The mode of action of 1-beta-D-arabinofuranosylcytosine in inhibiting DNA repair; new evidence using a sensitive assay for repair DNA synthesis and ligation in permeable cells

CBP and p300 acetylate PCNA to link its degradation with nucleotide excision repair synthesis

The proliferating cell nuclear antigen (PCNA) protein serves as a molecular platform recruiting and coordinating the activity of factors involved in multiple deoxyribonucleic acid (DNA) transactions. To avoid dangerous genome instability, it is necessary to prevent excessive retention of PCNA on chromatin. Although PCNA functions during DNA replication appear to be regulated by different post-translational modifications, the mechanism regulating PCNA removal and degradation after nucleotide excision repair (NER) is unknown. Here we report that CREB-binding protein (CBP), and less efficiently p300, acetylated PCNA at lysine (Lys) residues Lys13,14,77 and 80, to promote removal of chromatin-bound PCNA and its degradation during NER. Mutation of these residues resulted in impaired DNA replication and repair, enhanced the sensitivity to ultraviolet radiation, and prevented proteolytic degradation of PCNA after DNA damage. Depletion of both CBP and p300, or failure to load PCNA on DNA in NER deficient cells, prevented PCNA acetylation and degradation, while proteasome inhibition resulted in accumulation of acetylated PCNA. These results define a CBP and p300-dependent mechanism for PCNA acetylation after DNA damage, linking DNA repair synthesis with removal of chromatin-bound PCNA and its degradation, to ensure genome stability.

Trypanocidal activity of marine natural products

Marine natural products are a diverse, unique collection of compounds with immense therapeutic potential. This has resulted in these molecules being evaluated for a number of different disease indications including the neglected protozoan diseases, human African trypanosomiasis and Chagas disease, for which very few drugs are currently available. This article will review the marine natural products for which activity against the kinetoplastid parasites; Trypanosoma brucei brucei, T.b. rhodesiense and T. cruzi has been reported. As it is important to know the selectivity of a compound when evaluating its trypanocidal activity, this article will only cover molecules which have simultaneously been tested for cytotoxicity against a mammalian cell line. Compounds have been grouped according to their chemical structure and representative examples from each class were selected for detailed discussion.

Assessment of primary, oxidative and excision repaired DNA damage in hospital personnel handling antineoplastic drugs

The International Agency for Research on Cancer has classified several antineoplastic drugs in Group 1 (human carcinogens), among which chlorambucil, cyclophosphamide (CP) and tamoxifen, Group 2A (probable human carcinogens), among which cisplatin, etoposide, N-ethyl- and N-methyl-N-nitrosourea, and Group 2B (possible human carcinogens), among which bleomycins, merphalan and mitomycin C. The widespread use of these mutagenic/carcinogenic drugs in the treatment of cancer has led to anxiety about possible genotoxic hazards to medical personnel handling these drugs. The aim of the present study was to evaluate work environment contamination by antineoplastic drugs in a hospital in Central Italy and to assess the genotoxic risks associated with antineoplastic drug handling. The study group comprised 52 exposed subjects and 52 controls. Environmental contamination was assessed by taking wipe samples from different surfaces in preparation and administration rooms and nonwoven swabs were used as pads for the surrogate evaluation of dermal exposure, 5-fluorouracil and cytarabine were chosen as markers of exposure to antineoplastic drugs in the working environment. The actual exposure to antineoplastic drugs was evaluated by determining the urinary excretion of CP. The extent of primary, oxidative and excision repaired DNA damage was measured in peripheral blood leukocytes with the alkaline comet assay. To evaluate the role, if any, of genetic variants in the extent of genotoxic effects related to antineoplastic drug occupational exposure, the study subjects were genotyped for GSTM1, GSTT1, GSTP1 and TP53 polymorphisms. Primary DNA damage significantly increased in leukocytes of exposed nurses compared to controls. The use of personal protective equipment (i.e. gloves and/mask) was associated with a decrease in the extent of primary DNA damage.

