Effects of dietary transition metals on oxidative DNA lesions in neonatal rats.

Bulky endogenous oxidative lesions (type II I-compounds) reflect DNA damage associated with oxidative stress. As shown by 32P-postlabeling, their levels are enhanced by pro-oxidant genotoxins and also shortly after normal birth in several rat tissues as a function of time and the maternal diet. In order to elucidate which dietary components contribute to postnatal DNA damage, we have focused, herein, on the possible role of transition metals (iron, copper, and nickel). Pregnant Fischer 344 (F344) rats were fed AIN-93G purified diet containing different amounts of iron, copper, and nickel, or Purina-5001 natural-ingredient diet (which contains relatively high concentrations of these metals). Type II I-compounds were estimated by nuclease P1-enhanced 32P-postlabeling in liver and lung DNA of fetuses and at 24h and day 9 post-partum. Increased postnatal oxidative damage was detected in liver but not lung DNA of neonates exposed to higher amounts of dietary transition metals. There were significant positive linear correlations between maternal transition metal intake and neonatal, but not fetal and maternal type II I-compound levels. The results show that transition metals in the maternal diet affect perinatal oxidative DNA damage, presumably via a Fenton-type reaction. They also provide evidence for optimal levels in the maternal diet of transition metals, which on one hand, are essential for life, but on the other, can cause potentially deleterious DNA alterations in the offspring.

Effects of different diets and dietary restriction on perinatal endogenous DNA adducts. Time dependence of oxidative and presumptive nonoxidative lesions.

Type II I-compounds (indigenous DNA adducts) denote a class of bulky oxidative DNA lesions that are detectable by 32P-postlabeling and represent useful biomarkers of DNA damage induced by oxidative stress. Their levels are increased in tissue DNA under pro-oxidant conditions, for example, as previously shown, in newborn rat organs. Here we have investigated whether the maternal diet affects perinatal type II I-compound levels. Pregnant F344 rats were fed Purina-5001 natural-ingredient or AIN-93G purified diet from day 11 of gestation. Type II I-compounds were measured in liver DNA at three different developmental stages, i.e., fetus, and 24 h and 9 days postnatally. Higher adduct levels were detected in the Purina-5001 group at each stage. In a second experiment, pregnant F344 rats were subjected to dietary restriction (DR) (by 40%; Purina-5001) from day 12 of gestation. At 24 h postpartum hepatic type II I-compound levels were decreased compared to parallel ad libitum (AL) fed controls. As an unrelated observation, fetal lung, but not liver, kidney, and skin DNA contained a different pattern of nonpolar, apparently nonoxidative adducts, which were not diet-dependent. These spots were not detectable 24 h after birth and were observed at much reduced levels and only in a few samples at 9 days. The main results show for the first time that the maternal nutrition modulated levels of oxidative lesions in fetal and neonatal DNA, but the underlying mechanisms (e.g., differences in metal or caloric content of the diets) still need to be determined. The dietary effects were apparently transmitted through both placenta and the mother's milk.

Genotoxicity of complex PAH mixtures recovered from contaminated lake sediments as assessed by three different methods.

Although human exposure generally occurs to mixtures of chemicals, limited toxicological information is available to characterize the potential interactions of the components of environmental mixtures. This study was conducted to compare the genotoxicity of chemically characterized polycyclic aromatic hydrocarbon (PAH) mixtures using in vitro and in vivo techniques. A total of three extracts (E1-E3) were selected from sediment samples collected from a lake adjacent to an abandoned coal gasification site. Sediments were collected on a grid moving downstream and away from the most likely source of PAH contamination, with E1 collected closest to the shore, E2 at an intermediate distance, and E3 furthest from the shore. The sediment samples were extracted in methylene chloride and methanol, dried, and redissolved in an appropriate solvent for evaluation in a battery of genotoxicity assays. Samples were evaluated for their ability to produce point mutations in bacteria and DNA adducts in vitro without metabolic activation or in vivo. Samples were also analyzed using GC/MS. Sample E1 had both the highest concentration of benzo(a)pyrene (BP) (46.5 ppm) and carcinogenic PAHs and, using 32P-postlabeling, induced the highest adduct levels overall in vitro and in vivo. Sample E2, which had a BP concentration of 14 ppm, induced the greatest number of revertants in the bacterial mutagenicity assay. Sample E3, which had the lowest level of carcinogenic PAHs and BP, induced the lowest adduct levels. However, E3 was capable of inducing a positive genotoxic response in bacteria (with S9), although the slope of the response at lower doses was less than that of E2. The in vivo data showed that the major adduct formed by E1 and E2 was a BP adduct. This information could not have been obtained with the Salmonella or in vitro postlabeling tests. Among internal organs, the extracts of all three samples induced the greatest adduct levels in the lung, similarly to previous complex PAH mixtures studied. These data demonstrate the limitations of predicting genotoxic or carcinogenic potential based on chemical analysis or a single biological test. The results suggest that mixture interactions, cytotoxicity and metabolism are likely to have an influence on the potential of a complex mixture of chemicals to produce a carcinogenic effect. In addition, the concentration of genotoxic PAHs and both in vitro and in vivo DNA adduct formations were decreased with increasing distance from the shoreline.

