Effect of cell respiration inhibitors on the formation of structural mutations in human lymphocytes irradiated at different stages of the mitotic cycle

Human lymphocytes were irradiated by 60Co gamma-rays after 0, 10, 20, 35, 45, 48 and 49.5 h of incubation. Immediately after irradiation sodium cyanide, sodium fluoride or monoiodoacetic acid was given for 2.5 h. Non-irradiated cells were subjected to the same treatments. Chromosomal aberrations were analysed in metaphase cells of the first mitosis. When administered alone, all chemicals increased the frequency of chromatid aberrations. The special analysis showed that these chemicals were not mutagens in a strict sense, as the observed increase of aberration frequency was due to inhibition of repair processes, which increased the probability of manifestation of spontaneous changes (so-called "pseudomutagenesis"). The same chemicals increased the frequency of radiation-induced aberrations during two periods of the mitotic cycle, namely, in the end of the G1 stage and in the G2 stage. It has been recently shown that the inhibitor of DNA synthesis, 5-fluorodeoxyuridine, increased the frequency of radiation-induced aberrations during the same periods. It follows that the process of repair proceeding during these periods requires both DNA synthesis and energy supply.     

Critical periods of the mitotic cycle: influence of aminopterin and thymidine on production of chromosomal aberrations by radiation in Crepis capillaris.

The influence of aminopterin (AP), tritiated thymidine ([3H] TdR) and "cold" thymidine (TdR) on production of chromosomal aberrations in meristematic cells of Crepis capillaris irradiated in different stages of the mitotic cycle with 300 rad of 63Co gamma-rays was studied. All the chemical treatments increased most of all the frequency of aberrations induced during two "critical periods" localized before the stage of DNA synthesis (fixation 9 h after irradiation) and before that of mitosis (4 h). Treatments with TdR and [3H]TdR increased most of all the frequency of chromatid aberrations when irradiation was performed in G1, and the frequency of gaps when irradiated in G2. Treatment with AP increased the yield of different types of aberration more uniformly. The modifying effect of the chemicals tested appeared to be independent of replicative synthesis. The "critical periods" are suggested to be the stages when regular "proof reading" and correction of spontaneous errors takes place [9,13]. In addition to this regular mechanism, radiation induces an "emergency" mechanism of repair. AP inhibits the mechanism of regular repair; in addition TdR and [3H] TdR suppress the lateral spread of primary injuries across the chromosome.     

Chromatid damage induced by fluorescent light during G2 phase in normal and Gardner syndrome fibroblasts. Interpretation in terms of deficient DNA repair

Skin fibroblasts from Gardner syndrome (GS) compared with those from normal donors showed a significantly higher incidence of chromatid gaps and breaks following exposure to low-intensity, cool-white fluorescent light during G2 phase of the cell cycle. Considerable evidence supports the concept that chromatid gaps and breaks seen directly after exposure to DNA-damaging agents represent unrepaired DNA single- and double-strand breaks respectively. The changes in incidence of chromatid aberrations with time after light exposure are consistent with the sequence of events known to follow DNA damage and repair. Initially, the incidence of light-induced chromatid gaps was equivalent in GS and normal fibroblasts. In the normal cells, the chromatid gaps disappeared by 1 h post-exposure, presumably as a result of efficient repair of DNA single-strand breaks. In contrast, the incidence of gaps increased in GS cells by 0.5 h followed by a decrease at 1 h and concomitant increase in chromatid breaks. It appears from these findings that the increased incidence of chromatid damage in GS fibroblasts results from deficient repair of DNA single-strand breaks which arise from incomplete nucleotide excision of DNA damage during G2 phase.     

Chromosome damage in rat pulmonary alveolar macrophages following ozone inhalation

To determine whether ozone is clastogenic at environmentally relevant exposure levels, rats were exposed for 6 h to 0.0, 0.12, 0.27, or 0.80 ppm ozone. The alveolar macrophages were isolated from animals sacrificed 28 h after the end of the exposure. The mitotic index and frequency of chromosome aberrations were determined. No change in the mitotic index was detected following 0.12 ppm ozone exposure. A significant decrease in mitotic index was observed after exposure to 0.27 ppm ozone; a significant (4-fold) increase in the frequency of dividing macrophages was detected following exposure to 0.8 ppm ozone. Only chromatid-type aberrations were observed. There was a significant increase in the frequency of cells with chromatid gaps and in the frequency of cells with chromatid deletions. Animals exposed to 0.27 ppm ozone had the highest proportion of cells with chromatid deletions (0.172) relative to background level (0.028). No exchanges or chromosome-type aberrations were detected in any of the animals. These data suggest that ozone, at relatively low levels, is clastogenic in macrophages from exposed rats.     

