On the identity of dnaP and dnaF genes of Bacillus subtilis

Summary The dnaP strains of Bacillus subtilis are altered in the initiation of DNA replication at high temperature (Riva et al., 1975). Fine mapping of the gene shows that it is located very close to the dnaF gene, described by Karamata and Gross (1970) and mapped by Love et al. (1976) in the polC region. The phenotype of both mutants is indistinguishable: the DNA synthesis stops at non permissive temperature after synthesizing an amount of DNA equivalent to the completion of the rounds of replication already initiated; at permissive temperature they are abnormally sensitive to MMS and are reduced in the ability to be transformed. Both mutants are to be considered as belonging to the dnaF locus.The dnaF gene is very close to the polC gene, which specifies the DNA polymerase III of B. subtilis. The DNA polymerase III of the dnaF mutants is not temperature sensitive in vitro, however, the level of this enzyme is lower by a factor of 4 or 5 in the dnaF mutants, at the permissive temperature. Following shift of dnaF cultures to the non permissive temperature, the level of DNA polymerase III activity specifically decreases further by a factor of at least 10 in the mutant, whereas the DNA polymerase I level is unaffected.The possible roles of the dnaF gene in the control of the cellular level of the DNA polymerase III, and the possibility of a regulatory role of DNA polymerase III in the initiation of DNA replication in bacteria are discussed.Abbreviations and symbols HPUra 6-(p-hydroxyphenylazo)-uracil; mic, minimum inhibitory concentration - MMS methyl-methanesufonate - Pol I Pol II and Pol III: DNA polymerase I, II and III respectively - PCMB parachloro-mercuri-benzoate     

Mapping of the gene specifying DNA polymerase III of Bacillus subtilis

Summary polC, the gene specifying the structure of the replication-specific DNA polymerase III of B. subtilis, was mapped by exploiting azp-12, a mutation conferring resistance to azopyrimidine which determines a mutant, azopyrimidine-resistant enzyme. azp-12 was located in the area of the pyrA locus and is between spcB1 and recA1. azp-12 was linked by transformation to four other mutations which influence the in vitro behaviour of DNA polymerase III-polC25, polC26, mut-1(ts), and DNAF133; the close linkage of these five mutations strongly suggests that they are alleles of the same gene.     

Genetic structure and domains of DNA polymerase III of Bacillus subtilis

Summary We have determined the nucleotide sequence of the polC gene of Bacillus subtilis which codes for DNA polymerase III. Our recent analysis has revealed that the gene comprises 4311 nucleotides, from the start to the stop codon, 306 nucleotides more than we reported earlier. The plasmid reported by us and by N.C. Brown's laboratory contained a sequence at the end of the gene which is not related to the polC region of B. subtilis. We have isolated the rest of the gene, the sequence of which is presented in this paper. The new stop codon is followed by a hyphenated palindromic sequence of 13 nucleotides. The C-terminus' of the coding region contains the novel mutation, dnaF, which results in a defect in the initiation of replication due to a change in the codon TCC to TTC (serine to phenylalanine). The hypermutator mutation mut-1 is due to two point mutations in the 3 to 5 exonuclease domain, the proof reading function. The codon changes are GGA to GAA (glycine to glutamic acid) and AGC to AAC (serine to asparagine). The elongation defective mutation, polC26, affecting the catalytic site that adds nucleotides to the growing chain, is due to a change in the codon GTC to GAC (valine to aspartic acid). It is separated from the mutation reported earlier, azp-12, by 306 nucleotides. Knowing the locations of the mutational sites allowed us to deduce the domains of the gene and the enzyme it encodes, and permitted us to present a precise map of the gene at the molecular level.Abbreviations HPUra p-hydroxyphenyl azouracil - nt nucleotide - PCR polymerase chain reaction     

Prophage induction in Escherichia coli K12 cells deficient in DNA polymerase I.

