Temperature-dependent mutational specificity of an Escherichia coli mutator, dnaQ49, defective in 3'----5' exonuclease (proofreading) activity

Escherichia coli strains carrying the temperature-dependent dnaQ49 allele are strong mutators at 37 degrees C. Since the dnaQ49 gene encodes the epsilon subunit of DNA polymerase III, it is thought that the large number of errors results in part from impaired proofreading activity during DNA replication. We have examined dnaQ49-induced reversion patterns of defined trpA alleles to determine the kinds of errors produced by dnaQ49 at 30 degrees C and 37 degrees C. We found that at 37 degrees C dnaQ49 produced all types of base-pair substitutions in addition to frameshifts with transitions generally occurring more frequently than transversions. This generalized mutator activity is very similar to that displayed in rich medium by mutD5, another mutator allele at the dnaQ locus. However, when dnaQ49 strains were cultured at 30 degrees C, not only were reversion frequencies much lower than at 37 degrees C, but in addition, the spectrum was altered. Transversions became proportionally more prevalent in the reversion spectra at the lower temperature. We suggest the possibility that at 37 degrees C dnaQ49 results in defective proofreading and methyl-directed postreplicative mismatch repair, while at 30 degrees C mismatch repair is fully and proofreading partially restored.     

Mutational specificity of a conditional Escherichia coli mutator, mutD5

Summary MutD5, a conditional mutator in Escherichia coli, causes the stimulation of mutation frequencies 50 to 100 fold in minimal medium. In rich medium mutation frequencies are further increased 50 to 100 fold. We show here that all possible base-pair mutations are increased in a mutD5 strain grown in rich medium. A:TG:C transitions as well as A:TC:G, A:TT:A aud G:CC:G transversions are stimulated. Transitions occur more frequently than transversions. MutD5 also increases the reversion frequencies of three trpA frameshift mutations by causing base-pair additions, and, possibly, base-pair deletions.     

Frameshift mutations induced by an Escherichia coli strain carrying a mutator gene, mutD5

We have studied eight frameshift mutations induced by the Escherichia coli mutator allele mutD5 in a derivative of the bacteriophage M13mp8, carrying an insertion of 91 base pairs derived from the tetR gene of pBR 322. All mutations were analyzed by the dideoxy sequencing method and were found to be deletions of a GC base pair which occurred in regions characterized by the presence of at least two GC base pairs. We have attempted to explain these results by the looping-out model, which was previously proposed to unify the results obtained with mutD5.     

Characterization of a 3''----5'' exonuclease activity in the phage phi 29-encoded DNA polymerase.

Purified protein p2 of phage phi 29, characterized as a specific DNA polymerase involved in the initiation and elongation of phi 29 DNA replication, contains a 3'----5' exonuclease active on single-stranded DNA, but not on double-stranded DNA. No 5'----3' exonuclease activity was found. The 3'----5' exonuclease activity was shown to be associated with the DNA polymerase since 1) the two activities were heat-inactivated with identical kinetics and 2) both activities, present in purified protein p2, cosedimented in a glycerol gradient.     

Saturation of mismatch repair in the mutD5 mutator strain of Escherichia coli.

The mutD (dnaQ) gene of Escherichia coli codes for the proofreading activity of DNA polymerase III. The very strong mutator phenotype of mutD5 strains seems to indicate that their postreplicational mismatch repair activity is also impaired. We show that the mismatch repair system of mutD5 strains is functional but saturated, presumably by the excess of DNA replication errors, since it is recovered by inhibiting chromosomal DNA replication. This recovery depends on de novo protein synthesis.     

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.     

High expression of a 3''----5'' exonuclease activity is specific to B lymphocytes.

V(D)J joining, the immunoglobulin heavy-chain (IgH) class switch, and somatic hypermutation directed at variable regions are unique genetic recombination or mutation events which occur during B-cell differentiation. The enzymatic process directing and controlling these events remains obscure. An assay for exonucleolytic activity has been devised, and an exonuclease activity expressed at high levels in normal B lymphocytes has been detected. The high expression of this enzyme is specific to B lymphocytes and may be developmentally regulated. We have partially purified a B-cell-associated nuclease by column chromatography. Using this preparation, we have begun a rigorous analysis of its activity. This activity is a nonprocessive, 3'----5' exonuclease with a requirement for divalent cations. Our studies demonstrate that EDTA, poly(dI-dC), and glycerol are all inhibitory to B-cell-associated exonucleolytic activity. The exonuclease displays sequence preference but no sequence specificity when tested on a variety of native DNA substrates. This nuclease is distinct from other exonuclease activities previously described.     

