Interrelations between the content of reactive oxygen species and the state of DNA structure in bone marrow cells of mice after whole body gamma-irradiation

The aim of the research is a further analysis of a problem concerning two (regulatory and damaging) functions of reactive oxygen species (ROS) in viability of organism cells under acute exposure to ionizing radiation. For this purpose the ROS content and the state of DNA structure in bone marrow cells of male CBA and SHK mice have been studied in dynamics, from 15 minutes up to 185 day after acute exposure to a sublethal dose (1.5 Gy) of ionizing radiation. The analysis of dependencies between these parameters in the norm, immediately after irradiation and in later cell descendants showed the direct correlation between the ROS content and the DNA nativity in the norm; 185 days after irradiation the correlation disappeared. It was suggested that the correlation occurred in the norm indicates participation of the ROS (as a sensory link) in a system of reactions (under the control of the corresponding genetic program), that ensure the DNA structure and, ultimately, the genome stability. The loss of such connection after acute exposure to ionizing radiation indicates actuation of another module of reactions sustaining stability of cellular genome in new conditions, without regulatory participation of ROS, that can promote or demonstrate the development of radiation-induced genome instability.     

Dynamic component of maintaining genomic stability in murine bone marrow cells after chronic low-intensity irradiation lasting one year

For analysis of a dynamic component state of the system of maintenance of genome stability, which represent a condition of its expression (first of all, genes of the control of phases of cell cycle, the DNA repair and redox systems) after a long chronic exposure to a small dose, the activity of replicative, reparative DNA synthesis, DNA damage as well as oxyradical content in the bone marrow cells of mice (critical for radiation effects mammalian system) after 1 year radiation exposure to a dose 63.7 cGy (0.17 cGy/day) were studied. The considerable enhancement of replicative and reparative DNA synthesis activity by 67% (p = 0.0033) and 60% (p = 0.000004) accordingly in relation to the control and some, but statistically not significant (p = 0.149) tendency to increase (by 30%) the content of a superoxide anion-radical were established. Strong and highly significant correlation (r = 0.8681; P = 0.99975) between DNA damage and O2-. content in bone marrow cells of the irradiated mices, which indicate the large DNA damage by oxiradicals, probably, due to the loss of a part of structural proteins and conformation changes in expression sites of a chromatin, were detected. The obtained results interpreted as representing the change of a dynamic component state of a system of maintenance of genome stability, the epigenic transfer of that to descendants of the irradiated cells can be the cause for formation and maintenance of radiation-induced genome instability.     

Methylation changes in muscle and liver tissues of male and female mice exposed to acute and chronic low-dose X-ray-irradiation

The biological and genetic effects of chronic low-dose radiation (LDR) exposure and its relationship to carcinogenesis have received a lot of attention in the recent years. For example, radiation-induced genome instability, which is thought to be a precursor of tumorogenesis, was shown to have a transgenerational nature. This indicates a possible involvement of epigenetic mechanisms in LDR-induced genome instability. Genomic DNA methylation is one of the most important epigenetic mechanisms. Existing data on radiation effects on DNA methylation patterns is limited, and no one has specifically studied the effects of the LDR. We report the first study of the effects of whole-body LDR exposure on global genome methylation in muscle and liver tissues of male and female mice. In parallel, we evaluated changes in promoter methylation and expression of the tumor suppressor gene p16(INKa) and DNA repair gene O(6)-methylguanine-DNA methyltransferase (MGMT). We observed different patterns of radiation-induced global genome DNA methylation in the liver and muscle of exposed males and females. We also found sex and tissue-specific differences in p16(INKa) promoter methylation upon LDR exposure. In male liver tissue, p16(INKa) promoter methylation was more pronounced than in female tissue. In contrast, no significant radiation-induced changes in p16(INKa) promoter methylation were noted in the muscle tissue of exposed males and females. Radiation also did not significantly affect methylation status of MGMT promoter. We also observed substantial sex differences in acute and chronic radiation-induced expression of p16(INKa) and MGMT genes. Another important outcome of our study was the fact that chronic low-dose radiation exposure proved to be a more potent inducer of epigenetic effects than the acute exposure. This supports previous findings that chronic exposure leads to greater genome destabilization than acute exposure.     

