地高辛标记DNA探针杂交法检测Vero细胞DNA残留量的适用性验证及应用

目的对地高辛标记DNA探针杂交法检测人用狂犬病疫苗(Vero细胞)DNA残留量进行适用性验证及应用。方法对地高辛标记DNA探针杂交法检测人用狂犬病疫苗(Vero细胞)DNA残留量进行特异性、灵敏度及稳定性验证,并应用该方法检测3批人用狂犬病疫苗(Vero细胞)的DNA残留量。结果地高辛标记探针的标记效率为0.1 pg。验证结果显示探针与非同源DNA无杂交;最低检测限度为1 pg;探针在-20℃放置7个月后,检测灵敏度仍可达到1 pg;3批人用狂犬病疫苗(Vero细胞)中残留DNA含量均符合《中国药典》规定质量控制标准。结论地高辛标记DNA探针杂交法特异性、灵敏度好,结果稳定,适用于人用狂犬病疫苗(Vero细胞)中Vero细胞DNA残留量的检测及疫苗生产过程和其成品的质量控制,对其他以Vero细胞为基质的病毒性疫苗质量控制具有借鉴意义。     

定量荧光原位杂交测定端粒长度

目的:应用定量荧光原位杂交(Q-FISH)方法测定端粒长度。方法:选取4种端粒长度均一的标准细胞株采用Q-FISH的方法做出荧光亮度与端粒长度的标准曲线,从而得出实验细胞株的端粒长度,与DNA印迹法测定末端限制性片段(TRF)长度进行二者之间的相关性分析。结果:检测荧光强度的最佳线性曝光时间为400ms,相对于DNA印迹法,定量荧光原位杂交(Q-FISH)法所需标本量少,实验周期短,端粒长度结果与Southern杂交法具有很好的相关性。结论:采用定量荧光原位杂交方法测端粒长度具有重复性好、精确可靠的特点,适用于对珍贵标本的端粒改变进行分析。     

利用流式荧光原位杂交法测定细胞端粒长度

目的建立利用流式荧光原位杂交法检测细胞端粒长度的技术方法。方法以端粒酶敲除的G3小鼠和同龄野生型小鼠为检测对象,分离其外周血中的单个核细胞后与肽核酸荧光探针杂交,用流式细胞仪采集和分析其端粒长度,分别用荧光原位杂交方法和SYBR Green荧光定量PCR方法验证其准确性。结果流式荧光原位杂交法测定G3小鼠细胞端粒相对长度与C57BJ/6野生型小鼠相比为0.5345,荧光定量PCR测定端粒相对长度为0.5717,结果基本一致。结论流式细胞术与原位杂交方法结合起来检测细胞端粒的平均长度可靠易行,对单个核细胞端粒平均长度的检测有较高的实用性。     

化学发光法检测体外HBV复制

目的:建立化学发光法检测体外HBV复制水平的方法,研究其灵敏度和稳定性.方法:用HBV DNA重组质粒pCH9转染到人肝癌细胞株HepG2和Huh7中,5d后收集细胞并抽提其HBV复制中问体DNA,转印后以地高辛标记HBV DNA为探针进行杂交,用化学发光法检测杂交结果,同时进行探针灵敏度的检测.结果:转染后HepG2和Huh7细胞提取HBV DNA中检测出较强的复制中间体的信号,分别为松散环状DNA(rcDNA),双链线性DNA(dslDNA),单链DNA(ssDNA),探针检测的灵敏度可达到lpg,接近同位素法检测的灵敏度.整个实验重复3次获得同样结果.结论:成功建立了稳定的化学发光法检测体外HBV复制水平的方法.     

