Two routes for production and purification of Fab fragments in biopharmaceutical discovery research: Papain digestion of mAb and transient expression in mammalian cells

Fab (fragment that having the antigen binding site) of a monoclonal antibody (mAb) is widely required in biopharmaceutical research and development. At Centocor, two routes of Fab production and purification were used to enable a variety of research and development efforts, particularly, crystallographic studies of antibody–antigen interactions. One route utilizes papain digestion of an intact monoclonal antibody for Fab fragment production. After digestion, separation of the Fab fragment from the Fc (fragment that crystallizes) and residual intact antibody was achieved using protein A affinity chromatography. In another route, His-tagged Fab fragments were obtained by transient expression of an appropriate construct in mammalian cells, and typical yields are 1–20 mg of Fab fragment per liter of cell culture. The His-tagged Fab fragments were first captured using immobilized metal affinity chromatography (IMAC). To provide high quality protein sample for crystallization, Fabs from either proteolytic digestion or from direct expression were further purified using size-exclusion chromatography (SEC) and/or ion-exchange chromatography (IEC). The purified Fab fragments were characterized by mass spectrometry, SDS–PAGE, dynamic light scattering, and circular dichroism. Crystallization experiments demonstrated that the Fab fragments are of high quality to produce diffraction quality crystals suitable for X-ray crystallographic analysis.     

Evaluation of chemiluminescent estradiol conjugates by using a surface plasmon resonance detector

A series of chemiluminescent 17beta-estradiol probes were synthesized. Relative equilibrium dissociation constants (K(D)) for the interaction of an anti-E(2) Fab fragment for the probes in solution were evaluated using a single E(2)-analog biosensor surface on a BIAcore surface plasmon resonance instrument. The results show the antibody fragment binds all chemiluminescent conjugates tested with high affinity showing only minor preferences for site of substitution (C6 versus C7), stereochemistry (alpha versus beta), or linker moiety.     

Affinity electrophoresis used for determination of binding constants for antibody-antigen reactions.

The use of affinity electrophoresis in agarose gels for determination of binding constants for the interaction of antigens with monoclonal antibodies is exemplified for monoclonal anti-human serum albumin and anti-alpha 1-fetoprotein antibodies. The calculated binding constants are verified by independent binding assays. The electrophoretic separation of antigen-antibody complexes of different stoichiometry is also demonstrated. Thus, affinity electrophoresis represents an alternative method for both qualitative and quantitative assessment of antigen-antibody interactions.     

Biosensor-surface plasmon resonance: quantitative analysis of small molecule-nucleic acid interactions

Surface plasmon resonance (SPR)-biosensor techniques directly provide essential information for the study and characterization of small molecule-nucleic acid interactions, and the use of these methods is steadily increasing. The method is label-free and monitors the interactions in real time. Both dynamic and steady-state information can be obtained for a wide range of reaction rates and binding affinities. This article presents the basics of the SPR technique, provides suggestions for experimental design, and illustrates data processing and analysis of results. A specific example of the interaction of a well-known minor groove binding agent, netropsin, with DNA is evaluated by both kinetic and steady-state SPR methods. Three different experiments are used to illustrate different approaches and analysis methods. The three sets of results show the reproducibility of the binding constants and agreement from both steady-state and kinetic analyses. These experiments also show that reliable kinetic information can be obtained, even with difficult systems, if the experimental conditions are optimized to minimize mass transport effects. Limitations of the biosensor-SPR technique are also discussed to provide an awareness of the care needed to conduct a successful experiment.     

Analysis of the binding of the Fab fragment of monoclonal antibody NC10 to influenza virus N9 neuraminidase from tern and whale using the BIAcore biosensor: effect of immobilization level and flow rate on kinetic analysis.

