Influence of lipid rafts on CD1d presentation by dendritic cells

Our main objective was to analyze the role of lipid rafts in the activation of Vα-14^? and Vα-14⁺ T hybridomas by dendritic cells. We showed that activation of Vα-14⁺ hybridomas by dendritic cells or other CD1d-expressing cells was altered by disruption of lipid rafts with the cholesterol chelator MβCD. However, CD1d presentation to autoreactive Vα-14^? anti-CD1d hybridomas which do not require the endocytic pathway was not altered. Using partitioning of membrane fractions with Brij98 at 37°C, we confirmed that CD1d was enriched in subcellular fractions corresponding to lipid rafts and we describe that α-GalCer enhanced CD1d amount in the low density detergent insoluble fraction. We conclude that the membrane environment of CD1d can influence antigen presentation mainly when the endocytic pathway is required. Flow cytometry analysis can provide additional information on lipid rafts in plasma membranes and allows a dynamics follow-up of lipid rafts partitioning. Using this method, we showed that CD1d plasma membrane expression was sensitive to low concentrations of detergent. This may suggest either that CD1d is associated with lipid rafts mainly in intracellular membranes or that its association with the lipid rafts in the plasma membrane is weak.     

GM1-containing lipid rafts are depleted within clathrin-coated pits

Recent studies show that markers for lipid rafts are among the plasma membrane components most likely to be internalized independently of clathrin-coated pits, and there is evidence to suggest that lipid rafts may play a functional role in endocytic trafficking [1-5]. However, lipid rafts themselves are commonly defined purely in biochemical terms, by resistance to detergent extraction. The existence of rafts in live-cell membranes remains controversial [6-8], and their distribution relative to endocytic machinery has not been investigated. This study employs fluorescence resonance energy transfer (FRET) to show that in the plasma membrane (PM) of living cells the glycosphingolipid GM1, labeled with cholera toxin B subunit (CTB) [9,10], is found at least in part within clusters that also include GPI-linked proteins. These clusters are cholesterol-dependent and exclude non-raft proteins such as transferrin receptor and so possess predicted properties of lipid rafts. This type of lipid raft is largely excluded from clathrin-positive regions of the PM. They are found within Caveolin-positive regions at the same concentration as at the rest of the cell surface. The data provide evidence for a model in which lipid rafts are distributed uniformly across most of the PM of nonpolarized cells but are prevented from entering clathrin-coated pits.     

Raft partitioning of the yeast uracil permease during trafficking along the endocytic pathway

Lipid rafts, formed by the lateral association of sphingolipids and cholesterol in the external membrane leaflet, have been implicated in membrane traffic and cell signaling in mammalian cells. Yeast plasma membranes were also recently shown to contain lipid raft microdomains consisting of sphingolipids and ergosterol, and containing several plasma membrane proteins, including Gas1p, a GPI-anchored protein, and the [H⁺] ATPase Pma1p. In this study, we investigated whether lipid rafts were involved in the intracellular trafficking of a yeast transporter, uracil permease, which undergoes ubiquitin-dependent endocytosis. Regardless of its ubiquitination status, uracil permease was found to be associated with rafts in the plasma membrane. The expression of Fur4p in lcb1–100 cells, deficient in the first enzyme of sphingolipid synthesis, impaired the association of Fur4p with detergent-resistant fractions. When targeted to endocytic compartments, uracil permease appeared to be progressively transferred to detergent-soluble fractions, suggesting that the lipid environment might change between plasma membrane and endosomes. Consistent with this hypothesis, the wild-type form of the v-SNARE Snc1p, which is known to cycle between the plasma membrane and endosomal compartments, was recovered in both detergent-resistant and detergent-soluble fractions. In contrast, a variant Snc1p that accumulates at the plasma membrane was recovered exclusively in detergent-resistant fractions .     