Bulky endogenous DNA modifications (I-compounds) -possible structural origins and functional implications.

I-compounds are bulky covalent DNA modifications which increase with age in tissues of unexposed laboratory animals and are derived from endogenous DNA-reactive intermediates of nutrient and oxygen metabolism. They have been classified into 2 major groups, i.e., type I and type II. Profiles and levels of type I I-compounds show considerable variation depending on species, strain, tissue, and gender, but are also affected by diet and chemical and hormonal exposures, indicating their formation to be determined by genetic and environmental factors. For example, sex hormones, dietary oat lipids, and isoprenoids affect their profiles and/or levels in tissue DNA. A gradual depletion of many type I I-compounds occurs during carcinogenesis, as many carcinogens/tumor promoters significantly reduce their levels, and neoplasms display very low levels, apparently independent of growth rate, indicating a loss of the ability to form these modified nucleotides. Conversely, dietary restriction, the most effective method to retard carcinogenesis and aging, significantly elevates type I I-compound levels, as compared to age-matched ad libitum-fed animals. Levels of many liver and kidney I-compounds exhibit genotype- and diet-dependent positive linear correlations with median life span. Formation of high levels of oat-related type I I-compounds has been associated with reduced formation of carcinogen-induced preneoplastic hepatic foci. These results suggest that such DNA modifications may not represent DNA lesions but may rather be functionally important. This view is supported by circadian rhythms displayed by some I-compounds. Thus, certain type I I-compounds may play a protective role against carcinogenesis and age-associated degenerative processes. Type II I-compounds, on the other hand, represent DNA damage and include several bulky lesions, which are enhanced by pro-oxidant carcinogens such as ferric nitrilotri- acetate (Fe-NTA) in target organ (kidney) DNA of rodents and are identical to products generated by oxidizing DNA or oligonucleotides under Fenton reaction conditions in vitro. Some of these products appear to be base-base or base-sugar intrastrand crosslinks. Notably, Fe-NTA reduces the levels of type I I-compounds in renal DNA. Type II I-compound levels are increased in tissue DNA of normal newborn rats. The formation of oxidative DNA lesions in neonates is most likely caused by oxidative stress associated with the sudden increase of partial oxygen pressure in arterial blood and tissues at birth. In view of the rapid cell replication at this developmental stage, endogenous oxidative DNA lesions sustained early in life may contribute to the development of cancer and degenerative diseases later in life.

Acute elevation by short-term dietary restriction or food deprivation of type I I-compound levels in rat liver DNA.

Type I I-compounds are bulky endogenous DNA modifications detectable by 32P postlabeling that exhibit age, species, tissue, genotype, gender, and diet dependence. Their formation appears unrelated to oxidative stress. In fact, several lines of indirect evidence suggest that many type I I-compounds may represent normal functional DNA modifications. For example, long-term dietary restriction (DR), which retards the development of age-related diseases including cancer and extends median and maximum life spans, unexpectedly elicits significant increases rather than decreases in the levels of many I-compounds in different rodent tissues. Positive linear correlations have been observed between such levels and median life spans of the animals. In the present work we have investigated 1) whether elevation of I-compound levels does not depend on chronic DR, i.e., occurs after a short period of DR or fasting, and 2) whether I-compound levels return to control values after the animals are returned to unrestricted feeding after food deprivation. Female Fischer 344 rats (approx 140 g each) were randomized into three groups. Group I was fed a natural ingredient (Purina 5001) diet ad libitum (AL) throughout the study, Group 2 was switched to 60% of the AL amount (40% DR) at 0 hour, and Group 3 was given no food for up to 72 hours and then returned to AL feeding until the end of the experiment. Liver DNA of individual rats (n = 4) was isolated for I-compound analysis at 24, 72, and 240 hours. Restricted and food-deprived rats showed elevated levels of hepatic I-compounds, with fasting eliciting the highest levels. These effects were seen as early as the 24-hour time point. Refeeding after 72 hours of food deprivation restored the levels to control values, measured at 240 hours. Our observations are discussed in relation to carcinogenesis and tumor promotion. The almost instantaneous changes of endogenous DNA modifications showed their exquisite sensitivity to nutritional factors and provided strong new evidence for precise regulation of their formation and removal.

