Inhibition of IgE binding to RBL-2H3 cells by a monoclonal antibody (BD6) to a surface protein other than the high affinity IgE receptor.

A mAb was isolated (mAb BD6) that recognized a surface glycoprotein on rat basophilic leukemia cells (RBL-2H3). The antibody bound to 2 x 10(6) molecules/cell and specifically blocked IgE binding (50% inhibition with 3.48 +/- 0.51 micrograms/ml; mean +/- SEM), although neither IgE nor anti-high affinity IgE receptor (anti-Fc epsilon RI) mAb blocked mAb BD6 binding to the cells. mAb BD6 did not affect the rate of dissociation of cell-bound IgE, nor did it induce or inhibit the internalization of IgE. mAb BD6 did not release histamine. However, it did cause rapid spreading of the cells. By 1 h the cells had retracted to a spherical shape with their surface covered with membranous spikes, and they could easily be detached from the tissue culture plate. These changes differed from those observed after Fc epsilon RI activation. mAb BD6 immunoprecipitated a complex of two proteins, 38 to 50 kDa and 135 kDa from 125I-surface labeled rat basophilic leukemia cells that are not subunits of Fc epsilon RI. Chemical cross-linking studies showed that these molecules are associated on the cell surface. By immunoblotting, mAb BD6 reacted with a 40-kDa protein. Therefore, mAb BD6 binds to a surface protein that is close to the Fc epsilon RI and sterically inhibits 125I-IgE binding.     

Binding of monoclonal antibody AA4 to gangliosides on rat basophilic leukemia cells produces changes similar to those seen with Fc epsilon receptor activation.

The mAb AA4 binds to novel derivatives of the ganglioside Gd1b on rat basophilic leukemia (RBL-2H3) cells. Some of the gangliosides are located close to the high affinity IgE receptor (Fc epsilon RI), and binding of mAb AA4 inhibits Fc epsilon RI-mediated histamine release. In the present study, mAb AA4 was found to bind exclusively to mast cells in all rat tissues examined. In vitro, within 1 min of mAb AA4 binding, the cells underwent striking morphologic changes. They lost their normal spindle shaped appearance, increased their ruffling, and spread over the surface of the culture dish. These changes were accompanied by a redistribution of the cytoskeletal elements, actin, tubulin, and vimentin, but only the actin was associated with the membrane ruffles. Binding of mAb AA4 also induces a rise in intracellular calcium, stimulates phosphatidyl inositol breakdown, and activates PKC. However, the extent of these changes was less than that observed when the cells were stimulated with antigen or antibody directed against the Fc epsilon RI. None of these changes associated with mAb AA4 binding were seen when the cells were exposed to nonspecific IgG, IgE, or four other anti-cell surface antibodies, nor were the changes induced by binding mAb AA4 at 4 degrees C or in the absence of extracellular calcium. Although mAb AA4 does not stimulate histamine release, it enhances the effect of the calcium ionophore A23187 mediated release. The morphological and biochemical effects produced by mAb AA4 are similar to those seen following activation of the cell through the IgE receptor. Therefore, the surface gangliosides which bind mAb AA4 may function in modulating secretory events.     

A monoclonal antibody that inhibits secretion from rat basophilic leukemia cells and binds to a novel membrane component

