Browsing ECNIS - Environmental Cancer Risk, Nutrition and Individual Susceptibility by Subject (MeSH)
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Determination of endogenous and exogenously derived N7-(2-hydroxyethyl)guanine adducts in ethylene oxide-treated rats.Ethylene oxide (EO) is one of the most widely used intermediates in the chemical industry. It is also formed endogenously as a result of cytochrome P450-mediated metabolism of ethylene, which is ubiquitous in the environment. Additionally, ethylene is generated in vivo during normal physiological processes such as methionine oxidation and lipid peroxidation; therefore, humans are continually exposed to EO. EO is classed by the IARC as carcinogenic to humans and reacts with DNA, primarily forming N7-(2-hydroxyethyl)guanine adducts (N7-HEG), which can be used as biomarkers of exposure and potential cancer risk. To assess the risks to humans associated with occupational exposure to low EO concentrations, it is necessary to establish the relative contribution of DNA damage arising from endogenous and exogenously derived EO. Using a newly developed highly sensitive LC-MS/MS assay with selected reaction monitoring that offers a limit of detection of 0.1 fmol of N7-HEG on column, we have established background levels of N7-HEG (1.1-3.5 adducts/10(8) nucleotides) in tissues of rats. Following intraperitoneal administration of a single dose or three daily doses of EO (0.01-1.0 mg/kg), N7-HEG adducts generally increased with dose, except at the lowest concentration where total N7-HEG levels were no different to that detected in control animals, indicating that any increase was negligible as compared to the endogenous damage already present. In the 3 day study, the kinetics of adduct removal were also investigated and in comparing N7-HEG formation in the two studies, DNA damage did not appear to accumulate with repeated administration.
DNA adduct formation and oxidative stress from the carcinogenic urban air pollutant 3-nitrobenzanthrone and its isomer 2-nitrobenzanthrone, in vitro and in vivo.The carcinogenic vehicle emission product 3-nitrobenzanthrone (3-NBA) is known to rearrange in the atmosphere to the isomer 2-nitrobenzanthrone (2-NBA), which exists in 70-fold higher concentration in ambient air. The genotoxicity of 2-NBA and 3-NBA was studied both in vitro (human cell lines A549 and HepG2) and in vivo (F344 female rats intra-tracheally administered 5 mg/kg body weight of 3-NBA) models, using the (32)P-HPLC and the single-cell gel electrophoresis (Comet assay) methods. In vitro, also the parent compound benzanthrone (BA) and the metabolite 3-aminobenzanthrone (3-ABA) were evaluated. 3-NBA gave highest levels of DNA adducts in the two cell lines, but significantly higher in HepG2 (relative adduct level approximately 500 adducts/10(8) normal nucleotides), whereas 2-NBA formed about one-third and one-twentieth of the DNA adduct amount in A549 and HepG2 cells, respectively. 3-ABA formed only minute amounts of DNA adducts and only in the A549 cells, whereas BA did not give rise to any detectable levels. The DNA adduct patterns from 3-NBA were similar between the two model systems, but differed somewhat for 2-NBA. The oxidative stress induced by BA was almost as high as what was observed for 3-NBA and 3-ABA in both cell lines, and 2-NBA induced lowest level of oxidative stress. The oxidative stress and DNA adduct level, in whole blood, was significantly increased by 3-NBA but not by 2-NBA. However, 2-NBA showed similar toxicity to 3-NBA, with respect to DNA adduct formation in vivo, hence it is important to further study 2-NBA as a potential contributor to health risk. While DNA adduct level in the 3-NBA-exposed animals reached a peak around 1 and 2 days after instillation, 2-NBA-treated animals showed a tendency towards a continuing increase at the end of the study.
DNA damage and acute toxicity caused by the urban air pollutant 3-nitrobenzanthrone in rats: characterization of DNA adducts in eight different tissues and organs with synthesized standards.3-Nitrobenzanthrone (3-NBA) is an urban air pollutant and rat lung carcinogen that is among the most potent mutagens yet tested in the Salmonella reversion assay. In the present study, 1 mg 3-NBA was administered orally to female F344 rats and DNA adduct formation was examined in liver, lung, kidney and five sections of the gastrointestinal (GI) tract at 6 hr, and 1, 2, 3, 5, and 10 days after administration. The DNA adduct patterns, analyzed by (32)P-postlabelling followed by HPLC separation, were similar in all tissues and organs. Five of the adduct peaks cochromatographed with synthesized DNA adduct standards. Three of these unequivocally determined standards, dGp-C8-N-ABA, dGp-N2-C2-ABA, and dAp-N6-C2-ABA, were of the nonacetylated type, suggesting that at least part of the pathway for activation of 3-NBA proceeds through O-acetylation of the hydroxylamine intermediate. The two other DNA adduct standards, dGp-C8-C2-N-Ac-ABA, and dGp-N2-C2-N-Ac-ABA, were of the acetylated type, but there was some ambiguity in the characterization of these DNA adducts, since they varied inconsistently between samples and they also aligned with peaks found in controls. At 6 hr after treatment, the level of DNA adducts was highest in glandular stomach (relative adduct labeling (RAL), approximately 70 adducts/10(8) normal nucleotides (NN)); adduct levels in this organ decreased at 24 hr, but increased afterwards. DNA adduct levels in the majority of organs were characterized by an early increase (from 6 hr to 3 days), which was followed by a decrease at 5 days and a maximum level 10 days after administration (RAL approximately 120 adducts/10(8) NN for the lung, kidney and glandular stomach, approximately 80 adducts/10(8) NN for the forestomach and ceacum, and approximately 40 adducts/10(8) NN for the liver, small intestine, and colon). This pattern was consistent with pathological observations during autopsy showing high levels of tissue damage in the GI tract; the tissue damage included hemorrhages, loss of villous surface structure in the small intestine, as well as intestine fragility and oedema of the adipose tissue around the GI-tract. Tissue damage decreased and DNA adduct levels increased at 10 days after administration. These observations suggest that 3-NBA not only exerts acute toxic effects, but that the bioavailability is affected by storage in tissues and later becomes available, resulting in the increased DNA adduct levels at the later time points of collection.
DNA damage in rats after a single oral exposure to diesel exhaust particles.The gastrointestinal route of exposure to particulate matter is important because particles are ingested via contaminated foods and inhaled particles are swallowed when removed from the airways by the mucociliary clearance system. We investigated the effect of an intragastric administration by oral gavage of diesel exhaust particles (DEP) in terms of DNA damage, oxidative stress and DNA repair in colon epithelial cells, liver, and lung of rats. Eight rats per group were exposed to Standard Reference Material 2975 at 0.064 or 0.64 mg/kg bodyweight for 6 and 24 h. Increased levels of 8-oxo-7,8-dihydro-2'-deoxyguanosine lesions were observed at the highest dose after 6 and 24 h in all three organs. 8-Oxo-7,8-dihydro-2'-deoxyguanosine is repaired by oxoguanine DNA glycosylase 1 (OGG1); upregulation of this repair system was observed as elevated pulmonary OGG1 mRNA levels after 24 h at both doses of DEP, but not in the colon and liver. A general response of the antioxidant defence system is further indicated by elevated levels of heme oxygenase 1 mRNA in the liver and lung 24 h after administration. The level of bulky DNA adducts was increased in liver and lung at both doses after 6 and 24h (DNA adducts in colon epithelium were not investigated). In summary, DEP administered via the gastrointestinal tract at low doses relative to ambient exposure generates DNA damage and increase the expression of defence mechanisms in organs such as the lung and liver. The oral exposure route should be taken into account in risk assessment of particulate matter.