Differential precipitation of foot and mouth disease virus proteins made in vivo and in vitro by hyperimmune and virus particle guinea pig antisera

Immunogenicity of non-structural proteins of foot-and-mouth disease virus: differences between infected and vaccinated swine

Non-structural as well as VP1 recombinant proteins of foot-and-mouth disease virus (FMDV) produced in E. coli, have been used to study the specific antibody response of infected or vaccinated swine. An analysis of sera from infected pigs, using a direct ELISA, showed that polypeptide 3ABC (spanning non-structural proteins 3A, 3B and 3C) was the most antigenic among the recombinant proteins studied and allowed specific detection of FMDV infected swine from the second week after the infection. The sensitivity of this assay was comparable to that obtained when the whole FMDV was used as ELISA antigen. Conversely, use of polypeptide 3ABC did not allow detection of significant levels of antibodies in sera from vaccinated animals. This differential pattern of ELISA reactivities offers a promising approach for the distinction of infected from vaccinated pigs. In addition, a highly specific and sensitive method of diagnosis for FMDV replication was achieved using an immunoblotting assay which detected antibodies against the 3ABC polypeptide.

Expression of the aphthovirus RNA polymerase gene in Escherichia coli and its use together with other bioengineered nonstructural antigens in detection of late persistent infections

A plasmid has been constructed containing the DNA sequences that direct the expression of the aphthovirus RNA-dependent RNA polymerase (virus infection-associated antigen, VIAA) in its native form. The aphthovirus polypeptide was designed to contain only a single additional amino acid, the N-terminal methionine. The recombinant protein has been purified and used in enzyme-linked immunoelectrotransfer blots to detect aphthovirus-specific antibodies in the sera of persistently infected animals. Furthermore, studies were carried out to test the hypothesis that antibodies against other nonstructural antigens appear in the sera of these animals. It was established that antibodies against polypeptides 3A and 3B can serve as complementary markers for late aphthovirus-carrier state detection. The considerable potential of this approach to detect aphthovirus-specific antibodies, when the isolation of infectious virus is not possible, was demonstrated. Negative results were obtained in animals from virus-free areas and in vaccinated cattle. This assay has the added advantage that no infectious or noninfectious virus is involved during antigen production.

Identification of a nucleotide deletion in parts of polypeptide 3A in two independent attenuated aphthovirus strains

A set of antisera specific for each viral polypeptide of foot-and-mouth disease virus was used to provide a full comparison of polypeptides of two strains attenuated for cattle with respect to their parental virulent strains. Both attenuated strains, belonging to serotypes O1 Campos and C3 Resende, were obtained through serial passages of the corresponding virulent strains in chicken embryos. Although mutations were scattered throughout the genome, both attenuated strains showed an electrophoretic mobility on sodium dodecyl sulfate-polyacrylamide gel electrophoresis of viral polypeptide 3A faster than that of their respective wild-type strains. To determine the nature of this alteration, the nucleotide sequences of the genomic region encoding this polypeptide were determined. Comparative sequence analysis of wild-type and attenuated strains revealed 57 and 60 nucleotide deletions in the attenuated strains O1 Campos and C3 Resende, respectively. These studies, in conjunction with our previous analysis of recombinant viruses between wild-type and attenuated strains, which concluded that the major determinants of attenuation are located in the 3' half of the viral genome, strongly suggest that the alteration in polypeptide 3A of the attenuated strains is important for their reduced virulence in cattle.

Identification of foot-and-mouth disease virus replication in vaccinated cattle by antibodies to non-structural virus proteins

Antibodies raised in cattle against foot-and-mouth disease virus by vaccination or by experimental infection were distinguished. Vaccination elicited only antibodies to virus capsid proteins and the polymerase 3D. Virus replication in cattle elicited additional antibodies directed against the non-structural proteins 2B, 2C, 3AB1, and/or 3C irrespective of prior vaccination or whether the cattle exhibited symptoms of disease. Non-permissive mice inoculated with virus responded in the same way, indicating that antibodies raised due to the transient presence of antigen are safely recognized by the method applied which was radioimmunoprecipitation. All kinds of infections were thus detected and it was possible to differentiate between cattle exposed or not exposed to challenge in the field, and further between protected animals and possible virus carriers.

