碳离子束辐照对质粒DNA的损伤效应

为了证明DNA双链断裂(DSB)片段分布与DNA序列有关的假设,采用32keV／μm的^12C^6 离子和45ke V／μm的^13C^6 离子分别辐照pUCl8质粒,结合限制性内切酶处理,进行琼脂糖凝胶电泳,分析DNA断裂和片段分布。结果表明,除了由一个DSB导致的线性DNA带外,还出现了一条新的、小分子量线性DNA带;限制性内切酶处理后,有另一条线性DNA带产生。证明重离子辐照诱导的DSB是非随机分布的,DNA分子上存在对电离辐射相对敏感的位点。     

液相杂交快速检测特异DNA

检测特异DNA片段的方法中,传统Southern blot技术由于其高度可重复性及能够显示条带大小的特性,一直是DNA检测的“黄金标准”.但是杂交时间长,步骤复杂,放射性污染等问题亟待解决.为了简化Southern blot,研究使用了一种液相杂交快速检测DNA的方法,即使用异硫氰酸荧光素(FITC)标记的dUTP掺入探针后,在溶液中与待检测DNA样本42℃下杂交,然后琼脂糖凝胶电泳检测荧光杂交信号.利用质粒为模板,优化了探针制作、杂交液组成、杂交时间和温度等参数.在FITC-dUTP∶ dTTP比例为1∶3、模板质粒浓度为50μg、1×杂交缓冲液(25 mmol/LTris,10mmol/L EDTA,8mmol/L Nacl,PH =8.0)中95℃变性5～9 min和42℃杂交3h的实验条件下,可检出1.2μg的质粒,探针灵敏度为7.3 ng/μl.这种方法不需要转膜,曝光,大大节约了时间,简化了操作,荧光检测也为该方法同时检测多色样本提供了可能,可广泛应用于核酸检测.     

BRCA1与DSB修复路径取向

乳腺癌易感基因1(BRCA1)是一个肿瘤抑制基因.BRCA1参与DNA末端切除、细胞周期调控以及染色体修饰等来维护基因组的稳定性.有研究表明,它能够促进正确的DNA双链断裂(DSBs)修复,如同源重组修复(HDR)和经典的非同源末端连接(C-NHEJ);而抑制错误性的DSB修复,如单链退火修复(SSA)和非经典的末端连接(A-EJ);其机制是通过与某些DNA修复相关蛋白质的相互作用来引导DSB修复.目前,BRCA1在DSB修复通路中的作用机制尚未完全明确,仍有待进一步的研究.本文主要阐述BRCA1在DSB各修复通路中是如何发挥其引导作用的.     

泛素连接酶Brl2在DNA双链断裂修复中的作用分析

组蛋白H2B单泛素化在基因转录、DNA复制及损伤修复中发挥着重要的调控作用。在裂殖酵母(Schizosaccharomyces pombe)中,Brl2作为一个泛素化连接酶,调节H2B的119位赖氨酸的单泛素化。目前,有关Brl2在DNA损伤修复中的作用研究较少,本研究利用药物喜树碱(camptothecin, CPT)处理裂殖酵母产生高毒性的DNA双链断裂(DNA double-strand breaks, DSBs),探索Brl2在DSB修复过程中的作用。研究发现,brl2基因缺失的菌株对CPT高度敏感,并导致细胞内DNA自发重组频率下降。荧光分析表明Brl2和重组修复蛋白Rad52共定位到DSB处,且Brl2促进Rad52在DSB处的募集。在CPT产生的DSB条件下,Brl2会发生磷酸化。以上研究发现揭示了Brl2在DSB修复过程中起重要作用,为具体阐明Brl2在DNA同源重组及双链断裂修复的分子机制奠定了进一步研究的基础。     

