Disodium cromoglycate inhibits S mu-->S epsilon deletional switch recombination and IgE synthesis in human B cells.

IgE synthesis requires interleukin 4 (IL-4) and a T-B cell interaction that involves the B cell antigen CD40 and its ligand expressed on activated T cells. IL-4 induces epsilon germline transcription whereas ligation of CD40 results in deletional S mu-->S epsilon switch recombination, expression of mature epsilon transcripts, and IgE synthesis and secretion. We demonstrate that disodium cromoglycate (DSCG), a drug commonly used for the prophylactic treatment of allergic disease, inhibits T cell-driven IgE synthesis by human B cells at concentrations readily achievable in the course of inhaled therapy for asthma. Inhibition of IgE synthesis by DSCG was not the result of drug toxicity because DSCG did not affect the viability of T and B cells or their proliferation to mitogens. DSCG did not interfere with CD40 ligand expression by T cells but clearly targeted the B cells because it inhibited IgE synthesis induced by anti-CD40 and IL-4 in populations of highly purified B cells. DSCG had no effect on the induction of epsilon germline transcripts by IL-4 but strongly inhibited CD40 mediated S mu-->S epsilon deletional switch recombination in IL-4-treated B cells as assayed by nested primer PCR. The effect of DSCG was not specific for CD40-mediated induction of IgE isotype switching because DSCG inhibited IgE synthesis as well as S mu-->S epsilon deletional switch recombination induced by hydrocortisone and IL-4 in B cells. Moreover, the effect of DSCG was not specific for IgE isotype switching because DSCG inhibited the synthesis of IgG4 by B cells sorted for lack of surface expression of IgG4 and stimulated with anti-CD40 and IL-4. DSCG caused only minimal inhibition (< 15%) of spontaneous IgE synthesis by lymphocytes from patients with the hyper-IgE syndrome and did not affect pokeweed mitogen-induced IgG and IgA synthesis by lymphocytes suggesting that it has little effect on B cells that have already undergone isotype switching. These results indicate that DSCG inhibits switching to IgE in B cells and suggest a novel potential mechanism for the prevention of allergic disease by DSCG.

CD40 and IgE: synergism between anti-CD40 monoclonal antibody and interleukin 4 in the induction of IgE synthesis by highly purified human B cells.

A novel pathway of IgE-B cell differentiation has been identified. Engagement of the B cell antigen CD40 by F(ab')2 fragments of monoclonal antibody (mAb) 626.1 in the presence of recombinant interleukin 4 (rIL-4) induced intense IgE synthesis, but modest IgG synthesis, by highly purified human B cells. Surface IgE- B cells isolated by cell sorting were induced to produce IgE by mAb 626.1 and IL-4. Thus, IgE synthesis is unlikely to result from expansion of a B cell population precommitted to IgE in vivo. A neutralizing anti-IL-6 antibody strongly, but not completely, inhibited the IgE response. This indicates that autocrine production of IL-6 plays an important amplification role in IgE synthesis triggered by anti-CD40 mAb and IL-4. Although the exact role played by CD40 in IgE responses in vivo remains to be established, this T cell-independent system represents a useful model to characterize the biochemical and molecular events leading to IgE synthesis in human B cells.

Induction of human IgE synthesis requires interleukin 4 and T/B cell interactions involving the T cell receptor/CD3 complex and MHC class II antigens.

The induction of IgE synthesis by IL-4 requires T cells and monocytes, as well as T cell- and monocyte-derived cytokines. Optimal cytokine combinations, however, fail to induce highly purified B cells to secrete IgE, indicating that additional signals are required. We show herein that the induction of human IgE synthesis by rIL-4 requires cognate interaction between the T cell receptor/CD3 complex on T cells and MHC class II antigens on B cells: mAbs directed against these molecules completely blocked IL-4-dependent IgE induction. mAbs against cell adhesion molecules (CD2, CD4, LFA-1) also inhibited IgE synthesis induced by IL-4, confirming that cell-cell contact is necessary for IgE induction. The requirement for cognate T/B cell interaction was further shown by comparing the IgE-inducing ability of two human IL-4-producing alloreactive T cell clones: F6, which recognizes MHC class II antigens on both B cells and monocytes, and A1, which recognizes an HLA-DP-associated epitope expressed on monocytes, but not on B cells. When incubated with B cells and monocytes from a normal donor bearing the appropriate alloantigen, clone F6, but not clone A1, induced vigorous IgE synthesis, although both clones proliferated and secreted IL-4. Taken together, our results suggest that at least two, possibly synergizing, signals are required for the T cell-dependent induction of IgE synthesis by B cells: one signal is delivered by cognate T/B cell interaction, the other by T cell-derived IL-4.

