DNA and RNA aptamers: from tools for basic research towards therapeutic applications

The systematic evolution of ligands by exponential enrichment (SELEX) is a combinatorial oligonucleotide library-based in vitro selection approach in which DNA or RNA molecules are selected by their ability to bind their targets with high affinity and specificity, comparable to those of antibodies. Nucleic acids with high affinity for their targets have been selected against a wide variety of compounds, from small molecules, such as ATP, to membrane proteins and even whole organisms. Recently, the use of the SELEX technique was extended to isolate oligonucleotide ligands, also known as aptamers, for a wide range of proteins of importance for therapy and diagnostics, such as growth factors and cell surface antigens. The number of aptamers generated as inhibitors of various target proteins has increased following automatization of the SELEX process. Their diagnostic and therapeutic efficacy can be enhanced by introducing chemical modifications into the oligonucleotides to provide resistance against enzymatic degradation in body fluids. Several aptamers are currently being tested in preclinical and clinical trials, and aptamers are in the process of becoming a new class of therapeutic agents. Recently, the anti-VEGF aptamer pegaptanib received FDA approval for treatment of human ocular vascular disease.     

In vitro evolution of functional DNA using capillary electrophoresis

Electrophoretic selection with capillary electrophoresis (CE) is used, for the first time, to isolate functional nucleic acid sequences using SELEX (systematic evolution of ligands by exponential enrichment). SELEX uses molecular evolution to select functional sequences (aptamers) from random RNA or DNA libraries. Conventional SELEX is usually performed with affinity chromatography, which may introduce significant bias into the selection step. Important biases include the slow kinetics involved in the elution of strongly bound sequences and performing the selection with the target molecule tethered to the stationary support, not in free solution. In this novel CE-SELEX approach, selection occurs in free solution. The nucleic acid sequences that bind the target undergo a mobility shift, migrating at a different rate, allowing them to be separated from the inactive sequences. Thus, there is no need to wash the active sequences off a column as in conventional SELEX, eliminating any kinetic bias. In this work, the viability of CE-SELEX was demonstrated by performing selections against immunoglobulin E (IgE). Anti-IgE aptamers with dissociation constants as low as 40 nM were obtained in only two rounds of selection.     

细菌的核酸适配体筛选的研究进展

核酸适配体(aptamer)是通过指数富集配体系统进化技术(SELEX)筛选的能够以高亲和力和高特异性识别靶标分子或细胞的核糖核酸(RNA)和单链脱氧核糖核酸(ssDNA)。作为化学抗体,核酸适配体的制备和合成比抗体的成本更低。核酸适配体的靶标范围极其广泛,包括小分子、生物大分子、细菌和细胞等。针对细菌靶标筛选的适配体,目前主要应用于食品、医药和环境中的细菌检测。细菌的核酸适配体筛选可以通过离心法将菌体-适配体复合物与游离的适配体分离,并通过荧光成像、荧光光谱分析、流式细胞仪分选、DNA捕获元件、酶联适配体分析等方法表征适配体与靶标的相互作用。筛选出的适配体可结合生物、化学检测方法用于细菌检测。本文介绍了细菌适配体的筛选和表征方法以及基于适配体的检测方法的最新进展,分析了不同检测方法的利弊,并列出了2011~2015年筛选的细菌的核酸适配体。     

Applications of aptamers for chemistry analysis,medicine and food security

Since aptamer and its in vitro selection process called SELEX were independently described by Ellington and Gold in 1990, extensive research has been undertaken and numerous isolated aptamers for various targets have been applied. Aptamers can bind to a wide range of targets that include small organic molecules, inorganic compounds, haptens and even whole cells with high binding affinity and specificity. Aptamers for a wide range of targets have been selected currently. In addition, aptamers are thermo stable and can also be regenerated easily within a few minutes denaturation, which makes them easy to store or handle. These advantages make aptamers extremely suitable for applications based on molecular recognition as analytical, diagnostic and therapeutic tools. In this review, the recent applications of aptamers for chemistry analysis, medicine and food security, along with the future trend will be discussed.     

