Monitoring of mouse immunoglobulin G by flow-injection analytical affinity chromatography

A flow-injection analytical affinity chromatographic (FIAAC) system was developed for the on-line monitoring of mouse immunoglobulin G (IgG). Protein A or anti-mouse IgG antibodies immobilized on oxirane beads were filled in a miniature column. The IgG-containing samples and standards were passed through the column and detected fluorimetrically after elution with citrate buffer (pH 3 or 2.5). The on-line monitoring of mouse IgG 2a during a 7-day cultivation of hybridoma cells in a perfusion reactor by FIAAC is presented. A chemical barrier was used to prevent contamination of the reactor from the FIAAC.     

Molecular recognition of protein surfaces: high affinity ligands for the CBP KIX domain

Potent and specific inhibitors of protein.protein interactions have potential both as therapeutic compounds and biological tools, yet discovery of such molecules remains a challenge. Our laboratory has recently described a strategy, called protein grafting, for the identification of miniature proteins that bind protein surfaces with high affinity and specificity and inhibit the formation of protein.protein complexes. In protein grafting, those residues that comprise a functional alpha-helical binding epitope are stabilized on the solvent-exposed alpha-helical face of the small yet stable protein avian pancreatic polypeptide (aPP). Here we use protein grafting in combination with molecular evolution by phage display to identify phosphorylated peptide ligands that recognize the shallow surface of CBP KIX with high nanomolar to low micromolar affinity. Furthermore, we show that grafting of the CBP KIX-binding epitope of CREB KID onto the aPP scaffold yields molecules capable of high affinity recognition of CBP KIX even in the absence of phosphorylation. Importantly, both classes of designed ligands exhibit high specificity for the target CBP KIX domain over carbonic anhydrase and calmodulin, two unrelated proteins that bind hydrophobic or alpha-helical molecules that might be encountered in vivo.     

Multivalent gold glycoclusters: high affinity molecular recognition by bacterial lectin PA-IL

Multivalent protein-carbohydrate interactions are involved in the initial stages of many fundamental biological and pathological processes through lectin-carbohydrate binding. The design of high affinity ligands is therefore necessary to study, inhibit and control the processes governed through carbohydrate recognition by their lectin receptors. Carbohydrate-functionalised gold nanoclusters (glyconanoparticles, GNPs) show promising potential as multivalent tools for studies in fundamental glycobiology research as well as biomedical applications. Here we present the synthesis and characterisation of galactose functionalised GNPs and their effectiveness as binding partners for PA-IL lectin from Pseudomonas aeruginosa. Interactions were evaluated by hemagglutination inhibition (HIA), surface plasmon resonance (SPR) and isothermal titration calorimetry (ITC) assays. Results show that the gold nanoparticle platform displays a significant cluster glycoside effect for presenting carbohydrate ligands with almost a 3000-fold increase in binding compared with a monovalent reference probe in free solution. The most effective GNP exhibited a dissociation constant (K(d)) of 50 nM per monosaccharide, the most effective ligand of PA-IL measured to date; another demonstration of the potential of glyco-nanotechnology towards multivalent tools and potent anti-adhesives for the prevention of pathogen invasion. The influence of ligand presentation density on their recognition by protein receptors is also demonstrated.     

Nonaqueous affinity capillary electrophoresis investigation of small molecule molecular recognition

The conditional binding constants for a bis-guanidinium-like receptor and a series of dicarboxylate ligands have been determined in two buffer/solvent systems, namely 25 mM ammonium acetate/1% acetic acid in acetonitrile/methanol (7:3 v:v) and 30 mM N-methyl morpholine/15 mM methanesulfonic acid in acetonitrile/methanol (9:1 v:v). The latter buffer has not been applied before in capillary electrophoresis. The binding constants in both solvent systems decrease as the dicarboxylate length increases. The binding constants are larger in the less competitive N-methyl morpholine buffer. The dicarboxylates associate only weakly with a dicationic analog of the receptor, p-xylyl trimethylammonium, which is not a hydrogen bond donor.     

Bioaffinity chromatography: synergy between interactive chromatography and molecular recognition for the separation and analysis of macromolecules

Affinity chromatography, commonly regarded as an integral tool in macromolecular separation sciences, also provides an analytical method to study structure-function relationships of macromolecular interaction processes and to design recognition molecules. The latter, as found recently for the case of antisense peptides, may be useful as affinity agents in immobilized forms to effect new types of biomolecular separation.     

Study of the molecular interaction between lysozyme and heparin and application in affinity chromatography

Lysozyme interacts with heparin by giving a stable and insoluble complex that dissociates at increased ionic strength. The formation of the complex and its stability towards pH and sodium chloride concentration were studied in solution and in a heterogeneous phase by means of heparin immobilized on agarose beads. The two sets of results are in agreement and show that the interaction between heparin and lysozyme is essentially ionic. The practical consequence is the possibility of developing a one-step method of purification of egg-white lysozyme by affinity chromatography with a particularly high yield of biochemical activity.     

