Multiplex single nucleotide polymorphisms genotyping using solid-phase single base extension on magnetic nanoparticles

To fulfill the increasing need for large-scale genetic research, we have developed a new solid-phase single base extension (SBE) protocol on magnetic nanoparticles (MNPs) for multiplex SNP detection using adapter polymerase chain reaction (PCR) products as templates. Extension primers were covalently immobilized on the MNPs, and allele-specific extension took place along the stretch of target DNA for one-color ddNTP incorporation. The MNPs with fluorophores were spotted on a glass slide to fabricate a “bead array” to discriminate their genotypes. Eight SNP loci of three DNA samples were interrogated, and the experiment demonstrated that it is an efficient method for large-scale SNP genotyping.     

Rapid identification of single nucleotide polymorphisms by fluorescence-based capillary electrophoresis

We describe the application of two different fluorescence-based techniques (ddNTP primer extension and single-strand conformation polymorphism (SSCP)) to the detection of single nucleotide polymorphisms (SNPs) by capillary electrophoresis. The ddNTP primer extension technique is based on the extension, in the presence of fluorescence-labeled dideoxy nucleotides (ddNTP, terminators), of an unlabeled oligonucleotide primer that binds to the complementary template immediately adjacent to the mutant nucleotide position. Given that there are no unlabeled dNTPs, a single ddNTP is added to its 3' end, resulting in a fluorescence-labeled primer extension product which is readily separated by capillary electrophoresis. On the other hand, the non-radioisotopic version of SSCP established in this study uses fluorescent dye to label the PCR products, which are also analyzed by capillary electrophoresis. These procedures were used to identify a well-defined SNP in exon 7 of the human p53 gene in DNA samples isolated from two human cell lines (CEM and THP-1 cells). The results revealed a heterozygous single-base transition (G to A) at nucleotide position 14071 in CEM cells, proving that both fluorescence-based ddNTP primer extension and SSCP are rapid, simple, robust, specific and with no ambiguity in interpretation for the detection of well-defined SNPs.     

Development of an automated SNP analysis method using a paramagnetic beads handling robot

Biological and medical importance of the single nucleotide polymorphism (SNP) has led to development of a wide variety of methods for SNP typing. Aiming for establishing highly reliable and fully automated SNP typing, we have developed the adapter ligation method in combination with the paramagnetic beads handling technology, Magtration(R). The method utilizes sequence specific ligation between the fluorescently labeled adapter and the sample DNAs at the cohesive end produced by a type IIS restriction enzyme. Evaluation of the method using human genomic DNA showed clear discrimination of the three genotypes without ambiguity using the same reaction condition for any SNPs examined. The operations following PCR amplification were automatically performed by the Magtration(R)-based robot that we have previously developed. Multiplex typing of two SNPs in a single reaction by using four fluorescent dyes was successfully preformed at the almost same sensitivity and reliability as the single typing. These results demonstrate that the automated paramagnetic beads handling technology, Magtration(R), is highly adaptable to the automated SNP analysis and that our method best fits to an automated in-house SNP typing for laboratory and medical uses.     

Coupling single base extension to a spectral codification tool for increased throughput screening

We report a new strategy that combines a Förster Resonance Energy Transfer (FRET) based spectral codification tool with a single base extension (SBE) reaction for rapid and medium-throughput analysis of single nucleotide polymorphisms (SNPs). This strategy is based on the spectral codification - a donor (fluorophore labeled probe complementary to the region adjacent to an SNP) is used to induce specific FRET signatures from an acceptor fluorophore revealing the SNP variant. Using an SBE reaction and differently labeled ddNTPs, we can directly question each donor probe and retrieve information about which allele variant is present at that locus. The potential of the method is demonstrated by application to simultaneous questioning of two loci in the same reaction tube. Following calibration with all possible combinations of FRET pairs, an evaluation algorithm was calibrated so as to optimize base calling and allow unequivocal allele scoring with more than 80% confidence (for two simultaneous loci being questioned, one homo- and one heterozygous). In conclusion, this spectral codification approach may constitute a solution towards increasing throughput capability of single base extension based assays.     

