Your search keyword '"Georgia I. Terzoudi"' showing total 5 results

1. Low concentrations of caffeine induce asymmetric cell division as observed in vitro by means of the CBMN-assay and iFISH

Author

Katarzyna Barszczewska, Gabriel E. Pantelias, Ioanna Karachristou, Maria Karakosta, Vasiliki I. Hatzi, and Georgia I. Terzoudi

Subjects

DNA Replication, Cell division, Cytochalasin B, Health, Toxicology and Mutagenesis, Aneuploidy, In Vitro Techniques, Biology, Andrology, chemistry.chemical_compound, Caffeine, Genetics, medicine, Lymphocytes, Interphase, Metaphase, In Situ Hybridization, Fluorescence, Micronuclei, Chromosome-Defective, Carcinogen, Chromosome Aberrations, Micronucleus Tests, Dose-Response Relationship, Drug, medicine.disease, chemistry, Micronucleus test, Chromatid, Cell Division

Abstract

The dual role of caffeine as a chromosomal damage inducer and G2/M-checkpoint abrogator is well known but it is observed mainly at relatively high concentrations. At low concentrations, caffeine enhances the cytogenetic effects of several carcinogens and its intake during pregnancy has been recently reported to cause adverse birth outcomes. Interestingly, a threshold below which this association is not apparent was not identified. Since chromosomal abnormalities and aneuploidy are the major genetic etiologies of spontaneous abortions and adverse birth outcomes, we re-evaluate here the effects of caffeine at the cytogenetic level and propose a model for the mechanisms involved. Our hypothesis is that low caffeine concentrations affect DNA replication and cause chromosomal aberrations and asymmetric cell divisions not easily detected at metaphase since damaged cells are delayed during their G2/M-phase transition and the low caffeine concentrations cannot abrogate the G2-checkpoint. To test this hypothesis, caffeine-induced chromatid breaks and micronuclei in peripheral blood lymphocytes (PBLs) were evaluated in vitro after low caffeine concentration exposures, followed by a short treatment with 4mM of caffeine to abrogate the G2-checkpoint. The results show a statistically significant increase in chromatid breaks at caffeine concentrations ≥1mM. When caffeine was applied for G2/M-checkpoint abrogation, a statistically significant increase in chromatid breaks, compared to an active checkpoint, was only observed at 4mM of caffeine. The potential of low concentrations to induce asymmetric cell divisions was tested by applying a methodology combining the cytochalasin-B mediated cytokinesis-block micronucleus assay (CBMN) with interphase FISH (iFISH), using selected centromeric probes. Interestingly, low caffeine concentrations induce a dose dependent aneuploidy through asymmetric cell divisions, which are caused by misalignment of chromosomes through a mechanism unrelated to the formation of chromatid breaks. The cytogenetic approach used, combining CBMN with iFISH, is proposed as a valuable tool to test chemically induced asymmetric cell divisions.

Published

2015

2. Curcumin and trans-resveratrol exert cell cycle-dependent radioprotective or radiosensitizing effects as elucidated by the PCC and G2-assay

Author

J. I. Villaescusa, Gabriel E. Pantelias, Alegría Montoro, Georgia I. Terzoudi, Vasiliki I. Hatzi, José Miguel Soriano, David Hervás, and Natividad Sebastià

Subjects

G2 Phase, Radiation-Sensitizing Agents, Radiosensitizer, Curcumin, Antioxidant, DNA damage, Health, Toxicology and Mutagenesis, medicine.medical_treatment, Radioprotector, Cell, Radiation-Protective Agents, CHO Cells, Biology, Radiation Tolerance, Cell Fusion, chemistry.chemical_compound, Cricetulus, Cricetinae, Stilbenes, Genetics, medicine, Animals, Humans, Radiosensitivity, Molecular Biology, Cells, Cultured, Mutagenicity Tests, Cell Cycle, Cell cycle, Chromatin Assembly and Disassembly, medicine.anatomical_structure, G2-assay, Biochemistry, chemistry, Resveratrol, Peripheral blood lymphocyte, Cancer research, trans-Resveratrol, Premature chromosome condensation

