Importance of surface properties of affinity resin for capturing a target protein,Cyclooxygenase-1

We have prepared affinity resins based on two kinds of solid phases, including a commercially available solid phase, to re-realize the importance of surface properties of affinity resins such as controlled ligand density as well as existential surroundings of the ligand. Affinity resins were prepared using non-steroidal anti-inflammatory drugs, such as Ketoprofen, Ibuprofen, and Aspirin, having different activities as ligands. The ligand density was controlled through two different strategies: one strategy was that the solid phases having different amino group densities (20, 60, 100, 125 μmol/ml) were utilized then, Ketoprofen was fully immobilized through condensation reaction to amino groups; another strategy was that a solid phase having amino group density (125 μmol/ml) was utilized then, each ligand was immobilized with controlled immobilization rate. In addition, a typical hydrophobic group, stearoyl group (C₁₈ group), was immobilized on the affinity resin with controlled ligand immobilization rate to change the existential surroundings of the ligand. Affinity tests were performed for Cyclooxgenase-1 (COX-1) as it was the target protein in this work. The amount of captured COX-1 was evaluated utilizing each affinity resin. It was suggested that the density of surface ligand tends to relate to the amount of captured COX-1 on our solid phase-based affinity resins; however, several exceptions occurred according to the surface properties of affinity resins in the case of commercial one.     

An easy preparation of 'monolithic type' hydrophilic solid phase: capability for affinity resin to isolate target proteins

An easy preparation method of monolithic type hydrophilic solid phase was discussed. Newly invented functional monomer with a hydrophilic cross-linking agent was co-polymerized to realize well-controlled monolithic co-continuous structure by use of diethylene glycol as porogenic solvent. We were able to control the content of the functional monomer up to 40 vol% without loss of monolithic structure. Those prepared were utilized as affinity resins after immobilization of FK506, an immunosuppressive drug as a ligand. It was found that the affinity resins prepared were hydrophilic enough to eliminate non-specific adsorption of proteins, while two of the target proteins of FK506 tested were successfully captured.     

Affinity capture of a mammalian DNA polymerase beta by inhibitors immobilized to resins used in solid-phase organic synthesis

The application of resins normally used in solid-phase organic synthesis to the affinity capture of a mammalian DNA polymerase beta (pol beta) is reported. Lithocholic acid (LCA), an inhibitor of pol beta, was immobilized on various solid supports, and the batch affinity purification of pol beta from a mixture of proteins using these LCA-immobilized resins was examined. Of the resins tested, TentaGel was the most effective at purifying pol beta and at resisting nonspecific absorption of proteins. The immobilized LCA recognized pol beta specifically, which resulted in pol beta binding to the resin. Using the LCA-immobilized resin, it was possible to purify pol beta from a mixture of proteins. Furthermore, it was possible to concentrate pol beta from a crude nuclear extract of human T lymphoma Molt4 cells. To facilitate the immobilization of compounds on TentaGel resins, we also designed and prepared photoaffinity beads containing a photoreactive group at the free termini of the TentaGel resin. The pol beta inhibitors LCA, C18-beta-SQDG, and epolactaene were immobilized on the photoaffinity beads by photoreaction. The batch affinity purification of pol beta from a protein mixture could be also achieved with these beads.     

Essential role of the concentration of immobilized ligands in affinity chromatography:: Purification of guanidinobenzoatase on an ionized ligand

Guanidinobenzoatase, a plasma protein with possible application as a ‘tumor marker’, has been fully purified by one-step affinity chromatography. The affinity matrix was prepared by ‘controlled’ immobilization of an enzyme inhibitor (agmatine) onto commercial agarose gels containing carboxyl moieties activated as N-hydroxysuccinimide esters. In this way, agmatine becomes immobilized through an amido bond and preserves an ionized guanidino moiety. Different matrices with different concentration of ligands were prepared in order to evaluate their properties as affinity supports. Interestingly, matrices with a very low concentration of immobilized ligands (2 μmol/ml, corresponding to the modification of only 5% of active groups in the commercial resins) exhibited a low capacity for unspecific adsorption of proteins (as anion-exchange resins) and displayed also a high capacity for specific adsorption of our target protein. On the other hand, when affinity matrices possessed a moderate concentration of agmatine (10 μmol/ml of gel or higher), two undesirable phenomena were observed: (a) the matrix behaves as a very good anionic exchange support able to non-specifically adsorb most of plasma proteins and (b) the specific adsorption of our target protein becomes much lower. The latter phenomenon could be due to steric hindrances promoted by the interaction between each individual immobilized ligand and the corresponding binding pocket in the target protein. These hindrances could also be promoted by the presence of a fairly dense layer of immobilized ligands covering the support surface, thus preventing interactions between immobilized ligands and partially buried protein-binding pockets. In this way, a successful affinity purification (23.5% yield, ×220 purification factor, a unique electrophoretic band) could be achieved by combination of three approaches: (i) the use of affinity matrices possessing a very low density of immobilized ligands, (ii) performing affinity adsorption at high ionic strength and (iii) performing specific desorption with substrates or substrate analogues.     

