A comparison of aberration distribution and cell-cycle progression in cells treated with bleomycin with those exposed to X-rays

The extent of cell-cycle delay and the frequency of aberrant metaphases induced by bleomycin (BLM) and X-rays have been compared at doses which produce similar frequencies of chromosome aberrations by the 2 clastogenic agents (BLM, 40 micrograms/ml and X-rays, 2 Gy) in muntjac lymphocytes. The frequency of aberrant metaphases was low in BLM-treated cells; however, the number of aberrations per metaphase was higher than in cells exposed to X-rays. Thus in contrast to their uniform sensitivity to X-rays, the lymphocytes showed differential sensitivity to BLM. This might be due to differences among the cells in their uptake of BLM and/or its action on the nuclear membrane-DNA complex. In spite of the total number of chromosome aberrations being similar to that induced by X-rays, BLM did not induce a significant delay in cell-cycle progression as observed in the case of X-rays. A possible explanation could be that the DNA damages being limited to fewer cells than in the case of X-irradiation, the BLM-treated cultures had more normal cells allowing faster progression and/or unlike X-rays BLM may not be causing other cellular damages in addition to DNA breaks.     

Detection of carcinogen-induced DNA breaks by nick translation in permeable cells

A nick-translation reaction with $\text{E. coli}$ DNA polymerase I (pol. I) was used to detect $\text{in situ}$ DNA breaks produced by chemical carcinogens. Normal human fibroblasts treated with N-methyl-N′-nitro-N-nitrosoguanidine (MNNG) in various doses were permeabilized with lysolecithin, and were nick translated in the presence of [³H]dCTP and pol. I. The radioactivity incorporated increased with MNNG concentration, and was directly proportional to the poly(ADP-ribose) synthetase activity. Other DNA-damaging agents such as bleomycin or 4-nitroquinoline 1-oxide also caused the nick translation rate to increase. When MNNG-treated cells were cultured in fresh medium containing no MNNG, the increase in the rate of nick translation in permeable cells became less and this decrease was abolished by addition of aphidicolin or cytosine arabinoside. The nick translation method described here may be a useful means for estimating intrinsic DNA breaks in cells treated with carcinogens.     

Human lymphocytes exposed to low doses of ionizing radiations become refractory to high doses of radiation as well as to chemical mutagens that induce double-strand breaks in DNA

Human lymphocytes exposed to low doses of ionizing radiation from incorporated tritiated thymidine or from X-rays become less susceptible to the induction of chromatid breaks by high doses of X-rays. This response can be induced by 0.01 Gy (1 rad) of X-rays, and has been attributed to the induction of a repair mechanism that causes the restitution of X-ray-induced chromosome breaks. Because the major lesions responsible for the induction of chromosome breakage are double-strand breaks in DNA, attempts have been made to see if the repair mechanism can affect various types of clastogenic lesions induced in DNA by chemical mutagens and carcinogens. When cells exposed to 0.01 Gy of X-rays or to low doses of tritiated thymidine were subsequently challenged with high doses of tritiated thymidine or bleomycin, which can induce double-strand breaks in DNA, or mitomycin C, which can induce cross-links in DNA, approximately half as many chromatid breaks were induced as expected. When, on the other hand, the cells were challenged with the alkylating agent methyl methanesulfonate (MMS), which can produce single-strand breaks in DNA, approximately twice as much damage was found as was induced by MMS alone. The results indicate that prior exposure to 0.01 Gy of X-rays reduces the number of chromosome breaks induced by double-strand breaks, and perhaps even by cross-links, in DNA, but has the opposite effect on breaks induced by the alkylating agent MMS. The results also show that the induced repair mechanism is different from that observed in the adaptive response that follows exposure to low doses of alkylating agents.     

Induction of DNA ligase I by 1-beta-D-arabinosylcytosine and aphidicolin in MiaPaCa human pancreatic cancer cells

Exposure of MiaPaCa cells to 1-beta-D-arabinosylcytosine (ara-C) resulted in an increase in DNA ligase levels up to threefold compared to that in the untreated control cells, despite significant growth inhibition. Increased levels of DNA ligase I protein appear to correlate with the appearance of increased mRNA levels. The [(3)H]thymidine incorporation experiment and the biochemical assay of total polymerase activity revealed that an increase in DNA ligase I levels after treatment with ara-C was not accompanied by an increase of DNA synthesis or an increased presence of DNA polymerase activity inside cells. When cells resumed DNA synthesis after drug treatment, DNA ligase I levels began to drop, indicating that increased DNA ligase I is not required for DNA synthesis. An increase in DNA ligase I was also observed in cells treated with aphidicolin, another inhibitor of DNA synthesis that inhibits DNA polymerases without incorporating itself into DNA, indicating that an increase in DNA ligase I levels could be caused by the arrest of DNA replication by these agents. Interestingly, caffeine, which is a well-known inhibitor of DNA damage checkpoint kinases, abrogated the increase in DNA ligase I in MiaPaCa cells treated with ara-C and aphidicolin, suggesting that caffeine-sensitive kinases might be important mediators in the pathway leading to the increase in DNA ligase I levels in response to anticancer drugs, including ara-C and aphidicolin. We propose that ara-C and aphidicolin induce damage to the DNA strand by arresting DNA replication forks and subsequently increase DNA ligase I levels to facilitate repair of DNA damage.     

