Effects of three epoxides--ethylene oxide, propylene oxide and epichlorohydrin--on cell cycle progression and cell death in human diploid fibroblasts

Ethylene oxide (EtO), propylene oxide (PO), and epichlorohydrin (ECH) strongly influenced the G1/S progression in human diploid fibroblasts, VH-10. However, these epoxides did not affect substantially the G2/M progression. It was found that G1 arrest is induced by these epoxides 6-18 h after the treatment at doses above 5, 3, and 0.5 mMh for EtO, PO, and ECH, respectively. An inhibitory effect on DNA synthesis was also demonstrated at the same doses within the same time interval. On the contrary, the epoxides transiently stimulated DNA synthesis 3-18 h after the treatment with the lower doses (below 5, 3, and 0.5 mMh for EtO, PO, and ECH, respectively). This effect was manifested both as an elevated rate of DNA synthesis and as an increase in the number of cells in S-phase. Among the three studied epoxides EtO was the most effective one: the increases of the rate of DNA synthesis and of cells in S-phase were 35 and 55%, respectively. All the epoxides tested induced significant decrease of intracellular level of reduced glutathione (GSH) shortly after cell exposure. While low and moderate doses induced a transient decrease in GSH level the high doses induced its irreversible depletion. The extensive GSH depletion was related to cell death. Morphological examination of cell nuclei indicated that epoxide-treated cells die via necrosis. This conclusion is supported by the lack of such features of the apoptosis as chromatin condensation and the occurrence of so called 'apoptotic bodies'. The absence of nucleosomal fragmentation of DNA and an increase of the permeability of the plasma membrane after the epoxide treatment also indicated a necrotic form of cell death. ECH is about ten times more toxic than the two other epoxides, and it causes almost 100% necrosis at dose of 3.0 mMh.     

DNA damage induced by gamma-radiation in combination with ethylene oxide or propylene oxide in human fibroblasts

To estimate the effects of interaction of gamma-rays and an epoxide, cell survival and induction of DNA double-strand breaks (DSBs) following combined exposure to ionizing radiation and ethylene oxide (EtO) or propylene oxide (PO) were studied in human fibroblasts. Two treatment protocols were applied: (a) the cells were pre-exposed to different doses of gamma-rays and then treated with epoxide, and (b) the cells were pretreated with epoxide and then exposed to different doses of gamma-rays. Here we show that order of the treatment did not play a role in cell survival and that the effect of combined exposure on cell killing was additive for both epoxides. As to DNA DSBs induction, however, a difference dependent upon the order of the treatment was observed. While EtO or PO treatment followed by gamma-rays exposure led to an increased number of DSBs at higher gamma-ray doses (2-3 Gy), no significant increase of DSBs was detected after the opposite order of the treatment (gamma-ray exposure followed by EtO or PO treatment).     

The micronucleus assay in human exfoliated cells of the nose and mouth: application to occupational exposures to chromic acid and ethylene oxide

We have applied the micronucleus (MN) assay to exfoliated cells of buccal and nasal cavities to monitor the genotoxic risk in a group of workers exposed to chromic acid and in another group exposed to ethylene oxide (EtO). The first group comprised 16 subjects working in a 'hard' type chrome-plating factory showing increased chromium absorption and chromium-induced rhinopathy. The second group comprised 9 subjects working in a sterilization unit, exposed to EtO concentrations lower than 0.38 ppm as timed weighted average (TWA) for a working shift; 3 of them were involved in a acute exposure too. The frequency of MN in buccal mucosa was within the norm for exposure both to chromium and to EtO. The MN frequency in nasal mucosa was not altered in chromium platers, whereas a significant increase (p less than 0.01) in MN was found in 2 out of 3 subjects involved in the accidental EtO leakage and a non-significant increase in MN was found in the group chronically exposed to EtO.     

