Relative rates of repair of single-strand breaks and postirradiation DNA degradation in normal and induced cells of Escherichia coli.

Labeled DNA from irradiated Excherichia coli cells has been studied on an alkaline sucrose gradient without acid precipitation of the DNA. This enables the observation of both DNA repair and DNA degradation. The use of a predose of ultraviolet light (UV) causes induction of an inhibitor of postirradiation DNA degradation in lex+ strains. The effect of this induction on both the repair of single-strand breaks and DNA degradation has been followed in strains WU3610 (uvr+) and WU3610-89 (uvr-). The repair process is more rapid than the degradation, and when degradation is inhibited more repair is apparent. Cells that are lex- (Bs-1 and AB2474) cannot be induced for inhibition of degradation. Nevertheless, by observation at short times repair can be seen clearly. This repaired DNA is degraded, suggesting that the signal for DNA degradation is not a single-strand break.     

Mutation frequency decline following chemical mutagenesis of Salmonella typhimurium

The occurrence is reported of a mutation frequency decline process (MFD) following treatment of Salmonella typhimurium strain trpC₃ with two chemical mutagens which give rise predominantly to suppressor revertants. With the carcinogen 4-nitroquinoline-N-oxide (4NQO) the results are analogous to those obtained for UV-mutagenesis. In the case of methoxynamine, the process is due to specific excision of premutational lesions, since lethality is low and lethal lesions are non-excisable. Mutants are described which cannot perform MFD of lesions induced by one or both of the chemical mutagens, indicating that the loss of revertants is in each case due to a bacteial repair system rather than to spontaneous degradation of the induced lesion. The mutants, however, were isolated because of an altered response to UV mutagenesis, viz., their ability to express UV-induced mutants in the absence of amino acids to stimulate active post-irradiation protein synthesis. In all other respects tested, their response to UV is identical with that of the parent strain. The hypothesis is discussed that the total absence of UV-induced revertants of the strain S. typhimurium trpC₃ when active protein synthesis is inhibited is due to two processes, first, rapid MFD due to the specific excision of pyrimidine dimers (the predominant UV-lesion) and secondly, the slow excision of other premutational damage which may be other photoproducts or secondary distortions caused by close juxtaposition of several pyrimidine dimers.     

Mutation frequency decline in Escherichia coli B/r after mutagenesis with ethyl methanesulfonate

Nonsense-defective auxotrophic strains of Escherichia coli B/r were used to study mutation frequency decline (MFD) after mutagenesis with ethyl methanesulfonate (EMS). The mutation frequencies for prototrophic revertants that were either converted or de novo glutamine tRNA suppressor mutations declined as treated auxotrophic parental cells were incubated with glucose but without required amino acids (a condition typically producing MFD). The decline for converted suppressor mutations was more rapid than the decline for de novo suppressor mutations after low or moderate EMS treatment, but both suppressor mutation types showed the same slow decline after extensive treatment. The declines for both types of suppressor mutation were eliminated in uvrA-defective cells, and the rapid decline seen for converted suppressor mutations appeared as a slow decline in mfd-defective cells. The results are interpreted that true MFD (the rapid process) affects only the EMS-induced converted glutamine tRNA suppressor mutations. This would account for the rapid decline that is blocked in cells with an mfd defect and in cells with deficient excision repair activity (uvrA or excessive DNA damage). In addition, a second non-specific antimutation mechanism is proposed that is dependent on excision repair only and accounts for the slow decline seen with converted suppressor mutations in some instances and with de novo suppressor mutations at all times. The true MFD mechanism may consist of a physiologically dependent facilitated excision repair specifically for premutational residues located in the transcribed strand of the target DNA sequence (for O6-ethylguanine in cells treated with ethyl methanesulfonate or pyrimidine-pyrimidine photoproducts after UV irradiation).     

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.     

GATC sequence and mismatch repair in Escherichia coli.