Synergistic Effect of Aphidicolin and 1-β-d-arabinofuranosylcytosine on the Repair of γ-ray-induced DNA Damage in Normal Human Fibroblasts

The effects on enzymatic DNA repair of aphidicolin and 1-beta-D-arabinofuranosylcytosine (araC), two potent inhibitors of long-patch excision repair, were investigated in cultured human cells exposed to 60Co gamma-radiation. Using alkaline-sucrose velocity sedimentation analysis, both drugs were shown to inhibit markedly the repair of radioproducts in cultures exposed to greater than or equal to 150 Gy, indicating that a significant component of gamma-ray-induced DNA damage is operated on by a long-patch excision pathway. Moreover, while the extent of repair inhibited by aphidicolin was comparable to that suppressed by araC, combined exposure of irradiated cultures to the two drugs elicited a synergistic response. Specifically, in all three normal fibroblast strains examined, the yield of aphidicolin- or araC-detectable sites (lesions whose repair could be blocked by each drug alone) observed during the first 2 h after irradiation with 150 Gy ranged from 0.8 to 1.2 per 10(8) daltons genomic DNA, whereas the incidence of sites detected by combined exposure to the inhibitors was increased 4-fold (i.e. 3.8 per 10(8) daltons). This difference in site yield leads us to propose that simultaneous administration of aphidicolin and araC serves to block, in addition to long-patch repair, a second mode of excision repair which is refractory to each drug alone.

Single-cell Gel Electrophoresis Applied to the Analysis of UV-C Damage and Its Repair in Human Cells

DNA breaks in eukaryotic cells can be detected by alkaline electrophoresis of cells embedded in agarose. DNA containing breaks extends in the direction of the anode forming an image resembling the tail of a comet. We have adapted this procedure of single cell gel electrophoresis (SCGE) for studying DNA damage and repair induced by UV-C-radiation, using HeLa cells. UV-C itself does not induce DNA breakage, and though cellular repair of UV-C damage produces DNA breaks as intermediates, these are too short-lived to be detected by SCGE. Incubation of UV-C-irradiated cells with the DNA synthesis inhibitor aphidicolin causes accumulation of incomplete repair sites to a level readily detected by SCGE even after doses as low as 0.5 J m-2 and incubation for as little as 5 min. We have also used SCGE to study UV-C-dependent incision, repair synthesis and ligation in permeable cells. Finally, we have incubated permeable cells, after UV-C-irradiation, with exogenous UV endonuclease, examining the consequent breaks both by SCGE and by alkaline unwinding in order to express results of the electrophoretic method in terms of DNA break frequencies. The sensitivity of the SCGE technique can thus be estimated; as few as 0.1 DNA breaks per 10(9) daltons are detected.

Detection of excision repaired DNA damage in the comet assay by using Ara-C and hydroxyurea in three different cell types

Because of its characteristics, the comet assay has been used to evaluate the ability of virtually any type of eukaryotic cell to repair different kinds of DNA damage, including double and single strand breaks and base damage. The ability to detect excision repair sites using the alkaline version can be enhanced by the inclusion of repair inhibitors, DNA synthesis inhibitors, or chain terminators. In this sense, we evaluated the ability of hydroxyurea (HU) and cytosine arabinoside (Ara-C), for detecting lesions produced by the alkylating agents ethyl methanesulfonate (EMS) and methyl methanesulfonate (MMS) in three different cell systems. Two hundred cells for experimental point were analyzed in the alkaline version of the comet assay, and the results are evidences of the utility of the assay to detect alkylation of bases in the cells lines MRC-5 and TK-6, as the treatment with HU +Ara-C significantly increases both the basal and induced frequency of DNA damage. The use of whole blood, although it detected the effects of MMS, with and without repair inhibitors, failed to detect the effect of the selected dose of EMS and does not permit detection increases in the background level.

