Antigenic and immunogenic investigation of B-cell epitopes in the nucleocapsid protein of peste des petits ruminants virus

Attempts were made to identify and map epitopes on the nucleocapsid (N) protein of peste des petits ruminants virus (PPRV) (Nigeria75/1 strain) using seven monoclonal antibodies (MAbs) and deletion mutants. At least four antigenic domains (A-I, A-II, C-I, and C-II) were identified using the MAbs. Domains A-I (MAb 33-4) and A-II (MAbs 38-4, P-3H12, and P-13A9) were determined to be located on the amino-terminal half (amino acids [aa] 1 to 262), and domains C-I (P-14C6) and C-II (P-9H10 and P-11A6) were within the carboxy-terminal region (aa 448 to 521). Nonreciprocal competition between A-II MAbs and MAbs to C-I and C-II domains was observed, indicating that they may be exposed on the surface of the N protein and spatially overlap each other. Blocking or competitive enzyme-linked immunosorbent assay studies using PPRV serum antibodies revealed that epitopes on the domains A-II and C-II were immunodominant, whereas those on the domains A-I and C-I were not. The competition between MAb and rinderpest virus (RPV) serum antibodies raised against RPV strain LATC was found in two epitopes (P-3H12 and P-13A9) on the domain A-II, indicating that these epitopes may cause cross-reactivity between PPRV and RPV. Identification of immunodominant but PPRV-specific epitopes and domains will provide the foundation in designing an N-protein-based diagnostic immunoassay for PPRV.     

Characterization of monoclonal antibodies against apolipoproteins A-I and A-II. Epitope expression in LpA-I and LpA-I:A-II particles

Two monoclonal antibodies (MAbs) against apolipoprotein A-I (apo A-I), 6B9 and FF9B10, and one MAb against apolipoprotein A-II (apo A-II), 3F5, were characterized. To establish the epitope of apo A-I recognized by these antibodies, different experimental approaches were performed. First, competition between MAbs and the related epitopes on the same antigen was performed using double-determinant tests with previously characterized MAbs. Second, competition of different synthetic peptides of apo A-I in solution with apo A-I immobilized to solid phase was carried out. The MAbs against apo A-I (6B9 and FF9B10) appear to recognize discontinuous epitopes located in the amino-terminal region of the apo A-I. In competition experiments MAb 3F5 did not recognize central- or carboxy-terminal peptides of apo A-II. Furthermore, apo A-II was stronger recognized when it was included in HDL or LpA-I:A-II than in its purified form. So the epitope for 3F5 is better expressed in the lipoprotein structure. Finally, to establish the epitopes expression in different antigens in solution, competition of purified apo A-I, apo A-II, LpA-I, and LpA-I:A-II particles or HDL3, with apo A-I or HDL immobilized to solid phase, was carried out. The results showed that both MAbs against apo A-I reacted with poor affinity against free apo A-I, with high and similar affinities against Lp A-I and Lp A-I:A-II lipoparticles and with the highest affinity against HDL3. The MAb 3F5 against apo A-II recognized only LpA-I:A-II and not LpA-I lipoparticles.     

Epitope Detection in the Envelope of Intracellular Naked Orthopox Viruses and Identification of Encoding Genes

Monoclonal antibodies (MAbs) were generated against vaccinia virus, cowpox virus KR2 Brighton, monkeypox virus Copenhagen, or ectromelia virus. Pairwise epitope specificity studies by competition ELISAs identified 23 distinct antigenic sites in 19 different orthopox virus strains. Six epitopes were completely independent of each other, and 17 closely related antigenic sites formed three separate epitope complexes. As shown by immunogold electron microscopy (ELMI), all MAbs reacted with epitopes in the envelope of intracellular naked virus, 16 MAbs recognized proteins of 32, 30, 16 or 14 kDa in Western blotting (WB), and 9 MAbs neutralized virus infectivity. In rabbitpox virus (RPV) 18 epitopes were detected. A λgt11 expression library of RPV DNA was screened with the corresponding 18 MAbs. Fourteen recombinant bacteriophage clones (ph) were isolated. Cross-hybridizations of phage and RPV DNA demonstrated a reaction with the HindIII A, HindIII D, or HindIII H fragments, respectively. DNA of ph3D was related to the A25L gene, which corresponds to the A-type inclusion body gene of cowpox virus. Two phage clones contained sequences of the 14-kDa fusion protein gene (A27L gene). Ph1A contained nearly the entire 14-kDa gene encoding 4 neutralizing (neutr) and 2 nonneutr epitopes. Ph5, expressing only half of this gene product, encoded 1 nonneutr epitope. The fusion protein of vaccinia virus MVA was isolated by immune-affinity chromatography with a neutr. catching MAb. The protein formed hollow rods (ELMI) and the 6 antigenic sites that were present were identical to those expressed by Escherichia coli infected with ph1A. WB detection with a polyclonal hyperimmune serum detected protein bands of 54, 32, 30, 16, and 14 kDa. The catching MAb bound only to a 16-kDa band. The purified fusion protein induced neutralizing antibodies in mice and rabbits.     

