Maskless fabrication of light-directed oligonucleotide microarrays using a digital micromirror array.

Oligonucleotide microarrays, also called "DNA chips," are currently made by a light-directed chemistry that requires a large number of photolithographic masks for each chip. Here we describe a maskless array synthesizer (MAS) that replaces the chrome masks with virtual masks generated on a computer, which are relayed to a digital micromirror array. A 1:1 reflective imaging system forms an ultraviolet image of the virtual mask on the active surface of the glass substrate, which is mounted in a flow cell reaction chamber connected to a DNA synthesizer. Programmed chemical coupling cycles follow light exposure, and these steps are repeated with different virtual masks to grow desired oligonucleotides in a selected pattern. This instrument has been used to synthesize oligonucleotide microarrays containing more than 76,000 features measuring 16 microm 2. The oligonucleotides were synthesized at high repetitive yield and, after hybridization, could readily discriminate single-base pair mismatches. The MAS is adaptable to the fabrication of DNA chips containing probes for thousands of genes, as well as any other solid-phase combinatorial chemistry to be performed in high-density microarrays.     

Using a microfluidic device for 1 microl DNA microarray hybridization in 500 s

This work describes a novel and simple modification of the current microarray format. It reduces the sample/reagent volume to 1 microl and the hybridization time to 500 s. Both 20mer and 80mer oligonucleotide probes and singly labeled 20mer and 80mer targets, representative of the T-cell acute lymphocytic leukemia 1 (TAL1) gene, have been used to elucidate the performance of this hybridization approach. In this format, called shuttle hybridization, a conventional flat glass DNA microarray is integrated with a PMMA microfluidic chip to reduce the sample and reagent consumption to 1/100 of that associated with the conventional format. A serpentine microtrench is designed and fabricated on a PMMA chip using a widely available CO2 laser scriber. The trench spacing is compatible with the inter-spot distance in standard microarrays. The microtrench chip and microarray chip are easily aligned and assembled manually so that the microarray is integrated with a microfluidic channel. Discrete sample plugs are employed in the microchannel for hybridization. Flowing through the microchannel with alternating depths and widths scrambles continuous sample plug into discrete short plugs. These plugs are shuttled back and forth along the channel, sweeping over microarray probes while re-circulation mixing occurs inside the plugs. Integrating the microarrays into the microfluidic channel reduces the DNA-DNA hybridization time from 18 h to 500 s. Additionally, the enhancement of DNA hybridization reaction by the microfluidic device is investigated by determining the coefficient of variation (CV), the growth rate of the hybridization signal and the ability to discriminate single-base mismatch. Detection limit of 19 amol was obtained for shuttle hybridization. A 1 mul target was used to hybridize with an array that can hold 5000 probes.     

Using a microfluidic device for 1 μl DNA microarray hybridization in 500 s

This work describes a novel and simple modification of the current microarray format. It reduces the sample/reagent volume to 1 μl and the hybridization time to 500 s. Both 20mer and 80mer oligonucleotide probes and singly labeled 20mer and 80mer targets, representative of the T-cell acute lymphocytic leukemia 1 (TAL1) gene, have been used to elucidate the performance of this hybridization approach. In this format, called shuttle hybridization, a conventional flat glass DNA microarray is integrated with a PMMA microfluidic chip to reduce the sample and reagent consumption to 1/100 of that associated with the conventional format. A serpentine microtrench is designed and fabricated on a PMMA chip using a widely available CO₂ laser scriber. The trench spacing is compatible with the inter-spot distance in standard microarrays. The microtrench chip and microarray chip are easily aligned and assembled manually so that the microarray is integrated with a microfluidic channel. Discrete sample plugs are employed in the microchannel for hybridization. Flowing through the microchannel with alternating depths and widths scrambles continuous sample plug into discrete short plugs. These plugs are shuttled back and forth along the channel, sweeping over microarray probes while re-circulation mixing occurs inside the plugs. Integrating the microarrays into the microfluidic channel reduces the DNA–DNA hybridization time from 18 h to 500 s. Additionally, the enhancement of DNA hybridization reaction by the microfluidic device is investigated by determining the coefficient of variation (CV), the growth rate of the hybridization signal and the ability to discriminate single-base mismatch. Detection limit of 19 amol was obtained for shuttle hybridization. A 1 μl target was used to hybridize with an array that can hold 5000 probes.     