JP-8 jet fuel-induced DNA damage in H4IIE rat hepatoma cells

We investigated the genotoxicity of middle distillate jet fuel, Jet Propulsion 8 (JP-8), on H4IIE rat hepatoma cells in vitro. DNA damage was evaluated using the comet (single cell gel electrophoresis) assay. Cells were exposed for 4h to JP-8 (solubilized in ethanol (EtOH) at 0.1% (v/v)) to concentrations ranging from 1 to 20microg/ml. Exposure to JP-8 resulted in an overall increase in mean comet tail moments ranging from 0.74+/-0.065 (0.1% EtOH control) to 3.13+/-0.018,4.36+/-0.32,5.40+/-0.29,7.70+/-0.52 and 11.23+/-0.77 for JP-8 concentrations 3, 5, 10, 15 and 20microg/ml, respectively. Addition of DNA repair inhibitors hydroxyurea (HU) and cytosine arabinoside (Ara-C) to cell culture with JP-8 resulted in accumulation of DNA damage strand breaks and increase in comet tail length. Inclusion of 4mM HU and 40microM Ara-C with 3, 5, 10 and 20microg/ml JP-8 concentrations resulted in increased mean tail moments to 5.94+/-0.43,10.12+/-0.72,17.03+/-0.96,and29.25+/-1.55. JP-8, in the concentrations used in this study, did not result in cytotoxicity or significant apoptosis, as measured using the terminal deoxynucleotidyl transferase (TDT)-mediated dUTP-X nick end labeling (TUNEL) assay. These results demonstrate that relevant exposures to JP-8 result in DNA damage to H4IIE cells, and suggest that DNA repair is involved in mitigating these effects.

Cell cycle specificity of cytogenetic damage induced by 3,4-epoxy-1- butene

3,4-epoxy-1-butene (EB), a primary metabolite of butadiene, is a direct-acting "S-dependent" genotoxicant that can induce sister chromatid exchanges (SCEs) and chromosome aberrations (CAs) in cycling cells in vitro. However, EB is almost inactive when splenic or peripheral blood lymphocytes are exposed at the G(0) stage of the cell cycle. To investigate whether repair of DNA lesions is responsible for the lack of cytogenetic responses seen after G(0) treatments, we used cytosine arabinoside (ara-C) to inhibit DNA polymerization during DNA repair. If enough repairable lesions are present, double-strand breaks should accumulate and form chromosome-type ("S-independent") deletions and exchanges. This is exactly what occurred. EB induced chromosome deletions and dicentrics at the first division following treatment, when the EB exposure was followed by ara-C. Without ara-C treatment, there was no induction of CAs. These experiments indicate that the relatively low levels of damage induced by EB in G(0) lymphocytes are removed by DNA repair prior to DNA synthesis and thus, before the production of SCEs or chromatid-type aberrations.

Comet assay detects cold repair of UV-A damages in a human B-lymphoblast cell line

During DNA repair studies, cells are occasionally kept on ice in order to suppress DNA repair. In the present studies cultivated human NC37 B-lymphoblasts were damaged by UV-A irradiation (365 nm) and DNA single strand breaks were detected at the single cell level with the alkaline comet assay in the temperature range from 4 degrees C to 44 degrees C. Single cell studies, in contrast to bulk experiments, allow to identify apoptotic or necrotic cells, which can be omitted for data analysis. Unexpectedly, similarly efficient single phase repair kinetics was found at all temperatures below 37 degrees C, i.e., particularly also in the cold. For recovery times below 20 min a linear decrease of DNA damage was detected. After 20 min, no additional repair was observed, i.e., complete repair of single strand breaks was not achieved. At 44 degrees C DNA damage increased with time, probably due to heat damage and cell death. Nucleotide excision repair inhibitors such as aphidicolin, 1-beta-D-arabinofuranosyl cytosine (araC) and hydroxyurea, but not the base excision repair inhibitor methoxyamine caused a strong increase in DNA strand breaks. The use of repair inhibitors confirmed DNA repair at 4 degrees C. In conclusion, partial repair of UV-A damage is similar at 37 degrees C and 4 degrees C and is probably governed by nucleotide excision repair. Keeping samples on ice may not result in a total suppression of DNA repair.

