Low background signal platform for the detection of ATP: when a molecular aptamer beacon meets graphene oxide

A novel molecular aptamer beacon (MAB) was designed by integrating a single-labeled hairpin-shaped aptamer and graphene oxide (GO). The hairpin-shaped aptamer was constructed with anti-ATP aptamer and another five nucleotides added to the 5'-end of the aptamer which are complementary to nucleotides at the 3'-end of the aptamer to form a hairpin-shaped probe. This newly designed MAB which acts as a low background signal platform was used for the ATP detection based on long-range resonance energy transfer (LrRET). In the absence of ATP, the adsorption of the dye-labeled hairpin-shaped aptamer on GO makes the dyes close proximity to GO surface resulting in high efficiency quenching of fluorescence of the dyes. Therefore, the fluorescence of the designed MAB is completely quenched by GO, and the system shows very low background. Conversely, and very importantly, upon the adding of ATP, the quenched fluorescence is recovered significantly, and ATP can be detected in a wide range of 5-2500μM with a detection limit of 2μM and good selectivity. Moreover, when the GO-based MAB was used in cellular ATP assays, preeminent fluorescence signals were obtained, thus the platform of GO-based MAB could be used to detect ATP in real-world samples.     

An ultrasensitive fluorescent aptasensor for adenosine detection based on exonuclease III assisted signal amplification

We report here a graphene oxide (GO)-based fluorescent aptasensor for adenosine detection by employing exonuclease III (Exo III) as a signal amplifying element. In the absence of adenosine, the adenosine aptamers hybridized with the complementary DNA (cDNA), and the Exo III could not cleave the single-strand signal probes labeled with carboxylfluorescein (FAM) at its 5' ends. When the graphene oxide was finally added, it could strongly adsorb the single-strand signal probes and quenched the fluorophore effectively. In the presence of adenosine, the aptamers associated with the targets, which led to the formation of duplex DNAs between the cDNAs and the signal probes. The Exo III thereafter could digest the duplex DNAs from 3' blunt terminus of signal probes, liberating the fluorophore. Upon adding the GO, the fluorophore could not be adsorbed and quenched. By coupling cyclic enzymatic cleavage, a remarkable fluorescent increase was obtained. Due to the specific recognition ability of the aptamer for the target and the powerful quenching property of GO for signal probe, this proposed approach has a good selectivity and high sensitivity for adenosine. In the optimum conditions described, >100% signal enhancement was achieved and a limit of detection as low as 1 nM was obtained, which is lower than those of commonly used fluorescent aptamer sensors. Moreover, the biosensor exhibited an ultrahigh sensitivity and held a versatile platform for clinical diagnostics, molecular biology and drug developments.     

Aptasensor for amplified IgE sensing based on fluorescence quenching by graphene oxide

Water‐soluble graphene oxide (GO) with a two‐dimensional layered nanostructure was synthesized and used as a quencher to construct a highly sensitive and selective fluorescence resonance energy transfer (FRET) aptasensor for sensing Immunoglobulin E (IgE). The fluorescein isothiocyanate (FITC)‐labeled aptamer could be adsorbed stably onto the surface of GO via π → π stacking interaction, which led to the occurrence of FRET from FITC to GO, and the fluorescence of FITC‐labeled aptamer was quenched by GO via energy transfer. In the presence of IgE, the fluorescence was recovered due to a higher affinity between the aptamer and IgE compared with interactions between GO and the aptamer, leading to a high signal‐to‐background ratio. The fluorescence intensity of the aptamer increased in proportion to the amount of IgE in the sample,so that IgE could be detected with a linear range of 60–225 pM and a detection limit of 22 pM. The assay was highly selective because the aptamer was unaffected by the presence of immunoglobulin G (IgG), human serum albumin (HSA) and bovine serum albumin (BSA). The practical application of the proposed aptasensor was successfully carried out for the determination of IgE in human serum samples. Copyright © 2012 John Wiley & Sons, Ltd.     