Differential requirements of B cells from normal and allergic subjects for the induction of IgE synthesis by an alloreactive T cell clone.

Human T cell helper/inducer clones were used to induce IgE synthesis in B cells from both allergic and nonallergic donors. An alloreactive T cell clone, activated by recognition of specific HLA-DR antigens, stimulated peripheral blood B cells from both allergic and nonallergic donors to synthesize IgE antibody. B cells of allergic donors differed from those of nonallergic donors in their requirements for induction of IgE synthesis. Induction of IgE synthesis in B cells from nonallergic individuals occurred only under conditions of cognate interaction, in which the B cells expressed the alloantigen recognized by the T cells. In contrast, IgE synthesis in B cells from allergic donors occurred under conditions of cognate interaction with T cells as well as bystander conditions where the B cells did not express the alloantigen recognized by the T cell clones and where the T cell clones were stimulated by third-party monocytes bearing the relevant alloantigens. Furthermore, bystander stimulation of IgE synthesis in allergic donors occurred in the presence of tetanus toxoid (TT) antigen-specific T cell clones activated by the appropriate TT-pulsed monocytes. In contrast to the differing requirements of B cells from normal vs. allergic subjects for the induction of IgE synthesis, these B cells did not differ in their requirements for the induction of IgG synthesis. IgG synthesis was induced in all B cells under conditions of cognate interaction with the T cells as well as under conditions of bystander stimulation. These results suggest that cognate T-B cell interactions may be important in the development of IgE immune responses in the normal host.

Molecular analysis of the induction of immunoglobulin E synthesis in human B cells by interleukin 4 and engagement of CD40 antigen.

The molecular events leading to immunoglobulin E (IgE) synthesis in human sIgE- B cells stimulated with interleukin 4 (IL-4) and anti-CD40 monoclonal antibody (mAb) 626.1 were analyzed. Anti-CD40 mAb increased the levels of IL-4-induced germline C epsilon transcripts and induced the production of mature C epsilon mRNA. These effects were dependent on the presence of IL-4. Nested primer PCR revealed deletional switch recombination occurring only in B cell stimulated with both IL-4 and anti-CD40 mAb. DNA sequence analysis of switch fragments showed direct S mu/S epsilon joining, without the deletions or duplications within S mu often found in B cells stimulated with IL-4 and Epstein-Barr virus. Analysis of the switch junction map sites showed "hot spots" for recombination within S mu, but not within S epsilon. These findings indicate that IL-4 provides a signal to B cells to induce germline C epsilon transcription and concurrent CD40 engagement induces S mu/S epsilon deletional switch recombination, production of mature C epsilon mRNA, and IgE synthesis.

Human recombinant interleukin 4 induces Fc epsilon R2/CD23 on normal human monocytes.

rIL-4 (B cell stimulatory factor 1) induces the expression of Fc epsilon R2/CD23 on normal human monocytes (Mo). Fc epsilon R2/CD23 induction was detectable both by flow cytometry using anti-CD23 mAbs as well as soluble IgE, and by the immunoprecipitation with CD23-specific mAb or IgE of a 45-kD band from 125I-lactoperoxidase-labeled Mo. Fc epsilon R2/CD23 was fully expressed after a 24-h incubation with rIL-4, and was still detectable after 72 h from the addition of IL-4. This effect was specific, because none of the other rILs tested (IL-1, IL-2, IL-3, IL-5, B cell stimulatory factor 2, granulocyte-macrophage colony stimulating factor, and IFN-gamma) could induce FC epsilon R2/CD23, either alone or in various combinations. No synergism was observed between IL-4 and other ILs. IFN-gamma was not able to inhibit the IL-4-induced expression of Fc epsilon R2/CD23 on Mo, neither when added to the culture together with IL-4, nor when added 36 h earlier.

Glucocorticoids upregulate CD40 ligand expression and induce CD40L-dependent immunoglobulin isotype switching.

