Multiplex digital PCR: breaking the one target per color barrier of quantitative PCR

Quantitative polymerase chain reactions (qPCR) based on real-time PCR constitute a powerful and sensitive method for the analysis of nucleic acids. However, in qPCR, the ability to multiplex targets using differently colored fluorescent probes is typically limited to 4-fold by the spectral overlap of the fluorophores. Furthermore, multiplexing qPCR assays requires expensive instrumentation and most often lengthy assay development cycles. Digital PCR (dPCR), which is based on the amplification of single target DNA molecules in many separate reactions, is an attractive alternative to qPCR. Here we report a novel and easy method for multiplexing dPCR in picolitre droplets within emulsions-generated and read out in microfluidic devices-that takes advantage of both the very high numbers of reactions possible within emulsions (>10(6)) as well as the high likelihood that the amplification of only a single target DNA molecule will initiate within each droplet. By varying the concentration of different fluorogenic probes of the same color, it is possible to identify the different probes on the basis of fluorescence intensity. Adding multiple colors increases the number of possible reactions geometrically, rather than linearly as with qPCR. Accurate and precise copy numbers of up to sixteen per cell were measured using a model system. A 5-plex assay for spinal muscular atrophy was demonstrated with just two fluorophores to simultaneously measure the copy number of two genes (SMN1 and SMN2) and to genotype a single nucleotide polymorphism (c.815A>G, SMN1). Results of a pilot study with SMA patients are presented.     

Strategy for high-fidelity multiplex DNA copy number assay system using capillary electrophoresis devices

Structural variation of human genome such as duplications and deletions, collectively termed copy number variation (CNV), is one of the major genetic variations. Reliable and efficient measurement of CNV will be essential to develop diagnostic tools for CNV-related diseases. We established a strategy based on multiplex PCR and capillary electrophoresis (CE) for reliable CNV assay. Multiplex-PCR was performed using five primer sets for target loci and a diploid control (DC). We designed primers satisfying three conditions: different size of each PCR product for CE separation, unified annealing temperature for multiplex PCR, and suitability for quantitative PCR (qPCR). We defined the accurate PCR cycles for quantification of copy numbers at which the amplifications for all targets were supposed to be exponential, named maximum doubling cycle. CE was carried out with PCR product and the ratio of the peak areas (target/diploid control) was calculated. Our multiplex PCR-CE analysis reliably determined copy numbers of X chromosome with variable copies ranging from 1 to 5 and showed higher reliability than qPCR (correlation coefficient 0.996 versus 0.898). When measuring the six randomly selected autosomal CNV targets using our multiplex PCR-CE, the results agreed with those from qPCR. In addition, our strategy was validated for the broad application to commonly used CE devices. Taken together, this assay will be useful for accurate analysis of multiple disease-associated CNVs in a clinical setting.     

Colorimetric quantification of mRNA expression in rare tumour cells amplified by multiple ligation-dependent probe amplification

An enzyme-linked oligonucleotide assay (ELONA) for quantification of mRNA expression of five genes involved in breast cancer, extracted from isolated rare tumour cells and amplified by multiplex ligation-dependent probe amplification (MLPA) is presented. In MLPA, a multiplex oligonucleotide ligation assay is combined with a PCR reaction in which all ligation products are amplified by use of a single primer pair. Biotinylated probes complementary to each of the target sequences were immobilised on the surface of a streptavidin-coated microtitre plate and exposed to single-stranded MLPA products. A universal reporting probe sequence modified with horseradish peroxidase (URP–HRP) and complementary to a universal primer used during the MLPA step was further added to the surface-bound duplex as a reporter probe. Simultaneous addition of anchoring probe and target, followed by addition of reporter probe, rather than sequential addition, was achieved with no significant effect on sensitivity and limits of detection, but considerably reduced the required assay time. Detection limits as low as 20 pmol L⁻¹, with an overall assay time of 95 min could be achieved with negligible cross-reactivity between probes and non-specific targets present in the MLPA-PCR product. The same MLPA-PCR product was analysed using capillary electrophoresis, the technique typically used for analysis of MLPA products, and good correlation was observed. The assay presented is easy to carry out, relatively inexpensive, rapid, does not require sophisticated instrumentation, and enables quantitative analysis, making it very promising for the analysis of MLPA products.     

