Mutagenic primer design for mismatch PCR-RFLP SNP genotyping using a genetic algorithm

Polymerase chain reaction-restriction fragment length polymorphism (PCR-RFLP) is useful in small-scale basic research studies of complex genetic diseases that are associated with single nucleotide polymorphism (SNP). Designing a feasible primer pair is an important work before performing PCR-RFLP for SNP genotyping. However, in many cases, restriction enzymes to discriminate the target SNP resulting in the primer design is not applicable. A mutagenic primer is introduced to solve this problem. GA-based Mismatch PCR-RFLP Primers Design (GAMPD) provides a method that uses a genetic algorithm to search for optimal mutagenic primers and available restriction enzymes from REBASE. In order to improve the efficiency of the proposed method, a mutagenic matrix is employed to judge whether a hypothetical mutagenic primer can discriminate the target SNP by digestion with available restriction enzymes. The available restriction enzymes for the target SNP are mined by the updated core of SNP-RFLPing. GAMPD has been used to simulate the SNPs in the human SLC6A4 gene under different parameter settings and compared with SNP Cutter for mismatch PCR-RFLP primer design. The in silico simulation of the proposed GAMPD program showed that it designs mismatch PCR-RFLP primers. The GAMPD program is implemented in JAVA and is freely available at http://bio.kuas.edu.tw/gampd/.     

Restriction site insertion-PCR (RSI-PCR) for rapid discrimination and typing of closely related microbial strains

Taking advantage of point mutations between DNA sequences of closely related microbial strains, PCR primers modified with respect to the target sequence at positions 2-5 near the 3' end were designed to obtain a fragment harbouring an artificial restriction site specific for a given strain. The modified forward primer coupled with a specific reverse primer allows for the amplification of DNA fragments which can be digested with the specific endonuclease only in those strains where the restriction site is inserted by the DNA polymerase. The effectiveness of the method, named restriction site insertion-PCR (RSI-PCR), was tested on isolates of the 'Bacillus cereus group' for the rapid typing and discrimination of these closely related strains.     

DePIE: Designing Primers for Protein Interaction Experiments

Several primer prediction and analysis programs have been developed for diverse applications. However, none of these existing programs can be directly used for the design of primers in protein interaction experiments, since proteins may have transmembrane domains (TMDs) and/or a signal peptide that must be excluded from experiments. Furthermore, it is frequently the case that a short restriction sequences must be added to each primer in order to clone PCR products into a given destination vectors for expression. DePIE, a web-based primer design tool, was developed to address these deficiencies. The program takes as input NCBI protein accession numbers and returns primer information including nucleotide sequences, thermodynamic melting temperature of the nucleotide sequences and the target positions. DePIE is implemented in JAVA, PERL and PHP and has proven to be very efficient in designing primers for our interaction experiments. DePIE services can be accessed at the web site: http://biocore.unl.edu/primer/primerPI.html.     

ELISA detection of restriction site polymorphisms in the pig ryanodine receptor locus

We compare two strategies for ELISA detection of restriction site polymorphisms (EDRSP) that are suitable for high-throughput genotyping of the pig ryanodine receptor point mutation (RYR1 ^hal ). In both procedures, target DNA is amplified by PCR with one primer that is 5′ biotinylated and a second primer that is 5′ fluoresceinylated. PCR products are captured in duplicate wells on a streptavidin-coated, 96-well plate. The duplicates may be treated in two ways. In a single restriction enzyme assay, one duplicate is exposed to a restriction enzyme that cuts one allele specifically, and the second duplicate is exposed to no restriction enzyme. In a dual restriction enzyme assay, the second replicate is exposed to a second restriction enzyme that cuts the alternate allele specifically. Thereafter, the two procedures are similar; anti-fluorescein antibodies conjugated to peroxidase are allowed to bind to the fluoresceinylated ends, the plate is washed, and a substrate is converted to a colored end product. The ratio of the absorbances in the two wells is used to classify subjects by genotype. When the dual restriction enzyme assay is run, three genotype groups are easily distinguishable. When the single restriction enzyme assay is run, heterozygotes generate values that may overlap with those of the homozygotes that are not cut by the restriction enzyme. Dual restriction enzyme assays are more accurate than single restriction enzyme assays; however, single restriction enzyme assays are sufficient for identifying pigs that carry RYR1 ^hal . Received: 30 December 1997 / Accepted: 20 April 1998     

