Novel surface-based methodologies for investigating GH11 xylanase-lignin derivative interactions.

The recalcitrance of lignocellulose to bioprocessing represents the core problem and remains the limiting factor in creating an economy based on lignocellulosic ethanol production. Lignin is responsible for unproductive interactions with enzymes, and understanding how lignin impairs the susceptibility of biomass to enzymatic hydrolysis represents a significant aim in optimising the biological deconstruction of lignocellulose. The objective of this study was to develop methodologies based on surface plasmon resonance (SPR), which provide novel insights into the interactions between xylanase (Tx-xyn11) and phenolic compounds or lignin oligomers. In a first approach, Tx-xyn11 was fixed onto sensor surfaces, and phenolic molecules were applied in the liquid phase. The results demonstrated weak affinity and over-stoichiometric binding, as several phenolic molecules bound to each xylanase molecule. This approach, requiring the use of soluble molecules in the liquid phase, is not applicable to insoluble lignin oligomers, such as the dehydrogenation polymer (DHP). An alternative approach was developed in which a lignin oligomer was fixed onto a sensor surface. Due to their hydrophobic properties, the preparation of stable lignin layers on the sensor surfaces represented a considerable challenge. Among the various chemical and physico-chemical approaches assayed, two approaches (physisorption via the Langmuir-Blodgett technique onto self-assembled monolayer (SAM)-modified gold and covalent coupling to a carboxylated dextran matrix) led to stable lignin layers, which allowed the study of its interactions with Tx-xyn11 in the liquid phase. Our results indicated the presence of weak and non-specific interactions between Tx-xyn11 and DHP.

Differential recognition of epitopes present on monomeric and oligomeric forms of gp160 glycoprotein of human immunodeficiency virus type 1 by human monoclonal antibodies.

The mechanism of infectivity neutralization of human immunodeficiency virus type 1 (HIV-1) by Ig is poorly understood. Three human monoclonal antibodies (mAbs 1b12, 2G12 and 2F5) that are able to neutralize primary isolates of HIV-1 in vitro have been shown to act synergistically. In the present study this synergy was analyzed by measuring the epitope accessibility and binding kinetics for these three mAbs with respect to monomeric and oligomeric env protein gp160 IIIB using surface plasmon resonance. The results indicate that oligomerization of gp160 affects the accessibility of some of the epitopes recognized by the mAbs and provide some insight into the mechanism of synergy between different anti-(HIV-1) mAbs.

Active concentration measurements of recombinant biomolecules using biosensor technology.

Whereas the concentration of a biomolecule simply refers to the amount of chemical substance per unit of volume, its active concentration refers to a relational parameter that has meaning only with respect to the molecule's ability to interact specifically with one particular ligand. When proteins are studied in a biological context, it is the biologically active concentration that is relevant, and not the total concentration of correctly and incorrectly folded molecules. Using a biosensor instrument the concentration of active biomolecules in a preparation can be measured by injecting the preparation at different flow rates onto a sensor chip surface presenting a high concentration of a specific ligand. The method can be used under conditions of partial mass transport limitation and does not require a pre-established standard curve. When the method was used to measure the active concentration of several recombinant proteins it was found that the active concentration was much lower than the nominal concentration determined by conventional methods. The active concentration also depended on the ligand used in the binding assay, reflecting the fact that active concentration can only be defined with respect to one specific probe. Such discrepancies in concentration values, if undetected, may lead to erroneous conclusions regarding the properties and behaviour of recombinant proteins tested in different assays.

Properties of polyglutamine expansion in vitro and in a cellular model for Huntington's disease.

Eight neurodegenerative diseases have been shown to be caused by the expansion of a polyglutamine stretch in specific target proteins that lead to a gain in toxic property. Most of these diseases have some features in common. A pathological threshold of 35-40 glutamine residues is observed in five of the diseases. The mutated proteins (or a polyglutamine-containing subfragment) form ubiquitinated aggregates in neurons of patients or mouse models, in most cases within the nucleus. We summarize the properties of a monoclonal antibody that recognizes specifically, in a Western blot, polyglutamine stretches longer than 35 glutamine residues with an affinity that increases with polyglutamine length. This indicates that the pathological threshold observed in five diseases corresponds to a conformational change creating a pathological epitope, most probably involved in the aggregation property of the carrier protein. We also show that a fragment of a normal protein carrying 38 glutamine residues is able to aggregate into regular fibrils in vitro. Finally, we present a cellular model in which the induced expression of a mutated full-length huntingtin protein leads to the formation of nuclear inclusions that share many characteristics with those observed in patients: those inclusions are ubiquitinated and contain only an N-terminal fragment of huntingtin. This model should thus be useful in studying a processing step that is likely to be important in the pathogenicity of mutated huntingtin.