Effect of sustained elevated temperature prior to amplification on template copy number estimation using digital polymerase chain reaction

Digital polymerase chain reaction (dPCR) has the potential to enable accurate quantification of target DNA copy number provided that all target DNA molecules are successfully amplified. Following duplex dPCR analysis from a linear DNA target sequence that contains single copies of two independent template sequences, we have observed that amplification of both templates in a single partition does not always occur. To investigate this finding, we heated the target DNA solution to 95 °C for increasing time intervals and then immediately chilled on ice prior to preparing the dPCR mix. We observed an exponential decline in estimated copy number (R(2)≥ 0.98) of the two template sequences when amplified from either a linearized plasmid or a 388 base pair (bp) amplicon containing the same two template sequences. The distribution of amplifiable templates and the final concentration (copies per μL) were both affected by heat treatment of the samples at 95 °C from 0 s to 30 min. The proportion of target sequences from which only one of the two templates was amplified in a single partition (either 1507 or hmg only) increased over time, while the proportion of target sequences where both templates were amplified (1507 and hmg) in each individual partition declined rapidly from 94% to 52% (plasmid) and 88% to 31% (388 bp amplicon) suggesting an increase in number of targets from which both templates no longer amplify. A 10 min incubation at 95 °C reduced the initial amplifiable template concentration of the plasmid and the 388 bp amplicon by 59% and 91%, respectively. To determine if a similar decrease in amplifiable target occurs during the default pre-activation step of typical PCR amplification protocol, we used mastermixes with a 20 s or 10 min hot-start. The choice of mastermix and consequent pre-activation time did not affect the estimated plasmid concentration. Therefore, we conclude that prolonged exposure of this DNA template to elevated temperatures could lead to significant bias in dPCR measurements. However, care must be taken when designing PCR and non-PCR based experiments by reducing exposure of the DNA template to sustained elevated temperatures in order to improve accuracy in copy number estimation and concentration determination.     

A new PCR-CGE (size and color) method for simultaneous detection of genetically modified maize events

We present a novel multiplex PCR assay for simultaneous detection of multiple transgenic events in maize. Initially, five PCR primers pairs specific to events Bt11, GA21, MON810, and NK603, and Zea mays L. (alcohol dehydrogenase) were included. The event specificity was based on amplification of transgene/plant genome flanking regions, i.e., the same targets as for validated real-time PCR assays. These short and similarly sized amplicons were selected to achieve high and similar amplification efficiency for all targets; however, its unambiguous identification was a technical challenge. We achieved a clear distinction by a novel CGE approach that combined the identification by size and color (CGE-SC). In one single step, all five targets were amplified and specifically labeled with three different fluorescent dyes. The assay was specific and displayed an LOD of 0.1% of each genetically modified organism (GMO). Therefore, it was adequate to fulfill legal thresholds established, e.g., in the European Union. Our CGE-SC based strategy in combination with an adequate labeling design has the potential to simultaneously detect higher numbers of targets. As an example, we present the detection of up to eight targets in a single run. Multiplex PCR-CGE-SC only requires a conventional sequencer device and enables automation and high throughput. In addition, it proved to be transferable to a different laboratory. The number of authorized GMO events is rapidly growing; and the acreage of genetically modified (GM) varieties cultivated and commercialized worldwide is rapidly increasing. In this context, our multiplex PCR-CGE-SC can be suitable for screening GM contents in food.     

Stuffer‐free multiplex ligation‐dependent probe amplification based on conformation‐sensitive capillary electrophoresis: A novel technology for robust multiplex determination of copy number variation

Developing diagnostic tools based on the application of known disease/phenotype‐associated copy number variations (CNVs) requires the capacity to measure CNVs in a multiplex format with sufficient reliability and methodological simplicity. In this study, we developed a reliable and user‐friendly multiplex CNV detection method, termed stuffer‐free MLPA‐CE‐SSCP, that combines a variation of multiplex ligation‐dependent probe amplification (MLPA) with CE‐SSCP. In this variation, MLPA probes were designed without the conventionally required stuffer sequences. To separate the similar‐sized stuffer‐free MLPA products, we adopted CE‐SSCP rather than length‐dependent conventional CE analysis. An examination of the genomic DNA from five cell lines known to vary in X‐chromosome copy number (1–5) revealed that copy number determinations using stuffer‐free MLPA‐CE‐SSCP were more accurate than those of conventional MLPA, and the CV of the measured copy numbers was significantly lower. Applying our system to measure the CNVs on autosomes between two HapMap individuals, we found that all peaks for CNV targets showed the expected copy number changes. Taken together, our results indicate that this new strategy can overcome the limitations of conventional MLPA, which are mainly related to long probe length and difficulties of probe preparation.     

