DNA-PKcs基因沉默抑制人乳腺上皮细胞对低剂量辐射损伤的修复

DNA-PKcs作为DNA依赖性蛋白激酶(DNA-PK)的催化亚基在DNA双链断裂(DSBs)的非同源末端重组(NHEJ)通路中起重要的作用。本实验以人乳腺上皮细胞株MCF10F为研究对象,通过siRNA技术抑制细胞内DNA-PKcs的表达,用50cGy137CS照射细胞,测定细胞生长曲线以确定细胞对低剂量辐射(LDR)的敏感性,同时检测DNA修复相关蛋白表达的变化,旨在探讨DNA依赖蛋白激酶(DNA-PKcs)基因沉默对人乳腺上皮细胞株MCF10F低剂量辐射敏感性的影响及机制。结果显示:转染特异性siRNA可使人乳腺上皮细胞(MCF10F)DNA-PKcs基因沉默,增殖受到明显的抑制;50cGyγ射线辐射可使乳腺细胞内DNA-PKcs、Ku80、ATM、P53等DNA修复相关蛋白表达增多,但DNA-PKcs基因沉默细胞(MCF10Fpk)中,这些蛋白表达显著低于对照组(MCF10Fmock)。以上结果提示,DNA-PKcs基因沉默可引起乳腺细胞对低剂量辐射敏感性增加,其原因可能与相关DNA修复蛋白表达减少有关。     

ATP依赖型染色质重塑复合物在DNA双链断裂修复中的作用

DNA双链断裂修复缺陷易导致细胞基因组稳定性失衡、细胞发生癌变或死亡。真核生物主要通过同源重组和非同源末端连接两条途径来修复双链断裂。近年来发现多种ATP依赖型的染色质重塑蛋白复合物,包括RSC、INO80、Fun30、SWI/SNF和SWR1,直接参与了DNA双链断裂修复过程。它们主要通过调控DNA损伤检查点激活、断裂末端剪切及组蛋白H2AZ-H2B/H2A-H2B置换等重要步骤发挥功能。现以酿酒酵母中的研究为重点,综述主要ATP依赖型染色质重塑复合物在DNA双链断裂修复中的功能及作用机制。     

HIV-1Tat蛋白抑制DNA修复和增强细胞辐射敏感性

近年来临床研究发现,艾滋病合并肿瘤患者放疗后产生的正常组织和皮肤毒性反应明显高于普通肿瘤患者.本研究将探讨HIV-1Tat蛋白是否影响细胞对电离辐射敏感性及机理. 两个表达Tat蛋白的细胞系TT2和TE671-Tat均来源于人的横纹肌肉瘤细胞（TE671）并已转染了不同来源的tat基因.使用细胞辐射后克隆形成率检测辐射敏感性,RT-PCR和Western 印迹检测基因表达,彗星电泳和γ-H2AX位点检测DNA双链断裂和修复. TT2和TE671-Tat细胞的辐射敏感性与转染空载体及对照细胞相比明显增加.彗星电泳和γ-H2AX位点检测表明,在表达Tat蛋白的细胞中,辐射诱导DNA双链断裂的修复水平明显降低.通过RT-PCR和Western 印迹检测进一步证实,表达Tat蛋白的细胞中DNA修复蛋白DNA-PKcs的表达被抑制. HIV-1Tat蛋白抑制DNA-PKcs的表达,降低DNA双链断裂的修复,使细胞的电离辐射敏感性增高.本研究为了解AIDS合并肿瘤患者对放射治疗敏感性变化提供了重要信息.     

