The induction of chromatid deletions in accord with the breakage-and-reunion hypothesis.

In the present experiments it has been possible to study large numbers of X-ray induced chromatid deletions, or breads, in Chinese hamster chromosomes and to discern whether or not a sister chromatid exchange also occurs at the point of breadage. Chromatid deletions are only infrequently associated with a sister chromatid exchange. This is contrary to the expectations derived from the exchange hypothesis of Revell. Pn the basis of this hypothesis, in which chromatid deletions are considered to be incomplete exchanges that occur in the necks of little loops in the chromosomes, 40% of the chromatid breaks are expected to be associated with sister chromatid exchanges. The present data are in accord with the conclusions drawn from the earlier autoradiographic experiments of HEDDLE AND BODYCOTE, and show that chromatide breaks can be accounted for on the basis of the breakage-and reunion hypothesis, with the majority being simple breaks and some being incomplete exchanges between two such breaks.     

Analysis of the Chromosome Aberrations Induced by X-Rays in Somatic Cells of DROSOPHILA MELANOGASTER

A technique has been perfected for enabling good microscope preparations to be obtained from the larval ganglia of Drosophila melanogaster. This system was then tested with X-rays and an extensive series of data was obtained on the chromosome aberrations induced in the various stages of the cell cycle.-The analysis of the results obtained offers the following points of interest: (1) There exists a difference in radio-sensitivity between the two sexes. The females constantly display a greater frequency of both chromosome and chromatid aberrations. They also display a greater frequency of spontaneous aberrations. (2) In both sexes the overall chromosome damage is greater in cells irradiated in stages G(2) and G(1). These two peaks of greater radiosensitivity are produced by a high frequency of terminal deletions and chromatid exchanges and by a high frequency of dicentrics, respectively. (3) The aberrations are not distributed at random among the various chromosomes. On the average, the Y chromosome is found to be more resistant and the breaks are preferentially localized in the pericentromeric heterochromatin of the X chromosome and of the autosomes. (4) Somatic pairing influences the frequency and type of the chromosome aberrations induced. In this system, such an arrangement of the chromosomes results in a high frequency of exchanges and dicentrics between homologous chromosomes and a low frequency of scorable translocations. Moreover, somatic pairing, probably by preventing the formation of looped regions in the interphase chromosomes, results in the almost total absence of intrachanges at both chromosome and chromatid level.     

Cell-stage-specific enhancement by caffeine of the frequency of chromatid aberrations induced by X-rays in neural ganglia of Drosophila melanogaster

Caffeine (10(-2) M) induced a high level of chromatid aberrations in neural ganglia of third-instar larvae of Drosophila melanogaster only when it was added to cells in late G2 and mitotic prophase. No aberrations were observed after treatment in late S--middle G2 or C-mitosis. We observed that, in these stages, caffeine strongly increased X-ray-induced damage (500 R). This potentiation was quantitatively similar. But it involved all types of aberration after treatment in C-mitosis, and essentially isochromatid deletions and chromatid exchanges after treatment in S--G2. Some hypotheses are put forth to explain the possible mechanism of action of caffeine in the potentiation of X-ray-induced damage.     

Genotoxicity of barley stripe mosaic virus in infected host plants

A comparative study of the effect of barley stripe mosaic virus (BSMV) and gamma irradiation on mitotic divisions in barley (Hordeum vulgare L.) roots was performed by evaluating the mitotic index (MI), micronucleus (MN) frequency and sister chromatid exchanges (SCE). Results indicate that, similarly to gamma irradiation at doses of 100, 150 and 250 Gy, BSMV reduces the mitotic activity, increases the micronucleus frequency and the rate of SCE and promotes the formation of C-metaphases. In root meristematic cells of the three barley cultivars studied (Galactic, Sonor and Unirea), the mitotic index of infected plants was found to be 52.5, 54.48 and 64.17%, respectively, lower than the uninfected control. An increase in frequency of sister chromatid exchanges was observed in all the experimental variants. In treatments involving viral infection alone or in combination with gamma irradiation chromosomes with three and more chromatid exchanges were observed, while their percentage in the control or in treatments with gamma irradiation alone was reduced. The results of the study indicate that in plants derived from irradiated seeds, BSMV produces an effect that is correlated nonlinearly with the radiation dose applied. Cytological analysis of mitotic divisions in barley roots revealed the genotoxicity of BSMV infection.     

