A reliable assessment of 8-oxo-2-deoxyguanosine levels in nuclear and mitochondrial DNA using the sodium iodide method to isolate DNA

A major controversy in the area of DNA biochemistry concerns the actual in vivo levels of oxidative damage in DNA. We show here that 8-oxo-2-deoxyguanosine (oxo8dG) generation during DNA isolation is eliminated using the sodium iodide (NaI) isolation method and that the level of oxo8dG in nuclear DNA (nDNA) is almost one-hundredth of the level obtained using the classical phenol method. We found using NaI that the ratio of oxo8dG/10(5 )deoxyguanosine (dG) in nDNA isolated from mouse tissues ranged from 0.032 +/- 0.002 for liver to 0.015 +/- 0.003 for brain. We observed a significant increase (10-fold) in oxo8dG in nDNA isolated from liver tissue after 2 Gy of gamma-irradiation when NaI was used to isolate DNA. The turnover of oxo8dG in nDNA was rapid, e.g. disappearance of oxo8dG in the mouse liver in vivo after gamma-irradiation had a half-life of 11 min. The levels of oxo8dG in mitochondrial DNA isolated from liver, heart and brain were 6-, 16- and 23-fold higher than nDNA from these tissues. Thus, our results showed that the steady-state levels of oxo8dG in mouse tissues range from 180 to 360 lesions in the nuclear genome and from one to two lesions in 100 mitochondrial genomes.     

Influence of aging and long-term caloric restriction on oxygen radical generation and oxidative DNA damage in rat liver mitochondria

The effect of long-term caloric restriction and aging on the rates of mitochondrial H2O2 production and oxygen consumption as well as on oxidative damage to nuclear (nDNA) and mitochondrial DNA (mtDNA) was studied in rat liver tissue. Long-term caloric restriction significantly decreased H2O2 production of rat liver mitochondria (47% reduction) and significantly reduced oxidative damage to mtDNA (46% reduction) with no changes in nDNA. The decrease in ROS production was located at complex I because it only took place with complex I-linked substrates (pyruvate/malate) but not with complex II-linked substrates (succinate). The mechanism responsible for that decrease in ROS production was not a decrease in mitochondrial oxygen consumption because it did not change after long-term restriction. Instead, the caloric restricted mitochondria released less ROS per unit electron flow, due to a decrease in the reduction degree of the complex I generator. On the other hand, increased ROS production with aging in state 3 was observed in succinate-supplemented mitochondria because old control animals were unable to suppress H2O2 production during the energy transition from state 4 to state 3. The levels of 8-oxodG in mtDNA increased with age in old animals and this increase was abolished by caloric restriction. These results support the idea that caloric restriction reduces the aging rate at least in part by decreasing the rate of mitochondrial ROS production and so, the rate of oxidative attack to biological macromolecules like mtDNA.     

Urinary excretion of DNA repair products correlates with metabolic rates as well as with maximum life spans of different mammalian species

Using recently developed methodology, which includes HPLC prepurification followed by GC/MS with isotope dilution, we analyzed urinary excretion of possible repair products of oxidative DNA damage-8-oxo-7,8-dihydroguanine (8-oxoGua), 8-oxo-7,8-dihydro-2'-deoxyguanosine (8-oxodG), and 5-(hydroxymethyl)uracil (5-HMUra)-in mammalian species that substantially differ in metabolic rate and longevity, namely, mice, rats, rabbits, dogs, pigs, and humans. We found highly significant, positive correlations between specific metabolic rates of the animals studied and their excretion rates for all the modifications analyzed with respective r values for the lesions of (8-oxoGua) r = .891, p < .01; (8-oxodG) r = .998, p < .001; and (5-HMUra) r = .949, p < .005. However, only 8-oxoGua significantly correlates negatively with maximum life span (MLSP) (r = -.928, p < .01). Despite substantial differences in MLSP between humans and pigs (120 and 27 years, respectively), the rates of excretion of all measured modifications were very similar. The urinary levels of all measured modifications found in our study for mouse and humans account respectively for about 34,000 and 2800 repaired events per average cell, per 24 h. It is therefore possible that the high metabolic rate in mice (or other short-lived animals) may be responsible for severe everyday oxidative DNA insults that may be accumulated faster than in long-lived species.     

