采用纳米金和双链探针比色检测单碱基突变

将链置换的高度特异性与纳米金凝聚变色的光学特性相结合,设计了一种新型的单碱基突变比色检测方法。本方法直接采用纳米金作为比色报告基团,以两个末端均带有巯基的双链DNA为特异捕获探针,利用互补序列和单碱基突变序列对双链探针置换能力的差异,实现了对单碱基突变的检测。本检测方法直观、快速、简便、成本低,pmol级的样品无需仪器就可以观察到颜色的变化。     

高灵敏纳米金比色芯片检测乙型肝炎病毒DNA及其变异

构建了新型纳米金比色芯片,利用Taq DNA连接酶的连接特异性,将其与乙型肝炎病毒DNA( HBV-DNA)靶序列完全互补杂交的捕获探针(固定在芯片上)和纳米金修饰的探针连接成一条链,从而将纳米金颗粒固定到芯片点阵上,再通过银染反应放大,形成裸眼可见的显色信息.通过点阵的位置及灰度,即可判断HBV-DNA靶序列的单碱基突变,并得出相对定量信息.本实验对不同浓度的HBV-DNA靶序列进行了检测.结果显示:此技术对单碱基突变有很强的特异性识别能力,并且具有较高的灵敏度(约10 pmol/L),在10～100 pmol/L浓度范围内表现出较好的线性关系.该技术检测时间短(＜1 h)、操作简单、不需要特殊的检测设备,具有很好的临床应用前景.     

含寡聚腺嘌呤序列DNA探针在金纳米粒子上的固定及杂交性能

利用寡聚腺嘌呤序列(OAS)与金的强相互作用,在金纳米粒子(AuNPs)上固定不同密度DNA探针(DNAprobe),详细探究不同条件(OAS长度、AuNPs粒径、NaCl浓度等)下单链DNAprobe的固定效果,以及制备的纳米探针(Au-probe)与互补DNA目标分子(DNAtarget)的杂交性能.利用透射电子显微镜(TEM)、紫外可见分光光度计(UV-Vis)、激光粒度仪等对制备的AuNPs的形貌、粒径、表面DNAprobe固定及杂交性能等进行了研究.结果表明,随OAS碱基数量由10增加到30和50,Au-probe上固定的DNAprobe数量降低.对粒径为10.2和24.3 nm的AuNPs,杂交效果最佳的NaCl浓度分别为300和25 mmol/L.随着AuNPs粒径增大,AuNPs单位面积上的DNAprobe固定量及DNAtarget杂交量均呈下降趋势.     

基于纳米金探针和基因芯片的DNA检测新方法

运用荧光纳米金探针和基因芯片杂交建立一种新的DNA检测方法. 荧光纳米金探针表面标记有两种DNA探针: 一种为带有Cy5荧光分子的信号探针BP1, 起信号放大作用; 另一种为与靶DNA一部分互补的检测探针P532, 两种探针比例为5∶1. 当靶DNA存在时, 芯片上捕捉探针(与靶DNA的另一部分互补)通过碱基互补配对结合靶DNA, 将靶DNA固定于芯片上; 荧光纳米金探针通过检测探针与靶DNA及芯片结合, 在芯片上形成“三明治”复合结构, 最后通过检测信号探针上荧光分子的信号强度来确定靶DNA的量. 新方法检测灵敏度高, 可以检测浓度为1 pmol/L的靶DNA, 操作简单, 检测时间短. 通过改进纳米金探针的标记和优化杂交条件, 可进一步提高核酸检测的灵敏度, 这将在核酸检测方面具有重要的应用价值.     

