Induction of secondary immune response by reactivated Japanese encephalitis virus in latently infected mice.

Development of secondary immune response has been studied following reactivation of latent Japanese encephalitis virus (JEV) infection in mice. The virus could be reactivated in 43% of the latently infected mice at 27 weeks p.i. by treatment with cyclophosphamide. The reactivated virus induced delayed-type hypersensitivity (DTH) and leucocyte migration inhibition (LMI) responses in mice, with peak activity on Day 5 post-reactivation (p.r.). The DTH persisted at low levels for long periods. Humoral immunity measured by haemagglutination-inhibiting antibody showed a four-fold rise in antibody titres. DTH was transferable by immune spleen cells for 5 days p.r. only. It is, therefore, concluded that JEV reactivation generates a quick and short-lived secondary immune response.     

Distinction between suppressors of the delayed-type hypersensitivity and the humoral response to sheep erythrocytes.

Suppressors for both delayed-type hypersensitivity (DTH) and the humoral immune response could be simultaneously induced in the spleens of mice by immunization with a high dose of SRBC. Normal recipient mice of the spleen cells from donors immunized 5 days previously elicited depressed DTH or humoral response when immunized with SRBC. The suppressive activity was found to reside in T not B enriched fraction. Four hundred rad irradiation of the primed spleen cells resulted in complete loss of DTH suppressor activity, but only in some reduction of the suppressor activity for the humoral response. In contrast, hydrocortisone treatment of the donor mice caused no loss of DTH suppressor activity while approximately half of the suppressive activity for anti-SRBC PFC response was lost. Adult thymectomy prevented completely the induction of the DTH suppressor in contrast to little loss of the suppressor activity for the humoral response. DTH suppression was antigen-specific for the induction, but nonspecific for the expression. However the suppression of the humoral response was antigen-specific not only for the induction but also for the expression. In addition, DTH suppressor was capable of suppressing both the induction and expression of DTH while the humoral response was suppressed only in the induction stage by the suppressor.     

Induction of suppressor cells in Japanese encephalitis virus infected mice

Adoptive transfer of spleen cells obtained from mice primed with Japanese encephalitis virus (JEV) suppressed IgM antibody plaque forming cells (PFC) against JEV in the spleen. Similar suppression of PFC was also shown in vitro by adding primed spleen cells to JEV-stimulated spleen cell cultures. The suppressor activity appeared sharply in the third week after priming and persisted up to 6 weeks. By using various cell separation procedures it was found that the suppressor activity resided in the T cell enriched fraction and not in B cells or macrophages. Sensitivity of the cells to treatment with anti-Thy 1.2 antiserum and complement confirmed that suppressor cells were T lymphocytes. It was noted that the suppression was effective against dengue virus antigen also. Our findings thus show generation of suppressor T lymphocytes in JEV-infected mice.     

Induction of suppressor cells in Japanese encephalitis virus infected mice.

Adoptive transfer of spleen cells obtained from mice primed with Japanese encephalitis virus (JEV) suppressed IgM antibody plaque forming cells (PFC) against JEV in the spleen. Similar suppression of PFC was also shown in vitro by adding primed spleen cells to JEV-stimulated spleen cell cultures. The suppressor activity appeared sharply in the third week after priming and persisted up to 6 weeks. By using various cell separation procedures it was found that the suppressor activity resided in the T cell enriched fraction and not in B cells or macrophages. Sensitivity of the cells to treatment with anti-Thy 1.2 antiserum and complement confirmed that suppressor cells were T lymphocytes. It was noted that the suppression was effective against dengue virus antigen also. Our findings thus show generation of suppressor T lymphocytes in JEV-infected mice.     

Antigen-specific suppressor factors produced by T cell hybridomas for delayed-type hypersensitivity.

This study describes the generation of T hybridoma lines which secret factors specifically suppressing delayed-type hypersensitivity (DTH) to sheep red blood cells (SRBC). AKR strain-derived T lymphoma BW 5147 cells were fused with spleen cells from mice primed with SRBC and containing antigen-specific T suppressor cells for DTH. Supernants from the derived hybridomas were tested for suppression of either expression of induction of DTH to SRBC. Six lines produced specific suppressor activity for the expression of DTH; 4 lines produced suppressor activity for the induction of DTH of which only one line was antigen-specific. These lines were passaged in normal AKR mice, and the serum obtained had activity up to 10(-4) dilution. The factor was effective across the H-2 barrier.     

