Time course of the porcine cellular and humoral immune responses in vivo against pseudorabies virus after inoculation and challenge: significance of in vitro antigenic restimulation

We investigated the time course of porcine cellular and humoral immune responses against pseudorabies virus (PRV) after pigs were inoculated with PRV gE(-) mutant strain M141 and challenged with wild-type virus NIA-3. Peripheral blood mononuclear cells (PBMC) were isolated from blood samples; half were used directly and half were restimulated with PRV in vitro before use in a cytolytic assay. We determined time course and extent of PRV-specific lymphoproliferative and cytolytic response. In addition, serum samples were examined for neutralizing antibodies. After inoculation, the frequency of various lymphocyte subsets in peripheral blood was determined by FACScan. One week after inoculation, T-lymphocytes proliferated abundantly and a B-lymphocyte response was observed. When PBMC were used directly without restimulation, only 15% of the PRV-infected target cells were lysed, and about 15-20% of uninfected target cells were lysed. In contrast, when PBMC were restimulated with PRV, up to 50% of the PRV-infected target cells were lysed while only 30% of the uninfected target cells were lysed. The frequency of various T-lymphocyte subsets in the circulation did not change significantly after inoculation, which indicates that the number of PRV-specific lymphocytes in circulation was very small. After challenge, the T-lymphocyte response was enhanced, but the B-lymphocyte response was not. When PBMC were used directly, only 20% of the PRV-infected and uninfected target cells were lysed after challenge. In contrast, when PBMC were restimulated with PRV, they again lysed more PRV-infected target cells than uninfected target cells. Cytolytic cells were detected for a longer period after challenge than after inoculation. Since it was only possible to clearly detect cytolysis after lymphocytes were restimulated with PRV, it may be that they do not preferentially localize in blood or that they are too few in blood to be detected without further antigenic restimulation in vitro. These lymphocytes may instead localize in other tissues, such as mucosal tissues, tonsils and draining lymph nodes. Whether such a reservoir of PRV-specific cytolytic cells is important in clearing the virus is still unknown. In this study we demonstrated PRV-specific lymphocytes in circulation after they were restimulated in vitro with PRV.

Silent memory induction in maternal immune young animals

Maternal immunity was shown to be an effector mechanism which does not include transfer of memory. 'Boosting' of maternal immunity by vaccination was not effective. Transferred maternal immunity negatively interfered with the induction of optimal protection by vaccination. Antibody formation was not observed after vaccination of maternally immune piglets. In contrast, induction of memory had occurred in animals under maternal immune suppression. Vaccination in young animals negatively interfered with or abrogated, effective maternal immune protection. There was no correlation between specific serum antibody titres in piglets and protection to PRV. Thus apart from protection provided by antibodies contributions of other soluble factors and the cellular immune compartment as represented in colostrum and/or milk were important for protection.

The influence of maternal immunity on the development of the in vitro lymphocyte proliferation response against pseudorabies virus in pigs

In this study, the influence of maternal immunity against pseudorabies virus (PRV) on the development of a PRV-specific T-cell response in pigs was investigated. Pigs with or without maternal immunity were challenged by inoculation with wild-type PRV, or were vaccinated with 783 and subsequently inoculated. Peripheral blood lymphocytes, collected after vaccination and/or inoculation, were used for PRV-induced lymphocyte proliferation assays in vitro as a measure of a PRV-specific T-cell response. In unvaccinated pigs, the presence of maternal immunity did not inhibit the development of a T-cell response after inoculation with PRV. In contrast, maternal immunity did inhibit the development of a PRV-induced response after intramuscular vaccination. Moreover, vaccinated pigs without maternal immunity shed virus for a shorter period after inoculation than vaccinated pigs with maternal immunity. The greater T-cell response induced by the vaccine might have contributed to the more rapid clearance of PRV in these pigs.

