Facile conversion of ATP-binding RNA aptamer to quencher-free molecular aptamer beacon

We have developed RNA-based quencher-free molecular aptamer beacons (RNA-based QF-MABs) for the detection of ATP, taking advantage of the conformational changes associated with ATP binding to the ATP-binding RNA aptamer. The RNA aptamer, with its well-defined structure, was readily converted to the fluorescence sensors by incorporating a fluorophore into the loop region of the hairpin structure. These RNA-based QF-MABs exhibited fluorescence signals in the presence of ATP relative to their low background signals in the absence of ATP. The fluorescence emission intensity increased upon formation of a RNA-based QF-MAB·ATP complex.     

Serum inverts and improves the fluorescence response of an aptamer beacon to various vitamin D analytes

A dominant aptamer loop structure from a library of nearly 100 candidate aptamer sequences developed against immobilized 25‐hydroxyvitamin D₃ (calcidiol) was converted into a 5′‐TYE 665 and 3′‐Iowa black‐labelled aptamer beacon. The aptamer beacon exhibited a mild 'lights on' reaction in buffer as a function of increasing concentrations of several vitamin D analogues and metabolites, with a limit of detection of approximately 200 ng/mL, and was not specific for any particular congener. In 10% or 50% human serum, the same aptamer beacon inverted its fluorescence behaviour to become a more intense 'lights off' reaction with an improved limit of detection in the range 4–16 ng/mL. We hypothesized that this drastic change in fluorescence behaviour was due to the presence of creatinine and urea in serum, which might destabilize the quenched beacon, causing an increase in fluorescence followed by decreasing fluorescence as a function of vitamin D concentrations that may bind and quench increasingly greater fractions of the denatured beacons. However, the results of several control experiments in the presence of physiological or greater concentrations of creatinine and urea, alone or combined in buffer, failed to produce the beacon fluorescence inversion. Other possible mechanistic hypotheses are also discussed. Copyright © 2011 John Wiley & Sons, Ltd.     

Crystal structure of an RNA aptamer bound to thrombin

Aptamers, an emerging class of therapeutics, are DNA or RNA molecules that are selected to bind molecular targets that range from small organic compounds to large proteins. All of the determined structures of aptamers in complex with small molecule targets show that aptamers cage such ligands. In structures of aptamers in complex with proteins that naturally bind nucleic acid, the aptamers occupy the nucleic acid binding site and often mimic the natural interactions. Here we present a crystal structure of an RNA aptamer bound to human thrombin, a protein that does not naturally bind nucleic acid, at 1.9 A resolution. The aptamer, which adheres to thrombin at the binding site for heparin, presents an extended molecular surface that is complementary to the protein. Protein recognition involves the stacking of single-stranded adenine bases at the core of the tertiary fold with arginine side chains. These results exemplify how RNA aptamers can fold into intricate conformations that allow them to interact closely with extended surfaces on non-RNA binding proteins.     

适配子生物传感器对青霉素的快速检测

将玻碳电极进行阳极氧化和氨基化修饰,通过碳二亚胺盐酸盐(EDC)、N-羟基丁二酰亚胺(NHS)活化作用将青霉素适配子结合在电极表面。该适配子电化学生物传感器分子识别能力强、无放射性标记、检测速率快,青霉素类的最佳检测范围是2.81~281 nmol/L,最低检测限为2.81 nmol/L,检测时间为5 m in。     

适配子纳米生物传感器在青霉素检测中的应用

通过脉冲腐蚀法对硅片进行多孔硅的制备,利用玻片通过对共价法、离子吸附法和APTES修饰的戊二醛交联法3种固定适配子方法的对比,以确定较好的固定青霉素适配子的方法。将适配子固定在多孔硅上后,利用交流阻抗法对加入青霉素前后传感器阻抗值进行测定、对比,构建等效电路并进行阻抗拟合。对多孔硅传感器的Nyqu ist谱图进行分析以确定多孔硅表面成功固定了青霉素适配子,从而证明构建纳米生物传感器成功。传感器的线性检测范围为0.05~0.2 mg/L,检测限为0.05 mg/L。     

核酸适体生物传感器快速检测牛奶中抗生素

为了现场快速检测牛奶溶液中四环素类抗生素的含量,对电极进行阳极氧化、氨基化、活化等一系列处理,将四环素核酸适体作为识别分子,共价固定于玻碳电极表面,构建出新型核酸适体生物传感器。传感器可以特异性结合标本中四环素类抗生素,并产生电化学信号,强度与抗生素浓度相关。其最低检测量是1μg/L,检测时间为5 m in。     