Radiation-induced chromosome damage in X-ray-sensitive mutants (xrs) of the Chinese hamster ovary cell line

The frequency of both spontaneous and X-ray- (95 rad) induced cytogenetical aberrations has been determined for 2 X-ray-sensitive strains (xrs-6 and xrs-7) of the Chinese hamster ovary cell line, and their wild-type parent (CHO-K1). Increased levels of spontaneous aberrations were not a general feature of the xrs strains, although xrs-7 did show a 2-fold increase in chromatid gaps. Unsynchronied populations of xrs cells, estimated to have been irradiated in late S and G2, showed a 3-5-fold increase in chromatid gaps, breaks and exchanges compared to CHO-K1. The irradiation of synchronised populations of xrs-7 and CHO-K1 in G1 demonstrated a 3-5-fold increase in chromosome breaks, gaps and exchanges in xrs-7. In addition xrs-7 displayed a large increase in chromatid-type aberrations, particularly triradials. These X-ray-sensitive strains have previously been shown to have a defect in double-strand break rejoining (Kemp et al., 1984), and an increased number of double-strand breaks (DBSs) remain in their DNA after irradiation compared to wild-type cells. The increased number of DSBs remaining in these strains 20 min after irradiation, correlates well with the increase in chromosome breaks.     

Participation of the intracellular enzymes in the control of the mutation process

Summary The influence of repair and replication on the frequency of spontaneous chromosome aberrations and of those induced by gamma-irradiation is reported.Using the technique of labelling DNA with radioactive ³H-thymidine and measuring the radioactivity of DNA isolated from embryos, the time of initiation and the duration of DNA synthesis in barley seeds was studied after the soaking of the seeds had begun. The average duration of each phase of the first DNA synthesis cycle in soaking barley seeds was found to be as follows: pre-DNA synthesis stage, 10–11 hrs; DNA synthesis stage, 8 hrs. After gamma-irradiation, the intensity of DNA synthesis decreased and the beginning of DNA synthesis was delayed.It was found that the inhibition of repair by caffeine led to an increase in the frequency of both spontaneous and induced chromosome aberrations. Caffeine enhanced several times the frequency of chromosome and chromatid aberrations at the time of the maximal activity of repair enzymes. During DNA replication, caffeine had a lower effect on the realization of premutational lesions.An inhibitor of DNA replication — hydroxyurea — had no influence on the frequency of spontaneous chromosome aberrations during the replication period, whereas after gamma-irradiation, hydroxyurea enhanced the frequency of aberrations mainly at the stage of DNA replication.The relatively small mutagenic action of both agents (caffeine and hydroxyurea) was observed during all stages of the cell cycle of germinating barley seeds.     

Chromosome radiosensitivity in 2 successive mitotic cycles of human lymphocytes

A culture of human lymphocytes was irradiated with gamma-quanta (0.5 Gy) after incubation during different time intervals, i.e. at different relative frequencies of cells in the first and second mitotic cycle. The frequency of aberrations produced in the G2 stage was analysed. The total yield of aberrations gradually increased with the increase of time lapse between the onset of cultivation and irradiation. If, however, the relative frequencies of the first and second mitoses are taken into account, it could be concluded that radiosensitivity of chromosomes remains constant in each cycle and independent from its duration. Besides, radiosensitivity of chromosomes during the second cycle is one and half times stronger, as compared to the first cycle. In accordance with the data of other authors, 5-bromodeoxyuridine has been found to significantly increase radiosensitivity.     

An investigation using inhibition of G2 repair of the molecular basis of lesions which result in chromosomal aberrations

Cultures of JU56 cells were irradiated with 2.5 Gy X-rays and 16 h later the cultures were exposed to a moderately inhibitory dose of 1-beta-D-arabinofuranosylcytosine (ara-C) or aphidicolin (APC) and to colcemid, for 2 h. The c-metaphases collected for examination had therefore been exposed to X-rays in G1 or early S, and to the repair inhibitors APC and ara-C during the latter half of G2. It was found that treatment of cells irradiated early in cell cycle, that is, in G1 and early S, with APC or ara-C in G2, (1) reduced the frequency of chromatid and chromosome exchanges below that of cells treated with X-rays alone, (2) produced no more chromatid breaks and gaps than were seen in unirradiated cells, (3) increased the number of chromosome fragments and gaps in a more than additive fashion, and (4) produced only an additive effect, by comparison with the effect of X-rays and drug given separately, on the total number of chromosomal aberrations.     

