Oligonucleotide aptamers that recognize small molecules

Selection and identification of a DNA aptamer targeted to Vibrio parahemolyticus

A whole-bacterium systemic evolution of ligands by exponential enrichment (SELEX) method was applied to a combinatorial library of FAM-labeled single-stranded DNA molecules to identify DNA aptamers demonstrating specific binding to Vibrio parahemolyticus . FAM-labeled aptamer sequences with high binding affinity to V. parahemolyticus were identified by flow cytometric analysis. Aptamer A3P, which showed a particularly high binding affinity in preliminary studies, was chosen for further characterization. This aptamer displayed a dissociation constant (K(d)) of 16.88 ± 1.92 nM. Binding assays to assess the specificity of aptamer A3P showed a high binding affinity (76%) for V. parahemolyticus and a low apparent binding affinity (4%) for other bacteria. Whole-bacterium SELEX is a promising technique for the design of aptamer-based molecular probes for microbial pathogens that does not require the labor-intensive steps of isolating and purifying complex markers or targets.

Quantitation of femtomolar protein levels via direct readout with the electrochemical proximity assay

We have developed a separation-free, electrochemical assay format with direct readout that is amenable to highly sensitive and selective quantitation of a wide variety of target proteins. Our first generation of the electrochemical proximity assay (ECPA) is composed of two thrombin aptamers which form a cooperative complex only in the presence of target molecules, moving a methylene blue (MB)-conjugated oligonucleotide close to a gold electrode. Without washing steps, electrical current is increased in proportion to the concentration of a specific target protein. By employing a DNA-based experimental model with the aptamer system, we show that addition of a short DNA competitor can reduce background current of the MB peak to baseline levels. As such, the detection limit of aptamer-based ECPA for human thrombin was 50 pM via direct readout. The dual-probe nature of ECPA gave high selectivity and 93% recovery of signal from 2.5 nM thrombin in 2% bovine serum albumin (BSA). To greatly improve the flexibility of ECPA, we then proved the system functional with antibody-oligonucleotide conjugates as probes; the insulin detection limit was 128 fM with a dynamic range of over 4 orders of magnitude in concentration, again with high assay selectivity. ECPA thus allows separation-free, highly sensitive, and highly selective protein detection with a direct electrochemical readout. This method is extremely flexible, capable of detecting a wide variety of protein targets, and is amenable to point-of-care protein measurement, since any target with two aptamers or antibodies could be assayed via direct electrochemical readout.

A nanoscale drug delivery carrier using nucleic acid aptamers for extended release of therapeutic

We have synthesized, characterized, and optimized a novel nano drug-delivery carrier that utilizes the versatile properties of nucleic acid for programmable and on-demand drug release. The drug-delivery carrier consists of 15 nm gold nanoparticles (AuNPs) functionalized with drug binding DNA aptamers via single-stranded (ss) anchor DNA. The presence of anchor DNA makes the nanocarrier flexible to be reprogrammed with various aptamers. Under the optimum binding conditions (0.4 M NaCl and 4 μM DNA), a maximum of 101 ± 8 anchor DNA strands were conjugated per particle. On binding DNA-aptamer:drug complexes to AuNPs, a maximum of 35 neomycin molecules were bound per AuNP. Controlled and extended release of drug from the synthesized carrier was obtained by temperature and affinity modulations. Furthermore, for the first time, we demonstrated that neomycin could bind to DNA with very high affinity (K(d) = 98.101 nM). This DNA-based nanocarrier, designed using the principles of molecular biology, is expected to impact a number of treatment strategies.

FROM THE CLINICAL EDITOR

In this basic science work, the authors demonstrate the feasibility of utilizing a novel nano drug-delivery carrier with the versatile properties of nucleic acid for programmable and on-demand drug release.

Luminescent detection of DNA-binding proteins

Transcription factors play a central role in cell development, differentiation and growth in biological systems due to their ability to regulate gene expression by binding to specific DNA sequences within the nucleus. The dysregulation of transcription factor signaling has been implicated in the pathogenesis of a number of cancers, developmental disorders, inflammation and autoimmunity. There is thus a high demand for convenient high-throughput methodologies able to detect sequence-specific DNA-binding proteins and monitor their DNA-binding activities. Traditional approaches for protein detection include gel mobility shift assays, DNA footprinting and enzyme-linked immunosorbent assays (ELISAs) which tend to be tedious, time-consuming, and may necessitate the use of radiographic labeling. By contrast, luminescence technologies offer the potential for rapid, sensitive and low-cost detection that are amenable to high-throughput and real-time analysis. The discoveries of molecular beacons and aptamers have spear-headed the development of new luminescent methodologies for the detection of proteins over the last decade. We survey here recent advances in the development of luminescent detection methods for DNA-binding proteins, including those based on molecular beacons, aptamer beacons, label-free techniques and exonuclease protection.

