电离辐射生物标志物γ-H2AX的检测技术研究进展

电离辐射可导致DNA双链断裂,从而使组蛋白H2AX迅速在双链断裂处磷酸化为γ-H2AX。检测细胞中γ-H2AX聚集处形成的焦点数目可用于评价DNA双链断裂情况,且与辐射剂量相关。因此,γ-H2AX可作为电离辐射的生物标志物,用来评价电离辐射的致突变能力,亦可作为电离辐射生物剂量计,用于估算个体受照剂量。γ-H2AX检测技术在辐射生物学研究、辐射分子流行病学调查,以及辐射事故应急响应与医学处置等方面具有重要应用价值。本文将重点阐述近十年来国内外基于电离辐射生物标志物γ-H2AX的检测方法研究进展和应用前景。     

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。     

辐射敏感细胞ku80基因突变及其DNA结合活性研究

RT-PCR克隆辐射敏感细胞及其亲本细胞的ku80基因cDNA,发现辐射敏感细胞的ku80基因与双链断裂DNA末端相互作用的位置存在基因突变,用凝胶阻滞和DNA-蛋白质印迹进一步证实突变ku基因编码蛋白结合双链断裂末端DNA的能力下降,暗示其细胞辐射敏感性可能与Ku蛋白功能异常有关.     

ADPRT抑制剂对不同辐射敏感性人肿瘤细胞株的作用比较

从细胞的克隆形成能力和细胞DNA双链断裂及修复几方面分析了两个人卵巢癌细胞株HOC8和A2780对电离辐射的敏感性并探讨了ADP-核糖基转移酶（ADPR）的特异性抑制剂3-氨基苯甲酰胺（3－AB）对二者的辐射增敏效应,结果表明A2780细胞的辐射敏感性大大高于HOC8细胞,其D0值分别为0．9和2．5Gy;γ射线所致两株细胞的初始DNA双链断裂水平没有显著差异,但A2780细胞对DNA双链断裂的修复能力比HOC8细胞低．3AB能降低受照细胞的克隆形成能力及细胞对双链断裂的修复能力,其中对HOC8细胞的作用更为明显．     

H2AX活化与DNA双链断裂及辐射剂量的关系

H2AX是组蛋白H2A的一种亚型。过去对组蛋白的关注仅局限在维持染色质结构的认识方面,近来发现构成染色质核小体的组蛋白同时具有许多其他重要生物学功能,在DNA双链断裂修复中的作用就是最重要的发现之一。H2AX蛋白发挥其功能需要活化,活化后的H2AX称为γH2AX。检测γH2AX可以确定DNA双链断裂的存在,γH2AX的检测量与辐射剂量也存在良好的量效关系。     

咖啡因抑制辐照区和旁区细胞的γ-H2AX foci的形成

辐射诱导的旁效应不仅在体外实验存在,也在动物体内存在,这对辐射剂量的计算和辐射风险的评估有重要影响。咖啡因是一个模式辐射敏感剂,显著增强辐射的细胞毒性。咖啡因也显著增强辐射诱导的旁效应,咖啡因处理使未受辐照的旁细胞对损伤信号更加敏感,但其机理并不清楚。在正常人原代细胞AG1522中,分析了咖啡因处理对组蛋白H2AX磷酸化的影响,咖啡因显著减少α粒子辐射区和旁区γ-H2AX foci阳性细胞的比率和每个细胞γ-H2AX foci点数,表明咖啡因处理抑制了H2AX磷酸化,后者启动细胞对DNA双链断裂的修复,从而提示咖啡因增强辐射旁效应可能的机理,对辐射治疗具有重要意义。     

沉默DNA-PKcs对细胞信号转导相关基因转录的影响

利用RNA干扰技术构建DNA-PKcs表达抑制细胞模型,探讨DNA-PKcs对HeLa细胞信号转导相关基因表达的调控作用.通过观察细胞对辐射及顺铂的敏感性,鉴定细胞表型变化.用寡核苷酸芯片检测细胞信号转导相关基因的转录谱,并用RT-PCR方法和SEAP检测系统进一步验证基因的表达变化.所筛选出的DNA-PKcs表达抑制细胞对辐射及顺铂的敏感性升高,15个与细胞信号转导相关的基因表达升高,其中7个是与干扰素信号转导反应相关的基因.8个表达下降,包括有细胞增殖分化相关基因,如NFAT.RT-PCR检测结果与芯片结果相一致,利用SEAT报告系统检测,进一步证实NFAT转录活性下调.实验结果表明,DNA-PKcs除了参与DNA修复外,还调控细胞信号转导相关基因的表达,而且大多与细胞增殖分化相关.     

