Highly mutable sites for ICR-170-induced frameshift mutations are associated with potential DNA hairpin structures: studies with SUP4 and other Saccharomyces cerevisiae genes.

The majority of the mutations induced by ICR-170 in both the CYC1 gene (J. F. Ernst et al. Genetics 111:233-241, 1985) and the HIS4 gene (L. Mathison and M. R. Culbertson, Mol. Cell. Biol. 5:2247-2256, 1985) of the yeast Saccharomyces cerevisiae were recently shown to be single G . C base-pair insertions at monotonous runs of two or more G . C base pairs. However, not all sites were equally mutable; in both the CYC1 and HIS4 genes there is a single highly mutable site where a G . C base pair is preferentially inserted at a [sequence in text]. Here we report the ICR-170 mutagen specificity at the SUP4-o tyrosine tRNA gene of yeast. Genetic fine structure analysis and representative DNA sequence determination of ICR-170-induced mutations revealed that there is also a single highly mutable site in SUP4-o and that the mutation is a G . C base-pair insertion at a monotonous run of G . C base pairs. Analysis of DNA sequences encompassing the regions of highly mutable sites for all three genes indicated that the mutable sites are at the bases of potential hairpin structures; this type of structure could not be found at any of the other, less mutable G . C runs in SUP4, CYC1, and HIS4. Based on these results and recent information regarding novel DNA structural conformations, we present a mechanism for ICR-170-induced mutagenesis. (i) ICR-170 preferentially binds to DNA in the beta conformation; factors that increase the temporal stability of this structure, such as adjacent stem-and-loop formation, increase the frequency of ICR-170 binding; (ii) the observed mutagen specificity reflects formation of a preferred ICR-170 intercalative geometry at [sequence in text] sites; (iii) during replication or repair, ICR-170 remains associated with the single-stranded template; (iv) stuttering or strand slippage by the polymerization complex as it encounters the mutagen results in nucleotide duplication; (v) subsequent replication or mismatch repair fixes the insertion into the genome. This mechanism accounts for both the IRC-170 mutagenic specificity and the molecular basis of the highly mutable sites in S. cerevisiae.     

Suppressible and nonsuppressible +1 G-C base pair insertions induced by ICR-170 at the his4 locus in Saccharomyces cerevisiae.

Fifteen independent ICR-170-induced his4 mutations in Saccharomyces cerevisiae were examined by DNA sequence analysis. All of the mutations contained a +1 G-C base pair addition in the HIS4 coding region. Eleven different sites of insertion were identified. Combined with previous DNA sequence data, 21 ICR-170-induced his4 mutations distributed at 16 different sites were analyzed. The insertions were always located in a consecutive run of two or more G-C base pairs, with all base pairs in each run having identical orientation. Long consecutive G-C runs were preferred target sites over short runs. Although some consecutive G-C runs appeared to be preferred target sites over others of identical length, such preference was not due to any particular type of nucleotide pair immediately adjacent to a given target site. In addition, DNA sequence analyses of the his4 mutations provided a basis for examining the mechanism of mRNA sequence recognition by extragenic suppressors of ICR-170-induced mutations. The implications of these results for mechanisms of frameshift suppression are discussed.     

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.     

Sequencing Studies of Icr-170 Mutagenic Specificity in the am (Nadp-Specific Glutamate Dehydrogenase) Gene of NEUROSPORA CRASSA

The acridine half-mustard ICR-170-induced reversion of the mutant am15, which has a single base-pair deletion, at a frequency of between 9 and 28 X 10(-6). In each of three classes of revertants, the mutagen had induced the insertion of a -G- -C- base pair at a -G-G- -C-C- site. The mutant am6, which has a single base pair insertion, is known to be revertible, with UV light, by deletion of a -G- -C- base pair at a -G-G-G- -C-C-C- site. This mutant reverted with ICR-170 at a frequency of 0.1 X 10(-6). These results show that ICR-170 is able to induce addition frameshifts in Neurospora crassa within short, monotonous runs of G:C base pairs, but indicate a lack of deletion activity at such sequences.     

