Principal factors that determine the extension of detection range in molecular beacon aptamer/conjugated polyelectrolyte bioassays

A strategy to extend the detection range of weakly-binding targets is reported that takes advantage of fluorescence resonance energy transfer (FRET)-based bioassays based on molecular beacon aptamers (MBAs) and cationic conjugated polyelectrolytes (CPEs). In comparison to other aptamer-target pairs, the aptamer-based adenosine triphosphate (ATP) detection assays are limited by the relatively weak binding between the two partners. In response, a series of MBAs were designed that have different stem stabilities while keeping the constant ATP-specific aptamer sequence in the loop part. The MBAs are labeled with a fluorophore and a quencher at both termini. In the absence of ATP, the hairpin MBAs can be opened by CPEs via a combination of electrostatic and hydrophobic interactions, showing a FRET-sensitized fluorophore signal. In the presence of ATP, the aptamer forms a G-quadruplex and the FRET signal decreases due to tighter contact between the fluorophore and quencher in the ATP/MBA/CPE triplex structure. The FRET-sensitized signal is inversely proportional to [ATP]. The extension of the detection range is determined by the competition between opening of the ATP/MBA G-quadruplex by CPEs and the composite influence by ATP/aptamer binding and the stem interactions. With increasing stem stability, the weak binding of ATP and its aptamer is successfully compensated to show the resistance to disruption by CPEs, resulting in a substantially broadened detection range (from millimolar up to nanomolar concentrations) and a remarkably improved limit of detection. From a general perspective, this strategy has the potential to be extended to other chemical- and biological-assays with low target binding affinity.     

Label Free Determination of Potassium Ions Using Crystal Violet and Thrombin-Binding Aptamer

A label-free method for sensitive determination of potassium ions was developed. The most commonly studied thrombin-binding aptamer was used as the molecular probe and crystal violet was chosen as a fluorescence signal reporter. The fluorescence of crystal violet was significantly enhanced when the crystal violet solution was mixed with the single-stranded thrombin-binding aptamer. However, in the presence of potassium ions, due to the formation of potassium induced G-quadruplex structures, the fluorescence decreased. Potassium ions were determined using the change in fluorescence. The conformational transformation was investigated by circular dichroism, and interferences caused by sodium ions were studied. This label-free method offers a simple procedure that induces minimum effects on the G-quadruplex formation. Under the optimized conditions, the method exhibited a linear range from 30–420 µM for potassium ions with a detection limit of 6 µM.     

A highly selective bicyclic fluoroionophore for the detection of lithium ions

The macrobicyclic molecule, 21-(9-anthrylmethyl)-4,17,13,16-tetraoxa-1,10,21-triazabicyclo [8.8.5]tricosane-19,23-dione, I, was designed, synthesized and characterized as a fluoroionophore for the selective, optical detection of lithium ions. Compound I is based on a bridged diazacrown structure, which provides a semirigid binding framework. Binding takes place by electrostatic interactions between the oxygen atoms of the crown and the cation and is transduced to fluorescence emission from an attached anthracene fluorophore. In a 75:25 dichloromethane/tetrahydrofuran solvent mixture, I acts as an intramolecular electron transfer "off-on" fluorescence switch, exhibiting a greater than 190-fold enhancement in fluorescence emission intensity in the presence of lithium ions. The relative selectivity of I for lithium ions over sodium, potassium and ammonium ions was found to be log K(Li+,Na+) approximately -3.36, log K(Li+,K+) approximately -1.77 and log K(Li+,NH4+) approximately -2.78.     

Aptamer switch probe based on intramolecular displacement

A novel aptamer-based molecular probe design employing intramolecular signal transduction is demonstrated. The probe is composed of three elements: an aptamer, a short, partially cDNA sequence, and a PEG linker conjugating the aptamer with the short DNA strand. We have termed this aptamer probe an "aptamer switch probe", or ASP. The ASP design utilizes both a fluorophore and a quencher which are respectively modified at the two termini of the ASP. In the absence of the target molecule, the short DNA will hybridize with the aptamer, keeping the fluorophore and quencher in close proximity, thus switching off the fluorescence. However, when the ASP meets its target, the binding between the aptamer and the target molecule will disturb the intramolecular DNA hybridization, move the quencher away from the fluorophore, and, in effect, switch on the fluorescence. Both ATP and human alpha-thrombin aptamers were engineered to demonstrate this design, and both showed that fluorescence enhancement could be quantitatively mediated by the addition of various amounts of target molecules. Both of these ASPs presented excellent selectivity and prompt response toward their targets. With intrinsic advantages resulting from its intramolecular signal transduction architecture, the ASP design holds promising potential for future applications, such as biochip and in situ imaging, which require reusability, excellent stability, prompt response, and high sensitivity.     

