Involvement of soluble mediator(s) different from interleukin (IL) 1 in the antigen-induced IL 2 receptor expression and proliferation of L3T4+ (CD4+) T lymphocytes

CD40/CD40 ligand interactions are required for T cell-dependent production of interleukin-12 by mouse macrophages

We have previously shown that T cell receptor-activated mouse T helper (Th)1 clones induce the production of interleukin (IL)-12 by splenic antigen-presenting cells (APC). Here, we show that the expression of CD40L by activated T cells is critical for T cell-dependent IL-12 production by mouse macrophages. IL-12 was produced in cultures containing alloreactive Th1 clones stimulated with allogeneic peritoneal macrophages, or in cultures of splenocytes stimulated with anti-CD3. Anti-CD40L monoclonal antibodies (mAb) inhibited the production of IL-12, but not IL-2, in these cultures by approximately 90% and had dramatic inhibitory effects on antigen-dependent proliferation of Th1 clones. In addition, both activated T cells and a Th1 clone derived from CD40L knockout mice failed to induce IL-12 production from splenic APC or peritoneal macrophages. Finally, macrophages cultured in the absence of T cells produced IL-12 upon stimulation with soluble recombinant CD40L in combination with either supernatants from activated Th1 clones or with interferon-gamma and granulocyte/macrophage colony-stimulating factor. Thus, both CD40L-dependent and cytokine-mediated signals from activated T cells are required to induce the production of IL-12 by macrophages. A blockade at the level of IL-12 production may explain, at least in part, the dramatic ability of anti-CD40L mAb to inhibit disease in animal models that are dependent upon the generation of a cell-mediated immune response. Moreover, a defect in T cell-dependent induction of IL-12 may contribute to the immune status of humans that lack functional CD40L.

Interleukin-12 regulates the proliferation of Th1, but not Th2 or Th0, clones

Our results indicate that interleukin (IL)-12 is an important costimulator of antigen-dependent proliferation of murine Th1 clones. In addition, we demonstrate that IL-10 inhibits splenic antigen-presenting cell (APC)-dependent proliferation of Th1 clones, at least in part, via down-regulation of APC-derived IL-12. Moreover, the failure of activated B cells to provide costimulation via IL-12 accounts for their inability to support optimal proliferative responses of Th1 clones. We also show that IL-12 regulates the ability of Th1 clones to respond to IL-4 and enhances their proliferation in response to IL-2, IL-7, or IL-15. In contrast, Th2 and Th0 clones appear refractory to the effects of IL-12, on antigen-dependent or growth factor-induced proliferation.

Induction of IL-2 receptor expression and proliferation of T cell clones by a novel cytokine(s)

We found a unique T cell IL-2 receptor (IL-2R)3-inducing activity in the supernatant (SN) of the TH1 clone stimulated with antigen on spleen cells as antigen-presenting cells (APC). We have tentatively named this activity the IL-2R-inducing factor (IL-2RIF) and have characterized the activity. The SN induced IL-2R and proliferation of TH1 clones stimulated with B cell APC, which could not induce IL-2R in the absence of the SN. Other known cytokines were examined for a IL-2RIF activity; however, none of cytokines examined exerted a similar activity. Moreover, the neutralizing antibodies against the known cytokines tested did not block the IL-2RIF activity in the SN. When TH1 clones were stimulated with immobilized anti-CD3 or with fixed B cell APC in the presence of partially purified IL-2RIF, these clones expressed IL-2R and showed IL-2-dependent proliferation, whereas they induced neither IL-2R expression nor proliferation in the absence of IL-2RIF activity. These observations suggest that IL-2RIF activity is mediated by a novel cytokine(s) and the cytokine plays an important role as a second signal in the activation of the TH1 clone.

