双色荧光杂交芯片在近交系小鼠遗传监测中的应用

应用一种新的高通量SNP检测方法-双色荧光杂交芯片技术进行近交系小鼠遗传监测。应用双色荧光杂交芯片技术对4个品系近交系小鼠的多个基因组DNA 样本进行SNP分型,整合6个SNP位点的芯片杂交信息,对样本所属品系进行判断。研究结果表明SNP检测方法-双色荧光杂交芯片技术能够对选定的6个SNP位点进行高准确率分型;双色荧光杂交芯片技术是一种高通量SNP检测的良好工具,适合于对少量近交系品系来源的大样本量小鼠进行遗传污染监测和品系鉴定,并具有扩大应用的潜力。     

双色荧光杂交芯片在近交系小鼠遗传监测中的应用

应用一种新的高通量SNP检测方法-双色荧光杂交芯片技术进行近交系小鼠遗传监测。应用双色荧光杂交芯片技术对4个品系近交系小鼠的多个基因组DNA样本进行SNP分型,整合6个SNP位点的芯片杂交信息,对样本所属品系进行判断。研究结果表明SNP检测方法-双色荧光杂交芯片技术能够对选定的6个SNP位点进行高准确率分型;双色荧光杂交芯片技术是一种高通量SNP检测的良好工具,适合于对少量近交系品系来源的大样本量小鼠进行遗传污染监测和品系鉴定,并具有扩大应用的潜力。     

两种标记方法对60mer寡核苷酸芯片背景信号影响的初步分析

研究两种不同的样本标记方法对人全基因组高密度60mer寡核苷酸芯片背景信号的影响。收集5对患病与健康人外周血单个核细胞,分别提取总RNA后,采用限制性显示技术（restriction display,RD）进行样本双色（Cy3/Cy5）荧光标记,与5张Agilent 60mer高密度（22K）Human 1B寡核苷酸芯片进行杂交。芯片全部杂交点分3组：基因探针组、阳性对照组和阴性对照组。阳性对照采用荧光标记寡核苷酸直接掺入法进行标记。对全部杂交信号点的Cy3和Cy5背景信号值,用SPSS软件进行数据转换、正态性检验、方差齐性检验、变异系数分析和重复数据的方差分析。数据分析结果显示,Cy3 标记的背景信号值均高于 Cy5标记的背景信号值。重复测量数据的方差分析表明,在Cy3 和Cy5标记中,两种不同标记方法间的背景信号值的差异极显著（PCy3＜0.01, PCy5＜0.01）,且RD标记点的背景信号平均值低于荧光标记寡核苷酸直接掺入标记法标记的阳性对照点。RD标记方法是一种有用的低背景信号的高密度长链寡核苷酸芯片样本标记方法。     

基于磁性颗粒“在位”PCR和通用标签技术的新型高通量SNP分型方法

单核苷酸多态性(single nucleotide polymorphism,SNP)在对复杂疾病遗传易感性以及基于群体基因识别等方面的研究中起着非常重要的作用,尤其是对复杂疾病遗传易感性的研究,需要对大量样本进行分型.为了满足这种要求,亟待需要发展一种操作简单、成本较低、适于自动化和高通量的分型技术.利用磁性颗粒"在位"固相PCR(insituMPs-PCR)扩增的靶序列,通过与野生、突变标签探针以及双色荧光(Cy3,Cy5)通用检测子杂交实现对样本的分型.应用该方法,对96个样本的亚甲基四氢叶酸还原酶(MTHFR)基因C677T位点的多态性进行了检测,其野生型和突变型样本的正错配信号比大于4.5,杂合型正错配信号比接近1,分型结果与测序结果一致.     

