Crystal structures of neuraminidase-antibody complexes

Evolution and Antigenic Advancement of N2 Neuraminidase of Swine Influenza A Viruses Circulating in the United States following Two Separate Introductions from Human Seasonal Viruses

Two separate introductions of human seasonal N2 neuraminidase genes were sustained in U.S. swine since 1998 (N2-98) and 2002 (N2-02). Herein, we characterized the antigenic evolution of the N2 of swine influenza A virus (IAV) across 2 decades following each introduction. The N2-98 and N2-02 expanded in genetic diversity, with two statistically supported monophyletic clades within each lineage. To assess antigenic drift in swine N2 following the human-to-swine spillover events, we generated a panel of swine N2 antisera against representative N2 and quantified the antigenic distance between wild-type viruses using enzyme-linked lectin assay and antigenic cartography. The antigenic distance between swine and human N2 was smallest between human N2 circulating at the time of each introduction and the archetypal swine N2. However, sustained circulation and evolution in swine of the two N2 lineages resulted in significant antigenic drift, and the N2-98 and N2-02 swine N2 lineages were antigenically distinct. Although intralineage antigenic diversity was observed, the magnitude of antigenic drift did not consistently correlate with the observed genetic differences. These data represent the first quantification of the antigenic diversity of neuraminidase of IAV in swine and demonstrated significant antigenic drift from contemporary human seasonal strains as well as antigenic variation among N2 detected in swine. These data suggest that antigenic mismatch may occur between circulating swine IAV and vaccine strains. Consequently, consideration of the diversity of N2 in swine IAV for vaccine selection may likely result in more effective control and aid public health initiatives for pandemic preparedness. IMPORTANCE Antibodies inhibiting the neuraminidase (NA) of IAV reduce clinical disease, virus shedding, and transmission, particularly in the absence of neutralizing immunity against hemagglutinin. To understand antibody recognition of the genetically diverse NA in U.S. swine IAV, we characterized the antigenic diversity of N2 from swine and humans. N2 detected in swine IAV were derived from two distinct human-to-swine spillovers that persisted, are antigenically distinct, and underwent antigenic drift. These findings highlight the need for continued surveillance and vaccine development in swine with increased focus on the NA. Additionally, human seasonal N2 isolated after 2005 were poorly inhibited by representative swine N2 antisera, suggesting a lack of cross-reactive NA antibody-mediated immunity between contemporary swine and human N2. Bidirectional transmission between humans and swine represents a One Health challenge, and determining the correlates of immunity to emerging IAV strains is critical to mitigating zoonotic and reverse-zoonotic transmission.

Comparison of epitope structures of H3HAs through protein modeling of influenza A virus hemagglutinin: mechanism for selection of antigenic variants in the presence of a monoclonal antibody

Starting with nine plaques of influenza A/Kamata/14/91(H3N2) virus, we selected mutants in the presence of monoclonal antibody 203 (mAb203). In total, amino acid substitutions were found at nine positions (77, 80, 131, 135, 141, 142, 143, 144 and 146), which localized in the antigenic site A of the hemagglutinin (HA). The escape mutants differed in the extent to which they had lost binding to mAb203. HA protein with substitutions of some amino acid residues created by site-directed mutagenesis in the escape mutants retained the ability to bind to mAb203. Changes in the amino acid character affecting charge or hydrophobicity accounted for the binding capacity to the antibody of the HA with most of the substitutions in the escape mutants and binding-positive mutants. However, the effect of some amino acid substitutions remained unexplained. A three-dimensional model of the 1991 HA was constructed and used to analyze substituted amino acids in these mutants for the accessible surface hydrophobic and hydrophilic characters. One amino acid substitution in an escape mutant and another amino acid substitution in a binding-positive mutant seemed to be explained by the changes noted on this model.

