Replication fork collapse is a major cause of the high mutation frequency at three-base lesion clusters

Unresolved repair of clustered DNA lesions can lead to the formation of deleterious double strand breaks (DSB) or to mutation induction. Here, we investigated the outcome of clusters composed of base lesions for which base excision repair enzymes have different kinetics of excision/incision. We designed multiply damaged sites (MDS) composed of a rapidly excised uracil (U) and two oxidized bases, 5-hydroxyuracil (hU) and 8-oxoguanine (oG), excised more slowly. Plasmids harboring these U-oG/hU MDS-carrying duplexes were introduced into Escherichia coli cells either wild type or deficient for DNA n-glycosylases. Induction of DSB was estimated from plasmid survival and mutagenesis determined by sequencing of surviving clones. We show that a large majority of MDS is converted to DSB, whereas almost all surviving clones are mutated at hU. We demonstrate that mutagenesis at hU is correlated with excision of the U placed on the opposite strand. We propose that excision of U by Ung initiates the loss of U-oG-carrying strand, resulting in enhanced mutagenesis at the lesion present on the opposite strand. Our results highlight the importance of the kinetics of excision by base excision repair DNA n-glycosylases in the processing and fate of MDS and provide evidence for the role of strand loss/replication fork collapse during the processing of MDS on their mutational consequences.     

DNA N-glycosylase deficient mice: a tale of redundancy

The generation of mouse models of base excision repair deficiency has resulted in a re-examination of the cellular defence mechanisms that exist to counteract oxidative base damage. Contrary to exhibiting various detrimental effects of the gene disruption, the different strains of DNA-N-glycosylase deficient mice have proved to be remarkably resilient to the loss of the major activities that catalyse the removal of oxidised bases from DNA. Indeed, with a few exceptions, there is little evidence for the accumulation of oxidised bases in tissues and organs of the glycosylase knockout mice, even in older animals. This is highly suggestive of hitherto unknown backup mechanisms for dealing with the removal of oxidative base damage from genomic DNA. Results from both a genomics-based approach and biochemical analyses of cell free extracts from DNA glycosylase knockout mice have indicated that this is so and there is increasing evidence of several novel DNA glycosylase/AP lyases in mammalian cells that are capable of acting on oxidised bases in vitro. This, in parallel with other repair mechanisms involving mismatch repair, the Cockayne syndrome B protein and the efficient and accurate bypass of replication blocking lesions by a battery of translesion DNA polymerases, may explain the lack of severe phenotype observed for the DNA glycosylase deficient mice discussed in this article.     

Limited repair of 8-hydroxy-7,8-dihydroguanine residues in human testicular cells

Oxidative damage in testicular DNA is associated with poor semen quality, reduced fertility and increased risk of stillbirths and birth defects. These DNA lesions are predominantly removed by base excision repair. Cellular extracts from human and rat testicular cells and three enriched populations of rat male germ cells (primary spermatocytes, round spermatids and elongating/elongated spermatids) all showed proficient excision/incision of 5-hydroxycytosine, thymine glycol and 2,6-diamino-4-hydroxy-5-formamidopyrimidine. DNA containing 8-oxo-7,8-dihydroguanine was excised poorly by human testicular cell extracts, although 8-oxoguanine-DNA glycosylase-1 (hOGG1) was present in human testicular cells, at levels that varied markedly between 13 individuals. This excision was as low as with human mononuclear blood cell extracts. The level of endonuclease III homologue-1 (NTH1), which excises oxidised pyrimidines, was higher in testicular than in somatic cells of both species. Cellular repair studies of lesions recognised by formamidopyrimidine-DNA glycosylase (Fpg) or endonuclease III (Nth) were assayed with alkaline elution and the Comet assay. Consistent with the enzymatic activities, human testicular cells showed poor removal of Fpg-sensitive lesions but efficient repair of Nth-sensitive lesions. Rat testicular cells efficiently repaired both Fpg- and Nth-sensitive lesions. In conclusion, human testicular cells have limited capacity to repair important oxidative DNA lesions, which could lead to impaired reproduction and de novo mutations.     

