Peptide aptamers: specific inhibitors of protein function

In recent years, peptide aptamers have emerged as novel molecular tools that are useful for both basic and applied aspects of molecular medicine. Due to their ability to specifically bind to and inactivate a given target protein at the intracellular level, they provide a new experimental strategy for functional protein analyses, both in vitro and in vivo. In addition, by using peptide aptamers as "pertubagens", they can be employed for genetic analyses, in order to identify biochemical pathways, and their components, that are associated with the induction of distinct cellular phenotypes. Furthermore, peptide aptamers may be developed into diagnostic tools for the detection of a given target protein or for the generation of high-throughput protein arrays. Finally, the peptide aptamer technology has direct therapeutic implications. Peptide aptamers can be used in order to validate therapeutic targets at the intracellular level. Moreover, the peptide aptamer molecules themselves should possess therapeutic potential, both as lead structures for drug design and as a basis for the development of protein drugs.     

适体家族新成员－肽适体

肽适体是一种从随机氨基酸的肽文库中筛选出来,可以高亲合力地与靶物质特异性结 合的短肽序列．它的主要结构包括恒定的展示支架蛋白及通过两端限制性插入的高变肽环． 酵母双杂交技术常用于筛选针对细胞内特异性靶蛋白的肽适体过程,筛选出的肽适体通过特 异性结合识别靶标发挥类似“干扰基因”的作用从而影响蛋白的生物学活性．     

An antiproliferative genetic screening identifies a peptide aptamer that targets calcineurin and up-regulates its activity

Peptide aptamers are combinatorial recognition molecules that consist of a constant scaffold protein displaying a doubly constrained variable peptide loop. They bind specifically target proteins and interfere with their function. We have built a peptide aptamer library in a lentiviral expression system to isolate aptamers that inhibit cell proliferation in vitro. Using one of the isolated aptamers (R5G42) as a bait protein, we have performed yeast two-hybrid screening of cDNA libraries and identified calcineurin A as a target protein candidate. R5G42 bound calcineurin A in vitro and stimulated its phosphatase activity. When expressed transiently in human cells, R5G42 induced the dephosphorylation of BAD. We have identified an antiproliferative peptide aptamer that binds calcineurin and stimulates its activity. The use of this ligand may help elucidate the still elusive structural mechanisms of activation and inhibition of calcineurin. Our work illustrates the power of phenotypic screening of combinatorial protein libraries to interrogate the proteome and chart molecular regulatory networks.     

Selection and characterization of large collections of peptide aptamers through optimized yeast two-hybrid procedures

Peptide aptamers are combinatorial proteins that specifically bind intracellular proteins and modulate their function. They are powerful tools to study protein function within complex regulatory networks and to guide small-molecule drug discovery. Here we describe methodological improvements that enhance the yeast two-hybrid selection and characterization of large collections of peptide aptamers. We provide a detailed protocol to perform high-efficiency transformation of peptide aptamer libraries, in-depth validation experiments of the bait proteins, high-efficiency mating to screen large numbers of peptide aptamers and streamlined confirmation of the positive clones. We also describe yeast two-hybrid mating assays, which can be used to determine the specificity of the selected aptamers, map their binding sites on target proteins and provide structural insights on their target-binding surface. Overall, 12 weeks are required to perform the protocols. The improvements on the yeast two-hybrid method can be also usefully applied to the screening of cDNA libraries to identify protein interactions.     

Peptide aptamer-mediated inhibition of target proteins by sequestration into aggresomes

Peptide aptamers (PAs) can be employed to block the intracellular function of target proteins. Little is known about the mechanism of PA-mediated protein inhibition. Here, we generated PAs that specifically bound to the duck hepatitis B virus (HBV) core protein. Among them, PA34 strongly blocked duck HBV replication by inhibiting viral capsid formation. We found that PA34 led to a dramatic intracellular redistribution of its target protein into perinuclear inclusion bodies, which exhibit the typical characteristics of aggresomes. As a result, the core protein is efficiently removed from the viral life cycle. Corresponding findings were obtained for bioactive PAs that bind to the HBV core protein or to the human papillomavirus-16 (HPV16) E6 protein, respectively. The observation that PAs induce the specific sequestration of bound proteins into aggresomes defines a novel mechanism as to how this new class of intracellular inhibitors blocks the function of their target proteins.     

