Human Germline Antibody Gene Segments Encode Polyspecific Antibodies

Structural flexibility in germline gene-encoded antibodies allows promiscuous binding to diverse antigens. The binding affinity and specificity for a particular epitope typically increase as antibody genes acquire somatic mutations in antigen-stimulated B cells. In this work, we investigated whether germline gene-encoded antibodies are optimal for polyspecificity by determining the basis for recognition of diverse antigens by antibodies encoded by three V_H gene segments. Panels of somatically mutated antibodies encoded by a common V_H gene, but each binding to a different antigen, were computationally redesigned to predict antibodies that could engage multiple antigens at once. The Rosetta multi-state design process predicted antibody sequences for the entire heavy chain variable region, including framework, CDR1, and CDR2 mutations. The predicted sequences matched the germline gene sequences to a remarkable degree, revealing by computational design the residues that are predicted to enable polyspecificity, i.e., binding of many unrelated antigens with a common sequence. The process thereby reverses antibody maturation in silico. In contrast, when designing antibodies to bind a single antigen, a sequence similar to that of the mature antibody sequence was returned, mimicking natural antibody maturation in silico. We demonstrated that the Rosetta computational design algorithm captures important aspects of antibody/antigen recognition. While the hypervariable region CDR3 often mediates much of the specificity of mature antibodies, we identified key positions in the V_H gene encoding CDR1, CDR2, and the immunoglobulin framework that are critical contributors for polyspecificity in germline antibodies. Computational design of antibodies capable of binding multiple antigens may allow the rational design of antibodies that retain polyspecificity for diverse epitope binding.     

Structural plasticity and the evolution of antibody affinity and specificity

The germline precursor to the ferrochelatase antibody 7G12 was found to bind the polyether jeffamine in addition to its cognate hapten N-methylmesoporphyrin. A comparison of the X-ray crystal structures of the ligand-free germline Fab and its complex with either hapten or jeffamine reveals that the germline antibody undergoes significant conformational changes upon the binding of these two structurally distinct ligands, which lead to increased antibody-ligand complementarity. The five somatic mutations introduced during affinity maturation lead to enhanced binding affinity for hapten and a loss in affinity for jeffamine. Moreover, a comparison of the crystal structures of the germline and affinity-matured antibodies reveals that somatic mutations not only fix the optimal binding site conformation for the hapten, but also introduce interactions that interfere with the binding of non-hapten molecules. The structural plasticity of this germline antibody and the structural effects of the somatic mutations that result in enhanced affinity and specificity for hapten likely represent general mechanisms used by the immune response, and perhaps primitive proteins, to evolve high affinity, selective receptors for so many distinct chemical structures.     

Structural insights into parallel strategies for germline antibody recognition of lipopolysaccharide from Chlamydia

The structure of the antigen-binding fragment from the monoclonal antibody S64-4 in complex with a pentasaccharide bisphosphate fragment from chlamydial lipopolysaccharide has been determined by x-ray diffraction to 2.6 ? resolution. Like the well-characterized antibody S25-2, S64-4 displays a pocket formed by the residues of germline sequence corresponding to the heavy and light chain V gene segments that binds the terminal Kdo residue of the antigen; however, although S64-4 shares the same heavy chain V gene segment as S25-2, it has a different light chain V gene segment. The new light chain V gene segment codes for a combining site that displays greater affinity, different specificity, and allows a novel antigen conformation that brings a greater number of antigen residues into the combining site than possible in S25-2. Further, while antibodies in the S25-2 family use complementarity determining region (CDR) H3 to discriminate among antigens, S64-4 achieves its specificity via the new light chain V gene segment and resulting change in antigen conformation. These structures reveal an intriguing parallel strategy where two different combinations of germline-coded V gene segments can act as starting points for the generation of germline antibodies against chlamydial antigens and show how anti-carbohydrate antibodies can exploit the conformational flexibility of this class of antigens to achieve high affinity and specificity independently of CDR H3.     

