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.     

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.     

Haemophilus influenzae and Vibrio cholerae genes for mutH are able to fully complement a mutH defect in Escherichia coli

MutH, MutL and MutS are essential components of the mismatch repair system in Escherichia coli. Whereas mutS and mutL genes are found in most organisms, the mutH gene is limited to some proteobacteria. We show here that the cloned genes of MutH from Vibrio cholerae and Haemophilus influenzae are able to fully complement a mutH defect in E. coli. Moreover, the purified proteins were shown to be dam methylation sensitive endonucleases, which can be activated by the E. coli MutL protein. These results allow to narrow down regions that are important for the interaction of MutH with MutL.     

Mismatch repair genes of Streptococcus pneumoniae: HexA confers a mutator phenotype in Escherichia coli by negative complementation.

DNA repair systems able to correct base pair mismatches within newly replicated DNA or within heteroduplex molecules produced during recombination are widespread among living organisms. Evidence that such generalized mismatch repair systems evolved from a common ancestor is particularly strong for two of them, the Hex system of the gram-positive Streptococcus pneumoniae and the Mut system of the gram-negative Escherichia coli and Salmonella typhimurium. The homology existing between HexA and MutS and between HexB and MutL prompted us to investigate the effect of expressing hex genes in E. coli. Complementation of mutS or mutL mutations, which confer a mutator phenotype, was assayed by introducing on a multicopy plasmid the hexA and hexB genes, under the control of an inducible promoter, either individually or together in E. coli strains. No decrease in mutation rate was conferred by either hexA or hexB gene expression. However, a negative complementation effect was observed in wild-type E. coli cells: expression of hexA resulted in a typical Mut- mutator phenotype. hexB gene expression did not increase the mutation rate either individually or in conjunction with hexA. Since expression of hexA did not affect the mutation rate in mutS mutant cells and the hexA-induced mutator effect was recA independent, it is concluded that this effect results from inhibition of the Mut system. We suggest that HexA, like its homolog MutS, binds to mismatches resulting from replication errors, but in doing so it protects them from repair by the Mut system. In agreement with this hypothesis, an increase in mutS gene copy number abolished the hexA-induced mutator phenotype. HexA protein could prevent repair either by being unable to interact with Mut proteins or by producing nonfunctional repair complexes.     

Spontaneous mutators of salmonella typhimurium LT2 generated by insertion of transposable elements.

Spontaneous mutators of Salmonella typhimurium LT2 were generated by inserting the transposable element Tn5 or Tn10 into the bacterial chromosome. Two mutators mapped at the position of the mutH and mutL loci of S. typhimurium, and two other mutators mapped at positions corresponding to the mutS and uvrD loci of Escherichia coli. A fifth mutator, mutB, did not map at a position corresponding to any of the known mutators of S. typhimurium or E. coli. The mutH,L,S and uvrD alleles increased the frequency of both spontaneous base substitution and frameshift mutations, whereas the mutB allele increased the frequency only of spontaneous base substitution mutations. The increased frequency of base substitution mutations was recA+ independent in the mutH, mutL, and uvrD strains and partially recA+ independent in the mutS strain. The uvrD mutation decreased the resistance of the cells to killing by ultraviolet irradiation. The mutH,L,S and uvrD strains showed an increased sensitivity to mutagenesis by the alkylating agents methyl methane sulfonate and ethyl methane sulfonate, but not to mutagenesis by 4-nitroquinoline-1-oxide.     

Mutations affecting replication and copy number control in plasmid mini-F both reside in the gene for the 29-kDa protein

We have isolated and characterized cop, copts, and repam mutants of plasmid mini-F after in vitro mutagenesis with hydroxylamine. cop mutants exhibit a copy number of about 10 per cell. The copts mutants are cold-sensitive and have, at 25 degrees C, a copy number of about 30-40 copies per cell, which drops to 4 copies at 42 degrees C. The cop and repam mutations affect the 29-kDa E protein. The Copts phenotype results from the simultaneous occurrence of two mutations, a cop mutation in the E protein and a temperature-dependent mutation (termed ecp) enhancing the Cop phenotype at low temperature. The latter new type of mutation is located within the DNA region 44.1-44.85F. Complementation experiments with plasmid cointegrates show that the wild-type gene is dominant over the cop allele. The nucleotide sequences of the cop and the repam mutations have been determined.     

