Elevated G2 chromosomal radiosensitivity in Irish breast cancer patients: a comparison with other studies

Previous studies have shown that a significant proportion of breast cancer patients exhibit elevated G2 chromosomal radiosensitivity in contrast to controls (approximately 40%). In this study, the G2 assay was applied to a small number of Irish breast cancer patients who were recorded as sporadic cases and they were compared with a control group to compare and contrast with the previous documented studies. Lymphocyte cultures were set up on whole blood samples and stimulated with phytohaemagglutinin. The cultures were irradiated 74?h later with 0.5?Gy gamma-radiation and cells were arrested in metaphase by treating the cultures with colcemid. The chromosomes were harvested and the aberrations scored per 100 metaphases to assign a G2 score. The assay was first carried out on four donor controls to estimate intra-individual variation and then ten controls for inter-individual variation to measure assay reproducibility. The G2 assay was then applied to 27 breast cancer patients. Good intrinsic assay reproducibility was observed in the coefficient of variation (CV) data in three out of four controls. Intra-individual variation was similar in three out of four of the donors (4.6?–?5.1%) with one donor showing a higher CV compared with the others (22.9%). Inter-individual variation was calculated at 30.5% for all controls. No significant difference was observed between intra- and inter-individual variation using the variance ratio F-test. A G2 radiosensitivity cut-off of 110 aberrations/100 metaphases was calculated from the controls, and from this 70.4% of breast cancer patients and 7.7% of controls were calculated as G2 radiosensitive. This proportion of G2-sensitive breast cancer patients is the highest recorded in studies to date. It is thought that the G2 radiosensitivity assay is a biomarker of breast cancer predisposition genes of low penetrance, suggesting the presence of these genes in the Irish breast cancer patients used in this study who were recorded as sporadic cases. A larger number of Irish patients would be required to consolidate these findings and be representative of the Irish breast cancer population.     

Hypoxia-regulated p53 and its effect on radiosensitivity in cancer cells

Purpose: To determine the response of tumor suppressor p53 to hypoxia in different tumor cell lines and the involvement of p53 activity regulation in the effect of hypoxia on tumor cell sensitivity to radiation and hyperthermia.

Materials and methods: Three tumor cell lines with functional p53 were treated with chronic or cyclic hypoxia followed by radiation or hyperthermia to investigate p53 activity and cell survival. Flow cytometry was used to investigate the effect of hypoxia-induced cell cycle arrest on radiosensitivity in KHT-C (mouse fibrosarcoma) cells. Transient transfection was performed to determine the role of altered p53 activity in KHT-C and SCC VII (mouse squamous-cell carcinoma) radiosensitivity.

Results: Aerobic radiosensitivity was decreased in KHT-C and SCC VII cells after in vitro chronic or cyclic hypoxia pretreatment, but in HT1080 cells, it was slightly increased after chronic hypoxia, and was unchanged after acute hypoxia pretreatment. Decreased radiosensitivity in hypoxia-pretreated KHT-C and SCC VII cells was unlikely due to hypoxia-induced cell cycle arrest, but rather seemed to be associated with increased expression of Mdm2 (mouse double minute-2) and decreased p53. Furthermore, hypoxia pretreatment inhibited the activation of p53 by radiation. Similar results were observed in hyperthermia treated KHT-C cells. Finally, decreased radiosensitivity was observed in both KHT-C and SCC VII cells transiently transfected with Mdm2 or anti-sense p53 cDNA.

Conclusion: We demonstrated that hypoxia may decrease tumor cell radiosensitivity through the suppression of p53 activity in some tumor cell lines. These results suggested the response of p53 to hypoxia can be cell type specific and contribute to radiosensitivity of hypoxic cells.     

Static electric fields interfere in the viability of cells exposed to ionising radiation

Purpose: The interference of electric fields (EF) with biological processes is an issue of considerable interest. No studies have as yet been reported on the combined effect of EF plus ionising radiation. Here we report studies on this combined effect using the prokaryote Microcystis panniformis, the eukaryote Candida albicans and human cells.

