Pharmacokinetics of cyclophosphamide and its metabolites in bone marrow transplantation patients

Classical swine fever virus infection of pigs causes a severe leukopenia and immunosuppression. In the present study, the kinetics of virus infection, and identification of target cells for the virus in peripheral blood were analysed. Virus infection was often not detectable before 5-7 days p.i. A minority of animals yielded detectable infected cells at 3 days p.i., but < 5% PBMC. It was not until 10 days p.i. that this figure increased-to 35-70% PBMC depending on the animal. Detailed analysis of Ficoll-Hypaque-purified PBMC identified the major population to be SWC3+SWC8+CD14+MHCII- granulocytic cells. Microscopic observations determined that these low density granulocytic cells in the PBMC from CSFV infected animals were indeed immature cells. Both the low density granulocytic cells and monocytes were major targets for CSFV infection in the peripheral blood. This is the first demonstration that low density granulocytic cells dominate the blood leukocyte population during CSF, and that such cells are targets for virus infection. The present work also demonstrates that the leukocyte population changes, such as B lymphocyte depletion and the relative dominance of myeloid cells in the blood during CSF, occur before virus infection of the affected cells. Thus, the pathological mechanism therein is not a direct consequence of virus infection.     

Development and evaluation of a novel antigen capture assay for the detection of classical swine fever virus antigens

An antigen-capture enzyme immunoassay (EIA) was developed to detect classical swine fever virus (CSFV) antigen directly from 10% w/v tissue suspension. The assay, based on the sandwich principle, uses a biotinylated monoclonal antibody bound to streptavidin-coated microplates as the capture system and a swine anti-CSFV antibody and rabbit anti-swine HRPO-conjugate as the detector system. The antigen-capture EIA was compared with conventional virus isolation and polymerase chain reaction (PCR) for detection of CSFV in tissues. The ability of the antigen-capture EIA to discriminate classical swine fever (CSF) from bovine viral diarrhea and African swine fever viruses was also tested. The assay was shown to detect 21 different strains of CSFV and was unreactive with tissues from uninfected animals. Signal to noise (S/N) ratios were calculated from the EIA absorbance values. Readings from samples positive by virus isolation (n = 47) averaged a S/N ratio of 5.34. In contrast, samples negative by virus isolation (n = 96) demonstrated a mean S/N ratio of 0.16. At S/N cut-off value of 1.0, all samples that yield virus isolation and PCR negative result were negative in the antigen-capture EIA. Compared with virus propagation in tissue culture using PK15 cells (followed by indirect peroxidase assay detection) and PCR, the EIA had a specificity of 98.7% and a sensitivity of 91.4%. The EIA is simple, can be performed in 4 h and lends itself to automation for screening of tissues sample from pigs suspected of CSFV infection.     

Gene conversion tracts from double-strand break repair in mammalian cells

A new assay termed the dome disappearance method for classical swine fever virus (CSFV) using FS-L3 cells with serum-free culture medium was developed. The CSFV live vaccine GPE- strain grows well and shows a slight cytopathic effect (CPE) in FS-L3 cells. This CPE results in the disappearance of the unique fluid-filled multicellular domes on a single monolayer of FS-L3 cells. By using this phenomenon, dome disappearance, as a marker of infection, it was possible to determine the titers of CSFV and its neutralizing antibody. The virus titer determined by this method shows a good correlation with that determined by immunochemical and interference methods. Furthermore, the amount of neutralizing antibody measured by this method also correlated with that measured by the Exaltation of Newcastle Disease Virus (END) neutralizing method. The dome disappearance method developed in this experiment is a simple and safe procedure and has the great advantage that bovine serum, which may contain antibody against bovine viral diarrhea virus, is not necessary for the cultivation of FS-L3 cells.     

Congenital infection of pigs with ruminant-type pestiviruses

Congenital infections of pigs were induced with two ruminant-type pestiviruses isolated from pigs. One of the viruses was bovine viral diarrhoea virus-like and the other border disease virus-like. Both produced symptoms similar to those observed with low virulence strains of classical swine fever virus. A striking effect of persistent virus infection in post-natal life was stunting in viraemic animals. It was also shown that a congenitally infected pig shed virus for 2.5 years and in sufficient quantity to infect other pigs, even by indirect contact. Unlike ruminants, congenitally infected pigs sometimes had persistent viraemia but eventually eliminated the virus. Clearance of virus from the blood was related to the appearance of neutralizing antibodies. However, clearance from the tissues sometimes took as much as 5 months longer than from the blood.     