Dengue virus-induced thymus-derived suppressor cells in the spleen of mice.

Adoptive transfer of spleen cells obtained from mice given three weekly i.p. doses of dengue type 2 virus (DV) suppressed DV antigen-specific antibody secretion as detected by the Jerne plaque technique. This suppression was produced by non-glass-adherent cells but not by glass-adherent cells. Immune spleen cells depleted of macrophages by carbonyl iron treatment had higher suppressor activity. Immune spleen cell homogenate could transfer the activity equally well. The immune spleen cells were separated into T and B lymphocytes by a nylon wool column. B lymphocytes had no suppressor activity; almost all the suppressor activity was present in T lymphocytes. Thus, macrophages and B lymphocytes had no suppressor activity; it was mediated by T lymphocytes through soluble factors.     

Induction and Ly phenotype of suppressor T cells in mice during primary infection with dengue virus.

Infection of mice with dengue-4 virus produced a significant, transient immunosuppression of the delayed-type hypersensitivity (DTH) response to sheep red blood cells (SRBC). Suppression was noted on day 3 after infection, was maximal on day 5 and was no longer evident on day 13 after infection. The suppressive effect was transferable to normal mice by viable spleen cells from immune mice but not by immune serum. These cells appeared to be present in the spleens of infected mice as early as day 1 after infection and were still detectable on day 7. No evidence was obtained that suppression was mediated by a soluble factor. Further characterization of the cells which could transfer suppression showed them to be T cells possessing both Ly-1 and Ly-2 surface antigens. These data suggest that there may exist two types of T suppressor cells or that, alternatively, an interaction between Ly-1+ and Ly-2+ cells was required to produce suppression. The significance and implications of these findings are discussed.     

Characterization of a third-order suppressor T cell (Ts3) induced by cryptococcal antigen(s).

Previous studies from our laboratory have shown that a high dose of cryptococcal culture filtrate antigen (CneF) administered intravenously induces a complex suppressor cell cascade which down-regulates the cell-mediated immune response to Cryptococcus neoformans antigens. The primary objective of this investigation was to determine whether a suppressor cell induced by immunization is required for efferent suppression of the cryptococcal delayed-type hypersensitivity (DTH) response. Our approach to this problem was to immunize CBA/J mice with CneF emulsified in complete Freund adjuvant and then 6 days later to collect spleen cells from the immunized mice and adoptively transfer these cells along with C. neoformans-specific second-order suppressor T cells (Ts2) to naive syngeneic recipients at the time of footpad challenge of the recipients with CneF. To establish which populations of cells in the spleens of immunized mice play a suppressive role, mass cytolysis with specific antibodies and complement was performed before the spleen cells were transferred to naive animals. Since the phenotype of the cells responsible for the transfer of the cryptococcal DTH response had not been completely determined, we first demonstrated that the cells responsible for DTH were L3T4+ Lyt-2- cells. Subsequently, we established that a Thy-1+ L3T4- Lyt-2+ I-J+ cell population induced by immunization was required along with C. neoformans-specific Ts2 cells for efferent suppression of the cryptococcal DTH response. In addition, we demonstrated that the suppressor cells in the immune cell population were derived from cyclophosphamide-sensitive precursors. These data indicate that a third suppressor cell population is required for efferent suppression of the cryptococcal DTH response. As in the azobenzenearsonate and 4-hydroxy-3-nitrophenyl acetyl hapten suppressor models, the Ts2 cells in the circuit mediate their effects through this third suppressor component. Since the mode of induction and the phenotype of the third C. neoformans-specific suppressor cells are similar to those reported for Ts3 cells in other antigen-specific suppression models, we referred to this third suppressor cell in the C. neoformans-specific suppressor cell cascade as a Ts3 cell.     

High frequency detection of different T-cell subsets in mice by a modified virus plaque assay

Different T-cell subsets participating in immune responses were detected at a high frequency by a modified virus plaque assay (VPA). By using the modified VPA, different activated T-cell subsets generated in primary immune responses, helper and suppressor T cells participating in antibody formation, and effector T cells involved in the delayed-type hypersensitivity (DTH) reaction were enumerated directly without in vitro antigen stimulation. The frequency of detection in immune systems used was 7.5-17.7 V-PFC/10(3) spleen cells. Although neither helper T cells for antibody formation nor effector T cells for DTH reaction were detected as V-PFC at a high frequency by the original VPA, it was also found in secondary immune response that Lyt 1 positive, antigen-specific helper and effector T-cell subsets, and cyclophosphamide (CY)-resistant precursors were enumerated at a high frequency by the modified VPA when the received in vitro antigen stimulation, and that the proliferative stage of these cells was critical for the development of V-PFC.     