Evaluation of a poliovirus-binding inhibition assay as an alternative to the virus neutralization test

An enzyme-linked immunosorbent assay (ELISA)-based poliovirus-binding inhibition (PoBI) test to detect and quantify antibodies to polioviruses was optimized and evaluated for use in population studies as an alternative to the virus neutralization test (NT) in tissue culture. The sensitivities of the inhibition ELISA compared with the NT in an inactivated poliovirus vaccine (IPV)-vaccinated population were 98.6, 97.4, and 92.1% for serotypes 1, 2, and 3, respectively. The specificities of the PoBI test, as determined with sera from nonvaccinated persons, were also high for all three serotypes (99.0, 95.8, and 100%, respectively). Antibodies to other enteroviruses did not cross-react in the serotype 1 and 3 PoBI, and only levels of cross-reactivity were found for serotype 2. We found high correlations between the PoBI and NT titers for serotypes 1 and 2 in IPV-vaccinated blood donors (0.97 and 0.95), in oral poliovirus vaccine (OPV)-vaccinated blood donors (0.91 and 0.95), and in naturally immune persons (0.90 and 0.87). The correlation coefficient for serotype 3, however, was significantly lower in OPV-vaccinated blood donors (0.73) and in naturally immune persons (0.76) than in IPV-vaccinated persons (0.94; P < 0.01). These results indicate that the antibody response to serotype 3 poliovirus in IPV recipients is different from that in OPV recipients and naturally infected persons. We conclude that the PoBI test is a suitable alternative to the NT for estimating the seroprevalence of neutralizing antibodies to poliovirus, especially in large-scale population studies.

Establishment and characterization of porcine cytolytic cell lines and clones

Although non-major-histocompatibility-complex-restricted cytolytic cells appear to significantly influence antiviral immunity in pigs, the phenotype and functional characteristics of these cells are not well defined. To allow a detailed analysis of these subsets, we established and characterized cell lines and clones of interleukin-2-activated (IL-2) cytolytic cells. Cell lines and clones were obtained from peripheral blood mononuclear cells of minipigs of the swine-leucocyte-antigen-complex (SLA) d/d haplotype. Cells were cultured in the presence of human recombinant IL-2 and cloned by double limiting dilution in the presence of gamma-irradiated L14 cells (a retrovirus immortalized B-lymphoblastoid cell line of the haplotype SLAd/d) or gamma-irradiated autologous peripheral blood mononuclear cells as feeder cells. Cytolytic cell lines and clones were characterized for their ability to kill different target cells and for their cell surface phenotype. All obtained clones expressed CD2 and CD8 and were negative for CD4. The following three subsets of cytolytic cells were identified: Subset 1) CD3- CD5- cells that killed K562 cells (a natural killer cell susceptible target cell line), as well as the pseudorabies virus (PRV)-infected or uninfected porcine kidney cells. These cells were considered to be typical natural killer cells. Subset 2) CD3 gamma/delta + CD5- T-cells that killed K562 cells and PRV virus-infected or uninfected porcine kidney cells, infected or uninfected L14 cells, and L14 cells constitutively expressing the PRV viral glycoprotein gB or gC. These cells were considered to be gamma/delta T-cells with natural killer activity. Subset 3) CD3 alpha/beta + CD5+ T-cells that killed L14 cells, PRV-infected L14 cells, and PRV gB- and gC-transfected L14 cells. These cells were possibly induced by the L14 feeder cells, used in the in vitro culture system. None of the cytolytic effector cells killed only MHC-matched viral infected cells. In conclusion, we describe a method to isolate, clone, and culture cytolytic cells from pigs. The clones could be cultured for 5 months, which allowed appropriate phenotypic and functional characterization of the various clones. Two of the subsets, CD3 gamma/delta T- and the natural killer cell subset may be involved in antiviral immunity in this species.

Immunohistological characterization of the local cellular response directed against pseudorabies virus in pigs

