Lymphokine-independent induction of macrophage membrane IL-1 by autoreactive T cells recognizing either class I or class II MHC determinants

Here we report that autoreactive T cell clones and T cell hybridomas that recognize class I or class II MHC determinants can induce IL-1 expression on cultured macrophages in an MHC-restricted manner. This genetic restriction of membrane IL-1 (mIL-1) induction is not absolute, however; it is manifest only in macrophages that have been cultured for several days before stimulation. Macrophages that are evaluated within 24 h after adherence display a basal level of mIL-1, and the T cell-induced augmentation of basal mIL-1 expression is not MHC-restricted. It appears that T cells of both Th1 and Th2 type have the capacity to induce mIL-1, suggesting that this function is not limited to the T cell subset (Th2) that is able to use IL-1. Most importantly, the ability of T cells to induce IL-1 on macrophages seems to occur by virtue of direct cellular interactions, and is independent of lymphokine secretion. The induction event is rapid enough (2 to 4 h) to allow T cells to interact with both antigen and IL-1 during the initial T cell/macrophage contact. These findings thus reveal an efficient mechanism for the induction of IL-1 during Ag presentation to T cells.     

Evidence implicating utilization of different T cell receptor-associated signaling pathways by TH1 and TH2 clones

We have reported recently that high concentrations of anti-CD3 mAb inhibited IL-2-dependent proliferation of TH1 but not TH2 clones. The selective inhibitory effect on TH1 clones suggested that the two helper T lymphocyte subsets might utilize different TCR-associated signal transduction mechanisms. In the present study, we demonstrate that this distinction was not due to a gross difference in the level of TCR expression by TH1 and TH2 clones. Inhibition of TH1 proliferation by anti-CD3 mAb appeared to depend on calcium for maximal effect, suggesting that a substantial elevation of intracellular free calcium concentration ([Ca2+]i) might not occur after ligation of the TCR complex of TH2 clones. Calcium ionophore inhibited IL-2-dependent proliferation of both subsets, suggesting that receptor/ligand systems which stimulate elevated [Ca2+]i would be expected to inhibit proliferation. Although elevated [Ca2+]i and generation of inositol phosphates were readily detected in TH1 clones, these second messengers were not detected following stimulation of TH2 clones via the TCR complex. In addition, lymphokine production by TH1 clones was more sensitive to inhibition by cholera toxin, 8-bromoadenosine 3':5'-cyclic monophosphate, and cyclosporin A than was lymphokine production by TH2 clones. Collectively, these results suggest that TH1 and TH2 clones utilize distinct TCR-associated signal transduction mechanisms for lymphokine gene expression. The difference in signaling mechanisms suggests a potential pharmacologic target for intervention in situations where inappropriate activation of TH1 or TH2 cells occurs in vivo.     

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.     

An alternative pathway of induction of lymphokine production by T lymphocyte clones

We have previously described a variant murine CTL clone that in contrast to all other clones tested, exhibited a novel capacity to produce IFN-gamma in response to IL-2. This alternative pathway of IFN-gamma induction differed from the conventional TCR complex-mediated pathway in that it was independent of elevated intracellular Ca2+ and insensitive to cyclosporine A. We report here the presence of an analogous pathway in the majority of T lymphocyte clones tested, when these clones are stimulated with IL-2 in the presence of syngeneic or third-party splenocytes. The accessory function of splenocytes in this alternative pathway is mediated by the MAC-1+ subpopulation and apparently involves cell-cell contact. However, the structure with which the MAC-1 antibody reacts probably is not involved directly. No involvement of Ag or the TCR for Ag could be demonstrated in this alternative pathway of lymphokine induction. The array of lymphokines induced by this alternative pathway is only a subset of those induced by antigenic stimulation. Finally, as with the previously described variant clone, IL-2-mediated induction of IFN-gamma production by the normal T lymphocyte clones is independent of normal extracellular Ca2+ levels and insensitive to cyclosporine A. Thus, this alternative pathway of lymphokine induction apparently constitutes a distinct signaling pathway in cloned T lymphocytes.     