Materials and methods: Cultures of Microcystis panniformis (Cyanobacteria) in glass tubes were irradiated with doses in the interval 0.5–5 kGy, using a ⁶⁰Co gamma source facility. Samples irradiated with 3 kGy were exposed for 2 h to a 20 V · cm^?1 static electric field and viable cells were enumerated. Cultures of Candida albicans were incubated at 36°C for 20 h, gamma-irradiated with doses from 1–4 kGy, and submitted to an electric field of 180 V · cm^?1. Samples were examined under a fluorescence microscope and the number of unviable (red) and viable (apple green fluorescence) cells was determined. For crossing-check purposes, MRC5 strain of lung cells were irradiated with 2 Gy, exposed to an electric field of 1250 V/cm, incubated overnight with the anti-body anti-phospho-histone H2AX and examined under a fluorescence microscope to quantify nuclei with γ-H2AX foci.

Results: In cells exposed to EF, death increased substantially compared to irradiation alone. In C. albicans we observed suppression of the DNA repair shoulder. The effect of EF in growth of M. panniformis was substantial; the number of surviving cells on day-2 after irradiation was 12 times greater than when an EF was applied. By the action of a static electric field on the irradiated MRC5 cells the number of nuclei with γ-H2AX foci increased 40%, approximately.

Conclusions: Application of an EF following irradiation greatly increases cell death. The observation that the DNA repair shoulder in the survival curve of C. albicans is suppressed when cells are exposed to irradiation + EF suggests that EF likely inactivate cellular recovering processes. The result for the number of nuclei with γ-H2AX foci in MRC5 cells indicates that an EF interferes mostly in the DNA repair mechanisms. A molecular ad-hoc model is proposed.     

Effect of X-irradiation on DNA-labelling in Cells Exposed during Synthesis

Summary

Bean roots were exposed to 140–2500 r x-rays aerobically during a 16–17 min immersion in a solution of thymidine labelled with ¹⁴C or ³H. There was no evidence of increase in the rate of DNA synthesis due to irradiation, nor in the number of cells which became labelled. On the contrary, radiation exposure tended to decrease both these parameters. Appreciable activity remained in the cytoplasm.

The amount of cytoplasmic activity not removed by N/1 TCA hydrolysis at 60°c was greater in irradiated than in unirradiated cells.     

Survival Curves of Glutathione Synthetase Deficient Human Fibroblasts: Correlation between Radiosensitivity in Hypoxia and Glutathione Synthetase Activity

Summary

The role of intracellular non-protein bound sulphydryl compounds (NPSH), and in particular that of glutathione (GSH), in the response of cells to ionizing radiation under different O₂ concentrations has been assessed using cell strains deficient in glutathione synthetase and exhibiting different NPSH levels. The cell strains used originated from patients with 5-oxoprolinuria and from their relatives (heterozygotes and proficient homozygotes). No correlation has been found between NPSH and GSH concentrations and radiosensitivity under oxic, aerobic and hypoxic conditions. However, a highly significant correlation has been observed between radiosensitivity under hypoxic conditions (and therefore the oxygen enhancement ratio) and the glutathione synthetase activity, suggesting that synthesis of GSH is required after irradiation. In order to explain our results we postulated, beside radical processes, the existence of a GSH-dependent enzymatic repair mechanism for N₂ type damage. Hypoxic radio-sensitivity measured with survival curves would result from the interaction of both competition and biochemical repair processes.     

