Caterina Tanzarella

Immunofluorescent staining of kinetochores in micronuclei: a new assay for the detection of aneuploidy.

The immunofluorescent staining of kinetochores in micronuclei with antikinetochore antibodies was used to develop an in vitro assay for aneuploidy-inducing agents. The results show that about 80% of micronuclei induced by either colchicine or chloral hydrate contained kinetochores; only 9% of X-ray-induced micronuclei reacted positively to the antibody. These findings indicate that the in vitro micronucleus assay coupled with immunofluorescent staining of kinetochores can be a useful method for assessing the ability of chemicals to induce aneuploidy and/or chromosome aberrations.

The detection and evaluation of aneugenic chemicals.

Although aneuploidy makes a significant contribution to both somatic and inherited disease the mechanisms by which environmental chemicals may induce numerical chromosome aberrations are only poorly defined. The European Union Project was aimed to further our understanding of those chemical interactions with the components of the mitotic and meiotic cell division cycle which may lead to aneuploidy and to characterise the parameters such as cellular metabolism which may influence the activity of aneugenic chemicals. C-mitosis can be induced by the highly lipophilic polychlorinated biphenyl and the completion of mitosis and cleavage can be modified by agents which deplete cellular levels of reduced glutathione. Modifications of the fidelity of chromosome segregation were produced by inhibiting the functioning of topoisomerase II during chromatid separation. In contrast, the modification of centromere integrity resulted in chromosome breakage as opposed to disturbance of segregation. Modifiers of tubulin assembly and centriolar functioning in somatic cells such as acrylamide, vinblastine and diazepam reproduced their activity in rodent bone marrow and male germ cells. The analysis of chromosome malsegregation in Aspergillus nidulans by a structurally related series of halogenated hydrocarbons was used to develop a QSAR model which had high predictive value for the results of fungal tests for previously untested related chemicals. Metabolic studies of potential aneugens in genetically engineered human lymphoblastoid cells demonstrated the detoxification of the aneugenic activity of chloral hydrate and the activation of 2,3-dichlorobutane, 1,1,2-trichloroethane and trichloroethylene by Phase I biotransforming enzymes. Cell transformation studies in Syrian hamster dermal cultures using a panel of 22 reference and or potential aneugens indicated that 15 of the 22 produced positive results following single exposures. Five of the aneugens which were negative following single exposures produced positive results where cultures were continuously exposed for up to 6 weeks to low concentrations following a single non-transforming exposure to the mutagen dimethyl sulphate. The transformation studies indicate that a significant proportion of chemical aneugens are potential complete carcinogens and/or co-carcinogens. To optimise the enumeration of chromosomes following exposure to potential chemical aneugens whole chromosome paints and centromere specific probes suitable for use in fluorescence in situ hybridisation (FISH) were developed for the rat, mouse and Chinese hamster and selected human probes evaluated for their suitability for routine use. Molecular chromosome probes were used to develop protocols for enumerating chromosomes in metaphase cells and centromeres and micronuclei in interphase cells. The analysis of segregation of specific centromeres in binucleate cells following cytochalasin B treatment was shown to be a potentially valuable system for characterising non-disjunction following chemical exposure. Whole chromosome paints and centromere specific probes were used to demonstrate the presence of dose-response thresholds following treatment with a reference panel of spindle inhibiting chemicals. These data indicate that the FISH technology is suitable for evaluating the relative hazards of low-dose exposures to aneugenic chemicals.

Genetic effects of petroleum fuels : cytogenetic monitoring of gasoline station attendants

Workers in the petroleum distribution trades experience relatively high-level exposures to fuel vapours whose consequences have not been fully elucidated. In this study, the possible relationship between occupational exposure to petroleum fuels and cytogenetic damages in peripheral lymphocytes was investigated. Twenty-three male, non-smoking workers from the area of Rome were enrolled in the study, together with age-paired controls with no occupational exposure to fuels. Peripheral lymphocyte cultures were set up for the analysis of structural chromosome aberrations (CAs), sister chromatid exchanges (SCEs) and micronuclei (MN) in cytokinesis-blocked lymphocytes. Frequencies of CAs, SCEs and MN were compared between exposed and control groups, and evaluated in relation to blood lead level (as an indicator of engine exhausts exposure) for the whole group under study, and to yearly averaged exposure to benzene (8-h time weighted averages, as determined by repeated personal sampling) for fillingstation attendants only. Both CAs and SCEs were slightly increased in station attendants: 1.97 versus 1.46 aberrations per 100 cells, and 4.73 +/- 0.15 versus 4.48 +/- 0.11 SCEs/cell in exposed and control individuals, respectively. The difference between cumulative CA rates in the exposed and control populations was of borderline statistical significance (p = 0.066). However, when the exposed population was dichotomized for benzene exposure, a significant (p = 0.018) correlation of CAs with benzene exposure was found. The analysis of SCE data highlighted a significant increase of cells with more than 6 exchanges (HFCs), corresponding to the 75 degrees percentile of the overall distribution, in fillingstation attendants (relative risk (RR) = 1.3, 95% CI = 1.1-1.5) in comparison with controls. In the pooled population, the frequency of HFCs showed a statistically significant upward trend at increasing blood lead levels (chi 2 for trend = 27.8, p < 0.0001). A complex relationship between SCEs and benzene exposure was observed, with an increased frequency of HFCs in the medium exposure intensity class (RR = 1.5, 95% CI = 1.2-1.7), and no difference for exposure to higher benzene levels (RR = 1.0, 95% CI = 0.9-1.2), compared to reference subjects. Finally, the analysis of MN in both phytohemagglutinin- and pokeweed-stimulated cell cultures did not show significant excess of MN in binucleated lymphocytes of exposed workers with respect to the age-paired controls.

