MHC class II signaling in antigen-presenting cells

The MHC class II molecules have been recognized as signaling receptors for more than a decade, and recent work has revealed the importance of their signaling for the immune response. Today, we know that the function of MHC class II molecules on antigen-presenting cells (APCs) is not limited to their role as antigen-presenting structures; they are flexible receptors that, by triggering a variety of signaling pathways, can regulate APC activities from proliferation and maturation to apoptosis. Recent advances have provided insights into how these molecules might accommodate such regulation.

Analysis of lipid rafts in T cells

The plasma membrane of T cells is made of a combination of glycosphingolipids and protein receptors organized in glycolipoprotein microdomains termed lipid rafts. The structural assembly of lipid rafts was investigated by various physical and biochemical assays. Depending on the differentiation status of T cells, the lipid rafts seclude various protein receptors involved in T cell signaling, cytoskeleton reorganization, membrane trafficking, and the entry of infectious organisms into the cells. This review article summarizes the most common methods, and their limits and advantages for analyzing the composition and assembly of lipid rafts with protein receptors into lipid rafts microdomains in plasma membrane of T cells. It also includes new methods such as ELISA/Polysorp and flow cytometry, and a combined sucrose gradient centrifugation-FPLC-Western blot strategy developed in our laboratory to study non-covalent interactions between the GM1 glycosphingolipid and protein receptors in plasma membrane of T cells.

Signal transduction and functional changes in neutrophils with aging

It is well known that the immune response decreases during aging, leading to a higher susceptibility to infections, cancers and autoimmune disorders. Most widely studied have been alterations in the adaptive immune response. Recently, the role of the innate immune response as a first-line defence against bacterial invasion and as a modulator of the adaptive immune response has become more widely recognized. One of the most important cell components of the innate response is neutrophils and it is therefore important to elucidate their function during aging. With aging there is an alteration of the receptor-driven functions of human neutrophils, such as superoxide anion production, chemotaxis and apoptosis. One of the alterations underlying these functional changes is a decrease in signalling elicited by specific receptors. Alterations were also found in the neutrophil membrane lipid rafts. These alterations in neutrophil functions and signal transduction that occur during aging might contribute to the significant increase in infections in old age.

Cutting edge: optical microspectrophotometry supports the existence of gel phase lipid rafts at the lamellipodium of neutrophils: apparent role in calcium signaling

Although much progress has been made in elucidating the biochemical properties of lipid rafts, there has been less success in identifying these structures within living cell membranes, which has led to some concern regarding their existence. One difficulty in analyzing lipid rafts using optical microscopy is their small size. We now test the existence of lipid rafts in polarized neutrophils, which redistribute lipid raft markers into comparatively large lamellipodia. Optical microspectrophotometry of Laurdan-labeled neutrophils revealed a large blue shift at lamellipodia relative to cell bodies. This blue shift disappeared after exposure to methyl-beta-cyclodextrin (m beta CD), which disrupts lipid rafts. The Ca(2+) channel transient receptor potential-like channel-1, a lipid raft marker, traffics to lamellipodia, but redistributes uniformly about cells after exposure to m beta CD. This is accompanied by disruption of Ca(2+) waves normally initiated at lamellipodia. Thus, m beta CD-sensitive lipid-ordered domains are present at and participate in signaling from the lamellipodia of living neutrophils.

Combinational clustering of receptors following stimulation by bacterial products determines lipopolysaccharide responses

The innate immune system has the capacity to recognize a wide range of pathogens based on conserved PAMPs (pathogen-associated molecular patterns). In the case of bacterial LPS (lipopolysaccharide) recognition, the best studied PAMP, it has been shown that the innate immune system employs at least three cell-surface receptors: CD14, TLR4 (Toll-like receptor 4) and MD-2 protein. CD14 binds LPS from Enterobacteriaceae and then transfers it to MD-2, leading to TLR4 aggregation and signal transduction. LPS analogues such as lipid IVa seem to act as LPS antagonists in human cells, but exhibit LPS mimetic activity in mouse cells. Although TLR4 has been shown to be involved in this species-specific discrimination, the mechanism by which this is achieved has not been elucidated. The questions that remain are how the innate immune system can discriminate between LPS from different bacteria as well as different LPS analogues, and whether or not the structure of LPS affects its interaction with the CD14-TLR4-MD-2 cluster. Is it possible that the 'shape' of LPS induces the formation of different receptor clusters, and thus a different immune response? In the present study, we demonstrate using biochemical as well as fluorescence-imaging techniques that different LPS analogues trigger the recruitment of different receptors within microdomains. The composition of each receptor cluster as well as the number of TLR4 molecules that are recruited within the cluster seem to determine whether an immune response will be induced or inhibited.

Exclusion of lipid rafts and decreased mobility of CD94/NKG2A receptors at the inhibitory NK cell synapse

CD94/NKG2A is an inhibitory receptor expressed by most human natural killer (NK) cells and a subset of T cells that recognizes human leukocyte antigen E (HLA-E) on potential target cells. To elucidate the cell surface dynamics of CD94/NKG2A receptors, we have expressed CD94/NKG2A-EGFP receptors in the rat basophilic leukemia (RBL) cell line. Photobleaching experiments revealed that CD94/NKG2A-EGFP receptors move freely within the plasma membrane and accumulate at the site of contact with ligand. The enriched CD94/NKG2A-EGFP is markedly less mobile than the nonligated receptor. We observed that not only are lipid rafts not required for receptor polarization, they are excluded from the site of receptor contact with the ligand. Furthermore, the lipid raft patches normally observed at the sites where FcepsilonR1 activation receptors are cross-linked were not observed when CD94/NKG2A was coengaged along with the activation receptor. These results suggest that immobilization of the CD94/NKG2A receptors at ligation sites not only promote sustenance of the inhibitory signal, but by lipid rafts exclusion prevent formation of activation signaling complexes.