Genotoxic effects of ethylene oxide and propylene oxide: a comparative study

The two alkylating agents ethylene oxide (EO) and propylene oxide (PO) were compared for genotoxic effectiveness in various test systems. The study was undertaken partly to shed light on the difference between the compounds found after chronic exposure of monkeys (Lynch et al., 1984) where EO but not PO was able to induce SCE and chromosomal aberrations. In the present study EO was found to be 5–10 times more effective than PO with respect to gene conversion and reverse mutation in Saccharomyces cerevisiae D7 and sister-chromatid conversion in S. cerevisiae RS112. In contrast, the abilities of the two compounds to induce point mutation in S. typhimurium strains and SCE in human lymphocytes were approximately equal. One possible cause of EO being more effective than PO in certain respects, discussed on the basis of inference from earlier studies, is an expected difference in ability to cause strand breaks via alkylation of DNA-phosphate groups.     

Effects of ethylene oxide on soil microbial content and some soil chemical characteristics

The effects of ethylene oxide (EtO) on survival of soil microflora and on selected chemical properties of a sandy-loam soil were examined. Soil sterilization was achieved after 8 hours exposure to EtO. Ethylene oxide treatment increased soil pH and organic matter content. Extractable Mn and Fe slightly increased whereas P content decreased. Total N was not affected by the treatment.     

Unscheduled DNA synthesis correlated to alkylation of hemoglobin in individuals occupationally exposed to propylene oxide

Exposure to propylene oxide was determined previously by the degree of alkylation of hemoglobin measured on the histidine residue as N-3-(2-hydroxypropyl) histidine, using blood samples from 8 propylene oxide-exposed employees and 13 unexposed referents. Mononuclear leukocytes isolated from the same blood samples were used to quantify DNA repair proficiency following an in vitro challenge with the carcinogen, N-acetoxy-2-acetylamino-fluorene. Decreases in the DNA repair proficiency index correlated significantly to in vivo exposure levels to propylene oxide (r = –0.64, p <0.03). These data suggest a possible short-term biological assay for monitoring the in vivo genotoxic effects of propylene oxide exposure in the human population.Abbreviations EO ethylene oxide - NA-AAF N-acetoxy-2-acetylaminofluorene - HOPrHIS N-3-(2-hydroxypropyl) histidine - PO propylene oxide - UDS unscheduled DNA synthesis     

Toxicity potential of residual ethylene oxide on fresh or frozen embryos maintained in plastic straws

The toxic effects of residual ethylene oxide (EtO), a frequently used gas-sterilant, on embryos either frozen for long-term purposes or stored acutely for 30 min to 9 hr in a fresh condition in 0.25-ml straw containers were evaluated. In Experiment 1, fresh embryos were frozen (using conventional technology) in straws previously aerated for 0 hr to 8 mo after EtO sterilization. With the exception of the 8-mo group in which survival and quality ratings were depressed, embryo viability was not affected significantly by short-term prefreeze and post-thaw exposure to EtO residues. Experiment 2 was conducted to analyze the influence of prefreeze exposure to EtO residues on embryo development in vitro for embryos temporarily stored in previously sterilized straws aerated for different intervals. Compared to non-EtO-sterilized control straws, the development, quality, and viability of embryos exposed to EtO-treated straws were compromised (p < 0.05) as the aeration interval decreased and the exposure interval increased. The combined results of both experiments indicate that EtO-treated straws can be used to cryopreserve gametes efficiently, but only if the aeration interval is ≥72 hr and the prefreeze duration of exposure is ?3 hr.     

Measurement of DNA breakage in spermiogenic germ-cell stages of mice exposed to ethylene oxide, using an alkaline elution procedure

DNA breakage in spermiogenic stages of the mouse was studied after exposure to ethylene oxide (EtO), using an alkaline elution technique. At daily intervals over a 23-day period following i.p. injection of 100 mg EtO/kg, mature spermatozoa were recovered from treated ([3H]dThd-labeled) and control ([14C]dThd-labeled) animals, lysed together on polycarbonate filters, and the DNA was eluted with a high pH (12.2) buffer. Elution of germ-cell DNA from EtO-exposed animals increased (more DNA strand breaks) in stages sensitive to the genetic effects of EtO (late spermatids to early spermatozoa). The stage-related pattern of EtO-induced DNA breakage paralleled the pattern of sperm alkylation and protamine alkylation found to be produced by EtO in an earlier study (Sega and Owens, 1987). At 9 days posttreatment (sperm sampled were in late-spermatid stages at the time of EtO exposure) the amount of sperm DNA eluted did not change significantly over a pH range of 11.6-12.8, indicating that, at the time of assay, DNA breaks were already present in the sperm.     