ExPrimer: to design primers from exon--exon junctions

SUMMARY: ExPrimer is a web-based computer program to design primers mainly from a specified exon-exon junction (E-E-jn) of a gene of interest. The tool suggests the optimum primer-pair(s) of which the right (reverse) primer represents a particular E-E-jn of the mRNA. The 'product length' decides the location of the left primer. The results also include all other primer pairs considered and their 'scores'. ExPrimer can use the NCBI BLASTn program for sequence specificity of primers. The tool is useful in many areas of molecular biology research that involve hybridization of short sequences with mRNA or cDNA. AVAILABILITY: http://exprimer.ibab.ac.in/exprimer_html/exprimer.html     

CloneAssistant 1.0: a stand-alone software for automated cloning primer design

"CloneAssistant 1.0" is a stand-alone software compatible with the current Windows operating systems, which can automatically design cloning primers with full consideration of the sequence information of vectors and genes, cloning strategies, the principles of primer design, reading frames, position effects, and enzymatic reaction conditions for users. Five internal XML (extensible markup language) databases [restriction enzymes, plasmids, universal buffers, PCR (polymerase chain reaction) protection bases, and an MCS (multiple cloning site) double digest interference database] were established to serve as the basic support for "CloneAssistant 1.0". The primer pairs designed are sorted according to the difficulty of the follow-up experiments. Once a primer pair is selected by the user, detailed experimental guidance for this primer pair will be provided. In addition, "CloneAssistant 1.0" can be used for restriction map analysis, ORF (open reading frame) finding, sequence alignment and complementary analysis, translation, restriction enzyme and universal buffer queries, and isocaudamer analysis. "CloneAssistant 1.0" makes gene clone design much easier, and it can be freely downloaded from http://bis.zju.edu.cn/clone.     

DNA sequence heterogeneity in the gene encoding a 60-kilodalton extracellular protein of Listeria monocytogenes and other Listeria species.

Chromosomal DNA sequences from the 60 kilodalton protein gene of Listeria monocytogenes, amplified by the polymerase chain reaction, were used for restriction fragment length polymorphism differentiation of L. monocytogenes serotypes and other Listeria species. All 24 strains of L. monocytogenes examined produced an extracellular protein of molecular weight 60,000 (p60) as determined by Western blot analysis. Four of six other Listeria species had a protein that cross-reacted to antibodies to p60, but all differed in molecular weight, ranging from approximately 50,000 to 65,000. The gene encoding p60 was amplified from chromosomal DNA in all strains using polymerase chain reaction with a single primer pair. Restriction enzyme digestion with HindIII of the amplified product revealed a restriction pattern that was distinct between serotypes 1/2a and either 4b or 1/2b of L. monocytogenes. Of the other Listeria species, four strains that produced a cross-reacting protein likewise produced a polymerase chain reaction amplification product with the primer pair. Listeria innocua alone had a restriction pattern similar to that of Listeria monocytogenes serotype 4b and 1/2b. Genotypic heterogeneity, as revealed by DNA amplification and restriction endonuclease digestion of the p60 open reading frame, correlates with "electrophoretic type" grouping and may be related to differences in virulence mechanisms of Listeria monocytogenes and other Listeria species.     

AFLP: a new technique for DNA fingerprinting.

