High-sensitivity stable-isotope probing by a quantitative terminal restriction fragment length polymorphism protocol

Stable-isotope probing (SIP) has proved a valuable cultivation-independent tool for linking specific microbial populations to selected functions in various natural and engineered systems. However, application of SIP to microbial populations with relatively minor buoyant density increases, such as populations that utilize compounds as a nitrogen source, results in reduced resolution of labeled populations. We therefore developed a tandem quantitative PCR (qPCR)-TRFLP (terminal restriction fragment length polymorphism) protocol that improves resolution of detection by quantifying specific taxonomic groups in gradient fractions. This method combines well-controlled amplification with TRFLP analysis to quantify relative taxon abundance in amplicon pools of FAM-labeled PCR products, using the intercalating dye EvaGreen to monitor amplification. Method accuracy was evaluated using mixtures of cloned 16S rRNA genes, DNA extracted from low- and high-G+C bacterial isolates (Escherichia coli, Rhodococcus, Variovorax, and Microbacterium), and DNA from soil microcosms amended with known amounts of genomic DNA from bacterial isolates. Improved resolution of minor shifts in buoyant density relative to TRFLP analysis alone was confirmed using well-controlled SIP analyses.     

Alternative PCR protocol using a single primer set for assessing DNA quality in several tissues from a large variety of mammalian species living in areas endemic for leishmaniasis

The aim of this work was to establish a modified pre-diagnostic polymerase chain reaction (PCR) protocol using a single primer set that enables successful amplification of a highly conserved mammalian sequence in order to determine overall sample DNA quality for multiple mammalian species that inhabit areas endemic for leishmaniasis. The gene encoding interphotoreceptor retinoid-binding protein (IRBP), but not other conserved genes, was efficiently amplified in DNA samples from tail skin, ear skin, bone marrow, liver and spleen from all of the species tested. In tissue samples that were PCR-positive for Leishmania, we found that DNA from 100%, 55% and 22% of the samples tested resulted in a positive PCR reaction for the IRBP, beta-actin and beta-globin genes, respectively. Nucleotide sequencing of an IRBP amplicon resolved any questions regarding the taxonomical classification of a rodent, which was previously based simply on the morphological features of the animal. Therefore, PCR amplification and analysis of the IRBP amplicon are suitable for pre-diagnostically assessing DNA quality and identifying mammalian species living in areas endemic to leishmaniasis and other diseases.     

Real-time PCR: approaches to data analysis (a review)

The registration of the accumulation of polymerase chain reaction (PCR) products in the course of amplification (real-time PCR) requires specific equipment, i.e., detecting amplifiers capable of recording the level of fluorescence in the reaction tube during amplicon formation. By the time the reaction is completed, researchers obtain DNA accumulation graphs. The review discusses the most promising algorithms of analysis of real-time PCR curves and possible errors, whether caused by the software used or the operators' mistakes. The data included will assist researchers in understanding the features of the method to obtain more reliable results.     

PCR amplification using electrolytic resistance for heating and temperature monitoring

An alternative method of rapid-cycle PCR for DNA amplification is demonstrated using electrolyte resistance for heating and temperature monitoring. The PCR amplification solution is electrically conductive and can be heated by passing an alternating current through the sample. The temperature of the solution is evaluated by monitoring its electrical resistance. Cooling is accomplished by forced air convection at ambient temperature. Heating and cooling rates of up to 20 degrees C/s were achieved. The 35 cycles of PCR were completed in less than 12 min with product yields equivalent to conventional temperature cycling. Electrolyte resistance provides a method for both direct heating and monitoring the temperature of PCR samples.     

High-level multiplex DNA amplification.