Induction of Cycloheximide-Resistant Mutants in Saccharomyces cerevisiae with N-Methyl-N′-Nitro-N-Nitrosoguanidine and ICR-170

N-Methyl-N'-nitro-N-nitrosoguanidine (MNNG) induces cycloheximide-resistant mutations in Saccharomyces cerevisiae, but few, if any, resistant mutants are induced by the acridine mustard ICR-170. Cycloheximide sensitivity in yeast is associated with the ribosome, and treatment with the antibiotic at concentrations of 2 mug/ml results in complete inhibition of protein synthesis. Missense mutations induced by MNNG probably lead to the loss of cycloheximide binding sites on the ribosome, resulting in resistance to the antibiotic without altering the activity of the organelle in protein synthesis. ICR-170, however, induced primarily frameshift mutations that would alter ribosome structural integrity, resulting in cell death rather than resistance. ICR-170 and MNNG are both mutagenic in a system in which base-pair substitution and frameshift mutations can be detected. These results indicate that cycloheximide resistance in S. cerevisiae, like streptomycin and spectinomycin resistance in Escherichia coli, can be induced by base-pair substitution mutagens but not by frameshift mutagens such as ICR-170.     

Frameshift mutagenesis of lambda prophage by 9-aminoacridine, proflavin and ICR-191

Summary The changes in DNA base sequence induced in the lambda cI gene in an E. coli lysogen have been determined following mutagenesis by three acridine derivatives: 9-aminoacridine and proflavin, which bind reversibly to DNA; and ICR-191, which attaches covalently to DNA through a half-mustard group. For all three derivatives, most mutations are +1 and-1 frameshifts in runs of adjacent G:C pairs. The specificity of mutagenesis at various sites is similar for all three compounds. Prophage in mutL host cells, deficient in mismatch repair, are much more susceptible to mutagenesis by 9-aminoacridine. The induced mutations are also frameshifts, and the site specificity is the same as in lysogens of wild type cells. Thus, additions or deletions of single bases can be corrected by the mismatch repair system, but mismatch repair does not play an important role in determining the sequence specificity of the mutational events.     

Frameshift mutations induced by the acridine mustard ICR-191 in embryos and in the adult gill and hepatopancreas of rpsL transgenic zebrafish

To determine whether frameshift mutations can be detected in rpsL transgenic zebrafish (Brachydanio rerio), embryos, and adult fish were treated with 6-chloro-9-[3-(2-chloroethylamino)-propylamino]-2-methoxyacridine (ICR-191). Embryos exposed to 0, 10, or 20 microM ICR-191 in a water bath for 18 h exhibited induced mutant frequencies (MFs) of 14 x 10(-5), 16 x 10(-5), and 25 x 10(-5), respectively. Only embryos exposed to 20 microM ICR-191 showed a significant increase in MF. The mutational spectra differed between the control and ICR-191-treated groups and single G:C pair insertions, which are a marked characteristic of ICR-191 mutagenesis, were observed in both 10 and 20 microM-treated embryos. In adult fish treated with 1 microM ICR-191 in a water bath for 18 h, a significant increase in MFs was observed in both gill (12 x 10(-5) and 44 x 10(-5) in control and treated fish, respectively), and hepatopancreas (5 x 10(-5) and 29 x 10(-5), respectively) 2 weeks after exposure. Sequence analysis showed that 58% of mutations in gill and 94% of mutations in hepatopancreas were single G:C pair insertions, which is typical of mutations induced by ICR-191. Additionally, these mutations occurred predominantly at a single site (CC sequence at bps 140-141) in the rpsL gene. Three weeks after exposure, however, the increased MFs and prominent mutational spectra of ICR-treated fish were undetectable. These findings suggest that using our protocols the rpsL transgenic zebrafish mutation assay is more effective for adult fish than for embryos, but that frameshift mutations can be detected in both embryos and adults at appropriate sampling times after treatment with ICR-191.     

