Oligomerization and ring closure of immunoglobulin E class antibodies by divalent haptens

Cross-linking of antibodies constitutes a widespread initiation signal for their respective effector functions. Cross-linking IgE-class antibodies provide the triggering signal to mast cells for their degranulation process. To obtain a quantitative insight into these cross-linking processes, the interactions between a DNP-specific monoclonal antibody of the IgE class and a series of divalent DNP haptens with spacers of different length and flexibility have been studied by fluorescence titration experiments. These were analyzed by employing the theoretical model developed by Dembo and Goldstein [Dembo, M., & Goldstein, B. (1978) J. Immunol. 121, 345-353] in a fitting procedure. Equilibrium constants that describe the aggregation and ring-closure processes caused by divalent hapten binding have been used as free parameters. The intrinsic binding constants were determined by fluorescence titrations with corresponding monovalent haptens. The main results are the following: (1) The divalent haptens with a short and flexible spacer [i.e., N alpha, N epsilon-di-(DNP)-L-lysine,meso-bis[(DNP-beta-Ala)amino]succinate, and bis[(DNP-tri-D-Ala)amino]heptane, having a maximal DNP-DNP distance of gamma = 14, 21, and 45 A, respectively] effect aggregation of the antibodies mainly into closed dimers. (2) The divalent hapten family with long and rigid oligoproline spacers di(DNP)-Ahx-Asp-(Pro)n-Lys with n = 24, 27, and 33 (i.e., gamma = 100, 110, and 130 A) causes aggregation of the antibodies predominantly into closed dimers and trimers. The corresponding equilibrium constants of the respective ring-closure processes decrease significantly with longer spacer length. (3) Evidence was found that intramolecularly monomeric ring closure of the IgE antibodies is caused by haptens containing oligoproline spacers with n = 37 or 42 (gamma = 130-150 A). The equilibrium constant of the ring-closure process increases with spacer length. This increase in stability indicates a difference in the imposed strain. Furthermore, the latter results imply that the distance between the two binding sites of the IgE molecule lies in the range dictated by the rigid oligoproline part of the respective hapten's spacer, i.e., 115-130 A. (4) Nearly all oligomeric ring-closure processes proceed relatively slowly with an approximate lower limit of a half-life of 5-10 s. This slowing down of the aggregation and ring-closure processes most probably reflects steric factors.     

Thermodynamics of antibody-antigen reactions. 1. The binding of simple haptens to two classes of antibodies fractionated according to affinity

The thermodynamic parameters which characterize the binding of dinitrophenylglycine and dinitrophenylmethoxypoly(ethylene glycol) to selected affinity classes of equine IgG and IgG(T) antibodies were determined by fluorescence quenching and flow calorimetry. The binding enthalpies and entropies were in all cases large and negative, falling in the ranges -14 to -17 kcal/mol and -18 to -25 eu, respectively. The differences in the enthalpies and entropies of binding for different affinity classes and for different haptens are discussed with reference to differences in the structures of the haptens studied and as indications of differences in binding site structure. In addition, the apparent existence of fluorescent side chains which can transfer energy to either hapten binding site in IgG(T) antibodies but not in IgG antibodies is interpreted as indicative of a smaller average interbinding site distance in IgG(T) than in IgG antibodies.     

Immunochemical characterization of polyclonal and monoclonal Streptococcus group A antibodies by chemically defined glycoconjugates and synthetic oligosaccharides.

