Association of heat shock proteins and neuronal membrane components with lipid rafts from the rat brain

Lipid rafts are specialized plasma membrane microdomains enriched in cholesterol and sphingolipids that serve as major assembly and sorting platforms for signal transduction complexes. Constitutively expressed heat shock proteins Hsp90, Hsc70, Hsp60, and Hsp40 and a range of neurotransmitter receptors are present in lipid rafts isolated from rat forebrain and cerebellum. Depletion of cholesterol dissociates these proteins from lipid rafts. After hyperthermic stress, flotillin-1, a lipid raft marker protein, does not show major change in levels. Stress-inducible Hsp70 is detected in lipid rafts at 1 hr posthyperthermia, with the peak levels attained at 24 hr, suggesting that Hsp70 may play roles in maintaining the stability of lipid raft-associated signal transduction complexes following neural stress.     

Developmental partitioning of myelin basic protein into membrane microdomains

Specific membrane microdomains (including lipid rafts) exist in myelin but have not been fully characterized. Myelin basic protein (MBP) maintains the compactness of the myelin sheath and is highly posttranslationally modified. Thus, it has been suggested that MBP might also have other functions, e.g., in signal transduction. Here, the distribution of MBP and its modified forms was studied, spatially and temporally, by detailed characterization of membrane microdomains from developing and mature bovine myelin. Myelin membranes were extracted with three different detergents (Brij 96V, CHAPS, or Triton X-100) at 4 degrees C. The detergent-resistant membranes (DRMs), representing coalesced lipid rafts, were isolated as low-buoyant-density fractions on a sucrose density gradient. These myelin rafts were disrupted when cholesterol was depleted with methyl-beta-cyclodextrin. The use of CHAPS detergent led to enrichment of several myelin proteins, including phospho-Thr97-MBP, in the DRMs from mature myelin. Citrullinated and methylated MBP remained in "nonraft" microdomains. In contrast, the DRMs from early myelin were enriched in Golli-MBP, Fyn, Lyn, and CNP. The localization of various proteins in DRMs was further supported by the colocalization of these lipid raft components in cultured mouse oligodendrocytes. Thus, there is a developmental regulation of posttranslationally modified forms of MBP into specific membrane microdomains.     

Regulation of AMPA receptor localization in lipid rafts

Lipid rafts are special microdomains enriched in cholesterol, sphingolipids and certain proteins, and play important roles in a variety of cellular functions including signal transduction and protein trafficking. We report that in cultured cortical and hippocampal neurons the distribution of lipid rafts is development-dependent. Lipid rafts in mature neurons exist on the entire cell-surface and display a high degree of mobility. AMPA receptors co-localize and associate with lipid rafts in the plasma membrane. The association of AMPARs with rafts is under regulation; through the NOS-NO pathway, NMDA receptor activity increases AMPAR localization in rafts. During membrane targeting, AMPARs insert into or at close proximity of the surface raft domains. Perturbation of lipid rafts dramatically suppresses AMPA receptor exocytosis, resulting in significant reduction in AMPAR cell-surface expression.     

The activities of LDL Receptor-related Protein-1 (LRP1) compartmentalize into distinct plasma membrane microdomains

LDL Receptor-related Protein-1 (LRP1) is an endocytic receptor for diverse ligands. In neurons and neuron-like cells, ligand-binding to LRP1 initiates cell-signaling. Herein, we show that in PC12 and N2a neuron-like cells, LRP1 distributes into lipid rafts and non-raft plasma membrane fractions. When lipid rafts were disrupted, using methyl-β-cyclodextrin or fumonisin B1, activation of Src family kinases and ERK1/2 by the LRP1 ligands, tissue-type plasminogen activator and activated α₂-macroglobulin, was blocked. Biological consequences of activated LRP1 signaling, including neurite outgrowth and cell growth, also were blocked. The effects of lipid raft disruption on ERK1/2 activation and neurite outgrowth, in response to LRP1 ligands, were reproduced in experiments with cerebellar granule neurons in primary culture. Because the reagents used to disrupt lipid rafts may have effects on the composition of the plasma membrane outside lipid rafts, we studied the effects of these reagents on LRP1 activities unrelated to cell-signaling. Lipid raft disruption did not affect the total ligand binding capacity of LRP1, the affinity of LRP1 for its ligands, or its endocytic activity. These results demonstrate that well described activities of LRP1 require localization of this receptor to distinct plasma membrane microdomains.     

