Estimation of the hydrophobic effect in an antigen-antibody protein-protein interface.

Antigen-antibody complexes provide useful models for analyzing the thermodynamics of protein-protein association reactions. We have employed site-directed mutagenesis, X-ray crystallography, and isothermal titration calorimetry to investigate the role of hydrophobic interactions in stabilizing the complex between the Fv fragment of the anti-hen egg white lysozyme (HEL) antibody D1.3 and HEL. Crystal structures of six FvD1.3-HEL mutant complexes in which an interface tryptophan residue (V(L)W92) has been replaced by residues with smaller side chains (alanine, serine, valine, aspartate, histidine, and phenylalanine) were determined to resolutions between 1.75 and 2.00 A. In the wild-type complex, V(L)W92 occupies a large hydrophobic pocket on the surface of HEL and constitutes an energetic "hot spot" for antigen binding. The losses in apolar buried surface area in the mutant complexes, relative to wild-type, range from 25 (V(L)F92) to 115 A(2) (V(L)A92), with no significant shifts in the positions of protein atoms at the mutation site for any of the complexes except V(L)A92, where there is a peptide flip. The affinities of the mutant Fv fragments for HEL are 10-100-fold lower than that of the original antibody. Formation of all six mutant complexes is marked by a decrease in binding enthalpy that exceeds the decrease in binding free energy, such that the loss in enthalpy is partly offset by a compensating gain in entropy. No correlation was observed between decreases in apolar, polar, or aggregate (sum of the apolar and polar) buried surface area in the V(L)92 mutant series and changes in the enthalpy of formation. Conversely, there exist linear correlations between losses of apolar buried surface and decreases in binding free energy (R(2) = 0.937) as well as increases in the solvent portion of the entropy of binding (R(2) = 0.909). The correlation between binding free energy and apolar buried surface area corresponds to 21 cal mol(-1) A(-2) (1 cal = 4.185 J) for the effective hydrophobicity at the V(L)92 mutation site. Furthermore, the slope of the line defined by the correlation between changes in binding free energy and solvent entropy approaches unity, demonstrating that the exclusion of solvent from the binding interface is the predominant energetic factor in the formation of this protein complex. Our estimate of the hydrophobic contribution to binding at site V(L)92 in the D1.3-HEL interface is consistent with values for the hydrophobic effect derived from classical hydrocarbon solubility models. We also show how residue V(L)W92 can contribute significantly less to stabilization when buried in a more polar pocket, illustrating the dependence of the hydrophobic effect on local environment at different sites in a protein-protein interface.

Three-dimensional structure of the Fab from a human IgM cold agglutinin.

Cold agglutinins (CAs) are IgM autoantibodies characterized by their ability to agglutinate in vitro RBC at low temperatures. These autoantibodies cause hemolytic anemia in patients with CA disease. Many diverse Ags are recognized by CAs, most frequently those belonging to the I/i system. These are oligosaccharides composed of repeated units of N:-acetyllactosamine, expressed on RBC. The three-dimensional structure of the Fab of KAU, a human monoclonal IgM CA with anti-I activity, was determined. The KAU combining site shows an extended cavity and a neighboring pocket. Residues from the hypervariable loops V(H)CDR3, V(L)CDR1, and V(L)CDR3 form the cavity, whereas the small pocket is defined essentially by residues from the hypervariable loops V(H)CDR1 and V(H)CDR2. This fact could explain the V(H)4-34 germline gene restriction among CA. The KAU combining site topography is consistent with one that binds a polysaccharide. The combining site overall dimensions are 15 A wide and 24 A long. Conservation of key binding site residues among anti-I/i CAs indicates that this is a common feature of this family of autoantibodies. We also describe the first high resolution structure of the human IgM C(H)1:C(L) domain. The structural analysis shows that the C(H)1-C(L) interface is mainly conserved during the isotype switch process from IgM to IgG1.

X-ray crystal structure of an anti-Buckminsterfullerene antibody fab fragment: biomolecular recognition of C(60).

We have prepared a monoclonal Buckminsterfullerene specific antibody and report the sequences of its light and heavy chains. We also show, by x-ray crystallographic analysis of the Fab fragment and by model building, that the fullerene binding site is formed by the interface of the antibody light and heavy chains. Shape-complementary clustering of hydrophobic amino acids, several of which participate in putative stacking interactions with fullerene, form the binding site. Moreover, an induced fit mechanism appears to participate in the fullerene binding process. Affinity of the antibody-fullerene complex is 22 nM as measured by competitive binding. These findings should be applicable not only to the use of antibodies to assay and direct potential fullerene-based drug design but could also lead to new methodologies for the production of fullerene derivatives and nanotubes as well.