DNA hybridization in nanostructural molecular assemblies enables detection of gene mutations without a fluorescent probe

We have developed a simple single nucleotide polymorphisms (SNPs) analysis utilizing DNA hybridization in nanostructural molecular assemblies. The novel technique enables the detection of a single-base mismatch in a DNA sequence without a fluorescent probe. This report describes for the first time that DNA hybridization occurs in the nanostructural molecular assemblies (termed reverse micelles) formed in an organic medium. The restricted nanospace in the reverse micelles amplifies the differences in the hybridization rate between mismatched and perfectly matched DNA probes. For a model system, we hybridized a 20-mer based on the p53 gene sequence to 20-mer complementary oligonucleotides with various types of mismatches. Without any DNA labeling or electrochemical apparatus, we successfully detected the various oligonucleotide mismatches by simply measuring the UV absorbance at 260 nm.     

DNA point mutation detection based on DNA ligase reaction and nano-Au amplification: a piezoelectric approach

A novel piezoelectric method for DNA point mutation detection based on DNA ligase reaction and nano-Au-amplified DNA probes is proposed. A capture probe was designed with the potential point mutation site located at the 3' end and a thiol group at the 5' end to be immobilized on the gold electrode surface of quartz crystal microbalance (QCM). Successive hybridization with the target DNA and detection probe of nano-Au-labeled DNA forms a double-strand DNA (dsDNA). After the DNA ligase reaction and denaturing at an elevated temperature, the QCM frequency would revert to the original value for the target with single-base mismatch, whereas a reduced frequency response would be obtained for the case of the perfect match target. In this way, the purpose of point mutation discrimination could be achieved. The current approach is demonstrated with the identification of a single-base mutation in artificial codon CD17 of the beta-thalassemia gene, and the wild type and mutant type were discriminated successfully. The scanning electron microscope (SEM) image showing that plenty of gold nanoparticles remained on the electrode surface demonstrated that the nano-Au label served as an efficient signal amplification agent in QCM assay. A detection limit of 2.6 x 10(-9)mol/L of oligonucleotides was achieved. Owing to its ease of operation and low detection limit, it is expected that the proposed procedure may hold great promise in both research-based and clinical genomic assays.     

A gene-specific DNA sequencing chip for exploring molecular evolutionary change

Sequencing by hybridization (SBH) approaches to DNA sequencing face two conflicting constraints. First, in order to ensure that the target DNA binds reliably, the oligonucleotide probes that are attached to the chip array must be >15 bp in length. Secondly, the total number of possible 15 bp oligonucleotides is too large (>4¹⁵) to fit on a chip with current technology. To circumvent the conflict between these two opposing constraints, we present a novel gene-specific DNA chip design. Our design is based on the idea that not all conceivable oligonucleotides need to be placed on a chip— only those that capture sequence combinations occurring in nature. Our approach uses a training set of aligned sequences that code for the gene in question. We compute the minimum number of oligonucleotides (generally 15–30 bp in length) that need to be placed on a DNA chip to capture the variation implied by the training set using a graph search algorithm. We tested the approach in silico using cytochrome-b sequences. Results indicate that on average, 98% of the sequence of an unknown target can be determined using the approach.     

Hybridization of DNA with oligonucleotides immobilized in a gel: a convenient method for recording single base replacements

In an attempt to develop a reliable system for DNA sequence analysis with multiple hybridization probes, oligonucleotides down to 8 bases long were covalently immobilized in a thin layer of polyacrylamide gel fixed on a glass plate. It was shown possible to detect single base changes in DNA by hybridization of the immobilized oligonucleotides with radioactively and fluorescently labeled DNA fragments. Moreover, it was found that dissociation temperatures of differently GC-rich duplexes could be equalized by appropriate choice of immobilized oligonucleotides concentrations. A model accounting for this phenomenon is presented. In order to make the system more compact, a rectangular matrix of 200 mm dots of immobilized oligonucleotides ("hybridization chip") was designed which offered the sensitivity of 20 attomoles per dot for fluorescent DNA fragment. The applications and perspectives of the approach are discussed.     

Accuracy of genotyping for single nucleotide polymorphisms by a microarray-based single nucleotide polymorphism typing method involving hybridization of short allele-specific oligonucleotides.

