Modulation by Co(II) of UV-induced DNA repair, mutagenesis and sister-chromatid exchanges in mammalian cells

In bacterial test systems, Co(II) has been shown to be antimutagenic in combination with several chemical and physical agents. To investigate whether such modulations also apply to mammalian cells, the effect of Co(II) on UV-induced mutagenesis, sister-chromatid exchanges as well as DNA damage and its removal was determined. Co(II) itself is weakly mutagenic at the HPRT locus and increases the frequency of sister-chromatid exchanges. Additionally, at both endpoints the metal ions enhance the genotoxicity of UV light. To discriminate between an enhancement of DNA damage and an interference with repair processes, the number of pyrimidine cyclobutane dimers was determined by HPLC. While the induction of these DNA lesions is not affected by Co(II), their removal is inhibited at concentrations of 75 microM Co(II) and higher. Analysis of the kinetics of strand-break induction and closure after UV irradiation by nucleoid sedimentation reveals an accumulation of strand breaks in the presence of Co(II). This indicates that either the polymerization or the ligation step in excision repair is affected. Since similar interactions with the processing of UV-induced DNA damage have been observed with other carcinogenic and/or mutagenic metal ions, this appears to be a common mechanism of metal genotoxicity.     

Relationship of DNA repair to chromosome aberrations, sister-chromatid exchanges and survival during liquid-holding recovery in X-irradiated mammalian cells

The repair of X-ray induced DNA single strand breaks and DNA—protein cross-links was investigated in stationary phase, contact-inhibited mouse cells by the alkaline-elution technique. Approx. 90% of X-ray induced single strand breaks were rejoined during the first hour of repair, whereas most of the remaining breaks were rejoined more slowly during the next 5 h. At early repair times, the number of residual non-rejoined sungle strand breaks was approx. proportional to the X-ray dose. DNA—protein cross-links were removed at a slower rate (T1/2 approx. 10–12 h). Cells were held in stationary growth for various periods of time after irradiation before subculture at low density to score for colony survival (potentially lethal damage repair), chromosome aberrations in the first mitosis, and sister-chromatid exchanges in the second mitosis. Both cell killing and the frequency of chromosome aberrations decreased during the first several hours of recovery, reaching a minimum level by 6 h; this decrease correlated temporally with the repair of the slowly rejoining DNA-strand breaks. Relatively few sister-chromatid exchanges were observed when the cells were subcultured immediately after X-ray. The exchange frequency rose to maximum levels after a 4-h recovery interval, and returned to control levels after 12 h of recovery. The possible relationship of DNA repair to these changes in survival, chromosome aberrations, and sister-chromatid exchanges during liquid-holding recovery is discussed.     

Abnormal sister-chromatid exchange induction by 3-aminobenzamide in an SV40-transformed Indian muntjac cell line: relationships with DNA maturation and DNA-strand breakage.

In SVM cells, an SV40-transformed line of Indian muntjac fibroblasts, levels of sister-chromatid exchanges are known to be abnormally high after UV-irradiation or alkylation. The SVM line is also known to have a defect in the processing of DNA-strand breaks. Sister-chromatid exchange in other cells is known to be stimulated by the poly(ADP-ribose) transferase inhibitor, 3-aminobenzamide, which also retards DNA-break sealing. Sister-chromatid exchanges in SVM cells are found to be hypersensitive to 3-aminobenzamide, or to nicotinamide deprivation which similarly inhibits poly(ADP-ribosyl)ation; DNA-strand breaks are likewise induced by 3-aminobenzamide. Bromodeoxyuridine, needed to detect sister-chromatid exchanges, is more toxic to SVM cells and itself induces sister-chromatid exchanges to a greater extent than it does in normal muntjac cells. However, in contrast to the situation reported for other cell types prone to sister-chromatid exchange (the Chinese hamster ovary mutant EM9 and human Bloom's Syndrome cells), SVM cells do not show an abnormal delay in DNA maturation when, under the influence of bromodeoxyuridine and 3-aminobenzamide, they show a high level of sister-chromatid exchange. The mechanism by which BrdU exerts its effects can largely be explained in terms of familiar effects on deoxyribonucleotide pools and DNA integrity. 3-Aminobenzamide, however, induces sister-chromatid exchanges in SVM cells by another mechanism.     

