Cross-linking of receptor-bound IgE to aggregates larger than dimers leads to rapid immobilization

Controlled cross-linking of IgE-receptor complexes on the surface of rat basophilic leukemia cells and mast cells has allowed a comparison of the lateral mobility and cell triggering activity of monomers, dimers, and higher oligomers of receptors. Addition of a monoclonal anti-IgE(Fc) antibody to IgE-sensitized cells in stoichiometric amounts relative to IgE produces IgE-receptor dimers with high efficiency. These dimers are nearly as mobile as IgE-receptor monomers and trigger cellular degranulation poorly, but in the presence of 30% D2O, substantial immobilization of the dimers is seen and degranulation activity doubles. Addition of this monoclonal antibody in larger amounts results in the formation of larger oligomeric receptor clusters which are immobile and effectively trigger the cells. Thus, small receptor clusters that are active in stimulating degranulation are immobilized in a process that is not anticipated by simple hydrodynamic theories. Further experiments involving cross-linking of receptor-bound IgE by multivalent antigen demonstrate that immobilization of receptors occurs rapidly (less than 2 min) upon cross-linking and is fully and rapidly reversible by the addition of excess monovalent hapten. The rapidity and reversibility of the immobilization process are entirely consistent with the possibility that immobilization represents a recognition event between clustered receptors and cytoskeleton-associated components that plays an important role early in the cell triggering mechanism.     

Small oligomers of immunoglobulin E (IgE) cause large-scale clustering of IgE receptors on the surface of rat basophilic leukemia cells

We examined the distribution of small oligomers of IgE bound to rat basophilic leukemia cells using fluorescence microscopy. The oligomers were seen to cluster into visible patches on the cell surface at 4 degrees C; at higher temperatures internalization also was observed. In contrast, cells labeled with IgE monomers remained predominantly ring-stained. Evidence is provided that the observed clustering of IgE oligomers is a cell-induced phenomenon, and the possible significance of this clustering is discussed in the context of the oligomer-triggered degranulation of rat basophilic leukemia cells.     

Cross-linking of immunoglobulin E-receptor complexes induces their interaction with the cytoskeleton of rat basophilic leukemia cells

Bridging of immunoglobulin E (IgE)-receptor complexes on rat basophilic leukemia cells by polyclonal anti-IgE antibodies induces a detergent-resistant association of these complexes with the cellular cytoskeleton. In dose-response curves the extent of the cytoskeletal association appears to follow the extent of bridging, continuing to increase beyond where stimulated degranulation is maximal. This stable association is maintained after the aggregated IgE-receptor complexes have been internalized by the cell. Multivalent antigen and trimeric IgE cause less extensive receptor cross-linking than anti-IgE and stimulate degranulation; they also induce receptor association with the cytoskeleton that is revealed only after stabilization by addition of a chemical cross-linking reagent. The ability of a membrane impermeant chemical cross-linker to stabilize this association suggests that the receptor-cytoskeletal interaction may be mediated by a transmembrane protein that is exposed at the cell surface. Monomeric and dimeric IgE bound to receptors fail to induce a stable interaction with the cytoskeleton even in the presence of chemical cross-linkers and are poor (dimers) or insignificant (monomers) stimulators of cellular degranulation. These findings are consistent with a possible relationship between receptor attachment to the cytoskeleton, receptor immobilization as measured by fluorescence photobleaching recovery, and the triggering of cellular degranulation.     

Cross-linking of IgE-receptor complexes by rigid bivalent antigens greater than 200 A in length triggers cellular degranulation

We have examined the effect of cross-linking IgE-receptor complexes with variable receptor-receptor distances on the transmembrane signaling that leads to degranulation of rat basophilic leukemia cells. Linear polymers of the biotin-binding protein avidin were generated with bis biotin-1,12-diamidododecane, and a dinitrophenyl-biotin conjugate was bound at each end of the polymers to form a series of rigid bivalent haptens of well-defined length. The polymers were fractionated by size with nondenaturing PAGE, electro-eluted, and tested for their ability to stimulate degranulation of rat basophilic leukemia cells sensitized with anti-DNP IgE. We found that hexamers of avidin (of length greater than or equal to 240 A) were as effective in triggering degranulation as dimers (of length approximately 80 A), while the monomeric avidin antigen (of length approximately 40 A) elicited a poorer degranulation response from the cells. The mechanism by which aggregation of cell surface receptors can initiate signal transduction is discussed in light of these results.     