一氧化氮参与调节盐胁迫下脱落酸诱导的小麦幼苗叶片脯氨酸的累积

不同浓度(0.01～5.00mmol/L)的外源一氧化氮(NO)供体硝普钠(SNP)以浓度依赖性的性式诱导150mmol/LNaCl胁迫下小麦(Triticum aestivum L.cv.Yangmai 158)幼苗叶片脯氨酸的累积.其中0.1 mmol/L的SNP效果最明显,而结合采用NO清除剂c-PTIO和血红蛋白的处理均分别逆转了该效应.研究结果还发现:0.1 mmol/L SNP诱导的脯氨酸累积还可能有利于盐胁迫下小麦幼苗的保水性;0.1 mmol/L的SNP显著激活了内源ABA的合成,而结合血红蛋白的处理则证实,在外源ABA诱导脯氨酸累积的过程中NO可能作用于ABA信号分子的下游,但NO和ABA信号分子在此诱导反应中不存在累积效应.进一步研究脯氨酸合成和降解的酶促反应途径,发现外源NO处理前4天内可能主要是通过提高△'-吡咯啉-5-羧酸合成酶(P5CS)的活性来促进脯氨酸的合成,以后直至第8天主要是通过抑制脯氨酸脱氢酶(ProDH)的活性来抑制脯氨酸的降解;ABA对于P5CS和ProDH活性的调节能力弱于NO.此外,Ca2 在NO诱导的盐胁迫下小麦叶片脯氨酸累积的信号分子途径中起重要的介导作用.     

不同LET的重离子辐射对DSB诱导的影响

利用γ射线和不同LET的碳离子辐照小鼠B16黑色素瘤细胞的脱蛋白DNA,采用脉冲场凝胶电泳结合荧光扫描技术研究了DNA双链断裂（DSB）与LET之间的关系。结果表明：不同LET重离子诱导的PR都随剂量的增加而增加,并在超过一定的剂量之后逐渐趋于一个准阈值;而不同LET的重离子诱导的L值都与剂量呈线性关系;对于诱导DSB的RBE值则随着LET的增加先呈上升趋势,在LET超过100ke/μm后下降。     

一氧化氮参与调节盐胁迫下脱落酸诱导的小麦幼苗叶片脯氨酸的累积

不同浓度(0.01～5.00mmol/L)的外源一氧化氮(NO)供体硝普钠(SNP)以浓度依赖性的性式诱导150mmol/L NaCl胁迫下小麦(Triticum aestivum L.cv.Yangmai 158)幼苗叶片脯氨酸的累积。其中0.1 mmol/L的SNP效果最明显,而结合采用NO清除剂c-PTIO和血红蛋白的处理均分别逆转了该效应。研究结果还发现:0.1 mmol/L SNP诱导的脯氨酸累积还可能有利于盐胁迫下小麦幼苗的保水性;0.1 mmol/L的SNP显著激活了内源ABA的合成,而结合血红蛋白的处理则证实,在外源ABA诱导脯氨酸累积的过程中NO可能作用于ABA信号分子的下游,但NO和ABA信号分子在此诱导反应中不存在累积效应。进一步研究脯氨酸合成和降解的酶促反应途径,发现外源NO处理前4天内可能主要是通过提高Δ~1-吡咯啉-5-羧酸合成酶(P5CS)的活性来促进脯氨酸的合成,以后直至第8天主要是通过抑制脯氨酸脱氢酶(ProDH)的活性来抑制脯氨酸的降解;ABA对于P5CS和ProDH活性的调节能力弱于NO。此外,Ca~(2 )在NO诱导的盐胁迫下小麦叶片脯氨酸累积的信号分子途径中起重要的介导作用。     

豇豆初生叶多胺氧化酶的催化特性

从豇豆幼苗 (6d苗龄 )初生叶提纯得到的多胺氧化酶 (EC 1 .4.3 .6 )属于二胺氧化酶 ,最有效的底物是 1 ,4 二胺丁烷 (腐胺 )、1 ,5 二胺戊烷 (尸胺 )、1 ,6 二胺己烷、1 ,1 0 二胺癸烷等α 二胺 ,其催化活性随二胺类底物碳链的增长而相应减弱。豇豆多胺氧化酶对亚精胺和精胺也具有较高的催化活性。另外 ,底物腐胺和尸胺的浓度超过 2mmol/L或亚精胺和精胺浓度超过 3mmol/L时会对酶活性有抑制效应。以腐胺和尸胺为底物时 ,酶的最适 pH约为7.0 ,而以亚精胺和精胺为底物时其最适pH为 6 .5。该酶的催化活性还随反应介质的离子强度增加而降低。K ,Ca2 和Mg2 (皆为 1 0mmol/L)对酶活性无明显抑制作用 ,而同样浓度的Mn2 ,Zn2 ,Fe2 ,Co2 和Cd2 则对酶活性有不同程度的抑制作用。金属螯合剂EDTA(1 0mmol/L)和腺苷蛋氨酸脱羧酶抑制剂甲基乙二醛 双脒腙 (0 .1mmol/L)可抑制酶活性约 80 % ,而铜结合剂KCN(1 .0mmol/L)、羰基试剂羟胺 (0 .1mmol/L)和氨基胍 (0 .1mmol/L)可导致该酶完全失活     