基因表达谱芯片杂交影响因素的初步研究

通过对K562细胞基因表达谱芯片杂交影响因素的研究表明,用限制性显示技术制备的cDNA探针长度较均一,适合基因芯片杂交;在42℃条件下含甲酰胺的杂交液中杂交16．20h,可保证样品的有效杂交。并表现出很好的杂交特异性;用RD-PCR或线性PCR对少量样品进行扩增,并用荧光(Cy3或Cy5)标记的通用引物对样品进行标记,可提高芯片检测的灵敏度;一次杂交反应总RNA的用量仅需0．5～10μg,在每cm^2约含1000～1500个点的阵列中杂交时,标记样品用量1～2μg为宜;用PCR产物纯化柱对荧光标记产物进行纯化,可大大减小背景荧光,提高信噪比;同一批芯片经同一样品杂交结果的重复性很好,相关系数高达97．8％     

细小病毒B19诊断芯片的初步研究

初步探讨并制备细小病毒B19诊断芯片,进行实验室验证．用基因芯片点样仪将细小病毒B19诊断探针固定在特殊处理的玻片上,以细小病毒B19质粒重复检测．运用限制性显示(RD)技术,用Cy5标记的通用引物进行荧光标记,通过与基因芯片杂交,严谨洗涤,将非特异性的标记片段洗脱后,经扫描仪扫描,计算机解读．杂交结果显示,Cy5标记的探针均出现杂交信号,而阴性对照和空白对照的杂交信号均很弱：芯片检测具有高特异性、敏感性和可重复性．初步建立了较可靠的制备与检测细小病毒B19诊断芯片的方法,经验证诊断准确率高,假阳性率低．     

植物病毒检测芯片的杂交条件优化

利用芯片点样仪将5种侵染马铃薯的病毒/类病毒(苜蓿花叶病毒、黄瓜花叶病毒、黄瓜花叶病毒-卫星病毒、马铃薯病毒Y、马铃薯块茎纺锤状类病毒)的保守区寡核苷酸(Oligonucleotide,oligo)探针和PCR探针点样于玻片,并以植物18S rRNA作为内参照制成基因芯片。研究探针浓度、杂交时间、杂交温度以及点样液对芯片杂交的影响,并验证优化后病毒检测芯片的特异性。结果表明,寡核苷酸探针浓度介于5-20 ?mol/L之间对杂交信号强度影响不大,PCR探针浓度与杂交信号强度间呈线性关系;在45℃杂交4 h时,芯片的杂交信号最强,且该条件下进行杂交对两种探针芯片的影响趋势一致;点样液中以DMSO的杂交效果最好。经过整体条件优化后的两种探针芯片在杂交检测上具有较高的特异性,适于检测植物病毒。     

HPV病毒检测分型芯片的研制和优化

研制和优化寡核苷酸芯片以初步实现对多种常见HPV(Human papillomavirus)病毒的分型检测.应用生物学软件对四型常见HPV病毒(6、11、16、18型)的全基因组序列进行分析,设计具有型特异性、熔解温度(Tm)相近的～60 mer寡核苷酸探针,对玻片片基进行优化处理后,点样制备成寡核苷酸基因芯片.将含HPV全长基因序列的质粒作为阳性标准品,利用梯度限制性荧光标记技术对其进行荧光标记,标记好的样品与芯片杂交.结果显示HPV样品与相应的型特异性探针杂交有明显的荧光信号,而与阴性对照探针和空白对照探针没有杂交信号.通过对芯片片基处理和样品荧光标记方法的优化,可以提高芯片检测的杂交特异性和荧光信号强度.     

双色荧光杂交芯片在检测 P 1A 1M P I 基C 因多态性中的应用

目的：应用一种新的高通量SNP检测方法-双色荧光杂交芯片技术检测CYPIA1 MspI基因多态性。方法：收集江苏汉族人群原发性肺癌患者75例和相应对照77例,应用双色荧光杂交芯片技术检测了152例样本的CYPIAI基因MspI基因多态性,并应用PCR-RFLP技术验证双色荧光杂交芯片的特异性。结果：152例样本的CYPIAI基因双色荧光杂交芯片技术分型结果与PCR-RFLP结果完全相符,两种方法的基因型分型结果具有很好的一致性。结论：双色荧光杂交芯片技术是一个高通量SNP检测的良好工具,特异性高,在大规模人群SNP筛检中具有良好的发展前案。     

2型登革病毒检测基因芯片的研制

利用长片断PCR扩增含几乎全长的2型登革病毒cDNA,酶切PCR扩增产物,通过建立2型登革病毒。DNA文库获取芯片探针用点样仪将探针制备成2型登革病毒检测基因芯片,杂交时采用限制性显示(Restriction Display RD)技术标记样品,Scan Array芯片扫描仪检测杂交信号．杂交结果显示,样品和2型登革病毒基因芯片杂交的敏感性强、特异性高．     

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.     

