Relative susceptibilities of mitochondrial and nuclear DNA to damage induced by hydrogen peroxide in two mouse germ cell lines

Abstract

The objective of this study was to determine the relative susceptibilities to the damaging effects of hydrogen peroxide of DNA in the mitochondrial and nuclear compartments of two murine germ cell lines. We used a quantitative polymerase chain reaction assay (QPCR) to measure gene- and mitochondrial-specific DNA damage and examined for the presence of alkali-labile sites using alkaline gel electrophoresis. No DNA damage was observed in a nuclear gene (β-globin) in response to hydrogen peroxide treatment. In addition, no increase in alkali-labile sites was observed. However, mitochondrial DNA suffered extensive damage which increased in a dose-dependent manner. These results demonstrate that the nuclear DNA in these germ cell lines is relatively resistant to peroxide-mediated DNA damage, and that mitochondrial DNA is a sensitive biomarker for oxidative stress in these cells.     

Quantitative analysis of gene-specific DNA damage in human spermatozoa

Recent studies have suggested that human spermatozoa are highly susceptible to DNA damage induced by oxidative stress. However, a detailed analysis of the precise nature of this damage and the extent to which it affects the mitochondrial and nuclear genomes has not been reported. To induce DNA damage, human spermatozoa were treated in vitro with hydrogen peroxide (H2O2; 0-5 mM) or iron (as Fe(II)SO4, 0-500 microM). Quantitative PCR (QPCR) was used to measure DNA damage in individual nuclear genes (hprt, beta-pol and beta-globin) and mitochondrial DNA. Single strand breaks were also assessed by alkaline gel electrophoresis. H2O2 was found to be genotoxic toward spermatozoa at concentrations as high as 1.25 mM, but DNA damage was not detected in these cells with lower concentrations of H2O2. The mitochondrial genome of human spermatozoa was significantly (P<0.001) more susceptible to H2O2-induced DNA damage than the nuclear genome. However, both nDNA and mtDNA in human spermatozoa were significantly (P<0.001) more resistant to damage than DNA from a variety of cell lines of germ cell and myoblastoid origin. Interestingly, significant DNA damage was also not detected in human spermatozoa treated with iron. These studies report, for the first time, quantitative measurements of DNA damage in specific genes of male germ cells, and challenge the commonly held belief that human spermatozoa are particularly vulnerable to DNA damage.     

The formation of DNA single-strand breaks and alkali-labile sites in human blood lymphocytes exposed to 365-nm UVA radiation

The potency of UVA radiation, representing 90% of solar UV light reaching the earth׳s surface, to induce human skin cancer is the subject of continuing controversy. This study was undertaken to investigate the role of reactive oxygen species in DNA damage produced by the exposure of human cells to UVA radiation. This knowledge is important for better understanding of UV-induced carcinogenesis. We measured DNA single-strand breaks and alkali-labile sites in human lymphocytes exposed ex vivo to various doses of 365-nm UV photons compared to X-rays and hydrogen peroxide using the comet assay. We demonstrated that the UVA-induced DNA damage increased in a linear dose-dependent manner. The rate of DNA single-strand breaks and alkali-labile sites after exposure to 1 J/cm² was similar to the rate induced by exposure to 1 Gy of X-rays or 25 μM hydrogen peroxide. The presence of either the hydroxyl radical scavenger dimethyl sulfoxide or the singlet oxygen quencher sodium azide resulted in a significant reduction in the UVA-induced DNA damage, suggesting a role for these reactive oxygen species in mediating UVA-induced DNA single-strand breaks and alkali-labile sites. We also showed that chromatin relaxation due to hypertonic conditions resulted in increased damage in both untreated and UVA-treated cells. The effect was the most significant in the presence of 0.5 M Na⁺, implying a role for histone H1. Our data suggest that the majority of DNA single-strand breaks and alkali-labile sites after exposure of human lymphocytes to UVA are produced by reactive oxygen species (the hydroxyl radical and singlet oxygen) and that the state of chromatin may substantially contribute to the outcome of such exposures.     