Hexaplex PCR assay and liquid bead array for detection of stacked genetically modified cotton event 281-24-236×3006-210-23

A hexaplex system based on multiplex polymerase chain reaction (PCR) coupled with liquid bead array was developed to assist detection of stacked genetically modified (GM) cotton event 281-24-236 × 3006-210-23 (Widestrike) expressing two kinds of endotoxin from Bacillus thuringiensis (Bt). The efficiency of this multiplex detection system was assessed. Specific primer sets for simultaneous detection of six targets in the stacked GM cotton event were constructed and used for the PCR assay. Each of the six targets was amplified, and the amplicons could be separated as discrete bands by agarose gel electrophoresis. A liquid bead array assay for the stacked GM cotton was performed using the hexaplex PCR products followed by hybridization between the biotinylated targets and anti-tagged microsphere beads. The hybridization products produced fluorescent signals that were detected by the Luminex system. Signal strengths were analyzed by their median fluorescent intensity values. Comparison of the assays showed that results from the liquid bead array using specific probes agreed with those from the PCR, and detection of the different target elements was found to be very specific with no cross-reaction. Therefore, the combination of hexaplex PCR and liquid bead array for detection of stacked GM events can be a useful and efficient system for screening and analyzing multiple transgenes for simultaneous qualitative analysis.     

Development of a multiplex system to assess DNA persistence in taphonomic studies

In this study, we have developed a PCR multiplex that can be used to assess DNA degradation and at the same time monitor for inhibition: primers have been designed to amplify human, pig, and rabbit DNA, allowing pig and rabbit to be used as experimental models for taphonomic research, but also enabling studies on human DNA persistence in forensic evidence. Internal amplified controls have been added to monitor for inhibition, allowing the effects of degradation and inhibition to be differentiated. Sequence data for single‐copy nuclear recombination activation gene (RAG‐1) from human, pig, and rabbit were aligned to identify conserved regions and primers were designed that targeted amplicons of 70, 194, 305, and 384 bp. Robust amplification in all three species was possible using as little as 0.3 ng of template DNA. These have been combined with primers that will amplify a bacterial DNA template within the PCR. The multiplex has been evaluated in a series of experiments to gain more knowledge of DNA persistence in soft tissues, which can be important when assessing what material to collect following events such as mass disasters or conflict, when muscle or bone material can be used to aid with the identification of human remains. The experiments used pigs as a model species. When whole pig bodies were exposed to the environment in Northwest England, DNA in muscle tissue persisted for over 24 days in the summer and over 77 days in the winter, with full profiles generated from these samples. In addition to time, accumulated degree days (ADD) were also used as a measure that combines both time and temperature—24 days was in summer equivalent to 295 ADD whereas 77 days in winter was equivalent to 494 ADD.     

Portable chemiluminescence multiplex biosensor for quantitative detection of three B19 DNA genotypes

