Dynamics of signal transduction after aggregation of cell-surface receptors: studies on the type I receptor for IgE

A model of cell surface receptor aggregation

In this paper we construct and analyze a model of cell receptor aggregation. Experiments have shown that receptors in an aggregated state have greatly reduced mobility. We model the effects of this reduced mobility with a density dependent diffusion and study the impact of density dependent diffusion on aggregate formation in a one-dimensional domain. Critical values of receptor diffusivity and receptor activation are found and compared with numerical simulations. We find that the role of density dependant diffusion is quite limited in the formation of aggregate structures. In the case of receptor activation, the analytical results agree very well with the numerical calculations. Finally, we consider our model in higher dimensional domains. In this case our analysis is primarily numerical.

Fc Receptors and Fc Receptor-Like Molecules within the Immunoreceptor Family

Receptors for the Fc portion of immunoglobulins (FcRs) account for most cell-mediated biological activities of antibodies. The majority of FcRs are encoded by a set of genes, clustered in the fcr locus, on chromosome 1 in humans and on chromosome 1 and 3 in mice. Eight (in humans) and six (in mice) new genes were found, intermixed with FcR genes in corresponding fcr loci, which encode FcR-like molecules (FcRLs). FcRs and FcRLs are genetically, phylogenetically, structurally, and functionally related. FcRs and FcRLs, however, markedly differ by their ligands, their tissue distribution, and, therefore, by the biological functions they control. A systematic comparison of their biological properties leads to the conclusion that FcRLs are not like FcRs. They altogether form a single family within the immunoreceptor family, whose members fulfill distinct but complementary roles in immunity by differentially controlling innate and adaptive responses.

Fc Receptors in Immune Responses

Antibodies are major molecular effectors of adaptive immune responses. Most, if not all, biological activities of antibodies, however, depend on the functional properties of cells that express receptors for the Fc portion of antibodies (FcR). Most FcR are activating receptors; some are inhibitory. When engaged by antibodies and antigen, the various FcR expressed by a given cell trigger a mixture of positive and negative signals whose integration determines cellular responses. Responses of cell populations can be either protective or pathogenic. As a consequence, FcR are potential target/tools in a variety of diseases including infection, allergy, autoimmune diseases, and cancer.

Mast cells and company

Classically, allergy depends on IgE antibodies and on high-affinity IgE receptors expressed by mast cells and basophils. This long accepted IgE/FcεRI/mast cell paradigm, on which the definition of immediate hypersensitivity was based in the Gell and Coomb's classification, appears too reductionist. Recently accumulated evidence indeed requires that not only IgE but also IgG antibodies, that not only FcεRI but also FcγR of the different types, that not only mast cells and basophils but also neutrophils, monocytes, macrophages, eosinophils, and other myeloid cells be considered as important players in allergy. This view markedly changes our understanding of allergic diseases and, possibly, their treatment.

A detailed mathematical model predicts that serial engagement of IgE-Fc epsilon RI complexes can enhance Syk activation in mast cells

The term serial engagement was introduced to describe the ability of a single peptide, bound to a MHC molecule, to sequentially interact with TCRs within the contact region between a T cell and an APC. In addition to ligands on surfaces, soluble multivalent ligands can serially engage cell surface receptors with sites on the ligand, binding and dissociating from receptors many times before all ligand sites become free and the ligand leaves the surface. To evaluate the role of serial engagement in Syk activation, we use a detailed mathematical model of the initial signaling cascade that is triggered when FcepsilonRI is aggregated on mast cells by multivalent Ags. Although serial engagement is not required for mast cell signaling, it can influence the recruitment of Syk to the receptor and subsequent Syk phosphorylation. Simulating the response of mast cells to ligands that serially engage receptors at different rates shows that increasing the rate of serial engagement by increasing the rate of dissociation of the ligand-receptor bond decreases Syk phosphorylation. Increasing serial engagement by increasing the rate at which receptors are cross-linked (for example by increasing the forward rate constant for cross-linking or increasing the valence of the ligand) increases Syk phosphorylation. When serial engagement enhances Syk phosphorylation, it does so by partially reversing the effects of kinetic proofreading. Serial engagement rapidly returns receptors that have dissociated from aggregates to new aggregates before the receptors have fully returned to their basal state.

