New Labelling Technology for Molecular Probes Applied to the Ligation Detection Reaction–Universal Array System

The ligation detection reaction (LDR) associated with universal arrays (UA) uses a fluorescently labelled probe (DP) and a Zip Code-extended probe to detect single nucleotide polymorphisms in DNA target sequences. When used for genotyping, the LDR-UA technique uses two DPs, each specific to an allele and labelled with a different fluorophore. The fluorescent signals are processed to calculate the genotype. The uneven decay of fluorophores due to ageing and freezing/thawing cycles and the consequent unequal fluoresce level can lead to erroneous genotype calls. To circumvent this problem, an indirect labelling strategy was developed based on the substitution of the fluorophore with allele-specific 22 bp universal labelling sequences (ULS). Labelling is achieved with fluorescently labelled oligos complementary to the ULS (cULS). The strategy improved the uniformity in probe labelling, and generated results comparable to those using direct-labelled probes, as shown by genotyping 22 polymorphic sites in 70 samples with both strategies. This method can be easily implemented in the routine screening with LDR-UA or other techniques. Moreover, the approach results in a significant cost reduction over traditional direct labelling, and offers the possibility to interchange fluorophores and to increase the fluorescent signal by using multiple-labelled cULS.     

Choice of fluorophore affects dynamic DNA nanostructures

The ability to dynamically remodel DNA origami structures or functional nanodevices is highly desired in the field of DNA nanotechnology. Concomitantly, the use of fluorophores to track and validate the dynamics of such DNA-based architectures is commonplace and often unavoidable. It is therefore crucial to be aware of the side effects of popular fluorophores, which are often exchanged without considering the potential impact on the system. Here, we show that the choice of fluorophore can strongly affect the reconfiguration of DNA nanostructures. To this end, we encapsulate a triple-stranded DNA (tsDNA) into water-in-oil compartments and functionalize their periphery with a single-stranded DNA handle (ssDNA). Thus, the tsDNA can bind and unbind from the periphery by reversible opening of the triplex and subsequent strand displacement. Using a combination of experiments, molecular dynamics (MD) simulations, and reaction-diffusion modelling, we demonstrate for 12 different fluorophore combinations that it is possible to alter or even inhibit the DNA nanostructure formation—without changing the DNA sequence. Besides its immediate importance for the design of pH-responsive switches and fluorophore labelling, our work presents a strategy to precisely tune the energy landscape of dynamic DNA nanodevices.     

Bacteriophage strain typing by rapid single molecule analysis

Rapid characterization of unknown biological samples is under the focus of many current studies. Here we report a method for screening of biological samples by optical mapping of their DNA. We use a novel, one-step chemo-enzymatic reaction to covalently bind fluorophores to DNA at the four-base recognition sites of a DNA methyltransferase. Due to the diffraction limit of light, the dense distribution of labels results in a continuous fluorescent signal along the DNA. The amplitude modulations (AM) of the fluorescence intensity along the stretched DNA molecules exhibit a unique molecular fingerprint that can be used for identification. We show that this labelling scheme is highly informative, allowing accurate genotyping. We demonstrate the method by labelling the genomes of λ and T7 bacteriophages, resulting in a consistent, unique AM profile for each genome. These profiles are also successfully used for identification of the phages from a background phage library. Our method may provide a facile route for screening and typing of various organisms and has potential applications in metagenomics studies of various ecosystems.     

A Fast and Scalable Kymograph Alignment Algorithm for Nanochannel-Based Optical DNA Mappings

Optical mapping by direct visualization of individual DNA molecules, stretched in nanochannels with sequence-specific fluorescent labeling, represents a promising tool for disease diagnostics and genomics. An important challenge for this technique is thermal motion of the DNA as it undergoes imaging; this blurs fluorescent patterns along the DNA and results in information loss. Correcting for this effect (a process referred to as kymograph alignment) is a common preprocessing step in nanochannel-based optical mapping workflows, and we present here a highly efficient algorithm to accomplish this via pattern recognition. We compare our method with the one previous approach, and we find that our method is orders of magnitude faster while producing data of similar quality. We demonstrate proof of principle of our approach on experimental data consisting of melt mapped bacteriophage DNA.     