Rat basophilic leukemia (RBL-2H3) cells, like mast cells and basophils, carry monovalent membrane receptors with high affinity for IgE (Fc epsilon R). Cross-linking of these receptors provides the immunologic stimulus which initiates a series of biochemical events, culminating in secretion of inflammatory mediators. In an attempt to identify membrane components involved in the stimulus-secretion coupling of these cells, hybridomas were produced from splenocytes of mice immunized with intact RBL-2H3 cells. Here we report the production of a mAb (designated G63) that inhibits the Fc epsilon R-mediated secretion from RBL cells. At low degrees of Fc epsilon R aggregation, the mAb G63-induced inhibition may be complete, whereas at the maximum of secretion the inhibition is in the range of 30 to 40%. The relative degree of inhibition of secretion is dependent on the dose of mAb G63. Furthermore, inhibition requires the bivalency of G63, as the Fab fragments are inactive. The number of antigenic epitopes recognized by G63 per RBL-2H3 cell is 1.8 x 10(4) epitopes/cell, as determined by direct binding studies of 125I-labeled Fab fragments of G63. This number is 20 to 30 times smaller than that of Fc epsilon R on the same cells. The membrane component to which G63 binds has been identified by immunoprecipitation as a glycoprotein with an apparent Mr of 58 to 70 kDa. All of these results, and the fact that no competition for binding to RBL cells between mAb G63 and IgE can be resolved, indicate that mAb G63 binds to a membrane component which is distinct from the Fc epsilon R. mAb G63 suppresses the Fc epsilon R-mediated rise in cytoplasmic concentration of free Ca2+ ions, known to be one of the biochemical signals involved in the stimulus-secretion coupling in RBL-2H3 cells. G63 does not affect, however, the degranulation induced by the Ca2+ ionophore A23187. Therefore, mAb G63 probably exerts its inhibitory effect on a step preceding the rise in cytoplasmic free Ca2+. Thus, mAb G63 defines a previously unidentified membrane component that is involved in one of the early steps of the RBL-2H3 activation mediated by their Fc epsilon R.     

Monoclonal antibodies that inhibit IgE binding

Four monoclonal antibodies were produced that inhibit IgE binding to the high affinity IgE receptor (Fc epsilon R) on rat basophilic leukemia cells. The four monoclonal antibodies (mAb) fall into two groups. The first group was comprised of 3 antibodies (mAb BC4, mAb CD3, and mAb CA5) that reacted with the Fc epsilon R at epitopes close or identical to the IgE-binding site. With 125I-labeled antibodies there was reciprocal cross-inhibition between the antibodies and IgE. The antibodies activated both RBL-2H3 cells and normal rat mast cells for histamine release. The 3 antibodies immunoprecipitated the previously described alpha, beta, and gamma components of the receptor. The number of radiolabeled Fab fragments of 2 of these antibodies bound per cell was similar or equal to the number of IgE receptors. In contrast, the mAb BC4 Fab bound to 2.1 +/- 0.4 times the number of IgE receptor sites. Therefore, the portion of the Fc epsilon R exposed on the cell surface must have two identical epitopes and an axis of symmetry. These 3 monoclonal antibodies recognize different but closely related epitopes in the IgE-binding region of the Fc epsilon R. The fourth monoclonal antibody (mAb AA4) had different characteristics. In cross-inhibition studies, IgE and the other 3 monoclonals did not inhibit the binding of this 125I-labeled monoclonal antibody. The number of molecules of this antibody bound per cell was approximately 14-fold greater than the Fc epsilon R number. This monoclonal antibody caused the inhibition of histamine release and it appears to bind to several cell components.     

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.     

Kinetics of ligand binding to the type 1 Fc epsilon receptor on mast cells

Rates of association and dissociation of several specific monovalent ligands to and from the type I Fc epsilon receptor (Fc epsilon RI) were measured on live mucosal type mast cells of the rat line RBL-2H3. The ligands employed were a monoclonal murine IgE and Fab fragments prepared from three different, Fc epsilon RI-specific monoclonal IgG class antibodies. These monoclonals (designated H10, J17, and F4) were shown previously to trigger mediator secretion by RBL-2H3 mast cells upon binding to and dimerization of the Fc epsilon RI. Analysis of the kinetics shows that the minimal mechanism to which all data can be fitted involves two consecutive steps: namely, ligand binding to a low-affinity state of the receptor, followed by a conformational transition into a second, higher affinity state h of the receptor-ligand complex. These results resolve the recently noted discrepancy between the affinity of IgE binding to the Fc epsilon RI as determined by means of binding equilibrium measurements [Ortega et al. (1988) EMBO J. 7, 4101] and the respective parameter derived from the ratio of the rate constant of rat IgE dissociation and the initial rate of rat IgE association [Wank et al. (1983) Biochemistry 22, 954]. The probability of undergoing the conformational transition differs for the four different Fc epsilon RI-ligand complexes: while binding of Fab-H10 and IgE favors the h state, binding of Fab-J17 and Fab-F4 preferentially maintains the low-affinity 1 state (at 25 degrees C). The temperature dependence of the ligand interaction kinetics with the Fc epsilon RI shows that the activation barrier for ligand association is determined by positive enthalpic and entropic contributions. The activation barrier of the 1----h transition, however, has negative enthalpic contributions counteracted by a decrease in activation entropy. The h----1 transition encounters a barrier that is predominantly entropic and similar for all ligands employed, thus suggesting that the Fc epsilon RI undergoes a similar conformational transition upon binding any of the ligands.     