Detection of lysozyme with aptasensor based on fluorescence resonance energy transfer from carbon dots to graphene oxide

A photoluminescent aptasensor has been developed for the detection of lysozyme based on fluorescence resonance energy transfer (FRET) between the carbon dots (CDs) and graphene oxide (GO). In the sensing system, the CDs‐labeled aptamer is adsorbed onto the GO surface and the photoluminescence (PL) signal of the CDs is effectively quenched by GO. Addition of lysozyme can cause a significant FRET inhibition and recover the PL signal of the CDs due to the specific combination of lysozyme and its aptamer and the removal of the CDs‐labeled aptamer from GO surface. Under optimal conditions, the ratio of PL intensity change at 440 nm of the sensing system before and after the addition of lysozyme shows a good linear relationship against the concentration of lysozyme in the range of 0.01–2 μg/mL, with a low detection limit of 1 × 10^?3 μg/mL. In addition, the aptasensor has good selectivity so it can distinguish lysozyme with no or little interference by many other biomolecules. It was applied to the detection of lysozyme in human sera with satisfactory recoveries. The results demonstrate the applicability of the aptasensor for monitoring lysozyme in real samples. Copyright © 2016 John Wiley & Sons, Ltd.     

Time-resolved fluorescence biosensor for adenosine detection based on home-made europium complexes

In this protocol, the authors report a time-resolved fluorescence biosensor based on home-made europium complexes for highly sensitive detection of small molecules using adenosine as a model analyte. The fluorophore that used is europium complexes. Its signal can be measured in a time-resolved manner that eliminates most of the unspecific fluorescent background. The amino modified aptamer probe, which is designed to specifically recognize adenosine, is combined to the aldehyde-group modified glass slide by covalent bond. Europium complex-labeled a short ssDNA, designed to segment hybridize with aptamer probe is immobilized on the glass slide by hybridization reaction. In the presence of adenosine, the aptamer part is more inclined to bounds with adenosine and triggers structure-switching of the aptamer from aptamer/ssDNA duplex to aptamer/target complex. As a result, europium complexes-labeled ssDNA is forced to dissociate from the sensor interface, resulting in time-resolved fluorescence intensity decrease. The decrement intensity is proportional to the amount of adenosine. Under optimized assay conditions, a linear range (1.0×10(-8)M to 1.0×10(-7)M) is got with low detection limit of 5.61nM. The biosensor exhibits excellent selectivity and can provide a promising potential for aptamer-based adenosine detection.     

Selected ssDNA aptamers–graphene oxide-based fluorescent biosensor to detect sulfameter in milk

The abuse of sulfameter (SME) in animal husbandry can cause drug resistance and toxic or allergic reactions in humans. Therefore, it is very important to establish a simple, inexpensive, and efficient method for detecting SME in food. In this work, we propose a single fluorescent aptamer/graphene oxide (GO)-based biosensor to detect SME residues in milk. Aptamers that specifically bind to SME were screened using capture-SELEX and a ssDNA library immobilized on magnetic beads. The 68 active candidate aptamers were chemically synthesized for specificity and affinity characterization. Among the aptamers, the aptamer sulf-1 revealed the highest affinity (K_d = 77 ± 15 nM) to SME and was selected to construct a GO-based fluorescent biosensor for real milk sample detection. Under optimal conditions, the single fluorescent aptasensor had a wide linear range (R² was 0.997) from 7 to 336 ng/ml and a low detection limit of 3.35 ng/ml that was calculated with a 3SD/slope. The single fluorescent method was also validated using SME-fortified milk samples, showing average recoveries ranging from 99.01% to 104.60% with a relative standard deviation of less than 3.88%. These results demonstrate that this novel aptamer sensor provides an opportunity for sensitive, convenient, and accurate detection of SME residues in milk.     

