In vivo covalent binding of organic chemicals to DNA as a quantitative indicator in the process of chemical carcinogenesis

Acrylonitrile interaction with testicular DNA in rats

In the present study we report the in vivo interaction of acrylonitrile (VCN) with testicular tissue in rats. Covalent binding of radioactivity to testicular tissue DNA was examined for a period of 72 hr after a single oral dose (46.5 mg/kg) of [2,3-14C] VCN. Maximal covalent binding was observed at 0.5 hr (8.9 mumol VCN equivalent/mol nucleotide). Binding decreased gradually thereafter but was still detected (2.5 mumol VCN equivalent/mol nucleotide) at 72 hr following VCN administration. Further, we examined the effects of VCN on DNA synthesis and repair in the testes of rats following a single oral dose (46.5 mg/kg) of VCN to clarify the impact of the covalent binding observed on the testicular genetic material. A significant decrease in DNA synthesis (80% of control) was observed at 0.5 hr after treatment. At 24 hr following acrylonitrile administration, testicular DNA synthesis was severely inhibited (38% of control). Testicular DNA repair was increased 1.5-fold at 0.5 hr and more than 3.3-fold at 24 hr following treatment with VCN. These results suggest that VCN can act as a multipotent genotoxic agent by alkylating DNA in testicular tissue and may affect the male reproductive function by interfering with testicular DNA synthesis and repair processes.

Mercapturic acids, protein adducts, and DNA adducts as biomarkers of electrophilic chemicals

The possibilities and limitations of using mercapturic acids and protein and DNA adducts for the assessment of internal and effective doses of electrophilic chemicals are reviewed. Electrophilic chemicals may be considered as potential mutagens and/or carcinogens. Mercapturic acids and protein and DNA adducts are considered as selective biomarkers because they reflect the chemical structure of the parent compounds or the reactive electrophilic metabolites formed during biotransformation. In general, mercapturic acids are used for the assessment of recent exposure, whereas protein and DNA adducts are used for the assessment of semichronic or chronic exposure. 2-Hydroxyethyl mercapturic acid has been shown to be the urinary excretion product of five different reactive electrophilic intermediates. Classification of these electrophiles according to their acid-base properties might provide a tool to predict their preference to conjugate with either glutathione and proteins or with DNA. Constant relationships appear to exist in the cases of 1,2-dibromoethane and ethylene oxide between urinary mercapturic acid excretion and DNA and protein adduct concentrations. This suggests that mercapturic acids in some cases may also play a role as a biomarker of effective dose. It is concluded that simultaneous determination of mercapturic acids, protein and DNA adducts, and other metabolites can greatly increase our knowledge of the specific roles these biomarkers play in internal and effective dose assessment. If the relationship between exposure and effect is known, similar to protein and DNA adducts, mercapturic acids might also be helpful in (individual) health risk assessment.

Quantitative assessment of a human carcinogenic potency for propylene oxide

The potential for causing carcinogenic and mutagenic effects is the main concern when assessing the risks associated with low-level exposures of humans to the industrially important epoxide, propylene oxide (PO). The available basic information used in estimation of carcinogenic risk has been reviewed. It is concluded that the published data from gavage studies in rodents are less appropriate and that observed cancer incidences from long-term inhalation should preferably be utilized for quantitative risk assessment. Furthermore, PO and ethylene oxide (EO) are directly acting alkylating agents which exhibit several similarities. Although data are less comprehensive for PO than for EO, PO appears to yield a rather uniform alkylation pattern in various tissues. Also, similarly to EO, PO is probably detoxified at a rate which does not vary widely in various mammalian species, including man. For these reasons, the surface-based extrapolation model for estimation of the human equivalent dose may not be appropriate, and the previously derived carcinogenic potency factors should be revised downward. Alternative risk estimates are provided. From the most relevant available studies, we propose a carcinogenic potency factor of 0.001 (mg/kg/day)-1 for PO in humans by inhalation.

Poisoning by Gyromitra esculenta--a review

Gyromitra esculenta (Pers.: Fr.) Fr. and a few other mushrooms have caused severe poisonings and even deaths in humans. Clinical data are characterized primarily by vomiting and diarrhoea, followed by jaundice, convulsions and coma. Gastrointestinal disorders distinguish this poisoning. Frequent consumption can cause hepatitis and neurological diseases. The species of concern are mainly G. esculenta and G. gigas (Kromb.) Cooke (non Phill.). Nevertheless, recent advances in chromatography, biochemistry and toxicology have established that other Ascomycetes species also may prove toxic. Gyromitrin (acetaldehyde methylformylhydrazone, G) and its homologues are toxic compounds that convert in vivo into N-methyl-N-formylhydrazine (MFH), and then into N-methylhydrazine (MH). The toxicity of these chemicals, which are chiefly hepatotoxic and even carcinogenic, has been established through in vivo and in vitro experiments using animals, cell cultures and biochemical systems. When we consider the chemical nature and the reactivity of these natural compounds, we suggest that chemical and biochemical mechanisms may explain their intrinsic biological activity.

An experimental approach to identifying the genotoxic risk from cooked meat mutagens

In order to define the toxicological risk to the human population from the chemical compounds formed during the process of cooking animal meat, which have been described as possessing mutagenic, genotoxic and carcinogenic activities, an extensive study was undertaken of cooked meat extract and two cooked meat mutagens, 2-amino-3-methylimidazo(4,5-f)quinoline (IQ) and 2-amino-3,8-dimethylimidazo(4,5-f)quinoxaline (MeIQx). The study involved toxicokinetics and mouse-tissue distribution studies of the two chemicals, in vitro and in vivo mutagenicity/genotoxicity analyses (i.e. the detection of gene mutations, chromosome aberrations and micronuclei in mouse bone marrow cells, and mouse urine and faeces mutagenicity tests), as well as in vivo protein and DNA binding assays. IQ and MeIQx were found to be positive for the induction of gene mutations in Salmonella typhimurium TA98, but not in Chinese hamster V79 cells; IQ only was found to be positive for the induction of chromosome aberrations in Chinese hamster ovary cells and cultured human lymphocytes. IQ and MeIQx were negative for the induction of micronuclei in mice treated with 40 mg chemical/kg body weight; the lowest effective dose administered to the mice that produced mutagenic urine was 0.4 mg IQ/kg body weight and 0.04 mg MeIQx/kg. A dose of 40 mg IQ/kg, given orally by gavage to mice, produced an excretion of 1-4% of the applied dose in the urine and 0.1-2% of the applied dose in the faeces, when evaluated chemically or mutagenically. The number of DNA adducts in the liver correlated with the dose of IQ or MeIQx administered to the mice. All the data have been used for defining a possible risk estimate to the human population as a consequence of a cooked meat diet.

Evidence for and possible mechanisms of non-genotoxic carcinogenesis in mouse skin

Most chemicals that produce skin cancer are genotoxic by in vitro and in vivo short-term assays and produce a high incidence of skin cancer within a year if optimal doses are applied. If in long-term skin painting studies one or two tumours in 50 mice are observed there is a general consensus that no carcinogenic activity can be claimed and it has been suggested that if up to 10% tumours are induced by irritant substances this could be due to an enhancement of spontaneous tumour incidence. Observations of skin tumour incidences higher than 10% with non-genotoxic substances, usually after a long latent period, is considered to represent evidence for a non-genotoxic mechanism. Examples of such substances include croton oil, 12-O-tetradecanoyl-phorbol-13-acetate (TPA), sodium hydroxide, potassium hydroxide, phenol, dodecylbenzene and petroleum-derived middle distillates. Two distinct mechanisms appear to be involved in the production of tumours by a non-genotoxic substance. The first of these is that seen with the strong promoting agents. These, by binding to and activating protein kinase C, appear to directly stimulate sustained epidermal hyperplasia without severe skin damage. The other appears to involve substances producing severe skin damage either by a direct caustic effect or by cumulative irritancy. These changes give rise to marked epidermal hyperplasia with repeated episodes of regeneration and damage. The tumour induction by both mechanisms probably results from oncogene activation and it is possible that oxidative enzymes from inflammatory cells may be involved in the activation process. Various reasons are given why non-genotoxic carcinogenesis in the skin is considered not to be relevant to man and ways of recognising and avoiding its occurrence in animals studies are recommended.