Aptasensor for ampicillin using gold nanoparticle based dual fluorescence-colorimetric methods

A gold nanoparticle based dual fluorescence-colorimetric method was developed as an aptasensor to detect ampicillin using its single-stranded DNA (ssDNA) aptamer, which was discovered by a magnetic bead-based SELEX technique. The selected aptamers, AMP4 (5'-CACGGCATGGTGGGCGTCGTG-3'), AMP17 (5'-GCGGGCGGTTGTATAGCGG-3'), and AMP18 (5'-TTAGTTGGGGTTCAGTTGG-3'), were confirmed to have high sensitivity and specificity to ampicillin (K(d), AMP7 = 9.4 nM, AMP17 = 13.4 nM, and AMP18 = 9.8 nM, respectively). The 5'-fluorescein amidite (FAM)-modified aptamer was used as a dual probe for observing fluorescence differences and color changes simultaneously. The lower limits of detection for this dual method were a 2 ng/mL by fluorescence and a 10 ng/mL by colorimetry for ampicillin in the milk as well as in distilled water. Because these detection limits were below the maximum residue limit of ampicillin, this aptasensor was sensitive enough to detect antibiotics in food products, such as milk and animal tissues. In addition, this dual aptasensor will be a more accurate method for antibiotics in food products as it concurrently uses two detection methods: fluorescence and colorimetry.

Aptamers recognizing glycosylated hemagglutinin expressed on the surface of vaccinia virus-infected cells

Traditional methods for detection and identification of pathogenic viruses or bacteria tend to be slow and cumbersome. We have developed aptamer probes with the capacity to rapidly detect the presence of viral infection with specificity and sensitivity. Vaccinia virus (VV) was chosen as the model because it is closely related to variola virus that causes smallpox. A method known as cell-SELEX (systematic evolution of ligands by exponential enrichment) was used to generate very selective and highly specific aptamers designed to recognize proteins expressed on the surface of VV-infected cells. Characterization of the aptamers showed that the virus-encoded hemagglutinin, a protein expressed on the surface of infected cells, is the preferential binding target. These studies show the feasibility of generating aptamers against a given specific infectious agent and will enable further development of aptamers as diagnostic and/or therapeutic tools against a broad range of infectious agents.

Gold nanoparticle-based colorimetric detection of kanamycin using a DNA aptamer

A selective kanamycin-binding single-strand DNA (ssDNA) aptamer (TGGGGGTTGAGGCTAAGCCGA) was discovered through in vitro selection using affinity chromatography with kanamycin-immobilized sepharose beads. The selected aptamer has a high affinity for kanamycin and also for kanamycin derivatives such as kanamycin B and tobramycin. The dissociation constants (K(d) [kanamycin]=78.8 nM, K(d) [kanamycin B]=84.5 nM, and K(d) [tobramycin]=103 nM) of the new aptamer were determined by fluorescence intensity analysis using 5'-fluorescein amidite (FAM) modification. Using this aptamer, kanamycin was detected down to 25 nM by the gold nanoparticle-based colorimetric method. Because the designed colorimetric method is simple, easy, and visible to the naked eye, it has advantages that make it useful for the detection of kanamycin. Furthermore, the selected new aptamer has many potential applications as a bioprobe for the detection of kanamycin, kanamycin B, and tobramycin in pharmaceutical preparations and food products.

A simple and rapid approach for measurement of dissociation constants of DNA aptamers against proteins and small molecules via automated microchip electrophoresis

Automated microchip electrophoresis was used as a simple and rapid method to measure effective dissociation constants (K(d,eff)) of aptamers against both large and small molecule targets. Human thrombin, immunoglobulin E (IgE), and adenosine triphosphate (ATP) were selected as model analytes to validate the method, with four ligands including two DNA aptamers for thrombin (two distinct epitopes), an IgE aptamer, and an ATP aptamer. The approach is based on a microchip version of a DNA mobility shift assay. Non-denaturing microchip gel electrophoresis separations of DNA could resolve and quantify unbound from target-bound aptamers when using large molecules as targets. To extend the technique to small molecule targets such as ATP, an aptamer/competitor strategy was used, in which a DNA competitor complementary to the aptamer could be displaced by ATP and electrophoretically resolved. Using an automated microchip electrophoresis platform, parallel separations of 11 titration samples were completed in ~0.5 h. Analytical performance comparisons show that our approach provides significant advantages in minimized reagent consumption (typically tens of pmol of aptamer and target), reduced analysis time, and minimized user interaction when compared to previously reported methods for aptamer K(d) measurement. Moreover, the flexibility and ease of K(d,eff) measurement for aptamers against large and small targets make this a unique and valuable approach that should find widespread use. Finally, the feasibility of using this method during aptamer selection processes (e.g. SELEX) was shown by accurate bulk K(d,eff) measurement of a known thrombin aptamer (THRaptA) spiked into a random-sequence DNA pool at as low as 5.0% (molar %) of the total pool; only ~825 fmol of total binding sequences were needed for an 11-point titration curve.

