Real-time PCR test for detection and quantification of human polyomavirus BK (BKV) DNA

The human polyomavirus BK (BKV) is wide-spread pathogen, associated with urogenital tract disorders or even nephropathy in immunosuppressed patients. Nowadays molecular detection by real-time PCR (qPCR) is recognized as a method-of-choice for detecting human polyomaviruses in clinical samples. The aim of the study was development of real-time PCR assay for detection and quantification of polyomavirus BK DNA in clinical samples, using specific primers targeting a viral DNA VP3 gene and a TaqMan hydrolyzing probe. The analytical sensitivity of assay was tested using serial dilutions of BKV DNA in range between 13500 and 15 copies/ml. 27 urine samples and 23 plasma samples taken from a group of 22 adult recipients of allogeneic HSCT were tested for the presence of polyomavirus BK in the LightCycler system. Described in-house real-time PCR assay detected BKV DNA in 8 specimens (6 urine and 2 plasma). Detected average viral load was 170 copies/ml for plasma and 1250 copies/ml for urine samples, respectively. The results of this study show that developed TaqMan-based probe qPCR assay is very reliable and valuable for detection and quantification of BKV DNA, both in urine and plasma samples. These data, combined with its rapid turnaround time for results and decreased hands-on time, make the LightCycler PCR assay highly suitable for the rapid diagnostics of polyomavirus BK infections in the clinical laboratory.     

A quantitative polymerase chain reaction assay for detecting and identifying fungal contamination in human allograft tissue

To complement donor selection and tissue processing, rapid and reliable detection, discrimination, and quantification of fungal pathogens are extremely important for tissues destined to be implanted into humans. The current detection method for fungal pathogens, in particular, is difficult and time-consuming. Quantitative polymerase chain reaction (qPCR) technology is considered one of the most sensitive methods to detect low levels of DNA. Here a qPCR method is described that can detect clinically relevant, pathogenic fungal organisms. The assay allowed the quantification of fungal organisms within a tissue implant and provides a means to identify the contaminating species. The primers for the qPCR assay were designed to amplify a conserved region of the L2 region of the large ribosomal subunit (LSU) gene. This set of primers was able to detect fewer than 10 colony forming units from Aspergillus and Candida species in spiked samples. Clinical samples were also evaluated using this method and the data compared positively to the existing accepted 28-day fungal culture method for fungal detection. The qPCR method described herein significantly reduced the time required to identify fungal contamination in tissue implants.     

A Mechanistic Model of PCR for Accurate Quantification of Quantitative PCR Data

Background

Quantitative PCR (qPCR) is a workhorse laboratory technique for measuring the concentration of a target DNA sequence with high accuracy over a wide dynamic range. The gold standard method for estimating DNA concentrations via qPCR is quantification cycle () standard curve quantification, which requires the time- and labor-intensive construction of a standard curve. In theory, the shape of a qPCR data curve can be used to directly quantify DNA concentration by fitting a model to data; however, current empirical model-based quantification methods are not as reliable as standard curve quantification.

Principal Findings

We have developed a two-parameter mass action kinetic model of PCR (MAK2) that can be fitted to qPCR data in order to quantify target concentration from a single qPCR assay. To compare the accuracy of MAK2-fitting to other qPCR quantification methods, we have applied quantification methods to qPCR dilution series data generated in three independent laboratories using different target sequences. Quantification accuracy was assessed by analyzing the reliability of concentration predictions for targets at known concentrations. Our results indicate that quantification by MAK2-fitting is as reliable as standard curve quantification for a variety of DNA targets and a wide range of concentrations.

Significance

We anticipate that MAK2 quantification will have a profound effect on the way qPCR experiments are designed and analyzed. In particular, MAK2 enables accurate quantification of portable qPCR assays with limited sample throughput, where construction of a standard curve is impractical.     