Effects of HMG-CoA reductase inhibitors on endothelial function: role of microdomains and oxidative stress

Certain pleiotropic activities reported for 3-hydroxy-3-methylglutaryl coenzyme A (HMG-CoA) reductase inhibitors (statins) are related to reductions in cellular cholesterol biosynthesis and isoprenoid levels. In endothelial cells, these metabolic changes contribute to favorable effects on nitric oxide (NO) bioavailability. Given the essential role of NO in preserving vascular structure and function, this effect of statins is of considerable therapeutic importance. Statins have been demonstrated to restore endothelial NO production by several mechanisms, including upregulating endothelial NO synthase (eNOS) protein expression and blocking formation of reactive oxygen species. In this article, we will discuss additional ways in which statins restore endothelial NO production and improve endothelial function. (1) Statins modulate membrane microdomain formation, resulting in reduced expression of proteins that specifically inhibit eNOS activation. (2) Statins reduce sterol biosynthesis, thus interfering with the formation of pathologic microdomains, including cholesterol crystalline structures. This observation has important implications for plaque stabilization, as these microdomains contribute to cholesterol crystal formation and endothelial apoptosis. Finally, (3) statins improve endothelial function by interfering with oxidative stress pathways through both enzymatic and nonenzymatic mechanisms. The relationships between membrane microdomains, cholesterol biosynthesis, and endothelial function will be discussed.

Sigma-2 receptors are specifically localized to lipid rafts in rat liver membranes

We have previously shown that sigma-2 receptors are relatively difficult to solubilize (Eur. J. Pharmacol. 304 (1996) 201), suggesting possible localization in detergent-resistant lipid raft domains. Rat liver membranes were treated on ice with 1% Triton X-100 or 20 mM 3-[(3-cholamidopropyl)dimethylammonio]-1-propanesulfonate (CHAPS), and the extract subjected to centrifugation on a discontinuous gradient of 5%, 38%, and 40% sucrose. Gradient fractions were analyzed for sigma-1 receptors using [3H]+-pentazocine and for sigma-2 receptors using [3H]1,3-di-o-tolylguanidine ([3H]DTG), in the presence of dextrallorphan. Flotillin-2 was assessed by immunoblotting as a marker for lipid rafts. Sigma-2 receptors were found to discretely co-localize with flotillin-2 in lipid raft fractions. However, sigma-1 receptors were found throughout the gradient. Rafts prepared in CHAPS had sigma-2 receptors with normal pharmacological characteristics, whereas those in Triton X-100-prepared rafts had about seven-fold lower affinity for [3H]DTG and other ligands. Thus, sigma-2 receptors are resident in membrane lipid rafts, whereas sigma-1 receptors appear in both raft and non-raft membrane domains. Lipid rafts may play an important role in the mechanism of sigma-2 receptor-induced apoptosis.

High avidity CD8+ T cells generated from CD28-deficient or wildtype mice exhibit a differential dependence on lipid raft integrity for activation

CD28 has been shown to play an important role in T cell activation. Among the downstream events associated with CD28 engagement is the reorganization of the cytoskeleton resulting in lipid raft aggregation. In our previous studies we investigated the involvement of lipid rafts in the activation of high avidity CD8+ T lymphocytes, which recognize cells bearing very low levels of peptide antigen, versus low avidity cells, which require high levels of peptide antigen. In these studies we found that high avidity cells were much more sensitive to lipid raft disruption compared to low avidity cells. Given the important role for CD28 in lipid raft reorganization and our previous finding that high avidity cells are extremely dependent on lipid raft integrity, we hypothesized that high avidity cells could not be generated in the absence of CD28. Surprisingly, we have found that the absence of CD28 does not alter the ability to generate high or low avidity CD8+ T cells. In fact high and low avidity lines generated in parallel from CD28-deficient and WT mice exhibited very similar requirements for peptide antigen. We next compared the effect of lipid raft disruption on the activation of high versus low avidity cells from CD28-deficient and WT mice. While high avidity cells generated from WT mice exhibited the expected dependence on lipid raft integrity, high avidity cells from CD28-deficient mice were not affected. These data suggest that the lines generated from the CD28-deficient mice have developed alternative strategies to promote high sensitivity to peptide antigen.

Caspase-3 is a component of Fas death-inducing signaling complex in lipid rafts and its activity is required for complete caspase-8 activation during Fas-mediated cell death

Since its discovery, caspase-8 has been placed at the apex of the proteolytic cascade triggered by death receptor (DR) cross-linking. Because of its capacity to interact with the cytoplasmic portion of DR, it has been suggested that caspase-8 acts independently of other caspases in the initiation of Fas and other DR signaling. In this study, we demonstrate that in Jurkat cells, caspase-3 cleavage is an early step during Fas-induced apoptosis. We show that caspase-3 processing into its p20 occurs rapidly after Fas cross-linking, in the absence of mitochondrial depolarization and caspase-9 activation. Moreover, caspase-3 is present in lipid rafts of untreated Jurkat cells and peripheral T lymphocytes. Caspase-3, caspase-8, and Fas-associated death domain are further recruited to lipid rafts of Jurkat cells following anti-Fas treatment. Fas immunoprecipitation reveals that caspase-3 is a component of the death-inducing signaling complex, suggesting that this cysteine protease is in close proximity to caspase-8. Furthermore, transduction of Jurkat cells with a caspase-3 dominant-negative form inhibits caspase-8 processing and results in inhibition of apoptosis, suggesting that caspase-3 activity is required for caspase-8 activation. Overall, these findings support a model whereby caspase-3 is a component of the death-inducing signaling complex located in lipid rafts, and as such, is involved in the amplification of caspase-8 activity by the mitochondrion.

Lipid rafts and apical membrane traffic

Lipid rafts are dynamic assemblies floating freely in the surrounding membranes of living cells. This membrane heterogeneity provides a useful concept for understanding processes as diverse as cell polarity, signal transduction, and membrane sorting. Individual rafts are small entities containing thousands of lipids but only a few proteins. Regulation of raft association and size is an elementary feature of interactions at the molecular level. By clustering small rafts into a bigger platform, proteins are brought together for modification. Oligomerization might transform a monomeric weakly raft-associated protein into an assembly with higher raft affinity. Lectins are multivalent glycoprotein-binding proteins and are likely to be key players in mediating the clustering of rafts in vivo. Glycosylation-dependent surface delivery in a polarized fashion is a feature conserved across evolution, and we expect lectins to be at the heart of the molecular machinery responsible for lipid raft delivery to the cell surface. Currently, we are evaluating candidate proteins by affinity chromatography, proteomics, and RNA interference.

Caveolae and Caveolins in the Cardiovascular System

Caveolae and the caveolae coat proteins, caveolins, are putatively implicated in many cellular processes, including transcytosis of macromolecules, cholesterol transport, and signal transduction. Recent insights into the physiological and pathophysiological roles of these organelles and the caveolins from genetically modified mice suggest that they may be profoundly important for postnatal cardiovascular function, including endothelial barrier function, regulation of nitric oxide synthesis, cholesterol metabolism, and cardiac function.

