Differential abilities of Th1 and Th2 to induce polyclonal B cell proliferation.

Human gamma globulin-specific T helper cell (Th) clones, activated by HGG in the presence of antigen (Ag)-presenting cells, stimulated polyclonal B cell proliferation. Both Th1 and Th2 clones induced B cell proliferation, but Th1 clones were generally 5- to 10-fold less efficient than Th2 in this capacity. Th1 and Th2 each induced proliferation of both small and large B cells, although Th1 induced less B cell proliferation than Th2, regardless of B cell size. Th1-induced B cell proliferation was increased significantly by stimulating the Th1 clones with immobilized anti-CD3 mAb. The B cell response to Ag-activated Th1 clones was also increased by the addition of rIL-4 or culture supernatants from activated Th2 clones, and this enhancement was abolished by addition of anti-IL-4 mAb. The differential capacity of the Th subsets to stimulate B cells could not be attributed to differences in the degree of Ag-induced activation of the Th clones as reflected by Th proliferation or Th expression of activation markers, RL388 Ag, IL-2R, or TfR. Taken together the results suggest that even though Th1 and Th2 are similarly activated by Ag-presenting cells, Ag-activated Th2 interact more effectively with B cells than Ag-activated Th1. It is possible that inefficient interaction and subsequent intercellular signaling between Th1 and B cells results in inefficient Th1-induced B cell proliferation, and that this deficiency may be circumvented by signals (e.g., lymphokines) provided by Th2, or by the stimulation of Th1 with plate-bound anti-CD3 Ab rather than Ag.     

Th1 and Th2 clones differ in their response to a tolerogenic signal.

Th1 and Th2 clones specific for human gamma globulin (HGG) were compared and shown to differ in terms of the effects of tolerance induction on Ag-induced proliferation and helper activity. In developing a method to induce tolerance, splenic APC that had been pulsed with HGG and then fixed with 0.15% paraformaldehyde (HGG-FAPC) were used as a means to present Ag to the Th clones in the absence of costimulatory signals. Both Th1 and Th2 clones recognized HGG-FAPC as evidenced by their ability to proliferate to HGG-FAPC. Unlike Th2, Th1 proliferated to HGG-FAPC only in the presence of T cell-depleted allogeneic spleen cells as a source of accessory cell signals. The inability of Th1 cells to proliferate in the absence of costimulatory signals was due to Ag-specific inactivation: Th1 clones preincubated with HGG-FAPC were unable to proliferate when recultured with HGG and irradiated APC. In contrast to Th1 clones, Th2 clones showed no decrease in their Ag-induced proliferative capacity after exposure to any concentration of HGG-FAPC. However, when examined by using a second assay system, that of providing help for anti-HGG antibody production by primed B cells, Th2 preincubated with HGG-FAPC were markedly inhibited (up to 90%) in their ability to provide help. Preincubation with HGG-FAPC also inhibited the helper activity of the one Th1 clone that was found to induce a significant secondary antibody response. Taken together, the results suggest that exposure of Th1 to tolerogen in the form of HGG-pulsed fixed APC inactivates Th1 proliferative capacity, and possibly Th1 helper activity as well. Exposure of Th2 cells to a tolerogen suppresses the mechanism by which the Th2 cells provide Ag-induced B cell help, but does not inhibit the mechanism by which they proliferate to HGG. Furthermore, the results define a model that incorporates Ag processing as well as Ag presentation in the induction of tolerance in vitro.     

Heterogeneity of helper/inducer T lymphocytes. III. Responses of IL-2- and IL-4-producing (Th1 and Th2) clones to antigens presented by different accessory cells

Murine CD4+ T cell clones have been classified into at least two subsets, Th1 and Th2, on the basis of their distinct lymphokine secretion profiles and functions. In the present study, we compared the functional responses of Th1 and Th2 clones to Ag presentation by splenic B cells and peritoneal macrophages. Th2 clones secreted IL-4 in response to Ag presented by resting B cells, but their optimal proliferation required the addition of IL-1 or a source of IL-1. The degree of IL-1 dependence varied among the four Th2 clones examined. In contrast, Th1 clones secreted IL-2 and proliferated in response to Ag presented by both B cells and macrophages, without any requirement for exogenous IL-1. Furthermore, the proliferation of Th2 clones in response to Ag presented by splenocytes or macrophages was inhibited by an IL-1R antagonist. These results indicate that IL-1 is an important costimulator for the expansion of the Th2 subset of CD4+ T cells. The different requirements for the proliferation of Th1 and Th2 cells may be responsible for the preferential expansion of one or the other subset under different conditions of immunization.     

