Revision of th distribution of chromosome aberrations induced by chemical mutagens using the BUDR label

Cell distribution was analysed with the help of the BrDU label for the number of chromosome aberrations and breaks induced by one-center (thiophosphamide and phosphamide) and two-center (dipine and fotrine) mutagens at the stage G0 in the Ist mitosis of human lymphocytes harvested at different times of culturing (from 56 to 96 h). The comparison was made between the type of aberration distribution in cells and the dependence of their frequency on the harvesting point for various mutagens. Poisson aberration distribution in cells for two-center mutagens was found to correspond to their constant frequency observed at different times of harvesting. On the other hand, for one-center mutagens, a geometrical distribution of chromosome breaks corresponded to an exponential decrease in their frequency in time. It is suggested that two-center chemical mutagens and ionizing radiation cause largely short-live damages which are realized into chromosome aberrations rather quickly (during one cell cycle). One-center mutagens, however, cause such damages that the probability of their transformation into chromosome aberrations is decreasing rather slowly in time, under the exponential law, and their realization into chromosome aberrations can occur in subsequent cell cycle.     

The phenomenon of adaptive response in radiobiology]

Consideration is given to various adaptive reactions to low-level radiation, their association with an absorbed dose, dose rate, radiation quality and time-interval between exposures, as well as with a cell cycle phase. Possible mechanisms of the adaptive response and the character and role of DNA damages, that can induce gene expression of the adaptive response, are discussed. The data on the influence of a preliminary long-term exposure to low-level radiation on the radiosensitivity of biological objects are analyzed with due regard for the adaptive cell response. It is concluded that the adaptive response of cells to ionizing radiation is a particular case of the phenomenon of cell adaptation to the effect of genotoxic factors of the environment.     

低水平辐射诱导的细胞遗传学适应性反应

先用0.01GY x-射线(剂量率:0.01GY/分)体外照射人、兔外周血,经不同时间后再用1.5GY X-射线(0.44GY/分)照射,发现在G_0、G_1、S和G_2期受0.01GY X-射线照射后再给大剂量照射者,其染色体畸变率明显低于单纯受1.5GY X-射线照射组(P<0.01)。这一适应性反应能持续3个细胞周期,在接受小剂量照射后超过3个细胞周期再受大剂量照射者,染色体畸变率未见减少。若在第三细胞周期以后再次给予小剂量照射,可再次诱导适应性反应。用小鼠整体小剂量照射后骨髓细胞和生殖细胞亦出现这种适应性反应。另外也探讨了不同剂量和不同剂量率的预先照射对适应性反应的影响。     

Radiation induction of delayed recombination in Schizosaccharomyces pombe

Ionizing radiation is known to induce delayed chromosome and gene mutations in the descendants of the irradiated tissue culture cells. Molecular mechanisms of such delayed mutations are yet to be elucidated, since high genomic complexity of mammalian cells makes it difficult to analyze. We now tested radiation induction of delayed recombination in the fission yeast Schizosaccharomyces pombe by monitoring the frequency of homologous recombination after X-irradiation. A reporter with 200 bp tandem repeats went through spontaneous recombination at a frequency of 1.0 x 10(-4), and the frequency increased dose-dependently to around 10 x 10(-4) at 500 Gy of X-irradiation. Although the repair of initial DNA damage was thought to be completed before the restart of cell division cycle, the elevation of the recombination frequency persisted for 8-10 cell generations after irradiation (delayed recombination). The delayed recombination suggests that descendants of the irradiated cells keep a memory of the initial DNA damage which upregulates recombination machinery for 8-10 generations even in the absence of DNA double-strand breaks (DSBs). Since radical scavengers were ineffective in inhibiting the delayed recombination, a memory by continuous production of DNA damaging agents such as reactive oxygen species (ROS) was excluded. Recombination was induced in trans in a reporter on chromosome III by a DNA DSB at a site on chromosome I, suggesting the untargeted nature of delayed recombination. Interestingly, Rad22 foci persisted in the X-irradiated population in parallel with the elevation of the recombination frequency. These results suggest that the epigenetic damage memory induced by DNA DSB upregulates untargeted and delayed recombination in S. pombe.     

