Differential role of lipid rafts in the functions of CD4+ and CD8+ human T lymphocytes with aging

Lipid rafts are critical to the assembly of the T-cell receptor (TCR) signaling machinery. It is not known whether lipid raft properties differ in CD4+ and CD8+ T cells and whether there are age-related differences that may account in part for immune senescence. Data presented here showed that time-dependent interleukin-2 (IL-2) production was different between CD4+ and CD8+ T cells. The defect in IL-2 production by CD4+ T cells was not due to lower levels of expression of the TCR or CD28. There was a direct correlation between the activation of p56(Lck) and LAT and their association/recruitment with the lipid raft fractions of CD4+ and CD8+ T cells. p56Lck, LAT and Akt/PKB were weakly phosphorylated in lipid rafts of stimulated CD4+ T cells of elderly as compared to young donors. Lipid rafts undergo changes in their lipid composition (ganglioside M1, cholesterol) in CD4+ and CD8+ T cells of elderly individuals. This study emphasizes the differential role of lipid rafts in CD4+ and CD8+ T-cell activation in aging and suggests that the differential localization of CD28 may explain disparities in response to stimulation in human aging.     

Triglyceride-rich lipoprotein lipolysis increases aggregation of endothelial cell membrane microdomains and produces reactive oxygen species

Triglyceride-rich lipoprotein (TGRL) lipolysis may provide a proinflammatory stimulus to endothelium. Detergent-resistant plasma membrane microdomains (lipid rafts) have a number of functions in endothelial cell inflammation. The mechanisms of TGRL lipolysis-induced endothelial cell injury were investigated by examining endothelial cell lipid rafts and production of reactive oxygen species (ROS). Lipid raft microdomains in human aortic endothelial cells were visualized by confocal microscopy with fluorescein isothiocyanate-labeled cholera toxin B as a lipid raft marker. Incubation of Atto565-labeled TGRL with lipid raft-labeled endothelial cells showed that TGRL colocalized with the lipid rafts, TGRL lipolysis caused clustering and aggregation of lipid rafts, and colocalization of TGRL remnant particles on the endothelial cells aggregated lipid rafts. Furthermore, TGRL lipolysis caused translocation of low-density lipoprotein receptor-related protein, endothelial nitric oxide synthase, and caveolin-1 from raft regions to nonraft regions of the membrane 3 h after treatment with TGRL lipolysis. TGRL lipolysis significantly increased the production of ROS in endothelial cells, and both NADPH oxidase and cytochrome P-450 inhibitors reduced production of ROS. Our studies suggest that alteration of lipid raft morphology and composition and ROS production could contribute to TGRL lipolysis-mediated endothelial cell injury.     

Polyunsaturated eicosapentaenoic acid displaces proteins from membrane rafts by altering raft lipid composition

Polyunsaturated fatty acids (PUFAs) such as eicosapentaenoic acid (20:5 (n-3)) inhibit T lymphocyte activation probably by displacing acylated signaling proteins from membrane lipid rafts. Under physiological conditions, saturated fatty acyl residues of such proteins partition into the cytoplasmic membrane lipid leaflet with high affinity for rafts that are enriched in saturated fatty acyl-containing lipids. However, the biochemical alteration causing displacement of acylated proteins from rafts in PUFA-treated T cells is still under debate but could principally be attributed to altered protein acylation or changes in raft lipid composition. We show that treatment of Jurkat T cells with polyunsaturated eicosapentaenoic acid (20:5 (n-3)) results in marked enrichment of PUFAs (20:5; 22:5) in lipids from isolated rafts. Moreover, PUFAs were significantly incorporated into phosphatidylethanolamine that predominantly resides in the cytoplasmic membrane lipid leaflet. Notably, palmitate-labeled Src family kinase Lck and the linker for activation of T cells (LAT) were both displaced from lipid rafts indicating that acylation by PUFAs is not required for protein displacement from rafts in PUFA-treated T cells. In conclusion, these data provide strong evidence that displacement of acylated proteins from rafts in PUFA-treated T cells is predominantly due to altered raft lipid composition.     

