The Effect of PGE2 on Murine Helper-T-Cell Lymphokines

Prostaglandin E₂ (PGE₂) has selective effects on the production of murine helper-T-cell lymphokines. PGE₂ inhibits production of the Th1-associated lymphokines IL-2 and IFN-γ, but does not inhibit production of the Th2-associated lymphokines IL-4 and IL-5. This could have been due to differences in the Th1 and Th2 cells themselves or to differences in the cytokines. To discriminate between these models we first examined the effect of PGE₂ on IL-3 production, a lymphokine produced by both Th1 and Th2 cells. IL-3 production was inhibited by PGE₂ in some cells and enhanced in others, indicating that some property of the cell was critical. However, the effect on IL-3 production did not cleanly discriminate between Th1 and Th2 cells. Second, we examined the effect of PGE₂ on lymphokine production from Th0 cells. In some cells, production of IL-2, IL-3, and IL-4 was inhibited by PGE₂. In other cells, IL-2 and IL-3 were inhibited while IL-4 production was enhanced. These data again indicated that it was a property of the T cell, not necessarily the lymphokine itself, that determined the response to PGE₂. In Th1 and Th2 clones, both the mode of primary stimulation (antigen and antigen-presenting cells or calcium ionophore) and the presence of costimulation also were found to affect the response of IL-3 production to PGE₂. Therefore, the effect of PGE₂ on lymphokine production appears to depend upon the intracellular signaling pathways that are activated within a particular T cell.     

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.     

Central role for TCR/CD3 ligation in the differentiation of CD4+ T cells toward A Th1 or Th2 functional phenotype.

Activated CD4+ T cells can be classified into distinct subsets; the most divergent among them may be considered to be the IL-2 and IFN-gamma-producing Th1 clones and the IL-4 and IL-5-producing Th2 clones. Because Th1 and Th2 clones can usually be detected only after several months of culture, we used conditions that modulate the IL-2 and IL-4 production in short term culture. Here we show that freshly isolated and subsequently in vitro-activated CD4+ T cells that were cultured for 11 days with rIL-2 and restimulated showed a IFN-gamma+ IL-2+ IL-3+ IL-4- IL-5- pattern. Because these cells were not capable of providing B cell help for IgG1, IgG2a, or IgE in an APC- and TCR-dependent T-B cell assay, they expressed a phenotype typical for most Th1 clones. In contrast, activated T cells that were cultured for 11 days with IL-2 plus a mAb to CD3 and then restimulated produced a IFN-gamma- IL-2- IL-3+ IL-4+ IL-5+ pattern. These cells were capable of providing B cell help for IgG1, IgG2a, and IgE synthesis and thus presented a phenotype typical for Th2 clones. Similar results were observed when mitogenic mAb to Thy-1.2 or to framework determinants of the alpha beta TCR were used. The induction of Th1- and Th2-like cells did not depend on the relative expression of CD44 or CD45 by the T cells before activation in vitro. Because the incubation of activated T cells with anti-CD3/TCR mAb induced high unrestricted lymphokine production, the latter might be responsible for the Th2-like lymphokine pattern observed after restimulation. To address this point, TCR V beta 8+ and V beta 8- T cell blasts were co-cultured in the presence of mAb to V beta 8. After restimulation, V beta 8+ cells had a IL-4high IL-2low phenotype and V beta 8- cells had a IL-4low IL-2high phenotype. This demonstrates that TCR ligation but not lymphokines alone are capable of inducing Th2-like cells, and this points out a central role for the TCR in the generation of T cell subsets.     

Cognate interactions between helper T cells and B cells. V. Reconstitution of T helper cell function using purified plasma membranes from activated Th1 and Th2 T helper cells and lymphokines.

