William P. Watson

Computer prediction of possible toxic action from chemical structure: an update on the DEREK system

Computer-based assessment of potential toxicity has become increasingly popular in recent years. The knowledge-base system DEREK is developed under the guidance of a multinational Collaborative Group of expert toxicologists and provides a qualitative approach to toxicity prediction. Major developments of the DEREK program and knowledge-base have taken place in the last 3 years. Program developments include improvements in both the user interface and data processing. Work on the knowledge-base has concentrated on the areas of genotoxicity and skin sensitisation. DEREKs predictive capabilities for these toxicological end-points has been demonstrated. In addition to the continued expansion of the knowledge-base, a number of enhancements are planned in the DEREK program. In particular, work is in progress to develop further DEREKs ability to report the reasoning behind its predictions.

Role of biomarkers in monitoring exposures to chemicals: present position, future prospects

Biomarkers are becoming increasingly important in toxicology and human health. Many research groups are carrying out studies to develop biomarkers of exposure to chemicals and apply these for human monitoring. There is considerable interest in the use and application of biomarkers to identify the nature and amounts of chemical exposures in occupational and environmental situations. Major research goals are to develop and validate biomarkers that reflect specific exposures and permit the prediction of the risk of disease in individuals and groups. One important objective is to prevent human cancer. This review presents a commentary and consensus views about the major developments on biomarkers for monitoring human exposure to chemicals. A particular emphasis is on monitoring exposures to carcinogens. Significant developments in the areas of new and existing biomarkers, analytical methodologies, validation studies and field trials together with auditing and quality assessment of data are discussed. New developments in the relatively young field of toxicogenomics possibly leading to the identification of individual susceptibility to both cancer and non-cancer endpoints are also considered. The construction and development of reliable databases that integrate information from genomic and proteomic research programmes should offer a promising future for the application of these technologies in the prediction of risks and prevention of diseases related to chemical exposures. Currently adducts of chemicals with macromolecules are important and useful biomarkers especially for certain individual chemicals where there are incidences of occupational exposure. For monitoring exposure to genotoxic compounds protein adducts, such as those formed with haemoglobin, are considered effective biomarkers for determining individual exposure doses of reactive chemicals. For other organic chemicals, the excreted urinary metabolites can also give a useful and complementary indication of exposure for acute exposures. These methods have revealed ‘backgrounds’ in people not knowingly exposed to chemicals and the sources and significance of these need to be determined, particularly in the context of their contribution to background health risks.

The Relationships between Alkylation of Haemoglobin and DNA in Fischer 344 Rats Exposed to [14C]Ethylene Oxide

The quantification of products (adducts) of chemical reactions between geno-toxic chemicals and Hb may provide a basis for determining individual exposures to such agents and similarly the determination of Hb dose (in vivo) might be used to estimate the doses of ultimate genotoxic agents delivered to DNA (Ehrenberg et al 1974). The validation of this approach for its applicability to man relies on the study of the relationships in experimental species. Published data relating Hb- and tissue DNA- doses of EO are limited (Osterman-Golkar 1983; Segerback 1983). Thus the current study, designed to investigate the general utility of Hb as a DNA monitor in cases of exposure to EO, aimed to relate exposure doses of EO to the doses delivered in vivo to Hb and to DNA in F344 rats. The relationships obtained in this study can be compared with those obtained in other species with a view to determining the variation. These results are based on measurements of DNA doses of EO in brain, lung, liver, spleen, kidney and testis and Hb doses in blood of male F344 rats exposed to inhaled [14C]EO. The inhalation concentrations of EO used in this dosimetry study (1, 10 and 33 ppm, v/v) were similar to the lower range of exposures (10, 33 and 100 ppm, v/v) in the Bushy Run carcinogenicity study (Snellings et al 1984) and were selected with a view to investigating possible saturation kinetics at low doses.

