Sensitive Nucleic Acid Detection Research Articles

Controlled Microwave Heating Accelerates Rolling Circle Amplification.

Rolling circle amplification (RCA) generates single-stranded DNAs or RNA, and the diverse applications of this isothermal technique range from the sensitive detection of nucleic acids to analysis of single nucleotide polymorphisms. Microwave chemistry is widely applied to increase reaction rate as well as product yield and purity. The objectives of the present research were to apply microwave heating to RCA and indicate factors that contribute to the microwave selective heating effect. The microwave reaction temperature was strictly controlled using a microwave applicator optimized for enzymatic-scale reactions. Here, we showed that microwave-assisted RCA reactions catalyzed by either of the four thermostable DNA polymerases were accelerated over 4-folds compared with conventional RCA. Furthermore, the temperatures of the individual buffer components were specifically influenced by microwave heating. We concluded that microwave heating accelerated isothermal RCA of DNA because of the differential heating mechanisms of microwaves on the temperatures of reaction components, although the overall reaction temperatures were the same.

Digitale PCR in der Labordiagnostik

The need for new highly sensitive, cost-efficient, fast and robust nucleic acid detection and quantification technologies is a driving force. PCR, especially quantitative PCR (qPCR), is the method of choice in diagnostics and life-sciences. The digital PCR (dPCR) provides a new technology to measure absolute quantities of nucleic acids without the need for calibration curves. This review gives details on the dPCR technology and available platforms. We discuss the platform differences, common features as well as their advantages and disadvantages.

Focused upon Hybridization: Rapid and High Sensitivity Detection of DNA Using Isotachophoresis and Peptide Nucleic Acid Probes

We present a novel assay for rapid and high sensitivity detection of nucleic acids without amplification. Utilizing the neutral backbone of peptide nucleic acids (PNA), our method is based on the design of low electrophoretic mobility PNA probes, which do not focus under isotachophoresis (ITP) unless bound to their target sequence. Thus, background noise associated with free probes is entirely eliminated, significantly improving the signal-to-noise ratio while maintaining a simple single-step assay requiring no amplification steps. We provide a detailed analytical model and experimentally demonstrate the ability to detect targets as short as 17 nucleotides (nt) and a limit of detection of 100 fM with a dynamic range of 5 decades. We also demonstrate that the assay can be successfully implemented for detection of DNA in human serum without loss of signal. The assay requires 15 min to complete, and it could potentially be used in applications where rapid and highly sensitive amplification-free detection of nucleic acids is desired.

Ultrasensitive Electrochemical Detection of Nucleic Acids Based on the Dual-Signaling Electrochemical Ratiometric Method and Exonuclease III-Assisted Target Recycling Amplification Strategy.

Because of the intrinsic importance of nucleic acids as biotargets, the simple and sensitive detection of nucleic acids is very essential for biological studies and medical diagnostics. In this work, a novel, simple, and selective electrochemical DNA biosensor for the sensitive detection of target DNA (T-DNA) has been developed based on the dual-signaling electrochemical ratiometric method and exonuclease III (Exo III)-assisted target recycling amplification strategy. The assay strategy includes both "signal-on" and "signal-off" elements. The stem-loop (hairpin) DNA capture probe (HP), which was labeled by thiolated methylene blue (MB) at the 3'-protruding termini and ferrocene (Fc) in the middle of the loop, first self-assembled on the gold electrode surface via a Au-S bond. In the presence of T-DNA, the T-DNA hybridized with HP, which triggered the Exo III cleavage process and accompanied the release of T-DNA. As a result, the MB tags were away from and the Fc tags close to the gold electrode surface, leading to the decrease of the oxidation peak current of MB (I(MB)) and the increase of that of Fc (I(Fc)). The value of ΔI(Fc)/|ΔI(MB)| (ΔI(Fc) and ΔI(MB) are the change values of the oxidation peak currents of Fc and MB, respectively) is linear with the concentration of T-DNA from 0.01 pM to 0.8 pM. The detection limit (4.16 fM) of the developed method is much lower than that of the most reported electrochemical DNA biosensors. This strategy provides a simple and sensitive approach for the detection of T-DNA and has promising applications in bioanalysis, disease diagnostics, and clinical biomedicine.