Saturation of DNA mismatch repair and error catastrophe by a base analogue in Escherichia coli

Deoxyribosyl-dihydropyrimido[4,5-c][1,2]oxazin-7-one (dP) is a potent mutagenic deoxycytidine-derived base analogue capable of pairing with both A and G, thereby causing G. C --> A. T and A. T --> G. C transition mutations. We have found that the Escherichia coli DNA mismatch-repair system can protect cells against this mutagenic action. At a low dose, dP is much more mutagenic in mismatch-repair-defective mutH, mutL, and mutS strains than in a wild-type strain. At higher doses, the difference between the wild-type and the mutator strains becomes small, indicative of saturation of mismatch repair. Introduction of a plasmid containing the E. coli mutL(+) gene significantly reduces dP-induced mutagenesis. Together, the results indicate that the mismatch-repair system can remove dP-induced replication errors, but that its capacity to remove dP-containing mismatches can readily be saturated. When cells are cultured at high dP concentration, mutant frequencies reach exceptionally high levels and viable cell counts are reduced. The observations are consistent with a hypothesis in which dP-induced cell killing and growth impairment result from excess mutations (error catastrophe), as previously observed spontaneously in proofreading-deficient mutD (dnaQ) strains.     

Mutation spectrum in Escherichia coli DNA mismatch repair deficient (mutH) strain

The Dam-directed post-replicative mismatch repair system of Escherichia coli removes base pair mismatches from DNA. The products of the mutH, mutL and mutS genes, among others, are required for efficient mismatch repair. Absence of any of these gene products leads to persistence of mismatches in DNA with a resultant increase in spontaneous mutation rate. To determine the specificity of the mismatch repair system in vivo we have isolated and characterized 47 independent mutations from a mutH strain in the plasmid borne mnt repressor gene. The major class of mutations comprises AT to GC transitions that occur within six base pairs of the only two 5'-GATC-3' sequences in the mnt gene. In the wild type control strain, insertion of the IS1 element was the major spontaneous mutational event. A prediction of the Dam-directed mismatch repair model, that the mutation spectra of dam and mutH strains should be the same, was confirmed.     

Spontaneously arising mutL mutators in evolving Escherichia coli populations are the result of changes in repeat length

Over the course of thousands of generations of growth in a glucose-limited environment, 3 of 12 experimental populations of Escherichia coli spontaneously and independently evolved greatly increased mutation rates. In two of the populations, the mutations responsible for this increased mutation rate lie in the same region of the mismatch repair gene mutL. In this region, a 6-bp repeat is present in three copies in the gene of the wild-type ancestor of the experimental populations but is present in four copies in one of the experimental populations and two copies in the other. These in-frame mutations either add or delete the amino acid sequence LA in the MutL protein. We determined that the replacement of the wild-type sequence with either of these mutations was sufficient to increase the mutation rate of the wild-type strain to a level comparable to that of the mutator strains. Complementation of strains bearing the mutator mutations with wild-type copies of either mutL or the mismatch repair gene uvrD rescued the wild-type mutation rate. The position of the mutator mutations-in the region of MutL known as the ATP lid-suggests a possible deficiency in MutL's ATPase activity as the cause of the mutator phenotype. The similarity of the two mutator mutations (despite the independent evolutionary histories of the populations that gave rise to them) leads to a discussion of the potential adaptive role of DNA repeats.     

The extreme mutator effect of Escherichia coli mutD5 results from saturation of mismatch repair by excessive DNA replication errors.

Escherichia coli mutator mutD5 is the most potent mutator known. The mutD5 mutation resides in the dnaQ gene encoding the proofreading exonuclease of DNA polymerase III holoenzyme. It has recently been shown that the extreme mutability of this strain results, in addition to a proofreading defect, from a defect in mutH, L, S-encoded postreplicational DNA mismatch repair. The following measurements of the mismatch-repair capacity of mutD5 cells demonstrate that this mismatch-repair defect is not structural, but transient. mutD5 cells in early log phase are as deficient in mismatch repair as mutL cells, but they become as proficient as wild-type cells in late log phase. Second, arrest of chromosomal replication in a mutD5-dnaA(Ts) strain at a nonpermissive temperature restores mismatch repair, even from the early log phase of growth. Third, transformation of mutD5 strains with multicopy plasmids expressing the mutH or mutL gene restores mismatch repair, even in rapidly growing cells. These observations suggest that the mismatch-repair deficiency of mutD strains results from a saturation of the mutHLS-mismatch-repair system by an excess of primary DNA replication errors due to the proofreading defect.     

