Anisakis pegreffii: a quantitative fluorescence PCR assay for detection in situ

To facilitate improved diagnosis and detection of the third stage larva (L3) of Anisakis pegreffii from the Minnan-Taiwan bank fishing ground in Taiwan Strait, a real-time PCR method for the detection in situ and differentiation was developed to amplify a region of the second internal transcribed spacer (ITS-2) of this parasite. The real-time PCR assay was capable of detecting 1/3 of a single L3 in 30 mg of marine fish tissue, and also exhibited a high level of specificity for A. pegreffii, no fluorescence signals were observed in other five major larval anisakid species found in commercial marine fishes caught in this fishing ground.     

Real-time PCR assay for quantitative mismatch detection

We describe here a quantitative real-time PCR assay for the detection of single-base-pair differences that does not require fluorescently labeled gene-specific probes or complicated primer combinations. Following PCR or RT-PCR of a gene segment that may contain allele-specific differences, 100 pg amplified product are used for a real-time PCR with allele-specific primers and SYBR Green. The use of HEPES buffer at a pH of 6.95 together with AmpliTaq DNA polymerase results in a threshold difference between the correct template and the mismatched template of as many as 20 cycles, depending on the mismatch. Correct matches can be detected in an excess of mismatched template at least at the 0.01 level for the six primer-template matches versus mismatches tested: GC vs. A.C, AT vs. G.T, GC vs. C.C, GC vs. G.G, AT vs. C.T, and GC vs. G.A. Because the initial amplification is separate from real-time detection, conditions can be independently optimized for each step, making the assay particularly suitable for the detection of allele-specific expression in single cells.     

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.     

An assay for quantitative nucleic acid hybridization on membrane filters

A quantitative nucleic acid hybridization assay based on a 6-mm-diameter nitrocellulose membrane filter and only 20 microliters of hybridization mixture per determination is described. As a consequence of the small ratio of hybridization volume to membrane surface, the hybridization rates reached in this system are higher than those obtained at volume to surface ratios of conventional protocols, allowing even RNA at very low concentrations to complete hybridization. This advantage, together with the high reproducibility and hybrid stability obtained with the assay, increases the ability of the filter hybridization technique to analyze quantitatively minute amounts of RNA.     

A quantitative TaqMan PCR assay for the detection of Mycoplasma suis

Aim: To develop a TaqMan probe‐based, highly sensitive and specific quantitative PCR (qPCR) assay for the detection and quantification of Mycoplasma suis in the blood of pigs. Methods and Results: Primers and probes specific to Myc. suis 16S rRNA gene were designed. The qPCR assay’s specificity, detection limit, intra‐ and inter‐assay variability were evaluated and its performance was compared with a Myc. suis conventional PCR assay (cPCR). Blood of two experimentally infected pigs, 40 Indiana pigs, 40 Brazilian sows and 28 peccaries were tested. The assay detected as few as ten copies of Myc. suis plasmids and was 100‐fold more sensitive than the cPCR. No cross‐reactivity with nontarget pig mycoplasmas was observed. An average of 1·62 × 10¹¹ and 2·75 × 10⁸ target copies ml^?1 of blood were detected in the acutely and chronically infected pigs, respectively. Three (7·5%) pigs and 32 (80·0%) sows were positive while all peccaries were negative for Myc. suis. Conclusion: The developed qPCR assay is highly sensitive and specific for Myc. suis detection and quantification. Significance and Impact of the Study: TaqMan qPCR is an accurate and quick test for detection of Myc. suis infected pigs, which can be used on varied instrumentation platforms.     

A competitive PCR assay for quantitative detection of Neospora caninum

A quantitative-competitive PCR (QC-PCR) assay was developed for measurement of Neospora caninum levels in the tissues of infected animals. A molecule was synthesised for use in PCR as a competitor to the target Neospora-specific Nc5 genomic sequence. The assay was used to evaluate the relative level of parasites in the brain and lungs of mouse pups in a model of vertical transmission of N. caninum. Infection on day 11 of gestation resulted in similar levels of parasites in all offspring. The assay should be useful in evaluation of vaccines against Neospora infection. Incorporation of the competitor molecule in the detection assay also provides a control for PCR failure and facilitates identification of truly negative samples.     

PrimRglo: a multiplexable quantitative real-time polymerase chain reaction system for nucleic acid detection

We report the development of a new real-time polymerase chain reaction (PCR) detection system that uses oligonucleotide "tagged" PCR primers, a fluorophore-labeled "universal" detection oligonucleotides, and a complementary quenching oligonucleotide. The fluorescence signal decreases as PCR product accumulates due to the increase in detection/quencher hybrid formation as the tagged primer is consumed. We use plasmids containing the influenza A matrix gene and the porA and ctrA genes of Neisseria meningitidis as targets for developing the system. Cycle threshold (Ct) values were generated, and the sensitivity of the new system (dubbed "PrimRglo") compared favorably with the commonly used SYBR green and Taqman detection systems and, unlike the latter system, does not require the design of a new dual-labeled detection oligonucleotide for each new target sequence.     

