DNA芯片制作原理及其杂交信号检测方法

文章讨论了ＤＮＡ芯片的制作原理和杂交信号的检测方法。依其结构,ＤＮＡ芯片可分为两种形式,ＤＮＡ阵列和寡核苷酸微芯片。ＤＮＡ芯片的制作方法主要有光导原位合成法和自动化点样法。ＤＮＡ芯片与标记的探针或ＤＮＡ样品杂交,并通过探测杂交信号谱型业实现ＤＮＡ序列或基因表达的分析。适应于ＤＮＡ芯片的发展,同时出现了许多新型的杂交信号检测方法。主要有激光荧光扫描显微镜、激光扫描共焦显微镜、结合作用ＣＣＤ相机的荧光     

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。     

一种基于寡核苷酸微阵列芯片的多重可扩增探针杂交技术

多重可扩增探针杂交技术(multiplex amplifiable probe hybridization,MAPH)是近年来发展起来的一种用于基因组中DNA拷贝数检测的新技术。并发展了一种基于寡核苷酸微阵列芯片的MAPH技术。该方法根据所检测的DNA序列,制备若干具有通用引物的FCR产物作为可扩增探针组,与固定在尼龙膜上待测的基因组DNA杂交。用磁珠回收特异性杂交的探针,经生物素标记的通用引物扩增后,与相应的寡核苷酸微阵列芯片杂交。该特异性的寡核苷酸微阵列芯片包括10个抗肌营养不良基因的外显子探针和阴性、阳性探针。杂交清冼后,链霉亲和素-Cy3染色用芯片扫描仪得到杂交的荧光图像。分析荧光信号的强度差异给出特定基因片段拷贝数的变化。该方法用微阵列技术代替MAPH中的电泳检测技术,可大幅度增加检测的通量。选择了一个正常男性、一个正常女性和一个肌营养不良症患者的基因组DNA来进行验证。结果表明,该方法能够同时给出抗肌营养不良基因多个外显子中的基因片段拷贝数差异信息。     

DNA芯片的制作原理及其应用

综述了DNA芯片制作原理和杂交信号检测方法及发展趋势,对DNA芯片在研究基因结构和基因表达等方面的应用进行了分析。     

cDNA芯片阳性对照的制备及在芯片敏感性分析中的应用

cDNA芯片是一种高通量基因表达谱分析技术,在生理病理条件下细胞基因表达谱分析,新基因发现和功能研究等方面具有广阔应用前景。CDNA芯片阳性对照的选取以及CDNA芯片检测敏感性是芯片成功应用的关键问题之一。以在系统发育上与人类基因同源性小的荧火虫荧光素酶基因材料,制备了用于人类和其他动物基因表达谱CDNA芯片的通用型阳性对照探针和相应的mRNA参照物,经反转录对mRNA参照物进行Cy3荧光标记并与DNA芯片杂交后发现,mRNA参照物能特异性地与荧光酶基因cDNA片断杂交,而与人β-肌动蛋白基因,人G3PDH基因以及λDNA/HINDⅢ无杂交反应。把mRNA参照物以不同比例加入HepG2总RNA中,以反转录荧光标记后与CDNA芯片杂交,结果发现当总RNA中的MRNA含量为1/10^4稀释（即mRNA分子个数约为10^8个）时,CDNA芯片基本检测不出mRNA标记产物的杂交信号。而且,cDNA芯片检测的信号强度与芯片上固定的探针浓度密切相关,当探针浓度为2g/L时,杂交信号最强,随着探针浓度下降芯片的杂交信号趋于减弱。CDNA芯片通用型阳性参照物的制备以及应用于CDNA芯片检测敏感性研究为CDNA芯片应用于人和其他动物基因表达谱高通量分析和新基因功能研究提供了技术基础和理论依据。     

