Enhancements and modifications of primer design program Primer3

The determination of annealing temperature is a critical step in PCR design. This parameter is typically derived from the melting temperature of the PCR primers, so for successful PCR work it is important to determine the melting temperature of primer accurately. We introduced several enhancements in the widely used primer design program Primer3. The improvements include a formula for calculating melting temperature and a salt correction formula. Also, the new version can take into account the effects of divalent cations, which are included in most PCR buffers. Another modification enables using lowercase masked template sequences for primer design. Availability: Features described in this article have been implemented into the development code of Primer3 and will be available in future versions (version 1.1 and newer) of Primer3. Also, a modified version is compiled under the name of mPrimer3 which is distributed independently. The web-based version of mPrimer3 is available at http://bioinfo.ebc.ee/mprimer3/ and the binary code is freely downloadable from the URL http://bioinfo.ebc.ee/download/.     

PCR引物设计及软件使用技巧

介绍了使用软件设计PCR引物的技巧。在PCR引物设计原则的基础上 ,详细介绍了两种常用引物设计软件的基本使用方法 ,并对其各自的优缺点进行了比较。一般性引物自动搜索可采用“PremierPrimer 5”软件 ,而引物的评价分析则可采用“Oli go6”软件。     

SNPbox: a modular software package for large-scale primer design

SUMMARY: We developed a modular software package SNPbox that automates and standardizes the generation of PCR primers and is used in the strategy for constructing single nucleotide polymorphisms (SNPs) maps. In this strategy, the focus of primer design can be either on the validation of annotated public SNPs or on the SNP discovery in exon regions or extended genomic regions, both by resequencing. SNPbox relies on Primer3 for the primer design and combines this program with other publicly available software tools such as BLAST, Spidey and RepeatMasker, and newly developed algorithms. Primer conditions were chosen such that PCR amplifications are uniform for each PCR amplicon facilitating the use of high-throughput genetic platforms. SNPbox can also be used for the design of primer sets for mutation analysis, STR marker genotyping and microarray oligo design. Of the 2500 primer sets designed by SNPbox, 95% successfully amplified genomic DNA under uniform PCR conditions. AVAILABILITY: The software is available from the authors upon request. SUPPLEMENTARY INFORMATION: SNPbox_supplement.     

Specific primer design for the polymerase chain reaction

The design of primers has a major impact on the success of PCR in relation to the specificity and yield of the amplified product. Here, we introduce the applications of PCR as well as the definition and characteristics for PCR primer design. Recent primer design tools based on Primer3, along with several computational intelligence-based primer design methods which have been applied in primer design, are also reviewed. In addition, characteristics of population-based methods used in primer design are discussed in detail.     

EasyExonPrimer

EasyExonPrimer is a web-based software that automates the design of PCR primers to amplify exon sequences from genomic DNA. EasyExonPrimer is written in Perl and uses Primer3 to design PCR primers based on the genome builds and annotation databases available at the University of California, Santa Cruz (UCSC) Genome Browser database (http://genome.ucsc.edu/). It masks repeats and known single nucleotide polymorphism (SNP) sites in the genome and designs standardised primers using optimised conditions. Users can input genes by RefSeq mRNA ID, gene name or keyword. The primer design is optimised for large-scale resequencing of exons. For exons larger than 1 kb, the user has the option of breaking the exon sequence down into overlapping smaller fragments. All primer pairs are then verified using the In-Silico PCR software to test for uniqueness in the genome. We have designed >1000 pairs of primers for 90 genes; 95% of the primer pairs successfully amplified exon sequences under standard PCR conditions without requiring further optimisation. AVAILABILITY: EasyExonPrimer is available from http://129.43.22.27/~primer/. The source code is also available upon request. CONTACT: Xiaolin Wu (forestwu@mail.nih.gov).     

