Murine follicular dendritic cells and low affinity Fc receptors for IgE (Fc epsilon RII).

The present study was undertaken to determine whether mouse follicular dendritic cells (FDC) bear Fc epsilon RII (CD23) and whether IgE-immune complexes are retained by FDC. Mouse Fc epsilon RII was localized by both L and electron microscopy using the mAb B3B4. In lymph nodes of normal mice, Fc epsilon RII was low but detectable on FDC. By 14 days after Nippostrongylus brasiliensis infection, the level of Fc epsilon RII increased on B lymphocytes located in the cortex of draining mesenteric lymph nodes. However, the Fc epsilon RII level on FDC remained low. Although numerous IgE-producing plasma cells were seen at day 14, very little IgE was associated with FDC. By 26 days after infection, Fc epsilon RII was observed on FDC in increased levels and IgE binding was clearly associated with FDC. Unexpectedly, FDC of control mice immunized with albumin in CFA to elicit an IgG response showed intense labeling for Fc epsilon RII. In contrast, the B cells exhibited very little Fc epsilon RII. IgE immune complexes were observed in association with FDC in the CFA-immunized mice. When mice were given a hapten-specific monoclonal of the IgE isotype, hapten carrier complexes were trapped and retained on Fc epsilon RII-bearing FDC. In conclusion, FDC were clearly one of the major murine cell types bearing Fc epsilon RII. IgE immune complexes were found in association with FDC and Fc epsilon RII appeared to play a major role in trapping and retaining IgE immune complexes. FDC Fc epsilon RII was subject to regulatory control, but the Fc epsilon RII level on FDC was regulated very differently from the Fc epsilon RII level on B cells.     

Recombinant soluble Fc epsilon receptor II (Fc epsilon RII/CD23) has IgE binding activity but no B cell growth promoting activity

We have undertaken the production of recombinant soluble Fc epsilon receptor II (Fc epsilon RII) as a secretory protein, but not as a cleavage product of membrane-bound receptor. Several plasmid constructs containing soluble receptor sequence were prepared. Only a chimeric gene containing the sequences encoding IL-6 signal peptide and the soluble moiety of Fc epsilon RII could be expressed in Xenopus laevis oocytes and CHO cells, resulting in the secretion of soluble Fc epsilon RII. The recombinant soluble Fc epsilon RII was also produced in the yeast expression system. The NH2-terminal sequence analysis of the chimeric gene product generated by oocytes demonstrated the correct cleavage of IL-6 leader sequence by a signal peptidase. Moreover, most of CHO cell and all of the yeast-derived recombinant molecules were products identical with the native B cell-derived soluble Fc epsilon RII. These recombinant products as well as the natural soluble receptor derived from a human B cell line could bind both human IgE and two different anti-Fc epsilon RII mAb and could competitively inhibit the binding of IgE to Fc epsilon RII-expressing cells. However, the recombinant soluble Fc epsilon RII and highly purified native molecules did not display any B cell growth-promoting activity.     

Characterization of the murine T cell receptor for IgE (Fc epsilon RII). Demonstration of shared and unshared epitopes with the B cell Fc epsilon RII

Antigenic relationships between the low affinity Fc epsilon R present on murine B and T lymphocytes were studied. A rat mAb (B3B4) and two polyclonal antisera produced by immunizing with the murine B lymphocyte Fc epsilon RII were examined for their ability to inhibit binding of IgE to murine B or T lymphocytes, using an IgE-specific rosette assay. One polyclonal antiserum (goat-anti-mouse Fc epsilon R) inhibited binding of IgE to both B and T lymphocytes, whereas another polyclonal antiserum (rabbit-anti-mouse Fc epsilon R) and the rat mAb inhibited the binding of IgE to B lymphocytes but did not influence the binding of IgE to T lymphocytes. When lymphocytes were surface labeled with 125I, 49-kDa and 38-kDa IgE-binding proteins were immunoprecipitated from B lymphocyte lysates by B3B4 and from B and T lymphocyte lysates by the goat antiserum. Taken together, these results suggest that the Fc epsilon R present on murine B and T lymphocytes are structurally related receptors that share some, but not all, epitopes.     