Effect of inhalation exposure regimen on DNA binding potency of 1,2-dichloroethane in the rat

1,2-Dichloroethane (DCE) was reported to be carcinogenic in rats in a long-term bioassay using gavage in corn oil (24 and 48 mg/kg/day), but not by inhalation (up to 150-250 ppm, 7 h/day, 5 days/week). The daily dose metabolized was similar in the two experiments. In order to address this discrepancy, the genotoxicity of DCE was investigated in vivo under different exposure conditions. Female F-344 rats (183-188 g) were exposed to [1.2-14C]-DCE in a closed inhalation chamber to either a low, constant concentration (0.3 mg/l = 80 ppm for 4 h) or to a peak concentration (0.3 mg/l = 80 ppm for 4 h) or to a peak concentration (up to 18 mg/l = 4400 ppm) for a few minutes. After 12 h in the chamber, the dose metabolized under the two conditions was 34 mg/kg and 140 mg/kg. DNA was isolated from liver and lung and was purified to constant specific radioactivity. DNA was enzymatically hydrolyzed to the 3'-nucleotides which were separated by reverse phase HPLC. Most radioactivity eluted without detectable or with little optical density, indicating that the major part of the DNA radioactivity was due to covalent binding of the test compound. The level of DNA adducts was expressed in the dose-normalized units of the Covalent Binding Index, CBI = mumol adduct per mol DNA nucleotide/mmol DCE per kg body wt.(ABSTRACT TRUNCATED AT 250 WORDS)

Ethyl carbamate: analytical methodology, occurrence, formation, biological activity and risk assessment

Ethyl carbamate (EC) is a genotoxic compound in vitro and in vivo, it binds covalently to DNA and is an animal carcinogen. Today, EC is mainly found as a natural trace constituent in different alcoholic beverages and in fermented food items. Data on analytical methodology and the levels of EC in different food items are summarized and the daily burden of humans is estimated. Under normal dietary habits excluding alcoholic beverages, the unavoidable daily intake is 10-20 ng/kg b.w. On the basis of the evaluation of all toxicity data and its mode of action a conventional risk assessment of EC indicates that this level represents a negligible lifetime cancer risk (less than 0.0001%). Individual habits may greatly enhance the risk. Regular drinking of table wine (500 ml/day) would increase the risk up to 5 times, regular drinking of stone-fruit distillates (20-40 ml/day) would raise the calculated hypothetical tumor risk to near 0.01%. Human exposure to carcinogenic compounds should be as low as reasonably achievable. In order to take reliable measures to reduce EC levels in beverages and foods, it is crucial to know the mode of its formation. For its natural formation the presence of ethanol is absolutely required. In stone-fruit distillates hydrogen cyanide together with photochemically active substances are crucial to form EC. The main part of EC is formed after the distillation involving photochemical reactions. In wine (and probably bread) significant EC formation seems to depend on heat treatment. While in distillates hydrogen cyanide is the most important single precursor, in wine different carbamyl compounds, mainly urea, seem to be involved in EC formation. Despite this apparent difference a common EC formation pathway is discussed for all alcoholic beverages by assuming cyanic-/isocyanic acid as an important ultimate reactant with ethanol. Some ideas are presented as to the possible course of future work.

Relative bioavailability and DNA adduct formation of benzo[a]pyrene and metabolites in the diet of the winter flounder

1. Radiolabeled metabolites of the carcinogenic polycyclic aromatic hydrocarbon benzo[a]pyrene (BaP) were shown to be absorbed through the diet of the winter flounder, Pseudopleuronectes americanus. 2. Oral bioavailability of a mixture of naturally produced metabolites was significantly less than that of the parent BaP. 3. Oral bioavailability of a pure metabolite, BaP-7,8-dihydrodiol (7,8-D) was found to be similar to that of BaP. 4. Both metabolites and BaP formed DNA adducts in liver.

An experimental approach to identifying the genotoxic risk by cooked meat mutagens

In order to define the toxicological risk for the human population derived from the chemical compounds formed during the process of cooking animal meat, which have been described to possess a mutagenic, genotoxic, and carcinogenic activity, an extensive study has been developed on cooked meat extract and two cooked meat mutagens, IQ and MeIQx. The study has been based on toxicokinetics and mouse tissue distribution of the two chemicals, on in vitro and in vivo mutagenicity/genotoxicity analyses (gene mutation, chromosome aberration, micronuclea in mouse bone marrow cells, mice urine and faeces mutagenicity test), as well as in vivo protein and DNA binding. The two chemicals have been found positive for the induction of gene mutation on Salmonella, but not in V-79 Chinese hamster cells; IQ only has been found positive for the induction of chromosome aberrations on CHO cells and cultured human lymphocytes. IQ and MeIQx were negative for the induction of micronuclea in mice treated with 40 mg/kg of the chemicals; the lowest effective administered dose to the mice which produced mutagenic urine was 0.4 mg/kg of IQ and 0.04 mg/kg of MeIQx. A dose of 40 mg/kg of IQ given by gavage to mice produced an excretion of 1-4% of the applied dose in the urine and 0.1-2% of the applied dose in the faeces, when evaluated chemically or mutagenically. The DNA adducts for the liver were correlated with the dose of the IQ and MeIQx administered to the mice. All the data have been used for defining a possible risk estimate derived to the human population as a consequence of a cooked meat diet.

Carcinogen adducts as an indicator for the public health risks of consuming carcinogen-exposed fish and shellfish

A large variety of environmental carcinogens are metabolically activated to electrophilic metabolites that can bind to nucleic acids and protein, forming covalent adducts. The formation of DNA-carcinogen adducts is thought to be a necessary step in the action of most carcinogens. Recently, a variety of new fluorescence, immunochemical, and radioactive-postlabeling procedures have been developed that allow the sensitive measurement of DNA-carcinogen adducts in organisms exposed to environmental carcinogens. In some cases, similar procedures have been developed for protein-carcinogen adducts. In an organism with active metabolic systems for a given carcinogen, adducts are generally much longer lived than the carcinogens that formed them. Thus, the detection of DNA- or protein-carcinogen adducts in aquatic foodstuffs can act as an indicator of prior carcinogen exposure. The presence of DNA adducts would, in addition, suggest a mutagenic/carcinogenic risk to the aquatic organism itself. Vertebrate fish are characterized by high levels of carcinogen metabolism, low body burdens of carcinogen, the formation of carcinogen-macromolecule adducts, and the occurrence of pollution-related tumors. Shellfish, on the other hand, have low levels of carcinogen metabolism, high body burdens of carcinogen, and have little or no evidence of carcinogen-macromolecule adducts or tumors. The consumption of carcinogen adducts in aquatic foodstuffs is unlikely to represent a human health hazard. There are no metabolic pathways by which protein-carcinogen or DNA-carcinogen adducts could reform carcinogens. Incorporation via salvage pathways of preformed nucleoside-carcinogen adducts from foodstuffs into newly synthesized human DNA is theoretically possible.(ABSTRACT TRUNCATED AT 250 WORDS)

Consideration of the target organ toxicity of trichloroethylene in terms of metabolite toxicity and pharmacokinetics

