Monoplex/multiplex linear-after-the-exponential-PCR assays combined with PrimeSafe and Dilute-'N'-Go sequencing

This protocol describes the design and execution of monoplex and multiplex linear-after-the-exponential (LATE)-PCR assays using a novel reagent, PrimeSafe, that suppresses all forms of mispriming. LATE-PCR is an advanced form of asymmetric amplification that uses a limiting primer and an excess primer for efficient exponential amplification of double-stranded DNA, followed by linear amplification of one strand. Each single-stranded amplicon can be quantitatively detected in real time or at end point. By separating primer annealing from product detection, LATE-PCR enables product analysis at low temperatures. Alternatively, each single strand can be sequenced by a convenient Dilute-'N'-Go procedure. Amplified samples are diluted with individual sequencing primers without the use of columns or spins. We have amplified and then sequenced 15 different single-stranded products generated in a single multiplexed LATE-PCR comprised of 15 pairs of unrelated primers. Dilute-'N'-Go dideoxy sequencing is more convenient, faster and less expensive than sequencing double-stranded amplicons generated via conventional symmetric PCR. The preparation of LATE-PCR products for Dilute-'N'-Go sequencing takes only 30 seconds.     

A novel multiplex PCR assay for the detection of Salmonella enterica serovar Enteritidis in human faeces

AIMS: To develop a multiplex PCR assay for the detection of Salmonella enterica serovar Enteritidis in human faeces. METHODS AND RESULTS: A total of 54 Salmonella strains representing 19 serovars and non-Salmonella strains representing 11 different genera were used. Five primer pairs were employed in the assay. Three of them targeted to the genes hilA, spvA and invA that encode virulence-associated factors. A fourth primer pair amplified a fragment of a unique sequence within S. enterica serovar Enteritidis genomes. An internal amplification control (a fragment of a conservative sequence within the 16S rRNA genes) was targeted by a fifth primer pair. The assay produced two or three amplicons from the invA, hilA and 16S rRNA genes for 19 Salmonella serovars. All Salmonella and non-Salmonella strains yielded a band of an internal amplification control. For S. enterica serovar Typhimurium, four products (the fourth from the spvA gene), and for S. enterica serovar Enteritidis five amplicons (the fifth from the sdf gene) were observed. S. enterica serovar Enteritidis was cultured from three of 71 rectal swabs from diarrhoeal patients. Five specific amplicons were generated with the multiplex PCR assay only from culture-positive faecal samples. CONCLUSION: The multiplex PCR assay specifically detects S. enterica serovar Enteritidis. SIGNIFICANCE AND IMPACT OF THE STUDY: This is a novel multiplex PCR assay, which contains an internal amplification control and enables concurrent survey for Salmonella virulence genes.     

Fragment size difference between multiplex and singleplex PCR products and their practical implications

By simultaneously amplifying several loci in the same reaction, multiplex PCR has been used in gene mapping and DNA typing with polymorphic short tandem repeat loci. Previous studies have discussed in detail the various parameters and conditions that influence the quantity of individual products generated by multiplex PCR. In practice, when a primer pair fails to amplify in a multiplex PCR for some individuals, singleplex PCR is often employed as a supplement to amplify the primer pair. However, the reliability of this procedure is unknown. In this study, we used six primer pairs from ABI PRISM Linkage Mapping Set version 2 to perform multiplex and singleplex reactions. The fluorescence-labeled amplification products were separated and detected on ABI PRISM 310 Genetic Analyzer. We found that for the marker D1S468, multiplex and singleplex reactions for the majority of individuals yielded reactions of different sizes. Therefore, the potential size difference between multiplex and singleplex reactions needs to be investigated. This investigation is essential to employ multiplex PCR supplemented with singleplex PCR in gene mapping and DNA typing.     

Bias caused by template annealing in the amplification of mixtures of 16S rRNA genes by PCR.

