The repair of bleomycin-induced DNA damage and its relationship to chromosome aberration repair.

Previous studies using the technique of premature chromosome condensation indicated that nearly one-half of the bleomycin-induced chromatid breaks and gaps in CHO cells could be repaired within 1 h (repair starting at 30 min) after treatment. Cycloheximide and streptovitacin A (but not hydroxyurea or hycanthone) inhibited chromosome repair. The purpose of this study was to measure the kinetics of DNA repair after bleomycin treatment using the alkaline elution technique and to determine whether various inhibitors could block this repair. After bleomycin treatment, the major proportion of the repair of DNA damage occurred within 15 min, with significant repair evident by 2 min. This fast repair component was inhibited by 0.2% EDTA. A slower repair component was observed to occur up to 60 min after bleomycin treatment. None of the inhibitors tested were found to have a significant effect on the repair of bleomycin damage at the DNA level. Since chromosome breaks were observed not to begin repair until after 30 min while over 50% of the DNA was repaired by 15 min, these results suggest that the DNA lesions that are repaired quickly are not important in the formation of chromosome aberrations. Further, since cycloheximide and streptovitacin A blocked chromosome repair but had little measurable effect on DNA repair, these results suggest that the DNA lesions responsible for chromosome damage represent only a small proportion of the total DNA lesions produced by bleomycin.     

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.     

Induction by chemical clastogens of aberrations in prematurely condensed interphase chromatin of Chinese hamster ovary cells

The clastogenic activities of diepoxybutane and bleomycin were comparatively studied on prematurely condensed interphase chromatin and metaphase chromosomes of Chinese hamster ovary cells. The yield of chromosomal aberrations was distinctly higher in G2-premature chromosome condensation as compared to metaphase. Most notably, the clastogenic activity of bleomycin was visible in premature chromosome condensation after application of much lower final concentrations than necessary for induction of chromosome aberrations in metaphase. In addition, the different mechanisms of action of both clastogens were reflected by the aberration yield in GI and G2 immediately after exposure. While bleomycin induced aberrations throughout all stages of interphase, diepoxybutane did not induce aberrations in GI or G2. Though certainly not a routine system for genotoxicity testing, premature chromosome condensation analyses provide a powerful opportunity to demonstrate relationships between DNA damage and repair, and the production of chromosomal changes at the site of their formation.Abbreviations BM bleomycin - BrdUrd bromodeoxyuridine - CHO Chinese hamster ovary - DEB diepoxybutane - DMSO dimethylsulfoxide - FCS fetal calf serum - PCC premature chromosome condensation, prematurely condensed chromosomes - PEG polyethylene glycol     

Initial chromosome damage but not DNA damage is greater in ataxia telangiectasia cells.

Cells derived from individuals with ataxia telangiectasia (AT) exhibit increased sensitivity to ionizing radiation and certain drugs (e.g., bleomycin, neocarzinostatin, and etoposide) as evidenced by decreased survival and increased chromosome aberrations at mitosis when compared with normal cell lines. To understand better the basis of this sensitivity, three AT and two normal lymphoblastoid cell lines were fractionated into cell cycle phase-enriched populations by centrifugal elutriation and then examined for their survival and their relative initial levels of DNA damage (neutral DNA filter elution) and chromosome damage (premature chromosome condensation). AT cells exhibited decreased levels of survival in all phases of the cell cycle; however, AT cells in early G1 phase were especially sensitive compared with normal cells in G1 phase. While AT and normal cells exhibited similar levels of initial DNA double-strand breaks in exponential populations as well as throughout the cell cycle, AT cells showed nearly twofold higher initial levels of chromosome damage than normal control cells in G1 and G2 phase. These results suggest that there is a higher rate of conversion of DNA double-strand breaks into chromosome breaks in AT cells, perhaps due to a difference in chromatin organization or stability. Thus one determining component of cellular radiosensitivity might include chromatin structure.     