The binding of the Fab fragment of monoclonal antibody NC10 to influenza virus N9 neuraminidase, isolated from tern and whale, was measured using an optical biosensor. Both neuraminidases, homotetramers of 190 kDa, were immobilized to avoid multivalent binding, and the binding of the monovalent NC10 Fab to immobilized neuraminidase was analyzed using the 1:1 Langmuir binding model. A contribution of mass transport to the kinetic constants was demonstrated at higher surface densities and low flow rates, and was minimized at low ligand densities and relatively high flow rates (up to 100 microl/min). Application of a global fitting algorithm to a 1:1 binding model incorporating a correction term for mass transport indicated that mass transport was minimized under appropriate experimental conditions; analysis of binding data with a mass transport component, using this model, yielded kinetic constants similar to those obtained with the 1:1 Langmuir binding model applied to binding data where mass transport had been minimized experimentally. The binding constant for binding of NC10 Fab to N9 neuraminidase from tern influenza virus (K(A) = 6.3 +/- 1.3 x 10(7) M(-1)) was about 15-fold higher than that for the NC10 Fab binding to N9 neuraminidase from whale influenza virus (K(A) = 4.3 +/- 0.7 x 10(6) M(-1)). This difference in binding affinity was mainly attributable to a 12-fold faster dissociation rate constant of the whale neuraminidase-NC10 Fab complex and may be due to either (i) the long-range structural effects caused by mutation of two residues distant from the binding epitope or (ii) differences in carbohydrate residues, attached to Asn(200), which form part of the binding epitope on both neuraminidases to which NC10 Fab binds.     

Expression of multivalency in the affinity chromatography of antibodies. Appendix: Derivation and evaluation of equations for independent bivalent interacting systems in quantitative affinity chromatography.

The expression of multivalency in the interaction of antibody with immobilized antigen was evaluated by quantitative affinity chromatography. Zones of radioisotopically labeled bivalent immunoglobulin A monomer derived from the myeloma protein TEPC 15 were eluted from columns of phosphorylcholine-Sepharose both in the absence and presence of competing soluble phosphorylcholine. At sufficient immobilized phosphorylcholine concentration, the variation of elution volume of bivalent monomer with soluble ligand was found to deviate from that observed for the univalent binding of the corresponding Fab fragment. In addition, the apparent binding affinity of the bivalent monomer increased with immobilized antigen density. Use of equations relating the variation of elution volume with free ligand concentration for a bivalent binding protein allowed calculation of microscopic single-site binding parameters for the bivalent monomeric antibody to both immobilized and soluble phosphorylcholine. The chromatographic data not only demonstrate the effect of multivalency on apparent binding affinity but also offer a relatively simple means to measure microscopic dissociation constants for proteins participating in bivalent interactions with their ligands.     

Thermodynamic analysis of protein interactions with biosensor technology

A methodology using biosensor technology for combined kinetic and thermodynamic analysis of biomolecular interactions is described. Rate and affinity constants are determined with BIAcore. Thermodynamics parameters, changes in free energy, enthalpy and entropy, are evaluated from equilibrium data and by using rate constants and transition state theory. The methodology using van't Hoff theory gives complementary information to microcalorimetry, since only the direct binding is measured with BIAcore whereas microcalorimetry measures all components, including e.g. hydration effects. Furthermore, BIAcore gives possibilities to gain new information by thermodynamic analysis of the rate constants.     

Structure-binding relationships for the interaction between a vancomycin monoclonal antibody Fab fragment and a library of vancomycin analogues and tracers

A series of vancomycin analogues and tracers were synthesized, and their binding interactions with an anti-vancomycin Fab fragment were evaluated under mass transport limiting conditions using surface plasmon resonance detection. Differences observed in binding interactions were utilized to define the vancomycin structural elements critical for antibody recognition. Major structural regions of vancomycin shown to play an important role in anti-vancomycin Fab fragment recognition include two sugar moieties and one chlorinated phenyl ring. The N-methylleucyl residue, the carboxy terminal residue, and residues in the peptide-binding region of vancomycin have minimal impact on the anti-vancomycin Fab fragment/vancomycin binding interaction. The selection of an antibody with such binding properties plays a critical role in the development of a vancomycin immunoassay that employs stable calibrators and controls.     

