Detection of mismatched DNA on partially negatively charged diamond surfaces by optical and potentiometric methods

The effects of surface charge density on DNA hybridization have been investigated on a mixture of hydrogen-, oxygen-, and amine-terminated diamond surfaces. A difference in the hybridization efficiencies of complementary and mismatched DNA was clearly observed by fluorescence and potentiometric observations at a particular coverage of oxygen. In the fluorescence observation, singly mismatched DNA was detected with high contrast after appropriate hybridization on the surface with 10-20% oxygen coverage. The amount of oxygen in the form of C-O(-) (deprotonated C-OH) producing the surface negative-charge density was estimated by X-ray photoelectron spectroscopy. Electrolyte solution gate field-effect transistors (SGFETs) were used for potentiometric observations. The signal difference (change in gate potential) on the SGFET, which was as large as approximately 20 mV, was caused by the difference in the hybridization efficiencies of complementary target DNA (cDNA) and singly mismatched (1MM) target DNA with a common probe DNA immobilized on the same SGFET. The reversible change in gate potential caused by the hybridization and denaturation cycles and discriminating between the complementary and 1MM DNA targets was very stable throughout the cyclical detections. Moreover, the ratio of signals caused by hybridization of the cDNA and 1MM DNA targets with the probe DNA immobilized on the SGFET was determined to be 3:1 when hybridization had occurred (after 15 min on SGFET), as determined by real-time measurements. From the viewpoint of hybridization kinetics, the rate constant for hybridization of singly mismatched DNA was a factor of approximately 3 smaller than that of cDNA on this functionalized (oxidized and aminated) diamond surface.     

Electrochemical impedance sensing of DNA hybridization on conducting polymer film-modified diamond

The impedimetric sensing of DNA hybridization on polyaniline/polyacrylate (PANI/PAA)-modified boron-doped diamond (BDD) electrode has been investigated. An ultrathin film of PANI-PAA copolymer was electropolymerized onto the diamond surfaces to provide carboxylic groups for tethering to DNA sensing probes. The electrochemical impedance and the intrinsic electroactivity of the polymer-diamond interface were analyzed after the hybridization reaction with target and non-target DNA. The impedance measurement shows changes in the impedance modulus as well as electron-transfer resistance at the stage of probe DNA immobilization (single-strand), as well as after hybridization with target DNA (double-strand). DNA hybridization increases the capacitance of the polymer-DNA layer and reduces the overall impedance of the DNA-polymer-diamond stack significantly. The polymer-modified BDD electrode shows no detectable nonspecific adsorption, with good selectivity between the complementary DNA targets and the one-base mismatch targets. The detection limit was measured to be 2 x 10(-8) M at 1000 Hz. Denaturing test on the hybridized probe and subsequent reuse of the probe indicates chemical robustness of the sensor. Our results suggest that electropolymerization followed by the immobilization of biomolecules is a simple and effective way of creating a functional biomolecular scaffold on the diamond surface. In addition, label-free electrochemical impedance method can provide direct and noninvasive sensing of DNA hybridization on BDD.     

微囊藻属DNA电化学传感器的研制

利用自组装法将巯基修饰的DNA探针与6-巯基-1-己醇(MCH)固定到金电极表面,制备了微囊藻属特定DNA传感器,将该传感器与完全互补的微囊藻DNA序列、完全不互补序列,以及单碱基错配序列进行杂交,以Hoechst 33258为杂交指示剂,应用循环伏安法和线性扫描伏安法研究了该传感器对目标DNA的电化学检测行为.研究表明,当与完全互补DNA杂交后,Hoechst 33258氧化信号有明显的增强.实验对自组装时间、MCH浸泡时间及杂交液离子浓度进行了优化.结果表明,当自组装时间为90 min,MCH浸泡时间为1 h,杂交溶液中NaCl浓度为0.3 mol/L时,电化学信号最好.目标DNA的氧化峰电流值与其浓度在1×10~(-8) ～1×10~(-6) mol/L范围内呈良好的线性关系,检出限为8.1×10~(-9) mol/L.     

