Color multiplexing hybridization probes using the apolipoprotein E locus as a model system for genotyping.

Fluorescent hybridization probes were multiplexed for color genotyping of the apolipoprotein E locus using model oligonucleotide targets. Fluorescence resonance energy transfer was observed during adjacent hybridization of 3'-fluorescein-labeled "donor" probes paired with 5'-labeled "acceptor" probes with different emission spectra reporting at codons 112 and 158. The acceptor dyes emitted at either 640 nm (LightCycler Red 640) or 705 nm (LightCycler Red 705) and were monitored with a LightCycler, a thermal cycler with an integrated fluorimeter. The color of the acceptor dye identified each site and the characteristic melting temperatures of the fluorescein-labeled probes identified single base changes within each codon. Color compensation of temperature-dependent spectral overlap was applied to completely separate each channel. Competition between the probes and the complementary strand for the target sequence decreased resonance energy transfer, indicating an advantage of single-stranded target. Hybridization probes of the same length, but different GC content are T(m) shifted by the same amount during A:C mismatch duplex melting. Genotyping was optimal at both sites if melting curve analysis was preceded by a slow (1 degrees C/s) annealing phase. Although each site preferred different concentrations of Mg(2+) and target strand for optimal genotyping, conditions for multiplexing were found. This method, along with an appropriate amplification technique, should allow real-time multiplex genotyping from genomic DNA.     

Multiplex fluorescence melting curve analysis for mutation detection with dual-labeled, self-quenched probes

Probe-based fluorescence melting curve analysis (FMCA) is a powerful tool for mutation detection based on melting temperature generated by thermal denaturation of the probe-target hybrid. Nevertheless, the color multiplexing, probe design, and cross-platform compatibility remain to be limited by using existing probe chemistries. We hereby explored two dual-labeled, self-quenched probes, TaqMan and shared-stem molecular beacons, in their ability to conduct FMCA. Both probes could be directly used for FMCA and readily integrated with closed-tube amplicon hybridization under asymmetric PCR conditions. Improved flexibility of FMCA by using these probes was illustrated in three representative applications of FMCA: mutation scanning, mutation identification and mutation genotyping, all of which achieved improved color-multiplexing with easy probe design and versatile probe combination and all were validated with a large number of real clinical samples. The universal cross-platform compatibility of these probes-based FMCA was also demonstrated by a 4-color mutation genotyping assay performed on five different real-time PCR instruments. The dual-labeled, self-quenched probes offered unprecedented combined advantage of enhanced multiplexing, improved flexibility in probe design, and expanded cross-platform compatibility, which would substantially improve FMCA in mutation detection of various applications.     

Detection of nitrifying bacteria in activated sludge by fluorescent in situ hybridization and fluorescence spectrometry

16S rRNA-targeted oligonucleotide probes for eubacteria (EUB338), ammonium-oxidizing bacteria (Nsm156) and nitrite-oxidizing bacteria (Nb1000) were used for the rapid detection of nitrifying bacteria in the activated sludge of a pilot nitrifying reactor by whole-cell, fluorescent in situ hybridization (FISH). Emission scanning and synchronous scanning fluorescence spectrometry were used to measure the hybridization. The binding of the probes at a temperature significantly lower than the melting temperature of the hybrids was conventionally considered as non-specific. Total binding of the probes at a temperature significantly higher than the melting temperature of the hybrids was conventionally considered as the sum of non-specific and specific binding (hybridization). Non-specific binding of the oligonucleotide probes with a biomass of activated sludge was 37% of the total binding of the EUB338 probe, 54% of the total binding of the Nsm156 probe, and 69% of the total binding of the Nb1000 probe. The ratio of the specific binding of the Nsm156 and Nb1000 probes was 2.3:1. The ratio of the numbers of ammonium-oxidizing bacteria to nitrite-oxidizing bacteria, determined by microbiological methods, was 2.4:1. Measuring fluorescent in situ hybridization by fluorescence spectrometry appears to be a practical tool for monitoring the microbial communities that contain nitrifying bacteria. However, a method that accounts for the non-specific binding of the probes more easily and reliably should be developed for practical application.     