Kinetics of interaction between 3-hydroxyphthaloyl-beta-lactoglobulin and CD4 molecules.

Kinetics of 3-hydroxyphthaloyl-beta-lactoglobulin-CD4 interaction were evaluated using a biosensor instrument based on surface plasmon resonance. A very fast association (k(a)=2.4+/-0.3x10(6)M(-1)s(-1)) and slow dissociation (K(d)=2.3+/-0.14x10(-4)s(-1)) rate constants were observed indicating the high affinity of the complex. This result together with earlier data, suggest that "structure-specific" requirements must be met to endow acid anhydride modified lactoglobulin with the capacity for high affinity binding to CD4.

Measurement of antigen-antibody interactions with biosensors.

The introduction in 1990 of a new biosensor technology based on surface plasmon resonance has revolutionized the measurement of antigen-antibody binding interactions. In this technique, one of the interacting partners is immobilized on a sensor chip and the binding of the other is followed by the increase in refractive index caused by the mass of bound species. The following immunochemical applications of this new technology will be described: (1) functional mapping of epitopes and paratopes by mutagenesis; (2) analysis of the thermodynamic parameters of the interaction; (3) measurement of the concentration of biologically active molecules; (4) selection of diagnostic probes.

Thermodynamic analysis of antigen-antibody binding using biosensor measurements at different temperatures.

The thermodynamic parameters of the interaction between hen egg white lysozyme and Fab D1.3 were determined by measuring the temperature dependence of the ratio of its kinetic association and dissociation rate constants. Biosensor technology (BIAcore 2000) was used to measure the rate constants at temperatures ranging from 5 to 40 degrees C. The value of DeltaG degrees at 25 degrees C (-49 kJ M-1) calculated by this method was very close to that obtained previously from fluorescence quenching measurements (-48.5 kJ M-1). However, the value of DeltaH degrees measured at 25 degrees C by biosensor technology (-35 kJ M-1) was smaller than that determined previously by microcalorimetry (-90 kJ M-1). Another difference was the limited variation of ln K and DeltaG with temperature observed with BIAcore compared to the steady decrease of ln K with temperature found by calorimetry. Our data showed that the binding reaction was driven only by enthalpy below 23 degrees C, by enthalpy and entropy between 23 and 35 degrees C, and only by entropy above 35 degrees C. This suggests, inter alia, that the contribution from the enthalpy of hydration due to the water molecules present at the interface in the lysozyme-antibody complex is progressively eliminated as the temperature increases. Whereas calorimetric data pertain to all the components present in the sample, including solvent molecules, BIAcore measurements monitor only the physical association and dissociation of the two macromolecular species. The difference between the two sets of data may also reflect the complexity of the binding mechanism between lysozyme and Fab D1.3.

Analysis of cyclosporin interactions with antibodies and cyclophilin using the BIAcore.

The immunosuppressive cyclic undecapeptide cyclosporin A (CS) exists in various conformers in water. Up to 1 h is needed to reach maximum complex formation after mixing the drug with its receptor, cyclophilin or with a monoclonal antibody. Differences in the ability of CS and its analogs to bind to antibody or cyclophilin have been measured using the BIAcore. These experiments suggest that the rate-limiting step of complex formation is determined by the interconversion between different CS conformers existing in solution. The contribution to antibody binding of individual atomic groups of CS was evaluated by measuring the equilibrium affinity constants of analogs with the BIAcore. When the binding data were analyzed in terms of the known crystallographic structure of the CS/Fab complex, it could be shown that modifications of CS residues located in the central part of the binding site drastically affect affinity, while modifications of residues located at the periphery are more easily accommodated.

Cross-reactivity of monoclonal antibodies to a chimeric V3 peptide of HIV-1 with peptide analogues studied by biosensor technology and ELISA.