Label-free detection of DNA molecules on the dendron based self-assembled monolayer by electrochemical impedance spectroscopy

We report preparation of a novel platform for effective DNA hybridization and its application to the detection of single mismatched DNA. Cone-shaped dendrimer molecules have been immobilized on the gold surface at equidistance, 3.1 nm, from each other with a probe DNA molecule attached to the top of each dendrimer so that enough space would be secured for effective hybridization. This arrangement allows each probe DNA molecule to form a natural DNA double helix upon hybridization with a target DNA molecule. The single nucleotide polymorphism at either the central or end position of the 25-mer target DNA has been shown to be effectively discriminated against on this platform from each other as well as from a complementary DNA by electrochemical impedance measurements. We also report adverse effects exerted by probe ions, Fe(CN)₆^3−/4−, on DNA hybridization reactions. The significance of the results for the use in DNA analysis is discussed.     

Chemiluminescent detection of DNA hybridization and single-nucleotide polymorphisms on a solid surface using target-primed rolling circle amplification

A new chemiluminescent (CL) method has been developed for the sensitive detection of DNA hybridization and single-nucleotide polymorphisms (SNPs) with target-primed rolling circle amplification (RCA). The capture oligonucleotide probe is firstly immobilized on a polystyrene well plate and then hybridized with the wild DNA target. A designed padlock probe is circularized after perfect hybridization to the DNA target. Then the RCA reaction can be initiated from the DNA target that acts as a primer and generates a long tandem single-strand of DNA with repeat sequences. In contrast, the mutant DNA target, which contains a mismatched base with the padlock probe, cannot initiate the RCA reaction and primes only a limited extension with the unligated padlock probe. Afterwards, a biotinylated oligonucleotide is used to hybridize with the RCA product in each repeat sequence and streptavidin-alkaline phosphatase (STV-AP) is employed to combine the anchored biotin. The DNA target is detected with the CL reaction of STV-AP and 3-(2'-spiroadamantane)-4-methoxy-4-(3'-phosphoryloxy)phenyl-1,2-dioxetane (AMPPD). With the RCA-based method, the sensitivity of DNA detection can be increased by about two orders of magnitude compared with that of direct DNA hybridization. A DNA target as low as 3.6 pM can be detected. Wild-type DNA and the one-base mutant DNA can be differentiated with high selectivity through this RCA reaction.     

One Mismatch Detection of DNA Hybridization Using Fluorescence Polarization

Abstract

The potential of fluorescent polarization analysis as a method for detection of mismatch DNA hybridization was investigated. The dependency of DNA hybridization rate on salt concentration was surveyed. In greater than 0.1 M NaCl, the hybridization of probe and target DNA proceeds rapidly and the reaction is complete within 3 min. Furthermore, the hybridization of probe DNA and one mismatch target DNAs was investigated. It was successfully shown that even one mismatch could be detected using fluorescence polarization analysis if the mismatch position was on the base that pairs with the probe DNA at the 5′ terminus where fluorescein isothiocyanate (FITC) is attached.     

Fast and sensitive DNA analysis using changes in the FRET signals of molecular beacons in a PDMS microfluidic channel

A new DNA hybridization analytical method using a microfluidic channel and a molecular beacon-based probe (MB-probe) is described. A stem-loop DNA oligonucleotide labeled with two fluorophores at the 5′ and 3′ termini (a donor dye, TET, and an acceptor dye, TAMRA, respectively) was used to carry out a fast and sensitive DNA analysis. The MB-probe utilized the specificity and selectivity of the DNA hairpin-type probe DNA to detect a specific target DNA of interest. The quenching of the fluorescence resonance energy transfer (FRET) signal between the two fluorophores, caused by the sequence-specific hybridization of the MB-probe and the target DNA, was used to detect a DNA hybridization reaction in a poly(dimethylsiloxane) (PDMS) microfluidic channel. The azoospermia gene, DYS 209, was used as the target DNA to demonstrate the applicability of the method. A simple syringe pumping system was used for quick and accurate analysis. The laminar flow along the channel could be easily controlled by the 3-D channel structure and flow speed. By injecting the MB-probe and target DNA solutions into a zigzag-shaped PDMS microfluidic channel, it was possible to detect their sequence-specific hybridization. Surface-enhanced Raman spectroscopy (SERS) was also used to provide complementary evidence of the DNA hybridization. Our data show that this technique is a promising real-time detection method for label-free DNA targets in the solution phase. Figure FRET-based DNA hybridization detection using a molecular beacon in a zigzag-shaped PDMS microfluidic channel     

