Interaction of Structural Glycoprotein E2 of Classical Swine Fever Virus with Protein Phosphatase 1 Catalytic Subunit Beta (PPP1CB)

Classical swine fever virus (CSFV) E2 protein, the major virus structural glycoprotein, is an essential component of the viral envelope. E2 is involved in virus absorption, induction of a protective immune response and is critical for virulence in swine. Using the yeast two-hybrid system, we identified protein phosphatase 1 catalytic subunit beta (PPP1CB), which is part of the Protein Phosphatase 1 (PP1) complex, as a specific binding host partner for E2. We further confirmed the occurrence of this interaction in CSFV-infected swine cells by using two independent methodologies: Co-immunoprecipitation and Proximity Ligation Assay. In addition, we demonstrated that pharmacological activation of the PP1 pathway has a negative effect on CSFV replication while inhibition of the PP1 pathway or knockdown of PPP1CB by siRNA had no observed effect. Overall, our data suggests that the CSFV E2 and PPP1CB protein interact in infected cells, and that activation of the PP1 pathway decreases virus replication.

Establishment and characterization of a chimeric infectious cDNA clone of classical swine fever virus

Classical swine fever virus (CSFV) causes a highly contagious disease among swine that has an important economic impact worldwide. There are two important CSFV strains in China, Shimen and hog cholera lapinized virus (HCLV). Shimen strain is highly virulent while HCLV, also referred to as C-strain, is a live attenuated vaccine strain considered to be one of the most effective and safest live vaccines. In this study, a chimeric infectious cDNA clone of CSFV named pT7SM-c was engineered by replacing the E(rns) genomic region of an infectious clone of CSFV Shimen strain, pT7SM, with the same region obtained from HCLV. RNA transcripts of pT7SM-c containing an engineered EcoRI site that served as a genetic marker were directly infectious in PK15 cells. The rescued virus vT7SM-c showed similar growth kinetics and cytopathic effect with the parental virus vT7SM in the cells. The chimeric infectious cDNA clone can be used as a practical tool for further studying of the virulence, protein function and pathogenesis of CSFV through genetic manipulation.

Quantitative assessment of the likelihood of the introduction of classical swine fever virus into the Danish swine population

Classical swine fever virus (CSFV) is a major infectious-disease agent of livestock and causes production losses through increased morbidity and mortality, particularly of young pigs. We identified the pathways for introduction of CSFV into Denmark and assessed the annual probability of introduction (based on a US Department of Agriculture model). We developed pathways based on material from scientific articles, reports from veterinary agencies and custom officers, and consultations with experts in the field. Returning livestock trucks and legal meat imports were the most important pathways for CSFV introduction to Denmark from other EU states with predicted overall likelihood of one or more introductions of CSFV within a median of 130 years (46-280) provided mitigating steps, such as cleaning trucks, were maintained to a very high standard. The likelihood would increase dramatically if these activities were abandoned: one or more introductions within a median of 5.2 years (2-14). The predicted risks from live-animal imports and semen were extremely low given the very few imports of these products. The most important countries for Denmark's CSFV risk are Germany and the Netherlands, though this risk is again predicted to be dramatically reduced as long as mitigating activities are maintained. We predicted the risk from illegal movements of pork into Denmark to be low because little pork enters through this route and only a small fraction of this pork would be fed to pigs.

N-linked glycosylation status of classical swine fever virus strain Brescia E2 glycoprotein influences virulence in swine

E2 is one of the three envelope glycoproteins of classical swine fever virus (CSFV). Previous studies indicate that E2 is involved in several functions, including virus attachment and entry to target cells, production of antibodies, induction of protective immune response in swine, and virulence. Here, we have investigated the role of E2 glycosylation of the highly virulent CSFV strain Brescia in infection of the natural host. Seven putative glycosylation sites in E2 were modified by site-directed mutagenesis of a CSFV Brescia infectious clone (BICv). A panel of virus mutants was obtained and used to investigate whether the removal of putative glycosylation sites in the E2 glycoprotein would affect viral virulence/pathogenesis in swine. We observed that rescue of viable virus was completely impaired by removal of all putative glycosylation sites in E2 but restored when mutation N185A reverted to wild-type asparagine produced viable virus that was attenuated in swine. Single mutations of each of the E2 glycosylation sites showed that amino acid N116 (N1v virus) was responsible for BICv attenuation. N1v efficiently protected swine from challenge with virulent BICv at 3 and 28 days postinfection, suggesting that glycosylation of E2 could be modified for development of classical swine fever live attenuated vaccines.