The SCHOOL of nature: I. Transmembrane signaling

Receptor-mediated transmembrane signaling plays an important role in health and disease. Recent significant advances in our understanding of the molecular mechanisms linking ligand binding to receptor activation revealed previously unrecognized striking similarities in the basic structural principles of function of numerous cell surface receptors. In this work, I demonstrate that the Signaling Chain Homooligomerization (SCHOOL)-based mechanism represents a general biological mechanism of transmembrane signal transduction mediated by a variety of functionally unrelated single- and multichain activating receptors. within the SCHOOL platform, ligand binding-induced receptor clustering is translated across the membrane into protein oligomerization in cytoplasmic milieu. This platform resolves a long-standing puzzle in transmembrane signal transduction and reveals the major driving forces coupling recognition and activation functions at the level of protein-protein interactions-biochemical processes that can be influenced and controlled. The basic principles of transmembrane signaling learned from the SCHOOL model can be used in different fields of immunology, virology, molecular and cell biology and others to describe, explain and predict various phenomena and processes mediated by a variety of functionally diverse and unrelated receptors. Beyond providing novel perspectives for fundamental research, the platform opens new avenues for drug discovery and development.

Kinetic proofreading model

Kinetic proofreading is an intrinsic property of the cell signaling process. It arises as a consequence of the multiple interactions that occur after a ligand triggers a receptor to initiate a ignaling cascade and it ensures that false signals do not propagate to completion. In order for an active signaling complex to form after a ligand binds to a cell surface receptor, a sequence of binding and phosphorylation events must occur that are rapidly reversed if the ligand dissociates from the receptor. This gives rise to a mechanism by which cells can discriminate among ligands that bind to the same receptor but form ligand-receptor complexes with different lifetimes. We review experiments designed to test for kinetic proofreading and models that exhibit kinetic proofreading.

Combinatorial complexity and dynamical restriction of network flows in signal transduction

The activities and interactions of proteins that govern the cellular response to a signal generate a multitude of protein phosphorylation states and heterogeneous protein complexes. Here, using a computational model that accounts for 307 molecular species implied by specified interactions of four proteins involved in signalling by the immunoreceptor FcepsilonRI, we determine the relative importance of molecular species that can be generated during signalling, chemical transitions among these species, and reaction paths that lead to activation of the protein tyrosine kinase (PTK) Syk. By all of these measures and over two- and ten-fold ranges of model parameters--rate constants and initial concentrations--only a small portion of the biochemical network is active. The spectrum of active complexes, however, can be shifted dramatically, even by a change in the concentration of a single protein, which suggests that the network can produce qualitatively different responses under different cellular conditions and in response to different inputs. Reduced models that reproduce predictions of the full model for a particular set of parameters lose their predictive capacity when parameters are varied over two-fold ranges.

Two regions of down-regulation in the IgE-mediated signaling pathway in human basophils

Previous studies demonstrated that after stimulation of human basophils with a polyclonal anti-IgE Ab, early signaling elements showed sustained phosphorylation, whereas later elements were transient, suggesting that a region of down-regulation involved inhibition of phosphatidylinositol (PI) 3 kinase or its products. However, the current studies show that under some conditions, syk phosphorylation is transient. Generally, stimulation with a variety of Ags makes this early form of down-regulation more apparent. An exploration of the conditions needed to induce early down-regulation indicates that both the nature of aggregation and the cell surface density of IgE play roles. It was also found that the previously described late form of down-regulation (PI3 kinase product transience) can occur in cells displaying early down-regulation (transient syk phosphorylation), but this phenomenon is revealed by testing for subsequent down-regulation of the response to non-cross-reacting stimuli, altering their ability to induce phosphorylation of Akt or extracellular signal-regulated kinase. In contrast, phosphorylation of syk kinase, in response to a non-cross-reacting stimulus, was relatively unaffected by prior stimulation. The magnitude of cross-desensitization of the Akt or extracellular signal-regulated kinase response was a function of the strength of the first stimulus. Mediator release showed a similar cross-desensitization effect. Therefore, stimulation induces two forms of down-regulation, one operating before or at the level of syk phosphorylation, possibly characterizing the process formerly known as specific desensitization, and one that operates in the region of PI3 kinase, accounting for the process formerly known as nonspecific desensitization, which is dependent on the strength of stimulus.

