Hydrogen peroxide induces G:C to TA and G:C to C:G transversions in the supF gene of Escherichia coli

A vector plasmid, pZ189, carrying an Escherichia coli supF gene as a target for mutations, was treated with a combination of hydrogen peroxide and Fe³⁺/EDTA complex and propagated in E. coli host cells that had been induced for SOS functions by ultraviolet irradiation. The mutations frequency increased by up to 30-fold over spontaneous background levels with increasing concentrations of hydrogen peroxide. The increase in mutation frequency correlated with an increase in the formation of 8-hydroxydeoxyguanosine in the pZ189 DNA. Sequence analysis of 82 independent supF mutant plasmids revealed that 70 mutants contained base substitutions, with 63 of the 70 involving a G:C base pair, and with G:CC:G (28 cases) and G:CT:A (26 cases) transversions predominating. Investigation of the influence of the local DNA sequence on the transversions revealed that the guanine at the center of the triplet 5-PuGA-3 was five times more likely to mutate after treatment with hydrogen peroxide than that at the center of 5PyGN3. G:CT:A transversions presumably resulted from mispairing of an altered G (probably 8-hydroxydeoxyguanosine) with deoxyadenosine. The origin of the G:CC:G transversions may be an as yet unidentified lesion generated by hydrogen peroxide. Mutagenic hotspots for base substitutions were found at positions 133, 160 and 168. Mutation spectra and the positions of mutagenic hotspots, when compared with a previously determined spontaneous mutagenesis spectrum, also provide information on the mechanism of spontaneous mutagenesis.     

G:C-->T:A and G:C-->C:G transversions are the predominant spontaneous mutations in the Escherichia coli supF gene: an improved lacZ(am) E. coli host designed for assaying pZ189 supF mutational specificity.

Summary Escherichia coli K12 strain KS40 and plasmid pKY241 were designed for easy screening of supF mutations in plasmid pZ189. KS40 is a nalidixic acid-resistant (gyrA) derivative of MBM7070 (lacZ(am)CA7020). Using in vitro mutagenesis, an amber mutation was introduced into the cloned gyrA structural gene, of E. coli, to give pKY241, a derivative of pACYC184. When KS40 containing pKY241 (designated KS40/pKY241) is transformed with pZ189, nalidixic acid-resistant GyrA protein is produced from the chromosomal gyrA gene and wild-type GyrA protein from pKY241 because of the suppression of the gyrA amber mutation by supF. It is known that the wild-type, otherwise nalidixic acid-sensitive, phenotype is dominant over the nalidixic acid-resistant phenotype. Thus, KS40/pKY241 gives rise to nalidixic acid-sensitive colonies when it carries a pZ189 plasmid with an active supF suppressor tRNA. If the supF gene on the plasmid carries an inactivating mutation then KS40/pKY241 will form nalidixic acid-resistant colonies. By using this system, the spontaneous mutational frequency of the supF gene on pZ189 was calculated to be 3.06 × 10^–7 per replication. Among 51 independent supF mutations analyzed by DNA sequencing, 63% were base substitutions, 25% IS element insertions, 9.6% deletions and 1.9% single-base frameshifts. The base substitutions included both transversions (84.8%) and transitions (15.2%), the largest single group being G:C to T:A transversions (45.4% of the base substitutions). These results demonstrate that the KS40/pKY241 system we have developed can be used to characterize the DNA sequence changes induced by mutagens that give very low mutational frequencies.     

Glyoxal, a major product of DNA oxidation, induces mutations at G:C sites on a shuttle vector plasmid replicated in mammalian cells.