The aim of this study was to investigate the kinetics of a primary and secondary immune response against pseudorabies virus (PRV). Pigs vaccinated with strain 783 and unvaccinated pigs were challenged with wild-type PRV by either intranasal or subcutaneous infection. Non-challenged pigs were used as controls. On days 1, 3 and 7 after challenge, tissues from the site of infection, and the tonsils of intranasally and the draining lymph nodes of subcutaneously challenged pigs were sampled. Immunohistological staining was used to characterize the various cell populations at the primary site of virus replication and in the lymphoid tissue. Tissue sections were stained for the T-cell markers CD2, CD3 gamma delta, CD4 and CD8, for the B-cell markers IgM, IgA and IgG, for a macrophage marker, and for PRV antigen. After challenge, PRV was detected during a shorter period in vaccinated pigs, and was less disseminated than in unvaccinated pigs. Cellular infiltrates were detected both in the nasal mucosa and the subcutaneous tissue of both unvaccinated and vaccinated pigs. Cell infiltrates, however, appeared earlier in vaccinated than in unvaccinated pigs, indicating a difference in kinetics of the primary and secondary immune response. The appearance of T-cells preceded the appearance of B-cells, but the proportion of the various subsets did not differ between unvaccinated and vaccinated pigs. These findings suggest that the early immune response in vaccinated pigs may contribute to the rapid clearance of virus at the primary site of infection. In addition, T-cells appear to have a more important role in the clearance of PRV than B-cells.

Poliovirus-specific immunoglobulin A in persons vaccinated with inactivated poliovirus vaccine in The Netherlands

In The Netherlands the inactivated poliovirus vaccine (IPV) is used for protection against poliomyelitis. It is not clear if parenteral vaccination with IPV can lead to priming of the mucosal immune system. We developed and evaluated enzyme-linked immunosorbent assays for the detection of poliovirus serotype-specific immunoglobulin A (IgA) and secretory IgA antibodies. Using these assays we examined the kinetics of the IgA response in sequential serum samples from 15 poliomyelitis patients after natural infection with serotype 3 poliovirus. In 36% of the patients IgA remained present for up to 5 months postinfection. Furthermore, we examined, in an IPV-vaccinated population, the presence of IgA antibodies in sera from young children (4 to 12 years of age; n = 177), sera from older children (between 13 and 15 years of age; n = 123), sera from healthy blood donors (n = 66), and sera from naturally immune elderly persons (n = 54). The seroprevalence of IgA to all three serotypes was low in young vaccinated children (5 to 7%), and the seroprevalence of IgA types 2 and 3 was low in older vaccinated children (2 to 3%). The seroprevalence of antibodies to type 1 was significantly higher (18%) in older children than in younger children. This higher seroprevalence is most likely explained by the persistence of IgA following infection with the serotype 1 wild-type poliovirus strain during the 1978 epidemic. In healthy adults, the seroprevalence of type 1- and type 2-specific IgA was significantly higher than that in young children. These results suggest that at least part of the IgA found in the older population is induced by infections unrelated to the IPV vaccination schedule. Finally, we found that parenteral vaccination with IPV was able to boost secretory IgA responses in 74 to 87% of a naturally exposed elderly population (n = 54). While the presence of secretory IgA in IPV-vaccinated persons has been documented previously, our findings suggest that mucosal priming with live virus is necessary to obtain an IgA response after IPV booster vaccination.

Evaluation of tests for detection of antibodies to Aujeszky's disease (pseudorabies) virus glycoprotein E in the target population

Receiver operating characteristic (ROC) curves assess the quality of tests over the entire range of test signals. We compared the ability of an ELISA to detect antibodies to Aujeszky's disease (pseudorabies) virus gE in colostrum (test A) and in a single droplet of whole blood (test B) with the results obtained in serum (gold standard) in the target population by constructing and analyzing such curves. The area under the ROC curve, which is a quantitative measure of test performance, proved to be significantly (p < 0.01) smaller in test A than in test B or the gold standard. No significant differences in the area under the ROC curve were observed between test B and the gold standard.

No massive spread of pseudorabies virus in vaccinated sow herds

In this study, we quantified transmission of PRV in 99 sow herds in which the sows were vaccinated three times a year with strain 783 O/W and found that the reproduction ratio R was 0.66, which is significantly below one. This implies that massive spread of PRV cannot occur in such herds.

