Rates of Spontaneous Mutation in Bacteriophage T4 Are Independent of Host Fidelity Determinants

Bacteriophage T4 encodes most of the genes whose products are required for its DNA metabolism, and host (Escherichia coli) genes can only infrequently complement mutationally inactivated T4 genes. We screened the following host mutator mutations for effects on spontaneous mutation rates in T4: mutT (destruction of aberrant dGTPs), polA, polB and polC (DNA polymerases), dnaQ (exonucleolytic proofreading), mutH, mutS, mutL and uvrD (methyl-directed DNA mismatch repair), mutM and mutY (excision repair of oxygen-damaged DNA), mutA (function unknown), and topB and osmZ (affecting DNA topology). None increased T4 spontaneous mutation rates within a resolving power of about twofold (nor did optA, which is not a mutator but overexpresses a host dGTPase). Previous screens in T4 have revealed strong mutator mutations only in the gene encoding the viral DNA polymerase and proofreading 3'-exonuclease, plus weak mutators in several polymerase accessory proteins or determinants of dNTP pool sizes. T4 maintains a spontaneous mutation rate per base pair about 30-fold greater than that of its host. Thus, the joint high fidelity of insertion by T4 DNA polymerase and proofreading by its associated 3'-exonuclease appear to determine the T4 spontaneous mutation rate, whereas the host requires numerous additional systems to achieve high replication fidelity.     

DNA polymerase II as a fidelity factor in chromosomal DNA synthesis in Escherichia coli

Escherichia coli DNA polymerase III holoenzyme (HE) is the main replicase responsible for replication of the bacterial chromosome. E. coli contains four additional polymerases, and it is a relevant question whether these might also contribute to chromosomal replication and its fidelity. Here, we have investigated the role of DNA polymerase II (Pol II) (polB gene product). Mismatch repair-defective strains containing the polBex1 allele--encoding a polymerase-proficient but exonucleolytically defective Pol II--displayed a mutator activity for four different chromosomal lac mutational markers. The mutator effect was dependent on the chromosomal orientation of the lacZ gene. The results indicate that Pol II plays a role in chromosomal replication and that its role is not equal in leading- versus lagging-strand replication. In particular, the role of Pol II appeared larger in the lagging strand. When combined with dnaQ or dnaE mutator alleles, polBex1 showed strong, near multiplicative effects. The results fit a model in which Pol II acts as proofreader for HE-produced misinsertion errors. A second role of Pol II is to protect mismatched 3' termini against the mutagenic action of polymerase IV (dinB product). Overall, Pol II may be considered a main player in the polymerase trafficking at the replication fork.     

SOS-inducible DNA polymerase II of E coli is homologous to replicative DNA polymerase of eukaryotes

The polB gene of Escherichia coli encodes DNA polymerase II whose role in vivo is not defined. The polB gene has been cloned and shown to be identical to a DNA damage-inducible gene dinA which is regulated by the LexA repressor. Nucleotide sequencing of polB reveals that E coli DNA polymerase II is highly homologous to replicative DNA polymerases of eukaryotes which include human DNA polymerase alpha and Saccharomyces cerevisiae DNA polymerases I, II and III. The polB gene is not required for growth, UV-repair and UV-mutagenesis.     

Cloning the polB gene of Escherichia coli and identification of its product

Using an in vivo mini-Mu cloning system, we have cloned the polB gene of Escherichia coli into the multicopy plasmid, pUC18. A chromosomal insert of 4.9 kilobases gave 30-40-fold overproduction of DNA polymerase II, and the cells containing the plasmid showed normal growth. The restriction pattern of the polB gene does not match that of either the polA gene or polC gene. Plasmid-directed protein synthesis demonstrates peptides of 99 and 82 kDa which are not expressed by derivative plasmids without DNA polymerase II activity. It appears from in situ gel assays and high performance liquid chromatography that 82- and 55-kDa proteins are derived from the 99-kDa protein by degradation, but all retain activity. DNA polymerase I or DNA polymerase III antibody does not inhibit the synthesis reaction of partially purified DNA polymerase II, but DNA polymerase II antibody does. By the criteria of restriction pattern of the polB gene, molecular weight of the protein, and antibody inhibition of reaction, DNA polymerase II can be demonstrated to be a distinct DNA polymerase.     