Glyoxal is a major product of DNA oxidation in which Fenton-type oxygen free radical-forming systems are involved. To determine the mutation spectrum of glyoxal in mammalian cells and to compare the spectrum with those observed in other experimental systems, we analyzed mutations in a bacterial suppressor tRNA gene (supF) in the shuttle vector plasmid pMY189. We treated pMY189 with glyoxal and immediately transfected it into simian COS-7 cells. The cytotoxicity and mutation frequency increased according to the dose of glyoxal. The majority of glyoxal-induced mutations (48%) were single-base substitutions. Eighty three percent of the single-base substitutions occurred at G:C base pairs. Among them, G:C-->T:A transversions were predominant, followed by G:C-->C:G transversions and G:C-->A:T transitions. A:T-->T:A transversions were also observed. Mutational hotspots within the supF gene were detected. These results suggest that glyoxal may play an important role in mutagenesis induced by oxygen free radicals.     

Methylglyoxal induces G:C to C:G and G:C to T:A transversions in the supF gene on a shuttle vector plasmid replicated in mammalian cells

We previously reported that the majority of base-pair substitutions induced by an endogenous mutagen, methylglyoxal, were G:C-->T:A transversions and G:C-->A:T transitions in wild-type and nucleotide excision repair (NER)-deficient (uvrA or uvrC) Escherichia coli strains. To investigate the mutation spectrum of methylglyoxal in mammalian cells and to compare the spectrum with those detected in other experimental systems, we analyzed mutations in a bacterial suppressor tRNA (supF) gene in the shuttle vector plasmid pMY189. We treated pMY189 with methylglyoxal and immediately transfected it into simian COS-7 cells. The cytotoxicity and the mutation frequency (MF) increased according to the dose of methylglyoxal. In the mutants induced by methylglyoxal, multi-base deletions were predominant (50%), followed by base-pair substitutions (35%), in which 89% of the substitutions occurred at G:C sites. Among them, G:C-->C:G and G:C-->T:A transversions were predominant. The overall distribution of methylglyoxal-induced mutations detected in the supF gene was different from that for the spontaneous mutations. These results suggest that methylglyoxal may take part in causing G:C-->C:G and G:C-->T:A transversions in vivo.     

Characterization of TCHQ-induced genotoxicity and mutagenesis using the pSP189 shuttle vector in mammalian cells

Tetrachlorohydroquinone (TCHQ) is a major toxic metabolite of the widely used wood preservative, pentachlorophenol (PCP), and it has also been implicated in PCP genotoxicity. However, the underlying mechanisms of genotoxicity and mutagenesis induced by TCHQ remain unclear. In this study, we examined the genotoxicity of TCHQ by using comet assays to detect DNA breakage and formation of TCHQ-DNA adducts. Then, we further verified the levels of mutagenesis by using the pSP189 shuttle vector in A549 human lung carcinoma cells. We demonstrated that TCHQ causes significant genotoxicity by inducing DNA breakage and forming DNA adducts. Additionally, DNA sequence analysis of the TCHQ-induced mutations revealed that 85.36% were single base substitutions, 9.76% were single base insertions, and 4.88% were large fragment deletions. More than 80% of the base substitutions occurred at G:C base pairs, and the mutations were G:C to C:G, G:C to T:A or G:C to A:T transversions and transitions. The most common types of mutations in A549 cells were G:C to A:T (37.14%) and A:T to C:G transitions (14.29%) and G:C to C:G (34.29%) and G:C to T:A (11.43%) transversions. We identified hotspots at nucleotides 129, 141, and 155 in the supF gene of plasmid pSP189. These mutation hotspots accounted for 63% of all single base substitutions. We conclude that TCHQ induces sequence-specific DNA mutations at high frequencies. Therefore, the safety of using this product would be carefully examined.     

Genetic studies of the lac repressor. IV. Mutagenic specificity in the lacI gene of Escherichia coli.