Ligand-induced conformational capture of a synthetic tetracycline riboswitch revealed by pulse EPR

RNA aptamers are in vitro-selected binding domains that recognize their respective ligand with high affinity and specificity. They are characterized by complex three-dimensional conformations providing preformed binding pockets that undergo conformational changes upon ligand binding. Small molecule-binding aptamers have been exploited as synthetic riboswitches for conditional gene expression in various organisms. In the present study, double electron-electron resonance (DEER) spectroscopy combined with site-directed spin labeling was used to elucidate the conformational transition of a tetracycline aptamer upon ligand binding. Different sites were selected for post-synthetic introduction of either the (1-oxyl-2,2,5,5-tetramethylpyrroline-3-methyl) methanethiosulfonate by reaction with a 4-thiouridine modified RNA or of 4-isocyanato-2,6-tetramethylpiperidyl-N-oxid spin label by reaction with 2'-aminouridine modified RNA. The results of the DEER experiments indicate the presence of a thermodynamic equilibrium between two aptamer conformations in the free state and capture of one conformation upon tetracycline binding.

In vitro selection of Leishmania infantum H3-binding ssDNA aptamers

Aptamers are single-stranded DNA or RNA oligonucleotides that adopt specific three-dimensional structures binding with high affinity and specificity to their targets. These molecules are being currently used with detection and diagnosis purposes. Parasites of the genus Leishmania cause leishmaniosis in humans and animals. Interestingly, Leishmania do not condense their chromatin during mitosis, and histone genes could be responsible for this fact. Although histones are extremely conserved proteins, reflecting their apparent universality of function, sequence similarity of kinetoplastid core histones with that of higher eukaryotes is found predominantly in the globular region. However, high sequence divergences in the N-terminal and C-terminal domains are found that convert them into potential diagnostic and/or therapeutics targets. We have successfully isolated a pool of DNA aptamers, named SELH3, which binds to Leishmania infantum H3 with high affinity and specificity. Thus, it appears that this novel anti-H3 aptamer population may be of potential application as a diagnostic system for leishmaniosis.

In vitro selection of RNA aptamers to a small molecule target

This unit describes the selection of aptamers from a single-stranded RNA pool that bind to small molecule targets. Aptamers generated by this type of selection experiment can potentially function as receptors for small molecules in numerous applications, including medical diagnostics, therapeutics, and environmental monitoring. This unit describes two modes of selection, one by column filtration and one by batch selection.

Label-free fluorescent aptamer sensor based on regulation of malachite green fluorescence

We report a label-free fluorescent aptamer sensor for adenosine based on the regulation of malachite green (MG) fluorescence, with comparable sensitivity and selectivity to other labeled adenosine aptamer-based sensors. The sensor consists of free MG, an aptamer strand containing an adenosine aptamer next to an MG aptamer, and a bridging strand that partially hybridizes to the aptamer strand. Such a hybridization prevents MG from binding to MG aptamer, resulting in low fluorescence of MG in the absence of adenosine. Addition of adenosine causes the adenosine aptamer to bind adenosine, weakening the hybridization of the aptamer strand with the bridging strand, making it possible for MG to bind to the aptamer strand and exhibit high fluorescence intensity. Since this design is based purely on nucleic acid hybridization, it can be generally applied to other aptamers for the label-free detection of a broad range of analytes.

An alternative strategy to synthesize PNA and DNA magnetic conjugates forming nanoparticle assembly based on PNA/DNA duplexes

In this paper we report an alternative approach to synthesize PNA and DNA magnetic nanoconjugates. Chemical modifications were introduced on the 130 nm dextran-magnetite particles to obtain poly-functionalized particles containing reversible bonds sensitive to the cellular environment and suitable for the direct introduction of unmodified oligomers. Due to the polyvalent nature of the nanoparticles, when the complementary PNA and DNA nanoconjugates were mixed together, the resulting duplex structures bring to a nanoparticle assembly driven by W-C base pairs. The formation of the nanoparticle assembly was investigated by optical spectroscopy (UV, FTIR), scanning and transmission electron microscopies and by the analysis of the macroscopic behaviour of the nanoparticle-conjugates in aqueous solution with and without magnetic field application. Furthermore, serum stability assays revealed an increased enzymatic resistance in FCS of the PNA/DNA nanoconjugate duplex with respect to the unconjugated duplex. The described nanosystem could be extended to other duplex structures, possibly involving aptameric sequences of biomedical relevance, and could be very useful in order to obtain high local concentration at the target site of both the duplex and the magnetic nanoparticles in biotechnological applications.