Advances in technologies for identifying genetic polymorphisms rapidly and accurately will dramatically accelerate the discovery of disease-related genes. Among a variety of newly described methods for rapid typing of single-nucleotide polymorphisms (SNPs), gene detection using DNA microarrays is gradually achieving widespread use. This method involves the use of short (11- to 13-mer) allele-specific oligonucleotides. This method allows simultaneous analysis of many SNPs in DNAs from a large number of individuals, in a single experiment. In this work, we evaluated the accuracy of a new microarray-based short allele-specific oligonucleotide (ASO) hybridization method. There is a 96-well formatted array on a single plate, in which up to 256 spots are included in each well. Fluorescent probes for our experiments were produced by multiplex PCR amplification often target SNP-containing regions. We genotyped 192 individuals across a panel of ten single base variations, which included an insertion/deletion polymorphism. For comparison, we genotyped the same individuals for the same SNPs by the method of single-base extension with fluorescence detection. The typing accuracies of the microarray-based PCR-ASO and single-base extension methods were calculated as 99.9% and 99.1%, respectively, on the basis of genotyping results determined by direct sequencing. We conclude that the microarray-based hybridization method using short ASO probes represents a potential breakthrough technology for typing large numbers of SNPs rapidly and efficiently.     

质粒pCAMBIA1301的检测

用引物延伸芯片法实现对转基因水稻中 生物芯片技术是生物技术和微制造技术的融合, 已广泛用于生命科学的研究及实践、医学科研及临床、药物设计、环境保护、农业、军事等各个领域。而基因芯片是生物芯片中的一种,是指将大量基因探针分子固定于支持物上,然后与标记的样品进行杂交,所以一次可对大量核酸分子进行检测分析,从而解决了传统核酸印迹杂交技术操作复杂、自动化程度低、检测目的分子数量少、效率低等不足。文章探讨了用基因芯片这一新的检测手段对转基因植物的初步检测,采用一种新的反应机制－引物延伸芯片法（arrayed primer extension）,实现了样品扩增和杂交的一步化,而在传统的基因芯片检测中要需要两步来完成,从而为目前基因芯片中大片段样品的检测提供了一种可能性。 Abstract: Biochip technology which had emerged from the fusion of biotechnology and micro/nanofabrication technology at the end of 1980s has been widely used in life science ,medicine,clinical diagnosis,durg design,agricμLture,envioment pretection and strategics. DNA microarray (also call gene chip,DNA chip),one kind of biochips,is small chip containing many oligonucleotide probe .It can hybridize with labelled sample which makes it possible to detect large numbers of oligonucleotides at one time.So DNA microarray can overcome the disadvantage of traditional hybridization technology such as complexity,low automatization,poor efficiency and amount of detcting molecμLes. This paper describes a new method to detect transgenic plant with gene chip.We have developed a novel arrayed-primer extension technique. It combines hybridization and PCR at one step, while two separate steps are needed in the ordinary DNA microarray, therefore our method provide a feasibility to detect long DNA fragment .     

Electric chips for rapid detection and quantification of nucleic acids

A silicon chip-based electric detector coupled to bead-based sandwich hybridization (BBSH) is presented as an approach to perform rapid analysis of specific nucleic acids. A microfluidic platform incorporating paramagnetic beads with immobilized capture probes is used for the bio-recognition steps. The protocol involves simultaneous sandwich hybridization of a single-stranded nucleic acid target with the capture probe on the beads and with a detection probe in the reaction solution, followed by enzyme labeling of the detection probe, enzymatic reaction, and finally, potentiometric measurement of the enzyme product at the chip surface. Anti-DIG-alkaline phosphatase conjugate was used for the enzyme labeling of the DIG-labeled detection probe. p-Aminophenol phosphate (pAPP) was used as a substrate. The enzyme reaction product, p-aminophenol (pAP), is oxidized at the anode of the chip to quinoneimine that is reduced back to pAP at the cathode. The cycling oxidation and reduction of these compounds result in a current producing a characteristic signal that can be related to the concentration of the analyte. The performance of the different steps in the assay was characterized using in vitro synthesized RNA oligonucleotides and then the instrument was used for analysis of 16S rRNA in Escherichia coli extract. The assay time depends on the sensitivity required. Artificial RNA target and 16S rRNA, in amounts ranging from 10(11) to 10(10) molecules, were assayed within 25 min and 4 h, respectively.     