Abstract

Curcumin and trans-resveratrol are well-known antioxidant polyphenols with radiomodulatory properties, radioprotecting non-cancerous cells while radiosensitizing tumor cells. This dual action may be the result of their radical scavenging properties and their effects on cell-cycle checkpoints that are activated in response to radiation-induced chromosomal damage. It could be also caused by their effect on regulatory pathways with impact on detoxification enzymes, the up-regulation of endogenous protective systems, and cell-cycle-dependent processes of DNA damage. This work aims to elucidate the mechanisms underlying the dual action of these polyphenols and investigates under which conditions they exhibit radioprotecting or radiosensitizing properties. The peripheral blood lymphocyte test system was used, applying concentrations ranging from 1.4 to 140 mu M curcumin and 2.2 to 220 mu M trans-resveratrol. The experimental design focuses first on their radioprotective effects in non-cycling lymphocytes, as uniquely visualized using cell fusion-mediated premature chromosome condensation, excluding, thus, cell-cycle interference to repair processes and activation of checkpoints. Second, the radiosensitizing potential of these chemicals on the induction of chromatid breaks in cultured lymphocytes following G2-phase irradiation was evaluated by a standardized G2-chromosomal radiosensitivity predictive assay. This assay uses caffeine for G2-checkpoint abrogation and it was applied to obtain an internal control for radiosensitivity testing, which simulates conditions similar to those of the highly radiosensitive lymphocytes of AT patients. The results demonstrate for the first time the cell-cycle-dependent action of these polyphenols. When non-cycling cells are irradiated, the radioprotective properties of curcumin and trans-resveratrol are more prominent. However, when cycling cells are irradiated during G2-phase, the radiosensitizing features of these compounds are more pronounced. This observation offers a new biological basis for the mechanisms underlying the action of these polyphenols in cancer radiotherapy. (C) 2014 Elsevier B.V. All rights reserved.

Published

2014

3. Rapid assessment of high-dose radiation exposures through scoring of cell-fusion-induced premature chromosome condensation and ring chromosomes

Author

A.I. Lamadrid Boada, Gabriel E. Pantelias, Omar García, I. Romero Aguilera, J.E. Gonzalez Mesa, and Georgia I. Terzoudi

Subjects

Genetics, Cell fusion, Health, Toxicology and Mutagenesis, Ring chromosome, Chromosome, CHO Cells, Biology, Radiation Dosage, Molecular biology, Chromosomes, Cell Fusion, Cricetulus, Biodosimetry, Gamma Rays, Premature chromosome condensation, Animals, Humans, Ring Chromosomes, Chromatid, Lymphocytes, Mitosis, Whole blood

Abstract

Analysis of premature chromosome condensation (PCC) mediated by fusion of G0-lymphocytes with mitotic CHO cells in combination with rapid visualization and quantification of rings (PCC-Rf) is proposed as an alternative technique for dose assessment of radiation-exposed individuals. Isolated lymphocytes or whole blood from six individuals were γ-irradiated with 5, 10, 15 and 20Gy at a dose rate of 0.5Gy/min. Following either 8- or 24-h post-exposure incubation of irradiated samples at 37°C, chromosome spreads were prepared by standard PCC cytogenetic procedures. The protocol for PCC fusion proved to be effective at doses as high as 20Gy, enabling the analysis of ring chromosomes and excess PCC fragments. The ring frequencies remained constant during the 8-24-h repair time; the pooled dose relationship between ring frequency (Y) and dose (D) was linear: Y=(0.088±0.005)×D. During the repair time, excess fragments decreased from 0.91 to 0.59 chromatid pieces per Gy, revealing the importance of information about the exact time of exposure for dose assessment on the basis of fragments. Compared with other cytogenetic assays to estimate radiation dose, the PCC-Rf method has the following benefits: a 48-h culture time is not required, allowing a much faster assessment of dose in comparison with conventional scoring of dicentrics and rings in assays for chemically-induced premature chromosome condensation (PCC-Rch), and it allows the analysis of heavily irradiated lymphocytes that are delayed or never reach mitosis, thus avoiding the problem of saturation at high doses. In conclusion, the use of the PCC fusion assay in conjunction with scoring of rings in G0-lymphocytes offers a suitable alternative for fast dose estimation following accidental exposure to high radiation doses.