Antigen presentation to Th1 but not Th2 cells by macrophages results in nitric oxide production and inhibition of T cell proliferation: interferon-gamma is essential but insufficient

The induction and role of nitric oxide (NO) during antigen presentation by macrophages to T helper (Th) cell subsets was examined. When cultured with Th1 clones, macrophage APC produced NO only in the presence of cognate Ag, which in turn suppressed T cell proliferation. IFN-gamma production by the activated Th1 cells was essential for the induction of NO. Th2 cells presented with the same cognate Ag did not induce NO production and proliferated uninhibited. Coactivation of Th1 and Th2 cells specific for the same Ag indicated that Th2 cells did not inhibit NO production, but were sensitive to NO induced by stimulated Th1 cells. Antigenic activation of Th2 cells in the presence of rIFN-gamma resulted in NO-mediated inhibition of proliferation. Th2 cells provided only a cell-associated cofactor, whereas Th1 cells secreted a soluble cofactor for IFN-gamma as well, i.e., TNF-alpha. Finally, a role for IFN-gamma and NO during immune responses was studied in spleen cells obtained from immunized IFN-gamma(-/-) mice. NO production and subsequent inhibition of Ag-specific proliferation ex vivo was observed only after the addition of rIFN-gamma. These studies suggest an IFN-gamma-dependent regulatory role for NO during Ag-specific Th cell activation involving macrophages, with obvious implications for Th subset-dependent immune responses in general.     

IL-10 acts on the antigen-presenting cell to inhibit cytokine production by Th1 cells

Murine IL-10 (cytokine synthesis inhibitory factor) inhibits cytokine production by Th1 cell clones when they are activated under conditions requiring the presence of APC. By preincubating APC with IL-10, we demonstrate that IL-10 acts principally on APC to inhibit IFN-gamma production by Th1 clones. Moreover, IL-10 is not active when Th1 cells are stimulated with glutaraldehyde-fixed APC, which also indicates that its action involves regulation of APC function. Furthermore, IL-10 inhibits cytokine synthesis by Th1 cells stimulated with the super-antigen Staphylococcus enterotoxin B, which does not appear to require processing. Flow microfluorimetry purified splenic or peritoneal B cells and macrophages, and B cell and macrophage cell lines can present Ag to Th1 clones. However, IL-10 acts only on sorted macrophages and the macrophage cell line to suppress IFN-gamma production by Th1 clones. IL-10 does not show this effect when B cells are used as APC. In contrast, IL-10 does not impair the ability of APC to stimulate cytokine production by Th2 cells. IL-10 does not decrease IFN-gamma-induced I-Ad levels on a macrophage cell line. Inasmuch as IL-10 also inhibits IL-2-induced IFN-gamma production by Th1 cells in an Ag-free system requiring only the presence of accessory cells, these data suggest that IL-10 may inhibit macrophage accessory cell function which is independent of TCR-class II MHC interactions.     

Modulation of inhaled antigen-induced IgE tolerance by ongoing Th2 responses in the lung

The normal response to inhaled Ag is the absence of Ag-specific IgE and cytokine production to later Ag challenges. Although the mechanism of this aerosol-induced IgE tolerance is not completely understood, it may prevent sensitization to inhaled Ags, which could otherwise lead to allergy and asthma. We examined the consequences of ongoing Th1 and Th2 responses in the lungs of mice during OVA inhalation to mimic conditions that may subvert tolerance and lead to sensitization. We found that concurrent, secondary Th2 lung responses to keyhole limpet hemocyanin or primary responses to Nippostrongylus larvae or Asperigillus fumagatus extract prevented establishment of IgE tolerance to aerosolized OVA. Intranasal rIL-4 given before OVA aerosolization also prevented establishment of tolerance, whereas concurrent Th1 responses to influenza virus or Mycobacterium bovis bacillus Calmette-Guérin had no effect. However, once established, aerosol tolerance to OVA could not be completely broken by OVA rechallenge concurrent with a secondary Th2 response to keyhole limpet hemocyanin or A. fumagatus extract, or by intranasal rIL-4. These data suggest that the immune status of the lung of an individual may profoundly influence the initial response to inhaled Ag, and that aerosol-induced IgE tolerance may not be appropriately established in individuals undergoing concurrent, Th2-mediated responses to Ags or pathogens.     

