Your search keyword '"Georgia I. Terzoudi"' showing total 4 results

1. A new cytogenetic approach for the evaluation of mutagenic potential of chemicals that induce cell cycle arrest in the G2 phase

Author

Gabriel E. Pantelias, W. Makropoulos, K. Margaritis, S. I. Malik, Georgia I. Terzoudi, and K. N. Manola

Subjects

G2 Phase, medicine.medical_specialty, Cell cycle checkpoint, Health, Toxicology and Mutagenesis, Mitosis, Sister chromatid exchange, Biology, Toxicology, Chromosomes, Phosphoprotein Phosphatases, Genetics, medicine, Humans, Lymphocytes, Oxazoles, Metaphase, Genetics (clinical), Chromosome Aberrations, Cytogenetics, Cell cycle, Bromodeoxyuridine, Mutagenesis, Premature chromosome condensation, Cell Cycle Kinetics, Carcinogens, Cancer research, Marine Toxins, Sister Chromatid Exchange

Abstract

The aim of the present study was to develop and standardize a cytogenetic approach for evaluation of the mutagenic potential of chemicals that induce cell cycle arrest in the G2 phase. Even though cytogenetic end-points such as sister chromatid exchange (SCE) have been extensively used to indirectly assess the DNA-damaging potential of various chemicals, they are based on metaphase chromosome analysis. Cells delayed in G2 phase after chemical exposure are not included in conventional SCE analysis. The yield of SCEs obtained, therefore, can be biased, since predominantly undamaged cells proceed to metaphase without delay. To overcome this shortcoming of conventional SCE analysis, the use of a new cytogenetic approach for genotoxic studies is presented that enables the analysis of SCEs directly in G2 phase using drug-induced premature chromosome condensation in cultured peripheral blood lymphocytes. By means of this method, firstly, the possibility that SCE analysis in metaphase chromosomes underestimates the mutagenic potential of various chemicals was tested. Secondly, whether the genotoxic potential of suspected carcinogens could be evaluated using SCE analysis in G2 phase, even at exposures that arrest cells in G2 phase, was examined. Thirdly, whether an important part of the background variation in SCE frequency among individuals is due to the delay of affected cells in G2 phase, rather than to a true biological variation in the cytogenetic end-point used, was tested. The results showed that a higher SCE frequency was scored in G2 phase than in metaphase. Subsequently, the mutagenic potential of chemicals that temporarily arrest cells in G2 phase could now be evaluated more accurately. In addition, it may be of interest to further examine the involvement of cell cycle kinetics in the baseline SCE variation among individuals since a lesser SCE variability was observed when the analysis was carried out in G2 phase rather than at metaphase.

Published

2003

2. Pre-irradiation exposure of peripheral blood lymphocytes to glutaraldehyde induces radiosensitization by increasing the initial yield of radiation-induced chromosomal aberrations

Author

Vasilios Makropoulos, Gabriel E. Pantelias, Georgia I. Terzoudi, Vasiliki I. Hatzi, and Constantinos Maravelias

Subjects

G2 Phase, DNA repair, Health, Toxicology and Mutagenesis, Lymphocyte, Biology, Toxicology, Radiation Tolerance, Ionizing radiation, In vivo, Genetics, medicine, Chromosomes, Human, Humans, Radiosensitivity, Irradiation, Lymphocytes, Genetics (clinical), Cells, Cultured, Chromosome Aberrations, medicine.disease, medicine.anatomical_structure, Cross-Linking Reagents, Glutaral, Premature chromosome condensation, Cancer research, Chromosome abnormality, DNA Damage

Abstract

Glutaraldehyde (GA) is a high production volume chemical that is very reactive with a wide spectrum of medical, scientific and industrial applications. Since human exposure in anthropogenic and occupational environment occurs frequently, GA has been extensively tested for genotoxic activity in vitro and in vivo. However, there are conflicting results in the literature and there is a lack of information concerning the combined effects of exposure to both GA and ionizing radiation in human cells. In the present study, the results obtained using conventional cytogenetic analysis do not suggest a statistically significant clastogenic or genotoxic activity of GA when concentrations in the range of 10 -6 to 10 -2 mM were applied. However, a 24-h pre-irradiation exposure of human peripheral blood lymphocytes (PBLs) to non-genotoxic doses of GA showed a statistically significant (P > 0.05) increase in chromosomal radiosensitivity. The observed increase may be an effect of GA-induced alterations in the cell-cycle and feedback control mechanisms during the cell-cycle transition points or it may be a consequence of an effect of GA either on the DNA repair capacity of the cells after irradiation or on the initial induction of radiation-induced chromosomal damage. To elucidate the mechanism underlying the obtained radiosensitization, conventional cytogenetics, the G2 chromosomal radiosensitivity assay and premature chromosome condensation methodologies were applied. The results support the hypothesis that pre-irradiation exposure of PBLs to GA induces radiosensitization by increasing the initial yield of chromosomal aberrations following irradiation.

