Acrylonitrile: in vivo cytogenetic studies in mice and rats

Teratological effects of pesticides in vertebrates: a review

In the last decades, the use and misuse of pesticides in the agriculture have increased, having a severe impact on ecosystems and their fauna. Although the various effects of pesticides on biodiversity have been already documented in several studies, to our knowledge no consistent overview of the impact of pesticides in vertebrates, both terrestrial and aquatic, is available. In this review, we try to present a concise compilation of the teratogenic effects of pesticides on the different classes of vertebrates - mammals, birds, reptiles, amphibians and fish.

Assessment of protective potential of Nigella sativa oil against carbendazim- and/or mancozeb-induced hematotoxicity, hepatotoxicity, and genotoxicity

Nigella sativa oil (NSO) possesses antioxidant activity. However, its protective role against the hazards of fungicides has been poorly studied. Therefore, the present work aimed at determining the ameliorative potential of NSO against hepatotoxicity induced by carbendazim (CBZ) and/or mancozeb (MNZ) in female rats. In the present study, about 120 adult female Sprague-Dawley rats were randomly divided into eight equal groups. One group of animals was kept as a negative control (Gp. 1); groups 2, 3 and 4 orally received CBZ (200 mg/kg body wt) and/or MNZ (300 mg/kg body wt) daily for 2 weeks (positive groups). In order to assess the hepatoprotective potential of NSO, in comparison with NSO-treated rats (Gp. 5), groups 6, 7 and 8 were CBZ- and/or MNZ-exposed groups pre-treated orally with NSO (2 ml/kg body wt) daily for 2 weeks (prophylactic groups). All groups were kept further for 15 days without medications to observe the withdrawal effect. At the end of exposure and withdrawal periods, the body weight of all experimental rats was recorded and blood samples were collected for hematological, clinico-biochemical, and micronucleus assays. The animals were then sacrificed, and the liver and bone marrow were harvested for oxidative stress bioassay, chromosomal aberrations, DNA fragmentation, and histopathological examinations. The results suggested that pre-treatment with NSO remarkably diminished CBZ- and MNZ-induced macrocytic hypochromic anemia, leukocytosis, lymphocytosis, eosinophilia, and neutropenia. Besides, it also minimized the elevated liver enzymes, lipid peroxidation, micronucleus incidence, DNA damage, and chromosomal aberration frequency. Conversely, NSO significantly stimulated the CBZ- and/or MNZ-induced antioxidant system suppression. The NSO also normalized the hepatic structural architecture. As far as withdrawal effect is concerned, there was almost disappearance of the bad effects of these fungicides and the values were close to the normal range especially with the use of NSO. Ultimately, the results revealed that N. sativa oil is an effective hepatoprotective agent due to its genoprotective and free radical scavenging activities.

Neoplasms in Rats Ingesting Acrylonitrile for Two Years

Male Sprague-Dawley rats ingested 0, 20 ppm, or 500 ppm of acrylonitrile in drinking water for 2 years. Rats receiving 500 ppm of acrylonitrile exhibited early mortality and retarded weight gain. Tumors of Zymbal's gland were associated in dose-response fashion with acrylonitrile exposure. Age-associated incidence of pituitary adenomas containing immunoreactive prolactin was decreased in acrylonitrile-treated rats. A decrease in pituitary tumor incidence also was observed in rats treated with low doses of acrylonitrile, suggesting that reduction in this tumor frequency was not because of early death. No increases were found in tumors of other organ systems, but a trend toward development of forestomach papillomas was noted in rats receiving the highest concentration of acrylonitrile.

Cytotoxic effect of aspartame (diet sweet) on the histological and genetic structures of female albino rats and their offspring

