Multiplex automated primer extension analysis: simultaneous genotyping of several polymorphisms.

Accurate and fast genotyping of single nucleotide polymorphisms (SNPs) is of significant scientific importance for linkage and association studies. We report here an automated fluorescent method we call multiplex automated primer extension analysis (MAPA) that can accurately genotype multiple known SNPs simultaneously. This is achieved by substantially improving a commercially available protocol (SNaPshot). This protocol relies on the extension of a primer that ends one nucleotide 5'of a given SNP with fluorescent dideoxy-NTPs (minisequencing), followed by analysis on an ABI PRisMS 377 Semi-Automated DNA Sequencer Our modification works by multiplexing the initial reaction that produces the DNA template for primer extension and/or multiplexing several primers (corresponding to several SNPs) in the same primer extension reaction. Then, we run each multiplexed reaction on a single gel lane. We demonstrate that MAPA can be used to genotype up to four SNPs simultaneously, even in compound heterozygote samples, with complete accuracy (based on concordance with sequencing results). We also show that primer design, unlike the DNA template purification method, can significantly affect genotyping accuracy, and we suggest useful guidelines for quick optimization.     

A new approach to SNP genotyping with fluorescently labeled mononucleotides

Fluorescence resonance energy transfer (FRET) is one of the most powerful and promising tools for single nucleotide polymorphism (SNP) genotyping. However, the present methods using FRET require expensive reagents such as fluorescently labeled oligonucleotides. Here, we describe a novel and cost-effective method for SNP genotyping using FRET. The technique is based on allele-specific primer extension using mononucleotides labeled with a green dye and a red dye. When the target DNA contains the sequence complementary to the primer, extension of the primer incorporates the green and red dye-labeled nucleotides into the strand, and red fluorescence is emitted by FRET. In contrast, when the 3′ end nucleotide of the primer is not complementary to the target DNA, there is no extension of the primer, or FRET signal. Therefore, discrimination among genotypes is achieved by measuring the intensity of red fluorescence after the extension reaction. We have validated this method with 11 SNPs, which were successfully determined by end-point measurements of fluorescence intensity. The new strategy is simple and cost-effective, because all steps of the preparation consist of simple additions of solutions and incubation, and the dye-labeled mononucleotides are applicable to all SNP analyses. This method will be suitable for large-scale genotyping.     

A novel procedure for efficient genotyping of single nucleotide polymorphisms

Due to the surge in interest in using single nucleotide polymorphisms (SNPs) for genotyping a facile and affordable method for this is an absolute necessity. Here we introduce a procedure that combines an easily automatable single tube sample preparation with an efficient high throughput mass spectrometric analysis technique. Known point mutations or single nucleotide polymorphisms are easily analysed by this procedure. It starts with PCR amplification of a short stretch of genomic DNA, for example an exon of a gene containing a SNP. By shrimp alkaline phosphatase digest residual dNTPs are destroyed. Allele-specific products are generated using a special primer, a conditioned set of α-S-dNTPs and α-S-ddNTPs and a fresh DNA polymerase in a primer extension reaction. Unmodified DNA is removed by 5′-phosphodiesterase digestion and the modified products are alkylated to increase the detection sensitivity in the mass spectrometric analysis. All steps of the preparation are simple additions of solutions and incubations. The procedure operates at the lowest practical sample volumes and in contrast to other genotyping protocols with mass spectrometric detection requires no purification. This reduces the cost and makes it easy to implement. Here it is demonstrated in a version using positive ion detection on described mutations in exon 17 of the amyloid precursor protein gene and in a version using negative ion detection on three SNPs of the granulocyte-macrophage colony stimulating factor gene. Preparation and analysis of SNPs is shown separately and simultaneously, thus demonstrating the multiplexibility of this genotyping procedure. The preparation protocol for genotyping is adapted to the conditions used for the SNP discovery method by denaturing HPLC, thus demonstrating a facile link between protocols for SNP discovery and SNP genotyping. Results corresponded unanimously with the control sequencing. The procedure is useful for high throughput genotyping as it is required for gene identification and pharmacogenomics where large numbers of DNA samples have to be analysed. We have named this procedure the ‘GOOD Assay’ for SNP analysis.     

