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.     

应用纳米金探针检测HSV-2的目视化基因芯片

本实验建立了一种应用金标链霉亲和素探针的目视化高灵敏度检测单纯疱疹病毒2型(HerpesSimplexVirus-2,HSV-2)的基因芯片。该芯片以HSV-2DNA聚合酶的高保守区为靶序列,设计HSV-2特异性引物和探针,通过PCR反应使扩增产物标记上生物素;氨基修饰的探针固定在活化的玻片上,与生物素标记的扩增产物杂交;利用生物素与链酶亲和素高亲合力的特性,加入纳米金标记的链酶亲和素后形成生物素-链酶亲和素-纳米金生物反应放大系统;银染反应后,达到目视化检测HSV-2效果。该HSV-2检测基因芯片能目视化检测出100fmol/L的HSV-2扩增产物,具有灵敏度高,低成本的特点,通过临床标本验证表明该芯片具有较高的准确性。     

Electronic microarray analysis of 16S rDNA amplicons for bacterial detection

Electronic microarray technology is a potential alternative in bacterial detection and identification. However, conditions for bacterial detection by electronic microarray need optimization. Using the NanoChip electronic microarray, we investigated eight marine bacterial species. Based on the 16S rDNA sequences of these species, we constructed primers, reporter probes, and species-specific capture probes. We carried out two separate analyses for longer (533 bp) and shorter (350 and 200 bp) amplified products (amplicons). To detect simultaneously the hybridization signals for the 350- and 200-bp amplicons, we designed a common reporter probe from an overlapping sequence within both fragments. We developed methods to optimize detection of hybridization signals for processing the DNA chips. A matrix analysis was performed for different bacterial species and complementary capture probes on electronic microarrays. Results showed that, when using the longer amplicon, not all bacterial targets hybridized with the complementary capture probes, which was characterized by the presence of false-positive signals. However, with the shorter amplicons, all bacterial species were correctly and completely detected using the constructed complementary capture probes.     

PCR amplification and simultaneous digoxigenin incorporation of long DNA probes for fluorescence in situ hybridization.

Nonradioactive in situ hybridization has found widespread applications in cytogenetics. Basic requirements are DNA probes in sufficient amounts and of high specificity as well as a labeling protocol of good reproducibility. The PCR has been of fundamental importance for the amplification of DNA sequences and thus for the production of DNA probes. Meanwhile, PCR protocols for amplification of DNA have reached a high degree of automation. So far, incorporation of labeled nucleotides into these DNA probes has normally been done by nick translation. Here we show that in using the PCR, amplification of a DNA probe larger than one kilobase accompanied by simultaneous incorporation of digoxigenin-11-dUTP can be performed for in situ hybridization experiments. As an example, the DNA probe pUC 1.77 specific for the subcentromeric region q12 of chromosome number 1 was used and hybridized against metaphase chromosomes from human lymphocytes. The labeled chromosome region was detected by anti-digoxigenin-fluorescein, Fab fragments. The experiments were evaluated by digital image analysis of microphotographs.     

乙型脑炎病毒可视化分型基因芯片的制备

目的:制备乙型脑炎病毒(JEV)可视化分型基因芯片。方法:根据JEV的基因组序列,应用生物学软件设计JEV分型引物及探针,制备其可视化分型基因芯片;用生物素标记的引物PCR扩增目的片段,并与固定于玻片上的探针杂交,加入链霉亲和素标记的纳米金,银增强实现可视化;进行特异性、灵敏性及重复性试验。结果:探针特异地与相应的标记目的基因片段杂交,并在芯片上呈现较强的阳性杂交信号;2号探针能特异性检出JEV,3、4号探针可分别对Ⅰ型和Ⅲ型JEV进行分型;芯片对JEV质粒检测的灵敏度达105拷贝/mL;以蓝耳病病毒等5种病毒为对照,芯片只对JEV响应,具有特异性;制备的基因芯片具有批间、批内重复性。结论:制备的基因芯片具有高特异性、灵敏性及重复性,可以快速、准确、高通量地对JEV进行可视化分型检测。     

High sensitivity detection of HPV-16 in SiHa and CaSki cells utilizing FISH enhanced by TSA

