Structural studies on the mechanisms of antibody-mediated neutralization of human rhinovirus

Antibodies represent a major component of the mammalian immunological defense against picornavirus infection. The work reviewed here examines structural details of antibody-mediated neutralization of human rhinovirus 14 (HRV14) using a combination of crystallography, molecular biology and electron microscopy. The atomic structures of the Fab fragment from a neutralizing monoclonal antibody (Fab17-IA) and HRV14 were used to interpret the ∼25Å resolution cryo-electron microscopy structure of the Fab17-IA/HRV14 complex. While there were not any observable antibody-induced conformational changes in the HRV14 upon antibody binding, there was evidence that charge interactions dominate the paratope-epitope interface and that the intact antibody might bind bivalently across icosahedral two-fold axes. Site-directed mutagenesis results confirmed that charge interactions dominate antibody binding and electron microscopy studies on the mAb17-IA/HRV14 complex confirmed that this neutralizing antibody binds bivalently across icosahedral two-fold axes.     

Antibody-Mediated Neutralization of Human Rhinovirus 14 Explored by Means of Cryoelectron Microscopy and X-Ray Crystallography of Virus-Fab Complexes

The structures of three different human rhinovirus 14 (HRV14)-Fab complexes have been explored with X-ray crystallography and cryoelectron microscopy procedures. All three antibodies bind to the NIm-IA site of HRV14, which is the β-B–β-C loop of the viral capsid protein VP1. Two antibodies, Fab17-IA (Fab17) and Fab12-IA (Fab12), bind bivalently to the virion surface and strongly neutralize viral infectivity whereas Fab1-IA (Fab1) strongly aggregates and weakly neutralizes virions. The structures of the two classes of virion-Fab complexes clearly differ and correlate with observed binding neutralization differences. Fab17 and Fab12 bind in essentially identical, tangential orientations to the viral surface, which favors bidentate binding over icosahedral twofold axes. Fab1 binds in a more radial orientation that makes bidentate binding unlikely. Although the binding orientations of these two antibody groups differ, nearly identical charge interactions occur at all paratope-epitope interfaces. Nucleotide sequence comparisons suggest that Fab17 and Fab12 are from the same progenitor cell and that some of the differing residues contact the south wall of the receptor binding canyon that encircles each of the icosahedral fivefold vertices. All of the antibodies contact a significant proportion of the canyon region and directly overlap much of the receptor (intercellular adhesion molecule 1 [ICAM-1]) binding site. Fab1, however, does not contact the same residues on the upper south wall (the side facing away from fivefold axes) at the receptor binding region as do Fab12 and Fab17. All three antibodies cause some stabilization of HRV14 against pH-induced inactivation; thus, stabilization may be mediated by invariant contacts with the canyon.Picornaviruses are among the largest of animal virus families and include the well-known poliovirus, rhinovirus, foot-and-mouth disease virus (FMDV), coxsackievirus, and hepatitis A virus. The rhinoviruses, of which there are more than 100 serotypes subdivided into two groups, are major causative agents of the common cold in humans (42). The viruses are nonenveloped and have an ∼300-Å-diameter protein shell that encapsidates a single-stranded, plus-sense RNA genome of about 7,200 bases. The human rhinovirus 14 (HRV14) capsid exhibits a pseudo-T=3 (P=3) icosahedral symmetry and consists of 60 copies each of four viral proteins, VP1, VP2, VP3, and VP4, with VP4 at the RNA-capsid interface (40). An ∼20-Å deep canyon lies roughly at the junction of VP1 (forming the north rim) with VP2 and VP3 (forming the south rim) and surrounds each of the 12 icosahedral fivefold vertices. The canyon regions of HRV14 and HRV16, both major receptor group rhinoviruses, were shown to contain the binding site of the cellular receptor, intercellular adhesion molecule 1 (ICAM-1) (8, 24a, 37). Four major neutralizing immunogenic (NIm) sites, NIm-IA, NIm-IB, NIm-II, and NIm-III, were identified by studies of neutralization escape mutants with monoclonal antibodies (MAbs) (46, 47) and then mapped to four protruding regions on the viral surface (40).Several mechanisms of antibody-mediated neutralization have been proposed. Perhaps the simplest is based on