The involvement of polynucleotide ligase in the repair of UV-induced DNA damage in Escherichia coli K-12 cells.

Summary The effect of the ligts-7 mutation on cell survival and the extent of DNA repair after UV (254 nm) irradiation was determined for wild-type and uvrB5 cells of E. coli K-12 at 30° and 42°C. At the restrictive temperature (42°C) the ligts-7 mutation resulted in (i) a decrease in the extent of repair of DNA incision breaks arising during the excision repair process, and (ii) a decrease in the extent of post-replicational repair of gaps in newly-synthesized DNA. These deficiencies in DNA repair correlated with increases in cellular sensitivity to killing by UV radiation. Thus, DNA ligase plays an important role in vivo in both the excision and post-replicational repair processes.     

The role of the Rdh54 protein in regulation of DNA repair in yeast <Emphasis Type="Italic">Saccharomyces cerevisiae</Emphasis>

This work provides evidence that the product of the RDH54 gene participates in the coordination of some repair pathways of DNA lesions. The unique point mutation rdh54–29 described in our previous works confers the phenotype markedly differing from that of the strain with a full deletion of gene RDH54. The epistatic type of interaction between mutations rdh 54–29 and apn 1Δ allowed the product of gene RDH54 to be attributed to the base excision repair pathway. However, a pleiotropic effect of mutation rdh54–29 manifested as sensitivity to a wide spectrum of DNA-damagi ng agents suggests that Rdh54 is involved in the regulation of several DNA repair pathways. To verify this hypothesis, the direct influence of mutation rdh54–29 on recombination and mutagenesis was evaluated. The results obtained led to the assumption that, in addition to the involvement in base excision repair, Rdh54p may play a certain role in the coordination of DNA lesion repair by various systems, including recombinational and mutagenic repair pathways or nucleotide excision repair. This function supposedly is mediated through modification of chromatin structure at the location of DNA lesion, in particular, by alleviation of DNA-hi stone bonds, thus rendering DNA more susceptible to the action of various repair proteins.     

The broth effect and mutation frequency decline in cells ofEscherichia coli after irradiation with UV-light

Dependence of the broth effeot and the phenomenon of mutation frequency decline on dose of the applied UV radiation was investigated in the strainEscherichia coli B/r Hcr+ thy trp. Reversions to Trp⁺ were followed. The degree of the broth effect and the mutation frequency decline is minimal within the range of UV doses corresponding to a survival of cells lower than 10-1. In connection with the two effects, excision of thymine dimers, initiation of synthesis, synthesis and degradation of DNA were also investigated. It was found that stimulation or inhibition of an inaccurate postreplication repair mechanism, rather than inhibition or stimulation of excision of thymine dimers, are responsible for the broth effect and the mutation frequency decline, respectively.     

Mutation spectrum following transfection of ultraviolet-irradiated single-stranded or double-stranded shuttle vector DNA into monkey cells

We designed a shuttle vector system that allowed a comparison of the mutation spectrum on the supF target gene after transfection of single-stranded or double-stranded DNA into monkey cells. Single-strand-derived plasmids exhibited a spontaneous mutation frequency tenfold higher than double-strand-derived ones. These spontaneous mutations comprised deletions and point substitutions. This system was applied to the study of ultraviolet-induced mutagenesis. Single-stranded DNA exhibited a lower survival and a higher mutation frequency than double-stranded DNA after identical ultraviolet-irradiation. The use of single-stranded DNA allowed us to confirm and complete the data about the targeting of ultraviolet-induced mutations and the exact nature of the base changes involved. One class of mutations was more frequent after transfection of ultraviolet-irradiated single-stranded DNA than for double-stranded DNA: frameshifts represented 10% of the mutants. Multiple mutations, attributed by some authors to an error-prone excision repair process, have also been observed in the spontaneous and ultraviolet-induced mutation spectra following single-stranded DNA transfection, although it cannot be a direct substrate for excision repair.     