DNA repair in Mycobacterium tuberculosis. What have we learnt from the genome sequence?

The genome sequence of Mycobacterium tuberculosis was analysed by searching for homologues of genes known to be involved in the reversal or repair of DNA damage in Escherichia coli and related organisms. Genes necessary to perform nucleotide excision repair (NER), base excision repair (BER), recombination, and SOS repair and mutagenesis were identified. In particular, all of the genes known to be directly involved in the repair of oxidative and alkylative damage are present in M. tuberculosis . In contrast, we failed to identify homologues of genes involved in mismatch repair. This finding has potentially significant implications with respect to genome stability, strain variability at repeat loci and the emergence of chromosomally encoded drug resistance mutations.     

Oxidative damage to purines in DNA: role of mammalian Ogg1

DNA damage caused by reactive oxygen species is ubiquitous to all living organisms. More than 60 different base lesions have been identified, and the majority of these are removed via the base excision repair pathway. This pathway appears to represent a highly conserved and ancient mechanism of defence counteracting spontaneous DNA decay. In this review, we describe in more detail the Ogg1 enzyme and its conserved action of removing the oxidised base, 7,8-dihydro-8-oxoguanine (oxo(8)G). Recent updates include the cancer-prone ogg1/myh double knockout mouse and an elegant study which looks at the ability of hOgg1 to distinguish between the mutagenic lesion, oxo(8)G, and the vast majority of normal bases.     

Base excision repair sensitizes cells to sulfur mustard and chloroethyl ethyl sulfide

DNA repair generally functions to improve survival and reduce mutagenesis of cells that have suffered DNA damage. In this study we examine the role of nucleotide excision repair (NER) and base excision repair (BER) in recovery, mutagenesis and DNA repair in response to DNA damage inflicted by the mustard compounds, sulfur mustard (SM) and chloroethyl ethyl sulfide (CEES) in bacteria and mammalian cells. SM and CEES are compared because SM produces cross-links and monoadducts, whereas CEES produces only monoadducts that are similar to those produced by SM, thus allowing the examination of which types of lesions may be responsible for the effects seen. We find that the presence of a functional NER pathway increases survival and reduces mutagenesis, whereas the presence of a functional BER pathway reduces survival, increases mutagenesis, and decreases repair. The deleterious effects of BER appear to be due to an interaction between the DNA glycosylases and the lesions produced by SM and CEES. Possible mechanisms for BER-mediated sensitization by glycosylase action on mustard lesions are discussed.     

DNA Sequence Analysis of Mutagenicity and Site Specificity of Ethyl Methanesulfonate in Uvr+ and UvrB - Strains of ESCHERICHIA COLI

EMS-induced mutations within a 180 base pair region of the lacI gene of E. coli were cloned and sequenced. In total, 105 and 79 EMS-induced mutations from a Uvr+ and a UvrB- strain, respectively, were sequenced. The specificity of EMS-induced mutagenesis was very similar in the two strains; G:C----A:T transitions accounted for all but three of the mutants. The overall frequency of induced mutation was fivefold higher in the UvrB- strain compared to the Uvr+ strain. This demonstrates, at the DNA sequence level, that the presumed premutagenic lesion, O6-ethylguanine, is subject to repair by the uvrABC excision repair system of E. coli. An analysis of mutation frequencies with respect to neighboring base sequence, in the two strains, shows that O6-ethylguanine lesions adjacent to A:T base pairs present better targets for the excision repair machinery than those not adjacent to A:T base pairs.     