Nucleotide sequence and deletion analysis of the polB gene of Escherichia coli

The polB gene encodes DNA polymerase II in Escherichia coli. The nucleotide sequence shows an open reading frame of 2,304 nucleotides coding for a protein of 88 kD. The protein initiation signal is preceded by a lexA box lying 2 nucleotides from the termination signal of araD, and begins with GUG 75 nucleotides after the termination of araD. The polB gene and the araD gene are transcribed in the same direction. Initiation of protein synthesis was confirmed by peptide sequence. We have also demonstrated that the polB sequence is lacking in some strains. We conclude that DNA polymerase II is not a required protein in the cell. Sequence comparisons show that DNA polymerase II is an alpha-like DNA polymerase.     

The interaction of the Escherichia coli mutD and mutT pathways in the prevention of A:T-->C:G transversions.

The Escherichia coli mutT mutator allele produces high frequencies of exclusively A:T-->C:G transversions. This is thought to be caused by a failure to prevent or remove A:G mispairs during DNA replication. The mutD5 mutator allele maps to the dnaQ locus which encodes the epsilon subunit of the DNA polymerase III holoenzyme. This subunit provides 3'-->5' exonuclease, proofreading, activity for removing mispaired nucleotides at the 3' end of the newly synthesized DNA strand. mutD5 has an altered epsilon resulting in reduced levels of proofreading and subsequent high mutation frequencies for all base-pair substitutions. We have analyzed the interaction between mutD5 and mutT-induced A:T-->C:G transversions by measuring reversion frequencies in mutD5 and mutT single mutator strains and mutD5mutT double mutator strains using the well-characterized trpA58 and trpA88 alleles. We find that the double mutator strains produce more A:T-->C:G substitutions than would be expected from simple additivity of the single mutator strains. We interpret this to mean that the two systems, at least in part, do act together to prevent the same mutational intermediate from producing A:T-->C:G transversions. It is estimated that over 90% of the mutT-induced A:G mispairs are corrected by proofreading at the trpA58 site while only about 30% are corrected at trpA88. Reversion frequencies in the mutD5mutT double mutator strains indicate A:G misincorporations occur about 100 x more frequently at trpA58 than at the trpA88 site. Using these and other data we also provide estimations of the fidelity contributions for mutT editing, proofreading and methyl-directed mismatch repair at the two trpA sites for both transversions and the transition that could be scored. In the case of A:T-->C:G transversions, both mutT editing and proofreading make major contributions in error reduction with mismatch repair playing a small or no role at all. For the A:T-->G:C transition, proofreading and mismatch repair were both important in preventing mutations while no contribution was observed for mutT editing.     

The Escherichia coli polB gene, which encodes DNA polymerase II, is regulated by the SOS system.

The dinA (damage inducible) gene was previously identified as one of the SOS genes with no known function; it was mapped near the leuB gene, where the polB gene encoding DNA polymerase II was also mapped. We cloned the chromosomal fragment carrying the dinA region from the ordered Escherichia coli genomic library and mapped the dinA promoter precisely on the physical map of the chromosome. The cells that harbored multicopy plasmids with the dinA region expressed very high levels of DNA polymerase activity, which was sensitive to N-ethylmaleimide, an inhibitor of DNA polymerase II. Expression of the polymerase activity encoded by the dinA locus was regulated by SOS system, and the dinA promoter was the promoter of the gene encoding the DNA polymerase. From these data we conclude that the polB gene is identical to the dinA gene and is regulated by the SOS system. The product of the polB (dinA) gene was identified as an 80-kDa protein by the maxicell method.     

Characterization of the defect in the Escherichia coli mutT1 mutator gene.

With a probe constructed from the wild-type gene, a DNA fragment containing the entire mutT1 mutator gene was isolated and cloned into pUC18. Nucleotide sequence analysis revealed that the mutator defect was most likely due to an IS1 insertion into the wild-type gene.     

