Rewritable remote encoding and decoding of miniature multi-bit magnetic tags for high-throughput biological analysis

We have investigated a new magnetic labelling technology for high-throughput biomolecular identification and DNA sequencing. Planar multi-bit magnetic tags comprising a magnetic barcode formed by an ensemble of micron-sized thin film ferromagnetic Co bars and a 15 x 15 micron Au square for immobilization of probe molecules have been designed and fabricated. We show that by using a globally applied magnetic field and magneto-optical Kerr microscopy the magnetic elements in the multi-bit magnetic tags can be addressed individually and encoded/decoded remotely. The power of the approach is the read/write technique, which allows modest globally applied magnetic fields to write almost unlimited numbers of codes to populations of tags rather than individuals. The magnetic nature of the technology also lends itself naturally to fast, remote decoding and the ability to rewrite tags if needed. We demonstrate the critical steps needed to show the feasibility of this technology, including fabrication, remote writing and reading, and successful functionalization of the tags as verified by fluorescence detection. This approach is ideal for encoding information on tags in microfluidic flow or suspension, in order to label oligonucleotides during split-and-mix synthesis, and for combinatorial library-based high-throughput multiplexed bioassays.     

High-throughput biopolymer desalting by solid-phase extraction prior to mass spectrometric analysis.

In the last 10 years mass spectrometry (MS) has become an important method for analysis of peptides, proteins and DNA. It was recently utilized for accurate high-throughput protein identification, sequencing and DNA genotyping. The presence of non-volatile buffers compromises sensitivity and accuracy of MS biopolymer analysis; it is essential to remove sample contaminants prior to analysis. We have developed a fast and efficient method for desalting of DNA oligonucleotides and peptides using 96-well solid-phase extraction plates packed with 5 mg of Waters Oasis HLB sorbent (Waters, Milford, MA, USA). This reversed-phase sorbent retains the biopolymer analytes, while non-retained inorganic ions are washed out with pure deionized water. DNA oligonucleotides or peptides are eluted using a small amount (20-100 microl) of acetonitrile-water (70:30, v/v) solution. The SPE desalting performance meets the requirements for MS applications such as protein digest analysis and DNA genotyping.     

Tabu search algorithm for DNA sequencing by hybridization with isothermic libraries

In this paper, a problem of isothermic DNA sequencing by hybridization (SBH) is considered. In isothermic SBH a new type of oligonucleotide libraries is used. The library consists of oligonucleotides of different lengths depending on an oligonucleotide content. It is assumed that every oligonucleotide in such a library has an equal melting temperature. Each nucleotide adds its increment to the oligonucleotide temperature and it is assumed that A and T add 2 degrees C and C and G add 4 degrees C. The hybridization experiment using isothermic libraries should provide data with a lower number of errors due to an expected similarity of melting temperatures. From the computational point of view the problem of isothermic DNA sequencing with errors is hard, similarly like its classical counterpart. Hence, there is a need for developing heuristic algorithms that construct good suboptimal solutions. The aim of the paper is to propose a heuristic algorithm based on tabu search approach. The algorithm solves the problem with both positive and negative errors. Results of an extensive computational experiment are presented, which prove the high quality of the proposed method.     

Massively parallel display of genomic DNA fragments by rolling-circle amplification and strand displacement amplification on chip

Massively parallel genomic DNA fragments display on chip plays a key role in the new generation DNA sequencing. Here, we developed a new technology to display the parallel genomic DNA fragment massively based on two-step reaction with Ф29 DNA polymerase. The genomic DNA fragments were firstly amplified by rolling-circle amplification (RCA) reaction in liquid phase, and then amplified further on the chip by the strand displacement of Ф29 DNA polymerase. In our experiments, through DNA colonies produced by two-step amplification reaction T7 genomic DNA fragments are displayed massively and parallely on the chip, which has been verified through hybridizing the probe labeled with fluorescence or extension reaction with fluorescent-dNTP. The significant difference of fluourescence signals between background and displayed DNA fragments could be obtained. Our results show that the method has good reproducibility in experiments, which may be hopeful to serve the high-throughput sequencing.     