The present study evaluated the effect of aspartame intake on the histological and genetic structures of mother albino rats and their offspring. Sixty adult female albino rats and 180 of their offspring were equally divided into two groups (control and treated), each group divided into three subgroups. Each subgroup consisted of 10 pregnant rats and 30 of their offspring. The experimental design divided into three periods: (1) the gestation period (subgroup one), (2) the gestation period and three weeks after delivery (subgroup two) and (3) animals in the third subgroup treated as subgroup two then left till the end of the ninth week after delivery. Each pregnant rat in the treated subgroups was given a single daily dose of 1 mL aspartame solution (50.4 mg) by gastric gavage throughout the time intervals of experimental design. At the end of each experimental period for control and treated subgroups, the liver of half of both control and treated groups were subjected for histological study while the liver and bone marrow of the other halves were subjected for cytogenetic studies. Body weight of both groups were recorded individually twice weekly in the morning before offering the diet. The results revealed that the rats and their offspring in the subgroups of control animals showed increases in body weight, normal histological sections, low chromosomal aberration and low DNA fragmentation. The treated animals in the three subgroups rats and their offspring revealed decreases in body weight, high histological lesions, increases in the chromosomal aberration and DNA fragmentation compared with control groups. In conclusion, the consumption of aspartame leads to histopathological lesions in the liver and alterations of the genetic system in the liver and bone marrow of mother albino rats and their offspring. These toxicological changes were directly proportional to the duration of its administration and improved after its withdrawal.

Three-generation reproduction study of rats receiving acrylonitrile in drinking water

Acrylonitrile, a high volume organic chemical, was tested for reproductive effects in a three generation drinking water study with two matings per generation. Sprague-Dawley rats were exposed to acrylonitrile in drinking water at 0, 100, or 500 ppm. This corresponds to 0, 11+/-5 and 37+/-10 mg/kg, respectively, for males and 0, 20+/-3 and 40+/-8 mg/kg per day for the females, respectively. Water consumption was reduced in F0 rats in the 100 and 500 ppm groups. At 500 ppm, acrylonitrile reduced body weight gain and food intake of the first generation parental rats (F0). These parameters were not investigated at subsequent generations. The pup survival (both viability and lactation indices) was reduced at the 500 ppm treatment level in both matings of all three generations. Fostering the 500 ppm pups onto untreated mothers following the second mating lessened mortality, suggesting a maternal effect consistent with decreased water consumption. There was no remarkable change in the reproductive capacity in any of matings in rats at the 100 ppm concentration. In contrast, in all three generations, the body weights of the pups of the 500 ppm treatment level were reduced on Day 21 at both matings. No adverse findings were observed in the tissues of a limited number of third generation weanlings (F3b) upon gross and microscopic evaluation. No effect on the sciatic nerve was evident among the adult female rats held for 20 weeks after weaning of the second litter. There was a dose-related effect of acrylonitrile on gross masses in female rats at each parental generation held 20 weeks after the weaning of the second litter. Histopathological evaluation of these dams showed an increase in astrocytomas and zymbal gland tumors.

Acrylonitrile-induced morphological transformation in Syrian hamster embryo cells

Acrylonitrile (ACN) is a monomer used in the synthesis of rubber, fibers and plastics. Previous studies demonstrated that ACN induces brain neoplasms (predominately astrocytomas) in rats following chronic treatment. While the mechanisms of ACN-induced glial cell carcinogenicity have not been completely elucidated, investigations by our group and others have suggested a role for the induction of oxidative stress and the resultant oxidative damage in this process. In vitro cell transformation models are useful for detecting and studying the mechanisms of chemical carcinogenesis. Cell transformation by chemical carcinogens in Syrian hamster embryo (SHE) cells exhibits a multistage process similar to that observed in vivo, for both non-genotoxic and genotoxic carcinogens. In the present study, the ability of ACN to induce morphological transformation and oxidative damage was examined in SHE cells. ACN induced an increase in morphological transformation at doses of 50, 62.5 and 75 microg/ml (maximum sub-toxic dose tested) following 7 days of continuous treatment. SHE cells exposed to ACN for 24 h failed to increase morphological transformation. Morphological transformation by ACN was inhibited by co-treatment with the antioxidants alpha-tocopherol and (-)-epigallocathechin-3 gallate (EGCG) for 7 days. Treatment of SHE cells with 75 microg/ml ACN produced a significant increase in 8-hydroxy-2'-deoxyguanosine that was also inhibited by co-treatment with alpha-tocopherol or EGCG. These results support the proposal that oxidative stress and the resulting oxidative damage is involved in ACN-induced carcinogenicity.

