Current understanding of UV-induced base pair substitution mutation in E. coli with particular reference to the DNA polymerase III complex

UV mutagenesis in E. coli is believed to occur in two discrete steps. The second step involves continued DNA synthesis beyond a blocking lesion in the template strand. This bypass step requires induced levels of umuD and umuC gene products and activated recA protein. DNA polymerase III may be involved since a dnaE mutator strain (believed to have defective base selection) is associated with enhanced UV mutagenesis in conjunction with a genetic background permitting the bypass step. In non-UV-mutable umu and lexA strains, UV mutagenesis can be demonstrated if delayed photorevesal is given. This is interpreted as indicating that an earlier misincorporation step can occur in such strains but the resulting mutations do not survive because the bypass step is blocked. The misincorporation step does not require any induced SOS gene products and can occur either at the replication fork or during repair replication following excision of a DNA lesion. Neither a dnaE mutator gene (leading to a defective subunit of DNA polymerase III holoenzyme) nor a mutD5 mutator gene (leading to a defective ε proofreading subunit) had any effect on he misincorporation step. Although this is consistent with DNA polymerase III holoenzyme not being involved in the misincorporation step, other interpretations involving the inhibition of ε proofreading activity by recA protein are possible.

In vitro studies are reported in which sites of termination of synthesis by DNA polymerase III holoenzyme on UV-irradiated M13 mp8 DNA were examined in the presence of inhibitors of the 3′–5′ proofreading exonuclease (including recA protein). No evidence was found for incorporation of bases opposite photoproducts suggesting that either inhibition is more complete in the cell and/or that other factors are involved in the misincorporation step.     

Translesion synthesis of 7,8-dihydro-8-oxo-2'-deoxyguanosine by DNA polymerase eta in vivo

7,8-Dihydro-8-oxo-2′-deoxyguanosine (8-oxo-dG) is one of the most common DNA lesions induced by oxidative stress. This lesion can be bypassed by DNA polymerase eta (Pol η) using in vitro translesion synthesis (TLS) reactions. However, the role that Pol η plays in vivo contributing to 8-oxo-dG mutagenesis remains unclear. To clarify the role of Pol η in 8-oxo-dG mutagenesis, we have used an siRNA knockdown approach in combination with a supF shuttle vector (pSP189) which replicates in mammalian cells. The pSP189 plasmid was treated with methylene blue plus light (MBL), which produces predominantly 8-oxo-dG in DNA, and was then replicated in GM637 cells in presence of siRNA that knocks down the expression of Pol η, or in XP-V cells, which lack functional Pol η. The mutant frequencies were increased in the Pol η siRNA knockdown cells and in XP-V cells relative to control, meaning that Pol η plays an important role in preventing 8-oxo-dG mutagenesis. In the same system, knockdown of OGG1 also led to an increase in mutagenesis. Neither the type of mutations nor their distribution along the supF gene were significantly different between control and target specific siRNA-transfected cells (or XP-V cells) and were predominantly G to T transversions. These results show that Pol η has an important role in error-free 8-oxo-dG lesion bypass and avoidance of oxidative stress-induced mutagenesis in vivo.     

Strand Displacement by DNA Polymerase III Occurs through a ��-��-�� Link to Single-stranded DNA-binding Protein Coating the Lagging Strand Template

