Analysis of bispecific monoclonal antibody binding to immobilized antigens using an optical biosensor

The interaction between two different monoclonal antibodies (Mabs) and their corresponding bispecific antibodies (Babs) with immobilized antigens was investigated using an optical biosensor (IAsys). The analyzed panel of affinity-purified antibodies included two parental Mabs (one of which was specific to human IgG (hIgG), and another one to horseradish peroxidase (HRP)), as well as Babs derived thereof (anti-hIgG/HRP). Babs resulting from the fusion of parental hybridomas bear two antigen-binding sites toward two different antigens and thus may interact with immobilized antigen through only one antigen-binding site (monovalently). Using an IAsys biosensor this study shows that the bivalent binding of Mabs predominates over the monovalent binding with immobilized HRP, whereas anti-hIgG parental Mabs were bound monovalently to the immobilized hIgG. The observed equilibrium association constant (K _ass) values obtained in our last work [1] by solid-phase radioimmunoassay are consistent with those constants obtained by IAsys. The K _ass of anti-HRP Mabs was about 50 times higher than that of anti-HRP shoulder of Babs. The dissociation rate constant (k _diss) for anti-HRP shoulder of Babs was 21 times higher than k _diss for anti-HRP Mabs. The comparison of the kinetic parameters for bivalent anti-HRP Mabs and Babs derived from anti-Mb/HRP and anti-hIgG/HRP, allowed to calculate that 95% of bound anti-HRP Mabs are bivalently linked with immobilized HRP, whereas only 5% of bound anti-HRP Mabs are monovalently linked. In general, the data obtained indicate that Babs bearing an enzyme-binding site may not be efficiently used instead of traditional antibody–enzyme conjugates in the case of binding of bivalent Mabs.     

Study of the physical meaning of the binding parameters involved in effector-target conjugation using monoclonal antibodies against adhesion molecules and cholera toxin

In earlier work, we established a mathematical model to characterize the binding properties of cytotoxic cells to target cells. These properties can be described by the values of the maximum effector and target conjugate frequencies, alpha(max) and beta(max), respectively, and the dissociation constant of the conjugates formed, K(D) (Garcia-Pe?arrubia, P., Cabrera, L., Alvarez, R., and Galvez, J., J. Immunol. Methods 155 (1992) 133). Here, we address the problem of exploring the physical meaning of these parameters and their relationships with cytotoxicity. With this purpose, conjugation between a human leukemic NK cell line (NKL) and K562 tumor cells has been studied from binding isotherms obtained from data of effector (alpha) and target (beta) conjugate frequencies measured by flow cytometry analysis at different effector-to-target ratios (R). The results have been compared to those obtained after target cells treatment with monoclonal antibodies recognizing adhesion molecules ICAM-1 (CD54) and LFA-3 (CD58) (which are able to block some of the receptors implicated in conjugation), as well as with cholera toxin (CTX) that can modify the state of affinity of some adhesion molecules such as LFA-1 (CD11a/CD18). The results show that: (1) blocking adhesion receptors CD54 and CD58 on the surface of target cells leads to a significant decrease of alpha(max) and beta(max), indicating that these parameters are related to the density of expression of receptors implicated in effector-target adhesion; (2) treatment of effector cells with CTX induced an increase of K(D), demonstrating that this parameter is associated with the effector-target affinity of the system; and (3) parallel experiments of conjugation and cytotoxicity showed that effector-target affinity and saturability influence the cytotoxic activity of the effector population.     

Molecular basis for the binding polyspecificity of an anti-cholera toxin peptide 3 monoclonal antibody

The onset of autoimmune diseases is proposed to involve binding promiscuity of antibodies (Abs) and T‐cells, an often reported yet poorly understood phenomenon. Here, we attempt to approach two questions: first, is binding promiscuity a general feature of monoclonal antibodies (mAbs) and second, what is the molecular basis for polyspecificity? To this end, the anti‐cholera toxin peptide 3 (CTP3) mAb TE33 was investigated for polyspecific binding properties. Screening of phage display libraries identified two epitope‐unrelated peptides that specifically bound TE33 with affinities similar to or 100‐fold higher than the wild‐type epitope. Substitutional analyses revealed distinct key residue patterns recognized by the antibody suggesting a unique binding mode for each peptide. A database query with one of the consensus motifs and a subsequent binding study uncovered 45 peptides (derived from heterologous proteins) that bound TE33. To better understand the structural basis of the observed polyspecificity we modeled the new cyclic epitope in complex with TE33. The interactions between this peptide and TE33 suggested by our model are substantially different from the interactions observed in the X‐ray structure of the wild‐type epitope complex. However, the overall binding conformation of the peptides is similar. Together, our results support the theory of a general polyspecific potential of mAbs. Copyright © 2005 John Wiley & Sons, Ltd.     