Membrane-bound IgE receptor complexes fused with rat basophilic leukemia cells mediate degranulation

The high affinity receptor for IgE on rat basophilic leukemia (RBL) cells mediates antigen-triggered cellular degranulation. Polyethylene glycol-induced membrane fusion methods were used to introduce exogenous IgE receptors into living RBL cells, and these were tested for normal activities. In cell-cell fusion experiments, RBL cells with fluorescein-labeled rat IgE bound to receptors and containing [5-1,2-3H(N)]hydroxytryptamine binoxalate ([3H]5HT) in their secretory granules were fused to cells with receptors occupied by rhodamine-labeled anti-dinitrophenyl mouse IgE. The fused cells showed a uniform surface distribution of both types of IgE, which could be patched independently by anti-IgE or dinitrophenylated bovine gamma globulin (DNP16BGG). [3H]5HT release could be triggered specifically by DNP16BGG. In vesicle-cell fusion experiments, plasma membrane vesicles, with receptors occupied by fluorescein- and 125I-labeled anti-DNP mouse IgE, were fused to RBL cells containing [3H]5HT. The cells showed substantial associated fluorescein fluorescence and 125I counts, and [3H]5HT release could be triggered specifically by DNP16BGG. These experiments indicate that IgE receptors can be dissociated from their natural cellular interactions and retain the ability to reassociate with another cell's components to deliver the transmembrane signal for degranulation.     

Covalent cross-linking of subunits of the receptor for immunoglobulin E induced by immunoprecipitation

The receptor on rat basophilic leukemia and related normal cells that binds monomeric immunoglobulin E (IgE) with high affinity contains four polypeptide chains: alpha (to which the IgE binds), beta, and a disulfide-linked dimer of gamma chains. In this study, we have analyzed a further component variably seen when the purified receptors are analyzed on polyacrylamide gels. This component has an apparent Mr of approximately 43 000 and, after treatment with reducing agents, yields one beta and two gamma chains. This complex is generated by immunoprecipitation of preparations totally lacking in it. This novel in vitro phenomenon has provided additional information about the structure of the receptor. Its possible relationship to in vivo aggregation that triggers degranulation of the cells is of interest.     

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.     

Lateral electromigration and diffusion of Fc epsilon receptors on rat basophilic leukemia cells: effects of IgE binding

We have used in situ electromigration and post-field relaxation (Poo, M.-m., 1981, Annu. Rev. Biophys. Bioeng., 10:245-276) to assess the effect of immunoglobulin E (IgE) binding on the lateral mobility of IgE- Fc receptors in the plasmalemma of rat basophilic leukemia (RBL) cells. Bound IgE sharply increased the receptor's electrokinetic mobility, whereas removal of cell surface neuraminic acids cut it to near zero. In contrast, we found only a small difference between the lateral diffusion coefficients (D) of vacant and IgE-occupied Fc receptors (D: 4 vs. 3 X 10(-10) cm2/s at 24 degrees C). This is true for monomeric rat IgE; with mouse IgE, the difference in apparent diffusion rates was slightly greater (D: 4.5 vs. 2.3 X 10(-10) cm2/s at 24 degrees C). This range of D values is close to that found in previous photobleaching studies of the IgE-Fc epsilon receptor complex in RBL cells and rat mast cells. Moreover, enzymatic depletion of cell coat components did not measurably alter the diffusion rate of IgE-occupied receptors. Thus, binding of fluorescent macromolecular probes to cell surface proteins need not severely impede lateral diffusion of the probed species. If the glycocalyx of RBL cells does limit lateral diffusion of the Fc epsilon receptor, it must act primarily on the receptor itself, rather than on receptor-bound IgE.     