A method for HLA genotyping using the specific cleavage of DNA-rN1-DNA/DNA with RNase HII from Chlamydia pneumoniae

Single nucleotide polymorphisms (SNPs) provide a great opportunity for the study of human disease and bacterial drug resistance. However, many SNP typing techniques require dedicated instruments and high cost. Here, we develop a novel method for SNP genotyping based on specific cleavage properties of RNase HII from Chlamydia pneumoniae (CpRNase HII), termed the "CpRNase HII-based method." CpRNase HII cleaves the DNA-rN(1)-DNA/DNA duplex at the 5'-side of the ribonucleotide (rN(1) = one ribonucleotide). Moreover, the cleavage efficiencies of the perfectly matched DNA-rN(1)-DNA/DNA duplexes are higher than those carrying a mismatched ribonucleotide. DNA-rN(1)-DNA fragments are modified with a fluorophore at the 5'-end and a quencher at the 3'-end to generate molecular beacons (MBs), which hybridize with single-stranded DNA (analyte) to be cleaved by CpRNase HII. As perfectly matched duplexes can be cleaved efficiently and mismatched duplexes cannot, CpRNase HII-catalyzed reactions can differentiate between one-nucleotide variations on the DNA-rN(1)-DNA/DNA duplexes. We have validated this method with nine SNPs of the HLA gene, which were successfully determined by endpoint measurements of fluorescence intensity. The new method is simple and effective, because the design of MBs is easy, and all steps of the genotyping consist of simple additions of solutions and incubation. This method will be suitable for large-scale genotyping.     

MALDI mass spectrometry analysis of single nucleotide polymorphisms by photocleavage and charge-tagging

High-throughput procedures are an important requirement for future large-scale genetic studies such as genotyping of single nucleotide polymorphisms (SNPs). Matrix-assisted laser desorption/ ionisation mass spectrometry (MALDI-MS) has revolutionised the analysis of biomolecules and, in particular, provides a very attractive solution for the rapid typing of DNA. The analysis of DNA by MALDI can be significantly facilitated by a procedure termed ‘charge-tagging’. We show here a novel approach for the generation of charge-tagged DNA using a photocleavable linker and its implementation in a molecular biological procedure for SNP genotyping consisting of PCR, primer extension, photocleavage and a chemical reaction prior to MALDI target preparation and analysis. The reaction sequence is amenable to liquid handling automation and requires no stringent purification procedures. We demonstrate this new method on SNPs in two genes involved in complex traits.     

A novel MALDI-TOF based methodology for genotyping single nucleotide polymorphisms

A new MALDI-TOF based detection assay was developed for analysis of single nucleotide polymorphisms (SNPs). It is a significant modification on the classic three-step minisequencing method, which includes a polymerase chain reaction (PCR), removal of excess nucleotides and primers, followed by primer extension in the presence of dideoxynucleotides using modified thermostable DNA polymerase. The key feature of this novel assay is reliance upon deoxynucleotide mixes, lacking one of the nucleotides at the polymorphic position. During primer extension in the presence of depleted nucleotide mixes, standard thermostable DNA polymerases dissociate from the template at positions requiring a depleted nucleotide; this principal was harnessed to create a genotyping assay. The assay design requires a primer- extension primer having its 3'-end one nucleotide upstream from the interrogated site. The assay further utilizes the same DNA polymerase in both PCR and the primer extension step. This not only simplifies the assay but also greatly reduces the cost per genotype compared to minisequencing methodology. We demonstrate accurate genotyping using this methodology for two SNPs run in both singleplex and duplex reactions. We term this assay nucleotide depletion genotyping (NUDGE). Nucleotide depletion genotyping could be extended to other genotyping assays based on primer extension such as detection by gel or capillary electrophoresis.     