NMR evidence for mechanical coupling of phosphate B(I)-B(II) transitions with deoxyribose conformational exchange in DNA

2a2 is the most commonly rearranged gene in the human V(lambda )locus. It has been postulated that certain immunoglobulin genes (including 2a2) are rearranged preferentially because their germline sequences encode structures capable of binding to a range of antigens. Somatic mutation could then increase the specificity and affinity of binding to a particular antigen.We studied the properties of five IgG molecules in which the same heavy chain was paired with different light chains derived from 2a2. The pattern of somatic mutations in 2a2 was shown to be crucial in conferring the ability to bind DNA, but two different patterns of mutation each conferred this ability.Computer-generated models of the three-dimensional structures of these antibodies illustrate the ability of 2a2 to form a DNA binding site in different ways. Somatic mutations at the periphery of the DNA binding site were particularly important. In two different light chains, mutations to arginine at different sites in the complementarity determining regions (CDRs) enhanced binding to DNA. In a third light chain, however, mutation to arginine at a different site blocked binding to DNA.     

Detection of a unique human V kappa IV germline gene by a cloned cDNA probe.

We have cloned the cDNA encoding the KIV chain of a human antibody with specificity against the major carbohydrate antigen of Streptococcus A. The cDNA has been used as a genetic probe to estimate the number of germline VKIV genes in human DNA. The presence of unique hybridizing bands on digestion of human DNA with several restriction endonucleases and the equivalence of the DNA in a band to a single gene per haploid genome point to the conclusion that there is a unique human VKIV germline gene. The corollary of this conclusion is that the diversity of human VKIV chains must be exclusively due to somatic mutation. This is supported by examination of the sequences of human KIV chain genes and their KIV chain products. Fusion of the unique germline VKIV gene (1) with one of several JK segments, followed by somatic mutations in the V region of the rearranged KIV gene, can account for the known sequences. The restricted germline gene repertoire may account for the small proportion of human KIV chains in the human K chain sequence library (2).     

Enhancement and destruction of antibody function by somatic mutation: unequal occurrence is controlled by V gene combinatorial associations.

We examined the positive and negative effects of somatic mutation on antibody function using saturation mutagenesis in vitro to mimic the potential of the in vivo process to diversify antibodies. Identical mutations were introduced into the second complementarity determining region of two anti-phosphocholine antibodies, T15 and D16, which share the same germline VH gene sequence. T15 predominates in primary responses and does not undergo affinity maturation. D16 is representative of antibodies that co-dominate in memory responses and do undergo affinity maturation. We previously reported that > 50% of T15 mutants had decreased antigen binding capacity. To test if this high frequency of binding loss was unique to T15 or a consequence of random point mutations applicable to other combining sites, we analyzed the same mutations in D16. We show that D16 suffers a similar loss of function, indicating an equally high potential for B-cell wastage. However, only D16 displayed the capacity for somatic mutation to improve antigen binding, which should enhance its persistence in memory responses. Mutation of residues contacting the haptenic group, as determined by molecular modeling, did not improve binding. Instead, productive mutations occurred in residues that either contacted carrier protein or were distant from the antigen binding site, possibly increasing binding site flexibility through long-range effects. Targeting such residues for mutation should aid in the rational design of improved antibodies.     