Components of an antigen-/T cell receptor-independent pathway of lymphokine production

The general way to induce the synthesis of lymphokines by T cells is the stimulation through the T cell receptor (TcR) complex which results in an increase of intracellular [Ca2+] and in the activation of a tyrosine kinase as well as of protein kinase C. Lymphokine production induced via the TcR is inhibited by the immunosuppressive drug cyclosporin A (CsA). However, an alternative pathway of lymphokine production exists. Several T lymphocyte clones can synthesize interferon-gamma (IFN-gamma), granulocyte-monocyte colony-stimulating factor, and small amounts of interleukin (IL3) when stimulated with syngeneic or allogeneic accessory cells (AC) plus IL2. In contrast to the TcR pathway the alternative pathway does not require a rise of intracellular [Ca2+] and is insensitive to the effects of CsA. In this report we provide evidence for the involvement of T cell-stimulating factor (TSF)--a probably novel murine cytokine--in the alternative pathway of lymphokine production. It is shown that fixation of the AC with carbodiimide or treatment of the AC with UV light greatly reduces their capacity to induce (in combination with IL2) the synthesis of IFN-gamma by T cells. This function is restored by addition of TSF. Moreover, TSF alone (without IL2) in combination with fixed AC can induce the synthesis of substantial amounts of IFN-gamma. Furthermore, TSF in combination with IL2 can stimulate freshly isolated spleen cells to produce IFN-gamma. The target cell resides probably in the non-B cell, non-T cell population.

Requirements for the growth of TH1 lymphocyte clones

Besides the signal generated in a T lymphocyte after triggering the T cell receptor (TcR), most lymphocytes need a "second signal" to become fully activated. The necessity and nature of the "second signal" differs between different types of T cells. At the level of CD4-positive T helper lymphocytes interleukin 1 (IL 1) serves as "second signal" for those of the TH2 subtype (IL4, 5, 6 producer) but not for those of the TH1 subtype (IL 2, IFN-gamma producer). This correlates with the absence of the IL 1 receptor at the surface of TH1 clones. We report herein the further purification of T cell stimulating factor (TSF), a soluble mediator involved in the proliferation of TH1 lymphocytes. A preparation free of detectable IL 1, 2, 4 and IL 6 activity could act as "second signal" required for the growth of TH1 lymphocytes in a TcR-mediated, as well as a TcR-independent activation system. In addition, we suggest that IL 1 can influence the proliferation of TH1 clones in an indirect way, probably via the induction of TSF in accessory cells.

Enhanced proliferation of murine T cell lines following interaction of poly(Glu60,Phe40) (GPhe) and antigen-presenting accessory cells. I. GPhe-stimulated enhancement of antigen-dependent proliferative responses

Following interaction of the random polymer (Glu60,Phe40)n (GPhe) with antigen-presenting accessory cells (APC), unusual costimulatory activities were noted in several murine T cell systems. When GPhe, in contrast with other random copolymers (GT,GL), was added during "inhibition" and T cell "repertoire" studies as a (negative) control to GLA-reactive nonclonal T cell lines of haplotypes H-2d (DCL-2) or H-2bm12, augmentation of T cell proliferation ([3H]thymidine incorporation ([3HT]) to homologous antigen was observed. Augmentation by GPhe was also observed in the response of a GLPhe-reactive (H-2s X H-2d)F1 T cell line and the allogeneic response of the clonal T cell line D10.G4.1. This augmentation was critically dependent on the concentration of adherent accessory cells. Although the mechanism of action of GPhe remains, as yet, undefined, the GPhe-mediated enhancement of DCL-2 (a TH2, H-2d anti-GLA, T cell line) proliferation was not dependent upon the production of either IL-1 or IL-6 by accessory cells. In addition, enhanced DCL-2 proliferation was not accompanied by a significant increase in detectable IL-4 release.