Development of affinity chromatography using a bioactive peptide as a ligand

By repeatedly introducing hydrophilic polyethylene glycol (PEG) spacer (2) onto affinity resin bearing a bioactive peptide (1/2 secretory leukocyte protease inhibitor, 1/2SLPI) as a ligand, the adsorption of nonspecific binding proteins was effectively reduced and the purification efficacy of elastase, which is one of the target molecules for 1/2SLPI, from a protein mixture was improved. Moreover, using this resin, we also successfully detected L-plastin, as an endogenous target molecule for SLPI, from HL-60 cell lysate.     

Capture of proteins from mammalian cells in pilot scale using different STREAMLINE adsorbents

This presentation compares three different expanded bed matrices. STREAMLINE rProtein A, STREAMLINE SP-XL and STREAMLINE Chelating were monitored in respect to their ability to clarify the broth, to concentrate and to purify the distinct target protein. The capture of a mouse IgG₁ and a recombinant prothrombin (PT) was carried out in pilot scale using a 100-l bioreactor and STREAMLINE 100 and 200 columns, respectively. The robustness of the process was also estimated monitoring the expansion behaviour and the cell and debris concentrations during the load and in the eluat. In all cases the capture of the target proteins was comparable to conventional chromatographic systems. The purification success was mainly dependent on the selectivity of the ligand used. The affinity process resulted in a highly purified product. The ion exchanger and chelating material mainly concentrated the product. In all three cases 100 l of cell broth were successfully processed in one run. The robustness of the ion exchanger process was poor, because of strong cell matrix interaction. However, for the chelating and especially for the affinity matrix a highly reproducible process was obtained.     

Synthesis and characterization of pseudo-affinity ligand for penicillin acylase purification

The aim of this work was to test a chromatographic affinity support containing methacryloyl antipyrine (MAAP) for penicillin acylase (PA) purification by using pure penicillin acylase and crude extract. First, MAAP as a pseudo-specific ligand was synthesized by using methacryloyl chloride and 4-aminoantipyrine. Polymer beads (average size diameter: 40–120 μm) were prepared by suspension polymerization of ethylene glycol dimethacrylate (EGDMA) and MAAP. This approach for the preparation of adsorbent has several advantages over conventional preparation protocols. An expensive and time consuming step in the preparation of adsorbent is immobilization of a ligand to the adsorption matrix. In this procedure, affinity ligand MAAP acts as comonomer without further modification steps. Poly(EGDMA-MAAP) beads were characterized by FTIR, NMR and screen analysis. Elemental analysis of MAAP for nitrogen was estimated as 89.3 μmol/g. The prepared adsorbent was then used for the capture of penicillin acylase in batch system. The maximum penicillin acylase adsorption capacity of the poly(EGDMA-MAAP) beads was found to be 82.2 mg/g at pH 5.0. Chromatography with crude feedstock resulted in 23.2-fold purification and 93% recovery with 1.0 M NaOH.     

A novel affinity ligand for polystyrene surface from a phage display random library and its application in anti-HIV-1 ELISA system

In order to develop an affinity ligand for site-directed immobilization of target proteins on polystyrene (PS) surface, a linear 12-mer peptide phage display random library was screened. Phage clones that specifically bound to PS plate were sequenced after three rounds of biopanning. The obtained DNA sequences revealed that there were several aromatic and basic amino acid residues, which may be critical to binding. One of the selected dodecapeptides, named Lig1 (FKFWLYEHVIRG), was genetically fused to the N/C-terminus of recombinant antigen ENV which could be recognized by specific antibodies against human immunodeficiency virus type 1 (HIV-1), to investigate its performance as an affinity ligand. The ligand-fused ENVs overexpressed in Escherichia coli were compared to the original one in terms of the immobilization characteristics on PS plate in enzyme-linked immunosorbent assay (ELISA). The results indicated that the ligand-fused proteins showed a considerably improved affinity to PS surface, and were preferentially adsorbed on PS plate suffering only scarcely from interference by coexisting protein molecules. Anti-HIV-1 ELISA system, which employed Lig1-ENV (Lig1 fused to ENV N-terminus) as immobilization antigen also exhibited sufficiently high sensitivity and specificity in serodiagnosis tests.     