A common NH53K mutation in the combining site of antibodies raised against chlamydial LPS glycoconjugates significantly increases avidity

The crystal structures of the antigen-binding fragment of the murine monoclonal antibody (mAb) S25-39 in the presence of several antigens representing chlamydial lipopolysaccharide (LPS) epitopes based on the bacterial sugar 3-deoxy-α-D-manno-oct-2-ulosonic acid (Kdo) have been determined at resolutions from 2.4 to 1.8 ?. The antigen-binding site of this antibody differs from the well-characterized antibody S25-2 by a single mutation away from the germline of asparagine H53 to lysine, yet this one mutation results in a significant increase in avidity across a range of antigens. A comparison of the two antibody structures reveals that the mutated Lys H53 forms additional hydrogen bonds and/or charged-residue interactions with the second Kdo residue of every antigen having two or more carbohydrate residues. Significantly, the NH53K mutation results from a single nucleotide substitution in the germline sequence common among a panel of antibodies raised against glycoconjugates containing carbohydrate epitopes of chlamydial LPS. Like S25-2, S25-39 displays significant induced fit of complementarity determining region (CDR) H3 upon antigen binding, with the unliganded structure possessing a conformation distinct from those reported earlier for S25-2. The four different observed conformations for CDR H3 suggest that this CDR has evolved to exploit the recognition potential of a flexible loop while minimizing the associated entropic penalties of binding by adopting a limited number of ordered conformations in the unliganded state. These observations reveal strategies evolved to balance adaptability and specificity in the germline antibody response to carbohydrate antigens.     

Antigen-binding site anatomy and somatic mutations in antibodies that recognize different types of antigens

The number of antibody structures co-crystallized with their respective antigens has increased rapidly in the last few years, thus offering a formidable source of information to gain insight into the structure-function relationships of this family of proteins. We have analyzed here 140 unique middle-resolution to high-resolution (<3??) antibody structures, including 55 in complex with proteins, 39 with peptides, and 46 with haptens. We determined (i) length variations of the hypervariable loops, (ii) number of contacts with antigen, (iii) solvent accessible area buried upon binding, (iv) location and frequency of antigen contacting residues, (v) type of residues interacting with antigens, and (vi) putative somatic mutations. Except for somatic mutations, distinctive profiles were identified for all the variables analyzed. Compared with contacts, somatic mutations occurred with less abundance at any given position and extended beyond the regions in contact, with no clear difference among antibodies that recognize different types of antigens. This observation is consistent with the fact that although antigen recognition accomplished by shape and physicochemical complementarity is selective in nature, the somatic mutation process is stochastic and selection for mutations leading to improved affinity is not directly related to contact residues. Thus, the knowledge emerging from this study enhances our understanding of the structure-function relationship in antibodies while providing valuable guidance to design libraries for antibody discovery and optimization.     

Experimental analysis by site-directed mutagenesis of somatic mutation effects on affinity and fine specificity in antibodies specific for lysozyme.

To experimentally examine the functional roles of somatically derived structural variation in the lysozyme-binding mAb HyHEL-10, we have introduced three different point mutations and one insertion at two different sites in HyHEL-10 by site-directed mutagenesis and expression of the mutant antibodies. Mutation of Asp----Ala at position 101 of the H chain returns a somatically mutated residue to its germline sequence for HyHEL-10, and reduces affinity for chicken lysozyme by approximately 9000-fold. Lengthening the third H chain hypervariable region by two amino acids reduces affinity by about 2000-fold. Two mutations, Asp----Thr at position 101 in the H chain and Lys----Thr at position 49 in the L chain, model somatic differences found in another structurally related but functionally distinguishable mAb and minimally decrease affinity for chicken lysozyme. The H chain mutation Asp101VVH----Thr has little effect on affinity for other avian lysozymes but does alter relative fine specificity for these lysozymes. The L chain mutation Lys49VK----Thr increases affinity for duck lysozyme by approximately fivefold. Neither of the positions mutated, 101 in the H chain nor 49 in the L chain, nor the residues near the insertion contact lysozyme in the x-ray structure of the HyHEL-10 F(ab)-HEL complex. The results suggest that these mutations, which model observed somatic mutations, produce functional variation by indirect or long-range effects.     