aggregation of virions (5, 53, 54), which generally occurs over a narrow range of antibody/virus ratios. This limited range has raised questions about the role of aggregation in vivo. Alternative suggestions are that antibodies may neutralize virions by inducing extensive conformational changes in the capsid (15, 29), abrogate virus attachment to the host cell (8, 14), or prevent uncoating (57). There is no universal acceptance of a single neutralization mechanism, and the various MAbs may neutralize with different combinations of these mechanisms.Neutralizing MAbs against HRV14 have been divided into three groups: strong, intermediate, and weak neutralizers (26, 34). All strongly neutralizing antibodies bind to the NIm-IA site, which was defined by natural escape mutations at residues D1091 and E1095 of VP1 on the loop between the β-B and β-C strands of the VP1 β-barrel (the letter designates the amino acid, the first digit identifies the viral protein, and the remaining three digits specify the sequence number). Because strongly neutralizing antibodies form stable, monomeric virus-antibody complexes with a maximum stoichiometry of 30 antibodies per virion, it was concluded that they bind bivalently to the virions (26, 34). Weakly neutralizing antibodies form unstable, monomeric complexes with HRV14 and bind with a stoichiometry of ∼60 antibodies per virion (26, 52). The remaining antibodies, all of which precipitate the virions, are classified as intermediate neutralizers (26, 34).The structures of two complexes, the strongly neutralizing antibody MAb17-IA and its Fab fragment, Fab17, bound to HRV14, were determined by means of cryo-transmission electron microscopy (cryo-TEM) and three-dimensional image reconstruction (51, 52) and interpreted on the basis of model-building studies that used the atomic structures of HRV14 (40) and Fab17 (28). These studies showed that no observable conformational changes were induced in the viral capsid upon Fab or MAb binding. Modeling and site-directed mutagenesis studies demonstrated that electrostatic interactions play a key role in the binding of Fab17 to HRV14 (52). In the complex, the loop of the NIm-IA site on HRV14 sits clamped in the cleft between the heavy- and light-chain hypervariable regions and forms complementary electrostatic interactions with Lys58^H (on the heavy chain) and Arg91^L (on the light chain) of Fab17. In addition, a cluster of lysines on HRV14 (K1236, K1097, and K1085) interact with two acidic residues, Asp45^H and Asp54^H, in the CDR2 (CDR stands for complementarity-determining region) of the Fab heavy chain (49). Earlier modeling studies also suggested that bidentate binding of MAb17-IA to HRV14 is facilitated by rotation of the Fab constant domains about the elbow axes towards the viral twofold axes (51). This suggested that the flexibility of the elbow region (the junction between the variable and constant domains) plays a role in the bivalent binding process, which in turn increases antibody avidity. Finally, the 4-Å-resolution crystal structure of the Fab17-HRV14 complex clearly showed that the virion does not undergo conformational changes upon Fab binding (49). This crystal structure determination also revealed that the earlier docking of the HRV14 and Fab17 atomic structures into the 22-Å cryo-TEM density map (50) yielded a pseudo-atomic model that was very close to the real structure of the complex.We have expanded our complementary X-ray crystallography and cryo-TEM microscopy studies to examine the structures of two more Fab-virus complexes, using Fab fragments from two other NIm-IA antibodies, MAb1-IA (MAb1) and MAb12-IA (MAb12), bound to HRV14. MAb1 and MAb12 are weak and strong neutralizing antibodies, respectively. Image reconstructions of these two complexes are interpreted on the basis of pseudo-atomic models, which substantiate the previous hypothesis that neutralizing efficacy and binding valency are interrelated (34). Electrostatic interactions at the epitope-paratope interface are highly conserved and apparently important for the antibody binding to the virion surface. Like Fab17, Fab1 and Fab12 penetrate the canyon. There are, however, differences between the orientations of the strongly and weakly neutralizing antibodies and in the contacts made with the receptor binding region of the canyon. Finally, data suggesting that antibody binding to HRV14 is alone sufficient for neutralization and that other possible mechanisms are not required are presented.     