Kinetic and thermodynamic characterization of HIV-1 protease inhibitors

Interaction kinetic and thermodynamic analyses provide information beyond that obtained in general inhibition studies, and may contribute to the design of improved inhibitors and increased understanding of molecular interactions. Thus, a biosensor-based method was used to characterize the interactions between HIV-1 protease and seven inhibitors, revealing distinguishing kinetic and thermodynamic characteristics for the inhibitors. Lopinavir had fast association and the highest affinity of the tested compounds, and the interaction kinetics were less temperature-dependent as compared with the other inhibitors. Amprenavir, indinavir and ritonavir showed non-linear temperature dependencies of the kinetics. The free energy, enthalpy and entropy (DeltaG, DeltaH, DeltaS) were determined, and the energetics of complex association (DeltaG(on), DeltaH(on), DeltaS(on)) and dissociation (DeltaG(off), DeltaH(off), DeltaS(off)) were resolved. In general, the energetics for the studied inhibitors was in the same range, with the negative free energy change (DeltaG < 0) due primarily to increased entropy (DeltaS > 0). Thus, the driving force of the interaction was increased degrees of freedom in the system (entropy) rather than the formation of bonds between the enzyme and inhibitor (enthalpy). Although the DeltaG(on) and DeltaG(off) were in the same range for all inhibitors, the enthalpy and entropy terms contributed differently to association and dissociation, distinguishing these phases energetically. Dissociation was accompanied by positive enthalpy (DeltaH(off) > 0) and negative entropy (DeltaS(off) < 0) changes, whereas association for all inhibitors except lopinavir had positive entropy changes (DeltaS(on) > 0), demonstrating unique energetic characteristics for lopinavir. This study indicates that this type of data will be useful for the characterization of target-ligand interactions and the development of new inhibitors of HIV-1 protease.     

Evaluation of Staphylococcus aureus DNA aptamer by enzyme‐linked aptamer assay and isothermal titration calorimetry

To monitor the specificity of Staphylococcus aureus aptamer (SA‐31) against its target cell, we used enzyme‐linked aptamer assay. In the presence of target cell, horseradish peroxidase–conjugated streptavidin bound to biotin‐labeled SA‐31 showed specific binding to S   aureus among 3 different bacteria with limit of detection of 10³ colony‐forming unit per milliliter. The apparent K _a was 1.39 μM⁻¹ ± 0.3 μM⁻¹. The binding of SA‐31 to membrane proteins extracted from cell surface was characterized using isothermal titration calorimetry, and the effect of changes in binding temperature and salt concentrations of binding buffer was evaluated based on thermodynamic parameters (K _a, ΔH , and ΔG ). Since binding of aptamer to its targets solely depends on its 3‐dimensional structure under experimental conditions used in selection process, the change in temperature and ion concentration changed the affinity of SA‐31 to its target on surface of bacteria. At 4°C, SA‐31 did not show an affinity to its target with poor heat change upon injection of membrane fraction to aptamer solution. However, the apparent association constants of SA‐31 slightly varied from K _a = 1.56 μM⁻¹ ± 0.69 μM⁻¹ at 25°C to K _a = 1.03 μM⁻¹ ± 0.9 μM⁻¹ at 37°C. At spontaneously occurring exothermic binding reactions, affinities of S  aureus aptamer to its target were also 9.44 μM⁻¹ ± 0.38 μM⁻¹ at 50mM, 1.60 μM⁻¹ ± 0.11 μM⁻¹ at 137mM, and 3.28 μM⁻¹ ± 0.46 μM⁻¹ at 200 mM of salt concentration. In this study, it was demonstrated that enzyme‐linked aptamer assay and isothermal titration calorimetry were useful tools for studying the fundamental binding mechanism between a DNA aptamer and its target on the outer surface of S  aureus .     