用醋酸铵制备质粒DNA的简便方法

我们在生物化学与分子生物学实验教学中开设了质粒 DNA制备及酶切鉴定实验。鉴于本科生实验单元时间短 (4学时 ) ,用常规的 Brinboim和 Doly方法进行质粒 DNA的制备往往不能在规定学时内完成实验。因此 ,我们对原有的实验方法 ,略加改进 ,采用高离子浓度中性盐一步沉淀质粒 DNA,制备出高纯度、高产率的质粒 DNA样品。1　材料与方法1.1　材料　 p UC19重组质粒为本室构建 (内插入一约为 1kb大小的片段 ) ;LB培养基 ;溶液 (含 5 0 mmol葡萄糖 ,10 mmol EDTA,2 5 mmol Tris- HCl,p H8.0 ) ;溶液 (含新鲜配制 0 .2 N Na OH及 1%…     

产热凝胶土壤杆菌ATCC31749蛋白质组双向电泳图谱的构建

建立了热凝胶生产茵土壤杆茵茵体总蛋白的蛋白质提取方法和双向电泳方案,确定了使用蛋白质裂解液(7 mol/L尿素,2 mol/L硫脲,1%ASB-14去垢剂,40 mmol/L Tris,0.001%溴酚蓝,1 mmol/L EDTA,1%TBP和1%两性电解质)结合超声破碎法来提取茵体总蛋白的方案为最佳,选择17 cm...     

Enhancement of X-ray-induced breaks in DNA bound to molecules containing platinum: a possible application to hadrontherapy.

Complexes made of DNA and chloroterpyridine platinum (PtTC) bound to plasmid DNA were placed in aqueous solution and irradiated with monochromatic X rays tuned to the resonant photoabsorption energy of the L(III) shell of the platinum atom. The number of single- and double-strand breaks (SSBs and DSBs) induced by irradiation on a supercoiled DNA plasmid was measured by the production of the circular-nicked and linear forms. To distinguish the contribution of the direct effects of ionization from the indirect effects due to a free radical attack, experiments were also performed in the presence of a hydroxyl free radical scavenger, dimethyl sulfoxide (DMSO). An enhancement of the number of SSBs and DSBs was observed when the plasmids contained the platinum intercalating molecules. A quantitative analysis was made to evaluate the respective contributions of the direct effects (Auger effect) and the indirect effects (free radical attack) to the number of DNA strand breaks. Even when off-resonant X rays were used, the strand break efficiency remained higher than expected based upon the absorption cross section, suggesting that the platinum bound to DNA might be increasing the yield of strand breaks. A mechanism is suggested that involves photoelectrons generated from the ionization of water which efficiently ionize platinum atoms. If this mechanism is correct, then heavy atoms, with a large cross section for ionization by electrons that are bound to the DNA, should behave as a radiosensitizer. This observation may provide insight into understanding the effects of new radiotherapy protocols, related chemotherapeutic agents such as cisplatin, and conventional radiotherapy for the treatment of tumors. A possible way to deliver the dose selectively in a well-defined volume, which uses the properties of the linear energy transfer of atomic ions interacting with matter, is suggested.     

Radiation induced DNA DSBs: Contribution from stalled replication forks?