微囊藻属DNA电化学传感器的研制

利用自组装法将巯基修饰的DNA探针与6-巯基-1-己醇(MCH)固定到金电极表面,制备了微囊藻属特定DNA传感器,将该传感器与完全互补的微囊藻DNA序列、完全不互补序列,以及单碱基错配序列进行杂交,以Hoechst 33258为杂交指示剂,应用循环伏安法和线性扫描伏安法研究了该传感器对目标DNA的电化学检测行为.研究表明,当与完全互补DNA杂交后,Hoechst 33258氧化信号有明显的增强.实验对自组装时间、MCH浸泡时间及杂交液离子浓度进行了优化.结果表明,当自组装时间为90 min,MCH浸泡时间为1 h,杂交溶液中NaCl浓度为0.3 mol/L时,电化学信号最好.目标DNA的氧化峰电流值与其浓度在1×10~(-8) ～1×10~(-6) mol/L范围内呈良好的线性关系,检出限为8.1×10~(-9) mol/L.     

基于纳米金胶标记DNA探针的电化学DNA传感器研究

以纳米金胶为标记物,将其标记于人工合成的5-端巯基修饰的寡聚核苷酸片段上,制成了具有电化学活性的金胶标记DNA电化学探针;在一定条件下,使其与固定在玻碳电极表面的靶序列进行杂交反应,利用ssDNA与其互补链杂交的高度序列选择性和极强的分子识别能力,以及纳米金胶的电化学活性,实现对特定序列DNA片段的电化学检测以及对DNA碱基突变的识别.     

基于等离子激元耦合效应的高灵敏汞离子传感器

提出了一种基于单颗粒光谱技术,能够高灵敏检测汞离子的新方法,原理是基于汞离子诱导的纳米金自组装过程.在两种不同大小的纳米金表面分别修饰两段富含T碱基的DNA序列,当Hg²⁺存在时,两段DNA序列自发形成双链结构,导致小金球能够在大金球表面自组装成核-卫星纳米金结构,这一过程伴随着纳米颗粒散射光颜色和散射峰位置的变化,变化的程度与Hg²⁺浓度具有相关性,依托单颗粒光谱技术极高的检测灵敏度,该方法可以实现pmol/L级的检测.     

基于DNA聚合酶I的新型电化学传感器及其胰腺癌K-ras基因点突变检测

本文构建DNA聚合酶I的新型DNA电化学传感器,将捕获探针通过Au-S键固定于Au基底表面,与互补靶序列杂交至点突变前一个碱基,通过DNA聚合酶Ⅰ将dUTP-biotin连接在目标DNA的检测位点,再与avidin-HRP反应,而后测定在TMB溶液中的电化学特性. 结果表明,DNA电化学传感电极的检测电流值与K-ras突变型基因浓度（1.0×10^-15 ~ 1.0×10^-10 mol·L^-1）对数呈良好的线性关系,且灵敏度高,特异性较佳.     

基于高区别因子自组装三臂DNA纳米探针检测人体多重耐药基因

建立了一种新的基于高区别因子三臂DNA纳米探针的荧光分析法检测人体多重耐药(MDR)基因。此探针由保护链P1和互补链C1与信号报告部分(信号链S1和信号链S2)组成:P1与修饰了荧光猝灭基团Dabcyl的S1及C1部分碱基杂交;修饰了荧光基团FAM的S2与C1另一部分碱基杂交。探针内部Dabcyl和FAM相互靠近,荧光猝灭。当MDR基因存在时,其与三臂DNA纳米探针发生链替代反应,释放荧光信号。在最优条件下,单碱基错配产生的微小的热力学改变即可影响该探针链替代效率,从而实现高特异性检测MDR基因和其点突变基因(2m、3m、3d、5m、5d)。该探针对不同突变位点及同一突变位点的不同突变类型MDR基因均展现出良好的特异性,其检测3d的区别因子达到24.1,平均区别因子达到11.8。在混合人血清中,MDR基因的回收率为99.0%~101.7%。此外,本方法通用性好,不需要重新设计S1和S2即可实现对miR-21的特异性检测。     

基于银纳米粒子构建荧光传感平台用于核酸检测

报道了基于银纳米粒子构建的荧光传感平台,并用于核酸检测.此荧光传感平台对核酸检测基于以下策略:首先,荧光团标记的单链DNA探针被吸附到银纳米粒子的表面,荧光团与银纳米粒子近距离接触,发生荧光猝灭;加入与探针DNA序列互补的目标DNA,两者杂交形成双链DNA,并从银纳米粒子的表面脱离,荧光得到恢复.这种银纳米粒子构建的荧...     