基于核酸适配体的生物分析新方法研究进展

核酸适配体是从随机文库中采用SELEX技术筛选所得的单链短链寡核苷酸片段(通常为15-80个ss DNA或ss RNA)。其能够折叠形成独特稳定的三维结构,通过静电相互作用,氢键,范德华力,碱堆叠或多种作用力组合特异性地与多种靶标结合。适配体因具有构象变化能力而被用作生物分析中的理想识别配体。目前,基于适配体的生物分析新方法得到广泛研究,并用于蛋白多肽类药物分析、疾病标志物诊断、外泌体检测、循环肿瘤细胞检测和病毒检测等方面。本文综述了核酸适配体用于生物分析方法开发的最新进展,比较和讨论不同分析方法,并对基于适配体的生物分析新方法提出了设想和展望,为开发新的生物分析方法和检测技术提供了思路和借鉴。     

Peptide aptamers: tools for biology and drug discovery.

Peptide aptamer technology is relatively youthful. It has the advantage over existing techniques that the reagents identified are designed for expression in eukaryotic cells. This allows the construction of molecular tools that allow the logic of genetics, from knockouts to extragenic suppressors, to be applied to studies of proteins in tissue culture cells. Until recently, the available tools have limited our understanding of cell biology. The same limitation restricts out ability to validate the numerous candidate drug targets emerging from genome-wide approaches to cellular biology. Peptide aptamers represent a stride forwards in the evolution of a modular, molecular tool kit for cell biology and for drug target validation. The authors predict that they will also play a role in the transition from genomic to proteomic microarray technology.     

H1 RNA polymerase III promoter-driven expression of an RNA aptamer leads to high-level inhibition of intracellular protein activity

Aptamers offer advantages over other oligonucleotide-based approaches that artificially interfere with target gene function due to their ability to bind protein products of these genes with high affinity and specificity. However, RNA aptamers are limited in their ability to target intracellular proteins since even nuclease-resistant aptamers do not efficiently enter the intracellular compartments. Moreover, attempts at expressing RNA aptamers within mammalian cells through vector-based approaches have been hampered by the presence of additional flanking sequences in expressed RNA aptamers, which may alter their functional conformation. In this report, we successfully expressed a ‘pure’ RNA aptamer specific for NF-κB p50 protein (A-p50) utilizing an adenoviral vector employing the H1 RNA polymerase III promoter. Binding of the expressed aptamer to its target and subsequent inhibition of NF-κB mediated intracellular events were demonstrated in human lung adenocarcinoma cells (A549), murine mammary carcinoma cells (4T1) as well as a human tumor xenograft model. This success highlights the promise of RNA aptamers to effectively target intracellular proteins for in vitro discovery and in vivo applications.     

Combinatorial Library of Improved Peptide Aptamers,CLIPs to Inhibit RAGE Signal Transduction in Mammalian Cells

Peptide aptamers are small proteins containing a randomized peptide sequence embedded into a stable protein scaffold, such as Thioredoxin. We developed a robust method for building a Combinatorial Library of Improved Peptide aptamers (CLIPs) of high complexity, containing ≥3×10¹⁰ independent clones, to be used as a molecular tool in the study of biological pathways. The Thioredoxin scaffold was modified to increase solubility and eliminate aggregation of the peptide aptamers. The CLIPs was used in a yeast two-hybrid screen to identify peptide aptamers that bind to various domains of the Receptor for Advanced Glycation End products (RAGE). NMR spectroscopy was used to identify interaction surfaces between the peptide aptamers and RAGE domains. Cellular functional assays revealed that in addition to directly interfering with known binding sites, peptide aptamer binding distal to ligand sites also inhibits RAGE ligand-induced signal transduction. This finding underscores the potential of using CLIPs to select allosteric inhibitors of biological targets.     

