Induction of rat liver DNA alterations by chronic administration of peroxisome proliferators as detected by 32P-postlabeling

PPARα Agonist-Induced Rodent Tumors: Modes of Action and Human Relevance

Widely varied chemicals--including certain herbicides, plasticizers, drugs, and natural products--induce peroxisome proliferation in rodent liver and other tissues. This phenomenon is characterized by increases in the volume density and fatty acid oxidation of these organelles, which contain hydrogen peroxide and fatty acid oxidation systems important in lipid metabolism. Research showing that some peroxisome proliferating chemicals are nongenotoxic animal carcinogens stimulated interest in developing mode of action (MOA) information to understand and explain the human relevance of animal tumors associated with these chemicals. Studies have demonstrated that a nuclear hormone receptor implicated in energy homeostasis, designated peroxisome proliferator-activated receptor alpha (PPARalpha), is an obligatory factor in peroxisome proliferation in rodent hepatocytes. This report provides an in-depth analysis of the state of the science on several topics critical to evaluating the relationship between the MOA for PPARalpha agonists and the human relevance of related animal tumors. Topics include a review of existing tumor bioassay data, data from animal and human sources relating to the MOA for PPARalpha agonists in several different tissues, and case studies on the potential human relevance of the animal MOA data. The summary of existing bioassay data discloses substantial species differences in response to peroxisome proliferators in vivo, with rodents more responsive than primates. Among the rat and mouse strains tested, both males and females develop tumors in response to exposure to a wide range of chemicals including DEHP and other phthalates, chlorinated paraffins, chlorinated solvents such as trichloroethylene and perchloroethylene, and certain pesticides and hypolipidemic pharmaceuticals. MOA data from three different rodent tissues--rat and mouse liver, rat pancreas, and rat testis--lead to several different postulated MOAs, some beginning with PPARalpha activation as a causal first step. For example, studies in rodent liver identified seven "key events," including three "causal events"--activation of PPARalpha, perturbation of cell proliferation and apoptosis, and selective clonal expansion--and a series of associative events involving peroxisome proliferation, hepatocyte oxidative stress, and Kupffer-cell-mediated events. Similar in-depth analysis for rat Leydig-cell tumors (LCTs) posits one MOA that begins with PPARalpha activation in the liver, but two possible pathways, one secondary to liver induction and the other direct inhibition of testicular testosterone biosynthesis. For this tumor, both proposed pathways involve changes in the metabolism and quantity of related hormones and hormone precursors. Key events in the postulated MOA for the third tumor type, pancreatic acinar-cell tumors (PACTs) in rats, also begin with PPARalpha activation in the liver, followed by changes in bile synthesis and composition. Using the new human relevance framework (HRF) (see companion article), case studies involving PPARalpha-related tumors in each of these three tissues produced a range of outcomes, depending partly on the quality and quantity of MOA data available from laboratory animals and related information from human data sources.

Modes of action and species-specific effects of di-(2-ethylhexyl)phthalate in the liver

The industrial plasticizer di-(2-ethylhexyl)phthalate (DEHP) is used in manufacturing of a wide variety of polyvinyl chloride (PVC)-containing medical and consumer products. DEHP belongs to a class of chemicals known as peroxisome proliferators (PPs). PPs are a structurally diverse group of compounds that share many (but perhaps not all) biological effects and are characterized as non-genotoxic rodent carcinogens. This review focuses on the effect of DEHP in liver, a primary target organ for the pleiotropic effects of DEHP and other PPs. Specifically, liver parenchymal cells, identified herein as hepatocytes, are a major cell type that are responsive to exposure to PPs, including DEHP; however, other cell types in the liver may also play a role. The PP-induced increase in the number and size of peroxisomes in hepatocytes, so called 'peroxisome proliferation' that results in elevation of fatty acid metabolism, is a hallmark response to these compounds in the liver. A link between peroxisome proliferation and tumor formation has been a predominant, albeit questioned, theory to explain the cause of a hepatocarcinogenic effect of PPs. Other molecular events, such as induction of cell proliferation, decreased apoptosis, oxidative DNA damage, and selective clonal expansion of the initiated cells have been also been proposed to be critically involved in PP-induced carcinogenesis in liver. Considerable differences in the metabolism and molecular changes induced by DEHP in the liver, most predominantly the activation of the nuclear receptor peroxisome proliferator-activated receptor (PPAR)alpha, have been identified between species. Both sexes of rats and mice develop adenomas and carcinomas after prolonged feeding with DEHP; however, limited DEHP-specific human data are available, even though exposure to DEHP and other phthalates is common in the general population. This likely constitutes the largest gap in our knowledge on the potential for DEHP to cause liver cancer in humans. Overall, it is believed that the sequence of key events that are relevant to DEHP-induced liver carcinogenesis in rodents involves the following events whereby the combination of the molecular signals and multiple pathways, rather than a single hallmark event (such as induction of PPARalpha and peroxisomal genes, or cell proliferation) contribute to the formation of tumors: (i) rapid metabolism of the parental compound to primary and secondary bioactive metabolites that are readily absorbed and distributed throughout the body; (ii) receptor-independent activation of hepatic macrophages and production of oxidants; (iii) activation of PPARalpha in hepatocytes and sustained increase in expression of peroxisomal and non-peroxisomal metabolism-related genes; (iv) enlargement of many hepatocellular organelles (peroxisomes, mitochondria, etc.); (v) rapid but transient increase in cell proliferation, and a decrease in apoptosis; (vi) sustained hepatomegaly; (vii) chronic low-level oxidative stress and accumulation of DNA damage; (viii) selective clonal expansion of the initiated cells; (ix) appearance of the pre-neoplastic nodules; (x) development of adenomas and carcinomas.