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。     

梨自交不亲和基因cDNA芯片杂交条件优化及应用北大核心

[目的]优化梨自交不亲和基因(S-RNase或S基因)c DNA芯片杂交条件,利用芯片检测梨品种S基因型。[方法]提取梨品种雌蕊RNA,Cy3标记引物RT-PCR获得S基因荧光标记特异c DNA序列。设置不同杂交条件,用已知S基因型品种荧光标记的PCR产物在不同条件下分别与芯片杂交,杂交信号分析芯片杂交效果。用芯片优化杂交体系鉴定梨品种未知S基因型,DNA测序验证芯片鉴定结果。[结果]芯片杂交最佳条件:杂交温度42℃,杂交时间8~9 h,PCR纯化产物终浓度为200 ng·μl-1。优化杂交条件下芯片鉴定晚咸丰、秀水、丽江马占梨1、湘菊、木通梨、甘甜、弥渡小红梨、丽江大中古、金晶和弥渡火把等梨品种S基因型分别为:Pp S15Pp S52、Pp S4Pp S5、Pb S22Pp S37、Pp S1Pp S2、Pp S1Pp S3、Pp S13Pp S15、Pp S12Pb S42、Pb S21Pb S22、Pp S3Pp S60和Pp S5Pp S5。DNA测序验证各品种所含S基因与芯片鉴定结果一致。[结论]梨自交不亲和基因c DNA芯片优化杂交条件后可准确鉴定梨品种所含已鉴定的S基因资源。     

梨自交不亲和基因cDNA芯片杂交条件优化及应用

[目的]优化梨自交不亲和基因(S-RNase或S基因)c DNA芯片杂交条件,利用芯片检测梨品种S基因型。[方法]提取梨品种雌蕊RNA,Cy3标记引物RT-PCR获得S基因荧光标记特异c DNA序列。设置不同杂交条件,用已知S基因型品种荧光标记的PCR产物在不同条件下分别与芯片杂交,杂交信号分析芯片杂交效果。用芯片优化杂交体系鉴定梨品种未知S基因型,DNA测序验证芯片鉴定结果。[结果]芯片杂交最佳条件:杂交温度42℃,杂交时间8~9 h,PCR纯化产物终浓度为200 ng·μl-1。优化杂交条件下芯片鉴定晚咸丰、秀水、丽江马占梨1、湘菊、木通梨、甘甜、弥渡小红梨、丽江大中古、金晶和弥渡火把等梨品种S基因型分别为:Pp S15Pp S52、Pp S4Pp S5、Pb S22Pp S37、Pp S1Pp S2、Pp S1Pp S3、Pp S13Pp S15、Pp S12Pb S42、Pb S21Pb S22、Pp S3Pp S60和Pp S5Pp S5。DNA测序验证各品种所含S基因与芯片鉴定结果一致。[结论]梨自交不亲和基因c DNA芯片优化杂交条件后可准确鉴定梨品种所含已鉴定的S基因资源。     

制备炭疽芽胞杆菌检测基因芯片的初步研究

建立制备炭疽芽胞杆菌检测基因芯片的技术,并探讨研制检测炭疽芽胞杆菌基因芯片的方法。酶切炭疽芽胞杆菌的毒素质粒和荚膜质粒,通过建立质粒DNA文库的方法获取探针,并打印在经过氨基化修饰的玻片上,制成用于炭疽芽胞杆菌检测的基因芯片。收集了290个阳性克隆探针,制备了检测炭疽芽胞杆菌的基因芯片。提取炭疽芽胞杆菌质粒DNA与基因芯片杂交,经ScanArray Lite芯片阅读仪扫描得到初步的杂交荧光图像。通过分析探针的杂交信号初步筛选出273个基因片段作为芯片下一步研究的探针。     

DNA芯片与应用

DNA芯片就是利用光导原位化学合成或液相合成自动化点样,将数以万计的寡核苷酸固定于固相支持物硅片、尼龙膜上,与荧光素或同位素标记的特检样本DNA/cDNA杂交,通过对杂交信号分析反映样本中的DNA序列信息。它广泛应用基因表达、DNA测序、基因分型、基因突变与多态性检测和遗传作图等生物医学研究领域。     

Evaluation of two- and three-dimensional streptavidin binding platforms for surface plasmon resonance spectroscopy studies of DNA hybridization and protein-DNA binding

Surface plasmon resonance (SPR) spectroscopy has been used to study DNA assembly, DNA hybridization, and protein-DNA interactions on two streptavidin (SA) sensor chips. On one chip, SA molecules are immobilized on a biotin-exposed surface, forming an ordered two-dimensional (2D) SA monolayer. The other chip, BIAcore's SA chip, contains SA molecules immobilized within a three-dimensional (3D) carboxylated dextran matrix. Compared to the 2D chip, the 3D SA matrix allows for a slower immobilization rate of biotinylated DNA due to diffusion limitation in the dextran matrix, but with twice the amount of the immobilized DNA due to the greater number of reactive sites, which in turn enables a higher sensitivity for DNA hybridization detection. Interestingly, having a greater DNA probe dispersion in the 3D matrix does not induce a higher DNA hybridization efficiency. In a study of protein binding to immobilized DNA (estrogen receptor to estrogen response elements), aiming at assessing the DNA sequence dependent protein binding behavior, the 2D and 3D chips produce different binding characteristics. On the 2D chip, the protein binding exhibits a better selectivity to the specific sequences, regardless of binding stringency (e.g. salt concentration), whereas on the 3D chip, the liquid handling system needs to be optimized in order to minimize transport limitations and to detect small affinity differences. Through this study we demonstrate that the physicochemical structure of SPR chips affects the apparent binding behaviors of biomolecules. When interpreting SPR binding curves and selecting a sensor chip, these effects should be taken into account.     

