High-sensitive electrochemical detection of point mutation based on polymerization-induced enzymatic amplification

Here a highly sensitive electrochemical method is described for the detection of point mutation in DNA. Polymerization extension reaction is applied to specifically initiate enzymatic electrochemical amplification to improve the sensitivity and enhance the performance of point mutation detection. In this work, 5'-thiolated DNA probe sequences complementary to the wild target DNA are assembled on the gold electrode. In the presence of wild target DNA, the probe is extended by DNA polymerase over the free segment of target as the template. After washing with NaOH solution, the target DNA is removed while the elongated probe sequence remains on the sensing surface. Via hybridizing to the designed biotin-labeled detection probe, the extended sequence is capable of capturing detection probe. After introducing streptavidin-conjugated alkaline phosphatase (SA-ALP), the specific binding between streptavidin and biotin mediates a catalytic reaction of ascorbic acid 2-phosphate (AA-P) substrate to produce a reducing agent ascorbic acid (AA). Then the silver ions in solution are reduced by AA, leading to the deposition of silver metal onto the electrode surface. The amount of deposited silver which is determined by the amount of wild target can be quantified by the linear sweep voltammetry (LSV). The present approach proved to be capable of detecting the wild target DNA down to a detection limit of 1.0×10(-14) M in a wide target concentration range and identifying -28 site (A to G) of the β-thalassemia gene, demonstrating that this scheme offers a highly sensitive and specific approach for point mutation detection.     

QCM detection of DNA targets with single-base mutation based on DNA ligase reaction and biocatalyzed deposition amplification

A novel biosensing technique for highly specific identification of gene with single-base mutation is proposed based on the implementation of the DNA ligase reaction and the biocatalyzed deposition of an insoluble product. The target gene mediated deposition of an insoluble precipitate is then transduced by quartz crystal microbalance (QCM) measurements. In this method, the DNA target hybridizes with a capture DNA probe tethered onto the gold electrode and then with a biotinylated allele-specific detection DNA. A ligase reaction is performed to generate the ligation between the capture and the detection probes, provided there is perfect match between the DNA target and the detection probe. Otherwise even when there is an allele mismatch between them, no ligation would take place. After thermal treatment at an elevated temperature, the formed duplex melts apart that merely allows the detection probe perfectly matched with the target to remain on the electrode surface. The presence of the biotinylated allele-matched probe is then detected by the QCM via the binding to streptavidin-peroxide horseradish (SA-HRP), which catalyzes the oxidative precipitation of 3,3-diaminobenzidine (DAB) by H2O2 on the electrode and provides an amplified frequency response. The proposed approach has been successfully implemented for the identification of single-base mutation in -28 site of the beta-thalassemia gene with a detection limit of 0.1 nM, demonstrating that this method provides a highly specific and cost-efficient approach for point mutation detection.     

Electrochemical immunosensor with aptamer-based enzymatic amplification

An electrochemical immunosensor is reported by using aptamer-based enzymatic amplification with immunoglobulin E (IgE) as the model analyte. In this method, the IgE antibody is covalently immobilized as the capture probe on the gold electrode via a self-assembled monolayer of cysteamine. After the target is captured, the biotinylated anti-IgE aptamer is used as the detection probe. The specific interaction of streptavidin-conjugated alkaline phosphatase to the surface-bound biotinylated detection probe mediates a catalytic reaction of ascorbic acid 2-phosphate substrate to produce a reducing agent ascorbic acid. Then silver ions in the solution can be reduced, leading to the deposition of metallic silver on the electrode surface. The amount of deposited silver, which is determined by the amount of IgE target bound on the electrode surface, can be quantified using the stripping voltammetry. The results obtained demonstrated that the electrochemical immunosensor possesses high specificity and a wide dynamic range with a low detection limit that possibly arises from the combination of the highly specific aptamer and the highly sensitive stripping determination of enzymatically deposited silver.     

