共济失调毛细血管扩张症突变基因与端粒不稳定性关系研究进展

在电离辐射等因素造成的DNA损伤修复信号传导过程中,共济失调毛细血管扩张症突变基因(ATM)起关键作用。同时,ATM属于P13K家族成员,其功能与保持端粒长度有关。端粒是真核细胞内染色体末端的重复的DNA序列,端粒的长短和稳定性决定了细胞的寿命。ATM突变导致端粒的不稳定性,包括端粒连接、端粒染色质结构变化,影响端粒聚集等。     

DSB重组修复与肿瘤关系的研究进展

DNA损伤未及时有效地修复可导致基因组不稳定,增加肿瘤发生率。DSB是基因突变、染色体断裂的主要原因之一,并对肿瘤发生、发展具有一定影响,其修复主要是通过HR和NHEJ两条重组途径完成的。本综述了国外近来对DSB重组修复的HR和NHEJ途径,其与肿瘤抑制蛋白如P53、ATM、BRCA1和BRCA2之间的联系;DSB重组修复异常与某些肿瘤及具有肿瘤易感特征的共济失调性毛细血管扩张症和Nijmegen断裂综合征等疾病之间关系的研究进展。     

DNA双链断裂损伤反应及它的医学意义

DNA损伤应激反应是维持基因组稳定性的基石.细胞在长期进化中形成了由损伤监视、周期调控、损伤修复、凋亡诱导等在内的自稳平衡机制.一方面,借助感应、识别并启动精细而复杂的修复机制修复损伤;另一方面,通过DNA损伤应激活化的细胞周期检查点机制,延迟或阻断细胞周期进程,为损伤修复提供时间,使细胞能安全进入新一轮细胞周期;损伤无法修复时则诱导细胞凋亡.DNA双链断裂(double strand breaks,DSBs)是真核基因组后果最严重的损伤类型之一,其修复不利,同肿瘤等人类疾病的发生发展密切相关.新进展揭示:DSBs损伤反应信号分子ATM-Chk2-p53、H2AX等的组成性活化,是肿瘤形成早期所激活的细胞内可诱导的抗癌屏障,其信号网络的精确、精细调控在基因组稳定性维持中发挥重要作用.此外,HIV病毒整合进入宿主细胞基因组的过程也依赖于宿主细胞中ATM介导的DSBs损伤反应信号转导;ATM特异性的小分子抑制剂在抗HIV感染中显示重要的功能意义.文中重点讨论调控DSBs损伤应激反应信号网络的主要研究进展,及其在肿瘤发生、发展及抗HIV感染中的新医学意义.     

原发性肝癌ATM基因启动子甲基化及其与放疗疗效的相关性

为探究原发性肝癌(hepatocellular carcinoma, HCC)共济失调-毛细血管扩张突变基因(ataxia-telangiectasia mutated gene, ATM)启动子甲基化情况,分析其与临床特征的关系及与放疗疗效的相关性,采用甲基化特异性PCR法(methylation-specific PCR, MSP)检测50对肝癌手术标本及相应的癌旁肝组织标本、20例正常肝组织、38例局部中晚期肝癌肝穿刺标本的ATM基因启动子甲基化状态,并采用BSP (bisulfite sequencing PCR)测序法对样本的甲基化状态进行验证,分析ATM基因启动子甲基化状态与患者临床特征的关系及与放疗疗效的相关性。结果发现, 88例肝癌组织中ATM基因启动子甲基化率为39.8%(35/88),其中38例肝癌肝穿刺标本有42.1%(16/38)存在ATM基因启动子甲基化, 50例肝癌手术标本有38%(19/50)存在ATM基因启动子甲基化,相应癌旁肝组织只有8.0%(4/50)存在ATM基因启动子甲基化;正常肝组织未发现有ATM基因启动子甲基化, ATM基因启动子甲基化在肝癌组织中的发生率与癌旁肝组织、正常肝组织相比差异具有统计学意义(χ2=24.818,P0.05)。此外,存在ATM基因启动子甲基化的局部中晚期肝癌患者的放疗疗效显著优于无甲基化的病例(χ2=5.955,P=0.015), ATM基因启动子甲基化状态与肝癌放疗疗效呈显著正相关关系(r=0.396, P=0.014)。实验结果表明原发性肝癌ATM基因启动子存在异常甲基化, ATM基因启动子甲基化状态与肝癌放疗疗效关系密切,可为筛选放射敏感差异病人提供新的思路。     

