Preparative and analytical affinity chromatography of neurophysins on methionyl-tyrosyl-phenylalanyl-aminohexyl-agarose

Methionyl-tyrosyl-phenylalanyl-ω-aminohexyl-agarose was synthesized and shown to be suitable for both the affinity chromatographic purification of neurophysins and the measurement of the ligand binding parameters of these proteins by quantitative affinity chromatography. Bovine neurophysin I binds to the tripeptidyl matrix in 0.4 m ammonium acetate, pH 5.7, conditions under which no binding occurs with the parent ω-aminohexyl-agarose. Subsequent elution can be effected with 0.2 m acetic acid. The affinity matrices obtained have capacities for neurophysin of up to 4 mg/ml gel bed volume and therein provide for the convenient purification of the neurophysins by a two-step buffer-acid elution. [Carbamoyl-¹⁴C]neurophysin I also binds to the ligand-agarose matrix. Using this labeled protein, competitive elution analysis was performed by one-step elution of zones of protein with the binding buffer in the presence of varying amounts of soluble competitive ligand, lysine vasopressin. The characteristic decrease of elution volume of labeled protein with increasing soluble, competing ligand concentration indicates that the affinity matrix interacts biospecifically with neurophysin. This analysis allows the binding affinities for both soluble vasopressin and immobilized tripeptide ligand to be quantitated.     

Characterization of HIV-1 p24 self-association using analytical affinity chromatography.

Analytical affinity chromatography (AAC) was used to detect and quantitate the self-association of p24gag, the major structural capsid protein of human immunodeficiency virus (HIV-1). p24gag was immobilized on a hydrophilic polymer (methacrylate) chromatographic support. The resulting affinity column was able to interact with soluble p24, as judged by the chromatographic retardation of the soluble protein upon isocratic elution under nonchaotropic binding conditions. The variation of elution volume with soluble protein concentration fit to a monomer-dimer model for self-association. The soluble p24-immobilized p24 association process was observed using both frontal and zonal elution AAC at varying pH values; the dissociation constant was 3-4 x 10(-5) M at pH 7. That p24 monomer associates to dimers was determined in solution using analytical ultracentrifugation. The solution Kd was 1.3 x 10(-5) M at pH 7. AAC in the zonal elution mode provides a simple and rapid means to screen for other HIV-1 macromolecules that may interact with p24 as well as for modulators, including antagonists, of HIV p24 protein assembly.     

Quantitative reappraisal of general expressions for multivalent protein binding in subunit-exchange chromatography

Quantitative expressions have been derived for bivalent equilibria with immobilized ligand systems and for the equilibria for an immobilized protein whose self-association is modified by binding with a soluble ligand, as analyzed by affinity chromatography. These general expressions have been applied in a reexamination of multivalency in the affinity chromatography of antibodies, as reported by Eilat and Chaiken (Biochemistry 18 (1979) 790) and also to studies of neurophysin-peptide hormone interactions using glass matrices reported by Swaisgood and Chaiken (Biochemistry 25 (1986) 4148).     

Analysis of ribonuclease-nucleotide interactions by quantitative affinity chromatography.

Quantitative affinity chromatography on uridine-5'-(Sepharose-4-aminophenylphosphoryl)-2'(3')-phosphate was developed for the study of binding of ribonuclease species to nucleotide ligands. Elution of the native species ribonuclease-A and -S on the afffinity matrix in 0.4 M ammonium acetate, pH 5.2, containing various amounts of the soluble competing ligand 2'-cytidine monophosphate, reveals an inverse response of elution volume to concentration of soluble ligand. This response conforms to behavior expected for the competing binding equilibria enzyme-soluble ligand and enzyme-insoluble ligand. A-NALYSIS OF ELUTION DATA ALLOWS CALCULATION OF KI and KIM, the dissociation constants, respectively, for the soluble and insoluble protein-ligand complexes. The values of these chromatographically derived constants are similar to values of dissocation constants determined in solution by kinetics of inhibition by 2'-cytidine monophosphate and uridine-5'-(j-aminophenylphosphoryl)-2'(3')-phosphate. Successful competitive elution experiments with [p-F-Phe8]semisynthetic ribonuclease-S' and individual elution trials for [4-F-His12]semisynthetic ribonuclease-S' indicate the utility of the quantitative affinity chromatographic technique for determination of ligand binding properties of ribonuclease derivatives, including inactive species. Nonbiospecific aspects of the interaction of ribonuclease with the affinity matrix in ammonium acetate buffers of concentrations 0.1 M and below were noted, delinating limits of conditions allowing the biospecificity needed for ligand-binding analyses by competitive elution. The dependence of ribonuclease competitive elution behavior on the amount of protein eluted also was examined and related to theoretical considerations in the quantitative application of affinity chromatography.     