Responses of Huntington's disease and ataxia telangiectasia lymphoblastoid cells to bleomycin

Ionizing radiation sensitive, mutant human lymphoblastoid cell lines derived from patients with Huntington's disease (HD), or ataxia telangiectasia (AT) both showed cross sensitivity to bleomycin, as assayed by reduced cell viability and increased frequency of chromosome aberrations compared to normal controls. In contrast to AT cells which failed to show inhibition of DNA synthesis after exposure to ionizing radiation, or bleomycin treatment, the sensitive cells from HD patients had depressed rates of DNA synthesis after damage with these agents, similar to that seen in normal cells. In terms of progression through the cell cycle bleomycin damaged AT cells moved from G1 into S and from S to G2 + M at almost the same rate as untreated cells. Bleomycin treated HD cells showed a large proportion of cells blocked in G1, cells were slowed down in S, the rate of entry to G2 + M was reduced and only 5% of cycling cells reached G2. Progress through the cell cycle in normal cells exposed to bleomycin showed a partial block in G1 and the rate of entry to G2 + M was reduced. These differences in response of normal, AT and HD cells to ionizing radiation and bleomycin treatment indicates that the defect underlying the sensitivity is different in HD cells from that in AT cells.     

Comparison of DNA Strand Break Induction in CHO Cells Measured by Alkaline Elution and by Fluorometric Analysis of DNA Unwinding (FADU)

DNA damage in X-irradiated CHO cells was measured by alkaline filter elution and compared to fluorometric analysis of DNA unwinding (FADU). The FADU method proved to be as sensitive as the alkaline filter elution technique in detecting X-ray induced DNA breaks. Strand break induction was also measured after treatment with four radical generating chemicals (hydrogen peroxide, bleomycin, mitomycin C and methyl viologen) using the FADU technique.     

Comparison of DNA Strand Break Induction in CHO Cells Measured by Alkaline Elution and by Fluorometric Analysis of DNA Unwinding (FADU)

DNA damage in X-irradiated CHO cells was measured by alkaline filter elution and compared to fluorometric analysis of DNA unwinding (FADU). The FADU method proved to be as sensitive as the alkaline filter elution technique in detecting X-ray induced DNA breaks. Strand break induction was also measured after treatment with four radical generating chemicals (hydrogen peroxide, bleomycin, mitomycin C and methyl viologen) using the FADU technique.     

The relevance of caffeine post-treatment to SCE incidence induced in Chinese hamster cells

The influence of caffeine post-treatment on sister-chromatid exchanges (SCE) and chromosomal aberration frequencies on Chinese hamster cells exposed to a variety of chemical and physical agents followed by bromodeoxyuridine (BrdUrd) was determined. After 2 h treatment, N-methyl-N′-nitrosoguanidine (MNNG) and cis-platinum(II)diamine dichloride (cis-Pt(II)) induced a 7- and 6-fold increase in SCE, respectively, while 4-nitroquinoline-1-oxide (4NQO), methyl methanesulfonate (MMS), proflavine, and N-hydroxyfluorenylacetamide (OH-AAF) caused a 2–3-fold increase in SCE compared to controls treated with BrdUrd alone. Ultraviolet light doubled the number of SCE. The lowest increase of SCE was obtained with bleomycin and X-irradiation. Caffeine post-treatment caused a statistically significant increase in the frequency of SCE induced by UV- and X-irradiation as well as by 4NQO and MMS but did not alter the number of SCE induced by MNNG, cis-Pt(II), proflavine, OH-AAF, and bleomycin.

Caffeine post-treatment increased the number of cells with chromosomal aberrations induced by MNNG, cis-Pt(II), UV, 4NQO, MMS, and proflavine. With the exception of proflavine, these agents are dependent on DNA and chromosome replication for the expression of the chromosomal aberrations. Caffeine enhancement of cis-Pt(II) chromosomal aberrations occurred independently of the time interval between treatment and chromosome preparations. Chromosomal damage produced by bleomycin and X-irradiation, agents known to induce chromosomal aberrations independent of “S” phase of the cell cycle, as well as the damage induced with OH-AAF was not influenced by caffeine post-treatment.