Serological probes for some foot-and-mouth disease virus nonstructural proteins

Foot-and-mouth disease virus (FMDV) O1 Kaufbeuren-specific cDNA fragments were subcloned into the E. coli expression vector pRIT.2T. Fusion proteins thus produced in bacteria were purified by affinity chromatography and inoculated into rabbits. Three sera thus obtained were found to be monospecific for FMDV proteins 3A, 3C, and 3D, respectively. Two others were prevalently directed against protein 2C, but in addition, either to protein 2B or to protein 3A. Five out of six mature nonstructural virus proteins can therefore be separately investigated in FMDV-infected cells, either by indirect immunofluorescence or by radioimmunoprecipitation. Immunofluorescence shows all investigated proteins to be located exclusively in the cytoplasm. One of them, protein 2C, transiently forms aggregates at the periphery of cells. Radioimmunoprecipitation confirmed current knowledge on maturation of FMDV proteins. It was further used to characterize postinfectional sera with regard to FMDV-specific antibodies. Cattle and guinea pig were found to have responded differently to FMDV nonstructural antigens. Furthermore, antigenicity of yet to be described FMDV polypeptides was observed in the guinea pig.

A comparative study on the cell-free translation of the genomic RNAs of two aphid picorna-like viruses

The genomic RNAs of aphid lethal paralysis virus (ALPV) and Rhopalosiphum padi virus (RhPV)--two distinct picorna-like viruses found in aphids [Williamson et al. (1988) J Gen Virol 69: 787-795]--were both efficiently translated in rabbit reticulocyte lysates. ALPV RNA was translated into primary products with molecular weights ranging from 92 kDa to 170 kDa. These underwent time-dependent post-translational cleavage to produce smaller polypeptides including some with molecular weights comparable to those of the viral structural proteins. A 92 kDa polypeptide as well as smaller proteins were immunoprecipitated with capsid protein antisera, indicating the presence of at least one large capsid subunit protein precursor. RhPV RNA was translated into products of molecular weights ranging from 45 kDa to 175 kDa. There was no evidence for time-dependent post-translation cleavage of RhPV translation products. However, a 60 kDa polypeptide was precipitated with antiserum to RhPV virions, indicating that at least one capsid protein of RhPV is derived by proteolysis of a precursor protein, like those of ALPV and most other picornaviruses.

Proteolytic processing of foot-and-mouth disease virus polyproteins expressed in a cell-free system from clone-derived transcripts

All picornaviral genes are expressed as a single, large polyprotein, which is proteolytically processed into the system produces functional proteins, including viral protease 3C, which plays a major role in processing the precursor proteins. To study the function of the two putative proteases 3C and leader (L) in processing, we constructed several cDNA plasmids encoding various regions of the FMDV type A12 genome. These plasmids, containing FMDV cDNA segments under the control of the T7 promoter, were transcribed in vitro by using T7 RNA polymerase and then translated in rabbit reticulocyte lysates. The expressed FMDV gene products were identified by immunoprecipitation with specific antisera and analyzed by gel electrophoresis. The results demonstrate the following: (i) the leader protein, L, is processed from the structural protein precursor, P1, in the absence of any P2 or P3 region proteins; (ii) protein 2A remains associated with the structural protein precursor, P1, rather than the precursor, P2; (iii) the processing of the P1-2A/P2 junction is not catalyzed by 3C or L; (iv) the proteolytic processing of polyproteins from the structural P1 region (except VP4/VP2) and the nonstructural P2 and P3 region is catalyzed by 3C.

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.