Classical swine fever in 1993 in Switzerland: molecular-epidemiologic characterization of the virus isolate

RT-PCR followed by direct nucleotide sequencing of the amplified cDNA was carried out to analyse most of the 5' nontranslated region (5'NTR) of classical swine fever virus (CSFV) isolates from the five 1993 disease outbreaks in Switzerland. Sequence data were compared to other CSFV strains, and dendrograms were constructed in order to determine the phylogenetic relationship of the Swiss virus strains. Dendrograms formed by the analysis of different parts of the 5'NTR were compared. It was shown that all Swiss isolates were related to other CSFV strains involved in disease outbreaks in Europe in the 1990s. Two of the isolates were indistinguishable from a CSFV strain isolated from wild boar meat imported from China into Austria in 1993. The risk of introducing classical swine fever by improperly treated swill and, in particular by importing wild boar meat is discussed.     

The African swine fever virus proteins p54 and p30 are involved in two distinct steps of virus attachment and both contribute to the antibody-mediated protective immune response

The nature of the initial interactions of African swine fever (ASF) virus with target cells is only partially known, and to date only the ASF virus protein p12 has been identified as a viral attachment protein. More recently, antibodies to viral proteins p54 and p30 have been shown to neutralize the virus, inhibiting virus binding and internalization, respectively. Therefore, we investigated the role of these proteins in the receptor-mediated ASF virus endocytosis in swine macrophages, the natural host cells. Proteins p54 and p30, released from ASF virus particles after treatment of virions with a nonionic detergent, bound to virus-sensitive alveolar pig macrophages. Binding of these proteins was found to be specifically inhibited by neutralizing antibodies obtained from a convalescent pig or from pigs immunized with recombinant p54 or p30 proteins. The baculovirus-expressed proteins p54 and p30 retained the same biological properties as the viral proteins, since they also bound specifically to these cells, and their binding was equally inhibited by neutralizing antibodies. Binding of 35S-labeled recombinant p54 and p30 proteins to macrophages was specifically competed by an excess of unlabeled p54 and p30, respectively. However, cross-binding inhibition was not observed, suggesting the existence of two different saturable binding sites for these proteins in the susceptible cells. In addition, protein p54 blocked the specific binding of virus particles to the macrophage, while protein p30 blocked virus internalization. Both proteins independently prevented virus infection and in a dose-dependent manner, suggesting that binding interactions mediated by both proteins are necessary to give rise to a productive infection. The relevance of blockade of virus-cell interactions mediated by p54 and p30 in the protective immune response against ASF virus was then investigated. Immunization of pigs with either recombinant p54 or p30 proteins induced neutralizing antibodies which, as expected, inhibited virus attachment or internalization, respectively. However, immunized pigs were not protected against lethal infection and the disease course was not modified in these animals. In contrast, immunization with a combination of p54 and p30 proteins simultaneously stimulated both virus neutralizing mechanisms and modified drastically the disease course, rendering a variable degree of protection ranging from a delay in the onset of the disease to complete protection against virus infection. In conclusion, the above results strongly suggest that proteins p54 and p30 mediate specific interactions between ASF virus and cellular receptors and that simultaneous interference with these two interactions has a complementary effect in antibody-mediated protection.     

A recombinant classical swine fever virus stably expresses a marker gene

The gene coding for bacterial chloramphenicol acetyltransferase (CAT) was inserted in frame into the viral Npro gene of the full-length cDNA clone pA187-1 of the classical swine fever virus (CSFV) strain Alfort/187. RNA transcribed in vitro from the resulting plasmid was transfected into SK-6 porcine kidney cells. Infectious progeny virus vA187-CAT recovered from transfected cells had growth characteristics indistinguishable from those of parental virus vA187-1. In cells infected with vA187-CAT the predicted fusion protein, CAT-Npro, was detected, and it retained the enzymatic activities of both CAT and Npro. The CAT gene remained stably inserted in the viral genome after 10 virus passages. Thus, marker virus vA187-CAT represents a useful tool for quantitative analysis of viral replication and gene expression.     

Detection of mineral density on the surface of mouse parietal bones: backscattered electron imaging of low accelerating voltage scanning electron microscopy

The aim of this work was to genetically characterize Central European isolates of classical swine fever virus (CSFV) and to evaluate the applicability of molecular analysis in the epizootiology of CSFV infections. Thirty four viruses, derived from Central European pigs or wild boar, were examined. All of these viruses were detected by each of three sets of oligonucleotide primers which had been designed for the specific RT-PCR amplification of different genomic regions. Comparative sequence analysis of the PCR products showed that they were of a genetic type common in Western Europe. Further discrimination of virus isolates was possible, into subgroups that largely coincided with their regions of origin in Poland, Slovakia, Hungary and Estonia. The discriminatory ability of the technique was improved by the analysis of a composite dataset consisting of all of the sequence data from all of the viruses. Using this approach we were able to distinguish between all of the viruses and to group them in a manner that precisely matched their geographical origins, apart from a single Estonian isolate which grouped with viruses from Eastern Poland.     