Interaction of p72syk with the gamma and beta subunits of the high-affinity receptor for immunoglobulin E, Fc epsilon RI.

Activation of protein tyrosine kinases is one of the initial events following aggregation of the high-affinity receptor for immunoglobulin E (Fc epsilon RI) on RBL-2H3 cells, a model mast cell line. The protein tyrosine kinase p72syk (Syk), which contains two Src homology 2 (SH2) domains, is activated and associates with phosphorylated Fc epsilon RI subunits after receptor aggregation. In this report, we used Syk SH2 domains, expressed in tandem or individually, as fusion proteins to identify Syk-binding proteins in RBL-2H3 lysates. We show that the tandem Syk SH2 domains selectively associate with tyrosine-phosphorylated forms of the gamma and beta subunits of Fc epsilon RI. The isolated carboxy-proximal SH2 domain exhibited a significantly higher affinity for the Fc epsilon RI subunits than did the amino-proximal domain. When in tandem, the Syk SH2 domains showed enhanced binding to phosphorylated gamma and beta subunits. The conserved tyrosine-based activation motifs contained in the cytoplasmic domains of the gamma and beta subunits, characterized by two YXXL/I sequences in tandem, represent potential high-affinity binding sites for the dual SH2 domains of Syk. Peptide competition studies indicated that Syk exhibits a higher affinity for the phosphorylated tyrosine activation motif of the gamma subunit than for that of the beta subunit. In addition, we show that Syk is the major protein in RBL-2H3 cells that is affinity isolated with phosphorylated peptides corresponding to the phosphorylated gamma subunit motif. These data suggest that Syk associates with the gamma subunit of the high-affinity receptor for immunoglobulin E through an interaction between the tandem SH2 domains of SH2 domains of Syk and the phosphorylated tyrosine activation motif of the gamma subunit and that Syk may be the major signaling protein that binds to Fc epsilon RI tyrosine activation motif of the gamma subunit and that Syk may be the major signaling protein that binds to Dc epsilon tyrosine activation motifs in RBL-2H3 cells.     

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.     

Rotational dynamics of type I Fc epsilon receptors on individually-selected rat mast cells studied by polarized fluorescence depletion.

We report the first application of polarized fluorescence depletion (PFD), a technique which combines the sensitivity of fluorescence detection with the long lifetimes of triplet probes, to the measurement of membrane protein rotational diffusion on individually selected, intact mammalian cells. We have examined the rotation of type I Fc epsilon receptors (Fc epsilon RI) on rat mucosal mast cells of the RBL-2H3 line in their resting monomeric and differently oligomerized states using as probes IgE and three monoclonal antibodies (mAbs; H10, J17, and F4) specific for the Fc epsilon RI. PFD experiments using eosin (EITC)-IgE show that individual Fc epsilon RI on cells have a rotational correlation time (RCT) at 4 degrees C of 79 +/- 4 microseconds. Similarly, Fc epsilon RI-bound EITC-Fab fragments of the J17 Fc epsilon RI-specific mAb exhibit an RCT of 76 +/- 6 microseconds. These values agree with previous measurements of Fc epsilon RI-bound IgE rotation by time-resolved phosphorescence anisotropy methods. Receptor-bound EITC-conjugated divalent J17 antibody exhibits an increased RCT of 140 +/- 6 microseconds. This is consistent with the ability of this mAb to form substantial amounts of Fc epsilon RI dimers on these cell surfaces. The ratio of limiting to initial anisotropy in these experiments remains constant at about 0.5 from 5 degrees C through 25 degrees C for IgE, Fab, and intact mAb receptor ligands. Extensive cross-linking by second antibody of cell-bound IgE, of intact Fc epsilon RI-specific mAbs or of their Fab fragments, however, produced large fixed anisotropies demonstrating, under these conditions, receptor immobilization in large aggregates. PFD using the mAbs H10 and F4 as receptor probes yielded values for triplet lifetimes, RCT values, and anisotropy parameters essentially indistinguishable from those obtained with the mAb J17 clone. Possible explanations for these observations are discussed.     