Highly sensitive and selective colorimetric genotyping of single-nucleotide polymorphisms based on enzyme-amplified ligation on magnetic beads

Herein we report a new strategy for highly sensitive and selective colorimatric assay for genotyping of single-nucleotide polymorphisms (SNPs). It is based on the use of a specific gap ligation reaction, horseradish peroxidase (HRP) for signal amplification, and magnetic beads for the easy separation of the ligated product. Briefly, oligonucleotide capture probe functionalized magnetic beads are first hybridized to a target DNA. Biotinylated oligonucleotide detection probes are then allowed to hybridize to the already captured target DNA. A subsequent ligation at the mutation point joins the two probes together. The introduction of streptavidin-conjugated HRP and a simple magnetic separation allow colorimetric genotyping of SNPs. The assay is able to discriminate one copy of mutant in 1000 copies of wild-type KRAS oncogene at 30 picomolar. The detection limit of the assay is further improved to 1 femtomolar by incorporating a ligation chain reaction amplification step, offering an excellent opportunity for the development of a simple and highly sensitive diagnostic tool.     

Fluorescent oligonucleotide ligation technology for identification of ras oncogene mutations

A mutation detection strategy based on multiplex PCR followed by multiplex allele-specific oligonucleotide probe ligation was developed to detect single nucleotide substitutions in ras oncogenes, a common genetic abnormality in many human cancers. Mutation-specific probes are synthesized for each possible single-base, nonsilent mutation in codons 12, 13, and 61 of H-, K-, and N-ras oncogenes. Mutations are identified by competitive oligonucleotide probe ligation to detect normal and /or mutant genotypes in one reaction. Three probes (one common and two allelic probes) are needed for analysis of each mutation. Probes hybridized to target ras oncogene DNA are joined by a thermostable ligase if there are no mismatches at their junctions; temperature cycling results in a linear increase in product. Common probes are labeled with fluorochromes, and allelic probes each have different lengths. Ligation products are analyzed by denaturing polyacrylamide gel electrophoresis on a fluorescent DNA sequencer. We have applied this technology to identify ras mutations in pancreatic cancers and lung cancers and in patients with myelodysplastic syndromes and leukemias.     

Detection of single-base DNA mutations by enzyme-amplified electronic transduction

Here we describe a method for the sensitive detection of a single-base mutation in DNA. We assembled a primer thiolated oligonucleotide, complementary to the target DNA as far as one base before the mutation site, on an electrode or a gold-quartz piezoelectric crystal. After hybridizing the target DNA, normal or mutant, with the sensing oligonucleotide, the resulting assembly is reacted with the biotinylated nucleotide, complementary to the mutation site, in the presence of polymerase. The labeled nucleotide is coupled only to the double-stranded assembly that includes the mutant site. Subsequent binding of avidin-alkaline phosphatase to the assembly, and the biocatalyzed precipitation of an insoluble product on the transducer, provides a means to confirm and amplify detection of the mutant. Faradaic impedance spectroscopy and microgravimetric quartz-crystal microbalance analyses were employed for electronic detection of single-base mutants. The lower limit of sensitivity for the detection of the mutant DNA is 1 x 10-14 mol/ml. We applied the method for the analysis of polymorphic blood samples that include the Tay-Sachs genetic disorder. The sensitivity of the method enables the quantitative analysis of the mutant with no PCR pre-amplification.     

CuO thin film based uric acid biosensor with enhanced response characteristics

An electrochemical approach for detection of individual single nucleotide polymorphisms (SNPs) based on nucleobase-conjugated apoferritin probe loaded with metal phosphate nanoparticles is reported. Coupling of the nucleotide-modified nanoparticle probe to the mutant sites of duplex DNA was induced by DNA polymerase I (Klenow fragment) to preserve Watson-Crick base-pairing rules. After sequential liquid hybridization of biotinylated DNA probes with mutant DNA and complementary DNA, the resulting duplex DNA helixes were captured to the surface of magnetic beads through a well known and specific biotin-streptavidin affinity binding. For signaling each of eight possible Single-nucleotide polymorphisms (SNPs), Pb, Cu, Cd and Zn phosphate-loaded apoferritin nanoparticle probes were linked to adenosine (A), cytidine (C), guanosine (G), and thymidine (T) mononucleotides, respectively. Monobase-conjugated apoferritin probes were coupled to the mutant sites of the formed duplex DNA in the presence of DNA polymerase. Electrochemical stripping analyses of the metals loaded in apoferritin nanoparticle probes provide a means for detection and quantification of mutant DNA. Each mutation captures different nucleotide-conjugated apoferritin probe and provide a distinct four-potential voltammogram, whose peak potentials reflect the identity of the mismatch. The method is sensitive enough to accurately determine AG mutation, as the most thermodynamically stable mismatch to detect, in the range of 50-600 pM. The proposed protocol provides a simple, fast, cost-effective, accurate and sensitive method for detection of SNPs.     

