ROS stress in cancer cells and therapeutic implications.

Oxidative Nucleobase Modifications Leading to Strand Scission

There is extensive experimental evidence that oxidative damage permanently occurs to lipids of cellular membranes, proteins, and DNA. In nuclear and mitochondrial DNA, 8-hydroxy-2' -deoxyguanosine (8-OHdG) or 8-oxo-7,8-dihydro-2' -deoxyguanosine (8-oxodG) is one of the predominant forms of free radical-induced oxidative lesions, and has therefore been widely used as a biomarker for oxidative stress and carcinogenesis. Studies showed that urinary 8-OHdG is a good biomarker for risk assessment of various cancers and degenerative diseases. The most widely used method of quantitative analysis is high-performance liquid chromatography (HPLC) with electrochemical detection (EC), gas chromatography-mass spectrometry (GC-MS), and HPLC tandem mass spectrometry. In order to resolve the methodological problems encountered in measuring quantitatively 8-OHdG, the European Standards Committee for Oxidative DNA Damage was set up in 1997 to resolve the artifactual oxidation problems during the procedures of isolation and purification of oxidative DNA products. The biomarker 8-OHdG or 8-oxodG has been a pivotal marker for measuring the effect of endogenous oxidative damage to DNA and as a factor of initiation and promotion of carcinogenesis. The biomarker has been used to estimate the DNA damage in humans after exposure to cancer-causing agents, such as tobacco smoke, asbestos fibers, heavy metals, and polycyclic aromatic hydrocarbons. In recent years, 8-OHdG has been used widely in many studies not only as a biomarker for the measurement of endogenous oxidative DNA damage but also as a risk factor for many diseases including cancer.

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8-hydroxy-2' -deoxyguanosine (8-OHdG): A critical biomarker of oxidative stress and carcinogenesis.

Mechanisms of carcinogenicity are discussed for metals and their compounds, classified as carcinogenic to humans or considered to be carcinogenic to humans: arsenic, antimony, beryllium, cadmium, chromium, cobalt, lead, nickel and vanadium. Physicochemical properties govern uptake, intracellular distribution and binding of metal compounds. Interactions with proteins (e.g., with zinc finger structures) appear to be more relevant for metal carcinogenicity than binding to DNA. In general, metal genotoxicity is caused by indirect mechanisms. In spite of diverse physicochemical properties of metal compounds, three predominant mechanisms emerge: (1) interference with cellular redox regulation and induction of oxidative stress, which may cause oxidative DNA damage or trigger signaling cascades leading to stimulation of cell growth; (2) inhibition of major DNA repair systems resulting in genomic instability and accumulation of critical mutations; (3) deregulation of cell proliferation by induction of signaling pathways or inactivation of growth controls such as tumor suppressor genes. In addition, specific metal compounds exhibit unique mechanisms such as interruption of cell-cell adhesion by cadmium, direct DNA binding of trivalent chromium, and interaction of vanadate with phosphate binding sites of protein phosphatases.

Carcinogenic metal compounds : recent insight into molecular and cellular mechanisms

Expressed genes are scanned by translocating RNA polymerases, which sensitively detect DNA damage and initiate transcription-coupled repair (TCR), a subpathway of nucleotide excision repair that removes lesions from the template DNA strands of actively transcribed genes. Human hereditary diseases that present a deficiency only in TCR are characterized by sunlight sensitivity without enhanced skin cancer. Although multiple gene products are implicated in TCR, we still lack an understanding of the precise signals that can trigger this pathway. Futile cycles of TCR at naturally occurring non-canonical DNA structures might contribute to genomic instability and genetic disease.