Biochemical characterization of an aphthovirus type C3 strain Resende attenuated for cattle by serial passages in chicken embryos

We have compared several aspects of an aphthovirus strain attenuated for cattle (C3R-O/E) with the original strain (C3Res) from which it was derived after serial passages in chicken embryos. Biochemical differences detected by protein analysis in regular polyacrylamide gels (SDS-PAGE) and on electrofocusing gels (NEPHGE) suggest the presence of mutations throughout the genome. Changes were located in coat proteins VP1 and VP3 and in the polymerase precursor P100 (P3/ABCD). No other differences were found at the protein level by means of the techniques used. Polypeptide P100 of the attenuated strain showed a faster electrophoretic mobility in SDS-PAGE with respect to that of the wild-type strain, and the change seems to be located on its amino terminus half. Several functional differences were also found between the two viruses. Both strains grew equally well in BHK cells reaching roughly similar titers in plaque assays. However, the wild-type strain maintained its titer in cells of bovine origin (BK), whereas the titer of C3R-O/E strain decreased approximately one log in this cell system; moreover, plaques elicited by the attenuated strain were much smaller than the ones produced by C3Res. A diminution in the rate of RNA synthesis induced by C3R-O/E in BK cells compared with that of the wild-type strain was also detected; this trait was not observed in BHK cells. A delay in the kinetics of RNA synthesis was also detected in this strain. The virus yield of attenuated strain in BK cells was four times lower than in BHK cells.

Cytoskeletal association of an aphthovirus-induced polypeptide derived from the P3ABC region of the viral polyprotein

Monolayers of BHK cells infected with aphthovirus (FMDV) were labeled for short times with [35S]methionine at 2 hr p.i. and fractionated by detergent treatment and low speed centrifugation. Polyacrylamide gel analysis showed an asymmetric distribution of the FMDV-induced polypeptides among the three different subcellular fractions obtained. Polypeptide P88-1, the viral capsid protein precursor, is mainly found in the soluble cytoplasmic extract while polypeptides P100-3, P52-2AC, P34-2C, and P14-2A are the major viral components of a detergent soluble extract of the crude nuclear pellet. Analysis of the detergent resistant fraction (DRF), which is mainly composed of cell nuclear chromatin and insoluble cytoskeletal elements, shows a clear enrichment in an incompletely characterized polypeptide which is tentatively designated P54. Variable amounts of polypeptides P100-3 and those of the P72 complex are also detected in this fraction. The preferential location of P54 in an equivalent subcellular fraction obtained by mild detergent treatment of infected monolayers in situ, and also in a high-salt resistant subfraction of the DRF, strongly suggests a close association of this polypeptide with vimentin-actin containing components of the cell. Polypeptide P54 is immunoprecipitated by viral specific antiserum from convalescent guinea pigs but not by serum against FMDV capsid proteins, indicating that it does not share common antigenic determinants with polypeptides processed from the viral capsid precursors. On the other hand, protease V8 mapping of polypeptides P100-3, P54, P88-1, and VP1-3 shows that P54 derived from the 3' end coding region of the viral genome. Further analysis by limited protease digestion also demonstrates that P54 has partial overlap with P72-3CD while it does not share any common peptide with P56a-3D, indicating that P54 contains the sequences coded in the 3ABC region of the FMDV RNA. This assumption is reinforced by the basic behavior shown by P54 in two-dimensional gels. The results support the hypothesis of a close intracellular interaction of a short-lived polypeptide, containing the viral protease and VPg sequences, with the host cytoskeleton, during infection of BHK cells with FMDV.

Further characterization of a morphogenetic mutant of the foot-and-mouth disease virus

In this paper we describe further characterization of a foot-and-mouth disease virus (FMDV) temperature-sensitive mutant, ts 139. This mutant was very sensitive to heat inactivation, suggesting that its viral particles are somehow altered. The electrophoretic analysis of ts 139 structural proteins indicated that VP2 has an altered mobility. Furthermore, two known protein precursors of VP2, VP0 and p88, were shown to be altered, as was p64, which supports a VP2 precursor role for p64. The ts 139 viral particle assembly pathway was analyzed during viral replication. The empty-capsid to complete-viral-particle ratio was clearly increased compared to that found for the wt strain, indicating an alteration in the morphogenetic process. This encouraged us to search for the presence of possible viral precursors of low sedimentation coefficient which have not been described previously in aphthovirus-infected cells. Analysis of the viral morphogenetic process in ts 139-infected cells demonstrated the presence of viral complexes formed by VP0, VP1 and VP3 which sedimented slightly faster than a 12 S marker. The protein composition, the sedimentation coefficient of this complex and the pulse-chase results strongly suggest that it is a morphogenetic precursor of the mature viral particle.

