Non-gel based techniques for plant pathogen genotyping

The introduction of real-time PCR technology has significantly improved and simplified the quantification of nucleic acids, and this technology has become an invaluable tool for many scientists working in different disciplines. Particularly in the field of molecular diagnostics and genotyping, real-time PCR-based assays have gained favour in the recent past. Rapid real-time PCR diagnosis can result in appropriate control measures and eradication procedures in a faster and more accurate way than traditional methods based on pathogen isolation. Real-time quantitative PCR represents a highly sensitive and powerful technique for the gel-free detection of nucleic acids. In this review, the main chemistries used for the detection of PCR product during real-time PCR, as well as advantages and limitations of real-time PCR will be depicted. Furthermore, the existing literature as it applies to plant pathogens detection in the routine and research laboratory will be reviewed in order to focus on one of the many areas in which the application of real-time PCR has provided significant methodological benefits.     

Real-time PCR for mRNA quantitation

Real-time PCR has become one of the most widely used methods of gene quantitation because it has a large dynamic range, boasts tremendous sensitivity, can be highly sequence-specific, has little to no post-amplification processing, and is amenable to increasing sample throughput. However, optimal benefit from these advantages requires a clear understanding of the many options available for running a real-time PCR experiment. Starting with the theory behind real-time PCR, this review discusses the key components of a real-time PCR experiment, including one-step or two-step PCR, absolute versus relative quantitation, mathematical models available for relative quantitation and amplification efficiency calculations, types of normalization or data correction, and detection chemistries. In addition, the many causes of variation as well as methods to calculate intra- and inter-assay variation are addressed.     

47 Incorporation of alternative nucleic acid chemistries into G-quadruplex structure

Nucleic acids that form G-quadruplex (G4) structure have found applications in a host of research and technology regimes. Numerous G4 based aptamer drugs have been identified with pharmacological activity against cancer, HIV, prions, and blood coagulation (1). In the field of nanotechnology, G4 based sensors and nano-machines have also received much attention. The ability to synthesize nucleic acid ex-vivo allows for the site-specific incorporation of non-natural chemistries into nucleic acids that can be used to tune their physical and pharmacological properties. We summarize the results of a series of studies investigating the effective incorporation of alternative nucleic acid chemistries into G4 DNA. These modified chemistries include C8-modified guanine bases, as well as 2′-F, 2′-F-ANA, and Locked nucleic acid (LNA) modifications to the ribose sugar. We report primarily on the effect of these modifications on G-quadruplex folding topology, thermal stability, and structure. The substitution of LNA-guanosine into the core guanine tetrads disrupts structure in specific structural environments. On the other hand, 2′-F- and 2′-F-ANA guanosine can generally be incorporated without disrupting the structure when substituted into guanine bases in certain structural conformations. We find that 2′-F-ANA-guanosine and 2′-F-guanosine are powerful tools for controling the conformation of G4 structures (2). Functionalization at the C8 of the guanine base stabilizes in a manner dependent on the glycosidic conformation of the base, with different modification chemistries stabilizing to varying extents (3). The results of these studies provide useful insight on how to effectively incorporate some useful chemical tools from the growing toolbox of modified nucleic acid chemistries into G-quadruplex nucleic acid.     

High-sensitivity quantitative PCR platform

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

RTPrimerDB: the real-time PCR primer and probe database

The real-time polymerase chain reaction (PCR) methodology has become increasingly popular for nucleic acids detection and/or quantification. As primer/probe design and experimental evaluation is time-consuming, we developed a public database application for the storage and retrieval of validated real-time PCR primer and probe sequence records. The integrity and accuracy of the data are maintained by linking to and querying other reference databases. RTPrimerDB provides free public access through the Web to perform queries and submit user based information. Primer/probe records can be searched for by official gene symbol, nucleotide sequence, type of application, detection chemistry, LocusLink or Single Nucleotide Polymorphism (SNP) identifier, and submitter's name. Each record is directly linked to LocusLink, dbSNP and/or PubMed to retrieve additional information on the gene/SNP for which the primers/probes are designed. Currently, the database contains primer/probe records for human, mouse, rat, fruit fly and zebrafish, and all current detection chemistries such as intercalating dyes (SYBR Green I), hydrolysis probes (Taqman), adjacent hybridizations probes and molecular beacons. Real-time PCR primer/probe records are available at http://www.realtimeprimerdatabase.ht.st.     