Signal function of the reactive oxygen species in regulatory networks of the cell reaction to damaging effects: contribution of radiosensitivity and genome instability

Reactive oxygen species (ROS) have a few possible effects, such as metabolic (participation in regulation of protein functions), damaging (oxidative damage to proteins, lipids and nucleic acids) and signal; the latter is reviewed in the article. Superoxide anion-radical (O2-.), hydroperoxide (HO2) and nitroxide (NO) are capable to act as signal substances in the cell regulatory network, which determines a mode of cell response to disturbance: proliferation pace, a course of differentiation or a start of the apoptosis program. A role of ROS in the reaction network is reviewed: importance of their content in a cell; ROS-bound signal pathways, which trigger the programs of cell reactions to stimuli; initiations of the regulatory network, which determine a content of ROS in a cell; ROS reactions with network components, which influence its functioning. A significance of the ROS-bound segment of the network, which realizes regulatory signals of the damage, in formation of radiobiological effect is estimated. The data obtained by the authors are submitted; the prospects of studing substances (such as phenozan etc.), which can actively influence redox processes, as means of modification of radiation-induced genome instability and prevention of oncogenic transformation are considered.     

The research of molecular manifestations of genome instability for individuals exposed to ionizing radiation in clinical significant doses

The oxidative status (effective contents of a superoxide anion-radical (O2*-) in assay with methyltetrazolium compound MTT and the contents of the reactive oxygen species (ROS) in assay with dichlorodihydrofluorescein diacetate (DCF-DA), the state of DNA structure and the nature of correlation connection between these indexes in cells of a peripheral blood for 26 healthy donors and 26 patients (including exposed in emergency on Chernobyl power plant), examined in many years after the radiation exposure in clinically significant doses are investigated. The method of polymerase chain reaction-single strand conformation polymorphism in the same cells out the search of mutation changes in 5-8 exons of TP53 gene for 10 patients was carried. It was established, that the state of the oxidative status for the patients is characterized by lowered (in relation to the donor control of equal age) contents O2*- in a general fraction of leucocytes and in mononuclear cells accordingly on 25% (p < 0.001) and 30% (p < 0.003) and ROS in mononuclear more, than on 40% (p < 0.008). During 5-hour incubation of cells the positive correlation connection (unidirectional changes) between indexes of DNA nativity and of oxidative status of leucocytes for 36.4% of the donors and 13.3% of the patients and in mononuclears for 38.5% of the donors and for 20% of the patients (p < 0.05) was detected. The general part of the individuals with a direct correlation in any of above named cell fractions among the donors in 2 times was higher (61.5%), than among the patients (26.7%, p = 0.038). The mutation replacements in nucleotide sequences of 5-8 exones of TP53 genes for the inspected patients were not detected. The obtained data indicate the existence of such changes in a metabolism and in systems of its regulation in nuclear blood cells after irradiation, which can be conditioned or can mirror a state of radiation-induced genome instability. The presence for the majority of the patients on the moment of the examination of several chronic diseases does not eliminate the connection of the detected biomolecular changes with these pathologies.     

DNA double-strand breaks in human lymphocytes after single irradiation by low doses of pulsed X-rays: non-linear dose-response relationship

Effects of ionizing radiation registered in cells after low dose irradiation are still poorly understood. A pulsed mode of irradiation is even more problematic in terms of predicting the radiation-induced response in cells. Thus, the aim of this paper was to study and analyze the effects of dose and frequency of pulsed X-rays on the frequency of radiation-induced DNA double-strand breaks and their repair kinetics in human peripheral blood lymphocytes in vitro. Analysis of radiation-induced gammaH2AX and 53BP1 repair foci was used to assess the DNA damage in these cells. The dose-response curve of radiation-induced foci of both proteins has shown deviations from linearity to a higher effect in the 12-32 mGy dose range and a lower effect at 72 mGy. The dose-response curve was linear at doses higher than 100 mGy. The number of radiation-induced gammaH2AX and 53BP1 foci depended on the frequency of X-ray pulses: the highest effect was registered at 13 pulses per second. Moreover, slower repair kinetics was observed for those foci induced by very low doses with a nonlinear dose-response relationship.     