Mapping of B-cell epitopes of hemagglutinin protein of rinderpest virus

Monoclonal antibodies (mAbs) against secreted hemagglutinin (H) protein of rinderpest virus (RPV) expressed by a recombinant baculovirus were generated to characterize the antigenic sites on H protein and regions of functional significance. Three of the mAbs displayed hemagglutination inhibition activity and these mAbs were unable to neutralize virus infectivity. Western immunoblot analysis of overlapping deletion mutants indicated that three mAbs recognize antigenic regions at the extreme carboxy terminus (between amino acids 569 and 609) and the fourth mAb between amino acids 512 and 568. Using synthetic peptides, aa 569-577 and 575-583 were identified as the epitopes for E2G4 and D2F4, respectively. The epitopic domains of A12A9 and E2B6 mAbs were mapped to regions encompassing aa 527-554 and 588-609. Two epitopes spanning the extreme carboxy terminal region of aa 573 to 587 and 588 to 609 were shown to be immunodominant employing a competitive ELISA with polyclonal sera form vaccinated cattle. The D2F4 mAb which recognizes a unique epitope on RPV-H is not present on the closely related peste des petits ruminant virus HN protein and this mAb could serve as a tool in the seromonitoring program after rinderpest vaccination.     

Baculovirus display of fusion protein of Peste des petits ruminants virus and hemagglutination protein of Rinderpest virus and immunogenicity of the displayed proteins in mouse model

Recombinant Bombyx mori nucleopolyhedroviruses (BmNPV) displaying the immunodominant ectodomains of fusion glycoprotein (F) of Peste des petitis ruminants virus (PPRV) and the hemagglutinin protein (H) of Rinderpest virus (RPV), on the budded virions as well as the surface of the infected host cells have been constructed. The F and H protein sequences were inserted in-frame within the amino-terminal region of BmNPV envelope glycoprotein GP64 expressing under the strong viral polyhedrin (polh) promoter. We improved the recombinant virus selection in BmNPV by incorporating the green fluorescent protein gene (gfp) as selection marker under a separate promoter within the transfer cassette harboring the desired genes. Following infection of the insect larvae or the host-derived BmN cells with these recombinant BmNPVs, the expressed GP64 fusion proteins were displayed on the host cell surface and the budded virions. The antigenic epitopes of the recombinant proteins were properly displayed and the recombinant virus particles induced immune response in mice against PPRV or RPV.     

Analysis of epitopes in the capsid protein of avian hepatitis E virus by using monoclonal antibodies

Avian hepatitis E virus (HEV) is related genetically and antigenically to human and swine HEVs and capsid protein of avian HEV shares approximately 48-49% amino acid sequence identities with those of human and swine HEVs. Six monoclonal antibodies (MAbs) were produced and used to locate different epitopes in the ORF2 region of aa 339-570 of avian HEV Chinese isolate. The results showed that five epitopes were located in the aa 339-414 region and one in the aa 510-515 region. Two epitopes located in aa 339-355 and aa 384-414 regions are the immunodominant epitopes on the surface of the avian HEV particles as demonstrated by immune capture of viral particles and immunohistochemical detection of the ORF2 antigens with two MAbs.     