A novel DNA fingerprinting technique called AFLP is described. The AFLP technique is based on the selective PCR amplification of restriction fragments from a total digest of genomic DNA. The technique involves three steps: (i) restriction of the DNA and ligation of oligonucleotide adapters, (ii) selective amplification of sets of restriction fragments, and (iii) gel analysis of the amplified fragments. PCR amplification of restriction fragments is achieved by using the adapter and restriction site sequence as target sites for primer annealing. The selective amplification is achieved by the use of primers that extend into the restriction fragments, amplifying only those fragments in which the primer extensions match the nucleotides flanking the restriction sites. Using this method, sets of restriction fragments may be visualized by PCR without knowledge of nucleotide sequence. The method allows the specific co-amplification of high numbers of restriction fragments. The number of fragments that can be analyzed simultaneously, however, is dependent on the resolution of the detection system. Typically 50-100 restriction fragments are amplified and detected on denaturing polyacrylamide gels. The AFLP technique provides a novel and very powerful DNA fingerprinting technique for DNAs of any origin or complexity.     

Analysis by Polymerase Chain Reaction of α1 and α6 GABAA Receptor Subunit mRNAs in Individual Cerebellar Neurons After Whole-Cell Recordings

Abstract: With the use of the single-cell polymerase chain reaction (PCR), the GABA_A receptor subunit mRNA content was analyzed in granule and Purkinje neurons from rat cerebellar slices. We used an experimental protocol to assess simultaneously the presence of two subunits in each cell while electrophysiological recordings were performed with the whole-cell patch-clamp technique. Based on a computer alignment of the nucleotide sequence corresponding to α1 and α6 GABA_A receptor subunits, homologous regions were identified that allowed coamplification of both mRNAs using a single primer combination. The presence of selective restriction sites within the targeted templates allowed us to identify which receptor subunit mRNAs were coamplified by performing restriction enzyme-mediated cleavage of the amplification products. In all Purkinje neurons assayed, α1 subunit mRNA but not α6 mRNA was detected. In contrast, among individual granule neurons we found a heterogeneous distribution of the mRNA for the α1 and α6 GABA_A receptor subunits. A comparison of the results of the PCR amplification and the analysis of GABA-mediated inhibitory synaptic currents does not allow us to identify kinetic characteristics of synaptic currents that clearly correlate with the presence or the absence of α6 subunit mRNA.     

应用限制性显示PCR技术构建细菌poly(A)化mRNA的cDNA文库

针对细菌mRNA poly(A)化位点的高度多态性,利用oligo(dT)与poly(A)特异结合的特性,以oligo(dT)一纤维素纯化mRNA,并以oligo(dT)18为引物逆转录合成cDNA,用限制性内切酶消化cDNA,所得的限制性内切酶片段与通用接头相连,通过10个选择性引物组合进行选择性PCR,使各片段得以扩增并分布于10个亚组中,并进行克隆,成功地克隆了100多个基因片段,已对其中40个进行了测序分析,探讨了限制性显示PCR技术在细菌poly(A)化mRNA cDNA库构建中的应用价值。     

recA genotyping of Salmonella enteritidis phage type 4 isolates by restriction fragment length polymorphism analysis

AIMS: To subtype Salmonella enteritidis phage type 4 isolates by using recA genotyping. METHODS AND RESULTS: Random amplified polymorphic DNA analysis using a primer ERIC2 of 76 isolates of Salmonella enteritidis phage type 4 obtained in Northern Ireland in 1998 and in 1999 demonstrated the presence of five genotypes. Restriction fragment length polymorphism analysis, using a degenerate primer pair designed to amplify a segment (about 640 bp in length) of the recA gene from several members of the Enterobacteriaceae with restriction enzymes, HhaI and Sau3AI, showed that the resulting fragments could differentiate the isolates into three groups, respectively. CONCLUSION: recA gene amplification and HhaI and Sau3AI restriction digestion was demonstrated to increase the differentiating power between isolates of Salmonella enteritidis phage type 4 by combining the patterns of the random amplified polymorphic DNA analysis procedure using a primer ERIC2. Significance and Impact of the Study: A novel restriction fragment length polymorphism assay for isolates of Salmonella enteritidis phage type 4, based on the amplification of the recA gene was attained and its comparison and its combination with random amplified polymorphic DNA analysis was provided.     

