Antigenic sites on foot-and-mouth disease virus type A10

RGD sequence of foot-and-mouth disease virus is essential for infecting cells via the natural receptor but can be bypassed by an antibody-dependent enhancement pathway

Foot-and-mouth disease virus appears to initiate infection by binding to cells at an Arg-Gly-Asp (RGD) sequence found in the flexible beta G-beta H loop of the viral capsid protein VP1. The role of the RGD sequence in attachment of virus to cells was tested by using synthetic full-length viral RNAs mutated within or near the RGD sequence. Baby hamster kidney (BHK) cells transfected with three different RNAs carrying mutations bordering the RGD sequence produced infectious viruses with wild-type plaque morphology; however, one of these mutant viruses bound to cells less efficiently than wild type. BHK cells transfected with RNAs containing changes within the RGD sequence produced noninfectious particles indistinguishable from wild-type virus in terms of sedimentation coefficient, binding to monoclonal antibodies, and protein composition. These virus-like particles are defined as ads- viruses, since they were unable to adsorb to and infect BHK cells. These mutants were defective only in cell binding, since antibody-complexed ads- viruses were able to infect Chinese hamster ovary cells expressing an immunoglobulin Fc receptor. These results confirm the essential role of the RGD sequence in binding of foot-and-mouth disease virus to susceptible cells and demonstrate that the natural cellular receptor for the virus serves only to bind virus to the cell.

Antigenic heterogeneity of a foot-and-mouth disease virus serotype in the field is mediated by very limited sequence variation at several antigenic sites

Antigenic variation in a major discontinuous site (site D) of foot-and-mouth disease virus (FMDV) of serotype C has been evaluated with neutralizing monoclonal antibodies. Isolates representing the major evolutionary sublines previously defined for serotype C were compared. Extensive variation, comparable to that of continuous epitopes within the hypervariable immunodominant site A (the VP1 G-H loop), was found. The amino acid sequences of the complete capsids of three antigenically highly divergent FMDVs (C1 Haute Loire-Fr/69, C5 Argentina/69, and C3 Argentina/85) have been determined and compared with the corresponding sequences previously determined for seven additional type C viruses. Differences in antigenicity are due to a very limited number of substitutions of surface amino acids accessible to antibodies and located within antigenic sites previously identified on FMDV. A significant number of residues at these positions were also replaced in monoclonal antibody escape mutants. Depending on the variants compared, replacements within site A or at site D, or at both sites, contributed significantly to their antigenic differences. Examples of divergence mediated by a few amino acid replacements were found among FMDVs of Europe and South America. The results suggest that within a serotype of FMDV, antigenically highly divergent viruses can arise in the field by very limited sequence variation at exposed key residues of each of several antigenic sites.

The structure and antigenicity of a type C foot-and-mouth disease virus

BACKGROUND

Picornaviruses are responsible for a wide range of mammalian diseases and, in common with other RNA viruses, show considerable antigenic variation. Foot-and-mouth disease viruses (FMDVs) constitute one genus of the picornavirus family and are classified into seven serotypes, each of which shows considerable intratypic variation. This antigenic variation leads to continuing difficulties in controlling the disease. To date the structure of only one serotype, O, has been reported.

RESULTS

The three-dimensional structure of a serotype C (isolate C-S8c1) FMDV, has been determined crystallographically at 3.5 A resolution. The main chain conformation of the virion is very similar to that of type O1 virus. The immunodominant G-H loop of VP1, the presumed site of cell attachment, is disordered in both types of virus indicating a functional role for flexibility of this region. There are significant changes in the structure of other antigenic loops and in some internal regions involved in protomer-protomer contacts, including the entire amino-terminal portion of VP2, described here for the first time for a picornavirus. Antigenic sites have been identified by genetic and peptide mapping methods, and located on the capsid. The data reveal a major new discontinuous antigenic site (site D) which is located near to the three-fold axis and involves residues of VP1, VP2 and VP3 which lie adjacent to each other on the capsid.

