Occupational and Environmental Factors Enhancing the Genotoxicity of Asbestos

Epidemiological and experimental studies have suggested the enhancement of asbestos-induced disease processes by simultaneous exposure to kerosene, its soot, and cigarette smoke in asbestos-exposed animals as well as in humans. To determine the influence of these factors on the genotoxic potential of asbestos, a micronucleus test was performed in Syrian hamster embryo fibroblasts (SHE) and human lymphocytes. To observe the specific chromosomal damages, multicolor fluorescence in situ hybridization (FISH) was done in the lymphocytes from smokers and nonsmokers exposed in vitro to asbestos. Significantly higher numbers of micronuclei were observed in SHE cells after combined treatment with chrysotile and kerosene soot (111 micronuclei/1000 cells) in comparison to chrysotile and kerosene soot separately. Kinetochore staining revealed mainly clastogenic effects in all the cases. In human lymphocytes exposed in cultures to chrysotile and crocidolite the numbers of micronuclei were found higher in smokers than nonsmokers. Multicolor FISH assay suggested that asbestos fibers inflict high damage within 1q12 and in the region between 1cen and 1q12 of chromosome 1. In the exposed population of an asbestos cement factory, the highest genetic damage was found in the blood lymphocytes of exposed smokers. The study suggests that smokers occupationally exposed to asbestos and domestically to kerosene soot are at higher risk for the early development of asbestos-induced diseases.

The inhibitory effect of neuropathic organophosphate esters on neurite outgrowth in cell cultures: A basis for screening for delayed neurotoxicity

Organophosphates have previously been tested for the induction of delayed neuropathy in adult hens. An alternative in vitro test, which avoids the severe suffering caused by the test in hens, has been developed using permanent cell lines from a rat-brain glioma (C-6) or from a mouse-brain neuroblastoma (N-18). Addition of dibutyryl cAMP to these cell cultures triggers the development of neurite-like processes; the development of these processes is inhibited by the addition of various organophosphate compounds and this inhibition serves as an indicator of neurotoxicity. 26 compounds with positive results in the in vivo test in hens, and eight analogues with negative results were tested in vitro. An almost perfect correlation between the in vivo and in vitro results was found; two compounds with weak positive results in vitro (O,O,S-trimethyl phosphorothioate and O,S,S-trimethyl phosphorothioate) yielded negative results in hens but this discrepancy may be related to their bioavailability in hens. The in vitro test is recommended to avoid the pain and stress caused by testing in vivo in hens.

Smoking enhances asbestos-induced genotoxicity, relative involvement of chromosome 1: a study using multicolor FISH with tandem labeling

Several experimental and epidermological studies have indicated augmentation of asbestos induced diseases by cigarette smoke by the mechanisms, which are still unknown. To determine whether smoking affects genetic system of the cells and further modifies asbestos induced genotoxicity, whole blood from non-smokers and smokers was exposed to asbestos fibres separately in vitro and micronucleus test was performed. The number of micronuclei was found to be significantly higher (P<0 05) in cases of smoker's lymphocytes, asbestos exposed non-smokers lymphocytes as well as asbestos exposed smokers lymphocytes, as compared with unexposed non-smokers lymphocytes. Further we investigated involvement of chromosome 1 in the damaging process using multicolor FISH technique. FISH is fast and reliable method, distinguishing both structural and numerical alterations. The centric/pericentric regions of chromosome 1 (cen-q12) were labeled, as the pericentric heterochromatin region 1 (q12) is quite large, highly repetitive and prone to breakage. Multicolor FISH assay suggested that the genetic damage by asbestos fibres mainly involve chromosome 1 but in case of cigarette smoking the damage is not strictly connected to chromosome 1 only, but also involves damage to other chromosomes. Further the study suggested that smoking makes genetic system of the cells more vulnerable to the deleterious effects of asbestos.

Mutational analysis of the PTEN/MMAC1 tumour suppressor gene in primary human malignant mesotheliomas

Eighteen primary human malignant mesotheliomas obtained from 18 patients were screened for point mutations and microdeletions/insertions in all exons of the tumour suppressor gene PTEN/MMAC1 by SSCP analysis. No mutation could be found. Our preliminary data indicate that disarrangements of PTEN/MMAC1 are at least not frequently involved in mesothelioma formation.

Mutational analysis of N-ras, p53, p16INK4a, p14ARF and CDK4 genes in primary human malignant mesotheliomas

Nineteen specimens from primary human malignant mesotheliomas obtained from 19 patients were screened for activating point mutations in the oncogenes N-ras and CDK4 by combined RFLP-PCR/SSCP analysis. In addition, all tumours were screened for deletions and point mutations in the tumour suppressor genes p53, p16INK4a (CDKN2A) and p14ARF (exon-1beta) by combined multiplex-PCR/SSCP analysis. No mutations were found in N-ras, p53 and CDK4. Three tumours displayed homozygous deletion (co-deletion of exons 1, 2 and 3) of p16INK4a. One of them displayed additional homozygous deletion of p14ARF (exon-1beta). Two silent point mutations and 2 polymorphisms were found in p16INK4a in 3 tumours. Our preliminary data indicate that disarrangement of the Rb1 pathway may be involved in mesothelioma formation.

Quantification of acute neurotoxic effects of trimethyltin using neuronal networks cultured on microelectrode arrays

We used spontaneously active monolayer networks in vitro, cultured on thin film microelectrode arrays as experimental platforms for the determination of trimethyltin chloride (TMT) toxicity. Two different tissues of the mouse CNS (spinal cord and auditory cortex) exhibited characteristic and dose-dependent changes of their electrophysiological activity patterns after treatment with TMT, a standard neurotoxicant. Spinal cord networks began to respond to TMT at 1-2 microM and shut off activity at 4-7 microM. Auditory cortex cultures started to respond at 2-3 microM and shut off activity at 7-8 microM. Repeated applications of low doses of TMT always influenced the electrical activity in a reversible manner, with no overt cytotoxic effects. The inhibitory concentrations for a 50% reduction of activity (IC ) were 1.5+/-0.5 microM (spinal cord) and 4.3+/-0.9 microM (auditory cortex) indicating a relatively low interculture variability within one tissue type. The non-overlapping IC50 range for cortical and spinal cord cultures may suggest tissue specificity for network responses to TMT. Shut-off concentrations were found to be within a factor of two of the lethal concentrations reported for mice in vivo. Action potential amplitude and shape did not change even when complete cessation of activity was approached, suggesting that acute TMT applications did not affect neuronal metabolism that would lead to a lowering of membrane potentials. Our results suggest that spontaneously active monolayer networks in vitro are suitable for toxicological investigations since network activity can be influenced in a dose-dependent manner. These properties allow the development of neurotoxicity biosensors based on physiological responses of spontaneously active networks.

