Steven H. Herrmann

Evidence that rapamycin inhibits interleukin-12-induced proliferation of activated T lymphocytes.

Interleukin 12 is a heterodimeric cytokine involved in the regulation of natural killer cell and T lymphocyte responses. In previous studies, we found that IL-12 induces proliferation of T cells only after co-stimulation with lectin, alloantigen, or anti-CD3 antibody. The IL-2-mediated proliferation of long-term T cell lines generated in this fashion is typically insensitive to the immunosuppressive agent, cyclosporine but sensitive to rapamycin. In this study, we examined the effect of cyclosporine and rapamycin on T cells responsive to IL-12. For long-term cultured T cell lines stimulated with phytohemagglutinin, alloantigen, or solid-phase anti-CD3 antibody, rapamycin blocked IL-12-induced proliferation to background levels. Culture in cyclosporine produced minimal inhibition of IL-12-induced T cell proliferation. Freshly isolated CD3+ cells did not proliferate in response to IL-12, nor did culture of these cells in IL-12 lead to upregulation of IL-2 receptor. These data suggest that the effect of IL-12, an important growth regulator for activated T lymphocytes, may involve late cellular activation events.

[8] Purification of murine MHC antigens by monoclonal antibody affinity chromatography

Publisher Summary This chapter discusses the purification of murine major histocompatibility complex (MHC) antigens by monoclonal antibody affinity chromatography. The growing understanding of the role of MHC antigens in transplantation and immune system recognition has resulted in considerable interest in the functional and structural characteristics of these cell-surface glycoproteins. Monoclonal antibody affinity chromatography has proved to be a rapid and efficient means of purifying relatively large amounts of both class I and class II murine MHC antigens. There is a successfully use of four monoclonal antibodies as affinity reagents. The same general approach is applicable to the purification of a variety of MHC antigens using different monoclonal antibodies. The antigens purified in this way retain serological and biological activity and prove to be useful for studying the structure and function of these molecules.

IL-4-supported induction of cytolytic T lymphocytes requires IL-2 and IL-6.

Previous work indicated that a CTL response can be generated by the combination of IL-2 plus IL-6 or IL-4 alone. Because of the ubiquitous production of IL-6 and its apparent ability to induce IL-2, we explored the interdependence of these lymphokines in supporting a CTL response from murine thymocytes. For thymocytes cultured in IL-4, further addition of IL-6 enhanced thymocyte proliferation. In addition, a role for IL-6 in thymocyte activation was indicated by the ability of anti-IL-6 mAb to block both IL-4-directed proliferation and the cytotoxic response found in the presence of IL-4. The addition of IL-2 to limiting doses of IL-4 augmented the CTL response; however, the response to high levels of IL-4 was not augmented by addition of IL-2. Consistent with this apparent involvement of IL-2 in the IL-4-mediated response we found: (a) that mAb to IL-2 significantly reduced the CTL response generated in the presence of IL-4; (b) that IL-2 activity was present in culture supernatant following incubation of thymocytes with high levels of IL-4; and (c) that enhanced IL-2 receptor expression found in the presence of IL-4 was blocked with the addition of anti-IL-2 antibody to the thymocyte culture. In contrast to the data for proliferation, anti-IL-4 mAb had no effect on the generation of CTL in the presence of IL-2 + IL-6 but readily blocked the CTL response to IL-4. These results indicate that, for thymocyte responders, the CD8+ CTL generated in the presence of IL-4 require both IL-2 and IL-6.

Cytolytic T Lymphocyte Recognition of Subcellular Antigen

Specific antigen recognition is required to stimulate generation of a cytolytic T lymphocyte (CTL1) response and to allow the resulting effector CTLs to bind and lyse the target cells. Reliable assays allow in vitro assessment of stimulation of a primary and secondary response and of the effector-target interaction. The antigens required to trigger generation of a response are the same as those required to allow binding and lysis by the effector CTL.

