DNA extraction procedures meaningfully influence qPCR-based mtDNA copy number determination

Quantitative real time PCR (qPCR) is commonly used to determine cell mitochondrial DNA (mtDNA) copy number. This technique involves obtaining the ratio of an unknown variable (number of copies of an mtDNA gene) to a known parameter (number of copies of a nuclear DNA gene) within a genomic DNA sample. We considered the possibility that mtDNA:nuclear DNA (nDNA) ratio determinations could vary depending on the method of genomic DNA extraction used, and that these differences could substantively impact mtDNA copy number determination via qPCR. To test this we measured mtDNA:nDNA ratios in genomic DNA samples prepared using organic solvent (phenol–chloroform–isoamyl alcohol) extraction and two different silica-based column methods, and found mtDNA:nDNA ratio estimates were not uniform. We further evaluated whether different genomic DNA preparation methods could influence outcomes of experiments that use mtDNA:nDNA ratios as endpoints, and found the method of genomic DNA extraction can indeed alter experimental outcomes. We conclude genomic DNA sample preparation can meaningfully influence mtDNA copy number determination by qPCR.     

Molecular quantification of environmental DNA using microfluidics and digital PCR

Real-time PCR has been widely used to evaluate gene abundance in natural microbial habitats. However, PCR-inhibitory substances often reduce the efficiency of PCR, leading to the underestimation of target gene copy numbers. Digital PCR using microfluidics is a new approach that allows absolute quantification of DNA molecules. In this study, digital PCR was applied to environmental samples, and the effect of PCR inhibitors on DNA quantification was tested. In the control experiment using λ DNA and humic acids, underestimation of λ DNA at 1/4400 of the theoretical value was observed with 6.58ngμL(-1) humic acids. In contrast, digital PCR provided accurate quantification data with a concentration of humic acids up to 9.34ngμL(-1). The inhibitory effect of paddy field soil extract on quantification of the archaeal 16S rRNA gene was also tested. By diluting the DNA extract, quantified copy numbers from real-time PCR and digital PCR became similar, indicating that dilution was a useful way to remedy PCR inhibition. The dilution strategy was, however, not applicable to all natural environmental samples. For example, when marine subsurface sediment samples were tested the copy number of archaeal 16S rRNA genes was 1.04×10(3)copies/g-sediment by digital PCR, whereas real-time PCR only resulted in 4.64×10(2)copies/g-sediment, which was most likely due to an inhibitory effect. The data from this study demonstrated that inhibitory substances had little effect on DNA quantification using microfluidics and digital PCR, and showed the great advantages of digital PCR in accurate quantifications of DNA extracted from various microbial habitats.     

Simultaneous quantitative assessment of circulating cell-free mitochondrial and nuclear DNA by multiplex real-time PCR

Quantification of circulating nucleic acids in plasma and serum could be used as a non-invasive diagnostic tool for monitoring a wide variety of diseases and conditions. We describe here a rapid, simple and accurate multiplex real-time PCR method for direct synchronized analysis of circulating cell-free (ccf) mitochondrial (mtDNA) and nuclear (nDNA) DNA in plasma and serum samples. The method is based on one-step multiplex real-time PCR using a FAM-labeled MGB probe and primers to amplify the mtDNA sequence of the ATP 8 gene, and a VIC-labeled MGB probe and primers to amplify the nDNA sequence of the glycerinaldehyde-3-phosphate-dehydrogenase (GAPDH) gene, in plasma and serum samples simultaneously. The efficiencies of the multiplex assays were measured in serial dilutions. Based on the simulation of the PCR reaction kinetics, the relative quantities of ccf mtDNA were calculated using a very simple equation. Using our optimised real-time PCR conditions, close to 100% efficiency was obtained from the two assays. The two assays performed in the dilution series showed very good and reproducible correlation to each other. This optimised multiplex real-time PCR protocol can be widely used for synchronized quantification of mtDNA and nDNA in different samples, with a very high rate of efficiency.     