Gene conversion in Escherichia coli. Resolution of heteroallelic mismatched nucleotides by co-repair

We have constructed heteroduplex plasmid DNA that is similar in structure to the heteroduplex DNA expected to be produced during genetic recombination of plasmids, and studied its repair after transformation into different Escherichia coli strains. The heteroduplex DNA was constructed using two different parental plasmids, each of which contained a different ten-nucleotide insertion mutation. The effect of different defined states of dam-methylation on repair was also examined. We found that heteroduplex DNA repair occurred prior to the replication of the substrate DNA 60 to 80% of the time, regardless of the state of DNA methylation. Most excision/synthesis tracts covered two markers separated by 1243 base-pairs, and this process has been termed co-repair. The most efficient co-repair pathway was the Dam-instructed repair pathway that required the mutH, mutL, mutS and uvrD gene products and preferentially used the methylated strand as the template for DNA synthesis. If there was no methylation asymmetry, mismatch nucleotide repair occurred with a similar frequency; however, no strand bias was observed. Co-repair of symmetrically methylated heteroduplex DNA required the mutS and uvrD gene products, while repair of unmethylated heteroduplex DNA also required the mutL and mutH gene products.     

Hyper-Recombining Recipient Strains in Bacterial Conjugation

Using a direct enrichment and screening procedure, mutants of Escherichia coli have been isolated in which recombination frequencies for several intragenic Hfr X F- crosses are significantly higher (twofold to sixfold) than in the parental strains. These hyper-recombination mutations comprised five new mutS- and one new mutL- allele. Together with other known mut- alleles, they were analyzed for effects on intragenic recombination using several types of crosses. Hyper-recombination was found for mutS-, mutL-, mutH (= mutR)- and mutU (= uvrD)-, with the largest effects seen for certain alleles of uvrD; these resulted in over 20-fold excesses in recombinant production for Hfr X F- crosses and F'-chromosome homogenotization. Spontaneous mutator ability was not always correlated with degree of hyper-recombination.     

Nucleotide sequence of the Escherichia coli mutH gene.

The complete nucleotide sequence of mutH gene from E. coli has been determined. Based on the deduced amino acid sequence, the MutH protein has a molecular weight of 25.4 kdaltons in agreement with the previous estimates based on SDS-polyacrylamide gel electrophoresis of the purified protein. Deletion analysis of the DNA sequences upstream of mutH has identified the promoter region for this gene. Two independently isolated temperature sensitive alleles of the mutH gene have also been sequenced. One mutation results in an amino acid change at position 27 (thr to leu) while the other occurs at position 156 (asp to asn).     

DNA mismatch-repair in Escherichia coli counteracting the hydrolytic deamination of 5-methyl-cytosine residues.

Derivatives of phage M13 were constructed and used for the in vitro preparation of heteroduplex DNA molecules containing base/base mismatches that mimick DNA lesions caused by hydrolytic deamination of 5-meC residues in Escherichia coli DNA (i.e. they carry a T/G mismatch in the special sequence context provided by the recognition site -CCA/TGG-of the Dcm-methyltransferase). Upon introduction of these heteroduplex DNAs into CaCl2-treated E. coli cells, the mismatches are efficiently repaired with high bias in favour of the DNA strand containing the mismatched guanine residue. This special DNA mismatch-repair operates on fully dam-methylated DNA and is independent of gene mutH. It thus fulfills the salient requirements of a repair pathway responsible for counteracting the spontaneous hydrolytic deamination of 5-meC in vivo. The repair efficiency is boosted by a 5-methyl group present on the cytosine residue at the next-nearest position to the 5' side of the mismatched guanine. The repair is severely impaired in host strains carrying a mutation in any of the three loci dcm, mutL and mutS.     

Analysis of a recessive plasmid copy number mutant: evidence for negative control of Col E1 replication.

The Col E1-derivative copy number mutant plasmid pOP1Δ6 has been used to investigate the control of plasmid replication. pOP1Δ6 normally exists at about 200 copies per chromosome, while the wild-type plasmid from which it was derived (pBGP120) exists at about 15 copies per chromosome. We have observed that in E. coli containing both pOP1Δ6 and pBGP120, the copy number of pOP1Δ6 is lowered to 4–6 copies per chromosome. Thus the mutation in pOP1Δ6 is recessive. The association between the two plasmids is stable in E. coli, indicating that incompatibility properties as well as replication control characteristics have been altered in pOP1Δ6. Co-residence of the unrelated plasmid pSC101 with pOP1Δ6 has no detectable effect on pOP1Δ6 copy number. These results suggest that a plasmid-specific, diffusible repressor may act negatively to control plasmid copy number, and that pOP1Δ6 produces a defective repressor or is altered in repressor synthesis. We have constructed in vitro a plasmid which is identical in size to pQP1Δ6 but contains a replication origin region derived from pBGP120. Since this plasmid, pNOP1, exists stably (like pBGP120) at 10–15 copies per chromosome, the high copy number of pOP1Δ6 is not related to its reduced size relative to pBGP120. To localize the mutation in pOP1Δ6 responsible for DNA overproduction, we have cloned fragments of pBGP120 into pOP1Δ6 and selected for plasmids with wild-type copy number. We find that a 2.0 kb region of pBGP120 DNA surrounding the origin of plasmid DNA replication is capable of suppressing the DNA overproducer phenotype of pOP1Δ6. The 2.0 kb fragment is capable of independent self-replication or can integrate into pOP1Δ6 in vivo to form a composite plasmid with two origins of replication. The overproducer phenotype of pOP1Δ6 is suppressed in either configuration.     