Further investigation on the mode of entry of human rotavirus into cells

Summary Monoclonal antibodies (MAbs) to 2 epitopes on the haemagglutininneuraminidase (HN) protein of the Ulster strain of Newcastle disease virus neutralized synergistically: MAbs to HN-1 and HN-2 neutralized 1.2 and 1.7 log₁₀ infectious units (i. u.) of virus when single as compared to 4.1 when combined. Although MAb to HN-1 but not to HN-2 inhibited haemagglutination they both neutralized more virus on desialized cells compared to normal cells and were considered to have interfered with viral attachments in a cooperative manner when combined. A third MAb to fusion (F) protein reduced infectivity by five log₁₀ i. u. HN-1, HN-2 and F were not the only immunodominant epitopes because mutants, which simultaneously lacked all 3 epitopes, were indistinguishable from wild type when neutralized by polyclonal mouse, rabbit or chicken antiserum to whole virus.With 2 Figures     

Monoclonal antibodies to an Indian strain of type A foot-and-mouth disease virus

A set of five neutralizing monoclonal antibodies (MAbs) to an Indian strain (IND17/77) of type A (subtype A22) foot-and-mouth disease (FMD) virus (FMDV) was used in the study. Four of the MAbs (27S, 37S, 85S, and 143S) identified a trypsin-sensitive (TS) epitope(s) and were specific for VP1, while the remaining MAb (145S) reacted with a trypsin-resistant (TR) epitope and was specific for VP3 in Western blot analysis. Both the epitopes (TS and TR) were conformation-independent in nature. Results obtained in MAb-competition enzyme-linked immunosorbent assay (ELISA), and profiling of the (MAb) neutralization-escape mutants in ELISA and cross-neutralization test revealed two overlapping TS epitopes (27S/37S and 85S/143S) on the virus. Variation at both these epitopes was observed in some field isolates of serotype A. Comparison of deduced amino acid sequence in the VP1 region (aa 140-213) between the parent virus and the mutants identified Gly148 and Arg153 as critical for the formation of both the TS epitopes. Substitution of R153 by Gly or Ser was observed in mutants with no reactivity for the MAbs 85S/143S. However, these mutants maintained partial reactivity with MAbs 27S/37S, and substitution of Gly148 by Glu eliminated both the epitopes. No amino acid substitution was observed in the VP1 region of aa 200-213. Efficient neutralization of the MAb neutralization escape mutants (MAb-resistant (MAR) mutants) by bovine vaccinate serum (BVS) indicated involvement of other epitopes on the virion surface in eliciting neutralizing antibodies following vaccination.     

Novel monoclonal antibodies against Menangle virus nucleocapsid protein

Menangle virus (MenV) is a member of the family Paramyxoviridae isolated in Australia that causes a reproductive disease of pigs. There is a need for specific immunoassays for virus detection to facilitate the diagnosis of MenV infection. Three novel monoclonal antibodies (MAbs) of the IgG1 subtype were generated by immunizing mice with recombinant yeast-expressed MenV nucleocapsid (N) protein self-assembled to nucleocapsid-like structures. One MAb was cross-reactive with recombinant N protein of Tioman virus. The epitopes of MAbs were mapped using a series of truncated MenV N proteins lacking the 29–119 carboxy-terminal amino acid (aa) residues. The epitopes of two MAbs were mapped to aa 430–460 of the MenV N protein, whilst the epitope of one MAb was mapped to residues 460–490. All three MAbs specifically recognized MenV, as indicated by immunohistochemical staining of brain tissue isolated from a field case (a stillborn piglet) of MenV infection. The MAbs against MenV N protein may be a useful tool for immunohistological diagnosis of MenV infection.     

Detection of antiviral activity of monoclonal antibodies, specific to Marburg virus proteins

Monoclonal antibodies (MAbs) specific to Marburg virus (MBG), Popp strain, have been previously produced and characterized by indirect ELISA. Protein specificity of MAbs was determined by immunoblotting with SDS-PAGE proteins of MBG: one to NP, four to VP40, and protein specificity of one antibody was not detected. The effect of MAb binding to protein epitopes on viral functions was investigated in vitro and in vivo. None of antibodies neutralized the virus in the neutralization test in vitro, but MAb 5G9.G11 and 5G8.H5 specific to MBG VP40 protein were active in antibody-dependent complement mediated lysis of virus-infected cells. In vivo these antibodies (5G9.G11 and 5G8.H5) protected guinea pigs from lethal MBG infection after passive inoculation. Studies of biological activity and analysis of epitope specificity of MAb-antiVP40 by competitive ELISA showed that 2 of 7 epitopes of VP40 protein of MBG induce the production of protective antibodies. Hence, MAbs 5G9.G11 and 5G8.H5 reacting with MBG VP40 protein caused lysis of virus infected cells in the presence of the complement in vitro and protected guinea pigs from MBG infection by passive inoculation.     

