DNA断裂检测方法──单细胞凝胶电泳法

单细胞凝胶电泳(single cell gel electrophoresis assay,SCGE)也叫彗星试验(comet assay),是一种快速、敏感、简便、廉价的检测单个哺乳动物细胞DNA断裂的技术,目前已用于检测氧化、紫外线和电离辐射引起的损伤,以及三氯乙烷、丙烯酰胺等化学物及老化、吸烟所致损害的研究.文章介绍SCGE的发展、检测分析方法、原理及其在DNA损伤与修复、生物监测、遗传毒理研究、肿瘤治疗方案优化和疗效研究方面的应用前景．     

Variability in nucleotide excision repair and cancer risk: a review

Cancer initiation is classically associated with the induction of mutations on specific oncogenes or tumor suppressor genes, due to the presence of unrepaired DNA lesions produced by endogenous or exogenous genotoxic agents. Among several DNA repair pathways, the nucleotide excision repair (NER) is the most important and versatile one in removing the bulky adducts induced by physical and chemical carcinogens. Xeroderma pigmentosum (XP), characterized by a deficiency in NER and an over 1000-fold increased risk of skin cancer, represents a paradigm to understand the role of unrepaired lesion in the development of cancer. We reviewed here several NER assays used in epidemiological studies investigating the association between DNA repair efficiency and cancer risk. Reduced DNA repair could contribute to the development of cutaneous basal cell carcinoma (BCC), although discordant results have been reported. More consistent findings were observed between cellular sensitivity towards genotoxic agents and smoking-related cancers.     

Enzyme-based formulations for decontamination: current state and perspectives

Development of noncorrosive, cost-effective, environmentally benign, and broad-spectrum antimicrobial formulations is necessary for clinical, industrial, and domestic purposes. Many current decontaminating formulations are effective, but they require the use of strong oxidizing agents or organic solvents that have deleterious effects on human health and the surrounding environment. The emergence of antibiotic-resistant pathogens has motivated researchers to develop enzyme-based self-decontaminating formulations as alternatives to such chemical decontamination approaches. Hydrolytic and oxidative enzymes can be used to deactivate pathogens, including bacteria, spores, viruses, and fungi. Laccases, haloperoxidases, and perhydrolases catalyze the generation of biocidal oxidants, such as iodine, bromine, hypohalous acid (e.g., HOCl or HOBr), and peracetic acid. These oxidants have broad-spectrum antimicrobial activity. Due to the multi-pathway action of these oxidants, it has proven extremely difficult for microbes to gain resistance. Thus far, few examples have been reported on enzyme-based antimicrobial formulations. For these reasons, various enzyme-containing antimicrobial formulations are highlighted in this review.     

Qualitative and quantitative procedures for health risk assessment.

Numerous reactive mutagenic electrophiles are present in the environment or are formed in the human body through metabolizing processes. Those electrophiles can directly react with DNA and are considered to be ultimate carcinogens. In the past decades more than 200 in vitro and in vivo genotoxic tests have been described to identify, monitor and characterize the exposure of humans to such agents. When the responses of such genotoxic tests are quantified by a weight-of-evidence analysis, it is found that the intrinsic potency of electrophiles being mutagens does not differ much for the majority of the agents studied. Considering the fact that under normal environmental circumstances human are exposed to low concentration of about a million electrophiles, the relation between exposure to such agents and adverse health effects (e.g., cancer) will become a 'Pandora's box'. For quantitative risk assessment it will be necessary not only to detect whether the agent is genotoxic, but also understand the mechanism of interaction of the agent with the DNA in target cells needs to be taken into account. Examples are given for a limited group of important environmental and carcinogenic agents for which such an approach is feasible. The groups identified are agents that form cross-links with DNA or are mono-alkylating agents that react with base-moieties in the DNA strands. Quantitative hazard ranking of the mutagenic potency of these groups of chemical can be performed and there is ample evidence that such a ranking corresponds with the individual carcinogenic potency of those agents in rodents. Still, in practice, with the exception of certain occupational or accidental exposure situations, these approaches have not be successful in preventing cancer death in the human population. However, this is not only due to the described 'Pandora's box' situation. At least three other factors are described. Firstly, in the industrial world the medical treatment of cancer in patients occurs with high levels of extremely mutagenic agents. Actually, both in number of persons and in exposure levels such medical treatment is the single largest exposure of humans to known carcinogens. Although such treatments are very effective in curing the tumor as present in the patient, the recurrence of cancer in those patients later in life is very high. In other words: "curing cancer is not the same as preventing cancer death in the human population". Secondly, the rate of cancer death in the human population is also determined by the efficacy in which other major causes of death are prevented. For instance, cardiovascular diseases are the major cause of death in humans in the industrialized world. There is evidence that the treatment of cardiovascular diseases is more successful than that of cancer. On a population level this will result in increase of cancer being the ultimate death cause. Finally, the improvement of medical treatment of diseases together with an improved quality of life will lead to increase average age of the population. Because the onset of most cancer is long after the exposure to carcinogens-in human often more than 30 years-cancer is predominantly a disease of the old age. This means that if the average age of human increases, there will be a selective preference of cancer becoming an even more important cause of death. This especially will be pronounced in those countries were the age distribution in a population is abnormal.     

