Electronic transduction of DNA sensing processes on surfaces: amplification of DNA detection and analysis of single-base mismatches by tagged liposomes.

Tagged, negatively charged, liposomes are used to amplify DNA sensing processes. The analyses of the target DNA are transduced electrochemically by using Faradaic impedance spectroscopy, or by microgravimetric measurements with Au-quartz crystals. By one method, a probe oligonucleotide (1) is assembled on Au-electrodes or Au-quartz crystals. The formation of the double-stranded assembly with the analyte DNA (2) is amplified by the association of the 3-oligonucleotide-functionalized liposomes to the sensing interface. The target DNA is analyzed by this method with a sensitivity limit that corresponds to 1 x 10(-12) M. A second method to amplify the sensing of the analyte involves the interaction of the 1-functionalized electrode or Au-quartz crystal with the target DNA sample (2) that is pretreated with the biotinylated oligonucleotide (4). The formation of the three-component double-stranded assembly between 1/2/4 is amplified by the association of avidin and biotin-labeled liposomes to the sensing interfaces. By the secondary association of avidin and biotin-tagged liposomes, a dendritic-type amplification of the analysis of the DNA is accomplished. The analyte DNA (2) is sensed by this method with a sensitivity limit corresponding to 1 x 10(-13) M. The biotin-tagged liposomes are also used to probe and amplify single-base mismatches in an analyte DNA. The 6-oligonucleotide-functionalized Au-electrode or Au-quartz crystal was used to differentiate the single-base mismatch (G) in the mutant (5) from the normal A-containing gene (5a). Polymerase-induced coupling of the biotinylated-C-base to the double-stranded assembly generated between 6 and 5 followed by the association of avidin and biotin-tagged liposomes is used to probe the single base mismatch. The functionalized liposomes provide a particulate building unit for the dendritic amplification of DNA sensing.     

Amplified detection of DNA and analysis of single-base mismatches by the catalyzed deposition of gold on Au-nanoparticles

A novel amplification route for DNA detection based on the deposition of gold on a 10 nm Au-colloid/avidin conjugate label acting as a 'seeding' catalyst, is described. Microgravimetric quartz-crystal-microbalance measurements are employed to transduce the catalyzed deposition of gold on the piezoelectric crystals. Three different DNA detection schemes are described: (i) analysis of a 27-base nucleic acid fragment; (ii) analysis of the entire M13phi DNA (7229 bases); and (iii) detection of a single-base mismatch in a DNA. Ultrasensitive detection of DNA is accomplished by the catalyzed deposition of gold, detection limit approximately 1 x 10(-15) M.     

Highly sensitive amplified electronic detection of DNA by biocatalyzed precipitation of an insoluble product onto electrodes

The amplified detection of a target DNA, based on the alkaline phosphatase oxidative hydrolysis of the soluble 5-bromo-4-chloro-3-indoyl phosphate to the insoluble indigo product as an amplification path, is addressed by two different sensing configurations. The accumulation of the insoluble product on Au electrodes or Au/quartz crystals alters the interfacial electron-transfer resistance at the Au electrode or the mass associated with the piezoelectric crystal, thus enabling the quantitative transduction of the DNA sensing by Faradaic impedance spectroscopy or microgravimetric quartz crystal microbalance measurements, respectively. One sensing configuration involves the association of a complex consisting of the target DNA and a biotinylated oligonucleotide to the functionalized transducers. The binding of the avidin/alkaline phosphatase conjugate to the sensing interface followed by the biocatalyzed precipitation provides the amplification path for the analysis of the target DNA. This analysis scheme was used to sense the target DNA with a sensitivity limit that corresponds to 5 x 10(-14) M. The second amplified detection scheme involves the use of a nucleic-acid-functionalized alkaline phosphatase as a biocatalytic conjugate for the precipitation of the insoluble product. Following this scheme, the functionalized transducers are interacted with the analyzed sample that was pretreated with the oligonucleotide-modified alkaline phosphatase, followed by the biocatalyzed precipitation as the amplification route for the analysis of the target DNA. By the use of this configuration, a detection limit corresponding to 5 x 10(-13) M was achieved. Real clinical samples of the Tay-Sachs genetic disorder were easily analyzed by the developed detection routes.     