In addition to the well characterized processive replication reaction catalyzed by the DNA polymerase III holoenzyme on single-stranded DNA templates, the enzyme possesses an intrinsic strand displacement activity on flapped templates. The strand displacement activity is distinguished from the single-stranded DNA-templated reaction by a high dependence upon single-stranded DNA binding protein and an inability of γ-complex to support the reaction in the absence of τ. However, if γ-complex is present to load β₂, a truncated τ protein containing only domains III–V will suffice. This truncated protein is sufficient to bind both the α subunit of DNA polymerase (Pol) III and χψ. This is reminiscent of the minimal requirements for Pol III to replicate short single-stranded DNA-binding protein (SSB)-coated templates where τ is only required to serve as a scaffold to hold Pol III and χ in the same complex (Glover, B., and McHenry, C. (1998) J. Biol. Chem. 273, 23476–23484). We propose a model in which strand displacement by DNA polymerase III holoenzyme depends upon a Pol III-τ-ψ-χ-SSB binding network, where SSB is bound to the displaced strand, stabilizing the Pol III-template interaction. The same interaction network is probably important for stabilizing the leading strand polymerase interactions with authentic replication forks. The specificity constant (k_cat/K_m) for the strand displacement reaction is ∼300-fold less favorable than reactions on single-stranded templates and proceeds with a slower rate (150 nucleotides/s) and only moderate processivity (∼300 nucleotides). PriA, the initiator of replication restart on collapsed or misassembled replication forks, blocks the strand displacement reaction, even if added to an ongoing reaction.     

Mutation induction by thymine deprivation in Escherichia coli B/R. II. Mutation in the repressed and derepressed tryptophan operon.

True Trp⁺ reversions are induced by thymine deprivation in cells with repressed trp operons as efficiently as in derepressed cells. At least part of the mutations are fixed during thymine starvation, i.e. in the absence of net DNA synthesis. The hypothesis is put forward that thymineless mutagenesis is due to repair-replication under limited concentrations of 5′-dTTP, performed by an inducible error-prone “DNA-polymerizing activity” on single-strand gaps.     

Escherichia coli DNA polymerase II can efficiently bypass 3,N(4)-ethenocytosine lesions in vitro and in vivo

Escherichia coli DNA polymerase II (pol-II) is a highly conserved protein that appears to have a role in replication restart, as well as in translesion synthesis across specific DNA adducts under some conditions. Here, we have investigated the effects of elevated expression of pol-II (without concomitant SOS induction) on translesion DNA synthesis and mutagenesis at 3,N(4)-ethenocytosine (varepsilonC), a highly mutagenic DNA lesion induced by oxidative stress as well as by exposure to industrial chemicals such as vinyl chloride. In normal cells, survival of transfected M13 single-stranded DNA bearing a single varepsilonC residue (varepsilonC-ssDNA) is about 20% of that of control DNA, with about 5% of the progeny phage bearing a mutation at the lesion site. Most mutations are C-->A and C-->T, with a slight predominance of transversions over transitions. In contrast, in cells expressing elevated levels of pol-II, survival of varepsilonC-ssDNA is close to 100%, with a concomitant mutation frequency of almost 99% suggesting highly efficient translesion DNA synthesis. Furthermore, an overwhelming majority of mutations at varepsilonC are C-->T transitions. Purified pol-II efficiently catalyzes translesion synthesis at varepsilonC in vitro, accompanied by high levels of mutagenesis with the same specificity. These results suggest that the observed in vivo effects in pol-II over-expressing cells are due to pol-II-mediated DNA synthesis. Introduction of mutations in the carboxy terminus region (beta interaction domain) of polB eliminates in vivo translesion synthesis at varepsilonC, suggesting that the ability of pol-II to compete with pol-III requires interaction with the beta processivity subunit of pol-III. Thus, pol-II can compete with pol-III for translesion synthesis.     

The processivity factor β controls DNA polymerase IV traffic during spontaneous mutagenesis and translesion synthesis in vivo

The dinB-encoded DNA polymerase IV (Pol IV) belongs to the recently identified Y-family of DNA polymerases. Like other members of this family, Pol IV is involved in translesion synthesis and mutagenesis. Here, we show that the C-terminal five amino acids of Pol IV are essential in targeting it to the β-clamp, the processivity factor of the replicative DNA polymerase (Pol III) of Escherichia coli. In vivo, the disruption of this interaction obliterates the function of Pol IV in both spontaneous and induced mutagenesis. These results point to the pivotal role of the processivity clamp during DNA polymerase trafficking in the vicinity of damaged-template DNA.     