Summary The induction of prophage by ultraviolet light has been measured inE. coli K12 lysogenic cells deficient in DNA polymerase I. The efficiency of the induction process was greater inpolA1 polC(dnaE) double mutants incubated at the temperature that blocks DNA replication than inpolA ⁺ polC single mutants. Similarly, thepolA1 mutation sensitizedtif-promoted lysogenic induction in apolA1 tif strain at 42°. In strains bearing thepolA12 mutation, which growth normally at 30°, induction of the prophage occured after the shift to 42°. It is concluded that dissapearance of the DNA polymerase I activity leads to changes in DNA replication that are able, per se, to trigger the prophage induction process.     

Bacillus subtilis DNA polymerase III is required for the replication of DNA of bacteriophages SPP-1 and phi 105.

The replication of the Bacillus subtilis bacteriophages SPP-1 and phi 105 is sensitive to 6-(p-hydroxyphenylazo)-uracil (HPUra), a selective inhibitor of replicative DNA synthesis of B. subtilis which acts specifically at the levels of a replication-specific polymerase, DNA polymerase III (pol III). The origin of the HPUra-sensitive polymerase required for phage replication was examined by comparison of the drug sensitivity of phage development in a normosensitive host with that in a host carrying azp-12, a polC mutation that specifies production of an HPUra-resistant pol III. azp-12 specified HPUra-resistant phage host pol III. The host polIII requirement for SPP-1 replication also was confirmed by the demonstration that phage development was temperature sensitive in a host mutant carrying the polC mutation mut-1 (ts). Examination of the pol III activity of crude and purified cell-free preparations derived from phage-infected cells did not indicate any detectable changes in the specific activity, purification behavior, or drug sensitivity of the enzyme.     

Mutagenic DNA repair in Escherichia coli. VIII. Involvement of DNA polymerase III in constitutive and inducible mutagenic repair after ultraviolet and gamma irradiation.

Summary Mutagenic repair in Escherichia coli after ultraviolet (UV) irradiation has previously been shown to require a function of DNA polymerase III. In contrast, no effect of incubating a polC temperature-sensitive strain at 42° has been found after gamma irradiation. Thus at present there is no direct evidence for the involvement of polymerase III in gamma ray mutagenesis. This could, however, merely reflect the stability of the premutational lesion during the period of polymerase III insufficiency such that mutagenic repair is resumed on the plate during subsequent incubation at permissive temperature.It was previously suggested that an inducible factor might interact with polymerase III to enable it to polymerise in an error-prone way in daughter strand gaps opposite non-coding lesions in the template strand. A temperature-resistant revertant (CM 792) of a temperature-sensitive polC strain (CM 731) has been isolated which has properties expected of a strain in which the polymerase III complex is no longer susceptible to the inducible co-factor. Its UV sensitivity, spontaneous mutation rate and mutagenic response to ethyl methanesulphonate are all normal or near normal, also the rates of mutation to prototrophy after gamma irradiation and to streptomycin resistance after UV. These latter mutations are believed to arise through constitutive mutagenic repair at sites in pre-existing DNA. In contrast, the rate of UV-induced mutation to prototrophy due to changes at ochre suppressor loci is greatly depressed and no Weigle-reactivation of bacteriophage T3 is observable; both these effects are believed to result from the action of inducible mutagenic repair in newly-replicated DNA. It is suggested that the 3 to 5 exnnuclease activity of the polymerase III complex in CM 792 may not be susceptible to inhibition by an inducible factor and so continues to remove mismatched bases inserted in newly-replicated DNA opposite damage template sites thus preventing the fixation of errors as mutations.     

Plasmid replication in DNA Ts mutants of Bacillus subtilis.