Tissue-specific attenuation of endogenous DNA I-compounds in rats by carcinogen azoxymethane: possible role of dietary fish oil in colon cancer prevention

I-compounds are bulky covalent DNA modifications that are derived from metabolic intermediates of nutrients. Some I-compounds may play protective roles against cancer, aging, and degenerative diseases. Many carcinogens and tumor promoters significantly reduce I-compound levels gradually during carcinogenesis. Colon cancer is the second leading cause of cancer death in the United States, whereas cancer of the small intestine is relatively rare. Here we have studied levels of I-compounds in DNA of colon and duodenum of male Sprague-Dawley rats treated with azoxymethane. The effects of dietary lipids (fish oil or corn oil) on colon and duodenal DNA I-compounds were also investigated. Rats fed a diet containing fish oil or corn oil were treated with 15 mg/kg azoxymethane. Animals were terminated 0, 6, 9, 12, or 24 hours after injection. I-compound levels were analyzed by the nuclease P1-enhanced (32)P-postlabeling assay. Rats treated with azoxymethane displayed lower levels of I-compounds in colon DNA compared with control groups (0 hour). However, I-compound levels in duodenal DNA were not diminished after azoxymethane treatment. Animals fed a fish oil diet showed higher levels of I-compounds in colonic DNA compared with corn oil groups (mean adduct levels for fish and corn oil groups were 13.35 and 10.69 in 10(9) nucleotides, respectively, P = 0.034). Taken together, these results support claims that fish oil, which contains a high level of omega-3 polyunsaturated fatty acids, may have potent chemopreventive effects on carcinogen-induced colon cancer. The fact that duodenal I-compounds were not diminished by azoxymethane treatment may have been due to the existence of tissue-specific factors protecting against carcinogenesis. In conclusion, our observations show that endogenous DNA adducts may serve not only as sensitive biomarkers in carcinogenesis and cancer prevention studies, but are also helpful to further our understanding of the chemopreventive properties of omega-3 fatty acids and mechanisms of carcinogenesis.

Methods for testing compounds for DNA adduct formation

This article, based on a presentation on DNA adduct detection given at a Genetic Toxicology Association workshop, is an overview of methods used for testing compounds for DNA adduct formation. A DNA adduct study may be initiated on a case by case basis when there are conflicting results within the standard battery of genetic toxicology tests or when tumors are detected in the animal bioassay for nongenotoxic compounds. Methods for adduct detection include the 32P-postlabeling assay, the use of radioactive test chemicals, physicochemical methods, and immunoassays. Of these, the 32P-postlabeling assay and the use of radiochemicals are discussed in greater detail, since only these two methods are readily applicable to test a compound for the formation of uncharacterized DNA adducts. The other methods are applicable to those adducts that have been chemically characterized or that contain a fluorophore or electrochemically active groups. Evaluation of mutagenic and carcinogenic risk from DNA adducts would require the understanding of various parameters, including the chemical nature, quantity and stability of adducts, proliferation rates for target cells to fix adducts into mutations, mutagenic and repair efficiencies of adducts, and the extent of modifications in critical genes. Since such data cannot be readily obtainable, the toxicological risk from uncharacterized adducts is difficult to assess.

Hydrogen peroxide generation in peroxisome proliferator-induced oncogenesis

Peroxisome proliferators are a structurally diverse group of non-genotoxic chemicals that induce predictable pleiotropic responses including the development of liver tumors in rats and mice. These chemicals interact variably with peroxisome proliferator-activated receptors (PPARs), which are members of the nuclear receptor superfamily. Evidence derived from mice with PPARalpha gene disruption indicates that of the three PPAR isoforms (alpha, beta/delta and gamma), the isoform PPARalpha is essential for the pleiotropic responses induced by peroxisome proliferators. Peroxisome proliferator-induced activation of PPARalpha leads to profound transcriptional activation of genes encoding for the classical peroxisomal beta-oxidation system and cytochrome P450 CYP 4A isoforms, CYP4A1 and CYP4A3, among others. Livers with peroxisome proliferation manifest substantial increases in the expression of H(2)O(2)-generating peroxisomal fatty acyl-CoA oxidase, the first enzyme of the classical peroxisomal fatty acid beta-oxidation system, and of microsomal cytochrome P450 4A1 and 4A3 genes. Disproportionate increases in H(2)O(2)-generating enzymes and H(2)O(2)-degrading enzyme catalase and reductions in glutathione peroxidase activity by peroxisome proliferators, lead to increased oxidative stress in liver cells. Sustained oxidative stress resulting from chronic increases in H(2)O(2)-generating enzymes manifests as massive accumulation of lipofuscin in hepatocytes, and increased levels of 8-hydroxydeoxyguanosine adducts in liver DNA; this supports the hypothesis that oxidative stress plays a critical role in the development of liver tumors induced by these non-genotoxic chemical carcinogens. Evidence also indicates that cells stably overexpressing H(2)O(2)-generating fatty acyl-CoA oxidase or urate oxidase, when exposed to appropriate substrate(s), reveal features of neoplastic conversion including growth in soft agar and formation of tumors in nude mice. Mice with disrupted fatty acyl-CoA oxidase gene (AOX(-/-) mice), which encodes the first enzyme of the PPARalpha regulated peroxisomal beta-oxidation system, exhibit profound spontaneous peroxisome proliferation, including development of liver tumors, indicative of sustained activation of PPARalpha by the unmetabolized substrates of acyl-CoA oxidase. With the exception of fatty acyl-CoA oxidase, all PPARalpha responsive genes including CYP4A1 and CYP4A3 are up-regulated in the livers of these AOX(-/-) mice. Thus, the substrates of acyl-CoA oxidase serve as endogenous ligands for this receptor leading to a receptor-enzyme cross-talk, because acyl-CoA oxidase gene is transcriptionally regulated by PPARalpha. Peroxisome proliferators induce only a transient increase in liver cell proliferation and this may serve as an additional contributory factor, rather than play a primary role in liver tumor development. Thus, sustained activation of PPARalpha by either synthetic or natural ligands leads to reproducible pleiotropic responses culminating in the development of liver tumors. This phenomenon of peroxisome proliferation provides fascinating challenges in exploring the molecular mechanisms of cell specific transcription, and in identifying the PPARalpha responsive target genes, as well as events involved in their regulation. Genetically altered animals and cell lines should enable investigations on the role of H(2)O(2)-producing enzymes in neoplastic conversion.

