Affinity enhancement of complementary peptide recognition.

A peptide hydropathically complementary to Big Endothelin [Big ET] residues 16-29 has been synthesized in a multimeric form starting from an octadentate polylysine core, essentially in a way similar to the procedure used for the production of multiple antigenic peptides [MAP's]. Interaction between the multimeric complementary peptide [8 delta ET] and the Big ET fragment 16-32 containing the target complementary region, also synthesized in a multimeric form [8ET], was evaluated by analytical high performance affinity chromatography and solid phase binding assays. While the binding interaction between the monomerics peptide pair was in the micromolar range, the recognition between the corresponding multimeric form was characterized by enhanced binding affinity of at least two orders of magnitude. In solution, complex formation between multimeric complementary peptide and target Big ET sequence in the monomeric and multimeric form was accompanied by precipitation at concentrations higher than 0.5 mg/mL and 0.1 mg/mL, respectively. Polyclonal antibodies raised against the multimeric target sequence recognized multimeric and monomeric ET target sequences with binding affinities similar to binding affinities exhibited by the multimeric complementary peptide. Multimerization of hydropathically complementary peptides could provide an improved opportunity to measure and thus probe quantitative binding properties of complementary peptides.     

A rapid procedure for preparing fluorescein-labeled specific antibodies from whole antiserum: its use in analyzing cytoskeletal architecture

A rapid method for the direct conjugation of affinity-purified antibodies with fluorescein (termed DCAPA) is described. This procedure involves the immobilization of antibodies as antigen-antibody complexes on nitrocellulose blots, and subsequently the bound antibodies are reacted with fluorescein isothiocyanate. An enriched sample of smooth muscle tropomysin transferred to nitrocellulose paper by the Western blotting procedure has been used as the affinity medium for purification of specific tropomyosin antibody from whole rabbit antiserum. Direct conjugation of the antibody with fluorescein was carried out following the binding of antibody to antigen. Direct conjugation and affinity purification of antibodies directed against tropomyosin was accomplished in 2-3 d using an enriched tropomyosin sample and whole antiserum directed against tropomyosin. The immunofluorescence images obtained with this procedure exhibit distinct advantages with regard to background fluorescence and overall specificity of antibody binding. The usefulness of this direct conjugation method in various experimental protocols is discussed.     

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.     

Synthesis of Highly Immunogenic Multiple Antigenic Peptides for Epitopes of Viral Antigen to Use in ELISA

Synthesis of multiple antigenic peptides (MAPs) for predicted antigenic determinants of a viral antigen is described. The method includes prediction of linear epitopes using predictive computer algorithms, synthesis of peptides for the predicted regions, testing of peptides to find the most reactive sites, synthesis of MAPs and their testing. The procedure involves manual synthesis of MAPs by solid phase peptide synthesis with Wang resin as solid support. The MAPs were prepared in eight copies and used for immunization of rabbits to generate anti-peptide antibodies. Further, the reactivity of MAPs in detecting the native cognate antigen in the whole virus was confirmed by ELISA. The MAP and anti-peptide antibodies could serve as diagnostic tools for viral diseases. MAPs have efficiently been used to confirm the presence of linear antigenic and immunogenic epitopes on viral proteins, for possible use in diagnostic and vaccine. It was suggested that this method could help in epitope mapping of dreadful human or animal pathogens as it involves production of safe, chemically defined and non-infectious materials for use as antigen as well as immunogen.     

Analysis of antigen-specific antibodies and their isotypes in experimental malaria.