The development and application of guidance on EQ of analytical instruments: High performance liquid chromatography

 This paper describes the development and application of guidance on EQ (EQ) of high performance liquid chromatography instruments. EQ is a formal process that provides documented evidence that an instrument is fit for its intended purpose and kept in a state of maintenance and calibration consistent with its use.     

Design and synthesis of immobilized Tamiflu analog on resin for affinity chromatography

A resin linked with the Tamiflu core was synthesized by modifying our original synthetic route of oseltamivir phosphate (Tamiflu). The prepared resin bound to the influenza virus enzyme neuraminidase, the main target of Tamiflu. The immobilized Tamiflu analog will be useful for isolating and identifying presumed endogenous vertebrate proteins that interact with Tamiflu, which might relate to the abnormal behavior exhibited by some influenza patients treated with Tamiflu.     

Combining weak affinity chromatography, NMR spectroscopy and molecular simulations in carbohydrate-lysozyme interaction studies

By examining the interactions between the protein hen egg-white lysozyme (HEWL) and commercially available and chemically synthesized carbohydrate ligands using a combination of weak affinity chromatography (WAC), NMR spectroscopy and molecular simulations, we report on new affinity data as well as a detailed binding model for the HEWL protein. The equilibrium dissociation constants of the ligands were obtained by WAC but also by NMR spectroscopy, which agreed well. The structures of two HEWL-disaccharide complexes in solution were deduced by NMR spectroscopy using (1)H saturation transfer difference (STD) effects and transferred (1)H,(1)H-NOESY experiments, relaxation-matrix calculations, molecular docking and molecular dynamics simulations. In solution the two disaccharides β-d-Galp-(1→4)-β-D-GlcpNAc-OMe and β-D-GlcpNAc-(1→4)-β-D-GlcpNAc-OMe bind to the B and C sites of HEWL in a syn-conformation at the glycosidic linkage between the two sugar residues. Intermolecular hydrogen bonding and CH/π-interactions form the basis of the protein-ligand complexes in a way characteristic of carbohydrate-protein interactions. Molecular dynamics simulations with explicit water molecules of both the apo-form of the protein and a ligand-protein complex showed structural change compared to a crystal structure of the protein. The flexibility of HEWL as indicated by a residue-based root-mean-square deviation analysis indicated similarities overall, with some residue specific differences, inter alia, for Arg61 that is situated prior to a flexible loop. The Arg61 flexibility was notably larger in the ligand-complexed form of HEWL. N,N'-Diacetylchitobiose has previously been observed to bind to HEWL at the B and C sites in water solution based on (1)H NMR chemical shift changes in the protein whereas the disaccharide binds at either the B and C sites or the C and D sites in different crystal complexes. The present study thus highlights that protein-ligand complexes may vary notably between the solution and solid states, underscoring the importance of targeting the pertinent binding site(s) for inhibition of protein activity and the advantages of combining different techniques in a screening process.     

Combined use of lectin affinity chromatography and endo-beta-galactosidase to study polylactosamine sequences isolated from haemopoietic cell surfaces

The trypsin-sensitive glycopeptides from cell surfaces of a multipotential murine haemopoietic cell line (DE) have been studied using serial lectin affinity chromatography on columns of immobilized lentil lectin (LCA), concanavalin A (Con A), and wheat-germ agglutinin (WGA). WGA-binding material consisted of glycopeptides that failed to bind to LCA and Con A. Step elution from the WGA-column with 0.01-, 0.1-, 0.5- and 1.0 M N-acetyl-D-glucosamine yielded four affinity classes of glycopeptide (WGA-W, WGA-I, WGA-S and WGA-SS respectively). WGA-W, WGA-I and WGA-S contained both alkali-stable (N-linked) and alkali-labile (O-linked) carbohydrate on high molecular weight glycopeptides. The WGA-SS fraction contained only N-linked carbohydrate. N-linked glycopeptides isolated from each WGA-binding class differed in molecular size, relative N-acetylneuraminic acid content and affinity for Ricinus communis 120 agglutinin. endo-beta-Galactosidase digestion showed that these glycopeptides contained polylactosamine-type glycans. Gel filtration profiles of the enzyme treated materials were different for each WGA-binding population suggesting variation in branching patterns and/or substitution with fucose residues. Affinity chromatography has shown that the WGA binding molecules are the major glycopeptide group at DE cell surfaces.     