Th physically interact with B cells and produce lymphokines that influence B cell growth and differentiation. The respective contribution of cell contact and lymphokines to induction of B cell growth and differentiation was addressed using purified plasma membranes (PM) from resting Th (PMrest) and anti-CD3-activated Th (PMCD3) together with lymphokines. Results show that PMCD3, but not PMrest, induce 10% of resting B cells to enter the G1 phase of the cell cycle, with few B cells entering G1b and S/G2. The inclusion of IL-4, but not IL-2, IL-5, or IFN-gamma, amplifies the B cell response to PMCD3 by increasing the total percentage of activatable B cells to greater than 40% and inducing B cell progression into G1b, S, and G2. Direct comparison between PMrest and PMCD3 purified from Th1 and Th2 indicate that both Th1 and Th2 induce similar levels of B cell proliferation in the presence of IL-4. Further, the lymphokine requirements for B cell proliferation induced by PMCD3 from Th1 and Th2 is indistinguishable. B cell differentiation to IgM, IgG1, and IgG2a synthesis by PMCD3 required IL-4 and IL-5. Using lymphokine conditions that supported B cell differentiation, PMCD3 purified from Th1 and Th2 induced similar levels of IgM, and IgG1. Given the functional data on PMCD3 from Th1 and Th2, the data indicate that there are no substantive differences between Th1- and Th2-derived PMCD3, and that the major differences in the ability of viable Th1 and Th2 to activate B cells is the lymphokines produced by the cells.     

Characterization of T helper 1 and 2 cell subsets in normal mice. Helper T cells responsible for IL-4 and IL-5 production are present as precursors that require priming before they develop into lymphokine-secreting cells

We have shown that the requirements for the production of IL-4 and IL-5 by normal L3T4+T cells from murine spleen are very different from those for the production of IL-2. Secretion of detectable quantities of IL-4 and IL-5 and induction of the mRNA for each lymphokine occurs in vitro only after cells are primed and re-stimulated. This priming can be achieved by mitogens (Con A), by antibodies to the TCR (anti-T3) or by stimulation with alloantigen. In contrast, requirements for induction of lymphokine production after priming resemble those for initial production of IL-2. Thus the majority of T cells of helper phenotype that have the potential to become IL-4- and IL-5-secreting T cells, exist in the form of precursors requiring stimulation and several days of culture as well as re-stimulation with mitogen or Ag before they become detectable as lymphokine-secreting cells. In contrast, among fresh CD4+T cells, secretion of IL-2, IL-3, granulocyte/macrophage CSF, and IFN-gamma is easily detected within 24 h of stimulation with mitogen or Ag. These observations establish that distinct phenotypes of Th cells are found at different times after stimulation and support the concept that synthesis and secretion of different lymphokines or groups of lymphokines are regulated independently. Furthermore the patterns of lymphokines secreted by fresh vs primed Th cells, which largely correspond to the patterns that have been used to define the Th1 and Th2 subsets among Th cell lines, provides evidence that different subsets of normal T cells exist that may correspond to these designations. Secretion of different lymphokines by two subsets of Th cells at different times in an immune response, and perhaps in different places, suggests a model in which the ratio of the two T cell subsets (Th1 vs Th2) and state of differentiation of each (precursor vs effector), influence or determine the direction of the response, with variations in these parameters leading to differing responses.     

Generation of B cell memory and affinity maturation. Induction with Th1 and Th2 T cell clones.

We used an adoptive transfer system and CD4+ T cell clones with defined lymphokine profiles to examine the role of CD4+ T cells and the types of lymphokines involved in the development of B cell memory and affinity maturation. Keyhole limpet hemocyanin (KLH)-specific CD4+ Th2 clones (which produce IL-4 and IL-5 but not IL-2 or IFN-gamma) were capable of inducing B cell memory and affinity maturation, after transfer into nude mice or after transfer with unprimed B cells into irradiated recipients and immunization with TNP-KLH. In addition, KLH-specific Th1 clones, which produce IL-2 and IFN-gamma but not IL-4 or IL-5, were also effective in inducing B cell memory and high affinity anti-TNP-specific antibody. The induction of affinity maturation by Th1 clones occurred in the absence of IL-4, as anti-IL-4 mAb had no effect on the affinity of the response whereas anti-IFN-gamma mAb completely blocked the response. Th1 clones induced predominantly IgG2a and IgG3 antibody, although Th2 clones induced predominantly IgG1 and IgE antibody. We thus demonstrated that some Th1 as well as some Th2 clones can function in vivo to induce Ig synthesis. These results also suggest that a single type of T cell with a restricted lymphokine profile can induce both the terminal differentiation of B cells into antibody secreting cells as well as induce B cell memory and affinity maturation. Moreover, these results suggest that B cell memory and affinity maturation can occur either in the presence of Th2 clones secreting IL-4 but not IFN-gamma, or alternatively in the presence of Th1 clones secreting IFN-gamma but not IL-4.     

