Sensitivity enhancement of DNA microarray on nano-scale controlled surface by using a streptavidin-fluorophore conjugate

High throughput analysis of DNA in low concentration and small volume is an important issue and a continuing challenge in the field of DNA microarray and sensor. Recently, we have demonstrated that the DNA microarray on nano-scale controlled surface provides ample space for hybridization resulting in the best discrimination efficiency for SNP analysis. Here, we report the utility of the nano-scale controlled surface in conjunction with a multiply tagged protein. Application of streptavidin-fluorophore conjugates in combination with the highly controlled surface that suppresses non-specific binding of DNA allows highly sensitive detection of DNA while maintaining superior SNP discrimination efficiency comparable to our earlier results. The sensitivity of DNA microarray on the mesospaced surface is two orders of magnitude higher than that of the generic surface when a streptavidin-fluorophore conjugate was employed, and the detection limit on the former surface was found to be 50 fM of 15-mer target DNA. Various streptavidin-fluorophore conjugates including streptavidin-Cy3, streptavidin-Cy5, streptavidin-Alexa Flour 555 and streptavidin-phycoerythrin were examined.     

一种新的基于单碱基延伸的SNP芯片技术

单核苷酸多态性(Single nucleotide polymorphism, SNP)是人类基因组中最常见的一种变异, 与疾病易感性、药物代谢等有着密切的关系。已经建立了多种SNP检测技术并得到了应用。单碱基延伸(Single base extension, SBE)是常用的SNP分型技术之一。文章建立了SBE结合Zip-code芯片技术对SNP进行分型, 为个体化用药及临床诊断芯片的研究与开发提供技术和方法。     

Development of multiplex DNA electronic microarrays using a universal adaptor system for detection of single nucleotide polymorphisms

The NanoChip electronic microarray is designed for the rapid detection of genetic variation in research and clinical diagnosis. We have developed a multiplex electronic microarray assay, specific for single nucleotide polymorphism (SNP) genotyping and mutation detection, using universal adaptor sequences tailed to the 5' end of PCR primers specific to each target. PCR products, amplified by primers directed to the universal adaptor sequence, are immobilized on the microarray either directly or via capture oligonucleotides complementary to the universal adaptor sequence. This simple modification results in a significant increase in fidelity with improved specificity and accuracy. In addition, the multiplexing of genetic variant detection allows increased throughput and significantly reduced cost per assay. This general schema can also be applied to other microarray and macroarray formats.     

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.     

Free energy of DNA duplex formation on short oligonucleotide microarrays

DNA/DNA duplex formation is the basic mechanism that is used in genome tiling arrays and SNP arrays manufactured by Affymetrix. However, detailed knowledge of the physical process is still lacking. In this study, we show a free energy analysis of DNA/DNA duplex formation these arrays based on the positional-dependent nearest-neighbor (PDNN) model, which was developed previously for describing DNA/RNA duplex formation on expression microarrays. Our results showed that the two ends of a probe contribute less to the stability of the duplexes and that there is a microarray surface effect on binding affinities. We also showed that free energy cost of a single mismatch depends on the bases adjacent to the mismatch site and obtained a comprehensive table of the cost of a single mismatch under all possible combination of adjacent bases. The mismatch costs were found to be correlated with those determined in aqueous solution. We further demonstrate that the DNA copy number estimated from the SNP array correlates negatively with the target length; this is presumably caused by inefficient PCR amplification for long fragments. These results provide important insights into the molecular mechanisms of microarray technology and have implications for microarray design and the interpretation of observed data.     

Segmentation and Estimation for SNP Microarrays: A Bayesian Multiple Change‐Point Approach

Summary High‐density single‐nucleotide polymorphism (SNP) microarrays provide a useful tool for the detection of copy number variants (CNVs). The analysis of such large amounts of data is complicated, especially with regard to determining where copy numbers change and their corresponding values. In this article, we propose a Bayesian multiple change‐point model (BMCP) for segmentation and estimation of SNP microarray data. Segmentation concerns separating a chromosome into regions of equal copy number differences between the sample of interest and some reference, and involves the detection of locations of copy number difference changes. Estimation concerns determining true copy number for each segment. Our approach not only gives posterior estimates for the parameters of interest, namely locations for copy number difference changes and true copy number estimates, but also useful confidence measures. In addition, our algorithm can segment multiple samples simultaneously, and infer both common and rare CNVs across individuals. Finally, for studies of CNVs in tumors, we incorporate an adjustment factor for signal attenuation due to tumor heterogeneity or normal contamination that can improve copy number estimates.     