Analysis of Fc(epsilon)RI-mediated mast cell stimulation by surface-carried antigens

Clustering of the type I receptor for IgE (Fc[epsilon]RI) on mast cells initiates a cascade of biochemical processes that result in secretion of inflammatory mediators. To determine the Fc(epsilon)RI proximity, cluster size, and mobility requirements for initiating the Fc(epsilon)RI cascade, a novel experimental protocol has been developed in which mast cells are reacted with glass surfaces carrying different densities of both antigen and bound IgE, and the cell's secretory response to these stimuli is measured. The results have been analyzed in terms of a model based on the following assumptions: 1) the glass surface antigen distribution and consequently that of the bound IgE are random; 2) Fc(epsilon)RI binding to these surface-bound IgEs immobilizes the former and saturates the latter; 3) the cell surface is formally divided into small elements, which function as a secretory stimulus unit when occupied by two or more immobilized IgE-Fc(epsilon)RI complexes; 4) alternatively, similar stimulatory units can be formed by binding of surface-carried IgE dimers to two Fc(epsilon)RI. This model yielded a satisfactory and self-consistent fitting of all of the different experimental data sets. Hence the present results establish the essential role of Fc(epsilon)RI immobilization for initiating its signaling cascade. Moreover, it provides independent support for the notion that as few as two Fc(epsilon)RIs immobilized at van der Waals contact constitute an "elementary stimulatory unit" leading to mast cell (RBL-2H3 line) secretory response.     

Possible orientational constraints determine secretory signals induced by aggregation of IgE receptors on mast cells.

Three biologically active monoclonal antibodies (mAbs) specific for the monovalent, high-affinity membrane receptor for IgE (Fc epsilon R) were employed in analysing the secretory response of mast cells of the RBL-2H3 line to crosslinking of their Fc epsilon R. All three mAbs (designated F4, H10 and J17) compete with each other and with IgE for binding to the Fc epsilon R. Their stoichiometry of binding is 1 Fab:1 Fc epsilon R, hence, the intact mAbs can aggregate the Fc epsilon Rs to dimers only. Since all three mAbs induce secretion, we conclude that Fc epsilon R dimers constitute a sufficient 'signal element' for secretion of mediators for RBL-2H3 cells. The secretory dose-response of the cells to these three mAbs are, however, markedly different: F4 caused rather high secretion, reaching almost 80% of the cells' content, while J17 and H10 induced release of only 30-40% mediators content. Both the intrinsic affinities and equilibrium constants for the receptor dimerization were derived from analysis of binding data of the Fab fragments and intact mAbs. These parameters were used to compute the extent of Fc epsilon R dimerization caused by each of the antibodies. However, the different secretory responses to the three mAbs could not be rationalized simply in terms of the extent of Fc epsilon R dimerization which they produce. This suggests that it is not only the number of crosslinked Fc epsilon Rs which determines the magnitude of secretion-causing signal, but rather other constraints imposed by each individual mAb are also important.(ABSTRACT TRUNCATED AT 250 WORDS)     

Relationships between epitopes on IgE recognized by defined monoclonal antibodies and by the FC epsilon receptor on basophils

The present study investigated whether the sites on the FC region of the IgE molecule, recognized by different anti-IgE monoclonal antibodies (mAb), are identical to those recognized by the Fc receptor (Fc epsilon R). The anti-IgE mAb recognize different clusters of epitopes on the Fc region of IgE and could interfere to different degrees with the binding of IgE to mast cells and basophils, but still recognized cell-bound IgE. Analysis of the stoichiometry and affinity binding of 125I anti-IgE mAb Fab' to free IgE have revealed that anti-IgE mAb of one group (51.3) recognized three repetitive determinants on the IgE Fc portion, and another group (95.3) recognized only one determinant. When these stoichiometric studies were performed with cell-bound IgE, it was found that only one of the sites recognized by 51.3 mAb was involved in the Fc epsilon R binding site. On the other hand, the site recognized by 95.3 mAb was not the Fc epsilon R binding site. Such findings establish mAb 51.3 as a useful tool for isolating the IgE peptides involved in the binding site to the receptor.     