An Escherichia coli dnaE mutation with suppressor activity toward mutator mutD5.

The Escherichia coli mutator mutD5 is a conditional mutator whose strength is moderate when the strain is growing in minimal medium but very strong when it is growing in rich medium. The primary defect of this strain resides in the dnaQ gene, which encodes the epsilon (exonucleolytic proofreading) subunit of the DNA polymerase III holoenzyme. In one of our mutD5 strains we discovered a mutation that suppressed the mutability of mutD5. Interestingly, the level of suppression was strong in minimal medium but weak in rich medium. The mutation was localized to the dnaE gene, which encodes the alpha (polymerase) subunit of the DNA polymerase III holoenzyme. This mutation, termed dnaE910, also conferred improved growth of the mutD5 strain and caused increased temperature sensitivity in both wild-type and dnaQ49 backgrounds. The reduction in mutator strength by dnaE910 was also observed when this allele was placed in a mutL, a mutT, or a dnaQ49 background. The results suggest that dnaE910 encodes an antimutator DNA polymerase whose effect might be mediated by improved insertion fidelity or by increased proofreading via its effect on the exonuclease activity.     

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

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

Fate of thymine-containing dimers in the deoxyribonucleic acid of ultraviolet-irradiated mutator T1 Escherichia coli transfuctants

In order to determine whether a relationship generally exists between the mutator property (mutT1) and repair of ultraviolet (UV) irradiation damaged DNA, we performed spontaneous mutation rate and UV-survival determinations without and with acriflavin (4 μg/ml) in P1 phage mediated mut T1 Escherichia coli transductants. The strains constructed were assumed to be cosigenic except for the mutator factor. The mutT1 uvrA, uvrB or exrA transdunctants had mutation rates similar to the donor strain. Double mutants containing mutT1 and uvrB or exrA had the same level of UV survival as the parent with the same mutator phenotype. Mutator strains were normal for host-cell reactivation of UV-irradiated phage T1, and phage lambda was UV-inducible. The fate of UV-induced thymine-containing dimers in the deoxyribonucleic acid (DNA) of mutT1 transductants was investigated. Dark repair of pyrimidine dimers is equally sensitive in the nonmutator and mutator Hcr⁺. During incubation in the dark, dimers were excised to the same extent from the DNA of the Hcr⁺ mutator and nonmutator transductants but remained in the DNA of the Hcr^? mutant.     

Escherichia coli mutT mutator effect during in vitro DNA synthesis. Enhanced A.G replicational errors

The mechanism of the Escherichia coli mutT mutator effect was investigated using single-stranded phage as a mutational target. In vivo experiments showed that two M13mp2 lacZ alpha nonsense mutants reverted at a higher rate on a mutT1 host than on the wild-type host. The specificity of this mutator effect was identical to that observed for E. coli genes: A.T----C.G transversions. The mutT effect was subsequently demonstrated in vitro during DNA replication of M13mp2 DNA in cell-free extracts of E. coli. Replication (the single-stranded----replicative form conversion) in mutT1 extracts proceeded with a higher error rate than in wild-type extracts, and DNA sequence analysis of the in vitro revertants revealed the specific induction of A.T----C.G transversions. On the basis of the template specificity of the mutT effect in vitro, we conclude that the mutT effect involves the aberrant processing of A.G rather than T.C mispairs.     

DNA polymerase II (polB) is involved in a new DNA repair pathway for DNA interstrand cross-links in Escherichia coli