Trichloroethylene (TRI) is readily absorbed into the body through the lungs and gastrointestinal mucosa. Exposure to TRI can occur from contamination of air, water, and food; and this contamination may be sufficient to produce adverse effects in the exposed populations. Elimination of TRI involves two major processes: pulmonary excretion of unchanged TRI and relatively rapid hepatic biotransformation to urinary metabolites. The principal site of metabolism of TRI is the liver, but the lung and possibly other tissues also metabolize TRI, and dichlorovinyl-cysteine (DCVC) is formed in the kidney. Humans appear to metabolize TRI extensively. Both rats and mice also have a considerable capacity to metabolize TRI, and the maximal capacities of the rat versus the mouse appear to be more closely related to relative body surface areas than to body weights. Metabolism is almost linearly related to dose at lower doses, becoming dose dependent at higher doses, and is probably best described overall by Michaelis-Menten kinetics. Major end metabolites are trichloroethanol (TCE), trichloroethanol-glucuronide, and trichloroacetic acid (TCA). Metabolism also produces several possibly reactive intermediate metabolites, including chloral, TRI-epoxide, dichlorovinyl-cysteine (DCVC), dichloroacetyl chloride, dichloroacetic acid (DCA), and chloroform, which is further metabolized to phosgene that may covalently bind extensively to cellular lipids and proteins, and, to a much lesser degree, to DNA. The toxicities associated with TRI exposure are considered to reside in its reactive metabolites. The mutagenic and carcinogenic potential of TRI is also generally thought to be due to reactive intermediate biotransformation products rather than the parent molecule itself, although the biological mechanisms by which specific TRI metabolites exert their toxic activity observed in experimental animals and, in some cases, humans are not known. The binding intensity of TRI metabolites is greater in the liver than in the kidney. Comparative studies of biotransformation of TRI in rats and mice failed to detect any major species or strain differences in metabolism. Quantitative differences in metabolism across species probably result from differences in metabolic rate and enterohepatic recirculation of metabolites. Aging rats have less capacity for microsomal metabolism, as reflected by covalent binding of TRI, than either adult or young rats. This is likely to be the same in other species, including humans. The experimental evidence is consistent with the metabolic pathways for TRI being qualitatively similar in mice, rats, and humans. The formation of the major metabolites--TCE, TCE-glucuronide, and TCA--may be explained by the production of chloral as an intermediate after the initial oxidation of TRI to TRI-epoxide.(ABSTRACT TRUNCATED AT 400 WORDS)

Species differences in the metabolism and macromolecular binding of methapyrilene: a comparison of rat, mouse and hamster

1. The metabolism of methapyrilene (MPH) by rat, hamster and mouse liver microsomes in vitro was investigated together with the binding of 14C-MPH to calf thymus DNA after metabolic activation. 2. Both quantitative and qualitative differences in MPH metabolism were observed in these three species. Mouse liver microsomes catalyse the formation of two novel isomers of hydroxypyrdylmethapyrilene (hydroxypyridyl-MPH) as determined by mass spectral analysis. N,N'-Didesmethylmethapyrilene (didesmethyl-MPH) was formed in detectable quantities only when hamster liver microsomes were used. 3. Incubation of liver microsomes from all three species catalysed the binding of 14C-MPH to exogenous DNA, which was quantitatively similar for all three species. The effect of the cytochrome P-450 inhibitor, 2,4-dichloro-6-phenylphenoxyethylamine (DPEA), and methimazole, a flavin-dependent monooxygenase inhibitor, on binding differed significantly for the three species studied.

Thermospray high performance liquid chromatography/mass spectrometric identification of a bladder carcinogen metabolite isolated from guinea pig urine

An in vivo urinary metabolite of the bladder carcinogen 2-amino-4-(5-nitro-2-furyl) thiazole was isolated from guinea pig urine and was identified by direct analysis using thermospray mass spectrometry/high-performance liquid chromatography as 1-(2-amino-4-(5-nitro-2-furyl)-2-thiazolyl)-1-deoxy-beta-D-glucopyran uronic acid. The structure of this metabolite was also established by chemical synthesis. Both positive and negative ion thermospray mass spectrometry of the conjugate showed fragment ions resulting from cleavage across the pyran ring of the glucuronic acid comprising of aglycone moiety. These characteristic fragment ions may be diagnostic for identification of N-glucuronides from O-glucuronides.

Quantification of haemoglobin binding of 4,4'-methylenebis(2-chloroaniline) (MOCA) in rats

4,4'-Methylenebis(2-chloroaniline) (MOCA) is used as a curing agent in the production of polyurethane. MOCA is carcinogenic in experimental animals. Haemoglobin adducts have been proposed as dosimeters of aromatic amines for biological monitoring. A quantitative method to determine the adduct has now been worked out in female Wistar rats dosed per os with 3.82, 14.2 and 16.2 mumol/kg 14C-ring labeled MOCA or 0.25 and 0.50 mmol/kg unlabeled MOCA. MOCA bound in decreasing amounts to DNA, RNA and proteins of the lung, liver and kidney. Fractions of 0.19% and 0.026% of the dose were bound to the blood proteins haemoglobin and albumin, respectively. MOCA released by hydrolysis from haemoglobin was determined by HPLC with electrochemical detection or by GC-MS. Albumin did not form any hydrolysable adducts with MOCA.

In vitro transformation of BALB/c 3T3 cells by 1,1,2,2-tetrachloroethane

1,1,2,2-Tetrachloroethane (1,1,2,2-TTCE) was shown to be capable of inducing in vitro transformation of BALB/c 3T3 cells (clone A-31) either in the presence or in the absence of S9 activating system using an amplification-transformation (level-II) assay by reseeding confluent cells from each treatment and allowing additional rounds of cell replication. In the absence of metabolic activation, the highest assayed dose (1000 micrograms/ml), exerting the highest toxicity, was the only transforming dose. Lower doses of 1,1,2,2-TTCE were capable of transforming BALB/c cells in the presence of S9 activating system, the dose of 500 micrograms/ml exerting the highest transforming activity. The number and size of transformed foci recognized in the level-II plates were a function of the number of cells reseeded in the amplification assay. Foci obtained in the presence of S9 activating systems were larger in size, more deeply basophilic, and exhibited denser multilayering of constituent cells than foci recognized in the absence of exogenous metabolic activation.

Covalent interactions of 1,2,3-trichloropropane with hepatic macromolecules: studies in the male F-344 rat

Preliminary investigations into the role of biotransformation in 1,2,3-trichloropropane (TCP)-induced tumor formation have been undertaken. Male F-344 rats were administered 30 mg/kg [14C]TCP (100 microCi/kg) ip and killed 4 hr later. The extent of covalent binding to hepatic protein, DNA, and RNA was 418, 244, and 432 pmol [14C]TCP equivalents/mg, respectively. An in vivo covalent binding time course showed no significant change in [14C]TCP equivalents bound to hepatic DNA (1-48 hr), while binding to protein was maximal by 4 hr and decreased significantly by 48 hr. The binding of TCP-associated radioactivity to hepatic protein and DNA was shown to be cumulative for two and three doses when given 24 hr apart. Pretreatment of animals with phenobarbital caused a decrease while pretreatment with SKF 525-A caused an increase in covalent binding of [14C]TCP equivalents to protein and DNA. Pretreatment of rats with beta-naphthoflavone did not alter the covalent binding of [14C]TCP equivalents to protein or DNA. However, glutathione depletion with L-buthionine-(R,S)-sulfoximine increased binding to protein by 342% while it decreased binding to DNA by 56%. Intraperitoneal administration of TCP also depleted hepatic GSH by 41 and 61% 2 hr after doses of 30 and 100 mg/kg. The in vivo binding data suggest a dual role for GSH in the bioactivation of TCP. It may, in part, be that GSH is involved in the bioactivation and covalent binding of TCP to hepatic DNA. However, it also appears to detoxify a reactive intermediate(s) that binds to protein.

Genotoxicity of ethyl carbamate in the Drosophila wing spot test: dependence on genotype-controlled metabolic capacity

Ethylcarbamate has a clear genotoxic potential in Drosophila melanogaster. In the somatic mutation and recombination test (SMART) it induces, in a dose-dependent manner, single spots as well as twin spots. The twin spots indicate a recombinogenic activity of ethyl carbamate. A strong strain difference demonstrates that the metabolic activation of ethyl carbamate to DNA binding metabolites most probably also in Drosophila involves cytochrome P450-dependent enzyme activities.

