Characterization of a fluorophore binding RNA aptamer by fluorescence correlation spectroscopy and small angle X-ray scattering

Using fluorescence correlation spectroscopy (FCS), we have established an in vitro assay to study RNA dynamics by analyzing fluorophore binding RNA aptamers at the single molecule level. The RNA aptamer SRB2m, a minimized variant of the initially selected aptamer SRB-2, has a high affinity to the disulfonated triphenylmethane dye sulforhodamine B. A mobility shift of sulforhodamine B after binding to SRB2m was measured. In contrast, patent blue V (PBV) is visible only if complexed with SRB2m due to increased molecular brightness and minimal background. With small angle X-ray scattering (SAXS), the three-dimensional structure of the RNA aptamer was characterized at low resolution to analyze the effect of fluorophore binding. The aptamer and sulforhodamine B-aptamer complex was found to be predominantly dimeric in solution. Interaction of PBV with SRB2m led to a dissociation of SRB2m dimers into monomers. Radii of gyration and hydrodynamic radii, gained from dynamic light scattering, FCS, and fluorescence cross-correlation experiments, led to comparable conclusions. Our study demonstrates how RNA-aptamer fluorophore complexes can be simultaneously structurally and photophysically characterized by FCS. Furthermore, fluorophore binding RNA aptamers provide a tool for visualizing single RNA molecules.     

Characterization of enhanced monovalent and bivalent thrombin DNA aptamer binding using single molecule force spectroscopy

Thrombin aptamer binding strength and stability is dependent on sterical parameters when used for atomic force microscopy sensing applications. Sterical improvements on the linker chemistry were developed for high-affinity binding. For this we applied single molecule force spectroscopy using two enhanced biotinylated thrombin aptamers, BFF and BFA immobilized on the atomic force microscopy tip via streptavidin. BFF is a dimer composed of two single-stranded aptamers (aptabody) connected to each other by a complementary sequence close to the biotinylated end. In contrast, BFA consists of a single DNA strand and a complementary strand in the supporting biotinylated part. By varying the pulling velocity in force-distance cycles the formed thrombin-aptamer complexes were ruptured at different force loadings allowing determination of the energy landscape. As a result, BFA aptamer showed a higher binding force at the investigated loading rates and a significantly lower dissociation rate constant, k_off, compared to BFF. Moreover, the potential of the aptabody BFF to form a bivalent complex could clearly be demonstrated.     

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.     

Probing interactions between human lung adenocarcinoma A549 cell and its aptamers at single‐molecule resolution

Because cell‐specific aptamers have high potential for biomedical applications, investigation of the interaction between cell and its aptamers may be of key importance for an improved understanding of biochemical processes. Herein, the interaction between human lung adenocarcinoma A549 cell and its four aptamers was explored using single‐molecule force spectroscopy (SMFS). The values of the unbinding force varied from 117.1 to 171.0 pN at the loading rate of 1.8 × 10⁵ pN/s. Based on the dependence of singe molecule force on the atomic force microscopy loading rate, the corresponding kinetic parameters were obtained. The results revealed two activation barriers and two transient states in the unbinding process of aptamer/cell interaction. More importantly, the binding sites on A549 cells with its four aptamers were defined to be different using SMFS and flow cytometry. This work demonstrated that SMFS can be used as a powerful tool for exploring the aptamer/cell binding behavior at the single‐molecule level, and may provide valuable information for the design and application of aptamer probes. Copyright © 2014 John Wiley & Sons, Ltd.     

Selection of a DNA aptamer that binds 8-OHdG using GMP-agarose

DNA aptamers, which bind specific molecule, such as 8-OHdG, with high affinity were investigated using an in vitro selection strategy called systematic evolution of ligands by exponential enrichment (SELEX). However, 8-OHdG was difficult to immobilize on a carrier for SELEX. Therefore, a DNA aptamer binding to 8-OHdG was selected using GMP-agarose as an analogue from a library of about 4⁶⁰ random ssDNA sources. As a result, three aptamer candidates were selected. Among the selected DNA aptamers, the No. 22 DNA aptamer exhibited a high affinity for 8-OHdG. The dissociation constant, K_D, of No. 22 DNA aptamer was on the order of 0.1 μmol/L. This result suggests that using an analogue will be a useful new SELEX method for obtaining various aptamers that are difficult to immobilize on a matrix.     

