Electrostatic-assembly-driven formation of supramolecular rhombus microparticles and their application for fluorescent nucleic acid detection

In this paper, we report on the large-scale formation of supramolecular rhombus microparticles (SRMs) driven by electrostatic assembly, carried out by direct mixing of an aqueous HAuCl(4) solution and an ethanol solution of 4,4'-bipyridine at room temperature. We further demonstrate their use as an effective fluorescent sensing platform for nucleic acid detection with a high selectivity down to single-base mismatch. The general concept used in this approach is based on adsorption of the fluorescently labeled single-stranded DNA (ssDNA) probe by SRM, which is accompanied by substantial fluorescence quenching. In the following assay, specific hybridization with its target to form double-stranded DNA (dsDNA) results in desorption of ssDNA from SRM surface and subsequent fluorescence recovery.     

Conjugation polymer nanobelts: a novel fluorescent sensing platform for nucleic acid detection

In this article, we report on the facile and rapid synthesis of conjugation polymer poly(p-phenylenediamine) nanobelts (PNs) via room temperature chemical oxidation polymerization of p-phenylenediamine monomers by ammonium persulfate in aqueous medium. We further demonstrate the proof-of-concept that PNs can be used as an effective fluorescent sensing platform for nucleic acid detection for the first time. The general concept used in this approach lies in the facts that the adsorption of the fluorescently labeled single-stranded DNA probe by PN leads to substantial fluorescence quenching, followed by specific hybridization with the complementary region of the target DNA sequence. This results in desorption of the hybridized complex from PN surface and subsequent recovery of fluorescence. We also show that the sensing platform described herein can be used for multiplexing detection of nucleic acid sequences.     

Carbon nanoparticle for highly sensitive and selective fluorescent detection of mercury(II) ion in aqueous solution

In this article, carbon nanoparticles (CNPs) were used as a novel fluorescent sensing platform for highly sensitive and selective Hg(2+) detection. To the best of our knowledge, this is the first example of CNPs obtained from candle soot used in this type of sensor. The general concept used in this approach is based on that adsorption of the fluorescently labeled single-stranded DNA (ssDNA) probe by CNP via π-π stacking interactions between DNA bases and CNP leads to substantial dye fluorescence quenching; however, in the presence of Hg(2+), T-Hg(2+)-T induced hairpin structure does not adsorb on CNP and thus retains the dye fluorescence. A detection limit as low as 10nM was achieved. The present CNP-based biosensor for Hg(2+) detection exhibits remarkable specificity against other possible metal ions. Furthermore, superior selectivity performance was observed when Hg(2+) detection was carried out in the presence of a large amount of other interference ions. Finally, in order to evaluate its potential practical application, Hg(2+) detection was conducted with the use of lake water other than pure buffer and it is believed that it holds great promise for real sample analysis upon further development.     

Acridone-tagged DNA as a new probe for DNA detection by fluorescence resonance energy transfer and for mismatch DNA recognition

Acridone is highly fluorescent and stable against photodegradation, oxidation, and heat. It is also a small molecule with no charge, making it a promising fluorescent agent for use in a DNA probe. Thus, we have prepared 5'-terminal acridone-labeled DNAs by post-modification, and have examined their photophysical properties and their use as donors for a fluorescence resonance energy transfer (FRET) system in combination with a 3'-terminal dabcyl-tagged DNA as an acceptor, which can detect the target DNA by emission-quenching caused by FRET. The FRET with an acridone and dabcyl pair has been found to complement that with fluorescence and dabcyl and other fluorescence-quencher pairs. Significant amounts of quenching of the acridone emissions by guanine in the DNA were observed when guanine was close to acridone, which can be applied as a quencher-free probe for the detection of special sequence of DNA. The DNA bearing acridone at the C5 position of inner thymidine could discriminate the opposite T-T base mismatch, although enhancement of discrimination ability is needed for the practical use of SNP typing.     

Real‐time nucleic acid sequence–based amplification (NASBA) using an adenine‐induced quenching probe and an intercalator dye

Aims: We found that an adenine base caused fluorescence quenching of a fluorescein (FL)‐labelled probe in DNA:RNA hybrid sequences, and applied this finding to a nucleic acid sequence–based amplification (NASBA) method. Methods and Results: The present NASBA method employed a probe containing an FL‐modified thymine at its 3′ end and ethidium bromide (EtBr) on the basis of a combination of adenine‐induced quenching and fluorescence resonance energy transfer (FRET) between the FL donor and EtBr acceptor. This NASBA was used to detect Shiga toxin (STX) stx‐specific mRNA in STX‐producing Escherichia coli, demonstrating rapid quantification of the target gene with high sensitivity. Conclusion: Although the inherent quenching effect of adenine was inferior to that of guanine, FRET between the FL and EtBr moieties enhanced the adenine‐induced quenching, allowing rapid and sensitive real‐time NASBA detection. Significance and Impact of the Study: This study gives a novel real‐time diagnostic system based on NASBA for a sensitive mRNA (or viral RNA) detection.     

