Evaluation of short-term tests for carcinogenicity

Combinations of genotoxic tests for the evaluation of group 1 IARC carcinogens

Many of the known human carcinogens are potent genotoxins that are efficiently detected as carcinogens in human populations but certain types of compounds such as immunosuppressants, sex hormones, etc. act via non-genotoxic mechanism. The absence of genotoxicity and the diversity of modes of action of non-genotoxic carcinogens make predicting their carcinogenic potential extremely challenging. There is evidence that combinations of different short-term tests provide a better and efficient prediction of human genotoxic and non-genotoxic carcinogens. The purpose of this study is to summarize the in vivo and in vitro comet assay (CMT) results of group 1 carcinogens selected from the International Agency for Research on Cancer and to discuss the utility of the comet assay along with other genotoxic assays such as Ames, in vivo micronucleus (MN), and in vivo chromosomal aberration (CA) test. Of the 62 agents for which valid genotoxic data were available, 38 of 61 (62.3%) were Ames test positive, 42 of 60 (70%) were in vivo MN test positive and 36 of 45 (80%) were positive for the in vivo CA test. Higher sensitivity was seen in in vivo CMT (90%) and in vitro CMT (86.9%) assay. Combination of two tests has greater sensitivity than individual tests: in vivo MN + in vivo CA (88.6%); in vivo MN + in vivo CMT (92.5%); and in vivo MN + in vitro CMT (95.6%). Combinations of in vivo or in vitro CMT with other tests provided better sensitivity. In vivo CMT in combination with in vivo CA provided the highest sensitivity (96.7%).

A host-mediated in vivo/in vitro assay with peritoneal murine macrophages for the detection of carcinogenic chemicals

We have developed a host-mediated assay system for the detection of the transforming action of chemical carcinogens on peritoneal macrophages. Directly as well as indirectly acting carcinogenic substances administered intraperitoneally to NMRI mice could be examined in this way. Resident macrophages were recovered by peritoneal lavage from treated and untreated mice and were cultured in soft agar. After 5-6 days normal and transformed cells could be distinguished. Statistical analysis comparing cells, for example, from alpha-naphthylamine or diphenylhydantoin-treated animals with those from control mice proved that the test is positive at least on a significance level of 5% using the t-test. Further substances revealing a cell-transformation potential were benzene, benz(a)pyrene, 2,3,7,8-tetrachlorodibenzodioxin, N-nitrosodimethylamine, ethidium bromide, aflatoxin B1,N-methyl-N-nitrosourea, 1-methyl-3-nitro-1-nitrosoguanidine, 2-naphthylamine, dieldrin, suramin and trichloroethylene. A weak transforming potential was found for chlorambucil as well as for tetrachloroethylene. With toluene or azidothymidine no cell transformation could be observed. Several immortal cell lines could be established form NMRI mice treated with alpha-naphthylamine or N-methyl-N-nitrosourea. Athymic nu/nu mice injected subcutaneously with these cells developed tumors, establishing the oncogenic potential of these cell lines.

Prevention of formation of important mutagens/carcinogens in the human food chain

Etiological factors for gastric cancer, among others, involve consumption of smoked, salted, and pickled fish of certain types. Their chemical nature is not yet fully established but probably involves diazo phenols, and their formation can be prevented either by omitting the salting and pickling process, or by using vitamins C and E on the food prior to salting, pickling, or smoking. Both preventive approaches would limit the formation of mutagenic and carcinogenic diazo phenols. Sugimura and associates discovered new types of mutagens as heterocyclic amines that are formed during frying or broiling of meats and fish. In rats, these amines induce cancer specifically in organs such as breast, colon, or pancreas, associated with Western-type nutrition where promotional elements such as dietary fat play an enhancing role. Thus, inhibition of the formation of these new carcinogens during cooking would remove the genotoxic components from the diet. Mixing 10% soy protein with ground meat prior to frying prevents the formation of these mutagens presumably by affording a lower surface temperature. More effective is the addition of tryptophan, proline, or mixtures thereof, which specifically blocks the formation of these mutagens/carcinogens, probably by competing for reactive intermediary aldehydes, so that these cannot interact with the normal essential target, creatinine. Thus, we have available practical, yet science-based, mechanistically understood procedures to prevent the formation of carcinogens associated with important types of cancer prevalent in many countries.