Prostaglandin E2-dependent induction of granulocyte-macrophage colony-stimulating factor secretion by cloned murine helper T cells

PG are known to inhibit T cell proliferation, at least in part by suppressing IL-2 production, but effects of PG on the production of other lymphokines have not been well studied. We have found that PGE2 and PGE1, but not PGF2 alpha, inhibit both proliferation and production of granulocyte-macrophage (GM)-CSF by murine TH clones stimulated with Ag or anti-CD3 antibody. Thus, signals generated via the Ag receptor:CD3 complex were inhibited by PGE. Most interesting, however, was the finding that PGE2 and PGE1 could act synergistically with IL-2 for the induction of GM-CSF in some TH1 clones. Dependence on PGE2 for this response was not found in all clones, as some TH1 cells could produce GM-CSF after IL-2 alone, and some cells did not produce GM-CSF even in the presence of PGE2 and IL-2. These observations indicate that there is a subset of TH1 cells receptive to a stimulating activity of PGE2 in the presence of IL-2. PGE2 is known to elevate cAMP levels in T cells. Therefore, we tested whether other agents known to increase cAMP, such as forskolin and cholera toxin, could act in conjunction with IL-2 to induce GM-CSF secretion. As was found with PGE2, these compounds also induced GM-CSF activity in the presence of IL-2, suggesting a critical role for cAMP in this process. Overall these data indicate that the requirements for activation of GM-CSF secretion vary among individual T cells. Most importantly they provide the first evidence that E-series PG are positive signals for lymphokine induction in certain T cells, whereas simultaneously acting as negative signals limiting proliferation. This result also suggests that treatment with anti-inflammatory drugs that decrease PGE2 concentrations may inhibit lymphokine secretion normally stimulated by this pathway.     

Antigen-specific sIalo B cells do not secrete IgG2a in response to TH1 cells and antigen: responsiveness can be restored by IL-4

The ability of Th cells, type 1 (TH1), to activate and induce differentiation of B cells into antibody-secreting cells is controversial because 1) some clones of TH1 cells provide help while others do not, and 2) by using the same TH1 clone, different laboratories disagree on whether they provide help to B cells. One possible explanation for the latter is the variability in the activation status of the B cells used in different laboratories. In the present studies, we have used Ag-specific B cells from athymic (nu/nu) mice, or sterilely housed nu/+ mice to study the TH1-mediated activation of B cells that had received little or no prior help from T cells and/or antigen in vivo. These B cells express low levels of surface Ia (sIa) Ag, and fail to secrete IgG2a in response to TH1 cells plus Ag; in contrast, responses to TH2 cells plus Ag are normal. To explore this observation further, we prepared "surface(s) Ia1o" B cells from conventionally housed BALB/c mice by sorting spleen cells on the fluorescence-activated cell sorter. This sIalo population also failed to produce IgG2a in response to TH1 cells plus Ag. In contrast, the sIahi, (presumably more mature) B cells, responded to both the TH1 and TH2 cells. The addition of LPS, TH2 cells or the lymphokine, IL-4, to cultures of sIalo B cells from normal or nu/nu mice (plus Ag and TH1 cells), restored IgG2a responses to control levels. Low sIa levels were not the sole cause of nonresponsiveness of the nu/nu B cells because a 24-h pulse with IL-4 restored sIa to control levels without restoring IgG2a production after activation with TH1 cells plus Ag. These data support the conclusion that sIalo B cells are immature and require an activation/maturation signal from IL-4 in vivo in order to respond to TH1 cells and Ag in vitro.     

Differential effects of poly (Glu60, Phe40) (GPhe) on murine TH1 and TH2 cells.

The random amino acid copolymer (Glu60, Phe40)n (GPhe) was previously shown to augment antigen-dependent proliferation of the murine TH2 cell lines DCL-2 and D10.G4.1. In the present study, the addition of GPhe to (Glu36, Lys24, Ala40)n (GLA)-primed BALB/c primary lymph node (1 degree LN) T cell cultures, the source of DCL-2, resulted in significant suppression of both the proliferative and lymphokine response to GLA. Suppression by GPhe of the 1 degree LN response was subsequently shown to be neither antigen- nor haplotype restricted, and was inhibitable by polyclonal anti-GPhe antibodies. Studies were extended to a GLA-reactive T cell hybridoma clone (DL.4G6.1). where significant suppression by GPhe of GLA-stimulated lymphokine production was observed as measured by markedly decreased HT-2 stimulatory activity of the collected supernatants. Subsequent antibody blocking experiments employing the monoclonal anti-murine IL-4 antibody 11B11 revealed that BALB/c GLA-reactive 1 degree LN T cells and DL.4G6.1 did not produce detectable levels of IL-4 in their culture fluids when stimulated by GLA, which suggested that these cells, unlike DCL-2, were TH1-like in nature. The addition of GPhe to the TH1 clones 5.2 and 5.9 resulted in significant suppression of proliferation to homologous antigen (ovalbumin), in contrast to the augmentation observed with the TH2 cell lines DCL-2 and D10.G4.1. It was concluded from these data, that the addition of GPhe to various T cell cultures lead to unusual suppressive and augmenting activities specific for TH1 and TH2 cells, respectively. Although the mechanism for these dichotomous effects of GPhe is as yet undetermined, several possibilities are considered.     