Surface plasmon resonance biosensor for genetically modified organisms detection

The development of a surface plasmon resonance (SPR) affinity biosensor based on DNA hybridisation is described. This biosensor has been applied to genetically modified organisms (GMOs) detection. Single stranded DNA (ssDNA) probes were immobilised on the sensor chip of an SPR device and the hybridisation between the immobilised probe and the complementary sequence (target) was monitored. The probe sequences were internal to the sequence of 35S promoter and NOS terminator which are inserted sequences in the genome of GMO regulating the transgene expression. The system has been optimised using synthetic oligonucleotides, then applied to real samples analysis. Samples, containing the transgenic target sequences, were amplified by polymerase chain reaction (PCR) and then detected with the SPR biosensor.     

Biocompatible core-shell nanoparticle-based surface-enhanced Raman scattering probes for detection of DNA related to HIV gene using silica-coated magnetic nanoparticles as separation tools

A novel, highly selective DNA hybridization assay has been developed based on surface-enhanced Raman scattering (SERS) for DNA sequences related to HIV. This strategy employs the Ag/SiO₂ core-shell nanoparticle-based Raman tags and the amino group modified silica-coated magnetic nanoparticles as immobilization matrix and separation tool. The hybridization reaction was performed between Raman tags functionalized with 3′-amino-labeled oligonucleotides as detection probes and the amino group modified silica-coated magnetic nanoparticles functionalized with 5′-amino-labeled oligonucleotides as capture probes. The Raman spectra of Raman tags can be used to monitor the presence of target oligonucleotides. The utilization of silica-coated magnetic nanoparticles not only avoided time-consuming washing, but also amplified the signal of hybridization assay. Additionally, the results of control experiments show that no or very low signal would be obtained if the hybridization assay is conducted in the presence of DNA sequences other than complementary oligonucleotides related to HIV gene such as non-complementary oligonucleotides, four bases mismatch oligonucleotides, two bases mismatch oligonucleotides and even single base mismatch oligonucleotides. It was demonstrated that the method developed in this work has high selectivity and sensitivity for DNA detection related to HIV gene.     

A competitive displacement assay with quantum dots as fluorescence resonance energy transfer donors

The unique optoelectronic properties of semiconductor quantum dots (QDs) make them well-suited as fluorescent bioprobes for use in various biological applications. Modification of CdSe/ZnS QDs with biologically relevant molecules provides for multipotent probes that can be used for cellular labeling, bioassays, and localized optical interrogation by means of fluorescence resonance energy transfer (FRET). Herein, we demonstrate the use of red-emitting streptavidin-coated QDs (QD₆₀₅) as donors in FRET to introduce a competitive displacement-based assay for the detection of oligonucleotides. Various QD–DNA bioconjugates featuring 25-mer probe sequences diagnostic of Hsp23 were prepared. The single-stranded oligonucleotide probes were hybridized to dye-labeled (Alexa Fluor 647) reporter sequences, which were provided for a FRET-sensitized emission signal due to proximity of the QD and dye. The dye-labeled sequence was designed to be partially complementary and include base-pair mismatches to facilitate displacement by a more energetically favorable, fully complementary recognition motif embedded within a 98-mer displacer sequence. Overall, this study demonstrates proof-of-concept at the nM level for competitive displacement hybridization assays in vitro by reduction of fluorescence intensity that directly correlates to the presence of oligonucleotides of interest. This work demonstrates an analytical method that could potentially be implemented for monitoring of intracellular gene expression in the future.     