Endogenous genotoxic agents and processes as a basis of spontaneous carcinogenesis

A list of endogenous DNA-damaging agents and processes is given. Endogenous electrophiles are found with the cosubstrates of physiological transfer reactions (S-adenosylmethionine for methylation, ATP for phosphorylation, NAD+ for ADP-ribosylation, acetyl CoA for acetylation). Aldehyde groups (glyceraldehyde-3-phosphate, formaldehyde, open forms of reducing sugars, degradation products of peroxidation) or alkylating degradation products derived from endogenous nitroso compounds represent additional possibilities. Radical-forming reactions include leakage of the superoxide anion radical from terminal cytochromes and redox cycles, hydroxyl radical formation by the Fenton reaction from endogenous hydrogen peroxide, and the formation of lipid peroxides. Genetic instability by spontaneous deaminations and depurinations as well as replicative instability by tautomer errors and in the presence of mutagenic metal ions represent a third important class of endogenous genotoxic processes. The postulated endogenous genotoxicity could form the mechanistic basis for what is called 'spontaneous' tumor incidence and explain the possibility of an increased tumor incidence after treatment of animals with non-genotoxic compounds exhibiting tumor-promoting activity only. Individual differences are expected to be seen also with endogenous DNA damage. The presence of endogenous DNA damage implies that exogenous DNA-carcinogen adducts give rise to an incremental damage which is expected to be proportional to the carcinogen dose at lowest levels. An increased tumor risk due to exposure to exogenous genotoxic carcinogens could therefore be assessed in terms of the background DNA damage, for instance in multiples of the mean level or of the interindividual variability in a population.

A comparison of DNA adduct formation in white blood cells and internal organs of mice exposed to benzo[a]pyrene, dibenzo[c,g]carbazole, safrole and cigarette smoke condensate

Measurement of tissue/cell DNA adducts represents a suitable monitor of carcinogen exposure because the majority of chemical mutagens/carcinogens react with DNA, forming covalent adducts, a key event in the initiation of chemical carcinogenesis. Investigations of DNA-adduct formation in vivo in white blood cells (WBC) versus target tissues, i.e. internal organs for most carcinogens, is expected to yield useful information about the suitability of WBC for biomonitoring and risk assessment. For this purpose, female ICR mice were given 0.4 mmole/kg benzo[a]pyrene (BP), 0.045 mmole/kg dibenzo[c,g]carbazole (DBC) or 2.47 mmole/kg safrole by oral gavage or 4 daily doses (equivalent to 3 cigarettes) of cigarette-smoke condensate (CSC) by topical application. At 24 h after dosing, DNA adducts were detected by a nuclease P1-enhanced 32P-postlabeling assay [M.V. Reddy and K. Randerath, Carcinogenesis, 7 (1986) 1543] in WBC and internal tissues treated with individual carcinogens, while CSC treatment elicited aromatic adducts in most tissues but not in WBC. Adduct patterns of WBC DNA were qualitatively similar to those of internal organs, but adduct amounts varied. BP, a systemic carcinogen, bound nearly as much to WBC DNA as to target-tissue DNA samples; whereas the liver carcinogens, DBC and safrole, bound to WBC DNA considerably less (22- and 51-fold, respectively) compared with liver DNA. The number of adducts in 10(7) nucleotides of WBC, liver, lung, kidney and spleen DNA, respectively, were: 2, 5, 3, 2 and 3 with BP; 6, 131, 6, 14 and 4 with DBC; 5, 238, 3, 5 and 0.6 with safrole. For CSC, these values were 0, 1 and 0.02 in WBC, lung and spleen, respectively. Our results show that carcinogen binding to WBC DNA does not reflect binding to target-tissue DNA in a quantitative sense for the carcinogens studied except for BP, and that WBC are not suitable surrogates for monitoring CSC exposure by DNA-adduct measurement after topical application. The CSC data in mice was consistent with the previous findings in humans that smokers' tissues but not WBC show smoking-related bulky/aromatic DNA adducts, as measured by 32P-postlabeling.

Nitrosation of aspartic acid, aspartame, and glycine ethylester. Alkylation of 4-(p-nitrobenzyl)pyridine (NBP) in vitro and binding to DNA in the rat

In a colorimetric assay using 4-(p-nitrobenzyl)pyridine (NBP) as a nucleophilic scavenger of alkylating agents, the nitrosation and alkylation reactions were investigated for a number of amino acids and derivatives. The alkylating activity increased with the square of the nitrite concentration. The nitrosation rate constants for aspartic acid, aspartame, and glycine ethylester (= precursors C) were 0.08, 1.4 and less than or equal to 0.2, respectively, expressed in terms of the pH-dependent k2 rate constant of the equation dNOC/dt = k2.[C].[nitrite]2. The rates correlated inversely with the basicity of the amino group. The stability of the alkylating activity was astonishingly high, both in acid and at neutral pH. Half-lives of 500, 200, and 30 min were determined for aspartic acid (pH 3.5), aspartame (pH 2.5), and glycine ethylester (pH 2.5). Values of 60, 15, and 2 min, respectively, were found at pH 7. It is concluded that rearrangement of the primary N-nitroso product to the ultimate alkylating agent could be rate-limiting. The potential of nitrosated alpha-amino acids to bind to DNA in vivo was investigated by oral gavage of radiolabelled glycine ethylester to rats, followed immediately by sodium nitrite. DNA was isolated from stomach and liver and analysed for radioactivity and modified nucleotides. No indication of DNA adduct formation was obtained. Based on an estimation of the dose fraction converted from glycine ethylester to the nitroso product under the given experimental conditions, the maximum possible DNA-binding potency of nitroso glycine ethylester is about one order of magnitude below the methylating potency of N-nitrosomethylurea in rat stomach. The apparent discrepancy to the in vitro data could be due to efficient detoxification processes in mammalian cells.

The carcinogenic potential of ethyl carbamate (urethane): risk assessment at human dietary exposure levels

Ethyl carbamate is found in fermented foods: bread contains 3-15 ng/g, stone-fruit brandies 200-20,000 ng/g, and about one-third of table-wine samples analysed contained more than 10 ng/g. In animals, ethyl carbamate is degraded to CO2, H2O and NH3, with intermediate formation of ethanol. This degradation has been shown to be inhibited (postponed) in the mouse by ethanol concentrations in the blood of about 0.15% and higher. A quantitatively minor pathway involves a two-step oxidation of the ethyl group to vinyl carbamate and epoxyethyl carbamate, the postulated electrophilic moiety that reacts with DNA. This reaction is probably the mode of the mutagenic action observed in many cellular and animal systems. The fact that only vinyl carbamate, but not ethyl carbamate, is mutagenic in a standard Ames test is probably because there is insufficient production of the intermediate oxidation product in the standard test. Consistent with this metabolism is the carcinogenic activity of ethyl carbamate in various animal species and in different organs; this activity can be seen even after a single high dose in early life. Quantitative analysis of the total tumour incidences after chronic exposure of rats and mice to 0.1-12.5 mg ethyl carbamate/kg body weight/day in the drinking-water showed a dose-related increase. The main target organs were the mammary gland (female rats and mice having similar susceptibilities) and the lung (mice only). On the basis of sex- and organ-specific tumour data and with a linear extrapolation to a negligible increase of the lifetime tumour incidence by 0.0001% (one additional tumour in one million individuals exposed for life), a "virtually safe dose" of 20 to 80 ng/kg body weight/day was estimated. The daily burden reached under normal dietary habits without alcoholic beverages is in the range of about 20 ng/kg body weight/day. Regular table-wine consumption would increase the risk by a factor of up to five. Regular drinking of 20 to 40 ml stone-fruit brandy per day could raise the calculated lifetime tumour risk to near 0.01%.