Peptide- and aptamer-functionalized nanovectors for targeted delivery of therapeutics

Targeted delivery of therapeutics is an area of vigorous research, and peptide- and aptamer-functionalized nanovectors are a promising class of targeted delivery vehicles. Both peptide- and aptamer-targeting ligands can be readily designed to bind a target selectively with high affinity, and more importantly are molecules accessible by chemical synthesis and relatively compact compared with antibodies and full proteins. The multitude of peptide ligands that have been used for targeted delivery are covered in this review, with discussion of binding selectivity and targeting performance for these peptide sequences where possible. Aptamers are RNA or DNA strands evolutionarily engineered to specifically bind a chosen target. Although use of aptamers in targeted delivery is a relatively new avenue of research, the current state of the field is covered and promises of future advances in this area are highlighted. Liposomes, the classic drug delivery vector, and polymeric nanovectors functionalized with peptide or aptamer binding ligands will be discussed in this review, with the exclusion of other drug delivery vehicles. Targeted delivery of therapeutics, from DNA to classic small molecule drugs to protein therapeutics, by these targeted nanovectors is reviewed with coverage of both in vitro and in vivo deliveries. This is an exciting and dynamic area of research and this review seeks to discuss its broad scope.

Investigations on the specificity of DNA aptamers binding to ethanolamine

In our previous work, we selected aptamers binding to ethanolamine, one of the smallest molecular aptamer targets so far (Mann, D., Reinemann, C., Stoltenburg, R. and Strehlitz, B. Biochem. Biophys. Res. Commun. 2005, 338, 1928-1934). Two representatives of these aptamers (EA#14.3 and EA#9.4) were analyzed regarding their specificity. Ethanolamine is a very small organic molecule (M(w) = 61.08) with biological, medical, and industrial relevance. Its small size represented a challenge for aptamer development, as ethanolamine only consists of a short carbon chain (2C) and two functional groups (amino and hydroxyl group). Related organic molecules, ethanolamine derivatives, and some amino acids were tested to act as potential binding partners for these aptamers. In this way we were able to determine the exact binding domain within the target. The results revealed that both aptamers bind to various molecules, which contain a freely accessible ethyl- or methylamine group. In contrast to the amino group (in a primary, secondary, or tertiary amine) the hydroxyl group was not necessary for the aptamer binding. The aptamers were not able to bind to negatively charged organic molecules, despite containing an ethyl- or methylamine group, nor did they bind to molecules with quaternary amines. The selected ethanolamine binding aptamers are useful for the detection of molecules containing accessible ethyl- or methylamine groups; they can be used as linker elements to immobilize a target molecule of interest on a surface or to purify targets from complex samples.

Nanoparticles/Dip stick

Aptamers are single-stranded nucleic acids or peptides that can bind target molecules with high affinity and specificity. The conformation of an aptamer usually changes upon binding to its target analyte, and this property has been used in a wide variety of sensing applications, including detections based on fluorescence, electrochemistry, mass, or color change. Because native nucleic acids do not possess signaling moieties required for most detection methods, aptamer sensors usually involve labeling of external signaling groups. Among the many kinds of labels, inorganic nanoparticles are emerging as highly attractive candidates because some of their unique properties. Here, we describe protocols for the preparation of aptamer-linked gold nanoparticles (AuNPs) that undergo fast disassembly into red dispersed nanoparticles upon binding of target analytes. This method has been proven to be generally applicable for colorimetric sensing of a broad range of analytes. The sample protocols have also been successfully applied to quantum dots and magnetic nanoparticles. Finally, to increase the user friendliness of the method, the sensors have been converted into simple dipstick tests using lateral flow devices.

Sensing of UO22+ and design of logic gates by the application of supramolecular constructs of ion-dependent DNAzymes

Supramolecular constructs composed of ion-dependent DNAzymes and their substrates were used to develop DNAzyme cascades that enabled the sensitive detection of UO22+ or the activation of logic gate operations. The supramolecular complex between the UO22+-dependent DNAzyme and its substrate leads, in the presence of UO22+, to the cleavage of the substrate and to the release of the HRP-mimicking DNAzyme that enables the optical analysis of UO22+ (detection limit 1 x 10-9 M). Similarly, supramolecular complexes between the Mg2+- and UO22+-dependent DNAzymes and tailored substrates enables the design of the "OR" and "AND" logic gates, using Mg2+ and UO22+ as inputs.