Recent developments in DNA sequencing by capillary and microdevice electrophoresis

The present review covers papers published in the years 1997 and 1998 on DNA sequencing by capillary and microdevice electrophoresis. The article does not include other electrophoretic DNA applications such as analysis of oligonucleotides, genotyping, and mutational analysis. Capillary gel electrophoresis (CGE) is starting to become a viable competitor to slab gel electrophoresis for DNA sequencing. Commercially available multicapillary array sequencers are now entering sequencing facilities which to date have totally relied on traditional slab gel technology. CGE research on DNA sequencing therefore becomes increasingly concerned with the critical task of fine-tuning the operational parameters to create robust sequencing systems. Electrophoretic microdevices are being considered the next technological step in DNA sequencing by electrophoresis.     

Tandem mass spectrometric sequence characterization of synthetic thymidine-rich oligonucleotides

Tandem mass spectrometry (MS/MS) can provide direct and accurate sequence characterization of synthetic oligonucleotide drugs, including modified oligonucleotides. Multiple factors can affect oligonucleotide MS/MS sequencing, including the intrinsic properties of oligonucleotides (i.e., nucleotide composition and structural modifications) and instrument parameters associated with the ion activation for fragmentation. In this study, MS/MS sequencing of a thymidine (T)-rich and phosphorothioate (PS)-modified DNA oligonucleotide was investigated using two fragmentation techniques: trap-type collision-induced dissociation (“CID”) and beam-type CID also termed as higher-energy collisional dissociation (“HCD”), preceded by a hydrophilic interaction liquid chromatography (HILIC) separation. A low to moderate charge state (−4), which predominated under the optimized HILIC-MS conditions, was selected as the precursor ion for MS/MS analysis. Comparison of the two distinctive ion activation mechanisms on the same precursor demonstrated that HCD was superior to CID in promoting higher sequence coverage and analytical sensitivity in sequence elucidation of T-rich DNA oligonucleotides. Specifically, HCD provided more sequence-defining fragments with higher fragment intensities than CID. Furthermore, the direct comparison between unmodified and PS-modified DNA oligonucleotides demonstrated a loss of MS/MS fragmentation efficiency by PS modification in both CID and HCD approaches, and a resultant reduction in sequence coverage. The deficiency in PS DNA sequence coverage observed with single collision energy HCD, however, was partially recovered by applying HCD with multiple collision energies. Collectively, this work demonstrated that HCD is advantageous to MS/MS sequencing of T-rich PS-modified DNA oligonucleotides.     

DNA sequencing

Determination of the sequence of DNA is one of the most important aspects of modern molecular biology. New sequencing methods currently being developed enable DNA sequence to be determined increasingly faster and more efficiently. One of the major advances in sequencing technology is the development of automated DNA sequencers. These utilize fluorescent rather than radioactive labels. A laser beam excites the fluorescent dyes, the emitted fluorescence is collected by detectors, and the information analyzed by computer. Robotic work stations are being developed to perform template preparation and purification, and the sequencing reactions themselves. Research is currently in progress to develop the technology of mass spectrometry for DNA sequencing. Success in this endeavor would mean that the gel electrophoresis step in DNA sequencing could be eliminated. A major innovation has been the application of polymerase chain reaction (PCR) technology to DNA sequence determination, which has led to the development of linear amplification sequencing (cycle sequencing). This very powerful yet technically simple method of sequencing has many advantages over conventional techniques, and may be used in manual or automated methods. Other recent innovations proposed recently to increase speed and efficiency include multiplex sequencing. This consists of pooling a number of samples and processing them as pools. After electrophoresis, the DNA is transferred to a membrane, and sequence images of the individual samples are obtained by sequential hybridizations with specific labeled oligonucleotides. Multiplex DNA sequencing has been used in conjunction with direct blotting electrophoresis to facilitate transfer of the DNA to a membrane. Chemiluminescent detection can also be used in conjunction with multiplex DNA sequencing to visualize the image on the membrane.     