Synthetic oligosaccharides of increasing complexity that represent different epitopes of the Streptococcus Group A cell-wall polysaccharide were used as haptens and glycoconjugates of bovine serum albumin (BSA) and horse hemoglobin (HHb) to characterize polyclonal and monoclonal antibodies. Rabbits were immunized with the BSA glycoconjugates of a linear trisaccharide, branched trisaccharide, and branched pentasaccharide. The binding specificities of the polyclonal antisera were determined by a series of inhibition ELISA studies in which disaccharide through pentasaccharide haptens were used as inhibitors of antibody-glycoconjugate binding. Monoclonal antibodies derived from mice immunized with a killed bacterial vaccine were selected for their binding to native polysaccharide antigen coupled to BSA and the BSA glycoconjugates of the di- and linear tri-saccharides. Polyclonal antibodies were moderately specific for the oligosaccharide epitope of the immunizing glycoconjugate and only those antibodies raised to the branched pentasaccharide antigen showed cross-reaction with the bacterial antigen. The behaviour of selected monoclonal antibodies parallels the binding profile of polyclonal antibodies in that the two highest-titre antibodies were directed toward an epitope displayed by the branched pentasaccharide.     

Epitopic discrimination by monoclonal antibodies directed against the same alkylated nucleoside

Epitopic specificity of three monoclonal antibodies (mAb's) (coded as ER-6, ER-3, and EM-1) was examined through the utilization of haptenic structural analogs. The binding affinity expressed by the microscopic equilibrium constant (Ki) (Yuhasz, et al., Biochemistry 26, 2334-2342 (1987] of the immunizing hapten, O6-ethyl-2'-deoxy-guanosine (*G) and eight structural analogs, were analyzed by a nitrocellulose affinity filter assay (NAFA) and radioimmunoassay (RIA) for each mAb to determine the protein-hapten interaction between the epitope and the binding cavity. Several components of the *G hapten were determined to be critical for each mAb recognition, while all three mAb's were found to require the O6-ethyl moiety, conjugated guanine base ring, the glycosyl bond and the sugar ring C [1'] and C [2'] position. This investigation further probes and categorizes the binding specificity of the monoclonal antibodies after incorporation of the *G monomer into three short deoxyribooligomeric haptens: O6-ethyl-2'-deoxyguanylyl 3',5' deoxyadenosine (*GA), 2'-deoxyadenylyl 3',5' O6-ethyl-2'-deoxyguanylyl 3',5' 2'-deoxyadenosine (A*GA), and O6-ethyl-2'-deoxyguanylyl 3',5' 2'-deoxyadenylyl 3',5'-2'-deoxyadenylyl 3',5' 2'-deoxycytosine (*GAAC). Unlike the similar binding profiles for the monoclonal antibodies and the haptenic structural analogs, the binding profiles for the deoxyribooligomeric haptens were found to differ in their modes of recognition. These results will be compared to ascertain the key components of monomer and oligomer interaction of the binding cavity. It is important for investigations where monoclonal antibodies derived from small haptens are utilized in recognition of larger antigens containing those haptens.     

Multiple reactive immunization towards the hydrolysis of organophosphorus nerve agents: hapten design and synthesis

We designed and synthesized a series of haptens to elicit catalytic antibodies with phosphatase activity against nerve agents. The design is based on the novel concept of multiple reactive immunization which aims to afford two or more catalytic residues within the antibody's binding cleft. The haptens showed the desired reactivity in vitro and were submitted for immunization.     

Design and syntheses of three haptens to generate catalytic antibodies that cleave amide bonds with nucleophilic catalysis

Design principles and syntheses of three haptens that were recently reported to generate amide bond cleaving catalytic antibodies are described. The hapten designs sought to induce acidic and/or basic residues in antibody binding sites via charge complementarity, and also to generate a hydrophobic binding pocket for an external phenol nucleophile. The charged yet aromatic nature of these haptens presented some unique synthetic challenges and solutions to which are described below.     

