Role of damage-specific DNA polymerases in M13 phage mutagenesis induced by a major lipid peroxidation product trans-4-hydroxy-2-nonenal.

One of the major lipid peroxidation products trans-4-hydroxy-2-nonenal (HNE), forms cyclic propano- or ethenoadducts bearing six- or seven-carbon atom side chains to G>C≫A>T. To specify the role of SOS DNA polymerases in HNE-induced mutations, we tested survival and mutation spectra in the lacZα gene of M13mp18 phage, whose DNA was treated in vitro with HNE, and which was grown in uvrA(-)Escherichia coli strains, carrying one, two or all three SOS DNA polymerases. When Pol IV was the only DNA SOS polymerase in the bacterial host, survival of HNE-treated M13 DNA was similar to, but mutation frequency was lower than in the strain containing all SOS DNA polymerases. When only Pol II or Pol V were present in host bacteria, phage survival decreased dramatically. Simultaneously, mutation frequency was substantially increased, but exclusively in the strain carrying only Pol V, suggesting that induction of mutations by HNE is mainly dependent on Pol V. To determine the role of Pol II and Pol IV in HNE induced mutagenesis, Pol II or Pol IV were expressed together with Pol V. This resulted in decrease of mutation frequency, suggesting that both enzymes can compete with Pol V, and bypass HNE-DNA adducts in an error-free manner. However, HNE-DNA adducts were easily bypassed by Pol IV and only infrequently by Pol II. Mutation spectrum established for strains expressing only Pol V, showed that in uvrA(-) bacteria the frequency of base substitutions and recombination increased in relation to NER proficient strains, particularly mutations at adenine sites. Among base substitutions A:T→C:G, A:T→G:C, G:C→A:T and G:C→T:A prevailed. The results suggest that Pol V can infrequently bypass HNE-DNA adducts inducing mutations at G, C and A sites, while bypass by Pol IV and Pol II is error-free, but for Pol II infrequent.

Nucleotide excision repair and recombination are engaged in repair of trans-4-hydroxy-2-nonenal adducts to DNA bases in Escherichia coli.

One of the major products of lipid peroxidation is trans-4-hydroxy-2-nonenal (HNE). HNE forms highly mutagenic and genotoxic adducts to all DNA bases. Using M13 phage lacZ system, we studied the mutagenesis and repair of HNE treated phage DNA in E. coli wild-type or uvrA, recA, and mutL mutants. These studies revealed that: (i) nucleotide excision and recombination, but not mismatch repair, are engaged in repair of HNE adducts when present in phage DNA replicating in E. coli strains; (ii) in the single uvrA mutant, phage survival was drastically decreased while mutation frequency increased, and recombination events constituted 48% of all mutations; (iii) in the single recA mutant, the survival and mutation frequency of HNE-modified M13 phage was slightly elevated in comparison to that in the wild-type bacteria. The majority of mutations in recA(-) strain were G:C --> T:A transversions, occurring within the sequence which in recA(+) strains underwent RecA-mediated recombination, and the entire sequence was deleted; (iv) in the double uvrA recA mutant, phage survival was the same as in the wild-type although the mutation frequency was higher than in the wild-type and recA single mutant, but lower than in the single uvrA mutant. The majority of mutations found in the latter strain were base substitutions, with G:C --> A:T transitions prevailing. These transitions could have resulted from high reactivity of HNE with G and C, and induction of SOS-independent mutations.

Mutagenic potency of MMS-induced 1meA/3meC lesions in E. coli.