Live cell measurements of interaction forces and binding kinetics between Discoidin Domain Receptor 1 (DDR1) and collagen I with atomic force microscopy

BackgroundDiscoidin Domain Receptors (DDRs) are membrane-tethered proteins of the receptor tyrosine kinase family, which signal in response to collagen. DDR expression is associated with human diseases, including fibrosis and cancer. The role of DDRs in human pathogenesis is mediated by dysregulated receptor function in response to the collagenous milieu. Thus, understanding DDR-collagen interactions is important for developing novel therapeutic strategies against DDRs.MethodsWe developed a biophysical method to isolate and measure specific interactions between DDR1 and collagen in live cells at the single molecule level using atomic force microscopy. This new method is capable of providing density and kinetics of membrane receptors in live cells.ResultsWe isolated DDR1-collagen interactions and quantified the association and dissociation rates of the DDR1-collagen I complex. We estimated separate binding probabilities of collagen I to DDR and integrin, and by combining kinetic and binding probability data, we were able to estimate the density of receptors in two cancer cell types. We also tested the viability of a DDR1 blocking antibody and determined its efficacy in suppressing DDR1-collagen binding.ConclusionsThe new method shows promise in quantifying receptor-ligand kinetics and receptor density on live cells.General significanceThe new approach is applicable to other receptor-ligand systems and allows the determination of critical parameters at the single cell/single molecule level – in particular, the direct determination of kinetic and density differences of receptors in different cell types. This capability should prove to be useful in cancer research and drug design.     

Photoaptameric heterodimeric constructs as a new approach to enhance the efficiency of formation of photocrosslinks with a target protein

Using DNA aptamers selectively recognizing anion-binding exosites 1 and 2 of thrombin as a model, it has been demonstrated that their conjugation by a poly-(dT)-linker (ranging from 5 to 65 nucleotides (nt) in length) to produce aptamer heterodimeric constructs results into affinity enhancement. At the linker lengths ranged from 35 to 55 nt the apparent dissociation constants (K _D^app) measured using the optical biosensor Biacore-3000 for complexes of thrombin with the heterodimeric constructs reached minimum values (K _D^app) = 0.2–0.4 nM), which were approximately 30-fold less than for the complexes with the initial aptamers. A photoaptamer heterodimeric construct was designed connecting photoaptamer and aptamer sequences with the poly-(dT)-linker of 35 nt long. The photoaptamer used could form photo-induced cross-links with the exosite 2 of thrombin and the aptamer could bind to the exosite 1. The (K _D^app value for the photoaptamer construct was approximately 40-fold less than that for the primary photoaptamer (5.3 and 190 nM, respectively). Upon exposure of the equimolar mixtures of thrombin with the photoaptamer construct to the UV radiation at 308 nm the equal yield of the crosslinked complexes was observed at concentrations, which were lower by two orders of magnitude than in the case of the primary photoaptamer. It was found that concurrently with crosslinking to thrombin a photo-induced inactivation of the photoaptamer occurs presumably due to formation of the intermolecular crosslinking.     

RNA aptamers to S-adenosylhomocysteine: kinetic properties, divalent cation dependency, and comparison with anti-S-adenosylhomocysteine antibody

To explore the potential of RNA aptamers as small-molecule discriminating devices, we have characterized the properties of aptamers selected from a library of approximately 10(14) variants through their interaction with S-adenosylhomocysteine (SAH, AdoHcy). Competition studies with SAH and azaSAM analogues revealed that the Hoogsteen face of adenine is the main contributor to binding, whereas specificity for SAH is conferred by a secondary contact point at or near the sulfur/thioether of homocysteine (Hcy). Binding specificities were determined by both affinity chromatography and a novel method designed for the biosensor. The kinetic properties of individual aptamers, including the "classic" ATP aptamer that also emerged in our selection, were studied by biosensor analysis. Association rates were slow, but the complexes were stable, suggesting micro- to submicromolar affinities. A solution affinity of approximately 0.1 microM was found for the strongest binding variant under the conditions used for selection (5 mM Mg(2+)). Systematic studies of the effect of Mg(2+) and Mn(2+) on binding, however, revealed that the affinity of the aptamers could be substantially improved, and at optimized conditions of Mn(2+) the affinity of one of the aptamers approached that of an anti-SAH antibody with similar/identical binding specificity. Comparisons with the MAb suggest that the on rate is the limiting factor for high-affinity binding by these aptamers, and comparison with a truncated aptamer shows that shortening of RNA constructs may alter binding kinetics as well as sensitivity to ions.     

