Damage and Repair of DNA in 5-Bromodeoxyuridine-Labeled Chinese Hamster Cells Exposed to Fluorescent Light

Illumination of Chinese hamster cells with fluorescent light after 5-bromodeoxyuridine incorporation leads to extensive single-strand breakage in the DNA of the exposed cells. The rate of production of single-strand breaks is dependent on the extent to which thymine is replaced by 5-bromouracil. At least some of the breaks observed with alkaline gradients are probably produced in vivo and are probably not contingent upon alkaline hydrolysis since breakage can be demonstrated with neutral gradients also. Cells are able to rejoin most of the single-strand breaks within 60 min; however, damage to the DNA-containing material (the “complex”) initially released from cells is repaired more slowly. Cysteamine protects against single-strand breakage with a dose-modifying factor of 2.8. A comparison is made between the production of single-strand breaks by fluorescent light and X-rays, and the significance of such breaks relative to cell survival is discussed.     

DNA Damage and Decreased DNA Repair in Peripheral Blood Mononuclear Cells in Individuals Exposed to Arsenic and Lead in a Mining Site

The aim of this study was to evaluate DNA damage and the capacity for DNA repair in children exposed to arsenic and lead. During 2006, we studied a total of 85 healthy children (aged 4–11 years) who were residents of Villa de la Paz (community A), Matehuala (community B), and Soledad de Graciano Sanchez (community C) in San Luis Potosi, Mexico. The quantification of arsenic in urine (AsU) and lead in blood (PbB) was performed by atomic absorption spectrophotometry. The alkaline comet assay was used to evaluate DNA damage and DNA repair. The highest levels of AsU and PbB in children were found in community A (44.5 μg/g creatinine for arsenic and 11.4 μg/dL for lead), followed by community B (16.8 μg/g creatinine for arsenic and 7.3 μg/dL for lead) and finally by children living in community C (12.8 μg/g creatinine for arsenic and 5.3 μg/dL for lead). When DNA damage was assessed, children living in community A had the highest DNA damage. Analysis of these same cells 1 h after a challenge with H₂O₂ 10 μM showed a dramatic increase in DNA damage in the cells of children living in community B and community C, but not in the cells of children living in community A. Moreover, significantly higher levels of DNA damage were observed 3 h after the challenge ended (repair period) in cells from individuals living in community A. Our results show that children exposed to metals might be more susceptible to DNA alterations.     

DNA Damage in Astrocytes Exposed to Fumonisin B1

Fumonisins are a group of toxic metabolites mainly produced by Fusarium moniliforme and Fusarium proliferatum, fungi that commonly occur on corn throughout the world. Fumonisin B₁ (FB₁), structurally resembling sphingoid bases, is an inhibitor of ceramide synthase, a key enzyme involved in de novo sphingolipid biosynthesis and in the reacylation of free sphingoid bases derived from sphingolipid turnover. This inhibitory effect leads to accumulation of free sphinganine (SA) and sphingosine (SO), inducing cell death. However, little is known on the down stream effectors activated by these sphingolipids in the cell death signaling pathway. We exposed rat astrocytes to FB₁ with the aim of evaluating the involvement of oxygen free radicals and of some other biochemical pathways such as caspase-3 activity and DNA damage. Our results indicate that FB₁ treatment (48, 72 h and 6 days in vitro, DIV, and 10, 50, 100 M) does not affect cell viability. Conversely, after 72 h of treatment, FB₁ (50 and 100 M) induced DNA damage and an enhancement of caspase-3 activity compared to controls. In addition, FB₁ increased the expression of HSP70 at 10 and 50 M at 48, 72 h, and 6 DIV of treatment. We conclude that DNA damage of apoptotic type in rat astrocytes is caused by FB₁ and that the genotoxic potential of FB₁ has probably been underestimated and should be reconsidered.     

