Genome of porcine transmissible gastroenteritis virus.

The Purdue strain of transmissible gastroenteritis virus, a porcine coronavirus, was grown to titers of greater than 10(8) PFU/ml in a swine testicle cell line, and the RNA was isotopically labeled with [3H]uridine. The RNA was extracted from purified virus and was found to have the following properties. (i) It consisted primarily of a homogeneous large-molecular-weight species which electrophoretically migrated with an apparent molecular weight of 6.8 X 10(6) under denaturing conditions. (ii) It migrated electrophoretically at the same rate on nondenaturing gels before and after heat denaturation, suggesting that it does not consist of subunits. (iii) It was susceptible to pancreatic RNase A digestion in high (0.3 M) NaCl. (iv) It was polyadenylated to the extent that greater than 60% of the native RNA bound to oligodeoxythymidilic acid-cellulose under conditions of high (0.5 M) NaCl. RNA extracted from virions was infectious. This coronavirus can therefore be characterized as a positive-strand RNA virus.     

Characterization and translation of transmissible gastroenteritis virus mRNAs.

Three protein species were identified in purified transmissible gastroenteritis virus particles (strain Purdue). They are thought to represent constituents of the peplomer (E2; molecular weights of 280,000 and 240,000), the envelope (E1; molecular weights of 28,000, 31,500, and 33,000), and the nucleocapsid (N; molecular weight of 48,000). In infected cells, proteins with molecular weights of 195,000 (E2), 48,000 (N), and 28,000 (E1) were detected. Tunicamycin, an inhibitor of N glycosylation, prevented the appearance of polypeptides with molecular weights of 195,000 and 28,000 in infected cells; instead, proteins with molecular weights of 160,000 and 25,000 were observed. One minor and five major mRNA species were detected in porcine cells after infection. Their size was determined to be 23.6 kilobases (kb) (RNA1), 8.4 kb (RNA3), 3.8 kb (RNA4), 3.0 kb (RNA5), 2.6 kb (RNA6), and 1.9 kb (RNA7). The RNAs were translated in vitro. RNA7 was shown to code for the N protein. Although complete separation of RNA6 could not be achieved, it was shown to encode an unglycosylated (molecular weight of 25,000) precursor of E1 (molecular weight of 28,000). RNA4 was translated into a nonstructural protein with a molecular weight of 24,000. Translation of RNA3 resulted in proteins with molecular weights of 250,000 and 130,000 and smaller molecules which could be precipitated with a monoclonal antibody directed against E2.     

Antibody-selected variation and reversion in Sindbis virus neutralization epitopes.

Sindbis virus variants evidencing a complex and bidirectional tendency toward spontaneous antigenic change were isolated and characterized. Variants were selected on the basis of their escape from neutralization by individual monoclonal antibodies to either of the two envelope glycoproteins, E2 and E1. Multisite variants, including one altered in three neutralization sites, were obtained by selecting mutants consecutively in the presence of different neutralizing monoclonal antibodies. Two phenotypic revertants, each of which reacquired prototype antigenicity, were back-selected on the basis of their reactivity with a neutralizing monoclonal antibody. An incidental oligonucleotide marker distinguished these and the variant from which they arose from parental Sindbis virus and other mutants, thereby confirming that the revertants were true progeny of the antigenic variant. Prototype Sindbis virus and variants derived from it were compared on the basis of their reactivities with each of a panel of monoclonal antibodies; patterns revealed a minimum of five independently mutable Sindbis virus neutralization epitopes, segregating as three antigenic sites (two E2 and one E1).     

猪传染性胃肠炎病毒重组核衣壳(N)蛋白的纯化

通过对大肠杆菌表达,经载体pPROEXHTb克隆的TGEV重组N蛋白纯化方法中一系列条件的探索,最终得到了纯化融合蛋白的最佳优化方法。即在裂解液中含有1mM PMSF的条件下,分别经过2倍体积的bufferA和bufferB洗脱后,再收集pH5．9,含有80mM咪唑的1倍体积bufferC洗脱液,在波长280nm处检测蛋白吸收值A,再将峰值经SDS－PAGE电泳分析,可得到纯度较高的融合蛋白。     

Field trials on transmissible gastroenteritis live virus vaccine in newborn piglets.

Field trials were conducted on attenuated live virus vaccine of transmissible gastroenteritis to confer active immunity to newborn piglets. To examine innocuity and efficacy of the vaccine, a total of 714 newborn piglets were subjected to these trials. Of them, 357 piglets were administered orally with 10(7.0) TCID50 within 3 days after birth, and the other 357 piglets served as nonvaccinated controls. No undesirable postvaccinal reaction was observed in any vaccinated piglet. Suckling piglets born from nonimmune sows showed a good antibody response after vaccination. They were different, however, in antibody titer from one experimental place to another. Antibody levels were high in piglets raised in the northern experimental places. On the contrary, the antibody response of suckling piglets born from immune sows was influenced by vaccination. In most of these piglets, antibody titers declined markedly and disappeared finally 3 months after vaccination. About 25% of the non-vaccinated piglets showed an antibody response by pen contact with vaccinated ones.     