The specificity properties that distinguish members of a set of homologous anti-digoxin antibodies are controlled by H chain mutations

Five murine A/J strain anti-digoxin mAb (35-20, 40-40, 40-120, 40-140, and 40-160) have highly homologous H and L chain V regions, only differing by somatic mutation, yet differ in affinity and specificity. The availability of the VH and VL genomic clones from one hybridoma, 40-140, has now allowed studies involving in vitro mutagenesis and chain recombination among these five hybridomas. To determine the relative contributions of the mutations found in either VH or VL to the overall binding properties of these antibodies, we recombined the 40-140VH with the VL of each hybridoma. The 40-140VH gene was transfected into hybridoma variants that produce only VL. The recombinant antibodies show that the mutations present in VH, rather than in VL, affect the fine specificity properties of these antibodies, whereas, the mutations among both VH and VL chains are important in determining antigen affinity. From mutations present in VH that affect fine specificity properties, the comparison of the antibody sequences, and from the previously measured binding properties, we predicted and tested selected VH mutations for their ability to alter specificity or affinity by doing site-directed in vitro mutagenesis. The results for the somatic mutations found in this group of antibodies show: 1) VH mutations control the fine specificity properties that distinguish different members of this group; 2) in particular, VH residues 54 and 55 in CDR2 control the distinguishing characteristics of specificities between these antibodies; and 3) by mutagenesis, we had the unusual result of being able to alter Ag specificity without affecting affinity. A computer model of the 40-140 antibody binding site was generated which indicates that VH residues 54 and 55 are highly accessible.     

Immunologic memory to phosphocholine keyhole limpet hemocyanin. Recurrent mutations in the lambda 1 light chain increase affinity for antigen.

Anti-phosphocholine (PC)-keyhole limpet hemacyanin hybridomas representative of a memory response that express the lambda 1 L chain isotype have a high reactivity to PC-protein. A common feature of these hybridomas possessing high affinity for PC-protein is the occurrence of somatic mutations resulting in replacement changes in three CDR2 positions of the lambda 1 L chain. The influence of each of these three positions on the Ag binding properties of these antibodies was examined by site-specific mutagenesis and expression of recombinant antibody molecules by transfected cells. Affinity measurements and fine specificity profile determinations demonstrated the importance of the three lambda 1 CDR2 positions in Ag binding. Compared to antibodies expressing germline lambda 1, including one with an additional junctional serine that is not encoded by V or J, those antibodies possessing critical changes in CDR2 would have a strong selective advantage based on affinity differences for Ag. Sequence analysis of a group of clonally related hybridomas expressing mutated lambda 1 genes allowed construction of a hypothetical genealogic tree that suggests selection based on changes in CDR2 of lambda 1 in the absence of H chain mutations. The results are consistent with stepwise acquisition of mutations and selection based on affinity constraints.     

Validation of affinity reagents using antigen microarrays

There is a need for standardised validation of affinity reagents to determine their binding selectivity and specificity. This is of particular importance for systematic efforts that aim to cover the human proteome with different types of binding reagents. One such international program is the SH2-consortium, which was formed to generate a complete set of renewable affinity reagents to the SH2-domain containing human proteins. Here, we describe a microarray strategy to validate various affinity reagents, such as recombinant single-chain antibodies, mouse monoclonal antibodies and antigen-purified polyclonal antibodies using a highly multiplexed approach. An SH2-specific antigen microarray was designed and generated, containing more than 6000 spots displayed by 14 identical subarrays each with 406 antigens, where 105 of them represented SH2-domain containing proteins. Approximately 400 different affinity reagents of various types were analysed on these antigen microarrays carrying antigens of different types. The microarrays revealed not only very detailed specificity profiles for all the binders, but also showed that overlapping target sequences of spotted antigens were detected by off-target interactions. The presented study illustrates the feasibility of using antigen microarrays for integrative, high-throughput validation of various types of binders and antigens.     

