Quantitative DNA hybridization in solution using magnetic/luminescent core-shell nanoparticles

Nanoscale magnetic/luminescent core-shell particles were used for DNA quantification in a hybridization-in-solution approach. We demonstrated a rapid, simple, and non-polymerase chain reaction-based DNA hybridization-in-solution assay for quantifying bacteria capable of biodegrading methyl tertiary-butyl ether. Fe3O4/Eu:Gd2O3 core-shell nanoparticles synthesized by spray pyrolysis were biofunctionalized with NeutrAvidin. Following immobilization of a biotinylated probe DNA on the particles' surfaces via passive adsorption, target DNA labeled with fluorescein isothiocyanate was hybridized with probe DNA. The hybridized DNA complex was separated from solution with a magnet, while nonhybridized DNA remained in solution. The normalized fluorescence (fluorescein isothiocyanate/nanoparticles) measured with a spectrofluorometer indicated a linear quantification (R(2)=0.98) of the target bacterial 16 S rDNA. The rate of hybridization increased concurrently with the target DNA concentration. In addition, this approach differentiated between the signal outputs from perfectly complementary target and two-base mismatched target DNA in a range of concentrations, showing the specificity of the assay and the possibility for environmental applications.     

Microgravimetric DNA sensor based on quartz crystal microbalance: comparison of oligonucleotide immobilization methods and the application in genetic diagnosis

We report on the study of immobilization DNA probes onto quartz crystal oscillators by self-assembly technique to form variety types of mono- and multi-layered sensing films towards the realization of DNA diagnostic devices. A 18-mer DNA probe complementary to the site of genetic beta-thalassaemia mutations was immobilized on the electrodes of QCM by covalent bonding or electrostatic adsorption on polyelectrolyte films to form mono- or multi-layered sensing films by self-assembled process. Hybridization was induced by exposure of the QCMs immobilized with DNA probe to a test solution containing the target nucleic acid sequences. The kinetics of DNA probe immobilization and hybridization with the fabricated DNA sensors were studied via in-situ frequency changes. The characteristics of QCM sensors containing mono- or multi-layered DNA probe constructed by direct chemical bonding, avidin-biotin interaction or electrostatic adsorption on polyelectrolyte films were compared. Results indicated that the DNA sensing films fabricated by immobilization of biotinylated DNA probe to avidin provide fast sensor response and high hybridization efficiencies. The effects of ionic strength of the buffer solution and the concentration of target nucleic acid used in hybridization were also studied. The fabricated DNA biosensor was used to detect a set of real samples. We conclude that the microgravimetric DNA sensor with its direct detection of amplified products provide a rapid, low cost and convenient diagnostic method for genetic disease.     

Enhancement of DNA immobilization and hybridization on gold electrode modified by nanogold aggregates

Gold electrodes modified by nanogold aggregates (nanogold electrode) were obtained by the electrodeposition of gold nanoparticles onto planar gold electrode. The Electrochemical response of single-stranded DNA (ssDNA) probe immobilization and hybridization with target DNA was measured by cyclic voltammograms (CV) using methylene blue (MB) as an electroactive indicator. An improving method using long sequence target DNA, which greatly enhanced the response signal during hybridization, was studied. Nanogold electrodes could largely increase the immobilization amount of ssDNA probe. The hybridization amount of target DNA could be increased several times for the manifold nanogold electrodes. The detection limit of nanogold electrode for the complementary 16-mer oligonucleotide (target DNA1) and long sequence 55-mer oligonucleotide (target DNA2) could reach the concentration of 10(-9) mol/L and 10(-11) mol/L, respectively, which are far more sensitive than that of the planar electrode.     