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.     

Genotoxic effects of sodium arsenite on human cells.

The effects of sodium arsenite (SA) were studied either alone or in combination with X-rays in peripheral blood lymphocytes, and with short-wave ultraviolet (UV) radiation in primary human fibroblast culture systems. It was found that SA (i) inhibited the cell cycle progression of phytohaemagglutinin (PHA)-responsive lymphocytes, (ii) induced chromatid-type aberrations and sister-chromatid exchanges (SCEs) as a function of concentration and (iii) potentiated the X-ray- and UV-induced chromosomal damage. Our results suggest that SA interferes with the DNA repair process, presumably by inhibiting the ligase activity. This accounted for an increase in the DNA replication-dependent processes, chromatid aberrations and SCEs and synergistic enhancement of the X-ray- and UV-induced chromosomal damage. This ability of arsenite may be responsible for its comutagenic properties with different types of mutagens and hence its carcinogenicity.     

Enhancement of UV-induced mutagenesis and sister-chromatid exchanges by nickel ions in V79 cells: evidence for inhibition of DNA repair

With regard to contradictory results concerning the mutagenicity of nickel compounds in short-term assays, especially in bacterial test systems, Chinese hamster V79 cells were used to measure mutagenicity, comutagenicity and the induction of sister-chromatid exchanges (SCEs) by NiCl2. We confirmed the induction of mutations at the HGPRT locus as well as SCEs. In addition, NiCl2 shows a pronounced comutagenic effect towards UV. When using confluent cultures or resting cells due to serum deprivation, where more time is given for repair processes, the comutagenic effect is higher compared to logarithmically growing cells (10 and 4 times, respectively, compared to twice). Hence, we attribute this enhancement in mutagenicity to inhibition of DNA repair. Also the increase in induced SCEs after combined treatment with UV and NiCl2 supports this thesis. Furthermore, NiCl2 enhances the cyto-toxicity of cis-DDP about 12-fold. Since no comutagenic effect is observed in combination with MMS, we suggest that the inhibition of DNA repair by Ni(II) applies to all DNA changes that are repaired by the 'long-patch' excision repair system. This inhibition may occur via replacement of other divalent metal ions essential in repair and regulation processes.     

Modifying effects of components of plant essence on the induction of sister-chromatid exchanges in cultured Chinese hamster ovary cells

The influence of 21 kinds of components of plant essence on sister-chromatid exchanges (SCEs) induced by mitomycin C was investigated in cultured Chinese hamster CHO K-1 cells. Posttreatment with scopoletin, jasmone, caffeic acid and ferulic acid significantly increased the frequency of SCEs. Further investigation of the SCE-enhancing effect of analogues of caffeic acid and ferulic acid revealed that an alpha,beta-unsaturated carbonyl group may be necessary for SCE-enhancing effects. The influence of caffeic acid and ferulic acid on X-ray- or UV-induced SCEs was also studied. The frequencies of SCEs induced by UV were increased by treatment with these compounds. This increasing effect was observed in the S phase of the cell cycle. On the contrary, X-ray-induced SCEs were reduced by the treatment with these compounds. The decreasing effect was observed in the G1 phase but not in the S or G2 phase. To explain these contradictory results, we assumed that caffeic acid and ferulic acid may modify the repair of DNA strand breaks.     

Complex repair kinetics of DNA strand breaks induced by γ-rays or UV radiation in Ehrlich ascites tumour cells

Fluorometric analysis of DNA unwinding (FADU) – a sensitive technique for the detection of strand breaks in DNA – has been modified and used for the detailed investigation of repair kinetics of DNA-strand breaks arising under different conditions in Ehrlich ascites tumour (EAT) cells irradiated by γ-rays or ultraviolet (UV) radiation. The repair kinetics of DNA-strand breaks induced in EAT cells by γ-radiation was measured at radiation doses of 8, 20 and 50 Gy. We found complex repair curves in all cases, probably reflecting the combined processes of break rejoining and break generation during repair. In order to affect the above-mentioned processes, we have used different conditions of repair and different types of radiation. Lowering of the temperature of incubation and treating the cells by 5-fluoro-2′-deoxyuridine (FUdR) lead to complex changes of the repair curve with a reduced ``wave' pattern. In order to change the type of damage to DNA, we used UV radiation (254 nm, 10 and 20 J/m²). Detailed studies of the repair kinetics showed that the repair curve for 10 J/m² had a second maximum within 70 min after irradiation. Received: 17 May 1995 / Accepted in revised form: 15 March 1996     

