Gliotoxin causes oxidative damage to plasmid and cellular DNA

The cytotoxic effects of gliotoxin (Müllbacher, A., and Eichner, R. D. (1984) Proc. Natl. Acad. Sci. U.S.A. 81, 3835-3837), a fungal secondary metabolite, and related epipolythiodioxopiperazines have been investigated using plasmid and eukaryotic DNA. Incubation of the dithiol derivative of these compounds with DNA and Fe3+ is sufficient to cause single- and double-stranded breaks as determined by neutral agarose gel electrophoresis. The disulfide form is inactive except in the presence of a suitable reducing agent, such as reduced glutathione, dithiothreitol, or reduced pyridine coenzymes. The autooxidation of these dithiols produces reducing equivalents as evidenced by (i) the production of H2O2 and (ii) the generation of thiobarbituric acid reactive products when incubated with deoxyribose. The latter process is inhibited by ethanol and desferrioxamine. The DNA damage is abrogated by metal chelators and catalase. We conclude that the antiproliferative action of gliotoxin may be caused by DNA damage effected by reactive oxygen species or other radicals generated through redox cycling.     

8-Hydroxyguanine in a mutational hotspot of the c-Ha-ras gene causes misreplication, 'action-at-a-distance' mutagenesis and inhibition of replication

Mutations in particular codons of c-Ha-ras have a strong activating potential, and an activated ras oncogene has been found in a number of human cancers. Using fragments of the human c-Ha-ras gene containing 8-hydroxyguanine (8-OH-G) in codon 12, we provide evidence for highly complex biochemical events leading to activation of the oncogene. Replication with DNA polymerases α (Polα) and β (Polβ) led to misincorporation of dAMP, while DNA polymerase η (Polη) caused additional insertion of dGMP. For the first time we report an ‘action-at-a-distance’ mutagenic effect for Polη. Replication catalyzed by this enzyme resulted in misincorporating dAMP, dTMP and dGMP opposite non-oxidized guanine 3′-flanked by 8-OH-G. Interestingly, two adjacent 8-OH-G residues greatly relaxed the specificity of Polη, which in this system was able to incorporate all four nucleotides. Moreover, two adjacent 8-OH-G residues completely blocked Polα and strongly inhibited Polβ, whereas Polη was entirely resistant to this inhibition. These results suggest an important role for Polη in inducing hypermutability in codon 12. Our observations are important for understanding the consequences of 8-OH-G being positioned within the mutational hot spots of oncogenes, the outcome of which appears to be relatively complex even in minimal in vitro systems.     

8-Oxoguanine induces intramolecular DNA damage but free 8-oxoguanine protects intermolecular DNA from oxidative stress

7,8-Dihydro-8-oxoguanine (8-oxoguanine; 8-oxo-G), one of the major oxidative DNA adducts, is highly susceptible to further oxidation by radicals. We confirmed the higher reactivity of 8-oxo-G toward reactive oxygen (singlet oxygen and hydroxyl radical) or nitrogen (peroxynitrite) species as compared to unmodified base. In this study, we raised the question about the effect of this high reactivity toward radicals on intramolecular and intermolecular DNA damage. We found that the amount of intact nucleoside in oligodeoxynucleotide containing 8-oxo-G decreased more by various radicals at higher levels of 8-oxo-G incorporation, and that the oligodeoxynucleotide damage and plasmid cleavage by hydroxyl radical were inhibited in the presence of 7,8-dihydro-8-oxo-2'-deoxyguanosine (8-oxo-dG). We conclude that 8-oxo-G within DNA induces intramolecular DNA base damage, but that free 8-oxo-G protects intermolecular DNA from oxidative stress. These results suggest that 8-oxo-G within DNA must be rapidly released to protect DNA from overall oxidative damage.     