High levels of endogenous DNA adducts (I-compounds) in pig liver. Modulation by high cholesterol/high fat diet.

I (indigenous)-compounds are bulky endogenous DNA adducts which are detected by 32P-postlabeling in unexposed animals. I-compound levels in rodents depend on age, species, strain, gender, tissue, diet, and chemical exposure. There are two classes of I-compounds, type I and type II. While many type I I-compounds may not reflect DNA damage, type II I-compounds have been identified as oxidative DNA lesions some of which can be produced in vitro under Fenton reaction conditions. In rats, caloric restriction (CR) increases the levels of many type I I-compounds compared with ad libitum fed animals, while high fat diet has the opposite effect. Here, we have tested whether hepatic DNA of a non-rodent mammal, the pig, contains I-compounds and whether feeding a high cholesterol/high fat (HC/HF) diet modulates their levels, assuming this would affect the formation of lipid-related precursors and cause oxidative stress. Male Yorkshire pigs aged 2 months old, were fed either control or HC/HF diet (control diet supplemented with 2% cholesterol and 19% lard) for 2 months. Pig liver DNA contained at least 19 type I and five type II I-compounds. Among the former, only five matched corresponding spots in rat liver DNA, while all the latter DNA lesions were detected in both species. The levels of both types of DNA modifications were six to eight-fold higher in pig DNA. HC/HF diet reduced levels of many type I I-compounds up to several fold but had little effect on the oxidative lesions. Several type I I-compounds showed negative linear correlations with serum cholesterol levels, while this association was positive for total type II I-compounds. The substantially elevated steady-state levels of bulky endogenous DNA adducts in the species with the longer life expectancy were surprising. Thus, for the first time, an intimate link between nutritional status and endogenous DNA modifications has been established in a non-rodent system. We propose that in order to explain our observations, differences in diet composition, antioxidant defenses, and DNA repair, as well as cytochrome P450 modulation of precursor levels and hormonal effects need to be considered.

Partial characterization of two major liver I-compounds as unstable adducts which are readily hydrolyzed to unmodified guanine nucleotides.

I-compounds are endogenous bulky DNA modifications which are detected by nuclease P1-enhanced 32P-post-labeling in tissue DNA of animals not knowingly exposed to carcinogens. Their profiles and levels depend inter alia on animal age, species, strain, tissue, gender, diet and exposure to chemicals such as cytochrome P450 inducers and carcinogens. Due to lack of sufficient material obtainable from in vivo sources, chemical structures of I-compounds and their parent normal bases have not yet been identified. In this report we provide 32P-post-labeling and chromatographic evidence that two prominent I-compounds, herein called C1 and C2, which occur at relatively high levels in pig liver DNA are guanine derivatives. This result was obtained by showing that both compounds, isolated from 32P-post-labeling thin-layer maps, were chemically unstable, i.e. they could be readily hydrolyzed to 32P-post-labeled deoxyguanosine 3',5'-bisphosphate by heating in water. C1 appeared particularly labile, undergoing hydrolysis during thin-layer chromatography at pH 3.3 without heating. Several other I-compounds and adducts, as well as the four normal DNA nucleotides, were, however, highly resistant to hydrolysis under the conditions used here. The possible significance of these findings will be briefly discussed.

Enhanced levels in neonatal rat liver of 7,8-dihydro-8-oxo-2'-deoxyguanosine (8-hydroxydeoxyguanosine), a major mutagenic oxidative DNA lesion.

The purpose of this study was to determine whether the level of 7,8-dihydro-8-oxo-2'-deoxyguanosine (8-hydroxy-2'-deoxyguanosine) (8-oxo-dG), a major mutagenic DNA oxidation product, is enhanced in newborn rat liver DNA as a consequence of oxidative stress incurred during the early postnatal period. 32P-postlabeling showed this adduct to increase approximately 2-fold from the 20th day of gestation (2 days before birth) to a peak level at 50-53 h after birth. Postnatal levels exceeded fetal levels at all time points investigated, i.e. 0.5-1, 8, 24, 50-53, 100, 216 and 432 h after birth. Increased formation of this mutagenic DNA lesion during the critical postnatal phase when there is rapid cell proliferation in all tissues is proposed to contribute to carcinogenesis in susceptible tissues later in life.

