Previous reports from this laboratory identified bursaderived lymphocytes (B cells) and non-B cells as the predominant cell types respectively involved in the early cytolytic and subsequent latent infection of chickens with Marek's disease virus (MDV). It was not known whether these differences were qualitative or quantitative or if the method for detection of latent infection (viral antigen production after 48 h of in v i h o cultivation) was sensitive enough. To further define the cells involved in the various phases of MDV infection, we used monoclonal antibodies which specifically react with B cells, or T cells, or la-antigen-bearing cells. Dual fluorescence tests to detect surface markers and viral internal antigen (VIA) were conducted
Immune lymphocyte-mediated cytotoxicity (ILMC) was evaluated in dogs after intranasal exposure to one of the following three virulent strains of canine distemper virus: Cornell A75/17, Ohio R252, and Snyder Hill. Cytotoxicity was tested with peripheral blood lymphocytes as effector cells and primary dog testicle cells that were matched for histocompatibility as target cells. A strong correlation was found between ILMC and the course of the infection. Dogs that succumbed to encephalitis with any of the strains had little or no ILMC, whereas dogs that recovered had the highest activity. In the intermediate range were dogs with a delayed or reduced ILMC which developed persistent but subclinical central nervous system infections. A significant difference in onset, peak, and duration of ILMC was observed in dogs infected with different strains of canine distemper virus. ILMC responses began at 14 days postinfection (p.i.), reached a peak at 21 to 28 days p.i., and returned to preinoculation levels by 63 to 70 days p.i. in canine distemper virus A75/17and R252-infected dogs. In contrast, ILMC in canine distemper virus Snyder Hill-infected dogs began at 10 days p.i., peaked by 14 to 17 days p.i., and approached preinoculation levels by 28 days p.i. Antiviral immunity as measured by ILMC appears to be a critical factor in determining the outcome in canine distemper virus-infected hosts. Furthermore, for certain viral biotypes, a delayed ILMC response correlated with persistent infection of the central nervous system.
Kilham rat virus (KRV) infection of BB/Wor diabetes-resistant (DR) RT1(u) rats induces autoimmune diabetes without direct cytolytic infection of pancreatic beta-cells and is a new model of virus-induced IDDM. To investigate genetic susceptibility to KRV-induced diabetes, major histocompatibility complex congenic and other inbred rats were infected with the virus and studied for the appearance of diabetes and insulitis. KRV infection alone induced insulitis, selective beta-cell necrosis, and diabetes in BB/Wor DR and LEW1.WR1 (RT1 A(u) B/D(u) C(a)) but not other rats. Thus, KRV, an environmentally ubiquitous rat parvovirus, can precipitate autoimmune diabetes in rats that are not susceptible to spontaneous diabetes. If rats are injected with poly(I.C) immediately before KRV infection, diabetes frequency increases to >90% in BB/Wor DR and LEW1.WR1 rats, and PVG.RT1(u) rats are converted from KRV-resistant to KRV-susceptible status. Susceptibility to KRV-induced diabetes thus requires the presence of class I A(u) and class II B/D(u) gene products, which are shared by DR, LEW1.WR1, and PVG.RT1(u) rats. The RT1(u) haplotype is not sufficient for susceptibility, however, because while WF rats are RT1(u), they resist KRV-induced diabetes. If rats are depleted of RT6.1+ regulatory T-cells before KRV infection, the frequency of diabetes is dramatically increased in DR and LEW1.WR1, but not PVG.RT1(u) or other rats. These data confirm a regulatory role of RT6.1+ T-cells in diabetes induction, but indicate that they may not operate as such in all rat strains. KRV-induced diabetes is T-cell-mediated: DR and LEW1.WR1 rats are protected from diabetes by treatment with monoclonal antibodies directed against alpha beta T-cell receptor (TCR)+, CD5+, and CD8+ T-cells. Concanavalin A-activated spleen cells from KRV-infected DR rats adoptively transfer diabetes and insulitis into class II(u) compatible rats, suggesting that KRV infection of susceptible rats leads to the activation of diabetogenic class II(u) restricted T-cells. The ability of a common rat virus to initiate IDDM in multiple strains of rats strengthens the possibility that viruses may also initiate IDDM in human populations.
Pairs of specific pathogen free dogs were immunized with two injections of heat inactivated canine distemper virus (CDV) or one injection of a live CDV or live measles virus (MV) vaccine. Three unimmunized dogs were used as controls. All 9 dogs were challenged with virulent CDV (Snyder Hill strain). The three unimmunized dogs developed severe signs of disease with a lethal infection in one. The two dogs immunized with live CDV vaccine developed a strong humoral as well as cellular immune response after immunization and were protected against virus replication. Animals immunized with either inactivated CDV or modified live MV failed to develop a measurable cellular immune response after immunization and had a comparatively weak humoral immune response to distemper antigens. They showed mild signs of infection after challenge and responded with strong anamnestic cellular and humoral immunity. The measles vaccine immunized dogs had a moderate serum titer of measles hemolysin-inhibiting antibodies which, after exposure to distemper virus, was boosted to high levels. It is proposed that this response plays a role in the mitigation of the virulent distemper infection in these animals.
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