In an attempt to increase our understanding of plasmid replication in Bacillus subtilis we determined the effect of various dna Ts mutations [Gass, K. B., and Cozzarelli, N. R. (1973). J. Biol. Chem. 248, 7688–7700; Gross, J. D., Karamata, D., and Hempstead, P. G. (1968). Cold Spring Harbor Symp. Quant. Biol.33, 307–312; Karamata, D., and Gross, J. D. (1970). Mol. Gen. Genet.108, 277–287] on pUB110 replication. pUB110 is a kanamycin resistance plasmid originally isolated in Staphylococcus aureus and introduced into B. subtilis by transformation. At temperatures nonpermissive for chromosomal DNA synthesis dnaA13, dnaB19, dnaC6, dnaC30, dnaD23, dnaE20, and dnaI102 permit replication of the plasmid. In several cases this “amplification” continues until approximately equal amounts of plasmid and chromosomal DNA are present. dnaG34, dnaH151, dnaF133, mut-1, and polC26 affect both pUB110 and host DNA synthesis at nonpermissive temperatures. The last three mutations are known to affect the activity of DNA polymerase III (PolIII). When polC26 is incubated at a nonpermissive temperature, there is an accumulation of plasmid DNA with a density on EtBr-CsCl gradients intermediate between that of covalently closed circular (CCC) and open circular DNA. pUB110 can replicate in a strain which is deficient in DNA polymerase I (PolI). Finally, chloramphenicol (Cm) inhibits the replication of pUB110 as well as of chromosomal DNA.     

Escherichia coli DNA polymerase III is responsible for the high level of spontaneous mutations in mutT strains

Reactive oxygen species induce oxidative damage in DNA precursors, i.e. dNTPs, leading to point mutations upon incorporation. Escherichia coli mutT strains, deficient in the activity hydrolysing 8‐oxo‐7,8‐dihydro‐2′‐deoxyguanosine 5′‐triphosphate (8‐oxo‐dGTP), display more than a 100‐fold higher spontaneous mutation frequency over the wild‐type strain. 8‐oxo‐dGTP induces A to C transversions when misincorporated opposite template A. Here, we report that DNA pol III incorporates 8‐oxo‐dGTP ≈ 20 times more efficiently opposite template A compared with template C. Single, double or triple deletions of pol I, pol II, pol IV or pol V had modest effects on the mutT mutator phenotype. Only the deletion of all four polymerases led to a 70% reduction of the mutator phenotype. While pol III may account for nearly all 8‐oxo‐dGTP incorporation opposite template A, it only extends ≈ 30% of them, the remaining 70% being extended by the combined action of pol I, pol II, pol IV or pol V. The unique property of pol III, a C‐family DNA polymerase present only in eubacteria, to preferentially incorporate 8‐oxo‐dGTP opposite template A during replication might explain the high spontaneous mutation frequency in E. coli mutT compared with the mammalian counterparts lacking the 8‐oxo‐dGTP hydrolysing activities.     

DNA polymerase III of Mycoplasma pulmonis: isolation and characterization of the enzyme and its structural gene, polC

Mycoplasmas have originated from Gram-positive bacteria via rapid degenerative evolution. The results of previous investigations of mycoplasmal DNA polymerases suggest that the process of evolution has wrought a major simplification of the typical Gram-positive bacterial DNA polymerase profile, reducing it from three exonuclease (exo)-positive enzymes to a single exo-negative species. The objective of this work was to rigorousiy investigate this suggestion, focusing on the evolutionary fate of DNA polymerase III (Pol III), the enzyme which Gram-positive bacteria specifically require for replicative DNA synthesis. The approach used Mycoplasma pulmonis as the model organism and exploited structural gene cloning, enzymology, and Pol III-specific inhibitors of the HPUra class as investigative tools. Our results indicate that M. pulmonis has strongly conserved a single copy of a structural gene homologous to polC, the Gram-positive bacterial gene encoding Pol III M. pulmonis was found to possess a DNA polymerase that displays the size, primary structure, exonuclease activity, and level of HPUra sensitivity expected of a prototypical Gram-positive Pol III. The high level of sensitivity of M. pulmonis growth to Gram-positive Pol III-selective inhibitors of the HPUra type strongly suggests that Mycoplasma has conserved not only the basic structure of Pol III, but also its essential replicative function. Evidence for a second, HPUra-resistant polymerase activity in M. pulmonis is also described, indicating that the DNA polymerase composition of Mycoplasma is complex and closer to that of Gram-positive bacteria than previously thought.     