Qualitative differences between replicative and repair synthesis of DNA in normal and transformed mouse cells as measured by precursor discrimination

Inhibitors of DNA polymerase alpha such as aphidicolin (APC) or 1-beta-D-arabinofuranosyl-cytosine (araC) cause DNA-strand breaks to accumulate after UV-irradiation, at sites where repair resynthesis is inhibited. Transformed cells accumulate fewer such breaks than normal cells do; this may be due to differences in the extent, or the nature, of excision-repair synthesis in transformed and in normal cells. We have looked for differences in the nature of repair synthesis, comparing the labelling of DNA by deoxycytidine (dC) and araC through UV-induced repair in normal and transformed mouse cells. We have made parallel determinations of precursor discrimination in replicative synthesis, and find that normal cells discriminate better against araC in replicative synthesis than do transformed cells. But repair synthesis discriminates against araC less than normal replicative synthesis does, to a similar extent in both cell types. Thus, there are qualitative differences between the DNA polymerases engaged in UV excision repair and replication in normal and transformed mouse cells; but there is no evidence for a predominantly araC-insensitive repair synthesis in transformed cells, such as might account for the difference in break accumulation.     

DNA strand breaks and repair synthesis in Yoshida sarcoma cells with differential sensitivities to bifunctional alkylating agents and UV light

The induction of DNA-strand breaks and repair synthesis has been examined in cultured Yoshida sarcoma cell lines sensitive (YS) and resistant (YR) to methylene dimethanesulphonate (MDMS). Using an alkaline DNA unwinding-hydroxylapatite technique, we were able to detect breaks in DNA immediately after MDMS treatment and at similar levels in both YS and YR cells. MDMS treatment and post-treatment incubation in the presence of 1-β-D-arabino-furanosylcytosine (araC) lead to a large increase in the numbers of breaks when compared with MDMS treatment alone which indicated that many of the DNA-strand breaks seen after MDMS treatment were intermediates in excision repair. The magnitude of break incidence with the araC treatment was again equal in YS and YR cells indicating that these 2 lines made enzymic incision next to MDMS-induced lesions with equal capacities.During incubation following MDMS treatment, the levels of DNA-strand breaks in YR cells were found to decrease more rapidly than in YS cells. Parallel DNA-repair synthesis estimations, using BND-cellulose chromatography, revealed that the increased rate of decline in breaks in YR cells was accompanied by an increase in repair-synthesis activity compared to YS cells. This was interpreted as indicating that an intermediate step in an excision-repair pathway for MDMS-induced lesions was relatively deficient in YS compared to YR cells.A similar difference in the rates of decline of DNA-strand breaks between YS and YR cells was also observed following treatment with UV light to which MDMS-resistant YR cells also display cross-resistance. However, no such difference was detected following treatment with the monofunctional alkylating agent, methyl methanesulphonate, to which YS and YR cells are equally sensitive. These results suggest that resistance to MDMS in the YR cell line is achieved by an increased efficiency in the gap-sealing component of the excision-repair process.     

The formation of UV-induced chromosome aberrations involves ERCC1 and XPF but not other nucleotide excision repair genes

ERCC1-XPF, through its role in nucleotide excision repair (NER), is essential for the repair of DNA damage caused by UV light. ERCC1-XPF is also involved in recombinational repair processes distinct from NER. In rodent cells chromosome aberrations are a common consequence of UV irradiation. We have previously shown that ERCC1-deficient cells have a lower ratio of chromatid exchanges to breaks than wild type cells. We have now confirmed this result and have shown that XPF-deficient cells also have a lower ratio than wild type. However, cells deficient in the other NER genes, XPD, XPB and XPG, all have the same ratio of exchanges to breaks as wild type. This implies that ERCC1-XPF, but not other NER proteins, is involved in the formation of UV-induced chromosome aberrations, presumably through the role of ERCC1-XPF in recombinational repair pathways rather than NER. We suggest that ERCC1-XPF may be involved in the bypass/repair of DNA damage in replicating DNA by an exchange mechanism involving single strand annealing between non-homologous chromosomes. This mechanism would rely on the ability of ERCC1-XPF to trim non-homologous 3' tails.     