Solid phase capturable dideoxynucleotides for multiplex genotyping using mass spectrometry

We report an approach using solid phase capturable biotinylated dideoxynucleotides (biotin-ddNTPs) in single base extension for multiplex genotyping by mass spectrometry (MS). In this method, oligonucleotide primers that have different molecular weights and that are specific to the polymorphic sites in the DNA template are extended with biotin-ddNTPs by DNA polymerase to generate 3′-biotinylated DNA products. These products are then captured by streptavidin-coated solid phase magnetic beads, while the unextended primers and other components in the reaction are washed away. The pure extension DNA products are subsequently released from the solid phase and analyzed by matrix-assisted laser desorption/ionization time-of-flight MS. The mass of the extension products is determined using a stable oligonucleotide as a common internal mass standard. Since only the pure extension DNA products are introduced to the MS for analysis, the resulting mass spectrum is free of non-extended primer peaks and their associated dimers, which increases the accuracy and scope of multiplexing in single nucleotide polymorphism (SNP) analysis. The solid phase purification approach also facilitates desalting of the captured oligonucleotides, which is essential for accurate mass measurement by MS. We selected four biotin-ddNTPs with distinct molecular weights to generate extension products that have a 2-fold increase in mass difference compared to that with conventional ddNTPs. This increase in mass difference provides improved resolution and accuracy in detecting heterozygotes in the mass spectrum. Using this method, we simultaneously distinguished six nucleotide variations on synthetic DNA templates mimicking mutations in the p53 gene and two disease-associated SNPs in the human hereditary hemochromatosis gene.     

Genotools SNP manager: a new software for automated high-throughput MALDI-TOF mass spectrometry SNP genotyping

Analysis of single nucleotide polymorphisms (SNPs) is a rapidly growing field of research that provides insights into the most common type of differences between individual genomes. The resulting information has a strong impact in the fields of pharmacogenomics, drug development, forensic medicine, and diagnostics of specific disease markers. The technique of matrix-assisted laser desorption/ionization time of flight mass spectrometry (MALDI-TOF MS) has been shown to be a highly suitable tool for the analysis of DNA. It supplies a very versatile method for addressing a high-throughput SNP genotyping approach. Here, we present the Bruker genotools SNP MANAGER, a new software tool suitable for highly automated MALDI-TOF MS SNP genotyping. The genotools SNP MANAGER administers the sample preparation data, calculates masses of allele-specific primer extension products, performs genotyping analysis, and displays the results. In the current study, we have used the genotools SNP MANAGER to perform an automated duplex SNP analysis of two biallelic markers from the promoter of the gene encoding the inflammatory mediator interleukin-6.     

A novel single nucleotide polymorphism detection of a double-stranded DNA target by a ribonucleotide-carrying molecular beacon and thermostable RNase HII

Single nucleotide polymorphisms (SNPs) are the most abundant form of genetic variation. SNPs are important markers that link sequence variations to phenotypic changes. Because of the importance of SNPs in the life and medical sciences, a great deal of effort has been devoted to developing accurate, rapid, and cost-effective technologies for SNP analysis. In this article, we describe a novel method for SNP genotyping based on differential fluorescence emission due to cleavage by Thermus thermophilus RNase HII (TthRNase HII) of DNA heteroduplexes containing an SNP site-specific chimeric DNA-rN₁-DNA molecular beacon (cMB). We constructed a loop sequence for a cMB that contains a single SNP-specific ribonucleotide at the central site. When the cMB probe is hybridized to a target double-stranded DNA (dsDNA), a perfect match of the cMB/DNA duplex permits efficient cleavage with TthRNase HII, whereas a mismatch in the duplex due to an SNP greatly reduces efficiency. Cleavage efficiency is measured by the incremental difference of fluorescence emission of the beacon. We show that the genotypes of 10 individuals at 12 SNP sites across a series of human leukocyte antigen (HLA) can be determined correctly with respect to conventional DNA sequencing. This novel TthRNase HII-based method offers a platform for easy and accurate SNP analysis.     