 Detection of integrated human papillomavirus type 16 (HPV-16) DNA in SiHa and CaSki cells was used as a model system to demonstrate sensitivity and resolution of a well defined target. Using 293- to 1987-base polymerase chain reaction (PCR)-synthesized probes to the E6 and E7 open reading frames of HPV-16, several fluorescent in situ hybridization (FISH) detection methods, enhanced with tyramide signal amplification (TSA), were compared. The synthetic probes were biotin labeled by a nick translation method and the hybridized probes were detected by various fluorescent TSA methods using cyanine 3 tyramide, biotinyl tyramide and a biotin TSA Plus reagent. High sensitivity detection in SiHa cells was demonstrated using a 619-base probe to detect two single copies of integrated HPV-16 DNA. In CaSki cells, which contain up to 600 copies of HPV-16 DNA, a 293-base probe was used for detection. The results of these comparisons show that with refinement of TSA methods and reagents, increasing levels of high sensitivity detection can be achieved and that these methods allow subnuclear localization as well. Accepted: 20 June 1997     

A novel biotinylated adenylate analogue derived from pyrazolo[3,4-d]pyrimidine for labeling DNA probes.

A novel dATP analogue, 3-[5-[(N-biotinyl-6- amiocaproyl)amino]pentyl]-1-(2-deoxy-beta-D-erythro-pentofuranosyl )-1H-pyrazolo[3,4-d]pyrimidin-4-amine 5'-triphosphate (9, bio-13-dAPPTP), which is modified at the 3-position with a flexible linker arm bearing a terminal biotin moiety, has been synthesized. This nucleotide is readily incorporated into DNA probes by nick translation. These probes hybridize to complementary targets as well as probes labeled with bio-dUTP, as judged by slot blot. When incorporated into oligonucleotides, they do not cause the loss of hybridization efficiency that an N-6-substituted adenine nucleotide does when incorporated into the same sites in the oligonucleotide.     

Nonradioactive detection of nucleic acid by the universal probe system

A convenient and nonradioactive method for DNA hybridization tests termed the "Universal probe system" has been developed. This method is based on the principle of sandwich hybridization. This system consists of two single-stranded DNA probes (a primary probe and a biotin-labeled secondary probe). The primary probe is prepared from a chimeric phage-plasmid vector containing the complementary sequence to a target gene. The secondary probe has a sequence complementary to the vector portion of the primary probe and is labeled with biotin via the transamination reaction. An advantage of this method is that the single-stranded primary probe can be prepared with ease by using the chimeric phage-plasmid vector system, thereby avoiding tedious labeling of individually different probes. As the primary probe is not modified with biotin and other labels, it conserves the sequence to be hybridized with a target. Accordingly, the primary probe containing a relatively short hybridizing region (ca. 50 bp) can efficiently hybridize with the target. In fact, the universal probe is sensitive enough to detect a single-copy human gene on Southern blots.     

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.     

PCR-free mutation detection of BRCA1 on a zip-code microarray using ligase chain reaction

We describe here ligation-based strategy to detect mutations in BRCA1 utilizing zip-code microarray technology. In our first approach, PCR was performed to amplify the genomic regions containing the mutation sites. The PCR products were then used as templates in a subsequent ligation reaction using two ligation primers that flanked the mutation site. The primary allele-specific primer is designed to contain a base of mutation site at its 3′ end with 5′ complementarity to the respective zip-code sequence while the secondary common primer is modified by biotin at its 3′ end. Depending on the genotype of samples at the mutation site, the nick between the two ligation primers can be sealed in the presence of DNA ligase. The ligation products were then hybridized on the zip-code microarray followed by staining with streptavidine-cy3 to generate a fluorescent signal. Using this strategy we successfully genotyped selected Korean-specific mutation sites in exon 11 of BRCA1 with a wild type and two heterozygote mutant samples. Furthermore, we also demonstrated that ligase chain reaction using unamplified genomic DNA as direct templates is enough to generate sufficient signals for correct genotypings in a multiplexed manner, verifying first that PCR is not essential for this microarray-based strategy.     

Comparison of different labeling methods for the production of labeled target DNA for microarray hybridization

Different labeling methods were studied to compare various approaches to the preparation of labeled target DNA for microarray experiments. The methods under investigation included a post-PCR labeling method using the Klenow fragment and a DecaLabel DNA labeling kit, the use of a Cy3-labeled forward primer in the PCR, generating either double-stranded or single-stranded PCR products, and the incorporation of Cy3-labeled dCTPs in the PCR. A microarray that had already been designed and used for the detection of microorganisms in compost was used in the study. PCR products from the organisms Burkholderia cepacia and Staphylococcus aureus were used in the comparison study, and the signals from the probes for these organisms analyzed. The highest signals were obtained when using the post-PCR labeling method, although with this method, more non-specific hybridizations were found. Single-stranded PCR products that had been labeled by the incorporation of a Cy3-labeled forward primer in the PCR were found to give the next highest signals upon hybridization for a majority of the tested probes, with less non-specific hybridizations. Hybridization with double-stranded PCR product labeled with a Cy3-labeled forward primer, or labeled by the incorporation of Cy3-labeled dCTPs resulted in acceptable signal to noise ratios for all probes except the UNIV 1389a and Burkholderia genus probes, both located toward the 3' end of the 16S rRNA gene. The comparison of the different DNA labeling methods revealed that labeling via the Cy3-forward primer approach is the most appropriate of the studied methods for the preparation of labeled target DNA for our purposes.     