Effects of charged groups in haptens on adsorption equilibrium of hapten antibody

Antisera against charged (p-azobenzoate and p-azoben zenesulfonate) and uncharged (dinitrophenyl) haptenic groups were produced in rabbits, and the equilibrium characteristics of hapten-antibody were measured by use of immunoadsorbents. The antibody to the uncharged hapten formed a stable binding with the hapten to the changes in ionic strength and pH. On the other hand, the antibodies to the charged haptens showed affinities sensitive to the changes in pH and ionic strength. Therefore, the effect of the pK(a) of ionizable haptens on the pH dependence of the hapten-antibody binding was studied by comparing the interactions between a series of para-substituted benzoic acids and the anti-p-azobenzoate antibody. The pH dependence of the interactions was strongly affected by the pK(a) of ionizable groups in haptens. Furthermore, the equilibrium characteristics of anti-p-aminobenzoyl dipeptides were compared. The characteristics of interactions were affected by the features of amino acid residues.     

Antibodies elicited by defined oligodeoxyribonucleotide sequences.

Antibodies to the oligodeoxyribonucleotides d(pT)3, d(pT)4, d(pT)6 and d(pA-A-T-T) were elicited in rabbits by immunization with electrostatic complexes of the respective haptens with methylated bovine serum albumin (MBSA). The antisera were assayed by complement fixation using denatured DNA's of various sources as antigens. The specificities of the antibodies were determined by estimating the inhibition of the complement fixation reaction by defined oligodeoxyribonucleotides. The antibodies were shown to be specific for the sequence of the oligode-oxyribonucleotides or parts of it.     

New strategies for the design of catalytic antibodies.

A new approach is advanced which is aimed at expanding the scope of antibody catalysis. It entails the design and synthesis of haptens that will elicit antibodies to catalyze acyl transfer reactions by a methodology which we term "bait and switch" catalysis. What we have done involves the placement of a point charge on the hapten in close proximity to, or in direct substitution for, a chemical functional group we wish to transform in the respective substrate. The haptenic charge should induce a complementary charge (on an amino acid residue) at the binding site. The substrate will lack this charge but will retain a similar overall structure. The monoclonal antibodies that bind these substrates now have the potential to act as general acids/bases for substrates having hydrolyzable functional groups.     

Monoclonal Antibodies with High Affinity for Spiroperidol

A diverse panel of monoclonal antibodies was obtained from BALB/c mice immunized with two haptens structurally related to spiroperidol (SPD). Bromoacetyl derivatives of aminospiroperidol (NH2SPD) and N-amino-phenethylspiroperidol (NAPS) were synthesized to couple the haptens covalently to a protein carrier for immunization, thereby maintaining the butyrophenone portion of the immunogen. Hybridomas were selected based on their ability to secrete antibody that binds [3H]SPD with high affinity. Equilibrium dissociation constants for these antibodies ranged from 0.2 to greater than 100 nM. The antigen binding sites of the anti-NH2SPD and anti-NAPS antibodies were characterized in studies of the inhibition of the binding of [3H]-SPD by a series of ligands that are either (a) structurally related to SPD or (b) structurally unrelated to the butyrophenones but known to be selective antagonists of the D2 subtype of dopamine receptor. Based on the patterns of inhibition of the binding of [3H]SPD by these compounds, 12 classes of antibody combining sites were identified. Most of these antibodies bound butyrophenones with high affinity. One anti-NH2SPD and four anti-NAPS antibodies also bound domperidone, a nonbutyrophenone that has a high affinity for D2 receptors. None of the antibodies bound clebopride or sulpiride, D2-selective antagonists of the benzamide class, or the agonist dopamine.     

Analysis of triiodothyronine and thyroxine-binding autoantibodies in chickens susceptible to autoimmune thyroiditis