Simultaneous electrochemical DNA hybridization assay for PAT and FMV 35S gene sequence using quantum dots as labels

An electrochemical method for the simultaneous detection of two different DNA sequences from PAT and FMV 35S gene sequence using CdS and PbS quantum dots （QDs） as labels was described. The QDs were readily functionalized with oligonucleotides as electrochemical DNA probes and selectively hybridized to the complementary sequences immobilized on the microplate. The QDs anchored on the hybrids were dissolved in the solution by the oxidation of HNO3 and further detected by a sensitive differential pulse anodic stripping voltammetric method （DPASV）. The DPASV signals of the oxidation of Cd^2＋ and Pb^2＋ ions present in the solution were different and reflected the identity of corresponding ssDNA targets sequences.     

DNA-arrays with electrical detection: a label-free low cost technology for routine use in life sciences and diagnostics

Fast and highly parallel DNA analysis are essential for improved biomedical research and development. Currently fluorescence-based methods are state of the art in DNA microarray analysis. The necessity to modify the target DNA with labels is costly, laborious and requires skilled personnel. Moreover, false positive calls from unspecific adsorption are possible and it is difficult to discriminate perfect matching target sequences from those with a single mismatch. In this paper a new and simple electrochemical approach for hybridisation detection without the need of labelling the target DNA is described. The EDDA (Electrically Detected Displacement Assay) method uses a solution of short redox-labelled signalling oligonucleotides (oligonucleotides carrying a covalently attached redox active compound like ferrocene) to characterize the hybridisation state of label-free capture probe DNA immobilised on gold electrodes. The number of capture probes associated with signalling oligonucleotides is determined by chronocoulometry. This technique allows to separate the electrochemical response of capture probe associated signal probes from the response of freely diffusing signalling probes. In the absence of the complementary target sequences the redox-labelled signalling probes at the surface give rise to an instantaneous increase of the detection signal, while freely diffusing signalling probes show a significantly delayed response. Hybridisation with targets complementary to the capture probe displace the loosely associated signalling probes thereby decreasing the instantaneous signal. Besides an introduction to the EDDA technology, data validating the method for biological material will be presented and an outlook to the detection of single nucleotide polymorphisms (SNPs) is given.     

Dynamic-light-scattering-based sequence-specific recognition of double-stranded DNA with oligonucleotide-functionalized gold nanoparticles

An ultrasensitive and simple dynamic-light-scattering (DLS) assay for the sequence-specific recognition of double-stranded DNA (dsDNA) was developed based on detection of the average diameter change of Au nanoparticle (AuNP) probes modified with oligonucleotides 5'-TTTCTCTTCCTT- CTCTTC-(T)(12)-SH-3' (Oligo 1) and 5'-TTCTTTCTTTTCTTTTTC-(T)(12)- SH-3' (Oligo 2). The target dsDNA was composed of two complementary oligonucleotides: 5'-AAAGAGAAGGAAGAGAAGAAGAAAGAAAAGAAAAAG-3' (Oligo 3) and 3'-TTTCTCTTCCTTCTCTTCTTCTTTCTTTTCTTTTTC-5' (Oligo 4). Hybridization of the two AuNPs-Oligo probes with the target dsDNA induced aggregation of the target dsDNA by forming triplex DNA, which accordingly increased the average diameter. This diameter change could then be detected by DLS. The average diameter was proportional to the target dsDNA concentration over the range from 593 fM to 40 pM, with a detection limit of 593 fM. Moreover, the assay had good sequence specificity for the target dsDNA.     

Detection of terminal mismatches on DNA duplexes with fluorescent oligonucleotides

This paper describes the design of terminal-mismatch discriminating fluorescent oligonucleotides (TMDFOs). The method is based on the use of sets of oligo-2'-deoxyribonucleotide probes linked via their 5'-ends, and varying-sized flexible polymethylene chains, to thiazole orange, with the linker being attached to the benzothiazole moiety. The sequence of each set of labelled probes was identical and complementary to the sequence to be analyzed on the single-stranded nucleic acid target except at the interrogation position, located at the 5'-end of the probes in a position adjacent to the attachment site of the label, where each of the four nucleic bases were incorporated. This work allowed the selection of probes showing, upon their hybridization with the target sequence, good discrimination between the matched and the mismatched duplexes under non-stringent conditions, with the mismatched duplexes being more fluorescent than the perfectly matched ones.     