Specific detection of oxytetracycline using DNA aptamer-immobilized interdigitated array electrode chip

An electrochemical sensing system for oxytetracycline (OTC) detection was developed using ssDNA aptamer immobilized on gold interdigitated array (IDA) electrode chip. A highly specific ssDNA aptamer that bind to OTC with high affinity was employed to discriminate other tetracyclines (TCs), such as doxycycline (DOX) and tetracycline (TET). The immobilized thiol-modified aptamer on gold electrode chip served as a biorecognition element for the target molecules and the electrochemical signals generated from interactions between the aptamers and the target molecules was evaluated by cyclic voltammetry (CV) and square wave voltammetry (SWV). The current decrease due to the interference of bound OTC, DOX or TET was analyzed with the electron flow produced by a redox reaction between ferro- and ferricyanide. The specificity of developed EC-biosensor for OTC was highly distinguishable from the structurally similar antibiotics (DOX and TET). The dynamic range was determined to be 1-100 nM of OTC concentration in semi-logarithmic coordinates.

Metalloregulation of triple helix formation by control of the loop conformation

The flexible polypyridine ligand, 2,2':6',2('')-terpyridine (terpy), was built into the backbone of oligonucleotides to form DNA conjugates. The terpy unit functioned as a good loop when the conjugates formed the bimolecular triplexes with complementary oligopurine. The triplex structure was destabilized by the specific interaction with divalent transition metal ions (Cu(2+), Zn(2+), and Fe(2+)), in particular Cu(2+) ions. This ion destabilized one of the triplexes by 4.2 kcalmol(-1) or made the triplex formation constant less than 1/10(3) at 298 K. This result is attributed to the substantial turbulence of the terminal structure of the triplexes.

Kinetic capillary electrophoresis-based affinity screening of aptamer clones

DNA aptamers are single stranded DNA (ssDNA) molecules artificially selected from random-sequence DNA libraries for their specific binding to a certain target. DNA aptamers have a number of advantages over antibodies and promise to replace them in both diagnostic and therapeutic applications. The development of DNA aptamers involves three major stages: library enrichment, obtaining individual DNA clones, and the affinity screening of the clones. The purpose of the screening is to obtain the nucleotide sequences of aptamers and the binding parameters of their interaction with the target. Highly efficient approaches have been recently developed for the first two stages, while the third stage remained the rate-limiting one. Here, we introduce a new method for affinity screening of individual DNA aptamer clones. The proposed method amalgamates: (i) aptamer amplification by asymmetric PCR (PCR with a primer ratio different from unity), (ii) analysis of aptamer-target interaction, combining in-capillary mixing of reactants by transverse diffusion of laminar flow profiles (TDLFP) and affinity analysis using kinetic capillary electrophoresis (KCE), and (iii) sequencing of only aptamers with satisfying binding parameters. For the first time we showed that aptamer clones can be directly used in TDLFP/KCE-based affinity analysis without an additional purification step after asymmetric PCR amplification. We also demonstrated that mathematical modeling of TDLFP-based mixing allows for the determination of K(d) values for the in-capillary reaction of an aptamer and a target and that the obtained K(d) values can be used for the accurate affinity ranking of aptamers. The proposed method does not require the knowledge of aptamer sequences before screening, avoids lengthy (3-5 h) purification steps of aptamer clones, and minimizes reagent consumption to nanoliters.

Massively parallel interrogation of aptamer sequence, structure and function

Background

Optimization of high affinity reagents is a significant bottleneck in medicine and the life sciences. The ability to synthetically create thousands of permutations of a lead high-affinity reagent and survey the properties of individual permutations in parallel could potentially relieve this bottleneck. Aptamers are single stranded oligonucleotides affinity reagents isolated by in vitro selection processes and as a class have been shown to bind a wide variety of target molecules.

Methodology/Principal Findings

High density DNA microarray technology was used to synthesize, in situ, arrays of approximately 3,900 aptamer sequence permutations in triplicate. These sequences were interrogated on-chip for their ability to bind the fluorescently-labeled cognate target, immunoglobulin E, resulting in the parallel execution of thousands of experiments. Fluorescence intensity at each array feature was well resolved and shown to be a function of the sequence present. The data demonstrated high intra- and inter-chip correlation between the same features as well as among the sequence triplicates within a single array. Consistent with aptamer mediated IgE binding, fluorescence intensity correlated strongly with specific aptamer sequences and the concentration of IgE applied to the array.