Bulky DNA-adduct formation induced by Ni(II) in vitro and in vivo as assayed by 32P-postlabeling

Various small oxidation products (e.g. 8-hydroxydeoxyguanosine) can be induced in DNA by nickel compounds. In this study, the 32P-postlabeling assay was applied to determine whether Ni(II) compounds are able to induce bulky DNA-adduct formation in vitro and in vivo. In vitro studies detected two major and several minor adducts in DNA incubated with NiCl2 and H2O2 at 37 degrees C for 1 h. Formation of the two major adducts increased with incubation time (0-24 h) and NiCl2 concentration (0-800 microM). Adduct levels were greatly reduced by hydroxyl free-radical scavengers, i.e. 0.4 M sodium formate or 0.05 M p-nitrosodimethylaniline, and by a singlet oxygen scavenger, 0.05 M sodium azide. The in vitro effects of NiCl2 on DNA were significantly enhanced by (1) addition of 3 mM ascorbic acid, (2) replacement of H2O with D2O in the reaction, and (3) prior denaturation of DNA. Adduct formation presumably involved a Fenton-type reaction, in which DNA crosslinks may arise by reaction with hydroxyl free radicals and singlet oxygen. For in vivo studies, male 6-8 wk old B6C3F1 mice were used. In untreated mice, several I-compounds (putative indigenous DNA modifications that increase with age) were detected in liver, kidney, and lung. Two of these (spots 1 and 2) were chromatographically identical to the two major spots induced by Ni(II) in vitro. The intensities of spots 1 and 2 in kidney and of some other spots in liver and lung were increased 1 and 2 h after i.p. injection with a single dose of 170 mumols/kg NiAc2. The effects of NiAc2 were reduced or undetectable in the three tissues 24 h after treatment. These observations indicate the capacity of Ni(II) to induce and modulate bulky DNA modifications both in vitro and in vivo.

The mechanism of decomposition of N-methyl-N-nitrosourea (MNU) in water and a study of its reactions with 2′-deoxyguanosine, 2′-deoxyguanosine 5′-monophosphate and d(GTGCAC)☆

Abstract The carcinogenicity of N-methyl-N-nitrosourea (MNU) arises from its ability to methylate DNA. This occurs in an aqueous environment and therefore an appreciation of the mode of decomposition of MNU in water is essential to understanding the mechanism of DNA methylation and its base sequence dependence. The kinetics of MNU hydrolyses are shown to be first order in MNU with a steep rise in rate above pH 8. Using NMR for in situ monitoring of reaction intermediates and products from hydrolyses of [13CO]MNU, [15NH2]MNU and [13CH3]MNU, it is proved that base-induced hydrolysis of MNU is initiated by deprotonation at the carbamoyl group. The critical reactive species are shown to be the methyldiazonium ion (Me-N2+) and cyanate (NCO−). Investigations of reactions of [13CH3]MNU with 2′-deoxyguanosine (dGuo) and 2′-deoxyguanosine 5′-monophosphate (dGuo-5P) showed that: a) the site of methylation of dGuo is highly pH-dependent (relatively more N-1 and O6-methylation compared to N-7 occurs at higher pH); b) the principal site of methylation of dGuo-5P by MNU is at phosphate; c) incorporation of deuterium into methyl groups occurs in D2O at higher pH. Methylation of the oligonucleotide d(GT[15N]GCAC) by MNU in D2O showed partial deuteriation of the N7-methyl groups of the guanines, whilst methylation by MNU in water indicated no significant preference for either guanine with respect to N7-methylation.