Image analysis in quantitative PCR. An application for the measurement of c-erbB-2 oncogene amplification in DNA from human tumours

We present an application of image analysis for the direct quantification of PCR products after gel electrophoresis and ethidium bromide staining of DNA. This procedure has been applied to the development of an assay based on competitive PCR for the measurement of the degree of amplification of c-erbB-2 oncogene in DNA from human tumours. In this method two DNA species (genomic and competitor) compete for PCR amplification. Since results are calculated from the final competitor/genomic ratio any variable affecting the rate of PCR amplification has no effect on the accuracy of the ratio measurement. Results are reported which show that even large variations in the experimental conditions (number of PCR cycles, sample volumes and extracted DNA quality) did not interfere with the precision of the measurement of the competitor/genomic ratio.     

Chemically modified primers for improved multiplex polymerase chain reaction

Multiplex polymerase chain reaction (PCR), the amplification of multiple targets in a single reaction, presents a new set of challenges that further complicate more traditional PCR setups. These complications include a greater probability for nonspecific amplicon formation and for imbalanced amplification of different targets, each of which can compromise quantification and detection of multiple targets. Despite these difficulties, multiplex PCR is frequently used in applications such as pathogen detection, RNA quantification, mutation analysis, and (recently) next generation DNA sequencing. Here we investigated the utility of primers with one or two thermolabile 4-oxo-1-pentyl phosphotriester modifications in improving multiplex PCR performance. Initial endpoint and real-time analyses revealed a decrease in off-target amplification and a subsequent increase in amplicon yield. Furthermore, the use of modified primers in multiplex setups revealed a greater limit of detection and more uniform amplification of each target as compared with unmodified primers. Overall, the thermolabile modified primers present a novel and exciting avenue for improving multiplex PCR performance.     

Absolute quantitation of a heteroplasmic mitochondrial DNA deletion using a multiplex three-primer real-time PCR assay

Quantitation of wild-type and deleted mitochondrial DNA (mtDNA) coexisting within the same cell (a.k.a., heteroplasmy) is important in mitochondrial disease and aging. We report the development of a multiplex three-primer PCR assay that is capable of absolute quantitation of wild-type and deleted mtDNA simultaneously. Molecular beacons were designed to hybridize with either type of mtDNA molecule, allowing real-time detection during PCR amplification. The assay is specific and can detect down to six copies of mtDNA, making it suitable for single-cell analyses. The relative standard deviation in the threshold cycle number is approximately 0.6%. Heteroplasmy was quantitated in individual cytoplasmic hybrid cells (cybrids), containing a large mtDNA deletion, and bulk cell samples. Individual cybrid cells contained 100-2600 copies of wild-type mtDNA and 950-4700 copies of deleted mtDNA, and the percentage of heteroplasmy ranged from 43+/-16 to 95+/-16%. The average amount of total mtDNA was 3800+/-1600 copies/cybrid cell, and the average percentage of heteroplasmy correlated well with the bulk cell sample. The single-cell analysis also revealed that heteroplasmy in individual cells is highly heterogeneous. This assay will be useful for monitoring clonal expansions of mtDNA deletions and investigating the role of heteroplasmy in cell-to-cell heterogeneity in cellular models of mitochondrial disease and aging.     

基于数字PCR的不同品种鸭组织中线粒体与核DNA拷贝数差异研究

肉和肉制品是人类生活的重要营养来源,但近年来肉制品中发生的掺假使假事件屡见不鲜,使得肉品的质量安全问题已经成为全世界关注的热点话题。以核酸为目标的动物源鉴定是当前普遍使用的方法。在核酸检测中,常用线粒体基因或核基因作为靶标,缺乏统一标准。以绍兴鸭和北京鸭等不同品种及生鲜组织(鸭血、鸭胸肉、鸭肝、鸭皮、鸭心和鸭腿肉)为实验材料,提取DNA后利用微滴式数字PCR开展线粒体和核DNA拷贝数的比较研究,以两者拷贝数及其比值的变异系数为判定依据。结果显示,核DNA的拷贝数在不同品种鸭组织间相对稳定,且变异系数小于线粒体DNA,表明核DNA是开展鸭肉制品掺假定量检测的最适DNA来源。鸭腿肉中线粒体/核DNA拷贝数比值的变异系数最小,表明线粒体DNA作为靶基因的鸭肉掺假比例定量检测时,鸭腿肉来源的肉制品是最佳选择。     