The absence of the facts connected with the genomic instability after the irradiation in low doses by radiation with low LET

In the review which is a brief account of more complete document (Koterov A.N. // Int. J. Low Radiat. 2005. V. 1. No. 4. P. 376-451) the data of world researches devoted to a phenomenon of radiation-induced genomic instability (RIGI) are considered. The purpose of the review is the definition of the bottom limit of radiation doses which induced of RIGI in experiments at different methodical approaches (irradiation in vitro, in vivo, in utero, bystander effect and transgeneration effects of radiation). The action only radiation with low LET is examined. Among several hundreds works wasn't revealed any fact, when RIGI induced by low doses irradiation (up to 0.2 Gy) for normal cells and for organism left from maternal womb. Six exceptions are revealed which are named as "apparent" so in all cases the abnormal, unstable, defective objects or ambiguous final parameter were used. Thus, RIGI at low doses of radiation with low LET is a myth.     

A superoxide anion generator, pyrogallol induces apoptosis in As4.1 cells through the depletion of intracellular GSH content

We investigated the involvement of ROS such as H2O2 and O2*-, and GSH in As4.1 cell death induced by pyrogallol. The intracellular H2O2 levels were decreased or increased depending on the concentration and incubation time of pyrogallol. The levels of O2*- were significantly increased. Pyrogallol reduced the intracellular GSH content. And ROS scavengers, Tempol, Tiron, Trimetazidine and NAC could not significantly down-regulate the production of H2O2 and O2*-. However, these ROS scavengers slightly inhibited apoptosis. Interestingly, Tempol showing the recovery of GSH depletion induced by pyrogallol significantly decreased apoptosis without the significant reduction of intracellular O2*- levels. SOD and catalase did not change the level of H2O2 but decreased the level of O2*-. The inhibition of GSH depletion by these was accompanied with the decrease of apoptosis, as evidenced by sub-G1 DNA content, annexin V staining, mitochondria membrane potential (DeltaPsi(m)) and Western data. In addition, ROS scavengers and SOD did not alter a G2 phase accumulation of the cell cycle induced by pyrogallol. However, catalase changed the cell cycle distributions of pyrogallol-treated cells to those of pyrogallol-untreated cells. In summary, we have demonstrated that pyrogallol potently generates ROS, especially O2*-, in As4.1 JG cells, and Tempol, SOD and catalase could rescue to a lesser or greater extent cells from pyrogallol-induced apoptosis through the up-regulation of intracellular GSH content.     

Persistence of DNA double-strand breaks in normal human cells induced by radiation-induced bystander effect

Our previous study suggested that the DNA double-strand breaks (DSBs) induced by very low X-ray doses are largely due to bystander effects. The aim of this study was to verify whether DSBs created by radiation-induced bystander effects are likely to be repaired. We examined the generation of DSBs in cells by enumeration of phosphorylated ataxia telangiectasia mutated (ATM) foci, which are correlated with DSB repair, in normal human fibroblast cells (MRC-5) after X irradiation at doses ranging from 1 to 1000 mGy. At 24 h after irradiation, 100% (1.2 mGy), 58% (20 mGy), 12% (200 mGy) and 8.5% (1000 mGy) of the initial number of phosphorylated ATM foci were detected. The number of phosphorylated ATM foci in MRC-5 cells treated with lindane, an inhibitor of radiation-induced bystander effects, prior to X irradiation was assessed; phosphorylated ATM foci were not observed at 5 h (20 mGy) or 24 h (200 mGy) postirradiation. We also counted the number of phosphorylated ATM foci in MRC-5 cells cocultured with MRC-5 cells irradiated with 20 mGy. After 48 h of coculture, 81% of the initial numbers of phosphorylated ATM foci remained. These findings suggest that DSBs induced by the radiation-induced bystander effect persist for long periods, whereas DSBs induced by direct radiation effects are repaired relatively quickly.     