Comparison of the effects of various peroxisome proliferators on peroxisomal enzyme activities, DNA synthesis, and apoptosis in rat and human hepatocyte cultures

Peroxisome proliferators (PPs) are a class of rodent nongenotoxic hepatocarcinogens that cause hepatocyte peroxisome proliferation, increased DNA synthesis, and decreased spontaneous apoptosis. We examined the effects of various PPs such as the hypolipidemic agents clofibric acid (CLO), bezafibrate (BEZA), ciprofibrate (CIPRO), and nafenopin (NAFE) and the plasticizer di-(2-ethylhexyl)phthalate (DEHP) on the various parameters in vitro in rat and human hepatocyte cultures. In rat hepatocyte cultures, after 72 h of treatment with the various PPs at 100-500 microM, a compound-dependent increase in acyl CoA oxidase (ACO) and carnitine acetyl transferase (CAT) activities, markers of peroxisome proliferation, was observed with the following potencies: CIPRO = NAFE > BEZA > CLO > DEHP. A minor (120-150%), but significant, no concentration-dependent increase in DNA synthesis and a marked, no compound-dependent and, with the exception of NAFE, no concentration-dependent 60-80% decrease in spontaneous apoptosis was observed with all tested compounds (50-250 microM) after 48 h of treatment. Inhibition of spontaneous apoptosis in PP-treated versus control rat hepatocyte cultures was also observed morphologically. Furthermore, PPs inhibited transforming growth factor beta (TGFbeta)-induced apoptosis but not tumor necrosis factor alpha (TNFalpha)/alpha Amanitine (alphaAma)-induced apoptosis in rat hepatocyte cultures. In human hepatocyte cultures, the various PPs at 50-500 microM did not affect peroxisomal enzyme activities, DNA synthesis, or spontaneous and induced (TGFbeta or TNFalpha/alphaAma) apoptosis. The compound-dependent peroxisome proliferation but no compound-dependent disruption of the mitogenic/apoptotic balance elicited by PPs in primary rat hepatocyte cultures supports the hypothesis that oxidative stress is directly linked to the hepatocarcinogenic potential of a given PP in rodents and that disruption of the mitogenic/apoptotic balance contributes to the development of PP-induced hepatocarcinogenesis. In addition, the absence of effects of all PPs on both peroxisome proliferation-associated parameters and mitogenic/apoptotic balance supports the hypothesis that human liver cells are refractory to PP-induced hepatocarcinogenesis.

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.

Adduct formation, mutagenesis and nucleotide excision repair of DNA damage produced by reactive oxygen species and lipid peroxidation product

Reactive oxygen species are formed constantly in living organisms, as products of the normal metabolism, or as a result of many different environmental influences. Here we review the knowledge of formation of DNA damage, the mutations caused by reactive oxygen species and the role of the excision repair processes, that protect the organism from oxidative DNA damage. In particular, we have focused on recent studies that demonstrate the important role of nucleotide excision repair. We propose two major roles of nucleotide excision repair as 1) a backup when base excision repair of small oxidative lesions becomes saturated, and as 2) a primary repair pathway for DNA damage produced by lipid peroxidation products.

Biochemistry of peroxisomes in health and disease

The ubiquitous distribution of peroxisomes and the identification of a number of inherited diseases associated with peroxisomal dysfunction indicate that peroxisomes play an essential part in cellular metabolism. Some of the most important metabolic functions of peroxisomes include the synthesis of plasmalogens, bile acids, cholesterol and dolichol, and the oxidation of fatty acids (very long chain fatty acids > C22, branched chain fatty acids (e.g. phytanic acid), dicarboxylic acids, unsaturated fatty acids, prostaglandins, pipecolic acid and glutaric acid). Peroxisomes are also responsible for the metabolism of purines, polyamines, amino acids, glyoxylate and reactive oxygen species (e.g. O-2 and H2O2). Peroxisomal diseases result from the dysfunction of one or more peroxisomal metabolic functions, the majority of which manifest as neurological abnormalities. The quantitation of peroxisomal metabolic functions (e.g. levels of specific metabolites and/or enzyme activity) has become the basis of clinical diagnosis of diseases associated with the organelle. The study of peroxisomal diseases has also contributed towards the further elucidation of a number of metabolic functions of peroxisomes.

Use of rat and human liver slices for the detection of steroid hormone-induced DNA-adducts in vitro by means of the (32)P-postlabeling technique

Precision cut liver slices from humans and rats were used to investigate the covalent binding of xenobiotics to the DNA by means of the (32)P-postlabeling technique. Human liver slices were incubated with the structurally related steroid hormones chlormadinone acetate (5 mu g/ml), cyproterone acetate (0.01-5 mu g/ml), megestrol acetate (5 mu g/ml), and the positive control 2-aminofluorene (0.01-5 mu g/ml), which is known for its marked ability to form DNA-adducts in vivo. Rat liver slices were incubated with cyproterone acetate in concentrations of 0.1, 1, and 5 mu g/ml. The functional viability and metabolic activity of the slices were shown to be sufficiently maintained during the incubation time by measurement of the intracellular K(+)-content and the metabolic turnover of the model substrate 7-ethoxycoumarin, respectively. All three test substances and the control induced DNA-adducts in human liver slices, however, with a different adduct pattern. While the total DNA-adduct levels obtained with cyproterone acetate and megestrol acetate were in the same order of magnitude (on average 1000 DNA-adducts/10(9) nucleotides after incubation with 5 mu g /ml), the relative adduct labeling calculated for chlormadinone acetate was about 400. Following in vitro incubation of rat liver slices with cyproterone acetate, the relative adduct labeling values increased proportionally with increasing concentrations and added linearily to in vivo generated DNA-adducts. At the level of liver slices, different DNA-adduct patterns were induced by cyproterone acetate in rat and man. In contrast to the finding of others, using rat hepatocytes, the relative adduct labeling values of cyproterone acetate and megestrol acetate were in the same order of magnitude after incubation with human liver slices. The present study indicates that liver slices are a useful tool to investigate the in vitro DNA-adduct inducing potential of xenobiotics.