Competitive binding-based optical DNA mapping for fast identification of bacteria - multi-ligand transfer matrix theory and experimental applications on Escherichia coli

We demonstrate a single DNA molecule optical mapping assay able to resolve a specific Escherichia coli strain from other strains. The assay is based on competitive binding of the fluorescent dye YOYO-1 and the AT-specific antibiotic netropsin. The optical map is visualized by stretching the DNA molecules in nanofluidic channels. We optimize the experimental conditions to obtain reproducible barcodes containing as much information as possible. We implement a multi-ligand transfer matrix method for calculating theoretical barcodes from known DNA sequences. Our method extends previous theoretical approaches for competitive binding of two types of ligands to many types of ligands and introduces a recursive approach that allows long barcodes to be calculated with standard computer floating point formats. The identification of a specific E. coli strain (CCUG 10979) is based on mapping of 50–160 kilobasepair experimental DNA fragments onto the theoretical genome using the developed theory. Our identification protocol introduces two theoretical constructs: a P-value for a best experiment-theory match and an information score threshold. The developed methods provide a novel optical mapping toolbox for identification of bacterial species and strains. The protocol does not require cultivation of bacteria or DNA amplification, which allows for ultra-fast identification of bacterial pathogens.     

The origin of the DNA in transducing particles of bacteriophage Mu

Summary The origin of DNA in transducing particles of bacteriophage Mu was investigated by density labelling techniques. Unlabelled plaque-forming and leu⁺-transducing particles were of about the same density. Preinfection labelling of DNA with 5-bromodeoxyuridine increased the density of the transducing particles, but not that of the infective ones. Postinfection labelling increased the density of the infective particles twice as much as that of the transducing particles. We conclude that half of the transducing DNA is synthesized before infection and half is synthesized after infection, similar to the results obtained with Plkc transducing phages (Ikeda and Tomizawa, 1965).     

Optical mapping of DNA: single-molecule-based methods for mapping genomes

The technologies associated with DNA sequencing are rapidly evolving. Indeed, single-molecule DNA sequencing strategies are cheaper and faster than ever before. Despite this progress, every sequencing platform to date relies on reading the genome in small, abstract fragments, typically of less than 1000 bases in length. The overarching aim of the optical map is to complement the information derived from DNA sequencing by providing long-range context on which these short sequence reads can be built. This is typically done using an enzyme to target and modify at short DNA sequences of, say, six bases in length throughout the genome. By accurately placing these short pieces of sequence on long genomic DNA fragments, up to several millions of bases in length, a scaffold for sequence assembly can be obtained. This review focuses on three enzymatic approaches to optical mapping. Optical mapping was first developed using restriction enzymes to sequence-specifically cleave DNA that is immobilized on a surface. More recently, nicking enzymes have found application in the sequence-specific fluorescent labeling of DNA for optical mapping. Such covalent modification allows the DNA to be imaged in solution, and this, in combination with developing nanofluidic technologies, is enabling new high-throughput approaches to mapping. And, finally, this review will discuss the recent development of mapping with subdiffraction-limit precision using methyltransferase enzymes to label the DNA with an ultrahigh density.     

Rapid DNA mapping by fluorescent single molecule detection

DNA mapping is an important analytical tool in genomic sequencing, medical diagnostics and pathogen identification. Here we report an optical DNA mapping strategy based on direct imaging of individual DNA molecules and localization of multiple sequence motifs on the molecules. Individual genomic DNA molecules were labeled with fluorescent dyes at specific sequence motifs by the action of nicking endonuclease followed by the incorporation of dye terminators with DNA polymerase. The labeled DNA molecules were then stretched into linear form on a modified glass surface and imaged using total internal reflection fluorescence (TIRF) microscopy. By determining the positions of the fluorescent labels with respect to the DNA backbone, the distribution of the sequence motif recognized by the nicking endonuclease can be established with good accuracy, in a manner similar to reading a barcode. With this approach, we constructed a specific sequence motif map of lambda-DNA. We further demonstrated the capability of this approach to rapidly type a human adenovirus and several strains of human rhinovirus.     

A simple and novel DNA combing methodology for Fiber-FISH and optical mapping

Single molecule analysis can help us study genomics efficiently. It involves studying single DNA molecules for genomic studies. DNA combing is one of such techniques which allowed us to study single DNA molecules for multiple uses. DNA combing technology can be used to perform Fiber-FISH and optical mapping. Physical mapping of genomes can be studied by restriction digestion of combed DNA on glass slides. Restriction fragments can be arranged into optical maps by gathering fluorescent intensity data by CCD camera and image analysis by softwares. Physical mapping and DNA segment rearrangements can be studied by Fiber-FISH which involves application of probes on genomic DNA combed over glass slides. We developed a novel methodology involving combing solution optimization, denatured combed DNA and performed restriction digestion of combed DNA. Thus we provided an efficient and robust combing platform for its application in Fiber-FISH and optical mapping.     