DNA hybridization in reverse micelles and its application to mutation detection

DNA hybridization was investigated in AOT (sodium di-2-ethylhexyl sulfosuccinate)/isooctane reverse micelles. The single-stranded DNA molecules were encapsulated in the nanoscale water pools formed in the reverse micelles, reducing the hybridization rate. The DNA hybridization can be monitored by simply measuring the UV absorbance of the reverse micellar solution at 260 nm. We found that the DNA hybridization occurred only at the restricted water content (Wo = [H2O]/[AOT] = 20) and below room temperature. We applied this DNA hybridization behavior in reverse micelles to mutation detection in a model gene p53 and successfully detected the single nucleotide mutations in 20-mer. 30-mer and 50-mer nucleotides without a DNA labeling.     

Use of peptide nucleic acid probes for detecting DNA single-base mutations by capillary electrophoresis

Peptide nucleic acid (PNA) oligomers can be used as probes in pre-gel hybridization experiments, as an alternative to Southern hybridization. In this technique, the PNA probe is hybridized to a cyanine-5 labeled DNA sample denatured at low ionic strength, and the mixture is directly injected for size separation into a capillary electrophoresis (CE) system equipped with laser-induced fluorescence (LIF) detector. The neutral backbone of PNA allows hybridization to occur at low ionic strength and assures an efficient CE separation of the PNA/DNA hybrids from both double-stranded and single-stranded DNA. We have used as a model system the cystic fibrosis R553X and R1162X single-base mutations and we have assessed the influence of various factors, such as temperature and denaturants concentration on DNA/PNA hybrid stability in order to achieve the high specificity required for a single base pair discrimination.     

A novel electrochemical biosensor based on dynamic polymerase-extending hybridization for E. coli O157:H7 DNA detection

A novel biosensor based on single-stranded DNA (ssDNA) probe functionalized aluminum anodized oxide (AAO) nanopore membranes was demonstrated for Escherichia coli O157:H7 DNA detection. An original and dynamic polymerase-extending (PE) DNA hybridization procedure is proposed, where hybridization happens in the existence of Taq DNA polymerase and dNTPs under controlled reaction temperature. The probe strand would be extended as long as the target DNA strand, then the capability to block the ionic flow in the pores has been prominently enhanced by the double strand complex. We have investigated the variation of ionic conductivity during the fabrication of the film and the hybridization using cyclic voltammetry and impedance spectroscopy. The present approach provides low detection limit for DNA (a few hundreds of pmol), rapid label-free and easy-to-use bacteria detection, which holds the potential for future use in various ss-DNA analyses by integrated into a self-contained biochip.     