Adsorbents and columns in analytical high-performance liquid chromatography: a perspective with regard to development and understanding

A brief historical survey is presented on the evaluation of silica adsorbents in analytical HPLC. The theory of analytical HPLC is mostly still being based on the height equivalent to a theoretical plate concept and the van Deemter equation that was derived from gas phase adsorption involving a linear adsorption isotherm and fast mass transfer kinetics. One can obviously wonder whether the use of the van Deemter equation is relevant and valid for the evaluation of the performance of HPLC systems, where most often the liquid solutes involve charged molecules in electrolytes and in very many cases the adsorbates are macromolecules having diffusion coefficients of small magnitude. Instead of the van Deemter equation, a multi-scale modelling approach that involves microscopic and macroscopic dynamic non-linear mass-transfer-rate models should be employed. Furthermore, advanced experimental methods for the characterisation of porous media and the distribution of the density of immobilised active sites (e.g., ligands) on surfaces as well as microscopic pore-network modelling and molecular dynamics modelling and simulation methods could be used for the design of novel adsorbents whose porous structures and immobilised active sites would provide effective mass transport and adsorption rates for realising efficient separations as well as high dynamic capacities when larger throughputs are required.     

Interactions and uses of antisense peptides in affinity technology.

Antisense peptides, amino acid sequences encoded in the antisense strand of DNA, can interact with significant affinity and selectivity with their corresponding sensepeptides. Experimentally, sense-antisense peptide recognition has been observed repeatedly. However, skepticism about the biological relevance of this phenomenon has persisted. This is due in part to the unexpected and somewhat couterintutive nature of the interaction as well as to its non-universality as an empirical observation. Nonetheless, antisense peptides in several cases investigated so far have been used as immobilized ligands for the successful affinity chromatographic separation of native (sense) peptides and proteins. For example, immobilized antisense peptides corresponding to Arg8-vasopressin (AVP) have been used to separate vasopressin from oxytocin chromatographically as well as to affinity capture AVP-receptor complex. These results, together with improved understanding of the general features of amino acid sequence which drive antisense-sense peptide interactions as well as new ideas for making antisense peptides chimeras, are beginning to suggest improved ways to make antisense-related peptides as affinity agents for separation as well as for other biotechnology applications.     

A novel support with artificially created recognition for the selective removal of proteins and for affinity chromatography

Summary Acrylamide and N,N-methylenebisacrylamide were copolymerized in the presence of a protein to form a gel which was pressed through a sieve. The gel particles obtained were packed into a chromatographic tube. The experimental conditions for the polymerization are such that the pores of the gel particles are large enough to permit the protein to diffuse out of the particles, so that the entrapped protein can be removed from the bed by washing with an aqueous solution. However the interaction with the matrix is so strong that the protein can be desorbed only by a buffer containing 0.5 M sodium chloride or by a 10% solution of acetic acid containing 10% SDS. When a sample containing the protein present during the polymerization was applied to the column along with other proteins this protein was the only one adsorbed. The technique worked selectively with hemoglobin, cytochrome C and transferrin.     

Pattern recognition strategies for molecular surfaces: III. Binding site prediction with a neural network

An algorithm for the identification of possible binding sites of biomolecules, which are represented as regions of the molecular surface, is introduced. The algorithm is based on the segmentation of the molecular surface into overlapping patches as described in the first article of this series.1 The properties of these patches (calculated on the basis of physical and chemical properties) are used for the analysis of the molecular surfaces of 7821 proteins and protein complexes. Special attention is drawn to known protein binding sites. A binding site identification algorithm is realized on the basis of the calculated data using a neural network strategy. The neural network is able to classify surface patches as protein-protein, protein-DNA, protein-ligand, or nonbinding sites. To show the capability of the algorithm, results of the surface analysis and the predictions are presented and discussed with representative examples.     

First immobilization of a glycoluril-derived molecular clip on Merrifield resin: facile separation of dihydroxybenzenes by affinity chromatography

A practical method for the separation and purification of dihydroxybenzenes from phenol-dihydroxybenzene, methoxyphenol-dihydroxybenzene, and isomeric dihydroxybenzene mixtures was developed on the basis of affinity chromatography using a functionalized Merrifield resin. The resin was obtained by immobilization of a glycoluril-derived clip on Merrifield resin. This recyclable resin was repeatedly used for convenient and rapid separation of dihydroxybenzenes from the above-mentioned mixtures.     

Design of highly enantioselective organocatalysts based on molecular recognition

[reaction: see text] Various organocatalysts have been designed based on molecular recognition to catalyze the asymmetric direct aldol reaction of ketones with aryl and alkyl alpha-keto acids, affording beta-hydroxyl carboxylic acids with a tertiary stereogenic center with excellent enantioselectivities of up to 98% ee. A linear effect was observed for the reaction, demonstrating a single molecule of the catalyst involved in the catalysis.     

Combination of chelating behaviour with molecular recognition as interaction for ligand exchange chromatography

A novel chelating resin was synthesized, composed of chemically bonded glycinocyclodextrin (S-CD-G) to which silica gel was added as matrix and silanes with amino groups as spacer. It showed efficient complexation with transition metal cations. In this report the copper and zinc resin complexes were investigated for application as stationary phases for the separation of substituted phenol isomers. The results revealed that the copper resin complex has a high potential for this application.