Phosphorylation and lipid raft association of fibroblast growth factor receptor‐2 in oligodendrocytes

Fibroblast growth factors (FGFs) and their receptors (FGFRs) initiate diverse cellular responses that contribute to the regulation of oligodendrocyte (OL) function. To understand the mechanisms by which FGFRs elicit these cellular responses, we investigated the phosphorylation of signal transduction proteins and the role of cholesterol‐glycosphingolipid‐enriched “lipid raft” microdomains in differentiated OLs. Surprisingly, we found that the most abundant tyrosine‐phosphorylated protein in OLs was the 120‐kd isoform of FGFR2 and that it was phosphorylated even in the absence of FGF2, suggesting a potential ligand‐independent function for this receptor. Furthermore, FGFR2, but not FGFR1, was associated with lipid raft microdomains in OLs and myelin (but not in astrocytes). This provides the first evidence for the association of FGFR with TX‐100‐insoluble lipid raft fractions. FGFR2 phosphorylated the key downstream target, FRS2 in OLs. Raft disruption resulted in loss of phosphorylated FRS2 from lipid rafts, coupled with the loss of Akt but not of Mek or Erk phosphorylation. This suggests that FGFR2‐FRS2 signaling in lipid rafts operates via the PI3‐Kinase/Akt pathway rather than the Ras/Mek/Erk pathway, emphasizing the importance of microenvironments within the cell membrane. Also present in lipid rafts in OLs and myelin, but not in astrocytes, was a novel 52‐kd isoform of FGFR2 that lacked the extracellular ligand‐binding region. These results demonstrate that FGFR2 in OLs and myelin possess unique characteristics that are specific both to receptor type and to OLs and provide a novel mechanism to elicit distinct cellular responses that mediate both FGF‐dependent and ‐independent functions. © 2008 Wiley‐Liss, Inc.     

Lipid rafts of purified mouse brain synaptosomes prepared with or without detergent reveal different lipid and protein domains

Lipid rafts have been proposed to be important in a variety of functions including lipid transport, signal transduction and cell growth. There is increasing evidence that lipid rafts may play a role in cell functions in brain. Lipid rafts are typically isolated using a detergent such as Triton X-100. There has been, however, data from non-brain tissue indicating that preparation of lipid rafts using a detergent may represent different raft domains as compared with non-detergent preparation. The purpose of the present study was to compare protein and lipid markers of lipid rafts using a highly purified mouse synaptosomal fraction and non-detergent and detergent methods. The lipid raft marker proteins, alkaline phosphatase and flotillin, and the lipid markers, cholesterol and sphingomyelin, were highly enriched in lipid rafts prepared with detergent as compared with the non-detergent fraction. Enrichment of Na(+),K(+)-ATPase was greater in the non-detergent lipid raft fraction as compared with lipid rafts prepared with detergent. Lipid rafts from the nerve terminal of neurons prepared with or without detergents may represent different membrane domains each with unique specialized functions.     

Rafts are required for acetylcholine receptor clustering

Cholesterol-sphingolipid microdomains, or lipid rafts, are major regulators of molecular interactions in membrane organization. Because lipid rafts can move laterally and cluster into larger patches, they have been proposed to play a role in the redistribution of specific molecules to specialized cellular structures. Rafts have been shown to favor formation and maintenance of synaptic receptor clusters in neurons of the central nervous system. However, little is known about their role in formation of the neuromuscular junction (NMJ). To determine whether lipid rafts are involved in acetylcholine receptor (AChR) cluster formation and stabilization in myogenic cells, two standard tools were employed: (1) Perturbation of lipid rafts by drugs that deplete membrane cholesterol was carried out to verify that cholesterol is required for AChR clustering in agrin-treated C2C12 myotubes; and (2) detergent resistance of lipid-ordered domains was also used to demonstrate that AChRs, as well as key components of the postsynaptic membrane of the NMJ, are associated with rafts.     

