In vitro genotoxic effects of hard metal particles assessed by alkaline single cell gel and elution assays

Hard metals (WC-Co) are made of a mixture of cobalt metal (Co, 5-10%) and tungsten carbide particles (WC, >80%). Excessive inhalation of WC- Co is associated with the occurrence of different lung diseases including an excess of lung cancers. The elective toxicity of hard metal is based on a physico-chemical interaction between cobalt metal and tungsten carbide particles to produce activated oxygen species. The aim of the present study was to assess the genotoxic activity of hard metal particles as compared with Co and WC alone. In human peripheral lymphocytes incubated with Co or WC-Co, a dose- and time-dependent increased production of DNA single strand breaks (ssb) was evidenced by alkaline single cell gel electrophoresis (SCGE) and modified alkaline elution (AE) assays. Addition of 1 M formate, a hydroxyl radical scavenger, had a protective effect against the production of ssb by both WC-Co or Co alone. On the basis of an equivalent cobalt-content, WC-Co produced significantly more ssb than Co. WC alone did not produce DNA ssb detectable by the AE assay, but results obtained with the SCGE assay may suggest that it either allows some uncoiling of the chromatin loops or induces the formation of slowly migrating fragments. Overall, this in vitro study is the first demonstration of the clastogenic property of cobalt metal-containing dusts. The results are consistent with the implication of an increased production of hydroxyl radicals when Co is mixed with WC particles. The SCGE results also suggest that WC may modify the structure of the chromatin, leading to an increased DNA sensitivity to clastogenic effects. Both mechanisms are not mutually exclusive and may concurrently contribute to the greater clastogenic activity of WC-Co dust. This property of WC-Co particles may account for the excess of lung cancers observed in hard metal workers.      

Induction of DNA fragmentation and DNA repair synthesis in human and rat hepatocytes by diethylstilbestrol

The synthetic estrogen diethylstilbestrol (DES), a known human carcinogen, was examined for cytotoxicity, and the induction of DNA damage and repair in primary cultures of human and rat hepatocytes. In both species concentrations of DES ranging from 5.6 to 18 micrograms/ml constantly produced reduction of cell viability and DNA fragmentation in dose-related amounts. However, large individual quantitative differences in the sensitivity to the cytotoxic and DNA-damaging activities of DES were observed among cultures derived from the 5 human donors. DES capability of eliciting DNA-excision repair was weak but statistically significant in both human and rat hepatocytes. Taken as a whole these results contribute to support the hypothesis of a genotoxic mechanism in DES-induced carcinogenesis.     

Cobalt chloride induces apoptosis and zinc chloride suppresses cobalt-induced apoptosis by Bcl-2 expression in human submandibular gland HSG cells

To determine the effects of cobalt chloride on human submandibular gland cells, HSG cells were exposed to various concentrations of cobalt chloride. Cobalt chloride induced cytotoxicity and cell death in HSG cells as determined by phase-contrast microscopy and WST-1 cell viability assay. By using the Hoechst 33342 staining, marked nuclear condensation and fragmentation of chromatin were observed in cobalt chloride-treated cells. Cobalt chloride induced DNA ladder formation in HSG cells in both dose- and time-dependent manner with maximal effect at a concentration of 0.5 mM and 48 h, respectively. Cobalt chloride inhibited the expression of both Bcl-2 protein and mRNA in dose- and time-dependent manner. Zinc chloride recovered the cobalt-suppressed Bcl-2 expression and protected against cobalt-induced apoptosis in HSG cells. Our results show that the pathway of the apoptosis in HSG cells is regulated by cobalt chloride and zinc chloride. Our results also indicate that cobalt-induced apoptotic steps in HSG cells are related to the production of Bcl-2 protein.     

DNA damage response: the players, the network and the role in tumor suppression

One of the most common features of cancer is genetic instability. In response to numerous DNA-damaging insults, normal cells have evolved a complex mechanism to monitor and repair DNA damage lesions to maintain genomic integrity. The defects in DNA damage response, indeed, have been shown to associate closely with tumorigenesis. This review provides an overview on the molecular events in DNA damage signaling pathway, including cell cycle checkpoint and DNA repair. The recent research discoveries on how dysfunction in DNA damage response contributes to genomic instability and cancer development are also discussed.     