The BARC biosensor applied to the detection of biological warfare agents

The Bead ARray Counter (BARC) is a multi-analyte biosensor that uses DNA hybridization, magnetic microbeads, and giant magnetoresistive (GMR) sensors to detect and identify biological warfare agents. The current prototype is a table-top instrument consisting of a microfabricated chip (solid substrate) with an array of GMR sensors, a chip carrier board with electronics for lock-in detection, a fluidics cell and cartridge, and an electromagnet. DNA probes are patterned onto the solid substrate chip directly above the GMR sensors, and sample analyte containing complementary DNA hybridizes with the probes on the surface. Labeled, micron-sized magnetic beads are then injected that specifically bind to the sample DNA. A magnetic field is applied, removing any beads that are not specifically bound to the surface. The beads remaining on the surface are detected by the GMR sensors, and the intensity and location of the signal indicate the concentration and identity of pathogens present in the sample. The current BARC chip contains a 64-element sensor array, however, with recent advances in magnetoresistive technology, chips with millions of these GMR sensors will soon be commercially available, allowing simultaneous detection of thousands of analytes. Because each GMR sensor is capable of detecting a single magnetic bead, in theory, the BARC biosensor should be able to detect the presence of a single analyte molecule.     

Hydrogel drop microchips with immobilized DNA: properties and methods for large-scale production

Although gel-based microchips offer significant advantages over two-dimensional arrays, their use has been impeded by the lack of an efficient manufacturing procedure. Here we describe two simple, fast, and reproducible methods of fabrication of DNA gel drop microchips. In the first, copolymerization method, unsaturated groups are chemically attached to immobilized molecules, which are then mixed with gel-forming monomers. In the second, simpler polymerization-mediated immobilization method, aminated DNA without prior modification is added to a polymerization mixture. Droplets of polymerization mixtures are spotted by a robot onto glass slides and the slides are illuminated with UV light to induce copolymerization of DNA with gel-forming monomers. This results in immobilization of DNA within the whole volume of semispherical gel drops. The first method can be better controlled while the second one is less expensive, faster, and better suited to large-scale production. The microchips manufactured by both methods are similar in properties. Gel elements of the chip are porous enough to allow penetration of DNA up to 500 nucleotides long and its hybridization with immobilized oligonucleotides. As shown with confocal microscope studies, DNA is hybridized uniformly in the whole volume of gel drops. The gels are mechanically and thermally stable and withstand 20 subsequent hybridizations or 30-40 PCR cycles without decrease in hybridization signal. A method for quality control of the chips by staining with fluorescence dye is proposed. Applications of hydrogel microchips in research and clinical diagnostics are summarized.     

Chips from chips: application to the study of antibody responses to methylated proteins

Peptide microarrays are useful tools for the characterization of humoral responses against peptide antigens. The study of post-translational modifications requires the printing of appropriately modified peptides, whose synthesis can be time-consuming and expensive. We describe here a method named "chips from chips", which allows probing the presence of antibodies directed toward modified peptide antigens starting from unmodified peptide microarrays. The chip from chip concept is based on the modification of peptide microspots by simple chemical reactions. The starting peptide chip (parent chip) is covered by the reagent solution, thereby allowing the modification of specific residues to occur, resulting in the production of a modified peptide chip (daughter chip). Both parent and daughter chips can then be used for interaction studies. The method is illustrated using reductive methylation for converting lysines into dimethyllysines. The rate of methylation was studied using specific antibodies and fluorescence detection, or surface-assisted laser desorption ionization mass spectrometry. This later technique showed unambiguously the efficient methylation of the peptide probes. The method was then used to study the humoral response against the Mycobacterium tuberculosis heparin-binding hemagglutinin, a methylated surface-associated virulence factor and powerful diagnostic and protective antigen.     

Normalization of DNA-microarray data by nonlinear correlation maximization.