The Escherichia coli mismatch repair system greatly improves DNA replication fidelity by repairing single mispaired and unpaired bases in newly synthesized DNA strands. Transient undermethylation of the GATC sequences makes the newly synthesized strands susceptible to mismatch repair enzymes. The role of unmethylated GATC sequences in mismatch repair was tested in transfection experiments with heteroduplex DNA of phage phi 174 without any GATC sequence or with two GATC sequences, containing in addition either a G:T mismatch (Eam+/Eam3) or a G:A mismatch (Bam+/Bam16). It appears that only DNA containing GATC sequences is subject to efficient mismatch repair dependent on E. coli mutH, mutL, mutS and mutU genes; however, also in the absence of GATC sequence some mut-dependent mismatch repair can be observed. These observations suggest that the mismatch repair enzymes recognize both the mismatch and the unmethylated GATC sequence in DNA over long distances. The presence of GATC sequence(s) in the substrate appears to be required for full mismatch repair activity and not only for its strand specificity according to the GATC methylation state.     

Differential repair of premutational UV-lesions at tRNA genes in E. coli.

Summary Ultraviolet radiation produces bacterial revertants that frequently are the result of suppressor mutation. When irradiated cells are incubated under conditions unfavorable for protein synthesis there may be a large decrease in the frequency of observed mutants (mutation frequency decline, or MFD). MFD occurs only in excision-proficient strains and is inhibited by inhibitors of pyrimidine dimer excision. It has therefore been interpreted as enhanced excision of some premutational lesions. Potential de novo UAG suppressor mutation is very susceptible to MFD. Potential conversion mutation, the conversion of a UAG to a UAA suppressor, is at least ten times less susceptible to MFD. A base pair transition at a GC target in a particular tRNA gene is suggested for both de novo suppressor mutation and for conversion mutation. We interpret these results as indicating differential repair of premutational UV photoproducts at two closely spaced sites in the same tRNA gene. The significant difference between these two types of mutation may be the orientation of this target base pair in double helical DNA. The C would be in the transcribed strand of DNA when a nucleic acid alteration produces de novo suppressor mutation. The C would be in the nontranscribed strand, two base pairs removed, when a mutagenic alteration produces suppressor conversion. A model involving facilitated incision by hybridization of the transcribed strand of DNA to its cognate tRNA, under conditions promoting MFD, is described to explain this differential repair.     

Dimethyl Adenosine Transferase (KsgA) Deficiency in Salmonella enterica Serovar Enteritidis Confers Susceptibility to High Osmolarity and Virulence Attenuation in Chickens

Dimethyl adenosine transferase (KsgA) performs diverse roles in bacteria, including ribosomal maturation and DNA mismatch repair, and synthesis of KsgA is responsive to antibiotics and cold temperature. We previously showed that a ksgA mutation in Salmonella enterica serovar Enteritidis results in impaired invasiveness in human and avian epithelial cells. In this study, we tested the virulence of a ksgA mutant (the ksgA::Tn5 mutant) of S. Enteritidis in orally challenged 1-day-old chickens. The ksgA::Tn5 mutant showed significantly reduced intestinal colonization and organ invasiveness in chickens compared to those of the wild-type (WT) parent. Phenotype microarray (PM) was employed to compare the ksgA::Tn5 mutant and its isogenic wild-type strain for 920 phenotypes at 28°C, 37°C, and 42°C. At chicken body temperature (42°C), the ksgA::Tn5 mutant showed significantly reduced respiratory activity with respect to a number of carbon, nitrogen, phosphate, sulfur, and peptide nitrogen nutrients. The greatest differences were observed in the osmolyte panel at concentrations of ≥6% NaCl at 37°C and 42°C. In contrast, no major differences were observed at 28°C. In independent growth assays, the ksgA::Tn5 mutant displayed a severe growth defect in high-osmolarity (6.5% NaCl) conditions in nutrient-rich (LB) and nutrient-limiting (M9 minimum salts) media at 42°C. Moreover, the ksgA::Tn5 mutant showed significantly reduced tolerance to oxidative stress, but its survival within macrophages was not impaired. Unlike Escherichia coli, the ksgA::Tn5 mutant did not display a cold-sensitivity phenotype; however, it showed resistance to kasugamycin and increased susceptibility to chloramphenicol. To the best of our knowledge, this is the first report showing the role of ksgA in S. Enteritidis virulence in chickens, tolerance to high osmolarity, and altered susceptibility to kasugamycin and chloramphenicol.     

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.     