Interaction between a 1998 human influenza virus N2 neuraminidase and monoclonal antibody Mem5

Influenza virus constantly escapes antibody inhibition by introducing mutations that disrupt protein-protein interactions. Based on the structure of the complex between neuraminidase (NA) of influenza A/Memphis/31/98 (H3N2) and the Fab of a monoclonal antibody (Mem5) that binds and inhibits the Memphis/98 NA, we investigated the contribution made by individual amino acids of NA to the stability of the complex. We made mutations D147A, D147N, H150A, H197A, D198A, D198N, E199A, E199Q, K221R, A246K, D251N, and D251A. Binding of each mutant to NA was quantitated by NA inhibition assays and ELISA. Most of the mutant NAs were inhibited by Mem5 to the same extent as wild-type, but with lower affinity. The exceptions were E199A, E199Q, and K221R, in which binding was abrogated. The ELISA results confirmed a correlation between NA inhibition and binding. The Mem5 epitope is dominated by a few high-energy interactions as was found in the epitope on an avian subtype N9 NA that binds antibody NC41 and different to the more diffuse energy distribution in the NC10 epitope on N9 NA. Energetic dominance of a particular interaction, which is associated with potential for antibody escape mutations, may be associated with the absence of water molecules in the vicinity. Critical contacts in a dominant antigenic site are likely to mutate, allowing some predictions of antigenic drift.

Contacts between influenza virus N9 neuraminidase and monoclonal antibody NC10

We are interested in studying how influenza virus escapes antibody inhibition. Based on the structure of the complex between N9 NA and monoclonal antibody NC10 Fab (R. L. Malby, W. R. Tulip, V. R. Harley, J. L. McKimm-Breschkin, W. G. Laver, R. G. Webster, and P. M. Colman, 1994, Structure 2, 733-746), we investigated the contribution made by individual amino acids to the stability of the complex. We made conservative changes in residues that are centrally located in the epitope and more drastic changes in peripheral contacts. The mutations made were N200L (removing an N-linked oligosaccharide), N329Q, N345Q, S370T, S372A, N400L, and K432M. Binding of each mutant to NC10 was quantitated by NA inhibition assays and ELISA. Except for N200L and N329Q, the mutants were inhibited by NC10 to the same extent as wild-type NA although with less affinity. The enzyme activity (K(cat)) of N200L is 80% reduced, indicating a defect in folding or assembly; therefore, the loss in binding activity due to the missing sugar residue cannot be assessed. The K(d) for N329Q is sixfold higher than for wild-type NA in the inhibition test, but the same as wild-type in ELISA, indicating a change in disposition of the antibody but no loss of affinity. The results show that the NC10 epitope can accommodate a change at any site and is not dominated by a few high-energy interactions as was found in the NC41 epitope. We propose that the difference lies in the contribution of buried water molecules to the NA-NC10 complex.

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.

Studies of epitope restriction on myeloperoxidase (MPO), an important antigen in systemic vasculitis

Anti-neutrophil cytoplasmic antibodies are important components of the inflammatory response in patients with systemic vasculitis. Their role in the pathogenesis of these conditions remains incompletely defined. Several antigens have been identified, and MPO is one of the most important. To gain more understanding of the immune mechanisms involved, we were keen to see if the antibody response to MPO was restricted, or whether there was a general loss of tolerance to the whole surface of the molecule. To study the epitopes we employed both ELISA and biosensor technology, and were able to demonstrate restriction both in the number and localization of the epitopes being recognized.

Molecular and structural analysis of a continuous birch profilin epitope defined by a monoclonal antibody

The interaction of a mouse monoclonal antibody (4A6) and birch profilin, a structurally well conserved actin- and phosphoinositide-binding protein and cross-reactive allergen, was characterized. In contrast to serum IgE from allergic patients, which shows cross-reactivity with most plants, monoclonal antibody 4A6 selectively reacted with tree pollen profilins. Using synthetic overlapping peptides, a continuous hexapeptide epitope was identified. The exchange of a single amino acid (Gln-47 --> Glu) within the epitope was found to abolish the binding of monoclonal antibody 4A6 to other plant profilins. The NMR analyses of the birch and the nonreactive timothy grass profilin peptides showed that the loss of binding was not due to major structural differences. Both peptides adopted extended conformations similar to that observed for the epitope in the x-ray crystal structure of the native birch profilin. Binding studies with peptides and birch profilin mutants generated by in vitro mutagenesis demonstrated that the change of Gln-47 to acidic amino acids (e.g. Glu or Asp) led to electrostatic repulsion of monoclonal antibody 4A6. In conclusion the molecular and structural analyses of the interaction of a monoclonal antibody with a continuous peptide epitope, recognized in a conformation similar to that displayed on the native protein, are presented.