Isolation, characterization, and expression of cDNA clones encoding the mouse Fc receptor for IgE (Fc epsilon RII)1

We have isolated cDNA clones encoding a mouse low affinity receptor for IgE (Fc epsilon RII) from a cDNA library of BALB/c splenic B cells activated with LPS and IL-4. The 2.2-kb cDNA clone encodes a 331 amino acid membrane glycoprotein that is homologous to human Fc epsilon RII (CD23) and a family of carbohydrate-binding proteins. COS7 cells transfected with the cDNA clones expressed a 45,000 m.w. protein that bound IgE and the anti-Fc epsilon RII mAb, B3B4. Fc epsilon RII mRNA was up-regulated in mouse B cells by culture with IL-4, but not in B cells cultured with IgE. Fc epsilon RII mRNA was detected in IgM+/IgD+ B cell lines, but not in pre-B cell lines or in B cell lines which have undergone differentiation to secrete Ig. The monocyte line P388D1, mast cell lines MC/9 and PT18, and peritoneal macrophages stimulated with IL-4 lacked detectable Fc epsilon RII mRNA, as did Thy-1.2+, CD4+, and CD8+ normal T cells and Thy-1.2+ T cells from Nippostrongylus brasiliensis-infected mice.     

Superinduction of the murine B cell Fc epsilon RII by T helper cell clones. Role of IL-4

Th cell clones are known to induce an IL-4 dependent polyclonal IgE synthesis. Because IL-4 can induce the expression of the low affinity FcR for IgE (Fc epsilon RII) the ability of Th cell clones to induce Fc epsilon RII on purified splenic B cells was analyzed. It was found that a TH2 clone could cause a 50- to 100-fold superinduction of Fc epsilon RII after 2 days in culture; after 3 days, the Fc epsilon RII levels had almost returned to base line. The superinduction was inhibited by an anti-IL-4 antibody, 11B11, indicating its dependence on IL-4. A TH1 clone could cause a modest (four fold) induction of Fc epsilon RII, and this induction was not influenced by 11B11. A similar Fc epsilon RII induction was seen when using the supernatant from activated TH1 cells. The component(s) causing this relatively low level Fc epsilon RII induction is not known; a variety of known lymphokines were tested, and only IL-4 demonstrated any capacity for Fc epsilon RII induction on LPS-activated B cells. Addition of rIL-4 at concentrations of 400 U/ml or greater to the TH1 culture was sufficient to cause a Fc epsilon RII superinduction similar to that seen with the TH2 clone, while 40 U/ml was not. In order to determine a potential role for the Fc epsilon RII or its soluble fragment on the IgE synthesis mediated by TH2, a monoclonal anti-Fc epsilon RII, B3B4, was added to the culture. The addition of B3B4 did not have an influence on IgE levels in this system.     

Lack of Fc epsilon RII expression by murine B cells after in vivo immunization is directly associated with Ig secretion and not Ig isotype switching.

The "low affinity" Fc receptor for IgE (Fc epsilon RII) has been reported to be absent from normal murine and human B cells that express a membrane (m)Ig isotype other than mIgM or mIgD in vivo. This would suggest that Fc epsilon RII expression is specifically lost after in vivo Ig isotype switching. We demonstrate that during a murine immune response to the bacterium Brucella abortus, to goat anti-mouse IgD (G alpha M delta) antibody, or to infection with the nematode parasites Nippostrongylus brasilienis or Heligmosomoides polygyrus, Fc epsilon RII expression is low or absent on virtually all B cells secreting IgM, IgG1, IgG2a, and IgE. However, up to 50% of B cells that express mIgG1 after G alpha M delta injection continue to express Fc epsilon RII. These mIgG1 + Fc epsilon RII+ cells secrete little, if any, IgG1 when placed in vitro, in contrast to their mIgG1 + Fc epsilon RII- counterparts. The mIgG1 + Fc epsilon RII+ cells may be a transitional cell population, because they undergo substantial loss of Fc epsilon RII in culture, unlike mIgM+ Fc epsilon RII+ cells, which maintain constant levels of Fc epsilon RII throughout a comparable culture period. Thus, low or absent expression of Fc epsilon RII after immunization in vivo is directly associated with B cell differentiation to Ig production in the presence or absence of Ig isotype switching. However, all post-switched B cells may eventually lack Fc epsilon RII expression, independently of their differentiative state.     

Induction of Fc epsilon RII/CD23 on phytohemagglutinin-activated human peripheral blood T lymphocytes. I. Enhancement by IL-2 and IL-4.