The PCR is used widely for the study of rRNA genes amplified from mixed microbial populations. These studies resemble quantitative applications of PCR in that the templates are mixtures of homologs and the relative abundance of amplicons is thought to provide some measure of the gene ratios in the starting mixture. Although such studies have established the presence of novel rRNA genes in many natural ecosystems, inferences about gene abundance have been limited by uncertainties about the relative efficiency of gene amplification in the PCR. To address this question, three rRNA gene standards were prepared by PCR, mixed in known proportions, and amplified a second time by using primer pairs in which one primer was labeled with a fluorescent nucleotide derivative. The PCR products were digested with restriction endonucleases, and the frequencies of genes in the products were determined by electrophoresis on an Applied Biosystems 373A automated DNA sequencer in Genescan mode. Mixtures of two templates amplified with the 519F-1406R primer pair yielded products in the predicted proportions. A second primer pair (27F-338R) resulted in strong bias towards 1:1 mixtures of genes in final products, regardless of the initial proportions of the templates. This bias was strongly dependent on the number of cycles of replication. The results fit a kinetic model in which the reannealing of genes progressively inhibits the formation of template-primer hybrids.     

Primer design for Whole Genome Amplification using genetic algorithms

Whole Genome Amplification (WGA) is an important process to increase limiting amounts of genomic DNA prior to genomic analyses. Current amplification methods based on primer extension or strand displacement principles employ primers of partially or totally random sequence. In this paper, we present a method using Genetic Algorithms to optimize a single primer design to be used in a primer extension reaction to achieve unbiased WGA. Computational simulation and prediction of a suitable primer proposed two candidates NYP6-1 (ATCTCA) and NYP6-2 (TGAGAT). NYP6-1 amplified to a maximum length of 2537 base pairs (bp), had genome coverage of approximately 45.62%, with an average of 493 and variance of 163 amplicons per 1 megabasepairs (Mb). NYP6-2 amplified to a maximum length of 2926 bp and covered 54.35% of the genome with an average of 579 and a variance of 191 amplicons per Mb. In contrast, the original primer used in Degenerate Oligonucleotide-Primed PCR (DOP-PCR) had coverage of 20.93%, an average of 74 and variance of 188 amplicons per Mb when extended up to a length of 2000 bp. Successful WGA of miniscule amounts of genomic DNA requires the amplification method used to resolve issues on efficiency, accurate representation of the whole genome and ability to degraded DNA. The sequence NYP6-2 discovered using our method can be confidently used in a primer extension based protocol to perform quantitatively unbiased WGA.     

MPprimer: a program for reliable multiplex PCR primer design

Background  

Multiplex PCR, defined as the simultaneous amplification of multiple regions of a DNA template or multiple DNA templates using more than one primer set (comprising a forward primer and a reverse primer) in one tube, has been widely used in diagnostic applications of clinical and environmental microbiology studies. However, primer design for multiplex PCR is still a challenging problem and several factors need to be considered. These problems include mis-priming due to nonspecific binding to non-target DNA templates, primer dimerization, and the inability to separate and purify DNA amplicons with similar electrophoretic mobility.     

A Novel and Simple PCR Walking Method for Rapid Acquisition of Long DNA Sequence Flanking a Known Site in Microbial Genome

Acquisition of flanking sequence adjacent to a known DNA site is an important task in microbial genome-related research. In this study, we developed a new method containing two rounds of PCR followed by cloning and sequencing. Firstly, specific primer (SP) is added into the reaction system for primary locus-specific linear amplification, and then a complex long primer (CLP) is added into the cooled reaction system for only one cycle. Amplification products from the first round of PCR are directly purified without electrophoresis, diluted, and used as the templates of the second PCR. Secondly, one long specific primer (LSP) and one long base-fixed primer (LFP) are adopted. The amplicons are purified for cloning and sequencing. The achievement of specific amplification for long flanking region mainly depends on ingenious and precise settings of PCR programs, structure design of CLP primer, adding of CLP primer after specific linear amplification, concentration ratio of CLP and SP primer, applying long primers, etc. Through this method, we successfully performed the long PCR walkings (>1.5 Kb) on rpoB gene of Vibrio vulnificus, transposon-like gene of V. alginolyticus, and sto gene of V. cholerae. The method provides a robust and simple strategy for rapid amplification of long unknown DNA fragments from microbes.     