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.     

Synthetic peptide vaccine development: measurement of polyclonal antibody affinity and cross-reactivity using a new peptide capture and release system for surface plasmon resonance spectroscopy

A method has been developed for measurement of antibody affinity and cross-reactivity by surface plasmon resonance spectroscopy using the EK-coil heterodimeric coiled-coil peptide capture system. This system allows for reversible capture of synthetic peptide ligands on a biosensor chip surface, with the advantage that multiple antibody-antigen interactions can be analyzed using a single biosensor chip. This method has proven useful in the development of a synthetic peptide anti-Pseudomonas aeruginosa (PA) vaccine. Synthetic peptide ligands corresponding to the receptor binding domains of pilin from four strains of PA were conjugated to the E-coil strand of the heterodimeric coiled-coil domain and individually captured on the biosensor chip through dimerization with the immobilized K-coil strand. Polyclonal rabbit IgG raised against pilin epitopes was injected over the sensor chip surface for kinetic analysis of the antigen-antibody interaction. The kinetic rate constants, k(on) and k(off), and equilibrium association and dissociation constants, KA and KD, were calculated. Antibody affinities ranged from 1.14 x 10(-9) to 1.60 x 10(-5) M. The results suggest that the carrier protein and adjuvant used during immunization make a dramatic difference in antibody affinity and cross-reactivity. Antibodies raised against the PA strain K pilin epitope conjugated to keyhole limpet haemocyanin using Freund's adjuvant system were more broadly cross-reactive than antibodies raised against the same epitope conjugated to tetanus toxoid using Adjuvax adjuvant. The method described here is useful for detailed characterization of the interaction of polyclonal antibodies with a panel of synthetic peptide ligands with the objective of obtaining high affinity and cross-reactive antibodies in vaccine development.     

Biotinylated steroid derivatives as ligands for biospecific interaction analysis with monoclonal antibodies using immunosensor devices

Systematic ligand-binding studies of the biospecific interaction between steroids and antisteroid antibodies can be performed in real time using biosensor techniques. In this study, quartz crystal microbalance (QCM) and surface plasmon resonance (SPR) biosensor systems were applied. Different biotinylated testosterone (T) and 17beta-estradiol (E2) derivatives were preincubated with streptavidin and immobilized on the sensor surfaces. We obtained low matrix densities of antigen enabling the investigation of the binding kinetics and position specificities of various anti-E2 and anti-T monoclonal antibodies (mAbs) to these steroidal compounds. The highest immunoreactivity of anti-E2 and anti-T mAbs is not necessarily for the specific modified steroid that was used as a protein-coupled hapten for immunization. The kinetic data confirm that both 3- and 19-specific anti-T mAbs do not discriminate between the 3- and 19-biotinylated T derivatives, whereas the 7alpha-biotinylated T probe showed no affinity to these two anti-T mAbs. In the case of the 3-specific anti-E2 mAb, comparable interaction data were found for 3- and 6alpha-biotinylated E2 compounds. The 6-specific anti-E2 mAb showed comparable ligand binding, but a significant higher dissociation rate to the position-specific antigen. The QCM and SPR results correspond well to the data from cross-reactivity studies in solution as well as to enzyme immunoassay equilibrium measurements.     