Estimating mitochondrial DNA content of chinook salmon spermatozoa using quantitative real-time polymerase chain reaction

Animal mitochondrial DNA (mtDNA) is predominantly inherited maternally. Various mechanisms to avoid the transmission of paternal mtDNA to offspring have been proposed, including the dilution of paternal mtDNA by maternal mtDNA in the zygote. The effectiveness of dilution as a barrier will be determined by the number of mtDNA molecules contributed by each parental gamete, and is expected to be highly variable among different taxa due to interspecific differences in mating systems and gamete investment. Estimates of this ratio are currently limited to few mammalian species, and data from other taxa are therefore needed to better understand the mechanisms of mitochondrial inheritance. The present study estimates mtDNA content in salmon sperm, the first nonmammalian vertebrate to be examined. Although highly divergent, it appears that the mtDNA content may be conserved within vertebrate taxa, indicating that the reduction of mtDNA is a key factor of spermatogenesis to ensure mitochondrial functionality on the one hand, and to avoid paternal leakage at a significant or detectable level on the other hand. We employ quantitative real-time PCR (Q-PCR) and demonstrate the accuracy and high reproducibility of our experiments. Furthermore, we compare and evaluate two standard approaches used for the quantification of genes, Q-PCR and blotting methods, in regard to their utility in the accurate quantification of mitochondrial genes.     

Effects of X-irradiation on mitochondrial DNA damage and its supercoiling formation change

There have been a small number of reports of radiation-induced mtDNA damage, and mtDNA supercoiling formation change induced by ionizing radiation has not been investigated before. This study evaluated mtDNA damage and supercoiling formation change after X-irradiation. The human breast cancer cell line, MCF-7 cells were used for analysis. Modified supercoiling-sensitive real-time PCR approach was used to evaluate mitochondrial DNA supercoiling formation change and copy number; long-PCR method was applied for the quantification of mtDNA damage. MtDNA damage and formation change induced by high-dose irradiation was persistent in 24 h after irradiation and was not significant after low-dose irradiation. MtDNA copy number was slightly increased after high-dose irradiation and a transit increase was observed after low-dose irradiation. This is the first study to evaluate radiation-induced mitochondrial DNA supercoiling formation change using real-time PCR. Combined with data of ROS generation and dynamics of mitochondrial mass, our findings suggested that mtDNA is sensitive to radiation hazards, indicating mitochondrial biogenesis play an important role in radiation-induced cellular response.     

Calibration-curve-free quantitative PCR: a quantitative method for specific nucleic acid sequences without using calibration curves

We have developed a simple quantitative method for specific nucleic acid sequences without using calibration curves. This method is based on the combined use of competitive polymerase chain reaction (PCR) and fluorescence quenching. We amplified a gene of interest (target) from DNA samples and an internal standard (competitor) with a sequence-specific fluorescent probe using PCR and measured the fluorescence intensities before and after PCR. The fluorescence of the probe is quenched on hybridization with the target by guanine bases, whereas the fluorescence is not quenched on hybridization with the competitor. Therefore, quench rate (i.e., fluorescence intensity after PCR divided by fluorescence intensity before PCR) is always proportional to the ratio of the target to the competitor. Consequently, we can calculate the ratio from quench rate without using a calibration curve and then calculate the initial copy number of the target from the ratio and the initial copy number of the competitor. We successfully quantified the copy number of a recombinant DNA of genetically modified (GM) soybean and estimated the GM soybean contents. This method will be particularly useful for rapid field tests of the specific gene contamination in samples.     