A multiplexing single nucleotide polymorphism typing method based on restriction-enzyme-mediated single-base extension and capillary electrophoresis

Millions of single nucleotide polymorphisms (SNPs) have been identified in recent years. This provides a great opportunity for large-scale association and population studies. However, many high-throughput SNP typing techniques require expensive and dedicated instruments, which render them out of reach for many laboratories. To meet the need of these laboratories, we here report a method that uses widely available DNA sequencer for SNP typing. This method uses a type II restriction enzyme to create extendable ends at target polymorphic sites and uses single-base extension (SBE) to discriminate alleles. In this design, a restriction site is engineered in one of the two polymerase chain reaction (PCR) primers so that the restriction endonuclease cuts immediately upstream of the targeted SNP site. The digestion of the PCR products generates a 5'-overhang structure at the targeted polymorphic site. This 5'-overhang structure then serves as a template for SBE reaction to generate allele-specific products using fluorescent dye-terminator nucleotides. Following the SBE, the allele-specific products with different sizes can be resolved by DNA sequencers. Through primer design, we can create a series of PCR products that vary in size and contain only one restriction enzyme recognition site. This allows us to load many PCR products in a single capillary/lane. This method, restriction-enzyme-mediated single-base extension, is demonstrated by typing multiple SNPs simultaneously for 44 DNA samples. By multiplexing PCR and pooling multiplexed reactions together, this method has the potential to score 50-100 SNPs/capillary/run if the sizes of PCR products are arranged at every 5-10 bases from 100 to 600 base range.     

Multiplex genotyping of the human beta2-adrenergic receptor gene using solid-phase capturable dideoxynucleotides and mass spectrometry

Previously, we established the feasibility of using solid phase capturable (SPC) dideoxynucleotides to generate single base extension (SBE) products which were detected by matrix-assisted laser desorption/ionization time-of-flight mass spectrometry (MALDI-TOF MS) for multiplex genotyping, an approach that we refer to as SPC-SBE. We report here the expanding of the SPC-SBE method as a single-tube assay to simultaneously detect 20 single nucleotide variations in a model system and 3 single nucleotide polymorphisms (SNPs) in the human beta2-adrenergic receptor (beta2AR) gene. Twenty primers were designed to have a sufficient mass difference between all extension products for accurate detection of nucleotide variants of the synthetic templates related to the p53 gene. These primers were extended simultaneously in a single tube with biotin-ddNTPs to generate 3(')-biotinylated DNA products, which were first captured by streptavidin-coated magnetic beads and then released from the beads and analyzed with MALDI-TOF MS. This approach generates a mass spectrum free of primer peaks and their associated dimers, increasing the scope of multiplexing SNPs. We also simultaneously genotyped 3 SNPs in the beta2AR gene (5(')LC-Cys19Arg, Gly16Arg, and Gln27Glu) from the genomic DNA of 20 individuals. Comparison of this approach with direct sequencing and the restriction fragment length polymorphism method indicated that the SPC-SBE method is superior for detecting nucleotide variations at known SNP sites.     

Highly sensitive chemiluminescent point mutation detection by circular strand-displacement amplification reaction

Single nucleotide polymorphism (SNP) genotyping is attracting extensive attentions owing to its direct connections with human diseases including cancers. Here, we have developed a highly sensitive chemiluminescence biosensor based on circular strand-displacement amplification and the separation by magnetic beads reducing the background signal for point mutation detection at room temperature. This method took advantage of both the T4 DNA ligase recognizing single-base mismatch with high selectivity and the strand-displacement reaction of polymerase to perform signal amplification. The detection limit of this method was 1.3 × 10(-16)M, which showed better sensitivity than that of most of those reported detection methods of SNP. Additionally, the magnetic beads as carrier of immobility was not only to reduce the background signal, but also may have potential apply in high through-put screening of SNP detection in human genome.     

Touchdown thermocycling program enables a robust single nucleotide polymorphism typing method based on allele-specific real-time polymerase chain reaction

Different methods have been developed for single nucleotide polymorphism (SNP) typing during recent years. Allele-specific polymerase chain reaction (ASPCR) is a cost-saving method that scores SNPs by difference of the PCR efficiency of allele-specific primers. However, ASPCR for SNP typing is notoriously confounded for its locus-specific unpredictability and the laborious gel electrophoresis. In the current study, we investigated the real-time kinetics of ASPCR and found that a simple touchdown thermocycling protocol improved its specificity significantly. Combined with real-time PCR, we developed a homogeneous genotyping method and scored more than 1000 genotypes, including all transition and transversion SNPs. A clear genotyping result was identified and validated the robustness of the method. Optimization of reactions and intrinsic modification of allele-specific primers, a laborious process but one that is repeatedly reported to be inevitable for successful ASPCR, was proved to be unnecessary with our method. Accuracy was confirmed with mass spectrometry. These characters enabled real-time ASPCR with the touchdown thermocycling protocol being very competitive among various SNP typing methods for large-scale genetic studies.     