53BP1缺失补偿DNA同源重组修复增强BCCIP阴性乳腺癌细胞放疗抗性

三阴性乳腺癌作为预后较差的乳腺癌亚型,高辐射抗性及分子靶点不明确是影响其放疗效果的主要原因。本研究从一条新的途径,即BCCIP/53BP1途径,研究三阴性乳腺癌高辐射抗性的机制。首先,利用高通量染色体精确分析系统检测X射线照射后53BP1缺失对BCCIP阴性小鼠乳腺癌细胞染色体畸变率的影响,并以免疫荧光染色和蛋白质印迹(Western blot)方法检测53BP1缺失对BCCIP阴性乳腺癌细胞DNA双链断裂损伤恢复效率的影响;随后,采用DR-GFP荧光报告系统和姐妹染色体互换试验检测53BP1对BCCIP阴性乳腺癌细胞同源重组修复效率的调节作用;最后,通过克隆形成试验检测X射线照射后53BP1和BCCIP的共同缺失对乳腺癌细胞存活率的调控效果。结果表明:53BP1缺失下调BCCIP阴性小鼠乳腺癌细胞X射线照射后染色体畸变率的发生;53BP1/BCCIP双缺失乳腺癌细胞受照后,DNA双链断裂标志物γH2AX水平和焦点数量均低于BCCIP单缺失细胞;下调53BP1表达时,受照BCCIP阴性乳腺癌细胞的同源重组修复效率得到明显恢复,并且细胞辐射抗性得到明显增强。综上所述,53BP1缺失通过解除对同源重组修复的抑制,增加了BCCIP阴性乳腺癌细胞DNA双链断裂的修复效率,从而提高了细胞的辐射抗性。研究结果为阐明BCCIP/53BP1通过调控同源重组修复途径影响BCCIP阴性乳腺癌细胞辐射敏感性的作用机制,揭示三阴性乳腺癌放疗抗性的分子机制,以及发现新的放疗增敏靶点,提供了理论依据。     

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.     

X射线对人外周血淋巴细胞DNA损伤修复和凋亡的影响

目的 研究不同时间诱导X射线照射的淋巴细胞进入细胞周期DNA损伤修复与凋亡的影响.方法 X射线（0.5 Gy）作用于正常人外周血淋巴细胞,以照射后不同时间点（0、4 h）分别加入PHA并分成两组,即照射后0 h加PHA组（A组）和照射后4 h加PHA组（B组）,再分别培养0、0.5、2 h,用流式细胞术和免疫印迹法检测A组和B组γ-H2AX蛋白的表达,Annexin-V/PI法分析A、B两组的细胞凋亡率.结果 流式细胞术及免疫印迹结果均显示A组的γ-H2AX蛋白表达高于B组（P＜0.05）,且均先升高后降低.A组细胞凋亡率亦大于B组.结论 不同时间诱导被打击的淋巴细胞进入周期其可能发生DNA修复并同时伴随细胞凋亡的发生.     

The Efficiency of Homologous Recombination and Non-Homologous End Joining Systems in Repairing Double-Strand Breaks during Cell Cycle Progression

