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.     

The stage of chromosome duplication in the cell cycle as revealed by X-ray breakage and 3H-thymidine labeling

By means of combined experiments of X-irradiation and ³H-thymidine labeling of the chromosomes which are in the phase of synthesis, and the subsequent analysis at metaphase on the autoradiographs of the chromosomal damage induced during interphase, it was shown that in somatic cells from a quasi-diploid Chinese hamster line cultured in vitro the chromosomes change their response to radiation from single (chromosome type aberrations) to double (chromatid type aberrations) in late G₁. These results are interpreted to indicate that the chromosome splits into two chromatids in G₁, before DNA replication. — By extending the observations at the second metaphase after irradiation, it was also seen that cells irradiated while in G₂ or late S when they reach the second post-irradiation mitosis still exhibit, beside chromosome type aberrations, many chromatid exchanges, some of which are labeled. Two hypotheses are suggested to account for this unexpected reappearance of chromatid aberrations at the second post-irradiation division. The first hypothesis is that they arise from half-chromatid aberrations. The second hypothesis, which derives from a new interpretation of the mechanisms of production of chromosome aberrations recently forwarded by Evans, is that they arise from gaps or achromatic lesions which undergo, as the cells go through the next cycle, a two-step repair process culminating in the production of aberrations.This work was supported in part by grant No. RH-00304 from the Division of Radiological Health, Bureau of State Services, Public Health Service, U.S.A.     

Chromosome breakage and rejoining of sister chromatids in Bloom's syndrome

The occurrence of chromosome breaks and reunion of sister chromatids in lymphocytes of two patients with Bloom's syndrome has been compared with those found in X-rayed and control cells. The distribution of breaks in BS is non-random both between and within chromosomes, the centric regions of certain chromosomes being preferentially involved. The following working hypotheses are put forward: When chromosome breaks in human lymphocytes occur in G₀— G₁, practically no sister chromatid reunion (SCR) takes place, whereas ends created by an S—G₂ break show a considerable tendency to SCR. We propose further that chromosome aberrations in BS mainly result from breaks in S—G₂, including possible U-type rejoining of sister chromatid exchanges. Fragments extra to an intact chromosome complement result from a chromatid break or an asymmetrical chromatid translocation in a previous mitosis.     

THE RELATION BETWEEN DNA SYNTHESIS AND CHROMOSOME STRUCTURE AS RESOLVED BY X-RAY DAMAGE

Vicia faba root tip cells were treated for short periods with tritiated thymidine, either immediately before or after exposure of roots to x-rays, and autoradiograph preparations were analysed in an attempt to test the hypothesis that chromatid type (B') aberrations are induced only in those chromosome regions that have synthesized DNA prior to x-irradiation, whereas chromosome type (B') aberrations are induced only in unduplicated chromosome regions. Studying the relation between presence or absence of label at loci involved in aberrations, in cells irradiated at different development stages, and the pattern of labelling in cells carrying both types of aberration leads to the conclusion that B' aberrations are induced only in unreplicated chromosome regions. Following replication, only B' aberrations are induced, but these aberrations are also induced in chromosome regions preparing to incorporate DNA. It is suggested that the doubled response of the chromosome to x-rays prior to DNA incorporation might reflect a physical separation of replicating units prior to replication. The aberration yields in damaged cells which were irradiated in G₁ S, and early G₂ were in the ratio of 1.0:2.0:3.2. The data indicate that the increased yield of B' in early G₂ relative to S cells may be a consequence of changes in the spatial distribution of the chromosomes within the nucleus.     

Ethanol and acetaldehyde potentiate the clastogenicity of ultraviolet light, methyl methanesulfonate, mitomycin C and bleomycin in Chinese hamster ovary cells

Ethanol itself did not induce any apparent chromosome aberrations in Chinese hamster ovary cells. However, posttreatment with ethanol potentiated the chromosome aberrations induced by ultraviolet light (UV), methyl methanesulfonate (MMS), mitomycin C (MMC) or bleomycin (BLM). Chromatid exchanges were predominantly increased in cultures treated with UV, MMS or MMC and then with ethanol, whereas chromosome breaks and chromatid exchange were the major types of aberrations increased in the cultures treated with BLM and ethanol. Posttreatment with acetaldehyde, the major metabolite of ethanol, also potentiated the chromosome aberrations induced by UV, MMS, MMC or BLM. The main types of aberrations potentiated by posttreatment with acetaldehyde were similar to those by posttreatment with ethanol.     

