Cholera toxin stimulates IL-1 production and enhances antigen presentation by macrophages in vitro

Cholera toxin (CT) is a strong systemic and mucosal adjuvant that greatly enhances IgG and IgA immune responses. We investigated whether CT potentiates Ag presentation by macrophages as a possible mechanism underlying its adjuvant function. This was tested by preculturing APC in CT and analyzing the effect of CT treatment on the capacity to trigger 1) an allogeneic proliferative response of normal mesenteric lymph node T cells (H-2b) to the macrophage cell line P388D1 (H-2d) or 2) an Ag-specific proliferative response of D10.G4.1 clonal T cells in co-culture with normal macrophages and Ag. Pretreatment of APC, normal peritoneal macrophages or the P388D1 cells, with CT strongly enhanced Ag- and allogen-specific T cell proliferation. Also P388D1 APC treated with CT and then formalin-fixed demonstrated enhanced ability to stimulate T cell proliferation as compared to cells not exposed to CT, suggesting that the effect of CT on APC might be to enhance expression of a cell-associated factor. Flow microfluorimetry analysis of P388D1 cells cultured in CT-containing medium failed to detect an increase in class II MHC-Ag expression as compared to that found on cells not cultured in CT. In contrast, both soluble and cell-associated IL-1 formation was increased several-fold by CT, but with different CT dose requirements. A total of 10 to 100 times more CT were required for elevating the soluble IL-1 as compared to the cell associated IL-1, which was increased by as little as 1 ng/ml of CT. The soluble and cell-associated IL-1 activity induced by CT was abrogated by a polyclonal antiserum to IL-1-alpha. Similarly, the potentiating effect of CT on the ability of P388D1 APC to trigger alloreactive T cell proliferation was also blocked completely by the addition of the anti-IL-1-alpha antibody to the test system. This is the first study to demonstrate that CT potentiates Ag presentation. The mechanism for this effect probably involves induction of IL-1 production and in particular of a cell-associated form of IL-1 (IL-1-alpha). Potentiation of APC function might be important for the adjuvant action of CT on the immune response in vivo.     

Human atopen-specific types 1 and 2 T helper cell clones.

Eight representative T lymphocyte clones (TLC) randomly selected from previously described panels of CD4+ housedust mite Dermatophagoides pteronyssinus (Dp)-specific TLC from atopic and nonatopic donors were studied in more detail in a comparative investigation. The TLC from the atopic donors closely resembled murine type 2 Th (Th2) cells by secreting substantial IL-4, IL-5, IL-6, TNF-alpha, and granulocyte-macrophage (GM)-CSF, minimal IFN-gamma, and relatively little IL-2. In contrast, the nonatopic's TLC resembled murine type 1 Th (TH1) cells by secreting substantial IFN-gamma, IL-2, TNF-alpha, and GM-CSF, no IL-4, and little IL-5. A difference with murine Th1 cells was their additional secretion of IL-6. These cytokine profiles were consistent upon stimulation via different activation pathways including stimulation with specific Dp Ag, mitogenic lectins, and antibodies to CD2, CD3, or CD28. The observed differences in IL-2 secretion, however, were most evident upon stimulation with anti-CD28. If TLC cells were cultured with highly purified B cells and stimulated with anti-CD3 in the absence of exogenous IL-4, IgE synthesis was induced only in cultures with the atopics' Th2 clones, which could be completely abrogated by anti-IL-4. The mere presence of exogenous rIL-4, however, did not result in IgE synthesis, nor did unstimulated TLC cells alone. But if unstimulated TLC cells (that proved not to secrete detectable amounts of cytokines) were added together with rIL-4, again IgE synthesis was induced only in cultures with the atopics' Th2 clones, suggesting the involvement of an additional, as yet unidentified accessory helper function of the atopics' Th2 clones for IgE induction. Unstimulated Th2 clones showed a significantly higher expression of CD28 than the Th1 clones, but three days after stimulation, CD28 expression was elevated to comparable levels on both subsets. When added to B cells at this time point, together with rIL-4 and anti-IFN-gamma, still only the atopics' Th2 clones supported IgE synthesis, arguing against a role for CD28 in this accessory helper function. Whereas the atopics' Th2 clones were excellent helper cells for IgE induction, a unique property of the nonatopic's Th1 clones was their cytolytic activity toward autologous APC which could be induced by specific Dp Ag and by anti-CD3. The present data provide clear evidence for the existence of Th1 and Th2 cells in man.     