细胞周期监控点蛋白Rad9与非同源末端连接修复蛋白Ku70的相互作用研究

Rad9是一种重要的细胞周期监控点调控蛋白．越来越多的证据显示,Rad9也可与多种DNA损伤修复通路中的蛋白质相互作用,并调节其功能,在DNA损伤修复中发挥重要作用．非同源末端连接修复是DNA双链断裂的一条重要修复途径．Ku70、Ku80和DNA依赖的蛋白激酶催化亚基(DNA-PKcs)共同组成DNA依赖的蛋白激酶复合物(DNA-PK),在非同源末端修复连接中起重要作用．本研究中,检测到Rad9与Ku70有直接的物理相互作用和功能相互作用．我们在不同的细胞模型中发现,Rad9基因敲除、Rad9蛋白去除或Rad9表达降低会导致非同源末端连接效率明显下降．已有的研究表明,DNA损伤可导致细胞中Ku70与染色质结合增加及DNA-PKcs激酶活性增强．我们的结果显示,与野生小鼠细胞相比,Rad9基因敲除的小鼠细胞中, DNA损伤诱导的上述效应均减弱．综上所述,我们的研究首次报道了Rad9与非同源末端连接修复蛋白Ku70间有相互作用,并提示Rad9可通过调节Ku70/Ku80/DNA-PKcs复合物功能参与非同源末端连接修复．     

细胞周期监控点蛋白Rad9与非同源末端连接修复蛋白Ku70的相互作用研究（英文）

Rad9是一种重要的细胞周期监控点调控蛋白.越来越多的证据显示,Rad9也可与多种DNA损伤修复通路中的蛋白质相互作用,并调节其功能,在DNA损伤修复中发挥重要作用.非同源末端连接修复是DNA双链断裂的一条重要修复途径.Ku70、Ku80和DNA依赖的蛋白激酶催化亚基(DNA-PKcs)共同组成DNA依赖的蛋白激酶复合物(DNA-PK),在非同源末端修复连接中起重要作用.本研究中,检测到Rad9与Ku70有直接的物理相互作用和功能相互作用.我们在不同的细胞模型中发现,Rad9基因敲除、Rad9蛋白去除或Rad9表达降低会导致非同源末端连接效率明显下降.已有的研究表明,DNA损伤可导致细胞中Ku70与染色质结合增加及DNA-PKcs激酶活性增强.我们的结果显示,与野生小鼠细胞相比,Rad9基因敲除的小鼠细胞中, DNA损伤诱导的上述效应均减弱.综上所述,我们的研究首次报道了Rad9与非同源末端连接修复蛋白Ku70间有相互作用,并提示Rad9可通过调节Ku70/Ku80/DNA-PKcs复合物功能参与非同源末端连接修复.     

Ku基因在微生物中的研究进展

ku基因介导的非同源末端连接(NHEJ)途径是DNA双链断裂(DSBs)的一种修复机制,它不依赖于同源重组,且通过与之竞争而削弱同源重组。由于ku基因在生物进化过程中的高度保守性,其功能在很多微生物中已经得到研究,尤其在丝状真菌中,将ku基因敲除,在NHEJ途径缺陷的背景下,同源重组发挥主要作用,基因敲除的频率大为提高,从而方便了对基因功能的研究。     

DNA双链断裂修复与重症联合免疫缺陷

DNA双链断裂(double-strand breaks, DSBs)是细胞DNA损伤的主要类型,它的修复通过同源重组(HR)和非同源末端连接(NHEJ)两种机制实现.NHEJ是人和哺乳动物细胞DSBs修复的重要通路,主要由DNA依赖性蛋白激酶(DNA-PK)、X射线修复交叉互补蛋白4(XRCC4)、DNA连接酶Ⅳ、Artemis、XLF/Cernunnos和其它DNA损伤修复辅助因子组成.本文重点介绍了NHEJ机制主要成分的特性及其功能,以及这些组分的基因发生突变或缺失所引起的DSBs修复缺陷与辐射敏感性重症联合免疫缺陷(radiosensitive severe combined immunodeficiencies, RS-SCIDs).     