Despite evidence for the expression of low affinity Fc receptor for IgE (Fc epsilon RII)/CD23 in T cell lines and pathologic T cells, Fc epsilon RII/CD23 in normal human T cells is still unclear. We studied the expression of Fc epsilon RII/CD23 on T cells in short-term culture of normal human PBMC stimulated with 15 micrograms/ml PHA. PHA stimulation also resulted in the release of soluble Fc epsilon RII/CD23 (IgE binding factor). Using two-dimensional flow cytometry, more than 10% of the Fc epsilon RII/CD23+ cells were found to co-express CD3 Ag. Both CD4+ and CD8+ T cells expressed Fc epsilon RII/CD23. The induction of Fc epsilon RII/CD23 on PHA-activated T cells was enhanced by IL-2 as well as IL-4. Both IL-2 and IL-4 also augmented PHA-induced production of soluble Fc epsilon RII/CD23. The enhanced expression of Fc epsilon RII/CD23 on T cells by both lymphokines was suppressed by rabbit anti-IL-4 antiserum, suggesting the involvement of an IL-4-dependent process even in the IL-2-dependent Fc epsilon RII/CD23 expression on T cells. The expression of mRNA for Fc epsilon RII/CD23 on PHA and IL-4-stimulated PBMC was examined by Northern blot analysis. Fc epsilon RII/CD23 mRNA was detected in RNA prepared from the T cell fraction depleted of B cells and macrophages (Fc epsilon RII+CD3+ = 6.2%, Fc epsilon RII+CD3- = 0.8%). The expression of the mRNA for Fc epsilon RII/CD23 on CD3+ T cells was also confirmed by in situ hybridization with Fc epsilon RII/CD23 cDNA combined with CD3 rosette formation at the single cell level.     

Human Fc epsilon RIalpha-specific human single-chain Fv (scFv) antibody with antagonistic activity toward IgE/Fc epsilon RIalpha-binding

The alpha-chain of Fc epsilon RI (Fc epsilon RIalpha) plays a critical role in the binding of IgE to Fc epsilon RI. A fully human antibody interfering with this interaction may be useful for the prevention of IgE-mediated allergic diseases. Here, we describe the successful isolation of a human single-chain Fv antibody specific to human Fc epsilon RIalpha using human antibody phage display libraries. Using the non-immune phage antibody libraries constructed from peripheral blood lymphocyte cDNA from 20 healthy subjects, we isolated three phage clones (designated as FcR epsilon 27, FcR epsilon 51, and FcR epsilon 70) through two rounds of biopanning selection. The purified soluble scFv, FcR epsilon 51, inhibited the binding of IgE to recombinant Fc epsilon RIalpha, although both FcR epsilon 27 and FcR epsilon 70 showed fine binding specificity to Fc epsilon RIalpha. Since FcR epsilon 51 was determined to be a monomer by HPLC, BIAcore analysis was performed. The dissociation constant of FcR epsilon 51 to Fc epsilon RIalpha was estimated to be 20 nM, i.e., fortyfold lower than that of IgE binding to Fc epsilon RIalpha (K(d) = 0.5 nM). With these characteristics, FcR epsilon 51 exhibited inhibitory activity on the release of histamine from passively sensitized human peripheral blood mononuclear cells.     

Monoclonal anti-Fc epsilon receptor antibodies with different specificities and studies on the expression of Fc epsilon receptors on human B and T cells

Three monoclonal antibodies, 1-7 (gamma 2b), 3-5 (gamma 1), and 8-30 (mu), specific to Fc epsilon receptors (Fc epsilon R) on human B cells were established. The two monoclonals (1-7 and 8-30) could inhibit the binding of IgE to Fc epsilon R in rosette formation assays, as well as FACS analysis, and were shown to recognize the same epitope of Fc epsilon R. The other monoclonal antibody (3-5) recognized the same molecule but a different epitope, and marginally inhibited the IgE binding. The molecules on RPMI 8866 cells recognized by these monoclonal antibodies had Mr of 46,000 and 25,000 to 30,000 daltons as determined by immunoprecipitation and SDS-PAGE analysis. By employing these monoclonal antibodies, the expression of Fc epsilon R on circulating lymphocytes was studied. Approximately 50% of B cells from normal, nonatopic individuals were found to express Fc epsilon R, and a remarkable increase in the expression of Fc epsilon R was observed in B cells of atopic patients. The expression of Fc epsilon R was not detected in T cells from atopic patients (including hyper IgE syndrome) as well as normal individuals. Incubation of B cells with PHA-conditioned medium plus IgE augmented the expression of Fc epsilon R in the Fc epsilon R+ B cell population but not in Fc epsilon R- population. PHA-conditioned medium plus IgE did not induce Fc epsilon R expression on T cells.     