DNA sequencing and genotyping in miniaturized electrophoresis systems

Advances in microchannel electrophoretic separation systems for DNA analyses have had important impacts on biological and biomedical sciences, as exemplified by the successes of the Human Genome Project (HGP). As we enter a new era in genomic science, further technological innovations promise to provide other far-reaching benefits, many of which will require continual increases in sequencing and genotyping efficiency and throughput, as well as major decreases in the cost per analysis. Since the high-resolution size- and/or conformation-based electrophoretic separation of DNA is the most critical step in many genetic analyses, continual advances in the development of materials and methods for microchannel electrophoretic separations will be needed to meet the massive demand for high-quality, low-cost genomic data. In particular, the development (and commercialization) of miniaturized genotyping platforms is needed to support and enable the future breakthroughs of biomedical science. In this review, we briefly discuss the major sequencing and genotyping techniques in which high-throughput and high-resolution electrophoretic separations of DNA play a significant role. We review recent advances in the development of technology for capillary electrophoresis (CE), including capillary array electrophoresis (CAE) systems. Most of these CE/CAE innovations are equally applicable to implementation on microfabricated electrophoresis chips. Major effort is devoted to discussing various key elements needed for the development of integrated and practical microfluidic sequencing and genotyping platforms, including chip substrate selection, microchannel design and fabrication, microchannel surface modification, sample preparation, analyte detection, DNA sieving matrices, and device integration. Finally, we identify some of the remaining challenges, and some of the possible routes to further advances in high-throughput DNA sequencing and genotyping technologies.     

Strength in Numbers: Development of a Fluorescence Sensor Array for Secondary Structures of DNA

The high-throughput assessment of the secondary structures adopted by DNA oligonucleotides is currently hampered by the lack of suitable biophysical methods. Fluorescent sensors hold great potential in this respect; however, the moderate selectivity that they display for one DNA conformation over the others constitutes a major drawback to the development of accurate assays. Moreover, the use of single sensors impedes a comprehensive classification of the tested sequences. Herein, we propose to overcome these limitations through the development of a fluorescence sensor array constituted by easily accessible, commercial dyes. Multivariate analysis of the emission data matrix produced by the array allows the conformational preferences of DNA sequences of interest to be explored, either by calculating the probability of group membership in the six predefined structural categories (three G-quadruplex groups, double-stranded, and two groups of single-stranded forms) or by revealing their particular structural features. The assay enables rapid screening of synthetic DNA oligonucleotides in a 96-well plate format.     

High-throughput DNA analysis by microchip electrophoresis

DNA analysis plays a great role in genetic and medical research, and clinical diagnosis of inherited diseases and particular cancers. Development of new methods for high throughput DNA analysis is necessitated with incoming of post human genome era. A new powerful analytical technology, called microchip capillary electrophoresis (MCE), can be integrated with some experimental units and is characterized by high-speed, small sample and reagent requirements and high-throughput. This new technology, which has been applied successfully to the separation of DNA fragments, analysis of polymerase chain reaction (PCR) products, DNA sequencing, and mutation detection, for example, will become an attractive alternative to conventional methods such as slab gel electrophoresis, Southern blotting and Northern blotting for DNA analysis. This review is focused on some basic issues about DNA analysis by MCE, such as fabrication methods for microchips, detection system and separation schemes, and several key applications are summarized.     

Small-molecule discovery from DNA-encoded chemical libraries

Researchers seeking to improve the efficiency and cost effectiveness of the bioactive small-molecule discovery process have recently embraced selection-based approaches, which in principle offer much higher throughput and simpler infrastructure requirements compared with traditional small-molecule screening methods. Since selection methods benefit greatly from an information-encoding molecule that can be readily amplified and decoded, several academic and industrial groups have turned to DNA as the basis for library encoding and, in some cases, library synthesis. The resulting DNA-encoded synthetic small-molecule libraries, integrated with the high sensitivity of PCR and the recent development of ultra high-throughput DNA sequencing technology, can be evaluated very rapidly for binding or bond formation with a target of interest while consuming minimal quantities of material and requiring only modest investments of time and equipment. In this tutorial review we describe the development of two classes of approaches for encoding chemical structures and reactivity with DNA: DNA-recorded library synthesis, in which encoding and library synthesis take place separately, and DNA-directed library synthesis, in which DNA both encodes and templates library synthesis. We also describe in vitro selection methods used to evaluate DNA-encoded libraries and summarize successful applications of these approaches to the discovery of bioactive small molecules and novel chemical reactivity.     

