Mechanisms of ultraviolet-induced mutation. Mutational spectra in the Escherichia coli lacI gene for a wild-type and an excision-repair-deficient strain

We have analyzed the DNA sequence changes in a total of 409 ultraviolet light-induced mutations in the lacI gene of Escherichia coli: 227 in a Uvr+ and 182 in a UvrB- strain. Both differences and similarities were observed. In both strains the mutations were predominantly (60 to 75%) base substitutions, followed by smaller contributions of single-base frameshifts, deletions and frameshift hotspot mutations. The base substitutions proved largely similar in the two strains but differences were observed among the single-base frameshifts, the deletions and the hotspot mutations. Among the base substitutions, both transitions (72.5%) and transversions (27.5%) were observed. The largest single group was G.C----A.T (60% of all base substitutions). The sites where G.C----A.T changes occurred were strongly correlated (97.5%) with sequences of adjacent pyrimidines, indicating mutation targeted ultraviolet photoproducts. Comparable amounts of mutation occurred at cytosine/cytosine and (mixed) cytosine/thymine sites. From an analysis of the prevalence of mutation at either the 5' or 3' side of a dipyrimidine, we conclude that both cyclobutane dimers and (6-4) lesions may contribute to mutation. Despite the general similarity of the base-substitution spectra between the wild-type and excision-defective strains, a number of sites were uniquely mutable in the UvrB- strain. Analysis of their surrounding DNA sequences suggested that, in addition to damage directly at the site of mutation, the potential for nearby opposite-strand damage may be important in determining the mutability of a site. The ultraviolet light-induced frameshift mutations were largely single-base losses. Inspection of the DNA sequences at which the frameshifts occurred suggested that they resulted from targeted mutagenesis, probably at cyclobutane pyrimidine dimers. The prevalence of frameshift mutations at homodimers (TT or CC) suggests that their formation involves local misalignment (slippage) and that base-pairing properties are partially retained in cyclobutane dimers. While the frameshift mutations in the Uvr+ strain were distributed over many different sites, more than half in the UvrB- strain were concentrated at a single site. Ultraviolet light-induced deletions as well as frameshift hotspot mutations (+/- TGGC at positions 620 to 632) are considered to be examples of untargeted or semitargeted mutagenesis. Hotspot mutations in the Uvr+ strain showed an increased contribution by (-)TGGC relative to (+)TGGC, indicating that ultraviolet light may specifically promote the loss of the four bases.(ABSTRACT TRUNCATED AT 400 WORDS)     

Mutagenesis by 8-methoxypsoralen plus near-UV treatment: analysis of specificity in the lacI gene of Escherichia coli

We have studied the specificity of mutation induced by PUVA treatment in the lacI gene of E. coli. Cells were exposed to near UV (≈365 nm) in the presence of 8-methoxypsoralen under conditions yielding about 7% survival and a 10-fold increase in mutation frequency. The cloning and sequencing of 131 mutants recovered following PUVA treatment revealed that almost all classes of mutation including base substitutions, frameshifts and deletions were induced. The distribution of mutations was non-random and a region of the lacI gene was found to be virtually silent for all classes of mutation. Intriguingly, the broad spectrum of mutation is accompanied by the recovery of mutation at two spontaneous hotspots. We observed a 7-fold increase at a frameshift hotspot involving the gain or loss of a tetramer tandemly repeated 3 times at this site and a 23-fold increase at an A:T→G:C transition hotspot located at the +6 position in the lac operator region. However, despite the presence of these spontaneous hotspots, the mutational spectrum recovered following PUVA treatment was unique and a detailed analysis of the different classes of mutations indicates a role for DNA repair of both monoadducts and cross-links in the production of mutation.     