A new scheme of hybridization based on the Au(nano)-DNA modified glassy carbon electrode

DNA hybridization on the Au(nano)-DNA modified glassy carbon electrode (GCE) was investigated. The thiol modified probe oligonucleotides (SH-ssDNA) at the 5' phosphate end were assembled on the Au(nano)-DNA modified GCE surface. The electrochemical response of the probe immobilization and hybridization with target DNA was measured by differential pulse voltammetry (DPV) using methylene blue (MB) as the electroactive indicator. Gold nanoparticles can be dispersed effectively on the GCE surface in the presence of calf thymus DNA. Au(nano)-DNA modified GCE could greatly increase the active sites and enhance the response signal during immobilization and hybridization. The hybridization amount of target DNA could be greatly increased. The linear detection range of Au(nano)-DNA electrode for the complementary 21-mer oligonucleotide (cDNA) was achieved from 1.52 x 10(-10) to 4.05 x 10(-8) mol L(-1). The detection limit could reach the concentration of 10(-10) mol/L.     

DNA and protein microarray printing on silicon nitride waveguide surfaces

Sputtered silicon nitride optical waveguide surfaces were silanized and modified with a hetero-bifunctional crosslinker to facilitate thiol-reactive immobilization of contact-printed DNA probe oligonucleotides, streptavidin and murine anti-human interleukin-1 beta capture agents in microarray formats. X-ray photoelectron spectroscopy (XPS) was used to characterize each reaction sequence on the native silicon oxynitride surface. Thiol-terminated DNA probe oligonucleotides exhibited substantially higher surface printing immobilization and target hybridization efficiencies than non-thiolated DNA probe oligonucleotides: strong fluorescence signals from target DNA hybridization supported successful DNA oligonucleotide probe microarray fabrication and specific capture bioactivity. Analogously printed arrays of thiolated streptavidin and non-thiolated streptavidin did not exhibit noticeable differences in either surface immobilization or analyte capture assay signals. Non-thiolated anti-human interleukin-1 beta printed on modified silicon nitride surfaces reactive to thiol chemistry exhibited comparable performance for capturing human interleukin-1 beta analyte to commercial amine-reactive microarraying polymer surfaces in sandwich immunoassays, indicating substantial non-specific antibody-surface capture responsible for analyte capture signal.     

A nucleic acid biosensor for the detection of a short sequence related to the hepatitis B virus using bis(benzimidazole)cadmium(II) dinitrate as an electrochemical indicator

A novel hybridization indicator, bis(benzimidazole)cadmium(II) dinitrate (Cd(bzim)(2)(NO(3))(2)), was utilized to develop an electrochemical DNA biosensor for the detection of a short DNA sequence related to the hepatitis B virus (HBV). The sensor relies on the immobilization and hybridization of the 21-mer single-stranded oligonucleotide from the HBV long repeat at the glassy carbon electrode (GCE). The hybridization between the probe and its complementary sequence as the target was studied by enhancement of the peak of the Cd(bzim)(2)(2+) indicator using cyclic voltammetry (CV) and differential pulse voltammetry (DPV). Numerous factors affecting the probe immobilization, target hybridization, and indicator binding reactions were optimized to maximize the sensitivity and speed of the assay time. With this approach, a sequence of the HBV could be quantified over the range from 1.49x10(-7)M to 1.06x10(-6)M, with a linear correlation of r=0.9973 and a detection limit of 8.4x10(-8)M. The Cd(bzim)(2)(2+) signal observed from the probe sequence before and after hybridization with a four-base mismatch containing sequence was lower than that observed after hybridization with a complementary sequence, showing good selectivity. These results demonstrate that the Cd(bzim)(2)(2+) indicator provides great promise for the rapid and specific measurement of the target DNA.     

Time-resolved detection probe for homogeneous nucleic acid analyses in one-step format

We report here an extension of homogeneous assays based on fluorescence intensity and lifetime measuring on DNA hybridization. A novel decay probe that allows simple one-step nucleic acid detection with subnanomolar sensitivity, and is suitable for closed-tube applications, is introduced. The decay probe uses fluorescence resonance energy transfer (FRET) between a europium chelate donor and an organic fluorophore acceptor. The substantial change in the acceptor emission decay time on hybridization with the target sequence allows the direct separation of the hybridized and unhybridized probe populations in a time-resolved measurement. No additional sample manipulation or self-hybridization of the probes is required. The wavelength and decay time of a decay probe can be adjusted according to the selection of probe length and acceptor fluorophore, thereby making the probes applicable to multiplexed assays. Here we demonstrate the decay probe principle and decay probe-based, one-step, dual DNA assay using celiac disease-related target oligonucleotides (single-nucleotide polymorphisms [SNPs]) as model analytes. Decay probes showed specific response for their complementary DNA target and allowed good signal deconvolution based on simultaneous optical and temporal filtering. This technique potentially could be used to further increase the number of simultaneously detected DNA targets in a simple one-step homogeneous assay.     