This report reveals a surprisingly high incidence of thyroid hormone (T3 and T4) autoantibodies (THA) and thyroglobulin autoantibodies in a closed flock of untreated Cornell strain (CS) White Leghorn chickens. This flock is closely related to the Obese strain chicken, which develops a severe spontaneous autoimmune thyroiditis. A sensitive electrophoretic autoradiographic assay for THA was developed. This assay was applied to the study of autoantibodies to T3 and T4 in the sera of adult female CS chickens. Of 109 females, 29.4% had antibodies to T3 and 18.4% had antibodies to T4. The incidence of thyroglobulin antibodies, determined by passive hemagglutination, was 15.6%. The presence of THA affected RIA measurements because serum T3 and T4 hormone concentrations appeared elevated in those birds with moderate to high antibody levels. There was major variance in the electrophoretic heterogeneity of the THA from individual chickens; i.e., some of the sera contained antibodies to T3 or T4 that appeared to be monoclonal, whereas other sera exhibited polyclonal multi-banded patterns. To determine if antibodies reactive with T3 and T4 (which are haptens) were generated by antibody responses to the T3/T4 sites on the thyroglobulin molecule, competitive binding assays were performed to determine the relative binding affinities of the antibodies for the haptens (T3/T4) and the "hapten-conjugate" (thyroglobulin). In these assays, thyroglobulin competed with the haptens, thus supporting the above hypothesis.     

Dimerization kinetics of the IgE-class antibodies by divalent haptens. I. The Fab-hapten interactions.

The binding of divalent haptens to IgE-class antibodies leads predominantly to their oligomerization into open and closed dimers. Kinetics of the open dimer formation was investigated by fluorescence titrations of Fab fragments of monoclonal DNP-specific IgE antibodies with divalent haptens having different spacer length (gamma = 14-130 A). Binding was monitored by quenching of intrinsic tryptophan emission of the Fab. Addition of divalent haptens with short spacers (gamma = 14-21 A) to the Fabs at rates larger than a distinct threshold value caused a significant decrease of Fab-binding site occupation in the initial phase of the titration. This finding was interpreted to reflect a nonequilibrium state of hapten-Fab-binding. Such nonequilibrium titrations were analyzed by inserting a kinetic model into a theory of antibody aggregation as presented by Dembo and Golstein (Histamine release due to bivalent penicilloyl haptens. 1978. J. Immunol. 121, 345). Fitting of this model to the fluorescence titrations yielded dissociation rate constants of 7.8 x 10(-3) s-1 and 6 x 10(-3) s-1 for the Fab dimers formed by the flexible divalent haptens N alpha, N epsilon-di(dinitrophenyl)-L-lysine (gamma = 16 A) and bis(N beta-2,4-dinitrophenyl-alanyl)-meso-diamino-succinate (gamma = 21 A). Making the simplifying assumption that a single step binding equilibrium prevails, the corresponding dimer formation rate constants were calculated to be 1.9 x 10(5) M-1 s-1 and 1.1 x 10(4) M-1 s-1, respectively. In contrast, all haptens with spacers longer than 40 A (i.e., bis(N alpha-2,4-dinitrophenyl-tri-D-alanyl)-1,7-diamino-heptane, and di(N epsilon-2,4-dinitrophenyl)-6-aminohexanoate-aspartyl-(prolyl)n-L-l ysyl (n = 24, 27, 33) exhibit a relative fast dimerization rate of the Fab fragments (greater than 7 x 10(6) M-1 s-1). These observations were interpreted as being caused by orientational constraints set by the limited solid angle of the reaction between the macromolecular reactants. Thus, ligands having better access to the binding site would react faster.     

Binding of a monoclonal antibody and its Fab fragment to supported phospholipid monolayers measured by total internal reflection fluorescence microscopy.

The association of an anti-dinitrophenyl monoclonal antibody and its Fab fragment with supported phospholipid monolayers composed of a mixture of dipalmitoylphosphatidylcholine and dinitrophenyl-conjugated dipalmitoylphosphatidylethanolamine has been characterized with total internal reflection fluorescence microscopy. The surface densities of bound antibodies were measured as a function of the antibody and Fab solution concentrations, and as a function of the solution concentration of dinitrophenylglycine. The apparent association constant of Fab fragments with surface-associated haptens was approximately 10-fold lower than the association constant for haptens in solution, and the apparent surface association constant for intact antibodies was only approximately 10-fold higher than the constant for Fab fragments. Data analysis with simple theoretical models indicated that, at most antibody surface densities, 50-90% of membrane-associated intact antibodies were attached to the surface by two antigen binding sites.     