Binding of polycyclic and nitropolycyclic aromatic hydrocarbons to specific fractions of rat lung chromatin

Carcinogen-induced damage to nuclear matrix DNA, the site of DNA replication and transcription, could have profound effects on gene regulation and mutation. 1,6-Dinitropyrene (1,6-DNP), 1-nitropyrene (1-NP), 6-nitrobenzo[a]pyrene (6-NBP), benzo[a]pyrene (BP) and benzo[a]pyrene diolepoxide (BPDE) were investigated for their abilities to bind to selected regions of DNA in rat lung cell nuclei. Following in vitro exposure to carcinogen, nuclei were fractionated into active chromatin (AC), nuclear matrix (NM) and bulk (low and high salt) chromatin fractions. At an equivalent molar concentration, the highest binding to unfractionated (total) DNA was obtained with BPDE, followed in order by BP, 1,6-DNP, 6-NBP and 1-NP. BPDE, a direct alkylating compound, was bound approximately 18 times higher than the other compounds. All compounds were bound to AC (mononucleosomal DNA approximately 185 bp) and to NM in greater amounts than to bulk DNA. The binding ratios (AC + NM)/(LS + HS) varied from 2 to 21, depending upon the compound. The selective binding to specific DNA regions did not appear to be significantly related to the structures of the parent compounds or to their inferred metabolites. Thus, it appears that selective binding to specific regions is a general phenomenon that is related to the open state of the chromatin structure.

Lack of in vivo DNA binding of mercaptobenzothiazole to selected tissues of the rat

In this study, the in vivo binding of 14C-labelled 2-mercaptobenzothiazole (MBT) to DNA was investigated. Male and female Fischer 344 rats were gavaged with 375 mg MBT/kg body weight and killed 8 hours later. DNA was extracted from the liver, adrenal glands, pituitary gland, pancreas, and bone marrow and the amount of radioactivity associated with the DNA was determined. Results from this study indicate that MBT does not significantly bind to DNA from any of the tissues examined. CBI values for liver for the 3 methods of purification were -1-3 which are on the low end of the covalent binding index. The CBI values for the other tissues were always less than 1. Other chemicals with similar CBI values include estrone and diethylstilbesterol. Strong hepatocarcinogens such as dimethylnitrosamine and aflatoxin have CBI values ranging from 6000 to greater than 20000.

Nucleophilic selectivity as a determinant of carcinogenic potency (TD50) in rodents: a comparison of mono- and bi-functional alkylating agents and vinyl chloride metabolites

Using published data, the carcinogenic potency (TD50) in rodents of a series of monofunctional alkylating agents, bifunctional antitumor drugs and the vinyl chloride (VC) metabolites chloroethylene oxide (CEO) and chloroacetaldehyde (CAA) was compared to their nucleophilic selectivity (Swain and Scott's constant s or initial ratio of 7-/O6-alkylguanine in DNA). A positive correlation between the log of TD50 estimates and the s values for a series of 14, mostly monofunctional, alkylating agents was observed. This linear relationship also included 2 bifunctional chloroethylnitrosoureas, although their carcinogenic potency was compared to their initial 7-/O6-alkylguanine ratio rather than their s values (n = 16, r = 0.91, p less than 0.005). In addition, the carcinogenic potency of 2 alkyl sulfates, which is not yet known accurately, may correlate with their nucleophilic selectivity through the same relationship. By contrast, 2 methyl halides and 5 bifunctional antitumor drugs (nitrogen mustards and azyridinyl derivatives) did not follow this linear relationship: at similar nucleophilic selectivity, they were more potent carcinogens than the above 18 alkylating agents; this may hold true for CEO and CAA too, although further carcinogenicity experiments are needed to calculate their precise TD50 values. The possible molecular mechanisms involved in tumor induction by these agents are discussed on the basis of these findings. Comparison of the estimated TD50 for CEO, CAA and VC in rodents confirms that CEO is the ultimate carcinogenic metabolite of VC and suggests that only a very small proportion of metabolically generated CEO is available for DNA alkylation in vivo.

Chemical composition and genotoxic activity of petroleum derivatives collected in two working environments

Pitch and bitumen, two complex petroleum derivative mixtures, were studied for both their chemical composition and their mutagenic/DNA damaging activity. While bitumen revealed no genotoxic effect and low polycyclic aromatic hydrocarbons (PAHs) concentration, petroleum pitch showed a high concentration of mutagenic/carcinogenic PAHs, and also an elevated mutagenic activity when assayed by the Ames test, in the presence of postmitochondrial rat liver fractions. The in vitro mutagenic activity was detectable as frameshift mutation by assaying the pitch both as an in toto mixture and after HPLC fractionation, the most polar fractions being the most active. In contrast, both derivatives showed no in vivo DNA damage in rat liver, using the DNA alkaline elution technique and the fluorometric assay of DNA unwinding.

Covalent binding of [14C]-2,6-dimethylaniline to DNA of rat liver and ethmoid turbinate

The xylidide 2,6-dimethylaniline (2,6-DMA) has produced carcinomas and papillary adenomas in the nasal cavity of rats at high dietary doses (3000 ppm) in a 2-yr bioassay. The objective of the present study was to measure the covalent binding of 2,6-DMA to DNA of rat ethmoid turbinate tissues and, for comparison, to DNA of rat liver. The potent hepatocarcinogen 2-acetylaminofluorene (AAF) was studied as a positive control for adduct formation and covalent binding index (CBI) calculation. Both 2,6-DMA and AAF were administered as 14C-(ring)-labeled agents to naive rats and to rats pretreated for 9 d with unlabeled 2,6-DMA or AAF. The CBI value for 2,6-DMA adduct formation with ethmoid turbinate DNA was below the assay's sensitivity limit in nonpretreated rats, but increased to 41.9 in rats pretreated with unlabeled 2,6-DMA. It also increased from 0.6 in nonpretreated to 7.9 in liver of pretreated rats. The opposite pattern, however, was observed for AAF. In nonpretreated rats considerable adduct formation was observed in liver (CBI = 271.5) and modest values (CBI = 39.3) were calculated for ethmoid turbinate tissues. Pretreatment with unlabeled AAF caused a significant decrease in CBI values, to 18.3 for liver and less than 0.5 for ethmoid turbinate. The results suggest that there may be value in conducting DNA covalent binding assays in both naive animals and animals pretreated with the test article.

Covalent binding of 1,1,1,2-tetrachloroethane to nucleic acids as evidence of genotoxic activity

Twenty-two hours after ip administration to male Wistar rats and BALB/c mice, 1,1,1,2-tetrachloroethane (1,1,1,2-TTCE) is bound covalently to DNA, RNA, and proteins of liver, lung, kidney, and stomach. The in vivo reactivity leads to binding values to DNA generally higher in mouse organs than in rat organs. The covalent binding index (CBI) values (82 in mouse liver DNA and 40 in rat liver DNA) classify 1,1,1,2-TTCE as a weak to moderate initiator. Both microsomal and cytosolic enzymatic systems from rat and mouse organs are capable of bioactivating 1,1,1,2-TTCE in vitro. Liver fractions are the most effective. When the activating systems are simultaneously present in the incubation mixture a synergistic effect is observed. Unlike the related chemical 1,1,2,2-tetrachloroethane (1,1,2,2-TTCE), which is bioactivated only through an oxidative route, 1,1,1,2-TTCE metabolism is carried on by oxidative and reductive pathways, both dependent on cytochrome P-450. 1,1,1,2-TTCE is also bioactivated by microsomal GSH-transferases from liver and lung. These data further confirm that correlations exist between structure and genotoxic activity of halocompounds.