CD4+ subset regulation in viral infection. Preferential activation of Th2 cells during progression of retrovirus-induced immunodeficiency in mice.

Progressive lymphoproliferation and increasingly severe immunodeficiency are prominent features of a syndrome, designated mouse AIDS, which develops in susceptible strains of mice infected with the mixture of murine leukemia viruses, termed LP-BM5. Development of splenomegaly and lymphadenopathy, caused primarily by increases in B cell immunoblasts, requires the presence of CD4+ T cells and is assumed to be mediated by lymphokines produced by these cells inasmuch as progression of disease is markedly inhibited by treatment of infected mice with cyclosporin A. Studies of spleen cells from infected mice revealed spontaneous production of cytokines (IFN-gamma, IL-2, IL-4, IL-5, and IL-10) characteristic of Th0 (or a mixture of Th1 and Th2) T helper cells at 1 wk after infection. At later times, IFN-gamma and IL-2, characteristic products of Th1 helper clones, were expressed poorly, either spontaneously or after stimulation of cells with Con A. In contrast, IL-4, IL-5, IL-6, and IL-10, cytokines typically synthesized by Th2 cells, were produced in response to Con A or spontaneously through 18 wk post-infection. Increased serum IgE levels and enhanced IL-10 mRNA expression were consistent with expression of Th2 cytokines at biologically significant levels in vivo. Selective depletion of T cell subsets before stimulation with Con A showed that CD4+ T cells were the primary source of IL-2, IL-4, IL-10, and, to a lesser extent, IFN-gamma in spleens and lymph nodes of normal or infected mice. These results suggest that persistent activation of CD4+ T cells with the lymphokine profile of Th2 helper clones is responsible for chronic B cell stimulation, down-regulation of Th1 cytokines, and impaired CD8+ T cell function in mouse AIDS. This provides the first demonstration that, like many parasitic infections, viruses encoding potent antigenic stimuli can markedly affect the balance of Th subset expression.     

IL-4 directs the development of Th2-like helper effectors

Our studies show that the presence of IL-4 during the response of naive Th cells causes precursors to develop into a population comprised largely of "Th2-like" effectors that secrete IL-4 and IL-5, but little IL-2 or IFN-gamma. We find that the levels of IL-4 and IL-2 determine both the level of effectors developed in response to mitogen or Ag and the patterns of lymphokines they secrete when restimulated. IL-2 is required for optimum generation of effectors, and increasing levels of IL-2, augments the expansion of effectors secreting both IL-4/IL-5 and IFN-gamma. In contrast, IL-4 is required for the development of IL-4/IL-5 secreting effectors but suppresses the development of IL-2 and at higher doses IFN-gamma-secreting effectors detected after 4 days. Also dramatic are the effects of the presence or absence of IL-4 evaluated after an additional 1 to 2 wk. When cultures with or without initial IL-4 are cultured in IL-2 alone from days 4 to 11, they retain their distinct patterns of lymphokine production. Those cells that developed in cultures without IL-4 progressively secrete more IL-2 and can be maintained and expanded in IL-2. They continue to produce IFN-gamma, though the levels decrease somewhat with time, but they do not acquire the ability to produce IL-4 or IL-5. These cells thus increasingly resemble Th1 cell lines. In contrast, those cells in cultures initially exposed to IL-4, generate effectors which secrete high levels of IL-4/IL-5 (plus variable levels of IFN-gamma) at days 4 to 5, but the populations of cells developed, are not maintained well on IL-2 alone. Those cells that do survive continue to secrete IL-4 and IL-5 but not IL-2. In addition, IFN-gamma production, if present, falls off with time. Thus the cells in these cultures take on an increasingly Th2-like phenotype. It appears that the effects of low levels of IL-4 in suppressing IL-2 production by day 4 effectors appear to be transient whereas the higher levels appear to drive the development along a distinct pathway which is irreversible. These studies support the concept that different subsets of helper cells, which correspond roughly to Th1 and Th2 subsets, can develop rapidly in short term culture with respectively low vs high levels of IL-4. They support the concept that such distinct phenotypes arise from alternate pathways of differentiation that can be expected to reflect pathways available for helper T cell differentiation in the animal.     