CHIP-mediated degradation and DNA damage-dependent stabilization regulate base excision repair proteins

Base excision repair (BER) is the major pathway for processing of simple lesions in DNA, including single-strand breaks, base damage, and base loss. The scaffold protein XRCC1, DNA polymerase beta, and DNA ligase IIIalpha play pivotal roles in BER. Although all these enzymes are essential for development, their cellular levels must be tightly regulated because increased amounts of BER enzymes lead to elevated mutagenesis and genetic instability and are frequently found in cancer cells. Here we report that BER enzyme levels are linked to and controlled by the level of DNA lesions. We demonstrate that stability of BER enzymes increases after formation of a repair complex on damaged DNA and that proteins not involved in a repair complex are ubiquitylated by the E3 ubiquitin ligase CHIP and subsequently rapidly degraded. These data identify a molecular mechanism controlling cellular levels of BER enzymes and correspondingly the efficiency and capacity of BER.     

Measurement of DNA base and nucleotide excision repair activities in mammalian cells and tissues using the comet assay – A methodological overview

There is an increasing demand for phenotyping assays in the field of human functional genetics. DNA repair activity is representative of this functional approach, being seen as a valuable biomarker related to cancer risk. Repair activity is evaluated by incubating a cell extract with a DNA substrate containing lesions specific for the DNA repair pathway of interest. Enzymic incision at the lesion sites can be measured by means of the comet assay (single cell gel electrophoresis). The assay is particularly applicable for evaluation of base and nucleotide excision repair pathways (BER and NER). Substrate DNA containing oxidised purines gives a measure of BER, while UV-induced photolesions are the substrate for NER. While applications of comet-based DNA repair assays continue to increase, there are no commonly accepted standard protocols, which complicates inter-laboratory comparisons of results.     

DNA Damage and Repair in Eukaryotic Cells

DAMAGE IN DNA AFTER IRRADIATION CAN BE CLASSIFIED INTO FIVE KINDS: base damage, single-strand breaks, double-strand breaks, DNA-DNA cross-linking, and DNA-protein cross-linking. Of these, repair of base damage is the best understood. In eukaryotes, at least three repair systems are known that can deal with base damage: photoreactivation, excision repair, and post-replication repair. Photoreactivation is specific for UV-induced damage and occurs widely throughout the biosphere, although it seems to be absent from placental mammals. Excision repair is present in prokaryotes and in animals but does not seem to be present in plants. Post-replication repair is poorly understood. Recent reports indicate that growing points in mammalian DNA simply skip past UV-induced lesions, leaving gaps in newly made DNA that are subsequently filled in by de novo synthesis. Evidence that this concept is oversimplified or incorrect is presented.-Single-strand breaks are induced by ionizing radiation but most cells can rapidly repair most or all of them, even after supralethal doses. The chemistry of the fragments formed when breaks are induced by ionizing radiation is complex and poorly understood. Therefore, the intermediate steps in the repair of single-strand breaks are unknown. Double-strand breaks and the two kinds of cross-linking have been studied very little and almost nothing is known about their mechanisms for repair.-The role of mammalian DNA repair in mutations is not known. Although there is evidence that defective repair can lead to cancer and/or premature aging in humans, the relationship between the molecular defects and the diseased state remains obscure.     

The structure of the human AGT protein bound to DNA and its implications for damage detection

O6-Alklyguanine-DNA alkyltransferase (AGT) is an important DNA repair protein that protects cells from mutagenesis and toxicity arising from alkylating agents. We present an X-ray crystal structure of the wild-type human protein (hAGT) bound to double-stranded DNA with a chemically modified cytosine base. The protein binds at two different sites: one at the modified base, and the other across a sticky-ended DNA junction. The protein molecule that binds the modified cytosine base flips the base and recognizes it in its active site. The one that binds ends of neighboring DNA molecules partially flips an overhanging thymine base. This base is not inserted into the active-site pocket of the protein. These two different hAGT/DNA interactions observed in the structure suggest that hAGT may not detect DNA lesions by searching for the adduct itself, but rather for weakened and/or distorted base-pairs caused by base damage in the duplex DNA. We propose that hAGT imposes a strain on the DNA duplex and searches for DNA regions where the native structure is destabilized. The structure provides implications for pyrimidine recognition, improved inhibitor design, and a possible protein/protein interaction patch on hAGT.     

