Chromosome aberrations in human lymphocytes at a various duration of cultivation after irradiation

Human peripheral blood lymphocytes were exposed to 60Co gamma-rays (a dose of 3 Gy) and cultivated during seven days in the presence of PHA and BrdU. It was shown that the metaphases of the first and second mitosises occurred during cultivation of the irradiated and unirradiated lymphocytes, being evidence about of irregularity of the coming into division of various fractions of lymphocytes. The time of cultivation did not influence a rate of aberrations in metaphases of the first and second mitosises of the irradiated lymphocytes. During the first and the subsequent mitosises the number of exchange chromosome aberrations decreased and reached a control level in metaphases of the fourth and fifth mitosises. The number of paired fragments at second and third mitosises increased a little and started to decrease only in metaphases of the fourth and fifth mitosises. The decrease in chromosome aberrations with prolongation of the cultivation of lymphocytes after irradiating is a consequence of elimination of cells with chromosome damages during sequential mitotic divisions.     

Transmission of genomic instability from a single irradiated human chromosome to the progeny of unirradiated cells

Ionizing radiation can induce chromosome instability that is transmitted over many generations after irradiation in the progeny of surviving cells, but it remains unclear why this instability can be transmitted to the progeny. To acquire knowledge about the transmissible nature of genomic instability, we transferred an irradiated human chromosome into unirradiated mouse recipient cells by microcell fusion and examined the stability of the transferred human chromosome in the microcell hybrids. The transferred chromosome was stable in all six microcell hybrids in which an unirradiated human chromosome had been introduced. In contrast, the transferred chromosome was unstable in four out of five microcell hybrids in which an irradiated human chromosome had been introduced. The aberrations included changes in the irradiated chromosome itself and rearrangements with recipient mouse chromosomes. Thus the present study demonstrates that genomic instability can be transmitted to the progeny of unirradiated cells by a chromosome exposed to ionizing radiation, implying that the instability is caused by the irradiated chromosome itself and also that the instability is induced by the nontargeted effect of radiation.     

Adaptive response in different mitotic cycles after irradiation

The frequency of cells with chromosome aberrations and the number of aberrations per cell have been studied by metaphase analysis in the nonirradiated progeny of irradiated human blood lymphocytes. DNA fragmentation (DNA double-stranded breaks) has been investigated by DNA comet assay. To study the adaptive response (AR), PHA-stimulated lymphocytes were irradiated by the adaptive dose (0.05 Gy) in 24 h and by challenge dose (1 Gy) in 48 h after stimulation. The first through fourth mitoses were identified by 5-bromodeoxyuridine. It was found that the frequency of chromosome aberrations and double-strand breaks were increased in all mitotic cycles after the challenge irradiation. In most individuals, the adaptive response is induced by adaptive and challenge irradiations in the first and the second mitotic cycles (48 and 72 h after stimulation, respectively); however, it is absent in the third and the fourth mitoses. In the first mitosis (1Gy in 48 h after stimulation), only chromatid aberrations are observed; chromosome aberrations were registered in subsequent mitoses. DNA comet assay showed that the adaptive response was obvious at 48–72 h, but not 96 h, after stimulation. It can be concluded that the nonirradiated progeny of irradiated lymphocytes have genomic instability. The adaptive response is manifested up to the third mitosis and is explained by the decreasing number of chromatid and chromosome aberrations and DNA fragmentation. We suppose that double-stranded DNA breaks may be damage signals for the induction of adaptive response.     