CONCLUSION

In FMDV type C, amino acid substitutions seen in mutants that are resistant to neutralization by monoclonal antibodies (MAbs) map to predominantly surface-oriented residues with solvent-accessible side-chains not involved in interactions with other amino acids, whereas residues which are accessible but not substituted are found to be more frequently involved in protein-protein interactions. This provides a molecular interpretation for the repeated isolation of the same amino acid substitutions in MAb-resistant variants, an observation frequently made with RNA viruses. This first comparison of two FMDV serotypes shows how subtle changes at antigenic sites are sufficient to cause large changes in antigenic specificity between serotypes.

Characterization of monoclonal antibodies against a type SAT 2 foot-and-mouth disease virus

This paper is the first to describe characterization of monoclonal antibodies (MAbs) against a South African Territories 2 (SAT 2) foot-and-mouth disease virus (isolate Rho 1/48). Twelve MAbs which neutralized homologous virus were characterized in indirect and sandwich ELISA using purified Rho 1/48 virus particles, subunits, trypsin-treated, and chemically denatured virus. All the MAbs inhibited haemagglutination by parental virus. Binding of the MAbs to 73 SAT 2 field isolates was measured in a sandwich ELISA and defined four distinct antigenic regions. Preliminary characterization of escape mutants selected with some of the MAbs using virus neutralization tests, ELISA, and amino acid sequencing is included. MAbs 2, 25, 40, 48 and 64, reacted with a linear epitope on the VP1 loop region. An amino acid change at position 149 (valine to glutamic acid) was detected in mutants selected by MAb 2 and 40 and this eliminated binding and neutralization by all the other MAb. This epitope was conformation-dependent and was conserved in all 73 isolates of SAT 2 examined. Escape mutants isolated with MAb 41 and 44, had changes at positions 156 (glycine to aspartic acid), or 158 (serine to leucine) respectively. These MAbs bound with Rho 1/48 only out of 73 field strain viruses studies and the reactions of MAbs from the other groups was unaltered. MAb 27, 28 and 37 reacted with a conformation-dependent epitope on VP1 which was not conserved in field isolates. All mutants selected by these MAbs had a single amino acid substitution at position 149 (valine to alanine). The same change was always found in field isolates which did not bind MAbs from this group. MAb 11 reacted with a linear epitope associated with amino acids 147 or 148 on VP1 and showed similar binding characteristics to a conformation dependent MAb 7, no amino acid residue changes were found within VP1 for monoclonal antibody 7 mutants.

Use of substituted and tandem-repeated peptides to probe the relevance of the highly conserved RGD tripeptide in the immune response against foot-and-mouth disease virus

Antigenic site A of foot-and-mouth disease virus (FMDV) is an exposed, mobile loop which includes a central, highly conserved Arg-Gly-Asp tripeptide (RGD, VP1 residues 141-143 in serotype C) thought to be part of the cell attachment site. We have analyzed the contribution of RGD to the interaction of site A with antibodies by incorporating selected amino acid replacements at RGD into synthetic peptides representing site A, and analyzing the reactivity of substituted peptides with site A-specific monoclonal antibodies (MAbs). Replacement of Arg-141, Gly-142 or Asp-143 by alanine resulted in the loss of one, three and five epitopes, respectively, out of seven epitopes probed. Other replacements resulted in the loss of even larger numbers of epitopes, suggesting that the amino acids of the RGD region are either directly involved in interaction with antibodies or that they exert an important influence on the interaction of surrounding residues with antibodies. Thus, we explored the ability of tandem repeats of the RGDL sequence (corresponding to FMDV C-S8c1) to evoke neutralizing antibodies in rabbits and guinea pigs. Neutralizing activity was generally low but with a broad specificity for different FMDV serotypes and variants. Significant decreases in neutralizing titers were observed with boosting, suggesting a possible suppression of those anti-peptide antibodies which may also be directed to cellular RGD sequences. The results point to an involvement of RGD in the antigenic structure of site A, and open the possibility that broadly neutralizing antibodies might be induced by tandem repeats of the critical, conserved domain.

