The neutralization site on the E2 glycoprotein of Venezuelan equine encephalomyelitis (TC-83) virus is composed of multiple conformationally stable epitopes

The neutralization (N) site on the gp56 (E2) surface glycoprotein of the TC-83 vaccine strain of Venezuelan equine encephalomyelitis (VEE) virus has been characterized using monoclonal antibodies. Five new epitopes (E2d-h) were identified three of which could be mapped into the critical N site by using a competitive binding assay (CBA). Antibodies reactive with these three epitopes had either N or N and hemagglutination-inhibition activity. All epitopes contained within this N site elicited monoclonal antibodies that could protect mice from peripheral virus challenge. Antibodies reactive with the N site on other subtypes of VEE virus (IC and II) bound to, but failed to neutralize, TC-83 virus. Epitopes defined by these antibodies could be located outside of the N site on TC-83 virus by CBA. Antigenic activity of all epitopes except E2d was resistant to treatment with 2% SDS, 3% beta-mercaptoethanol, or cleavage with Staphylococcus aureus V8 protease. Those antibodies which defined epitopes located within the N site of TC-83 with CBA bound the same V8 fragments in immunoblots. Those antibodies which defined epitopes not located within the N site bound a different set of fragments than neutralizing antibodies. These results indicate that there is a specific N site on the E2 of VEE virus which undergoes significant antigenic drift while maintaining structural and functional integrity.     

Detailed immunologic analysis of the structural polypeptides of rubella virus using monoclonal antibodies

A panel of murine monoclonal antibodies prepared against rubella virus is described. Fourteen of these monoclonal antibodies react with the E1 glycoprotein of rubella virus and define a total of six spacially separate epitopes in competitive inhibition assays. Antibodies binding to epitopes E1(a), E1(b), E1(c), or E1(e) inhibit the hemagglutinin function of the virus, while antibodies binding to epitopes E1(d) or E1(f) do not. Monoclonal antibodies binding to epitopes E1(c) or E1(d) prevent virus infectivity and identify antigen in distinct intracytoplasmic vacuoles of rubella virus-infected Vero cells by indirect immunofluorescence. Monoclonal antibody to epitope E1(f) localizes antigen primarily to the plasma membrane of infected cells, while antibodies binding to epitopes E1(a), E1(b), or E1(e) localize antigen throughout the infected cell's cytoplasm. A single monoclonal antibody is described which only reacts with the mature form of the virion E2 glycoprotein after rubella virus is treated with a disulfide-bond reducing agent. This antibody immunoprecipitates a 43,000 MW precursor to the E2 glycoprotein from lysates of infected cells and localizes its antigen throughout the cytoplasm of infected cells. The five remaining monoclonal antibodies react with the rubella virus C polypeptide. They define four topographically separate epitopes on the C polypeptide, C(a), C(b), C(c), and C(d), each of which is diffusely distributed throughout the cytoplasm of rubella virus-infected cells.     

Antigenic structure of the E2 glycoprotein from transmissible gastroenteritis coronavirus

The antigenic structure of transmissible gastroenteritis (TGE) virus E2 glycoprotein has been defined at three levels: antigenic sites, antigenic subsites and epitopes. Four antigenic sites (A, B, C and D) were defined by competitive radioimmunoassay (RIA) using monoclonal antibodies (MAbs) selected from 9 fusions. About 20% (197) of the hybridomas specific for TGE virus produced neutralizing MAbs specific for site A, which was one of the antigenically dominant determinants. Site A was differentiated in three antigenic subsites: a, b and c, by characterization of 11 MAb resistant (mar) mutants, that were defined by 8, 3, and 3 MAbs, respectively. These subsites were further subdivided in epitopes. A total of 11 epitopes were defined in E2 glycoprotein, eight of which were critical for virus neutralization. Neutralizing MAbs were obtained only when native virus was used to immunize mice, although to produce hybridomas mice immunizations were made with antigen in the native, denatured, or mixtures of native and denatured form. All neutralizing MAbs reacted to conformational epitopes. The antigenic structure of the E2-glycoprotein has been defined with murine MAbs, but the antigenic sites were relevant in the swine, the natural host of the virus, because porcine sera reacted against these sites. MAbs specific for TGE virus site C reacted to non-immune porcine sera. This reactivity was not directed against porcine immunoglobulins. These results indicated that TGE virus contains epitope(s) also present in some non-immunoglobulin component of porcine serum.     