Identification of a novel virulence determinant within the E2 structural glycoprotein of classical swine fever virus

Classical swine fever virus (CSFV) E2 glycoprotein contains a discrete epitope (TAVSPTTLR, residues 829-837 of CSFV polyprotein) recognized by monoclonal antibody (mAb) WH303, used to differentiate CSFV from related ruminant pestiviruses, Bovine Viral Diarrhea Virus (BVDV) and Border Disease Virus (BDV), that infect swine without causing disease. Progressive mutations were introduced into mAb WH303 epitope in CSFV virulent strain Brescia (BICv) to obtain the homologous amino acid sequence of BVDV strain NADL E2 (TSFNMDTLA). In vitro growth of mutants T1v (TSFSPTTLR), T2v (TSFNPTTLR), T3v (TSFNMTTLR) was similar to parental BICv, while mutants T4v (TSFNMDTLR) and T5v (TSFNMDTLA) exhibited a 10-fold decrease in virus yield and reduced plaque size. In vivo, T1v, T2v or T3v induced lethal disease, T4v induced mild and transient disease and T5v induced mild clinical signs. Protection against BICv challenge was observed at 3 and 21 days post-T5v infection. These results indicate that E2 residues TAVSPTTLR play a significant role in CSFV virulence.

Neuropathologic study of experimental classical swine fever

The aim of this study was to report on the lesions occurring in the central nervous system (CNS) during experimental classical swine fever (CSF) to clarify the spatial and chronologic distribution of the lesions and virus antigen in the CNS. To learn more about the pathogenetic mechanisms of the lesions during CSF in the CNS and to investigate the role of the virus in these mechanisms, cellular infiltrates and infected cells have been characterized. Twenty-eight pigs were inoculated with the virulent CSF virus isolate Alfort 187 and slaughtered from 2 to 15 postinoculation days; 4 animals of similar background served as a control group. Immunohistochemistry, electron microscopy, and the transferase-mediated deoxyuridine triphosphate nick-end labeling method were used to detect viral antigens and apoptosis. The results showed the presence of nonpurulent meningoencephalitis, occasional microhemorrhages, and apoptosis of the lymphocytes forming the perivascular and interstitital infiltrate in swine with CSF. Macrophages appeared to display little involvement in CNS lesions. The infected cells observed at the early stage of disease were lymphocytes and microglial cells in the rostral portion of the telencephalon, with infection of these cells in other areas in the next stages. The relationship between these lesions and the presence of viral antigen varied according to the type of lesion: hemorrhages were not associated with the presence of antigen in endothelial cells, but infiltrate-cell apoptosis was temporally and spacially associated to viral infection. However, the link between viral infection and the presence of cell infiltrate was far from clear.

Characterisation of the discrepancy between PCR and virus isolation in relation to classical swine fever virus detection

In order to confirm and characterise further the discrepancies observed between diagnostic RT-nPCR and virus isolation results for the detection of classical swine fever virus (CSFV), a test panel of three new RT-PCRs was designed, amplifying parts of the NS2, NS3 and NS5A regions. Screening of negative samples by virus isolation with the new panel not only confirmed the discrepancies previously observed but also indicated that these were not associated with a specific genomic region. However, none of the PCR-positive samples were positive on all the different PCRs and preferential amplification was not obtained even when a more sensitive real-time RT-PCR was used. Furthermore, the primer-dependent amplification, most likely caused by the presence of viral fragments, demonstrates the necessity of confirming a single positive PCR result, certainly in the presence of contradictory virus isolation results. The new PCR panel, in combination with sequencing, can be used as a tool to provide additional information on the nature of the viral RNA present in the sample.

