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

Influence of Neurospora endonuclease on trenimon-induced structural chromosomal aberrations and sister-chromatid exchanges in human peripheral lymphocytes and Chinese hamster ovary cells

Human peripheral lymphocytes and Chinese hamster ovary cells were treated in the G1 phase of the cell cycle with the trifunctional alkylating agent trenimon (TRN) and post-treated with a single-strand specific endonuclease from Neurospora crassa (NE). TRN induces chromosomal aberrations of the chromatid type (CA) and sister-chromatid exchanges (SCE). NE post-treatment leads to an elevation of the frequencies of CA but not of SCEs. This indicates that TRN induced CA are the result of DNA double-strand breaks and that the SCEs originate from other types of lesions, most probably base damage.

Induction of chromosome damage by Neurospora endonuclease in repair-inhibited quiescent normal human fibroblasts

The purpose of these experiments was to determine the role of double-strand breaks in chromosome aberration formations. Quiescent normal human fibroblasts were treated with 3 microM nitrogen mustard and then allowed to repair their DNA damage for 24 h prior to cell fusion and induction of premature chromosome condensation. The extent of chromosome damage was determined in the G1 prematurely condensed chromosomes (G1 PCC). The presence of cytosine arabinoside and hydroxyurea during the repair period in order to accumulate single-strand DNA breaks resulted in an increase in the chromosome-break frequency. Treatment of these repair-inhibited cells with single-strand-specific neurospora endonuclease during fusion to change single-strand lesions into double-strand breaks resulted in a doubling of the aberration frequency. These results support the notion that double-strand breaks are important in chromosome-aberration formation.

Liquid-holding experiments with human peripheral lymphocytes. II. Experiments with trenimon and 1-beta-D-arabinosylcytosine

Liquid holding of trenimon-treated human peripheral lymphocytes in the G0 stage of the cell cycle leads to an elevation in the frequencies of chromosome aberrations and a decrease in the frequencies of chromatid aberrations. The frequencies of aberrant metaphases are not influenced significantly under these experimental conditions. Storage of trenimon-treated cells in the presence of 1-beta-D-arabinosylcytosine (araC) leads to an additional increase in the frequencies of chromosome-type aberrations, with an increase in the frequencies of aberrant metaphases as well. These findings are interpreted as DNA double-strand breaks being formed during the repair of damaged DNA, and that araC exaggerates this effect by inhibiting repair. AraC does not influence the frequencies of SCEs significantly, which indicates that either the lesions or the repair pathways leading to chromosome aberrations are different from those leading to SCEs.

Molecular mechanisms involved in the production of chromosomal aberrations. III. Restriction endonucleases

Chinese hamster ovary cells (CHO cells) and mouse fibroblasts (PG 19) were permeabilized with inactivated Sendai virus, treated with different types of restriction endonucleases (Eco RV, Pvu II, Bam HI, Sma I, Asu III, Nun II), and studied for the occurrence of chromosomal aberrations at different times following treatment. The pattern of chromosomal aberrations observed was similar to that induced by ionizing radiations. Restriction endonucleases that induce blunt double-strand breaks (Eco RV, Pvu II) were more efficient in inducing chromosomal aberrations than those that induce breaks with cohesive ends (Bam HI, Nun II, Asu III). Ring types were very frequent among the aberrations induced by restriction enzymes. Cytosine arabinoside, an inhibitor of DNA repair, was found to increase the frequencies of aberrations induced by restriction enzymes, indicating its effect on ligation of double-strand breaks. The relevance of these results to the understanding of the mechanisms of chromosomal aberration formation following treatment with ionizing radiations is discussed.

