Molecular haplotype determination using allele-specific PCR and pyrosequencing technology

Haplotyping of single-nucleotide polymorphisms (SNPs) is usually performed statistically by computational analysis or by time-consuming cloning techniques. Here we present a simple molecular approach for reliable haplotype determination on individual samples. The procedure is based on allele-specific PCR (AS-PCR) in combination with Pyrosequencing analysis. AS-PCR primers for each allelic variant of the investigated SNPs were used. A mismatch introduced at the second base from the 3' end dramatically improved allele specificity. Analysis of multiple SNPs on amplified fragments using Pyrosequencing technology allowed determination of haplotypes. Genotyping of heterozygote samples after AS-PCR gave a typical monoallelic pattern at each SNP, in which the identity of the present allele depended on the allele-specific initial amplification. Haplotype determination by the described procedure proved to be highly reliable. The results obtained by Pyrosequencing technology have the benefit of being truly quantitative, enabling detection of any nonspecific allele amplification.     

Single nucleotide polymorphism genotyping using allele-specific PCR and fluorescence melting curves

We present a PCR method for identification of single nucleotide polymorphisms (SNPs), using allele-specific primers designed for selective amplification of each allele. Matching the SNP at the 3' end of the forward or reverse primer, and additionally incorporating a 3' mismatch to prevent amplification of the incorrect allele, results in selectivity of the allele-specific primers. DNA melting analysis with fluorescent SYBR Green affords detection of the PCR products. By incorporating a GC-rich sequence into one of the two allele-specific primers to increase the melting temperature, both alleles can be measured simultaneously at their respective melting temperatures. Applying the DNA melting analysis to SNPs in ApoE and ABCA1 yielded results identical to those obtained with other genotyping methods. This provides a cost-effective, high-throughput method for amplification and scoring of SNPs.     

Cloning of two classes of PR genes and the development of SNAP markers for powdery mildew resistance loci in chestnut rose (<Emphasis Type="Italic">Rosa roxburghii</Emphasis> Tratt)

Pathogenesis-related (PR) genes were isolated from chestnut rose (Rosa roxburghii Tratt) using a PCR approach with degenerate primers designed for the conserved regions of two PR gene families: class 2 (β-1,3-glucanase) and class 5 (osmotin). Thirteen PR2 and ten PR5 genes were obtained, with a nucleotide identity that ranged from 40.1 to 99.7% and from 99.2 to 99.8%, respectively. Sequence comparison revealed the presence of single nucleotide polymorphisms (SNPs) in these sequences with, on an average, one SNP in every 64-bp fragment for the PR2 genes and one in every 68-bp fragment for the PR5 genes. A total of 23 primers were used to genotype these SNPs for use in developing single nucleotide-amplified polymorphisms (SNAP) markers. One marker (Glu7) was found to be linked to powdery mildew resistance loci. Based on genetic mapping of a segregating F₁ population, we determined that 16 of the 23 SNAP markers formed one group and subsequently detected a quantitative trait locus that accounted for 12% of the variation in the powdery mildew resistance phenotype. The results of this study provide a first insight into the genomic structure of PR genes and show that the candidate gene approach in combination with SNAP markers is an attractive strategy to search for powdery mildew resistance loci in chestnut rose.     

Electrophoretic detection of single-nucleotide polymorphisms

Single-nucleotide polymorphisms (SNPs) represent the most prevalent class of genetic markers available for linkage disequilibrium or cladistic analyses. PCR primers may be labeled with fluorescent dyes and used to rapidly and accurately differentiate among alleles that are defined by a single-nucleotide differences. Here, we describe the primer-mediated detection of SNPs based on primer mismatch during allele-specific amplification of preamplified target sequences. Primers are labeled with different fluors at their 5' nucleotides, with their 3' termini at the transition mutation that defines allelic variation at the target locus. Each primer perfectly matches one of the two available alleles for each locus. Electrophoretic detection permits characterization of the product both by size and fluor. This report demonstrates some of the capabilities of this assay, including heterozygote determination and multiplexed analysis.     

A simple method to score single nucleotide polymorphisms based on allele‐specific PCR and primer‐induced fragment‐length variation

We describe a simple protocol to genotype single nucleotide polymorphisms (SNPs), which combines allele‐specific polymerase chain reaction (PCR) with fragment‐length analysis. Three primers are used in the PCR: two allele‐specific forward primers with a length‐difference and one reverse primer. The forward primers induce a length‐difference between the SNP‐variants, which can be assessed with standard fragment‐length analyses. We designed primers for 21 SNPs, and codominance was achieved for 76% of these SNPs. An inexpensive and flexible laser‐detection scoring protocol can be achieved with multiplex scoring and by incorporating the M13(‐21) genotyping method.     