Characterization of B-cell populations bearing Fc epsilon receptor II

We have characterized the B-cell population that expresses low affinity Fc receptors for IgE (Fc epsilon RII). Fc epsilon RII+ B cells from normal adult BALB/c mice expressed high levels of surface IgD and low/medium levels of surface IgM and constituted the majority of mature splenic B cells. Fc epsilon RII+ splenic B cells expressed high levels of class II MHC antigens and medium to high levels of B220, and consisted of approximately equal numbers of J11dhigh and J11dlow cells. CD5+ B cells did not appear to be Fc epsilon RII+, and interleukin 4 did not induce Fc epsilon RII expression on CD5+ B cells. Fc epsilon RII was not expressed by B cells that had differentiated to secrete immunoglobulin but was expressed on activated B cells. These data suggest that Fc epsilon RII is a differentiation marker expressed on mature and activated B lymphocytes in the major B-cell lineage.     

The binding of IgE to murine Fc epsilon RII is calcium-dependent but not inhibited by carbohydrate

Despite extensive study, little is known about the functions of the moderate affinity IgE receptors (Fc epsilon RII) on B cells. Recent cDNA and genomic cloning studies have demonstrated that, in contrast to other FcR, Fc epsilon RII is not a member of the Ig gene superfamily. Moreover, it uniquely expresses a region that is highly homologous with a membrane-associated, calcium-dependent binding lectin, the asialoglycoprotein receptor. We now report that the interaction between IgE and the Fc epsilon RII of murine B cells and macrophages requires calcium. Furthermore, as might be expected of asialoglycoprotein lectins, this binding was pH-dependent and resulted in ligand internalization. However, although 125I-Fc epsilon RII bound in a calcium-dependent manner to monosaccharide-agarose beads, high concentrations of mono- and disaccharides did not inhibit the interaction between either 125I-IgE and intact B cells or 125I-Fc epsilon RII (from surface-labeled B cells) and IgE-Sepharose. These results suggest that although murine Fc epsilon RII is a lectin, it is not strictly dependent upon IgE oligosaccharides for its binding to IgE.     

Monoclonal antibody (H107) inhibiting IgE binding to Fc epsilon R(+) human lymphocytes

A hybridoma-producing monoclonal antibody blocking the binding of human IgE to lymphocytes Fc receptor (Fc epsilon R) was established by the fusion of murine myeloma cells. P3X63.653.Ag8, with BALB/c spleen cells immunized with Fc epsilon R(+) human B lymphoblastoid cell line cells, RPMI1788. A clone of the hybridoma (H107) produced a monoclonal IgG2b antibody that inhibited the rosette formation of Fc epsilon R(+) human B lymphoblastoid cell line cells (RPMI1788, RPMI8866, CESS, Dakiki, and IM9) with fixed ox red blood cells (ORBC) conjugated with human IgE (IgE-ORBC). In contrast, the rosette formation with IgG-conjugated ORBC (IgG-ORBC) on Fc gamma R(+), Fc epsilon R(-) Daudi cells were not affected by the H107 antibodies. A close association of Fc epsilon R and the antigenic determinant recognized by H107 antibody was suggested by the following results. First, the bindings of 125I-labeled IgE (125I-IgE) or 125I-labeled H107 IgG2b antibody (125I-H107) to RPMI8866 cells were inhibited by cold human IgE and H107 IgG2b but not by other classes of human Ig (IgA and IgG), MPC11 IgG2b, or unrelated monoclonal antibodies. Second, H107 antibody reacted with Fc epsilon R(+) B cell lines but not with Fc epsilon R(-) B cell lines as determined by an indirect immunofluorescence. Third, Fc epsilon R(+) cells were depleted by the incubation in the dish coated with H107 antibody or IgE but not in the dish coated with unrelated antibodies. Finally, there was a correlation between the increase of Fc epsilon R(+) cells and that of H107(+) cells in the peripheral blood lymphocytes of the patients with atopic dermatitis. The surface antigens on Fc epsilon R(+) RPMI8866 cells recognized by H107 antibodies had the molecular size of 45,000 as determined by immunoprecipitation and sodium dodecyl sulfate-polyacrylamide gel electrophoresis analysis.     

Immunoglobulin E-binding site in Fc epsilon receptor (Fc epsilon RII/CD23) identified by homolog-scanning mutagenesis.