Aggregation of IgE-receptor complexes on rat basophilic leukemia cells does not change the intrinsic affinity but can alter the kinetics of the ligand-IgE interaction.

The aggregation of IgE anchored to high-affinity Fc epsilon receptors on rat basophilic leukemia (RBL) cells by multivalent antigens initiates transmembrane signaling and ultimately cellular degranulation. Previous studies have shown that the rate of dissociation of bivalent and multivalent DNP ligands from RBL cells sensitized with anti-DNP IgE decreases with increasing ligand incubation times. One mechanism proposed for this effect is that when IgE molecules are aggregated, a conformational change occurs that results in an increase in the intrinsic affinity of IgE for antigen. This possibility was tested by measuring the equilibrium constant for the binding of monovalent DNP-lysine to anti-DNP IgE under two conditions, where the cell-bound IgE is dispersed and where it has been aggregated into visible patches on the cell surface using anti-IgE and a secondary antibody. No difference in the equilibrium constant in these two cases was observed. We also measured the rate of dissociation of a monovalent ligand from cell surface IgE under these two conditions. Whereas the affinity for monovalent ligand is not altered by IgE aggregation, we observe that the rate of ligand dissociation from IgE in clusters is slower than the rate of ligand dissociation from unaggregated IgE. These results are discussed in terms of recent theoretical developments concerning effects of receptor density on ligand binding to cell surfaces.     

The fate of IgE bound to rat basophilic leukemia cells. IV. Functional association between the receptors for IgE

Rat basophilic leukemia cells (RBL-2H3) have receptors for immunoglobulin E (IgE) and immunoglobulin G (IgG). These receptors for IgE mediate the endocytosis of chemically or immunochemically cross-linked IgE but not monomeric IgE. However, unoccupied receptors were endocytosed with cross-linked IgE. To further assess the degree and specificity of the observed coendocytosis, we exposed cells carrying monomeric rat IgE and monomeric mouse IgE anti-DNP to a DNP-protein conjugate. We found that up to 30% of the surface-bound monomeric rat IgE redistributed at 0 to 4 degrees C and was then internalized at 37 degrees C with the immunochemically cross-linked mouse IgE. To assess the specificity of the coendocytosis, we exposed cells carrying monomeric rat IgE to immunochemically cross-linked mouse IgG. We found that the binding, patching, and endocytosis of cross-linked mouse IgG had no effect on the monomerically bound rat IgE. The rate of coendocytosis was the same as the rate of endocytosis (t 1/2 3 to 5 min). The extent of coendocytosis depended on the extent of endocytosis but was relatively insensitive to changes in the ratio between mouse and rat IgE over a broad range. These results indicate that some of the receptors for IgE are associated in a specific fashion.     

Rotational motion of monomeric and dimeric immunoglobulin E-receptor complexes.

Erythrosin 5'-thiosemicarbazide labeled immunoglobulin E (IgE) was used to monitor the rotational dynamics of monomeric and dimeric Fc epsilon RI receptors for IgE on rat basophilic leukemia (RBL) basophilic leukemia (RBL) cells using time-resolved phosphorescence anisotropy. Receptors were studied both on living RBL cells and on membrane vesicles derived from RBL cell plasma membrane. The un-cross-linked IgE-receptor complexes on cells and vesicles exhibit rotational correlation times that are consistent with those expected for freely rotating monomers, but a small fraction of these complexes on cells may be rotationally immobile. A comparison of the initial phosphorescence anisotropy values for erythrosin-labeled IgE-receptor complexes on cells and vesicles reveals a fast component of rotational motion that is greater on the vesicles and may be due to a site of segmental flexibility in the receptor itself. Dimers of IgE-receptor complexes formed with anti-IgE monoclonal antibodies appear to be largely immobile on cells, but they are mobile on vesicles with a 2-fold larger rotational correlation time than the monomeric complexes. The results suggest that dimeric IgE-receptor complexes undergo interactions with other membrane components on intact cells that do not occur on the membrane vesicles. The possible significance of these interactions to receptor function is discussed.     