Enzymatic restriction of mammalian cell DNA using Pvu II and Bam H1: evidence for the double-strand break origin of chromosomal aberrations

Permeabilized Chinese hamster cells were treated with the restriction enzymes Pvu II and Bam H1 which generate blunt-ended with cohesive-ended double-strand breaks in the DNA respectively. Cells were then allowed to progress to the first mitosis, where chromosomal aberrations were scored. It was found that blunt-ended double-strand breaks induced both chromosome and chromatid aberrations of exchange and deletion types, including a high frequency of tri-radials. The total aberration frequency at high enzyme concentrations was more than ten times the control background frequency. Treatment with Bam H1 on the other hand did not induce aberrations above the background rate. This may indicate that the cohesive ends generated by this enzyme may be easily repaired by the cell due to the stabilization of the hydrogen bonding at the site of the double-strand break. Measurements using the unwinding method showed that the enzymes caused strand breaks in the DNA of permeabilized cells, and an approximate X-ray dose equivalent of the restriction-enzyme-induced breaks could be calculated. This indicated that restriction-induced blunt-ended double-strand breaks are relatively inefficient in causing chromosomal aberrations. This may be because of the presence of 'clean ends' at the site of a double-strand break, which may be repaired by ligation. The method of introducing restriction enzymes into cells opens up a new model approach for the study of the conversion of double-strand breaks into chromosome aberrations.

On the origin of chromosomal aberrations in human peripheral lymphocytes in vitro. I. Experiments with Neurospora endonuclease and polyethylene glycol

Post-treatment of mutagen-treated human peripheral lymphocytes with a single-strand specific endonuclease from Neurospora crassa leads to a significant elevation of the rate of structural chromosomal aberrations. Our results indicate that DNA double-strand breaks (DSB) are ultimate lesions for the formation of chromosomal aberrations in the G1 and G2 phase of the cell cycle and probably also in the S-phase. Post-treatment of X-irradiated G2 cells with polyethylene glycol (PEG) leads to an elevation of the frequencies of chromatid type aberrations. This result is taken as an indication that nucleases from PEG-damaged lysosomes transform lesions in X-ray damaged chromosomes to DSB. With respect to the origin of chromosomal aberrations, our results are in favour of the breakage and reunion hypothesis of K. Sax , and not of Revell 's exchange hypothesis.

The contribution of DNA single-strand breaks to the formation of chromosome aberrations and SCEs

The induction of sister chromatid exchanges (SCEs) and chromosomal aberrations (CAs) with bleomycin (BLM), hydrogen peroxide (H2O2), short-wave ultraviolet (UV)-irradiation, and long-wave UV-irradiation was investigated in V79 cells with BrdUrd-substituted DNA. The application of a Neurospora endonuclease (NE) which specifically cleaves single-stranded DNA after these treatments showed that DNA single-strand breaks (SSBs) are induced by these agents. The SSBs are converted to double-strand breaks (DSBs) by NE and become visible as CAs on metaphase chromosomes. H2O2 and both types of UV-irradiation also led to an induction of CAs and SCEs, whereas BLM only induced aberrations. Cysteine (Cys) reduced the frequency of the induced SSB-dependent CAs in all treatments, but had no influence on the SCE frequencies after BLM and H2O2 treatment and had only a slight effect on the UV-induced SCEs. The results confirm the opinion that directly induced SSBs can contribute to the induction of CAs in cells with BrdUrd-substituted DNA, but that these SSBs are not efficiently converted to SCEs. The more recent conceptions regarding the mechanism of SCE are in accordance with these findings and the conclusions derived therefrom.

Chromatid damage after G2 phase x-irradiation of cells from cancer-prone individuals implicates deficiency in DNA repair

Ten lines of skin fibroblasts from individuals with genetic disorders predisposing to a high risk of cancer were compared with nine lines from normal adult donors with respect to chromatid damage after x-irradiation [25, 50, and 100 rad (0.25, 0.50, and 1 gray)] during G2 phase. The 10 cell lines represented five genetic disorders: Bloom syndrome, familial polyposis, Fanconi anemia, Gardner syndrome, and xeroderma pigmentosum, complementation groups A(XP-A), C(XP-C), E(XP-E), and variant (XP-Va). The incidence of chromatid breaks in all cancer-prone lines except XP-E and XP-A was significantly higher than in the normal lines. The incidence of chromatid gaps in all cancer-prone lines except XP-A and XP-Va was significantly higher than in the normal lines. Because each chromatid apparently contains a single continuous DNA double strand, chromatid breaks and gaps represent unrepaired DNA strand breaks arising directly or indirectly during excision repair of x-ray-induced DNA damage. These cytogenetic data together with results from use of the DNA repair inhibitor arabinofuranosyl cytosine (cytosine arabinoside) suggest that cells from all of these cancer-prone individuals are deficient in some step of DNA repair, predominantly excision repair operative during the G2-prophase period of the cell cycle. It appears that these DNA repair deficiencies are associated with a genetic predisposition to a high risk of cancer.

