Separation of the SOS-dependent and SOS-independent components of alkylating-agent mutagenesis.

Escherichia coli plasmids containing the rpsL+ gene (Strs phenotype) as the target for mutation were treated in vitro with N-methyl-N-nitrosourea. Following fixation of mutations in E. coli MM294A cells (recA+ Strs), an unselected population of mutant and wild-type plasmids was isolated and transferred into a second host, E. coli 6451 (recA Strr). Strains carrying plasmid-encoded forward mutations were then selected as Strr isolates, while rpsL+ plasmids conferred the dominant Strs phenotype in the second host. Mutation induction and reduced survival of N-methyl-N-nitrosourea-treated plasmids were shown to be dose dependent. Because this system permitted analysis and manipulation of the levels of certain methylated bases produced in vitro by N-methyl-N-nitrosourea, it afforded the opportunity to assess directly the relative roles of these bases and of SOS functions in mutagenesis. The methylated plasmid DNA gave a mutation frequency of 6 X 10(-5) (a 40-fold increase over background) in physiologically normal cells. When the same methylated plasmid was repaired in vitro by using purified O6-methylguanine DNA methyltransferase (to correct O6-methylguanine and O4-methylthymine), no mutations were detected above background levels. In contrast, when the methylated plasmid DNA was introduced into host cells induced by UV light for the SOS functions, rpsL mutagenesis was enhanced eightfold over the level seen without SOS induction. This enhancement of mutagenesis by SOS was unaffected by prior treatment of the DNA with O6-methylguanine DNA methyltransferase. These results demonstrate a predominant mutagenic role for alkylation lesions other than O6-methylguanine or O4-methylthymine when SOS functions are induced. The mutation spectrum of N-methyl-N-nitrosourea under conditions of induced SOS functions revealed a majority of mutagenic events at A . T base pairs.     

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.     

Pyrimidine dimers are not the principal pre-mutagenic lesions induced in lambda phage DNA by ultraviolet light

Experiments were performed to examine the role of cyclobutyl pyrimidine dimers in the process of mutagenesis by ultraviolet (u.v.) light. Lambda phage DNA was irradiated with u.v. and then incubated with an Escherichia coli photoreactivating enzyme, which monomerizes cyclobutyl pyrimidine dimers upon exposure to visible light. The photoreactivated DNA was packaged into lambda phage particles, which were used to infect E. coli uvr- host cells that had been induced for SOS functions by ultraviolet irradiation. Photoreactivation removed most toxic lesions from irradiated phage, but did not change the frequency of induction of mutations to the clear-plaque phenotype. This implies that cyclobutyl pyrimidine dimers can be lethal, but usually do not serve as sites of mutations in the phage. The DNA sequences of mutants derived from photoreactivated DNA showed that almost two-thirds (16/28) were transitions, the same fraction found for u.v. mutagenesis without photoreactivation. These results show that in this system, the lesion inducing transitions (the major type of u.v.-induced mutation) is not the cyclobutyl pyrimidine dimer; a strong candidate for a mutagenic lesion is the Pyr(6-4)Pyo photoproduct. On the other hand, photoreactivation of SOS-induced host cells before infection with u.v.-irradiated phage reduced mutagenesis substantially. In this case, photoreversal of cyclobutyl dimers serves to reduce expression of the SOS functions that are required in the process of targeted u.v. mutagenesis.     

Evidence for Escherichia coli polymerase II mutagenic bypass of intrastrand DNA crosslinks

The mutagenic potentials of DNAs containing site- and stereospecific intrastrand DNA crosslinks were evaluated in Escherichia coli cells that contained a full complement of DNA polymerases or were deficient in either polymerases II, IV, or V. Crosslinks were made between adjacent N(6)-N(6) adenines and consisted of R,R- and S,S-butadiene crosslinks and unfunctionalized 2-, 3-, and 4-carbon tethers. Although replication of single-stranded DNAs containing the unfunctionalized 3- and 4-carbon tethers were non-mutagenic in all strains tested, replication past all the other intrastrand crosslinks was mutagenic in all E. coli strains, except the one deficient in polymerase II in which no mutations were ever detected. However, when mutagenesis was analyzed in cells induced for SOS, mutations were not detected, suggesting a possible change in the overall fidelity of polymerase II under SOS conditions. These data suggest that DNA polymerase II is responsible for the in vivo mutagenic bypass of these lesions in wild-type E. coli.     