The IgE-binding site of the human low-affinity receptor for IgE (Fc epsilon RII/CD23) has previously been mapped to the extracellular domain between amino acid residues 160 and 287. We now have investigated which conformational epitope within this domain specifies the receptor-ligand interaction. The analysis of homolog-scanning mutants expressed in mammalian cells demonstrates that amino acid side chains that affect IgE binding are located in two discontinuous segments, between residues 165-190 and 224-256. The overall structure of the chimeric binding domains, as probed with 11 conformation-sensitive monoclonal antibodies, is generally not distorted, except by replacement of residues 165-183. In this region, disruption of binding function appears to be caused by global conformational constraints on the binding site. Substitution and deletion mutants demonstrate that six out of eight extracellular cysteines, Cys163, Cys174, Cys191, Cys259, Cys273, and Cys282, are necessary for IgE binding and are most likely involved in intramolecular disulfide bridges. We show that the Fc epsilon RII domain delineated by Cys163 and Cys282 encodes all the structural information required to form the IgE-binding site.     

A novel human immunoglobulin Fc gamma Fc epsilon bifunctional fusion protein inhibits Fc epsilon RI-mediated degranulation

Human mast cells and basophils that express the high-affinity immunoglobulin E (IgE) receptor, Fc epsilon receptor 1 (Fc epsilon RI), have key roles in allergic diseases. Fc epsilon RI cross-linking stimulates the release of allergic mediators. Mast cells and basophils co-express Fc gamma RIIb, a low affinity receptor containing an immunoreceptor tyrosine-based inhibitory motif and whose co-aggregation with Fc epsilon RI can block Fc epsilon RI-mediated reactivity. Here we designed, expressed and tested the human basophil and mast-cell inhibitory function of a novel chimeric fusion protein, whose structure is gamma Hinge-CH gamma 2-CH gamma 3-15aa linker-CH epsilon 2-CH epsilon 3-CH epsilon 4. This Fc gamma Fc epsilon fusion protein was expressed as the predicted 140-kappa D dimer that reacted with anti-human epsilon- and gamma-chain specific antibodies. Fc gamma Fc epsilon bound to both human Fc epsilon RI and Fc gamma RII. It also showed dose- and time-dependent inhibition of antigen-driven IgE-mediated histamine release from fresh human basophils sensitized with IgE directed against NIP (4-hydroxy-3-iodo-5-nitrophenylacetyl). This was associated with altered Syk signaling. The fusion protein also showed increased inhibition of human anti-NP (4-hydroxy-3-nitrophenylacetyl) and anti-dansyl IgE-mediated passive cutaneous anaphylaxis in transgenic mice expressing human Fc epsilon RI alpha. Our results show that this chimeric protein is able to form complexes with both Fc epsilon RI and Fc gamma RII, and inhibit mast-cell and basophil function. This approach, using a Fc gamma Fc epsilon fusion protein to co-aggregate Fc epsilon RI with a receptor containing an immunoreceptor tyrosine-based inhibition motif, has therapeutic potential in IgE- and Fc epsilon RI-mediated diseases.     

Human neutrophils express the high-affinity receptor for immunoglobulin E (Fc epsilon RI): role in asthma.

Polymorphonuclear neutrophils (PMNs) are important effector cells in host defense and the inflammatory response to antigen. The involvement of PMNs in inflammation is mediated mainly by the Fc receptor family, including IgE receptors. Recently, PMNs were shown to express two IgE receptors (CD23/Fc epsilon RII and galectin-3). In allergic diseases, the dominant role of IgE has been mainly ascribed to its high-affinity receptor, Fc epsilon RI. We have examined the expression of Fc epsilon RI by PMNS: mRNA and cell surface expression of Fc epsilon RI alpha chain was identified on PMNs from asthmatic subjects. Furthermore, preincubation with human IgE Fc fragment blocks completely the binding of anti-Fc epsilon RI alpha chain (mAb15--1) to human PMNS: Conversely, preincubation of PMNs with mAb15--1 inhibits significantly the binding of IgE Fc fragment to PMNs, indicating that IgE bound to the cell surface of PMNs mainly via the Fc epsilon RI. Peripheral blood and bronchoalveolar lavage (BAL) PMNs from asthmatic subjects also express intracellular Fc epsilon RI alpha and beta chain immunoreactivity. Engagement of Fc epsilon RI induces the release of IL-8 by PMNS: Collectively, these observations provide new evidence that PMNs express the Fc epsilon RI and suggest that these cells may play a role in allergic inflammation through an IgE-dependent activation mechanism.     