Effects of target length on the hybridization efficiency and specificity of rRNA-based oligonucleotide microarrays

The effect of target size on microarray hybridization efficiencies and specificity was investigated using a set of 166 oligonucleotide probes targeting the 16S rRNA gene of Escherichia coli. The targets included unfragmented native rRNA, fragmented rRNA ( approximately 20 to 100 bp), PCR amplicons (93 to 1,480 bp), and three synthetic single-stranded DNA oligonucleotides (45 to 56 bp). Fluorescence intensities of probes hybridized with targets were categorized into classes I (81 to 100% relative to the control probe), II (61 to 80%), III (41 to 60%), IV (21 to 40%), V (6 to 20%), and VI (0 to 5%). Good hybridization efficiency was defined for those probes conferring intensities in classes I to IV; those in classes V and VI were regarded as weak and false-negative signals, respectively. Using unfragmented native rRNA, 13.9% of the probes had fluorescence intensities in classes I to IV, whereas the majority (57.8%) exhibited false-negative signals. Similar trends were observed for the 1,480-bp PCR amplicon (6.6% of the probes were in classes I to IV). In contrast, after hybridization of fragmented rRNA, the percentage of probes in classes I to IV rose to 83.1%. Likewise, when DNA target sizes were reduced from 1,480 bp to 45 bp, this percentage increased approximately 14-fold. Overall, microarray hybridization efficiencies and specificity were improved with fragmented rRNA (20 to 100 bp), short PCR amplicons (<150 bp), and synthetic targets (45 to 56 bp). Such an understanding is important to the application of DNA microarray technology in microbial community studies.     

Array-based nano-amplification technique was applied in detection of hepatitis E virus

A rapid method for the detection of Hepatitis E Virus (HEV) was developed by utilizing nano-gold labeled oligonucleotide probes, silver stain enhancement and the microarray technique. The 5'-end -NH(2) modified oligonucleotide probes were immobilized on the surface of the chip base as the capture probe. The detection probe was made of the 3'-end -SH modified oligonucleotide probe and nano-gold colloid. The optimal concentrations of these two probes were determined. To test the detection sensitivity and specificity of this technique, a conservative fragment of the virus RNA was amplified by the RT-PCR/PCR one step amplification. The cDNA was hybridized with the capture probes and the detection probes on microarray. The detection signal was amplified by silver stain enhancement and could be identified by naked eyes.100 fM of amplicon could be detected out on the microarray. As the results, preparation of nano-gold was improved and faster. Development time also was shortened to 2 min. Thus, considering high efficiency, low cost, good specificity and high sensitivity, this technique is alternative for the detection of HEV.     

Chromosomal in situ hybridization with double-labeled DNA: signal amplification at the probe level.

A double-labeling approach was applied to nonisotopic in situ hybridization with individual cosmid and plasmid clones, using digoxigenin or biotin as label and a combination of two separate enzymatic labeling methods. Probe labeling was achieved by nick translation, followed by tailing of the probe by terminal deoxynucleotidyl transferase. The double-labeling method, in conjunction with an improved detection protocol, provides for a higher signal intensity than that obtainable with single-labeled probes.     

两种DNA探针杂交检测结核分支杆菌方法的研究

为改进结核杆菌DNA探针的特异性与实用性,研制了以生物素标记的两种对结核分支杆菌特异的DNA探针:一个5’端标记的20bp的寡核苷酸探针和一个采用PCR方法合成的188bp长链探针。两种探针分别与结核分支杆菌的全染色体DNA,以及基因组上IS6110序列的一段317bp的PCR扩增产物进行斑点杂交,以碱性磷酸酶(AP)催化的染色反应检测,测试了两个探针的敏感性和特异性。系统地比较研究了两种探针杂交检测条件:探针的浓度选择,杂交温度与洗膜温度的选择,以及杂交与洗膜温度对检测的敏感性与特异性的影响。寡核苷酸探针和188bp探针杂交检测纯化结核分支杆菌基因组DNA的敏感性分别为100ng与6ng,杂交检测PCR产物的敏感性分别是400pg与50pg。两探针的最佳杂交浓度均为40～160ng/ml,最佳杂交温度分别是42℃与68℃,最佳洗膜温度分别是60℃与60～68℃之间。两种探针均仅与结核分支杆菌及BCG有杂交信号,而与其它受试分支杆菌及非分支杆菌杂交结果都呈阴性。它们的特异性都很强,但188bp探针的敏感性约是寡核苷酸探针的7～16倍,而且188bp探针检测本底较低,是检测结核分支杆菌的较佳选择     

