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.     

A fluorescent biosensor reveals conformational changes in human immunoglobulin E Fc: implications for mechanisms of receptor binding, inhibition, and allergen recognition

IgE binding to its high affinity receptor FcεRI on mast cells and basophils is a key step in the mechanism of allergic disease and a target for therapeutic intervention. Early indications that IgE adopts a bent structure in solution have been confirmed by recent x-ray crystallographic studies of IgEFc, which further showed that the bend, contrary to expectation, is enhanced in the crystal structure of the complex with receptor. To investigate the structure of IgEFc and its conformational changes that accompany receptor binding in solution, we created a F?rster resonance energy transfer (FRET) biosensor using biologically encoded fluorescent proteins fused to the N- and C-terminal IgEFc domains (Cε2 and Cε4, respectively) together with the theoretical basis for quantitating its behavior. This revealed not only that the IgEFc exists in a bent conformation in solution but also that the bend is indeed enhanced upon FcεRI binding. No change in the degree of bending was seen upon binding to the B cell receptor for IgE, CD23 (FcεRII), but in contrast, binding of the anti-IgE therapeutic antibody omalizumab decreases the extent of the bend, implying a conformational change that opposes FcεRI engagement. HomoFRET measurements further revealed that the (Cε2)(2) and (Cε4)(2) domain pairs behave as rigid units flanking the conformational change in the Cε3 domains. Finally, modeling of the accessible conformations of the two Fab arms in FcεRI-bound IgE revealed a mutual exclusion not seen in IgG and Fab orientations relative to the membrane that may predispose receptor-bound IgE to cross-linking by allergens.     

Conservation of signal transduction mechanisms via the human Fc epsilon RI alpha after transfection into a rat mast cell line, RBL 2H3.

The high affinity receptor for IgE (Fc epsilon RI) is present on mast cells and basophils, and the aggregation of IgE-occupied receptors by Ag is responsible for the release of allergic mediators. The Fc epsilon RI is composed of at least three different subunits, alpha, beta, and gamma, with the alpha subunit binding IgE. The series of biochemical events linking receptor aggregation to the release of mediators has not been fully delineated. As a step towards understanding these processes, and for the development of functional cell lines, we have transfected the human Fc epsilon RI alpha subunit into the rat mast cell line RBL 2H3. These human Fc epsilon RI alpha-transfected cell lines have been characterized with respect to the association of the human alpha subunit with endogenous rat beta and gamma subunits and the ability of aggregated Fc epsilon RI alpha subunits to mediate a variety of biochemical events. The signal transduction events monitored include phosphoinositide hydrolysis, Ca2+ mobilization, tyrosine phosphorylation, histamine release, and arachidonic acid metabolism. In all cases, the events mediated by aggregating human Fc epsilon RI alpha subunits were indistinguishable from those produced via the rat Fc epsilon RI alpha. These results demonstrate that the human Fc epsilon RI alpha subunit can functionally substitute for the rat Fc epsilon RI alpha subunit during signal transduction. The availability of this cell line will provide a means of evaluating potential Fc epsilon RI antagonists.     

Mapping of the CD23 Binding Site on Immunoglobulin E (IgE) and Allosteric Control of the IgE-Fc{epsilon}RI Interaction

IgE, the antibody that mediates allergic responses, acts as part of a self-regulating protein network. Its unique effector functions are controlled through interactions of its Fc region with two cellular receptors, FcεRI on mast cells and basophils and CD23 on B cells. IgE cross-linked by allergen triggers mast cell activation via FcεRI, whereas IgE-CD23 interactions control IgE expression levels. We have determined the CD23 binding site on IgE, using a combination of NMR chemical shift mapping and site-directed mutagenesis. We show that the CD23 and FcεRI interaction sites are at opposite ends of the Cε3 domain of IgE, but that receptor binding is mutually inhibitory, mediated by an allosteric mechanism. This prevents CD23-mediated cross-linking of IgE bound to FcεRI on mast cells and resulting antigen-independent anaphylaxis. The mutually inhibitory nature of receptor binding provides a degree of autonomy for the individual activities mediated by IgE-FcεRI and IgE-CD23 interactions.     

Ala12]MCD peptide: a lead peptide to inhibitors of immunoglobulin E binding to mast cell receptors.