DNA aptamers against the receptor binding region of hemagglutinin prevent avian influenza viral infection

The entrance of influenza virus into host cells is facilitated by the attachment of the globular region of viral hemagglutinin to the sialic acid receptors on host cell surfaces. In this study, we have cloned the cDNA fragment encoding the entire globular region (residues 101–257) of hemagglutinin of the H9N2 type avian influenza virus (A/ck/Korea/ms96/96). The protein segment (denoted as the H9 peptide), which was expressed and purified in E. coli, was used for the immunization of BALB/c mice to obtain the anti-H9 antiserum. To identify specific DNA aptamers with high affinity to H9 peptide, we conducted the SELEX method; 19 aptamers were newly isolated. A random mixture of these aptamers showed an increased level of binding affinity to the H9 peptide. The sequence alignment analysis of these aptamers revealed that 6 aptamers have highly conserved consensus sequences. Among these, aptamer C7 showed the highest similarity to the consensus sequences. Therefore, based on the C7 aptamer, we synthesized a new modified aptamer designated as C7-35M. This new aptamer showed strong binding capability to the viral particles. Furthermore, it could prevent MDCK cells from viral infection by strong binding to the viral particles. These results suggest that our aptamers can recognize the hemagglutinin protein of avian influenza virus and inhibit the binding of the virus to target receptors required for the penetration of host cells.     

Higher-order association states of cellular ERBB3 probed with photo-cross-linkable aptamers

Nucleic acid aptamers are rapidly gaining prominence as diagnostic tools, targeting reagents, and potential therapeutics. To extend the use of aptamers into the biochemical analysis of protein interactions on the surface of live cells, we converted an enzymatically generated RNA aptamer into a photo-cross-linkable affinity tag through the replacement of all uracils with 4-thiouracil. Specifically, we converted a previously selected, inhibitory aptamer that binds the soluble extracellular domains of the ERBB3 receptor into a targeted and highly specific cross-linking reagent in a live cell setting. Since the photo-cross-linkable aptamer has two functionalities, targeted and highly selective as well as unspecific cross-linking capability, the attachment of this inhibitory aptamer converts ERBB3 into a passive and signaling incompetent probe of its immediate receptor environment. This approach detects receptor clustering of endogenous ERBB3 in the breast cancer cell line MCF7 at levels as low as 25000 receptors per cell and at aptamer concentrations as low as 20 nM. Our analysis also indicates that ERBB3 receptors are apparently segregated from ERBB2 receptors in their resting state, and both ligand-activated ERBB3 and ERBB2 do not share the same microenvironment as inactive ERBB3.     

Development of a biosensor for electrochemical detection of tumor-associated proteins in blood plasma of cancer patients by aptamers

A molecular biosensor based on DNA aptamers (aptasensor) for the diagnosis of lung cancer in blood plasma samples was designed. To create the aptasensor, the aptamer 17_80, obtained in the study of postoperative material, was used. The affinity and binding selectivity of the aptamer 17_80 to the lung tumor tissue was confirmed on histological sections of postmortem samples of lung tissue. Using affinity enrichment and mass spectrometry, a possible target molecule of the aptamer 17_80, vimentin, was found.     

Rapid and sensitive detection of Nampt (PBEF/visfatin) in human serum using an ssDNA aptamer-based capacitive biosensor

A single-stranded DNA (ssDNA) aptamer was successfully developed to specifically bind to nicotinamide phosphoribosyl transferase (Nampt) through systematic evolution of ligands by exponential enrichment (SELEX) and successfully implemented in a gold-interdigitated (GID) capacitor-based biosensor. Surface plasmon resonance (SPR) analysis of the aptamer revealed high specificity and affinity (K(d)=72.52nM). Changes in surface capacitance/charge distribution or dielectric properties in the response of the GID capacitor surface covalently coupled to the aptamers in response to changes in applied AC frequency were measured as a sensing signal based on a specific interaction between the aptamers and Nampt. The limit of detection for Nampt was 1ng/ml with a dynamic serum detection range of up to 50ng/ml; this range includes the clinical requirement for both normal Nampt level, which is 15.8ng/ml, and Nampt level in type 2 diabetes mellitus (T2DM) patients, which is 31.9ng/ml. Additionally, the binding kinetics of aptamer-Nampt interactions on the capacitor surface showed that strong binding occurred with increasing frequency (range, 700MHz-1GHz) and that the dissociation constant of the aptamer under the applied frequency was improved 120-240 times (K(d)=0.3-0.6nM) independent on frequency. This assay system is an alternative approach for clinical detection of Nampt with improved specificity and affinity.     