Cytogenetical characterization of Chinese hamster ovary X-ray-sensitive mutant cells xrs 5 and xrs 6. VII. Complementation analysis of X-irradiated wild-type CHO-K1 and xrs mutant cells using the premature chromosome condensation technique

The complementation effect of wild-type CHO-K1 and xrs mutants after fusion, as judged by the frequencies of X-ray-induced G1 and G2 premature chromosome condensation (PCC), was studied. For induction of PCC, X-irradiated interphase cells (G1 and G2) were fused immediately with untreated mitotic cells of the same cell line or with mitotic cells of another line. The frequencies of breaks in G1-PCC, or breaks and chromatid exchanges in G2-PCC were determined and the latter parameter was compared with the frequency of chromosomal aberrations in mitotic cells following G2 irradiation. CHO-K1 cells were capable of complementing the X-ray sensitivity of both xrs 5 and xrs 6 cells. However, full restoration of the repair defect in xrs cells could never be accomplished. The mutants failed to complement each other. In CHO-K1 cells, the incidence of chromosomal aberrations was significantly higher in G2-PCC (2.5-fold) than that observed in mitotic cells at 2.5 h after irradiation. The ratio of the induced frequency of aberrations in G2-PCC to that in mitotic cells was correlated with the degree of repair of DNA double-strand breaks (dsb) and reached almost 1 in xrs 5 cells indicating no repair. In addition the data indicated that, during the period of recovery of CHO-K1 cells, X-ray-induced breaks decreased but exchanges remained at the same level. In contrast, due to a deficiency in rejoining of dsb in xrs mutants, breaks remained open for a long period of time, allowing the formation of additional chromatid exchanges during recovery time.     

Genotoxic effect of benzene hexachloride in cultured human lymphocytes

Summary Chromosomal aberrations, sister chromatid exchanges, mitotic index and cell kinetics were observed in human peripheral lymphocytes after treatment with four different concentrations (0.0125, 0.025, 0.05 and 0.1 g/ml) of benzene hexachloride (BHC), an organochlorine pesticide. Cells were treated with BHC for 24, 48 and 72h. There was a dose-dependent increase in the frequency of chromosomal aberrations and sister chromatid exchanges. A significant decrease in mitotic index was observed at all concentrations and times of exposure. BHC did not show a significant effect on cell kinetics.     

An individual variability of the adaptive response to irradiation in human cells. Approach to its determination

On human blood lymphoxytes with micronuclei (MN) assay and cytokinetic cytochalasin block and analysis of chromosome aberrations the change of cell population composition, adaptive response (AR) and phenomenon of enhanced radiosensitivity after low dose (5 cGy) and challenge doses (1.0 Gy) have been studied. Irradiation have been carried out in G1 and G2 phases of cell cycle (24 h and 48 h after PHA stimulation). Fixation of cells have been conducted after 50 h (2 h after demecolcin adding) and 72 h (24 h after cytochalasin adding) chromosome and MN assay. Evaluation criteria were the frequency of binucleated cells with MN on 1000 binucleated cells and the frequency of cells with chromatid aberration on 100 metaphases. It was shown that cell population constitution change, AR occurring depended on the individual peculiarity. The evaluation of AR presence by the indexes of bimucleated cells with MN frequency and cells with chromatid aberrations don't coincide (coincidence is observed in 3 cases from 15). It is supposed that in G2 phase after irradiation in challenge dose the MN assay and metaphase analysis can register different cells (24 h and 2 h after mitotic block). The cell population constitution change can probably influence on the AR evaluation but in isn't the AR mechanism. The main mechanism of AR forming * the protection from the damages by different ways. AR depends on many factors, individual peculiarities observes by the use of definite evaluation criteria, in individuals with definite genetic constitution. Perhaps these considerations permit to discuss the problem of AR universality.     

Lack of synergistic effect between X-ray and UV irradiation on the frequency of chromosome aberrations in PHA-stimulated human lymphocytes in the G1 stage.

