Telomere length measurement by a novel monochrome multiplex quantitative PCR method

The current quantitative polymerase chain reaction (QPCR) assay of telomere length measures telomere (T) signals in experimental DNA samples in one set of reaction wells, and single copy gene (S) signals in separate wells, in comparison to a reference DNA, to yield relative T/S ratios that are proportional to average telomere length. Multiplexing this assay is desirable, because variation in the amount of DNA pipetted would no longer contribute to variation in T/S, since T and S would be collected within each reaction, from the same input DNA. Multiplexing also increases throughput and lowers costs, since half as many reactions are needed. Here, we present the first multiplexed QPCR method for telomere length measurement. Remarkably, a single fluorescent DNA-intercalating dye is sufficient in this system, because T signals can be collected in early cycles, before S signals rise above baseline, and S signals can be collected at a temperature that fully melts the telomere product, sending its signal to baseline. The correlation of T/S ratios with Terminal Restriction Fragment (TRF) lengths measured by Southern blot was stronger with this monochrome multiplex QPCR method (R² = 0.844) than with our original singleplex method (R² = 0.677). Multiplex T/S results from independent runs on different days were highly reproducible (R² = 0.91).     

Telomere length analysis of human mesenchymal stem cells by quantitative PCR

Human mesenchymal stem cells (hMSCs) have attracted much attention for tissue repair and wound healing because of their self-renewal capacity and multipotentiality. In order to mediate an effective therapy, substantial numbers of cells are required, which necessitates extensive sub-culturing and expansion of hMSCs. Throughout ex vivo expansion, the cells undergo telomere shortening, and critically short telomeres can trigger loss of cell viability. Telomeres are nucleoprotein structures that cap the ends of chromosomes, and serve to protect the DNA from the degradation which occurs due to the end-replication problem in all eukaryotes. As hMSCs have only a finite ability for self-renewal like most somatic cells, assaying for telomere length in hMSCs provides critical information on the replicative capacity of the cells, an important criterion in the selection of hMSCs for therapy. Telomere length is generally quantified by Southern blotting and fluorescence in situ hybridization, and more recently by PCR-based methods. Here we describe the quantification of hMSC telomere length by real-time PCR; our results demonstrate the effect of telomere shortening on the proliferation and clonogenicity of hMSCs. Thus, this assay constitutes a useful tool for the determination of relative telomere length in hMSCs.     

荧光定量PCR测定端粒长度

目的应用实时荧光定量聚合酶链式反应（Q—PCR）方法测定端粒长度。方法选取9种人类细胞株,提取基因组DNA,采用Q—PCR方法测定相对T／S比率,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。结果定量PCR测定端粒长度相对T／S比率为0．68±0．57,DNA印迹法测量平均TRF值为8．57±2．34,两种方法测定结果的相关性分析R2=0．7807（P〈0．01）。结论采用荧光定量PCR方法测量端粒长度具有重复性好、省时、简便、可靠的特点,可高通量处理大量样品。     

Real-time quantitative PCR assay for measurement of avian telomeres

We present the application of a real-time quantitative PCR assay, previously developed to measure relative telomere length in humans and mice, to two bird species, the zebra finch Taeniopygia guttata and the Alpine swift Apus melba . This technique is based on the PCR amplification of telomeric (TTAGGG)_n sequences using specific oligonucleotide primers. Relative telomere length is expressed as the ratio (T/S) of telomere repeat copy number (T) to control single gene copy number (S). This method is particularly useful for comparisons of individuals within species, or where the same individuals are followed longitudinally. We used glyceraldehyde-3-phosphate dehydrogenase (GAPDH) as a single control gene. In both species, we validated our PCR measurements of relative telomere length against absolute measurements of telomere length determined by the conventional method of quantifying telomere terminal restriction fragment (TRF) lengths using both the traditional Southern blot analysis (Alpine swifts) and in gel hybridization (zebra finches). As found in humans and mice, telomere lengths in the same sample measured by TRF and PCR were well correlated in both the Alpine swift and the zebra finch.. Hence, this PCR assay for measurement of bird telomeres, which is fast and requires only small amounts of genomic DNA, should open new avenues in the study of environmental factors influencing variation in telomere length, and how this variation translates into variation in cellular and whole organism senescence.     