DNA supercoiling suppresses real-time PCR: a new approach to the quantification of mitochondrial DNA damage and repair

As a gold standard for quantification of starting amounts of nucleic acids, real-time PCR is increasingly used in quantitative analysis of mtDNA copy number in medical research. Using supercoiled plasmid DNA and mtDNA modified both in vitro and in cancer cells, we demonstrated that conformational changes in supercoiled DNA have profound influence on real-time PCR quantification. We showed that real-time PCR signal is a positive function of the relaxed forms (open circular and/or linear) rather than the supercoiled form of DNA, and that the conformation transitions mediated by DNA strand breaks are the main basis for sensitive detection of the relaxed DNA. This new finding was then used for sensitive detection of structure-mediated mtDNA damage and repair in stressed cancer cells, and for accurate quantification of total mtDNA copy number when all supercoiled DNA is converted into the relaxed forms using a prior heat-denaturation step. The new approach revealed a dynamic mtDNA response to oxidative stress in prostate cancer cells, which involves not only early structural damage and repair but also sustained copy number reduction induced by hydrogen peroxide. Finally, the supercoiling effect should raise caution in any DNA quantification using real-time PCR.     

The real-time polymerase chain reaction

The scientific, medical, and diagnostic communities have been presented the most powerful tool for quantitative nucleic acids analysis: real-time PCR [Bustin, S.A., 2004. A-Z of Quantitative PCR. IUL Press, San Diego, CA]. This new technique is a refinement of the original Polymerase Chain Reaction (PCR) developed by Kary Mullis and coworkers in the mid 80:ies [Saiki, R.K., et al., 1985. Enzymatic amplification of beta-globin genomic sequences and restriction site analysis for diagnosis of sickle cell anemia, Science 230, 1350], for which Kary Mullis was awarded the 1993 year's Nobel prize in Chemistry. By PCR essentially any nucleic acid sequence present in a complex sample can be amplified in a cyclic process to generate a large number of identical copies that can readily be analyzed. This made it possible, for example, to manipulate DNA for cloning purposes, genetic engineering, and sequencing. But as an analytical technique the original PCR method had some serious limitations. By first amplifying the DNA sequence and then analyzing the product, quantification was exceedingly difficult since the PCR gave rise to essentially the same amount of product independently of the initial amount of DNA template molecules that were present. This limitation was resolved in 1992 by the development of real-time PCR by Higuchi et al. [Higuchi, R., Dollinger, G., Walsh, P.S., Griffith, R., 1992. Simultaneous amplification and detection of specific DNA-sequences. Bio-Technology 10(4), 413-417]. In real-time PCR the amount of product formed is monitored during the course of the reaction by monitoring the fluorescence of dyes or probes introduced into the reaction that is proportional to the amount of product formed, and the number of amplification cycles required to obtain a particular amount of DNA molecules is registered. Assuming a certain amplification efficiency, which typically is close to a doubling of the number of molecules per amplification cycle, it is possible to calculate the number of DNA molecules of the amplified sequence that were initially present in the sample. With the highly efficient detection chemistries, sensitive instrumentation, and optimized assays that are available today the number of DNA molecules of a particular sequence in a complex sample can be determined with unprecedented accuracy and sensitivity sufficient to detect a single molecule. Typical uses of real-time PCR include pathogen detection, gene expression analysis, single nucleotide polymorphism (SNP) analysis, analysis of chromosome aberrations, and most recently also protein detection by real-time immuno PCR.     

Comparison of DNA extraction methods for multiplex polymerase chain reaction

We compared six DNA extraction methods for obtaining DNA from whole blood and saliva for use in multiplex polymerase chain reaction (PCR) assays. The aim was to evaluate saliva sampling as an alternative to blood sampling to obtain DNA for molecular diagnostics, genetic genealogy, and research purposes. The DNA quantity, DNA purity (A_260/280), PCR inhibition ratio, and mitochondrial DNA/genomic DNA ratio were measured to compare the extraction methods. The different extraction methods resulted in variable DNA quantity and purity, but there were no significant differences in the efficiency of multiplex PCR and oligomicroarray signals after single-base extension on the arrayed primer extension 2 (APEX-2).     