Duplication Mutation as an Sos Response in Escherichia Coli: Enhanced Duplication Formation by a Constitutively Activated Reca

The SOS response in Escherichia coli involves the induction of a multioperon regulatory system, which copes with the presence of DNA lesions that interfere with DNA replication. Induction depends on activation of the RecA protein to cleave the LexA repressor of SOS operons. In addition to inducible DNA repair, the SOS system produces a large increase in the frequency of point mutations. To examine the possibility that other types of mutations are induced as part of the SOS response, we have studied the production of tandem duplications. To avoid the complications of indirect effects of the DNA lesions, we have activated the SOS response by a constitutive mutation in the recA gene, recA730. The introduction of the recA730 mutation results in an increase in duplications in the range of tenfold or greater, as judged by two different criteria. Based on its genetic requirements, the pathway for induced duplication formation is distinct from the point mutation pathway and also differs from the major normal recombination pathway. The induction of pathways for both duplications and point mutations shows that the SOS system produces a broad mutagenic response. We have suggested previously that many types of mutations might be induced by severe environmental stress, thereby enhancing genetic variation in an endangered population.     

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.     

Non-targeted mutagenesis of unirradiated lambda phage in Escherichia coli host cells irradiated with ultraviolet light

Non-targeted mutagenesis of lambda phage by ultraviolet light is the increase over background mutagenesis when non-irradiated phage are grown in irradiated Escherichia coli host cells. Such mutagenesis is caused by different processes from targeted mutagenesis, in which mutations in irradiated phage are correlated with photoproducts in the phage DNA. Non-irradiated phage grown in heavily irradiated uvr+ host cells showed non-targeted mutations, which were 3/4 frameshifts, whereas targeted mutations were 2/3 transitions. For non-targeted mutagenesis in heavily irradiated host cells, there were one to two mutant phage per mutant burst. From this and the pathways of lambda DNA synthesis, it can be argued that non-targeted mutagenesis involves a loss of fidelity in semiconservative DNA replication. A series of experiments with various mutant host cells showed a major pathway of non-targeted mutagenesis by ultraviolet light, which acts in addition to "SOS induction" (where cleavage of the LexA repressor by RecA protease leads to din gene induction): (1) the induction of mutants has the same dependence on irradiation for wild-type and for umuC host cells; (2) a strain in which the SOS pathway is constitutively induced requires irradiation to the same level as wild-type cells in order to fully activate non-targeted mutagenesis; (3) non-targeted mutagenesis occurs to some extent in irradiated recA recB cells. In cells with very low levels of PolI, the induction of non-targeted mutagenesis by ultraviolet light is enhanced. We propose that the major pathway for non-targeted mutagenesis in irradiated host cells involves binding of the enzyme DNA polymerase I to damaged genomic DNA, and that the low polymerase activity leads to frameshift mutations during semiconservative DNA replication. The data suggest that this process will play a much smaller role in ultraviolet mutagenesis of the bacterial genome than it does in the mutagenesis of lambda phage.     

Induction of base substitution mutations by aflatoxin B1 is mucAB dependent in Escherichia coli.

Recovery of aflatoxin B1-induced base substitution mutations in Escherichia coli was almost completely dependent on the presence of the SOS-mutagenesis-enhancing operon mucAB+; the normal E. coli analog, umuDC+, was not sufficient. Yet aflatoxin B1 induced the SOS response, including the umuDC operon, as well as did UV light. Neither preinduction of the SOS response nor the presence of additional copies of umuDC+ allowed the recovery of aflatoxin B1-induced base substitutions. Thus, the premutagenic DNA lesions induced by aflatoxin B1 reveal a functional difference between UmuDC and MucAB. We estimate that in the presence of MucAB the probability that aflatoxin B1-induced DNA lesions will be converted into mutations is increased at least 10-fold.     

Biological properties of imidazole ring-opened N7-methylguanine in M13mp18 phage DNA.