Structure of a Neutralizing Antibody Bound Monovalently to Human Rhinovirus 2

The structure of a complex between human rhinovirus 2 (HRV2) and the Fab fragment of neutralizing monoclonal antibody (MAb) 3B10 has been determined to 25-Å resolution by cryoelectron microscopy and three-dimensional reconstruction techniques. The footprint of 3B10 on HRV2 is very similar to that of neutralizing MAb 8F5, which binds bivalently across the icosahedral twofold axis. However, the 3B10 Fab fragment (Fab-3B10) is bound in an orientation, inclined at approximately 45° to the surface of the virus capsid, which is compatible only with monovalent binding of the antibody. The canyon around the fivefold axis is not directly obstructed by the bound Fab. The X-ray structures of a closely related HRV (HRV1A) and a Fab fragment were fitted to the density maps of the HRV2–Fab-3B10 complex obtained by cryoelectron microscope techniques. The footprint of 3B10 on the viral surface is largely on VP2 but also covers the VP3 loop centered on residue 3064 and the VP1 loop centered on residue 1267. MAb 3B10 can interact directly with VP2 residue 2164, the site of an escape mutation on VP2, and with VP1 residues 1264 to 1267, the site of a deletion escape mutation. Deletion of these residues shortens the VP1 loop, moving it away from the MAb binding site. All structural and biochemical evidence indicates that MAb 3B10 binds to a conformation epitope on HRV2.     

Formation of rhinovirus-soluble ICAM-1 complexes and conformational changes in the virion.

Viral receptors serve both to target viruses to specific cell types and to actively promote the entry of bound virus into cells. Human rhinoviruses (HRVs) can form complexes in vitro with a truncated soluble form of the HRV cell surface receptor, ICAM-1. These complexes appear to be stoichiometric, with approximately 60 ICAM molecules bound per virion or 1 ICAM-1 molecule per icosahedral face of the capsid. The complex can have two fates, either dissociating to yield free virus and free ICAM-1 or uncoating to break down to an 80S empty capsid which has released VP4, viral RNA, and ICAM-1. This uncoating in vitro mimics the uncoating of virus during infection of cells. The stability of the virus-receptor complex is dependent on temperature and the rhinovirus serotype. HRV serotype 14 (HRV14)-ICAM-1 complexes rapidly uncoat, HRV16 forms a stable virus-ICAM complex which does not uncoat detectably at 34 degrees C, and HRV3 has an intermediate phenotype. Rhinovirus can also uncoat after exposure to mildly acidic pH. The sensitivities of individual rhinovirus serotypes to ICAM-1-mediated virus uncoating do not correlate with uncoating promoted by incubation at low pH, suggesting that these two means of virus destabilization occur by different mechanisms. Soluble ICAM-1 and low pH do not act synergistically to promote uncoating. The rate of uncoating does appear to be inversely related to virus affinity for its receptor.     

Three-dimensional structure of the Fab fragment of a neutralizing antibody to human rhinovirus serotype 2.

The crystal structure of the antigen-binding fragment of a monoclonal antibody (8F5) that neutralizes human rhinovirus serotype 2 has been determined by X-ray diffraction studies. Antibody 8F5, obtained by immunization with native HRV2 virions, cross-reacts with peptides of the viral capsid protein VP2, which contribute to the neutralizing immunogenic site B in this serotype. The structure was solved by the molecular replacement method and has been refined to an R-factor of 18.9% at 2.8 A resolution. The elbow angle, relating the variable and constant modules of the molecule is 127 degrees, representing the smallest elbow angle observed so far in an Fab fragment. Furthermore, the charged residues of the epitope can be well accommodated in the antigen-binding site. This is the first crystal structure reported for an antibody directed against an icosahedral virus.     

Potent Dengue Virus Neutralization by a Therapeutic Antibody with Low Monovalent Affinity Requires Bivalent Engagement

We recently described our most potently neutralizing monoclonal antibody, E106, which protected against lethal Dengue virus type 1 (DENV-1) infection in mice. To further understand its functional properties, we determined the crystal structure of E106 Fab in complex with domain III (DIII) of DENV-1 envelope (E) protein to 2.45 Å resolution. Analysis of the complex revealed a small antibody-antigen interface with the epitope on DIII composed of nine residues along the lateral ridge and A-strand regions. Despite strong virus neutralizing activity of E106 IgG at picomolar concentrations, E106 Fab exhibited a ∼20,000-fold decrease in virus neutralization and bound isolated DIII, E, or viral particles with only a micromolar monovalent affinity. In comparison, E106 IgG bound DENV-1 virions with nanomolar avidity. The E106 epitope appears readily accessible on virions, as neutralization was largely temperature-independent. Collectively, our data suggest that E106 neutralizes DENV-1 infection through bivalent engagement of adjacent DIII subunits on a single virion. The isolation of anti-flavivirus antibodies that require bivalent binding to inhibit infection efficiently may be a rare event due to the unique icosahedral arrangement of envelope proteins on the virion surface.     