The fate of IgE bound to rat basophilic leukemia cells. II. Endocytosis of IgE oligomers and effect on receptor turnover

We have assessed the internalization of variously sized oligomers of IgE bound to rat basophilic leukemia (RBL) cells by measuring their accessibility to the extracellular environment, and by direct visualization of the radiolabeled ligands. We also followed the fate of the internalized ligands and their receptors, as well as the fate of the free receptor on cells internalizing oligomers. In contrast to monomeric IgE, surface-bound oligomeric IgE was internalized. Notably, dimers provided an effective signal for internalization, although larger oligomers seem to be internalized more efficiently. In our experiments, 48% of the cell-bound dimers and 67% of the trimers were eliminated from the cell surface in 180 min. One-half of the maximal internalization observed with dimers and trimers occurred in 25 and 11 min, respectively. Release of radioactivity into the supernatant followed internalization; the released radioactivity did not bind to fresh cells and was only partially TCA-precipitable. Radioactive ligands remaining associated with the cells were unchanged as judged by m.w; they also were shown to remain receptor-bound. During either internalization or release of substantial amounts of the originally cell-bound oligomers, there was no increase in IgE-binding activity. In contrast, there was a transient drop (25%) in the number of free surface receptors suggesting internalization of the free receptors together with the oligomer-occupied receptor. Cells that failed to release histamine (RBL-I) processed dimeric and trimeric IgE similarly to histamine-releasing (RBL-2H3) cells. We conclude that dimeric and trimeric IgE are internalized by RBL cells and later are released to the medium in a partially degraded form. The ligand-bound receptor seems to be internalized with the ligand, along with some free receptor, and does not appear to be reusable or to recycle rapidly to the cell surface.     

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.     

Flotillin-1 regulates IgE receptor-mediated signaling in rat basophilic leukemia (RBL-2H3) cells

Cross-linking of high-affinity IgE receptors by multivalent Ag on mast cells (rat basophilic leukemia (RBL)-2H3) induces the phosphorylation of ITAM motifs of an IgE receptor by Src family tyrosine kinase, Lyn. The phosphorylation of IgE receptors is followed by a series of intracellular signals, such as Ca(2+) mobilization, MAPK activation, and degranulation. Therefore, Lyn is a key molecule in the activation of mast cells, but the molecular mechanisms for the activation of Lyn are still unclear. Recently, it is suggested that the localization of Lyn in lipid rafts is critical for its activation in several cell lines, although the precise mechanism is still unknown. In this study, we found that flotillin-1, which is localized in lipid rafts, is involved in the process of Lyn activation. We obtained flotillin-1 knockdown (KD)(2) rat basophilic leukemia (RBL)-2H3 cells, which express a low level of flotillin-1. In the flotillin-1 KD cells, we observed a significant decrease in Ca(2+) mobilization, the phosphorylation of ERKs, tyrosine phosphorylation of the gamma-subunit of IgE receptor, and IgE receptor-mediated degranulation. We also found that flotillin-1 is constitutively associated with Lyn in lipid rafts in RBL-2H3 cells, and Ag stimulation induced the augmentation of flotillin-1 binding to Lyn, resulting in enhancement of kinase activity of Lyn. These results suggest that flotillin-1 is an essential molecule in IgE receptor-mediated mast cell activation, and regulates the kinase activity of Lyn in lipid rafts.     

Association of the crosslinked IgE receptor with the membrane skeleton is independent of the known signaling mechanisms in rat basophilic leukemia cells.