Development and evaluation of a quantitative real-time PCR assay for the detection of saltwater Bacteriovorax

Bdellovibrio-and-like-organisms (BALOs) are small, Gram-negative predatory bacteria with the ability to prey on a wide variety of Gram-negative bacteria, and which may have a significant ecological role. Detection and quantification of BALOs by culture-dependent methods are complicated, as their reproduction is dependent upon the use of appropriate prey. For this reason, a sensitive and specific molecular detection method was developed. This paper describes a SYBR Green-based real-time PCR (quantitative PCR) assay that combines the use of a specific 16S rDNA primer with a universal primer for quantitative detection of halophilic Bacteriovorax. 16S rDNA sequences from 174 BALO strains, including both halophilic and freshwater, were aligned and a consensus region was identified that is unique to the halophilic Bacteriovorax strains. A specific primer was designed and analysed for specificity. The PCR conditions were optimized to obtain high specificity and sensitivity. The specificity was evaluated by testing a series of halophilic Bacteriovorax samples and prey specimens, including both pure cultures and environmental saltwater samples. A linear and reproducible standard curve was obtained over a range of 10(1)-10(6) gene copies and the detection limit was determined to be 10 copies of 16S rRNA gene per reaction. The results presented in this study validate the procedure as a rapid, sensitive and accurate method for the detection and quantification of halophilic Bacteriovorax in environmental saltwater samples. It is anticipated that this culture-independent method will facilitate future investigations of the distribution and population dynamics of these interesting predatory bacteria, leading to a better understanding of their ecological role.     

Adapting a conventional PCR assay for Toxoplasma gondii detection to real-time quantitative PCR including a competitive internal control

We have developed a quantitative PCR assay (LightCycler* using the pair of primers JW58 and JW59 for the detection of the 35-fold repeated B gene of oxoplasma gondii. This real-time PCR, using fluorescence resonance energy transfert (FRET) hybridization probes, allows the quantification of . gondii with several technical requirements not previously described: i) an internal amplification control (co-amplified in a single tube with the same primers), ii) Uracil-N-Glycosylase and iii) a standard curve corresponding to a serial dilution from a calibrated suspension of T. gondii ranging from 40 to 4.106( )parasites in one ml of amniotic fluid (1 to 105( ) . gondii/PCR). In artificial samples, one parasite could be detected if at least three reactions were performed.     

Novel bioluminescent quantitative detection of nucleic acid amplification in real-time

Background

The real-time monitoring of polynucleotide amplification is at the core of most molecular assays. This conventionally relies on fluorescent detection of the amplicon produced, requiring complex and costly hardware, often restricting it to specialised laboratories.

Principal Findings

Here we report the first real-time, closed-tube luminescent reporter system for nucleic acid amplification technologies (NAATs) enabling the progress of amplification to be continuously monitored using simple light measuring equipment. The Bioluminescent Assay in Real-Time (BART) continuously reports through bioluminescent output the exponential increase of inorganic pyrophosphate (PP_i) produced during the isothermal amplification of a specific nucleic acid target. BART relies on the coupled conversion of inorganic pyrophosphate (PP_i) produced stoichiometrically during nucleic acid synthesis to ATP by the enzyme ATP sulfurylase, and can therefore be coupled to a wide range of isothermal NAATs. During nucleic acid amplification, enzymatic conversion of PP_i released during DNA synthesis into ATP is continuously monitored through the bioluminescence generated by thermostable firefly luciferase. The assay shows a unique kinetic signature for nucleic acid amplifications with a readily identifiable light output peak, whose timing is proportional to the concentration of original target nucleic acid. This allows qualitative and quantitative analysis of specific targets, and readily differentiates between negative and positive samples. Since quantitation in BART is based on determination of time-to-peak rather than absolute intensity of light emission, complex or highly sensitive light detectors are not required.

Conclusions

The combined chemistries of the BART reporter and amplification require only a constant temperature maintained by a heating block and are shown to be robust in the analysis of clinical samples. Since monitoring the BART reaction requires only a simple light detector, the iNAAT-BART combination is ideal for molecular diagnostic assays in both laboratory and low resource settings.     