BACKGROUND: Measuring antibody production in response to antigen exposure or vaccination is key to disease prevention and treatment. Our understanding of the mechanisms involved in the antibody response is limited by a lack of sensitive analysis methods. We address this limitation using multiplexed microsphere arrays for the semi -quantitative analysis of antibody production in response to malaria infection. METHODS: We used microspheres as solid supports on which to capture and analyze circulating antibodies. Antigen immobilized on beads captured antigen-specific antibodies for semi- quantitative analysis using fluorescent secondary antibodies. Anti-immunoglobulin antibodies on beads captured specific antibody isotypes for affinity estimation using fluorescent antigen. RESULTS: Antigen-mediated capture of plasma antibodies enables determination of antigen-specific antibody "titer," a semi-quantitative parameter describing a convolution of antibody abundance and avidity, as well as parameters describing numbers of antibodies bound/bead at saturation and the plasma concentration-dependent approach to saturation. Results were identical in single-plex and multiplex assays, and in qualitative agreement with similar parameters derived from ELISA-based assays. Isotype-specific antibody-mediated capture of plasma antibodies allowed the estimation of the affinity of antibody for antigen. CONCLUSION: Analysis of antibody responses using microspheres and flow cytometry offer significant advantages in speed, sample size, and quantification over standard ELISA-based titer methods.     

Oriented immobilization of biologically active proteins as a tool for revealing protein interactions and function

The advantages of oriented immobilization of biologically active proteins are good steric accessibilities of active binding sites and increased stability. This not only may help to increase the production of preparative procedures but is likely to promote current knowledge about how the living cells or tissues operate. Protein inactivation starts with the unfolding of the protein molecule by the contact of water with hydrophobic clusters located on the surface of protein molecules, which results in ice-like water structure. Reduction of the nonpolar surface area by the formation of a suitable biospecifc complex or by use of carbohydrate moieties thus may stabilize proteins. This review discusses oriented immobilization of antibodies by use of immobilized protein A or G. The section about oriented immobilization of proteins by use of their suitable antibodies covers immobilization of enzymes utilizing their adsorption on suitable immunosorbents prepared using monoclonal or polyclonal antibodies, preparation of bioaffinity adsorbent for the isolation of concanavalin A and immobilization of antibodies by use of antimouse immunoglobulin G, Fc-specific (i.e. specific towards the constant region of the molecule). In the further section immobilization of antibodies and enzymes through their carbohydrate moieties is described. Oriented immobilization of proteins can be also based on the use of boronate affinity gel or immobilized metal ion affinity chromatography technique. Biotin–avidin or streptavidin techniques are mostly used methods for oriented immobilization. Site-specific attachment of proteins to the surface of solid supports can be also achieved by enzyme, e.g., subtilisin, after introduction a single cysteine residue by site-directed mutagenesis.     

Redesign of a protein–peptide interaction: Characterization and applications

The design of protein–peptide interactions has a wide array of practical applications and also reveals insight into the basis for molecular recognition. Here, we present the redesign of a tetratricopeptide repeat (TPR) protein scaffold, along with its corresponding peptide ligand. We show that the binding properties of these protein–peptide pairs can be understood, quantitatively, using straightforward chemical considerations. The recognition pairs we have developed are also practically useful for the specific identification of tagged proteins. We demonstrate the facile replacement of these proteins, which we have termed T‐Mods (TPR‐based recognition module), for antibodies in both detection and purification applications. The new protein–peptide pair has a dissociation constant that is weaker than typical antibody–antigen interactions, yet the recognition pair is highly specific and we have shown that this affinity is sufficient for both Western blotting and affinity purification. Moreover, we demonstrate that this more moderate affinity is actually advantageous for purification applications, because extremely harsh conditions are not required to dissociate the T‐Mod‐peptide interaction. The results we present are important, not only because they represent a successful application of protein design but also because they help define the properties that should be sought in other scaffolds that are being developed as antibody replacements.     

Rapid single-tube method for small-scale affinity purification of polyclonal antibodies using HaloTag™ Technology

Even in this era of advanced biotechniques, specific antibodies against a protein still prove to be powerful tools to study proteins and their functions. The polyclonal antisera obtained from the immunized rabbits, however, are not always pure, high affinity, antigen-specific polyclonal antibodies. With our new rapid HaloTag-based procedure, specific antibodies are obtained in just two, short steps: (1) simultaneous purification and covalent coupling of the antigen to Sepharose resin via the HaloTag and HaloLink reaction, and (2) affinity column purification of the polyclonal serum (10 μl). The combined antigen purification and coupling step requires only 1 h of room-temperature incubation, plus successive washing steps. Because different regions of an antigen can elicit the production of low affinity antibodies with relatively high cross-reactivity, the best way to produce high affinity antibodies against a protein of interest is to survey all antigenic determinants of that protein and identify the epitopes that result in the production of antibodies with a high affinity and specificity for that protein. Because our HaloTag procedure is quite rapid and simple, potential epitopes can be assessed with relatively little effort for their ability to elicit the production of highly specific antibodies.     