Inhalation exposure-rate of ethylene oxide affects the level of DNA breakage and unscheduled DNA synthesis in spermiogenic stages of the mouse

The effect of ethylene oxide (EtO) inhalation-exposure rate on the induction of DNA breakage in late spermatids and on unscheduled DNA synthesis (UDS) in early spermatids was studied. The exposures were 450 parts per million (ppm) for 4 h, 900 ppm for 2 h, and 1800 ppm for 1 h. Thus, the total exposure was always 1800 ppm-h. Both DNA breakage and UDS were found to increase by a factor of approximately 3 in going from the low to high EtO concentration, suggesting that the molecular dose of EtO to the testis had increased by a similar factor. Our results are consistent with the EtO exposure-rate effect found by Generoso et al. (1986) for induction of dominant-lethal mutations in late spermatids and early spermatozoa.     

Protective effect of low doses in mutagenesis with ethylene oxide in E. coli

The influence of pre-exposure to low doses of ethylene oxide (EtO) on the frequency of leu+ revertants in the E. coli strain, WU36-10, and its excision-repair-deficient mutant, WU36-10-89, after treatment with high doses of EtO, was studied. Low doses had an adaptive effect in both strains with respect to high doses of EtO which was manifested by a decreased number of revertants and lower lethality.     

Mutagenic activity of ethylene oxide and propylene oxide under XPG proficient and deficient conditions in relation to N-7-(2-hydroxyalkyl)guanine levels in Drosophila

Ethylene oxide (EO) and propylene oxide (PO) are direct acting mutagens with high Swain-Scott s-values, which indicate that they react preferentially with ring nitrogens in the DNA. We have previously described that in the X-linked recessive lethal (RL) assay in Drosophila postmeiotic male germ cells EO is, per unit exposure dose, 5-10 times more mutagenic than PO. Furthermore, at the higher dose range of EO tested, 62.5-1000 ppm, up to 20-fold enhanced mutation rates were measured in the absence of maternal nucleotide excision repair (NER) compared to repair proficient conditions. The lower dose range of EO tested, 2-7.8 ppm, still produced a small increased mutation rate but without a significant elevated effect when the NER system is being suppressed. The lowest dose of PO tested, 15.6 ppm, produced only in NER- condition an increased mutation rate. The aim of the present study was to compare the mutagenic effect of EO and PO in the RL assay under XPG proficient and deficient conditions with the formation of N-7-(2-hydroxyethyl)guanine (7-HEG) and N-7-(2-hydroxypropyl)guanine (7-HPG), respectively, the major DNA adducts formed. The formation of 7-HEG and 7-HPG was investigated in Drosophila males exposed to EO and PO as a measure of internal dose for exposures ranging from 2 to 1000 or 2000 ppm, respectively, for 24h. Analysis of 7-HEG and 7-HPG, using a highly sensitive 32P-postlabelling assay, showed a linear increase of adduct levels over the entire dose range. The non-linear dose-response relationship for mutations could therefore not be explained by a reduced inhalation or increased detoxification at higher exposure levels. In analogy with the four times higher reactivity of EO the level of N-7-guanine alkylation per ppm was for EO 3.5-fold higher than that for PO. Per unit N-7-guanine alkylation EO was found to be slightly more mutagenic than PO, whereas PO was the more potent clastogenic agent. While this research has not identified the DNA lesions that cause the increase in repair deficient flies, it supports the hypothesis that efficient error-free repair of some N-alkylation products can explain why these agents tend to be weakly genotoxic or even inactive in repair-competent (premeiotic) germ cells of the mouse and the Drosophila fly.     