Mycobacterium tuberculosis lipoprotein-induced association of TLR2 with protein kinase C zeta in lipid rafts contributes to reactive oxygen species-dependent inflammatory signalling in macrophages

Membrane lipid rafts are enriched in cholesterol and play an important role as signalling platforms. However, the roles of lipid rafts and associated signalling molecules in the innate immune responses to mycobacteria remain unknown. Here we show that stimulation with Mycobacterium tuberculosis 19 kDa lipoprotein, a TLR2/1 agonist, results in translocation of TLR2 to lipid rafts, coalescence of lipid rafts and production of reactive oxygen species (ROS) that drive pro-inflammatory responses. Disruption of lipid raft organization markedly reduced lipoprotein-induced ROS and inflammatory responses. Remarkably, the atypical protein kinase C (PKC) ζ was specifically recruited into detergent-resistant membrane fractions and associated with TLR2. PKCζ activity was critical for lipoprotein-dependent ROS generation, raft coalescence and the pro-inflammatory responses by macrophages. Moreover, lipid raft organization was required for 19 kDa mediated PKCζ activation. These results demonstrate that TLR2 trafficking and raft coalescence play an essential role for the initiation of lipoprotein-induced innate immune responses via TLR2 and ROS signalling. In addition, PKCζ targets to lipid rafts and may act as a critical adaptor molecule to regulate lipid raft dynamics during TLR2 signalling.     

Dynamic changes in the mobility of LAT in aggregated lipid rafts upon T cell activation

Lipid rafts are known to aggregate in response to various stimuli. By way of raft aggregation after stimulation, signaling molecules in rafts accumulate and interact so that the signal received at a given membrane receptor is amplified efficiently from the site of aggregation. To elucidate the process of lipid raft aggregation during T cell activation, we analyzed the dynamic changes of a raft-associated protein, linker for activation of T cells (LAT), on T cell receptor stimulation using LAT fused to GFP (LAT-GFP). When transfectants expressing LAT-GFP were stimulated with anti-CD3-coated beads, LAT-GFP aggregated and formed patches at the area of bead contact. Photobleaching experiments using live cells revealed that LAT-GFP in patches was markedly less mobile than that in nonpatched regions. The decreased mobility in patches was dependent on raft organization supported by membrane cholesterol and signaling molecule binding sites, especially the phospholipase C gamma 1 binding site in the cytoplasmic domain of LAT. Thus, although LAT normally moves rapidly at the plasma membrane, it loses its mobility and becomes stably associated with aggregated rafts to ensure organized and sustained signal transduction required for T cell activation.     

T-Cell Receptor Microclusters Critical for T-Cell Activation Are Formed Independently of Lipid Raft Clustering