Induction of competence to respond to IL-4 by CD4+ T helper type 1 cells requires costimulation.

Rested murine CD4+ Th1 clones do not produce IL-4, but have previously been shown to be capable of responding to IL-4 if they are first activated with Ag and APC. In this study, we have examined the activation requirements for induction of competence to respond to IL-4 in these clones. TCR occupancy alone (given either as chemically fixed APC and Ag, anti-CD3, Con A, or ionomycin and PMA) was inadequate, but the addition of a source of costimulation to any of these stimuli resulted in complete induction of competence to respond to IL-4. Pretreatment of the Th1 clones with TCR occupancy alone induced an anergic state from which subsequent full stimulation with Ag and APC failed to give IL-4 responsiveness. Pretreatment of the cells with IL-2 alone was an inadequate signal to induce IL-4 responsiveness and only a partial response was obtained when TCR occupancy was combined with IL-2. Addition of anti-IL-2 and anti-IL-2R antibodies during full activation with APC and Ag gave a 50% inhibition of competence induction. These results demonstrate that costimulation, in addition to its role in IL-2 production, is an important second signal for inducing T cells to become competent to respond to IL-4.     

Inhibition of antigen-specific proliferation of type 1 murine T cell clones after stimulation with immobilized anti-CD3 monoclonal antibody

The effect of stimulating normal type 1 murine T cell clones with anti-CD3 antibody was examined in vitro. In the absence of accessory cells, anti-CD3 antibody immobilized on plastic plates stimulated inositol phosphate production, suboptimal proliferation, IL-2 and IL-3 production, and maximal IFN-gamma production. Addition of accessory cells augmented lymphokine production and proliferation when the effects of "high-dose suppression" were relieved by removing the T cells from the antibody-coated plates. Exposure of type 1 T cell clones to immobilized anti-CD3 antibody alone rapidly induced long-lasting proliferative unresponsiveness (anergy) to Ag stimulation that could be prevented by accessory cells. This anergic state was characterized by a lymphokine production defect, not a failure of the T cells to respond to exogenous IL-2 or to express surface Ti/CD3 complexes. In addition, anergy could not be induced in the presence of cyclosporine A. These results suggest that under certain conditions anti-CD3 antibodies may have potent immunosuppressive effects independent of Ti/CD3 modulation. Furthermore, our results support a two-signal model of type 1 T cell activation in which Ti/CD3 occupancy alone (signal 1) induces anergy, whereas Ti/CD3 occupancy in conjunction with a costimulatory signal (signal 2) induces a proliferative response.     

Costimulatory requirements of murine Th1 clones. The role of accessory cell-derived signals in responses to anti-CD3 antibody

We examined the role of accessory cell-derived signals in promoting growth and lymphokine production by murine Th1 clones. Five of six Th1 clones failed to proliferate to immobilized anti-CD3 antibody despite producing IL-2 and IFN-gamma. These clones became unresponsive to Ag after exposure to anti-CD3. With the addition of irradiated splenic accessory cells (SAC), Th1 clones proliferated to anti-CD3 and produced greater amounts of IL-2 and IFN-gamma. High doses of plate-bound anti-CD3 completely inhibited responses of these clones to IL-2 and diminished the growth-promoting activity of SAC. The costimulatory effects of SAC on growth of Th1 clones were also seen in the presence of exogenous IL-2, indicating that enhanced IL-2 production alone was not responsible for the costimulatory effect. Delivery of the costimulatory signal from SAC required their close proximity to the T cells. The costimulatory activity of SAC was not reproduced by the addition of IL-1, IL-6, or IL-1 plus IL-6. IL-7 induced weak proliferation of Th1 clones, but did not synergize with plate-bound anti-CD3. Our results suggest a model in which SAC-derived costimulatory signals regulate growth of Th1 cells primarily at the level of cell cycle progression rather than at the level of IL-2 production.     