Chronic oxidative DNA damage due to DNA repair defects causes chromosomal instability in Saccharomyces cerevisiae

Oxidative DNA damage is likely to be involved in the etiology of cancer and is thought to accelerate tumorigenesis via increased mutation rates. However, the majority of malignant cells acquire a specific type of genomic instability characterized by large-scale genomic rearrangements, referred to as chromosomal instability (CIN). The molecular mechanisms underlying CIN are not entirely understood. We utilized Saccharomyces cerevisiae as a model system to delineate the relationship between genotoxic stress and CIN. It was found that elevated levels of chronic, unrepaired oxidative DNA damage caused chromosomal aberrations at remarkably high frequencies under both selective and nonselective growth conditions. In this system, exceeding the cellular capacity to appropriately manage oxidative DNA damage resulted in a “gain-of-CIN” phenotype and led to profound karyotypic instability. These results illustrate a novel mechanism for genome destabilization that is likely to be relevant to human carcinogenesis.     

Thermostable repair enzyme for oxidative DNA damage from extremely thermophilic bacterium, Thermus thermophilus HB8.

The mutM (fpg) gene, which encodes a DNA glycosylase that excises an oxidatively damaged form of guanine, was cloned from an extremely thermophilic bacterium, Thermus thermophilus HB8. Its nucleotide sequence encoded a 266 amino acid protein with a molecular mass of approximately 30 kDa. Its predicted amino acid sequence showed 42% identity with the Escherichia coli protein. The amino acid residues Cys, Asn, Gln and Met, known to be chemically unstable at high temperatures, were decreased in number in T.thermophilus MutM protein compared to those of the E.coli one, whereas the number of Pro residues, considered to increase protein stability, was increased. The T.thermophilus mutM gene complemented the mutability of the E.coli mutM mutY double mutant, suggesting that T. thermophilus MutM protein was active in E.coli. The T.thermophilus MutM protein was overproduced in E.coli and then purified to homogeneity. Size-exclusion chromatography indicated that T. thermophilus MutM protein exists as a more compact monomer than the E.coli MutM protein in solution. Circular dichroism measurements indicated that the alpha-helical content of the protein was approximately 30%. Thermus thermophilus MutM protein was stable up to 75 degrees C at neutral pH, and between pH 5 and 11 and in the presence of up to 4 M urea at 25 degrees C. Denaturation analysis of T.thermophilus MutM protein in the presence of urea suggested that the protein had at least two domains, with estimated stabilities of 8.6 and 16.2 kcal/mol-1, respectively. Thermus thermophilus MutM protein showed 8-oxoguanine DNA glycosylase activity in vitro at both low and high temperatures.     

Melanin both causes and prevents oxidative base damage in DNA: quantification by anti-thymine glycol antibody.

The present study employs immunological methods to measure modified bases in DNA. A polyclonal antibody specific for thymine glycol was used to quantify the level of thymine glycol in calf thymus DNA gamma-irradiated in solutions containing varying concentrations of DOPA-eumelanin. Melanin decreased the number of thymine glycols produced by 200 Gy at low melanin concentrations. At high melanin concentrations, the number of thymine glycols increased. Thymine glycol was also produced in unirradiated DNA-eumelanin mixtures. DOPA-eumelanin was found to produce single-strand breaks in supercoiled phi X174 RF DNA. The breaks were measured by conversion of form I to form II as detected by agarose gel electrophoresis. The level of damage produced by melanin could be modulated by agents known either to stabilize or to scavenge active oxygen species. These studies demonstrate that melanin can both scavenge and generate active free radicals.     

Superoxide and the production of oxidative DNA damage.

