Ferric-ion-photosensitized damage to DNA by hydroxyl and non-hydroxyl radical mechanisms

Quantification of Legionella pneumophila by real-time quantitative PCR from samples with humic acid and ferric ion

This study determined and overcame the influences of humic acid (HA) and/or ferric ion (Fe) on quantification of Legionella pneumophila by real-time quantitative PCR (qPCR). Four commonly used DNA isolation methods, QiAamp DNA Mini Kit (Q), Q with Sepharose 4B gel column (Q/G), freeze-thaw/phenol-chloroform lysis (FT-PC), and FT-PC/G, were adopted to isolate L. pneumophila DNA from samples containing Fe alone (0-30 mg l(-1)) or Fe/HA (0/0-3/100 mg l(-1)). Among the four DNA isolation methods, Q removed HA effectively and obtained the greatest DNA yield regardless of Fe and HA concentration (P<0.05). For samples containing Fe (0.3-3 mg l(-1)) or Fe/HA (0.3/10-3/100 mg l(-1)), qPCR inhibition was found in all isolated DNA, especially in those obtained by Q/G and FT-PC/G. DNA dilution at either 10 or 100 folds reduced qPCR inhibition and increased cell recovery (P<0.05). Under 10-fold dilution, Q acquired the highest concentrations of L. pneumophila determined by qPCR. Consequently, Q with post 10-fold dilution is suggested prior to qPCR for quantifying L. pneumophila from water containing Fe (≤ 3 mg l(-1)) or Fe/HA (≤ 3/100 mg l(-1)).

Stannous chloride mediates single strand breaks in plasmid DNA through reactive oxygen species formation

Stannous ion (Sn) has been employed in nuclear medicine and in food industry. We described that Stannous Chloride (SnCl2) inactivation effect in Escherichia coli is mediated by a Fenton-like reaction. The effect of SnCl2 was studied through: (i) the alteration of plasmid topology in neutral and acidic pH by gel electrophoresis; and (ii) the transformation efficiency of an wild type E. coli strain. Treatment of plasmid DNA pUC 9.1 with SnCl2, at pH 7.4, results in DNA single-strand breaks (SSB), in a dose-dependent manner. Addition of sodium benzoate partly inhibited the DNA damage, while EDTA completely abolishes DNA-SSB. Furthermore, the ability of the plasmid to transform E. coli was reduced. At pH 1.3, SnCl2 exerts a protective effect on plasmid against HCI depurination. Our results suggest the generation of ROS, such as *OH by a Fenton-like reaction, close to the site of the lesions due to a possible complexation of stannous ion to DNA.

Central Role of Ferrous/Ferric Iron in the Ultraviolet B Irradiation-mediated Signaling Pathway Leading to Increased Interstitial Collagenase (Matrix-degrading Metalloprotease (MMP)-1) and Stromelysin-1 (MMP-3) mRNA Levels in Cultured Human Dermal Fibroblasts

Reactive oxygen species (ROS) are important second messengers for the induction of several genes in a variety of physiological and pathological conditions. Ultraviolet B (UVB) irradiation has recently been shown to generate lipid peroxidation products and hydroxyl radicals (HO.) with detrimental long term effects like cancer formation and premature aging of the skin. Here, we addressed the question of whether ferric/ferrous iron via the generation of ROS may mediate the UVB response, finally leading to connective tissue degradation, a hallmark in carcinogenesis and aging. Therefore, we studied the involvement of iron and ROS in the modulation of Jun N-terminal kinase 2 (JNK2) activity, c-jun and c-fos mRNA levels, key signaling steps in the transcriptional control of matrix-degrading metalloprotease (MMP)-1/interstitial collagenase and MMP-3/stromelysin-1 after UVB irradiation of human dermal fibroblasts in vitro. The iron-driven generation of lipid peroxides and hydroxyl radicals were identified as early events in the downstream signaling pathway of the UVB response leading to a 15-fold increase in JNK2 activity, a 3.5-fold increase in c-jun, to a 6-fold increase in MMP-1, and a 3.8-fold increase in MMP-3 mRNA levels, while virtually no alteration of c-fos mRNA levels were observed. Diminished generation of reactive oxygen species resulted in a significant reduction of JNK2 activity, c-jun, MMP-1, and MMP-3 mRNA levels after UVB irradiation compared with UVB-irradiated cells. Collectively, we have identified the iron-driven Fenton reaction and lipid peroxidation as possible central mechanisms underlying signal transduction of the UVB response.