Chromosome instability revealed in children of fathers irradiated during Chernobyl accident

Four children groups with and without thyroid pathology born to fathers exposed to ionizing irradiation in 1986 during Chernobyl accident as liquidators as well as residents of territory with radioactive contamination have been cytogenetically observed. The frequency and spectrum of chromosome aberrations in peripheral blood lymphocytes have been studied using two-termed cultivation (during 48 and 144 hours). Under the short-term incubation the observed groups did not significantly differ on the mean-group integral cytogenetic parameters which corresponded to age norm, but in progeny of parents from radionuclide contaminated territory the increased level of chromosome type exchanges has been revealed. In long-termed lymphocyte cultures of children with chronic thyroiditis the significantly increased cytogenetic effects of both chromatid (single fragments) and chromosome types (abnormal monocentrics, centric rings) have been established. The data received testified the reality of the transmissible chromosome instability phenomenon in progeny of irradiated parents and confirmed the possibility of its expression in consequent mitoses.     

Chromosome aberrations in peripheral lymphocytes and radiation dose to active bone marrow in patients treated for cancer of the cervix

An international study of cervical cancer patients reported a doubling of the risk for leukemia following radiotherapy. To evaluate the extent of residual chromosome damage in circulating T-cell lymphocytes in this population, approximately 200 metaphases were examined from each of 96 irradiated and 26 nonirradiated cervical cancer patients treated more than 17 years ago (average 23 years). Radiation dose averaged over the total red bone marrow was estimated to be 8.1 Gy. The type and frequency of stable and unstable chromosome aberrations were quantified in 24,117 metaphases. Unstable aberrations did not differ significantly between irradiated and nonirradiated patients (P greater than 0.5). Stable aberrations (i.e., translocations, inversions, or chromosomes with deleted segments), however, were significantly higher among irradiated (2.8 per 100 cells) compared to nonirradiated (0.7 per 100 cells) women (P less than 10(4). The frequency of these stable aberrations was found to increase significantly with increasing dose to the bone marrow. These data indicate that a direct relationship between radiation dose and extent of damage to somatic cells persists in populations and can be detected many years after partial-body radiation exposure. The stable aberration rate in irradiated cervical cancer patients was 50 to 75% lower than those observed 25 years or more after radiation exposure in atomic bomb survivors and in ankylosing spondylitis patients treated with radiotherapy. The average marrow dose was only 1 Gy in the examined atomic bomb survivors and 3.5 Gy in the ankylosing spondylitis patients. It appears, then, that a very high dose delivered to the pelvic cavity in fractionated doses resulted in far fewer persistent stable aberrations than lower doses delivered either in acute whole-body exposure or in fractionated doses to the spinal column and sacroiliac joints. The higher radiation dose and the concentration of that dose in a smaller area of the body appear to be responsible for the lower rate of persistent aberrations observed in cervical cancer patients.     

Chromosomal changes induced by chrysotile fibres or benzo-3,4-pyrene in rat pleural mesothelial cells

The induction of chromosomal aberrations in rat pleural mesothelial cells (RPMC) following in vitro treatment with chrysotile fibres has been demonstrated. The production of chromosomal aberrations was also observed after treatment of the cells with benzo-3,4-pyrene (BP). The yield of abnormal metaphases was dose-dependent and reached 58% at a BP dose of 2 micrograms/ml. Chrysotile fibres at 7 micrograms/ml induced 21% abnormal metaphases and the frequency decreased with further increases in fibre concentration. Their decline is possibly related to a lethal effect. Chrysotile-induced chromosomal aberrations were primarily of the chromatid type and included breaks and fragments. BP induced chromosome exchanges which were not seen following chrysotile treatment. Minutes and double minutes were detected in BP-treated RPMC and occasionally found after chrysotile application. These results confirm that chrysotile fibres are clastogenic for some cultured cells and demonstrate that the fibres induce chromosome damage in target RPMC.     