The E2 glycoprotein of classical swine fever virus is a virulence determinant in swine

To identify genetic determinants of classical swine fever virus (CSFV) virulence and host range, chimeras of the highly pathogenic Brescia strain and the attenuated vaccine strain CS were constructed and evaluated for viral virulence in swine. Upon initial screening, only chimeras 138.8v and 337.14v, the only chimeras containing the E2 glycoprotein of CS, were attenuated in swine despite exhibiting unaltered growth characteristics in primary porcine macrophage cell cultures. Additional viral chimeras were constructed to confirm the role of E2 in virulence. Chimeric virus 319.1v, which contained only the CS E2 glycoprotein in the Brescia background, was markedly attenuated in pigs, exhibiting significantly decreased virus replication in tonsils, a transient viremia, limited generalization of infection, and decreased virus shedding. Chimeras encoding all Brescia structural proteins in a CS genetic background remained attenuated, indicating that additional mutations outside the structural region are important for CS vaccine virus attenuation. These results demonstrate that CS E2 alone is sufficient for attenuating Brescia, indicating a significant role for the CSFV E2 glycoprotein in swine virulence.

[Cultivation of the vaccine strain of the virus of porcine classic plague]

Several cell cultures were compared and examined for their capability to support reproduction of Classical Swine Fever Virus (CSFV). Experimental conditions of virus cultivation were optimized. The subculture of primary lamb testicular (LT) cells was selected for large cell cultivation of CSFV. In contrast to many cell lines, these cells were free of Bovine Viral Diarrhea Virus (BVDV) contamination partly due to liquid nitrogen storage and gamma-ray sterilization of serum used in the growth media. The vaccine strain CS of CSFV was obtained in the titers of 6.7-7.7 TCID50/ml under the optimal conditions of virus reproduction in the LT cells.

Influence of a 12-nt insertion present in the 3' untranslated region of classical swine fever virus HCLV strain genome on RNA synthesis

The function of a 12-nt insertion 'CTTTTTTCTTTT' in the 3' untranslated region (3'UTR) of the HCLV strain, a vaccine strain derived from the Shimen strain of classical swine fever virus (CSFV), was examined in vitro. RNA synthesis increased when the 12-nt insertion was deleted from the 3'UTR of the HCLV strain. RNA synthesis also decreased when the 12-nt insertion was introduced into the 3'UTR of the CSFV Shimen, virulent strain. Therefore, the 12-nt insertion present in the 3'UTR of the HCLV strain may be a marker for avirulence. It was also found that the predicted secondary structure of the 3'UTR of the HCLV strain was more stable when the 12-nt insertion was deleted, and that the 3'UTR of Shimen strain was more unstable when the 12-nt insertion was introduced. Replacement of the 12-nt insertion 'CTTTTTTCTTTT' by another 12-nt fragment 'ATTATTATTTAT' in the 3'UTR of HCLV strain facilitated RNA synthesis and stabilized the predicted secondary structure, which was also observed in the 3'UTR of the Shimen strain.

A branching model for the spread of infectious animal diseases in varying environments

This paper is concerned with a stochastic model, describing outbreaks of infectious diseases that have potentially great animal or human health consequences, and which can result in such severe economic losses that immediate sets of measures need to be taken to curb the spread. During an outbreak of such a disease, the environment that the infectious agent experiences is therefore changing due to the subsequent control measures taken. In our model, we introduce a general branching process in a changing (but not random) environment. With this branching process, we estimate the probability of extinction and the expected number of infected individuals for different control measures. We also use this branching process to calculate the generating function of the number of infected individuals at any given moment. The model and methods are designed using important infections of farmed animals, such as classical swine fever, foot-and-mouth disease and avian influenza as motivating examples, but have a wider application, for example to emerging human infections that lead to strict quarantine of cases and suspected cases (e.g. SARS) and contact and movement restrictions.

Effect of prostaglandin A1 in porcine cells persistently infected with classical swine fever virus

Cyclopentenone prostaglandins are potent inhibitors of a wide variety of RNA and DNA viruses. In this report we describe that prostaglandin A1 (PGA1) potently inhibited the replication of classical swine fever virus in cultures of PK-15 cells. The highest non-toxic dose (5 microg/ml) inhibited virus yield in 99% at the initial phase of infection and in 77% in persistent infected cells. However when PGA1 was removed from persistently infected cells, the inhibition of virus replication was partially reverted.

