A comparative chemical and serological study of the full and empty particles of foot-and mouth disease virus.

The chemical and serological properties of the full, naturally occurring empty and artificially produced empty particles of foot-and-mouth disease virus, serotype A(subtype 10, strain 16) have been studies. The full 146S particles comprised the virus RNA, three polypeptides (VP1 to VP3) mol. wt. about 30 X 10-3, one polypeptide (VP4) mol. wt. about 13-5 X 10-3, and a small amount of a polypeptide (VPo) mol. wt. about 43 X 10-3. The naturally occurring 75S empty particles contained no RNA and much less VP1 and VP4 than were found in the fall particles. However they contained a much greater proportion of VPo than the full particles. Dialysis of purified full particles against tris-EDTA, pH 7-6, produced artificial 75S empty particles which contained only a small amount of RNA and no VP4; otherwise the polypeptide composition was similar to that of the full particles. Immunological and serological tests showed that the full particles were antigenically similar to the naturally occurring empty particles but distinct from the artificial empty particles. The latter particles, however, had serological properties similar to those of the 12S protein subunit of the virus. Both the full and naturally occurring empty particles attached efficiently to susceptible cells, whereas the artificial empty particles attached only to a limited extent. The results are related to the function of the individual polypeptides of the virus particle and compared with published work on other picornaviruses.     

Evidence for common, intertypic antigenic determinants on poliovirus capsid polypeptides

Polyclonal antibodies prepared against individualized type 1 poliovirus structural polypeptides VP1, VP2, and VP3 were used to analyze the presence of common antigenic determinants among the three poliovirus serotypes. Each anti-VP antiserum immunoprecipitated specifically the polypeptide against which it had been prepared, as well as the corresponding polypeptide of the heterotypic viruses. Anti-VP1 antisera also reacted with type 1, type 2, and type 3 heat-denaturated poliovirions (C particles), whereas anti-VP2 and anti-VP3 sera formed immune complexes with type 1 and type 3, but not with type 2, C particles. It was concluded that capsid polypeptides VP1, VP2, and VP3 of the three serotypes share common antigenic determinants which are masked in mature virions (D particles), but can be unmasked, at least partially, upon heat inactivation of the virus.     

Immunochemical studies of polioviruses: identification of immunoreactive virus capsid polypeptides

Investigation of the immunological reactions with individual poliovirus capsid polypeptides of antisera and monoclonal antibodies raised against poliovirus type 3 antigens are described. Virus polypeptides were separated by electrophoresis, transferred electrophoretically to nitrocellulose sheets and treated with antibody preparations. Antibody binding specifically to the virus polypeptides was then detected by application of 125I-labelled anti-immunoglobulin followed by autoradiography. The technique readily enabled the identification of the polypeptides recognized by the antibody. Antibodies present in polyclonal, type-specific neutralizing sera to poliovirus type 3 bound to the two largest capsid polypeptides (VP1 and VP2) of the homotypic poliovirus, and also to the VP1 of poliovirus type 1 and type 2. There was no obvious difference between the antibody binding patterns obtained with neutralizing and non-neutralizing antisera or between C-specific and D-specific antisera. VP1 appeared to be the immunodominant virus polypeptide. Among monoclonal antibodies specific for the C antigen of poliovirus type 3, a proportion reacted homotypically with the VP1 of poliovirus type 3. Other monoclonal antibodies of C antigen or D antigen specificity, or which reacted both with D and C antigens, some of which had potent virus-neutralizing activity, failed to give demonstrable binding reactions. The non-correlation of neutralization and immunoblot reactivity suggests that sequence determinants alone do not mediate virus neutralization which may depend on antigenic determinants specified by complex conformational arrangements of the virus capsid proteins.     