Probing the mechanisms of two exonuclease domain mutators of DNA polymerase ϵ

We report the properties of two mutations in the exonuclease domain of the Saccharomyces cerevisiae DNA polymerase ϵ. One, pol2-Y473F, increases the mutation rate by about 20-fold, similar to the catalytically dead pol2-D290A/E290A mutant. The other, pol2-N378K, is a stronger mutator. Both retain the ability to excise a nucleotide from double-stranded DNA, but with impaired activity. pol2-Y473F degrades DNA poorly, while pol2-N378K degrades single-stranded DNA at an elevated rate relative to double-stranded DNA. These data suggest that pol2-Y473F reduces the capacity of the enzyme to perform catalysis in the exonuclease active site, while pol2-N378K impairs partitioning to the exonuclease active site. Relative to wild-type Pol ϵ, both variants decrease the dNTP concentration required to elicit a switch between proofreading and polymerization by more than an order of magnitude. While neither mutation appears to alter the sequence specificity of polymerization, the N378K mutation stimulates polymerase activity, increasing the probability of incorporation and extension of a mismatch. Considered together, these data indicate that impairing the primer strand transfer pathway required for proofreading increases the probability of common mutations by Pol ϵ, elucidating the association of homologous mutations in human DNA polymerase ϵ with cancer.     

The role of DNA polymerase I, II and III in the replication of the bacteriocinogenic factor Clo DF13

Summary The replication of the bacteriocinogenic factor Clo DF13 was studied in Escherichia coli mutants which lack either DNA polymerase I (polA1 and resA1 mutants), DNA polymerase II (polB1 mutant) or DNA polymerase III (dnaE mutant). DNA polymerase I is required for Clo DF13 replication. The Clo DF13 factor, however, can be maintained in a strain carrying the polA107 mutation and thus lacking the 53 exonucleolytic activity of DNA polymerase I. DNA polymerase II is not required for transfer replication and maintenance of the Clo DF13 plasmid. In the temperature sensitive dnaE mutant, Clo DF13 can replicate at the nonpermissive temperature during the first two hours after the temperature shift from 30°C to 43°C. During this period DNA polymerase III seems not to be essential for Clo DF13 replication.     

Genetic mapping of the Saccharomyces cerevisiae DNA polymerase I gene and characterization of a pol1 temperature-sensitive mutant altered in DNA primase-polymerase complex stability

Summary The cloned DNA polymerase I gene has been used to map the POL1 locus on the left arm of chromosome XIV, between MET4 and TOP2. Temperature-sensitive mutants in POL1 have been obtained by in vitro mutagenesis of the cloned gene and in vivo replacement of the wild-type allele with the mutated copy. Physiological and biochemical characterization of one temperature-sensitive mutant (pol1-1) shows that cells shifted to the non-permissive temperature can complete one round of cell division and DNA replication before they arrest. Analysis of DNA polymerase I in crude extracts and in partially purified preparations indicates that the pol1-1 mutation results in a conformational change and affects the stability of the DNA primase-polymerase complex.     

The polymerase subunit of DNA polymerase III of Escherichia coli. I. Amplification of the dnaE gene product and polymerase activity of the alpha subunit