Repair of products of oxidative DNA base damage in human cells.

Oxidative DNA damage is the most frequent type of damage encountered by aerobic cells and may play an important role in biological processes such as mutagenesis, carcinogenesis and aging in humans. Oxidative damage generates a myriad of modifications in DNA. We investigated the cellular repair of DNA base damage products in DNA of cultured human lymphoblast cells, which were exposed to oxidative stress by H2O2. This DNA-damaging agent is known to cause base modifications in genomic DNA of mammalian cells [Dizdaroglu, M., Nackerdien, Z., Chao, B.-C., Gajewski, E. and Rao, G. (1991) Arch. Biochem. Biophys. 285, 388-390]. Following treatment with H2O2, the culture medium was freed from H2O2 and cells were incubated for time periods ranging from 10 min to 6 h. DNA was isolated from control cells, hydrogen peroxide-treated cells and cells incubated after H2O2 exposure. DNA samples were analyzed by gas chromatography/isotope-dilution mass spectrometry. Eleven modified bases were identified and quantified. The results showed a significant formation of these DNA base products upon H2O2-treatment of cells. Subsequent incubation of cells caused a time-dependent excision of these products from cellular DNA. The cell viability did not change significantly by various treatments. There were distinct differences between the kinetics of excision of individual products. The observed excisions were attributed to DNA repair in cells. The rate of repair of purine lesions was slower than that of pyrimidine lesions. Most of the identified products are known to possess various premutagenic properties. The results of this work may contribute to the understanding of the cellular repair of oxidative DNA damage in human and other mammalian cells.     

Replication of Damaged DNA and the Molecular Mechanism of Ultraviolet Light Mutagenesis

Abstract

On UV irradiation of Escherichia coli cells, DNA replication is transiently arrested to allow removal of DNA damage by DNA repair mechanisms. This is followed by a resumption of DNA replication, a major recovery function whose mechanism is poorly understood. During the post-UV irradiation period the SOS stress response is induced, giving rise to a multiplicity of phenomena, including UV mutagenesis. The prevailing model is that UV mutagenesis occurs by the filling in of single-stranded DNA gaps present opposite UV lesions in the irradiated chromosome. These gaps can be formed by the activity of DNA replication or repair on the damaged DNA. The gap filling involves polymerization through UV lesions (also termed bypass synthesis or error-prone repair) by DNA polymerase III. The primary source of mutations is the incorporation of incorrect nucleotides opposite lesions. UV mutagenesis is a genetically regulated process, and it requires the SOS-inducible proteins RecA, UmuD, and UmuC. It may represent a minor repair pathway or a genetic program to accelerate evolution of cells under environmental stress conditions.     

The effect of oxidative metabolism on spontaneous Pol zeta-dependent translesion synthesis in Saccharomyces cerevisiae

DNA lesions can stall or block high-fidelity polymerases, thus inhibiting replication. To bypass such lesions, low-fidelity translesion synthesis (TLS) polymerases can be used to insert a nucleotide across from the lesion or extend from a lesion:base mispair. When DNA repair is compromised in Saccharomyces cerevisiae, spontaneous DNA lesions can lead to a novel mutational event in which a frameshift is accompanied by one or more base pair substitutions. These "complex frameshifts" are dependent upon the TLS polymerase Pol zeta, and provide a mutational signature for mutagenic Pol zeta-dependent activity. In the current study, we have found that a specific subset of the Pol zeta-dependent mutational events requires oxidative metabolism. These results suggest that translesion bypass of spontaneously oxidized DNA bases can be a significant source of mutagenesis in repair compromised cells.     