Comparison of two pseudorabies virus vaccines, that differ in capacity to reduce virus excretion after a challenge infection, in their capacity of reducing transmission of pseudorabies virus

Pseudorabies virus (PRV) vaccines are often compared for their capacity to reduce virus excretion after a challenge infection. Vaccines, used for the eradication of PRV, however, should reduce transmission of PRV among pigs. The purpose of this study was to investigate whether the amount of virus excreted after a challenge infection is an accurate measure of the capacity of a vaccine to reduce transmission of PRV among pigs. Two experiments were carried out, each using two groups of 10 pigs. The pigs in group one were intramuscularly vaccinated once with the glycoprotein E (gE)-negative vaccine X, the pigs in group two with the gE-negative strain 783. Eight weeks later, 5 pigs in each group were inoculated with wild-type PRV. A gE-ELISA was used to detect PRV infection. The transmission of PRV was estimated from the number of contact infections and expressed as the reproduction ratio R. The inoculated pigs vaccinated with vaccine X shed significantly more virus than the inoculated pigs vaccinated with strain 783. However, despite the difference in virus excretion, the transmission of PRV between the two groups did not differ. We conclude that virus excretion is not an accurate measure for determining vaccine effectiveness. However, R of vaccine X (R = 0.98) was not significantly below one, whereas R of vaccine 783 (R = 0) was significantly below one. Consequently, we cannot exclude the possibility that major outbreaks of PRV occur among pigs vaccinated with vaccine X.

The influence of maternal immunity on the transmission of pseudorabies virus and on the effectiveness of vaccination

The purpose of this study was to investigate whether maternal immunity could prevent transmission of pseudorabies virus (PRV) among pigs, and whether it reduced the effectiveness of a single or double vaccination with regard to the transmission of PRV. In five experiments, the transmission of PRV, expressed as the reproduction ratio R, was compared in groups of pigs with maternal immunity and in groups of pigs without maternal immunity. Transmission of PRV among unvaccinated pigs with maternal immunity (R = 0.2) was significantly lower than among pigs without maternal immunity (R = 6.3). Furthermore, maternal immunity in young pigs prevented transmission of PRV, as R was significantly below one. In once-vaccinated groups, PRV spread extensively among pigs with maternal immunity (R = 23), but did not spread extensively among pigs without maternal immunity (R = 0.6). In twice-vaccinated groups, transmission of PRV among pigs with maternal immunity (R = 0.6) did not differ significantly from the transmission of PRV among pigs without maternal immunity (R = 0.3). Thus, a single vaccination of pigs with PRV strain 783 at 10 weeks of age, when they still possessed maternal immunity, seemed not sufficient to prevent transmission of PRV. Virus transmission could be reduced, however, if maternally immune pigs were vaccinated twice at 10 and 14 weeks of age.

Pseudorabies virus infections in pigs. Role of viral proteins in virulence, pathogenesis and transmission

This paper reviews new findings on the biological functions of pseudorabies virus (PRV) proteins. It focuses on the role of PRV proteins in the pathogenicity, immunogenicity and transmission of PRV vaccine strains in pigs. Furthermore, it evaluates potential risks that are connected with the use of PRV vector strains. Special emphasis is placed upon the spread of genetically engineered vaccine strains within pigs or between pigs.

Lack of serum antibodies against glycoprotein E in pseudorabies virus-immune pigs infected with wild-type virus

OBJECTIVE

To examine whether pigs with solid immunity against pseudorabies virus (PRV) could harbor latent infection with wild-type PRV without developing antibodies against glycoprotein E (gE), which is used as a marker protein to differentiate pigs that have been vaccinated from pigs infected with wild-type PRV.

ANIMALS

Specific-pathogen-free pigs that were seronegative for antibodies to PRV.

PROCEDURE

Oropharyngeal swab specimens were collected, and virus content was measured, Serum samples were obtained 1 week before and 2 and 4 weeks after challenge exposure. Four weeks after challenge exposure, pigs were slaughtered; various tissues were collected for virus isolation, and DNA was analyzed by polymerase chain reaction.

RESULTS

Of the intranasally inoculated pigs, only 1 pig shed virus (for 1 day) but none developed antibodies directed against gE. Of the inoculated IM pigs, 3 pigs shed virus (for several days) and 5 developed antibodies directed against gE. One pig did not shed virus and did not develop detectable gE antibodies. However, variable amounts of wild-type virus DNA were detected in various tissues.

CONCLUSIONS

Immunized pigs can be infected with wild-type PRV without being detected by the gE-specific ELISA, which is routinely used to discriminate between infected and vaccinated pigs. The implication for eradication programs is that these pigs might be a source of new outbreaks.