Enhanced Reliability and Accuracy for Field Deployable Bioforensic Detection and Discrimination of Xylella fastidiosa subsp. pauca,Causal Agent of Citrus Variegated Chlorosis Using Razor Ex Technology and TaqMan Quantitative PCR

A reliable, accurate and rapid multigene-based assay combining real time quantitative PCR (qPCR) and a Razor Ex BioDetection System (Razor Ex) was validated for detection of Xylella fastidiosa subsp. pauca (Xfp, a xylem-limited bacterium that causes citrus variegated chlorosis [CVC]). CVC, which is exotic to the United States, has spread through South and Central America and could significantly impact U.S. citrus if it arrives. A method for early, accurate and sensitive detection of Xfp in plant tissues is needed by plant health officials for inspection of products from quarantined locations, and by extension specialists for detection, identification and management of disease outbreaks and reservoir hosts. Two sets of specific PCR primers and probes, targeting Xfp genes for fimbrillin and the periplasmic iron-binding protein were designed. A third pair of primers targeting the conserved cobalamin synthesis protein gene was designed to detect all possible X. fastidiosa (Xf) strains. All three primer sets detected as little as 1 fg of plasmid DNA carrying X. fastidiosa target sequences and genomic DNA of Xfp at as little as 1 - 10 fg. The use of Razor Ex facilitates a rapid (about 30 min) in-field assay capability for detection of all Xf strains, and for specific detection of Xfp. Combined use of three primer sets targeting different genes increased the assay accuracy and broadened the range of detection. To our knowledge, this is the first report of a field-deployable rapid and reliable bioforensic detection and discrimination method for a bacterial phytopathogen based on multigene targets.     

Species-specific detection and quantification of common barnacle larvae from the Japanese coast using quantitative real-time PCR

Species-specific detection and quantification methods for barnacle larvae using quantitative real-time polymerase chain reaction (qPCR) were developed. Species-specific primers for qPCR were designed for 13 barnacle species in the mitochondrial 12S ribosomal RNA gene region. Primer specificity was examined by PCR using template DNA extracted from each of the 13 barnacle species, other unidentified barnacle species, and field collected zooplankton samples. The resulting PCR products comprised single bands following agarose gel electrophoresis when the templates corresponded to primers. The amplifications were highly species-specific even for the field plankton samples. The field plankton samples were subjected to qPCR assay. The calculated DNA contents for each barnacle species were closely correlated with the number of larvae measured by microscopic examination. The method could be applied to quantify barnacle larvae in natural plankton samples.     

Species-specific detection and quantification of common barnacle larvae from the Japanese coast using quantitative real-time PCR

Species-specific detection and quantification methods for barnacle larvae using quantitative real-time polymerase chain reaction (qPCR) were developed. Species-specific primers for qPCR were designed for 13 barnacle species in the mitochondrial 12S ribosomal RNA gene region. Primer specificity was examined by PCR using template DNA extracted from each of the 13 barnacle species, other unidentified barnacle species, and field collected zooplankton samples. The resulting PCR products comprised single bands following agarose gel electrophoresis when the templates corresponded to primers. The amplifications were highly species-specific even for the field plankton samples. The field plankton samples were subjected to qPCR assay. The calculated DNA contents for each barnacle species were closely correlated with the number of larvae measured by microscopic examination. The method could be applied to quantify barnacle larvae in natural plankton samples.     

Development of a qPCR assay for specific quantification of Botrytis cinerea on grapes

The aim of this study was to develop a system for rapid and accurate real-time quantitative PCR (qPCR) identification and quantification of Botrytis cinerea, one of the major pathogens present on grapes. The intergenic spacer (IGS) region of the nuclear ribosomal DNA was used to specifically detect and quantify B. cinerea. A standard curve was established to quantify this fungus. The qPCR reaction was based on the simultaneous detection of a specific IGS sequence and also contained an internal amplification control to compensate for variations in DNA extraction and the various compounds from grapes that inhibit PCR. In these conditions, the assay had high efficiency (97%), and the limit of detection was estimated to be 6.3 pg DNA (corresponding to 540 spores). Our method was applied to assess the effects of various treatment strategies against Botrytis in the vineyard. Our qPCR assay proved to be rapid, selective and sensitive and may be used to monitor Botrytis infection in vineyards.     