Comparison of intertypic antigenicity of Aino virus isolates by dot immunobinding assay using neutralizing monoclonal antibodies

Neutralizing monoclonal antibodies (MAbs) against the Aino virus were prepared, and the neutralizing epitopes of the virus were defined by competitive binding assay. Seven continuous and overlapping neutralizing epitopes existed on the G1 glycoprotein of the Aino virus. Two antigenic domains were identified and were designated I and II, with domain II consisting of six epitopes. Dot immunobinding assays (DIAs) were performed with MAbs that recognized these seven neutralizing epitopes. DIAs were performed with 1 Australian strain and 21 isolates found in Japan between the years 1964 and 1995. The MAb response patterns of all isolates were divided into four groups. The Japanese isolates did not show large differences in antigenicity, but the antigenicity of the Australian strain collected in 1968 was significantly different from that of the Japanese strains; the Australian strain lacked reactivity to three epitopes and showed only low reactivity to one epitope.     

Antigenic mapping of the surface proteins of rhesus rotavirus

Monoclonal antibodies have been produced and used to map the functional topography of the surface proteins of rhesus rotavirus (RRV) that mediate viral neutralization. Ten monoclonal antibodies directed to VP7 were studied in neutralization assays and competitive binding studies. A large neutralization domain with several interrelated epitopes on VP7 was apparent. Twelve monoclonal antibodies directed to VP3 were used in similar studies and delineated at least 2 distinct neutralization domains on that protein. Neutralizing monoclonal antibodies directed at both VP3 and VP7 were used to isolate viral antigenic variants, which were than studied in neutralization and hemagglutination inhibition assays. The viral variant studies, while confirming the general conclusions obtained from the competitive binding studies, allowed the apparent distinction of two separate neutralization domains on VP7 and three on VP3. All VP7-specific monoclonal antibodies (mAb) mediated serotype-specific neutralization, but a VP3-specific mAb was identified that neutralized rotaviruses of three distinct serotypes. No alteration of viral virulence was apparent in studies of suckling mice orally inoculated with antigenic variant viruses selected with our panel of neutralizing VP3 or VP7-specific mAbs.     

Antigenic mapping of the envelope proteins of equine infectious anemia virus: identification of a neutralization domain and a conserved region on glycoprotein 90

Summary Monoclonal antibodies (MCAbs) were used to dissect the antigenic sites of the surface glycoproteins of the prototype cell-adapted Wyoming strain of equine infectious anemia virus (EIAV) Serologic reactivities of these MCAbs were determined by ELISA, additive ELISA, competitive ELISA, and Western blot assays. The results indicated that antigenic reactivity of gp90 was localized on at least four distinct epitopes, two of which were important in neutralization. Our studies also revealed that these epitopes were localized on overlapping antigenic sites on gp90. On the other hand, only two distinct non-overlapping epitopes were identified on gp45. Competitive binding studies of neutralizing MCAbs and reference EIA-positive horse serum delineated the presence of a neutralization domain on gp90 that appears to be immunodominant both in naturally infected horses and in mice immunized with EIAV. Limited proteolytic fragmentation of the gp90 component of several serologically distinct EIAV isolates produced common 12K immunoreactive fragments that contained a conserved epitope. These results indicate the occurrence of conserved antigenic regions on EIAV glycoproteins as well as a neutralization domain on gp90, which can be used as potential targets for vaccine development.     

Functional and topographical analyses of epitopes on bovine herpesvirus type 1 glycoprotein IV

Summary Bovine herpesvirus type 1 (BHV-1) glycoprotein gIV was purified by affinity chromatography. Purified preparations showed two distinct components of 71 K and 140 K following electrophoresis in sodium dodecyl sulphate polyacrylamide gels. The polypeptides were separated, excised from the gel and used to immunize rabbits; the resulting antisera showed a high degree of cross reactivity indicating that these polypeptides represent monomeric and dimeric forms of the same glycoprotein. Purified gIV was also used to develop a gIV-specific panel of monoclonal antibodies. Neutralizing monoclonal antibodies directed against gIV were conjugated to horseradish peroxidase and subjected to competition binding assays by ELISA. Three distinct neutralizing antigenic domains on gIV were identified. Domain 1 comprised two overlapping epitopes, whereas domain 2 was represented by a single monoclonal antibody. The third antigenic domain was made up of a complex of four identical or overlapping epitopes designated 3a, b, c, and d. Evidence is presented suggesting that domain 1 of gIV may be involved in penetration of the virus into the cell.Published with the permission of the Director as Journal Series No. 67     