Protein-resistant silicones: incorporation of poly(ethylene oxide) via siloxane tethers

Silicones with enhanced protein resistance were prepared by introducing poly(ethylene oxide) (PEO) chains via siloxane tethers (a-c) of varying lengths. Three unique ambifunctional molecules (a-c) having the general formula alpha-(EtO)3Si(CH2)2-oligodimethylsiloxanen-block-poly(ethylene oxide)8-OCH3 (n = 0 (a), 4, (b), and 13 (c)) were prepared via regioselective Rh-catalyzed hydrosilylation. Nine films were subsequently produced by the H3PO4-catalyzed sol-gel cross-linking of a-c each with alpha,omega-bis(Si-OH)polydimethylsiloxane (P, Mn = 3000 g/mol) in varying ratios (1:1, 1:2, and 2:3 molar ratio a, b, or c to P). Films prepared with a 2:3 molar ratio (a-c to P) contained the least amount of un-cross-linked materials, which may migrate to the film surface. For this set of films, surface hydrophilicity and protein resistance increased with siloxane tether length (a-c). These results indicate that PEO was more effectively mobilized to the surface if incorporated into silicones via longer siloxane tethers.     

Extending the alkene substrate range of vinyl chloride utilizing Nocardioides sp. strain JS614 with ethene oxide

Nocardioides sp. strain JS614 grows on the C₂ alkenes ethene (Eth), vinyl chloride, and vinyl fluoride as sole carbon sources. The presence of 400–800 μM ethene oxide (EtO) extended the growth substrate range to propene (C₃) and butene (C₄). Propene-dependent growth of JS614 was CO₂ dependent and was prevented by the carboxylase/reductase inhibitor 2-bromoethanesulfonic acid, sodium salt (BES), while growth on Eth was not CO₂ dependent or BES sensitive. Although unable to promote growth, both propene and propene oxide (PrO)-induced expression of the genes encoding the alpha subunit of alkene monooxygenase (etnC) and epoxyethane CoM transferase (etnE) to similar levels as did Eth and EtO. Propene was transformed by Eth-grown and propene-grown/EtO-induced JS614 to PrO at a rate 4.2 times faster than PrO was consumed. As a result PrO accumulated in growth medium to 900 μM during EtO-induced growth on propene. PrO (50–100 μM) exerted inhibitory effects on growth of JS614 on both acetate and Eth, and on EtO-induced growth on Eth. However, higher EtO concentrations (300–400 μM) overcame the negative effects of PrO on Eth-dependent growth.     

DNA adducts: effects of low exposure to ethylene oxide, vinyl chloride and butadiene

Dose-response relationships of genotoxic agents differ greatly depending on the agent and the endpoint being evaluated. Simple conclusions that genotoxic effects are linear cannot be applied universally. The shape of the molecular dose of DNA adducts varies from linear, to supralinear, to sublinear depending on metabolic activation and detoxication, and repair of individual types of DNA adducts. For mutagenesis and other genotoxicity endpoints, the dose-response reflects the molecular dose of each type of DNA adduct, cell proliferation, as well as endogenous factors that lead to mutagenesis such as the formation and repair of endogenous DNA adducts. These same factors are important when interpreting the shape of dose-response data for carcinogenesis of genotoxic agents, however, tumor background variability adds additional complexity. Endogenously formed DNA adducts may be identical to those formed by chemicals, as in the case of vinyl chloride and ethylene oxide, or they may be those associated with oxidative stress. Data presented in this paper demonstrate that the exogenous number of adducts induced by 5 days of exposure to 10 ppm vinyl chloride is only 2. 2-fold greater than that present as a steady-state amount in unexposed control rats. Similar data are shown for ethylene oxide. Extremely sensitive methods have been developed for measuring the molecular dose of genotoxins. These methods can detect DNA adducts as low as 1 per 10(9) to 10(10). However, in view of the high number of endogenous DNA adducts that are present in all cells, it is unlikely that causal relationships can be attributed to very low numbers of such DNA adducts. Effects of both exogenous and endogenous DNA adducts need to be factored into the interpretation of chemical exposures.     