Transcription-coupled DNA repair: two decades of progress and surprises

The role of metal ion-DNA interactions in the Fenton reaction-mediated formation of putative intrastrand cross-links, 8-hydroxydeoxyguanosine (8-OHdG) and single- and double-strand breaks was investigated. Salmon sperm DNA and pBluescript K+ plasmid were incubated with hydrogen peroxide and either copper(II), iron(II), or nickel(II), which differ in both their affinity for DNA and in the spectrum of oxidative DNA damage they induce in Fenton reactions. EDTA was included in these incubations according to two different strategies; the first (strategy 1) in which DNA and metal ions were mixed prior to the addition of EDTA, the second (strategy 2) in which EDTA and metal ions were mixed prior to the addition of DNA. The formation of the putative intrastrand cross-links, monitored by 32P-postlabelling, was not affected by the addition of between 10 microM and 5 mM EDTA to the copper(II) Fenton reaction according to strategy 1. In contrast, the level of cross-links declined significantly upon inclusion of 20 microM EDTA and above when added according to strategy 2. Similarly, formation of these lesions declined in the iron(II) Fenton reaction more dramatically upon addition of 5 mM EDTA when added according to strategy 2 compared to strategy 1, while the yield of cross-links formed in the nickel(II) Fenton reaction declined equally with both strategies with up to 25 mM EDTA. The formation of single- and double-strand breaks was investigated in plasmid DNA by agarose gel electrophoresis and subsequent densitometry. The formation of linear DNA in the iron(II) Fenton reaction decreased dramatically upon inclusion of EDTA according to strategy 2, while no such decline was observed using strategy 1. In contrast, the formation of linear DNA in the copper(II) Fenton reaction decreased upon inclusion of EDTA according to both strategies. A decrease in the formation of open-circular DNA was also observed upon inclusion of EDTA according to both strategies; however this decrease occurred at a lower EDTA concentration in strategy 2 (100 microM) compared to strategy 1 (200 microM), and the level of open-circular DNA reached a lower level (8. 5% compared to 24.2%). The nickel(II) Fenton reaction generated only open-circular DNA, and this was completely inhibited upon addition of 25 microM EDTA according to both strategies. There was less formation of 8-OHdG in the copper(II) and iron(II) Fenton reactions when EDTA was added according to strategy 2 than according to strategy 1. These results suggest that a site-specific mechanism is involved in the formation of double-strand breaks and, to a lesser extent, 8-OHdG and the putative intrastrand cross-links, while the formation of single-strand breaks is more likely to involve generation of hydroxyl radicals in solution.

Oxidative DNA damage mediated by copper(II), iron(II) and nickel(II) Fenton reactions: evidence for site-specific mechanisms in the formation of double-strand breaks, 8-hydroxydeoxyguanosine and putative intrastrand cross-links

Generation of putative intrastrand cross-links and strand breaks was investigated in salmon sperm DNA exposed to Fenton-type oxygen radical-generating systems. 32P-Postlabeling analysis of DNA treated with hydrogen peroxide and either copper(II), chromium(VI), cobalt(II), iron(II), nickel(II), or vanadium(III) resulted in the detection of between four and eight radioactive TLC spots that are probably hydroxyl radical-mediated oxidative DNA lesions. The copper Fenton system generated the highest total yield of these DNA lesions (75.6 per 108 nucleotides), followed by cobalt (47.5), nickel (26.2), chromium (25.1), iron (21.7), and vanadium (17.1). Two spots, common to all these Fenton systems, were the major oxidation products in each case. Similar Fenton-type treatment of the purine dinucleotides dApdG and dApdA resulted in products that were chromatographically identical on anion-exchange TLC and on reverse-phase HPLC to the two major products generated in DNA. These results extend our earlier studies sug...

Generation of putative intrastrand cross-links and strand breaks in DNA by transition metal ion-mediated oxygen radical attack.

The formation of 8-hydroxydeoxyguanosine (8-OHdG) and both single- and double-strand breaks in DNA by Fenton-type reactions has been investigated. Salmon sperm DNA was exposed to hydrogen peroxide (50 mM) and one of nine different transition-metal ions (25 microM-1 mM). Modified DNA was isolated and subjected to analysis by liquid chromatography coupled to an electrochemical detection system (LC-ECD), to evaluate the formation of 8-OHdG. The highest yield of 8-OHdG was obtained following treatment of DNA with the chromium(III) Fenton reaction (a maximum of 19 400/10(6) nucleotides), followed by iron(II) (13 600), vanadium(III) (5800), and copper(II) (5200). The chromium(VI) Fenton reaction generated a moderate yield of 8-OHdG (3600/10(6) nucleotides), while the yield obtained in DNA treated with cobalt(II), nickel(II), cadmium(II), and zinc Fenton reactions was not significantly higher than in control incubations of DNA with hydrogen peroxide alone. Similar treatment of the double-stranded plasmid pBluescript K+ with hydrogen peroxide (1 mM) and each transition-metal ion (1-100 microM) followed by quantitative agarose gel electrophoresis demonstrated that open-circle DNA, resulting from single-strand breaks, was generated in Fenton reactions involving all nine metal ions. In contrast, linear DNA was only formed in Fenton reactions involving chromium(III), copper(II), iron(II), and vanadium(III) ions. Formation of linear DNA, under conditions that generated relatively few single-strand breaks, suggests that these four transition-metal ions partake in Fenton reactions to generate true double-strand breaks. Furthermore, the generation of 8-OHdG exhibits a good correlation with the formation of double-strand breaks, suggesting that they arise by a similar mechanism.