Nucleic acid aptamers for target validation and therapeutic applications.

In the simplest view, aptamers can be thought of as nucleic acid analogs to antibodies. They are able to bind specifically to proteins, and, in many cases, that binding leads to a modulation of protein activity. New aptamers are rapidly generated through the SELEX (Systematic Evolution of Ligands by Exponential enrichment) process and have a very high target affinity and specificity (picomoles to nanomoles). Furthermore, aptamers composed of modified nucleotides have a long in vivo half-life (hours to days), are nontoxic and nonimmunogenic, and are easily produced using standard nucleic acid synthesis methods. These properties make aptamers ideal for target validation and as a new class of therapeutics. As a target validation tool, aptamers provide important information that complements that provided by other methods. For example, siRNA is widely used to demonstrate that protein knock-out in a cellular assay can lead to a biological effect. Aptamers extend that information by showing that the dose-dependent modulation of protein activity can be used to derive a therapeutic benefit. That is, aptamers can be used to demonstrate that the protein is a good target for drug development. As a new class of therapeutics, aptamers bridge the gap between small molecules and biologics. Like biologics, biologically active aptamers are rapidly discovered, have no class-specific toxicity, and are adept at disrupting protein-protein interaction. Like small molecules, aptamers can be rationally engineered and optimized, are nonimmunogenic, and are produced by scalable chemical procedures at moderate cost. As such, aptamers are emerging as an important source of new therapeutic molecules.     

Molecular signaling aptamers for real-time fluorescence analysis of protein

Aptamers are a new class of nucleic acids that are selected in vitro for binding target molecules with high affinity and selectivity. They are promising protein-binding molecular probes that rival conventional antibodies for protein analysis. There have been recent advances in the development of molecular signaling aptamers that can transduce target protein binding to sensitive fluorescence signal changes. This facilitates the real time protein monitoring in homogenous solution as well as potentially in vivo. Different signaling strategies of using dual labeled aptamers based on fluorescence resonance energy transfer (FRET), one fluorophore labeled aptamers based on fluorescence anisotropy assay, or other label-free aptamers are reviewed.     

A novel unstructured scaffold based on 4EBP1 enables the functional display of a wide range of bioactive peptides

Target validation using protein aptamers enables the characterization of a specific function of a target protein in an environment that resembles native conditions as closely as possible. A major obstacle to the use of this technology has been the generation of bioactive aptamers, which is dependent on the choice of scaffold. Constraining binding peptides within a particular scaffold does not necessarily result in binding aptamers, as suboptimal presentation of peptides can occur. It is therefore understandable that different peptides might require different scaffolds for optimal presentation. In this article, we describe a novel scaffold protein that bypasses the conventional requirement for scaffolds to have known rigid structures and yet successfully presents several peptides that need to adopt a wide range of conformations for binding to their target protein. Using an unstructured protein, 4EBP1, as scaffold, we successfully construct binding aptamers to three different target proteins: Mdm2, proliferating cell nuclear antigen, and cyclin A. The Mdm2-binding aptamer constructed using 4EBP1 as scaffold demonstrates better stability and bioactivity compared to that constructed using thioredoxin as scaffold. This new scaffold protein, which makes it relatively easy to create bioactive aptamers based on known interaction sequences, will greatly facilitate the aptamer approach to target validation.     