Cooperation between an anti-T cell (anti-CD28) monoclonal antibody and monocyte-produced IL-6 in the induction of T cell responsiveness to IL-2

CD28 is an Ag of 44-kDa Mr that is expressed on the membrane of the majority of human T cells and that is recognized by mAb 9.3. The functional effects of mAb 9.3 on peripheral blood T cells were studied. mAb 9.3 was not mitogenic, unless it was combined with PMA. When CD28 was cross-linked after binding of mAb 9.3 to the T cell by immobilized or soluble anti-mouse IgG, T cells proliferated in response to rIL-2, provided that monocytes were also present. The additional signal required for IL-2 responsiveness after cross-linking of CD28 could also be delivered in cultures of purified T cells by a cellfree monocyte culture supernatant. Expression of IL-2R on about 10% of the T cells was demonstrated by staining with an anti-IL-2R mAb, and was found to be largely restricted to CD4+ cells. The active compound responsible for the helper signal in the monocyte culture supernatant was identified as IL-6 because purified IL-6 (but not IL-1 beta) had similar activity and because an antiserum to IL-6 (but not an antiserum to IL-1 beta) neutralized the activity of the monocyte supernatant and blocked T cell proliferation. An anti-IL-2R antibody also completely inhibited T cell proliferation induced by the combination of mAb 9.3, IL-2, and IL-6. Our results provide evidence that cross-linking of CD28 induces functional IL-2R and that this activity is dependent on a helper signal provided by monocytes, more specifically IL-6. Moreover, our results indicate that IL-6 (previously called B cell stimulatory factor-2) is active on T cells. If a natural ligand for CD28 can be identified, the mechanism of induction of IL-2 responsiveness described here might explain how T cells become nonspecifically involved in an ongoing cellular immune reaction.     

T cell derived IL-6 is differentially required for antigen-specific antibody secretion by primary and secondary B cells

IL-6 (formerly PCTGF, HP-1, BSF-2, HGF, IFN-beta 2, 26 kDa) is a recently defined lymphokine demonstrating activity on multiple cell types, including hepatocytes, thymocytes, T cells, plasmacytomas, and B cells. The biologic effects of IL-6 on lymphocytes, particularly B cells, suggest this factor may be involved in the regulation of normal immune responses. Accordingly, we have investigated the role of IL-6 in Ag-specific responses of B cells from both naive and Ag-primed mice. When Ag-primed splenic T cells were used as a source of help, naive (primary) B cell responses specific for the hemagglutinin molecule of the influenza A virus (PR8) were fully inhibited by the addition of an anti-IL-6 antiserum, and are thus IL-6 dependent. In contrast, secondary B cell responses were essentially IL-6 independent, being unaffected by this antiserum even at concentrations 10-fold higher than required to completely inhibit primary responses. This differential IL-6 requirement was further investigated by using a panel of hemagglutinin molecule-specific Th clones. Consistent with the above findings, a Th1 clone secreting biologically active IL-6 enables antibody secretion by both primary and secondary B cells, whereas Th1 clones that do not produce IL-6 support secondary responses, but fail to help primary B cell responses unless exogenous IL-6 is added. These results provide the first instance of differential lymphokine requirements among primary vs secondary B cell responses, and suggest T cell-derived IL-6 plays a critical role during the regulation of humoral immune responses. Moreover, functionally distinct Th1 clones were identified that differed in IL-6 secretion and their corresponding ability to induce Ig secretion by primary and secondary B cells.     

Murine T helper cell clones secrete granulocyte-macrophage colony-stimulating factor (GmCSF) by both interleukin-2-dependent and interleukin-2-independent pathways

Granulocyte-macrophage colony-stimulating factor (GmCSF) is a lymphokine secreted by class II major histocompatibility complex (MHC)-restricted T cells after lectin or antigen stimulation. To investigate the relationship between interleukin-2 (IL-2) and GmCSF production, we utilized long-term cultures of porcine myelin basic protein (PMBP)-specific T helper cell clones that were maintained with IL-2 in the absence of antigen or irradiated antigen-presenting cells (APC). We have found that supernatants of these T cell clones contained GmCSF activity after IL-2 stimulation. Inhibition of cell proliferation by irradiation failed to stop GmCSF production. When these clones were stimulated with PMBP and irradiated APC in the presence of anti-IL-2 receptor antibody, the T cell supernatants still contained GmCSF activity. These results indicate that (1) GmCSF production by T helper clones after IL-2 stimulation is independent of cell proliferation and (2) antigen/MHC-stimulated GmCSF production by T cell clones can occur by an IL-2-independent pathway.     