Environmentally relevant metal and transition metal ions enhance Fc epsilon RI-mediated mast cell activation

Upon contact with allergen, sensitized mast cells release highly active proinflammatory mediators. Allergen-mediated mast cell activation is an important mechanism in the pathogenesis of atopic asthma. Asthmatic patients are especially susceptible to air pollution. Epidemiologic studies found a positive correlation between severity of symptoms among asthmatic patients and the level of particulate matter (PM) in the air. Among the constituents of PM are metals and transition metals, which could mediate some of its adverse effects on human health. We sought to determine the effect of metal and transition metal ions on allergen-mediated mast cell activation. We observed that several metal and transition metal ions activated mast cells and enhanced allergen-mediated mast cell activation. Thus, Al(3+), Cd(2+), and Sr(2+) induced release of granule-associated N-acetyl-ss-d-hexosaminidase, and Al(3+) and Ni(2+) enhanced antigen-mediated release. Metal and transition metal ions also induced significant secretion of interleukin (IL)-4 and increased antigen-mediated IL-4 secretion in mast cells. These effects of metal and transition metal ions on mast cells were observed at concentrations that do not result in direct cytotoxicity and might be relevant for environmental exposure. Thus, metals and transition metals could increase the level of allergen-mediated mast cell activation, which might be one of the mechanisms mediating exacerbation of allergen-driven asthma symptoms by air pollution.

Investigation of early events in Fc epsilon RI-mediated signaling using a detailed mathematical model

Aggregation of Fc epsilon RI on mast cells and basophils leads to autophosphorylation and increased activity of the cytosolic protein tyrosine kinase Syk. We investigated the roles of the Src kinase Lyn, the immunoreceptor tyrosine-based activation motifs (ITAMs) on the beta and gamma subunits of Fc epsilon RI, and Syk itself in the activation of Syk. Our approach was to build a detailed mathematical model of reactions involving Fc epsilon RI, Lyn, Syk, and a bivalent ligand that aggregates Fc(epsilon)RI. We applied the model to experiments in which covalently cross-linked IgE dimers stimulate rat basophilic leukemia cells. The model makes it possible to test the consistency of mechanistic assumptions with data that alone provide limited mechanistic insight. For example, the model helps sort out mechanisms that jointly control dephosphorylation of receptor subunits. In addition, interpreted in the context of the model, experimentally observed differences between the beta- and gamma-chains with respect to levels of phosphorylation and rates of dephosphorylation indicate that most cellular Syk, but only a small fraction of Lyn, is available to interact with receptors. We also show that although the beta ITAM acts to amplify signaling in experimental systems where its role has been investigated, there are conditions under which the beta ITAM will act as an inhibitor.

Kinetic proofreading models for cell signaling predict ways to escape kinetic proofreading

In the context of cell signaling, kinetic proofreading was introduced to explain how cells can discriminate among ligands based on a kinetic parameter, the ligand-receptor dissociation rate constant. In the kinetic proofreading model of cell signaling, responses occur only when a bound receptor undergoes a complete series of modifications. If the ligand dissociates prematurely, the receptor returns to its basal state and signaling is frustrated. We extend the model to deal with systems where aggregation of receptors is essential to signal transduction, and present a version of the model for systems where signaling depends on an extrinsic kinase. We also investigate the kinetics of signaling molecules, "messengers," that are generated by aggregated receptors but do not remain associated with the receptor complex. We show that the extended model predicts modes of signaling that exhibit kinetic discrimination for some range of parameters but for other parameter values show little or no discrimination and thus escape kinetic proofreading. We compare model predictions with experimental data.