基于全基因组测序的法医单核苷酸多态性系谱推断研究

目的 通过全基因组测序（whole genome sequencing，WGS）获得高密度单核苷酸多态性（single nucleotide polymorphism，SNP）分型数据，评估分型准确性，研究建立WGS数据用于法医SNP系谱推断的方法。方法 通过华大MGISEQ-200RS测序平台对样本进行深度为30×的WGS，从测序数据中提取Wegene GSA芯片中的645 199个常染色体SNP位点，质控过滤后运用IBS/IBD算法计算预测亲缘关系，并对样本的族群来源进行分析。结果 从测序数据中提取的SNP分型与Wegene GSA芯片分型的一致率大于99.62%。测序获得的SNP数据使用IBS算法可预测1~4级亲缘关系，4级亲缘预测置信区间准确性达100%，使用IBD算法可预测1~7级亲缘关系，7级亲缘预测为有亲缘关系的准确性达100%，通过高深度WGS数据获取的SNP系谱推断能力与芯片预测结果无显著差异。同时，WGS数据用于族群推断与调查结果一致。结论 WGS技术可应用于法医SNP系谱推断，为案件侦破提供线索。     

Proofreading genotyping assays mediated by high fidelity exo+ DNA polymerases

DNA polymerases with 3'-5' proofreading function mediate high fidelity DNA replication but their application for mutation detection was almost completely neglected before 1998. The obstacle facing the use of exo(+) polymerases for mutation detection could be overcome by primer-3'-termini modification, which has been tested using allele-specific primers with 3' labeling, 3' exonuclease-resistance and 3' dehydroxylation modifications. Accordingly, three new types of single nucleotide polymorphism (SNP) assays have been developed to carry out genome-wide genotyping making use of the fidelity advantage of exo(+) polymerases. Such SNP assays might also provide a novel approach for re-sequencing and de novo sequencing. These new mutation detection assays are widely adaptable to a variety of platforms, including real-time PCR, multi-well plate and microarray technologies. Application of exo(+) polymerases to genetic analysis could accelerate the pace of personalized medicine.     

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 .     

激光显微切割分选少量胃癌细胞中PSCA基因的SNP分析

随着基因组关联分析方法的应用,越来越多与胃癌相关的易感基因被发现．易感基因的多态性检测已逐步进入胃癌临床诊断和研究．然而,利用少量胃粘膜细胞开展单核苷酸多态性（SNP）分析对胃癌进行早期诊断常遇下述困难,一是少量胃癌细胞混杂在多种细胞中,异常信号常易被淹没,二是细胞量极少,因此获得的基因组DNA量微,进行多位点或全基因组分析存在困难. 本文利用激光显微切割技术分选少量胃癌细胞,结合全基因组放大技术,进行胃癌相关的前列腺干细胞抗原基因(PSCA)的SNP分析．通过聚合酶链反应-限制性片段长度多态性(PCR-RFLP)和克隆测序方法分析,在分选的胃癌细胞中检测到PSCA的rs2976392位点胃癌相关的“A”等位与rs2294008位点胃癌相关的“T”等位．研究结果表明,所采用的全基因组放大方法保真性高,经过分选的胃癌细胞中SNP位点的检测灵敏度和可靠性大为提高．所建立的少量细胞基因多位点检测方法将同样应用于其它肿瘤和组织的少量细胞研究中,全基因组放大产物也可进行高通量的基因芯片和第二代测序研究．     

Large-scale Genotyping and Genetic Mapping in Plasmodium Parasites

The completion of many malaria parasite genomes provides great opportunities for genomewide characterization of gene expression and high-throughput genotyping. Substantial progress in malaria genomics and genotyping has been made recently, particularly the development of various microarray platforms for large-scale characterization of the Plasmodium falciparum genome. Microarray has been used for gene expression analysis, detection of single nucleotide polymorphism (SNP) and copy number variation (CNV), characterization of chromatin modifications, and other applications. Here we discuss some recent advances in genetic mapping and genomic studies of malaria parasites, focusing on the use of high-throughput arrays for the detection of SNP and CNV in the P. falciparum genome. Strategies for genetic mapping of malaria traits are also discussed.     

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.     