Genotoxicity of aniline derivatives in various short-term tests

Various substituted aniline derivatives were tested for genotoxicity in several short-term tests in order to examine the hypothesis that a substitution at both ortho positions (2,6-disubstitution) could prevent genotoxicity due to steric hindrance of an enzymatic activation to electrophilic intermediates. In the Salmonella/microsome assay, 2,6-dialkylsubstituted anilines and 2,4,6-trimethylaniline (2,4,6-TMA) were weakly mutagenic in strain TA100 when 20% S9 mix was used, although effects were small compared to those of 2,4-dimethylaniline and 2,4,5-trimethylaniline (2,4,5-TMA). In Drosophila melanogaster, however, 2,4,6-TMA and 2,4,6-trichloroaniline (TCA) were mutagenic in the wing spot test at 2-3 times lower doses than 2,4,5-TMA. In the 6-thioguanine resistance test in cultured fibroblasts, 2,4,6-TMA was again mutagenic at lower doses than 2,4,5-TMA. Two methylene-bis-aniline derivatives were also tested with the above methods: 4,4'-methylene-bis-(2-chloroaniline) (MOCA) was moderately genotoxic in all 3 test systems whereas 4,4'-methylene-bis-(2-ethyl-6-methylaniline) (MMEA) showed no genotoxicity at all. DNA binding studies in rats, however, revealed that both MOCA and MMEA produced DNA adducts in the liver at levels typically found for moderately strong genotoxic carcinogens. These results indicate that the predictive value of the in vitro test systems and particularly the Salmonella/microsome assay is inadequate to detect genotoxicity in aromatic amines. Genotoxicity seems to be a general property of aniline derivatives and does not seem to be greatly influenced by substitution at both ortho positions.

The rat-liver carcinogen N-nitrosomorpholine initiates unscheduled DNA synthesis and induces micronuclei in the rat liver in vivo

Alkylation of DNA is generally accepted as the primary event in the carcinogenicity of nitrosamines. However, the cyclic nitrosamine N-nitrosomorpholine (NMOR), a potent rat hepatocarcinogen, has been reported as binding at very low levels to the liver DNA of treated rats. This led us to investigate the activity of NMOR in two in vivo rat-liver genotoxicity assays--for the induction of unscheduled DNA synthesis (UDS) and the production of micronucleated hepatocytes in the liver micronucleus assay (LMN). Rats treated with oral doses of NMOR (10-200 mg/kg) gave a positive liver UDS response either 2.5 h or 12 h after dosing. Similarly, treatment with oral doses of NMOR (10 or 100 mg/kg) followed by mitogenic stimulation with 4-acetylaminofluorene (4AAF) resulted in high incidences of micronucleated hepatocytes in the LMN assay. These data confirm that the genotoxicity reported for NMOR in vitro can be reproduced in vivo and that NMOR interacts with liver DNA of treated rats. Earlier reports of only very weak binding of radiolabelled NMOR to rat liver DNA in vivo are discussed within the context of these data.

Protection against chemically induced skin tumorigenesis in SENCAR mice by tannic acid

Tannic acid, a naturally occurring dietary polyphenol, was evaluated as a possible anticarcinogen in an initiation-and-promotion skin tumorigenesis protocol. In the 2-stage tumor protocol in SENCAR mice, using DMBA, BP and MNU as the initiating agents followed by twice-weekly applications of TPA as tumor promotor, tannic acid was found to be an effective inhibitor of tumor formation whether the tumor data are considered as cumulative number of tumors, percentage of mice with tumors or tumors/mouse. After 9 weeks of TPA application, the number of tumors/mouse in the groups receiving DMBA, BP and MNU were 32.10 +/- 3.18, 3.70 +/- 0.55 and 2.00 +/- 0.53, respectively, whereas the corresponding numbers in the DMBA, BP and MNU groups receiving prior applications of tannic acid were 11.50 +/- 2.38, 0.35 +/- 0.15 and 0.35 +/- 0.13, respectively. These results suggest that tannic acid may prove useful in reducing the risk of chemically-induced skin tumorigenesis.

Comparison of DNA alkylation, fragmentation, and repair in maternal and fetal tissues of pregnant rats treated with a single dose of ethyl methanesulfonate, ethyl-N-nitrosourea, N-nitrosodiethylamine, and methyl-N-nitrosourea

The occurrence and persistence of DNA damage, as detected by the alkaline elution technique, have been studied in some tissues of both fetal and adult Sprague-Dawley rats (18th day of gestation) after administration of a single equimolar dose (0.5 mmol/kg) of ethyl methanesulfonate (EMS), N-ethyl-N-nitrosourea (ENU), N-nitrosodiethylamine (NDEA), and N-methyl-N-nitrosourea (MNU). EMS, ENU, and MNU, injected intravenously, produced a statistically significant increase of DNA elution rate, which is considered indicative of DNA fragmentation, in both maternal and fetal liver, kidney, and brain. NDEA, introduced by gastric gavage, induced DNA breaks in both liver and kidney of dams, but only in the liver of fetuses. The frequency of DNA lesions was found to vary with the four alkylating agents and in the three organs tested, to exhibit a different time course, and usually to be higher in maternal than in fetal tissues. Results provided by the concomitant determination of DNA binding levels demonstrated a satisfactory correlation with the amounts of DNA fragmentation. In contrast, the values of both these parameters did not show any positive correlation with the different susceptibility of the three organs to tumor induction. In conclusion, these findings suggest that when a compound is not available in radiolabeled form, measurement of DNA fragmentation may represent a useful alternative to the determination of DNA binding level in order to obtain information on the distribution of its reactive species in maternal and fetal tissues.

Glucuronides in mussel Mytilus galloprovincialis as a possible biomonitor of environmental carcinogens

1. The in vitro incubation of mussel digestive gland with 1 mM aminofluorene resulted in the formation of glucuronides that (a) became mutagenic with carp liver S9, and (b) liberated S9-dependent mutagenic aglucones after beta-glucuronidase treatment. 2. Natural populations of mussels from unpolluted and polluted sites, as well as mussels exposed to 3 ppm of aminofluorene or to used engine oil, did not accumulate detectable amounts of premutagens, mutagens, or mutagenic glucuronides/aglucones either in digestive gland tissue or in shell-cavity water. 3. The mutagenicity testing of mussel's glucuronides/aglucones does not seem to be useful as a biomonitor of environmental carcinogens.

Age-related induction and disappearance of carcinogen-DNA-adducts in livers of rats exposed to low levels of 2-acetylaminofluorene

It was investigated whether in vivo aging of rat liver is associated with changes in the induction and rate of disappearance of DNA damage. For this purpose 6- and 36-month-old rats were intraperitoneally injected with a single, low dose (5 mg/kg body wt.) of the model liver carcinogen 2-acetylaminofluorene (AAF). Using the 32P-postlabeling assay we found that N-(deoxyguanosin-8-yl)-2-aminofluorene (dG-C8-AF) was the major DNA-adduct formed. The minor adduct N-(deoxyguanosin-8-yl)-2-acetylaminofluorene (dG-C8-AAF) could only be detected after doses of 20 mg/kg or more. Quantitation of adduct levels at various time points after treatment indicated a rapid induction of AF-adducts, which were already present at 6 h after treatment. The subsequent loss of AF-adducts was relatively slow, as was indicated by the presence of a substantial amount of AF-adducts as late as 21 days after treatment. Slight age-related differences in the pattern of induction and disappearance of AF-adducts and a somewhat higher level of persisting lesions in old than in young rats were observed.