Electrochemical enzyme-linked immunoassay in a DNA hybridization sensor

In most of the currently developed electrochemical DNA hybridization sensors short single-stranded probe DNA is immobilized on an electrode and both the hybridization and detection steps are carried out on the electrode surface. Here we use a new technology in which DNA hybridization is performed on commercially available magnetic beads and detection on solid electrodes. Paramagnetic Dynabeads Oligo(dT)₂₅ (DBT) with covalently bound (dT)₂₅ probe are used for the hybridization with target DNA containing adenine stretches. Target DNA is modified with osmium tetroxide,2,2′-bipyridine (Os,bipy) and the immunogenic DNA-Os,bipy adduct is determined by the enzyme-linked immunoassay with electrochemical detection. Electroinactive 1-naphthyl phosphate is used as a substrate and the electroactive product (1-naphthol) is measured on the carbon electrodes. Alternatively Os,bipy-modified target DNA can be determined directly by measuring the osmium signal on the pyrolytic graphite electrode (PGE). A comparison between determinations of the 67-mer oligodeoxynucleotide on carbon electrodes using (a) the guanine oxidation signal, (b) direct determination of the DNA-Os,bipy adduct and (c) its electrochemical immunoassay showed immunoassay to be the most sensitive method. In combination with DBT, the DNA hybridization of long target deoxyoligonucleotides (such as 67- and 97-mers) and a DNA PCR product (226-base pairs) have been detected by immunoassay at high sensitivity and specificity.     

Rapid screening of phenylketonuria using a CD microfluidic device

We herein present a compact disc (CD) microfluidic chip based hybridization assay for phenylketonuria (PKU) screening. This CD chip is composed of a polydimethylsiloxane (PDMS) top layer containing 12 DNA hybridization microchannels, and a glass bottom layer with hydrogel pad conjugated DNA oligonucleotides. Reciprocating flow was generated on the CD chip through a simple rotation-pause operation to facilitate rapid DNA hybridization. When rotated the CD chip, the sample solution was driven into the hybridization channel by centrifugal force. When stopped the CD chip, the sample plug was pulled backward through the channel by capillary force. The hybridization assay was firstly validated with control samples and was then used to analyze 30 clinical samples from pregnant women with suspected PKU fetus. The on-chip DNA hybridization was completed in 15 min with a sample consumption as low as 1.5μL, and the limit-of-detection (LOD) of DNA template was 0.7ng/μL. Among the 30 samples tested, V245V mutation was identified in 4 cases while R243Q mutation was detected in one case. Results of the hybridization assay were confirmed by DNA sequencing. This CD-chip based hybridization assay features short analysis time, simple operation and low cost, thus has the potential to serve as the tool for PKU screening.     

DNA hybridization enhancement using piezoelectric microagitation through a liquid coupling medium

In conventional DNA microarray hybridization, delivery of target cDNAs to surface-bounded probes depends solely on diffusion, which is notoriously slow, and thus typically requires 6-20 h to complete. In this study, piezoelectric microagitation through a liquid coupling medium is employed to enhance DNA hybridization efficiency and the results are compared with the standard static hybridization method. DNA hybridization was performed in a sealed aluminium chamber containing DNA microarray glass chip, coupling medium and piezoelectric transducers. 3×SSC (Saline Sodium Citrate) was used as a coupling medium to prevent overheating of the piezoelectric transducers and to effectively transmit ultrasonic wave to the glass chip. Flow visualization using fluidic dye and velocimetry (PTV) technique was applied to observe fluid transport in the hybridization chamber. It was revealed that the dye solution was homogeneously distributed within 10 min under dynamic agitation while it took over 1 h to reach the same level of homogeneity in static condition. Plasmodium falciparum DNA microarrays and total RNA extracted from parasite cells were used as a model for DNA microarray experiments. It was found that the required hybridization time may be substantially reduced from 16 h to 4 h by the use of dynamic hybridization scheme. With the same hybridization time of 16 h, dynamic hybridization resulted in higher fluorescent signals of ～33% and ～24% compared to static hybridization in Cy3 and Cy5 channels, respectively. Additionally, good/effective spots, some of which were not formed by static method, were enhanced and distributed more uniformly over the microarray. Therefore, the developed dynamic hybridization with integrated piezoelectric microagitation platform is highly promising for DNA analysis in molecular biology and medical applications.     