hnRNP U复合物结构及功能

核不均一核糖核蛋白（heterogeneous nuclear ribonucleoprotein,hnRNPs）是一组RNA结合蛋白,它们与人体健康密切相关,参与肿瘤发生、病毒感染、细胞凋亡等多种病理生理过程的调节.hnRNP U是其中分子量最大的磷酸化蛋白质,对基因的转录、定位和表达特别是性染色体的表观失活过程发挥着重要作用.hnRNP U多以DNA/RNA蛋白复合物形式参与细胞功能调节.     

核孔复合物的结构、组装及功能

核孔复合物(NPC)是一个巨型分子复合物,相对分子质量约125×106。脊椎动物的NPC由大约30种蛋白质组成,这些蛋白质的序列大多具有FG(苯丙氨酸-甘氨酸)重复序列。NPC锚定于双层核膜上,并且是物质跨核膜运输的惟一通道,它可快速介导小分子物质的被动运输以及大分子物质的主动运输过程。虽然NPC具有较大的相对分子质量和复杂的结构,但它可在细胞分裂过程中分离并重新组装。生物大分子经NPC的跨核膜运输直接影响真核细胞的生长、增殖、分化、发育等多种生命活动。本文重点介绍NPC的结构、组装及其功能特点。     

乳腺癌易感蛋白2的结构和功能

乳腺癌易感蛋白2是由乳腺癌易感基因2编码的一种在维持哺乳动物细胞染色体的稳定及DNA损伤生物应答中发挥重要作用的蛋白质。文章通过介绍近几年来对乳腺癌易感蛋白2的结构研究,阐述其在双链DNA损伤修复中的作用模型及其在肿瘤抑制中的功能。     

DNA双链断裂损伤修复系统研究进展

多种内源或外源因素都能造成细胞基因组DNA损伤,细胞内建立了复杂的修复系统来应对不同形式的损伤。其中DNA双链断裂(DNA double-strand breaks,DSBs)作为最严重的损伤形式,主要激活同源重组修复(Homologous recombination repair)和非同源末端连接(Non-homologous end joining)通路。这两条通路都是由多个修复元件参与、经过多步反应的复杂过程。两者各具特点、协同作用,共同维护细胞基因组的稳定性。对其分子机制的阐明为肿瘤放化疗的辅助治疗提供了潜在的作用靶点。     

毛细血管扩张性共济失调突变蛋白在细胞凋亡过程中被Caspase┐3降解

新近的研究揭示：ｃａｓｐａｓｅ蛋白酶在细胞凋亡中起着死亡执行者的重要功能．一些蛋白相继被证明在细胞凋亡中可被ｃａｓｐａｓｅ特异切割,其中参与ＤＮＡ损伤修复过程的聚ＡＤＰ核糖聚合酶（ＰＡＲＰ）以及ＤＮＡ依赖的蛋白激酶（ＤＮＡ－ＰＫ）,在细胞凋亡过程中被ｃａｓｐａｓｅ选择性切割具有特殊的功能意义．为探索与ＤＮＡ－ＰＫ催化亚基有较高同源性,含有ｃａｓｐａｓｅ切割位点,且功能上目前也被认为是感受ＤＮＡ损伤和参与信号传导途径的ＡＴＭ（Ａｔａｘｉａｔｅｌａｎｇ－ｉｅｃｔａｓｉａｍｕｔａｔｅｄ）蛋白,是否在凋亡过程中也可被切割而降解？应用体外转录与翻译系统获得ＡＴＭ蛋白的ＰＩ３Ｋ结构域,同时通过建立无细胞反应体系获得含ｃａｓｐａｓｅ活性的细胞抽提液,将两者在体外共同保温．结果发现：ＡＴＭ蛋白与ｃａｓｐａｓｅ－３能免疫共沉淀,ＡＴＭ蛋白的ＰＩ３Ｋ结构域可被ｃａｓｐａｓｅ－３特异切割,并观察到辐射诱发细胞调亡中ＡＴＭ蛋白的降解．从而进一步证实了ＤＮＡ损伤修复的抑制,促进细胞凋亡的发生．     

DNA链断裂检测技术的进展

DNA链损伤特别是DNA双链段裂(dsb)的检测方法是研究DNA辐射损伤的一个关键因素.已发展的检测DNA dsb的方法很多,但各种检测法均有其一定的优越性和适用范围,近年来应用较多并日益受到重视的新方法有原位杂交法,彗星试验(单细胞电泳法)以及高效毛细管电泳法等等.     