Construction of an infectious chimeric classical swine fever virus containing the 5′UTR of bovine viral diarrhea virus, and its application as a universal internal positive control in real-time RT-PCR

RT-PCR is used widely as a diagnostic method to detect and differentiate pestiviruses. The construction of two chimeric classical swine fever virus (CSFV) recombinants based on a marker virus constructed previously [J. Virol. 72 (1998) 5318-5322] is described. These viruses, termed vA187CAT_5UTRBVD and vA187CAT_IRESBVD, contain the entire 5' untranslated region (5'UTR) or the internal ribosome entry site (IRES) of bovine viral diarrhea virus (BVDV), respectively. Both chimeric viruses proved to be infectious in cell culture. Hence, the 5'UTR as well as the IRES element only of BVDV can substitute for the corresponding genome region of CSFV. Next, two sets of primers and corresponding dual-labeled TaqMan probes were designed; one detecting specifically a conserved but CSFV-specific area within the 5'UTR of wild-type CSFV, the other one targeting the CAT gene inserted in vA187CAT_5UTRBVD. The two primer/probe sets were combined in a closed-tube multiplex one-step RT-PCR. To monitor the entire extraction and detection process limited amounts of vA187CAT_5UTRBVD were added directly to clinical samples before RNA extraction. The multiplex RT-PCR proved to be as sensitive as the single primer/probe set method, but allowed the validation of each sample tested individually, based on the detection of the CAT marker gene. vA187CAT_5UTRBVD was also used successfully for foot-and-mouth disease virus (FMDV) TaqMan RT-PCR. Therefore, it is considered a universal internal positive control for RT-PCR assays to exclude loss of RNA during extraction, or failure of amplification due to inhibitory substances present in the sample.

Classical swine fever--an update

Classical swine fever (CSF) is a serious and contagious viral disease of pigs and wild boar with a widespread worldwide distribution. The immunopathology of the disease is poorly understood, but the ability of the CSF virus to infect cells without triggering apoptosis and to kill uninfected cells is probably highly significant. The virus may be spread by various direct and indirect methods, but in most cases the exact mechanisms involved in local spread between farms are not known. Excellent diagnostic tools and typing methods are available, but tests that could be performed on-farm, in pre-clinically infected pigs or on meat would also be advantageous. A more complete picture of the viruses circulating in different parts of the world is needed. There is great interest to develop and use marker vaccines for the control of CSF in domestic pigs and in wild boar. Epidemiological modelling is increasingly used to evaluate control options.

Risk analysis of the spread of classical swine fever virus through "neighbourhood infections" for different regions in Belgium

Risk factors associated with the occurrence of "neighbourhood infections" [Epidemiology of classical swine fever. In: Truszczynski, M. (Ed.), Proceedings of the Workshop on Diagnostic Procedures and Measures to Control Classical Swine Fever in Domestic Pigs and the European Wild Boar. Pulaway, Poland, pp. 119-130] during classical swine fever (CSF) outbreaks were examined based on information collected during a CSF-epidemic, which occurred in the East Flanders Province of Belgium in 1994. The only risk factor that was associated with the occurrence of "neighbourhood infections" was a kernel estimation of the intensity of neighbouring herds (P=0.055) [Interactive spatial data analysis. Pearson Education Limited, Harlow, Essex], i.e. the higher the kernel estimation, the higher the risk for the occurrence of neighbourhood infections. In a second part of the study, the likelihood for the occurrence of neighbourhood infections within an area with a 1 km radius was predicted for every Belgian pig herd, assuming that the herd was infected with CSF-virus. For the prediction of these likelihoods, the model resulting from the risk assessment was used. Finally, the predicted likelihoods were transformed into a raster map after applying a smoothing technique. As a result, different areas in Belgium of higher or lower risk for CSF-virus spread through "neighbourhood infections" could be identified on the map. The areas in Belgium where CSF-outbreaks including "neighbourhood infections" occurred in the past decades were all predicted by the model to be of high risk.