The low-density lipoprotein receptor-related protein-1 associates transiently with lipid rafts

The low-density lipoprotein receptor-related protein-1 (LRP-1) is a multifunctional receptor that undergoes constitutive endocytosis and recycling. To identify LRP-1 in lipid rafts, we biotin-labeled cells using a membrane-impermeable reagent and prepared Triton X-100 fractions. Raft-associated proteins were identified in streptavidin affinity-precipitates of the Triton X-100-insoluble fraction. PDGF beta-receptor was identified exclusively in lipid rafts, whereas transferrin receptor was excluded. LRP-1 distributed partially into rafts in murine embryonic fibroblasts (MEFs) and HT 1080 cells, but not in smooth muscle cells and CHO cells. LRP-1 partitioning into rafts was not altered by ligands, including alpha2-macroglobulin, platelet-derived growth factor-BB, and receptor-associated protein (RAP). To examine LRP-1 trafficking between membrane microdomains, we developed a novel method based on biotinylation and detergent fractionation. Association of LRP-1 with rafts was transient; by 15 min, nearly all of the LRP-1 that was initially raft-associated exited this compartment. LRP-1 in the Triton X-100-soluble fraction, which excludes lipid rafts, demonstrated complex kinetics, with phases reflecting import from rafts, endocytosis, and recycling. Potassium depletion blocked LRP-1 endocytosis but did not inhibit trafficking of LRP-1 from rafts into detergent-soluble microdomains. Our data support a model in which LRP-1 transiently associates with rafts but does not form a stable pool. Fluid movement of LRP-1 between microdomains may facilitate its function in promoting the endocytosis of other plasma membrane proteins, such as the urokinase receptor, which localizes in lipid rafts.     

The secretory pathway Ca-ATPase 1 is associated with cholesterol-rich microdomains of human colon adenocarcinoma cells

Lipid rafts are often considered as microdomains enriched in sphingomyelin and cholesterol, predominantly residing in the plasma membrane but which originate in earlier compartments of the cellular secretory pathway. Within this pathway, the membranes of the Golgi complex represent a transition stage between the cholesterol-poor membranes of the endoplasmic reticulum (ER) and the cholesterol-rich plasma membrane. The rafts are related to detergent-resistant membranes, which because of their ordered structure are poorly penetrated by cold non-ionic detergents and float in density gradient centrifugation. In this study the microdomain niche of the Golgi-resident SPCA Ca²⁺/Mn²⁺ pumps was investigated in HT29 cells by Triton X-100 detergent extraction and density-gradient centrifugation. Similarly to cholesterol and the raft-resident flotillin-2, SPCA1 was found mainly in detergent-resistant fractions, while SERCA3 was detergent-soluble. Furthermore, cholesterol depletion of cells resulted in redistribution of flotillin-2 and SPCA1 to the detergent-soluble fractions of the density gradient. Additionally, the time course of solubilization by Triton X-100 was investigated in live COS-1 and HT29 cells expressing fluorescent SERCA2b, SPCA1d or SPCA2. In both cell types, the ER-resident SERCA2b protein was gradually solubilized, while SPCA1d resisted to detergent solubilization. SPCA2 was more sensitive to detergent extraction than SPCA1d. To investigate the functional impact of cholesterol on SPCA1, ATPase activity was monitored. Depletion of cholesterol inhibited the activity of SPCA1d, while SERCA2b function was not altered. From these results we conclude that SPCA1 is associated with cholesterol-rich domains of HT29 cells and that the cholesterol-rich environment is essential for the functioning of the pump.     

Lipid rafts are required for efficient signal transduction by CD1d

Plasma membranes of eukaryotic cells are not uniform, possessing distinct cholesterol- and sphingolipid-rich lipid raft microdomains which constitute critical sites for signal transduction through various immune cell receptors and their co-receptors. CD1d is a conserved family of major histocompatibility class I-like molecules, which has been established as an important factor in lipid antigen presentation to natural killer T (NKT) cells. Unlike conventional T cells, recognition of CD1d by the T cell receptor (TCR) of NKT cells does not require CD4 or CD8 co-receptors, which are critical for efficient TCR signaling. We found that murine CD1d (mCD1d) was constitutively present in the plasma membrane lipid rafts on antigen presenting cells, and that this restricted localization was critically important for efficient signal transduction to the target NKT cells, at low ligand densities, even without the involvement of co-receptors. Further our results indicate that there may be additional regulatory molecule(s), co-located in the lipid raft with mCD1d for NKT cell signaling.     