Analytical chemistry: Clamping down on cancer detection.

An electrochemical clamp assay that enables the rapid and sensitive detection of nucleic acids containing single base mutations has now been developed. It has been shown to differentiate between cancer patient samples featuring a specific mutation, and controls from healthy donors or other cancer patients, all directly in unprocessed serum.

Linear light-scattering of gold nanostars for versatile biosensing of nucleic acids and proteins using exonuclease III as biocatalyst to signal amplification.

Gold nanomaterials promise a wide range of potential applications in chemical and biological sensing, imaging, and catalysis. In this paper, we demonstrate a facile method for room-temperature synthesis of gold nanostars (AuNSs) with a size of ~50 nm via seeded growth. Significantly, the AuNSs are found to have high light-scattering properties, which are successfully used as labels for sensitive and selective detection of nucleic acids and proteins by using exonuclease III (Exo III) as a biocatalyst. For DNA detection, the binding of targets to the functionalized AuNS probes leads to the Exo III-stimulated cascade recycling amplification. As a result, a large amount of AuNSs are released from magnetic nanoparticles (MNPs) into solution, providing a greatly enhanced light-scattering signal for amplified sensing process. Moreover, a binding-induced DNA three-way junction (DNA TWJ) is introduced to thrombin detection, in which the binding of two aptamers to thrombin triggers assembly of the DNA motifs and initiates the subsequent DNA strand displacement reaction (SDR) and Exo III-assisted cascade recycling amplification. The detection limits of 89 fM and 5.6 pM are achieved for DNA and thrombin, respectively, which are comparable to or even exceed that of the reported isothermal amplification methods. It is noteworthy that based on the DNA TWJ strategy the sequences are independent on target proteins. Additionally, the employment of MNPs in the assays can not only simplify the operations but also improve the detection sensitivity. Therefore, the proposed amplified light-scattering assay with high sensitivity and selectivity, acceptable accuracy, and satisfactory versatility of analytes provides various applications in bioanalysis.

Fluorescent protein-based molecular beacons by zinc finger protein-guided assembly.

Molecular beacons (MBs) are stem-loop structured oligonucleotides capable of sensitive and specific nucleic acid detection. However, large-scale usage of MBs for high throughput applications has been hindered by the many expensive and tedious chemical modifications. In this paper, we reported a new class of fluorescent protein-based molecular beacons (FP-MBs) based on zinc finger protein-guided assembly. The design consisted of a single oligonucleotide which forms a hairpin structure with an extending arm on both ends for the attachment of two different fluorescent proteins upon simple mixing. This new design allows for simplified MB assembly and modifications for a wide range of applications.

Sequence-specific DNA detection at 10 fM by electromechanical signal transduction.

Target DNA fragments at 10 fM concentration (approximately 6 × 105 molecules) were detected against a DNA background simulating the noncomplementary genomic DNA present in real samples using a simple, PCR-free, optics-free approach based on electromechanical signal transduction. The development of a rapid, sensitive, and cost-effective nucleic acid detection platform is highly desired for a range of diverse applications. We previously described a potentially low-cost device for sequence-specific nucleic acid detection based on conductance change measurement of a pore blocked by electrophoretically mobilized bead-(peptide nucleic acid probe) conjugates upon hybridization with target nucleic acid. Here, we demonstrate the operation of our device with longer DNA targets, and we describe the resulting improvement in the limit of detection (LOD). We investigated the detection of DNA oligomers of 110, 235, 419, and 1613 nucleotides at 1 pM to 1 fM and found that the LOD decreased as DNA length increased, with 419 and 1613 nucleotide oligomers detectable down to 10 fM. In addition, no false positive responses were obtained with noncomplementary, control DNA fragments of similar length. The 1613-base DNA oligomer is similar in size to 16S rRNA, which suggests that our device may be useful for detection of pathogenic bacteria at clinically relevant concentrations based on recognition of species-specific 16S rRNA sequences.