Biologic activity of hydroxylamine: a review

Although hydroxylamine, as such, is a product of normal cellular metabolism it is also a potent mutagen in vitro. However, in spite of this potential, it has not been shown to possess carcinogenic capabilities. Indeed, this chemical has demonstrated carcinostatic activity against certain tumors in animals. In addition, hydroxylamine has been shown to inactivate or inhibit a number of cellular enzymes and some viruses in vitro. It is also a skin irritant and sensitizer. It causes dermatitis and it is corrosive to the eyes. Acute and chronic exposures to hydroxylamine have caused methemoglobinemia and sulfhemoglobinemia.

Quantitation of aflatoxin B1 adduction within the ribosomal RNA gene sequences of rat liver DNA

The in vivo formation of covalent aflatoxin B1 (AFB1)-DNA adducts within the rRNA gene sequences of nuclear DNA has been studied in AFB1-treated rats. Liver nuclear DNA, enriched in ribosomal DNA (rDNA) by one round of cesium salt density gradient centrifugation, was treated under buffered alkaline conditions to convert unstable AFB1-N7-guanine adducts to stable AFB1-formamidopyrimidine derivatives. The alkali-treated DNA was hybridized to 18S and 28S rRNA in 70% formamide buffer to form rRNA X rDNA hybrids. These hybrids were separated from the bulk of nuclear DNA by two rounds of centrifugation in CsCl, and the level of AFB1 adduction to rDNA versus total nuclear DNA was compared as a function of dose 2 hr after AFB1 administration. Over an 8-fold dose range (0.25-2.0 mg of AFB1 per kg of body weight), rDNA contained 4- to 5-fold more AFB1 residues than nuclear DNA, indicating that rDNA is preferentially accessible to carcinogen modification in vivo. While aflatoxin B1 forms adducts with DNA principally at guanine residues, the guanine enrichment of rDNA was insufficient to explain the magnitude of observed preferential AFB1 modification of rDNA. These results support the hypothesis that rDNA regions are preferentially accessible to carcinogen modification because of the diffuse conformation maintained within transcribed genes. This experimental approach permits the quantitative description of carcinogen modification within a defined gene sequence; further refinement of this approach may be useful in defining the precise relationships between covalent chemical-DNA interactions and the alterations in gene expression that result.

The unique role of rodents in the detection of possible human carcinogens and mutagens

Some of the probable reasons underlying the observation that not all chemicals shown to be genotoxic in vitro are capable of eliciting tumours in rodents or humans are discussed using appropriate examples. It is suggested that a substantial proportion of the resources currently available for conducting rodent carcinogenicity bioassays should be employed in the short-term evaluation in vivo of some of the many hundreds of chemicals recently defined as genotoxic in vitro, rather than in the protracted evaluation of a few chemicals, often of unknown activity in vitro, for carcinogenicity. A decision tree approach to the evaluation of chemicals for human mutagenic/carcinogenic potential is presented which is at variance with the construction and philosophy of many of the current legislative guidelines. The immediate need for the adoption of one of the available short-term in vivo liver assays, and/or the development of a short-term in vivo rodent assay capable of concomitantly monitoring different genetic end-points in a range of organs or tissues is emphasized.

Detection of chemical carcinogens by assay of unscheduled DNA synthesis in rat tracheal epithelium in short-term organ culture

A short-term organ culture of rat tracheal epithelium was used to detect the ability of 53 chemicals to induce UDS. In this system all direct-acting compounds (ultimate or proximate carcinogens) tested induced UDS. Of 24 compounds requiring metabolism (procarcinogens), nine induced UDS, viz., 4NQO, AF-2, BP, DMN, DEN, and NP. Urethane, AAF, and 2,7-AAF induced very slight UDS. 3-Methyl-4NQO for which carcinogenicity data is incomplete as positive in our system. Among the cancer chemotherapeutic agents tested only mitomycin C induced UDS. MC and DMBA, which are known to induce cancer of respiratory organs in experimented animals, and DAB, aflatoxin B1 and Trp-P-1, which are strong carcinogens in the liver, did not induce UDS within 2 h. With the longer exposure (24 h), these carcinogens also failed to elicit UDS. All the carcinogens that induce UDS showed clear dose-dependent effects. No non-carcinogens tested induced UDS. These results suggested that this system should be useful for screening environmental chemicals suspected of damaging DNA of the respiratory organ on the basis of organotropic effects for UDS induction in cultured rat tracheal epithelium.