Crystallization of the Fab from a human monoclonal antibody against gp 41 of human immunodeficiency virus type I

A monoclonal IgG antibody directed against gp 41 from the human immunodeficiency virus (HIV-1) has been crystallized in both intact and Fab forms. Crystals of the intact antibody grow as tetragonal-like prisms too small for conventional X-ray analysis. However, the Fab portion of the antibody produces suitable plate-like crystals which belong to the space group P2(1)2(1)2(1) with unit cell constants of a = 66.5 A, b = 74.3 A and c = 105.3 A. There is one molecule of Fab in the asymmetric unit. The Fab crystals show diffraction to d-spacings less than 3.0 A.     

Docking of a human rhinovirus neutralizing antibody onto the viral capsid

The structure of the complex between the Fab fragment of a human rhinovirus serotype 2 (HRV2) neutralizing antibody (8F5) and a cross-reactive synthetic peptide derived from the viral capsid protein VP2 has been recently determined by crystallographic methods.¹ The conformation adopted by the peptide was very similar to and could be superimposed onto the corresponding region of the viral protein VP2 of human rhinovirus 1A (HRV1A) whose three-dimensional structure is known.² The structure of the Fab fragment determined in the complex was docked onto the viral capsid using the superimposition transformation found for the peptide. In the resulting model the Fab protrudes almost radially to about 60 Å from the surface of the virion without any major steric problem. The Fab fragment was then placed on each one of the 60 equivalent epitopes using the T = 1 icosahedral symmetry of the virus. The closest pairs of Fab fragments are related by viral 2-fold axes and run almost parallel to each other without clashing. These axes of symmetry from the viral particle could thus be coincident with the dyad axes of the antibodies. Furthermore, comparison of the three-dimensional structure of the Fab/peptide complex with the structure of the Fab fragment alone³ indicates that the flexibility of the antibody's elbow would facilitate bivalent attachment to the same viral particle. In accordance with the docking results, experimental determination of the stoichiometry of binding yielded a ratio of 30 IgG molecules per virion also suggesting bivalent attachment of antibody 8F5 onto the viral particle. The neutralization of viral infectivity, being neither aggregation (this paper) nor inhibition of receptor binding,⁴ might be mainly achieved by reducing viral spread from cell to cell and/or inhibition of uncoating. © 1995 Wiley-Liss, Inc.     

Immunoelectron microscopic localization of idiotypes and allotypes on immunoglobulin molecules

We have developed a novel approach to the analysis of antigenic (allotypic and idiotypic) determinants on intact immunoglobulin molecules. Immune complexes composed of IgG in combination with anti-idiotype or anti-allotype antibody were "visualized" by transmission electron microscopy. Individual Fab fragments of anti-idiotype or anti-allotype antibody, when bound to the IgG, altered the "Y" configuration in a reproducible and interpretable manner. Anti-idiotype antibody (either as Fab or IgG) bound to the terminus of the presumed V region of the IgG molecule, thus extending the apparent length of the Fab arms. Analysis of a rabbit VH framework allotype (a1) revealed that the determinant(s) is (are) located on the lateral portion of the V region of IgG. Binding of the anti-a1 Fab fragments was always at approximately right angles to the axis of the Fab arms of IgG. Fab antibody to the rabbit kappa light chain (b4) allotype bound to the lateral portion of the terminal half of the IgG Fab arms. This technique should be of value in localizing less well defined immunoglobulin determinants.     