Two types of murine helper T cell clone. II. Delayed-type hypersensitivity is mediated by TH1 clones

We have previously shown that at least two types of Lyt-1+, Lyt-2-, L3T4+ helper T cell clones can be distinguished in vitro by different patterns of lymphokine secretion and by different forms of B cell help. Evidence is presented here to show that one type of helper T cell clone (TH1) causes delayed-type hypersensitivity (DTH) when injected with the appropriate antigen into the footpads of naive mice. The antigen-specific, major histocompatability complex (MHC)-restricted footpad swelling reaction peaked at approximately 24 hr. Footpad swelling was induced by all TH1 clones tested so far, including clones specific for soluble, particulate, or allogeneic antigens. In contrast, local transfer of TH2 cells and antigen did not produce a DTH reaction, even when supplemented with syngeneic spleen accessory cells. Similarly, local transfer of an alloreactive cytotoxic T lymphocyte clone into appropriate recipients did not produce DTH. The requirements for the DTH reaction induced by TH1 cells were investigated further by using TH1 clones with dual specificity for both foreign antigens and M1s antigens. Although these clones responded in vitro to either antigen + syngeneic presenting cells, or M1s disparate spleen cells, they responded in vivo only to antigen + MHC and did not cause footpad swelling in an M1s-disparate mouse in the absence of antigen. Moreover, in vitro preactivation of TH1 or TH2 cells with the lectin concanavalin A was insufficient to induce DTH reactions upon subsequent injection into footpads. From these results, we conclude that the lack of DTH given by TH2 clones in vivo could be due to the inability of the TH2 cells to produce the correct mediators of DTH, or to a lack of stimulation of TH2 clones in the footpad environment.     

Antigen-specific activation of effector macrophages by IFN-gamma producing (TH1) T cell clones. Failure of IL-4-producing (TH2) T cell clones to activate effector function in macrophages

IFN-gamma-producing (TH1) and IL-4-producing (TH2) clones were assayed for their ability to directly induce cytostatic activity in macrophages generated from splenic myeloid precursors (M phi-c). In the presence, but not in the absence, of antigen, TH1 clones activated the M phi-c to inhibit the growth of P815 tumor cells in vitro. TH2 clones were not able to activate such effector activity in the M phi-c. The M phi-c did effectively present Ag to the TH2 clones as evidenced by the proliferation of TH2 cells cultured with Ag in the presence, but not in the absence, of M phi-c. Therefore, although both TH1 and TH2 were activated by cognate interaction with antigen presenting M phi-c, only TH1:M phi-c interactions displayed reciprocity resulting in activation of the M phi-c. TH1-derived lymphokines or rIFN-gamma, in the presence of LPS, could activate proteose-peptone elicited M phi, resident peritoneal M phi, and M phi-c whereas neither TH2-derived lymphokines nor rIL4 could induce detectable activity in any of the 3 M phi populations. IFN-gamma, in the absence of LPS, could activate the elicited M phi and to a lesser and more variable degree, the resident M phi Only the M phi-c consistently required both IFN-gamma and LPS for induction of cytostatic activity. Since M phi-c consistently required at least two signals for activation, the ability of TH1-derived lymphokines to synergize with TH2 cells in M phi activation was examined. TH2 could activate the Ag-presenting M phi-c in the presence of IFN-gamma. The ability of added IFN-gamma to synergize with TH2 indicates that the cognate interaction between TH2 and antigen presenting M phi-c does result in delivery of at least one of the signal required for M phi activation.     

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.     