Signal data from DNA-microarray ("chip") technology can be noisy; i.e., the signal variation of one gene on a series of repetitive chips can be substantial. It is becoming more and more recognized that a sufficient number of chip replicates has to be made in order to separate correct from incorrect signals. To reduce the systematic fraction of the noise deriving from pipetting errors, from different treatment of chips during hybridization, and from chip-to-chip manufacturing variability, normalization schemes are employed. We present here an iterative nonparametric nonlinear normalization scheme called simultaneous alternating conditional expectation (sACE), which is designed to maximize correlation between chip repeats in all-chip-against-all space. We tested sACE on 28 experiments with 158 Affymetrix one-color chips. The procedure should be equally applicable to other DNA-microarray technologies, e.g., two-color chips. We show that the reduction of noise compared to a simple normalization scheme like the widely used linear global normalization leads to fewer false-positive calls, i.e., to fewer genes which have to be laboriously confirmed by independent methods such as TaqMan or quantitative PCR.     

Characterization of DNA chips by nanogold staining

DNA microarray is an important tool in biomedical research. Up to now, there are no chips that can allow both quality analysis and hybridization using the same chip. It is risky to draw conclusions from results of different chips if there is no knowledge of the quality of the chips before hybridization. In this article, we report a colorimetric method to do quality control on an array. The quality analysis of probe spots can be obtained by using gold nanoparticles with positive charges to label DNA through electrostatic attraction. The probe spots can also be detected by a simple personal computer scanner. Gold nanoparticles deposited on a glass surface can be dissolved in bromine-bromide solution. The same microarray treated with gold particles staining and destaining can still be used for hybridization with nearly the same efficiency. This approach makes quality control of a microarray chip feasible and should be a valuable tool for biomarker discovery in the future.     

Detection of bacteriophage infection and prophage induction in bacterial cultures by means of electric DNA chips

Infections of bacterial cultures by bacteriophages are common and serious problems in many biotechnological laboratories and factories. A method for specific, quantitative, and quick detection of phage contamination, based on the use of electric DNA chip is described here. Different phages of Escherichia coli and Bacillus subtilis were analyzed. Phage DNA was isolated from bacterial culture samples and detected by combination of bead-based sandwich hybridization with enzyme-labeled probes and detection of the enzymatic product using silicon chips. The assay resulted in specific signals from all four tested phages without significant background. Although high sensitivity was achieved in 4h assay time, a useful level of sensitivity (10(7)-10(8) phages) is achievable within 25 min. A multiplex DNA chip technique involving a mixture of probes allows for detection of various types of phages in one sample. These analyses confirmed the specificity of the assay.     

Immunoassays and sequence-specific DNA detection on a microchip using enzyme amplified electrochemical detection

A CMOS fabricated silicon microchip was used as a platform for immunoassays and DNA synthesis and hybridization. The chip is covered with a biofriendly matrix wherein the chemistries occur. The active silicon chip has over 1000 active electrodes that can be individually addressed for both synthesis of DNA and protein attachment to a membrane on the chip surface. Additionally, the active chip can be further used for the detection of various analytes at the chip surface via digital read out resulting from the redox enzymes on the captured oligonucleotide or antibody.     

Enhanced detection of staphylococcal genomes in positive blood cultures using a polymeric enzyme complex

This article describes a simple and inexpensive signal amplification method, termed polymeric enzyme detection (PED), which permits rapid and sensitive detection of conserved sequences in the tuf gene that identify Staphylococcus genus, conserved sequences in the femB gene that specifically detect Staphylococcus aureus species, and the methicillin resistance gene mecA directly from positive blood culture bottles. Microbe-specific capture probes were immobilized onto microtiter plates or silicon chips. Target sequences and biotin-labeled, target-specific probes were hybridized to complementary capture probes to create a biotin-labeled, surface-immobilized tripartite complex. In a two-step process, signal was amplified by incubating the surface-immobilized biotin with streptavidin followed by the addition of a 500-kDa dextran polymer conjugated with approximately 80 biotins. Signal was then developed by binding of a streptavidin-horseradish peroxidase conjugate followed by incubation with the substrate tetramethylbenzidine. Use of the PED method improved the lower limit of detection 10- to 100-fold in model DNA hybridization assays with limits of detection as low as 1 fmol/L target DNA. This level of sensitivity permits detection of genomic DNA from methicillin-resistant S. aureus positive blood cultures within 25 to 35 min using either a thin film biosensor chip or a microtiter plate-based assay.