Major receptor-binding and neutralization determinants are located within the same domain of the transmissible gastroenteritis virus (coronavirus) spike protein.

The spike glycoprotein (S) of coronavirus, the major target for virus-neutralizing antibodies, is assumed to mediate the attachment of virions to the host cell. A 26-kilodalton fragment proteolytically cleaved from transmissible gastroenteritis virus (TGEV) S protein was previously shown to bear two adjacent antigenic sites, A and B, both defined by high-titer neutralizing antibodies. Recombinant baculoviruses expressing C-terminal truncations of the 26-kilodalton region were used to localize functionally important determinants in the S protein primary structure. Two overlapping 223- and 150-amino-acid-long products with serine 506 as a common N terminus expressed all of the site A and B epitopes and induced virus-binding antibodies. Coexpression of one of these truncated protein S derivatives with aminopeptidase N (APN), a cell surface molecule acting as a receptor for TGEV, led to the formation of a complex which could be immunoprecipitated by anti-S antibodies. These data provide evidence that major neutralization-mediating and receptor-binding determinants reside together within a domain of the S protein which behaves like an independent module. In spite of their ability to prevent S-APN interaction, the neutralizing antibodies appeared to recognize a preformed complex, thus indicating that antibody- and receptor-binding determinants should be essentially distinct. Together these findings bring new insight into the molecular mechanism of TGEV neutralization.     

Epitope specificity of protective lactogenic immunity against swine transmissible gastroenteritis virus.

The epitope specificity of the protective immune response against swine transmissible gastroenteritis (TGE) has been investigated by using circulating and secretory antibodies. This study was carried out with sows vaccinated with TGEV or the antigenically related porcine respiratory coronavirus (PRCV). TGEV vaccination of sows resulted in greater lactogenic protection of suckling piglets against TGEV challenge and a higher secretory immune response than PRCV vaccination did. These differences in the immune response were conditioned by the route of antigen presentation as a result of the different tropism of each virus. Epitopes on S protein, and in particular those contained in its antigenic site. A, were more immunogenic than epitopes on N and M proteins in both groups of vaccinated sows, as determined by a competitive radioimmunoassay. Minor differences in antibody response against the previously defined antigenic subsites Aa, Ab, and Ac were also detected, with subsite Ab being the most antigenic in both TGEV- and PRCV-immune sows. These findings suggest that antigenic site A on S protein, involved in virus neutralization, is the immunodominant site in pregnant sows that confer lactogenic protection. They also validate, in experiments with secretory antibodies, the antigenic maps made with murine monoclonal antibodies. Therefore, this antigenic site should be considered for vaccine or diagnostic development.     

Analysis and simulation of a neutralizing epitope of transmissible gastroenteritis virus.

The amino acid sequences recognized by monoclonal antibodies (MAbs) specific for the antigenic site IV of the spike protein S of transmissible gastroenteritis virus were analyzed by PEPSCAN. All MAbs of group IV recognized peptides from the S region consisting of residues 378 to 390. In addition, the neutralizing MAbs (subgroup IV-A) also bound to peptides from the region consisting of residues 1173 to 1184 and to several other peptides with a related amino acid composition. The contribution of the individual residues of both sequences to the binding of a MAb was determined by varying the length of the peptide and by a consecutive deletion or replacement of parental residues by the 19 other amino acids. The sequence consisting of residues 326 to 558, tested as part of a cro-beta-galactosidase hybrid protein, was antigenic, but the sequence consisting of residues 1150 to 1239 was not. Furthermore, antibodies raised in rabbits against the peptide SDSSFFSYGEIPFGN (residues 377 to 391), but not those raised against the peptide VRASRQLAKDKVNEC (residues 1171 to 1185), recognized the virus and had neutralizing activity. We infer that the epitope of the neutralizing MAbs is composite and consists of the linear sequence SFFSYGEI (residues 380 to 387) with contributions of A, D, K, N, Q, or V residues from other parts of the S molecule. The complex epitope was simulated by synthesizing peptides in which the sequences consisting of residues 380 to 387 and 1176 to 1184 were combined. MAbs of subgroup IV-A recognized the combination peptides two to six times better than the individual sequences. These results may offer prospects for the development of an experimental vaccine.     

Comparison of properties between virulent and attenuated strains of transmissible gastroenteritis virus.