Extinction of IL-12 signaling promotes Fas-mediated apoptosis of antigen-specific T cells.

In previous studies we have shown that peripheral tolerance achieved by high dose feeding of OVA to intact OVA-TCR transgenic mice was enhanced when endogenous IL-12 was neutralized simultaneously. To generalize this phenomenon, in the present study we investigated the tolerogenic mechanisms underlying the blockade of IL-12 signaling following oral and systemic Ag delivery. We found that the numbers of Ag-specific T cells in several lymphoid organs were significantly reduced due to T cell apoptosis following oral OVA or systemic OVA administration when combined with anti-IL-12 injection, but there was no decrease in T cell numbers for OVA-fed, OVA-injected, or anti-IL-12 alone-treated mice compared with those in untreated control mice. In addition, mostly Fas+ T cells were subject to apoptotic deletion in the OVA- plus anti-IL-12-treated groups, and an enhanced cell death of T cells upon OVA restimulation in vitro could be partially reversed by blockade of the Fas/Fas ligand interaction. Finally, in a murine model of superantigen-driven T cell expansion and deletion, we observed no deletional effects of anti-IL-12 treatment on CD4+ cells in Fas-deficient (MRL/lpr) mice, but did find these effects in MRL wild-type mice. In summary, our data suggest that in the course of Ag-induced cell proliferation of Th1 cells, signaling through IL-12 is required to prevent an induction of Fas-mediated apoptosis. Thus, the use of anti-IL-12 may be potentially useful in modulating peripheral immune responses by promotion of Fas-mediated cell death.     

Anti-CD3 antibody induces unresponsiveness to IL-2 in Th1 clones but not in Th2 clones

Culture of murine T cells with immobilized (platebound) anti-CD3 antibody results in autocrine growth factor secretion in both Th1 (IL-2 producing) and Th2 (IL-4 producing) cells. Using a panel of murine T cell clones, we demonstrate that the IL-2-induced proliferation of Th1 clones is dramatically inhibited by immobilized anti-CD3 antibody, whereas that of Th2 clones is not. This unresponsiveness of Th1 clones to IL-2 is not due to decreases in IL-2R expression. Supernatants from Th1 or Th2 cell cultures fail to alter the effects of anti-CD3 on the two types of clones, suggesting that unresponsiveness induced in Th1 clones or the lack thereof in Th2 clones is not mediated by a stable cytokine(s). Accessory cells enhance the proliferation of Th1 cells exposed to low concentrations of anti-CD3, but the unresponsiveness induced by high concentrations of anti-CD3 is not prevented by accessory cells. Finally, soluble anti-CD4 antibody prevents the induction of the unresponsive state even at high concentrations of anti-CD3. These experiments demonstrate that two subsets of cloned CD4+ T cells differ in their responses to anti-CD3, and that CD4 molecules may play a critical role in regulating the outcome of receptor-mediated stimulation.     

Allogeneic non-T spleen cells restore the responsiveness of normal T cell clones stimulated with antigen and chemically modified antigen-presenting cells

Stimulation of IL-2-producing T cell clones with chemically modified APC and Ag induces a state of proliferative unresponsiveness, i.e., subsequent stimulation with normal APC and Ag fails to elicit IL-2 production. One possible effect of chemical modification on the APC is the destruction of its ability to provide costimulatory signals. To test this, various potential costimulators were added to T cells at the time of exposure to Ag and chemically modified APC. None of the cytokines tested, including IL-1, had a positive effect; however, addition of allogeneic spleen cells allowed a T cell proliferative response and prevented the induction of subsequent unresponsiveness. Fractionation of the spleen cells showed that low density B cells and macrophages were the best source of costimulatory activity. Allogeneic resting B cells provided some costimulatory activity and resting T cells, none at all. Attempts to mimic costimulatory signals with the phorbol ester PMA were only partially successful. PMA prevented the induction of T cell unresponsiveness but failed to allow T cell proliferation in response to Ag plus chemically modified APC. Our results suggest that IL-2 production by normal T cell clones is dependent not only on T cell receptor occupancy, but also on short range costimulatory signals that are provided to different degrees by various non-T accessory cells.     