Assessment of the quality of tests for the detection of antibodies to Aujeszky's disease virus glycoprotein gE in a target population by the use of receiver operating characteristic curves

The performance of tests for the detection of antibodies to Aujeszky's disease virus glycoprotein E (gE) in a target population was evaluated by constructing and analysing receiver operating characteristic (ROC) curves. These curves assess the discriminating ability of a test over the entire range of test signals. The advantages of applying the analysis to a sample of the target population (all commercial pigs in the Netherlands), as compared to using a panel of test sera, are that the estimates of sensitivity and specificity, the comparisons between tests and the choices of the cut-off values are all relevant for the target population. The results of a gE-ELISA in colostrum (test A) and in a single droplet of whole blood (test B) were compared with the results obtained with the same ELISA in serum (gold standard). The area under the ROC curve, which is a quantitative measure of test performance, was significantly (P < 0.01) smaller with test A than test B or the gold standard, indicating that test B performed better than test A. No significant difference was observed between test B and the gold standard.

No major outbreaks of pseudorabies virus in well-immunized sow herds

In this study we quantified the transmission of pseudorabies virus (PRV) in well-immunized sow herds in The Netherlands. In three herds, sows were tested for antibodies to gE of PRV every time after they had been transported to another barn (survey A). In 99 other herds, sows were tested simultaneously once or twice yearly (survey B). We observed six introductions in survey A and 53 in survey B. None of these introductions resulted in extensive spread of the virus. The reproduction ratio R, which is defined as the mean number of secondary infections caused by one infectious sow, was significantly less than one. We conclude that PRV can be eliminated from sow herds by vaccination.

Cell-mediated immunity to pseudorabies virus: cytolytic effector cells with characteristics of lymphokine-activated killer cells lyse virus-infected and glycoprotein gB- and gC-transfected L14 cells

We examined cytolytic cells that lyse pseudorabies virus (PRV)-infected cells in pigs. In vitro stimulation of peripheral blood mononuclear cells from PRV-immune pigs with live PRV generated cells that lysed PRV-infected immortalized B cells. Several lines of evidence indicated a major contribution of non-major histocompatibility complex (MHC)-restricted cytolytic cells, which displayed characteristics of natural killer (NK) or lymphokine-activated killer cells: cytolysis was non-MHC-restricted, depended on CD2+CD4-CD8bright- (or CD2+CD4-CD8dull+) cells, was strongly augmented by in vitro antigenic stimulation and was not limited to virus-infected cells, i.e. the NK cell-susceptible target cell line K562 was also lysed. Cytolytic cells were also generated by in vitro antigenic stimulation with UV-inactivated PRV. Target cells transfected with and stably expressing PRV gB or gC were lysed to the same degree as PRV-infected target cells.

An indirect double-antibody sandwich enzyme-linked immunosorbent assay (ELISA) using baculovirus-expressed antigen for the detection of antibodies to glycoprotein E of pseudorabies virus and comparison of the method with blocking ELISAs

Antibodies in porcine sera against glycoprotein E (gE) of pseudorabies virus (PRV) are usually measured in blocking enzyme-linked immunosorbent assays (ELISAs) with one or two murine monoclonal antibodies (MAbs) directed against gE. Our aim was to develop a confirmation assay which is based on another principle and which is able to detect antibodies directed against most potential binding sites on gE with high specificity. Therefore, we developed an indirect double-antibody sandwich assay (IDAS) using recombinant gE expressed by baculovirus (BacgE960). A fragment of the gE gene consisting of nucleotide positions +60 to +1020 of gE, coding for the major antigenic sites of gE but not the transmembrane region, was cloned behind the signal sequence of PRV gG and the p10 promoter in a baculovirus vector. Immunoblot analysis showed that the expressed protein reacted with MAbs directed against five of the six antigenic sites on gE. Although the conformation of some antigenic sites, notably antigenic sites E and C, was not identical to their natural conformation, the expressed protein bound gE-specific antibodies in porcine sera in Western blots (immunoblots) and ELISAs. For the IDAS, a coating MAb directed against the nonimmunodominant antigenic site A on gE was chosen. A major obstacle in binding ELISAs, such as the IDAS, appeared to be the high nonspecific binding activity observed in porcine sera. As a result, sera could be tested only in relatively high dilutions in the BacgE960 IDAS, in contrast to the testing of sera in blocking ELISAs. The sensitivity and specificity of the newly developed BacgE960 IDAS were evaluated and compared with those of five commercially available blocking ELISAs by using several sets of sera of known PRV disease history. The BacgE960 IDAS assay had a high diagnostic specificity and a moderate sensitivity. The five blocking ELISAs differed remarkably in sensitivity and specificity, thereby illustrating the need for standardization and confirmation. We conclude that the BacgE960 IDAS is a useful and specific additional (confirmatory) test for the detection of antibodies to gE.