Rapid single-tube method for small-scale affinity purification of polyclonal antibodies using HaloTag Technology

Even in this era of advanced biotechniques, specific antibodies against a protein still prove to be powerful tools to study proteins and their functions. The polyclonal antisera obtained from the immunized rabbits, however, are not always pure, high affinity, antigen-specific polyclonal antibodies. With our new rapid HaloTag-based procedure, specific antibodies are obtained in just two, short steps: (1) simultaneous purification and covalent coupling of the antigen to Sepharose resin via the HaloTag and HaloLink reaction, and (2) affinity column purification of the polyclonal serum (10 microl). The combined antigen purification and coupling step requires only 1 h of room-temperature incubation, plus successive washing steps. Because different regions of an antigen can elicit the production of low affinity antibodies with relatively high cross-reactivity, the best way to produce high affinity antibodies against a protein of interest is to survey all antigenic determinants of that protein and identify the epitopes that result in the production of antibodies with a high affinity and specificity for that protein. Because our HaloTag procedure is quite rapid and simple, potential epitopes can be assessed with relatively little effort for their ability to elicit the production of highly specific antibodies.     

Controlled antibody immobilization onto immunoanalytical platforms by synthetic peptide

Antibody immobilization on a solid surface is inevitable in the preparation of immunochips/sensors. Antibody-binding proteins such as proteins A and G have been extensively employed to capture antibodies on sensor surfaces with right orientations, maintaining their full functionality. Because of their synthetic versatility and stability, in general, small molecules have more advantages than proteins. Nevertheless, no small molecule has been used for oriented and specific antibody immobilization. Here is described a novel strategy to immobilize an antibody on various sensor surfaces by using a small antibody-binding peptide. The peptide binds specifically to the Fc domain of immunoglobulin G (IgG) and, therefore, affords a properly oriented antibody surface. Surface plasmon resonance analysis indicated that a peptide linked to a gold chip surface through a hydrophilic linker efficiently captured human and rabbit IgGs. Moreover, antibodies captured by the peptide exhibited higher antigen binding capacity compared with randomly immobilized antibodies. Peptide-mediated antibody immobilization was successfully applied on the surfaces of biosensor substrates such as magnetic particles and glass slides. The antibody-binding peptide conjugate introduced in this work is the first small molecule linker that offers a highly stable and specific surface platform for antibody immobilization in immunoassays.     

Antibodies against synthetic peptides used to determine the topology and site of glycosylation of the cGMP-gated channel from bovine rod photoreceptors.

Peptides corresponding to amino acids 321-339 (peptide GS21) and 416-431 (peptide GS31) of the cGMP-gated channel from bovine rod photoreceptors were synthesized and used as antigens for the preparation of polyclonal antibodies. After affinity purification, both antipeptide antibodies were found to bind specifically to the channel protein after Western blotting, but only the antibody against GS21 gave satisfactory results on enzyme-linked immunosorbent assay and electron microscopy. Using immunocytochemistry, we were able to localize amino acids 321-339 to the extracellular side of the rod photoreceptor plasma membrane. By synthesizing heptapeptides corresponding to amino acids 324-330 (peptide GS2s) and 420-426 (peptide GS3s), we were able to affinity purify antibodies specific for two N-glycosylation consensus sites in the channel protein. As assessed by Western blotting, antibodies against GS3s were found to bind to both the glycosylated and deglycosylated channel proteins, whereas antibodies against GS2s only bound to the channel protein after enzymatic deglycosylation. Together, these results allow the refinement of folding models for the cGMP-gated channel and implicate Asn-327 as being the sole site of N-glycosylation.     