Dose-dependence, sex- and tissue-specificity, and persistence of radiation-induced genomic DNA methylation changes

Radiation is a well-known genotoxic agent and human carcinogen that gives rise to a variety of long-term effects. Its detrimental influence on cellular function is actively studied nowadays. One of the most analyzed, yet least understood long-term effects of ionizing radiation is transgenerational genomic instability. The inheritance of genomic instability suggests the possible involvement of epigenetic mechanisms, such as changes of the methylation of cytosine residues located within CpG dinucleotides. In the current study we evaluated the dose-dependence of the radiation-induced global genome DNA methylation changes. We also analyzed the effects of acute and chronic high dose (5Gy) exposure on DNA methylation in liver, spleen, and lung tissues of male and female mice and evaluated the possible persistence of the radiation-induced DNA methylation changes. Here we report that radiation-induced DNA methylation changes were sex- and tissue-specific, dose-dependent, and persistent. In parallel we have studied the levels of DNA damage in the exposed tissues. Based on the correlation between the levels of DNA methylation and DNA damage we propose that radiation-induced global genome DNA hypomethylation is DNA repair-related.     

Trans-generational radiation-induced chromosomal instability in the female enhances the action of chemical mutagens

Genomic instability can be produced by ionising radiation, so-called radiation-induced genomic instability, and chemical mutagens. Radiation-induced genomic instability occurs in both germinal and somatic cells and also in the offspring of irradiated individuals, and it is characterised by genetic changes including chromosomal rearrangements. The majority of studies of trans-generational, radiation-induced genomic instability have been described in the male germ line, whereas the authors who have chosen the female as a model are scarce. The aim of this work is to find out the radiation-induced effects in the foetal offspring of X-ray-treated female rats and, at the same time, the possible impact of this radiation-induced genomic instability on the action of a chemical mutagen. In order to achieve both goals, the quantity and quality of chromosomal damage were analysed.

In order to detect trans-generational genomic instability, a total of 4806 metaphases from foetal tissues from the foetal offspring of X-irradiated female rats (5 Gy, acute dose) were analysed. The study's results showed that there is radiation-induced genomic instability: the number of aberrant metaphases and the breaks per total metaphases studied increased and were found to be statistically significant (p ≤ 0.05), with regard to the control group.

In order to identify how this trans-generational, radiation-induced chromosomal instability could influence the chromosomal behaviour of the offspring of irradiated rat females in front of a chemical agent (aphidicolin), a total of 2481 metaphases were studied. The observed results showed that there is an enhancement of the action of the chemical agent: chromosomal breaks per aberrant metaphases show significant differences (p ≤ 0.05) in the X-ray- and aphidicolin-treated group as regards the aphidicolin-treated group.

In conclusion, our findings indicate that there is trans-generational, radiation-induced chromosomal instability in the foetal cells from X-ray-treated female rats and that this RIGI enhances the chromosomal damage caused by the chemical agent aphidicolin.     

Opposite Roles for p38MAPK-Driven Responses and Reactive Oxygen Species in the Persistence and Resolution of Radiation-Induced Genomic Instability

