Maria Widel

Modifying effect of vitamins C, E and beta-carotene against gamma-ray-induced DNA damage in mouse cells

The modifying effect of treatment with vitamins C, E and beta-carotene on the clastogenic activity of gamma rays was investigated in mice. Damage in vivo was measured by the micronucleus assay in bone marrow polychromatic erythrocytes and exfoliated bladder cells. The vitamins were administered orally, either for five consecutive days before or immediately after irradiation with 2 Gy of gamma rays. The results show that pretreatment with vitamin E (100-200 mg/kg/day) and beta-carotene (3-12 mg/kg/day) were effective in protecting against micronucleus induction by gamma rays. Vitamin C depending on its concentration enhanced the radiation effect (400 mg/kg/day), or reduced the number of micronucleated polychromatic erythrocytes (50-100 mg/kg/day). Such effect was weekly observed in exfoliated bladder cells. The most effective protection in both tissues was noted when a mixture of these vitamins was used as a pretreatment. Administration of the all antioxidant vitamins to mice immediately after irradiation was also effective in reducing the radiation-induced micronucleus frequency. The data from the in vitro experiments based on the comet assay show that the presence of the vitamins in culture medium influences the kinetic of repair of radiation-induced DNA damage in mouse leukocytes.

Ionizing radiation-induced bystander effects, potential targets for modulation of radiotherapy

Cells exposed to ionizing radiation show DNA damage, apoptosis, chromosomal aberrations or increased mutation frequency and for a long time it was generally accepted that these effects resulted from ionization of cell structures and the action of reactive oxygen species formed by water radiolysis. In the last few years, however, it has appeared that cells exposed to ionizing radiation and other genotoxic agents can release signals that induce very similar effects in non-targeted neighboring cells, phenomena known as bystander effects. These signals are transmitted to the neighboring non-hit cells by intercellular gap-junction communication or are released outside the cell, in the case of cultured cells into the medium. The signaling is mutual, and irradiated cells can also receive signals from non-irradiated neighbors. Most experiments show a decrease in survival of unirradiated bystander cells, but some studies of the influence of unirradiated or low dose-irradiated cells on those irradiated with higher doses show that intercellular bystander signaling can also increase the survival of irradiated cell populations. In the last few years, communication between irradiated and non-irradiated cells has attracted interest in many studies as a possible target for modulation of radiotherapy. Understanding the mechanisms underlying bystander effects is important for radiation risk assessment and for evaluation of protocols for cancer radiotherapy. In this review we describe different aspects of ionizing radiation-induced bystander effects: experimental examples, types of DNA damage, situations in vivo, and their possible role in adaptive response to irradiation, and we discuss their possible significance for anticancer therapy.

Radiation-induced micronucleus frequency in peripheral blood lymphocytes is correlated with normal tissue damage in patients with cervical carcinoma undergoing radiotherapy.

Abstract Widel, M., Jedrus, S., Lukaszczyk, B., Raczek-Zwierzycka, K. and Swierniak, A. Radiation-Induced Micronucleus Frequency in Peripheral Blood Lymphocytes is Correlated with Normal Tissue Damage in Patients with Cervical Carcinoma Undergoing Radiotherapy. Radiat. Res. 159, 713–721 (2003). In an effort to find a test to predict the response of normal tissue to radiotherapy, the lymphocyte micronucleus assay was used on blood samples from patients with cervical carcinoma. Peripheral blood samples from 55 patients with advanced-stage (II B–IV B) cervical carcinoma were obtained before radiotherapy. The patients were treated with external-beam radiotherapy followed by high-dose-rate brachytherapy. Acute and late normal tissue reactions were scored and correlated with the micronucleus frequency in lymphocytes after irradiation with 4 Gy in vitro. Great interindividual variability was observed in the radiation-induced lymphocyte micronucleus frequency, especially at 4 Gy. The mean number of micronuclei per 100 binucleated cells in cells irradiated with 4 Gy in vitro was significantly higher in samples from patients who suffered from acute and/or late normal tissue reactions than in those from patients with no reactions (51.0 ± 17.7 and 29.6 ± 10.1, respectively). A significant correlation was also found between the micronucleus frequency at 4 Gy and the severity of acute reactions and late reactions. However, the overlap between the micronucleus frequencies of patients with high-grade late normal tissue reactions and low-grade reactions is too great to recommend the micronucleus assay in its present form for routine clinical application.