Combretastatin CA-4 and combretastatin derivative induce mitotic catastrophe dependent on spindle checkpoint and caspase-3 activation in non-small cell lung cancer cells

Combretastatin A-4 (CA-4), a natural stilbenoid isolated from Combretum caffrum, is a new vascular targeting agent (VTA) known for its antitumor activity due to its anti-tubulin properties. We investigated the molecular mechanisms leading to cell death in non-small cell lung cancer H460 cells induced by natural (CA-4) and synthetic stilbenoids (ST2151) structurally related to CA-4. We found that both compounds induced depolymerization and rearrangement of spindle microtubules, as well as an increasingly aberrant organization of metaphase chromosomes in a dose- and time-dependent manner. Prolonged exposition to ST2151 led cells to organize multiple sites of tubulin repolymerization, whereas tubulin repolymerization was observed only after CA-4 washout. H460 cells were arrested at a pro-metaphase stage, with condensed chromosomes and a triggered spindle assembly checkpoint, as evaluated by kinetochore localization of Bub1 and Mad1 antibodies. Persistent checkpoint activation led to mitochondrial membrane permeabilization (MMP) alterations, cytochrome c release, activation of caspase-9 and -3, PARP cleavage and DNA fragmentation. On the other hand, caspase-2, and -8 were not activated by the drug treatment. The ability of cells to reassemble tubulin in the presence of an activated checkpoint may be responsible for ST2151-induced multinucleation, a recognized sign of mitotic catastrophe. In conclusion, we believe that discovery of new agents able to trigger mitotic catastrophe cell death as a result of mitotic block and prolonged spindle checkpoint activation is particularly worthwhile, considering that tumor cells have a high proliferative rate and mitotic failure occurs irrespective of p53 status.

Impaired p53-mediated DNA damage response, cell-cycle disturbance and chromosome aberrations in Nijmegen breakage syndrome lymphoblastoid cell lines.

PURPOSE To investigate the p53 ionizing radiation-induced response, G1/S cell-cycle block and cytogenetic damage in Nijmegen breakage syndrome (NBS) cells characterized by different haplotypes. MATERIAL AND METHODS Lymphoblastoid cell lines derived from three normals, five NBS and two ataxia telangiectasia (AT) individuals were treated with moderate doses of X-rays and changes in the p53 response were studied by dose-response and time-course experiments. Multiparametric flow cytometry analysis of bromodesoxyuridine-incorporated cells was carried out to analyse G1/S checkpoint alterations. Cytogenetic damage induced by 2 Gy radiation was assessed in cells harvested 28 h later. RESULTS Comparison of mean values of p53 accumulation in NBS, AT and control cells indicated that protein induction in NBS cells was between normal and AT cells. Cell-cycle experiments showed a markedly reduced S-phase fraction in irradiated samples of normal cell lines, while NBS, and particularly AT cells, showed less reduction in S-phase fraction. Irrespective of differences in p53 induction and G1/S block, chromatid-type aberrations were induced at a comparable level in both syndromes, while being almost absent in normal cells. CONCLUSIONS The data suggested that failure of NBS cells to initiate cell-cycle delay cannot account alone for their extreme sensitivity to radiation.

Chromosome Instability and Nibrin Protein Variants in NBS Heterozygotes

The frequency of spontaneous chromosome abnormalities in peripheral blood lymphocytes and the X-ray G2 sensitivity in lymphoblastoid cell lines (LCL) have been evaluated in heterozygous subjects from three unrelated Nijmegen Breakage Syndrome (NBS) families, characterised by different mutations in the NBS1 gene. In all the 13 NBS heterozygotes analysed, we found spontaneous chromosome instability consisting in chromosome and chromatid breakages and rearrangements, while radiosensitivity was similar to that of control LCLs in seven out of eight tested NBS heterozygotes. The densitometric analysis of nibrin by immunoblotting indicated only a slight reduction in some of the LCLs from NBS carriers, whereas the immunoprecipitation assay appears a more reliable tool to detect NBS carriers. By means of immunoprecipitation, we investigated two homozygous and four heterozygous subjects. In the cells of the NBS patient 668, with the mutation 900del25, an alternative form of nibrin with a molecular weight of approximately 55 kDa has been detected. This variant protein, together with the normal p95, was also found in the LCL 34 established from a carrier of the same family. Signals of nibrin with a molecular weight lower than 95 kDa, but higher than that observed in LCLs 668 and 34, were detected also in three carriers from the family with mutation 835del4.