MethyScan：一种甲基化特异性PCR引物设计及评估工具

DNA甲基化是重要的表观遗传现象,对基因表达发挥重要调控功能.大量研究表明,基因DNA甲基化是重要的临床诊断生物标志物.在临床上,实施快速、准确的DNA甲基化状态检测是诊断应用的前提和关键.甲基化特异性PCR(methylation specific PCR,MSP)通过将两种引物与甲基化、非甲基化模板各自特异性结合和扩增,实现基因甲基化状态的区分,是切实可行、简单便捷的临床诊断实验技术.但是,不同于常规PCR,MSP主要存在如何强化引物-甲基化/非甲基化模板特异性结合、降低引物序列Tm值差异、去除假阳性扩增及提高敏感性等四大难点.尽管大多数MSP引物设计软件对上述难题都提出了各自解决办法,但在引物设计影响因素考虑、设计与评估并行处理及特异性扩增预测等方面仍然存在较大缺陷.为此,本研究通过对MethPrimer、MSPPrimer、MethBlast、BiSearch等现有MSP引物设计软件原理的深入探究,以及对Bowtie、SAMtools和BEDTools等工具的有效综合整合,基于图形库Matplotlib和第三方Python功能库BioPython与Primer3-py实现了具有系列优点的甲基化特异性PCR引物设计与评估可视化工具MethyScan.它具有引物设计、基因组索引、引物评估等三大完整功能模块,不仅可快速进行MSP引物设计,实现巢式(Nested)引物适配,还可基于4种基因组碱基转换模板分析引物结合信息,图形化展示非特异性扩增与目的片段差异,从而综合评估引物特异性-非特异性扩增.同时,对食管癌、结直肠癌等多种恶性肿瘤中6个潜在生物标志物TFPI-2、NDRG4、CDKN2A、CD44、CASP8和SDHD的甲基化引物设计对比结果表明,MethyScan不仅可获得更多CpG位点的检测引物,而且所获得MSP引物位置与其他软件结果相同或相近,且引物间Tm值差值更小.总之,作为首个图形化展示特异性-非特异性扩增差异MSP引物设计工具,MethyScan可有效提高甲基化引物设计准确性,为临床DNA甲基化检测项目开展、检测试验实施及诊断试剂盒研发提供有力支撑.MethyScan工具下载地址:https://github.com/bioinfo-ibms-pumc/MethyScan.     

利用MPprimer设计引物并优化扩增条件以提高多重PCR效率的实验研究

多重PCR技术广泛应用于多个研究领域,其中引物设计及扩增条件是提高多重PCR实验效率的关键因素.为探讨优化多重PCR实验的方法,以小鼠5个看家基因为研究对象,使用实验室新近开发的MPprimer程序设计多重PCR引物,并通过改变多种反应条件来优化多重PCR实验.结果表明,MPprimer程序能够设计出理想的多重PCR引物,并且通过对退火温度及延伸时间进行优化,可显著提高多重PCR实验效率,对于提高基因表达的规模化检测能力具有积极的促进作用.     

基因结构分析软件对实时定量PCR引物进行设计和筛选

目的：以人丝裂原活化蛋白激酶3(mitogen-activated protein kinase 3, ) 基因结构为例,利用不同生物相关软件分析、 设计和筛选合适的定量PCR 引物。方法：利用NCBI 的Gene 数据库查找人基因的参考序列、UniGene 数据库查找标准 参考序列;并用在线软件如Spidey, UCSC, Ensembl 等分析基因结构;利用Primer3,Oligo6,IDT 等软件进行引物设计;用MFOLD 程序分析基因二级结构后,选择引物可定位的外显子位置;利用电子PCR进行引物扩增特异性的检验;最后通过实验检验引物的 扩增效果。结果：从程序软件推荐的引物列表中筛选出一对能特异扩增人基因的引物。结论：基因结构分析软件有助于定 量PCR 引物的设计。     

Greene SCPrimer: a rapid comprehensive tool for designing degenerate primers from multiple sequence alignments

Polymerase chain reaction (PCR) is widely applied in clinical and environmental microbiology. Primer design is key to the development of successful assays and is often performed manually by using multiple nucleic acid alignments. Few public software tools exist that allow comprehensive design of degenerate primers for large groups of related targets based on complex multiple sequence alignments. Here we present a method for designing such primers based on tree building followed by application of a set covering algorithm, and demonstrate its utility in compiling Multiplex PCR primer panels for detection and differentiation of viral pathogens.     