DNA Sequence Analysis of Mutagenicity and Site Specificity of Ethyl Methanesulfonate in Uvr+ and UvrB - Strains of ESCHERICHIA COLI

EMS-induced mutations within a 180 base pair region of the lacI gene of E. coli were cloned and sequenced. In total, 105 and 79 EMS-induced mutations from a Uvr+ and a UvrB- strain, respectively, were sequenced. The specificity of EMS-induced mutagenesis was very similar in the two strains; G:C----A:T transitions accounted for all but three of the mutants. The overall frequency of induced mutation was fivefold higher in the UvrB- strain compared to the Uvr+ strain. This demonstrates, at the DNA sequence level, that the presumed premutagenic lesion, O6-ethylguanine, is subject to repair by the uvrABC excision repair system of E. coli. An analysis of mutation frequencies with respect to neighboring base sequence, in the two strains, shows that O6-ethylguanine lesions adjacent to A:T base pairs present better targets for the excision repair machinery than those not adjacent to A:T base pairs.     

Mutational specificity of the dnaE173 mutator associated with a defect in the catalytic subunit of DNA polymerase III of Escherichia coli.

We developed a system to examine forward mutations that occurred in the rpsL gene of Escherichia coli placed on a multicopy plasmid. Using this system we determined the mutational specificity for a dnaE173 mutator strain in which the editing function of DNA polymerase III is impeded. The frequency of rpsL- mutations increased 32,000-fold, due to the dnaE173 mutator, and 87 independent rpsL- mutations in the mutator strain were analyzed by DNA sequencing, together with 100 mutants recovered from dnaE+ strain, as the control. While half the number of mutations that occurred in the wild-type strain were caused by insertion elements, no such mutations were recovered from the mutator strain. A novel class of mutation, named "sequence substitution" was present in mutants raised in the dnaE173 strain; seven sequence substitutions induced in the mutator strain occurred at six sites, and all were located in quasipalindromic sequences, carrying the GTG or CAC sequence at one or both endpoints. While other types of mutation were found in both strains, single-base frameshifts were the most frequent events in the mutator strain. Thus, the mutator effect on this class of mutation was 175,000-fold. A total of 95% of the single-base frameshifts in the mutator strain were additions, most of which occurred at runs of A or C bases so as to increase the number of identical residues. Base substitutions, the frequency of which was enhanced 25,000-fold by the mutator effect, occurred primarily at several hotspots in the mutator strain, whereas those induced in the wild-type strain were more randomly distributed throughout the rpsL sequence. The dnaE173 mutator also increased the frequency of duplications 28,000-fold. Of the three duplications recovered from the mutator strain, one was a simple duplication, the region of which was flanked by direct repeats. The other duplications were complex, one half part of which was in the inverted orientation of a region containing two sets of inverted repeats. The same duplications were also recovered from the wild-type strain. The present data suggest that dnaE173 is a novel class of mutator that sharply induces sequence-directed mutagenesis, yielding high frequencies of single base frameshifts, duplications with inversions, sequence substitutions and base substitutions at hotspots.     

Deoxyuridine misincorporation causes site-specific mutational lesions in the lacI gene of Escherichia coli

Spontaneous forward mutation in lacI was analyzed by DNA sequencing in a Dut- strain of E. coli. Hyperuracil incorporation into DNA due to the defect in deoxyuridinetriphosphatase caused a 5-fold increase in mutation frequency. Deletion, duplication and base-substitution frequencies were all enhanced in the Dut- strain. However, the analysis of the specificity of mutation revealed a remarkable site- and class-specificity. For example, base substitutions at a single site, a G:C = greater than A:T transition (Ochre 34) accounted for 55% of the base substitutions recovered. The spontaneous A:T = greater than G:C hotspot at position +6 at the lac operator was also recovered at an enhanced frequency in the Dut- strain where it accounted for 25% of the base substitutions. Many of the deletion and duplication events were recovered more than once; most had endpoints in A/T rich regions. The spontaneous frameshift hotspot involving the gain or loss of 5'-CTGG-3' in a region where this tetramer is tandemly repeated 3 times, was also greatly enhanced. No frameshifts involving a single base pair nor IS1 insertions were identified among the 86 lacI mutants sequenced. The analysis of these events reveals them to be generally consistent with a mechanism involving AP sites generated by the removal of misincorporated uracil by uracil-N-glycosylase. Considering the number of potential AP sites (approximately 1 per 170 base pairs) E. coli is remarkably refractory to mutational consequences of deoxyuridine misincorporation in place of thymidine.     

