Cyto-differentiation of the neuroblasts from the neural ectodermal cells in grasshopper,Chortophaga viridifasciata (De Geer) (Orthoptera: Acrididae) embryos

The first sign of neurogenesis in the embryo of grasshopper, Chortophaga viridifasciata (Orthoptera: Acrididae), is signaled by a partition of the ectodermal cells into non-neural ectodermal cells and neural eetodermal cells. The neuroblasts are differentiated from neural ectodermal cells. In the present study, we examined the pattern of mitotic activity in the developing embryo by tracing the incorporation of BrdU in S phase nuclei. The results indicate that the ectodermal cells in 6-day old embryos do not show any signs of differentiation. In 7-day old embryos, in which ectodermal cells become partitioned into 2 types, almost no neural ectodermal cells are incorporated with BrdU, whereas a constant incorporation is revealed in non-neural ectodermal cells. Among the mitotically quiescent neural ectodermal cells, which are arrested at the GI stage of the cell cycle, in 8-day old embryos, the neuroblasts are the first to resume their mitotic activity, while the other cells are then released from the mitotic quiescence. It seems that the mitotic quiescence may be an essential process to acquire a neural fate.     

C-banding as a simple tool to discriminate between micronuclei induced by clastogens and aneugens

If mouse bone marrow preparations are treated with a classical C-banding procedure, it may be possible to distinguish between micronuclei with or without centromeres. This allows discrimination between micronuclei originating from chromosome breakage and those originating from chromosome loss. Thus, using C-banding, the micronucleus test can be used not only for the detection of clastogens but also aneugens. In this way, more exhaustive methods such as immunological staining using antikinetochore antibodies may not be necessary.     

C-Banding as a Simple Tool to Discriminate Between Micronuclei Induced by Clastogens and Aneugens

If mouse bone marrow preparations are treated with a classical C-banding procedure, it may be possible to distinguish between micronuclei with or without centromeres. This allows discrimination between micronuclei originating from chromosome breakage and those originating from chromosome loss. Thus, using C-banding, the micronucleus test can be used not only for the detection of clastogens but also aneugens. In this way, more exhaustive methods such as immunological staining using antikinetochore antibodies may not be necessary.     

Oxygen metabolism causes chromosome breaks and is associated with the neuronal apoptosis observed in DNA double-strand break repair mutants

Cells deficient in a major DNA double-strand break repair pathway (nonhomologous DNA end joining [NHEJ]) have increased spontaneous chromosome breaks; however, the source of these chromosome breaks has remained undefined. Here, we show that the observed spontaneous chromosome breaks are partially suppressed by reducing the cellular oxygen tension. Conversely, elevating the level of reactive oxygen species by overexpressing the antioxidant enzyme superoxide dismutase 1 (SOD1), in a transgenic mouse, increases chromosome breakage. The effect of SOD1 can also be modulated by cellular oxygen tension. The elevated chromosome breakage correlates histologically with a significant increase in the amount of neuronal cell death in Ku86(-/-) SOD1 transgenic embryos over that seen in Ku86(-/-) embryos. Therefore, oxygen metabolism is a major source of the genomic instability observed in NHEJ-deficient cells and, presumably, in all cells.     

Linear dose-response of acentric chromosome fragments down to 1 R of x-rays in grasshopper neuroblasts, a potential mutagen-test system

Grasshopper-embryo neuroblasts have no spontaneous chromosome breakage; therefore they permit easy detection of agents that break chromosomes. An X-ray exposure of 1 R induces in them a detectable number of chromosome fragments. The dose-response of acentric fragment frequency fits a linear model between 0 and 128 R. Thus another cell type is added to those previously demonstrated to have no threshold dose for the induction of chromosome or gene mutations.     