Mechanisms of frameshift mutagenesis by aflatoxin B1-2,3-dichloride

In order to characterize frameshift mutagenesis by aflatoxin B1-2,3-dichloride (AFB1Cl2), we have introduced a +1 (BK8) or a -1 (HS8) frameshift within the lacZ alpha gene segment contained in the phage M13mp8 to obtain lacZ alpha- derivatives. BK8 or HS8 replicative form DNA was modified with AFB1Cl2 in vitro, transfected into appropriate Escherichia coli hosts and lacZ alpha+ revertants scored and defined by DNA sequencing. The -1 frameshift (BK8) results suggest the following. (1) The E. coli recA gene is not absolutely required for AFB1Cl2-induced frameshift mutagenesis; however, in recA+ cells, ultraviolet light (SOS) induction enhances AFB1Cl2 mutagenesis, but such ultraviolet induction is not required. The plasmid pGW270 (mucAB+) significantly enhances the AFB1Cl2-induced frameshift mutagenesis. The uvrABC+ excision system plays a major role in the repair of AFB1Cl2-induced damage. (2) Sequence analysis reveals that AFB1Cl2 induces two classes of -1 frameshift mutations: the simple class in which the frameshift is due to the loss of one base-pair, and the complex class in which the loss of a base-pair is coupled to a vicinal base substitution. Both types of mutations occur predominantly at G.C runs, which are hotspots for AFB1Cl2 damage. The complex mutations appear to be concerted events targeted by a single AFB1Cl2 adduct. The frequency of these complex mutations is significantly enhanced by mucAB activity. In this system, recA activity is required for generation of significant levels of complex mutations. An analysis of the +1 frameshifts (HS8) reveals that AFB1Cl2 induces +1 frameshifts with an efficiency comparable to that for -1 frameshifts. Most +1 frameshifts occur by the addition of a base, and a third of the additions are complex mutations because they are accompanied by at least one base substitution. All simple additions occur at G.C runs; however, in a striking contrast to spontaneous insertions, a majority of the induced events introduce an A.T pair at these sites. Our data suggest a model for the generation of base substitution as well as simple and complex frameshift mutations induced by AFB1Cl2. To the extent determined, the frameshift specificity of aflatoxin B1 activated by metabolic enzymes is similar to that of AFB1Cl2.     

Mechanisms of spontaneous mutagenesis: an analysis of the spectrum of spontaneous mutation in the Escherichia coli lacI gene

We have obtained via DNA sequence analysis a spectrum of 174 spontaneous mutations occurring in the lac I gene of Escherichia coli. The spectrum comprised base substitution, frameshift, deletion, duplication and insertion mutations, of which the relative contributions to spontaneous mutation could be estimated. Two thirds of all lacI mutations occurred in the frameshift hotspot site. An analysis of the local DNA sequence suggested that the intensity of this hotspot may depend on structural features of the DNA that extend beyond those permitted by the repeated tetramer at this site. Deletions comprised the largest non-hotspot class (37%). They could be divided into two subclasses, depending on whether they included the lac operator sequence; the latter was found to be a preferred site for deletion endpoints. Most of the deletions internal to the lacI gene were associated with the presence of directly or invertedly repeated sequences capable of accounting for their endpoints. Base substitutions comprised 34% of the non-hotspot events. Unlike the base substitution spectrum obtained via nonsense mutations, G . C----A . T transitions do not predominate. A new base substitution hotspot was discovered at position +6 in the lac operator; its intensity may reflect specific features of the operator DNA. IS1 insertion mutations contributed 12% of the non-hotspot mutations and occurred dispersed throughout the gene in both orientations. Since the lacI gene is not A + T-rich, the contribution of IS1 insertion to spontaneous mutation in general might be underestimated. Single-base frameshift mutations were found only infrequently. In general, they did not occur in runs of a common base. Instead, their occurrence seemed based on the "perfection" of direct or inverted repeats in the local DNA sequence. Three (tandem) duplication events were recovered. No repeated sequences were found that might have determined their endpoints.     

New Suppressors of Frameshift Mutations in SALMONELLA TYPHIMURIUM

Several new types of suppressor mutants have been isolated. These were identified among revertants of mutants originally generated by mutagens other than the acridine-derived ICR191. The new suppressors correct mutations other than those with runs of C or G which are recognized by the previously described suppressors. Several frameshift mutations are corrected by more than one suppressor type. Apparently, the DNA base sequence near these mutant sites includes sites of action for several distinct suppressor types.     

Frameshift suppressor mutations outside the anticodon in yeast proline tRNAs containing an intervening sequence.

