Cooperative oligonucleotides mediating direct capture of hepatitis C virus RNA from serum

Direct microRNA detection with universal tagged probe and time-resolved fluorescence technology

microRNAs have emerged as the central player in gene expression regulation and have been considered as potent cancer biomarkers for early disease diagnosis. Direct microRNA detection without amplification and labeling is highly desired. Here we present a rapid, sensitive and selective microRNA detection method based on the base stacking hybridization coupling with time-resolved fluorescence technology. Other than planar microarrays, magnetic beads are used as reaction platforms. In this method, one universal tag is used to report all microRNA targets. Its specificity allows for discrimination between microRNAs differing by a single nucleotide, and between precursor and mature microRNAs. This method also provides a high sensitivity down to 20 fM. Moreover, the full protocol can be completed in about 3 h starting from total RNA.

A reverse transcription-free real-time PCR assay for rapid miRNAs quantification based on effects of base stacking

A rapid and reverse transcription-free real-time PCR microRNA assay was developed based on effects of base stacking. This microRNA assay has been shown to be highly specific to homogenous miRNAs, and the procedure can be completed within 30 min starting from total RNA.

Ultrasensitive and selective electrochemical identification of hepatitis C virus genotype 1b based on specific endonuclease combined with gold nanoparticles signal amplification

This work proposes a new strategy for the electrochemical detection of hepatitis C virus (HCV) RNA level and identification of HCV-1b genotype based on the site-specific cleavage of BamHI endonuclease combined with gold nanoparticles (AuNPs) signal amplification. The assay procedures include the reverse transcription, polymerase chain reaction (PCR) amplification, and electrochemical detection. The samples of 244 mer sequence of HCV RNA from the highly conserved region of HCV-1a, HCV-1b, HCV-1, and HCV-6a, respectively, were first reverse transcribed into complementary cDNA and amplified by PCR. The PCR-amplified samples were then analyzed using a synthetic 21 mer DNA probe, which has been assembled on the electrode surface via a bifunctional molecule of p-aminobenzoic acid (ABA). The results demonstrated that the developed approach can be used for specifically identification of the HCV-1b genotype and selective and sensitive detection of HCV-1b cDNA (244 mer) with a detection limit as low as (3.1 ± 0.8) × 10(-22) M (less than 200 molecules; the concentration refers to the one before PCR amplification). Moreover, the developed method has an ability to discriminate the HCV-1b cDNA sequence from even single-base mismatched DNA sequence, to assay the HCV-1b cDNA level precisely from the mixture of HCV-1, HCV-1b, HCV-1a, and HCV-6a, and to detect HCV in real clinical samples. The protocol has high potential application in molecular diagnostics of HCV in clinical environments.

Rapid, specific and sensitive electrochemical detection of foodborne bacteria

Electrochemical biochips are an emerging tool for point-of-care diagnostic systems in medicine, food and environmental monitoring. In the current study, a thermostable reporter enzyme, esterase 2 (EST2) from Alicyclobacillus acidocaldarius, is used for specific and sensitive detection of bacteria by one-step rRNA/DNA hybridization between a bacterium-specific capture oligodeoxynucleotide (ODN), bacterial 16S rRNA and an uniform EST2-ODN reporter conjugate. The detection limit corresponds to approximately 500 colony forming units (cfu) Escherichia coli. Beside high sensitivity, the application of electrochemical biochips allows discrimination of two gram-negative and two gram-positive bacteria demonstrating the specificity and the potential for parallel detection of microorganisms. The feasibility of identification of foodborne bacteria was studied with meat juice contaminated with E. coli. This detection system has the capability to be applied for monitoring of bacterial food contamination.

Development of a base stacking hybridization-based microarray method for rapid identification of clinical isolates

A base stacking hybridization-based microarray method was developed for rapid identification of clinical isolates within 2 h. The oligonucleotide probe sequences for species or genus-level identification were targeted against ribosomal RNA. Isolates were lysed and directly hybridized to the microarray-bound capture probes without conventional DNA or RNA isolation and prior polymerase chain reaction amplification. Five bacterial species encountered frequently in the clinical setting, Pseudomonas aeruginosa, Staphylococcus aureus, Escherichia coli, Klebsiella pneumoniae and Enterobacter cloacae, and one genus Enterococcus, could be discriminated by the microarray-based assay. Identification by this method matched biochemical identification for 150 of 152 clinical strains. This base-stacking hybridization microarray offers a simple, fast (</=2 h), and accurate identification of bacterial cultures and is a potential tool for routine clinical diagnosis.