Relation between rate of cell proliferation and formation of micronuclei after combined treatment with X-rays and caffeine

We studied the effects of caffeine (2 mM), X-rays (1 Gy) and the combination of both agents on cell proliferation and formation of micronuclei in the early stages of preimplantation mouse embryos in vitro. Two-cell embryos were exposed to the agents shortly before division to the 4-cell stage. Proliferation and micronucleus production was monitored every 2 h in the 4- and 8-cell stages. A rather peculiar pattern of micronucleus formation after radiation exposure alone was observed for 8-cell embryos: those embryos that were the first to enter the 8-cell stage showed two to three times higher numbers of micronuclei per cell when compared with those embryos that entered the 8-cell stage some hours later. Studies of the kinetics of cell proliferation and of micronucleus formation in 4- and 8-cell embryos and exposure to caffeine revealed that this result could be explained by two factors: a slight asynchrony in the developmental stage at the time of exposure and the length of the interval being available for repair processes. When caffeine was present, a third factor had to be taken into consideration: direct inhibition of repair by caffeine.Dedicated to Prof. W. Jacobi on the occasion of his 65th birthday     

Comparison of the levels of chromosome aberration and sister chromatid exchange induced by chemical mutagens in vitro

Dose dependencies of the induction of sister chromatid exchanges (SCEs) and chromosome aberrations were studied under in vivo exposure of mouse bone marrow cells to 5 alkylating agents. The efficacy of the induction of SCEs for all the substances was 20 to 60 times higher than that of the induction of chromosome aberrations. It was demonstrated that SCEs induced by chemical mutagens in vivo and in vitro are more sensitive tests than chromosome aberrations.     

Mitomycin C effects on cell cycle progression, including inhibition of very late prophase, as seen in living neuroblasts of Chortophaga viridifasciata, with some observations on mitomycin C purity

Observations were made on living neuroblasts (Nbs) of the grasshopper (Chortophaga viridifasciata) embryo during a 4-h recovery period following 1-h in vitro exposure to 10(-8), 10(-6), and 10(-4) M mitomycin C (MMC). None of these concentrations affected the duration of mid-mitosis (prometaphase, metaphase, anaphase), but one as low as 10(-8) M causes a small reduction in the rate at which Nbs move through the remainder of the cell cycle, primarily by retarding their progress through S. As the concentration is increased there is slower movement through S and also prophase (there are no true G1 and G2 periods in the rapidly dividing Nb: 4-h cell cycle at 38 degrees C). A significant proportion of the cells exposed to 10(-4) M are blocked for 1 or more h at very late prophase, i.e., just before nuclear membrane breakdown. In such retarded prophases the chromosomes resemble c-metaphase chromosomes even though the nuclear membrane remains intact. Mass spectrometry data revealed that one lot of the MMC used contained one or more impurities.     

Genotoxic ability of cadmium, chromium and nickel salts studied by kinetochore staining in the cytokinesis-blocked micronucleus assay

The aneugenic and clastogenic ability of cadmium chloride(II), cadmium sulfate(II), nickel chloride(II), nickel sulfate(II), chromium chloride(III) and potassium dichromate(IV) have been evaluated through kinetochore-stained micronucleus test. Traditional genotoxicity assays evaluate DNA damage, gene mutations and chromosome breakage. However, these tests are not adequate to detect aneugenic agents that do not act directly on DNA. Staining kinetochores in the cytokinesis-blocked micronucleus assay is a useful way to discriminate between clastogens and aneuploidogens and may allow a rapid identification of aneuploidy-inducing environmental compounds.Human diploid fibroblasts (MRC-5) were employed. All compounds increased micronuclei frequency in a statistically significant way. However, increases in kinetochore-positive micronuclei frequencies were higher than in kinetochore-negative ones. The present work demonstrates the genotoxic ability of the cadmium and chromium salts studied. Aneugenic as well as clastogenic ability could be observed with this assay. Nickel salts, as it was expected because of their known weak mutagenicity, showed lower genotoxic effects than the other metal salts studied. As the test employed only allows the detection of malsegregation, it is proposed that this mechanism is at least one of those by which the tested metal salts induced aneuploidy. On the other hand, visualization of kinetochores in all experiments suggests that the compounds studied did not act by damaging these structures.     

