A fluorescent aptasensor for analysis of adenosine triphosphate based on aptamer–magnetic nanoparticles and its single‐stranded complementary DNA labeled carbon dots

A new fluorimetric aptasensor was designed for the determination of adenosine triphosphate (ATP) based on magnetic nanoparticles (MNPs) and carbon dots (CDs). In this analytical strategy, an ATP aptamer was conjugated on MNPs and a complementary strand of the aptamer (CS) was labeled with CDs. The aptamer and its CS were hybridized to form a double helical structure. The hybridized aptamers could be used for the specific recognition of ATP in a biological complex matrix using a strong magnetic field to remove the interfering effect. In the absence of ATP, no CDs–CS could be released into the solution and this resulted in a weak fluorescence signal. In the presence of ATP, the target binds to its aptamer and causes the dissociation of the double helical structure and liberation of the CS, such that a strong fluorescence signal was generated. The increased fluorescence signal was proportional to ATP concentration. The limit of detection was estimated to be 1.0 pmol L^–1 with a dynamic range of 3.0 pmol L^–1 to 5.0 nmol L^–1. The specific aptasensor was applied to detect ATP in human serum samples with satisfactory results. Moreover, molecular dynamic simulation (MDS) studies were used to analyze interactions of the ATP molecule with the aptamer.     

Fluorescence detection of adenosine triphosphate through an aptamer-molecular beacon multiple probe

An aptamer-molecular beacon (MB) multiple fluorescent probe for adenosine triphosphate (ATP) assay is proposed in this article. The ATP aptamer was used as a molecular recognition part, and an oligonucleotide (short strand, SS) partially complementary with the aptamer and an MB was used as the other part. In the presence of ATP, the aptamer bound with it, accompanied by the hybridization of MB and SS and the fluorescence recovering. Wherever there is only very weak fluorescence can be measured in the absence of ATP. Based on the relationship of recovering fluorescence and the concentration of ATP, a method for quantifying ATP has been developed. The fluorescence intensity was proportional to the concentration of ATP in the range of 10 to 500 nM with a detection limit of 0.1 nM. Moreover, this method was able to detect ATP with high selectivity in the presence of guanosine triphosphate (GTP), cytidine triphosphate (CTP), and uridine triphosphate (UTP). This method is proved to be simple with high sensitivity, selectivity, and specificity.     

Detection of adenosine using surface-enhanced Raman scattering based on structure-switching signaling aptamer

In the present study, we report a novel sensitive method for the detection of adenosine using surface-enhanced Raman scattering (SERS) sensing platform based on a structure-switching aptamer. First, Ag-clad Au colloids film on a polished gold disc is prepared as enhanced substrate and modified with thiolated capture DNA. The formation of an aptamer/DNA duplex of expanded anti-adenosine aptamer and tetramethylrhodamine-labeled DNA (denoted TMR-DNA) is then developed, in which TMR-DNA could also hybridize completely with capture DNA. The introduction of adenosine thus triggers structure switching of the aptamer from aptamer/DNA duplex to aptamer/target complex. As a result, the released TMR-DNA is captured onto the SERS substrate, resulting in an increase of SERS signal. Under optimized assay conditions, a wide linear dynamic range (2.0x10(-8)M to 2x10(-6)M) was reached with low detection limit (1.0x10(-8)M). Moreover, high selectivity, stability and facile regeneration are achieved. The successful test demonstrates the feasibility of the strategy for adenosine assay.     

Competitive aptamer bioassay for selective detection of adenosine triphosphate based on metal-paired molecular conformational switch and fluorescent gold nanoclusters