Detection of Differential Host Susceptibility to the Marine Oomycete Pathogen Eurychasma dicksonii by Real-Time PCR: Not All Algae Are Equal

In the marine environment, a growing body of evidence points to parasites as key players in the control of population dynamics and overall ecosystem structure. However, their prevalence and impact on marine macroalgal communities remain virtually unknown. Indeed, infectious diseases of seaweeds are largely underdocumented, partly because of the expertise required to diagnose them with a microscope. Over the last few years, however, real-time quantitative PCR (qPCR) has emerged as a rapid and reliable alternative to visual symptom scoring for monitoring pathogens. Thus, we present here a qPCR assay suitable for the detection and quantification of the intracellular oomycete pathogen Eurychasma dicksonii in its ectocarpalean and laminarialean brown algal hosts. qPCR and microscopic observations made of laboratory-controlled cultures revealed that clonal brown algal strains exhibit different levels of resistance against Eurychasma, ranging from high susceptibility to complete absence of symptoms. This observation strongly argues for the existence of a genetic determinism for disease resistance in brown algae, which would have broad implications for the dynamics and genetic structure of natural populations. We also used qPCR for the rapid detection of Eurychasma in filamentous brown algae collected in Northern Europe and South America and found that the assay is specific, robust, and widely applicable to field samples. Hence, this study opens the perspective of combining large-scale disease monitoring in the field with laboratory-controlled experiments on the genome model seaweed Ectocarpus siliculosus to improve our understanding of brown algal diseases.     

Detection of Helicobacter pylori in sewage and water using a new quantitative PCR method with SYBR green

Aims: To demonstrate the application of a new quantitative polymerase chain reaction (qPCR) technique for the determination of Helicobacter pylori concentrations in water, and to use this method to investigate the occurrence of the bacteria in sewage. The other aim was to study the survival capacity and detectability of the bacteria in artificially contaminated groundwater at different temperatures of 4 and 15°C. Methods and Results: The detection of H. pylori in water was aided by PCR using specific primers designed for the amplification of a fragment within the major vacuolating cytotoxin gene. Conventional culture was compared with conventional PCR and the new real-time (RT) qPCR approach for the quantification of the bacterium. Helicobacter pylori remained culturable for 120 h at 4°C as opposed to only 24 h at 15°C. RT qPCR demonstrated a 100-fold greater sensitivity for the detection of H. pylori DNA in comparison with conventional PCR. Scanning electron microscopic (SEM) observation showed that the normal spiral form changed to a coccoid form after 24 and 72 h at 15 and 4°C, respectively. Helicobacter pylori was found at 2–28 cells ml⁻¹ in sewage, of the 23 sewage samples – 84% were positive for H. pylori species-specific vacuolating cyctotoxin gene (vacA) by RT qPCR, but were negative by conventional PCR. Conclusions: The RT qPCR assay provided a specific, sensitive and rapid method for the quantitative detection of H. pylori in sewage. This molecular method would be valuable in studying the prevalence of H. pylori as required by the United States Environmental Protection Agency Contaminant Candidate List, particularly in nondisinfected ground waters, in sewage as a source of contamination, and for addressing the possible presence of viable but nonculturable of H. pylori. Significance and Impact of the Study: The quantitative detection of H. pylori by rapid and less-expensive methods than the TaqMan Assay using SYBR green could be an important tool to monitor infection in community by measuring the concentrations in sewage and to meet the new regulatory and risk-based frameworks for water supplies.     