Antigen-specific T-helper cells abrogate suppression in Trypanosoma cruzi-infected mice.

The ability of antigen-specific T-helper (Th) cells to enhance direct plaque-forming cell responses in spleen cells from Trypanosoma cruzi-infected C57BL/6 mice was investigated at various times during the course of infection from day 7 to day 230. The injection of antigen-specific Th cells in vivo or the addition of antigen-specific Th cells in vitro was effective in enhancing direct plaque-forming cell responses, except at the time of the most intense suppression during the acute phase of infection (i.e., day 28). The ability of antigen-specific Th cells to overcome nonspecific immunosuppression was due not only to the activity of antigen-specific Th cells added to Mishel-Dutton cultures but also to activation of resident T cells. Thus, antigen-specific Th cells and resident T cells act in concert to produce enhanced direct plaque-forming cell responses. The effect of plastic-adherent spleen cells from infected mice on the ability of antigen-specific Th cells to stimulate anti-sheep erythrocyte responses of normal spleen cells was examined because macrophages have been shown to have an immunoregulatory role during the course of experimental American trypanosomiasis. Increasing numbers of macrophages from infected mice caused increased immunosuppression of normal spleen cells that could not be overcome with the addition of primed Th cells. It can be concluded from these data that antigen-specific Th cells can potentiate immune responses in mice infected with T. cruzi but that highly active suppressor macrophages can inhibit the expression of these primed Th cells.     

Immunological memory in latent Japanese encephalitis virus infection.

Long term B-cell memory to Japanese encephalitis virus (JEV) in latently infected mice was investigated by adoptive cell transfer. Both IgM and IgG memory were elicited by antigen challenge or cyclophosphamide induced reactivation of virus. A weak antigen-specific IgM response for a brief period and a strong IgG response were detected in Swiss albino mice exposed to secondary infection. A correlation between the secondary IgM antibody and protection against JEV challenge was observed in adoptive transfer experiments. This was abrogated by pretreatment of the serum with 2-mercaptoethanol. Similarly secondary immune splenic T-cells up to day 5 post-reactivation provided protection. These results suggest that a long term antigen-specific IgM and IgG memory was induced by JEV challenge in latently infected mice. Further, the role of IgM antibody and T-cells in the response of mice to secondary JEV infection has been shown.     

Immunological memory in latent Japanese encephalitis virus infection

Long term B-cell memory to Japanese encephalitis virus (JEV) in latently infected mice was investigated by adoptive cell transfer. Both IgM and IgG memory were elicited by antigen challenge or cyclophosphamide induced reactivation of virus. A weak antigen-specific IgM response for a brief period and a strong IgG response were detected in Swiss albino mice exposed to secondary infection. A correlation between the secondary IgM antibody and protection against JEV challenge was observed in adoptive transfer experiments. This was abrogated by pretreatment of the serum with 2-mercaptoethanol. Similarly secondary immune splenic T-cells up to day 5 post-reactivation provided protection. These results suggest that a long term antigen-specific IgM and IgG memory was induced by JEV challenge in latently infected mice. Further, the role of IgM antibody and T-cells in the response of mice to secondary JEV infection has been shown.     

T-Cell Effector Function and Unresponsiveness in the Murine Lymphocytic Choriomeningitis Virus Infection