UVB light stimulates production of reactive oxygen species: unexpected role for catalase

In keratinocytes, UVB light stimulates the production of reactive oxygen species (ROS). Lysates of these cells were found to possess a non-dialyzable, trypsin- and heat-sensitive material capable of generating ROS in response to UVB light. Using ion exchange, metal affinity, and size exclusion chromatography, a 240-kDa protein was isolated with ROS generating activity. The protein exhibited strong absorption in the 320-360 nm range with additional soret peaks around 400-410 nm, suggesting the presence of heme. Sequencing using liquid chromatography-ion trap mass spectrometry identified the protein as catalase. Using purified catalases from a variety of species, the ROS generating activity was found to be temperature- and O2-dependent, stimulated by inhibitors of the catalatic activity of catalase, including 3-aminotriazole and azide, and inhibited by cyanide. A marked increase in the production of ROS was observed in UVB-treated cells overexpressing catalase and decreased generation of oxidants was found in UVB-treated keratinocytes with reduced levels of catalase. Our data indicate that catalase plays a direct role in generating oxidants in response to UVB light. The finding that catalase mediates the production of ROS following UVB treatment is both novel and highly divergent from the well known antioxidant functions of the enzyme. We hypothesize that, through the actions of catalase, high energy DNA damaging UVB light is absorbed by the enzyme and converted to reactive chemical intermediates that can be detoxified by cellular antioxidant enzymes. Accumulation of excessive ROS, generated through the action of catalase, may lead to oxidative stress, DNA damage, and the development of skin cancer.     

Immunochemical detection of oxidatively damaged DNA

Oxidatively damaged DNA is implicated in various diseases, including neurodegenerative disorders, cancer, diabetes, cardiovascular and inflammatory diseases as well as aging. Several methods have been developed to detect oxidatively damaged DNA. They include chromatographic techniques, the Comet assay, (32)P-postlabelling and immunochemical methods that use antibodies to detect oxidized lesions. In this review, we discuss the detection of 8-oxo-7,8-dihydro-29-deoxyguanosine (8-oxodG), the most abundant oxidized nucleoside. This lesion is frequently used as a marker of exposure to oxidants, including environmental pollutants, as well as a potential marker of disease progression. We concentrate on studies published between the years 2000 and 2011 that used enzyme-linked immunosorbent assay (ELISA) and immunohistochemistry to detect 8-oxodG in humans, laboratory animals and in cell lines. Oxidative damage observed in these organisms resulted from disease, exposure to environmental pollutants or from in vitro treatment with various chemical and physical factors.     

