四步法消除SYBR GreenⅠ实时定量RT-PCR中引物二聚体的影响

为建立一种新的SYBRgreenⅠ实时定量RT PCR方法 ,使之能够有效消除引物二聚体 (PDs)对实时定量结果的影响 .对RT PCR特异性扩增产物和PDs分别进行了凝胶电泳检测和熔解曲线分析 .依据PDs和扩增产物的熔解温度 (Tm)特点 ,在通用的三步法的延伸步骤之后 ,增加一个短暂的 (5s)恒温和荧光检测步骤 ,使这个步骤的温度高于PDs的Tm,但低于扩增产物的Tm,简称该法为四步法 .PDs的Tm 通常高于 72℃ ,但低于扩增产物的Tm .将四步法第四步的温度设置在高于PDs的Tm ,但低于扩增产物的Tm 时 ,四步法能够有效地消除PDs的影响 .对三步法和四步法SYBRgreenⅠ实时定量RT PCR进行了比较 ,发现三步法根本不能用于RNA的实时定量 ,而四步法能够实现包括低丰度RNA在内的RNA的定量 .选择Tm 值尽可能小的引物 ,使PDs与扩增产物Tm 值之间有足够的差距 ,将更有利于四步法的应用 ,并可成功地用于低丰度RNA的准确定量     

SYBR Green实时荧光PCR高通量检测转基因大豆油

采用SYBR Green实时荧光PCR技术,建立了食用大豆油转基因成分的检测方法.根据转基因大豆中内源参照基因lectin和外源基因35S启动子、NoS终止子和ep4 epsps基因,设计特异性引物,在Roche荧光PCR仪上进行实时荧光PCR扩增.荧光曲线表明,SYBR Green实时荧光PCR可特异性地检测大豆油中的转基因成分,方法准确、快速,并运用熔解曲线进行产物分析,验证了试验结果的特异性和准确性,检测方法灵敏度高.     

荧光PCR扩增相关技术

利用荧光PCR(FPCR)技术扩增DNA是现代生物学研究的重要内容.本文以FPCR的发明为起始,以其主要的发展历程为主线,介绍和阐述了实时定量式PCR(QPCR,包括染料法、水解探针法及其衍生种类、划分为分子信标和阴阳探针等类型的杂交探针法、染料熔解曲线法和探针熔解曲线法)与数字式PCR(DPCR,主要是芯片式DPCR...     

HPV病毒检测分型芯片的研制和优化

研制和优化寡核苷酸芯片以初步实现对多种常见HPV(Human papillomavirus)病毒的分型检测.应用生物学软件对四型常见HPV病毒(6、11、16、18型)的全基因组序列进行分析,设计具有型特异性、熔解温度(Tm)相近的～60 mer寡核苷酸探针,对玻片片基进行优化处理后,点样制备成寡核苷酸基因芯片.将含HPV全长基因序列的质粒作为阳性标准品,利用梯度限制性荧光标记技术对其进行荧光标记,标记好的样品与芯片杂交.结果显示HPV样品与相应的型特异性探针杂交有明显的荧光信号,而与阴性对照探针和空白对照探针没有杂交信号.通过对芯片片基处理和样品荧光标记方法的优化,可以提高芯片检测的杂交特异性和荧光信号强度.     

高分辨率熔解曲线分析技术及其应用进展

高分辨率熔解曲线分析(High Resolution Melting,HRM)是结合饱和荧光染料、未标记探针和实时荧光定量PCR的一种新的检测基因突变与基因分型的分子诊断技术,具有高通量、低成本、简单快捷、结果准确、灵敏度和特异性高和真正闭管操作等优点。本文就高分辨率熔解曲线分析的临床应用和研究进展进行综述。     