A highly selective Hsp90 affinity chromatography resin with a cleavable linker

Over 200 proteins have been identified that interact with the protein chaperone Hsp90, a recognized therapeutic target thought to participate in non-oncogene addiction in a variety of human cancers. However, defining Hsp90 clients is challenging because interactions between Hsp90 and its physiologically relevant targets involve low affinity binding and are thought to be transient. Using a chemo-proteomic strategy, we have developed a novel orthogonally cleavable Hsp90 affinity resin that allows purification of the native protein and is quite selective for Hsp90 over its immediate family members, GRP94 and TRAP 1. We show that the resin can be used under low stringency conditions for the rapid, unambiguous capture of native Hsp90 in complex with a native client. We also show that the choice of linker used to tether the ligand to the insoluble support can have a dramatic effect on the selectivity of the affinity media.     

Site-specific immobilization of recombinant antibody fragments through material-binding peptides for the sensitive detection of antigens in enzyme immunoassays

The immobilization of an antibody is one of the key technologies that are used to enhance the sensitivity and efficiency of the detection of target molecules in immunodiagnosis and immunoseparation. Recombinant antibody fragments such as VHH, scFv and Fabs produced by microorganisms are the next generation of ligand antibodies as an alternative to conventional whole Abs due to a smaller size and the possibility of site-directed immobilization with uniform orientation and higher antigen-binding activity in the adsorptive state. For the achievement of site-directed immobilization, affinity peptides for a certain ligand molecule or solid support must be introduced to the recombinant antibody fragments. In this mini-review, immobilization technologies for the whole antibodies (whole Abs) and recombinant antibody fragments onto the surfaces of plastics are introduced. In particular, the focus here is on immobilization technologies of recombinant antibody fragments utilizing affinity peptide tags, which possesses strong binding affinity towards the ligand molecules. Furthermore, I introduced the material-binding peptides that are capable of direct recognition of the target materials. Preparation and immobilization strategies for recombinant antibody fragments linked to material-binding peptides (polystyrene-binding peptides (PS-tags) and poly (methyl methacrylate)-binding peptide (PMMA-tag)) are the focus here, and are based on the enhancement of sensitivity and a reduction in the production costs of ligand antibodies. This article is part of a Special Issue entitled: Recent advances in molecular engineering of antibody.     

Avidity‐mediated virus separation using a hyperthermophilic affinity ligand

Immunoaffinity separation of large multivalent species such as viruses is limited by the stringent elution conditions necessary to overcome their strong and highly avid interaction with immobilized affinity ligands on the capture surface. Here we present an alternate strategy that harnesses the avidity effect to overcome this limitation. Red clover necrotic mosaic virus (RCNMV), a plant virus relevant to drug delivery applications, was chosen as a model target for this study. An RCNMV binding protein (RBP) with modest binding affinity (K_D ～100 nM) was generated through mutagenesis of the Sso7d protein from Sulfolobus solfataricus and used as the affinity ligand. In our separation scheme, RCNMV is captured by a highly avid interaction with RBP immobilized on a nickel surface through a hexahistidine (6xHis) tag. Subsequently, disruption of the multivalent interaction and release of RCNMV is achieved by elution of RBP from the nickel surface. Finally, RCNMV is separated from RBP by exploiting the large difference in their molecular weights (～8 MDa vs. ～10 kDa). Our strategy not only eliminates the need for harsh elution conditions, but also bypasses chemical conjugation of the affinity ligand to the capture surface. Stable non‐antibody affinity ligands to a wide spectrum of targets can be generated through mutagenesis of Sso7d and other hyperthermophilic proteins. Therefore, our approach may be broadly relevant to cases where capture of large multivalent species from complex mixtures and subsequent release without the use of harsh elution conditions is necessary. © 2012 American Institute of Chemical Engineers Biotechnol. Prog., 2013     

Affinity purification of immunoglobulins from chicken egg yolk using a new synthetic ligand