Strains of transmissible gastroenteritis (TGE) virus possessing different pathogenicity were examined for stability to digestive enzymes and acid, and growth at various temperatures. In growth experiments, virus titer obtained at 37 degrees C were about equal between attenuated and virulent strains, but titers attained by the attenuated strain were higher at 30 degrees C. The attenuated virus multiplied at 28 degrees C, but the virulent virus did not at this temperature. The virulent virus was significantly stable to trypsin and pepsin, but the attenuated virus was inactivated rapidly by these proteolytic enzymes. No significant differences were observed in stability to acid between the attenuated and virulent strains. At different pH, both lost their infectivity more rapidly at 37 degrees C than at 22 degrees C.     

Unprocessed foot-and-mouth disease virus capsid precursor displays discontinuous epitopes involved in viral neutralization.

A foot-and-mouth disease virus (FMDV) cDNA cassette containing sequences encoding the capsid precursor P1, peptide 2A and a truncated 2B (abbreviated P1-2A) of type C FMDV, has been modified to generate the authentic amino terminus and the myristoylation signal. This construct has been used to produce a recombinant baculovirus (AcMM53) which, upon infection of Spodoptera frugiperda insect cells, expressed a recombinant P1-2A precursor with a high yield. This polyprotein reacted with neutralizing monoclonal antibodies (MAbs) that bind to continuous epitopes of the major antigenic site A (also termed site 1) of capsid protein VP1. Unexpectedly, it also reacted with neutralizing MAbs which define complex, discontinuous epitopes previously identified on FMDV particles. The reactivity of MAbs with P1-2A was quantitatively similar to their reactivity with intact virus and, in both cases, the reactivity with MAbs that recognized discontinuous epitopes was lost upon heat denaturation of the antigen. The finding that a capsid precursor may fold in such a way as to maintain discontinuous epitopes involved in virus neutralization present on the virion surface opens the possibility of using unprocessed capsid precursors as novel antiviral immunogens.     

Passive immunization against transmissible gastroenteritis virus in piglets by ingestion of milk of sows inoculated with attenuated virus.

Pregnant sows were inoculated with the attenuated strain, TO--163, of swine transmissible gastroenteritis virus. Suckling piglets born from them received challenge inoculation with the virulent virus at 3 days after birth, and examined for ability to prevent infection and the immunoglobulin (Ig) classes of antibody in milk. A pregnant sow was inoculated intramuscularly with a dose of 10(8.0) TCID50 and intranasally with a dose of 10(9.3) TCID50 of attenuated virus. Piglets born from it suffered from diarrhea after challenge inoculation, but none of them died eventually. Their dam was also affected with diarrhea for 4 to 7 days after challenge inoculation of them. Another pregnant sow was inoculated twice with 10(9.3) TCID50 of attenuated virus, first by the intramuscular and secondly by the intranasal route. Of nine piglets born from it, one excreted soft feces after challenge inoculation, but all survived to grow normally. Their dam manifested no clinical symptoms at all after challenge inoculation of them. The higher the titer of virus inoculated into pregnant sows, the higher the neutralizing antibody titer in serum and milk of the sows after farrowing. The puerperal sow which had received two doses of 10(9.3) TCID50 each of attenuated virus by the intramuscular and intranasal route, respectively, presented the highest neutralizing antibody titer of all the inoculated sows. This titer was 2,048 in serum and 14,183 in colostrum immediately after farrowing. In that sow IgG was the main class of immunoglobulins in neutralizing antibody in milk. Even the IgA antibody titer of that sow was higher than that of any other sow which had been administered with virus of low titer. It was 392 and 19 3 and 9 days, respectively, after farrowing.     

Entry kinetics and mouse virulence of Ross River virus mutants altered in neutralization epitopes.

Previously we identified the locations of three neutralization epitopes (a, b1 and b2) of Ross River virus (RRV) by sequencing a number of variants resistant to monoclonal antibody neutralization which were found to have single amino acid substitutions in the E2 protein (S. Vrati, C.A. Fernon, L. Dalgarno, and R.C. Weir, Virology 162:346-353, 1988). We have now studied the biological properties of these variants in BHK cells and their virulence in mice. While variants altered in epitopes a and/or b1 showed no difference, variants altered in epitope b2, including a triple variant altered in epitopes a, b1, and b2, showed rapid penetration but retarded kinetics of growth and RNA and protein synthesis in BHK cells compared with RRV T48, the parent virus. Variants altered in epitopes a and/or b1 showed no change in mouse virulence. However, two of the six epitope b2 variants examined had attenuated mouse virulence. They had a four- to fivefold-higher 50% lethal dose (LD50), although no change in the average survival time of infected mice was observed. These variants grew to titers in mouse tissues similar to those of RRV T48. The ID50 of the triple variant was unchanged, but infected mice had an increased average survival time. This variant produced lower levels of viremia in infected mice. On the basis of these findings we propose that both the receptor binding site and neutralization epitopes of RRV are nearby or in the same domain of the E2 protein.