B cell presentation of a tolerogenic signal to Th clones.

Lightly irradiated (950 R) splenic B cells were inefficient, in comparison to unseparated spleen cells, in stimulating antigen-specific proliferation of Th1 clones specific for human gamma globulin (HGG). This inefficiency was due to antigen-specific inactivation: Th1 clones preincubated with HGG and lightly irradiated B cells or mitomycin C-treated B cells were unable to proliferate to HGG in secondary cultures. In contrast to Th1 clones, Th2 clones proliferated well in response to B cell APC, and showed no decrease in their subsequent antigen-induced proliferative capacity after exposure to lightly irradiated B cells and HGG. However, preincubation of Th2 with lightly irradiated B cells and HGG did inactivate the capacity of Th2 to provide help for antibody production in secondary cultures. These results suggest that under certain conditions B cells may present antigen to Th1 and Th2 cells in a tolerogenic rather than an immunogenic manner.     

The processing and presentation of the self-antigen hemoglobin. Self-reactivity can be limited by antigen availability and costimulator expression.

APC do not distinguish between self- and foreign proteins. Previous studies from our laboratory demonstrated that most endogenous host APC constitutively processed and presented the self-Ag, hemoglobin (Hb), as detected by the Hb-specific T cell hybridoma, YO1.6. We have now examined APC in organs known to be involved in RBC degradation (liver Kupffer cells and splenic small resting B cells) for the presence of Hb/Ia complexes and for the expression of the costimulation necessary to trigger proliferation of T cell clones. We detected Hb/Ia complexes not only on splenic small resting B cells, but also on liver Kupffer cells. Interestingly, complexes were not present on lymph node small resting B cells. Splenic small resting B cells expressed costimulatory activity and efficiently stimulated the Th2 clones only. The opposite pattern was observed with liver Kupffer cells, which expressed costimulatory activity for Th1 clones only. However, if costimulatory activity was provided for the Th2 clones (IL-1 beta) and Th1 clones (allogenic spleen cells), the clones did proliferate in response to Kupffer cells and small resting B cells, respectively. In this report we have demonstrated that 1) endogenously formed self Hb/Ia complexes are expressed on splenic small resting B cells and liver Kupffer cells but not on lymph node small resting B cells and 2) these APC are also able to limit the expression of costimulatory activity for Th2 and Th1 T cell clones. Thus, endogenous APC not only constitutively process and present the self-Ag Hb, but also limit expression of the costimulatory activity necessary to trigger T cell proliferation against a self-Ag. The constitutive processing and presentation of self-Ag, as well as the regulation of costimulatory activity on APC, is likely an important feature of the maintenance of self-tolerance.     

Antigen-nonspecific recruitment of Th2 cells to the lung as a mechanism for viral infection-induced allergic asthma

Respiratory viral infections have been shown to trigger exacerbations of asthma; however, the mechanism by which viral Th1-type inflammation exacerbates an allergic Th2-type disease remains unclear. We have previously shown that although adoptively transferred Th2 cells are inefficiently recruited to the lung in response to Ag, cotransfer of Th1 cells can increase accumulation of Th2 cells. In this study, we show that respiratory viral infection increases recruitment of resting Th2 cells specific for OVA even in the absence of OVA challenge. These findings suggest that the mechanism by which Th1-type inflammation enhances allergy is via an effect on recruitment. To study the role of the antigenic specificity of Th1 cells in the enhancement of Th2 cell recruitment and to determine whether virus-induced recruitment of OVA-specific Th2 cells may involve Th1 cells specific to a different Ag, we tested whether hen egg lysozyme-specific Th1 cells could synergize with OVA-specific Th2 cells. Challenge of mice that had received adoptively transferred Th1 cells plus Th2 cells induced the expression of inflammatory chemokines in the lung and increased both recruitment and activation of Th2 cells, leading to eosinophil recruitment, even in the absence of challenge with the Th2 Ag. Interestingly, as IL-5 supports eosinophilia, culture of resting Th2 cells with fresh APC induced production of IL-5 in the absence of specific Ag. Thus, Ag-specific activation of Th1 cells enhances the recruitment potential of the lung leading to recruitment and activation of Th2 cells. This implies that circulating Th2 cells in allergic individuals could enter the lungs in response to infection or inflammation and become activated to trigger allergy.     