Genotyping and detection of multiple infections of Toxoplasma gondii using Pyrosequencing

A Pyrosequencing assay, based on SAG2 gene polymorphisms, was designed for genotyping and detection of multiple infections of Toxoplasma gondii. The assay was tested on samples spiked with DNA from single and multiple genotypes of T. gondii and also on a DNA sample from the brain of a rat with multiple infections. To evaluate the comparative efficacy of the assay, identical samples were also analysed by PCR-restriction fragment length polymorphism (RFLP) and dideoxy sequencing. The Pyrosequencing assay was found to be superior to the two conventional techniques. Genotyping and detection of multiple alleles were possible after a single PCR assay in duplex format, from both the spiked and direct samples. The simplex PCR assay enabled accurate quantification of the different alleles in the mix. In comparison, PCR-RFLP and dideoxy sequencing were neither able to unequivocally detect multiple genotype infections, nor quantify the relative concentrations of the alleles. We conclude that Pyrosequencing offers a simple, rapid and efficient means for diagnosis and genotyping of T. gondii, as well as detection and quantification of multiple genotype infections of T. gondii.     

Why the need for qPCR publication guidelines?—The case for MIQE

The polymerase chain reaction (PCR) has matured from a labour- and time-intensive, low throughput qualitative gel-based technique to an easily automated, rapid, high throughput quantitative technology. Real-time quantitative PCR (qPCR) has become the benchmark technology for the detection and quantification of nucleic acids in a research, diagnostic, forensic and biotechnology setting. However, ill-assorted pre-assay conditions, poor assay design and inappropriate data analysis methodologies have resulted in the recurrent publication of data that are at best inconsistent and at worst irrelevant and even misleading. Furthermore, there is a lamentable lack of transparency of reporting, with the “Materials and Methods” sections of many publications, especially those with high impact factors, not fit for the purpose of evaluating the quality of any reported qPCR data. This poses a challenge to the integrity of the scientific literature, with serious consequences not just for basic research, but potentially calamitous implications for drug development and disease monitoring. These issues are being addressed by a set of guidelines that propose a minimum standard for the provision of information for qPCR experiments (“MIQE”). MIQE aims to restructure to-day’s free-for-all qPCR methods into a more consistent format that will encourage detailed auditing of experimental detail, data analysis and reporting principles. General implementation of these guidelines is an important requisite for the maturing of qPCR into a robust, accurate and reliable nucleic acid quantification technology.     

Detection of Mycobacterium avium ssp. paratuberculosis in cheese, milk powder and milk using IS900 and f57-based qPCR assays

Aims: To develop a quantitative PCR assay for sensitive and specific detection of Mycobacterium avium ssp. paratuberculosis (Map) in a range of dairy products. Methods and Results: TaqMan^® assays were designed to target the IS900 and f57 genetic elements of Map. Both real‐time PCR assays were integrated with the Adiapure^® Map DNA extraction kit and assessed separately for the detection/quantification of Map in spiked milk, Cheddar cheese and milk powder. Assays were validated against Cheddar cheese samples containing known concentrations of Map. The IS900 qPCR assay was significantly more sensitive than the assay based on the f57 primer/probe. At a threshold cycle value of 38, limits of detection (LOD) for the IS900 qPCR assay were 0·6 CFU ml^?1, 2·8 CFU g^?1 and 30 CFU g^?1 for artificially contaminated pasteurized milk, whole milk powder and Cheddar cheese, respectively. The respective LOD’s for the f57 assay were 6·2 CFU ml^?1, 26·7 CFU g^?1 and 316 CFU g^?1. Conclusion: The integrated Adiapure^® extraction – IS900 real time assay described is a sensitive, quantitative method for the detection of Map in dairy products. This is the first study to consider qPCR as a quantitative estimation of Map‐DNA in cheese and whole milk powder. Significance and Impact of the Study: The assay developed allows sensitive detection and quantification of Map DNA in a range of dairy products which is valuable for the screening and surveillance of this potential zoonotic organism.     