DNA point mutation detection based on DNA ligase reaction and nano-Au amplification: a piezoelectric approach

A novel piezoelectric method for DNA point mutation detection based on DNA ligase reaction and nano-Au-amplified DNA probes is proposed. A capture probe was designed with the potential point mutation site located at the 3' end and a thiol group at the 5' end to be immobilized on the gold electrode surface of quartz crystal microbalance (QCM). Successive hybridization with the target DNA and detection probe of nano-Au-labeled DNA forms a double-strand DNA (dsDNA). After the DNA ligase reaction and denaturing at an elevated temperature, the QCM frequency would revert to the original value for the target with single-base mismatch, whereas a reduced frequency response would be obtained for the case of the perfect match target. In this way, the purpose of point mutation discrimination could be achieved. The current approach is demonstrated with the identification of a single-base mutation in artificial codon CD17 of the beta-thalassemia gene, and the wild type and mutant type were discriminated successfully. The scanning electron microscope (SEM) image showing that plenty of gold nanoparticles remained on the electrode surface demonstrated that the nano-Au label served as an efficient signal amplification agent in QCM assay. A detection limit of 2.6 x 10(-9)mol/L of oligonucleotides was achieved. Owing to its ease of operation and low detection limit, it is expected that the proposed procedure may hold great promise in both research-based and clinical genomic assays.     

A new approach to revealing point mutations in DNA analyzed by colorimetric detection

A new approach to detection of point mutations in an amplified DNA was developed. The approach is based on highly selective ligation (T4 DNA ligase) of a tandem of short oligonucleotides one of which contains the biotin group. The ligation product is formed only when the hybridization complex DNA/tandem is formed and the tandem is perfect. The hybridization complex DNA/(biotinylated ligation product) was separated from the biotinylated component of the tandem by UV-immobilization of the reaction mixture on a nylon membrane. The immobilized hybridization complex was detected colorimetrically by a streptavidin-alkaline phosphatase cojugate with a chromogenic substrate.     

An alternative nonradioactive method for labeling DNA using biotin

An alternative nonradioactive labeling method and a highly sensitive technique for detecting specific DNA sequences are described. The labeling method requires the "Klenow" fragment of DNA polymerase I and random hexanucleotides (synthesized or naturally extracted) as a primer for the production of highly sensitive DNA probes. The system has three main steps: (i) labeling of DNA with biotinylated 11-dUTP; (ii) detection of biotinylated DNA by a one-step procedure with streptavidin-alkaline phosphatase complex; (iii) blocking of background with Tween 20. Twenty attograms (2 X 10(-17) g) of pBR322 plasmid DNA was detected by dot-blot hybridization. Upon Southern blot hybridization, 7.4 fg (7.4 X 10(-15) g) of pBR322 HindIII DNA was detected using the biotinylated pBR322 plasmid DNA probe; 40.8 ag and 7.4 fg of lambda HindIII DNA were detected with the biotinylated whole lambda DNA probe by dot and Southern blot hybridization, respectively. Specific bands were also detected with the biotinylated argininosuccinolyase probe upon Northern blotting of mouse poly(A+) RNA. Further applications for in situ hybridization are also described.     