Lateral flow microarrays: a novel platform for rapid nucleic acid detection based on miniaturized lateral flow chromatography

Widely used nucleic acid assays are poorly suited for field deployment where access to laboratory instrumentation is limited or unavailable. The need for field deployable nucleic acid detection demands inexpensive, facile systems without sacrificing information capacity or sensitivity. Here we describe a novel microarray platform capable of rapid, sensitive nucleic acid detection without specialized instrumentation. The approach is based on a miniaturized lateral flow device that makes use of hybridization-mediated target capture. The miniaturization of lateral flow nucleic acid detection provides multiple advantages over traditional lateral flow devices. Ten-microliter sample volumes reduce reagent consumption and yield analyte detection times, excluding sample preparation and amplification, of <120 s while providing sub-femtomole sensitivity. Moreover, the use of microarray technology increases the potential information capacity of lateral flow. Coupled with a hybridization-based detection scheme, the lateral flow microarray (LFM) enables sequence-specific detection, opening the door to highly multiplexed implementations for broad-range assays well suited for point-of-care and other field applications. The LFM system is demonstrated using an isothermal amplification strategy for detection of Bacillus anthracis, the etiologic agent of anthrax. RNA from as few as two B. anthracis cells was detected without thermocycling hardware or fluorescence detection systems.

Development of a method for concentrating and purifying SARS coronavirus RNA by a magnetic bead capture system

Severe acute respiratory syndrome (SARS) is a recently emerged infectious disease caused by a novel coronavirus, which has been designated the SARS coronavirus (SARS-CoV). To date, molecular assays for the detection of SARS-CoV has focused mainly on reverse transcriptase-PCR (RT-PCR) analysis of specimens. However, RT-PCR assays currently available have low sensitivity during the early stage of the disease in which the viral load in specimens is very low. A method for concentrating and purifying SARS-CoV RNA by a magnetic bead capture system was developed and followed by an RT-PCR assay in this study with the goal of improving the sensitivity of the RT-PCR method. This approach takes advantage of the cooperative interaction between adjacently hybridized oligonucleotides. A capture probe was covalently coupled to magnetic beads and a second probe, which anneals adjacent to the capture probe site, was prehybridized in solution to the target. It was shown that, when applied to SARS RNA samples, the sensitivity of nucleic acid capture RTPCR was about 10-fold greater than routine RT-PCR. This nucleic acid capture system was effective in improving the sensitivity of the RT-PCR, due to enriching and purifying SARS-CoV RNA. The method will be helpful for the early detection of the SARS-associated coronavirus.

Enumeration of bacteria from the Clostridium leptum subgroup in human faecal microbiota using Clep1156 16S rRNA probe in combination with helper and competitor oligonucleotides

Target site inaccessibility represents a significant problem for fluorescent in situ hybridisation (FISH) of 16S rRNA oligonucleotide probes. For this reason, the Clep1156 probe targeting 16S rRNA of the Clostridium leptum phylogenetic subgroup used for dot blot experiments could not be used until now for FISH. Considering that bacteria from the C. leptum subgroup are very abundant in the human faecal microbiota and may play a significant role in host health, we have used unlabelled helper and competitor oligonucleotides to improve the 16S rRNA in situ accessibility and specificity of the Clep1156 probe and applied this approach to enumerate C. leptum bacteria in this ecosystem. Nine C. leptum target strains and five non-target strains were selected to develop and validate the helper-competitor strategy. Depending on the target strains, the use of helpers enhanced the fluorescence intensity signal of Clep1156 from 0.4-fold to 8.4-fold with a mean value of 3.6-fold, switching this probe from the brightness class V-VI (masked sites) to III-IV (accessible sites). The simultaneous use of helper and competitor oligonucleotides with Clep1156 probe allowed the expected specificity without disturbing in situ accessibility. Quantified by FISH combined with flow cytometry, C. leptum bacteria in human faecal samples (n=22) represented 19 +/- 7% of bacteria on average [4.9-37.5]. We conclude that helper oligonucleotides are very useful to circumvent the problem of target site in situ accessibility, especially when probe design is limited to only one 16S rRNA area and that helpers and competitors may be efficiently combined.