An effort was made to discover mast cell degranulating (MCD) peptide analogs that bind with high affinity to mast cell receptors without triggering secretion of histamine or other mediators of the allergic reaction initiated by immunoglobulin E (IgE) after mast cell activation. Such compounds could serve as inhibitors of IgE binding to mast cell receptors. An alanine scan of MCD peptide reported previously showed that the analog [Ala12]MCD was 120-fold less potent in histamine-releasing activity and fivefold more potent in binding affinity to mast cell receptors than the parent MCD peptide. Because this analog showed marginal intrinsic activity and good binding affinity it was subsequently tested in the present study as an IgE inhibitor. In contrast to MCD peptide, [Ala12]MCD showed a 50% inhibition of IgE binding to the Fc epsilon RI alpha mast cell receptor by using rat basophilic leukemia (RBL-2H3) mast cells and fluorescence polarization. Furthermore, in a beta-hexosaminidase secretory assay, the peptide also showed a 50% inhibition of the secretion of this enzyme caused by IgE. An attempt was made to relate structural changes and biologic differences between the [Ala12]MCD analog and the parent MCD peptide. The present results show that [Ala12]MCD may provide a base for designing agents to prevent IgE/Fc epsilon RI alpha interactions and, consequently, allergic conditions.     

Immunoglobulin E receptor signaling and asthma

Elevated IgE levels and increased IgE sensitization to allergens are central features of allergic asthma. IgE binds to the high-affinity Fcε receptor I (FcεRI) on mast cells, basophils, and dendritic cells and mediates the activation of these cells upon antigen-induced cross-linking of IgE-bound FcεRI. FcεRI activation proceeds through a network of signaling molecules and adaptor proteins and is negatively regulated by a number of cell surface and intracellular proteins. Therapeutic neutralization of serum IgE in moderate-to-severe allergic asthmatics reduces the frequency of asthma exacerbations through a reduction in cell surface FcεRI expression that results in decreased FcεRI activation, leading to improved asthma control. Our increasing understanding of IgE receptor signaling may lead to the development of novel therapeutics for the treatment of asthma.     

Death of a dogma or enforcing the artificial: monomeric IgE binding may initiate mast cell response by inducing its receptor aggregation

Several recent reports have suggested that binding monomeric IgE (mIgE) to its type 1 receptor, Fc epsilon RI, on mast cells induces important responses. These observations contradict the notion that it is the aggregation of this receptor that is essential for initiating mast cell response. In the present study, we suggest that the most probable causes for the reported observations are the experimental protocol used combined with the high expression levels of the Fc epsilon RI by mast cells. Specifically, we suggest using the published data and physicochemical calculations that the exceptionally high number of cell surface Fc epsilon RI-bound monoclonal IgE yields, in the two-dimensions of the cells' membranes, a situation where even a low affinity of these mIgE for epitopes on their own structure or on another cell surface component may lead to their aggregation. Hence, we hypothesize that the reported response to mIgE binding is a result of such an Fc epsilon RI-IgE induced aggregation.     

Complete structure of the mouse mast cell receptor for IgE (Fc epsilon RI) and surface expression of chimeric receptors (rat-mouse-human) on transfected cells

The high affinity receptor for IgE (Fc epsilon RI) found on mast cells and basophils is a tetrameric complex of a single alpha subunit, a single beta subunit, and two identical gamma subunits. The genes for the three subunits of mouse Fc epsilon RI have now been cloned from the mast cell line, PT18. When compared at the DNA level, the rat and mouse subunits are similarly conserved. However, at the protein level the homology between mouse and rat alpha is surprisingly low (71% identities) especially in the cytoplasmic regions (57% identities) which are of different length (25 and 20 residues, respectively). By contrast the beta and gamma are homogeneously conserved between mouse and rat (83 and 93% identities, respectively). The consensus amino acid sequence of the alpha subunit derived from three species (rat, mouse, and human) shows that the cytoplasmic tail diverges to the same extent as the leader peptide. Conversely, the transmembrane domain of the alpha is highly conserved and contains 10 consecutive residues that are identical. Comparisons between mouse Fc epsilon RI and other mouse proteins reveal regions of high homology between the alpha subunit and Fc gamma RIIa and between the gamma subunit and the zeta chain of the T cell receptor. Cells transfected with the alpha gene express the alpha subunit on their surface very inefficiently. Efficient expression is only achieved after co-transfection of the three rodent genes or of the human alpha gene together with the rodent gamma without apparent need for beta. The subunits are completely interchangeable upon transfection so that various chimeric mouse-rat-human receptors can be expressed.     