Organ-specific oxidative DNA damage associated with normal birth in rats.

Mammalian DNA contains bulky endogenous DNA modifications (I-compounds), which increase with age in unexposed animals, as shown by 32P-postlabeling. We have examined the perinatal formation of a subclass (type II) of I-compounds in rat liver, kidney, skin and lung. These I-compounds represent bulky oxidative DNA lesions, defined herein as intrastrand base-base and base-sugar cross-links, adducts of lipid peroxidation products and DNA-protein cross-links. We observed a rapid increase in the levels of five bulky oxidative DNA lesions during the first hours after normal birth of rats, with total levels increasing 4.2-, 3.0- and 1.3-fold, respectively, in liver, kidney and skin. This effect was not noted in lung. The results were consistent with oxidative stress induced by the known sudden increase in partial oxygen pressure at birth in blood and tissues, implying inadequate antioxidant defenses in the affected neonatal organs. Hepatic oxidative damage appeared intensified by increased concentrations of pro-oxidants and reduced concentrations of antioxidants in the maternal diet. The postnatal DNA lesions are postulated to be premutagenic, as indicated by their bulky nature and persistence. Pathophysiological effects of oxidative DNA damage would be exacerbated by rapid cell proliferation in neonatal tissues and consequent fixation as mutations. In addition to inherited mutations, DNA lesions acquired as a consequence of normal birth may play a hitherto unrecognized role in spontaneous carcinogenesis and age-related degenerative diseases.

Effects of cytochrome P450 inducers on tamoxifen genotoxicity in female mice in vivo.

We recently reported that administration of the antiestrogen tamoxifen (TAM) gives rise to two groups of DNA adducts in female mouse liver in vivo, as measured by 32P-postlabeling, and provided evidence that 4-hydroxytamoxifen and alpha-hydroxytamoxifen are proximate carcinogenic metabolites leading to group I and group II adducts, respectively (Randerath et al., Carcinogenesis 15: 2087-2094, 1994). Because cytochrome P450 (CYP) enzymes play an important role in TAM metabolism, in this investigation we tested the hypothesis that induction of liver CYP enzymes may affect TAM metabolism profoundly, resulting in increased or decreased TAM-DNA adduct formation in vivo. To this end, we treated female ICR mice with TAM either alone or in combination with one of several classic CYP inducers, i.e. phenobarbital (PB), beta-naphthoflavone (BNF), and pregnenolone-16 alpha-carbonitrile (PCN), and determined the levels of 32P-postlabeled TAM-DNA adducts and the activities of several CYP-dependent enzymes. Each of the inducers greatly diminished levels of group II, but did not affect group I adducts. TAM elicited induction of benzphetamine N-demethylase activity in liver, while activities of other enzymes were not affected. TAM, when given in combination with BNF, elicited a synergistic induction of ethoxyresorufin O-deethylase (EROD) (CYP1A1) and methoxyresorufin O-demethylase (MROD) (CYP1A2) activities. Likewise, PCN given along with TAM caused synergistic induction of EROD and ethylmorphine N-demethylase activities. There was no synergism between PB and TAM, however. Overall, the results further support the existence of two pathways of TAM metabolism to DNA-reactive electrophiles and strongly suggest that the classic CYP inducers tested enhance detoxication of TAM to non-genotoxic metabolites.

Comparative 32P-postlabeling analysis of exogenous and endogenous DNA adducts in mouse skin exposed to a wood-preserving waste extract, a complex mixture of polycyclic and polychlorinated chemicals.

Wood preserving waste (WPW) sites contain numerous toxic compounds, including phenols, polycyclic aromatic hydrocarbons (PAHs), polychlorinated dibenzodioxins, and dibenzofurans. Previous in vitro and in vivo 32P-postlabeling studies showed the induction of multiple carcinogen-DNA adducts by WPW extracts. We now have tested the hypothesis in a mouse skin bioassay that a WPW extract not only causes the formation of exogenous, xenobiotic-derived DNA adducts, but also alters the levels of endogenous DNA modifications. Skin DNA of female ICR mice treated topically with an organic WPW extract was found by 32P-postlabeling to contain significantly increased levels of bulky oxidative DNA lesions (type II I-compounds), in addition to exogenous PAH-derived adducts. The mechanism of this increase is postulated to proceed through electrophilic quinoid compounds, which presumably were formed from phenols by chemical reactions of waste material or biologically by oxidative metabolism. On the other hand, the levels of another class of endogenous DNA adducts (type I I-compounds) were reduced significantly in exposed skin DNA. This effect was explained by the presence of cytochrome P450 inducers in the extract. All three types of DNA alterations observed may play a significant role in carcinogenesis. Our results imply that in addition to exogenous carcinogen-DNA adducts, alterations of endogenous DNA modifications may need to be considered in evaluating carcinogenic risk from toxic chemical wastes and the effects of remediation measures.