Tandem oligonucleotide synthesis using linker phosphoramidites

Multiple oligonucleotides of the same or different sequence, linked end-to-end in tandem can be synthesized in a single automated synthesis. A linker phosphoramidite [R. T. Pon and S. Yu (2004) Nucleic Acids Res., 32, 623–631] is added to the 5′-terminal OH end of a support-bound oligonucleotide to introduce a cleavable linkage (succinic acid plus sulfonyldiethanol) and the 3′-terminal base of the new sequence. Conventional phosphoramidites are then used for the rest of the sequence. After synthesis, treatment with ammonium hydroxide releases the oligonucleotides from the support and cleaves the linkages between each sequence. Mixtures of one oligonucleotide with both 5′- and 3′-terminal OH ends and other oligonucleotides with 5′-phosphorylated and 3′-OH ends are produced, which are deprotected and worked up as a single product. Tandem synthesis can be used to make pairs of PCR primers, sets of cooperative oligonucleotides or multiple copies of the same sequence. When tandem synthesis is used to make two self-complementary sequences, double-stranded structures spontaneously form after deprotection. Tandem synthesis of oligonucleotide chains containing up to six consecutive 20mer (120 bases total), various trinucleotide codons and primer pairs for PCR, or self-complementary strands for in situ formation of double-stranded DNA fragments has been demonstrated.

Direct detection of 16S rRNA using oligonucleotide microarrays assisted by base stacking hybridization and tyramide signal amplification

A simple method has been developed and validated for direct, sensitive detection and specific identification of 16S rRNA. We first report our direct investigation of discrimination efficiency for sequence variations in RNA using oligonucleotide microarrays assisted by base stacking hybridization, and demonstrate that the sequence variations of double base substitution, single base substitution and single base deletion in RNA could be directly identified. With the help of tyramide signal amplification (TSA), the detection sensitivity of this method for four clinically important bacterial species was below 0.5, 5, 1 and 1 ng of total RNA, which are 100-1000 fold more sensitive than the published methods.

Development of an integrated automation system with a magnetic bead-mediated nucleic acid purification device for genetic analysis and gene manipulation

We have developed an integrated automation system for genetic analysis and gene manipulation. The system, SX-8G Plus, is equipped with an 8-nozzle dispensing unit, a thermal cycler, a cooled reagent reservoir, four tip storage racks, four microplate platforms, buffer reservoirs, an agarose gel electrophoresis unit, a power supply, a pump for exchanging electrophoresis buffer, and a CCD camera. Automation of nucleic acid extraction and purification, the most difficult step in automating genetic analysis and gene manipulation, was realized using magnetic beads with Magtration Technology, which we have previously developed for automating the handling of paramagnetic beads. Using this system, we could perform the automated separation and purification of DNA fragments by agarose gel electrophoresis starting from sample loading. The system would enable the automation of almost all procedures in genetic analysis and gene manipulation.

Efficiency of coaxial stacking depends on the DNA duplex structure

Thermodynamic parameters of coaxial stacking at complementary helix-helix interfaces GX*pYG/CZVC (X,Y=A,C,T,G;*-nick) created by contiguous oligonucleotide hybridization were determined. The data obtained were compared to the thermodynamic parameters of coaxial stacking at the interfaces CX*pYC/GZVG. Multiple linear regression analysis has revealed that the free-energy increments of interaction for the contacts GX*pYG/CZVC and CX*pYC/GZVG can be described by a set of uniform Delta G degrees(X*pY/ZV) values. The difference in the observed free-energy of the coaxial stacking between the two sets is defined by the contribution from the factors reflecting structural differences between compared DNA duplexes.

Piezoelectric biosensors for real-time monitoring of hybridization and detection of hepatitis C virus

The piezoelectric quartz crystal resonators modified with oligonucleotide probes were used for detection of hepatitis C virus (HCV) in serum. The gold electrodes on either rough or smooth surface crystals were modified with a self-assembled monolayer of cystamine. After activation with glutaraldehyde, either avidin or streptavidin were immobilized and used for attachment of biotinylated DNA probes (four different sequences). Piezoelectric biosensors were used in a flow-through setup for direct monitoring of DNA resulting from the reverse transcriptase-linked polymerase chain reaction (RT-PCR) amplification of the original viral RNA. The samples of patients with hepatitis C were analyzed and the results were compared with the standard RT-PCR procedure (Amplicor test kit of Roche, microwell format with spectrophotometric evaluation). The piezoelectric hybridization assay was completed in 10 min and the same sensing surface was suitable for repeated use.