Enhanced excretion of thioethers in urine of operators of chemical waste incinerators

Thioether concentrations were determined in urine samples obtained from ten workers in the despatch department (n = 69), three chemical waste incinerator operators (n = 67), and an analyst (n = 21), all working in the same chemical plant. Urine samples (n = 196) obtained from non-exposed men, including smokers, served as controls. Enhanced excretion of thioethers was found in urine samples taken from incinerator workers at the end of work. A regular pattern in the time course of the urinary thioether excretion was shown by a non-smoking incinerator worker; end-of-work values were always higher than prework values. This phenomenon was not found in samples obtained from the analyst. These findings suggest that incinerator workers inhale or otherwise absorb electrophilic compounds or their precursors, which are subsequently metabolised to, and excreted as, thioethers in urine.

Comparative induction of unscheduled DNA synthesis by physical and chemical agents in non-proliferating primary cultures of rat hepatocytes

The incorporation of [3H]thymidine into DNA due to unscheduled DNA synthesis (UDS) induced by N-OH-2-acetylaminofluorene (N-OH-AAF), aflatoxin B1 (AFB1), ethyl methanesulfonate (EMS) and ultra-violet light was quantitated by autoradiography and by scintillation spectrometry on acid precipitable macromolecules or DNA insolated by isopycnic banding in cesium chloride (CsCl). Dose-dependent increases in UDS due to N-OH-AAF and AFB1 treatment were found. Only 2-fold increases at the highest dose levels were found, however, when incorporated [3H]thymidine was quantitated by scintillation spectrometry. Seven, 11, and 25-fold increases in UDS induced by AFB1, N-OH-AAF and ultra-violet light, respectively, were found when incorporated [3H]thymidine was quantitated by autoradiography, indicating a high sensitivity for detecting 'long patch' repair by this technique. Scintillation spectrometry was completely ineffective in detecting EMS-induced UDS, whereas autoradiography demonstrated a small, but significant induction in [3H]thymidine incorporation at high dose levels. The non-proliferative nature of the primary hepatocyte prohibits the uniform radioactive prelabeling of DNA, necessary in other techniques, for the detection of 'short patch' repair induced by compounds such as EMS. Therefore, the sensitivity of the primary cultured rat hepatocyte in conjunction with UDS for detecting DNA damage caused by mutagens and carcinogens which induce 'short patch' repair may be limited to the autoradiographic analysis of the unscheduled incorporation of [3H]thymidine.

Mutagenic and carcinogenic effects of pesticides

A discussion of the mutagenic and carcinogenic effects of various classes of commonly used pesticides. Classes discussed include halogenated hydrocarbons organophosphorus insecticides, and certain herbicides and fungicides. Halogenated hydrocarbons were found generally hazardous, causing sterility and displaying marginal or definite carcinogenic activity. Several organophosphorus insecticides have been shown to be mutagens; some have been shown to be carcinogens. Both the herbicide impurity tetrachlorodibenzodioxin, TCDD, and maleic hydrazide have been shown to be carcinogenic in mice and rats. The role of DNA as a critical target for carcinogenic activity is also discussed.

Screening of toxic compounds in tissue culture

To screen toxicity of chemicals most often easily manageable cultures of less differentiated cells have been used. This work includes 3 fields: (i) Screening of chemicals and fermentation broths for their cytoinhibitory effect, to predict antineoplastic activity. A related practical approach is to achieve optimal antitumour drug therapy by testing drugs on cultures of tumour cells from the patient. (ii) Screening of metal and plastic materials used in medicine, surgery and dentistry for their cytoinhibitory effect to predict local irritation. (iii) Screening of the mutagenicity or transformation capacity of chemicals in tissue culture, to predict their carcinogenicity. In addition, organ-specific cultures of most specialized cells (hepatocytes, ova, nerve cells, heart cells, skin cells, respiratory mucosa, and macrophages) have also been used to predict drug action on corresponding targets in the body. The author's group has focused on 2 new uses of standard cells for screening chemical toxicity: (i) Comparisons of in vitro cytotoxicity with in vivo toxicity of 85 randomly selected drugs indicated that for most drugs a systemic lethal action was brought about by cytotoxicity. A screening model is advocated by which results of cytotoxicity tests are compared with systemic toxicity in vivo to evaluate the systemic cytotoxicity of chemicals. (ii) Combinations of compounds with a cytotoxic lethal action in man indicated by the previous method have been screened in vitro for their combined systemic toxicity. By systematic comparison of results from standardized in vitro tests with in vivo toxicity, steps have been taken to resolve the question of the relevance of screening in tissue culture and to contribute to the development of an emerging subdiscipline to toxicology -- in vitro cytotoxicology.