Formation of chromatid-type aberrations in G2 stage of the cell cycle

CHO cells were treated in G1 stage of the cell cycle with chromosome-breaking agents that act in an S-dependent manner. The cells were challenged in G2 stage, before fixation, with various inhibitors of DNA synthesis or repair. Short-wave UV, mitomycin C, decarbomyl mitomycin and 4-nitroquinoline oxide (4NQO) were used as chromosome-breaking agents. The inhibitors of DNA repair or synthesis used were hydroxyurea, aphidicolin and caffeine. Permeabilization of cells followed by a treatment with Neurospora endonuclease (a treatment to convert DNA single-strand breaks into double-strand breaks) did not have any influence on the frequencies of chromatid aberrations induced by the chemicals used, whereas with the inhibitors the extent of potentiation varied depending on the mutagen and the inhibitor used.

The exchange hypothesis for the formation of chromatid aberrations: an experimental test using bleomycin

The association between bleomycin-induced chromatid aberrations and BUdR-label exchange between sister chromatids was investigated in order to evaluate Revell's exchange hypothesis for the formation of chromatid aberrations. The results of this study indicate that a larger than expected proportion of chromatid breaks can be accounted for by the exchange hypothesis though not all breaks are the result of incomplete exchange.

Mechanisms for chromosomal aberrations in mammalian cells

Experimental evidence is presented for the involvement of DNA double-strand breaks in the formation of radiation-induced chromosomal aberrations. When X-irradiated cells were post-treated with single-strand specific Neurospora crassa endonuclease (NE), the frequencies of all classes of aberration increased by about a factor 2. Under these conditions, the frequencies of DNA double-strand breaks induced by X-rays (as determined by neutral sucrose-gradient centrifugation), also increased by a factor of 2. The frequency of chromosomal aberrations induced by fast neutrons (which predominantly induce DNA double-strand breaks) was not influenced by post-treatment with NE. Inhibition of poly(ADP-ribose) polymerase, an enzyme that uses DNA with double-strand breaks as an optimal template, by 3-aminobenzamide also increased the frequencies of X-ray-induced chromosomal aberrations, which supports the idea that DNA double-strand breaks are important lesions for the production of chromosomal aberrations induced by ionizing radiation.

Effects of aphidicolin on repair replication and induced chromosomal aberrations in mammalian cells

The influence of aphidicolin, an inhibitor of polymerase alpha, on UV-induced repair replication in human skin fibroblasts, as well as in HeLa cells, was determined. In growing fibroblasts and in HeLa cells, aphidicolin had a potentiating effect on UV-induced repair replication, whereas in fibroblasts grown to confluency, aphidicolin had an inhibitory effect. This inhibitory effect was stronger when measured in the presence of hydroxyurea. In HeLa cells the presence of both aphidicolin and hydroxyurea also had an inhibitory effect, but in the presence of hydroxyurea alone, UV-induced repair replication was enhanced. The results of these studies can be explained on the basis of differences in deoxyribonucleotide triphosphate pool sizes in growing and confluent cells. Post-treatment of X-irradiated human lymphocytes in the G0 and G1 stages with aphidicolin increased the frequencies of X-ray-induced chromosomal aberrations. Such an increase was not observed in G1 cells of CHO after similar treatment with X-rays and aphidicolin. However, treatment with aphidicolin, in the G2 stage, of CHO cells that had been exposed to UV or alkylating agents in the G1 stage increased the frequencies of induced chromatid breaks. The significance of these results is discussed.