Published

2008

3. Conversion of DNA damage into chromosome damage in response to cell cycle regulation of chromatin condensation after irradiation

Author

Gabriel E. Pantelias and Georgia I. Terzoudi

Subjects

G2 Phase, DNA damage, Health, Toxicology and Mutagenesis, Mitosis, CHO Cells, Biology, Toxicology, S Phase, Cell Fusion, Prophase, Cricetinae, Genetics, Animals, Humans, Radiosensitivity, Lymphocytes, Genetics (clinical), Chromosome Aberrations, X-Rays, Cell Cycle, G1 Phase, Temperature, Cell cycle, Molecular biology, Chromatin, Premature chromosome condensation, Culture Media, Conditioned, Chromatid, DNA Damage

Abstract

Cell fusion, premature chromosome condensation (PCC) and conventional cytogenetics were used to test whether the biochemical process of chromatin condensation-decondensation throughout the cell cycle, which depends on cyclin-regulated histone H1 kinase activity, affects the conversion of DNA damage into chromosome damage and determines intrinsic cell cycle-stage radiosensitivity. Results from three sets of experiments are presented. Irradiated G 0 human lymphocytes were fused to exponentially growing hamster cells and time allowed for repair, while following the hamster cells in their progress towards mitosis. Severe fragmentation was observed in the induced lymphocyte PCCs when hamster cells entered mitosis 13 h after irradiation, suggesting conversion of DNA damage into non-repairable chromosome damage during G 1 / S transition. When PCC was used to analyse chromosome damage directly in G 0 and G 2 phase lymphocytes, the induction of breaks per cell per chromatid per Gy was found to be similar, suggesting that G 2 increased radiosensitivity is related to chromatin condensation occurring during G 2 /M transition and not to an inherent chromatin structure at this phase. When chromatin condensation-decondensation at the G 1 /S and G 2 /M transitions was modified after irradiation by using conditioned media or elevated temperature (40°C), a dramatic change in the yield and the type of chromosomal aberrations was observed. All results obtained were consistent with the proposed hypothesis. They may be also helpful in the characterization of a DNA-chromosome damage conversion process which could give a biochemical explanation of the variability in radiosensitivity observed at the various stages of the cell cycle as well as among mutant cells and cells of different origin. The proposed conversion process is cell cycle-regulated and, therefore, subject to up-regulation or down-regulation following mutagen exposure and genetic alterations.

Published

1997

4. Pre-irradiation exposure of peripheral blood lymphocytes to glutaraldehyde induces radiosensitization by increasing the initial yield of radiation-induced chromosomal aberrations.

Author

Vasiliki I. Hatzi, Georgia I. Terzoudi, Vasilios Makropoulos, Constantinos Maravelias, and Gabriel E. Pantelias

Subjects

*IRRADIATION, *LYMPHOCYTES, *CHEMICALS, *CHROMOSOME abnormalities

Abstract

Glutaraldehyde (GA) is a high production volume chemical that is very reactive with a wide spectrum of medical, scientific and industrial applications. Since human exposure in anthropogenic and occupational environment occurs frequently, GA has been extensively tested for genotoxic activity in vitro and in vivo. However, there are conflicting results in the literature and there is a lack of information concerning the combined effects of exposure to both GA and ionizing radiation in human cells. In the present study, the results obtained using conventional cytogenetic analysis do not suggest a statistically significant clastogenic or genotoxic activity of GA when concentrations in the range of 10−6 to 10−2 mM were applied. However, a 24-h pre-irradiation exposure of human peripheral blood lymphocytes (PBLs) to non-genotoxic doses of GA showed a statistically significant (P > 0.05) increase in chromosomal radiosensitivity. The observed increase may be an effect of GA-induced alterations in the cell-cycle and feedback control mechanisms during the cell-cycle transition points or it may be a consequence of an effect of GA either on the DNA repair capacity of the cells after irradiation or on the initial induction of radiation-induced chromosomal damage. To elucidate the mechanism underlying the obtained radiosensitization, conventional cytogenetics, the G2 chromosomal radiosensitivity assay and premature chromosome condensation methodologies were applied. The results support the hypothesis that pre-irradiation exposure of PBLs to GA induces radiosensitization by increasing the initial yield of chromosomal aberrations following irradiation. [ABSTRACT FROM AUTHOR]

Published

2008