Insight into the molecular recognition of spermine by DNA quadruplexes from an NMR study of the association of spermine with the thrombin‐binding aptamer

The preferred residence sites and the conformation of DNA‐bound polyamines are central to understanding the regulatory roles of polyamines. To this end, we have used a series of selective ¹³C‐edited and selective total correlation spectroscopy‐edited one‐dimensional (1D) nuclear Overhauser effect spectroscopy NMR experiments to determine a number of intramolecular ¹H nuclear Overhauser effect (NOE) connectivities in ¹³C‐labelled spermine bound to the thrombin‐binding aptamer. The results provide evidence that the aptamer‐bound spermine adopts a conformation that optimizes electrostatic and hydrogen bond contacts with the aptamer backbone. The distance between the nitrogen atoms of the central aminobutyl is reduced by an increase in the population of gauche conformers at the C6–C7 bonds, which results in either a curved or S‐shaped spermine conformation. Molecular modelling contributes insight toward the mode of spermine binding of these spermine structures within the narrow grooves of DNA quadruplexes. In each case, the N5 ammonium group makes hydrogen bonds with two nearby phosphates across the narrow groove. Our results have implications for the understanding of chromatin structure and the rational design of quadruplex‐binding drugs. Copyright © 2013 John Wiley & Sons, Ltd.     

In vitro selection of sialic acid specific RNA aptamer and its application to the rapid sensing of sialic acid modified sugars

Sialic acids (SAs) are located on the terminal positions of glycan on a cell surface, which play important role in the spread and metastasis of cancer cells and infection of pathogen. For their detection and diagnosis, the finding of SA specific ligand is an essential prerequisite. Here, RNA aptamer for N‐acetylneuraminic acid (Neu5Ac), a representative of SAs, with the high affinity of 1.35 nM and the selectivity was screened by in vitro selection method. The strong binding of the screened aptamer was enough to protect the hydrolysis of Neu5Ac by neuraminidase with the stoichiometry of 1:1 molar ratio. For the rapid detection of SAs, the RNA aptamer was further engineered to the aptazyme sensor by conjugating with a ribozyme following the characterization of selected aptamer by RNase footprinting assay. Without additional desialylation, modification, or/and purification processes, the aptazyme indicated high catalytic activities in the presence of Neu5Ac over 20 µM in several minutes. Also, we observed that the aptazyme sensor shows high sensitivities to Neu5Ac‐conjugated sugars as well as Neu5Ac monomer, but not in non‐Neu5Ac modified sugars. The aptamer for Neu5Ac can support valuable tools in a wide range of bioanalytical applications as well as biosensors. Biotechnol. Bioeng. 2013; 110: 905–913. © 2012 Wiley Periodicals, Inc.     

Specific monitoring of aflatoxin M1 in real samples using aptamer binding to DNFS based on turn‐on method: A novel biosensor

In the present work, a novel biocompatible scaffold was fabricated for the DNA aptamer immobilization. For the first time, amino‐functionalized dendritic fibrous nanosilica (KCC‐1‐nPr‐NH₂) and gold nanoparticle supported by chitosan (AuNPs‐CS) were synthesized and electrodeposited successfully on the surface of the glassy carbon electrode by chronoamperometry technique. Unique oligonucleotide of aflatoxin M1 (5′‐ATC CGT CAC ACC TGC TCT GAC GCT GGG GTC GAC CCG GAG AAA TGC ATT CCC CTG TGG TGT TGG CTC CCG TAT) labeled by toluidine blue was immobilization on the prepared interface. Hence, a novel aptamer‐based bioassay was formed for highly sensitive quantitation of AFM1 using cyclic voltammetry and differential plus voltammetry. The structure and morphology of GQDs‐CS/KCC‐1‐nPr‐NH₂ were investigated by Fourier‐transform infrared spectroscopy, X‐ray diffraction, atomic force, scanning electron microscopy, and energy‐dispersive X‐ray spectroscopy. The achieved low limit of quantification of apta‐assay for detection of AFM1 was 10fM. Also, calibration curve was linear from 0.1μM to 10fM in real samples. The proposed apta‐assay has acceptable long‐term stability. Designed aptasensor has a lot of remarkable advantages including excellent selectivity, sensitivity, and stability that could be used as facile bio‐device for the determination of AFM1 in milk samples.     

Development of a Biosensor for Measuring Plasma Fibrinogen Based on an Enzyme Kinetic Model

A biosensor has been designed for measuring plasma fibrinogen concentrations based on an enzyme kinetic model. The values obtained correspond linearly to those of a clinical method but have a higher sensitivity within the normal range of fibrinogen. By using the disposable biosensor technology, this method is easy to follow, quick (within 2 min) and precise (with coefficients of variation to be as low as below 5%) and requires only a small amount of plasma sample (<50 μl). This biosensor technology also holds potential for use in point-of-care diagnostics.     