双链荧光核酸适体探针用于蛋白质的简便快速检测

发展了一种基于双链荧光核酸适体(F-Aptamer)探针的简单快速检测蛋白质的分析方法.该双链荧光Aptamer探针由一条带荧光标记的Aptamer探针和带猝灭标记的互补DNA组成,当靶蛋白存在时,能形成比双链荧光Aptamer探针更稳定的F-Aptamer/蛋白质复合物,并发出荧光,从而实现对蛋白质的简便快速检测,检测线性范围为6~100 nmol/L,检出限为6 nmol/L.该方法设计简单,对核酸适体分子的大小和空间结构没有要求,可作为一种通用的基于F-Aptamer识别机理的蛋白质检测方法.     

Fluorescence detection of potassium ion using the G-quadruplex structure

Oligonucleotides with sequences of human telomere DNA or thrombin binding aptamer (TBA) are known to form tetraplex structures upon binding the K(+) ion. Structural changes associated with the formation of tetraplex assemblies led to the development of potassium-sensing oligonucleotide (PSO) probes, in which two fluorescent dyes were attached to both termini of particular oligonucleotide. The combination of dyes included fluorescence resonance energy transfer (FRET) and excimer emission approaches, and the structural changes upon binding K(+) ion could be monitored by a fluorescence technique. These systems showed a very high preference for K(+) over Na(+) ion, which was suitable for fluorescence imaging of the potassium concentration gradient in a living cell. In the case of human telomere DNA, it was also possible to follow the polymorphism of its tetraplex structures.     

Inhibited aptazyme-based catalytic molecular beacon for amplified detection of adenosine

Combining the inhibited aptazyme and molecular beacon(MB),we developed a versatile sensing strategy for amplified detection of adenosine.In this strategy,the adenosine aptamer links to the 8-17 DNAzyme to form an aptazyme.A short sequence,denoted as inhibitor,is designed to form a duplex spanning the aptamer–DNAzyme junction,which blocks the catalytic function of the DNAzyme.Only in the presence of target adenosine,the aptamer binds to adenosine,thus the inhibitor dissociates from the aptamer portion of the aptazyme and can no longer form the stable duplex required to inhibit the catalytic activity of the aptazyme.The released DNAzyme domain will hybridize to the MB and catalyze the cleavage in the presence of Zn2+,making the fluorophore separate from the quencher and resulting in fluorescence signal.The results showed that the detection method has a dynamic range from 10 nmol/L to 1 nmol/L,with a detection limit of 10 nmol/L.     

Metal-enhanced fluorescence of nano-core–shell structure used for sensitive detection of prion protein with a dual-aptamer strategy

Metal-enhanced fluorescence (MEF) as a newly recognized technology is widespread throughout biological research. The use of fluorophore–metal interactions is recognized to be able to alleviate some of fluorophore photophysical constraints, favorably increase both the fluorophore emission intensity and photostability. In this contribution, we developed a novel metal-enhanced fluorescence (MEF) and dual-aptamer-based strategy to achieve the prion detection in solution and intracellular protein imaging simultaneously, which shows high promise for nanostructure-based biosensing. In the presence of prion protein, core–shell Ag@SiO₂, which are functionalized covalently by single stranded aptamer (Apt1) of prions and Cyanine 3 (Cy3) decorated the other aptamer (Apt2) were coupled together by the specific interaction between prions and the anti-prion aptamers in solution. By adjusting shell thickness of the pariticles, a dual-aptamer strategy combined MEF can be realized by the excitation and/or emission rates of Cy3. It was found that the enhanced fluorescence intensities followed a linear relationship in the range of 0.05–0.30 nM, which is successfully applied to the detection of PrP in mice brain homogenates.     