Reactive oxygen species-induced DNA damage and its modification: a chemical investigation

The main purpose of this study was to determine whether well-known reactive oxygen species (ROS)-generating agents can induce DNA damage in a simple chemical system with or without Fenton reaction components (iron and reducing agents), and to explore whether antioxidants which normally exist in the cellular environment can modify such damage, i.e. to determine chemical reactions of relevance to biological systems. A neutral electrophoresis technique was used to investigate DNA double stranded breaks (DSBs) caused by chemical treatments of lambda-DNA in eppendorf tubes by various ROS-generating compounds and the degree of DNA damage was categorised by analysis of enhanced digital images. Double strand breaks were induced by hydroquinone (HQ), benzoquinone (BQ), benzenetriol (BT), hydrogen peroxide (H2O2), bleomycin (BLM) and sodium ascorbate (Vit C). DNA damage was modulated by various agents including catalase (CAT), superoxide dismutase (SOD), desferoxamine mesylate (DFO), ferrous chloride (FeCl2), reduced glutathione (GSH), trolox, silymarin and myricetin. Individual chemicals (except BLM) at the concentration of 1 mM did not induce large numbers of DSBs without iron [Fe(II) or Fe(III) at 25 microM]. GSH enhanced the damaging effect of HQ, BT and Vit C, did not alter the non-damaging effect of H2O2, but had a small protective effect on BLM. When compared with the non-enzyme protein, bovine serum albumin (BSA), SOD had a protective effect against BT, H2O2 and BLM; in the presence of GSH, SOD diminished the effect of HQ, BQ and Vit C but enhanced the effect of BT, H2O2 and BLM. With both GSH and Fe and compared with BSA, SOD enhanced the effect of HQ, BQ and BLM, ameliorated the effect of H2O2, and did not affect the others. CAT showed a protective effect for almost all examined compounds, but had little effect on BLM. With GSH alone, DFO enhanced the effect of HQ, BQ, H2O2 and ameliorated the effect of BT, BLM and Vit C and trolox was largely protective. With GSH and Fe, DFO was protective for all compounds except doxorubicin (Dox), trolox was protective for all compounds except Dox and BLM, silymarin was protective except that it had little effect on BLM and Dox, but myricetin did not show any protective effect. In conclusion, the results from the present study have further highlighted the adverse potential of reducing agents and redox cycling agents, and also the need for a cautious view of antioxidants.

Immunogenicity of DNA damaged by reactive oxygen species--implications for anti-DNA antibodies in lupus

Reactive oxygen species (ROS) are implicated in the inflammatory, autoimmune, connective tissue disease, systemic lupus erythematosus (SLE), particularly in respect of processes leading to the formation of pathological anti-DNA antibodies. Exposure to ROS increases the antigenicity of DNA for SLE antibodies, but data on the immunogenicity of ROS-DNA are not conclusive. In this study, we have examined the immunogenicity in rabbits, of DNA modified by three hydroxyl radical generating systems. Additionally, we investigated the antigenicity of UVA, UVB, and UVC irradiated DNA for lupus anti-DNA antibodies. Modification of DNA by both ROS and far UV dramatically increased its immunogenicity; the Fe2+ and H2O2 system resulted in antibodies that recognized both native and modified DNA. In our ELISA system, none of the UV antigens showed any antigenicity above native DNA for SLE sera. The data suggested that different profiles of antigenicity and immunogenicity arise dependent on the method of ROS production, but also that ROS-DNA may be a factor in antigen-driven immune complex formation in SLE.