We studied the function of lipid rafts in generation and signaling of T-cell receptor microclusters (TCR-MCs) and central supramolecular activation clusters (cSMACs) at immunological synapse (IS). It has been suggested that lipid raft accumulation creates a platform for recruitment of signaling molecules upon T-cell activation. However, several lipid raft probes did not accumulate at TCR-MCs or cSMACs even with costimulation and the fluorescence resonance energy transfer (FRET) between TCR or LAT and lipid raft probes was not induced at TCR-MCs under the condition of positive induction of FRET between CD3ζ and ZAP-70. The analysis of LAT mutants revealed that raft association is essential for the membrane localization but dispensable for TCR-MC formation. Careful analysis of the accumulation of raft probes in the cell interface revealed that their accumulation occurred after cSMAC formation, probably due to membrane ruffling and/or endocytosis. These results suggest that lipid rafts control protein translocation to the membrane but are not involved in the clustering of raft-associated molecules and therefore that the lipid rafts do not serve as a platform for T-cell activation.Lipid rafts are specialized liquid-ordered membrane microdomains that are enriched in cholesterol and sphingolipids. Many studies using various methodologies have shown that lipid rafts exist as leaflets less than 200 nm in size and float on the plasma membrane (6, 10, 24, 28, 32). They have been implied to play a role in protein sorting and cell activation as a platform by recruiting various signaling molecules such as Src family kinases, G proteins, and adaptor molecules. Because of size limitation, all of the raft-associated molecules could not be accommodated on the same lipid raft, and heterogeneity of lipid rafts both in size and in the repertoire of resident molecules has been suggested (22). The functional importance of lipid rafts in signal transduction has been particularly appreciated in T-cell activation through the T-cell receptor (TCR). Some of the initial observations in this area included the findings that cross-linking of the raft-associated ganglioside GM1 induces T-cell activation (12) and that a mutant of LAT, a membrane adaptor protein, that was unable to localize to rafts failed to induce activation signals (33). Since then, increasing data have demonstrated that lipid raft accumulation creates a platform to stabilize the signaling complex for T-cell activation (13, 29).T cells are activated upon recognition of peptide-major histocompatibility complex (MHC) complexes expressed on antigen-presenting cells (APC). An immunological synapse (IS) is formed at the interface between the T cell and the APC where a specialized segregated structure of T-cell surface receptors is generated. This supramolecular activation cluster (SMAC) contains the TCR in the central region (cSMAC) and lymphocyte function-associated antigen 1 (LFA-1) in the peripheral region (pSMAC). The accumulation of lipid rafts at this interface, particularly in the cSMAC, has been suggested to create a transient structure to mediate signal transduction (13, 17). In addition, CD28-mediated costimulation has been suggested to enhance lipid raft accumulation and TCR activation (29). However, the idea that lipid rafts accumulated in the cSMAC serve as the platform for T-cell activation has been controversial; the accumulation of the lipid raft was only partial in the contact area (3), or the concentration of lipid raft was constant even in the area of T-cell activation (5, 8, 28, 32). These variations could be partly attributed to differences in experimental approaches such as the cell systems being analyzed, stimulation conditions, and detection methods, including imaging and biochemical fractionation. The idea that the cSMAC is the site responsible for inducing signals for T-cell activation has been recently revised based on analysis of the dynamic assembly of signaling complexes upon TCR stimulation. Analysis of T-cell activation using a planar membrane system containing glycosylphosphatidylinositol (GPI)-anchored MHC-peptide complexes and the LFA-1 ligand intercellular adhesion molecule 1 (ICAM-1) revealed that small clusters containing approximately a hundred TCRs, kinases, and adaptors, which we termed TCR microclusters (MCs), were generated at the initial contact sites. This was followed by translocation of the MCs to the center of the interface to generate a cSMAC (31). Since protein phosphorylation, including that of ZAP-70, was induced in the TCR-MCs and Ca²⁺ mobilization was induced in parallel with the formation of TCR-MCs, these MCs appear to be the very first and minimum unit for generating TCR activation signals (31). Furthermore, a major costimulatory receptor, CD28, forms clusters which are also colocalized in TCR-MCs to regulate costimulatory signals (30).Among these TCR proximal signaling molecules, LAT is a well-studied raft-associated membrane adaptor protein that is indispensable for TCR activation. LAT is phosphorylated by ZAP-70 and then behaves as a signal scaffold, recruiting various signaling adaptors and effector molecules such as phospholipase Cγ (PLCγ), SLP-76, and Grb2/Gads. Because mutation of LAT palmitoylation sites (C26,29A) resulted in its dislocation from lipid rafts and defective signaling, it was concluded that the association with lipid rafts is essential for the function of LAT (33). However, a recent study showed that this mutant LAT has impaired trafficking to the plasma membrane in the Jurkat T-cell line (27), raising the question of whether the impaired signaling resulting from this LAT mutation was due to dislocation from the raft or defective trafficking to the membrane.Here, we analyzed the role of lipid rafts in T-cell activation, particularly their relationship with immunological synapse formation (9). Provided that lipid raft functions as a platform for T-cell activation, the new idea that TCR-MCs serve as the signal unit for activation would predict that lipid raft could be accumulated in or interact with TCR-MCs (29).Utilizing several lipid raft probes, which retain the capability of raft localization but lack signaling capacity, we found that the full-length LAT generated MCs, but none of the raft probes formed visible clusters at TCR-MCs or cSMAC, even in conjunction with CD28-mediated costimulation. Furthermore, no significant interaction between lipid rafts and TCR-MCs was revealed by fluorescence resonance energy transfer (FRET) analysis. Conversely, the non-raft-localizing LAT mutant showed MC formation upon TCR stimulation. These results suggest that lipid rafts do not serve as a platform for TCR signaling but rather regulate the traffic/recruitment of proteins to the plasma membrane. Furthermore, our data indicate that the previous observation of lipid raft accumulation at the cSMAC may reflect membrane ruffling and endocytosis rather than active formation of signal platform.     