Sites of preferential induction of cyclobutane pyrimidine dimers in the nontranscribed strand of lacI correspond with sites of UV-induced mutation in Escherichia coli

An approach utilizing fluorescence-activated DNA sequencing technology was used to study the position and frequency of UV-induced lesions in the lacI gene of Escherichia coli. The spectrum of sites of UV damage in the NC+ region of the gene was compared with a published spectrum of UV-induced mutation in lacI (Schaaper, R.M., Dunn, R.L., and Glickman, B.W. (1987) J. Mol. Biol. 198, 187-202). On average, the frequency of UV-induced lesions in the nontranscribed strand was higher than that in the transcribed strand in the region analyzed. A large fraction of mutations occurs at sites of UV-induced lesions in the nontranscribed strand, but not in the transcribed strand. This bias is reduced in an excision repair deficient (UvrB-) strain. In addition, mutations occur overwhelmingly at sites where a dipyrimidine sequence is present in the nontranscribed strand. This bias is also markedly reduced in the UvrB- strain. In light of recent work Mellon and Hanawalt (Mellon, I., and Hanawalt, P.C. (1989) Nature 342, 95-98) describing the preferential removal of cyclobutane dimers from the transcribed strand of the expressed lacZ gene in E. coli, our data suggest that preferential strand repair may have a significant effect on mutagenesis.     

Influence of uvrB and pKM101 on the spectrum of spontaneous, UV- and gamma-ray-induced base substitutions that revert hisG46 in Salmonella typhimurium

Oligonucleotide probes were used to identify base substitutions in 1089 revertants of hisG46 in Salmonella typhimurium that arose spontaneously or following irradiation with UV- or gamma-rays. The hisG46 allele, carrying a mutant CCC codon (Pro) in place of the wild-type codon CTC (Leu69) reverted via 6 distinguishable mutational events--C to T transitions at codon sites 1 or 2, C to A or C to G transversions at codon site 1, C to A at codon site 2, and an extragenic suppressor mutation. The distribution of hisG46 revertants differed among treatments and was influenced by the DNA-repair capacity of the bacteria. Plasmid pKM101 enhanced the frequencies of both spontaneous and induced mutations; transversion events were enhanced more efficiently by pKM101 than were transition events. Compared to Uvr+ bacteria, Uvr- bacteria had higher frequencies of spontaneous and induced mutations; transition mutations were enhanced more efficiently than were transversion mutations. The influence of DNA-repair activities on the mutational spectra provides some insights on the origins of spontaneous and UV-induced mutations.     

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.     

Escherichia coli mutator (Delta)polA is defective in base mismatch correction: the nature of in vivo DNA replication errors

We constructed a set of Escherichia coli strains containing deletions in genes encoding three SOS polymerases, and defective in MutS and DNA polymerase I (PolI) mismatch repair, and estimated the rate and specificity of spontaneous endogenous tonB(+)-->tonB- mutations. The rate and specificity of mutations in strains proficient or deficient in three SOS polymerases was compared and found that there was no contribution of SOS polymerases to the chromosomal tonB mutations. MutS-deficient strains displayed elevated spontaneous mutation rates, consisting of dominantly minus frameshifts and transitions. Minus frameshifts are dominated by warm spots at run-bases. Among 57 transitions (both G:C-->A:T and A:T-->G:C), 35 occurred at two hotspot sites. PolI-deficient strains possessed an increased rate of deletions and frameshifts, because of a deficiency in postreplicative deletion and frameshift mismatch corrections. Frameshifts in PolI-deficient strains occurred within the entire tonB gene at non-run and run sequences. MutS and PolI double deficiency indicated a synergistic increase in the rate of deletions, frameshifts and transitions. In this case, mutS-specific hotspots for frameshifts and transitions disappeared. The results suggested that, unlike the case previously known pertaining to postreplicative MutS mismatch repair for frameshifts and transitions and PolI mismatch repair for frameshifts and deletions, PolI can recognize and correct transition mismatches. Possible mechanisms for distinct MutS and PolI mismatch repair are discussed. A strain containing deficiencies in three SOS polymerases, MutS mismatch repair and PolI mismatch repair was also constructed. The spectrum of spontaneous mutations in this strain is considered to represent the spectrum of in vivo DNA polymerase III replication errors. The mutation rate of this strain was 219x10(-8), about a 100-fold increase relative to the wild-type strain. Uncorrected polymerase III replication errors were predominantly frameshifts and base substitutions followed by deletions.     