Highly sensitive fluorescence detection of target DNA by coupling exonuclease-assisted cascade target recycling and DNAzyme amplification

Because of the intrinsic importance of nucleic acid as bio-targets, the simple and sensitive detection of nucleic acid is very essential for biological studies and medical diagnostics. Herein, a simple, isothermal and highly sensitive fluorescence detection of target DNA was developed with the combination of exonuclease III (Exo III)-assisted cascade target recycling and DNAzyme amplification. A hairpin DNA probe was designed, which contained the 3′-protruding DNA fragment as target recognition unit, the caged DNA fragment in the stem region as target analogue, and the caged 8–17 DNAzyme sequence in the loop region as signal response unit. Upon sensing of target DNA, the 3′-strand of hairpin DNA probe could be stepwise removed by Exo III, accompanied by the releasing of target DNA and autonomous generation of new target analogues for the successive hybridization and cleavage process. Simultaneously, the 8–17 DNAzyme unit could be exponentially released from this hairpin DNA probe and activated for the cyclic cleavage toward the ribonucleotide-containing molecular beacon substrate, inducing a remarkable fluorescence signal amplification for target detection. A low detection limit of 20fM with an excellent selectivity toward target DNA could be achieved. The developed cascade amplification strategy may be further extended for the detection of a wide spectrum of analytes including protein and biological small molecules by combining DNA aptamer technology.

Highly selective and sensitive nucleic acid detection based on polysaccharide-functionalized silver nanoparticles

Polysaccharide-functionalized silver nanoparticles (Oc-AgNPs) with a mean diameter of 15nm were utilized as a novel and effective fluorescence-sensing platform for nucleic acid detection. Tests on the oligonucleotide sequences associated with the human immunodeficiency virus as a model system showed that the Oc-AgNPs effectively absorbed and quenched dye-labeled single-stranded DNA through strong hydrogen bonding interactions and slight electrostatic attractive interactions. The proposed system efficiently differentiated between complementary and mismatched nucleic acid sequences with high selectivity and good reproducibility at room temperature.

Target-catalyzed dynamic assembly-based pyrene excimer switching for enzyme-free nucleic acid amplified detection.

Because of the intrinsic importance of nucleic acid as biotargets, the simple and sensitive detection of nucleic acid is very essential for biological studies and medical diagnostics. Herein, a new strategy for enzyme-free nucleic acid amplified detection has been opened up by combining the signal-amplification capability of target-catalyzed dynamic assembly with the spatially sensitive fluorescent signal of the pyrene excimer. In this strategy, three metastable pyrene-labeled hairpin DNA probes were designed as assembly components, which were kinetically handicapped from cross-opening in the absence of the target DNA. However, in the presence of the target, the dynamic assembly of branched junctions was circularly catalyzed and accompanied by the switching of the pyrene excimer which emits at ~488 nm. Thus, the target DNA could be detected by this simple mix-and-detect amplification method, without expensive and perishable protein enzymes. A good detection capability exhibited with a detectable minimum target concentration of 10 pM, which was comparable to or even better than some reported enzyme-dependent amplification methods, and the potential for the target detection from complex fluids was verified. In addition, as a novel transformation of dynamic DNA assembly technology into enzyme-free signal-amplification analytical application, we infer that the proposed strategy will hold promising potential for application in a wider range of fields, including aptamer-based non-nucleic acid target sensing, biomedicine, and bioimaging.