Quantitative affinity chromatography of alpha-chymotrypsin

Affinity chromatography on a column of 4-phenylbutylamine, immobilized on succinylated polyacrylic hydrazide agarose, has been employed to study binding of ligands to α-chymotrypsin. In contrast to earlier studies of competitive elution phenomena, where an added soluble ligand interferes with enzyme binding to an affinity matrix, benzyloxycarbonyl derivatives of aromatic acids have been shown to facilitate binding of chymotrypsin to this matrix. This behavior has been analyzed in terms of an expanded binding scheme for affinity chromatography including the formation of a ternary complex (α-chymotrypsin · benzyloxycarbonyl-amino acid · 4-phenylbutylamine · matrix) where the soluble ligand and immobilized ligand bind to different sites. Equations to describe the phenonema have been derived and utilized to quantitate equilibrium constants for dissociation of the binary and ternary complexes. Benzyloxycarbonyl-Ala-Ala was found to promote earlier elution of the enzyme from its affinity matrix. Other ligands known to bind to the active site do not alter the binding to the 4-phenylbutylamine affinity matrix. These results illustrate the conclusion that binding of a small molecule can alter affinity retention in positive, negative, or neutral modes. This suggests that affinity chromatography could be “fine-tuned” by appropriate selection of cosolutes and illustrates the value of relatively weakly binding affinity matrices in enzyme studies.     

Co-operative binding interactions in affinity chromatography: Theoretical considerations

A theoretical relationship has been developed to allow the effect of free ligand concentration on the capacity of an affinity Chromatography matrix to be determined where the protein adsorbed shows co-operative binding. Computer simulations using literature values for association constants show that under optimal conditions resin capacity can be increased significantly in the presence of a small but finite concentration of free ligand. The model also allows prediction of the soluble ligand concentration required for biospecific elution. The results obtained suggest the possibility of a new elution technique, "reverse biospecific elution," that reduces the amount of free ligand required to effect elution.     

Evaluation of quantitative affinity chromatography by comparison with kinetic and equilibrium dialysis methods for the analysis of nucleotide binding to staphylococcal nuclease.

The elution of staphylococcal nuclease on thymidine 3'-(p-Sepharose-aminophenyl phosphate) 5'-phosphate (nucleotide ligand of nuclease covalently bound to Sepharose 4B) was studied in the presence of a variety of soluble nucleotide ligands. The elution volumes of nuclease vary proportionally with matrix-bound ligand concentration (at constant soluble ligand concentration), inversely with soluble ligand concentration (at constant matrix-bound ligand concentration), and inversely with dissociation constant of soluble ligand (at constant concentrations of soluble and matrix-bound ligand). The variation of elution volume was related to an expression which described the competition of soluble and matrix-bound ligand for nuclease binding. Using this expression, values for dissociation constants were derived for nucleotide ligands in both the soluble and bound form. The values for soluble ligand were found to correspond closely to those obtained by either equilibrium dialysis or kinetics of inhibition of nuclease activity. Furthermore, a close correspondence was found between the values of dissocation constants for matrix-bound and soluble thymidine 3'-(p-aminophenyl phosphate) 5'-phosphate, thus defining the interaction of nuclease with the matrix-bound ligand as a process quite similar to that occurring in solution.     

Predicting the elution behavior of proteins in affinity chromatography on non-porous particles.

Affinity chromatography on non-porous particles of microsize is particularly useful for the rapid analysis and micropreparative separation of proteins. The elution behavior of proteins in an affinity column packed with non-porous copolymerized particles of styrene, methyl methacrylate and glycidyl methacrylate was investigated both theoretically and experimentally, using the lysozyme-Cibacron Blue 3G-A affinity system. Equations used to predict the elution profiles, resulting from the elution by increasing the ionic strength (NaCl concentration) in the mobile phase, were obtained. The maximum adsorbate concentration, desorption rate constant and equilibrium constant under elution conditions were determined by matching experimental data with predicted elution profiles. Based on the parameters determined at a flow-rate of 0.5 ml/min and with 1 M NaCl in the elution buffer, the model equations could predict the elution profiles for other experimental runs, where different flow-rates and sodium chloride concentrations were used. Both the experimental and predicted results revealed that the affinity interaction kinetics are not significantly influenced by the flow-rate and, hence, the film mass transfer. To elute bound lysozyme from immobilized dye ligand, a higher value of the ionic strength leads to a faster elution and a sharper elution peak. The influence of elution conditions on the kinetic and thermodynamic parameters and, consequently, on the elution peak profiles was evaluated. The model equations can also predict the behavior of protein elution from an affinity column by changing the pH of the mobile phase, according to a previous study.     