The mutagenic activity of MMS in E. coli depends on the susceptibility of DNA bases to methylation and their repair by cellular defense systems. Among the lesions in methylated DNA is 1meA/3meC, which is recently recognized as being mutagenic. In this report, special attention is focused on the mutagenic properties of 1meA/3meC which, by the activity of AlkB-dioxygenase, are quickly and efficiently converted to natural A/C bases in the DNA of E. coli alkB(+) strains, preventing 1meA/3meC-induced mutations. We have found that in the absence of AlkB-mediated repair, MMS treatment results in an increased frequency of four types of base substitutions: GC-->CG, GC-->TA, AT-->CG, and AT-->TA, whereas overproduction of PolV in CC101-106 alkB(-)/pRW134 strains leads to a markedly elevated level of GC-->TA, GC-->CG, and AT-->TA transversions. It has been observed that in the case of AB1157 alkB(-) strains, the MMS-induced and 1meA/3meC-dependent argE3-->Arg(+) reversion occurs efficiently, whereas lacZ(-)--> Lac(+) reversion in a set of CC101-106 alkB(-) strains occurs with much lower frequency. We considered several reasons for this discrepancy, namely, the possible variance in the level of the PolV activity, the effect of the PolIV contents that is higher in CC101-106 than in AB1157 strains and the different genetic cell backgrounds in CC101-106 alkB(-) and AB1157 alkB(-) strains, respectively. We postulate that the difference in the number of targets undergoing mutation and different reactivity of MMS with ssDNA and dsDNA are responsible for the high (argE3-->Arg(+)) and low (lacZ(-) --> Lac(+)) frequency of MMS-induced mutations.

Inducible SOS response system of DNA repair and mutagenesis in Escherichia coli.

Chromosomal DNA is exposed to continuous damage and repair. Cells contain a number of proteins and specific DNA repair systems that help maintain its correct structure. The SOS response was the first DNA repair system described in Escherichia coli induced upon treatment of bacteria with DNA damaging agents arrest DNA replication and cell division. Induction of the SOS response involves more than forty independent SOS genes, most of which encode proteins engaged in protection, repair, replication, mutagenesis and metabolism of DNA. Under normal growth conditions the SOS genes are expressed at a basal level, which increases distinctly upon induction of the SOS response. The SOS-response has been found in many bacterial species (e.g., Salmonella typhimurium, Caulobacter crescentus, Mycobacterium tuberculosis), but not in eukaryotic cells. However, species from all kingdoms contain some SOS-like proteins taking part in DNA repair that exhibit amino acid homology and enzymatic activities related to those found in E. coli. but are not organized in an SOS system. This paper presents a brief up-to-date review describing the discovery of the SOS system, the physiology of SOS induction, methods for its determination, and the role of some SOS-induced genes.

Mutator specificity of Escherichia coli alkB117 allele.

The Escherichia coli AlkB protein encoded by alkB gene was recently found to repair cytotoxic DNA lesions 1-methyladenine (1-meA) and 3-methylcytosine (3-meC) by using a novel iron-catalysed oxidative demethylation mechanism that protects the cell from the toxic effects of methylating agents. Mutation in alkB results in increased sensitivity to MMS and elevated level of MMS-induced mutations. The aim of this study was to analyse the mutational specificity of alkB117 in a system developed by J.H. Miller involving two sets of E. coli lacZ mutants, CC101-106 allowing the identification of base pair substitutions, and CC107-CC111 indicating frameshift mutations. Of the six possible base substitutions, the presence of alkB117 allele led to an increased level of GC-->AT transitions and GC-->TA and AT-->TA transversions. After MMS treatment the level of GC-->AT transitions increased the most, 22-fold. Among frameshift mutations, the most numerous were -2CG, -1G, and -1A deletions and +1G insertion. MMS treatment appreciably increased all of the above types of frameshifts, with additional appearance of the +1A insertion.

AlkB dioxygenase in preventing MMS-induced mutagenesis in Escherichia coli: effect of Pol V and AlkA proteins.

The deleterious effect of defective alkB allele encoding 1meA/3meC dioxygenase on reactivation of MMS-treated phage DNA has been frequently studied. Here, it is shown that: (i) AlkB protects the cells not only against the genotoxic but also against the potent mutagenic activity of MMS; (ii) mutations arising in alkB-defected strains are umuDC-dependent, and deletion of umuDC dramatically reduce MMS-induced mutations resulting from the presence of 1meA/3meC in DNA; (iii) specificity of MMS-induced argE3-->Arg+ reversions in AB1157 alkB-defective cells are predominantly AT-->TA transversions and GC-->AT transitions; (iv) overproduction of AlkA and the resultant decrease in 3meA residues in DNA dramatically reduce MMS-induced mutations. This reduction is most probably a secondary effect of AlkA due to a decrease in 3meA residues in DNA and, in consequence, suppression of SOS induction and Pol V expression. Overproduction of UmuD'C proteins reverses this effect.