DNA adducts and chronic degenerative disease. Pathogenetic relevance and implications in preventive medicine.

Chronic degenerative diseases are the leading causes of death in developed countries. Their control is exceedingly difficult due to their multiplicity and diversity, the interconnection with a network of multiple risk factors and protective factors, the long latency and multistep pathogenesis, and the multifocal localization. Adducts to nuclear DNA are biomarkers evaluating the biologically effective dose, reflecting an enhanced risk of developing a mutation-related disease more realistically than the external exposure dose. The localization and accumulation of these promutagenic lesions in different organs are the composite result of several factors, including (a) toxicokinetics (first-pass effect); (b) local and distant metabolism; (c) efficiency and fidelity of DNA repair; and (d) cell proliferation rate. The last factor will affect not only the dilution of DNA adducts but also the possible evolution towards either destructive processes, such as emphysema or cardiomyopathies, or proliferative processes, such as benign or malignant tumors at various sites. They also include heart tumors affecting fetal myocytes after transplacental exposure to DNA-binding agents, blood vessel tumors, and atherosclerotic plaques. In this article, particular emphasis is given to molecular alterations in the heart, which is the preferential target for the formation of DNA adducts in smokers, and in human aorta, where an extensive molecular epidemiology project is documenting the systematic presence of adducts to the nuclear DNA of smooth muscle cells from atherosclerotic lesions, and their significant correlation with known atherogenic risk factors. Exocyclic DNA adducts resulting from lipid peroxidation, and age-related indigenous adducts (I-compounds) may also originate from endogenous sources, chronic infections and infestations, and inflammatory processes. Type II I-compounds are bulky DNA lesions resulting from oxidative stress, whereas type II-compounds are presumably normal DNA modifications, which display positive correlations with median life span and are decreased in cancer and other pathological conditions. Profiles of type II-compounds strongly depend on diet and are related to the antidegenerative effects of caloric/ dietary restriction. Even broader is the possible meaning of adducts to mitochondrial DNA, which have been detected in rodents exposed to genotoxic agents and complex mixtures, as well as in untreated rodents, in larger amounts when compared to the nuclear DNA of the same cells. Mutations in mitochondrial DNA increase the number of oxidative phosphorylation-defective cells, especially in energy-requiring postmitotic tissues such as brain, heart and skeletal muscle, thereby playing an important role in aging and a variety of chronic degenerative diseases. A decreased formation of DNA adducts is an indicator of reduced risk of developing the associated disease. Therefore, these molecular dosimeters can be used as biomarkers in the prevention of chronic degenerative diseases, pursued either by avoiding exposure to adduct-forming agents or by using chemopreventive agents. Interventions addressed to the human organism by means of dietary measures or pharmacological agents have encountered a broad consensus in the area of cardiovascular diseases, and are deserving a growing interest also in cancer prevention. The efficacy of chemopreventive agents can be assessed by evaluating inhibition of nuclear DNA or mitochondrial DNA adduct formation in vitro, in animal models, and in phase II clinical trials in high-risk individuals.

Organ-specific oxidative DNA damage associated with normal birth in rats.

Mammalian DNA contains bulky endogenous DNA modifications (I-compounds), which increase with age in unexposed animals, as shown by 32P-postlabeling. We have examined the perinatal formation of a subclass (type II) of I-compounds in rat liver, kidney, skin and lung. These I-compounds represent bulky oxidative DNA lesions, defined herein as intrastrand base-base and base-sugar cross-links, adducts of lipid peroxidation products and DNA-protein cross-links. We observed a rapid increase in the levels of five bulky oxidative DNA lesions during the first hours after normal birth of rats, with total levels increasing 4.2-, 3.0- and 1.3-fold, respectively, in liver, kidney and skin. This effect was not noted in lung. The results were consistent with oxidative stress induced by the known sudden increase in partial oxygen pressure at birth in blood and tissues, implying inadequate antioxidant defenses in the affected neonatal organs. Hepatic oxidative damage appeared intensified by increased concentrations of pro-oxidants and reduced concentrations of antioxidants in the maternal diet. The postnatal DNA lesions are postulated to be premutagenic, as indicated by their bulky nature and persistence. Pathophysiological effects of oxidative DNA damage would be exacerbated by rapid cell proliferation in neonatal tissues and consequent fixation as mutations. In addition to inherited mutations, DNA lesions acquired as a consequence of normal birth may play a hitherto unrecognized role in spontaneous carcinogenesis and age-related degenerative diseases.