Map construction of sequence-tagged sites (STSs) in barley (Hordeum vulgare L.)

 In order to identify sequence-tagged sites (STSs) appropriate for recombinant inbred lines (RILs) of barley cultivars ‘Azumamugi’ × ‘Kanto Nakate Gold’, a total of 43 STS primer pairs were generated on the basis of the terminal sequences of barley restriction fragment length polymorphism (RFLP) clones. Forty one of the 43 primer pairs amplified PCR products in Azumamugi, Kanto Nakate Gold, or both. Of these, two showed a length polymorphism and two showed the presence or absence of polymorphism between the parents. PCR products of the remaining 37 primers were digested with 46 restriction endonucleases, and polymorphisms were detected for 15 primers. A 383.6-cM linkage map of RILs of Azumamugi×Kanto Nakate Gold was constructed from the 19 polymorphic STS primer pairs (20 loci) developed in this study, 45 previously developed STS primer pairs (47 loci), and two morphological loci. Linkage analysis and analysis of wheat-barley chromosome addition lines showed that with three exceptions, the chromosome locations of the STS markers were identical with those of the RFLP markers. Received: 4 August 1998 / Accepted: 8 October 1998     

Transfer of sequence tagged site PCR markers between wheat and barley.

Transfer of mapping information between related species has facilitated the development of restriction fragment length polymorphism (RFLP) maps in the cereals. Sequence tagged site (STS) primer sets for use in the polymerase chain reaction may be developed from mapped RFLP clones. For this study, we mapped 97 STS primer sets to chromosomes in wheat and barley to determine the potential transferability of the primer sets and the degree of correspondence between RFLP and STS locations. STS products mapped to the same chromosome group in wheat and barley 75% of the time. RFLP location predicted STS location 69% of the time in wheat and 56% of the time in barley. Southern hybridizations showed that most primer sets amplified sequences homologous to the RFLP clone, although additional sequences were often amplified that did not hybridize to the RFLP clone. Nontarget sequences were often amplified when primer sets were transferred across species. In general, results suggest a good probability of success in transferring STSs between wheat and barley, and that RFLP location can be used to predict STS location. However, transferability of STSs cannot be assumed, suggesting a need for recombinational mapping of STS markers in each species as new primer sets are developed. Key words : sequence tagged sites, PCR, wheat, barley.     

Efficient procedure for site-directed mutagenesis mediated by PCR insertion of a novel restriction site