Detergent-resistant microdomains offer no refuge for proteins phosphorylated by the IgE receptor

When the high affinity receptor for IgE and related receptors become aggregated, they emigrate to specialized microdomains of the plasma membrane that are enriched in certain lipids and lipid-anchored proteins. Among the latter are the kinases that initiate signaling cascade(s) by phosphorylating the receptors. In studying the IgE receptor, we explored whether, in addition to their potential role in enhancing the initiation of signaling by the kinase(s), the microdomains might augment the stimulation by excluding phosphatases. In vitro assessment of phosphatase activity, using either a relevant or irrelevant substrate, suggested that the microdomains were deficient in phosphatase activity, but, in vivo, proteins confined to the microdomains were found to be no less vulnerable to dephosphorylation than those outside such domains. In the course of our experiments, we observed that the procedures routinely used to isolate the detergent-resistant domains dissociated the receptor for IgE, thereby artificially accentuating the observed preferential distribution of phosphorylated subunits in the microdomains.

One lyn molecule is sufficient to initiate phosphorylation of aggregated high-affinity IgE receptors

In response to antigenic stimuli, the multisubunit immune recognition receptors become aggregated and then phosphorylated on their cytoplasmic tyrosines. For the clonotypic receptors of B and T cells and for Fc receptors such as the high-affinity receptor for IgE (FcepsilonRI), a Src family kinase initiates this phosphorylation. We ask whether aggregation of the initiating kinase itself is required for signal transduction or whether, alternatively, a single associated kinase molecule can phosphorylate the receptors in an aggregate. We formulate the alternative molecular mechanisms mathematically and compare predictions with experimental findings on FcepsilonRI-bearing cells expressing varying amounts of the transfected Src family kinase Lyn. The data are consistent with the requirement of only a single Lyn molecule per FcepsilonRI aggregate to initiate signaling and are inconsistent with a mechanism requiring more than one Lyn molecule.

The dynamics of T cell receptor signaling: complex orchestration and the key roles of tempo and cooperation

T cells constantly sample their environment using receptors (TCR) that possess both a germline-encoded low affinity for major histocompatibility complex (MHC) molecules and a highly diverse set of CDR3 regions contributing to a range of affinities for specific peptides bound to these MHC molecules. The decision of a T cell "to sense and to respond" with proliferation and effector activity rather than "to sense, live on, but not respond" is dependent on TCR interaction with a low number of specific foreign peptide:MHC molecule complexes recognized simultaneously with abundant self peptide-containing complexes. Interaction with self-complexes alone, on the other hand, generates a signal for survival without a full activation response. Current models for how this distinction is achieved are largely based on translating differences in receptor affinity for foreign versus self ligands into intracellular signals that differ in quality, intensity, and/or duration. A variety of rate-dependent mechanisms involving assembly of molecular oligomers and enzymatic modification of proteins underlie this differential signaling. Recent advances have been made in measuring TCR:ligand interactions, in understanding the biochemical origin of distinct proximal and distal signaling events resulting from TCR binding to various ligands, and in appreciating the role of feedback pathways. This new information can be synthesized into a model of how self and foreign ligand recognition each evoke the proper responses from T cells, how these two classes of signaling events interact, and how pathologic responses may arise as a result of the underlying properties of the system. The principles of signal spreading and stochastic resonance incorporated into this model reveal a striking similarity in mechanisms of decision-making among T cells, neurons, and bacteria.

A quantitative approach to signal transduction

The high affinity receptor for IgE (FcepsilonRI), is one of a family of immunoreceptors whose antigen-induced clustering leads to a variety of cellular responses. The signaling pathways are enormously complex but by focusing on only the most initial steps, it is now possible to sketch plausible molecular models that relate the interaction of multivalent antigens with the receptor-bound IgE to the earliest cellular events. In this paper, we describe how we have combined quantitative experimentation and mathematical modeling to probe this system further. We also discuss some of the formidable challenges that remain before we can claim reasonably complete understanding of even these early events.