Comparison of the Formation of 8-Hydroxy-2‘-deoxyguanosine and Single- and Double-Strand Breaks in DNA Mediated by Fenton Reactions

The most versatile cellular pathway for dealing with a large variety of structurally-unrelated DNA alterations is nucleotide excision repair (NER). Most genomic damage, if not repaired, may contribute to mutagenesis and carcinogenesis, as well as to cellular lethality. There are two subpathways of NER, termed global genomic repair (GGR) and transcription-coupled repair (TCR); While GGR deals with all repairable lesions throughout the genome, TCR is selective for the transcribed DNA strand in expressed genes. Proteins involved in the initial recognition of lesions for GGR as well as for TCR (i.e. RNA polymerase) may sometimes initiate gratuitous repair events in undamaged DNA. However, the damage recognition enzymes for GGR are normally maintained at very low levels unless the cells are genomically stressed. Following UV irradiation in human fibroblasts the efficiency of GGR is upregulated through activation of the p53 tumor suppressor gene. The transactivation role of p53 includes control of expression of the genes, XPC and XPE, which are implicated in GGR but not TCR. These inducible responses are essential for the efficient repair of the most prominent lesion produced by UV, the cyclobutane pyrimidine dimer (CPD). They are also clinically relevant, as we have shown them to operate upon chemical carcinogen DNA damage at levels to which humans are environmentally exposed (e.g. through smoking). Thus, for benzo(a)pyrene (at 10-50 adducts per 10(8) nucleotides) repair was essentially complete within 1 day in p53(+/+) human fibroblasts while no repair was detected within 3 days in p53(-/-) cells. The levels of all four DNA adducts formed by benzo(g)chrysene, also exhibited p53-dependent control in human fibroblasts. However, unlike humans most rodent tissues are deficient in the p53-dependent GGR pathway. Since rodents are used as surrogates for humans in environmental cancer risk assessment it is very important that we determine how they differ from humans with respect to DNA repair and oncogenic responses to environmental genotoxins.

Functional characterization of global genomic DNA repair and its implications for cancer.

The global genomic repair of DNA adducts formed by the human carcinogen (±)- anti- benzo[ a ]pyrene-7,8-diol-9,10-epoxide (BPDE) has been studied by 32P-postlabeling in human fibroblasts in which p53 expression can be regulated. At low BPDE adduct levels (10–50 adducts/108 nucleotides), repair was rapid and essentially complete within 24 h in p53+ cells, whereas no repair was detected within 72 h in similarly treated p53− cells. At 10-fold higher BPDE adduct levels, repair under both conditions was rapid up to 8 h, after which a low level of adducts persisted only in p53− cells. These results demonstrate a dependence on p53 for the efficient repair of BPDE adducts at levels that are relevant to human environmental exposure and, thus, have significant implications for human carcinogenesis.

https://cancerres.aacrjournals.org/content/canres/60/3/517.full.pdf

Daniel R. Lloyd

Papers

Oxidative DNA damage mediated by copper(II), iron(II) and nickel(II) Fenton reactions: evidence for site-specific mechanisms in the formation of double-strand breaks, 8-hydroxydeoxyguanosine and putative intrastrand cross-links

Generation of putative intrastrand cross-links and strand breaks in DNA by transition metal ion-mediated oxygen radical attack.

Comparison of the Formation of 8-Hydroxy-2‘-deoxyguanosine and Single- and Double-Strand Breaks in DNA Mediated by Fenton Reactions

Functional characterization of global genomic DNA repair and its implications for cancer.

p53-dependent global genomic repair of benzo[a]pyrene-7,8-diol-9,10-epoxide adducts in human cells.