Proteins associated with mitochondrial DNA protect it against the action of X-rays and hydrogen peroxide

It has been suggested in a number of investigations that the high vulnerability of mitochondrial DNA to reactive oxygen species and other damaging agents is due to the absence in mitochondria of histones complexed with DNA. In the present study it was shown that DNA-binding proteins of mitochondrial nucleoids were able to shield mitochondrial DNA from X-ray radiation and hydrogen peroxide, as nuclear histones did. Mitochondria, mitochondrial nucleoid proteins, and histones were isolated from mouse liver cells. The degree of damage to or protection of mitochondrial DNA was assessed from the yield of its PCR amplification product. The in vitro experiments demonstrated that mouse mitochondrial DNA, when in complex with mitochondrial nucleoids or nuclear histones, was damaged much less by radiation and/or hydrogen peroxide than in the absence of these proteins and histones. No significant difference between mitochondrial nucleoid proteins and nuclear histones was revealed in their efficiency to protect mitochondrial DNA from the damaging effect of radiation and hydrogen peroxide. It is likely that the nucleoid proteins in the mitochondria shield mitochondrial DNA against the attack of reactive oxygen species, thus significantly decreasing the level of the oxidative damage to mitochondrial DNA.     

Repair of alkali-labile sites within the mitochondrial DNA of RINr 38 cells after exposure to the nitrosourea streptozotocin.

Studies were initiated to investigate whether mechanisms exist within mitochondria to repair damage incurred by mitochondrial DNA after exposure to alkylating toxins. A clonal isolate from a rat insulinoma cell line was utilized to measure the formation and repair of alkali-labile sites within the mitochondrial genome after exposure to the alkylating antibiotic streptozotocin. Alkali-labile sites were formed in mitochondrial DNA in a dose-dependent fashion. Eight hours after exposure to the toxin, 55% of the lesions were removed. The level of repair increased to 70% after 24 h. In comparison, only 46% of N7-methylguanines were removed across the entire cellular genome. These studies demonstrate that streptozotocin causes appreciable mitochondrial DNA damage in a dose-dependent manner and provide the first evidence that a repair mechanism for alkali-labile sites is present within the mitochondrion.     

Mitochondrial Telomerase Protects Cancer Cells from Nuclear DNA Damage and Apoptosis

Most cancer cells express high levels of telomerase and proliferate indefinitely. In addition to its telomere maintenance function, telomerase also has a pro-survival function resulting in an increased resistance against DNA damage and decreased apoptosis induction. However, the molecular mechanisms for this protective function remain elusive and it is unclear whether it is connected to telomere maintenance or is rather a non-telomeric function of the telomerase protein, TERT. It was shown recently that the protein subunit of telomerase can shuttle from the nucleus to the mitochondria upon oxidative stress where it protects mitochondrial function and decreases intracellular oxidative stress. Here we show that endogenous telomerase (TERT protein) shuttles from the nucleus into mitochondria upon oxidative stress in cancer cells and analyzed the nuclear exclusion patterns of endogenous telomerase after treatment with hydrogen peroxide in different cell lines. Cell populations excluded TERT from the nucleus upon oxidative stress in a heterogeneous fashion. We found a significant correlation between nuclear localization of telomerase and high DNA damage, while cells which excluded telomerase from the nucleus displayed no or very low DNA damage. We modeled nuclear and mitochondrial telomerase using organelle specific localization vectors and confirmed that mitochondrial localization of telomerase protects the nucleus from inflicted DNA damage and apoptosis while, in contrast, nuclear localization of telomerase correlated with higher amounts of DNA damage and apoptosis. It is known that nuclear DNA damage can be caused by mitochondrially generated reactive oxygen species (ROS). We demonstrate here that mitochondrial localization of telomerase specifically prevents nuclear DNA damage by decreasing levels of mitochondrial ROS. We suggest that this decrease of oxidative stress might be a possible cause for high stress resistance of cancer cells and could be especially important for cancer stem cells.     