Exploration of specificity in germline monoclonal antibody recognition of a range of natural and synthetic epitopes

To explore the molecular basis of antigen recognition by germline antibodies, we have determined to high resolution the structures of the near-germline monoclonal antibody S25-2 in complex with seven distinct carbohydrate antigens based on the bacterial sugar 3-deoxy-α-d-manno-oct-2-ulosonic acid (Kdo). In contrast to previous findings, the inherited germline Kdo monosaccharide binding site is not restricted to this bacterial sugar but is able to accommodate an array of substitutions and chemical modifications of Kdo, including naturally occurring antigens containing the related monosaccharide d-glycero-α-d-talo-oct-2-ulosonic acid as well as nonterminal Kdo residues. However, we show by surface plasmon resonance and ELISA how antibody S25-2 specificity is so dependent on the context in which the antigen is presented that a free disaccharide displays strong binding while the same lipid-A-bound disaccharide does not bind. These structures provide insight into how inherited germline genes code for immunoglobulins of limited flexibility that are capable of binding a range of epitopes from which affinity-matured antibodies are generated.     

Three-dimensional structure determination of an anti-2-phenyloxazolone antibody: the role of somatic mutation and heavy/light chain pairing in the maturation of an immune response.

The three-dimensional structure of the Fab fragment of an anti-2-phenyloxazolone monoclonal antibody (NQ10/12.5) in its native and complexed forms has been determined at 2.8 and 3.0 A resolution, respectively. Identification of hapten-contacting residues has allowed us to evaluate the contribution of individual somatic point mutations to maturation of the immune response. In particular, amino acid residues 34 and 36 of the light chain, which are frequently mutated in antibodies with increased affinity for 2-phenyloxazolone, are shown to interact directly with the hapten. We propose that the strict maintenance of certain amino acid sequences at the potentially highly variable VL-JL and VH-D-JH junctions observed among anti-2-phenyloxazolone antibodies is due largely to structural constraints related to antigen recognition. Finally, the three-dimensional model of NQ10/12.5, which uses the typical light chain of primary response anti-2-phenyloxazolone antibodies but a different heavy chain, allows an understanding of how, by preserving key contact residues, a given heavy chain may be replaced by another, apparently unrelated one, without loss of hapten binding activity and why the V kappa Ox1 germline gene is so frequently selected amongst the other known members of this family.     

Antibody responses of experimentally infected lambs to antigens collected during in vitro maintenance of the adult, metacestode or oncosphere stages of Taenia hydatigena and Taenia ovis with further observations on anti-oncospheral antibodies

The antigenicity and specificity of crude antigens collected during the in vitro maintenance of Taenia hydatigena and T. ovis, excretory/secretory (ES) antigens, were assessed in a peroxidase microenzyme-linked immunosorbent assay (ELISA), using sera from lambs given experimental monospecific infections with T. hydatigena, T. ovis, Echinococcus granulosus or Fasciola hepatica. ES antigens of larval cysts of T. ovis and T. hydatigena were less reactive than those of adult or oncosphere stages. Strong interspecific cros-reactions occurred between all antigen preparations, and these antigens offered no better specificity than crude somatic extracts. IgG1 was the major immunoglobulin detected in sera from lambs experimentally infected with T. ovis or T. hydatigena using antigens prepared from sonicated oncospheres. Discrete peaks of anti-oncospheral antibodies were detected following initial and challenge infections with eggs (whether the homologous or heterologous species), when sera were assayed with a PBS sonicate or an ES antigen from oncospheres. However, when oncospheres solubilised with sodium deoxycholate were used, the antibody response was prolonged and resembled that reported previously when somatic extracts of adult and metacestode stages were used as antigen. The results showed that oncospheres share antigens in common with other life-cycle stages, but also support the notion that they may possess some unique stage-specific antigenic determinants.     