Classical Swine Fever: pathology of bone marrow

Twenty pigs were inoculated with a virulent isolate (Quillota strain) of classical swine fever (CSF) virus to determine the chronological development of lesions in bone marrow. Histopathologic, ultrastructural and immunohistochemical (detection of viral antigen gp55, myeloid-histiocyte antigen, CD3 antigen, and FVIII-rag), and morphometric techniques were employed. Viral antigen was detected from 2 days postinfection (dpi) in stromal and haematopoitic cells, and severe atrophy related to apoptosis of haematopoitic cells was observed. Megakaryocytes (MKs) did not show significant changes in number, but there were important qualitative changes including 1) increased numbers of cloud-nuclei MKs, microMKs, apoptotic MKs, and atypical nucleated MKs and 2) decreased number of typical nucleated MKs. Morphometric study of these cells showed a decrease in cytoplasmic area. MK infection was detected from 2 dpi, but in a small percentage of cells. Myeloid cells showed quantitative changes, with an increase in granulocyte numbers. Apoptosis of lymphocytes and viral infection of erythroblasts were also observed. The main changes in stroma were depletion of T lymphocytes in the middle phase of the experiment and macrophages. Viral infection was also observed in these cells. MK lesions suggest dysmegakaryocytopoiesis, which would aggravate the thrombocytopenia already present and could be responsible for it. Granulocyte changes would lead to the appearance of circulating immature forms, whereas lymphocyte apoptosis in bone marrow would contribute to lymphopenia.

Modeling and real-time prediction of classical swine fever epidemics

We propose a new method to analyze outbreak data of an infectious disease such as classical swine fever. The underlying model is a two-type branching process. It is used to deduce information concerning the epidemic from detected cases. In particular, the method leads to prediction of the future course of the epidemic and hence can be used as a basis for control policy decisions. We test the model with data from the large 1997-1998 classical swine fever epidemic in The Netherlands. It turns out that our results are in good agreement with the data.

The correlation of virus-specific interferon-gamma production and protection against classical swine fever virus infection

The level of antigen-specific interferon-gamma (IFN-gamma) production can be used as an indicator of cellular immunity. In this study, we investigated the role of cellular immune response in protection against classical swine fever virus (CSFV). Pigs were vaccinated once with CSFV vaccine and challenged 6 days post-vaccination (dpv). Vaccinated animals had significantly higher CSFV-specific IFN-gamma secreting cells than the unvaccinated pigs (p<0.05) at the time of challenge and were protected against CSFV infection, whereas the control pigs died within 14 days post-infection (dpi). In the second experiment, pigs were vaccinated once with either CSFV vaccine or CSFV vaccine combined with Aujeszky's disease (AD) vaccine and challenged at 140 dpv. All vaccinated pigs developed both CSFV-specific, cellular and antibody responses and were protected against CSFV infection. However, differences in cellular, but not antibody, responses were observed in the two vaccinated groups. The group vaccinated with CSFV vaccine developed a significantly higher number of CSFV-specific, IFN-gamma secreting cells (p<0.05), exhibited a shorter fever period and less pathological changes, when compared with the group vaccinated with the combined vaccine. The kinetics of IFN-gamma production, following challenge in the two vaccinated groups, were also different. Taken together, our results indicated that CSFV-specific, IFN-gamma production could be detected early after antigen exposure and correlated with protection against CSFV challenge. Our findings highlight the role of cellular immune responses in porcine anti-viral immunity.

The effect of vaccination with the PAV-250 strain classical swine fever (CSF) virus on the airborne transmission of CSF virus

The airborne transmission of Classical Swine Fever (CSF) virus to susceptible pigs, as well as the effect of vaccination with the CSF virus PAV-250 strain was investigated on this mode of transmission. Experiment I: four pigs were inoculated with the ALD CSFV strain (10(4.3) 50% TCID) by the intramuscular route, and at the onset of fever, they were introduced into an enclosed chamber. At the end of the experiment surviving pigs were sedated, anesthetized and euthanatized. Experiment II: four pigs were previously vaccinated with the CSF virus PAV-250 strain, and at 14 days post-vaccination they were challenged with the CSF virus ALD strain. In both experiments, four susceptible pigs were exposed to infectious aerosols by placing them in a chamber connected by a duct to the adjacent pen containing the infected animals and were kept there for 86 hs. In Experiment I, pigs exposed to contaminated air died as a result of infection with CSF virus on days 14, 21 and 28 post-inhalation. These four pigs seroconverted from day 12 post-inhalation. CSF virus was isolated from these animals, and the fluorescent antibody test on tonsils was positive. In Experiment II, a vaccinated pig exposed to contaminated air did not seroconvert, nor was CSF virus isolated from lymphoid tissues. However, mild fluorescence in tonsil sections from these pigs was observed. In conclusion, CSF virus was shown to be transmitted by air at a distance of 1 m to susceptible pigs. Vaccination with the PAV-250 CSF virus strain protected the pigs from clinical disease under the same conditions.