No evidence of mitochondrial respiratory dysfunction in OGG1-null mice deficient in removal of 8-oxodeoxyguanine from mitochondrial DNA

Accumulation of high levels of mutagenic oxidative mitochondrial DNA (mtDNA) lesions like 8-oxodeoxyguanine (8-oxodG) is thought to be involved in the development of mitochondrial dysfunction in aging and in disorders associated with aging. Mice null for oxoguanine DNA glycosylase (OGG1) are deficient in 8-oxodG removal and accumulate 8-oxodG in mtDNA to levels 20-fold higher than in wild-type mice (N.C. Souza-Pinto et al., 2001, Cancer Res. 61, 5378-5381). We have used these animals to investigate the effects on mitochondrial function of accumulating this particular oxidative base modification. Despite the presence of high levels of 8-oxodG, mitochondria isolated from livers and hearts of Ogg1-/- mice were functionally normal. No differences were detected in maximal (chemically uncoupled) respiration rates, ADP phosphorylating respiration rates, or nonphosphorylating rates with glutamate/malate or with succinate/rotenone. Similarly, maximal activities of respiratory complexes I and IV from liver and heart were not different between wild-type and Ogg1-/- mice. In addition, there was no indication of increased oxidative stress in mitochondria from Ogg1-/- mice, as measured by mitochondrial protein carbonyl content. We conclude, therefore, that highly elevated levels of 8-oxodG in mtDNA do not cause mitochondrial respiratory dysfunction in mice.     

Age-associated change in mitochondrial DNA damage

There is an age-associated decline in the mitochondrial function of the Wistar rat heart. Previous reports from this lab have shown a decrease in mitochondrial cytochrome c oxidase (COX) activity associated with a reduction in COX gene and protein expression and a similar decrease in the rate of mitochondrial protein synthesis. Damage to mitochondrial DNA may contribute to this decline.

Using the HPLC-Coularray system (ESA, USA), we measured levels of nuclear and mitochondrial 8-oxo-2'-deoxyguanosine (8-oxodG) from 6-month (young) and 23-month-old (senescent) rat liver DNA. We measured the sensitivity of the technique by damaging calf thymus DNA with photoactivated methylene blue for 30s up to 2h. The levels of damage were linear over the entire time course including the shorter times which showed levels comparable to those expected in liver. For the liver data, 8-oxodG was reported as a fraction of 2-deoxyguanosine (2-dG). There was no change in the levels of 8-oxodG levels in the nuclear DNA from 6 to 23-months of age. However, the levels of 8-oxodG increased 2.5-fold in the mitochondrial DNA with age. At 6 months, the level of 8-oxodG in mtDNA was 5-fold higher than nuclear and increased to approximately 12-fold higher by 23 months of age. These findings agree with other reports showing an age-associated increase in levels of mtDNA damage; however, the degree to which it increases is smaller. Such damage to the mitochondrial DNA may contribute to the age-associated decline in mitochondrial function.     

Mitochondrial DNA 4977 bp deletion and OH8dG levels correlate in the brain of aged subjects but not Alzheimer's disease patients.

The levels of mitochondrial DNA 4977 bp deletion (mtDNA4977) and mitochondrial DNA 8'-hydroxy-2'-deoxyguanosine (OH8dG) were determined in the same samples from two brain areas of healthy subjects and Alzheimer's disease (AD) patients. A positive correlation between the age-related increases of mtDNA4977 and of OH8dG levels was found in the brain of healthy individuals. On the contrary, in both brain areas of AD patients, mtDNA4977 levels were very low in the presence of high OH8dG amounts. These results might be explained assuming that the increase of OH8dG above a threshold level, as in AD patients, implies consequences for mtDNA replication and neuronal cell survival.     

