Lipid rafts and regulation of the cytoskeleton during T cell activation

The ability of polarized cells to initiate and sustain directional responses to extracellular signals is critically dependent on direct communication between spatially organized signalling modules in the membrane and the underlying cytoskeleton. Pioneering work in T cells has shown that the assembly of signalling modules critically depends on the functional compartmentalization of membrane lipids into ordered microdomains or lipid rafts. The significance of rafts in T cell activation lies not only in their ability to recruit the signalling partners that eventually assemble into a mature immunological synapse but also in their ability to regulate actin dynamics and recruit cytoskeletal associated proteins, thereby achieving the structural polarization underlying stability of the synapse-a critical prerequisite for activation to be sustained. Lipid rafts vary quite considerably in size and visualizing the smallest of them in vivo has been challenging. Nonetheless it is now been shown quite convincingly that a surprisingly large proportion-in the order of 50%-of external membrane lipids (chiefly cholesterol and glycosphingolipids) can be dynamically localized in these liquid ordered rafts. Complementary inner leaflet rafts are less well characterized, but contain phosphoinositides as an important functional component that is crucial for regulating the behaviour of the actin cytoskeleton. This paper provides an overview of the interdependency between signalling and cytoskeletal polarization, and in particular considers how regulation of the cytoskeleton plays a crucial role in the consolidation of rafts and their stabilization into the immunological synapse.     

A novel approach to examining compositional heterogeneity of detergent-resistant lipid rafts

Lipid rafts play an important role in cell signalling, cell adhesion and other cellular functions. Compositional heterogeneity of lipid rafts provides one mechanism of how lipid rafts provide the spatial and temporal regulation of cell signalling and cell adhesion. The constitutive presence of some signalling receptors/molecules and accumulation of others in the lipid raft allows them to interact with each other and thereby facilitate relay of signals from the plasma membrane to the cell interior. Devising a method that can analyze these lipid microdomains for the presence of signalling receptors/molecules on an individual raft basis is required to address the issue of lipid raft heterogeneity. SDS-PAGE analysis, currently used for analyses of detergent-resistant lipid rafts, does not address this question. We have designed a cell-free assay that captures detergent-resistant lipid rafts with an antibody against a raft-resident molecule and detects the presence of another lipid raft molecule. Our results suggest that detergent-resistant lipid rafts, also known as detergent-resistant membranes, are heterogeneous populations on an immortalized mouse T-cell plasma membrane with respect to antigen receptor/signalling complex and other signalling/adhesion proteins. This cell-free assay provides a simple and quick way to examine the simultaneous presence of two proteins in the lipid rafts and has the potential to estimate trafficking of molecules in and out of the lipid microdomains during cell signalling on a single detergent-resistant lipid raft basis.     

Regulation of TrkB receptor translocation to lipid rafts by adenosine A2A receptors and its functional implications for BDNF-induced regulation of synaptic plasticity

Brain-derived neurotrophic factor (BDNF) signalling is critical for neuronal development and transmission. Recruitment of TrkB receptors to lipid rafts has been shown to be necessary for the activation of specific signalling pathways and modulation of neurotransmitter release by BDNF. Since TrkB receptors are known to be modulated by adenosine A_2A receptor activation, we hypothesized that activation of A_2A receptors could influence TrkB receptor localization among different membrane microdomains. We found that adenosine A_2A receptor agonists increased the levels of TrkB receptors in the lipid raft fraction of cortical membranes and potentiated BDNF-induced augmentation of phosphorylated TrkB levels in lipid rafts. Blockade of the clathrin-mediated endocytosis with monodansyl cadaverine (100 μM) did not modify the effects of the A_2A receptor agonists, but significantly impaired BDNF effects on TrkB recruitment to lipid rafts. The effect of A_2A receptor activation in TrkB localization was mimicked by 5 μM forskolin, an adenylyl cyclase activator. Also, it was blocked by the PKA inhibitors Rp-cAMPs and PKI-(14-22) and by the Src-family kinase inhibitor PP2. Moreover, removal of endogenous adenosine or disruption of lipid rafts reduced BDNF stimulatory effects on glutamate release from cortical synaptosomes. Lipid raft integrity was also required for the effects of BDNF upon hippocampal long-term potentiation at CA1 synapses. Our data demonstrate, for the first time, a BDNF-independent recruitment of TrkB receptors to lipid rafts, induced by the activation of adenosine A_2A receptors, with functional consequences for TrkB phosphorylation and BDNF-induced modulation of neurotransmitter release and hippocampal plasticity.     