This study investigated the efficiency of Non-Homologous End Joining (NHEJ) and Homologous Recombination (HR) repair systems in rejoining DNA double-strand breaks (DSB) induced in CCD-34Lu cells by different γ-ray doses. The kinetics of DNA repair was assessed by analyzing the fluorescence decrease of γ-H2AX foci measured by SOID (Sum Of Integrated Density) parameter and counting foci number in the time-interval 0.5–24 hours after irradiation. Comparison of the two methods showed that the SOID parameter was useful in determining the amount and the persistence of DNA damage signal after exposure to high or low doses of ionizing radiation. The efficiency of DSB rejoining during the cell cycle was assessed by distinguishing G1, S, and G2 phase cells on the basis of nuclear fluorescence of the CENP-F protein. Six hours after irradiation, γ-H2AX foci resolution was higher in G2 compared to G1 cells in which both NHEJ and HR can cooperate. The rejoining of γ-H2AX foci in G2 phase cells was, moreover, decreased by RI-1, the chemical inhibitor of HR, demonstrating that homologous recombination is at work early after irradiation. The relevance of HR in DSB repair was assessed in DNA-PK-deficient M059J cells and in CCD-34Lu treated with the DNA-PKcs inhibitor, NU7026. In both conditions, the kinetics of γ-H2AX demonstrated that DSBs repair was markedly affected when NHEJ was absent or impaired, even in G2 phase cells in which HR should be at work. The recruitment of RAD51 at DSB sites was, moreover, delayed in M059J and in NU7026 treated-CCD-34Lu, with respect to DNA-PKcs proficient cells and continued for 24 hours despite the decrease in DNA repair. The impairment of NHEJ affected the efficiency of the HR system and significantly decreased cell survival after ionizing radiation, confirming that DSB rejoining is strictly dependent on the integrity of the NHEJ repair system.     

γ-H2AX and other histone post-translational modifications in the clinic

Chromatin is a dynamic complex of DNA and proteins that regulates the flow of information from genome to end product. The efficient recognition and faithful repair of DNA damage, particularly double-strand damage, is essential for genomic stability and cellular homeostasis. Imperfect repair of DNA double-strand breaks (DSBs) can lead to oncogenesis. The efficient repair of DSBs relies in part on the rapid formation of foci of phosphorylated histone H2AX (γ-H2AX) at each break site, and the subsequent recruitment of repair factors. These foci can be visualized with appropriate antibodies, enabling low levels of DSB damage to be measured in samples obtained from patients. Such measurements are proving useful to optimize treatments involving ionizing radiation, to assay in vivo the efficiency of various drugs to induce DNA damage, and to help diagnose patients with a variety of syndromes involving elevated levels of γ-H2AX. We will survey the state of the art of utilizing γ-H2AX in clinical settings. We will also discuss possibilities with other histone post-translational modifications. The ability to measure in vivo the responses of individual patients to particular drugs and/or radiation may help optimize treatments and improve patient care. This article is part of a Special Issue entitled: Chromatin in time and space.     

Monoubiquitination of H2AX protein regulates DNA damage response signaling

Double strand breaks (DSBs) are the most deleterious of the DNA lesions that initiate genomic instability and promote tumorigenesis. Cells have evolved a complex protein network to detect, signal, and repair DSBs. In mammalian cells, a key component in this network is H2AX, which becomes rapidly phosphorylated at Ser(139) (γ-H2AX) at DSBs. Here we show that monoubiquitination of H2AX mediated by the RNF2-BMI1 complex is critical for the efficient formation of γ-H2AX and functions as a proximal regulator in DDR (DNA damage response). RNF2-BMI1 interacts with H2AX in a DNA damage-dependent manner and is required for monoubiquitination of H2AX at Lys(119)/Lys(120). As a functional consequence, we show that the H2AX K120R mutant abolishes H2AX monoubiquitination, impairs the recruitment of p-ATM (Ser(1981)) to DSBs, and thereby reduces the formation of γ-H2AX and the recruitment of MDC1 to DNA damage sites. These data suggest that monoubiquitination of H2AX plays a critical role in initiating DNA damage signaling. Consistent with these observations, impairment of RNF2-BMI1 function by siRNA knockdown or overexpression of the ligase-dead RNF2 mutant all leads to significant defects both in accumulation of γ-H2AX, p-ATM, and MDC1 at DSBs and in activation of NBS1 and CHK2. Additionally, the regulatory effect of RNF2-BMI1 on γ-H2AX formation is dependent on ATM. Lacking their ability to properly activate the DNA damage signaling pathway, RNF2-BMI1 complex-depleted cells exhibit impaired DNA repair and increased sensitivity to ionizing radiation. Together, our findings demonstrate a distinct monoubiquitination-dependent mechanism that is required for H2AX phosphorylation and the initiation of DDR.     