Compartmentalization of the Type I Fc epsilon receptor and MAFA on mast cell membranes

The Mast cell Function-associated Antigen (MAFA) is a membrane glycoprotein on rat mast cells (RBL-2H3) expressed at a ratio of approximately 1:30 with respect to the Type I Fc epsilon receptor (Fc epsilon RI). Despite this stoichiometry, clustering MAFA by its specific mAb G63 substantially inhibits secretion of both granular and de novo synthesized mediators induced upon Fc epsilon RI aggregation. Since the Fc epsilon RIs apparently signal from within raft micro-environments, we investigated possible co-localization of MAFA within these membrane compartments containing aggregated Fc epsilon RI. We used cholera toxin B subunit (CTB) to cluster the raft component ganglioside GM1 and studied the effects of this perturbation on rotation of Fc epsilon RI and MAFA by time-resolved phosphorescence anisotropy of erythrosin-conjugated probes. CTB treatment would be expected to substantially inhibit rotation of raft-associated molecules. Experimentally, CTB has no effect on rotational parameters such as the long-time anisotropy (r(infinity)) of unperturbed Fc epsilon RI or MAFA. However, on cells where Fc epsilon RI-IgE has previously been clustered by antigen (DNP(14)-BSA), CTB treatment increases the Fc epsilon RI-IgE's r(infinity) by 0.010 and MAFA's by 0.014. Similarly, CTB treatment of cells where MAFA had been clustered by mAb G63 increases MAFA's r(infinity) by 0.010 but leaves Fc epsilon RI's unaffected. Evaluation of raft localization of Fc epsilon RI and MAFA using sucrose gradient ultracentrifugation of Triton X-100 treated membrane fragments demonstrates that a significant fraction of MAFA molecules sediments with rafts when Fc epsilon RI is clustered by antigen or when MAFA itself is clustered by mAb G63. The large excess of Fc epsilon RI over MAFA explains why clustering MAFA does not substantively affect Fc epsilon RI dynamics. Moreover, in single-particle tracking studies of individual Fc epsilon RI-IgE or MAFA molecules, these proteins, upon clustering by antigen, move into small membrane compartments of reduced, but similar, dimensions. This provides additional indication of constitutive interactions between Fc epsilon RI and MAFA. Taken together, these results of distinct methodologies suggest that MAFA functions within raft microdomains of the RBL-2H3 cell membrane and thus in close proximity to the Fc epsilon RI which themselves signal from within the raft environment.     

Rotational dynamics of the Fc epsilon receptor on mast cells monitored by specific monoclonal antibodies and IgE.

The rotational motions of the type I receptor for the Fc epsilon domains (Fc epsilon RI) present on mast cells were investigated by measuring the phosphorescence emission and anisotropy decay kinetics of erythrosin (Er) covalently bound to several Fc epsilon RI-specific macromolecular ligands. The latter consisted of three murine monoclonal antibodies (IgG class) raised against the Fc epsilon RI of rat mast cells (RBL-2H3 line), their Fab fragments, and a murine monoclonal IgE. Different anisotropy decay patterns were observed for the three monovalent Er-Fab fragments bound to the Fc epsilon RI, reflecting the rotational motion of the Fe epsilon RI reported by each specific macromolecular probe bound to its particular epitope. Internal motions of the tethered Er-labeled ligands may also contribute to the observed anisotropy decay, particularly in the case of cell-bound IgE. The results corroborate an earlier study with rat Er-IgE in which the Fc epsilon RI-IgE complex was shown to be mobile throughout the temperature range examined (5-37 degrees C). The anisotropy decays of the three Er-labeled, Fc epsilon RI-specific intact mAbs bound to cells also differed markedly. Whereas the decay curves of one mAb (H10) were characterized by temperature-dependent positive amplitudes and rather short rotational correlation times, the decay of a second mAb (J17) showed complex qualitative variations with temperature, and in the case of the third antibody (F4), there was no apparent decay of anisotropy over the time and temperature ranges examined.(ABSTRACT TRUNCATED AT 250 WORDS)     