Physico-chemical study of complex formation of DNA with wild-type and mutant E. coli RNA polymerases. Recognition properties of beta-subunit

Complex formation of T₇ DNA with RNA polymerase from E. coli B/r WU-36-10-11-12 (E. coli W 12) and its rifampicin-resistant mutant rpoB409 was studied. The rpoB409 mutant possesses a highly pleiotropic effect due to alteration in the RNA polymerase β-subunit structure. The two RNA polymerases have been previously shown to differ in gene selection during RNA synthesis on T₇ DNA. In this study it was found that the change in selective properties of the mutant RNA polymerase occurs during its interaction with DNA, the general ability of the enzyme to melt DNA being unaffected.     

Generation and analyses of the transgenic potatoes expressing heterologous thermostable β-amylase

β-Amylase hydrolyzes the -1,4-glycosidic linkages of starch resulting in the release of maltose. This reaction is of industrial importance for maltose production and for the preparation process of fermented foods and alcoholic beverages. A demand for an acceleration of the rate of enzymatic cleavage of the starch macro-molecule is a prerequisite for large-scale and highly efficient production. Increasing the temperature up to the optimum of approximately 60 °C can significantly speed up the reaction. However, at higher temperatures, the effect on protein denaturation becomes dominant, and the conversion rate decreases. The primary objective of this study was to generate transgenic plants of the “Kennebec” potato variety for production of thermostable β-amylase using Agrobacterium-mediated transformation. Four chimeric genes encoding the β-amylase with or without signal peptide sequences for targeting expression in cytoplasm, amyloplasts, or vacuoles were constructed and driven by high tuber expression promoter from Sucrose synthetase gene Sus4. Forty-two transgenic lines were selected for this study. Transgenic lines with various β-amylase constructs were verified for the existence and expression of the transgenes by PCR approaches. The expression level of the introduced β-amylase protein was estimated by immunoblot analyses using polyclonal antibodies. Recombinant β-amylase was successfully expressed in Escherichia coli B21 (DE3), and temperature ranges of these inducible recombinant proteins were found to be between 40 and 90 °C. This enzymatic complex produced in the in vitro cultured microtubers and field-grown tubers from transgenic potatoes were proved to be stable and active at 60 °C. The relative activities of β-amylase in tubers of field-grown potatoes were compared, and the maximum increase was found with transgenic line #6A of the pSUS4-AMY construct which has an 11-fold greater increase than the untransformed “Kennebec”. Variations of the chemical compositions were found in the selected transgenic lines. Results of this study suggest the feasibility of utilizing thermostable β-amylase in transgenic potatoes for the starch-processing industries.     

The property of DNA polymerase zeta: REV7 is a putative protein involved in translesion DNA synthesis and cell cycle control

Translesion DNA synthesis (TLS) is an important damage tolerance system which rescues cells from severe injuries caused by DNA damage. Specialized low fidelity DNA polymerases in this system synthesize DNA past lesions on the template DNA strand, that replicative DNA polymerases are usually unable to pass through. However, in compensation for cell survival, most polymerases in this system are potentially mutagenic and sometimes introduce mutations in the next generation. In yeast Saccharomyces cerevisiae (S. cerevisiae), DNA polymerase ζ, which consists of Rev3 and Rev7 proteins, and Rev1 are known to be involved in most damage-induced and spontaneous mutations. The human homologs of S. cerevisiae REV1, REV3, and REV7 were identified, and it is revealed that the human REV proteins have similar functions to their yeast counterparts, however, a large part of the mechanisms of mutagenesis employing REV proteins are still unclear. Recently, the new findings about REV proteins were reported, which showed that REV7 interacts not only with REV3 but also with REV1 in human and that REV7 is involved in cell cycle control in Xenopus. These findings give us a new point of view for further investigation about REV proteins. Recent studies of REV proteins are summarized and several points are discussed.     