Subunit interaction in B19 parvovirus empty capsids

Summary B19 parvovirus is a small single-stranded DNA virus with a genome that encodes only two structural proteins, designated VP1 and VP2. 60 copies of the structural proteins assemble into the viral capsid, with approximately 95% VP2 and 5% VP1. Recombinant empty capsids composed of VP2 alone or of VP2 and VP1 self-assemble into particles that are morphologically indistinguishable from full virions. Empty capsids containing both VP2 and VP1 elicit a strong neutralizing antibody response when used to immunize rabbits. Capsids containing only VP2 are similarly antigenic but elicit only weak neutralizing activity. We performed fine structure epitope mapping by measuring the reactivity of antisera raised against capsids composed of VP2 and VP1 or VP2 alone against 85 overlapping peptides spanning the sequence of the two structural proteins. A profile of the antigenic difference between empty capsids with and without VP1 was produced from the resulting data. This profile divided the sequence of the structural proteins into four regions that correlated well with expected viral structures. Thus, the addition of a small number of VP1 residues altered the antigenicity of the entire capsid. The major area of enhanced antigenicity is homologous to the spike of canine parvovirus, an area known to contain both neutralizing and host-range determinants. Our data are consistent with a model in which the unique region of VP1 is necessary for the virus to assume its mature capsid conformation.     

Isolation and characterization of 'dense particles' from poliovirus-infected HeLa cells.

Dense poliovirus particles (buoyant density 1.44 g/ml in CsCl) isolated from infected HeLa cells contain the normal four structural polypeptides VP1 to VP4, and 35S poliovirus RNA. In addition, small amounts of VPo and single-stranded RNA sedimenting slower than the poliovirus genome are present. Dense particles have a low specific infectivity, are neutralized by type-specific poliovirus antisera, and are detected during growth as early as normal virus but disappear when virus production stops. They appear to represent a different, more open, conformation of the normal virus capsid.     

Binding of neutralizing monoclonal antibodies to empty capsids of poliovirus can be blocked by monospecific antisera to structural polypeptides VP1 and VP2

Summary Binding of two neutralizing monoclonal antibodies (Nt-mAbs) to natural empty capsids (NEC) of poliovirus, type 1, was blocked to the extent of 83 per cent to 98 per cent by monospecific rabbit antisera directed against the structural polypeptides VP1 and VP2. Monospecific antisera against VP3 or VP4, however, did not show this blocking effect. It is therefore assumed that VP1 and VP2 are located close together at the antigenic sites for the two mAbs.With 1 Figure     

Preparation and characterization of antisera to electrophoretically purified SA11 virus polypeptides.

Antisera to SA11 virus proteins were prepared by immunizing rabbits with individual polypeptides separated by polyacrylamide gel electrophoresis under reducing or nonreducing conditions; the resulting antisera were characterized by four immunological methods. Results of complement fixation tests with double-shelled rotavirus particles and sera raised against reduced or unreduced proteins of the outer shell of the virus suggested the presence of common antigenic determinants in the outer capsid layers of SA11 and the Northern Ireland strain of calf rotavirus. In this test, antisera to outer shell polypeptides gp34 (O2) and gp25 (O4) cross-reacted with calf rotavirions, whereas those to p62 (O1) and p26 (O3) reacted only with the homologous virus. Antisera to the reduced outer shell proteins of the virus did not neutralize viral infectivity, nor did they possess hemagglutination inhibition activity. Evidence suggesting the presence of type-specific antigenic determinant(s) in the major inner protein p42 (I4) of SA11 virus, capable of inducing neutralizing antibody, is presented and discussed. Antisera produced against unreduced gp34 and p26 polypeptides of the virus contained type-specific neutralizing antibodies. Polypeptide gp34 was also capable of inducing hemagglutination inhibiting antibody. All of the antisera to unreduced polypeptides had agglutinating activity against double-shelled particles of homologous and heterologous rotaviruses.     