Chemical instability of protein pharmaceuticals: Mechanisms of oxidation and strategies for stabilization

Oxidation is one of the major chemical degradation pathways for protein pharmaceuticals. Methionine, cysteine, histidine, tryptophan, and tyrosine are the amino acid residues most susceptible to oxidation due to their high reactivity with various reactive oxygen species. Oxidation during protein processing and storage can be induced by contaminating oxidants, catalyzed by the presence of transition metal ions and induced by light. Oxidative modification depends on the structural features of the proteins as well as the particular oxidation mechanisms inherent in various oxidative species, and may also be influenced by pH, temperature, and buffer composition. Protein oxidation may result in loss of biological activity and other undesirable pharmaceutical consequences. Strategies to stabilize proteins against oxidation can be classified into intrinsic methods (site-directed mutagenesis and chemical modification), physical methods (solid vs. liquid formulations) and use of chemical additives. The optimum choice of chemical additives needs to be evaluated on the basis of the specific oxidation mechanism. Oxidation induced by the presence of oxidants in the system is referred to as a non-site-specific mechanism. Under such conditions, oxidation can be effectively inhibited by the appropriate addition of antioxidants or free radical scavengers. metal-catalyzed oxidation is a site-specific process, in which the addition of antioxidants may accelerate the oxidation reaction. Careful screening of chelating agents has been shown to be an alternative method for preventing metal-catalyzed oxidation. (c) 1995 John Wiley & Sons, Inc.     

Internal hazards: baseline DNA damage by endogenous products of normal metabolism.

Recent improvements in the ability to detect chemically modified bases in DNA have revealed that not only does the genetic material incur damage by foreign chemicals, but that it also sustains injury by reactive products of normal physiological processes. This review summarises current understanding of the DNA-damaging potential of various substances of endogenous origin, including oxidants, lipid peroxidation products, alkylating agents, estrogens, chlorinating agents, reactive nitrogen species, and certain intermediates of various metabolic pathways. The strengths and weaknesses of the existing database for DNA damage by each class of substance are discussed, as are future strategies for resolving the difficult question of whether endogenous chemicals are significant contributors to spontaneous mutagenesis and cancer development in vivo.     

Potentiation of DNA damage and cytotoxicity by calmodulin antagonists

Many physical and chemical agents used in anti-neoplastic therapy are known to act by effecting DNA damage. The possibility that calmodulin may be an important modulator of the response to DNA damage in eukaryotic cells has been explored in a number of studies which use calmodulin antagonists in combination with agents known to damage DNA. We review these studies and discuss the therapeutic potential of calmodulin antagonists in combination therapy.     

Chemical basis of inflammation-induced carcinogenesis

Chronic inflammation induced by biological, chemical, and physical factors has been associated with increased risk of human cancer at various sites. Inflammation activates a variety of inflammatory cells, which induce and activate several oxidant-generating enzymes such as NADPH oxidase, inducible nitric oxide synthase, myeloperoxidase, and eosinophil peroxidase. These enzymes produce high concentrations of diverse free radicals and oxidants including superoxide anion, nitric oxide, nitroxyl, nitrogen dioxide, hydrogen peroxide, hypochlorous acid, and hypobromous acid, which react with each other to generate other more potent reactive oxygen and nitrogen species such as peroxynitrite. These species can damage DNA, RNA, lipids, and proteins by nitration, oxidation, chlorination, and bromination reactions, leading to increased mutations and altered functions of enzymes and proteins (e.g., activation of oncogene products and/or inhibition of tumor-suppressor proteins) and thus contributing to the multistage carcinogenesis process. Appropriate treatment of inflammation should be explored further for chemoprevention of human cancers.     

Induction of the cytoplasmic 'petite' mutation by chemical and physical agents in Saccharomyces cerevisiae.

A range of physical and chemical agents induce the mitochondrial 'petite' mutation in the yeast Saccharomyces cerevisiae. DNA intercalating agents as well as chemicals which can interfere with DNA synthesis induce this mutation, but only in growing cells. Many chemical or physical agents that produce a DNA lesion which is not simply reversed can induce various levels of the petite mutation, and may be more effective in non-growing cells. A limited number of chemicals act like ethidium bromide, inducing a high frequency of petites which is partially reversible with increasing concentration or time. The ability of a specific compound to be transported into mitochondria or its affinity for AT base pairs in DNA may determine whether it acts primarily as a nuclear or mitochondrial mutagen. In mammalian cells, some neoplastic changes occur at the mitochondrial level. Analogies between yeast and mammalian mitochondria suggest that agents which increase petite mutagenesis in yeast may have some carcinogenic potential. Although some types of petite inducer may have potential as antitumour drugs, those which are very effective antimitochondrial agents appear to be too toxic for therapeutic use. A process comparable to early stages in petite mutagensis occurs in human degenerative diseases and it seems possible that a consequence of exposure to petite mutagens could be an increase in the rate of degenerative diseases or of the aging process.     