Classical swine fever virus is genetically stable in vitro and in vivo

Phylogenetic analyses of large numbers of classical swine fever strains have revealed a high degree of sequence conservation in the genomic regions examined, suggesting either a recent common ancestor or a low evolution rate. This low variability is in contrast to findings with other RNA viruses. To investigate the consequence of this apparent genetic stability on phylogenetic examinations, the Belgian field isolate Wingene'93 was passaged in pigs as well as in cell culture by various methods. Sequence analyses of viruses collected after various passages in three target regions proposed for phylogenetic studies (5' NTR, E2, and NS5B) revealed a complete sequence conservation. Only when the amount of passaged virus was lowered, mimicking a genetic bottleneck, a single point mutation was observed in the E2 gene. Additionally, only four nucleotide substitutions were observed when the genome of a virus obtained after 96 cell passages in persistently infected cells was compared with its parental virus, the recombinant virus derived from an infectious cDNA clone of CSFV strain Alfort/187. This low mutation frequency observed both in vitro and in vivo demonstrates that classical swine fever virus is genetically stable. Hence, even minor mutations can be considered significant in molecular epidemiological studies.

Transmission of classical swine fever virus by artificial insemination

Classical swine fever (CSF) virus was introduced into an artificial insemination centre during the CSF epizootic of 1997-1998 in the Netherlands. The risk of further spread of CSF virus via contaminated semen was recognised, but could not be assessed because scientific data on this issue were not available. An animal experiment was performed to determine whether CSF virus could be transmitted via artificial insemination with contaminated semen. Three boars were inoculated with a CSF virus field isolate and from Day 5 till Day 18 thereafter, ejaculates were collected and prepared for insemination. Ruttish sows were inseminated with the extended semen from Day 5 till Day 18 after inoculation of the boars. All the inoculated boars remained healthy throughout the experiment and developed CSF neutralising antibodies between 14 and 21 days after inoculation. Virus was isolated from several semen samples collected from 5 till 11 days after inoculation. Two out of six sows inseminated with CSF contaminated semen seroconverted after insemination. All the other sows remained seronegative. In the foetuses of both the seropositive sows, CSF virus was detected at approximately 35 days post insemination. These results demonstrate that adult boars infected with CSF virus can excrete virus with semen and can, subsequently, transmit the virus to sows and their foetuses via artificial insemination.

Thermal and pH stability of pestiviruses

Three strains/isolates of hog cholera virus (HCV) and two strains/isolates each of cytopathogenic (cp) and non-cytopathogenic (ncp) biotype of bovine virus diarrhoea virus (BVDV) were each exposed to pH 3, 3.5 and 4 at 4 degrees C, 21 degrees C and 37 degrees C in a number of combinations. Infectivity titration and half-life determinations following correlation and regression analysis showed a significant temperature-dependent shortening of half-lives within the pH range investigated. At pH 3, mean half-lives were more than tenfold lower when HCV was kept at an ambient temperature of 21 degrees C rather than at 4 degrees C. Additionally, in some of the strains/isolates tested, half-lives of HCV kept at 4 degrees C were four to ten times lower when the pH was raised from 3 to 4. BVDV appeared more sensitive at 4 degrees C and pH 3 than HCV, but equally sensitive at 21 degrees C. Differences in temperature or pH stability between cp and ncp biotypes of BVDV could not be statistically verified although, in general, the cp biotypes seemed to be more stable than the ncp strains/isolates.

Survival of hog cholera virus (HCV) in sausage meat products (Italian salami)

Survival of hog cholera virus (HCV) was determined in several sausage meat products (Italian salami) prepared with meats from experimentally infected hogs slaughtered at the peak of disease. Meats were processed following the technology applied by the main factories of the typical Italian production. The survival of HCV was assessed through inoculation in both PK 15 cell monolayers and fully susceptible piglets. In all types of sausages examined HCV was detected up to 75 days of curing by piglet inoculation. This technique was much more sensitive than use of cell culture.