Species-specific DNA probe and development of a quantitative PCR assay for the detection of Morganella morganii

Aims: To develop a SYBR Green quantitative PCR assay (qPCR) for the specific detection of Morganella morganii, a fish pathogen responsible for the Histamine Fish Poisoning. Methods and Results: A new primer set, amplifying a 179‐bp fragment of the 16S rRNA gene, was selected for specificity, and 14 M. morganii strains and 32 non‐Morganella strains were evaluated. The melting temperature of 84°C was consistently specific for the amplicon. Two standard curves were constructed: the minimum detection sensitivity was 0·563 pg of pure DNA, corresponding to DNA extracted from nine cells of M. morganii. The qPCR assay was evaluated in experiments with seeded fish samples, and the regression coefficient values were calculated. Conclusions: A highly specific and rapid assay was developed for the detection of M. morganii in tuna fish samples. Significance and Impact of the Study: This method represents the first study about the quantification of pathogenic M. morganii in fish products. This approach can be utilized to prevent the presence of this undesirable species in the food chain.     

First LightCycler real-time PCR assay for the quantitative detection of Mycoplasma suis in clinical samples

Mycoplasma suis cannot be cultivated in vitro. Therefore, PCR-based methods are irreplaceable for the diagnosis of M. suis infections especially when clinical symptoms are not evident. Currently, no easy and reliable method allowing the quantitative detection of M. suis is available. This report describes the development of a quantitative LightCycler PCR assay based on the msg1 gene of M. suis (LC MSG1 PCR). No PCR signals were obtained with closely related haemotrophic and non-haemotrophic mycoplasmas, with other bacteria, and with M. suis-free blood and tissue arguing for a high analytical specificity. Test sensitivity was found to be 100%, and test specificity 96.7%. To test the diagnostic suitability of the LC MSG1 PCR, 25 pigs with clinical porcine eperythrozoonosis and 25 healthy pigs were investigated. All ill pigs revealed a positive real-time PCR result whereas only one healthy pig was detected to be M. suis-infected. M. suis was quantitatively detected in 19 blood specimens of 100 sows from Switzerland and in 17 of 160 post-weaning piglets from Germany. In conclusion, this new LC MSG1 PCR assay represents a powerful tool for the improvement of the current M. suis diagnosis and for prevalence and pathogenesis studies.     

Real-time nucleic acid sequence-based amplification assay for detection of hepatitis A virus

A nucleic acid sequence-based amplification (NASBA) assay in combination with a molecular beacon was developed for the real-time detection and quantification of hepatitis A virus (HAV). A 202-bp, highly conserved 5' noncoding region of HAV was targeted. The sensitivity of the real-time NASBA assay was tested with 10-fold dilutions of viral RNA, and a detection limit of 1 PFU was obtained. The specificity of the assay was demonstrated by testing with other environmental pathogens and indicator microorganisms, with only HAV positively identified. When combined with immunomagnetic separation, the NASBA assay successfully detected as few as 10 PFU from seeded lake water samples. Due to its isothermal nature, its speed, and its similar sensitivity compared to the real-time RT-PCR assay, this newly reported real-time NASBA method will have broad applications for the rapid detection of HAV in contaminated food or water.     

Presymptomatic and quantitative detection of Mycosphaerella graminicola development in wheat using a real-time PCR assay

Presymptomatic and accurate diagnosis of Mycosphaerella graminicola leaf blotch is desirable for the disease prediction and the timely application of fungicides. To develop a sensitive PCR assay, four specific primer pairs were designed. They were more specific than three known specific primer pairs. Three of them could detect as little as 0.5 pg M. graminicola DNA in a conventional PCR. A real-time PCR assay was applied for monitoring the disease progression in both inoculated and naturally infected wheat plants using the primer pair ST-rRNA F/R. In inoculated plants, M. graminicola DNA could be detected immediately after inoculation and a steady increase was detected before visible symptoms appeared at 8 days. The rapid growth period took place between 6 and 16 days postinoculation. In the field, the disease progression in the top three leaf layers was followed during the epidemic period. The results were significantly correlated to the disease indices (R=0.8986) and also to the number of pycnidia per leaf (R=0.9227). These suggest that the real-time PCR assay is a reliable approach for the presymptomatic and accurate detection of M. graminicola development in the field.     

Diagnosis of Indian visceral leishmaniasis by nucleic acid detection using PCR

Background

PCR based diagnosis for Visceral Leishmaniasis (VL), despite numerous published primers, remains far from being applied in the field. The present study was planned to design a Leishmania specific diagnostic assay and to evaluate its sensitivity and specificity on a sample size, which to the best of our knowledge is the largest ever screened in one study.

Methods

Leishmania specific primers were developed using 18S rRNA gene and their sensitivity was evaluated on 500 parasitologically confirmed patients with VL and 25 Post Kala-azar Dermal Leishmaniasis (PKDL) patients. Specificity was calculated on 250 healthy endemic controls, 250 healthy non endemic controls and 250 non leishmanial diseases like malaria.

