Structural evidence for induced fit as a mechanism for antibody-antigen recognition.

The three-dimensional structure of a specific antibody (Fab 17/9) to a peptide immunogen from influenza virus hemagglutinin [HA1(75-110)] and two independent crystal complexes of this antibody with bound peptide (TyrP100-LeuP108) have been determined by x-ray crystallographic techniques at 2.0 A, 2.9 A, and 3.1 A resolution, respectively. The nonapeptide antigen assumes a type I beta turn in the antibody combining site and interacts primarily with the Fab hypervariable loops L3, H2, and H3. Comparison of the bound and unbound Fab structures shows that a major rearrangement in the H3 loop accompanies antigen binding. This conformational change results in the creation of a binding pocket for the beta turn of the peptide, allowing TyrP105 to be accommodated. The conformation of the peptide bound to the antibody shows similarity to its cognate sequence in the HA1, suggesting a possible mechanism for the cross-reactivity of this Fab with monomeric hemagglutinin. The structures of the free and antigen bound antibodies demonstrate the flexibility of the antibody combining site and provide an example of induced fit as a mechanism for antibody-antigen recognition.

X-ray crystal structure of C3d: a C3 fragment and ligand for complement receptor 2.

Activation and covalent attachment of complement component C3 to pathogens is the key step in complement-mediated host defense. Additionally, the antigen-bound C3d fragment interacts with complement receptor 2 (CR2; also known as CD21) on B cells and thereby contributes to the initiation of an acquired humoral response. The x-ray crystal structure of human C3d solved at 2.0 angstroms resolution reveals an alpha-alpha barrel with the residues responsible for thioester formation and covalent attachment at one end and an acidic pocket at the other. The structure supports a model whereby the transition of native C3 to its functionally active state involves the disruption of a complementary domain interface and provides insight into the basis for the interaction between C3d and CR2.

X-ray crystal structures of animal lectins.

Several important advances in the structure determination of animal lectins were made in the past year. The X-ray crystal structures of trimeric fragments of the human and rat mannose-binding proteins have defined for the first time the three-dimensional subunit organization of a multimeric C-type lectin. In addition, the structure of a galectin-biantennary oligosaccharide complex has provided a model for what might be biochemically relevant cross-linking interactions. Finally, in a novel variation on lectin cross-linking, independent carbohydrate-binding sites on basic fibroblast growth factor have been found to recognize opposing faces of a synthetic heparin/heparan sulphate fragment, leading to growth-factor polymerization.

New animal lectin structures.

The past year has provided the X-ray crystal structures of both the N-terminal domain of sialoadhesin and the extracytoplasmic domain of the cation-dependent mannose 6-phosphate receptor. These structures represent the first examples from the I- and P-type lectin families and provide important insights into how these transmembrane-spanning receptors function. In addition, structures of galectin-7 and of the carbohydrate-recognition domain of galectin-3 have given evidence of a new galectin quaternary structure. Finally, the structure of tachylectin-2, the first example of a fivefold symmetric beta-propeller protein, sheds light on the role played by this lectin in horseshoe crab host defense.

Glycosyltransferase structure and mechanism.

The high-resolution X-ray crystal structures of a new form of bacteriophage T4 beta-glucosyltransferase, Escherichia coli MurG, Bacillus subtilis SpsA, bovine beta-1,4-galactosyltransferase 1 and rabbit N-acetylglucosaminyltransferase I have now been solved. These glycosyltransferase structures have provided the first detailed view of the structural basis of catalysis, as well as new insight into glycosyltransferase classification.

Major antigen-induced domain rearrangements in an antibody.

BACKGROUND: Recent structural results have shown that antibodies use an induced fit mechanism to recognize and bind their antigens. Here we present the crystallographically determined structure of an Fab directed against an HIV-1 peptide (Fab 50.1) in the unliganded state and compare it with the peptide-bound structure. We perform a detailed analysis of the components that contribute to enhanced antigen binding and recognition. RESULTS: Induced fit of Fab 50.1 to its peptide antigen involves a substantial rearrangement of the third complementarity determining region loop of the heavy chain (H3), as well as a large rotation of the variable heavy (VH) chain relative to the variable light (VL) chain. Analysis of other Fab structures suggests that the extent of the surface area buried at the VL-VH interface correlates with the ability to alter antibody quaternary structure by reorientation of the VL-VH domains. CONCLUSION: Fab 50.1 exhibits the largest conformational changes yet observed in a single antibody. These can be attributed to the flexibility of the variable region. Comparisons of new data with previous examples lend to the general conclusion that a small VL-VH interface, due in part to a short H3 loop, permits substantial alterations to the antigen-binding pocket. This has major implications for the prediction, engineering and design of antibody-combining sites.

Detailed analysis of the free and bound conformations of an antibody. X-ray structures of Fab 17/9 and three different Fab-peptide complexes.

