NASBA方法制备HIV／SHIV RNA定量测定标准品及其应用

目的应用NASBA方法制备SIV／SHIV RNA定量测定标准品。方法应用NASBA方法直接扩增SIVmac251病毒gag基因上1476～1685之间的片段,扩增的RNA产物（RS-NASBA）纯化后10倍系列稀释,测定定量曲线、标准曲线,测定该标准品的稳定性和重复性。结果应用Qiagen公司QuantiTect SYBR GREEN RT-PCRKit,该标准品可精确定量到2．033×10 copies／μL。结论外标准品RS．NASBA纯度高,稳定性好,可用于定量测定SIV／SHIV RNA拷贝数。     

Using real-time PCR to determine transgene copy number in wheat

Transgene copy number is usually determined by means of Southern blot analysis which can be time consuming and laborious. In this study, quantitative real-time PCR was developed to determine transgene copy number in transgenic wheat. A conserved wheat housekeeping gene,puroindoline-b, was used as an internal control to calculate transgene copy number. Estimated copy number in transgenic lines using real-time quantitative PCR was correlated with actual copy number based on Southern blot analysis. Real-time PCR can analyze hundreds of samples in a day, making it an efficient method for estimating copy number in transgenic wheat.     

Determination of Transgene Copy Number in Stably Transfected Mammalian Cells by PCR-Capillary Electrophoresis Assay

The quantitative determination of transgene copy number in stably transfected mammalian cells has been traditionally estimated by Southern blot analysis. Recently, other methods have become available for appraisal of gene copy number, such as real-time PCR. Herein we describe a new method based on a fluorescently labeled PCR, followed by capillary electrophoresis. We amplified our target gene (prothrombin) and the internal control originating from genomic DNA (18S rRNA) in the same PCR tube and calculated the mean peak height ratio of the target:control gene for every cell clone sample. With this approach we identified stably transfected cell clones bearing the same transgene copy number. The results of our assay were confirmed by real-time PCR. Our method proves to be fast, low-cost, and reproducible compared with traditionally used methods. This assay can be used as a rapid screening tool for the determination of gene copy number in gene expression experiments.     

实时荧光定量PCR法检测转基因小鼠拷贝数

目的利用实时荧光定量PCR法鉴定转基因小鼠外源基因插入拷贝数。方法以TG-CARK转基因首见鼠为研究对象,选取小鼠的高度保守基因Fabpi为内参,利用绝对定量的实时荧光PCR法鉴定转基因小鼠拷贝数,并与传统的Southern blot方法的定量结果进行比较。结果实时定量PCR鉴定的转基因拷贝数与Southernblot法完全一致,三只TG-CARK首见小鼠的拷贝数分别为1,7,45。结论实时定量PCR技术具有高准确性、高稳定性、高通量和低成本的优点,是比传统杂交技术更好的鉴定小鼠转基因拷贝数的方法。     

Probe-free allele-specific copy number detection and analysis of tumors

Cancer development and progression frequently involve nucleotide mutations as well as amplifications and deletions of genomic segments. Quantification of allele-specific copy number is an important step in characterizing tumor genomes for precision medicine. Despite advances in approaches to high-throughput genomic DNA analysis, inexpensive and simple methods for analyzing complex nucleotide and copy number variants are still needed. Real-time polymerase chain reaction (PCR) methods for discovering and genotyping single nucleotide polymorphisms are becoming increasingly important in genetic analysis. In this study, we describe a simple, single-tube, probe-free method that combines SYBR Green I-based quantitative real-time PCR and quantitative melting curve analysis both to detect specific nucleotide variants and to quantify allele-specific copy number variants of tumors. The approach is based on the quantification of the targets of interest and the relative abundance of two alleles in a single tube. The specificity, sensitivity, and utility of the assay were demonstrated in detecting allele-specific copy number changes critical for carcinogenesis and therapeutic intervention. Our approach would be useful for allele-specific copy number analysis or precise genotyping.     