When cells are exposed to radiation serious lesions are introduced into the DNA including double strand breaks (DSBs), single strand breaks (SSBs), base modifications and clustered damage sites (a specific feature of ionizing radiation induced DNA damage). Radiation induced DNA damage has the potential to initiate events that can lead ultimately to mutations and the onset of cancer and therefore understanding the cellular responses to DNA lesions is of particular importance. Using γH2AX as a marker for DSB formation and RAD51 as a marker of homologous recombination (HR) which is recruited in the processing of frank DSBs or DSBs arising from stalled replication forks, we have investigated the contribution of SSBs and non-DSB DNA damage to the induction of DSBs in mammalian cells by ionizing radiation during the cell cycle. V79-4 cells and human HF19 fibroblast cells have been either irradiated with 0–20 Gy of γ radiation or, for comparison, treated with a low concentration of hydrogen peroxide, which is known to induce SSBs but not DSBs. Inhibition of the repair of oxidative DNA lesions by poly(ADP ribose) polymerase (PARP) inhibitor leads to an increase in radiation induced γH2AX and RAD51 foci which we propose is due to these lesions colliding with replication forks forming replication induced DSBs. It was confirmed that DSBs are not induced in G₁ phase cells by treatment with hydrogen peroxide but treatment does lead to DSB induction, specifically in S phase cells. We therefore suggest that radiation induced SSBs and non-DSB DNA damage contribute to the formation of replication induced DSBs, detected as RAD51 foci.     

Monte Carlo simulation of strand-break induction on plasmid DNA in aqueous solution by monoenergetic electrons

The radiation-induced process of strand breaks on pBR322 plasmid DNA in aqueous solution for different energy electrons was studied by Monte Carlo simulation. Assumptions of induction mechanisms of single- and double-strand breaks (SSBs and DSBs) used in the simulation are that SSB is induced by OH or H reaction with DNA and that DSB is induced by two SSBs on the opposite strands within 10 bp. Dose-response relationships of SSBs and DSBs were demonstrated for monoenergetic electrons of 100 eV, 10 keV, 1 keV and 1 MeV, and the yields of SSB and DSB were calculated. The dose-response relationships of SSBs and DSBs can be fitted by linear and linear-quadratic functions, respectively. The ratio of quadratic to linear components of DSB induction changes due to the electron energy. A high contribution of the linear component is observed for 1 keV electrons in the dose range below 160 Gy. The yields of SSBs and DSBs for all examined electron energies lie well within the experimental data when the probability of strand-break induction by OH and H is assumed to be around 0.1-0.2. The yield of SSBs has a minimum at 1 keV, while the yield of DSBs has a maximum at 1 keV in the examined energies. The strand breaks are formed most densely for 1 keV electrons.     

Activation of ataxia telangiectasia mutated by DNA strand break-inducing agents correlates closely with the number of DNA double strand breaks

The protein kinase ataxia telangiectasia mutated (ATM) is activated when cells are exposed to ionizing radiation (IR). It has been assumed that ATM is specifically activated by the few induced DNA double strand breaks (DSBs), although little direct evidence for this assumption has been presented. DSBs constitute only a few percent of the IR-induced DNA damage, whereas the more frequent single strand DNA breaks (SSBs) and base damage account for over 98% of the overall DNA damage. It is therefore unclear whether DSBs are the only IR-induced DNA lesions that activate ATM. To test directly whether or not DSBs are responsible for ATM activation, we exposed cells to drugs and radiation that produce different numbers of DSBs and SSBs. We determined the resulting ATM activation by measuring the amount of phosphorylated Chk2 and the numbers of SSBs and DSBs in the same cells after short incubation periods. We found a strong correlation between the number of DSBs and ATM activation but no correlation with the number of SSBs. In fact, hydrogen peroxide, which, similar to IR, induces DNA damage through hydroxyl radicals but fails to induce DSBs, did not activate ATM. In contrast, we found that calicheamicin-induced strand breaks activated ATM more efficiently than IR and that ATM activation correlated with the relative DSB induction by these agents. Our data indicate that ATM is specifically activated by IR-induced DSBs, with little or no contribution from SSBs and other types of DNA damage. These findings have implications for how ATM might recognize DSBs in cells.     