Lipid rafts are critical membrane domains in blood platelet activation processes

Among the various hematopoi;etic cells, platelets are critical for maintaining the integrity of the vascular system. They must be rapidly activated by sequential and coordinated mechanisms in order to efficiently prevent haemorrhage upon vascular injury. Several signal transduction pathways lead to platelet activation in vitro and in vivo, among them, several are initiated via receptors or co-receptors containing immuno-receptor tyrosine-based activation motifs (ITAM) which trigger downstream signalling like the immune receptors in lymphocytes. However, in contrast to immune cells for which the role of lipid rafts in signalling has largely been described, the involvement of laterally segregated membrane microdomains in platelet activation has been investigated only recently. The results obtained until now strongly suggest that early steps of platelet activation via the collagen receptor GpVI or via FcgammaRIIa occur preferentially in these microdomains where specific proteins efficiently organize key downstream signalling pathways. In addition, lipid rafts also contribute to platelet activation via heterotrimeric G-protein-coupled receptors. They are sites where the phosphoinositide (PI) metabolism is highly active, leading to a local generation of lipid second messengers such as phosphatidylinositol 3,4,5-trisphosphate. Here, evidence is accumulating that cholesterol-enriched membrane microdomains are part of a general process that contributes to the efficiency and the coordination of platelet activation mechanisms. Here we will discuss the biochemical and functional characterizations of human platelet rafts and their potential impact in platelet physiopathology.     

Lipid rafts are critical membrane domains in blood platelet activation processes

Among the various hematopo?̈etic cells, platelets are critical for maintaining the integrity of the vascular system. They must be rapidly activated by sequential and coordinated mechanisms in order to efficiently prevent haemorrhage upon vascular injury. Several signal transduction pathways lead to platelet activation in vitro and in vivo, among them, several are initiated via receptors or co-receptors containing immuno-receptor tyrosine-based activation motifs (ITAM) which trigger downstream signalling like the immune receptors in lymphocytes. However, in contrast to immune cells for which the role of lipid rafts in signalling has largely been described, the involvement of laterally segregated membrane microdomains in platelet activation has been investigated only recently. The results obtained until now strongly suggest that early steps of platelet activation via the collagen receptor GpVI or via FcγRIIa occur preferentially in these microdomains where specific proteins efficiently organize key downstream signalling pathways. In addition, lipid rafts also contribute to platelet activation via heterotrimeric G-protein-coupled receptors. They are sites where the phosphoinositide (PI) metabolism is highly active, leading to a local generation of lipid second messengers such as phosphatidylinositol 3,4,5-trisphosphate. Here, evidence is accumulating that cholesterol-enriched membrane microdomains are part of a general process that contributes to the efficiency and the coordination of platelet activation mechanisms. Here we will discuss the biochemical and functional characterizations of human platelet rafts and their potential impact in platelet physiopathology.     

Lipid rafts and little caves. Compartmentalized signalling in membrane microdomains.

Lipid rafts are liquid-ordered membrane microdomains with a unique protein and lipid composition found on the plasma membrane of most, if not all, mammalian cells. A large number of signalling molecules are concentrated within rafts, which have been proposed to function as signalling centres capable of facilitating efficient and specific signal transduction. This review summarizes current knowledge regarding the composition, structure, and dynamic nature of lipid rafts, as well as a number of different signalling pathways that are compartmentalized within these microdomains. Potential mechanisms through which lipid rafts carry out their specialized role in signalling are discussed in light of recent experimental evidence.     