Characterization of the adaptive response to ionizing radiation induced by low doses of X rays to human lymphocytes

In previous studies we have shown that low doses of radiation from incorporated tritiated thymidine can make human lymphocytes less susceptible to the genetic damage manifested as chromatid breakage induced by a subsequent high dose of X rays. We have also shown that this adaptive response to ionizing radiation can be induced by very low doses of X rays (0.01 Gy; i.e., 1 rad) delivered during S phase of the cell cycle. To see if a low dose of X rays could induce this response in cells at other phases of the cell cycle, human lymphocytes were irradiated with 0.01 or 0.05 Gy before stimulation by phytohemagglutinin (G0) or with 0.01 Gy at various times after stimulation (G1), followed by 1.5 Gy (150 rad) at G2 phase. Although G0 lymphocytes failed to exhibit an adaptive response, G1 cells irradiated as early as 4 h after stimulation did show the response. Experiments were also carried out to determine how long the adaptive response induced by 0.01 Gy could persist. A 0.01-Gy dose was delivered to lymphocytes in the first S phase, followed by 1.5 Gy in the same or subsequent cell cycles. Lymphocytes receiving a 1.5-Gy dose at 40, 48, or 66 h after stimulation exhibited an adaptive response, whereas those receiving a 1.5-Gy dose at 90 or 114 h did not. Duplicate cultures containing bromodeoxyuridine showed that at 40 h all the lymphocytes were in their first cell cycle after stimulation, at 48 h half of the lymphocytes were in their first cell cycle and half in their second, and at 66 h 80% of the lymphocytes were in their third cell cycle. Thus the adaptive response persists for at least three cell cycles after it is induced by 0.01 Gy of X rays. In other experiments, the time necessary for maximal expression of the adaptive response was determined by delivering 0.01 Gy at hourly intervals 1-6 h before the 1.5-Gy dose. While a 4-h interval was enough for expression of the adaptive response, shorter intervals were not.     

DNA damage-induced cell death： lessons from the central nervous system

DNA damage can, but does not always, induce cell death. While several pathways linking DNA damage signals to mitochondria-dependent and -independent death machineries have been elucidated, the connectivity of these pathways is subject to regulation by multiple other factors that are not well understood. We have proposed two conceptual models to explain the delayed and variable cell death response to DNA damage： integrative surveillance versus autonomous pathways. In this review, we discuss how these two models may explain the in vivo regulation of cell death induced by ionizing radiation （IR） in the developing central nervous system, where the death response is regulated by radiation dose, cell cycle status and neuronal development.     

Responses of Huntington's disease and ataxia telangiectasia lymphoblastoid cells to bleomycin

Ionizing radiation sensitive, mutant human lymphoblastoid cell lines derived from patients with Huntington's disease (HD), or ataxia telangiectasia (AT) both showed cross sensitivity to bleomycin, as assayed by reduced cell viability and increased frequency of chromosome aberrations compared to normal controls. In contrast to AT cells which failed to show inhibition of DNA synthesis after exposure to ionizing radiation, or bleomycin treatment, the sensitive cells from HD patients had depressed rates of DNA synthesis after damage with these agents, similar to that seen in normal cells. In terms of progression through the cell cycle bleomycin damaged AT cells moved from G1 into S and from S to G2 + M at almost the same rate as untreated cells. Bleomycin treated HD cells showed a large proportion of cells blocked in G1, cells were slowed down in S, the rate of entry to G2 + M was reduced and only 5% of cycling cells reached G2. Progress through the cell cycle in normal cells exposed to bleomycin showed a partial block in G1 and the rate of entry to G2 + M was reduced. These differences in response of normal, AT and HD cells to ionizing radiation and bleomycin treatment indicates that the defect underlying the sensitivity is different in HD cells from that in AT cells.     