We report the functional and temporal relationship between cellular phenotypes such as oxidative stress, p38MAPK-dependent responses and genomic instability persisting in the progeny of cells exposed to sparsely ionizing low-Linear Energy Transfer (LET) radiation such as X-rays or high-charge and high-energy (HZE) particle high-LET radiation such as ⁵⁶Fe ions. We found that exposure to low and high-LET radiation increased reactive oxygen species (ROS) levels as a threshold-like response induced independently of radiation quality and dose. This response was sustained for two weeks, which is the period of time when genomic instability is evidenced by increased micronucleus formation frequency and DNA damage associated foci. Indicators for another persisting response sharing phenotypes with stress-induced senescence, including beta galactosidase induction, increased nuclear size, p38MAPK activation and IL-8 production, were induced in the absence of cell proliferation arrest during the first, but not the second week following exposure to high-LET radiation. This response was driven by a p38MAPK-dependent mechanism and was affected by radiation quality and dose. This stress response and elevation of ROS affected genomic instability by distinct pathways. Through interference with p38MAPK activity, we show that radiation-induced stress phenotypes promote genomic instability. In contrast, exposure to physiologically relevant doses of hydrogen peroxide or increasing endogenous ROS levels with a catalase inhibitor reduced the level of genomic instability. Our results implicate persistently elevated ROS following exposure to radiation as a factor contributing to genome stabilization.     

Copper-induced oxidative stress and antioxidant defence in Arabidopsis thaliana

Content of reactive oxygen species (ROS): O2*-, H2O2 and OH* as well as activities of antioxidant enzymes: superoxide dismutase (SOD), guaiacol peroxidase (POX) and catalase (CAT) were studied in leaves of Arabidopsis thaliana ecotype Columbia, treated with Cu excess (0, 5, 25, 30, 50, 75, 100, 150 and 300 microM). After 7 days of Cu action ROS content and the activity of SOD and POX increased, while CAT activity decreased in comparison with control. Activities of SOD, POX and CAT were correlated both with Cu concentration (0-75 microM) in the growth medium and with OH* content in leaves. Close correlation was also found between OH* content and Cu concentration. Oxidative stress in A. thaliana under Cu treatment expressed in elevated content of O2*-, H2O2 and OH* in leaves. To overcome it very active the dismutase- and peroxidase-related (and not catalase-related, as in other plants) ROS scavenging system operated in A. thaliana. Visual symptoms of phytotoxicity: chlorosis, necrosis and violet colouring of leaves as well as a reduction of shoot biomass occurred in plants.     

Radiation-induced epigenetic alterations after low and high LET irradiations

Epigenetics, including DNA methylation and microRNA (miRNA) expression, could be the missing link in understanding radiation-induced genomic instability (RIGI). This study tests the hypothesis that irradiation induces epigenetic aberrations, which could eventually lead to RIGI, and that the epigenetic aberrations induced by low linear energy transfer (LET) irradiation are different than those induced by high LET irradiations. GM10115 cells were irradiated with low LET X-rays and high LET iron (Fe) ions and evaluated for DNA damage, cell survival and chromosomal instability. The cells were also evaluated for specific locus methylation of nuclear factor-kappa B (NFκB), tumor suppressor in lung cancer 1 (TSLC1) and cadherin 1 (CDH1) gene promoter regions, long interspersed nuclear element 1 (LINE-1) and Alu repeat element methylation, CpG and non-CpG global methylation and miRNA expression levels. Irradiated cells showed increased micronucleus induction and cell killing immediately following exposure, but were chromosomally stable at delayed times post-irradiation. At this same delayed time, alterations in repeat element and global DNA methylation and miRNA expression were observed. Analyses of DNA methylation predominantly showed hypomethylation, however hypermethylation was also observed. We demonstrate that miRNA expression levels can be altered after X-ray irradiation and that these miRNA are involved in chromatin remodeling and DNA methylation. A higher incidence of epigenetic changes was observed after exposure to X-rays than Fe ions even though Fe ions elicited more chromosomal damage and cell killing. This distinction is apparent at miRNA analyses at which only three miRNA involved in two major pathways were altered after high LET irradiations while six miRNA involved in five major pathways were altered after low LET irradiations. This study also shows that the irradiated cells acquire epigenetic changes suggesting that epigenetic aberrations may arise in the cell without initiating chromosomal instability.     