A bone marrow-derived APC in the gut-associated lymphoid tissue captures oral antigens and presents them to both CD4+ and CD8+ T cells

We have previously reported that feeding OVA to C57BL/6 mice can lead to a weak CTL response that is dependent on CD4+ T cell help and is capable of causing autoimmunity. In this study, we investigated the basis of the class I and class II-restricted Ag presentation required for such CTL induction. Two days after feeding OVA, Ag-specific CD4+ and CD8+ T cells were seen to proliferate in the Peyer's patches and mesenteric lymph nodes. Little proliferation was evident in other lymphoid tissues, except at high Ags doses, in which case some dividing CD4+ T cells were observed in the spleen and peripheral lymph nodes. Using chimeric mice, the APC responsible for presenting orally derived Ags was shown to be derived from the bone marrow. Examination of the Ag dose required to activate either CD4+ or CD8+ T cells indicated that a single dose of 6 mg OVA was the minimum dose that consistently stimulated either T cell subset. These data indicate that oral Ags can be transported from the gut into the gut-associated lymphoid tissue, where they are captured by a bone marrow-derived APC and presented to both CD4+ and CD8+ T cells.     

Virus-induced interferon alpha/beta (IFN-alpha/beta) production by T cells and by Th1 and Th2 helper T cell clones: a study of the immunoregulatory actions of IFN-gamma versus IFN-alpha/beta on functions of different T cell populations

Spleen cells, resting T cells, activated T cells, and T cell clones characterized as type 1 (Th1) and type 2 (Th2) were investigated for their ability to produce interferon (IFN) following in vitro culture with Newcastle disease virus (NDV). All of the above cell populations, including both Th1 and Th2 T cell clones, produced high levels of IFN following in vitro culture with NDV. This IFN was characterized as a mixture of IFN-alpha and IFN-beta with IFN-alpha being the predominate species of IFN contained in the mixture. IL-2 greatly enhanced the production of IFN-alpha/beta by all cell populations in response to NDV. These different T cell populations responded very differently to the immunoregulatory actions of IFN-gamma versus IFN-alpha/beta. IFN-alpha/beta was shown to be a potent inhibitor of Con A or IL-2-induced proliferation of different T cell populations. This inhibition was not associated with a reduction in lymphokine production since spleen cells or Th1 T cell clones cultured with Con A and IFN-alpha/beta had no decrease in IL-2 or IFN-gamma production when compared to Con A-stimulated control cultures. IFN-gamma had little to no inhibitory activity on Con A-induced proliferation of spleen cells. In fact, Con A-induced proliferation was usually enhanced by IFN-gamma when nylon wool-enriched T cells were assessed. Different results were observed when IFN-gamma and IFN-alpha/beta were investigated for their ability to inhibit IL-2-induced proliferation of different T helper cell clones. IFN-gamma and IFN-alpha/beta were both capable of inhibiting IL-2-induced proliferation of T cell clones characterized as type 2 (Th2). In contrast, IFN-gamma had no effect on IL-2-induced proliferation of Th1 clones. IFN-alpha/beta, however, inhibited IL-2-induced proliferative responses of both Th1 and Th2 T cell clones. These results document the facts that (1) IFN-gamma and IFN-alpha/beta differ in their immunoregulatory actions, (2) different T cell subpopulations vary in their susceptibility to IFN-gamma regulation, and (3) virus induction of IFN-alpha/beta appears to be a ubiquitous function associated with different T cell populations.     

Heterogeneity in antigen processing by different types of antigen-presenting cells. Effect of cell culture on antigen processing ability.