Self-assembly DNA-conjugated polymer for detection of single nucleotide polymorphism

We developed a self-assembly DNA-conjugated polymer based on polyacrylic acid (PAA) for DNA chip fabrication. A 20-mer single-stranded DNA (ssDNA, probe-1), and 3-(2-pyridyldithio)propionyl hydrazide (PDPH), for promoting self-assembled immobilization, were both covalently attached to PAA as sidechains. This DNA-conjugated PAA was then spontaneously immobilized on a gold substrate. Probe-1 on the immobilized polymer was hybridized to a 34-mer ssDNA (probe-2), which had the sequence desired for analyzing the target DNA. The fluorescence intensity after incubating the P-1 DNA-conjugated polymer with probe-2 DNA was much higher than with control sequence in the first hybridization. The interactions between target DNA and the DNA-conjugated PAA were investigated by fluorescence measurement. The interaction of fully matched target DNA with this immobilized DNA conjugated polymer has been studied at different ion strength conditions. SNP sequences as targets showed less than 15% the intensity of fully matched target DNA in the second hybridization, indicating that the gold surfaces coated with the DNA-conjugated PAA was highly specific to fully matched DNA. The DNA-conjugated PAA immobilized on a gold substrate is characterized by reduced nonspecific adsorption, due to less electrostatic repulsion as well as the polymer coating. Therefore, DNA-conjugated PAA can be used for probe DNA immobilization method.     

Introduction of hematoxylin as an electroactive label for DNA biosensors and its employment in detection of target DNA sequence and single-base mismatch in human papilloma virus corresponding to oligonucleotide

For the detection of DNA hybridization, a new electrochemical biosensor was developed on the basis of the interaction of hematoxylin with 20-mer deoxyoligonucleotides (from human papilloma virus, HPV). The study was performed based on the interaction of hematoxylin with an alkanethiol DNA probe self-assembled gold electrode (ss-DNA/AuE) and its hybridization form (ds-DNA/AuE). The optimum conditions were found for the immobilization of HPV probe on the gold electrode (AuE) surface and its hybridization with the target DNA. Electrochemical detection of the self-assembled DNA and the hybridization process were performed by cyclic voltammetry (CV) and differential pulse voltammetry (DPV) over the potential range where the accumulated hematoxylin at the modified electrode was electroactive. Observing a remarkable difference between the voltammetric signals of the hematoxylin obtained from different hybridization samples (non-complementary, mismatch and complementary DNAs), we confirmed the potential of the developed biosensor in detecting and discriminating the target complementary DNA from non-complementary and mismatch oligonucleotides. Under optimum conditions, the electrochemical signal had a linear relationship with the concentration of the target DNA ranging from 12.5 nM to 350.0 nM, and the detection limit was 3.8 nM.     

DBD-fish on neutral comets: simultaneous analysis of DNA single- and double-strand breaks in individual cells