Influence of physiological conditions on DNA repair and mutagenesis in higher plants

In barley ( Hordeum vulgare L.) and grass pea ( Lathyrus sativus L.), caffeine, an inhibitor of DNA repair activity, and Na₂ethylenediaminetetraacetate, an inhibitor of DNA-endonucleases, sharply decreased the excision repair of pyrimidine dimers induced in DNA by ultraviolet irradiation. An inhibitor of RNases, diethylpyro-carbonate, did not inhibit the process of excision, and in one experiment it even enhanced excision. Caffeine markedly increased the frequency of mutations and inhibited the growth of seedlings after UV-radiation. Such enhancement was greater with the higher UV fluence. Results of chemical inhibition were further confirmed by the suppression of repair by low temperatures: the frequency of chromatid aberrations induced with propyl methanesulfonate was increased more than 3 times and chromatid aberrations 1.5 times. Evidence for participation of repair enzymes in the modification of mutation processes was also obtained in the experiments which combined γ-irradiation and treatment with propyl methanesulfonate. Conditions favouring repair activity caused a drastic reduction in the frequency of aberrations, whereas with conditions preventing enzyme function the mutation frequency increased. In one of the experiments of this series we were able to demonstrate, with identical mutagenic treatment, that by changing post-mutagen conditions (wetting and drying of seeds, storage after mutagenic treatment) it was possible to alter the mutation frequency and to obtain below-additive, additive and synergistic mutational response.     

Epistatic analysis of the roles of the RAD27 and POL4 gene products in DNA base excision repair in S. cerevisiae

The cellular role of the DNA polymerase encoded by the Saccharomyces cerevisiae POL4 gene is unclear. We have used an epistasis analysis to investigate whether the proteins encoded by the POL4 and RAD27 genes participate in alternative, non-redundant subpathways of DNA base excision repair (BER). We constructed strains in which the genes were deleted singly or in combination and have examined their sensitivity to DNA damaging agents as well as spontaneous mutation frequency. The double deletion strain is no more sensitive to damaging agents and has no higher spontaneous mutation frequency than the most sensitive single mutant. These data indicate that the protein encoded by the POL4 gene does not participate in a non-redundant subpathway of base excision repair under these conditions. We discuss the implications of these results in light of the recent classification of the POL4 gene product as a member of the DNA polymerase lambda family.     

Inhibition of spontaneous mutagenesis by vanillin and cinnamaldehyde in Escherichia coli: Dependence on recombinational repair

Vanillin (VAN) and cinnamaldehyde (CIN) are dietary antimutagens that effectively inhibit both induced and spontaneous mutations. We have shown previously that VAN and CIN reduced the spontaneous mutant frequency in Salmonella TA104 (hisG428, rfa, ΔuvrB, pKM101) by approximately 50% and that both compounds significantly reduced mutations at GC sites but not at AT sites. Previous studies have suggested that VAN and CIN may reduce mutations in bacterial model systems by modulating DNA repair pathways, particularly by enhancing recombinational repair. To further explore the basis for inhibition of spontaneous mutation by VAN and CIN, we have determined the effects of these compounds on survival and mutant frequency in five Escherichia coli strains derived from the wild-type strain NR9102 with different DNA repair backgrounds. At nontoxic doses, both VAN and CIN significantly reduced mutant frequency in the wild-type strain NR9102, in the nucleotide excision repair-deficient strain NR11634 (uvrB), and in the recombination-proficient but SOS-deficient strain NR11475 (recA430). In contrast, in the recombination-deficient and SOS-deficient strain NR11317 (recA56), both VAN and CIN not only failed to inhibit the spontaneous mutant frequency but actually increased the mutant frequency. In the mismatch repair-defective strain NR9319 (mutL), only CIN was antimutagenic. Our results show that the antimutagenicity of VAN and CIN against spontaneous mutation required the RecA recombination function but was independent of the SOS and nucleotide excision repair pathways. Thus, we propose the counterintuitive notion that these antimutagens actually produce a type of DNA damage that elicits recombinational repair (but not mismatch, SOS, or nucleotide excision repair), which then repairs not only the damage induced by VAN and CIN but also other DNA damage—resulting in an antimutagenic effect on spontaneous mutation.     

Starvation as an inducer of error-free DNA repair in Escherichia coli

Previous work in this laboratory has shown that heat shock or vitamin B1 deprivation induces an error-free DNA-repair process in Escherichia coli. The system is absolutely dependent on excision repair, while its induction is delayed in lon- or recA- cells. We have now shown that starvation of E. coli for amino acids, glucose or phosphate, conditions known to induce the stringent response or the glu and pho regulons, respectively, leads to a similar uvrA-dependent increase in UV resistance and decrease in UV-induced mutation frequency. These results support the hypothesis that the effect is a general response to non-mutagenic stress that may play an important role in the survival of cells exposed to harsh environments.     