Conclusion and Significance

The massively parallel sequence-function analyses provided by this approach confirmed the importance of a consensus sequence found in all 21 of the original IgE aptamer sequences and support a common stem:loop structure as being the secondary structure underlying IgE binding. The microarray application, data and results presented illustrate an efficient, high information content approach to optimizing aptamer function. It also provides a foundation from which to better understand and manipulate this important class of high affinity biomolecules.

Prior interaction of ATP with yeast mRNAs enhances protein synthesis at the initiation step

ATP hydrolysis is important for different stages of the protein synthesis process. A novel effect of this nucleotide was detected using mRNAs isolated from S. cerevisiae after phenol extraction of polysomes. When polysomal mRNA (pmRNA) or poly(A)(+) RNA were preincubated with ATP (approximately 3 mM, near physiological concentration), their translational activity in a cell-free system from yeast was stimulated 2-3 fold. This increased translational activity is specific for the poly(A)(+) RNA fraction, correlates with facilitated assembly of 80S initiation complexes, and is associated to increased synthesis of high molecular weight polypeptides. TCA precipitation assays of RNA incubated with [(14)C]ATP suggested an association of the nucleotide with the nucleic acid. The amount of [(14)C]ATP co-precipitated was dependent on magnesium (optimum at 5-6 mM), was partially inhibited by monovalent ions, and was maximal with poli(A)(+) RNA. Existence of RNA-associated kinases or ATPases appear unlikely since neither phosphorylation nor nucleotide hydrolysis were observed during preincubation of pmRNA with ATP. Another evidence of ATP-RNA interaction was an increased absorbance at 260 nm after incubation suggesting unwinding of the RNA secondary structure. Therefore, preincubation with ATP may affect the conformation of mRNAs and thereby facilitate the initiation of protein synthesis. This event could be part of an in vivo energy-dependent mechanism for translational control.

Aptamer displacement identifies alternative small-molecule target sites that escape viral resistance

Aptamers targeting reverse transcriptase (RT) from HIV-1 inhibit viral replication in vitro, presumably by competing with binding of the primer/template complex. This site is not targeted by the currently available small-molecule anti-HIV-1 RT inhibitors. We have identified SY-3E4, a small-molecule inhibitor of HIV-1 RT, by applying a screening assay that utilizes a reporter-ribozyme regulated by the anti-HIV-1 RT aptamer. SY-3E4 displaces the aptamer from the protein, selectively inhibits DNA-dependent, but not RNA-dependent, polymerase activity, and inhibits the replication of both the wild-type virus and a multidrug-resistant strain. Analysis of available structural data of HIV-1 and HIV-2 RTs rationalizes many of the observed characteristics of the inhibitory profiles of SY-3E4 and the aptamer and suggests a previously not considered region in these RTs as a target for antiviral therapy. Our study reveals unexplored ways for rapidly identifying alternative small-molecule target sites in proteins and illustrates strategies for overcoming resistance-conferring mutations with small molecules.

Selection of fluorescent aptamer beacons that light up in the presence of zinc

In order to generate nucleic acid biosensors that could undergo a reversible conformation change in the presence of the metal zinc, a random sequence pool of single-stranded DNA was immobilized on an oligonucleotide affinity column. In the presence of zinc, those species that underwent a conformational change were released from the column, collected, and amplified. A series of negative and positive selections refined the metal specificity of the selected aptamer beacons. Since the aptamer beacons contained a fluorophore, while the bound oligonucleotide contained a quencher, zinc binding also resulted in an increase in fluorescence. One of the selected beacons, Zn-6m2, bound zinc in the low micromolar range, gave a dose-dependent fluorescence signal, and showed an approximately sixfold increase in fluorescence on zinc binding. While some cross-reactivity with cadmium was observed, it should nonetheless prove possible to use the novel selection method to generate and tune the specificity of a variety of reversible metal biosensors. Such biosensors could potentially be used for continuous monitoring of metals in environmental samples.

Electronic aptamer-based sensors

The selection of aptamers-nucleic acids that specifically bind low-molecular-weight substrates or proteins-by the SELEX (systematic evolution of ligands by exponential enrichment) procedure has attracted recent efforts directed to the development of new specific recognition units. In particular, extensive activities have been directed to the application of aptamers as versatile materials for the design of biosensors. The Minireview summarizes the recent accomplishments in developing electronic aptamer-based sensors (aptasensors), which include electrochemical, field-effect transistor, and microgravimetric quartz crystal microbalance sensors, and describes methods to develop amplified aptasensor devices and label-free aptasensors.