Production of Humanized Fab Fragment against Human High Affinity IgE Receptor in Pichia pastoris

Binding of allergen-IgE complexes to the high affinity IgE receptor (FcεRI) on mast cells and basophils leads to the release of various mediaters such as histamine. Fab fragments prepared by the papain digestion of humanized antibody against human FcεRI inhibited the release of histamine from human basophils. Here we established an expression system to directly produce Fab fragments of the humanized anti-human FcεRI antibody in methylotropic yeast, P. pastoris. Fab fragments were efficiently secreted into the medium at a concentration of 10-40 mg/L using a signal sequence from the P. pastoris phosphatase gene. They were consisted of disulfide-linked light and heavy chains correctly starting from the first amino acid residues by proper cleavage of the signal peptides. The obtained Fab fragments inhibited the binding between IgE and FcεRI as efficiently as the counterpart prepared by papain digestion of the whole antibody.     

Cutting edge: Helminth infection induces IgE in the absence of mu- or delta-chain expression

Infections with helminth parasites are associated with an IgE isotype switch and high serum IgE concentrations. IgE is rapidly bound by the high affinity IgE receptor (Fc epsilonRI), thereby sensitizing Fc epsilonRI-bearing basophils and mast cells for IgE-inducible effector functions such as IL-4 production. The development of Ab-secreting B cells is dependent on IgM and consequently, muMT mice, which lack surface IgM, are considered devoid of Abs. In this study we report the unexpected finding that C57BL/6 muMT mice generate robust IgE responses upon infection with three distinct helminth parasites, Heligmosomoides polygyrus, Trichuris muris, and Schistosoma mansoni. IgE is produced despite an apparent block in B cell development and licenses basophils for IgE-induced IL-4 production. Our findings reveal the existence of an evolutionarily conserved, IgM-independent pathway for the production of IgE upon infection with helminth parasites.     

Expression of a functional high-affinity IgG receptor, Fc gamma RI, on human mast cells: Up-regulation by IFN-gamma

Biologically relevant activation of human mast cells through Fc receptors is believed to occur primarily through the high-affinity IgE receptor Fc epsilon RI. However, the demonstration in animal models that allergic reactions do not necessarily require Ag-specific IgE, nor the presence of a functional IgE receptor, and the clinical occurrence of some allergic reactions in situations where Ag-specific IgE appears to be lacking, led us to examine the hypothesis that human mast cells might express the high-affinity IgG receptor Fc gamma RI and in turn be activated through aggregation of this receptor. We thus first determined by RT-PCR that resting human mast cells exhibit minimal message for Fc gamma RI. We next found that IFN-gamma up-regulated the expression of Fc gamma RI. This was confirmed by flow cytometry, where Fc gamma RI expression on human mast cells was increased from approximately 2 to 44% by IFN-gamma exposure. Fc epsilon RI, Fc gamma RII, and Fc gamma RIII expression was not affected. Scatchard plots were consisted with these data where the average binding sites for monomeric IgG1 (Ka = 4-5 x 108 M-1) increased from approximately 2,400 to 12,100-17,300 per cell. Aggregation of Fc gamma RI on human mast cells, and only after IFN-gamma exposure, led to significant degranulation as evidenced by histamine release (24.5 +/- 4.4%): and up-regulation of mRNA expression for specific cytokines including TNF-alpha, GM-CSF, IL-3 and IL-13. These findings thus suggest another mechanism by which human mast cells may be recruited into the inflammatory processes associated with some immunologic and infectious diseases.     

Signal transduction by the cytoplasmic domains of Fc epsilon RI-gamma and TCR-zeta in rat basophilic leukemia cells.

The gamma subunit of the high affinity IgE receptor, Fc epsilon RI, is a member of a family of proteins which form disulfide-linked dimers. This family also includes the zeta- and eta-chains of the T cell receptor. Engagement of Fc epsilon RI activates src-related protein tyrosine kinases in basophils and mast cells. However, the role of individual subunits of Fc epsilon RI in this activation is still not known. In an effort to determine the function of Fc epsilon RI-gamma, we used chimeric proteins containing the extracellular and transmembrane domains of the alpha chain of the human interleukin 2 receptor (Tac) and the cytoplasmic domains of either T cell receptor-zeta or Fc epsilon RI-gamma. We show that while cross-linking of the Tac chimeras in the rat basophilic leukemia cell line RBL-2H3 resulted in the tyrosine phosphorylation of a subset of proteins and a portion of the degranulation normally observed after Fc epsilon RI-mediated stimulation, no detectable activation of p56lyn or pp60c-src was observed. In contrast, an apparent transient deactivation of these two kinases was observed after Tac chimera cross-linking. These observations suggest that Fc epsilon RI-gamma is responsible for some, but not all, of the signaling that occurs after engagement of its receptor, and that other receptor subunits may also play important roles in this signaling process.     