Induction of bystander effects by UVA, UVB, and UVC radiation in human fibroblasts and the implication of reactive oxygen species

Radiation-induced bystander effects are various types of responses displayed by nonirradiated cells induced by signals transmitted from neighboring irradiated cells. This phenomenon has been well studied after ionizing radiation, but data on bystander effects after UV radiation are limited and so far have been reported mainly after UVA and UVB radiation. The studies described here were aimed at comparing the responses of human dermal fibroblasts exposed directly to UV (A, B, or C wavelength range) and searching for bystander effects induced in unexposed cells using a transwell co-incubation system. Cell survival and apoptosis were used as a measure of radiation effects. Additionally, induction of senescence in UV-exposed and bystander cells was evaluated. Reactive oxygen species (ROS), superoxide radical anions, and nitric oxide inside the cells and secretion of interleukins 6 and 8 (IL-6 and IL-8) into the medium were assayed and evaluated as potential mediators of bystander effects. All three regions of ultraviolet radiation induced bystander effects in unexposed cells, as shown by a diminution of survival and an increase in apoptosis, but the pattern of response to direct exposure and the bystander effects differed depending on the UV spectrum. Although UVA and UVB were more effective than UVC in generation of apoptosis in bystander cells, UVC induced senescence both in irradiated cells and in neighbors. The level of cellular ROS increased significantly shortly after UVA and UVB exposure, suggesting that the bystander effects may be mediated by ROS generated in cells by UV radiation. Interestingly, UVC was more effective at generation of ROS in bystanders than in directly exposed cells and induced a high yield of superoxide in exposed and bystander cells, which, however, was only weakly associated with impairment of mitochondrial membrane potential. Increasing concentration of IL-6 but not IL-8 after exposure to each of the three bands of UV points to its role as a mediator in the bystander effect. Nitric oxide appeared to play a minor role as a mediator of bystander effects in our experiments. The results demonstrating an increase in intracellular oxidation, not only in directly UV-exposed but also in neighboring cells, and generation of proinflammatory cytokines, processes entailing cell damage (decreased viability, apoptosis, senescence), suggest that all bands of UV radiation carry a potential hazard for human health, not only due to direct mechanisms, but also due to bystander effects.

Bystander normal human fibroblasts reduce damage response in radiation targeted cancer cells through intercellular ROS level modulation.

The radiation-induced bystander effect is a well-established phenomenon which results in damage in non-irradiated cells in response to signaling from irradiated cells. Since communication between irradiated and bystander cells could be reciprocal, we examined the mutual bystander response between irradiated cells and co-cultured with them non-irradiated recipients. Using a transwell culture system, irradiated human melanoma (Me45) cells were co-cultured with non-irradiated Me45 cells or normal human dermal fibroblasts (NHDF) and vice versa. The frequency of micronuclei and of apoptosis, ROS level, and mitochondrial membrane potential were used as the endpoints. Irradiated Me45 and NHDF cells induced conventional bystander effects detected as modest increases of the frequency of micronuclei and apoptosis in both recipient neighbors; the increase of apoptosis was especially high in NHDF cells co-cultured with irradiated Me45 cells. However, the frequencies of micronuclei and apoptosis in irradiated Me45 cells co-cultured with NHDF cells were significantly reduced in comparison with those cultured alone. This protective effect was not observed when irradiated melanomas were co-cultured with non-irradiated cells of the same line, or when irradiated NHDF fibroblasts were co-cultured with bystander melanomas. The increase of micronuclei and apoptosis in irradiated Me45 cells was paralleled by an increase in the level of intracellular reactive oxygen species (ROS), which was reduced significantly when they were co-cultured for 24h with NHDF cells. A small but significant elevation of ROS level in NHDF cells shortly after irradiation was also reduced by co-culture with non-irradiated NHDF cells. We propose that in response to signals from irradiated cells, non-irradiated NHDF cells trigger rescue signals, whose nature remains to be elucidated, which modify the redox status in irradiated cells. This inverse bystander effect may potentially have implications in clinical radiotherapy.