Microfluidic selection and applications of aptamers

The high affinity and specificity of aptamers make them ideal reagents for a wide range of analytical applications. It is not surprising that they are finding application in microfluidics as well. CE has proven to be an efficient technique for isolating aptamers. Aptamers have been used as affinity reagents in CE assays. Aptamer-based chromatography stationary phases have demonstrated unique selectivities. Possibly the application that holds the highest potential is aptamer microarrays for screening proteomic samples.

Minimum sequence requirements for selective RNA-ligand binding: a molecular mechanics algorithm using molecular dynamics and free-energy techniques

In vitro evolution techniques allow RNA molecules with unique functions to be developed. However, these techniques do not necessarily identify the simplest RNA structures for performing their functions. Determining the simplest RNA that binds to a particular ligand is currently limited to experimental protocols. Here, we introduce a molecular-mechanics based algorithm employing molecular dynamics simulations and free-energy methods to predict the minimum sequence requirements for selective ligand binding to RNA. The algorithm involves iteratively deleting nucleotides from an experimentally determined structure of an RNA-ligand complex, performing energy minimizations and molecular dynamics on each truncated structure, and assessing which truncations do not prohibit RNA binding to the ligand. The algorithm allows prediction of the effects of sequence modifications on RNA structural stability and ligand-binding energy. We have implemented the algorithm in the AMBER suite of programs, but it could be implemented in any molecular mechanics force field parameterized for nucleic acids. Test cases are presented to show the utility and accuracy of the methodology.

Preparation of aptamer-linked gold nanoparticle purple aggregates for colorimetric sensing of analytes

Aptamers are single-stranded DNA or RNA molecules that can bind target molecules with high affinity and specificity. The conformation of an aptamer usually changes upon binding to its target analyte, and this property has been used in a wide variety of sensing applications, including detection based on fluorescence intensity, polarization, energy transfer, electrochemistry or color change. Colorimetric sensors are particularly important because they minimize or eliminate the necessity of using expensive and complicated instruments. Among the many colorimetric sensing strategies, metallic nanoparticle-based detection is desirable because of the high extinction coefficients and strong distance-dependent optical properties of the nanoparticles. Here, we describe a protocol for the preparation of aptamer-linked gold nanoparticle purple aggregates that undergo fast disassembly into red dispersed nanoparticles upon binding of target analytes. This method has proved to be generally applicable for colorimetric sensing of a broad range of analytes. The time range for the entire protocol is approximately 5 d, including synthesis and functionalization of nanoparticles, preparation of nanoparticle aggregates and sensing.

SELEX--a (r)evolutionary method to generate high-affinity nucleic acid ligands

SELEX stands for systematic evolution of ligands by exponential enrichment. This method, described primarily in 1990 [Ellington, A.D., Szostak, J.W., 1990. In vitro selection of RNA molecules that bind specific ligands. Nature 346, 818-822; Tuerk, C., Gold, L., 1990. Systematic evolution of ligands by exponential enrichment: RNA ligands to bacteriophage T4 DNA polymerase. Science 249, 505-510] aims at the development of aptamers, which are oligonucleotides (RNA or ssDNA) binding to their target with high selectivity and sensitivity because of their three-dimensional shape. Aptamers are all new ligands with a high affinity for considerably differing molecules ranging from large targets as proteins over peptides, complex molecules to drugs and organic small molecules or even metal ions. Aptamers are widely used, including medical and pharmaceutical basic research, drug development, diagnosis, and therapy. Analytical and separation tools bearing aptamers as molecular recognition and binding elements are another big field of application. Moreover, aptamers are used for the investigation of binding phenomena in proteomics. The SELEX method was modified over the years in different ways to become more efficient and less time consuming, to reach higher affinities of the aptamers selected and for automation of the process. This review is focused on the development of aptamers by use of SELEX and gives an overview about technologies, advantages, limitations, and applications of aptamers.

A DNA aptamer population specifically detects Leishmania infantum H2A antigen

Aptamers are short single-stranded DNA or RNA oligonucleotides that are selected in vitro by their affinity and specificity for the target. Binding is a consequence of the particular tertiary structure that they are able to acquire, depending on their sequence. Parasites of the genus Leishmania belongs to the lower eukaryote order Kinetoplastida that causes leishmaniosis in man and animals. Histone genes in Leishmania are of considerable interest because these flagellates do not condense their chromatin during mitosis. Thus, the study of the structural features of histones has been considered of particular interest and, as a result, in recent years a great number of histone genes have been characterized in trypanosomatids. Histones are extremely conserved proteins, reflecting their apparent universality of function. Sequence similarity of kinetoplastid core histones those of higher eukaryotes is found predominantly in the globular region with high sequence divergences in the N- and in the C-terminal domains. These divergences indicate that they may be potential diagnostic and/or therapeutics targets. We have successfully isolated a pool of DNA sequences, named SELH2A, which specifically binds to Leishmania infantum H2A. When tested in an enzyme-linked oligonucleotide assay, slot blot and Western blot analysis, the aptamer pool exhibited specificity in its ability to bind only to H2A antigen but not to other proteins from L. infantum including other histones. Thus, it appears that this novel anti-H2A aptamer population may be of potential application as a diagnostic system for leishmaniosis.