用地高辛标记Y染色体特异探针检测人的性别

采用了一种新的DNA探针非同位素标记方法，即地高辛配基标记人Y染色体特异DNA探针，成功地用于人基因组中男性特异DNA的检测。同时，将此种方法与生物素标记探针方法作了比较。结果表明：地高辛配基标记探针方法优于生物素标记。     

腹透液相关浓度葡萄糖对人腹膜间皮细胞端粒长度的影响及葛根素的拮抗作用

目的:研究腹透液相关浓度葡萄糖(1.5%、2.5%)对人腹膜间皮细胞端粒长度的影响及葛根素的拮抗作用.方法:人腹膜间皮细胞在含糖(1.5%、2.5%)、含糖含葛根素(葛根素终浓度为100μg/ml)的无血清培养基培养24h后,收集细胞,提取DNA,采用Southerm杂交测定细胞端粒长度.结果:经含糖1.5%和2.5%培养基培养24h后腹膜间皮细胞大多出现肥大.高浓度葡萄糖组细胞端粒长度缩短,2.5%组和1.5%组无显著差别(P>0.05).葛根素加入后含糖组腹膜间皮细胞端粒长度延长(P<0.05).结论:高糖可使间皮细胞端粒缩短,且可能与高糖作用下细胞肥大有关,葛根素可拮抗高糖对间皮细胞端粒长度的影响.     

地高辛标记的Northern blot检测鼠疫菌sRNA

[目的]随着高通量测序方法的应用,越来越多的sRNA (small non-coding RNA,sRNA)需验证.本研究建立用地高辛标记Northern blot检测鼠疫菌sRNA的技术,为细菌sRNA验证提供一种灵敏、特异的方法.[方法]在低铁条件下,提取鼠疫菌总RNA,10％ dPAGE分离后电转到尼龙膜上并用紫外线交联RNA.膜经地高辛标记RyhB1或RyhB2寡核苷酸RNA探针过夜杂交后洗脱、封闭和免疫检测,最后曝光显影.[结果]地高辛标记的Northern blot曝光时间为20 s-3 min,RyhB1或RyhB2检测灵敏度分别为0.005 μg和0.05 μg.RyhB1或RyhB2探针特异性好,相互间无交叉反应.带正电或中性的尼龙膜都适用于杂交反应.RNA探针在42℃-65℃内杂交均可,提高温度可减少非特异性反应;而DNA探针杂交温度需摸索.[结论]本研究成功构建一种地高辛标记Northern blot检测鼠疫菌sRNA技术,具有特异性好、灵敏度高、探针易保存、曝光时间短等优点,为细菌sRNA验证和功能研究提供有利工具.     

荧光探针研究新进展

自从Southern(1975)首次进行DNA探针杂交后,至今核酸分子杂交已成为分子生物学的最基本方法。Matthews和Kricka[1]总结了各种杂交方法,将其归为两大类:一是异相杂交(heterogeneousassay)即固相杂交,目的核酸结合于不溶性支持物上;二是同相杂交(homogeneousassay)即液相杂交,一般同时使用两个探针。为了检测杂交,寡核苷酸探针需要标记,探针的标记物有放射性同位素和非放射性标记物。固相杂交常使用放射性同位素,荧光素是一种非放射性标记物,它能检测到的DNA浓度比吸收减色测定方法所需DNA浓度低100-1000倍[2],在同相杂交中广泛用于探针的标记。最近,荧光探针研究获得了新的进展,Tyagi和Krammer(1996)建立了一种新的荧光探针-分子信标探针,并得到许多应用,我们实验室也开展了这方面的研究。本文拟对荧光探针的研究进展作一综述。     

水稻草矮病毒血清学和分子检测方法的比较

将间接ELISA、非放射性分子杂交和RT-PCR三种方法应用于水稻草矮病毒(RGSV)的检测.结果表明,利用自制的融合蛋白GST-NC的抗血清检测RGSV的灵敏度为1mg鲜重的病株叶片或84ng提纯病毒,利用地高辛(DIG)标记的DNA探针NC的点杂交方法检测RGSV的灵敏度为50μg病叶或6ng病毒,而RT-PCR的检测灵敏度则为10μg 病叶或2ng的病毒,对上述三种方法的灵敏度和可操作性也进行了比较.     