Highly sensitive biosensor based on aptamer and hybridization chain reaction for detection of cadmium ions

In this work, a highly sensitive biosensor for detecting cadmium ions (Cd²⁺) was developed based on a Cd²⁺-specific DNA aptamer and a hybridization chain reaction (HCR). The Cd²⁺ aptamer (named S0) was used to recognize Cd²⁺ and trigger the HCR. Without Cd²⁺, S0 initiated the HCR to form long nicked dsDNA structures to quench the fluorescence. Then, Cd²⁺ could bind with S0 to block HCR to recover fluorescence. This biosensor had high sensitivity with a detection limit of 0.36 nM and a linear range from 0 to 10 nM. Moreover, it showed a satisfactory selectivity and recovery rates.     

多孔硅Bragg反射镜适配子生物传感器检测心肌肌钙蛋白I

通过脉冲腐蚀法制备多孔硅Bragg反射镜,将心肌肌钙蛋白I（cTnI）适配子共价固定到多孔硅Bragg反射镜的孔洞中,发现适配子能与cTnI分子特异性结合。定量分析不同浓度的cTnI与适配子结合后多孔硅Bragg反射镜的反射谱峰位的红移情况。结果表明：基于多孔硅Bragg反射镜适配子生物传感器的光学检测具有良好的特异性,且具有免标记及检测时间短等优异性能。传感器的线性检测范围0．05-4nmol／L,最低检测限为0．05nmol／L。     

Nanostructure shape effects on response of plasmonic aptamer sensors

A localized surface plasmon resonance (LSPR) sensor surface was fabricated by the deposition of gold nanorods on a glass substrate and subsequent immobilization of the DNA aptamer, which specifically bind to thrombin. This LSPR aptamer sensor showed a response of 6‐nm λ_max shift for protein binding with the detection limit of at least 10 pM, indicating one of the highest sensitivities achieved for thrombin detection by optical extinction LSPR. We also tested the LSPR sensor fabricated using gold bipyramid, which showed higher refractive index sensitivity than the gold nanorods, but the overall response of gold bipyramid sensor appears to be 25% less than that of the gold nanorod substrate, despite the approximately twofold higher refractive index sensitivity. XPS analysis showed that this is due to the low surface density of aptamers on the gold bipyramid compared with gold nanorods. The low surface density of the aptamers on the gold bipyramid surface may be due to the effect of shape of the nanostructure on the kinetics of aptamer monolayer formation. The small size of aptamers relative to other bioreceptors is the key to achieving high sensitivity by biosensors on the basis of LSPR, demonstrated here for protein binding. The generality of aptamer sensors for protein detection using gold nanorod and gold nanobipyramid substrates is anticipated to have a large impact in the important development of sensors toward biomarkers, environmental toxins, and warfare agents. Copyright © 2013 John Wiley & Sons, Ltd.     

Isolation of a new ssDNA aptamer against staphylococcal enterotoxin B based on CNBr‐activated sepharose‐4B affinity chromatography

Staphylococcus aureus are potent human pathogens possessing arsenal of virulence factors. Staphylococcal food poisoning (SFP) and respiratory infections mediated by staphylococcal enterotoxin B (SEB) are common clinical manifestations. Many diagnostic techniques are based on serological detection and quantification of SEB in different food and clinical samples. Aptamers are known as new therapeutic and detection tools which are available in different ssDNA, dsDNA and protein structures. In this study, we used a new set of ssDNA aptamers against SEB. The methods used included preparation of a dsDNA library using standard SEB protein as the target analyte, affinity chromatography matrix in microfuge tubes, SELEX procedures to isolate specific ssDNA‐aptamer as an affinity ligand, aptamer purification using ethanol precipitation method, affinity binding assay using ELISA, aptamer cloning and specificity test. Among 12 readable sequences, three of them were selected as the most appropriate aptamer because of their affinity and specificity to SEB. This study presents a new set of ssDNA aptamer with favorable selectivity to SEB through 12 rounds of SELEX. Selected aptamers were used to detect SEB in infected serum samples. Results showed that SEB c1 aptamer (2 µg SEB/100 nM aptamer) had favorable specificity to SEB (k_d = 2.3 × 10^?11). In conclusion, aptamers can be considered as useful tools for detecting and evaluating SEB. The results showed that affinity chromatography was an affordable assay with acceptable accuracy to isolate sensitive and selective novel aptamers. Copyright © 2016 John Wiley & Sons, Ltd.