A dose response for radiation-induced intrachromosomal DNA rearrangements detected by inverse polymerase chain reaction.

X-ray-induced intrachromosomal DNA rearrangements were detected in the 5' region of the MYC gene of cells of the human bladder carcinoma cell line, EJ-30, by using PCR with inverted primers. When the cells were allowed to repair/misrepair for 6 or 23 h after irradiation, the frequency of rearrangements increased with dose from (0.7 +/- 0.4) x 10(-5) per copy of MYC for unirradiated cells to (3.2 +/- 0.7) x 10(-5) after 30 Gy, (5.4 +/- 1.2) x 10(-5) after 70 Gy, and (5.9 +/- 1.0) x 10(-5) after 100 Gy. No significant difference was observed between 6 and 23 h of repair. Sequences obtained from the products suggest that there was no homology between the two sequences involved in the recombination event and that there was no clustering of breakpoints. The procedure is relatively simple, requiring only one digestion with a rare-cutting restriction enzyme prior to PCR amplification of the DNA purified from irradiated cells. The site of enzyme digestion is located between a pair of primer sites 120 bp apart for which the primers face in opposite directions. If no intrachromosomal rearrangement has occurred, no PCR product would be obtained. However, if an intrachromosomal rearrangement has occurred between two regions located on either side of the primer sites, an episome or duplication event would result if the rearrangement had occurred either within the same chromatid or between two sister chromatids, respectively. Digestion between the primers would linearize an episome or release a linear molecule containing the duplicated primer sites from a larger molecule. After both types of rearrangement events, the primers would be facing each other and would be located on either end of the linear molecule; and if they are less than approximately 5 kb apart, PCR amplification should result in a product. This procedure is relatively simple and rapid and does not require any cell division after irradiation or phenotypic selection of mutants. Also, quantification is based on the number of PCR products detected in a known amount of DNA, and not on a precise determination of the amount of PCR amplification that has occurred. Thus the inverse PCR procedure has the potential ofbeing used as an assay to detect variations in radiation-induced frequencies of DNA rearrangements.     

Quantification of total mitochondrial DNA and the 4977-bp common deletion in Pearson's syndrome lymphoblasts using a fluorogenic 5'-nuclease (TaqMan) real-time polymerase chain reaction assay and plasmid external calibration standards

This study describes a multiplex real-time polymerase chain reaction (PCR) assay that quantifies total mitochondrial DNA (mtDNA(total)) and mtDNA bearing the 4977-base pair 'common deletion' (deltamtDNA4977) in lymphoblasts derived from an individual diagnosed with Pearson's syndrome. The method is unique in its use of plasmids as external quantification standards and its use of multiplex conditions. Standards are validated by comparison with purified mtDNA amplification curves and by the fact that curves are largely unaffected by nuclear DNA (nucDNA). Finally, slopes of standard curves and unknowns are shown to be similar to each other and to theoretical predictions. From these data, mtDNA(total) in these cells is calculated to be 3258 (+723/-592) copies per cell while deltamtDNA4977 averages 232 (+136/-86) copies per cell or 7% (+4.65/-2.81).     

Quantification of Escherichia coli genomic DNA contamination in recombinant protein preparations by polymerase chain reaction and affinity-based collection

This study describes the development of a novel assay for the quantification of Escherichia coli genomic DNA contamination in recombinant protein samples. The technique is based on PCR amplification and digoxygenin labeling of the genes encoding 5S ribosomal RNA followed by affinity-based collection and detection. Samples containing 1 pg x mL(-1) of extracted E. coli genomic DNA (gDNA) could be measured using this method. Using extracted E. coli gDNA as standards, a 35-cycle PCR reaction exhibited a linear response versus template concentration between 1 pg x mL(-1) and1 ng x mL(-1) genomic DNA even when diluted in a variety of buffering conditions. Comparison of the novel assay with a traditional filter binding and hybridization technique using recombinant protein samples confirmed that the procedure was accurate and sensitive. The assay described in this report is a safer and less expensive alternative to radioactive techniques employed for DNA quantification, utilizing readily available reagents and apparatus.     