DNA Damage and Repair in Eukaryotic Cells

DAMAGE IN DNA AFTER IRRADIATION CAN BE CLASSIFIED INTO FIVE KINDS: base damage, single-strand breaks, double-strand breaks, DNA-DNA cross-linking, and DNA-protein cross-linking. Of these, repair of base damage is the best understood. In eukaryotes, at least three repair systems are known that can deal with base damage: photoreactivation, excision repair, and post-replication repair. Photoreactivation is specific for UV-induced damage and occurs widely throughout the biosphere, although it seems to be absent from placental mammals. Excision repair is present in prokaryotes and in animals but does not seem to be present in plants. Post-replication repair is poorly understood. Recent reports indicate that growing points in mammalian DNA simply skip past UV-induced lesions, leaving gaps in newly made DNA that are subsequently filled in by de novo synthesis. Evidence that this concept is oversimplified or incorrect is presented.-Single-strand breaks are induced by ionizing radiation but most cells can rapidly repair most or all of them, even after supralethal doses. The chemistry of the fragments formed when breaks are induced by ionizing radiation is complex and poorly understood. Therefore, the intermediate steps in the repair of single-strand breaks are unknown. Double-strand breaks and the two kinds of cross-linking have been studied very little and almost nothing is known about their mechanisms for repair.-The role of mammalian DNA repair in mutations is not known. Although there is evidence that defective repair can lead to cancer and/or premature aging in humans, the relationship between the molecular defects and the diseased state remains obscure.     

A Fluorescent Probe to Measure DNA Damage and Repair

DNA damage and repair is a fundamental process that plays an important role in cancer treatment. Base excision repair (BER) is a major repair pathway that often leads to drug resistance in DNA-targeted cancer chemotherapy. In order to measure BER, we have developed a near infrared (NIR) fluorescent probe. This probe binds to a key intermediate, termed apurinic/apyrimidinic (AP) site, in the BER pathway where DNA damage and repair occurs. We have developed an assay to show the efficacy of the probe binding to AP sites and have shown that it can distinguish AP sites in DNA extract from chemotherapy treated cells. This probe has potential application in monitoring patient response to chemotherapy and evaluating new drugs in development.     

Sirtuin家族与DNA损伤修复

DNA损伤的发生与积累是造成细胞功能紊乱的根本原因,也是引起衰老与肿瘤等疾病发生的关键事件。为维持机体自身遗传物质的完整性与稳定性,生物体内拥有多种针对不同类型DNA损伤的修复方式。Sirtuin蛋白是一组NAD+依赖的、高度保守的组蛋白去乙酰化酶,可通过去乙酰化作用调节众多底物蛋白质的表达、活性与稳定性。 近来的研究显示,DNA损伤修复途径的多个关键蛋白质是Sirtuin的下游底物。Sirtuin蛋白通过调节同源重组修复、非同源末端修复、核苷酸切除修复等途径中的核心蛋白质参与修复包括双链断裂（double stranded breakes, DSBs）在内的多种DNA损伤类型,从而在维持基因组稳定性、寿命以及细胞能量代谢调节等一系列生物学作用中发挥至关重要的作用。本综述将介绍近年来Sirtuin与DNA损伤修复的研究进展。     

He-Ne激光对小麦幼苗增强UV-B辐射损伤的修复研究

分别采用5mW·mm-2He-Ne激光辐照和增强UV-B辐射(10.08kJ·m-2·d-1)及其二者组合对晋麦8号小麦幼苗进行处理,5d后测定各处理幼苗叶片可溶性蛋白、硝酸还原酶和谷氨酸脱氢酶活性的变化以分析He-Ne激光对小麦幼苗受增强UV-B损伤的修复作用.结果显示:He-Ne激光辐照可使UV-B辐射后小麦幼苗叶片的可溶性蛋白含量增加,谷氨酸脱氢酶活性增强,而使硝酸还原酶活性先升高后降低.表明小麦幼苗叶片可溶性蛋白、谷氨酸脱氢酶、硝酸还原酶的变化同小麦幼苗损伤修复的能力相关,一定剂量的He-Ne激光辐照可部分修复增强UV-B对小麦幼苗氮代谢水平的辐射损伤.     

DNA Damage Signalling and Repair in Dictyostelium discoideum

Repair of DNA double strand breaks (DSBs) is critical for the maintenance of genome integrity. DNA DSBs can be repaired by either homologous recombination (HR) or nonhomologous end-joining (NHEJ). Whilst HR requires sequences homologous to thedamaged DNA template in order to facilitate repair, NHEJ occurs through recognition of DNA DSBs by a variety of proteins that process and rejoin DNA termini by direct ligation. Here we review two recent reports that NHEJ is conserved in the social amoebaDictyostelium discoideum. Certain components of the mammalian NHEJ pathway that are absent in genetically tractable organisms such as yeast are present in Dictyostelium and we discuss potential directions for future research, in addition to considering this organism as a genetic model system for the study of NHEJ in vivo.     