The results of treating periapical periodontitis with ultraviolet irradiation of the root canal and the use of gentamycin

A serological and immunohistochemical study of African swine fever was carried out in wild boar killed in seven municipalities in the north of the province of Córdoba during two hunting seasons (1991-92 and 1992-93), when the area was affected by the disease. Fourteen of 147 wild boar analysed by ELISA and immunoblotting had antibodies to African swine fever virus. The immunohistochemical study revealed that four cases (two seropositive and two seronegative) showed immunoreactivity to the anti-VP73 monoclonal antibody. Two of the VP73+ wild boar had severe generalised haemorrhages consistent with the acute from of the disease, and another had lesions consistent with subacute African swine fever, but none of the remaining 144 animals had gross or microscopic changes suggestive of the disease. These results indicate that wild boar can suffer from African swine fever without showing clinical signs. The disease in wild boar was associated with the disease in domestic pigs. Thus, no African swine fever-positive boar were found either in one municipality with no out-breaks in domestic pigs or in three municipalities with only one outbreak in pigs during the hunting seasons and during the previous year. These results suggest that European wild boar do not play an important role as carriers of the virus of African swine fever.     

Evaluation of the enzyme-linked immunosorbent assay for the rapid screening and detection of classical swine fever virus antigens in the blood of pigs

A workshop was convened, at which seven enzyme-linked immunosorbent assays (ELISAs) were compared with virus isolation for the detection of viraemia in serial blood samples collected from six pigs at up to fourteen days after inoculation with classical swine fever virus. All ELISAs were of the double antibody sandwich type, using monoclonal and/or polyclonal antibodies to detect a variety of viral proteins in leukocytes, or in anti-coagulated blood or serum. Compared to virus isolation, specificity of the ELISA was good: only one sample found negative by virus isolation yielded a positive result in a single ELISA. Some false-negative results occurred with samples collected at up to eight days after inoculation, but all tests found samples collected between nine and fourteen days post-inoculation to be positive. The ELISAs require less-specialised facilities and can be performed much more rapidly than virus isolation. They are therefore extremely promising tools for screening large numbers of live pigs.     

The African swine fever virus thymidine kinase gene is required for efficient replication in swine macrophages and for virulence in swine

African swine fever virus (ASFV) replicates in the cytoplasm of infected cells and contains genes encoding a number of enzymes needed for DNA synthesis, including a thymidine kinase (TK) gene. Recombinant TK gene deletion viruses were produced by using two highly pathogenic isolates of ASFV through homologous recombination with an ASFV p72 promoter-beta-glucuronidase indicator cassette (p72GUS) flanked by ASFV sequences targeting the TK region. Attempts to isolate double-crossover TK gene deletion mutants on swine macrophages failed, suggesting a growth deficiency of TK- ASFV on macrophages. Two pathogenic ASFV isolates, ASFV Malawi and ASFV Haiti, partially adapted to Vero cells, were used successfully to construct TK deletion viruses on Vero cells. The selected viruses grew well on Vero cells, but both mutants exhibited a growth defect on swine macrophages at low multiplicities of infection (MOI), yielding 0.1 to 1.0% of wild-type levels. At high MOI, the macrophage growth defect was not apparent. The Malawi TK deletion mutant showed reduced virulence for swine, producing transient fevers, lower viremia titers, and reduced mortality. In contrast, 100% mortality was observed for swine inoculated with the TK+ revertant virus. Swine surviving TK- ASFV infection remained free of clinical signs of African swine fever following subsequent challenge with the parental pathogenic ASFV. The data indicate that the TK gene of ASFV is important for growth in swine macrophages in vitro and is a virus virulence factor in swine.     