Sodium arsenite enhances the cytotoxicity, clastogenicity, and 6-thioguanine-resistant mutagenicity of ultraviolet light in Chinese hamster ovary cells

Cytotoxicity, chromosome aberrations, and mutations to 6-thioguanine resistance were synergistically increased by incubating the ultraviolet light (UV)-irradiated Chinese hamster ovary (CHO) cells in medium containing sodium arsenite. However, the frequencies of sister-chromatid exchanges and mutations to ouabain resistance induced by UV were not synergistically increased by sodium arsenite. The synergistic effect of sodium arsenite on UV-induced chromosome aberrations varied with cell-harvesting time and decreased with increasing time intervals between UV and sodium arsenite treatments.     

The effect of gossypol on the frequency of DNA-strand breaks in human leukocytes in vitro

Gossypol, a human antifertility agent isolated from the cotton plant, was found to induce a dose-dependent increase in the frequency of DNA-strand breaks in human leukocytes exposed to 2-40 micrograms/ml of the drug for 1 h in serum-free medium in vitro. DNA-strand breaks were studied by alkaline elution or alkaline unwinding of DNA followed by hydroxylapatite-chromatography. No decrease of gossypol-induced DNA-strand breaks was observed after post-treatment incubation times up to 24 h, whereas X-ray-induced DNA breaks disappeared within 2 h under the same incubation conditions. Cells exposed to gossypol in the presence of 10% fetal calf serum showed no or little increase of DNA breaks, suggesting that serum proteins inhibit the DNA-damaging activity of the drug. Both optical isomers of gossypol induced DNA-strand breaks. However, the effect of (-)-gossypol was only about half of that of (+)-gossypol and the racemic form. The induction and persistence of DNA-strand breaks by gossypol, as well as the reduction of this effect in the presence of serum should be considered in the evaluation of the potential in vivo genotoxicity of the drug.     

In vivo nicking and rejoining of nuclear DNA in ultraviolet-irradiated radiation-resistant and sensitive strains of Dictyostelium discoideum

Summary Some aspects of DNA repair in several radiation-resistant and radiation-sensitive strains of Dictyostelium discoideum were investigated by using alkaline sucrose gradients to analyze for the production and resealing of single-strand breaks following irradiation with 254 nm UV. All radiation-resistant strains and all mutants assayed that are sensitive to both UV and ⁶⁰Co gamma rays produced singlestrand breaks in their nuclear DNA after a UV fluence of 15 J/m². Mutants at the radC locus which are sensitive to UV but as resistant as their parental strains to ⁶⁰Co gamma rays produced many fewer single-strand breaks in their DNA after irradiation with UV. Thus, the radC mutations alter a repair pathway specific for UV-induced DNA damage and presumably affect the activity of a UV-damage-specific endonuclease involved in excision repair. All radiation-resistant strains and all of our mutants sensitive to gamma rays rejoined much of their DNA during a three-hour post-UV-irradiation incubation, suggesting that these strains have at least a partially intact excision repair system.Abbreviations used UV ultraviolet light - PBS phosphate buffered saline - cpm counts per minute     

A replication model for sister-chromatid exchange

A model for the production of sister-chromatid exchanges is presented, based on the idea that double-strand breaks are generated at junctions between a completely duplicated replicon cluster and a partially duplicated replicon cluster. Agents that induce absolute blocks to DNA fork displacement will cause this condition to persist longer than normal, whereas agents that inhibit initiation of whole clusters will rarely cause it at all. During the blunt-end repair of the double-strand breaks, sister-chromatid exchange would be initiated when daughter strands of a duplicated cluster recombine with the parental strands of the partially replicated cluster. When the latter finishes replication, sister-chromatid exchange would be completed.     

