Electrochemical detection of a Vibrio parahaemolyticus sequence-specific gene based on a gold electrode modified with a single stranded probe

An electrochemical DNA biosensor for specific-sequences detection of Vibrio parahaemolyticus (VP) was fabricated. A single-stranded 20-mer oligonucleotide (ssDNA) and 6-mercapto-1-hexanol (MCH) were immobilized via a thiol linker on gold disk electrodes by self-assembling. The ssDNA underwent hybridization in a hybridization solution containing complementary or non-complementary or single base pair mismatched DNA sequences of VP. Examination of changes in response to these three target DNAs showed that the developed biosensor had a high selectivity and sensitivity.     

DNA Terminal Mismatch‐Induced Stabilization of Polymer Micelles from RAFT‐Generated Poly(N‐isopropylacrylamide)‐DNA Block Copolymers

Temperature‐responsive diblock copolymers made of poly(N‐isopropylacrylamide) (PNIPAAm) generated by reversible addition‐fragmentation chain transfer (RAFT) polymerization and a single‐stranded DNA (ssDNA) self‐assembled into polymer micelles. The micelles consisted of the PNIPAAm core surrounded by the ssDNA corona with a hydrodynamic diameter up to 300 nm in an aqueous medium above the lower critical solution temperature. In a medium of high ionic strength, the formation of the fully matched duplex with the complementary ssDNA on the surface of the polymer micelles induced rapid and spontaneous aggregation. By contrast, the micelles remained dispersed under the identical conditions when single‐base‐substituted ssDNA was added to form the corresponding terminal‐mismatched duplex on the micellar surface. This highly sequence‐selective process took place irrespective of the size of the PNIPAAm core.     

Alteration of the selectivity of hybridization of immobilized oligonucleotide probes by co-immobilization with charged oligomers of ethylene glycol

A significant challenge exists in the creation of an environment for immobilized probe oligonucleotides that offer good structural regularity and reproducibility, where nearest neighbour interactions provide for control of selectivity, yet where the degree of hybridization does not alter nearest neighbour interactions. This new work explores whether a “matrix isolation” method will produce the desired environment for the probe molecules. The DNA oligonucleotide probes are polyelectrolytes with charged backbones and significant flexibility. It is possible to isolate the probe molecules by surrounding each, on average, with a sheath of immobilized oligomer that is not based on complementary nucleic acid, yet that is a polyelectrolyte in order to control the surface density and charge within the mixed film. Preliminary work investigates a mixture of dT₂₀ as the probe oligonucleotide, and a 20-mer oligomer primarily containing ethylene glycol phosphate, as a matrix isolation material in a 1:20 mole ratio, respectively. Melt temperature (T_m) measurements indicate that the thermodynamic stability of the probe molecules can be adjusted using the oligomer matrix to achieve lower T_m values by up to 5 °C, with full retention of selectivity for discrimination of single base pair mismatches even under conditions where the probes at a surface are saturated with complementary target.     

Recognition of single-base mismatch DNA by Au nanoparticle-assisted electroelution

A simple, convenient and effective method based on the surface plasmon resonance (SPR) technique was introduced for recognition of single-base mismatch DNA (smDNA) by Au nanoparticle (AuNPs)-assisted electroelution. In this method, target DNA, including perfectly matched DNA and smDNA, hybridized with the DNA probes immobilized on Au film and AuNPs, then the Au film was negatively charged. Owing to the difference in stability between single-base mismatch and perfect match DNA, effective distinction between complementary DNA (cDNA) and smDNA was achieved in the presence of an electric field: double-stranded DNA (dsDNA) formed between smDNA targets and DNA probes was denatured by the repulsion force acting on the negatively-charged DNA-linked AuNPs, while the perfectly matched duplex was not influenced. However, if the AuNPs were absent, the effects of cDNA and smDNA were not distinguishable. The effects of electric field intensity and mismatch sites were also investigated. All of the operations were performed under mild conditions. The results showed that AuNP-assisted electroelution may be exploited for the construction of biosensors with high selectivity.     

PNA for one-base differentiating protection of DNA from nuclease and its use for SNPs detection

By the combination of peptide nucleic acid (PNA) with single-stranded DNA specific nucleases, alteration of a single base to another in DNA has been detected with high accuracy. Only the DNAs in DNA/PNA duplexes involving a mismatch are efficiently hydrolyzed by these enzymes, whereas fully matching sequences are kept intact. This difference is visually scored by adding 3,3'-diethylthiadicarbocyanine, which changes its color from blue to purple upon binding to DNA/PNA duplexes. These findings are applied to the convenient and straightforward detection of single nucleotide polymorphisms (SNPs). When the target site in the sample DNA is completely complementary with the PNA, a notable amount of DNA/PNA duplex remains and thus the solution exhibits purple color. In the presence of even one mismatch between PNA and DNA, however, the DNA is completely digested by the enzyme and therefore the dye shows its intrinsic blue color. The SNPs in the apolipoprotein E gene of human DNA have been successfully genotyped by this method.     