The enhancement by caffeine, an inhibitor of the gap-filling process in post-replication repair, of chromosomal aberrations induced by “S” dependent agents, is consistent with the involvement of this type of repair in chromosomal aberration formation. The lack of inhibition of SCE frequency by caffeine indicates that post-replication repair is probably not important in SCE formation.     

The relationship of DNA and chromosome damage to survival of synchronized X-irradiated L5178Y cells. I. Initial damage

We investigated the role of initial DNA and chromosome damage in determining the radiosensitivity difference between the variant murine leukemic lymphoblast cell lines L5178Y-S (sensitive) and L5178Y-R (resistant) and the difference in cell cycle-dependent variations in radiosensitivity of L5178Y-S cells. We measured initial DNA damage (by the neutral filter elution method) and chromosome damage (by the premature chromosome condensation method) and compared them with survival (measured by cloning) for both cell lines synchronized in G1 or G2 phase of the cell cycle (by centrifugal elutriation) and irradiated with low doses of X rays (up to 10 Gy). The initial yield of DNA and chromosome damage in G2 L5178Y-S cells was almost twice that in G1 L5178Y-S cells and G1 or G2 L5178Y-R cells. In all cases DNA damage expressed as relative elution corresponded with chromosome damage (breaks in G1 chromosomes, breaks and gaps in G2 chromosomes). Also we found that the initial DNA and chromosome damage did not determine cell age-dependent radiosensitivity variations in L5178Y-S cells, as there was less initial damage in the more sensitive G1 phase than in the G2 phase. L5178Y-R cells showed only small changes in survival or initial yield of DNA and chromosome damage throughout the cell cycle. Because survival and initial damage in sensitive and resistant cells irradiated in G2 phase correlated, the difference in radiosensitivity between L5178Y-S and L5178Y-R cells might be determined by initial damage in G2 phase only.     

Defective repair of DNA single- and double-strand breaks in the bleomycin- and X-ray-sensitive Chinese hamster ovary cell mutant, BLM-2

Using filter elution techniques, we have measured the level of induced single- and double-strand DNA breaks and the rate of strand break rejoining following exposure of two Chinese hamster ovary (CHO) cell mutants to bleomycin or neocarzinostatin. These mutants, designated BLM-1 and BLM-2, were isolated on the basis of hypersensitivity to bleomycin and are cross-sensitive to a range of other free radical-generating agents, but exhibit enhanced resistance to neocarzinostatin. A 1-h exposure to equimolar doses of bleomycin induces a similar level of DNA strand breaks in parental CHO-K1 and mutant BLM-1 cells, but a consistently higher level is accumulated by BLM-2 cells. The rate of rejoining of bleomycin-induced single- and double-strand DNA breaks is slower in BLM-2 cells than in CHO-K1 cells. BLM-1 cells show normal strand break repair kinetics. The level of single- and double-strand breaks induced by neocarzinostatin is lower in both BLM-1 and BLM-2 cells than in CHO-K1 cells. The rate of repair of neocarzinostatin-induced strand breaks is normal in BLM-1 cells but retarded somewhat in BLM-2 cells. Thus, there is a correlation between the level of drug-induced DNA damage in BLM-2 cells and the bleomycin-sensitive, neocarzinostatin resistant phenotype of this mutant. Strand breaks induced by both of these agents are also repaired with reduced efficiency by BLM-2 cells. The neocarzinostatin resistance of BLM-1 cells appears to be a consequence of a reduced accumulation of DNA damage. However, the bleomycin-sensitive phenotype of BLM-1 cells does not apparently correlate with any alteration in DNA strand break induction or repair, as analysed by filter elution techniques, suggesting an alternative mechanism of cell killing.     