The current status of the adaptive response to ionizing radiation in mammalian cells

The results of numerous studies indicate that cells can become refractory to the detrimental effect of ionizing radiation when previously exposed to a low, “adapting dose”;. This phenomenon has been termed an “adaptive response”; to ionizing radiation. It has been postulated that the induced radioresistance is due to the induction of DNA repair systems which efficiently protect the adapted cells from the effects of a subsequent, high “challenging dose”;. However, a direct proof of this hypothesis is still lacking. The analyzed endpoints include chromosomal aberrations, survival, mutations, genetic instability and DNA damage repair measured by the comet assay. Frequently contradictory results were published by different authors. For example some authors observed a reduced frequency of apoptosis in adapted cells, whereas others reported the opposite. The source of variablity of the adaptive response in human lymphocytes remains unresolved. While there is no doubt that an adapting dose can trigger some protecting mechanisms within the cell it appears that there is no single, universal mechanism of the adaptive response that is valid for all cell types and irradiation conditions.     

Micronucleus formation in the bone marrow cells of chronically irradiated mice with subsequent acute gamma irradiation]

With the use of the micronuclear test method it has been shown that mice preirradiated with gamma rays at a low dose rate exhibit a decreased frequency of chromosome aberrations induced in bone marrow cells by subsequent acute exposure to gamma radiation as compared to mice not subjected to preliminary irradiation. Such animals have a higher radioresistance with respect to the survival rate. The results obtained suggest the possibility of induction by ionizing radiation, at a low dose rate, of adaptive repair response at the organism level.     

Role of Mammalian Rad9 in Genomic Stability and Ionizing Radiation Response

Eukaryotic cells have evolved DNA damage response mechanisms utilizing proficient DNA repair and cell cycle checkpoints in order to maintain genomic stability. The Schizosaccharomyces pombe Rad9 gene was initially identified as encoding a cell cycle checkpoint protein. When the mammalian homologue of S. pombe Rad9 was inactivated, however, chromosomal instability was observed even in the absence of DNA damaging agents. Both an increase in chromosome end-to-end associations and telomere loss were observed in cells with inactivated mammalian Rad9. This telomere instability correlated with enhanced S- and G2-phase specific cell killing, delayed kinetics of &gamma;-H2AX foci appearance and disappearance, and reduced chromosomal repair after ionizing radiation (IR) exposure, suggesting that Rad9 plays a role in cell cycle phase specific DNA damage repair. Inactivation of mammalian Rad9 also resulted in decreased homologous recombinational (HR) repair, which occurs predominantly in the S- and G2-phase of the cell cycle. These newly defined functions of mammalian Rad9 are discussed in relation to telomere stability and HR repair as a mechanism for promoting cell survival after IR exposure.     

The role of regulatory networks of the cell response to damages in radiation effects

In view of modern knowledge and concepts about components, function and mechanisms of response of cell molecular structures to damaging effects, response which is generating specialized modules of reactions, it is shown that main components of the mechanism of maintenance of genome constancy at ionizing radiation exposure are checkpoints of cell cycle, DNA repair and apoptosis. They operate under the control of a genetic system at participation of Tp53 gene, corresponding protein and of regulatory networks formed by cascades of mitogen-activated protein kinases (MAPK). At ionizing radiation exposure the MAPK special modules participate in formation of radiation effect: ERK 1/2 (extracellular signal-regulated kinase 1 and 2), JNK/SAPK (c-Jun N-terminal kinase/stress activated protein kinase) and p38 MAPK. Executing physiological functions of maintenance of normal life activity of cells, they do not lose this capacity after exposure to ionizing radiation, participating in formation of radiation effect in a wide range of doses, and are inactivated only by exposure to very high doses. It is concluded that in light of the modern data the main problem is not a problem of mechanisms of biological effect of ionizing radiation but a problem of biological mechanisms of radiation exposure.     

Effect of low-dose radiation on repair of DNA and chromosome damage

In this report results of studies on the effect of different doses of low LET (linear energy transfer) radiations on the unscheduled DNA synthesis (UDS) and DNA polymerase activity as well as the induction of adaptive response in bone marrow cells (BMC) by low dose radiation were presented. It was found that whole-body irradiation (WBI) with X-ray doses above 0.5 Gy caused a dose-dependent depression of both UD5 and DNA polymerase activity, while low dose radiation below 250 mGy could stimulate the DNA repair synthesis and the enzyme activity. WBI of mice with low doses of X-rays in the range of 2-100 mGy at a dose rate of 57.3 mGy per minute induced an adaptive response in the BMC expressed as a reduction of chromosome aberrations following a second exposure to a larger dose (0.65 mGy). It was demonstrated that the magnitude of the adaptive response seemed to be inversely related to the induction dose. The possibility of induction of adaptive response in GO phase of the cell cycle and the possibility of a second induction of the adaptive response were discussed.     