Fluorescent sensors for specific RNA: a general paradigm using chemistry and combinatorial biology

Here, we describe a new paradigm for the development of small molecule-based RNA sensors. We prepared a series of potential PET (photoinduced electron transfer) sensors on the basis of 2',7'-dichlorofluorescein (DCF) fluorophore conjugated with two aniline derivatives as electron donors (quenchers). NMR and fluorescent spectroscopic analyses of these DCF derivatives revealed the correlation between the conformations, the PET, and the fluorescent intensities of these DCF derivatives, enabling us to select a sensor candidate. RNA aptamers were raised against the aniline-based quencher via in vitro selection (SELEX). One of these aptamers enhanced the fluorescence intensity of the DCF-aniline conjugate in a concentration-dependent manner. To demonstrate the power and generality of this approach, additional in vitro selection was performed and aptamers from this selection were found to have similar activities. These results show that one can develop fluorescence-inducing reporter RNA and morph it into remotely related sequences without prior structural insight into RNA-ligand binding.     

Controlling protein activity with ligand-regulated RNA aptamers

Controlling the activity of a protein is necessary for defining its function in vivo. RNA aptamers are capable of inhibiting proteins with high affinity and specificity, but this effect is not readily reversible. We describe a general method for discovering aptamers that bind and inhibit their target protein, but addition of a specific small molecule disrupts the protein-RNA complex. A SELEX protocol was used to raise RNA aptamers to the DNA repair enzyme, formamidopyrimidine glycosylase (Fpg), and neomycin was employed in each round to dissociate Fpg-bound RNAs. We identified an RNA molecule able to completely inhibit Fpg at 100 nM concentration. Importantly, Fpg activity is recovered by the addition of neomycin. We envision these ligand-regulated aptamers (LIRAs) as valuable tools in the study of biological phenomena in which the timing of molecular events is critical.     

全细胞的核酸适配体筛选的研究进展

核酸适配体(aptamer)是从人工合成的随机单链DNA(ssDNA)或RNA文库中筛选得到的,能够高亲和力、高特异性地与靶标结合的ssDNA或RNA。核酸适配体的靶标范围广,可包括小分子、蛋白质、细胞、微生物等多种靶标。其中以细胞为靶标的适配体在生物感应、分子成像、医学诊断、药物传输和疾病治疗等领域有很大的应用潜能。但全细胞的核酸适配体筛选过程复杂,筛选难度大,筛选的适配体性能不佳是导致目前可用的适配体非常有限的主要原因。由于细胞表面蛋白质在提取纯化过程中分子结构和形态会发生改变,故以膜表面蛋白质为靶标筛选的适配体很难应用于识别整体细胞。以全细胞为靶标的核酸适配体筛选则不需要准确了解细胞表面的分子结构,筛选过程中可保持细胞的天然状态,以全细胞为靶标筛选出的核酸适配体有望直接用于全细胞识别。本文总结了2008~2015年全细胞的核酸适配体筛选的研究进展,介绍了靶细胞的分类、核酸库的设计、筛选条件和方法以及核酸适配体的亲和力表征方法等。并列出全细胞靶标的核酸适配体序列。     

Dynamic Combinatorial Chemistry: A New Methodology Comes of Age

Dynamic combinatorial chemistry (DCC) has repeatedly proven to be an effective approach to generate directed ligand libraries for macromolecular targets. In the absence of an external stimulus, a dynamic library forms from reversibly reacting building blocks and reaches a stable thermodynamic equilibrium. However, upon addition of a macromolecular host which can bind and stabilize certain components of the library, the equilibrium composition changes and induces an evolution-like selection and enrichment of high-affinity ligands. A valuable application of this so-called target-directed DCC (tdDCC) is the identification of potent ligands for pharmacologically relevant targets. Over time, the term tdDCC has been applied to describe a number of different experimental setups, leading to some ambiguity concerning its definition. This article systematically classifies known procedures for tdDCC and related approaches, with a special focus on the methods used for analysis and evaluation of experiments.     

