-repetitive sequences.     

A mutation-promotive role of nucleotide excision repair in cell cycle-arrested cell populations following UV irradiation

Growing attention is paid to the concept that mutations arising in stationary, non-proliferating cell populations considerably contribute to evolution, aging, and pathogenesis. If such mutations are beneficial to the affected cell, in the sense of allowing a restart of proliferation, they are called adaptive mutations. In order to identify cellular processes responsible for adaptive mutagenesis in eukaryotes, we study frameshift mutations occurring during auxotrophy-caused cell cycle arrest in the model organism Saccharomyces cerevisiae. Previous work has shown that an exposure of cells to UV irradiation during prolonged cell cycle arrest resulted in an increased incidence of mutations. In the present work, we determined the influence of defects in the nucleotide excision repair (NER) pathway on the incidence of UV-induced adaptive mutations in stationary cells. The mutation frequency was decreased in Rad16-deficient cells and further decreased in Rad16/Rad26 double-deficient cells. A knockout of the RAD14 gene, the ortholog of the human XPA gene, even resulted in a nearly complete abolishment of UV-induced mutagenesis in cell cycle-arrested cells. Thus, the NER pathway, responsible for a normally accurate repair of UV-induced DNA damage, paradoxically is required for the generation and/or fixation of UV-induced frameshift mutations specifically in non-replicating cells.     

Frameshift mutagenesis in Escherichia coli by reversible DNA intercalators: sequence specificity

The mutagenic potency of the simple reversible intercalators isopropyl-OPC (iPr-OPC) and 9-aminoacridine (9-AA) is assessed in E. coli using reversion assays based on plasmids derived from pBR322 carrying various frameshift mutations within the tetracycline resistance gene in repetitive sequences: +/- 2 frameshift mutations within alternating GC sequences; +/- 1 frameshift mutation at runs of guanines. The results obtained show that iPr-OPC and 9-AA have a sequence specificity for mutagenesis: they revert +1 and -1 frameshift mutations within runs of monotonous G:C base pairs. The precise determination of the size of a small restriction fragment which contains the mutation allowed us to demonstrate that reversion occurred by -1 deletions for the +1 frameshift mutations and by +1 additions for the -1 frameshift mutations. The possible relations of this specific reversion with the base sequence specificity of the mutagenesis are briefly discussed.     

Roles of RecA protease and recombinase activities of Escherichia coli in spontaneous and UV-induced mutagenesis and in Weigle repair.

The RecA protein has a second, direct role in the mutagenesis of Escherichia coli and bacteriophage lambda in addition to its first, indirect role of inducing the SOS system by enhancing the proteolytic cleavage of the LexA repressor protein. The need for RecA protease and recombinase functions in the direct role was examined in cells containing split-phenotype RecA mutations, in the absence of LexA protein. Spontaneous mutation of E. coli (his----his+) required both the protease and recombinase activities. The mutation frequency increased with increasing RecA protease strength. In contrast, UV-induced mutation of E. coli required only the RecA protease activity. Weigle repair and mutation of UV-irradiated phage S13 required only RecA protease activity, and even weak activity was highly effective; RecA recombinase activity was not required. RecA+ protein inhibited RecA (Prtc [protease constitutive] Rec+) protein in effecting spontaneous mutation of E. coli. We discuss the nature of the direct role of the RecA protein in spontaneous mutation and in repair and mutagenesis of UV-damaged DNA and also the implications of our results for the theory that SOS-mutable cryptic lesions might be responsible for the enhanced spontaneous mutation in Prtc Rec+ strains.     

Translesion synthesis in Escherichia coli: lessons from the NarI mutation hot spot

Duplication of DNA containing damaged bases is a challenge to DNA polymerases that normally replicate with high speed, high accuracy and high processivity undamaged templates only. When a replicative DNA polymerase encounters a chemically altered base that it is unable to copy, a process called translesion synthesis (TLS) takes place during which the replicative polymerase is transiently replaced by a so-called specialized or lesion bypass polymerase. In addition to the central players that are the replicative and translesion DNA polymerases, TLS pathways involve accessory factors such as the general replication processivity factor (i.e. the beta-clamp in prokaryotes and PCNA in eukaryotes). In Escherichia coli, besides the beta-clamp, RecA plays a fundamental role as a co-factor of Pol V the major bypass polymerase in this organism. An integrated view of TLS pathways necessarily requires both genetic and biochemical studies. In this review we will attempt to summarize the insights into TLS gained over the last 25 years by studying a frameshift mutation hot spot, the NarI site. This site was initially discovered by serendipity when establishing a forward mutation spectrum induced by a chemical hepatocarcinogen, N-2-acetylaminofluorene (AAF). Indeed, this chemical carcinogen covalently binds to DNA forming adducts with guanine residues. When bound to G* in the NarI site, 5'-GGCG*CC-, AAF induces the loss of the G*pC dinucleotide at a frequency that is approximately 10(7)-fold higher than the spontaneous frequency. In vivo studies showed that the NarI mutation hot spot is neither restricted to the NarI sequence itself, nor to the carcinogen AAF. Instead, the hot spot requires a sequence containing at least two GpC repeats and any of a family of aromatic amides and nitro aromatic compounds that form a large class of human carcinogens. Genetic analysis initially revealed that the NarI frameshift pathway is SOS dependent but umuDC (i.e. Pol V) independent. More recently, DNA Pol II was identified as the enzyme responsible of this frameshift pathway. Concurrently the AAF adduct in the NarI site can be bypassed in an error-free way by Pol V. The NarI site thus offers a unique possibility to study the interplay between two specialized DNA polymerases, Pol II and Pol V, that can both extend replication intermediates formed when the replicative Pol III dissociates in the vicinity of the damage. Full reconstitution of the two pathways led us to highlight a key feature for TLS pathways, namely that it is critical the specialized DNA polymerase synthesizes, during the course of a single binding event, a patch of DNA synthesis (TLS patch) that is long enough as to "hide the lesion induced distortion" from the proofreading activity upon reloading of the replicative DNA polymerase (or any exonuclease that may get access to the primer when the specialized DNA polymerase detaches). The beta-clamp, to which all DNA polymerases bind, plays a critical role in allowing the specialized DNA polymerases to synthesize TLS patches that are long enough to resist such "external proofreading" activities.     

