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.     

Monoclonal antibody and porcine antisera recognized B-cell epitopes of Nsp2 protein of a Chinese strain of porcine reproductive and respiratory syndrome virus

Porcine reproductive and respiratory syndrome virus (PRRSV) is one of the most economically important pathogens for swine industry. The non-structural protein 2 (Nsp2) is considered to be one of the immunogenic proteins of PRRSV. In this study, the B-cell epitopes of the Nsp2 protein of a North American type Chinese strain PRRSV BJ-4 were identified on a prokaryotic expressed Nsp2 fragment (73-567aa). A total of six monoclonal antibodies (mAbs) recognizing different epitopes on the expressed protein were prepared. All six mAbs exhibited immunoreactivity with the denatured Nsp2 protein in Western blotting and produced strong perinuclear staining in PRRSV infected MARC-145 cells in an immunofluorescence assay. Pepscan analysis revealed six distinct linear epitopes for the six mAbs, respectively, and of which four were identified to be novel linear Nsp2 B-cell epitopes: T(73)LPERVRPPDDWAT(86), D(385)ELKDQMEED(394), P(452)VPAPRRKVGSDCGS(466), and P(467)VSLGGDVPNS(477). All of the six mAb specific peptides could be recognized by porcine PRRSV antiserum, indicating that the epitopes involving these synthetic peptides were immunogenic and immunodominant during PRRSV infection in pigs. Our results provided valuable information for developing novel PRRSV vaccines using the Nsp2 epitopes as potential serological markers.     

Neuraminidase-deficient Sendai virus HN mutants provide protection from homologous superinfection

Binding of hemagglutinin-neuraminidase proteins (HN) to sialylated receptors initiates the infection process of several paramyxoviruses, whereas later in the viral life cycle, the neuramindase (NA) activity of newly synthesized HN destroys all receptors. Prior to NA action, expressed HN has to bind the receptor. To evaluate this HN–receptor complex with respect to receptor inactivation, three temperature-sensitive Sendai virus HN mutants carrying amino acid exchanges at positions 262, 264 and/or 461 were created that uncoupled NA activity from receptor binding at 39°C. Interestingly, at elevated temperature, when there is no detectable neuramindase activity, all infected cells are protected against homologous superinfection. Mutated HN protein on the cell surface is mainly bound to sialylated cell-surface components but can be released by treatment with NA. Thus, continuous binding to HN already inactivates the receptors quantitatively. Furthermore, mutant HN bound to receptors is prevented from being incorporated into virus particles in the absence of NA. It is shown here for the first time that during paramyxoviral infection, quantitative receptor inactivation already occurs due to binding of receptors to expressed HN protein without involvement of NA and is independent of NA activity of viral progeny. NA subsequently functions in the release of HN from the complex, coupled with desialysation of receptors. These findings could have implications for further antiviral drug development.     

Mapping of three antigenic sites on the haemagglutinin-neuraminidase protein of Newcastle disease virus

Nine neutralizing monoclonal antibodies (MAbs), each of which react with the haemagglutinin-neuraminidase (HN) glycoprotein of the Beaudette C strain of Newcastle disease virus (NDV), have been used in competitive binding assays to delineate three non-overlapping antigenic sites A, B and C. Epitopes within these sites have been identified on the basis of cross-reactivity of MAb-resistant mutants against the panel of MAbs, determined by plaque assays and Western blotting. Site A contains three non-overlapping epitopes (A1, A2 and A3). A1 is the only linear epitope; all remaining epitopes are conformational. MAbs which react with epitopes A2 and A3 inhibit neuraminidase activity (NA) when assayed with neuraminlactose. Site B contains three partially overlapping epitopes (B1, B2 and B3) and site C is represented by a single epitope (C1). HN gene sequence analysis of MAb-resistant mutants showed that they each had only single amino acid substitutions which range from amino acid residues 347-460 for site A, 284-325 for site B, and at 481 for the C1 epitope. The apparent molecular mass of the HN glycoprotein of one mutant was increased from 72 to 75 kDa. This correlates well with the creation of an additional potential glycosylation site in this mutant from Asn-Ser-Pro(325) to Asn-Ser-Ser(325).     