Heterogeneity in direct cytotoxic function of L3T4 T cells. TH1 clones express higher cytotoxic activity to antigen-presenting cells than TH2 clones

In the process of generating culture supernatant from T cell clones, with anti-CD3 antibodies and the B lymphoma A20 as APC, a striking difference in the stimulation of TH1 and TH2 clones was observed, i.e., TH2 clones produced higher levels of lymphokines than TH1 clones. This prompted us to test the hypothesis that differential killing of APC (thus the removal of stimuli) by T cells led to differential T cell activation. By studying a panel of five TH1 and seven TH2 clones, it was demonstrated that TH1 clones mediated significantly higher levels of cytotoxicity toward A20 cells in the presence of soluble anti-CD3 antibody (as opposed to immobilized anti-CD3). Although T cell clones could, when activated with immobilized anti-CD3, produce lymphokines cytotoxic to A20 cells, experiments in which lymphokine production was blocked indicated that T cell clones, in the presence of soluble anti-CD3, mediated killing of A20 through direct cytotoxicity. A higher level of cytotoxicity, by TH1 compared with TH2 clones, was not restricted to anti-CD3 or a particular target cell type, because it also occurred with Con A- or Ag-dependent killing (a monocyte-macrophage cell line), and LPS blasts. Furthermore, the higher cytotoxic activity of TH1 clones compared with TH2 clones was independent of the stage of T cell activation and was unlikely a result of the length of in vitro culture. High levels of killing of APC led to low levels of T cell activation, the significance of which may be as a negative feedback mechanism in the immune response. Other biologic relevancies of higher cytotoxic activity in TH1 vs TH2 cells were also discussed.     

T cell induction of membrane IL 1 on macrophages

We have studied the role of T cells in the induction of a membrane-associated form of interleukin 1 (mIL 1) in murine macrophages. T helper cell clones and a T cell hybridoma induced macrophages to express mIL 1 after an antigen-specific, Ia-restricted interaction. Induction of mIL 1 was proportional to antigen concentration and was increased in the early course of the response in macrophages pretreated in culture with interferon-gamma. mIL 1 activity was detectable 4 hr after interaction with T cells. mIL 1 induction was inhibited by antibodies to either class II molecules or the T cell receptor. Two pathways of T cell-mediated mIL 1 induction could be defined. In the first, T cells, whose protein synthesizing capacity was completely eliminated by pretreatment with the irreversible protein synthesis inhibitor emetine, induced levels of mIL 1 expression indistinguishable from controls. In the second, T cells stimulated by paraformaldehyde-fixed macrophages in the presence of concanavalin A or antigen secreted a soluble factor that induced macrophage mIL 1 expression. Thus, it appears that T cells may induce macrophages to express mIL 1 both by direct cell-cell contact mediated through binding of T cell receptor to the Ia/antigen complex, and through the release of a lymphokine after activation. This lymphokine does not appear to be IL 2, IFN-gamma, BSF-1, or CSF-1.     

Cognate interactions between helper T cells and B cells. II. Dissection of cognate help by using a class II-restricted, antigen-specific, IL-2-dependent helper T cell clone

In order to determine the involvement of T-B cell contact vs lymphokine production in mediating B cell cycle entry and progression, Th cell clones "defective" in lymphokine production were cloned. Th-3.1 is one such clone that required IL-2 to produce significant levels of IL-4 and IFN-gamma. Unlike conventional Th clones, Th-3.1 induced B cell proliferation only in the presence of Ag and IL-2. In contrast to the absolute requirement of IL-2 for Th-3.1-induced B cell proliferation, IL-2 was not required for the formation of stable Th-3.1-B cell conjugates or Th-3.1-induced B cell entry into the G1 phase of the cell cycle. In the absence of IL-2 and under conditions that promoted Th-B cell interactions, Th-3.1 induced 10 to 20% of resting B cells to enter G1. B cell entry into the cell cycle was not inhibited by anti-lymphokine mAb or promoted by exogenous lymphokines, suggesting that endogenous lymphokine activity was not required for Th-3.1-induced G0 to G1 transition. The data suggested that the IL-2-independent induction of B cells into G1 by Th-3.1 was a cell contact-dependent event. Direct proof that Th-3.1-B cell contact was necessary for B cell cycle entry was provided by comparative in situ analysis of the RNA synthetic activity and the RNA content of B cells that were in physical contact with Th-3.1 or not in contact with Th-3.1. In situ autoradiography of RNA synthesis illustrated that a high frequency of B cells in contact with Th-3.1 expressed heightened RNA synthetic activity, whereas "bystander" B cells were less frequently induced into cycle. In situ laser cytometry of B cell size and total RNA content showed that B cells in physical contact with Th-3.1 had a higher RNA content and were larger than "bystander" B cells present in the same microcultures. This model system has allowed the dissection of T cell help into IL-2-dependent and IL-2-independent phases. Early cell contact-dependent events and B cell cycle progression into G1 were IL-2 independent, whereas the production of lymphokines (IL-4, IFN-gamma) by Th-3.1 and Th-3.1-induced B cell proliferation was IL-2 dependent.     