Oligomerization of amyloid beta-protein occurs during the isolation of lipid rafts

Cholesterol- and glycosphingolipid-rich microdomains, called "lipid rafts," are suggested to initiate and promote the pathophysiology of Alzheimer's disease by serving as a platform for generation, aggregation, or degradation of amyloid-beta protein (Abeta). However, methods for biochemical isolation of these microdomains may produce artifacts. In this study, when synthetic Abeta1- 40 monomers were added to the brain fragment at a final concentration of 2.1 microM, followed by homogenization and isolation of lipid rafts by an established method, Abeta1- 40 accumulated as oligomers in the lipid raft fraction. However, in the absence of a brain homogenate, synthetic Abeta1- 40 did not accumulate in the lipid raft fraction. When fractionation was performed in the absence of synthetic Abeta1-40 and synthetic Abeta1-40 was incubated in an aliquot of each fraction, a marked oligomerization of Abeta1- 40 was observed in the lipid raft aliquot. These results indicate that exogenous Abeta associates with lipid rafts, and Abeta bound to rafts forms oligomers during the isolation of lipid rafts. In addition, endogenous Abeta1-40 in a Triton X-100-insoluble fraction of a brain homogenate of the Tg2576 transgenic mouse model of Alzheimer's disease formed oligomers when the fraction was incubated at 4 degrees C for 20 hr. Thus, one should be careful when one discusses the role of lipid rafts in amyloid precursor protein processing and in the generation, aggregation, and degradation of Abeta.     

Neuronal membranes are key to the pathogenesis of Alzheimer's disease: the role of both raft and non-raft membrane domains

Membrane rafts are sterol- and sphingolipid-enriched domains that compartmentalize cellular processes. Membrane rafts isolated from post-mortem AD brain are enriched in both β-amyloid and phosphorylated tau. Proteolytic processing of APP to generate β-amyloid, the principle component of amyloid plaques, can occur in membrane rafts, implicating them in the pathogenesis of Alzheimer's disease (AD). Secondary to their role in β-amyloid generation, membrane rafts have more recently been implicated in the accumulation, aggregation and degradation of β-amyloid, with evidence supporting a specific role for membrane raft gangliosides in the binding and aggregation of β-amyloid. In addition, membrane domain composition has a direct impact on both the generation of β-amyloid and its subsequent toxic actions and as such is a key target for the development of therapeutic strategies. This mini-review will focus on recent advances in our understanding of the relevance of membrane composition, of both raft and non-raft domains, to AD progression in models and in human disease. We will discuss how manipulation of membrane composition can alter both the proteolytic processing of APP and the subsequent binding and aggregation of β-amyloid peptide.     

Lipid binding activity of a neuron-specific protein NAP-22 studied in vivo and in vitro

There exists a microdomain called "raft" in the cell membrane. The enrichment of cholesterol and sphingolipids in its outer leaflet is well recognized. In contrast, little is known of the lipid composition of the inner leaflet of raft, where many acylated signal-transducing molecules, such as trimeric G proteins and protein tyrosine kinases, associate. NAP-22 is a neuronal protein localized on the inner leaflet of raft domain. This protein was found to bind cholesterol in the liposome. In this study, we further analyze the lipid binding activity of NAP-22 using eukaryotic and bacterial expression systems. In addition to cholesterol, NAP-22 showed a phosphatidylethanolamine (PE)- and polyphosphoinositide-dependent membrane binding in the liposome assay. The N-terminal myristoylation was essential for the liposome binding. The C-terminal deletion up to D61 showed little effect on the binding. The lipid binding region was hence judged to be in the N-terminal 60-amino-acid sequence. NAP-22 was then expressed in COS7 cells, and the intracellular localization was studied. Biochemical analysis showed the localization of NAP-22 in a Triton-insoluble low-density fraction. Cell staining analysis showed colocalization patterns of NAP-22 with PE and cholesterol in the membrane.     

The prion protein requires cholesterol for cell surface localization

The cellular prion protein PrP(c) is attached to the plasma membrane by a glycosyl-phosphatidyl-inositol (GPI-) anchor and is localized in lipid rafts, membrane microdomains characterized by a high content of sphingolipids and cholesterol. Previous studies revealed that perturbation of cholesterol synthesis prevents prion conversion, explained by redistribution of PrP(c) at the plasma membrane. We investigated the influence of inhibition of cholesterol synthesis by the HMG-CoA-reductase inhibitor mevinolin on the trafficking of PrP(c) in neuronal cells. Treatment with mevinolin significantly reduces the amount of surface PrP(c) and leads to its accumulation in the Golgi compartment. Analysis of mutant PrPs highlights the importance of the GPI-anchor for raft localization and provides information about domains implicated in lipid raft association of PrP in the secretory pathway. Our data show that cholesterol is essential for the cell surface localization of PrP(c), known to be necessary for prion conversion.     