Guanine residues methylated at the N-7 position (7-MeGua) are susceptible to cleavage of the imidazole ring yielding 2,6-diamino-4-hydroxy-5N-methyl-formamidopyrimidine (Fapy-7-MeGua). The presence of Fapy-7-MeGua in DNA template causes stops in DNA synthesis in vitro by E. coli DNA polymerase I. The biological consequences of Fapy-7-MeGua lesions for survival and mutagenesis were investigated using single-stranded M13mp18 phage DNA. Fapy-7-MeGua lesions were generated in vitro in phage DNA by dimethylsulfate (DMS) methylation and subsequent ring opening of 7-MeGua by treatment with NaOH (DMS-base). The presence of Fapy-7-MeGua residues in M13 phage DNA correlated with a significant decrease in transfection efficiency and an increase in mutation frequency in the lacZ gene, when transfected into SOS-induced JM105 E.coli cells. Sequencing analysis revealed unexpectedly, that mutation rate at guanine sites was only slightly increased, suggesting that Fapy-7-MeGua was not responsible for the overall increase in the mutagenic frequency of DMS-base treated DNA. In contrast, mutation frequency at adenine sites yielding A----G transitions was the most frequent event, 60-fold increased over DMS induced mutations. These results show that treatment with alkali of methylated single-stranded DNA generates a mutagenic adenine derivative, which mispairs with cytosine in SOS induced bacteria. The results also imply that the Fapy-7-MeGua in E. coli cells is primarily a lethal lesion.     

Reverse Southern hybridization.

A DNA oligomer 25 nucleotides long which contained an HMT (4'-hydroxymethyl-4,5', 8-trimethylpsoralen) furan side monoadduct to thymidine at a 5'-TpA-3' site was used as a probe for the polylinker sequence present in single-stranded M13 mp19 DNA and in double-stranded pUC 19 DNA. Hybridization and photofixation were carried out simultaneously in solution under conditions approximating the melting temperature of the probe-target hybrid. Use of probe concentrations greater than 10(-8) M permitted hybridization times of a few minutes. Irradiation with near ultraviolet light converted the HMT monoadduct present in hybrid complexes into an interstrand crosslink. Efficient photofixation removed hybrid from the equilibrium distribution and resulted in the formation of additional probe-target complex. After removal of excess probe by centrifugation through a semi-permeable membrane (Centricon-30), samples were electrophoresed through an alkaline agarose gel which was analyzed by autoradiography. When using an HMT-modified 25-mer probe end-labeled with 3,000 Ci/mmole 32P, 0.015 ng (3.8 X 10(6) copies) of M13 DNA could be detected. With this same probe 10 micrograms of denatured human DNA (corresponding to 3.0 X 10(6) copies) did not give a signal.     

Specificity and kinetics of interstrand and intrastrand bifunctional alkylation by nitrogen mustards at a G-G-C sequence.

Previous work showed that melphalan-induced mutations in the aprt gene of CHO cells are primarily transversions and occur preferentially at G-G-C sequences, which are potential sites for various bifunctional alkylations involving guanine N-7. To identify the DNA lesion(s) which may be responsible for these mutations, an end-labeled DNA duplex containing a frequent site of melphalan-induced mutation in the aprt gene was treated with melphalan, mechlorethamine or phosphoramide mustard. The sequence specificity and kinetics of formation of both interstrand and intrastrand crosslinks were determined. All mustards selectively formed two base-staggered interstrand crosslinks between the 5'G and the G opposite C in the 5'G-G-C sequence. Secondary alkylation was much slower for melphalan than for the other mustards and the resulting crosslink was more stable. Mechlorethamine and phosphoramide mustard induced intrastrand crosslinks between the two contiguous Gs in the G-G-C sequence in double-stranded DNA, but melphalan did not. Molecular dynamic simulations provided a structural explanation for this difference, in that the monofunctionally bound intermediates of mechlorethamine and phosphoramide mustard assumed thermodynamically stable conformations with the second arm in a position appropriate for intrastrand crosslink formation, while the corresponding melphalan monoadduct did not.     

Pairing properties of bromouracil and repair of bromouracil-containing DNA. Possible utilization of bromodeoxyuridine triphosphate for site-directed mutagenesis.

5-Bromo-2'-deoxyuridine triphosphate (Br-dUTP) and dTTP are used interchangeably for DNA synthesis in vitro by the Klenow fragment of Escherichia coli DNA polymerase I. When DNA containing Br-dUMP instead of dTMP at a few preselected sites is transfected into competent bacteria, no mutation occurs, indicating that in vivo E. coli DNA polymerase always places a dAMP residue in front of any unrepaired Br-dUMP residue. On the other hand, in vitro Br-dUTP can also replace dCTP, but only with difficulty: when dCTP is absent, Br-dUMP can be forced in front of a dGMP residue, but the Klenow polymerase pauses before and after addition of Br-dUMP. Transfection into E. coli of the substituted DNA leads to the expected G----A transitions. These mutations can easily be targeted by using a suitable primer and the correctly chosen mix of deoxynucleoside triphosphates containing Br-dUTP. When Br-dUMP has been placed in front of a dGMP residue, the mutation yield is not 100%, showing a partial repair of the transfected DNA before it is replicated. Advantage can be taken of this partial repair to prepare a set of different mutations within a target region in a single experiment.     