An extensive set of amber and ochre sites in the lacI gene has been characterized with respect to the base change required to generate the nonsense codon (Miller et al., 1977; Coulondre &; Miller, 1977). These mutations have been used to analyze the forward mutational spectrum of a series of mutagens in Escherichia coli. The sites induced by N′-methyl-N′-nitro-N-nitrosoguanidine, ethyl methanesulfonate, 4-nitroquinoline-1-oxide, and ultraviolet light, were examined, as well as those which arose spontaneously. Sites induced by the G · C → A · T transition were compared with those generated by 2-aminopurine mutagenesis. All together, more than 4000 independent occurrences of amber and ochre mutations were tabulated in order to define the respective mutagenic specificities. With the exception of the A · T → G · C change, all base substitutions lead to the generation of nonsense codons from wild-type. The A · T → G · C transition was monitored in a reversion system, in which the ochre to amber conversion (UAA → UAG) was scored, as well as the UAA → CAA reversion.Both NG³ and EMS were found to be highly specific for the G · C → A · T transition, less than 1% transversions appearing in either case. At between 1% and 5% the level of the G · C → A · T change, NG can stimulate the A · T → G · C transition. EMS stimulates the A · T → G · C transition at a significantly lower rate. NQO is also highly specific for G · C base-pairs, but approximately 10% of the changes found at these sites are transversions. Mutations found spontaneously or after irradiation with ultraviolet light showed none of the specificities found for EMS, NG or NQO. All transversions were detected in both cases. Moreover, a significant number of tandem double base changes were found to be induced by u.v. irradiation. Some of these have been verified directly by protein sequencing. The frequencies of occurrence of amber and ochre mutations arising from the G · C → A · T transition have been compared for different mutagens, revealing several striking hotspots. The implications of these findings with respect to the mechanism of mutagenesis and the application of different mutagens are discussed.     

UV-induced base substitution mutations in a shuttle vector plasmid propagated in group C xeroderma pigmentosum cells.

To assess the contribution to mutagenesis of human DNA repair defects, the UV-irradiated shuttle vector plasmid pZ189 was propagated in fibroblasts derived from a xeroderma pigmentosum (XP) patient in DNA repair complementation group C. In comparison to results with DNA repair-proficient human cells (WI-38 VA13), UV-irradiated pZ189 propagated in the XP-C (XP4PA(SV)) cells showed fewer surviving plasmids and a higher frequency of mutated plasmids. Base sequence analysis of 67 mutated plasmids recovered from the XP-C cells revealed similar classes of point mutations and mutation spectrum, and a higher frequency of G:C to A:T transitions along with a lower frequency of transversions among plasmids with single or tandem mutations compared to plasmids recovered from the normal line. Most single-base substitution mutations (83%) occurred at G:C base pairs in which the 5'-adjacent base of the cytosine was thymine or cytosine. These results indicate that the DNA repair defects in XP-C, in comparison to data previously reported for XP-A, XP-D and XP-F, result in different UV survival and mutation frequency but in similar types of base substitution mutations.     

Mutational specificity of the base analogue, 2-aminopurine,in Escheichica coli

2-Aminopurine (2-AP) is a base analogue of adenine which mispairs with cytosine and causes base-pair substitutions of the transition type. By analyzing the reversion patterns of defined trpA alleles in Escheriachia coli we confirm that 2-AP cuases both A:T → G:C and G:C → A:T transitions whith the former induced more frequently than the latter. We also find that 2-AP enhances transversion at 3 sites and frameshift mutations at 1 other site. It is unlikely that 2-AP can cause transversions and frameshifts solely by a mispairing mechanism. However, 2-AP-induced transversion and frameshift mutagenesis was not abolished by the presence of an inactive recA allele, indicating this mutagenic activity is not dependent upon recA-directed misrepair.     

Specificity of mutations induced by riboflavin mediated photosensitization in the supF gene of Escherichia coli

Riboflavin-mediated photosensitization has been shown to produce 8-hydroxyguanine (oh⁸Gua) in DNA. We investigated the specificity of mutation of photosensitized supF gene induced in Escherichia coli. The oh⁸Gua repair deficient E. coli mutant mutM and mutY were transformed with plasmid pUB3 carrying the supF gene irradiated with white light in the presence of riboflavin. Under these conditions, riboflavin photosensitization increased the amounts of oh⁸Gua in pUB3 DNA. Three types of a single base substitution occurring at G:C pairs were detected in both wild-type and mutM mutant strains. Almost all base substitutions were transversions to T:A or C:G pairs occurring at a similar extent in both wild-type and mutM strains. Mutations derived from mutY strain transformed with photosensitized DNA were only G:C to T:A transversions. These G:C to T:A transversions observed in the mutY strain were suggested to be the result of mispairing of oh⁸Gua with adenine. Riboflavin-mediated photosensitization may also produce lesions on DNA causing G:C to C:G changes by unknown mechanisms.     