We present data on efficient amplification of large number of DNA targets using a single-tube polymerase chain reaction (PCR). This is a further enhancement of our approach to multiplexed PCR based on PCR suppression, which allows multiple DNA amplification using only one sequence-specific primer per amplicon while the second primer is common for all targets (Broude, N.E., et al., Proc. Natl. Acad. Sci. USA 98, 206-211, 2001). The reaction conditions have been optimized for simultaneous synthesis of 30 DNA targets, mostly consisting of fragments containing single nucleotide polymorphisms (SNP). The size of the amplified fragments, derived from many different human chromosomes, varies from 100 to 600 bp. We conclude that this method has potential for highly multiplexed DNA amplification useful for SNP analyses, DNA diagnostics, and forensics.     

Real-time PCR method for detection of pathogenic Yersinia enterocolitica in food

The current methods for the detection of pathogenic Yersinia enterocolitica bacteria in food are time consuming and inefficient. Therefore, we have developed and evaluated in-house a TaqMan probe-based real-time PCR method for the detection of this pathogen. The complete method comprises overnight enrichment, DNA extraction, and real-time PCR amplification. Also included in the method is an internal amplification control. The selected primer-probe set was designed to use a 163-bp amplicon from the chromosomally located gene ail (attachment and invasion locus). The selectivity of the PCR method was tested with a diverse range (n = 152) of related and unrelated strains, and no false-negative or false-positive PCR results were obtained. The sensitivity of the PCR amplification was 85 fg purified genomic DNA, equivalent to 10 cells per PCR tube. Following the enrichment of 10 g of various food samples (milk, minced beef, cold-smoked sausage, fish, and carrots), the sensitivity ranged from 0.5 to 55 CFU Y. enterocolitica. Good precision, robustness, and efficiency of the PCR amplification were also established. In addition, the method was tested on naturally contaminated food; in all, 18 out of 125 samples were positive for the ail gene. Since no conventional culture method could be used as a reference method, the PCR products amplified from these samples were positively verified by using conventional PCR and sequencing of the amplicons. A rapid and specific real-time PCR method for the detection of pathogenic Y. enterocolitica bacteria in food, as presented here, provides a superior alternative to the currently available detection methods and makes it possible to identify the foods at risk for Y. enterocolitica contamination.     

Multiplex PCR-based Alu insertion polymorphisms genotyping for identifying individuals of Japanese ethnicity

Discrimination of Alu insertions is a useful tool for geographic ancestry analysis, and is usually performed by Alu element amplification and agarose gel electrophoresis. Here, we have developed a new fluorescence-based method for multiple Alu genotyping in forensic identification. Allele frequencies were determined in 70 Japanese individuals, and we selected 30 polymorphic Alu insertions. Three primers were designed for each Alu locus to discriminate alleles using the 3-6 bp differences in amplicon sizes. Furthermore, we classified the amplification primers for the 30 loci into three different sets, and PCR using each set of primers provided 10 loci fragments ranging from 50 to 137 bp. Based on population data, the probability of incorrectly assigning a match was 3.7×10(-13). Three independent amplifications and subsequent capillary electrophoresis enabled the sensitive genotyping of small amounts of DNA, indicating that this method is suitable for identifying individuals of Japanese ethnicity.     

Profiling DNA methylation by melting analysis

The idea of modifying DNA with bisulfite has paved the way for a variety of polymerase chain reaction (PCR) methods for accurately mapping 5-methylcytosine at specific genes. Bisulfite selectively deaminates cytosine to uracil under conditions where 5-methylcytosine remains unreacted. Following conventional PCR amplification of bisulfite-treated DNA, original cytosines appear as thymine while 5-methylcytosines appear as cytosine. Because the relative thermostability of a DNA duplex increases with increasing content of G:C base pairs, PCR products originating from DNA templates with different contents of 5-methylcytosine differ in melting temperature, i.e., the temperature required to convert the double helix into random coils. We describe two methods that resolve differentially methylated DNA sequences on the basis of differences in melting temperature. The first method integrates PCR amplification of bisulfite-treated DNA and subsequent melting analysis by using a thermal cycler coupled with a fluorometer. By including in the reaction a PCR-compatible, fluorescent dye that specifically binds to double-stranded DNA, the melting properties of the PCR product can be examined directly in the PCR tube by continuous fluorescence monitoring during a temperature transition. The second method relies on resolution of alleles with different 5-methylcytosine contents by analysis of PCR products in a polyacrylamide gel containing a gradient of chemical denaturants. Optimal resolution of differences in melting temperature is achieved by a special design of PCR primers. Both methods allow resolution of "heterogeneous" methylation, i.e., the situation where the content and distribution of 5-methylcytosine in a target gene differ between different molecules in the same sample.     