Structural, functional and immunological studies on a polymeric bacterial protein.

The characterization of proteins from Brucella spp, the causative agent of brucellosis, has been the subject of intensive research. We have described an 18-kDa cytoplasmic protein of Brucella abortus and shown the potential usefulness of this protein as an antigen for the serologic diagnosis of brucellosis. The amino acid sequence of the protein showed a low but significant homology with that of lumazine synthases. Lumazine is an intermediate product in bacterial riboflavin biosynthesis. The recombinant form of the 18-kDa protein (expressed in E. coli) folds like the native Brucella protein and has lumazine-synthase enzymatic activity. Three-dimensional analysis by X-ray crystallography of the homolog Bacillus subtilis lumazine synthase has revealed that the enzyme forms an icosahedral capsid. Recombinant lumazine synthase from B. abortus was crystallized, diffracted X rays to 2.7-A resolution at room temperature, and the structure successfully solved by molecular replacement procedures. The macromolecular assembly of the enzyme differs from that of the enzyme from B. subtilis. The Brucella enzyme remains pentameric (90 kDa) in its crystallographic form. Nonetheless, the active sites of the two enzymes are virtually identical at the structural level, indicating that inhibitors of these enzymes could be viable pharmaceuticals across a broad species range. We describe the structural reasons for the differences in their quaternary arrangement and also discuss the potential use of this protein as a target for the development of acellular vaccines.

Structural, functional and immunological studies on a polymeric bacterial protein

The characterization of proteins from Brucella spp, the causative agent of brucellosis, has been the subject of intensive research. We have described an 18-kDa cytoplasmic protein of Brucella abortus and shown the potential usefulness of this protein as an antigen for the serologic diagnosis of brucellosis. The amino acid sequence of the protein showed a low but significant homology with that of lumazine synthases. Lumazine is an intermediate product in bacterial riboflavin biosynthesis. The recombinant form of the 18-kDa protein (expressed in E. coli) folds like the native Brucella protein and has lumazine-synthase enzymatic activity. Three-dimensional analysis by X-ray crystallography of the homolog Bacillus subtilis lumazine synthase has revealed that the enzyme forms an icosahedral capsid. Recombinant lumazine synthase from B. abortus was crystallized, diffracted X rays to 2.7-A resolution at room temperature, and the structure successfully solved by molecular replacement procedures. The macromolecular assembly of the enzyme differs from that of the enzyme from B. subtilis. The Brucella enzyme remains pentameric (90 kDa) in its crystallographic form. Nonetheless, the active sites of the two enzymes are virtually identical at the structural level, indicating that inhibitors of these enzymes could be viable pharmaceuticals across a broad species range. We describe the structural reasons for the differences in their quaternary arrangement and also discuss the potential use of this protein as a target for the development of acellular vaccines.

Divergence in macromolecular assembly: X-ray crystallographic structure analysis of lumazine synthase from Brucella abortus.

We have determined the three-dimensional structure of 6, 7-dimethyl-8-ribityllumazine synthase (lumazine synthase) from Brucella abortus, the infectious organism of the disease brucellosis in animals. This enzyme catalyses the formation of 6, 7-dimethyl-8-ribityllumazine, the penultimate product in the synthesis of riboflavin. The three-dimensional X-ray crystal structure of the enzyme from B. abortus has been solved and refined at 2.7 A resolution to a final R-value of 0.18 (R(free)=0.23). The macromolecular assembly of the enzyme differs from that of the enzyme from Bacillus subtilis, the only other lumazine synthase structure known. While the protein from B. subtilis assembles into a 60 subunit icosahedral capsid built from 12 pentameric units, the enzyme from B. abortus is pentameric in its crystalline form. Nonetheless, the active sites of the two enzymes are virtually identical indicating inhibitors to theses enzymes could be effective pharmaceuticals across a broad species range. Furthermore, we compare the structures of the enzyme from B. subtilis and B. abortus and describe the C teminus structure which accounts for the differences in quaternary structure.

Crystallization and preliminary x-ray diffraction analysis of the lumazine synthase from Brucella abortus.