Electrochemical DNA Sensing at Single‐walled Carbon Nanotubes Chemically Assembled on Gold Surfaces

An electrochemical DNA sensor was constructed using single‐walled carbon nanotubes (SWNTs) attached to a self‐assembled monolayer of 11‐amino‐1‐undecanethiol on a gold surface. The voltammetric peak of methylene blue (MB), which interacts with the DNA guanine bases specifically, was used to follow the DNA hybridization process. After DNA hybridization with its complementary DNA strand, the MB electrochemical signal response decreased and the change in MB signal response was used as the basis for the electrochemical sensing of DNA hybridization. The as described DNA sensor demonstrated to have good stability, selectivity, a linear response over the DNA concentration range from 100 to 1,000 nM and a limit of detection of 7.24 nM.     

Microelectronic array devices and techniques for electric field enhanced DNA hybridization in low-conductance buffers

A variety of electronic DNA array devices and techniques have been developed that allow electric field enhanced hybridization to be carried out under special low-conductance conditions. These devices include both planar microelectronic DNA array/chip devices as well as electronic microtiter plate-like devices. Such "active" electronic devices are able to provide controlled electric (electrophoretic) fields that serve as a driving force to move and concentrate nucleic acid molecules (DNA/RNA) to selected microlocation test-sites on the device. In addition to ionic strength, pH, temperature and other agents, the electric field provides another controllable parameter that can affect and enhance DNA hybridization. With regard to the planar microelectronic array devices, special low-conductance buffers were developed in order to maintain rapid transport of DNA molecules and to facilitate hybridization within the constrained low current and voltage ranges for this type of device. With regard to electronic microtiter plate type devices (which do not have the low current/voltage constraints), the use of mixed buffers (low conductance upper chamber/high conductance lower chamber) can be used in a unique fashion to create favorable hybridization conditions in a microzone within the test site location. Both types of devices allow DNA molecules to be rapidly and selectively hybridized at the array test sites under conditions where the DNA in the bulk solution can remain substantially denatured.     

Thiazole orange and Cy3: improvement of fluorescent DNA probes with use of short range electron transfer

Thiazole orange was synthetically incorporated into oligonucleotides by using the corresponding phosphoramidite as the building block for automated DNA synthesis. Due to the covalent fixation of the TO dye as a DNA base surrogate, the TO-modified oligonucleotides do not exhibit a significant increase of fluorescence upon hybridization with the counterstrand. However, if 5-nitroindole (NI) is present as a second artificial DNA base (two base pairs away from the TO dye) a fluorescence increase upon DNA hybridization can be observed. That suggests that a short-range photoinduced electron transfer causes the fluorescence quenching in the single strand. The latter result represents a concept that can be transferred to the commercially available Cy3 label. It enables the Cy3 fluorophore to display the DNA hybridization by a fluorescence increase that is normally not observed with this dye.     

Biocompatible core-shell nanoparticle-based surface-enhanced Raman scattering probes for detection of DNA related to HIV gene using silica-coated magnetic nanoparticles as separation tools

A novel, highly selective DNA hybridization assay has been developed based on surface-enhanced Raman scattering (SERS) for DNA sequences related to HIV. This strategy employs the Ag/SiO₂ core-shell nanoparticle-based Raman tags and the amino group modified silica-coated magnetic nanoparticles as immobilization matrix and separation tool. The hybridization reaction was performed between Raman tags functionalized with 3′-amino-labeled oligonucleotides as detection probes and the amino group modified silica-coated magnetic nanoparticles functionalized with 5′-amino-labeled oligonucleotides as capture probes. The Raman spectra of Raman tags can be used to monitor the presence of target oligonucleotides. The utilization of silica-coated magnetic nanoparticles not only avoided time-consuming washing, but also amplified the signal of hybridization assay. Additionally, the results of control experiments show that no or very low signal would be obtained if the hybridization assay is conducted in the presence of DNA sequences other than complementary oligonucleotides related to HIV gene such as non-complementary oligonucleotides, four bases mismatch oligonucleotides, two bases mismatch oligonucleotides and even single base mismatch oligonucleotides. It was demonstrated that the method developed in this work has high selectivity and sensitivity for DNA detection related to HIV gene.     