Mitochondrial DNA mutations and breast tumorigenesis

Breast cancer is a heterogeneous disease and genetic factors play an important role in its genesis. Although mutations in tumor suppressors and oncogenes encoded by the nuclear genome are known to play a critical role in breast tumorigenesis, the contribution of the mitochondrial genome to this process is unclear. Like the nuclear genome, the mitochondrial genome also encodes proteins critical for mitochondrion functions such as oxidative phosphorylation (OXPHOS), which is known to be defective in cancer including breast cancer. Mitochondrial DNA (mtDNA) is more susceptible to mutations due to limited repair mechanisms compared to nuclear DNA (nDNA). Thus changes in mitochondrial genes could also contribute to the development of breast cancer. In this review we discuss mtDNA mutations that affect OXPHOS. Continuous acquisition of mtDNA mutations and selection of advantageous mutations ultimately leads to generation of cells that propagate uncontrollably to form tumors. Since irreversible damage to OXPHOS leads to a shift in energy metabolism towards enhanced aerobic glycolysis in most cancers, mutations in mtDNA represent an early event during breast tumorigenesis, and thus may serve as potential biomarkers for early detection and prognosis of breast cancer. Because mtDNA mutations lead to defective OXPHOS, development of agents that target OXPHOS will provide specificity for preventative and therapeutic agents against breast cancer with minimal toxicity.     

Protein kinase C signaling and oxidative stress

Oxidative stress is involved in the pathogenesis of various degenerative diseases including cancer. It is now recognized that low levels of oxidants can modify cell-signaling proteins and that these modifications have functional consequences. Identifying the target proteins for redox modification is key to understanding how oxidants mediate pathological processes such as tumor promotion. These proteins are also likely to be important targets for chemopreventive antioxidants, which are known to block signaling induced by oxidants and to induce their own actions. Various antioxidant preventive agents also inhibit PKC-dependent cellular responses. Therefore, PKC is a logical candidate for redox modification by oxidants and antioxidants that may in part determine their cancer-promoting and anticancer activities, respectively. PKCs contain unique structural features that are susceptible to oxidative modification. The N-terminal regulatory domain contains zinc-binding, cysteine-rich motifs that are readily oxidized by peroxide. When oxidized, the autoinhibitory function of the regulatory domain is compromised and, consequently, cellular PKC activity is stimulated. The C-terminal catalytic domain contains several reactive cysteines that are targets for various chemopreventive antioxidants such as selenocompounds, polyphenolic agents such as curcumin, and vitamin E analogues. Modification of these cysteines decreases cellular PKC activity. Thus the two domains of PKC respond differently to two different type of agents: oxidants selectively react with the regulatory domain, stimulate cellular PKC, and signal for tumor promotion and cell growth. In contrast, antioxidant chemopreventive agents react with the catalytic domain, inhibit cellular PKC activity, and thus interfere with the action of tumor promoters.     

Sequence-dependent formation of alkyl DNA adducts: A review of methods, results, and biological correlates

Understanding the influence of the DNA sequence on chemical-DNA interactions may provide insight into the processes of chemical carcinogenesis and mutagenesis. This article provides a brief overview of studies and methods devoted to examining the distribution of DNA adducts produced by alkylating agents. Particular emphasis is placed on discussion of DNA adducts generated by simple alkylating agents and the role that their distribution may play in the generation of mutational hotspots.     