Kerosene soot genotoxicity: enhanced effect upon co-exposure with chrysotile asbestos in Syrian hamster embryo fibroblasts

Epidemiological and experimental studies have suggested an enhancement of asbestos-induced bronchogenic carcinoma by cigarette smoke. Further, our recent experimental and epidemiological studies have indicated that besides smoking, several other compounds including kerosene soot may accelerate disease processes in asbestos-exposed animals as well as in the humans. Incomplete combustion of kerosene oil generates large volumes of soot, which contains various polycyclic aromatic hydrocarbons and aliphatic compounds. As reported earlier, exposure to kerosene soot is known to cause biochemical and pathological changes in the pulmonary tissue, which may cause cardiopulmonary disorders. In this study we investigated genotoxic effects caused by kerosene soot and chrysotile asbestos as well as co-exposure of kerosene soot and chrysotile using Syrian hamster embryo fibroblasts (SHE). The micronucleus assay revealed a significant increase of induced micronuclei (MN), (P</=0.05) in SHE cells after treatment with kerosene soot (0.5-1.0 microg/cm(2)) for 66 h (36 MN/1000 cells). Combined treatment with chrysotile and soot induced up to 110 MN/1000 cells (chrysotile alone: 80 MN/1000 cells; concentrations: 1 microg/cm(2), exposure times: 66 h). Kinetochore staining revealed mainly clastogenic effects in all cases (soot: 21.3% CRMN(+); chrysotile: 27%; soot+chrysotile: 27.6%; control: 20.8%). This is the first study showing that kerosene soot is not only genotoxic but it can also elevate the genotoxic potential of chrysotile asbestos. This information may be of importance for workers occupationally exposed to asbestos and domestically exposed to kerosene soot.

Glutathione redox system in oxidative lung injury

Glutathione (GSH) is a ubiquitous intracellular thiol present in all tissues, including lung. Besides maintaining cellular integrity by creating a reduced environment, GSH has multiple functions, including detoxification of xenobiotics, synthesis of proteins, nucleic acids, and leukotrienes. Present in high concentrations in bronchoalveolar lavage fluid (BALF), GSH provides protection to the lung from oxidative injury induced by different endogenous or exogenous pulmonary toxicants. Its depletion in the lung has been associated with the increased risk of lung damage and disease. The redox system of GSH consists of primary and secondary antioxidants, including glutathione peroxidase (GPx), glutathione reductase (GR), glutathione S-transferase (GST), and glucose 6-phosphate dehydrogenase (G6PD). Alterations in the activities of these enzymes may reflect reduced cellular defense and may serve as surrogate markers of many lung diseases. As GSH is also involved in the regulation of expression of protooncogenes and apoptosis (programmed cell death), the development of diseases such as cancer and human immune deficiency may be affected by depleting or elevating cellular GSH levels. Exogenous delivery of GSH or its precursor N-acetyl cysteine (NAC) is being used as chemotherapeutic approach.

Delayed cytotoxic and genotoxic effects in a human cell line following X-irradiation

BACKGROUND

In order to clarify the relationship between delayed reproductive death and radiation-induced genomic instability, the colony-forming efficiency of surviving, irradiated human squamous carcinoma cells and centromere positive as well as centromere negative micronuclei in surviving progeny were examined.

MATERIALS AND METHODS

Colony-forming ability and micronucleus (MN) frequency in binucleated cells 24 h after the addition of cytochalasin B during 2 weeks of post-irradiation growth were determined in a squamous cell carcinoma cell line (SCL-II) of human origin. In addition, centromeres in micronuclei were detected using FISH.

RESULTS

In the human epithelial cell line used for these experiments, delayed reproductive death was pronounced and persisted for at least 2 weeks after irradiation. Although there is evidence for an increased rate of centromere positive micronuclei, but not of centromere negative micronuclei, arising during the first week of post-irradiation proliferation, this decreases later while the rate of delayed reproductive death remains elevated.

CONCLUSION

In the studied cell line, the observed delayed reproductive death is not closely related to the investigated criteria of radiation-induced genomic instability. This casts doubt on the common assumption that delayed reproductive death is a direct manifestation of radiation-induced genomic instability.

Mutational analysis of the N-ras, p53, p16INK4a, CDK4, and MC1R genes in human congenital melanocytic naevi

Eighteen human congenital melanocytic naevi (CMN) from 17 patients were screened for activating point mutations in the oncogenes N-ras and CDK4 and for sequence variants in the MC1R gene by combined RFLP-PCR/SSCP analysis. In addition, all lesions were screened for deletions and point mutations in the tumour suppressor genes p53 and p16INK4a (CDKN2A) by combined multiplex PCR/SSCP analysis. Positive screening data were specified by sequencing of the corresponding PCR product. Activating point mutations in the N-ras gene (nine CAA (Gln) to AAA (Lys) transversions and one CAA (Gln) to CGA (Arg) transition at codon 61) were detected at high frequency (56%). Furthermore, three missense mutations (V92M) and two silent mutations (CGA (Arg) to CGG (Arg), codon 213, exon 6) were found in the MC1R and p53 genes, respectively. No mutations were found in p16 or CDK4. The activated N-ras oncogene, which is also found in human cutaneous melanomas, may constitute a potential risk factor for melanoma formation within CMN.

Induction of genotoxic effects and modulation of the intracellular calcium level in syrian hamster embryo (SHE) fibroblasts caused by ochratoxin A

The mycotoxin ochratoxin A (OTA) is a naturally occuring contaminant of food. The genotoxic status of OTA is still controversial because contradictory results were obtained in various microbial and mammalian gene mutation assays. In this study, OTA was investigated to examine its potency to induce micronuclei (MN) in SHE cells. The SHE-micronucleus assay revealed that OTA induces MN in a dose- and time-dependent manner. The results of kinetochore analysis revealed that mainly clastogenic events are involved in OTA genotoxicity. Induction of mitotic disturbances can be closely related to changes of the intracellular calcium concentration ([Ca2+]i). The investigated time course of OTA-induced [Ca2+]i changes revealed that the obtained signal is a short spike signal resembling physiological responses. In the absence of extracellular calcium, a long-lasting signal indicates possible damage to intracellular calcium stores or channels. Our data show that the OTA-induced [Ca2+]i rise is caused by Ca2+ -release from intracellular stores as well as Ca2+ influx from extracellular area. Finally, the influence of the changed intracellular calcium level on the actin cytoskeleton was investigated. Visualization of the actin filaments revealed time- and concentration-dependent effects. Cell shrinkage and depolymerized filaments were observed. We conclude that OTA disrupts actin filaments by a direct irreversible binding to actin.

