Immunomagnetic DNA aptamer assay

DNA aptamers, oligonucleotides with antibody-like binding properties, are easy to manufacture and modify. As a class of molecules, they represent the biggest revolution to immunodiagnostics since the discovery of monoclonal antibodies. To demonstrate that DNA aptamers are versatile reagents for use as in vitro diagnostic tools, we developed a hybrid immunobead assay based on a 5'-biotinylated DNA thrombin aptamer (5'-GGTTGGTGTGGTTGG-3') and an anti-thrombin antibody (EST-7). Our results show that the thrombin DNA aptamer is capable of binding to its target molecule under stringent in vitro assay conditions and at physiological concentrations. These findings also support the view that DNA aptamers have potential value as complementary reagents in diagnostic assays.     

Selectivity analysis of single binder assays used in plasma protein profiling

The increasing availability of antibodies toward human proteins enables broad explorations of the proteomic landscape in cells, tissues, and body fluids. This includes assays with antibody suspension bead arrays that generate protein profiles of plasma samples by flow cytometer analysis. However, antibody selectivity is context dependent so it is necessary to corroborate on‐target detection over off‐target binding. To address this, we describe a concept to directly verify interactions from antibody‐coupled beads by analysis of their eluates by Western blots and MS. We demonstrate selective antibody binding in complex samples with antibodies toward a set of chosen proteins with different abundance in plasma and serum, and illustrate the need to adjust sample and bead concentrations accordingly. The presented approach will serve as an important tool for resolving differential protein profiles from antibody arrays within plasma biomarker discoveries.     

Production and processing of aptamer microarrays

Aptamers are nucleic acid species that are selected in vitro for their specific binding properties. We describe methods for the production and processing of aptamer microarrays, including detailed procedures for the high-throughput, enzymatic synthesis of 5' RNA biotinylated aptamers and for arraying them onto streptavidin-coated glass slides. Also presented are methods for processing the aptamer microarrays, including blocking, washing, drying, and scanning. Examples are shown for the specific capture of fluorescently labeled target proteins either alone in binding buffer or in competition with labeled intracellular proteins from cell lysates. Consideration is given to the challenges involved in producing multiplex aptamer chips composed of aptamers taken from disparate literature sources, and to the development of standardized methods for characterizing the performance of capture reagents used in biosensors.     

Monoclonal antibodies for the structural analysis of the Na+/H+ antiporter NhaA from Escherichia coli

Since their advent some 25 years ago, monoclonal antibodies have developed into powerful tools for structural and functional analysis of their cognate antigens. Together with the respective antigen binding fragments, antibodies offer exclusive capacities in detection, characterization, purification and functional assays for every given ligand. Antibody-fragment mediated crystallization represents a major advance in determining the three-dimensional structure of membrane-bound protein complexes. In this review, we focus on the methods used to generate monoclonal antibodies against the NhaA antiporter from Escherichia coli as a paradigm of secondary transporters. We describe examples on how antibodies are helpful in understanding structure and function relationships for this important class of integral membrane proteins. The generated conformation-specific antibody fragments are highly valuable reagents for co-crystallization attempts and structure determination of the antiporter.     

Development of an Efficient Targeted Cell-SELEX Procedure for DNA Aptamer Reagents

Background

DNA aptamers generated by cell-SELEX offer an attractive alternative to antibodies, but generating aptamers to specific, known membrane protein targets has proven challenging, and has severely limited the use of aptamers as affinity reagents for cell identification and purification.

Methodology

We modified the BJAB lymphoblastoma cell line to over-express the murine c-kit cell surface receptor. After six rounds of cell-SELEX, high-throughput sequencing and bioinformatics analysis, we identified aptamers that bound BJAB cells expressing c-kit but not wild-type BJAB controls. One of these aptamers also recognizes c-kit endogenously expressed by a mast cell line or hematopoietic progenitor cells, and specifically blocks binding of the c-kit ligand stem cell factor (SCF). This aptamer enables better separation by fluorescence-activated cell sorting (FACS) of c-kit⁺ hematopoietic progenitor cells from mixed bone marrow populations than a commercially available antibody, suggesting that this approach may be broadly useful for rapid isolation of affinity reagents suitable for purification of other specific cell types.