Eprobe Mediated Real-Time PCR Monitoring and Melting Curve Analysis

Real-time monitoring of PCR is one of the most important methods for DNA and RNA detection widely used in research and medical diagnostics. Here we describe a new approach for combined real-time PCR monitoring and melting curve analysis using a 3′ end-blocked Exciton-Controlled Hybridization-sensitive fluorescent Oligonucleotide (ECHO) called Eprobe. Eprobes contain two dye moieties attached to the same nucleotide and their fluorescent signal is strongly suppressed as single-stranded oligonucleotides by an excitonic interaction between the dyes. Upon hybridization to a complementary DNA strand, the dyes are separated and intercalate into the double-strand leading to strong fluorescence signals. Intercalation of dyes can further stabilize the DNA/DNA hybrid and increase the melting temperature compared to standard DNA oligonucleotides. Eprobes allow for specific real-time monitoring of amplification reactions by hybridizing to the amplicon in a sequence-dependent manner. Similarly, Eprobes allow for analysis of reaction products by melting curve analysis. The function of different Eprobes was studied using the L858R mutation in the human epidermal growth factor receptor (EGFR) gene, and multiplex detection was demonstrated for the human EGFR and KRAS genes using Eprobes with two different dyes. Combining amplification and melting curve analysis in a single-tube reaction provides powerful means for new mutation detection assays. Functioning as “sequence-specific dyes”, Eprobes hold great promises for future applications not only in PCR but also as hybridization probes in other applications.     

Fluorescence-based temperature control for polymerase chain reaction

The ability to accurately monitor solution temperature is important for the polymerase chain reaction (PCR). Robust amplification during PCR is contingent on the solution reaching denaturation and annealing temperatures. By correlating temperature to the fluorescence of a passive dye, noninvasive monitoring of solution temperatures is possible. The temperature sensitivity of 22 fluorescent dyes was assessed. Emission spectra were monitored and the change in fluorescence between 45 and 95 °C was quantified. Seven dyes decreased in intensity as the temperature increased, and 15 were variable depending on the excitation wavelength. Sulforhodamine B (monosodium salt) exhibited a fold change in fluorescence of 2.85. Faster PCR minimizes cycling times and improves turnaround time, throughput, and specificity. If temperature measurements are accurate, no holding period is required even at rapid speeds. A custom instrument using fluorescence-based temperature monitoring with dynamic feedback control for temperature cycling amplified a fragment surrounding rs917118 from genomic DNA in 3 min and 45 s using 35 cycles, allowing subsequent genotyping by high-resolution melting analysis. Gold-standard thermocouple readings and fluorescence-based temperature differences were 0.29 ± 0.17 and 0.96 ± 0.26 °C at annealing and denaturation, respectively. This new method for temperature cycling may allow faster speeds for PCR than currently considered possible.     

Evaluation of quantification methods for real-time PCR minor groove binding hybridization probe assays

Real-time PCR data analysis for quantification has been the subject of many studies aimed at the identification of new and improved quantification methods. Several analysis methods have been proposed as superior alternatives to the common variations of the threshold crossing method. Notably, sigmoidal and exponential curve fit methods have been proposed. However, these studies have primarily analyzed real-time PCR with intercalating dyes such as SYBR Green. Clinical real-time PCR assays, in contrast, often employ fluorescent probes whose real-time amplification fluorescence curves differ from those of intercalating dyes. In the current study, we compared four analysis methods related to recent literature: two versions of the threshold crossing method, a second derivative maximum method, and a sigmoidal curve fit method. These methods were applied to a clinically relevant real-time human herpes virus type 6 (HHV6) PCR assay that used a minor groove binding (MGB) Eclipse hybridization probe as well as an Epstein-Barr virus (EBV) PCR assay that used an MGB Pleiades hybridization probe. We found that the crossing threshold method yielded more precise results when analyzing the HHV6 assay, which was characterized by lower signal/noise and less developed amplification curve plateaus. In contrast, the EBV assay, characterized by greater signal/noise and amplification curves with plateau regions similar to those observed with intercalating dyes, gave results with statistically similar precision by all four analysis methods.     

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.     