高通量飞行时间质谱基因分型方法的研究

为了考察飞行时间质谱基因分型方法 (MALDI-TOF) 的位点分型成功率和分型结果质量的关系,分析了 96 个 SNPs 位点的近 10 000 个基因分型数据 (用 MALDI-TOF “4 重”实验方法检测 ). 结果显示,位点分型成功率和分型结果的质量显著正相关 . 分型成功率低于 82% 的 SNP 位点,其高质量结果占的比例开始逐渐降低 . 提示 82% 的分型成功率可以作为衡量分型结果质量的数据点 . 为了进一步提高通量并降低成本,在 MALDI-TOF “ 4 重”实验方法的基础上,发展了两种“准 8 重”实验方法 . 用新的实验方法检测了 95 个样本的 32 个 SNPs 位点 . 结果显示“混合准 8 重”实验方法与“ 4 重”实验方法相比无显著差异,而“复点准 8 重”的结果差于“ 4 重”分型方法 .     

Allele-specific extension allows base-pair neutral homozygotes to be discriminated by high-resolution melting of small amplicons

Not all single-nucleotide polymorphisms (SNPs) can be determined using high-resolution melting (HRM) of small amplicons, especially class 3 and 4 SNPs. This is due mainly to the small shift in the melting temperature (Tm) between two types of homozygote. Choosing rs1869458 (a class 4 SNP) as a sample, we developed a modified small amplicon HRM assay. An allele-specific extension (ASE) primer, which ended at an SNP site and matched only one of the alleles, was added to the reaction as well as additional thermal steps for ASE. Following asymmetric polymerase chain reaction and melting curve analysis, heterozygotes were easily identified. Two types of homozygote were also distinguishable, indicating that extension primers 11 to 13 bases in length worked efficiently in an allele-specific way. Modification of the limiting amplification primer with locked nucleic acid increased the Tm difference between extension and amplification peaks and facilitated subsequent genotyping. In addition, 194 human genomic DNA samples were genotyped with the developed assay and by direct sequencing, with the different methods providing identical genotyping results. In conclusion, ASE-HRM is a simple, inexpensive, closed-tube genotyping method that can be used to examine all types of SNP.     

Direct transduction of allele-specific primer extension into electrical signal using genetic field effect transistor

We have developed a genetic field effect transistor (FET) for single nucleotide polymorphism (SNP) genotyping, which is based on potentiometric detection of molecular recognition on the gate insulator. Here, we report direct transduction of allele-specific primer extension on the gate surface into electrical signal using the genetic FETs. This method is based on detection of intrinsic negative charges of polynucleotide synthesized by DNA polymerase. The charge density change at the gate surface could be monitored during primer extension reaction. Moreover, three different genotypes could be successfully distinguished without any labeling for target DNA by the use of the genetic FET in combination with allele-specific primer extension. The platform based on the genetic FETs is suitable for a simple, accurate and inexpensive system for SNP genotyping in clinical diagnostics.     

Facile method for automated genotyping of single nucleotide polymorphisms by mass spectrometry

In the future, analysis of single nucleotide polymorphisms (SNPs) should become a powerful tool for many genetic applications in areas such as association studies, pharmacogenetics and traceability in the agro-alimentary sector. A number of technologies have been developed for high-throughput genotyping of SNPs. Here we present the simplified GOOD assay for SNP genotyping by matrix-assisted laser desorption/ionization time-of-flight mass spectrometry (MALDI). The simplified GOOD assay is a single-tube, purification-free, three-step procedure consisting of PCR, primer extension and phosphodiesterase II digestion followed by mass spectrometric analysis. Due to the application of charge-tag technology, no sample purification is required prior to the otherwise very impurity-sensitive MALDI analysis. The use of methylphosphonate containing primers and ddNTPs or α-S-ddNTPs together with a novel DNA polymerase derived from Thermotoga maritima for primer extension allow the fluent preparation of negatively charge-tagged, allele-specific products. A key feature of this polymerase is its preference for ddNTPs and α-S-ddNTPs over dNTPs. The simplified GOOD assay was run with automatic liquid handling at the lowest manageable volumes, automatic data acquisition and interpretation. We applied this novel procedure to genotyping SNPs of candidate genes for hypertension and cardiovascular disease.     