Differential sensitivity to X-ray of chromosomes of blood T-lymphocytes and B- and T-cell lines

Summary Normal T-lymphocytes, B-cell line (CCRF-SB) and T-cell line (CCRF-HSB-2) cells, all diploid in their chromosome constitution, were exposed in vitro to various doses of X-ray and analyzed at their first mitotic division for structural chromosome abnormalities. The irradiation effects were determined also by a viability test of the cells, using trypan blue dye. The irradiated T-cell line (CCRF-HSB-2) showed a remarkably high frequency of chromosome aberrations, including chromosome and chromatid deletions, chromatid exchanges, dicentrics, rings and acentric fragments. On the other hand, the chromosome aberrations observed in the irradiated B-cell line and normal T-lymphocytes consisted mainly of dicentrics, rings, deletions and acentric fragments; the frequency of chromosome and chromatid deletions was low as compared to that of the T-cell line. The cell viability test showed a significantly higher percent reduction of viable cells at every dose of X-ray in the irradiated T-cell line than in the B-cell line or the normal T-lymphocytes. It is possible that the increased radiosensitivity of the T-cell line is related to the original malignant nature of the cells, which originated from the lymphocytes of a patient with acute lymphoblastic leukemia. Supported in part by USPHS grants CA-14413 and CA-16935.     

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.     

Differential sensitivity to x-ray of chromosomes of blood T-lymphocytes and B-and T-cell lines.

Normal T-lymphocytes, B-cell line (CCRF-SB) and T-cell line (CCRF-HSB-2) cells, all diploid in their chromosome constitution, were exposed in vitro to various doses of X-ray and analyzed at their first mitotic division for structural chromosome abnormalities. The irradiation effects were determined also by a viability test of the cells, using trypan blue dye. The irradiated T-cell line (CCRF-HSB-2) showed a remarkably high frequency of chromosome aberrations, including chromosome and chromatid deletions, chromatid exchanges, dicentrics, rings and acentric fragments. On the other hand, the chromosome aberrations observed in the irradiated B-cell line and normal T-lymphocytes consisted mainly of dicentrics, rings, deletions and acentric fragments; the frequency of chromosome and chromatid deletions was low as compared to that of the T-cell line. The cell viability test showed a singificantly higher percent reduction of viable cells at every dose of X-ray in the irradiated T-cell line than in the B-cell line or the normal T-lymphocytes. It is possible that the increased radiosensitivity of the T-cell line is related to the original malignant nature of the cells, which originated from the lymphocytes of a patient with acute lymphoblastic leukemia.     

Induction of sister chromatid exchanges (SCE) in G0 lymphocytes by plutonium-238 alpha-particles

Irradiation of human G0 lymphocytes with plutonium-238 alpha-particles and X-rays was performed to investigate the production of sister chromatid exchanges (SCE). Alpha-particles produce a significant increase in SCE and this elevation is more significant when separated lymphocytes are irradiated. X-ray irradiation did not induce any significant increase in SCE. Therefore the relative biological effectiveness (RBE) for the induction of SCE by alpha-particles in this system is undefined and effectively infinite.     

Types and frequencies of chromosomal aberrations induced by irradiation of different parts of interphase in Crepis capillaris

Quantitative and qualitative estimates of chromosomal damage in roots of Crepis capillaris were made in metaphase cells at many time intervals after irradiation with 200 or 400 rad of ⁶⁰Co gamma-rays. The results have confirmed the general pattern described for cells of other organisms, and have revealed in addition the following new facts. (1) The formation of aberrations of chromosome and chromatid type is not determined by the time of chromosome duplication alone. (2) The relative frequencies of different types of discontinuity form peaks with the following time succession: single gaps, chromatid breaks, isolocus breaks. (3) The location of peaks does not depend on the radiation dose, and shows no correlation which the time of synthesis. (4) Irradiation of G₂ induces a significant number of chromosome-type exchanges in Crepis. (5) Higher doses of radiation in G₂ favour the formation of chromatid over chromosome exchanges and of isochromatid breaks over chromosome breaks. A new interpretation of the production of certain types of aberration is discussed.     

A cell-cycle stage-related chromosomal X-ray hypersensitivity in larval neuroblasts of Drosophila mei-9 and mei-41 mutants suggesting defective DNA double-strand break repair

We have examined the chromosomal X-ray hypersensitivity in relation to the cell cycle in larval neuroblasts of the mutagen-sensitive and excision repair-defective mutant mei-9 and of the mutagen-sensitive and post-replication repair-defective mutant mei-41 of Drosophila melanogaster. When compared to wild-type cells, cells bearing the mei-9L1 allele produced unusually high levels in particular of chromatid deletions and to a lesser extent also of isochromatid deletions, but virtually no exchange aberrations. The chromosomal hypersensitivity is apparent at M1 when cells are irradiated in S or G2 but not when irradiated in G1. On the other hand, following irradiation cells bearing the mei-41D5 allele predominantly produce chromosome deletions. Also dicentric and chromatid exchange formation is enhanced with a moderate increase in chromatid deletions. The phases of major sensitivity are the S and G1. Mei-9 and mei-41 mutants have been classified to date as proficient in DNA double-strand break repair. The data presented in this paper revealed an S-independent clastogenic hypersensitivity of mei-9 and mei-41 cells. They are interpreted as indicative evidence for the presence of impaired DNA double-strand break repair. The cell-cycle-related difference in the ratio of chromatid- versus chromosome-type deletions in both mutants suggests repair defects at partially different phases of the cell cycle in mei-9 and mei-41 mutant cells.     