Effective binding to protein antigens by antibodies from antibody libraries designed with enhanced protein recognition propensities

Antibodies provide immune protection by recognizing antigens of diverse chemical properties, but elucidating the amino acid sequence-function relationships underlying the specificity and affinity of antibody-antigen interactions remains challenging. We designed and constructed phage-displayed synthetic antibody libraries with enriched protein antigen-recognition propensities calculated with machine learning predictors, which indicated that the designed single-chain variable fragment variants were encoded with enhanced distributions of complementarity-determining region (CDR) hot spot residues with high protein antigen recognition propensities in comparison with those in the human antibody germline sequences. Antibodies derived directly from the synthetic antibody libraries, without affinity maturation cycles comparable to those in in vivo immune systems, bound to the corresponding protein antigen through diverse conformational or linear epitopes with specificity and affinity comparable to those of the affinity-matured antibodies from in vivo immune systems. The results indicated that more densely populated CDR hot spot residues were sustainable by the antibody structural frameworks and could be accompanied by enhanced functionalities in recognizing protein antigens. Our study results suggest that synthetic antibody libraries, which are not limited by the sequences found in antibodies in nature, could be designed with the guidance of the computational machine learning algorithms that are programmed to predict interaction propensities to molecules of diverse chemical properties, leading to antibodies with optimal characteristics pertinent to their medical applications.     

Genetics of the phosphocholine-specific antibody response to Streptococcus pneumoniae. Germ-line but not mutated T15 antibodies are dominantly selected

The role that somatic mutations play in the phosphocholine-specific, antibody response to Streptococcus pneumoniae was examined by studying sets of hybridomas from different individual mice. As expected most of the cell lines were from the T15 anti-phosphocholine family and were not encoded by the v1 gene of the T15 VH family and V kappa 22. A minority of antibodies were from the M603 (v1/V kappa 8) and M511 (v1/V kappa 24) families. Three additional antibodies were encoded by the v11 gene of the T15 family; two were paired with a V lambda and the other with a V kappa 1 gene. In vitro binding studies showed that T15- and M603-like antibodies had the highest affinity for S. pneumoniae. Complete sequencing of the VH and VL mRNA from 25 of the hybridomas revealed somatic mutations in 11 of the antibodies. A total of 17 independently derived T15 positive cell lines were studied in detail, six of these were mutated. These mutations were scattered throughout the V regions and the replacement to silent ratio was typical of that for framework regions. Statistical evaluation of the placement of mutations showed that there was a slight but significantly decreased frequency of mutations in complementarity determining regions. Comparisons of mutated and unmutated T15-related antibodies showed that mutations caused a decrease in binding to S. pneumoniae in every case. These results argue that the optimal specificity for this molecular form of phosphocholine is encoded in the germline and that Ag-driven events favor selection of B cells expressing these germ-line encoded antibodies.     