Amino acid changes outside the G-H loop of capsid protein VP1 of type O foot-and-mouth disease virus confer resistance to neutralization by antipeptide G-H serum

Antiserum to a peptide corresponding to the 135-154 sequence of capsid protein VP1 of the foot-and-mouth disease virus O1 Kaufbeuren was raised in a pig. Although this serum contained neutralizing antibodies, the pig showed clinical symptoms after challenge. Virus isolated from this pig was identified as a mutant, with changes at positions 50, 198 and 211 of VP1 and at position 209 of VP2. This mutant, as well as a plaque isolate of it, differing from the challenge virus at positions 198 on VP1 (alanine being substituted for glutamic acid) and 209 on VP2 (histidine being substituted for tyrosine) resisted neutralization by the anti-peptide serum also in vitro. The same was observed with the O1 Kaufbeuren-related strain O1 Burgwedel, isolated from cattle in the field. It had substitutions only at positions 43 and 101 on VP1. The results show that neutralization epitopes flanking positions 145-147 on VP1 are modulated by other capsid protein parts. These parts seem to be important for neutralization escape in natural FMDV host species.

Crystallization and preliminary X-ray analysis of three serotypes of foot-and-mouth disease virus

Foot-and-mouth disease viruses from serotypes O, A and C have been crystallized. The particular strains studied include O1K, A10(61), A22 Iraq 24/64, A24 Cruzeiro and C-S8c1. In addition, crystals have been grown of G67, a monoclonal antibody neutralization escape mutant derived from O1K, and of virus R100, recovered after the establishment of a persistent infection in baby hamster kidney cells with C-S8c1. Empty particles, capsids which lack the RNA genome, have also been crystallized for subtypes A22 Iraq 24/64 and A10(61). In almost all cases, crystals suitable for high resolution structure determination were obtained from (NH4)2SO4 or mixtures of polyethylene glycol and NH4Cl.

Proliferative lymphocyte responses to foot-and-mouth disease virus and three FMDV peptides after vaccination or immunization with these peptides in cattle

We studied proliferative responses of bovine T lymphocytes to foot-and-mouth disease virus (FMDV) serotypes A, O and C as well as to three peptides including the two major B-cell epitopes of FMDV (VP1[141-156] and VP1[200-213]). Peripheral blood mononuclear cells (PBMC) from cattle previously vaccinated with monovalent vaccine responded to both homotypic and heterotypic virus strains. Of 14 FMDV-specific bovine T-cell clones, which were prepared from PBMC of an animal vaccinated with the trivalent vaccine, 11 reacted to each of the three serotypes A, O and C. This indicates that several T-cell epitopes might be conserved among these serotypes. PBMC from one of two cattle immunized with VP1[141-156]KLH, one of two cattle immunized with VP1[200-213]KLH and two of three cattle immunized with CC-VP1[200-213]-PPS-VP1[141-156]-PCG responded to the homotypic virus strain. After immunizations with VP1[200-213]KLH also heterotypic responses were found. Thus, it appears that these two B-cell sites include T-cell determinants that are recognized by some cattle. However, when proliferative responses of PBMC from an animal vaccinated with the trivalent vaccine were tested, no responses were found to VP1[141-156] and VP1[200-213], whereas the response was very poor to CC-VP1[200-213]-PPS-VP1[141-156]-PCG. These results suggest that these sequences do not represent dominant T-cell epitopes and/or that T-cell reactivity towards these synthetic peptides does not completely cover the T-cell reactivity towards the fragments present after processing of the whole virus.