The effect of G2-treatments with 2′-deoxyadenosine on the frequency of chromatid aberrations in human lymphocytes depends on the type of culture

The effect of G₂-treatments with 2-deoxyadenosine (dAdo) on the frequency of chromatid aberrations in X-irradiated and unirradiated human lymphocytes depends on the method of culture. In whole-blood cultures dAdo alone produced very few if any aberrations, but in the presence of inhibitors of adenosine deaminase (ADA), such as EHNA or coformycin, a high frequency of chromatid gaps, chromatid breaks, and isochromatid breaks were produced. In cultures of purified lymphocytes, dAdo produced aberrations even in the absence of an ADA inhibitor. Apparently the lymphocytes are protected against the chromosome-damaging effect of dAdo by the ADA activity of the erythrocytes. — When given as a post-treatment, dAdo also enhances the frequency of chromatid aberrations induced by X-rays in G₂. In whole-blood cultures this effect is obtained even in the absence of an ADA inhibitor, although the concentration required to produce enhancement is about twenty times higher than in the presence of the inhibitor.     

Enhanced expression of X-ray- and UV-induced chromosome aberrations by cytosine arabinoside in ataxia telangiectasia cells

The effect of cytosine arabinoside (ara-C) on the frequency of X-ray- or UV-induced chromosome aberrations was studied in cultured skin fibroblasts derived from 2 normal persons, 4 ataxia telangiectasia (AT) patients and 2 obligate AT heterozygotes. Density-inhibited cells were irradiated with X-rays or UV, post-treated with ara-C, and chromosomes in the first post-irradiation mitoses were examined. UV, a poor inducer of chromosome-type aberrations in G1, caused chromosome-type aberrations (dicentrics and rings) when coupled with ara-C both in normal and AT cells, but to a much greater extent in AT cells. In AT cells, an elevated induction of both terminal deletions and chromatid aberrations was also observed by the application of UV and ara-C, and unexpectedly, UV alone induced a considerable frequency of both types of aberrations. The enhancing effect of ara-C on X-irradiated cells was less pronounced than on UV-irradiated cells. The responses of AT heterozygotes were virtually the same as those of normal cells. These findings suggest that ara-C can convert the UV-induced DNA damage into the type that has a potential to induce dicentrics and rings in G1 as well as to elicit a hypersensitive response of AT cells.     

Synergism of 1-β-d-arabinofuranosylcytosine with itself and aphidicolin

JU56 cells have been exposed to 1-β-d-arabinofuranosylcytosine (ara-C) in S phase, and again to aphidicolin (APC) or ara-C during G₂, and examined for chromosomal aberrations at c-metaphase. It was found that the two exposures acted synergistically in the production of chromosomal lesions of both the chromatid and isochromatid type. The results were interpreted as indicating that inhibition of the G₂ repair system prevented the repair of DNA single-strand regions produced by the incorporation of ara-C during semiconservative DNA synthesis.     

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.     

Cytogenetic insights into DNA damage and repair of lesions induced by a monomethylated trivalent arsenical

Arsenic is a human carcinogen, and only recently animal models have been developed that are useful in investigating its carcinogenic mode of action (MOA). However, how arsenic induces cancer is still an open question. In a previous paper, we proposed a model detailing how arsenic might induce DNA lesions leading to cytogenetic damage [A.D. Kligerman, A.H. Tennant, Toxicol. Appl. Pharmacol. 222 (2007) 281–288]. In this model we hypothesized that arsenic does not induce chromosome damage via DNA adduction but induces short-lasting lesions from the action of reactive oxygen species (ROS). These lesions cause single-strand breaks (SSB) that induce chromosome breakage when treatment is in late G₁- or S-phase. However, if treatment is confined to the G₀- or early G₁-phase of the cell cycle, it is predicted that little or no cytogenetic damage will result at the subsequent metaphase. Here, we describe the results from testing this model using monomethylarsonous acid (MMA^III) and cytosine arabinoside (araC), a DNA chain terminator, to extend the time that DNA lesions remain open during repair to allow the lesions to reach S-phase or interact to form DNA exchanges that would lead to exchange aberrations at metaphase. The results of our study only partially confirmed our hypothesis. Instead, the results indicated that the lesions induced by MMA^III are quickly repaired through base excision repair, that there is little chance for araC to extend the life of the lesions, and thus the DNA damage induced by arsenicals that leads to chromosome aberrations is very short lived.     