Functional heterogeneity among human inducer T cell clones

Analysis of mouse CD4+ inducer T cells at the clonal level has established that a dichotomy among CD4+ T cell clones exists with regard to types of lymphokines secreted. Mouse T cell clones designated Th1 have been shown to secrete IL-2 and IFN-gamma, whereas T cell clones designated Th2 have been shown to produce IL-4 but not IL-2 or IFN-gamma. To determine if such a dichotomy in the helper inducer T cell subset occurred in man, we examined a panel of human CD4+ helper/inducer T cell clones for patterns of lymphokine secretion and for functional activity. We identified human T cell clones which secrete IL-4 but not IL-2 or IFN-gamma, and which appeared to correspond to murine Th2 clones. In marked contrast to murine IL-2 secreting Th1 clones which do not produce IL-4 or IFN-gamma, we observed that some human T cell clones secrete IL-2, and IFN-gamma as well as IL-4. Southern blot analysis indicated that these multi-lymphokine-secreting clones represented the progeny of a single T cell. IL-4 secretion did not always correlated with enhanced ability to induce Ig synthesis. Although one T cell clone which secreted IL-2, IL-4, and IFN-gamma could efficiently induce Ig synthesis, another expressed potent cytolytic and growth inhibitory activity for B cells, and was ineffective or inhibitory in inducing Ig synthesis. These results indicate that although the equivalent of murine Th2 type cells appears to be present in man, the simple division of T cells into a Th1 and Th2 dichotomy may not hold true for human T cells.     

Nematode infection enhances survival of activated T cells by modulating accessory cell function.

The type of immune response generated following exposure to Ag depends on a variety of factors, including the nature of the Ag, the type of adjuvant used, the site of antigenic entry, and the immune status of the host. We have previously shown that infection of rodents with Nippostrongylus brasiliensis (Nb) shifts the development of type 1 allo-specific responses toward type 2 immunity, suggesting nematode modulation of T cell activation. In this report we explore the immunomodulatory effects of Nb on T cell activation. We found that spleen cells from Nb-infected mice exhibited dramatically increased proliferation in response to Con A and anti-CD3. This hyperproliferation could be transferred in vitro to naive splenocytes by coculture with mitomycin C-treated cells from Nb-infected animals. The transfer was mediated by non-T accessory cells and supernatants derived from Con A-activated non-T cells, suggesting the involvement of a soluble factor secreted by accessory cells. The accessory cells secreted high levels of IL-6, and anti-IL-6 treatment abrogated the supernatant-induced hyperproliferation, thus confirming that IL-6 was mediating the effect. Further, spleen cells from Nb-infected mice were more resistant to activation-induced cell death (AICD) following mitogenic stimulation. Reduced AICD was also transferable and IL-6 dependent. Thus, the hyperproliferation was in part due to enhanced activated T cell survival. These phenomena mediated by accessory cells may contribute to the powerful polyclonal activation of type 2 immunity caused by nematode infection.     

Potential contribution of IL-17-producing Th(1)cells to defective repair activity in joint inflammation: partial correction with Th(2)-promoting conditions

To assess the contribution of cell interactions to the production of cytokines and type I collagen, fixed synovium T cell clones were cocultured on synoviocytes and levels of IL-6, LIF and PICP, a marker of type I collagen synthesis measured. Levels of IL-6 and LIF were higher with Th(1)than with Th(0)and Th(2)clones. Levels of PICP were decreased with Th(1)clones and increased with Th(2)clones. IL-17-producing T cells, all Th(1), were among the highest inducers of cytokine and inhibitors of collagen synthesis. Preincubation of clones in Th(1)conditions (IL-12 plus anti-IL-4) increased IL-6 production, whereas Th(2)conditions (IL-4 plus anti-IL-12) strongly inhibited IL-6 production and restored repair activity. As rheumatoid synovium is infiltrated by Th(1)cells, local cell interactions result in a pro-inflammatory pattern with defective repair, which can be reversed at least in part, by a Th(2)pattern.     