Phospholipase C-gamma 1 is translocated to the membrane of rat basophilic leukemia cells in response to aggregation of IgE receptors.

Aggregation of the high affinity receptor for IgE (Fc epsilon RI) on the surface of mast cells results in the rapid hydrolysis of membrane inositol phospholipids by phospholipase C (PLC). Although at least seven isoenzymes of PLC have been characterized in different mammalian cells, the isoenzyme involved in Fc epsilon RI-mediated signal transduction and the mechanism of its activation have not been demonstrated. We now report that PLC-gamma 1 is translocated to the membrane of mast cells after aggregation of Fc epsilon RI. Activation of rat basophilic leukemia cells, a rat mast cell line, with oligomeric IgE resulted in an increase in PLC activity in washed membrane preparations in a cell free assay containing exogenous [3H]phosphatidylinositol (PI). The increase in PLC activity has the same dose-response to oligomeric IgE as receptor mediated hydrolysis of inositol lipids (PI hydrolysis) in intact cells. Analysis by Western blot probed with anti-PLC-gamma 1 antibody revealed that there is a three- to fourfold increase in PLC-gamma 1 in membranes from activated cells. The increase in PLC activity is augmented a further 20% by the addition of orthovanadate to the incubation medium suggesting that a tyrosine phosphatase is involved in the down-regulation of this phenomenon. These findings demonstrate translocation of PLC-gamma 1 to the membrane following activation of a receptor which does not contain intrinsic tyrosine kinase activity. Activation of PLC-gamma 1 by this pathway may account for Fc epsilon RI-mediated PI hydrolysis.     

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.     

IgE by Itself Affects Mature Rat Mast Cell Preformed and De Novo-Synthesized Mediator Release and Amplifies Mast Cell Migratory Response

Background

Immunoglobulin E (IgE) binds to high affinity receptor FcεRI numerously expressed on mast cells. Recent findings have revealed that IgE by itself may regulate various aspects of mast cell biology, however, detailed data is still limited.

Methodology/Findings

Here, we have examined the influence of IgE alone, used at different concentrations, on mast cell activity and releasability. For the study we have employed in vivo differentiated mature tissue mast cells isolated from rat peritoneal cavity. Mast cells were exposed to IgE alone and then the release of preformed and de novo-synthesized mediators, surface FcεRI expression and mast cell migratory response were assessed. IgE by itself was found to up-regulate FcεRI expression and activate mast cells to degranulation, as well as de novo synthesis and release of cysteinyl leukotrienes and TNF. We have provided evidence that IgE alone also amplified spontaneous and CCL5- or TNF-induced migration of mast cells. Importantly, IgE was effective only at concentrations ≥ 3 µg/mL. A molecular basis investigation using an array of specific inhibitors showed that Src kinases, PLC/PLA₂, MAP kinases (ERK and p38) and PI3K were entirely or partially involved in IgE-induced mast cell response. Furthermore, IgE alone stimulated the phosphorylation of MAP kinases and PI3K in rat mast cells.

Conclusion

Our results clearly demonstrated that IgE by itself, at higher concentrations, influences mast cell activity and releasability. As there are different conditions when the IgE level is raised it might be supposed that in vivo IgE is one of the important factors modulating mast cell biology within tissues.     

What precedes the initial tyrosine phosphorylation of the high affinity IgE receptor in antigen-activated mast cell?

An interaction of multivalent antigen with its IgE bound to the high-affinity IgE receptor (FcεRI) on the surface of mast cells or basophils initiates a series of signaling events leading to degranulation and release of inflammatory mediators. Earlier studies showed that the first biochemically defined step in this signaling cascade is tyrosine phosphorylation of the FcεRI β subunit by Src family kinase Lyn. However, the processes affecting this step remained elusive. In this review we critically evaluate three current models (transphosphorylation, lipid raft, and our preferential protein tyrosine kinase-protein tyrosine phosphatase interplay model) substantiating three different mechanisms of FcεRI phosphorylation.     