Transgenerational transmission of radiation induced genomic instability

Stability of genome is one of the evolutionary important trait of cells. Various mutations (gene, chromosomal, genomic) as well as artificial manipulations with genomes (inbreeding, DNA transfection, introduction of Br-DU in DNA) cause the genetic instability. Ionizing radiation is known as the factor which induced instability of genome in late mitotic descendants of cells after in vitro and in vivo exposure. Radiation induced genetic instability can be transmitted through germline cells. On the cell level both types of radiation induced genomic instability are manifested in elevated frequency of mutations, chromosome aberrations, micronuclei, increased radiosensitivity, disappearance of adaptive response, changes in gene expression. In studies of 1970-1980 years clear evidences on the different morphological and functional injuries in tissues of irradiated organisms as well as in tissues of the progeny of exposed parents were obtained. On the organism level the instability of mitotic and of meiotic progeny of irradiated cells is resulted in increased risk of cancer and of other somatic diseases. It seems to be useful to review the earlier radiobiology literature where delayed and transgenerational effects of ionizing radiation on tissues and on organisms level were clearly shown in animals. For the estimation of pathogenic role of radiation induced genomic instability in humans, particularly in children of exposed parents the parallel study of the same human cohorts using clinical parameters and various characteristic of genomic instability seems to be very important.     

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.     

Induction of incomplete and complex chromosome aberrations by 30 kVp X rays

X rays of 26-30 kVp are routinely used for mammography screening. For radioprotection purposes, a quality factor (Q) of 1 is assumed for all photon energies, but it is thought that the relative biological effectiveness (RBE) increases as the photon energy decreases. The analysis of radiation-induced chromosome aberrations is one of the most widely used methods to study the interaction between radiation and DNA. Here we present a FISH study on metaphases from peripheral blood samples irradiated with three different X-ray energies (30, 80 and 120 kVp). The study comprises two FISH approaches: one using pantelomeric and pancentromeric probes to evaluate the induction of incomplete chromosome aberrations and the other using mFISH to evaluate the induction of complex chromosome aberrations. The results indicate that exposure to 30 kVp X rays resulted in a modest increase in the induction of incomplete elements and complex aberrations compared to 80 and 120 kVp X rays.     

Chromosome aberrations in F1 from irradiated male mice studied by their synaptonemal complexes

Possible implications of surface-spread synaptonemal complex (SC) karyotyping in analysing the causes of sterility of F1 from irradiated male mice are demonstrated in this work. After irradiation by 137Cs gamma-rays at a dose of 5 Gy the males were mated to unirradiated females and genetic analysis of fertility in the F1 progeny was carried out. Males with abnormal fertility were examined for the presence of chromosome aberrations in diakinesis-metaphase I and in pachytene by the method of surface-spread SC karyotyping. In most cases, SC karyotyping provides additional information and permits the detection and analysis of aberrations that are not revealed in diakinesis. Two reciprocal translocations, one X autosomal and one nonreciprocal translocation were discovered in five F1 males studied. It is concluded that the method is efficient in detecting translocations in pachytene in partially fertile F1 hybrids of irradiated and normal mice.     

Chromosome aberrations in relation to radiation dose following partial-body exposures in three populations

Structural chromosome aberrations were evaluated in peripheral blood samples obtained from three populations exposed to partial-body irradiation. These included 143 persons who received radiotherapy for enlarged thymus glands during infancy and 50 sibling controls; 79 persons irradiated for enlarged tonsils and 81 persons surgically treated for the same condition during childhood; and 77 women frequently exposed as young adults to fluoroscopic chest X rays during lung collapse treatment for tuberculosis (TB) and 66 women of similar ages treated for TB with other therapies. Radiation exposures occurred 30 and more years before blood was drawn. Doses to active bone marrow averaged over the entire body were 21, 6, and 14 cGy for the exposed thymic, tonsil, and TB subjects, respectively. Two hundred metaphases were scored for each subject, and the frequencies of symmetrical (stable) and asymmetrical (unstable) chromosome aberrations were quantified in 97,200 metaphases. Cells with stable aberrations were detected with greater frequency in the irradiated subjects compared with nonirradiated subjects in all three populations, and an overall test for an association between stable aberrations and partial-body ionizing radiation was highly significant (P less than 0.001). We found no evidence that radiation-induced aberrations varied by age at exposure. These data show that exposure of children or young adults to partial-body fractionated radiation can result in detectable increased frequencies of stable chromosome aberrations in circulating lymphocytes 30 years later, and that these aberrations appear to be informative as biological markers of population exposure.     