An ion-exchange nanomembrane sensor for detection of nucleic acids using a surface charge inversion phenomenon

We present a novel low-cost biosensor for rapid, sensitive and selective detection of nucleic acids based on an ionic diode feature of an anion exchange nanoporous membrane under DC bias. The ionic diode feature is associated with external surface charge inversion on the positively charged anion exchange nanomembrane upon hybridization of negatively charged nucleic acid molecules to single-stranded oligoprobes functionalized on the membrane surface resulting in the formation of a cation selective monolayer. The resulting bipolar membrane causes a transition from electroconvection-controlled to water-splitting controlled ion conductance, with a large ion current signature that can be used to accurately quantify the hybridized nucleic acids. The platform is capable of distinguishing two base-pair mismatches in a 22-base pairing segment of microRNAs associated with oral cancer, as well as serotype-specific detection of dengue virus. We also show the sensor׳s capability to selectively capture target nucleic acids from a heterogeneous mixture. The limit of detection is 1pM for short 27 base target molecules in a 15-min assay. Similar hybridization results are shown for short DNA molecules as well as RNAs from Brucella and Escherichia coli. The versatility and simplicity of this low-cost biosensor should enable point-of-care diagnostics in food, medical and environmental safety markets.

Synthesis and evaluation of new BODIPY-benzofuroquinoline conjugates for sensitive and selective DNA detection

The sensitive and selective detection of nucleic acids is important for basic research and many applied fields. Herein, a series of new BODIPY-benzofuroquinoline conjugates were designed, synthesized and evaluated as DNA intercalating dyes. All compounds were characterized by using 1H, 13C NMR, IR, UV–Vis and fluorescence spectroscopy, and DNA binding properties of these conjugates to calf thymus DNA were studied by using fluorescence titration, UV titration, isothermal titration calorimetry and CD analysis. Significant enhancement of the fluorescent quantum yield was observed for all the conjugates in the presence of calf thymus DNA, and one compound showed excellent sensitivity and selectivity offering its potential application as a DNA specific fluorescent probe. Our results showed that these conjugates could intercalate into calf thymus DNA with high binding affinities. The properties of these dyes as fluorescent probes for living cells imaging were also investigated.

Clinical Utility of PCR for Common Viruses in Acute Respiratory Illness

Acute respiratory illness (ARI) accounts for a large proportion of all visits to pediatric health facilities. Quantitative real-time polymerase chain reaction (qPCR) analyses allow sensitive detection of viral nucleic acids, but it is not clear to what extent specific viruses contribute to disease because many viruses have been detected in asymptomatic children. Better understanding of how to interpret viral findings is important to reduce unnecessary use of antibiotics. To compare viral qPCR findings from children with ARI versus asymptomatic control subjects. Nasopharyngeal aspirates were collected from children aged ≤5 years with ARI and from individually matched, asymptomatic, population-based control subjects during a noninfluenza season. Samples were analyzed by using qPCR for 16 viruses. Respiratory viruses were detected in 72.3% of the case patients (n = 151) and 35.4% of the control subjects (n = 74) (P = .001). Rhinovirus was the most common finding in both case patients and control subjects (47.9% and 21.5%, respectively), with a population-attributable proportion of 0.39 (95% confidence interval: 0.01 to 0.62). Metapneumovirus, parainfluenza viruses, and respiratory syncytial virus were highly overrepresented in case patients. Bocavirus was associated with ARI even after adjustment for coinfections with other viruses and was associated with severe disease. Enterovirus and coronavirus were equally common in case patients and control subjects. qPCR detection of respiratory syncytial virus, metapneumovirus, or parainfluenza viruses in children with ARI is likely to be causative of disease; detection of several other respiratory viruses must be interpreted with caution due to high detection rates in asymptomatic children.

Ultraspecific and highly sensitive nucleic acid detection by integrating a DNA catalytic network with a label-free microcavity.

Nucleic acid detection with label-free biosensors circumvents costly fluorophore functionalization steps associated with conventional assays by utilizing transducers of impressive ultimate detection limits. Despite this technological prowess, molecular recognition at a surface limits the biosensors' sensitivity, specificity, and reusability. It is therefore imperative to integrate novel molecular approaches with existing label-free transducers to overcome those limitations. Here, we demonstrate this concept by integrating a DNA strand displacement circuit with a micron-scale whispering gallery mode (WGM) microsphere biosensor. The integrated biosensor exhibits at least 25-fold improved nucleic acid sensitivity, and sets a new record for label-free microcavity biosensors by detecting 80 pM (32 fmol) of a 22nt oligomer; this improvement results from the catalytic behavior of the circuit. Furthermore, the integrated sensor exhibits extremely high specificity; single nucleotide variants yield 40- to 100-fold lower signal. Finally, the same physical sensor was demonstrated to alternatingly detect 2 different nucleic acid sequences through 5 cycles of detection, showcasing both its reusability and its versatility.