Two mechanisms of antigenic diversification of foot-and-mouth disease virus

The amino acid replacements that underlay the diversification of the main antigenic site A (VP1 residues 138 to 150) of foot-and-mouth disease virus (FMDV) of serotype C have been identified. Sixteen new VP1 sequences of isolates from 1926 until 1989 belonging to subtypes C1, C2, C3, C4, C5, and unclassified are reported. The reactivities in enzyme-linked immunoelectrotransfer blot assays of capsid protein VP1 with a panel of neutralizing monoclonal antibodies that recognize sites A or C (the VP1 carboxy-terminus) have been correlated with the amino acid sequence at the relevant epitopes. The analyses involving the immunodominant site A reveal two mechanisms of antigenic change. One is a gradual increase in antigenic distance brought about by accumulation of amino acid replacements at two hypervariable segments within site A. A second mechanism consists of an abrupt antigenic change manifested by loss of many epitopes, caused by one replacement at a critical position (particularly Ala (145)----Val or His (146)----Gln). The identification of the amino acid substitutions responsible for such large antigenic changes provides new information for the design of synthetic anti-FMD vaccines. However, the screening of isolates from six decades suggests that the virus, even within the confines of a single serotype, has exploited a minimum of its potential for antigenic variation.

Detection and localization of single-base sequence differences in foot-and-mouth disease virus genomes by the RNase mismatch cleavage method

The RNase mismatch cleavage method was examined for its efficiency of indicating single-base sequence differences in the capsid protein-coding regions of different foot-and-mouth disease virus subtype O1 strains. The method was found suitable for indicating such differences. RNase A as well as RNase T1 contributed to substrate conversion. Examples for the cleavage of eleven different single-base mismatches in RNA double-strands are now known. All virus genomes found to differ from each other exhibited three or more non-neighboured single-base sequence differences. Other genomes found to be indistinguishable by this method were those of a recent field isolate adapted to cell culture, and those of a vaccine production strain; its progeny was transmitted to pig and cow and then analyzed. The results suggest that host change does not necessarily select for antigenic variant virus, and that virus submitted to some kind of selection pressure is changed at more than one position.

Antigenic stability of foot-and-mouth disease virus variants on serial passage in cell culture

Two neutralizing monoclonal antibody (MAb)-resistant variants selected from an isolate of foot-and-mouth disease virus (FMDV) type A5 were repeatedly passaged in cell culture and monitored for susceptibility to neutralization by the selecting MAb. A variant isolated with a MAb to a conformational epitope (1-OG2) lost resistance in 20 passages, while a variant isolated with a MAb to a linear epitope (1-HA6) persisted for 30 passages. In both cases, the virus population emerging after passage was antigenically and genetically indistinguishable from the original wild-type parental virus (FMDV A5 Spain-86). Coinfection assays with the wild type and each variant, and between the variants, showed rapid conversion to a homogeneous population. Wild-type virus prevailed over the variants and for coinfection between the variants, the linear epitope variant 1-HA6. While both variants arose from a single nucleotide substitution and reversion to wild type occurred for each, it appears that the variant based on the continuous epitope (1-HA6) was more stable. We discuss the implications of these results for the antigenic diversity of FMDV and its relationship to virus evolution.

Chimeric polioviruses that include sequences derived from two independent antigenic sites of foot-and-mouth disease virus (FMDV) induce neutralizing antibodies against FMDV in guinea pigs

Five poliovirus recombinants containing sequences corresponding to foot-and-mouth disease virus (FMDV) antigenic sites were constructed. Viable virus was recovered from four of these plasmids, in which the VP1 beta B-beta C loop (antigenic site 1) of poliovirus type 1 Sabin had been replaced with sequences derived from the VP1 beta G-beta H loop (antigenic site 1) of FMDV O1 Kaufbeuren (O1K), chimera O1.1 (residues 141 to 154), chimera O1.2 (residues 147 to 156), and chimera O1.3 (residues 140 to 160) or from the beta B-beta C loop of VP1 (antigenic site 3) in chimera O3.1 (residues 40 to 49). One chimera (O1.3) was neutralized by FMDV-specific polyclonal serum and monoclonal antibodies directed against antigenic site 1 of FMDV. Chimeras O1.3 and O3.1 induced site-specific FMDV-neutralizing antibodies in guinea pigs. Chimera O1.3 was capable of inducing a protective response against FMDV challenge in some guinea pigs.