A fluorescence aptasensor based on DNA charge transport for sensitive protein detection in serum

A novel fluorescence aptasensor based on DNA charge transport for sensitive protein detection has been developed. A 15nt DNA aptamer against thrombin was used as a model system. The aptamer was integrated into a double strand DNA (dsDNA) that was labeled with a hole injector, naphthalimide (NI), and a fluorophore, Alexa532, at its two ends. After irradiation by UV light, the fluorescence of Alexa532 was bleached due to the oxidization of Alexa532 by the positive charge transported from naphthalimide through the dsDNA. In the presence of thrombin, the binding of thrombin to the aptamer resulted in the unwinding of the dsDNA into ssDNA, which led to the blocking of charge transfer and the strong fluorescence emission of Alexa532. By monitoring the fluorescence signal change, we were able to detect thrombin in homogeneous solutions with high selectivity and high sensitivity down to 1.2 pM. Moreover, as DNA charge transfer is resistant to interferences from biological contexts, the aptasensor can be used directly in undiluted serum with similar sensitivity as that in buffer. This new sensing strategy is expected to promote the exploitation of aptamer-based biosensors for protein assays in complex biological matrixes.     

A sensitive fluorescence anisotropy method for detection of lead (II) ion by a G-quadruplex-inducible DNA aptamer

Sensitive and selective detection of Pb²⁺ is of great importance to both human health and environmental protection. Here we propose a novel fluorescence anisotropy (FA) approach for sensing Pb²⁺ in homogeneous solution by a G-rich thrombin binding aptamer (TBA). The TBA labeled with 6-carboxytetramethylrhodamine (TMR) at the seventh thymine nucleotide was used as a fluorescent probe for signaling Pb²⁺. It was found that the aptamer probe had a high FA in the absence of Pb²⁺. This is because the rotation of TMR is restricted by intramolecular interaction with the adjacent guanine bases, which results in photoinduced electron transfer (PET). When the aptamer probe binds to Pb²⁺ to form G-quadruplex, the intramolecular interaction should be eliminated, resulting in faster rotation of the fluorophore TMR in solution. Therefore, FA of aptamer probe is expected to decrease significantly upon binding to Pb²⁺. Indeed, we observed a decrease in FA of aptamer probe upon Pb²⁺ binding. Circular dichroism, fluorescence spectra, and fluorescence lifetime measurement were used to verify the reliability and reasonability of the sensing mechanism. By monitoring the FA change of the aptamer probe, we were able to real-time detect binding between the TBA probe and Pb²⁺. Moreover, the aptamer probe was exploited as a recognition element for quantification of Pb²⁺ in homogeneous solution. The change in FA showed a linear response to Pb²⁺ from 10 nM to 2.0 μM, with 1.0 nM limit of detection. In addition, this sensing system exhibited good selectivity for Pb²⁺ over other metal ions. The method is simple, quick and inherits the advantages of aptamer and FA.     

Gold nanoparticle-based homogeneous fluorescent aptasensor for multiplex detection

We developed a homogeneous fluorescence assay for multiplex detection based on the target induced conformational change of DNA aptamers. DNA aptamers were immobilized on quantum dots (QDs), and QDs conjugated ssDNA was adsorbed on the surface of gold nanoparticles (AuNPs) by electrostatic interaction between uncoiled ssDNA and the AuNPs. Subsequently the fluorescence of QDs was effectively quenched by the AuNPs due to fluorescence resonance energy transfer (FRET) of QDs to AuNPs. In the presence of targets, the QDs conjugated aptamers were detached from AuNPs by target induced conformational change of aptamers, consequently the fluorescence of the QDs was recovered proportional to the target concentration. In this study, three different QD/aptamer conjugates were used for multiplex detection of mercury ions, adenosine and potassium ions. In a control experiment, all of the three targets were simultaneously detected with high selectivity.     

Fluorescence signaling of Zr4+ by hydrogen peroxide assisted selective desulfurization of thioamide

Thioamide derivative with a pyrene fluorophore was smoothly transformed to its corresponding amide by Zr(4+) ions in the presence of hydrogen peroxide. The transformation was evidenced by (1)H NMR spectroscopy and the signaling was completed within 10 min after sample preparation. Interference from Ag(+) and Hg(2+) ions in Zr(4+)-selective fluorescence signaling was readily suppressed with the use of Sn(2+) as a reducing additive. Discrimination of Zr(4+) from closely related hafnium, which is a frequent contaminant in commercial zirconium, was not possible. Prominent Zr(4+)-selective turn-on type fluorescence signaling was possible with a detection limit of 4.6 × 10(-6) M in an aqueous 99% ethanol solution.     