PHA-stimulated human lymphocytes in the G1 stage were irradiated with UV radiation and X-rays, and the cells were analyzed for chromosomal aberrations in the first mitotic division. The frequency of dicentric chromosomes after single X-irradiation in the G1 stage was about twice the yield in the G0 stage. No increase in the yield of dicentrics was observed after combined irradiation with UV and X-rays. This is contrary to the finding for G0 lymphocytes, where a 2-fold increase of chromosome aberrations was observed. UV irradiation of G1 lymphocytes induced chromatid-type aberrations whereas no significant yield of dicentric chromosomes was observed. This is in agreement with previous findings in Chinese hamster cells in the G1 stage [7]. Irradiation of G0 lymphocytes with UV radiation induce a low frequency of dicentric chromosomes. Thus, the present data indicate that the ratio between chromosome-type and chromatid-type aberrations is different in the G1 and G0 stages in human lymphocytes irradiated with UV radiation.     

Increase in the frequency of gamma-ray induced chromosomal aberrations in mammalian cells by post-treatment with novobiocin

The effect of novobiocin (an inhibitor of DNA topoisomerase and polymerase) on the frequency of chromosomal aberrations was examined in Chinese hamster V79 cells irradiated with gamma-rays in the plateau phase of growth and subcultured in the presence of novobiocin until the first mitosis after irradiation. Novobiocin alone affected cell survival, DNA synthesis and the mitotic frequency of unirradiated cells in a dose-dependent manner, without causing any significant increase in the frequency of chromosome- or chromatid-type aberrations. The frequency of chromosome-type aberrations induced by gamma-radiation was not influenced by novobiocin at 200 microM, but the frequency of chromosome deletions (but not rings and dicentrics) showed a two-fold increase when 300 microM novobiocin was present. Irradiation produced a low level of chromatid-type aberrations and post-treatment with novobiocin at concentrations greater than 100 microM significantly increased the frequency of chromatid gaps and breaks. The results support the idea that different radiation-induced lesions lead to chromosome- as opposed to chromatid-type aberrations.     

Effect of novobiocin on the frequencies of chromatid-type aberrations and sister-chromatid exchanges following gamma-irradiation

The effect of novobiocin on the frequencies of chromatid-type aberrations and SCEs was examined in Chinese hamster V79 cells which were exposed to gamma-rays and post-treated with novobiocin. While no chromatid aberrations were induced in the unirradiated cells by novobiocin, the frequency of SCEs was slightly increased by treatment with novobiocin alone. Irradiation of G2 cells produced multiple chromatid-type aberrations and post-treatment of the irradiated cells with novobiocin resulted in a significant increase of the aberrations, including chromatid gaps and breaks. In contrast, novobiocin failed to increase the frequency of SCEs induced by gamma-rays when the irradiated cells were post-treated with novobiocin.     

The induction of chromosomal aberrations and SCEs by visible light in combination with dyes. II. Cell cycle dependence, and the effect of hydroxyl radical scavengers during light exposure in cultures of Chinese hamster ovary cells sensitized with acridine orange

Chinese hamster ovary (CHO) cells were synchronized by mitotic shake-off, treated with the fluorochrome acridine orange (AO; 0.5 micrograms/ml), washed free of excess dye and subsequently exposed to visible light (2 X 40 W/8 Wm-2). The light exposure was performed on cells in the G1, G1/S, S or G2 phase of the cell cycle. AO + light induced high frequencies of aberration in the S phase and even higher in the G1 phase. The aberrations observed were all of the chromatid type. The chromosome-type aberrations (dicentrics, rings) obtained when cells in the G1 phase were exposed to X-rays were not found after corresponding treatments with AO + light. With the exception of an increased frequency of gaps, no chromosomal aberrations were induced in G2-phase cells. Sister-chromatid exchanges were efficiently produced by the photodynamic system in the G1, G1/S and S phase of the cell cycle. In other experiments, AO-treated unsynchronized CHO cells were exposed to light in the presence of the hydroxyl radical scavengers mannitol (100 mM) and 5-dimethyl thiourea (100 mM). In parallel experiments these scavengers were found to reduce markedly the chromosome breaking effects by X-rays but had no influence on the photodynamic induction of chromosomal alterations. The results presented show that the visible light-induced chromosomal alterations in CHO cells sensitized with the fluorochrome AO are obtained by an S-dependent mechanism. Furthermore, the results indicate that the hydroxyl free radical does not play a major role in the production of chromosomal alterations by AO + light.     