The conventional model of oxidative DNA damage posits a role for superoxide (O2-) as a reductant for iron, which subsequently generates a hydroxyl radical by transferring the electron to H2O2. The hydroxyl radical then attacks DNA. Indeed, mutants of Escherichia coli that lack superoxide dismutase (SOD) were 10-fold more vulnerable to DNA oxidation by H2O2 than were wild-type cells. Even the pace of DNA damage by endogenous oxidants was great enough that the SOD mutants could not tolerate air if enzymes that repair oxidative DNA lesions were inactive. However, DNA oxidation proceeds in SOD-proficient cells without the involvement of O2-, as evidenced by the failure of SOD overproduction or anaerobiosis to suppress damage by H2O2. Furthermore, the mechanism by which excess O2- causes damage was called into question when the hypersensitivity of SOD mutants to DNA damage persisted for at least 20 min after O2- had been dispelled through the imposition of anaerobiosis. That behavior contradicted the standard model, which requires that O2- be present to rereduce cellular iron during the period of exposure to H2O2. Evidently, DNA oxidation is driven by a reductant other than O2-, which leaves the mechanism of damage promotion by O2- unsettled. One possibility is that, through its well-established ability to leach iron from iron-sulfur clusters, O2- increases the amount of free iron that is available to catalyze hydroxyl radical production. Experiments with iron transport mutants confirmed that increases in free-iron concentration have the effect of accelerating DNA oxidation. Thus, O2- may be genotoxic only in doses that exceed those found in SOD-proficient cells, and in those limited circumstances it may promote DNA damage by increasing the amount of DNA-bound iron.     

UvrABC nuclease complex repairs thymine glycol, an oxidative DNA base damage

The UvrABC nuclease complex recognizes a wide spectrum of DNA lesions including pyrimidine dimers, bulky chemical adducts and O6-methylguanine. In this study we have demonstrated that the UvrABC complex is also able to incise PM2 DNA containing the oxidative DNA lesion, thymine glycol. However, DNA containing dihydrothymine, a lesion with a similar structure to thymine glycol, was not incised. The UvrABC complex was also able to incise DNA containing reduced apurinic sites or apurinic sites modified with O-alkyl hydroxylamines, but not DNA containing apurinic sites or urea residues. In vivo, in the absence of base-excision repair, nucleotide excision repair was operable on phi X-174 RF transfecting DNA containing thymine glycols. The level of the repair was found to be directly related to the level of the UvrABC complex. Thus, UvrABC-mediated nucleotide excision repair appears to play a role in the repair of thymine glycol, an oxidative DNA-base lesion that is produced by ionizing radiation or formed during oxidative respiration.     

Repair of oxidative DNA damage

Cellular genomes suffer extensive damage from exogenous agents and reactive oxygen species formed during normal metabolism. The MutT homologs (MutT/MTH) remove oxidized nucleotide precursors so that they cannot be incorporated into DNA during replication. Among many repair pathways, the base excision repair (BER) pathway is the most important cellular protection mechanism responding to oxidative DNA damage. The 8-oxoG glycosylases (Fpg or MutM/OGG) and the MutY homologs (MutY/MYH) glycosylases along with MutT/MTH protect cells from the mutagenic effects of 8-oxoG, the most stable and deleterious product known caused by oxidative damage to DNA. The key enzymes in the BER process are DNA glycosylases, which remove different damaged bases by cleavage of the N-glycosylic bonds between the bases and the deoxyribose moieties of the nucleotide residues. Biochemical and structural studies have demonstrated the substrate recognition and reaction mechanism of BER enzymes. Cocrystal structures of strated the substrate recognition and reaction mechanism of BER enzymes. Cocrystal structures of several glycosylases show that the substrate base flips out of the sharply bent DNA helix and the minor groove is widened to be accessed by the glycosylases. To complete the repair after glycosylase action, the apurinic/apyrimidinic (AP) site is further processed by an incision step, DNA synthesis, an excision step, and DNA ligation through two alternative pathways. The short-patch BER (1-nucleotide patch size) and long-patch BER (2–6-nucleotide patch size) pathways need AP endonuclease to generate a 3′ hydroxyl group but require different sets of enzymes for DNA synthesis and ligation. Protein-protein interactions have been reported among the enzymes involved in BER. It is possible that the successive players in the repair pathway are assembled in a complex to perform concerted actions. The BER pathways are proposed to protect cells and organisms from mutagenesis and carcinogenesis.     