A new orthorhombic crystal form of Fab 17/9 has been determined in complex with a 7-mer peptide from influenza virus hemagglutinin (HA1 101-107, acetylated and amidated). The three-dimensional structure was resolved to 2.8 A with an improved refinement and better geometry than two previously determined Fab 17/9-peptide (HA1 100-108) complexes, facilitating a detailed description of the Fab-peptide interactions. The binding pockets and the peptide antigen are structurally similar in all three peptide complexes of Fab 17/9. The peptide adopts an extended conformation (residues 100 to 103) and a type I reverse turn (residues 104 to 107). Additionally, the antigenic determinant described here correlates well with previous epitope mapping studies. The structures of the free and antigen bound Fab illustrate the role of induced fit as a mechanism for antibody-antigen recognition. Fab 17/9 undergoes a large conformational change, mainly in the H3 loop, upon peptide binding. As a result, the shape of the binding pocket changes substantially in the liganded Fab. However, the backbone conformations of the other hypervariable loops (L2, L3, H1 and H2) show no significant difference between free and bound structures. The conformation of the L1 loop is also maintained in all structures, but its position relative to the framework varies in different crystal environments. The availability of three X-ray structures of an Fab-peptide complex in three different space groups makes it possible to clearly distinguish between crystal packing and antigen binding as the cause of structural differences. Two distinct H3-loop conformations, free and bound, are observed with no evidence otherwise for multiple conformations of the hypervariable loops (CDRs) or increased flexibility in either the free or bound forms.

Crystallization and preliminary X-ray diffraction studies of a pea lectin-methyl 3,6-di-O-(alpha-D-mannopyranosyl)-alpha-D-mannopyranoside complex.

The seed lectin isolated from garden peas (Pisum sativum) has been co-crystallized with methyl 3,6-di-O-(alpha-D-mannopyranosyl)-alpha-D-mannopyranoside in the orthorhombic space group P2(1)2(1)2(1) with unit cell dimensions a = 64.3 A, b = 73.4 A and C = 108.5 A. The asymmetric unit contains one pea lectin dimer (alpha 2 beta 2). The crystals are suitable for high-resolution structure analysis.

Crystallization and preliminary X-ray diffraction analysis of the human dimeric S-Lac lectin (L-14-II).

The human recombinant S-Lac lectin, L-14-II, produced in an Escherichia coli expression system, has been co-crystallized in the presence of lactose by the hanging drop vapor diffusion method. The crystals grow in space group P2(1)2(1)2(1) with unit cell dimensions of a = 43.6 A, b = 57.8 A, c = 108.2 A, with a dimer in the asymmetric unit. On a conventional rotating anode the crystals diffract to at least 2.8 A resolution.

Intensity-based domain refinement of oriented but unpositioned molecular replacement models.

A program is described that performs least-squares group refinement of oriented molecular replacement models whose positions in the unit cell are unknown. The program (INTREF) is designed to produce improved models for use in a translation function by optimizing the orientations and relative translations of the model domains. The molecular contents of the asymmetric unit are refined as a small number of rigid bodies whose origins relative to each other may be unknown. More than one molecule in the asymmetric unit can be accommodated. The refinement seeks to minimize the residual error between the observed and calculated intensities that have been modified to produce the equivalent of a radial weighting in Patterson space. Calculated intensities include contributions from all symmetry-related molecules, enabling meaningful refinement in high-symmetry space groups. Derivatives of the intensities with respect to the rigid-body parameters are evaluated numerically using fast Fourier transforms and the shifts are obtained by non-linear least-squares analysis. Results with test cases show that the program is capable of adjusting the orientations and relative translations of protein domains to give models that more closely resemble the known structures. Consequently, the resulting models produce more accurate and more interpretable results in translation functions. The importance of including all crystallographically related molecules and of downweighting the contribution of the longer-radius region of the Patterson function is demonstrated.

Pandemic H1N1 Influenza Infection and Vaccination in Humans Induces Cross-Protective Antibodies that Target the Hemagglutinin Stem.

Most monoclonal antibodies (mAbs) generated from humans infected or vaccinated with the 2009 pandemic H1N1 (pdmH1N1) influenza virus targeted the hemagglutinin (HA) stem. These anti-HA stem mAbs mostly used IGHV1-69 and bound readily to epitopes on the conventional seasonal influenza and pdmH1N1 vaccines. The anti-HA stem mAbs neutralized pdmH1N1, seasonal influenza H1N1 and avian H5N1 influenza viruses by inhibiting HA-mediated fusion of membranes and protected against and treated heterologous lethal infections in mice with H5N1 influenza virus. This demonstrated that therapeutic mAbs could be generated a few months after the new virus emerged. Human immunization with the pdmH1N1 vaccine induced circulating antibodies that when passively transferred, protected mice from lethal, heterologous H5N1 influenza infections. We observed that the dominant heterosubtypic antibody response against the HA stem correlated with the relative absence of memory B cells against the HA head of pdmH1N1, thus enabling the rare heterosubtypic memory B cells induced by seasonal influenza and specific for conserved sites on the HA stem to compete for T-cell help. These results support the notion that broadly protective antibodies against influenza would be induced by successive vaccination with conventional influenza vaccines based on subtypes of HA in viruses not circulating in humans.