A fluorescent aptasensor for sensitive analysis oxytetracycline based on silver nanoclusters

A fluorescent aptasensor for detection of oxytetracycline (OTC) was presented based on fluorescence quenching of DNA aptamer‐templated silver nanoclusters (AgNCs). The specific DNA scaffolds with two different nucleotides fragments were used: one was enriched with a cytosine sequence fragment (C12) that could produce DNA–AgNCs via a chemical reduction method, and another was the OTC aptamer fragment that could selectively bind to the OTC antibiotic. Thus, the as‐prepared AgNCs could exhibit quenched fluorescence after binding to the target OTC. The fluorescence ratio of the DNA–AgNCs was quenched in a linearly proportional manner to the concentration of the target in the range of 0.5 nM to 100 nM with a detection limit of 0.1 nM. This proposed nanobiosensor was demonstrated to be sensitive, selective, and simple, introducing a viable alternative for rapid determination of toxin OTC in honey and water samples. Copyright © 2016 John Wiley & Sons, Ltd.     

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.     

A novel aptasensor based on silver nanoparticle enhanced fluorescence

In the present study, we report a novel aptasensor based on silver nanoparticle enhanced fluorescence for the detection of adenosine. First, the distance dependence nature of silver nanoparticle enhanced fluorescence was investigated through fluorescent dyes modified oligonucleotides to control the spacing distance between dyes and AgNP. The results showed that the fluorescence intensity reached the maximum value with the spacing distance of dyes about 8 nm from AgNP surface. The fluorescence intensity decreases when the spacing distance is either above or below this value. Based on this result, a fluorescence switch is constructed. In the "OFF" state, without the target molecules, there is a greater spacing distance between the Cy3 dyes and the AgNP giving comparatively lower fluorescence intensity. While in the "ON" state, in the presence of target molecules, the fluorescence signals increased for the conformation structure change of the aptamer which shorten the spacing distance between the Cy3 dyes and the AgNP to 8 nm. Using adenosine as target, the aptasensor produced a linear range from 200 nM to 200 μM with a correlation coefficient of 0.9949 and the detection limit was 48 nM estimated using 3σ. The aptasensor was also found to be specific in targeting adenosine. The presented method shows a new strategy of combining aptamer recognition and silver nanoparticle for fluorescence signal enhancement and increasing sensitivity.     

A coordination polymer nanobelt (CPNB)-based aptasensor for sulfadimethoxine

A polymer-based aptasensor, which consisted of fluorescein amidite (FAM)-modified aptamers and coordination polymer nanobelts (CPNBs), was developed utilizing the fluorescence quenching effect to detect sulfadimethoxine residue in food products. A single-stranded DNA (ssDNA) aptamer, which was a specific bio-probe for sulfadimethoxine (Su13; 5'-GAGGGCAACGAGTGTTTATAGA-3'), was discovered by a magnetic bead-based systematic evolution of ligands by exponential enrichment (SELEX) technique, and the fluorescent quenchers CPNBs were produced by mixing AgNO(3) and 4,4'-bipyridine. This aptasensor easily and sensitively detected sulfadimethoxine in solution with a limit of detection (LOD) of 10ng/mL. Furthermore, the antibiotic dissolved in milk was also effectively detected with the same LOD value. In addition, this aptamer probe offered high specificity for sulfadimethoxine compared to other antibiotics. These valuable results provide ample evidence that the CPNB-based aptasensor can be used to quantify sulfadimethoxine residue in food products.     

A graphene oxide-peptide fluorescence sensor for proteolytically active prostate-specific antigen

This paper presents a novel sensor to detect proteolytically active prostate-specific antigen (PSA) by assembling a purpose-designed FITC-labeled peptide with graphene oxide (GO). The fluorescence of the dye-labeled peptide was quenched in the presence of GO. Reaction of the sensor with PSA cleaves the peptide, leading to the release of the dye moiety and a great increase in fluorescence intensity in a dose- and time-dependent manner, and PSA can be quantified accordingly. This approach is simple compared to existing methods since the GO-peptide-based sensor is easily assembled and detection can be achieved without the involvement of complicated procedures. Moreover, the applicability of the method has been demonstrated by detecting PSA in spiked urine samples.     