Interactions of protein antigens with antibodies

There are now several crystal structures of antibody Fab fragments complexed to their protein antigens. These include Fab complexes with lysozyme, two Fab complexes with influenza virus neuraminidase, and three Fab complexes with their anti-idiotype Fabs. The pattern of binding that emerges is similar to that found with other protein-protein interactions, with good shape complementarity between the interacting surfaces and reasonable juxtapositions of polar residues so as to permit hydrogen-bond formation. Water molecules have been observed in cavities within the interface and on the periphery, where they often form bridging hydrogen bonds between antibody and antigen. For the most part the antigen is bound in the middle of the antibody combining site with most of the six complementarity-determining residues involved in binding. For the most studied antigen, lysozyme, the epitopes for four antibodies occupy approximately 45% of the accessible surface area. Some conformational changes have been observed to accompany binding in both the antibody and the antigen, although most of the information on conformational change in the latter comes from studies of complexes with small antigens.

Crystal structure of an idiotype-anti-idiotype Fab complex

Anti-idiotypic monoclonal antibody 409.5.3 is raised against an antibody that neutralizes feline infectious peritonitis virus. This antibody, used as an immunogen, elicits the production of anti-anti-idiotypic antibodies that in turn neutralize the virus. The crystal structure of the complex between anti-idiotypic Fab 409.5.3 and idiotypic Fab fragment of virus-neutralizing antibody has been solved by molecular replacement using real-space Patterson search and filtering by Patterson correlation-coefficient refinement. The structure has been refined to an R value of 0.21 based on 21,310 unique reflections between 40.0 and 2.9 A. The three-dimensional structure reveals extensive, specific interactions that involve 118 van der Waals contacts and at least 9 probable hydrogen bonds. The two Fabs are rotated 61 degrees with respect to each other around the approximate long axis of the complex and are within 26 degrees being aligned along their major axes.

PREDITOP: a program for antigenicity prediction

A program (PREDITOP) for predicting the location of antigenic regions (or epitopes) on proteins is described. This program and the associated ones are written in Turbo Pascal and run on IBM-PC compatibles. The program contains 22 normalized scales, corresponding to hydrophilicity, accessibility, flexibility, or secondary structure propensities. New scales are easily implemented. An hydrophobic moment procedure has also been implemented in order to determine amphiphilic helices. The program generates a result file where the values represent a particular physicochemical aspect of the studied protein. PREDITOP can display one or several result files by simple graphical super-imposition. Curve combinations can be done by the ADDITIO or MULTIPLI routines which create a new result file by adding or multiplying previously calculated files representing several propensities. The program is useful and efficient for identifying potential antigenic regions in a protein with the aim of raising antibodies against synthesized peptides which cross-react with the native protein.

Three-dimensional structure of a heteroclitic antigen-antibody cross-reaction complex

Although antibodies are highly specific, cross-reactions are frequently observed. To understand the molecular basis of this phenomenon, we studied the anti-hen egg lysozyme (HEL) monoclonal antibody (mAb) D11.15, which cross-reacts with several avian lysozymes, in some cases with a higher affinity (heteroclitic binding) than for HEL. We have determined the crystal structure of the Fv fragment of D11.15 complexed with pheasant egg lysozyme (PHL). In addition, we have determined the structure of PHL, Guinea fowl egg lysozyme, and Japanese quail egg lysozyme. Differences in the affinity of D11.15 for the lysozymes appear to result from sequence substitutions in these antigens at the interface with the antibody. More generally, cross-reactivity is seen to require a stereochemically permissive environment for the variant antigen residues at the antibody-antigen interface.