Comparative Assessment of 5′ A/T-Rich Overhang Sequences with Optimal and Sub-optimal Primers to Increase PCR Yields and Sensitivity

Efficient PCR amplifications require precisely designed and optimized oligonucleotide primers, components, and cycling conditions. Despite recent software development and reaction improvement, primer design can still be enhanced. The aims of this research are to understand (1) the effect on PCR efficiency and DNA yields of primer thermodynamics parameters, and (2) the incorporation of 5′ A/T-rich overhanging sequences (flaps) during primer design. Two primer sets, one optimal (ΔG = 0) and one sub-optimal (ΔG = 0.9), were designed using web interface software Primer3, BLASTn, and mFold to target a movement protein gene of Tobacco mosaic virus. The optimal primer set amplifies a product of 195 bp and supports higher PCR sensitivity and yields compared to the sub-optimal primer set, which amplifies a product of 192 bp. Greater fluorescence was obtained using optimal primers compared to that with sub-optimal primers. Primers designed with sub-optimal thermodynamics can be substantially improved by adding 5′ flaps. Results indicate that even if the performance of some primers can be improved substantially by 5′ flap addition, not all primers will be similarly improved. Optimal 5′ flap sequences are dependent on the primer sequences, and alter the primer’s T _m value. The manipulation of this feature may enhance primer’s efficiency to increase the PCR sensitivity and DNA yield.     

URPD: A Specific Product Primer Design Tool

ABSTRACT: BACKGROUND: Polymerase chain reaction (PCR) plays an important role in molecular biology. Primer design fundamentally determines its results. Here, we present a currently available software for a rather straight-forward way of visualizing the primer design process for infrequent users. RESULTS: URPD (yoUR Primer Design), a web-based specific product primer design tool, combines the NCBI Reference Sequences (RefSeq), UCSC In-Silico PCR, memetic algorithm (MA) and genetic algorithm (GA) primer design methods to obtain specific primer sets. A friendly user interface is accomplished by built-in parameter settings. The incorporated smooth pipeline operations effectively guide both occasional and advanced users. URPD contains an automated process, which produces feasible primer pairs that satisfy the specific needs of the experimental design with practical PCR amplifications. Visual virtual gel electrophoresis and in silico PCR provide a simulated PCR environment. The comparison of Practical gel electrophoresis comparison to virtual gel electrophoresis facilitates and verifies the PCR experiment. Wet-laboratory validation proved that the system provides feasible primers. CONCLUSIONS: URPD is a user-friendly tool that provides specific primer design results. The pipeline design path makes it easy to operate for beginners. URPD also provides a high throughput primer design function. Moreover, the advanced parameter settings assist sophisticated researchers in performing experiential PCR. Several novel functions, such as a nucleotide accession number template sequence input, local and global specificity estimation, primer pair redesign, user-interactive sequence scale selection, and virtual and practical PCR gel electrophoresis discrepancies have been developed and integrated into URPD. The URPD program is implemented in JAVA and freely available at http://bio.kuas.edu.tw/urpd/.     

MethPrimer: designing primers for methylation PCRs

MOTIVATION: DNA methylation is an epigenetic mechanism of gene regulation. Bisulfite- conversion-based PCR methods, such as bisulfite sequencing PCR (BSP) and methylation specific PCR (MSP), remain the most commonly used techniques for methylation mapping. Existing primer design programs developed for standard PCR cannot handle primer design for bisulfite-conversion-based PCRs due to changes in DNA sequence context caused by bisulfite treatment and many special constraints both on the primers and the region to be amplified for such experiments. Therefore, the present study was designed to develop a program for such applications. RESULTS: MethPrimer, based on Primer 3, is a program for designing PCR primers for methylation mapping. It first takes a DNA sequence as its input and searches the sequence for potential CpG islands. Primers are then picked around the predicted CpG islands or around regions specified by users. MethPrimer can design primers for BSP and MSP. Results of primer selection are delivered through a web browser in text and in graphic view.     