Membrane Radiosensitivity of Fatty Acid Supplemented Fibroblasts as Assayed by the Loss of Intracellular Potassium

Summary

Leakage of potassium from mouse fibroblast LM cells, X-irradiated at 0°C with doses up to 400 Gy is shown to be related to plasma membrane lipid composition. Fatty acid supplemented cells, containing about 40 per cent polyunsaturated fatty acids (PUFA) in their membranes were much more sensitive to radiation, as measured by increased permeability, than normal cells, which contained 7 per cent PUFA. The damage observed after irradiation at 0°C was partially repaired during a post-irradiation incubation at 22°C. The o.e.r. for potassium leakage was about 4 for normal fibroblasts and 8 for the PUFA-supplemented cells. No oxygen-dependent radiation damage could be observed in cells treated with high amounts of vitamin E. Depletion of glutathione in PUFA cells sensitized oxic cells to radiation damage, resulting in an increase of the o.e.r. from 8 to 17. No lipid peroxidation (malondialdehyde production and disappearance of fatty acyl chains) could be demonstrated. While PUFA, normal and vitamin E grown cells showed a differential sensitivity in radiation-induced potassium leakage and trypan blue uptake (high doses, interphase death), no difference in radiation-induced clonogenic ability (reproductive death) could be observed after the different cell treatments. The experiments reported are supportive of a role of membranes in the mechanism of radiation-induced interphase death and show that increased damage may be expected when high amounts of polyunsaturated membrane lipids are present under conditions of low amounts of appropriate antioxidants.     

Lentivirus-mediated RNA interference of Ku70 to enhance radiosensitivity of human mammary epithelial cells

Purpose:?To investigate the radiosensitising effect of Ku autoantigen 70 (Ku70) and Ku autoantigen 80 (Ku80) knockdown by lentivirus-mediated RNA interference (RNAi) in the MCF10A immortalised human mammary epithelial cell line.

Materials and methods:?MCF10A cells were infected with lentiviral vectors for RNAi of Ku70. The Ku70-knockdown cell line (Ku70i) and a mock-infected control cell line (LVTHM) were used to perform radiation experiments. For the in?vitro Micronucleus (MN) assay, both cell lines were irradiated with doses of 2 and 4 Gy ⁶⁰Co γ-rays. For cell survival experiments, doses ranging between 0 and 8 Gy were used.

Results:?Western blot analysis showed that the Ku70 lentiviral vector was effective in silencing the expression of both Ku70 and Ku80. A significantly higher radiation-induced MN yield was obtained in the Ku70i cell line compared to the control LVTHM cell line. RNAi of Ku70 also resulted in a lower survival yield after irradiation compared to the control cell line. Analysis of cell death mechanisms showed that MCF10A cells (Ku70i and LVTHM) do not undergo apoptosis, but undergo post-irradiation cellular senescence.

Conclusion:?RNAi of Ku70 resulted in increased chromosomal and cellular radiosensitivity in the MCF10A human mammary cell line after irradiation with ⁶⁰Co γ-rays. These results further strengthen the role of the Ku protein in correct DNA double strand break (DSB) repair.     

Enhanced cellular radiosensitivity induced by cofilin-1 over-expression is associated with reduced DNA repair capacity

Abstract

Purpose: A previous report has indicated that over-expression of cofilin-1 (CFL-1), a member of the actin depolymerizing factor (ADF)/cofilin protein family, enhances cellular radiosensitivity. This study explores the involvement of various DNA damage responses and repair systems in the enhanced cellular radiosensitivity as well as assessing the role of CFL-1 phosphorylation in radiosensitivity.

Materials and methods: Human non-small lung cancer H1299 cells harboring a tet-on gene expression system were used to induce exogenous expression of wild-type CFL-1. Colony formation assays were used to determine cell survival after γ-ray exposure. DNA damage levels were determined by Comet assay. DNA repair capacity was assessed by fluorescence-based DNA repair analysis and antibody detection of various repair proteins. The effects of CFL-1 phosphorylation on radiation responses were explored using two mutant CFL-1 proteins, S3D and S3A. Finally, endogenous CFL-1 phosphorylation levels were investigated using latrunculin A (LA), cytochalasin B (CB) and Y27632.