Single-reaction for SNP Genotyping on Agarose Gel by Allele-specific PCR in Black Poplar (Populus nigra L.)

The wide development of single nucleotide polymorphism (SNP) markers also in non-model species increases the need for inexpensive methods that do not require sophisticated equipment and time for optimization. This work presents a new method for polymerase chain reaction (PCR) amplification of multiple specific alleles (PAMSA), which allows efficient discrimination of SNP polymorphisms in one reaction tube with standard PCR conditions. This improved PAMSA requires only three unlabeled primers: a common reverse primer and two allele-specific primers having a tail of different length to differentiate the two SNP alleles by the size of amplification products on agarose gel. A destabilizing mismatch within the five bases of the 3′ end is also added to improve the allele specificity. To validate the accuracy of this method, 94 full-sib individuals were genotyped with three SNPs and compared to the genotypes obtained by cleaved amplified polymorphic sequence (CAPS) or derived CAPS. This method is flexible, inexpensive, and well suited for high throughput and automated genotyping.     

Development of reliable PCR-based markers linked to downy mildew resistance genes in lettuce

Summary Sequence characterized amplified regions (SCARs) were derived from eight random amplified polymorphic DNA (RAPD) markers linked to disease resistance genes in lettuce. SCARs are PCR-based markers that represent single, genetically defined loci that are identified by PCR amplification of genomic DNA with pairs of specific oligonucleotide primers; they may contain high-copy, dispersed genomic sequences within the amplified region. Amplified RAPD products were cloned and sequenced. The sequence was used to design 24-mer oligonucleotide primers for each end. All pairs of SCAR primers resulted in the amplification of single major bands the same size as the RAPD fragment cloned. Polymorphism was either retained as the presence or absence of amplification of the band or appeared as length polymorphisms that converted dominant RAPD loci into codominant SCAR markers. This study provided information on the molecular basis of RAPD markers. The amplified fragment contained no obvious repeated sequences beyond the primer sequence. Five out of eight pairs of SCAR primers amplified an alternate allele from both parents of the mapping population; therefore, the original RAPD polymorphism was likely due to mismatch at the primer sites.     

SNP discovery based on CATS and genotyping in the finless porpoise (Neophocaena phocaenoides)

Single nucleotide polymorphisms (SNPs) discovery and genotyping were performed for the finless porpoises (Neophocaena phocaenoides). About 202 comparative anchor tagged sequence primers derived from genomes of human, mouse and some other mammals were used to screen the finless porpoise population. Of the 51 SNPs discovered, 25 were further characterized with ideal genotyping primers and using fragment length discrepant allele specific PCR assay. This is the first report of SNP loci for the finless porpoise, which is helpful to provide some novel molecular markers and new genetic information relevant to the conservation and management of this endangered species.     

SOP3: a web-based tool for selection of oligonucleotide primers for single nucleotide polymorphism analysis by Pyrosequencing

SOP3 is a web-based software tool for designing oligonucleotide primers for use in the analysis of single nucleotide polymorphisms (SNPs). Accessible via the Internet, the application is optimized for developing the PCR and sequencing primers that are necessary for Pyrosequencing. The application accepts as input gene name, SNP reference sequence number, or chromosomal nucleotide location. Output can be parsed by gene name, SNP reference number, heterozygosity value, location, chromosome, or function. The location of an individual polymorphism, such as an intron, exon, or 5' or 3' untranslated region is indicated, as are whether nucleotide changes in an exon are associated with a change in an amino acid sequence. SOP3 presents for each entry a set of forward and biotinylated reverse PCR primers as well as a sequencing primer for use during the analysis of SNPs by Pyrosequencing. Theoretical pyrograms for each allele are calculated and presented graphically. The method has been tested in the development of Pyrosequencing assays for determining SNPs and for deletion/insertion polymorphisms in the human genome. Of the SOP3-designed primer sets that were tested, a large majority of the primer sets have successfully produced PCR products and Pyrosequencing data.     