耐辐射球菌DNA双链断裂修复机制研究新进展

耐辐射球菌对于电离辐射等DNA损伤剂具有极强的抗性,能够将同一个基因组中同时产生的高达100个以上的DNA双链断裂在数十小时内高效而精准地进行修复,是研究DNA双链断裂修复机制的重要模式生物。同源重组、非同源末端连接和单链退火途径作为3个主要的修复途径参与了耐辐射球菌基因组DNA双链断裂的修复过程。此外,一系列新发现的重要蛋白质,如Ppr I、Ddr B等对于耐辐射球菌基因组的修复过程同样至关重要。根据本实验室和国内外在这一研究领域近年来的报道,以不同的修复途径为线索,综述该菌DNA双链断裂修复机制的最新研究成果。     

AT细胞DNA双链断裂重接修复效率及其忠实性

用脉冲电场凝胶电泳和双标记基因质粒ＤＮＡ转染技术研究辐射敏感的毛细血管扩张性共济失调症患者皮肤成纤维细胞（ＡＴ５ＢＩＶＡ）和正常辐射抗性的人宫颈癌细胞（ＨｅＬａＳ３）ＤＮＡ双链断裂重接修复率及其忠实性。结果表明γ射线照射诱发ＤＮＡ双链断裂的产额和重接修复率,在两株细胞间无差别．而ＡＴ细胞对导入的限制性内切酶ＥｃｏＲＶ产生双链断裂质粒ＤＮＡ的重接修复忠实性显著低于ＨｅｌａＳ３ｔｅ胞,表明ＡＴ细胞易发生ＤＮＡ错误修复,这很可能就是ＡＴ细胞高度辐射敏感性的主要原因。     

电离辐射诱导DNA—PKcs缺失小鼠T细胞特异的V（D）J重组恢复

NA依赖的蛋白激酶 (DNA PK)是一种DNA活化的核丝氨酸苏氨酸蛋白激酶。DNA PK由一种与DNA末端结合的调节亚单位异构二聚体Ku蛋白和DNA PK催化亚单位 (DNA PKcs)组成。DNA PK在DNA暴露于电离辐射后诱导的双链损伤修复中起主要作用。为了更好地了解与DNA PKcs缺失相关的DNA修复缺陷的本质。建立了DNA PKcs-/ -小鼠胚胎成纤维细胞株和裸鼠模型 ,调查这些突变的细胞和小鼠对DNA损害的反应。DNA PKcs-/ -细胞对电离辐射超敏感 ,在克隆形成实验中显示较低的生成率。同样 ,DNA PKcs-/ -小鼠也显示极大的放射敏感性 ,新生DNA PKcs-/ -小鼠用亚致死剂量电离辐射处理恢复T细胞受体 (TCR) β重组和T细胞成熟。然而 ,放射辐射并不恢复B细胞发育。DNA PKcs-/ -小鼠最终发生胸腺淋巴瘤。这些结果提示DNA双链断裂 (DSB)修复 ,V(D)J重组和淋巴瘤发生之间的相互关系。提供一种体内模型以阐明DNADSB修复调节、V(D)J重组和淋巴瘤发生分子机制三者之间的关键通路     

Mutations in two Ku homologs define a DNA end-joining repair pathway in Saccharomyces cerevisiae.

DNA double-strand break (DSB) repair in mammalian cells is dependent on the Ku DNA binding protein complex. However, the mechanism of Ku-mediated repair is not understood. We discovered a Saccharomyces cerevisiae gene (KU80) that is structurally similar to the 80-kDa mammalian Ku subunit. Ku8O associates with the product of the HDF1 gene, forming the major DNA end-binding complex of yeast cells. DNA end binding was absent in ku80delta, hdf1delta, or ku80delta hdf1delta strains. Antisera specific for epitope tags on Ku80 and Hdf1 were used in supershift and immunodepletion experiments to show that both proteins are directly involved in DNA end binding. In vivo, the efficiency of two DNA end-joining processes were reduced >10-fold in ku8Odelta, hdfldelta, or ku80delta hdf1delta strains: repair of linear plasmid DNA and repair of an HO endonuclease-induced chromosomal DSB. These DNA-joining defects correlated with DNA damage sensitivity, because ku80delta and hdf1delta strains were also sensitive to methylmethane sulfonate (MMS). Ku-dependent repair is distinct from homologous recombination, because deletion of KU80 and HDF1 increased the MMS sensitivity of rad52delta. Interestingly, rad5Odelta, also shown here to be defective in end joining, was epistatic with Ku mutations for MMS repair and end joining. Therefore, Ku and Rad50 participate in an end-joining pathway that is distinct from homologous recombinational repair. Yeast DNA end joining is functionally analogous to DSB repair and V(D)J recombination in mammalian cells.     