Association of ionizing radiation-induced foci of NBS1 with chromosomal instability and breast cancer susceptibility

NBS1, a protein essential for DNA double-strand break repair, relocalizes into subnuclear structures upon induction of DNA damage by ionizing radiation, forming ionizing radiation-induced foci. We compared radiation-induced NBS1 foci in peripheral blood lymphocytes (PBLs) from 46 sporadic breast cancer patients and 30 healthy cancer-free volunteers. The number of persistent radiation-induced NBS1 foci per nucleus at 24 h after irradiation for patients with invasive cancer was significantly higher than for normal healthy volunteers. The frequency of spontaneous chromosome aberration increased as the number of persistent radiation-induced NBS1 foci increased, indicating that the number of persistent radiation-induced NBS1 foci might be associated with chromosome instability. There was also an inverse correlation between the number of radiation-induced NBS1 foci and the activity of DNA-dependent protein kinase (DNA-PK), which plays an important role in the nonhomologous end-joining (NHEJ) pathway, another mechanism of DNA DSB repair, indicating a close interrelationship between homologous recombination (HR) and NHEJ in DNA DSB repair. In conclusion, the number of persistent radiation-induced NBS1 foci is associated with chromosomal instability and risk of sporadic breast cancer and hence might be used to select individuals for whom a detailed examination is necessary because of their increased susceptibility to breast cancer, although refinement of the techniques for technical simplicity and accuracy will be required for clinical use.     

Molecular manifestations of radiation-induced genome instability: the possibility of chemical modification

The molecular manifestations of radiation-induced genome instability-changes of the DNA structure, the excision DNA repair and the contents of the reactive oxygen forms in bone marrow cells of the repair proficient mice (CBA) and of the repair-defective (101/H) lines in the dynamics up to 185 day after ionizing radiation exposure in the dose of 1.5 Gy were studied. Is was established, that after irradiation in bone marrow cells the descendants with the decreased activity of excision DNA repair and prone to increased changes of DNA structure DHK is arised. The injection of the phenozane in concentrations causing its receptor interaction with cells, did not defend DNA of the bone marrow cells from the radiation injury after the exposure in a sublethal dose, however it exerted influence on long-term changes. Due to the phenosane of the bone marrow cells of the irradiated mice of CBA line exhibited the larger activity in a DNA repair from damages and maintenance of vitality. The bone marrow cells of male mice of repair defective 101/H line, which phenozan was entered before the irradiation, remained unfit to the remuval of DNA damages by the repair, that probably resulted the activations of the program of the maintenance of genome constancy by the apoptosis in the cells--carriers of the structural defects and the cause of animal lethality.     

Mitochondrial dysfunction, a probable cause of persistent oxidative stress after exposure to ionizing radiation

Several recent studies have suggested that the reactive oxygen species (ROS) generated from mitochondria contribute to genomic instability after exposure of the cells to ionizing radiation, but the mechanism of this process is not yet fully understood. We examined the hypothesis that irradiation induces mitochondrial dysfunction to cause persistent oxidative stress, which contributes to genomic instability. After the exposure of cells to 5 Gy gamma-ray irradiation, we found that the irradiation induced the following changes in a clear pattern of time courses. First, a robust increase of intracellular ROS levels occurred within minutes, but the intracellular ROS disappeared within 30 min. Then the mitochondrial dysfunction was detected at 12 h after irradiation, as indicated by the decreased activity of NADH dehydrogenase (Complex I), the most important enzyme in regulating the release of ROS from the mitochondrial electron transport chain (ETC). Finally, a significant increase of ROS levels in the mitochondria and the oxidation of mitochondrial DNA were observed in cells at 24 h or later after irradiation. Although further experiments are required, results in this study support the hypothesis that mitochondrial dysfunction causes persistent oxidative stress that may contribute to promote radiation-induced genomic instability.     