Affinity chromatography of trypsin and related enzymes. V. Basic studies of quantitative affinity chromatography.

A detailed study of the quantitative affinity chromatography of trypsin [EC 3.4.21.4] is reported here. Frontal chromatography using an enzyme solution of very low concentration on an affinity adsorbent gave the dissociation constant of the enzyme-immobilized ligand complex (Kd). Kd values determined under various conditions enabled us to discuss in detail the interaction of trypsin and affinity adsorbents (mainly Gly-Gly-Arg Sepharose). The pH dependence of Kd was consistent with that of the interaction of trypsin and product-type compounds. The effects of changes in temperature, ionic strength, dielectric constant, etc., were also studied. The Ki values of soluble competitive inhibitors can be determined by analysis of their effects on the elution volume of the enzyme. The values obtained were in good agreement with those obtained by kinetic analysis. The present method proved to be useful as a general procedure to investigate the interaction of a protein and a specific ligand.     

Enantioselective affinity chromatography of a chiral drug by crystalline and carrier-bound antibody fab fragment

An antibody Fab fragment, ENA5His, capable of enantioselective affinity chromatographic separation of a chiral drug, finrozole, was stabilized against organic solvents by chemical cross-linking. High concentration of methanol is needed to release the bound drug from the antibody fragment. However, in native form the antibody fragment is unstable at these conditions. We used cross-linked protein crystal technology to stabilize the antibody fragment molecule. Glutaraldehyde cross-linked ENA5His crystals (CLAC) packed in a column separated pure enantiomers from the racemic mixture of the drug. CLAC was totally stable at the elution conditions, enabling reuse of the immunoaffinity column packed with CLAC. However, the specific drug enantiomer binding capacity of CLAC was only 50% of the corresponding capacity of immobilized ENA5His. We were also able to cross-link immobilized ENA5His by glutaraldehyde. This method produced a protein matrix with high activity and stability in the elution conditions.     

Structural and thermodynamic basis of affinity in anti-dinitrophenyl antibody.

The thermodynamic quantities of the anti-dinitrophenyl antibody-hapten interaction are reported for rabbit, goat, and guinea pig antibodies. Rabbit and goat antibodies had similar exothermic enthalpy changes for their reaction with 2,4-dinitrophenyl-L-lysine (-13.9 and -14.8 kcal/mol, respectively). The enthalpy change with guinea pig antibody was much less exothermic (-8.7 kcal/mol), and this value was the same for two guinea pig antibody preparations that differed in affinity by almost two orders of magnitude. A heterogeneous goat anti-dinitrophenyl antibody preparation was fractionated on a molecular sieve column in the presence of a bivalent ligand, a procedure that has been reported to separate antibodies according to differences in the depth of interaction with the ligand. The relationship of these differences in apparent site depth to changes in interactions with the hapten tail was examined by comparing the affinities of various fractions for two haptens. The results show that the presumed deeper sites have stronger interactions with the hapten tail. These studies suggest that the heterogeneity of anti-dinitrophenyl antibodies with respect to affinity results from differences in entropy driven lysyl side-chain interactions which arise from a heterogeneity in antigen binding site depth.     

Beta-glycosylamidine as a ligand for affinity chromatography tailored to the glycon substrate specificity of beta-glycosidases