Characterization of the progeny of X-ray irradiated males from two Drosophila virilis strains differing in genetic instability.

Significant effects of X-ray treatment on the increase in the number of phenotypic variations, two visible mutations, and chromosome aberrations were found in the progeny of irradiated males from the D. virilis laboratory stock that is capable of hybrid dysgenesis syndrome induction. This effect is much more pronounced than in the progeny of irradiated males from strong wild-type strains studied. A correlation between genetic instability and chromosome radiosensitivity was outlined. The mechanism of this phenomenon and the possibilities of using the property of genome instability for the productive induction of gene and chromosome damage in radiation mutagenesis experiments are discussed.     

Investigation of radiation-induced "bystaner effect" using model of adaptive response in mixed lymphocyte culture from humans of different gender

The novel method for the investigation of radiation-induced "bystander effect" has been tested on the model of mixed lymphocyte culture from humans of different gender. The "bystander effect" was estimated by the ability of nonirradiated female/male cells to develop an adaptive response in mixed culture with irradiated at the dose 0.05 Gy of X-rays G0 lymphocytes of opposite gender. The preliminary results indicate that both irradiated lymphocytes and non-irradiated but neighbouring with pre-exposed cells are less susceptible to the genetic damages manifested as chromosome aberrations induced in G1 lymphocytes by a subsequent high dose of X-ray (1.0 Gy). Direct adaptive response as well as indirect one were expressed more obvious in female lymphocytes.     

Detection of genomic instability in offspring of male mice chronically exposed to gamma-radiation by the "adaptive response" test

The genomic instability (GI) in somatic cells of the progeny (F1 generation) of male mice chronically exposed to low-dose gamma-radiation was studied by comparative analysis of chromosome damage. BALB/C male mice exposed to 0.1 Gy (0.01 Gy/day) and 0.5 Gy (0.01 and 0.05 Gy/day) were mated with unirradiated females 15 days after irradiation. For comparison of radiosensitivity, two-month-old males, the descendants of irradiated and unirradiated animals, were subjected to irradiation with a dose of 1.5 Gy (0.47 Gy/min) from a 60Co source. GI was revealed by the standard scheme of adaptive response. The experiments indicated that, by using the test "adaptive response", it is possible to detect the transition of gamma-radiation-induced genomic instability in sex cells of male parent into somatic cells of mice (F1 generation) either from changes in radiosensitivity or by the absence of the adaptive response induced by a standard scheme.     

The analysis of chromosome lesions in lymphocytes of Hodgkin's lymphoma patients after chemotherapy and radiation therapy

The analysis of chromosome lesions in peripheral blood lymphocytes of Hodgkin's lymphoma (HL) patients after chemotherapy and chemotherapy with the subsequent course of radiation therapy is carried out. Is shown, that the mean aberration frequency was significantly higher in HL patients after chemotherapy (7.20 +/- 0.58 per 100 metaphases) than in non-treated HL patients (4.80 +/- 0.54, p < 0.01). The subsequent carrying out of radiation therapy enlarges number of chromosome aberrations on 100 metaphases up to 46.7 +/- 10.7 (p < 0.05), of which chromosome-type aberrations (43.2 +/- 10.3 on 100 metaphases) averaged 92.5%. In lymphocytes of 37 out of 43 HL antitumoral treatment patients, we found, in addition to ordinary aberrant cells, a large number of multiaberrant (MA-cells) cells, i.e. metaphases carrying multiple (at least four) chromosome-type exchange aberrations. In 30 non-treated HL patients only one MA-cell was found. From 171 MA-cells which were in 43 HL patients after antitumoral treatment, 114 MA-cells were found at inspection of 9766 diploid metaphases, and the remaining 57 MA-cells were found at inspection of 196 polyploid metaphases. The carrying out after chemotherapy of radiation therapy enlarges in lymphocytes frequency of appearance of MA-cells. The analysis of MA-cells in diploid and polyploid metaphases shown, that the MA-cells could be formed both in vivo, and in vitro in absence of influence of clastogenic factors, and could survive at least two rounds of in vitro replication.     