Parameters determining the stimulatory capacity of the type I Fc epsilon-receptor

Several experiments and theoretical considerations aimed at obtaining the parameters which determine the capacity of type I Fc epsilon-receptors to stimulate the secretion of mast cells are reviewed. Earlier studies have established that secretion requires Fc epsilon RI clustering at least two dimers. The roles of such clusters lifetimes and configuration requires a detailed and quantitative analysis of Fc epsilon RI clustering and stimulus secretion. Different approaches to these issues are described and discussed. We especially address the relevance of the general concept of kinetical proof reading (T.W. McKeithan, Proc. Natl. Acad. Sci. USA 92 (1995) 5042) which is based on the assumption that the stimulating receptors must stay in an active state sufficiently long to bridge the time interval between initiation and termination of cell activation. For mast cells which generally secrete upon clustering of type I Fc epsilon-receptors, this implies that effective stimulation requires a sufficiently long lifetime of such clusters. This notion is corroborated by results obtained from several experiments performed in the last 20 years which are briefly described and compared in this review.

An unusual mechanism for ligand antagonism

The ratio of late to early events stimulated by the mast cell receptor for immunoglobulin E (IgE) correlated with the affinity of a ligand for the receptor-bound IgE. Because excess receptors clustered by a weakly binding ligand could hoard a critical initiating kinase, they prevented the outnumbered clusters engendered by the high-affinity ligands from launching the more complete cascade. A similar mechanism could explain the antagonistic action of some peptides on the activation of T cells.

Characterization of protein-tyrosine phosphatases that dephosphorylate the high affinity IgE receptor

An early event that follows aggregation of the high affinity receptor for IgE (FcepsilonRI) is the phosphorylation of protein tyrosines, especially those on the beta- and gamma-subunits of the receptor. Disaggregation of the receptors leads to their rapid dephosphorylation, but even stably aggregated receptors undergo continual rounds of phosphorylation and dephosphorylation. We developed assays to study dephosphorylation of the receptors and other cellular proteins. Whole cell extracts dephosphorylated both subunits of the receptors rapidly and were as active against aggregated as against disaggregated FcepsilonRI. Upon disaggregation, the in vivo dephosphorylation of the FcepsilonRI and several other proteins followed first-order kinetics with closely similar rate constants despite substantial differences in the extent of phosphorylation. These results suggest that the level of phosphorylation of FcepsilonRI is largely controlled by the aggregation-induced action of kinase(s) and not from changes in susceptibility to or activity of the phosphatases. Much of the total phosphatase is lost when the cells are permeabilized, but the rate of dephosphorylation of disaggregated FcepsilonRI was comparable in intact and permeabilized cells. Thus, much of the activity utilized by the cell to dephosphorylate the FcepsilonRI is likely to be associated with the plasma membrane.

Biochemical evidence that the phosphorylated tyrosines, serines, and threonines on the aggregated high affinity receptor for IgE are in the immunoreceptor tyrosine-based activation motifs

Activation of cells mediated by the high affinity receptor for IgE leads to rapid phosphorylation of tyrosines (and later other residues) on the receptor's beta and gamma subunits, and there is circumstantial evidence that the tyrosines modified are in the so-called immunoreceptor tyrosine-based activation motifs (ITAMs). We identified and quantitated the residues phosphorylated on the subunits of the native receptor by comparing the properties of peptides derived from the receptors radiolabeled in vivo or in vitro with those of synthetic peptides. Our results with receptors labeled in vivo confirm that only the tyrosines in the ITAMs of beta and gamma became phosphorylated, and preferentially, those in the canonical YXX(L/I) sequences. The extent of phosphorylation of the canonical tyrosines was of the same order of magnitude, but the amino-terminal canonical tyrosine in the ITAM of the beta subunit was consistently phosphorylated to a lesser degree. The non-canonical ITAM tyrosine in the beta subunit was considerably less phosphorylated. Phosphorylation of serine (on beta) and threonine (on gamma) also occurred mainly in the ITAMs, but selectively at some positions whose characteristics seem to be conserved among other receptors containing ITAMs. The studies with receptor complexes isolated and radiolabeled in vitro gave similar results for phosphorylation of tyrosines, suggesting that the latter, much simpler system is a useful model for more detailed studies.

