A Single Electrochemical Probe Used for Analysis of Multiple Nucleic Acid Sequences

Electrochemical hybridization sensors have been explored extensively for analysis of specific nucleic acids. However, commercialization of the platform is hindered by the need for attachment of separate oligonucleotide probes complementary to a RNA or DNA target to an electrode's surface. Here we demonstrate that a single probe can be used to analyze several nucleic acid targets with high selectivity and low cost. The universal electrochemical four‐way junction (4J)‐forming (UE4J) sensor consists of a universal DNA stem‐loop (USL) probe attached to the electrode's surface and two adaptor strands (m and f) which hybridize to the USL probe and the analyte to form a 4J associate. The m adaptor strand was conjugated with a methylene blue redox marker for signal ON sensing and monitored using square wave voltammetry. We demonstrated that a single sensor can be used for detection of several different DNA/RNA sequences and can be regenerated in 30 seconds by a simple water rinse. The UE4J sensor enables a high selectivity by recognition of a single base substitution, even at room temperature. The UE4J sensor opens a venue for a re‐useable universal platform that can be adopted at low cost for the analysis of DNA or RNA targets.     

Hybridization Detection of Osmium Tetroxide Bipyridine‐Labeled DNA and RNA on Heated Gold Wire Electrodes

We report about hybridization detection of different nucleic acids on capture probe‐modified heated gold wire electrodes. We have compared three kinds of nucleic acid targets: DNA, uracil‐conjugated DNA, and RNA. All three sorts of nucleic acids targets could be labeled with osmium tetroxide bipyridine, hybridized with immobilized DNA capture probes and then detected by square‐wave voltammetry. Heating the gold electrode instead of the entire bulk hybridization solution leads to improved hybridization efficiency in most cases. The reason could be found in a thermal micro‐stirring effect around the heated wire electrode. Also selectivity was improved. Mismatches could be discriminated for DNA and uracil‐conjugated DNA targets. Mismatches in RNA strands, however, are more difficult to detect due to relatively stable secondary structures.     

Molecular-beacon-based tricomponent probe for SNP analysis in folded nucleic acids

Hybridization probes are often inefficient in the analysis of single‐stranded DNA or RNA that are folded in stable secondary structures. A molecular beacon (MB) probe is a short DNA hairpin with a fluorophore and a quencher attached to opposite sides of the oligonucleotide. The probe is widely used in real‐time analysis of specific DNA and RNA sequences. This study demonstrates how a conventional MB probe can be used for the analysis of nucleic acids that form very stable (T_m>80 °C) hairpin structures. Here we demonstrate that the MB probe is not efficient in direct analysis of secondary structure‐folded analytes, whereas a MB‐based tricomponent probe is suitable for these purposes. The tricomponent probe takes advantage of two oligonucleotide adaptor strands f and m. Each adaptor strand contains a fragment complementary to the analyte and a fragment complementary to a MB probe. In the presence of a specific analyte, the two adaptor strands hybridize to the analyte and the MB probe, thus forming a quadripartite complex. DNA strand f binds to the analyte with high affinity and unwinds its secondary structure. Strand m forms a stable complex only with the fully complementary analyte. The MB probe fluorescently reports the formation of the quadripartite associate. It was demonstrated that the DNA analytes folded in hairpin structures with stems containing 5, 6, 7, 8, 9, 11, or 13 base pairs can be detected in real time with the limit of detection (LOD) lying in the nanomolar range. The stability of the stem region in the DNA analyte did not affect the LOD. Analytes containing single base substitutions in the stem or in the loop positions were discriminated from the fully complementary DNA at room temperature. The tricomponent probe promises to simplify nucleic acid analysis at ambient temperatures in such applications as in vivo RNA monitoring, detection of pathogens, and single nucleotide polymorphism (SNP) genotyping by DNA microarrays.     

Capillary waveguide nucleic acid based biosensor

Micro-capillaries are finding increasing utility in the development of portable analytical sensors. We present design guidelines for optimizing the collection of free propagating fluorescence for capillary waveguide sensors used in the detection of nucleic acids. A dual function integrated opto/fluid connector is also described. Evanescent wave excitation of the coating layer containing a DNA probe is achieved by using a fiber optic ring arrangement for coupling light directly into the capillary wall. The central part of the connector is used for injecting a DNA or RNA target into the capillary channel. In situ hybridization has been used to detect target molecules at a concentration of 30 pg ml⁻¹. The sensor can be regenerated for repeated detection of DNA or RNA targets.     