Survival and mutagenesis of bacteriophage T7 damaged by methyl methanesulfonate and ethyl methanesulfonate

We have examined survival and mutagenesis of bacteriophage T7 after exposure to the alkylating agents methyl methanesulfonate (MMS) and ethyl methanesulfonate (EMS). It was found that although both alkylating agents caused increased reversion of specific T7 mutations, EMS caused a higher frequency of reversion than did MMS. Exposure of the host cells to ultraviolet light so as to induce the SOS system resulted in increased survival (Weigle reactivation) of T7 phage damaged with either EMS or MMS. However, after SOS induction of the host we did not detect an accompanying increase in mutation frequency measured as either reversion of specific T7 mutants or by generation of mutations in the T7 gene that codes for phage ligase. Neither mutation frequency nor survival of alkylated phage was affected by the umuD,C mutation in the Escherichia coli host nor by the presence of plasmid pKM101. This may mean that the mode of Weigle reactivation that is detected in T7 is not mutagenic in nature.     

Site-specific methylases induce the SOS DNA repair response in Escherichia coli.

Expression of the site-specific adenine methylase HhaII (GmeANTC, where me is methyl) or PstI (CTGCmeAG) induced the SOS DNA repair response in Escherichia coli. In contrast, expression of methylases indigenous to E. coli either did not induce SOS (EcoRI [GAmeATTC] or induced SOS to a lesser extent (dam [GmeATC]). Recognition of adenine-methylated DNA required the product of a previously undescribed gene, which we named mrr (methylated adenine recognition and restriction). We suggest that mrr encodes an endonuclease that cleaves DNA containing N6-methyladenine and that DNA double-strand breaks induce the SOS response. Cytosine methylases foreign to E. coli (MspI [meCCGG], HaeIII [GGmeCC], BamHI [GGATmeCC], HhaI [GmeCGC], BsuRI [GGmeCC], and M.Spr) also induced SOS, whereas one indigenous to E. coli (EcoRII [CmeCA/TGG]) did not. SOS induction by cytosine methylation required the rglB locus, which encodes an endonuclease that cleaves DNA containing 5-hydroxymethyl- or 5-methylcytosine (E. A. Raleigh and G. Wilson, Proc. Natl. Acad. Sci. USA 83:9070-9074, 1986).     

Thermostability of double-stranded deoxyribonucleic acids: effects of covalent additions of a psoralen

We have carried out a thermodynamic study on the effects of covalent additions of the psoralen derivative HMT, 4'-(hydroxymethyl)-4,5',8-trimethylpsoralen, on the stability of double-stranded deoxyoligonucleotides. This was done with two systems. The first was a double-stranded DNA formed by two non-self-complementary oligonucleotides, 5'-GAAGCTACGAGC-3' and 5'-GCTCGTAGCTTC-3', where we site specifically placed an HMT molecule on the thymidine residue in oligonucleotide 5'-GAAGCTACGAGC-3' as either a furan-side monoadduct or a pyrone-side monoadduct. The second was a double-stranded DNA formed by a self-complementary oligonucleotide, 5'-GGGTACCC-3', where we placed an HMT molecule on the thymidine residue of each strand as a furan-side monoadduct or cross-linked the two strands with an HMT molecule linked to the two thymidines. We found that HMT cross-linking of the two strands stabilizes the double helix formed by 5'-GGGTACCC-3', as one might expect. Less predictable results were that the monoaddition of a psoralen stabilizes the double helix formed by the two non-self-complementary oligonucleotides by as much as 1.3 kcal/mol as a furan-side monoadduct and 0.7 kcal/mol as a pyrone-side monoadduct at 25 degrees C in 50 mM NaCl. In contrast, the monoaddition of a psoralen on each of the two thymidines in the double helix formed by 5'-GGGTACCC-3' destabilizes the helix by 1.8 kcal/mol at 25 degrees C in 1 M NaCl. This destabilization arises from an unfavorable enthalpy change (8.6 kcal/mol) and a favorable entropy change (23 cal/K X mol) due to the two HMT molecules at the centers of each strand.(ABSTRACT TRUNCATED AT 250 WORDS)     

Single-strand-specific exonucleases prevent frameshift mutagenesis by suppressing SOS induction and the action of DinB/DNA polymerase IV in growing cells