Deoxyribonucleic acid repair in Escherichia coli mutants deficient in the 5''----3'' exonuclease activity of deoxyribonucleic acid polymerase I and exonuclease VII.

A series of Escherichia coli strains deficient in the 5'----3' exonuclease activity associated with deoxyribonucleic acid (DNA) polymerase I (exonuclease VI) and exonuclease VII has been constructed. Both of these enzymes are capable of pyrimidine dimer excision in vitro. These strains were examined for conditional lethality, sensitivity to ultraviolet (UV) and X-irradiation, postirradiation DNA degradation, and ability to excise pyrimidine dimers. It was found that strains deficient in both exonuclease VI (polAex-) and exonuclease VII (xseA-) are significantly reduced in their ability to survive incubation at elevated temperature (43 degrees C) beyond the reduction previously observed for the polAex single mutants. The UV and X-ray sensitivity of the exonuclease VI-deficient strains was not increased by the addition of the xseA7 mutation. Mutants deficient in both enzymes are about as efficient as wild-type strains at excising dimers produced by up to 40 J/m2 UV. At higher doses strains containing only polAex- mutations show reduced ability to excise dimers; however, the interpretation of dimer excision data at these doses is complicated by extreme postirradiation DNA degradation in these strains. The additional deficiency in the polAex xseA7 double-mutant strains has no significant effect on either postirradiation DNA degradation or the apparent deficiency in dimer excision at high UV doses observed in polAex single mutants.     

Genetic requirements and mutational specificity of the Escherichia coli SOS mutator activity.

To better understand the mechanisms of SOS mutagenesis in the bacterium Escherichia coli, we have undertaken a genetic analysis of the SOS mutator activity. The SOS mutator activity results from constitutive expression of the SOS system in strains carrying a constitutively activated RecA protein (RecA730). We show that the SOS mutator activity is not enhanced in strains containing deficiencies in the uvrABC nucleotide excision-repair system or the xth and nfo base excision-repair systems. Further, recA730-induced errors are shown to be corrected by the MutHLS-dependent mismatch-repair system as efficiently as the corresponding errors in the rec+ background. These results suggest that the SOS mutator activity does not reflect mutagenesis at so-called cryptic lesions but instead represents an amplification of normally occurring DNA polymerase errors. Analysis of the base-pair-substitution mutations induced by recA730 in a mismatch repair-deficient background shows that both transition and transversion errors are amplified, although the effect is much larger for transversions than for transitions. Analysis of the mutator effect in various dnaE strains, including dnaE antimutators, as well as in proofreading-deficient dnaQ (mutD) strains suggests that in recA730 strains, two types of replication errors occur in parallel: (i) normal replication errors that are subject to both exonucleolytic proofreading and dnaE antimutator effects and (ii) recA730-specific errors that are not susceptible to either proofreading or dnaE antimutator effects. The combined data are consistent with a model suggesting that in recA730 cells error-prone replication complexes are assembled at sites where DNA polymerization is temporarily stalled, most likely when a normal polymerase insertion error has created a poorly extendable terminal mismatch. The modified complex forces extension of the mismatch largely at the exclusion of proofreading and polymerase dissociation pathways. SOS mutagenesis targeted at replication-blocking DNA lesions likely proceeds in the same manner.     

