GFP质控芯片的初步研究

目的：建立一种质量控制芯片来监测样品标记、杂交和检测过程中的失误。方法：针对GFP基因设计的4条60mer寡核苷酸探针和1条阳性对照探针polv（U）与流感寡核苷酸探针一起打印在DAKO玻片上,并构建了GFP基因的克隆载体和体外表达载体,将从这两种重组载体上获得的绿色荧光蛋白（Green Fluorescent Protein,GFP）基因的ILNA、DNA片段和人的全血样品中的DNA用限制性显示技术（Restriction Display technology,RD）扩增标记,将标记的样品和荧光标记的通用引物U分别与芯片杂交、检测,并对扫描的结果进行统计分析。结果：GFP探针与相应的样品杂交时出现阳性信号,阳性对照探针在所有的杂交中均出现阳性信号,而空白对照则未检测荧光信号。结论：建立的质控芯片具有较好的敏感性和特异性,可以用于基因芯片中的质量监控。     

应用抑制消减杂交和cDNA芯片技术筛选流行性感冒病毒感染相关基因

病毒基因组有限的编码能力和以病毒蛋白为靶的抗病毒药物易出现耐药性,使从病毒感染宿主筛选病毒感染相关生物大分子作为抗病毒药靶和诊断标志物成为新的研究方向。为了筛选流行性感冒（流感）病毒感染相关基因,采用抑制消减杂交（suppression subtractive hybridization,SSH)技术,以流感病毒A／鲁防／93－9（H3N2）感染的MDCK细胞及正常MDCK细胞为材料,构建病毒感染特异性差减cDNA文库。从文库中随机挑取约800个克隆,PCR扩增其中插入片段,经纯化、紫外定量后,用基因芯片自动点样仪点在氨基片上,制备cDNA芯片。将流感病毒感染的MDCK细胞和正常MDCK细胞的总RNA分别用Cy3、Cy5反转录荧光标记后,与cDNA芯片杂交,用芯片扫描仪扫描获得芯片杂交信号,经阳性对照校正和归一化处理后,以如下条件作为判定基因差异表达的标准;（a)Cy3与Cy5的信号比值大于1．5（正常细胞用Cy5标记）或小于0．67（正常细胞用Cy3标记）;（b)Cy3和Cy5信号值之一必须大于1000。经cDNA芯片筛选获得了18个流感病毒感染特异性克隆,经测序和生物信息学分析发现均为流感病毒感染相关新基因EST。流感病毒感染相关基因cDNA片段的获得,为新型病毒药靶诊断标志物发现和功能研究提供了基础。     

近交系小鼠双色荧光正相杂交芯片技术体系的建立和优化

目的探讨采用单核苷酸多态性（SNP）检测方法-双色荧光正相杂交芯片技术对近交系小鼠遗传质量监测及相关影响因素。方法运用基于芯片的双色荧光正相杂交检测SNP技术,进行芯片杂交动力学研究,考察信号值（Cy3,Cy5）和ratio值（Cy5/Cy3）与PCR产物点样浓度、PCR产物长度和荧光标记探针长度之间的关系,研究PCR产物点样浓度、PCR产物长度和荧光标记探针长度对SNP分型的影响。结果采用正反标记实验后,Ratio值随着PCR产物点样浓度的增加呈稳定趋势;PCR双链产物长度对信号值影响比较大,点样时其长度不宜太长,最好不超过450 bp;随荧光标记探针长度的增加,基因分型能力明显下降,长度为15 bp最佳,长度超过20 bp时,已基本没有区分能力。结论PCR产物点样浓度、PCR产物长度和荧光标记探针长度是双色荧光正相杂交SNP分型系统的重要影响因素,采取适当的PCR产物点样浓度、PCR产物长度和荧光标记探针长度,并采用正反标记实验,可以取得稳定、准确的基因分型效果。为进一步进行近交系小鼠遗传质量监测的研究奠定基础。     

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.     

间隔臂和探针长度与寡核苷酸芯片重复性相关性研究

研究寡核苷酸芯片的重复性与间隔臂（spacer）和探针长度之间的相关性。设计12条不同长度的带有不同spacer的探针,与749bp荧光标记靶序列杂交。扫描分析三次杂交结果,用Quantrray定量分析软件进行分析,随探针长度的延长,杂交信号的变异系数逐步降低,15mer的探针杂交的信号较弱,杂交不够稳定,重复性也相对较差,20mer、25mer、30mer的探针的变异系数逐渐降低。spacer为15时变异系数最小。说明选择spacer为poly（dT）15的25mer和30mer的探针可以获得较好的重复性。     

百合病毒的DNA芯片检测技术研究

根据已知的黄瓜花叶病毒,百合无症病毒、百合斑驳病毒基因核苷酸序列,设计引物和探针,制备寡核苷酸芯片.用Cy3标记核苷酸引物,不对称RT-PCR扩增产物与芯片上的寡核苷酸探针杂交,荧光扫描仪检测并分析信号.研究制备的基因芯片能够检测侵染百合的3种重要病毒核酸的特异性荧光信号,该项技术具有特异、灵敏、快速的优点.     