Conclusions/Significance

Here we describe a novel procedure for the efficient generation of DNA aptamers that bind to specific cell membrane proteins and can be used as high affinity reagents. We have named the procedure STACS (Specific TArget Cell-SELEX).     

Monoclonal antibodies for the structural analysis of the Na/H antiporter NhaA from Escherichia coli

Since their advent some 25 years ago, monoclonal antibodies have developed into powerful tools for structural and functional analysis of their cognate antigens. Together with the respective antigen binding fragments, antibodies offer exclusive capacities in detection, characterization, purification and functional assays for every given ligand.Antibody-fragment mediated crystallization represents a major advance in determining the three-dimensional structure of membrane-bound protein complexes. In this review, we focus on the methods used to generate monoclonal antibodies against the NhaA antiporter from Escherichia coli as a paradigm of secondary transporters. We describe examples on how antibodies are helpful in understanding structure and function relationships for this important class of integral membrane proteins.The generated conformation-specific antibody fragments are highly valuable reagents for co-crystallization attempts and structure determination of the antiporter.     

Magnetic bead assisted labeling of antibodies at nanogram scale

There are currently several initiatives that aim to produce binding reagents for proteome‐wide analysis. To enable protein detection, visualization, and target quantification, covalent coupling of reporter molecules to antibodies is essential. However, current labeling protocols recommend considerable amount of antibodies, require antibody purity and are not designed for automation. Given that small amounts of antibodies are often sufficient for downstream analysis, we developed a labeling protocol that combines purification and modification of antibodies at submicrogram quantities. With the support of magnetic microspheres, automated labeling of antibodies in parallel using biotin or fluorescent dyes was achieved.     

An engineered ultra‐high affinity Fab‐Protein G pair enables a modular antibody platform with multifunctional capability

Engineered recombinant antibody‐based reagents are rapidly supplanting traditionally derived antibodies in many cell biological applications. A particularly powerful aspect of these engineered reagents is that other modules having myriad functions can be attached to them either chemically or through molecular fusions. However, these processes can be cumbersome and do not lend themselves to high throughput applications. Consequently, we have endeavored to develop a platform that can introduce multiple functionalities into a class of Fab‐based affinity reagents in a “plug and play” fashion. This platform exploits the ultra‐tight binding interaction between affinity matured variants of a Fab scaffold (Fab^S) and a domain of an immunoglobulin binding protein, protein G (GA1). GA1 is easily genetically manipulatable facilitating the ability to link these modules together like beads on a string with adjustable spacing to produce multivalent and bi‐specific entities. GA1 can also be fused to other proteins or be chemically modified to engage other types of functional components. To demonstrate the utility for the Fab‐GA1 platform, we applied it to a detection proximity assay based on the β‐lactamase (BL) split enzyme system. We also show the bi‐specific capabilities of the module by using it in context of a Bi‐specific T‐cell engager (BiTE), which is a therapeutic assemblage that induces cell killing by crosslinking T‐cells to cancer cells. We show that GA1‐Fab modules are easily engineered into potent cell‐killing BiTE‐like assemblages and have the advantage of interchanging Fabs directed against different cell surface cancer‐related targets in a plug and play fashion.     

Aptamers as affinity reagents for clinical proteomics

Application of proteomic results to scientific and medical practice will depend in many respects on progress of affinity microchips technologies. This determines continuous search for inexpensive and robust affinity reagents alternative to monoclonal antibodies. Among synthetic mimetics of antibodies, the oligonucleotide aptamers are of the greatest interest as the affinity reagents due to the possibility to automate their selection and due to the low cost of oligonucleotide synthesis. In the review we consider the problems related to the automation and optimization of aptamer selection and also to selection of photoaptamers capable to form photoinduced covalent complexes with the protein targets. The existing approaches to the post-selection modification of the aptamers to increase their affinity and selectivity to protein targets are discussed.     