单核苷酸多态性检测方法研究进展

：单核苷酸多态性（singlenucleotidepolymorphism,SNP）是指在基因组水平上由单个核苷酸的变异引起的一种DNA序列多态性。SNP作为第三代分子标记,具有数量多、分布广等特点,已成为人类后基因组时代的主要研究内容之一。单核苷酸多态性在医学研究、临床诊断、药物开发与合理用药、法医学、遗传学的发展方面具有重要意义。因此,建立高度自动化和高通量的SNP检测分析技术十分重要。各种SNP分型检测方法都由等位基因特异性的识别反应和等住基因识别产物的分析检测两个部分组成。本文系统的介绍了引物延伸反应、序列杂交反应、酶连接反应、酶切割反应、核酸链构象差异反应等SNP检测的等位基因特异性的识别原理,以及质谱、荧光共振和偏振信号、化学发光、毛细管电泳测序、生物传感器等分析检测手段,并简要介绍了相关识别原理和分析检测手段的优缺点及应用范围,并对SNP检测技术的发展进行了展望。     

Efficient mutagenesis method for producing the templates of single nucleotide polymorphisms

DNA templates harboring specific single nucleotide polymorphism (SNP) sites are largely needed as positive controls in practical SNP analysis and in determination of the reliability of newly developed methods in high-throughput screening assays. Here we report a one-step method to produce SNP templates by amplifying a wild-type sequence with primers having single nucleotide mismatches at or near their 3′ ends. A short amplicon harboring an EcoRI site was used to evaluate the feasibility of our strategy. Perfectly matched primers and primers with a single base mismatch occurring from the first base to the sixth base of the EcoRI site were used for primer extension. By using polymerase without a proofreading function, we kept mismatched nucleotides from occurring in extended primer products, as confirmed by EcoRI digestion and sequencing analysis. The strategy of using primers with a single mismatched base and exo- polymerase was shown to be an efficient one-step method for preparing SNP templates, either for application in the development of SNP screening assays or as positive controls in practical SNP assays.     

四引物PCR扩增反应的单管SNP快速测定法

建立一种在单管中进行单核苷酸多型性 (SNP)快速测定的高效廉价方法 .以人ABCA1基因中的I82 3M为研究对象 ,设计 4种引物进行PCR扩增 ,其中两种引物用于扩增一段含有SNP位点的DNA片段 ,另两种引物为SNP位点特异性引物 ,4种引物在单管中同时进行PCR扩增反应 ,根据延伸产物的长度确定SNP的类型 .为提高SNP测定的特异性 ,在特异性引物的 3′端倒数第 3个碱基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 .实验结果表明 ,所建立的方法简单 ,操作简便 ,可在单管中完成SNP的测定反应 .     

Single nucleotide polymorphism detection by combinatorial fluorescence energy transfer tags and biotinylated dideoxynucleotides

Combinatorial fluorescence energy transfer (CFET) tags, constructed by exploiting energy transfer and combinatorial synthesis, allow multiple biological targets to be analyzed simultaneously. We here describe a multiplex single nucleotide polymorphism (SNP) assay based on single base extension (SBE) using CFET tags and biotinylated dideoxynucleotides (biotin-ddNTPs). A library of CFET-labeled oligonucleotide primers was mixed with biotin-ddNTPs, DNA polymerase and the DNA templates containing the SNPs in a single tube. The nucleotide at the 3′-end of each CFET-labeled oligonucleotide primer was complementary to a particular SNP in the template. Only the CFET-labeled primer that is fully complementary to the DNA template was extended by DNA polymerase with a biotin-ddNTP. We isolated the DNA extension fragments that carry a biotin at the 3′-end by capture with streptavidin-coated magnetic beads, while the unextended primers were eliminated. The biotinylated fluorescent DNA fragments were subsequently analyzed in a multicolor fluorescence electrophoresis system. The distinct fluorescence signature and electrophoretic mobility of each DNA extension product in the electropherogram coded the SNPs without the use of a sizing standard. We simultaneously distinguished six nucleotide variations in synthetic DNA templates and a PCR product from the retinoblastoma tumor suppressor gene. The use of CFET-labeled primers and biotin-ddNTPs coupled with the specificity of DNA polymerase in SBE offered a multiplex method for detecting SNPs.     