Genotoxic ability of cadmium, chromium and nickel salts studied by kinetochore staining in the cytokinesis-blocked micronucleus assay

The aneugenic and clastogenic ability of cadmium chloride(II), cadmium sulfate(II), nickel chloride(II), nickel sulfate(II), chromium chloride(III) and potassium dichromate(IV) have been evaluated through kinetochore-stained micronucleus test. Traditional genotoxicity assays evaluate DNA damage, gene mutations and chromosome breakage. However, these tests are not adequate to detect aneugenic agents that do not act directly on DNA. Staining kinetochores in the cytokinesis-blocked micronucleus assay is a useful way to discriminate between clastogens and aneuploidogens and may allow a rapid identification of aneuploidy-inducing environmental compounds.Human diploid fibroblasts (MRC-5) were employed. All compounds increased micronuclei frequency in a statistically significant way. However, increases in kinetochore-positive micronuclei frequencies were higher than in kinetochore-negative ones. The present work demonstrates the genotoxic ability of the cadmium and chromium salts studied. Aneugenic as well as clastogenic ability could be observed with this assay. Nickel salts, as it was expected because of their known weak mutagenicity, showed lower genotoxic effects than the other metal salts studied. As the test employed only allows the detection of malsegregation, it is proposed that this mechanism is at least one of those by which the tested metal salts induced aneuploidy. On the other hand, visualization of kinetochores in all experiments suggests that the compounds studied did not act by damaging these structures.     

Cytogenetic studies using various clastogens in two patients with Werner syndrome and control individuals

Summary Chromosome studies were performed on peripheral lymphocytes from two patients with Werner syndrome and two healthy control individuals to detect spontaneous and/or mutagen-induced chromosomal instability of this disease. Diepoxybutane, isonicotinic acid hydrazide, 4-nitro-quinoline-1-oxide, and bleomycin were used as standard clastogens. While the spontaneous frequency of chromosomal breakage was much higher in lymphocytes from both patients than in the control cells, the basic rate of sister chromatid exchange (SCE) was found to be in the control range. The sensitivity to clastogens of the patients' cells, however, was not substantially increased as compared with the controls if the degree of multiplication of the spontaneous breakage rate or SCE frequency was taken as the basis for comparison. No indication of a greater inhibition of proliferation by the clastogens in the patients' cells than in normal cells was observed using BrdU-labelled lymphocytes. Thus, the lymphocytes from both patients of the present study lacked essential features of the classical chromosome instability syndromes.     

The in vitro micronucleus technique

The study of DNA damage at the chromosome level is an essential part of genetic toxicology because chromosomal mutation is an important event in carcinogenesis. The micronucleus assays have emerged as one of the preferred methods for assessing chromosome damage because they enable both chromosome loss and chromosome breakage to be measured reliably. Because micronuclei can only be expressed in cells that complete nuclear division a special method was developed that identifies such cells by their binucleate appearance when blocked from performing cytokinesis by cytochalasin-B (Cyt-B), a microfilament-assembly inhibitor. The cytokinesis-block micronucleus (CBMN) assay allows better precision because the data obtained are not confounded by altered cell division kinetics caused by cytotoxicity of agents tested or sub-optimal cell culture conditions. The method is now applied to various cell types for population monitoring of genetic damage, screening of chemicals for genotoxic potential and for specific purposes such as the prediction of the radiosensitivity of tumours and the inter-individual variation in radiosensitivity. In its current basic form the CBMN assay can provide, using simple morphological criteria, the following measures of genotoxicity and cytotoxicity: chromosome breakage, chromosome loss, chromosome rearrangement (nucleoplasmic bridges), cell division inhibition, necrosis and apoptosis. The cytosine-arabinoside modification of the CBMN assay allows for measurement of excision repairable lesions. The use of molecular probes enables chromosome loss to be distinguished from chromosome breakage and importantly non-disjunction in non-micronucleated binucleated cells can be efficiently measured. The in vitro CBMN technique, therefore, provides multiple and complementary measures of genotoxicity and cytotoxicity which can be achieved with relative ease within one system. The basic principles and methods (including detailed scoring criteria for all the genotoxicity and cytotoxicity end-points) of the CBMN assay are described and areas for future development identified.     