Transmission of two pseudorabies virus strains that differ in virulence and virus excretion in groups of vaccinated pigs

OBJECTIVE

To determine whether 2 pseudorabies virus (PRV) strains that differ in virulence differ in transmission among vaccine strain 783-inoculated pigs.

DESIGN

Three experiments were conducted, each with 2 groups of 10 pigs inoculated with the glycoprotein E-negative vaccine 783. In the first 2 experiments, half of one group was inoculated with the mildly virulent strain Sterksel, and half of the other group was inoculated with the virulent strain NIA-3. The remaining pigs were contact-exposed to the inoculated pigs. In the third experiment, 2 pigs in each group were inoculated with strain NIA-3, and the other 8 pigs in each group were contact-exposed to these 2 pigs.

ANIMALS

Specific-pathogen-free pigs that were sero-negative for antibodies to PRV.

PROCEDURE

Estimation of the transmission of virus in each group was based on a stochastic model, in which the observable variable was the number of contact infections. The sole parameter of the model was the reproduction ratio theta. A glycoprotein E ELISA was used to determine whether infection occurred. Virus excretion in the oropharyngeal fluid was determined by plaque assay to measure infectivity.

RESULTS

Vaccinated pigs had a significant difference in virus excretion between the mildly virulent and virulent strains. Sterksel strain-inoculated pigs shed significantly more virus than did NIA-3 strain-inoculated pigs. Despite this difference in virus excretion, the 2 strains did not differ in transmission.

CONCLUSIONS

Both PRV strains would be eliminated from a population of vaccine strain 783-inoculated pigs.

Comparison of the protective efficacy of recombinant pseudorabies viruses against pseudorabies and classical swine fever in pigs; influence of different promoters on gene expression and on protection

The glycoprotein E (gE) locus in the genome of pseudorabies virus (PRV) was used as an insertion site for the expression of glycoprotein E1 of classical swine fever virus (CSFV). Transcription of E1 in the recombinants M401, M402 or M403 was regulated by the gD promoter of PRV, the immediate early gene promoter of human cytomegalovirus, or the gE promoter of PRV, respectively. Groups of four pigs were vaccinated once intramuscularly with 10(6) plaque forming units (p.f.u.) of the recombinant viruses and challenged intranasally with 100 50% lethal doses of virulent CSFV and with 10(5) p.f.u. of virulent PRV. All pigs vaccinated with M402 were fully protected against both classical swine fever and pseudorabies.

Experimental quantification of transmission of genetically engineered pseudorabies virus

There is concern that live pseudorabies virus (PRV) vaccine or PRV vector vaccine strains may spread from vaccinated to unvaccinated pigs. Moreover, it is feared that recombining PRV vaccine strains with related vaccine or wild-type strains may lead to spread and survival of recombinant PRV. To learn more about to what extent different PRV vaccine strains could spread we used a previously described experimental model to study the transmission of intranasally inoculated PRV mutant strains under experimental conditions. We used PRV strains that lacked glycoprotein E (gE) or thymidine kinase (TK), and a PRV vector vaccine (gE-, TK-, gG-) that expresses the glycoprotein E1 (E1) of hog cholera virus. In addition, we investigated whether intranasally co-inoculated gE-negative and gE-positive PRV strains competed in transmission among pigs. The extent of transmission was estimated using the reproduction ratio R. This ratio has a threshold property; when R1, the infection can spread; when R < 1, the infection will disappear. We found that R for a gE-negative strain was 10.1, and R for a TK-negative strain was 5. Furthermore, the R for the vector vaccine (gE-, TK-, gG-) expressing E1 was 0.18, and did not differ significantly from the R for the control strain without E1. The R of gE-negative strain was significantly 1 (P = 0.0005). Co-inoculation with a gE-positive field strain did not prevent the transmission of a gE-negative strain. This study shows that a small-scale experiment can be used to estimate the transmission of genetically engineered organisms in their host species. The results of this study indicate that the deletion of gE alone or TK alone is not enough to prevent spread of PRV among susceptible pigs, and that transmission of gE-negative PRV is not firmly limited by co-presence of a gE-positive strain.