Induction of peroxisome proliferation and increase of catalase activity in yeast, Candida albicans, by cadmium

The effects of cadmium on the growth rate, catalase activity, and peroxisome proliferation in yeast, Candida albicans, were evaluated. The yeast growth was markedly inhibited by 1 mM cadmium at the initial hours. The toxic effect of cadmium on the cell growth persisted. The catalase activity of the cells treated with 1 mM Cd2+ first decreased, and then rose at 24 h to about 2.6 times that of the controls. The average number of peroxisomes per cell in the yeast treated with 1 mM Cd2+ was about sixfold higher than the control groups. The proliferation of peroxisomes and the increase of catalase activity following cadmium toxicity gives credence to the hypothesis that cadmium toxicity is related to its potential to induce oxidative stress in cells.

Rapid decreases in indigenous covalent DNA modifications (I-compounds) of male Fischer-344 rat liver DNA by diquat treatment

I-compounds are indigenously appearing covalent DNA modifications that can be detected by 32P-postlabeling assay in tissues of normal animals without known exposure to any carcinogens or toxins. Although these compounds have not been structurally identified, indirect evidence from earlier work suggested the possibility of involvement of molecular fragments derived from lipid peroxides. Diquat is a herbicide that stimulates lipid peroxidation and massive intrahepatic oxidant stress through redox cycling-mediated generation of reactive oxygen species. In the present study, we examined the effects of diquat on hepatic I-compounds of male Fischer-344 rats. Two groups of rats, approximately 14 weeks and 8 weeks old, were given a hepatotoxic dose (0.1 mmol/kg) of diquat or equal volumes of saline, i.p. Two and 6 h later plasma alanine aminotransferase (ALT) activities were measured and hepatic DNA I-compound levels were examined by nuclease P1-enhanced 32P-postlabeling. Elevated ALT activities were observed in some animals in both groups, at both time points, but considerable inter-animal variation was seen. A total of 15-16 I-compound fractions were measured in control and in diquat-treated animals, but no extra spots indicative of treatment-induced adducts were detected. Despite the qualitative similarities, the quantities of individual I-compounds were markedly decreased at 2 h in diquat-treated animals of both age groups. In 14 week old rats the hepatic I-compound contents were decreased at 2 h by 22-59%, which was statistically significant (ANOVA, P < 0.05) for all of the 9 polar I-compound fractions and none of the non-polar fractions. Eleven I-spots from this group showed significant negative linear correlations (P < 0.05) with ALT values. In 8 week old rats treated with diquat a 22-43% depletion in I-compound contents was statistically significant for 4 of the 7 nonpolar and 2 of the 8 polar adduct fractions, but there was no significant correlation of I-compound contents with ALT values at the 2 h time point. By 6 h most of the I-spot levels had returned to normal or above normal values in both groups of animals. While most I-spots from 14 week old rats did not correlate with ALT levels at 6 h, two I-spots displayed positive correlations in the 8 week group. Overall, the susceptibility to diquat-associated DNA alterations appeared to differ with age.(ABSTRACT TRUNCATED AT 400 WORDS)

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.

Biomarkers of aging: correlation of DNA I-compound levels with median lifespan of calorically restricted and ad libitum fed rats and mice

I-compounds are species-, tissue-, genotype-, gender-, and diet-dependent bulky DNA modifications whose levels increase with animal age. While a few of these DNA modifications represent oxidation products, the majority of I-compounds appear to be derived from as yet unidentified endogenous DNA-reactive intermediates other than reactive oxygen species. Circadian rhythms of certain I-compounds in rodent liver imply that levels of these DNA modifications are precisely regulated. Caloric restriction (CR), the currently most effective method available to retard aging and carcinogenesis, has been previously shown to elicit significant elevations of I-compound levels in tissue DNA from Brown-Norway (BN) and F-344 rats as compared to age-matched ad libitum fed (AL) animals. The present investigation has extended this work by examining liver and kidney DNA I-compound levels in three genotypes of rats (F-344, BN, and F-344 x BN) and two genotypes of mice (C57BL/6N and B6D2F1) under identical experimental conditions in order to determine whether correlations exist between I-compound levels, measured in middle-aged animals, and median lifespan. Levels of a number of liver and kidney I-compounds were found to display genotype- and diet-dependent, statistically significant positive linear correlations with median lifespan in both species. In particular, the longer-lived hybrid F-344 x BN rats and B6D2F1 mice tended to exhibit higher I-compound levels than the parent strains. CR enhanced I-compound levels substantially in both rats and mice. Thus, I-compounds, measured at middle age, reflected the functional capability ('health') of the organism at old age, suggesting their predictive value as biomarkers of aging. The positive linear correlations between levels of certain I-compounds (designated as type I) and lifespan suggest that these modifications may be functionally important and thus not represent endogenous DNA lesions (type II), whose levels would be expected to correlate inversely with lifespan.