用于未纯化蛋白样品核酸适配体筛选的Western印迹-SELEX筛选技术的建立

目的:建立一种基于Western印迹的指数式富集的配体系统进化(SELEX)技术,用于未纯化蛋白样品核酸适配体筛选。方法:将目的蛋白经SDS-PAGE分离后转移到PVDF膜上,用生物素标记的ss DNA与PVDF膜上的蛋白共同孵育,获得能与靶蛋白特异结合的适配体,最后通过生物素-链霉亲和素-辣根过氧化物酶系统、基因克隆测序、MEME在线软件和RNAstructure软件分析适配体的一、二级结构,并对筛选得到的适配体进行鉴定。结果:经过4轮筛选,获得了能特异识别靶蛋白而不识别无关蛋白的适配体,原库Gp45则与上述蛋白均没有结合。结论:建立了Western印迹-SELEX技术,可用于未纯化蛋白样品核酸适配体筛选。     

A screening method for DNA aptamers that bind to␣a␣specific, unidentified protein in tissue samples

Aptamers are oligonucleotide ligands with a high affinity to, and specificity for, various target molecules and they are expected to be powerful tools for proteomic analysis. To select aptamers that bind to a specific unidentified protein in tissues for protein analysis, a screening method was developed using chicken skeletal muscle as a model. Target proteins in the target mixture were separated by electrophoresis and transferred to a membrane, and a DNA library was added onto it. The aptamers that bound to the target protein were visualized by chemiluminescence and collected by cutting out the visualized band. The specific aptamers to the target protein were selected by only one round of selection using this screening, suggesting this screening method might be useful for selecting aptamers for proteome analysis.     

RNA and DNA aptamers in cytomics analysis.

BACKGROUND: The systematic evolution of ligands by exponential enrichment (SELEX) technique is a combinatorial library approach in which DNA or RNA molecules (aptamers) are selected by their ability to bind their protein targets with high affinity and specificity, comparable to that of monoclonal antibodies. In contrast to antibodies conventionally selected in animals, aptamers are generated by an in vitro selection process, and can be directed against almost every target, including antigens like toxins or nonimmunogenic targets, against which conventional antibodies cannot be raised. METHODS: Aptamers are ideal candidates for cytomics, as they can be attached to fluorescent reporters or nanoparticles in order to study biological function by fluorescence microscopy, by flow cytometry, or to quantify the concentration of their target in biological fluids or cells using ELISA, RIA, and Western blot assays. RESULTS: We demonstrate the in vitro selection of anti-kinin B1 receptor aptamers that could be used to determine B1 receptor expression during inflammation processes. These aptamers specifically recognize their target in a Northern-Western blot assay, and bind to their target protein whenever they are exposed in the membrane. CONCLUSIONS: Currently, aptamers are linked to fluorescent reporters. We discuss here the present status and future directions concerning the use of the SELEX technique in cytomics.     

Human Protein 53-Derived Cell-Penetrating Peptides

Tumor suppressor protein 53 plays an important role in the initiation of cell cycle arrest and apoptosis. Being highly mutated in several different cancer types, p53 is a good target for anticancer therapeutics. It has been shown that a peptide derived from the C-terminus of p53 activates specific DNA-binding of endogenous mutated p53, restoring its original activity. Detection of short cell-penetrating peptide sequences using quantitative structure?Cactivity relationship algorithm gives new opportunities for developing novel peptide-based platforms for modulation of biological activity inside the cell. Here we present novel human protein 53 C-terminal domain-derived peptides, Peptide4 and Peptide5 that were designed using cell-penetrating peptide prediction algorithm and synthesised by Fmoc chemistry. Peptide4 and Peptide5 showed to be capable for translocation inside the breast cancer cells. Subsequent introduction of stearic acid moiety in the backbone of these peptides at N-terminal or lysine 3-orthogonal positions enhanced their cell-penetrating ability. Moreover Peptide4 and Peptide5 showed certain cytotoxic activity and were able to induce apoptosis in MDA-MB-231 cell line in the absence of serum. We suggest that human protein 53 C-terminal domain-derived cell-penetrating peptides Peptide4 and Peptide5 have promising perspectives for the future anticancer applications.     