Identification of neutralizing antigenic sites on VP1 and VP2 of type A5 foot-and-mouth disease virus, defined by neutralization-resistant variants

Five neutralizing monoclonal antibodies (nMAbs) obtained against type A5 Spain-86 foot-and-mouth disease virus were used to generate a series of neutralization-resistant variants. In vitro and in vivo assays showed that the variants were fully refractory to neutralization by the selecting nMAb. On the basis of cross-neutralization and binding assays, two neutralizing antigenic sites have been located on the virus surface; one, located near the C-terminus of VP1, displayed a linear epitope, and the second, located on VP2, displayed two conformational epitopes. Nucleotide sequencing of RNA of the parental and variant capsid protein-coding region P1 has placed the amino acid changes at position 198 of VP1 for the first site and at positions 72 and 79 of VP2 for the related epitopes in the second site. The relative importance of these two sites in the biological properties of foot-and-mouth disease virus is discussed.

Characterization of Mengo virus neutralization epitopes

A set of four monoclonal antibodies which neutralized the infectivity of Mengo virus was used to select 20 non-neutralizable (escape) mutants. Altered amino acids were identified by sequence analyses of the capsid-coding regions of the mutant virus genomes. Mutations were found predominantly in proteins VP2 and VP3, while mutations in VP1 were detected only as second mutations. The Mengo virus VP2 mutations at amino acid residues 2144, 2145, 2147, and 2148 align with site Nlm II in human rhinovirus-14 and site 2 in polioviruses 1 and 3. The mutation at 2075 as well as those at 3057, 3061, and 3068 in VP3 correspond to site 3 in poliovirus. These alignments notwithstanding, the results of cross-neutralization experiments indicate the existence of a single composite neutralization site on the Mengo virion. Considering the three-dimensional structure of the Mengo capsid, the amino acids which are altered in the escape mutants are all exposed on the outer surface and none are found in the "pit," the probable site for binding of a cellular receptor. The VP3 mutations are located in the VP3 "knob" and the VP2 mutations on a nearby ridge. Together these mutations define a set of epitopes within a single composite antigenic determinant which forms a crescent-shaped area around the three-fold icosahedral axes of the Mengo virion.

The capsid protein-encoding sequence of foot-and-mouth disease virus O2Brescia

Nucleotide sequences encoding the four capsid proteins of foot-and-mouth disease virus subtype O2Brescia/1947 have been determined. These and the deduced amino acid sequences were compared with those of a subtype O1 virus strain. The nucleotide sequences differed at 259 positions, causing only 35 amino acid changes. VP4 and VP2 differed by 2.4 and 1.8%, whereas VP1, known as major viral antigen, and VP3 differed by 8% and 5.5%, respectively. The differences occur mainly in protein domains not involved in the formation of alpha-helices and beta-sheets, suggesting that the surfaces of both viruses are more variable than their scaffolds. The O2Brescia sequence has been submitted to the GenBank data base and has the accession number M 55287.

Sequence analysis of monoclonal antibody resistant mutants of type O foot and mouth disease virus: evidence for the involvement of the three surface exposed capsid proteins in four antigenic sites

Sequence analysis of monoclonal antibody resistant mutants of type O foot and mouth disease virus has been performed. Distinct clusters of amino acid substitutions conferring resistance to neutralization at each of the four previously defined antigenic sites (McCahon et al., 1989, J. Gen. Virol. 70, 639-645) have been identified. One site corresponds to the well-known 140-160 region of VP1, a second site is also on VP1, one site is on VP2, and the fourth site is on VP3. All of the amino acid substitutions identified are located on the surface of the virus. Despite the differences in three-dimensional structure between FMDV and other picornaviruses the neutralizing antigenic sites occur in analogous positions on the capsid surface.