Binding of human tumor necrosis factor alpha to multimeric complementary peptides.

A peptide with binding properties for tumor necrosis factor (TNF alpha) sequence 144-157 has been designed, using a computer-assisted method able to create peptide sequences hydropathically complementary to a given sequence. The complementary peptide was synthesized in a multimeric form starting from an octadentate polylysine core, to facilitate its immobilization and to provide interaction multivalency. Once immobilized on a solid support to prepare an affinity column, it recognized the target TNF144-157 peptide selectively from crude peptide mixtures containing TNF fragments encompassing the entire TNF alpha sequence. Similar selectivity and specificity were shown for full-length recombinant TNF alpha, allowing its purification from crude Escherichia coli extracts. The octameric complementary peptide preserved its recognition properties for TNF alpha and biotinylated TNF alpha even after coating on microtiter plates. Competitive binding occurred with unlabeled TNF alpha in the range between 0.01 and 10 micrograms/ml, in the presence of detergent such as 0.05% Tween 20 and in the presence of 1% normal goat serum. The effect of complementary peptide multimerization was evidenced by its enhanced binding affinity for TNF alpha, which exists in solution as a trimer, while the target TNF[144-157] peptide was recognized with much lower strength. The dissociation constant for interaction with TNF alpha was close to 10 nM, allowing its easy detection by solid phase assays in concentrations as low as 10 pmol/ml.     

Immunoglobulin specificity of TG19318: a novel synthetic ligand for antibody affinity purification

A synthetic ligand [TG19318], able to mimic protein A in the recognition of the immunoglobulin Fc portion, has been previously identified in our laboratory through the synthesis and screening of multimeric combinatorial peptide libraries. In this study we have fully characterized its applicability in affinity chromatography for the downstream processing of antibodies, examining the specificity and selectivity for polyclonal and monoclonal immunoglobulins derived from different sources. Ligand specificity was broader than protein A, since IgG deriving from human, cow, horse, pig, mouse, rat, rabbit, goat and sheep sera, IgY obtained from egg yolk, and IgM, IgA and IgE were efficiently purified on TG19318 affinity columns. Adsorbed antibodies were conveniently eluted by a buffer change to 0.1 M acetic acid or 0.1 M sodium bicarbonate pH 9, with full retention of immunological properties. Monoclonal antibodies deriving from cell culture supernatants or ascitic fluids were also conveniently purified on TG19318 affinity columns, even from very diluted samples. The affinity constant for the TG19318-IgG interaction was 0.3 microM, as determined by optical biosensor measurements. Under optimized conditions, antibody purity after affinity purification was close to 95%, as determined by densitometric scanning of SDS-PAGE gels of purified fractions, and maximal column capacity reached 25 mg Ig/ml support. In vivo toxicity studies in mice indicated a ligand oral toxicity greater than 2000 mg kg-1 while intravenous toxicity was close to 150 mg kg-1. Validation of antibody affinity purification processes for therapeutic use, a very complex, laborious and costly procedure, is going to be simplified by the use of TG19318, which could reduce considerably the presence of biological contaminants in the purified preparation, a very recurrent problem when using recombinant or extractive biomolecules as affinity ligands.     

The solid phase in affinity chromatography: strategies for antibody attachment.

Antibodies (Ab) are commonly used in affinity chromatography (AC) as a versatile and specific means of isolating target molecules from complex mixtures. A number of procedures have been developed to immobilize antibodies on the solid matrix. Some of these methods couple the antibody via chemical groups that may be important for specific recognition of antigen, resulting in loss of functionality in a proportion of the antibodies. In other methods, the outcome of immobilization is coupling via unique sites in the Fc region of the antibody molecule, ensuring orientation of the antibody combining sites (Fab) towards the mobile phase. This review discusses the advantages and disadvantages of the various methods available for immobilization and outlines protocols for site-directed, covalent coupling of the antibody to the solid phase that essentially retains the activity of the antibody.     