A competitive aptamer bioassay was developed for the selective detection of adenosine triphosphate (ATP). The proposed bioassay employed the T-Hg-T induced hairpin-structure as the molecule conformational switch (MCS), aptamer as a specific recognizer, and mercaptoundecanoic acid modified gold nanoclusters (MUA-AuNCs) as a sensitive signal reporter. The T-rich MCS ssDNA with the sequence complementary with that for the aptamer of ATP was bound with Hg(2+) to form the metal-paired hairpin-structure. Addition of the aptamer and its target biomolecule ATP resulted in a competitive aptamer bioassay. The aptamer competed with Hg(2+) to hybridize with T-rich MCS ssDNA, thereby destroyed the hairpin-structure. As a result, the Hg(2+) was released and the signal transduction was achieved. The ATP affected the interaction between aptamer and hairpin-structure, thus mediated the release of Hg(2+), which was sensitively quantified by fluorescent MUA-AuNCs. Under selected conditions, the developed method allowed sensitive and selective detection of ATP with a linear range of 100-2000 nM and a detection limit (3s) of 48 nM. The relative standard deviation for sixty replicate detections of 200 nM ATP was 2.1%, and the recoveries of the spiked ATP in urine samples ranged from 89% to 105%. The developed metal-paired MCS can be easily extended to the sensitive and selective detection of other biomolecules by changing the base sequence of hairpin structure and choosing the corresponding aptamer for the target biomolecule.     

Fluorescent-labeled single-strand ATP aptamer DNA: chemo- and enantio-selectivity in sensing adenosine

One of the intriguing applications of aptamers is sensing molecules. In principle, an aptamer can specifically recognize and bind to a unique ligand, leading to a structural change of an aptamer. By acquiring information for the structural change, the detection of the ligand can be achieved. To design and explore an aptamer molecule to detect adenosine, we have synthesized some ATP aptamer variants labeled with donor and acceptor fluorophores. Although the fluorescent response of the aptamer variants was highly dependent on experimental temperature, we have found one of the variants showing suitable fluorescent response by titration with adenosine. The aptamer variant showed remarkable selectivity for adenosine over the other ribonucleosides. On the other hand, the enantio-specificity of the aptamer variant in the ligand recognition was not enough to selectively detect d-adenosine over l-adenosine.     

A novel,modification-dependent ATP-binding aptamer selected from an RNA library incorporating a cationic functionality

An analogue of uridine triphosphate containing a cationic functional group was incorporated into a degenerate RNA library by enzymatic polymerization. In vitro selection experiments using this library yielded a novel receptor that binds ATP under physiological pH and salt conditions in a manner completely dependent on the presence of the cationic functionality. The consensus sequence and a secondary structure model for the ATP binding site were obtained by the analysis of functional sequences selected from a partially randomized pool based on the minimal parental sequence. Mutational studies of this receptor indicated that several of the modified uridines are critical for ATP binding. Analysis of the binding of ATP analogues revealed that the modified RNA receptor makes numerous contacts with ATP, including interactions with the triphosphate group. In contrast, the aptamer repeatedly isolated from natural RNA libraries does not interact with the triphosphate group of ATP. The incorporation of a cationic amine into nucleic acids clearly allows novel interactions to occur during the molecular recognition of ligands, which carries interesting implications for the RNA world hypothesis. In addition, new materials generated from such functionalized nucleic acids could be useful tools in research and diagnostics.     

Quantification without purification of blood and tissue adenosine by radioimmunoassay

Highly specific anti-adenosine antibodies were produced in rabbits by the injection of N6-carboxymethyl adenosine-methylated serum albumin conjugates. They were used to develop a radioimmunoassay allowing the quantitation of adenosine in the range 0.1-10 pmol per sample. Inosine did not interfere except at 300 times higher concentrations, while AMP (ATP) did not displace the [3H]adenosine tracer even at 10(5) (10(6) ) times higher amounts. Due to the high specificity of the anti-adenosine antibodies, determination of blood and tissue adenosine levels could be performed directly from perchloric acid extracts. Values for human peripheral venous blood from various donors obtained with this procedure varied between 46 and 148 pmol/ml blood. The procedure was also applied to HeLa cultures with low and high intracellular adenosine. The reliability of the method was demonstrated by comparative analyses using HPLC purification of adenosine prior to the radioimmunoassay.     