Using DNA sequencing electrophoresis compression artifacts as reporters of stable mRNA structures affecting gene expression

The formation of secondary structure in oligonucleotide DNA is known to lead to "compression" artifacts in electropherograms produced through DNA sequencing. Separately, the formation of secondary structure in mRNA is known to suppress translation; in particular, when such structures form in a region covered by the ribosome either during, or shortly after, initiation of translation. Here, we demonstrate how a DNA sequencing compression artifact provides important clues to the location(s) of translation-suppressing secondary structural elements in mRNA. Our study involves an engineered version of a gene sourced from Rhodothermus marinus encoding an enzyme called Cel12A. We introduced this gene into Escherichia coli with the intention of overexpressing it, but found that it expressed extremely poorly. Intriguingly, the gene displayed a remarkable compression artifact during DNA sequencing electrophoresis. Selected "designer" silent mutations destroyed the artifact. They also simultaneously greatly enhanced the expression of the cel12A gene, presumably by destroying stable mRNA structures that otherwise suppress translation. We propose that this method of finding problem mRNA sequences is superior to software-based analyses, especially if combined with low-temperature CE.     

Design and synthesis of a photocleavable fluorescent nucleotide 3'-O-allyl-dGTP-PC-Bodipy-FL-510 as a reversible terminator for DNA sequencing by synthesis

DNA sequencing by synthesis (SBS) using reversible fluorescent nucleotide terminators is potentially an efficient approach to address the limitations of current DNA sequencing techniques. Here, we report the design and synthesis of a 3'-O-allyl photocleavable fluorescent nucleotide analogue, 3'-O-allyl-dGTP-PC-Bodipy-FL-510, as a reversible terminator for SBS. The nucleotide is efficiently incorporated by DNA polymerase into a growing DNA strand to terminate the polymerase reaction. After that, the fluorophore is photocleaved quantitatively by irradiation at 355 nm, and the allyl group is rapidly and efficiently removed by using a Pd-catalyzed reaction under DNA-compatible conditions to regenerate a free 3'-OH group to reinitiate the polymerase reaction. Two cycles of such steps were successfully demonstrated to sequence a homopolymeric region of a DNA template, facilitating the development of SBS as a viable approach for high-throughput DNA sequencing.     

Multiple-channel microchips for high-throughput DNA analysis by capillary electrophoresis

Capillary electrophoresis on microfabricated multiple-channel chips has great potential for high-throughput analysis. This review focuses on multiple-channel chips used for high-throughput DNA analysis. It covers progress in the design and fabrication of multiple-channel chips and detection schemes used on these chips. Applications are concentrated on DNA fragment sizing, genotyping, and sequencing.     

Synthesis and Characterization of DNA Fragments Bearing an Adenine Radiation Product: 7,8-Dihydroadenin-8-one

The 7,8-dihydroadenin-8-one is one of the base derivatives formed by the action of ionizing radiation upon DNA. In order in investigate the mutagenic effects and the repair of DNA lesions induced by gamma rays, the synthesis of oligonucleotides bearing this damage has been performed by the phosphoramidite methodology. The preparation of the corresponding protected mononucleotide 6 (see Scheme) and its insertion into a DNA fragment are described. The modified oligonucleotide was purified by HPLC, characterized by DNA sequencing, enzymatic hydrolysis, and FAB mass spectrometry. In the experimental conditions used herein, no basic or acidic degradation was observed. In the DNA chain, the lesion is stable on piperidine heating under the usual DNA sequencing conditions.     