Multiplex PCR with the blunt hairpin primers for next generation sequencing

The multiplex PCR is one of the important methods to enrich the target DNAs for next generation sequencing. The non-specific amplification and interaction between the primers are the pivotal challenges of multiplex PCR. Here, we introduce the novel blunt hairpin primers for effective reducing the primer dimers and mispriming events. We also used a pair of auxiliary primers to enhance PCR efficiency. We simultaneously amplified 89 target regions from 44 samples and sequenced all amplicons on ion torrent PGM platform. Among all the filtrated amplicons (3438 different amplicons), 99.7, 97.6, 90.1 and 72.8% had sequencing depths fell within 200, 100, 50 and 25-fold range. The sequencing depth variations among all the samples were less than 27-fold. We also amplified multiplex regions with blunt hairpin, stick hairpin and normal linear primers, and the blunt hairpin primers could significantly reduce the amount of primer dimers and unspecific products.These results show that multiplex PCR with the blunt hairpin primers is a flexible, specific and economical target-region captured approach for the next generation sequencing.     

Reducing amplification artifacts in high multiplex amplicon sequencing by using molecular barcodes

Background

PCR amplicon sequencing has been widely used as a targeted approach for both DNA and RNA sequence analysis. High multiplex PCR has further enabled the enrichment of hundreds of amplicons in one simple reaction. At the same time, the performance of PCR amplicon sequencing can be negatively affected by issues such as high duplicate reads, polymerase artifacts and PCR amplification bias. Recently researchers have made some good progress in addressing these shortcomings by incorporating molecular barcodes into PCR primer design. So far, most work has been demonstrated using one to a few pairs of primers, which limits the size of the region one can analyze.

Results

We developed a simple protocol, which enables the use of molecular barcodes in high multiplex PCR with hundreds of amplicons. Using this protocol and reference materials, we demonstrated the applications in accurate variant calling at very low fraction over a large region and in targeted RNA quantification. We also evaluated the protocol’s utility in profiling FFPE samples.

Conclusions

We demonstrated the successful implementation of molecular barcodes in high multiplex PCR, with multiplex scale many times higher than earlier work. We showed that the new protocol combines the benefits of both high multiplex PCR and molecular barcodes, i.e. the analysis of a very large region, low DNA input requirement, very good reproducibility and the ability to detect as low as 1 % mutations with minimal false positives (FP).

Electronic supplementary material

The online version of this article (doi:10.1186/s12864-015-1806-8) contains supplementary material, which is available to authorized users.     

Multiplex amplification enabled by selective circularization of large sets of genomic DNA fragments

We present a method to specifically select large sets of DNA sequences for parallel amplification by PCR using target-specific oligonucleotide constructs, so-called selectors. The selectors are oligonucleotide duplexes with single-stranded target-complementary end-sequences that are linked by a general sequence motif. In the selection process, a pool of selectors is combined with denatured restriction digested DNA. Each selector hybridizes to its respective target, forming individual circular complexes that are covalently closed by enzymatic ligation. Non-circularized fragments are removed by exonucleolysis, enriching for the selected fragments. The general sequence that is introduced into the circularized fragments allows them to be amplified in parallel using a universal primer pair. The procedure avoids amplification artifacts associated with conventional multiplex PCR where two primers are used for each target, thereby reducing the number of amplification reactions needed for investigating large sets of DNA sequences. We demonstrate the specificity, reproducibility and flexibility of this process by performing a 96-plex amplification of an arbitrary set of specific DNA sequences, followed by hybridization to a cDNA microarray. Eighty-nine percent of the selectors generated PCR products that hybridized to the expected positions on the array, while little or no amplification artifacts were observed.     

A novel universal primer-multiplex-PCR method with sequencing gel electrophoresis analysis

In this study, a novel universal primer-multiplex-PCR (UP-M-PCR) method adding a universal primer (UP) in the multiplex PCR reaction system was described. A universal adapter was designed in the 5'-end of each specific primer pairs which matched with the specific DNA sequences for each template and also used as the universal primer (UP). PCR products were analyzed on sequencing gel electrophoresis (SGE) which had the advantage of exhibiting extraordinary resolution. This method overcame the disadvantages rooted deeply in conventional multiplex PCR such as complex manipulation, lower sensitivity, self-inhibition and amplification disparity resulting from different primers, and it got a high specificity and had a low detection limit of 0.1 ng for single kind of crops when screening the presence of genetically modified (GM) crops in mixture samples. The novel developed multiplex PCR assay with sequencing gel electrophoresis analysis will be useful in many fields, such as verifying the GM status of a sample irrespective of the crop and GM trait and so on.     