Platelet tetraspanin complexes and their association with lipid rafts

Tetraspanins are a superfamily of integral membrane proteins that facilitate the organization of membrane and intracellular signaling molecules into dynamic signaling microdomains, tetraspanin-enriched microdomains (TEMs). Four tetraspanin family members have been identified in platelets: CD9, CD151 and TSSC6, which are constitutively associated with alphaIIbbeta3, and CD63, which is present on granule membranes in resting platelets and associates with alphaIIbbeta3-CD9 following platelet activation. CD63 and CD9 associate with a type II phosphatidylinositol 4-kinase, PI4K55, in both resting and activated platelets. Immunoelectron microscopic studies showed co-localization of CD63 and PI4K55 on internal membranes of resting platelets and on the filopodia of thrombin-activated platelets. Because TEMs in malignant cell lines appear to be distinct from prototypic lipid rafts, this study examined whether CD63-PI4K55 and CD9-PI4K55 complexes were resident in platelet-lipid rafts, or formed distinct microdomains. CD63, CD9 and PI4K55 were recovered from low-density membrane fractions (LDMFs) of sucrose gradients following platelet lysis in Brij 35, but unlike lipid-raft proteins were not insoluble in Triton X-100, being absent from LDMFs of platelets lysed with Triton. Incubation of platelets with methyl-beta-cyclodextrin, to deplete cholesterol and disrupt lipid rafts, shifted the complexes to higher density sucrose gradient fractions, but did not disrupt the tetraspanin-PI4K55 complexes. These results demonstrate that tetraspanin complexes in platelets form cholesterol-associated microdomains that are distinct from lipid rafts. It is probable that TEMs and lipid rafts associate under certain conditions, resulting in the close proximity of distinct sets of signaling molecules, facilitating signal transduction.     

Developmental changes in the association of NMDA receptors with lipid rafts

Lipid rafts (LR) are lipid microdomains present in the cell surface membrane that are organizational platforms involved in protein trafficking and formation of cell signaling complexes. In the adult brain, NMDA receptors (NMDAR) and receptor-associated proteins such as membrane-associated guanylate kinases (PSD-95 and SAP102), are distributed between the postsynaptic density (PSD) and lipid rafts. However, the time course of the association of NMDAR with LR during neural development is not known. We therefore investigated the effect of development on the association of NMDAR with LR prepared from rat brains ranging in postnatal age from 1-35 days and compared this with their expression in PSDs. LR and PSD fractions were prepared by extraction of P2 membranes with Tx-100 followed by sucrose density gradient centrifugation. The yield of LR, as reflected by levels of protein, Thy-1, and flotillin-1 increased during postnatal development. NR2A was associated predominantly with the lipid raft fraction at all ages examined whereas NR2B underwent a gradual shift from PSDs to lipid rafts during the first 3 weeks after birth. These changes in the distribution of NR2A and NR2B were paralleled by changes in the distribution of PSD-95 and SAP102 respectively. Tyrosine-phosphorylated proteins, including NR2A and NR2B, were preferentially associated with lipid rafts in older, as compared to younger, animals. These results show that the association of NMDAR with LR is regulated developmentally.     

Absence of TrkB and insulin receptor beta in the Triton insoluble low-density fraction (raft)

Cholesterol- and glycolipid-enriched microdomains within the plasma membrane of animal cells, including neurons, have been purified and used as a low-density membrane domain after extraction with Triton X-100 (raft), or after subcellular fractionation without detergent (LDM). In this study, we compared the protein compositions in the raft and the LDM. Membrane receptors, acylated- and glycosylphosphatidylinositol (GPI)- anchored proteins were enriched in the LDM. Further treatment of the LDM with Triton X-100 excluded the membrane receptors, TrkBs and insulin receptor beta. In the presence of calcium ions, the endogenous tyrosine kinase activities in the LDM and the raft were enhanced, suggesting an important role of calcium ions in the signal transduction via the LDM and the raft.     