Lumazine synthase from Brucella abortus was overexpressed in Escherichia coli, refolded, and purified to apparent homogeneity. Crystals of lumazine synthase were grown by the hanging drop vapor diffusion method using polyethylene glycol 8000 or ammonium sulfate as precipitants. They belong to the trigonal space group P321 with cell parameters a = b = 132.00A, c = 167.25 A. A complete diffraction data set to 3.7 A resolution has been collected using synchrotron radiation. Preliminary analysis of the quaternary structure of this protein by means of a self-rotation function calculated with the diffraction data clearly indicates 532 symmetry compatible with the presence of an icosahedral lumazine synthase particle.

Anatomy of an antibody molecule: structure, kinetics, thermodynamics and mutational studies of the antilysozyme antibody D1.3.

Using site-directed mutagenesis, x-ray crystallography, microcalorimetric, equilibrium sedimentation and surface plasmon resonance detection techniques, we have examined the structure of an antibody-antigen complex and the structural and thermodynamic consequences of removing specific hydrogen bonds and van der Waals interactions in the antibody-antigen interface. These observations show that the complex is considerably tolerant, both structurally and thermodynamically, to the truncation of antibody and antigen side chains that form contacts. Alterations in interface solvent structure for two of the mutant complexes appear to compensate for the unfavorable enthalpy changes when antibody-antigen interactions are removed. These changes in solvent structure, along with the increased mobility of side chains near the mutation site, probably contribute to the observed entropy compensation. In concert, data from structural studies, reaction rates, calorimetric measurements and site directed mutations are beginning to detail the nature of antibody-protein antigen interactions.

A mutational analysis of binding interactions in an antigen-antibody protein-protein complex.

Alanine scanning mutagenesis, double mutant cycles, and X-ray crystallography were used to characterize the interface between the anti-hen egg white lysozyme (HEL) antibody D1.3 and HEL. Twelve out of the 13 nonglycine contact residues on HEL, as determined by the high-resolution crystal structure of the D1.3-HEL complex, were individually truncated to alanine. Only four positions showed a DeltaDeltaG (DeltaGmutant - DeltaGwild-type) of greater than 1.0 kcal/mol, with HEL residue Gln121 proving the most critical for binding (DeltaDeltaG = 2.9 kcal/mol). These residues form a contiguous patch at the periphery of the epitope recognized by D1.3. To understand how potentially disruptive mutations in the antigen are accommodated in the D1.3-HEL interface, we determined the crystal structure to 1.5 A resolution of the complex between D1.3 and HEL mutant Asp18 --> Ala. This mutation results in a DeltaDeltaG of only 0.3 kcal/mol, despite the loss of a hydrogen bond and seven van der Waals contacts to the Asp18 side chain. The crystal structure reveals that three additional water molecules are stably incorporated in the antigen-antibody interface at the site of the mutation. These waters help fill the cavity created by the mutation and form part of a rearranged solvent network linking the two proteins. To further dissect the energetics of specific interactions in the D1.3-HEL interface, double mutant cycles were carried out to measure the coupling of 14 amino acid pairs, 10 of which are in direct contact in the crystal structure. The highest coupling energies, 2.7 and 2.0 kcal/mol, were measured between HEL residue Gln121 and D1.3 residues VLTrp92 and VLTyr32, respectively. The interaction between Gln121 and VLTrp92 consists of three van der Waals contacts, while the interaction of Gln121 with VLTyr32 is mediated by a hydrogen bond. Surprisingly, however, most cycles between interface residues in direct contact in the crystal structure showed no significant coupling. In particular, a number of hydrogen-bonded residue pairs were found to make no net contribution to complex stabilization. We attribute these results to accessibility of the mutation sites to water, such that the mutated residues exchange their interaction with each other to interact with water. This implies that the strength of the protein-protein hydrogen bonds in these particular cases is comparable to that of the protein-water hydrogen bonds they replace. Thus, the simple fact that two residues are in direct contact in a protein-protein interface cannot be taken as evidence that there necessarily exists a productive interaction between them. Rather, the majority of such contacts may be energetically neutral, as in the D1.3-HEL complex.

Characterization of anti-anti-idiotypic antibodies that bind antigen and an anti-idiotype.