Rosemary-stimulated reduction of DNA strand breaks and FPG-sensitive sites in mammalian cells treated with H2O2 or visible light-excited Methylene Blue

In this study possible protective effects of rosemary against oxidative DNA damage induced by H2O2- and visible light-excited Methylene Blue in colon cancer cells CaCo-2 and hamster lung cells V79 were investigated. The level of DNA damage (DNA strand breaks) was measured using the classical and modified single cell gel electrophoresis, so-called comet assay. Our findings showed that an ethanol extract from rosemary reduced the genotoxic activity of both agents after a long-term (24 h; 0.3 microg/ml) or short-term (2 h; 30 microg/ml) pre-incubation of cells. We suggest that the extract of rosemary exhibits a protective effect against oxidative damage to DNA as a consequence of scavenging of both *OH radicals and singlet oxygen ((1)O2).     

Effect of soluble and particulate nickel compounds on the formation and repair of stable benzo[a]pyrene DNA adducts in human lung cells.

Nickel compounds are well-known human carcinogens, but the underlying mechanisms are still not fully understood. Even though only weakly mutagenic, nickel chloride has been shown previously to impair the repair of UV-induced DNA damage as well as oxidative DNA damage. However, the carcinogenic potential depends largely on solubility, with poorly water-soluble nickel subsulfide and nickel oxide being strong carcinogens. Within the present study we investigated the effects of particulate black NiO and soluble NiCl(2) on the induction and removal of stable DNA adducts formed by benzo[a]pyrene (B[a]P) measured by a highly sensitive high performance liquid chromatography (HPLC)/fluorescence assay. With respect to adduct formation, NiO but not NiCl(2) reduced the generation of DNA lesions by approximately 30%. Regarding their repair, in the absence of nickel compounds, most lesions were removed within 24 h; nevertheless, between 20 and 35% of induced adducts remained even 48 h after treatment. NiCl(2) and NiO reduced the removal of adducts in a dose-dependent manner. Thus, 100 microM NiCl(2) led to approximately 80% residual repair capacity; after 500 microM the repair was reduced to approximately 36%. Also, even at the completely non-cytotoxic concentration of 0.5 microg/cm(2) black NiO, lesion removal was reduced to approximately 35% of control and to 15% at 2.0 microg/cm(2). Furthermore, both nickel compounds increased the benzo[a]pyrene-7,8-diol 9,10-epoxide (BPDE)-induced cytotoxicity. Taken together, our results indicate that the nucleotide excision repair pathway is affected in general by water-soluble and particulate nickel compounds and provide further evidence that DNA repair inhibition may be one predominant mechanism in nickel-induced carcinogenicity.     

Prophylaxis of oxidative DNA damage by formamidopyrimidine-DNA glycosylase

Lying at the gas-exchange interface, lung epithelia may be at risk of oxidation-induced mutagenesis. Further, inflammation processes possibly consequent on smoking liberate reactive oxygen species that multiply the carcinogenic effects of tobacco. DNA repair mechanisms play a major role in counteracting the deleterious effects of oxidative DNA damage. Some studies find positive associations between lung cancer and variations in the human 8-oxoguanine DNA glycosylase (hOGG1) gene that encodes a major DNA glycosylase for oxidized lesions with sluggish kinetics properties. The bacterial homologue formamidopyrimidine-DNA glycosylase (FPG) is 80-fold faster than hOGG1 in repairing mutagenic oxidative lesions. Cell-culture studies have shown that FPG can be expressed in mammalian cells, where it accelerates DNA repair and abates mutagenicity of a wide range of DNA-damaging agents. Prophylaxis of oxidative DNA damage and mutation could be achieved in lung epithelia and other tissues of at-risk individuals by expression of the FPG protein. Currently available vehicles for this peculiar type of gene therapy are briefly surveyed.     

Expression of base excision DNA repair genes is a sensitive biomarker for in vivo detection of chemical-induced chronic oxidative stress: identification of the molecular source of radicals responsible for DNA damage by peroxisome proliferators

Oxidative stress to DNA is recognized as one of the mechanisms for the carcinogenic effects of some environmental agents. Numerous studies have been conducted in an attempt to document the fact that chemical carcinogens that are thought to induce production of oxidants also cause the formation of oxidative DNA lesions. Although many DNA adducts continue to be useful biomarkers of dose/effect, changes in gene expression have been proposed to be a practical novel tool for studying the role of chemically induced oxidative DNA damage. Here, we hypothesized that expression of base excision DNA repair genes is a sensitive biomarker for in vivo detection of chemically induced chronic oxidative stress. To test this hypothesis, mice were treated with a known rodent carcinogen and peroxisome proliferator, WY-14,643 (500 ppm, 1 month). A number of end points that are commonly used to assess oxidative DNA damage were considered. Our data demonstrate that no difference in 8-oxoguanine, the number of abasic sites, or single strand breaks can be detected in genomic DNA from livers of control or WY-treated animals. However, a concordant marked induction of genes specific for the long-patch base excision DNA repair, a predominant pathway that removes oxidized DNA lesions in vivo, was observed in livers of WY-treated mice. Kupffer cell NADPH oxidase, and peroxisomes in parenchymal cells have been proposed as the potential sources of peroxisome proliferator-induced oxidants. The analysis of expression of base excision DNA repair genes was used to assess whether this biomarker of oxidative stress can be used to determine the source of oxidants. The data suggest that DNA-damaging oxidants are generated by enzymes that are induced after activation of peroxisome proliferator activator receptor alpha, such as those involved in lipid metabolism in peroxisomes, and are not the result of activation of NADPH oxidase in Kupffer cells. We conclude that expression of base excision DNA repair genes is a sensitive in vivo biomarker for chemically induced oxidative stress to DNA that can be successfully used for the identification of the molecular source of radicals responsible for DNA damage in vivo.     