A comprehensive system for protein purification and biochemical analysis based on antibodies to c-myc peptide.

The genomics revolution has created a need for increased speed and generality for recombinant protein production systems as well as general methods for conducting biochemical assays with the purified protein products. 9E10 is a well-known high-affinity antibody that has found use in a wide variety of biochemical assays. Here we present a standardized system for purifying proteins with a simple epitope tag based on c-myc peptide using an antibody affinity column. Antibodies with binding parameters suitable for protein purification have been generated and characterized. To purify these antibodies from serum-containing medium without carrying through contaminating immunoglobulin G, a peptide-based purification process was developed. A fluorescence polarization binding assay was developed to characterize the antigen-antibody interaction. Protein purification protocols were optimized using a fluorescein-labeled peptide as a surrogate "protein." Binding and elution parameters were evaluated and optimized and basic operating conditions were defined. Several examples using this procedure for the purification of recombinant proteins are presented demonstrating the generality of the system. In all cases tested, highly pure final products are obtained in good yields. The combination of the antibodies described here and 9E10 allow for almost any biochemical application to be utilized with a single simple peptide tag.     

Affinity purification of immunoglobulin M using a novel synthetic ligand

While monoclonal antibodies of the G class can be conveniently purified by affinity chromatography using immobilized protein A or G, even on a large scale, scaling up IgM purification still presents several problems, since specific and cost-effective ligands for IgM are not available. A synthetic peptide (TG19318), deduced from the screening of a combinatorial peptide library, was characterized previously by our group for its binding properties for immunoglobulins of the G class and its applicability as a synthetic ligand for polyclonal and monoclonal IgG purification, from sera or cell culture supernatants. In this study, we have examined the ligand recognition properties for IgM, immobilizing the synthetic peptide on different affinity supports and examining its ability to purify IgMs from serum, ascitic fluid and cell culture supernatants. TG19318 affinity columns proved useful for a very convenient one-step purification of monoclonal IgMs directly from crude sources, loading the samples on the columns equilibrated with saline buffers at pH values ranging from 5 to 7, and eluting adsorbed IgM by a buffer change to 0.1 M acetic acid or 0.05–0.1 M sodium bicarbonate, pH 9.0. Antibody purity after affinity purification was very high, close to 85–95%, as determined by densitometric scanning of sodium dodecyl sulfate–polyacrylamide gels of purified fractions, and by gel permeation analysis. Antibody activity was fully recovered after purification, as determined by immunoassays. Column capacity was related to the type of support used for ligand immobilization, and ranged from 2 to 8 mg of IgM/ml of support.     

Generation and refinement of peptide mimetic ligands for paratope-specific purification of monoclonal antibodies

Paratope-specific purification of antibodies has distinct advantages over conventional methods of antibody purification with respect to its capacity to isolate product of high purity and immunoreactivity. The present report addresses the problems of identifying peptide ligands for the purification of antibodies reactive with nonprotein antigens. Using an anti-steroid antibody as the model, a lead sequence that bound antibody was identified from a peptide phage display library. The minimum binding unit in this sequence was deduced using a series of truncated peptides synthesized on the heads of polyethylene pins. Replacement Net analysis of the minimum binding unit identified peptides with increased affinity for the antibody. The affinity-matured peptide mimotope bound antibody in solution. By molecular modeling the peptide was superimposable onto estrone-3-glucuronide localized in the crystal structure of the antibody binding pocket. In order to resolve problems of presentation posed by the reversal of orientation of the peptide on the affinity matrix compared with the pins, the mimotope peptide was synthesized in reverse sequence using d-amino acids. The resulting affinity matrix was effective for the purification of antibody. Eluted product demonstrated molecular homogeneity and high immunoreactivity. It is concluded that the combination of biological and chemical library techniques described provides a method for the generation and affinity maturation of mimotopes for antibodies against nonprotein antigens.     