Monophosphate 32P-postlabeling assay of DNA adducts from 1,2:3,4-diepoxybutane, the most genotoxic metabolite of 1,3-butadiene: in vitro methodological studies and in vivo dosimetry.

Among the main DNA-reactive metabolites of 1,3-butadiene (BD), both 1,2:3,4-butadiene diepoxide (BDE) and 1,2-epoxy-3-butene (BME) have been reported in mice and rats exposed to BD, but blood and tissue levels of these metabolites are much higher in mice than in rats under similar exposure conditions. BDE, being more reactive and genotoxic than BME, is thought to be responsible for the greater susceptibility of mice to BD carcinogenicity. While BDE is a DNA-alkylating agent and some BDE adducts have been characterized, no sufficiently sensitive method has been reported for studying BDE-DNA binding in vivo. In the present investigation, a modified dinucleotide/monophosphate version of the 32P-postlabeling assay was applied to detect BDE-DNA adducts, which were prepared by reacting BDE with calf thymus DNA or deoxyribooligonucleotides [(AC)10, (AG)10, (CCT)7 and (GGT)7] in vitro or with skin DNA of mice in vivo upon topical treatment. Optimal resolution by 2-D PEI-cellulose TLC of the highly polar 5'-monophosphate adducts was achieved at +4 degrees C using 0.3 M LiCI (DI) and 0.4 M NaCl, 0.04 M H3BO3, pH 7.6 (D2). The profiles of the 32P-postlabeled adducts were similar for calf thymus and skin DNA, with 3 major spots being detected. Adducts obtained in in vitro and in vivo experiments were compared by re- and cochromatography in 4 or 5 different solvents, and these experiments provided evidence that corresponding BDE adducts, for the most part, were identical and represented adenine derivatives. Guanine adducts were not detected by this method although literature data indicate their formation. Quantitatively, the assay responded linearly to adduct concentration, as shown in an experiment where BDE-modified skin DNA was serially diluted up to 81-fold with control DNA. The limit of detection was approximately 1 adduct in 10(8) normal nucleotides. Further, in an in vivo dosimetry study, skin DNA from groups of 8 individual mice treated with different doses of BDE (1.9, 5.7, 17, 51 and 153 mumol/mouse) for 3 days exhibited a linear relationship (r > or = 0.992) between adduct levels and dose. The results suggest that the 32P-postlabeling assay described herein will have utility in mechanistic studies and biomonitoring of DNA adduct formation from BDE and possibly other polar epoxides.

DNA damage induced in mouse tissues by organic wood preserving waste extracts as assayed by 32P-postlabeling.

Numerous wood preserving waste (WPW) sites in the United States pose genotoxic hazards. WPWs consist of complex mixtures containing toxic, including genotoxic, compounds which are derived from the preservatives coal tar creosote and pentachlorophenol (PCP) and other polychlorinated aromatics. The genotoxicity of WPW extracts, which has not been tested in mammals, cannot be evaluated on the basis of data for individual components because of possible compound interactions. Therefore, whole extracts need to be assayed. 32P-postlabeling represents a powerful tool to determine DNA adduct formation by complex genotoxic mixtures, such as cigarette smoke, diesel exhaust, and coke oven and foundry emissions in experimental animals and humans. In the present study, a mouse bioassay was used in combination with 32P-postlabeling to determine DNA adduct formation induced by hexane/acetone extracts of two samples from a WPW site. Female ICR mice were treated dermally with extract corresponding to 3 mg residue or vehicle control once per day for 2 days and killed 24 h later. Skin, lung, liver, kidney, and heart DNA preparations were assayed by nuclease P1-enhanced postlabeling. Adduct profiles were tissue-specific and displayed a multitude of non-polar DNA adducts with levels amounting to one adduct in 1.6 x 10(6) DNA nucleotides in skin (both extracts) and one adduct in 3.2 x 10(7) or 1.2 x 10(7) DNA nucleotides in liver (extract 1 or extract 2). Based on their chromatographic properties, these adducts appeared largely derived from polycyclic aromatic hydrocarbons (PAHs) present in the extracts. One of the major adducts was identified as the 32P-labeled derivative of the reaction product of 7 beta, 8 alpha-dihydroxy-9 alpha, 10 alpha-epoxy-7, 8,9,10-tetrahydrobenzo[a]pyrene (BPDE I) with N2 of deoxyguanosine. Total non-polar DNA adduct levels were highest in skin and lung, amounting to 17.4 and 24.0% of the skin values for extracts 1 and 2, respectively, in lung while the corresponding levels in liver were 5.0 and 12.6%. These results were in accord with the carcinogenic potencies of PAHs in these organs. Extract 2 induced higher adduct levels in internal organs, although its PAH concentrations were lower than those of extract 1, i.e. lung, liver, kidney, and heart had 1.4, 2.5, 1.9, and 1.7 times higher total adduct levels and 1.6, 3.3, 1.6, and 1.9 times higher benzo[a]pyrene adduct levels. With the exception of total adducts in lung, the differences between the two extracts were all significant, suggestive of compound interactions. The benzo[a]pyrene adduct levels in the five tissues correlated linearly with total adduct levels and thus represented a surrogate for the latter. Overall, the results suggest that DNA adducts in mouse tissues, as analyzed by 32P-postlabeling, are suitable biomarkers and dosimeters of the genotoxicity of WPW extracts.