A miniaturized multiplex biosensor exploiting a microfluidic oligonucleotide array and chemiluminescence (CL) lensless imaging detection has been developed for parvovirus B19 genotyping. The portable device consists of a reaction chip, comprising a glass slide arrayed with three B19 genotype-specific probes and coupled with a polydimethylsiloxane microfluidic layer, and a charge-coupled device camera modified for lensless CL imaging. Immobilized probes were used in DNA hybridization reactions with biotin-labeled targets, and then hybrids were measured by means of an avidin-horseradish peroxidase (HRP) conjugate and CL detection. All hybridization assay procedures have been optimized to be performed at room temperature through the microfluidic elements of the reaction chip, with sample and reagents delivery via capillary force exploiting adsorbent pads to drive fluids along the microchannels. The biosensor enabled multiplex detection of all B19 genotypes, with detectability down to 80 pmol?L^?1 for all B19 genotype oligonucleotides and 650 pmol?L^?1 for the amplified product of B19 genotype 1, which is comparable with that obtained in traditional PCR-ELISA formats and with notably shorter assay time (30 min vs. 2 h). The specificity of the assay has been evaluated by performing DNA–DNA hybridization reactions among sequences with different degrees of homology, and no cross hybridizations among B19 genotypes have been observed. The clinical applicability has been demonstrated by assaying amplified products obtained from B19 reference serum samples, with results completely consistent with the reference PCR-ELISA method. The next crucial step will be integration in the biosensor of a miniaturized PCR system for DNA amplification and for heat treatment of amplified products.

一种可绝对定量核酸的数字PCR微流控芯片

构建了一种新型的可进行核酸单分子扩增和核酸绝对定量的数字聚合酶链式反应(数字PCR)微流控芯片. 应用多层软光刻技术, 以聚二甲基硅氧烷(PDMS)作为芯片材料, 盖玻片作为基底制作了具有3层结构以及微阀控制功能的微流控芯片. 芯片的大小与载玻片相当, 可同时检测4个样品, 每个样品通入芯片后平均分配到640个反应小室, 每个小室的体积为6 nL. 以从肺癌细胞A549中提取的18sRNA为样品检测了该芯片的可行性. 将样品稀释数倍后通入芯片, 核酸分子随机分布在640个小室中并扩增. 核酸分子在芯片中的分布符合泊松分布原理, 当样品中待测核酸分子平均拷贝数低于0.5个/小室时, 则每个反应小室包含0个或1个分子. 经过PCR扩增后, 有模板分子的小室检测结果为阳性反应, 而无模板分子的小室为阴性反应, 最后通过计数阳性反应室的个数, 可绝对定量原始待测样品中的目标DNA分子拷贝数. 实验结果表明, 该数字 PCR芯片可实现DNA单分子反应和核酸绝对定量, 具有成本低、 灵敏度高、 节省时间和试剂以及操作简单等优点, 为数字PCR方法在普通实验室的应用提供了一种新途径, 可用于癌症及感染性疾病的早期诊断、 单细胞分析、 产前诊断以及各种细菌病毒的核酸检验等研究.     

On-line monitoring of all-acrylic emulsion polymerization reactors by Raman spectroscopy

Fourier Transform Raman spectroscopy was used as an on-line sensor in order to monitor high solids content (50 wt%) n-BA/MMA emulsion copolymerization reactions. Due to the similarity of the chemical structure of the monomers, no separate bands could be detected for each monomer, and therefore a multivariate calibration technique was required (Partial Least Squares Regression, PLSR). Using experimental data from several semi-batch reactions independent PLSR models were built for the solids content, cumulative copolymer composition and unreacted amounts of n-BA and MMA. Those models were experimentally validated by monitoring reactions not used for calibration. It is demonstrated that FT-Raman spectroscopy can be successfully applied to on-line monitor emulsion polymerization reactors. This technique also shows a high potential for process control purposes because independent information about several molecular properties can be obtained from a single apparatus.     

Nucleic acid analysis using an expanded genetic alphabet to quench fluorescence

Organic chemistry has made possible the synthesis of molecules that expand on Nature's genetic alphabet. Using the previously described nonstandard DNA base pair constructed from isoguanine and 5-methylisocytosine, we report a highly specific and sensitive method that allows for the fast and specific quantitation of genetic sequences in a closed tube format. During PCR amplification, enzymatic site-specific incorporation of a quencher covalently linked to isoguanine allows for the simultaneous detection and identification of multiple targets. The specificity of method is then established by analysis of thermal denaturation or melting of the amplicons. The appropriate functions of all reactions are further verified by incorporation of an independent target into the reaction mixture. We report that the method is sensitive down to the single copy level, and specificity is demonstrated by multiplexed end-point genotypic analysis of four targets simultaneously using four separate fluorescent reporters. The method is general enough for quantitative and qualitative analysis of both RNA and DNA using previously developed primer sets. Though the method described employs the commonly used PCR, the enzymatic incorporation of reporter groups into DNA site-specifically should find broad utility throughout molecular biology.     