Absence of anthracycline-induced degradation of nuclear DNA in Ehrlich ascites tumour cells

The in vivo effects of anthracycline antibiotics on the integrity of Ehrlich ascites tumour cell DNA have been studied by sedimentation analysis of nuclear structures containing superhelical DNA in neutral sucrose gradients. These fast-sedimenting protein-DNA complexes may be released by gently lysing cells in solution containing non-ionic detergents and high NaCl concentrations (1.95 M). The supercoiled structure of DNA in these protein-DNA complexes is suggested by the characteristic sedimentation in the presence of intercalating agents. Apparently, no DNA damage could be detected in Ehrlich cells from 7-day-old tumours within 3 h after various doses of daunomycin (0.5–10 mg/kg of body wt.) were administered i.p. to mice. Sedimentation anomalies could not be observed even 15 or 30 h after administration of therapeutic doses of daunomycin or adriamycin. In contrast, at 30 min after administration to mice, therapeutic doses of bleomycin (2–8 mg/kg) caused extensive fragmentation of tumour cell DNA, which could be monitored as slowly sedimenting DNA structures (compared with the control). Similarly, DNA damage could be induced by procarbazine at therapeutic doses. Exposure to bleomycin or procarbazine abolished the characteristic biphasic response to ethidium bromide. The absence of anthra-cycline-induced degradation of Ehrlich ascites tumour cell DNA is apparently in contrast with the DNA damage observed in L1210 tumour cells. These observations suggest that DNA damage is not a necessary condition for antitumour activity.     

Poly(ADP-ribose) polymerase: A guardian of the genome that facilitates DNA repair by protecting against DNA recombination

We have studied the clonogenic survival response to X-rays and MNNG of V79 Chinese hamster cells and two derivative cell lines, ADPRT54 and ADPRT351, deficient in poly(ADP-ribose) polymerase (PARP) activity. Under conditions of exponential growth, both PARP-deficient cell lines are hypersensitive to X-rays and MNNG compared to their parental V79 cells. In contrast, under growth-arrested, confluent conditions, V79 and PARP-deficient cells become similarly sensitive to X-rays and MNNG suggesting that PARP may be involved in the repair of X-ray or MNNG-induced DNA damage in logarithmically growing cells but not in growth-arrested confluent cells. This suggestion, however, creates a dilemma as to how PARP can be involved in DNA repair in only selected growth phases while it is functionally active in all growth phases. To explain these paradoxical results and resolve this dilemma we propose a hypothesis based on the consistent observation that inhibition of PARP results in a significant increase in sister chromatid exchange (SCEs). Thus, we propose that PARP is a guardian of the genome that protects against DNA recombination. We have extended this theme to provide an explanation for our results and the studies done by many others.     

Reduced inhibition of replicon initiation and chain elongation by neocarzinostatin in skin fibroblasts from patients with ataxia telangiectasia

Cells from patients with the genetic disease ataxia telangiectasia are hypersensitive to the DNA-breaking agents X-rays, bleomycin and neocarzinostatin, and show reduced inhibition of DNA synthesis after treatment with these agents, as compared to normal cells. The rate of replicon initiation and chain elongation was measured shortly after brief exposure of two normal and two ataxia telangiectasia fibroblast strains to low doses (0.10-0.30 microgram/ml) of neocarzinostatin, by means of alkaline sucrose gradient analysis. Neocarzinostatin was found to inhibit both initiation and elongation, and both components of DNA synthesis were more resistant to this inhibition in the A-T strains.     

Relationships between chromosome damage, cell cycle delay and cell killing induced by bleomycin or X-rays

The extent of mitotic delay and chromosome aberration induction by X-rays and bleomycin has been compared in normal human foetal fibroblasts at doses giving approximately equal levels of cell killing, assayed as colony-forming ability. Bleomycin induced much less G2 delay and chromosome damage than X-rays. We conclude that the major mechanism of cell killing by bleomycin does not involve chromosome damage but the cells pass through a number of division cycles before dying and a common DNA lesion is involved in G2 delay and chromosome damage.     