Resonance Raman-spectroscopic studies of the hapten features involved in the binding of 2,4-dinitrophenyl haptens by the mouse myeloma proteins MOPC 315 and MOPC 460.

The binding of four dinitrophenyl haptens to the mouse myeloma proteins MOPC 315 IgA (immunoglobulin A) and MOPC 460IgA was studied by resonance Raman spectroscopy. Isotopic substitution with 15N and 2H was used to assign features in the resonance Raman spectra of the free haptens. Changes in each of these features on binding to the proteins could then be attributed to interactions of the proteins' binding sites with either the p-NO2 or the o-NO2/amine regions of the haptens. The interactions between a given hapten and MOPC 315 IgA are often quite distinct from those between the same hapten and MOPC 460 IgA. Moreover, for both antibodies the nature of the R side chain in a Dnp-NHR (Dnp, 2,4-dinitrophenyl) compound appears to modify the interactions between the Dnp chromophore and the protein. Thus, with the haptens studied, there is no unique set of contacts between the Dnp group and the binding site. The contacts expected between epsilon-2,4-dinitrophenyl-L-lysine and the site on MOPC 315 IgA, on the basis of a recent model for this site [Dwek, Wain-Hobson, Dower, Gettins, Sutton, Perkins & Givol (1977) Nature (London) 266, 31--37] were not detected. However, the contacts between this hapten and the site on MOPC 460 IgA were closer to those predicted by the model for MOPC 315 IgA.     

Mechanism by which antibodies inhibit hapten-malate dehydrogenase conjugates. An enzyme immunoassay for morphine.

Antimorphine antibodies inhibit the activity of morphine conjugates of mitochondrial malate dehydrogenase. Conjugation of malate dehydrogenase through tyrosine and amino groups resulted in only moderate losses of enzyme activity. On conjugation through disulfide bonds the enzyme activity first increased but dropped sharply with increasing substitution. Only the former conjugates were inhibited by excess antibodies. The degree of inhibition (up to 86%) was directly related to the number of morphine residues bonded directly to amino groups. The maximum number of antibody binding sites that bind to enzyme was nearly equal to the number of haptens provided there were 16 or less haptens/enzyme. However up to 26 haptens/enzyme became completely bound by antibody on long incubation. Inhibition of enzyme activity was detectably reduced by 2 times 10 minus 9 M morphine or 2 times 10 minus 10 M codeine, thus providing a sensitive assay for these drugs. The data suggest that enzyme inhibition occurs by conformational freezing of the enzyme when antibody binds to a morphine residue attached to one specific amino group.     

Structural and dynamical aspects of membrane immunochemistry using model membranes.

Three different phospholipid haptens have been synthesized, in which the haptenic group is the paramagnetic nitroxide (spin-label) group. These lipid haptens differ from one another in the length and composition of the molecular chain linking the 2,2,6,6-tetramethylpiperidinyl-N-oxy moiety to the phosphodiester group of the lipid. These lipid haptens have been incorporated at low molar concentrations (0.01 to 0.5 mol %) in liposomes containing various proportions of cholesterol and dipalmitoylphosphatidylcholine (DPPC). A study has been made of specific antinitroxide IgG (and Fab) binding to these liposomes, and the fixation of complement. From these studies we conclude: (a) For lipid haptens whose possible extension above the bilayer plane is limited (e.g., approximately 10-20 A), antibody binding and complement fixation depend strongly on the hapten structure and host lipid composition, because of steric limitations on the accessibility of lipid haptens to the binding sites in the protein. (b) Complement fixation by specific IgG antibodies directed against the nitroxide group as part of a lipid hapten depends strongly on the lateral mobility of the lipid hapten when its molar concentration in the plane of the membrane is of the order of 0.1 mol % or less. It is likely that this conclusion applies to many lipid haptens, and possibly other membrane components. (c) The inclusion of cholesterol in lipid membranes has at least two distinct effects on complement fixation involving lipid haptens. Through a steric effect on bilayer structure (probably involving lateral molecular ordering) cholesterol in phosphatidylcholine bilayers can enhance hapten exposure to antibody binding sites, enhance antibody binding, and thereby enhance complement fixation. It is likely that cholesterol also affects complement fixation at low hapten concentrations through a modification of membrane fluidity.     