Rapid detection and quantification of bisulfite reductase genes in oil field samples using real-time PCR

Sulfate-reducing bacteria (SRB) pose a serious problem to offshore oil industries by producing sulfide, which is highly reactive, corrosive and toxic. The dissimilatory sulfite reductase ( dsr ) gene encodes for enzyme dissimilatory sulfite reductase and catalyzes the conversion of sulfite to sulfide. Because this gene is required by all sulfate reducers, it is a potential candidate as a functional marker. Denaturing gradient gel electrophoresis fingerprints revealed the presence of considerable genetic diversity in the DNA extracts achieved from production water collected from various oil fields. A quantitative PCR (qPCR) assay was developed for rapid and accurate detection of dsrB in oil field samples. A standard curve was prepared based on a plasmid containing the appropriate dsrB fragment from Desulfomicrobium norvegicum . The quantification range of this assay was six orders of magnitude, from 4.5 × 10⁷ to 4.5 × 10² copies per reaction. The assay was not influenced by the presence of foreign DNA. This assay was tested against several DNA samples isolated from formation water samples collected from geographically diverse locations of India. The results indicate that this qPCR approach can provide valuable information related to the abundance of the bisulfite reductase gene in harsh environmental samples.     

Multiplex qPCR for Detection and Absolute Quantification of Malaria

We describe development of an absolute multiplex quantitative real-time PCR for detection of Plasmodium spp., P. falciparum and P. vivax targets in order to produce an assay amenable to high throughput but with reduced costs. Important qPCR experimental details and information that is critical to performance and reliability of assay results were investigated. Inhibition studies were performed to test and compare co-purification of PCR inhibitors in samples extracted from whole blood using either the manual or automated methods. To establish the most optimal qPCR reaction volume, volume titration of the reaction master mix was performed starting at 10 µl to 1 µl reaction master mix with 1 µl of template DNA in each reaction. As the reaction volume decreased, qPCR assays became more efficient with 1 µl reaction master mix being the most efficient. For more accurate quantification of parasites in a sample, we developed plasmid DNAs for all the three assay targets for absolute quantification. All of absolute qPCR assays performed with efficiency of more than 94%, R² values greater than 0.99 and the STDEV of each replicate was <0.167. Linear regression plots generated from absolute qPCR assays were used to estimate the corresponding parasite density from relative qPCR in terms of parasite/µl. One copy of plasmid DNA was established to be equivalent to 0.1 parasite/µl for Plasmodium spp. assay, 0.281 parasites for P. falciparum assay and 0.127 parasite/µl for P. vivax assay. This study demonstrates for the first time use of plasmid DNA in absolute quantification of malaria parasite. The use of plasmid DNA standard in quantification of malaria parasite will be critical as efforts are underway to harmonize molecular assays used in diagnosis of malaria.     

A duplex real-time PCR assay for detection of drug-induced mitochondrial DNA depletion in HepG2 cells

Screening of drug-induced mitochondrial DNA (mtDNA) depletion during early preclinical drug development is of major interest. Here we describe the establishment of a novel duplex calibrator-normalized real-time polymerase chain reaction (PCR) assay for rapid and reliable quantification of mtDNA in HepG2 cells. This assay involves quantification of an mtDNA target gene (cytochrome b) relative to a nuclear DNA (nDNA) reference gene (β-actin) in one tube. The assay was evaluated for its precision, linearity, and reproducibility, and reliable detection of mtDNA depletion was demonstrated. Using this novel real-time PCR assay, drug-induced mtDNA depletion could be accurately detected.     

Detection and differentiation of coccidian oocysts by real-time PCR and melting curve analysis

Rapid and reliable detection and identification of coccidian oocysts are essential for animal health and foodborne disease outbreak investigations. Traditional microscopy and morphological techniques can identify large and unique oocysts, but they are often subjective and require parasitological expertise. The objective of this study was to develop a real-time quantitative PCR (qPCR) assay using melting curve analysis (MCA) to detect, differentiate, and identify DNA from coccidian species of animal health, zoonotic, and food safety concern. A universal coccidia primer cocktail was designed and employed to amplify DNA from Cryptosporidium parvum, Toxoplasma gondii, Cyclospora cayetanensis, and several species of Eimeria, Sarcocystis, and Isospora using qPCR with SYBR Green detection. MCA was performed following amplification, and melting temperatures (T(m)) were determined for each species based on multiple replicates. A standard curve was constructed from DNA of serial dilutions of T. gondii oocysts to estimate assay sensitivity. The qPCR assay consistently detected DNA from as few as 10 T. gondii oocysts. T(m) data analysis showed that C. cayetanensis, C. parvum, Cryptosporidium muris, T. gondii, Eimeria bovis, Eimeria acervulina, Isospora suis, and Sarcocystis cruzi could each be identified by unique melting curves and could be differentiated based on T(m). DNA of coccidian oocysts in fecal, food, or clinical diagnostic samples could be sensitively detected, reliably differentiated, and identified using qPCR with MCA. This assay may also be used to detect other life-cycle stages of coccidia in tissues, fluids, and other matrices. MCA studies on multiple isolates of each species will further validate the assay and support its application as a routine parasitology screening tool.     

