PrimerCE: Designing Primers for Cloning and Gene Expression

A number of primer design programs have been developed for diverse applications. However, none of these programs can be used to design primers for gene cloning aimed at expressing protein. Here we report the design of PrimerCE, which can be used to cover the whole process of gene cloning and expression. The main features of PrimerCE include inspection of restriction enzyme recognition sequence, open reading frame verification, stop codon inspection, base adjustment, primer optimization, sequence assembly and protein analysis. In addition to this, the program can be modified based on the different needs of users, e.g. new vector sequence and restriction enzyme recognition sequences can be integrated. With the use of PrimerCE, a pair of primers can be designed within minutes. The program has been proven to be efficient in designing primers in our high throughput cloning and gene expression experiments. The software is freely available at .     

CODEHOP (COnsensus-DEgenerate Hybrid Oligonucleotide Primer) PCR primer design

We have developed a new primer design strategy for PCR amplification of distantly related gene sequences based on consensus-degenerate hybrid oligonucleotide primers (CODEHOPs). An interactive program has been written to design CODEHOP PCR primers from conserved blocks of amino acids within multiply-aligned protein sequences. Each CODEHOP consists of a pool of related primers containing all possible nucleotide sequences encoding 3-4 highly conserved amino acids within a 3' degenerate core. A longer 5' non-degenerate clamp region contains the most probable nucleotide predicted for each flanking codon. CODEHOPs are used in PCR amplification to isolate distantly related sequences encoding the conserved amino acid sequence. The primer design software and the CODEHOP PCR strategy have been utilized for the identification and characterization of new gene orthologs and paralogs in different plant, animal and bacterial species. In addition, this approach has been successful in identifying new pathogen species. The CODEHOP designer (http://blocks.fhcrc.org/codehop.html) is linked to BlockMaker and the Multiple Alignment Processor within the Blocks Database World Wide Web (http://blocks.fhcrc.org).     

用于聚合酶链式反应(PCR)引物设计的计算机程序

 本文报道了两个用于PCR引物设计的计算机程序PCRDESN和PCRDESNA。PCRDESN程序主要从以下4个方面评价用户自己设计的一对引物的质量:(1)引物内的碱基反向重复或发夹结构,(2)两个引物之间的碱基互补配对,(3)两个引物之间的同源性,(4)引物的碱基组成及特点和T_m值计算。通过用多例文献发表的及本院有关实验室提供的引物对序列的验证,确定了程序的运算参数,证明该程序能较好地检验引物对的质量和解释某些PCR实验失败的原因。PCRDESNA程序采用逐级优化的方法和比PCRDESN所选用的更严紧的引物选择参数对用户提供的核酸序列进行快速检索,以确定所有可能的和合适的引物对。     

insilico.mutagenesis: a primer selection tool designed for sequence scanning applications used in directed evolution experiments

Several primer prediction programs have been developed for a variety of applications. However none of these tools allows the prediction of a large set of primers for whole gene site-directed mutagenesis experiments using the megaprimer method. We report a novel primer prediction tool (insilico.mutagenesis), accessible at www.insilico.uni-duesseldorf.de, developed for the application to high-throughput mutagenesis used in directed evolution or structure-function dependency projects, which involve the subsequent mutagenesis of a large number of amino acid positions (e.g., in whole gene saturation or gene scanning mutagenesis experiments). Furthermore, the program is suitable for all site-directed (saturation) mutagenesis approaches, such as saturation mutagenesis of promoter sequences and other types of untranslated intergenic regions. In anticipation of downstream cloning steps, the primer design tool also includes a restriction site control feature alerting the user if unwanted restriction sites have been introduced within the mutagenesis primer. The use of our tool promises to speed up the process of site-directed mutagenesis, as it instantly allows predicting a large set of primers.     

PrimerIdent: A web based tool for conserved primer design

Conserved primers across multiple species and simultaneously specific for a certain isozyme can be rare and difficult to find. PrimerIdent was developed aiming to automate this primer design and selection process in a given nucleotide sequence alignment, providing an intuitive, easy to interpret graphical result, which offers a list of all possible primers that meet the user criteria, with a colour-code identity to each sequence in the alignment. The software here presented is a simple and intuitive web based tool that is suitable for distinguishing very similar nucleotide sequences, such as isozymes-coding sequences, to enable the conserved primer design across multiple species, necessary for approaches that rely on knowing if a primer is suitable for a certain set of pre-aligned sequences, to design a specific primer to a certain sequence variation, or a combination thereof. This extremely useful software can, therefore, be used as a tool for the specific amplification of individual members of multigenic families across related species and also to evaluate the differential expression of isogenes for a given species. AVAILABILITY: http://primerident.up.pt.     