Detection of periodontal pathogen Porphyromonas gingivalis by loop-mediated isothermal amplification method

A method for nucleic acid amplification, loop-mediated isothermal amplification (LAMP) was employed to develop a rapid and simple detection system for periodontal pathogen, Porphyromonas gingivalis. A set of six primers was designed by targeting the 16S ribosomal RNA gene. By the detection system, target DNA was amplified and visualized on agarose gel within 30 min under isothermal condition at 64 degrees C with a detection limit of 20 cells of P. gingivalis. Without gel electrophoresis, the LAMP amplicon was directly visualized in the reaction tube by addition of SYBR Green I for a naked-eye inspection. The LAMP reaction was also assessed by white turbidity of magnesium pyrophosphate (a by-product of LAMP) in the tube. Detection limits of these naked-eye inspections were 20 cells and 200 cells, respectively. Although false-positive DNA amplification was observed from more than 10(7) cells of Porphyromonas endodontalis, no amplification was observed in other five related oral pathogens. Further, quantitative detection of P. gingivalis was accomplished by a real-time monitoring of the LAMP reaction using SYBR Green I with linearity over a range of 10(2)-10(6) cells. The real-time LAMP was then applied to clinical samples of dental plaque and demonstrated almost identical results to the conventional real-time PCR with an advantage of rapidity. These findings indicate the potential usefulness of LAMP for detecting and quantifying P. gingivalis, especially in its rapidity and simplicity.     

Parallel DNA amplification by convective polymerase chain reaction with various annealing temperatures on a thermal gradient device

We present a thermal gradient convective polymerase chain reaction (PCR) for parallel DNA amplification with different annealing temperatures. The thermal gradient for microfluidic gradient PCR is produced by an innovative fin design whose formation principle is given. Without the need for a pump, the buoyancy forces continuously circulate reagents in a closed loop through different thermal zones, which brings self-actuated convective-flow PCR. In our prototype, we measured a temperature difference of about 45 °C along the gradient direction on the copper flake (45 × 40 × 4 mm). When the temperature of the hot zone is 90-97 °C and the temperature of the cold zone is 60-70 °C, the convection triggered two-temperature amplification of 112-bp fragment of Escherichia coli DNA. The time for amplification is less than 45 min. Interestingly, parallel DNA amplification with different annealing temperatures ranging from 60 to 70 °C was performed by this method. The PCR thermocycler demonstrated herein can be further scaled down and the loop length can be further reduced, and therefore the PCR times can be further reduced. These devices are suited as a platform for a new generation of low-power, portable DNA analysis systems.     

Real-time PCR: A review of approaches to data analysis

The registration of the accumulation of polymerase chain reaction (PCR) products in the course of amplification (real-time PCR) requires specific equipment, i.e., detecting amplifiers capable of recording the level of fluorescence in the reaction tube during amplicon formation. When the time of the reaction is complete, researchers are able to obtain DNA accumulation graphs. This review discusses the most promising algorithms of the analysis of real-time PCR curves and possible errors, caused by the software used or by operators’ mistakes. The data included will assist researchers in understanding the features of a method to obtain more reliable results.     