Differential Regulation of TNF-R1 Signaling: Lipid Raft Dependency of p42mapk/erk2 Activation, but Not NF-κB Activation

The TNFR, TNF-R1, is localized to lipid raft and nonraft regions of the plasma membrane. Ligand binding sets in motion signaling cascades that promote the activation of p42(mapk/erk2) and NF-kappaB. However, the role of receptor localization in the activation of downstream signaling events is poorly understood. In this study, we investigated the dynamics of TNF-R1 localization to lipid rafts and the consequences of raft localization on the activation of p42(mapk/erk2) and NF-kappaB in primary cultures of mouse macrophages. Using sucrose density gradient ultracentrifugation and a sensitive ELISA to detect TNF-R1, we show that TNF-R1 is rapidly and transiently recruited to lipid rafts in response to TNF-alpha. Disruption of lipid rafts by cholesterol depletion prevented the TNF-alpha-dependent recruitment of TNF-R1 to lipid rafts and inhibited the activation of p42(mapk/erk2), while the activation of NF-kappaB was unaffected. In addition, phosphorylated p42(mapk/erk2), but not receptor interacting protein, I-kappaB kinase-gamma, or I-kappaBalpha was detected in raft-containing fractions following TNF-alpha stimulation. These findings suggest that TNF-R1 is localized to both lipid raft and nonraft regions of the plasma membrane and that each compartment is capable of initiating different signaling responses. We propose that segregation of TNF-R1 to raft and nonraft regions of the plasma membrane contributes to the diversity of signaling responses initiated by TNF-R1.

Integrin signaling and lipid rafts

Integrin-mediated adhesion regulates the recruitment of the small GTPase Rac to the plasma membrane and subsequent activation of downstream signaling. We recently reported that Rac binds preferentially to cholesterol-rich membranes ("lipid rafts"), and integrins regulate Rac function by preventing the internalization of its binding sites within these domains. Regulation of lipid rafts by integrins may be important for the spatial control of cell migration and signaling pathways involved in anchorage-dependent cell growth.

Ceramide, membrane rafts and infections

Distinct domains in the cell membrane, termed rafts, emerge as central for the infection of mammalian cells by many pathogens. Rafts consist of sphingolipids and cholesterol that interact strongly, and thus spontaneously separate from other phospholipids in the cell membrane. Recent studies suggest that at least some pathogens activate the acid sphingomyelinase that releases ceramide in membrane rafts. The generation of ceramide transforms small rafts into a signaling unit and results in the fusion of small rafts to large platforms. Membrane rafts and ceramide-enriched membrane platforms have been shown to mediate internalization of bacteria, viruses and parasites into the host cell, to initiate apoptosis of the host cell upon infection and to regulate the release of cytokines from infected mammalian cells. Furthermore, rafts and ceramide have been implicated in the intracellular trafficking of phagosomes and in the budding of viruses from infected cells. The molecular function of rafts and ceramide-enriched membrane platforms seems to be the re-organization of receptor and intracellular signaling molecules in the cell membrane permitting the interaction of the pathogen with the cell. This suggests that rafts and ceramide-enriched membrane platforms function as central structures involved in the infection of mammalian cells by pathogens and as targets for the development of anti-infective drugs.

A role for lipid rafts in C1q-triggered O2$minus; generation by human neutrophils

Calreticulin, a candidate C1q receptor, was shown recently to be present on the surface of human neutrophils in association with glycosylphosphatidylinositol (GPI) anchored proteins, particularly CD59. In this study, we show that antibodies to CD59, as well as to every other GPI-anchored protein tested, inhibited the C1q-triggered release of O(2)(-) from PMN. Methyl beta cyclodextrin (M beta CD) treatment of the cells to disrupt lipid rafts also prevented C1q-triggered O(2)(-) production. beta(2) integrin-dependent co-stimulation is required for O(2)(-) production from PMN, however M beta CD had no effect on LFA-1 or Mac-1-mediated adhesion, soluble iC3b binding to PMN, or spreading and migration, all of which suggested that PMN integrin function remained intact. Flow cytometric analysis of PMN treated with M beta CD showed upregulation of PMN granule-associated integrins and a corresponding increase in integrin activation-reporter epitopes, in contrast to the decreased expression of GPI-anchored antigens. These data support a model where lipid rafts and their associated GPI-anchored proteins are critical for C1q-triggered O(2)(-) production, consistent with a model where calreticulin serves as the C1q receptor for O(2)(-) production from PMN.

Impact of cholesterol depletion on shape changes, actin reorganization, and signal transduction in neutrophil-like HL-60 cells

Stimulation of neutrophils with chemotactic peptide induces actin reorganization, formation of actin-rich protrusions, and development of polarity. Shape changes and actin polymerization can also be induced by phorbol ester-mediated direct activation of protein kinase C (PKC). We have investigated the role of cholesterol in stimulus-dependent motile events and in activation of signaling pathways in neutrophil-like differentiated HL-60 cells. Depletion of plasma membrane cholesterol using methyl-beta-cyclodextrin (MbetaCD) prevented chemotactic peptide and phorbol ester-induced shape changes and increases in cytoskeletal actin. Cholesterol depletion almost completely suppressed chemotactic peptide-mediated activation of p42/44 mitogen-activated protein kinase (MAPK). Phosphorylation of protein kinase B on Thr-308, which is indicative of activation of phosphatidylinositol 3-kinase, was in contrast only partially inhibited. Stimulus-mediated membrane recruitment of different PKC isoforms was differentially affected by treatment of cells with MbetaCD. Membrane recruitment of PKCalpha induced by chemotactic peptide or phorbol ester was suppressed, whereas that of PKCbetaII was only partially affected. Membrane association of PKCdelta was almost insensitive to cholesterol depletion. In summary, our results implicate an important role of cholesterol-containing lipid microdomains (rafts) especially in chemotactic peptide-induced activation of MAPK pathways and in chemotactic peptide- and phorbol ester-mediated activation of PKCalpha.