Use of the cytokinesis-block micronucleus method in mouse splenocytes

Mouse splenocytes have been used in the cytokinesis-block method for the evaluation of micronuclei induced by mutagenic agents in vitro as well as in vivo. Stimulation with concanavalin A for 48 h followed by 16-24-h treatment with 5 micrograms/ml cytochalasin B was found to be an optimum condition to obtain micronuclei in the binucleated splenocytes after the cells were cultured in vitro. Under the above conditions splenocytes from mice pretreated with a single i.p. injection of cyclophosphamide gave a significant increase in micronucleus production. This increase was dependent on the dose of cyclophosphamide (r = 0.99). A dose of 50 mg/kg resulted in 22% of the binucleated cells producing micronuclei, more than 20 times the level in the untreated control. The increase was also dependent on the time of cyclophosphamide injection before removal of the spleen. A duration of 4-8 h after cyclophosphamide injection gave rather sharp optimum values for the production of micronuclei. When splenocytes from non-treated mice were treated with mitomycin C together with cytochalasin B in the above in vitro condition, there was a significant increase in micronucleus production in the binucleated cells. It was also dependent on the dose of mitomycin C (r = 0.975) and a dose of 0.5 micrograms/ml resulted in a more than 20-fold increase over the untreated control. Thus, the use of mouse splenocytes in the cytokinesis-block micronucleus assay was shown to be sensitive enough for testing mutagenic agents in vivo as well as in vitro.     

Discrimination of aneuploidogens from clastogens by C-banding, DNA and area measurements of micronuclei from mouse bone marrow.

Micronuclei (MN) obtained from mouse bone marrow cells, in vivo exposed to 3 typical clastogens (procarbazine, azathioprine, ethyl methanesulfonate) and 3 typical aneuploidogens (vinblastine, tubulazole, colchicine), were examined for C-band, area and DNA content. C-banding allows a clear discrimination between clastogens and aneuploidogens: the clastogens do not exceed 50% C-band-positive MN and the aneuploidogens all 3 produce 65-75% C-band-positive MN. Concerning the DNA content the percentages of MN containing more DNA than an average chromosome (chr) are lower than 12% for the clastogens and 38-60% for the aneuploidogens. As far as the area of the MN is concerned the percentages of MN which have a larger area than chr are lower than 23% for the clastogens and range from 47% to 71% for the aneuploidogens. Additionally 3 other mutagens were studied. Hydroquinone induces 43% C-band-positive MN with DNA content far below the content of chr; considering the area measurements, however, hydroquinone behaves as an aneuploidogen (65% of the MN are larger than chr). Mitomycin C lies between the clastogens and the aneuploidogens for all 3 criteria but 5-azacytidine is comparable to the model aneuploidogens.     

Kinetochore analysis of micronuclei allows insights into the actions of colcemid and mitomycin C

We have induced micronuclei in two strains of diploid human fibroblasts with a known aneugen, colcemid, and a known clastogen, mitomycin C. Using immunofluorescence to detect the presence of kinetochores in micronuclei, we were able to demonstrate a 26.8-fold increase in fluorescence-positive micronuclei (aneuploidy) in colcemid-treated cells. However, colcemid also induced an increase in kinetochore-negative micronuclei. Our findings support previous reports that suggest colcemid may induce chromosome breakage in addition to its major aneugenic effect. The frequency of kinetochore-negative micronuclei (chromosome breakage) in mitomycin C-treated cells rose an average of 7.9-fold in the two test strains, a clear reflection of its clastogenic action. However, a 4-fold increase in the kinetochore-positive fraction was seen. We conclude that the fibroblast micronucleus assay, coupled with kinetochore immunofluorescence, provides a useful screening approach for genotoxic agents. The delineation of the precise mechanism by which an agent perturbs the rates of chromosomal breakage or lag may require more detailed analysis.     