Thermodynamically balanced inside-out (TBIO) PCR-based gene synthesis: a novel method of primer design for high-fidelity assembly of longer gene sequences

A novel thermodynamically-balanced inside-out (TBIO) method of primer design was developed and compared with a thermodynamically-balanced conventional (TBC) method of primer design for PCR-based gene synthesis of codon-optimized gene sequences for the human protein kinase B-2 (PKB2; 1494 bp), p70 ribosomal S6 subunit protein kinase-1 (S6K1; 1622 bp) and phosphoinositide-dependent protein kinase-1 (PDK1; 1712 bp). Each of the 60mer TBIO primers coded for identical nucleotide regions that the 60mer TBC primers covered, except that half of the TBIO primers were reverse complement sequences. In addition, the TBIO and TBC primers contained identical regions of temperature- optimized primer overlaps. The TBC method was optimized to generate sequential overlapping fragments (~0.4–0.5 kb) for each of the gene sequences, and simultaneous and sequential combinations of overlapping fragments were tested for their ability to be assembled under an array of PCR conditions. However, no fully synthesized gene sequences could be obtained by this approach. In contrast, the TBIO method generated an initial central fragment (~0.4–0.5 kb), which could be gel purified and used for further inside-out bidirectional elongation by additional increments of 0.4–0.5 kb. By using the newly developed TBIO method of PCR-based gene synthesis, error-free synthetic genes for the human protein kinases PKB2, S6K1 and PDK1 were obtained with little or no corrective mutagenesis.     

PRaTo: a web-tool to select optimal primer pairs for qPCR

An essential pre-requisite to perform sound quantitative real-time polymerase chain reaction (qPCR) assays is to design outstanding primer pairs. This means they must have a good efficiency and be not prone to produce multiple amplicons or primer dimer products. To circumvent these issues, several softwares are available to help primer design. Although satisfactory computer-aided primer design tools are available for standard PCR, less efforts were done to provide specific methods for selection of optimal primer pairs for qPCR. We have developed PRaTo a web-based tool that enables checking and ranking of primers pairs for their attitude to perform optimally and reliably when used in qPCR experiments. PRaTo is available at http://prato.daapv.unipd.it.     

GONOME: measuring correlations between GO terms and genomic positions

Background

The design of oligonucleotides and PCR primers for studying large genomes is complicated by the redundancy of sequences. The eukaryotic genomes are particularly difficult to study due to abundant repeats. The speed of most existing primer evaluation programs is not sufficient for large-scale experiments.

Results

In order to improve the efficiency and success rate of automatic primer/oligo design, we created a novel method which allows rapid masking of repeats in large sequence files, for example in eukaryotic genomes. It also allows the detection of all alternative binding sites of PCR primers and the prediction of PCR products. The new method was implemented in a collection of efficient programs, the GENOMEMASKER package. The performance of the programs was compared to other similar programs. We also modified the PRIMER3 program, to be able to design primers from lowercase-masked sequences.

Conclusion

The GENOMEMASKER package is able to mask the entire human genome for non-unique primers within 6 hours and find locations of all binding sites for 10 000 designed primer pairs within 10 minutes. Additionally, it predicts all alternative PCR products from large genomes for given primer pairs.     

Flexgrepps--flexible greedy peptide pool search: computation of near-optimal sets of degenerate polypeptides for antigenic screening

Although synthesizing and utilizing individual peptides and DNA primers has become relatively inexpensive, massively parallel probing and next-generation sequencing approaches have dramatically increased the number of molecules that can be subjected to screening; this, in turn, requires vast numbers of peptides and therefore results in significant expenses. To alleviate this issue, pools of related molecules are often used to downselect prior to testing individual sequences. A computational selection process to create pools of related sequences at large scale has not been reported for peptides. In the case of PCR primers, there have been successful attempts to address this problem by designing degenerate primers that can be produced at the same cost as conventional, unique primers and then be used to amplify several different genomic regions. We present an algorithm, "FlexGrePPS" (Flexible Greedy Peptide Pool Search), that can create a near-optimal set of peptide pools. This approach is also applicable to nucleotide sequences and outperforms most DNA primer selection programs. For the proteomic compression with FlexGrePPS, the main body of our work presented here, we demonstrate the feasibility of the computation of an exhaustive cover of pathogenic proteomes with degenerate peptides that lend themselves to antigenic screening. Furthermore, we present preliminary data that demonstrate the experimental utility of highly degenerate peptides for antigenic screening. FlexGrePPS provides a near-optimal solution for proteomic compression and there are no programs available for comparison. We also demonstrate computational performance of our GreedyPrime implementation, which is a modified version of FlexGrePPS applicable to the design of degenerate primers and is comparable to existing programs for the design of degenerate primers. Specifically, we focus on the comparisons with PAMPS and DPS-DIP, software tools that have recently been shown to be superior to other methods. FlexGrePPS forms the foundation of a novel antigenic screening methodology that is based on the representation of an entire proteome by near-optimal degenerate peptide pools. Our preliminary wet lab data indicate that the approach will likely prove successful in comprehensive wet lab studies, and hence will dramatically reduce the expenses for antigenic screening and make whole proteome screening feasible. Although FlexGrePPS was designed for computational performance in order to handle vast data sets, there is the very surprising finding that even for small data sets the primer design version of FlexGrePPS, GreedyPrime, offers similar or even superior results for MP-DPD and most MDPD instances when compared to existing methods; despite the much longer run times, other approaches did not fare significantly better in reducing the original data sets to degenerate primers. The FlexGrePPS and GreedyPrime programs are available at no charge under the GNU LGPL license at http://sourceforge.net/projects/flexgrepps/.     