Cellular determinants of the mutational specificity of 1-nitroso-6-nitropyrene and 1-nitroso-8-nitropyrene in the lacI gene of Escherichia coli.

We have characterized 202 lacI⁻ mutations, and 158 dominant lacI^−d mutations following treatment of Escherichia coli strains NR6112 and EE125 with 1-nitroso-6-nitropyrene (1,6-NONP), an activated metabolite of the carcinogen 1,6-dinitropyrene. In all, 91% of the induced point mutations occurred at G:C residues. The −(G:C) frameshifts were the dominant mutational class in the lacI⁻ collections of both NR6112 and EE125, and in the lacI^−d collection of NR6112. Frameshift mutations occurred preferentially in runs of guanine residues, and their frequency increased with the length of the reiterated sequence. In strain EE125, which contained the plasmid pKM101, there was a marked stimulation in the frequency of base substitution mutations that was particularly apparent in the lacI^−d collection. This study completes a comprehensive analysis of 1194 lacI⁻ and 348 lacI^−d mutations induced by either 1,6-NONP or its positional isomer 1-nitroso-8-nitropyrene (1,8-NONP) in strains of E. coli that differ with regard to their ability to carry out nucleotide excision repair and/or their ability to express the translesion synthesis DNA polymerase RI (MucAB) encoded by plasmid pKM101. Among the mutations are 763 frameshift mutations, 367 base substitutions and 47 deletions; these mutations have been characterized at more than 300 distinct sites in the lacI gene. Our studies provide detailed insight into the DNA sequence alterations and mutational mechanisms associated with dinitropyrene mutagenesis. We review the mutational spectra, and discuss cellular lesion repair or tolerance mechanisms that modulate the observed mutational specificity.     

Involvement of separate pathways in the repair of mutational and lethal lesions induced by a monofunctional sulfur mustard.

The mutagenic and lethal effects of a monofunctional sulfur mustard, 2-chloro-ethylethylsulfide (CEES), have been studied in a number of repair deficient variants of Escherichia coli K12, B/r and B. The results indicate that CEES induces a (pre)mutational lesion which is subject to Uvr+-excision-repair. Extensive CEES-induced mutagenesis can occur in exrA- uvrA- and recA- uvrB- variants suggesting that the majority of the mutations in Uvr-bacteria do not arise from error-prone repair. These findings are similar to results previously reported with a volatile degradation product of captan and with ethyl methanesulfonate (EMS) but differ from those reported with methyl methanesulfonate (MMS). It is hypothesized that CEES alkylates guanine at the O-6 position (R-O-6-G) and that this R-O-6-G which is Uvr+-excisable is directly mutagenic by producing G-C to A-T transitions during replication. Reduced levels of induced mutation frequencies observed in an endonuclease II-deficient variant lead us to postulate that, in constrast to Uvr- bacteria, CEES-induced mutation in wild-type cells arise from error-prone repair of apurinic sites. Analysis of the lethal actions of CEES indicates that the lesion produced is largely unexcisable by the Uvr+ system. Host-cell reactivation of CEES-treated TI bacteriophage shows that the production of the (pre)ethal lesion is dependent on both the initial dose and post-treatment incubation. The efficient repair of the (pre)ethal lesion requires both endonuclease II and polymerase I. Moreover, deficiencies of these two enzymes rendered bacteria more sensitive to the cytotoxic action of CEES. It is postulated that the lethal mechanism of CEES involves: (I) alkylation at the N-3 position of adenine and the N-7 position of guanine; (2) spontaneous depurination of these alkylated bases; and (3) production of apurinic sites which are lethal unless repaired by the endonuclease II-polymerase I excision-repair system.     