Structural origins of bulky oxidative DNA adducts (type II I-compounds) as deduced by oxidation of oligonucleotides of known sequence.

Bulky DNA adducts, previously termed type II I-compounds, are detected by 32P-postlabeling following treatment of DNA with several Fenton-type oxygen radical-generating reagents, i.e., mixtures of Fe(II) or Ni(II) and H2O2. In an attempt to characterize the chemical nature and mechanism(s) of formation of these novel adducts, 16 single-stranded deoxyribooligonucleotides (20- and 21-mers) of known sequence were oxidized with Fe(II) or Ni(II) and H2O2, and the products were analyzed by 32P-postlabeling. Eight adducts were obtained reproducibly by oxidation of DNA and test oligonucleotides in a sequence-dependent manner. One major adduct (2) was formed only if the test oligonucleotide contained two adjacent adenine residues. Similarly, adducts 3 and 8 specifically originated in AC and CA sequences, respectively. Adduct 6 required a 5'-C-purine-3' sequence. On the other hand, GN sequences (where N is any normal nucleotide) gave rise to adduct 1, another major product, and adduct 7. Similarly, adducts 4 and 5 were produced by the oxidation of AN sequences. These observations are most readily explained if the oxidation reactions caused intrastrand cross-links between adjacent nucleotides, leading to dimer formation. The observation that adducts 1, 4, 5, and 7 did not require a specific 3'-nucleotide was consistent with the notion that these nucleotides lacked a 3'-base, suggesting the presence of a 5'-->3' purine-sugar cross-linked in the oxidized products. The majority of the lesions came from AA and 5'-purine-N-3' sequences. The effects of Fe(II) and Ni(II) were qualitatively similar; however, higher yields of products were observed with Fe(II) as the catalyst. The definition of the chemical origins of these bulky DNA modifications, which represent a new type of DNA damage, is expected to contribute to a better understanding of the mechanism of metal carcinogenesis and to shed light upon the origins of certain endogenous DNA lesions. Recently, some of the major oxidative DNA adducts characterized here were detected by 32P-postlabeling in the renal DNA of male rats treated with ferric nitrilotriacetate, a known potent prooxidative kidney carcinogen in these animals.

Evidence from 32P-postlabeling and the use of pentachlorophenol for a novel metabolic activation pathway of diethylstilbestrol and its dimethyl ether in mouse live: likely alpha-hydroxylation of ethyl group(s) followed by sulfate conjugation.