Modulation of the intracellular calcium level in mammalian cells caused by 17beta-estradiol, different phytoestrogens and the anti-estrogen ICI 182780

In previous investigations it was shown that the synthetic estrogen diethylstilbestrol (DES) induces a rise of the intracellular calcium level ([Ca2+]i) in C6 rat glioma cells [P. Tas, H. Stopper, K. Koschel, D. Schiffmann, Influence of the carcinogenic oestrogen diethylstilboestrol on the intracellular calcium level in C6 rat glioma cells. Toxic. In vitro 5 (1991) 463-465] which is accompanied by changes of the arrangement of the cytoskeleton. In the present study, we compared the induction of these effects in COS (monkey kidney cells) lacking estrogen receptors (ER) with those in RUCA-I (rat endometrial carcinoma) cells containing ER. The [Ca2+]i in RUCA-I and COS cells following 17beta-estradiol (ES), genistein (GEN), daidzein (DZ) and coumestrol (CES) treatment was analyzed. A significant increase of [Ca2+]i induced by all compounds was observed in RUCA-I cells. No effects were detected in COS cells after ES and GEN treatment. The anti-estrogen ICI 182780 completely blocked the ES-and GEN-induced rise of [Ca2+]i. Dose and time dependencies of changes of calcium levels were analyzed and a biphasic response could be observed. The actin staining showed disintegrated stress fibers in RUCA-I cells. The degree of the observed effects correlates with the known estrogenicity of the applied compounds (DES > ES > GEN). It remains to be elucidated whether or not the effects observed are mediated by the "classic" genomic estrogen receptor pathway or by alternate nongenomic or receptor-independent pathways.

Analysis of chromosomal alterations induced by asbestos and ceramic fibers

Asbestos and other mineral fibers have long been known as carcinogenic agents. However, the primary mechanisms of fiber-induced carcinogenesis still remain unclear. We have investigated mitotic disturbances caused by amosite, crocidolite, and chrysotile in Syrian hamster embryo (SHE) fibroblasts. We also analyzed micronucleus formation as a result of mitotic disturbances, and carried out a characterization of the induced micronucleus population by kinetochore staining. In addition, the spindle fiber morphology was examined. Supravital UV-microscopy was used to analyze changes in chromatin structure, impaired chromatid separation and blocked cytokinesis. All three fiber types induced micronuclei in SHE cells with a high frequency (up to 200 MN/2000 cells; dose range: 0.1-5.0 microg/cm2) in a dose-dependent manner with a maximum between 48 and 66 h. Kinetochore staining revealed that 48% of fiber-induced micronuclei reacted positively. Furthermore, spindle deformation was observed in cells with disturbed meta- and anaphases while the spindle fiber morphology appeared unchanged. Our results show that asbestos fibers may cause both loss as well as breakage of chromosomes in the absence of direct interaction with spindle fibers. In addition, we analyzed the induction of micronuclei, hyperdiploidy and chromosome breakage in human amniotic fluid cells (AFC) in vitro by amosite, chrysotile and crocidolite asbestos and ceramic fibers. The response of human (AFC) and rodent (SHE) cells to fiber treatment was compared using the micronucleus assay. AFC were much less susceptible than SHE cells to the induction of micronuclei by mineral fibers. The application of fluorescence in situ hybridization (FISH) with tandem DNA probes yielded more detailed informations about specific structural chromosome aberrations in the 1(cen-q12) and 9(cen-q12) regions and about abnormal numbers of chromosomes in interphase AFC. Using this FISH approach we found a statistically significant increase of chromosomal breakage in the pericentric heterochromatin regions of chromosomes 1 and 9 in AFC after exposure to asbestos and ceramic fibers. The number of hyperdiploid cells was also significantly increased. These results show that asbestos as well as ceramic fibers are inducers of structural and numerical chromosomal alterations.

Detection of hyperdiploidy and chromosome breakage affecting the 1 (1cen-q12) region in lentigo malignant melanoma (LMM), superficial spreading melanoma (SSM) and congenital nevus (CN) cells in vitro by the multicolor FISH technique

The centric/pericentric region of chromosome 1 (cen-q 2) of human melanoma cells of different stages of carcinogenicity (superficial spreading melanoma (SSM), lentigo malignant melanoma (LMM)) and premalignant precursor lesions (congenital nevus (CN)) were investigated by fluorescence in situ hybridization (FISH) with tandem DNA probes. The pericentric heterochromatin region 1(q12) is large and highly prone to breakage in contrast to the adjacent centromeric region which is much smaller and less prone to such events. All samples of melanoma cells were obtained from patients and cultivated in vitro. LMM cells showed the highest number of breakage events within the 1q12 region (90% of cells). The number of hyperdiploid cells was not increased in comparison to CN cells. In contrast to LMM cells, SSM cells showed a significant increased number of hyperdiploid cells which were mainly tetrasomic for chromosome 1 (P < or = 0.05). The number of chromosome breaks was not significantly increased in this type of melanoma cells. The spontaneous rates of chromosomal breakage and hyperdiploidy is relatively low in CN cells (1.5-2.5% and 3.2-5.8%, respectively) but these frequencies also differ between CN samples from different patients. These results show that the multicolor FISH technique represents a fast and reliable detection method, distinguishing structural and numerical chromosomal alterations in interphase nuclei. This technique is useful as a histological marker to differentiate between specific tumor subtypes and to investigate the relationship between genomic instability and clinopathological parameters (tumor grading and staging).

Induction of micronuclei, hyperdiploidy and chromosomal breakage affecting the centric/pericentric regions of chromosomes 1 and 9 in human amniotic fluid cells after treatment with asbestos and ceramic fibers

This article describes the induction of micronuclei, hyperdiploidy and chromosome breakage in human amniotic cells in vitro by amosite, chrysotile and crocidolite asbestos, and ceramic fibers. The response of human (amniotic fluid cells) and rodent (Syrian hamster embryo fibroblasts, SHE) cells to fiber treatment was compared using the micronucleus assay. The data of the rodent studies were taken from a previous investigation (Dopp, E. et al. (1995) Environ. Health Perspect., 103, 268-271). All types of mineral fibers caused a significant increase of micronucleated cells. The kinetochore analysis revealed that all three types of asbestos and ceramic fibers yielded similar effects. Approximately 50% of the induced micronuclei were kinetochore-negative indicating formation through clastogenic events. Human amniotic cells were much less susceptible than SHE cells to the induction of micronuclei by mineral fibers. This again demonstrates that SHE cells are more susceptible to chromosomal changes than human amniotic fluid cells. The application of fluorescence in situ hybridization (FISH) with tandem DNA probes yielded more detailed information about specific structural chromosome aberrations in the 1 (cen-q12) and 9 (cen-q12) regions and about abnormal numbers of chromosomes in interphase human amniotic fluid cells. Using this FISH approach we found a statistically significant increase of chromosomal breakage in the pericentric heterochromatin regions of chromosomes 1 and 9 in interphase human amniotic cells after exposure to asbestos and ceramic fibers compared to control cells. The number of hyperdiploid cells was also significantly increased. Our results show that asbestos fibers as well as ceramic fibers are inducers of structural and numerical chromosomal aberrations in human amniotic fluid cells.