Premature aging is associated with higher levels of 8‐oxoguanine and increased DNA damage in the Polg mutator mouse

Mitochondrial dysfunction plays an important role in the aging process. However, the mechanism by which this dysfunction causes aging is not fully understood. The accumulation of mutations in the mitochondrial genome (or “mtDNA”) has been proposed as a contributor. One compelling piece of evidence in support of this hypothesis comes from the Polg ^D257A/D257A mutator mouse (Polg ^mut/mut ). These mice express an error‐prone mitochondrial DNA polymerase that results in the accumulation of mtDNA mutations, accelerated aging, and premature death. In this paper, we have used the Polg ^mut/mut model to investigate whether the age‐related biological effects observed in these mice are triggered by oxidative damage to the DNA that compromises the integrity of the genome. Our results show that mutator mouse has significantly higher levels of 8‐oxoguanine (8‐oxoGua) that are correlated with increased nuclear DNA (nDNA) strand breakage and oxidative nDNA damage, shorter average telomere length, and reduced mtDNA integrity. Based on these results, we propose a model whereby the increased level of reactive oxygen species (ROS) associated with the accumulation of mtDNA mutations in Polg ^mut/mut mice results in higher levels of 8‐oxoGua, which in turn lead to compromised DNA integrity and accelerated aging via increased DNA fragmentation and telomere shortening. These results suggest that mitochondrial play a central role in aging and may guide future research to develop potential therapeutics for mitigating aging process.     

Endogenous Oxidative DNA Damage,Aging, and Cancer

Progress in identifying the important endogenous processes damaging DNA and developing methods to assay this damage in individuals is presented. This approach may aid studies on modulation of cancer and aging.

The endogenous background level of oxidant-induced DNA damage in vivo has been assayed by measuring 8-hydroxydeoxyguanosine (oh⁸dG), thymine glycol and thymidine glycol in urine and oh⁸dG in DNA. oh⁸dG is one of about 20 adducts found on oxidizing DNA, e.g., by radiation. The level of oxidative DNA damage as measured by oh⁸dG in normal rat liver is shown to be extensive, especially in mtDNA (1/130,000 bases in nuclear DNA and 1/8,000 bases in mitochondrial DNA). We also discuss three hitherto unrecognized antioxidants in man.     

The long amplicon quantitative PCR for DNA damage assay as a sensitive method of assessing DNA damage in the environmental model, Atlantic killifish (Fundulus heteroclitus)

DNA damage is an important mechanism of toxicity for a variety of pollutants, and therefore, is often used as an indicator of pollutant effects in ecotoxicological studies. Here, we adapted a PCR-based assay for nuclear and mitochondrial DNA damage for use in an important environmental model, the Atlantic killifish (Fundulus heteroclitus). We refer to this assay as the long amplicon quantitative PCR (LA-QPCR) assay. To validate this method in killifish, DNA damage was measured in liver, brain, and muscle of fish dosed with 10 mg/kg benzo[a]pyrene. This exposure caused 0.4-0.8 lesions/10 kb. We also measured DNA damage in liver and muscle tissues from killifish inhabiting a Superfund site, confirming the utility of this method for biomonitoring. In both cases, damage levels were comparable in nuclear DNA (nDNA) and mitochondrial DNA (mtDNA). Since extensive nDNA sequence data are not readily available for many environmentally relevant species, but mitochondrial genomes are frequently fully sequenced, this assay can be adapted to examine mtDNA damage in virtually any species with little development. Therefore, we argue that this assay will be a valuable tool in assessing DNA damage in ecotoxicological studies.     

Mitochondrial DNA-depleted A549 cells are resistant to bleomycin

Alveolar epithelial cells are considered to be the primary target of bleomycin-induced lung injury, leading to interstitial fibrosis. The molecular mechanisms by which bleomycin causes this damage are poorly understood but are suspected to involve generation of reactive oxygen species and DNA damage. We studied the effect of bleomycin on mitochondrial DNA (mtDNA) and nuclear DNA (nDNA) in human alveolar epithelial A549 cells. Bleomycin caused an increase in reactive oxygen species production, DNA damage, and apoptosis in A549 cells; however, bleomycin induced more mtDNA than nDNA damage. DNA damage was associated with activation of caspase-3, cleavage of poly(ADP-ribose) polymerase, and cleavage and activation of protein kinase D1 (PKD1), a newly identified mitochondrial oxidative stress sensor. These effects appear to be mtDNA-dependent, because no caspase-3 or PKD1 activation was observed in mtDNA-depleted (ρ(0)) A549 cells. Survival rate after bleomycin treatment was higher for A549 ρ(0) than A549 cells. These results suggest that A549 ρ(0) cells are more resistant to bleomycin toxicity than are parent A549 cells, likely in part due to the depletion of mtDNA and impairment of mitochondria-dependent apoptotic pathways.     