Development and antigen specificity of the lymphoproliferation responses of pigs to pseudorabies virus: dichotomy between secondary B- and T-cell responses

To better understand the contribution of T cells to the immunity of pigs to pseudorabies virus (PRV), we examined the lymphoproliferation response to this virus. Depletion studies demonstrated that both CD2+CD8+ and CD2+CD4+ cells contributed to lymphoproliferation, but to varying degrees upon stimulation with live and ultraviolet (UV) light-inactivated PRV. Flow cytometric analysis revealed the emergence of both CD2+CD8+ and CD2+CD4+ lymphoblastoid cells. To examine the contribution of specific viral proteins, we prepared immortalized porcine B cells of haplotype d/d that stably expressed a single PRV protein, and used these cells for in vitro stimulation of lymphocytes from PRV-immune miniature pigs of the same haplotype. Cells expressing PRV gB or gC induced proliferation. An immunization/challenge experiment showed that the lymphoproliferation response was stronger upon immunization with the virulent NIA-3 strain than with the attenuated Bartha strain. Upon challenge inoculation, the NIA-3-immunized pigs were almost completely immune, in contrast to the Bartha-immunized pigs. Such poorly protected pigs showed secondary B- and T-cell immune responses upon challenge. In contrast, the better protected NIA-3-immunized pigs did not show a secondary B-cell response. However, they developed a secondary lymphoproliferation response, which was quicker and stronger than in the Bartha-immunized pigs. This dichotomy between secondary B- and T-cell responses indicates that an effective T-cell memory response is able to quickly eliminate challenge virus in immune pigs, so preventing a secondary B-cell response.

The US3-encoded protein kinase from pseudorabies virus affects egress of virions from the nucleus

We examined the influence of inactivation of various genes located in the unique short (U(S)) region of pseudorabies virus on virus replication and assembly in porcine nasal mucosa explant cultures. The following strains were used: the virulent wild-type strain NIA-3, and strains derived from NIA-3 containing a mutation inactivating the genes encoding either the US3-encoded protein kinase (PK), gG, gD, gI, gE, the 28 kDa ('28K') protein (single mutant), or the 28K and 11 kDa ('11K') proteins (double mutant). In addition a wild-type rescuant was used, which was generated by marker rescue from a PK- mutant. All virus strains infected nasal epithelium and had invaded the stroma after approximately 24 h. The morphogenesis in nasal epithelium cells of two PK- mutants showed the most striking differences compared to the parent NIA-3 strain and the other mutant strains. The changes could be ascribed to the US3-encoded PK because the rescue mutant showed a similar morphogenesis to wild-type NIA-3. The transmembrane transport of the PK- mutants was impaired at the outer nuclear membrane which resulted in an accumulation of virions in the perinuclear space. These results suggest that proteins, phosphorylated by the US3-encoded PK, are involved in debudding of virus particles at the outer nuclear membrane. This defect in the transport of the US3 mutant probably explains their reduced replication in vitro. The gG-, gD-, gI-, gE-, 28K- and 11K- mutant strains showed minor or no changes in viral assembly. Thus the reported decreased virulence of the gD-, gI- and gE- mutants was, in contrast to that of the PK- mutants, not associated with clear alterations in morphogenesis.