Identification of amino acid positions associated with neuraminidase activity of the hemagglutinin-neuraminidase glycoprotein of sendai virus

Identification of amino acid positions associated with neuraminidase activity on the hemagglutinin-neuraminidase (HN) glycoprotein of paramyxoviruses has been difficult because neuraminidase-inhibiting antibodies are not neutralizing and thus, escape mutants have not been isolated. Instead, many investigators have correlated an altered neuraminidase (NA) activity of natural virus variants, such as plaque-size variants, with sequence changes in the HN protein. To identify regions on the HN glycoprotein of Sendai virus (SV) that are associated with NA activity, we investigated NA activity of three plaque-size variants which potentially differed from the standard SV (SV/std). NA activity was measured by the ability of virus to elute from chicken erythrocytes as a result of cleaving sialic acid receptors, and by the ability of virus to cleave sialic acid from the small trisaccharide neuraminlactose and the larger substrate fetuin in an in vitro assay. Virions purified from each of the isolated plaques had a HN content and hemagglutinating activity similar to that of SV/std, yet each variant eluted much more rapidly from chicken erythrocytes than SV/std. In vitro NA activity of the plaque-size variants was 1.6 to 3.8 times greater than that of SV/std, providing supporting evidence for the elution data. Although all plaque-size variants showed elevated NA activity, there was no correlation of activity with plaque size. Sequence analysis showed that one of the variants had an amino acid change from glutamic acid to valine at position 165 and from lysine to glutamic acid at position 461, while a second variant had only the change at position 461. A third variant had a nearby change at position 468, from threonine to lysine. Taken together, these data support the conclusion that the amino acid residues at positions 461-468 and 165 are involved in neuraminidase activity of SV.     

Differences in bovine parainfluenza 3 virus variants studied by sequencing of the genes of viral envelope proteins

By determining gene nucleotide sequences we compared the primary structures of the membrane (M), fusion (F), and hemagglutinin-neuraminidase (HN) proteins of bovine parainfluenza 3 virus strains, M, SC, and MR which are substrains derived from a wild strain YN. The M and SC viruses are indistinguishable in having very weak hemagglutination (HA) and neuraminidase (NA) activities, but M virus' syncytium-inducing (SI) activity is considerably higher than that of the SC virus. However, the results showed that the amino acid sequence of the F protein was identical in M and SC viruses, demonstrating that M virus' high SI activity was not due to alteration of its F protein. Two differences in M and SC viruses' other proteins then seemed to be important, although their significance in the SI activity is not clear at present; the first being the 70th amino acid residue of the M protein, which was Asp in the M virus and Gly in the SC virus, and the other being the 539th residue of the HN protein, which was Tyr in the M virus and His in the SC virus. The nucleocapsid proteins of both M and SC viruses were identical. The MR virus, which is a variant derived from the M virus and has high HA and NA activities but very weak SI activity, was different from the M virus at only one site throughout the M, F, and HN proteins; the 193rd amino acid residue of the HN protein was Leu in the MR virus and Phe in the M virus. This result strongly suggested that the substitution of Leu with Phe at this particular site was closely linked to the drastic reduction in both HA and NA activities.     

Extensive antigenic diversity among human parainfluenza type 2 virus isolates and immunological relationships among paramyxoviruses revealed by monoclonal antibodies