Microtubules and actin microfilaments regulate lipid raft/caveolae localization of adenylyl cyclase signaling components

Microtubules and actin filaments regulate plasma membrane topography, but their role in compartmentation of caveolae-resident signaling components, in particular G protein-coupled receptors (GPCR) and their stimulation of cAMP production, has not been defined. We hypothesized that the microtubular and actin cytoskeletons influence the expression and function of lipid rafts/caveolae, thereby regulating the distribution of GPCR signaling components that promote cAMP formation. Depolymerization of microtubules with colchicine (Colch) or actin microfilaments with cytochalasin D (CD) dramatically reduced the amount of caveolin-3 in buoyant (sucrose density) fractions of adult rat cardiac myocytes. Colch or CD treatment led to the exclusion of caveolin-1, caveolin-2, beta1-adrenergic receptors (beta1-AR), beta2-AR, Galpha(s), and adenylyl cyclase (AC)5/6 from buoyant fractions, decreasing AC5/6 and tyrosine-phosphorylated caveolin-1 in caveolin-1 immunoprecipitates but in parallel increased isoproterenol (beta-AR agonist)-stimulated cAMP production. Incubation with Colch decreased co-localization (by immunofluorescence microscopy) of caveolin-3 and alpha-tubulin; both Colch and CD decreased co-localization of caveolin-3 and filamin (an F-actin cross-linking protein), decreased phosphorylation of caveolin-1, Src, and p38 MAPK, and reduced the number of caveolae/mum of sarcolemma (determined by electron microscopy). Treatment of S49 T-lymphoma cells (which possess lipid rafts but lack caveolae) with CD or Colch redistributed a lipid raft marker (linker for activation of T cells (LAT)) and Galpha(s) from lipid raft domains. We conclude that microtubules and actin filaments restrict cAMP formation by regulating the localization and interaction of GPCR-G(s)-AC in lipid rafts/caveolae.     

Palmitoylation and intracellular domain interactions both contribute to raft targeting of linker for activation of T cells

Some transmembrane proteins must associate with lipid rafts to function. However, even if acylated, transmembrane proteins should not pack well with ordered raft lipids, and raft targeting is puzzling. Acylation is necessary for raft targeting of linker for activation of T cells (LAT). To determine whether an acylated transmembrane domain is sufficient, we examined raft association of palmitoylated and nonpalmitoylated LAT transmembrane peptides in lipid vesicles by a fluorescence quenching assay, by microscopic examination, and by association with detergent-resistant membranes (DRMs). All three assays detected very low raft association of the nonacylated LAT peptide. DRM association was the same as a control random transmembrane peptide. Acylation did not measurably enhance raft association by the first two assays but slightly enhanced DRM association. The palmitoylated LAT peptide and a FLAG-tagged LAT transmembrane domain construct expressed in cells showed similar DRM association when both were reconstituted into mixed vesicles (containing cell-derived proteins and lipids and excess artificial raft-forming lipids) before detergent extraction. We conclude that the acylated LAT transmembrane domain has low inherent raft affinity. Full-length LAT in mixed vesicles associated better with DRMs than the peptide. However, cells appeared to contain two pools of LAT, with very different raft affinities. Since some LAT (but not the transmembrane domain construct) was isolated in a protein complex, and the Myc- and FLAG-tagged forms of LAT could be mutually co-immunoprecipitated, oligomerization or interactions with other proteins may enhance raft affinity of one pool of LAT. We conclude that both acylation and other factors, possibly protein-protein interactions, target LAT to rafts.     