An affinity adsorbent for beta-glycosidases has been prepared by using beta-glycosylamidine as a ligand. beta-Glucosylamidine and beta-galactosylamidine, highly potent and selective inhibitors of beta-glucosidases and beta-galactosidases, respectively, were immobilized by a novel one-pot procedure involving the addition of a beta-glycosylamine and 2-iminothiolane.HCl simultaneously to a matrix modified with maleimido groups via an appropriate spacer to give an affinity adsorbent for beta-glucosidases and beta-galactosidases, respectively. This one-pot procedure enables various beta-glycosylamidine ligands to be formed and immobilized conveniently according to the glycon substrate specificities of the enzymes. A crude enzyme extract from tea leaves (Camellia sinensis) and a beta-galactosidase from Penicillium multicolor were chromatographed directly on each affinity adsorbent to give a beta-glucosidase and a beta-galactosidase to apparent homogeneity in one step by eluting the column with glucose or by a gradient NaCl elution, respectively. The beta-glucosidase and beta-galactosidase were inhibited competitively by a soluble form of the corresponding beta-glycosylamidine ligand with an inhibition constant (K(i)) of 2.1 and 0.80 microM, respectively. Neither enzyme was bound to the adsorbent with a mismatched ligand, indicating that the binding of the glycosidases was of specific nature that corresponds to the glycon substrate specificity of the enzymes. The ease of preparation and the selective nature of the affinity adsorbent should promise a large-scale preparation of the affinity adsorbent for the purification and removal of specific glycosidases according to their glycon substrate specificities.     

Effect of microsphere binding site density on the apparent affinity of an interaction partner.

BACKGROUND: Flow cytometric microsphere-based binding assays can be used to measure molecular interactions with high sensitivity. We have used multiplexed microsphere technology to explore the effect that binding site density has on the apparent affinity of a soluble interaction partner. METHODS: The interaction of a nuclear receptor, peroxisome proliferator-activated receptor gamma ligand binding domain (PPARgamma LBD), with a synthetic peptide derived from a nuclear receptor coactivator protein, PPARgamma coactivator-1 alpha (PGC-1alpha), is the interacting system being studied. The density of this peptide coupled to fluorescently unique microsphere populations is varied by co-incubating the biotinylated peptide and avidin-coated microsphere populations with increasing the amounts of free D-biotin. The discrete-density peptide-coupled microsphere populations are combined to conduct a multiplexed binding experiment with Alexa 532-labeled PPARgamma LBD, in the absence or presence of a small molecule ligand. RESULTS: As the immobilized binding site density of PGC-1alpha peptide on fluorescent microspheres is increased the measured apparent affinity for PPARgamma LBD is increased. CONCLUSIONS: The density of binding sites immobilized to a surface has a pronounced effect on the apparent affinity for soluble binding partners. By controlling and varying the binding site density it is possible to increase the sensitivity of an interaction assay. In multiplexed assay formats it should be possible to normalize intrinsically unequal binding interactions by individually optimizing the binding site density of the immobilized interaction partner. However, to quantitatively measure intrinsic affinities of molecular interactions, low binding site densities are required and multivalent reagents must be avoided.     

High-performance analytical applications of immobilized metal ion affinity chromatography

The separation of three sets of standard protein mixtures on a high-performance immobilized metal ion affinity chromatography (HP-IMAC) column by elution with linear gradients of imidazole is described. The affinity of the test proteins for the immobilized metal ions follows the order Cu2+ greater than Ni2+ greater than Zn2+. The iminodiacetic acid-Cu2+ column gives the best resolution of all three protein mixtures and is the only immobilized metal ion column that can be used for elution of absorbed proteins with a decreasing pH gradient. An application of HP-IMAC for the separation of monoclonal IgG from mouse ascites fluid is also outlined. This versatile separation method is thus suitable for both analytical and preparative separations of proteins and peptides resulting in high recoveries and good reproducibility. The leakage of immobilized metal ions from the TSK gel chelate-5PW is apparent if the column is eluted by buffers containing low concentrations of (i) glycine or (ii) primary amines at round neutral pH. Considerable amounts of immobilized Zn2+ and Ni2+ ions also leak from the column by washing with buffers of pH 4.5 or lower. However, all three immobilized metal ions are stable toward exposure to low concentrations of imidazole (up to 50 mM) in phosphate buffers between pH 6.5 and 8.0. Adsorbed proteins could thus be eluted conveniently by using linear gradients of imidazole to give reproducible results. Moreover, this elution procedure made it possible to use the IMAC columns for repeated runs without the need for regeneration and recharging of the columns with fresh metal ions after each use.     

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     

New approach in evaluating affinity of bivalent antibodies by the method of surface plasmon resonance. Theory

Theoretical aspects of the affinity evaluation for the interaction between bivalent receptors (or antibodies) and corresponding ligands (or antigens) are considered. It was shown that the ligand presence in the solution at the stage when the receptor dissociation occurs leads to the increase of the affinity evaluation accuracy. We demonstrated that the analysis of the dissociative curve of the receptor from the chip is not necessary for affinity determination; the analysis of associative curve is sufficient for this purpose. We also suggested a new approach for evaluating the affinity of bivalent receptors (or antibodies) when these reagents are present in the studied solution and the correspondent ligand (or antigen) is immobilized on the chip.     