The MRN complex in double-strand break repair and telomere maintenance

Genomes are subject to constant threat by damaging agents that generate DNA double-strand breaks (DSBs). The ends of linear chromosomes need to be protected from DNA damage recognition and end-joining, and this is achieved through protein-DNA complexes known as telomeres. The Mre11-Rad50-Nbs1 (MRN) complex plays important roles in detection and signaling of DSBs, as well as the repair pathways of homologous recombination (HR) and non-homologous end-joining (NHEJ). In addition, MRN associates with telomeres and contributes to their maintenance. Here, we provide an overview of MRN functions at DSBs, and examine its roles in telomere maintenance and dysfunction.     

Comet assay evaluation of DNA single- and double-strand breaks induction and repair in C3H10T1/2 cells

Ionizing radiation is a potent inducer of DNA damage because it causes single- and double-strand breaks, alkali-labile sites, base damage, and crosslinks. The interest in ionizing radiation is due to its environmental and clinical implications. Single-strand breaks, which are the initial damage induced by a genotoxic agent, can be used as a biomarker of exposure, whereas the more biologically relevant double-strand breaks can be analyzed to quantify the extent of damage. In the present study the effects of ¹³⁷Cs γ-radiation at doses of 1, 5, and 10 Gray on DNA and subsequent repair by C3H10T1/2 cells (mouse embryo fibroblasts) were investigated. Two versions of the comet assay, a sensitive method for evaluating DNA damage, were implemented: the alkaline one to detect single-strand breaks, and the neutral one to identify double-strand breaks. The results show a good linear relation between DNA damage and radiation dose, for both single-strand and double-strand breaks. A statistically significant difference with respect to controls was found at the lowest dose of 1 Gy. Heterogeneity in DNA damage within the cell population was observed as a function of radiation dose. Repair kinetics showed that most of the damage was repaired within 2 h after irradiation, and that the highest rejoining rate occurred with the highest dose (10 Gy). Single-strand breaks were completely repaired 24 h after irradiation, whereas residual double-strand breaks were still present. This finding needs further investigation. This revised version was published online in July 2006 with corrections to the Cover Date.     

The role of NBS1 in DNA double strand break repair, telomere stability, and cell cycle checkpoint control

The genomes of eukaryotic cells are under continuous assault by environmental agents and endogenous metabolic byproducts. Damage induced in DNA usually leads to a cascade of cellular events, the DNA damage response. Failure of the DNA damage response can lead to development of malignancy by reducing the efficiency and fidelity of DNA repair. The NBS1 protein is a component of the MRE11/RAD50/NBS 1 complex （MRN） that plays a critical role in the cellular response to DNA damage and the maintenance of chromosomal integrity. Mutations in the NBS1 gene are responsible for Nijmegen breakage syndrome （NBS）, a hereditary disorder that imparts an increased predisposition to development of malignancy. The phenotypic characteristics of cells isolated from NBS patients point to a deficiency in the repair of DNA double strand breaks. Here, we review the current knowledge of the role of NBS1 in the DNA damage response. Emphasis is placed on the role of NBS1 in the DNA double strand repair, modulation of the DNA damage sensing and signaling, cell cycle checkpoint control and maintenance oftelomere stability.     

Mislocalization of the MRN complex prevents ATR signaling during adenovirus infection

The protein kinases ataxia‐telangiectasia mutated (ATM) and ATM‐Rad3 related (ATR) are activated in response to DNA damage, genotoxic stress and virus infections. Here we show that during infection with wild‐type adenovirus, ATR and its cofactors RPA32, ATRIP and TopBP1 accumulate at viral replication centres, but there is minimal ATR activation. We show that the Mre11/Rad50/Nbs1 (MRN) complex is recruited to viral centres only during infection with adenoviruses lacking the early region E4 and ATR signaling is activated. This suggests a novel requirement for the MRN complex in ATR activation during virus infection, which is independent of Mre11 nuclease activity and recruitment of RPA/ATR/ATRIP/TopBP1. Unlike other damage scenarios, we found that ATM and ATR signaling are not dependent on each other during infection. We identify a region of the viral E4orf3 protein responsible for immobilization of the MRN complex and show that this prevents ATR signaling during adenovirus infection. We propose that immobilization of the MRN damage sensor by E4orf3 protein prevents recognition of viral genomes and blocks detrimental aspects of checkpoint signaling during virus infection.     