The roles of DNA polymerases alpha, beta, and gamma in DNA repair synthesis induced in hamster and human cells by different DNA damaging agents

The involvement of DNA polymerases alpha, beta, and gamma in DNA repair synthesis was investigated in subcellular preparations of cultured hamster and human cells. A variety of DNA damaging agents, including bleomycin, neocarzinostatin, UV irradiation, and alkylating agents, were utilized to induce DNA repair. The sensitivity of repair synthesis, as well as replicative synthesis and purified DNA polymerase beta activity, to inhibition by the DNA polymerase inhibitors dideoxythymidine triphosphate, aphidicolin, cytosine arabinoside triphosphate, and N-ethylmaleimide was determined. No evidence was obtained for a major role of polymerase gamma in any type of repair synthesis. In both hamster and human cells, the sensitivity of bleomycin- and neocarzinostatin-induced repair synthesis to ddTTP inhibition was essentially identical with that observed for purified polymerase beta, indicating these repair processes proceeded through a mechanism utilizing polymerase beta. Repair synthesis induced by UV irradiation and alkylating agents was not sensitive to ddTTP, indicating repair of these lesions occurred through a pathway primarily utilizing a different DNA polymerase; presumably polymerase alpha. However, replicative synthesis was much more sensitive to polymerase alpha inhibitors than was repair synthesis induced by UV irradiation or alkylating agents. Neither the amount of DNA damage nor the amount of induced repair synthesis influenced the degree to which the different DNA polymerases were involved in repair synthesis. The possibility that "patch size" or the actual type of DNA damage determines the extent to which different polymerases participate in DNA repair synthesis is discussed.     

Effect of the antitumor antibiotic bleomycin on DNA polymerase activity

Treatment with bleomycin activates considerably a repair synthesis of DNA in rat liver chromatin in vitro and can cause loosening of the nucleoprotein complex, which facilitates the accessibility or repair enzymes for lesions in chromatin DNA. The bleomycin action on DNA-template increases severalfold the rate of synthesis catalyzed by DNA polymerase beta inhibits the activity of DNA polymerase I from Escherichia coli and suppresses severalfold the activity of DNA polymerase alpha and DNA polymerase of bacteriophage T4. The effect of bleomycin consists in a prevailing increase of nicks and minimal gaps in DNA as compared to the rise of moderate gaps, thus suggesting that bleomycin is a gamma-mimetic.     

Reduced inhibition of replicon initiation and chain elongation by neocarzinostatin in skin fibroblasts from patients with ataxia telangiectasia

Cells from patients with the genetic disease ataxia telangiectasia are hypersensitive to the DNA-breaking agents X-rays, bleomycin and neocarzinostatin, and show reduced inhibition of DNA synthesis after treatment with these agents, as compared to normal cells. The rate of replicon initiation and chain elongation was measured shortly after brief exposure of two normal and two ataxia telangiectasia fibroblast strains to low doses (0.10–0.30 μg/ml) of neocarzinostatin, by means of alkaline sucrose gradient analysis. Neocarzinostatin was found to inhibit both initiation and elongation, and both components of DNA synthesis were more resistant to this inhibition in the A-T strains.     

Hypersensitivity to ionizing radiation, in vitro, in a new chromosomal breakage disorder, the Nijmegen Breakage Syndrome

The Nijmegen Breakage Syndrome (NBS) is a new chromosomal instability disorder different from ataxia telangiectasia (AT) and other chromosome-breakage syndromes. Cells from an NBS patient appeared hypersensitive to X-irradiation. X-rays induced significantly more chromosomal damage in NBS lymphocytes and fibroblasts than in normal cells. The difference was most pronounced after irradiation in G2. Further, NBS fibroblasts were more readily killed by X-rays than normal fibroblasts. In addition, the DNA synthesis in NBS cells was more resistant to X-rays and bleomycin than that in normal cells. The reaction of NBS cells to X-rays and bleomycin was similar to that of cells from patients with ataxia telangiectasia. Our results indicate that NBS and AT, which also have similar chromosomal characteristics, must be closely related.     