Cell polarity protein Par3 complexes with DNA-PK via Ku70 and regulates DNA double-strand break repair

The partitioning-defective 3 (Par3),a key component in the conserved Par3/Par6/aPKC complex,plays fundamentalroles in cell polarity.Herein we report the identification of Ku70 and Ku80 as novel Par3-interacting proteins throughan in vitro binding assay followed by liquid chromatography-tandem mass spectrometry.Ku70/Ku80 proteins are twokey regulatory subunits of the DNA-dependent protein kinase (DNA-PK),which plays an essential role in repairingdouble-strand DNA breaks (DSBs).We determined that the nuclear association of Par3 with Ku70/KuS0 was enhancedby y-irradiation (IR),a potent DSB inducer.Furthermore,DNA-PKcs,the catalytic subunit of DNA-PK,interacted withthe Par3/Ku70/Ku80 complex in response to IR.Par3 over-expression or knockdown was capable of up-or downregulat-ing DNA-PK activity,respectively.Moreover,the Par3 knockdown cells were found to be defective in random plasmidintegration,defective in DSB repair following IR,and radiosensitive,phenotypes similar to that of Ku70 knockdowncells.These findings identify Par3 as a novel component of the DNA-PK complex and implicate an unexpected link ofcell polarity to DSB repair.     

The Ku complex promotes DNA end-bridging and this function is antagonized by Tel1/ATM kinase

DNA double-strand breaks (DSBs) can be repaired by either homologous recombination (HR) or non-homologous end-joining (NHEJ). NHEJ is induced by the binding to DSBs of the Ku70–Ku80 heterodimer, which acts as a hub for the recruitment of downstream NHEJ components. An important issue in DSB repair is the maintenance of the DSB ends in close proximity, a function that in yeast involves the MRX complex and Sae2. Here, we provide evidence that Ku contributes to keep the DNA ends tethered to each other. The ku70-C85Y mutation, which increases Ku affinity for DNA and its persistence very close to the DSB ends, enhances DSB end-tethering and suppresses the end-tethering defect of sae2Δ cells. Impairing histone removal around DSBs either by eliminating Tel1 kinase activity or nucleosome remodelers enhances Ku persistence at DSBs and DSB bridging, suggesting that Tel1 antagonizes the Ku function in supporting end-tethering by promoting nucleosome removal and possibly Ku sliding inwards. As Ku provides a block to DSB resection, this Tel1 function can be important to regulate the mode by which DSBs are repaired.     

Cmku70基因敲除对蛹虫草生长发育的影响

ku70和ku80是非同源末端连接修复通路的关键基因,在一些丝状真菌中其基因敲除株可作为底盘菌株,提高同源重组效率和基因敲除效率.本研究从蛹虫草基因组中鉴定得到Cmku70 及 Cmku80基因,分别编码分子量为71.50kDa和80.96kDa的蛋白,均含有Ku core结构域,预测均定位于细胞核.系统进化分析表明K...     