Hypersensitivity to radiation-induced non-apoptotic and apoptotic death in cell lines from patients with the ICF chromosome instability syndrome

Immunodeficiency, centromeric region instability, and facial anomalies (ICF), a rare recessive chromosome instability syndrome, involves the loss of DNA methyltransferase 3B activity and the consequent hypomethylation of a small portion of the genome. We demonstrate for the first time that ICF cells are strongly hypersensitive to a genotoxic agent, namely, ionizing radiation. However, unlike cell lines from patients with ataxia telangiectasia or Nijmegen breakage syndrome, chromosome instability syndromes also associated with unusual sensitivity to ionizing radiation, ICF cells did not show any deficiencies in their cell cycle checkpoints. ICF lymphoblastoid cell lines demonstrated increased apoptosis, long-term cell cycle arrest, and loss of viability in clonogenicity assays after irradiation compared to analogous normal cell lines. Also, the ICF cell lines were subject to high frequencies of rapid non-apoptotic cell death upon irradiation but not to abnormally high levels of radiation-induced, cytogenetically detectable chromosome abnormalities. ICF-associated undermethylation of some regulatory gene(s) might lead to an exaggerated response to radiation-induced breaks in DNA yielding increased rates of cell death and irreversible cell cycle arrest. As a defense against their frequent spontaneous breaks in chromosomes 1 and 16, ICF patients may be abnormally prone to chromosome break-induced apoptosis, non-apoptotic cell death, and permanent cell cycle arrest so as to minimize the number of cycling cells with spontaneous rearrangements. A similarly increased cell death and cycle-arrest response to chromosome breaks due to cancer-linked DNA hypomethylation might occur during carcinogenesis.     

Aspects of the adaptive response to very low doses of radiation and other agents

When human lymphocytes and other cells are pre-exposed to very low doses of ionizing radiation and subsequently exposed to a high dose, less genetic damage, i.e., fewer chromosome aberrations, is found than is observed in cells that had not been pre-exposed. This has been termed the adaptive response and has been attributed to the induction of a repair mechanism by the low dose exposure. Several experiments have now been carried out on this adaptive response to better characterize the phenomenon. (A) Experiments with differential display of mRNAs indicate that human lymphocytes exposed to 2 cGy of X-rays have somewhat different mRNAs expressed than do unexposed cells. This is providing access to DNA that might be involved in adaptation. (B) Other experiments with embryonic cells from transgenic mice that are deficient in superoxide dismutase (SOD) have shown that the adaptive response is unrelated to the amount of SOD in the cells, and thus is independent of superoxide radicals. (C) Experiments in which very low doses of various restriction enzymes were electroporated into human lymphocytes have shown that low levels of double-strand DNA breaks alone are able to induce the adaptive response. (D) Experiments in which human male lymphocytes (XY chromosome constitution) and human female lymphocytes (XX chromosome constitution) were cocultivated have shown that adaptation is not caused by a change in the rate of cell progression to mitosis after a challenge dose, and is a further indication that cell stage sensitivity is not a factor in the adaptive response.     

Cellular responses to ionizing radiation: effects of interrupting DNA repair with chemical agents

This review is concerned with the influence of different classes of chemical agents on cellular repair of DNA damage induced by ionizing radiation. Single-strand break rejoining is little affected by inhibitors of DNA synthesis; however, such inhibitors do lead to a persistence of double-strand breaks in the DNA, and this correlates with an enhancement of chromosome aberrations and cell killing. Experiments with antagonists of topoisomerase II suggest an intriguing role for this DNA unwinding enzyme in double-strand break repair. Interference with poly(ADP-ribose) synthesis, by means of the inhibitor 3-aminobenzamide, does not have a clear-cut effect on recovery from ionizing radiation damage. Various substances (for example, caffeine and trypsin) affect DNA repair via a modulation of the cell cycle, altering the time available to the cell for repairing potentially lethal DNA damage before such damage is 'fixed' by the process of DNA replication. Finally, disturbing cellular energy metabolism, and depressing the level of ATP, can inhibit the repair of radiation damage.     