Investigation of the interaction between split aptamer and vascular endothelial growth factor 165 using single molecule force spectroscopy

Understanding the binding of split aptamer/its target could become a breakthrough in the application of split aptamer. Herein, vascular endothelial growth factor (VEGF), a major biomarker of human diseases, was used as a model, and its interaction with split aptamer was explored with single molecule force spectroscopy (SMFS). SMFS demonstrated that the interaction force of split aptamer/VEGF₁₆₅ was 169.44 ± 6.59 pN at the loading rate of 35.2 nN/s, and the binding probability of split aptamer/VEGF₁₆₅ was dependent on the concentration of VEGF₁₆₅. On the basis of dynamic force spectroscopy results, one activation barrier in the dissociation process of split aptamer/VEGF₁₆₅ complexes was revealed, which was similar to that of the intact aptamer/VEGF₁₆₅. Besides, the dissociation rate constant (k_off) of split aptamer/VEGF₁₆₅ was close to that of intact aptamer/VEGF₁₆₅, and the interaction force of split aptamer/VEGF₁₆₅ was higher than the force of intact aptamer/VEGF₁₆₅. It indicated that split aptamer also possessed high affinity with VEGF₁₆₅. The work can provide a new method for exploring the interaction of split aptamer/its targets at single‐molecule level.     

Electrochemical impedance spectroscopy for study of aptamer-thrombin interfacial interactions

A simple and highly sensitive electrochemical impedance spectroscopy (EIS) biosensor based on a thrombin-binding aptamer as molecular recognition element was developed for the determination of thrombin. The signal enhancement was achieved by using gold nanoparticles (GNPs), which was electrodeposited onto a glassy carbon electrode (GCE), as a platform for the immobilization of the thiolated aptamer. In the measurement of thrombin, the change in interfacial electron transfer resistance of the biosensor using a redox couple of [Fe(CN)₆]^3−/4− as the probe was monitored. The increase of the electron transfer resistance of the biosensor is linear with the concentration of thrombin in the range from 0.12 nM to 30 nM. The association and dissociation rate constants of the immobilized aptamer–thrombin complex were 6.7 × 10³ M⁻¹ s⁻¹ and 1.0 × 10⁻⁴ s⁻¹, respectively. The association and dissociation constants of three different immobilized aptamers binding with thrombin were measured and the difference of the dissociation constants obtained was discussed. This work demonstrates that GNPs electrodeposited on GCE used as a platform for the immobilization of the thiolated aptamer can improve the sensitivity of an EIS biosensor for the determination of protein. This work also demonstrates that EIS method is an efficient method for the determination of association and dissociation constants on GNPs modified GCE.     

Molecular recognition force spectroscopy study of the dynamic interaction between aptamer GBI‐10 and extracellular matrix protein tenascin‐C on human glioblastoma cell

Molecular recognition force spectroscopy (MR‐FS) was applied to investigate the dynamic interaction between aptamer GBI‐10 and tenascin‐C (TN‐C) on human glioblastoma cell surface at single‐molecule level. The unbinding force between aptamer GBI‐10 and TN‐C was 39 pN at the loading rate of 0.3 nN sec^?1. A series of kinetic parameters concerning interaction process such as the unbinding force f_u, the association rate constant k_on, dissociation rate constant at zero force k_off, and dissociation constant K_D for aptamer GBI‐10/TN‐C complexes were acquired. In addition, the interaction of aptamer GBI‐10 with TN‐C depended on the presence of Mg²⁺. This work demonstrates that MR‐FS can be used as an attractive tool for exploring the interaction forces and dynamic process of aptamer and ligand at the single‐molecule level. As a future perspective, MR‐FS may be used as a potential diagnostic and therapeutic tool by combining with other techniques. Copyright © 2012 John Wiley & Sons, Ltd.     

Generation of RNA aptamers to the G-protein-coupled receptor for neurotensin,NTS-1

G-protein-coupled receptors (GPCRs) are integral membrane proteins involved in signal transduction and constitute major drug targets for disease therapy. Aptamers, which are globular RNA or DNA molecules evolved to specifically bind a target, could represent a valuable tool with which to probe the role of such receptors in normal tissue and disease pathology and for cocrystallization with receptors for structure determination by X-ray crystallography. Using the bacterially expressed rat neurotensin receptor NTS-1 as an example, we describe a strategy for the generation of GPCR-specific RNA aptamers. Seven rounds of a "subtractive," paramagnetic bead-based selection protocol were used to enrich for neurotensin receptor-specific aptamers, while circumventing the evolution of aptamers reactive to minor protein contaminants. Representatives of each aptamer family were analyzed in Escherichia coli membrane nitrocellulose filter binding assays. Eight aptamers demonstrated specificity for the neurotensin receptor. One aptamer, P19, was characterized in detail and shown to bind to both the rat receptor and the human receptor with nanomolar affinity. P19 was also shown to interact with rat neurotensin receptor expressed in CHO cells, in both membrane preparations and intact cells. P19 represents the first example of a GPCR-specific RNA aptamer.     