Delayed transfection of DNA after riboflavin mediated photosensitization increases G:C to C:G transversions of supF gene in Escherichia coli mutY strain.

We have previously reported that the majority of base substitution mutations of the Escherichia coli supF gene induced by riboflavin mediated photosensitization were G:C to C:G changes, in addition to G:C to T:A changes which were probably caused by 8-hydroxyguanine (oh(8)Gua), in wild type and mutM mutator mutant strains. This implies that lesions other than oh(8)Gua are produced by riboflavin-photosensitization. G:C to C:G base substitutions have been found in the mutations induced by ionizing radiation and reactive oxygen species, as well as spontaneous mutation. To characterize the G:C to C:G mutation, riboflavin- photosensitized plasmid DNA carrying the supF gene was left at room temperature for 5 h in the dark before transfection. The delayed transfection gave a mutational spectrum different from that for immediate transfection. G:C to C:G transversions significantly increased in mutY mutator strain, in which the transversion was not detected in the immediate transfection. Lesions causing G:C to C:G changes increased during 5-h holding after photosensitization and MutY protein presumably takes part in this type of base change mutation.     

Escherichia coli MutY protein has a guanine-DNA glycosylase that acts on 7,8-dihydro-8-oxoguanine:guanine mispair to prevent spontaneous G:C-->C:G transversions.

Low rates of spontaneous G:C-->C:G transversions would be achieved not only by the correction of base mismatches during DNA replication but also by the prevention and removal of oxidative base damage in DNA. Escherichia coli must have several pathways to repair such mismatches and DNA modifications. In this study, we attempted to identify mutator loci leading to G:C-->C:G transversions in E.coli. The strain CC103 carrying a specific mutation in lacZ was mutagenized by random miniTn 10 insertion mutagenesis. In this strain, only the G:C-->C:G change can revert the glutamic acid at codon 461, which is essential for sufficient beta-galactosidase activity to allow growth on lactose. Mutator strains were detected as colonies with significantly increased rates of papillae formation on glucose minimal plates containing P-Gal and X-Gal. We screened approximately 40 000 colonies and selected several mutator strains. The strain GC39 showed the highest mutation rate to Lac+. The gene responsible for the mutator phenotypes, mut39 , was mapped at around 67 min on the E.coli chromosome. The sequencing of the miniTn 10 -flanking DNA region revealed that the mut39 was identical to the mutY gene of E.coli. The plasmid carrying the mutY + gene reduced spontaneous G:C-->T:A and G:C-->C:G mutations in both mutY and mut39 strains. Purified MutY protein bound to the oligonucleotides containing 7,8-dihydro-8-oxo-guanine (8-oxoG):G and 8-oxoG:A. Furthermore, we found that the MutY protein had a DNA glycosylase activity which removes unmodified guanine from the 8-oxoG:G mispair. These results demonstrate that the MutY protein prevents the generation of G:C-->C:G transversions by removing guanine from the 8-oxoG:G mispair in E.coli.     

Multiple mutations and frameshifts are the hallmark of defective hPMS2 in pZ189-transfected human tumor cells

Two HeLa variants defective in the mismatch repair protein hPMS2 were isolated by selection for methylation tolerance. Neither variant expressed detectable hPMS2 protein as determined by western blotting. Cell extracts were defective in correcting a single base mispair and were unable to perform mismatch repair-dependent processing of a methylated DNA substrate. Correction of the repair defect and restoration of sensitivity to a methylating agent was achieved by introducing a wild-type copy of chromosome 7 on which the hPMS2 gene is located. Loss of hPMS2 function in the HeLa variants was associated with a 5-fold increase in mutation frequency in the supF gene of the pZ189 shuttle vector. Wild-type levels of mutagenesis were restored by the transferred chromosome 7. Comparisons of mutational spectra identified multiple base substitutions, frameshifts and, to a lesser extent, single base pair changes as the types of mutation which are selectively increased in a hPMS2-defective background. The location of multiple mutations and frameshifts indicates that misalignment-mediated mutagenesis could underlie most of these events. Thus the mutator phenotype associated with loss of hPMS2 most likely arises because of the failure to correct replication slippage errors. Our data also suggest that a considerable fraction of mutagenic intermediates are recognized by the hMutSβ complex and processed via the hMLH1/hPMS2 heterodimer.     