Selective Chemical Modification to the Higher-Order Structures of Nucleic Acids

DNA and RNA can adopt a variety of stable higher-order structural motifs, including G-quadruplex (G4 s), mismatches, and bulges. Many of these secondary structures are closely related to the regulation of gene expression. Therefore, the higher-order structure of nucleic acids is one of the candidate therapeutic targets, and the development of binding molecules targeting the higher-order structure of nucleic acids has been pursued vigorously. Furthermore, as one of the methodologies for detecting the higher-order structures of these nucleic acids, developing techniques for the selective chemical modification of the higher-order structures of nucleic acids is also underway. In this personal account, we focus on the following higher-order structures of nucleic acids, double-stranded DNA containing the abasic site, T−T/U−U mismatch structure, and G-quadruplex structure, and describe the development of molecules that bind to and chemically modify these structures.     

A Multi‐component All‐DNA Biosensing System Controlled by a DNAzyme

We report on a programmable all‐DNA biosensing system that centers on the use of a 4‐way junction (4WJ) to transduce a DNAzyme reaction into an amplified signal output. A target acts as a primary input to activate an RNA‐cleaving DNAzyme, which then cleaves an RNA‐containing DNA substrate that is designed to be a component of a 4WJ. The formation of the 4WJ controls the release of a DNA output that becomes an input to initiate catalytic hairpin assembly (CHA), which produces a second DNA output that controls assembly of a split G‐quadruplex as a fluorescence signal generator. The 4WJ can be configured to produce either a turn‐off or turn‐on switch to control the degree of CHA, allowing target concentration to be determined in a quantitative manner. We demonstrate this approach by creating a sensor for E. coli that could detect as low as 50 E. coli cells mL^?1 within 85 min and offers an amplified bacterial detection method that does not require a protein enzyme.     

Genetically Encoded Ratiometric RNA‐Based Sensors for Quantitative Imaging of Small Molecules in Living Cells

Precisely determining the intracellular concentrations of metabolites and signaling molecules is critical in studying cell biology. Fluorogenic RNA‐based sensors have emerged to detect various targets in living cells. However, it is still challenging to apply these genetically encoded sensors to quantify the cellular concentrations and distributions of targets. Herein, using a pair of orthogonal fluorogenic RNA aptamers, DNB and Broccoli, we engineered a modular sensor system to apply the DNB‐to‐Broccoli fluorescence ratio to quantify the cell‐to‐cell variations of target concentrations. These ratiometric sensors can be broadly applied for live‐cell imaging and quantification of metabolites, signaling molecules, and other synthetic compounds.     

A Surface Plasmon Resonance Sensor Platform Coupled with Gold Nanoparticle Probes for Unpurified Nucleic Acids Detection

In this work, a surface plasmon resonance sensor system was designed and implemented for determination of nucleic acids in unpurified samples. First, through blocking non-specific interaction sites on the sensor surface to reduce non-specific adsorption from unpurified sample matrix, it was determined that at the optimal BSA concentration of 100 µg/ml the non-specific interaction can be reduced by 50%, although improvement for direct detection of nucleic acids in unpurified sample is required. Second, bearing nonspecific adsorption onto gold films, nucleic acids adsorbed on sensor surface in unpurified sample matrix were detected through a secondary hybridization approach. Using DNA-lined AuNPs shows the new SPR sensor can be applied for the determination of target ssDNA with a detection range of 0.1–10 µM for targets in purified and 1–10 µM in unpurified samples, respectively. Results imply that the new SPR sensor system is promising for specific and convenient analysis of nucleic acids directly in unpurified samples. Development of the new SPR sensor technique can have applications in fast field diagnostics and monitoring.     