Dealing with repetitions in sequencing by hybridization

DNA sequencing by hybridization (SBH) induces errors in the biochemical experiment. Some of them are random and disappear when the experiment is repeated. Others are systematic, involving repetitions in the probes of the target sequence. A good method for solving SBH problems must deal with both types of errors. In this work we propose a new hybrid genetic algorithm for isothermic and standard sequencing that incorporates the concept of structured combinations. The algorithm is then compared with other methods designed for handling errors that arise in standard and isothermic SBH approaches. DNA sequences used for testing are taken from GenBank. The set of instances for testing was divided into two groups. The first group consisted of sequences containing positive and negative errors in the spectrum, at a rate of up to 20%, excluding errors coming from repetitions. The second group consisted of sequences containing repeated oligonucleotides, and containing additional errors up to 5% added into the spectra. Our new method outperforms the best alternative procedures for both data sets. Moreover, the method produces solutions exhibiting extremely high degree of similarity to the target sequences in the cases without repetitions, which is an important outcome for biologists. The spectra prepared from the sequences taken from GenBank are available on our website http://bio.cs.put.poznan.pl/.     

Binding‐Induced DNA Nanomachines Triggered by Proteins and Nucleic Acids

We introduce the concept and operation of a binding‐induced DNA nanomachine that can be activated by proteins and nucleic acids. This new type of nanomachine harnesses specific target binding to trigger assembly of separate DNA components that are otherwise unable to spontaneously assemble. Three‐dimensional DNA tracks of high density are constructed on gold nanoparticles functionalized with hundreds of single‐stranded oligonucleotides and tens of an affinity ligand. A DNA swing arm, free in solution, is linked to a second affinity ligand. Binding of a target molecule to the two ligands brings the swing arm to AuNP and initiates autonomous, stepwise movement of the swing arm around the AuNP surface. The movement of the swing arm, powered by enzymatic cleavage of conjugated oligonucleotides, cleaves hundreds of oligonucleotides in response to a single binding event. We demonstrate three nanomachines that are specifically activated by streptavidin, platelet‐derived growth factor, and the Smallpox gene. Substituting the ligands enables the nanomachine to respond to other molecules. The new nanomachines have several unique and advantageous features over DNA nanomachines that rely on DNA self‐assembly.     

Oligonucleotide analysis with MALDI-ion-mobility-TOFMS

Matrix-assisted laser-desorption ionization followed by ion-mobility separation and time-of-flight mass analysis (MALDI-IM-TOFMS) has been used to characterize native and chemically modified DNA oligonucleotides up to eight bases in length. Mobility resolution between 20 and 30 can be used to separate oligonucleotides of different length, but not to differentiate between isomers or even different compositions of the same length. MALDI-IM-TOFMS does, however, have additional utility in the analysis of mixtures of DNA oligonucleotides and peptides, because these classes of molecules can be distinguished on the basis of differences in their mobility. Oligonucleotide sequencing is also possible by MALDI-IM-TOFMS. Ion signals corresponding to nucleobase losses, w-type, and y-type fragments were identified by use of differences in ion mobility. MALDI-IM-TOFMS was also used to resolve DNA-platinum adducts from the corresponding unmodified oligonucleotides.     

Electrokinetic injection of DNA from gel micropads: basis for coupling polony technology with CE separation

We propose a novel method for electrokinetic injection of DNA samples into capillaries from nanoliter gel micropads, deposited on glass slides, which are coated with electroconducting film. Theoretical and experimental proof is presented for the proposed method. The method allows efficient and highly precise injection without physical contact between the gel pad and the capillary. Read length of more than 700 bp at Q20 has been reproducibly demonstrated in fused-silica capillaries using the proposed injection technique. Based on the obtained results we discuss a novel DNA sequencing system which combines DNA amplification and cycle sequencing in arrays of subnanoliter gel micropads and high-throughput electrophoretic separation in monolith multicapillary arrays.     

四色荧光标记二硫键可逆终端的合成及在DNA合成测序中的应用

分别以5-碘-2'-脱氧尿苷、 5-碘-2'-脱氧胞苷、 7-去氮-7-碘-2'-脱氧腺苷及7-去氮-7-碘-2'-脱氧鸟苷为原料, 以二硫键为可裂解连接单元, 通过多步反应合成了四色荧光标记不同碱基的脱氧核糖核苷酸; 研究了该类荧光标记核苷酸作为可逆终端在DNA合成测序中的应用. 所得产物结构经¹H NMR, ³¹P NMR及HRMS表征, 并对其进行了DNA高通量测序的测试. 结果表明, 该类荧光标记核苷酸作为DNA合成测序的可逆终端能够满足高通量测序的生化反应要求, 具有较好的应用前景.