DNA-Ag nanoclusters as fluorescence probe for turn-on aptamer sensor of small molecules

As promising substitutes for organic dyes and quantum dots, few-atom fluorescent silver nanoclusters (Ag NCs) have recently gained much attention in a wide range from cellular imaging to chemical/biological detection applications owing to their ultrasmall size (<2 nm), excellent photostability, good biocompatibility and water solubility. Herein, we design an aptamer, guanine-rich (G-rich) DNA and Ag NCs nanocomplex to investigate its ability for the detection of small molecules. The design contains two DNA strands which are both chimeric conjugates of the DNA aptamer sequence fragment and G-rich sequence fragment. Using cocaine as a model molecule, the two DNA strands are in free state if there is no cocaine present, and the formed Ag NCs through the reduction of Ag(+) by NaBH(4) show weak fluorescence emission. In the presence of cocaine, however, the two aptamer fragments bind cocaine, which in turn puts the two G-rich sequence fragments in proximity and the fluorescent intensity of DNA-Ag NCs enhances greatly. As a result, DNA-Ag NCs are demonstrated as a novel, cost-effective and turn-on fluorescent probe for the analysis of cocaine, with a detection limit of 0.1 μM. Besides, successful detection of adenosine triphosphate (ATP) with detection limit of 0.2 μM demonstrates its potential to be a general method.     

Quantum dots electrochemical aptasensor based on three-dimensionally ordered macroporous gold film for the detection of ATP

A sensitive electrochemical aptasensor was successfully fabricated for the detection of adenosine triphosphate (ATP) by combining three-dimensionally ordered macroporous (3DOM) gold film and quantum dots (QDs). The 3DOM gold film was electrochemically fabricated with an inverted opal template, making the active surface area of the electrode up to 9.52 times larger than that of a classical bare flat one. 5′-thiolated ATP-binding aptamer (ABA) was first assembled onto the 3DOM gold film via sulfur–gold affinity. Then, 5′-biotinated complementary strand (BCS) was immobilized via hybridization reaction to form the DNA/DNA duplex. Since the tertiary structure of the aptamer was stabilized in the presence of target ATP, the duplex can be denatured to liberate BCS. The reaction was monitored by electrochemical stripping analysis of dissolved QDs which were bound to the residual BCS through biotin-streptavidin system. The decrease of peak current was proportional to the amount of ATP. The unique interconnected structure in 3DOM gold film along with the "built-in" preconcentration remarkably improved the sensitivity. ATP detection with high selectivity, wide linear dynamic range of 4 orders of magnitude and high sensitivity down to 0.01 nm were achieved. The results demonstrated that the novel strategy was feasible for sensitive ATP assay and provided a promising model for the detection of small molecules.     

Highly effective colorimetric and visual detection of ATP by a DNAzyme-aptamer sensor

A new and simple method was developed to detect adenosine triphosphate (ATP) by using a DNAzyme aptamer sensor. The DNAzyme used was a single‐stranded DNA that could combine with hemin. The aptamer, a single, short nucleic acid sequence that can specifically bind with many targets, was an anti‐ATP aptamer. Two DNA sequences were designed: i) a functional chain (Chain A) consisting of two parts, i.e., the anti‐ATP aptamer (recognition part) and the DNAzyme (signal transduction part) and ii) a blocker chain (Chain B), which could partially hybridize with Chain A. The hybridized chains A and B were unfolded by the addition of ATP and hemin, and the blocker chain and the complex of the functional chain with ATP and hemin were in solution. The DNAzyme in the functional chain formed a G‐quadruplex with hemin and then catalyzed the oxidation by H₂O₂ of 2,2′‐azinobis(3‐ethylbenzthiazoline‐6‐sulfonic acid) (ABTS²⁻) to the colored ABTS^.− radical. The color change caused by this reaction could be clearly observed by naked eye, and the absorbance was recorded at 414 nm. The detection limit was 1×10⁻⁶ M .     