Published

2013

4. Mitochondria malfunctions as mediators of stem-cells’ related carcinogenesis: A hypothesis that supports the highly conserved profile of carcinogenesis

Author

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

Subjects

Mitochondrial DNA, Population, Apoptosis, Mitochondrion, Biology, medicine.disease_cause, Models, Biological, Adenosine Triphosphate, Neoplasms, Autophagy, medicine, Humans, education, education.field_of_study, Cancer, General Medicine, medicine.disease, Mitochondria, Cell biology, Cell Transformation, Neoplastic, Cancer cell, Neoplastic Stem Cells, Stem cell, Energy Metabolism, Carcinogenesis

Abstract

Cancer development is an evolutionary process that has been highly conserved among centuries within organisms. Based on this, the interest in cancer research focuses on cells, organelles and genes that possess a genetic conservatism from yeasts to human. Towards this thought, mitochondria, the highly conserved and responsible for the cellular bioenergetic activity organelles, might play crucial role in carcinogenesis. Interestingly, tumors with low bioenergetic signature have worse prognosis and show a decreased expression of ATPase protein. Furthermore, according to the stem-cell theory of carcinogenesis, aggressive tumors are characterized by an increase number of malignant stem-like cell population and their resistance to chemotherapy has been found to be mitochondrially driven. The above considerations triggered us to hypothesize that mitochondrial bioenergetic processes in stem-like cancer cells plays a crucial role in the highly conserved process of carcinogenesis. Specifically, we support that mitochondrial and/or nuclear DNA alterations that control stem cells’ ATP production drive stem cells to “immortalization” (Otto Warburg theory) that mediates cancer initiation and progression. Substantiation of our hypothesis requires evidence that: (1) alterations in mitochondria bioenergetic metabolites and enzymes encoded either from the mtDNA or the nuclear DNA are linked to human cancer and (2) mitochondrial functions are regulated by highly conserved genes involved in cancer-related cellular processes such as apoptosis, aging and autophagy. Experimental approach on how this hypothesis might be tested and promising strategies in cancer therapeutics are also discussed. In case the hypothesis of stem-cell bioenergetic malformations’ related carcinogenesis proves to be correct, it would contribute to the development of new prognostic, diagnostic and even more effective therapeutic interventions against various types of cancer.

Published

2013

5. A standardized G2-assay for the prediction of individual radiosensitivity

Author

Gabriel E. Pantelias and Georgia I. Terzoudi

Subjects

Male, DNA Repair, DNA damage, Repair Kinetics, Biology, Radiation Dosage, Radiation Tolerance, Sampling Studies, Predictive Value of Tests, Reference Values, Neoplasms, Humans, Radiology, Nuclear Medicine and imaging, Lymphocytes, Radiosensitivity, Chromosome Aberrations, Cancer predisposition, Hematology, G2 assay, G2-M DNA damage checkpoint, G2 Phase Cell Cycle Checkpoints, Clinical Practice, Oncology, Case-Control Studies, Cancer research, Female, Chromatid, DNA Damage

Abstract

Background and purpose An increased yield of chromatid breaks following G2-phase irradiation could be a marker of radiosensitivity-predisposing genes that respond to DNA damage. We have shown that the dynamic nature of chromatin–nucleoprotein complex, which is capable of rapid unfolding, disassembling, assembling and refolding, affects repair of radiation-induced DNA-lesions and causes chromatid breaks during G2-M transition in damaged DNA sites. Here, we investigate induction and repair kinetics of chromatid breaks, their potential role in radiosensitivity predisposition and a standardized G2-assay is proposed to assess individual radiosensitivity. Materials and methods Lymphocytes from 125 blood donors with significant inter-individual radiosensitivity variation (healthy, cancer, AT-patients) are used to correlate G2-checkpoint efficiency with chromatid breakage and individual radiosensitivity. Experiments involve repair kinetics of chromatid breaks using colcemid-block and treatment with caffeine to abrogate G2-checkpoint, generate internal controls and standardize the G2-assay. Results Radiation-induced chromatid breaks during G2–M transition, following 4 h repair, remained unchanged and a significant correlation between G2-chromosomal radiosensitivity and G2-checkpoint efficiency to prevent chromatid breakage was found. A standardized G2-assay is developed by introducing normalization to conditions reflecting lack of checkpoint and repair similar to those of AT-patients, generating a unique standard for individual radiosensitivity testing. Conclusions The standardized G2-assay can minimize inter-laboratory and intra-experimental variations and may have straightforward application in clinical practice for individualization of radiotherapy protocols.

Published

2011