T cell clones for antigen selection and lymphokine production in murine Schistosomiasis mansoni.

The role of T cells in immunity to murine schistosomiasis was examined through the use of T cell clones that recognize the live schistosomulum stage of Schistosoma mansoni. T cell clones of three different phenotypes were isolated and expanded into long term culture from lymph nodes of C57B1/6J mice vaccinated with irradiated S. mansoni larvae. They were characterized by surface markers, lymphokine production, and functional assays. The m.w. range of the Ag recognized by one clone was identified through nitrocellulose blotting and confirmed with a preparation of the putative protein made by immunoaffinity purification. All but one of the clones were CD4+, CD5+, Th cells. One clone, 35, produced Il-2 and IFN-gamma and was designated a TH1 clone. The others were designated TH2 clones because of Il-4 production. One clone was CD8+ and failed to show help. Clone 35 recognized live schistosomula and produced Il-2 when presented a 27-kDa protein from nitrocellulose. It proliferated in response to purified Ag. Clone 35 participated along with macrophages to induce up to 98% killing of live schistosomula in vitro. IFN-gamma and TNF-alpha were essential to the killing mechanism whereas Il-1, Il-2, and Il-4 were not required. This study has approached Ag identification for vaccine development from the point of view of T cells and showed that TH1 cells are essential to in vitro macrophage killing of schistosomula in murine schistosomiasis.     

Membranes from both Th1 and Th2 T cell clones stimulate B cell proliferation and prepare B cells for lymphokine-induced differentiation to secrete Ig.

Plasma membranes from the mitogen-activated mouse Th2 cell clone D10.G4.1 have recently been shown to provide the cell contact-dependent signals necessary for the induction of small B cell proliferation. Together with the Th2-derived lymphokines IL-4 and IL-5, these membranes stimulate production of Ig isotypes identical to those produced when B cells were stimulated by intact Th2 cells. In contrast, Th1 clones are poor inducers of Ig production in vitro. This could be solely due to differences in the lymphokines released by Th1 and Th2 cells or to differences in the cell-cell contact signals delivered by activated Th1 and Th2 cells. We report that membranes from three different activated Th1 clones induced strong Ag-independent proliferation of small dense B cells. The level of B cell proliferation was enhanced approximately fourfold by the addition of lymphokine-containing supernatant from Con A-activated Th2 cells and was unaffected by any of the lymphokine-containing supernatants from Con A-activated Th1 clones. As with D10.G4.1 membranes, Th1 membranes alone induced B cell proliferation but not secretion of Ig. However, addition of supernatant from Con A-activated D10.G41 cells, but not any supernatants from Con A-activated Th1 cells, induced Ig secretion of all isotypes. These effects were shown to not simply result from increased B cell numbers after stimulation with Th2 lymphokines. Thus, Th1 cell clones seem to poorly induce antibody responses entirely because of their lymphokine repertoire and not because of differences or deficiencies in the ability of these cells to deliver cell contact-dependent signals to B cells.     

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.     

IL 1 induction by murine T cell clones: detection of an IL 1-inducing lymphokine

T cell activation is widely believed to depend on interleukin 1 (IL 1) provided by antigen (Ag)-presenting cells (APC). Because IL 1 is not a constitutive product of APC, we examined the features of its production during the interaction of murine T cell clones and APC. We observed that IL 1 was detectable in supernatants of most myoglobin-specific T cell clones grown with APC and Ag. Two of these T cell clones induced exceptionally high levels of IL 1 in their supernatants, and these same clones demonstrated the unusual restriction to I-Ek, which is a low responder type for sperm whale myoglobin. One of these clones was characterized additionally as to the mechanism of IL 1 induction. This clone rapidly stimulated IL 1 production in the APC population (detectable at 4 hr of co-culture) or in macrophages (M phi) or a M phi-like cell line. IL 1 induction was Ag dependent and H-2 restricted. Induction was radioresistant, both on the part of the T cell and of the IL 1 producer. The IL 1-induction process was attributable to a lymphokine produced by the T cell clone. This lymphokine was distinct from IFN-gamma, TNF and CSF-1 and may account for a principal mechanism of T----APC signalling. The induced IL 1 was the same in size, co-mitogenicity, and pyrogenicity as lipopolysaccharide-induced IL 1.     