Induction of antigen-specific antibody responses in primed and unprimed B cells. Functional heterogeneity among Th1 and Th2 T cell clones

CD4+ T cells have been recently divided into two subsets. The functions of these subsets are thought to be distinct: one subset (Th1) is responsible for delayed type hypersensitivity responses and another (Th2) is primarily responsible for induction of antibody synthesis. To more precisely define the roles of both subsets in humoral immune responses, we examined the ability of a panel of nominal antigen specific Th1 and Th2 clones to induce anti-TNP specific antibody synthesis in TNP-primed or unprimed B cells. Four of nine Th1 clones induced little or no antibody synthesis with TNP-primed B cells. However, five other Th1 clones were very effective at inducing IgG anti-TNP plaque-forming cell (PFC) responses in primed B cells. One of these Th1 clones was analysed in detail and found to also provide helper function for unprimed B cells. Cognate B-T cell interaction was required for induction of both primary and secondary responses with this clone, indicating that a Th1 clone could function as a "classical" Th cell. The seven IL-4 producing Th2 clones examined were also heterogeneous in their ability to induce antibody secretion by TNP-primed B cells. Although four of the Th2 clones induced IgG and IgM anti-TNP PFC responses, two Th2 clones induced only IgM and no IgG antibody, and another clone failed to induce any anti-TNP PFC. All Th2 clones failed to induce any anti-TNP PFC. All Th2 clones produced high levels of IL-4, but "helper" Th2 clones produced significantly greater amounts of IL-5 than "non-helper" Th2 clones. These studies indicate that some IL-2- and some IL-4-producing T cell clones can induce TNP-specific antibody in cell clones can induce TNP-specific antibody in primed and unprimed B cells, and that Th1 and Th2 clones are heterogeneous in their ability to induce Ig synthesis. Therefore, although T cell clones can be classified as Th1 or Th2 types according to patterns of IL-2, IFN-gamma, or IL-4 synthesis, the functional capacity to induce antibody synthesis cannot be predicted solely by their ability to secrete these lymphokines.     

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.     

Prostaglandin E2 selectively inhibits human CD4+ T cells secreting low amounts of both IL-2 and IL-4

PGE2 is a potent inflammatory mediator with profound immune regulatory actions. The present study examined the effects of PGE2 on the activation/proliferation of CD4+ T cells using 37 cloned CD4+ T cell lines. Ten T cell clones sensitive to PGE2 and 10 T cell clones resistant to PGE2, as measured by proliferation in response to anti-CD3 Ab, were selected for comparison. It was found that the PGE2-sensitive T cells were characterized by low production (<200 pg/ml) of both IL-2 and IL-4, while PGE2-resistant T cells secreted high levels (>1000 pg/ml) of IL-2, IL-4, or both. The roles of IL-2 and IL-4 were confirmed by the finding that addition of exogenous lymphokines could restore PGE2-inhibited proliferation, and PGE2-resistant Th1-, Th2-, and Th0-like clones became PGE2 sensitive when IL-2, IL-4, or both were removed using Abs specific for the respective lymphokines. In addition, we showed that the CD45RA expression in PGE2-sensitive T cells was significantly lower than that in PGE2-resistant cells (mean intensity, 1.2 +/- 0.6 vs 7.8 +/- 5.7; p = 0.001). In contrast, CD45RO expression in PGE2-sensitive T cells was significantly higher that that in PGE2-resistant cells (mean intensity, 55.7 +/- 15.1 vs 33.4 +/- 12.9; p = 0.02). In summary, PGE2 predominantly suppressed CD45RA-RO+ CD4+ T cells with low secretion of both IL-2 and IL-4.     

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.     

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.     

A common factor regulates both Th1- and Th2-specific cytokine gene expression.