Lipid rafts mediate chemotropic guidance of nerve growth cones

Axon guidance requires signal transduction of extracellular cues through the plasma membrane for directional motility. Here we present evidence that cholesterol- and sphingolipid-enriched membrane microdomains (lipid rafts) mediate specific guidance responses of nerve growth cones. Disruption of lipid rafts by various approaches targeting cholesterol or gangliosides selectively abolished growth cone attraction and repulsion in BDNF and netrin-1 gradients, respectively, without affecting glutamate-induced attraction. Interestingly, local raft disruption on one side of the growth cone in bath BDNF or netrin-1 produced opposite turning responses to that induced by the gradients. Raft manipulation also blocked Semaphorin 3A-induced growth cone repulsion, inhibition, and collapse. Finally, guidance responses appeared to involve raft-dependent activation of p42/p44 MAPK and ligand-induced receptor recruitment to lipid rafts. Together with the observation of asymmetric receptor-raft associations at the growth cone in guidance gradients, our findings indicate that localized signaling through membrane rafts plays a role in mediating guidance actions of extracellular cues on developing axons.

Dissection of the mammalian midbody proteome reveals conserved cytokinesis mechanisms

Cytokinesis is the essential process that partitions cellular contents into daughter cells. To identify and characterize cytokinesis proteins rapidly, we used a functional proteomic and comparative genomic strategy. Midbodies were isolated from mammalian cells, proteins were identified by multidimensional protein identification technology (MudPIT), and protein function was assessed in Caenorhabditis elegans. Of 172 homologs disrupted by RNA interference, 58% displayed defects in cleavage furrow formation or completion, or germline cytokinesis. Functional dissection of the midbody demonstrated the importance of lipid rafts and vesicle trafficking pathways in cytokinesis, and the utilization of common membrane cytoskeletal components in diverse morphogenetic events in the cleavage furrow, the germline, and neurons.

Lipid rafts as organizing platforms for cell chemotaxis and axon guidance

Lipid rafts are thought to serve as plasma membrane platforms for localized trafficking and signaling. Recent findings reported by Guirland et al. in this issue of Neuron and by Gómez-Moutón in a recent issue of JCB support a direct role of lipid microdomains in organizing spatial signaling during axon guidance and cell chemotaxis by concentrating the gradient-sensing machinery at the leading edge.

Activation of mast cells by incorporation of cholesterol into rafts

IgE plus antigen-stimulated mast cells degranulate, synthesize leukotrienes and secrete cytokines. According to the coalescence model this process is initiated in specific membrane compartments termed rafts. There, enhanced levels of glycosphingolipids and cholesterol stabilize the interaction of FcepsilonRI and Lyn, and thus facilitate the first steps of signal transduction. Enforced changes in raft architecture by cholesterol deprivation and exogenous application of glycosphingolipids influence these early events by loss of tyrosine kinase activity or receptor-independent signal initiation respectively. Here we show that exogenously added cholesterol accumulates in rafts and activates mast cells. An investigation of the signaling events reveals that in contrast to IgE plus antigen-mediated stimulation, cholesterol triggers p38 mitogen-activated protein kinase and preferentially induces expression of FosB. Consequently, a comparative large-scale microarray analysis demonstrates that a number of IgE plus antigen-induced immediate early genes (peak expression at 30 min after induction) are repressed by cholesterol. These changes further translate into altered expression levels and time kinetics of a number of early genes (peak expression at 2 h after stimulation). As the most prominent example for cholesterol-dependent genes, we identified PAI1 (plasminogen activator inhibitor 1), a protein regarded as a risk factor for atherosclerosis.

Methyl-beta-cyclodextrin stimulates glucose uptake in Clone 9 cells: a possible role for lipid rafts

An acute increase in the Vmax for glucose uptake occurs in many mammalian cell types after exposure to osmotic or metabolic stress. In the rat epithelial Clone 9 cell line, the glucose transporter isoform GLUT1 is responsible for this enhanced uptake. Although stimulation of transport in these cells is known to result from the unmasking of 'cryptic' exofacial permeant-binding sites in GLUT1 molecules resident in the plasma membrane, the mechanism of such unmasking remains unclear. One possibility involves changes in the lipid environment of the transporter: reconstitution experiments have shown that transport activity in vitro is acutely sensitive to the phospholipid and cholesterol composition of the membrane. In the current study we found that treatment of Clone 9 cells with methyl-beta-cyclodextrin, which removed >80% of the cell cholesterol, led to a 3.5-fold increase in the Vmax for 3-O-methyl-D-glucose transport while having little effect on the Km. In contrast to the metabolic stress induced by inhibition of oxidative phosphorylation, cholesterol depletion led neither to depletion of cellular ATP nor stimulation of AMP-activated protein kinase. Similarly, it did not result in stimulation of members of the stress- and mitogen-activated protein kinase families. In unstressed, cholesterol-replete cells, a substantial proportion of GLUT1 in detergent lysates co-fractionated with the lipid-raft proteins caveolin and stomatin on density-gradient centrifugation. Immunocytochemistry also revealed the presence of GLUT1-enriched domains, some of which co-localized with stomatin, in the plasma membrane. Both techniques revealed that the abundance of such putative GLUT1-containing domains was decreased not only by cholesterol depletion but also in cells subjected to metabolic stress. Taken together, these data suggest that a change in the lipid environment of GLUT1, possibly associated with its re-distribution between different microdomains of the plasma membrane, could play a role in its activation in response to stress.

Lipid rafts: feeling is believing

In the late 1990s, accumulated evidence led to the proposal that biological membranes are composed of microdomains of different lipids, which form functional "rafts." Recent work using atomic force microscopy has given us new insights into the factors influencing the formation and behavior of these physiological microenvironments

A hypothesis to explain division site selection in Escherichia coli by combining nucleoid occlusion and Min

The positioning of the site of cell division in Escherichia coli results, it is generally believed, from the operation of nucleoid occlusion in combination with the Min system. Nucleoid occlusion prevents division over the nucleoids and directs it by default to the mid-cell region between segregating nucleoids or to polar regions while the Min system prevents division in polar regions. Unresolved questions include how these systems interact to control the earliest known event in division, the assembly at the membrane of the tubulin-like protein, FtsZ, and, more importantly, what exactly constitutes a division site. Evidence exists that (1) the coupled transcription, translation and insertion of proteins into membrane (transertion), can structure the cytoplasmic membrane into phospholipid domains, (2) the MinD protein can convert vesicles into tubes and (3) a variety of membranous structures can be observed at mid-cell. These data support a model in which transertion from the segregating daughter chromosomes leads to the formation of a distinct proteolipid domain between them at mid-cell; the composition of this domain allows phospholipid tubes to extend like fingers into the cytoplasm; these tubes then become the substrate for the dynamic assembly and disassembly of FtsZ which converts them into the invaginating fold responsible for division; the Min system inhibits division at unwanted sites and times by removing these tubes especially at the cell poles.