Effects of polychlorinated dibenzofurans on compounds in hepatic DNA of female Sprague-Dawley rats: structure dependence and mechanistic considerations

Previous work indicated that covalent age-dependent DNA modifications of endogenous origin termed I-compounds may represent useful biomarkers for tumor promotion/carcinogenesis, as various tumor promoters/carcinogens, including 2,3,7,8-tetrachlorodibenzo-p-dioxin (TCDD) and phenobarbital, reduce rat I-compound levels in liver, the target organ. The present study addressed the question as to whether polychlorinated dibenzofurans (PCDFs), which are related to TCDD and its congeners with regard to their toxic and biochemical properties, would also affect hepatic I-compound patterns and levels, and whether such effects would be chemical structure-dependent. Female Sprague-Dawley rats were treated once a week with a single dose (100 micrograms/kg) of 1,2,3,7,8-pentachlorodibenzofuran (1,2,3,7,8-PeCDF), 1,2,4,7,8-PeCDF, 2,3,4,7,8-PeCDF, or 2,3,4,6,7,8-hexachlorodibenzofuran (2,3,4,6,7,8-HeCDF) for 4 weeks and liver DNA was analyzed at the end of the last week by 32P-postlabeling assay. No carcinogen-DNA adducts were detected; however, levels of both non-polar and polar I-compounds were reduced in a structure-dependent manner. Potencies increased in the order, control (100%, 122 modifications in 10(9) DNA nucleotides = 1,2,4,7,8-PeCDF (104%) < 1,2,3,7,8-PeCDF (80%) < 2,3,4,7,8-PeCDF (61%) and 2,3,4,6,7,8-HeCDF (61%). Structure-activity relationships for total I-compounds, therefore, paralleled those reported for Ah receptor agonist activity, i.e., compounds that exhibit high cytosolic Ah receptor binding affinities and are also potent inducers of aryl hydrocarbon hydroxylase activity (1,2,3,7,8-PeCDF, 2,3,4,7,8-PeCDF, and 2,3,4,6,7,8-HeCDF) were active, while 1,2,4,7,8-PeCDF, which is a less potent Ah receptor agonist, was inactive. Polar I-compounds responded to a greater extent than did non-polar ones and, in general, individual I-compounds were affected differentially, thus decreased formation or increased removal of I-compounds played a role in the observed effects of the toxins on DNA. It is proposed that Ah receptor-mediated enzyme induction, particularly of cytochrome P450, is involved in reduced hepatic I-compound formation and that subnormal I-compound levels may contribute to tumor promotion.

Fatty-acid metabolism and the pathogenesis of hepatocellular carcinoma: review and hypothesis

Despite increasing understanding of the genetic control of cell growth and the identification of several involved chemical and infectious factors, the pathogenesis of clinical and experimental hepatocellular carcinoma remains unknown. Available evidence is consistent with the possibility that selected changes in the hepatocellular metabolism of long-chain fatty acids may contribute significantly to this, process. Specifically, studies of the peroxisome proliferators, a diverse group of xenobiotics that includes the fibrate class of hypolipidemic drugs, suggest that increased fatty acid oxidation by way of extramitochondrial pathways (i.e., omega-oxidation in the smooth endoplasmic reticulum and beta-oxidation in the peroxisomes) results in a corresponding increase in the generation of hydrogen peroxide and, thus, oxidative stress. This in turn leads to alterations in gene expression and in DNA itself. We also review evidence supporting a potentially decisive influence of particular aspects of hepatocellular fatty acid metabolism in determining the activity of the extramitochondrial pathways. Moreover, certain intermediates of extramitochondrial fatty acid oxidation (e.g., the long-chain dicarboxylic fatty acids) impair mitochondrial function and are implicated as modulators of gene expression through their interaction with the peroxisome proliferator-activated receptor. Finally, the occurrence of hepatic tumors in type I glycogen storage disease (glucose-6-phosphatase deficiency) may exemplify this general mechanism, which may also contribute to nonneoplastic liver injury and to tumorigenesis in other tissues.

Effects of perfluoro fatty acids on peroxisome proliferation and mitochondrial size in mouse liver: dose and time factors and effect of chain length

1. Male mice were fed a diet containing perfluoro fatty acids of varying chain length (i.e. perfluoroacetic, -butyric, -octanoic and -decanoic acids) at different doses (0.02 or 0.1% w/w of diet) for different periods of time (2-10 days), and effects on liver weight, hepatic mitochondrial protein and hepatic peroxisomal palmitoyl-CoA oxidation, lauroyl-CoA oxidase and catalase were monitored. 2. The greatest effects were obtained with perfluoro-octanoic and perfluoro decanoic acids, while perfluoro acetic acid was inactive. The effects with 0.02% w/w of diet perfluoro-octanoic acid were at least as great as those observed with 0.1%. A more detailed dose-response investigation focused on perfluoro-octanoic acid revealed that maximal effects with this substance could be obtained with a dietary dose of 0.01% for 10 days and that significant changes were also observed with 0.001%. 3. Maximal effects with 0.02% w/w of diet perfluoro-octanoic acid were attained after 6-10 days of feeding. 4. As with other peroxisome proliferators, perfluoro fatty acids increase mouse hepatic peroxisomal fatty acid beta-oxidation more extensively than they increase catalase, thus increasing hepatic oxidative stress. 5. As with other peroxisome proliferators, perfluoro fatty acids increase mouse liver mitochondrial protein. This effect is due primarily to a redistribution of mitochondria from the nuclear to the mitochondrial fraction, caused by an apparent decrease in the mean size of hepatic mitochondria after treatment.