Effects of 1-β-D-arabinofuranosylcytosine on chromosomes,depending upon the cell cycle stage at the time of exposure

1-β-D-Arabinofuranosyl cytosine (ara-C) is a clinically important cytotoxic drug which is a potent inhibitor of DNA but which has a minimal effect on other cellular processes. The cytotoxic action of ara-C on mammalian cells has been suggested to be due to the chromosome aberrations induced by this compound. Using a marsupial cell line (JU56), the cells of which contain only 9 readily identified chromosomes, the different types of chromosome aberrations induced by a pulse of ara-C have been quantified, and the cell cycle dependence of the damage has been assessed. It was found that, for cells exposed in G₂, both chromatid-type and chromosome-type lesions were produced. The frequency of these lesions was reduced by a chase of deoxycytidine, and there was some evidence that the initial lesions are gaps which may later be converted to true breaks. In early G₂ and late S cells, lesions were produced chiefly at one chromosome locations; this location was not specifically late-replicating. At all stages of S, lesions were chiefly chromatid-type, and some exchanges occurred. The level of damage in S cells was not influences by a deoxycytidine chase. There was negligible damage in cells exposed in G₁.It is suggested that the reason previous investigators have obtained very different cell cycle dependence of chromosomes damage is that the delaying effects of ara-C on cell cycle progression was not taken into account.     

A search for radioresistance in experimental populations of Drosophila with radiation histories

Human lymphocytes in the G₀ stage were irradiated with UV light and X-rays. A 2-fold increase in the yield of dicentrics was observed in comparison with the yield for X-rays alone. This synergistic effect was constant irrespective of the variation in the UV dose between 50 and 100 erg/mm².The individual chromosomes participated in interchange aberrations as expected from a random distribution per mitotic chromosome length unit. This observation is in contrast with the recent finding that X-ray-induced chromosome-type breakage is preferentially located on chromosomes with relatively large amounts of R-bands. Thus, the present data indicate that the additional breakage points, due to the synergism, had a different distribution between chromosomes from those induced by X-irradiation alone. Mechanisms that could account for the synergistic reaction are discussed.     

Effects of Ultraviolet and X-Ray Radiation on in vitro Cultivated Cells of Haplopappus gracilis

A cell strain of Haplopappus gracills was used for investigations of the effects of UV (2537 A) and X-ray irradiation. Mitotic inhibition and killing after UV exposure were studied. A survival curve of UV treated and then plated cells is presented. The LD₅₀ seems to be about 2000 erg. mm^?2 under the experimental conditions used. All types of chromosome aberrations are induced by UV irradiation, but the frequency is relatively low at doses which do not completely inhibit cell division. A mutant strain of chromosome type is isolated after UV treatment and then plating. Mitotic inhibition and killing after X-ray treatment were studied. A survival curve is presented and the LD₅₀ under the culture conditions used seems to be about 2000 R. The frequency of chromosome aberrations induced by X-rays is highly increased by aeration during X-ray treatment which indicates that some degree of cell anoxia exists in a cell suspension. There arr indications that chromosome aherrations may not cause growth inhibition to such an extent as is usually believed.     

Cytological effects on Chinese hamster cells of synchronizing concentrations of hydroxyurea

The cytological effects of 2 mM hydroxyurea upon Chinese hamster cells at various phases of the cell cycle were examined. Cells in the G₁, G₂, or M phases of the generation cycle treated with hydroxyurea showed no chromosomal aberrations. Cell treated in S phase became moribund and eventually lysed. Some of these moribund S cells reached mitosis much later and were found to have chromatid aberrations. Cells in the log phase of growth, surviving exposure to 2 mM hydroxyurea for six hours, also showed no aberrations. Thus, viable (colony-forming) cells, resulting from synchrony procedures with hydroxyurea are free of chromosomal aberrations.     

Radiation-induced chromatid aberrations in the bone marrow and lymph nodes of the rat during the first 24 h after irradiation

Wistar rats of both sexes were exposed to 100 R of X-rays. Chromatid-type aberrations in metaphase figures of bone marrow and lymph node cells were scored after 2, 4, 6, 8 and 24 h and 3, 5, 7, 9 and 24 h, respectively.The shape of the curve for chromatid plus isochromatid breaks in bone marrow cells versus time is exponential. It is suggested that this shape is mainly a consequence of the continuous entrance into mitosis of cells irradiated while in S phase, in addition to those that were irradiated in G₂. For lymph nodes the frequency of chromatid plus isochromatid deletions increased up to the 5th h, then began to fall off in a manner similar to that for the bone marrow. The difference in the shape of the two curves is the consequence of the different dependence on time for chromatid and isochromatid breaks in each tissue. While the frequency of chromatid breaks fell steeply with time both for the bone marrow and for lymph nodes, the frequency of isochromatid breaks remained nearly constant for bone marrow, whereas it rose to a peak at the 5th h for the lymph nodes.These differences are tentatively explained by a shift in the phases of the cell cycle sampled owing to the greater mitotic delay of G₂ cells in lymph nodes, with the suggestion that in the late S phase the frequency of isochromatid breaks is lower than in all other phases of the cell cycle.     