改造地高辛标记DNA和检测试剂盒用于凝胶阻滞实验的新方法

凝胶阻滞实验（gel retardation）,又称为电泳迁移率变动实验（Electrophoretic mobility shift assay,EMSA）,是研究蛋白和DNA相互作用的一种技术。传统的³²P标记探针的凝胶阻滞实验,具有很高的灵敏度,然而也有接触危险性的放射性同位素且不容易定量分析的缺点。最近利用非放射性标记的凝胶阻滞实验,已有很多成功的报导,该方法快捷,安全,灵活,但非放射性标记探针的凝胶阻滞试剂盒的费用却很高。在论文中,我们提供了一种改造地高辛标记DNA和检测试剂盒用于凝胶阻滞实验的新方法。首先将双链DNA探针末端引入EcoRI 粘性末端以便进行3′末端标记,然后利用价格比较便宜的地高辛标记DNA和检测试剂盒(DIG High Prime DNA Labeling and Detection Starter Kit II, Rohe) 进行探针标记和凝胶阻滞信号检测。经过多次实验参数的摸索,最终得到了成功的结果,为利用地高辛标记DNA和检测试剂盒进行凝胶阻滞实验提供了成功的例子和方法。      

端粒保护蛋白

端粒保护蛋白（pmtection of telomere 1,PoT1）是存在于人和裂殖酵母的端粒相关蛋白,特异性地与端粒单链DNA相结合。人POT1基因位于7号染色体上,由22个外显子组成,其中4个外显子属于跳跃外显子,可形成5个剪接变异体。POT1的功能在于维持端粒的稳定,通过TRF1．TIN2．PIP1-POT通路调节端粒长度。     

The telomere lengthening conundrum – it could be biology

Longitudinal studies of human leucocyte telomere length often report a percentage of individuals whose telomeres appear to lengthen. However, based on theoretical considerations and empirical data, Steenstrup et al. (Nucleic Acids Research, 2013, vol 41(13): e131) concluded that this lengthening is unlikely to be a real biological phenomenon and is more likely to be an artefact of measurement error. We dispute the logic underlying this claim. We argue that Steenstrup et al.'s analysis is incomplete because it failed to compare predictions derived from assuming a scenario with no true telomere lengthening with alternative scenarios in which true lengthening occurs. To address this deficit, we built a computational model of telomere dynamics that allowed us to compare the predicted percentage of observed telomere length gainers given differing assumptions about measurement error and the true underling dynamics. We modelled a set of scenarios, all assuming measurement error, but both with and without true telomere lengthening. We found a range of scenarios assuming some true telomere lengthening that yielded either similar or better quantitative fits to the empirical data on the percentage of individuals showing apparent telomere lengthening. We conclude that although measurement error contributes to the prevalence of apparent telomere lengthening, Steenstrup et al.'s conclusion was too strong, and current data do not allow us to reject the hypothesis that true telomere lengthening is a real biological phenomenon in epidemiological studies. Our analyses highlight the need for process‐level models in the analysis of telomere dynamics.     

Extent and variability of interstitial telomeric sequences and their effects on estimates of telomere length

Telomeres often shorten with time, although this varies between tissues, individuals and species, and their length and/or rate of change may reflect fitness and rate of senescence. Measurement of telomeres is increasingly important to ecologists, yet the relative merits of different methods for estimating telomere length are not clear. In particular the extent to which interstitial telomere sequences (ITSs), telomere repeats located away from chromosomes ends, confound estimates of telomere length is unknown. Here we present a method to estimate the extent of ITS within a species and variation among individuals. We estimated the extent of ITS by comparing the amount of label hybridized to in‐gel telomere restriction fragments (TRF) before and after the TRFs were denatured. This protocol produced robust and repeatable estimates of the extent of ITS in birds. In five species, the amount of ITS was substantial, ranging from 15% to 40% of total telomeric sequence DNA. In addition, the amount of ITS can vary significantly among individuals within a species. Including ITSs in telomere length calculations always underestimated telomere length because most ITSs are shorter than most telomeres. The magnitude of that error varies with telomere length and is larger for longer telomeres. Estimating telomere length using methods that incorporate ITSs, such as Southern blot TRF and quantitative PCR analyses reduces an investigator's power to detect difference in telomere dynamics between individuals or over time within an individual.     