How viruses enter animal cells

Viruses replicate within living cells and use the cellular machinery for the synthesis of their genome and other components. To gain access, they have evolved a variety of elegant mechanisms to deliver their genes and accessory proteins into the host cell. Many animal viruses take advantage of endocytic pathways and rely on the cell to guide them through a complex entry and uncoating program. In the dialogue between the cell and the intruder, the cell provides critical cues that allow the virus to undergo molecular transformations that lead to successful internalization, intra-cellular transport, and uncoating.

Rafts and related glycosphingolipid-enriched microdomains in the intestinal epithelium: bacterial targets linked to nutrient absorption

Plasma membrane microdomains such as lipid rafts or caveolae play a major role in host-pathogen interactions. Although this field of research has been extensively studied, two important points have been poorly addressed: (i) the molecular basis of raft-pathogen interactions, and (ii) the effect of such interactions on nutrient absorption. The aim of this review was to propose a biochemical analysis of bacterial adhesion to lipid raft components exposed on the mucosal surface of the intestinal epithelium. A special attention has been given to CH-pi interactions that allow the sugar rings of glycosphingolipids (GSL) to stack against aromatic side chains of bacterial adhesins and toxins. These interactions are controlled by cholesterol molecules intercalated between membrane GSL and/or by the presence of an alpha-OH group in the acyl chain of the ceramide backbone of GSL. In the second part of the review, we analysed the experimental data suggesting the involvement of lipid rafts in the intestinal absorption of nutrients, the mechanisms by which bacteria could impair intestinal functions, and possible therapeutic strategies based on the biochemistry of raft-pathogen interactions.

CD44 interaction with ankyrin and IP3 receptor in lipid rafts promotes hyaluronan-mediated Ca2+ signaling leading to nitric oxide production and endothelial cell adhesion and proliferation

In this study, we have showed that aortic endothelial cells (GM7372A cell line) express CD44v10 [a hyaluronan (HA) receptor], which is significantly enriched in cholesterol-containing lipid rafts (characterized as caveolin-rich plasma membrane microdomains). HA binding to CD44v10 promotes recruitment of the cytoskeletal protein, ankyrin and inositol 1,4,5-triphosphate (IP3) receptor into cholesterol-containing lipid rafts. The ankyrin repeat domain (ARD) of ankyrin is responsible for binding IP3 receptor to CD44v10 at lipid rafts and subsequently triggering HA/CD44v10-mediated intracellular calcium (Ca2+) mobilization leading to a variety of endothelial cell functions such as nitric oxide (NO) production, cell adhesion and proliferation. Further analyses indicate (i) disruption of lipid rafts by depleting cholesterol from the membranes of GM7372A cells (using methyl-beta-cyclodextrin treatment) or (ii) interference of endogenous ankyrin binding to CD44 and IP3 receptor using overexpression of ARD fragments (by transfecting cells with ARDcDNA) not only abolishes ankyrin/IP3 receptor accumulation into CD44v10/cholesterol-containing lipid rafts, but also blocks HA-mediated Ca2+ signaling and endothelial cell functions. Taken together, our findings suggest that CD44v10 interaction with ankyrin and IP3 receptor in cholesterol-containing lipid rafts plays an important role in regulating HA-mediated Ca2+ signaling and endothelial cell functions such as NO production, cell adhesion and proliferation.

Ion channels and membrane rafts in apoptosis

Ion channels have been demonstrated to be a central element in the induction and the execution of apoptosis. In particular, mitochondrial ion channels, including not only the permeability transition pore but also a mitochondrial, ATP-sensitive (mKATP) channel as well as a mitochondrial calcium-activated potassium channel are involved critically in apoptotic changes in mitochondria. Ion channels in the cell membrane that are altered by induction of apoptosis include potassium, chloride and calcium channels. The Kv1.3 potassium channel belongs to the best-characterized ion channels involved in apoptosis and a genetic model of cells deficient for Kv1.3 has indicated a critical role for Kv1.3, at least in some forms of apoptosis. The mechanisms regulating ion channels during apoptosis are, however, still poorly defined. Recent studies have suggested a function for distinct membrane domains, termed rafts, in the cell membrane for the regulation of ion channels during apoptosis. Small sphingolipid- and cholesterol-enriched membrane domains are modified by many apoptotic stimuli to form large ceramide-enriched membrane platforms. These platforms serve to cluster receptor molecules, to re-organize intracellular signalling molecules including ion channels, to bring ion channels into close contact with their regulators and/or to separate proteins from a specific ion channel. Finally, the lipid composition of the cell membrane might be involved directly in ion channel regulation.

Altered lipid raft-associated signaling and ganglioside expression in T lymphocytes from patients with systemic lupus erythematosus

Systemic lupus erythematosus (SLE) is characterized by abnormalities in T lymphocyte receptor-mediated signal transduction pathways. Our previous studies have established that lymphocyte-specific protein tyrosine kinase (LCK) is reduced in T lymphocytes from patients with SLE and that this reduction is associated with disease activity and parallels an increase in LCK ubiquitination independent of T cell activation. This study investigated the expression of molecules that regulate LCK homeostasis, such as CD45, C-terminal Src kinase (CSK), and c-Cbl, in lipid raft domains from SLE T cells and investigated the localization of these proteins during T cell receptor (TCR) triggering. Our results indicate that the expression of raft-associated ganglioside, GM1, is increased in T cells from SLE patients and LCK may be differentially regulated due to an alteration in the association of CD45 with lipid raft domains. CD45 tyrosine phosphatase, which regulates LCK activity, was differentially expressed and its localization into lipid rafts was increased in T cells from patients with SLE. Furthermore, T cells allowed to "rest" in vitro showed a reversal of the changes in LCK, CD45, and GM1 expression. The results also revealed that alterations in the level of GM1 expression and lipid raft occupancy cannot be induced by serum factors from patients with SLE but indicated that cell-cell contact, activating aberrant proximal signaling pathways, may be important in influencing abnormalities in T cell signaling and, therefore, function in patients with SLE.