Rationally designed fluorescently labeled sulfate-binding protein mutants: evaluation in the development of a sensing system for sulfate

Periplasmic binding proteins from E. coli undergo large conformational changes upon binding their respective ligands. By attaching a fluorescent probe at rationally selected unique sites on the protein, these conformational changes in the protein can be monitored by measuring the changes in fluorescence intensity of the probe which allow the development of reagentless sensing systems for their corresponding ligands. In this work, we evaluated several sites on bacterial periplasmic sulfate-binding protein (SBP) for attachment of a fluorescent probe and rationally designed a reagentless sensing system for sulfate. Eight different mutants of SBP were prepared by employing the polymerase chain reaction (PCR) to introduce a unique cysteine residue at a specific location on the protein. The sites Gly55, Ser90, Ser129, Ala140, Leu145, Ser171, Val181, and Gly186 were chosen for mutagenesis by studying the three-dimensional X-ray crystal structure of SBP. An environment-sensitive fluorescent probe (MDCC) was then attached site-specifically to the protein through the sulfhydryl group of the unique cysteine residue introduced. Each fluorescent probe-conjugated SBP mutant was characterized in terms of its fluorescence properties and Ser171 was determined to be the best site for the attachment of the fluorescent probe that would allow for the development of a reagentless sensing system for sulfate. Three different environment-sensitive fluorescent probes (1,5-IAEDANS, MDCC, and acylodan) were studied with the SBP171 mutant protein. A calibration curve for sulfate was constructed using the labeled protein and relating the change in the fluorescence intensity with the amount of sulfate present in the sample. The detection limit for sulfate was found to be in the submicromolar range using this system. The selectivity of the sensing system was demonstrated by evaluating its response to other anions. A fast and selective sensing system with detection limits for sulfate in the submicromolar range was developed.     

Copper nanoclusters: an efficient fluorescence sensing platform for quinoline yellow

Fluorescence quenching behavior of artificial food colorant quinoline yellow (QY), on interaction with l ‐cysteine stabilized copper nanoclusters (l ‐Cys‐CuNCs) is investigated in this work. For this purpose, l ‐cysteine stabilized CuNCs were synthesized and characterized using various analytical techniques. Results demonstrated that the synthesized probe (size ~2 nm) had very promising optical features such as bright blue fluorescence, significant quantum yield and excellent photostability. l ‐Cys‐CuNCs can function as a fluorescence sensor by selectively sensing QY among other yellow colorants, giving a detection limit as low as 0.11 μM. The developed sensor exhibited a linear concentration range from 5.50 to 0.20 μM. The developed fluorescence assay was successfully applied for testing commercial samples, thereby making this sensing strategy significant for quality control of food stuffs.     

An exonuclease III and graphene oxide-aided assay for DNA detection

We have developed a novel DNA assay based on exonuclease III (ExoIII)-induced target recycling and the fluorescence quenching ability of graphene oxide (GO). This assay consists of a linear DNA probe labeled with a fluorophore in the middle. Introduction of target sequence induces the exonuclease III catalyzed probe digestion and generation of single nucleotides. After each cycle of digestion, the target is recycled to realize the amplification. Finally, graphene oxide is added to quench the remaining probes and the signal from the resulting fluorophore labeled single nucleotides is detected. With this approach, a sub-picomolar detection limit can be achieved within 40 min at 37°C. The method was successfully applied to multicolor DNA detection and the analysis of telomerase activity in extracts from cancer cells.     