Quantitative binding studies of a monoclonal antibody to immobilized protein-A.

Binding constants and column capacities are important factors for evaluating an affinity chromatography system. Scatchard plots based on classical equilibrium binding have been used to demonstrate how association constants and column capacities can be computed from simple binding experiments and a commercial computer program. The analysis has been demonstrated on a monoclonal antibody type IgG-1 Kappa against Serratia marcescens nuclease and a commercial protein-A column, Prosep-A. Additional analyses were performed with the same antibody and other protein-A affinity systems and the different binding constants and column capacities obtained confirmed the value of the analysis for evaluating an affinity system.     

Equilibrium binding parameters of an autoimmune monoclonal antibody specific for double-stranded DNA

Two techniques have been developed to estimate binding parameters for Jel 241 under equilibrium conditions. Jel 241 is an autoimmune monoclonal antibody derived from an NZB/NZW mouse which binds to double-stranded DNA. Thermal denaturation profiles of poly[d(AT)] were measured in the presence of increasing concentrations of IgG Jel 241. From these data it was estimated that the IgG occludes 12 base-pairs on duplex DNA, and the binding to double-stranded DNA was at least four orders of magnitude greater than to single-stranded DNA. In addition, intrinsic association constants (K(O)) were measured by a gel filtration technique for the interaction of both Fab and IgG Jel 241 to native calf thymus DNA. K(O) for the IgG was only 60-fold greater than for the Fab fragment for which K(O) was 4.4 X 10(4) M-1 at an NaCl concentration of 150 mM. Also, K(O) for the Fab increased dramatically with decreasing ionic strength, suggesting that there are four phosphates involved in the interaction. These techniques should be applicable to most autoimmune antibodies which bind to nucleic acid polymers.     

Preparation and characterization of monoclonal antibodies to the cholera toxin

Monoclonal antibodies to cholera toxin were obtained. They do not cross-react with the termolabile toxin (LT) of Escherichia coli, ricin, diphtherial toxin, staphylococcus enterotoxins of SEA, SEB, SEI, SEG, or the lethal factor and protective antigen of the anthrax toxin. Pairs of antibodies for the quantitative measurement of the cholera toxin in sandwich enzyme immunoassay (EIA) were selected. The detection limit of the toxin is 0.2 ng/ml for plate EIA and 0.44 ng/ml for microchip EIA. The presence of milk, broth, or surface water in the toxin samples does not reduce the sensitivity of EIA.     

Use of bacteriophage T7 displayed peptides for determination of monoclonal antibody specificity and biosensor analysis of the binding reaction

A heptapeptide library displayed by bacteriophage T7 was used to characterize epitopes of the monoclonal antibodies F4, F5, and LT1 directed against mouse polyomavirus large T-antigen. Phage selected by biopanning was cloned by plaque isolation, and the binding specificity of individual clones was confirmed by enzyme-linked immunosorbent assay. In phage reacting with the F5 antibody the deduced amino acid sequence of the displayed peptides corresponded to a segment of large T-antigen. In phage reacting with the antibodies F4 and LT1, no such similarity was observed. The kinetics of phage particle-monoclonal antibody complex formation and dissociation was analyzed in an optical biosensor instrument. Sensor chips of standard quality were useful for binding analysis of T7 phage in crude lysates of infected Escherichia coli. We synthesized peptides corresponding to selected consensus sequences and showed by biosensor analysis that these peptides (linear NH3-CPNSLTPADPTMDY-COOH and NH3-NSLTPCNNKPSNRC-COOH with an intramolecular S--S bridge) were able to compete with large T-antigen in binding to the corresponding antibodies (LT1 and F4). These synthetic peptides were also used for gentle and specific dissociation of large T-antigen-antibody complexes. The results demonstrate the potential of phage T7 for display of peptides and for rapid analysis of interactions of these peptides with ligands.     

A flow method for determination of the kinetic parameters for immobilized enzymes.

A flow method is described for determination of the kinetics parameters (V-m and K-m) for enzymes that are bound to particles, to membranes, and to the interior surfaces of tubes. Substrate solution is pumped through Tygon tubing to a microvolume flow cell and back into the reaction mixture, the flow rate being adjusted to be faster than the rate of formation of product. To illustrate the technique, it is applied to the determination of the parameters for electric-eel acetylcholinesterase attached to particles, to membranes, and to the inner surface of nylon tubing.     