Human immunodeficiency virus type 1 uses lipid raft-colocalized CD4 and chemokine receptors for productive entry into CD4(+) T cells

In this report, we describe a crucial role of lipid raft-colocalized receptors in the entry of human immunodeficiency virus type 1 (HIV-1) into CD4(+) T cells. We show that biochemically isolated detergent-resistant fractions have characteristics of lipid rafts. Lipid raft integrity was required for productive HIV-1 entry as determined by (i) semiquantitative PCR analysis and (ii) single-cycle infectivity assay using HIV-1 expressing the luciferase reporter gene and pseudotyped with HIV-1 HXB2 envelope or vesicular stomatitis virus envelope glycoprotein (VSV-G). Depletion of plasma membrane cholesterol with methyl-beta-cyclodextrin (MbetaCD) relocalized raft-resident markers to a nonraft environment but did not significantly change the surface expression of HIV-1 receptors. MbetaCD treatment inhibited productive infection of HIV-1 by 95% as determined by luciferase activity in cells infected with HXB2 envelope-pseudotyped virus. In contrast, infection with VSV-G-pseudotyped virus, which enters the cells through an endocytic pathway, was not suppressed. Biochemical fractionation and confocal imaging of HIV-1 receptor distribution in live cells demonstrated that CD4, CCR5, and CXCR4 colocalized with raft-resident markers, ganglioside GM1, and glycosylphosphatidylinositol-anchored CD48. While confocal microscopy analysis revealed that HIV-1 receptors localized most likely to the same lipid microdomains, sucrose gradient analysis of the receptor localization showed that, in contrast to CD4 and CCR5, CXCR4 was associated preferentially with the nonraft membrane fraction. The binding of HIV-1 envelope gp120 to lipid rafts in the presence, but not in the absence, of cholesterol strongly supports our hypothesis that raft-colocalized receptors are directly involved in virus entry. Dramatic changes in lipid raft and HIV-1 receptor redistribution were observed upon binding of HIV-1 NL4-3 to PM1 T cells. Colocalization of CCR5 with GM1 and gp120 upon engagement of CD4 and CXCR4 by HIV-1 further supports our observation that HIV-1 receptors localize to the same lipid rafts in PM1 T cells.     

Sorting of Lens Aquaporins and Connexins into Raft and Nonraft Bilayers: Role of Protein Homo-Oligomerization

Two classes of channel-forming proteins in the eye lens, the water channel aquaporin-0 (AQP-0) and the connexins Cx46 and Cx50, are preferentially located in different regions of lens plasma membranes ( [1] and [2]). Because these membranes contain high concentrations of cholesterol and sphingomyelin, as well as phospholipids such as phosphatidylcholine with unsaturated hydrocarbon chains, microdomains (rafts) form in these membranes. Here we test the hypothesis that sorting into lipid microdomains can play a role in the disposition of AQP-0 and the connexins in the plane of the membrane. For both crude membrane fractions and proteoliposomes composed of lens proteins in phosphatidylcholine/sphingomyelin/cholesterol lipid bilayers, detergent extraction experiments showed that the connexins were located primarily in detergent soluble membrane (DSM) fractions, whereas AQP-0 was found in both detergent resistant membrane and DSM fractions. Analysis of purified AQP-0 reconstituted in raft-containing bilayers showed that the microdomain location of AQP-0 depended on protein/lipid ratio. AQP-0 was located almost exclusively in DSMs at a 1:1200 AQP-0/lipid ratio, whereas ∼50% of the protein was sequestered into detergent resistant membranes at a 1:100 ratio, where freeze-fracture experiments show that AQP-0 oligomerizes (3). Consistent with these detergent extraction results, confocal microscopy images showed that AQP-0 was sequestered into raft microdomains in the 1:100 protein/lipid membranes. Taken together these results indicate that AQP-0 and connexins can be segregated in the membrane by protein-lipid interactions as modified by AQP-0 homo-oligomerization.     

Differential sorting and fate of endocytosed GPI-anchored proteins

In this paper, we studied the fate of endocytosed glycosylphosphatidyl inositol anchored proteins (GPI- APs) in mammalian cells, using aerolysin, a bacterial toxin that binds to the GPI anchor, as a probe. We find that GPI-APs are transported down the endocytic pathway to reducing late endosomes in BHK cells, using biochemical, morphological and functional approaches. We also find that this transport correlates with the association to raft-like membranes and thus that lipid rafts are present in late endosomes (in addition to the Golgi and the plasma membrane). In marked contrast, endocytosed GPI-APs reach the recycling endosome in CHO cells and this transport correlates with a decreased raft association. GPI-APs are, however, diverted from the recycling endosome and routed to late endosomes in CHO cells, when their raft association is increased by clustering seven or less GPI-APs with an aerolysin mutant. We conclude that the different endocytic routes followed by GPI-APs in different cell types depend on the residence time of GPI-APs in lipid rafts, and hence that raft partitioning regulates GPI-APs sorting in the endocytic pathway.     