The ability of normal B cells, peritoneal macrophages, and splenic APC to process and present OVA to a panel of T-T hybridomas with different specificities was investigated. In all cases, B cells were less efficient than unfractionated splenocytes in presenting OVA or its peptides. However, when the presentation of native Ag was compared to the presentation of peptides, it was obvious that there were marked differences in the ability of these two APC populations to generate different epitopes from OVA. Leupeptin inhibits the processing of selected epitopes from native OVA differently when it was presented by spleen cells or B cells, suggesting that these two APC populations differ in their protease content. The effect of in vitro culture on the ability of splenic and peritoneal APC to process OVA was also investigated. Native OVA presentation by macrophages and spleen cells was affected by in vitro culture, more for some epitopes than for other epitopes. In contrast, presentation of exogenous peptides by paraformaldehyde-fixed APC was either not affected by previous culturing for 3 days, or very much improved. Altogether, these data demonstrate that different epitopes on the same protein may be independently and differentially processed by B cells and spleen cells. Furthermore, the precise peptides that are produced may vary with the physiologic state of the APC.     

Different roles for thiol and aspartyl proteases in antigen presentation of ovalbumin.

By using the model Ag, chicken OVA, the proteolytic events required for effective presentation of the antigenic epitope, OVA323-339 to H-2d-restricted Th cells were investigated. First, the ability of aspartyl and thiol proteases to generate antigenic fragments of Ova in vitro was determined. It was found that cathepsin D, an aspartyl protease, digested OVA to fragments that could be recognized by Th cells without further processing by APC. Cathepsin B, a thiol protease, was unable to generate antigenic fragments of OVA in vitro. These results provide evidence that APC do not require thiol protease activity for processing OVA. In contrast, APC were unable to present OVA to Th cells when thiol protease inhibitors were added to the incubation. Taken together, these observations indicate that thiol proteases may be important, not for processing, OVA, but for presentation of processed fragments by APC. This conclusion is supported by evidence obtained from experiments in which APC were treated with thiol protease inhibitors before addition of the antigenic peptide, OVA323-339. Under these conditions, the capacity of I-Ad at the cell surface to present OVA323-339 to Th cells was reduced. The results of these experiments provide evidence that Ag presentation of OVA may be achieved through the action of two different classes of proteases: aspartyl proteases such as cathepsin D, which process OVA to antigenic fragments, and thiol proteases such as cathepsin B, which are important for expression of functional MHC II molecules by APC.     

Th type 1-stimulating activity of lung macrophages inhibits Th2-mediated allergic airway inflammation by an IFN-gamma-dependent mechanism

In the mucosal immune system, resident dendritic cells are specialized for priming Th2-polarized immunity, whereas the Ag-presenting activity of macrophages has been linked with the development of Th1 phenotype. As an immune switch toward Th1 can protect against Th2-mediated allergic response, this study investigated the capacity of lung macrophages to stimulate Th1 responses during the secondary exposure to inhaled allergen, thereby suppressing Th2-mediated allergic airway inflammation in a murine model of allergic asthma. Following airway macrophage depletion in OVA-sensitized mice, lung T cells defaulted to a phenotype that produced less Th1 (IFN-gamma) and more Th2 (IL-4 and IL-5) cytokines, leading to more severe airway hyperreactivity and inflammation after intranasal Ag challenge. After OVA pulsing and adoptive transfer, lung macrophages selectively promoted a Th1 response in Ag-sensitized recipients and did not induce pulmonary eosinophilia. By contrast, OVA pulsing and adoptive transfer of a lung cell preparation, consisting of dendritic cells, B cells, and macrophages, promoted a Th2 response with an associated inflammatory response that was suppressed when macrophages were present and pretreated with IFN-gamma, but exacerbated when macrophages were depleted before IFN-gamma treatment. In addition, Th1-promoting activity of lung macrophages was not related to the autocrine production of IL-12p40. These results suggest that the Th1-promoting APC activity may be an inherent property of the lung macrophage population, and may play an important role, upon stimulation by IFN-gamma, in antagonizing an ongoing Th2 immunity and Th2-dependent allergic responses.     