Effects of base excision repair proteins on mutagenesis by 8-oxo-7,8-dihydroguanine (8-hydroxyguanine) paired with cytosine and adenine

8-Oxo-7,8-dihydroguanine (8-oxo-Gua, also known as 8-hydroxyguanine) is a major base lesion that is generated by reactive oxygen species in both the DNA and nucleotide pool. The role of DNA glycosylases, which initiate base excision repair, in the mutagenic processes of 8-oxo-Gua in DNA and 8-oxo-7,8-dihydro-2′-deoxyguanosine 5′-triphosphate (8-oxo-dGTP, also known as 8-hydroxy-2′-deoxyguanosine 5′-triphosphate) were investigated using supF shuttle plasmids propagated in human cells. The DNA glycosylases, OGG1, MUTYH, NTH1, and NEIL1, in 293T cells were individually knocked-down by siRNAs and plasmid DNAs containing an 8-oxo-Gua:C/8-oxo-Gua:A pair, and 8-oxo-dGTP plus unmodified plasmid DNA were then introduced into the knocked-down cells. The knock-down of OGG1, MUTYH, NTH1, and NEIL1 resulted in a significant increase in G:C → T:A transversions caused by the 8-oxo-Gua:C pair in the shuttle plasmid. The knock-down of MUTYH resulted in a reduction in A:T → C:G transversions induced by 8-oxo-dGTP and the 8-oxo-Gua:A pair, but the knockdown of OGG1, NTH1, and NEIL1 had no effect on mutagenesis. These results indicate that all of the above DNA glycosylases suppress mutations caused by 8-oxo-Gua:C in DNA. In contrast, it appears that MUTYH enhances A:T → C:G mutations caused by 8-oxo-dGTP.     

Analysis of spontaneous base substitutions generated in mutator strains of Bacillus subtilis

In the current studies, we investigated base substitutions in the Bacillus subtilis mutT, mutM, and mutY DNA error-prevention system. In the wild type strain, spontaneous mutations were mainly transitions, either G:C --> A:T or A:T --> G:C. Although both transitions and transversions were observed in mutY and mutM mutants, mutM/mutY double mutants contain strictly G:C --> T:A transversions. In the mutT strain, A:T --> C:G transversion was not observed, and over-expression of the B. subtilis mutT gene had no effect on the mutation rate in the Escherichia coli mutT strain. Using 8-oxo-dGTP-induced mutagenesis, transitions especially A:T --> G:C were predominant in the wild type and mutY strains. In contrary, transversion was high on mutY and double mutant (mutM mutY). Finally, the opuBC and yitG genes were identified from the B. subtilis chromosome as mutator genes that prevented the transition base substitutions.     

Miscoding and misincorporation of 8-oxo-guanine during leading and lagging strand synthesis in Escherichia coli

We examined whether strand identity with respect to DNA replication influences strand bias for 8-oxo-7,8-dihydroguanine (8-oxoG) mutagenesis. The specificity of 8-oxoG mutagenesis was determined in a mutM mutY or a mutT strain carrying the supF gene on one of two vectors that differed only in the orientation of supF with respect to a unique origin of replication. Most of the supF mutations in the mutM mutY strain were base substitutions (67%), predominantly G:C-->T:A transversions (> 64%), while the majority in the mutT strain were base substitutions (> 92%), predominantly A:T-->C:G transversions (> 91%). The distributions of frequently mutated sites of G:C-->T:A and A:T-->C:G transversions in the supF gene in the mutM mutY and mutT strains, respectively, did not differ markedly between the two vectors. These results suggest that gene orientation is not an important determinant of the strand bias of 8-oxoG mutagenesis.     