Target‐Activated DNA Polymerase Activity for Sensitive RNase H Activity Assay

Herein, the ribonuclease H (RNase H) activity assay based on the target‐activated DNA polymerase activity is described. In this method, a detection probe composed of two functional sequences, a binding site for DNA polymerase and a catalytic substrate for RNase H, serves as a key component. The detection probe, at its initial state, suppresses the DNA polymerase activity, but it becomes destabilized by RNase H, which specifically hydrolyzes RNA in RNA/DNA hybrid duplexes. As a result, DNA polymerase recovers its activity and initiates multiple primer extension reactions in a separate TaqMan probe‐based signal transduction module, leading to a significantly enhanced fluorescence “turn‐on” signal. This assay can detect RNase H activity as low as 0.016 U mL^?1 under optimized conditions. Furthermore, its potential use for evaluating RNase H inhibitors, which have been considered potential therapeutic agents against acquired immune deficiency syndrome (AIDS), is successfully explored. In summary, this approach is quite promising for the sensitive and accurate determination of enzyme activity and inhibitor screening.     

Optical detection of DNA hybridization based on fluorescence quenching of tagged oligonucleotide probes by gold nanoparticles

A novel system for the detection of DNA hybridization in a homogeneous format is developed. This method is based on fluorescence quenching by gold nanoparticles used as both nanoscaffolds for the immobilization of capture sequences and nanoquenchers of fluorophores attached to detection sequences. The oligonucleotide-functionalized gold nanoparticles are synthesized by derivatizing the colloidal gold solution with 5'-thiolated 12-base oligonucleotides. Introduction of sequence-specific target DNAs (24 bases) into the mixture containing dye-tagged detection sequences and oligonucleotide-functionalized gold nanoparticles results in the quenching of carboxytetramethylrhodamine-labeled DNA fluorescence because DNA hybridization occurs and brings fluorophores into close proximity with oligonucleotide-functionalized gold nanoparticles. The quenching efficiency of fluorescence increases with the target DNA concentration and provides a quantitative measurement of sequence-specific DNA in sample. A linearity is obtained within the range from 1.4 to 92 nM. The target sequence is detected down to 2 nM. This new system not only overcomes many of the drawbacks inherent in radioisotopic measurement or enzyme-linked assay but also avoids the requirement for the stem-loop structure compared with conventional molecular beacons. Furthermore, the background signal that is defined as fluorescence quenching arising from electrostatic attraction between positively charged fluorophores and negatively charged gold nanoparticles is comparatively low due to electrostatic repulsion between negatively charged oligonucleotides. In addition, this is a homogeneous assay that can offer the potential to be monitored in real time, be amenable to automation, eliminate washing steps, and reduce the risk of contamination.     

Y-shaped probe for convenient and label-free detection of microRNA-21 in vitro

A simple, highly selective, and label-free microRNA (miRNA) detection method based on l-alanine-reduced graphene oxide fluorescence quenching with a Y-shaped probe is proposed. The Y-shaped probe was synthesized by silver nitrate and a cytosine-rich molecular beacon (MB) in two terminals through sodium borohydride reduction, which generated a stronger fluorescent signal than ordinary DNA-templated silver nanoclusters (AgNCs). Meanwhile, the Y-shaped probe contained a single-stranded loop structure, which could be superbly adsorbed onto the surface of reduced graphene oxide (RGO) via π–π stacking interaction, and this special structure of the probe was designed to improve its sensitivity and selectivity. In addition, the quenching capacities of graphene oxide (GO) and RGO were compared in this research. The strong interaction between nucleobases of the loop structure and RGO nanosheet made the MB-AgNCs-RGO system exhibit minimal background fluorescence. In the presence of miRNA-21, the loop structure of the Y-shaped probe can hybridize with target miRNA-21; the molecular beacon encapsulated probe is far away from RGO surface and produces a detectable signal. The MB-AgNCs based approach provides a label-free avenue to detect miRNA with high selectivity and good reproducibility, which has a promising application in early clinical diagnosis and biomedical research.     

Efficient detection of secondary structure folded nucleic acids related to Alzheimer's disease based on junction probes

Single stranded DNA often forms stable secondary structures under physiological conditions. These DNA secondary structures play important physiological roles. However, the analysis of such secondary structure folded DNA is often complicated because of its high thermodynamic stability and slow hybridization kinetics. In this article, we demonstrate that Y-shaped junction probes could be used for rapid and highly efficient detection of secondary structure folded DNA. Our approach contained a molecular beacon (MB) probe and an assistant probe. In the absence of target, the MB probe failed to hybridize with the assistant probe. Whereas, the MB probe and the assistant probe could cooperatively unwind the secondary structure folded DNA target to form a ternary Y-shaped junction structure. In this condition, the MB probe was also opened, resulting in separating the fluorophores from the quenching moiety and emitting the fluorescence signal. This approach allowed for the highly sensitive detection of secondary structure folded DNA target, such as a tau specific DNA fragment related to Alzheimer's disease in this case. Additionally, this approach showed strong SNPs identifying capability. Furthermore, it was noteworthy that this newly proposed approach was capable of detecting secondary structure folded DNA target in cell lysate samples.     