DNA-DNA interstrand cross-links are the cytotoxic lesions for many chemotherapeutic agents. A plasmid with a single nitrogen mustard (HN2) interstrand cross-link (inter-HN2-pTZSV28) was constructed and transformed into Escherichia coli, and its replication efficiency (RE = [number of transformants from inter-HN2-pTZSV28]/[number of transformants from control]) was determined to be approximately 0.6. Previous work showed that RE was high because the cross-link was repaired by a pathway involving nucleotide excision repair (NER) but not recombination. (In fact, recombination was precluded because the cells do not receive lesion-free homologous DNA.) Herein, DNA polymerase II is shown to be in this new pathway, since the replication efficiency (RE) is higher in a polB+ ( approximately 0. 6) than in a DeltapolB (approximately 0.1) strain. Complementation with a polB+-containing plasmid restores RE to wild-type levels, which corroborates this conclusion. In separate experiments, E. coli was treated with HN2, and the relative sensitivity to killing was found to be as follows: wild type < polB < recA < polB recA approximately uvrA. Because cells deficient in either recombination (recA) or DNA polymerase II (polB) are hypersensitive to nitrogen mustard killing, E. coli appears to have two pathways for cross-link repair: an NER/recombination pathway (which is possible when the cross-links are formed in cells where recombination can occur because there are multiple copies of the genome) and an NER/DNA polymerase II pathway. Furthermore, these results show that some cross-links are uniquely repaired by each pathway. This represents one of the first clearly defined pathway in which DNA polymerase II plays a role in E. coli. It remains to be determined why this new pathway prefers DNA polymerase II and why there are two pathways to repair cross-links.     

Two Family B DNA Polymerases from Aeropyrum pernix, an Aerobic Hyperthermophilic Crenarchaeote

DNA polymerase activities in fractionated cell extract of Aeropyrum pernix, a hyperthermophilic crenarchaeote, were investigated. Aphidicolin-sensitive (fraction I) and aphidicolin-resistant (fraction II) activities were detected. The activity in fraction I was more heat stable than that in fraction II. Two different genes (polA and polB) encoding family B DNA polymerases were cloned from the organism by PCR using degenerated primers based on the two conserved motifs (motif A and B). The deduced amino acid sequences from their entire coding regions contained all of the motifs identified in family B DNA polymerases for 3'-->5' exonuclease and polymerase activities. The product of polA gene (Pol I) was aphidicolin resistant and heat stable up to 80 degrees C. In contrast, the product of polB gene (Pol II) was aphidicolin sensitive and stable at 95 degrees C. These properties of Pol I and Pol II are similar to those of fractions II and I, respectively, and moreover, those of Pol I and Pol II of Pyrodictium occultum. The deduced amino acid sequence of A. pernix Pol I exhibited the highest identities to archaeal family B DNA polymerase homologs found only in the crenarchaeotes (group I), while Pol II exhibited identities to homologs found in both euryarchaeotes and crenarchaeotes (group II). These results provide further evidence that the subdomain Crenarchaeota has two family B DNA polymerases. Furthermore, at least two DNA polymerases work in the crenarchaeal cells, as found in euryarchaeotes, which contain one family B DNA polymerase and one heterodimeric DNA polymerase of a novel family.     

Escherichia coli cells bearing mutA, a mutant glyV tRNA gene, express a recA-dependent error-prone DNA replication activity

A base substitution mutation (mutA) in the Escherichia coli glyV tRNA gene potentiates asp --> gly mistranslation and confers a strong mutator phenotype that is SOS independent, but requires recA, recB and recC genes. Here, we demonstrate that mutA cells express an error-prone DNA polymerase by using an in vitro experimental system based on the conversion of phage M13 single-stranded viral DNA bearing a model mutagenic lesion to the double-stranded replicative form. Amplification of the newly synthesized strand followed by multiplex DNA sequence analysis revealed that mutation fixation at 3, N4-ethenocytosine (varepsilonC) was approximately 3% when the DNA was replicated by normal cell extracts, approximately 48% when replicated by mutA cell extracts and approximately 3% when replicated by mutA recA double mutant cell extracts, in complete agreement with previous in vivo results. Mutagenesis at undamaged DNA sites was significantly elevated by mutA cell-free extracts in the M13 lacZ(alpha) forward mutagenesis system. Neither polA (DNA polymerase I) nor polB (DNA polymerase II) genes are required for the mutA phenotype, suggesting that the phenotype is mediated through a modification of DNA polymerase III or the activation of a previously unidentified DNA polymerase. These findings define the major features of a novel mutagenic pathway and imply the existence of previously unrecognized links between translation, recombination and replication.     