Murine T helper cell clones are classified into two distinct subsets, T helper 1 (Th1) and T helper 2 (Th2), on the basis of cytokine secretion patterns. Th1 clones produce interleukin-2 (IL-2), tumor necrosis factor-beta (TNF-beta) and interferon-gamma (IFN-gamma), while Th2 clones produce IL-4, IL-5, IL-6 and IL-10. These subsets differentially promote delayed-type hypersensitivity or antibody responses, respectively. The nuclear factor NF-AT is induced in Th1 clones stimulated through the T cell receptor-CD3 complex, and is required for IL-2 gene induction. The NF-AT complex consists of two components: NF-ATp, which pre-exists in the cytosol and whose appearance in the nucleus is induced by an increase of intracellular calcium, and a nuclear AP-1 component whose induction is dependent upon activation of protein kinase C (PKC). Here we report that the induction of the Th2-specific IL-4 gene in an activated Th2 clone involves an NF-AT complex that consists only of NF-ATp, and not the AP-1 component. On the basis of binding experiments we show that this 'AP-1-less' NF-AT complex is specific for the IL-4 promoter and does not reflect the inability of activated Th2 cells to induce the AP-1 component. We propose that NF-ATp is a common regulatory factor for both Th1 and Th2 cytokine genes, and that the involvement of PKC-dependent factors, such as AP-1, may help determine Th1-/Th2-specific patterns of gene expression.     

Comparison of Th1- and Th2-associated immune reactivities stimulated by single versus multiple vaccination of mice with irradiated Schistosoma mansoni cercariae.

Mice immunized against Schistosoma mansoni by a single percutaneous exposure to radiation-attenuated parasite larvae demonstrate partial resistance to challenge infection that has been shown to correlate with development of cell-mediated immunity, whereas mice hyperimmunized by multiple exposure to attenuated larvae produce antibodies capable of transferring partial protection to naive recipients. Measurement of Ag-specific lymphokine responses in these animals suggested that the difference in resistance mechanisms may be due to the differential induction of Th subset response by the two immunization protocols. Thus, upon Ag stimulation, singly immunized mice predominantly demonstrated responses associated with Th1 reactivity, including IL-2 and IFN-gamma production, whereas multiply immunized animals showed increased IL-5, IL-4, and IgG1 antibody production associated with enhanced Th2 response. These responses demonstrated some degree of organ compartmentalization, with splenocytes demonstrating higher Th1-related lymphokine production and cells from draining lymph nodes showing stronger proliferation and Th2 type reactivity. However, hyperimmunized mice also continued to demonstrate substantial Th1-associated immune reactivity. Moreover, in vivo Ag challenge elicited activated larvacidal macrophages in hyperimmunized animals. These observations indicate that protective cell-mediated mechanisms associated with induction of CD4+ Th1 cell reactivity predominate in singly vaccinated mice. Further vaccination stimulates Th2 responses, such as enhanced IgG1 production, that may also contribute to protective immunity.     

Distinct regulation of lymphokine production is found in fresh versus in vitro primed murine helper T cells

The kinetics of lymphokine RNA induction and secretion of biologically active lymphokine from CD4-enriched splenic T cell populations was investigated. Cells stimulated immediately after isolation from murine spleen ("fresh" T cells) and cells restimulated after 4 days of in vitro culture ("primed" T cells) were compared. Northern blot analysis and bioassays were used to analyze and quantitate production of eight lymphokines and the IL-2R. Fresh T cells produced high levels of IL-2 and low to moderate levels of IL-3, granulocyte/macrophage-CSF, and IFN-gamma. In vitro primed T cells produced IL-2, IL-3, IL-4, IL-5, IL-6, granulocyte/macrophage-CSF, IFN-gamma, and high levels of IL-2R RNA. Comparison of RNA levels and bioassays of supernatants from these populations indicated that primed T cells produced at least 10-fold more of six of the lymphokines than fresh T cells. Only IL-2 was produced in near equal amounts by fresh and primed T cells. There were also marked differences in the kinetics of lymphokine production by fresh and primed CD4+ T cells. After restimulation with Con A and PMA, primed cells produced a short burst of lymphokine RNA that peaked between 7.5 and 13 h and declined after 18 h. Fresh T cells lagged in the initial production of lymphokine RNA, with levels peaking 18 to 44 h after mitogenic stimulation. Depletion of CD4+ cells indicated that cells of helper phenotype were responsible for the majority of lymphokine production from the primed cells. Thus different subpopulations of Th cells defined by their respective ability to respond either directly (fresh T cells) or only after culture and restimulation (primed T cells) show different patterns of lymphokine gene regulation. Other studies suggest that the activity of "fresh" Th cells is due to a population with a "memory" phenotype, while the cells which require culture have a "precursor" phenotype. These distinct patterns of lymphokine gene regulation in the two populations of Th cells may account in part for differences seen in the kinetics and magnitude of the naive and memory immune responses which are regulated by Th cells.     