Fluorescence Determination of Merucury(II) Using a Thymine Aptamer

A label-free thymine-rich sequence and a molecular beacon were synthesized to construct a highly sensitive and selective fluorescence probe for the determination of mercury(II). The aptamer of the thymine-rich sequence selectively bonded with mercury(II) with an accompanying change in the fluorescence intensity of the molecular beacon due to the higher affinity of the aptamer with mercury(II). The limit of detection was 12.7 nanomolar, and a linear relationship was obtained between the fluorescence and mercury(II) concentrations up to 1 micromolar. The assay was highly selective for the mercury(II) and not significantly affected by other metal ions.     

Target-Dependent Protection of DNA Aptamers against Nucleolytic Digestion Enables Signal-On Biosensing with Toehold-Mediated Rolling Circle Amplification

We report a generalizable strategy for biosensing that takes advantage of the resistance of DNA aptamers against nuclease digestion when bound with their targets, coupled with toehold mediated strand displacement (TMSD) and rolling circle amplification (RCA). A DNA aptamer containing a toehold extension at its 5′-end protects it from 3′-exonuclease digestion by phi29 DNA polymerase (phi29 DP) in a concentration-dependent manner. The protected aptamer can participate in RCA in the presence of a circular template that is designed to free the aptamer from its target via TMSD. The absence of the target leads to aptamer digestion, and thus no RCA product is produced, resulting in a turn-on sensor. Using two different DNA aptamers, we demonstrate rapid and quantitative real-time fluorescence detection of two human proteins: platelet-derived growth factor (PDGF) and thrombin. Sensitive detection of PDGF was also achieved in human serum and human plasma, demonstrating the selectivity of the assay.     

Quenching of fluorophore-labeled DNA oligonucleotides by divalent metal ions: implications for selection, design, and applications of signaling aptamers and signaling deoxyribozymes

Recent years have seen a dramatic increase in the use of fluorescence-signaling DNA aptamers and deoxyribozymes as novel biosensing moieties. Many of these functional single-stranded DNA molecules are either engineered to function in the presence of divalent metal ion cofactors or designed as sensors for specific divalent metal ions. However, many divalent metal ions are potent fluorescence quenchers. In this study, we first set out to examine the factors that contribute to quenching of DNA-bound fluorophores by commonly used divalent metal ions, with the goal of establishing general principles that can guide future exploitation of fluorescence-signaling DNA aptamers and deoxyribozymes as biosensing probes. We then extended these studies to examine the effect of specific metals on the signaling performance of both a structure-switching signaling DNA aptamer and an RNA-cleaving and fluorescence-signaling deoxyribozyme. These studies showed extensive quenching was obtained when using divalent transition metal ions owing to direct DNA-metal ion interactions, leading to combined static and dynamic quenching. The extent of quenching was dependent on the type of metal ion and the concentration of supporting monovalent cations in the buffer, with quenching increasing with the number of unpaired electrons in the metal ion and decreasing with the concentration of monovalent ions. The extent of quenching was independent of the fluorophore, indicating that quenching cannot be alleviated simply by changing the nature of the fluorescent probe. Our results also show that the DNA sequence and the local secondary structure in the region of the fluorescent tag can dramatically influence the degree of quenching by divalent transition metal ions. In particular, the extent of quenching is predominantly determined by the fluorophore location with respect to guanine-rich and duplex regions within the strand sequence. Examination of the effect of both the type and concentration of metal ions on the performance of a fluorescence-signaling aptamer and a signaling deoxyribozyme confirms that judicious choice of divalent transition metal ions is important in maximizing signals obtained from such systems.     

Fluorescent sensing ochratoxin A with single fluorophore-labeled aptamer

We explored a fluorescent strategy for sensing ochratoxin A (OTA) by using a single fluorophore-labeled aptamer for detection of OTA. This method relied on the change of the fluorescence intensity of the labeled dye induced by the specific binding of the fluorescent aptamer to OTA. Different fluorescein labeling sites of aptamers were screened, including the internal thymine bases, 3′-end, and 5′-end of the aptamer, and the effect of the labeling on the aptamer affinity was investigated. Some fluorophore-labeled aptamers showed a signal-on or signal-off response. With the fluorescent aptamer switch, simple, rapid, and selective sensing of OTA at nanomolar concentrations was achieved. OTA spiked in diluted red wine could be detected, showing the feasibility of the fluorescent aptamer for a complex matrix. This method shows potential for designing aptamer sensors for other targets.