New separation-free assay technique for SNPs using two-photon excitation fluorometry

A new separation-free method for detection of single nucleotide polymorphisms (SNPs) is described. The method is based on the single base extension principle, fluorescently labeled dideoxy nucleotides and two-photon fluorescence excitation technology, known as ArcDia™ TPX technology. In this assay technique, template-directed single base extension is carried out for primers which have been immobilized on polymer microparticles. Depending on the sequence of the template DNA, the primers are extended either with a labeled or with a non-labeled nucleotide. The genotype of the sample is determined on the basis of two-photon excited fluorescence of individual microparticles. The effect of various assay condition parameters on the performance of the assay method is studied. The performance of the new assay method is demonstrated by genotyping the SNPs of human individuals using double-stranded PCR amplicons as samples. The results show that the new SNP assay method provides sensitivity and reliability comparable to the state-of-the-art SNaPshot™ assay method. Applicability of the new method in routine laboratory use is discussed with respect to alternative assay techniques.     

DNA-probes for the highly sensitive identification of single nucleotide polymorphism using single-molecule spectroscopy

This article presents a new, highly sensitive method for the identification of single nucleotide polymorphisms (SNPs) in homogeneous solutions using fluorescently labeled hairpin-structured oligonucleotides (smart probes) and fluorescence single-molecule spectroscopy. While the hairpin probe is closed, fluorescence intensity is quenched due to close contact between the chromophore and several guanosine residues. Upon hybridization to the respective target SNP sequence, contact is lost and the fluorescence intensity increases significantly. High specificity is achieved by blocking sequences containing mismatch with unlabeled oligonucleotides. Time-resolved single-molecule fluorescence spectroscopy enables the detection of individual smart probes passing a small detection volume. This method leads to a subnanomolar sensitivity for this single nucleotide specific DNA assay technique.     

PCR amplification on magnetic nanoparticles: application for high-throughput single nucleotide polymorphism genotyping

A novel approach for the genotyping of single nucleotide polymorphisms (SNPs) based on solidphase PCR on magnetic nanoparticles (MNPs) is described. PCR products were amplified directly on MNPs. The genotypes of a given SNP were differentiated by hybridization with a pair of allele-specific probes labeled with dual-color fluorescence (Cy3, Cy5). The results were analyzed by scanning the microarray printed with the denatured fluorescent probes on an unmodified glass slide. Electrophoresis analysis indicated that PCR could proceed successfully when MNPs-bound primers were used. Furthermore, nine different samples were genotyped and their fluorescent signals were quantified. Genotyping results showed that three genotypes for the locus were very easily discriminated. The fluorescent ratios (match probe:mismatch probe signal) of homozygous samples were over 9.3, whereas heterozygous samples had ratios near 1.0. Without any purification and concentration of PCR products, this new MNP-PCR based genotyping assay potentially provides a rapid, labor-saving method for genotyping of a large number of individuals.     

Visual, base-specific detection of nucleic acid hybridization using polymerization-based amplification

Polymerization-based signal amplification offers sensitive visualization of biotinylated biomolecules functionalized to glass microarrays in a manner suitable for point-of-care use. Here we report using this method for visual detection of multiplexed nucleic acid hybridizations from complex media and develop an application toward point mutation detection and single nucleotide polymorphism (SNP) typing. Primer extension reactions were employed to label selectively and universally all complementary surface DNA hybrids with photoinitiators, permitting simultaneous and dynamic photopolymerization from positive sites to 0.5-nM target concentrations. Dramatic improvements in signal ratios between complementary and mismatched hybrids enabled visual discrimination of single base differences in KRAS codon-12 biomarkers.     

Multiplex SNP typing by bioluminometric assay coupled with terminator incorporation (BATI)