Sequential monitoring of cytogenetic damage in rat lymphocytes following in vivo exposure to aflatoxin B1 and N-nitrosophenacetin

Rats were treated intraperitoneally with different concentrations of aflatoxin B1 (AFB1) or N-nitrosophenacetin (NP). Blood was sequentially drawn by venous puncture at 6, 24, 72, 120 h and 14 days after a single injection of AFB1 or NP. After AFB1 the frequency of SCEs and chromosome aberrations increased progressively and reached a maximum level after 24 h and then decreased with time. By 2 weeks post treatment, the SCE and chromosome aberration values were within the control range. A small but significant SCE induction was observed when rats were treated with NP, but no chromosome breakage was induced even at the highest dose (20 mg/kg). We suggest that the elimination of DNA damage by repair mechanisms and lymphocyte turnover is responsible for the reduction of SCEs and chromosome aberrations with time. This assay seems promising for sequential monitoring of cytogenetic damage in rat lymphocytes following in vivo exposure to genotoxicants.     

Induction and repair of psoralen cross-links in DNA of normal human and xeroderma pigmentosum fibroblasts

Skin fibroblasts from normal human subjects were exposed in vitro to long-wave ultraviolet radiation (UVA, 320–400 nm) alone, or in combination with 8-methoxypsoralen (8-MOP). DNA damage was analysed with the alkaline elution technique before and after post-treatment incubation of the cells at 37°C for various times.Cells treated with UVA at 1.1 J/cm² showed an increased DNA elution rate, which returned to the normal level within 30 min of post-treatment incubation. In cells treated with PUVA (8-MOP at 20 μg/ml plus UVA at 0.04 J/cm²), the alkaline elution rate was not different from untreated control cells, either before or after post-treatment incubation for times up to 7 days.When the PUVA treatment was followed first by a washing, to remove any unbound 8-MOP, and then by UVA (PUVA + UVA) at 1.1 J/cm², the alkaline elution rate decreased below the control level. During the post-treatment incubation of the PUVA + UVA-treated cells there was a gradual increase of the alkaline elution rate to a level significantly above that in control cells. This increase was observed after 30 min. It reached a miaximum after 24 h and remained after 7 days of post-treatment incubation. Cells from a patient with xeroderma pigmentosum of complementation group A, which were given the same PUVA + UVA treatment, did not show any change in the alkaline elution rate during the post-treatment incubation.If, as seems likely, an increased alkaline elution rate indicates an increase of DNA breaks, and a decreased alkaline elution rate indicates the sealing of breaks and/or the formation of cross-links, the results would suggest the following: (1) UVA irradiation in itself is capable of inducing DNA breaks, which are rapidly sealed during post-treatment incubation; (2) PUVA treatment induces mono-adducts, some of which appear to remain in the DNA for at least 7 days of post-treatment incubation and can be activated to form DNA cross-links by a second dose of UVA; (3) DNA cross-links induced by PUVA + UVA can be recognized by a repair process that involves the formation of DNA breaks. This process is not observed in xeroderma pigmentosum cells of group A.     

Induction of chromosome damage by restriction enzymes during mitosis.

Once electroporated into the nucleus of eukaryotic cells, restriction enzymes will bind at specific DNA sequences and cleave DNA to make double-strand breaks. These induced breaks can lead to chromosome aberrations and consequently offer one approach to determining the mechanism(s) of aberration formation. Because the higher-order structure of DNA in eukaryotic cells might influence the ability of restriction enzymes to locate their recognition sequence, bind, and cleave DNA, we have investigated whether enzymes will cut DNA during metaphase when the chromosomes are most condensed. Chinese hamster ovary cells synchronized in mitosis and treated with either AluI or Sau3AI showed few chromosome aberrations when held in mitosis for 1, 2, or 3 h after enzyme treatment. However, some disruption of chromosome morphology was seen, especially after exposure to Sau3AI. When cells were allowed to complete one cell cycle after enzyme treatment in the preceding mitosis, there was extensive chromosome damage, with the most abundant type of lesion being the interstitial deletion. It appears that restriction enzymes will cleave the highly condensed DNA in mitotic cells but that decondensation, DNA replication, and recondensation are required before the aberrations are manifested.     