Foot-and-mouth disease virus-induced RNA polymerase is associated with Golgi apparatus

Electrophoretic analysis of the Golgi apparatus isolated by differential centrifugation from radiolabeled cells infected with foot-and-mouth disease virus showed about 10 protein bands. The virus-induced RNA polymerase was identified by immunoprecipitation and electron microscope staining procedures. Pulse-chase experiments indicated that the polymerase passed through the Golgi apparatus in less than 1 h.

Biochemical characterization of an aphthovirus type 0(1) strain campos attenuated for cattle by serial passages in chicken embryos

The biochemical properties of a virulent and an attenuated strain of foot-and-mouth disease virus (FMDV) Type 0(1) Campos (0(1)C) were compared in order to establish differences that could account for their altered biological functions. The avirulent strain (0(1)C-O/E) was derived from the virulent strain 0(1)C by serial passages in chicken embryos. Analysis of the RNase T1-generated oligonucleotides of the viral RNA through one- and two-dimensional (2D) gel electrophoresis (fingerprints) revealed a few changes in the genome structure of the 0(1)C-O/E strain compared to the wild type strain. In addition there was a significant decrease in the length of the poly(C) rich tract of the 0(1)C-O/E RNA. All virion structural proteins, except VP4, their precursors, and the viral RNA polymerase (p56a) show charge differences. In addition a significant decrease in the apparent molecular weight of polypeptide p100 (primary translational product from the 3' end region of the genome) of the attenuated strain was observed.

Molecular cloning and nucleotide sequence of rat lingual lipase cDNA

Purified rat lingual lipase (EC3113), a glycoprotein of approximate molecular weight 52,000, was used to generate polyclonal antibodies which were able to recognise the denatured and deglycosylated enzyme. These immunoglobulins were used to screen a cDNA library prepared from mRNA isolated from the serous glands of rat tongue cloned in E. coli expression vectors. An almost full length cDNA clone was isolated and the nucleotide and predicted amino acid sequence obtained. Comparison with the N-terminal amino acid sequence of the purified enzyme confirmed the identity of the cDNA and indicated that there was a hydrophobic signal sequence of 18 residues. The amino acid sequence of mature rat lingual lipase consists of 377 residues and shares little homology with porcine pancreatic lipase apart from a short region containing a serine residue at an analogous position to the ser 152 of the porcine enzyme.

Multiple proteases in foot-and-mouth disease virus replication

Translation of foot-and-mouth disease virus RNA in a rabbit reticulocyte lysate for short time intervals resulted in the production of the peptides P20a , P16, and P88 (Lab, Lb, and P1) (R. R. Rueckert , Recommendations of the 3rd European Study Group on Molecular Biology of Picornavirus, Urbino , Italy, 1983). If further translation was prevented, the structural protein precursor P88 was not cleaved, even after prolonged incubation. This result indicates that the mechanism of the cleavage between P20a -P16 and P88 and of that between P88 and P52 (P2) differs from the mechanism of the secondary cleavages which produce the structural proteins. Furthermore, treatment of foot-and-mouth disease virus-infected cells with the protease inhibitor D-valyl phenylalanyl lysyl chloromethyl ketone prevented the in vivo cleavage between P20a -P16 and P88 but had no effect on any of the other cleavage events. These results suggest that the cleavage of the foot-and-mouth disease virus polyprotein utilizes two different host proteases.

Biologically active protease of foot and mouth disease virus is expressed from cloned viral cDNA in Escherichia coli

Foot and mouth disease virus O1K cDNA had been cloned in Escherichia coli. Here we report on in vitro recombination of cDNA fragments according to the cDNA restriction map and on expression of viral proteins in E. coli. Use was made of the expression vector pPLVP1 , which is known to express the virus capsid protein VP1. Recombined cDNAs of various sizes were inserted downstream from the VP1 gene. The constructed plasmids differ from each other in the number of virus genes coding for nonstructural proteins. The effects caused by their expression in E. coli are compared. It is shown that the virus protease is expressed in E. coli as an active enzyme that recognizes the simultaneously produced virus-specific polyprotein as substrate. The virus protease gene was mapped 5'-adjacent to the virus replicase gene.