Lipid rafts: cell surface platforms for T cell signaling

The Src family tyrosine kinase Lck is essential for T cell development and T cell receptor (TCR) signaling. Lck is post-translationally fatty acylated at its N-terminus conferring membrane targeting and concentration in plasma membrane lipid rafts, which are lipid-based organisational platforms. Confocal fluorescence microscopy shows that Lck colocalizes in rafts with GPI-linked proteins, the adaptor protein LAT and Ras, but not with non-raft membrane proteins including the protein tyrosine phosphatase CD45. The TCR also associates with lipid rafts and its cross-linking causes coaggregation of raft-associated proteins including Lck, but not of CD45. Cross-linking of either the TCR or rafts strongly induces specific tyrosine phosphorylation of the TCR in the rafts. Remarkably, raft patching alone induces signalling events analogous to TCR stimulation, with the same dependence on expression of key TCR signalling molecules. Our results indicate a mechanism whereby TCR engagement promotes aggregation of lipid rafts, which facilitates colocalization of signaling proteins including Lck, LAT, and the TCR, while excluding CD45, thereby potentiating protein tyrosine phosphorylation and downstream signaling. We are currently testing this hypothesis as well as using imaging techniques such as fluorescence resonance energy transfer (FRET) microscopy to study the dynamics of proteins and lipids in lipid rafts in living cells undergoing signaling events. Recent data show that the key phosphoinositide PI(4,5)P2 is concentrated in T cell lipid rafts and that on stimulation of the cells it is rapidly converted to PI(3,4,5)P3 and diacylglycerol within rafts. Thus rafts are hotspots for both protein and lipid signalling pathways.     

Lycopene suppresses proinflammatory response in lipopolysaccharide-stimulated macrophages by inhibiting ROS-induced trafficking of TLR4 to lipid raft-like domains

We recently showed that lycopene inhibited lipopolysaccharide (LPS)-induced productions of nitric oxide (NO) and interleukin-6 (IL-6) in murine RAW264.7 macrophages by mechanisms related to inhibition of ERK and nuclear factor-κB. Since the assembly of Toll-like receptor 4 (TLR4) in lipid rafts is a key element in LPS induced signaling, we investigated whether this process would be influenced by lycopene. We found that pretreatment of RAW264.7 cells with lycopene inhibited LPS-induced recruitment of TLR4 into fractions — enriched with lipid raft marker. By the methods of immunoprecipitation and immunoblotting, we also found that lycopene inhibited the subsequent formation of the complex of TLR4 with its adaptors including myeloid differentiation primary-response protein 88 and TIR domain–containing adaptor-inducing IFN-β. We also found that the lycopene induced inhibition was associated with reduced formation of reactive oxygen species (ROS), which was an upstream mechanism for the effects of lycopene, because treating the cells with the antioxidant N-acetyl-l-cysteine and NADPH oxidase inhibitor diphenyleneiodonium chloride significantly inhibited LPS-induced recruitment of TLR4 into lipid raft-like domains as well as the production of proinflammatory molecule NO and IL-6. Thus, our findings suggest that lycopene may prevent LPS-induced TLR4 assembly into lipid rafts through reducing intracellular ROS level.     

B and T lymphocyte attenuator interacts with CD3zeta and inhibits tyrosine phosphorylation of TCRzeta complex during T-cell activation

B and T lymphocyte attenuator (BTLA) is an important negative regulator of T-cell activation. T-cell activation involves partitioning of receptors into discrete membrane compartments known as lipid rafts and the formation of an immunological synapse (IS) between the T cell and antigen-presenting cell (APC). Here we show that after T-cell stimulation, BTLA co-clusters with the CD3zeta and is then involved in IS, as determined by a two-photon microscope. BTLA can interact with the phosphorylated form of T-cell receptor (TCR) within the lipid raft, which is associated with the T-cell signaling complex. Coligation of BTLA with the TCR significantly decreased the amount of phosphorylated TCR-related signal accumulation in the lipid raft during T-cell activation. These results suggest that BTLA functions to regulate T-cell signaling by controlling the phosphorylated form of TCRzeta accumulation in the lipid raft.     