线粒体DNA与DNA甲基化的关系

线粒体DNA（mitochondrial DNA,mtDNA）遗传信息量虽小,却控制着线粒体一些最基本的性质,对细胞及其功能有着重要影响。mtDNA的损伤与衰老、肿瘤等疾病的发生有关。DNA甲基化是调节基因表达的重要方式之一。mtDNA基因的表达受核DNA（nuclear DNA,nDNA）的调控,mtDNA和nDNA协同作用参与机体代谢调节和发病。本文就近年来mtDNA与DNA甲基化的关系作一综述。     

The structure of animal mitochondrial DNA (base composition,pyrimidine clusters,character of methylation)

Summary Base composition, content of pyrimidine isopliths and the degree of methylation of mitochondrial DNA (mtDNA) and nuclear DNA (nDNA) from various vertebrates and protozoonCrithidia oncopelti have been studied. MtDNAs from mammals (ox, rat) do not differ in fact in the GC content from the respective nDNA. The GC content in mtDNA from fishes (sheat fish) and birds (duck, chicken) is 1.5–2.5 mole % higher than in the respective nDNA. Kinetoplast DNA (kDNA) fromCrithidia oncopelti (GC = 42.9 mole %) differs significantly in base composition from nDNA (GC = 51.3 mole %). All the mtDNA and kDNA studied differ from the respective nDNA by a lower degree of pyrimidine clustering. Th amount of mono and dipyrimidine fragments in mtDNA is more than 30 mole %, whereas in nDNA it does not exceed 23 mole %. The quantity of long pyrimidine clusters (hexa and others) is 2–4 times lower in mtDNA than in nDNA. The lower degree of clustering of pyrimidine nucleotides seems to be a specific feature of all the mtDNA studied. This may be indicative of common traits in the organization and origin of mtDNA. All mtDNA of vertebrates contain 5-methylcytosine as a minor base (1.5–3.15 mole %) and surpass by 1.5–2 times the respective nDNA in the methylation degree. It has been found that in animals mtDNA is species specific as far as the 5-methyl-cytosine content is concerned. In mitochondria and nuclei of rat liver certain DNA methylase activity has been detected, which providesin vitro the methylation of cytosine residues both in homologous DNA and various heterologous DNAs. The specificity of methylationin vitro of cytosine residues in the same heterologous DNA fromE. coli B varies with the source of enzymes. The mitochondrial enzyme methylates cytosine as the lone monopyrimidine residue, whereas the nuclear enzyme methylates cytosine in the di- and tripyrimidine fragments.     

Numerical chromosomal abnormalities in equine embryos produced in vivo and in vitro

Alkaline gel electrophoresis, pulsed field gel electrophoresis, and quantitative PCR analyses (QPCR) of the nuclear (nDNA) and mitochondrial (mtDNA) genomes were used to assess DNA integrity in the spermatozoa of three species exposed to oxidative stress. In human and murine spermatozoa, the mtDNA was significantly more susceptible to H2O2-mediated damage than nDNA. In both eutherian species, exposure to 250 microM H2O2 induced around 0.6 lesions/10 kb of mtDNA. The mtDNA of human spermatozoa was particularly vulnerable to oxidative stress; 0.25, 1, and 5 mM H2O2 inducing DNA damage equivalent to 0.62, 1.34, and 1.42 lesions/10 kb, respectively. Such results emphasize the diagnostic significance of mtDNA as a biomarker of oxidative stress in the male germ line. In contrast, no damage could be detected by QPCR in the nDNA of either eutherian species, on exposure to H2O2 at doses as high as 5 mM. However, electrophoretic analysis indicated that severe oxidative stress could induce detectable nDNA fragmentation in human, but not murine spermatozoa. The mtDNA of tammar wallaby spermatozoa was relatively resistant to oxidative stress, only exhibiting damage (0.6 lesions/10 kb DNA) on exposure to 5 mM H2O2. By contrast, the nDNA of wallaby spermatozoa was significantly more susceptible to this oxidant than the other species. Such vulnerability is consistent with the lack of disulfide cross-linking in marsupial sperm chromatin and suggests that chromatin condensation during epididymal maturation may be important in establishing the resistance of these cells to the genotoxic effects of reactive oxygen species.     