Quantitative evaluation of solution equilibrium binding interactions by affinity partitioning: application to specific and nonspecific protein-heparin interactions

A variation of the quantitative affinity chromatography (QAC) method of Winzor, Chaiken, and co-workers for the analysis of protein-ligand interactions has been developed and used to characterize sequence-specific and nonspecific protein-heparin interactions relevant to blood coagulation. The method allows quantitation of the binding of two components, A and B, from the competitive effect of one component, B, on the partitioning of the other component, A, between an immobilized acceptor phase and solution phase at equilibrium. Under the conditions employed, the differences in total A concentrations yielding an equivalent degree of saturation of the immobilized acceptor in the absence and presence of B defines the concentration of A bound to B in solution, thereby enabling conventional Scatchard or nonlinear least-squares analysis of the A-B equilibrium interaction. Like the QAC method, quantitation of the competitor interaction does not depend on the nature of the affinity matrix interaction, which need only be described empirically. The additional advantage of the difference method is that only the total rather than the free competitor ligand concentration need be known. The method requires that the partitioning component A be univalent, but allows for multivalency in the competitor, B, and can in principle be used to study binding interactions involving nonidentical, interacting, or nonspecific overlapping sites. Both the binding constant and the stoichiometry for the specific antithrombin-heparin interaction as well as the apparent binding constant for the nonspecific thrombin-heparin interaction at low thrombin binding densities obtained using this technique were in excellent agreement with values determined using spectroscopic probes.     

Antibody-directed liposomes. Determination of affinity constants for soluble and liposome-bound antifluorescein

We have used the binding of liposomes conjugated with antifluorescein antibody specific for fluorescein isothiocyanate-modified erythrocytes as a model for multivalent antigen-antibody interactions. We examined a series of liposome preparations which were conjugated to between 0 and 332 active antibodies per liposome. The antigen binding capacity and mean intrinsic affinity of the soluble and conjugated antibody were determined by fluorescence quenching of carboxyfluorescein. Liposome-cell interaction data were fitted with a Scatchard-type equation. Functional affinity of liposomes for cells was up to 1000-fold greater than the intrinsic affinity of the antibody for soluble ligand. Analysis for binding at high cell concentrations revealed that liposome-induced cell agglutination reduces the number of available binding sites per cell.     

One step purification of D-galactose and L-arabinose kinases from Phaseolus aureus seedlings by ATP-sepharose affinity chromatography.

8-β-Aminoethylthio-adenosine triphosphate has been synthesized as an ATP derivative and was successfully coupled with N-hydroxysuccinate ester sepharose. The bounded ATP analog can be used on affinity chromatography as a specific substrate ligand for the purification of kinases by means of enzyme substrate binding interaction. Both solubilized and membrane-bound d-galactokinase and l-arabinokinase extracted from mung bean seedlings were immobilized on the ATP-sepharose gel and purified by elution either with a high ionic strength solution (1 m NaCl) or high concentration of a second substrate.     

Peptide heterodimers for molecular imaging

One main issue with peptide-based molecular imaging probes is their relatively low tumor affinity and short retention time. To improve peptide binding affinity, multivalency approach has been introduced. Traditionally, this approach involves the use of peptide homodimers or homomultimers in which peptide ligands of the same type are constructed with suitable linkers. Recently, a new approach using peptide heterodimers has emerged as a promising method for targeting multi-receptor over-expressed tumor cells. Significant affinity enhancements have been observed with peptide heterodimers compared with their parent peptide monomers. In a peptide heterodimer, two different peptide ligands capable of targeting two different receptors are covalently linked. The binding modes of peptide heterodimers can be monovalent or bivalent depending on whether simultaneous binding of two ligands can be achieved. Increased local ligand concentration and improved binding kinetics contribute to enhanced binding in both monovalent- and bivalent binding modes, while multivalency effect also plays an important role in bivalent binding mode. As many tumors overexpress multiple receptors, more peptide heterodimer-based molecular imaging probes are expected to be developed in future. This review article will discuss the peptide homodimers and heterodimers for molecular imaging with special emphasis on peptide heterodimers.