Ethylene oxide: evaluation of genotoxicity data and an exploratory assessment of genetic risk

A risk estimate of the heritable effects of ethylene oxide exposure, using the parallelogram approach, as suggested by Frits Sobels, is described. The approach is based on available data on the ethylene oxide-induced responses for the same genetic endpoint in somatic cells of both laboratory animals and humans, and for germ cell mutations in the same laboratory animal. Human germ cell effects are estimated. The available data sets for this approach were evaluated. We consider this as complementary to the genetic risk assessment carried out by U.S. EPA scientists, in which the risk from heritable (reciprocal) translocations induced by ethylene oxide was estimated. In the present study we restricted our assessment to dominant mutations. The sensitivity factor relating mouse to man was based on ethylene oxide-induced HPRT mutant frequencies in lymphocytes in vivo. From this comparison, it could be concluded that occupational exposure for 1 year to 1 ppm ethylene oxide would lead to a risk of a dominantly inherited disease in the offspring of 4 × 10⁻⁴ above the background level. The uncertainty interval of this figure is quite large (0.6–28) × 10⁻⁴. The values are compatible with the existing estimates of the corresponding risk from exposure to low LET radiation when the genotoxic potency ratio of ethylene oxide and radiation is considered. This risk estimation approach has allowed us to identify additional data that are required for a more complete risk estimation of the heritable effects of ethylene oxide, or indeed any mutagenic chemical.     

Dual effect of nitric oxide on phenoloxidase-mediated melanization

The study has demonstrated a dual effect of nitric oxide on phenoloxidase (PO)-mediated DOPA oxidation and melanization process. NO generated at low rates proportionally increased in PO-mediated DOPA oxidation. Competitive PO inhibitor, phenylthiourea, resulted in significant inhibition of NO-mediated DOPA oxidation. Further analysis using fluorescent and EPR methods demonstrated that the effect of NO on DOPA oxidation is explained by oxidation of NO to NO₂ at the active site of PO followed by oxidation of DOPA by NO₂. On the contrary, the bolus addition of NO gas solution resulted in a significant decrease in observed PO activity. Similar dose-dependent effect of NO was observed for the insect’s haemocytes quantified as percentage of melanized cells after treatment with nitric oxide. In conclusion, the results of the study suggest that NO may have a significant regulatory role on melanization process in invertebrates as well as in human and result in protective or damaging effects.     

Lack of additive effect in mutagenesis of E. coli by UV-light and ethylene oxide

The interaction of UV-irradiation and ethylene oxide (EtO) on forward mutation frequencies in the lacI gene of E. coli strains 3835 and 3951 and on the frequency of leu+ revertants in E. coli WU36-10-89 were studied. Pre-exposure to low doses of UV-light with the following treatment by low and intermediate doses of EtO showed lack of additive effect in the mutagenic response in all strains studied. The number of mutants actually obtained in the respective experiments was much lower than the additive model predicted.     