The effect of chemical anti-inhibitors on fibrinolytic enzymes and inhibitors

Based on published gene sequences of bovine viral diarrhoea virus (BVDV) type I and classical swine fever virus (CSFV), genus- and species-specific primers were designed to detect and identify pestivirus cDNA sequences in a nested polymerase chain reaction (PCR). The PCR primers were validated using cDNA synthesized from 146 pestivirus isolates, comprising representatives of all four so far described genotypes (BVDV type I, BVDV type II, CSFV and border disease virus), as well as others of uncertain classification. PCR products of the predicted size were amplified from all viruses with the genus-specific primers. All 53 cattle isolates, including 5 typed antigenically as BVDV type II were amplified by the internal BVDV-specific primers, but not the CSFV-specific primers. The same result was found for other BVDV type I and II viruses isolated from sheep and pigs. Seventy-seven CSF viruses were amplified by their respective internal primers. Available information strongly indicate that 4 CSF viruses also amplified by the BVDV-specific primers had been contaminated with BVDV in cell cultures. Border disease viruses were mostly not detected by the BVDV-specific primers, but were detected weakly by the CSFV-specific primer pair. Using carrier RNA for extraction of viral RNA, the sensitivity of detection of the single and nested PCR was, respectively, 5 and 50 times higher than obtained with a cell culture assay. The RT-PCR also detected BVDV in all of 15 commercial batches of fetal calf serum examined, and verified three earlier diagnoses of CSFV by detecting specific gene sequences in 30 year old frozen archival organ samples.     

Clinical study on air in epidural hematomas

Twenty 2nd specific pathogen-free pigs were divided into 4 groups: Group A were infected with porcine reproductive and respiratory syndrome (PRRS) virus at 6 weeks of age and treated with available swine erysipelas and swine fever combined vaccine (vaccinated) at 7 weeks of age; Group B were vaccinated at 7 weeks of age and infected with PRRS virus at 8 weeks of age; Group C were vaccinated at 7 weeks of age: Group D were neither vaccinated nor infected with PRRS virus. All pigs were challenged to Erysipelothrix rhusiopathiae C42 strain at 10 weeks of age. No clinical signs appeared after vaccination of group A and B pigs, thus confirming that the safety of the vaccine was not influenced by infection with PRRS virus. None of the pigs in Groups A and C developed erysipelas after challenge exposure to E. rhusiopathiae. In contrast, fever and/or urticaria appeared transiently in all pigs of Group B after challenge exposure. At the time of challenge exposure to E. rhusiopathiae, the PRRS virus titer was high in sera of Group B, but was low in those from Group A. However, vaccination of pigs with attenuated E. rhusiopathiae was effective in dual infection with PRRS virus and E. rhusiopathiae, because the clinical signs were milder and the E. rhusiopathiae strain was less recovered from these pigs compared to pigs of group D.     

Immunity to porcine rubulavirus infection in adult swine

The immune response against the porcine rubulavirus was analyzed in experimentally infected adult pigs. High titers of virus neutralizing and hemagglutinating inhibitory antibodies were identified in infected animals. The antibody specificity was directed towards HN, M, and NP rubula virion proteins; immunodominance of HN proteins was demonstrated. Peripheral blood mononuclear cells from infected, but not from non-infected pigs proliferated in vitro in response to virus antigenic stimuli, showing a bell-shaped plot with the highest peak at 5 weeks post-infection. Virus-induced lymphoblasts expressed CD4+ CD8+ phenotype, whereas lectin-induced lymphoblasts were mainly identified as CD4+ CD8- cells. Phenotype analysis of freshly prepared PBMC revealed increased number of both monocytes (PoM1+) and total T lymphocytes (CD2+) early during infection, with reduced values of B lymphocytes at 4 weeks post-infection. Decrease in CD4+ CD8- blood cells was observed at 3 weeks post-infection, whereas both CD4- CD8+ and CD4+ CD8+ cells increased 1 and 4 weeks post-infection, respectively. This work discusses the relevance of CD4+ CD8+ T cells in the control of porcine rubulavirus infection.     

Double-labelling immunohistochemical study of megakaryocytes in African swine fever

Bone marrow samples from pigs infected with the highly virulent Malawi'83 or moderately virulent Dominican Republic (DR'78) isolates of African swine fever virus were studied by means of a double labelling immunohistochemical technique which stained the major structural protein VP73 of the virus and megakaryocytes simultaneously. In pigs infected with the highly virulent Malawi'83 isolate, 2.2 per cent of megakaryocytes were VP73+ five days after inoculation, and at six and seven days 2.5 and 9.5 per cent of megakaryocytes were VP73+. Some infected and uninfected megakaryocytes showed pyknosis and karyorrhexis, particularly at seven days after inoculation. However, in comparison with uninfected pigs, the number of megakaryocytes decreased only at seven days after inoculation. In pigs infected with the moderately virulent DR'78 isolate, only 0.2 per cent of megakaryocytes were VP73+ at eight days after inoculation. However, at eight, nine and 10 days after inoculation the total number of megakaryocytes was significantly lower (P < 0.01) than in control uninfected pigs, and the majority of the megakaryocytes showed signs of cell death such as pyknosis and karyorrhexis. The fact that this greater destruction of megakaryocytes was associated with the lower rate of infection of this cell type suggests that indirect damage to megakaryocytes is an additional mechanism of thrombocytopenia in acute and subacute African swine fever.