两种DNA探针杂交检测结核分支杆菌方法的研究

为改进结核杆菌DNA探针的特异性与实用性,研制了以生物素标记的两种对结核分支杆菌特异的DNA探针:一个5’端标记的20bp的寡核苷酸探针和一个采用PCR方法合成的188bp长链探针。两种探针分别与结核分支杆菌的全染色体DNA,以及基因组上IS6110序列的一段317bp的PCR扩增产物进行斑点杂交,以碱性磷酸酶(AP)催化的染色反应检测,测试了两个探针的敏感性和特异性。系统地比较研究了两种探针杂交检测条件:探针的浓度选择,杂交温度与洗膜温度的选择,以及杂交与洗膜温度对检测的敏感性与特异性的影响。寡核苷酸探针和188bp探针杂交检测纯化结核分支杆菌基因组DNA的敏感性分别为100ng与6ng,杂交检测PCR产物的敏感性分别是400pg与50pg。两探针的最佳杂交浓度均为40～160ng/ml,最佳杂交温度分别是42℃与68℃,最佳洗膜温度分别是60℃与60～68℃之间。两种探针均仅与结核分支杆菌及BCG有杂交信号,而与其它受试分支杆菌及非分支杆菌杂交结果都呈阴性。它们的特异性都很强,但188bp探针的敏感性约是寡核苷酸探针的7～16倍,而且188bp探针检测本底较低,是检测结核分支杆菌的较佳选择     

高分辨率熔解曲线及其应用

饱和荧光染料、未标记探针与实时荧光PCR结合产生的高分辨率熔解曲线(HRM)是一种新的实时定量技术,在检测速度、灵敏度和准确性上具有突出的优点,近几年来在突变扫描、DNA甲基化和基因分型等医学检测中发展迅速.就HRM的原理、应用以及在HRM基础上发展起来的未标记探针(unlabled probe)HMR、弹回探针(snap probe)HMR技术作一介绍.     

实时荧光PCR结合融解曲线分析快速鉴定临床常见曲霉菌

目的 采用实时荧光PCR结合融解曲线分析的方法快速将临床常见曲霉菌鉴定到种的水平.方法 ①普通PCR扩增真菌ITS区后进行序列比对,准确鉴定菌种并设计种特异性引物和探针.②采用实时荧光PCR的方法及融解曲线分析,根据不同的解链温度将5种临床常见曲霉菌鉴定到种的水平.③特异性、敏感性、重复性试验.结果 ①解链曲线分析显示,不同种曲霉菌的种特异性探针有特异的Tm值,根据Tm值的不同可以将5种曲霉菌区分开来:烟曲霉Tm =61.4℃,黄曲霉Tm=57.4℃,黑曲霉Tm=67.7℃,土曲霉Tm=55.2℃和64.5℃,构巢曲霉Tm=65.8℃.其中小孢根霉和疣状瓶霉与烟曲霉探针发生交叉反应,阴性对照不出现特异性的解链曲线.②该方法对5种曲霉菌的检测下限分别为:烟曲霉56.8 fg,黄曲霉1 110fg,黑曲霉13.7 fg,土曲霉123 fg,构巢曲霉780 fg.③重复性试验结果显示,同一种曲霉菌的Tm值波动范围不超过0.5℃.结论 采用实时荧光PCR结合融解曲线分析的方法可以快速准确地将临床常见曲霉菌鉴定到种的水平,具有良好的敏感性、特异性和可重复性,有助于临床侵袭性曲霉感染的诊断和指导抗真菌药物使用.     

近交系小鼠双色荧光正相杂交芯片技术体系的建立和优化

目的探讨采用单核苷酸多态性（SNP）检测方法-双色荧光正相杂交芯片技术对近交系小鼠遗传质量监测及相关影响因素。方法运用基于芯片的双色荧光正相杂交检测SNP技术,进行芯片杂交动力学研究,考察信号值（Cy3,Cy5）和ratio值（Cy5/Cy3）与PCR产物点样浓度、PCR产物长度和荧光标记探针长度之间的关系,研究PCR产物点样浓度、PCR产物长度和荧光标记探针长度对SNP分型的影响。结果采用正反标记实验后,Ratio值随着PCR产物点样浓度的增加呈稳定趋势;PCR双链产物长度对信号值影响比较大,点样时其长度不宜太长,最好不超过450 bp;随荧光标记探针长度的增加,基因分型能力明显下降,长度为15 bp最佳,长度超过20 bp时,已基本没有区分能力。结论PCR产物点样浓度、PCR产物长度和荧光标记探针长度是双色荧光正相杂交SNP分型系统的重要影响因素,采取适当的PCR产物点样浓度、PCR产物长度和荧光标记探针长度,并采用正反标记实验,可以取得稳定、准确的基因分型效果。为进一步进行近交系小鼠遗传质量监测的研究奠定基础。     

