Proteins specified by African Swine Fever virus

African Swine Fever virus infected MS cells labeled with radioactive 14C-amino acids, 32Pi or [3H]-glucosamine were examined by high resolution sodium dodecylsulfate polyacrylamide gel electrophoresis and showed 43 infected cell polypeptides. Twenty-one of these proteins were present in the nuclear fraction of infected cells. At least 22 of the infected cell polypeptides induced antibodies during natural infections in swine. The pattern of infected cell polypeptides modified by incorporation of showed prosthetic groups that at least 8 polypeptides were phosphorylated and at least three specific viral glycoproteins (A, B and C) were detected by immunoprecipitation. The most highly glycosylated polypeptide corresponds to the structural viral protein VP51.     

Epitopic diversity of African swine fever virus

African swine fever (ASF) is caused by an icosahedral cytoplasmic, double stranded DNA virus. In the acute form of the disease, pigs die from disseminated intravascular coagulation (DIC) with extensive damage of the free and fixed macrophage systems and the reticular epithelial cells of the thymus; mortality is virtually 100%. In recent years, subacute and chronic forms of ASF have become more prevalent in the field, especially in outbreaks occurring outside the continent of Africa, and virus isolated from these outbreaks have often been of lesser virulence. In pigs experimentally infected with such isolates, a number of immunopathological manifestations have been encountered, e.g. hypergammaglobulinemia associated with necrotizing pneumonia, persistent infection in the presence of ASF-specific antibodies, and lack of demonstrable virus neutralizing antibodies. Nevertheless, the immune systems of pigs that have clinically recovered have not been impaired by the infection. We suggest that the heterogeneous composition of the virus population in a given isolate may be one of the causes of the anomalous immune responses. When a number of biological markers, i.e., hemadsorption characteristics, plaque size, infectivity, virulence, antigenic determinants, and genomic structure, were used to characterize the virus clones derived from various ASF virus (ASFV) isolates, considerable heterogeneity was apparent. In the present investigation, 20 monoclonal antibodies (MAb), which specifically identified the 14 kDa viral protein within the cytoplasmic membrane of the infected cells, were used to determine epitopic differences among a number of virus clones derived from various isolates. All of the non-African isolates examined contained two epitopically different groups of virus clones, and the reaction profiles obtained were distinctly different from those obtained with the clones of an African isolate (Tengani). It was concluded that an ASFV isolate is composed of a biologically diverse virus population with distinctly different members which are only identified after cloning.     

Proteins specified by African swine fever virus

Infection of MS cells with African swine fever virus (ASFV) produces inhibition of protein synthesis which is detectable from 4.5 hours after infection. At least 34 viral polypeptides have been indentified with molecular weights ranging between 9500 and 243,000 daltons. Three of these proteins show affinity for the cell nucleus and nine are in both the nuclear and cytoplasmic fractions. Ten early proteins were found, and most of the structural proteins were late proteins. Most of the proteins are synthesized within the first 8 hours after infection. At least nine proteins induced antibodies in the natural infection. Six of these proteins are structural proteins. The antigenic determinants of VP172, VP162, VP146, VP73, VP34, and IP23.5 are in the primary structure of the proteins.     

Proteins specified by African swine fever virus

Summary At least 28 polypeptides have been identified in intracellular virus, with molecular weights ranging from 11,500 to 243,000 daltons. By treatment with Nonidet P-40 and 2-mercaptoethanol it is possible to obtain subviral particles that have lost some proteins and have a density in CsCl of 1.31 g/cm³ which is higher than that of the complete virus (1.23 g/cm³). After addition of NaCl the virus loses its major protein VP73 which indicates that it is localized in the viral envelope. Cores obtained after this treatment are made up of at least 14 proteins. Incorporation of³H-fucose and³H-glucosamine in intracellular virus occurs in three minor components. The protein VP42 is possibly the cell actin and appears to be strongly associated with the virus. It is not possible to eliminate it under conditions where the viral envelopes desappear morphologically. At least the proteins VP172, VP162, VP146 and VP73 act as antigens in the natural infection.With 5 Figures     