Recombinant human IgG1-murine IgE chimeric Ig. Construction, expression, and binding to human Fc gamma receptors

We have constructed a set of chimeric Ig by exchanging corresponding H chain C domains between human (hu) IgG1 and murine (m) IgE. We used this set of Ig to dissect the interaction of individual Ig domains with human Fc gamma receptors. Only one of the chimeras, epsilon/C gamma 2,3 (an mIgE with C epsilon 3 and C epsilon 4 replaced by C gamma 2 and C gamma 3 from huIgG1), binds tightly to the human Fc gamma RI on U937 cells. We found that epsilon/C gamma 2,3 has only twofold lower affinity for Fc gamma RI as compared to huIgG1. The gamma/C epsilon 4 (huIgG1 with C epsilon 4 replacing C gamma 3) binds weakly to Fc gamma RI. The other chimeric Ig, epsilon/C gamma 3, epsilon/C gamma 2, and gamma/C epsilon 3, as well as mIgE do not bind detectably to Fc gamma RI. From these data we conclude that the C gamma 2 domain is crucial for binding and contains the majority of the binding site for Fc gamma RI on IgG1. The C gamma 3 domain makes a smaller contribution to the binding, and the C gamma 1 domain and the hinge region have very little effect on the Fc gamma RI-IgG1 interaction. The chimeric epsilon/C gamma 2,3 and huIgG1 both mediate the formation of rosettes between K562 cells and antigen-sensitized E with similar concentration dependences. These results suggest similar ability to bind to Fc gamma RII. The other chimeric Ig do not cause rosettes in this assay system. Hence, both C gamma 2 and C gamma 3 seem to be required for binding to Fc gamma RII, but the C gamma 1-hinge region has no detectable effect.     

Intracellular expression and release of Fc epsilon RI alpha by human eosinophils.

Although Fc epsilon R have been detected on human eosinophils, levels varied from moderate to extremely low or undetectable depending on the donor and methods used. We have attempted to resolve the conflicting data by measuring levels of IgE, Fc epsilon RI, and Fc epsilon RII in or on human eosinophils from a variety of donors (n = 26) and late-phase bronchoalveolar lavage fluids (n = 5). Our results demonstrated little or no cell surface IgE or IgE receptors as analyzed by immunofluorescence and flow cytometry. Culture of eosinophils for up to 11 days in the presence or absence of IgE and/or IL-4 (conditions that enhance Fc epsilon R on other cells) failed to induce any detectable surface Fc epsilon R. However, immunoprecipitation and Western blot analysis of eosinophil lysates using mAb specific for Fc epsilon RI alpha showed a distinct band of approximately 50 kDa, similar to that found in basophils. Western blotting also showed the presence of FcR gamma-chain, but no Fc epsilon RI beta. Surface biotinylation followed by immunoprecipitation again failed to detect surface Fc epsilon RI alpha, although surface FcR gamma was easily detected. Since we were able to detect intracellular Fc epsilon RI alpha, we examined its release from eosinophils. Immunoprecipitation and Western blotting demonstrated the release of Fc epsilon RI alpha into the supernatant of cultured eosinophils, peaking at approximately 48 h. We conclude that eosinophils possess a sizable intracellular pool of Fc epsilon RI alpha that is available for release, with undetectable surface levels in a variety of subjects, including those with eosinophilia and elevated serum IgE. The biological relevance of this soluble form of Fc epsilon RI alpha remains to be determined.     