An enzyme-based E-DNA sensor for sequence-specific detection of femtomolar DNA targets

In this work, we report an enzyme-based E-DNA sensor for the sequence-specific detection of nucleic acids. This DNA sensor employs a "stem-loop" DNA probe dually labeled with biotin and digoxigenin (DIG). The probe is immobilized at an avidin-modified electrode surface via the biotin-avidin bridge, and the DIG serves as an affinity tag for the enzyme binding. In the initial state of the sensor, the probe adopts the stem-loop structure, which shields DIG from being approached by a bulky horseradish peroxidase-linked-anti-DIG antibody (anti-DIG-HRP) due to the steric effect. After hybridization, the probe undergoes a significant conformational change, forcing DIG away from the electrode. As a result, the DIG label becomes accessible by the anti-DIG-HRP, and the target hybridization event can be sensitively transduced via the enzymatically amplified electrochemical current signal. By using this new strategy, we demonstrate that the prototype E-DNA sensor has been able to detect as low as femtomolar DNA targets with excellent differentiation ability for even single mismatches.     

Design of a highly sensitive and specific nucleotide sensor based on photon upconverting particles

We have designed and developed a novel sensor that reports the presence of specific nucleic acids in solutions, based on photon upconverting particles. The significantly high signal-to-noise ratio of photon upconverting particles leads to high sensitivity of the sensor. The sensor does not suffer from photobleaching. It also displays high specificity and self-calibrating capability. We expect nucleotide sensors of this type to be effective for applications in both DNA/RNA detection and protein-DNA/RNA interaction studies.     

E-DNA sensors for convenient, label-free electrochemical detection of hybridization

We review the development of reagentless, electrochemical sensors for the sequence-specific detection of nucleic acids that are based on the target-induced folding or unfolding of electrode-bound oligonucleotides. These devices, which are sometimes termed E-DNA sensors, are comprised of an oligonucleotide probe modified on one terminus with a redox reporter and attached to an electrode at the other. Hybridization of this probe DNA to a target oligonucleotide influences the rate at which the redox reporter collides with the electrode, leading to a detectable change in redox current. Because all sensing elements of this method are strongly linked to the interrogating electrode, E-DNA sensors are label-free, operationally convenient and readily reusable. As E-DNA signaling is predicated on a binding-specific change in the dynamics of the probe DNA (rather than simply monitoring the adsorption of a target to the sensor surface) and because electroactive contaminants (interferents) are relatively rare, this class of sensors is notably resistant to false positives arising from the non-specific adsorption of interferents, and performs well even when challenged directly with blood serum, soil and other complex sample matrices. We review the history of and recent advances in this promising DNA and RNA detection approach.     

Novel Sensing Assembly Comprising Engineered Gold Dendrites and MWCNT‐AuNPs Nanohybrid for Acetaminophen Detection in Human Urine

A layered nanohybrid comprising of multi walled carbon nanotubes(MWCNT)‐gold nanoparticles (AuNPs) has been designed as a matrix for the development of Au dendritic nanostructures (AuDN) with enhanced catalytic activity. The developed sensor matrix was thoroughly characterized by scanning electron microscope (SEM), transmission electron microscope (TEM), and energy dispersive X‐ray spectroscopy (EDX). The developed sensor probe MWCNT‐AuNPs/AuDN over glassy carbon electrode (GCE) was used for the label free detection of acetaminophen (AP), a commonly used drug associated with hepatotoxicity when overdosed, as a model molecule. The final sensor probe was characterized by cyclic voltammetry (CV), electrochemical impedance spectroscopy (EIS), linear sweep voltammetry (LSV), and differential pulse voltammetry (DPV). The sensor shows excellent analytical performances with a linear dynamic range (LDR) of 100 to 7500 nM, and a low limit of detection (LOD) of 2.12 (±0.03) nM, which is better than recently reported AP sensors. The practical application / clinical possibilities of the final sensor were evaluated by real sample analysis in human urine by spike and recovery method, where the AP recoveries were found in between 92 % to 96 %. The sensor probe shows negligible response towards co‐existing interfering molecules like glucose, urea, uric acid and various amino acids, which are commonly found in real samples (p<0.001, n=3). The shelf life of the sensor probe was evaluated and found to be stable for 8 weeks. The fabricated sensor probe using MWCNT‐AuNPs/AuDN is easy to fabricate, simple, robust, and able to detect AP in urine with high recoveries shows its possibilities to be used in clinical settings.     