Single molecule detection in nanofluidic digital array enables accurate measurement of DNA copy number

Digital polymerase chain reaction (PCR) is a promising technique for estimating target DNA copy number. PCR solution is distributed throughout numerous partitions, and following amplification, target DNA copy number is estimated based on the proportion of partitions containing amplified DNA. Here, we identify approaches for obtaining reliable digital PCR data. Single molecule amplification efficiency was significantly improved following fragmentation of total DNA and bias in copy number estimates reduced by analysis of short intact target DNA fragments. Random and independent distribution of target DNA molecules throughout partitions, which is critical to accurate digital PCR measurement, was demonstrated by spatial distribution analysis. The estimated relative uncertainty for target DNA concentration was under 6% when analyzing five digital panels comprising 765 partitions each, provided the panels contained an average of 212 to 3,365 template molecules. Partition volume was a major component of this uncertainty estimate. These findings can be applied to other digital PCR studies to improve confidence in such measurements. Figure Digital PCR amplification plot (left) and panel read out (right) of HindIII-digested pIRMM69. pIRMM69 contains one HindIII restriction enzyme site outside the hmg and transgene fragments used as targets in PCR. Red boxes with white shade denote positive hits containing one or more target DNA molecules, and white boxes with grey shade refer to no target being amplified.     

Essential problems in quantification of proteins following colloidal staining with coomassie brilliant blue dyes in polyacrylamide gels, and their solution.

Quantitative determination of stained proteins following polyacrylamide gel electrophoresis (PAGE) is of increasing interest especially since computer-aided densitometers have become available as well as recipes for sensitive and background-free staining with Coomassie Brilliant Blue dyes. However, avoidance of separation artifacts is not the only essential prerequisite for quantitative evaluation. The local particle density of a protein in a given gel is of critical importance since it determines its stainability. Depending on local protein concentration, the dye binding to the same amount of a given protein differs considerably. Since the stainability of proteins using colloidal staining procedures, as with Coomassie Brilliant Blue dyes, is time-dependent and, in addition, also dependent on the pore size of a given polyacrylamide gel used for PAGE, calibration curves for quantitative determinations have to be prepared in polyacrylamide gels of the same composition as used for PAGE. Staining conditions also have to be identical for calibration gels and gels under analysis. If, however, a set of calibration curves is prepared for different staining times, it is possible to calculate a generalized calibration curve, allowing for quantitative evaluation with flexible staining time. Furthermore, and in consequence of the implications due to particle density, quantitative determination via densitometry is only possible by determining the protein amount of each single measuring point (pixel) via its absorbance on the basis of a calibration curve. Since the particle density is inherent in a calibration curve, the final summation of the protein amount per pixel will give values close to reality.     

Analysis of four PCR/SNaPshot multiplex assays analyzing 52 SNPforID markers

The SNPfor ID consortium identified a panel of 52 SNPs for forensic analysis that has been used by several laboratories worldwide. The original analysis of the 52 SNPs was based on a single multiplex reaction followed by two single‐base‐extension (SBE) reactions each of which was analyzed using capillary electrophoresis. The SBE assays were designed for high throughput genetic analyzers and were difficult to use on the single capillary ABI PRISM 310 Genetic Analyzer and the latest generation 3500 Genetic Analyzer, as sensitivity on the 310 was low and separation of products on the 3500 with POP‐7™ was poor. We have modified the original assay and split it into four multiplex reactions, each followed by an SBE assay. These multiplex assays were analyzed using polymer POP‐4™ on ABI 310 PRISM® and polymers POP‐4™, POP‐6™ and POP‐7™ on the 3500 Genetic Analyzer. The assays were sensitive and reproducible with input DNA as low as 60 pg using both the ABI 310 and 3500. In addition, we found that POP‐6™ was most effective with the 3500, based on the parameters that we assessed, achieving better separation of the small SBE products; this conflicted with the recommended use of POP‐7™ by the instrument manufacturer. To support the use of the SNP panel in casework in Malaysia we have created an allele frequency database from 325 individuals, representing the major population groups within Malaysia. Population and forensic parameters were estimated for all populations and its efficacy evaluated using 51 forensic samples from challenging casework.     