Anti-proliferative effect of IFN-gamma in immune regulation. II. IFN-gamma inhibits the proliferation of murine bone marrow cells stimulated with IL-3, IL-4, or granulocyte-macrophage colony-stimulating factor

A biphasic dose response curve was observed when the bone marrow-derived cell line FDCP1, used as an indicator line for IL-3 bioassays, was exposed to supernatants from some activated T cell clones but not others. The active component which inhibited proliferation at the higher supernatant concentrations appeared to be IFN-gamma, based on the following observations. 1) Only those culture supernatants which contained IFN-gamma gave a biphasic dose response curve; 2) with these supernatants, an anti-IFN-gamma mAb augmented the proliferation of FDCP1 cells at the higher supernatant concentrations; and 3) rIFN-gamma profoundly inhibited the proliferation of FDCP1 cells stimulated with rIL-3 or rIL-4. rTNF-alpha inhibited FDCP1 proliferation only to a modest extent, yet the combination of rTNF-alpha + rIFN-gamma provided greater inhibition than each agent alone. The proliferation of a second bone marrow-derived cell line, DA1, was not inhibited by rIFN-gamma or rIFN-gamma + rTNF-alpha when stimulated with rIL-3 or recombinant granulocyte-macrophage colony-stimulating factor (rGM-CSF). Fresh bone marrow cells also showed a suboptimal proliferative response when stimulated with T cell supernatants containing IFN-gamma, and this response was augmented considerably upon the addition of anti-IFN-gamma mAb. Bone marrow cell proliferation was observed upon exposure to rIL-3, rIL-4, or rGM-CSF, and these responses were inhibited by rIFN-gamma; rTNF-alpha also produced a synergistic effect with these cells. Bone marrow cell colony formation stimulated by rIL-3 or rGM-CSF also was inhibited by rIFN-gamma. Colony formation in bone marrow cell cultures was not observed in response to rIL-4. Collectively, these results suggest that Th1 cells, which in addition to IL-3 and GM-CSF also produce IFN-gamma, may regulate hemopoietic cell proliferation and colony formation differently from the way Th2 cells do, which do not produce IFN-gamma.     

Antiproliferative effect of IFN-gamma in immune regulation. III. Differential selection of TH1 and TH2 murine helper T lymphocyte clones using recombinant IL-2 and recombinant IFN-gamma

Supernatants collected after primary or secondary stimulation of spleen cells contain different arrays of lymphokines. Primary supernatants from spleen cells stimulated with Con A or allogeneic spleen cells (MLC-SF) contain IL-2 but little IL-4 or IGN-gamma; in contrast, secondary MLC-SF contains IL-2 as well as substantial IL-4 and IFN-gamma. Our laboratory previously had always used secondary MLC-SF for cloning T cells, and had routinely obtained TH1 helper T lymphocyte clones. In the present study, when primary Con A-SF was used as source of growth factors, TH2 and not TH1 clones were preferentially derived. Considering the possibility that IFN-gamma may be one important factor in determining whether TH1 or TH2 clones are preferentially obtained, clone derivation was then performed either in the presence of rIL-2 or rIL-2 plus rIFN-gamma. The majority of clones derived using rIL-2 alone were TH2 cells, whereas the majority of clones derived using rIL-2 plus rIFN-gamma were TH1 cells. Using either procedure, some clones were obtained that produced IL-2, IL-4, and IFN-gamma. These data are consistent with our previous observations that IFN-gamma inhibits the proliferation of TH2 but not TH1 clones, and suggest that the presence of IFN-gamma during an immune response would result in the preferential expansion of helper T lymphocytes of the TH1 phenotype. Our procedure for the differential selection of TH1 and TH2 clones reactive with the same Ag should be useful for designing in vitro systems for studying the function of these cell subsets in specific immune responses.     

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.     

Egg deposition is the major stimulus for the production of Th2 cytokines in murine schistosomiasis mansoni.