Sister chromatid exchange (SCE) and structural chromosome aberration in mutagenicity testing

Data from previous studies published on the induction by mutagens of sister chromatid exchanges (SCEs) and structural chromosome damage were compared qualitatively and quantitatively. Although a good correlation between the incidence of both cytogenetic phenomena has been pointed out in many previous publications, about 30% of the agents for which comparable data were available yielded non-corresponding qualitative results concerning both indicator effects. However, even in groups with good qualitative agreement distinct quantitative differences indicated different molecular mechanisms of the formation of SCEs and breaks. Additional information supporting the importance of these differences for the validity of both indicator systems has been derived from the results obtained using strong clastogens exhibiting a low or no SCE-inducing activity and vice versa, from special observations on chromosomal breakage syndromes, and from studies on the action of known co- and anti-clastogens on SCE-induction by chemical mutagens. As a result, it has been suggested that the SCE-technique should be considered as a valuable additional method for cytogenetic mutagenicity testing, which, however, is not adequate to replace the classical methods of analysis of structural chromosome damage.

Localisation of 7-12-dimethylbenz(a)anthracene induced chromatid breaks and sister chromatid exchanges in chromosomes 1 and 2 of bone marrow cells of rat in vivo

The frequency of chromatid breaks associated with sister chromatid exchanges at the break point was determined in rat bone marrow cells treated in vivo with 7-12 DMBA, during the late S phase of the cell cycle. The chromosomal aberrations and SCEs were scored in the same cells. Under the experimental conditions employed, more than 40% of the chromatid breaks were found to be associated with an SCE, a frequency expected according to Revell's hypothesis for the formation of chromatid breaks.

Use of the 5-bromodeoxyuridine-labelling technique for exploring mechanisms involved in the formation of chromosomal aberrations

Synchronized G1 CHO cells with chromosomes of TB or TT constitution were irradiated with X-rays, short-wave UV and long-wave UV. The types and frequencies of chromosomal aberrations observed in the ensuing mitosis were studied. X-Rays induced predominantly chromosome types of aberration in chromosomes of TT constitution, whereas both chromosome- and chromatid-types of aberration were induced in cells with chromosomes of TB constitution. Short-wave UV induced only chromatid types of aberration in cells containing chromosomes of TT constitution, but both chromosome and chromatid types of aberration in cells with chromosomes of TB constitution. Long-wave UV induced chromosome and chromatid types of aberration in cells with chromosomes of TB constitution and no aberrations in cells containing chromosomes of TT constitution. Long-wave UV-irradiation of cells containing chromosomes of TB constitution increases the frequencies of SCEs. The relationship between chromosome constitution (TT or TB), the type of lesions induced by the 3 different agents employed, and the types of chromosomal aberration induced are discussed.

Has diagnostic ultrasound mutagenic effects?

Chinese hamster ovary cells were treated with ultrasound from a fetal pulse detector (Eucotone, Siemens) operated at 10 mW/cm2 and 2.2 MHz. The frequencies of structural chromosomal aberrations and of sister chromatid exchanges were not increased by the treatment. There was no indication of single-strand breaks induced by ultrasound in the G2 phase of the cell cycle.

The effect of caffeine posttreatment on X-ray-induced chromosomal aberrations in human blood lymphocytes in vitro

The potentiating effect of caffeine on X-ray-induced chromosomal aberrations in human blood lymphocytes has been investigated, with special reference to cell cycle stages (G0 and G2). Both quantitative and qualitative differences in the yield of chromosomal aberrations were detected in caffeine-posttreated cells, depending on the cell stage irradiated. The studies on caffeine potentiating effects on X-irradiated G0 lymphocytes from normal adults, newborns, Down syndrome patients, and an ataxia telangiectasia patient pointed to interindividual variations in the response to caffeine potentiation among normal probands and a very profound effect in ataxia cells.