Pathway utilization in response to a site-specific DNA double-strand break in fission yeast

We have examined the genetic requirements for efficient repair of a site-specific DNA double-strand break (DSB) in Schizosaccharomyces pombe. Tech nology was developed in which a unique DSB could be generated in a non-essential minichromosome, Ch(16), using the Saccharomyces cerevisiae HO-endonuclease and its target site, MATa. DSB repair in this context was predominantly through interchromosomal gene conversion. We found that the homologous recombination (HR) genes rhp51(+), rad22A(+), rad32(+) and the nucleotide excision repair gene rad16(+) were required for efficient interchromosomal gene conversion. Further, DSB-induced cell cycle delay and efficient HR required the DNA integrity checkpoint gene rad3(+). Rhp55 was required for interchromosomal gene conversion; however, an alternative DSB repair mechanism was used in an rhp55Delta background involving ku70(+) and rhp51(+). Surprisingly, DSB-induced minichromosome loss was significantly reduced in ku70Delta and lig4Delta non-homologous end joining (NHEJ) mutant backgrounds compared with wild type. Furthermore, roles for Ku70 and Lig4 were identified in suppressing DSB-induced chromosomal rearrangements associated with gene conversion. These findings are consistent with both competitive and cooperative interactions between components of the HR and NHEJ pathways.     

Overexpression of human Ku70/Ku80 in rat cells resulting in reduced DSB repair capacity with appropriate increase in cell radiosensitivity but with no effect on cell recovery.

The effect of an overexpression of human Ku70/80 was studied using cells of the rat cell lines Rat-1 and R7080, the latter being transfected with the human cDNAs for Ku70 and Ku80. The overexpression was found to result in a 20% reduction of the DNA-PK activity. The kinetics of DSB repair, which was studied after exposure of the cells to 30 Gy of X rays, was biphasic and had identical half-times for Rat-1 and R7080 cells (tfast = 7 min and tslow = 135 min). However, there was a significant difference between the cell lines in the fractions of DSBs repaired with slow and fast kinetics. In R7080 cells, about twice as many DSBs were repaired with slow kinetics compared to Rat-1 cells (34% compared to 16%). A similar difference was found in the number of residual DSBs (3.6% compared to 2.0%). R7080 cells also showed a reduced capacity to repair chromosome damage as detected by the PCC technique. Concerning cell killing, R7080 cells were clearly more radiosensitive than Rat-1 cells (D0.1 = 6.4 compared to 10.5 Gy), and this increase in sensitivity correlated well with the increase in residual DSBs. The two cell lines, however, did not vary in cell recovery. For sublethal as well as potentially lethal damage, Rat-1 and R7080 cells showed identical recovery ratios. These data demonstrate that the overexpression of human Ku70/Ku80 led to a reduced capacity for DSB repair with an associated increase in cell sensitivity but with no effect on cell recovery.     

Ablating putative Ku70 phosphorylation sites results in defective DNA damage repair and spontaneous induction of hepatocellular carcinoma

Multiple pathways mediate the repair of DNA double-strand breaks (DSBs), with numerous mechanisms responsible for driving choice between the pathways. Previously, we reported that mutating five putative phosphorylation sites on the non-homologous end joining (NHEJ) factor, Ku70, results in sustained retention of human Ku70/80 at DSB ends and attenuation of DSB repair via homologous recombination (HR). In this study, we generated a knock-in mouse, in which the three conserved putative phosphorylation sites of Ku70 were mutated to alanine to ablate potential phosphorylation (Ku70^3A/3A), in order to examine if disrupting DSB repair pathway choice by modulating Ku70/80 dynamics at DSB ends results in enhanced genomic instability and tumorigenesis. The Ku70^3A/3A mice developed spontaneous and have accelerated chemical-induced hepatocellular carcinoma (HCC) compared to wild-type (Ku70^+/+) littermates. The HCC tumors from the Ku70^3A/3A mice have increased γH2AX and 8-oxo-G staining, suggesting decreased DNA repair. Spontaneous transformed cell lines from Ku70^3A/3A mice are more radiosensitive, have a significant decrease in DNA end resection, and are more sensitive to the DNA cross-linking agent mitomycin C compared to cells from Ku70^+/+ littermates. Collectively, these findings demonstrate that mutating the putative Ku70 phosphorylation sites results in defective DNA damage repair and disruption of this process drives genomic instability and accelerated development of HCC.     