Label-Free and Simple G-quadruplex-based Turn-Off Fluorescence Assay for the Detection of Kanamycin

We have developed a label-free and turn-off fluorescence assay for the determination of kanamycin. The detection system consists of an aptamer for specifically recognizing kanamycin and two auxiliary probes functionalized with two GGG repeats at the 3′ or 5′ ends for signal reporting. Two probes both hybridize with the aptamer and then their G-rich sequences combine to form a G-quadruplex. When thioflavin T, a fluorophore, is bound to the G-quadruplex, the fluorescence intensity of the solution dramatically increases. Upon the addition of the kanamycin, the aptamer–kanamycin binding inhibits the hybridization of two probes and aptamer, and restrains the GGG repeats from getting closer to form the G-quadruplex structure, resulting a significant decrease in the fluorescence intensity. The proposed aptamer-based fluorescent sensing platform showed a linear relationship with the concentration of kanamycin from 0.6 to 20.0?nM. The detection limit was determined to be 0.33?nM. The sensing platform provides resistance to interferences from other antibiotics and can be used to efficiently recognize kanamycin in real samples.     

基于双重猝灭原理的分子信标定量检测凝血酶

利用G碱基和有机猝灭基团对荧光基团的双重猝灭作用构建了分子信标,建立了一种基于双重猝灭原理的检测凝血酶的简单方法.此分子信标中荧光基团设计为羧基荧光素(FAM),有机猝灭基团设计为Black Hole Quencher 1(BHQ-1),BHQ-1连接3个含有G碱基的核苷酸,分子信标的环设计为凝血酶的核酸适配体.体系中没有凝血酶时,分子信标呈茎环结构,荧光基团FAM与有机猝灭基团BHQ-1及G碱基相互靠近,FAM的荧光在BHQ-1及G碱基的双重猝灭下,其荧光信号很弱;当体系中有凝血酶存在时,分子信标与凝血酶特异性结合,形成G-四联体结构,茎-环结构被破坏,FAM远离猝灭基团BHQ-1及G碱基,其荧光得到恢复.在最适条件下,体系的荧光强度(△I)与凝血酶的浓度(C)在0.4~40 nmol/L范围内具有良好的线性关系,线性回归方程为△I=24.63C(nmol/L)+13.06(R2=0.9972),检出限为0.18 nmol/L(3σ,n=9).实际血样加标回收率为96.3%~98.7%.     

Fluorescent aptasensor for the determination of Salmonella typhimurium based on a graphene oxide platform

We report on an aptamer with high affinity against Salmonella typhimurium (S. typhimurium) and selected from an enriched oligonucleotide pool by a whole-cell SELEX process in a method for the fluorimetric determination of S. typhimurium using a graphene oxide platform. In the absence of target, the fluorescence was fairly weak as result of the FAM-labeled aptamer adjacent to graphene oxide. If, however, the fluorophore is released from the graphene oxide due to the formation of the target/aptamer complexes, fluorescence intensity is substantially increased. Under the optimum conditions, the assay displays a linear response to bacteria in the concentration range from 1?×?10³ to 1?×?10⁸ CFU·mL^?1, with a detection limit of 100 CFU·mL^?1. The method is selective in that fluorescence is not much enhanced in case of other bacteria. This aptasensor displays higher sensitivity and selectivity than others and is believed to possess a large potential with respect to the rapid detection of bacteria.

基于荧光探针噻唑橙与核酸适体构象变化的钾离子检测

建立了一种基于核酸适体(Aptamer)构象效应和荧光探针噻唑橙(TO)为荧光分子开关进行钾离子检测的光学方法.室温下钾离子可与Aptamer结合形成G-四面体结构,使双链解链变为四面体结构和单链,从而导致TO荧光强度降低.考察了TO浓度、反应温度及反应时间的影响.在最佳实验条件下,钾离子浓度在1.0×10-6 ～2....