Liquid-liquid partition chromatography as a method to examine surface properties of antibodies and antigen-antibody complexes

We demonstrate liquid-liquid partition chromatography in aqueous two-phase systems (LLPC) as a simple method for examining the surface properties of immunoglobulins and antigen-antibody complexes in solution. LLPC separates molecules with respect to the properties of the exposed surfaces. As an example, the method may be used to detect changes in the conformation of IgG following chemical modification like acylation or iodination. We have studied the partitioning of antibodies and antigen-antibody complexes, modelled by rabbit antibodies against three human serum proteins, in aqueous polyethylene glycol/dextran two-phase systems at pH 7. Analysis of both polyclonal and monoclonal antibodies against various antigens suggested that the partition properties of immunoglobulins are related mainly to their antigen specificity and not to subclass-specific structures. Furthermore, experiments indicated that changes in the surface properties of antigen and/or antibody following complexation may be detected. Thus, LLPC may prove to be a new way of studying the relation between antibody structure and function in solution.

Recombinant antineuraminidase single chain antibody: expression, characterization, and crystallization in complex with antigen

The variable heavy (VH) and variable light (VL) genes of NC10, a monoclonal antibody with specificity toward N9 neuraminidase (NA), were cloned and sequenced. A single chain Fv (scFv) fragment of NC10, consisting of VH and VL domains joined by a peptide linker, was designed, constructed and expressed in the E. coli expression vector pPOW. The N-terminal secretion signal PelB directed the synthesized protein into the periplasm where it was associated with the insoluble membrane fraction. An octapeptide (FLAG) tail was fused to the C-terminus of the single chain Fv to aid in its detection and remained intact throughout the protein purification process. NC10 scFv was purified by solubilization of the E. coli membrane fraction with guanidinium hydrochloride followed by column chromatography. The purified NC10 scFv showed binding affinity for its antigen, NA, 2-fold lower than that of the parent Fab. The complex between NA and the scFv has been crystallized by the vapor diffusion method. The crystals are tetragonal, space group P42(1)2, with unit cell dimensions a = b = 141 A, c = 218 A.

Crystallographic analysis of the interaction between cyclosporin A and the Fab fragment of a monoclonal antibody

The structure of the complex between cyclosporin A and the Fab fragment of a monoclonal antibody has been established by crystallographic analysis to 2.65 A resolution. The structure has been solved by molecular replacement using a composite Fab model. The current R-factor after refinement is 0.179 between 8 and 2.65 A resolution. The antibody is one among three known structures with long H3 loops. This loop conformation is observed for the first time in the presence of the antigen. Residues from all six hypervariable loops interact with cyclosporin A. However, the 17 residues long loop H3 is the main contributor to the buried combining site area and to the van der Waals contacts made with cyclosporin A, with 52 and 63%, respectively, of the total contribution.

Identification of critical contact residues in the NC41 epitope of a subtype N9 influenza virus neuraminidase

We have examined amino acids on influenza virus neuraminidase (NA) subtype N9 (A/tern/Australia/G70c/75) which are in contact with monoclonal antibody NC41 to analyze individual interactions important for antibody recognition. The crystal structure of NA complexed with NC41 Fab1 shows antibody contacts at 19 amino acid residues on the NA surface which are localized on five polypeptide loops surrounding the enzyme active site. Fifteen mutant NA genes were constructed to encode a protein which contained a single amino acid substitution and these were tested for effects of the replacement on NC41 binding. Our data revealed that NAs with changes at 368, 400, and 434 completely lost NC41 recognition. NAs with side chains replaced at residues 346 and 373 exhibited binding reduced to less than 50% of wild-type binding. Changes in seven other contacting residues, including substituted side chains which differed considerably from wild-type NA in size and charge, had no significant effect on NC41 binding. These results indicate that only a few of the many residues which make up an epitope are crucial for interaction and provide the critical contacts required for antibody recognition. This implies that antibody escape mutants are selected only if they contain changes at these crucial sites, or changes which introduce bulky side chains that sterically prevent antibody attachment.