Gamma histone 2AX (γ-H2AX)as a predictive tool in radiation oncology

Abstract

Ionizing radiation cause DNA damage to cells, leading them to cell death via DNA double-strand breaks (DSBs) formation. DSBs formation is followed immediately by histone H2AX phosphorylation (γ-H2AX) and multitude repair factors accumulation. Here we present the methods and the bio-sampling for γ-H2AX detection, γ-H2AX formation in normal cells and animal tissues, in cancer cell lines/tissues and in clinical trials after radiation treatment, alone or in combination with other factors. The purpose of this review is to highlight the use of γ-H2AX, as a marker to assess DNA damage and repair.     

Accumulation of DSBs in gamma-H2AX domains fuel chromosomal aberrations

DNA double strand breaks (DSBs) pose a severe hazard to the genome as erroneous rejoining of DSBs can lead to mutation and cancer. Here, we have investigated the correlation between X irradiation-induced γ-H2AX foci, theoretically induced DSBs, and the minimal number of mis-rejoined DNA breaks (MNB) in irradiated lymphocytes obtained from two healthy humans by painting of the whole chromosome complement by spectral karyotyping. There were less γ-H2AX foci/dose than theoretically expected, while misrepair, as expressed by MNB/γ-H2AX focus, was similar at 0.5 and 1 Gy but 3.6-fold up at 3 Gy. Hence, our results suggest that X-ray-induced γ-H2AX foci in G0 lymphocyte nuclei contain more than one DSB and that the increasing number of DSBs per γ-H2AX repair factory lead to an increased rate of misrepair.     

Mismatch-repair protein MSH6 is associated with Ku70 and regulates DNA double-strand break repair

MSH6, a key component of the MSH2-MSH6 complex, plays a fundamental role in the repair of mismatched DNA bases. Herein, we report that MSH6 is a novel Ku70-interacting protein identified by yeast two-hybrid screening. Ku70 and Ku86 are two key regulatory subunits of the DNA-dependent protein kinase, which plays an essential role in repair of DNA double-strand breaks (DSBs) through the non-homologous end-joining (NEHJ) pathway. We found that association of Ku70 with MSH6 is enhanced in response to treatment with the radiomimetic drug neocarzinostatin (NCS) or ionizing radiation (IR), a potent inducer of DSBs. Furthermore, MSH6 exhibited diffuse nuclear staining in the majority of untreated cells and forms discrete nuclear foci after NCS or IR treatment. MSH6 colocalizes with γ-H2AX at sites of DNA damage after NCS or IR treatment. Cells depleted of MSH6 accumulate high levels of persistent DSBs, as detected by formation of γ-H2AX foci and by the comet assay. Moreover, MSH6-deficient cells were also shown to exhibit impaired NHEJ, which could be rescued by MSH6 overexpression. MSH6-deficient cells were hypersensitive to NCS- or IR-induced cell death, as revealed by a clonogenic cell-survival assay. These results suggest a potential role for MSH6 in DSB repair through upregulation of NHEJ by association with Ku70.     

Cytolethal distending toxin (CDT) is a radiomimetic agent and induces persistent levels of DNA double-strand breaks in human fibroblasts