Induction by H2O2 of DNA and interphase chromosome damage in plateau-phase Chinese hamster ovary cells.

The induction by H2O2 of DNA breaks, DNA double-strand breaks (DSBs), and interphase chromatin damage and their relationship to cytotoxicity were studied in plateau-phase Chinese hamster ovary (CHO) cells. Damage in interphase chromatin was assayed by means of premature chromosome condensation (PCC); DNA DSBs were assayed by nondenaturing filter elution (pH 9.6), and DNA breaks by hydroxyapatite chromatography. Cells were treated with H2O2 in suspension at 0 degrees C for 30 min and treatment was terminated by the addition of catalase. Concentrations of H2O2 lower than 1 mM were not cytotoxic, whereas concentrations of 40 and 60 mM reduced cell survival to 0.1 and 0.004, respectively. An induction of DNA breaks that was dependent on H2O2 concentration was observed at low H2O2 concentrations that reached a maximum at approximately 1 mM; at higher H2O2 concentrations induction of DNA breaks either remained unchanged or decreased. Damage at the chromosome level was not evenly distributed among the cells, when compared to that expected based on a Poisson distribution. Three categories of cells were identified after exposure to H2O2: cells with intact, control-like chromosomes, cells showing chromosome fragmentation similar to that observed in cells exposed to ionizing radiation, and cells showing a loss in the ability of their chromatin to condense into chromosomes under the PCC reaction. The fraction of cells with fragmented chromosomes, as well as the number of excess chromosomes per cell, showed a dose response similar to that of DNA DSBs, reaching a maximum at 1 mM and decreasing at higher concentrations. The results indicate that induction of DNA and chromosome damage by H2O2 follows a complex dependence probably resulting from a depletion of reducing equivalents in the vicinity of the DNA. Reducing equivalents are required to recycle the transition metal ions that are needed to maintain a Fenton-type reaction. The absence of cell killing at H2O2 concentrations that yielded the maximum amount of DNA and chromosome damage suggests that this damage is nonlethal and repairable. It is suggested that lethal DNA and chromosome damage is induced at higher concentrations of H2O2 where cell killing is observed by an unidentified mechanism.     

Comet-FISH for the evaluation of plant DNA damage after mutagenic treatments

The aim of this study was to perform a comparative investigation of the actions of three mutagens that are widely used in plant mutagenesis using the comet-FISH technique. The comet-FISH technique was used for the analysis of DNA damage and the kinetics of repair within specific DNA sequences. FISH with rDNA and telomeric/centromeric DNA probes was applied to comets that were obtained from an alkaline/neutral comet assay. Migration within specific DNA sequences was analysed after treatment with two chemical mutagens-maleic hydrazide (MH) and N-nitroso-N-methylurea (MNU), and γ-rays. Barley was used as a model plant in this study. The possible utility of specific DNA sequences in a comparative assessment of the distribution of DNA damage within a plant genome was evaluated. This study proved that the comet-FISH technique is suitable for a detailed quantification of DNA damage and repair within specific DNA sequences in plant mutagenesis. The analysis of FISH signals demonstrated that the involvement of specific DNA sequences in DNA damage was different and was dependent on the mutagen used. We showed that 5S rDNA and telomeric DNA sequences are more sensitive to mutagenic treatment, which was expressed by a stronger fragmentation and migration in comparison to the other probes used in the study. We found that 5S rDNA and telomeric DNA probes are more suitable for testing the genotoxicity of environmental factors. A comparison of the involvement of specific chromosome domains in direct DNA breakage/repair and in chromosome aberration formation after mutagen treatment indicates the compatibility of the results.     