A thermodynamic approach to PCR primer design

We developed a primer design method, Pythia, in which state of the art DNA binding affinity computations are directly integrated into the primer design process. We use chemical reaction equilibrium analysis to integrate multiple binding energy calculations into a conservative measure of polymerase chain reaction (PCR) efficiency, and a precomputed index on genomic sequences to evaluate primer specificity. We show that Pythia can design primers with success rates comparable with those of current methods, but yields much higher coverage in difficult genomic regions. For example, in RepeatMasked sequences in the human genome, Pythia achieved a median coverage of 89% as compared with a median coverage of 51% for Primer3. For parameter settings yielding sensitivities of 81%, our method has a recall of 97%, compared with the Primer3 recall of 48%. Because our primer design approach is based on the chemistry of DNA interactions, it has fewer and more physically meaningful parameters than current methods, and is therefore easier to adjust to specific experimental requirements. Our software is freely available at http://pythia.sourceforge.net.     

Primer Prim'r: A web based server for automated primer design

The Northeast Structural Genomics Consortium (NESG) is one of nine NIH-funded pilot projects created to develop technologies needed for structural studies of proteins on a genome-wide scale. One of the most challenging aspects of this emerging field is the production of protein samples amenable to structural determination. To do this efficiently, all steps in the protein production pipeline must be automated. Here we describe the Primer program (linked from http://www-nmr.cabm.rutgers.edu/bioinformatics, www-nmr.cabm.rutgers.edu/bioinformatics, a web-based primer design program freely available to the scientific community, which was created to automate this time consuming and laborious task. This program has the ability to simultaneously calculate plasmid specific primer sets for multiple open reading frame (ORF) targets, including 96-well and greater formats. Primer includes a library of commonly used plasmid systems and possesses the ability to upload user-defined plasmid systems. In addition to calculating gene-specific annealing regions for each target, the program also adds appropriate restriction endonuclease recognition or viral recombination sites while preserving a reading frame with plasmid based fusions. Primer has several useful features such as sorting calculated primer sets by target size, facilitating interpretation of PCR amplifications by agarose gel electrophoresis, as well as supplying the molecular biologist with many important characteristics of each target such as the expected size of the PCR amplified DNA fragment and internal restriction sites. The NESG has cloned over 1500 genes using oligonucleotide primers designed by Primer.     

AutoDimer: a screening tool for primer-dimer and hairpin structures

The ability to select short DNA oligonucleotide sequences capable of binding solely to their intended target is of great importance in developing nucleic acid based detection technologies. Applications such as multiplex PCR rely on primers binding to unique regions in a genome. Competing side reactions with other primer pairs or template DNA decrease PCR efficiency: Freely available primer design software such as Primer3 screens for potential hairpin and primer-dimer interactions while selecting a single primer pair. The development of multiplex PCR assays (in the range of 5 to 20 loci) requires the screening of all primer pairs for potential cross-reactivity. However, a logistical problem results due to the number of total number of comparisons required. Comparing the primer set for a 10-plex assay (20 total primer sequences) results in 210 primer-primer combinations that must be screened. The ability to screen sets of candidate oligomers rapidly for potential cross-reactivity reduces overall assay devlelopment time. Here we report the application of a familiar sliding algorithm for comparing two strands of DNA in an overlapping fashion. The algorithm has been employed in a software package wherein the user can compare multiple sequences in a single computational run. After the screening is completed, a score is assigned to potential duplex interactions exceeding a user-defined threshold. Additional criteria of predicted melting temperature (Tm) and free energy of melting (deltaG) are included for further ranking. Sodium counterion and total stand concentrations can be adjusted for the Tm and deltaG calculations. The predicted interactions are saved in a text file for further evaluation.     