A microgel electrophoresis technique for the direct quantitation of DNA damage and repair in individual fibroblasts cultured on microscope slides

We demonstrate by single-cell microgel electrophoresis that the 2 main techniques, trypsinization and scraping, used to collect normal diploid mammalian cells cultured in monolayer induce DNA damage. To minimize this potential interference with studies on DNA damage and repair, we have standardized the single-cell gel electrophoretic (SCG) technique for the in situ quantitation of DNA single-strand breaks and alkali-labile sites in cultured human-fibroblasts. To demonstrate the utility of this technique, human neonatal foreskin-derived fibroblasts were allowed to attach to frosted microscope slides and then either irradiated with X-rays (25-200 rad) or treated for 1 h with hydrogen peroxide (2.2-140.8 mumoles). Treatment with either agent induced a dose-dependent increase in DNA migration. At equal levels of DNA damage, cell-to-cell variability in DNA migration was more heterogeneous for hydrogen peroxide-treated cells than for X-irradiated cells. A time course study to evaluate the kinetics of DNA repair for X-ray (200 rad)-induced damage indicated that the damage was completely repaired within 2 h. Applications of this technique for in vitro toxicology are discussed.     

Sequence specific damage of DNA induced by reducing sugars.

Reducing sugars induced alkali-labile sites in DNA. The DNA reacted with D-fructose 6-phosphate or D-fructose in the presence of Cu2+ was cleaved by the treatment with aqueous piperidine at 90 degrees C for 30 min. Alkali-labile sites were induced frequently at the pyrimidine residues, especially at the pyrimidine residues in pyrimidine-purine (5'----3') sequences. Transition metal ions such as Cu2+ and oxygen radicals such as hydrogen peroxide were possibly involved in the induction of alkali-labile sites.     

Labile iron pool correlates with iron content in the nucleus and the formation of oxidative DNA damage in mouse lymphoma L5178Y cell lines

Labile iron pool (LIP) constitutes a crossroad of metabolic pathways of iron-containing compounds and is midway between the cellular need for iron, its uptake and storage. In this study we investigated oxidative DNA damage in relation to the labile iron pool in a pair of mouse lymphoma L5178Y (LY) sublines (LY-R and LY-S) differing in sensitivity to hydrogen peroxide. The LY-R cells, which are hydrogen peroxide-sensitive, contain 3 times more labile iron than the hydrogen peroxide-resistant LY-S cells. Using the comet assay, we compared total DNA breakage in the studied cell lines treated with hydrogen peroxide (25 microM for 30 min at 4 degrees C). More DNA damage was found in LY-R cells than in LY-S cells. We also compared the levels of DNA lesions sensitive to specific DNA repair enzymes in both cell lines treated with H(2)O(2). The levels of endonuclease III-sensitive sites and Fapy-DNA glycosylase-sensitive sites were found to be higher in LY-R cells than in LY-S cells. Our data suggest that the sensitivity of LY-R cells to H(2)O(2) is partially caused by the higher yield of oxidative DNA damage, as compared to that in LY-S cells. The critical factor appears to be the availability of transition metal ions that take part in the OH radical-generating Fenton reaction (very likely in the form of LIP).     

L-carnitine enhances resistance to oxidative stress by reducing DNA damage in Ataxia telangiectasia cells

In this study, the modulating effect of L-carnitine on tert-butyl-hydroperoxide-induced DNA damage was compared with that of mannitol, a well known scavenger of hydroxyl radicals, both in normal and Ataxia telangiectasia mutated (ATM)-deficient lymphoblastoid cell lines established from A. telangiectasia (A-T) patients. The alkaline version of the comet assay was employed to measure the frequency of single-strand breaks (SSBs) and alkali-labile sites induced by t-butyl-OOH immediately after treatment and at different recovery times in normal and A-T cell lines, with and without pre-treatment with L-carnitine. In addition, both the yield of induced chromosomal damage and the effect on cell proliferation were evaluated. Our results show that pre-treatment of cells with L-carnitine produced an enhancement of the rate and extent of DNA repair in A-T cell lines at early recovery time; furthermore, in samples pre-treated with L-carnitine a reduction of all types of chromosomal aberration was observed, both in A-T and in wild-type cell lines. The reducing effect of L-carnitine pre-treatment on oxidative DNA damage was more prominent than that of pre-treatment with mannitol. In conclusion, we demonstrated a protective effect of L-carnitine on oxidative stress-induced DNA damage in A-T cells, suggesting its possible role in future pharmacological applications in A-T therapy.     