Genotoxicity assessment of ethylenediamine dinitrate (EDDN) and diethylenetriamine trinitrate (DETN)

Ethylenediamine dinitrate (EDDN) and diethylenetriamine trinitrate (DETN) are relatively insensitive explosive compounds that are being explored as safe alternatives to other more sensitive compounds. When used in combination with other high explosives they are an improvement and may provide additional safety during storage and use. The genetic toxicity of these compounds was evaluated to predict the potential adverse human health effects from exposure by using a standard genetic toxicity test battery which included: a gene mutation test in bacteria (Ames), an in vitro Chinese Hamster Ovary (CHO) cell chromosome aberration test and an in vivo mouse micronucleus test. The results of the Ames test showed that EDDN increased the mean number of revertants per plate with strain TA100, without activation, at 5000μg/plate compared to the solvent control, which indicated a positive result. No positive results were observed with the other tester strains with or without activation in Salmonella typhimurium strains TA98, TA1535, TA1537, and Escherichia coli strain WP2 uvrA. DETN was negative for all Salmonella tester strains and E. coli up to 5000μg/plate both with and without metabolic activation. The CHO cell chromosome aberration assay was performed using EDDN and DETN at concentrations up to 5000μg/mL. The results indicate that these compounds did not induce structural chromosomal aberrations at all tested concentrations in CHO cells, with or without metabolic activation. EDDN and DETN, when tested in vivo in the CD-1 mouse at doses up to 2000mg/kg, did not induce any significant increase in the number of micronuclei in bone marrow erythrocytes. These studies demonstrate that EDDN is mutagenic in one strain of Salmonella (TA100) but was negative in other strains, for in vitro induction of chromosomal aberrations in CHO cells, and for micronuclei in the in vivo mouse micronucleus assay. DETN was not genotoxic in all in vitro and in vivo tests. These results show the in vitro and in vivo genotoxicity potential of these chemicals.     

Evidence for chromosome instability in vivo in bloom syndrome: Increased numbers of micronuclei in exfoliated cells

Summary The incidence of exfoliated epithelial cells containing micronuclei was determined in two small human populations, one homozygous and the other heterozygous for the Bloom syndrome gene (bl). The objectives of the study were two: (1) to learn whether the chromosome instability featured so prominently by Bloom syndrome (BS) cells proliferating in vitro also occurs in vivo, and (2) as part of a broad survey of various cancer-prone populations, to determine whether estimating micronucleus frequencies in exfoliated cell samples might be useful for identifying individuals with genetically determined chromosome instability. Eight individuals homozygous (bl/bl) for the BS gene, i.e., persons with the clinical syndrome, were examined, along with 11 obligate heterozygotes (bl/+), parents of affected persons. Exfoliated cells were obtained from two sites, the oral cavity and the urinary tract. Striking and statistically highly significant elevations in the frequencies of cells with micronuclei were observed in cells from both sites in bl/bl individuals compared to that in bl/+ (P<0.001) and in a control population, indicating that chromosome instability occurs in vivo in BS. In contrast, micronucleus frequencies at either site did not differ significantly between bl/+ individuals and the control population. This survey, in combination with similar earlier ones of populations predisposed to cancer not on a genetic basis but because of exposure to some environmental carcinogen, suggests that the exfoliated cell micronucleus test identifies individuals whose somatic genetic material has, for either genetic or environmental reasons, been damaged in a way that produces chromosome breakage and rearrangement.     