A New Approach to Revealing Point Mutations in DNA Analyzed by Colorimetric Detection

A new approach to detection of point mutations in an amplified DNA was developed. The approach is based on highly selective ligation (T4 DNA ligase) of a tandem of short oligonucleotides one of which contains the biotin group. The ligation product is formed only when the hybridization complex DNA/tandem is formed and the tandem is perfect. The hybridization complex DNA/(biotinylated ligation product) was separated from the biotinylated component of the tandem by UV‐immobilization of the reaction mixture on a nylon membrane. The immobilized hybridization complex was detected colorimetrically by a streptavidin‐alkaline phosphatase cojugate with a chromogenic substrate.     

A single-step silver enhancement method permitting rapid diagnosis of cytomegalovirus infection in formalin-fixed, paraffin-embedded tissue sections by in situ hybridization and immunoperoxidase detection

A single-step silver enhancement method was developed which intensifies the polymerized nickel-complexed diaminobenzidine (Ni-DAB) reaction product of peroxidase. With such enhancement, an in situ hybridization procedure can be performed in less than 8 hr by using a 2-hr hybridization incubation and direct detection. Cytomegalovirus (CMV)-infected lung sections were hybridized in situ for 2 hr with a biotinylated CMV genomic-length probe. The probe was detected directly with avidin-biotinylated peroxidase using Ni-DAB as the substrate, and the reaction product was enhanced with silver. Silver was deposited only on the Ni-DAB and not on normally argyrophilic substances. Indirect detection of the probe using a sandwich technique before silver enhancement proved more sensitive, but the length of the procedure was increased without substantially changing the result (infection vs. no infection). Sensitivity was also improved by omitting the dehydration step before applying the probe, and by increasing the temperature and duration of denaturation. In a blinded study of 21 open-lung biopsies, 13 of 13 culture-negative specimens were negative by hybridization, and 7 of 8 culture-positive specimens were positive by hybridization. Modified short hybridization with a biotinylated probe and silver-enhanced direct detection therefore provides a rapid but sensitive method for diagnosis of viral infection.     

Analysis of polymerase chain reaction products by high-performance liquid chromatography with fluorimetric detection and its application to DNA diagnosis

We describe the development of a sensitive high-performance liquid chromatographic (HPLC) method for polymerase chain reaction (PCR) products using bisbenzimide (Hoechst 33258 dye) based fluorimetric detection. The detection limit and specificity for double-strand DNA detection are improved in comparison with HPLC with UV absorbance detection. This HPLC, using a column packed with diethylaminoethyl-bonded non-porous resin particles, was applied to the detection of allele-specific PCR and restriction fragment length polymorphism analysis. We also developed a hybridization method analyzed by HPLC. DNA fragments (149 bp) containing the mutation site (C→A,G,T) in the N-ras gene were amplified by PCR. Fluorescein isothiocyanate (FITC)-labeled DNA probes were also prepared by PCR using FITC-labeled 5′ primer. Analysis of mutation was performed by the separation of a hybrid and non-reactive DNA probe with HPLC with fluorimetric detection after the hybridization of target DNA (149 bp) and a FITC DNA probe. The effects of various factors on hybridization were examined to establish optimal assay conditions. Under the conditions determined, a point mutation in PCR products obtained from the N-ras gene could be detected specifically by this method. The analysis of PCR products by HPLC may potentially be useful for DNA diagnosis.     

Nonenzymatic autoligation in direct three-color detection of RNA and DNA point mutations

Enzymatic ligation methods are useful in diagnostic detection of DNA sequences. Here we describe the investigation of nonenzymatic phosphorothioate-iodide DNA autoligation chemistry as a method for detection and identification of both RNA and DNA sequences. Combining ligation specificity with the hybridization specificity of the ligated product is shown to yield discrimination of a point mutation as high as >10(4)-fold. Unlike enzymatic ligations, this reaction is found to be equally efficient on RNA or DNA templates. The reaction is also shown to exhibit a significant level of self-amplification, with the template acting in catalytic fashion to ligate multiple pairs of probes. A strategy for fluorescence labeling of three autoligating energy transfer (ALET) probes and directly competing them for autoligation on a target sequence is described. The method is tested in several formats, including solution phase, gel, and blot assays. The ALET probe design offers direct RNA detection, combining high sequence specificity with an easily detectable color change by fluorescence resonance energy transfer (FRET).     