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

The covalent binding of chemical carcinogens to DNA of mammalian organs is expressed per unit dose, and a 'Covalent-Binding Index', CBI, is defined. CBI for various carcinogens span over 6 orders of magnitude. A similar range is observed for the carcinogenic potency in long-term bioassays on carcinogenicity. For the assessment of a risk from exposure to a carcinogen, the total DNA dmaage can be estimated if the actual dose is also accounted for. A detailed description is given for planning and performing a DNA-binding assay. A complete literature survey on DNA binding in vivo (83 compounds) is given with a calculation of CBI, where possible, 153 compounds are listed where a covalent binding to any biological macromolecule has been shown in vivo or in vitro. Recent, so far unpublished findings with aflatoxin M1, macromolecule-bound aflatoxin B1, diethylstilbestrol, and 1,2-epithiobutyronitrile are included. A comparison of CBI for rat-liver DNA with hepatocarcinogenic potency reveals a surprisingly good quantitative correlation. Refinements for a DNA-binding assay are proposed. Possibilites and limitations in the use of DNA binding in chemical carcinogenesis are discussed extensively.

Transplacental mutagenesis of products formed in the stomach of golden hamsters given sodium nitrite and morpholine

Hamster embryos were exposed in utero to the action of sodium nitrite (NaNO2) and morpholine (Mo) administered simultaneously by stomach tube to the mothers on the 11th or 12th day of pregnancy. Embryo cells were examined for chromosomal aberrations, micronuclear formation, morphological or malignant transformation and drug resistance mutations. For detection of induced mutations, the embryo cells were cultured in normal medium for 72 h and then transferred to medium containing 10 or 20 micrograms/ml of 8-azaguanine (8AG) or 1m7 ouabain (Oua). The number of 8AG-, Ouaresistant colonies was markedly increased after administration of NaNO2 and Mo. The embryonic fibroblasts also showed a markedly increased frequency of micronucleation and a slight increase in chromosome aberrations. This treatment also caused morphological or malignant transformation of fetal cells. After cultivation in vitro, cells from some transformed colonies produced tumors when inoculated into the cheek pouch of young golden hamsters. Orally administered N-nitroso-morpholine (N-Mo), as a positive control, had the same transplacental biological actions on embryonic fibroblasts. However, transplacentally Mo alone was ineffective. A single administration of 500 mg/kg NaNO2 had only slight biological effects. N-Mo was produced in the stomachs of animals treated simultaneously with NaNO2 and Mo. A small amount of a nitrosamine, N-nitrosodimethylamine (DMN), was detected in the stomach after a single dose of NaNO2.

Mutagenicity, cytotoxicity and DNA crosslinking in V79 Chinese hamster cells treated with cis- and trans-Pt(II) diamminedichloride

The mutagenicity and cytotoxicity of cis- and trans-Pt(II) diamminedichloride (PDD) were examined in V79 Chinese hamster lung cells and compared with effects on DNA measured by alkaline elution. DNA--protein crosslinks and DNA interstrand crosslinks were detected following doses of cis-PDD which reduced cell survival 80--90% and which produced a mutant frequency of 3 X 10(-4) at the HGPRT locus. Equitoxic doses of trans-PDD were much less mutagenic than cis-PDD. At equitoxic doses, trans-PDD produced more DNA-protein crosslinking than did cis-PDD, but interstrand crosslinking for the two isomers was comparable. Hence, the interstrand crosslink could be the cytotoxic lesion produced by these Pt compounds whereas neither of these DNA lesions are necessarily mutagenic. The mutagenesis produced by cis-PDD could be due to crosslinks of a different type than those produced by trans-PDD or it may be due to monofunctional damage.