Mutagenic specificity of ultraviolet light

Genetic and sequencing studies of ultraviolet light (u.v.)-induced mutations in the lacI gene of Escherichia coli show the following: u.v. stimulates many types of mutations. In lacI, base substitutions account for 60 to 65% of the observed mutations, small frameshifts 30 to 35%, and deletions of more than several base-pairs approximately 5%. A comparison of the mutational spectrum of u.v.-induced mutations with those of other SOS-dependent mutagens and with the mutations produced by inducing the SOS system in the absence of mutagenic treatment indicates that most u.v.-induced base substitutions are "targeted", resulting from premutational lesions across from the site of the mutations. Among base substitutions, both transitions and transversions occur, although the most favored mutational sites involve G X C----A X T transitions. G X C----A X T transitions are induced preferentially at sites of adjacent pyrimidines. In one case the conversion of a site from -A-C-A- to -T-C-A- results in a 15-fold increase in u.v.-induced C----T transitions. Frameshifts at certain sites are well-induced by u.v., and the largest hotspot in the I gene involves the loss of an (sequence in text) base pair from a (sequence in text) sequence. Of 25 frameshifts detected by DNA sequencing, 23 mutations at seven different sites result from the elimination of a single base-pair, and two mutations result from the elimination of two base-pairs. No additions were detected. The use of a lacI-Z fusion system, which allows direct selection of frameshifts of either sign, reveals that throughout the entire gene frameshifts that eliminate a single base-pair (-1) predominate by a factor of 20 or more over frameshifts that add a single base-pair (+1). In one case a two-base-pair elimination occurs frequently, resulting in the loss of a -C-T- sequence (on one strand), or a -T-C- sequence, from a -C-T-C-T-C-T-C- sequence. For both frameshifts and base substitutions, some aspect of the larger surrounding sequence beyond the nearest neighbors can influence mutation rates by as much as 50-fold, thus determining which sites are seen as hotspots. The bearing of these and other data on the detailed mechanism of mutagenesis is considered in the Discussion.     

Spectrum of spontaneous frameshift mutations. Sequences of bacteriophage T4 rII gene frameshifts

The DNA sequences of 185 independent spontaneous frameshift mutations in the rIIB gene of bacteriophage T4 are described. Approximately half of the frameshifts, including those at hot spot sites, are fully consistent with classical proposals that frameshift mutations are produced by a mechanism involving the misaligned pairing of repeated DNA sequences. However, the remaining frameshifts are inconsistent with this model. Correlations between the positions of two base-pair frameshifts and the bases of DNA hairpins suggest that local DNA topology might influence frameshift mutation. Warm spots for larger deletions share the property of having endpoints adjacent to DNA sequences whose complementarity to sequences a few base-pairs away suggest that non-classical DNA misalignments may participate in deletion mutation. A model for duplication mutation as a consequence of strand displacement synthesis is discussed. In all, 15 frameshifts were complex combinations of frameshifts and base substitutions. Three of these were identical, and have extended homology to a sequence 256 base-pairs away that is likely to participate in the mutational event; the remainder are unique combinations of frameshifts and transversions. The frequency and diversity of complex mutants suggest a challenge to the assumption that the molecular evolution of DNA must depend primarily upon the accumulation of single nucleotide changes.     