百合病毒的DNA芯片检测技术研究

根据已知的黄瓜花叶病毒,百合无症病毒、百合斑驳病毒基因核苷酸序列,设计引物和探针,制备寡核苷酸芯片。用Cy3标记核苷酸引物,不对称RT-PCR扩增产物与芯片上的寡核苷酸探针杂交,荧光扫描仪检测并分析信号。研究制备的基因芯片能够检测侵染百合的3种重要病毒核酸的特异性荧光信号,该项技术具有特异、灵敏、快速的优点。     

生物芯片检测细胞中microRNA的表达

目的：制备mieroRNA（miRNA）检测芯片,检测细胞中miRNA的表达。方法：将210个（206个miRNA,4个阳性对照）与已知人类和小鼠miRNA互补的序列作为探针,点干玻片上制备寡核苷酸芯片;提取肿瘤细胞（HeLa,MCF-7,A549,HT-29,ES-2,K562）的miRNA,用荧光染料Cy3标记,并与制备好的芯片杂交;用Sean Array^TM Express1．0扫描仪扫描荧光信号。采用SeanArray3．0和Cluster3．0软件分析处理扫描结果,并用RT—PCR方法对芯片检测结果进行验证。结果：建立了利用生物芯片检测miRNA表达的方法;发现不同细胞miRNA表达谱各异。结论：应用生物芯片技术检测细胞中miRNA的表达是可行的,可为研究miRNA的生理功能和作用机制奠定基础。     

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．     

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％     

Oligonucleotide Microarray with RD-PCR Labeling Technique for Detection and Typing of Human Papillomavirus

Currently, screening for high-risk human papillomavirus (HPV) infection remains an important health concern throughout the world, because of the close association between certain types of HPV and cervical cancer. In this study, we explore the possibility of using ∼70mer oligonucleotide microarray for detection and genotyping of HPV. The ∼70mer type-specific oligonucleotide probes of four different types HPV were designed by using biological software Arraydesigner 2.0, which analyzed the whole genome sequences of HPV and selected optimal probes. These probes were synthesized and printed onto the surface of glass slides in order to prepare a low-density microarray. HPV samples were labeled with fluorescence dyes Cy3 using a method of restriction display polymerase chain reaction (RD-PCR). HPV plasmid DNA was restricted with Sau3A I to produce multiple fragments that were ligated to adaptors subsequently and used as PCR template. PCR labeling was performed with the fluorescently labeled universal primer (Cy3-UP) whose sequence is designed according to the adaptor of the RD-PCR approaches. The labeled samples were hybridized with the oligonucleotide microarray. The scanning results showed that HPV DNA hybridized specifically with multiple spots correspondingly to show positive signals, whereas no signals were detected of all the negative and blank controls. These results demonstrated that ∼70mer oligonucleotide microarray can be applied to HPV detection and genotyping. The application of RD-PCR in the sample labeling can increase significantly the sensitivity of the assay and will be especially useful for the discriminate diagnosis of multiple pathogens.     

三种寡核苷酸芯片片基的比较

将荧光标记的寡核苷酸打印在Corning、多聚赖氨酸包被的DAKO玻片和多聚赖氨酸处理的一种显微镜载玻片上,并按常规方法进行洗脱,通过GenePix4100A扫描并以Genepix6．0软件分析点的大小、荧光强度和背景荧光强度来衡量3种片基的均一性和固定效率,并通过不同浓度梯度的60bp寡核苷酸探针的杂交实验来衡量片基对杂交效率的影响．结果显示,3种片基的均一性都较好,而多聚赖氨酸包被的DAKO和Cornning芯片的固定效率和杂交效率优于国产芯片．     

Analysis of oligonucleotide microarrays by 3' end labeling using fluorescent nucleotides and terminal transferase

A simple enzymatic labeling procedure is described to determine spot quality in oligonucleotide microarrays. By using fluorescently labeled dideoxynucleotides or ribonucleotides as substrate for terminal deoxynucleotidyl transferase (TdT), a single fluorophore can be covalently attached at the 3' end of each oligonucleotide probe molecule in the spot. Fluorescein-12-ddUTP CyTM3-ddUTP Cy5-UTP, and Cy3-UTP were compared as TdT substrates for 3' end labeling an array of 1273 hexamer probes. Cy5-UTP was found to show minimal bias toward probe base composition and is therefore well suited for quantitative analysis of microarray spots where the oligonucleotide probes are coupled via a 5' end linkage to the solid phase.     

An oligonucleotide microarray bait for isolation of target gene fragments

A new molecular-baiting method was studied by retrieving targeted gene fragments from an oligonucleotide microarray bait after hybridization. To make the microarray bait, 70-mer oligonucleotides that were designed to specifically represent the SSA1 gene of Saccharomyces cerevisiae were printed on the slide. Samples of the Saccharomyces cerevisiae mRNA were extracted and labeled by the RD-PCR (Restriction Display PCR) method using the Cy5-labelled universal primer, then applied for hybridization. The sample fragments that hybridized to the microarray were stripped, and the eluted cDNAs were retrieved and cloned into the pMD 18-T vector for transformation, plasmid preparation, and sequencing. BLAST searching of the GenBank database identified the retrieved fragments as being identical to the SSA1 gene (from 2057-2541bp). A new method is being established that can retrieve the sample fragments using an oligo-microarray-bait.     