A comparison of chromosomal radiosensitivities of somatic cells of mouse and man.

A cell culture technique for quantitative analysis of radiation-induced chromosome aberrations in somatic cells has been developed and used for the comparison of chromosomal sensitivity of skin cells of mouse and man to 60Co-gamma-rays. This includes culture of irradiated tissues or cells in culture in arginine and isoleucine-deficient medium and subsequent refeeding with complete medium (CM). With this technique, radiation-induced chromosome aberrations can be analyzed selectively in the cells exposed in G1 phase and recovered at their first post-irradiation mitosis. When tested on the human embryonic cells, the dicentric yield was essentially the same whether they were skin cells irradiated in silu or cultured cells at various in vitro passages irradiated in vitro. In contrast, when studied in the skin cells irradiated in silu, mouse embryos and newborns were insensitive to the induction of dicentrics. In young mice on day II however, the sensitivity was at a level comparable to that in human embryonic cells and it was intermediate on day 4. Such embryonic insensitivity of the mouse cells was rapidly lost during serial transfer in vitro; and, when tested at 4th or later subculture generations, mouse and human cells were equally sensitive to the induction of dicentrics. These results suggest that the chromosomal radiosensitivity is essentially the same for mouse and human cells but can be modified by some biological factors, possibly DNA repair mechanisms, which differ between species as well as among the states of differentiation of particular cell types. Special attention was paid to the parellelism between the age-dependent changes in the chromosomal, mutational and carcinogenic radiosensitivities in the mouse. If this parallelism can be carried over to man, human pre-natal irradiation will not present any reduced genetic hazards.     

Detection of chromosomal instability in alpha-irradiated and bystander human fibroblasts

There is increasing evidence biological responses to ionizing radiation are not confined to those cells that are directly hit, but may be seen in the progeny at subsequent generations (genomic instability) and in non-irradiated neighbors of irradiated cells (bystander effects). These so called non-targeted phenomena would have significant contributions to radiation-induced carcinogenesis, especially at low doses where only a limited number of cells in a population are directed hit. Here we present data using a co-culturing protocol examining chromosomal instability in alpha-irradiated and bystander human fibroblasts BJ1-htert. At the first cell division following exposure to 0.1 and 1Gy alpha-particles, irradiated populations demonstrated a dose dependent increase in chromosome-type aberrations. At this time bystander BJ1-htert populations demonstrated elevated chromatid-type aberrations when compared to controls. Irradiated and bystander populations were also analyzed for chromosomal aberrations as a function of time post-irradiation. When considered over 25 doublings, all irradiated and bystander populations had significantly higher frequencies of chromatid aberrations when compared to controls (2-3-fold over controls) and were not dependent on dose. The results presented here support the link between the radiation-induced phenomena of genomic instability and the bystander effect.     

The mechanisms of adaptive response. Estimation of capacity of human blood lymphocytes to radiation adaptive response using different criteria