Humanblood leukocytes exposed to X-rays were immersed in an agarose microgel on a slide, extensively deproteinized, and electrophoresed under neutral conditions. Following this single-cell gel electrophoresis assay, characteristics of DNA migration (i.e., area of the comet) are related to the DNA double-strand breaks (dsbs) yield. After electrophoresis, comets were briefly incubated in an alkaline unwinding solution, transforming DNA breaks and alkali-labile sites into restricted single-stranded DNA (ssDNA) motifs. These motifs behave as target sites for hybridization with a whole genome probe, following the DNA breakage detection-fluorescence in situ hybridization (DBD-FISH) procedure. As DNA breakage increases with dose, more ssDNA is produced in the comet by the alkali and more DNA probe hybridizes, resulting in an increase in the mean fluorescence intensity. Since radiation-induced DNA single-strand breaks (ssbs) are far more frequent than dsbs, the mean fluorescence intensity of the DBD-FISH signal from the comet is related to the ssb level, whereas the surface area of the same comet signal is indicative of the dsb yield. Thus, both DNA break types may be simultaneously analyzed in the same cell. This was confirmed in a repair assay performing the DBD-FISH on neutral comets from a human cell line defective in the repair of dsbs. Otherwise, treatment with hydrogen peroxide, a main inducer of ssbs, increased the mean fluorescence intensity, but not the surface, of X-ray-exposed human leukocytes.     

The effect of surface probe density on DNA hybridization

The hybridization of complementary strands of DNA is the underlying principle of all microarray-based techniques for the analysis of DNA variation. In this paper, we study how probe immobilization at surfaces, specifically probe density, influences the kinetics of target capture using surface plasmon resonance (SPR) spectroscopy, an in situ label-free optical method. Probe density is controlled by varying immobilization conditions, including solution ionic strength, interfacial electrostatic potential and whether duplex or single stranded oligonucleotides are used. Independent of which probe immobilization strategy is used, we find that DNA films of equal probe density exhibit reproducible efficiencies and reproducible kinetics for probe/target hybridization. However, hybridization depends strongly on probe density in both the efficiency of duplex formation and the kinetics of target capture. We propose that probe density effects may account for the observed variation in target-capture rates, which have previously been attributed to thermodynamic effects.     

Application of multiple response optimization design to quantum dot-encoded microsphere bioconjugates hybridization assay

The optimization of DNA hybridization for genotyping assays is a complex experimental problem that depends on multiple factors such as assay formats, fluorescent probes, target sequence, experimental conditions, and data analysis. Quantum dot-doped particle bioconjugates have been previously described as fluorescent probes to identify single nucleotide polymorphisms even though this advanced fluorescent material has shown structural instability in aqueous environments. To achieve the optimization of DNA hybridization to quantum dot-doped particle bioconjugates in suspension while maximizing the stability of the probe materials, a nonsequential optimization approach was evaluated. The design of experiment with response surface methodology and multiple optimization response was used to maximize the recovery of fluorescent probe at the end of the assay simultaneously with the optimization of target–probe binding. Hybridization efficiency was evaluated by the attachment of fluorescent oligonucleotides to the fluorescent probe through continuous flow cytometry detection. Optimal conditions were predicted with the model and tested for the identification of single nucleotide polymorphisms. The design of experiment has been shown to significantly improve biochemistry and biotechnology optimization processes. Here we demonstrate the potential of this statistical approach to facilitate the optimization of experimental protocol that involves material science and molecular biology.     

Nonisotopic detection of RNA in an enzyme immunoassay using a monoclonal antibody against DNA-RNA hybrids

A sensitive nonisotopic solution hybridization assay for detection of RNA is described and characterized using a pSP65 plasmid model system. The assay procedure is based on a hybridization reaction in solution between a biotinylated DNA probe and a target RNA. The biotin-labeled hybrids are captured on a microtiter plate coated with an antibody to biotin. Bound DNA-RNA hybrids are detected by an immunoreaction with an enzyme-labeled monoclonal antibody specifically directed against DNA-RNA heteropolymers and the hybrids are quantitatively measured with the addition of a fluorogenic substrate. Optimal conditions under which to perform the assay were hybridization time, 1000 min; temperature, 75 degrees C; probe concentration, 0.2 microgram/ml; extent of probe biotinylation, 6.7%; buffer stringency, 2x SSC. A bisulfite-modified DNA probe was compared to nick-translated probes synthesized with reporter groups of different lengths (bio-11-dUTP or bio-19-dUTP). All probes could detect 10 pg/ml of target RNA. The presence of nonhomologous DNA or RNA sequences reduced the sensitivity of RNA detection by one half-log to 32 pg/ml (1.6 pg/assay).     