[Is feeding of green silage in areas with hog cholera in wild boar a danger for domestic swine herds? Experimental study]

In an experimental study we tested the survival of hog cholera virus (HCV) contained in pieces of muscular tissue and organs from experimentally infected swine after incubation in silage. In big (diameter greater than 20 cm) muscular pieces HCV survived even in excellent mineral acid silage (pH 3.8-4.0) after a storage of 5 months. On the other hand in smaller parts (musculature tissue, organs less than 20 cm diameter) we never found virulent HCV after 3 months of incubation. Independent of the size of the tested organs we did not find any virulent HCV in silage with pH 5.2 after 3 months. The results of our investigations show, that the feeding of green silage in areas with hog cholera among wild boar is a potential risk for the domestic swine population. In conclusion we propose to feed green silage to unvaccinated pigs in such areas only after a storage of 9 month.

General characteristics and viral susceptibility of a newborn pig kidney (NPK) continuous culture

We have developed a fibroblastic-like continuous culture of newborn pig kidney (NPK). The current cell line was serially passaged 160 times and appeared to be well suited for production and assay of a number of viruses affecting pigs, such as pig parvovirus, pseudorabies and transmissible gastroenteritis. The cell line appeared aneuploid, with a modal chromosome number of 36 and induced tumors, classified as fibrosarcoma, in athymic mice.

High titre Hog Cholera virus production on Cytodex 3 microcarrier cultures

In an attempt to produce Hog Cholera virus (HCV) preparations of high titre, optimal growth and trypsinization conditions of PK-15 microcarrier cell cultures were defined. Infecting a PK-15 Cytodex 3 microcarrier culture with HCV increased the yield of virus more than 10 times compared with conventional monolayer culture in Roux flasks.

A study on the susceptibility of minipig kidney (MPK) and rabbit kidney (RK13) cell line cultures to the lapinized Chinese strain of hog cholera virus

The susceptibility of two established cell lines of pig (MPK = minipig kidney) and rabbit (RK13 = rabbit kidney) origin to the lapinized Chinese (LC) strain of hog cholera virus (HCV) was studied. Spleen cells from rabbits infected with the virus under study were inoculated to cell cultures of either MPK and RK13 cells and subsequent passages were made by culturing the trypsinized infected cells with the normal cells. Only the MPK cell line appeared to be susceptible to virus replication. Since no cytopathic effects (CPE) were observed, the presence of the viral antigen in the inoculated cultures was detected by immunofluorescence tests. The virulence of the virus for rabbits was enhanced after its cultivation in MPK cell cultures. When the MPK cell culture system adapted virus was tested in neutralization trials in the presence of an HCV reference immune serum it was found that the virus did not modify its antigenic structure in any extent. Finally, the culture adapted virus appeared to be more immunogenic for rabbits than the original rabbits adapted virus. Based on these results, it seems reasonable to suggest the use of MPK cell line for the propagation of the LC strain of HCV as an alternative to the use of rabbits for the preparation of HCV vaccine.

Characteristics of the porcine kidney cell line IB-RS-2 clone D10 (IB-RS-2 D10) which is free of hog cholera virus

A Brazilian stock of clone C17 of the IB-RS-2 porcine kidney cell line which was contaminated with hog cholera virus (HCV) was cloned. One clone designated IB-RS-2 D10 was determined to be free of HCV, 20 other viruses, and Mycoplasma. IB-RS-2 D10 cells possessed the same viral susceptibility pattern as the contaminated parent cells to the viruses of foot-and-mouth disease, swine vesicular disease, vesicular exanthema of swine, transmissible gastroenteritis, and several other viruses. The IB-RS-2 D10 cells had a median chromosome count of 34, were morphologically epithelioid cells, and were resistant to HCV infection. Freedom from HCV affords advantages for vaccine production and avoids laboratory contamination.

Susceptibility of a minipig kidney cell line (MPK) to hog cholera virus

A comparitive study on the different susceptibility of MPK cells (Minipig Kidney cell line) and PK15 cells (Pig Kidney cell line) to the Hog Cholera Virus (HCV) was conducted. Higher HCV titres (3 log10) were reached on MPK cells compared with PK15 cells.

Classical swine fever: virulence and tissue distribution of a 1986 English isolate in pigs

Following the recurrence of classical swine fever in the United Kingdom in 1986, a virus isolated from a single outbreak was studied. A major factor in the spread of this disease is considered to be the presence of infectious virus in tissues taken from animals at certain stages of infection, although their condition may escape detection by routine inspection either before or after slaughter. Intranasal inoculation of the isolate into eight-week-old pigs reproduced the acute form of the disease. The pigs were killed or died between seven and 25 days after inoculation. The virus concentration was determined in a wide range of tissues taken at different stages of infection. Infectious virus was present at high concentrations in all the tissues taken and at all stages of infection. Any porcine tissue is therefore a potential source of infection even when it is taken either before the animal displays detectable signs of disease of after it develops serum neutralising antibodies.