The reactivity of monoclonal antibodies (Mabs) raised against a cyclic peptide representing a chimeric V3 loop of HIV-1 gp120 with different peptide analogues was studied with a biosensor system (BIAcore) and by ELISA. In both assays, the Mabs cross-reacted extensively with the V3 regions of different HIV-1 strains and recognized the cyclic form of the peptide immunogen better than its linear form. The highest degree of cross-reactivity was observed with peptides that shared a Lys312 with the chimeric sequence. Dissociation rate constants of ten Mabs measured with the BIAcore with respect to different peptides increased with increasing numbers of substitutions in the flanking regions of the V3 tip sequence Gly Pro Gly Arg. Immobilization of the cyclic peptide on the sensor chip via a thiol group added near the end of the loop structure preserved the conformation of the peptide. In view of the good correlation between the BIAcore and ELISA results, biosensor data should be useful for selecting peptides to be used in diagnostic solid phase assays.

Interaction of cyclosporin A and two cyclosporin analogs with cyclophilin: relationship between structure and binding.

The immunosuppressant drug cyclosporin A exists as various conformers in water. Up to 1 h is needed to reach maximum complex formation after mixing the drug with its receptor, cyclophilin, or an antibody, indicating that only a fraction of the conformers in aqueous solution adopts a conformation suitable for binding. In the present study we compare the binding behavior of cyclosporin to that of two analogs, using a biosensor instrument (BIAcore, Pharmacia). The amount of complex formation was measured as a function of time after adding the peptides to cyclophilin. The equilibrium affinity constants of cyclophilin for these analogs have been measured. The slow binding of cyclosporin to cyclophilin compared to the instant binding of the cyclosporin analogs supports the hypothesis that cyclophilin recognizes a well defined conformation of cyclosporin that exists in water prior to binding.

Antigenic mimicry of natural L-peptides with retro-inverso-peptidomimetics.

Three analogues of the model peptide of sequence IRGERA corresponding to the COOH-terminal residues 130-135 of histone H3 were synthesized, and their antigenicity, immunogenicity, and resistance to trypsin were compared to those of the natural L-peptide. The three analogues correspond to the D-enantiomer, containing only D-residues, and two retro-peptides containing NH-CO bonds instead of natural peptide bonds. The chirality of each residue was maintained in the retro-peptide and inverted in the retro-inverso-peptide. Antibodies to the four peptide analogues were produced by injecting BALB/c mice with peptides covalently coupled to small unilamellar liposomes containing monophosphoryl lipid A. Each of the four peptide analogues induced IgG antibodies of various subclasses. The IgG3 antibodies reacted similarly with the four analogues, whereas antibodies of the IgG1, IgG2a, and IgG2b isotypes showed strong conformational preferences for certain peptides. The retro-inverso-peptide IRGERA mimicked the structure and antigenic activity of the natural L-peptide but not of the D- and retro-peptides, whereas the retro-peptide IRGERA mimicked the D-peptide but not the L- and retro-inverso-peptides. The equilibrium affinity constants (Ka) of three monoclonal antibodies generated against the L- and D-peptides with respect to the four peptide analogues were measured in a biosensor system. Large differences in Ka values were observed when each monoclonal antibody was tested with respect to the four peptides. The use of retro-inverso-peptides to replace natural L-peptides is likely to find many applications in immunodiagnosis and as potential synthetic vaccines.

Structure-activity relationships for the interaction between cyclosporin A derivatives and the Fab fragment of a monoclonal antibody.

The crystallographic structure of a complex between cyclosporin A and the Fab fragment of monoclonal antibody R45-45-11 has been solved to 2.65 A resolution (Altschuh et al., 1992a, Science 256, 92; Vix et al., 1993, Proteins 15, 339), yielding a precise three-dimensional picture of interacting surfaces. In order to evaluate the contribution of observed contacts to the energy of interaction, we have measured the effect on binding affinity of minor chemical modifications of CS. The equilibrium binding constant of the Fab fragment for a set of cyclosporin analogs was obtained by measuring in a biosensor instrument the dependence of complex formation on Fab concentration, at constant analog concentrations. Data were analysed using Scatchard plots. Differences in binding energy resulting from cyclosporin modifications discriminated between two types of contact areas. The first type displays adaptability to structural modifications of cyclosporin at the cost of a small decrease in binding energy, and contacting residues in the antibody form the periphery of the combining site. The second type does not accommodate structural changes and corresponds in cyclosporin to three residues whose modifications drastically decrease binding energy with the antibody. The corresponding contact residues in the antibody form the core of the antibody combining site.