Recycling CD1d1 molecules present endogenous antigens processed in an endocytic compartment to NKT cells

Mouse CD1d1 molecules present endogenous glycolipids to NKT cells. Although glycolipid presentation requires CD1d1 transport through the endocytic pathway, the processing requirements for such endogenous Ag presentation by CD1d1 molecules are undefined. We examined CD1d1 Ag presentation to NKT cells by disrupting endocytic trafficking and function in cells expressing normal and mutated CD1d1 expressed by recombinant vaccinia viruses. Consistent with previous studies, we found that preventing CD1d1 localization to endosomes by altering its cytoplasmic targeting sequences abrogated recognition by Valpha14Jalpha281(+) NKT cells without affecting recognition by Valpha14(-) NKT cells. Increasing the pH of acidic compartments by incubating cells with chloroquine or bafilomycin A1 blocked CD1d1 recognition by Valpha14(+) (but not Valpha14(-)) NKT cells without reducing levels of cell surface CD1d1. Similar results were obtained with primaquine, which interferes with the recycling of cell surface glycoproteins. These results suggest that the loading of a subset of glycolipid ligands onto CD1d1 molecules entails the delivery of cell surface CD1d1 molecules and an acidic environment in the endocytic pathway.     

Cholesterol: Coupling between membrane microenvironment and ABC transporter activity

Lipid composition of biological membranes is closely related to the function of the ATP-binding cassette (ABC) transporter P-Glycoprotein (Pgp). Herein, we studied how membrane physico-chemical properties affect Pgp-activity. We effectively modulated the cellular cholesterol content using methyl-beta-cyclodextrin (MbetaCD) and MbetaCD-cholesterol-inclusion complex. Pgp was not liberated from the plasma membrane during cholesterol modulation and functional inhibition of Pgp was related to varying cholesterol levels in the plasma membrane. Our data indicate that membrane fluidity does not solely account for cholesterol dependent modifications of Pgp-activity. Therefore, we isolated lipid rafts and examined distinct membrane microdomains. Both depletion and cholesterol enrichment induces a disassembly of lipid rafts. In cholesterol-depleted cell membranes a shift in the Pgp localisation to detergent soluble fractions was observed. Enrichment of membrane cholesterol changed lipid raft distribution but not the localisation of Pgp. From our data we conclude that Pgp-transport capacity depends on accurate lipid raft properties.     

Relationships between EGFR signaling-competent and endocytosis-competent membrane microdomains

Membrane microdomains, the so-called lipid rafts, function as platforms to concentrate receptors and assemble the signal transduction machinery. Internalization, in most cases, is carried out by different specialized structures, the clathrin-coated pits. Here, we show that several endocytic proteins are efficiently recruited to morphologically identified plasma membrane lipid rafts, upon activation of the epidermal growth factor (EGF) receptor (EGFR), a receptor tyrosine kinase. Analysis of detergent-resistant membrane fractions revealed that the EGF-dependent association of endocytic proteins with rafts is as efficient as that of signaling effector molecules, such as Grb2 or Shc. Finally, the EGFR, but not the nonsignaling transferrin receptor, could be localized in nascent coated pits that almost invariably contained raft membranes. Thus, specialized membrane microdomains have the ability to assemble both the molecular machineries necessary for intracellular propagation of EGFR effector signals and for receptor internalization.     

Regulation of CD1a surface expression and antigen presentation by invariant chain and lipid rafts

In immature dendritic cells (DCs), CD1a is almost exclusively expressed at the cell surface and its membrane organization is poorly understood. In this study, we report that MHC class II, invariant chain (Ii), and CD9 molecules are coimmunoprecipitated with CD1a in immature DCs, and that CD1a/Ii colocalization is dependent on lipid raft integrity. In HeLa-CIITA cells CD1a expression leads to increased Ii trafficking to the cell surface, confirming the relevance of this association. Furthermore, silencing of Ii in DCs induces significant CD1a accumulation on the plasma membrane whereas the total CD1a expression remains similar to that of control cells. These data suggest that CD1a recycling is facilitated by the association with the Ii. The CD1a localization in lipid rafts has functional relevance as demonstrated by inhibition of CD1a-restricted presentation following raft disruption. Overall, these findings identify Ii and lipid rafts as key regulators of CD1a organization on the surface of immature DCs and of its immunological function as Ag-presenting molecule.     