Extragenic suppressors of +1 frameshift mutations in proline codons map in genes encoding two major proline tRNA isoacceptors. We have shown previously that one isoacceptor encoded by the SUF2 gene (chromosome 3) contains no intervening sequence. SUF2 suppressor mutations result from the base insertion of a G within a 3'-GGA-5' anticodon, allowing the tRNA to read a 4-base code word. In this communication we describe suppressor mutations in genes encoding a second proline tRNA isoacceptor (wild-type anticodon 3'-GGU-5') that result in a novel mechanism for translation of a 4-base genetic code word. The genes that encode this isoacceptor include SUF7 (chromosome 13), SUF8 (chromosome 8), trn1 (chromosome 1), and at least two additional unmapped genes, all of which contain an intervening sequence. We show that suppressor mutations in the SUF7 and SUF8 genes result in G-to-U base substitutions at position 39 that disrupted the normal G . C base pairing in the last base pair of the anticodon stem adjacent to the anticodon loop. These anticodon stem mutations might alter the size of the anticodon loop and permit the use of a 3'-GGGU-5' sequence within the loop to read 4-base proline codons. Uncertainty regarding the exact structure of the mature suppressor tRNAs results from the possibility that anticodon stem mutations might affect sites of intervening sequence removal. The possible role of the intervening sequence in the generation of mature suppressor tRNA is discussed. Besides an analysis of suppressor tRNA genes, we have extended previous observations of the apparent relationship between tRNA genes and repetitive delta sequences found as solo elements or in association with the transposable element TY1. Hybridization studies and a computer analysis of the DNA sequence surrounding the SUF7 gene revealed two incomplete, inverted delta sequences that form a stem and loop structure located 165 base pairs from the 5' end of the tRNA gene. In addition, sequences beginning 164 base pairs from the 5' end of the trn1 gene also exhibit partial homology to delta. These observations provide further evidence for a nonrandom association between tRNA genes and delta sequences.     

Fidelity of replication of repetitive DNA in mutS and repair proficient Escherichia coli

Replication fidelity is not constant among strains within a species or at all genetic loci within a genome. Altered fidelity of replication may affect patterns of pathogenesis and the evolution of these strains. We have been studying replication fidelity in Escherichia coli, both in laboratory attenuated strains and in food-borne pathogens. To understand the altered patterns of mutagenesis at the molecular level, we used a shuttle vector plasmid with a tRNA mutational marker gene which had been altered to include homopolymeric runs of five, seven and nine [G:C] pairs, as well as non-repetitive DNA. Replication of the plasmid in mutS strains resulted in a 20-fold increase in mutant progeny plasmids. The mutations were almost all (>90%) frameshift mutations, while base substitution mutations were rare. Most mutations were insertions or deletions of one or two [G:C] pairs in the longest homopolymeric runs. Larger deletions (5 to >70bp), also targeted to the repetitive sequence, were likewise common. Mutations increased exponentially with the length of the homopolymeric run. These patterns of mutation, including unexpectedly high levels in repair proficient strains, led to an examination of the E. coli K-12 genome for homopolymeric DNA. This sequence motif was found to be rare, particularly in genes and open reading frames. Amino acid homotrimers were found to avoid usage of homopolymeric codons, even when they are preferred among synonymous codons in E. coli. There appears to be active selection against tandem direct nucleotide repeats in the E. coli genome, correlated with the inability of the organism to accurately replicate such sequence.     

The Influence of Local DNA Sequence and DNA Repair Background on the Mutational Specificity of 1-Nitroso-8-Nitropyrene in Escherichia Coli: Inferences for Mutagenic Mechanisms