Antibodies to oxidative DNA damage: Characterization of antibodies to 8-oxopurines

The 8-oxo-7,8-dihydropurines (8-oxopurines) are important cellular premutagenic lesions produced in DNA by free radicals. Specific antibodies were prepared to detect these lesions. For antigens, 8-oxo-7,8-dihydroadenosine (8-oxoAdo) and 8-oxo-7,8-dihydroguanosine (8-oxoGuo) were synthesized from the bromonucleosides, and the immunogens were produced by conjugating these to either bovine serum albumin or rabbit serum albumin by the periodate method. Polyclonal antibodies specific for the haptens were elicited from rabbits immunized with the BSA conjugates. The antibodies to 8-oxoAdo (anti-8-oxoAdo) and 8-oxoGuo (anti-8-oxoGuo) precipitated the homologous antigens in an Ouchterlony gel diffusion assay and no cross-reactivity was observed toward the normal nucleosides or to the heterologous 8-oxopurine. Specificity was also examined by hapten inhibition of antibody reactivity with the homologous conjugates using ELISA. For anti-8-oxoAdo, the IC50 for 8-oxoAdo was 8 µmol/L and 8-bromoadenosine, guanosine, and inosine did not inhibit, even at concentrations of 1.25 mmol/L. Similarly, the IC50 for anti-8-oxoGuo for 8-oxoGuo was 0.1 µmol/L. 8-Methoxyguanosine also inhibited the reaction but was about 500-fold less effective than the eliciting hapten. Other nucleosides tested did not inhibit at concentrations up to 100 µmol/L. Both antibodies could easily detect the corresponding damage in x-irradiated fl DNA at a dose of 7.5 Gy and both antibodies recognized the corresponding lesion in duplex DNA; however, with anti-8-oxoGuo the signal was reduced about 50% compared to single-stranded DNA. In order to determine the exact amount of each lesion produced in irradiated DNA, and to standardize the ELISA signal, both products were measured after alkaline phosphatase digestion of x-irradiated calf thymus DNA using high-pressure liquid chromatography (HPLC) coupled to an electrochemical detector. Anti-8-oxoGuo could detect ten 8-oxoG residues and anti-8-oxoAdo could detect two 8-oxoA residues per 10 000 nucleotides. Thus, these antibodies should be useful for the detection and measurement of 8-oxopurines in cellular DNA.     

Nickel(II)-catalysed oxidative guanine and DNA damage beyond 8-oxoguanine

Oxidative DNA damage is one of the most important and most studied mechanisms of disease. It has been associated with a range of terminal diseases such as cancer, heart disease, hepatitis, and HIV, as well as with a variety of everyday ailments. There are various mechanisms by which this type of DNA damage can be initiated, through radiation and chemical oxidation, among others; however, these mechanisms have yet to be fully elucidated. A HPLC-UV-EC study of the oxidation of DNA mediated by nickel(II) obtained results that show an erratic, almost oscillatory formation of 8-oxoguanine (8-oxoG) from free guanine and from guanine in DNA. Sporadic 8-oxoG concentrations were also observed when 8-oxoG alone was subjected to these conditions. A HPLC-MS/MS study showed the formation of oxidised-guanidinohydantoin (oxGH) from free guanine at pH 11, and the formation of guanidinohydantoin (GH) from DNA at pH 5.5.     

Assays for 8-hydroxy-2'-deoxyguanosine: a biomarker of in vivo oxidative DNA damage.

HPLC with electrochemical detection (HPLC-EC) is a highly sensitive and a selective method for detecting 8-hydroxy-2'-deoxyguanosine (oh8dG), a biomarker of oxidative DNA damage that is formed from hydroxyl radical attack of guanine residues in DNA. We propose that the noninvasive measurement of oh8dG in urine can be used to estimate in vivo oxidative damage. Application of this assay to urine samples obtained from rats of different ages and various species provide examples of the utility of this assay. The measurement of steady-state levels of oh8dG in DNA combined with the urinary excretion rates of oh8dG and oh8Gua, offer a powerful approach for estimating oxidative DNA damage and its repair. This method will be useful for studies designed to investigate the relationship of oxidative stress in DNA damage and the role of this damage in aging and cancer.     