Crystal structure of an in vitro affinity- and specificity-matured anti-testosterone Fab in complex with testosterone. Improved affinity results from small structural changes within the variable domains

A highly selective, high affinity recombinant anti-testosterone Fab fragment has been generated by stepwise optimization of the complementarity-determining regions (CDRs) by random mutagenesis and phage display selection of a monoclonal antibody (3-C(4)F(5)). The best mutant (77 Fab) was obtained by evaluating the additivity effects of different independently selected CDR mutations. The 77 Fab contains 20 mutations and has about 40-fold increased affinity (K(d) = 3 x 10(-10) m) when compared with the wild-type (3-C(4)F(5)) Fab. To obtain structural insight into factors, which are needed to improve binding properties, we have determined the crystal structures of the mutant 77 Fab fragment with (2.15 A) and without testosterone (2.10 A) and compared these with previously determined wild-type structures. The overall testosterone binding of the 77 Fab is similar to that of the wild-type. The improved affinity and specificity of the 77 Fab fragment are due to more comprehensive packing of the testosterone with the protein, which is the result of small structural changes within the variable domains. Only one important binding site residue Glu-95 of the heavy chain CDR3 is mutated to alanine in the 77 Fab fragment. This mutation, originally selected from the phage library based on improved specificity, provides more free space for the testosterone D-ring. The light chain CDR1 of 77 Fab containing eight mutations has the most significant effect on the improved affinity, although it has no direct contact with the testosterone. The mutations of CDR-L1 cause a rearrangement in its conformation, leading to an overall fine reshaping of the binding site.     

Crystal structure of an anti-interleukin-2 monoclonal antibody Fab complexed with an antigenic nonapeptide

The three-dimensional structure of the Fab fragment of a monoclonal antibody (LNKB-2) to human interleukin-2 (IL-2) complexed with a synthetic antigenic nonapeptide, Ac-Lys-Pro-Leu-Glu-Glu-Val-Leu-Asn-Leu-OMe, has been determined at 3.0 A resolution. In the structure, four out of the six hypervariable loops of the Fab (complementarity determining regions [CDRs] L1, H1, H2, and H3) are involved in peptide association through hydrogen bonding, salt bridge formation, and hydrophobic interactions. The Tyr residues in the Fab antigen binding site play a major role in antigen-antibody recognition. The structures of the complexed and uncomplexed Fab were compared. In the antigen binding site the CDR-L1 loop of the antibody shows the largest structural changes upon peptide binding. The peptide adopts a mostly alpha-helical conformation similar to that in the epitope fragment 64-72 of the IL-2 antigen. The side chains of residues Leu 66, Val 69, and Leu 70, which are shielded internally in the IL-2 structure, are involved in interactions with the Fab in the complex studied. This indicates that antibody-antigen complexation involves a significant rearrangement of the epitope-containing region of the IL-2 with retention of the alpha-helical character of the epitope fragment.     

Active site-independent recognition of substrates and product by bovine prothrombinase: a fluorescence resonance energy transfer study

The conversion of prothrombin to thrombin is catalyzed by prothrombinase, an enzyme complex composed of the serine proteinase factor Xa and a cofactor protein, factor Va, assembled on membranes. Kinetic studies indicate that interactions with extended macromolecular recognition sites (exosites) rather than the active site of prothrombinase are the principal determinants of binding affinity for substrate or product. We now provide a model-independent evaluation of such ideas by physical studies of the interaction of substrate derivatives and product with prothrombinase. The enzyme complex was assembled using Xa modified with a fluorescent peptidyl chloromethyl ketone to irreversibly occlude the active site. Binding was inferred by prethrombin 2-dependent perturbations in the fluorescence of Oregon Green(488) at the active site of prothrombinase. Active site-independent binding was also unequivocally established by fluorescence resonance energy transfer between 2,6-dansyl tethered to the active site of Xa and eosin tethered to the active sites of either thrombin or meizothrombin des fragment 1. Comparable interprobe distances obtained from these measurements suggest that substrate and product interact equivalently with the enzyme. Competition established the ability of a range of substrate or product derivatives to bind in a mutually exclusive fashion to prothrombinase. Equilibrium dissociation constants obtained for the active site-independent binding of prothrombin, prethrombin 2, meizothrombin des fragment 1 and thrombin to prothrombinase were comparable with their affinities inferred from kinetic studies using active enzyme. Our findings directly establish that binding affinity is principally determined by the exosite-mediated interaction of either the substrate, both possible intermediates, or product with prothrombinase. A single type of exosite binding interaction evidently drives affinity and binding specificity through the stepwise reactions necessary for the two cleavage reactions of prothrombin activation and product release.     