DNA microdevice for electrochemical detection of Escherichia coli 0157:H7 molecular markers

An electrochemical DNA sensor based on the hybridization recognition of a single-stranded DNA (ssDNA) probe immobilized onto a gold electrode to its complementary ssDNA is presented. The DNA probe is bound on gold surface electrode by using self-assembled monolayer (SAM) technology. An optimized mixed SAM with a blocking molecule preventing the nonspecific adsorption on the electrode surface has been prepared. In this paper, a DNA biosensor is designed by means of the immobilization of a single stranded DNA probe on an electrochemical transducer surface to recognize specifically Escherichia coli (E. coli) 0157:H7 complementary target DNA sequence via cyclic voltammetry experiments. The 21 mer DNA probe including a C6 alkanethiol group at the 5' phosphate end has been synthesized to form the SAM onto the gold surface through the gold sulfur bond. The goal of this paper has been to design, characterise and optimise an electrochemical DNA sensor. In order to investigate the oligonucleotide probe immobilization and the hybridization detection, experiments with different concentration of DNA and mismatch sequences have been performed. This microdevice has demonstrated the suitability of oligonucleotide Self-assembled monolayers (SAMs) on gold as immobilization method. The DNA probes deposited on gold surface have been functional and able to detect changes in bases sequence in a 21-mer oligonucleotide.     

Directed covalent immobilization of aminated DNA probes on aminated plates

A new protocol that enables the immobilization of DNA probes on aminated micro-titer plates activated with aldehyde-dextran via an amino group artificially introduced in the 3' end of the oligonucleotide probe is reported in this work. The method is based on the use of hetero-functional-dextran as a long and multifunctional spacer arm covalently attached to an aminated surface capable of immobilizing DNA oligonucleotides. The immobilization occurred only via the amino introduced in the 3' end of the probe, with no implication of the DNA bases in the immobilization, ensuring that the full length of the probe is available for hybridization. These plates having immobilized oligonucleotide probes are able to hybridize complementary DNA target molecules. The tailor-made hetero-functional aldehyde-aspartic-dextran together with the chemical blocking of the remaining primary amino groups on the support using acetic anhydride avoid the nonspecific adsorption of DNA on the surface of the plates. Using these activated plates, (studying the effect of the probe concentration, temperature, and time of the plate activation on the achieved signal), thus, the covalent immobilization of the aminated DNA probe was optimized, and the sensitivity obtained was similar to that achieved using commercial biotin-streptavidin systems. The new DNA plates are stable under very drastic experimental conditions (90% formamide, at 100 degrees C for 30 min or in 100 mM NaOH).     

Oligonucleotide derivatives in the hybridization analysis of nucleic acids: II. Isothermal signal amplification in DNA analysis by minisequencing

An isothermal amplification of a reporter signal during the analysis of the hybridization of nucleic acids was studied by limited probe extension (minisequencing). The intensity of the reporter signal was shown to increase due to the multiple enzymatic labeling of the probes during consecutive hybridization with one DNA template in both the homophase and heterophase assays using various detection methods: radioisotope or fluorescent labeling or enzyme-linked assay. The kinetic scheme of the process was proposed and the kinetic parameters for each step were evaluated. It was shown that the signal intensity correlated with the physicochemical characteristics for probe/DNA and product/DNA complexes. The maximum intensity was observed at the minimal difference between the thermodynamic stability of these complexes, provided that the reaction temperature was close to their melting temperature values; increasing or decreasing the reaction temperature led to a decrease in the amount of the reporting product. The signal intensity is significantly reduced when the analyzed DNA contains single-nucleotide discrepancies. The limited probe extension assay is useful not only for the detection of analyzed DNA, but also for its quantitative characterization.     