DNA damage, gadd153 expression, and cytotoxicity in plateau-phase renal proximal tubular epithelial cells treated with a quinol thioether

2-Bromo-bis-(glutathion-S-yl)hydroquinone [2-Br-bis-(GSyl)HQ] causes DNA single-strand breaks (SSB), causes growth arrest, induces the expression of gadd153 (a gene inducible by growth arrest and DNA damage), and decreases histone H2B mRNA in log-phase renal proximal tubular epithelial cells (LLC-PK1). Renal epithelial cells in vivo normally exhibit a low mitotic index, therefore experiments in both plateau- and log-phase cells are necessary for a comprehensive understanding of the stress response to 2-Br-bis-(GSyl)HQ. In the present article we demonstrate that not all features of the stress response in log-phase cells are reproduced in plateau-phase cells. Thus, although 2-Br-bis-(GSyl)HQ causes concentration and time-dependent increases in DNA SSB, and increases the expression of gadd153, histone H2B mRNA levels are unaltered in plateau-phase cells. The relationship between reactive oxygen species, DNA damage, gene expression, and cytotoxicity was also investigated. Our findings suggest that (i) 2-Br-bis-(GSyl)HQ-mediated DNA damage in LLC-PK1 cells is mediated by the generation of H2O2; (ii) DNA damage, either directly or indirectly, contributes to cell death; and (iii) DNA damage, either directly or indirectly, provides the initial signal for gadd153 expression. In addition, DNA repair is rapid in LLC-PK1 cells, and the DNA-repair inhibitors 1-beta-D-arabinofuranosylcytosine and hydroxyurea have no effect on the amount of DNA SSB. Although the addition of 3-aminobenzamide following 2-Br-bis-(GSyl)HQ exposure has no effect on the removal of DNA SSB, it causes a slight but significant increase in gadd153 expression and cell viability, indicating that activation of poly(ADP-ribose)polymerase may exacerbate toxicity. Finally, aurintricarboxylic acid did not prevent DNA SSB or cytotoxicity in 2-Br-bis-(GSyl) HQ-treated LLC-PK1 cells, implying that activation of endonucleases does not play a role in these processes.

Influence of ara A on the formation of dicentrics in irradiated quiescent CHO cells

CHO K1-cells, arrested in G0/G1 phase were irradiated with graded doses of 150-kV X-rays, and the dicentric chromosome aberrations in the first metaphase after reincubation in full growth medium were evaluated. When 500 microM ara A was administered at least 1 h before irradiation, maximal enhancement of the dicentric yield was obtained under 'immediate plating' conditions as well as under 'delayed plating' conditions, and under both conditions only the linear component alpha D of the aberration yield was affected. Since ara A had no effect upon the number of induced dsbs, as measured with PFGE at doses up to 100 Gy, the action pathway of ara A is suggested to be the repair/misrepair process manifested in the linear component of the dicentric yield. By varying the time at which either ara A at 37 degrees C was administered before irradiation or ara A at 4 degrees C was added after irradiation, it was observed that the repair step sensitive to ara A was completed within about 5 min after irradiation. This is in agreement with other observations of ara A action upon a fast repair step. The conversion of DNA single-strand breaks or base damage sites into double-strand breaks as a consequence of polymerase beta inhibition by ara A would explain the present results.