Regulation of oxidative DNA damage repair: The adenine:8-oxo-guanine problem

Reactive oxygen species (ROS) constantly attack DNA. One of the best-characterized oxidative DNA lesions is 7,8-dihydro-8-oxoguanine (8-oxo-G). Many human diseases, such as cancer and neurodegenerative disorders, have been correlated with oxidative DNA damage. In the last few years, DNA polymerase (Pol) λ, one of the 15 cellular Pols, has been identified to play an important role in performing accurate translesion synthesis over 8-oxo-G. This is eminently important, since normally faithful replicative Pols α, δ and ε, with their tight active center, often wrongly incorporate adenine (A) opposite the 8-oxo-G lesion. A:8- oxo-G mispairs are accurately repaired by the pathway identified in our laboratory involving MutY DNA glycosylase homolog (MutYH) and Pol λ. Until now, very little was known about the spatial and temporal regulation of Pol λ and MutYH in active repair complexes. We now showed in our latest publication that the E3 ligase Mule can ubiquitinate and degrade Pol λ, and that the control of Pol λ levels by Mule has functional consequences for the ability of mammalian cells to deal with 8-oxo-G lesions. In contrast, phosphorylation of Pol λ by Cdk2/cyclinA counteracts this degradation by recruiting it to MutYH on chromatin to form active 8-oxo-G repair complexes.     

Spt16 and Pob3 of Saccharomyces cerevisiae form an essential, abundant heterodimer that is nuclear, chromatin-associated, and copurifies with DNA polymerase alpha.

Previously we showed that the yeast proteins Spt16 (Cdc68) and Pob3 are physically associated, and interact physically and genetically with the catalytic subunit of DNA polymerase alpha, Pol1 [Wittmeyer and Formosa (1997) Mol. Cell. Biol. 17, 4178-4190]. Here we show that purified Spt16 and Pob3 form a stable, abundant, elongated heterodimer and provide evidence that this is the functional form of these proteins. Genetic interactions between mutations in SPT16 and POB3 support the importance of the Spt16-Pob3 interaction in vivo. Spt16, Pob3, and Pol1 proteins were all found to localize to the nucleus in S. cerevisiae. A portion of the total cellular Spt16-Pob3 was found to be chromatin-associated, consistent with the proposed roles in modulating chromatin function. Some of the Spt16-Pob3 complex was found to copurify with the yeast DNA polymerase alpha/primase complex, further supporting a connection between Spt16-Pob3 and DNA replication.     

Peptide repair of oxidative DNA damage

Guanyl radical species are produced in DNA by electron removal caused by ionizing radiation, photoionization, oxidation, or photosensitization. DNA guanyl radicals can be reduced by electron donation from mild reducing agents. Important biologically relevant examples are the redox active amino acids cysteine, cystine, methionine, tryptophan, and tyrosine. We have quantified the reactivity of derivatives of these amino acids with guanyl radicals located in plasmid DNA. The radicals were produced by electron removal using the single electron oxidizing agent (SCN)(2)(*)(-). Disulfides (cystine) are unreactive. Thioethers (methionine), thiols (cysteine), and phenols (tyrosine) react with rate constants in the range 10(4)-10(6), 10(5)-10(6), and 10(5)-10(6) dm(3) mol(-1) s(-1), respectively. Indoles (tryptophan) are the most reactive with rate constants of 10(7)-10(8) dm(3) mol(-1) s(-1). Selenium analogues of amino acids are over an order of magnitude more reactive than their sulfur equivalents. Increasing positive charge is associated with a ca. 10-fold increase in reactivity. The results suggest that amino acid residues located close to DNA (for example, in DNA binding proteins such as histones) might participate in the repair of oxidative DNA damage.     

Experimental study of oxidative DNA damage

Animal experiments allow the study of oxidative DNA damage in target organs and the elucidation of dose-response relationships of carcinogenic and other harmful chemicals and conditions as well as the study of interactions of several factors. So far the effects of more than 50 different chemical compounds have been studied in animal experiments mainly in rats and mice, and generally with measurement of 8-oxodG with HPLC-EC. A large number of well-known carcinogens induce 8-oxodG formation in liver and/or kidneys. Moreover several animal studies have shown a close relationship between induction of dative DNA damage and tumour formation.