Estimation of the reaction efficiency in polymerase chain reaction

Polymerase chain reaction (PCR) is largely used in molecular biology for increasing the copy number of a specific DNA fragment. The succession of 20 replication cycles makes it possible to multiply the quantity of the fragment of interest by a factor of 1 million. The PCR technique has revolutionized genomics research. Several quantification methodologies are available to determine the DNA replication efficiency of the reaction which is the probability of replication of a DNA molecule at a replication cycle. We elaborate a quantification procedure based on the exponential phase and the early saturation phase of PCR. The reaction efficiency is supposed to be constant in the exponential phase, and decreasing in the saturation phase. We propose to model the PCR amplification process by a branching process which starts as a Galton-Watson branching process followed by a size-dependent process. Using this stochastic modelling and the conditional least-squares estimation method, we infer the reaction efficiency from a single PCR trajectory.     

Intraradical dynamics of two coexisting isolates of the arbuscular mycorrhizal fungus Glomus intraradices sensu lato as estimated by real-time PCR of mitochondrial DNA

Real-time PCR in nuclear ribosomal DNA (nrDNA) is becoming a well-established tool for the quantification of arbuscular mycorrhizal (AM) fungi, but this genomic region does not allow the specific amplification of closely related genotypes. The large subunit of mitochondrial DNA (mtDNA) has a higher-resolution power, but mtDNA-based quantification has not been previously explored in AM fungi. We applied real-time PCR assays targeting the large subunit of mtDNA to monitor the DNA dynamics of two isolates of Glomus intraradices sensu lato coexisting in the roots of medic (Medicago sativa). The mtDNA-based quantification was compared to quantification in nrDNA. The ratio of copy numbers determined by the nrDNA- and mtDNA-based assays consistently differed between the two isolates. Within an isolate, copy numbers of the nuclear and the mitochondrial genes were closely correlated. The two quantification approaches revealed similar trends in the dynamics of both isolates, depending on whether they were inoculated alone or together. After 12 weeks of cultivation, competition between the two isolates was observed as a decrease in the mtDNA copy numbers of one of them. The coexistence of two closely related isolates, which cannot be discriminated by nrDNA-based assays, was thus identified as a factor influencing the dynamics of AM fungal DNA in roots. Taken together, the results of this study show that real-time PCR assays targeted to the large subunit of mtDNA may become useful tools for the study of coexisting AM fungi.     

Tag/hybridization-based sensitive detection of polymerase chain reaction products

The polymerase chain reaction (PCR) is an important technology to amplify a single copy or a few copies of DNA segment in genomic DNAs, visualizing the segment as DNA fragment. Thus, PCR is frequently used in various examinations such as detection of bacteria and fungi in the food industry. Here, we report a simple and sensitive method for detection of PCR products using single-strand tag sequence and hybridization of the tag sequence to the complementary tag sequence immobilized on solid material (STH). The detection sensitivity was found to be at least 50 times higher than electrophoresis/ethidium bromide (EtBr) visualization for approximately a 500-bp fragment and higher than the ordinary hybridization, that is, hybridization of denatured PCR product to probe sequence immobilized on solid material.     

Large mitochondrial repeats multiplied during the polymerase chain reaction

The number of repeats in repetitive DNA like micro‐ and minisatellites is often determined by polymerase chain reaction (PCR). When we counted repeats in an array of mitochondrial repeats in the cattle tick (Boophilus microplus) we found that the number of repeats increased during PCR. Multiplication of the repeats was independent of the primers used to amplify the region, the PCR annealing temperature and the length of the PCR product. The use of PCR to determine the number of repeats in arrays needs to be reassessed. For long repeats, a subset of samples should always be analysed by Southern blot hybridization to confirm the PCR results.