Set of novel tools for PCR primer design.

We have developed a new package of computer programs and algorithms for different PCR applications, including allele-specific PCR, multiplex PCR, and long PCR. The package is included in the upcoming VectorNTI suite software and attempts to incorporate most of the current knowledge about PCR primer design. A wide range of primer characteristics is available for user manipulation to provide improved efficiency and increased flexibility of primer design. To accelerate the primer calculations, we have optimized algorithms using recent advances in computer science such as dynamic trees and lazy evaluation. Proper structural organization of input parameters provides further program acceleration. New Vector NTI primer design software allows calculations of primer pairs for long PCR amplification of 120-kb genomic DNA in 5 min under most stringent input parameters and clustering 435 primer pairs for multiplex PCR within 30 min on a standard Pentium III PC. Our program allows the user to take advantage of molecule annotation by applying different kinds of filtering features during PCR primer design.     

Four PCR primers necessary for the detection of periplasmic nitrate reductase genes in all groups of Proteobacteria and in environmental DNA

Generic primers are available for detecting bacterial genes required for almost every reaction of the biological nitrogen cycle, the one notable exception being napA (gene for the molybdoprotein of the periplasmic nitrate reductase) encoding periplasmic nitrate reductases. Using an iterative approach, we report the first successful design of three forward oligonucleotide primers and one reverse primer that, in three separate PCRs, can amplify napA DNA from all five groups of Proteobacteria. All 140 napA sequences currently listed in the NCBI (National Center for Biotechnology Information) database are predicted to be amplified by one or more of these primer pairs. We demonstrate that two pairs of these primers also amplify PCR products of the predicted sizes from DNA isolated from human faeces, confirming their ability to direct the amplification of napA fragments from mixed populations. Analysis of the resulting amplicons by high-throughput sequencing will enable a good estimate to be made of both the range and relative abundance of nitrate-reducing bacteria in any community, subject only to any unavoidable bias inherent in a PCR approach to molecular characterization of a highly diverse target.     

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。     

New strategy for identification of novel Cry-type genes from Bacillus thuringiensis strains

We designed five degenerate primers for detection of novel cry genes from Bacillus thuringiensis strains. An efficient strategy was developed based on a two-step PCR approach with these primers in five pair combinations. In the first step, only one of the primer pairs is used in the PCR, which allows amplification of DNA fragments encoding protein regions that include consensus domains of representative proteins belonging to different Cry groups. A second PCR is performed by using the first-step amplification products as DNA templates and the set of five primer combinations. Cloning and sequencing of the last-step amplicons allow both the identification of known cry genes encoding Cry proteins covering a wide phylogenetic distance and the detection and characterization of cry-related sequences from novel B. thuringiensis isolates.     

MARA: a novel approach for highly multiplexed locus-specific SNP genotyping using high-density DNA oligonucleotide arrays

We have developed a locus-specific DNA target preparation method for highly multiplexed single nucleotide polymorphism (SNP) genotyping called MARA (Multiplexed Anchored Runoff Amplification). The approach uses a single primer per SNP in conjunction with restriction enzyme digested, adapter-ligated human genomic DNA. Each primer is composed of common sequence at the 5′ end followed by locus-specific sequence at the 3′ end. Following a primary reaction in which locus-specific products are generated, a secondary universal amplification is carried out using a generic primer pair corresponding to the oligonucleotide and genomic DNA adapter sequences. Allele discrimination is achieved by hybridization to high-density DNA oligonucleotide arrays. Initial multiplex reactions containing either 250 primers or 750 primers across nine DNA samples demonstrated an average sample call rate of ~95% for 250- and 750-plex MARA. We have also evaluated >1000- and 4000-primer plex MARA to genotype SNPs from human chromosome 21. We have identified a subset of SNPs corresponding to a primer conversion rate of ~75%, which show an average call rate over 95% and concordance >99% across seven DNA samples. Thus, MARA may potentially improve the throughput of SNP genotyping when coupled with allele discrimination on high-density arrays by allowing levels of multiplexing during target generation that far exceed the capacity of traditional multiplex PCR.     