IL-4 and CD40 ligation are essential for IgE synthesis by B cells. We have shown previously that hydrocortisone (HC) induces IgE synthesis in IL-4-stimulated human B cells. In this study we demonstrate that HC fails to induce IgE synthesis in B cells from CD40 ligand-deficient (CD40L-deficient) patients. Disruption of CD40L-CD40 interactions by soluble CD40-Ig fusion protein or anti-CD40L mAb blocked the capacity of HC to induce IgE synthesis in normal B cells. HC upregulated CD40L mRNA expression in PBMCs and surface expression of CD40L in PBMCs as well as in purified populations of T and B cells. Upregulation of CD40L mRNA in PBMCs occurred 3 hours after stimulation with HC and was inhibited by actinomycin D. Upregulation of CD40L mRNA and induction of IgE synthesis by HC were inhibited by the steroid hormone receptor antagonist RU-486. These results indicate that ligand-mediated activation of the glucocorticoid receptor upregulates CD40L expression in human lymphocytes.

Human dermal fibroblasts present tetanus toxoid antigen to antigen-specific T cell clones.

Cultured human dermal fibroblasts treated with immune interferon express HLA-DR antigens. We report here that DR-positive fibroblasts present tetanus toxoid (TT) to autologous TT-specific monoclonal helper T cells vigorously depleted of monocytes by passage over Sephadex G10 columns followed by treatment with the monoclonal antibodies (mAb) OKM1 and Leu M1 plus complement. The extent of T cell proliferation in response to TT presented by DR-positive fibroblasts was similar to that elicited using monocytes as antigen-presenting cells. The proliferative response was TT dependent, antigen specific, depended upon DR expression by fibroblasts, appeared MHC restricted, and was completely blocked by mouse mAb to HLA-DR but not by mAb to HLA-A,B, or DQ. DR-positive fibroblasts pulsed with TT were similarly effective in antigen presentation. In summary, immune interferon-stimulated human dermal fibroblasts can substitute for classical antigen-presenting cells in antigen-specific proliferative responses. Since fibroblasts are a ubiquitous cell type in the body, they may play a significant role in the immunobiology of the host.

Regulation of immunoglobulin (Ig)E synthesis in the hyper-IgE syndrome.

The hyper-IgE (HIE) syndrome is characterized by high IgE serum levels, chronic dermatitis, and recurrent infections. The mechanisms responsible for hyperproduction of IgE in HIE patients are presently unknown. We investigated whether spontaneous in vitro IgE synthesis by PBMC from seven HIE patients was sensitive to signals (cell adhesion, T/B cell cognate interaction and lymphokines: IL-4, IL-6, and IFN-gamma) known to regulate IgE induction in normals. Our results show that, unlike IL-4 dependent IgE synthesis induced in normals, spontaneous IgE production by PBMC from HIE patients was not blocked by monoclonal antibodies to CD2, CD4, CD3, and MHC class II antigens. Furthermore, antibodies to IL-4 and IL-6 did not significantly suppress IgE production. IFN-gamma had no significant effects on spontaneous in vitro IgE synthesis. To test whether an imbalance in lymphokine production might underlie hyperproduction of IgE in HIE patients, mitogen-induced secretion of IL-4 and IFN-gamma by PBMC was assessed. No significant difference was detected between HIE patients and normal controls. Thus, ongoing IgE synthesis in the HIE syndrome is largely independent of cell-cell interactions and endogenous lymphokines, and is due to a terminally differentiated B cell population, no longer sensitive to regulatory signals.

Role of protein tyrosine kinases and phosphatases in isotype switching: crosslinking CD45 to CD40 inhibits IgE isotype switching in human B cells.

Protein tyrosine kinases and protein tyrosine phosphatases play an important role in the transduction of signals via antigen receptors in T and B cells, and in CD40-dependent B-cell activation. To examine the role of tyrosine kinases and phosphatases in B-cell isotype switching, we examined the effects of the engagement of the transmembrane phosphatase CD45 on the synthesis of IgE induced by IL-4 and anti-CD40 monoclonal antibody (mAb). Crosslinking CD45 to CD40 using biotinylated mAbs and avidin strongly inhibited CD40-mediated IgE synthesis in IL-4-treated human B cells. CD40/CD45 crosslinking did not affect epsilon germline transcription in B cells stimulated with IL-4, but strongly inhibited induction of S mu/S epsilon switch recombination as detected by a nested primer polymerase chain reaction assay. The B-cell src-type tyrosine kinase lyn, which is activated following CD40 engagement, is a potential target for the effects of CD45 observed in our experiments, because CD45/CD40 crosslinking resulted in the inhibition of CD40-mediated lyn phosphorylation and activation. These results suggest an important role for protein tyrosine kinases and phosphatases in CD40-mediated induction of isotype switching to IgE.

Regulation of human IgE synthesis.