Biochemical and biological characteristics of epitopes on the E1 glycoprotein of western equine encephalitis virus

Antigenic determinants identified by monoclonal antibodies (Mabs) on the E1 glycoprotein of western equine encephalitis (WEE) virus have been characterized by their serological activity, requirements for secondary structure, expression on the mature virion, and their role in protecting animals from WEE virus challenge. On the basis of a cross-reactivity enzyme-linked immunosorbent assay (ELISA) and hemagglutination inhibition assay, eight antigenic determinants (epitopes) on the E1 glycoprotein have been identified, ranging in reactivity from WEE-specific to alphavirus group reactive. No neutralization of virus infectivity was demonstrable with any of the Mabs. An alphavirus group-reactive hemagglutination (HA) site, a WEE complex-reactive HA site, and a WEE virus-specific HA site were identified. Spatial arrangement of these epitopes was determined by a competitive binding ELISA. Four competition groups defining three distinct antigenic domains were identified. Antibodies directed against four E1 epitopes were capable of precipitating the E1/E2 heterodimer from infected cells or purified virus disrupted with nonionic detergents. These same antibodies precipitated only E1 in the presence of 0.1% SDS. That E1 conformation was important was shown by the inability of antibodies specific for seven of the epitopes to bind to virus denatured in 0.5% SDS. As determined by equilibrium gradient analysis of virus-antibody mixtures, four epitopes were found to be fully accessible on the mature virion, three epitopes were inaccessible, and one epitope was partially accessible to antibody binding. Antibodies specific for three epitopes were able to passively protect mice from WEE virus challenge.     

Topological mapping of murine leukemia virus proteins by competition-binding assays with monoclonal antibodies

Monoclonal antibodies produced by hybrid cells in culture are chemically homogeneous reagents that react with constant avidity to single antigenic determinants (epitopes). As such, these antibodies are remarkably specific probes for small regions of complex antigenic proteins. We have used a panel of monoclonal antibodies in competition binding assays to investigate the arrangement of six epitopes on the envelope proteins of AKR leukemia virus. It was reasoned that if two epitopes were adjacent to each other on a single protein, the binding of antibody to one epitope would sterically hinder the binding of antibody to the other epitope. On the other hand, if the two epitopes were at distant sites on the protein, the binding of antibody to one epitope would not influence the binding of antibody to the other epitope. The results of these competition binding assays demonstrated the presence of two distinct antigen sites on both the gp70 and p15(E) envelope proteins. With the gp70 protein, one antigen site contained the gp70^b and gp70^c epitopes; the other antigen site on this protein contained the gp70^a epitope. With p15(E), one of the antigen sites contained the p15(E)^b and p15(E)^c epitopes, while the other site contained the p15(E)^a epitope. These findings demonstrate the utility of this type of serological analysis for the study of the tertiary structure of individual viral proteins.     

Monoclonal antibodies directed to E1 glycoprotein of rubella virus

Summary We have prepared four monoclonal antibodies to rubella virus E1 glycoprotein. Three nonoverlapping antigenic sites were delineated on E1 protein by competitive binding assays. Antibodies binding to one site were characterized by high hemagglutination inhibition (HI) titer but poor neutralizing activity. The addition of antiglobulin conferred neutralizing activity. Antibodies directed to two other antigenic sites had modest hemolysis inhibition but little or no HI and neutralizing activities. The addition of antiglobulin markedly augmented HI activity but had little effect on neutralizing activity. Epitopes defined by three antibodies were conserved among four rubella virus strains examined.With 4 Figures     

Topographical analysis of viral epitopes using monoclonal antibodies: Mechanism of virus neutralization