端粒位置效应与人类衰老

端粒随细胞分裂进行性缩短不但防止了人类肿瘤的发展,而且与人类的衰老密切相关。另外,端粒中存在一种特殊的现象：端粒位置效应,它首先在酵母中发现,表现为靠近端粒序列附近的基因表达因端粒的位置效应而沉默。在人类细胞中也存在端粒位置效应,并且有多种因子参与此效应,它可能对细胞生长停止、肿瘤以及衰老发生时等许多随端粒缩短密切相关基因的程序性表达产生重要作用。     

端粒维持研究进展

端粒是现代生物学的研究热点,与肿瘤发生、基因表达调控、衰老有着密切的关系。本综述介绍当前对端粒维持机理研究的进展。在端粒维持过程中有两类重要的蛋白：端粒相关蛋白和端粒酶。端粒相关蛋白是直接或间接与端粒结合的蛋白 ,在维持端粒稳定性方面有重要作用。端粒酶,特别是其催化亚基ｈＴＥＲＴ,在端粒延长过程中起着不可替代的作用,与细胞永生化和癌变密切相关。此外还介绍了在某些细胞中存在的不依赖端粒酶的端粒延长机     

依赖端粒酶的端粒维持机制

端粒是真核生物染色体的末端重要结构复合物,对维持染色体稳定性起着重要作用。端粒酶的主要功能是复制端粒末端DNA,维持端粒长度。端粒酶活性调节与肿瘤发生和细胞衰老有着密切关系。本简要综述近年来依赖端粒酶的端粒维持机理的研究进展。     

Restriction Enzyme-Resistant High Molecular Weight Telomeric DNA Fragments in Tobacco

Restriction endonuclease-resistant high-molecular-weight (HMW)DNA fragments were isolated from nuclear DNA fragments in tobacco.The size of the fragments produced by EcoRI, HindIII, AfaI,and HaeIII ranged from 20 kb to over 166 kb. The kinetics ofdigestion by Bal31 nuclease showed that most of the HMW fragmentsare chromosome ends. The consensus sequence for tobacco telomererepeats was determined to be CCCTAAA by genomic sequencing usingthe HMW fragments and by sequencing after cloning. Besides thetelomere sequence, 9 tandem repeats of a 45-bp sequence wereidentified, in which a 35-bp unit sequence (AGTCAGCATTAGGGTTTTAAACCCTAAACTGAACT)formed a stem structure. The front of the stem is composed ofa palindrome of the telomere repeats. This highly conservedunit is surrounded by less conserved internal sequences thatare around 10–11 bp in size and contain a TTTT stretch.The internal sequences resemble the 10–11 bp consensusfor the scaffold attachment regions found in yeast and drosophila.The characteristic 45-bp sequence was abundant on the ends ofchromosomes. The shortest distance between the repeats containingtelomeric stem and the telomere was less than 20 kb. This architectureof the tobacco chromosome end region resembles the end regionof yeast chromosomes in which autonomous replication sequencesare present frequently.     

高等植物端粒和端粒酶的研究进展

端粒是构成真核生物线状染色体末端重要的DNA-蛋白质复合结构,DNA由简单的串联重复序列组成。它的合成由一个特殊的具有反转录活性的核糖核蛋白-端粒酶完成。端粒对染色体、整个生物基因组,甚至对细胞的稳定都具有重要意义。本文就植物端粒、端粒酶、端粒结合蛋白,以及端粒变化、端粒酶在植物生长发育中的调节作一概述。