Identification of a pathogenic epitope involved in initiation of Heymann nephritis

Heymann nephritis is an experimental autoimmune disease model for human membranous nephropathy. We have recently identified a pathogenic epitope, clone 14 (C14), responsible for formation and deposition of glomerular immune complexes that is contained within the small subunit of the Heymann nephritis antigenic complex (HNAC). HNAC is a heterodimer composed of a large subunit designated gp330 and a smaller (44 kDa) subunit, which is immunologically identical to the receptor-associated protein. In this study, we prepared antibodies to fusion proteins with C-terminal deletions in the C14 sequence and assessed their ability to promote formation of immune deposits (IDs). When IgG specific for the shortest truncated fusion protein (C14/delta 3; 86 amino acids) was injected into rats, small IDs developed. In contrast, when IgG raised against the full-length C14 sequence was depleted of its reactivity toward the C14/delta 3 fusion protein (C14/delta 3-fp), no IDs could be detected. These data indicate that at least one pathogenic epitope is contained within the N-terminal 86 amino acids of C14. Since the IDs induced with the C14/delta 3-fp-specific IgG are smaller than those induced with the poly-epitope-specific anti-gp330 antibodies, it is likely that other epitopes in addition to those expressed by the C14/delta 3-fp are required for formation and growth of immune complexes.

The use of multiple-pin peptide synthesis in an analysis of the continuous epitopes recognised by various anti-(recombinant bovine growth hormone) sera. Comparison with predicted regions of immunogenicity and location within the three-dimensional structure of the molecule

A recently developed technology called epitope scanning permits the rapid and accurate delineation of continuous stretches of amino acids in a protein which constitute the sequential epitopes recognised by an antiserum raised to that protein. In the present report, we describe the use of this technique to identify the epitopes in the recombinant bovine growth-hormone (rbGH) molecule recognised by three polyclonal guinea-pig antisera and two polyclonal rabbit antisera. The results obtained show that, for guinea-pig antisera, 3 or 4, very-well-defined major continuous epitopes are present. As would be expected given the intrinsic genetic factors (major histocompatibility restriction, antigen processing and presentation) controlling the immune response in individual animals, subtle differences are evident in the precise location and relative reactivities of these epitopes in different guinea-pig antisera. Nevertheless, there is a large degree of overlap in these epitopes, such that immunodominant regions of the antigen can be clearly delineated. In a structural sense, these epitopes share a common motif in that they are sited in areas of the protein antigen with little secondary structure (loop/coil), although there is some contribution by neighbouring alpha-helices. For the two rabbit antisera, the response tends to be rather more heterogeneous, with recognition of more peptides and less clearly defined epitopes than was the case with the guinea-pig antiserum. Comparison of the four guinea-pig epitopes, identified by our experimental methods with computer predictions for this molecule (Jameson-Wolf antigenic index), indicate that two are strongly predicted, one is weakly predicted and one is not predicted. These observations, together with the displayed intraspecies and interspecies variation clearly indicate the limitations of these predictive methods. In conclusion, we have demonstrated that, despite the expected variation in the exact location of continuous epitopes defined by different anti-rbGH sera, there are large regions of overlap defining immunogenic core regions within the molecule. We believe that studies of this nature, together with further understanding of antigen processing and peptide presentation to immune cells, may have a role to play in the development of candidate peptide vaccines.

Investigation of the solid- and solution-phase binding reactivities of continuous epitopes recognized by polyclonal guinea-pig anti-recombinant bovine growth hormone antisera

We have used the technique of multiple pin peptide synthesis to identify three major continuous epitopes in the recombinant bovine (rb) GH molecule. We have synthesized these peptides, residues 24-40, 139-152 and 179-189, as N-terminally acetylated, C-terminal amides and confirmed their reactivity in a standard solid-phase ELISA. Subsequently, for epitope 139-152, we have synthesized a peptide affinity column and used this to isolate antibodies with this epitope specificity from whole antiserum. In addition, we demonstrate that under native conditions in a liquid phase RIA, these antibodies will precipitate [125I]rbGH. Further, peptide 139-152 itself also cross-reacts in an rbGH RIA inhibiting binding by up to 20%. Our data suggest that during the immune response to rbGH in guinea-pigs a substantial part of the B-cell response is directed to the 139-152 region and that this part of the protein is a native epitope.