Mutagenicity studies on urine concentrates from female users of dark hair color products

Urines from women, collected before and after hair dyeing, were evaluated for mutagenic activity in the Ames Salmonella-Microsome Test. Thirty (30) sets of samples were tested as concentrates following removal of histidine on an XAD-2 resin column. None of the samples taken following the use of various Clairol products containing high levels of dyes gave any indication of increased mutagenic activity when compared to samples taken before hair dyeing. These results indicate that the use of hair dyes does not result in exposure of the urinary system to mutagens detectable in a sensitive microbial system, and thus suggest the absence of significant biological effects among users of hair dyes and persons occupationally exposed.

Interactions of vinyl chloride with rat-liver DNA in vivo

9beta-D-2'-Deoxyribofuranosyl-imidazo-[2,1-i]purine ("etheno-deoxyadenosine") and 1beta-D-2'-deoxyribofuranosyl-1,2-dihydro-2-oxo-imidazo-[1,2-c]pyrimidine ("etheno-deoxycytidine") are identified in the enzyme hydrolysates obtained (i) from calf-thymus DNA which had been modified by chemical reaction with chloroacetaldehyde and (ii) from liver DNA prepared from rats which had been exposed orally to vinyl chloride in their drinking water (250 ppm) for approx. 2 years. Thus, vinyl chloride-derived chloroethylene oxide and/or chloroacetaldehyde behaves as a bifunctional alkylating agent towards deoxyadenosine and deoxycytidine residues of DNA. The separation of deoxyribonucleosides and the two etheno-deoxyribosyl-nucleosides by liquid chromatography, and the mass spectra of etheno-deoxyadenosine and etheno-deoxycytidine and of their O-bis-(trimethylsilyl) derivatives are described. In the animal experiment (ii), the resulting proportion of etheno-deoxyadenosine is small compared with that of etheno-deoxycytidine. Imidazo-[2,1-i]purine (etheno-adenine) is identified: (a) in the supernatant after sedimentation of the modified DNA in the model experiment (i), and (b) in the product resulting from the reaction between chloroacetaldehyde and deoxyadenosine. The effect on the structure of DNA of the imidazo-cyclization of deoxyadenosine and deoxycytidine residues and of the depurination of etheno-deoxyadenosine residues is discussed in relation to vinyl chloride oncogenicity.

A possible short-term prediction of potential carcinogenicity of chemical compounds in vivo by means of a promoting activity test (PAT)

Carcinogens of chemically unrelated structure and different organotropism cause a mitotic stimulation of adrenocortical epithelia in vivo. A similar response is observed in liver regenerating rats following partial hepatectomy or intoxication by carbon tetrachloride. It is very probable from these and other results that the short-term effect (48 hours p. applic.) is brought about by the emergence of humoral growth stimulators which are evidenced in restorative regeneration and, therefore, accounts for the promoting activity of carcinogens. Special problems resulting from false positive (indomethacin, sodium nitrite) and false negative (7,12-dimethylbenz(a)anthracene, ethionine) findings as well as such of the role of solvents are discussed. The proof of the "contradictory" test result by long-term treatment in the case of trinitroso-trimethylene-triamine, nitroso-ethyltert-butylamine or nitroso-diallylamine has shown the accuracy of this short-term test.

Cutting fluids and their effects on the skin of mice. An experimental study with special reference to carcinogenicity

Reports of skin malignancies due to occupational exposure have decreased since the introduction of solvent-refining of mineral oil fraction in the manufacture of oil based cutting fluids. Commercial mineral oil based cutting fluids caused local and general pathological changes after repeated application to the skin of mice in the present study. Forty-eight per cent of the mice exposed to oils showed severe dysplasia or malignancy of the skin on histological examination. The corresponding figure for the control group, where various additives were used was 8 per cent. The frequency of papillomas was also increased in the mice exposed to oils. The systemic lesions included focal necrosis of the liver, associated with amyloid deposition, as well as amyloidosis of the skin, spleen and kidneys. The substances responsible for these apparent carcinogenic properties of the complex mixtures may be polycyclic hydrocarbons; the latter are still present in the commercial products despite solvent refining; on the other hand the carcinogens may be additives to the cutting oils the composition of which is generally a trade secret.