Lack of p53 mutations and loss of heterozygosity in non-cultured human melanocytic lesions

In this study we analysed snap-frozen surgical resections of 16 superficial spreading melanomas, 13 nodular malignant melanomas, 2 lentigo maligna melanomas, 1 dysplastic nevus, 1 congenital nevus and 5 normal nevi from 38 patients for point mutations in the human p53 gene at exons 5-8 by polymerase chain reaction/single-strand conformation polymorphism as well as for loss of heterozygosity of p53 by restriction-fragment-length polymorphism/polymerase chain reaction in order to determine whether p53 aberrations are associated with melanoma subtypes. In addition, we analysed six melanoma cell lines for point mutations in p53. Our results revealed the absence of point mutations and loss of heterozygosity in all fresh resected lesions. However, a TAC (Tyr) to TGC (Cys) transition at codon 163 in exon 5 was found in one cell line.

Nongenotoxic carcinogens: development of detection methods based on mechanisms: a European project

While the accumulation of genetic changes in a somatic cell is considered essential for the genesis of a cancer, it has become clear that not all carcinogens are genotoxic, suggesting that some carcinogens indirectly participate in the generation of genetic changes during carcinogenesis. A European project funded by the European Community was thus conceived to study mechanisms of nongenotoxic aspects of carcinogenesis. Two main strategical approaches were adapted: (i) to study whether and how Syrian hamster embryo (SHE), Syrian hamster dermal (SHD) and BALB/c 3T3 cell transformation systems simulate in vivo carcinogenesis, and to examine whether they can detect nongenotoxic carcinogens; (ii) to study, refine and validate mechanisms-based end-points for detection of nongenotoxic carcinogens. For mechanisms-based research, the proposed end-points included gap junctional intercellular communication (GJIC) inhibition, altered expression of critical genes, immortalization and aberrant cell proliferation. We also selected model compounds commonly usable for various endpoints. Our major results can be summarized as follows: (1) SHE and BALB/c 3T3 transformation systems reflect both genotoxic and nongenotoxic carcinogenic events; they detect not only genotoxic but also many although not all, nongenotoxic carcinogens. This is further supported by the fact that both genotoxic and nongenotoxic carcinogens were able to immortalize SHD cells. (2) Many nongenotoxic carcinogens, although not all, inhibit GJIC in vitro as well as in vivo. Mechanistic studies suggest an important role of blocked GJIC in carcinogenesis and that different mechanisms are involved in inhibition of the communication by different agents used. However, inhibition of GJIC is not a prerequisite for the enhancement (or induction) of transformation of SHE or BALB/c 3T3 cells. (3) Among compounds examined, there was a good correlation between induction of micronuclei and cell transformation in SHE cells while no such correlation was found between the induction of cell transformation and ornithine decarboxylase activity. (4) Two transgenic mouse mutation assays (lacI and lacZ) were established and validated. The genotoxin dimethylnitrosamine was shown to be mutagenic to the liver in both assays. Ortho-anisidine, a bladder-specific carcinogen that was inactive in standard rodent genetic toxicity assays was uniquely mutagenic to the bladder of the transgenic mice. The peroxisome proliferator methyl clofenipate was established as nonmutagenic to the liver of both transgenic mice. That eliminated DNA damage as a cause of the liver tumours produced by this chemical and weakened the idea that induced cell division leads to mutation induction. (5) With an in vitro DNA replication model, it was found that DNA damage induced by genotoxic agents can be responsible for inhibition of DNA replication, while certain nongenotoxic agents such as phorbol esters increase DNA replication. (6) An attempt to use structure-activity relationship for subfamilies of nongenotoxic carcinogens, e.g., receptor-mediated carcinogens, has been initiated with some promising results. Our results support the idea that there are multiple nongenotoxic mechanisms in carcinogenesis, and that working hypothesis-oriented approaches are encouraged rather than simple screening of chemicals in developing test systems for the detection of nongenotoxic carcinogens.

Mitotic disturbances and micronucleus induction in Syrian hamster embryo fibroblast cells caused by asbestos fibers

Asbestos and other mineral fibers have long been known to induce lung cancer and mesothelioma. However, the primary mechanisms of fiber-induced carcinogenesis still remain unclear. We investigated the occurrence of mitotic disturbances induced by asbestos (amosite, crocidolite, chrysotile) in an in vitro approach using Syrian hamster embryo (SHE) fibroblast cells. The following endpoints were investigated: micronucleus formation as a result of mitotic disturbances and characterization of the induced micronucleus population by kinetochore staining and visualization of the spindle apparatus. Supravital UV-microscopy was used to analyze changes in interphase chromatin structure, impaired chromatid separation, and blocked cytokinesis. All three asbestos fiber types induced a high frequency of micronucleus formation in SHE cells (> 200/2000 cells) in a dose-dependent manner (0.1-5.0 micrograms/cm2), with a maximum between 48 hr and 66 hr exposure time. At higher concentrations (more than 5.0 micrograms/cm2) the micronucleus formation decreased again as a result of increased toxicity. Kinetochore staining of micronuclei revealed that 48 +/- 2% of asbestos-induced micronuclei reacted positively with CREST (antikinetochore) serum. Furthermore, spindle apparatus deformations occurred in cells with disturbed metaphases and anaphases, while the spindle fiber morphology appeared unchanged. Our results show that asbestos fibers may cause both loss and breakage of chromosomes in the absence of direct interaction with spindle fibers.