Direct comparison of binding equilibrium, thermodynamic, and rate constants determined by surface- and solution-based biophysical methods

The binding interactions of small molecules with carbonic anhydrase II were used as model systems to compare the reaction constants determined from surface- and solution-based biophysical methods. Interaction data were collected for two arylsulfonamide compounds, 4-carboxybenzenesulfonamide (CBS) and 5-dimethyl-amino-1-naphthalene-sulfonamide (DNSA), binding to the enzyme using surface plasmon resonance, isothermal titration calorimetry, and stopped-flow fluorescence. We demonstrate that when the surface plasmon resonance biosensor experiments are performed with care, the equilibrium, thermodynamic, and kinetic constants determined from this surface-based technique match those acquired in solution. These results validate the use of biosensor technology to collect reliable data on small molecules binding to immobilized macromolecular targets. Binding kinetics were shown to provide more detailed information about complex formation than equilibrium constants alone. For example, although carbonic anhydrase II bound DNSA with twofold higher affinity than CBS, kinetic analysis revealed that CBS had a fourfold slower dissociation rate. Analysis of the binding and transition state thermodynamics also revealed significant differences in the enthalpy and entropy of complex formation. The lack of labeling requirements, high information content, and high throughput of surface plasmon resonance biosensors will make this technology an important tool for characterizing the interactions of small molecules with enzymes and receptors.     

The mechanism of reassembly of immunoglobulin G.

The noncovalent interaction of light (L) chain with heavy (H) chain or Fd isolated from a human myeloma protein Jo (IgG1, kappa) was studied by following circular dichroic (CD) change at 235 nm. The dimerization constants of Jo-L chain determined by measuring the CD change at 293 nm with protein concentration showed that the Jo-L chain exists as the monomeric form under the experimental conditions used for recombination with H chain. The second-order rate constants for the interaction between H and L chains were in good agreement with those for the interaction between Fd and L chain at various pH values. The binding behavior of L chain to Fd could be described by a single association constant. In the interpretation of the binding of L chain to H chain, however, it was necessary to assume that the binding of L chain to one of the two sites on H chain dimer (H2) decreases the affinity of the other site for L chain. The binding constant of the first L chain to H2 was the same as that of L chain to Fd. Renaturation processes of L chain, Fd, Fab(SS) fragment (with intact interchain disulfide bond), and Fab(RA) fragment (in which the interchain disulfide bond had been reduced and alkylated) from the denatured states in 0.5 or 1 M acetic acid on neutralization were studied. The renaturation of Fd occurred very rapidly, while that of L chain consisted of a very rapid process and a slow process which followed first-order kinetics. The renaturation process of Fab(SS) consisted of rapid and slow phases, of which the latter followed first-order kinetics. The renaturation process of Fab(RA) also consisted of rapid and slow phases, but the latter process followed second-order kinetics. The overall rate constant of renaturation of Fab(RA) was the same as that of the reformation of Fab(RA) from isolated Fd and L chain. On the basis of these facts, the kinetic mechanism by which Fd and L chain recombine to yield Fab(RA) can be described in terms of the scheme Fd + L in equilibrium Fd ... L leads to Fab(RA), where Fd ... L is an intermediate, and CD change is only observed in the second unimolecular process and not in the first bimolecular process.     

Real-time analysis of the assembly of ligand, receptor, and G protein by quantitative fluorescence flow cytometry.