Specificity of spontaneous mutation in the lacI gene cloned into bacteriophage M13

We have studied the specificity of spontaneous mutation in the lacI gene of Escherichia coli cloned into bacteriophage M13. The comparison of the spectrum of 85 spontaneous mutations with that of the lacI gene carried on an E. coli F' episone revealed the following characteristics: (i) base substitution was predominant, accounting for 80% of spontaneous events compared with only 11% on the F' episome; (ii) among the base substitutions, the majority were G:C----A:T transitions (86%); (iii) not one mutation recovered on M13 corresponded to a mutation at the spontaneous hotspots seen in the F' spectrum (i.e., neither the addition or deletion of the tetramer 5'-CTGG-3' at position 620-631 nor the A:T----G:C transition at position +6 of lacO were recovered). The enhanced rate of cytosine deamination in single-stranded DNA, the unique replication mechanism and the refractory nature of single-stranded DNA to excision-repair processes present likely explanations for the observed mutational spectrum.     

Comparison of the Ames test and a newly developed assay for detection of mutagenic pollution of marine environments

Mismatch repair (MMR) genes, such as Msh2, are classified as "mutator" genes, responsible for the microsatellite instability identified in many tumors. In the current study, the mutation frequency and mutational spectrum in thymic lymphoma arising in Msh2 deficient mice are investigated. Thymic lymphoma developed in Msh2-/- background displayed an eight to nine-fold increase in mutation frequency compared to the normal thymi in Msh2 deficient animals. Sequencing demonstrated significantly different mutational spectra between normal thymus tissue and thymic lymphomas in Msh2-/- mice (P=0.02). The tumor mutational spectrum is characterized by an increase in base substitutions occurring at A:T sites, and multiple mutations, as well as a minor increase in -1 frameshifts. We analyzed mutations in different parts of the tumors, and different regional hotspots could be identified. Several hotspot mutations that are a rare event in normal tissues were identified in the tumor tissues. We conclude that thymic lymphomas arising in Msh2 deficient genetic background are hypermutable and the altered mutational spectrum might be an indication of infidelity of DNA replication during tumorigenesis.     

Cellular determinants of the mutational specificity of 1-nitroso-6-nitropyrene and 1-nitroso-8-nitropyrene in the lacI gene of Escherichia coli

We have characterized 202 lacI⁻ mutations, and 158 dominant lacI^−d mutations following treatment of Escherichia coli strains NR6112 and EE125 with 1-nitroso-6-nitropyrene (1,6-NONP), an activated metabolite of the carcinogen 1,6-dinitropyrene. In all, 91% of the induced point mutations occurred at G:C residues. The −(G:C) frameshifts were the dominant mutational class in the lacI⁻ collections of both NR6112 and EE125, and in the lacI^−d collection of NR6112. Frameshift mutations occurred preferentially in runs of guanine residues, and their frequency increased with the length of the reiterated sequence. In strain EE125, which contained the plasmid pKM101, there was a marked stimulation in the frequency of base substitution mutations that was particularly apparent in the lacI^−d collection. This study completes a comprehensive analysis of 1194 lacI⁻ and 348 lacI^−d mutations induced by either 1,6-NONP or its positional isomer 1-nitroso-8-nitropyrene (1,8-NONP) in strains of E. coli that differ with regard to their ability to carry out nucleotide excision repair and/or their ability to express the translesion synthesis DNA polymerase RI (MucAB) encoded by plasmid pKM101. Among the mutations are 763 frameshift mutations, 367 base substitutions and 47 deletions; these mutations have been characterized at more than 300 distinct sites in the lacI gene. Our studies provide detailed insight into the DNA sequence alterations and mutational mechanisms associated with dinitropyrene mutagenesis. We review the mutational spectra, and discuss cellular lesion repair or tolerance mechanisms that modulate the observed mutational specificity.     

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.     

Induced mutation spectra at the upp locus in Salmonella typhimurium: response of the target gene in the FU assay to mechanistically different mutagens