RNA-templated single-base mutation detection based on T4 DNA ligase and reverse molecular beacon

A novel RNA-templated single-base mutation detection method based on T4 DNA ligase and reverse molecular beacon (rMB) has been developed and successfully applied to identification of single-base mutation in codon 273 of the p53 gene. The discrimination was carried out using allele-specific primers, which flanked the variable position in the target RNA and was ligated using T4 DNA ligase only when the primers perfectly matched the RNA template. The allele-specific primers also carried complementary stem structures with end-labels (fluorophore TAMRA, quencher DABCYL), which formed a molecular beacon after RNase H digestion. One-base mismatch can be discriminated by analyzing the change of fluorescence intensity before and after RNase H digestion. This method has several advantages for practical applications, such as direct discrimination of single-base mismatch of the RNA extracted from cell; no requirement of PCR amplification; performance of homogeneous detection; and easily design of detection probes.     

滚环扩增型压电石英晶体传感器检测乙型肝炎病毒

通过捕获探针与纳米金膜之间的共价连接, 保证了滚环扩增(RCA)产物始终结合于金膜表面, Phi29 DNA聚合酶的高效扩增和Escherichia coli DNA链接酶的高度精确性使检测达到单碱基识别, 检测灵敏度达到10⁴ copies/mL. 实验结果表明, 与单碱基错配序列相比, RCA可明显增强检测的灵敏度. 该RCA基因传感器操作简单, 灵敏度和特异性较高, 在乙型肝炎病毒的快速检测方面具有一定的开发潜力.     

DNA sensor based on an Escherichia coli lac Z gene probe immobilization at self-assembled monolayers-modified gold electrodes

A novel approach to construct an electrochemical DNA sensor based on immobilization of a 25 base single-stranded probe, specific to E. coli lac Z gene, onto a gold disk electrode is described. The capture probe is covalently attached using a self-assembled monolayer of 3,3′-dithiodipropionic acid di(N-succinimidyl ester) (DTSP) and mercaptohexanol (MCH) as spacer. Hybridization of the immobilized probe with the target DNA at the electrode surface was monitored by square wave voltammetry (SWV), using methylene blue (MB) as electrochemical indicator. Variables involved in the sensor performance, such as the DTSP concentration in the modification solution, the self-assembled monolayers (SAM) formation time, the DNA probe drying time atop the electrode surface and the amount of probe immobilized, were optimized.

A good stability of the single- and double-stranded oligonucleotides immobilized on the DTSP-modified electrode was demonstrated, and a target DNA detection limit of 45 nM was achieved without signal amplification. Hybridization specificity was checked with non-complementary and mismatch oligonucleotides. A single-base mismatch oligonucleotide gave a hybridization response only 7 ± 3%, higher than the signal obtained for the capture probe before hybridization. The possibility of reusing the electrochemical genosensor was also tested.     

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.     

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.     

Method for detection of single-base mismatches using bimolecular beacons

This paper describes a method for the detection of single-base mismatches using DNA microarrays in a format that does not require labeling of the sample ("target") DNA. The method is based on disrupting fluorescence energy transfer (FRET) between a fluorophore attached to an immobilized DNA strand ("probe") and a quencher-containing sequence that is complementary except for an artificial mismatch (e.g. 5-nitroindole, 3-nitropyrole, or abasic site) at the site of interrogation. As the displacement of the FRET acceptor and hybridization of the unlabeled probe are bimolecular, the term "bimolecular beacons" is used to describe this approach. The analysis of a mismatch was based on differences in the amount of disruption in FRET upon hybridization of perfectly matched DNA targets and those containing single-base mismatches. Using this method and an oligonucleotide model system, A/C single-base mismatches were successfully discriminated at levels greater than that observed using surface-immobilized molecular beacons. The amount of discrimination was dependent on the identity of the artificial mismatch; greater discrimination was observed with 5-nitroindole (a "universal" base) than with an abasic site. G/T mismatches, considered to be particularly difficult to detect, were also successfully discriminated when quencher sequences containing 5-nitroindole were used.     