Biologic markers in ethylene oxide-exposed workers and controls

Ethylene oxide (EtO) is an alkylating agent and a model direct-acting mutagen and carcinogen. This study has evaluated a panel of biologic markers including EtO-hemoglobin adducts (EtO-Hb), sister-chromatid exchanges (SCEs), micronuclei, chromosomal aberrations (CAs), DNA single-strand breaks (SSB) and an index of DNA repair (ratio of UDS to NA-AAF-DNA binding) in the peripheral blood cells of 34 workers at a sterilization unit of a large university hospital and 23 controls working in the university library. Comprehensive environmental histories were obtained on each subject including detailed occupational and smoking histories. Industrial hygiene data obtained prior to the study and personal monitoring during the 8 years preceding the study showed that workers were subject to low-level exposure near or below the current Occupational Safety and Health Administration (OSHA) standard of 1 ppm (TWA). Personal monitoring data obtained during 2 weeks prior to blood sampling were uniformly less than 0.3 ppm (TWA). After adjusting for smoking, EtO workplace exposure was significantly (p less than 0.001) associated with EtO-Hb (a carcinogen-protein adduct) and 2 measures of SCEs [the average number of SCEs/cell (SCE50) and the number of high frequency cells (SCEHFC)]. There was an apparent suppression of DNA repair capacity in EtO-exposed individuals as measured by the DNA repair index; i.e., the ratio of unscheduled DNA synthesis (UDS) and NA-AAF-DNA binding (p less than 0.01). No association of DNA repair index with smoking was found. Another important finding of this study is the highly significant correlation between EtO-Hb adduct levels and SCEHFC (p less than 0.01) and SCEs (p less than 0.02) which provides evidence of a direct link between a marker of biologically effective dose and markers of genotoxic response. In contrast, micronuclei, CAs and SSBs were not significantly elevated in the workers. The activity of the u-isoenzyme of glutathione-S-transferase (GT) was measured as a possible genetic marker of susceptibility and a modulator of biomarker formation. However, possibly because of confounding by age, no significant relationships were found between GT and any of the exposure-related markers by ANOVA or among other independent variables by regression. This study demonstrates significant effects of low-level EtO exposure, independent of smoking history, near or below 1 ppm on multiple biomarkers and suggests that the current OSHA standard may not be adequately protective. Previously described effects of smoking on EtO-Hb adducts, SCEs and SCEHFC were also seen in this study.(ABSTRACT TRUNCATED AT 400 WORDS)     

Increased genotoxic susceptibility of breast epithelial cells to ethylene oxide

This study was carried out with the aim of elucidating the organ-specific effects of ethylene oxide in comparison with the sensitivity of cells from different tissues. An increased incidence of leukemia and lymphoma has been observed in workers exposed to ethylene oxide. However, contradictory findings exist regarding its ability to induce other tumor types, such as breast cancer. We characterized the genotoxicity of ethylene oxide by means of the alkaline version of comet assay in in vitro systems, in order to investigate the hypothesized role of this substance in the development of breast cancer. For this study, we used primary and secondary cultures of lymphoblasts (well-known target cells of the genotoxicity of ethylene oxide), breast epithelial cells (hypothesized target), peripheral blood lymphocytes (cells commonly used in biomonitoring), and of keratinocytes and cervical epithelial cells. DNA damage was measured and expressed as tail DNA, tail length, and tail moment. In the concentration range 0-100 microM, ethylene oxide induced a dose-dependent increase of DNA damage in the investigated cell types without notable cytotoxicity. A statistically significant increase of DNA damage could be observed after treatment with 20 microM ethylene oxide in lymphoblasts (51% increase of tail moment over the background), breast epithelial cells (26% increase) and peripheral lymphocytes (71% increase). In keratinocytes (5% increase) and cervical epithelial cells (5% increase) significant DNA damage could not be detected at this dose, but at higher concentrations (50-100 microM), such an increase was observed. These results are indicative of an increased sensitivity of breast epithelial cells towards genotoxic insults of ethylene oxide. Our observations provide additional data to evaluate the hypothesis that exposure to ethylene oxide may play a role in breast cancer, and the findings may contribute to the development of screening tests for monitoring an early response to genotoxic insults in occupational settings.     

Effect of deficiency in excision repair and umuC function on the mutagenicity with ethylene oxide in the lacI gene of E. coli

The influence of uvrB and umuC genes on the induction of lacI- mutants and nonsense mutants by ethylene oxide (EtO) in the lacI gene of E. coli was studied. The uvrB mutation was characterized by much higher mutation frequencies. In contrast the umuC mutation does not significantly affect the induction kinetics. Thus mutation by EtO is enhanced by the lack of excision repair but not influenced by error-prone repair.