Lectin structure.

Lectins comprise a structurally very diverse class of proteins characterized by their ability to bind carbohydrates with considerable specificity. They are found in organisms ranging from viruses and plants to humans and serve to mediate biological recognition events. Although lectins bind monosaccharides rather weakly, they employ common strategies for enhancing both the affinity and specificity of their interactions for more complex carbohydrate ligands. The terms subsite and subunit multivalency are defined to describe the ways in which these enhancements are achieved. Analysis of the X-ray crystal structures of different lectin types serves to illustrate how, in structural terms, subsite and subunit multivalency confer context-specific functional properties.

Structural basis of calcium-induced E-cadherin rigidification and dimerization.

The cadherins mediate cell adhesion and play a fundamental role in normal development. They participate in the maintenance of proper cell-cell contacts: for example, reduced levels of epithelial cadherin (E-cadherin) correlate with increased invasiveness in many human tumour cell types. The cadherins typically consist of five tandemly repeated extracellular domains, a single membrane-spanning segment and a cytoplasmic region. The N-terminal extracellular domains mediate cell-cell contact while the cytoplasmic region interacts with the cytoskeleton through the catenins. Cadherins depend on calcium for their function: removal of calcium abolishes adhesive activity, renders cadherins vulnerable to proteases (reviewed in ref. 4) and, in E-cadherin, induces a dramatic reversible conformational change in the entire extracellular region. We report here the X-ray crystal structure at 2.0 A resolution of the two N-terminal extracellular domains of E-cadherin in the presence of calcium. The structure reveals a two-fold symmetric dimer, each molecule of which binds a contiguous array of three bridged calcium ions. Not only do the bound calcium ions linearize and rigidify the molecule, they promote dimerization. Although the N-terminal domain of each molecule in the dimer is aligned in a parallel orientation, the interactions between them differ significantly from those found in the neural cadherin (N-cadherin) N-terminal domain (NCD1) structure. The E-cadherin dual-domain structure reported here defines the role played by calcium in the cadherin-mediated formation and maintenance of solid tissues.

Amino acid sequence differences in the alpha chains of pea seed isolectins: C-terminal processing.

The complete amino acid sequence of the alpha chains of both isolectins found in pea seeds has been determined using automated Edman degradation. We show that the alpha chains of these two proteins differ only at their C-termini: isolectin B is two amino acids longer than isolectin A. Furthermore, the alpha chains of both isolectins are shorter than would be predicted from the nucleotide sequence of a cDNA clone for pea lectin. We suggest, therefore, that these proteins arise from differential C-terminal processing. Amino acid composition data and C-terminal analysis show that the beta chains have also been processed at their C-termini, but in this case identical chains for both isolectins are produced.

X-ray crystal structure of the human dimeric S-Lac lectin, L-14-II, in complex with lactose at 2.9-A resolution.

S-Lac lectins are a family of soluble lactose-binding animal lectins, some of which have been implicated in modulating cell-cell and cell-matrix interactions through specific carbohydrate-mediated recognition. We report here the x-ray crystal structure of a representative member of this family, the human dimeric S-Lac lectin, L-14-II, in complex with lactose, at 2.9-A resolution. The two-fold symmetric dimer is made up of two extended anti-parallel beta-sheets, which associate in a beta-sandwich motif. Remarkably, the L-14-II monomer shares not only the same topology, but a very similar beta-sheet structure with that of the leguminous plant lectins, suggesting a conserved structure-function relationship. Carbohydrate binding by L-14-II was found to involve protein residues that are very highly conserved among all S-Lac lectins. These residues map to a single DNA exon, suggesting a carbohydrate binding cassette common to all S-Lac lectins.

X-ray crystal structure of rabbit N-acetylglucosaminyltransferase I: catalytic mechanism and a new protein superfamily.