Mineral fibers induce apoptosis in Syrian hamster embryo fibroblasts

It is known that asbestos and other mineral fibers induce lung cancer and mesothelioma. However, the primary mechanisms of fiber-induced carcinogenesis still remain to be elucidated. Previous studies, including our own, have shown that asbestos causes specific mitotic disturbances, micronucleus formation and typical changes in chromatin structure resembling those of apoptosis. This effect has been considered as programmed cell death removing damaged or pre-cancerous cells. We investigated the induction of apoptosis by asbestos (amosite, crocidolite, chrysotile) and ceramic fibers. The typical ladder pattern of DNA fragments was identified by means of gel electrophoresis, the intracellular calcium concentration was measured and flow cytometry analyses were carried out to determine the percentage of apoptotic cells. The different fibers showed different potencies for the induction of apoptosis in Syrian hamster embryo (SHE) cells. Depending on the type of fiber applied 3-33% of cells underwent apoptosis. Chrysotile proved to be the most potent inducer of apoptosis compared to the other fibers. In addition, an increase intracellular calcium level was observed in apoptotic SHE cells. Chrysotile induced apoptosis after a considerably longer exposure time (66-72 h) than cisplatin (24 h). In view of these findings we hypothesize that chrysotile induces apoptosis resulting from long-term changes in intracellular regulation pathways.

Analysis of ras mutations in human melanocytic lesions: activation of the ras gene seems to be associated with the nodular type of human malignant melanoma

We have analyzed the Ha-ras, Ki-ras and N-ras gene for point mutations at codons 12, 13 and 61 via restriction fragment length polymorphism/polymerase chain reaction analysis and subsequent direct sequencing in non-cultured fresh-frozen tissues of 16 superficial spreading melanomas (SSM), 13 nodular malignant melanomas (NMM), 2 lentigo malignant melanomas (LMM), 1 dysplastic nevus, 1 congenital nevus and 5 normal nevi from 38 patients. Mutations were found in 4 melanoma samples, all belonging to the nodular malignant type. Three of them were mutated in N-ras and one in the Ha-ras gene. Mutation in N-ras was also detected in the congenital nevus. All mutations were exclusively located at the first two base pairs of codon 61. No Ki-ras mutation was detected in any lesion. No mutation could be found in SSM and LMM in addition to dysplastic and normal nevi. The frequency of ras mutation in NMM was 31%, whereas in SSM it was 0%. Our study suggests (a) an association between ras mutations (mainly N-ras) and the NMM as a subgroup of human melanoma; (b) that activation of Ki-ras is not involved in the pathogenesis of melanoma. The role of UV radiation in point mutations of ras genes in human melanoma is discussed.

Is micronucleus induction by aneugens an early event leading to mutagenesis?

This study was designed to investigate a previously unidentified potential mechanism for mutation induction as well as to clarify a biological consequence of micronuclei with mutation induction as measured by trifluorothymidine (TFT) resistance in mouse L5178Y cells using four aneugens: colcemid, diethylstilbestrol, griseofulvin and vinblastine. All four compounds induced micronuclei which appeared in the first cell cycle after treatment. More than 85% of the micronuclei induced by each compound stained positive for the presence of kinetochores implying that the micronuclei contained whole chromosomes. However, these same compounds were unable to induce TFT resistance under three different treatment regimes. We concluded that these compounds, under conditions where they induce primarily kinetochore positive micronuclei, were not able to induce mutations. Thus, the induction of micronuclei containing whole chromosomes harboring a selectable gene is not an early event leading to mutations in these cells.

Effect of indanyl analogues of diethylstilboestrol on morphological transformation of Syrian hamster embryo fibroblasts and micronuclei in vitro

Two analogues of the carcinogenic oestrogen diethylstilboestrol (DES), indenoestrol A (IA) and indenoestrol B (IB), have been studied with respect to their genotoxic and cell transforming properties in mammalian cells. The conformation and oestrogenicity of IA and IB are very similar, but they differ with respect to their ease of peroxidation and the resulting reactive intermediates: only IA is readily converted to a p-quinone. Both DES derivatives caused morphological transformation of Syrian hamster embryo (SHE) fibroblasts with similar efficiency at concentrations (1 to 10 mum) that did not affect cloning efficiency. In addition, IA and IB (5 to 50 mum) induced micronuclei in the same cell system. These micronuclei were detectable as early as 1-3 hr after a 5-hr treatment with IA or IB. Such a time course is characteristic of compounds that cause mitotic disturbances. Indomethacin, an inhibitor of prostaglandin H synthase (the enzyme responsible for oxidation of DES in target cells), did not affect the frequency of micronuclei induced by IA or by IB. From these data we conclude that peroxidative metabolism resulting in quinone formation is not a prerequisite for the genotoxicity of these compounds. In addition to DES and several of its analogues the indanyl derivatives now also have been shown to be active in both of these short-term assays, suggesting that the in vitro micronucleus formation and morphological cell transformation are causally related events.

Immune response impairment, genotoxicity and morphological transformation induced by Taenia solium metacestode

In chronic helminthic infections such as cysticercosis, where the parasites live for years, profound modulation of the host immune response has been reported. To evaluate the genotoxicity of a drug used to treat cysticercosis, we observed the occurrence of genetic damage in cultured lymphocytes from cysticercotic swine and patients who had not been exposed to the drug. The human lymphocytes also showed a slower proliferation. These data suggested that the disease itself was promoting genetic damage in host lymphocytes which, in part, could explain the retardation of the lymphocyte proliferation observed in cysticercotic patients. Pigs infected with Taenia solium cysticerci showed an increased lymphocyte proliferation for 6-8 weeks post infection, followed by an impaired proliferation after this period. Significant induction of sister-chromatid exchanges was also observed in lymphocytes from infected pigs after the 6th week post infection. Additionally, it was found that a factor secreted by the cysticerci morphologically transformed primary fibroblasts in culture. The results strongly suggest that the parasite produces genetic instability in the host cells, which could result in immunosuppression and malignant transformation of target cells.

Evaluation of the carcinogenic and genotoxic potential of praziquantel in the Syrian hamster embryo cell transformation assay

Praziquantel, a drug used for the treatment of neurocysticercosis, was tested for its ability to induce morphological transformation of Syrian hamster embryo fibroblasts. Results indicate that praziquantel transforms these cells without affecting their viability. Further experiments were carried out to investigate its possible mechanism of action in the same cell system. Micronucleus formation was observed in cultures treated with concentrations which induced morphological transformation, about 40% of these micronuclei were positive to a kinetochore antibody. No induction of DNA repair synthesis was observed even at cytotoxic concentrations. These results suggest that praziquantel has an aneugenic effect which could be responsible for its ability to transform morphologically these cells. Risk-benefit analysis should be carried out whenever this drug is utilized.