A multiplex single-nucleotide polymorphism (SNP) typing platform using ‘bioluminometric assay coupled with terminator [2′,3′-dideoxynucleoside triphosphates (ddNTPs)] incorporation’ (named ‘BATI’ for short) was developed. All of the reactions are carried out in a single reaction chamber containing target DNAs, DNA polymerase, reagents necessary for converting PPi into ATP and reagents for luciferase reaction. Each of the four ddNTPs is dispensed into the reaction chamber in turn. PPi is released by a nucleotide incorporation reaction and is used to produce ATP when the ddNTP dispensed is complementary to the base in a template. The ATP is used in a luciferase reaction to release visible light. Only 1 nt is incorporated into a template at a time because ddNTPs do not have a 3′ hydroxyl group. This feature greatly simplifies a sequencing spectrum. The luminescence is proportional to the amount of template incorporated. Only one peak appears in the spectrum of a homozygote sample, and two peaks at the same intensity appear for a heterozygote sample. In comparison with pyrosequencing using dNTP, the spectrum obtained by BATI is very simple, and it is very easy to determine SNPs accurately from it. As only one base is extended at a time and the extension signals are quantitative, the observed spectrum pattern is uniquely determined even for a sample containing multiplex SNPs. We have successfully used BATI to type various samples containing plural target sequence areas. The measurements can be carried out with an inexpensive and small luminometer using a photodiode array as the detector. It takes only a few minutes to determine multiplex SNPs. These results indicate that this novel multiplexed approach can significantly decrease the cost of SNP typing and increase the typing throughput with an inexpensive and small luminometer.     

SNP typing by apyrase-mediated allele-specific primer extension on DNA microarrays

This study reports the development of a microarray-based allele-specific extension method for typing of single nucleotide polymorphisms (SNPs). The use of allele-specific primers has been employed previously to identify single base variations but it is acknowledged that certain mismatches are not refractory to extension. Here we have overcome this limitation by introducing apyrase, a nucleotide-degrading enzyme, to the extension reaction. We have shown previously that DNA polymerases exhibit slower reaction kinetics when extending a mismatched primer compared with a matched primer. This kinetic difference is exploited in the apyrase-mediated allele-specific extension (AMASE) assay, allowing incorporation of nucleotides when the reaction kinetics are fast but degrading the nucleotides before extension when the reaction kinetics are slow. Here we show that five homozygous variants (14% of the total number of variants) that were incorrectly scored in the absence of apyrase were correctly typed when apyrase was included in the extension reaction. AMASE was performed in situ on the oligonucleotide microarrays using fluorescent nucleotides to type 10 SNPs and two indels in 17 individuals generating approximately 200 genotypes. Cluster analysis of these data shows three distinct clusters with clear-cut boundaries. We conclude that SNP typing on oligonucleotide microarrays by AMASE is an efficient, rapid and accurate technique for large-scale genotyping.     

Analysis of single nucleotide incorporation reactions by capillary electrophoresis

Single nucleotide incorporation assays have been used to probe the kinetic parameters of many DNA and RNA polymerases. Traditionally, oligonucleotide primers are 5'-(32)P labeled using T4 kinase and annealed to a complementary template with a 5' overhang. To quantify the reaction kinetics, the products of the primer extension reactions are usually separated using denaturing polyacrylamide gel electrophoresis and quantified using a phosphorimager or other method to measure radioactivity. We have developed a method using a 5' fluorescently labeled oligonucleotide to examine the kinetics of single nucleotide incorporation catalyzed by recombinant human mitochondrial polymerase gamma (Pol gamma) holoenzyme. Using laser-induced fluorescence detection in the P/ACE MDQ instrument, primers 5' labeled with fluorescent probes such as 6-carboxyfluorescein can be rapidly separated and quantified. However, we also show that only select probes can be used, presumably due to unfavorable interactions between Pol gamma and certain 5' labels.     

Single nucleotide polymorphism genotyping of aldehyde dehydrogenase 2 gene using a single bacterial magnetic particle

A single nucleotide polymorphism (SNP) genotyping for aldehyde dehydrogenase 2 gene (ALDH2) has been developed by using a nano-sized magnetic particle, which was synthesized intracellularly by magnetic bacteria. Streptavidin-immobilized on bacterial magnetic particles (BMPs) were prepared using biotin labeled cross-linkers reacting with the amine group on BMPs. ALDH2 fragments from genomic DNA were amplified using a TRITC labeled primer and biotin labeled primer pair, and conjugated onto BMP surface by biotin-streptavidin interaction. PCR product-BMP complex was observed at a single particle level by fluorescence microscopy. These complexes were treated with restriction enzyme, specifically digesting the wild-type sequence of ALDH2 (normal allele of ALDH2). The homozygous (ALDH2*1/*1), heterozygous (ALDH2*1/*2), and mutant (ALDH2*2/*2) genotypes were discriminated by three fluorescence patterns of each particle. SNP genotyping of ALDH2 has been successfully achieved at a single particle level using BMP.