Oxidative damage to DNA: formation, measurement and biochemical features

Emphasis is placed in the first part of this survey on mechanistic aspects of the formation of 8-oxo-7,8-dihydroguanine (8-oxoGua) as the result of exposure to z.rad;OH radical, one-electron oxidants and singlet oxygen (1O(2)) oxidation. It was found that 8-oxoGua, which is generated by either hydration of the guanine radical cation or .OH addition at C8 of the imidazole ring, is a preferential target for further reactions with 1O(2) and one-electron oxidants, including the highly oxidizing oxyl-type guanine radical. Interestingly, tandem base lesions that involve 8-oxoGua and a vicinal formylamine residue were found to be generated within DNA as the result of a single .OH radical hit. The likely mechanism of formation of the latter lesions involves the transient generation of 5-(6)-peroxy-6-(5)-hydroxy-5,6-dihydropyrimidyl radicals that may add to the C8 of a vicinal guanine base before undergoing rearrangement. Another major topic which is addressed deals with recent developments in the measurement of oxidative base damage to cellular DNA. This was mostly achieved using the accurate and highly specific HPLC method coupled with the tandem mass spectrometry detection technique. Interestingly, optimized conditions of DNA extraction and subsequent work-up allow the accurate measurement of 11 modified nucleosides and bases within cellular DNA upon exposure to oxidizing agents including UVA and ionizing radiations. Finally, recently available data on the substrate specificity of DNA repair enzymes belonging to the base excision and nucleotide excision pathways are briefly reviewed. For this purpose modified oligonucleotides in which cyclopurine, and cyclopyrimidine nucleosides were site-specifically inserted were synthesized.     

Mechanisms of DNA damage repair in adult stem cells and implications for cancer formation

Maintenance of genomic integrity in tissue-specific stem cells is critical for tissue homeostasis and the prevention of deleterious diseases such as cancer. Stem cells are subject to DNA damage induced by endogenous replication mishaps or exposure to exogenous agents. The type of DNA lesion and the cell cycle stage will invoke different DNA repair mechanisms depending on the intrinsic DNA repair machinery of a cell. Inappropriate DNA repair in stem cells can lead to cell death, or to the formation and accumulation of genetic alterations that can be transmitted to daughter cells and so is linked to cancer formation. DNA mutational signatures that are associated with DNA repair deficiencies or exposure to carcinogenic agents have been described in cancer. Here we review the most recent findings on DNA repair pathways activated in epithelial tissue stem and progenitor cells and their implications for cancer mutational signatures. We discuss how deep knowledge of early molecular events leading to carcinogenesis provides insights into DNA repair mechanisms operating in tumours and how these could be exploited therapeutically.     

Effect of Free Radicals and Temperature on Sister Chromatid Exchanges in Hordeum vulgare L.

The clastogenic (chromosome-damaging) effect of many chemical and physical agents is believed to be mediated by reactive oxygen-detived radicals. The interaction of these free radicals with DNA and the significance of the radical-induced DNA lesions in mutagenesis and carcinogenesis have been the subjects of increasing interest during recent years. Sister chromatid exchange (SCE) reflects an interchange between DNA molecules at homologous loci within a replicating chromosome. SCE analysis was found to have increased use for monitoring the exposure of cell to mutagenic carcinogens. The authors found that the induction of SCEs in cells of Hordeum vulgare L. by ascorbic acid, mitomycin C, adriamycin and maleic hydrazid was through the action of free radicals. They also studied the influence of growth temperature on average generation time(AGT) and SCEs. and disclosed a close correlation between AGT and SCEs. The Brdu-Giemsa techniques were used for the detection of SCEs and AGT in cytological preparations of metaphase chromosomes.     

Chromosome instability and kinetochore dysfunction

Chromosomal instability (CIN) has been recognized as a hallmark of human cancer and is caused by continuous chromosome missegregation during mitosis. Proper chromosome segregation requires a physical connection between spindle microtubules and centromeric DNA and this attachment occurs at proteinaceous structures called kinetochore. Thus, defect in kinetochore function is a candidate source for CIN and the generation of aneuploidy. Recently, a number of kinetochore components have been shown to be mutated and/or aberrantly expressed in human cancers, which suggests an important role of kinetochore for CIN and carcinogenesis. In this article, we will discuss about how kinetochore dysfunction causes CIN and might lead to the development of cancer.