Unique amino acid substitutions in the capsid proteins of foot-and-mouth disease virus from a persistent infection in cell culture

Maintenance of a persistent foot-and-mouth disease virus (FMDV) infection in BHK-21 cells involves a coevolution of cells and virus (J. C. de la Torre, E. Martínez-Salas, J. Díez, A. Villaverde, F. Gebauer, E. Rocha, M. Dávila, and E. Domingo, J. Virol. 62:2050-2058, 1988). The resident FMDV undergoes a number of phenotypic changes, including a gradual decrease in virion stability. Here we report the nucleotide sequence of the P1 genomic segment of the virus rescued after 100 passages of the carrier cells (R100). Only 5 of 15 mutations in P1 of R100 were silent. Nine amino acid substitutions were fixed on the viral capsid during persistence, and three of the variant amino acids are not represented in the corresponding position of any picornavirus sequenced to date. Cysteine at position 7 of VP3, that provides disulfide bridges at the FMDV fivefold axis, was substituted by valine, as determined by RNA, cDNA, and protein sequencing. The modified virus shows high buoyant density in cesium chloride and depicts the same sensitivity to photoinactivation by intercalating dyes as the parental FMDV C-S8c1. Amino acid substitutions fixed in VP1 resulted in altered antigenicity, as revealed by reactivity with monoclonal antibodies. In addition to defining at the molecular level the alterations the FMDV capsid underwent during persistence, the results show that positions which are highly invariant in an RNA genome may change when viral replication occurs in a modified environment.

Structural and serological evidence for a novel mechanism of antigenic variation in foot-and-mouth disease virus

Changes resulting in altered antigenic properties of viruses nearly always occur on their surface and have been attributed to the substitution of residues directly involved in binding antibody. To investigate the mechanism of antigenic variation in foot-and-mouth disease virus (FMDV), variants that escape neutralization by a monoclonal antibody have been compared crystallographically and serologically with parental virus. FMDVs form one of the four genera of the Picornaviridae. The unenveloped icosahedral shell comprises 60 copies each of four structural proteins VP1-4. Representatives from each of the genera have similar overall structure, but differences in the external features. For example, human rhinovirus has a pronounced 'canyon' that is proposed to contain the cell attachment site, whereas elements of the attachment site for FMDV, which involves the G-H loop (residues 134-160) and C-terminus (200-213) of VP1, are exposed on the surface. Moreover, this G-H loop, which is a major antigenic site of FMDV, forms a prominent, highly accessible protrusion, a feature not seen in other picornaviruses. It is this loop that is perturbed in the variant viruses that we have studied. The amino acid mutations characterizing the variants are not at positions directly involved in antibody binding, but result in far-reaching perturbations of the surface structure of the virus. Thus, this virus seems to use a novel escape mechanism whereby an induced conformational change in a major antigenic loop destroys the integrity of the epitope.

Quantification of intact 146S foot-and-mouth disease antigen for vaccine production by a double antibody sandwich ELISA using monoclonal antibodies

A double antibody sandwich (DAS) enzyme-linked immunosorbent assay (ELISA) was developed to quantify 146S antigen of foot-and-mouth disease virus (FMDV) strain A10 Holland grown in suspension cultures of surviving bovine tongue epithelium. When virus harvests were incubated with trypsin--which affects VP1, the most immunogenic structural protein of FMDV--the concentration of 146S antigen as determined by ELISA was reduced by greater than 90%. Therefore, the test detected essentially only those virus particles with intact VP1. When the test was compared with the sucrose density gradient method, concentrations of 146S antigen correlated well (r = 0.87). The rate of variation in both tests was the same. In contrast to the sucrose density gradient method, the DAS-ELISA can simultaneously quantify 146S antigen in many samples, and also indicates when VP1 of 146S particles has disintegrated by the action of proteases.