Bleomycin-induced DNA damage and DNA repair in chicken embryo cells as compared to X-irradiation

Following in vitro- and in ovo-exposure of chicken embryo cells, the level of bleomycin (BM)-induced damage was evaluated by using DNA synthesis, nucleoid sedimentation (SED), and viscometry of alkaline cell lysates (VISC). This damage was compared to X-irradiation, using 5.9-378 nM BM in vitro, 1.5-116 micrograms BM/egg in ovo, and 2-32 Gy, respectively, in vitro as well as in ovo. With respect to BM, the most notable result is the increase in DNA synthesis and VISC at the lowest concentrations of the drug. A decrease in both parameters was observed at high BM concentrations and following exposure to X-rays, concomitantly with an increase in SED. Regarding the radiomimetic drug BM and X-rays, different modes of DNA damage and DNA repair are suggested by previous investigations and the present results. Therefore, further evidence is presented, that the chicken embryo can act as a simple, rapid and inexpensive test system to characterize the biological effects of many nucleo- and/or cytotoxic agents.     

Evidence that DNA polymerases alpha and beta participate differentially in DNA repair synthesis induced by different agents

The roles of DNA polymerases alpha and beta in DNA replication and repair synthesis were studied in permeable animal cells, using different agents to induce repair synthesis. DNA polymerase inhibitors were used to investigate which polymerases were involved in repair synthesis and in replication. Polymerase alpha was responsible for replication. On the other hand, both polymerases alpha and beta were involved in DNA repair synthesis; the extent to which each polymerase participated depended primarily on the agent used to damage DNA. Polymerase beta was primarily responsible for repair synthesis induced by bleomycin or neocarzinostatin, whereas polymerase alpha played a more prominent role in repair synthesis indiced by N-methyl-N'-nitro-N-nitrosoguanidine or N-nitrosomethyl urea. More DNA damage was induced by the alkylating agents than by bleomycin or neocarzinostatin, suggesting that the extent of involvement of polymerase alpha or beta in DNA repair synthesis is related to the amount or type of DNA damage. In addition, salt concentration was found to have little or no effect on the results obtained with the DNA polymerase inhibitors. Our findings provide an explanation for conflicting reports in the literature concerning the roles of DNA polymerases alpha and beta in DNA repair.     

Suppressing effect of antimutagenic flavorings on chromosome aberrations induced by UV-light or X-rays in cultured Chinese hamster cells

Chromosome aberrations induced by UV-light or X-rays were suppressed by the post-treatment with antimutagenic flavorings, such as anisaldehyde, cinnamaldehyde, coumarin, and vanillin. UV- or X-ray-irradiated surviving cells increased in the presence of each flavoring. X-ray-induced breakage-type and exchange-type chromosome aberrations were suppressed by the vanillin treatment in the G1 phase of the cell cycle and a greater decrease in the number of X-ray-induced chromosome aberrations during G1 holding was observed in the presence of vanillin. Furthermore, a greater decrease in the number of X-ray-induced DNA single-strand breaks was observed in the presence of vanillin. Treatment with vanillin in the G2 phase suppressed UV- and X-ray-induced breakage-type but not exchange-type chromosome aberrations. The suppression of breakage-type aberrations was assumed to be due to a modification of the capability of the post-replicational repair of DNA double-strand breaks. These G1- and G2-dependent anticlastogenic effects were not observed in the presence of 2',3'-dideoxythymidine, an inhibitor of DNA polymerase beta. Based on these results, the anticlastogenic effect of vanillin was considered to be due to the promotion of the DNA rejoining process in which DNA polymerase beta acts.     

Mutation induction with UV- and X-radiations in spores and vegetative cells of Bacillus subtilis.

Spores and vegetative cells of Bacillus subtilis strains with various defects in DNA-repair capacities (hcr-, ssp-, hcr-ssp-) were irradiated with UV radiation or X-rays. Induced mutation frequency was determined from the observed frequency of prototrophic reversion of a suppressible auxotrophic mutation. At equal physical dose, after either UV- or X-irradiation, spores were more resistant to mutations as well as to killing than were vegetative cells. However, quantitative comparison revealed that, at equally lethal doses, spores and vegetative cells were almost equally mutable by X-rays whereas spores were considerably less mutable by UV than were vegetative cells. Thus, as judged from their mutagenic efficiency relative to the lethality, X-ray-induced damage in the spore DNA and the vegetative DNA were equally mutagenic, while UV-induced DNA photoproducts in the spore were less mutagenic than those in vegetative cells. Post-treatment of UV-irradiated cells with caffeine decreased the survival and the induced mutation frequency for either spores or vegetative cells for all the strains. In X-irradiated spores, however, a similar suppressing effect of caffeine was observed only for mutability of a strain lacking DNA polymerase I activity.     

Purification and characterization of an endonuclease specific for apurinic sites in DNA from a permanently established mouse plasmacytoma cell line.