Kinetic analysis of site-specific photoaptamer-protein cross-linking

ssDNA oligonucleotides containing bromodeoxyuridine, BrdU-photoaptamers, are rapidly emerging as specific protein capture reagents in protein microarray technologies. A mathematical model for the kinetic analysis of photoaptamer-protein photocross-linking reactions is presented. The model is based on specific aptamer/protein binding followed by laser excitation that can lead to either covalent cross-linking of the photoaptamer and protein in the complex or irreversible photodamage to the aptamer. Two distinct kinetic regimes, (1) frozen and (2) rapid equilibrium, are developed analytically to model binding kinetics between laser pulses. The models are used to characterize the photocross-linking between three photoaptamers and their cognate protein targets; photoaptamers 0650 and 0615 cross-link human basic fibroblast growth factor and 0518 cross-links HIV MN envelope glycoprotein. Data for cross-linking reaction yields as a function of both laser energy dose and target protein concentration are analyzed for affinity constants and cross-link reaction rates. The binding dissociation constants derived from the cross-linking data are in good accord with independent measurements; the rapid equilibrium model appears to produce results more consistent with the experimental observations, although there is significant overlap between the two models for most conditions explored here. The rate of photodamage for 0615 and 0518 is 3.5 and 2.5 times that of the specific cross-link, giving low maximum reaction yields of approximately 20% and approximately 30%, whereas 0650 cross-links with a rate over five times higher than its photodamage rate and has a maximum reaction yield exceeding 80%. Quantum yields for the three systems are estimated from the data; photoaptamer 0650 has a reasonably high quantum yield of approximately 0.2 for protein cross-linking, while 0518 and 0615 have quantum yields of 0.07 and 0.02. The work presented here provides a useful set of metrics that allow for refinement of photoaptamer properties.     

Aptamer‐based downstream processing of his‐tagged proteins utilizing magnetic beads

Aptamers are synthetic nucleic acid‐based high affinity ligands that are able to capture their corresponding target via molecular recognition. Here, aptamer‐based affinity purification for His‐tagged proteins was developed. Two different aptamers directed against the His‐tag were immobilized on magnetic beads covalently. The resulting aptamer‐modified magnetic beads were characterized and successfully applied for purification of different His‐tagged proteins from complex E. coli cell lysates. Purification effects comparable to conventional immobilized metal affinity chromatography were achieved in one single purification step. Moreover, we have investigated the possibility to regenerate and reuse the aptamer‐modified magnetic beads and have shown their long‐term stability over a period of 6 months. Biotechnol. Bioeng. 2011;108: 2371–2379. © 2011 Wiley Periodicals, Inc.     

Molecular dynamics simulation of the induced‐fit binding process of DNA aptamer and L‐argininamide

Aptamers are rare functional nucleic acids with binding affinity to and specificity for target ligands. Recent experiments have lead to the proposal of an induced‐fit binding mechanism for L ‐argininamide (Arm) and its binding aptamer. However, at the molecular level, this mechanism between the aptamer and its coupled ligand is still poorly understood. The present study used explicit solvent molecular dynamics (MD) simulations to examine the critical bases involved in aptamer‐Arm binding and the induced‐fit binding process at atomic resolution. The simulation results revealed that the Watson‐Crick pair (G10‐C16), C9, A12, and C17 bases play important roles in aptamer‐Arm binding, and that binding of Arm results in an aptamer conformation optimized through a general induced‐fit process. In an aqueous solution, the mechanism has the following characteristic stages: (a) adsorption stage, the Arm anchors to the binding site of aptamer with strong electrostatic interaction; (b) binding stage, the Arm fits into the binding site of aptamer by hydrogen‐bond formation; and (c) complex stabilization stage, the hydrogen bonding and electrostatic interactions cooperatively stabilize the complex structure. This study provides dynamics information on the aptamer‐ligand induced‐fit binding mechanism. The critical bases in aptamer‐ligand binding may provide a guideline in aptamer design for molecular recognition engineering.     

VL position 34 is a key determinant for the engineering of stable antibodies with fast dissociation rates