The isolation and characterisation of a mutant of Salmonella typhimurium defective in mutation frequency decline

A mutant of Salmonella typhimurium strain trpC3 has been isolated which is defective in mutation frequency decline (MFD) for UV-induced suppressor revertants to tryptophan independence. Several characteristics of this mutant, PW₄, suggest that it is altered in the timing or rate of the general excision repair mechanism. Survival is greater in strain PW₄ when the first post-irradiation cell division is delayed by the inhibition of immediate protein synthesis. Similarly, stationary phase cells, which show an extended lag after irradiation, are more UV-resistant than lag-phase cells, which recover more rapidly. These data are consistent with the hypothesis that, in contrast with the parent strain trpC₃, the time available in the mutant strain for the action of excision repair is critical in the determination of survival after UV treatment. Contransductional analysis of the mutant locus indicates close linkage to metE, a region in which excision repair genes have been located.     

The formation and annealing of structural defects in lipid bilayer vesicles

It is shown that sonication of phospholipid-water dispersions below the crystalline → liquid crystalline phase transition temperature (T_c) produces bilayer vesicles with structural defects within the bilayer membrane, which permit rapid permeation of ions and catalyze vesicle-vesicle fusion. These structural defects are annihilated simply by annealing the vesicle suspension above T_c. The rate of annealing was found to be slow, of the order of an hour for T = 3 °C above T_c, but annealing is complete within 10 min for T = 10 °C above T_c. It is proposed that these structural defects are fault-dislocations in the bilayer structure, which arise from a population defect in the distribution of the lipid molecules between the outer and inner monolayers, when small bilayer fragments reassemble to form the small bilayer vesicles during the sonication procedure. Such a population defect can only be remedied by lipid transport via the inside ? outside flip-flop mechanism, which would account for the slow kinetics of annealing observed even at 3 °C above the phase transition.     

The Tn5 bleomycin resistance gene confers improved survival and growth advantage on Escherichia coli

The bleomycin resistance gene (ble) of transposon Tn5 is known to decrease the death rate of Escherichia coli during stationary phase. Bleomycin is a DNA-damaging agent and bleomycin resistance is produced by improved DNA repair which also requires the host genes aidC and polA coding, respectively, for an alkylation-inducible gene product and DNA polymerase I. In the absence of the drug, this DNA repair system is believed to cause the slower death rate of bleomycin-resistant bacteria. In this study, the effect of ble and aidC genes on the viability of bacteria and their growth rate in chemostat competitions was studied. The results indicate, that bleomycin-resistant bacteria display greater fitness under these conditions. Another beneficial effect of transposon Tn5 had been previously attributed to the insertion sequence IS50R. We were not able to reproduce this result with IS50R, however, the complete transposon was beneficial under similar conditions. Moreover, we showed the Tn5 fitness effect to be aidC-dependent. The ble gene was discovered after the fitness effect of IS50R had been established; it has not previously been considered to mediate the beneficial effect of Tn5. This possibility is discussed based on the molecular mechanism of bleomycin resistance.     

Methyl-directed DNA mismatch repair in Escherichia coli

Some of the molecular aspects of methyl-directed mismatch repair in E. coli have been characterized. These include: mismatch recognition by mutS protein in which different mispairs are bound with different affinities; the direct involvement of d(GATC) sites; and strand scission by mutH protein at d(GATC) sequences with strand selection based on methylation of the DNA at those sites. In addition, communication over a distance between a mismatch and d(GATC) sites has been implicated. Analysis of mismatch correction in a defined system (Lahue et al., unpublished) should provide a direct means to further molecular aspects of this process.     

Methylation of GATC sites is required for precise timing between rounds of DNA replication in Escherichia coli.

We have used the Koppes and Nordstr?m (Cell 44:117-124, 1986) CsCl density transfer approach for analysis of DNA from exponentially growing, isogenic Escherichia coli dam+ and dam mutant cells to show that timing between DNA replication initiation events is precise in the dam+ cells but is essentially random in the dam cells. Thus, methylation of one or more GATC sites, such as those found in unusual abundance within the origin, oriC, is required for precise timing between rounds of DNA replication, and precise timing between initiation events is not required for cell viability. Both the dam-3 point mutant and the delta(dam)100 complete deletion mutant were examined. The results were independent of the mismatch repair system; E. coli mutH cells showed precise timing, whereas timing in the isogenic E. coli mutH delta(dam)100 double mutant was random. The mechanism is thus different from the role of Dam methylation in mismatch repair and probably involves conversion of hemimethylated GATC sites present in daughter origins just after initiation to a fully methylated state.