Cloning and characterization of mutL and mutS genes of Vibrio cholerae: nucleotide sequence of the mutL gene.

The mutL and mutS genes of Vibrio cholerae have been identified using interspecific complementation of Escherichia coli mutL and mutS mutants with plasmids containing the gene bank of V. cholerae. The recombinant plasmid pJT470, containing a 4.7 kb fragment of V. cholerae DNA codes for a protein of molecular weight 92,000. The product of this gene reduces the spontaneous mutation frequency of the E. coli mutS mutant. The plasmid, designated pJT250, containing a 2.5 kb DNA fragment of V. cholerae and coding for a protein of molecular weight 62,000, complements the mutL gene function of E. coli mutL mutants. These gene products are involved in the repair of mismatches in DNA. The complete nucleotide sequence of mutL gene of V. cholerae has been determined.     

Plasmid expression of mutS, -L and/or -H gene in Escherichia coli dam cells results in strains that display reduced mutation frequency

Escherichia colidam cells have an active but non-directed mismatch repair system; therefore, assembly of MutSLH complex at a mismatched base pair can result in MutH-mediated cleavage of GATC sites in both DNA strands. Unpaired double-strand breaks on a fraction of the replication errors occurring in dam cells presumably cause cell death, selectively eliminating these putative mutants from the population. We show that E. colidam cells transformed with plasmids containing either the mutS, mutL or mutH gene display a mutation frequency three to eight times lower than that of the parental dam strain, due to increased mismatch-stimulated cell killing. Transformed strains are also more susceptible to killing by the base analogue 2-aminopurine. However, dam and dam transformed cells have similar duplication time, proportion of live/dead cells and morphology.     

SOS mutator effect in E. coli mutants deficient in mismatch correction.

We have used bacteriophage lambda to characterize the mutator effect of the SOS response induced by u.v. irradiation of Escherichia coli. Mutagenesis of unirradiated phages grown in irradiated or unirradiated bacteria was detected by measuring forward mutagenesis in the immunity genes or reversion mutagenesis of an amber codon in the R gene. Relative to the wild-type, the SOS mutator effect was higher in E. coli mismatch correction-deficient mutants (mutH, mutL and mutS) and lower in an adenine methylation-deficient mutant ( dam3 ). We conclude that a large proportion of SOS-induced 'untargeted' mutations are removed by the methyl-directed mismatch correction system, which acts on newly synthesized DNA strands. The lower SOS mutator effect observed in E. coli dam mutants may be due to a selective killing of mismatch-bearing chromosomes resulting from undirected mismatch repair. The SOS mutator effect on undamaged lambda DNA, induced by u.v. irradiation of the host, appears to result from decreased fidelity of DNA synthesis.     

Structural/functional analysis of the human OXR1 protein: identification of exon 8 as the anti-oxidant encoding function

ABSTRACT: BACKGROUND: The human OXR1 gene belongs to a class of genes with conserved functions that protect cells from reactive oxygen species (ROS). The gene was found using a screen of a human cDNA library by its ability to suppress the spontaneous mutator phenotype of an E. coli mutH nth strain. The function of OXR1 is unknown. The human and yeast genes are induced by oxidative stress and targeted to the mitochondria; the yeast gene is required for resistance to hydrogen peroxide. Multiple spliced isoforms are expressed in a variety of human tissues, including brain. RESULTS: In this report, we use a papillation assay that measures spontaneous mutagenesis of an E. coli mutM mutY strain, a host defective for oxidative DNA repair. Papillation frequencies with this strain are dependent upon a G->T transversion in the lacZ gene (a mutation known to occur as a result of oxidative damage) and are suppressed by in vivo expression of human OXR1. N-terminal, C-terminal and internal deletions of the OXR1 gene were constructed and tested for suppression of the mutagenic phenotype of the mutM mutY strain. We find that the TLDc domain, encoded by the final four exons of the OXR1 gene, is not required for papillation suppression in E. coli. Instead, we show that the protein segment encoded by exon 8 of OXR1 is responsible for the suppression of oxidative damage in E. coli. CONCLUSION: The protein segment encoded by OXR1 exon 8 plays an important role in the anti-oxidative function of the human OXR1 protein. This result suggests that the TLDc domain, found in OXR1 exons 12-16 and common in many proteins with nuclear function, has an alternate (undefined) role other than oxidative repair.