Microarray and allele specific PCR detection of point mutations in Mycobacterium tuberculosis genes associated with drug resistance

Global public health is threatened by the emergence of potentially dangerous antibiotic drug-resistant strains of Mycobacterium tuberculosis. Point mutations in certain M. tuberculosis genes are associated with the resistance of M. tuberculosis strains to antibiotic drugs. The purpose of this study was to develop a suitable microarray-based protocol for the detection of point mutations in M. tuberculosis genes associated with drug resistance. We initially developed a conventional, oligonucleotide microarray protocol and used it to detect and identify on a single microarray slide a number of point mutation-containing rpoB and katG gene target sequences. However, the occurrence of some non-specific hybridization led us to the development of an improved protocol based on allele specific PCR combined with tags/anti-tags and microarrays. This protocol was evaluated by detecting point mutations in M. tuberculosis katG and rpoB gene templates produced by recombinant PCR. The methodology allowed sequences containing single point mutations to be readily distinguished from wild type sequences. The data obtained with the improved protocol had strong and specific signals and relatively low amounts of non-specific hybridization. We successfully used this protocol to detect and identify (<8 h) a number of clinically relevant point mutations in the rpoB, katG and rpsL genes of M. tuberculosis clinical isolates. Our allele specific PCR/tags and anti-tags/microarray protocol has several advantages over our conventional oligonucleotide microarray protocol, and it may have broad applications for point mutation detection.     

蛋白微阵列研究进展

蛋白微阵列是随着基因微阵列技术发展起来的,用于基因微阵列的制备方法、信号的检测及分析系统,也可用于蛋白微阵列。各种蛋白微阵列基质的发展,提高了蛋白的固定效率。放射性同位数、化学发光、激光共聚焦荧光扫描等技术都已用于微阵列的检测。重组蛋白技术的发展,提高了蛋白微阵列检测的通量和灵敏度。蛋白微阵列具有通量高、使用样品少、重复性好、可定量的特点,使其在生物医药科学研究中得到了广泛应用。本综述了蛋白微阵列的制备及其在免疫检测、医学诊断及蛋白组研究中的应用。     

SNP Chart: an integrated platform for visualization and interpretation of microarray genotyping data

SNP Chart is a Java application for the visualization and interpretation of microarray genotyping data primarily derived from arrayed primer extension-based chemistries. Spot intensity output files from microarray analysis tools are imported into SNP Chart, together with a multi-channel TIFF image of the original array experiment and a list of the actual single nucleotide polymorphisms (SNPs) being tested. Data from different and/or replicate probes that interrogate the same SNP, but that are scattered across the array grid, can be reassembled into a single chart format, specific for the SNP. This allows a quick and very effective 'visualization'/'quality control' of the data from multiple probes for the same SNP that can be easily interpreted and manually scored as a genotype. AVAILABILITY: http://www.snpchart.ca.     

Development of the Handy Bio-Strand and its application to genotyping of OPRM1 (A118G)

We previously developed a three-dimensional microarray system, the Bio-Strand, which exhibits advantages in automated DNA analysis in combination with our Magtration Technology. In the current study, we have developed a compact system for the Bio-Strand, the Handy Bio-Strand, which consists of several tools for the preparation of Bio-Strand Tip, hybridization, and detection. Using the Handy Bio-Strand, we performed single nucleotide polymorphism (SNP) genotyping of OPRM1 (A118G) by allele-specific oligonucleotide competitive hybridization (ASOCH). DNA fragments containing SNP sites were amplified from genomic DNA by PCR and then were fixed on a microporous nylon thread. Thus, prepared Bio-Strand Tip was hybridized with allele-specific Cy5 probes (<15mer), on which the SNP site was designed to be located in the center. By optimizing the amount of competitors, the selectivity of Cy5 probes increased without a drastic signal decrease. OPRM1 (A118G) genotypes of 23 human genomes prepared from whole blood samples were determined by ASOCH using the Handy Bio-Strand. The results were perfectly consistent with those determined by PCR direct sequencing. ASOCH using the Handy Bio-Strand would be a very simple and reliable method for SNP genotyping for small laboratories and hospitals.     