The Escherichia coli dnaE gene, which encodes the alpha subunit of DNA polymerase III (pol III) holoenzyme, has been cloned in a plasmid containing the PL promoter of phage lambda and thermally induced to overproduce the alpha subunit. In cells carrying this plasmid (pKH167), the alpha subunit was amplified, after heat induction, to a level of about 0.2% of the total cellular protein. Polymerase activity was assayed in three ways: (i) gap-filling by pol III holoenzyme and subassemblies of it, (ii) the extensive replication of a primed, single-stranded DNA circle only by pol III holoenzyme, and (iii) complementation of a crude, inactive pol III holoenzyme (temperature-sensitive dnaE mutant fraction) in replication of a primed, single-stranded DNA circle. Amplification of the alpha subunit raised the polymerase level 10-fold in assay (i), indicative of the dependence of pol III gap-filling activity on this polypeptide; pol III holoenzyme activity remained unaffected (assay (ii)), but the complementation activity was raised 5-fold (assay (iii)). Thus, the elevated alpha subunit (free or in a subassembly form) can substitute in vitro for a defective alpha subunit in pol III holoenzyme, but cannot increase the in vivo level of about eight pol III holoenzyme molecules per cell. This low level of pol III holoenzyme is fixed in wild type cells (bearing no plasmid) despite the presence of a 5-fold excess of the alpha subunit, as inferred from the various assays. These results suggest that the low level of pol III holoenzyme is determined by a factor or factors other than the level of the alpha subunit.     

On the molecular mechanism of GC content variation among eubacterial genomes

Background  

As a key parameter of genome sequence variation, the GC content of bacterial genomes has been investigated for over half a century, and many hypotheses have been put forward to explain this GC content variation and its relationship to other fundamental processes. Previously, we classified eubacteria into dnaE-based groups (the dimeric combination of DNA polymerase III alpha subunits), according to a hypothesis where GC content variation is essentially governed by genome replication and DNA repair mechanisms. Further investigation led to the discovery that two major mutator genes, polC and dnaE2, may be responsible for genomic GC content variation. Consequently, an in-depth analysis was conducted to evaluate various potential intrinsic and extrinsic factors in association with GC content variation among eubacterial genomes.     

Conditional lethality of the recA441 and recA730 mutants of Escherichia coli deficient in DNA polymerase I

E. coli strains bearing the recA441 mutation and various mutations in the polA gene resulting in enzymatically well-defined deficiencies of DNA polymerase I have been constructed. It was found that the recA441 strains bearing either the polA1 or polA12 mutation causing deficiency of the polymerase activity of pol I are unable to grow at 42 degrees C on minimal medium supplemented with adenine, i.e., when the SOS response is continuously induced in strains bearing the recA441 mutation. Under these conditions the inhibition of DNA synthesis is followed in recA441 polA12 by DNA degradation and loss of cell viability. A similar lethal effect is observed with the recA730 polA12 mutant. The recA441 strain bearing the polA107 mutation resulting in the deficiency of the 5'-3' exonuclease activity of pol I shows normal growth under conditions of continuous SOS response. We postulate that constitutive expression of the SOS response leads to an altered requirement for the polymerase activity of pol I.     

Holoenzyme DNA polymerase III fixes mutations

DNA polymerase III is required for mutagenesis after damage to the chromosome. This effect is not modulated by the presence or absence of DNA polymerase II activity in the cell. In cells containing a temperature-sensitive dnaE mutation, the alpha-subunit of DNA polymerase III is inactivated at the restrictive temperature, resulting in lethality. Cells containing the pcbA1 mutation can continue replication if DNA polymerase I activity is present. When such cells are shifted from the permissive to the restrictive temperature, mutagenesis decreases rapidly after 10 min. These results are compatible with conversion of the replicative apparatus from one containing a functional DNA polymerase III synthetic subunit to one containing DNA polymerase I. We also find that DNA polymerase I dependent replication is markedly sensitive to coumermycin A1. We conclude that DNA polymerase III holoenzyme with the alpha-subunit is required for fixing mutations in the genome.     