Optimization of primer design for the detection of variable genomic lesions in cancer

Primer approximation multiplex PCR (PAMP) is a new experimental protocol for efficiently assaying structural variation in genomes. PAMP is particularly suited to cancer genomes where the precise breakpoints of alterations such as deletions or translocations vary between patients. The design of PCR primer sets for PAMP is challenging because a large number of primer pairs are required to detect alterations in the hundreds of kilobases range that can occur in cancer. These sets of primers must achieve high coverage of the region of interest, while avoiding primer dimers and satisfying the physico-chemical constraints of good PCR primers. We describe a natural formulation of these constraints as a combinatorial optimization problem. We show that the PAMP primer design problem is NP-hard, and design algorithms based on simulated annealing and integer programming, that provide good solutions to this problem in practice. The algorithms are applied to a test region around the known CDKN2A deletion, which show excellent results even in a 1:49 mixture of mutated:wild-type cells. We use these test results to help set design parameters for larger problems. We can achieve near-optimal designs for regions close to 1 Mb.     

PCR引物特异性核查系统(PSC)的构建与应用

聚合酶链式反应(PCR)虽已广泛用于分子生物学研究中,然而PCR实验中的非特异性产物问题将直接影响PCR的效率,在多重PCR实验中更是如此。为了最大限度地降低非特异性产物的出现率,同时避免用户频繁使用Blast比对检查非特异性,我们开发了基于NCBI-Blast的引物评估和模板DNA特异性结合能力评估的核查系统PSC(Primer Specificity Checking,http://biocompute.bmi.ac.cn/PSC),并基于虚拟PCR实验确定了用于引物质量核查计算的多种参数,能够在线提供多个物种的引物特异性核查结果。该系统可以有效地对引物序列可能产生的所有非特异性扩增进行预测,有助于实验前引物优化或者对非特异扩增结果进行解释,最终达到提高PCR效率的目的。     

MRPrimer: a MapReduce-based method for the thorough design of valid and ranked primers for PCR

Primer design is a fundamental technique that is widely used for polymerase chain reaction (PCR). Although many methods have been proposed for primer design, they require a great deal of manual effort to generate feasible and valid primers, including homology tests on off-target sequences using BLAST-like tools. That approach is inconvenient for many target sequences of quantitative PCR (qPCR) due to considering the same stringent and allele-invariant constraints. To address this issue, we propose an entirely new method called MRPrimer that can design all feasible and valid primer pairs existing in a DNA database at once, while simultaneously checking a multitude of filtering constraints and validating primer specificity. Furthermore, MRPrimer suggests the best primer pair for each target sequence, based on a ranking method. Through qPCR analysis using 343 primer pairs and the corresponding sequencing and comparative analyses, we showed that the primer pairs designed by MRPrimer are very stable and effective for qPCR. In addition, MRPrimer is computationally efficient and scalable and therefore useful for quickly constructing an entire collection of feasible and valid primers for frequently updated databases like RefSeq. Furthermore, we suggest that MRPrimer can be utilized conveniently for experiments requiring primer design, especially real-time qPCR.     

Efficient primer design algorithms

MOTIVATION: Primer design involves various parameters such as string-based alignment scores, melting temperature, primer length and GC content. This entails a design approach from multicriteria decision making. Values of some of the criteria are easy to compute while others require intense calculations. RESULTS: The reference point method was found to be tractable for trading-off between deviations from ideal values of all the criteria. Some criteria computations are based on dynamic programs with value iteration whose run time can be bounded by a low-degree polynomial. For designing standard PCR primers, the scheme offers in a relative gain in computing speed of up to 50: 1 over ad-hoc computational methods. Single PCR primer pairs have been used as model systems in order to simplify the quantization of the computational acceleration factors. The program has been structured so as to facilitate the analysis of large numbers of primer pairs with minor modifications. The scheme significantly increases primer design throughput which in turn facilitates the use of oligonucleotides in a wide range of applications including: multiplex PCR and other nucleic acid-based amplification systems, as well as in zip code targeting, oligonucleotide microarrays and nucleic acid-based nanoengineering.