A real‐time PCR assay for detection and quantification of Lactococcus garvieae

Aims: To develop a rapid, sensitive, specific tool for the detection and quantification of Lactococcus garvieae in food and environmental samples. Methods and Results: A real‐time quantitative PCR (qPCR) assay with primers for CAU12F and CAU12R based on the 16S rRNA gene of L. garvieae was successfully established. The limit of detection for L. garvieae genomic DNA was 1 ng DNA in conventional PCR and 32 fg with a mean C_T value of 36·75 in qPCR. Quantification of L. garvieae vegetative cells was linear (R² = 0·99) over a 7‐log‐unit dynamic range down to ten L. garvieae cells. Conclusions: This method is highly specific, sensitive and reproducible for the detection of L. garvieae compared to gel‐based conventional PCR assays, thus providing precise quantification of L. garvieae in food and natural environments. Significance and Impact of the Study: This work provides efficient diagnostic and monitoring tools for the rapid identification of L. garvieae, an emerging pathogen in aquaculture and an occasional human pathogen from other members of the genus Lactobacillus.     

Real-Time PCR Quantification of the Plant Growth Promoting Bacteria Herbaspirillum seropedicae Strain SmR1 in Maize Roots

The plant growth promoting bacteria Herbaspirillum seropedicae SmR1 is an endophytic diazotroph found in several economically important crops. Considering that methods to monitor the plant–bacteria interaction are required, our objective was to develop a real-time PCR method for quantification of PGPB H. seropedicae in the rhizosphere of maize seedlings. Primer pairs were designed, and their specificity was verified using DNA from 12 different bacterial species. Ten standard curves of qPCR assay using HERBAS1 primers and tenfold serial dilutions of H. seropedicae SmR1 DNA were performed, and PCR efficiency of 91 % and correlation coefficient of 0.99 were obtained. H. seropedicae SmR1 limit of detection was 10¹ copies (corresponding to 60.3 fg of bacterial DNA). qPCR assay using HERBAS1 was used to detect and quantify H. seropedicae strain SmR1 in inoculated maize roots, cultivated in vitro and in pots, harvested 1, 4, 7, and 10 days after inoculation. The estimated bacterial DNA copy number per gram of root was in the range 10⁷–10⁹ for plants grown in vitro and it was around 10⁶ for plants grown in pots. Primer pair HERBAS1 was able to quantify H. seropedicae SmR1, and this assay can be useful for monitoring plant–bacteria interaction.     

肠出血性大肠杆菌(O157：H7)的特异性荧光探针检测方法的建立

目的:建立一种real-time PCR,快速准确检测肠出血性大肠杆菌O157:H7。方法:以肠出血性大肠杆菌0157:H7 rfbE为待检靶基因,设计一对引物和一条Taqman探针,探针5’端用FAM基团标记,3’端用TAMRA标记。通过重组质粒的构建,建立并优化了大肠杆菌0157:H7的荧光定量PCR检测方法。结果:在人工污染样本无需富集的情况下,检测的最低DNA浓度是10拷贝/反应(3CFU/mL);特异性检测实验中,0157菌株检测结果均为rfbE阳性,而非0157:H7菌株检测结果均为阴性;重复性实验中,批内、批间变异系数均小于3%。结论:实验结果显示此荧光定量PCR方法特异性、灵敏度高,重复性好,可对分离的可疑大肠杆菌0157:H7菌株进行快速鉴定。