Trypanosomes lacking uracil-DNA glycosylase are hypersensitive to antifolates and present a mutator phenotype

Cells contain low amounts of uracil in DNA which can be the result of dUTP misincorporation during replication or cytosine deamination. Elimination of uracil in the base excision repair pathway yields an abasic site, which is potentially mutagenic unless repaired. The Trypanosoma brucei genome presents a single uracil-DNA glycosylase responsible for removal of uracil from DNA. Here we establish that no excision activity is detected on U:G, U:A pairs or single-strand uracil-containing DNA in uracil-DNA glycosylase null mutant cell extracts, indicating the absence of back-up uracil excision activities. While procyclic forms can survive with moderate amounts of uracil in DNA, an analysis of the mutation rate and spectra in mutant cells revealed a hypermutator phenotype where the predominant events were GC to AT transitions and insertions. Defective elimination of uracil via the base excision repair pathway gives rise to hypersensitivity to antifolates and oxidative stress and an increased number of DNA strand breaks, suggesting the activation of alternative DNA repair pathways. Finally, we show that uracil-DNA glycosylase defective cells exhibit reduced infectivity in vivo demonstrating that efficient uracil elimination is important for survival within the mammalian host.     

Mutagenicity of 7H-dibenzo[c,g]carbazole and its tissue specific derivatives in genetically engineered Chinese hamster V79 cell lines stably expressing cytochrome P450

The biological mechanisms responsible for aging remain poorly understood. We propose that increases in DNA damage and mutations that occur with age result from a reduced ability to repair DNA damage. To test this hypothesis, we have measured the ability to repair DNA damage in vitro by the base excision repair (BER) pathway in tissues of young (4-month-old) and old (24-month-old) C57BL/6 mice. We find in all tissues tested (brain, liver, spleen and testes), the ability to repair damage is significantly reduced (50-75%; P<0.01) with age, and that the reduction in repair capacity seen with age correlates with decreased levels of DNA polymerase beta (beta-pol) enzymatic activity, protein and mRNA. To determine the biological relevance of this age-related decline in BER, we measured spontaneous and chemically induced lacI mutation frequency in young and old animals. In line with previous findings, we observed a three-fold increase in spontaneous mutation frequency in aged animals. Interestingly, lacI mutation frequency in response to dimethyl sulfate (DMS) does not significantly increase in young animals whereas identical exposure in aged animals results in a five-fold increase in mutation frequency. Because DMS induces DNA damage processed by the BER pathway, it is suggested that the increased mutagenicity of DMS with age is related to the decline in BER capacity that occurs with age. The inability of the BER pathway to repair damages that accumulate with age may provide a mechanistic explanation for the well-established phenotype of DNA damage accumulation with age.     

A network of enzymes involved in repair of oxidative DNA damage in Neisseria meningitidis

Although oxidative stress is a key aspect of innate immunity, little is known about how host‐restricted pathogens successfully repair DNA damage. Base excision repair is responsible for correcting nucleobases damaged by oxidative stress, and is essential for bloodstream infection caused by the human pathogen, Neisseria meningitidis. We have characterized meningococcal base excision repair enzymes involved in the recognition and removal of damaged nucleobases, and incision of the DNA backbone. We demonstrate that the bi‐functional glycosylase/lyases Nth and MutM share several overlapping activities and functional redundancy. However, MutM and other members of the GO system, which deal with 8‐oxoG, a common lesion of oxidative damage, are not required for survival of N. meningitidis under oxidative stress. Instead, the mismatch repair pathway provides back‐up for the GO system, while the lyase activity of Nth can substitute for the meningococcal AP endonuclease, NApe. Our genetic and biochemical evidence shows that DNA repair is achieved through a robust network of enzymes that provides a flexible system of DNA repair. This network is likely to reflect successful adaptation to the human nasopharynx, and might provide a paradigm for DNA repair in other prokaryotes.     