Use of an oxygen microsensor for the determination of intrinsic kinetic parameters of an immobilized oxygen reducing enzyme

An oxygen microsensor was used to measure internal oxygen profiles in biocatalyst particles of different diameter and activity. The particles were made of agarose gel and contained an oxygen reducing enzyme, L-lactate mono-oxygenase. The kinetics of the enzyme could be well described by the Michaelis-Menten equation. From the internal substrate concentration profile the intrinsic kinetic parameters were determined by means of fitting a simulated profile to the measurements, using Marquardt's algorithm. The intrinsic kinetic parameters found following this procedure appeared to be independent of particle radius or enzyme loading used, proving the method to be reliable. These parameters were also compared with the kinetic parameters of the free enzyme which were determined in a biological oxygen monitoring system. The intrinsic kinetic parameters showed a decrease with a factor 2.3 for V(m) value and with a factor 2.7 for the K(m) value compared to the parameters for the free enzyme. From this the conclusion can be drawn that the immobilization as such or the carrier material not only can have an effect on the maximum intrinsic conversion rate (V(m)) but also on the affinity of the enzyme (K(m)) for oxygen.     

Effect of methanol on the interaction of monoclonal antibody with free and immobilized atrazine studied using the resonant mirror-based biosensor

The interaction of monoclonal anti-atrazine antibody D6F3 with free and immobilized atrazine was studied using the resonant mirror-based optical biosensor system IAsys. The binding of antibody to atrazine immobilized on silanized surface through albumin spacer was studied in the presence of methanol. The highest affinity was observed in 10% methanol, the kinetic equilibrium association constant KA was 1.16 x 10(9) mol-1 l compared to 4.3 x 10(8) mol-1 l determined in water. The surface binding capacity was 2-fold lower in the presence of methanol compared to aqueous buffer solution. The kinetic rate constants were significantly improved with low contents of methanol; the fastest association and slowest dissociation occurred at 5 and 10% methanol, respectively. The formation of immunocomplexes was observed even in the presence of 50% methanol. To avoid possible disturbing effects resulting from the immobilization of atrazine, the interaction of free atrazine and antibody was studied using the competitive procedure. The determined values of KA were 9.35, 0.73 and 410 x 10(6) mol-1 l for interactions carried out in 10, 30 and 50% methanol, respectively. For practical determination of atrazine using this antibody, the content of 10% methanol in the assay mixture seems to be the best choice. Thirty percent methanol resulted in the lowest affinity; 50% methanol provides the highest affinity, but much smaller signal is measured. The affinity biosensor system IAsys appeared to be a suitable, rapid and convenient tool for studies of binding interactions in the presence of organic solvents.     

Cell cycle kinetic measurements in an irradiated rat rhabdomyosarcoma using a monoclonal antibody to bromodeoxyuridine

Cell cycle kinetics after X-irradiation were studied in a solid rat rhabdomyosarcoma using a monoclonal antibody to bromodeoxyuridine (BrdUrd) in cells in which the DNA was labeled by BrdUrd. It could be shown that this tumor was composed of about 80% diploid host cells, and only 20% of the cells in the dissociated tumor were actually tetraploid tumor cells. When rats were injected intraperitoneally with BrdUrd to label S-phase cells in the tumor, only a fraction of both types of cells became labeled with BrdUrd during S-phase, even 24 h after injection. The diploid BrdUrd-labeled cells progressed rapidly into cycle; 4 h after injection of BrdUrd, labeled diploid G1-phase cells could be observed. Only 25% of the tetraploid S-phase cells could be labeled by a single injection of BrdUrd (160 mg/kg body weight). These labeled tetraploid cells progressed through the cell cycle with similar velocities as did labeled diploid cells. Using a "Mini Osmotic Pump" containing bromodeoxycytidine (BrdCyd) at high concentration (0.3 mol/L) that released BrdCyd continuously into the organism where it was converted to BrdUrd, it could be shown that after 2 days about 60% of cells in S-phase and 70% of cells in G2-phase were labeled. The fraction of labeled G2-phase cells in irradiated tumors (D = 10 and 20 Gy) was enhanced between 10 and 50 h after irradiation due to a radiation-induced G2 block in cycling tetraploid tumor cells.(ABSTRACT TRUNCATED AT 250 WORDS)     

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^TM, 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 results 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.     