Two mouse monoclonal anti-anti-idiotopic antibodies (anti-anti-Id, Ab3), AF14 and AF52, were prepared by immunizing BALB/c mice with rabbit polyclonal anti-idiotypic antibodies (anti-Id, Ab2) raised against antibody D1.3 (Ab1) specific for the antigen hen egg lysozyme. AF14 and AF52 react with an "internal image" monoclonal mouse anti-Id antibody E5.2 (Ab2), previously raised against D1.3, with affinity constants (1.0 x 10(9) M-1 and 2.4 x 10(7) M-1, respectively) usually observed in secondary responses against protein antigens. They also react with the antigen but with lower affinity (1.8 x 10(6) M-1 and 3.8 x 10(6) M-1). This pattern of affinities for the anti-Id and for the antigen also was displayed by the sera of the immunized mice. The amino acid sequences of AF14 and AF52 are very close to that of D1.3. In particular, the amino acid side chains that contribute to contacts with both antigen and anti-Id are largely conserved in AF14 and AF52 compared with D1.3. Therapeutic immunizations against different pathogenic antigens using anti-Id antibodies have been proposed. Our experiments show that a response to an anti-Id immunogen elicits anti-anti-Id antibodies that are optimized for binding the anti-Id antibodies rather than the antigen.

Analysis of binding interactions in an idiotope-antiidiotope protein-protein complex by double mutant cycles.

The idiotope-antiidiotope complex between the anti-hen egg white lysozyme antibody D1.3 and the anti-D1.3 antibody E5.2 provides a useful model for studying protein-protein interactions. A high-resolution crystal structure of the complex is available [Fields, B. A., Goldbaum, F. A., Ysern, X., Poljak, R.J., & Mariuzza, R. A. (1995) Nature 374, 739-742], and both components are easily produced and manipulated in Escherichia coli. We previously analyzed the relative contributions of individual residues of D1.3 to complex stabilization by site-directed mutagenesis [Dall'Acqua, W., Goldman, E. R., Eisenstein, E., & Mariuzza, R. A. (1996) Biochemistry 35, 9667-9676]. In the current work, we introduced single alanine substitutions in 9 out of 21 positions in the combining site of E5.2 involved in contacts with D1.3 and found that 8 of them play a significant role in ligand binding (delta Gmutant-delta Gwild type > 1.5 kcal/mol). Furthermore, energetically important E5.2 and D1.3 residues tend to be juxtaposed in the crystal structure of the complex. In order to further dissect the energetics of specific interactions in the D1.3-E5.2 interface, double mutant cycles were carried out to measure the coupling of 13 amino acid pairs, 9 of which are in direct contact in the crystal structure. The highest coupling energy (4.3 kcal/mol) was measured for a charged-neutral pair which forms a buried hydrogen bond, while side chains which interact through solvated hydrogen bonds have lower coupling energies (1.3-1.7 kcal/mol), irrespective of whether they involve charged-neutral or neutral-neutral pairs. Interaction energies of similar magnitude (1.3-1.6 kcal/mol) were measured for residues forming only van der Waals contacts. Cycles between distant residues not involved in direct contacts in the crystal structure also showed significant coupling (0.5-1.0 kcal/mol). These weak long-range interactions could be due to rearrangements in solvent or protein structure or to secondary interactions involving other residues.

pH dependence of antibody/lysozyme complexation.

Association between proteins often depends on the pH and ionic strength conditions of the medium in which it takes place. This is especially true in complexation involving titratable residues at the complex interface. Continuum electrostatics methods were used to calculate the pH-dependent energetics of association of hen egg lysozyme with two closely related monoclonal antibodies raised against it and the association of these antibodies against an avian species variant. A detailed analysis of the energetic contributions reveals that even though the hallmark of association in the two complexes is the presence of conserved charged-residue interactions, the environment of these interactions significantly influences the titration behavior and concomitantly the energetics. The contributing factors include minor structural rearrangements, buried interfacial area, dielectric environment of the key titratable residues, and geometry of the residue dispositions. Modeled structures of several mutant complexes were also studied so as to further delineate the contribution of individual factors to the titration behavior.

Crystal structure of an Fv-Fv idiotope-anti-idiotope complex at 1.9 A resolution.