A dominant (mutD5) and a recessive (dnaQ49) mutator of Escherichia coli

The two known strong mutators of Escherichia coli K12, mutD5 (Degnen & Cox, 1974) and dnaQ49 (Horiuchi et al., 1978), are located at almost the same position, at five minutes on the linkage map. To clarify the genetical and functional relationships between these two mutators, we have constructed hybrid plasmids and phages carrying dnaQ+ or mutD5 by using in vivo and in vitro recombination techniques and examined their effect on the phenotype of wild-type or mutant bacteria. The results indicated that the mutD5 mutator is dominant over the wild-type allele whereas dnaQ49 is recessive. Thus, mutD5 plasmid or mutD5 transducing lambda phage can be used to convert a wild-type strain to a highly mutable strain. Both dnaQ+ and mutD5 plasmids carried a 1.5 X 10(3) base DNA fragment derived from the E. coli chromosome and they were indistinguishable from each other by restriction enzyme analysis. Moreover, specific labeling of the plasmid-encoded proteins by the maxicell method revealed that the mutD5 plasmid codes for two proteins, one whose molecular weight is 25,000 and the other whose molecular weight is 21,000, which correspond to the dnaQ protein and RNase H, respectively. Insertion of the gamma delta sequence into the mutD gene of the plasmid resulted in disappearance of the 25,000 Mr protein. These results suggested that the dnaQ49 and mutD5 mutator are mutations that have arisen in a single gene, though they differ in many respects.     

Characterization of 3''----5'' exonuclease associated with DNA polymerase of silkworm nuclear polyhedrosis virus.

3'----5' Exonuclease specific for single-stranded DNA copurified with DNA polymerase of nuclear polyhedrosis virus of silkworm Bombyx mori (BmNPV Pol). BmNPV Pol has no detectable 5'----3' exonuclease activity on single-stranded or duplex DNA. Analysis of the products of 3'----5' exonucleolytic reaction showed that deoxynucleoside monophosphates were released during the hydrolysis of single-stranded DNA. The exonuclease activity cosedimented with the polymerase activity during ultracentrifugation of BmNPV Pol in glycerol gradient. The polymerase and the exonuclease activities of BmNPV Pol were inactivated by heat with nearly identical kinetics. The mode of the hydrolysis of single-stranded DNA by BmNPV Pol-associated exonuclease was strictly distributive. The enzyme dissociated from single-stranded DNA after the release of a single dNMP and then reassociated with a next polynucleotide being degradated.     

Mutational specificity of a proof-reading defective Escherichia coli dnaQ49 mutator

Summary The dnaQ (mutD) gene product which encodes the -subunit of the DNA polymerase III holoenzyme has a central role in controlling the fidelity of DNA replication because both mutD5 and dnaQ49 mutations severely decrease the 3–5 exonucleolytic editing capacity.It is shown in this paper that more than 95% of all anaQ49-induced base pair substitutions are transversions of the types G:C-T:A and A:T-T:A. Not only is this unusual mutational specificity precisely that observed recently for a number of potent carcinogens such as benzo(a) pyrene diolepoxide (BPDE) and aflatoxin B1 (AFB1), which are dependent on the SOS system to mutagenize bacteria, but it is also seen for the constitutively expressed SOS mutator activity in E. coli tif-1 strains as well as for the SOS mutator activity mediated gap filling of apurinic sites. Because the G:C-T:A and A:T-T:A transversions can either result from the insertion of an adenine across from apurinic sites or arise due to the incorporation of syn-adenine opposite a purine base, we postulate that the DNA polymerase III holoenzyme also has a reduced discrimination ability in a dnaQ49 background.The introduction of a lexA (Ind^-) allele, which prevents the expression of SOS functions, led to a significant reduction in the dnaQ49-caused mutator effect.Both, the mutational specificity observed and the partial lexA ⁺ dependence of the mutator effect provoke a reanalysis of the hypothesis that the DNA polymerase III holoenzyme can be converted into the postulated but until now unidentified SOS polymerase.     

Selective inactivation of the 3'' to 5'' exonuclease activity of Escherichia coli DNA polymerase I by heat

Heat selectively inactivates the 3' to 5' exonuclease activity of E. coli DNA polymerase I, resulting in reduced dNTP turnover and lower fidelity of replication of homopolymer and natural DNA templates.     

DNA methylation alters the pattern of spontaneous mutation in Escherichia coli cells (mutD) defective in DNA polymerase III proofreading

We have shown previously that dam mutants of Escherichia coli have a weak mutator phenotype which generates mostly transition mutations in the P22 mnt gene. In contrast, in mutD5 cells, which have a strong mutator phenotype, transversion mutations were the most prevalent. A dam-16 mutD5 strain, defective in both DNA polymerase III associated-proofreading and Dam-directed mismatch repair exhibits a strong mutator phenotype but, surprisingly, its mutation spectrum is similar to that of the dam rather than the mutD parent. The most likely explanation is that Dam-directed mismatch repair in the mutD5 strain corrects most of the potential transition mutations (therefore yielding transversions) in the newly synthesised strand. When the dam-16 allele is present together with mutD5 a reduced efficiency of repair as well as loss of strand discrimination and misdirected repair results in the appearance of transition mutations at high frequency.     