Cell cycle disturbance in relation to micronucleus formation induced by the carcinogenic estrogen diethylstilbestrol

In addition to its tumor-promoting activity in hormone-receptive tissue, the carcinogenic estrogen diethylstilbestrol (DES) has been found to induce cell transformation, aneuploidy and micronucleus formation in mammalian cells. The majority of these micronuclei contained whole chromosomes and were formed during mitosis. Here a possible relationship between a disturbance in cell cycle progression and micronucleus formation is investigated by exposing Syrian hamster embryo (SHE) cells to DES. Continuous bromodeoxyuridine labeling followed by bivariate Hoechst 33258/ethidium bromide flow cytometry was employed for analysis of cell cycle transit and related to the time course of micronucleus formation. Treatment of SHE cells with DES resulted in delayed and impaired cell activation (exit from the G0/G1 phase), impaired S-phase transit and, mainly, G2-phase traverse. Cells forming micronuclei, on the other hand, were predominantly in G2 phase during DES treatment. These results suggest that impairment of S and G2 transit may involve a process ultimately leading to micronucleus formation.

The insecticide buprofezin induces morphological transformation and kinetochore-positive micronuclei in cultured Syrian hamster embryo cells in the absence of detectable DNA damage

The insecticide buprofezin was examined for its genotoxicity in cultured Syrian hamster embryo cells in order to better understand the mechanisms underlying the genotoxicity of the compound in mammalian cells. Exposure to buprofezin concentrations of 12.5-100 microM did not significantly affect the colony-forming ability of the cells, but did result in increased frequencies of morphologically transformed colonies. Treatment with buprofezin did not cause a detectable induction of DNA repair synthesis, an indicator of DNA damage, but significantly increased the frequency of micronuclei. Immunostaining of the cells with antikinetochore antibody (CREST antibody) showed that essentially all of the buprofezin-induced micronuclei were kinetochore-positive. The results suggest that morphological transformation of Syrian hamster embryo cells by buprofezin results from an interaction of the compound or a metabolite of it with the mitotic apparatus rather than from DNA damage.

Testing of known carcinogens and noncarcinogens in the Syrian hamster embryo (SHE) micronucleus test in vitro; correlations with in vivo micronucleus formation and cell transformation

Seventy-five chemicals, carcinogens and noncarcinogens, were tested in the SHE (Syrian hamster embryo) micronucleus test in vitro. Substances inducing a reproducible and dose dependent increase in micronucleus frequency were regarded as positive. The acquired data were analyzed for correlations with results obtained from the in vivo mouse bone marrow micronucleus test and from morphological transformation of SHE cells. Out of 48 carcinogens tested 41 (85%) yielded a positive result and out of 17 noncarcinogens all proved negative. For 7 chemicals no carcinogenicity data were available so far; these compounds yielded no response in the mouse bone marrow and in the SHE micronucleus assay. For 3 chemicals only inadequate carcinogenicity data were available. A high degree of concordance with data from the in vivo micronucleus test was found (89%) and the accordance with results from morphological SHE cell transformation was even higher (95%). These findings provide new evidence that the in vitro SHE micronucleus test does in fact represent a short-term test of high predictive value.

An investigation of micronucleus and mutation induction by oxazepam in mammalian cells

The benzodiazepines are a class of drugs that are widely used in the treatment of various psychiatric disorders. One member of this class, oxazepam, is also a common metabolite of several other benzodiazepines. Since the evidence for the genetic toxicity and carcinogenic properties of these compounds is inconsistent, we investigated the oxazepam-induced formation of micronuclei in Syrian Hamster embryo fibroblast (SHE) cells, human amniotic fluid fibroblast-like (AFFL) cells and L5178Y mouse cells. A dose-dependent increase in micronucleus fractions was found in all three cell lines. The time course of micronucleus induction in L5178Y cells showed a maximum at 5 h after treatment, suggesting that the micronuclei were formed in the first mitosis after treatment. Kinetochore staining (CREST-antiserum) revealed the presence of kinetochores in approximately 50% of the micronuclei in all three cell types. This result was further confirmed by in situ hybridization in L5178Y cells and indicates the presence of whole chromosomes or centric fragments as well as acentric fragments in the oxazepam-induced micronuclei. The L5178Y cells did not show a mutagenic response to oxazepam at any of the doses or expression times used.

Cell-cycle dependent micronucleus formation and mitotic disturbances induced by 5-azacytidine in mammalian cells

5-Azacytidine was originally developed to treat human myelogenous leukemia. However, interest in this compound has expanded because of reports of its ability to affect cell differentiation and to alter eukaryotic gene expression. In an ongoing attempt to understand the biochemical effects of this compound, we examined the effects of 5-azacytidine on mitosis and on micronucleus formation in mammalian cells. In L5178Y mouse cells, 5-azacytidine induced micronuclei at concentrations at which we and others have already reported its mutagenicity at the tk locus. Using CREST staining and C-banding studies, we showed that the induced micronuclei contained mostly chromosomal fragments although some may have contained whole chromosomes. By incorporating BrdU into the DNA of SHE cells, we determined that micronuclei were induced only when the compound was added while the cells were in S phase. Microscopically visible effects due to 5-azacytidine treatment were not observed until anaphase of the mitosis following treatment or thereafter. 5-Azacytidine did not induce micronuclei via interference with formation of the metaphase chromosome arrangement in mitosis, a common mechanism leading to aneuploidy. Supravital UV microscopy revealed that chromatid bridges were observed in anaphase and, in some cases, were sustained into interphase. In the first mitosis after 5-azacytidine treatment we observed that many cells were unable to perform anaphase separation. All of these observations indicate that 5-azacytidine is predominantly a clastogen through its incorporation into DNA.

Cytogenetic changes in primary, immortalized and malignant mammalian cells

Some chromosomes in transformed rat cells and somatic cell hybrids fail to display the presence of kinetochore proteins as detected by antikinetochore antibodies. Such chromosomes (K- chromosomes) may constitute a novel mechanism for the genesis of aneuploidy. We have analyzed primary, immortalized and malignant mammalian cells for the presence of kinetochore proteins and micronuclei. Our results suggest a correlation of the K- chromosome and micronucleus frequency with the variability in chromosome number. Upon in situ hybridization with the minor satellite and alpha satellite sequences some K- chromosomes showed a signal. This indicates that the observed lack of kinetochores is not necessarily due to a lack of centromeric DNA. We conclude that dislocated K- chromosomes may become incorporated into micronuclei which are prone to loss. Such events would be associated with the generation of aneuploidy.