Blood lymphocytes of 15 healthy donors have been investigated for the ability to decrease their radiosensitivity after treatment with low dose irradiation named radioinduced adaptive response (AR). The unstable chromosome aberrations were used to evaluate the radiosensitivity change after irradiation of cells with low adaptive dose (5 cGy) and subsequent high challenge dose (1.0 Gy) in comparison with the effect of challenge irradiation only. Three indexes were used: the frequency of cells with aberrations in all analyzed cells (A), the number of chromosome aberrations per cell (B) and the number of chromosome aberrations per one aberrant cell (C). It has been discovered that all donors examined can be divided into four groups: 1--individuals which cells did not show AR by all indexes used; 2--individuals which cells showed AR by indexes A and B, but not C; 3--AR was demonstrated by indexes B and C; 4--AR was confirmed by all three indexes. Generally accepted repair model for AR formation explains only the case of donor groups 3 and 4, but can not explain the mechanism leading to the case of group 2. For understanding this mechanism, the distribution of metaphases by the number of chromosome aberrations per cell was analyzes for each donor. It was shown that the part of cells without aberrations in group 2 donors increased significantly after treatment with the adaptive and challenge irradiation in comparison with that after irradiation with challenge dose only. The conclusion is that in this case AR is formed as a result of change in the frequency 0 cell class--population shift. The analogous shift was observed in the distributions of metaphases for all donors of the group 4, but was absent in the group 3 donors. The data obtained suggest that AR of blood lymphocytes might be a result of several processes: activation of submutational genome damage repair; population shifts manifested by the change in the part of undamaged cells; and, possibly, activation of apoptotic cell death. The complex nature of AR affects each of radiosensitivity evaluation criteria to a different extent.     

Alpha-Particle-Induced Complex Chromosome Exchanges Transmitted through Extra-Thymic Lymphopoiesis In Vitro Show Evidence of Emerging Genomic Instability

Human exposure to high-linear energy transfer α-particles includes environmental (e.g. radon gas and its decay progeny), medical (e.g. radiopharmaceuticals) and occupational (nuclear industry) sources. The associated health risks of α-particle exposure for lung cancer are well documented however the risk estimates for leukaemia remain uncertain. To further our understanding of α-particle effects in target cells for leukaemogenesis and also to seek general markers of individual exposure to α-particles, this study assessed the transmission of chromosomal damage initially-induced in human haemopoietic stem and progenitor cells after exposure to high-LET α-particles. Cells surviving exposure were differentiated into mature T-cells by extra-thymic T-cell differentiation in vitro. Multiplex fluorescence in situ hybridisation (M-FISH) analysis of naïve T-cell populations showed the occurrence of stable (clonal) complex chromosome aberrations consistent with those that are characteristically induced in spherical cells by the traversal of a single α-particle track. Additionally, complex chromosome exchanges were observed in the progeny of irradiated mature T-cell populations. In addition to this, newly arising de novo chromosome aberrations were detected in cells which possessed clonal markers of α-particle exposure and also in cells which did not show any evidence of previous exposure, suggesting ongoing genomic instability in these populations. Our findings support the usefulness and reliability of employing complex chromosome exchanges as indicators of past or ongoing exposure to high-LET radiation and demonstrate the potential applicability to evaluate health risks associated with α-particle exposure.     

Chromosomes lacking telomeres are present in the progeny of human lymphocytes exposed to heavy ions

High-charge and energy (HZE) nuclei represent one of the main health risks for human space exploration, yet little is known about the mechanisms responsible for the high biological effectiveness of these particles. We have used in situ hybridization probes for cross-species multicolor banding (RxFISH) in combination with telomere detection to compare yields of different types of chromosomal aberrations in the progeny of human peripheral blood lymphocytes exposed to either high-energy iron ions or gamma rays. Terminal deletions showed the greatest relative variation, with many more of these types of aberrations induced after exposure to accelerated iron ions (energy 1 GeV/nucleon) compared with the same dose of gamma rays. We found that truncated chromosomes without telomeres could be transmitted for at least three cell cycles after exposure and represented about 10% of all aberrations observed in the progeny of cells exposed to iron ions. On the other hand, the fraction of cells carrying stable, transmissible chromosomal aberrations was similar in the progeny of cells exposed to the same dose of densely or sparsely ionizing radiation. The results demonstrate that unrejoined chromosome breaks are an important component of aberration spectra produced by the exposure to HZE nuclei. This finding may well be related to the ability of such energetic particles to produce untoward late effects in irradiated organisms.