Human dehydroepiandrosterone sulfotransferase pharmacogenetics: Quantitative Western analysis and gene sequence polymorphisms

Dehydroepiandrosterone sulfotransferase (DHEA ST) catalyzes the sulfation of DHEA and other hydroxysteroids. DHEA ST enzymatic activity in individual human liver biopsy samples has been shown to vary over a five-fold range, and frequency distribution histograms are bimodal, with approximately 25% of subjects included in a high activity subgroup. We set out to characterize the molecular basis for variation in human liver DHEA ST activity. The first step involved performing quantitative Western analysis of cytosol preparations from 92 human liver samples that had been phenotyped with regard to level of DHEA ST enzymatic activity. There was a highly significant correlation (r_s = 0.635, P < 0.0001) between levels of DHEA ST activity and immunoreactive protein. We next attempted to determine whether the expression of DHEA ST might be controlled, in part, by a genetic polymorphism. DNA was isolated from three “low” and three “high” DHEA ST activity liver samples. Exons and the 5′-flanking region of the DHEA ST gene (STD) were amplified for each of these samples with the polymerase chain reaction (PCR). When compared with “wild type” STD sequence, some of the samples contained a T → C transition at DHEA ST cDNA nucleotide 170, located within exon 2, resulting in a Met 57 → Thr change in amino acid. Other samples contained an A → T transversion at nucleotide 557 within STD exon 4 that resulted in a Glu 186 → Val change. STD exons 2 and 4 were then sequenced for DNA isolated from an additional 87 liver samples that had been phenotyped with regard to level of DHEA ST enzymatic activity. The allele frequency for the exon 2 polymorphism in these samples was 0.027, whereas that for the exon 4 polymorphism was 0.038, but neither polymorphism was systematically related to the level of enzyme activity in these samples. Transient expression in COS-1 cells of cDNA that contained the nucleotide 170 and 557 polymorphisms, either separately or together, resulted in decreased expression of both DHEA ST enzymatic activity and level of immunoreactive protein, but only when the nucleotide 557 variant was present. Identification of common genetic polymorphisms within STD will now make it possible to test the hypothesis that those polymorphisms might alter in vivo expression and/or function of this important human steroid-metabolizing enzyme.     

Genetic control of the UV-induced SOS mutator effect in single- and double-stranded DNA phages

The SOS hypothesis postulated that the mutator effect on undameged DNA that generates phage-untargeted mutagenesis (UTM) results directly from the mechanism of targeted mutagenesis. RecA protein, which stimulates the cleavage of both the LexA repressor and UmuD protein, and the UmuDC gene products are required for UV-induced targeted mutagenesis. The use of phage λ for analyzing UV-induced mutagenesis has permitted a distinction to be made between the mechanisms of targeted and untargeted mutagenesis, in that the two processes differ with respect to their genetic requirements for recA⁺ and umuDC⁺ genes. In this paper, we show thet (i) proficiency for excision repair is required for UTM in double-stranded DNA phage but not in single-stranded DNA phage; (ii) the umuC function, which is not required for UTM of the double-stranded DNA phage λ, is necessary for untargeted mutagenesis of the single-stranded DNA phages M13 and φX174; (iii) for both single-stranded and double-stranded DNA phage, UV irradiation of the host increases the level of recA730-induced UTM. Our results are also consistent with the interpretation that the expression of untargeted mutagenesis in phage λ and in M13 depends on the polymerase and to a lesser extent on the exonuclease 5′ → 3′, activities of Po1I. These results suggest that the involvement of the RecA and UmuDC proteins may be related to more than the presence of base damage in the DNA substrate.     