Crosslinking of the IgE receptor on the surface of rat basophilic leukemia (RBL) cells by multivalent antigen induces an association of these receptors with the detergent-insoluble membrane skeleton. Detergent insolubility of the receptor can also be induced on purified plasma membranes isolated from RBL cells by the use of either IgE oligomers or IgE monomers plus multivalent antigen. The critical event in initiating this interaction between the receptor and the membrane skeleton is cross-linking of the receptor. This association is rapid, and, when triggered by multivalent antigen, it is quickly reversed by the addition of excess monovalent antigen. The fact that this association occurs with the use of purified plasma membranes indicates that all of the components necessary for this interaction are present in the plasma membrane and that intracellular components are not required. Although crosslinking of the receptor activates phospholipase C and phospholipase A2 leading to the generation of several second messengers, none of these signaling mechanisms appears to be involved in IgE receptor interaction with the membrane skeleton. This interaction cannot be induced by phorbol 12-myristate 13-acetate (PMA), ionomycin, or a combination of these two reagents, although this will result in degranulation. Furthermore, receptor detergent insolubility is temperature independent when triggered by multivalent antigen, thus indicating that enzyme-catalyzed reactions are not important. This was verified by the fact that a variety of inhibitors that block phosphatidylinositol metabolism, arachidonic acid metabolism, Ca2+ influx, and protein kinase C (PKC) activation had no effect on antigen-induced association of the receptor with the membrane skeleton. These results indicate that the signaling mechanisms leading to the degranulation response are not involved in the association of the crosslinked receptor with the membrane skeleton.     

Immobilization and internalization of mutated IgE receptors in transfected cells.

Earlier studies have shown that the mast cell receptor IgE (Fc epsilon RI) for is expressed on COS-7 cells transfected with the cDNA for each of the three types of subunits that form the tetrameric, alpha beta gamma 2, receptor. Although such transfected COS cells fail to exhibit some of the early biochemical perturbations initiated by aggregation of the receptor on normal mast cells and related tumor lines, we show here that other characteristics of the endogenous Fc epsilon RI are retained. Thus, the unaggregated transfected wild-type receptors were found to have a restricted translational diffusion similar to that observed for endogenous receptors on mast cells as assessed by fluorescence photobleaching and recovery. Similarly, as with endogenous receptors the mobility of transfected receptors was sharply reduced when the receptors were aggregated by reaction with small oligomers of IgE. In addition, aggregation of the transfected Fc epsilon RI caused them to be internalized by the COS cells by a cytochalasin-sensitive mechanism, albeit at a considerably slower rate than was seen with endogenous receptors on mast cells or with transfected receptors in a line of receptor-deficient mast cells. We also examined the mobility and internalization before and after aggregation, of some 13 different combinations of receptor subunit mutants in which one or more of the five cytoplasmic domains of the receptor had been truncated. Our results show that whatever interactions between the receptor and cellular components may account for the phenomena we studied, such interactions do not critically depend upon the bulk of the cytoplasmic domains of the receptor.     

Natural cytotoxic (NC) cell activity in basophilic cells: release of NC-specific cytotoxic factor by IgE receptor triggering

A murine interleukin 3 (IL 3)-dependent basophilic mast cell line, PT-18 (A17), and a rat basophilic leukemic cell line, RBL-2H3, were shown to be capable of selective natural cytotoxic (NC) but not natural killer (NK) cell activity. The basophilic cell types could also be augmented in their NC activity by bridging of their surface IgE receptors. IgE-mediated triggering of the basophilic cells was accomplished by coating the cells with IgE and exposing the IgE-bound cells to specific antigen or to anti-IgE monoclonal antibody. Another method of triggering was by direct binding of basophilic cells to anti-IgE receptor monoclonal antibody. Basophilic cells, triggered by these methods, not only displayed increased NC activity but also released a soluble factor capable of selectively lysing NC tumor targets, WEHI-164, but not three of the NK-sensitive targets, YAC-1, RLM1, and RBL-5. Normal C3H/HeJ mouse embryonic fibroblasts were also not lysed. Dose response and time course of the cytotoxic factor release from triggered RBL-2H3 cells were similar to those of tritiated serotonin release. As with serotonin or histamine release, the NC-specific cytotoxic factor (NCCF) was not released in the absence of extracellular calcium. Therefore, NCCF appears to be released along with other mediators during the triggering of basophilic cells by bridging of IgE receptors. The m.w. of the native form of this factor, determined by a gel filtration method, was about 43,000.     