Escherichia coli strains carrying null alleles of genes encoding single-strand-specific exonucleases ExoI and ExoVII display elevated frameshift mutation rates but not base substitution mutation rates. We characterized increased spontaneous frameshift mutation in ExoI- ExoVII- cells and report that some of this effect requires RecA, an inducible SOS DNA damage response, and the low-fidelity, SOS-induced DNA polymerase DinB/PolIV, which makes frameshift mutations preferentially. We also find that SOS is induced in ExoI- ExoVII- cells. The data imply a role for the single-stranded exonucleases in guarding the genome against mutagenesis by removing excess single-stranded DNA that, if left, leads to SOS induction and PolIV-dependent mutagenesis. Previous results implicated PolIV in E. coli mutagenesis specifically during starvation or antibiotic stresses. Our data imply that PolIV can also promote mutation in growing cells under genome stress due to excess single-stranded DNA.     

Singlet oxygen-induced mutations in M13 lacZ phage DNA

The mutagenic consequences of damages to M13 mp19 RF DNA produced by singlet oxygen have been determined in a forward mutational system capable of detecting all classes of mutagenic events. When the damaged M13 mp19 RF DNA is used to transfect competent E. coli JM105 cells, a 16.6-fold increase in mutation frequency is observed at 5% survivors when measured as a loss of alpha-complementation. The enhanced mutagenicity is largely due to single-nucleotide substitutions, frameshift events and double-mutations. The single-nucleotide substitutions occur in the regulatory and in the structural part of the lacZ gene under the predominant form of a G:C to T:A transversion. The spectrum of mutations detected among the M13 lacZ phages surviving the singlet oxygen treatment is totally different from those appearing spontaneously. SOS induction mediated through u.v.-irradiation of bacteria leads to an increase of the mutation frequency in the M13 surviving to the singlet oxygen treatment. The mutation spectrum in this case is a mixture between those observed with the spontaneous mutants and the mutants induced by singlet oxygen. Lesions introduced in the M13 mp19 RF DNA can be partly repaired by the enzymatic machinery of the bacteria. It turns out that excision-repair and SOS repair are probably involved in the removal of these lesions by singlet oxygen.     

SOS-dependent replication past a single trans-syn T-T cyclobutane dimer gives a different mutation spectrum and increased error rate compared with replication past this lesion in uninduced cells.

We have transfected SOS-induced and uninduced cells of a uvrA6 strain of Escherichia coli with single-stranded M13mp7-based vectors that carried a single trans-syn T-T cyclobutane dimer at a unique site. Unlike constructs carrying the cis-syn isomer of this lesion, these vectors could be replicated with modest efficiency (14%) in the absence of SOS induction and therefore provided an opportunity to measure directly the influence of such induction on error rate and mutation spectrum. We found that translesion synthesis in the absence of SOS induction was remarkably accurate; only 4% of the replicated bacteriophage contained mutations, which were exclusively targeted single T deletions. In SOS-induced cells, error frequency increased to 11% and the resulting mutations included targeted substitutions and near-targeted single base additions, as well as the T deletions. Replication efficiency was 29% in these conditions. SOS induction therefore leads not only to an enhanced capacity to replicate damaged DNA but also to a marked change in mutation frequency and spectrum.     

Damaged-site independent mutagenesis of phage lambda produced by inducible error-prone repair

The existence of damaged-site independent mutagenesis is confirmed here by scoring the appearance of clear-plaque (c-) or virulent (vir) forward mutations on intact (non-irradiated) phage lambda grown on UV-irradiated E. coli K12 hosts. The mutation frequency was measured as a function of the incubation time between the occurrence of host DNA lesions and phage infection. The time course of mutagenesis of intact phage followed the induction pattern observed upon UV-reactivation of UV-damaged phage by Defais et al. (1976). Intact phage did not mutate in UV-irradiated hosts carrying the uvm-25 mutation known to prevent the occurrence of UV-reactivation. These findings suggest that damaged-site independent mutagenesis results from inducible error-prone repair. Clear-plaque mutations arising on intact phage were mostly found in phage bursts consisting of clear and turbid plaque formers whereas UV-damaged phage gave rise to mostly clear-plaque formers. Contrarily to damaged-site dependent mutagenesis, damaged-site independent mutagenesis can arise even at late times during the phage replication cycle. Our data indicate that about half of the phage mutations that arise upon UV-reactivation are damaged-site independent mutations. Replication of intact phage DNA in a host during induction of SOS functions provides a sensitive assay for the detection of damaged-site independent mutagenesis.