The suitability of the micronucleus assay in human lymphocytes as a new biomarker of excision repair

The cytokinesis blocked micronucleus assay is relatively insensitive to detect agents that predominantly induce excision repairable DNA lesions. However, it has been recently proposed that excision-repairable DNA lesions induced in G0/G1 phase can be converted to micronuclei by using inhibitors of the gap filling step of excision repair so that unfilled gaps are converted to double stranded breaks after S phase and micronuclei (MN) at completion of mitosis. As it has been recently demonstrated this process could be improved by combining cytosine arabinoside (ARA-C) and hydroxyurea (HU). In the present work, we have investigated the suitability of this new approach by studying its ability to detect excision repairable DNA lesions induced by 10 pesticides (alachlor, atrazine, cypermethrin, deltamethrin, fenpropathrin, fenvalerate, maleic hydrazide, paraquat, permethrin and trifluralin) and 3 well-known mutagenic agents (ethyl methane sulphonate, EMS; methylnitrosourea, MNU; and mytomicin C, MMC). Our results showed that the combination of ARA-C and HU substantially increased the level of MN in whole blood lymphocyte cultures, but it provided an excess of toxicity when further treatments, such as MNU, were performed. When ARA-C alone was used, the ARA/CBMN assay appeared to be highly sensitive and specific in detecting agents known to induce excision repairable DNA lesions. Thus, EMS and MNU but not MMC greatly induced DNA excision repair. On the other hand, alachlor, permethrin and, to a lesser extent, trifluralin and fenpropathrin also increased the ratio of excision repairable DNA lesions converted to MN. On the contrary, atrazine, cypermethrin, deltamethrin, fenvalerate, maleic hydrazide and paraquat did not induce excision repair.

Effect of DNA polymerase inhibitors on repair of gamma ray-induced DNA damage in proliferating (intact versus permeable) human fibroblasts: evidence for differences in the modes of action of aphidicolin and 1-beta-D-arabinofuranosylcytosine

The mammalian DNA polymerase inhibitors aphidicolin and 1-beta-D-arabinofuranosylcytosine (araC), when used in combination, inhibit the repair of DNA damage induced by gamma rays or 4-nitroquinoline 1-oxide in normal human fibroblasts to an extent 2- to 4-fold greater than that seen with each inhibitor alone. Thus either aphidicolin modulates the rate of intracellular accumulation of araC 5'-triphosphate (araCTP), the presumed rate-limiting step in the genotoxic action of araC, or aphidicolin and araC inhibit repair by different mechanisms. To explore these possibilities, we compared the effects of aphidicolin, araC, araCTP, and 2',3'-dideoxythymidine triphosphate (ddTTP) on repair of DNA damage induced by 60Co gamma radiation in intact versus permeable human fibroblasts. Both aphidicolin and araC strongly inhibited repair in permeable cells, as indicated by the accumulation of DNA strand breaks in irradiated cultures that were subsequently treated with saponin (25 micrograms/ml; 10 min) and incubated for 2 h with either chemical. The extent of repair inhibition by each drug was comparable in intact and permeable cells, amounting to approximately 1.1 sites/10(8) daltons/2 h upon exposure to 150 Gy. The active metabolite of araC, araCTP, did not inhibit repair in intact cells, but did so in permeable cells to an extent within the range of that seen with araC or aphidicolin alone. The incidence of DNA strand breaks accumulating in gamma-irradiated permeable cultures as a result of incubation with araCTP plus aphidicolin, or araC plus aphidicolin, was approximately 2-fold greater than that arising in parallel cultures which had been incubated with optimal concentrations of each of the three drugs alone. Although the resolution of our assays compelled us to monitor repair events in moribund cell populations, we have reason to be confident that within the short post-irradiation period considered here, the observed drug-accumulated breaks truly represent functional repair inhibition and not merely abortive pathological responses. We thus conclude that (1) the accumulation of araCTP in intact cells is not limiting the ability of araC to inhibit DNA repair; and (2) the mode of the inhibitory action of araC/araCTP on gamma ray repair is different from that of aphidicolin. In contrast to the observations with these chemicals, ddTTP (20 microM), a potent inhibitor of DNA polymerase beta, did not produce any measurable effect on DNA repair in gamma-irradiated permeable fibroblasts, nor did it enhance the efficacy of araC, araCTP or aphidicolin to inhibit repair. These results strongly suggest that DNA polymerase beta plays no significant role in the repair of gamma radioproducts in human fibroblasts.(ABSTRACT TRUNCATED AT 400 WORDS)