Activation of immediate-early gene expression by peroxisome proliferators in vitro

The hepatocarcinogenicity of peroxisome proliferators (PPs) in rodents has been attributed both to oxidative DNA damage resulting from excessive leakage of peroxisomal H2O2 and to increased hepatocellular replication that may be independent of peroxisome proliferation. Because of the growing association between tumor promotion and alterations in growth-regulatory signal transduction pathways, we investigated whether PPs can modulate these pathways in a mouse liver epithelial cell line, BNL-CL.2. We tested two PPs that differ markedly in rodent tumorigenicity for their ability to activate immediate-early proto-oncogene expression. 4-Chloro-6-(2,3-xylidino)-2-pyrimidinylthioacetic acid (Wy-14643), a highly tumorigenic PP, was an exceptionally strong inducer of c-fos expression. Wy-14643 was also stronger than DEHP in stimulating c-jun expression, whereas both PPs were fairly strong inducers of jun-B and jun-D. The induction of fos and jun expression by Wy-14643 was specifically inhibited by the protein kinase C inhibitor 1-(5-isoquinolinesulfonyl)-2-methylpiperizine dihydrochloride (H-7). DEHP-induced gene expression was strongly inhibited by H-7, but was also partially inhibited by an inhibitor of protein kinase A. The activation of fos and jun gene expression by PPs was independent of peroxisome proliferation since it was an immediately-early response not requiring protein synthesis and since the cell lines used in this study do not undergo peroxisome proliferation. Our r results raise the possibility that the carcinogenicity of PPs may be due, in part, to epigenetic modulation of growth-regulatory signal transduction pathways.

Enhancement of age-related increases in DNA I-compound levels by calorie restriction: comparison of male B-N and F-344 rats

Caloric restriction (CR), known to extend median and maximum life spans, improve resistance to carcinogenesis, and significantly retard age-associated degenerative diseases in rodents, was previously reported to modulate levels of indigenous, age-dependent DNA modifications, called I-compounds, in male Brown-Norway (B-N) rats. Since profiles of these adduct-like derivatives are species-, strain-, sex-, and tissue-specific, we explored this apparent CR/I-compound relationship in a comparative study between male B-N and male Fischer 344 (F-344) rats, the latter having a shorter life expectancy and high incidence of renal disease. Control animals were fed NIH-31 diet ad libitum (AL), while the caloric intake of CR animals was limited to 60% of AL, starting at 3.5 months. Liver and kidney DNA from 1, 8, 12, 16, 24 (AL, CR), and 30 (CR only) month old rats was analyzed by 32P-postlabeling. Corresponding tissues from the two strains yielded similar DNA profiles. Total liver I-compound levels displayed 2.3-4.6-fold age-dependent increases from 1 to 24 months, and kidney values at 24 months were 5.2-8 times higher than those at 1 month. In both strains, I-compound levels of CR animals were higher, up to 2-fold, than in age-matched AL rats. Regression analyses indicated linear relationships between most CR relative adduct labeling values (both total and individual fractions) and age, whereas many AL values exhibited this type of link with log age. These findings confirm that a correlation exists between CR and I-compound levels, and, given the above physiological benefits of CR, indicate that I-compounds represent biomarkers of aging with potential utility in intervention studies.

Lack of mutations of the p53 tumor suppressor gene in hepatocellular carcinomas induced in rats by a peroxisome proliferator

Immunohistochemical, immunoblotting, and DNA-sequencing analyses were performed on hepatocellular carcinomas induced in rats chronically fed BR931, a peroxisome proliferator, to determine whether the tumors carried mutations or other alterations of the p53 gene. None were detected. Inactivation of this tumor suppressor gene does not appear, therefore, to be involved in the carcinogenicity of BR931, a nongenotoxic chemical hepatocarcinogen.

The molecular mechanism of peroxisome proliferator action: a model for species differences and mechanistic risk assessment

An increasing number of chemicals that produce tumours in rodent bioassays belong to the non-genotoxic class of carcinogens. There are no suitable tests for these carcinogens and our understanding of their mechanism of action is poor. Importantly, assessment of their potential hazard to man is usually difficult without extensive research. Peroxisome proliferators (PP) are a diverse group of rodent non-genotoxic carcinogens that include hypolipidemic drugs, plasticizers and herbicides. We have reported previously the cloning of a member of the nuclear hormone receptor superfamily and, through the use of chimeric receptors, discovered that it could be activated by PPs. The receptor is therefore termed the PP activated receptor (PPAR). The most widely used marker of PP action is the peroxisomal beta-oxidation enzyme acyl CoA oxidase (ACO). Interestingly, it has been speculated that the hydrogen peroxide produced as a result of ACO activity could lead to DNA damage and tumorigenesis. We have now demonstrated that PPAR recognizes a specific PP response element (PPRE) located in the ACO gene promoter and that the response is dependent upon the presence of receptor and the addition of the PP Wy-14,643. These data therefore support a model in which the mechanism of PP action is mediated by PPAR in a manner similar to that of steroid hormone action. Learning more about the function of PPAR offers a unique opportunity to understand the mechanism of action of some non-genotoxic carcinogens. Furthermore, this knowledge when combined with comparison of receptor expression between rodents and man will be important in providing a framework for a new threshold model of risk assessment based upon receptor-mediated carcinogenesis.

Effects of perfluoro fatty acids on xenobiotic-metabolizing enzymes, enzymes which detoxify reactive forms of oxygen and lipid peroxidation in mouse liver

Male mice were exposed via their diet to perfluoro fatty acids of various chain-lengths (2-10 carbon atoms) at different doses (0.02 and 0.1% weight) and for different periods of time (2-10 days). Thereafter, we monitored effects on liver and body weights and a number of hepatic parameters, including mitochondrial protein content, microsomal contents of cytochromes P450 and b5, NADPH-cytochrome P450 reductase activity [measured as NADPH-cytochrome c reductase (EC 1.6.2.3)], microsomal and cytosolic epoxide hydrolase (EC 3.3.2.3) activities, cytosolic DT-diaphorase (EC 1.6.99.2), glutathione transferase (EC 2.5.1.18), glutathione peroxidase (EC 1.11.1.9) and superoxide dismutase (EC 1.15.1.1) activities, and levels of thiobarbituric acid-reactive material (as an indicator of lipid peroxidation) in the mitochondrial subfraction. The most dramatic changes observed were a 5-9-fold increase in mitochondrial protein, a 3-6-fold increase in the microsomal content of cytochrome P450, a 3-10-fold increase in cytosolic DT-diaphorase activity, an approximately 2-fold increase in cytosolic epoxide hydrolase activity and as much as a 60% decrease in the level of thiobarbituric acid-reactive compounds in the mitochondrial fraction. Smaller increases in microsomal epoxide hydrolase activity and decreases in cytosolic glutathione peroxidase activity were also observed. Of the perfluoro fatty acids tested, perfluorooctanoic acid caused the largest changes in the parameters examined here. Dietary exposure of mice to a 0.02% dose of this substance for 10 days results in a maximal or near-maximal effect in most cases.