Sister chromatid exchanges occur in G2-irradiated cells

DNA double-strand breaks (DSBs) are arguably the most important lesions induced by ionizing radiation (IR) since unrepaired or misrepaired DSBs can lead to chromosomal aberrations and cell death. The two major pathways to repair IR-induced DSBs are non-homologous end-joining (NHEJ) and homologous recombination (HR). Perhaps surprisingly, NHEJ represents the predominant pathway in the G₁ and G₂ phases of the cell cycle, but HR also contributes and repairs a subset of IR-induced DSBs in G₂. Following S-phase-dependent genotoxins, HR events give rise to sister chromatid exchanges (SCEs), which can be detected cytogenetically in mitosis. Here, we describe that HR occurring in G₂-irradiated cells also generates SCEs in ∼50% of HR events. Since HR of IR-induced DSBs in G₂ is a slow process, SCE formation in G₂-irradiated cells requires several hours. During this time, irradiated S-phase cells can also reach mitosis, which has contributed to the widely held belief that SCEs form only during S phase. We describe procedures to measure SCEs exclusively in G₂-irradiated cells and provide evidence that following IR cells do not need to progress through S phase in order to form SCEs.Key words: sister chromatid exchanges, double-strand break repair, ionizing radiation, homologous recombination, G₂ phase     

Isolation and subregional mapping of a human cDNA clone detecting a common RELP on chromosome 12

Summary Peripheral blood lymphocytes from three patients with Down syndrome (DS; trisomy 21; aged 5–6 years) and three age-matched control children were studied for the induction of chromosomal aberrations and sister chromatid exchanges (SCEs).Cells in G₀ were exposed to bleomycin (20–100 g/ml) for 3 h, and then cultured in medium containing 5-bromodeoxyuridine and phytohemagglutinin for 66 h. By the sister chromatid differential staining method, chromosome analyses were performed on metaphase cells that had divided one, two, or three or more times after treatment. The results indicate that DS cells exposed to bleomycin are hypersensitive to the production of dicentric and ring chromosomes compared to normal cells. Bleomycin also led to a dose-related increase in the frequency of SCEs, but no difference was found between the SCE frequencies in DS or normal lymphocytes exposed to bleomycin.     

Chromosome and DNA damage and their repair in higher plants irradiated with short-wave ultraviolet light

In this review the authors present only their own results. They include the determination of the duration of the different stages of the cell cylce in UV-irradiated barley cells, the effect of different UV doses on the frequency of chromosome aberrations in barley, the increase in UV-induced chromosome aberration frequency induced in barley by caffeine and the effect of UV doses on the induction of pyrimidine dimers and sites sensitive to UV-endonuclease action (ESS) in barley cells and Nicotina tabacum protoplasts. In addition, the excision of pyrimidine dimers and ESS after irradiation with various doses of UV, unscheduled DNA synthesis in N. tabacum protoplasts and the correlation between the induction of pyrimidine dimers in DNA and the frequency of chromosome aberrations are reported. Data demonstrating that photoreactivation decrease the number of DNA lesions and chromosome aberrations induced by UV are also presented.     

Effects of X-irradiation in G1 and G2 on Bloom's syndrome and normal chromosomes

Summary The X-ray sensitivity of chromosomes from a Bloom's syndrome patient and a normal control was compared in G₁ and G₂. There was no significant difference in the number of aberrations induced by irradiation in G₁. An increased sensitivity of the BS chromosomes was found in G₂. The frequency of mitotic chiasmata in the BS cells was not increased by the G₂-irradiation, even though the frequency of chromatid translocations was much increased. This provides further evidence for the fundamental difference of these two phenomena. Evidence from the types of aberrations induced suggests that there is no appreciably increased frequency of pairing of homologous chromosomes in the BS cells over that in normal cells.     

A correlation between radiation sensitivity and initial chromatid breaks in cancer cell lines revealed by Calyculin A-induced premature condensation

Three human malignancy cell lines were irradiated with ⁶⁰Co γ-rays. Initial chromatid breaks were measured by using the chemically induced premature chromosome condensation technique. Survival curves of cells exposed to gamma rays was linear-quadratic while the efficiency of Calyculin A in inducing PCC of G₂ PCC was about five times more than G₁ PCC. A dose-dependent increase in radiation-induced chromatid/isochromatid breaks was observed in G₁ and G₂ phase PCC and a nearly positive linear correlation was found between cell survival and chromatin breaks. This study implies that low LET radiation-induced chromatid/isochromatid breaks can potentially be used to predict the radiosensitivity of tumor cells either in in vitro experimentation or in in vivo clinical radiotherapy.