Aptamers: molecular tools for analytical applications

Aptamers are artificial nucleic acid ligands, specifically generated against certain targets, such as amino acids, drugs, proteins or other molecules. In nature they exist as a nucleic acid based genetic regulatory element called a riboswitch. For generation of artificial ligands, they are isolated from combinatorial libraries of synthetic nucleic acid by exponential enrichment, via an in vitro iterative process of adsorption, recovery and reamplification known as systematic evolution of ligands by exponential enrichment (SELEX). Thanks to their unique characteristics and chemical structure, aptamers offer themselves as ideal candidates for use in analytical devices and techniques. Recent progress in the aptamer selection and incorporation of aptamers into molecular beacon structures will ensure the application of aptamers for functional and quantitative proteomics and high-throughput screening for drug discovery, as well as in various analytical applications. The properties of aptamers as well as recent developments in improved, time-efficient methods for their selection and stabilization are outlined. The use of these powerful molecular tools for analysis and the advantages they offer over existing affinity biocomponents are discussed. Finally the evolving use of aptamers in specific analytical applications such as chromatography, ELISA-type assays, biosensors and affinity PCR as well as current avenues of research and future perspectives conclude this review.     

Recent trends in SELEX technique and its application to food safety monitoring

The method referred to as “systemic evolution of ligands by exponential enrichment” (SELEX) was introduced in 1990 and ever since has become an important tool for the identification and screening of aptamers. Such nucleic acids can recognize and bind to their corresponding targets (analytes) with high selectivity and affinity, and aptamers therefore have become attractive alternatives to traditional antibodies not the least because they are much more stable. Meanwhile, they have found numerous applications in different fields including food quality and safety monitoring. This review first gives an introduction into the selection process and to the evolution of SELEX, then covers applications of aptamers in the surveillance of food safety (with subsections on absorptiometric, electrochemical, fluorescent and other methods), and then gives conclusions and perspectives. The SELEX method excels by its features of in vitro, high throughput and ease of operation. This review contains 86 references.

Aptamers selected for higher-affinity binding are not more specific for the target ligand

Previous study of eleven different in vitro-selected RNA aptamers that bind guanosine triphosphate (GTP) with K(d)s ranging from 8 microM to 9 nM showed that more information is required to specify the structures of the higher-affinity aptamers. We are interested in understanding how the more complex aptamers achieve higher affinities for the ligand. In vitro selection produces structural solutions to a functional problem that are are as simple as possible in terms of the information content needed to define them. It has long been assumed that the simplest way to improve the affinity of an aptamer is to increase the shape and functional group complementarity of the RNA binding pocket for the ligand. This argument underlies the hypothesis that selection for higher-affinity aptamers automatically leads to structures that bind more specifically to the target molecule. Here, we examined the binding specificities of the eleven GTP aptamers by carrying out competition binding studies with sixteen different chemical analogues of GTP. The aptamers have distinct patterns of specificity, implying that each RNA is a structurally unique solution to the problem of GTP binding. However, these experiments failed to provide evidence that higher-affinity aptamers bind more specifically to GTP. We suggest that the simplest way to improve aptamer K(d)s may be to increase the stability of the RNA tertiary structure with additional intramolecular RNA-RNA interactions; increasingly specific ligand binding may emerge only in response to direct selection for specificity.     

FluMag-SELEX as an advantageous method for DNA aptamer selection

Aptamers are ssDNA or RNA oligonucleotides with very high affinity for their target. They bind to the target with high selectivity and specificity because of their specific three-dimensional shape. They are developed by the so-called Systematic Evolution of Ligands by Exponential Enrichment (SELEX) process. We have modified this method in two steps—use of fluorescent labels for DNA quantification and use of magnetic beads for target immobilization. Thus, radioactive labelling is avoided. Immobilization on magnetic beads enables easy handling, use of very small amounts of target for the aptamer selection, rapid and efficient separation of bound and unbound molecules, and stringent washing steps. We have called this modified SELEX technology FluMag-SELEX. With FluMag-SELEX we have provided a methodological background for our objective of being able to select DNA aptamers for targets with very different properties and size. These aptamers will be applied as new biosensor receptors. In this work selection of streptavidin-specific aptamers by FluMag-SELEX is described. The streptavidin-specific aptamers will be used to check the surface occupancy of streptavidin-coated magnetic beads with biotinylated molecules after immobilization procedures.     