Equilibrium and kinetic parameters for the interaction of a monoclonal antibody with liposomes bearing fluorescent haptens

We have obtained equilibrium and rate constants for the interaction of monoclonal IgG and its monovalent Fab fragment with a hapten (fluorescein) attached to the surface of a liposome. Binding was detected at nanomolar hapten concentrations by the quenching of the hapten's fluorescence on antibody binding. The binding parameters were computed from nonlinear least squares fits, using mass-action models. Crypticity of the hapten was observed and interpreted as an equilibrium between two states, extended and sequestered, the latter representing haptens associated with the membrane surface. Depending on the lipid composition of the liposomes, the fraction of sequestered hapten ranged from 0.25 to 0.975; transitions between the two states took place on the time scale of minutes. Fab interactions with extended hapten on the membrane were similar to interactions with water-soluble hapten. The ability of IgG to bind bivalently to membrane gave it an avidity two to six times the affinity for purely monovalent binding. However, the equilibrium constant for the monovalent-bivalent binding equilibrium was effectively four to five orders of magnitude less than that for the initial binding step. This probably reflects steric penalties for the simultaneous binding of two haptens on a membrane.     

Affinity purification of tetanus toxin using polyclonal and monoclonal antibody immunoadsorbents

Tetanus toxin has been immunopurified on immunoadsorbent columns derived from equine polyclonal antitoxin coupled to cyanogen bromide-activated Sepharose CL4B. Desorption of bound toxin in active form was achieved only when the immunoadsorbent was mixed with Sephadex G15 and this mixture overlaid on a further volume of Sephadex G15. With equine antibody, 64% of adsorbed toxin was recovered with a specific activity of 2400 limiting flocculation units (Lf)/mg protein N (1.2 × 10⁸ minimum lethal doses (MLD)/mg protein N). Similarly prepared immunoadsorbent derived from murine monoclonal antitoxin of low affinity had improved desorption with less acidic desorbents, without the requirement for Sephadex G15; greater than 80% of adsorbed toxin was recovered with a specific activity of 3000 Lf/mg protein N (1.6 × 10⁸ MLD/mg protein N).     

Second generation mimics of ganglioside GM1 as artificial receptors for cholera toxin: replacement of the sialic acid moiety

In a program directed towards the design and synthesis of mimics of ganglioside GM1, the NeuAc recognition domain was replaced by simple hydroxy acids, and the affinity of the new ligands to the cholera toxin was determined by fluorescence spectroscopy. The (R)-lactic acid derivative 4 was found to display the highest affinity of the series (KD = 190 microM).     

Affinity purification of tetanus toxin using polyclonal and monoclonal antibody immunoadsorbents

Tetanus toxin has been immunopurified on immunoadsorbent columns derived from equine polyclonal antitoxin coupled to cyanogen bromide-activated Sepharose CL4B. Desorption of bound toxin in active form was achieved only when the immunoadsorbent was mixed with Sephadex G15 and this mixture overlaid on a further volume of Sephadex G15. With equine antibody, 64% of adsorbed toxin was recovered with a specific activity of 2400 limiting flocculation units (Lf)/mg protein N (1.2 X 10(8) minimum lethal doses (MLD)/mg protein N). Similarly prepared immunoadsorbent derived from murine monoclonal antitoxin of low affinity had improved desorption with less acidic desorbents, without the requirement for Sephadex G15; greater than 80% of adsorbed toxin was recovered with a specific activity of 3000 Lf/mg protein N (1.6 X 10(8) MLD/mg protein N).     

Chemometric exploration of an amperometric biosensor array for fast determination of wastewater quality

Four wastewater samples of different treatment qualities; untreated, alarm, alert and normal, from a Swedish chemi-thermo-mechanical pulp mill and pure water were investigated using an amperometric bio-electronic tongue in a batch cell. The aim was to explore enzymatically modified screen-printed amperometric sensors for the discrimination of wastewater quality and to counteract the inherent drift. Seven out of eight platinum electrodes on the array were modified with four different enzymes; tyrosinase, horseradish peroxidase, acetyl cholinesterase and butyryl cholinesterase. At a constant potential the current intensity on each sensor was measured for 200s, 100s before injection and 100s after injection of the sample. The dynamic biosensor response curves from the eight sensors were used for principal component analysis (PCA). A simple baseline and sensitivity correction equivalent to multiplicative drift correction (MDC), using steady state intensities of reference sample (catechol) recordings, was employed. A clear pattern emerged in perfect agreement with prior knowledge of the samples explaining 97% of the variation in the data by two principal components (PCs). The first PC described the treatment quality of the samples and the second PC described the difference between treated and untreated samples. Horseradish peroxidase and pure platinum sensors were found to be the determinant sensors, while the rest did not contribute much to the discrimination. The wastewater samples were characterized by the chemical oxygen demand (COD), biological oxygen demand (BOD), total organic carbon (TOC), inhibition of nitrification, inhibition of respiration and toxicity towards Vibrio fischeri using Microtox, the freshwater alga Pseudokirchneriella subcapita and the freshwater crustacean Daphnia magna.