Role of viral proteins and concanavalin A in in vitro replication of pseudorabies virus in porcine peripheral blood mononuclear cells

We examined the capability of pseudorabies virus (PRV) to replicate in vitro in porcine peripheral blood mononuclear cells (PBMC) and characterized the phenotype of infected cells. In addition, we investigated whether inactivation of various PRV proteins or the expression of a foreign gene affected this replication. Finally, we studied the replication of PRV strains in concanavalin A (Con A)-stimulated lymphocytes. The replication of PRV mutants with inactivated glycoproteins gE or gG, thymidine kinase (TK), ribonucleotide reductase (RR) or US3-encoded protein kinase (PK), and the replication of PRV vector strains expressing the envelope glycoprotein E1 of hog cholera virus (HCV) were studied. By adherence of PBMC to plastic, monocytes and lymphocytes were largely separated. Infected monocytes were analysed with an immunostaining monolayer assay and infected lymphocytes were analysed with immunofluorescence staining and flow cytometry. We found that the wild-type NIA-3 virus replicated in both lymphocyte and monocyte cultures. NIA-3 infected relatively more monocytes (> 90%) than non-adherent B cells (46-65%) and T cells (17-28%); approximately equal numbers of CD4+ and CD8+ T cells were infected. Although E1 is probably involved in adsorption of HCV to host cells, the expression of E1 by PRV vector strains did not change the level of replication. Inactivation of TK and RR, but not inactivation of gE, gG or PK, severely affected the replication in both monocytes and lymphocytes. Con A stimulation of lymphocytes restored the reduced replication of the TK mutant, but not of the RR mutant. Moreover, Con A stimulation of lymphocytes reduced the replication of the wild-type NIA-3 virus. We concluded that both viral TK and RR activity are important for efficient replication of PRV in resting lymphocytes. Furthermore, Con A-stimulated lymphocytes can restore the viral TK defect and PRV replication can also be influenced by cellular metabolism.

Interaction of pseudorabies virus with immortalized porcine B cells: influence on surface class I and II major histocompatibility complex and immunoglobulin M expression

We examined whether the L14 cell line, an immortalized B cell line originating from inbred miniature pigs of the MHC haplotype d/d, could be useful to study T cell responses of pigs to pseudorabies virus (PRV). Compared with porcine kidney cells, the replication of PRV in L14 cells was slower and yielded lower quantities of infectious virus, which agrees with the reported poor replication of PRV in peripheral blood lymphocytes of swine. The virus yield and the number of L14 cells expressing the viral glycoprotein gE were both maximal at 48 h postinfection, when approximately 90% of all viable L14 cells expressed gE. Morphologically detectable effects of PRV replication in L14 cells were not obvious, but the number of viable cells at 72 h postinfection was lower in infected cultures than in uninfected cultures. Major histocompatibility complex (MHC) class I and II antigen expression was significantly higher at different time points postinfection on infected than on uninfected L14 cells. In contrast, expression of IgM appeared very slightly reduced on infected L14 cells, indicating a selective influence of PRV on cellular protein expression. PRV-infected L14 cells were lysed by lymphocytes from PRV-immune minipigs of MHC haplotype d/d, indicating their usefulness in in vitro cytolytic assays.

Genetic recombination of pseudorabies virus: evidence that homologous recombination between insert sequences is less frequent than between autologous sequences

We studied in vivo recombination between a thymidine kinase (TK) negative, glycoprotein E (gE) negative, attenuated strain and a virulent strain of pseudorabies virus (PRV) in pigs. To simplify the detection of recombination we inserted different but overlapping (375 bp) parts of the E1 gene of classical swine fever virus into the gG locus of both virus strains. Recombination between the E1 sequences of these viruses results in reconstitution of the complete E1 coding sequence and expression of the E1 protein. Since E1 is highly immunogenic, we expected to detect in vivo recombination in co-inoculated pigs by the presence of serum antibodies against E1. However, after co-inoculation of pigs with high doses of both virus strains, we were unable to detect antibodies against E1, suggesting that in vivo recombination did not occur or remained below the detection limit. Analysis of individual progeny viruses showed that 13 out of 995 (1.3%) possessed a recombinant TK-negative gE-positive phenotype. In contrast, no E1-positive viruses were detected among 5000 analyzed. This result showed that in vivo recombination between the two virus strains did occur, but was much more frequent between the TK and gE loci than between the E1 sequences. Similar results were obtained in in vitro recombination experiments in which possible growth differences between the various virus strains were excluded. The different recombination frequencies could not be attributed to the difference in distance of the genetic loci since recombination between mutations at a distance of 266 bp in the TK gene occurred as frequent as recombination between the TK and gE genes which are separated by approximately 60 kilobasepairs. These results indicate that some property of the E1 sequence and/or the location of the E1 sequence within the PRV genome affects the frequency of recombination.