Regulated recruitment of MHC class II and costimulatory molecules to lipid rafts in dendritic cells

T cell activation has long been associated with the partitioning of Ag receptors and associated molecules to lipid microdomains. We now show that dendritic cells (DCs) also accomplish the selective recruitment to lipid rafts of molecules critical for Ag presentation. Using mouse bone marrow-derived DCs, we demonstrate that MHC class II molecules become substantially localized to rafts upon DC maturation. Even more striking is the fact that CD86 is recruited to rafts upon T cell-DC interaction. Recruitment is Ag dependent and requires CD28 on T cells. Despite the regulated recruitment of MHC class II and CD86 to rafts, unlike the counter-receptors in T cells, DCs do not polarize these molecules to sites of DC-T cell contact. This difference may reflect the necessity for DCs to interact with multiple T cells simultaneously and emphasizes that the biochemical and morphological correlates of lipid rafts are not necessarily equivalent.     

A simplified method for the preparation of detergent-free lipid rafts

Lipid rafts are small plasma membrane domains that contain high levels of cholesterol and sphingolipids. Traditional methods for the biochemical isolation of lipid rafts involve the extraction of cells with nonionic detergents followed by the separation of a low-density, detergent-resistant membrane fraction on density gradients. Because of concerns regarding the possible introduction of artifacts through the use of detergents, it is important to develop procedures for the isolation of lipid rafts that do not involve detergent extraction. We report here a simplified method for the purification of detergent-free lipid rafts that requires only one short density gradient centrifugation, but yields a membrane fraction that is highly enriched in cholesterol and protein markers of lipid rafts, with no contamination from nonraft plasma membrane or intracellular membranes.     

CD1 and major histocompatibility complex II molecules follow a different course during dendritic cell maturation

The maturation of dendritic cells is accompanied by the redistribution of major histocompatibility complex (MHC) class II molecules from the lysosomal MHC class II compartment to the plasma membrane to mediate presentation of peptide antigens. Besides MHC molecules, dendritic cells also express CD1 molecules that mediate presentation of lipid antigens. Herein, we show that in human monocyte-derived dendritic cells, unlike MHC class II, the steady-state distribution of lysosomal CD1b and CD1c isoforms was unperturbed in response to lipopolysaccharide-induced maturation. However, the lysosomes in these cells underwent a dramatic reorganization into electron dense tubules with altered lysosomal protein composition. These structures matured into novel and morphologically unique compartments, here termed mature dendritic cell lysosomes (MDL). Furthermore, we show that upon activation mature dendritic cells do not lose their ability of efficient clathrin-mediated endocytosis as demonstrated for CD1b and transferrin receptor molecules. Thus, the constitutive endocytosis of CD1b molecules and the differential sorting of MHC class II from lysosomes separate peptide- and lipid antigen-presenting molecules during dendritic cell maturation.     

Distinct endosomal trafficking requirements for presentation of autoantigens and exogenous lipids by human CD1d molecules

CD1d molecules present both self Ags and microbial lipids to NKT cells. Previous studies have established that CD1d lysosomal trafficking is required for presentation of autoantigens to murine invariant NKT cells. We show in this study that this is not necessary for autoantigen presentation by human CD1d, but significantly affects the presentation of exogenous Ags. Wild-type and tail-deleted CD1d molecules stimulated similar autoreactive responses by human NKT clones, whereas presentation of exogenous lipids by tail-deleted CD1d was highly inefficient. Chloroquine treatment markedly inhibited exogenous Ag presentation by wild-type CD1d transfectants, but did not affect NKT autoreactive responses. Conversely, APC expression of HLA-DRalphabeta and the invariant chain (Ii) was associated with faster internalization of CD1d into the endocytic system and enhanced CD1d-mediated presentation of exogenous Ags, but did not appear to augment NKT autoreactivity. Knockdown of the Ii by small interfering RNA resulted in reduced CD1d surface expression and slower internalization in HLA-DR+ APCs, but not HLA-DR- APCs, demonstrating a direct effect of MHC/Ii complexes on CD1d trafficking. CD1d-mediated presentation of exogenous Ags was much more efficient in immature dendritic cells, which actively recycle MHC class II molecules through the endocytic system, than in mature dendritic cells that have stabilized MHC class II expression at the cell surface, suggesting a physiological role for MHC/Ii complexes in modulating CD1d function. These results indicate that autoantigens and exogenous lipids are acquired by human CD1d at distinct cellular locations, and that Ii trafficking selectively regulates CD1d-mediated presentation of extracellular Ags.     