Lack of effect of inhibitors of DNA synthesis/repair on the ionizing radiation-induced chromosomal damage in G2 stage of ataxia telangiectasia cells

The relationship between the repair processes occuring at the G2 phase of the cell cycle and cytogenetic damage in ataxia telangiectasia (AT) cells was studied. Lymphoblastoid cells derived from normal, heterozygote AT (HzAT) and three AT patients were exposed to X-rays or fission neutrons and post-treated with inhibitors of DNA synthesis/repair, such as inhibitors of DNA polymerases alpha, delta and epsilon (cytosine arabinoside, ara-C; aphidicolin, APC; buthylphenylen-guanine, BuPdG) or ribonucleotide reductase (hydroxyurea, HU). A strong increase of radiation-induced chromosomal aberrations was observed in normal and HzAT cells post-treated with ara-C, APC and HU, but not in the presence of BuPdG. No enhancing effect was observed in cells derived from AT patients, except for HU post-irradiation treatment. These results suggest that the enzymes that can be inhibited by these agents are not directly involved in the repair of radiation damage induced in G2 cells from AT patients, indicating that probably the AT cells that we used lack the capability to transform the primary DNA lesions into reparable products, or that AT cells might contain a mutated form of DNA polymerase resistant to the inhibitors.

Enhancement of X-ray toxicity in squamous cell carcinoma cell lines by DNA polymerase inhibitors

The effect of the DNA polymerase inhibitors adenine 9-beta-arabinofuranoside (ara-A), cytosine 1-beta-arabinofuranoside (ara-C), and aphidicolin on X-radiation sensitivity was studied in a group of exponentially growing squamous cell carcinoma cell lines. The tumour cell lines varied in radiation sensitivity, with D0 (radiation sensitivity) values ranging from 1.0 to 3.9 Gy. The addition of non-toxic concentrations of ara-A 30 min before irradiation and removal 30 min after irradiation potentiated cell killing in five of eight cell lines. Four of these five responsive cell lines were relatively radioresistant lines, having D0 > 2.0 Gy. One of the cell lines was more radiosensitive (D0 = 1.4 Gy). Ara-A was also effective in potentiating killing in the radioresistant cell lines even when added 60 min after irradiation. Pre- or post-treatment with ara-A had no effect on X-ray sensitivity of the other three relatively sensitive cell lines (D0 ranging from 1.0 to 1.3 Gy). Both ara-C and aphidicolin were effective in potentiating X-ray sensitivity in JSQ-3, a relatively resistant cell line that was sensitized by ara-A treatment, but they had no effect on the X-ray sensitivity of SCC-61, a relatively radiosensitive cell line that was insensitive to ara-A effects on X-ray response. At the concentrations used, the polymerase inhibitors were equally effective in inhibiting DNA synthesis.

Detection of DNA double-strand breaks through the cell cycle after exposure to X-rays, bleomycin, etoposide and 125IdUrd

Ionizing radiation-induced DNA double-strand breaks (DSBs) are generally more difficult to detect in S-phase cells than in cells from other phases of the cell cycle. To explore the basis for this observation, other double-strand breaking agents were examined: etoposide, bleomycin and 125IdUrd. DSBs induced by these agents in single cells in S, G1 or G2/M-phases of cell cycle were measured using the neutral comet assay. Regardless of the nature or location of the DSBs, Chinese hamster V79 cells with S-phase DNA content showed about 2-3 times less damage by all agents than cells with G1 or G2/M-phase DNA content. Residual protein content measured after lysis of S-phase cells embedded in agarose did not differ significantly from the protein content of asynchronous cells, and removal of proteins prior to irradiation did not enhance S phase migration. The number of DSBs, the physical nature of the DSB, or the presence of residual proteins, did not appear to influence migration. Therefore, we conclude that differences in DNA structure are responsible for reduced sensitivity for detecting DSBs in S-phase cells.