A comparative analysis of the immunological evolution of antibody 28B4

In an effort to gain greater insight into the evolution of the redox active, catalytic antibody 28B4, the germline genes used by the mouse to generate this antibody were cloned and expressed, and the X-ray crystal structures of the unliganded and hapten-bound germline Fab of antibody 28B4 were determined. Comparison with the previously determined structures of the unliganded and hapten-bound affinity-matured Fab [Hsieh-Wilson, L. C., Schultz, P. G., and Stevens, R. C. (1996) Proc. Natl. Acad. Sci. U.S.A. 93, 5363] shows that the germline antibody binds the p-nitrophenyl ring of hapten 3 in an orientation significantly different from that seen in the affinity-matured antibody, whereas the phosphonate moiety is bound in a similar mode by both antibodies. The affinity-matured antibody 28B4 has more electrostatic and hydrophobic interactions with hapten 3 than the germline antibody and binds the hapten in a lock-and-key fashion. In contrast, significant conformational changes occur in the loops of CDR H3 and CDR L1 upon hapten binding to the germline antibody, consistent with the notion of structural plasticity in the germline antibody-combining site [Wedemayer, G. J., Patten, P. A., Wang, L. H., Schultz, P. G., and Stevens, R. C. (1997) Science 276, 1665]. The structural differences are reflected in the differential binding affinities of the germline Fab (K(d) = 25 microM) and 28B4 Fab (K(d) = 37 nM) to hapten 3. Nine replacement mutations were found to accumulate in the affinity-matured antibody 28B4 compared to its germline precursor. The effects of each mutation on the binding affinity of the antibody to hapten 3 were characterized in detail in the contexts of both the germline and the affinity-matured antibodies. One of the mutations, Asp95(H)Trp, leads to a change in the orientation of the bound hapten, and its presence is a prerequisite for other somatic mutations to enhance the binding affinity of the germline antibody for hapten 3. Thus, the germline antibody of 28B4 acquired functionally important mutations in a stepwise manner, which fits into a multicycle mutation, affinity selection, and clonal expansion model for germline antibody evolution. Two other antibodies, 20-1 and NZA6, with very different antigen specificities were found to be highly homologous to the germline antibody of 28B4, consistent with the notion that certain germline variable-region gene combinations can give rise to polyspecific hapten binding sites [Romesberg, F. E., Spiller, B., Schultz, P. G., and Stevens, R. C. (1998) Science 279, 1929]. The ultimate specificity of the polyspecific germline antibody appears to be defined by CDR H3 variability and subsequent somatic mutation. Insights into the evolution of antibody-combining sites provided by this and other structural studies are discussed.     

High affinity antigen recognition of the dual specific variants of herceptin is entropy-driven in spite of structural plasticity

The antigen-binding site of Herceptin, an anti-human Epidermal Growth Factor Receptor 2 (HER2) antibody, was engineered to add a second specificity toward Vascular Endothelial Growth Factor (VEGF) to create a high affinity two-in-one antibody bH1. Crystal structures of bH1 in complex with either antigen showed that, in comparison to Herceptin, this antibody exhibited greater conformational variability, also called "structural plasticity". Here, we analyzed the biophysical and thermodynamic properties of the dual specific variants of Herceptin to understand how a single antibody binds two unrelated protein antigens. We showed that while bH1 and the affinity-improved bH1-44, in particular, maintained many properties of Herceptin including binding affinity, kinetics and the use of residues for antigen recognition, they differed in the binding thermodynamics. The interactions of bH1 and its variants with both antigens were characterized by large favorable entropy changes whereas the Herceptin/HER2 interaction involved a large favorable enthalpy change. By dissecting the total entropy change and the energy barrier for dual interaction, we determined that the significant structural plasticity of the bH1 antibodies demanded by the dual specificity did not translate into the expected increase of entropic penalty relative to Herceptin. Clearly, dual antigen recognition of the Herceptin variants involves divergent antibody conformations of nearly equivalent energetic states. Hence, increasing the structural plasticity of an antigen-binding site without increasing the entropic cost may play a role for antibodies to evolve multi-specificity. Our report represents the first comprehensive biophysical analysis of a high affinity dual specific antibody binding two unrelated protein antigens, furthering our understanding of the thermodynamics that drive the vast antigen recognition capacity of the antibody repertoire.     

Structure of an anti-blood group A Fv and improvement of its binding affinity without loss of specificity.

The specificity of antibody recognition of the ABO blood group trisaccharide antigens has been explored by crystal structure analysis and mutation methods. The crystal structure of the Fv corresponding to the anti-blood group A antibody AC1001 has been determined to 2.2-A resolution and reveals a binding pocket that is complementary to the blood group A-trisaccharide antigen. The effect of mutating specific residues lining this pocket on binding to the A and B blood group oligosaccharide antigens was investigated through a panel of single point mutations and through a phage library of mutations in complementarity determining region H3. Both approaches gave several mutants with improved affinity for antigen. Surface plasmon resonance indicated up to 8-fold enhancement in affinity for the A-pentasaccharide with no observable binding to the blood group B antigen. This is the first example of single point mutations in a carbohydrate-binding antibody resulting in significant increases in binding affinity without loss of specificity.