Membrane lipid rafts: new targets for immunoregulation

Engagement of immune receptors by antigen may lead to activation, cell proliferation, differentiation and effector functions. It has recently been proposed that the initiation and propagation of the signaling events taking place in immune cells occur in specialized membrane regions called lipid rafts. These detergent-insoluble glycolipid domains are specialized membrane compartments enriched in cholesterol and glycolipids. They also contain many lipid-modified signaling proteins such as tyrosine kinases of the Src family, GPI (glycosylphosphatidylinositol)-linked proteins as well as adaptor proteins. The confinement of signaling molecules in membrane subdomains suggests that lipid rafts function as platforms for the formation of multicomponent transduction complexes. Indeed, upon receptor binding, immune receptors become raft-associated and additional components of the signaling pathways are recruited to rafts in order to form signaling complexes. It has been speculated that the entry of immune receptors into rafts can regulate cell activation. Accordingly, numerous experiments have provided substantial evidence that raft integrity is crucial for the initiation and maintenance of intracellular signals. Recent studies have also shown that the access and translocation of immune receptors to lipid rafts are developmentally regulated (immature versus mature cells, Th1 versus Th2 lymphocytes) and sensitive to pharmacological agents. The aim of the present review is to summarize the current knowledge of immune receptor signal transduction with particular emphasis on the role of membrane compartments in immune activation. Finally, experimental evidences indicating that these membrane structures may represent clinically relevant potential targets for immune regulation, will be discussed.     

Lipid rafts in health and disease

Lipid rafts are sphingolipid- and cholesterol-rich domains of the plasma membrane which contain a variety of signalling and transport proteins. Different subtypes of lipid rafts can be distinguished according to their protein and lipid composition. Caveolae are types of rafts that are rich in proteins of the caveolin family (caveolin-1, -2 and -3) which present a distinct signalling platform. The importance of lipid raft signalling in the pathogenesis of a variety of conditions, such as Alzheimer's, Parkinson's, cardiovascular and prion diseases, systemic lupus erythematosus and HIV, has been elucidated over recent years and makes these specific membrane domains an interesting target for pharmacological approaches in the cure and prevention of these diseases. This Review analyses the importance of lipid raft proteins and lipids in health and disease, with a focus on the current state of knowledge.     

生物膜结构研究的一些进展

膜蛋白三维结构的解析存在很多困难.最近几年由于一些通道(如K⁺通道,Cl^-通道,水通道Aquaporin 1等)和泵（如Ca^2＋泵）的结晶获得成功,这些膜蛋白具有原子分辨率三维结构的解析才得以完成,从而基本阐明一些极性分子和离子选择性通过生物膜的分子机理.在膜脂结构方面,动物细胞质膜膜脂的分布是不均匀的.近年来已多方面证明,质膜具有一些被命名为“脂筏（lipid rafts）”和“质膜微囊（Caveolae）”的微区.它们富含鞘脂和胆固醇。简单介绍了这些脂质微区的大小、组分以及动态变化.根据研究结果,这类脂质微区含有大量信号分子,很可能具有信号传递中心的作用.此外,对脂筏在膜运送过程中的作用也进行一些评述.     

Detergent-insoluble glycosphingolipid/cholesterol-rich membrane domains, lipid rafts and caveolae (review).

Within the cell membrane glycosphingolipids and cholesterol cluster together in distinct domains or lipid rafts, along with glycosyl-phosphatidylinositol (GPI)-anchored proteins in the outer leaflet and acylated proteins in the inner leaflet of the bilayer. These lipid rafts are characterized by insolubility in detergents such as Triton X-100 at 4 degrees C. Studies on model membrane systems have shown that the clustering of glycosphingolipids and GPI-anchored proteins in lipid rafts is an intrinsic property of the acyl chains of these membrane components, and that detergent extraction does not artefactually induce clustering. Cholesterol is not required for clustering in model membranes but does enhance this process. Single particle tracking, chemical cross-linking, fluorescence resonance energy transfer and immunofluorescence microscopy have been used to directly visualize lipid rafts in membranes. The sizes of the rafts observed in these studies range from 70-370 nm, and depletion of cellular cholesterol levels disrupts the rafts. Caveolae, flask-shaped invaginations of the plasma membrane, that contain the coat protein caveolin, are also enriched in cholesterol and glycosphingolipids. Although caveolae are also insoluble in Triton X-100, more selective isolation procedures indicate that caveolae do not equate with detergent-insoluble lipid rafts. Numerous proteins involved in cell signalling have been identified in caveolae, suggesting that these structures may function as signal transduction centres. Depletion of membrane cholesterol with cholesterol binding drugs or by blocking cellular cholesterol biosynthesis disrupts the formation and function of both lipid rafts and caveolae, indicating that these membrane domains are involved in a range of biological processes.     