Molecular dosimetry of DNA adducts in rainbow trout (Oncorhynchus mykiss) exposed to benzo(a)pyrene by different routes

Farm raised rainbow trout (Oncorhynchus mykiss) were exposed by various routes to benzo(a)pyrene (BP) as a representative carcinogenic polycyclic aromatic hydrocarbon (PAH). Following exposure of fish to the chemical by intraperitoneal (i.p.) injection, 32P-postlabelling studies indicated that non-feral trout were relatively resistant to the formation of BP-DNA adducts in liver. No adducts were detected in fish exposed to single doses (20 mg/kg) of BP. Multiple exposures (e.g. 2×25 mg/kg) were necessary in order for adducts to be detected, indicating that induction of the metabolising enzymes required for the bioactivation of BP is necessary. These studies provided reference information on DNA adducts for comparison with data from subsequent experiments at environmentally realistic low level exposures. Two types of low level aquatic exposure were carried out. The first procedure exposed fish for 30 days to a nominally constant low level (1.2 and 0.4 μg/l) of a homogeneous dispersion of BP in water, to simulate low level aquatic environmental exposures. Following 32P-postlabelling analysis of the liver DNA of exposed fish, BP-DNA adducts were not detected. In the second procedure, fish were exposed to a constant low level of BP (ca. 0.5 μg/l) for 15 days then to a pulse (60 μg/l) which was allowed to naturally decline (to ca. 2 μg/l) during a further 15 days. Following this exposure, significant levels of BP-DNA adducts were detected in livers of trout. The effect of dietary exposures was investigated by feeding trout a diet containing either 58 μg or 288 μg BP per day for 6 days, equivalent to total doses of 43 mg/kg and 216 mg/kg. In both cases BP-DNA adducts were detected in livers of exposed fish. The results provide useful information on the types of exposures to PAHs which may pose a genotoxic risk to fish in the environment.

Intensification and depletion of specific bulky renal DNA adducts (I-compounds) following exposure of male F344 rats to the renal carcinogen ferric nitrilotriacetate (Fe-NTA).

The effects of the renal carcinogen ferric nitrilotriacetate (Fe-NTA) on kidney DNA of male F344 rats were studied to determine whether bulky DNA oxidation products (putative intrastrand crosslinks) could be detected by 32P-postlabeling in the target organ of carcinogenesis. Rats (10-11 weeks old) were given a single dose of Fe-NTA (15 mg Fe/kg body weight) i.p. at 3:00 pm. After 5 h, renal DNA from Fe-NTA-treated and vehicle control animals was assayed by 32P-postlabeling. Thin-layer chromatography and quantitative analysis of two labeled nucleotide fractions of increasing polarity, L and C, showed that three spots (L1, L2, and C3) were intensified 3.5- to 4.2-fold in treated animals. L1 consisted of subfractions L1a, L1b, and L1c, which could be resolved chromatographically. L1c, L2, and C3 were identical to DNA oxidation products generated by the Fenton reaction in vitro, while L1a and L1b apparently did not arise by this mechanism. DNA damage and toxicity appeared reduced in younger animals and animals treated in the morning, presumably due to differences in antioxidant defenses. Liver and lung (non-target organs) DNA did not exhibit enhanced L1, L2, and C3 spots. In addition to augmenting renal I-compounds, Fe-NTA reduced the levels of three major polar kidney I-compounds (C4, C5, and C6) to 22-53% of control. This reduction did not appear to arise by direct oxidative DNA damage, resembling the previously documented loss of liver I-compounds induced by numerous hepatocarcinogens. Two of these I-compounds (C4 and C5) have been reported to exhibit positive linear correlations with median lifespan of male F344 rats. The pleiotropic response of kidney I-compound levels to Fe-NTA was consistent with different roles of different types (I and II) of I-compounds in Fe-NTA-mediated renal carcinogenesis. The results strongly support a causal relationship between oxidative DNA lesions and Fe-NTA-mediated carcinogenesis.

Simple syntheses of isomers of muconaldehyde and 2-methylmuconaldehyde

Abstract Periodate oxidation of cis -1,2-dihydrocatechol ( 3a ) affords ( Z,Z )-muconaldehyde ( 2b ), which can be readily converted (thermolysis and triethylamine catalysis, respectively) into its ( E,Z )- ( 2c ) and ( E,E )-isomer ( 2a ). Similarly, cis -1,2-dihydro-3-methylcatechol ( 3b ) gives( Z,Z )-2-methylmuconaldehyde ( 2d ) and thence ( E,E )-2-methylmuconaldehyde ( 2c ).