Surface-enhanced Raman scattering detection of DNAs derived from virus genomes using Au-coated paramagnetic nanoparticles

A magnetic capture-based, surface-enhanced Raman scattering (SERS) assay for DNA detection has been developed which utilizes Au-coated paramagnetic nanoparticles (Au@PMPs) as both a SERS substrate and effective bioseparation reagent for the selective removal of target DNAs from solution. Hybridization reactions contained two target DNAs, sequence complementary reporter probes conjugated with spectrally distinct Raman dyes distinct for each target, and Au@PMPs conjugated with sequence complementary capture probes. In this case, target DNAs were derived from the RNA genomes of the Rift Valley Fever virus (RVFV) or West Nile virus (WNV). The hybridization reactions were incubated for a short period and then concentrated within the focus beam of an interrogating laser by magnetic pull-down. The attendant SERS response of each individually captured DNA provided a limit of detection sensitivity in the range 20-100 nM. X-ray diffraction and UV-vis analysis validated both the desired surface plasmon resonance properties and bimetallic composition of synthesized Au@PMPs, and UV-vis spectroscopy confirmed conjugation of the Raman dye compounds malachite green (MG) and erythrosin B (EB) with the RVFV and WNV reporter probes, respectively. Finally, hybridization reactions assembled for multiplexed detection of both targets yielded mixed MG/EB spectra and clearly differentiated peaks which facilitate the quantitative detection of each DNA target. On the basis of the simple design of a single-particle DNA detection assay, the opportunity is provided to develop magnetic capture-based SERS assays that are easily assembled and adapted for high-level multiplex detection using low-cost Raman instrumentation.     

Highly multiplex and sensitive SNP genotyping method using a three‐color fluorescence‐labeled ligase detection reaction coupled with conformation‐sensitive CE

For the development of clinically useful genotyping methods for SNPs, accuracy, simplicity, sensitivity, and cost‐effectiveness are the most important criteria. Among the methods currently being developed for SNP genotyping technology, the ligation‐dependent method is considered the simplest for clinical diagnosis. However, sensitivity is not guaranteed by the ligation reaction alone, and analysis of multiple targets is limited by the detection method. Although CE is an attractive alternative to error‐prone hybridization‐based detection, the multiplex assay process is complicated because of the size‐based DNA separation principle. In this study, we employed the ligase detection reaction coupled with high‐resolution CE‐SSCP to develop an accurate, sensitive, and simple multiplex genotyping method. Ligase detection reaction could amplify ligated products through recurrence of denaturation and ligation reaction, and SSCP could separate these products according to each different structure conformation without size variation. Thus, simple and sensitive SNP analysis can be performed using this method involving the use of similar‐sized probes, without complex probe design steps. We found that this method could not only accurately discriminate base mismatches but also quantitatively detect 37 SNPs of the tp53 gene, which are used as targets in multiplex analysis, using three‐color fluorescence‐labeled probes.     

Feasibility and extension of universal quantitative models for moisture content determination in beta-lactam powder injections by near-infrared spectroscopy

In present work, we investigated the feasibility of universal calibration models for moisture content determination of a much complicated products system of powder injections to simulate the process of building universal models for drug preparations with same INN (International Nonproprietary Name) from diverse formulations and sources. We also extended the applicability of universal model by model updating and calibration transfer. Firstly, a moisture content quantitative model for ceftriaxone sodium for injection was developed, the results show that calibration model established for products of some manufacturers is also available for the products of others. Then, we further constructed a multiplex calibration model for seven cephalosporins for injection ranging from 0.40 to 9.90%, yielding RMSECV and RMSEP of 0.283 and 0.261, respectively. However, this multiplex model could not predict samples of another cephalosporin (ceftezole sodium) and one penicillins (penicillin G procaine) for injection accurately. With regard to such limits and the extension of universal models, two solutions are proposed: model updating (MU) and calibration transfer. Overall, model updating is a robust method for the analytical problem under consideration. When timely model updating is impractical, piecewise direct standardization (PDS) algorithm is more desirable and applied to transfer calibration model between different powder injections. Both two solutions have proven to be effective to extend the applicability of original universal models for the new products emerging.