Morphological transformation of early passage golden Syrian hamster embryo cells derived from cryopreserved primary cultures as a reliable in vitro bioassay for identifying diverse carcinogens

Cryopreserved primary cultures of golden Syrian hamster embryo cells were used as the source of target and feeder cells for establishing an in vitro carcinogenesis bioassay. The primary culture giving the best overall response in a pretest before freezing gave positive results in 20 consecutive experiments when retested with 3-methylcholanthrene after cryopreservation, indicating that pretested cryopreserved cultures can serve as a source of susceptible target cells in an in vitro carcinogenesis bioassay. Similarly prepared and cryopreserved cultures served satisfactorily as feeder cells. Susceptible positive cultures were used to test a large number of carcinogenic and non-carcinogenic chemicals in this system. The results showed a very high positive correlation (90.8%) between morphological transformation and the reported carcinogenic activity of the chemicals. Transformation was not observed when cells were tested with a few carcinogens that may not be metabolized to their active forms by early passage hamster embryo cells. N-2-acetylaminofluorene transformed cells only when tested in the presence of hamster liver microsomes. No false positive results were obtained when non-carcinogens were bioassayed, nor was spontaneous transformation observed in control cultures treated with medium alone, 0.2% dimethylsulfoxide or other solvents. Cultures derived from morphologically transformed colonies arising after treatment of cells with several known carcinogens were tumorigenic in vivo, confirming the correlation of morphological transformation with tumorigenicity and the validity of altered morphology as an in vitro criterion for carcinogenicity in vivo.

In vitro mutagenesis assays as predictors of chemical carcinogenesis in mammals

In vitro microbial mutagenesis assays coupled with mammalian activation systems offer promising technique to screen chemicals for their potential carcinogenic activity. The correlation between mutagenic and carcinogenic properties for a large array of chemicals is approximately 0.9. The best correlation exists for those carcinogens which are themselves highly electrophilic or produce electrophilic metabolites. Correlation between mutagenicity and carcinogenicity for hormonal, metallic, or physical carcinogens has been disappointing but not unexpected based on their proposed mechanisms of action. In addition to the application of in vitro mutagenesis techniques to screening chemicals for the identification of potential carcinogens, they are useful tools for investigating genetic, biochemical, and pharmacologic properties of different animal species. Studies with the chemical carcinogen dimethylnitrosamine have been conducted and show a functional relationship between mutagenesis and carcinogenesis. The assays can also be conducted using activation systems prepared from the tissues of any mammalian species. This permits a direct assessment of phylogenic extrapolation by comparing the metabolic activation capabilities of tissues from several mammalian species, including human samples. The advantages of mutagenicity testing are the short period of time required for results, the high sensitivity of the assay (microgram of nanogram quantities of chemicals can be used), and the fact that the ultimate agent can be detected biologically without first necessitating chemical identification and isolation. It appears from current studies that in vitro mutagenesis techniques may well open new avenues of investigation into some old toxicologic problems.

Mutagenic effect of nialamide on Salmonella typhimurium

The mutagenicity of an antidepressant drug, nialamide, was studied with Salmonella typhimurium TA1535-8. Nialamied was mutagenic for strain TA1535 in the absence of rat liver extracts.

The capacity of Drosophila for detecting relevant genetic damage

For the detection and study of mutagenic agents, Drosophila offers many advantages. It is a higher organism with a short generation time that is cheap and easy to breed in large numbers. The simple genetic testing methods provide unequivocal answers about the whole spectrum of relevant genetic damage. A comparison of the detection capacity of assays sampling different kinds of genetic damage revealed that various substances are highly effective in inducing mutations, but do not produce chromosome breakage effects at all, or only at much higher concentrations than those required for mutation induction. Of the different assay systems available, the classical sex-linked recessive lethal test thus deserves priority, in view of its superior capacity to detect mutagens. Of practical importance is also its high sensitivity, because a large number of loci in one-fifth of the genome is tested for newly induced forward mutations, including small deletions. Drosophila is capable of carrying out the same metabolic activation reactions as the mammalian liver. An additional advantage, in this respect, is the capacity of Drosophila for detecting short-lived activation products, because intracellular activation occurs within the spermatids ans spermatocytes. These properties make the test for recessive sex-linked lethals a useful tool for verifying results obtained in the pre-screening of potential mutagens with fast microbial assay systems. In studies on non-disjunction, detailed genetic analysis of the induced changes is possible, and these may shed light on the mechanisms involved. A new adaptation of the bithorax transvection method by Mendelson permits the recovery of high yields of chromosome aberrations in a fast one-generation test.