When the virus dose is increased from 10(2) (low dose) to 10(4) LD50 (high dose) a fatal lymphocytic choriomeningitis virus (LCMV) infection is changed into a subclinical one, and a selective virus-specific delayed-type hypersensitivity (DTH) unresponsiveness is induced, while the cytotoxic T-cell response remains essentially unchanged. When low-dose spleen effectors were transferred intravenously into intracerebrally infected high-dose mice, fatal LCM disease occurred, which means that infected central nervous system target structures in these animals are sensitive to virus-specific T cells. When low-dose cells were transferred to intravenously infected high-dose mice, these animals regained their TD function (the effect of T cells mediating DTH). Since this indicates that the survival of intracerebrally infected high-dose mice is intimately linked with the absence of virus-specific DTH reactivity, a search for T suppressor (TS) activity in these animals was performed by transferring high-dose spleen cells to lethally (intracerebrally) infected low-dose recipients. In this way we obtained an afferent suppression, which was not H-2 restricted, but was abrogated when the spleen cells were pretreated with neutralizing anti-LCMV serum, indicating a suppressive effect of virus transferred with the infected cells. When tolerance induction was attempted with virus alone, a potentially fatal immune reaction could be altered to unresponsiveness (i.e. survival) as late as 4 days after an otherwise lethal infection with LCMV. The results indicate that the maturation of the virus-specific TD response is sensitive to large amounts of virus antigen. We conclude that this impairment and the resulting DTH unresponsiveness is due to a clonal deletion or anergy rather than to the effect of TS cells, and that the TD effector function is critical to the development of fatal LCM disease.     

MHC- and Igh-unrestricted interaction between L3T4+, Lyt-2- Ts inducer cells and L3T4-, Lyt-2+ Ts effector cells is required for T cell-dependent suppression of DTH to histocompatibility antigens

This paper describes the characteristics of T suppressor inducer (Ts ind) cells which can interact with T suppressor effector (Ts eff) cells and thereby can account for suppression of delayed-type hypersensitivity (DTH) to alloantigens. Adoptive transfer of spleen cells from mice intravenously (i.v.) injected with allogeneic spleen cells one day earlier induced an antigen-specific state of suppression in the recipients. This became apparent when DTH was induced by subcutaneous (s.c.) immunization of the recipients three days after transfer. The induction of suppression after adoptive transfer of spleen cells required Thy-1+, L3T4+, Lyt-1+2- cells. These cells that by themselves did not exert a suppressive effect induced a state of suppression in recipient mice by activation of recipient-type Ts eff cells. Therefore, the former cell type was classified as Ts ind cell. When athymic nude mice were used as recipients, Lyt-2+ precursors of Ts eff cells had to be transferred together with the Ts ind cells to induce a state of suppression in these mice. The Ts ind cells could activate Ts eff cells in MHC- and Igh-incompatible recipients. The results are discussed in relation to previously described immunoregulatory T cell pathways.     

T-T cell interaction in the in vitro induction of delayed-type hypersensitivity (DTH) responses: demonstration of vaccinia virus-reactive helper T cell activity involved in enhanced induction of DTH responses

C3H/HeN mice were inoculated i.p. with viable vaccinia virus to generate virus-reactive helper T cell activity. 850R X-irradiated spleen cells from vaccinia virus-primed or unprimed mice as helper cells were stimulated in vitro with either trinitrophenyl (TNP)-modified syngeneic spleen cells (TNP-self), vaccinia virus-infected spleen cells (virus-self), or cells modified with TNP subsequent to virus infection (virus-self-TNP) in the presence of normal C3H/HeN spleen cells (responding cells). After 5 days of culture, effector cells were tested for anti-TNP delayed-type hypersensitivity (DTH) responses by adoptive transfer into footpads of syngeneic C3H/HeN recipient mice together with TNP-self. The results demonstrate that spleen cells from virus-primed mice failed to enhance anti-TNP DTH responses when in vitro stimulation was provided by either virus-self or TNP-self alone. In contrast, spleen cells from vaccinia virus-primed mice, but not from unprimed mice, could augment anti-TNP DTH responses when stimulated by virus-self-TNP. Such a helper activity provided by vaccinia virus-primed mice was shown to be antigen-specific, and mediated by Lyt-1+2-T cells. DTH effector cells enhanced by helper cells were also antigen-specific and Lyt-1+2-T cells. Furthermore, vaccinia virus-reactive helper T cell activity could be applied to augmented induction of anti-tumor DTH responses by stimulation with virus-infected syngeneic fibrosarcoma tumor cells. Thus, these results provide evidence for the role of antigen-specific helper T cells in augmenting the development of DTH responses to cell surface antigens including tumor antigens.     

Memory suppressor T cells in latent Japanese encephalitis virus infection.

The generation of secondary suppressor T (Ts) cells has been studied during latent Japanese encephalitis virus (JEV) infection of mice. The mice infected with JEV 27 weeks earlier, on challenge with the homologous virus, showed accelerated generation of secondary Ts cells; these appeared on Day 6, with peak activity on Day 8, and lasted for 27 days. The secondary Ts cells were Thy1.2+, Ly1-2+, antigen-specific, and acted in a dose-dependent manner. The secondary Ts cells could also be generated by reactivation of the JEV in latently infected mice. The findings thus show the presence of memory suppressor T cells in mice latently infected with JEV that can be stimulated to produce secondary Ts cells by exogenous or endogenous virus challenge. This phenomenon could help to persistence of the virus.     