Combined action of gamma irradiation and 5-bromodeoxyuridine on human chromosomes

A combined effect has been studied of 5-bromo-deoxyuridine (BDU) and gamma-radiation on human lymphocytes at the G0 stage. BDU is shown to induce chromatid aberrations irrespective of its radiation. The frequency of chromatid aberrations rises with the BDU concentration. BDU modifies the effect of gamma-radiation on human lymphocytes at the G0 stage, increasing the number of chromosome aberrations. BDU slows down the lymphocyte cell cycle.     

Method of differential staining of sister chromatids for the study of the effects of gamma rays on the frequency of sister chromatid exchange in human lymphocytes]

Human lymphocytes were incubated during two cycles of replication in the presence of 5-bromodeoxyuridine, fixed after a 96 hours cultivation, stained with fluorescenct compound "Hoechst 33258", illuminated with sunlight and repeatedly stained with azureosine. After such a treatment, the two chromatids of metaphase chromosomes are stained with different intensity revealing numerous sister chromatid exchanges (SCE) which could be exactly recorded. In spite of the use if tge standard technique, the frequency of SCE was different in two donors. Irradiation after a 47 hours incubation (mainly G2 stage of the first cycle) increased the frequency of SCE, whereas the irradiation 2 hours before fixation (G2 stage of the second cycle) decreased it. The change of the frequence of SCE produced by irradiation was not proportional to the chromosome length.     

Analysis of the cell cycle in the root meristem of Allium cepa under the influence of ledakrin

The influence of a polish anticancer drug on the cell cycle using Allium test was studied. Methods of aceto-orcein squash slides, curve of labelled mitoses after 3H-thymidine incubation and cytophotometrics after Feulgen's reaction were employed. Ledakrin acts strongly antimitotically, but it does not block the cell cycle completely. The cytostatic activity of ledakrin results from its action on the interphase. The phases G1 and S are prolonged while M is unchanged after 6h incubation with ledakrin. During postincubation in water without ledakrin it was noted, at the beginning, that the mitotic activity decreases and it is brought about the lengthening of S and G2 phases. The duration of the cell cycle phases returns to the control level during further postincubation. The results of analysis of chromatin aberrations and the micronucleus test point to a mutagenic effect of ledakrin.     

Molecular mechanisms involved in the production of cromosomal aberrations II. Utilization of neurospora endonuclease for the study of aberration production by X-rays in G1 and G2 stages of the cell cycle

Chinese hamster ovary cells (CHO) were X-irradiated in G₁ and G₂ stages of the cell cycle and subsequently Neurospora endonuclease (NE) (E.C.3.1.4), an enzyme which is specific in cleaving single-stranded DNA, was introduced into the cells, after making the cells permeable by treatment with inactivated Sendai virus. With this treatment all classes of X-ray-induced chromatid aberrations increased in G₂ cells, whereas in G₁ cells an increase in cromosome type of aberrations was found, associated with a profound induction of chromatid type of aberrations as well. Duration of the availability of single-strand gaps for the action of NE has been studied in G₂ cells following X-irradiation and the influence of different parts of the G₂ stage on the type and frequencies of chromatid aberrations was discerned. While the increase in chromosome type of aberrations by NE in X-irradiated G₁ cells has been interpreted as due to the conversion of DNA single-strand breaks or gaps to double-strand breaks by NE, the induction of chromatid aberrations in G₁ has been assumed to be due to conversion of some of the damaged bases strand breaks by NE. Biochemical evidence is presented for the conversion by NE of DNA single-strand breaks induced by X-rays into double-strand breaks using neutral sucrose gradient centrifugation.     

Analysis of structural and numerical chromosomal aberrations at the first and second mitosis after X irradiation of two-cell mouse embryos

Two-cell mouse embryos were X-irradiated in the late G2 phase in vivo. The first and second postradiation mitoses were analyzed for chromosomal anomalies. The majority of structural aberrations visible at the first mitosis after irradiation were chromatid breaks and chromatid gaps; only a few interchanges and dicentrics were observed. The aberration frequency resulted in a dose-effect relationship which was well described by a linear model. At the second mitosis 29% of the structural aberrations of the first mitosis were counted; the aberration quality changed only slightly. It is discussed whether these aberrations are to be considered "new," "derived," or unchanged transmitted aberrations. Contrary to the results obtained after irradiation of one-cell embryos, little chromosome loss was induced by radiation in two-cell embryos.