Massive conversion of guanosine to 8-hydroxy-guanosine in mouse liver mitochondrial DNA by administration of azidothymidine.

As typical mitochondrial myopathy has been reported to be expressed among many patients with AIDS treated with long-term azidothymidine (AZT) therapy, we examined changes in mouse liver mitochondrial DNA (mtDNA) after 4-week administration of AZT. Even below 1/10th the dose given to the patients (AZT, 1 mg/kg/day), 25% of the total deoxyguanosine (dG) was converted to be 8-hydroxy-deoxyguanosine (8-OH-dG). 38% of the total dG was converted to 8-OH-dG with AZT 5 mg/kg/day. In vitro, the conversion of dG to 8-OH-dG was demonstrated by incubating mtDNA in the oxygen radical producing system containing NADH and KCN treated mitochondrial inner membrane. Thus it is concluded that, by lack of repairing system, damaged mtDNA with AZT results in impaired mitochondrial respiratory chain causing oxygen radicals which are responsible for 8-OH-dG formation. These results suggest that the oxygen damage of mtDNA is the primary cause of mitochondrial myopathy with AZT therapy.     

Endogenous DNA damage as related to cancer and aging

The endogenous background level of oxidant-induced DNA damage in vivo has been assayed by measuring 8-hydroxydeoxyguanosine (oh8dG), thymine glycol and thymidine glycol in urine and oh8dG in DNA. The level of oxidative DNA damage as measured by oh8dG in normal rat liver is shown to be extensive (1/130,000 bases in nuclear DNA and 1/8000 bases in mitochondrial DNA), especially in mtDNA. The methylation adduct 7-methylguanine (m7G) has also been found. m7G is one of about 5 adducts found on methylating DNA, and oh8dG is one of about 20 adducts found on oxidizing DNA, e.g., by radiation. We also discuss 3 hitherto unrecognized antioxidants in man.     

DNA damage, repair, and antioxidant systems in brain regions: a correlative study

8-Hydroxy-2'-deoxyguanosine (oxo(8)dG) has been used as a marker of free radical damage to DNA and has been shown to accumulate during aging. Oxidative stress affects some brain regions more than others as demonstrated by regional differences in steady state oxo(8)dG levels in mouse brain. In our study, we have shown that regions such as the midbrain, caudate putamen, and hippocampus show high levels of oxo(8)dG in total DNA, although regions such as the cerebellum, cortex, and pons and medulla have lower levels. These regional differences in basal levels of DNA damage inversely correlate with the regional capacity to remove oxo(8)dG from DNA. Additionally, the activities of antioxidant enzymes (Cu/Zn superoxide dismutase, mitochondrial superoxide dismutase, and glutathione peroxidase) and the levels of the endogenous antioxidant glutathione are not predictors of the degree of free radical induced damage to DNA in different brain regions. Although each brain region has significant differences in antioxidant defenses, the capacity to excise the oxidized base from DNA seems to be the major determinant of the steady state levels of oxo(8)dG in each brain region.     