Better understanding of proteins'' structure/function relationship and dissecting their functional domains are still challenges yet to be mastered. Site-directed mutagenesis approaches that can alter bases at precise positions on the gene sequence can help to reach this goal. This article describes an efficient strategy that can be applied not only for both deletion and substitution of target amino acids, but also for insertion of point mutations in promoter regions to study cis-regulating elements. This method takes advantage of the plasticity of the genetic code and the use of compatible restriction sites.Key words: site-directed mutagenesis, restriction site, cloning, PCRUnderstanding the proteins structure/function relationship and dissecting their functional domains is one of the biggest challenges to current proteomic studies.¹ This is mainly achieved by site-directed mutagenesis experiments that can alter bases at precise positions on the gene sequence.² Modifying DNA sequences has become feasible with PCR amplification.³ During the last decade, several strategies have been developed to simplify this approach and increase its efficiency.⁴ The introduction of a site-directed mutation can be realized by one or more PCR reactions. Most of the strategies used in site-directed mutagenesis are based on a substitution of a single base, which leads to a change in one amino acid. This article describes an efficient strategy that can be applied for either deletion or substitution of target amino acids. This strategy is based on performing PCR reactions to create a new restriction site in the sequence of origin, corresponding to the desired mutation. The choice of the restriction site to be created depends on the nature of the amino acid that one desires to introduce in the protein sequence. Since such restriction sites may extend beyond the mutated codon. The preservation of the other codon is done by taking advantage of the plasticity of the genetic code where one amino acid can be encoded by multiple codons.This method was performed in two steps (Fig. 1). In the first step, the DNA sequence of interest, cloned in a plasmid, served as a template for two PCR reactions. Two PCR products are generated. The first one consists of the beginning of the sequence, from the start codon to the mutagenized amino acid codon, where the forward primer bears the start codon region and the reverse primer bears the newly introduced restriction site at the same location of the mutagenized codon. The second PCR product consists of the end of the coding sequence, from the mutagenized amino acid codon to the stop codon. This fragment is generated using a forward primer bearing the same new restriction site as the first PCR product''s reverse primer, and a reverse primer bearing the stop codon region. The two PCR products were cloned separately into a vector in the appropriate orientation. In the second step, the cloning vector bearing the first PCR product was digested with a restriction enzyme site in the vector, and by the restriction enzyme corresponding to the restriction site created by the reverse primer used in the PCR reaction. The resulting fragment was cloned into the vector containing the second PCR fragment, predigested with same two restriction enzymes. The whole mutagenized coding sequence is reassembled by in-frame subcloning of the 3′ end of the coding sequence downstream the 5′ end. All the PCR products were generated using the high fidelity Pfu DNA Polymerase (Promega, Madison, WI USA). For any site-directed mutagenesis experiment, this two-step cloning procedure requires the use of appropriate PCR primers that harbor the desired mutation of the target amino acid. These primers are partially overlapping and contain a common or complementary restriction site enabling the in-frame assembly of the whole coding sequence.Open in a separate windowFigure 1Mutagenesis strategy by restriction enzyme site insertion. (A) In the first step, two PCR products were generated using the full length coding sequence as template. The mutation is carried by the two primers b and c, which are flanked by the same or compatible restriction enzyme''s site (white segment). Both PCR products are separately cloned in the cloning vector in the appropriate orientation. In the second step, the whole mutagenized coding sequence is reassembled by in-frame sub cloning of the 3′ end of the coding sequence downstream the 5′ end. (B) Substitution of threonine by arginine as a result of the insertion of a BglII restriction site. DNA sequencing is carried out to make sure that only the desired change is introduced in the coding sequence. (B-1) The sequence of the native cDNA. (B-2) the sequence of the mutagenized cDNA included BglII restriction site sequence.This approach has been used in a recent study to address the structure/function relationship of the STAS domain of the Arabidopsis thaliana Sultr1;2 sulfate transporter.⁵ A good example of this approach is the replacement of the threonine-serine couple at position 587–588 with an arginine-serine couple. The codon for threonine is: TGT, and that for arginine is: TCT. Serine can be encoded by both TCA and AGA codons. The chosen restriction site used for the reassembly of the whole coding sequence is that of the BglII enzyme: TCT AGA. The insertion of this restriction site enables the substitution of the Thr in position 587 with an Arg while preserving the serine residue in position 588. The BglII restriction site is introduced in the reverse primer and the forward primer used to generate the first and second PCR products respectively. The DNA sequence of the reassembled mutagenized cDNA was checked by sequencing. Than it was expressed, under pGAL1O promoter bearing by pYES2 vector, in yeast mutant deficient in sulfate transporter and the mutagenic protein was detected by imunodetection.Bioinformatic study reveals that this method can be applied to checked a large number of substitutions, insertions or deletions and that finding the right restriction site is not a limiting factor (data no shown).In conclusion, this article describes an efficient two-step procedure for site-directed mutagenesis using primers bearing a restriction site, which is absent from the sequence of origin. The primers flanked by sequences introducing the same or compatible restriction sites mediate the incorporation of the mutation at the selection site. The choice of the restriction site depends on the nature of the desired mutation: insertion, substitution or deletion of an amino acid in a particular position. This strategy can be also used to insert point mutations in promoter regions to study cis-regulating elements.     