Formation of modified cleavage termini from the reaction of chromium(V) with DNA

Reaction of a 25 bp oligonucleotide with the high valent chromium complex, bis(2-ethyl-2-hydroxybutyrato)oxochromate(V) (Cr(V)-EHBA) produced both Frank- and alkali-labile strand breaks that were sequence-neutral. Frank strand break formation was found to be O2-dependent while formation of alkali-labile strand breaks were O2-independent. Reaction of Cr(V)-EHBA with the 5'-32P-labeled oligomer under oxygenated conditions formed the modified 3'-terminus, 3'-phosphoglycolate, as well as the 3'-phosphate terminus. Formation of the 3'-phosphoglycolate termini, and the O2 dependence of the reactions were consistent with a mechanism involving abstraction of the C4' hydrogen atom from the deoxyribose moiety of DNA. Identical reactions using the 3'-32P-labeled oligomer yielded only 5'-phosphate termini as assigned by co-migration with Maxam-Gilbert markers. Analogous cleavage profiles and modified termini were observed for the reaction of Cr(V)-EHBA and DNA in the presence of hydrogen peroxide. With the addition of hydrogen peroxide, the DNA cleavage reactions were O2-independent and the level of DNA cleavage was enhanced over that observed with Cr(V)-EHBA alone. These findings suggest an oxidation mechanism whereby a reductive intermediate of the carcinogen chromate, Cr(V), can cause DNA damage that mimics oxygen radical DNA damaging pathways.     

DNA damage in human colonic mucosa cells induced by bleomycin and the protective action of vitamin E

Using the alkaline comet assay, we showed that bleomycin at 0.1-5 microg/ml induced DNA strand breaks and/or alkali-labile sites, measurable as the comet tail moment, in human colonic mucosa cells. This DNA damage was completely repaired during a 120-minute post-treatment incubation of the cells. Post-treatment of the bleomycin-damaged DNA with 3-methyladenine-DNA glycosylase II (AlkA), an enzyme recognizing alkylated bases, gave rise to a significant increase in the extent of DNA damage, indicating that the drug could induce alkylative bases in DNA. We did not observe any change in the comet tail moment in the presence of catalase. Vitamin E ((+)-alpha -tocopherol) decreased DNA damage induced by bleomycin. The results obtained suggest that hydrogen peroxide might not be involved in the formation of DNA lesions induced by bleomycin in the colonic mucosa cells.     

Fluorescence detection of 8-oxoguanine in nuclear and mitochondrial DNA of cultured cells using a recombinant Fab and confocal scanning laser microscopy

The presence of 8-oxoguanine (8-oxoG) in DNA is considered a marker of oxidative stress and DNA damage. We describe a multifluorescence technique to detect the localization of 8-oxoG in both nuclear and mitochondrial DNA using a mouse recombinant Fab 166. The Fab was generated by repertoire cloning and combinatorial phage display, and specifically recognized 8-oxoG in DNA, as determined by competitive enzyme-linked immunosorbent assays (ELISAs). In situ detection of 8-oxoG was accomplished using rat lung epithelial (RLE) cells and human B lymphoblastoid (TK6) cells treated with hydrogen peroxide (H(2)O(2)) or ionizing radiation, respectively. Using confocal scanning laser microscopy, we observed nuclear and perinuclear immunoreactivity of 8-oxoG in control cultures. The simultaneous use of a nuclear DNA stain, propidium iodide, or the mitochondrial dye, MitoTracker (Molecular Probes, Eugene, OR, USA), confirmed that 8-oxoG immunofluorescence occurred in nuclear and mitochondrial DNA. Marked increases in the presence of 8-oxoG in nuclear DNA were apparent after treatment with H(2)O(2) or ionizing radiation. In control experiments, Fab 166 was incubated with 200 microM purified 8-oxodG or with formamidopyrimidine DNA-glycosylase (Fpg) to remove 8-oxoG lesions in DNA. These protocols attenuated both nuclear and mitochondrial staining. We conclude that both nuclear and mitochondrial oxidative DNA damages can be simultaneously detected in situ using immunofluorescence labeling with Fab 166 and confocal microscopy.     