Genotoxicity studies of benzofuran dioxetanes and epoxides with isolated DNA, bacteria and mammalian cells

1,2-Dioxetanes, very reactive and high energy molecules, are involved as labile intermediates in dioxygenase-activated aerobic metabolism and in physiological processes. Various toxicological tests reveal that dioxetanes are indeed genotoxic. In supercoiled DNA of bacteriophage PM2 they induce endonuclease-sensitive sites, most of them are FPG protein-sensitive base modifications (8-hydroxyguanine, formamidopyrimidines). Pyrimidine dimers and sites of base loss (AP sites) which were probed by UV endonuclease and exonuclease III are minor lesions in this system. While the alkyl-substituted dioxetanes do not show any significant mutagenic activity in different Salmonella typhimurium strains, heteroarene dioxetranes such any significant mutagenic activity in different Salmonella typhimurium strains, heteroarene dioxetanes such as benzofuran and furocoumarin dioxetanes are strongly mutagenic in S. typhimurium strain TA100. DNA adducts formed with an intermediary alkylating agent appear to be responsible for the mutagenic activity of benzofuran dioxetane. We assume that the benzofuran epoxides, generated in situ from benzofuran dioxetanes by deoxygenation are the ultimate mutagens of the latter, since benzofuran epoxides are highly mutagenic in the S. typhimurium strain TA100 and they form DNA adducts, as detected by the 32P-postlabelling technique. Our results imply that the type of DNA damage promoted by dioxetanes is dependent on the structural feature of dioxetanes. Furthermore, the direct photochemical DNA damage by energy transfer, i.e., pyrimidine dimers, plays a minor role in the genotoxicity of dioxetanes. Instead, photooxidation dominates in isolated DNA, while radical damage and alkylation prevail in the cellular system.

5-azacytidine induces micronuclei in and morphological transformation of Syrian hamster embryo fibroblasts in the absence of unscheduled DNA synthesis

It is known that 5-azacytidine (5-AC) induces tumors in several organs of rats and mice. The mechanisms of these effects are still poorly understood although it is known that 5-AC can be incorporated into DNA. Furthermore, it can inhibit DNA methylation. The known data on its clastogenic and/or gene mutation-inducing potential are still controversial. Therefore, we have investigated the kinds of genotoxic effects caused by 5-AC in Syrian hamster embryo (SHE) fibroblasts. Three different endpoints (micronucleus formation, unscheduled DNA synthesis (UDS) and cell transformation) were assayed under similar conditions of metabolism and dose at target in this cell system. 5-AC induces morphological transformation of SHE cells, but not UDS. Therefore, 5-AC does not seem to cause repairable DNA lesions. Furthermore, our studies revealed that 5-AC is a potent inducer of micronuclei in the SHE system. Immunocytochemical analysis revealed that a certain percentage of these contain kinetochores indicating that 5-AC may induce both clastogenic events and numerical chromosome changes.

Genotoxicity and cell transformation studies with sorbates in Syrian hamster embryo fibroblasts

Sorbic acid, sodium sorbate and potassium sorbate were tested for their genotoxic potential in the Syrian hamster embryo (SHE) fibroblast micronucleus assay and the SHE cell transformation test in vitro. Sorbic acid and potassium sorbate showed no activity in either test system. When freshly prepared sodium sorbate solutions were used, no genotoxic or cell-transforming activity was detected. However, sodium sorbate as stored solution, which previously had been heated and sonicated to facilitate solubilization, yielded a positive response in both test systems. It is concluded that oxidation products of sodium sorbate that possess genotoxic and cell-transforming properties are formed under conditions of heating, sonication and storage.

Characterization of the Syrian hamster c-Ha-ras gene and intron-D-exon transcript

The coding sequences as well as 5'- and 3'-flanking sequences of the Syrian hamster c-Ha-ras gene were deduced from cDNA clones derived from embryo fibroblast cell lines. Sequences of introns B, C, and D were obtained from genomic DNA after amplification by the polymerase chain reaction. Sequence comparisons with rat, mouse, and human c-Ha-ras genes revealed a high degree of homology. One of 12 cDNA clones contained intron-D-exon (IDX) sequences due to alternative splicing that would encode a p19 Ha-ras gene product. Conservation between species suggests a functional role for the IDX, possibly as a negative control of p21 Ha-ras expression.

Kinetochore proteins, peripheral location of chromosomes and nuclear budding: another look at the genesis of aneuploidy

Some chromosomes in the rat do not have detectable levels of kinetochore proteins as determined by antikinetochore antibody, which may constitute a mechanism for the genesis of aneuploidy. An analysis of three mouse cell lines for the presence of kinetochore proteins showed that some chromosomes lacked these proteins, i.e. are akinetochoric by this criterion. This phenomenon may contribute to the variability of chromosome number that is characteristic of such lines. In some cells there appears to be en masse detachment of kinetochores. Several kinetochore-bearing chromosomes were also observed to be located peripherally to the spindle. These might be associated with the genesis of aneuploidy. In one cell line an apparently new phenomenon of nuclear budding was observed. In this case, one to several chromosomes appear to be pushed out of the nucleus in bud-like structures. These were surrounded by a nuclear membrane and appeared to detach from the main nucleus. Perhaps these structures eventually break off as micronuclei and, hence, would also be associated with the genesis of aneuploidy.

Genotoxic and cell-transforming properties of (trans,trans)-muconaldehyde

(trans,trans)-Muconaldehyde, a putative metabolite of benzene, should be expected to have mutagenic properties by virtue of its twin alpha,beta-unsaturated carbonylic function. It displayed definitely mutagenic properties in S. typhimurium TA100 without metabolic activation and with a 5-fold concentration of tester organisms in the preincubation assay and induced SOS response in E. coli. It induced micronucleus formation and morphological transformation in a dose-dependent manner in Syrian hamster embryofibroblasts. No DNA single-strand breaks or interstrand cross-links could be detected using the alkaline elution technique; however, strand-break generation by subsequent gamma-irradiation was found to be increased.

Dislocation of chromatin elements in prophase induced by diethylstilbestrol: a novel mechanism by which micronuclei can arise

The in vitro micronucleus test with Syrian hamster embryo (SHE) cells assays the induction of micronuclei by chemical agents. Both chromosome fragments and lagging chromosomes can give rise to micronuclei. Nevertheless, only limited information is available on the ultrastructure of micronuclei and the mechanisms of their formation. Diethylstilbestrol (DES), a non-mutagenic carcinogen, as well as its analogue 3.3'-DES induce micronuclei in SHE cells. A comparison of the dose response of DES-induced micronucleus formation with the previously published ones for aneuploidy and transformation shows that all 3 run in parallel. Thus, a functional relationship between these endpoints, in the SHE system, may be implied. The present study is designed to address the formation of micronuclei using supravital UV microscopy, to test for the presence of defined chromosome domains within micronuclei using immunocytochemistry, and to define aspects of their ultrastructure by electron microscopy. Supravital UV microscopy showed that 3.3'-DES induces displacement of chromosomes/chromatids during prophase/anaphase and formation of micronuclei during cytokinesis. Immunocytochemistry revealed that micronuclei contain, at high frequencies, CREST antibody-reactive kinetochores, indicating the presence of whole chromosomes or centric fragments in these structures. Moreover, transmission electron microscopy showed that micronuclei exhibit ultrastructural details typical of interphase nuclei. Specifically, micronuclei exhibited morphological evidence of a nuclear lamina and segregation of karyoplasm into euchromatic and heterochromatic regions. All micronuclei examined were enclosed by a nuclear envelope of normal morphology and showed nuclear pore complexes. Together the findings provide evidence that DES interferes with the mitotic apparatus as early as prophase, resulting in the formation of micronuclei and, as a consequence, in the loss of chromatids or chromosomes.