Analysis of Linear B-Cell Epitopes of the Nucleoprotein of Ebola Virus That Distinguish Ebola Virus Subtypes

Ebola virus consists of four genetically distinguishable subtypes. We developed monoclonal antibodies (MAbs) to the nucleoprotein (NP) of Ebola virus Zaire subtype and analyzed their cross-reactivities to the Reston and Sudan subtypes. We further determined the epitopes recognized by these MAbs. Three MAbs reacted with the three major subtypes and recognized a fragment containing 110 amino acids (aa) at the C-terminal extremity. They did not show specific reactivities to any 10-aa short peptides in Pepscan analyses, suggesting that these MAbs recognize conformational epitope(s) located within this region. Six MAbs recognized a fragment corresponding to aa 361 to 461 of the NP. Five of these six MAbs showed specific reactivities in Pepscan analyses, and the epitopes were identified in two regions, aa 424 to 430 and aa 451 to 455. Three MAbs that recognized the former epitope region cross-reacted with all three subtypes, and one that recognized the same epitope region was Zaire specific. One MAb, which recognized the latter epitope region, was reactive with Zaire and Sudan subtypes but not with the Reston subtype. These results suggest that Ebola virus NP has at least two linear epitope regions and that the recognition of the epitope by MAbs can vary even within the same epitope region. These MAbs showing different subtype specificities might be useful reagents for developing an immunological system to identify Ebola virus subtypes.     

Analysis of linear B-cell epitopes of the nucleoprotein of ebola virus that distinguish ebola virus subtypes

Ebola virus consists of four genetically distinguishable subtypes. We developed monoclonal antibodies (MAbs) to the nucleoprotein (NP) of Ebola virus Zaire subtype and analyzed their cross-reactivities to the Reston and Sudan subtypes. We further determined the epitopes recognized by these MAbs. Three MAbs reacted with the three major subtypes and recognized a fragment containing 110 amino acids (aa) at the C-terminal extremity. They did not show specific reactivities to any 10-aa short peptides in Pepscan analyses, suggesting that these MAbs recognize conformational epitope(s) located within this region. Six MAbs recognized a fragment corresponding to aa 361 to 461 of the NP. Five of these six MAbs showed specific reactivities in Pepscan analyses, and the epitopes were identified in two regions, aa 424 to 430 and aa 451 to 455. Three MAbs that recognized the former epitope region cross-reacted with all three subtypes, and one that recognized the same epitope region was Zaire specific. One MAb, which recognized the latter epitope region, was reactive with Zaire and Sudan subtypes but not with the Reston subtype. These results suggest that Ebola virus NP has at least two linear epitope regions and that the recognition of the epitope by MAbs can vary even within the same epitope region. These MAbs showing different subtype specificities might be useful reagents for developing an immunological system to identify Ebola virus subtypes.     

Immunological characteristics of Aujeszky's disease virus glycoprotein

A panel of monoclonal antibodies (MAbs) specific to glycoprotein D (gD) of Aujeszky's disease virus (ADV, Suid herpesvirus 1) was produced and characterized. MAbs were used to identify 9 topologically different epitopes and epitopic groups on gD. The majority of the identified epitopes were conformational. Most gD-specific MAbs possessed virus-neutralizing activity in the presence and absence of the complement. MAbs neutralized the virus at the stage of its penetration into the cell and inhibited the cell-to-cell spread of viruses. Two immunodominant epitopes and one immunodominant domain that induce the most prominent humoral immune response were identified when the animals were infected and immunized. A method was developed for affinity purification of ADV glycoprotein D. Immunization of mice with affinity-purified gD induced a strong humoral immune response and protected mice against lethal ADV challenge. In passive immunization, the majority of gD-specific MAbs protected mice against infection. The findings confirm the important role of ADV glycoprotein D in inducing protective anti-ADV immunity.     