An endonuclease specific for apurinic sites in double stranded DNA has been purified 373-fold from the nuclei of mouse plasmacytoma cells (line MPC-11). The enzyme is free of any detectable amounts of aspecific nucleases. The enzyme does not act on methylated or OsO4-treated DNA. However, high doses of UV-light and gamma-rays render the DNA slightly susceptible to endonucleolytic attack, which is believed to be due to depurination of depyrimidination caused by the treatment. The molecular weight of the enzyme is determined to be 28,000 and its apparent Km of the purified enzyme is calculated to be 2.7 nM apurinic sites. The activity is not absolutely dependent upon the presence of Mg2+ in the assay mixture although metal chelating agents such as sodium citrate and EDTA abolish the activity completely. The nuclease was stimulated by moderate concentrations of potassium chloride optimizing at 50 mM, and higher concentrations inhibiting the activity. The pH optimun for the reaction was 9.5.     

In vitro detection of endonuclease IV-specific DNA damage formed by bleomycin in vivo.

Endonuclease IV of Escherichia coli has been implicated by genetic studies in the repair of DNA damage caused by the antitumor drug bleomycin, but the lesion(s) recognized by this enzyme in vivo have not been identified. We used the sensitive primer activation assay, which monitors the formation of 3'-OH groups that support in vitro synthesis by E.coli DNA polymerase I, to determine whether endonuclease IV-specific damage could be detected in the chromosomal DNA of cells lacking the enzyme after in vivo treatment with bleomycin. Chromosomal DNA isolated after a 1 h bleomycin treatment from wild-type, endonuclease IV-deficient (nfo-) and endonuclease IV-overproducing (p-nfo; approximately 10-fold) strains all supported modest polymerase activity. However, in vitro treatment with purified endonuclease IV activated subsequent DNA synthesis with samples from the nfo- strain (an average of 2.6-fold), to a lesser extent for samples from wild-type cells (2.1-fold), and still less for the p-nfo samples (1.5-fold). This pattern is consistent with the presence of unrepaired damage that correlates inversely with the in vivo activity of endonuclease IV. Incubation of the DNA from bleomycin-treated nfo- cells with polymerase and dideoxynucleoside triphosphates lowered the endonuclease IV-independent priming activity, but did not affect the amount of activation seen after endonuclease IV treatment. Primer activation with DNA from the nfo- strain could also be obtained with purified E.coli exonuclease III in vitro, but a quantitative comparison demonstrated that endonuclease IV was > or = 5-fold more active in this assay. Thus, endonuclease IV-specific damage can be detected after in vivo exposure to bleomycin. These may be 2-deoxy-pentos-4-ulose residues, but other possibilities are discussed.     

Effect of low-dose radiation on repair of DNA and chromosome damage

In this report results of studies on the effect of different doses of low LET (linear energy transfer) radiations on the unscheduled DNA synthesis (UDS) and DNA polymerase activity as well as the induction of adaptive response in bone marrow cells (BMC) by low dose radiation were presented. It was found that whole-body irradiation (WBI) with X-ray doses above 0.5 Gy caused a dose-dependent depression of both UD5 and DNA polymerase activity, while low dose radiation below 250 mGy could stimulate the DNA repair synthesis and the enzyme activity. WBI of mice with low doses of X-rays in the range of 2-100 mGy at a dose rate of 57.3 mGy per minute induced an adaptive response in the BMC expressed as a reduction of chromosome aberrations following a second exposure to a larger dose (0.65 mGy). It was demonstrated that the magnitude of the adaptive response seemed to be inversely related to the induction dose. The possibility of induction of adaptive response in GO phase of the cell cycle and the possibility of a second induction of the adaptive response were discussed.     

Heat-induced alterations in DNA polymerase activity of HeLa cells and of isolated nuclei. Relation to cell survival

The activity of DNA polymerase alpha and beta was assayed in heated HeLa S3 cells as well as in nuclei isolated from these cells. The enzyme activity as measured in cells and in nuclei has been compared with the extent of cell survival after the different hyperthermic doses. It was found that although the activity of the cellular DNA polymerases was related to cell survival after single heat doses, no correlation was found when thermotolerant cells were heated. When the activity of the DNA polymerases was determined in nuclei isolated from non-heated and heated cells, more polymerase activity was found in the nuclei of the heated cells. However, the heat sensitivity of DNA polymerase activity was the same for nuclei isolated from control, pre-heated and thermotolerant cells. Heat protection of polymerase activity by erythritol and sensitization by procaine was found when cells, but not when nuclei, were heated in the presence of these modifiers. It is concluded that (the nuclear bound) DNA polymerases are not to be considered as key enzymes in cellular heat sensitivity of HeLa S3 cells.