Silica nanoparticles based label-free aptamer hybridization for ATP detection using hoechst33258 as the signal reporter

In this work, we have developed a simple and sensitive method for ATP detection using silica nanoparticles (NPs) as the platform and hoechst33258 as the signal reporter. The ATP-binding aptamers hybridize with the probe DNA (DNA(p)) immobilized NPs to form the aptamer/DNA(p) duplex on the NPs surface. The conformational change of the aptamer leads to the decrease of the aptamer/DNA(p) duplex on the NPs due to the ATP-binding aptamer switches its structure from the aptamer/DNA(p) duplex to the aptamer/target complex in the presence of ATP. ATP detection can be easily realized by separating the silica nanoparticles and adding the hoechst33258 of intercalating to aptamer/DNA(p) (dsDNA). Good selectivity between ATP and CTP, GTP or UTP has been demonstrated, which is due to the specific recognition between ATP aptamer and ATP. The K(d) was estimated to be ～1mM from 0 to 4mM and a liner response was observed from 0 to 0.2mM with a detection limit of ～20μM. Compared with other methods, the carboxyl-modified silica nanoparticles (～60nm) prepared by the reverse microemulsion method can serve as a stable and sensitive sensor platform because of their smaller size and facile conjugation with amine-containing molecules. In addition, the high sensitivity and selectivity of hoechst33258 was employed for the ssDNA and dsDNA determination, which takes advantage of the label-free aptamer and lower cost.     

An ace in the hole..

In this issue of Structure, Tesmer and coworkers report the structure of a small RNA aptamer in an inhibitory complex with a G protein receptor kinase. The aptamer adopts a charming structure that inserts an adenosine residue into the ATP binding pocket of the kinase.     

Determination of lycopene and beta-carotene by high-performance liquid chromatography using sudan I as internal standard

A reverse-phase HPLC method based on ion-pair formation with UV detection was set up for the simultaneous determination of gemcitabine diphosphate (dFdCDP) and triphosphate (dFdCTP) in human cells. The separation was achieved on a Tracer Excel ODSA column (100 mm x 4.6mm i.d., 3 microm particle size) at room temperature. Nine nucleotides were separated by isocratic elution in 26 min. Accuracy, linearity, sensitivity and precision studies for dFdCDP, dFdCTP, adenosine diphosphate (ADP) and triphosphate (ATP) validated this method. This assay was used to provide data from gemcitabine treated patients and in vitro grown human cancer cells.     

Determination of urinary adenosine using resonance light scattering of gold nanoparticles modified structure-switching aptamer

A novel sensitive method has been developed for the detection of adenosine (AD) in human urine by using enhanced resonance light scattering (RLS). This method is based on the specific recognition and signal amplification of adenosine aptamer (Apt) coupled with gold nanoparticles (GNPs) via G-quartet-induced nanoparticle assembly, which was fabricated by triggering a structure switching of the 3′ terminus G-rich sequence and aptamer duplex. RLS signal linearly correlated with the concentration of adenosine over the range of 6-115 nM. The limit of detection (LOD) for adenosine is 1.8 nM with relative standard deviations (RSD) of 2.90-4.80% (n = 6). The present method has been successfully applied to determination of adenosine in real human urine, and the obtained results were in good agreement with those obtained by the HPLC method. Our investigation shows that the combination of the excellent selectivity of aptamer with the high sensitivity of the RLS technique could provide a promising potential for aptamer-based small molecule detection, and be beneficial in extending the application of RLS.     

ATP bioluminescence rapid detection of total viable count in soy sauce

The adenosine triphosphate (ATP) bioluminescence rapid determination method may be useful for enumerating the total viable count (TVC) in soy sauce, as it has been previously used in food and beverages for sanitation with good precision. However, many factors interfere with the correlation between total aerobic plate counts and ATP bioluminescence. This study investigated these interfering factors, including ingredients of soy sauce and bacteria at different physiological stages. Using the ATP bioluminescence method, TVC was obtained within 4 h, compared to 48 h required for the conventional aerobic plate count (APC) method. Our results also indicated a high correlation coefficient (r = 0.90) between total aerobic plate counts and ATP bioluminescence after filtration and resuscitation with special medium. The limit of quantification of the novel detection method is 100 CFU/mL; there is a good linear correlation between the bioluminescence intensity and TVC in soy sauce in the range 1 × 10²–3 × 10⁴ CFU/mL and even wider. The method employed a luminescence recorder (Tristar LB‐941) and 96‐well plates and could analyse 50–100 samples simultaneously at low cost. In this study, we evaluated and eliminated the interfering factors and made the ATP bioluminescence rapid method available for enumerating TVC in soy sauce. Copyright © 2011 John Wiley & Sons, Ltd.     