A novel automated assay with dual-color hybridization for single-nucleotide polymorphisms genotyping on gold magnetic nanoparticle array

A high-throughput and cost-effective single-nucleotide polymorphism (SNP) genotyping method based on a gold magnetic nanoparticle (GMNP) array with dual-color hybridization has been designed. Biotinylated single-strand polymerase chain reaction (PCR) products containing the SNP locus were captured by the GMNPs that were coated with streptavidin. The GMNP array was fabricated by immobilizing single-stranded DNA (ssDNA)-GMNP complexes onto a glass slide using a magnetic field, and SNPs were identified with dual-color fluorescence hybridization. Three different SNP loci from 24 samples were genotyped successfully using this platform. This procedure allows the user to directly analyze the bead fluorescence to determine the SNP genotype, and it eliminates the need for background subtraction for signal determination. This method also bypasses tedious PCR purification and concentration procedures, and it facilitates large-scale SNP studies by using a method that is highly sensitive, simple, labor-saving, and potentially automatable.     

Directly labeled DNA probes using fluorescent nucleotides with different length linkers.

Directly labeled fluorescent DNA probes have been made by nick translation and PCR using dUTP attached to the fluorescent label, Cy3, with different length linkers. With preparation of probes by PCR we find that linker length affects the efficiency of incorporation of Cy3-dUTP, the yield of labeled probe, and the signal intensity of labeled probes hybridized to chromosome target sequences. For nick translation and PCR, both the level of incorporation and the hybridization fluorescence signal increased in parallel when the length of the linker arm is increased. Under optimal conditions, PCR yielded more densely labeled probes, however, the yield of PCR labeled probe decreased with greater linear density of labeling. By using a Cy3-modified dUTP with the longest linker under optimal conditions it was possible to label up to 28% of the possible substitution sites on the target DNA with reasonable yield by PCR and 18% by nick translation. A mechanism involving steric interactions between the polymerase, cyanine-labeled sites on template and extending chains and the modified dUTP substrate is proposed to explain the inverse correlation between the labeling efficiency and the yield of DNA probe synthesis by PCR.     

Suspension arrays for high throughput, multiplexed single nucleotide polymorphism genotyping

BACKGROUND: Genetic diversity can help explain disease susceptibility and differential drug response. The most common type of variant is the single nucleotide polymorphism (SNP). We present a low-cost, high throughput assay for SNP genotyping. METHODS: The assay uses oligonucleotide probes covalently attached to fluorescently encoded microspheres. These probes are hybridized directly to fluorescently labeled polymerase chain reaction (PCR) products and the results are analyzed in a standard flow cytometer. RESULTS: The genotypes determined with our assay are in good agreement with those determined by TaqMan. The range of G/C content for oligonucleotide probes was 23.5-65% in the 17 bases surrounding the SNP. Further optimization of probe length and target concentration is shown to dramatically enhance the assay performance for certain SNPs. Using microspheres which have unique fluorescent signatures, we performed a 32-plex assay where we simultaneously determined the genotypes of eight different polymorphic genes. CONCLUSIONS: We demonstrate, for the first time, the feasibility of multiplexed genotyping with suspension arrays using direct hybridization analyses. Our approach enables probes to be removed from or added to an array, enhancing flexibility over conventional chips. The ability to multiplex both the PCR preparation and the hybridization should enhance the throughput, cost, and speed of the assay.     