Production and characterization of monoclonal antibodies directed to the kringle V and protease domains of human apolipoprotein(a)

Production and use of anti-apolipoprotein(a) monoclonal antibodies (MAbs) specific to single copy regions in the polymorphic lipoprotein(a) (Lp(a)) has been emphasized to be important for the standardization of measurements of the coronary heart disease risk factor, Lp(a). Here, mouse MAbs were prepared against the kringle V (V) and protease (P) domains of human apolipoprotein(a) (apo(a)), which domains are present in single copy in the apo(a) molecule. The cDNA for apo(a)VP was cloned from human liver cDNA library, and the V-P recombinant protein overexpressed in Escherichia coli was used as an antigen for the antibody production. Two antibodies named as MAb(a)20 and MAb(a)23 were finally produced, and they were characterized for their binding specificity and epitopes. The specificity of the antibodies was confirmed by an immunoblotting procedure and an enzyme-linked immunoassay (ELISA). It was shown that the antibodies had little, if any, cross-reactivity with human plasminogen, which is relatively abundant in human serum and is highly homologous (85%) with apo(a) in amino acid (aa) sequence. For epitope analysis, 3'-deletional series of apo(a)VP cDNA were constructed, and expression products of them were analyzed for the binding MAb(a)20 and MAb(a)23 do. It has been revealed that distinct epitopes were recognized by the two MAbs: MAb(a)23 (gamma2b, kappa) bound to the V region about 60 aa downstream from the N-terminal, and MAb(a)20 (gamma1, kappa) bound to the P region close to the C-terminal. A one step-sandwich ELISA system for Lp(a) was developed using MAb(a)20 as a capturing antibody and horseradish peroxidase (HRP)-coupled MAb(a)23 as a detecting antibody. The assay was found to be sensitive and useful for detecting Lp(a) in the range of 4-150 microg/dL (80 pM-3 nM).     

Neutralizing human monoclonal antibodies to hepatitis A virus recovered by phage display

Four human monoclonal antibodies (MAbs) to hepatitis A virus (HAV) were isolated from a phage-displayed antibody library constructed from the peripheral blood lymphocytes (PBLs) of HAV-immune donors. The four MAbs showed differences in their affinity: two (HA6, HA9) of them were dominant after four rounds of panning, and showed higher affinity than the other two (HA1, HA12). All four MAbs showed HAV-neutralizing activity in radioimmunofocus inhibition assay and their neutralizing activity was positively correlated with their affinities. Analysis of their epitope specificity by cross-competition binding assays suggested that HA6 and HA9 recognize extensively overlapping epitopes, which overlap with those of HA1 and HA12, although HA1 and HA12 recognize distinct epitopes. In addition, competition assays with known neutralizing murine MAbs suggested that the epitopes of four human MAbs extensively overlap with those of B5B3 and K34C8 which are distinct but reside within the single, immunodominant neutralization site on the HAV capsid. The human MAbs (HA6 and HA9) with highest affinity may be useful in the immunoprophylaxis of HAV infection.     

Comparisons of rotavirus VP7-typing monoclonal antibodies by competition binding assay.

Three sets of neutralizing monoclonal antibodies (MAbs) used to type the outer capsid protein VP7 of four group A rotavirus serotypes (1 through 4) were compared in competition immunoassays. Reciprocal competition was observed for each of the VP7 type 2-, 3-, and 4-specific MAbs. The VP7 type 1 MAbs exhibited variable competition patterns with other VP7 type 1 MAbs. MAb RV4:3, which has been used to recognize antigenic variants within VP7 type 1 strains, showed reciprocal competition with the four VP7 type 3 MAbs (RV3:1, YO-1E2, 4F8, and 159) using a VP7 type 3 virus (SA11) as antigen. MAb 2C9, also prepared against VP7 type 1, reacted with VP7 type 3 strains and competed with a VP7 type 3 MAb, 159, using RRV as antigen. Use of the different sets of VP7 type-specific MAbs in the enzyme-linked immunosorbent assay permitted the recognition of six antigenic variants within VP7 types 1, 2, and 3 among specimens whose VP7 type could not be determined previously with only one set of typing MAbs. These results demonstrate differences of typing ability among these VP7-specific MAbs and emphasize the need to improve the sensitivity of typing systems by incorporating panels of MAbs reacting with several neutralizing epitopes.     