The dependence of the mutagenicity of methanesulphonic acid esters in S. typhimurium TA100 on the alkylation mechanism

Four different model nucleophiles, 4-(p-nitrobenzyl)pyridine (NBP), N-methylmercaptoimidazole (MMI), trifluoroacetic acid (TFA) and H2O were tested with 22 methanesulphonates of widely varying structures for their suitability to predict mutagenic activities in S. typhimurium TA100. The soft nucleophiles NBP (N-alkylation) and MMI (S-alkylation) revealed as highly sensitive for SN2 reactivities whereas TFA (solvolysis at the O-atom) and H2O (hydrolysis) were very sensitive for SN1 reactivities. No correlation between the NBP or the MMI test and the Ames test was found. Quite good correlations could be demonstrated for the TFA test and the hydrolysis rates: with rising activities in the TFA solvolysis the mutagenic potencies were increasing up to a maximum at i-propyl methanesulphonate. After that due to the fast hydrolysis the mutagenicities were decreasing again despite increasing TFA solvolysis rates. In general the secondary methanesulphonates exerted high SN1 reactivities and distinct mutagenic activities, whereas the primary compounds showed no or very low SN1 reactivities and low mutagenic potentials. The "activated" compounds cyclopropylmethyl methanesulphonate, benzyl methanesulphonate and allyl methanesulphonate exerted high SN1 and SN2 reactivities. Methyl methanesulphonate displayed a high mutagenicity in spite of its lack in SN1 reactivity. This is probably due to the induction of the error prone repair (pkM 101 plasmid in TA100). The relation between the alkylating reactivities (SN1 and SN2) and the molecular mechanisms leading to back mutation is discussed.

Modification of aflatoxin B1 biotransformation in vitro and DNA binding in vivo by dietary broccoli in rats

Cruciferous vegetables have been shown to have anticarcinogenic effects in animals but biochemical mechanisms have not been completely elucidated. The effects of dietary broccoli on in vivo DNA binding of the hepatocarcinogen aflatoxin B1 (AFB) and in vitro formation of the putative carcinogenic intermediate, AFB-8,9-epoxide, as well as detoxification of the epoxide by conjugation with glutathione (GSH), were examined in this study. Animals were fed a purified diet, a purified diet plus 25% freeze-dried broccoli, or standard rodent chow for 3 wk. In vivo binding of AFB to hepatic DNA was determined. Biotransformation of AFB in vitro (microsomal oxidation to AFB-8,9-epoxide, as well as hydroxylated metabolites, and cytosolic GSH conjugation of AFB-8,9-epoxide generated in situ) was measured by an HPLC method that allows specific and direct determination of AFB metabolites and thus, the rates of their formation. Microsomal mixed-function oxidase and epoxide hydrolase activities and cytosolic glutathione S-transferase activities were also measured with commonly used surrogate substrates. The rate of cytosolic conjugation of AFB-8,9-epoxide was increased 2.8-fold by the broccoli diet and 2.2-fold by the chow diet. These changes were not fully reflected by increases in activity with surrogate substrates. The chow diet did not affect epoxide hydrolase activity nor glutathione S-transferase activity toward 3,4-dichloronitrobenzene or benzo[a]pyrene 4,5-oxide, whereas these activities were significantly increased by the broccoli diet. Microsomal formation of AFB-8,9-epoxide was unaffected by the dietary treatments, whereas formation of aflatoxin M1 was increased. The chow diet, but not the broccoli diet, increased the amount of aflatoxin Q1 formed from AFB. Binding of AFB to DNA in vivo was significantly lower in the broccoli group but not in the chow-fed animals. These results indicate that broccoli contains substances that cause a reduction in the binding of AFB metabolites to DNA, possibly through the induction of glutathione S-transferase(s). Broccoli and rodent chow differ in their constituents that increase levels of xenobiotic biotransformation enzymes relative to a purified diet. The results also indicate the limitations of reliance on measurements of biotransformation pathways using surrogate substrates instead of carcinogenic compounds of interest.

International Commission for Protection against Environmental Mutagens and Carcinogens. ICPEMC working paper No. 5. Genotoxicity tests as predictors of carcinogens: an analysis

Differences between the results of numerical validation studies comparing in vitro and in vivo genotoxicity tests with the rodent cancer bioassay are leading to the perception that short-term tests predict carcinogenicity only with uncertainty. Consideration of factors such as the pharmacokinetic distribution of chemicals, the systems available for metabolic activation and detoxification, the ability of the active metabolite to move from the site of production to the target DNA, and the potential for expression of the induced lesions, strongly suggests that the disparate sensitivity of the different test systems is a major reason why numerical validation is not more successful. Furthermore, genotoxicity tests should be expected to detect only a subset of carcinogens, namely genotoxic carcinogens, rather than those carcinogens that appear to act by non-genetic mechanisms. Instead of relying primarily on short-term in vitro genotoxicity tests to predict carcinogenic activity, these tests should be used in a manner that emphasizes the accurate determination of mutagenicity or clastogenicity. It must then be determined whether the mutagenic activity is further expressed as carcinogenicity in the appropriate studies using test animals. The prospects for quantitative extrapolation of in vitro or in vivo genotoxicity test results to carcinogenicity requires a much more precise understanding of the critical molecular events in both processes.

Binding of hexachloroethane to biological macromolecules from rat and mouse organs

Hexachloroethane (HCE) binds to macromolecules of rat and mouse both in vivo and in vitro after metabolic activation. The covalent binding index (CBI) to liver DNA in vivo is comparable to that of compounds classified as weak-moderate initiators and is of approximately the same order of magnitude as those of other halocompounds such as 1,2-dichloroethane. HCE is bioactivated in vitro by microsomal enzymatic systems from murine liver and kidney and, to a greater extent, by cytosolic fractions from all assayed organs. HCE is less reactive than 1,1,2,2-tetrachloroethane, which is more toxic and oncogenic. The ability of hexachloroethane and five other chloroethanes to react covalently with mouse liver DNA both in vivo and in vitro parallels the relative oncogenic potency of these hepatocarcinogenic chemicals in mouse liver.

Hemoglobin adducts in animals exposed to gasoline and diesel exhausts. 1. Alkenes

Blood samples from rats and hamsters exposed to automotive engine exhausts in the Committee of Common Market Automobile Constructors long-term inhalation study at Battelle-Geneva were analysed for the levels of 2-hydroxyethylvaline (HOEtVal) and 2-hydroxypropylvaline (HOPrVal) in hemoglobin (Hb). These adducts to the N-terminus of the Hb chains were determined by gas chromatography-mass spectrometry of derivatives obtained by a modified Edman degradation that specifically cleaves off alkylated N-terminal amino acids (valine in Hb). The adduct levels found correspond to the metabolic conversion of about 5-10% of inhaled ethene and propene to ethylene oxide and propylene oxide, respectively, in agreement with results from earlier studies on mice inhaling radio-labelled alkenes. It is concluded that the alkenes, via epoxides, are the main sources of the observed HOEtVal and HOPrVal. From calculated doses and estimates of genotoxic potency the contribution from ethene in urban air to human cancer risk is discussed.

Statistical analysis of Salmonella test data and comparison to results of animal cancer tests

A quantitative framework for the analysis of results of the Salmonella (Ames) test is presented, and the relationship between mutagenesis and carcinogenesis is examined. Color graphics are used for the Salmonella data to describe variability, and trends across multiple chemicals and test conditions. Positivity in the Salmonella test, using statistical criteria to classify results, is compared to positivity in carcinogenesis bioassays for 48 chemicals tested in NCI/NTP-sponsored programs. Sensitivity of the Salmonella test across 5 tester strains was 91% (21/23), while specificity was only 36% (9/25). Results were most concordant for TA100 Aroclor-induced rat S9: sensitivity was 87%, specificity 64%. The correlation of mutagenic potency and carcinogenic potency was 0.41 (p less than 0.001) for 80 chemicals, using results from both the general published literature and the NCI/NTP-sponsored programs. After removal of 3 extreme values, the correlation was 0.24 (p = 0.04).