Electrochemical Determination of Label Free BRCA Hybridization by Single Use Antioxidant Modified Electrode

A novel DNA probe based on caffeic acid modified disposable pencil graphite electrodes were developed for the first time for the electrochemical determination of breast cancer gene sequence (BRCA) hybridization. Amino‐linked BRCA probe highly immobilized onto the caffeic acid modified electrode by means of the interaction between the amino group of BRCA probe and the carboxyl group of caffeic acid compared to the bare electrode. 44 % signal enhancement in guanine oxidation signal was measured by caffeic acid modified electrode. Besides, these probes exhibited high selectivity towards its complementary DNA sequences (target). Hybridization between probe and target (BRCA1) was studied to evaluate the selectivity of the probes for complementary, non‐complementary and mismatch sequences. The selectivity was also tested in the presence of mixture containing the target and one base mismatch BRCA sequences in the same ratio (1 : 1). It can be said this probe can select its complementary from the mixture.     

High Sensitive Electrochemical Detection of Sequence‐Specific DNA Using Low Current Voltammetry

In this article, we report on efforts to construct a high sensitive electrochemical sensor with immobilized sandwich‐type DNA borne ferrocene (Fc) head for sequence‐specific DNA detection using ultramicroelectrode and low current voltammetry. Based on the difference in deformability between the bending rigid complementary DNA double helix and its anomalous flexile mismatches, the fully complementary target can be distinguished from mismatched targets including the single‐base mismatched target. Detection limit estimated as the amount of DNA is observed to be 100 fM via low current voltammetry. The method offers great promise of high sensitivity and selectivity simultaneously for effective gene identification.     

Fluorescence resonance energy transfer (FRET) for DNA biosensors: FRET pairs and Förster distances for various dye-DNA conjugates

Fluorescence resonance energy transfer (FRET) between the extrinsic dye labels Cyanine 3 (Cy3), Cyanine 5 (Cy5), Carboxytetramethyl Rhodamine (TAMRA), Iowa Black Fluorescence Quencher (IabFQ), and Iowa Black RQ (IabRQ) has been studied. The F?rster distances for these FRET-pairs in single- and double-stranded DNA conjugates have been determined. In particular, it should be noted that the quantum yield of the donors Cy3 and TAMRA varies between single- and double-stranded DNA. While this alters the F?rster distance for a donor-acceptor pair, this also allows for detection of thermal denaturation events with a single non-intercalating fluorophore. The utility of FRET in the development of nucleic acid biosensor technology is illustrated by using TAMRA and IabRQ as a FRET pair in selectivity experiments. The differential quenching of TAMRA fluorescence by IabRQ in solution has been used to discriminate between 0 and 3 base pair mismatches at 60 degrees C for a 19 base sequence. At room temperature, the quenching of TAMRA fluorescence was not an effective indicator of the degree of base pair mismatch. There appears to be a threshold of duplex stability at room temperature which occurs beyond two base pair mismatches and reverses the observed trend in TAMRA fluorescence prior to that degree of mismatch. When this experimental system is transferred to a glass surface through covalent coupling and organosilane chemistry, the observed trend in TAMRA fluorescence at room temperature is similar to that obtained in bulk solution, but without a threshold of duplex stability. In addition to quenching of fluorescence by FRET, it is believed that several other quenching mechanisms are occurring at the surface.     

Reactivity of ferrocenylcarbodiimide with DNA duplex containing single-mismatched base pairs.

Ferrocenylcarbodiimide (1), which is known to react with a guanine (G) or thymine (T) base of single stranded DNA, was allowed to react with DNA duplex having a single mismatched base pair of G-T, T-T, or T-cytosine (C). Electrophoreograms of the reaction mixture showed that 1 could react with G or T base of the mismatched sites on the DNA duplex. However, 1 also reacted with the G base of the terminal site on the DNA duplex. This showed that 1 can react with an unpaired base or unstable base pair such as a terminal or mismatched base on the DNA duplex. Electrochemical mismatch detection could be achieved after hybridization of the ferrocenylated mismatched DNA duplex with a selected DNA probe-immobilized electrode. These results revealed that 1 has a potentiality of serving as a labeling reagent of mismatched bases on the DNA duplex, which is important in the search for heterozygous single nucleotide polymorphisms (SNPs).     