Allergic diseases result from the interaction with IgE bound to cell surface receptors. Therefore, rational therapeutic approaches to allergic diseases would be aimed at decreasing IgE and/or at blocking the binding of IgE to effector cells such as mast cells and monocytes. Our investigation of the mechanism of IgE synthesis in man shows that IgE synthesis by peripheral blood mononuclear cells (PBMC) absolutely requires the presence of IL-4 and requires endogenous IL-6, because antibody to IL-6 inhibits IgE production completely. IgE synthesis requires T/B cell contact and involves interactions between B cell surface MHC Class II molecules and T cell surface receptors, as antibodies to both of these cell surface molecules inhibit IgE synthesis. Furthermore, alloreactive T cell clones which are unable to engage the B cell MHC Class II molecules fail to induce IgE synthesis in spite of their ability to secrete IL-4. Studies on the immunoglobulin sites that are involved in IgE binding to high affinity receptors on mast cells and basophils have used recombinant fragments of IgE to block mast cell binding. These studies suggest that a stretch of 76 amino acids which straddles the C epsilon 2 and C epsilon 3 domains is essential for this binding. Parallel studies on IgE binding to low affinity receptors on monocytes and B cells suggest that sequences within C epsilon 3 are involved in this binding. Peptides or analogues that inhibit IgE binding to its cellular receptors may be useful in the treatment of allergic diseases.

Engagement of CD14 on monocytes inhibits the synthesis of human Igs, including IgE.

Engagement of CD14 on normal human monocytes results in monocyte activation and, furthermore, delivers a negative signal that terminates T cell proliferation. We show herein that engagement of selected CD14 epitopes by specific mAbs inhibited PWM-induced IgM and IgG synthesis, as well as IL-4-dependent IgE synthesis by human PBMCs. Inhibition by anti-CD14 mAb was still evident when the Ab was added after 6 days of culture, suggesting that inhibition targets a late B cell activation event. In experiments that focused on the role of CD14 in IgE regulation, suppression of IgE synthesis after CD14 engagement did not result from the release of inhibitory monokines (IL-10, TGF-beta, and PG). In fact, neutralizing Abs and specific inhibitors did not restore the IgE response and anti-CD14-conditioned monocyte supernatants did not inhibit IgE synthesis. On the other hand, inhibition of IgE synthesis by anti-CD14 mAb was not likely to be caused by the lack of soluble factors with amplificatory effects on the IgE response, because addition of either rIL-6 or rTNF-alpha did not overcome CD14-dependent inhibition of IgE production. IgE inhibition after CD14 engagement was exerted at the B cell level, inasmuch as it was observed not only in T cell-dependent IgE induction i.e., mononuclear cells stimulated with IL-4, but also in T cell-independent systems, i.e., T cell-depleted populations stimulated with IL-4 plus anti-CD40 mAb or IL-4 plus hydrocortisone. These data indicate that CD14 plays a regulatory role in B cell responses.

The superantigen toxic shock syndrome toxin-1 induces CD40 ligand expression and modulates IgE isotype switching.

Isotype switching to IgE requires two signals. The first signal is provided by the cytokines IL-4 or IL-13, and the second signal is delivered by the interaction between the B cell antigen CD40 and its ligand (CD40L) which is expressed on activated T cells. Since superantigens have been shown to activate T cells, we examined the effect of the superantigen toxic shock syndrome toxin-1 (TSST-1) on CD40L expression on T cells. TSST-1 induced expression of CD40L in both freshly isolated T cells and in T cell lines expanded by re-stimulation with TSST-1. CD40L was preferentially expressed in the V beta 2 subset of T cells expanded by TSST-1. We next examined the effect of TSST-1 on IgE synthesis by human peripheral blood mononuclear cells (PBMC). Addition of TSST-1 to PBMC inhibited IL-4-induced IgE synthesis in a dose-dependent manner. This inhibition was reversed partly by adding a neutralizing antibody to IFN-gamma. In contrast, TSST-1 induced high amounts of IgE synthesis in the presence of IL-4 at low T:B cell ratios (0.5:10 to 4:10), a condition which circumvents the inhibitory effect of IFN-gamma. TSST-1 induction of IgE synthesis was inhibited by a mAb to CD40L. These results indicate that superantigens induce CD40L expression in T cells and cause isotype switching in B cells which is mediated by CD40L-CD40 interaction.

Mechanisms of inhibition of IgE synthesis by nedocromil sodium: nedocromil sodium inhibits deletional switch recombination in human B cells.