Sensitivity to x-radiation of strains of Escherichia coli K-12 which lack DNA polymerase II

Summary The polB1 and polA1 polB1 strains of E. coli K-12, wihch are deficient in DNA polymerase II and in DNA polymerases I and II, respectively, were found to have essentially the same sensitivity to anoxic or aerobic X-irradiation as their related wild-type and polA1 strains, respectively. Thus, DNA polymerase II appears to play no major role in the repair of X-ray damage.     

Involvement of Escherichia coli DNA polymerase II in response to oxidative damage and adaptive mutation.

DNA polymerase II (Pol II) is regulated as part of the SOS response to DNA damage in Escherichia coli. We examined the participation of Pol II in the response to oxidative damage, adaptive mutation, and recombination. Cells lacking Pol II activity (polB delta 1 mutants) exhibited 5- to 10-fold-greater sensitivity to mode 1 killing by H2O2 compared with isogenic polB+ cells. Survival decreased by about 15-fold when polB mutants containing defective superoxide dismutase genes, sodA and sodB, were compared with polB+ sodA sodB mutants. Resistance to peroxide killing was restored following P1 transduction of polB cells to polB+ or by conjugation of polB cells with an F' plasmid carrying a copy of polB+. The rate at which Lac+ mutations arose in Lac- cells subjected to selection for lactose utilization, a phenomenon known as adaptive mutation, was increased threefold in polB backgrounds and returned to wild-type rates when polB cells were transduced to polB+. Following multiple passages of polB cells or prolonged starvation, a progressive loss of sensitivity to killing by peroxide was observed, suggesting that second-site suppressor mutations may be occurring with relatively high frequencies. The presence of suppressor mutations may account for the apparent lack of a mutant phenotype in earlier studies. A well-established polB strain, a dinA Mu d(Apr lac) fusion (GW1010), exhibited wild-type (Pol II+) sensitivity to killing by peroxide, consistent with the accumulation of second-site suppressor mutations. A high titer anti-Pol II polyclonal antibody was used to screen for the presence of Pol II in other bacteria and in the yeast Saccharomyces cerevisiae. Cross-reacting material was found in all gram-negative strains tested but was not detected in gram-positive strains or in S. cerevisiae. Induction of Pol II by nalidixic acid was observed in E. coli K-12, B, and C, in Shigella flexneri, and in Salmonella typhimurium.     

Bacteriophage Mu-1-induced mutation to mutT in Escherichia coli.

Of approximately 10,000 independent phage Mu-1 lysogens, 3 had a mutator phenotype. One (mutation designated mut-49) resembled mutT1 in the frequency and types of mutations induced. mut-49 was mapped between leu and ace and was not separable from the Mu prophage. mut-49 was recessive and did not complement mutT1. mut-49, like mutT1, did not increase the reversion of the frameshift mutation lac Z (ICR48). mut-49 and mutT1 induced the same two classes of trpA78 revertants, indicating that mut-49 induced adenine-thymine leads to cytosine-guanine transversions. The results support previous work indicating that the mutational specificity of mutT is gene and not allele specific.     

Bacterial DNA repair genes and their eukaryotic homologues: 2. Role of bacterial mutator gene homologues in human disease. Overview of nucleotide pool sanitization and mismatch repair systems

Since the discovery of the first E. coli mutator gene, mutT, most of the mutations inducing elevated spontaneous mutation rates could be clearly attributed to defects in DNA repair. MutT turned out to be a pyrophosphohydrolase hydrolyzing 8-oxodGTP, thus preventing its incorporation into DNA and suppresing the occurrence of spontaneous AT-->CG transversions. Most of the bacterial mutator genes appeared to be evolutionarily conserved, and scientists were continuously searching for contribution of DNA repair deficiency in human diseases, especially carcinogenesis. Yet a human MutT homologue--hMTH1 protein--was found to be overexpressed rather than inactivated in many human diseases, including cancer. The interest in DNA repair contribution to human diseases exploded with the observation that germline mutations in mismatch repair (MMR) genes predispose to hereditary non-polyposis colorectal cancer (HNPCC). Despite our continuously growing knowledge about DNA repair we still do not fully understand how the mutator phenotype contributes to specific forms of human diseases.