Junin virus-induced suppressor cells are effective only on the efferent limb of the delayed-type hypersensitivity response

Junin virus (JV), the etiological agent of Argentinian hemorrhagic fever, induces high mortality in the suckling BALB/c mouse, which correlates with delayed-type hypersensitivity (DTH)-like immune response. In contrast, the adult mouse is resistant to infection, and no DTH response can be detected. An antigen-nonspecific DTH suppressor T-cell activity induced by JV has been described that may be related to adult mouse survival. In this report, we present evidence supporting the inability of such cells, identified here as bearing the L3T4 marker, to affect the normal establishment of a DTH reaction. In the same form, virus-induced suppressor cells were unable to alter the expression of DTH effector cells in the absence of antigen-specific DTH suppressor cells. Besides, we found that a single high dose (200 mg/kg) of cyclophosphamide before or after JV inoculation was unable to alter the activity of virus-induced suppressor cells.     

Kinetics of murine delayed-type hypersensitivity response to Eimeria falciformis (Apicomplexa: Eimeriidae)

Mice recovering from a primary infection with an intestinal protozoan parasite, Eimeria falciformis (Apicomplexa: Eimeriidae), showed a classic delayed-type hypersensitivity (DTH) reaction to oocyst antigen challenge. This reaction was characterized by a biphasic pattern of footpad swelling. The first swelling peaked at 2 h after antigen challenge, whereas the second swelling peaked at 24 to 48 h after challenge. The DTH reaction was transferable with a T-cell-enriched spleen cell population from mice that had recovered from E. falciformis infection. Cytotoxic depletion of immune T cells with anti-L3T4 antibody and complement abrogated DTH transfer, indicating that L3T4-positive T cells were required. A T-cell-enriched spleen cell population from acutely infected mice suppressed the transfer of DTH with immune cells from recovered animals, implicating the existence of infection-induced immunoregulatory cells controlling the parasite-specific immune response during infection. Immune spleen cells also transferred resistance to infection as measured by oocyst production and death rate of recipients. Together, these results indicate that the DTH reaction, induced by infection with E. falciformis, is mediated by L3T4-positive T cells and is associated with resistance to infection.     

Lipopolysaccharide-induced suppression of graft-versus-host reactivity in mice

Reconstitution of lethally irradiated mice with spleen cells from donors that had been treated with lipopolysaccharide (LPS) intravenously and allogeneic spleen cells subcutaneously leads to a suppressed anti-host delayed-type hypersensitivity (DTH). Either donor injection alone proved to be ineffective. The state of suppression appeared to be antigen-specific, but, depending on the experimental conditions, also anti-host DTH to third-party alloantigens could be suppressed. The suppression was mediated by a population of Thy-1- suppressor cells that could also be induced in athymic nude mice. The suppressor cells specifically adhered to anti-kappa-coated plastic plates, but were not adsorbed by passage through a Sephadex G-10 column. Thus, it appears that the combined donor treatment with LPS and allogeneic spleen cells induces a population of B cells that can suppress anti-host immune reactivity.     

Lipopolysaccharide-induced suppressor cells for delayed-type hypersensitivity to herpes simplex virus: nature of suppressor cell and effect on pathogenesis of herpes simplex.

Treatment of mice with LPS at the time of priming with herpes simplex virus type 1 (HSV1) causes the preferential activation of virus-specific T suppressor (Ts) cells. These Ts cells can transfer suppression to the efferent limb of a DTH response. Priming under these conditions is associated with enhanced cell-recruitment to the inoculation site, but had no effect on virus clearance. The induction of suppression was abrogated by pretreatment of mice with cyclophosphamide or indomethacin. LPS had no effect on the antibody response to HSV1 during acute infection, although treated mice showed a raised antibody titre one month after inoculation. Susceptible mice inoculated with HSV1 and given LPS showed protection, both from lethal herpes encephalitis and from demyelination within the CNS as reflected by ear paralysis. These results imply that, during some stages of acute infection, T cell effector mechanisms may themselves mediate tissue damage. At such times, Ts cells may perform a beneficial role leading to a reduction in pathology.