To characterize Th cell populations induced by helminth infection, spleen cells from mice infected with Schistosoma mansoni were stimulated with parasite (worm or egg Ag) or mitogen (Con A) and the supernatants assayed for the Th1-specific cytokines IFN-gamma and IL-2 and the Th2-specific cytokines IL-4 and IL-5. Th2 cytokine production was not detected in substantial quantity until the 6 to 8th wk of infection and after reaching peak levels at 8 to 12 wk declined slowly thereafter. The time courses of IL-4 and IL-5 production, whereas differing from each other, closely resembled corresponding published data on IgE and peripheral blood eosinophil levels during murine schistosome infection. In contrast, Th1 cytokine responses occurred only during the first 6 wk of infection and were virtually absent during the peak period of Th2 production. To assess the role of egg deposition in the observed pattern of Th response, cytokine production was assayed in mice carrying unisexual schistosome infections in which parasite eggs are absent. Splenocytes from these animals displayed only marginal Th2 cytokine synthesis but greater Th1 cytokine responses than the corresponding cells from mice with bisexual infections. Moreover, cultures of liver tissue or isolated granulomas from infected mice constitutively produced high levels of IL-4 and IL-5 but failed to synthesize significant amounts of IL-2 and IFN-gamma even when stimulated with egg Ag or mitogen. Taken together the data indicate that egg deposition is the major stimulus of Th2 cytokine response in S. mansoni-infected mice and suggest that T cells belonging to this subset must play a major role in egg granuloma formation.     

Induction of class I MHC-restricted, peptide-specific cytolytic T lymphocytes by peptide priming in vivo

The present study investigated the possibility that protein Ag fragments in the form of peptides could serve as the priming Ag in the generation of a MHC class I-restricted immune response. Trypsin-digested chicken ovalbumin (OVA-TD) fragments were used as the model Ag. The results demonstrate the peptides within OVA-TD, when injected into C57BL/6 mice, could prime T cells which lysed H-2b Ia-EL4 target cells in an OVA-TD-specific manner. In contrast to priming with OVA-TD, immunization of mice with intact OVA did not lead to generation of CTL against OVA-TD or OVA. Furthermore, target cells sensitized with intact OVA failed to be recognized by OVA-peptide-specific CTL indicating that the target cells serving as APC were unable to generate the relevant peptide determinants recognized by the T cells. These results support the idea that the processing pathway within APC for class I-restricted T cells may differ from that used for class II-restricted T cells. Using OVA-TD-specific CTL clones (phenotypically Thy 1+, CD8+, CD4-, Pgp-1+) isolated from primed animals to screen OVA-TD fractions separated by HPLC, two T cell peptide determinants were identified corresponding to OVA sequences 111-122 and 370-381. Both determinants were recognized by CTL clones in the context of the H-2Db molecule.     

Helper-independent CD8+ cytotoxic T lymphocytes express IL-1 receptors and require IL-1 for secretion of IL-2

The purpose of this study was to examine the role of IL-1 on the activation of CD8+/CD4- class I-restricted helper cell-independent cytolytic T cell (HITc) clones known to produce IL-2 and proliferate in vitro after Ag stimulation with a Friend retrovirus-induced leukemia (FBL). The functional role of IL-1 in Ag-specific proliferation and IL-2 secretion was assessed by stimulating the T cell clones with FBL either in the presence or absence of macrophages (M phi), rIL-1, or rIL-2. Resting cloned HITc cells, purified from residual accessory cells, failed to proliferate in response to FBL alone, but proliferated in response to FBL plus M phi, rIL-1 or rIL-2. Stimulation with FBL alone in the absence of M phi or IL-1 was sufficient for induction of IL-2R expression, and rendered cells responsive to IL-2, but M phi or IL-1 were also required to induce production of IL-2. The activity of IL-1 was further examined by measuring the binding of [125I]rIL-1 alpha, which demonstrated that resting cloned HITc cells expressed IL-1R that increased in number after activation with Ag. This expression of IL-1R and requirement for IL-1 by CD8+ HITc was surprising because previous studies examining T cell populations after mitogen stimulation have not detected IL-1R on the CD8+ population. Therefore, the role of IL-1 in the activation of CD8+ CTL that do not secrete IL-2 after activation was assessed. By contrast to HITc, CD8+ CTL required exogenous IL-2 to proliferate in vitro and did not express IL-1R. These data demonstrate that the subset of CD8+ T cells responsible for IL-2 production express IL-1R and that triggering this receptor with IL-1 after Ag stimulation results in the production of IL-2 and subsequent proliferation.