A decreased mitochondrial DNA content is related to insulin resistance in adolescents

The aim of this study was to investigate whether mitochondrial DNA (mtDNA) content is associated with insulin resistance (IR) in a sample of adolescents with features of metabolic syndrome. We further studied the link between polymorphisms in three genes involved in mitochondrial biogenesis and the presence of deleted mtDNA and mtDNA content. Data and blood samples were collected from 175 adolescents out of a cross-sectional, population-based study of 934 high school students. On the basis of the median value of homeostasis model assessment of IR (HOMA-IR) of the whole sample (2.2), the population was divided into two groups: noninsulin resistance (NIR) and IR. mtDNA quantification using nuclear DNA (nDNA) as a reference was carried out using a real-time quantitative PCR method. Genotyping for peroxisome proliferator-activated receptor-gamma (PPAR-gamma) (pro12Ala), PPAR- gamma coactivator-1alpha (PGC-1alpha) (Gly482Ser), and Tfam (rs1937 and rs12247015) polymorphisms was performed by PCR-based restriction fragment length polymorphism. Long-extension PCR was performed to amplify the whole mitochondrial genome. The mtDNA/nDNA ratio was significantly lower in the IR group (median: 9.08, range: 68.94) in comparison with the NIR group (12.24, 71.92) (P<0.03). Besides, the mtDNA/nDNA ratio was inversely correlated with HOMA (R: -0.18, P<0.02), glucose (R: -0.21, P<0.008), and uric acid (R: -0.18, P<0.03). Genotypes for the PPAR- gamma, PGC-1alpha, and Tfam variants were not associated with the mtDNA/nDNA ratio. Long-extension PCR did not show significant levels of mtDNA deletions. In conclusion, our findings indicate that reduced mtDNA content in peripheral leukocytes is associated with IR. This result seems not to be related with the previously mentioned variants in genes involved in the regulation of mitochondrial biogenesis.     

Cardioselective and cumulative oxidation of mitochondrial DNA following subchronic doxorubicin administration

We recently reported the preferential accumulation of 8-hydroxydeoxyguanosine (8OHdG) adducts in cardiac mitochondrial DNA (mtDNA) following acute intoxication of rats with doxorubicin (C.M. Palmeira et al., Biochim. Biophys. Acta, 1321 (1997) 101-106). The concentration of 8OHdG adducts decreased to control values within 2 weeks. Since conventional antineoplastic therapy entails repeated administration of small doses of doxorubicin, it was of interest to characterize the kinetics for the accumulation and repair of 8OHdG adducts in the various DNA fractions. Weekly injections of doxorubicin (2 mg/kg, i.p.) to adult male Sprague-Dawley rats caused a cumulative dose-dependent increase in the concentration of 8OHdG adducts in both mtDNA and nuclear DNA (nDNA) from heart and liver. Following six weekly injections, the concentration of 8OHdG in cardiac mtDNA was 50% higher than liver mtDNA and twice that of cardiac nDNA. In contrast to the rapid repair of 8OHdG observed during the first days following an acute intoxicating dose of doxorubicin, the concentration of 8OHdG adducts remained constant between 1 and 5 weeks following the last injection. This was true for all DNA fractions examined. The cardioselective accumulation and persistence of 8OHdG adducts to mtDNA is consistent with the implication of mitochondrial dysfunction in the cumulative and irreversible cardiotoxicity observed clinically in patients receiving doxorubicin cancer chemotherapy.     

Lipids and DNA oxidation in Staphylococcus aureus as a consequence of oxidative stress generated by ciprofloxacin

Ciprofloxacin induced an increment of reactive oxygen species in sensitive strains of Staphylococcus aureus leading to oxidative stress detected by chemiluminescence while resistant strains did not suffer such stress. Oxidation of lipids was performed by employing thiobarbituric acid reaction to detect the formation of the amplified intermediate between reactive species oxygen and cytoplasmic macromolecules, namely malondialdehyde (MDA). The sensitive strain presented higher peroxidation of lipids than the resistant strain. The oxidative consequence for DNA was investigated by means of bacteria incubation with ciprofloxacin and posterior extraction of DNA, which was studied by high performance liquid chromatography (HPLC). Sensitive S. aureus ATCC 29213 showed an increase of 8-oxo-7,8-dihydro-2′-deoxyguanosine (8-oxodG) respect controls without antibiotic; there was evident increase of the ratio between 8-oxodG and deoxyguanosine (dG) as a consequence of oxidation of dG to 8-oxodG considered the major DNA marker of oxidative stress. The resistant strain showed low oxidation of DNA and the analysis of 8-oxodG/dG ratio indicated lesser formation of 8-oxodG than S. aureus ATCC 29213.