Blockade of Fc receptor-mediated binding to U-937 cells by murine monoclonal antibodies directed against a variety of surface antigens

The effect of murine IgG hybridoma antibodies directed against leukocyte antigens on the Fc receptor function of human cells was studied. For this purpose, the specific binding of 125I-labeled monomeric human IgG1 to a macrophage-like cell-line (U-937) was quantitated before and after incubation in the presence of murine monoclonal hybridoma antibodies. Four monoclonal hybridoma antibodies (A1G3, 23D6, 4F2, and 3A 10), each of which binds to different antigens on the surface of U-937 cells, rapidly and potently inhibited the specific binding of labeled IgG1 to these cells. Inasmuch as inhibition was mediated only by IgG antibodies with an intact Fc fragment and antibody activity against surface antigens found on U-937, inhibition appears to have resulted from the formation of a three-component complex composed of antibody bound by its Fab portion to antigen and by its Fc fragment to a Fc receptor. Equilibrium binding studies performed on treated cells confirmed that reduced Fc receptor-mediated binding was due to a reduction in the number of available receptors. Binding studies employing double isotope labeling methods demonstrated that about 0.5 to 1.0 Fc receptor was blocked for each molecule of intact antibody bound to a U-937 cell. Using several techniques, it was shown that most of the monoclonal antibody bound to cells and the Fc receptors blocked by antibody remained on the cell surface despite incubation at 37 degrees C for 3 hr. Thus, the loss of receptor function observed in these experiments was almost exclusively due to reversible receptor blockade rather than receptor internalization or degradation. The antibodies identified in these studies also markedly inhibited Fc receptors on one other human cell line (HL-60) as well as those on normal human peripheral blood monocytes.     

Ligand-loaded but not free complement receptors for C3b/C4b and C3d co-cap with cross-linked B cell surface IgM and IgD

We have performed experiments to investigate possible physical interactions between C receptors (CR) and surface Ig (sIg) on the B cell plasma membrane. These molecules were found to be independent, non-linked, B cell surface structures, because capping CR1, CR2, sIgM, or sIgD with a specific antibody did not affect the distribution of the remainder of these molecules. Both CR1 and CR2, if bound by antibodies that did not independently cap CR, however, became associated with cross-linked sIg because CR that have been bound by intact anti-CR antibodies or their Fab fragments co-capped with sIgM or sIgD that had been bound by divalent anti-IgM or anti-IgD antibody. CR1 that had bound C3b similarly co-capped with sIg when sIg was cross-linked. Ligand-bound or even cross-linked CR did not associate with non-cross-linked sIg because sIgD, bound by a univalent Fab fragment of anti-IgD antibody, did not co-cap with CR that had been cross-linked by a sandwich of mouse anti-CR antibody and goat anti-mouse Ig. Other surface molecules, such as B1 and HLA-DR Ag, when bound by specific antibodies, did not cap with cross-linked sIg, and sIgD, when bound by a univalent Fab fragment of anti-IgD antibody, did not co-cap with cross-linked sIgM. Interactions between CR and sIg were not mediated by an association with IgG FcR because co-capping of CR and sIg was observed when F(ab')2 fragments of both anti-CR and anti-Ig antibodies were used. These results demonstrate that B cell surface CR can become associated with sIg, but only if sIg is cross-linked and CR is bound by anti-CR antibody or has bound its natural ligand.     

Capsid Antibodies to Different Adeno-Associated Virus Serotypes Bind Common Regions

Interactions between viruses and the host antibody immune response are critical in the development and control of disease, and antibodies are also known to interfere with the efficacy of viral vector-based gene delivery. The adeno-associated viruses (AAVs) being developed as vectors for corrective human gene delivery have shown promise in clinical trials, but preexisting antibodies are detrimental to successful outcomes. However, the antigenic epitopes on AAV capsids remain poorly characterized. Cryo-electron microscopy and three-dimensional image reconstruction were used to define the locations of epitopes to which monoclonal fragment antibodies (Fabs) against AAV1, AAV2, AAV5, and AAV6 bind. Pseudoatomic modeling showed that, in each serotype, Fabs bound to a limited number of sites near the protrusions surrounding the 3-fold axes of the T=1 icosahedral capsids. For the closely related AAV1 and AAV6, a common Fab exhibited substoichiometric binding, with one Fab bound, on average, between two of the three protrusions as a consequence of steric crowding. The other AAV Fabs saturated the capsid and bound to the walls of all 60 protrusions, with the footprint for the AAV5 antibody extending toward the 5-fold axis. The angle of incidence for each bound Fab on the AAVs varied and resulted in significant differences in how much of each viral capsid surface was occluded beyond the Fab footprints. The AAV-antibody interactions showed a common set of footprints that overlapped some known receptor-binding sites and transduction determinants, thus suggesting potential mechanisms for virus neutralization by the antibodies.     