Combining sequence-specific probes and DNA binding dyes in real-time PCR for specific nucleic acid quantification and melting curve analysis

Currently, in real-time PCR, one often has to choose between using a sequence-specific probe and a nonspecific double-stranded DNA (dsDNA) binding dye for the detection of amplified DNA products. The sequence-specific probe has the advantage that it only detects the targeted product, while the nonspecific dye has the advantage that melting curve analysis can be performed after completed amplification, which reveals what kind of products have been formed. Here we present a new strategy based on combining a sequence-specific probe and a nonspecific dye, BOXTO, in the same reaction, to take the advantage of both chemistries. We show that BOXTO can be used together with both TaqMan probes and locked nucleic acid (LNA) probes without interfering with the PCR. The probe signal reflect formation of target product, while melting curve analysis of the BOXTO signal reveals primer-dimer formation and the presence of any other anomalous products.     

Bacillus thuringiensis growth and toxicity

PCR-based amplification of nucleic acids has had a major impact in almost every field of basic research and has already found extensive applications in the area of clinical diagnosis. For many of these applications, quantitative data are sought to relate the quantity of amplified product to the amount of original target nucleic acid present in the sample. Since the PCR methodology with its exponential nature can be adapted for this purpose, a lot of different strategies have emerged in the last few years for sensitive and specific PCR product detection and quantification. Basic strategies, including the use of external and internal standards, are presented with respect to statistical aspects, and the advantages as well as the limitations of individual protocols are discussed. Furthermore the suitability of conventional laboratory techniques, such as gel systems or HPLC, nonradioactive labeling procedures, and the principles of advanced solid-phase-mediated strategies for the precise determination of amplification products, are outlined with the help of selected examples.     

Innovative tools for detection of plant pathogenic viruses and bacteria

Detection of harmful viruses and bacteria in plant material, vectors or natural reservoirs is essential to ensure safe and sustainable agriculture. The techniques available have evolved significantly in the last few years to achieve rapid and reliable detection of pathogens, extraction of the target from the sample being important for optimising detection. For viruses, sample preparation has been simplified by imprinting or squashing plant material or insect vectors onto membranes. To improve the sensitivity of techniques for bacterial detection, a prior enrichment step in liquid or solid medium is advised. Serological and molecular techniques are currently the most appropriate when high numbers of samples need to be analysed. Specific monoclonal and/or recombinant antibodies are available for many plant pathogens and have contributed to the specificity of serological detection. Molecular detection can be optimised through the automatic purification of nucleic acids from pathogens by columns or robotics. New variants of PCR, such as simple or multiplex nested PCR in a single closed tube, co-operative-PCR and real-time monitoring of amplicons or quantitative PCR, allow high sensitivity in the detection of one or several pathogens in a single assay. The latest development in the analysis of nucleic acids is micro-array technology, but it requires generic DNA/RNA extraction and pre-amplification methods to increase detection sensitivity. The advances in research that will result from the sequencing of many plant pathogen genomes, especially now in the era of proteomics, represent a new source of information for the future development of sensitive and specific detection techniques for these microorganisms.     

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.     

实时PCR技术在植物研究上的应用

实时PCR是在常规PCR基础上运用荧光共振能量转移现象,加入荧光标记探针,巧妙地把核酸扩增、杂交、光谱分析和实时检测技术结合在一起的一项新技术,具有快速、灵敏、特异性强、定量准确等特点,广泛应用于医学、检验检疫、军事、农业、基础研究等领域。着重就实时PCR技术的特性及在植物上的应用进行了讨论,并与目前常用的相关技术进行了比较。     

The power of real-time PCR

In recent years, real-time polymerase chain reaction (PCR) has emerged as a robust and widely used methodology for biological investigation because it can detect and quantify very small amounts of specific nucleic acid sequences. As a research tool, a major application of this technology is the rapid and accurate assessment of changes in gene expression as a result of physiology, pathophysiology, or development. This method can be applied to model systems to measure responses to experimental stimuli and to gain insight into potential changes in protein level and function. Thus physiology can be correlated with molecular events to gain a better understanding of biological processes. For clinical molecular diagnostics, real-time PCR can be used to measure viral or bacterial loads or evaluate cancer status. Here, we discuss the basic concepts, chemistries, and instrumentation of real-time PCR and include present applications and future perspectives for this technology in biomedical sciences and in life science education.     