High-throughput SNP genotyping based on solid-phase PCR on magnetic nanoparticles with dual-color hybridization

Single-nucleotide polymorphisms (SNPs) are one-base variations in DNA sequence that can often be helpful when trying to find genes responsible for inherited diseases. In this paper, a microarray-based method for typing single nucleotide polymorphisms (SNPs) using solid-phase polymerase chain reaction (PCR) on magnetic nanoparticles (MNPs) was developed. One primer with biotin-label was captured by streptavidin coated magnetic nanoparticles (SA-MNPs), and PCR products were directly amplified on the surface of SA-MNPs in a 96-well plate. The samples were interrogated by hybridization with a pair of dual-color probes to determine SNP, and then genotype of each sample can be simultaneously identified by scanning the microarray printed with the denatured fluorescent probes. The C677T polymorphisms of methylenetetrahydrofolate reductase (MTHFR) gene from 126 samples were interrogated using this method. The results showed that three different genotypes were discriminated by three fluorescence patterns on the microarray. Without any purification and reduction procedure, and all reactions can be performed in the same vessel, this approach will be a simple and labor-saving method for SNP genotyping and can be applicable towards the automation system to achieve high-throughput SNP detection.     

The application of single nucleotide polymorphism microarrays in cancer research

The development of microarray technology has had a significant impact on the genetic analysis of human disease. The recently developed single nucleotide polymorphism (SNP) array can be used to measure both DNA polymorphism and dosage changes. Our laboratory has applied SNP microarray analysis to uncover frequent uniparental disomies and sub-microscopic genomic copy number gains and losses in different cancers. This review will focus on the wide range of applications of SNP microarray analysis to cancer research. SNP array genotyping can determine loss of heterozygosity, genomic copy number changes and DNA methylation alterations of cancer cells. The same technology can also be used to investigate allelic association in cancers. Therefore, it can be applied to the identification of cancer predisposition genes, oncogenes and tumor suppressor genes in specific types of tumors. As a consequence, they have potential in cancer risk assessment, diagnosis, prognosis and treatment selection.     

Position Dependent Plasmonic Interaction Between a Single Nanoparticle and a Nanohole Array

The interaction of surface plasmons supported on a nanohole array and a single nanoparticle affixed to an atomic force microscopy (AFM) probe was studied for optimizing gap mode enhancement of the plasmonic field. Scanning probe microscopy controlled the AFM probe position, and the location specific interaction of the single nanoparticle (SNP) probe-nanohole array surface plasmons, was measured by darkfield spectroscopy. Raster-scanned darkfield imaging of the surface plasmons on the nanohole array is demonstrated, as well as image formation from measuring the SNP interaction at various (X, Y) locations relative to the nanohole. Coupling of the nanoparticle to the nanohole array exhibited maximal coupling when the SNP resided within a nanohole, resulting in a maximum SPR wavelength shift of 17 nm and an increase in scatter intensity of 137×. This technique may be expanded to mapping nanostructure coupling across three dimensions to determine optimal coupling conditions for applications in biosensing and surface enhanced spectroscopy. This contribution presents the first empirical observations of scanning probe microscopy (SPM) controlled gap mode enhancement of more complex nanostructures, a method for positioning optimization prior to sensing applications and experimental evidence for optimal lateral SNP-nanohole array positioning.     

Guidelines for incorporating non-perfectly matched oligonucleotides into target-specific hybridization probes for a DNA microarray

Sequence-specific oligonucleotide probes play a crucial role in hybridization techniques including PCR, DNA microarray and RNA interference. Once the entire genome becomes the search space for target genes/genomic sequences, however, cross-hybridization to non-target sequences becomes a problem. Large gene families with significant similarity among family members, such as the P450s, are particularly problematic. Additionally, accurate single nucleotide polymorphism (SNP) detection depends on probes that can distinguish between nearly identical sequences. Conventional oligonucleotide probes that are perfectly matched to target genes/genomic sequences are often unsuitable in such cases. Carefully designed mismatches can be used to decrease cross-hybridization potential, but implementing all possible mismatch probes is impractical. Our study provides guidelines for designing non-perfectly matched DNA probes to target DNA sequences as desired throughout the genome. These guidelines are based on the analysis of hybridization data between perfectly matched and non-perfectly matched DNA sequences (single-point or double-point mutated) calculated in silico. Large changes in hybridization temperature predicted by these guidelines for non-matched oligonucleotides fit independent experimental data very well. Applying the guidelines to find oligonucleotide microarray probes for P450 genes, we confirmed the ability of our point mutation method to differentiate the individual genes in terms of thermodynamic calculations of hybridization and sequence similarity.