A simple rapid fluorescent assay for adenosine deaminase activity.

A simple, rapid (2 hours), fluorescent test for the activity of blood adenosine deaminase (ADA) is described. The test which can be performed on both heparinized and dried blood, is based on the conversion of adenosine to inosine and ammonium in the presence of ADA. The enzyme activity is visually estimated by the oxidation of NADH (fluorescent) to NAD+ (non-fluorescent) in a coupled reaction with glutamate dehydrogenase. The disappearance of fluorescence indicates ADA activity in the sample. The advantages are discussed of the use of this test for the study of the autosomal recessive severe combined immunodeficiency.     

Automated enzymatic measurement of adenosine deaminase isoenzyme activities in serum

We developed a simple, rapid, and automated method for simultaneous measurement of adenosine deaminase (ADA, EC 3.5.4.4) isoenzymes in human serum, based on their apparent difference in Ki values for erythro-9-(2-hydroxy-3-nonyl)adenine (EHNA) as inhibitor. Serum ADA was partially purified by CM-Sephadex, gel-filtration, and affinity chromatography into two types of isoenzymes, designated ADA1 (300 kDa) and ADA2 (120 kDa). Because ADA2 has a higher Km for adenosine and higher Ki values for EHNA than does ADA1, the activity of ADA1 is almost completely inhibited by EHNA at 0.1 mM (analytical recovery 4.1%), whereas ADA2 is practically unaffected (analytical recovery 94.8%) by that concentration of EHNA. We measured the activities of ADA2 and total ADA in the presence and absence of 0.1 mM EHNA. ADA1 activities were calculated by subtracting the activity of ADA2 from that of total ADA. The mean within-assay CV was 5.7% for ADA1 and 2.7% for ADA2. The interassay CV was 2.8% for ADA1 and 3.1% for ADA2. Results of the present method correlated well (r = 0.9026 for ADA1, 0.9438 for ADA2) with those of the ion-exchange chromatography method. The upper limits of the reference intervals, as calculated from data for 320 healthy donors, are 7.2 U/liter for ADA1, and 14.6 U/liter for ADA2. This method is suitable for analysis of large numbers of samples in clinical laboratories for routine monitoring of the activities of ADA isoenzymes in serum.     

Aptamer biosensor for protein detection using gold nanoparticles

Combining gold nanoparticles (GNPs) as fluorescence quencher and aptamer as probe, we have developed protein biosensors by using DNA-modified GNPs. We examined how the experimental design, such as the type of interaction between DNA strands and GNPs, temperature, and microenvironment of aptamer, influences the recognition ability of the biosensor. Under our experimental conditions, the recognition of protein by the complex of dye-labeled DNA hybridized with aptamer that is immobilized on GNPs (Ap-Im-GNPs) shows the best character in protein detection.     

A novel impedimetric aptasensor,based on functionalized carbon nanotubes and prussian blue as labels

A simple and feasible electrochemical sensing protocol was developed for the detection of bisphenol A (BPA) by employing the gold nanoparticles (AuNPs), prussian blue (PB) and functionalized carbon nanotubes (AuNPs/PB/CNTs-COOH). An aminated complementary DNA as a capture probe and specific aptamer against BPA as a detection probe was immobilized on the surface of a modified glassy carbon (GC) electrode via the formation of covalent amide bond and hybridization, respectively. The proposed nanoaptasensor combined the advantages of the in situ formation of PB as a label, the deposition of neatly arranged AuNPs, and the covalent attachment of the capture probe to the surface of the modified electrode. Upon addition of target BPA, the analyte reacted with the aptamer and caused the steric/conformational restrictions on the sensing interface. The formation of BPA–aptamer complex at the electrode surface retarded the interfacial electron transfer reaction of the PB as a probe. Sensitive quantitative detection of BPA was carried out based on the variation of electron transfer resistance which relevant to the formation of BPA– aptamer complex at the modified electrode surface. Under the optimized conditions, the proposed aptasensor exhibited a high sensitivity, wide linearity to BPA and low detection limit. This aptasensor also displayed a satisfying electrochemical performance with good stability, selectivity and reproducibility.     