Anti-idiotopic antibodies react with unique antigenic features, usually associated with the combining sites, of other antibodies. They may thus mimic specific antigens that react with the same antibodies. The structural basis of this mimicry is analyzed here in detail for an anti-idiotopic antibody that mimics the antigen, hen egg-white lysozyme. The crystal structure of an anti-hen-egg-white lysozyme antibody (D1.3) complexed with an anti-idiotopic antibody (E5.2) has been determined at a nominal resolution of 1.9 A. E5.2 contacts substantially the same residues of D1.3 as lysozyme, thus mimicking its binding to D1.3. The mimicry embodies conservation of hydrogen bonding: six of the 14 protein-protein hydrogen bonds bridging D1.3-E5.2 are structurally equivalent to hydrogen bonds bridging D1.3-lysozyme. The mimicry includes a similar number of van der Waals interactions. The mimicry of E5.2 for lysozyme, however, does not extend to the topology of the non-polar surfaces of E5.2 and lysozyme, which are in contact with D1.3 as revealed by a quantitative analysis of the contacting surface similarities between E5.2 and lysozyme. The structure discussed herein shows that an anti-idiotopic antibody can provide an approximate topological and binding-group mimicry of an external antigen, especially in the case of the hydrophilic surfaces, even though there is no sequence homology between the anti-idiotope and the antigen.

Crystal structure of the complex of the variable domain of antibody D1.3 and turkey egg white lysozyme: a novel conformational change in antibody CDR-L3 selects for antigen.

The crystal structure of the Fv fragment of the murine monoclonal anti-lysozyme antibody D1.3, complexed with turkey egg-white lysozyme (TEL), is presented. D1.3 (IgG1, kappa) is a secondary response antibody specific for hen egg-white lysozyme (HEL). TEL and HEL are homologous and differ in amino acid sequence in the antibody-antigen interface only at position 121. The side-chain of HEL residue Gln121 makes a pair of hydrogen bonds to main-chain atoms of the antibody light chain. In the D1.3-TEL structure, TEL residue His121 makes only one hydrogen bond with the light chain as a result of 129 degree and 145 degree change in peptide torsion angles for residues Trp92 and Ser93. Probably as a consequence of this conformational change, the D1.3-TEL association occurs at a much slower rate than the D1.3-HEL association. The D1.3-TEL complex is destabilized with respect to the D1.3-HEL interaction by the loss of two hydrogen bonds, exclusively due to the substitution of histidine for glutamine. While antibodies of secondary responses are indeed highly specific for antigen, this work demonstrates that by undergoing subtle conformational change antibodies can still recognize mutated protein antigens, albeit at a cost to affinity.

Crystal structure of the V alpha domain of a T cell antigen receptor.

The crystal structure of the V alpha domain of a T cell antigen receptor (TCR) was determined at a resolution of 2.2 angstroms. This structure represents an immunoglobulin topology set different from those previously described. A switch in a polypeptide strand from one beta sheet to the other enables a pair of V alpha homodimers to pack together to form a tetramer, such that the homodimers are parallel to each other and all hypervariable loops face in one direction. On the basis of the observed mode of V alpha association, a model of an (alpha beta)2 TCR tetramer can be positioned relative to the major histocompatibility complex class II (alpha beta)2 tetramer with the third hypervariable loop of V alpha over the amino-terminal portion of the antigenic peptide and the corresponding loop of V beta over its carboxyl-terminal residues. TCR dimerization that is mediated by the alpha chain may contribute to the coupling of antigen recognition to signal transduction during T cell activation.

Conservation of water molecules in an antibody-antigen interaction.

The solvation of the antibody-antigen Fv D1.3-lysozyme complex is investigated through a study of the conservation of water molecules in crystal structures of the wild-type Fv fragment of antibody D1.3, 5 free lysozyme, the wild-type Fv D1.3-lysozyme complex, 5 Fv D1.3 mutants complexed with lysozyme and the crystal structure of an idiotope (Fv D1.3)-anti-idiotope (Fv E5.2) complex. In all, there are 99 water molecules common to the wild-type and mutant antibody-lysozyme complexes. The antibody-lysozyme interface includes 25 well-ordered solvent molecules, conserved among the wild-type and mutant Fv D1.3-lysozyme complexes, which are bound directly or through other water molecules to both antibody and antigen. In addition to contributing hydrogen bonds to the antibody-antigen interaction the solvent molecules fill many interface cavities. Comparison with x-ray crystal structures of free Fv D1.3 and free lysozyme shows that 20 of these conserved interface waters in the complex were bound to one of the free proteins. Up to 23 additional water molecules are also found in the antibody-antigen interface, however these waters do not bridge antibody and antigen and their temperature factors are much higher than those of the 25 well-ordered waters. Fifteen water molecules are displaced to form the complex, some of which are substituted by hydrophilic protein atoms, and 5 water molecules are added at the antibody- antigen interface with the formation of the complex. While the current crystal models of the D1.3-lysozyme complex do not demonstrate the increase in bound waters found in a physico-chemical study of the interaction at decreased water activities, the 25 well- ordered interface waters contribute a net gain of 10 hydrogen bonds to complex stability.