Predictive engineering of antibodies exhibiting fast kinetic properties could provide reagents for biotechnological applications such as continuous monitoring of compounds or affinity chromatography. Based on covariance analysis of murine germline antibody variable domains, we selected position L34 (Kabat numbering) for mutational studies. This position is located at the VL/VH interface, at the base of the paratope but with limited antigen contacts, thus making it an attractive position for mild alterations of antigen binding properties. We introduced a serine at position L34 in two different antibodies: Fab (fragment antigen binding) 57P (Asn34Ser) and scFv (single chain fragment variable) 1F4 (Gln34Ser), that recognize peptides derived from the coat protein of tobacco mosaic virus and the oncoprotein E6, respectively. Both mutated antibodies exhibited similar properties: (i) expression levels of active fragments in Escherichia coli were markedly improved; (ii) thermostability was enhanced; and (iii) dissociation rate parameters (k(off)) were increased by 2- and at least 57-fold for scFv1F4 and Fab57P, respectively, while their association rate parameters (k(on)) remained unchanged. The L34 Ala and Thr mutants of both antibody fragments did not possess these properties. This first demontration of similar effects observed in two antibodies with different specificities may open the way to the predictive design of molecules with enhanced stability and fast dissociation rates.     

A Combinatorial Histidine Scanning Library Approach to Engineer Highly pH-Dependent Protein Switches

There is growing interest in the development of protein switches, which are proteins whose function, such as binding a target molecule, can be modulated through environmental triggers. Efforts to engineer highly pH sensitive protein–protein interactions typically rely on the rational introduction of ionizable groups in the protein interface. Such experiments are typically time intensive and often sacrifice the protein's affinity at the permissive pH. The underlying thermodynamics of proton‐linkage dictate that the presence of multiple ionizable groups, which undergo a pK_a change on protein binding, are necessary to result in highly pH‐dependent binding. To test this hypothesis, a novel combinatorial histidine library was developed where every possible combination of histidine and wild‐type residue is sampled throughout the interface of a model anti‐RNase A single domain VHH antibody. Antibodies were coselected for high‐affinity binding and pH‐sensitivity using an in vitro, dual‐function selection strategy. The resulting antibodies retained near wild‐type affinity yet became highly sensitive to small decreases in pH, drastically decreasing their binding affinity, due to the incorporation of multiple histidine groups. Several trends were observed, such as histidine “hot‐spots,” which will help enhance the development of pH switch proteins as well as increase our understanding of the role of ionizable residues in protein interfaces. Overall, the combinatorial approach is rapid, general, and robust and should be capable of producing highly pH‐sensitive protein affinity reagents for a number of different applications.     

Detection system based on the conformational change in an aptamer and its application to simple bound/free separation

Aptamers are good molecular recognition elements for biosensors. Especially, their conformational change, which is induced by the binding to the target molecule, enables the development of several types of useful detection systems. We applied this property to bound/free separation, which is a crucial process for highly sensitive detection. We designed aptamers which change their conformation upon binding to the target molecule and thereby expose a single-strand bearing the complementary sequence to the capture probe immobilized onto the support. We named the designed aptamers "capturable aptamers" and the capture probe "capture DNA". Three capturable aptamers were designed based on the PrP aptamer, which binds to prion protein. One of these capturable aptamers was demonstrated to recognize prion protein and change its conformation upon binding to it. A detection system using this designed capturable aptamer for prion protein was developed. Capturable aptamers and capture DNA allow us to perform simple bound/free separation with only one target ligand.     

Selection of DNA aptamers against insulin and construction of an aptameric enzyme subunit for insulin sensing

We selected DNA aptamers against insulin and developed an aptameric enzyme subunit (AES) for insulin sensing. The insulin-binding aptamers were identified from a single-strand DNA library which was expected to form various kinds of G-quartet structures. In vitro selection was carried out by means of aptamer blotting, which visualizes the oligonucleotides binding to the target protein at each round. After the 6th round of selection, insulin-binding aptamers were identified. These identified insulin-binding aptamers had a higher binding ability than the insulin-linked polymorphic region (ILPR) oligonucleotide, which can be called a "natural" insulin-binding DNA aptamer. The circular-dichroism (CD) spectrum measurement of the identified insulin-binding DNA aptamers indicated that the aptamers would fold into a G-quartet structure. We also developed an AES by connecting the best identified insulin-binding aptamer with the thrombin-inhibiting aptamer. Using this AES, we were able to detect insulin by measuring the thrombin enzymatic activity without bound/free separation.     