DNA损伤修复过程表观遗传学改变

多种化学、物理及生物因素可诱发细胞DNA损伤,损伤后DNA损伤位点被相关损伤感受器识别,激活相应的修复通路进行DNA修复。越来越多的证据表明DNA甲基化状态、蛋白翻译后修饰、染色质重塑、miRNA等修饰方式参与了DNA的损伤修复。文章通过不同损伤修复通路中这些修饰的特点,阐述表观遗传学改变在DNA损伤修复发展过程中的作用机制。     

DNA Damage Checkpoint, Damage Repair, and Genome Stability

Genomic DNA is under constant attack from both endogenous and exogenous sources of DNA damaging agents. Without proper care, the ensuing DNA damages would lead to alteration of genomic structure thus affecting the faithful transmission of genetic information. During the process of evolution, organisms have acquired a series of mechanisms responding to and repairing DNA damage, thus assuring the maintenance of genome stability and faithful transmission of genetic information. DNA damage checkpoint is one such important mechanism by which, in the face of DNA damage, a cell can respond to amplified damage signals, either by actively halting the cell cycle until it ensures that critical processes such as DNA replication or mitosis are complete or by initiating apoptosis as a last resort. Over the last decade, complex hierarchical interactions between the key components like ATM/ATR in the checkpoint pathway and various other mediators, effectors including DNA damage repair proteins have begun to emerge. In the meantime, an intimate relationship between mechanisms of damage checkpoint pathway, DNA damage repair, and genome stability was also uncovered. Reviewed hereinare the recent findings on both the mechanisms of activation of checkpoint pathways and their coordination with DNA damage repair machinery as well as their effect on genomic integrity.     

DNA损伤检验点与损伤修复及基因组稳定性

生物有机体基因组DNA经常会受到内源或外源因素的影响而导致结构发生变化,产生损伤;在长期进化过程中,有机体也相应形成了一系列应对与修复损伤DNA,并维持染色体基因组正常结构功能的机制。其中DNA损伤检验点（DNA damage checkpoint）就是在感应DNA损伤的基础上,对损伤感应信号进行转导,或引起细胞周期的暂停,从而使细胞有足够的时间对损伤DNA进行修复,或最终导致细胞发生凋亡。DNA损伤检验点信号转导途径是一个高度保守的信号感应过程,整个途径大致可以分为损伤感应、信号传递及信号效应3个组成部分。其中3-磷脂酰肌醇激酶家族类成员ATM（ataxia-telangiectasia mutated）和ATR（ataxia-telangiectasia and Rad3-related）活性的增加构成整个途径活化的第一步。它们通过激活下游的效应激酶,Chk2／Chk1,通过协同作用许多其他调控细胞周期、DNA复制、DNA损伤修复及细胞凋亡等过程的蛋白质因子来实现细胞对DNA损伤的高度协调反应。近十几年,随着此领域研究的不断深入,人们逐步揭示了DNA损伤检验点途径发生过程中,各种核心组分通过与不同调节因子、效应因子及DNA损伤修复蛋白间的复杂相互作用,以实现监测感应异常DNA结构并实施相应反应的机制;其中,检验点衔接因子（mediators）及染色质结构,尤其是核小体组蛋白的共价修饰在调控ATM／ATR活性,促进ATM／ATR与底物间的相互作用以及介导DNA损伤位点周围染色质区域上多蛋白复合物在时间与空间上的动态形成发挥着重要的作用。同时,人们也开始发现DNA损伤检验点途径与DNA损伤修复、基因组稳定性以及肿瘤发生等过程之间某些内在的联系。该反应途径在通过协调细胞针对DNA损伤做出各种反应的基础上,直接或间接地参与或调控DNA损伤修复过程,并与DNA损伤修复途径协同作用最终保证染色体基凶组结构的完整性,而检验点途径的改变,则会引起基因组不稳定的发生,包括从突变频率的提高到大范围的染色体重排,以及染色体数量的畸变。如：突变发生在肿瘤形成早期,会大大增加肿瘤发生的几率。文章将对DNA损伤检验点途径机制及其对DNA损伤修复、基因组稳定性影响的最新进展进行综述。     