Chromosomal sensitivity to clastogenic agents and cell cycle perturbations in Nijmegen Breakage Syndrome lymphoblastoid cell lines

The relationship between chromosomal breakage and perturbations of cell cycle progression was investigated in lymphoblastoid cell lines established from a healthy donor, two subjects affected by Nijmegen Breakage Syndrome (NBS) and an ataxia-telangiectasia (AT) patient. The cytogenetic analysis revealed a similar chromosomal hypersensitivity in both NBS and AT cells exposed in the G1 phase to 200 cGy X-rays or in G2 to 15-30 cGy. Similarly, no differences were observed in the frequency of chromatid-type aberrations induced in G2 by 1-2 pg/ml calicheamicin gamma 1I, a DNA double-strand break inducer. In addition, as observed in AT cells, the rate of G2 radiation-induced chromosomal damage was less enhanced in NBS than in control cells following 3-h incubation with inhibitors of DNA synthesis/repair (cytosine arabinoside, aphidicolin, DMSO, hydroxyurea, caffeine). This is suggestive of an altered DNA lesion-processing pathway common to both syndromes. Despite the close resemblance of cellular phenotypes in the two syndromes, the analysis of mitotic indices carried out at 2 and 4 h postirradiation indicated that NBS sustained a G2-delay greater than that observed in AT cells, Furthermore, the flow cytometric analysis of 50-300 cGy irradiated cells at 10 and 20 h before harvesting showed that NBS cells sustained a G2/M phase arrest markedly lower than AT cells. Our data indicate that NBS and AT gene products are involved in a common pathway of radiation-induced chromosomal damage, but in a different one for cell cycle control after irradiation.

SIMULTANEOUS INHIBITION OF CONTRACTILE RING AND CENTRAL SPINDLE FORMATION IN MAMMALIAN CELLS TREATED WITH CYTOCHALASIN B

Abstract. In this work we have used the inhibitor of F-actin polymerisation cytochalasin B (Cyt B) to test the hypothesis that the contractile ring and the central spindle are mutually interdependent structures in mammalian mitotic cells. Double fluorescence staining of α-tubulin and F-actin was employed to analyse anaphase and telophase figures from asynchronously growing cultures and prometaphase-synchronised cells. Testing for the presence of the central spindle and contractile ring in human primary fibroblasts, human hepatoma cells and Chinese hamster cells after Cyt B treatment showed that both structures were simultaneously absent in over 60% of treated anaphases and 80% of telophases. Experiments on resumption of cytokinesis in cleavage-arrested cells further showed that Cyt B-treated human fibroblasts proceeded to cleavage within minutes after removal of the drug from the medium, concomitant with the re-formation of both cellular structures in cleaving cells. These data suggest that the presence of a correctly assembled contractile ring is essential for the formation and persistence of the central spindle during ana-telophase and provide further support for the idea of a strong co-operative interaction between these two structures during cytokinesis.

Topoisomerase II inhibition in mitosis produces numerical and structural chromosomal aberrations in human fibroblasts

We investigated the effects of treatment of mitotic human fibroblasts with the topoisomerase II inhibitor etoposide (VP-16) on chromosome segregation at anaphase and the genetic consequence to daughter cells of topoisomerase inhibition during mitosis. The most striking effect of VP-16 treatment during mitosis was the production of anaphase cells with several entangled chromosomes (catenated anaphase cells). To analyze the effects of sister chromatid catenation at anaphase on the daughter cells, several interphase methodologies were applied to binucleated human fibroblasts that were blocked during cytokinesis. Post-treatment of mitotic cells with the cytokinesis inhibitor cytochalasin-B maintains the reciprocal products of a mitotic division in the same cytoplasm, allowing the distribution of whole chromosomes or chromosome fragments in daughter nuclei or micronuclei to be followed. The presence of micronuclei containing kinetochores, as detected by antikinetochore staining, suggested that VP-16 treatment during mitosis induces chromosome loss in binucleated fibroblasts. Induction of aneuploid cells for chromosomes 7 and 11 was observed by double in situ hybridization using chromosome-specific alphoid probes in binucleated fibroblasts. In addition, double in situ hybridization with adjacent alphoid and classical satellite DNA probes to chromosome 1 demonstrated that both numerical and structural aberrations contribute to the genetic effects of topoisomerase II inhibition in mitosis.

Cytokinesis-block micronucleus assay with kinetochore detection in colchicine-treated human fibroblasts

A modified micronucleus assay using antikinetochore antibody has been developed in cytokinesis-blocked human fibroblasts as a simple method to identify aneuploidy-inducing agents. Different protocols for inducing binucleated cells by cytochalasin B in colchicine-treated human fibroblasts were investigated. A dose-related increase in kinetochore-positive micronuclei was obtained when cytochalasin B was given subsequent to colchicine treatment. No induction of micronuclei was observed in combined treatments of the two substances. These results indicate that the detection of kinetochores in micronucleated cytokinesis-blocked human fibroblasts can be effectively applied to the identification of environmental agents with aneuploidy-inducing potential. However, in testing such compounds particular attention should be paid to the protocol used for inducing cytokinesis-blocked cells.