Due to the peculiar composition of the egg yolk and the lack of specific affinity ligands, Y immunoglobulins are normally purified using complex and time consuming procedures involving a combination of precipitation and chromatographic steps first to extract and capture and then to polish IgY. In this study, we have examined the applicability for IgY affinity purification of TG19318, a synthetic ligand for immunoglobulin, obtained from the screening of combinatorial libraries, and already characterized for its capability to purify immunoglobulins of class G, M, E and A. Soluble proteins were separated from the lipidic fraction of egg yolk by the water dilution method and loaded on to TG19318 affinity columns prepared by immobilizing the ligand on the commercially available support Emphaze™. In a single chromatographic step TG19318 affinity columns led to an efficient capture of IgY directly from crude samples, and with a purity degree higher than 90%, as determined by densitometric scanning of SDS–PAGE analysis of bound fractions, and with full recovery of antibody activity, as determined by ELISA assay. Higher recovery and purity of IgY was obtained by using loading buffers at pH close to 6.5. Column capacity, determined by applying 4× excess IgY to 1 ml bed volume column, and eluting the retained immunoglobulins, was close to 65 mg of IgY per ml of resin. Chemical and chromatographic stability of TG19318/Emphaze was tested before and after various treatments. The derivatized matrix was found to be very stable, in terms of ligand leakage and maintenance of IgY binding capacity, under conditions of normal column usage, cleaning and storage.     

Affinity regulates spatial range of EGF receptor autocrine ligand binding

Proper spatial localization of EGFR signaling activated by autocrine ligands represents a critical factor in embryonic development as well as tissue organization and function, and ligand/receptor binding affinity is among the molecular and cellular properties suggested to play a role in governing this localization. We employ a computational model to predict how receptor-binding affinity affects local capture of autocrine ligand vis-a-vis escape to distal regions, and provide experimental test by constructing cell lines expressing EGFR along with either wild-type EGF or a low-affinity mutant, EGF(L47M). The model predicts local capture of a lower affinity autocrine ligand to be less efficient when the ligand production rate is small relative to receptor appearance rate. Our experimental data confirm this prediction, demonstrating that cells can use ligand/receptor binding affinity to regulate ligand spatial distribution when autocrine ligand production is limiting for receptor signaling.     

Polymerized liposome as ligand carrier for affinity precipitation of proteins

A polymerized liposome (PLS) was prepared using a synthesized phospholipid with a diacetylene moiety in the hydrophobic chain and an amino group in the hydrophilic head. The PLS was used as a novel ligand carrier for affinity precipitation of proteins because it showed a reversibly precipitable property on salt addition and removal. Soybean trypsin inhibitor (STI) was easily immobilized on the PLS by a one-step carbodiimide reaction. The PLS showed no nonspecific adsoprtion of proteins. It had a large ligand coupling capacity, and then a large adsorption capacity for trypsin after STI immobilization. The PLS with immpbilized STI was recycled three times for the purification of trypsin from a crude pancreatic extract. Although the degree of purification was compromised by the impurity of the STI employed, in each run the purification factor reached about 6 and more than 80% of trypsin activity was recovered. The results indicated that the PLS was a potential ligand carrier for affinity precipitation of proteins. (c) 1995 John Wiley & Sons, Inc.     

In vivo biotinylated proteins as targets for phage-display selection experiments

Screening phage-displayed combinatorial libraries represents an attractive method for identifying affinity reagents to target proteins. Two critical components of a successful selection experiment are having a pure target protein and its immobilization in a native conformation. To achieve both of these requirements in a single step, we have devised cytoplasmic expression vectors for expression of proteins that are tagged at the amino- or carboxy-terminus (pMCSG16 and 15) via the AviTag, which is biotinylated in vivo with concurrent expression of the BirA biotin ligase. To facilitate implementation in high-throughput applications, the engineered vectors, pMCSG15 and pMCSG16, also contain a ligase-independent cloning site (LIC), which permits up to 100% cloning efficiency. The expressed protein can be purified from bacterial cell lysates with immobilized metal affinity chromatography or streptavidin-coated magnetic beads, and the beads used directly to select phage from combinatorial libraries. From selections using the N-terminally biotinylated version of one target protein, a peptide ligand (Kd= 9 microM) was recovered that bound in a format-dependent manner. To demonstrate the utility of pMCSG16, a set of 192 open reading frames were cloned, and protein was expressed and immobilized for use in high-throughput selections of phage-display libraries.     