实时荧光定量TaqMan-MGB探针法检测杆菌样巴尔通体

【目的】应用Taq Man探针实时荧光定量PCR技术建立特异性强、敏感性高和稳定性好的快速杆菌样巴尔通体检测方法。【方法】应用生物信息学方法查找杆菌样巴尔通体特有基因,从中筛选出一段特有的基因序列为模板设计探针和引物。通过比较Ct值和荧光强度确定扩增反应的最佳退火温度、探针和引物浓度;将扩增产物连接到p EASY-T载体上制备标准品,绘制标准曲线,分析扩增效率和线性关系;评估方法的特异性、敏感性及重复性。【结果】优化后退火温度为60°C,探针和引物浓度均为200 nmol/L,反应体系20μL。特异性实验显示只有杆菌样巴尔通体扩增出荧光信号,其他种属细菌均未见荧光信号;标准曲线线性关系良好(R2=1),扩增效率E=98.18%;最低检出限为每个PCR反应3个拷贝;组内和组间的变异系数CV值分别为0.21%–0.42%和0.29%–0.59%,在允许范围内。【结论】研究建立的实时荧光定量Taq Man-MGB探针法特异性强、灵敏度高、稳定性好,可快速检测鉴定杆菌样巴尔通体,为这种巴尔通体所引起的一系列疾病的早期快速诊断、监测和流行病学调查等研究提供有效手段。     

基于荧光定量PCR扩增反应的SNP测定法

建立一种利用荧光定量PCR扩增反应进行单核苷酸多态性(SNP)快速测定的方法.以人β肾上腺素受体2基因中的Arg16Gly为研究对象,利用荧光染料SYBRGreenⅠ标记定量PCR产物,通过PCR生长曲线和融解曲线分析结果进行SNP分型.为提高SNP测定的特异性,分别在野生型和突变型等位基因的特异性引物3′端倒数第3个碱基位置,引入了一个人为错配碱基,使引物的错误延伸率显著降低,大大提高了SNP分析的准确性.通过DNA测序验证荧光定量PCR对β肾上腺素受体2基因中Arg16Gly分型结果的准确率.实验结果表明,所建立的方法操作简便,结果准确,适合进行大规模样品的SNP检测工作.     

Evaluation of quantification methods for real-time PCR minor groove binding hybridization probe assays

Real-time PCR data analysis for quantification has been the subject of many studies aimed at the identification of new and improved quantification methods. Several analysis methods have been proposed as superior alternatives to the common variations of the threshold crossing method. Notably, sigmoidal and exponential curve fit methods have been proposed. However, these studies have primarily analyzed real-time PCR with intercalating dyes such as SYBR Green. Clinical real-time PCR assays, in contrast, often employ fluorescent probes whose real-time amplification fluorescence curves differ from those of intercalating dyes. In the current study, we compared four analysis methods related to recent literature: two versions of the threshold crossing method, a second derivative maximum method, and a sigmoidal curve fit method. These methods were applied to a clinically relevant real-time human herpes virus type 6 (HHV6) PCR assay that used a minor groove binding (MGB) Eclipse hybridization probe as well as an Epstein-Barr virus (EBV) PCR assay that used an MGB Pleiades hybridization probe. We found that the crossing threshold method yielded more precise results when analyzing the HHV6 assay, which was characterized by lower signal/noise and less developed amplification curve plateaus. In contrast, the EBV assay, characterized by greater signal/noise and amplification curves with plateau regions similar to those observed with intercalating dyes, gave results with statistically similar precision by all four analysis methods.     

Rapid and inexpensive species differentiation using a multiplex real-time polymerase chain reaction high-resolution melt assay

We demonstrate a method for developing real-time polymerase chain reaction (PCR) high-resolution melt (HRM) assays to identify multiple species present in a mixture simultaneously using LCGreen Plus and melt temperatures. Highly specific PCR primers are designed to yield amplicons with different melt temperatures for simple routine species identification compared with differentiating melt curve kinetics traces or difference plots. This method is robust and automatable, and it leads to savings in time and reagent costs, is easily modified to probe any species of interest, eliminates the need for post-PCR gel or capillary electrophoresis in routine assays, and requires no expensive dye-labeled primers.     