We have examined the mutational specificity of 1-nitroso-8-nitropyrene (1,8-NONP), an activated metabolite of the carcinogen 1,8-dinitropyrene, in the lacI gene of Escherichia coli strains which differ with respect to nucleotide excision repair (+/- delta uvrB) and MucA/B-mediated error-prone translesion synthesis (+/- pKM101). Several different classes of mutation were recovered, of which frameshifts, base substitutions, and deletions were clearly induced by 1,8-NONP treatment. The high proportion of point mutations (> 92%) which occurred at G.C sites correlates with the percentage of 1,8-NONP-DNA adducts which occur at the C(8) position of guanine. The most prominent frameshift mutations were -(G.C) events, which were induced by 1,8-NONP treatment in all strains, occurred preferentially in runs of guanine residues, and whose frequency increased markedly with the length of the reiterated sequence. Of the base substitution mutations G.C-->T.A transversions were induced to the greatest extent by 1,8-NONP. The distribution of the G.C-->T.A transversions was not influenced by the nature of flanking bases, nor was there a strand preference for these events. The presence of plasmid pKM101 specifically increased the frequency of G.C-->T.A transversions by a factor of 30-60. In contrast, the -(G.C) frameshift mutation frequency was increased only 2-4-fold in strains harboring pKM101 as compared to strains lacking this plasmid. There was, however, a marked influence of pKM101 on the strand specificity of frameshift mutation; a preference was observed for -G events on the transcribed strand. The ability of the bacteria to carry out nucleotide excision repair had a strong effect on the frequency of all classes of mutation but did not significantly influence either the overall distribution of mutational classes or the strand specificity of G.C-->T.A transversions and -(G.C) frameshifts. Deletion mutations were induced in the delta uvr, pKM101 strain. The endpoints of the majority of the deletion mutations were G.C rich and contained regions of considerable homology. The specificity of 1,8-NONP-induced mutation suggests that DNA containing 1,8-NONP adducts can be processed through different mutational pathways depending on the DNA sequence context of the adduct and the DNA repair background of the cell.     

Oxygen-dependent upstream activation sites of Saccharomyces cerevisiae cytochrome c genes are related forms of the same sequence.

In Saccharomyces cerevisiae, the two genes, CYC1 and CYC7, that encode the isoforms of cytochrome c are expressed at different levels. Oxygen regulation is mediated by the expression of the CYP1 gene, and the CYP1 protein interacts with both CYC1 upstream activation sequence 1 (UAS1) and CYC7 UASo. In this study, the homology between the CYP1-binding sites of both genes was investigated. The most noticeable difference between the CYC1 and CYC7 UASs is the presence of GC base pairs at the same positions in a repeated sequence in CYC7 compared with CG base pairs in CYC1. Directed mutagenesis changing these GC residues to CG residues in CYC7 led to CYC1-like expression of CYC7 both in a CYP1 wild-type strain and in a strain carrying the semidominant mutation CYP1-16 which reverses the oxygen-dependent expression of the two genes. Our results strongly support the hypothesis that the CYP1-binding sites in CYC1 and CYC7 are related forms of the same sequence and that the CYP1-16 protein has altered specificity for the variant forms of the consensus sequences in both genes.     

Induction of genetic duplications and frameshift mutations in Salmonella typhimurium by acridines and acridine mustards: dependence on covalent binding of the mutagen to DNA

Summary The aroC321 allele permits positive selection for the detection of a large genetic duplication that arises in the Salmonella typhimurium chromosome by homologous recombination. Strains that contain both aroC321 and the hisC3076 allele were constructed so that the induction of genetic duplications and frameshift mutations in a run of GC base pairs could be studied simultaneously by selecting for tryptophan and histidine prototrophy, respectively. Using these strains, we examined the ability of 9-aminoacridine, quinacrine, four acridine mustards (ICR-170, ICR-191, ICR-372, and quinacrine mustard) and the nitroacridine Entozon to induce genetic duplications and frameshift mutations. Although all these compounds induce reversion of hisC3076, only the four mustards and Entozon are effective as inducers of genetic duplications under identical treatment conditions. The induction of genetic duplications by acridine mustards, like the toxic and mutagenic effects of these compounds, is enhanced by a deficiency for excision repair caused by a deletion through the uvrB gene. The ineffectiveness of 9-aminoacridine and quinacrine in the test for genetic duplications indicates that simple intercalation is sufficient for the mutagenic effect measured with the hisC3076 allele but that the induction of duplications by the acridine mustards and Entozon requires covalent binding of the chemical to DNA.     