Malondialdehyde,a product of lipid peroxidation,is mutagenic in human cells

Malondialdehyde (MDA) is an endogenous genotoxic product of enzymatic and oxygen radical-induced lipid peroxidation whose adducts are known to exist in DNA isolated from healthy human beings. To evaluate the mutagenic potential of MDA in human cells, we reacted MDA with pSP189 shuttle vector DNA and then transfected them into human fibroblasts for replication. MDA induced up to a 15-fold increase in mutation frequency in the supF reporter gene compared with untreated DNA. Sequence analysis revealed that the majority of MDA-induced mutations occurred at GC base pairs. The most frequent mutations were large insertions and deletions, but base pair substitutions were also detected. MDA-induced mutations were completely abolished when the adducted shuttle vector was replicated in cells lacking nucleotide excision repair. MDA induction of large deletions and the apparent requirement for nucleotide excision repair suggested the possible involvement of a DNA interstrand cross-link as a premutagenic lesion. Indeed, MDA formed interstrand cross-links in duplex plasmids and oligonucleotides. Substrates containing the sequence 5'-d(CG) were preferentially cross-linked, consistent with the observation of base pair substitutions in 5'-d(CG) sites in the MDA-induced mutation spectrum. These experiments provide biological and biochemical evidence for the existence of MDA-induced DNA interstrand cross-links that could result from endogenous oxidative stress and likely have potent biological effects.     

Reduction of background mutations by low-dose X irradiation of Drosophila spermatocytes at a low dose rate

A sex-linked recessive lethal mutation assay was performed in Drosophila melanogaster using immature spermatocytes and spermatogonia irradiated with X rays at a high or low dose rate. The mutation frequency in the sperm irradiated with a low dose at a low dose rate was significantly lower than that in the sham-irradiated group, whereas irradiation with a high dose resulted in a significant increase in the mutation frequency. It was obvious that the dose-response relationship was not linear, but rather was U-shaped. When mutant germ cells defective in DNA excision repair were used instead of wild-type cells, low-dose irradiation at a low dose rate did not reduce the mutation frequency. These observations suggest that error-free DNA repair functions were activated by low dose of low-dose-rate radiation and that this repaired spontaneous DNA damage rather than the X-ray-induced damage, thus producing a practical threshold.     

UV-sensitivity and repair of UV-damages in Salmonella of wild type.

Summary The UV-sensitivity of wild type Salmonella strains has been compared to that of wild type E. coli and its UV-sensitive mutants. Many wild type Salmonella strains are 4–5 times more sensitive than wild type E. coli and their inactivation curve is similar to that for E. coli with a mutation in the polA gene. Alkaline sucrose gradient centrifugation has shown a deficiency of these strains in normal excision repair of UV-damaged DNA. This deficiency is not a Salmonella genus feature because one strain as resistant as wild type E. coli was found. This resistant strain showed normal excision repair in alkaline sucrose gradient centrifugation experiments. The possible influence of plasmids and mutations in repair genes on the ability of Salmonella to repair UV-damaged DNA is discussed.     

The <Emphasis Type="Italic">Helicobacter pylori mutY</Emphasis> homologue HP0142 is an antimutator gene that prevents specific C to A transversions

Extensive genetic variability resulting from a high mutation rate and frequent recombination is a characteristic of Helicobacter pylori. Its average mutation rate is 1 × 10⁻⁶, similar to that of Escherichia coli mutator strains. Few genes involved in DNA repair have been functionally characterized in H. pylori. In E. coli, the DNA glycosylase MutY is a part of the base excision repair system. The H. pylori mutY homolog HP0142 was analyzed in this study. HP0142 was disrupted by inserting a kanamycin resistance cassette. Mutation rates were determined by measuring the frequency of point mutations in rpoB conferring resistance against rifampicin. Inactivation of mutY in H. pylori resulted in an increase of the mutation frequency by a factor of up to 34. Sequence analysis of rpoB in rifampicin-resistant clones selected from the mutY mutant showed a modest increase of G:C/T:A transversions in comparison to clones selected from wild type strains. In contrast, inactivation of mutY had a profound impact on the distribution of mutations within rpoB. This finding suggests that the efficiency with which mutY prevents transversions is strongly dependent upon the sequence context. Inactivation of mutY was associated with a stationary phase fitness deficit in competitive cultures with the wild type strain.     

Molecular characterization of mutations at the hprt locus in V79 Chinese hamster cells induced by bleomycin in the presence of inhibitors of DNA repair.