Mutagenic specificity of N-acetoxy-3-aminobenzanthrone, a major metabolically activated form of 3-nitrobenzanthrone, in shuttle vector plasmids propagated in human cells

3-Nitrobenzanthrone (3-NBA) is a potent environmental mutagen and a potential human carcinogen present in diesel exhaust and airborne particulates. N-acetoxy-3-aminobenzanthrone (N-Aco-ABA) has been shown to be a major reactive metabolite of 3-NBA, which mainly produces adducts with guanine and adenine in cellular DNA. Here we analyzed mutations induced by N-Aco-ABA using supF shuttle vector plasmids to elucidate the mutagenic specificity of 3-NBA in human cells. Base sequence analysis of more than 100 plasmids with supF mutations induced in wildtype and DNA repair-deficient XP cells revealed that the major mutation was base substitutions of which the majority (42 and 38%, respectively) were G:C to T:A transversions. The next major mutation was G:C to A:T and A:T to G:C base substitutions in wildtype and XP cells, respectively. The DNA polymerase stop assay using N-Aco-ABA-treated plasmids as a template showed that most stop signals, i.e., adducted sites, appeared at G:C sites. These results suggest that N-Aco-ABA binds preferably to guanine rather than adenine, and adducted adenine is repaired more efficiently by the nucleotide excision repair. Error-prone DNA polymerases could insert adenine at sites opposite to N-Aco-ABA-adducted guanine, which leads to G:C to T:A transversion. These findings could be very important to evaluate the human lung cancer risk of environmental 3-NBA.     

DNA sequence analysis of spontaneous and γ-radiation (anoxic)-induced lacI mutations in Escherichia coliumuC122::Tn5: differential requirement for umuC at G · C vs. A · T sites and for the production of transversions vs. transitions

Escherihica coliumC122::Tn5 cells were γ-radiated (¹³⁷Cs, 750 Gy, under N₂), and lac-constitutive mutants were produced at 36% of the wild-type level (the umC strain was not deficient in spontaneous mutagenesis, and the mutational spectrum determined by sequencing 263 spontaneous lacI^d mutations was very similar to that for the wild-type strain). The specific nature of the umC strain's partial radiation was determined by sequencing 325 radiation-induced lacI^d mutations. The yields of radiation-induced mutation classes in the umC strain (as a percentage of the wild-type yield) were: 80% for A · T → G · C transitions, 70% for multi-base additions, 60% for single-base deletions, 53% for A · T → C · G transversions, 36% for G · C → A · T transitions, 25% for multi-base deletions, 21% for A · T → T · A transversions, 11% for G · C → C · G transversions, 9% for G · C → T · A transversions and 0% for multiple mutations. Based on these deficiencies and other factors, it is concluded that the umC strain is near-normal for A · T → G · C transitions, single-base deletions and possibly A · T → C · G transversions; is generally deficient for mutagenesis at G · C sites fro transversions, and is grossly deficient in multiple mutations. Damage at G · C sites seems more difficult for translesion DNA synthesis to bypass than damage at A · T sites, and especially when trying to produced a transversion. The yield of G · C → A · T transitions in the umC strain *36% of the wild-type level) argues that a basic sites are involved in no more than 64% of γ-radiation-induced base substitutions in the wild-type strain. Altogether, these data suggest that the UmuC and UmuD′ proteins facilitate, rather than being absolutely required for, translesion DNA synthesis; with the degree of facilitation being dependent both on the nature of the noncoding DNA damage, i.e., at G · C vs A · T sites, and on the nature of the misincorporated base, i.e., whether it induces transversions or transitions.     

Cr(III)-mediated crosslinks of glutathione or amino acids to the DNA phosphate backbone are mutagenic in human cells.