Protein motion and lock and key complementarity in antigen-antibody reactions.

Antibodies possess a highly complementary combining site structure to that of their specific antigens. In many instances their reactions are driven by enthalpic factors including, at least in the case of the reaction of monoclonal antibody D1.3 with lysozyme, enthalpy of solvation. They require minor structural rearrangements, and their equilibrium association constants are relatively high (10(7)-10(11) M-1). By contrast, in an idiotope--anti-idiotope (antibody-antibody) reaction, which is entropically driven, the binding equilibrium constant is only 1.5 x 10(5) M-1 at 20 degrees C. This low value results from a slow association rate (10(3) M-1 s-1) due to a selection of conformational states that allow one of the interacting molecular surfaces (the idiotope on antibody D1.3) to become complementary to that of the anti-idiotopic antibody. Thus, antibody D1.3 reacts with two different macromolecules: with its specific antigen, hen egg lysozyme, and with a specific anti-idiotopic antibody. Complementarity with lysozyme is closer to a "lock and key" model and results in high affinity (2-4 x 10(8) M-1). That with the anti-idiotopic antibody involves conformational changes at its combining site and it results in a lower association constant (1.5 x 10(5) M-1). Thus, an "induced fit" mechanism may lead to a broadening of the binding specificity but with a resulting decrease in the intrinsic binding affinity which may weaken the physiological function of antibodies.

Structural features of the reactions between antibodies and protein antigens.

Antibodies bind protein antigens over large sterically and electrostatically complementary surfaces. Van der Waals forces, hydrogen bonds, and occasionally ion pairs provide stability to antibody-antigen complexes. In addition, water molecules contribute hydrogen bonds linking antigen and antibody, and increase the complementarity of antigen-antibody interfaces. In qualification to a strict 'lock and key' mechanism, evidence of conformational changes between free and complexed antibodies indicate some accommodation to the antigen. Antibody-protein antigen reactions are enthalpically driven with varying degrees of entropic compensation, often dependent on the magnitude of the enthalpy of the reaction. In the case of two antibody-combining sites studied by X-ray diffraction, the relative arrangements of the variable domains of the light and heavy chains of the antibody change slightly from the free to the antigen-bound state. Furthermore, the contacting residues of both antibodies exhibit similar reduced mobilities when complexed to antigen, suggesting that differences in 'solvent entropy' rather than in conformational freedom may be the source of different entropic compensation factors. In concert, data from structural studies, reaction rates, calorimetric measurements, molecular dynamics simulations, and site-directed mutagenesis are beginning to detail the nature of antibody-protein antigen interactions.

Three-dimensional structures of the free and the antigen-complexed Fab from monoclonal anti-lysozyme antibody D44.1.

The three-dimensional structures of the free and antigen-complexed Fabs from the mouse monoclonal anti-hen egg white lysozyme antibody D44.1 have been solved and refined by X-ray crystallographic techniques. The crystals of the free and lysozyme-bound Fabs were grown under identical conditions and their X-ray diffraction data were collected to 2.1 and 2.5 A, respectively. Two molecules of the Fab-lysozyme complex in the asymmetric unit of the crystals show nearly identical conformations and thus confirm the essential structural features of the antigen-antibody interface. Three buried water molecules enhance the surface complementarity at the interface and provide hydrogen bonds to stabilize the complex. Two hydrophobic buried holes are present at the interface which, although large enough to accommodate solvent molecules, are void. The combining site residues of the complexed FabD44.1 exhibit reduced temperature factors compared with those of the free Fab. Furthermore, small perturbations in atomic positions and rearrangements of side-chains at the combining site, and a relative rearrangement of the variable domains of the light (VL) and the heavy (VH) chains, detail a Fab accommodation of the bound lysozyme. The amino acid sequence of the VH domain, as well as the epitope of lysozyme recognized by D44.1 are very close to those previously reported for the monoclonal antibody HyHEL-5. A feature central to the FabD44.1 and FabHyHEL-5 complexes with lysozyme are three salt bridges between VH glutamate residues 35 and 50 and lysozyme arginine residues 45 and 68. The presence of the three salt bridges in the D44.1-lysozyme interface indicates that these bonds are not responsible for the 1000-fold increase in affinity for lysozyme that HyHEL-5 exhibits relative to D44.1.