The semi-quantitative comparison of oxidative stress mediated DNA single and double strand breaks using terminal deoxynucleotidyl transferase mediated end labeling combined with a slot blot technique

The accumulation of DNA damages by environmental stresses is represented by the steady state level of single strand breaks (SSBs) and double strand breaks (DSBs). Terminal deoxynucleotidyl transferase (TdT) mediated end labeling is suitable in detecting DSBs, but is unsuitable for SSBs due to its catalyzing characteristics. However, the sensitivity of TdT to detect SSBs may be significantly improved by first denaturing the double strands and expose all the DNA nicks as potential substrates for TdT. By coupling DNA denaturation to slot blot southern hybridization, the authors demonstrate the sensitive detection of SSBs as well as DSBs in 20 ng DNA samples derived from a retinal pigment epithelial cell line treated with tert-butyl hydroperoxide. The signal intensity of denatured and TdT-treated DNA in slot blot hybridization correlated to the amount of SSBs calculated in an S1 nuclease digestion assay. The signal ratio between denatured and non-denatured DNA likely approximates the SSBs/DSBs ratio in genomic DNA. The combination of DNA denaturing, TdT treatment and slot blot hybridization could be a useful method to assess oxidative stress-induced DNA strand damages.     

Numerical Analysis of Etoposide Induced DNA Breaks

Background

Etoposide is a cancer drug that induces strand breaks in cellular DNA by inhibiting topoisomerase II (topoII) religation of cleaved DNA molecules. Although DNA cleavage by topoisomerase II always produces topoisomerase II-linked DNA double-strand breaks (DSBs), the action of etoposide also results in single-strand breaks (SSBs), since religation of the two strands are independently inhibited by etoposide. In addition, recent studies indicate that topoisomerase II-linked DSBs remain undetected unless topoisomerase II is removed to produce free DSBs.

Methodology/Principal Findings

To examine etoposide-induced DNA damage in more detail we compared the relative amount of SSBs and DSBs, survival and H2AX phosphorylation in cells treated with etoposide or calicheamicin, a drug that produces free DSBs and SSBs. With this combination of methods we found that only 3% of the DNA strand breaks induced by etoposide were DSBs. By comparing the level of DSBs, H2AX phosphorylation and toxicity induced by etoposide and calicheamicin, we found that only 10% of etoposide-induced DSBs resulted in histone H2AX phosphorylation and toxicity. There was a close match between toxicity and histone H2AX phosphorylation for calicheamicin and etoposide suggesting that the few etoposide-induced DSBs that activated H2AX phosphorylation were responsible for toxicity.

Conclusions/Significance

These results show that only 0.3% of all strand breaks produced by etoposide activate H2AX phosphorylation and suggests that over 99% of the etoposide induced DNA damage does not contribute to its toxicity.     

No change in DNA damage or repair of single- and double-strand breaks as human diploid fibroblasts age in vitro

Using the in vitro human diploid fibroblast model, we tested theories of aging which hypothesize that either accumulation of DNA damage or decreased DNA repair capacity is causally related to cellular senescence. Between population doubling level (PDL) 32 and 71, fetal lung-derived normal diploid human fibroblasts (IMR 90) were assayed for both DNA single-strand breaks (SSBs, spontaneous and induced by 6 Gy) and DNA double-strand breaks (DSBs, spontaneous and induced by 100 Gy). After gamma-irradiation cells were kept on ice unless undergoing repair incubation at 37 degrees C for 7.5-120 min or 18-24 h. To assay DNA strand breaks we used the filter elution technique in conjunction with a fluorometric determination of DNA which is not biased in favor of proliferating aging cells as are radioactive labelling methods. We found no change with in vitro age in the accumulation of spontaneous SSBs or DSBs, nor in the kinetics or completeness of DNA strand rejoining after gamma-irradiation. Cells at varying PDLs rejoined approx. 90% of SSBs and DSBs after 60 min repair incubation and 100% after 18-24 h repair incubation. We conclude that aging and senescence as measured by proliferative lifespan in IMR 90 cells are neither accompanied nor caused by accumulation of DNA strand breaks or by diminished capacity to rejoin gamma-radiation-induced SSBs or DSBs in DNA.     

On the chemical yield of base lesions, strand breaks, and clustered damage generated in plasmid DNA by the direct effect of X rays