A target-triggered strand displacement reaction cycle: The design and application in adenosine triphosphate sensing

A strand displacement reaction (SDR) system that runs solely on oligonucleotides has been developed for the amplification detection of adenosine triphosphate (ATP). It involves a target-induced SDR and an entropy-driven catalytic cycle of two SDRs with five oligonucleotides, denoted as substrate, fuel, catalyst, C-1, and C-2. Catalyst, released from the ATP aptamer–catalyst duplex by ATP molecule, catalyzes the SDRs to finally form the substrate–fuel duplex. All of the intermediates in the catalytic SDR processes have been identified by polyacrylamide gel electrophoresis (PAGE) analysis. The introduction of ATP into the SDR system will induce the ATP aptamer to form G-quadruplex conformation so as to release catalyst and trigger the SDR cycle. When the substrate and C-2 oligonucleotides were labeled with a carboxyfluorescein (FAM) fluorophore and a 4-([4-(dimethylamino)phenyl]azo)benzoic acid (DABCYL) quencher, this SDR catalytic system exhibited a “turn-on” response for ATP. The condition for detecting ATP, such as Mg²⁺ concentration, has been optimized to afford a detection limit of 20 nM. This work provides an enzyme-free biosensing strategy and has potential application in aptamer-based biosensing.     

Haemodynamic effects of purinergic receptor stimulation in isolated fish gills

The haemodynamic responses of the isolated, perfused gill of the tropical cichlid, Oreochromas (Sarotherodon) niloticus, to exogenous application of adenosine and adenosine triphosphate (ATP) showed that both drugs are potent vasoactive agents. However, while adenosine had vasoconstrictory effect, ATP induced vasodilation. ATP-induced vasodilation was reversibily inhibited in the presence of the enzyme, adenosine deaminase, and the P1 receptor antagonist, theophylline, but was unaffected by the P2 receptor antagonist, quinidine. This indicates that ATP acts specifically through P1 receptor stimulation. The significance of the inhibition of ATP by adenosine deaminase remains obscure since in purine metabolism the enzyme catalyzes the conversion of the haemodynamically active adenosine to inactive inosine.     

Simultaneous determination of adenosine triphosphate and its metabolites in human whole blood by RP-HPLC and UV-detection

To obtain insight in mechanisms of action of extracellular adenosine triphosphate (ATP) and adenosine, a simple HPLC method has been optimized and applied to investigate ATP metabolism in human whole blood ex vivo. This method provided good chromatographic resolution and peak shape for all eight compounds within a 19 min run time. The baseline was clean, the lower limit of quantification was below 0.3 micromol/L for all adenine nucleotides and the method demonstrated good linearity. Within-day precision ranged from 0.7 to 5.9% and between-days from 2.6 to 15.3%. Simplicity and simultaneous detection of ATP and its metabolites make this method suitable for clinical pharmacokinetic studies.     

Rapidly photoactivatable ATP probes for specific labeling of tropomyosin within the actomyosin protein complex

Tropomyosin-specific photoaffinity adenosine triphosphate (ATP) probes have been first developed, in which a diazirine moiety is incorporated into the γ-phosphate group as a rapidly carbene-generating photophore. These probes clearly labeled tropomyosin in the presence of other actomyosin components, that is, myosin, actin, and troponins. The specific labeling of tropomyosin was easily identified by selective trapping of the photo-incorporated ATP probe on Fe³⁺-immobilized metal ion affinity chromatography (IMAC) beads. The characteristic nature of tropomyosin-specific photocross-linking was further confirmed with a biotin-carrying derivative of the ATP probe. These data suggest that the tropomyosin on the actin filament assembly is located in close proximity to the ATP binding cavity of myosin.