Results

Our PCR assay had a sensitivity of 87.8% (95%CI: 84.1–89.8) using 200 µL of patient''s peripheral-blood. Specificity was absolute in non-endemic healthy controls and in subjects with different diseases while in endemic controls it was 84% (95%CI: 78.9–88.0). Its overall specificity was 94.6% (95%CI-92.8–96.1).

Conclusions

The PCR assay developed is sensitive enough to detect the 18S rRNA gene in an amount equivalent to a single parasite or less in a one million human cell environment. The high sensitivity of this PCR diagnostic test with relatively non-invasive peripheral blood sampling method opens up the possibility of its deployment in field for the routine diagnosis of VL.     

A nucleic acid sequence-based amplification assay for real-time detection of norovirus genogroup II

AIMS: To use molecular beacon based nucleic acid sequence-based amplification (NASBA) to develop a rapid, sensitive, specific detection method for norovirus (NV) genogroupII (GII). METHODS AND RESULTS: A method to detect NV GII from environmental samples using real-time NASBA was developed. This method was routinely sensitive to 100 copies of target RNA and intermittent amplification occurred with as few as 10 copies. Quantitative estimates of viral load were possible over at least four orders of magnitude. CONCLUSIONS: The NASBA method described here is a reliable and sensitive assay for the detection of NV. This method has the potential to be linked to a handheld NASBA device that would make this real-time assay a portable and inexpensive alternative to bench-top, lab-based assays. SIGNIFICANCE AND IMPACT OF THE STUDY: The development of the real-time NASBA assay described here has resulted in a simple, rapid (<1 h), convenient testing format for NV. To our knowledge, this is the first example of a molecular beacon based NASBA assay for NV.     

Competitive PCR for precise nucleic acid quantification

The exact quantification of tiny amounts of nucleic acids in biological samples continues to remain a requirement in both the experimental and the diagnostic laboratory. Competitive PCR involves the coamplification of a target DNA sample with known amounts of a competitor DNA that shares most of the nucleotide sequence with the target; in this way, any predictable or unpredictable variable affecting PCR amplification has the same effect on both molecular species. Competitive PCR therefore permits the quantification of the absolute number of target molecules in comparison to the amount of competitor DNA. Although requiring intensive post-PCR manipulation, the accuracy of competitive PCR by far exceeds that of any other quantitative PCR procedure, including real-time PCR. This protocol covers all stages in the competitive PCR and RT-PCR methods, from the design and construction of competitor molecules, and the competitive PCR itself, to the analysis of data and quantification of target DNA. Once the correct primers are available, the protocol can be completed in about 24 h.     

New molecular quantitative PCR assay for detection of host-specific Bifidobacteriaceae suitable for microbial source tracking

Bifidobacterium spp. belong to the commensal intestinal microbiota of warm-blooded animals. Some strains of Bifidobacterium show host specificity and have thus been proposed as host-specific targets to determine the origin of fecal pollution. Most strains have been used in microbial-source-tracking (MST) studies based on culture-dependent methods. Although some of these approaches have proved very useful, the low prevalence of culturable Bifidobacterium strains in the environment means that molecular culture-independent procedures could provide practical applications for MST. Reported here is a set of common primers and four Bifidobacterium sp. host-associated (human, cattle, pig, and poultry) probes for quantitative-PCR (qPCR) assessment of fecal source tracking. This set was tested using 25 water samples of diverse origin: urban sewage samples, wastewater from four abattoirs (porcine, bovine, and poultry), and water from a river with a low pollution load. The selected sequences showed a high degree of host specificity. There were no cross-reactions between the qPCR assays specific for each origin and samples from different fecal origins. On the basis of the findings, it was concluded that the host-specific qPCRs are sufficiently robust to be applied in environmental MST studies.     

Development of a TaqMan quantitative PCR assay specific for Cryptosporidium parvum

A rapid detection method that is both quantitative and specific for the water-borne human parasite Cryptosporidium parvum is reported. Real-time polymerase chain reaction (PCR) combined with fluorescent TaqMan technology was used to develop this sensitive and accurate assay. The selected primer-probe set identified a 138-bp section specific to a C. parvum genomic DNA sequence. The method was optimized on a cloned section of the target DNA sequence, then evaluated on C. parvum oocyst dilutions. Quantification was accomplished by comparing the fluorescence signals obtained from test samples of C. parvum oocysts with those obtained from standard dilutions of C. parvum oocysts. This real-time PCR assay allowed reliable quantification of C. parvum oocysts over six orders of magnitude with a baseline sensitivity of six oocysts in 2 h.