Structure and Dynamics of DNA Duplexes Containing a Cluster of Mutagenic 8-Oxoguanine and Abasic Site Lesions

Clustered DNA damage sites are caused by ionizing radiation. They are much more difficult to repair than are isolated single lesions, and their biological outcomes in terms of mutagenesis and repair inhibition are strongly dependent on the type, relative position and orientation of the lesions present in the cluster. To determine whether these effects on repair mechanism could be due to local structural properties within DNA, we used ¹H NMR spectroscopy and restrained molecular dynamics simulation to elucidate the structures of three DNA duplexes containing bistranded clusters of lesions. Each DNA sequence contained an abasic site in the middle of one strand and differed by the relative position of the 8-oxoguanine, staggered on either the 3′ or the 5′ side of the complementary strand. Their repair by base excision repair protein Fpg was either complete or inhibited. All the studied damaged DNA duplexes adopt an overall B-form conformation and the damaged residues remain intrahelical. No striking deformations of the DNA chain have been observed as a result of close proximity of the lesions. These results rule out the possibility that differential recognition of clustered DNA lesions by the Fpg protein could be due to changes in the DNA's structural features induced by those lesions and provide new insight into the Fpg recognition process.     

Genomic approaches to DNA repair and mutagenesis

DNA damage is a constant threat to cells, causing cytotoxicity as well as inducing genetic alterations. The steady-state abundance of DNA lesions in a cell is minimized by a variety of DNA repair mechanisms, including DNA strand break repair, mismatch repair, nucleotide excision repair, base excision repair, and ribonucleotide excision repair. The efficiencies and mechanisms by which these pathways remove damage from chromosomes have been primarily characterized by investigating the processing of lesions at defined genomic loci, among bulk genomic DNA, on episomal DNA constructs, or using in vitro substrates. However, the structure of a chromosome is heterogeneous, consisting of heavily protein-bound heterochromatic regions, open regulatory regions, actively transcribed genes, and even areas of transient single stranded DNA. Consequently, DNA repair pathways function in a much more diverse set of chromosomal contexts than can be readily assessed using previous methods. Recent efforts to develop whole genome maps of DNA damage, repair processes, and even mutations promise to greatly expand our understanding of DNA repair and mutagenesis. Here we review the current efforts to utilize whole genome maps of DNA damage and mutation to understand how different chromosomal contexts affect DNA excision repair pathways.     

HU protein of Escherichia coli has a role in the repair of closely opposed lesions in DNA

Closely opposed lesions form a unique class of DNA damage that is generated by ionizing radiation. Improper repair of closely opposed lesions could lead to the formation of double strand breaks that can result in increased lethality and mutagenesis. In vitro processing of closely opposed lesions was studied using double-stranded DNA containing a nick in close proximity opposite to a dihydrouracil. In this study we showed that HU protein, an Escherichia coli DNA-binding protein, has a role in the repair of closely opposed lesions. The repair of dihydrouracil is initiated by E. coli endonuclease III and processed via the base excision repair pathway. HU protein was shown to inhibit the rate of removal of dihydrouracil by endonuclease III only when the DNA substrate contained a nick in close proximity opposite to the dihydrouracil. In contrast, HU protein did not inhibit the subsequent steps of the base excision repair pathway, namely the DNA synthesis and ligation reactions catalyzed by E. coli DNA polymerase and E. coli DNA ligase, respectively. The nick-dependent selective inhibition of endonuclease III activity by HU protein suggests that HU could play a role in reducing the formation of double strand breaks in E. coli.     

Silent repair accounts for cell cycle specificity in the signaling of oxidative DNA lesions

Reactive oxygen species are the most important source of DNA lesions in aerobic organisms, but little is known about the activation of the DNA checkpoints in response to oxidative stress. We show that treatment of yeast cells with sublethal concentrations of hydrogen peroxide induces a Mec1-dependent phosphorylation of Rad53 and a Rad53-dependent cell cycle delay specifically during S phase. The lack of Rad53 phosphorylation after hydrogen peroxide treatment in the G1 and G2 phases is due to the silent repair of oxidative DNA lesions produced at these stages by the base excision repair (BER) pathway. Only the disruption of the BER pathway and the accumulation and/or treatment of DNA intermediates by alternative repair pathways reveal the existence of primary DNA lesions induced at all phases of the cell cycle by hydrogen peroxide. Our data illustrate both the concept of silent repair of DNA damage and the high sensitivity of S-phase cells to hydrogen peroxide.     