Evidence for a Rad18-independent frameshift mutagenesis pathway in human cell-free extracts

Bypass of replication blocks by specialized DNA polymerases is crucial for cell survival but may promote mutagenesis and genome instability. To gain insight into mutagenic sub-pathways that coexist in mammalian cells, we examined N-2-acetylaminofluorene (AAF)-induced frameshift mutagenesis by means of SV40-based shuttle vectors containing a single adduct. We found that in mammalian cells, as previously observed in E. coli, modification of the third guanine of two target sequences, 5'-GGG-3' (3G) and 5'-GGCGCC-3' (NarI site), induces -1 and -2 frameshift mutations, respectively. Using an in vitro assay for translesion synthesis, we investigated the biochemical control of these events. We showed that Pol eta, but neither Pol iota nor Pol zeta, plays a major role in the frameshift bypass of the AAF adduct located in the 3G sequence. By complementing PCNA-depleted extracts with either a wild-type or a non-ubiquitinatable form of PCNA, we found that this Pol eta-mediated pathway requires Rad18 and ubiquitination of PCNA. In contrast, when the AAF adduct is located within the NarI site, TLS is only partially dependent upon Pol eta and Rad18, unravelling the existence of alternative pathways that concurrently bypass this lesion.     

Specificity of N-acetoxy-N-2-acetylaminofluorene-induced frameshift mutation spectrum in mismatch repair deficient Escherichia coli strains mutH, L, S and U

The mismatch repair system of Escherichia coli is known to contribute to the fidelity of the replicational process. This system involves the functions of mutH, mutL, mutS and mutU (uvrD) loci which recognize mispaired bases as a consequence of errors due to the polymerase itself. Chemical modifications of DNA have also been suspected to create mispaired bases which, if the mispaired bases are removed, will lead to mutations by frameshift. Using the pBR322 plasmid DNA modified by the ultimate carcinogen N-acetoxy-N-2-acetylaminofluorene (N-Aco-AAF) we have investigated this possibility in a forward mutational assay (tetracycline sensitivity). This fluorene derivative has been shown to induce predominantly frameshift mutations. Our results show that: The sensitivity of the deficient strains mutH, mutL and mutS to the AAF adducts is similar to that of the corresponding wild-type strain. However, the mutU strain appears much more sensitive to those adducts although less than a uvrA, B or C-deficient strain. This suggests that the mutU gene product is involved in the repair of AAF adducts. For the four mut deficient strains, and as it was shown with the wild-type strain, AAF adducts induced mutations to tetracycline sensitivity are only observed when the SOS system of the host bacteria is induced by irradiation of the cells prior to transformation with the modified plasmid. The mutation frequencies depend upon the ultraviolet light doses and similar maxima were found for the four mut strains and the corresponding wild-type strain. In agreement with the results obtained with wild-type or uvrA strains we observe that AAF adducts induce mostly frameshift mutations in the mut strains. Two types of hot spots of mutagenesis were described in wild-type and uvrA strains occurring either at repetitive sequences or at sequences of the type 5' G-G-C-G-C-C 3' (NarI restriction enzyme recognition sequence). While the second type of mutational hot spot does exist in the mismatch repair-deficient strains, we observe that the repetitive sequences are no longer hot spots of mutations in these strains, suggesting that the mismatch repair protein complex is involved in the establishment of AAF-induced frameshift mutations at repetitive sequences.     

A RecA protein mutant deficient in its interaction with the UmuDC complex

recA1730 is a dominant point mutation preventing SOS mutagenesis. We demonstrate here that: i) RecA1730 fails to produce mutagenesis even though UmuD' is formed, ii) recA1730, when complemented by recA+, can cleave LexA protein and it displays a UmuDC- phenotype in spite of adequate concentrations of matured UmuD' and UmuC proteins, iii) the Mut- phenotype caused by RecA1730 is partially alleviated by MucAB proteins, functional analogs of UmuDC. To explain the mutant phenotype, we postulate that recA1730 impairs a RecA function required for the positioning of the UmuD'C complex within the replisome at the site of lesions.     