Polypeptides and structure of African swine fever virus

Extracellular and intracellular African swine fever virus (ASFV) was purified using a two-phase aqueous polymer system. Both the structure of the virus and the polypeptides present during the purification procedure were studied. After PEG/dextran phase separation and centrifugation through 20% (w/v) Ficoll, 79% of input infectivity was recovered as semi-purified virus. The density of the virus after equilibrium centrifugation in sucrose was 1.19 g/ml. The envelope of the virion consisting of a unit membrane was removed from the virion after centrifugation in sucrose. Removal of envelope was associated with the loss of a 230 kilodalton (kd) glycoprotein from the virion. Disruption of the viral surface structure resulted in a loss of infectivity. Eighteen of the most prominent of the 33 polypeptides of extracellular or cell free (CF) virus were those with molecular weights of 230, 195, 165, 155, 150, 125, 116, 97, 92, 73, 62, 58, 50, 45, 35, 33, 25 and 11 kd, while the fourteen most prominent polypeptides in intracellular or cell associated (CA) virus were 103, 97, 92, 84, 73, 62, 58, 54, 47, 45, 35, 33, 25 and 17 kd. The 45 kd polypeptide may be actin which copurifies with the virus. No major differences were found in the number or size of proteins among three isolates of ASFV. Electron micrographs of thin sections of ASFV show the capsid to consist of a distinct double layer of closely packed capsomeres enclosed on both sides with a semi-transparent layer. Cell associated virus measured from side-to-side 188 nm and vertex-to-vertex 212 nm. The capsid encloses an inner core composed of a dense nucleoid surrounded by a 40-48 nm layer of core protein.     

Interaction of African swine fever virus with macrophages

Morphological data obtained by electron microscopy have shown that African swine fever virus adapted to VERO cells enters swine macrophages, its natural host cell, by a mechanism of receptor-mediated endocytosis. Binding studies with 3H-labeled virus and competition experiments with UV-inactivated virus have shown that the virus entry that leads to a productive infection in swine macrophages is mediated by saturable binding sites on the plasma membrane. The virus also penetrated into rabbit macrophages that do not produce infectious virus and initiated the synthesis of some early viral proteins; however, the viral replication cycle was aborted since viral DNA synthesis did not occur. The interaction of ASF virus particles with rabbit macrophages was mediated by nonsaturable binding sites, suggesting that the lack of specific receptors in these cells may be related to the absence of a productive infection. A similar abortive infection was detected in macrophages from other virus-resistant animal species.     

Glycosylated components of African swine fever virus particles

Extracellular African swine fever (ASF) virus particles were specifically agglutinated by several lectins, suggesting the presence of surface glycosylated component(s) containing at least glucose, mannose, or both; galactose, N-acetylgalactosamine, or both; N-acetylneuraminic acid and N-acetylglucosamine, but not fucose. When virions were purified from infected Vero cells labeled with [14C]glucosamine, [14C]galactose and analyzed by polyacrylamide gel electrophoresis, no major structural glycoproteins were detected. However, several species of glycolipids were found when virions were extracted with organic solvents and analyzed by thin layer chromatography. These, plus two minor glycosylated structural components, of apparent mol wt 230K and 95K, could account for the agglutination of ASF virions with concanavalin A.     

Molecular cloning of African swine fever virus DNA

African swine fever virus DNA (about 170 kbp) was cleaved with the restriction endonuclease EcoRI and most of the resulting 31 fragments were cloned in either the phage vector λWES.λB or the plasmid pBR325. Three fragments were not cloned in those vectors, the largest fragment EcoRI-A (21.2 kbp) and the two crosslinked terminal fragments, EcoRI-K′ and D′. Endonuclease SalI cut fragment EcoRI-A into three pieces which were cloned in plasmid pBR322. The two terminal EcoRI fragments were cloned after removal of the crosslinks with nuclease S1 and addition of EcoRI linkers to the fragment ends. The complete library of the cloned fragments accounted for about 98% of ASF virus genome, the missing sequences being those removed by the nuclease S1 in the process of cloning the terminal fragments.     

Protein kinase activity in African swine fever virus

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DNA-binding proteins specified by African swine fever virus

[35S]Methionine-labeled proteins from total or cytoplasmic extracts of Vero cells infected with African swine fever virus were chromatographed on native and denatured DNA-cellulose and DNA-binding proteins were analyzed by SDS-polyacrylamide gel electrophoresis (SDS-PAGE), by DNA binding to Western blots, or by two-dimensional electrophoresis. Thirteen virus-specific DNA-binding proteins were detected by one-dimensional analysis. Major species have molecular mass 44,000 (44K), 38K, 20K, 18K, 14K, 13K, and 12K. The remaining DNA-binding proteins are proteins with molecular mass 130K, 110K, 35K, 33K, 17K, and 14.5K. When viral DNA used in the binding assay the results were very similar but the 13K protein did not bind viral DNA. Seven other minor virus-specific DNA-binding proteins could be detected by two-dimensional analysis. This technique also enabled the assignment of virus-specific proteins. Seven of the virus-specific DNA-binding proteins are structural proteins. Twelve are late proteins, the remaining being early proteins synthesized before viral DNA replication. Most of the virus-specific DNA-binding proteins bind both to double-stranded and to single-stranded DNA. The 110K, 29K, and 18K DNA-binding proteins bind only to single-stranded DNA. Two virus-specific enzymatic activities, DNA polymerase and RNA polymerase, were present in the fractions separated by DNA-cellulose chromatography. The virus-specific single-stranded DNA nuclease did not bind to DNA.     