X-irradiation and bystander effects induce similar changes of transcript profiles in most functional pathways in human melanoma cells.

Unirradiated cells which neighbor cells exposed to ionizing radiation (IR) show responses termed bystander effects, including DNA damage, chromosomal instability, mutation, and apoptosis. We used genome-wide microarrays to compare the change in transcript profiles in Me45 (human melanoma) cells grown in culture medium from irradiated cells (irradiation conditioned medium, ICM) with those which occurred after IR, sampling after more than one division cycle to detect long-term changes which could be relevant in radiotherapy. Transcripts of >10,000 genes showed an increased or decreased level in both conditions using the criterion of a >+/-10% change, and >85% of these were common to growth in ICM and after IR. When these genes were grouped into metabolic pathways according to the Kyoto Encyclopedia of Genes and Genomes (KEGG), significant differences (p<0.01) were seen between the numbers of up- and down-regulated transcripts in certain groups after both ICM and IR, particularly in the groups neuroactive ligand-receptor interactions, oxidative phosphorylation, cytokine-cytokine receptor interactions, proteasomes, and ribosomes. Quantitative RT-PCR assays of transcripts of selected genes in these pathways confirmed the similar effects of growth in ICM and IR. We conclude that factors transmitted from irradiated cells can influence transcript levels in bystander cells, and that these changes persist for more than one cell cycle consistent with the long-term transmissible effects seen in progeny cells, revealing new facets of the IR-induced bystander effect.

Inverse Dose-Rate Effect for the Induction of Micronuclei in Lewis Lung Carcinoma after Exposure to Cobalt-60 Gamma Rays

Induction of micronuclei was used as a measure of the dose-rate effect in Lewis lung carcinoma in vivo. Tumors transplanted on the hind legs of male C57BL mice were irradiated at dose rates of 1 and 0.34 Gy/min, cells were isolated and cultured in vitro, and micronuclei were scored at 24-h intervals. Maximum expression of micronuclei was observed 72 h after plating. The frequency of cells containing micronuclei and the number of micronuclei per single cell were linearly dependent on dose in the range 0-6 Gy. However, a marked inverse dependence on dose rate was observed. The inverse dose-rate effectiveness factor, calculated as the ratio of damage per gray at the lower dose rate to that at the higher dose rate, was 3.25 for frequency of micronuclei and was even higher (4.57) for micronuclei per cell (P < 0.05). Since the differences in exposure time for the different dose rates are not large, our results cannot be explained by the differential effect on cell kinetics during tumor irradiation. However, it cannot be excluded that the differential effect of radiation on division delay and redistribution of cells in the phases of the cell cycle may be expressed during incubation of cells in vitro for micronucleus expression. Furthermore, it can be hypothesized that more cells may die in culture because of interphase death and apoptosis in the higher dose-rate group than in the lower dose-rate group and that these cells were not accessible for the micronucleus assay. The actual explanation for the phenomenon observed requires further experimentation.