"Modeled microgravity" affects cell response to ionizing radiation and increases genomic damage

The aim of this work was to assess whether "modeled microgravity" affects cell response to ionizing radiation, increasing the risk associated with radiation exposure. Lymphoblastoid TK6 cells were irradiated with various doses of gamma rays and incubated for 24 h in a modeled microgravity environment obtained by the Rotating Wall Vessel bioreactor. Cell survival, induction of apoptosis and cell cycle alteration were compared in cells irradiated and then incubated in 1g or modeled microgravity conditions. Modulation of genomic damage induced by ionizing radiation was evaluated on the basis of HPRT mutant frequency and the micronucleus assay. A significant reduction in apoptotic cells was observed in cells incubated in modeled microgravity after gamma irradiation compared with cells maintained in 1g. Moreover, in irradiated cells, fewer G2-phase cells were found in modeled microgravity than in 1g, whereas more G1-phase cells were observed in modeled microgravity than in 1g. Genomic damage induced by ionizing radiation, i.e. frequency of HPRT mutants and micronucleated cells, increased more in cultures incubated in modeled microgravity than in 1g. Our results indicate that modeled microgravity incubation after irradiation affects cell response to ionizing radiation, reducing the level of radiation-induced apoptosis. As a consequence, modeled microgravity increases the frequency of damaged cells that survive after irradiation.     

Bcl2-independent chromatin cleavage is a very early event during induction of apoptosis in mouse thymocytes after treatment with either dexamethasone or ionizing radiation

We have quantified the emergence of early chromatin breaks during the signal transduction phase of apoptosis in mouse thymocytes after treatment with either ionizing radiation or dexamethasone. Dexamethasone at 1 microM can induce significant levels of DNA breaks (equivalent to the amount induced directly by 7.5 Gy ionizing radiation) within 0.5 h of treatment. The execution phase of apoptosis was not observed until 4-6 h after the same treatment. The presence of the Bcl2 transgene under the control of the p56lck promoter almost completely inhibited apoptosis up to 24 h after treatment, but it had virtually no effect on the early chromatin cleavage occurring in the first 6 h. Ionizing radiation induced chromatin cleavage both directly by damaging DNA and indirectly with kinetics similar to the induction of chromatin cleavage by dexamethasone. The presence of the Bcl2 transgene had no effect on the direct or indirect radiation-induced cleavage in the first 6 h, but after the first 6 h, the Bcl2 gene inhibited further radiation-induced chromatin cleavage. These results suggest that endonucleases are activated within minutes of treatment with either dexamethasone or ionizing radiation as part of the very early signal transduction phase of apoptosis, and prior to the irreversible commitment to cell death.     

Melanin decreases clastogenic effects of ionizing radiation in human and mouse somatic cells and modifies the radioadaptive response

Melanin’s influence on the chromosome aberration frequency induced by radiation in human lymphocytes and mouse bone marrow cells has been studied. We revealed earlier that melanin significantly decreases the frequencies of different radiation-induced mutations in animal germ cells. Melanin protection in somatic cells has been found to be less effective. The melanin effect in somatic cells depends on radiation dose: the lower the damage level, the better the melanin protection. In order to determine the influence of melanin at low radiation doses, the adaptive response was investigated in mouse bone marrow cells in vivo. The level of chromosome aberrations in these cells after fractionated irradiation of 0.2 Gy+1.5 Gy with a 4-h interval was about half that after a single dose of 1.7 Gy. If melanin was injected prior to irradiation, the aberration level decreased by a factor of about two in both cases. This observed result may be due to the potential radioprotective effect of melanin and to the absence of any adaptive response, whereas in the case of melanin application between the priming and challenge doses, the combined effect of the adaptive response as well as melanin protection resulted in a 4-fold decrease of chromosome aberrations. These results allow us to draw the following conclusions: adaptive response can be prevented by a radioprotector such as melanin, and melanin is capable of completely removing low-dose radiation effects. Received: 2 December 1998 / Accepted in revised form: 15 September 1999