Increased genomic instability in somatic cells of the progeny of female mice exposed to acute X-radiation in the preconceptional period

The level of genome instability (GI) was studied in the progeny of female mice exposed in the preconceptional period to radiation doses of 0.5, 1, and 2 Gy in comparison to that in the progeny of the same parent pairs born before irradiation of the females. To assess the level of genome instability, we analyzed polymorphism of DNA fragments from postmitotic (blood and brain) and proliferating (spleen and tail tip) tissues amplified by AP-PCR (PCR amplification with an arbitrary primer). It was found that polymorphism of the spectrum of AP-PCR products, which is a multilocus genetic marker (MGM), in the genome of somatic cells in the progeny of female mice exposed to 2 Gy was higher than in the progeny of male mice exposed to the same doses. In the progenies of female mice born before and after irradiation, tissue-specific variations in the level of DNA polymorphism were detected. The maximum value of this polymorphism (with respect to the frequency of “nonparental bands”) was determined for peripheral blood DNA in comparison with the other tissues. Estimations of the MGM polymorphism with the AP-PCR method demonstrate an increased level of genome instability in somatic cells of offsprings from female mice exposed to a single acute dose of X-rays (0.5, 1, and 2 Gy) in the preconceptional period. Radiation-induced transgenerational genome instability with an increase in the dose of preconceptional irradiation of female mice was more pronounced in DNA of the postmitotic tissues (blood and brain DNA) than in DNA of the proliferating tissues (spleen and tail tip epithelium).     

Genetic mechanisms of formation of radiation-induced instability of the genome and its transgenerational effects in the descendants of chronically irradiated individuals of Drosophila melanogaster

The article is devoted to the study of the role of intracellular mechanisms in the formation of radiation-induced genetic instability and its transgenerational effect in cells of different tissues of the descendants of Drosophila melanogaster mutant strains whose parents were exposed to chronic radiation (0.42 and 3.5 mGy/h). The level of DNA damage (alkali-labile sites (ALS), single-strand (SSB) and double-strand (DSB) breaks) in cells of somatic (nerve ganglia, imaginal discs) and generative (testis) tissues from directly irradiated animals and their unirradiated offspring was evaluated. Confident transgenerational instability (on the level of ALSs and SSBs), observed only in somatic tissues and only at the higher dose rate, is characteristic for mus209 mutant strains defective in excision repair and, less often, for mus205 and mus210 mutant strains. The greatest manifestation of radiation-induced genetic instability was found in evaluating the DSBs. Dysfunction of the genes mus205, mus304, mei-9 and mei-41, which are responsible for postreplicative repair, excision repair, recombination and control of the cell cycle, affects transgenerational changes in the somatic tissues of the offspring of parents irradiated in both low and high dose rates. In germ cells, the key role in maintaining genetic stability under chronic irradiation is played by the non-recombination postreplication repair mus101 gene. We revealed the tissue specificity of the radiation-induced effects, transgenerational transmission and accumulation of DNA damage to descendants of chronically irradiated animals.     

Activation of antioxidative enzymes induced by low-dose-rate whole-body gamma irradiation: adaptive response in terms of initial DNA damage

An adaptive response induced by long-term low-dose-rate irradiation in mice was evaluated in terms of the amount of DNA damage in the spleen analyzed by a comet assay. C57BL/ 6N female mice were irradiated with 0.5 Gy of (137)Cs gamma rays at 1.2 mGy/h; thereafter, a challenge dose (0.4, 0.8 or 1.6 Gy) at a high dose rate was given. Less DNA damage was observed in the spleen cells of preirradiated mice than in those of mice that received the challenge dose only; an adaptive response in terms of DNA damage was induced by long-term low-dose-rate irradiation in mice. The gene expression of catalase and Mn-SOD was significantly increased in the spleen after 23 days of the low-dose-rate radiation (0.5 Gy). In addition, the enzymatic activity of catalase corresponded to the gene expression level; the increase in the activity was observed at day 23 (0.5 Gy). These results suggested that an enhancement of the antioxidative capacities played an important role in the reduction of initial DNA damage by low-dose-rate radiation.