Cold Induces Micro- and Nano-Scale Reorganization of Lipid Raft Markers at Mounds of T-Cell Membrane Fluctuations

Whether and how cold causes changes in cell-membrane or lipid rafts remain poorly characterized. Using the NSOM/QD and confocal imaging systems, we found that cold caused microscale redistribution of lipid raft markers, GM1 for lipid and CD59 for protein, from the peripheral part of microdomains to the central part on Jurkat T cells, and that cold also induced the nanoscale size-enlargement (1/3- to 2/3-fold) of the nanoclusters of lipid raft markers and even the colocalization of GM1 and CD59 nanoclusters. These findings indicate cold-induced lateral rearrangement/coalescence of raft-related membrane heterogeneity. The cold-induced re-distribution of lipid raft markers under a nearly-natural condition provide clues for their alternations, and help to propose a model in which raft lipids associate themselves or interact with protein components to generate functional membrane heterogeneity in response to stimulus. The data also underscore the possible cold-induced artifacts in early-described cold-related experiments and the detergent-resistance-based analyses of lipid rafts at 4°C, and provide a biophysical explanation for recently-reported cold-induced activation of signaling pathways in T cells. Importantly, our fluorescence-topographic NSOM imaging demonstrated that GM1/CD59 raft markers distributed and re-distributed at mounds but not depressions of T-cell membrane fluctuations. Such mound-top distribution of lipid raft markers or lipid rafts provides spatial advantage for lipid rafts or contact molecules interacting readily with neighboring cells or free molecules.     

Palmitoylation of LAT contributes to its subcellular localization and stability

Palmitoylation is a protein modification for trafficking to lipid raft. Without palmitoylation, linker for activation of T cells (LAT), an adaptor molecule mediating T cell receptor signaling, is unable to localize in lipid rafts and to mediate T cell activation. We here show a novel role for palmitoylation in LAT trafficking to the plasma membrane and in the stability of the LAT protein. The human LAT mutant lacking palmitoylation was unable to traffic to the plasma membrane despite the presence of transmembrane portion. The mouse LAT mutant lacking palmitoylation was unstable and susceptible to degradation via the proteasome pathway. The human LAT mutant became unstable when the extracellular portion was swapped for that from mouse, indicating that both palmitoylation and the extracellular portion regulate the stability of LAT. These results suggest that palmitoylation has an important role in trafficking to the plasma membrane and the stability of LAT.     

LAT displacement from lipid rafts as a molecular mechanism for the inhibition of T cell signaling by polyunsaturated fatty acids

Polyunsaturated fatty acids (PUFAs) suppress immune responses and inhibit T cell activation through largely unknown mechanisms. The displacement of signaling proteins from membrane lipid rafts has recently been suggested as underlying PUFA-mediated T cell inhibition. We show here that PUFA treatment specifically interferes with T cell signal transduction by blocking tyrosine phosphorylation of LAT (linker for activation of T cells) and phospholipase Cgamma1. A significant fraction of LAT was displaced from rafts by PUFA treatment along with other signaling proteins. However, retaining LAT alone in lipid rafts effectively restored phospholipase Cgamma1/calcium signaling in PUFA-treated T cells. These data reveal LAT displacement from lipid rafts as a molecular mechanism by which PUFAs inhibit T cell signaling and underline the predominant importance of LAT localization in rafts for efficient T cell activation.     

Acidic sphingomyelinase induced by electrophiles promotes proinflammatory cytokine production in human bladder carcinoma ECV-304 cells