Chromosomal mapping of the major and minor ribosomal genes, (GATA)n and (TTAGGG)n by one-color and double-color FISH in the toadfish Halobatrachus didactylus (Teleostei: Batrachoididae)

The karyotype of Halobatrachus didactylus presents 46 chromosomes, composed of eight metacentric, 18 submetacentric, four subtelocentric, and 16 acrocentric chromosomes. The results of FISH showed that the major ribosomal genes were located in the terminal position of the short arm of a large submetacentric chromosome. They also showed a high variation in the hybridization signals. The products of amplification of 5S rDNA produced bands of about 420 pb. The PCR labeled products showed hybridization signals in the subcentromeric position of the long arm of a submetacentric chromosome of medium size. Double-color FISH indicated that the two ribosomal families are not co-located since they hybridizated in different chromosomal pairs. Telomeres of all the chromosomes hybridized with the (TTAGGG) _n probe. The GATA probe displayed a strong signal in the long arm of a submetacentric chromosome of medium size, in the subcentromeric position. The double-color FISH showed that the microsatellite GATA and the 5S rDNA gene are located in different chromosomal pairs. The majority presence of GATA probes in one pair of chromosomes is unusual and considering its distribution through different taxa it could be due to evolutionary mechanisms of heterochromatine accumulation, leading to the formation of differentiated sex chromosomes.     

Characterization and application of soybean YACs to molecular cytogenetics

Yeast artificial chromosomes (YACs) are widely used in the physical analysis of complex genomes. In addition to their value in chromosome walking for map-based cloning, YACs represent excellent probes for chromosome mapping using fluorescence in situ hybridization (FISH). We have screened such a library for low-copy-number clones by hybridization to total genomic DNA. Four clones were chosen for chromosome tagging based upon their low or moderate signal. By using degenerate oligonucleotide-primed PCR (DOP-PCR), we were able to use relatively small amounts of soybean YAC DNA, isolated directly by preparative pulsed-field gel electrophoresis, as FISH probes for both metaphase chromosome spreads and interphase nuclei. FISH chromosomal analysis using the three of the clones as probes resulted in relatively simple hybridization patterns consistent with a single homologous locus or two homoeologous loci. The fourth YAC probe resulted in a diffuse hybridization pattern with signal on all metaphase chromosomes. We conclude that YACs represent a valuable source of probes for chromosomal analysis in soybean.     

Detection of Legionella species in potting mixes using fluorescent in situ hybridisation (FISH)

This study used Fluorescent in situ Hybridisation (FISH) with rRNA targeted oligonucleotide probes combined with scanning confocal laser microscopy to successfully detect Legionella spp. in commercially available potting mix. A range of techniques were explored to optimise the FISH method by reducing background fluorescence and preventing non-specific binding of probes. These techniques included the use of a blocking agent, UV light treatment, image subtraction of a nonsense probe and spectral unmixing of specific probes fluorescence and autofluorescence dependent on the specific emission spectra of probe fluorophores.Spectral unmixing was the best microscopy technique for reducing background fluorescence and non-specific binding of probes was not observed. The rapid turnaround time and increased sensitivity of the FISH provides as an alternative to traditional culture methods, which are tedious and often give varied results. FISH is also advantageous compared to PCR methods as it provides information on the structure of the microbial community the bacteria is situated in. This study demonstrates that FISH could provide an alternative method for Legionella detection and enumeration in environmental samples.     

Minor groove binder-conjugated DNA probes for quantitative DNA detection by hybridization-triggered fluorescence

Here we describe the properties of a novel class of oligonucleotide probes capable of sensitive hybridization-triggered fluorescence. These fluorogenic probes, known commercially as MGB Eclipse probes, are characterized by having a conjugated minor groove binder (MGB) ligand at the 5'-end and a fluorophore at the 3'-end. Additionally, they have an efficient quencher moiety at the 5'-end that is useful with a wide variety of fluorescent dyes. Fluorescence of the single-stranded MGB Eclipse probe is efficiently quenched by the interaction of the terminal dye and quencher groups when not hybridized. Upon hybridization to a complementary target, the MGB molecule folds into duplex and hyper-stabilizes it, allowing the use of shorter, more specific probe sequences. The 5'-MGB-quencher group also prevents nuclease digestion by Taq DNA polymerase during PCR. Because of the hybridization-triggered fluorescence and the excellent specificity imparted by the MGB, these 5'-MGB Eclipse probes have great versatility for real-time PCR applications. The high sensitivity and specificity are illustrated using single nucleotide polymorphism detection, viral load determination, and gene expression analysis.     