Analysis of specificity of interaction between synthetic key saccharide components of lipopolysaccharides and monoclonal antibodies to Coxiella burnetii

Two monoclonal antibodies (MAbs) against the lipopolysaccharides (LPSs) of Coxiella burnetii (C.b.) strains Priscilla and Nine Mile were prepared characterized by their interaction with synthetic glycoconjugates representing parts of LPSs of C.b. in virulent phase. Both MAbs were directed against immunodominant epitopes comprising core constituent of LPSs, Kdo (3-deoxy-alpha-D-manno-2-octulo-pyranosylonic acid). ELISA showed that the anti-Nine Mile MAb 4/11 bound preferably to disaccharides (alpha-Kdo (2 --> 4) alpha-Kdo and alpha-Kdo (2 --> 4) alpha-(5d) Kdo), while the anti-Priscilla MAb 1/4/H bound to all conjugates, though with various intensity. On the other hand, immunoelectron microscopy revealed a positive binding of only one glycoconjugate, namely the trisaccharide alpha-Kdo (2 --> 4) alpha-Kdo (2 --> 4) alpha-Kdo-BSA, to both MAbs. In competitive ELISA (cELISA), the anti-Priscilla MAb 1/4/H distinguished the strains Nine Mile and Priscilla, while the anti Nine Mile MAb 4/11 did not.     

Monoclonal antibodies against human basic fibroblast growth factor

Recombinant human basic fibroblast growth factor (hbFGF) was used as an antigen to develop, by a somatic cell fusion technique, four monoclonal antibodies (MAbs), that recognize the complete and amino-terminal truncated form of hbFGF. Isotype identification showed that MAbs designated MAb12 and MAb98 were IgG1; and those designated MAb52 and MAb78 were IgG2b. All these MAbs bound the complete form of hbFGF produced in E.coli. Competition with synthetic polypeptides, a replication of 1-9 aa and of 141-146 aa of hbFGF, and truncated forms of hbFGF by 13 and 40 amino acid residues in its amino-terminal produced in E. coli by recombinant technique, revealed at least two epitopes recognized by the four IgG type MAbs. MAb12 and MAb78 recognized the epitope located within the first 9 amino acid residues at the amino terminal of the complete hbFGF. MAb52 and MAb98 recognized the one located between the amino acid residue no. 14 and 40. None of MAbs bound bovine acidic FGF (aFGF). Using MAb52 or MAb98 and MAb78, a two-site EIA has been developed. This EIA is sensitive enough to detect 0.5 ng/ml of hbFGF. Furthermore, MAb78 was used as a ligand for affinity chromatography to purify hbFGF mutein CS4, which binds weakly to a heparin affinity column.     

Monoclonal antibodies directed against conserved epitopes on the nucleocapsid protein and the major envelope glycoprotein of equine arteritis virus

We recently developed a highly effective immunization procedure for the generation of monoclonal antibodies (MAbs) directed against the porcine reproductive and respiratory syndrome virus (E. Weiland, M. Wieczorek-Krohmer, D. Kohl, K. K. Conzelmann, and F. Weiland, Vet. Microbiol. 66:171-186, 1999). The same method was used to produce a panel of 16 MAbs specific for the equine arteritis virus (EAV). Ten MAbs were directed against the EAV nucleocapsid (N) protein, and five MAbs recognized the major viral envelope glycoprotein (G(L)). Two of the EAV G(L)-specific MAbs and one antibody of unknown specificity neutralized virus infectivity. A comparison of the reactivities of the MAbs with 1 U.S. and 22 newly obtained European field isolates of EAV demonstrated that all N-specific MAbs, the three nonneutralizing anti-G(L) MAbs, and the weakest neutralizing MAb (MAb E7/d15-c9) recognized conserved epitopes. In contrast, the two MAbs with the highest neutralization titers bound to 17 of 23 (MAb E6/A3) and 10 of 23 (MAb E7/d15-c1) of the field isolates. Ten of the virus isolates reacted with only one of these two MAbs, indicating that they recognized different epitopes. The G(L)-specific MAbs and the strongly neutralizing MAb of unknown specificity (MAb E6/A3) were used for the selection of neutralization-resistant (NR) virus variants. The observation that the E6/A3-specific NR virus variants were neutralized by MAb E7/d15-c1 and that MAb E6/A3 blocked the infectivity of the E7/d15-c1-specific NR escape mutant confirmed that these antibodies reacted with distinct antigenic sites. Immunoelectron microscopy revealed for the first time that the antigenic determinants recognized by the anti-G(L) MAbs were localized on the virion surface. Surprisingly, although the immunofluorescence signal obtained with the neutralizing antibodies was relatively weak, they mediated binding of about three times as much gold granules to the viral envelope than the nonneutralizing anti-G(L) MAbs.