Selection,Characterization and Application of Nucleic Acid Aptamers for the Capture and Detection of Human Norovirus Strains

Human noroviruses (HuNoV) are the leading cause of acute viral gastroenteritis and an important cause of foodborne disease. Despite their public health significance, routine detection of HuNoV in community settings, or food and environmental samples, is limited, and there is a need to develop alternative HuNoV diagnostic reagents to complement existing ones. The purpose of this study was to select and characterize single-stranded (ss)DNA aptamers with binding affinity to HuNoV. The utility of these aptamers was demonstrated in their use for capture and detection of HuNoV in outbreak-derived fecal samples and a representative food matrix. SELEX (Systematic Evolution of Ligands by EXponential enrichment) was used to isolate ssDNA aptamer sequences with broad reactivity to the prototype GII.2 HuNoV strain, Snow Mountain Virus (SMV). Four aptamer candidates (designated 19, 21, 25 and 26) were identified and screened for binding affinity to 14 different virus-like particles (VLPs) corresponding to various GI and GII HuNoV strains using an Enzyme-Linked Aptamer Sorbant Assay (ELASA). Collectively, aptamers 21 and 25 showed affinity to 13 of the 14 VLPs tested, with strongest binding to GII.2 (SMV) and GII.4 VLPs. Aptamer 25 was chosen for further study. Its binding affinity to SMV-VLPs was equivalent to that of a commercial antibody within a range of 1 to 5 µg/ml. Aptamer 25 also showed binding to representative HuNoV strains present in stool specimens obtained from naturally infected individuals. Lastly, an aptamer magnetic capture (AMC) method using aptamer 25 coupled with RT-qPCR was developed for recovery and detection of HuNoV in artificially contaminated lettuce. The capture efficiency of the AMC was 2.5–36% with an assay detection limit of 10 RNA copies per lettuce sample. These ssDNA aptamer candidates show promise as broadly reactive reagents for use in HuNoV capture and detection assays in various sample types.     

Elevational trends in life histories: revising the pace‐of‐life framework

Life‐history traits in birds, such as lifespan, age at maturity, and rate of reproduction, vary across environments and in combinations imposed by trade‐offs and limitations of physiological mechanisms. A plethora of studies have described the diversity of traits and hypothesized selection pressures shaping components of the survival–reproduction trade‐off. Life‐history variation appears to fall along a slow–fast continuum, with slow pace characterized by higher investment in survival over reproduction and fast pace characterized by higher investment in reproduction over survival. The Pace‐of‐Life Syndrome (POLS) is a framework to describe the slow–fast axis of variation in life‐history traits and physiological traits. The POLS corresponds to latitudinal gradients, with tropical birds exhibiting a slow pace of life. We examined four possible ways that the traits of high‐elevation birds might correspond to the POLS continuum: (i) rapid pace, (ii) tropical slow pace, (iii) novel elevational pace, or (iv) constrained pace. Recent studies reveal that birds breeding at high elevations in temperate zones exhibit a combination of traits creating a unique elevational pace of life with a central trade‐off similar to a slow pace but physiological trade‐offs more similar to a fast pace. A paucity of studies prevents consideration of the possibility of a constrained pace of life. We propose extending the POLS framework to include trait variation of elevational clines to help to investigate complexity in global geographic patterns.     

应用核酸适配子检测细胞因子的新方法—ELONA法

以人肿瘤坏死因子(Human tumor necrosis factor,hTNF—α)特异性的核酸适配子为检测分子建立了酶联寡聚核苷酸吸附试验(Enzyme—linked Oligonucleotide assay,ELONA)方法,用于hTNF—α的检测。通过SELEX(Systematic Evolution of Ligands by Exponential Enrichment)方法从随机RNA库中筛选到与hTNF—α特异结合的RNA适配子。根据其序列,用体外转录方法合成生物素标记的RNA适配子,并对其进行了氨基修饰以增加其稳定性。以hTNF—α的单克隆抗体为捕获分子,生物素标记的hTNF—α特异性RNA适配子为检测分子建立了ELONA方法,并对这种检测方法的灵敏度、精密度和准确度等进行了分析。同时用ELONA和ELISA方法检测了正常人血清中的hTNF—α水平,并对检测结果进行比较。结果显示,ELONA方法的灵敏度为100pg／mL,具有较好的精密度和准确度。ELONA法的检测结果与ELISA法检测结果基本一致。该方法适用于血清、细胞培养上清等多种生物标本中各种细胞因子及其它蛋白的检测。