A complex-trapping-blocking (CTB) ELISA, using monoclonal antibodies and detecting specifically antibodies directed against foot-and-mouth disease types A, O and C. I. Method and characteristics

A complex-trapping-blocking (CTB) enzyme-linked immunosorbent assay (ELISA) was developed for the detection of antibodies directed against foot-and-mouth disease virus (FMDV) strains A10 Holland, O1 BFS, and C1 Detmold. For each strain two monoclonal antibodies directed against different antigenic sites of FMDV were used. The assay used either infectious, not inactivated antigen or inactivated antigen. We concluded that the CTB-ELISA was sensitive, type-specific, and more reproducible (P less than 0.05) than the serum neutralisation test (SNT). In addition, the test was easy to perform and results could be recorded within 3 hours. The cross-reactivity of bovine reference sera raised against the three FMDV strains was comparable in the CTB-ELISA and the SNT.

Expression of foreign epitopes in P-fimbriae of Escherichia coli

Hypervariable regions (HRs) of the major subunit of F11 fimbriae were exploited for insertion of foreign epitopes. Two insertion vectors were created that contain a unique cloning site in HR1 or HR4 respectively. Several oligonucleotides, coding for antigenic determinants derived from different pathogens, were cloned in both insertion vectors. Hybrid fimbrial subunits were generally shown to be assembled in fimbriae when the length of the inserted peptide did not exceed 14 amino acids. The inserted peptides appeared to be exposed in the fimbrial filament. One hybrid fimbrial protein induced detectable levels of antibodies against the inserted epitope if injected into mice.

The effect of peptides containing the arginine-glycine-aspartic acid sequence on the adsorption of foot-and-mouth disease virus to tissue culture cells

Sequencing of the VP1 of a large number of subtypes of foot-and-mouth disease virus (FMDV) has revealed the presence of a conserved arginine-glycine-aspartic acid (RGD) sequence located in a highly exposed region. This sequence has been shown to be essential for the interaction of certain extracellular matrix and adhesion proteins with a superfamily of cell-surface receptors called integrins. We have examined the effects of synthetic peptides containing the RGD sequence on the binding of eight different subtypes of FMDV to tissue culture cells. The results showed that such peptides inhibited viral adsorption by 50-80%. The inhibition was dose dependent but not as great as that achieved by using a saturating amount of virus as an inhibitor. Substitution of other amino acids for any of the three main residues lowered the inhibitory properties of the peptides. These results suggest that the RGD sequence in FMDV VP1 appears to be important for the interaction of virus with cellular receptor sites.

Neutralizing antibodies to all seven serotypes of foot-and-mouth disease virus elicited by synthetic peptides

Uncoupled peptides from all seven serotypes of foot-and-mouth disease virus (FMDV) protein VP1 have been used to elicit neutralizing antibody responses in guinea-pigs. The responses were largely serotype specific, although some significant cross-neutralization was observed. Dimeric tandem peptides have also been used to simultaneously elicit neutralizing antibodies to two different FMDV serotypes. The possible existence of structural features common to the B-cell neutralization sites or the guinea-pig helper T-cell sites within all seven peptides are analysed and discussed.

Analysis of neutralizing antigenic sites on the surface of type A12 foot-and-mouth disease virus

A series of seven neutralizing monoclonal antibodies (nMAbs) directed against type A12 foot-and-mouth disease virus was used to generate neutralization-resistant variants. Both plaque reduction neutralization and microneutralization assays showed that the variants were no longer neutralized by the nMAbs used to generate them, although some of the variants still reacted with the nMAbs at high antibody concentrations. Results of cross-neutralization studies by both plaque reduction neutralization and microneutralization assays suggested the presence of at least one immunodominant antigenic site on the surface of type A12 foot-and-mouth disease virus, along with evidence of a second antigenic site on the viral surface. Two of the variants had reduced virulence in tissue culture as evidenced by their inability to inhibit cellular protein synthesis and a marked reduction in virus-induced cellular morphological alterations. Nucleotide sequencing of the variant genomes placed three epitopes of the major antigenic site on VP1 and the fourth epitope on VP3 and VP1. The one epitope of the minor site appears to reside only on VP1.