A new MALDI-TOF based mini-sequencing assay for genotyping of SNPS

A new MALDI-TOF based mini-sequencing assay termed VSET was developed for genotyping of SNPs. In this assay, specific fragments of genomic DNA containing the SNP site(s) are first amplified, followed by mini-sequencing in the presence of three ddNTPs and the fourth nucleotide in the deoxy form. In this way, the primer is extended by only one base from one allele, while it is typically extended by two bases from another allele. The products are then analyzed using MALDI-TOF mass spectrometry. The genotype of the SNP site is identified based on the number of nucleotides added. This assay has been examined using both synthetic and genomic DNA samples. In addition, multiplexed assays were successfully performed to genotype four SNP sites in a single tube. The main aspect of this assay is that it can overcome the key problems associated with the currently used mini-sequencing methods. First, it significantly reduces the stringent high-resolution and extensive desalting requirements that are essential to the pinpoint assay. Second, it avoids the long extension problem associated with the PROBE assay.     

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.     

Flow cytometric platform for high-throughput single nucleotide polymorphism analysis

We have developed a rapid, cost-effective, high-throughput readout for single nucleotide polymorphism (SNP) genotyping using flow cytometric analysis performed on a Luminex 100 flow cytometer. This robust technique employs a PCR-derived target DNA containing the SNP, a synthetic SNP-complementary ZipCode-bearing capture probe, a fluorescent reporter molecule, and a thermophilic DNA polymerase. An array of fluorescent microspheres, covalently coupled with complementary ZipCode sequences (cZipCodes), was hybridized to the reaction products and sequestered them for flow cytometric analysis. The single base chain extension (SBCE) reaction was used to assay 20 multiplexed SNPs for 633 patients in 96-well format. Comparison of the microsphere-based SBCE assay results to gel-based oligonucleotide ligation assay (OLA) results showed 99.3% agreement in genotype assignments. Substitution of direct-labeled R6G dideoxynucleotide with indirect-labeled phycoerythrin dideoxynucleotide enhanced signal five- to tenfold while maintaining low noise levels. A new assay based on allele-specific primer extension (ASPE) was validated on a set of 15 multiplexed SNPs for 96 patients. ASPE offers both the advantage of streamlining the SNP analysis protocol and the ability to perform multiplex SNP analysis on any mixture of allelic variants.     

Quantitative evaluation by minisequencing and microarrays reveals accurate multiplexed SNP genotyping of whole genome amplified DNA

Whole genome amplification (WGA) procedures such as primer extension preamplification (PEP) or multiple displacement amplification (MDA) have the potential to provide an unlimited source of DNA for large-scale genetic studies. We have performed a quantitative evaluation of PEP and MDA for genotyping single nucleotide polymorphisms (SNPs) using multiplex, four-color fluorescent minisequencing in a microarray format. Forty-five SNPs were genotyped and the WGA methods were evaluated with respect to genotyping success, signal-to-noise ratios, power of genotype discrimination, yield and imbalanced amplification of alleles in the MDA product. Both PEP and MDA products provided genotyping results with a high concordance to genomic DNA. For PEP products the power of genotype discrimination was lower than for MDA due to a 2-fold lower signal-to-noise ratio. MDA products were indistinguishable from genomic DNA in all aspects studied. To obtain faithful representation of the SNP alleles at least 0.3 ng DNA should be used per MDA reaction. We conclude that the use of WGA, and MDA in particular, is a highly promising procedure for producing DNA in sufficient amounts even for genome wide SNP mapping studies.     

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.     

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。     

Development of a single tube 640-plex genotyping method for detection of nucleic acid variations on microarrays

Detection of DNA sequence variation is critical to biomedical applications, including disease genetic identification, diagnosis and treatment, drug discovery and forensic analysis. Here, we describe an arrayed primer extension-based genotyping method (APEX-2) that allows multiplex (640-plex) DNA amplification and detection of single nucleotide polymorphisms (SNPs) and mutations on microarrays via four-color single-base primer extension. The founding principle of APEX-2 multiplex PCR requires two oligonucleotides per SNP/mutation to generate amplicons containing the position of interest. The same oligonucleotides are then subsequently used as immobilized single-base extension primers on a microarray. The method described here is ideal for SNP or mutation detection analysis, molecular diagnostics and forensic analysis. This robust genetic test has minimal requirements: two primers, two spots on the microarray and a low cost four-color detection system for the targeted site; and provides an advantageous alternative to high-density platforms and low-density detection systems.