Antisense PCR: A simple and robust method for performing nested single-tube PCR

To overcome the disadvantages of two-round nested PCR, we developed a simple and robust closed single-tube nested PCR method (antisense PCR). The method uses antisense oligonucleotides that carry a 5′ tag and that can potentially hybridize to the 3′ ends of the outer primers, depending on the annealing temperature. During initial cycles, which are performed at a high annealing temperature, the antisense oligonucleotides do not hybridize and amplification is directed by the outer primers. During later cycles, for which the annealing temperature is decreased, the outer primers hybridize to the antisense oligonucleotides, extend to produce sequences that are mismatched to the amplicon templates, and consequently become inactivated, whereas the inner primers hybridize to the amplicon templates and continue amplification. Antisense quantitative PCR (qPCR) was compared with one-round qPCR for real-time amplification of four PCR targets (BCR, APC, N-RAS, and a rearranged IGH gene). It had equal amplification efficiency but produced much less nonspecific amplification. Antisense PCR enables both endpoint detection and real-time quantification. It can substitute for two-round nested PCRs but may also be applicable to instances of one-round PCR in which nonspecificity is a problem.     

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.     

A fast,highly sensitive double‐nested PCR‐based method to screen fish immunobiomes

Efficient methods for constructing 16S tag amplicon libraries for pyrosequencing are needed for the rapid and thorough screening of infectious bacterial diversity from host tissue samples. Here we have developed a double‐nested PCR methodology that generates 16S tag amplicon libraries from very small amounts of bacteria/host samples. This methodology was tested for 133 kidney samples from the lake whitefish Coregonus clupeaformis (Salmonidae) sampled in five different lake populations. The double‐nested PCR efficiency was compared with two other PCR strategies: single primer pair amplification and simple nested PCR. The double‐nested PCR was the only amplification strategy to provide highly specific amplification of bacterial DNA. The resulting 16S amplicon libraries were synthesized and pyrosequenced using 454 FLX technology to analyse the variation of pathogenic bacteria abundance. The proportion of the community sequenced was very high (Good’s coverage estimator; mean = 95.4%). Furthermore, there were no significant differences of sequence coverage among samples. Finally, the occurrence of chimeric amplicons was very low. Therefore, the double‐nested PCR approach provides a rapid, informative and cost‐effective method for screening fish immunobiomes and most likely applicable to other low‐density microbiomes as well.     

High‐resolution melt analysis without DNA extraction affords rapid genotype resolution and species identification

Extracting and sequencing DNA from specimens can impose major time and monetary costs to studies requiring genotyping, or identification to species, of large numbers of individuals. As such, so‐called direct PCR methods have been developed enabling significant savings at the DNA extraction step. Similarly, real‐time quantitative PCR techniques (qPCR) offer very cost‐effective alternatives to sequencing. High‐resolution melt analysis (HRM) is a qPCR method that incorporates an intercalating dye into a double‐stranded PCR amplicon. The dye fluoresces brightly, but only when it is bound. Thus, after PCR, raising the temperature of the amplicon while measuring the fluorescence of the reaction results in the generation of a sequence‐specific melt curve, allowing discrimination of genotypes. Methods combining HRM (or other qPCR methods) and direct PCR have not previously been reported, most likely due to concerns that any tissue in the reaction tube would interfere with detection of the fluorescent signal. Here, we couple direct PCR with HRM and, by way of three examples, demonstrate a very quick and cost‐effective method for genotyping large numbers of specimens, using Rotor‐Gene HRM instruments (QIAGEN). In contrast to the heated‐block design of most qPCR/HRM instruments, the Rotor‐Gene's centrifugal rotor and air‐based temperature‐regulation system facilitate our method by depositing tissues away from the pathway of the machine's fluorescence detection optics.     