Functional role of lipid raft microdomains in cyclic nucleotide-gated channel activation

Cyclic nucleotide-gated (CNG) channels are the primary targets of light- and odorant-induced signaling in photoreceptors and olfactory sensory neurons. Compartmentalized cyclic nucleotide signaling is necessary to ensure rapid and efficient activation of these nonselective cation channels. However, relatively little is known about the subcellular localization of CNG channels or the mechanisms of their membrane partitioning. Lipid raft domains are specialized membrane microdomains rich in cholesterol and sphingolipids that have been implicated in the organization of many membrane-associated signaling pathways. Herein, we report that the alpha subunit of the olfactory CNG channel, CNGA2, associates with lipid rafts in heterologous expression systems and in rat olfactory epithelium. However, CNGA2 does not directly bind caveolin, and its membrane localization overlaps only slightly with that of caveolin at the surface of human embryonic kidney (HEK) 293 cells. To test for a possible functional role of lipid raft association, we treated HEK 293 cells with the cholesterol-depleting agent, methyl-beta-cyclodextrin. Cholesterol depletion abolished prostaglandin E1-stimulated CNGA2 channel activity in intact cells. Recordings from membrane patches excised from CNGA2-expressing HEK 293 cells revealed that cholesterol depletion dramatically reduced the apparent affinity of homomeric CNGA2 channels for cAMP but only slightly reduced the maximal current. Our results show that olfactory CNG channels target to lipid rafts and that disruption of lipid raft microdomains dramatically alters the function of CNGA2 channels.

Lipids as Targeting Signals: Lipid Rafts and Intracellular Trafficking

Our view of biological membranes has evolved dramatically over the last few decades. In the bilayer model from Singer & Nicholson (Science 1972;175:720-731), both proteins and lipids freely diffuse within the plane of the membrane. Currently, however, membranes are viewed as a mosaic of different compartments or domains maintained by an active cytoskeleton network (Ritchie et al. Mol Membr Biol 2003; 20:13-18). Due to interactions between membrane components, several types of subdomains can form with different characteristics and functions. Lipids are likely to play an important role in the formation of so-called lipid-enriched microdomains or lipid rafts, adding another order of complexity to the membrane model. Rafts represent a type of domain wherein lipids of specific chemistry may dynamically associate with each other, to form platforms important for membrane protein sorting and construction of signaling complexes (Simons & Toomre. Nat Rev Mol Cell Biol 2000;1:31-39). Currently, there are several hypotheses concerning the nature of rafts (reviewed in (Edidin. Annu Rev Biophys Biomol Struct 2003;32: 257-283; Zurzolo et al. EMBO Rep 2003;4:1117-1121)). The most commonly cited one, proposed by Kai Simons (Simons & Ikonen. Nature 1997;387:569-572; Pralle et al. J Cell Biol 2000;148:997-1008), suggests that rafts are relatively small structures ( approximately 50 nm) enriched in cholesterol and sphingolipids within which associated proteins are likely to be concentrated. Another proposal (Anderson & Jacobson. Science 2002;296:1821-1825) suggests that rafts are constructed of lipid shells. These are small dynamic assemblies wherein 'raft' proteins are preferentially associated with certain types of lipids. These 'shells' are thermodynamically stable mobile entities in the plane of the membrane that are able to target the protein they encase to preexisting rafts/caveolae domains. In this review we summarize the data suggesting a specific role for lipid domains in intracellular trafficking and sorting and present a modification of the raft model that may help explain the observed phenomena.

Thrombospondin-1-induced focal adhesion disassembly in fibroblasts requires Thy-1 surface expression, lipid raft integrity, and Src activation

The hep I peptide of thrombospondin-1 is known to induce the disassembly of focal adhesions, a critical step in regulating cellular adhesive changes needed for cell motility. Fibroblasts that are heterogeneous with respect to the surface expression of Thy-1 differ markedly in morphology, cytoskeletal organization, and migration, suggesting differential regulation of focal adhesion dynamics. Here we demonstrate that disassembly of focal adhesions mediated by both full-length thrombospondin-1 and the hep I peptide in fibroblasts requires the expression of Thy-1, although it does not appear to function as a stable member of the hep I receptor complex. Consistent with a known function of Thy-1 in regulating lipid raft-associated signaling, intact lipid rafts are necessary for hep I-mediated focal adhesion disassembly. Furthermore, we establish Src family kinase (SFK) activation as a novel component required for hep I-induced signaling leading to focal adhesion disassembly. hep I induces transient phosphorylation of SFKs in Thy-1-expressing fibroblasts only. Therefore, we conclude that Thy-1 surface expression is required for thrombospondin-1-induced focal adhesion disassembly in fibroblasts through an SFK-dependent mechanism. This represents a novel role for Thy-1 in the regulation of fibroblast-matrix interactions critical to tissue homeostasis and remodeling.

Cholesterol efflux alters lipid raft stability and distribution during capacitation of boar spermatozoa

A reduction in plasma membrane cholesterol is one of the early events that either triggers or is closely associated with capacitation of mammalian spermatozoa. In this investigation, we have examined the effects of cholesterol efflux on tyrosine phosphorylation, lipid diffusion, and raft organization in boar spermatozoa. Results show that a low level of cholesterol efflux, mediated by 5 mM methyl-beta-cyclodextrin (MBCD), enhances capacitation and induces phosphorylation of two proteins at 26 and 15 kDa without affecting sperm viability. Lipid diffusion rates under these conditions are largely unaffected except when cholesterol efflux is excessive. Low-density Triton X100-insoluble complexes (lipid rafts) were isolated from spermatozoa and found to have a restricted profile of proteins. Capacitation-associated cholesterol efflux has no effect on raft composition, but cholesterol depletion destabilizes them completely and phosphorylation is suppressed. During MBCD-mediated capacitation, the distribution of GM1 gangliosides on spermatozoa changes in a sequential manner from overlying the sperm tail to clustering on the sperm head. It is concluded that there is a safe window for removal of plasma membrane cholesterol from spermatozoa within which protein phosphorylation and polarized migration of lipid rafts take place. A preferential loss of cholesterol from the nonraft pool may be the stimulus that promotes raft clustering over the anterior sperm head.