Analysis of metal-induced DNA lesions and DNA-repair replication in mammalian cells

The potency of several metal compounds in causing lesions in DNA either directly or by exposure of intact cultured cells has been examined using the neutral conditions of nucleoid gradient sedimentation. HgCl2 was clearly the most potent inducer of single-strand breakage when added to isolated nucleoids or when nucleoids were prepared from cells treated with this compound. CaCrO4 , however, caused DNA-strand breaks in nucleoids isolated from cells treated with this agent but did not induce DNA strand breaks when added directly to nucleoids. Although less potent than HgCl2, NiCl2 also caused significant single strand breakage in isolated nucleoids or in nucleoids prepared from cells treated with this metal. Since strand breakage of DNA in intact cells may occur secondary to activation of DNA-dependent nucleases during repair replication, CsCl gradient density sedimentation was utilized to examine whether repair processes were induced by exposure of cells to NiCl2, HgCl2 and CaCrO4 . CaCrO4 and NiCl2 induced substantial DNA-repair activity at concentrations and exposure times where DNA lesions could not be detected whereas HgCl2 induced a 10-fold lower level of DNA-repair activity compared to CaCrO4 at optimal concentrations which again were below the concentrations of this metal that produced measurable DNA lesions. Both the induction of DNA-repair activity and DNA-strand breakage by these metals was concentration- and time-dependent. These results demonstrate some unique aspects of the interaction of HgCl2, NiCl2 and CaCrO4 with the DNA of intact cells and point to the possible important correlation of induction of DNA repair to carcinogenesis since nickel and chromate have clearly been implicated as carcinogens and induce considerable repair whereas HgCl2 is not considered a carcinogen and induces the least DNA repair despite its potency in producing DNA lesions.     

Mechanisms in metal genotoxicity: the significance of in vitro approaches

A survey of the literature published on the ability of metal salts to produce, in vitro, gene mutations, structural chromosome aberrations, sister-chromatid exchanges, to interfere with the chromosome distribution or to induce mammalian cell transformation demonstrates that the carcinogenicity of inorganic compounds is clearly associated with their genotoxicity. The induction of structural aberrations, SCEs and forward gene mutations represents the most sensitive and specific assay to assess the carcinogenic potential of metal salts.     

Nucleotide excision repair or polymerase V-mediated lesion bypass can act to restore UV-arrested replication forks in Escherichia coli

Nucleotide excision repair and translesion DNA synthesis are two processes that operate at arrested replication forks to reduce the frequency of recombination and promote cell survival following UV-induced DNA damage. While nucleotide excision repair is generally considered to be error free, translesion synthesis can result in mutations, making it important to identify the order and conditions that determine when each process is recruited to the arrested fork. We show here that at early times following UV irradiation, the recovery of DNA synthesis occurs through nucleotide excision repair of the lesion. In the absence of repair or when the repair capacity of the cell has been exceeded, translesion synthesis by polymerase V (Pol V) allows DNA synthesis to resume and is required to protect the arrested replication fork from degradation. Pol II and Pol IV do not contribute detectably to survival, mutagenesis, or restoration of DNA synthesis, suggesting that, in vivo, these polymerases are not functionally redundant with Pol V at UV-induced lesions. We discuss a model in which cells first use DNA repair to process replication-arresting UV lesions before resorting to mutagenic pathways such as translesion DNA synthesis to bypass these impediments to replication progression.     

Current aspects in metal genotoxicity

While carcinogenic metal ions are mostly non-mutagenic in bacteria, different types of cellular damage have been observed in mammalian cells, which may account for their carcinogenic potential. Two modes of action seem to be predominant: the induction of oxidative DNA damage, best established for chromium compounds, and the interaction with DNA repair processes, leading to an enhancement of genotoxicity in combination with a variety of DNA damaging agents. In the case of Cd(II), Ni(II), Co(II), Pb(II) and As(III), DNA repair processes are disturbed at low, non-cytotoxic concentrations of the respective metal compounds. Even though different steps in DNA repair are affected by the diverse metals, one common mechanism might be the competition with essential metal ions.