We describe a general approach for the quantitative analysis of the interaction among fluorescent peptide ligands (L), receptors (R), and G proteins (G) using fluorescence flow cytometry. The scheme depends upon the use of commercially available fluorescent microbeads as standards to calibrate the concentration of fluorescent peptides in solution and the receptor number on cells in suspension. We have characterized a family of fluoresceinated formyl peptides and analyzed both steady-state and dynamic aspects of ligand formyl peptide-receptor interactions in digitonin-permeabilized human neutrophils. Detailed receptor-binding studies were performed with the pentapeptide N-formyl-Met-Leu-Phe-Phe-Lys-fluorescein. Equilibrium studies showed that GTP [S] caused a loss of binding affinity of approximately two orders of magnitude, from approximately 0.04 nM (LRG) to approximately 3 nM (LR), respectively. Kinetic studies revealed that this change in affinity was principally due to an increase in the dissociation rate constants from approximately 1 x 10(-3) s-1 (LRG) to approximately 1 x 10(-1) s-1 (LR). In contrast, the association rate constants in the presence and absence of guanine nucleotide (approximately 3 x 10(7) s-1 M-1) were statistically indistinguishable and close to the diffusion limit. In the presence of guanine nucleotide (LR), the kinetic data were adequately fit by a single-step reversible-binding model. In the absence of guanine nucleotides, not all receptors have rapid access to G to form the LRG ternary complex. Mathematically, those R that have rapid access to G are either precoupled to R or the association of G with R is fast compared to the association of L with R. The physiological consequences of coupling heterogeneity are discussed.     

Molecular interaction analysis in ligand design using mass transport,kinetic and thermodynamic methods

Ligand design in biotechnology is underpinned by the control of molecular affinity. Hence, measuring binding interactions is a key component in designing ligands for such uses as therapeutics, diagnostics, biomaterials and separation science. Mass transport, kinetic and thermodynamic methods have been used for macromolecular interaction analysis but also have potential applicability as direct methods for measuring small molecular interactions. They can enhance the ligand design process by providing the ability to choose ligands based on both their kinetic and thermodynamic binding properties.     

Multi-sample acoustic biosensing microsystem for protein interaction analysis

The current work describes a novel setup for multi-sample biomolecular analysis. It is based on the assembly of a dual acoustic device chip with a four-channel microfluidic module, forming an array of eight available domains for experiments. Initially, multiple detection was demonstrated via the specific interaction of neutravidin with four different biotinylated proteins, namely protein G, protein A, bovine serum albumin, and immunoglobulin G; results revealed a reproducibility between the microchannel domains better than 90%. Real-time analysis of the binding interactions was used to calculate the affinity and kinetic constants of the four biotinylated molecules binding to surface-immobilized neutravidin; this was the first time that this information was derived using a biosensing device and four biotinylated molecules. Interestingly, all calculated kinetic and affinity constants resemble those typical of antibody-antigen interactions, although the investigated specific binding was of avidin-biotin nature. Finally, under device pre-functionalization conditions, it was possible to probe eight interactions all together, exploiting the full capacity of the microsystem and reducing significantly the analysis time, contrary to the use of the standard acoustic device configuration. The outcome of this full-scale validation opens the way for the integrated acoustic platform to be implemented in even higher throughput detection for future diagnostic/biomedical applications, as well as in fundamental research studies regarding biomolecular interaction investigation and characterization.     

Determination of rate constants of antigen-antibody reaction. A theory

A new method of determination of rate constants for antigen-antibody interactions is proposed. This method is based on a solid phase immunoenzymatic analysis of the dynamics of elution of immobilized antigen-bound antibodies in the presence of a free antigen. The kinetics of this process is described by a system of differential equations, whose solution results in expression defining the dynamics of antibody interaction with immobilized and free antigens. Simple formulas were derived for the calculation of the rate and equilibrium constants for the antibody-antigen reaction on the basis of experimental kinetic curves. The use of theoretical kinetic curves for antibody elution showed that these formulas reflect with a high degree of accuracy the kinetic properties of the reaction under study.