A panel of 128 monoclonal antibodies (MAbs) directed against hemagglutinin-neuraminidase (HN), fusion (F), matrix (M), and polymerase (P) proteins, and nucleoprotein (NP) of the Toshiba strain of human parainfluenza type 2 virus (PIV2) was prepared to examine the antigenic relationships among clinical isolates of PIV2 and among paramyxoviruses by indirect enzyme-linked immunosorbent assays. The HN proteins of 18 clinical isolates of PIV2 showed extensive antigenic diversity: 23 of 33 anti-HN MAbs showed no or limited reactivity to many isolates, while other structural proteins were antigenically well conserved. Some anti-HN MAbs recognizing conserved epitopes of the isolates exhibited two types of neutralizing activity, that is, these antibodies inhibited viral infectivity through attachment inhibition or fusion inhibition. This result also showed the presence of a potential third function of the HN protein which might affect the fusing activity of the F protein besides the hemagglutinating and neuraminidase activities. Many of the anti-NP and anti-P MAbs reacted with simian virus 41 (SV41) and simian virus 5 (SV5), whereas a few reacted with mumps virus or PIV4. Two of 6 anti-F MAbs reacted with SV41. None of the 128 MAbs showed reactivity with PIV1, PIV3, Newcastle disease virus (NDV), and measles virus. This result confirmed antigenic proximity of SV5 and SV41 to PIV2 and revealed comparatively restricted immunological relatedness among PIV2, PIV4, and mumps virus.     

Role of a conserved sequence in the maturation and function of the NDV HN glycoprotein

The hemagglutinin-neuraminidase (HN) proteins of viruses in the Paramyxouirus genus have a short conserved sequence, G(A, S)EGR(I, L, V). The role of this sequence in the intracellular processing and function of the Newcastle disease virus HN protein was explored by site directed mutagenesis. Mutations in this region fall into two categories. One set of mutants (G398A, E400D, R402K, and a deletion removing amino acids 400–403) was defective in folding. These mutant proteins formed little or no mature, disulfide linked oligomer. They had few or no antigenic sites found on the mature protein and they were transported to the cell surface poorly or not at all. The second class of mutants (A399G, G401A, G401L) was minimally affected in folding and intracellular transport. When normalized to surface expression, this group of mutant proteins had wild type levels of attachment activity, neuraminidase activity, and fusion promotion activity. Thus mutations in this region directly affect intracellular processing but not the biological activities of the protein. This sequence may, therefore, be conserved in the HN proteins of Paramyxoviruses because it is critical to the folding of the molecule.     

Epitope analysis of mumps virus proteins in a persistent cell culture infection: changes in the hemagglutinin-neuraminidase polypeptide

Monoclonal antibodies (MABs) against major structural mumps virus proteins were used for epitope analysis in primarily and persistently infected HEp-2 cells by means of immunofluorescence and radioimmunoprecipitation techniques. Qualitatively, no differences were found in MAB binding between corresponding proteins of the original and persistent viruses, whereas quantitative differences observed might be explained in terms of weakened viral protein synthesis in persistent infection. Limited proteolysis of MAB-bound antigen has revealed alterations in certain epitopes on persistent virus HN polypeptide. Despite the inability of HEp-2 infected cells for hemadsorption, HN protein was expressed on the surface of these cells to the same extent as in the hemadsorbing system of mumps virus-infected Vero cells.     

Functional and neutralization profile of seven overlapping antigenic sites on the HN glycoprotein of Newcastle disease virus: monoclonal antibodies to some sites prevent viral attachment

We have previously identified five antigenic sites on the hemagglutinin-neuraminidase (HN) glycoprotein of the Australia-Victoria isolate of Newcastle disease virus (Iorio and Bratt, J. Virol. 48, 440-450; Iorio et al., J. Gen. Virol. 67, 1393-1403). Two additional sites (designated 12 and 23) are now described, bringing to a total of seven the number of antigenic sites defined by our panel of neutralizing anti-HN antibodies. Competition antibody binding and additive neutralization assays reveal that each of these newly-identified sites overlaps two previously-defined ones. The seven HN antigenic sites thus form a continuum in the three-dimensional conformation of the molecule. Studies on the inhibition of hemagglutination (HA), neuraminidase (NA) and the attachment of virus to chick cell monolayers have been used to construct a functional profile of each antigenic site. Monoclonal antibodies (mAbs) to three overlapping sites (12, 2 and 23) inhibit HA and NA and prevent viral attachment to chick cell monolayers. These findings are consistent with the domains recognized by these mAbs being close to the NA and receptor-binding sites. MAbs to two other overlapping sites, 14 and 1 (which in turn, overlap site 12), inhibit HA quite effectively, and attachment to a lesser extent. Sites 14 and 1 probably identify a second domain involved in receptor recognition. MAbs to the two remaining sites (3 and 4), though neutralizing, are negative in all three assays, thus recognizing domains not involved in HA or NA or attachment to chick cells.     