Microarrays for bacterial detection and microbial community analysis

Several types of microarrays have recently been developed and evaluated for bacterial detection and microbial community analysis. These studies demonstrated that specific, sensitive and quantitative detection could be obtained with both functional gene arrays and community genome arrays. Although single-base mismatch can be differentiated with phylogenetic oligonucleotide arrays, reliable specific detection at the single-base level is still problematic. Microarray-based hybridization approaches are also useful for defining genome diversity and bacterial relatedness. However, more rigorous and systematic assessment and development are needed to realize the full potential of microarrays for microbial detection and community analysis.     

凝胶基片的制备与应用研究

在Bind-Silane^R处理的玻片上交联聚丙烯酰胺凝胶层(15mm×15mm×20μm),戊二醛活化。与末端氨基修饰的寡核苷酸片段共价结合制成芯片。这种芯片能够区分液相中序列不同的Cy3标记的目标核酸。与平面基片相比,凝胶基片具有背景低、固定探针量高、杂交时间短的优点。将细胞因子IL-4、IL-5、IL-6、IL-7、ANG、I-309和VEGF的单克隆抗体加样于凝胶基片上制成蛋白质芯片,对乳腺癌患者和正常人的血清进行检测,发现乳腺癌患者细胞因子IL-4、IL-5、I-309和VEGF的表达量高于正常人的表达量,对临床诊断具有重要的参考意义。     

Simple detection of point mutations in DNA oligonucleotides using SYBR Green I

A novel and simple method for detection of mutations in DNA oligonucleotides using a double-stranded DNA specific dye (SYBR Green I) is reported. The SYBR Green I is bound specifically with a duplex DNA oligonucleotide (intercalation). This intercalation induces fluorescent emission at 525 nm with excitation at 494 nm. The fluorescence intensity of mismatched oligonucleotides (40-mer) decreases (by more than 13%) in comparison with the perfectly matched oligonucleotides. Moreover, fluorescence measurement of the SYBR Green I can distinguish various types of single-base mismatches, except for the T-G terminal mismatch. The addition of 20% (v/v) formamide, however, to an oligonucleotide solution improved the sensitivity of detection and also enabled the detection of the T-G terminal-mismatch. This detection method requires only a normal fluorescence spectrophotometer, an inexpensive dye and just 50 pmol of sample DNA.     

A laminated, flex structure for electronic transport and hybridization of DNA

We have developed the first prototypes of a three-dimensional, electrophoretically driven microlaboratory for the analysis of proteins and DNA. By selecting the appropriate spacing and geometrical configuration, oligonucleotides were transported, in a controlled, rapid fashion, by electrophoresis in free-space. Transport efficiencies over 2 mm distances exceeded 70%. Electrodes of similar design were combined with an electronically addressed DNA hybridization chip to form a fully electrophoretic microlaboratory. In this instance, gold-plated copper electrodes were patterned on a 2 mil thick polyimide substrate. This polyimide layer was stiffened with 20 mil of polyimide to provide support for flip-chip bonding of our standard 100-site Nanochip. This composite structure illustrated three-dimensional transport of target oligonucleotides, through a via in the polyimide, along a series of electrodes and onto the diagnostic chip. Upon reaching the diagnostic chip, electronic hybridization was performed for a competitive reverse dot blot assay. The electronic assay showed a specific to nonspecific ratio in excess of 20:1. These results suggested that this type of structure might be of practical consequence with the development of a microlaboratory for biowarfare applications.     

A CMOS label-free DNA sensor using electrostatic induction of molecular charges

This paper reports a label-free biosensor for the detection of DNA hybridization. The proposed biosensor measures the surface potential on oligonucleotide modified electrodes using a direct charge accumulation method. The sensor directly and repeatedly measures the charges induced in the working electrode, which correspond to intrinsic negative charges in immobilized molecules. The sensor achieves an improved signal-to-noise ratio (SNR), through the oversampling effect of accumulation for charges and the differential architecture. The sensor also shows stable, robust, and reproducible measurement independent of slight changes in the reference voltage, unlike previous ion-sensitive field effect transistors (ISFETs), providing the benefits of choosing a wide variety of reference electrode materials. The proposed device is integrated with working electrodes, a reference electrode and readout circuits into one package via a 0.35 μm complementary metal-oxide-semiconductor (CMOS) process. The sensor achieves a detectable range of 88.3 dB and a detection limit of 36 μV for surface potential. It is demonstrated that the sensor successfully achieves specific detection of oligonucleotide sequences derived from the H5N1 avian influenza virus. The experiments show a limit of detection of 100 pM and include a single-base mismatch test in 18-mer oligonucleotides.     