In vivo molecular analysis of lymphokines involved in the murine immune response during Schistosoma mansoni infection. II. Quantification of IL-4 mRNA, IFN-gamma mRNA, and IL-2 mRNA levels in the granulomatous livers, mesenteric lymph nodes, and spleens during the course of modulation.

Parasite egg-induced granulomas are the primary pathogenic lesions in murine schistosomiasis mansoni. This cell-mediated granulomatous response is specific for soluble egg Ag and appears to be mediated predominantly by CD4+ Th2 cells. As infection progresses from the acute to the chronic phase, the cell-mediated anti-soluble egg Ag responses attenuate in a process termed modulation. In this study the hypothesis that modulation is effected by a chronic phase increase in Th2-inhibiting Th1 cell activity was investigated. Northern blot quantification of mRNA specific for the Th2 lymphokine, IL-4, and the Th1 lymphokines, IFN-gamma and IL-2, in the spleens, mesenteric lymph nodes, and granulomatous livers of mice infected for various lengths of time over the course of modulation was performed. Also, the capacity of mitogen- and Ag-stimulated spleen cells to produce message for these lymphokines was compared. Peak tissue levels of both IL-4 mRNA and IFN-gamma mRNA were seen in acutely infected mice, and levels of both messages declined as infection became chronic. Stimulated spleen cells from acutely infected mice also produced higher levels of IL-4 and IFN-gamma mRNA than cells from chronically infected mice. IL-2 mRNA was never detected in any tissue sample but was detected in the stimulated spleen cells, again with acute phase levels higher than chronic phase levels. Hence, this study shows no evidence for increased Th1 cell activity during chronic infection and suggests that modulation may be effected by a generalized suppression of lymphokine synthesis.     

Correlation between the biologic functions and the generation of lymphokines in T cell clones

We have recently reported that various murine T cell clones produce IL-1. Based on this observation we have analyzed in the present study the correlation between the biological functions and the generation of different lymphokines in (T,G)-A--L specific CD4+ clones. One subset of clones--the "helper clones"--were found to provide help to primed B cells, in vitro. These cells could be shown to produce IL-1, IL-2, and B cell stimulatory factor 1 (IL-4) activities and to express mRNA encoding for these three cytokines. The second subset of clones, termed "proliferative clones", were unable to help B cells in vitro but expressed vigorous Ag-dependent proliferations. These cells did not express IL-1, IL-2, or IL-4 activities. They produced another lymphokine(s) which may be granulocyte-macrophage-CSF, or some other factor recognized by the HT2 cell line. This study further substantiates the link between T cell activities and lymphokine repertoire with a special emphasis on the potential role(s) of T cell-derived IL-1.     

Protein kinase A regulates GATA-3-dependent activation of IL-5 gene expression in Th2 cells

Treatment of Th cells with compounds that elevate cAMP levels augments Th2-type lymphokine expression, in particular the synthesis of IL-5. Using primary murine CD4(+) T lymphocytes, we show in this study that inhibition of protein kinase A (PKA) activity in Th2 effector cells impairs IL-5 synthesis, whereas the expression of PKA catalytic subunit alpha enhances IL-5 synthesis in Th0 cells. In addition, we observed by coexpression of PKA catalytic subunit and GATA-3 in Th1 cells that the stimulatory effect of PKA is dependent on GATA-3 activity. These data demonstrate that activation of PKA in Th effector cells induces the IL-5 gene expression in a GATA-3-dependent manner.