Ethanol mimics ligand-mediated activation and endocytosis of IL-1RI/TLR4 receptors via lipid rafts caveolae in astroglial cells

We have recently reported that ethanol-induced inflammatory processes in the brain and glial cells are mediated via the activation of interleukin-1 beta receptor type I (IL-1RI)/toll-like receptor type 4 (TLR4) signalling. The mechanism(s) by which ethanol activates these receptors in astroglial cells remains unknown. Recently, plasma membrane microdomains, lipid rafts, have been identified as platforms for receptor signalling and, in astrocytes, rafts /caveolae constitute an important integrators of signal events and trafficking. Here we show that stimulation of astrocytes with IL-1β, lipopolysaccharide or ethanol (10 and 50 mM), triggers the translocation of IL-1RI and/or TLR4 into lipid rafts caveolae-enriched fractions, promoting the recruitment of signalling molecules (phospho-IL-1R-associated kinase and phospho-extracellular regulated-kinase) into these microdomains. With confocal microscopy, we further demonstrate that IL-1RI is internalized by caveolar endocytosis via enlarged caveosomes organelles upon IL-1β or ethanol treatment, which sorted their IL-1RI cargo into the endoplasmic reticulum–Golgi compartment and into the nucleus of astrocytes. In short, our findings demonstrate that rafts /caveolae are critical for IL-1RI and TLR4 signalling in astrocytes, and reveal a novel mechanism by which ethanol, by interacting with lipid rafts caveolae, promotes IL-1RI and TLR4 receptors recruitment, triggering their endocytosis via caveosomes and downstream signalling stimulation. These results suggest that TLRs receptors are important targets of ethanol-induced inflammatory damage in the brain.     

Lipid rafts and the control of neurotrophic factor signaling in the nervous system: variations on a theme

Lipid rafts are specialized, liquid-ordered subdomains of the plasma membrane. Through their ability to promote specific compartmentalization of lipids and membrane proteins, lipid rafts have emerged as membrane platforms specialized for signal transduction. In recent years, signaling by neurotrophic factors and their receptors has been shown to depend upon the integrity and function of lipid rafts and associated components. It has also been shown that these microdomains play critical roles in selective axon-dendritic sorting and the proteolytic processing of several neurotrophic ligands and receptors in neuronal cells. The available evidence supports an important role for lipid rafts in the initiation, propagation and maintenance of signal transduction events triggered by different neurotrophic factors and their receptors in the nervous system.     

Annexin A6 is an organizer of membrane microdomains to regulate receptor localization and signalling

Annexin A6 (AnxA6) belongs to the conserved annexin protein family--a group of Ca(2+) -dependent membrane binding proteins. It is the largest of all annexin proteins and upon activation, binds to negatively charged phospholipids in the plasma membrane and endosomes. In addition, AnxA6 associates with cholesterol-rich membrane microdomains termed lipid rafts. Membrane cholesterol triggers Ca(2+) -independent translocation of AnxA6 to membranes and AnxA6 levels determine the number of caveolae, a form of specialized rafts at the cell surface. AnxA6 also has an F-actin binding domain and interacts with cytoskeleton components. Taken together, this suggests that AnxA6 has a scaffold function to link membrane microdomains with the organization of the cytoskeleton. Such a link facilitates AnxA6 to participate in plasma membrane repair and it would also impact on receptor signalling at the cell surface, growth factor, and lipoprotein receptor trafficking, Ca(2+) -channel activity and T cell activation. Hence, the regulation of cell surface receptors by AnxA6 may be facilitated by its unique structure that allows recruitment of interaction partners and simultaneously bridging specialized membrane domains with cortical actin surrounding activated receptors.     