Binding of a monoclonal antibody and its Fab fragment to supported phospholipid monolayers measured by total internal reflection fluorescence microscopy.

The association of an anti-dinitrophenyl monoclonal antibody and its Fab fragment with supported phospholipid monolayers composed of a mixture of dipalmitoylphosphatidylcholine and dinitrophenyl-conjugated dipalmitoylphosphatidylethanolamine has been characterized with total internal reflection fluorescence microscopy. The surface densities of bound antibodies were measured as a function of the antibody and Fab solution concentrations, and as a function of the solution concentration of dinitrophenylglycine. The apparent association constant of Fab fragments with surface-associated haptens was approximately 10-fold lower than the association constant for haptens in solution, and the apparent surface association constant for intact antibodies was only approximately 10-fold higher than the constant for Fab fragments. Data analysis with simple theoretical models indicated that, at most antibody surface densities, 50-90% of membrane-associated intact antibodies were attached to the surface by two antigen binding sites.     

Characterization of a human antibody fragment Fab and its calcium phosphate nanoparticles that inhibit rabies virus infection with vaccine

Recombinant antibody phage display technology has been used to mimic many aspects of the processes that govern the generation and selection of high-affinity natural human antibodies in the human immune system, especially for infectious disease prophylaxis. An anti-rabies virus immunized phage-display Fab library was constructed from peripheral blood lymphocytes from vaccinated volunteers. The immunized antibody library, with a diversity of 6.7×10(8), was used to select and produce antibodies that bound to rabies virus glycoprotein. After five rounds of immobilized fixed rabies virion panning, four unique DNA sequences were found in the higher binding clones, and only one, Fab094, showed neutralization activity. Fab094 components were analyzed by ELISA, immunoprecipitation and immunofluorescent staining. ELISA and immunofluorescence showed that Fab094 bound specifically to rabies virions. Immunoprecipitation and mass spectrometry showed that Fab094 reacted with rabies virus glycoprotein. To improve the penetration power of Fab094 antibodies, we developed Fab094 calcium phosphate nanoparticles (Fab094-CPNPs) and tested their efficacy. The rapid fluorescent focus inhibition test indicated that the neutralizing antibody titers of Fab094 and Fab094-CPNPs were reached at 200.17 IU/Kg and 246.12 IU/Kg, respectively. These findings were confirmed in vivo in a Kunming mouse challenge model. Our results demonstrate that human Fab094 and Fab094-CPNPs are efficacious candidate drugs to replace rabies immunoglobulin in post-exposure prophylaxis (PEP).     

Interaction of platelet factor 4 with human platelets

Human washed resting platelets bound 125I-labeled platelet factor 4 in a reaction which was saturable and approached equilibrium within 15-30 min. Scatchard plot analysis of the binding isotherms suggested a single class of specific binding sites. Excess of unlabeled protein and low- and high-affinity heparin competed for platelet factor 4 binding sites on the platelet surface and caused a partial displacement of this molecule. Anti-platelet factor 4 Fab fragments caused inhibition of binding of 125I-platelet factor 4 to platelets. Most of the labeled platelet factor 4 which was bound to intact platelets was recovered in the Triton X-100-insoluble cytoskeletal fraction prepared from the same platelets after their stimulation by thrombin. The association with the cytoskeleton was inhibited by anti-platelet factor 4 Fab fragments and by low-affinity heparin. Anti-platelet factor 4 125I-labeled Fab fragments bound to resting platelets, and this binding was greatly increased following platelet stimulation with thrombin. This suggested that endogenously secreted platelet factor 4 also binds to the platelet surface. No significant binding to platelets of 125I-labeled beta-thromboglobulin and 125I-labeled anti-beta-thromboglobulin Fab fragments was observed. Fab fragments of monospecific anti-human platelet factor 4 antibody raised in rabbits inhibited platelet aggregation and secretion induced by low concentrations of thrombin. Fab fragments of anti-beta-thromboglobulin antibody had no inhibitory effect. We suggest that the binding of alpha-granule-derived platelet factor 4 to the specific sites on the surface of platelets may modulate platelet aggregation and secretion induced by low levels of platelet agonists.     