Immunoreactivity of human and rabbit antisera to hepatitis A virus

Rabbit antibodies produced by immunization with complete hepatitis A virions (HAV) recognized all the viral structural proteins and neutralized HAV infectivity in cell culture. Rabbit antibodies to chromatographically purified individual viral proteins and to synthetic peptides representing epitopes on the structural viral protein VP1 neither recognized whole virus nor neutralized infectivity, indicating that native epitopes on the virus surface are necessary for virus recognition and neutralization. Human anti-HAV-positive sera of the acute and convalescent phase of disease recognized and neutralized viral particles. Analysis of the immunoreactivity of these human sera in immunoblot showed that the IgM antibody preferentially recognizes the structural viral proteins VP0 and VP3 of HAV, whereas IgA and IgG antibodies reacted more strongly with VP1.     

Antigens to viral capsid and non-capsid proteins are present in brain tissues and antibodies in sera of Theiler's virus-infected mice

Recombinant proteins to the LP, VP1, VP2, VP3, VP4, 2A, 2B, 2C, 3A, and 3D genes of Theiler's murine encephalomyelitis virus (TMEV) were generated and antibodies were produced against them for use in analysis of the TMEV epitopes responsible for eliciting the antibody responses observed during acute and chronic disease. Antibodies against recombinant VP1, VP2, and VP3 recognized the corresponding proteins from purified TMEV particles. In immunohistochemical analysis, antibodies against recombinant capsid (VP1, VP2, and VP3), and non-capsid (2A, 2C, 3A) proteins were reactive with PO-2D cells (astrocytes) infected with TMEV in vitro and with brain tissues of acutely infected mice. Antibodies against VP4, 2B, and 3D antigens were not reactive with corresponding viral proteins in infected astrocytes cells or brain tissues, but they reacted with TMEV precursor proteins produced during the early viral replication phase. Sera from SJL/J mice infected with TMEV acutely (14 days) and chronically (45 days) reacted with VP1, VP2, VP4, 2A, and 2C proteins. In an in vitro assay for neutralization, only anti-VP1 antibodies neutralized TMEV infection. These findings suggest that both capsid and non-capsid proteins of TMEV play a role in the immunopathology of the TMEV disease in the central nervous system.     

Isoelectric points of polypeptides of standard poliovirus particles of different serological types and of empty capsids and dense particles of poliovirus type 1.

The isoelectric points of polypeptides of standard and dense poliovirus particles and of empty capsids have been determined by isoelectric focusing in urea and by two-dimensional analysis. Comparing virus strains belonging to the three serological types of poliovirus, differences in the pI of some, but not all of the structural polypeptides are found. The pI of polypeptides of dense particles and of empty capsids are identical with those of standard particles. Polypeptide VPo present in empty capsids has a pI between those of VP4 and VP2.     

Detection by monoclonal antibodies of an antigenic determinant critical for poliovirus neutralization present on VP1 and on heat-inactivated virions

Hybridoma cell lines were established against poliovirus type 1 (Mahoney) heat-denatured virions (C particles). Each anti-C monoclonal antibody (McAb) immunoprecipitated specifically one of the individualized poliovirus capsid polypeptides VP1, VP2, or VP3. One of the anti-C McAb (C-3), reacting with VP1, neutralized homologous virus and immunoprecipitated infectious D particles. Its properties have been compared to those of a neutralizing anti-D McAb (D-Ic). In contrast with the C-3 antigenic site, the D-Ic epitope was not present on C particles nor on individualized structural polypeptide. This demonstrates that C-3 and D-Ic epitopes represent two independent antigenic determinants, both critical for poliovirus neutralization.     

Induction of neutralizing antibodies and immunity in vaccinated guinea pigs by cyanogen bromide-peptides of VP3 of foot-and-mouth disease virus.