A monoclonal anti-IgE antibody against an epitope (amino acids 367-376) in the CH3 domain inhibits IgE binding to the low affinity IgE receptor (CD23)

We have produced three different mAb specific for human IgE-Fc. Their binding pattern to either heat-denatured IgE or a family of overlapping IgE-derived recombinant peptides and their ability to affect interaction of IgE with its low affinity receptor Fc epsilon R2/CD23 demonstrate that they recognize distinct epitopes on the IgE molecule. All three mAb were able to induce basophil degranulation as measured by the induction of histamine release. mAb 173 recognizes a thermolabile epitope in the CH4 domain. It does not affect the binding of IgE to Fc epsilon R2/CD23. mAb 272 recognizes a thermostable epitope that maps to a sequence of 36 amino acids (AA) spanning part of the CH2 and CH3 domain and it does not affect the binding of IgE to Fc epsilon R2/CD23. mAb 27 recognizes a thermolabile epitope located on a 10 AA stretch (AA 367-376) in the CH3 domain. This area contains one N-linked oligosaccharide (Asn-371), but the antibody is not directed against carbohydrate because it binds to Escherichia coli-derived IgE peptides. mAb 27 inhibits the binding of IgE to Fc epsilon R2/CD23 but is still capable of reacting with IgE already bound to Fc epsilon R2/CD23. These data suggest that upon binding to Fc epsilon R2/CD23, the IgE molecule engages one of two equivalent-binding sites close to the glycosylated area of the CH3 domain.     

Differential regulation of the low affinity Fc receptor for IgE (Fc epsilon R2/CD23) and the IL-2 receptor (Tac/p55) on eosinophilic leukemia cell line (EoL-1 and EoL-3)

Two types of activation Ag, low affinity FcR for IgE (Fc epsilon R2)/CD23 and IL-2R (Tac/p55), were expressed and differently regulated on human eosinophilic leukemia cell lines (EoL-1 and EoL-3). Because the binding of IgE on EoL-3 cells was completely inhibited by H107 (anti-Fc epsilon R2/CD23 mAb) but not by irrelevant mAb, essentially all the low affinity Fc epsilon R2 on EoL-3 seemed to be the Fc epsilon R2/CD23 molecules. Both IL-4 and IFN-gamma enhanced the surface expression of Fc epsilon R2, whereas IL-1, IL-2, and IL-5 showed no effects, as determined by surface staining with anti-Fc epsilon R2 antibody (H107). In contrast to Fc epsilon R2 up-regulation, IL-4 and IFN-gamma showed a differential effect on the regulation of IL-2R (Tac/p55). Whereas IFN-gamma up-regulated the receptor expression of IL-2R/Tac, IL-4 did not. The result suggests that these lymphokines are involved in the different aspects of the activation pathway of the eosinophils. The possible role of Fc epsilon R2 and IL-2R on the function of eosinophils in allergic reaction is discussed.     

CD45 is essential for Fc epsilon RI signaling by ZAP70, but not Syk, in Syk-negative mast cells.

The ZAP70/Syk family of protein tyrosine kinases plays an important role in Ag receptor signaling. Structural similarity of Syk and ZAP70 suggests their functional overlap. Previously, it was observed that expression of either ZAP70 or Syk reconstitutes Ag receptor signaling in Syk-negative B cells. However, in CD45-deficient T cells, Syk, but not ZAP70, restores T cell receptor-signaling pathway. To study the function of Syk, ZAP70, and CD45 in mast cells, a Syk/CD45 double-deficient variant of RBL-2H3 cells was characterized. After transfection, stable cell lines were isolated that expressed ZAP70, Syk, CD45, ZAP70 plus CD45, and Syk plus CD45. IgE stimulation did not induce degranulation in parental double-deficient cells, nor in the cells expressing only CD45. ZAP70 expression did not restore Fc epsilon RI signaling unless CD45 was coexpressed in the cells. However, Syk alone restored the IgE signal transduction pathway. The coexpression of CD45 with Syk had no significant effects on the responses to FcepsilonRI-aggregation. There was much better binding of Syk than ZAP70 to the phosphorylated Fc epsilon RI gamma-ITAM. Furthermore, unlike Syk, ZAP70 required CD45 to display receptor-induced increase in kinase activity. Therefore, in mast cells, ZAP70, but not Syk, requires CD45 for Ag receptor-induced signaling.     

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.