Effects of Escherichia coli dnaE antimutator alleles in a proofreading-deficient mutD5 strain.

We have previously isolated seven mutants of Escherichia coli which replicate their DNA with increased fidelity. These mutants were isolated as suppressors of the elevated mutability of a mismatch-repair-defective mutL strain. Each mutant was shown to contain a single amino acid substitution in the dnaE gene product, the alpha (i.e., polymerase) subunit of DNA polymerase III holoenzyme responsible for replicating the E. coli chromosome. The mechanism(s) by which these antimutators exert their effect is of interest. Here, we have examined the effects of the antimutator alleles in a mutD5 mutator strain. This strain carries a mutation in the dnaQ gene, which results in defective exonucleolytic proofreading. Our results show that dnaE mutations also confer a strong antimutator phenotype in this background, the effects being generally much greater than those observed previously in the mutL background. The results suggest that the dnaE antimutator alleles can exert their effect independently of exonucleolytic proofreading activity. The large magnitude of the antimutator effects in the mutD5 background can be ascribed, at least in part, to the (additional) restoration of DNA mismatch repair, which is generally impaired in mutD5 strains because of error saturation. The high mutability of mutD5 strains was exploited to isolate a strong new dnaE antimutator allele on the basis of its ability to suppress the high reversion rate of an A.T-->T.A transversion in this background. A model suggesting how the dnaE antimutator alleles might exert their effects in proofreading-proficient and -deficient backgrounds is presented.     

Defect in excision repair alters the mutational specificity of PUVA treatment in the lacI gene of Escherichia coli

The sequences of 152 lacI- mutations obtained following exposure of Escherichia coli UvrB- strain NR3951 to ultraviolet light in the presence of 8-methoxypsoralen (PUVA treatment) were compared to the spectrum of mutation induced by PUVA treatment in a Uvr+ strain, NR3835. Mutations recovered following PUVA treatment of the UvrB- strain were quite different from those recovered in the Uvr+ strain. In addition, they occurred at a restricted number of unique sites. For example, A.T----T.A base substitutions at position 141, minus G frameshifts at positions 586/587/588 and deletions of 15 base-pairs from position 78 to 92 accounted for 50% or more of mutations recovered in each of the above mutational classes. This altered mutational specificity was accompanied by a failure to recover mutations frequently identified following PUVA treatment of the Uvr+ strain. These mutations include spontaneous-hotspot frameshifts involving the gain or loss of a tetramer 5'-CTGG-3' repeated three times at position 620 to 631; and minus A.T base-pair frameshifts recovered at potential T-T crosslink sites. These results indicate that while crosslinks may play a substantial role in the induction of mutation in the Uvr+ strain, they do not contribute substantially to mutagenesis in the UvrB- strain. In addition, the data also suggest that excision repair may not always occur in an error-free manner.     

Structural basis for the 3''-5'' exonuclease activity of Escherichia coli DNA polymerase I: a two metal ion mechanism.

The refined crystal structures of the large proteolytic fragment (Klenow fragment) of Escherichia coli DNA polymerase I and its complexes with a deoxynucleoside monophosphate product and a single-stranded DNA substrate offer a detailed picture of an editing 3'-5' exonuclease active site. The structures of these complexes have been refined to R-factors of 0.18 and 0.19 at 2.6 and 3.1 A resolution respectively. The complex with a thymidine tetranucleotide complex shows numerous hydrophobic and hydrogen-bonding interactions between the protein and an extended tetranucleotide that account for the ability of this enzyme to denature four nucleotides at the 3' end of duplex DNA. The structures of these complexes provide details that support and extend a proposed two metal ion mechanism for the 3'-5' editing exonuclease reaction that may be general for a large family of phosphoryltransfer enzymes. A nucleophilic attack on the phosphorous atom of the terminal nucleotide is postulated to be carried out by a hydroxide ion that is activated by one divalent metal, while the expected pentacoordinate transition state and the leaving oxyanion are stabilized by a second divalent metal ion that is 3.9 A from the first. Virtually all aspects of the pretransition state substrate complex are directly seen in the structures, and only very small changes in the positions of phosphate atoms are required to form the transition state.