Suppression of a DNA double-strand break repair gene,Ku70, increases radio- and chemosensitivity in a human lung carcinoma cell line

Ku70 protein, cooperating with Ku80 and DNA-dependent protein kinase (DNA-PK) catalytic subunit (DNA-PKcs), is involved in DNA double-strand break (DNA DSB) repair and V(D)J recombination. Recent studies have revealed increased ionizing radiosensitivity in Ku70-deficient cells. The presented study, using a human squamous cell lung carcinoma cell line, demonstrated that introduction of an antisense Ku70 nucleic acid made the cells more radio- and chemosensitive than the parental cells. Ku70 protein expression was suppressed in the cells with antisense Ku70 construct when compared to the wild-type cells. A relatively small but statistically significant increase in radiosensitivity of the cells was achieved by the introduction of the antisense Ku70. The increased radiosensitivity in vitro was accompanied by an approximately two-fold increase in alpha and alpha/beta values in a linear-quadratic model. The antisense Ku70 increased the chemosensitivity of the cells to some DNA-damaging agents such as bleomycin and methyl methanesulfonate, but not to cisplatin, mitomycin C, and paclitaxel. This system provides us with partial suppression of Ku70, and will be a useful experimental model for investigating the physiological roles of the DNA DSB repair gene.     

Persistently bound Ku at DNA ends attenuates DNA end resection and homologous recombination

DNA double strand breaks (DSBs) are repaired by non-homologous end joining (NHEJ) or homologous recombination (HR). The DNA cell cycle stage and resection of the DSB ends are two key mechanisms which are believed to push DSB repair to the HR pathway. Here, we show that the NHEJ factor Ku80 associates with DSBs in S phase, when HR is thought to be the preferred repair pathway, and its dynamics/kinetics at DSBs is similar to those observed for Ku80 in non-S phase in mammalian cells. A Ku homolog from Mycobacterium tuberculosis binds to and is retained at DSBs in S phase and was used as a tool to determine if blocking DNA ends affects end resection and HR in mammalian cells. A decrease in DNA end resection, as marked by IR-induced RPA, BrdU, and Rad51 focus formation, and HR are observed when Ku deficient rodent cells are complemented with Mt-Ku. Together, this data suggests that Ku70/80 binds to DSBs in all cell cycle stages and is likely actively displaced from DSB ends to free the DNA ends for DNA end resection and thus HR to occur.     

KARP-1 works as a heterodimer with Ku70, but the function of KARP-1 cannot perfectly replace that of Ku80 in DSB repair

Ku, the heterodimer of Ku70 and Ku80, plays an essential role in the DNA double-strand break (DSB) repair pathway, i.e., non-homologous end-joining (NHEJ). Two isoforms of Ku80 encoded by the same genes, namely, Ku80 and KARP-1 are expressed and function in primate cells, but not in rodent cells. Ku80 works as a heterodimer with Ku70. However, it is not yet clear whether KARP-1 forms a heterodimer with Ku70 and works as a heterodimer. Although KARP-1 appears to work in NHEJ, its physiological role remains unclear. In this study, we established and characterized EGFP-KARP-1-expressing xrs-6 cell lines, EGFP-KARP-1/xrs-6. We found that nuclear localization signal (NLS) of KARP-1 is localized in the C-terminal region. Our data showed that KARP-1 localizes within the nucleus in NLS-dependent and NLS-independent manner and forms a heterodimer with Ku70, and stabilizes Ku70. On the other hand, EGFP-KARP-1 could not perfectly complement the radiosensitivity and DSB repair activity of Ku80-deficient xrs-6 cells. Furthermore, KARP-1 could not accumulate at DSBs faster than Ku80, although EGFP-KARP-1 accumulates at DSBs. Our data demonstrate that the function of KARP-1 could not perfectly replace that of Ku80 in DSB repair, although KARP-1 has some biochemical properties, which resemble those of Ku80, and works as a heterodimer with Ku70. On the other hand, the number of EGFP-KARP-1-expressing xrs-6 cells showing pan-nuclear γ-H2AX staining significantly increases following X-irradiation, suggesting that KARP-1 may have a novel role in DSB response.