The mouse mammary tumor virus (MMTV) was used in neutralization studies with monoclonal antibodies (monoclones) to the major external glycoprotein gp52. Monoclones to MMTV gp52 showed that epitopes with different antigenic specificities were targets for virus neutralization. These epitopes were group specific (common to C3H, GR, RIII, and C3Hf MMTVs), class specific (common to C3H and GR MMTVs), and type specific (unique to C3H MMTV). Competition antibody binding assays using a radioiodinated C3H MMTV type-specific neutralizing monoclone revealed that all the monoclones that neutralized virus infectivity also blocked the binding of the type-specific monoclone to C3H MMTV. A topographically distinct site from this determinant was found using other monoclones which did not compete for the binding of the type-specific monoclone and their epitopes did not function as targets for neutralizing antibodies. However, these nonneutralizing monoclones could neutralize virus infectivity in the presence of antimouse IgG sera. Therefore, two topographically distinct sites could be identified on a single protein of the virus. One site functioned as a target for neutralization and the second site bound antibody but did not affect neutralization. The observation that virus bound to cells was no longer susceptible to neutralization by monoclones showed that neutralization affected virus prior to its binding to cell surface receptors. This result further indicated that antibody prevented virus adsorption to cells and that neutralization was mediated by steric hindrance from antibodies binding to epitopes adjacent to those determinants which functioned in virus binding to cell surface receptors.     

The antigenic structure of glycoprotein E2 in the Venezuelan equine encephalomyelitis virus studied using rat monoclonal antibodies]

A collection of 21 rat hybridomas secreting high-affinity monoclonal antibodies to Venezuelan equine encephalomyelitis (VEE) virus was generated. Using a panel of 15 monoclonal antibodies to glycoprotein E2, the antigenic structure of this protein of VEE strains TC-83 and 230 was studied. A competitive radioimmunoassay suggested a new map of the antigenic structure of glycoprotein E2 in which 5 sites including 11 epitopes of monoclonal antibody binding were distinguished. Antibody to E2-2 site neutralized virus infectivity and blocked hemagglutination test and antibody to E2-3 site could only block hemagglutination. Antibodies to other E2 protein sites lacked any biological activity.     

Characterization of monoclonal antibodies to bovine enteric coronavirus and antigenic variability among Quebec isolates

Summary Twenty monoclonal antibodies (MAbs) were prepared against the Mebus strain of bovine enteric coronavirus, 14 of them reacting with the peplomeric S (gp 100) glycoprotein. Competition binding assays allowed the definition of at least 4 distinct antigenic domains for the S glycoprotein, designated as A, B, C, and D; epitopes associated to neutralizing activity being located in sites A, B, and C. One MAb directed to the hemagglutinin HE (gp 140/gp 65) glycoprotein inhibited the hemagglutinating activity of the virus, but had no neutralizing activity. Comparison of Quebec enteropathogenic BCV isolates using polyclonal antiserum and MAbs directed to the S glycoprotein confirmed their close antigenic relationship, but also revealed the occurrence of at least three distinct antigenic subgroups. Antigenic domain D was highly conserved among BCV isolates, as well as non-neutralizing epitopes assigned to antigenic domains A and C. The Minnesota strain of turkey enteric coronavirus could be distinguished from BCV isolates by MAbs directed to epitopes of antigenic domain C, whereas human coronavirus HCV-OC 43 could be distinguished by MAbs directed to epitopes of antigenic domain A. The porcine hemagglutinating encephalomyelitis virus could be distinguished from the other hemagglutinating coronaviruses by neutralizing epitopes located on antigenic domains A, B, and C.     

Classical swine fever virus: Antigenic architecture of the E2 glycoprotein elucidated by epitope mapping using synthetic peptides

Detailed epitope characterization of the major envelope glycoprotein E2 of the classical swine fever virus (CSFV) is important for our understanding of interactions between the virus and the host immune system, as well as for the development of CSFV-specific diagnostic assays and epitope- or peptide-based marker vaccines. As was shown previously by competitive binding assay, monoclonal antibodies obtained by our group recognize eight epitopes on the E2 protein. Here, we report mapping of five linear, nonoverlapping B-cell epitopes that use a set of synthetic peptides, which encompass the full sequence of the CSFV E2 protein (Shimen strain). Two of the epitopes are located in the antigenic domain A of the E2, while another three belong to a highly structured region of this glycoprotein. The alignment of the identified gene sequences was performed for 12 CSFV strains, three strains of bovine viral diarrhea virus (BVDV), and two strains of the border disease virus (BDV). The data obtained could be used to improve CSFV diagnostic assays, as well as to investigate the effects of aminoacid substitutions in E2 on its antigenic properties.     