Long-Chain Fatty Acid Uptake into Adipocytes Depends on Lipid Raft Function

This study investigates the role of lipid rafts and caveolae, a subclass of lipid raft microdomains, in the binding and uptake of long-chain fatty acids (LCFA) by 3T3-L1 cells during differentiation. Disruption of lipid rafts by beta-cyclodextrin (betaCD) or selective inhibition of caveolae by overexpression of a dominant-negative mutant of caveolin-3 (Cav(DGV)) resulted in disassembly of caveolae structures at the cell surface, as assessed by electron microscopy. While in 3T3-L1 fibroblasts, which express few caveolae, Cav(DGV) or betaCD had no effect on LCFA uptake, in 3T3-L1 adipocytes the same treatments decreased the level of [(3)H]oleic acid uptake by up to 55 +/- 8 and 49 +/- 7%, respectively. In contrast, cholesterol loading of 3T3-L1 adipocytes resulted in a 4-fold increase in the extent of caveolin-1 expression and a 1.7-fold increase in the level of LCFA uptake. Both the inhibitory and enhancing effects of these treatments were constantly increasing with the [(3)H]oleic acid incubation time up to 5 min. Incubation of 3T3-L1 adipocytes with [(3)H]stearate followed by isolation of a caveolin-1 positive detergent-resistant membrane (DRM) fraction revealed that [(3)H]stearate binds to caveolae. Fatty acid translocase (FAT/CD36) was found to be present in this DRM fraction as well. Our data thus strongly indicate a critical involvement of lipid rafts in the binding and uptake of LCFA into 3T3-L1 adipocytes. Furthermore, our findings suggest that caveolae play a pivotal role in lipid raft-dependent LCFA uptake. This transport mechanism is induced in conjunction with cell differentiation and might be mediated by FAT/CD36.

Leishmania-induced inhibition of macrophage antigen presentation analyzed at the single-cell level

A number of studies have previously examined the capacity of intracellular Leishmania parasites to modulate the capacity of macrophages to process and present Ags to MHC class II-restricted CD4(+) T cells. However, the bulk culture approaches used for assessing T cell activation make interpretation of some of these studies difficult. To gain a more precise understanding of the interaction between Leishmania-infected macrophages and effector T cells, we have analyzed various parameters of T cell activation in individual macrophage-T cell conjugates. Leishmania-infected macrophages efficiently stimulate Ag-independent as well as Ag-dependent, TCR-mediated capping of cortical F-actin in DO.11 T cells. However, infected macrophages are less efficient at promoting the sustained TCR signaling necessary for reorientation of the T cell microtubule organizing center and for IFN-gamma production. A reduced ability to activate these T cell responses was not due to altered levels of surface-expressed MHC class II-peptide complexes. This study represents the first direct single-cell analysis of the impact of intracellular infection on the interaction of macrophages with T cells and serves to emphasize the subtle influence Leishmania has on APC function.

Caveolar and lipid raft localization of the growth hormone receptor and its signaling elements: impact on growth hormone signaling

The growth hormone receptor (GHR) is a cell surface receptor that mediates the somatogenic and metabolic effects of the growth hormone (GH). GHR signaling is transduced via the receptor-associated cytoplasmic tyrosine kinase called Janus protein kinase 2 (JAK2). The major intracellular signaling systems activated by JAK2 in response to GH include the signal transducer and activator of transcription (STAT) 5 and extracellular signal-regulated kinase (ERK)-1 and -2 pathways. In this report, we investigate the role of cholesterol-rich plasma membrane microdomains (caveolae and lipid rafts) in GH signaling. By subcellular fractionation of the GH-responsive 3T3-F442A murine preadipocyte, we found dramatic enrichment (6.7-fold) of plasma membrane GHR in the caveolae membranes (CM). JAK2 was also represented in the CM fraction, but was less enriched (2.5-fold) than GHR. ERK1/2 and the important ERK pathway upstream small adaptor protein, Grb2 (growth factor receptor-bound protein 2), were also enriched in caveolae (2.3- and 8.3-fold, respectively), but STAT5 was barely detected in the same fraction. Correspondingly, GH-induced tyrosine-phosphorylated GHR, JAK2, and ERK1/2 were highly represented in the CM fraction, whereas tyrosine-phosphorylated STAT5 was enriched in the non-membranous fraction of the post-nuclear supernatant. Additionally, GH induced further accumulation of GHR, Grb2, and SHC proteins in the CM fraction. Interestingly, treatment of the cells with the caveolae-disrupting agent, methyl-beta-cyclodextrin (mbetaCD), selectively inhibited GH-induced ERK1/2 activation but not STAT5 phosphorylation; repletion of cholesterol in mbetaCD-treated cells restored GH-induced ERK activation. Comparison of 3T3-F442A cells with the GHR-expressing human IM-9 lymphoblasts revealed similar enrichment of GHR in the lipid raft fraction of IM-9 as in the CM fraction of 3T3-F442A, but there were dramatic differences in the ERKs and Grb2. The IM-9 cell, in which ERKs are not activated by GH, displayed no enrichment of ERKs and Grb2 in the lipid raft fraction. Our results suggest that localization of GHRs in the CM fraction of the plasma membrane plays important roles in signaling.

HIV-1 assembly and maturation

HIV-1 particles have been studied by structural and chemical approaches, however, the processes of assembly, budding and maturation are just beginning to be characterized, and molecular details of these processes remain poorly defined. This brief review summarizes some recent findings on the final steps of the HIV-1 life cycle and touches upon some unanswered questions, particularly regarding the processes involved in virus maturation and infectivity.

Formation and dynamic alterations of horizontal microdomains in sperm membranes during progesterone-induced acrosome reaction

Capacitated mammalian spermatozoa undergo a fusion response of their head plasma membrane and the outer acrosomal membrane leading to vesiculation classically known as acrosome reaction. Acrosome reaction occurs in response to various acrosome reaction inducers including zona pellucida proteins, calcium ionophore, dibutyryl cAMP, progesterone, etc. All the acrosome reaction inducers cause a transient of calcium influx into the sperm through voltage-dependent cation channels. Efflux of chloride, stimulation of activity of phospholipases, and phosphorylation of proteins are other known changes introduced by acrosome reaction inducers. Macromolecular organization and dynamics of sperm membranes during the progression of this vesiculation are largely unexplored. In this study, we report that progesterone induced the formation of horizontal microdomains within the exofacial surfaces of sperm membranes, which showed progressive and independent alterations in molecular dynamics. In the light of this observation, we propose that sperm membrane rafts may contain both horizontal and vertical microdomains.

Lipid rafts and plasma membrane microorganization: insights from Ras

The spatial organization of plasma membrane components in discrete microdomains is thought to be a key factor in the generation of distinct signal outputs. A detailed characterization of plasma membrane microdomains, including descriptions of their size, dynamics and abundance, has proved to be a taxing problem for cell biologists and biophysicists. The use of novel techniques is providing exciting new insights into the challenging problem of plasma membrane microstructure and has allowed the visualization of domains with the characteristics expected of lipid rafts - microdomains of the plasma membrane enriched in cholesterol and sphingolipids. This review focuses on some of these recent advances and uses Ras signaling as a paradigm for understanding inner plasma membrane organization and the role of lipid rafts in cellular function.