Telomere length measurement in mouse chromosomes by a modified Q-FISH method

Telomeres are physical ends of mammalian chromosomes that dynamically change during the lifetime of a cell or organism. In order to understand mechanisms responsible for telomere dynamics, it is necessary to develop methods for accurate telomere length measurement. The most sensitive method for measuring telomere length in mouse chromosomes is quantitative fluorescence in situ hybridization (Q-FISH). The usual protocol for Q-FISH requires plasmids with variable numbers of telomeric repeats and fluorescence beads as calibration standards. Here, we describe a Q-FISH protocol in which two mouse lymphoma cell lines with well-defined telomere lengths are used as calibration standards. Using this protocol we demonstrate that reproducible results can be obtained in a set of four different mouse cell lines. This method can be adapted so that any pair of mammalian cell lines can serve as an internal calibration standard.     

Quantification of PCR products by phosphate measurement

Various techniques for quantification of PCR are available. Most frequently, the densitometric intensities of ethidium bromide-stained PCR products separated in gels are compared after normalizing to the levels of housekeeping gene products such as β-actin. More precise, but extremely time consuming, is the technique of competitive PCR. Newer methods, such as tracking amplification in real-time, have high start-up and maintenance costs (e.g., TaqMan, Applied Biosystems; LightCycler, Roche; I-Cycler, Bio-Rad). Here, I describe an alternative, simple technique to quantify PCR products by determining the entire phosphate released during PCR. The method can be performed using common laboratory equipment, and the reagents needed are extremely cheap. The method is validated by measuring the induction of inducible nitric oxide synthase gene expression in cell culture and comparing the results with data obtained by LightCycler experiments and RNase protection assays.     

High-sensitivity quantitative PCR platform

Real-time PCR methods have become widely used within the past few years. However, real-time PCR is rarely used to study chronic diseases with low pathogen loads, presumably because of insufficient sensitivity. In this report, we developed an integrated nucleic acid isolation and real-time PCR platform that vastly improved the sensitivity of the quantitative detection of the intracellular bacterium, Chlamydia spp., by fluorescence resonance energy transfer real-time PCR. Determinants of the overall detection sensitivity were analyzed by extracting nucleic acids from bovine milk specimens spiked with low amounts of chlamydial organisms. Nucleic acids were optimally preserved and recovered by collection in guanidinium stabilization buffer, binding to a matrix of glass fiber fleece, and elution in low volume. Step-down thermal cycling and an excess of hot-start Taq polymerase vastly improved the robustness and sensitivity of the real-time PCR while essentially maintaining 100% specificity. The amplification of Chlamydia 23S rRNA allowed for the differentiation of chlamydial species and was more robust at low target numbers than amplification of the omp1 gene. The best combined method detected single targets per a 100-microL specimen equivalent in a 5-microL real-time PCR input. In an initial application, this high-sensitivity real-time PCR platform demonstrated a high prevalence of chlamydial infection in cattle.     

Reliability and short-term intra-individual variability of telomere length measurement using monochrome multiplexing quantitative PCR

Background

Studies examining the association between telomere length and cancer risk have often relied on measurement of telomere length from a single blood draw using a real-time PCR technique. We examined the reliability of telomere length measurement using sequential samples collected over a 9-month period.

Methods and Findings

Relative telomere length in peripheral blood was estimated using a single tube monochrome multiplex quantitative PCR assay in blood DNA samples from 27 non-pregnant adult women (aged 35 to 74 years) collected in 7 visits over a 9-month period. A linear mixed model was used to estimate the components of variance for telomere length measurements attributed to variation among women and variation between time points within women. Mean telomere length measurement at any single visit was not significantly different from the average of 7 visits. Plates had a significant systematic influence on telomere length measurements, although measurements between different plates were highly correlated. After controlling for plate effects, 64% of the remaining variance was estimated to be accounted for by variance due to subject. Variance explained by time of visit within a subject was minor, contributing 5% of the remaining variance.

Conclusion

Our data demonstrate good short-term reliability of telomere length measurement using blood from a single draw. However, the existence of technical variability, particularly plate effects, reinforces the need for technical replicates and balancing of case and control samples across plates.     

Detection and measurement of PCR bias in quantitative methylation analysis of bisulphite-treated DNA.

Methylation analysis of individual cytosines in genomic DNA can be determined quantitatively by bisulphite treatment and PCR amplification of the target DNA sequence, followed by restriction enzyme digestion or sequencing. Methylated and unmethylated molecules, however, have different sequences after bisulphite conversion. For some sequences this can result in bias during the PCR amplification leading to an inaccurate estimate of methylation. PCR bias is sequence dependent and often strand-specific. This study presents a simple method for detection and measurement of PCR bias for any set of primers, and investigates parameters for overcoming PCR bias.     