A reporter mouse for in vivo detection of DNA damage in embryonic germ cells

Maintaining genome integrity in the germline is essential for survival and propagation of a species. In both mouse and human, germ cells originate during fetal development and are hypersensitive to both endogenous and exogenous DNA damaging agents. Currently, mechanistic understanding of how primordial germ cells respond to DNA damage is limited in part by the tools available to study these cells. We developed a mouse transgenic reporter strain expressing a 53BP1‐mCherry fusion protein under the control of the Oct4ΔPE embryonic germ cell‐specific promoter. This reporter binds sites of DNA double strand breaks (DSBs) on chromatin, forming foci. Using ionizing radiation as a DNA DSB‐inducing agent, we show that the transgenic reporter expresses specifically in the embryonic germ cells of both sexes and forms DNA damage induced foci in both a dose‐ and time‐dependent manner. The dynamic time‐sensitive and dose‐sensitive DNA damage detection ability of this transgenic reporter, in combination with its specific expression in embryonic germ cells, makes it a versatile and valuable tool for increasing our understanding of DNA damage responses in these unique cells.     

Contrasting effects of Krüppel‐like factor 4 on X‐ray‐induced double‐strand and single‐strand DNA breaks in mouse astrocytes

Astrocytes, the most common cell type in the brain, play a principal role in the repair of damaged brain tissues during external radiotherapy of brain tumours. As a downstream gene of p53, the effects of Krüppel‐like factor 4 (KLF4) in response to X‐ray‐induced DNA damage in astrocytes are unclear. In the present study, KLF4 expression was upregulated after the exposure of astrocytes isolated from the murine brain. Inhibition of KLF4 expression using lentiviral transduction produced less double‐strand DNA breaks (DSB) determined by a neutral comet assay and flow cytometric analysis of phosphorylated histone family 2A variant and more single‐strand DNA breaks (SSB) determined by a basic comet assay when the astrocytes were exposed to 4 Gy of X‐ray radiation. These data suggest that radiation exposure of the tissues around brain tumour during radiation therapy causes KLF4 overexpression in astrocytes, which induces more DSB and reduces SSB. This causes the adverse effects of radiation therapy in the treatment of brain tumours. Copyright © 2013 John Wiley & Sons, Ltd.     

Molecular mechanisms of exon shuffling: illegitimate recombination

Illegitimate recombination (IR) is a process that takes place far more often than homologous recombination and is characterized by the recombination between non-homologous or short homologous sequences. The consequences of IR frequently emerge after the introduction of DNA in cell lines because it more frequently integrates in non-homologous than in homologous regions of the host genome. As a result, unexpected truncated or elongated products may be found. By not discarding those products as transfection artifacts, but by studying how they are generated, it might elucidate a possible molecular mechanism of IR. Here we review the current literature describing different mechanisms by which non-homologous DNA recombination can be induced.     

Acylpeptide hydrolase is a component of the cellular response to DNA damage

Acylpeptide hydrolase (APEH) deacetylates N-alpha-acetylated peptides and selectively degrades oxidised proteins, but the biochemical pathways that are regulated by this protease are unknown. Here, we identify APEH as a component of the cellular response to DNA damage. Although APEH is primarily localised in the cytoplasm, we show that a sub-fraction of this enzyme is sequestered at sites of nuclear damage following UVA irradiation or following oxidative stress. We show that localization of APEH at sites of nuclear damage is mediated by direct interaction with XRCC1, a scaffold protein that accelerates the repair of DNA single-strand breaks. We show that APEH interacts with the amino-terminal domain of XRCC1, and that APEH facilitates both single-strand break repair and cell survival following exposure to H₂O₂ in human cells. These data identify APEH as a novel proteolytic component of the DNA damage response.