Exogenous and endogenous DNA modifications as monitored by 32P-postlabeling: relationships to cancer and aging

32P-postlabeling analysis, a highly sensitive method for the detection and measurement of covalent carcinogen-DNA adducts and other DNA modifications, does not require radioactive test substances and, therefore, can be applied to DNA of mammals, including humans exposed to low doses of environmental or occupational genotoxicants. The basic procedure entails the enzymatic incorporation of 32P-label into hydrolysis products of DNA, followed by chromatographic mapping and autoradiography of the 32P-labeled digestion products and quantitative scintillation spectrometry. Microgram amounts of DNA are analyzed: Thus the assay is suited for limited amounts of cells or tissues. Various versions of the assay afford different sensitivities of adduct detection. A single aromatic or bulky/hydrophobic adduct in 10(8)-10(10) nucleotides can be detected and measured (corresponding to 0.3-30 amol adduct/micrograms DNA or 0.1-10 nmol adduct/mol DNA-P). In animal models, the assay has been successfully applied to a variety of mutagenic (genotoxic) as well as nonmutagenic carcinogens. In humans, DNA specimens from cigarette smokers, iron foundry workers, and coke oven workers whose total aromatic adduct levels ranged from 1 adduct in 10(6)-10(8) DNA nucleotides have been examined by 32P-postlabeling. The assay also detects DNA modifications--Indigenous (I)-compounds--that increase with age in untreated animals. I-compound profiles and levels are highly species-, strain-, sex-, and tissue-specific, and also depend on diet composition. Caloric restriction, a highly efficient method for improving resistance to carcinogenesis and extending life span, increased rather than decreased I-compound levels in various tissues of male rats. Nonmutagenic hepatocarcinogens reduced levels of I-compounds in the target organ. Because of the specificity of this effect, reduction of I-compound levels appears to represent a novel biomarker for the action of nonmutagenic carcinogens. DNA from various hepatomas was found largely devoid of I-compounds. The results support a possible antineoplastic and antiaging role of these DNA modifications.

Sex-specific modulation of hepatic covalent DNA modifications (I-compounds) by the cytochrome P450 inducer, pregnenolone-16 alpha-carbonitrile

I-compounds are recently discovered, age-dependent covalent DNA modifications, which are detectable by 32P-postlabeling assay for DNA adducts. The effects of the catatoxic antiglucocorticoid, pregnenolone-16 alpha-carbonitrile (PCN), on hepatic and renal I-compound levels have been studied in male and female Sprague-Dawley rats together with the levels of microsomal cytochrome P450 and rates of ethylmorphine N-demethylation. PCN (50 mg/kg ip) was dissolved in corn oil and administered to rats once daily for 4 days, and animals were killed at 1 day or 8 days after the last treatment. Hepatic and renal I-compounds were analyzed by 32P-postlabeling in control and PCN-treated animals at both time points. Microsomal cytochrome P450 and ethylmorphine N-demethylase activities were also determined. Total levels of liver nonpolar and polar I-compounds were reduced in female rats by 37 and 51%, respectively, compared to controls, at 1 day. Ten out of sixteen individual I-compounds were also markedly reduced in female rat liver DNA as a result of PCN administration. In contrast to females, total levels of liver I-compounds were not significantly altered in males by PCN at 1 day; however, two individual I-compounds were lowered. I-compound levels recovered 8 days after termination of PCN treatment in both males and females. Total levels of renal I-compounds were not affected by PCN treatment in either males or females. [3H]Methylthymidine incorporation studies showed an increase in mean DNA synthesis rate at 1 day in liver of both males and females, but this was significant in males only. Marked induction of hepatic microsomal cytochrome P450 (2.2-fold) and ethylmorphine N-demethylase (4.0-fold) activity was observed in female rats treated with PCN at 1 day as compared to controls. The extent of induction of these enzymes was much higher in females than males. At 8 days the levels of cytochrome P450 and ethylmorphine N-demethylase activity had returned to uninduced values. The results are consistent with a pivotal role for PCN-inducible cytochrome P450 in the metabolism of I-compounds.

Natural dietary ingredients (oats and alfalfa) induce covalent DNA modifications (I-compounds) in rat liver and kidney

Mammalian tissue DNA has recently been found, via 32P postlabeling, to contain complex profiles of age-dependent bulky carcinogen adductlike covalent modifications, which have been termed I-compounds, referring to their apparent indigenous origin without exposure to exogenous carcinogens. I-compound patterns are highly species, sex, tissue, and diet specific. As shown here, the presence of certain plant ingredients in diet, i.e., ground oats and alfalfa meal, significantly contributed to the formation of these DNA derivatives. Six groups of weanling female Sprague-Dawley rats were fed one of the following diets for three months: a natural ingredient diet containing neither oats nor alfalfa (Wayne MRH 22/5 Rodent Blox), Wayne diet supplemented with oats or alfalfa or both, a purified semisynthetic diet (AIN-76A), and AIN diet supplemented with oats. The natural ingredient diet produced more complex patterns and higher levels of I-compounds than purified diet in both liver and kidney DNA. Supplementation of either diet with oats elicited the formation of four additional oats-specific I-compounds in liver DNA. Oats and alfalfa, individually and in combination, tended to significantly raise nonpolar and diminish polar I-compound levels. To determine whether the oats-related extra spots were derived from mycotoxin contamination, two groups of rats were fed either Wayne diet or Wayne diet containing zearalenone (0.05 mg/kg) for three weeks. Zearalenone significantly increased the uterine weight but did not induce any DNA adduct formation.(ABSTRACT TRUNCATED AT 250 WORDS)