基于荧光定量PCR扩增反应的SNP测定法

建立一种利用荧光定量PCR扩增反应进行单核苷酸多态性(SNP)快速测定的方法.以人β肾上腺素受体2基因中的Arg16Gly为研究对象,利用荧光染料SYBRGreenⅠ标记定量PCR产物,通过PCR生长曲线和融解曲线分析结果进行SNP分型.为提高SNP测定的特异性,分别在野生型和突变型等位基因的特异性引物3′端倒数第3个碱基位置,引入了一个人为错配碱基,使引物的错误延伸率显著降低,大大提高了SNP分析的准确性.通过DNA测序验证荧光定量PCR对β肾上腺素受体2基因中Arg16Gly分型结果的准确率.实验结果表明,所建立的方法操作简便,结果准确,适合进行大规模样品的SNP检测工作.     

On/off switch mediated by Exo+ polymerases: experimental analysis for its physiological and technological implications

The potential physiological role and technological application of the premature termination of DNA polymerization through the off-switch of exo+ polymerases were studied using 3' phosphorothioate-modified or unmodified primers with single base mismatch distal to the 3' terminus. With exonuclease-digestible unmodified primers, a gradient premature termination of DNA polymerization was observed when amplified with exo+ polymerases. With 3' allele specific phosphorothioate-modified primers, an efficient off-switch effect occurred in the discrimination of a single nucleotide polymorphism when directly using genomic DNA. Clearly, the off-switch of exo+ polymerases is useful in biomedical research.     

Single-base discrimination mediated by proofreading inert allele specific Primers

The role of 3' exonuclease excision in DNA polymerization was evaluated for primer extension using inert allele specific primers with exonuclease-digestible ddNMP at their 3' termini. Efficient primer extension was observed in amplicons where the inert allele specific primers and their corresponding templates were mismatched. However, no primer-extended products were yielded by matched amplicons with inert primers. As a control, polymerase without proofreading activity failed to yield primer-extended products from inert primers regardless of whether the primers and templates were matched or mismatched. These data indicated that activation was undertaken for the inert allele specific primers through mismatch proofreading. Complementary to our previously developed SNP-operated on/off switch, in which DNA polymerization only occurs in matched amplicon, this new mutation detection assay mediated by exo(+) DNA polymerases has immediate applications in SNP analysis independently or in combination of the two assays.     

Specific detection of bacillus anthracis using a TaqMan mismatch amplification mutation assay

Single nucleotide polymorphisms (SNPs) are increasingly recognized as important diagnostic markers for the detection and differentiation of Bacillus anthracis. The use of SNP markers for identifying B. anthracis DNA in environmental samples containing genetically similar bacteria requires the ability to amplify and detect DNA with single nucleotide specificity. We designed a TaqMan mismatch amplification mutation assay (TaqMAMA) around a SNP in the plcR gene of B. anthracis. The assay permits specific, low-level detection (25 fg DNA) of this B. anthracis-specific SNP, even in the presence of environmental DNA extracts containing a 20,000-fold excess of the alternate allele. We anticipate that the ability to selectively amplify and detect low copy number DNAs with single nucleotide specificity will represent a valuable tool in the arena of biodefense and microbial forensics.     

Associations between single nucleotide polymorphisms in candidate genes and growth rate in Arctic charr (Salvelinus alpinus L.)

We tested for associations between single nucleotide polymorphisms (SNPs) in five candidate genes allied with the growth hormone axis and the age-specific growth rate of Arctic charr (Salvelinus alpinus L.: Salmonidae). Two large full sib families (N=217 and 95) were created by backcrossing males that were hybrids between two phenotypically divergent populations from Labrador, Canada and from Nauyuk Lake, Canada to females that were from Nauyuk Lake. Measures of individual growth rate (wet weight and fork length) were made three times during a 420-day period after the juveniles were transferred from 4 to 11 degrees C. We then identified SNP markers in 10 proposed candidate genes known to be related to the growth hormone axis. Comparative alignments of amino-acid sequences and nucleotide sequences from other fish species were used to design PCR primers that would amplify 0.5-3 kb DNA regions of the candidate genes. All the individuals in the two backcross families were genotyped for these SNP markers using either polymerase chain reaction-restriction fragment length polymorphisms (PCR-RFLP) or bidirectional amplification of specific alleles (Bi-PASA) approaches. A significant association between a particular SNP allele and early growth was found for the locus containing the growth hormone-releasing hormone and pituitary adenylate cyclase-activating polypeptide genes (GHRH/PACAP2, P=0.00001). We argue that using comparative sequence information to design PCR primers for candidate genes is an efficient method for locating quantitative triat loci in nonmodel organisms.     