Consequences of lipid raft association on G-protein-coupled receptor function

GPCRs (G-protein-coupled receptors) play key roles in many cellular processes, and malfunction may lead to a range of pathologies, including psychiatric and neurological disorders. It is therefore not surprising that this group of receptors supplies a majority of the targets for pharmaceutical drug development. Despite their importance, the mechanisms that regulate their function and signalling still remain only partially understood. Recently, it has become evident that a subset of GPCRs is not homogeneously distributed in the plasma membrane, but localizes instead to specific membrane microdomains known as lipid rafts. Lipid rafts are characterized by their enrichment in cholesterol and sphingolipids, and have been suggested to serve as platforms for a range of cellular signalling complexes. In the present review, we will be discussing the effects of the lipid raft environment on trafficking, signalling and internalization of raft-associated GPCRs.     

Role of lipid rafts in agrin-elicited acetylcholine receptor clustering

Emerging concepts of membrane organization point to the compartmentalization of the plasma membrane into distinct lipid microdomains. This lateral segregation within cellular membranes is based on cholesterol-sphingolipid-enriched microdomains or lipid rafts which can move laterally and assemble into large-scale domains to create plasma membrane specialized cellular structures at specific cell locations. Such domains are likely involved in the genesis of the postsynaptic specialization at the neuromuscular junction, which requires the accumulation of acetylcholine receptors (AChRs), through activation of the muscle specific kinase MuSK by the neurotropic factor agrin and the reorganization of the actin cytoskeleton. We used C2C12 myotubes as a model system to investigate whether agrin-elicited AChR clustering correlated with lipid rafts. In a previous study, using two-photon Laurdan confocal imaging, we showed that agrin-induced AChR clusters corresponded to condensed membrane domains: the biophysical hallmark of lipid rafts [F. Stetzkowski-Marden, K. Gaus, M. Recouvreur, A. Cartaud, J. Cartaud, Agrin elicits membrane condensation at sites of acetylcholine receptor clusters in C2C12 myotubes, J. Lipid Res. 47 (2006) 2121-2133]. We further demonstrated that formation and stability of AChR clusters depend on cholesterol. We also reported that three different extraction procedures (Triton X-100, pH 11 or isotonic Ca++, Mg++ buffer) generated detergent resistant membranes (DRMs) with similar cholesterol/GM1 ganglioside content, which are enriched in several signalling postsynaptic components, notably AChR, the agrin receptor MuSK, rapsyn and syntrophin. Upon agrin engagement, actin and actin-nucleation factors such as Arp2/3 and N-WASP were transiently recovered within raft fractions suggesting that the activation by agrin can trigger actin polymerization. Taken together, the present data suggest that AChR clustering at the neuromuscular junction relies upon a mechanism of raft coalescence driven by agrin-elicited actin polymerization.     

The platelet receptor for type III collagen (TIIICBP) is present in platelet membrane lipid microdomains (rafts)

Platelet interactions with collagen are orchestrated by the presence or the migration of platelet receptor(s) for collagen into lipid rafts, which are specialized lipid microdomains from the platelet plasma membrane enriched in signalling proteins. Electron microscopy shows that in resting platelets, TIIICBP, a receptor specific for type III collagen, is present on the platelet membrane and associated with the open canalicular system, and redistributes to the platelet membrane upon platelet activation. After platelet lysis by 1% Triton X-100 and the separation of lipid rafts on a discontinuous sucrose gradient, TIIICBP is recovered in lipid raft-containing fractions and Triton X-100 insoluble fractions enriched in cytoskeleton proteins. Platelet aggregation, induced by type III collagen, was inhibited after disruption of the lipid rafts by cholesterol depletion, whereas platelet adhesion under static conditions did not require lipid raft integrity. These results indicate that TIIICBP, a platelet receptor involved in platelet interaction with type III collagen, is localized within platelet lipid rafts where it could interact with other platelet receptors for collagen (GP VI and α2β1 integrin) for efficient platelet activation. Pascal Maurice and Ludovic Waeckel have contributed equally to this work.     