Shuttling of initiating kinase between discrete aggregates of the high affinity receptor for IgE regulates the cellular response

Using defined oligomers of IgE, our group previously studied the quantitative relationship between the aggregation of the high affinity receptors for IgE (Fc epsilonRI) and the earliest signals initiated by such aggregation: the phosphorylation of tyrosines on the receptor. Notably, at certain doses of the oligomers such phosphorylation reached a plateau level well before the aggregation of the receptors had reached a maximum. These findings and others led us to propose that aggregates of the receptor were competing for a limited amount of the critical kinase-thought to be Lyn in this system. This paper describes a test of this proposal. We incubated cells with two distinguishable IgEs and examined the effect of aggregating one or the other or both types on the phosphorylation. When receptors binding antigen-specific IgE were aggregated with polyvalent antigen, they became rapidly phosphorylated as expected. Remarkably, however, Fc epsilonRI that had already been phosphorylated by the binding of dimers of IgE, became dephosphorylated simultaneously. Furthermore, when the antigen-driven aggregates were dissociated with hapten, the phosphorylation pattern reverted to that seen prior to the addition of antigen: as the antigen-driven aggregates became dephosphorylated, the receptors stably aggregated by the bound oligomers became rapidly rephosphorylated. Dephosphorylation of oligomer-driven aggregates was also partially reversed during the "spontaneous" dephosphorylation of the antigen-driven receptors seen at longer times after addition of antigen. Thus signal transduction in this system is in part regulated by the shuttling of limited amounts of the kinase that initiates the cascade of phosphorylations.

Fc epsilon RI-mediated association of 6-micron beads with RBL-2H3 mast cells results in exclusion of signaling proteins from the forming phagosome and abrogation of normal downstream signaling

Cells of the mucosal mast cell line, RBL-2H3, are normally stimulated to degranulate after aggregation of high affinity receptors for IgE (Fc epsilon RI) by soluble cross-linking ligands. This cellular degranulation process requires sustained elevation of cytoplasmic Ca2+. In this study, we investigated the response of RBL-2H3 cells to 6-micron beads coated with IgE-specific ligands. These ligand-coated beads cause only small, transient Ca2+ responses, even though the same ligands added in soluble form cause larger, more sustained Ca2+ responses. The ligand-coated 6-micron beads also fail to stimulate significant degranulation of RBL-2H3 cells, whereas much larger ligand-coated Sepharose beads stimulate ample degranulation. Confocal fluorescence microscopy shows that the 6-micron beads (but not the Sepharose beads) are phagocytosed by RBL-2H3 cells and that, beginning with the initial stages of bead engulfment, there is exclusion of many plasma membrane components from the 6-micron bead/cell interface, including p53/56lyn and several other markers for detergent-resistant membrane domains, as well as an integrin and unliganded IgE-Fc epsilon RI. The fluorescent lipid probe DiIC16 is a marker for the membrane domains that is excluded from the cell/bead interface, whereas a structural analogue, fast DiI, which differs from DiIC16 by the presence of unsaturated acyl chains, is not substantially excluded from the interface. None of these components are excluded from the interface of RBL-2H3 cells and the large Sepharose beads. Additional confocal microscopy analysis indicates that microfilaments are involved in the exclusion of plasma membrane components from the cell/bead interface. These results suggest that initiation of phagocytosis diverts normal signaling pathways in a cytoskeleton-driven membrane clearance process that alters the physiological response of the cells.