Detection of single nucleotide polymorphisms within the Listeria genus using an 'asymmetric' fluorogenic probe set and fluorescence resonance energy transfer based-PCR

AIMS: We describe a novel and inexpensive fluorescence energy transfer (FRET)-based PCR protocol to distinguish single nucleotide polymorphisms (SNPs) within the genus Listeria. METHODS AND RESULTS: Sequence information for the 16S rRNA gene of representative Listeria species was used to design genus-specific primers and two species-specific probes that differed in sequence by one single nucleotide. The probes were 5' labelled with either fluorescein or Texas Red, quenched with a shorter yet complementary 3' dimethyl-amino-phenyloazo benzoic acid (DABCYL) labelled oligonucleotide, and then incorporated into a previously reported 'asymmetric' FRET-based PCR detection protocol. CONCLUSIONS: Listeria monocytogenes could be readily distinguished from other members of the Listeria genus after PCR amplification and measurement of endpoint fluorescence at two different wavelengths. SIGNIFICANCE AND IMPACT OF THE STUDY: The relatively low cost and high flexibility of this system will benefit laboratories in their efforts to develop rapid and specific methods to detect minor sequence differences between related microorganisms.     

Should We Have Blind Faith in Bioinformatics Software? Illustrations from the SNAP Web-Based Tool

Bioinformatics tools have gained popularity in biology but little is known about their validity. We aimed to assess the early contribution of 415 single nucleotide polymorphisms (SNPs) associated with eight cardio-metabolic traits at the genome-wide significance level in adults in the Family Atherosclerosis Monitoring In earLY Life (FAMILY) birth cohort. We used the popular web-based tool SNAP to assess the availability of the 415 SNPs in the Illumina Cardio-Metabochip genotyped in the FAMILY study participants. We then compared the SNAP output with the Cardio-Metabochip file provided by Illumina using chromosome and chromosomal positions of SNPs from NCBI Human Genome Browser (Genome Reference Consortium Human Build 37). With the HapMap 3 release 2 reference, 201 out of 415 SNPs were reported as missing in the Cardio-Metabochip by the SNAP output. However, the Cardio-Metabochip file revealed that 152 of these 201 SNPs were in fact present in the Cardio-Metabochip array (false negative rate of 36.6%). With the more recent 1000 Genomes Project release, we found a false-negative rate of 17.6% by comparing the outputs of SNAP and the Illumina product file. We did not find any ‘false positive’ SNPs (SNPs specified as available in the Cardio-Metabochip by SNAP, but not by the Cardio-Metabochip Illumina file). The Cohen’s Kappa coefficient, which calculates the percentage of agreement between both methods, indicated that the validity of SNAP was fair to moderate depending on the reference used (the HapMap 3 or 1000 Genomes). In conclusion, we demonstrate that the SNAP outputs for the Cardio-Metabochip are invalid. This study illustrates the importance of systematically assessing the validity of bioinformatics tools in an independent manner. We propose a series of guidelines to improve practices in the fast-moving field of bioinformatics software implementation.     

A New PCR Method: One Primer Amplification of PCR-CTPP Products

Polymerase chain reaction with confronting two-pair primers (PCR-CTPP) is a convenient method for genotyping single nucleotide polymorphisms, saving time, and costs. It uses four primers for PCR; F1 and R1 for one allele, and F2 and R2 for the other allele, by which three different sizes of DNA are amplified; between F1 and R1, between F2 and R2, and between F1 and R2. To date, we have applied PCR-CTPP successfully for genotyping more than 60 polymorphisms. However, it is not rare that PCR does not produce balanced amplification of allele specific bands. Accordingly, the method was modified by attaching a common sequence at the 5' end of two-pair primers and adding another primer with the common sequence in PCR, in total five different primers in a tube for PCR. The modification allowed one primer amplification for the products of initial PCR with confronting two-pair primers, named as one primer amplification of PCR-CTPP products (OPA-CTPP). This article demonstrates an example for an A/G polymorphism of paraoxonase 1 (PON1) Gln192Arg (rs662). PCR-CTPP failed clear genotyping for the polymorphism, while OPA-CTPP successfully produced PCR products corresponding to the allele. The present example indicated that the OPA-CTPP would be useful in the case that PCR-CTPP failed to produce balanced PCR products specific to each allele.     

Characterization of 12 single nucleotide polymorphisms in weathervane scallop

We describe 27 single nucleotide polymorphisms (SNPs) in a commercially important bivalve, the weathervane scallop (Patinopecten caurinus), identified using a targeted‐gene approach. We further characterize 12 of these using 5′‐nuclease and allele‐specific PCR assays. Polymorphisms were identified in both mitochondrial and nuclear genes. These are the first SNPs developed for delineating population structure in the weathervane scallop and will provide a useful complement to currently available genetic markers.