Lipid rafts in T cell receptor signalling

The molecular events and the protein components that are involved in signalling by the T cell receptor (TCR) for antigen have been extensively studied. Activation of signalling cascades following TCR stimulation depends on the phosphorylation of the receptor by the tyrosine kinase Lck, which localizes to the cytoplasmic face of the plasma membrane by virtue of its post-translational modification. However, the precise order of events during TCR phosphorylation at the plasma membrane, remains to be defined. A current theory that describes early signalling events incorporates the function of lipid rafts, microdomains at the plasma membrane with distinct lipid and protein composition. Lipid rafts have been implicated in diverse biological functions in mammalian cells. In T cells, molecules with a key role in TCR signalling, including Lck, localize to these domains. Importantly, mutant versions of these proteins which fail to localise to raft domains were unable to support signalling by the TCR. Biochemical studies using purified detergent-resistant membranes (DRM) and confocal microscopy have suggested that upon stimulation, the TCR and Lck-containing lipid rafts may come into proximity allowing phosphorylation of the receptor. Further, there are data suggesting that phosphorylation of the TCR could depend on a transient increase in Lck activity that takes place within lipid rafts to initiate signalling. Current results and a model of how lipid rafts may regulate TCR signalling are discussed.     

Critical role for lipid raft-associated Src kinases in activation of PI3K-Akt signalling

Lipid rafts are membrane microdomains distinct from caveolae, whose functions in polypeptide growth factor signalling remain unclear. Here we show that in small cell lung cancer (SCLC) cells, specific growth factor receptors such as c-Kit associate with lipid rafts and that these domains play a critical role in the activation of phosphoinositide 3-kinase (PI3K) signalling. The class IA p85/p110alpha associated with Src in lipid rafts and was activated by Src in vitro. Lipid raft integrity was essential for Src activation in response to stem cell factor (SCF) and raft disruption selectively inhibited activation of protein kinase B (PKB)/Akt in response to SCF stimulation. Moreover, inhibition of Src kinases blocked PKB/Akt activation and SCLC cell growth. The use of fibroblasts with targeted deletion of the Src family kinase genes confirmed the role of Src kinases in PKB/Akt activation by growth factor receptors. Moreover a constitutively activated mutant of Src also stimulated PI3K/Akt in lipid rafts, indicating that these microdomains play a role in oncogenic signalling. Together our data demonstrate that lipid rafts play a key role in the activation of PI3K signalling by facilitating the interaction of Src with specific PI3K isoforms.     

Cellular lipid dynamics

During the past years, the notion of microdomains at the surface of cellular membranes has been developed. These are constituted by lipid rafts which involve sphingoglycolipids and cholesterol. To these rafts are associated proteins which have a lipid anchor or are transmembrane proteins. These lipid rafts target specific proteins at the plasma membrane surface and can remain associated with them. They are present in surface receptors and endocytosis occurs upon binding of the specific ligands. Thus these rafts participate to major aspects of cellular dynamics. These rafts are complex structures, insoluble in non-ionic detergents. According to the detergent used, many types of rafts can be isolated. Any alteration of cholesterol, sphingoglycolipids, or abnormalities of the proteins themselves, can lead to abnormal targeting at the membrane surface. It is possible that specific sphingoglycolipids are necessary to target specific proteins at the membrane surface. This may explain the complexity of the sphingoglycolipid molecules, both in relation to their oligosaccharide and to their ceramide structures. There is both a cellular and a tissue specificity of these constituents. Complex sphingoglycolipids are involved in cellular differentiation, cellular polarization, and modified in relation to cancer. Virus and bacteria can be linked to the sphingoglycolipids of these microdomains and alter cellular signaling and function. Sphingoglycolipids are involved in autoimmune diseases as antibody targets and in neurolipidoses which are genetic diseases involving their catabolism. The dynamics of the lipid rafts, in relation to cholesterol, can be altered in Niemann-Pick's disease type C and in Alzheimer's disease. Thus these microdomains are involved in many aspects related to normal and pathological cellular dynamics.