Imbalancing the DNA base excision repair pathway in the mitochondria; targeting and overexpressing N-methylpurine DNA glycosylase in mitochondria leads to enhanced cell killing

The DNA base excision repair (BER) pathway is responsible for the repair of alkylation and oxidative DNA damage.The short-patch BER pathway, beginning with the simple glycosylase N-methylpurine DNA glycosylase (MPG), is responsible for the removal of damaged bases such as 3-methyladenine and 1,N(6)-ethenoadenine from the DNA after alkylation or oxidative DNA damage. The resulting apurinic site is further processed by the other members in the pathway, resulting in the insertion of the correct nucleotide. If apurinic sites accumulate, they are mutagenic and cytotoxic to the cell. To evaluate its efficacy in sensitizing breast cancer cells to chemotherapy, MPG has been overexpressed in the breast cancer cell line, MDA-MB231. With MPG overexpression, an increase in DNA damage and increased cytotoxicity to methyl methanesulfonate as well as increased apoptosis levels was observed in these cells. Because mitochondrial DNA has been shown to be more sensitive to DNA damage than nuclear DNA, a construct containing mitochondrial-targeted MPG using the human manganese superoxide dismutase mitochondrial-targeting sequence was made. Overexpression of the mitochondrially targeted MPG dramatically increased the breast cancer cells' sensitivity to methyl methanesulfonate. In conclusion, we believe that the increase in sensitivity to DNA damage by overexpression of nuclear MPG is because of an imbalance in the BER pathway, and an even greater increase in cell sensitivity is observed when mitochondrial DNA is targeted.     

Inhibition of DNA repair and the enhancement of cytotoxicity of alkylating agents

DNA damage was evaluated by flow cytometric (FCM) analysis of cells treated with L-phenylalanine mustard (L-PAM) and stained with anti-DNA monoclonal antibody (MAb) F7-26. DNA damage was rapidly repaired, as indicated by the loss of DNA immunoreactivity after removal of L-PAM. Two types of drug combinations were found to inhibit DNA repair. Combinations containing inhibitors of DNA polymerase (ara-C, aphidicolin) or these inhibitors and hydroxyurea inhibited DNA repair in A2780/PAM and A549 cells. The inhibition of DNA repair by combinations of DNA-damaging agents thioTEPA or cisplatin and DNA polymerase inhibitors is a novel observation based on the specificity of DNA damage assay with MAb F7-26. Combinations containing thioTEPA or cisplatin inhibited DNA repair in A549 but not in A2780/PAM cells. Drug combinations which inhibited DNA repair also significantly enhanced cell killing by L-PAM. Cell survival in cultures treated with L-PAM and efficient inhibitors was 2 to 3 orders of magnitude lower than was expected for additive survival. ThioTEPA and cisplatin play a dual role in combination chemotherapy by inducing DNA damage and inhibiting repair of DNA damage. FCM analysis of DNA repair may be a useful component of drug evaluation and could be applied to determine cell-type specific sensitivity to inhibitors of DNA repair.     

Lack of specific inhibition of DNA repair in WI-38 human diploid fibroblasts by sodium saccharin

The ability of sodium saccharin (NaS) to inhibit the repair of DNA damaged by UV irradiation was examined in cultured WI-38 human diploid fibroblasts. Cesium chloride density gradient ultracentrifugation was used to measure DNA repair and DNA replication. NaS (10-10,000 micrograms/ml) did not specifically inhibit UV light-induced DNA repair. At doses of NaS (1785 and 10,000 micrograms/ml) that caused a 62-67% inhibition of semiconservative DNA replication, there was little or no inhibition of DNA repair synthesis. In cell cultures not exposed to UV irradiation, NaS failed to induce DNA repair. RNA synthesis and protein synthesis were unaffected by NaS at all doses tested. The inhibition of semiconservative DNA replication at higher doses of NaS may be a manifestation of cytotoxicity. In contrast to results with NaS, WI-38 cells were very sensitive to DNA repair inhibition by the well-studied inhibitor quinacrine-HCl. These results do not support mechanisms of saccharin-induced tumorigenesis involving either direct induction of DNA damage or inhibition of the repair of DNA damage caused by other agents.     