Microbial mutagenicity studies with (Z)-1,3-dichloropropene

This study has confirmed that the direct mutagenicity previously observed when S. typhimurium TA100 was treated with (Z)-1,3-dichloropropene (DCP) was in fact due to trace impurities. These impurities result from autoxidation of (Z)-1,3-DCP and have now been identified. Both (Z)- and (E)-2-chloro-3-(chloromethyl)oxiranes (DCP oxides) were identified as significant products during this autoxidation. The mutagenic impurities formed by autoxidation were completely removed by adsorption chromatography on silicic acid. (Z)-1,3-DCP purified in this way had no direct-acting mutagenicity towards S. typhimurium TA100. However, (Z)-1,3-DCP undergoes mono-oxygenase-catalysed conversion into bacterial mutagens in the presence of S9 fraction or washed microsomes from rat liver. The glutathione-linked conjugation systems of mammalian tissues provided efficient protection against this indirect mutagenic action. However, the low concentration of glutathione in standard bacterial mutagenicity assays limits the glutathione S-alkyl transferase-catalysed detoxification of (Z)-1,3-DCP and its primary bioactivation product(s). When the concentration of glutathione was adjusted to the normal physiological concentration, the mono-oxygenase-dependent mutagenic action of (Z)-1,3-DCP was virtually eliminated. These results therefore are consistent with the view that bacterial mutation assays are only qualitative indicators of potential mammalian genotoxicity.

Studies on the dermal and systemic bioavailability of polycyclic aromatic compounds in high viscosity oil products

Abstract The assessment of skin penetration by viscous oil products is an important element in the risk assessment of these materials where skin contact is likely. Systemic bioavailability (body uptake) is viewed as a good indicator of skin penetration following cutaneous exposures. The results of this study provide quantitative information on the influence of viscosity on the bioavailability of a specific polycyclic aromatic compound (benzo(a)pyrene) in base oils, residual aromatic extracts and bitumens following skin exposures to mice. The materials studied were a base mineral oil (viscosity 32 cSt at 35 °C), a 1:1 blend of the mineral base oil and a residual aromatic extract (198 cSt), several residual aromatic extracts (ca. 5000 cSt, 35 °C) and a range of bitumens (0.65–69 × 106 cSt, 35 °C). These were each spiked with 0.1% radiolabelled benzo(a)pyrene, as a representative carcinogenic polycyclic aromatic compound, then used for cutaneous exposures to mice. The results indicate that as viscosity increased in the range ca. 30 to 5000 cSt (base oil to residual aromatic extract) the uptake of the radiolabelled benzo(a)pyrene into blood was reduced by ca. fivefold. Further increases in viscosity from ca. 5000 to 69 × 106 cSt (i.e. residual aromatic extract to bitumen) resulted in a further but smaller (ca. twofold) reduction in uptake. The relationship between the amounts of free benzo(a)pyrene measured in blood and viscosity showed the same trend. This trend was also mirrored by the degree of binding of benzo(a)pyrene metabolites to DNA in skin. The findings in mouse skin in vivo indicate that viscosity can significantly affect skin penetration and systemic bioavailability of polycyclic aromatic compound components of oil products. Results obtained with viable human skin in vitro also showed that the bioavailability of benzo(a)pyrene was reduced by the viscosity of the oil product matrix. It is thus necessary to take account of physical properties such as viscosity in the overall risk assessment of viscous oil products, particularly in the case of very viscous materials such as bitumens. The significantly reduced bioavailability of hazardous compounds from undiluted materials is thus an important factor to consider when assessing the risks from dermal exposures.