Nicardipine normalizes elevated levels of antioxidant activity in response to xanthine oxidase-induced oxidative stress in hypertensive rat heart

It has been reported that the production of oxygen radicals mediated by xanthine oxidase (XO) is stimulated in hypertensive cardiovascular endothelium, suggesting involvement of oxidative stress in pathogenesis of hypertension. In this study we estimated the effect of nicardipine, a calcium blocker, on the oxidative stress and antioxidant activities in left ventricles from spontaneously hypertensive rat (SHR) and stroke-prone SHR (SHRSP). The activity of XO increased 3.5-fold in SHR and 6.2-fold in SHRSP compared to that in normal controls (WKY). Interestingly, the levels of glutathione (GSH) and the activity of its synthesizing enzyme (γ-glutamylcysteine synthetase, γ-GCS) elevated concomitantly in SHR and SHRSP: the level of GSH increased 1.2-fold in SHR and 1.3-fold in SHRSP. The activity of γ-GCS was elevated 1.5-fold in SHR and 2.4-fold in SHRSP, accompanying an increase in the expression of its mRNA. Treatment of these rats with nicardipine, for 4 weeks improved blood pressure, from 176 ± 10 to 140 ± 8 mmHg in SHR, and from 201 ± 11 to 167 ± 5 mmHg in SHRSP, respectively, and decreased wet weight of heart, levels of GSH, and the activities of XO and γ-GCS. Nicardipine reduced the expression of γ-GCS mRNA. Collectively, these results suggest that reactive oxygen species produced by XO in hypertensive rat heart cause induction of the expression of γ-GCS and nicardipine plays a role in reducing the oxidative stress in hypertensive heart.     

Mutator effects of overproducing DNA polymerase eta (Rad30) and its catalytically inactive variant in yeast

DNA polymerase eta synthesizes DNA in vitro with low fidelity. Based on this, here we report the effects of deletion or increased expression of yeast RAD30 gene, encoding for polymerase eta (Pol eta), on spontaneous mutagenesis in vivo. Deletion of RAD30 did not affect spontaneous mutagenesis. Overproduction of Rad30p was slightly mutagenic in a wild-type yeast strain and moderately mutagenic in strains with inactive 3'-->5'-exonuclease of DNA polymerase epsilon or DNA mismatch repair. These data suggest that excess Rad30p reduces replication fidelity in vivo and that the induced errors may be corrected by exonucleolytic proofreading and DNA mismatch repair. However, the magnitude of mutator effect (only up to 10-fold) suggests that the replication fork is protected from inaccurate synthesis by Pol eta in the absence of DNA damage. Overproduction of catalytically inactive Rad30p was also mutagenic, suggesting that much of the mutator effect results from indirect perturbation of replication rather than from direct misincorporation by Pol eta. Moreover, while excess wild-type Pol eta primarily induced base substitutions in the msh6 and pms1 strains, excess inactive Rad30p induced both base substitutions and frameshifts. This suggests that more than one mutagenic mechanism is operating when RAD30 is overexpressed.     

Depurination-induced infidelity of deoxyribonucleic acid synthesis with purified deoxyribonucleic acid replication proteins in vitro

Removal of purine bases from phi X174 single-stranded DNA leads to increased reversion frequency of amber mutations when this DNA is copied in vitro with purified DNA polymerases. This depurination-induced mutagenesis is observed at three different genetic loci and with several different purified enzymes, including Escherichia coli DNA polymerases I and III, avian myeloblastosis virus DNA polymerase, and eukaryotic DNA polymerases alpha, beta, and gamma. The extent of mutagenesis correlates with the estimated frequency of bypass of the lesion and is greatest with inherently inaccurate DNA polymerases which lack proofreading capacity. With E. coli DNA polymerase I, conditions which diminish proofreading result in a 3-5-fold increase in depurination-induced mutagenesis, suggesting a role for proofreading in determining the frequency of bypass of apurinic sites. The addition of E. coli single-stranded DNA-binding protein to polymerase I catalyzed reactions with depurinated DNA had no effect on the extent of mutagenesis. Analysis of wild-type revertants produced during in vitro DNA synthesis by polymerase I or avian myeloblastosis virus DNA polymerase on depurinated phi X174 amber 3 DNA indicates a preference for insertion of dAMP opposite the putative apurinic site at position 587. These results are discussed in relation both to the mutagenic potential of apurinic sites in higher organisms and to studies on error-prone DNA synthesis.     