Mutagenicity, carcinogenicity, and teratogenicity of acrylonitrile

Acrylonitrile (AN) is an important intermediary for the synthesis of a variety of organic products, such as artificial fibres, household articles and resins. Although acute effects are the primary concern for an exposure to AN, potential genotoxic, carcinogenic and teratogenic risks of AN have to be taken seriously in view of the large number of workers employed in such industries and the world-wide population using products containing and possibly liberating AN. An understanding of the effect of acrylonitrile must be based on a characterization of its metabolism as well as of the resulting products and their genotoxic properties. Tests for mutagenicity in bacteria have in general been positive, those in plants and on unscheduled DNA synthesis doubtful, and those on chromosome aberrations in vivo negative. Wherever positive results had been obtained, metabolic activation of AN appeared to be a prerequisite. The extent to which such mutagenic effects are significant in man depends, however, also on the conditions of exposure. It appears from the limited data that the ultimate mutagenic factor(s), such as 2-cyanoethylene oxide, may have little opportunity to act under conditions where people are exposed because it is formed only in small amounts and is rapidly degraded. The carcinogenic action of AN has been evaluated by various agencies and ranged from 'reasonably be anticipated to be a human carcinogen' to 'cannot be excluded', the most recent evaluation being 'possibly carcinogenic to humans'. Animal data that confirm the carcinogenic potential of AN have certain limitations with respect to the choice of species, type of tumors and length of follow up. Epidemiological studies which sometimes, but not always, yielded positive results, encounter the usual difficulties of confounding factors in chemical industries. Exposure of workers to AN should continue to be carefully monitored, but AN would not have to be considered a cancer risk to the population provided limitations on releases from consumer products and guidelines on AN in water and air are enforced. AN is teratogenic in laboratory animals (rat, hamster) at high doses when foetal/embryonic (and maternal) toxicity already is manifest. Pregnant workers should not be exposed to AN. In view of the small concentrations generally encountered outside plants, women not professionally exposed would appear not to be at risk of teratogenic effects due to AN. Future research should concentrate on the elucidation of the different degradation pathways in man and on epidemiological studies in workers including pregnant women, assessing also, if possible, individual exposure by bio-monitoring.

In vitro reactions of 2-cyanoethylene oxide with calf thymus DNA

2-cyanoethylene oxide (CEO) is a direct-acting mutagen and the postulated proximate carcinogenic form of acrylonitrile (AN). We have studied the reactions of CEO with 2'-deoxyribonucleosides and in vitro with calf thymus DNA at pH 7.0-7.5 and 37 degrees C for 3 h. Reaction of CEO with dAdo gave 2 adducts, N6-(2-hydroxy-2-carboxyethyl)-dAdo (N6-HOCE-dAdo) (2% yield) and 1,N6-etheno-dAdo (epsilon-dAdo) (11%); reaction with dCyd resulted in the isolation of 3-HOCE-dUrd (22%); reaction with dGuo gave 7-(2-oxoethyl)-Gua (7-OXE-Gua) (31%) and reaction with dThd yielded 3-OXE-dThd (3%). Structural elucidation of adducts was accomplished by ultraviolet spectroscopy, high-field proton NMR spectroscopy and mass spectrometry. Structural confirmation was provided by an accurate mass measurement technique where diagnostic ions in the electron impact mass spectra of trimethylsilyl derivatives were measured to within 0.0007 atomic mass units. The facile Dimroth rearrangement of 1-HOCE-dAdo to N6-HOCE-dAdo and hydrolytic deamination of a dCyd adduct to 3-HOCE-dUrd is postulated to be catalyzed by the hydroxyl group on the 3-carbon side chain of the adduct. Reaction of CEO with calf thymus DNA yielded (nmol/mg DNA) N6-HOCE-dAdo (2); epsilon-dAdo (11); 3-HOCE-dUrd (80); 7-OXE-Gua (110) and 3-OXE-dThd (1). Thus CEO, like its metabolic precursor AN, directly alkylates DNA in vitro but at a much more rapid rate.