银杏叶提取物对过氧化氢诱导的星形胶质细胞氧化损伤的保护作用

目的 研究银杏叶提取物（EGb761）对H2O2所致星形胶质细胞氧化损伤的保护作用。方法 用不同浓度的EGb761预处理细胞,再加入H2O2,通过噻唑蓝（MTT）实验、线粒体跨膜电位（△ψm）及细胞色素C释放实验、DNA损伤实验及半胱氨酰天冬氨酸特异性蛋白酶-3（Caspase-3）活性测定,观察EGb761对细胞存活率、线粒体膜通透性、DNA氧化损伤及Caspase-3活性的影响。结果 EGb761能明显降低Hz02对星形胶质细胞的氧化损伤,提高细胞的存活率;维持线粒体膜的完整性,抑制跨膜电位的耗散和细胞色素C的释放;抑制Caspase-3的活化和DNA的降解。结论 EGb761具有清除活性氧,减轻H2O2所致星形胶质细胞的氧化损伤,对星形胶质细胞有保护作用。     

Oxidative damage-induced PCNA complex formation is efficient in xeroderma pigmentosum group A but reduced in Cockayne syndrome group B cells.

Proliferating cell nuclear antigen (PCNA), a processivity factor for DNA polymerases delta and epsilon, is essential for both DNA replication and repair. PCNA is required in the resynthesis step of nucleotide excision repair (NER). After UV irradiation, PCNA translocates into an insoluble protein complex, most likely associated with the nuclear matrix. It has not previously been investigated in vivo whether PCNA complex formation also takes place after oxidative stress. In this study, we have examined the involvement of PCNA in the repair of oxidative DNA damage. PCNA complex formation was studied in normal human cells after treatment with hydrogen peroxide, which generates a variety of oxidative DNA lesions. PCNA was detected by two assays, immunofluorescence and western blot analyses. We observed that PCNA redistributes from a soluble to a DNA-bound form during the repair of oxidative DNA damage. PCNA complex formation was analyzed in two human natural mutant cell lines defective in DNA repair: xeroderma pigmentosum group A (XP-A) and Cockayne syndrome group B (CS-B). XP-A cells are defective in overall genome NER while CS-B cells are defective only in the preferential repair of active genes. Immunofluorescent detection of PCNA complex formation was similar in normal and XP-A cells, but was reduced in CS-B cells. Consistent with this observation, western blot analysis in CS-B cells showed a reduction in the ratio of PCNA relocated as compared to normal and XP-A cells. The efficient PCNA complex formation observed in XP-A cells following oxidative damage suggests that formation of PCNA-dependent repair foci may not require the XPA gene product. The reduced PCNA complex formation observed in CS-B cells suggests that these cells are defective in the processing of oxidative DNA damage.     

Radiation-induced DNA base damage detected in individual aerobic and hypoxic cells with endonuclease III and formamidopyrimidine-glycosylase.

X-ray-induced DNA base damage can be detected using endonuclease III and formamidopyrimidine-glycosylase, which create DNA strand breaks at enzyme-sensitive sites. Strand breaks can then be measured with excellent sensitivity using the alkaline comet assay, a single-cell gel electrophoresis method that detects DNA damage in individual cells. In using this approach to measure the oxygen enhancement ratio (OER) for radiation-induced base damage, we observed that the number of enzyme-sensitive sites increased with dose up to 4 Gy in air and 12 Gy in hypoxic WIL2NS cells. After rejoining of radiation-induced strand breaks, base damage was detected more easily after higher doses. The number of radiation-induced enzyme-sensitive sites was similar under both air and nitrogen. Base damage produced by hydrogen peroxide and 4-nitroquinoline-N-oxide (4NQO) was also measured. Results with hydrogen peroxide (20 min at 4 degrees C) were similar to those observed for X rays, indicating that enzyme-sensitive sites could be detected most efficiently when few direct strand breaks were present. Removing DNA-associated proteins before irradiation did not affect the ability to detect base damage. Base damage produced by 4NQO (30 min at 37 degrees C) was readily apparent after treatment with low concentrations of the drug when few 4NQO-induced strand breaks were present, but the detection sensitivity decreased rapidly as direct strand breaks increased after treatment with higher concentrations. We conclude that: (1) the OER for base damage is approximately 1.0, and (2) the presence of direct DNA strand breaks (>2000-4000 per cell) prevents accurate detection of base damage measured as enzyme-sensitive sites with the alkaline comet method.     