Structure-function relationships in the peroxisome: implications for human disease

Progress relevant to human peroxisomal disorders over the past 3 years includes improved biochemical delineation of disease phenotypes and new insights into peroxisomal structure and biogenesis. Immunoblotting studies using antibodies to peroxisomal beta-oxidation enzymes have defined mutations affecting each step of the pathway, some with clinical phenotypes as severe as disorders with global peroxisome deficiency. The latter disorders, typified by Zellweger syndrome, often lack matrix proteins but retain major membrane species of 150, 70, 35, and 22 kDa in empty peroxisomal "ghost" structures. The hypothesis that peroxisomal deficiency disorders result from altered targeting or import of peroxisomal matrix proteins has been strengthened by the demonstration of a carboxy terminal peroxisome-targeting signal which is distinct from amino terminal signals directing proteins to mitochondria. A mutation which mistargets alanine/glyoxylate aminotransferase from peroxisomes to mitochondria in primary hyperoxaluria provides a graphic example of these signals. The structural significance of membrane function is supported by the primacy of membrane assembly in normal ontogeny or regenerating liver. The coordinate control, targeting, and striking inducibility of peroxisomal proteins suggests a potential vehicle for gene and enzyme therapy.

Effects of aging and caloric restriction on I-compounds in liver, kidney and white blood cell DNA of male Brown-Norway rats

Rodent tissues display species-, strain-, sex- and tissue-specific adduct-like DNA modifications termed I-compounds, which increase with age, are modulated by diet and are presumably derived from indigenous metabolic intermediates. We have explored whether I-compounds are affected by caloric restriction, which is known to extend life span and retard age-related degenerative and neoplastic diseases. Male Brown-Norway rats were fed NIH-31 diet ad libitum (AL). Calorically restricted (CR) rats received 60% of AL consumption, starting at 3.5 months. DNA was analyzed by 32P-postlabeling at 1, 4, 8, 12, 16 and 24 months of age in liver, kidney and white blood cells. I-compounds in AL liver and kidney exhibited complex tissue specific profiles; I-compound levels increased with age, plateaued between 8 and 18 months depending on tissue and diet and were 8.7 (liver) and 27.4 (kidney) modifications in 10(8) nucleotides at 24 months, thereby exceeding the corresponding 1-month values by 3.7- and 16.6-fold. CR resulted in similar profiles but did not diminish age-related increases, rather I-compound levels in CR liver and kidney were increased by about 70% and 30% versus age-matched AL rats. White blood cells exhibited few I-compounds and at low levels; age-related increases were small overall but more pronounced in CR rats. Higher I-compound levels in CR animals, which were presumably a consequence of metabolic effects elicited by CR, thus correlated with extended life span and, therefore, may be beneficial, in agreement with previous findings showing an association between reduced I-compound levels and hepatocarcinogenesis as well as organ susceptibility to diseases.

Short-term effects of the tumor promoting polychlorinated biphenyl mixture, Aroclor 1254, on I-compounds in liver, kidney and lung DNA of male Sprague-Dawley rats

The effects of a tumor promoting polychlorinated biphenyl mixture, Aroclor 1254, on I-compounds (tissue, species and sex dependent DNA modifications that increase with age in untreated rodents) were studied by 32P-postlabeling in male Sprague-Dawley rat liver, kidney, and lung DNA. Aroclor 1254 was dissolved in corn oil and intraperitoneally (i.p.) injected (2 x 500 mg/kg, 2 weeks apart) into 3-month-old rats. Control rats were given corn oil. Groups of 3 animals were sacrificed at 2 and 6 weeks after the second injection of corn oil or Aroclor 1254. At both time points Aroclor 1254-treated rats had significantly lower body weights and higher liver weights while kidney and lung weights were unaffected. Thymidine incorporation into liver and lung DNA was significantly increased at both time points, while kidney DNA showed a small decrease at 2 weeks. Treatment resulted in significant reductions (ranging from 29 to 100%) of each of nine liver I-spots at 2 and 6 weeks. In treated rats there was no decrease in kidney I-spots at 2 weeks, while the levels of only two out of ten kidney spots were reduced by 42-91% at 6 weeks. At 2 weeks three out of seven and at 6 weeks four out of seven lung I-spots were lowered by 51-100% in the Aroclor 1254-treated rats. Thus the effects decreased in the order liver greater than lung greater than kidney. Since Aroclor 1254 has been reported to be a tumor promoter in liver and lung but not kidney, these results suggest a correlation between organ specific promotion of carcinogenesis by Aroclor 1254 and the reduction of DNA I-compounds.

On the mechanism of the hepatocarcinogenicity of peroxisome proliferators

The absence of a genotoxic action in the rat of several peroxisome proliferators (PP) has been confirmed by measuring gross degradation, unscheduled DNA-synthesis (UDS), as well as by measurement of single strand breaks using alkali unwinding in absence and presence of inhibitors of DNA-repair. Similar results were obtained even after drastically lowering the glutathione content of liver. Further, after oral administration of ciprofibrate, no potentiating effect was found in vivo on the generation of micronuclei in hepatocytes by ionizing radiation. The metabolically inert PP, perfluorooctanoic acid, was found to act as a promoter of liver tumors in the rat induced by diethylnitrosamine in an initiation-selection-promotion protocol. The results are discussed in light of available information concerning the mechanism of action of PPs.