The purpose of this study was to determine the yield of DNA base damages, deoxyribose damage, and clustered lesions due to the direct effects of ionizing radiation and to compare these with the yield of DNA trapped radicals measured previously in the same pUC18 plasmid. The plasmids were prepared as films hydrated in the range 2.5 < Gamma < 22.5 mol water/mol nucleotide. Single-strand breaks (SSBs) and double-strand breaks (DSBs) were detected by agarose gel electrophoresis. Specific types of base lesions were converted into SSBs and DSBs using the base-excision repair enzymes endonuclease III (Nth) and formamidopyrimidine-DNA glycosylase (Fpg). The yield of base damage detected by this method displayed a strikingly different dependence on the level of hydration (Gamma) compared with that for the yield of DNA trapped radicals; the former decreased by 3.2 times as Gamma was varied from 2.5 to 22.5 and the later increased by 2.4 times over the same range. To explain this divergence, we propose that SSB yields produced in plasmid DNA by the direct effect cannot be analyzed properly with a Poisson process that assumes an average of one strand break per plasmid and neglects the possibility of a single track producing multiple SSBs within a plasmid. The yields of DSBs, on the other hand, are consistent with changes in free radical trapping as a function of hydration. Consequently, the composition of these clusters could be quantified. Deoxyribose damage on each of the two opposing strands occurs with a yield of 3.5 +/- 0.5 nmol/J for fully hydrated pUC18, comparable to the yield of 4.1 +/- 0.9 nmol/J for DSBs derived from opposed damages in which at least one of the sites is a damaged base.     

Elaboration of cellular DNA breaks by hydroperoxides.

Cellular damage produced by ionizing radiation and peroxides, hydrogen peroxide (HOOH) and the organic peroxides tert-butyl (tBuOOH) or cumene hydroperoxide (CuOOH) were compared. DNA breaks, toxicity, malondialdehyde production, and the rate of peroxide disappearance were measured in a human adenocarcinoma cell line (A549). The alkaline and neutral filter elution assays were used to quantitate the kinetics of single and double strand break formation and repair (SSB and DSB), respectively. Peroxides, at 0.01-1.0 mM, produce multiphasic dose response curves for both toxicity and DNA SSBs. Radiation, 1-6 Gy, produced a shouldered survival curve, and both DNA SSB and DSBs produced in cells x-rayed on ice were nearly linear with dose. The peroxides produced more SSBs than radiation at equitoxic doses. X-ray induced DNA single strand breaks were rejoined rapidly by cells at 37 degrees C with approximately 80% of initial damage repaired in 20 min. Peroxide induced SSBs were maximal after 15 min at 37 degrees C. Rejoining proceeded thereafter, but at a rate less than for x-ray induced strand breaks. Significant DNA DSBs could not be achieved by peroxides even at concentrations 50-fold higher than required to produce SSBs. HOOH treatment of DNA on filters following cell lysis and proteolysis produced SSBs. CuOOH and tBuOOH produced no SSBs in lysed cell DNA. None of the peroxides produced DSBs when incubated with lysed cell DNA. Malondialdehyde was released from cells incubated with organic hydroperoxides, but not HOOH, nor up to 40 Gy of x-rays. HOOH was metabolized three times faster than the organic peroxides. The overall results demonstrate the necessity for a metabolically active cell environment to elaborate maximal DNA strand breaks and cell death at hydroperoxide concentrations of 10(-4) or greater, but prevent strand breaks and stimulate cell growth at 10(-5) M.     

The complexity of radiation-induced DNA damage as revealed by exposure to cell extracts.

The rejoining of single-strand breaks (SSBs) induced in plasmid DNA in the presence of 10 mmol dm(-3) Tris scavenger by aluminum K (Al(K)) ultrasoft X rays has been compared with that for SSBs induced by gamma radiation. The Al(K) ultrasoft X rays interact to produce low-energy secondary electrons, which are thought to be the main contributors to the formation of complex damage by low-LET radiations. The rejoining of radiation-induced SSBs was investigated using human whole cell extracts. The efficiency of rejoining of SSBs induced by Al(K) ultrasoft X rays is less than that observed for gamma-ray-induced SSBs. From the similarity of the extent of rejoining of SSBs induced by gamma rays under aerobic and anaerobic conditions, the chemical nature of the stand break termini does not significantly influence SSB rejoining. A simple nick induced in plasmid DNA by gpII protein is rejoined rapidly compared with the slower rejoining processes for radiation-induced SSBs. Therefore, ligation is not rate-determining in processing radiation-induced SSBs. This study provides further evidence that nonrejoining of radiation-induced SSBs reflects the complexity of DNA damage. From comparison of the extent of rejoining of SSBs induced by different radiations, it is inferred that double-strand breaks represent only a minor component of the overall yield of complex damage.