IgE synthesis requires IL-4 and a T cell-B cell interaction that involves the B-cell antigen CD40 and its ligand expressed on activated T cells. Nedocromil sodium (NS), an effective prophylactic agent in asthma, inhibits IgE synthesis by human B cells. In this report we examined the mechanisms of this inhibition. NS targeted the B cells because it inhibited IgE synthesis induced by anti-CD40 and IL-4 in highly purified B cells (greater than 98% CD19+). NS had no effect on the induction of epsilon-germline transcripts by IL-4 but strongly inhibited CD40-mediated S mu --> S epsilon deletional switch recombination. The effect of NS was not specific for CD40 because it inhibited IgE synthesis in B cells stimulated with hydrocortisone plus IL-4. Moreover, the effect of NS was not specific for IgE because it inhibited CD40/IL-4-driven IgG4 synthesis by B cells sorted for lack of surface expression of IgG4. NS caused only modest inhibition of spontaneous IgE synthesis by B cells from patients with hyper-IgE syndrome, suggesting that it has little effect on B cells that have already undergone isotype switching. These results strongly suggest that NS inhibits IgE isotype switching by inhibiting deletional switch recombination and that NS has a novel potential mechanism for the prevention of asthma and other allergic diseases.

Endogenous interleukin 6 plays an obligatory role in interleukin 4-dependent human IgE synthesis.

The lymphokine interleukin (IL) 4 plays a crucial role in the regulation of IgE synthesis. In the present study, the cellular and cytokine requirements for the IL4-dependent induction of IgE synthesis in humans were analyzed. Recombinant IL4 could induce IgE synthesis by peripheral blood mononuclear cells and autologous T/B cell mixtures, but not by highly purified B cells. IgE induction by IL4 was strongly decreased in monocyte-depleted peripheral blood mononuclear cells. These results show that the induction of IgE synthesis by recombinant IL4 is T cell dependent and optimal in the presence of monocytes. IL5 and IL6, but not IL2, IL1 and tumor necrosis factor-alpha, strongly up-regulated the IL4-dependent synthesis of IgE, with modest effects on cell proliferation. An anti-IL6 polyclonal antibody strongly inhibited IL4-driven IgE production. Endogenous IL6 plays, therefore, an obligatory role in the IL4-dependent induction of IgE. However, a combination of IL4, IL5 and IL6 (with or without IL1) at optimal concentrations could not induce IgE synthesis by purified normal B cells, indicating that cytokine-mediated signals, although essential, are not sufficient for the IL4-dependent induction of IgE synthesis.

Sequential switching from mu to epsilon via gamma 4 in human B cells stimulated with IL-4 and hydrocortisone.

The molecular events leading to IgE synthesis in human B cells stimulated with IL-4 and hydrocortisone were analyzed. IL-4, but not hydrocortisone, induced C epsilon germ line transcription. However, hydrocortisone increased the levels of IL-4-induced germ line C epsilon transcripts by twofold and delivered the signal required for transcription of mature C epsilon mRNA. Nested primer polymerase chain reaction of high m.w. DNA revealed deletional switch recombination occurring in B cells sorted for lack of expression of surface IgE and stimulated with both IL-4 and hydrocortisone, but not in B cells stimulated with IL-4 alone or hydrocortisone alone. DNA sequence analysis of 10 switch fragments revealed direct joining of S mu to S epsilon in eight fragments, one of which exhibited an 876-bp deletion in S mu. The ninth fragment contained a 50-bp insertion at the S mu/S epsilon junction, which was likely to be derived from S gamma 4. The sequence of the 10th fragment was consistent with either a 17-bp insertion at the S mu/S epsilon junction derived from S gamma 4 or with a complex 38-bp deletion within S epsilon. Mapping of the switch junction sites showed "hot spots" for recombination within S mu but not within S epsilon. These findings indicate that hydrocortisone induces S mu-S epsilon deletional switch recombination in IL-4-treated B cells, and support a model of sequential isotype switching from IgM to IgE via IgG4.

HLA-DR-4-associated alloreactivity of an HLA-DR-3-restricted human tetanus toxoid-specific T cell clone: inhibition of both reactivities by an alloantiserum.