Conformational changes,plasma membrane penetration,and infection by human rhinovirus type 2: role of receptors and low pH

Human rhinovirus type 2 (HRV2) is internalized by members of the low-density lipoprotein (LDL) receptor (LDLR) family. It then progresses into late endosomes, where it undergoes conversion from D- to C-antigenicity at pH < 5.6. Upon uncoating, the viral RNA is transferred into the cytoplasm across the endsosomal membrane. However, C-antigenic particles fail to attach to LDLR; this raised the question of whether the virus remains attached to the receptors and is carried to late compartments or rather falls off at the higher pH in early endosomes. We therefore determined the pH dependence of virus-receptor dissociation and virus conversion to C-antigen under conditions preventing endocytosis. (35)S-HRV2 was attached to HeLa cells at 4 degrees C and incubated in buffers of pH 7.4 to 5.0; levels of native virus and C-antigenic particles remaining cell associated or having been released into the medium were determined by immunoprecipitation. At pH 6.0, HRV2 was readily released from plasma membrane receptors in its native form, whereas at pH < or = 5.4, it was entirely converted to C-antigen, which, however, only dissociated from the surface upon prolonged incubation. The antigenic conversion occurred at the same pH regardless of whether HRV2 was free in solution or bound to its receptors. These data suggest that, in vivo, the virus is no longer bound to its receptors when the antigenic conversion and uncoating occur in more acidic late endosomes. When virus was bound to HeLa cells at 4 degrees C, converted into C-antigen by exposure to pH 5.3, and subsequently warmed to 34 degrees C in the presence of bafilomycin (to prevent endosomal uncoating), viral de novo synthesis was detected. This study demonstrates for the first time that a nonenveloped virus such as HRV2 can infect from the plasma membrane when artificially exposed to low pH. This implies that the viral RNA can gain access to the cytoplasm from the plasma membrane.     

Structure of a neutralizing antibody bound bivalently to human rhinovirus 2.

The structure of a complex between human rhinovirus serotype 2 (HRV2) and the weakly neutralizing monoclonal antibody 8F5 has been determined to 25 A resolution by cryo-electron microscopy and 3-D reconstruction techniques. THe antibody is seen to be bound bivalently across the icosahedral 2-fold axis, despite the very short distance of 60 A between the symmetry-related epitopes. The canyon around the 5-fold axis is not obstructed. Due to extreme flexibility of the hinge region the Fc domains occupy random orientations and are not visible in the reconstruction. The atomic coordinates of Fab-8F5 complexes with a synthetic peptide derived from the viral protein 2 (VP2) epitope were fitted to the structure obtained by cryo-electron microscope techniques. The X-ray structure of HRV2 is not unknown, so that of the closely related HRV1A was placed in the electron microscopic density map. The footprint of 8F5 on the viral surface is largely on VP2, but also covers the VP3 loop centred on residue 3060. C alpha atoms of VP1 and 8F5 come no closer than 10 A. Based on the fit of the X-ray coordinates to the electron microscope data, the synthetic 15mer peptide starts and ends in close proximity to the corresponding amino acids of VP2 on HRV1A. However, the respective loops diverge considerably in their overall spatial disposition. It appears from this study that bivalent binding of an antibody directed against a picornavirus exists for a smaller spanning distance than was previously thought possible. Also bivalent binding does not ensure strong neutralization.     

Minute virus of mice, a parvovirus, in complex with the Fab fragment of a neutralizing monoclonal antibody

The structure of virus-like particles of the lymphotropic, immunosuppressive strain of minute virus of mice (MVMi) in complex with the neutralizing Fab fragment of the mouse monoclonal antibody (MAb) B7 was determined by cryo-electron microscopy to 7-A resolution. The Fab molecule recognizes a conformational epitope at the vertex of a three-fold protrusion on the viral surface, thereby simultaneously engaging three symmetry-related viral proteins in binding. The location of the epitope close to the three-fold axis is consistent with the previous analysis of MVMi mutants able to escape from the B7 antibody. The binding site close to the symmetry axes sterically forbids the binding of more than one Fab molecule per spike. MAb as well as the Fab molecules inhibits the binding of the minute virus of mice (MVM) to permissive cells but can also neutralize MVM postattachment. This finding suggests that the interaction of B7 with three symmetry-related viral subunits at each spike hinders structural transitions in the viral capsid essential during viral entry.     