Enhanced proliferation of murine T cell lines following interaction of poly(Glu60,Phe40) (GPhe) and antigen-presenting accessory cells. II. The role of accessory cells and cytokines in the activity of GPhe on antigen-independent proliferation

Our previous study (1) demonstrated the "cytokine-like" activity of poly(Glu60,Phe40)(GPhe) in augmenting the antigen-dependent proliferation of a variety of long-term murine T cell lines, particularly the bulk, BALB/c anti-poly (Glu36,Lys24,Ala40) (GLA), interleukin-4-producing, DCL-2 T cell line. GPhe was found to also augment the antigen-independent proliferation of DCL-2 in response to exogenous cytokines ([interleukin(IL)-2 +/- IL-1] in most experiments). Such exogenous cytokine-driven proliferative responses of DCL-2 were used to investigate further the role of accessory cells and of various soluble factors in the action of GPhe. GPhe did not act as a direct mitogen for T cells, rather it acted in a costimulatory fashion, requiring the presence of plastic-adherent accessory cells and a T cell growth factor (either IL-2 or IL-4). In the presence of accessory cells and exogenous IL-2, augmentation of antigen-independent DCL-2 proliferation by GPhe or by IL-1 depended upon the induction of autocrine IL-4 production. However, GPhe also augmented the response of these cells in the presence of exogenous IL-4 (+/- IL-2, +/- IL-1), and exogenous IL-4 added in combination with exogenous IL-2 (+/- IL-1) failed to mimic the GPhe effect, suggesting that another signal was involved in the mechanism of action of GPhe. The ability of allogeneic accessory cells to interact with GPhe to augment proliferative responses suggested that either a soluble factor or an unusual non-MHC-restricted cell-cell interaction provided this signal. In the presence of uv-irradiated accessory cells, DCL-2 proliferation was enhanced over that observed in the presence of non-uv-treated accessory cells, mimicking the GPhe effect, and interaction of GPhe with uv-irradiated accessory cells did not result in further enhancement of DCL-2 cytokine-driven proliferation. Using monoclonal antibodies which could block the function of IA or CD4 molecules, these cell-surface "adhesion" molecules were shown not to participate in the activity of GPhe. By the addition of recombinant cytokines, neutralizing antibodies, or indomethacin, the mechanism of action of GPhe was also shown not to be dependent upon IL-1, IL-6, IL-7, TNF alpha, or prostaglandin production by accessory cells. However, the presence, individually, of some of these factors (IL-1, IL-7, or prostaglandins) could influence to a variable degree the magnitude of the GPhe effect.

Processing requirements for the recognition of insulin fragments by murine T cells

In this study we investigated aspects of antigen processing using insulin and insulin A chain-derived fragments as model antigens in Ab alpha Ak beta-restricted T-cell stimulation. Similarly to other proteins, the immunodominant region of insulin recognized by these T cells is limited in size. It is located on the insulin A chain and encompasses a portion of the molecule that is represented faithfully by peptide A1-14(SSO3-)3. Efficient presentation of intact insulin and its entire A chain is dependent on uptake and processing by APC. Whereas peptides stemming from various globular proteins are known to be presented to T cells by APC without requiring processing, this is not the case with A-chain fragment A1-14 (SSO3-)3. This observation suggested that, in addition to proteolytic degradation, other mechanisms might play a role in the processing of these antigens. Three cys-residues are located in close proximity to those amino acid residues of the insulin A chain that are inferred to participate in the specific interaction with MHC class II molecules and the TcR. In A-chain derivatives that are stimulatory for the T cells or in intact insulin these cys residues are engaged in disulfide bonds or are S-sulfonated. Both linkages can be reversibly modified by reaction with thiols. Functional data indicate that from intact insulin and from structurally distinct A-chain derivatives a closely similar or identical peptide is formed and bound to class II molecules for recognition by the T cells. The question arises as to whether, in this processed peptide, the cys residues are present in reduced form, engaged in disulfide bonds, or are modified in some other way. Taken together, these findings suggest that modification of cys residues or isomerization of disulfide bonds may play a role in insulin processing. It can be expected that other proteins carrying cys residues in their immunodominant peptides may show similar processing requirements. The inhibition of N-glycosylation of proteins by tunicamycin in APC blocked the processing and presentation of insulin and OvA whereas, under the same conditions, the presentation of a processing-independent peptide was not affected. Furthermore, an autoreactive T-cell clone was capable of recognizing tunicamycin-treated APC. Since the expression of class II molecules was found to be unaltered as demonstrated by cytofluorometric analysis the deficient N-glycosylation appears to have little influence on class II antigen-mediated T-cell recognition but interferes with uptake of antigen and/or its processing by APC.