The 3′ → 5′ exonucleases of both DNA polymerases δ and ε participate in correcting errors of DNA replication in Saccharomyces cerevisiae

DNA polymerases II (ε) and III(δ) are the only nuclear DNA polymerases known to possess an intrinsic 3′ → 5′ exonuclease in Saccharomyces cerevisiae. We have investigated the spontaneous mutator phenotypes of DNA polymerase δ and ε 3′ → 5′ exonuclease-deficient mutants, pol3-01 and pol2-4, respectively. pol3-01 and pol2-4 increased spontaneous mutation rates by factors of the order of 10² and 10¹, respectively, measured as URA3 forward mutation and his7-2 reversion. Surprisingly, a double mutant pol2-4 pol3-01 haploid was inviable. This was probably due to accumulation of unedited errors, since a pol2-4/pol2-4 pol3-01/pol3-01 diploid was viable, with the spontaneous his7-2 reversion rate increased by about 2 × 10³-fold. Analysis of mutation rates of double mutants indicated that the 3′ → 5′ exonucleases of DNA polymerases δ and ε can act competitively and that, like the 3′ → 5′ exonuclease of DNA polymerase δ the 3′ → 5′ exonuclease of DNA polymerase ε acts in series with the PMS1 mismatch correction system. Mutational spectra at a URA3 gene placed in both orientations near to a defined replication origin provided evidence that the 3′ → 5′ exonucleases of DNA polymerases δ and ε act on opposite DNA strands, but were in sufficient to distinguish conclusively between different models of DNA replication.     

The exceptionally high rate of spontaneous mutations in the polymerase delta proofreading exonuclease-deficient Saccharomyces cerevisiae strain starved for adenine

Background

Mutagenesis induced in the yeast Saccharomyces cerevisiae by starvation for nutrilites is a well-documented phenomenon of an unknown mechanism. We have previously shown that the polymerase delta proofreading activity controls spontaneous mutagenesis in cells starved for histidine. To obtain further information, we compared the effect of adenine starvation on mutagenesis in wild-type cells and, in cells lacking the proofreading activity of polymerase delta (phenotype Exo^-, mutation pol3-01).

Results

Ade⁺ revertants accumulated at a very high rate on adenine-free plates so that their frequency on day 16 after plating was 1.5 × 10^-4 for wild-type and 1.0 × 10^-2 for the Exo^- strain. In the Exo^- strain, all revertants arising under adenine starvation are suppressors of the original mutation, most possessed additional nutritional requirements, and 50% of them were temperature sensitive.

Conclusions

Adenine starvation is highly mutagenic in yeast. The deficiency in the polymerase delta proofreading activity in strains with the pol3-01 mutation leads to a further 66-fold increase of the rate of mutations. Our data suggest that adenine starvation induces genome-wide hyper-mutagenesis in the Exo^- strain.     

Replication slippage of different DNA polymerases is inversely related to their strand displacement efficiency.

Replication slippage is a particular type of error caused by DNA polymerases believed to occur both in bacterial and eukaryotic cells. Previous studies have shown that deletion events can occur in Escherichia coli by replication slippage between short duplications and that the main E. coli polymerase, DNA polymerase III holoenzyme is prone to such slippage. In this work, we present evidence that the two other DNA polymerases of E. coli, DNA polymerase I and DNA polymerase II, as well as polymerases of two phages, T4 (T4 pol) and T7 (T7 pol), undergo slippage in vitro, whereas DNA polymerase from another phage, Phi29, does not. Furthermore, we have measured the strand displacement activity of the different polymerases tested for slippage in the absence and in the presence of the E. coli single-stranded DNA-binding protein (SSB), and we show that: (i) polymerases having a strong strand displacement activity cannot slip (DNA polymerase from Phi29); (ii) polymerases devoid of any strand displacement activity slip very efficiently (DNA polymerase II and T4 pol); and (iii) stimulation of the strand displacement activity by E. coli SSB (DNA polymerase I and T7 pol), by phagic SSB (T4 pol), or by a mutation that affects the 3' --> 5' exonuclease domain (DNA polymerase II exo(-) and T7 pol exo(-)) is correlated with the inhibition of slippage. We propose that these observations can be interpreted in terms of a model, for which we have shown that high strand displacement activity of a polymerase diminishes its propensity to slip.