The utilization of in vitro mutagenesis techniques to explain strain, age and sex related differences in dimethylnitrosamine tumor susceptibilities in mice

The carcinogen dimethylnitrosamine (DMNA) is known to exhibit a high degree of strain, organ, age, and sex related tumor specificity in mice. Using microbial mutagenesis assay coupled with mouse tissue microsomal enzyme activation systems, evidence has been obtained that demonstrated a close relationship between the level of in vitro DMNA activation to a mutagen and in vivo tumor susceptibility. DMNA activation by liver, lung, and kidney microsomes from several mouse strains was compared by measuring the rate of mutagenic metabolites formed during incubation of the carcinogen in mutation assays using Salmonella typhimurium G-46 as the indicator microorganism.

Mutagenicity of beta-oxidized N,N,-di-n-propylnitrosamine derivatives in S. typhimurium mediated by rat and hamster tissues

The relative abilities of liver, kidney and lung fractions from untreated or phenobarbitone-pretreated rats and hamsters to convert N,N-di-n-propylnitrosamine and several beta-oxidized synthetic putative intermediates into mutagens was quantitatively compared in a tissue-mediated mutagenicity assay with S. typhimurium TA 1530 in vitro. With one exception, namely, N,N-di(2-acetoxy-n-propyl)nitrosamine, liver was the most active tissue from hamsters; in rats also, only liver fractions were able to activate some nitroso-compounds to mutagens. The highest enzyme-mediated mutagenicities were observed with N-2-hydroxy-n-propyl-N-n-propylnitrosamine, N,N-di-n-propylnitrosamine and N,N-di(2-acetoxy-n-propyl)nitrosamine. Hamster lung tissue converted N,N-di-n-propylnitrosamine, N-2-hydroxy-n-propyl-N-n-propylnitrosamine and N,N-di(2-acetoxy-n-propyl)nitrosamine into mutagens; activity with the latter compound was greater with lung tissue than with liver tissue when untreated animals were used. N-methyl-N-n-propylnitrosamine was mutagenic in the presence of hamster liver fraction but less so than N,N-di-n-propylnitrosamine. The results of the mutagenicity assays using various tissues are qualitatively compared to sites of tumour formation in rats and hamsters by these N-nitrosamines.

Carcinogen-induced DNA repair in primary rat liver cell cultures; a possible screen for chemical carcinogens

Primary rat liver cell cultures were exposed to a direct acting carcinogen, methyl methanesulfonate, and procarcinogens requiring metabolic activation, aflatoxin B1 and B2. DNA damage by these agents was evidenced by the induction of DNA repair, measured as unscheduled DNA synthesis. The sensitivity of these cultures to the potent porcarcinogen aflatoxin B1 indicates that this system may be adapted for screening suspected chemical procarcinogens, and for investigating the relationship between metabolic activation of procarcinogens, DNA damage, DNA repair, and carcinogenicity.

Industrial mutagens and potential mutagens I. Halogenated aliphatic derivatives

The halogenated aliphatic hydrocarbons represent one of the most important categories of industrial chemicals from a consideration of volume, use categories, environmental and toxicological considerations and hence most importantly, potential population risk. The major halocarbons reviewed, primarily in terms of their occurrence, utility, stability, distribution, and levels of exposure as well as their metabolism, carcinogenicity and mutagenicity included: vinylchloride, vinylidene chloride, trichloroethylene, perchloroethylene, ethylene dichloride, ethylene dibromide, chloroprene, chloroform, carbon tetrachloride, fluorocarbons (trichlorofluoromethane and dichlorodifluoromethane), epichlorohydrin, halohydrins (2-chloro- and 2-bromoethanol) and haloethers (bis(chloromethyl); chloromethyl'-methyl; bis(2-chloroethyl)-and bis(2-chloroisopropyl)ether. In many instances, data were not available to assess world production, populations at risk and degrees of exposure. With the exception of vinylchloride, vinylidene chloride, epichlorohydrin and 2-halo ethanols, there is an acknowledged paucity of definitive mutagenicity data concerning the majority of halogenated hydrocarbons. Their ubiquitous distribution, and in a number of cases, their carcinogenicity both in man and animals, dictates the urgent need to more exhaustively investigate their potential mutagenicity.

Suppression of sebaceous gland non-specific esterase activity be electrophilic alpha beta-unsaturated compounds

Sebaceous gland non-specific esterase activity was suppressed following application to mouse skin of 2 electrophilic alpha beta-unsaturated compounds, o-chlorobenzylidenemalononitrile and beta-nitrostyrene, but not by three others.