Loss of Urokinase Receptor Sensitizes Cells to DNA Damage and Delays DNA Repair

DNA damage induced by numerous exogenous or endogenous factors may have irreversible consequences on the cell leading to cell cycle arrest, senescence and cell death. The DNA damage response (DDR) is powerful signaling machinery triggered in response to DNA damage, to provide DNA damage recognition, signaling and repair. Most anticancer drugs induce DNA damage, and DNA repair in turn attenuates therapeutic efficiency of those drugs. Approaches delaying DNA repair are often used to increase efficiency of treatment. Recent data show that ubiquitin-proteasome system is essential for signaling and repair of DNA damage. However, mechanisms providing regulation of proteasome intracellular localization, activity, and recruitment to DNA damage sites are elusive. Even less investigated are the roles of extranuclear signaling proteins in these processes. In this study, we report the involvement of the serine protease urokinase-type plasminogen activator receptor (uPAR) in DDR-associated regulation of proteasome. We show that in vascular smooth muscle cells (VSMC) uPAR activates DNA single strand break repair signaling pathway. We provide evidence that uPAR is essential for functional assembly of the 26S proteasome. We further demonstrate that uPAR mediates DNA damage-induced phosphorylation, nuclear import, and recruitment of the regulatory subunit PSMD6 to proteasome. We found that deficiency of uPAR and PSMD6 delays DNA repair and leads to decreased cell survival. These data may offer new therapeutic approaches for diseases such as cancer, cardiovascular and neurodegenerative disorders.     

Human Telomeres Are Hypersensitive to UV-Induced DNA Damage and Refractory to Repair

Telomeric repeats preserve genome integrity by stabilizing chromosomes, a function that appears to be important for both cancer and aging. In view of this critical role in genomic integrity, the telomere''s own integrity should be of paramount importance to the cell. Ultraviolet light (UV), the preeminent risk factor in skin cancer development, induces mainly cyclobutane pyrimidine dimers (CPD) which are both mutagenic and lethal. The human telomeric repeat unit (5′TTAGGG/CCCTAA3′) is nearly optimal for acquiring UV-induced CPD, which form at dipyrimidine sites. We developed a ChIP–based technique, immunoprecipitation of DNA damage (IPoD), to simultaneously study DNA damage and repair in the telomere and in the coding regions of p53, 28S rDNA, and mitochondrial DNA. We find that human telomeres in vivo are 7-fold hypersensitive to UV-induced DNA damage. In double-stranded oligonucleotides, this hypersensitivity is a property of both telomeric and non-telomeric repeats; in a series of telomeric repeat oligonucleotides, a phase change conferring UV-sensitivity occurs above 4 repeats. Furthermore, CPD removal in the telomere is almost absent, matching the rate in mitochondria known to lack nucleotide excision repair. Cells containing persistent high levels of telomeric CPDs nevertheless proliferate, and chronic UV irradiation of cells does not accelerate telomere shortening. Telomeres are therefore unique in at least three respects: their biophysical UV sensitivity, their prevention of excision repair, and their tolerance of unrepaired lesions. Utilizing a lesion-tolerance strategy rather than repair would prevent double-strand breaks at closely-opposed excision repair sites on opposite strands of a damage-hypersensitive repeat.     

Sirtuins家族在DNA损伤修复中的作用

Sirtuins家族蛋白是一类依赖NAD的去乙酰化酶,属于第Ш类去乙酰化酶(HDACs),哺乳动物Sirtuins家族成员共有7个(SIRT1-7),其主要具有去乙酰化酶的活性,可以使多种蛋白发生去乙酰化,进而参与DNA的损伤修复、基因的转录调控、细胞凋亡、代谢及衰老等诸多生物进程。本文主要对Sirtuins家族在DNA损伤修复中的作用及其相关机制进行阐述。     

DNA Mismatch Repair and Chk1-Dependent Centrosome Amplification in Response to DNA Alkylation Damage

Centrosome amplification is frequently observed in tumour cells exposed to genotoxic stress, however the underlying mechanisms and biological consequences are poorly understood. Here, we show that the anti-metabolite and alkylating agent 6-thioguanine (6-TG) induces centrosome amplification resulting in the formation of multi-polar spindles when damaged cells subsequently enter mitosis. These aberrant, multi-polar mitoses are frequently resolved by asymmetric cell divisions causing unequal segregation of genetic material and cell death in one or both daughter products. We show that this phenomenon is associated with transient cell cycle delay in S- and G2-phase and is dependent on DNA mismatch repair (DNA MMR) proficiency and Chk1 protein kinase activity. Although Chk1-deficient cells do not exhibit cell cycle delay, centrosome amplification, or multi-polar spindle formation, continued cell cycle progression in the presence of 6-TG eventually results in increased levels of mitotic catastrophe, most probably due to mitosis with incompletely replicated DNA. Taken together, these results reveal novel mechanisms of cell killing by 6-TG and underscore the importance of interactions between cell cycle checkpoints and DNA MMR in determining the fate of cells bearing DNA damage.