Electrogenerated chemiluminescence detection of adenosine based on triplex DNA biosensor

A novel electrogenerated chemiluminescence (ECL) biosensor based on the construction of triplex DNA for the detection of adenosine was designed. The ECL biosensor employs an aptamer as a molecular recognition element, and quenches ECL of tris(2,2'-bipyridine) ruthenium (Ru(bpy)(3)(2+)) by ferrocenemonocarboxylic acid (FcA). Through self-assembly technology, the ECL probe of thiolated hairpin adenosine aptamer tagged was self-assembled onto the surface of a gold electrode with an ECL signal producer Ru(bpy)(3)(2+) derivative (Ru-DNA-1). The adenosine aptamer, including a section of triplex characteristic chain, formatted triplex DNA with two other DNAs (DNA-2, Fc-DNA-3) in the presence of triplex DNA binder coralyne chloride (CORA). Fc-DNA-3 was tagged with an ECL quencher ferrocenemonocarboxylic acid (FcA), a quenching probe. In the presence of adenosine, the aptamer sequence (Ru-DNA-1) prefers to form the aptamer-adenosine complex with hairpin configuration and the switch of the DNA-1 occurs in conjunction with the generation of a strong ECL signal owing to the dissociation of a quenching probe. Meanwhile, a control experiment was performed; the ECL-duplex biosensor was designed to detect adenosine. The detection limits were 2.7×10(-10) mol L(-1) and 2.3×10(-9) mol L(-1) for the ECL-triplex DNA biosensor and ECL-duplex DNA biosensor, respectively, which demonstrated that the ECL-triplex DNA biosensor improved the sensitivity and specificity greatly.     

Purification and characterization of Plasmodium yoelii adenosine deaminase

Plasmodium lacks the de novo pathway for purine biosynthesis and relies exclusively on the salvage pathway. Adenosine deaminase (ADA), first enzyme of the pathway, was purified and characterized from Plasmodium yoelii, a rodent malarial species, using ion exchange and gel exclusion chromatography. The purified enzyme is a 41 kDa monomer. The enzyme showed K_m values of 41 μM and 34 μM for adenosine and 2′-deoxyadenosine, respectively. Erythro-9-(2-hydroxy-3-nonyl) adenine competitively inhibited P. yoelii ADA with K_i value of 0.5 μM. The enzyme was inhibited by DEPC and protein denaturing agents, urea and GdmCl. Purine analogues significantly inhibited ADA activity. Inhibition by p-chloromercuribenzoate (pCMB) and N-ethylmaleimide (NEM) indicated the presence of functional –SH groups. Tryptophan fluorescence maxima of ADA shifted from 339 nm to 357 nm in presence of GdmCl. Refolding studies showed that higher GdmCl concentration irreversibly denatured the purified ADA. Fluorescence quenchers (KI and acrylamide) quenched the ADA fluorescence intensity to the varied degree. The observed differences in kinetic properties of P. yoelii ADA as compared to the erythrocyte enzyme may facilitate in designing specific inhibitors against ADA.     

One-pot fluorescence detection of multiple analytes in homogenous solution based on noncovalent assembly of single-walled carbon nanotubes and aptamers

We have developed a new multicolor fluorescent sensing system to detect multiple analytes in one pot. This design is based on the noncovalent assembly of dye-labeled aptamer with single-walled carbon nanotubes (SWNTs) by π-stacking between the nucleotide bases and the SWNTs sidewalls. In the presence of the targets, the aptamer-target binding separates the assembly of dye-labeled aptamers and SWNTs, resulting in the restoration of fluorescence signal of the dye labeled with aptamers. As a proof of concept, we demonstrate that a two-color fluorescent system can simultaneously and selectively detect two targets (thrombin and adenosine triphosphate) in a single solution. Since the method is mix-and-detect manner, the present strategy is simple and cost-effective.