In principle the level of oxidative DNA damage in an organ or cell may be studied by measurement of modified bases in extracted DNA by immunohistochemical visualisation, and from assays of strand breakage before and after treatment with repair enzymes. However, this level is a balance between the rates of damage and repair. Until the repair rates and capacity can be adequately assessed the rate of damage can only be estimated from the urinary excretion of repair products albeit only as an average of the entire body.

A number of model compounds have been used to induce oxidative DNA damage in experimental animals. The hepatocarcinogen 2-nitropropane induces up to 10-fold increases in 8-oxodG levels in rat liver DNA. The level of 8-oxodG is also increased in kidneys and bone marrow but not in the testis. By means of 2-nitropropane we have shown correspondence between the increases in 8-oxodG in target organs and the urinary excretion of 8-oxodG and between 8-oxodG formation and the comet assay in bone marrow as well potent preventive effects of extracts of Brussels sprouts. Others have shown similar effects of green tea extracts and its components. Drawbacks of the use of 2-nitropropane as a model for oxidative DNA damage relate particularly to formation of 8-aminoguanine derivatives that may interfere with HPLC-EC assays and have unknown consequences. Other model compounds for induction of oxidative DNA damage, such as ferric nitriloacetate, iron dextran, potassium bromate and paraquat, are less potent and/or more organ specific.

Inflammation and activation of an inflammatory response by phorbol esters or E. coli lipopolysaccharide (LPS) induce oxidative DNA damage in many target cells and enhance benzene-induced DNA damage in mouse bone marrow.

Experimental studies provide powerful tools to investigate agents inducing and preventing oxidative damage to DNA and its role in carcinogenesis. So far, most animal experiments have concerned 8-oxodG and determination of additional damaged bases should be employed. An ideal animal model for prevention of oxidative DNA damage has yet to he developed.     

Tomato consumption modulates oxidative DNA damage in humans.

Consumption of a single serving of tomatoes by healthy human volunteers was sufficient to alter levels of oxidative DNA base damage in white cell DNA within 24 h. Levels of the mutagenic oxidized purine base 8-hydroxyguanine decreased, especially in those subjects whose initial levels of this base were higher than the mean. However, total DNA base damage remained unchanged since levels of 8-hydroxyadenine rose. The ability of tomato consumption to modulate oxidative DNA damage in the short term may indicate why daily consumption of fruits and vegetables is beneficial in decreasing cancer incidence.     

Urinary excretion of 8-oxo-7,8-dihydroguanine as biomarker of oxidative damage to DNA

Oxidatively damaged DNA may be important in carcinogenesis. 8-Oxo-7,8-dihydroguanine (8-oxoGua) is an abundant and mutagenic lesion excised by oxoguanine DNA glycosylase 1 (OGG1) and measurable in urine or plasma by chromatographic methods with electrochemical or mass spectrometric detectors, reflecting the rate of damage in steady state. A common genetic OGG1 variant may affect the activity and was associated with increased levels of oxidized purines in leukocytes without apparent effect on 8-oxoGua excretion or major change in cancer risk. 8-OxoGua excretion has been associated with exposure to air pollution, toxic metals, tobacco smoke and low plasma antioxidant levels, whereas fruit and vegetable intake or dietary interventions showed no association. In rodent studies some types of feed may be source of 8-oxoGua in collected urine. Of cancer therapies, cisplatin increased 8-oxoGua excretion, whereas radiotherapy only showed such effects in experimental animals. Case-control studies found high excretion of 8-oxoGua in relation to cancer, dementia and celiac disease but not hemochromatosis, although associations could be a consequence rather than reflecting causality of disease. One prospective study found increased risk of developing lung cancer among non-smokers associated with high excretion of 8-oxoGua. Urinary excretion of 8-oxoGua is a promising biomarker of oxidatively damaged DNA.