The protective value of vaccine-induced neutralising antibody titres in swine fever

The relationship between vaccine-induced antibody titres against swine fever virus (SFV), as measured by the neutralisation peroxidase-linked assay (NPLA), and protection against virus multiplication, excretion and transmission, disease and death was studied in 46 pigs. The pigs were housed individually and challenged intranasally with 100 pig ID50 of the virulent Brescia strain of SFV. In order to detect virus transmission, a swine fever (SF)-susceptible sentinel pig was placed in contact with the vaccinated animal 2 days after challenge. All 11 pigs with pre-challenge NPLA titres less than 12.5 responded to the challenge with fever, 8 out of 10 showed leucopenia, 7 transmitted virus to their contact and 3 died. Of the 9 animals with titres greater than or equal to 12.5 and less than 25, 8 developed fever, 6 out of 7 had leucopenia, 2 excreted and/or transmitted virus and all survived. Of the 12 pigs with pre-challenge titres greater than or equal to 25 and less than 50, 5 responded with fever, 6 out of 10 had leucopenia, 4 excreted virus and none died. Although all pigs with prechallenge titres greater than or equal to 50 showed a booster response, virus transmission was not observed, indicating that in the case of exposure such animals would not contribute towards the spread of field virus. From an epidemiological point of view, titres less than 32 were found inadequate.

End-point dilution-fluorescent antibody technique for cloning hog cholera virus

Hog cholera virus was cloned by incubating selected pretitrated dilutions of the virus on PK-15 cell cultures for 2 hours. After a thorough washing, the coverslip cell cultures were overlaid with medium containing 0.1% hog cholera immune serum to prevent secondary foci. Forty-eight hours later, the cultures were vigorously washed and maintenance medium containing 5% bovine fetal serum was added. When examined by the fluorescent antibody technique 18 hours later, single plaques were observed in some cultures with no evidence of secondary foci. The virus clone subsequently yielded a homogeneous population of hog cholera virus that retained the characteristics of the parent strain; pathogenicity of the virus clone in pigs was demonstrated, and specific immunofluorescence occurred in infected cell cultures stained with fluorescein isothiocyanate-labeled antibody. The method used gave reasonable assurance of the cloned virus' freedom from extraneous agents.

Hog cholera antibodies in pigs vaccinated with an Aujeszky-vaccine based on antigen produced in IB-RS-2 cells

The cell line IB-RS-2 is confirmed to be persistently infected with hog cholera virus. Vaccination of pigs against Aujeszky’s Disease with an inactivated vaccine based on antigen produced on this cell line induced neutralizing antibodies against hog cholera virus.

Thermal inactivation of hog cholera virus in ham

Experiments were conducted to determine the temperatures required to inactivate hog cholera virus (HCV) in fresh ham after 1 minute and in cured and processed (canned) ham after 90 minutes. A momentary or "flash" temperature of 71 C for 1 minute caused inactivation of the virus in 15 of 15 cubes (2 cm3) of ham. Hog cholera virus was destroyed in 21 of 21 canned hams (weighing 0.91 kg each) when an internal temperature of 65 C was sustained for 90 minutes. Pigs were found to be more sensitive than tissue culture cells for detecting viable HCV in heat-processed fresh hams. Virus was isolated by tissue culture technique only from those hams exposed to temperatures below 61 C. The relative concentration of HCV in unheated cured hams of experimentally infected pigs varied over a wide range; these pigs were inoculated with the virulent Ames strain and were killed on postinfection day 6 or 7.

[Isolation of a cytolytic strain of hog cholera virus from IB-RS2 cells (author's transl)]

An infectious agent, able to induce a definite cytopathic effect in pig kidney cell monolayers, was isolated from the IB-RS2 cell line. Immunofluorescence, seroneutralization and ultracentrifugation studies have permitted to identify this agent as hog cholera virus (HCV). Representative HCV-strains being devoid of pathogenicity in tissue culture, the practical and theoretical interest of such an isolation is discussed.