Nickel chloride inhibits the DNA repair of UV-treated but not methyl methanesulfonate-treated Chinese hamster ovary cells

Nickel, a human carcinogen, has been shown to enhance the cytotoxicity, mutagenicity, and sister-chromatid exchanges (SCE) induced by ultraviolet (UV) light but not by methyl methanesulfonate (MMS). To verify that the cocytotoxicity and cogenotoxicity of nickel are correlated with its inhibition on DNA repair, the effects of nickel on the DNA repair induced by UV and by MMS have been investigated. Our analyses of DNA repair of single-strand breaks by alkaline elution and alkaline sucrose sedimentation indicate that nickel inhibited the DNA repair in UV-treated, but not in MMS-treated cells. Therefore, the inhibition of DNA repair seems to play an important role in the cocytotoxicity and comutagenicity of nickel. However, the inhibition of DNA repair seems not to play a decisive role in enhancing SCE, because we have previously shown that arsenite inhibits the UV-induced DNA repair, but has no enhancing effect on the UV-induced SCE. Our results also show that nickel had obvious inhibitory effects on DNA ligation and postreplication repair, but had no apparent effect on nucleotide excision and DNA polymerization in the UV repair. The results of the DNA ligation inhibition by nickel in UV but not in MMS repair suggest that different ligases are used in the DNA repair of UV- and MMS-induced damages.

Molecular characterization of methyl methanesulphonate (MMS)-induced HPRT mutations in V79 cells

Spontaneous and methyl methanesulphonate-induced HPRT-deficient mutants were analysed for changes in the hprt gene structure using multiplex polymerase chain reaction. The PCR amplification pattern of 21 MMS-induced mutations revealed one total deletion of the hprt coding exons and one small deletion within exon 5, while 19 mutants showed the V79 wild-type pattern. Molecular analysis of 30 spontaneous mutations revealed no mutants with amplification patterns which differed from those of wild-type cells. We further analysed MMS-induced mutants in a different V79 cell line with a high (40%) spontaneous deletion frequency. MMS caused a dose-dependent increase in the mutant frequency but the incidence of deletions was reduced to 6% at 2 x 10(-4) M and to 13% at 5 x 10(-4) M indicating that mainly point mutations were induced. The repair inhibitor cytosine arabinoside (araC) enhanced mutation induction by MMS but did not change the proportion of deletions in the mutation spectrum. The results indicate that different V79 cell lines spontaneously produce different amounts of deletion mutations. The frequency of MMS-induced deletions does not depend on the frequency of spontaneous deletions in a given cell line. The MMS-induced mutation spectrum seems to be unchanged even at high concentrations with a strong cytotoxic effect. Deletions are not increased as a consequence of araC-inhibited repair of MMS-induced lesions.

The yield of fission neutron-induced chromatid aberrations in G2-stage human lymphocytes: effect of caffeine, hydroxyurea and cytosine arabinoside post-irradiation

To evaluate the influence of inhibitors of DNA synthesis/repair on the yield of chromosomal aberrations in the G2 phase of the cell cycle, whole-blood cultures of human lymphocytes were exposed to various doses of fission neutrons or X-rays and treated post-irradiation during the last 2.45 h before harvesting, with 5 mM caffeine, 5 mM hydroxyurea (HU) and 0.05 mM cytosine arabinoside (ara-C). The presence of caffeine and HU strongly potentiated the yield of chromatid-type aberrations induced by both neutrons and X-rays. No potentiating effect, except at the highest dose of neutrons, was observed when irradiated cells were subsequently treated with ara-C. Since ara-C strongly potentiated the frequency of chromatid aberrations induced in G2 lymphocytes by X-rays, the results presented here indicate that fission neutrons produce a smaller proportion of lesions, the repair of which can be inhibited by ara-C, compared with the number produced by X-rays. In addition, neutron-induced mitotic delay was shortened by treatment with caffeine, mainly within the first 2 h after irradiation.