A signal-amplified electrochemical immunosensor for aflatoxin B1 determination in rice

A sensitive and simple electrochemical immunosensor based on enzymatic silver deposition amplification was constructed for the detection of aflatoxin B₁ (AFB₁) in rice. The immunosensor was based on an indirect competitive format between free AFB₁ and aflatoxin B₁-bovine serum albumin (AFB₁-BSA) conjugate immobilized on the electrode surface for binding to a fixed amount of anti-AFB₁ antibody. Then the alkaline phosphatase (ALP)-labeled anti-mouse immunoglobulin G (IgG) secondary antibody was bound to the electrode surface through reaction with primary antibody. Finally, ALP catalyzed the substrate, ascorbic acid 2-phosphate, into ascorbic acid that reduced silver ions in solution to metal silver deposited onto the electrode surface. Linear sweep voltammetry was carried out to quantify the metal silver, which indirectly reflected the amount of the analyte. The experimental parameters, such as the dilution ratio of antibody and the concentration of AFB₁-BSA conjugate, have been evaluated and optimized. At the optimal conditions, the working range of the electrochemical immunosensor was from 0.1 to 10 ng/ml with a detection limit of 0.06 ng/ml. Good recoveries were obtained for the detection of spiked rice samples. So, the proposed method in this article could find a good use for screening AFB₁ in real samples.     

Highly sensitive amperometric detection of genomic DNA in animal tissues

A simple and highly sensitive method for the detection of genomic DNA in tissue samples is described. It is based on amperometric detection of target DNA by forming an analyte/polymeric activator bilayer on a gold electrode. The biotinylated target DNA is hybridized to oligonucleotide capture probes immobilized on the gold electrode, forming the first layer. A subsequent binding of glucose oxidase– avidin conjugate to the target DNA and the introduction of a second layer of a redox polymer to the electrode, via layer-by-layer electrostatic self-assembly, allow for electrochemical detection of the catalytic oxidation current of glucose in a PBS solution. Less than 2.0 fg of rat genomic DNA, for both regulated and house-keeping genes, can be easily detected in 2.5 µl droplets. The proposed procedure shows very high specificity for genomic DNA in a RT–PCR mixture.     

HBV—DNA的生物素寡聚核苷酸探针快速检测

本文建立一种快速ＨＢＶ－ＤＮＡ检测方法,此法是基于生物素标记的寡聚核苷酸与硝酸纤维素滤膜上的靶ＤＮＡ杂交,然后通过Ｓｔｒｅｐｔｏａｖｉｄｉｎ－碱性磷酸酶偶联体及生色底物进行检测。本文研究了此法的实用性,表明对于实验室及临床的ＨＢＶ－ＤＮＡ检测,此法是一种快速（４小时）、灵敏（１－１０ｐｇ）、特异、方便的方法。     

Development of tag-free photoprobes for studies aimed at identifying the target of novel Group A Streptococcus antivirulence agents

We previously reported the identification and development of novel inhibitors of streptokinase (SK) expression by Group A Streptococcus (GAS), originating from a high throughput cell-based phenotypic screen. Although phenotypic screening is well-suited to identifying compounds that exert desired biological effects in potentially novel ways, it requires follow-up experiments to determine the macromolecular target(s) of active compounds. We therefore designed and synthesized several classes of chemical probes for target identification studies, guided by previously established structure–activity relationships. The probes were designed to first irreversibly photolabel target proteins in the intact bacteria, followed by cell lysis and click ligation with fluorescent tags to allow for visualization on SDS–PAGE gels. This stepwise, ‘tag-free’ approach allows for a significant reduction in molecular weight and polar surface area compared to full-length fluorescent or biotinylated probes, potentially enhancing membrane permeability and the maintenance of activity. Of the seven probes produced, the three most biologically active were employed in preliminary target identification trials. Despite the potent activity of these probes, specific labeling events were not conclusively observed due to a considerable degree of nonspecific protein binding. Nevertheless, the successful synthesis of potent biologically active probe molecules will serve as a starting point for initiating more sensitive methods of probe-based target identification.