重要肠道病原菌多重PCR-基因芯片检测方法研究

目的:建立并初步评价一种针对重要肠道病原菌的多重PCR 基因芯片检测方法。方法：对筛选出的特异引物进行多重PCR优化,将引物分别按种属内混合和种属间混合的方案排查引物间的竞争性抑制现象,再将不同菌属的模板混合,用相对应的混合引物扩增,探寻高效特异的引物组合。分别掺入和不掺入荧光素,验证其对混合PCR反应的影响,并与芯片杂交,探寻多重PCR扩增效率对芯片杂交的影响。分析不同数量引物组合产生的杂交结果,筛选出无交叉反应的最优引物组合。结果:种属内引物混合均得到特异性扩增结果。种属间混合霍乱弧菌和空肠弯曲菌得到部分预期条带,随着混合引物数量的增加,交叉抑制现象也增多。杂交信号强度随多重PCR扩增效率的增加而增强。反应中掺入荧光素的扩增条带产量低于无荧光素的产物。可将35对混合引物拆成3个体系分别标记样品,以避免假阴性结果。结论:PCR反应中掺入荧光素降低扩增效率和杂交效率,但并不影响对杂交结果的判读和数据分析。基因芯片杂交信号强度取决于多重PCR的扩增效率。肠道病原菌多重PCR 基因芯片检测方法具有较高的特异性,混合PCR可以分别按照种属内和种属间的引物组合方案用于多病原的筛检。该基因芯片检测可以采用3个引物体系完成样品标记。     

Seven-color, homogeneous detection of six PCR products.

We describe an extension of the fluorogenic PCR 5'-nuclease assay, or "Taq-Man" assay. Sequence-specific probes consisted of a novel nonfluorescent quencher, nitrothiazole blue (NTB), at the 3' terminus and six different reporter dyes at the 5' terminus. The six reporters were 6-FAM, dR110, dR6G, dTMR, dROX and JAZ dyes. The seventh color was from aluminum phthalocyanine tetrasulfonate and was utilized as a "passive reference" to calibrate concentration variations. Our test system was a set of three single-nucleotide polymorphisms (SNPs). Each SNP system consisted of two primers and two sequence-specific probes, each labeled with a different reporter dye and NTB. Following PCR, the reactions were diluted with water and measured in a microcuvette on a luminescence spectrometer in synchronous scanning mode. In this method, both the excitation and emission wavelengths were scanned, with a fixed wavelength difference (delta gamma) between excitation and emission wavelengths. The spectral overlap in the set was evaluated by calculation of the condition number of the 7 x 7 matrix (dye fluorescence vs. wavelength). The small value of the condition number (1.5) proved that the cross-talk between the dyes was minimal. SNP analyses of known, synthetic target sequences and genomic DNA were plotted both as normalized, subtracted spectra and as data points in three separate dot plots.     

Humic substances cause fluorescence inhibition in real-time polymerase chain reaction

Real-time polymerase chain reaction (qPCR) is the cornerstone of DNA analysis, enabling detection and quantification of minute nucleic acid amounts. However, PCR-based analysis is limited, in part, by the presence of inhibitors in the samples. PCR inhibition has been viewed solely as failure to efficiently generate amplicons, that is, amplification inhibition. Humic substances (HS) are well-known inhibitors of PCR amplification. Here we show that HS from environmental samples, specifically humic acid (HA), are very potent detection inhibitors, that is, quench the fluorescence signal of double-stranded DNA (dsDNA) binding dyes. HA quenched the fluorescence of the commonly used qPCR dyes EvaGreen, ResoLight, SYBR Green I, and SYTO 82, generating lowered amplification plots, although amplicon production was unaffected. For EvaGreen, 500 ng of HA quenched nearly all fluorescence, whereas 1000 ng of HA completely inhibited amplification when applying Immolase DNA polymerase with bovine serum albumin (BSA). Fluorescence spectroscopy measurements showed that HA quenching was either static or collisional and indicated that HA bound directly to the dye. Fulvic acid did not act as a qPCR detection inhibitor but inhibited amplification similarly to HA. Hydrolysis probe fluorescence was not quenched by HA. Detection inhibition is an overlooked phenomenon that needs to be considered to allow for development of optimal qPCR assays.     

Use of a fluorogenic probe in a PCR-based assay for the detection of Listeria monocytogenes.