Cytogenetischer Befund und Ätiologie bei Fanconi-Anämie

Summary In addition to findings in four cases of Fanconi's anemia with hexokinase deficiency recently reported we are able to show cytogenetic results in a further case without any defect in carbohydrate metabolism.Cultures were made from peripheral blood. 30% of the mitoses showed chromatid type aberrations. Although the findings in this case no. 274 proved to be similar to those of the other patients, there are some differences, however.In this case 1. the number of chromatid breaks is smaller, 2. the number of mitoses with several coincidental aberrations is lower, 3. the number of chromatid exchanges in higher and 4. mostly the reunion is the only aberration within the metaphase (7 out of 10). It is shown that most of the cells with two chromatid breaks were able to rejoin. In numerous cells with hexokinase defect, however, several breaks without any sign of rejoining were found.This means, that in case 274 the reunion system is not damaged in the same way by an unknown genetic defect as in cells with the hexokinase deficiency. This also means, that these two types of Fanconi's anemia can be detected by different cytogenetic findings. The absence of cells with accessory nuclei in the bone marrow film is discussed in this respect, too.Our suggestion is based on results of experimental cytogenetics. Different frequencies of chromatid exchanges found in experiments on the influence of chemical mutagenes and irradiation according to the special lesion on the rejoining system are discussed.

---

---

Mit Unterstützung durch die Deutsche Forschungsgemeinschaft.     

The diplochromosome of endoreduplicated cells: A new approach to highlight the mechanism of sister chromatid exchange

Chinese hamster lung embryonic cells (CL1) were treated with colchicine in order to induce endoreduplication and subsequently with mitomycin-C (MMC) to induce exchanges within the diplochromosome. The use of chromosomal differential staining through incorporation of 5-bromodeoxyuridine, resulting in only one stained chromatid, has allowed the analysis of all classes of exchanges among the four chromatids of the diplochromosome. Three classes of exchanges may occur: intradiplochromatid exchanges (ICEs) between the two inner chromatids, cousin chromatid exchanges (CCEs) between one inner and one outer chromatid, and sister chromatid exchanges (SCEs) between the two sister chromatids of the diplochromosome. The results show that MMC treatment, in the last cell cycle of endoreduplication, as expected, significantly increases only the frequency of SCEs, whereas the frequency of ICEs and CCEs remains unchanged. This result supports replication models of formation of SCEs. Furthermore the fact that the number of ICEs does not increase means that the molecular mechanism of somatic crossing over is not related to that of SCE formation, or very rarely. The results also indicate a statistically significant lower induction of SCEs in endoreduplicated metaphases as compared with diploid ones both in control and MMC-treated cells. Such a result may be due to structural restrictions within the diplochromosome. Received: 29 December 1995; in revised form; 4 March 1996 / Accepted: 24 March 1996     

Influence of sodium butyrate on the induction of radiation-induced chromosomal aberrations and sister chromatid exchanges in Chinese hamster ovary (CHO) cells.

CHO cells were pre-treated with sodium butyrate (SB) for 24 h and then X-irradiated in G1. Metaphases were scored for the induction of chromosomal aberrations and sister chromatid exchanges (SCEs). The data were compared with those obtained after irradiation of cells not pre-treated with SB and showed that SB has different effects on the endpoints examined. The frequencies of dicentric chromosomes were elevated and of small acentric rings (double minutes, DMs) reduced. These results are discussed to be a consequence of conformational changes in hyperacetylated chromatin which could lead to more interchromosomal and to less intrachromosomal exchanges. SB itself induces a few SCEs but suppresses the induction of SCEs by X-rays. We assume that a minor part of radiation induced SCEs are 'false' resulting from structural chromosomal aberrations, such as inversions, induced in G1. Inversions are the symmetrical counterparts of DMs. If inversions are suppressed by SB treatment to a similar extent as DMs a small reduction of SCEs by SB can be expected.     