Hybridization of oligonucleotide by using DNA self-assembled monolayer

The interaction between DNA immobilized on surface and oligonucleotides at the interface is important in detection and diagnostic processes. However, it is difficult to immobilize DNA with maintaining its activity and to realize an efficient hybridization in previous methods. Here, to establish a novel DNA-functionalized surface, the DNA self-assembled monolayer (SAM) was constructed on a gold substrate using thiolated DNA composed of double-stranded (ds) and single-stranded (ss) portion. The DNA SAM was characterized by surface plasmon resonance (SPR), XPS. The hybridization of ss portion of DNA was attempted using the SAM, and in situ monitored by SPR. XPS measurement indicated that the thiolated DNA could form a stable monolayer on a gold substrate through sulfur–gold interaction. SPR measurement implied that the long axis of the DNA standing on the substrate. These results indicated formation of the DNA SAM on the substrate. Hybridization of target DNA containing a complementary sequence for the probe portion was observed by SPR. Moreover, one mismatch of oligonucleotide could be distinguished using the DNA SAM. The SPR result indicates that hybridization of target DNA and probe DNA on the DNA SAM occurs on the DNA SAM.     

Rapid aggregation of gold nanoparticles induced by non-cross-linking DNA hybridization

To date, aggregation of DNA-functionalized gold nanoparticles by hybridization of target DNA in a cross-linking configuration has been intensively studied. Here, we report that aggregation in a non-cross-linking configuration is also possible and is even better from the viewpoint of genetic analysis because of its speed and sensitivity. In this system, 15 nm diameter gold nanoparticles functionalized with (alkanethiol)-15mer DNA are hybridized to target 15mer DNA at room temperature. At high NaCl concentration (>/=0.5 M), hybridization with complementary target DNA induces nanoparticle aggregation based on the salting-out effect. The aggregation can be detected by a colorimetric change of the colloidal solution within 3 min. Furthermore, unusual sensitivity of this system for single-base mismatch at the terminus opposite to the anchored side has been discovered. In fact, target DNA with such a kind of mismatch does not induce the colorimetric change at all, while target DNA with single-base mismatch at the middle of it cannot be discriminated from the fully complementary target. This non-cross-linking aggregation system opens up a new possibility of rapid and reliable genetic analysis.     

Label-free and non-enzymatic detection of DNA based on hybridization chain reaction amplification and dsDNA-templated copper nanoparticles

A label-free and non-enzymatic amplification fluorescent method for detection of DNA has been developed by using hybridization chain reaction (HCR) and dsDNA-templated copper nanoparticles (CuNPs). First, the biotinylated capture DNA probes were immobilized on the streptavidin-modified beads through the interaction of biotin and streptavidin. Then, target DNA hybridized with the capture DNA probes, which formed a hybridized DNA with sticky end. The sticky end triggered the HCR process and formation of dsDNA polymers while two hairpin probes coexisted. Subsequently, the dsDNA polymers were employed as template for synthesis of CuNPs with excellent fluorescent properties, which provided a label-free, non-enzymatic signal response. Meanwhile, the fluorescence sensing depended on the target DNA triggered HCR, which render this method a high selectivity against single-base mismatch sequences. The concept and methodology developed in this work show great promise in the quantitative detection of DNA in biological and medical applications.     

Application of 3,4,9,10-perylenetetracarboxylic diimide microfibers as a fluorescent sensing platform for biomolecular detection

In this paper, we report on the use of 3,4,9,10-perylenetetracarboxylic diimide microfibers (PDIMs) as an effective fluorescent sensing platform for DNA detection for the first time. This sensing system exhibits a detection limit as low as 15 nmol L⁻¹ and has a high selectivity down to single-base mismatch. The general concept used in this approach is based on adsorption of fluorescently labeled single-stranded DNA (ssDNA) probe by PDIM due to the strong π–π stacking between unpaired DNA bases and PDIM. As a result, the fluorophore is brought into close proximity of PDIM, leading to substantial fluorescence quenching. In the presence of the target, the specific hybridization of the probe with its complementary DNA sequence generates a double stranded DNA (dsDNA) which detaches from PDIM, leading to fluorescence recovery. Its generality of this sensing platform for protein detection is also demonstrated.     