Induction of G.C to A.T transitions by the acridine half-mustard ICR-191 supports a mispairing mechanism for mutagenesis by some bulky mutagens

As the most nucleophilic atom in DNA, the guanine N7 atom is a major site of attack for a large number of chemical mutagens as well as chemotherapeutic agents. Paradoxically, while methylation of guanine N7 is believed to be largely nonmutagenic, aflatoxin B1, among the most potent mutagens, appears to exert its mutagenic activity through adduction at this site. On the basis of an analysis of the specificity of mutations induced by various adduct forms of aflatoxin B1, we have previously proposed mechanisms that can both resolve the paradox and account for the specificity of mutagenesis by aflatoxin B1. The hypothesized mechanisms specify how a bulky guanine N7 lesion can promote G.C to A.T transitions as well as frame-shift mutations. Since the proposed mechanisms are in principle lesion-independent, a simple test of the proposed mechanisms would be to examine the specificity of mutations induced by a structurally different bulky guanine N7 adduct. Toward this goal, M13 replicative form DNA was subjected to in vitro adduction with the acridine mutagen ICR-191 and transfected into Escherichia coli. Mutations in the LacZ(alpha) gene segments were scored and defined at the sequence level. The results show that ICR-191 adduction induces both base substitutions and frame shifts with near-equal efficiency. A clear majority of base substitutions were G.C to A.T transitions. On the other hand, unlike aflatoxin B1 which could induce both -1 and +1 frameshifts, ICR-191 appears to predominantly induce +1 frame shifts. This preference appears to arise by lesion-dependent mechanisms.(ABSTRACT TRUNCATED AT 250 WORDS)     

N-methyl-N'-nitro-N-nitrosoguanidine-induced mutation in a RecA strain of Escherichia coli

274 N-methyl-N'-nitro-N-nitrosoguanidine (MNNG)-induced forward mutations in the lacI gene of an Escherichia coli RecA- strain were cloned and sequenced. Base substitutions accounted for 264 mutations and consisted of 261 G:C----A:T transitions (including one double mutant with two G:C----A:T transitions separated by 25 base pairs), two A:T----G:C transitions and one A:T----T:A transversion. Therefore, 263 of the 274 mutations (all the transitions) can be explained as a result of the direct mispairing of O6-methylguanine, and O4-methylthymine residues during DNA synthesis. The source of the transversion is not known. The remaining mutations, one 16-base pair deletion, two -1 frameshifts and 7 frameshifts at the lacI frameshift hotspot, are located in runs of identical bases or flanked by directly repeated DNA sequences and can therefore be explained by template slippage events during DNA synthesis. The observed distribution of mutations recovered is identical to that found in a RecA+ background indicating little involvement of RecA function in MNNG-induced mutation. Analysis of neighbouring base sequence revealed that the G:C----A:T transition was 6 times more likely to be recovered if the mutated guanine residue was preceded by a purine rather than a pyrimidine. A most striking aspect of this distribution concerns particular residues in the core domain of the lac repressor protein. Within this domain the great majority of mutations generate nonsense codons or alter Gly codons.     

Spontaneous Mutation at the Mtr Locus in Neurospora: The Molecular Spectrum in Wild-Type and a Mutator Strain

Sequence analysis of 34 mtr mutations has yielded the first molecular spectrum of spontaneous mutants in Neurospora crassa. The great majority of the mutations are base substitutions (48%) or deletions (35%). In addition, sequence analysis of the entire mtr region, including the 1472-base pair open reading frame and 1205 base pairs of flanking DNA, was performed in both the Oak Ridge and Mauriceville strains of Neurospora, which are known to be divergent at the DNA level. Sixteen sequence differences between these two strains have been found in the mtr region, with 13 of these in DNA flanking the open reading frame. The differences consisted of base substitutions and small frameshifts at monotonic runs. This set of sequence differences has allowed a comparison of mutations in unselected DNA to those mutations that produce a phenotypic signal. We have isolated a mutator strain (mut-1) of Neurospora in which the spontaneous mutation rate at various loci is as much as 80-fold higher than in the non-mutator (wild type). Twenty-one mtr mutations in the mutator background have been sequenced and compared to the non-mutator spectrum, revealing a striking increase in -1 frameshift mutations. These frameshifts occur exclusively within or adjacent to monotonic runs and can be explained by small slippage events during DNA replication. This argues for a role of the mut-1 gene in this process.     

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.