Relationships between Levels of Serum IgE,Cell-Bound IgE,and IgE-Receptors on Peripheral Blood Cells in a Pediatric Population

Background

Elevated serum immunoglobulin (Ig) E is a diagnostic marker of immediate-type allergic reactions. We hypothesize that serum IgE does not necessarily reflect total body IgE because in vivo IgE can be bound to cell surface receptors such as FcεRI and FcεRII (CD23). The aim of this study was to analyze the relationships between levels of serum IgE, cell-bound IgE, and IgE-receptors on peripheral blood cells in a pediatric population.

Methodology

Whole blood samples from 48 children (26 boys, 22 girls, mean age 10,3±5,4 years) were analyzed by flow cytometry for FcεRI, CD23, and cell-bound IgE on dendritic cells (CD11c+MHC class II+), monocytes (CD14+), basophils (CD123+MHC class II-) and neutrophils (myeloperoxidase+). Total serum IgE was measured by ELISA and converted into z-units to account for age-dependent normal ranges. Correlations were calculated using Spearman rank correlation test.

Principal Findings

Dendritic cells, monocytes, basophils, and neutrophils expressed the high affinity IgE-receptor FcεRI. Dendritic cells and monocytes also expressed the low affinity receptor CD23. The majority of IgE-receptor positive cells carried IgE on their surface. Expression of both IgE receptors was tightly correlated with cell-bound IgE. In general, cell-bound IgE on FcεRI+ cells correlated well with serum IgE. However, some patients carried high amounts of cell-bound IgE despite low total serum IgE levels.

Conclusion/Significance

In pediatric patients, levels of age-adjusted serum IgE, cell-bound IgE, and FcεRI correlate. Even in the absence of elevated levels of serum IgE, cell-bound IgE can be detected on peripheral blood cells in a subgroup of patients.     

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.     

Transmembrane signaling in P815 mastocytoma cells by transfected IgE receptors

In order to delineate structural-functional relationships of the mast cell receptor for IgE (Fc epsilon RI) by molecular-genetic analysis, a transfectable cell must be identified which resembles mast cells except for being deficient in receptors. We have found that the well known murine mastocytoma P815 is suitable. These cells express no Fc epsilon RI, lack mRNA for the alpha and beta subunits of the receptor, but contain some mRNA for gamma chains. After transfection with the cDNA for each of the subunits, stable clones could be isolated which expressed several hundred thousand normal Fc epsilon RI and synthesized large amounts of mRNA for alpha, beta, and gamma, the last at 3-fold higher levels than in the untransfected cells. Aggregation of the transfected receptors led to opening of presumptive calcium channels and to activation of phospholipase C, phospholipase A2, and protein kinase C. The kinetics and other characteristics of the signals were similar to those observed after stimulation of the rat tumor mast cells from which the receptor genetic material had been derived but were smaller in magnitude. These weaker signals most likely result from an overall reduced reactivity exhibited by the P815 cells since stimulation by other ligands led to weaker or even no responses. The cells failed to degranulate after either receptor aggregation or reaction with ionophores with or without phorbol ester. Both the transfected and untransfected P815 cells express Fc receptors for IgG (Fc gamma RII) which, interestingly, independently triggered similar responses despite their apparently simpler subunit structure.     

Isolation of cross-linked IgE-receptor complexes from rat macrophages

Receptors for IgE on macrophages have been characterized by binding assays (1-3), but to date there has been only one report on the isolation of this receptor from macrophages, with use of the cell line U937 (4). In that report the receptor was isolated by using a heavily absorbed polyclonal antibody raised against lymphocytes bearing receptors for IgE (5). Monomeric IgE binds so weakly to macrophages that affinity chromatography of IgE-receptor complexes, such as has been used for isolation of the receptors for IgE on basophils (6) and for IgG on macrophages (7), cannot be readily accomplished. We have used oligomers of IgE to enhance the binding of IgE to macrophages (3), but this alone would not be sufficient because--depending on whether the receptors are multi- or univalent--once the cells are solubilized, multipoint attachment would again be reduced if not abrogated. In this report we describe the use of cross-linking reagents to stabilize further the interaction between IgE and its receptor on peritoneal macrophages. With this approach we have found that the receptor is likely to be composed of two chains whose gross properties are similar to the polypeptides constituting the receptor with high affinity for monomeric IgE on rat basophilic leukemia cells and mast cells.