IgE production by normal human B cells induced by alloreactive T cell clones is mediated by IL-4 and suppressed by IFN-gamma

Seven T cell clones were established from mixed leukocyte cultures in which PBMC from two healthy donors and from one patient suffering from the hyper-IgE syndrome were stimulated by the irradiated EBV-transformed B cell lines JY or UD53. Five of seven T cell clones, after activation by co-cultivation with JY or UD53 cells, induced a low degree of IgE production by normal blood B cells. In one experiment in which the normal B cells could activate the T cell clones directly, IgE production was also observed in the absence of the specific stimulator cells. IgE production was also obtained with supernatants of the T cell clones collected 4 to 5 days after activation by their specific stimulator cells. In addition, the supernatants induced IgG, IgA, and IgM synthesis. All seven clones produced variable concentrations of IL-4 and IFN-gamma. The clones FA-28 and BG-39, which failed to induce IgE synthesis, produced, compared with the other clones tested, relatively high quantities of IFN-gamma (4700 and 2500 pg/ml, respectively). These high levels of IFN-gamma accounted for the lack of induction of IgE synthesis, because in the presence of a polyclonal anti-IFN-gamma antiserum, supernatants of FA-10 and BG-39 induced significant IgE production. In addition, the low degree of IgE production induced by supernatants of two other T cell clones (FA28 and BG24) was 15- and 3-fold enhanced, respectively, in the presence of the anti-IFN-gamma antiserum. IgE synthesis by normal B cells was also induced by rIL-4, indicating that IL-4 present in T cell clone supernatants was responsible for induction of IgE production. This notion was supported by the finding that IgE production induced by supernatant of BG-24 was strongly inhibited by a polyclonal anti-IL-4 antiserum. In contrast, IgG and IgA production induced by supernatant of BG-24 were not significantly affected by the anti-IL-4 antiserum. Only a slight inhibition of IgM synthesis was observed. Collectively, our results indicate that both recombinant and naturally produced IL-4 induce normal human B cells to synthesize IgE. However, final IgE production induced by T cell clone supernatants is the net result of the inducing and suppressive effects of IL-4 and IFN-gamma respectively, that are secreted simultaneously by the T cell clones upon activation.     

Cross-linking Fc receptors on monocytes triggers IL-6 production. Role in anti-CD3-induced T cell activation

IL-6 is a multifunctional cytokine which is produced by a variety of cells. Therefore it was examined whether anti-CD3-induced T cell activation was associated with the induction of functionally relevant IL-6 in human monocyte accessory cells. Significantly increased amounts of IL-6 were detected in supernatants of anti-CD3-treated PBMC. Stimulation of FACS-sorted greater than 98% pure monocyte accessory cells, but not of highly purified T cells with anti-CD3, resulted in an increased IL-6 production. Furthermore, anti-CD3 significantly enhanced IL-6 mRNA expression in monocyte accessory cells. IL-6 production was not limited to anti-CD3, inasmuch as equivalent IL-6 stimulation could be achieved with a mouse IgG2a isotype control antibody. In contrast to solid phase-bound mouse IgG2a, the soluble form of this antibody failed to induce IL-6 secretion indicating a requirement for Fc gamma RI receptor cross-linking. Moreover, this property may be specific for the Fc gamma RI receptor inasmuch as mouse IgG1 antibodies binding to the Fc gamma RII receptor did not significantly enhance IL-6 production. The role of IL-6 being an additional signal in T cell activation was confirmed by the finding that an anti-IL-6 antiserum was able to suppress anti-CD3-induced T cell activation. These data indicate that binding of anti-CD3 to Fc gamma RI may generate an activation signal towards the monocyte accessory cell leading to the production and secretion of monocyte IL-6, which in turn augments T cell activation, and also may be relevant to a variety of antibody-mediated immune responses against viral and bacterial infections.     

On the mechanisms of T cell silencing by IL-10 DNA: direct and indirect inhibition of T cell functions

Previously we reported that mucosal IL-10 DNA administration resulted in long-term suppression of virus-induced inflammatory responses by silencing Th1-type CD4+ T cell functions. However, the mechanism by which IL-10 silences the activity of CD4+ T cells was not clear. The present report has shown that mucosal IL-10 DNA administration led to the reduction of reactivity of T cells following TCR stimulation. IL-10 DNA also downregulated APC functions to stimulate T cells but the effect was temporary. Bystander suppression, including that of IL-10 producing regulatory cells, appeared not to be directly involved in the inhibition of T cell reactivity because both anti-IL-10 and anti-IL-10R could not block the suppression of T cell functions. This silenced state could be maintained following adoptive transfer to untreated animals. The nature of the silencing appears to be a reversible anergic state since Ag stimulation in the presence of exogenous IL-2 restored T cell reactivity. Furthermore, IL-10-induced silenced T cells could be induced in vitro by culturing the T cells with rIL-10 in the presence or the absence of antigen stimulation. This state persisted in the absence of rIL-10 and persisted for at least 3 days. A more notable effect, however, was observed when the T cells were incubated with IL-10 in the presence of APC and Ag. These results indicate that IL-10 induced a long-term silenced state in T cells by direct and indirect inhibition of T cell functions.     