Mutagenicity of acrylonitrile and its metabolite 2-cyanoethylene oxide in human lymphoblasts in vitro

The mutagenicity of the rat carcinogen acrylonitrile (ACN) and its metabolite 2-cyanoethylene oxide (CNEtO) was assessed in vitro in human lymphoblasts using the heterozygous thymidine kinase (tk) locus as a genetic marker. ACN was tested in both the presence and absence of an Aroclor-induced rat-liver homogenate S9. In the absence of S9, ACN was not mutagenic over the concentration range tested (0.4-1.5 mM X 2 h). In the presence of S9, the mutagenic response of ACN was enhanced, resulting in a significant response at a concentration of 1.4 mM X 2 h. CNEtO, the proposed ultimate mutagenic metabolite of ACN, induced a significant mutagenic response without activation at 100 microM and 150 microM X 2 h. Two phenotypic classes of spontaneous and CNEtO-induced tk-/- mutants were observed; one class of mutants (tkn) had a normal growth rate relative to wild-type while the second class (tks) grew at a slower rate. The molecular nature of these two phenotypic classes was investigated by Southern blot analysis. CNEtO-induced tkn mutant clones (11/12) and 7/9 tkn spontaneous mutants had no detectable alterations in their tk restriction fragment pattern. In contrast, 25/26 tks mutants analyzed (spontaneous and CNEtO-induced) had lost a 14.8-kb polymorphic fragment of the +tk allele.

Primary brain tumours in Fischer 344 rats chronically exposed to acrylonitrile in their drinking-water

Acrylonitrile (ACN) has been tested for carcinogenicity by various routes in a number of rat strains. At relatively high levels of administration (e.g. 500 ppm in the drinking-water) there were statistically significant increases in microscopically detectable primary brain tumours, which were difficult to classify. In a further study of ACN-induced brain tumours, ACN was administered to groups of 50 male and 50 female F-344 rats from 6 wk of age at levels of 0, 100 and 500 ppm in the drinking-water. A fourth group of 300 rats (147 males, 153 females), was also given 500 ppm ACN. Neurological signs were observed in 0, 4, 16 and 29, respectively, of the rats in these four groups within 12-18 months. Among the treated animals, females died slightly earlier than males. Few controls of either sex had died by month 18, but, apart from those killed for tumour donation, a high proportion of the rats in the 500-ppm groups had died by that time. Of the 49 brain tumours found in rats exposed to 500 ppm ACN, 11 were only detectable microscopically, 28 were 1-5 mm in diameter and 10 were greater than 5 mm. Despite this variation in size, all the tumours were similar in cellular and architectural features. They were densely cellular, with occasional areas of focal necrosis, and were infiltrative at the margins. They were negative for glial fibrillary acidic protein (GFAP). Ultrastructurally, the tumour cells showed intermingling cytoplasmic processes but no glial filaments and no neurosecretory granules or specialized cell contacts. Samples of tumour tissue were successfully grown in culture, but transplantation of samples from these cultures (observed for up to 12 wk) was unsuccessful. However, a direct intracerebral transplantation from a large tumour was successful.

Sister chromatid exchange and chromosome aberration analyses in mice after in vivo exposure to acrylonitrile, styrene, or butadiene monoxide

The use of polymers in plastic and rubber products has generated concern that monomers potentially active in biological systems may be eluted from these substances. We have evaluated two such monomers, acrylonitrile and styrene, for the induction of chromosome damage in mice. Butadiene monoxide, a presumed metabolite of a third important monomer, 1,3-butadiene, was also tested. These chemicals were administered as a single intraperitoneal injection; sister chromatid exchanges and chromosome aberrations were analyzed in bone marrow cells. Acrylonitrile and styrene were largely negative for these endpoints when tested at doses ranging to 60 mg/kg and 1,000 mg/kg, respectively. Butadiene monoxide, which previously has not been tested in a mammalian system, was determined to be a very effective inducer of sister chromatid exchanges and chromosome aberrations. Both endpoints showed a clear dose response and a greater than ten-fold increase over control levels at high doses. These studies represent an initial step in our efforts to evaluate genetic risk associated with exposure to common polymeric chemicals.

Acrylonitrile: a suspected human carcinogen

The literature on carcinogenicity of acrylonitrile (an important intermediate in the chemical industry) is reviewed. The three main conclusions are: (1) Acrylonitrile has genotoxic effects in various tests in microorganisms and in mammal cells. (2) Chronic exposure to acrylonitrile causes tumours in rats. (3) Results of epidemiological studies indicate that acrylonitrile may be a human carcinogen. From this it is clear that acrylonitrile is very probably carcinogenic to humans. Therefore the authors plead for a reduction of acrylonitrile standards to the lowest practicable limit.