The effect of continuous gamma irradiation on formation of sister chromatid exchanges (SCEs) and chromosomal aberrations in meristematic cells ofVicia faba

Germinated seeds ofVicia faba were continuously irradiated at low dose rate of gamma rays (0.05 Gy h-¹) up to a total accumulated dose of 2 Gy. The FPG (fluorescence plus Giemsa) technique of differential chromatid staining was used to monitor the frequency of sister chromatid exchanges (SCEs) in irradiated root tip meristem cells. The results of the experiments have demonstrated that SCE frequency is raised by continuous gamma irradiation only in plant cells containing BrdU in the chromosomal DNA. No effect concerning SCE formation was recorded at continuous irradiation of meristematic cells of Vicia faba with native, i. e. BrdU-nonsubstituted, DNA. In contrast to SCEs, a significant increase was found in the yield of chromosomal aberrations in all variants of irradiation.     

THE FREQUENCY OF SISTER CHROMATID EXCHANGES FOLLOWING EXPOSURE TO VARYING DOSES OF H3-THYMIDINE OR X-RAYS

In the Chinese hamster cell line CHEF-125, sister chromatid exchanges occurred at a rate of a little higher than one per three chromosomes for each cell cycle. The exchanges were detectable by labeling with H³-thymidine and autoradiographic analyses of chromosomes at the second and subsequent metaphases after labeling had occurred. To test the hypothesis that sister chromatid exchanges are caused by radiation, cells were incubated in media with different amounts of H³-thymidine. No statistically significant change in the exchange rate was detected over 100-fold range of variation in the amount of incorporated H³-thymidine (determined by grain counts of autoradiographs). We have concluded that sister chromatid exchanges are not caused by tritium radiation and therefore are spontaneous events. Cultures were also irradiated with acute doses of x-rays up to 200 r and scored for sister chromatid exchanges. Between zero and 50 r there was a statistically significant increase in the rate of exchanges. This is interpreted as evidence that x-rays can induce some exchanges, although the majority of these events are probably spontaneous.     

Variations of chromosome radiation sensitivity in fetal and adult mice during gestation

Mice were exposed to 2 Gy of γ-rays at various days of pregnancy, and just before and after gestation. Chromosomes were analyzed 4 h after irradiation in spontaneously dividing hematopoietic cells from liver for fetuses and bone marrow for mothers. On average, there was significantly less chromosome damage in fetuses than in mothers. A very strong increase of chromosome breakage was observed in mothers at days 16–19 of gestation. This increase parallels that of gestation hormones, suggesting a direct relationship. The differences between fetuses and mothers in relation to gestation age result from the increase in the rate of chromatid and chromosome breaks but not of chromatid exchanges, which remained stable. This suggests that a DNA repair step involved in joining broken extremities is the cause. More experiments are needed to understand the origin of these variations of radiation sensitivity and the possible extrapolation of these observations to other species.     

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.     

X-ray-induced chromosome aberrations in mouse dictyate oocytes. I. Time and dose relationships.

Structural chromosome aberrations were analyzed in superovulated metaphase-I oocytes of the mouse, Mus musculus, at various times after a single acute dose of 200 R of X-rays. The aberrations seen were of the chromatid type, i.e., chromatid interchanges, isochromatid deletions and chromatid deletions. The aberration frequency was low during the interval 24 h to 5 days between irradiation and ovulation; peak frequency was reached when irradiation was given 14 days prior to ovulation. A dose-response study was made 14 days prior to ovulation at doses of 50, 100, 200, 300 and 400 R. A curve of these data indicated that a significant two-track component was present for both interchanges and deletions. Centromere staining revealed that symmetrical and asymmetrical interchanges occurred at approximately equal frequency and also that the asymmetrical equivalent of crossing-over was induced at a measurable frequency.     

Studies on radiation-induced chromosome aberrations in mouse spermatocytes. I. Stage specificity and dose-response relationships of chromosome aberrations induced in mouse primary spermatocytes following X-irradiation

The cytological analysis of chromosome aberrations induced at diplotene, mid-pachytene, zygotene and leptotene stages following X-irradiation was performed at diakinesis-metaphase I in mouse spermatocytes. The dose-response relationships fitted well to linear equations for deletion-type aberrations at each stage, and to linear-quadratic equations for exchange-type aberrations at all stages except for leptotene. The radiosensitivity to chromosome aberration induction tended to increase gradually with progression through synaptic and post-synaptic stages, diplotene being the most sensitive. Chromatid exchanges were hardly observed at leptotene, the aberrations being mainly isochromatid fragments. On the contrary, chromatid exchanges and isochromatid deletions were mainly observed at later stages (zygotene-diplotene). The specificity of chromosome aberration induction in primary spermatocytes might be influenced by chromatin organization and chromosomal configuration peculiar to meiotic cells.