Development of Ty1-copia retrotransposon-based SSAP molecular markers for the study of genetic diversity in peach

Sequence-specific amplified polymorphism (SSAP) technology is a novel, anchored PCR approach derived from AFLP, which amplifies the region between a transposon insertion and an adjacent restriction site and have higher levels of polymorphism. In the current study, we developed 16 SSAP markers based on the long terminal repeat (LTR) sequences of Ty1-copia retrotransposons in the peach and used them for DNA profiling of 52 individual peaches: 44 peach cultivars and 8 ornamental peaches. These primer combinations produced a total of 1,553 fragments and 1,517 polymorphic bands with a polymorphism percentage of 97.7%. Furthermore, the Shannon's information index of each primer combination ranged from 0.1593 to 0.4456. Neighbor-joining analyses revealed two main genetic clusters, corresponding to the fruit flesh types: (A-1) MF (melting flesh) with clingstone and ornamental peaches; (A-2) MF with freestone and NMF (non-melting flesh) with clingstone. Finally, cluster analyses revealed that all ornamental peaches are closely related to the MF with clingstone peach cultivars. The application of these primer combinations identified using SSAP will facilitate future cultivar identification and germplasm management in peaches.     

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。     

Very efficient template/primer-independent DNA synthesis by thermophilic DNA polymerase in the presence of a thermophilic restriction endonuclease

We have found that, in the presence of a thermophilic restriction endonuclease, thermophilic DNA polymerase efficiently synthesizes and amplifies DNA in the absence of any added template and primer nucleic acid under isothermal conditions. More than 10 microg of DNA can be synthesized by 1 unit of DNA polymerase in 1 h, and the reaction proceeds until available dNTPs are consumed. We used mostly the Tsp509I restriction endonuclease (recognition sequence: decreasing AATT), the TspRI restriction endonuclease (recognition sequence: NNCA(G/C)TGNN decreasing), and Vent (exo(-)) and Vent DNA polymerase. The synthesized double-stranded DNA has a highly repetitive palindromic sequence, e.g. (AAAAATTTTT)(n) and (ATACACTGTATATACAGTGTAT)(n). In every repeating unit, there are one or two recognition sites for the restriction enzyme. Our data show that the high efficiency of the restriction-endonuclease-DNA-polymerase (RE-pol) DNA synthesis results from an efficient exponential amplification involving digestion-elongation cycles: a longer DNA with numerous recognition sites for the restriction enzyme is digested to short fragments, and the short fragments are used as seeds for elongation to synthesize longer DNA. A possible role of RE-pol DNA synthesis in the evolutionary development of genetic materials is briefly discussed.     

A high-resolution, fluorescence-based, semiautomated method for DNA fingerprinting

We describe a fluorescence-based method for the automated analysis of DNA fragments on polyacrylamide gels. A single-stranded oligonucleotide primer (18-mer) with a fluorochrome covalently bound to its 5'-end is annealed to a synthetic oligonucleotide to create a double-stranded oligonucleotide linker with a 5'-overhang complementary to a restriction enzyme site. Cosmid or plasmid DNA is digested with the appropriate restriction enzyme and then ligated to the fluorochrome-labeled linker. The labeled restriction fragments are loaded on a denaturing polyacrylamide gel in a commercially available DNA sequencer. As the restriction fragments migrate through the gel, they intersect a laser beam which excites the fluorochrome-labeled fragment. Fluorescence emission data are captured on a computer in real time and analyzed after the completion of electrophoresis. Fragment length is nearly linearly related to migration time. This method offers very near single-base resolution up to 400 bases and the ability to quantitate fragment size up to 2000 bases. The fluorochrome-labeling chemistry relies on straightforward enzymatic reactions and can be performed in a single reaction tube. Because four different fluorochromes can be used, each of 16 lanes on the gel can be used to analyze four different digest reactions, one in each color. One of the fluorochromes can be used to label size standards in each lane, eliminating interlane variability and allowing more precise estimates of fragment size. We apply the method to the analysis of overlapping cosmids.