[Chemically methylated DNA repair in Escherichia coli--the role of alkB protein]. / Naprawa chemicznie metylowanego DNA w escherichia coli-rola bialka Alkb.

Methylating agents belong to mutagens occurring most frequently in our environment. They methylate mainly the nitrogen bases in DNA and RNA, affecting their functions. In E. coli the alkylated bases are repaired by proteins and enzymes either permanently present in the cells (Ogt, Ada) or produced transiently (Ada, AlkB, AlkA, Aid), after induction of the Ada defence system. Alkylating agents induce also the SOS system, which enhances the synthesis of about 40 proteins, including those participating in recombination, replication and mutagenesis of DNA. All DNA interactions, modifications and repairs constitute an amazing and highly efficiently functioning cellular system. Among the repair proteins there are some which affect the alkylated bases in a non-conventional way, very rarely occurring in nature. Especially amazing is the mechanism of action of dioxogenase AlkB, which combines the repair of methyl-, ethyl- and etheno-base derivatives with oxidation and dissociation of the modified groups, leading to direct recovery of natural bases. This review attempts to elucidate the role of the individual proteins involved in the repair processes.

Mutator activity and specificity of Escherichia coli dnaQ49 allele--effect of umuDC products.

The high fidelity of DNA replication in Escherichia coli is ensured by the alpha (DnaE) and epsilon (DnaQ) subunits of DNA polymerase providing insertion fidelity, 3'-->5' exonuclease proofreading activity, and by the dam-directed mismatch repair system. dnaQ49 is a recessive allele that confers a temperature-sensitive proofreading phenotype resulting in a high rate of spontaneous mutations and chronic induction of the SOS response. The aim of this study was to analyse the mutational specificity of dnaQ49 in umuDC and DeltaumuDC backgrounds at 28 and 37 degrees C in a system developed by J.H. Miller. We confirmed that the mutator activity of dnaQ49 was negligible at 28 degrees C and fully expressed at 37 degrees C. Of the six possible base pair substitutions, only GC-->AT transitions and GC-->TA and AT-->TA transversions were appreciably increased. However, the most numerous mutations were frameshifts, -1G deletions and +1A insertions. All mutations which increased in response to dnaQ49 damage were to a various extent umuDC-dependent, especially -1G deletions. This type of mutations decreased in CC108dnaQ49DeltaumuDC to 10% of the value found in CC108dnaQ49umuDC+ and increased in the presence of plasmids producing UmuD'C or UmuDC proteins. In the recovery of dnaQ49 mutator activity the plasmid harbouring umuD'C genes was more effective than the one harbouring umuDC. Analysis of mutational specificity of pol III with defective epsilon subunit indicates that continuation of DNA replication is allowed past G:T, C:T, T:T (or C:A, G:A, A:A) mismatches but does not allow for acceptance of T:C, C:C, A:C (or A:G, G:G, T:G) (the underlined base is in the template strand).

Effect of deletion of SOS-induced polymerases, pol II, IV, and V, on spontaneous mutagenesis in Escherichia coli mutD5.