基于Cell-SELEX的核酸适配体在生化分析与生物成像中的应用

基于Cell-SELEX的核酸适配体是指以活细胞为靶标物,通过指数富集的配基系统进化技术(Systematic evolution of ligands by exponential enrichment,SELEX)从人工合成的DNA/RNA文库中筛选得到的单链寡核苷酸.它能够与靶标细胞高亲和性、高特异性结合,具有分子量低、合成简单、化学稳定性好、免疫原性低、易于功能化修饰等优点,已广泛应用于生命科学研究领域.本文综述了基于Cell-SELEX技术筛选的核酸适配体在肿瘤细胞检测、分析和成像方面的研究进展,并对核酸适配体研究的发展前景和趋势进行了展望.     

Combinatorial Synthesis and Multidimensional NMR Spectroscopy: An Approach to Understanding Protein–Ligand Interactions

Combinatorial chemistry is a laboratory emulation of natural recombination and selection processes. Strategies in this developing discipline involve the generation of diverse, molecular libraries through combinatorial synthesis and the selection of compounds that possess a desired property. Such approaches can facilitate the identification of ligands that bind to biological receptors, promoting our chemical understanding of cellular processes. This article illustrates that the coupling of combinatorial synthesis, multidimensional NMR spectroscopy, and biochemical methods has enhanced our understanding of a protein receptor used commonly in signal transduction, the Src Homology 3 (SH3) domain. This novel approach to studying molecular recognition has revealed a set of rules that govern SH3–ligand interactions, allowing models of receptor–ligand complexes to be constructed with only a knowledge of the polypeptide sequences. Combining combinatorial synthesis with structural methods provides a powerful new approach to understanding how proteins bind their ligands in general.     

Dynamic mixtures: challenges and opportunities for the amplification and sensing of scents

Nature generates compounds as complicated mixtures, but surprisingly little is known about the synergies or inhibitory effects of compound mixtures, which is likely to become an important research area in life sciences in the near future. Some recently developed concepts in dynamic combinatorial/covalent chemistry (DCC) have been applied to amplify (increase the intensity and long-lastingness of perception) and sense (selectively detect and discriminate) individual bioactive volatile molecules in compound mixtures. This Concept article focuses on the potential of DCC to impact and modulate the biological and chemical properties of mixtures of bioactive volatile compounds to gain a more fundamental understanding of the properties of compound mixtures in molecular recognition.     

Single-stranded DNA (ssDNA) production in DNA aptamer generation

The discovery that synthetic short chain nucleic acids are capable of selective binding to biological targets has made them to be widely used as molecular recognition elements. These nucleic acids, called aptamers, are comprised of two types, DNA and RNA aptamers, where the DNA aptamer is preferred over the latter due to its stability, making it widely used in a number of applications. However, the success of the DNA selection process through Systematic Evolution of Ligands by Exponential Enrichment (SELEX) experiments is very much dependent on its most critical step, which is the conversion of the dsDNA to ssDNA. There is a plethora of methods available in generating ssDNA from the corresponding dsDNA. These include asymmetric PCR, biotin-streptavidin separation, lambda exonuclease digestion and size separation on denaturing-urea PAGE. Herein, different methods of ssDNA generation following the PCR amplification step in SELEX are reviewed.     