One‐step synthesis of nitrogen,boron co‐doped fluorescent carbon nanoparticles for glucose detection

Heteroatom‐doped carbon nanoparticles (CNPs) have attracted considerable attention due to an effective improvement in their intrinsic properties. Here, a facile and simple synthesis of nitrogen, boron co‐doped carbon nanoparticles (NB‐CNPs) from a sole precursor, 3‐aminophenylboronic acid, was performed via a one‐step solid‐phase approach. Because of the presence of boronic acid, NB‐CNPs can be used directly as a fluorescent probe for glucose. Based on a boronic acid‐triggered specific reaction, we developed a simple NB‐CNP probe without surface modification for the detection of glucose. When glucose was introduced, the fluorescence of NB‐CNPs was suppressed through a surface‐quenching states mechanism. Obvious fluorescence quenching allowed the highly sensitive determination of glucose with a limit of detection of 1.8 μM. Moreover, the proposed method has been successfully used to detect glucose in urine from people with diabetes, suggesting potential application in sensing glucose.     

A portable generic DNA bioassay system based on in situ oligonucleotide synthesis and hybridization detection

In this study, we present a portable and generic DNA bioassay system based on in situ oligonucleotide synthesis followed by hybridization based detection. The system include two main parts, an oligonucleotide synthesizer and a fluorescence detection system. The oligonucleotide synthesizer is based on microfluidic technology and capable of synthesizing any desired oligonucleotide which can be either used as a primer for PCR based detection (external) or a probe for hybridization based detection (integrated) of a target DNA analyte. The oligonucleotide sequence can be remotely sent to the system. The integrated fluorescence detection system is based on a photodiode to detect Texas Red fluorophore as low as 0.5 fmol. The complete system, integrating the oligonucleotide synthesizer and fluorescence detection system, was successfully used to distinguish DNA from two different bacteria strains. The presented generic portable instrument has the potential to detect any desired DNA target sequence in the field. Potential applications are for homeland security and fast responses to emerging bio-threats.     

Characterization and applications of CataCleave probe in real-time detection assays

Cycling probe technology (CPT), which utilizes a chimeric DNA-RNA-DNA probe and RNase H, is a rapid, isothermal probe amplification system for the detection of target DNA. Upon hybridization of the probe to its target DNA, RNase H cleaves the RNA portion of the DNA/RNA hybrid. Utilizing CPT, we designed a catalytically cleavable fluorescence probe (CataCleave probe) containing two internal fluorophores. Fluorescence intensity of the probe itself was weak due to F?rster resonance energy transfer. Cleavage of the probe by RNase H in the presence of its target DNA caused enhancement of donor fluorescence, but this was not observed with nonspecific target DNA. Further, RNase H reactions with CataCleave probe exhibit a catalytic dose-dependent response to target DNA. This confirms the capability for the direct detection of specific target DNA through a signal amplification process. Moreover, CataCleave probe is also ideal for detecting DNA amplification processes, such as polymerase chain reaction (PCR) and isothermal rolling circle amplification (RCA). In fact, we observed signal enhancement proportional to the amount of RCA product formed. We were also able to monitor real-time PCR by measuring enhancement of donor fluorescence. Hence, CataCleave probe is useful for real-time monitoring of both isothermal and temperature-cycling nucleic acid amplification methods.     

Reusable evanescent wave DNA biosensor for rapid, highly sensitive, and selective detection of mercury ions

Mercury ions (Hg(2+)) are a highly toxic and ubiquitous pollutants requiring rapid and sensitive on-site detection methods in the environment and foods. Herein, we report an envanescent wave DNA-based biosensor for rapid and very sensitive Hg(2+) detection based on a direct structure-competitive detection mode. In this system, a DNA probe covalently immobilized onto a fiber optic sensor contains a short common oligonucleotide sequences that can hybidize with a fluorescently labeled complementary DNA. The DNA probe also comprises a sequence of T-T mismatch pairs that binds with Hg(2+) to form a T-Hg(2+)-T complex by folding of the DNA segments into a hairpin structure. With a structure-competitive mode, a higher concentration of Hg(2+) leads to less fluorescence-labeled cDNA bound to the sensor surface and thus to lower fluorescence signal. The total analysis time for a single sample, including the measurement and surface regeneration, was under 6 min with a Hg(2+) detection limit of 2.1 nM. The high specificity of the sensor was demonstrated by evaluating its response to a number of potentially interfering metal ions. The sensor's surface can be regenerated with a 0.5% SDS solution (pH 1.9) over 100 times with no significant deterioration of performance. This platform is potentially applicable to detect other heavy metal ions or small-molecule analytes for which DNA/aptamers can be used as specific sensing probes.     