A spatially resolved nucleic acid biochip based on a gradient of density of immobilized probe oligonucleotide

The potential for a new biochip design based on a continuous gradient of density of immobilized single-stranded DNA oligonucleotide probes (ssDNA) is explored. This gradient resolved information platform (GRIP) can provide sequence identification based on the spatial location and extent of hybridization by a target sequence. Surfaces based on indium-tin oxide (ITO) on glass were first functionalized by 3-aminopropyltriethoxysilane (APTES) followed by attachment of glutaraldehyde, prior to immobilization of oligonucleotide probe that was terminated with amine. The use of Cy₃ and Cy₅ dye-labelled ssDNA probes and targets allowed estimation of density and correlation of the location of binding of labelled targets. Probe molecules of 20 mer lengths were loaded to produce density gradients in the range of 1.0-200 ng/mm². The biochips could resolve a mixture of fully complementary five base-pair mismatched targets by the location of binding on the surface. Thermal control provided additional selectivity. Thermal cycling and washing provided for regeneration of the surface, and the fluorescence intensities showed no deterioration in at least five cycles of hybridization reactions.     

Analysis of mismatched DNA by mismatch binding ligand (MBL)–Sepharose affinity chromatography

Mismatch binding molecules (MBLs), strongly and selectively bound to the mismatched base pair in duplex DNA, were immobilized on Sepharose. Three MBL–Sepharose columns were prepared with three MBLs, naphthyridine dimer (ND), naphthyridine–azaquinolone (NA), and aminonaphthyridine dimer (amND), which exhibited different binding profiles to the mismatched base pairs. These three MBL–Sepharose columns showed characteristic elution profiles for DNA duplexes containing mismatched base pairs. The ND–Sepharose column separated the G–G and G–A mismatched DNA from fully matched duplexes. The NA–Sepharose column separated the A–A and G–A mismatched DNA from other DNA duplexes. The amND–Sepharose column separated the C–C mismatched DNA. These chromatographic profiles were very consistent with the binding preference of each MBL. By changing the elution conditions from sodium hydroxide to sodium chloride, MBL–Sepharose columns were also able to separate the mismatched DNA that weakly bound to the MBL from fully matched DNA duplex. Figure MBL-Sepharose affinity chromatography successfully separates the mismatched duplex DNA from fully matched duplex.     

A low-cost surface plasmon resonance instrument based on detection of resonance excitation wavelength

A laboratory-made surface plasmon resonance (SPR) instrument based on the detection of resonance excitation wavelength has been successfully fabricated. The performance and workability of the SPR instrument was demonstrated as a DNA biosensor. Biotinylated single-stranded oligonucleotides (ssDNA) were chemically immobilized on a gold-film surface of the SPR instrument as a DNA probe for the detection of its fully complementary, half-complementary and non-complementary ssDNA. The immobilization of the ssDNA probe was done by avidin-biotin linkage. The ssDNA used were 12-mer oligonucleotides. The sensing mechanism was based on the shift in resonance wavelength of an excitation light beam as the target ssDNA hybridized with the ssDNA on the gold-film surface. The linear dynamic ranges of the DNA biosensor for fully complementary and half-complementary ssDNA are 0.04-1.2 pM and 0.08-1.1 pM, respectively. The DNA biosensor showed higher sensitivity to fully complementary ssDNA than to half-complementary ssDNA. But no shift of resonance wavelength to the non-complementary ssDNA was observed.     

The SPR sensor detecting cytosine[bond]cytosine mismatches

We have synthesized the first surface plasmon resonance (SPR) sensor that detects cytosine-cytosine (C[bond]C) mismatches in duplex DNA by immobilizing aminonaphthyridine dimer on the gold surface. The ligand consisting of two 2-aminonaphthyridine chromophores and an alkyl linker connecting them strongly stabilized the C[bond]C mismatches regardless of the flanking sequences. The fully matched duplexes were not stabilized at all under the same conditions. The C[bond]T, C[bond]A, and T[bond]T mismatches were also stabilized with a reduced efficiency. SPR analyses of mismatch-containing 27-mer duplexes were performed with the sensor surface on which the aminonaphthyridine dimer was immobilized. The response for the C[bond]C mismatch in 5'-GCC-3'/3'-CCG-5' was about 83 times stronger than that obtained for the fully matched duplex. The sensor successfully detects the C[bond]C mismatch at the concentration of 10 nM. SPR responses are proportional to the concentration of the C[bond]C mismatch in a range up to 200 nM. Aminonaphthyridine dimer could bind strongly to the C[bond]C mismatches having 10 possible flanking sequences with association constants in the order of 10(6) M(-1). The facile protonation of 2-aminonaphthyridine chromophore at pH 7 producing the hydrogen-bonding surface complementary to that of cytosine was most likely due to the remarkably high selectivity of 1 to the C[bond]C mismatch.     