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).     

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.     

DNA聚合酶与引物/模板的相互作用对PCR效率的影响

PCR是体外酶促合成特异DNA片段的一种方法,引物的优劣直接关系到PCR的特异性与成功与否。传统的PCR引物设计软件基本上忽略了DNA聚合酶与引物/模板的亲和性对PCR效率的影响。为揭示DNA聚合酶与引物/模板的相互作用是否对PCR的效率有影响,通过构建Taq DNA 聚合酶与不同序列引物/模板DNA相互作用的三维结构模型,采用MM/GBSA方法计算复合物的结合自由能,以结合自由能为参数,为人血清白蛋白基因(Human Serum Albumin gene,HSA gene)和结核杆菌pyrF基因(Mycobacterium tuberculosis pyrF gene)设计了PCR引物。PCR实验结果表明,引物的PCR效率与结合自由能相关：引物与聚合酶的结合自由能越低,PCR实验的效率相对越高。这说明DNA聚合酶与引物/模板的相互作用对PCR效率有重要影响。因此,引物/模板DNA与聚合酶的结合自由能可以作为PCR引物设计的新参数。     

ROCK: a spreadsheet-based program for the generation and analysis of random oligonucleotide primers used in PCR.

Oligonucleotide primers used to amplify target DNA regions via PCR should meet certain design criteria to maximize the potential for efficient priming. The Random Oligonucleotide Construction Kit (ROCK), a spreadsheet-based program that runs under Microsoft Excel 97 or later version for Microsoft Windows, was developed to facilitate the design of efficient random oligonucleotide primers. Primer sequences are generated that meet user-defined criteria with regard to G + C content, size of a 3' GC clamp, maximum intramolecular/intermolecular complementation potential, and maximum intersequence similarity. The user can analyze the intramolecular/intermolecular complementation potential of program-generated primer sequences or of sequences entered manually. The latter may contain any of the standard nucleotide symbols, including ambiguous bases. Primer sequence length, GC%, individual base composition, molecular weight, approximate melting temperature, and mass/volume/concentration relationships can be determined for any sequence generated by ROCK or entered manually.     

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.     

Development of a real-time PCR assay for the detection of Cladosporium fulvum in tomato leaves

Aims: The aim of this study was to develop a sensitive real-time polymerase chain reaction (PCR) assay for the rapid detection of Cladosporium fulvum in tomato leaves. Methods and Results: Three PCR primer pairs were designed based on the nucleotide sequences of: (i) the internal transcribed spacer regions of ribosomal RNA; (ii) a microsatellite region amplified by the microsatellite primer M13; and (iii) the β-tubulin gene of C. fulvum. Each primer pair amplified the expected target DNA fragment from geographically diverse isolates of C. fulvum. No PCR products were amplified with these primer pairs from DNA of other fungal species. Among the three pairs of primers, the primer pair CfF1/CfR1 developed based on the microsatellite region was the most sensitive. Using this sensitive primer pair, a real-time PCR assay was developed to detect early infection of C. fulvum in tomato leaves. Significance and Impact of the Study: DNA regions amplified by the microsatellite primer M13 have a high potential for developing highly sensitive species-specific PCR primers for the detection of phytopathogenic fungi. The real-time PCR assay developed in this study is useful in monitoring early infection of C. fulvum, and can help growers make timely decisions on fungicide application.     

Predicting failure rate of PCR in large genomes

We have developed statistical models for estimating the failure rate of polymerase chain reaction (PCR) primers using 236 primer sequence-related factors. The model involved 1314 primer pairs and is based on more than 80 000 PCR experiments. We found that the most important factor in determining PCR failure is the number of predicted primer-binding sites in the genomic DNA. We also compared different ways of defining primer-binding sites (fixed length word versus thermodynamic model; exact match versus matches including 1–2 mismatches). We found that the most efficient prediction of PCR failure rates can be achieved using a combination of four factors (number of primer-binding sites counted in different ways plus GC% of the primer) combined into single statistical model GM1. According to our estimations from experimental data, the GM1 model can reduce the average failure rate of PCR primers nearly 3-fold (from 17% to 6%). The GM1 model can easily be implemented in software to premask genome sequences for potentially failing PCR primers, thus improving large-scale PCR-primer design.     

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.     

UniquePrimer — a web utility for design of specific PCR primers and probes

We have developed a web-based tool for design of specific PCR primers and probes. The program allows you to enter primer sequence information as well as an optional probe, and sequence similarity searches (MegaBLAST) will be performed to see if the sequences match the same sequence entry in the specified database. If primers (and probe) match, this will be reported. The program can handle overlapping amplicons, amplification from a single primer, ambiguous bases and other problematic cases.