Carcinogenic Cr(VI) compounds were previously found to induce amino acid/glutathione-Cr(III)-DNA crosslinks with the site of adduction on the phosphate backbone. Utilizing the pSP189 shuttle vector plasmid we found that these ternary DNA adducts were mutagenic in human fibroblasts. The Cr(III)-glutathione adduct was the most potent in this assay, followed by Cr(III)-His and Cr(III)-Cys adducts. Binary Cr(III)-DNA complexes were only weakly mutagenic, inducing a significant response only at a 10 times higher number of adducts compared with Cr(III)-glutathione. Single base substitutions at the G:C base pairs were the predominant type of mutations for all Cr(III) adducts. Cr(III), Cr(III)-Cys and Cr(III)-His adducts induced G:C-->A:T transitions and G:C-->T:A transversions with almost equal frequency, whereas the Cr(III)-glutathione mutational spectrum was dominated by G:C-->T:A transversions. Adduct-induced mutations were targeted toward G:C base pairs with either A or G in the 3' position to the mutated G, while spontaneous mutations occurred mostly at G:C base pairs with a 3' A. No correlation was found between the sites of DNA adduction and positions of base substitution, as adducts were formed randomly on DNA with no base specificity. The observed mutagenicity of Cr(III)-induced phosphotriesters demonstrates the importance of a Cr(III)-dependent pathway in Cr(VI) carcinogenicity.     

Evaluation of chromosome painting to assess the induction and persistence of chromosome aberrations in bone marrow cells of mice treated with benzene

Intact pZ189 DNA was allowed to replicate in FL-FEN-1⁻ cell line that was established in this laboratory in which the expression of FEN-1 gene was blocked by dexamethasone-inducible expression of antisense RNA to FEN-1. E. coli MBM7070 was transfected with the replicated plasmid, and those with mutations in the supF gene were identified. The frequency of mutants that did not contain recognizable changes in the electrophoretic mobility of the plasmid DNA was scored. The frequency of such mutants was 19.1 × 10⁻⁴ (34/17781), significantly higher than those of 2.9 × 10⁻⁴ (4/13668) and 3.0 × 10⁻⁴ (3/9857) in the corresponding controls, respectively. Sequence analysis of the supF genes of these mutants showed that all (37/37) the base substitutions occurred at C:G base pairs; 68% (23/37) of the base substitutions were base transversions, while 32% (12/37) were transitions. Approximately 76% (23/37) of these base substitutions occurred frequently at nine positions; two of these sites contain triple pyrimidine (T or C) repeat upstream to the mutated base; four of these sites consist of 5′-TTN₁N₂ and mutations occurred at N₁ site sequence; another two sites have the characteristics of triple A flanked at both 5′ and 3′ side by TCT, with the base substitution occurring at C in the context sequence. These data suggested that these sites are the hot spot of mutagenesis in plasmid replicated in FEN-1-deficient cells. Besides the mutator phenotype of the FEN-1-deficient cell, it was also demonstrated that FEN-1-deficient cell exhibited an increased N-methyl-N′-nitro-N-nitrosoguanidine (MNNG) sensitive phenotype.     

Unique pattern of point mutations arising after gene transfer into mammalian cells.

We have used a simian virus 40 (SV40)-based shuttle vector, pZ189, to analyze the sequence specificity of spontaneous point mutations that arise after transfection of this vector into monkey cells. The majority of the mutants which we studied had multiple base substitutions (mostly G-C----A-T transitions and G-C----T-A transversions) within the 160-bp region sequenced. Almost all of the mutations occurred in the right-hand G-C bp of one of the two following sequences, 5'-TC-3':3'-AG-5' or 5'-CC-3':3'-GG-5'. We postulate that these mutations result from DNA replication infidelity occurring during repair of the transfected DNA which has been damaged by cellular nucleases. The sequence specificity of the mutations suggests an effect of the following nucleotide on misincorporation wherein A (or less frequently T) is preferentially misincorporated opposite C when the next nucleotide inserted is A (or less frequently G). Our results support the utility of the shuttle vector as a model in studies on gene transfer and document the extreme plasticity of DNA transfected into mammalian cells.