Results: When phosphorylatable CFL-1 was expressed, radiosensitivity was enhanced after exposure to γ-rays and this was accompanied by DNA damage. Phosphorylated histone H2AX (γ-H2AX) and p53-binding protein-1 (53BP1) foci, as well as Chk1/2 phosphorylation, were apparently suppressed, although ataxia telangiectasia mutated (ATM) kinase activation was apparently unaffected. In addition, two radiation-induced double-strand break (DSB) repair systems, namely homologous recombination repair (HRR) and non-homologous end joining (NHEJ), were suppressed. Moreover, over-expression of CFL-1 S3D and CFL-1 S3A both enhanced radiosensitivity. However, enhanced radiosensitivity and reduced γ-H2AX expression were only detected in cells treated with LA which increased endogenous phospho-CFL-1, and not in cells treated with Y27632, which dephosphorylates CFL-1.

Conclusion: CFL-1 over-expression enhances radiosensitivity and this is associated with reduced DNA repair capacity. Although phosphorylated CFL-1 seems to be involved in radiosensitivity, further studies are required to address the importance of CFL-1 activity to the regulation of radiosensitivity.     

From radioresistance to radiosensitivity: In vitro evolution of L5178Y lymphoma

Abstract

Purpose: To discuss the possible reasons for the loss of tumourigenicity and the acquisition of new phenotypic features (among them, sensitivity to X and UVC radiations) as a result of in vitro cultivation of L5178Y lymphoma cells.

Results: Ten years ago the phenotypic differences between LY-R (original L5178Y maintained in vivo and examined in vitro) and LY-S lines were reviewed in detail by the author. The loss of tumourigenicity of LY-R cells upon in vitro cultivation accompanying the acquirement of the LY-S phenotype had been described earlier by Beer et al. (1983). In spite of their common origin, the sublines were shown to differ in their relative sensitivity to a number of DNA damaging agents and in numerous other features. Here, selected differences between LY-R and LY-S lines are briefly reviewed. It is proposed that Wallace's concept (2010a) that mitochondria are the interface between environmental conditions and the genome may explain the LY-R–LY-S conversion under prolonged in vitro cultivation.

Conclusion: The differences between the LY lines were probably of epigenetic rather than genetic character. The properties of LY-R cells changed as a result of exposure to an oxic in vitro milieu. The changes could be preconditioned by heteroplasmy and the selection of cells endowed with mitochondria best fitted to a high oxygen-low carbon dioxide environment.     

Famitinib enhances nasopharyngeal cancer cell radiosensitivity by attenuating radiation-induced phosphorylation of platelet-derived growth factor receptor and c-kit and inhibiting microvessel formation

Purpose: Famitinib is a novel tyrosine kinase inhibitor. We investigated the effects of famitinib on the radiosensitivity of human nasopharyngeal carcinoma (NPC) cell radiosensitivity in vitro and in vivo, and explored its possible mechanisms.

Materials and methods: Human nasopharyngeal carcinoma cell line (CNE-2) were treated with famitinib and radiation, and analyzed by3-(4,5-dimethylthaizol-2-yl)-2,5-diphenyltetrazolium bromide (MTT), clonogenic survival assay, and Western blot. A xenograft model using CNE-2 cells was established to analyze the effects of famitinib and radiation on tumor volume and microvessel density (MVD).

Results: Famitinib dose-dependently inhibited CNE-2 cells growth and significantly reduced clonogenic survival (p < 0.05), with a sensitivity enhancement ratio (SER) of 1.45. The tumor inhibition rate of the combined treatment group was 91%, which was significantly higher than the radiation group (35%, p < 0.05) and famitinib group (46%, p < 0.05). Famitinib attenuated radiation-induced phosphorylation of the platelet-derived growth factor receptor (PDGFR) and stem cell factor (c-kit) at 0, 30, 60 min after radiation treatment. Furthermore, radiation combined with famitinib decreased tumor MVD (p < 0.05).

Conclusions: Famitinib significantly increased CNE-2 cell radiosensitivity in vitro and in vivo by attenuating radiation-induced PDGFR and c-kit phosphorylation and by inhibiting microvessel formation.