Neoplastic transformation of human osteoblast cells to the tumorigenic phenotype by heavy metal-tungsten alloy particles: induction of genotoxic effects

Heavy metal-tungsten alloys (HMTAs) are dense heavy metal composite materials used primarily in military applications. HMTAs are composed of a mixture of tungsten (91-93%), nickel (3-5%) and either cobalt (2-4%) or iron (2-4%) particles. Like the heavy metal depleted uranium (DU), the use of HMTAs in military munitions could result in their internalization in humans. Limited data exist, however, regarding the long-term health effects of internalized HMTAs in humans. We used an immortalized, non-tumorigenic, human osteoblast-like cell line (HOS) to study the tumorigenic transforming potential of reconstituted mixtures of tungsten, nickel and cobalt (rWNiCo) and tungsten, nickel and iron (rWNiFe). We report the ability of rWNiCo and rWNiFe to transform immortalized HOS cells to the tumorigenic phenotype. These HMTA transformants are characterized by anchorage-independent growth, tumor formation in nude mice and high level expression of the K-ras oncogene. Cellular exposure to rWNiCo and rWNiFe resulted in 8.90 +/- 0.93- and 9.50 +/- 0.91-fold increases in transformation frequency, respectively, compared with the frequency in untreated cells. In comparison, an equivalent dose of crystalline NiS resulted in a 7.7 +/- 0.73-fold increase in transformation frequency. The inert metal tantalum oxide did not enhance HOS transformation frequency above untreated levels. The mechanism by which rWNiCo and rWNiFe induce cell transformation in vitro appears to involve, at least partially, direct damage to the genetic material, manifested as increased DNA breakage or chromosomal aberrations (i.e. micronuclei). This is the first report showing that HMTA mixtures of W, Ni and Co or Fe cause human cell transformation to the neoplastic phenotype. While additional studies are needed to determine if protracted HMTA exposure produces tumors in vivo, the implication from these in vitro results is that the risk of cancer induction from internalized HMTAs exposure may be comparable with the risk from other biologically reactive and insoluble carcinogenic heavy metal compounds (e.g. nickel subsulfide and nickel oxide).     

Radiation-induced DNA damage and its repair in lymphocytes of patients with head and neck cancer and healthy donors

BACKGROUND: DNA repair capacity may be an important factor in determining both individual susceptibility to cancer and the response to cancer therapy. The aim of this work was to compare DNA damage and the repair process in cells originating from healthy donors and cancer patients. MATERIALS AND METHODS: Using the micronucleus and comet assays, we compared the induction of DNA damage and its repair in lymphocytes isolated from blood samples of 14 healthy donors and 24 patients with head and neck tumours. Gamma-rays at the dose of 2 or 4 Gy were used as the damaging factor. The micronucleus test was performed according to Fenech (1) and the comet assay according to Green et al. (2). RESULTS AND CONCLUSION: Lymphocytes of both healthy donors and tumour patients showed great diversification in reaction to the same dose of gamma irradiation as well as differences in the kinetics of DNA repair. The patient group contained significantly more individuals whose lymphocytes were characterized by higher background DNA damage and higher damage inducibility. Blood cells of donors showing high damage inducibility also showed increased levels of micronuclei induced by ionizing radiation. Micronuclei induction did not correlate with a high level of unrepaired DNA damage.     

Influence of nitric oxide on the generation and repair of oxidative DNA damage in mammalian cells