Protein engineering to optimize recombinant protein purification

Genetic approaches have been used to facilitate purification of recombinant proteins, on both a large and a small scale. Based on developments in three different areas: (i) affinity chromatography; (ii) specific cleavage of fusion proteins and (iii) secretion of fusion proteins, a coupled expression/secretion system was designed. It was further improved by protein engineering. Using a synthetic DNA fragment, encoding two IgG-binding domains derived from staphylococcal protein A, gene products were secreted to the culture medium of Escherichia coli and purified with a one-step affinity procedure. The system has been used for large-scale production of biologically active human peptide hormones, to generate peptides for antibody production and to immobilize proteins on solid supports.     

Class, amounts, and affinities of anti-dinitrophenyl antibodies in chickens. II. Production of a restricted population of high affinity 7S antibodies by injection of antigen emulsified in adjuvant.

The response of chickens given a single intramuscular injection of maximally coupled dinitrophenylated-gamma-bovine beta-globulin in either Freund's complete (FCA) or incomplete (FIA) adjuvants was characterized by an initial synthesis of 7S and 17S antibodies followed by the exclusive and persistent production of 7S antibodies. The 17S antibodies were not detected either 3 to 4 weeks after a single injection or after an intravenous boost 16 months later. Injections of low doses of antigen in FCA induced the synthesis of 7S antibodies of high affinity at least by 4 months. Analyses of the Sips plots generated from equilibrium dialysis data indicated that a shift in the distribution of 7S antibody affinities occurred because of the production of a restricted population of high affinity antibodies. The changes in the binding properties of antibody during the immune response from chickens given antigen in FIA were less apparent, although qualitatively similar, to those found in birds given antigen in FCA. Three possibilities were presented to explain the effect of adjuvant on the class and affinity of the antibody: a) the requirement of a second signal for B cell differentiation, b) the presence of subpopulation of B cells, and c) somatic mutation events.     

幽门螺杆菌致病岛CagL重组抗原的可溶性表达及其多克隆抗体的制备和分析*

目的:利用原核表达和蛋白质纯化技术获得高纯度的幽门螺杆菌致病岛CagL重组抗原(rCagL),利用其制备anti-CagL多克隆抗体,并分析抗体的特异性。方法:通过生物信息学软件分析rCagL的抗原结构;利用PCR长片段DNA合成技术合成不含有信号肽序列的幽门螺杆菌致病岛CagL基因,将其插入表达质粒pCzn1中,构建重组质粒pCzn1-rCagL。然后,将pCzn1-rCagL转入大肠杆菌Arctic Express中,经IPTG诱导表达后,通过Ni-IDA镍离子亲和层析纯化重组抗原rCagL,利用Western blot鉴定rCagL与His标签抗体和Anti-H. pylori抗体的免疫反应性;最后,通过rCagL辅以弗氏佐剂免疫BALB/c小鼠,制备anti-CagL多克隆抗血清,通过ELISA方法分析抗血清的特异性。结果:生物信息学软件表明重组抗原rCagL具有较好的抗原性质;重组质粒pCzn1-rCagL经双酶切和基因测序等技术鉴定,证实rCagL核苷酸序列与理论序列完全一致;基因工程菌株pCzn1-rCagL/Arctic Express在低温11℃条件经IPTG诱导表达。 SDS-PAGE实验结果证实:rCagL可实现相对高效地可溶性蛋白表达,可溶性蛋白约占包涵体的62.07%。经Ni-IDA亲和层析柱纯化,可获得高纯度rCagL,纯度约为96.6%。Western blot结果证实:重组抗原rCagL可特异性与His标签抗体和Anti-H. pylori抗体结合。ELISA结果证实:经rCagL免疫小鼠制备的多克隆抗体anti-CagL可特异性识别rCagL和H. pylori裂解物,具有较高的抗体特异性。结论:重组抗原rCagL在低温条件下可实现可溶性表达,经纯化可获得高纯度抗原蛋白;rCagL具有较好的抗原性,制备的多克隆抗体具有较好的免疫特异性,为发展H. pylori相关诊断试剂奠定了实验基础。