A PCR-based assay for Listeria monocytogenes that uses the hydrolysis of an internal fluorogenic probe to monitor the amplification of the target has been formatted. The fluorogenic 5' nuclease PCR assay takes advantage of the endogenous 5' --> 3' nuclease activity of Taq DNA polymerase to digest a probe which is labelled with two fluorescent dyes and hybridizes to the amplicon during PCR. When the probe is intact, the two fluorophores interact such that the emission of the reporter dye is quenched. During amplification, the probe is hydrolyzed, relieving the quenching of the reporter and resulting in an increase in its fluorescence intensity. This change in reporter dye fluorescence is quantitative for the amount of PCR product and, under appropriate conditions, for the amount of template. We have applied the fluorogenic 5' nuclease PCR assay to detect L. monocytogenes, using an 858-bp amplicon of hemolysin (hlyA) as the target. Maximum sensitivity was achieved by evaluating various fluorogenic probes and then optimizing the assay components and cycling parameters. With crude cell lysates, the total assay could be completed in 3 h with a detection limit of approximately 50 CFU. Quantification was linear over a range of 5 x 10(1) to 5 x 10(5) CFU.     

Identification of N-acetyltransferase 2 genotypes by continuous monitoring of fluorogenic hybridization probes.

Three polymorphic sites in the N-acetyltransferase 2 (NAT2) gene were detected using rapid cycle DNA amplification with allele-specific fluorescent probes and melting curve analysis. Two fluorogenic adjacent hybridization probes were designed to NAT2*5A (C(481)T), NAT2*6A (G(590)A), and NAT2*7A (G(857)A). During amplification, probe hybridization is observed as fluorescence resonance energy transfer. The fluorescence increases every cycle as the product accumulates during amplification. A single base mismatch resulted in a melting temperature shift (T(m)) of 5 to 6 degrees C, allowing for the easy distinction of a wild-type allele from the mutant allele. The protocol is rapid, requiring 40 min for the completion of 45 cycles including the melting curves. It is also a simple and flexible method, since DNA templates prepared from different sources, including DNA from serum and paraffin-embedded tissue sections, could be used without adverse effects. Fluorescence genotyping of all three polymorphisms in a total of 155 DNA samples correlated perfectly with our previously validated genotyping by restriction enzyme digestion (PCR-RFLP). This new facile approach allows for the easy detection of NAT2 polymorphisms in hundreds of samples in only a day.     

Real-time PCR detection of Brucella abortus: a comparative study of SYBR green I, 5'-exonuclease,and hybridization probe assays

Real-time PCR provides a means of detecting and quantifying DNA targets by monitoring PCR product accumulation during cycling as indicated by increased fluorescence. A number of different approaches can be used to generate the fluorescence signal. Three approaches-SYBR Green I (a double-stranded DNA intercalating dye), 5'-exonuclease (enzymatically released fluors), and hybridization probes (fluorescence resonance energy transfer)-were evaluated for use in a real-time PCR assay to detect Brucella abortus. The three assays utilized the same amplification primers to produce an identical amplicon. This amplicon spans a region of the B. abortus genome that includes portions of the alkB gene and the IS711 insertion element. All three assays were of comparable sensitivity, providing a linear assay over 7 orders of magnitude (from 7.5 ng down to 7.5 fg). However, the greatest specificity was achieved with the hybridization probe assay.     

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.     

SNP genotyping through the melting analysis of unlabelled oligonucleotide applied on dilute PCR amplicon

Adaptation of DNA melting analysis for polymorphic single nucleotides (SNPs) genotyping using an unlabeled oligonucleotide probe for polymorphic DNAs under the presence of fluorescent DNA binding dye necessitates a reaction condition where the probe efficiently associates with a target strand that is PCR amplified. We present experimental evidence that application of an unlabeled probe to a dilute PCR amplicon provides a condition such that the fluorescent signals gained subsequently by probe melting are sufficient to discriminate allelic identities. This approach is best exploited by adapting the multiplexing PCR technique in order to cover multiple SNPs for given samples. 3′-end modification of the probe is unnecessary as the amplicon dilution step provides a way of inactivating the polymerase through divalent cation chelation. With the use of low-cost reagents and ordinary laboratory equipment, this method offers a rapid, simple and cost-efficient way of SNP genotyping.