A fluorescence study on the mobility of surface antigens of untreated tumor cells and of tumor cells undergoing cell-mediated lysis

Heterologous (rabbit) antibodies were raised against murine P-815 mastocytoma cells of DBA/2 origin. Antisera and IgG preparations were highly cytotoxic, whereas Fab fragments thereof lost all activity. Fab fragments also showed a much lower avidity than IgG, both for tumor and normal DBA/2 and C57 spleen cells as measured by the release of iodinated Fab and IgG. Both preparations bound specifically to P-815 cells since they were capable of inhibiting T cell-mediated target cell lysis. The binding of IgG and monovalent Fab fragments was studied by fluorescence. Rhodamine-coupled IgG bound homogeneously in the cold and quickly formed patches upon warming but did not form caps even after prolonged incubation at 37 degrees C. Rhodamine-coupled Fab fragments also bound homogeneously. Their distribution was unaltered after incubation at 37 degrees C even when tumor cells formed uropod-like tails. Fab fragments, however, could be induced to cap with a second and third antibody layer. P-815 cells labeled with rhodamine-coupled Fab fragments were incubated with cytolytic T cells (CTL). The conjugates formed between CTL and fluorescent target cells were observed. No gross redistribution of surface antigens on target cells was observed even at late stages of the lytic process. CTL, therefore, do not seem to operate via a redistribution of surface antigens.     

Identification and characterization of a new cross-reactive human immunodeficiency virus type 1-neutralizing human monoclonal antibody

The identification and characterization of new human monoclonal antibodies (hMAbs) able to neutralize primary human immunodeficiency virus type 1 (HIV-1) isolates from different subtypes may help in our understanding of the mechanisms of virus entry and neutralization and in the development of entry inhibitors and vaccines. For enhanced selection of broadly cross-reactive antibodies, soluble HIV-1 envelope glycoproteins (Envs proteins) from two isolates complexed with two-domain soluble CD4 (sCD4) were alternated during panning of a phage-displayed human antibody library; these two Env proteins (89.6 and IIIB gp140s), and one additional Env (JR-FL gp120) alone and complexed with sCD4 were used for screening. An antibody with relatively long HCDR3 (17 residues), designated m14, was identified that bound to all antigens and neutralized heterologous HIV-1 isolates in multiple assay formats. Fab m14 potently neutralized selected well-characterized subtype B isolates, including JRCSF, 89.6, IIIB, and Yu2. Immunoglobulin G1 (IgG1) m14 was more potent than Fab m14 and neutralized 7 of 10 other clade B isolates; notably, although the potency was on average significantly lower than that of IgG1 b12, IgG1 m14 neutralized two of the isolates with significantly lower 50% inhibitory concentrations than did IgG1 b12. IgG1 m14 neutralized four of four selected clade C isolates with potency higher than that of IgG1 b12. It also neutralized 7 of 17 clade C isolates from southern Africa that were difficult to neutralize with other hMAbs and sCD4. IgG1 m14 neutralized four of seven primary HIV-1 isolates from other clades (A, D, E, and F) much more efficiently than did IgG1 b12; for the other three isolates, IgG b12 was much more potent. Fab m14 bound with high (nanomolar range) affinity to gp120 and gp140 from various isolates; its binding was reduced by soluble CD4 and antibodies recognizing the CD4 binding site (CD4bs) on gp120, and its footprint as defined by alanine-scanning mutagenesis overlaps that of b12. These results suggest that m14 is a novel CD4bs cross-reactive HIV-1-neutralizing antibody that exhibits a different inhibitory profile compared to the only known potent broadly neutralizing CD4bs human antibody, b12, and may have implications for our understanding of the mechanisms of immune evasion and for the development of inhibitors and vaccines.