DNA damage and repair in embryonic mouse limbs exposed to teratogenic doses of methylnitrosourea

The alkaline elution assay was used to monitor DNA single-strand breaks in embryonic tissue following exposure to the DNA-damaging teratogen N-methyl-N-nitrosourea (MNU, CAS No. 694-93-5). An animal model was developed in which nearly every fetus exposed to the highest dose of MNU had malformations of the hindlimbs while the fetuses exposed to the lowest dose of MNU had none. Hindlimbs pooled within litters were analyzed for DNA single-strand breaks by alkaline elution conducted at rapid (0.35 ml/min) and slow (0.35 ml/min) speeds. Breaks in the DNA of hindlimbs exposed to teratogenic doses of MNU were readily detected by alkaline elution only if slower speeds were used in the assay. Using the more sensitive procedure, DNA breakage was monitored over a 24-h period. DNA breakage peaked in the MNU-exposed hindlimbs in a dose-dependent manner 4 h after injection. While the elution profiles of hindlimbs exposed to the lower doses of MNU returned to control levels 8 h after injection, single-strand breaks persisted in the hindlimbs exposed to the highest dose of MNU for at least 20 h. These latter data suggest that the highly teratogenic dose of MNU induced DNA damage that was more slowly repaired than that produced at lower doses, possibly by saturation of DNA repair systems. Although some necrosis did occur in hindlimbs exposed at teratogenic dose levels, it was not severe and it did not appear to influence the alkaline elution results. These experiments show that alkaline elution is a sensitive assay for the detection of DNA damage in embryonic tissues.     

DNA damage processing and aberration formation in plants

Various types of DNA damage, induced by endo- and exogenous genotoxic impacts, may become processed into structural chromosome changes such as sister chromatid exchanges (SCEs) and chromosomal aberrations. Chromosomal aberrations occur preferentially within heterochromatic regions composed mainly of repetitive sequences. Most of the preclastogenic damage is correctly repaired by different repair mechanisms. For instance, after N-methyl-N-nitrosourea treatment one SCE is formed per >40,000 and one chromatid-type aberration per approximately 25 million primarily induced O6-methylguanine residues in Vicia faba. Double-strand breaks (DSBs) apparently represent the critical lesions for the generation of chromosome structural changes by erroneous reciprocal recombination repair. Usually two DSBs have to interact in cis or trans to form a chromosomal aberration. Indirect evidence is at hand for plants indicating that chromatid-type aberrations mediated by S phase-dependent mutagens are generated by post-replication (mis)repair of DSBs resulting from (rare) interference of repair and replication processes at the sites of lesions, mainly within repetitive sequences of heterochromatic regions. The proportion of DSBs yielding structural changes via misrepair has still to be established when DSBs, induced at predetermined positions, can be quantified and related to the number of SCEs and chromosomal aberrations that appear at these loci after DSB induction. Recording the degree of association of homologous chromosome territories (by chromosome painting) and of punctual homologous pairing frequency along these territories during and after mutagen treatment of wild-type versus hyperrecombination mutants of Arabidopsis thaliana, it will be elucidated as to what extent the interphase arrangement of chromosome territories becomes modified by critical lesions and contributes to homologous reciprocal recombination. This paper reviews the state of the art with respect to DNA damage processing in the course of aberration formation and the interphase arrangement of homologous chromosome territories as a structural prerequisite for homologous rearrangements in plants.     

Fractionation of DNA from mammalian cells by alkaline elution.