Epitope mapping of the gp53 envelope protein of bovine viral diarrhea virus

Epitopes recognized by nine monoclonal antibodies (mAbs) on the envelope protein, gp53, of two strains of bovine viral diarrhoea virus (NADL and Oregon C24V) were mapped by competitive binding assays and by the characterization and sequence analyses of mAb neutralization escape mutants. This defined an antigenic domain on gp53 that was shared by many BVDV strains, while other less conserved epitopes were possibly distinct. Sequencing of escape mutant viruses revealed that a cluster of three amino acids in the N-terminal half of gp53 were involved in the main antigenic domain shared by both NADL and Oregon C24V viruses, while an amino acid 31 residues further toward the N-terminus was involved in a second site present only on the NADL strain. Since other amino acids defining these epitopes were located at distant positions within the gp53 protein, it is likely that a major domain [corrected] on gp53 consist of composite, conformation-dependent epitopes.     

Monoclonal antibodies to gp110 and gp41 of human immunodeficiency virus.

Six mouse hybridomas secreting monoclonal antibodies specific for the glycoproteins of human immunodeficiency virus were developed. All six antibodies reacted by radioimmunoprecipitation with the glycoprotein precursor of 150,000 daltons as well as one of the proteolytic processing products of 110,000 daltons (gp110) or 41,000 daltons (gp41). Recombinant polypeptides spanning the env coding region were used to locate epitopes on the glycoprotein molecule. The panel of antibodies detected two distinct epitopes of gp41 and one epitope of gp110. We used the antibodies in indirect immunofluorescence assays to evaluate 13 clinical isolates of human immunodeficiency virus from diverse geographic regions, and we found that the gp110 epitope was recognized on all tested isolates, whereas the two gp41 epitopes were detected on 10 of 13 and 4 of 13 isolates.     

Antigenic relationships of murine coronaviruses: Analysis using monoclonal antibodies to JHM (MHV-4) virus

Monoclonal antibodies were produced to JHMV-DL, a neurotropic member of the mouse hepatitis virus (MHV) or murine coronavirus group. Of 23 antibodies isolated, 10 were specific for the major envelope glycoprotein, gp180/90, 10 for the nucleocapsid protein, pp60, and 3 for the minor envelope glycoprotein, gp25. Eleven different MHV isolates were used in antibody binding assays to study antigenic relationships among the viruses. Each MHV isolate tested had a unique pattern of antibody binding, indicating that each is a distinct strain. Conservation of JHMV-DL antigenic determinants varied among the three proteins, with pp60 showing intermediate conservation, gp180/90 little conservation, and gp25 marked conservation in the different MHV strains. Monoclonal antibodies to pp60 proved most useful in delineating antigenic relationships among MHV strains. These antigenic groups correlated with pathogenic types, indicating that pp60 may be one of the gene products which mediates the distinct disease patterns manifested by different murine coronaviruses.     

Use of synthetic peptides to map sequential epitopes recognized by monoclonal antibodies on the bovine leukemia virus external glycoprotein.

Six sequential epitopes (A, B, B', D, D', E) were previously defined on the bovine leukemia virus (BLV) envelope glycoprotein gp51 by their reactivity with monoclonal antibodies. A panel of synthetic peptides covering almost the entire sequence of gp51 was tested in enzyme-linked immunosorbent assays in order to localize these epitopes. E was shown to be included in peptide 142-161 (MCF4), B and B' in peptide 195-205, D and D' in peptide 218-237 (MCF6), and A in peptide 249-268 (MCF7). These results extend and confirm previous observations suggesting that the sequential epitopes recognized by our battery of monoclonal antibodies are located in the carboxylic half of BLV gp51.     

Location of a major antigenic site involved in Ross River virus neutralization

The location of a major antigenic domain involved in the neutralization of an alphavirus, Ross River virus, has been defined in terms of its position in the amino acid sequence of the E2 glycoprotein. The domain encompasses three topographically close epitopes which were identified using three E2-specific neutralizing monoclonal antibodies in competitive binding assays. Nucleotide sequencing of the structural protein genes of monoclonal antibody-selected antigenic variants showed that for each variant there was a single nucleotide change in the E2 gene leading to a nonconservative amino acid substitution in E2. Changes were at positions 216, 234, and 246-251 in the amino acid sequence. The epitopes are in a region of E2 which, though not strongly conserved as to sequence among Ross River virus, Semliki Forest virus, and Sindbis virus, is conserved in its hydropathy profile among the three alphaviruses. The epitopes lie between two asparagine-linked glycosylation sites (residues 200 and 262) in E2. They are conserved as to position between the mouse virulent T48 strain and the mouse avirulent NB5092 strain.