Synergistic effects of nano-ZnO/multi-walled carbon nanotubes/chitosan nanocomposite membrane for the sensitive detection of sequence-specific of PAT gene and PCR amplification of NOS gene

The remarkable synergistic effects of the zinc oxide (ZnO) nanoparticles and multi-walled carbon nanotubes (MWNTs) were developed for the ssDNA probe immobilization and fabrication of the electrochemical DNA biosensor. The ZnO/MWNTs/chitosan nanocomposite membrane-modified glassy carbon electrode (ZnO/MWNTs/CHIT/GCE) was fabricated and the ssDNA probes were immobilized on the modified electrode surface. The preparation method is quite simple and inexpensive. The hybridization events were monitored by differential pulse voltammetry (DPV) using methylene blue (MB) as an indicator. As compared with previous MWNTs-based DNA biosensors, this composite matrix combined the attractive biocompatibility of ZnO nanoparticles with the excellent electron-transfer ability of MWNTs and fine membrane-forming ability of CHIT increased the DNA attachment quantity and complementary DNA detection sensitivity. The approach described here can effectively discriminate complementary DNA sequence, noncomplementary sequence, single-base mismatched sequence and double-base mismatched sequence related to phosphinothricin acetyltransferase (PAT) gene in transgenic corn. Under optimal conditions, the dynamic detection range of the sensor to PAT gene complementary target sequence was from 1.0 × 10⁻¹¹ to 1.0 × 10⁻⁶ mol/L with the detection limit of 2.8 × 10⁻¹² mol/L. The polymerase chain reaction (PCR) amplification of nopaline synthase (NOS) gene from the real sample of one kind of transgenic soybeans was also satisfactorily detected with this electrochemical DNA biosensor, suggesting that the ZnO/MWNTs/CHIT nanocomposite hold great promises for sensitive electrochemical biosensor applications.     

Combining ligation reaction and capillary gel electrophoresis to obtain reliable long DNA probes

New DNA amplification methods are continuously developed for sensitive detection and quantification of specific DNA target sequences for, e.g. clinical, environmental or food applications. These new applications often require the use of long DNA oligonucleotides as probes for target sequences hybridization. Depending on the molecular technique, the length of DNA probes ranges from 40 to 450 nucleotides, solid-phase chemical synthesis being the strategy generally used for their production. However, the fidelity of chemical synthesis of DNA decreases for larger DNA probes. Defects in the oligonucleotide sequence result in the loss of hybridization efficiency, affecting the sensitivity and selectivity of the amplification method. In this work, an enzymatic procedure has been developed as an alternative to solid-phase chemical synthesis for the production of long oligonucleotides. The enzymatic procedure for probe production was based on ligation of short DNA sequences. Long DNA probes were obtained from smaller oligonucleotides together with a short sequence that acts as bridge stabilizing the molecular complex for DNA ligation. The ligation reactions were monitored by capillary gel electrophoresis with laser-induced fluorescence detection (CGE-LIF) using a bare fused-silica capillary. The capillary gel electrophoresis-LIF method demonstrated to be very useful and informative for the characterization of the ligation reaction, providing important information about the nature of some impurities, as well as for the fine optimization of the ligation conditions (i.e. ligation cycles, oligonucleotide and enzyme concentration). As a result, the yield and quality of the ligation product were highly improved. The in-lab prepared DNA probes were used in a novel multiplex ligation-dependent genome amplification (MLGA) method for the detection of genetically modified maize in samples. The great possibilities of the whole approach were demonstrated by the specific and sensitive detection of transgenic maize at percentages lower than 1%.