Electrochemical Quantitative Analysis of Nucleic Acids Using β‐Cyclodextrin Modified Gold Electrode

We present an electrochemical biosensor for the analysis of nucleic acids upon hybridization on the β‐cyclodextrin (β‐CD)‐modified gold electrode. The strategy is based on the following: The 5’‐ferrocene‐labeled single stranded capture probe DNA (5’‐fc‐ss‐DNA) was incorporated into the cavity of thiolated β‐CD which was immobilized on the surface of gold electrode. After hybridization of complementary target DNA, hybridized double stranded DNA (ds‐DNA) was released from the cavity of β‐CD. The difference of electrochemical properties on the modified gold electrode was characterized by cyclic voltametry and surface plasmon resonance. We successfully applied this method to the investigation of the sensor responses due to hybridization on various concentrations of applied target DNA. As a result, the label‐free electrochemical DNA sensor can detect the target DNA with a detection limit of 1.08 nM. Finally, our method does not require either hybridization indicators or other signalling molecules such as DNA intercalaters which most of electrochemical hybridization detection systems require.     

DNA hybridization at microbeads with cathodic stripping voltammetric detection

In electrochemical DNA hybridization sensors generally a single-stranded probe DNA was immobilized at the electrode followed by hybridization with the target DNA and electrochemical detection of the hybridization event at the same electrode. In this type of experiments nonspecific adsorption of DNA at the electrode caused serious difficulties especially in the case of the analysis of long target DNAs. We propose a new technology in which DNA is hybridized at a surface H and the hybridization is detected at the detection electrode (DE). This technology significantly extends the choice of hybridization surfaces and DEs. Here we use paramagnetic Dynabeads Oligo(dT)(25) (DBT) as a transportable reactive surface H and a hanging mercury drop electrode as DE. We describe a label-free detection of DNA and RNA (selectively captured at DBT) based on the determination of adenines (at ppb levels, by cathodic stripping voltammetry) released from the nucleic acids by acid treatment. The DNA and RNA nonspecific adsorption at DBT is negligible, making thus possible to detect the hybridization event with a great specificity and sensitivity. Specific detection of the hybridization of polyribonucleotides, mRNA, oligodeoxynucleotides, and a DNA PCR product (226 base pairs) is demonstrated. New possibilities in the development of the DNA hybridization sensors opened by the proposed technology, including utilization of catalytic signals in nucleic acid determination at mercury (e.g. signals of osmium complexes covalently bound to DNA) and solid DEs (e.g. using enzyme-labeled antibodies against chemically modified DNAs) are discussed.     

Rapid hybridization at high salt concentration and detection of bacterial DNA using fluorescence polarization

The effects of NaCl concentration and temperature on the rate of hybridization of complementary single-stranded DNA (24-mers) were investigated. The single label of fluorescein was used for the probe DNA. The time courses of fluorescence polarization for the probe DNA were monitored. It was shown that detection of a specific DNA sequence (24-mer) was possible in less than 10 min using fluorescence polarization under the optimized conditions of 0.8 M NaCl at 46 degrees C in TE buffer. The effects of base-pair mismatches on DNA hybridization in the presence of NaCl or MgCl(2) were also investigated, and the specificity was considered by comparing the hybridization rate of the fluorescein-labeled probe. Determination of a specific DNA sequence was also possible in TE buffer containing 0.2 M MgCl(2). Moreover, in the presence of 0.2 M MgCl(2), there were no undesirable effects on hybridization and the presence of a single base pair mismatch could be identified. Rapid and specific determination of the DNA of enterohemorrhagic Escherichia coli, methicillin resistant Staphylococcus aureus and Legionella pneumophila, which had been multiplied by the asymmetric PCR, was performed under the optimized conditions for hybridization. It was confirmed that the conditions were also applicable to the hybridization between the probes and the amplified products of the actual bacterial genes. The combination of fluorescence polarization with the asymmetric PCR was quite effective. Moreover, the nested and asymmetric PCR product of bacterial gene could be detected effectively. The DNA detection method could also be used even if the specificity of the DNA amplification was not perfect and some unexpected bands were mixed with the target band during electrophoresis.