肿瘤相关基因表达检测寡核苷酸芯片的制备及其初步应用

为研制肿瘤相关寡核苷酸芯片,并实现其在抗肿瘤反义核酸“癌泰得”作用机理研究方面的初步应用,制备了包含近450种肿瘤相关基因特异寡核苷酸探针的寡核苷酸芯片,建立了相应的质控标准.“癌泰得”用脂质体转染HepG2肿瘤细胞,提取细胞总RNA反转录并荧光标记cDNA,用制备的寡核苷酸芯片检测肝癌细胞HepG2的肿瘤相关基因表达水平,用软件分析获得其差异基因表达谱.0.4 μmol/L的反义核酸“癌泰得”作用于HepG2细胞15 h后,MDNCF、DHS等基因mRNA表达下调,MUC2、MPP11、LAT、HRIF-B、JNK3A1等mRNA基因表达上调,初步检测到了“癌泰得”的抗肿瘤作用可能的相关基因,为进一步的分子作用机理的探讨奠定基础.结果表明,制备的肿瘤相关芯片敏感度高、特异性高、重复性均较好,可用于检测肿瘤相关基因的表达谱,为临床诊断和基础研究提供了技术平台.     

Design and application of an oligonucleotide microarray for the investigation of compost microbial communities

A microarray consisting of oligonucleotide probes targeting variable regions of the 16S rRNA gene was designed and tested for the investigation of microbial communities in compost. Probes were designed for microorganisms that have been previously reported in the composting process and for plant, animal and human pathogens. The oligonucleotide probes were between 17 and 25 bp in length and included mostly species-specific sequences. Validation of probe specificity and optimization of hybridization conditions were conducted using fluorescently labeled 16S rRNA gene PCR products of pure culture strains. A labeling method employing a Cy3 or Cy5-labeled forward primer together with a phosphate-conjugated reverse primer for the production of single stranded DNA after a digestion step was optimised and used to label target DNA. A combination of two different DNA extraction methods using both physical and chemical lysis was found to give the best DNA yields. Increased hybridization signal intensities were obtained for probes modified with a 12 mer T-spacer. The microarray was found to have a detection limit of 10(3) cells, although in compost spiking experiments, the detection limit was reduced to 10(5) cells. The application of the microarray to compost samples indicated the presence of Streptococcus, Acinetobacter lwoffii, and Clostridium tetani in various compost samples. The presence of A. lwoffii in those compost samples was confirmed by PCR using primers specific for the organism. The aim of this study was to develop a molecular tool that would allow screening for the presence or absence of different microorganisms within compost samples.     

The Efficiency of DNA Labeling with Near-Infrared Fluorescent Dyes

The efficiency of DNA labeling was assessed for 2'-deoxyuridine 5'-triphosphate (dUTP) derivatives containing the Cy7 cyanine dye as a fluorophore. Two fluorescent Cy7-labeled dUTP analogs differed in the chemical structure of the linker between the fluorophore and nucleotide moieties. The efficiency of the polymerase chain reaction (PCR) and inhibition with modified nucleotides were estimated by real-time PCR. The efficiency of labeled nucleotide incorporation in PCR products was measured by quantitative electrophoresis. The efficiency of target DNA labeling was evaluated by binding the fluorescently labeled PCR products to a microarray of oligonucleotide probes immobilized in hydrogel drops (a biochip). The near-infrared hybridization signal was detected by digital luminescence microscopy. An increase in linker length was found to provide more efficient incorporation of the labeled nucleotide. Both of the compounds provided high sensitivity and high specificity of DNA testing via allele-specific hybridization on a biochip.

     

Identification and removal of contaminating fluorescence from commercial and in-house printed DNA microarrays

Microarray analysis is a critically important technology for genome-enabled biology, therefore it is essential that the data obtained be reliable. Current software and normalization techniques for microarray analysis rely on the assumption that fluorescent background within spots is essentially the same throughout the glass slide and can be measured by fluorescence surrounding the spots. This assumption is not valid if background fluorescence is spot-localized. Inaccurate estimates of background fluorescence under the spot create a source of error, especially for low expressed genes. We have identified spot-localized, contaminating fluorescence in the Cy3 channel on several commercial and in-house printed microarray slides. We determined through mock hybridizations (without labeled target) that pre-hybridization scans could not be used to predict the contribution of this contaminating fluorescence after hybridization because the change in spot-to-spot fluorescence after hybridization was too variable. Two solutions to this problem were identified. First, allowing 4 h of exposure to air prior to printing on to Corning UltraGAPS slides significantly reduced contaminating fluorescence intensities to approximately the value of the surrounding glass. Alternatively, application of a novel, hyperspectral imaging scanner and multivariate curve resolution algorithms, allowed the spectral contributions of Cy3 signal, glass, and contaminating fluorescence to be distinguished and quantified after hybridization.