Nanostructured Screen Printed Graphite Electrode for the Development of a Novel Electrochemical Genosensor

The aim of this work is the preparation of DNA‐sensing architectures based on gold nanoparticles (AuNPs) in conjunction with an enzyme‐amplified detection to improve the analytical properties of genosensor. In order to assess the utility of study as DNA‐sensing devices, a thiolated DNA capture probe sequence was immobilized on the gold nanoparticle modified surface. After labeling of the biotinylated hybrid with a streptavidin‐alkaline phosphatase conjugate, the electrochemical detection of the enzymatic product was performed on the surface of a disposable electrode. Two different enzymatic substrates to detect the hybridization event were studied. In the first case, the enzyme catalyzed the hydrolysis of α‐naphthyl phosphate; the product is electroactive and has been detected by means of differential pulse voltammetry (DPV). In the second one, the enzyme catalyzed the precipitation of an insoluble and insulating product on the sensing interface. In this case, the electrochemical transduction of the hybridization process was performed by electrochemical impedance spectroscopy (EIS).     

Electronic detection of single-base mismatches in DNA with ferrocene-modified probes.

Genotyping and gene-expression monitoring is critical to the study of the association between genetics and drug response (pharmacogenomics) and the association of sequence variation with heritable phenotypes. Recently, we developed an entirely electronic method for the detection of DNA hybridization events by the site-specific incorporation of ferrocenyl derivatives into DNA oligonucleotides. To perform rapid and accurate point mutation detection employing this methodology, two types of metal-containing signaling probes with varying redox potentials are required. In this report we describe a new ferrocene-containing phosphoramidite 9 that provides a range of detectable redox potentials. Using automated DNA/RNA synthesis techniques the two ferrocenyl complexes were inserted at various positions along oligonucleotide probes. Thermal stability analysis of these metal-containing DNA oligonucleotides indicates that incorporation of 9 resulted in no destabilization of the duplex. A mixture of oligonucleotides containing compounds 9 and I was analyzed by alternating current voltammetry (ACV) monitored at the 1st harmonic. The data demonstrate that the two ferrocenyl oligonucleotide derivatives can be distinguished electrochemically. A CMS-DNA array was prepared on an array of gold electrodes on a printed circuit board substrate with a self-assembled mixed monolayer, coupled to an electronic detection system. Experiments for the detection of a single-base match utilizing two signaling probes were carried out. The results demonstrate that rapid and accurate detection of a single-base mismatch can be achieved by using these dual-signaling probes on CMS-DNA chips.     

Detection of mismatched caspase-3 DNA oligonucleotides with an SPR biosensor following amplification by Taq polymerase

We demonstrate that base mismatches of caspase-3 DNA sequences can be detected by surface plasmon resonance (SPR) following signal amplification by polymerase from Thermus aquaticus (Taq). The concentration of magnesium ions and the respective dNTPs for polymerase binding to the oligonucleotides on the sensing surface were optimized. Taq polymerase binds to double-stranded DNA that is self-assembled on the gold surface of the biosensor to induce an SPR signal. Experiments are presented on the effect of Mg(II) and dNTP concentrations on the activity of the polymerase on the sensing surface. The detection limits are 50 pM, 0.1 nM, 0.7 nM, 7 nM, and 20 nM for correctly matched, single-base mismatched, two-base mismatched, three-base mismatched and four-base mismatched DNA of caspase-3, respectively. This is attributed to the optimized experimental conditions, with samples containing 2 μM of Mg(II) and 0.3 mM of dNTP.

Quartz crystal microbalance genosensor for sequence specific detection of attomolar DNA targets

A mass sensitive quartz crystal microbalance (QCM) based genosensor has been developed using breast cancer 1 (BRCA1) gene as a model gene. We modified the traditional sandwich assay by conjugating reporter probe DNA (DNA-r) with an assembly of gold nanoparticles leading to an increased mass on the surface, which enhanced the sensitivity to few orders of magnitude. The unique cleavage function of endonuclease is used for achieving the selectivity to complementary DNA over mismatched DNA. With this combination, the sensor exhibited excellent sensitivity with a detection limit of 10 aM BRCA1 gene and it showed good selectivity for even single base mismatch DNA targets. This ultrasensitive and cost-effective DNA detection protocol can be extended to the direct analysis of any non-amplified genomic DNA.     