Detection of Single-Base Substitutions in Amplified Fragments via Ligation of a Tandem of Short Oligonucleotides in Solution and on a Solid Carrier

Ligation of a tandem of short oligonucleotides was proposed for detecting single-base substitutions in amplified DNA fragments. An octamer–tetramer–octamer tandem was ligated on a 20-mer template with T4 DNA ligase. As shown with radiolabeled oligonucleotides, the efficiency and selectivity of ligation did not change with an octamer linked to a water-soluble carrier based on polyethylene glycol (MPEG), while ligation was somewhat lower with the octamer immobilized on methacrylate beads (DMEG). In both cases, polymer attachment improved the discrimination of 20-mer templates with single-base substitutions in the binding site for the tetramer or for the immobilized octamer. Tandems with a radiolabeled or biotinylated component were also efficiently ligated on amplified DNA fragments. The data obtained with DNA fragments of HIV-1 strains bru and rf demonstrate the possibility of reliable detection of single-base substitutions via ligation of a tandem and colorimetric detection of the immobilized ligation product with the streptavidin–alkaline phosphatase technique.     

Array-based mutation detection of BRCA1 using direct probe/target hybridization

We describe here an efficient microarray-based multiplex assay to detect Korean-specific mutations in breast cancer susceptibility gene BRCA1 using direct probe/target hybridization. Allele-specific oligonucleotides were covalently immobilized on an aldehyde-activated glass slide to prepare an oligonucleotide chip. From a wild-type sample, a two-step method was used to generate labeled multiplex polymerase chain reaction (PCR) amplification products of genomic regions containing the mutation sites. Amino allyl-dUTP, an amine-modified nucleotide, was incorporated during multiplex PCR amplifications and a monofunctional form of cyanine 3 dye was subsequently attached to the reactive amine group of the PCR products. Hybridization of the labeled PCR products to the oligonucleotide chip successfully identified all of the genotypes for the selected mutation sites. This work demonstrates that oligonucleotides chip-based analysis is a good candidate for efficient clinical testing for BRCA1 mutations when combined with the indirect strategy to prepare labeled target samples.     

Cartridge-based high-throughput purification of oligonucleotides for reliable oligonucleotide arrays

A novel, cartridge-based procedure for the efficient and irreversible detritylation of oligonucleotides is reported. This method, combined with a process for the elimination of depurinated fragments produces, in a highly parallel fashion, oligonucleotides with better purity than those traditionally obtained using reversed-phase high-performance liquid chromotography purification. Our combined detritylation and purification methodology compares favorably with commercial cartridge-based purification systems. The benefits of working with pure oligonucleotides, with regard to higher signal and better signal linearity, are shown in array-based hybridization experiments.     

Digestion of restriction enzyme for the detection of single-base mismatch in DNA

DNA hybridization and enzymatic digestion for the detection of mutation was investigated on the gold nanoparticles-calf thymus DNA (AuNPs-ctDNA) modified glassy carbon electrode (GCE). The thiol modified probe oligonucleotides (SH-ssDNA) were assembled on the surface of AuNPs-ctDNA modified GCE. The electrochemical response of the electrode was measured by differential pulse voltammetry and cyclic voltammetry. Methylene blue (MB) was used as the electroactive indicator. AuNPs were then dispersed effectively on the GCE surface in the presence of ct-DNA. When hybridization occurred, a decrease in the signal of MB current was observed. The modified electrode was used for the detection of mutations during the enzymatic digestion reaction in DNA. During this reaction, an increase in the signal of MB current was observed. So, the modified SH-ssDNA had a higher electrochemical response on the AuNPs-ctDNA/GCE because of the strong affinity of MB for guanine residues in it. The electrochemical detection of restriction enzyme digestion can provide a simple and practical method for observing single-base mismatches that can help in distinguishing mismatch sequences of DNA from the complementary ones.