Preferential V beta gene usage and lack of junctional sequence conservation among human T cell receptors specific for a tetanus toxin-derived peptide: evidence for a dominant role of a germline-encoded V region in antigen/major histocompatibility complex recognition

To investigate the structural and genetic basis of the T cell response to defined peptide/major histocompatibility (MHC) class II complexes in humans, we established a large panel of T cell clones (61) from donors of different HLA-DR haplotypes and reactive with a tetanus toxin-derived peptide (tt830-844) recognized in association with most DR molecules (universal peptide). By using a bacterial enterotoxin-based proliferation assay and cDNA sequencing, we found preferential use of a particular V beta region gene segment, V beta 2.1, in three of the individuals studied (64%, n = 58), irrespective of whether the peptide was presented by the DR6wcI, DR4w4, or DRw11.1 and DRw11.2 alleles, demonstrating that shared MHC class II antigens are not required for shared V beta gene use by T cell receptors (TCRs) specific for this peptide. V alpha gene use was more heterogeneous, with at least seven different V alpha segments derived from five distinct families encoding alpha chains able to pair with V beta 2.1 chains to form a tt830-844/DR-specific binding site. Several cases were found of clones restricted to different DR alleles that expressed identical V beta and (or very closely related) V alpha gene segments and that differed only in their junctional sequences. Thus, changes in the putative complementary determining region 3 (CDR3) of the TCR may, in certain cases, alter MHC specificity and maintain peptide reactivity. Finally, in contrast to what has been observed in other defined peptide/MHC systems, a striking heterogeneity was found in the junctional regions of both alpha and beta chains, even for TCRs with identical V alpha and/or V beta gene segments and the same restriction. Among 14 anti-tt830-844 clones using the V beta 2.1 gene segment, 14 unique V beta-D-J beta junctions were found, with no evident conservation in length and/or amino acid composition. One interpretation for this apparent lack of coselection of specific junctional sequences in the context of a common V element, V beta 2.1, is that this V region plays a dominant role in the recognition of the tt830-844/DR complex.

Antigen mobility in the combining site of an anti-peptide antibody

The interaction between a high-affinity antibody, raised against a peptide incorporating the loop region of hen egg lysozyme (residues 57-84), and a peptide antigen corresponding to this sequence, has been probed by proton NMR. The two-dimensional correlated spectroscopy spectrum of the antibody-antigen complex shows sharp, well-resolved resonances from at least half of the bound peptide residues, indicating that the peptide retains considerable mobility when bound to the antibody. The strongly immobilized residues (which include Arg-61, Trp-62, Trp-63, and Ile-78) do not correspond to a contiguous region in the sequence of the peptide. Examination of the crystal structure of the protein shows that these residues, although remote in sequence, are grouped together in the protein structure, forming a hydrophobic projection on the surface of the molecule. The antibody binds hen egg lysozyme with only a 10-fold lower affinity than the peptide antigen. We propose that the peptide could bind to the antibody in a conformation that brings these groups together in a manner related to that found in the native protein, accounting for the high crossreactivity.

Antibodies that are specific for a single amino acid interchange in a protein epitope use structurally distinct variable regions

We have analyzed how the immune system generates antibodies that are specific for analogues of an epitope on the influenza virus hemagglutinin (HA) that differ solely by the presence of Asp or Gly at amino acid 225. Most antibodies induced in response to HA(Asp225) use one of a few closely related variable (V) region structures that are encoded by characteristic VH/Vk gene segment combinations. Remarkably, none of these VH/Vk combinations was induced in response to HA(Gly225). Instead of modifying the HA(Asp225)-specific V regions by junctional variation or somatic mutation to recognize the altered epitope, new VH/Vk combinations were used. The expression of unique VH/Vk combinations appears to confer exquisite specificity to the selection of HA-specific B cells from the pre-immune repertoire.