Distinct Stages of Stimulated FcεRI Receptor Clustering and Immobilization Are Identified through Superresolution Imaging

Recent advances in fluorescence localization microscopy have made it possible to image chemically fixed and living cells at 20 nm lateral resolution. We apply this methodology to simultaneously record receptor organization and dynamics on the ventral surface of live RBL-2H3 mast cells undergoing antigen-mediated signaling. Cross-linking of IgE bound to FcεRI by multivalent antigen initiates mast cell activation, which leads to inflammatory responses physiologically. We quantify receptor organization and dynamics as cells are stimulated at room temperature (22°C). Within 2 min of antigen addition, receptor diffusion coefficients decrease by an order of magnitude, and single-particle trajectories are confined. Within 5 min of antigen addition, receptors organize into clusters containing ∼100 receptors with average radii of ∼70 nm. By comparing simultaneous measurements of clustering and mobility, we determine that there are two distinct stages of receptor clustering. In the first stage, which precedes stimulated Ca²⁺ mobilization, receptors slow dramatically but are not tightly clustered. In the second stage, receptors are tightly packed and confined. We find that stimulation-dependent changes in both receptor clustering and mobility can be reversed by displacing multivalent antigen with monovalent ligands, and that these changes can be modulated through enrichment or reduction in cellular cholesterol levels.     

A cDNA presumptively coding for the alpha subunit of the receptor with high affinity for immunoglobulin E

Rat mast cells and a neoplastic analogue such as rat basophilic leukemia (RBL) cells have receptors that have exceptionally high affinity for immunoglobulin E (IgE). When aggregated, these receptors induce cellular degranulation. The alpha chain of the receptor contains the binding site for IgE; the function(s) of the noncovalently associated beta and gamma chains is (are) still undefined. Using a cDNA library constructed from the mRNA of RBL cells, we have isolated a cDNA clone whose sequence predicts a putative 23-residue signal peptide, followed by a sequence that accurately predicts the amino acid composition, the peptide molecular weight, and six peptide sequences (encompassing 59 residues or 26% of the total number) determined for the alpha chain by direct analysis. These findings provide strong evidence that the cDNA codes for the alpha chain, even though expression has not been unambiguously achieved. The sequence suggests that the alpha chain contains a 180-residue extracellular portion with two homologous domains of approximately 35 residues, a 20-residue transmembrane segment containing an aspartic acid, and a 27-residue cytoplasmic portion containing 9 basic amino acids. The sequence shows no homology with the low-affinity receptor for IgE from lymphocytes but over 30% homology with an Fc gamma receptor.     

Distinct Stages of Stimulated FcεRI Receptor Clustering and Immobilization Are Identified through Superresolution Imaging

Recent advances in fluorescence localization microscopy have made it possible to image chemically fixed and living cells at 20 nm lateral resolution. We apply this methodology to simultaneously record receptor organization and dynamics on the ventral surface of live RBL-2H3 mast cells undergoing antigen-mediated signaling. Cross-linking of IgE bound to FcεRI by multivalent antigen initiates mast cell activation, which leads to inflammatory responses physiologically. We quantify receptor organization and dynamics as cells are stimulated at room temperature (22°C). Within 2 min of antigen addition, receptor diffusion coefficients decrease by an order of magnitude, and single-particle trajectories are confined. Within 5 min of antigen addition, receptors organize into clusters containing ∼100 receptors with average radii of ∼70 nm. By comparing simultaneous measurements of clustering and mobility, we determine that there are two distinct stages of receptor clustering. In the first stage, which precedes stimulated Ca²⁺ mobilization, receptors slow dramatically but are not tightly clustered. In the second stage, receptors are tightly packed and confined. We find that stimulation-dependent changes in both receptor clustering and mobility can be reversed by displacing multivalent antigen with monovalent ligands, and that these changes can be modulated through enrichment or reduction in cellular cholesterol levels.