Role of enterobactin and intracellular iron in cell lethality during near-UV irradiation in Escherichia coli

In Escherichia coli, fur mutants that constitutively express their native iron chelating agent, enterobactin, are significantly more sensitive to near-UV radiation (NUV) than wild type, An entA mutant, which is incapable of synthesizing enterobactin, is equal to wild type in resistance to NUV irradiation. However, the addition of Fe+3 enterobactin but not AI+3 enterobactin to entA cell suspensions just prior to irradiation results in an increased sensitivity to NUV irradiation. A fes mutant, which is unable to reduce and release iron from enterobactin, is significantly more sensitive to NUV irradiation than wild type. The addition of nontoxic levels of H2O2 (5 microM) just prior to irradiation significantly increases sensitivity of both fur and fes mutants. These results suggest that one mechanism by which NUV irradiation leads to cell lethality is by creating a transient iron overload, producing very favorable conditions for the production of highly deleterious free radicals through a variety of mechanisms that lead to oxidative stress and DNA damage including lethal and mutagenic lesions. These results are consistent with the hypothesis that enterobactin is an endogenous chromophore for NUV and contributes to cell lethality via the destruction of its ligand, releasing Fe+2 into the cytoplasm to catalyze the production of highly reactive hydroxyl radicals and other toxic oxygen species via the Haber-Weiss reaction.

Both UVA and UVB induce cytoskeleton-dependent surface blebbing in epidermoid cells

Data on the morphological changes induced by UVA or UVB irradiation of A431 epidermoid cells in culture are presented. After irradiation with different doses of UVB (120-2400 J m-2) or UVA (10(4)-10(5) J m-2), the membrane and cytoskeleton of these cells were analysed by immunofluorescence and scanning electron microscopy at different times after exposure (0-48 h). Both UVA and UVB alter microtubules and microfilaments and surface blebs are formed after UV irradiation. In particular, UVB induces multiple small blebs on the cells, while UVA induces one single large bleb on each cell. Since cytoskeletal damage and surface blebbing of this type are also induced by oxidative stress, these results add to the body of evidence indicating that UV radiation is capable of pro-oxidant behaviour. Specifically, the morphological changes described in this paper are reminiscent of the modifications which accompany epidermal keratinocytes during their transformation to sunburn cells after UV irradiation. The physiological implications of these findings are discussed.

The complexity of DNA damage: relevance to biological consequences

Ionizing radiation causes both singly and multiply damaged sites in DNA when the range of radical migration is limited by the presence of hydroxyl radical scavengers (e.g. within cells). Multiply damaged sites are considered to be more biologically relevant because of the challenges they present to cellular repair mechanisms. These sites occur in the form of DNA double-strand breaks (dsb) but also as other multiple damages that can be converted to dsb during attempted repair. The presence of a dsb can lead to loss of base sequence information and/or can permit the two ends of a break to separate and rejoin with the wrong partner. (Multiply damaged sites may also be the biologically relevant type of damage caused by other agents, such as UVA, B and/or C light, and some antitumour antibiotics.) The quantitative data available from radiation studies of DNA are shown to support the proposed mechanisms for the production of complex damage in cellular DNA, i.e. via scavengable and non-scavengable mechanisms. The yields of complex damages can in turn be used to support the conclusion that cellular mutations are a consequence of the presence of these damages within a gene. Literature data are used to support these statements and to develop overall mechanisms connecting the production of primary species to the production of biologically relevant damages. The consequences of the LET of the radiation on multiplicity of damage are discussed and suggestions made for the cause of the decrease of the oxygen enhancement ratio as the LET increases.

Cu(II) sensitizes pBR322 plasmid DNA to inactivation by UV-B (280-315 nm)

Copper(II), in the presence of UV-B radiation (280-315 nm), can generate single-strand breaks in the sugar-phosphate backbone of pBR322 plasmid DNA. A low level of single-strand backbone breaks occurs in the presence of Cu(II) alone, but UV-B irradiation increases the rate by the more than 100-fold. Concomitant with the damage to the DNA backbone is a loss of transforming activity. Oxygen is required for generation of the single-strand breaks but not for the loss of transforming activity. A DNA glycosylase (Fpg), which participates in the repair of certain DNA nitrogenous base damage, does not repair plasmid DNA damaged by Cu(II). The hydroxyl radical scavenging compound DMSO is only somewhat effective at protecting the physical and biological properties of the DNA. These results with Cu(II) are compared to those obtained previously with pBR322 plasmid DNA in the presence of Fe(III) and UV-A.