Lipid raft localization of GABA A receptor and Na+, K+-ATPase in discrete microdomain clusters in rat cerebellar granule cells

The microdomain localization of the GABA(A) receptor in rat cerebellar granule cells was studied by subcellular fractionation and fluorescence- and immunogold electron microscopy. The receptor resided in lipid rafts, prepared at 37 degrees C by extraction with the nonionic detergent Brij 98, but the raft fraction, defined by the marker ganglioside GM(1) in the floating fractions following density gradient centrifugation, was heterogeneous in density and protein composition. Thus, another major raft-associated membrane protein, the Na(+), K(+)-ATPase, was found in discrete rafts of lower density, reflecting clustering of the two proteins in separate membrane microdomains. Both proteins were observed in patchy "hot spots" at the cell surface as well as in isolated lipid rafts. Their insolubility in Brij 98 was only marginally affected by methyl-beta-cyclodextrin. In contrast, both the GABA(A) receptor and Na(+), K(+)-ATPase were largely soluble in ice cold Triton X-100. This indicates that Brij 98 extraction defines an unusual type of cholesterol-independent lipid rafts that harbour membrane proteins also associated with underlying scaffolding/cytoskeletal proteins such as gephyrin (GABA(A) receptor) and ankyrin G (Na(+), K(+)-ATPase). By providing an ordered membrane microenvironment, lipid rafts may contribute to the clustering of the GABA(A) receptor and the Na(+), K(+)-ATPase at distinct functional locations on the cell surface.     

Making membranes green: construction and characterization of GFP-fusion proteins targeted to discrete plasma membrane domains

Cell membranes contain glycolipid-enriched membrane (GEM) domains, or lipid rafts. GEM domains represent a discrete assembly ofproteins and lipids within the plasma membrane thatfunctions in cell signaling. However, studies of the GEM domains often include the disruption of cells with detergent. Thus, many of the physical and biological properties of GEM domains remain unknown and even controversial. An approach to study these domains but avoid detergent lysis is to measure their properties using the fluorescence imaging of live cells. Accordingly, GFP was targeted to either the GEM or the non-GEMfraction of the plasma membrane using the minimal membrane-anchoring signals of p56lck and pp60c-Src, respectively. The targeting of the fusion proteins to the respective membrane fractions was assayed by membrane fractionation and by quantitating the enrichment in GEM caps in stimulated T cells. The results show that the GEM marker was targeted to GEM domains with similar efficiency as other GEM-associated proteins. Conversely, the non-GEM marker was completely excluded from GEM domains. These constructs represent a useful toolfor studying the discrete fractions of the plasma membrane in live cells using fluorescence imaging.     

Relationship between localization on cellular membranes and cytotoxicity of Vibrio vulnificus hemolysin

Vibrio vulnificus secretes a hemolysin/cytolysin (VVH) that induces cytolysis in target cells. A detergent resistant membrane domain (DRM) fraction of the cells after sucrose gradient centrifugation includes cholesterol-rich membrane microdomains which have been called "lipid rafts". It was reported that some pore-forming toxins require association with DRM and/or lipid rafts to exert their cytotoxicity. It has also been thought that cellular cholesterol is involved in VVH cytotoxicity because VVH cytotoxicity was inhibited by pre-incubation with cholesterol. However, both cellular localization and mode of action of VVH cytotoxicity remain unclear. In this study, we investigated the relationship between VVH localization on the cellular membrane and its cytotoxicity. Oligomers of VVH were detected from DRM fractions by sucrose gradient ultracentrifugation but all of these oligomers shifted from DRM fractions to non-DRM fractions after treatment with methyl-beta-cyclodextrin (MβCD), a cholesterol sequestering agent. On the other hand, immunofluorescence analysis showed that VVH did not co-localize with major lipid raft markers on cellular membrane of CHO cells. These data suggested that VVH localized at membrane regions which are relatively abundant in cholesterol but which are not identical with lipid rafts. To determine the linkage between localization and cytotoxicity of VVH, cytotoxicity was evaluated in MβCD-treated CHO cells. The cytotoxicity of VVH was not decreased by the MβCD treatment. In addition, the amount of VVH oligomer did not decrease in MβCD-treated CHO cells. Thus, we found that the amount of oligomer on cellular membrane is important for induction of cytotoxicity, whereas localization to lipid rafts on the cellular membrane was not essential to cytotoxicity.