Simple Detection of the IS6110 Sequence of Mycobacterium tuberculosis Complex in Sputum,Based on PCR with Graphene Oxide

Graphene oxide (GO) has proven to be a satisfactory DNA-sensor platform for applications in enzyme-free signal amplification, fluorescence-based amplification, and nanoparticle-based platforms because of its excellent electrical, thermal, and optical properties. In this study, we designed a novel platform for the fluorescence detection of biomolecules, using a fluorescent dye-labeled primer and GO. We applied this system for the detection of the IS6110 insertion sequence of the Mycobacterium tuberculosis complex (MTB) and evaluated its feasibility for use in molecular diagnostics. Fifty-four sputum specimens were collected at our institution from October 2010 to March 2012. To detect MTB in the samples, we performed PCR amplification of the IS6110 DNA sequence using FAM-labeled primers, after which the PCR amplicon was incubated with GO and the fluorescence was measured. The results were compared with those obtained by conventional real-time quantitative PCR (RQ-PCR). The fluorescence intensity observed increased in a concentration-dependent manner with the FAM-labeled IS6110 amplicon. The results of the PCR-GO system for detecting IS6110 DNA were in good agreement with those obtained with conventional RQ-PCR (kappa statistic = 0.925). The PCR-GO system detected MTB DNA in 23 of 25 RQ-PCR-positive sputum samples (92.0%; 95% CI, 75.0–98.0%), but not in 29 of 29 RQ-PCR-negative sputum samples (100%; 95% CI, 88.1–100.0%). These results indicate the utility of the PCR-GO system in molecular diagnostics.     

多重实时荧光PCR相对定量法快速诊断唐氏综合征

为了建立一种基于多重实时荧光相对定量PCR技术并应用之于唐氏综合征分子诊断, 选择21号染色体上唐氏综合征特异区域基因片段(DSCR3)为目的基因, 以12号染色体上的磷酸甘油醛脱氢酶基因(GAPDH)为参照基因, 设计合成两对引物以及分别以不同荧光标记的TaqMan探针, 在同一个反应管中进行扩增。以相对定量指标△CT值区分唐氏综合征患者与正常人。采用EB 病毒转化技术, 把唐氏综合征患者外周血B 淋巴细胞转化成永生淋巴母细胞系作为标准品。通过优化反应条件, 使得目的基因和参照基因的扩增效率基本一致, 接近100%, 模板浓度在3～300 ng/μL范围内, △CT值的变异系数小于15%, 浓度在30 ng/μL时, 变异系数最小(＜10%), 以该浓度的DNA作为模板进行批内和批间实验的△CT值重复性好, 变异系数分别为9.8%和13.3%。运用建立的方法检测20例唐氏综合征患者的血标本和30例正常人的血标本, 正常人△CT值范围是-1.90～-1.30, 患者的△CT值范围是-2.95～-2.15, 两组之间无交叉重叠, 有明显差异(P＜0.001)。唐氏综合征患者永生细胞系建系成功 ,染色体核型和DNA 分析表明建系前后遗传是稳定的。因此, 实时荧光定量PCR比较△CT值的相对定量法快速诊断唐氏综合征是可行的。     

Development of a simplified polymerase chain reactionenzyme immunoassay for the detection of Chlamydia pneumoniae

The 16S rRNA genes of two Chlamydia pneumoniae and two C. psittaci strains of different serovars were sequenced then compared to previously reported Chlamydia 16S rRNA gene sequences. Chlamydia pneumoniae -specific regions were identified and specific primers for nested PCR were synthesized. Nested PCR reactions were performed, in a single tube, by varying the annealing temperature of the amplification cycles. The initial thermal cycles were selected to allow annealing and extension of only the outer primer pair, whilst in later cycles a temperature that allowed inner primer annealing was employed. The inner primers were labelled, one with biotin and the other with fluorescein and consequently the dual labelled amplicon could be immobilized onto antibiotin-coated microtitre plates and detected colorimetrically via an antifluorescein-enzyme conjugate. The assay was found to be sensitive and specific. No cross reactions were observed with C. trachomatis, C. psittaci or other common respiratory pathogens.