Quantification using real-time PCR technology: applications and limitations

The introduction of real-time PCR technology has significantly improved and simplified the quantification of nucleic acids, and this technology has become an invaluable tool for many scientists working in different disciplines. Especially in the field of molecular diagnostics, real-time PCR-based assays have gained favour in the recent past. However, the wide use of real-time PCR methods has also highlighted some of the critical points and limitations of these assays. These aspects must be considered to increase the reliability of the obtained data.     

Processing of gene expression data generated by quantitative real-time RT-PCR

Quantitative real-time PCR represents a highly sensitive and powerful technique for the quantitation of nucleic acids. It has a tremendous potential for the high-throughput analysis of gene expression in research and routine diagnostics. However, the major hurdle is not the practical performance of the experiments themselves but rather the efficient evaluation and the mathematical and statistical analysis of the enormous amount of data gained by this technology, as these functions are not included in the software provided by the manufacturers of the detection systems. In this work, we focus on the mathematical evaluation and analysis of the data generated by quantitative real-time PCR, the calculation of the final results, the propagation of experimental variation of the measured values to the final results, and the statistical analysis. We developed a Microsoft Excel-based software application coded in Visual Basic for Applications, called Q-Gene, which addresses these points. Q-Gene manages and expedites the planning, performance, and evaluation of quantitative real-time PCR experiments, as well as the mathematical and statistical analysis, storage, and graphical presentation of the data. The Q-Gene software application is a tool to cope with complex quantitative real-time PCR experiments at a high-throughput scale and considerably expedites and rationalizes the experimental setup, data analysis, and data management while ensuring highest reproducibility.     

Locked nucleic acids for optimizing displacement probes for quantitative real-time PCR

Displacement probes have recently been described as a novel probe-based detection system for use in both quantitative real-time polymerase chain reaction (PCR) and single nucleotide polymorphism genotyping analysis. Previous reports have shown that shorter probes (23 mer) had improved detection sensitivity relative to longer probes (29 mer), with the likely reason for this effect being the improved hybridization kinetics of shorter probes. Sterically modified locked nucleic acids (LNAs) have been used to improve the design of a range of real-time PCR probes by raising the melting temperature (Tm) of the probe and enabling shorter probe designs to be considered. A displacement probe for gapdh was designed and tested successfully, and this probe was then redesigned with LNAs to an 11 mer probe. This probe showed increased detection sensitivity compared with the original 26 mer probe. To detect the widest range of displacement probe designs at maximum sensitivity, we have also developed a novel fluorescence capture two-step PCR protocol. This method produces enhanced probe quenching with a single standardized protocol ideal for high-throughput applications. The displacement probes tested produced sensitive and efficient quantitative analyses of template serial dilutions when compared with a range of commercially available predesigned real-time PCR detection systems, including TaqMan MGB probes, QuantiTect MGB probes, and LUX primers.     

Improved real-time PCR estimation of gene copy number in soil extracts using an artificial reference

Application of polymerase chain reaction (PCR) techniques has developed significantly from a qualitative technology to include powerful quantitative technologies, including real-time PCR, which are regularly used for detection and quantification of nucleic acids in many settings, including community analysis where culture-based techniques are not suitable. Many applications of real-time PCR involve absolute quantification which is susceptible to inaccuracies caused by losses during DNA extraction or inhibition caused by co-extracted compounds. We present here an improvement to this approach involving the addition of an artificial internal standard, prior to nucleic acid extraction. The standard was generated by in-situ mutagenesis from an E. coli template to ensure it both did not amplify with bacterial primers used for quantification and was short enough to minimise possible interference with other analyses. By estimating gene target copies by relative abundance, this approach accounts for both loss during extraction and inhibition effects. We present a novel application of relative real time PCR, using the internal standard as a reference, allowing accurate estimation of total bacterial populations both within and across a wide range of soils and demonstrate its improvement over absolute quantification by comparison of both approaches to ester linked fatty acid analysis of the same soils.     