Inhaled radon-induced genotoxicity in Wistar rat,Syrian hamster,and Chinese hamster deep-lung fibroblasts in vivo

This study was performed (1) to provide a comparison of the genotoxin effects of inhaled radon and radon progeny, referred to as radon in this paper, among three species of rodents: Wistar rats, Syrian hamsters, and Chinese hamsters; (2) to determine if initial chromosome damage was related to the risk of induction of lung cancer; and (3) to evaluate the tissue repair and long-term presence of cytogenetic damage in respiratory tract cells. These species were selected because Syrian hamsters are very resistant to radon induction of lung cancer and Wistar rats are sensitive; no literature is available on the in vivo effects of radon in the Chinese hamster. Exposure-response relationships were established for the rats and Syrian hamsters while the Chinese hamsters received a single exposure of radon. At 4 h (0.2 days), 15 days, and 30 days after the highest WLM exposure to radon, Wistar rats, Chinese hamsters, and Syrian hamsters were killed, and lung fibroblasts were isolated and grown in culture to determine the frequency of induced micronuclei. Animals at each level of exposure showed an increase in the frequency of micronuclei relative to that in controls (P < 0.05). The exposure-response relationship data for rats and Syrian hamsters killed 0.2 days after the end of exposure were fit to linear equations (micronuclei/1000 binucleated cells = 15.5±14.4+0.53±0.06 WLM and 38.3±15.1+0.80±0.08 WLM, respectively). For the single exposure level used (496 WLM) in Chinese hamsters killed at 0.2 days after exposure, the frequency of micronuclei/1000 binucleated cells/WLM was 1.83±0.02. A comparison of the sensitivity for induction of micronuclei/WLM illustrated that Chinese hamsters were three times more sensitive than rats. The Syrian hamsters also showed a significantly elevated response (P < 0.05) relative to rats. These data suggest that initial chromosome damage is not the major factor responsible for the high rate of radon-induced cancer in rats relative to Syrian hamsters. The frequency of micronuclei in radon-exposed rats, Syrian hamsters, and Chinese hamsters significantly decreased (P < 0.05) as a function of time after the exposure. The rate of loss of damaged cells from the lung was greatest in the Chinese hamsters, followed by Wistar rats and Syrian hamsters, respectively. Our experiments demonstrated that the mammalian lung fibroblast/micronucleus method has the potential to (1) detect species differences in the induction of in vivo genotoxic damage in the lungs by inhaled environmentalal agents; (2) evaluate exposure-response relationships for in vivo induction of genetic damage; and (3) determine the persistence in vivo of preclastogenic and premutagenic lesions in cell populations.     

A comparison between short-term evolution of micronuclei induced by X-rays and colchicine in root tips of Vicia faba

The short-term evolution of micronuclei derived from acentric fragments and whole chromosomes was studied in root tips of Vicia faba. Micronuclei were induced by X-rays (30 cGy and 120 cGy) and colchicine (10(-5) M and 3 X 10(-4) M). Frequencies of chromosome breakage or loss of micronuclei in interphase and mitotic cells were studied. The DNA content of micronuclei in interphase cells was also measured. Micronuclei derived from whole chromosome showed a higher probability to survive and to undergo mitotic condensation in synchrony with main nuclei than micronuclei derived from an acentric fragment. PCC (Premature Chromosome Condensation) was not observed for both types of micronuclei in Vicia faba, in contrast to the ones reported in mammalian cells in culture.     

A comparison of diameters of micronuclei induced by clastogens and by spindle poisons

To compare the size of micronuclei induced by clastogens and by spindle poisons, bone-marrow smears were prepared 24 h after a single intraperitoneal injection of triethylenemelamine (TEM) (0.3 mg/kg) or vincristine (VCR) (0.125 mg/kg) into male mice. 100 micronucleated erythrocytes (MNEs) were randomly selected from each group and photomicrographed. Diameters of the cytoplasm (D) and the micronucleus (d) of each MNE were measured on the photographs. Relatively large micronuclei (d?D/4) were frequent (74%) in the VCR-treated group, and infrequent (2%) in the TEM-treated group. The frequencies of MNEs resulting in d?D/4 were determined for several other mutagens. All clastogens tested could be classified as TEM type, and all spindle poisons as VCR type.These findings indicate that it is possible to analyze the action site of micronucleus-inducing agents on the basis of the relative sizes of micronuclei.