T-cell mediated immunity in murine malaria. I. Induction of T-cell dependent proliferative responses to Plasmodium chabaudi

Mycobacterial proliferation in macrophages is prevented by incubation with lymphocytes activated in vitro with a mycobacterial antigen complex

Antigen A60 from Mycobacterium bovis bacillus Calmette Guérin was shown to trigger both humoral and cellular immune reactions. We explored the ability of A60 to block intracellular proliferation of phagocytosed mycobacteria with a model system involving peritoneal murine macrophages infected with Mycobacterium avium. Mixed lymphocytes from lymph nodes of mice inoculated with A60 hindered intracellular proliferation of this mycobacterium, owing to A60-specific cells, proliferation of which was induced in vitro in an antigen concentration-dependent manner. The lymphokines released by A60-stimulated T lymphocytes in vitro were identified as interleukin 2 (IL2) and interferon-gamma (IFN-gamma): their production showed a clear A60 dose dependence. When supernatants of such induced lymphocyte cultures were incubated with anti-IFN-gamma antibodies, macrophage activation was prevented, whereas anti-IL 2 immunoglobulin had little effect. Treatment of infected macrophages with recombinant IFN-gamma reduced intracellular proliferation of mycobacteria, while exogenous IL 2 and tumor necrosis factor were ineffective. Therefore, A60 elicits in vitro proliferation of T lymphocytes responding specifically to this antigen with production of IFN-gamma, which in turn activates macrophages and prevents multiplication of phagocytosed mycobacteria.

Mechanisms of resistance/susceptibility to murine encephalitozoonosis

Mechanisms of resistance/susceptibility to the obligate intracellular protozoan Encephalitozoon cuniculi were studied in resistant BALB/c and susceptible C57BL/6 mice. Three immunological functions were examined: the production of lymphokine(s) (LK) by T-lymphocytes, the proliferative response of spleen cells to parasite spore fragments, and the ability of splenic and thioglycollate-induced peritoneal macrophages to act as accessory cells in antigen-induced T-cell proliferation. The two strains showed differences in the time required for LK production in vitro but not in their ability to generate LK. Spore fragment-induced lymphoblastogenesis was found in spleen cells of infected BALB/c and C57BL/6 mice. There was no difference between the two strains in dose response and time of maximal response, but the magnitude of maximal response was significantly less in C57BL/6 mice. Indomethacin was found to augment the lymphoproliferative response of C57BL/6 but not BALB/c mice, suggesting that prostaglandin production may be involved in immunosuppression in C57BL/6 mice. C57BL/6 mice required more splenic adherent cells to achieve the same proliferative response as found in BALB/c mice. The ability of thioglycollate-induced peritoneal macrophages to act as accessory cells in antigen-induced T-cell proliferation was less in C57BL/6 mice than in BALB/c mice. Thus, it appeared that the relative susceptibility of C57BL/6 mice to encephalitozoonosis may be due to defective accessory cell function of splenic and peritoneal macrophages, depressed lymphoproliferation against spore fragments (possibly due to prostaglandin-mediated suppression) and a delay in LK production. There was no significant difference between the survival times of BALB/c-nu and C57BL/6-nu mice, suggesting that non-immune mediated resistance did not play a role in determining resistance/susceptibility.

Comparative evaluation of the protective effect of immune spleen cells and immune RNA against Plasmodium berghei

Earlier studies from this laboratory indicated that passive transfer of viable or frozen-thawed cells from spleens and lymph nodes of immune mice resulted in a significant protective immunity against Plasmodium berghei in syngeneic recipients. To assess whether immune RNA played a role in conferring such protection, experiments were designed wherein immune RNA was isolated from immune monkeys, rats and mice and transferred to normal mice. The effect of transfer was assessed by challenging RNA-primed animals with Plasmodium berghei. Results indicated that immune RNA failed to confer resistance against P. berghei both in syngeneic and in heterologous systems.

Activation of antigen-specific suppressor T cells by the intravenous injection of soluble blood-stage malarial antigen

The regulation of delayed-type hypersensitivity (DTH) to soluble antigens derived from blood-stage parasites was investigated. DTH responses to soluble blood-stage malarial antigen were induced by subcutaneous (sc) sensitization in the flanks and elicited by ear challenge with the same antigen 6 days later. Adoptive transfer studies revealed that T cells of the L3T4+ phenotype were mediating this response. When a high dose of malarial antigen was injected intravenously (iv) prior to sc sensitization, immunosuppression of DTH resulted. The degree of immunosuppression was dependent on the dose of antigen injected iv and the time at which it was administered prior to sc sensitization. Immunosuppression was antigen-specific and mediated by Lyt-2+ splenic T cells.

T cell-mediated immunity in murine malaria. II. Induction of protective immunity to P. chabaudi by antigen-fed macrophages and antigen-educated lymphocytes

We previously described assay systems for generating antigen specific proliferating T cells to P. chabaudi antigens. In the present study we examine whether the various sensitization approaches confer immunity against a cloned virulent strain IP-PCI of P. chabaudi. We present data indicating that effective specific protective immunity can be induced through P. chabaudi antigen fed macrophages and antigen educated spleen cells (initiator lymphocytes). The expression of this protective immunity is proposed to depend on (a) antigen presentation and/or accessory function of macrophages and (b) the subsequent activation of T cell functions related to protection. Indeed analysis of different macrophage populations revealed a correlation between the expression of Ia molecules and IL-1 secretion with their capacity to induce antigen specific T cells in vivo and subsequent protective immune mechanisms. Thus these results emphasize the critical functions of accessory cells in determining the outcome of malaria infections.