Comparative thermodynamic analysis of thrombin interaction with anti-thrombin aptamers and their heterodimeric construct

Aptamers interacting selectively with the anion-binding exosites 1 and 2 of thrombin were merged into dimeric oligonucleotide constructs by means of a poly-(dT)-linker of 35 nucleotides (nt) in length. Complexes of thrombin with the aptamers and their hetero- and homodimeric constructs were measured using an optical biosensor Biacore-3000. The K _D values obtained for the hetero- and homodimeric constructs were correspondingly 25–30- and 2–3-fold lower than those for the primary aptamers. Analysis of temperature dependencies of the K _D values within the temperature interval of 10–40°C has shown that affinity increases with the temperature decrease. The values of the enthalpy change ΔH upon formation of complexes of thrombin with the aptamers and the heterodimeric construct were basically the same. The value of the entropy change ΔS upon complex formation of thrombin with the aptamer heterodimeric construct was 1.5–2-fold higher than the ΔS values for the complexes with the aptamers. The complex formation and dissociation rates increased with the elevation of temperature from 10 to 37°C. However, at both temperatures the dissociation rate for the complex of thrombin with the heterodimeric construct was evidently lower that for the complexes with the aptamers.     

Aptamer Selection Based on G4-Forming Promoter Region

We developed a method for aptamer identification without in vitro selection. We have previously obtained several aptamers, which may fold into the G-quadruplex (G4) structure, against target proteins; therefore, we hypothesized that the G4 structure would be an excellent scaffold for aptamers to recognize the target protein. Moreover, the G4-forming sequence contained in the promoter region of insulin can reportedly bind to insulin. We thus expected that G4 DNAs, which are contained in promoter regions, could act as DNA aptamers against their gene products. We designated this aptamer identification method as “G4 promoter-derived aptamer selection (G4PAS).” Using G4PAS, we identified vascular endothelial growth factor (VEGF)165, platelet-derived growth factor-AA (PDGF)-AA, and RB1 DNA aptamers. Surface plasmon resonance (SPR) analysis revealed that the dissociation constant (K _d) values of VEGF165, PDGF-AA, and RB1 DNA aptamers were 1.7 × 10⁻⁷ M, 6.3 × 10⁻⁹ M, and 4.4 × 10⁻⁷ M, respectively. G4PAS is a simple and rapid method of aptamer identification because it involves only binding analysis of G4 DNAs to the target protein. In the human genome, over 40% of promoters contain one or more potential G4 DNAs. G4PAS could therefore be applied to identify aptamers against target proteins that contain G4 DNAs on their promoters.     

Selection of DNA aptamers for capture and detection of Salmonella Typhimurium using a whole-cell SELEX approach in conjunction with cell sorting

Alternative ligands such as nucleic acid aptamers can be used for pathogen capture and detection and offer advantages over antibodies, including reduced cost, ease of production and modification, and improved stability. DNA aptamers demonstrating binding specificity to Salmonella enterica serovar Typhimurium were identified by whole-cell-systematic evolution of ligands by exponential enrichment (SELEX) beginning with a combinatorial library of biotin-labeled single stranded DNA molecules. Aptamer specificity was achieved using whole-cell counter-SELEX against select non-Salmonella genera. Aptamers binding to Salmonella were sorted, cloned, sequenced, and characterized for binding efficiency. Out of 18 candidate aptamers screened, aptamer S8-7 showed relatively high binding affinity with an apparent dissociation constant (K _d value) of 1.73?±?0.54 μM and was selected for further characterization. Binding exclusivity analysis of S8-7 showed low apparent cross-reactivity with other foodborne bacteria including Escherichia coli O157: H7 and Citrobacter braakii and moderate cross-reactivity with Bacillus cereus. Aptamer S8-7 was successfully used as a ligand for magnetic capture of serially diluted Salmonella Typhimurium cells, followed by downstream detection using qPCR. The lower limit of detection of the aptamer magnetic capture-qPCR assay was 10²–10³?CFU equivalents of Salmonella Typhimurium in a 290-μl sample volume. Mean capture efficiency ranged from 3.6 to 12.6 %. Unique aspects of the study included (a) the use of SELEX targeting whole cells; (b) the application of flow cytometry for aptamer pool selection, thereby favoring purification of ligands with both high binding affinity and targeting abundant cell surface moieties; and (c) the use of pre-labeled primers that circumvented the need for post-selection ligand labeling. Taken together, this study provides proof-of-concept that biotinylated aptamers selected by whole-cell SELEX can be used in a qPCR-based capture-detection platform for Salmonella Typhimurium.