We present here the first report of a human helper/inducer T cell clone (F6) that specifically recognizes tetanus toxoid (TT) in the context of self-major histocompatibility complex (MHC) determinant(s) (HLA-DR3), and in addition recognizes a specific but unrelated MHC determinant(s) in the absence of conventional antigen. Extensive subcloning insured that the cells were progeny of a single cell. Furthermore, removal of the cells proliferating to the alloantigen with bromodeoxyuridine and light removed cells responding to both TT plus self-MHC and to the stimulating alloantigen, again indicating that F6 was the progeny of a single cell. The alloantigen recognized by this TT-specific clone appears to be closely linked to HLA-DR4 since cells from 13 of 14 HLA-DR4+ donors stimulated F6. An antiserum which recognizes HLA-DR4, when added to cultures, blocked the alloreactivity of F6, and in addition blocked its proliferation to TT plus HLA-DR3. Absorption of this antiserum with HLA-DR4+ cells or with TT-pulsed HLA-DR3+ cells removed its capacity to inhibit the proliferation of F6. These results suggest that the antigen recognition unit on F6 is stimulated both by allodeterminants expressed on HLA-DR4 cells and by TT plus HLA-DR3. These moieties cross-react at the T cell recognition level as well as at the antibody level.

Antigen presentation by human dermal fibroblasts: activation of resting T lymphocytes.

We have shown that human dermal fibroblasts, exposed to interferon-gamma (IFN-gamma) to induce surface class II major histocompatibility complex (MHC) antigens, were capable of presenting tetanus toxoid (TT) antigen to human TT-specific T cell clones. Antigen presentation by fibroblasts was antigen dependent, required HLA-DR expression by fibroblasts, and was MHC restricted. In contrast, we now report that IFN-gamma-treated fibroblasts are unable to present TT antigen to purified resting T cells obtained from the peripheral blood of TT-immune donors. In addition, although IFN-gamma-treated fibroblasts were able to stimulate alloreactive T cell clones, they were unable by themselves to stimulate primary allogeneic responses in resting T cells. The failure of fibroblasts to stimulate resting T cells was not due to suppressor effects by fibroblasts, because induction of TT and alloantigen responses in resting T cells by monocytes was not inhibited by the presence of fibroblasts. On the contrary, IFN-treated fibroblasts were synergistic with small numbers of monocytes in activating resting T cells. In addition, the failure of antigen presentation by fibroblasts to resting T cells was reversed by the addition of recombinant human interleukin 2 (rIL 2) to cultures, but not of purified human interleukin 1 (IL 1). These results emphasize that the requirements for activation of resting T cells differ from those of T cell clones. Although fibroblasts can efficiently present antigen to T cell clones, antigen presentation by fibroblasts to resting T cells requires the addition of exogenous IL 2. It is postulated that fibroblasts differ from classical antigen-presenting cells in that fibroblasts are incapable of stimulating the production of IL 2 in resting T cells.

IL-4 inhibits the synthesis of IFN-gamma and induces the synthesis of IgE in human mixed lymphocyte cultures.

The T cell-derived lymphokine IL-4 is essential for the induction of IgE synthesis by human lymphocytes. The IgE-inducing effect of IL-4 is antagonized by IFN-gamma. The secretion of IFN-gamma is vigorously triggered in MLC. Thus, IL-4-stimulated MLC represent a suitable model to characterize the functional antagonism between IL-4 and IFN-gamma. In this report, we show that rIL-4 consistently induced IgE synthesis when added to human primary MLC. IL-4-dependent IgE production required cognate T/B cell recognition, because it was inhibited by antibodies to CD3 and MHC class II (HlA-DR) Ag. A neutralizing anti-IFN-gamma mAb dramatically enhanced IL-4-dependent IgE synthesis by MLC, indicating that endogenous IFN-gamma is a major inhibitor of IgE production. More importantly, addition of rIL-4 markedly inhibited the release of IFN-gamma in supernatants of MLC and Con A-activated PBMC. The decrease in IFN-gamma protein was accompanied by a decreased expression of IFN-gamma mRNA transcripts. The downregulation of IFN-gamma by IL-4 is likely to play an important role in the IL-4-dependent induction of IgE synthesis.

Interleukin 4 dependent induction of IgE synthesis and CD23 expression by the supernatants of a human helper T cell clone.

The supernatants of the human alloreactive helper T cell clone A1, which secretes interleukins (IL) 4 and 5, could induce IgE synthesis by normal peripheral blood mononuclear cell and expression of Fc epsilon R2/CD23 on normal human monocytes. Both effects were IL-4 dependent, since they could be induced by recombinant IL-4 alone and were inhibited by an anti-IL-4 antibody. The activation of such clones may contribute to the high IgE production and the high percentage of circulating CD23+ monocytes observed in allergic disorders.