荧光热漂移实验体外检测核小体的解聚

核小体是真核生物染色质的基本组成单元。核小体的解聚可以动态调控诸如DNA复制、转录、重组等以DNA为模板的生物学过程。特定荧光探针分子与蛋白质疏水残基结合后可被激发荧光信号。荧光热漂移（fluorescence thermal shift,FTS）是一种利用该原理检测温度上升时蛋白质变性过程的方法。本文以Widom 601序列为DNA模板,盐透析法体外装配核小体;分别在实时荧光定量PCR仪的VIC和TAMRA通道激发下,利用FTS检测了核小体在Tris-NaCl（TN）缓冲液和HEPES缓冲液中的解聚状态。研究结果发现,DNA对照序列在TN缓冲液中产生的背景噪声较大,VIC通道激发下组蛋白八聚体产生的荧光信号相对较强。FTS检测核小体的结果显示,随着温度的上升核小体的解聚过程分为2个阶段,～71℃和～84℃是核小体解聚速度最快的温度范围,而75℃～80℃是降解速度较慢的阶段。基于FTS基本原理,本研究发展了一种新颖的可用于检测核小体结构稳定性的方法,为核小体与染色质结构相关问题的研究奠定了一定的技术基础。     

Multiplex fluorescence melting curve analysis for mutation detection with dual-labeled, self-quenched probes

Probe-based fluorescence melting curve analysis (FMCA) is a powerful tool for mutation detection based on melting temperature generated by thermal denaturation of the probe-target hybrid. Nevertheless, the color multiplexing, probe design, and cross-platform compatibility remain to be limited by using existing probe chemistries. We hereby explored two dual-labeled, self-quenched probes, TaqMan and shared-stem molecular beacons, in their ability to conduct FMCA. Both probes could be directly used for FMCA and readily integrated with closed-tube amplicon hybridization under asymmetric PCR conditions. Improved flexibility of FMCA by using these probes was illustrated in three representative applications of FMCA: mutation scanning, mutation identification and mutation genotyping, all of which achieved improved color-multiplexing with easy probe design and versatile probe combination and all were validated with a large number of real clinical samples. The universal cross-platform compatibility of these probes-based FMCA was also demonstrated by a 4-color mutation genotyping assay performed on five different real-time PCR instruments. The dual-labeled, self-quenched probes offered unprecedented combined advantage of enhanced multiplexing, improved flexibility in probe design, and expanded cross-platform compatibility, which would substantially improve FMCA in mutation detection of various applications.     

Combining sequence-specific probes and DNA binding dyes in real-time PCR for specific nucleic acid quantification and melting curve analysis

Currently, in real-time PCR, one often has to choose between using a sequence-specific probe and a nonspecific double-stranded DNA (dsDNA) binding dye for the detection of amplified DNA products. The sequence-specific probe has the advantage that it only detects the targeted product, while the nonspecific dye has the advantage that melting curve analysis can be performed after completed amplification, which reveals what kind of products have been formed. Here we present a new strategy based on combining a sequence-specific probe and a nonspecific dye, BOXTO, in the same reaction, to take the advantage of both chemistries. We show that BOXTO can be used together with both TaqMan probes and locked nucleic acid (LNA) probes without interfering with the PCR. The probe signal reflect formation of target product, while melting curve analysis of the BOXTO signal reveals primer-dimer formation and the presence of any other anomalous products.     

Characterization and applications of CataCleave probe in real-time detection assays

Cycling probe technology (CPT), which utilizes a chimeric DNA-RNA-DNA probe and RNase H, is a rapid, isothermal probe amplification system for the detection of target DNA. Upon hybridization of the probe to its target DNA, RNase H cleaves the RNA portion of the DNA/RNA hybrid. Utilizing CPT, we designed a catalytically cleavable fluorescence probe (CataCleave probe) containing two internal fluorophores. Fluorescence intensity of the probe itself was weak due to F?rster resonance energy transfer. Cleavage of the probe by RNase H in the presence of its target DNA caused enhancement of donor fluorescence, but this was not observed with nonspecific target DNA. Further, RNase H reactions with CataCleave probe exhibit a catalytic dose-dependent response to target DNA. This confirms the capability for the direct detection of specific target DNA through a signal amplification process. Moreover, CataCleave probe is also ideal for detecting DNA amplification processes, such as polymerase chain reaction (PCR) and isothermal rolling circle amplification (RCA). In fact, we observed signal enhancement proportional to the amount of RCA product formed. We were also able to monitor real-time PCR by measuring enhancement of donor fluorescence. Hence, CataCleave probe is useful for real-time monitoring of both isothermal and temperature-cycling nucleic acid amplification methods.     