Interaction of cyclosporin A with an Fab fragment or cyclophilin. Affinity measurements and time-dependent changes in binding.

Different conformers of the immunosuppressant cyclosporin A have been observed in structural studies of the isolated molecule and of its complex with cyclophilin or with an Fab fragment. The factors that control this conformational change are not well understood. Variations in the amount of complex formed with cyclophilin or with the antibody were measured as a function of time after adding cyclosporin to the proteins, using the Pharmacia BIAcore biosensor instrument. Up to 1 hour was needed to reach maximum complex formation in solution, which is likely to reflect the time needed for a conformational transition of cyclosporin. The equilibrium affinity constant of both proteins for cyclosporin has been measured.

Epitope analysis using kinetic measurements of antibody binding to synthetic peptides presenting single amino acid substitutions.

The fine modulation of peptide-antibody interactions was investigated with anti-peptide monoclonal antibodies recognizing peptide 125-136 of the coat protein of tobacco mosaic virus. Nine synthetic peptides presenting single amino acid substitutions were selected for detailed analysis on the basis of their reactivity in ELISA. Kinetic measurements of the binding of four antibodies to these peptides performed with a biosensor instrument (BIAcore, Pharmacia) were used to quantify the contribution of individual residues to antibody binding. The results showed that even conservative exchanges of some residues in the epitope resulted in a small but significant decrease of the equilibrium affinity constant due mostly to a higher dissociation rate constant of the monoclonal antibodies. Two amino acid residues directly adjacent to the epitope, which appeared to play no role when tested by ELISA, were shown to influence the kinetics of binding. These data should be useful for computer modelling of the peptide-antibody interactions.

Monoclonal antipeptide antibodies: affinity and kinetic rate constants measured for the peptide and the cognate protein using a biosensor technology.

The interaction of antipeptide antibodies with the corresponding peptide and the cognate protein has been compared using a novel biosensor technology (BIAcore, Pharmacia). The peptide corresponds to residues 110-135 of the coat protein of tobacco mosaic virus, known to encompass an alpha-helical region reactive with antiprotein antibodies. A panel of 33 monoclonal antibodies raised against the peptide was studied and the epitope recognized by these antibodies was determined by the pepscan method. Further discrimination between the antibodies was performed by measurements of association and dissociation kinetic constants. Several antibodies showed an heterogeneous binding profile when reacting with the 25 residue long peptide but not with a shorter 10 residue peptide suggesting that they recognized different conformational states in the longer peptide. Equilibrium affinity constants were calculated for five of the antibodies and were found to be 10-50 times higher for the peptide than for the protein, the difference being caused mainly by a lower association rate constant.

Tobacco mosaic virus: a model antigen to study virus-antibody interactions.

For more than 50 years, tobacco mosaic virus (TMV) has been used as a model system for studying various aspects of virus-antibody interactions. Distinct epitopes called neotopes and cryptotopes have been identified in intact TMV particles and dissociated viral protein respectively and a correlation has been found to exist between the location of continuous epitopes and the extent of segmental mobility along the viral polypeptide chain. The occurrence of bivalent antibody binding was shown to influence the observed affinity of TMV antibodies and kinetic measurements of antibody binding to viral peptides made it possible to analyze the mechanism of binding of monoclonal antibodies. It seems likely that the TMV model will continue to yield a rich harvest of immunochemical data relevant to many viral systems.

Determination of kinetic constants for the interaction between a monoclonal antibody and peptides using surface plasmon resonance.

Differences in the affinity of a monoclonal antibody raised against the protein of tobacco mosaic virus for 15 related peptides (residues 134-146) carrying single-residue modifications were investigated using a novel biosensor technology (Pharmacia BIAcore). Analysis of the peptide-antibody interaction in real time allowed fast and reproducible measurements of both association and dissociation rate constants. Out of 15 mutant peptides analyzed, five were not recognized by the antibody at all, and seven were recognized as well as the wild-type peptide. For three of the peptides, the rate constants were different for the mutant and wild-type peptides. The pattern of residue recognition suggests that the epitope is formed by three residues (140, 143, and 144) in a helical conformation that mimics the structure in the protein. Even a minor modification of these residues totally abolishes recognition by the antibody. Modifications of adjacent residues result in small but significant differences in association and/or dissociation rate constants. One of the recognized residues is totally buried in the three-dimensional structure of TMV protein, suggesting that a structural rearrangement next to the helix occurs during protein-antibody interaction.