DNA-binding studies with 6BT and 5I: implications for DNA-binding/carcinogenicity and DNA-binding/mutagenicity correlations

The divergent activities of a reported carcinogen/noncarcinogen pair of monoazo dyes related to the hepatocarcinogen Butter Yellow (DAB) are currently under investigation in our laboratories. As part of these studies we have determined (a) target organ distribution after oral dosing to rats and (b) covalent binding of 14C-labelled compound to DNA. In DNA-binding studies, 3 rat liver-metabolising systems were employed: in vivo (whole liver), isolated intact hepatocytes, and liver subcellular fractions. Distribution studies revealed that comparable levels of both compounds were detected in the liver at similar times after dosing, and these in vivo tissue concentrations were used for in vitro DNA-binding studies. At this 'in vivo equivalent dose', the carcinogen was consistently bound to DNA more effectively, and the difference (ratio of DNA binding) between the 2 compounds was far greater in vivo. In subsequent studies, covalent DNA binding to bacterial (Salmonella) DNA was assessed at the in vivo equivalent dose. In contrast to the afore-mentioned findings in mammalian systems, the carcinogen was bound less effectively to DNA, and gave fewer revertant counts/plate when the 2 compounds were bound to an equivalent extent. These data are discussed in view of their implications for DNA-binding/carcinogenicity correlations, and with respect to the relationship between DNA binding and mutagenicity in the Salmonella assay.

Alkylating activity in food products--especially sauerkraut and sour fermented dairy products--after incubation with nitrite under quasi-gastric conditions

N-Nitroso compounds may well rank high among the genotoxic carcinogens present in our environment. Small amounts of such compounds may be formed in the human stomach after consumption of high-nitrate vegetables. Volatile nitrosamines can be conveniently determined but reliable methods of analysis for non-volatile N-nitroso compounds are still lacking. In this study we have used the 4-(4-nitrobenzyl)pyridine test to look for the formation of alkylating compounds such as N-nitroso-N-methylurea in a wide range of food products after incubation with nitrite under simulated gastric conditions. Our results indicate that many food products do not form alkylating compounds in appreciable amounts, even though the nitrite concentration used was five to ten times that found in saliva after a high-nitrate meal. Comparatively strong alkylating activity, however, was detected after incubation of samples of sauerkraut, certain dairy products (yoghurt, biogarde, quark, buttermilk and milk), wine and smoked mackerel. Samples of sauerkraut incubated with simulated gastric fluid, but without (added) nitrite, also displayed appreciable alkylating activity. The formation of alkylating substances in non-fat yoghurt was markedly inhibited by addition of ascorbic acid. The identity of the alkylating agents remains unknown. The isolation procedure was optimized for N-nitroso-N-methylurea, but will certainly result in the isolation of other compounds, such as C-nitroso-, C-nitro- or perhaps even C-nitroso-C'-nitro-compounds as well. Biogenic amines, glucosinolates, indole derivatives or other compounds may be involved as precursors. If alkylating agents are formed in vivo after ingestion of high-nitrate vegetables or drinking water, this is likely to occur only when the food products mentioned above are ingested simultaneously with or shortly after the nitrate load and not appreciably (except perhaps in the case of sauerkraut) when they are ingested alone, without a nitrate source. The health implications of these findings cannot yet be established. Many alkylating agents, however, have strong carcinogenic properties and continued investigation of food products (and their interaction products with nitrite) is indicated.

Biomonitoring of aromatic amines and alkylating agents by measuring hemoglobin adducts

Analysis of hemoglobin adducts in blood samples is suitable for the biological monitoring of genotoxic chemicals. The method is specific because the compound to which the individual was exposed is identified. The sensitivity of the method depends on the analytical procedure applied, but is hardly limiting since large amounts of the protein can be obtained. The method provides not only information about the internal exposure to the environmental chemical, but also about the individual's capacity to generate ultimate genotoxic metabolites from it. Since macromolecular damage in blood cells is correlated to that in potential target tissues, this information is relevant to risk assessment, insofar as macromolecular damage produced by a specific chemical can be correlated with the development of tumors.

Trenbolone growth promotant: covalent DNA binding in rat liver and in Salmonella typhimurium, and mutagenicity in the Ames test

DNA binding in vivo: [6,7-3H]beta-trenbolone (beta-TBOH) was administered p.o. and i.p. to rats. After 8 or 16 h, DNA was isolated from the livers and purified to constant specific radioactivity. Enzymatic digestion to deoxyribonucleotides and separation by HPLC revealed about 90% of the DNA radioactivity eluting in the form of possible TBOH-nucleotide adducts. The extent of this genotoxicity, expressed in units of the Covalent Binding Index, CBI = (mumol TBOH bound per mol nucleotide)/(mmol TBOH administered per kg body weight) spanned from 8 to 17, i.e. was in the range found with weak genotoxic carcinogens. Ames test: low doses of beta-TBOH increased the number of revertants in Salmonella strain TA100 reproducibly and in a dose-dependent manner. The mutagenic potency was 0.2 revertants per nmol after preincubation of the bacteria (20 min at 37 degrees C) with doses between 30 and 60 micrograms per plate (47 and 94 micrograms/ml preincubation mixture). Above this dose, the number of revertants decreased to control values, accompanied by a reduction in survival. The addition of rat liver S9 inhibited the mutagenicity. DNA binding in vitro: calf thymus DNA was incubated with tritiated beta-TBOH with and without rat liver S9. Highest DNA radioactivities were determined in the absence of the "activation" system. Addition of inactive S9 (without cofactors) reduced the DNA binding by a factor of up to 20. Intermediate results were found with active S9. DNA binding in Salmonella: beta-TBOH was irreversibly bound to DNA isolated from S. typhimurium TA100 after incubation of bacteria with [3H]beta-TBOH.

The potential usefulness of biological markers in risk assessment

Substantial data have been generated during the last 5 years in experimental systems and human populations which shed light on the potential usefulness of biological markers in human cancer risk assessment. Following a brief review of overall progress to date in the biomonitoring of human populations, this paper turns to the growing body of data regarding carcinogen-DNA and protein adducts as illustrative markers of biologically effective dose of carcinogens. The data base illustrates considerable human inter-individual variation in binding and the presence of significant "background" levels of adducts--both of which support the absence of human population thresholds for exposure to carcinogens. The contribution of adduct data to our understanding of the shape of low dose-response curve and the reliability of inter-species extrapolation, as well as the relevance of adducts to cancer risk, are also discussed. Even though adducts can now be useful in hazard identification or qualitative risk assessment, more research is needed before they can serve as quantitative predictors of human cancer risk.

Activation of deoxycholic acid by the lipid peroxy radical and its covalent binding to nucleic acids

Deoxycholic acid, a colon tumor promoter, was found to bind covalently to DNA and RNA in the presence of methyl linoleate hydroperoxide and ferrous ion. This binding was shown to occur specifically with guanine residues and its covalent nature was demonstrated by analysis of hydrolysates of nucleic acid adducts. These findings are discussed in connection with the increased risk of colon cancer associated with a high fat and meat diet.

The effects of dietary cabbage on xenobiotic-metabolizing enzymes and the binding of aflatoxin B1 to hepatic DNA in rats

The effect of dietary cabbage (Brassica oleracea) on the binding of aflatoxin B1 (AFB1) to hepatic DNA and on the activities of liver and intestinal microsomal and cytosolic enzymes was studied in weanling male Fischer 344 rats. Freeze-dried cabbage was fed to rats at a level of 25% in the diet for 21 days, while others received a basal diet. In the cabbage-fed group there was an 87% (P less than 0.01) reduction in the binding of AFB1 to hepatic DNA 2 hr after the ip injection of [3H]AFB1 (3 micrograms/kg). There was also a 41% (P less than 0.05) increase in liver weight expressed relative to body weight. Hepatic and intestinal glutathione S-transferase activities were significantly increased (2.1- and 2.3-fold, respectively) over those in rats fed the basal diet. Hepatic and intestinal microsomal epoxide hydrolase activities were significantly increased (2.6- and 1.4-fold, respectively) over the basal group. Intestinal aryl hydrocarbon hydroxylase (AHH) and ethoxycoumarin O-deethylase (ECD) activities were significantly increased (2.3- and 2.5-fold, respectively), over the basal group but dietary cabbage had no significant effect on hepatic AHH or ECD activities.