High sensitive and label-free colorimetric DNA detection based on nicking endonuclease-assisted activation of DNAzymes

Horseradish peroxidase mimicking DNAzyme (HRP-DNAzyme) attracts growing interest as an amplifying label for biorecognition and biosensing events, especially for DNA detection. However, in the traditional designs, one target molecule can only generate one HRP-DNAzyme, which limits the signal enhancement and thus its sensitivity. In this article, we propose an amplified and label-free colorimetric DNA detection strategy based on nicking endonuclease (NEase)-assisted activation of HRP-DNAzymes (NEAA-DNAzymes). This new strategy relies on the hairpin-DNAzyme probe and NEase-assisted target recycling. In the hairpin-DNAzyme probe, the HRP-DNAzyme sequence is protected in a “caged” inactive structure, whereas the loop region includes the target complementary sequence. Upon hybridization with target, the beacon is opened, resulting in the activation of the HRP-DNAzyme. Meanwhile, upon formation of the duplex, the NEase recognizes a specific nucleotide sequence and cleaves the hairpin-DNAzyme probe into two fragments. After nicking, the fragments of the hairpin-DNAzyme probe spontaneously dissociate from the target DNA. Amplification is accomplished by another hairpin-DNAzyme probe hybridizing to the released intact target to continue the strand-scission cycle, which results in activation of numerous DNAzymes. The activated HRP-DNAzymes generate colorimetric or chemiluminescence readout signals, thus providing the amplified detection of DNA. The detection limit of the colorimetric method is 10 pmol/L, which are three orders of magnitude lower than that without NEase. In addition, the detection limit of the chemiluminescence method is 0.2 pmol/L. Meanwhile, this strategy also exhibits high discrimination ability even against single-base mismatch.     

Electrochemical DNA sensor by the assembly of graphene and DNA-conjugated gold nanoparticles with silver enhancement strategy

Sensitive and selective detection of DNA is in urgent need due to its important role in human bodies. Many disorders, such as Alzheimer's disease and various cancers, are closely related with DNA damage. In this work, a novel electrochemical DNA biosensor was constructed on a DNA-assembling graphene platform which provided a robust, simple and biocompatible platform with large surface area for DNA immobilization. The as-designed DNA sensor was fabricated by directly assembling captured ssDNA on a graphene-modified electrode through the π-π stacking interaction between graphene and ssDNA bases. Then, the target DNA sequence and oligonucleotide probes-labeled AuNPs were able to hybridize in a sandwich assay format, following the AuNPs-catalyzed silver deposition. The deposited silver was further detected by differential pulse voltammetry. Owing to the high DNA loading ability of graphene and the distinct signal amplification by AuNPs-catalyzed silver staining, the resulting biosensor exhibited a good analytical performance with a wide detection linear range from 200 pM to 500 nM, and a low detection limit of 72 pM. Additionally, the biosensor was proved to be able to discriminate the complementary sequence from the single-base mismatch sequence. The simple biosensor is promising in developing electronic, on-chip assays in clinical diagnosis, environmental control, and drug discovery.     

Hairpin Assembly Amplified Electrochemical Biosensor for Highly Sensitive and Specific Detection of DNA

In this report, a simple electrochemical biosensor has been developed for highly sensitive and specific detection of DNA based on hairpin assembly amplification. In the presence of target DNA, the biotin‐labelled hairpin H1 is opened by hybridizing with target DNA through complementary sequences. Then the opened hairpin H1 assembles with the hairpin H2 to displace the target DNA, generating H1‐H2 complex. The displaced target DNA could trigger the next cycle of hairpins assembly, resulting in the generation of numerous H1‐H2 complexes. Subsequently, the H1‐H2 complex hybridizes with the capture probe immobilized on the electrode. Finally, the streptavidin alkaline phosphatase (ST‐ALP) binds to biotin in the capture probe‐H1‐H2 complex and catalyzes the substrate α‐naphthol (α‐NP) to produce electrochemical signal. To make a more fascinating hairpin assembly amplification strategy in signal amplification, mismatched base sequences are designed in hairpin H2 to decrease non‐specific binding of the hairpin substrates. The developed biosensor achieves a sensitivity of 20 pM with a linear range from 25 pM to 25 nM, and shows high selectivity toward single‐base mismatch. Thus, the proposed electrochemical biosensor might have the potential for early clinical diagnosis and therapy.