The molecular basis of bleomycin (BLM)-induced mutations in the absence and presence of inhibitors of DNA repair was investigated in V79 cells with Southern hybridization techniques. 43% of the BLM-induced thioguanine-resistant mutants suffer from large alterations of hprt DNA sequences. To understand the role of DNA repair in the process of mutagenesis, the effect of inhibitors of DNA repair on the frequency and types of BLM-induced mutations was tested. The inhibitors used were arabinofuranosyl cytosine (araC), didesoxythymidine (ddThd) and 3-aminobenzamide (3AB), which inhibit different steps of excision repair. Only 3AB caused a comutagenic effect. The increased mutation frequency was mainly due to additionally induced gene deletions. In the presence of 3AB, 70% of the HPRT-deficient mutants revealed partial or total deletions of the hprt coding sequences. Thus, it could be shown that BLM induces a broad range of types of mutation and that inhibited repair of BLM-induced DNA damage leads to specific types of mutations.     

Enhancement of excision-repair efficiency by conditioned medium from density-inhibited cultures in V79 Chinese hamster cells: Evidence for excision repair as an error-free repair process

Conditioned medium from density-inhibited V79 Chinese hamster cell cultures, given as a post-treatment to UV-irradiated homologous cells, was demonstrated to reduce the lethal action of ultraviolet light by temporarily blocking DNA replication. Since the increased survival was not affected by various nontoxic concentrations of caffeine, such protective effect would be attributable to the prolonged intervention of excision repair before DNA replication during the post-treatment period. The influence of conditioned medium on the UV-induced mutation at the ouabain-resistance locus was also examined and a significant decrease in mutation frequency was noted. The observed reduction in killing and mutation as a result of post-incubation in conditioned medium, which delays DNA replication, would be interpreted as evidence that conditioned medium provides a longer period of time for an error-free excision-repair process, leaving lesion in DNA available for error-prone post-replication repair.     

Mutational specificity and the influence of excision repair: insights into the mechanisms of error-avoidance and error-fixation

The excision repair process controlled by the uvrABC gene in Escherichia coli is the major pathway for the repair of a diverse series of DNA damages. To achieve a better understanding of the mechanics of this repair pathway and its impact upon mutagenesis, we have applied a recently developed technology by which the nature of mutation is determined at the DNA sequence level. A comparison of the classes and distribution of mutation in excision-repair-proficient and excision-repair-deficient strains of E. coli reveals that the absence of excision repair can alter both the nature of the mutations recovered as well as their distribution. This can occur in one of several ways. For example, under some circumstances the action of the UvrABC pathway can lead to interruptions of DNA strand continuity and an enhancement of both frameshift and deletion events. Such an effect is seen following damage by psoralen plus near UV (PUVA) treatment that produces crosslinks in the DNA. In comparison, several other treatments produce similar distributions within the classes of mutations recovered but demonstrate an alteration in site specificity. Such is the case following UV irradiation. In this case, the data indicate that while the premutagenic lesions may be the same, mutation fixation in the presence and absence of excision repair may involve different mechanisms. Similarly, evidence from the repair of damage by ethylating agents indicates that while the nature of the mutations recovered is not altered, the preferred location of these events is altered in the absence of excision repair. These results indicate that local DNA sequence can affect on the efficiency of excision repair.(ABSTRACT TRUNCATED AT 250 WORDS)     

Induction of the SOS response in <Emphasis Type="Italic">Escherichia coli</Emphasis> cells under osmotic stress and in the presence of N-methyl-N′-nitro-N-nitrosoguanidine

We investigated the dynamics of the SOS response induction and the frequency of reversions induced by the monofunctional alkylating compound N-methyl-N′-nitro-N-nitrosoguanidine in Escherichia coli cells exposed to osmotic stress for 1 h. During the stress treatment of the wild-type cultures adapted and not adapted to the alkylating agent, the maximum SOS response values and induced reversion frequencies were recorded twice. The SOS response values and induced reversion frequencies remained unchanged during the whole period after attaining the maximum values in adapted and nonadapted cells carrying a mutation in the excision repair gene. Presumably, the SOS mutagenesis mechanisms are turned on in the cells with an inactivated excision repair system earlier than in wild-type cells.