Synthetic haptens as probes of antibody response and immunorecognition

The molecular forces that bind antibody to antigen have long fascinated chemists. The use of synthetic haptens to study immunochemical phenomena can be traced back to the classic work of Karl Lansteiner. His utilization of small-molecule-protein conjugates first demonstrated the shape-selective nature of antibody binding. Later work by Linus Pauling and David Pressman employed multivalent, synthetic ligands to establish the bivalent nature of antibodies and explain the nature of immunoprecipitation. Fluorescent probes such as dansyl, fluorescein, and Ru(bpy)(2+)(3) have been used to study affinity maturation, quantify antibody affinities, and investigate polyclonal antibody heterogeneity. Finally, X-ray crystallography has yielded a molecular picture of how antibodies exercise intermolecular forces (e.g., charge-charge interactions, H-bonding, and Van der Waals) to bind haptens. Studies inspired by Landsteiner's original work continue to play an important role in fields ranging from immunodiagnostics to catalytic antibodies.     

Monoclonal antibodies that recognize minimal differences in the three-dimensional structures of metal-chelate complexes

Immunization of BALB/c mice with a cadmium-chelate-protein conjugate resulted in the isolation of two hybridoma cell lines (A4 and E5) that synthesized antibodies with different variable regions, but similar metal-chelate affinity. The ability of these two monoclonal antibodies to interact with 12 different metal-chelate complexes was studied using the KinExA 3000 immunoassay instrument. The two antibodies showed the highest affinity for cadmium and mercury complexes of ethylenediamine N,N,N',N'-tetraacetic acid (EDTA). The E5 antibody bound to EDTA complexes of cadmium and mercury with equilibrium dissociation constants (K(d)) of 1.62 x 10(-)(9) M and 3.64 x 10(-)(9) M, respectively. The corresponding values for the A4 antibody were 14.7 x 10(-)(9) M and 3.56 x 10(-)(9) M. Addition of a cyclohexyl ring to the EDTA backbone increased the affinity of E5 for the metal-chelate haptens, while decreasing the binding of A4 to the same haptens. Based on available crystal structures, molecular models were constructed for five different divalent metal-chelate complexes. The models were compared to determine structural features of the haptens that may influence antibody recognition. Difference distance matrixes were used to identify areas of the metal-chelate haptens that differed in three-dimensional space. Antibody affinity correlated well with the extent of total structural difference for these metal-EDTA complexes.     

Human catalytic antibodies with glutathione peroxidase activity

In order to generate catalytic antibodies with glutathione peroxidase (GPx) activity, we prepared GSH-S-DNP butyl ester and GSH-S-DNP benzyl ester as the haptens. Two ScFvs that bound specifically to the haptens were selected from the human phage-displayed antibody library. The two ScFv genes were highly homologous, consisting of 786 bps and belonging to the same VH family-DP25. In the premise of maintaining the amino acid sequence, mutated plasmids were constructed by use of the mutated primers in PCR, and they were over-expressed in E. coli. After the active site serine was converted into selenocysteine with the chemical modifying method, we obtained two human catalytic antibodies with GPx activity of 72.2U/micromol and 28.8U/micromol, respectively. With the aid of computer mimicking, it can be assumed that the antibodies can form dimers and the mutated selenocysteine residue is located in the binding site. Furthermore, the same Ping-Pong mechanism as the natural GPx was observed when the kinetic behavior of the antibody with the higher activity was studied.