Target-induced quenching for highly sensitive detection of nucleic acids based on label-free luminescent supersandwich DNA/silver nanoclusters

Luminescent silver nanoclusters (AgNCs) were anchored by designed oligonucleotides, acting as fluorescent labels. They hybridized with specific nucleic acid targets to form a supersandwich structure resulting in the fluorescence intensity of the DNA/AgNCs decreasing linearly with respect to the concentration of the target DNA.

Isothermal amplified detection of DNA and RNA

This review highlights various methods that can be used for a sensitive detection of nucleic acids without using thermal cycling procedures, as is done in PCR or LCR. Topics included are nucleic acid sequence-based amplification (NASBA), strand displacement amplification (SDA), loop-mediated amplification (LAMP), Invader assay, rolling circle amplification (RCA), signal mediated amplification of RNA technology (SMART), helicase-dependent amplification (HDA), recombinase polymerase amplification (RPA), nicking endonuclease signal amplification (NESA) and nicking endonuclease assisted nanoparticle activation (NENNA), exonuclease-aided target recycling, Junction or Y-probes, split DNAZyme and deoxyribozyme amplification strategies, template-directed chemical reactions that lead to amplified signals, non-covalent DNA catalytic reactions, hybridization chain reactions (HCR) and detection via the self-assembly of DNA probes to give supramolecular structures. The majority of these isothermal amplification methods can detect DNA or RNA in complex biological matrices and have great potential for use at point-of-care.

Paper-Based Integrated Diagnostic Device for Nucleic Acid Detection of HIV from Blood

Paper materials with good biocompatibility, porous structures, hydrophilic property, capillary effect, low non-specific binding, and multi-modification have been widely applied in diagnostic devices for environmental monitoring, food safety, and healthcare. However, utilizing these properties on one paper chip for quantitative measurement of nucleic acid amplification from blood is a big challenge for point-of-care (POC) device. Here we report an integrative paper-based molecular diagnostic device (IPMD) with the capability of fast plasma separation and sensitive nucleic acid (NA) detection of HIV from blood. The IPMD is composed of a highly efficient plasma generation membrane over a rapid flow nitrocellulose layer for plasma separation, HIV NA collection, amplification, and fluorescence read-out. 100 μL of whole blood sample is separated on-chip within 5 min. The hydrophilic, porous, capillary properties of nitrocellulose are beneficial to pre-store all the chemical components of nucleic acid amplification by a lyophilization process. HIV NA with a limit-of-detection of 10 copies is achieved by analyzing the fluorescence intensity of the nitrocellulose layer after NA amplification for 20 min. These results suggest that our IMPD platform can promote the development of POC devices for global healthcare and personalized medicine.

A new isothermal nucleic acid detection strategy mediated by a double-nicked beacon

A new isothermal and cascade signal amplification method for sensitive nucleic acid detection was developed, which is ultra-simple because it only depends on one double-nicked beacon.

Isothermal Strand-Displacement Polymerase Reaction for Visual Detection of the Southeast Asian–Type Deletion of α-Thalassemia

A rapid and reliable screening test for thalassemia carrier couples is the most effective strategy to decrease the risk of conceiving fetuses with severe thalassemia. We present an approach based on the isothermal strand-displacement polymerase reaction and the use of a lateral flow strip for the visual detection of an α-thalassemia Southeast Asian-type deletion. This assay was used to evaluate 86 clinical samples (72 cases of Southeast Asian-type deletions and 14 cases of other types of thalassemia), and the results obtained were 100% consistent with those obtained using conventional gap-PCR. The approach thus provides a simple, sensitive, rapid, and cost-effective method for the diagnosis of thalassemia genotypes.