Legionella pneumophila-Induced IL-1: Responses of murine peritoneal,splenic, and pulmonary macrophages

The ability ofLegionella pneumophila to induce secreted IL-1 (sIL-1) and membrane associated IL-1 (mIL-1) in murine peritoneal, splenic, and pulmonary macrophages was examined. Two preparations ofL. pneumophila were utilized, specifically, a formalin-killed, whole-cell preparation and viable bacteria. We demonstrated that both forms induce mIL-1 and sIL-1 in each of the macrophage populations tested; however, there were differences in the magnitude of responses with the different macrophage populations. In general, the viable bacteria induced greater IL-1 activity than did equivalent numbers of formalin-killed bacteria, with the exception of the highest concentrations tested (10⁷ bacteria/ml). The results demonstrate thatL. pneumophila induces production of both sIL-1 and mIL-1 activities by murine macrophages from a variety of tissues.     

Multidose streptozotocin induction of diabetes in BALB/c mice induces a dominant oxidative macrophage and a conversion of TH1 to TH2 phenotypes during disease progression

Macrophages (Mp) are implicated in both early and late phases in type 1 diabetes development. Recent study has suggested that a balance between reductive Mp (RMp) and oxidative Mp (OMp) is possible to regulate TH1/TH2 balance. The aim of this study is to investigate the redox status of peritoneal Mp and its cytokine profile during the development of autoimmune diabetes induced by multiple low-dose streptozotocin in BALB/c mice. Meanwhile, the polarization of TH1/TH2 of splenocytes or thymocytes was also examined. We found that peritoneal Mp appeared as an "incomplete" OMp phenotype with decreased icGSH along with disease progression. The OMp showed reduced TNF-alpha, IL-12, and NO production as well as defective phagocytosis activity compared to nondiabetic controls; however, there was no significant difference with IL-6 production. On the other hand, the levels of IFN-gamma or IL-4 of splenocytes in diabetic mice were significantly higher compared to the control mice. The ratio of IFN-gamma to IL-4 was also higher at the early stage of diabetes and then declined several weeks later after the occurrence of diabetes, suggesting a pathogenetic TH1 phenotype from the beginning gradually to a tendency of TH2 during the development of diabetes. Our results implied that likely OMp may be relevant in the development of type 1 diabetes; however, it is not likely the only factor regulating the TH1H/TH2 balance in MLD-STZ-induced diabetic mice.     

Effect of prostaglandin E2 on the gamma-interferon induction of antigen-presenting ability in P388D1 cells and on IL-2 production by T-cell hybridomas

The effect of prostaglandin E2 on the gamma-interferon (IFN-gamma)-mediated induction of Ia expression and antigen-presenting activity in macrophage cell lines was studied. Using a lymphokine preparation obtained from the T-cell hybridoma FS7-20.6.18 (known to produce interferon) to induce the expression of Ia in P388D1 cells, the influence of PGE2 on this phenomenon was studied. Screening of the cell cultures by indirect immunofluorescence using an anti-I-Ad monoclonal antibody confirmed the inhibitory effect of PGE2 in the induction of I-Ad. However, the inhibition of the antigen-presenting ability of these cells, as measured by their capacity to stimulate interleukin 2 (IL-2) production by antigen-specific, I-region-restricted (Ag/I) T-cell hybridomas, was more difficult to demonstrate and was only evident when using low concentrations of Ia-inducing lymphokines or when using "low avidity" T-cell hybridomas. The latter were distinguished by the limited response (in the form of IL-2 production) that was observed when they were tested with P388D1 cells that had been induced with IFN-gamma. By contrast, PGE2 had profound inhibitory effects on the ability of T-cell hybridomas to secrete IL-2 in response to Ag/I or concanavalin A. These results suggest that although PGE2 inhibits the full induction of Ia on macrophages, it has little effect on the induction of Ag/I presentation by the same cells, probably because most T cells require relatively low levels of Ia on the surface of presenting cells. T-cell responses to Ag/I are inhibited, however, because of the effects of PGE2 on the T cells themselves.