Activated RecA protein may induce expression of a gene that is not controlled by the LexA repressor and whose function is required for mutagenesis and repair of UV-irradiated bacteriophage lambda.

The activated form of the RecA protein (RecA) is known to be involved in the reactivation and mutagenesis of UV-irradiated bacteriophage lambda and in the expression of the SOS response in Escherichia coli K-12. The expression of the SOS response requires cleavage of the LexA repressor by RecA and the subsequent expression of LexA-controlled genes. The evidence presented here suggests that RecA induces the expression of a gene(s) that is not under LexA control and that is also necessary for maximal repair and mutagenesis of damaged phage. This conclusion is based on the chloramphenicol sensitivity of RecA -dependent repair and mutagenesis of damaged bacteriophage lambda in lexA(Def) hosts.     

Sequence specificity of point mutations induced during passage of a UV-irradiated shuttle vector plasmid in monkey cells.

A simian virus 40-based shuttle vector was used to characterize UV-induced mutations generated in mammalian cells. The small size and placement of the mutagenesis marker (the supF suppressor tRNA gene from Escherichia coli) within the vector substantially reduced the frequency of spontaneous mutations normally observed after transfection of mammalian cells with plasmid DNA; hence, UV-induced mutations were easily identified above the spontaneous background. UV-induced mutations characterized by DNA sequencing were found primarily to be base substitutions; about 56% of these were single-base changes, and 17% were tandem double-base changes. About 24% of the UV-induced mutants carried multiple mutations clustered within the 160-base-pair region sequenced. The majority (61%) of base changes were the G . C----A . T transitions; the other transition (A . T----G . C) and all four transversions occurred at about equal frequencies. Hot spots for UV mutagenesis did not correspond to hot spots for UV-induced photoproduct formation (determined by a DNA synthesis arrest assay); in particular, sites of TT dimers were underrepresented among the UV-induced mutations. These observations suggest to us that the DNA polymerase(s) responsible for mutation induction exhibits a localized loss of fidelity in DNA synthesis on UV-damaged templates such that it synthesizes past UV photoproducts, preferentially inserting adenine, and sometimes misincorporates bases at undamaged sites nearby.     

Induction of ?2 frameshift mutations within alternating GC sequences by carcinogens that bind to the C8 position of guanine residues Development of a specific mutation assay

Summary Using a forward mutation assay we have previously found that N-2-acetylaminofluorene (AAF), a strong chemical carcinogen, induces a majority of frameshift mutations located at specific sequences called mutation hot spots. Among these hot spot sequences, the NarI sequence (GGCGCC), is specific for –2 frameshifts (GGCGCC) GGCC). Interestingly, these frameshift mutations occur independently of a functional umuDC locus. Being interested in elucidating this mutation pathway we have developed a reversion assay that is specific for this class of mutations. The assay is based on the reversion of a +2 frameshift mutant of plasmid pBR322 from tetracycline sensitivity to tetracycline resistance. It is shown that only true reversion events lead to tetracycline resistance. The carcinogen AAF induces this reversion event at a frequency that is increased four- to fivefold over the background frequency. A series of chemical carcinogens which, like AAF, bind covalently to the C8 position of guanine, are compared for their efficiency to induce this specific mutation event. Large variations in the mutagenic efficiency of these chemicals are observed and discussed in terms of the anti/syn conformation of the carcinogen-modified guanine residue. Based on this test, we describe a convenient spot assay that this presently used in our laboratory to isolate Escherichia coli mutants affected in this mutation pathway.     

Alteration of ultraviolet-induced mutagenesis in yeast through molecular modulation of the REV3 and REV7 gene expression

DNA damage can lead to mutations during replication. The damage-induced mutagenesis pathway is an important mechanism that fixes DNA lesions into mutations. DNA polymerase zeta (Pol zeta), formed by Rev3 and Rev7 protein complex, and Rev1 are components of the damage-induced mutagenesis pathway. Since mutagenesis is an important factor during the initiation and progression of human cancer, we postulate that this mutagenesis pathway may provide an inhibiting target for cancer prevention and therapy. In this study, we tested if UV-induced mutagenesis can be altered by molecular modulation of Rev3 enzyme levels using the yeast Saccharomyces cerevisiae as a eukaryotic model system. Reducing the REV3 expression in yeast cells through molecular techniques was employed to mimic Pol zeta inhibition. Lower levels of Pol zeta significantly decreased UV-induced mutation frequency, thus achieving inhibition of mutagenesis. In contrast, elevating the Pol zeta level by enhanced expression of both REV3 and REV7 genes led to a approximately 3-fold increase in UV-induced mutagenesis as determined by the arg4-17 mutation reversion assays. In vivo, UV lesion bypass by Pol zeta requires the Rev1 protein. Even overexpression of Pol zeta could not alleviate the defective UV mutagenesis in the rev1 mutant cells. These observations provide evidence that the mutagenesis pathway could be used as a target for inhibiting damage-induced mutations.