Simultaneous quantitative detection of relevant biomarkers in breast cancer by quantitative real-time PCR

The assessment of ERa, PgR and HER2 status is routinely performed today to determine the endocrine responsiveness of breast cancer samples. Such determination is usually accomplished by means of immunohistochemistry and in case of HER2 amplification by means of fluorescent in situ hybridization (FISH). The analysis of these markers can be improved by simultaneous measurements using quantitative real-time PCR (Qrt-PCR). In this study we compared Qrt-PCR results for the assessment of mRNA levels of ERa, PgR, and the members of the human epidermal growth factor receptor family, HER1, HER2, HER3 and HER4. The results were obtained in two independent laboratories using two different methods, SYBR Green I and TaqMan probes, and different primers. By linear regression we demonstrated a good concordance for all six markers. The quantitative mRNA expression levels of ERa, PgR and HER2 also strongly correlated with the respective quantitative protein expression levels prospectively detected by EIA in both laboratories. In addition, HER2 mRNA expression levels correlated well with gene amplification detected by FISH in the same biopsies. Our results indicate that both Qrt-PCR methods were robust and sensitive tools for routine diagnostics and consistent with standard methodologies. The developed simultaneous assessment of several biomarkers is fast and labor effective and allows optimization of the clinical decision-making process in breast cancer tissue and/or core biopsies.     

Rapid detection of selected aneuploidies by quantitative fluorescent PCR

Selected aneuploidies can be rapidly diagnosed by the analysis of fluorescent polymerase chain reaction (PCR) products of chromosome-specific and highly polymorphic small tandem repeats (STRs). The quantitative STR patterns obtained from samples of normal individuals are markedly different from those seen when patients with aneuploidies involving chromosome X, or trisomies of chromosomes 21 and 18, are tested. For example, while samples from normal subjects – tested with a chromosome 21-derived STR (D21S11) – show two fluorescent PCR peaks with similar activities in a 1:1 ratio, the analysis of samples from patients with trisomy 21 reveals the presence of either three peaks (ratio 1:1:1), or two peaks with a ratio of 2:1. The use of an internal non-polymorphic marker allows identification of trisomic samples with three copies of the same allele. This rapid approach (24 hours) is particularly valuable when applied to prenatal diagnosis of chromosomal abnormalities since it reduces the time of anxiety of the parents waiting for the results of the conventional cytogenetic tests, which require several weeks.     

Basic principles of quantitative PCR

The polymerase chain reaction (PCR) is an extremely sensitive method owing to the repetitive multiplication of template molecules. This property is a drawback for quantitative measurements because small differences in the multiplication factor lead to large differences in the amount of product. Two methods can be used to solve the problem of quantification: kinetic methods based on the determination or comparison of the amplification factor; and coamplification methods, which compare the amount of product to that of a simultaneously amplified standard template. An overview of the theoretical background of both methods is presented. For selection of a suitable method, both theoretical and practical considerations are important. Kinetic methods are the most convenient if PCR can be performed without opening the tubes, as in some apparatus using fluorescence detection. Coamplification methods can be done without expensive equipment but requires the parallel running of several PCR tubes. When the number of initial template molecules is close to one, as in the limiting dilution technique, statistical considerations become important.     

Real-time quantitative PCR in parasitology

Standard techniques for counting parasites are often time-consuming, difficult and inaccurate, and occasionally unpleasant. Real-time quantitative polymerase chain reaction has recently been applied to parasitology, specifically Plasmodium, Toxoplasma, Leishmania and Neospora. These techniques are truly quantitative, give results over a range of 6-7 orders of magnitude, are quick to perform and require no manipulations post-amplification. They can be used to count genome numbers and to study levels of gene expression. The advantages and limitations of existing thermocyclers and applicable detection systems are discussed here, and promising new developments are highlighted.     

Statistical significance of quantitative PCR

Background  

PCR has the potential to detect and precisely quantify specific DNA sequences, but it is not yet often used as a fully quantitative method. A number of data collection and processing strategies have been described for the implementation of quantitative PCR. However, they can be experimentally cumbersome, their relative performances have not been evaluated systematically, and they often remain poorly validated statistically and/or experimentally. In this study, we evaluated the performance of known methods, and compared them with newly developed data processing strategies in terms of resolution, precision and robustness.     

实时荧光PCR技术定量检测转Bt基因水稻的研究

以转Bt基因的"克螟稻"为研究材料,通过使用特异的引物和荧光标记探针,以已知转基因成份含量的水稻样品为模板建立标准曲线,对转基因水稻的NOS和Bt外源基因进行了荧光定量检测分析.初步建立了转基因水稻定量检测的技术方法.