A Peptide Nucleic Acid (PNA) Heteroduplex Probe Containing an Inosine–Cytosine Base Pair Discriminates a Single‐Nucleotide Difference in RNA

Selective discrimination of a single‐nucleotide difference in single‐stranded DNA or RNA remains a challenge with conventional DNA or RNA probes. A peptide nucleic acid (PNA)‐derived probe, in which PNA forms a pseudocomplementary heteroduplex with inosine‐containing DNA or RNA, effectively discriminates a single‐nucleotide difference in a closely related group of sequences of single‐stranded DNA and/or RNA. The pseudocomplementary PNA heteroduplex is easily converted to a fluorescent probe that distinctively detects a member of highly homologous let‐7 microRNAs.     

Chemoselective Modification of Vinyl DNA by Triazolinediones

A new method for the post‐synthetic modification of nucleic acids was developed that involves mixing a phenyl triazolinedione (PTAD) derivative with DNA containing a vinyl nucleobase. The resulting reactions proceeded through step‐wise mechanisms, giving either a formal [4+2] cycloaddition product, or, depending on the context of nucleobase, PTAD addition along with solvent trapping to give a secondary alcohol in water. Catalyst‐free addition between PTAD and the terminal alkene of 5‐vinyl‐2′‐deoxyuridine (VdU) was exceptionally fast, with a second‐order rate constant of 2×10³ m ⁻¹ s⁻¹. PTAD derivatives selectively reacted with VdU‐containing oligonucleotides in a conformation‐selective manner, with higher yields observed for G‐quadruplex versus duplex DNA. These results demonstrate a new strategy for copper‐free bioconjugation of DNA that can potentially be used to probe nucleic acid conformations in cells.     

Monitoring Dissociation Kinetics during Electrophoretic Focusing to Enable High‐Specificity Nucleic Acid Detection

A wide range of medical conditions can be diagnosed through sequence‐specific analysis of nucleic acids. However, a major challenge remains in detecting a specific target in samples containing a high concentration of mismatching sequences. A single‐step kinetic homogenous (free solution) assay is presented in which free sequence‐specific probes are continuously separated from probe–target hybrids during electrophoretic sample focusing, allowing monitoring of dissociation kinetics. Under these conditions, the different kinetics of targets versus mismatches result in distinct patterns of the signal (for example, linear increase for target versus exponential decay for mismatch), allowing the detection of desired sequences even in the presence of high background nucleic acid content. Additionally, an analytical model provides insight into the underlying dynamics, and allows design of assays based on this mechanism.     

Module Assembly Strategy for Single-Cell Nucleic Acid Imaging at the Sub-Molecule Level

Single-cell imaging has unique advantages of maintaining the in situ physiological state, morphology, and microenvironment, becoming a powerful tool to unravel the nature of intracellular nucleic acids. The analysis of nucleic acids unprecedentedly demands the sub-molecule details at segment or subunit, secondary structure and monomer levels, instead of just probing the sequence and the abundance of nucleic acids. Detection of nucleic acids at the sub-molecule level requires higher specificity and higher sensitivity, which becomes a new challenge in nucleic acid analysis. Herein, we summarize the recent progress in the design and the application of single-cell nucleic acid imaging methods at the sub-molecule level, including the visualization of RNA splicing variants, RNA G-quadruplexes in an individual gene, single nucleotide variation of mitochondrial DNA, and RNA m⁶A methylation. Remarkably, we highlight the key strategy, “Module Assembly”, for high-performance molecular recognition and demonstrate the required improvements in future research.     

Recognition of Nucleic Acid Junctions Using Triptycene‐Based Molecules

The modulation of nucleic acids by small molecules is an essential process across the kingdoms of life. Targeting nucleic acids with small molecules represents a significant challenge at the forefront of chemical biology. Nucleic acid junctions are ubiquitous structural motifs in nature and in designed materials. Herein, we describe a new class of structure‐specific nucleic acid junction stabilizers based on a triptycene scaffold. Triptycenes provide significant stabilization of DNA and RNA three‐way junctions, providing a new scaffold for the development of nucleic acid junction binders with enhanced recognition properties. Additionally, we report cytotoxicity and cell uptake data in two human ovarian carcinoma cell lines.