IL-1 production by human thymic dendritic cells: studies on the interrelation with DC accessory function

Thymic dendritic cells (DC) have been proposed to play a critical role in the generation of immunocompetent T lymphocytes. Since IL-1 is widely considered to be an important second signal in T cell stimulation, we have studied the ability of isolated human thymic DC to produce IL-1. Using the EL4/CTLL conversion assay standardized with recombinant IL-1 beta (rIL-1 beta), we demonstrate that upon LPS-stimulation thymic DC produce small amounts of IL-1 as compared to peripheral blood monocytes (PBM). In contrast with PBM, DC IL-1 production is not influenced by indomethacin. IL-1 activity was detected in the supernatants of DC cultures from all thymuses tested, although quantitative variability was noted among individual thymic donors. The specificity of the active factor was confirmed by neutralization assays with anti-IL-1 beta mAb. On the other hand, we demonstrate that rIL-1 beta cannot substitute for nor amplify the accessory function of thymic DC and that anti-IL-1 beta mAb fails to block the DC accessory function. Thus we conclude that IL-1 beta might not be a major factor for the efficient DC accessory function toward mature thymocytes recently demonstrated in our laboratory. Of interest, IL-1 beta was also detected in the supernatants of DC-thymocyte cocultures in the absence of mitogenic factor, suggesting that thymocyte contacts can constitute a sufficient signal to induce DC to produce IL-1. These observations indicate that human thymic DC represent an intrathymic source of IL-1 whose role in thymocyte proliferation or maturation remains to be understood.     

Yersinia enterocolitica activates a T helper type 1-like T cell subset in reactive arthritis.

The profile of lymphokines secreted by 14 T cell clones and 24 T cell lines reactive with Yersinia Ag isolated from the synovial fluid cells of two HLA-B27+ patients with Yersinia-triggered reactive arthritis was characterized. In response to Ag-specific or -nonspecific stimulation, all of the Yersinia-reactive T cell clones and lines had a pattern of lymphokine secretion resembling that of murine (Th1) cells. A total of 50% of T cell lines and clones randomly isolated from a reactive arthritis patient, without prior in vitro stimulation with Yersinia Ag, also exhibited a Th1-like profile of cytokine secretion upon nonspecific activation. This indicates that the selective expansion of this subset of T cells had already occurred in vivo. The possibility that the predominance of Th1-like T cells was an artefact generated by the T cell cloning procedure was excluded; 50% of the randomly isolated T cell clones and lines produced IL-4, IL-5, or both cytokines upon nonspecific activation. These results indicate that Yersinia Ag selectively activate a Th1-like subset of T cells in patients with Yersinia-triggered reactive arthritis. Accumulation of such cells in the synovial tissue of patients with reactive arthritis may play a key role in the pathogenesis of this disease.     

IL-1 as a co-factor for lymphokine-secreting CD8+ murine T cells

Immunologically important among the known biologic activities of IL-1 is its ability to function as a co-factor for responses mediated by lymphokine secreting CD4+ Th cells. In contrast to its known effects in CD4+ T cell responses, IL-1 is not known to play a role in CD8+ T cell responses. In the present study, we have assessed the ability of murine recombinant IL-1 to function as a co-factor for stimulating CD8+ T cells to secrete lymphokines such as IL-2. We found that, in conjunction with either Ag or mitogen, IL-1 is able to stimulate lymphokine-secreting CD8+ T cells. Furthermore, we found that, as a consequence of its stimulation of lymphokine-secreting CD8+ T cells, IL-1 is able to reconstitute MHC class I allospecific cytolytic T lymphocyte responses by cell populations depleted of both accessory cells and CD4+ T cells. These results demonstrate that the biologic activity of IL-1 is not restricted to CD4+ cell responses, and suggests that IL-1 can function as a co-factor for the stimulation of lymphokine-secreting Th cells regardless of their CD4/CD8 phenotype. If IL1 acts directly on lymphokine-secreting T cells or on the APC with which they interact is not yet certain.