Laboratory evaluation of a fully automated chemiluminescence immunoassay for rapid detection of HBsAg, antibodies to HBsAg, and antibodies to hepatitis C virus

The performance of a fully automated, random access, enhanced chemiluminescence immunoassay (Ortho/ECi) for the detection of antibody to hepatitis C virus (HCV) (anti-HCV), HBsAg, and antibody to HBsAg (anti-HBsAg), in human serum was compared to a Abbott second-generation enzyme immunoassay (EIA 2.0). The Ortho/ECi assays employ an immunometric technique with enhanced chemiluminescence for optimal assay performance. With regard to the study of clinical laboratory performance, six groups of sera prescreened with Abbott EIAs were assayed: anti-HCV-negative samples (n = 318), anti-HCV-positive samples (n = 177), anti-HBsAg-negative samples (n = 241), anti-HBsAg-positive samples (n = 239), HBsAg-positive samples (n = 158), and HBsAg-negative samples (n = 312). Sera with discrepant results in the two serological assays were resolved by confirmatory tests. Sera with indeterminate results by one or more confirmatory tests were evaluated by reviewing medical records. The overall concordance between the Ortho/ECi assay and the Abbott EIA were 97.78, 93.54, and 97.66% for anti-HCV antibodies, anti-HBsAg antibodies, and HBsAg, respectively. After resolving the discrepancies, the specificities of the new assay for anti-HCV and anti-HBsAg antibodies and HBsAg were 98.1, 92.8, and 100%, respectively. The sensitivities of the new assay for anti-HCV, anti-HBsAg, and HBsAg were 100, 98.8, and 97.4%, respectively. In conclusion, The Ortho/ECi assays for diagnosis of HCV and hepatitis B virus (HBV) infections are highly specific and sensitive assays. The rapid turnaround time, random access, full automation, and high throughput make it an effective assay system for clinical laboratory diagnosis of HCV and HBV infections.

LNA-enhanced detection of single nucleotide polymorphisms in the apolipoprotein E

Genotyping of single nucleotide polymorphisms (SNPs) in large populations presents a great challenge, especially if the SNPs are embedded in GC-rich regions, such as the codon 112 SNP in the human apolipoprotein E (apoE). In the present study, we have used immobilized locked nucleic acid (LNA) capture probes combined with LNA-enhancer oligonucleotides to obtain efficient and specific interrogation of SNPs in the apoE codons 112 and 158, respectively. The results demonstrate the usefulness of LNA oligonucleotide capture probes combined with LNA enhancers in mismatch discrimination. The assay was applied to a panel of patient samples with simultaneous genotyping of the patients by DNA sequencing. The apoE genotyping assays for the codons 112 and 158 SNPs resulted in unambiguous results for all patient samples, concurring with those obtained by DNA sequencing.

Current and future hepatitis C virus diagnostic testing: problems and advancements

Serological antibody assays used in hepatitis C virus diagnosis have improved in sensitivity and specificity. However, detection of active viremia or monitoring levels of virus during or after patient treatment is most commonly undertaken using nucleic acid-based technologies. Advancements in diagnostic technologies and implications for managing patients with hepatitis C in various clinical settings are discussed.

Survey of the 1998 optical biosensor literature

The utilization of optical biosensors to study molecular interactions continues to expand. In 1998, 384 articles relating to the use of commercial biosensors were published in 130 different journals. While significant strides in new applications and methodology were made, a majority of the biosensor literature is of rather poor quality. Basic information about experimental conditions is often not presented and many publications fail to display the experimental data, bringing into question the credibility of the results. This review provides suggestions on how to collect, analyze and report biosensor data.

Quantitative investigation of the modular primer effect for DNA and peptide nucleic acid hexamers

The effect on oligonucleotide-template duplex stability upon cohybridization of adjacently annealing oligonucleotides, the modular primer effect, was studied with biosensor technology. DNA and peptide nucleic acid (PNA) hexamer modules and sensor chip-immobilized template DNA strands were designed for analysis of nick, overlap, and gap modular hybridization situations. The fast hybridization kinetics for such hexamer modules allowed for the determination of apparent duplex affinities from equilibrium responses. The results showed that the hybridizational stability of modular hexamer pairs is strongly dependent on the positioning, concentration, and inherent affinity of the adjacently annealing hexamer module. Up to 80-fold increases in apparent affinities could be observed for adjacent modular oligonucleotide pairs compared to affinities determined for single hexamer oligonucleotide hybridizations. Interestingly, also for coinjections of different module combinations where DNA hexamer modules were replaced by their PNA counterparts, a modular primer effect was observed. The introduction of a single base gap between two hexamer modules significantly reduced the stabilization effect, whereas a gap of two bases resulted in a complete loss of the effect. The results suggest that the described biosensor-based methodology should be useful for the selection of appropriate modules and working concentrations for use in different modular hybridization applications.