Modulation of pyrene fluorescence in DNA probes depends upon the nature of the conformationally restricted nucleotide

The DNA probes (ODNs) containing a 2'-N-(pyren-1-yl)-group on the conformationally locked nucleosides [2'-N-(pyren-1-yl)carbonyl-azetidine thymidine, Aze-pyr (X), and 2'-N-(pyren-1-yl)carbonyl-aza-ENA thymidine, Aza-ENA-pyr (Y)], show that they can bind to complementary RNA more strongly than to the DNA. The Aze-pyr (X) containing ODNs with the complementary DNA and RNA duplexes showed an increase in the fluorescence intensity (measured at lambda em approximately 376 nm) depending upon the nearest neighbor at the 3'-end to X [dA ( approximately 12-20-fold) > dG ( approximately 9-20-fold) > dT ( approximately 2.5-20-fold) > dC ( approximately 6-13-fold)]. They give high fluorescence quantum yields (Phi F = 0.13-0.89) as compared to those of the single-stranded ODNs. The Aza-ENA-pyr (Y)-modified ODNs, on the other hand, showed an enhancement of the fluorescence intensity only with the complementary DNA (1.4-3.9-fold, Phi F = 0.16-0.47); a very small increase in fluorescence is also observed with the complementary RNA (1.1-1.7-fold, Phi F = 0.17-0.22), depending both upon the site of the Y modification introduced as well as on the chemical nature of the nucleobase adjacent to the modification site into the ODN. The fluorescence properties, thermal denaturation experiments, absorption, and circular dichroism (CD) studies with the X- and Y-modified ODNs in the form of matched homo- and heteroduplexes consistently suggested (i) that the orientation of the pyrene moiety is outside the helix of the nucleic acid duplexes containing a dT-d/rA base pair at the 3'-end of the modification site for both X and Y types of modifications, and (ii) that the microenvironment around the pyrene moiety in the ODN/DNA and ODN/RNA duplexes is dictated by the chemical nature of the conformational constraint in the sugar moiety, as well as by the nature of neighboring nucleobases. The pyrene fluorescence emission in both X and Y types of the conformationally restricted nucleotides is found to be sensitive to a mismatched base present in the target RNA: (i) The X-modified ODN showed a decrease ( approximately 37-fold) in the fluorescence intensity (measured at lambda em approximately 376 nm) upon duplex formation with RNA containing a G nucleobase mismatch (dT-rG pair instead of dT-rA) opposite to the modification site. (ii) In contrast, the Y-modified ODN in the heteroduplex resulted in a approximately 3-fold increase in the fluorescence intensity upon dT-rG mismatch, instead of matched dT-rA pair, in the RNA strand. Our data corroborate that the pyrene moiety is intercalated in the X-modified mismatched ODN/RNA (G mismatch) heteroduplex as compared to that of the Y-modified ODN/RNA (G mismatch) heteroduplex, in which it is located outside the helix.     

Nucleic acid detection using carbon nanoparticles as a fluorescent sensing platform

In this communication, we demonstrate for the first time the proof of concept that carbon nanoparticles (CNPs) can be used as an effective fluorescent sensing platform for nucleic acid detection with selectivity down to single-base mismatch. The dye-labeled single-stranded DNA (ssDNA) probe is adsorbed onto the surface of the CNP via π-π interaction, quenching the dye. In the target assay, a double-stranded DNA (dsDNA) hybrid forms, recovering dye fluorescence.     

寡聚酰胺为探针的电化学DNA生物传感器

DNA分子中的碱基对可以长程传递电荷, DNA分子中的碱基π堆积结构为电荷的长程传递提供了良好的通道. 电荷在DNA分子中的传递受碱基序列的影响, 利用这种性质可以构建DNA碱基错配检测的电化学传感器. 寡聚酰胺能和DNA以小沟绑定方式高亲和力地结合, 并且具有序列识别功能, 本文以带有硝基官能团的寡聚酰胺分子为电化学探针, 设计了电化学DNA生物传感器. 结果显示, 寡聚酰胺与DNA修饰电极作用后, 电化学响应显著增强, 并且可以作为检测DNA碱基错配的电化学探针分子.     