Development of a single tube 640-plex genotyping method for detection of nucleic acid variations on microarrays

Detection of DNA sequence variation is critical to biomedical applications, including disease genetic identification, diagnosis and treatment, drug discovery and forensic analysis. Here, we describe an arrayed primer extension-based genotyping method (APEX-2) that allows multiplex (640-plex) DNA amplification and detection of single nucleotide polymorphisms (SNPs) and mutations on microarrays via four-color single-base primer extension. The founding principle of APEX-2 multiplex PCR requires two oligonucleotides per SNP/mutation to generate amplicons containing the position of interest. The same oligonucleotides are then subsequently used as immobilized single-base extension primers on a microarray. The method described here is ideal for SNP or mutation detection analysis, molecular diagnostics and forensic analysis. This robust genetic test has minimal requirements: two primers, two spots on the microarray and a low cost four-color detection system for the targeted site; and provides an advantageous alternative to high-density platforms and low-density detection systems.     

Detection of Thelohania solenopsae (Microsporidia: Thelohaniidae) in Solenopsis invicta (Hymenoptera: Formicidae) by multiplex PCR

Oligonucleotide primer pairs were designed to unique areas of the small subunit (16S) rRNA gene of Thelohania solenopsae and a region of the Gp-9 gene of Solenopsis invicta. Multiplex PCR resulted in sensitive and specific detection of T. solenopsae infection of S. invicta. The T. solenopsae-specific primer pair only amplified DNA from T. solenopsae and T. solenopsae-infected S. invicta. This primer pair did not produce any amplification products from DNA preparations from uninfected S. invicta, seven additional species of microsporidia (including Vairimorpha invictae), or Mattesia spp. The Gp-9-specific primers recognized and amplified DNA from Solenopsis xyloni, Solenopsis richteri, Solenopsis geminata, the invicta/richteri hybrid, and monogyne and polygyne S. invicta, but not from T. solenopsae, and, as such, served as a positive control verifying successful DNA preparation. Multiplex PCR detected T. solenopsae in worker fire ants infected with as few as 5000 spores. Furthermore, multiplex PCR detected T. solenopsae in all developmental stages of S. invicta. However, detection could be made more sensitive by using only the T. solenopsae-specific primer pair; ants infected with as few as 10 spores were able to be discerned. Multiplex PCR detection of T. solenopsae offers the advantages of a positive control, a single PCR amplification, detection of all developmental stages, and increased sensitivity and specificity compared with microscopy.     

New Strategy for Identification of Novel cry-Type Genes from Bacillus thuringiensis Strains

We designed five degenerate primers for detection of novel cry genes from Bacillus thuringiensis strains. An efficient strategy was developed based on a two-step PCR approach with these primers in five pair combinations. In the first step, only one of the primer pairs is used in the PCR, which allows amplification of DNA fragments encoding protein regions that include consensus domains of representative proteins belonging to different Cry groups. A second PCR is performed by using the first-step amplification products as DNA templates and the set of five primer combinations. Cloning and sequencing of the last-step amplicons allow both the identification of known cry genes encoding Cry proteins covering a wide phylogenetic distance and the detection and characterization of cry-related sequences from novel B. thuringiensis isolates.     

PCR-RFLP和多重PCR技术检测常见病原性丝状真菌的实验研究

目的建立检测常见丝状真菌感染病原菌的PCR-RFLP和多重PCR方法。方法建立以PCR技术为基础的限制片段长度多态性(RFLP)方法 ,首先用真菌通用引物扩增丝状真菌的ITS区,然后用限制性核酸内切酶对PCR产物进行酶切。用4种丝状真菌的特异性引物建立多重PCR体系,用该体系检测单模板、双模板和三模板的扩增情况,并测定该体系的特异性和敏感性。结果用PCR-RFLP技术能够鉴别5种常见丝状真菌,多重PCR能够根据扩增片段的不同鉴别菌种,在合适的反应条件下,对单模板、双模板和三模板均能扩增出目的片段。结论 PCR-RFLP和多重PCR技术能够快速鉴定丝状真菌感染病原菌,有临床应用的良好前景。