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.     

Antigenic regions of bovine somatotropin as defined by monoclonal antibodies

Three distinct antigenic regions of bovine somatotropin (bST) were identified on the basis of the ability of a set of monoclonal antibodies to bind to proteolytic fragments and deletion variants of recombinant bST (rbST) in Western blot analyses. One of the regions is further subdivided into two epitopes on the basis of the cross-reaction of somatotropins from several species with the same set of antibodies in solid-phase RIA. The RIA and Western blot results suggest that amino acids 134–150, 181–190 and the amino terminus may be involved in the binding specificity of antibodies to the bovine somatotropin molecule. The total of four antigenic regions on the bST molecule parallels results described for human somatotropin. Labeled antibody competition tests were used to show that the epitope involving amino acids 134–150 is spatially separated from the other three epitopes.     

A high‐throughput shotgun mutagenesis approach to mapping B‐cell antibody epitopes

Characterizing the binding sites of monoclonal antibodies (mAbs) on protein targets, their ‘epitopes’, can aid in the discovery and development of new therapeutics, diagnostics and vaccines. However, the speed of epitope mapping techniques has not kept pace with the increasingly large numbers of mAbs being isolated. Obtaining detailed epitope maps for functionally relevant antibodies can be challenging, particularly for conformational epitopes on structurally complex proteins. To enable rapid epitope mapping, we developed a high‐throughput strategy, shotgun mutagenesis, that enables the identification of both linear and conformational epitopes in a fraction of the time required by conventional approaches. Shotgun mutagenesis epitope mapping is based on large‐scale mutagenesis and rapid cellular testing of natively folded proteins. Hundreds of mutant plasmids are individually cloned, arrayed in 384‐well microplates, expressed within human cells, and tested for mAb reactivity. Residues are identified as a component of a mAb epitope if their mutation (e.g. to alanine) does not support candidate mAb binding but does support that of other conformational mAbs or allows full protein function. Shotgun mutagenesis is particularly suited for studying structurally complex proteins because targets are expressed in their native form directly within human cells. Shotgun mutagenesis has been used to delineate hundreds of epitopes on a variety of proteins, including G protein‐coupled receptor and viral envelope proteins. The epitopes mapped on dengue virus prM/E represent one of the largest collections of epitope information for any viral protein, and results are being used to design better vaccines and drugs.     

Production and characterization of monoclonal antibodies against binary ethylenimine inactivated Nipah virus

Nipah virus, a zoonotic paramyxovirus which emerged recently was chemically inactivated using binary ethylenimine (BEI). The inactivated virus was concentrated and purified by sucrose gradient centrifugation. The gradient fractions were examined by electron microscopy and Western immunoblot, and gradient fraction containing mainly Nipah matrix (M) and nucleocapsid (N) proteins was used for immunizing BALB/c mice to generate hybridomas. Screening of the resultant hybridoma clones identified five strongly positive clones producing IgG monoclonal antibodies (mAbs) reactive to the Nipah virus antigen. The protein specificity of these mAbs was determined by Western immunoblot using Nipah virus and recombinant Nipah virus proteins expressed in mammalian cells. Four mAbs reacted with Nipah N protein and one reacted with Nipah M protein. None of the mAbs neutralized Nipah virus infectivity in vitro. However, all mAbs recognized Nipah virus in ELISA and immunofluorescence assay. F45G2 mAb was most suitable for immunohistochemistry on long term formalin-fixed Nipah virus infected swine tissues. Three of the anti-nucleocapsid mAbs (F45G2, F45G3 and F45G6) showed cross-reactivity with closely related Hendra virus N protein in both immunofluorescence and Western Immunoblot assays. Two of the mAbs were specific for the Nipah virus only, F45G4 (anti-N) and F45G5 (anti-M), and could be used in the primary identification of Nipah virus. The use of these immunoreagents to develop new diagnostic assays is discussed.     