We have analysed the effects of endogenously and exogenously generated nitric oxide (NO) in cultured mammalian fibroblasts on: (i) the steady-state (background) levels of oxidative DNA base modifications; (ii) the susceptibility of the cells to the induction of additional DNA damage and micronuclei by H(2)O(2); and (iii) the repair kinetics of various types of DNA modifications. Steady-state levels of oxidative DNA base modifications, measured by means of an alkaline elution assay in combination with the repair endonuclease Fpg protein, were similar in NO-overproducing B6 mouse fibroblasts stably transfected with an inducible NO synthase (iNOS) and in control cells. Increased oxidative damage was only observed after exposure to high (toxic) concentrations of exogenous NO generated by decomposition of dipropylenetriamine-NONOate (DPTA-NONOate). Under these conditions, the spectrum of DNA modifications was similar to that induced by 3-morpholinosydnonimine, which generates peroxynitrite. The repair rate of additional oxidative DNA base modifications induced by photosensitization was not affected by the endogenous NO generation in the iNOS-transfected cells. However, it was completely blocked after pre-treatment with DPTA-NONOate at concentrations that did not cause oxidative DNA damage by themselves. In contrast, the repair of DNA single-strand breaks, sites of base loss (AP sites) and UVB-induced pyrimidine photodimers, was not affected. The endogenous generation of NO in the iNOS-transfected fibroblasts was associated with a protection from DNA single-strand break formation and micronuclei induction by H(2)O(2). These results indicate that NO generates cellular DNA damage only inefficiently and can even protect from DNA damage by H(2)O(2), but it selectively inhibits the repair of oxidative DNA base modifications.     

基于双荧光素酶报告基因的DNA损伤与修复检测系统的建立与应用

目的： 建立一种能够同时对环境致癌物所致HepG2细胞DNA损伤和细胞对损伤DNA的修复能力进行快速检测的系统。方法：5 μmol/L氯化镉体外损伤质粒pTK-RL,质粒pgadd153-luc和体外受损的质粒pTK-RL共转染到HepG2细胞中,以16种已知致癌物或3种无遗传毒性的非致癌物刺激细胞,利用双荧光素酶检测方法同时检测DNA损伤和细胞的修复能力;双荧光素酶检测系统检测居民区、垃圾焚烧厂和农田3个不同污染区土壤中非挥发性有机提取物对DNA的损伤作用和细胞对该损伤的修复能力;彗星实验检测DNA的损伤。结果：双荧光素酶报告基因检测系统均可检出已知环境致癌物对DNA损伤与修复能力的影响,非致癌物均未检测到DNA损伤作用和对细胞DNA修复能力的影响;3个不同污染区土壤中非挥发性有机提取物均可诱导DNA损伤并抑制细胞对DNA损伤的修复能力,强度为居民区>垃圾焚烧厂>农田土壤。结论：在本研究条件下建立了可同时检测环境致癌物DNA损伤与细胞修复能力的双荧光素酶报告基因检测系统并可用于环境污染区检测。     

Biotransformation of aromatic ainines to DNA-damaging products by urinary bladder organ cultures

Urinary bladder is a target tissue for aromatic amine car-cinogens.The intrinsic capacity of this tissue to form DNA-damaging productswas investigated in explant cultures of bladder isolated fromNew Zealand white rabbits. DNA repair, measured by autoradiography,was used as the in dicator of DNA damage. DNA repair was inducedby 2-aminofluorene (2-AF) and its acetylated derivatives 2-acetyl-aminofluoreneand N-hydroxy-2-acetylaminofluorene. A positive response wasobserved with benzidine (BZD), but no repair was seen in culturesexposed to monoacetyl BZD or diacetyl BZD. These results indicatethat rabbit urinary blad der has the ability to biotransformaromatic amines to DNA-damaging products and has the capacityto repair damaged DNA. Unlike liver, where activation of BZDseems to require N-acetylation, acetylated BZD in the bladderappeared to be a detoxification product. The lack of damageby acetylated BZD is consistent with activation of BZD in bladderby prosta glandin synthetase-mediated pathways.     

Inactivation of human MAD2B in nasopharyngeal carcinoma cells leads to chemosensitization to DNA-damaging agents

Rev7p has been suggested to play an important role in regulating DNA damage response in yeast, and recently, the human homologue (i.e., MAD2B) has been identified, which shares significant homology to the mitotic checkpoint protein MAD2. In this study, we investigated whether MAD2B played a key role in cellular sensitivity to DNA-damaging anticancer drugs by suppressing its expression using RNA interference in nasopharyngeal carcinoma cells. Using colony formation assay, we found that suppression of MAD2B conferred hypersensitivity to a range of DNA-damaging agents, especially DNA cross-linkers, such as cisplatin, and gamma-irradiation. This effect was associated with reduced frequencies of spontaneous and drug-induced mutations, elevated phosphorylation of histone H2AX, and markedly increased chromosomal aberrations in response to DNA damage. In addition, there was also a significant decrease in cisplatin-induced sister chromatid exchange rate, a marker for homologous recombination-mediated post-replication repair in MAD2B-depleted cells. These results indicate that MAD2B may be a key factor in regulating cellular response to DNA damage in cancer cells. Our findings reveal a novel strategy for cancer therapy, in which cancer cells are sensitized to DNA-damaging anticancer drugs through inactivation of the MAD2B gene.