African swine fever virus replication in porcine lymphocytes

Purified preparation of porcine lymphocytes were infected with three isolates of virulent African swine fever virus (ASFV). Electron microscopy showed the presence of small numbers of mature virus particles in degenerating cells. The titres of infective virus released were low and reached a maximum by 24 h after infection.     

DNA-dependent RNA polymerase in African swine fever virus

African swine fever (ASF) virus has a DNA-dependent RNA polymerase activity which does not require the addition of exogenous DNA. The polymerase activity copurifies with ASF virus and reaches a maximum specific activity value of 5–15 pmol UMP/μg of virus protein, when the virus particles are pretreated with NP-40. In vitro RNA synthesis by ASF virus requires higher concentrations of ATP than of GTP or CTP. The RNA product has a sedimentation rate of 6–14 S and anneals specifically with virus DNA.     

Restriction site map of African swine fever virus DNA

Treatment of African swine fever virus DNA (about 170 kbp) with the restriction endonucleases SalI, EcoRI, KpnI, PvuI, and SmaI yielded 14, 31, 17, 13, and 11 fragments, respectively. The order of the restriction fragments produced by each nuclease was established by identifying the crosslinked EcoRI and SalI terminal fragments and then finding overlapping fragments. The five restriction fragment maps were integrated into a single map by locating SalI, KpnI, PvuI, and SmaI sites in cloned EcoRI fragments, and orienting each fragment in the overall map.     

Association of African swine fever virus with the cytoskeleton

The association of African swine fever virus (ASFV) with the cytoskeleton was investigated. Immunofluorescent studies of ASFV infected cells with anti-ASFV serum showed a temporal and spatial development of viral inclusions which moved from a peripheral to a perinuclear location and fused to give a single large perinuclear factory. The migration and fusion of viral inclusions was inhibited by colchicine suggesting a function for microtubules in assembly site organization not previously described. Accumulation of virions outside the inclusions and inhibition of viral release was also observed in colchicine treated cells. Viral antigens and structural elements were retained on the cytoskeleton fraction of Triton X-100 extracted cells. Reorganization of cytoskeletal elements around the assembly sites was demonstrated by transmission electronmicroscopy and by immunofluorescent studies using monoclonal antibodies against actin, tubulin and vimentin. Intermediate filaments accumulated around the viral factories, microtubules were greatly decreased in number and microfilaments were reorganized in association with the plasma membrane. Bundles of 15 nm tubules of unknown origin were also observed around the assembly sites. The distribution of viral proteins in soluble, cytoskeleton and detergent insoluble nuclear fractions was studied by pulse-chase experiments with [35S]methionine. SDS-PAGE analysis showed the presence in the cytoskeletal and nuclear fractions of 150, 72, 38, 28, 19 and 15 kDa virus structural proteins which increased after a 5 h chase. Our results indicate a close association of ASFV replication with the cytoskeleton similar to events described during FV3 replication but which differ from those occurring in poxvirus-infected cells.     

Vaccinia virus-mediated expression of African swine fever virus genes

Bacteriophage lambda and plasmid clones containing African swine fever virus (ASFV) DNA inserts, which together covered more than 90% of the genome of a Malawi ASFV isolate (LIL 20/1), were transfected into vaccinia virus (VV)-infected cells. Expression of ASFV-encoded proteins was assayed at late times after VV infection by immunoprecipitation of [35S]methionine-labeled proteins with hyperimmune serum from ASFV-infected pigs, separation of immunoprecipitated proteins by denaturing polyacrylamide gel electrophoresis, and detection by autoradiography. Synthesis of eight additional proteins not observed in control experiments was detected. Seven VV recombinants were constructed, each containing an ASFV DNA insert from a separate bacteriophage lambda clone ranging in size from 9 to 15 kb. BSC40 cells were infected with recombinant viruses and expression of ASFV-encoded proteins assayed at early and late times postinfection. Synthesis of additional proteins, not observed in control experiments, was detected by immunoprecipitation with ASFV antiserum both early and late postinfection with two of these recombinants. In these experiments VV promoters were not included upstream of individual ASFV genes.     

Immune reactions to the African swine fever virus]

Host immune reactions to African swine fever virus variants differing in their virulence were studied comparatively. Their obvious variabilities in antibody induction to some polypeptides active in antibody-dependent cell cytotoxicity and cytotoxic T-lymphocytes were demonstrated. T-helpers of immune pig splenocytes were found to recognize the cells infected with avirulent but not virulent virus variants. The described differences were not connected with the changes in SLA-1 antigen expression in the infected cells but correlated with induction of host resistance, chronic or acute course of the disease with fatal outcome.     

Nucleoside triphosphate phosphohydrolase activities in African swine fever virus

Archives of Virology - African swine fever virus contains nucleoside triphosphate phosphohydrolase activity which releases32P phosphate from γ-32P ATP at a rate of about 1 µmol/h mg of...