应用于胶体金免疫层析的MDMA单克隆抗体的制备与鉴定

目的：制备高特异性的抗3,4亚甲二氧基甲基苯丙胺（MDMA）单克隆抗体,用于建立快速检测MDMA的胶体金免疫层析方法。方法：用MDMA人工抗原免疫BALB/c小鼠,将小鼠脾细胞与骨髓瘤细胞SP2/0融合,经亚克隆筛选得到稳定分泌抗MDMA单克隆抗体的杂交瘤细胞株。制备腹水,辛酸-饱和硫酸铵法纯化得到抗MDMA单克隆抗体（mAb）,并用胶体金免疫层析筛选出适用的抗MDMA单克隆抗体（mAb）,并对其进行特异性、纯度、亚类的鉴定分析。结果：经多次亚克隆后筛选得到4C10、4D10、7D11、8D4 4株分泌抗MDMA单克隆抗体的杂交瘤细胞株。其中细胞株8D4分泌的抗体适用于胶体金免疫层析。结论：成功筛选出能稳定分泌mAb的细胞株,为MDMA快速检测试剂的研制提供了关键材料。     

Development and characterization of murine monoclonal antibodies to first and second Ljungan virus genotypes

Ljungan virus (LV) is a rodent pathogen that causes diabetes and myocarditis in its natural host. In addition, LV has been associated with human disease during pregnancy and of neonates, respectively. A panel of 22 monoclonal antibodies (mAbs) against first and second LV genotypes were produced by immunization of BALB/c mice with whole virus. Thirteen mAbs were class IgG antibodies and nine were class IgM antibodies; all of them contained kappa light chains. All mAbs were reactive with LV by capture enzyme-linked immunosorbent assay and indirect immunofluorescence assay. In addition, five mAbs showed a positive staining in immunohistochemistry. No mAb bound to denatured capsid proteins detected by western immunoblotting. In contrast, the target capsid protein(s) of 20 mAbs were identified by immune precipitation, revealing the conformational nature of epitopes required for mAb binding. None of the mAbs reacted with third and fourth LV genotypes. mAbs characterized should provide useful tools for the development of diagnostic assays and the investigation of LV first and second genotype properties and its pathogenesis.     

A single amino acid substitution in the hemagglutinin-neuraminidase of Newcastle disease virus results in a protein deficient in both functions.

Sequence determinations of the hemagglutinin-neuraminidase (HN) glycoproteins of a temperature-sensitive mutant of Newcastle disease virus and two sequentially selected revertants had previously shown that substitution at a pair of residues, 129 and 175, resulted in a deficiency in neuraminidase (NA) activity, which was partially restored by a third substitution at residue 193. To evaluate the role of the substitution at residue 175 in diminished NA activity, the mutation was introduced into HN and the protein expressed in COS cells. The mutated HN not only had minimal NA activity but also was unable to absorb chicken erythrocytes, even though it was transported to the cell surface in normal amounts, in an apparently antigenic form. Attachment function was restored to the protein by the introduction of the additional substitution(s) at 129 and/or 193. These results indicate that residue 175 influences not only NA activity but also receptor recognition.     