Persistence of tyrosine-phosphorylated FcepsilonRI in deactivated cells

Engagement of the high affinity IgE receptor (FcepsilonRI) with a multimeric antigen leads to immediate tyrosine phosphorylation of its beta and gamma subunits, recruitment, and activation of the tyrosine kinase Syk, and later to cell degranulation. Monovalent hapten treatment reverses these events, resulting in receptor dephosphorylation and an abrupt arrest of cell degranulation. Thus far, it has been assumed that there is a direct linkage between receptor tyrosine phosphorylation, Syk activation and phosphorylation, and cell degranulation. However, we show here that when FcepsilonRI receptors are cross-linked for extended periods of time, hapten-mediated receptor dephosphorylation is delayed. These receptors, which remain tyrosine-phosphorylated despite the addition of hapten, are progressively targeted to a Triton X-100-insoluble fraction, suggesting their progressive association with the membrane skeleton. In contrast to FcepsilonRI receptors, hapten-induced Syk dephosphorylation and the consequent arrest of degranulation are not affected by prolonged cross-linking. Thus, some tyrosine-phosphorylated receptors persist in deactivated cells. We propose that, with time, some tyrosine-phosphorylated receptors become unaccessible to phosphatases and, in addition, unable to activate Syk. This inactive status of tyrosine-phosphorylated FcepsilonRI may be the result of membrane skeleton compartmentalization. However, another population of clustered receptors that includes the ones most recently formed is still immediately sensitive to hapten deactivation. This latter population is critical in maintaining Syk activity and cell degranulation. The shift from a transiently active state of phosphorylated receptors toward an inactive state could be a general mechanism of desensitization also utilized by other antigen receptors.

Intracluster restriction of Fc receptor gamma-chain tyrosine phosphorylation subverted by a protein-tyrosine phosphatase inhibitor

This study shows that aggregation of U937 cell high affinity IgG Fc receptor (Fc gamma RI) results in the transient tyrosine phosphorylation of Fc gamma RI gamma-chain but not the phosphorylation of gamma-chains associated with nonaggregated IgA Fc receptors (Fc alpha R) on the same cells. Thus, normally, tyrosine phosphorylation of gamma-chains is limited to FcR in aggregates. In contrast, aggregation of Fc gamma RI in the presence of vanadate induced the sustained tyrosine phosphorylation of Fc gamma RI gamma-chains and the rapid and extensive phosphorylation of nonaggregated Fc alpha R gamma-chains and low affinity IgG Fc receptors (Fc gamma RII). This global phosphorylation of motifs on nonaggregated FcR was also detected upon aggregation of Fc alpha R or Fc gamma RII, which induced the phosphorylation of nonaggregated Fc gamma RI gamma-chains. Vanadate prevented dephosphorylation of proteins and increased kinase activity in stimulated cells. Evidence failed to support alternative explanations such as acquisition of phospho-gamma through subunit exchange or a coalescence of nonaggregated with aggregated FcR. It is likely, therefore, that activated kinases interacted with nonaggregated FcR in stimulated cells. Pervanadate induced the tyrosine phosphorylation of gamma-chains in the absence of FcR cross-linking, indicating that the kinases could be activated by phosphatase inhibition and could react with nonaggregated substrates. We conclude that under normal conditions there is a vanadate-sensitive mechanism that prevents tyrosine phosphorylation of nonaggregated FcR gamma-chain motifs in activated cells, restricting their phosphorylation to aggregates.

Kinetics of tyrosine phosphorylation when IgE dimers bind to FC epsilon receptors on rat basophilic leukemia cells

Previously, we demonstrated that aggregates of the high affinity receptor for IgE (Fc epsilon RI), formed by the binding of chemically cross-linked oligomers of IgE, continue to signal early and late cellular responses long after the formation of new aggregates is blocked. In the present work, we explore quantitatively the relationship between aggregation of the receptors and one of the earliest biochemical changes this initiates. We compare the time course of aggregate formation, inferred from studies of the binding of dimers of IgE, and the time course of phosphorylation of tyrosines on receptor subunits when the receptors are aggregated. A simple model does not fit the data. It appears that aggregates formed late in the response are less effective signaling units than those formed initially. We propose new explanations for the persistence of the response and the unusual kinetics.