Cytolethal distending toxin (CDT) is a unique genotoxin produced by several pathogenic bacteria. The tripartite protein toxin is internalized into mammalian cells via endocytosis followed by retrograde transport to the ER. Upon translocation into the nucleus, CDT catalyzes the formation of DNA double-strand breaks (DSBs) due to its intrinsic endonuclease activity. In the present study, we compared the DNA damage response (DDR) in human fibroblasts triggered by recombinant CDT to that of ionizing radiation (IR), a well-known DSB inducer. Furthermore, we dissected the pathways involved in the detection and repair of CDT-induced DNA lesions. qRT-PCR array-based mRNA and western blot analyses showed a partial overlap in the DDR pattern elicited by CDT and IR, with strong activation of both the ATM-Chk2 and the ATR-Chk1 axis. In line with its in vitro DNase I-like activity on plasmid DNA, neutral and alkaline Comet assay revealed predominant induction of DSBs in CDT-treated fibroblasts, whereas irradiation of cells generated higher amounts of SSBs and alkali-labile sites. Using confocal microscopy, the dynamics of the DSB surrogate marker γ-H2AX was monitored after pulse treatment with CDT or IR. In contrast to the fast induction and disappearance of γ-H2AX-foci observed in irradiated cells, the number of γ-H2AX-foci induced by CDT were formed with a delay and persisted. 53BP1 foci were also generated following CDT treatment and co-localized with γ-H2AX foci. We further demonstrated that ATM-deficient cells are very sensitive to CDT-induced DNA damage as reflected by increased cell death rates with concomitant cleavage of caspase-3 and PARP-1. Finally, we provided novel evidence that both homologous recombination (HR) and non-homologous end joining (NHEJ) protect against CDT-elicited DSBs. In conclusion, the findings suggest that CDT functions as a radiomimetic agent and, therefore, is an attractive tool for selectively inducing persistent levels of DSBs and unveiling the associated cellular responses.     

Multispectral imaging flow cytometry reveals distinct frequencies of γ-H2AX foci induction in DNA double strand break repair defective human cell lines

The measurement of γ-H2AX foci induction in cells provides a sensitive and reliable method for the quantitation of DNA damage responses in a variety of cell types. Accurate and rapid methods to conduct such observations are desirable. In this study, we have employed the novel technique of multispectral imaging flow cytometry to compare the induction and repair of γ-H2AX foci in three human cell types with different capacities for the repair of DNA double strand breaks (DSB). A repair normal fibroblast cell line MRC5-SV1, a DSB repair defective ataxia telangiectasia (AT5BIVA) cell line, and a DNA-PKcs deficient cell line XP14BRneo17 were exposed to 2 Gy gamma radiation from a (60)Cobalt source. Thirty minutes following exposure, we observed a dramatic induction of foci in the nuclei of these cells. After 24 hrs, there was a predictable reduction on the number of foci in the MRC5-SV1 cells, consistent with the repair of DNA DSB. In the AT5BIVA cells, persistence of the foci over a 24-hr period was due to the failure in the repair of DNA DSB. However, in the DNA-PKcs defective cells (XP14BRneo17), we observed an intermediate retention of foci in the nuclei indicative of partial repair of DNA DSB. In summary, the application of imaging flow cytometry has permitted an evaluation of foci in a large number of cells (20,000) for each cell line at each time point. This provides a novel method to determine differences in repair kinetics between different cell types. We propose that imaging flow cytometry provides an alternative platform for accurate automated high through-put analysis of foci induction in a variety of cell types.     

Decay of γ-H2AX foci correlates with potentially lethal damage repair and P53 status in human colorectal carcinoma cells

The influence of p53 status on potentially lethal damage repair (PLDR) and DNA double-strand break (DSB) repair was studied in two isogenic human colorectal carcinoma cell lines: RKO (p53 wild-type) and RC10.1 (p53 null). They were treated with different doses of ionizing radiation, and survival and the induction of DNA-DSB were studied. PLDR was determined by using clonogenic assays and then comparing the survival of cells plated immediately with the survival of cells plated 24 h after irradiation. Doses varied from 0 to 8 Gy. Survival curves were analyzed using the linear-quadratic formula: S(D)/S(0) = exp-(αD+βD²). The γ-H2AX foci assay was used to study DNA DSB kinetics. Cells were irradiated with single doses of 0, 0.5, 1 and 2 Gy. Foci levels were studied in non-irradiated control cells and 30 min and 24 h after irradiation. Irradiation was performed with gamma rays from a ¹³⁷Cs source, with a dose rate of 0.5 Gy/min. The RKO cells show higher survival rates after delayed plating than after immediate plating, while no such difference was found for the RC10.1 cells. Functional p53 seems to be a relevant characteristic regarding PLDR for cell survival. Decay of γ-H2AX foci after exposure to ionizing radiation is associated with DSB repair. More residual foci are observed in RC10.1 than in RKO, indicating that decay of γ-H2AX foci correlates with p53 functionality and PLDR in RKO cells.