The specificity of guinea pig antisera against large cyanogen bromide-cleaved peptides of the virus capsid protein VP3 of foot-and-mouth disease virus type O1, strain Kaufbeuren has been characterized by double immunodiffusion, virus neutralization and protection tests. Antibodies to purified 146S particles and the cleavage peptides of VP3 showed an incomplete cross-section against VP3 peptide antigen when reacted in immunodiffusion tests, indicating that new antigenic determinants are exhibited by the peptides which are not recognized by the antiserum against the native virus proteins. The immune response against the reduced, unfolded chain constituents of VP3 was lower in comparison to that of native virus particles but still some immunological determinants remained actively capable of inducing virus-neutralizing antibodies in immunized guinea pigs.     

Antigenic comparison of the polypeptides of foot-and-mouth disease virus serotypes and other picornaviruses

The cross-reactivity of proteins coded for by the seven serotypes of foot-and-mouth disease virus (FMDV) was assessed by reaction of infected cell lysates with polyclonal and monospecific antisera against the structural and nonstructural proteins of FMDV type A12 strain 119ab. It was shown that the homologous polypeptides from most serotypes are antigenically related. The least cross-reactivity occurred between VP1, VP3, and the protease (3C) of type A12 and South African Territories types 1 and 3. There was also a reduced degree of reactivity of A12 VP1 serum with VP1 from some A subtypes and the other serotypes. Comparison of FMDV proteins with polypeptides from other picornaviruses by a radioimmune binding assay revealed a low level of reactivity of antisera against some A12 polypeptides with encephalomyocarditis virus (EMCV) infected cell lysates but no reactivity with bovine enterovirus type 1 and swine vesicular disease virus infected cells. The same EMCV proteins were immunoprecipitated by the various reactive A12 antisera, but the reaction was abolished if the lysate from EMCV infected cells was denatured prior to immunoprecipitation.     

Capsid protein identification and analysis of mature Triatoma virus (TrV) virions and naturally occurring empty particles

Triatoma virus (TrV) is a non-enveloped + ssRNA virus belonging to the insect virus family Dicistroviridae. Mass spectrometry (MS) and gel electrophoresis were used to detect the previously elusive capsid protein VP4. Its cleavage sites were established by sequencing the N-terminus of the protein precursor and MS, and its stoichiometry with respect to the other major capsid proteins (VP1-3) was found to be 1:1. We also characterized the polypeptides comprising the naturally occurring non-infectious empty capsids, i.e., RNA-free TrV particles. The empty particles were composed of VP0-VP3 plus at least seven additional polypeptides, which were identified as products of the capsid precursor polyprotein. We conclude that VP4 protein appears as a product of RNA encapsidation, and that defective processing of capsid proteins precludes genome encapsidation.     

Characterization of three antigenic particles of swine vesicular disease virus.

Three distinct particles were isolated from cell culture harvests of swine vesicular disease virus (SVDV) by sucrose and CsCl gradient centrifugation. Virions (148S), RNA-free empty capsids (81S), and a third particle (49S) also free of RNA showed immune reactivity with SVDV antiserum. The 81S and 49S particles had polypeptides typical of naturally occurring empty capsids. Injection of purified antigens into guinea pigs produced antisera which distinguished empty capsids from virions on immunodiffusion; the 49S antigen appeared similar to virions. Antisera produced to freshly prepared virus antigen grown in brains of baby mice distinguished SVDV from the serologically related Coxsackie B-5 virus but did not distinguish the individual S particle antigens. Partly purified virus preparations degraded to empty capsids when incubated in guinea pig serum. The possible origin of empty capsids and 49S particles and their relationship to antigenicity of virus preparations are discussed.     

The open reading frame L2 of cottontail rabbit papillomavirus contains antibody-inducing neutralizing epitopes.