Identification of ligands for the Tau exon 10 splicing regulatory element RNA by using dynamic combinatorial chemistry

We describe the use of dynamic combinatorial chemistry (DCC) to identify ligands for the stem-loop structure located at the exon 10-5'-intron junction of Tau pre-mRNA, which is involved in the onset of several tauopathies including frontotemporal dementia with Parkinsonism linked to chromosome 17 (FTDP-17). A series of ligands that combine the small aminoglycoside neamine and heteroaromatic moieties (azaquinolone and two acridines) have been identified by using DCC. These compounds effectively bind the stem-loop RNA target (the concentration required for 50% RNA response (EC(50)): 2-58 μM), as determined by fluorescence titration experiments. Importantly, most of them are able to stabilize both the wild-type and the +3 and +14 mutated sequences associated with the development of FTDP-17 without producing a significant change in the overall structure of the RNA (as analyzed by circular dichroism (CD) spectroscopy), which is a key factor for recognition by the splicing regulatory machinery. A good correlation has been found between the affinity of the ligands for the target and their ability to stabilize the RNA secondary structure.     

蛋白质的核酸适配体筛选的研究进展

核酸适配体是通过指数富集系统配体进化(SELEX)筛选获得的,与靶标具有高亲和力和特异性结合的单链DNA或RNA。蛋白质是生命进程中的关键功能分子。近年来,以蛋白质为靶标的适配体筛选在蛋白质相关的基础及应用研究领域受到广泛关注。核酸适配体应用性能的优劣取决于其亲和力、特异性与稳定性。目前,适配体筛选方法的优化主要是提高筛选效率、提升适配体性能及降低筛选成本。适配体主要筛选步骤包括复合物分离、核酸库优化、次级库的富集、适配体序列分析以及亲和力表征等。迄今为止,以蛋白质-核酸复合物的分离为核心步骤的适配体筛选方法有20余种。本文归纳总结了2005年以来以蛋白质为靶标的适配体筛选技术,讨论了各方法的缺陷与局限。介绍了核酸库的设计优化方法、适配体的序列特征,以及常用的亲和力表征方法。     

Non-SELEX selection of aptamers

Aptamers are typically selected from libraries of random DNA (or RNA) sequences by SELEX, which involves multiple rounds of alternating steps of partitioning and PCR amplification. Here we report, for the first time, non-SELEX selection of aptamers-a process that involves repetitive steps of partitioning with no amplification between them. A highly efficient affinity method, non-equilibrium capillary electrophoresis of equilibrium mixtures (NECEEM), was used for partitioning. We found that three steps of NECEEM-based partitioning in the non-SELEX approach were sufficient to improve the affinity of a DNA library to a target protein by more than 4 orders of magnitude. The resulting affinity was higher than that of the enriched library obtained in three rounds of NECEEM-based SELEX. Remarkably, NECEEM-based non-SELEX selection took only 1 h in contrast to several days or several weeks required for a typical SELEX procedure by conventional partitioning methods. In addition, NECEEM-based non-SELEX allowed us to accurately measure the abundance of aptamers in the library. Not only does this work introduce an extremely fast and economical method for aptamer selection, but it also suggests that aptamers may be much more abundant than they are thought to be. Finally, this work opens the opportunity for selection of drug candidates from libraries of small molecules, which cannot be PCR-amplified and thus are not approachable by SELEX.     

DNA‐Encoded Dynamic Combinatorial Chemical Libraries

Dynamic combinatorial chemistry (DCC) explores the thermodynamic equilibrium of reversible reactions. Its application in the discovery of protein binders is largely limited by difficulties in the analysis of complex reaction mixtures. DNA‐encoded chemical library (DECL) technology allows the selection of binders from a mixture of up to billions of different compounds; however, experimental results often show low a signal‐to‐noise ratio and poor correlation between enrichment factor and binding affinity. Herein we describe the design and application of DNA‐encoded dynamic combinatorial chemical libraries (EDCCLs). Our experiments have shown that the EDCCL approach can be used not only to convert monovalent binders into high‐affinity bivalent binders, but also to cause remarkably enhanced enrichment of potent bivalent binders by driving their in situ synthesis. We also demonstrate the application of EDCCLs in DNA‐templated chemical reactions.