A novel forward mutation assay has been developed in Salmonella typhimurium based on resistance to 5-fluorouracil (FU). The mutational target in the FU assay was determined to be the uracil phosphoribosyl transferase (upp) gene. To validate the upp gene as a suitable target for monitoring a variety of induced mutations, the mutational specificity was determined for five mechanistically different mutagens. The mutagens included a polycyclic hydrocarbon (benzo[a]pyrene, B[a]P), SN1 and SN2 alkylating agents (N-nitroso-N-methylurea, MNU, and methyl methanesulfonate, MMS, respectively), a frameshift mutagen (ICR-191), and an oxidative-damaging agent (hydrogen peroxide, H2O2). Induced mutation frequencies were measured in the presence and absence of the plasmid pKM101 (strain FU100 and FU1535, respectively). pKM101 renders FU100 more susceptible to induced mutation by providing error-prone replicative bypass of DNA adducts. B[a]P, MMS, and H2O2 failed to induce the mutant frequency in FU1535, demonstrating the dependence of pKM101 on induced mutations with these agents. ICR-191 and MNU were not dependent on pKM101, and did significantly induce mutations in FU1535. In contrast to FU1535, all agents significantly induced mutations in FU100. Approximately 60 independent mutants were sequenced for each agent that significantly induced the mutant frequency above background. The resulting mutational spectra illustrated predictable molecular fingerprints based on known mutagenic mechanisms for each agent. The predominant mutations observed were G:C to T:A transversions for B[a]P, A:T to T:A and G:C to T:A transversions for MMS, G:C to T:A transversions and A:T frameshifts for H2O2, G:C frameshifts for ICR-191, and G:C to A:T transitions for MNU. It can be concluded that the upp gene in the FU assay is a sensitive and suitable target to monitor a variety of induced mutations in Salmonella.     

Mechanisms of spontaneous mutation in DNA repair-proficient Escherichia coli

This paper describes the DNA sequence analysis of 729 independent spontaneous lacI⁻ mutation This total is comprised of 478 novel mutations and 251 previously described events, and therefore should allow a more comprehensive view of spontaneous mutation in Escherichia coli. The spectrum is dominated by a hotspot (71% of all events). Mutations at this site consist of related addition and deletion events involving a number of repetitive sequences. Here we discuss how the frequency and proportion of these events vary in different DNA repair-deficient genetic backgrounds. The distribution of non-hotspot events includes base substitutions (38%), deletions (35%), frameshifts (14%), duplications (4%) and insertion elements (4%). G:C → A:T events dominate among base substitutions, while G:C → C:G events are the least common; the remaining types of base substitution are equally represented. Among deletions, a significant number do not display repeated sequences at their endpoints (26/72). However, almost all multiply recovered events (15/17) possess repeated sequences capable of accounting for the deletion endpoints. Similarily, over of all duplications recovered (5/7) display repeated endpoints. Single-base frameshifts are equally divided between A:T and G:C sites, in each case (−) 1 events occur 3-fold more frequently that (+)1 events. A comparative analysis of each mutational class recovered to lacI⁻ spectra available in a variety of DNA repair/metabolism-deficient strains is presented here in an attempt to assess possible contributions from chemical, physical and enzymic sources of damage.     

The distribution of UV damage in the lacI gene of Escherichia coli: correlation with mutation spectrum.

We have determined the UV (254 nm) damage distribution in the transcribed and non-transcribed strands of the i-d region of the Escherichia coli lacI gene. The locations of replication blocking lesions were revealed as termination sites of T7 DNA polymerase and/or T4 DNA polymerase 3'-5' exonuclease. Termination products, i.e. both cyclobutane pyrimidine dimers and 6-4 photoproducts, were resolved and analysed on an automated DNA sequencer. These two major photoproducts are not randomly distributed along the gene, but occur in clusters, in longer runs of pyrimidines. We also have compared the UV damage distribution with the previously reported UV-induced base substitutions in the same region. Mutational hotspots, in both repair-deficient and repair-proficient strains of E. coli, are all located in stretches of pyrimidines, and thus correlate well with the distribution of photolesions. One mutational hotspot in the wild-type strain may reflect the high frequency of closely opposed lesions. To explain the other mutational hotspots, we propose that the repair of UV lesions is impaired due to the local conformation of the DNA, which might deviate from the B-form. This hypothesis is supported by the excess of mutational hotspots in pyrimidine runs in the Uvr+ strain compared to Uvr-. Runs of pyrimidines thus represent both damage- and mutation-prone sequences following UV treatment.