Structural hierarchy in the clustering of HLA class I molecules in the plasma membrane of human lymphoblastoid cells

Major histocompatibility complex (MHC) class I antigens in the plasma membranes of human T (HUT-102B2) and B (JY) lymphoma cells were probed by immunochemical reagents using fluorescence, transmission electron, and scanning force microscopies. Fluorescent labels were attached to monoclonal antibodies W6/32 or KE-2 directed against the heavy chain of HLA class I (A, B, C) and L368 or HB28 against the beta 2-microglobulin light chain. The topological distribution in the nanometer range was studied by photobleaching fluorescence resonance energy transfer (pbFRET) on single cells. A nonrandom codistribution pattern of MHC class I molecules was observed over distances of 2-10 nm. A second, nonrandom, and larger-scale topological organization of the MHC class I antigens was detected by indirect immunogold labeling and imaging by transmission electron microscopy (TEM) and scanning force microscopy (SFM). Although some differences in antigen distribution between the B- and T-cell lines were detected by pbFRET, both cell lines exhibited similar clustering patterns by TEM and SFM. Such defined molecular distributions on the surfaces of cells of the immune system may reflect an underlying specialization of membrane lipid domains and fulfill important functional roles in cell-cell contacts and signal transduction.

Aggregation of the high-affinity IgE receptor and enhanced activity of p53/56lyn protein-tyrosine kinase

Aggregation of the receptor with high affinity for IgE (Fc epsilon RI) on the surface of mast cells and basophils stimulates phosphorylation of protein tyrosines, a process in which p53/56lyn kinase has been implicated. We measured the association between Fc epsilon RI and the kinase, using chemical crosslinking to stabilize their interaction. In the rat basophilic leukemia mast cell line, 3-4%, and at most 20%, of Fc epsilon RI appear to be associated with the kinase prior to aggregation, even though there is an excess of total cell lyn kinase. Aggregating the Fc epsilon RI causes three to four times more of the kinase to associate with receptors, a process requiring a prior phosphorylation step. In an in vitro assay, the lyn associated with the aggregated receptors becomes disproportionately more phosphorylated than would be predicted from the amount of lyn associated with the receptors. These and other data are consistent with a model in which aggregation of the receptor leads to its transphosphorylation by constitutively associated lyn kinase. We propose that additional molecules of this kinase are thereby recruited and that this markedly enhances transphosphorylation of tyrosine on the receptor and associated proteins, thereby initiating a cascade of further biochemical changes. This model is also consistent with data on receptors such as the clonotypic receptors on B and T lymphocytes, which share structural and functional features with Fc epsilon RI.

Transphosphorylation as the mechanism by which the high-affinity receptor for IgE is phosphorylated upon aggregation

When aggregated, the high-affinity receptors for IgE on mast cells (Fc epsilon RI) launch a series of phosphorylations, particularly of protein tyrosines. We have analyzed how aggregation initiates this cascade. We examined Fc epsilon RI from unstimulated cells and from cells exposed to a polyvalent hapten conjugate that aggregates the Fc epsilon RI via the receptor-bound anti-hapten IgE. We also examined the latter receptors after they had been disaggregated in vitro with monovalent hapten. By an in vitro kinase assay: (i) Unaggregated and disaggregated receptors are associated with a kinase that phosphorylates an exogenous (peptide) substrate but minimally, or not at all, the subunits of Fc epsilon RI or associated proteins (endogenous substrates). After aggregation, phosphorylation of the exogenous substrate is linear with time, but the modification of the endogenous substrates reaches a plateau, presumably because only those endogenous substrates that are adjacent to the kinase are phosphorylated. (ii) Aggregated receptors and disaggregated receptors have enhanced kinase activity toward exogenous substrate. The state of phosphorylation of the receptor correlates strongly with the yield of enhanced kinase activity. We propose that upon aggregation of Fc epsilon RI, a constitutively associated kinase phosphorylates endogenous substrates by transphosphorylation. As a result, additional kinase activity becomes manifest and this promotes further transphosphorylation. In view of the homology between Fc epsilon RI and other receptors central to the immune response, the latter receptors likely utilize a similar transphosphorylation mechanism.