Label-free and homogeneous DNA hybridization detection using gold nanoparticles-based chemiluiminescence system

We find that the catalytic activity of gold nanoparticles (GNPs) on luminol-H₂O₂ chemiluminescence (CL) system is greatly enhanced after it is aggregated by 0.5 M NaCl. We use this observation to design a CL detection of DNA hybridization. It is based on that the single- and double-stranded oligonucleotides have different propensities to adsorb on GNPs in colloidal solution, and the hybridization occurred between the probe DNA and target DNA can result in aggregation of the GNPs, producing strong CL emission. In the assay, no covalent functionalization of the GNPs, the probe, or the target DNA is required. The assay, including hybridization and detection, occurs in homogenous solution. The detection limit of target DNA (3σ) was estimated to be as low as 1.1 fM. The sensitivity was increased more than 6 orders of magnitude over that of GNPs-based colorimetric method. The present CL method for DNA hybridization detection offers the advantages of being simple, cheap, rapid and sensitive.     

Oligonucleotide derivatives in the nucleic acid hybridization analysis. II. Isothermal signal amplification in process of DNA analysis by minisequencing

The isothermal amplification of reporter signal via limited probe extension (minisequencing) upon hybridization of nucleic acids has been studied. The intensity of reporter signal has been shown to increase due to enzymatic labeling of multiple probes upon consecutive hybridization with one DNA template both in homophase and heterophase assays using various kinds of detection signal: radioisotope label, fluorescent label, and enzyme-linked assay. The kinetic scheme of the process has been proposed and kinetic parameters for each step have been determined. The signal intensity has been shown to correlate with physicochemical characteristics of both complexes: probe/DNA and product/DNA. The maximum intensity has been observed at minimal difference between the thermodynamic stability of these complexes, provided the reaction temperature has been adjusted near their melting temperature values; rising or lowering the reaction temperature reduces the amount of reporting product. The signal intensity has been shown to decrease significantly upon hybridization with the DNA template containing single-nucleotide mismatches. Limited probe extension assay is useful not only for detection of DNA template but also for its quantitative characterization.     

Cadmium sulfide-modified GCE for direct signal-amplified sensing of DNA hybridization

A novel DNA hybridization sensor based on nanoparticle CdS modified glass carbon electrode (GCE) was constructed and characterized coupled with Cyclic Voltammogram (CV) and Differential Pulse Voltammogram (DPV) techniques. The mercapto group-linked probe DNA was covalently immobilized onto the CdS layer and exposed to oligonucleotide (ODN) target for hybridization. The structure of DNA sensor was characterized by X-ray diffraction (XRD), field-emission microscopy (FESEM) and X-ray photoelectron spectra (XPS). Sensitive electrical readout achieved by CV and DPV techniques shown that when the target DNA hybridized with probe CdS-ODN conjugates and the double helix formed on the modified electrode, a significant increased response was observed comparing with the bare electrodes. The selectivity of the sensor was tested using a series of matched and certain-point mismatched sequences with concentration grads ranging from 10(-6) microM to 10(1) microM. The signal was in good linear with the minus logarithm of target oligonucleotide concentration with detection limit <1 pM and the optimized target DNA concentration was 10(-6) microM for the signal amplification. Due to great surface properties, the additional negative charges and space resistance of as-prepared CdS nanoparticles, the sensor was able to robustly discriminate the DNA hybridization responses with good sensitivity and stability.     

A simple colorimetric DNA detection by target-induced hybridization chain reaction for isothermal signal amplification

A novel DNA detection method is presented based on a gold nanoparticle (AuNP) colorimetric assay and hybridization chain reaction (HCR). In this method, target DNA hybridized with probe DNA modified on AuNP, and triggered HCR. The resulting HCR products with a large number of negative charges significantly enhanced the stability of AuNPs, inhibiting aggregation of AuNPs at an elevated salt concentration. The approach was highly sensitive and selective. Using this enzyme-free and isothermal signal amplification method, we were able to detect target DNA at concentrations as low as 0.5 nM with the naked eye. Our method also has great potential for detecting other analytes, such as metal ions, proteins, and small molecules, if the target analytes could make HCR products attach to AuNPs.