The role of CD18 in phorbol ester-induced human monocyte-mediated cytotoxicity

Monocyte cell surface molecules play an important role in the regulation of monocyte function. To investigate the molecular basis of monocyte-mediated cytotoxicity, we tested the ability of a variety of mediators to stimulate human monocyte-mediated cytotoxicity. Phorbol myristic acetate (PMA) stimulated significant monocyte-mediated killing of tumor cells in an 18-hr indium-111 release assay. Five other cytoactive substances did not induce monocyte-mediated cytotoxicity. The acquisition of monocyte cytotoxicity was associated with nearly a twofold increase in surface expression of three CD18-bearing cell surface molecules (CD11a, CD11b, CD11c). The direct involvement of the CD18-bearing molecules in monocyte-mediated cytotoxicity was investigated using monoclonal antibody (MAb) inhibition. MAb recognizing the CD18 subunit significantly inhibited monocyte-mediated killing. The inhibition by anti-CD18 MAb could not be attributed to LFA-1 (CD11a) alone, suggesting that CR3 (CD11b) and p150,95 (CD11c) may also participate in monocyte-mediated cytotoxicity. In contrast, seven of eight other cell surface structures were not affected by PMA treatment, and MAb to all eight cell surface structures did not inhibit killing. These findings suggest that CD18-bearing molecules are upregulated with monocyte activation and may play a functional role in monocyte-mediated killing.

The mechanism of antigen presentation by dendritic cells and splenic adherent cells in the induction of an allogeneic cytotoxic T-lymphocyte response to H-2Kk liposomes

Induction of an allogeneic cytotoxic T-lymphocyte (CTL) response to purified alloantigen is partially dependent on uptake and processing of the class I alloantigen by antigen-presenting cells (APC) followed by recognition of the alloantigen and self Ia by helper T cells (TH). The activated TH provides the helper signal(s) to the alloantigen-specific CTL for proliferation and differentiation into an active effector CTL. The role of antigen processing and presentation of major histocompatibility complex alloantigens was examined and the ability of different types of APC to present purified H-2Kk liposomes was investigated. Splenic adherent cells (SAC), splenic dendritic cells (DC), and B-cell lymphoblastoid lines were all shown to be effective in the presentation of H-2Kk liposomes. The relative ability of these cells to serve as APC was determined to be DC greater than B-cell tumors greater than SAC. The role of processing of H-2Kk liposomes by SAC and DC was examined by investigating the effect of weak bases on pulsing of the APC. These experiments suggest that presentation of alloantigen by both SAC and DC involves a step which is sensitive to inhibition by weak bases. We examined whether the TH were activated by similar mechanisms when stimulated by the various APC. The functional involvement of the T-cell surface marker L3T4 was demonstrated in the induction of TH. In contrast, L3T4 was not involved in the subsequent generation of CTL since monoclonal antibody (MAb) specific for L3T4 was not effective in blocking CTL function in the presence of nonspecific T helper factor (THF). Similarly, Ia on the APC was shown to be involved in the stimulation of the TH pathway but not directly in the differentiation of the CTL. Thus, DC and B cells in addition to SAC can present H-2Kk to TH. The presentation of alloantigen by both cell types may involve an intracellular route as demonstrated by the blocking of the TH response by weak bases. Both Ia and L3T4 are required on the APC for induction of the TH response. The minimal requirements for activation of the CTL were H-2Kk liposomes and a source of THF.

Generation of targets for alloreactive CTL using purified H-2Kk in liposomes and polyethylene glycol.

The ability of a purified major histocompatibility antigen to serve as the target cell antigen for alloreactive CTL (H-2d anti-H-2k) was examined. Tumor cells syngeneic with responding CTL were used as targets following modification with purified alloantigen (H-2Kk). A short incubation of tumor cells with H-2Kk liposomes followed by the addition of polyethylene glycol (PEG) yielded modified tumor cells that were recognized and lysed by CTL. The macrophage-like cell line P388D1 was readily recognized following liposome and PEG modification; apparently because these cells can withstand PEG mediated insertion of H-2Kk and lipid into their membrane. The generation of targets by PEG mediated modification was most efficient using liposomes prepared with an H-2Kk:lipid ratio of about 1:500. H-2Kk containing liposomes prepared with negatively charged phospholipids readily attached to P388D1 cells, however these cells were not targets for CTL unless PEG was added. The specificity of CTL recognition and lysis of liposome modified cells was shown by the reactivity of CTL primed against alloantigens other than H-2Kk and by antibody (anti-H-2Kk) blocking of recognition and lysis. These results demonstrate that purified H-2Kk can serve as the alloantigen for CTL lysis and suggest that the H-2 must be oriented in the target cell lipid bilayer to serve as the alloantigen for CTL mediated target cell lysis.