Diethylstilbestrol (DES), a synthetic stilbene estrogen, is a potent development toxin and carcinogen in humans and rodents. A number of 32P-postlabeling studies suggest that genotoxic effects of DES substantially contribute to these biological effects. The mechanisms involved in DES-mediated genotoxicity are not completely understood, however. As reported here, the structural resemblance of tamoxifen to DES led to the hypothesis that DES may be hydroxylated and sulfated at the allylic C2 and/or C5 of the ethyl side chains in analogy to alpha-hydroxylation and sulfation of and DNA adduct formation by tamoxifen. Female ICR mice were administered 500 mumol/kg DES or its dimethyl ether derivative (DiMeDES), either alone or in combination with the sulfotransferase inhibitor pentachlorophenol (PCP) (75 mumol/kg), once daily for 4 days. Liver DNA adducts were measured 24 h after the last dose by dinucleotide/monophosphate 32P-postlabeling. Administration of DES or DiMeDES led to the formation of a unique and novel pattern of several major DNA adducts which were absent in vehicle controls. With minor exceptions the pattern was qualitatively similar for the two compounds, suggesting rapid O-demethylation of DiMeDES to DES in vivo followed by metabolic activation. Adducts formed in vivo did not chromatographically match DES quinone adducts synthesized in vitro. Co-administration of PCP with DES or DiMeDES significantly decreased adduct formation from either compound, by 33-61%. Taken together, these results are consistent with a hitherto unrecognized pathway of metabolic activation and DNA adduct formation by DES involving the putative hydroxylation of the allylic alpha-carbon of the ethyl side chain(s), followed by formation of DNA-reactive sulfuric acid esters. DES is now known to induce DNA damage in vivo by at least four different mechanisms. It is postulated that this multiplicity of mechanisms in itself explains why this drug elicits such a plethora of unique and complex pathophysiological effects in adults and off-spring of different species.

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.

32P-postlabeling of bile components: bulky adduct-like behavior in polyethyleneimine-cellulose thin layer chromatography.

The 32P-postlabeling assay has been used widely in carcinogen-DNA adduct analysis because of its sensitivity and reproducibility. Cloned T4 polynucleotide kinase (PNK), routinely used in this assay, phosphorylates the 5'-OH groups of adducted nucleotides in the presence of [gamma-32P]ATP. However, as an exception to this property, PNK has been reported to phosphorylate non-adducted carcinogen metabolites, such as tetrol derivatives of benzo[a]pyrene and chrysene. Also, PNK phosphorylates both 5'-OH and 3'-OH groups of safrole-adducted deoxydinucleoside monophosphates having an unmodified purine in the 3'-position. In the present study we show that T4 PNK catalyzed the transfer of [32P]phosphate from [gamma-32P]ATP to rat bile components or purified bile acids (derivatives of 3 alpha-hydroxy-5 beta-cholanic acid) in the absence of nucleic acids or nucleases. However, labeling of the bile acids appeared over 100,000-fold less efficient than labeling of 2'-deoxyadenosine-5'-monophosphate. There was no reaction in the absence of bile components or PNK. Dehydrocholic acid, which lacks hydroxyl groups, was resistant to phosphorylation. On polyethyleneimine-cellulose TLC maps, 32P-labeled rat bile extract gave an array of non-polar radioactive spots which resembled carcinogen-DNA adducts, while 32P-labeled purified bile acids each gave a single spot. These 32P-labeled products liberated 32Pi upon incubation with prostatic acid phosphatases. Two of the radioactive spots obtained from rat bile were identified as phosphorylated taurocholic and taurodeoxycholic acids by co-chromatography with 32P-labeled standards. These findings demonstrate for the first time that PNK is able to phosphorylate natural products other than nucleotides and further emphasize the need to rule out contamination with bile acids and possibly other bulky/hydrophobic alcohols when analyzing DNA samples by 32P-postlabeling.

DNA damage induced by wood preserving waste extracts in vitro without metabolic activation, as assayed by 32P-postlabeling.

Aqueous wood preserving waste (WPW) extracts were tested for their ability to damage DNA in vitro without metabolic activation. Two extracts were prepared from a surface tar and a surface clay soil sample of a WPW site. As assayed by 32P-post-labelling incubation of DNA with these extracts gave rise to highly complex, extract-specific profiles of DNA adducts whose formation depended on the concentration of WPW material. Most of the adducts appeared to be derived from polycyclic aromatic hydrocarbons (PAHs). Three mg organic WPW residue gave rise to total adduct levels of 13.8 (extract 1) and 66.2 (extract 2) DNA modifications in 10(7) DNA nucleotides, corresponding to 13.9 and 26.9 modifications, respectively, per 10 mg of soil. Thus, extract 2 was more active, although the parent residue had a 1.4-times lower PAH content as determined by gas chromatography/mass spectrometry (GC/MS). DNA adduct formation presumably was a consequence of (i) free radical reactions, possibly involving semiquinones and oxygen free radicals, and (ii) reaction of direct-acting electrophiles, derived from metabolism of WPW toxicants by soil microorganisms. These reactions appeared to be more active in sample 2. The results suggest that ground water at WPW sites contains DNA-reactive compounds posing a cancer hazard to humans. The in vitro DNA adduct assay represents a novel tool to readily assess this type of hazard and the possible effects of remediation measures.