Potential influence of the first PCR cycles in real-time comparative gene quantifications

There is an underlying assumption in real-time PCR that the amplification efficiency is equal from the first cycles until a signal can be detected. In this study, we evaluated this assumption by analyzing genes with known gene copy number using real-time PCR comparative gene quantifications. Listeria monocytogenes has six 23S rRNA gene copies and one copy of the hlyA gene. We determined 23S rRNA gene copy numbers between 0.9 and 1.6 relative to hlyA when applying the comparative gene quantification approach. This paper focuses on the first cycles of PCR to explain the difference between known and determined gene copy numbers. Both theoretical and experimental evaluations were done. There are three different products (types 1-3) dominating in the first cycles. Type 1 is the original target, type 2 are undefined long products, while type 3 are products that accumulate during PCR. We evaluated the effects of type 1 and 2 products during the first cycles by cutting the target DNA with a restriction enzyme that cuts outside the boundaries of the PCR products. The digestion resulted in a presumed increased amplification efficiency for type 1 and 2 products. Differences in the amplification efficiencies between type 1, 2, and 3 products may explain part of the error in the gene copy number determinations using real-time PCR comparative gene quantifications. Future applications of real-time PCR quantifications should account for the effect of the first few PCR cycles on the conclusions drawn.     

同步PCR技术及其在植物核酸分子定量中的应用

同步PCR是一种集生化、光电和计算机技术于一体的封闭式DNA扩增系统,采用荧光染料将扩增与检测过程结合在一起,实现了在PCR过程中在线显示PCR反应,通过检测荧光强度来绝对定量起始模板的拷贝数.该技术大大简化和加速了核酸分子的定量过程,不仅快速、灵敏、准确、重复性好,而且很容易计算出待测样品中核酸分子的绝对起始拷贝数.同微阵列等分子生物技术一起,同步PCR技术将会在功能基因解析和病害分子诊断等方面发挥重要作用.本综述除了介绍同步PCR技术的原理和应用外,还介绍了定量拟南芥Aux/IAA基因的转录水平的实验,并就同步PCR操作过程中的问题进行了讨论.     

Rapid determination of transgene copy number in stably-transfected mammalian cells by competitive PCR

We describe here an application of the competitive PCR technique to the analysis of copy number of recombinant rat parathyroid hormone-related protein (rPTHrP) gene in stably-transfected murine erythroleukemia (MEL) cell lines. A single-copy reference gene (endogenous mouse PTHrP gene or mPTHrP) is used as an internal control. This control gene, present in the genome of MEL cells, shares the same primer binding sites as the rPTHrP cDNA but contains an internal PvuII site, which allows resolution of the amplified products after restriction enzyme digestion by polyacrylamide gel electrophoresis (PAGE). The transgene copy number is determined by the ratio of band intensity of the rPTHrP product to that of the mPTHrP product. Using this method, we have determined the copy number of the rPTHrP transgene from isolated genomic DNA, and compared the results with those obtained from Southern blot analysis. In addition, we have demonstrated that the procedure can be applied very simply to whole MEL cells without DNA extractions and that as few as 10⁴ cells are required for the analysis.     

SYBR GreenⅠ实时荧光定量RT-PCR测定肠道病毒71型（EV71）RNA拷贝数方法的建立

目的建立SYBR GreenⅠ荧光染料实时定量RT-PCR方法,测定实验动物等来源的EV71病毒RNA。方法运用EV71VP1保守区引物,优化real time RT-PCR条件,运用NASBA方法扩增EV71病毒RNA,计算拷贝数,经10倍系列稀释做出标准曲线,作为EV71病毒RNA定量检测的外标准品。结果应用Qiagen公司QuantiTect SYBR Green RT-PCR Kit,该标准品可精确定量到100copies/μL,PCR扩增效率达到99.5%。结论 SYBRGreenⅠ荧光染料实时定量PCR法测定EV71病毒RNA拷贝数的方法敏感性高、稳定性好,可用于EV71病毒RNA载量的定量测定。     

Technical considerations for genotyping multi-allelic copy number variation (CNV), in regions of segmental duplication

Background

Intrachromosomal segmental duplications provide the substrate for non-allelic homologous recombination, facilitating extensive copy number variation in the human genome. Many multi-copy gene families are embedded within genomic regions with high levels of sequence identity (>95%) and therefore pose considerable analytical challenges. In some cases, the complexity involved in analyzing such regions is largely underestimated. Rapid, cost effective analysis of multi-copy gene regions have typically implemented quantitative approaches, however quantitative data are not an absolute means of certainty. Therefore any technique prone to degrees of measurement error can produce ambiguous results that may lead to spurious associations with complex disease.