Masking oligonucleotides improve sensitivity of mutation detection based on guanine quenching

Guanine quenching of a fluorescence-labeled DNA probe is a powerful tool for detecting a mutation in a targeted site of a DNA strand. However, a different guanine adjacent to a targeted site can interfere with detection of a point mutation, resulting in unsatisfactory sensitivity. In the current study, we developed a simple method to improve sensitivity of the guanine quenching method using a masking DNA oligonucleotide. The simple addition of a masking DNA oligonucleotide was found to mask the interference of a different guanine in a target oligonucleotide on fluorescence and to enhance difference in the quenching ratio between wild-type and mutant oligonucleotides. Based on this strategy, we succeeded in discriminating various mutations from the wild-type YMDD motif of the hepatitis B virus DNA polymerase gene using guanine quenching with a masking oligonucleotide.     

A versatile graphene-based fluorescence "on/off" switch for multiplex detection of various targets

We have designed a versatile molecular beacon (MB)-like probe for the multiplex sensing of targets such as sequence-specific DNA, protein, metal ions and small molecule compounds based on the self-assembled ssDNA-graphene oxide (ssDNA-GO) architecture. The probe employs fluorescence "on/off" switching strategy in a single step in homogeneous solution. Compared to traditional molecular beacons, the proposed design is simple to prepare and manipulate and has little background interference, but still gives superior sensitivity and rapid response. More importantly, this ssDNA-GO architecture can serve as a universal beacon platform by simply changing the types of ssDNA sequences for the different targets. In this work, the ssDNA-GO architecture probe has been successfully applied in the multiplex detection of sequence-specific DNA, thrombin, Ag(+), Hg(2+) and cysteine, and the limit of detection was 1 nM, 5 nM, 20 nM, 5.7 nM and 60 nM, respectively. The results demonstrate that the ssDNA-GO architecture can be an excellent and versatile platform for sensing multiplex analytes, easily replacing the universal molecular beacon.     

DNA detection by strand displacement amplification and fluorescence polarization with signal enhancement using a DNA binding protein.

Strand displacement amplification (9SDA) is an isothermal in vitro method of amplifying a DNA sequence prior to its detection. We have combined SDA with fluorescence polarization detection. A 5'-fluorescein-labelled oligodeoxynucleotide detector probe hybridizes to the amplification product that rises in concentration during SDA and the single- to double strand conversion is monitored through an increase in fluorescence polarization. Detection sensitivity can be enhanced by using a detector probe containing an EcoRI recognition sequence at its 5'-end that is not homologous to the target sequence. During SDA the probe is converted to a fully double-stranded form that specifically binds a genetically modified form of the endonuclease EcoRI which lacks cleavage activity but retains binding specificity. We have applied this SDA detection system to a target sequence specific for Mycobacterium tuberculosis.     

Design of a sandwich-mode amperometric biosensor for detection of PML/RARα fusion gene using locked nucleic acids on gold electrode

In this study, a novel DNA electrochemical probe (locked nucleic acid, LNA) was designed and involved in constructing an electrochemical DNA biosensor for detection of promyelocytic leukemia/retinoic acid receptor alpha (PML/RARα) fusion gene in acute promyelocytic leukemia for the first time. This biosensor was based on a 'sandwich' sensing mode, which involved a pair of LNA probes (capture probe immobilized at electrode surface and biotinyl reporter probe as an affinity tag for streptavidin-horseradish peroxidase (streptavidin-HRP). Since biotin can be connected with streptavidin-HRP, this biosensor offered an enzymatically amplified electrochemical current signal for the detection of target DNA. In the simple hybridization system, DNA fragment with its complementary DNA fragment was evidenced by amperometric detection, with a detection limit of 74 fM and a linear response range of 0.1-10 pM for synthetic PML/RARα fusion gene in acute promyelocytic leukemia (APL). Otherwise, the biosensor showed an excellent specificity to distinguish the complementary sequence and different mismatch sequences. The new pattern also exhibited high sensitivity and selectivity in mixed hybridization system.