Aptamer-based detection and quantitative analysis of ricin using affinity probe capillary electrophoresis

The ability to detect sub-nanomolar concentrations of ricin using fluorescently tagged RNA aptamers is demonstrated. Aptamers rival the specificity of antibodies and have the power to simplify immunoassays using capillary electrophoresis. Under nonequilibrium conditions, a dissociation constant, Kd, of 134 nM has been monitored between the RNA aptamer and ricin A-chain. With use of this free-solution assay, the detection of 500 pM (approximately 14 ng/mL) or 7.1 amol of ricin is demonstrated. The presence of interfering proteins such as bovine serum albumin and casein do not inhibit this interaction at sub-nanomolar concentrations. When spiked with RNAse A, ricin can still be detected down to 1 nM concentrations despite severe aptamer degradation. This approach offers a promising method for the rapid, selective, and sensitive detection of biowarfare agents.

DNA aptamer-based bioanalysis of IgE by fluorescence anisotropy

A rapid, homogeneous aptamer-based bioanalysis is reported for the sensitive detection of immunoglobulin E (IgE) using fluorescence polarization (FP). 5'-End-labeled D17.4 DNA aptamer was used for IgE detection based on the anisotropy differences of the labeled ligand. Two different fluorophores, fluorescein and Texas Red, were used to analyze IgE in the low-nanomolar range with high specificity. Measurable anisotropy changes were observed with a short equilibration time. Analysis of the binding data reveals a possible cooperative binding process in solution. The nature of the fluorophore clearly influences the sensitivity of the analysis more than the tether length used for the dye conjugation. The local fluorophore motion is seen to influence the sensitivity of the FP probe significantly. Texas Red is seen to be relatively more sensitive for this approach and has apparently favorable dye-DNA interactions, and a limit of detection of 350 pM was obtained. Significant temperature dependence of the FP responses has been observed in this work. Ionic composition of the binding buffer also influences the assay sensitivity. The results confirm the promise and potential of similar homogeneous assays for aptamer-based bioanalysis.

Structures of RNA Switches: Insight into Molecular Recognition and Tertiary Structure

RNA switches (riboswitches) have important functions in gene regulation. They comprise an aptamer domain, which is responsible for ligand binding, and an expression platform that transmits the ligand-binding state of the aptamer domain through a conformational change. Riboswitches can regulate gene expression either at the level of transcription or translation, and it has been proposed that riboswitch mechanisms are even used to regulate the processing of mRNA. This Minireview summarizes the current understanding of the structures and mode of action of RNA switches, with particular focus on secondary and tertiary interactions, which stabilize the global RNA structure and thus determine the function of the aptamer domain.

Structural transitions and thermodynamics of a glycine-dependent riboswitch from Vibrio cholerae

Riboswitches are complex folded RNA domains found in noncoding regions of mRNA that regulate gene expression upon small molecule binding. Recently, Breaker and coworkers reported a tandem aptamer riboswitch (VCI-II) that binds glycine cooperatively. Here, we use hydroxyl radical footprinting and small-angle X-ray scattering (SAXS) to study the conformations of this tandem aptamer as a function of Mg(2+) and glycine concentration. We fit a simple three-state thermodynamic model that describes the energetic coupling between magnesium-induced folding and glycine binding. Furthermore, we characterize the structural conformations of each of the three states: In low salt with no magnesium present, the VCI-II construct has an extended overall conformation, presumably representing unfolded structures. Addition of millimolar concentrations of Mg(2+) in the absence of glycine leads to a significant compaction and partial folding as judged by hydroxyl radical protections. In the presence of millimolar Mg(2+) concentrations, the tandem aptamer binds glycine cooperatively. The glycine binding transition involves a further compaction, additional tertiary packing interactions and further uptake of magnesium ions relative to the state in high Mg(2+) but no glycine. Employing density reconstruction algorithms, we obtain low resolution 3-D structures for all three states from the SAXS measurements. These data provide a first glimpse into the structural conformations of the VCI-II aptamer, establish rigorous constraints for further modeling, and provide a framework for future mechanistic studies.