IL-6 augments Fc IgE receptor (Fc epsilon RII/CD23) expression on human monoblastic/monocytic cell lines U937, THP-1, and Mono-Mac-6 but not on blood monocytes. Regulatory effects of IL-4 and IFN-gamma.

Human monoblastic/monocytic leukemia cell lines U937, THP-1, Mono-Mac-6, and blood monocytes were incubated with various concentrations of human rIL-6 and other cytokines and analyzed for their capacity to bind several anti-Fc epsilon RII/CD23 mAb. A marked and dose-dependent increase in the percentage of CD23+ cells, as well as in the mean channel fluorescence intensity, as demonstrated by FACS analysis, was noted after 8- to 72-h incubation of U937 cells with 1 to 1000 U/ml of human rIL-6. Furthermore, rIL-4 synergized with rIL-6 and rIFN-tau in augmenting the Fc epsilon RII expression on U937 cells, whereas rIFN-tau and rIL-6 showed rather additive effects. The enhancement of CD23 expression on IL-6-treated U937 cells was blocked by anti-IL-6 antibodies. Northern blot analysis, employing cDNA probes for Fc epsilon RII, showed that U937 cells contain Fc epsilon RII-specific mRNA. The level of Fc epsilon RII-encoding mRNA was evidently increased by treatment of U937 cells with human rIL-6, rIL-4, or with rIL-6 + rIL-4. The expression of CD23 on THP-1 and Mono-Mac-6 cells was increased slightly by rIL-6 and markedly by rIL-4, rIFN-tau, or a mixture of them. Approximately 14% of blood monocytes, isolated from apparently healthy donors, constitutively possess Fc epsilon RII. In contrast to the cell lines, the Fc epsilon RII density and the percentage of blood monocytes bearing Fc epsilon RII was not augmented by IL-6. Furthermore, rIL-6, and more evidently rIFN-tau, down-regulate rIL-4-driven Fc epsilon RII expression on monocytes but not on monocytic cell lines. Our findings point to differences in the capability of mononuclear phagocytes to respond to cytokine treatment, which may be differentiation dependent, and suggest separate regulatory pathways.     

A B cell-specific differentiation antigen, CD23, is a receptor for IgE (Fc epsilon R) on lymphocytes

Two independent L cell transformants expressing human lymphocyte Fc epsilon R were established by using cellular DNA from RPMI 8866 cells. The surface expression of the receptor was confirmed on the basis of the binding of a panel of anti-Fc epsilon R antibodies and its ability to bind IgE. Anti-CD23 antibodies strongly stained the transformants, indicating possible identity or antigenic relationship between Fc epsilon R and CD23. This interesting observation warrants additional clarification as to the role of CD23 and Fc epsilon R in B cell differentiation.     

Leukotriene B4 potentiates the expression and release of Fc epsilon RII/CD23, and proliferation and differentiation of human B lymphocytes induced by IL-4

This study documents the influence of leukotriene (LT) B4 on human B lymphocyte responses. Incubation of freshly isolated B lymphocytes with LTB4, but not LTC4, induced a slight but significant, time- and dose-dependent increase in the surface expression of Fc epsilon RII/CD23 and class II MHC Ag and in the release of soluble CD23. These changes were maximal at 10 nM LTB4 after an incubation period of 48 h. When B lymphocytes were preactivated in vitro with Staphylococcus aureus Cowan strain I (SAC), neither LTB4 nor LTC4 was able to promote proliferation and/or IgG and IgM secretion. In contrast, when resting B lymphocytes were stimulated with a suboptimal concentration (3 U/ml) of IL-4, LTB4, but not LTC4, potentiated both the Fc epsilon RII/CD23 and the class II MHC antigen expression, and the release of soluble CD23 in a dose-dependent manner, without affecting the kinetics of these responses. Furthermore, LTB4, but not LTC4, amplified both the proliferative response and the IgG and IgM secretion induced by addition of a suboptimal dose of IL-4 (3 U/ml) to SAC-preactivated B lymphocytes. Again, LTB4 did not modify the kinetics of the proliferative response promoted by IL-4. Although LTB4 potentiated IL-4-induced IgG and IgM secretion from SAC-activated B lymphocytes, no production of IgE was observed. These data indicate that LTB4 could play a regulatory role in the modulation of IL-4-induced signaling in human B lymphocytes.