A sol-gel-based microfluidics system enhances the efficiency of RNA aptamer selection

RNA and DNA aptamers that bind to target molecules with high specificity and affinity have been a focus of diagnostics and therapeutic research. These aptamers are obtained by SELEX often requiring many rounds of selection and amplification. Recently, we have shown the efficient binding and elution of RNA aptamers against target proteins using a microfluidic chip that incorporates 5 sol-gel binding droplets within which specific target proteins are imbedded. Here, we demonstrate that our microfluidic chip in a SELEX experiment greatly improved selection efficiency of RNA aptamers to TATA-binding protein, reducing the number of selection cycles needed to produce high affinity aptamers by about 80%. Many aptamers were identical or homologous to those isolated previously by conventional filter-binding SELEX. The microfluidic chip SELEX is readily scalable using a sol-gel microarray-based target multiplexing. Additionally, we show that sol-gel embedded protein arrays can be used as a high-throughput assay for quantifying binding affinities of aptamers.     

RNA Aptamers Inhibit the Growth of the Fish Pathogen Viral Hemorrhagic Septicemia Virus (VHSV)

Viral hemorrhagic septicemia virus (VHSV) is a serious disease impacting wild and cultured fish worldwide. Hence, an effective therapeutic method against VHSV infection needs to be developed. Aptamer technology is a new and promising method for diagnostics and therapeutics. It revolves around the use of an aptamer molecule, an artificial ligand (nucleic acid or protein), which has the capacity to recognize target molecules with high affinity and specificity. Here, we aimed at selecting RNA aptamers that can specifically bind to and inhibit the growth of a strain of fish VHSV both in vitro and in vivo. Three VHSV-specific RNA aptamers (F1, F2, and C6) were selected from a pool of artificially and randomly produced oligonucleotides using systematic evolution of ligands by exponential enrichment. The three RNA aptamers showed obvious binding to VHSV in an electrophoretic mobility shift assay but not to other tested viruses. The RNA aptamers were tested for their ability to inhibit VHSV in vitro using hirame natural embryo (HINAE) cells. Cytopathic effect and plaque assays showed that all aptamers inhibited the growth of VHSV in HINAE cells. In vivo tests using RNA aptamers produced by Rhodovulum sulfidophilum showed that extracellular RNA aptamers inhibited VHSV infection in Japanese flounder. These results suggest that the RNA aptamers are a useful tool for protection against VHSV infection in Japanese flounder.     

Developing aptamer probes for acute myelogenous leukemia detection and surface protein biomarker discovery

Background

The majority of patients with acute myelogenous leukemia (AML) still die of their disease. In order to improve survival rates in AML patients, new strategies are necessary to discover biomarkers for the detection and targeted therapy of AML. One of the advantages of the aptamer-based technology is the unique cell-based selection process, which allows us to efficiently select for cell-specific aptamers without knowing which target molecules are present on the cell surface.

Methods

The NB4 AML cell line was used as the target cell population for selecting single stranded DNA aptamers. After determining the affinity of selected aptamers to leukocytes, the aptamers were used to phenotype human bone marrow leukocytes and AML cells in clinical specimens. Then a biotin-labelled aptamer was used to enrich and identify its target surface protein.

Results

Three new aptamers were characterized from the selected aptamer pools (JH6, JH19, and K19). All of them can selectively recognize myeloid cells with Kd in the low nanomole range (2.77 to 12.37 nM). The target of the biotin-labelled K19 aptamer probe was identified as Siglec-5, a surface membrane protein in low abundance whose expression can serve as a biomarker of granulocytic maturation and be used to phenotype AML. More importantly, Siglec-5 expression can be used to detect low concentrations of AML cells in human bone marrow specimens, and functions as a potential target for leukemic therapy.

Conclusions

We have demonstrated a pipeline approach for developing single stranded DNA aptamer probes, phenotyping AML cells in clinical specimens, and then identifying the aptamer-recognized target protein. The developed aptamer probes and identified Siglec-5 protein may potentially be used for leukemic cell detection and therapy in our future clinical practice.