High-throughput single-nucleotide structural mapping by capillary automated footprinting analysis

The use of capillary electrophoresis with fluorescently labeled nucleic acids revolutionized DNA sequencing, effectively fueling the genomic revolution. We present an application of this technology for the high-throughput structural analysis of nucleic acids by chemical and enzymatic mapping ('footprinting'). We achieve the throughput and data quality necessary for genomic-scale structural analysis by combining fluorophore labeling of nucleic acids with novel quantitation algorithms. We implemented these algorithms in the CAFA (capillary automated footprinting analysis) open-source software that is downloadable gratis from https://simtk.org/home/cafa. The accuracy, throughput and reproducibility of CAFA analysis are demonstrated using hydroxyl radical footprinting of RNA. The versatility of CAFA is illustrated by dimethyl sulfate mapping of RNA secondary structure and DNase I mapping of a protein binding to a specific sequence of DNA. Our experimental and computational approach facilitates the acquisition of high-throughput chemical probing data for solution structural analysis of nucleic acids.     

Determination of DNA polymerase and nuclease activities of DNA-dependent polymerases using fluorescence detection under real-time conditions

A new method is proposed for estimation of polymerase activities using fluorescence detection during isothermal reaction. The method allows simultaneous determination of DNA-dependent DNA polymerase and 5'-3'-exonuclease activities using amplifiers supplied with an optical module for fluorescence detection under real-time conditions. Different primer-template combinations used as polymerase substrates were compared. Primer elongation (polymerase reaction) is detected by changes in SYBR Green I fluorescence upon binding to dsDNA during reaction; nuclease activities are detected by changes in fluorescence due to cleavage of the probe, containing the reporter fluorophore and fluorescence quencher, and hybridized in advance to the template single-stranded region. It was also shown that the method can be used for determination of relative activities of DNA polymerase preparations, estimation of temperature-time dissociation parameters of polymerase complexes with specific antibodies to its active center, and analysis of effects of inhibitors and activators of different nature on reaction rates of dsDNA polymerization and 5'-3'-exonuclease cleavage by polymerase. The method can be also used for estimation of endonuclease activities of DNA polymerases.     

Replication of lambda dv DNA in vitro.

Exogenous lambda dv DNA was replicated in extracts prepared from E. coli cells carrying plasmids with inducible lambda O and /or P genes. Extracts from cells carrying only one of the two lambda replication functions complement each other in this reaction. The reaction further requires ribonucleotide triphosphates, an ATP regenerating system, DNA gyrase and RNA polymerase functions. Density labelling of the superhelical reaction products results in hybrid density indicating that one complete round of replication has taken place in vitro.     

Single molecule analysis of DNA replication

We describe here a novel approach for the study of DNA replication. The approach is based on a process called molecular combing and allows for the genome wide analysis of the spatial and temporal organization of replication units and replication origins in a sample of genomic DNA. Molecular combing is a process whereby molecules of DNA are stretched and aligned on a glass surface by the force exerted by a receding air/water interface. Since the stretching occurs in the immediate vicinity of the meniscus, all molecules are identically stretched in a size and sequence independent manner. The application of fluorescence hybridization to combed DNA results in a high resolution (1 to 4 kb) optical mapping that is simple, controlled and reproducible. The ability to comb up to several hundred haploid genomes on a single coverslip allows for a statistically significant number of measurements to be made. Direct labeling of replicating DNA sequences in turn enables origins of DNA replication to be visualized and mapped. These features therefore make molecular combing an attractive tool for genomic studies of DNA replication. In the following, we discuss the application of molecular combing to the study of DNA replication and genome stability.     

Encoded metal nanoparticle-based molecular beacons for multiplexed detection of DNA

In this paper we describe a molecular beacon format assay in which encoded nanowire particles are used to achieve multiplexing. We demonstrate this principle with the detection of five viral pathogens; Hepatitis A virus, Hepatitis C virus, West Nile Virus, Human Immune Deficiency virus and Severe Acute Respiratory Syndrome virus. Oligonucleotides are designed complementary to a target sequence of interest containing a 3′ universal fluorescence dye. A 5′ thiol causes the oligonucleotides to self-assemble onto the metal nanowire. The single-stranded oligonucleotide contains a self-complementary hairpin stem sequence of 10 bases that forces the 3′ fluorophore to come into contact with the metallic nanowire surface, thereby quenching the fluorescence. Upon addition of target DNA, there is hybridization with the complementary oligonucleotides. The resulting DNA hybrid is rigid, unfolds the hairpin structure, and causes the fluorophore to be moved away from the surface such that it is no longer quenched. By using differently encoded nanowires, each conjugated with a different oligonucleotide sequence, multiplexed DNA assays are possible using a single fluorophore, from a multiplexed RT-PCR reaction.     