Electrophiles in environmental pollutants or cigarette smoke are high risk factors for various diseases caused by cell injuries such as apoptosis and inflammation. Here we show that electrophilic compounds such as diethyl malate (DEM), methyl mercury and cigarette smoke extracts significantly enhanced the expression of acidic sphingomyelinase (ASMase). ASMase activity and the amount of ceramide of DEM-treated cells were approximately 6 times and 4 times higher than these of non-treated cells, respectively. Moreover, we found that DEM pretreatment enhanced the production of IL-6 induced by TNF-α. Knockdown of ASMase attenuated the enhancement of TNF-α-dependent IL-6 production. On the other hand, enhancement of TNF-α-induced IL-6 production was observed in ASMase-overexpressing cells without DEM. Fractionation of the lipid raft revealed that the TNF receptor 1 (TNFR1) was migrated into the lipid raft in DEM-treated cells or ASMase-overexpressing cells. The TNF-α-induced IL-6 expression required the clustering of TNFR1 since IL-6 expression were decreased by the destruction of the lipid raft with filipin. These results demonstrated a new role for ASMase in the acceleration of the production of TNF-induced IL-6 as a pro-inflammatory cytokine and indicated that electrophiles could potentiate inflammation response by up-regulating of ASMase expression following formation of lipid rafts.     

The death-inducing signalling complex is recruited to lipid rafts in Fas-induced apoptosis

Membrane microdomains known as lipid rafts have been shown recently to be involved in Fas signalling and apoptosis in T and B cell lines. Here, we have investigated further the role of lipid rafts in Fas-induced apoptosis in non-transformed human CD4 T cells. We show that Fas-induced apoptosis in CD4 T cells was inhibited by the lipid raft disrupter methyl-beta-cyclodextrin. When lipid rafts were isolated from control and Fas ligand treated cells, we found that a small proportion of Fas was present in the raft fraction in untreated cells and that this was greatly increased upon Fas ligation. The other components of the Death Inducing Signalling Complex (DISC), FADD, and procaspase 8, were also present at higher levels in the raft fraction isolated from Fas ligand treated cells. We conclude that formation of the DISC occurs in lipid rafts and that these membrane microdomains are required for efficient Fas signalling and apoptosis.     

7-Dehydrocholesterol enhances ultraviolet A-induced oxidative stress in keratinocytes: roles of NADPH oxidase, mitochondria, and lipid rafts

Long wavelength solar UVA radiation stimulates formation of reactive oxygen species (ROS) and prostaglandin E(2) (PGE(2)), which are involved in skin photosensitivity and tumor promotion. High levels of 7-dehydrocholesterol (7-DHC), the precursor to cholesterol, cause exaggerated photosensitivity to UVA in patients with Smith-Lemli-Opitz syndrome (SLOS). Partially replacing cholesterol with 7-DHC in keratinocytes rapidly (<5 min) increased UVA-induced ROS, intracellular calcium, phospholipase A(2) activity, PGE(2), and NADPH oxidase activity. UVA-induced ROS and PGE(2) production were inhibited in these cells by depleting the Nox1 subunit of NADPH oxidase using siRNA or using a mitochondrial radical quencher, MitoQ. Partial replacement of cholesterol with 7-DHC also disrupted membrane lipid raft domains, although depletion of cholesterol, which also disrupts lipid rafts, did not affect UVA-induced increases in ROS and PGE(2). Phospholipid liposomes containing 7-DHC were more rapidly oxidized by a free radical mechanism than those containing cholesterol. These results indicate that 7-DHC enhances rapid UVA-induced ROS and PGE(2) formation by enhancing free radical-mediated membrane lipid oxidation and suggests that this mechanism might underlie the UVA photosensitivity in SLOS.     

Cutting Edge: Localization of linker for activation of T cells to lipid rafts is not essential in T cell activation and development

It has been proposed that upon T cell activation, linker for activation of T cells (LAT), a transmembrane adaptor protein localized to lipid rafts, orchestrates formation of multiprotein complexes and activates signaling cascades in lipid rafts. However, whether lipid rafts really exist or function remains controversial. To address the importance of lipid rafts in LAT function, we generated a fusion protein to target LAT to nonraft fractions using the transmembrane domain from a nonraft protein, linker for activation of X cells (LAX). Surprisingly, this fusion protein functioned well in TCR signaling. It restored MAPK activation, calcium flux, and NFAT activation in LAT-deficient cells. To further study the function of this fusion protein in vivo, we generated transgenic mice that express this protein. Analysis of these mice indicated that it was fully capable of replacing LAT in thymocyte development and T cell function. Our results demonstrate that LAT localization to lipid rafts is not essential during normal T cell activation and development.