Crystallization and preliminary X-ray diffraction data of the Fab fragment of a monoclonal antibody against apamin, a bee venom neurotoxin

Fab fragments of anti-apamin monoclonal antibodies have been purified to homogeneity and crystallized. The crystals belong to the monoclinic space group P21 with cell dimensions a = 99.0 +/- 0.3 A, b = 137.1 +/- 0.4 A, c = 76.0 +/- 0.2 A and beta = 92.9 +/- 0.9 degrees. They most likely contain four molecules in the asymmetric unit (Vm = 2.39 A3/Da). The possibility of the existence of non-crystallographic symmetry is discussed.

Three antibody molecules can bind simultaneously to each monomer of the tetramer of influenza virus neuraminidase and the trimer of influenza virus hemagglutinin

Trimeric hemagglutinin and tetrameric neuraminidase molecules isolated from influenza virus bind an average of 9 and 13 molecules respectively of monovalent antibody fragments prepared from IgG isolated from polyclonal sera. In each case this represents an average of approximately three molecules of antibody binding to each protomer. Although there is compelling evidence for the presence of multiple adjacent and overlapping epitopes covering the surface of these two viral antigens, steric hindrance ensures that even under saturating conditions only three molecules of monovalent antibody fragments can be simultaneously accommodated on each monomer.

Spot-scan imaging of microcrystals of an influenza neuraminidase-antibody fragment complex

Electron micrographs of two-dimensional microcrystals of a complex of an avian influenza virus neuraminidase and an antibody Fab fragment, termed 32/3, have been recorded using the spot-scan method of imaging. The crystals have a large unit cell (159.5 A x 159.5 A x 130.5 A) and a high solvent content (approximately 71% by volume) and are a challenging specimen for testing the spot-scan methodology. Crystalline order was preserved to beyond 4 A resolution as demonstrated by electron diffraction, using an embedding medium of a mixture of glucose and neutral potassium phosphotungstate. Using a Philips C400 computer control system interfaced to an EM420 electron microscope, and with the inclusion of additional software in the system, we have been able to record micrographs at low temperature with a relatively narrow (1500 A diameter) moving beam. There is evidence that the use of such a spot-scan beam reduces the effects of beam-induced specimen motion on the quality of micrographs. Conventional low-dose "flood-beam" images showed good isotropic optical diffraction in only 15% of cases whereas 30% of spot-scan images showed good diffraction. The best flood-beam images gave phases to only 15 A resolution after computer processing, whereas the best spot-scan images gave phases to 7 A resolution. Electron diffraction patterns were also recorded at low temperature, and the resulting diffraction amplitudes combined with phases from spot-scan images to yield a projection map of the structure. A 7 A resolution projection map of the complex is presented, and is compared with the projection map of the same avian influenza neuraminidase complexed with a different monoclonal Fab fragment, NC41, which has been solved to high resolution by X-ray diffraction.

Mechanism of antigenic variation in an individual epitope on influenza virus N9 neuraminidase

Monoclonal antibodies which inhibit influenza virus neuraminidase (NA) and which therefore indirectly neutralize virus infectivity bind to epitopes located on the rim of the active-site crater. The three-dimensional structure of one of these epitopes, recognized by monoclonal antibody NC41, has previously been determined (W. R. Tulip, J. N. Varghese, R. G. Webster, G. M. Air, W. G. Laver, and P. M. Colman, Cold Spring Harbor Symp. Quant. Biol. 54:257-263, 1989). Nineteen escape mutants of influenza virus A/tern/Australia/G70c/75 (N9) NA selected with NC41 were sequenced. A surprising restriction was seen in the sequence changes involved. Ten mutants had a Ser-to-Phe change at amino acid 372, and six others had mutations at position 367. No escape mutants with changes at 369 or 370 were found, although these mutations were selected with other antibodies and rendered the epitope unrecognizable by antibody NC41. Another N9 NA, from A/ruddy turnstone/NJ/85, which differs by 14 amino acids from the tern virus NA, still bound antibody NC41. Epitope mapping by selecting multiple escape mutants with antibody NC41 thus identified only three of the five polypeptide loops on NA that contact the antibody. Escape mutants selected sequentially with three different monoclonal antibodies showed three sequence changes in two loops of the NC41 epitope. The multiple mutants were indistinguishable from wild-type virus by using polyclonal rabbit antiserum in double immunodiffusion tests, but NA inhibition titers were fourfold lower. The results suggest that although the NC41 epitope contains 22 amino acids, only a few of these are so critical to the interaction with antibody that a single sequence change allows selection of an escape mutant. In that case, the variety of amino acid sequence changes which can lead to polyclonal selection of new epidemic viruses during antigenic drift might be very limited.