Polyclonal antisera were generated against bacterially derived fusion proteins of the open reading frames (ORFs) of the capsid proteins of cottontail rabbit papillomavirus (CRPV). The carboxy-terminal two-thirds of CRPV L1 and the carboxy-terminal half of CRPV L2 were cloned into a bacterial expression vector and induced proteins were used as antigen and immunogen. The polyclonal antisera were tested in a series of immunological assays, including ELISA, Western blot, and neutralization of CRPV. ELISA demonstrated that the polyclonal antisera raised against expressed L1 proteins reacted strongly to disrupted CRPV virion antigen and weakly both to intact CRPV virion and disrupted BPV-1 virion. Anti-CRPV L2 antisera reacted strongly only to intact and disrupted CRPV virion antigen. Viral capsid proteins of CRPV were detected in Western blots of HPV-11, BPV-1, and CRPV virus particles by these polyclonal antisera. The anti-L1 sera recognized the major capsid protein (60 kDa) and the anti-L2 sera identified a 76-kDa viral protein of CRPV. Only the antisera generated against expressed L2 neutralized CRPV. The neutralizing titer of the anti-L2 sera, however, was several orders of magnitude lower than the titer of a neutralizing polyclonal antiserum that was generated by immunizations with intact CRPV virions.     

Picornavirus proteins share antigenic determinants with heat shock proteins 60/65

Immunological cross-reactions between enteroviruses and islet cell autoantigens have been suggested to play a role in the etiopathogenesis of insulin dependent diabetes mellitus (IDDM). In the nonobese diabetic mouse, an autoimmune model of IDDM, one of the reactive beta cell autoantigens is the heat shock protein 60 (HSP60). These studies were prompted by sequence homology discovered between the immunogenic region in HSP60 and two regions in enterovirus capsid proteins, one in the VP1 protein and the other in the VP0, the precursor of VP2 and VP4 proteins. Possible immunological cross-reactions between enterovirus proteins and heat shock proteins were studied by EIA and immunoblotting by using purified virus preparations, viral expression proteins VP1 and VP0, and recombinant HSP60/65 proteins, and corresponding polyclonal antisera. The HSP60/65 family of proteins is highly conserved and there is a striking degree of homology between bacterial and human heat shock proteins. Rabbit antibodies to HSP65 of Mycobacterium bovis that reacted with human HSP60 were also found to recognise capsid protein VP1 of coxsackievirus A9, VP1, and/or VP2 of coxsackievirus B4. Both viruses were also recognised by antisera raised against HSP60 of Chlamydia pneumoniae. In addition to the capsid proteins derived from native virions, antisera to both bacterial HSP proteins recognised expression protein VP1 of coxsackievirus A9. The cross-reactivity was also demonstrated the other way around; antisera to purified virus particles reacted with the HSP 60/65 proteins to some extent. These results suggest that apart from the well-documented sequence homology between the 2C protein of coxsackieviruses and the beta-cell autoantigen glutamic acid decarboxylase, there are other motifs in picornavirus proteins homologous to islet cell autoantigens, which might induce cross-reacting immune responses during picornavirus infections.     

Immunological relatedness of papovaviruses of the simian virus 40-polyoma subgroup.

Viral antigens in permissive cells infected with JC virus, K virus, and SA12 virus were reactive in immunofluorescence tests to antisera against sodium dodecyl sulfate-disrupted simian virus 40 capsids and polyoma VP1. The major capsid polypeptides of all papovaviruses of the simian virus 40-polyoma subgroup are immunologically related.     

Binding site of neutralizing monoclonal antibodies obtained after in vivo priming with purified VP1 of poliovirus type 1 is located between amino acid residues 93 and 104 of VP1

Three hybridomas obtained after in vitro stimulation of spleen cells of mice primed in vivo with purified VP1 of poliovirus type 1 (Mahoney) with the homologous virus produced antibodies which reacted with VP1 and immunoprecipitated and neutralized only the homologous virus. Evidence for the location of their binding sites was obtained by inhibition of virus neutralization and virus binding by a synthetic peptide comprising the amino acid sequence 93-104 of VP1 of poliovirus type 1 (Mahoney).