Biochemical map of polypeptides specified by foot-and-mouth disease virus

Pulse-chase labeling of foot-and-mouth disease virus-infected bovine kidney cells revealed stable and unstable viral-specific polypeptides. To identify precursor-product relationships among these polypeptides, antisera against a number of structural and nonstructural viral-specific polypeptides were used. Cell-free translations programmed with foot-and-mouth disease virion RNA or foot-and-mouth disease virus-infected bovine kidney cell lysates, which were shown to contain almost identical polypeptides, were immunoprecipitated with the various antisera. To further establish identity, some proteins were compared by partial protease digestion. Evidence for a membrane association of the polypeptides coded for by the middle genome region is also presented. A biochemical map of the foot-and-mouth disease virus genome was established from the above information.

In vitro morphogenesis of foot-and-mouth disease virus

Foot-and-mouth disease virion RNA is translated efficiently and completely in a rabbit reticulocyte lysate cell-free system. Treatment of cell-free lysates with monospecific serum prepared against the individual viral structural proteins or with monoclonal antibodies prepared against the inactivated virus or against a viral structural protein precipitated all of the structural proteins, suggesting that structural protein complexes were formed in vitro. Sucrose gradient analysis of the cell-free lysate indicated that complexes sedimenting at 5, 14, 60 to 70, and ca. 110S were assembled in vitro. Structural proteins VP0, VP1, and VP3 were the major polypeptides found in these complexes. The material sedimenting at 110S, i.e., containing VP0, VP1, and VP3, was precipitated by a 140S-specific monoclonal antibody but not by a 12S subunit-specific monoclonal antibody, suggesting that this capsid structure contained at least one epitope present on the intact virus.

Structure of the FMDV translation initiation site and of the structural proteins

A cDNA clone of Foot and Mouth Diseases Virus (FMDV), strain C1, has been sequenced. The limits of the structural genes were defined by comparison with the available protein data. We identified two potential translation initiation sites for the viral polyprotein separated by 84 nucleotides. We suggest that these two initiation sites could be used to express two proteins differing only at the N-terminal, P16 and P20a. This model is supported by the fact that antiserum against a bacterially synthesized polypeptide corresponding to the anterior region of the polyprotein precipitates specifically both P16 and P20a. Comparison of the C1 sequence with two other serotypes, O1K and A10 revealed variability in the major immunogenic structural protein, VP1, and also in two other capsid proteins, VP2 and VP3. P16/P20a, VP4, and the N-terminal part of the precursor of the nonstructural genes, P52, are rather conserved between the different FMDV strains.

A tandem repeat gene in a picornavirus

Three closely related genes for the small genome-linked protein (VPg) of picornaviruses have been identified by sequence analysis as a tandem repeat in the genome of Foot and Mouth Disease Virus (FMDV), strain O1K. This unusual structure was also found in the genome of strain C1O, belonging to a different FMDV serotype. Predicted biochemical properties of the three VPg gene products are in excellent agreement with the data from protein analysis of a heterogeneous VPg population from a third FMDV serotype, strain A10 (1). Taken together, these data indicate that the VPgs from all three genes function equally well in vivo. This is the first report of a tandem repeat gene in a viral genome.

Molecular cloning and nucleotide sequence of cDNA coding for calf preprochymosin

DNA complementary to calf stomach mRNA has been synthesised and inserted into the Pst1 site of pAT153 by G-C tailing. Clones containing sequences coding for prochymosin were recognised by colony hybridisation with cDNA extended from a chemically synthesised oligodeoxynucleotide primer, the sequence of which was predicted from the published amino acid sequence of calf prochymosin. Two clones were identified which together contained a complete copy of prochymosin mRNA. The nucleotide sequence is in substantial agreement with the reported amino acid sequence of prochymosin and shows that this protein has a mol.wt. of 40431 and chymosin a mol.wt. of 35612. The sequence also indicates that prochymosin is synthesised as a precursor molecule, preprochymosin, having a 16 amino acid hydrophobic leader sequence analogous to that reported for other secreted proteins.