Results

In this study we have focused on testing the accuracy and reproducibility of quantitative analysis techniques. With reference to the C-C Chemokine Ligand-3-like-1 (CCL3L1) gene, we performed analysis using real-time Quantitative PCR (QPCR), Multiplex Ligation-dependent Probe Amplification (MLPA) and Paralogue Ratio Test (PRT). After controlling for potential outside variables on assay performance, including DNA concentration, quality, preparation and storage conditions, we find that real-time QPCR produces data that does not cluster tightly around copy number integer values, with variation substantially greater than that of the MLPA or PRT systems. We find that the method of rounding real-time QPCR measurements can potentially lead to mis-scoring of copy number genotypes and suggest caution should be exercised in interpreting QPCR data.

Conclusions

We conclude that real-time QPCR is inherently prone to measurement error, even under conditions that would seem favorable for association studies. Our results indicate that potential variability in the physicochemical properties of the DNA samples cannot solely explain the poor performance exhibited by the real-time QPCR systems. We recommend that more robust approaches such as PRT or MLPA should be used to genotype multi-allelic copy number variation in disease association studies and suggest several approaches which can be implemented to ensure the quality of the copy number typing using quantitative methods.     

实时荧光定量PCR(TaqMan)法测定外源基因的拷贝数

实时荧光定量PCR是近年新兴的一项技术,因其快速、方便、便宜,需要DNA样品量少,无需放射性检测等优点被广泛应用于基因的定量分析。该文就实时荧光定量PCR(TaqMan)技术的发展、基本原理及测定外源基因拷贝数的技术流程做一介绍。     

实时荧光PCR结果的四维杂交的核酸技术分析

本研究采用四维杂交试剂,测定PCR产物的特征熔点温度(temperature of melting point,Tmp),对实时荧光定量PCR所获得阳性信号(特异性的或非特异性的)的结果进行分析和确认,以使检测结论更客观.将荧光探针模式的实时荧光PCR检测后的标本再进行熔解曲线温度扫描,然后在4℃冰箱冷却5min,向反应管加入1μL四维杂交液,再按照温度扫描程序做熔解曲线实验.结果显示,加四维杂交试剂之后的熔解曲线中信号峰值是收敛的,且信噪比增大.相同扩增产物的Tmp的误差是在±1℃之内.实验结果证明,四维杂交试剂对荧光探针模式实时荧光PCR结果可进行更精细的分析和确认.     

A proportional analysis method using non-kinetic real-time PCR

Prompted by increasing interest in proportional analysis of genetic types, we developed a simple assay technique for determining the ratio of a specific target gene in the total genes that can be amplified with the same PCR primer. The key feature of this method is that the following two tasks are performed in a single-tube real-time PCR system: task 1, PCR amplification of the total genes including the target using a labeled PCR primer, with concurrent monitoring of the total copy number of the PCR product; task 2, detection of the signal of the target gene at each cycle of amplification, using a labeled nucleotide probe. In principle, the ratio of the target gene to the total genes is represented by the signal detected in 'task 2' at the cycle in which the PCR product reached a prescribed copy number (assessed by 'task 1').     

Quantitative analysis of total mitochondrial DNA: competitive polymerase chain reaction versus real-time polymerase chain reaction

An efficient and effective method for quantification of small amounts of nucleic acids contained within a sample specimen would be an important diagnostic tool for determining the content of mitochondrial DNA (mtDNA) in situations where the depletion thereof may be a contributing factor to the exhibited pathology phenotype. This study compares two quantification assays for calculating the total mtDNA molecule number per nanogram of total genomic DNA isolated from human blood, through the amplification of a 613-bp region on the mtDNA molecule. In one case, the mtDNA copy number was calculated by standard competitive polymerase chain reaction (PCR) technique that involves co-amplification of target DNA with various dilutions of a nonhomologous internal competitor that has the same primer binding sites as the target sequence, and subsequent determination of an equivalence point of target and competitor concentrations. In the second method, the calculation of copy number involved extrapolation from the fluorescence versus copy number standard curve generated by real-time PCR using various dilutions of the target amplicon sequence. While the mtDNA copy number was comparable using the two methods (4.92 +/- 1.01 x 10(4) molecules/ng total genomic DNA using competitive PCR vs 4.90 +/- 0.84 x 10(4) molecules/ng total genomic DNA using real-time PCR), both inter- and intraexperimental variance were significantly lower using the real-time PCR analysis. On the basis of reproducibility, assay complexity, and overall efficiency, including the time requirement and number of PCR reactions necessary for the analysis of a single sample, we recommend the real-time PCR quantification method described here, as its versatility and effectiveness will undoubtedly be of great use in various kinds of research related to mitochondrial DNA damage- and depletion-associated disorders.