Jak2 tyrosine kinase mediates oxidative stress-induced apoptosis in vascular smooth muscle cells

In vascular smooth muscle cells, Jak2 tyrosine kinase becomes activated in response to oxidative stress in the form of hydrogen peroxide. Although it has been postulated that hydrogen peroxide-induced Jak2 activation promotes cell survival, this has never been tested. We therefore examined the role that Jak2 plays in vascular smooth muscle cell apoptosis following hydrogen peroxide treatment. Here, we report that Jak2 tyrosine kinase activation by hydrogen peroxide is required for apoptosis of vascular smooth muscle cells. Upon treatment of primary rat aortic smooth muscle cells with hydrogen peroxide, we observed laddering of genomic DNA and nuclear condensation, both hallmarks of apoptotic cells. However, apoptosis was prevented by either the expression of a dominant negative Jak2 protein or by the Jak2 pharmacological inhibitor AG490. Moreover, expression of the proapoptotic Bax protein was induced following hydrogen peroxide treatment. Again, expression of a dominant negative Jak2 protein or treatment of cells with AG490 prevented this Bax induction. Following Bax induction by hydrogen peroxide, mitochondrial membrane integrity was compromised, and caspase-9 became activated. In contrast, in cells expressing a Jak2 dominant negative we observed that mitochondrial membrane integrity was preserved, and no caspase-9 activation occurred. These data demonstrate that the activation of Jak2 tyrosine kinase by hydrogen peroxide is essential for apoptosis of vascular smooth muscle cells. Furthermore, this report identifies Jak2 as a potential therapeutic target in vascular diseases in which vascular smooth muscle cell apoptosis contributes to pathological progression.     

Mitochondrial DNA integrity may be a determinant of endothelial barrier properties in oxidant-challenged rat lungs

In cultured pulmonary artery endothelial cells and other cell types, overexpression of mt-targeted DNA repair enzymes protects against oxidant-induced mitochondrial DNA (mtDNA) damage and cell death. Whether mtDNA integrity governs functional properties of the endothelium in the intact pulmonary circulation is unknown. Accordingly, the present study used isolated, buffer-perfused rat lungs to determine whether fusion proteins targeting 8-oxoguanine DNA glycosylase 1 (Ogg1) or endonuclease III (Endo III) to mitochondria attenuated mtDNA damage and vascular barrier dysfunction evoked by glucose oxidase (GOX)-generated hydrogen peroxide. We found that both Endo III and Ogg1 fusion proteins accumulated in lung cell mitochondria within 30 min of addition to the perfusion medium. Both constructs prevented GOX-induced increases in the vascular filtration coefficient. Although GOX-induced nuclear DNA damage could not be detected, quantitative Southern blot analysis revealed substantial GOX-induced oxidative mtDNA damage that was prevented by pretreatment with both fusion proteins. The Ogg1 construct also reversed preexisting GOX-induced vascular barrier dysfunction and oxidative mtDNA damage. Collectively, these findings support the ideas that mtDNA is a sentinel molecule governing lung vascular barrier responses to oxidant stress in the intact lung and that the mtDNA repair pathway could be a target for pharmacological intervention in oxidant lung injury.     

Antioxidants Inhibit the Human Cortical Neuron Apoptosis Induced by Hydrogen Peroxide,Tumor Necrosis Factor Alpha,Dopamine and Beta-amyloid Peptide 1-42

Several substances related to the neurodegenerative diseases of Alzheimer and Parkinson, such as hydrogen peroxide, tumor necrosis factor alpha, dopamine and beta-amyloid peptide 1-42, have been shown to induce apoptosis in tumoral cell lines and rat neurons but not in human neurons. Moreover, the role of mitochondria (membrane potential) during neuronal apoptosis is still a matter of debate. We present here, for the first time, in cultured human cortical neurons that the DNA fragmentation induced by these substances was preceded by a decrease of the mitochondrial membrane potential. We have also examined the antiapoptotic effect of the antioxidants glutathione, N -acetyl-cysteine and ascorbic acid. All these antioxidants inhibited the apoptosis induced by hydrogen peroxide, tumor necrosis factor alpha, dopamine and beta-amyloid peptide 1-42, since they were able to inhibit completely the mitochondrial membrane potential depolarization and the DNA fragmentation.