Microarray-based method for genotyping of functional single nucleotide polymorphisms using dual-color fluorescence hybridization

Screening disease-related single nucleotide polymorphism (SNP) markers in the whole genome has great potential in complex disease genetics and pharmacogenetics researches. It has led to a requirement for high-throughput genotyping platforms that can maximize the efficient screening functional SNPs with respect to accuracy, speed and cost. In this study, we attempted to develop a microarray-based method for scoring a number of genomic DNA in parallel for one or more molecular markers on a glass slide. Two SNP markers localized to the methylenetetrahydrofolate reductase gene (MTHFR) were selected as the investigated targets. Amplified PCR products from nine genomic DNA specimens were spotted and immobilized onto a poly-l-lysine coated glass slide to fabricate a microarray, then interrogated by hybridization with dual-color probes to determine the SNP genotype of each sample. The results indicated that the microarray-based method could determine the genotype of 677 and 1298 MTHFR polymorphisms. Sequencing was performed to validate these results. Our experiments successfully demonstrate that PCR products subjected to dual-color hybridization on a microarray could be applied as a useful and a high-throughput tool to analyze molecular markers.     

Single nucleotide polymorphism detection in aldehyde dehydrogenase 2 (ALDH2) gene using bacterial magnetic particles based on dissociation curve analysis

Single nucleotide polymorphism (SNP) detection for aldehyde dehydrogenase 2 (ALDH2) gene based on DNA thermal dissociation curve analysis was successfully demonstrated using an automated system with bacterial magnetic particles (BMPs) by developing a new method for avoiding light scattering caused by nanometer-size particles when using commercially available fluorescent dyes such as FITC, Cy3, and Cy5 as labeling chromophores. Biotin-labeled PCR products in ALDH2, two allele-specific probes (Cy3-labeled detection probe for ALDH2*1 and Cy5-labeled detection probe for ALDH2*2), streptavidin-immobilized BMPs (SA-BMPs) were simultaneously mixed. The mixture was denatured at 70 degrees C for 3 min, cooled slowly to 25 degrees C, and incubated for 10 min, allowing the DNA duplex to form between Cy3- or Cy5-labeled detection probes and biotin-labeled PCR products on SA-BMPs. Then duplex DNA-BMP complex was heated to 58 degrees C, a temperature determined by dissociation curve analysis and a dissociated single-base mismatched detection probe was removed at the same temperature under precise control. Furthermore, fluorescence signal from the detection probe was liberated into the supernatant from completely matched duplex DNA-BMP complex by heating to 80 degrees C and measured. In the homozygote target DNA (ALDH2*1/*1 and ALDH2*2/*2), the fluorescence signals from single-base mismatched were decreased to background level, indicating that mismatched hybridization was efficiently removed by the washing process. In the heterozygote target DNA (ALDH2*1/*2), each fluorescence signals was at a similar level. Therefore, three genotypes of SNP in ALDH2 gene were detected using the automated detection system with BMPs.     

A single nucleotide polymorphism genotyping method using phosphate-affinity polyacrylamide gel electrophoresis

To date, various methods have been developed to facilitate the genotyping of a single nucleotide polymorphism (SNP) for aiding in the diagnosis and treatment of inherited diseases. The most commonly used method for SNP genotyping is an allele-specific hybridization procedure using an expensive fluorochrome-labeled oligonucleotide probe and a specialized fluorescence analyzer. Here, we introduce a simple and reliable genotyping method using a 1:1 mixture of 5'-phosphate-labeled and nonlabeled allele-specific polymerase chain reaction (PCR) primers. The method is based on the difference in mobility of the phosphorylated and nonphosphorylated PCR products (in the same number of basepairs) on phosphate-affinity polyacrylamide gel electrophoresis. The phosphate-affinity site is a polyacrylamide-bound dinuclear zinc(II) complex, which preferentially captures the 5'-phosphate-labeled allele-specific product compared with the corresponding nonlabeled product. The obtained DNA migration bands can be visualized by ethidium bromide staining. We demonstrate the genotyping of a SNP reported in a human cardiac sodium channel gene, SCN5A, using this novel procedure.