Production of random DNA oligomers for scalable DNA computing

While remarkably complex networks of connected DNA molecules can form from a relatively small number of distinct oligomer strands, a large computational space created by DNA reactions would ultimately require the use of many distinct DNA strands. The automatic synthesis of this many distinct strands is economically prohibitive. We present here a new approach to producing distinct DNA oligomers based on the polymerase chain reaction (PCR) amplification of a few random template sequences. As an example, we designed a DNA template sequence consisting of a 50-mer random DNA segment flanked by two 20-mer invariant primer sequences. Amplification of a dilute sample containing about 30 different template molecules allows us to obtain around 10¹¹ copies of these molecules and their complements. We demonstrate the use of these amplicons to implement some of the vector operations that will be required in a DNA implementation of an analog neural network.     

Mapping of repeated DNA sequences in plant chromosomes by PRINS and C-PRINS

 The primed in situ DNA labelling (PRINS) procedure was optimised for the rapid physical mapping of several types of repetitive DNA sequences on the mitotic chromosomes of Vicia faba, Pisum sativum and Secale cereale. A localization of the highly repeated FokI sequence on V. faba chromosomes was achieved after a 7-min total reaction time. In addition, we report a procedure for direct cycling-PRINS (C-PRINS), a variation of PRINS which involves a sequence of thermal cycles analogous to the polymerase chain reaction. Compared to PRINS, C-PRINS was more sensitive. Further work is needed to improve the sensitivity of the reaction to allow for the reliable detection of low-copy DNA sequences. Received: 17 September 1996 / Accepted: 18 October 1996     

Spin-on end-functional diblock copolymers for quantitative DNA immobilization

We demonstrate a simple means to covalently bond DNA to both hard (i.e., glass and silicon wafers) and soft (i.e., polymeric) substrates that provides quantitative and precise control of the DNA areal density. The approach is based on spin coating an alkyne-end-functional diblock copolymer, alpha-alkyne-omega-Br-poly( tBA- b-MMA), that self-assembles on both types of substrates as an ordered monolayer and thereby directs alkyne groups to the surface. Azido-functionalized DNA is covalently linked to the alkyne functionalized substrates by means of a "click" reaction between azide and alkyne groups. The density of immobilized DNA can be quantitatively controlled by varying the parameters used for spin-coating the copolymer film, that is, solution concentration and rotational speed, or by varying the copolymer molecular weight. We find the yield of the DNA coupling reaction to be dependent on the nature of the polymer underlying the reactive alkyne functional groups, being higher for more hydrophilic polymers.     

An on-chip thin film photodetector for the quantification of DNA probes and targets in microarrays

A flat microdevice which incorporates a thin-film amorphous silicon (a-Si:H) photodetector with an upper layer of functionalized SiO₂ is used to quantify the density of both immobilized and hybridized DNA oligonucleotides labeled with a fluorophore. The device is based on the photoconductivity of hydrogenated amorphous silicon in a coplanar electrode configuration. Excitation, with near UV/blue light, of a single-stranded DNA molecule tagged with the fluorophore 1-(3-(succinimidyloxycarbonyl)benzyl)-4-(5-(4-methoxyphenyl)oxazol-2-yl) pyridinium bromide (PyMPO), results in the emission of visible light. The emitted light is then converted into an electrical signal in the photodetector, thus allowing the optoelectronic detection of the DNA molecules. The detection limit of the present device is of the order of 1 × 10¹² molecules/cm² and is limited by the efficiency of the filtering of the excitation light. A surface density of 33.5 ± 4.0 pmol/cm² was measured for DNA covalently immobilized to the functionalized SiO₂ thin film and a surface density of 3.7 ± 1.5 pmol/cm² was measured for the complementary DNA hybridized to the bound DNA. The detection concept explored can enable on-chip electronic data acquisition, improving both the speed and the reliability of DNA microarrays.     

Cross-Talk-Free Multi-Color STORM Imaging Using a Single Fluorophore

Multi-color stochastic optical reconstruction microscopy (STORM) is routinely performed; however, the various approaches for achieving multiple colors have important caveats. Color cross-talk, limited availability of spectrally distinct fluorophores with optimal brightness and duty cycle, incompatibility of imaging buffers for different fluorophores, and chromatic aberrations impact the spatial resolution and ultimately the number of colors that can be achieved. We overcome these complexities and develop a simple approach for multi-color STORM imaging using a single fluorophore and sequential labelling. In addition, we present a simple and versatile method to locate the same region of interest on different days and even on different microscopes. In combination, these approaches enable cross-talk-free multi-color imaging of sub-cellular structures.