Protocadherin α3 Acts at Sites Distinct from Classic Cadherins in Rat Testis and Sperm1

The testis expresses a variety of cadherin superfamily members including classic cadherins and protocadherins. This report describes the first localization of a protocadherin protein in testis and sperm. After cloning rat cDNAs for protocadherin alpha3 and alpha4, isoform-specific polyclonal antibodies were generated against protocadherin alpha3. Western blotting of rat testis showed that protocadherin alpha3 was solubilized completely by Triton X-100, in contrast to the adhesion junction components N-cadherin, beta-catenin, and p120 catenin. Corroborating this data, protocadherin alpha3 was immunolocalized to the spermatid acrosomal area, intercellular bridge, and flagellum, but not classic cadherin-based adhesion junctions. Acrosome-associated protocadherin alpha3 was first detected at step 8 of spermiogenesis, and this association remained on cauda epididymal sperm. Acrosome immunostaining was reduced, but present, in acrosome-reacted sperm. Spermatid intercellular bridges became positive for protocadherin alpha3 coincident with the appearance of plectin, occurring at spermiogenic steps 8 to 9, and elongate spermatid bridges remained positive throughout spermatogenesis. The developing flagellum was uniformly immunostained for protocadherin alpha3 up to approximately spermiogenic step 17. Subsequently, flagellar immunostaining was confined to the principal piece, and this pattern continued in cauda epididymal sperm. These data show that protocadherin alpha3 performs functions unique from classic cadherins in spermatogenesis and suggest a role for protocadherin alpha3 in organizing germ cell-specific structures including the intercellular bridge, flagellum, and acrosome.

CD226 (DNAM-1) is involved in lymphocyte function-associated antigen 1 costimulatory signal for naive T cell differentiation and proliferation

Upon antigen recognition by the T cell receptor, lymphocyte function–associated antigen 1 (LFA-1) physically associates with the leukocyte adhesion molecule CD226 (DNAM-1) and the protein tyrosine kinase Fyn. We show that lentiviral vector-mediated mutant (Y-F³²²) CD226 transferred into naive CD4⁺ helper T cells (Ths) inhibited interleukin (IL)-12–independent Th1 development initiated by CD3 and LFA-1 ligations. Moreover, proliferation induced by LFA-1 costimulatory signal was suppressed in mutant (Y-F³²²) CD226-transduced naive CD4⁺ and CD8⁺ T cells in the absence of IL-2. These results suggest that CD226 is involved in LFA-1–mediated costimulatory signals for triggering naive T cell differentiation and proliferation. We also demonstrate that although LFA-1, CD226, and Fyn are polarized at the immunological synapse upon stimulation with anti-CD3 in CD4⁺ and CD8⁺ T cells, lipid rafts are polarized in CD4⁺, but not CD8⁺, T cells. Moreover, proliferation initiated by LFA-1 costimulatory signal is suppressed by lipid raft disruption in CD4⁺, but not CD8⁺, T cells, suggesting that the LFA-1 costimulatory signal is independent of lipid rafts in CD8⁺ T cells.

Hypothesis: could the signalling function of membrane microdomains involve a localized transition of lipids from liquid to solid state?

Background

Over the past decade, it has become apparent that specialised membrane microdomains, commonly called rafts, where lipids like sphingolipids and cholesterol are arranged compactly in a liquid ordered phase are involved in cell signalling.

Hypothesis

The core of the hypothesis presented here is that resting cells may actively maintain their plasma membrane in liquid phase, corresponding to a metastable thermodynamic state. Following a physiological stimulus such as ligands binding to their membrane receptors, the tendency of membrane components to undergo a localised transition towards a gel state would increase, resulting in initial minute solid structures. These few membrane components having undergone a liquid to solid state transition, would then act as seeds for the specific recruitment of additional membrane components whose properties are compatible with the crystalline growth of these initial docks. Cells could therefore be using the propensity of lipids to assemble selectively to generate stable platforms of particular cellular components either for intra-cellular transport or for signal transduction.

Testing the hypothesis

could presumably be done via biophysical approaches such as EPR spin labelling, X-ray diffraction or FRET coupled to direct microscopic observation of cells to which very localized stimuli would be delivered.

Implications

Such a model of selective growth of membrane docks would provide an explanation for the existence of different types of microdomains, and for the fact that, depending on the state of the cells and on the procedures used to isolate them, membrane microdomains can vary greatly in their properties and composition. Ultimately, a thorough understanding of how and why lipid domains are assembled in biological membranes will be essential for many aspects of cell biology and medicine.

Ephrin signaling: One raft to rule them all? One raft to sort them? One raft to spread their call and in signaling bind them?

The Eph receptor tyrosine kinases (RTK) and their membrane-bound ligands, the ephrins, mediate cell-contact-dependent signaling events that control multiple aspects of metazoan embryonic development. The ephrins and their receptors regulate cell movement that is essential for forming and stabilizing the spatial organization of tissues and cell types. This includes the guidance of migrating cells or neuronal growth cones to specific targets. Although the biological responses mediated by the ephrin-Eph system were thought to be imparted by the Eph receptor via 'classical' RTK signaling pathways, there is now accumulating evidence that the ephrins are not merely ligands but have biological activity independent of the kinase activity of their cognate Eph receptor. This activity is commonly referred to as 'reverse' or 'bi-directional' signaling. Furthermore, ephrin-mediated signaling is restricted to specific membrane microdomains known as 'lipid rafts', which we believe imparts specificity to the extracellular signal. This review highlights the current data to support a role for lipid rafts in regulating aspects of ephrin-mediated signaling.

Tea polyphenol epigallocatechin-3-gallate associates with plasma membrane lipid rafts: lipid rafts mediate anti-allergic action of the catechin

High-affinity IgE receptor FcepsilonRI is key molecule in the IgE-mediated allergic reactions. Epigallocatechin-3-gallate (EGCG) has a suppressive effect of the expression of the FcepsilonRI. We show here that EGCG highly associates with plasma membrane microdomains, lipid rafts. The disruption of these lipid rafts caused a reduction of the amount of raft-associated EGCG and the FcepsilonRI -suppressive effect of EGCG. These results suggest that the interaction between EGCG and the lipid rafts is important for EGCG's ability to downregulate FcepsilonRI expression.