Purine 5′,8-cyclo-2′-deoxynucleoside lesions: formation by radical stress and repair in human breast epithelial cancer cells

5′,8-Cyclo-2′-deoxyadenosine (cdA) and 5′,8-cyclo-2′-deoxyguanosine (cdG) in their two diastereomeric forms, 5′S and 5′R, are tandem lesions produced by the attack of hydroxyl radicals to the purine moieties of DNA. Their formation has been found to challenge the cells’ repair machinery, initiating the nucleotide excision repair (NER) for restoring the genome integrity. The involvement of oxidatively induced DNA damage in carcinogenesis and the reduced capacity of some cancer cell lines to repair oxidised DNA base lesions, intrigued us to investigate the implication of these lesions in breast cancer, the most frequently occurring cancer in women. Using liquid chromatography tandem mass spectrometry (LC-MS/MS), we measured the levels of diastereomeric cdA’s and cdG’s in estrogen receptor-alpha positive (ER-α) MCF-7 and triple negative MDA-MB-231 breast cancer cell lines before and after exposure to two different conditions: ionising radiations and hydrogen peroxide, followed by an interval period to allow DNA repair. An increase at the measured levels of all four lesions, i.e. 5′S-cdA, 5′R-cdA, 5′S-cdG and 5′R-cdG, was observed either after γ-irradiation (5?Gy dose) or hydrogen peroxide treatment (300?μM) compared to the untreated cells (control), independently from the length of the interval period for repair. For comparison reasons, we also measured the levels of 8-oxo-2′-deoxyadenosine (8-oxo-dA), a well-known oxidatively induced DNA damage lesion and base excision repair (BER) substrate. The collected data indicate that MCF-7 and MDA-MB-231 breast cancer cells are highly susceptible to radiation-induced DNA damage, being mainly defective in the repair of these lesions.     

Deletion of the MAG1 DNA glycosylase gene suppresses alkylation-induced killing and mutagenesis in yeast cells lacking AP endonucleases.

DNA base excision repair (BER) is initiated by DNA glycosylases that recognize and remove damaged bases. The phosphate backbone adjacent to the resulting apurinic/apyrimidinic (AP) site is then cleaved by an AP endonuclease or glycosylase-associated AP lyase to invoke subsequent BER steps. We have used a genetic approach in Saccharomyces cerevisiae to address whether AP sites are blocks to DNA replication and the biological consequences if AP sites persist in the genome. We found that yeast cells deficient in the two AP endonucleases (apn1 apn2 double mutant) are extremely sensitive to killing by methyl methanesulfonate (MMS), a model DNA alkylating agent. Interestingly, this sensitivity can be reduced up to 2500-fold by deleting the MAG1 3-methyladenine DNA glycosylase gene, suggesting that Mag1 not only removes lethal base lesions, but also benign lesions and possibly normal bases, and that the resulting AP sites are highly toxic to the cells. This rescuing effect appears to be specific for DNA alkylation damage, since the mag1 mutation reduces killing effects of two other DNA alkylating agents, but does not alter the sensitivity of apn cells to killing by UV, gamma-ray or H(2)O(2). Our mutagenesis assays indicate that nearly half of spontaneous and almost all MMS-induced mutations in the AP endonuclease-deficient cells are due to Mag1 DNA glycosylase activity. Although the DNA replication apparatus appears to be incapable of replicating past AP sites, Polzeta-mediated translesion synthesis is able to bypass AP sites, and accounts for all spontaneous and MMS-induced mutagenesis in the AP endonuclease-deficient cells. These results allow us to delineate base lesion flow within the BER pathway and link AP sites to other DNA damage repair and tolerance pathways.