The E. coli dnaQ gene encodes the epsilon subunit of DNA polymerase III (pol III) responsible for the proofreading activity of this polymerase. The mutD5 mutant of dnaQ chronically expresses the SOS response and exhibits a mutator phenotype. In this study we have constructed a set of E. coli AB1157 mutD5 derivatives deleted in genes encoding SOS-induced DNA polymerases, pol II, pol IV, and pol V, and estimated the frequency and specificity of spontaneous argE3-->Arg(+) reversion in exponentially growing and stationary-phase cells of these strains. We found that pol II exerts a profound effect on the specificity of spontaneous mutation in exponentially growing cells. Analysis of growth-dependent Arg(+) revertants in mutD5 polB(+) strains revealed that Arg(+) revertants were due to tRNA suppressor formation, whereas those in mutD5 DeltapolB strains arose by back mutation at the argE3 ochre site. In stationary-phase bacteria, Arg(+)revertants arose mainly by back mutation, regardless of whether they were proficient or deficient in pol II. Our results also indicate that in a mutD5 background, the absence of pol II led to increased frequency of Arg(+) growth-dependent revertants, whereas the lack of pol V caused its dramatic decrease, especially in mutD5 DeltaumuDC and mutD5 DeltaumuDC DeltapolB strains. In contrast, the rate of stationary-phase Arg(+)revertants increased in the absence of pol IV in the mutD5 DeltadinB strain. We postulate that the proofreading activity of pol II excises DNA lesions in exponentially growing cells, whereas pol V and pol IV are more active in stationary-phase cultures.

E. coli BW535, a triple mutant for the DNA repair genes xth, nth, and nfo, chronically induces the SOS response.

A strong chronic induction of the SOS response system occurs in E. coli BW535, a strain defective in nth, nfo and xth genes, and hence severely deficient in the repair of abasic sites in DNA. This was shown here by visualization of filamentous growth of the BW535 strain and by measuring the level of beta-galactosidase expressed in BW535/pSK1002 in comparison to the AB1157/pSK1002 strain. The plasmid pSK1002 bears an umuC::lacZ fusion in which lacZ is under the control of the umuC promoter and regulated under the SOS regulon. Increases in the expression of beta-galactosidase occur in BW535 without any exogenous SOS inducer. Chronic induction of the SOS response was observed previously in E. coli strains bearing mutations in certain genes that have mutator activity and BW535 is a moderate mutator strain. However, not all mutators show this property, since chronic induction of SOS was not observed in mutT or mutY mutators. MutT and MutY proteins, when active, protect bacteria from mutations induced by 8-oxoG lesions in DNA. This suggests that accumulation of abasic sites, but not 8-oxoG residues in DNA, induce the SOS response.

Lethality of visible light for Escherichia coli hemH1 mutants influence of defects in DNA repair.

The hemH gene encodes ferrochelatase, the final enzyme of the heme biosynthetic pathway. Defects of this enzyme lead to accumulation of protoporphyrin IX and an increase in reactive oxygen species, causing susceptibility to blue and white light in bacteria and protoporphyria in humans. Here we show that the photosensitivity of hemH1 strains is much increased when the bacteria are devoid of ability to repair abasic sites. The sensitivity is increased 10- or 50-fold, in mutants bearing single xth or triple xth-nth-nfo mutations, respectively, but is not changed in mutants bearing nth, fpg, mutY, and mutT that are positive or negative for uvrA. This may indicate that in hemH1 mutants abasic sites are accumulated to a greater degree than oxidised bases, and/or that protoporphyrin, in the presence of abasic sites, increases the photosensitivity of hemH1 cells. It was shown in this work that the level of abasic sites (and/or strand breaks) in DNA of hemH1 strains increases greatly. Abasic sites and oxidative bases are potential mutagenic lesions. Nevertheless, the sensitivity of hemH1 bacteria to the lethal effect of visible light is not accompanied by increase in mutations. One of the possible explanations is that the genotoxic effect due to damage of hemH, shortage of heme and/or accumulating of protoporphyrin IX makes mutagenesis impossible.

Induction of the SOS response in starved Escherichia coli.

The SOS system in Escherichia coli is induced in response to DNA damage and the arrest of DNA synthesis. Here we show that in AB1157 bacteria starved for arginine, conditions for induction of adaptive mutations, the LexA-dependent SOS system is induced, but that this occurs only when the bacteria resume growth and when the source of carbon is glycerol rather than glucose (glycerol, but not glucose, enables synthesis of cAMP). Therefore, we conclude that starved cells accumulate some lesions in DNA, which in growth conditions may trigger SOS induction by a process that is cAMP-dependent.