Thermodynamically modulated partially double-stranded linear DNA probe design for homogeneous real-time PCR

Real-time PCR assays have recently been developed for diagnostic and research purposes. Signal generation in real-time PCR is achieved with probe designs that usually depend on exonuclease activity of DNA polymerase (e.g. TaqMan probe) or oligonucleotide hybridization (e.g. molecular beacon). Probe design often needs to be specifically tailored either to tolerate or to differentiate between sequence variations. The conventional probe technologies offer limited flexibility to meet these diverse requirements. Here, we introduce a novel partially double-stranded linear DNA probe design. It consists of a hybridization probe 5'-labeled with a fluorophore and a shorter quencher oligo of complementary sequence 3'-labeled with a quencher. Fluorescent signal is generated when the hybridization probe preferentially binds to amplified targets during PCR. This novel class of probe can be thermodynamically modulated by adjusting (i) the length of hybridization probe, (ii) the length of quencher oligo, (iii) the molar ratio between the two strands and (iv) signal detection temperature. As a result, pre-amplification signal, signal gain and the extent of mismatch discrimination can be reliably controlled and optimized. The applicability of this design strategy was demonstrated in the Abbott RealTime HIV-1 assay.     

双链探针实时荧光PCR核酸检测新技术研究*

目的:采用一种“双链探针”实时荧光PCR技术,提高HBV核酸检测灵敏度,并在同一反应管中实现代谢酶CYP2C19^*2基因型检测。方法:采用双链探针与TaqMan探针同时检测不同浓度HBV血清样本,使用上海宏石SLAN 96实时荧光PCR仪进行核酸Ct值检测和结果统计分析;采用双链探针检测代谢酶CYP2C19^*2不同基因型样本,使用上海宏石SLAN 96实时荧光PCR仪进行核酸Ct值检测和基因型确定。结果:不同浓度HBV血清样本检测,双链探针荧光本底低,检测灵敏度更高,与TaqMan探针检测结果相比,两者核酸检测Ct值存在显著性差异(P<0.05);双链探针检测36份样本的代谢酶CYP2C19^*2基因型,检测结果与Sanger测序结果完全一致。结论:双链探针实时荧光PCR检测技术可完成目的基因的高灵敏核酸检测,也可实现基因型分析。     

Evaluation of probe chemistries and platforms to improve the detection limit of real-time PCR

A validated PCR-based Salmonella method targeting a 94-bp sequence of the ttr gene was used as a model to compare six different combinations of reporter and quencher dyes of a TaqMan probe, on three different instruments, to improve the detection limit in a real-time PCR assay with the aim of a same-day analysis. The use of locked nucleic acids (LNA) and Scorpion probes were also tested. The combination FAM-BHQ1 or Cy5-BHQ3, both dark quenchers, gave the best results (Cycle threshold (Ct) of 25.42+/-0.65 and 24.47+/-0.18 at 10(3) DNA copies). When comparing different probe technologies, the LNA probe (FAM-BHQ1) was the most sensitive with the strongest fluorescence signal (dR last 48066), resulting in 0.6 to 1.1 lower Ct values than a DNA TaqMan probe, and 1.9 to 4.0 lower Ct than the Scorpion system (FAM-BHQ1). The RotorGene real-time PCR instrument gave 0.4-1.0 lower Ct values (more sensitive) than the Mx3005p, and 1.5-3.0 lower than the ABI 7700. Using the LNA in a RotorGene instrument, we detected the following Salmonella DNA copies in 1-ml pre-enriched samples: fishmeal (100 copies), chicken rinse (100 copies) and pig feces (10 copies). The detection probability of the final assay on inoculated fecal samples was 100% at 2x10(4) copies per ml. In conclusion, the LNA probe with annealing temperature of 65 degrees C could be useful for more sensitive detection limits.