Expression of human dihydrofolate reductase cDNA and its induction by chloramphenicol in Bacillus subtilis

A bifunctional plasmid (pMP358) able to replicate and to express cloned human dihydrofolate reductase cDNA (cDHFR) in both Escherichia coli and Bacillus subtilis was constructed. The expression of cDHFR in B. subtilis was the result of a deletion that placed the cDNA fragment under the control of the chloramphenicol acetyltransferase (CAT) gene promoter of Staphylococcus aureus plasmid pC194. By sequence analysis of plasmid pMP358, we observed a gene fusion occurring between the cDHFR and the 32nd codon of the CAT gene. We report that such a “hybrid” gene is able to direct the synthesis of a 25-kDal “hybrid” protein, which was found to be inducible by supplementing B. subtilis cells with sublethal doses of chloramphenicol.     

Replication Fork Collapse and Genome Instability in a Deoxycytidylate Deaminase Mutant

Ribonucleotide reductase (RNR) and deoxycytidylate deaminase (dCMP deaminase) are pivotal allosteric enzymes required to maintain adequate pools of deoxyribonucleoside triphosphates (dNTPs) for DNA synthesis and repair. Whereas RNR inhibition slows DNA replication and activates checkpoint responses, the effect of dCMP deaminase deficiency is largely unknown. Here, we report that deleting the Schizosaccharomyces pombe dcd1⁺ dCMP deaminase gene (SPBC2G2.13c) increases dCTP ∼30-fold and decreases dTTP ∼4-fold. In contrast to the robust growth of a Saccharomyces cerevisiae dcd1Δ mutant, fission yeast dcd1Δ cells delay cell cycle progression in early S phase and are sensitive to multiple DNA-damaging agents, indicating impaired DNA replication and repair. DNA content profiling of dcd1Δ cells differs from an RNR-deficient mutant. Dcd1 deficiency activates genome integrity checkpoints enforced by Rad3 (ATR), Cds1 (Chk2), and Chk1 and creates critical requirements for proteins involved in recovery from replication fork collapse, including the γH2AX-binding protein Brc1 and Mus81 Holliday junction resolvase. These effects correlate with increased nuclear foci of the single-stranded DNA binding protein RPA and the homologous recombination repair protein Rad52. Moreover, Brc1 suppresses spontaneous mutagenesis in dcd1Δ cells. We propose that replication forks stall and collapse in dcd1Δ cells, burdening DNA damage and checkpoint responses to maintain genome integrity.     

Site-directed mutagenesis of the χ subunit of DNA polymerase III and single-stranded DNA-binding protein of E. coli reveals key residues for their interaction

During DNA replication in Escherichia coli, single-stranded DNA-binding protein (SSB) protects single-stranded DNA from nuclease action and hairpin formation. It is known that the highly conserved C-terminus of SSB contacts the χ subunit of DNA polymerase III. However, there only exists a theoretical model in which the 11 C-terminal amino acids of SSB have been docked onto the surface of χ. In order to refine this model of SSB/χ interaction, we exchanged amino acids in χ and SSB by site-directed mutagenesis that are predicted to be of key importance. Detailed characterization of the interaction of these mutants by analytical ultracentrifugation shows that the interaction area is correctly predicted by the model; however, the SSB C-terminus binds in a different orientation to the χ surface. We show that evolutionary conserved residues of χ form a hydrophobic pocket to accommodate the ultimate two amino acids of SSB, P176 and F177. This pocket is surrounded by conserved basic residues, important for the SSB/χ interaction. Mass spectrometric analysis of χ protein cross-linked to a C-terminal peptide of SSB reveals that K132 of χ and D172 of SSB are in close contact. The proposed SSB-binding site resembles those described for RecQ and exonuclease I.