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。     

Universal DNA array detection of small insertions and deletions in BRCA1 and BRCA2

Array-based mutation detection methodology typically relies on direct hybridization of the fluorescently labeled query sequence to surface-bound oligonucleotide probes. These probes contain either small sequence variations or perfect-match sequence. The intensity of fluorescence bound to each oligonucleotide probe is intended to reveal which sequence is perfectly complementary to the query sequence. However, these approaches have not always been successful, especially for detection of small frameshift mutations. Here we describe a multiplex assay to detect small insertions and deletions by using a modified PCR to evenly amplify each amplicon (PCR/PCR), followed by ligase detection reaction (LDR). Mutations were identified by screening reaction products with a universal DNA microarray, which uncouples mutation detection from array hybridization and provides for high sensitivity. Using the three BRCA1 and BRCA2 founder mutations in the Ashkenazi Jewish population (BRCA1 185delAG; BRCA1 5382insC; BRCA2 6174delT) as a model system, the assay readily detected these mutations in multiplexed reactions. Our results demonstrate that universal microarray analysis of PCR/PCR/LDR products permits rapid identification of small insertion and deletion mutations in the context of both clinical diagnosis and population studies.     

An oligonucleotide microarray for microRNA expression analysis based on labeling RNA with quantum dot and nanogold probe

MicroRNAs (miRNAs) play important regulatory roles in animals and plants by targeting mRNAs for cleavage or translational repression. They have diverse expression patterns and might regulate various developmental and physiological processes. Profiling miRNA expression is very helpful for studying biological functions of miRNAs. We report a novel miRNA profiling microarray, in which miRNAs were directly labeled at the 3′ terminus with biotin and hybridized with complementary oligo-DNA probes immobilized on glass slides, and subsequently detected by measuring fluorescence of quantum dots labeled with streptavidin bound to miRNAs through streptavidin–biotin interaction. The detection limit of this microarray for miRNA was ~0.4 fmol, and the detection dynamic range spanned about 2 orders of magnitude. We made a model microarray to profile 11 miRNAs from leaf and root of rice (Oryza sativa L. ssp. indica) seedlings. The analysis results of the miRNAs had a good reproducibility and were consistent with the northern blot result. To avoid using high-cost detection equipment, colorimetric detection, a method based on nanogold probe coupled with silver enhancement, was also successfully introduced into miRNA profiling microarray detection.     

Amplification of target-specific,ligation-dependent circular probe

We describe a novel polymerase chain reaction (PCR)-based gene amplification method utilizing a circularizable oligodeoxyribonucleotide probe (C-probe). The C-probe contains two target complementary regions located at each terminus and an interposed generic PCR primer binding region. The hybridization of C-probe to a target brings two termini in direct apposition as the complementary regions of C-probe wind around the target to form a double helix. Subsequent ligation of the two termini results in a covalently linked C-probe that becomes `locked on to' the target. The circular nature of the C-probe allows for the generation of a multimeric single-stranded DNA (ssDNA) via extension of the antisense primer by Taq DNA polymerase along the C-probe and displacement of downstream strand, analogous to `rolling circle' replication of bacteriophage in vivo. This multimeric ssDNA then serves as a template for multiple sense primers to hybridize, extend, and displace downstream DNA, generating a large ramified (branching) DNA complex. Subsequent thermocycling denatures the dsDNA and initiates the next round of primer extension and ramification. This model results in significantly improved amplification kinetics (super-exponential) as compared to conventional PCR. Our results show that the C-probe was 1000 times more sensitive than the corresponding linear hemiprobes for detecting Epstein–Barr virus early RNA. The C-probe not only increases the power of amplification but also offers a means for decontaminating carryover amplicons. As the ligated C-probes possess no free termini, they are resistant to exonuclease digestion, whereas contaminated linear amplicons are susceptible to digestion. Treatment of the ligation reaction mixture with exonuclease prior to amplification eliminated the amplicon contaminant, which could also have been co-amplified with the same PCR primers; only the ligated C-probes were amplified. The combined advantages of the C-probe and thermocycling have a broad applicability for the detection of both DNA and RNA. Finally, we described a novel isothermal amplification method, ramification extension amplification, utilizing circular nature of C-probe and displacement activity of DNA polymerase.