Three-dimensional structure of an idiotope-anti-idiotope complex

Serologically detected antigenic determinants unique to an antibody or group of antibodies are called idiotopes. The sum of idiotopes of an antibody constitute its idiotype. Idiotypes have been intensively studied following a hypothesis for the self-regulation of the immune system through a network of idiotype-anti-idiotype interactions. Furthermore, as antigen and anti-idiotypes can competitively bind to idiotype-positive, antigen-specific antibodies, anti-idiotypes may carry an 'internal image' of the external antigen. Here we describe the structure of the complex between the monoclonal anti-lysozyme FabD1.3 and the anti-idiotopic FabE225 at 2.5 A resolution. This complex defines a private idiotope consisting of 13 amino-acid residues, mainly from the complementarity-determining regions of D1.3. Seven of these residues make contacts with the antigen, indicating a significant overlap between idiotope and antigen-combining site. Idiotopic mimicry of the external antigen is not achieved at the molecular level in this example.

Small rearrangements in structures of Fv and Fab fragments of antibody D1.3 on antigen binding

The potential use of monoclonal antibodies in immunological, chemical and clinical applications has stimulated the protein engineering and expression of Fv fragments, which are heterodimers consisting of the light and heavy chain variable domains (VL and VH) of antibodies. Although Fv fragments exhibit antigen binding specificity and association constants similar to their parent antibodies or Fab moieties, similarity in their interactions with antigen at the level of three-dimensional structure has not been investigated. We have determined the high-resolution crystal structure of the genetically engineered FvD1.3 fragment of the anti-hen egg-white lysozyme (HEL) monoclonal antibody D1.3, and of its complex with HEL. On comparison with the crystallographically refined FabD1.3-HEL complex, we find that FvD1.3 and FabD1.3 make, with minor exceptions, very similar contacts with the antigen. Furthermore, a small but systematic rearrangement of the domains of FvD1.3 occurs on binding HEL, bringing the contacting residues closer to the antigen by a mean value of about 0.7 A for VH (aligning on VL) or of 0.5 A for VL (aligning on VH). This is indicative of an induced fit rather than a 'lock and key' fit to the antigen.

Evolutionary changes in influenza B are not primarily governed by antibody selection

Influenza B viruses evolve more slowly than human influenza A, but no reasons for the difference have been established. We have analyzed sequence changes in the hemagglutinin and neuraminidase of influenza B viruses (and have determined four hemagglutinin sequences, of B/Bonn/43, B/USSR/100/83, B/Victoria/3/85, and B/Memphis/6/86) in relation to antigenic properties and compared these with similar analyses of variation in influenza A antigens. Independent of the slower rate of change in influenza B antigens, only approximately 30% of nucleotide changes in either the hemagglutinin or neuraminidase gene sequence result in amino acid changes in the protein, whereas in influenza A 50% of nucleotide changes result in altered amino acids. Thus, there is less selection for change, or less tolerance to change, in the influenza B antigens. This is similar to findings with influenza C and findings with influenza A viruses that replicate in lower animals and birds and is closer to the type of variation found in other RNA viruses. We propose that human influenza A is unique in that it is the only virus group in which antibody selection dominates evolutionary change.