Early peroxidising effects of myocardial damage in rats after gamma-irradiation and farmorubicin (4′-epidoxorubicin) treatment

Changes in lipid peroxide levels (TBA-RS) in rat serum and heart tissue as well as creatine kinase enzyme (CPK) activity in serum were used as early indicators of peroxidizing effects of heart damage after fractionated gamma-irradiation (4 x 5 Gy) and/or farmorubicin (4 x 2.5 mg/kg) treatment. An increase in the TBA-RS and enzyme activity was observed after the action of both agents given separately or in combination. The maximal expression of biochemical effects appeared a few days after irradiation or farmorubicin treatment. The application of the antioxidant, vitamin E, diminished the level of TBA-RS in serum and in heart homogenates plus CPK activity in serum, indicating the involvement of peroxidizing mechanisms in myocardial damage by both agents.

The influence of XPD, APE1, XRCC1, and NBS1 polymorphic variants on DNA repair in cells exposed to X-rays.

Polymorphism of genes coding for proteins which participate in DNA repair may predispose to or protect against development of cancer. Here we studied how common polymorphisms of the genes XPD (Asp312Asn and Lys751Gln), APE1 (Asp148Glu), XRCC1 (Arg399Gln), and NBS1 (Gln185Glu) influence DNA repair and other responses after X-irradiation of lymphocytes from colon carcinoma patients. Genotypes with polymorphic Asp148Glu APE1 and Asp312Asn XPD showed a significantly higher level of DNA incisions immediately after irradiation (p=0.049 and p=0.047 respectively) and Asp312Asn XPD showed a significantly increased capacity to repair of DNA strand breaks as measured 180min after irradiation by comet assays (p=0.004). In contrast, it was the wild type XRCC1 genotype which was associated with a lower level of DNA breaks after irradiation (p=0.014, at 180min after irradiation) and polymorphism of NBS1 did not correlate with any changes in DNA breaks or repair capacity. To confirm the influence of XPD polymorphism on repair, we established stably-transfected HCT116 (colon carcinoma) cells which over-expressed the wild-type or variant XPD protein. Cells over-expressing Asp312Asn XPD showed a higher level of DNA breaks shortly after irradiation and more efficient repair than cells over-expressing the wild-type gene XPD312Asp, and an earlier inhibition of cell cycle transit but faster recovery from this inhibition. Polymorphisms in DNA repair genes therefore influence not only DNA repair capacity but also cell proliferation, and may serve as markers of individual repair capacity and susceptibility to environmental and occupational carcinogens.

The different radiation response and radiation-induced bystander effects in colorectal carcinoma cells differing in p53 status.

Radiation-induced bystander effect, appearing as different biological changes in cells that are not directly exposed to ionizing radiation but are under the influence of molecular signals secreted by irradiated neighbors, have recently attracted considerable interest due to their possible implication for radiotherapy. However, various cells present diverse radiosensitivity and bystander responses that depend, inter alia, on genetic status including TP53, the gene controlling the cell cycle, DNA repair and apoptosis. Here we compared the ionizing radiation and bystander responses of human colorectal carcinoma HCT116 cells with wild type or knockout TP53 using a transwell co-culture system. The viability of exposed to X-rays (0-8 Gy) and bystander cells of both lines showed a roughly comparable decline with increasing dose. The frequency of micronuclei was also comparable at lower doses but at higher increased considerably, especially in bystander TP53-/- cells. Moreover, the TP53-/- cells showed a significantly elevated frequency of apoptosis, while TP53+/+ counterparts expressed high level of senescence. The cross-matched experiments where irradiated cells of one line were co-cultured with non-irradiated cells of opposite line show that both cell lines were also able to induce bystander effects in their counterparts, however different endpoints revealed with different strength. Potential mediators of bystander effects, IL-6 and IL-8, were also generated differently in both lines. The knockout cells secreted IL-6 at lower doses whereas wild type cells only at higher doses. Secretion of IL-8 by TP53-/- control cells was many times lower than that by TP53+/+ but increased significantly after irradiation. Transcription of the NFκBIA was induced in irradiated TP53+/+ mainly, but in bystanders a higher level was observed in TP53-/- cells, suggesting that TP53 is required for induction of NFκB pathway after irradiation but another mechanism of activation must operate in bystander cells.