Nanocrystals modified with peptide nucleic acids (PNAs) for selective self-assembly and DNA detection

Gold nanocrystals modified with peptide nucleic acids (PNAs) have been prepared and applied to self-assembly and DNA sensing. Experiments with different PNA structural motifs show that (1). the versatility in PNA synthetic design can be used to modulate the electrostatic surface properties of nanocrystals, presenting an opportunity to control assembly rate and aggregate size, (2). short (6 base) PNAs can hybridize effectively while attached to nanoparticles, providing a route to generating materials with small interparticle spacings, and (3). the superior base pair mismatch selectivity of PNAs is further enhanced on nanosurfaces, enabling PNA-modified nanoparticles to act as highly selective nanoscale sensors, as well as synthons for defect-free self-assembly. This last feature was coupled with a substantial change in colloidal stability upon DNA hybridization to develop a novel colorimetric DNA assay that detects the presence of single base imperfections within minutes. Various modes of PNA hybridization, including the first practical application of PNA-PNA interactions, were used to direct the assembly of nanoparticles into macroscopic arrangements. Shorter duplex interconnects and greater specificity in assembly were obtained compared to similar experiments with DNA-modified nanocrystals.     

Coordination Polymer Nanobelts as an Effective Sensing Platform for Fluorescence‐enhanced Nucleic Acid Detection

In this communication, the application of coordination polymer nanobelts (CPNs) assembled from H₂PtCl₆ and 3,3′,5,5′‐tetramethylbenzidine (TMB) are explored as an effective fluorescent sensing platform for nucleic acid detection for the first time. The suggested method has a high selectivity down to single‐base mismatch. DNA detection is accomplished by the following two steps: (1) CPN binds fluorecent dye‐labeled single‐stranded DNA (ssDNA) probe via both electrostatic attraction and π‐π stacking interactions between unpaired DNA bases and CPN. As a result, the fluorescent dye is brought into close proximity to CPN and substantial fluorescence quenching occurs due to photoinduced electron transfer from the nitrogen atom in CPN to the excited fluorophore. (2) The hybridization of adsorbed ssDNA probe with its target generates a double stranded DNA (dsDNA). The duplex cannot be adsorbed by CPN due to its rigid conformation and the absence of unpaired DNA bases, leading to an obvious fluorescence enhancement.

     

Sensitive sequence-specific molecular identification system comprising an aluminum micro-nanofluidic chip and associated real-time confocal detector

A method for the development of continuous density gradients of immobilized oligonucleotide probes (20mer) along the length of microfluidic channels is demonstrated. The development of continuous density gradients was achieved using variable electrokinetic transport of probes in hybrid glass-polydimethylsiloxane microfluidic chips. The probes were terminated with an amine functional group, and were delivered by electrokinetic pumping to the flat glass channel wall after it had been densely coated with covalently immobilized aldehyde groups. This method provided probe immobilization densities ranging from 4.5(±0.8)×10(13) to 2.5(±0.8)×10(11) molecules cm(-2), with longitudinal dilution and differential mass transport of the injected plug of probes being the primary factors responsible for the gradient of density. The utility of the resulting density gradient of immobilized probes to control the selectivity of hybridization was demonstrated at room temperature by discrimination between a fully complementary oligonucleotide target, and a target strand containing 3 base pair mismatches (3 BPM) based on the spatial pattern of hybridization for sub-picomole quantities of targets. Single nucleotide polymorphism (SNP) discrimination was possible when temperature control was implemented to improve resolution of the mismatch discrimination, allowing SNP discrimination at 35 °C with a contrast ratio of almost 5 to 1.     

Tethered thiazole orange intercalating dye for development of fibre-optic nucleic acid biosensors

Single-stranded DNA (ssDNA) oligonucleotide in solution, or that is immobilized onto a surface to create a biosensor, can be used as a selective probe to bind to a complementary single-stranded sequence. Fluorescence enhancement of thiazole orange (TO) occurs when the dye intercalates into double-stranded DNA (dsDNA). TO dye has been covalently attached to probe oligonucleotides (homopolymer and mixed base 10mer and 20mer) through the 5′ terminal phosphate group using polyethylene glycol linker. The tethered TO dye was able to intercalate when dsDNA formed in solution, and also at fused silica surfaces using immobilized ssDNA. The results indicated the potential for development of a self-contained biosensor where the fluorescent label was available as part of the immobilized oligonucleotide probe chemistry. The approach was shown to be able to operate in a reversible manner for multiple cycles of detection of targeted DNA sequences.