N:-acetylglucosaminyltransferase I (GnT I) serves as the gateway from oligomannose to hybrid and complex N:-glycans and plays a critical role in mammalian development and possibly all metazoans. We have determined the X-ray crystal structure of the catalytic fragment of GnT I in the absence and presence of bound UDP-GlcNAc/Mn(2+) at 1.5 and 1.8 A resolution, respectively. The structures identify residues critical for substrate binding and catalysis and provide evidence for similarity, at the mechanistic level, to the deglycosylation step of retaining beta-glycosidases. The structuring of a 13 residue loop, resulting from UDP-GlcNAc/Mn(2+) binding, provides an explanation for the ordered sequential 'Bi Bi' kinetics shown by GnT I. Analysis reveals a domain shared with Bacillus subtilis glycosyltransferase SpsA, bovine beta-1,4-galactosyl transferase 1 and Escherichia coli N:-acetylglucosamine-1-phosphate uridyltransferase. The low sequence identity, conserved fold and related functional features shown by this domain define a superfamily whose members probably share a common ancestor. Sequence analysis and protein threading show that the domain is represented in proteins from several glycosyltransferase families.

Independent Lec1A CHO glycosylation mutants arise from point mutations in N-acetylglucosaminyltransferase I that reduce affinity for both substrates. Molecular consequences based on the crystal structure of GlcNAc-TI.

A key enzyme in regulating the maturation of N-linked glycans is UDP-N-acetylglucosamine:alpha-3-D-mannoside beta-1,2-N-acetylglucosaminyltransferase I (GlcNAc-TI, EC 2.4.1.101). Lec1 CHO cells lack GlcNAc-TI activity and synthesize only the oligomannosyl class of N-glycans. By contrast, Lec1A CHO mutants have weak GlcNAc-TI activity due to the reduced affinity of GlcNAc-TI for both the UDP-GlcNAc and Man(5)GlcNAc(2)Asn substrates. Lec1A CHO mutants synthesize hybrid and complex N-glycans, albeit in reduced amounts compared to parental CHO cells. In this paper, we identify two point mutations that gave rise to the Lec1A phenotype in three independent Lec1A CHO mutants. The G634A mutation in Lec1A.2C converts an aspartic acid to an asparagine at amino acid 212, disrupting a conserved DXD motif (E(211)DD(213) in all GlcNAc-TIs) that makes critical interactions with bound UDP-GlcNAc and Mn(2+) ion in rabbit GlcNAc-TI. The C907T mutation in Lec1A.3E and Lec1A.5J converts an arginine conserved in all GlcNAc-TIs to a tryptophan at amino acid 303, altering interactions that are important in stabilizing a critical structural element in rabbit GlcNAc-TI. Correction of each mutation by site-directed mutagenesis restored their GlcNAc-TI activity and lectin binding properties to parental levels. The effect of the two amino acid changes on GlcNAc-TI catalysis is discussed in relation to the crystal structure of rabbit GlcNAc-TI complexed with manganese and UDP-GlcNAc.

X-ray crystal structure of the human galectin-3 carbohydrate recognition domain at 2.1-A resolution.

Galectins are a family of lectins which share similar carbohydrate recognition domains (CRDs) and affinity for small beta-galactosides, but which show significant differences in binding specificity for more complex glycoconjugates. We report here the x-ray crystal structure of the human galectin-3 CRD, in complex with lactose and N-acetyllactosamine, at 2.1-A resolution. This structure represents the first example of a CRD determined from a galectin which does not show the canonical 2-fold symmetric dimer organization. Comparison with the published structures of galectins-1 and -2 provides an explanation for the differences in carbohydrate-binding specificity shown by galectin-3, and for the fact that it fails to form dimers by analogous CRD-CRD interactions.

X-ray crystal structure of a pea lectin-trimannoside complex at 2.6 A resolution.

The x-ray crystal structure of pea lectin, in complex with a methyl glycoside of the N-linked-type oligosaccharide trimannosyl core, methyl 3,6-di-O-(alpha-D-mannopyranosyl)-alpha-D-mannopyranoside, has been solved by molecular replacement and refined at 2.6-A resolution. The R factor is 0.183 for all data in the 8.0 to 2.6 A resolution range with an average atomic temperature factor of 26.1 A2. Strong electron density for a single mannose residue is found in the monosaccharide-binding site suggesting that the trisaccharide binds primarily through one of the terminal alpha-linked mannose residues. The complex is stabilized by hydrogen bonds involving the protein residues Asp-81, Gly-99, Asn-125, Ala-217, and Glu-218, and the carbohydrate oxygen atoms O3, O4, O5, and O6. In addition, the carbohydrate makes van der Waals contacts with the protein, involving Phe-123 in particular. These interactions are very similar to those found in the monosaccharide complexes with concanavalin A and isolectin 1 of Lathyrus ochrus, confirming the structural relatedness of this family of proteins. Comparison of the pea lectin complex with the unliganded pea lectin and concanavalin A structures indicates differences in the conformation and water structure of the unliganded binding sites of these two proteins. Furthermore, a correlation between the position of the carbohydrate oxygen atoms in the complex and the bound water molecules in the unliganded binding sites is found. Binding of the trimannose core through a single terminal monosaccharide residue strongly argues that an additional fucose-binding site is responsible for the high affinity pea lectin-oligosaccharide interactions.