PCR增强剂在核酸体外扩增检测技术的研究进展

在各种高致病性病原体、禽流感病毒、食源性微生物等引起的疾病随时大规模流行的背景下,利用聚合酶链式反应（polymerase chain reaction,PCR）技术对第一例或第一波病例的快速实验室诊断显得尤为重要,同时发展出多种以PCR技术为基础的检测技术以便更加快速、高通量、敏感地对疾病进行诊断、预防或预测。然而,在实际病原体检测中,常常出现灵敏度低、准确性差的结果。PCR增强剂是在PCR及PCR衍生技术中添加的一类物质,其可从产率、特异性、灵敏度等方面提高核酸扩增性能,从而优化核酸检测,解决病原体检测的应用瓶颈,为第一例病原体检出节约宝贵的时间。结合以PCR为基础的核酸体外扩增检测技术对PCR增强剂在其中的应用、优缺点、作用机理进行介绍,以期为病原体核酸检测的实际应用提供一些参考。     

Comparison of nucleic acid extraction platforms for detection of select biothreat agents for use in clinical resource limited settings

High-quality nucleic acids are critical for optimal PCR-based diagnostics and pathogen detection. Rapid sample processing time is important for the earliest administration of therapeutic and containment measures, especially in the case of biothreat agents. In this context, we compared the Fujifilm QuickGene-Mini80 to Qiagen's QIAamp Mini Purification kits for extraction of DNA and RNA for potential use in austere settings. Qiagen (QIAamp) column-based extraction is the currently recommended purification platform by United States Army Medical Research Institute for Infectious Diseases for both DNA and RNA extraction. However, this sample processing system requires dedicated laboratory equipment including a centrifuge. In this study, we investigated the QuickGene-Mini80, which does not require centrifugation, as a suitable platform for nucleic acid extraction for use in resource-limited locations. Quality of the sample extraction was evaluated using pathogen-specific, real-time PCR assays for nucleic acids extracted from viable and γ-irradiated Bacillus anthracis, Yersinia pestis, vaccinia virus, Venezuelan equine encephalitis virus, or B. anthracis spores in buffer or human whole blood. QuickGene-Mini80 and QIAamp performed similarly for DNA extraction regardless of organism viability. It was noteworthy that γ-irradiation did not have a significant impact on real-time PCR for organism detection. Comparison with QIAamp showed a less than adequate performance of the Fujifilm instrument for RNA extraction. However, QuickGene-Mini80 remains a viable alternative to QIAamp for DNA extraction for use in remote settings due to extraction quality, time efficiency, reduced instrument requirements, and ease of use.     

Discrimination of viable Acanthamoeba castellani trophozoites and cysts by propidium monoazide real-time polymerase chain reaction

Even though the advent of quantitative polymerase chain reaction (PCR) has improved the detection of pathogen microorganisms in most of areas of microbiology, a serious limitation of this method may arise from the inability to discriminate between viable and nonviable pathogens. To overcome it, the use of real-time PCR and selective nucleic acid intercalating dyes like propidium monoazide (PMA) have been effectively evaluated for different microorganisms. To assess whether PMA pretreatment can inhibit PCR amplification of nonviable amoeba DNA, Acanthamoeba castellani survival was measured using cell culture and real-time PCR with and without PMA pretreatment. Autoclave and contact lens disinfecting solutions were used to inactivate amoebae. After these inactivation treatments, the results indicated that the PMA pretreatment approach is appropriate for differentiating viable A. castellani, both trophozoites and cysts. Therefore, the PMA-PCR approach could be useful as a rapid and sensitive analytical tool for monitoring treatment and disease control, assessing effective disinfection treatments, and for a more reliable understanding of the factors that contribute to the interaction amoeba-pathogenic bacteria.     

癌症液体活检新思路：数字PCR检测DNA甲基化

癌症的早期诊断可提高患者生存率.微创采集人体体液的液体活检方法可避免传统肿瘤组织活检方法侵入性和异质性的问题,逐渐成为癌症诊断的新方式.另外,DNA甲基化作为预测癌症发生发展的标志物,引起了越来越多研究者的关注.但传统DNA甲基化的检测方法灵敏度不高,且容易出现假阳性.近年来,数字PCR技术因其超高的检测灵敏度和精确度、无需标准曲线即可进行核酸绝对定量检测的优势,被用于DNA甲基化的定量检测中.本文首先介绍了DNA甲基化与癌症发生发展的关系,总结了传统DNA甲基化检测方法及其在癌症临床诊断中的应用,阐述了基于不同核酸样本分散方法的数字PCR技术及其在微量DNA甲基化检测中的优势,总结了采用数字PCR技术检测癌症患者体液中DNA甲基化的具体步骤,列举了数字PCR技术在癌症DNA甲基化检测中的研究成果及应用进展,最后提出了数字PCR技术检测癌症DNA甲基化未来可能面临的挑战,并对数字PCR技术在癌症液体活检方面的应用前景进行了展望.