Antigenic properties of the coat of Cucumber mosaic virus using monoclonal antibodies

The coat protein (CP) of Cucumber mosaic virus (CMV) was characterized by antigen-capture-ELISA using a panel of monoclonal antibodies (mAbs) which were produced against Pepo-CMV-CP. Comparative analysis of three mAbs with four different strains by competitive ELISA revealed that the binding affinity of the mAb decreased about 10-fold with both MY17- and Y-CMV than with Pepo-CMV. The CP of these three strains showed high homology (98%) following comparison in the GenBank database. CMV has a negatively charged loop structure, the βH–βI loop, although the amino acid at position 193 is not conserved. In addition, an amino acid residue identified within the variable region spanning amino acids 191–198, specifically at position 194, showed significant changes in Threonine, Alanine, Alanine, and Lysine of the Pepo-, MY17-, Y-, and M2-CMV strains, respectively. Evidence from competitive ELISA and GenBank database amino acid residues, when taken together, provide strong support suggesting that the dominant epitope site of CMV-CP-specific mAbs is the βH–βI loop 191–198. The four mAbs were chosen because they represent distinct, overlapping epitopes within the group-specific determinant located on the CMV-CP and because they all recognize linear epitopes. Knowledge of specific immunoglobulin genes for a common epitope may lead to insight on pathogen–host co-evolution and may help prevent virus infection in plants.     

Categorization of North American porcine reproductive and respiratory syndrome viruses: Epitopic profiles of the N, M, GP5 and GP3 proteins and susceptibility to neutralization

Summary.   Eleven epitopes were identified by murine monoclonal antibodies (MAbs) that represented the N, M, GP5 and GP3 proteins of the North American (NA) porcine reproductive and respiratory syndrome (PRRS) virus, KY 35 (NVSL 46907). Three discontinuous epitopes of the N and M proteins were designated EpORF7-Fd through Hd and EpORF6-Ad through Cd. Five continuous epitopes of the GP5 and GP3 proteins were designated EpORF5-A through C and EpORF3-A and B. The MAbs representing EpORF5-C and EpORF6-A and B had neutralizing activity. The MAbs representing the above epitopes, except EpORF7-Gd and Hd, expanded the virus marker system described in a previous study in which a panel of 69 NA viruses and the Lelystad virus were categorized into 5 antigenic groups, I₁₅ through V₁₅ based on the presence or absence of 5 continuous epitopes of the N protein. Antigenic groups I₁₅ and II₁₅, which represented 84.7 and 11.6% of all viruses tested, were categorized further into 9 and 4 subgroups, respectively. The remaining NA viruses and the Lelystad virus were distributed among 4 groups, one of which was represented by 2 subgroups. Significant (P<0.05) differences in sensitivity to neutralization of 28 viruses representing 6 antigenic groups by the 3 neutralizing MAbs suggested that sensitivity to neutralization may also be of value in categorizing PRRS viruses. Received October 18, 1999 Accepted March 2, 2000     

Characterization of epitopes for neutralizing monoclonal antibodies to classical swine fever virus E2 and Erns using phage-displayed random peptide library

Summary. Infection of cells with classical swine fever virus (CSFV) is mediated by the interaction of envelope glycoproteins E2 and E^rns with receptor molecules on the cell surface. These proteins are also the major antigens for eliciting neutralizing antibodies and conferring protective immunity. Here we report the identification of multiple neutralizing epitopes on these proteins by screening a phage-displayed random peptide library with CSFV-specific neutralizing monoclonal antibodies. Two different E2-specific neutralizing mAbs (a18 and 24/10) were found to bind to a common motif SPTxL, which is similar to the sequence SPTTL of the E2 protein (aa 289–293), indicating that this is likely to be an immunodominant epitope. Similarly, an immunodominant epitope corresponding to the sequence DKN of E^rns (aa 117–119) was identified for two independent E^rns-specific neutralizing antibodies, b4-22 and 24/16, respectively. Another binding motif, CxNNxTC, was identified for mAb 24/16, but not for b4-22. Sequencing analysis of the genes coding for the light chain of these mAbs was conducted to ensure that all mAbs were derived from different hybridomas, rather than from different subclones of a common parent line. Inhibition studies using immunofluorescent antibody assay and virus neutralization test demonstrated that the mimotope peptides truly mimicked the antibody binding determinants on the viral proteins. The detailed mapping data for these neutralizing epitopes will be useful for development of improved diagnostic tests and perhaps a peptide-based vaccine for this important swine disease.