An enzymatic strategy for site-specific immobilization of functional proteins using microbial transglutaminase

A novel strategy for site-specific immobilization of recombinant proteins was investigated using microbial transglutaminase (MTG). Alkaline phosphatase (AP) was selected as a model protein and tagged with a short peptide (MKHKGS) at the N-terminus to provide a reactive Lys residue for MTG. On the other hand, casein, a well-known substrate for MTG, was chemically attached onto a polyacrylic resin to provide reactive Gln residues for the enzymatic immobilization of the recombinant AP. As a result, we succeeded in MTG-mediated functional immobilization of the recombinant AP onto casein-coated polyacrylic resin. It was found that the immobilized AP prepared using MTG exhibited much higher specific activity than that prepared by chemical modification. Moreover, enzymatic immobilization gave an immobilized formulation with higher stability upon repeated use than that obtained by physical adsorption. Use of this ability of MTG in posttranslational protein modification will provide us with a benign, site-specific immobilization method for functional proteins.     

Identification of protein binding partners of ALK-5 kinase inhibitors

We have investigated the binding characteristics of a potent member of the bis-ortho-substituted five-membered nitrogen heterocycle class of ALK-5 kinase inhibitors with lysates of cultured HEK-293 cells to identify protein binding partners of potential biological significance. An affinity chromatographic resin containing an immobilized ALK-5 kinase inhibitor, 2-phenyl-4-[3-(pyridin-2-yl)-1H-pyrazol-4-yl]pyridine, was used to capture specific proteins from the cell lysate. The soluble inhibitor was then used to specifically elute the proteins which selectively bound to the pharmacophore ligand structure. Application of 2-D SDS–PAGE analysis with positive and negative controls demonstrated the inhibitor bound several different proteins via selective molecular recognition processes. The structural features of the specifically eluted proteins were identified by peptide mass fingerprinting (PMF) methods and included proteins with structural, metabolic and chaperone functions. Furthermore, these PMF results identified the therapeutic target in various cancer treatment studies, HSP-70, as a potential high-affinity binding partner. These observations warrant examination of bis-ortho-substituted five-membered nitrogen heterocycles as dual ALK-5/HSP-70 inhibitors for anti-cancer drug development.     

HaloTag7: A genetically engineered tag that enhances bacterial expression of soluble proteins and improves protein purification

Over-expression and purification of soluble and functional proteins remain critical challenges for many aspects of biomolecular research. To address this, we have developed a novel protein tag, HaloTag7, engineered to enhance expression and solubility of recombinant proteins and to provide efficient protein purification coupled with tag removal. HaloTag7 was designed to bind rapidly and covalently with a unique synthetic linker to achieve an essentially irreversible attachment. The synthetic linker may be attached to a variety of entities such as fluorescent dyes and solid supports, permitting labeling of fusion proteins in cell lysates for expression screening, and efficient capture of fusion proteins onto a purification resin. The combination of covalent capture with rapid binding kinetics overcomes the equilibrium-based limitations associated with traditional affinity tags and enables efficient capture even at low expression levels. Following immobilization on the resin, the protein of interest is released by cleavage at an optimized TEV protease recognition site, leaving HaloTag7 bound to the resin and pure protein in solution. Evaluation of HaloTag7 for expression of 23 human proteins in Escherichia coli relative to MBP, GST and His₆Tag revealed that 74% of the proteins were produced in soluble form when fused to HaloTag7 compared to 52%, 39% and 22%, respectively, for the other tags. Using a subset of the test panel, more proteins fused to HaloTag7 were successfully purified than with the other tags, and these proteins were of higher yield and purity.     

A novel approach for affinity-based screening of target specific ligands: application of photoreactive D-glyceraldehyde-3-phosphate dehydrogenase

A novel application of the photoaffinity technique has been developed for the efficient discovery of small ligand and macromolecule interaction. The approach, photoaffinity capture, uses a photoreactive protein together with immobilized ligand for the rapid screening of competitive inhibitors. The set of photoreactive glyceraldehyde-3-phosphate dehydrogenase (photo-GAPDH) and immobilized dye ligand was prepared and examined as a model system. The photo-GAPDH was shown to efficiently capture the immobilized ligand. When nonimmobilized competitive ligands were included in the system, the capture was prevented in accordance with the affinity of the ligands. The present approach would provide an efficient tool for affinity-based screening of ligand libraries.