Structural requirements for the in vitro transformation of Syrian hamster embryo cells by stilbene estrogens and triphenylethylene-type antiestrogens

The mechanisms of estrogen-induced cancer are still a matter of debate. Previous studies with stilbene estrogens and steroidal estrogens have shown that the in vitro transformation of primary Syrian hamster embryo (SHE) fibroblasts is a good experimental system for discriminating hormonal from nonhormonal events. We have now extended these studies to the triphenylethylene-type antiestrogens tamoxifen (TAM), 3-hydroxy-TAM, 4-hydroxy-TAM and 3,4-dihydroxy-TAM. Furthermore, a structural isomer of diethylstilbestrol (DES) with the hydroxy groups shifted into the meta-positions (3,3'-DES) was included. Our data clearly show that TAM and 4-hydroxy-TAM give rise to morphologic and neoplastic transformation of SHE cells in culture. In contrast, neither 3-hydroxy-TAM nor 3,3'-DES led to a significant transformation, in spite of the fact that both compounds are hormonally active. These results support the notion that nonhormonal events are essential for SHE cell transformation and suggest certain structural features to be necessary for the transforming capability. The putative carcinogenicity of TAM and 4-hydroxy-TAM but not of 3-hydroxy-TAM, as implied by these in vitro transformation studies, is corroborated by recent reports on ovarian and Leydig cell tumors in mice and hepatocellular carcinomas in rats.

Non-genotoxicity of acrylic acid and n-butyl acrylate in a mammalian cell system (SHE cells)

Acrylic acid (AA), ethyl acrylate (EA) and n-butyl acrylate (BA) are widely used in the production of plastics, coatings and acrylic fibres. Occupational exposure occurs primarily via inhalation and/or skin contact. In chronic inhalation experiments EA and BA did not induce neoplastic changes in rats and mice (Klimisch and Reininghaus 1984; Miller et al. 1985). Additional investigations showed that AA and BA were not carcinogenic in mice after chronic dermal application (De Pass et al. 1984). However, recently other authors reported a weak carcinogenic potential of AA and BA after chronic dermal administration to mice (Cote et al. 1986). The conditions of the latter study lead to the suggestion that the observed tumours had developed secondarily due to the local irritating and corrosive properties of AA and BA. This view is supported by the negative results of AA, EA and BA in the conventional Ames test (Waegemaekers and Bensink 1984). Mutagenicity data in mammalian cell systems of EA were equivocal (Henschler 1986) and were lacking for AA and BA. For this reason the mutagenic potential of AA and BA was investigated in Syrian hamster embryo fibroblasts (SHE cells). DNA repair (UDS assay), chromosomal changes (micronucleus assay) and morphological transformation were chosen as biological end-points.

Granulocytic differentiation of HL-60 cells is not regulated by DNA de novo methylation

DNA cytosine methylation and transcription of specific genes are inversely correlated. In granulocytic differentiation of HL-60 cells there is a distinct down regulation of the c-myc proto-oncogene expression, which is probably a causal mechanism. With differentiation of HL-60 cells we found no restriction enzyme fragment length polymorphism (RFLP) within the c-myc proto-oncogene, which indicates that there is no loss of regulatory elements (e.g., TATAA boxes within the first exon). Furthermore, we found no de novo methylation in this region. Methylation of other DNA regions, which could influence c-myc expression, is also not necessary for differentiation, as was shown by inhibition of DNA methylase. L-Ethionine and S-adenosyl-L-homocysteine are both potent inhibitors of DNA methylase and do not influence proliferation of HL-60 cells, as shown by FACS analysis.

Single-electron-transfer in the reduction of 1,2-dioxetanes by biologically active substrates

Substances of low oxidation potential, which can also make available protons and hydrogen atoms, e.g. phenothiazines, NADH, and ascorbic acid efficiently reduce 1,2-dioxetanes to their vic-diols by single-electron-transfer; a significant side reaction is catalytic decomposition of dioxetanes into the corresponding ketone fragments.

Characterization of an in vitro micronucleus assay with Syrian hamster embryo fibroblasts

The use of Syrian hamster embryo cells for assessing genotoxicity provides the unique opportunity to determine 5 different end-points (gene mutations, DNA-strand breaks, aneuploidy, DNA repair (unscheduled DNA synthesis, UDS) and neoplastic transformation) in the one cell system. This approach allows direct comparisons of results produced under identical conditions of dose at target, metabolism and bioavailability. We report here on the characterization of an additional end-point in the same cell system: the formation of micronuclei indicating chromosomal changes induced by chemicals. For a preliminary validation of this new test system we have investigated 14 carcinogens and 3 non-carcinogenic structural analogues in order to evaluate the significance of micronucleus induction for carcinogenic properties. All tested carcinogens induced micronuclei in a dose-dependent manner; all non-carcinogens yielded negative results. Correlations between the formation of micronuclei and the Ames test, induction of UDS, cell transformation and the in vivo bone marrow micronucleus test are demonstrated.

Induction of unscheduled DNA synthesis and micronucleus formation in Syrian hamster embryo fibroblasts treated with cysteine S-conjugates of chlorinated hydrocarbons

S-(chloroethyl)-cysteine (CEC) and S-(1,2-dichlorovinyl)-cysteine (DCVC) have been proposed as intermediates in the metabolic transformation of the carcinogens 1,2-dichloroethane and 1,1,2-trichloroethylene. We have tested the ability of CEC and DCVC to induce DNA repair and genotoxic effects at the chromosomal level by comparative assessment of unscheduled DNA synthesis induction and micronucleus formation in Syrian hamster embryo fibroblasts. CEC induced a potent and dose-dependent response in both assays, whereas DCVC treatment resulted in a comparatively weak induction of DNA repair and failed to raise micronucleus formation above control rates. Inhibition of cysteine conjugate beta-lyase diminished the effect of DCVC, but had no influence on the genotoxicity of CEC either in the unscheduled DNA synthesis or micronucleus assay.