The method of alkaline elution provides a sensitive measure of DNA single-strand length distribution in mamalian cells and is applicable to a variety of problems concerning DNA damage, repair, and replication. The physical basis of the elution process was studied. The kinetics of elution above the alkaline transition pH were found to occur in two phases: an initial phase in which single-strand length is rate limiting, followed by a phase in which elution is accelerated due to the accumulation of alkali-induced strand breaks. The range of DNA single-strand lengths that can be discriminated by elution above the alkaline transition pH was estimated by calibration relative to the effects of x ray, and was found to be 5 X 10(8)-10(10) daltons. Shorter DNA strands elute within the pH transition zone, which extended from pH 11.3 to 11.7 when tetrapropylammonium hydroxide was used as base. This elution was relatively rapid, but was sharply limited by pH, according to the length of the strands: the length of the strands eluted increased with increasing pH. Alkaline elution was inhibited by treatment of cells with low concentrations of nitrogen mustard, a bifunctional alkylating known to cross-link DNA. On investigation of the possibility that DNA subclasses may differ in their elution behavior, satellite L strands were found to elute more slowly from cells exposed to a low dose of x ray than did the bulk DNA.     

Chromosomal instability in an oxygen-tolerant variant of Chinese hamster ovary cells

Background levels of chromosomal aberrations and sister-chromatid exchanges (SCEs) were determined in CHO-99 cells, an oxygen-tolerant variant substrain of Chinese hamster ovary (CHO-20) cells capable of stable proliferation under an atmosphere of 99% O2/1% CO2, a level of hyperoxia at which cultured mammalian cells normally cannot survive. The mean chromosomal aberration frequency in CHO-99 cells was as high as 1 aberration per cell (mainly chromatid and chromosome gaps and breaks) versus 0.05 aberration/cell in CHO-20 cells, while the SCE frequency was 1.7- to 2.1-fold increased. While most aberrations were apparently distributed at random over the chromosomes, up to 31% of the aberrations appeared to be involved in site-specific fragility at a homologous site in chromosomes Z3 and Z4. Immediately upon shifting CHO-99 cells to air-equilibrated conditions their SCE frequency decreased to the control level, whereas the aberration rate persisted at a still elevated level of 0.16-0.31 aberration per cell, even after a culture period of 14 weeks under normoxia. This indicates that at least part of the chromosomal instability is a constitutional property of the variant cells, i.e., not directly dependent upon hyperoxic stress. In CHO-99 X CHO-20 hybrids the occurrence of chromatid-type aberrations and fragile site but not that of chromosome-type aberrations was suppressed under normoxic conditions, suggesting that chromatid-type aberrations and fragile site expression on the one hand and chromosome-type aberrations on the other hand are mediated by different constitutional defects in CHO-99 cells. No gross alterations in (deoxy)ribonucleoside triphosphate pools were detected in CHO-99 cells that could be held responsible for their chromosomal instability. In addition, no increased level of DNA damage was detected by the technique of alkaline elution. The excessive chromosomal instability in CHO-99 cells, as observed under hyperoxic conditions, may originate from reactive intermediates giving rise to DNA double-strand breaks and/or a type of DNA lesion that is resistant to the conditions of the alkaline elution technique. However, alternative mechanisms based upon reactive species interfering with DNA replication/repair processes cannot be excluded.     

Calmodulin antagonist W 13 prevents DNA repair after bleomycin treatment of human urological tumor cells growing on extracellular matrix

1. The combined application of DNA strand-scission agents (bleomycin) and inhibitors of recovery from lethal damage (calmodulin antagonist W-13) could be a novel and potentially important approach to cancer therapy. 2. As determined by alkaline elution, both DNA-DNA and DNA-protein cross-links in bleomycin-treated cells were revealed by the presence of the proteinase K assay. 3. This lethal effect could be potentiated by the addition of calmodulin antagonist W-13 that prevents the repair of DNA strand breaks and DNA cross-links caused by bleomycin. 4. The results indicated that combinations of bleomycin and W-13 were more effective than treatment with either single agent. Isobologram analysis suggests synergistic effect of these drugs. 5. Therefore, the rational use of combinations of DNA-strand-scission agents and inhibitors of recovery from lethal damage based on mechanistic considerations should result with improved therapeutic regimens for the treatment of cancer.