Rafts in oligodendrocytes: evidence and structure-function relationship

The plasma membrane of eukaryotic cells exhibits lateral inhomogeneities, mainly containing cholesterol and sphingomyelin, which provide liquid-ordered microdomains (lipid "rafts") that segregate membrane components. Rafts are thought to modulate the biological functions of molecules that become associated with them, and as such, they appear to be involved in a variety of processes, including signal transduction, membrane sorting, cell adhesion and pathogen entry. Although still a matter of ongoing debate, evidence in favor of the presence of these microdomains is gradually accumulating but a consensus on issues like their size, lifetime, composition, and biological significance has yet to be reached. Here, we provide an overview of the evidence supporting the presence of rafts in oligodendrocytes, the myelin-producing cells of the central nervous system, and discuss their functional significance. The myelin membrane differs fundamentally from the plasma membrane, both in lipid and protein composition. Moreover, since myelin membranes are unusually enriched in glycosphingolipids, questions concerning the biogenesis and functional relevance of microdomains thus appear of special interest in oligodendrocytes. The current picture of rafts in oligodendrocytes is mainly based on detergent methods. The robustness of such data is discussed and alternative methods that may provide complementary data are indicated.     

Lipid rafts in neuronal signaling and function

Lipid rafts are plasma membrane microdomains rich in cholesterol and sphingolipids, which provide a particularly ordered lipid environment. Rafts are enriched in glycosylphosphatidylinositol (GPI)-anchored proteins, as well as proteins involved in signal transduction and intracellular trafficking. In neurons, lipid rafts act as platforms for the signal transduction initiated by several classes of neurotrophic factors, including neurotrophins and glial-derived neurotrophic factor (GDNF)-family ligands. Emerging evidence also indicates that such rafts are important for neuronal cell adhesion, axon guidance and synaptic transmission. Thus, lipid rafts are structurally unique components of plasma membranes, crucial for neural development and function.     

Virus-induced alterations of membrane lipids affect the incorporation of PrP Sc into cells

Prion diseases are fatal neurodegenerative disorders characterized by long incubation periods. To investigate whether concurrent diseases can modify the clinical outcome of prion‐affected subjects, we tested the effect of viral infection on the binding and internalization of PrP^Sc, essential steps of prion propagation. To this effect, we added scrapie brain homogenate or purified PrP^Sc to fibroblasts previously infected with minute virus of mice (MVM), a mouse parvovirus. We show here that the rate of incorporation of PrP^Sc into MVM‐infected cells was significantly higher than that observed for naïve cells. Immunostaining of cells and immunoblotting of subcellular fractions using antibodies recognizing PrP and LysoTracker, a lysosomal marker, revealed that in both control and MVM‐infected cells the incorporated PrP^Sc was associated mostly with lysosomes. Interestingly, floatation gradient analysis revealed that the majority of the PrP^Sc internalized into MVM‐infected cells shifted toward raft‐containing low‐density fractions. Concomitantly, the MVM‐infected cells demonstrated increased levels of the glycosphingolipid GM1 (an essential raft lipid component) throughout the gradient and a shift in caveolin 1 (a raft protein marker) toward lighter membrane fractions compared with noninfected cells. Our results suggest that the effect of viral infection on membrane lipid composition may promote the incorporation of exogenous PrP^Sc into rafts. Importantly, membrane rafts are believed to be the conversion site of PrP^C to PrP^Sc; therefore, the association of exogenous PrP^Sc with such membrane microdomains may facilitate prion infection. © 2008 Wiley‐Liss, Inc.     

Targeting of Kv7.5 (KCNQ5)/KCNE channels to surface microdomains of cell membranes

Background: Kv7.5 (KCNQ5) channels conduct M‐type potassium currents in the brain, are expressed in skeletal muscle, and contribute to vascular muscle tone. Methods: We coexpressed Kv7.5 and KCNE1–3 peptides in HEK293 cells and then analyzed their association using electrophysiology and co‐immunoprecipitation, assessed localization using confocal microscopy, examined targeting of the oligomeric channels to cholesterol‐rich membrane surface microdomains using lipid raft isolation, and evaluated their membrane dynamics using fluorescence recovery after photobleaching (FRAP). Results: Kv7.5 forms oligomeric channels specifically with KCNE1 and KCNE3. The expression of Kv7.5 targeted to cholesterol‐rich membrane surface microdomains was very low. Oligomeric Kv7.5/KCNE1 and Kv7.5/KCNE3 channels did not localize to lipid rafts. However, Kv7.5 association impaired KCNE3 expression in lipid raft microdomains. Conclusions: Our results indicate that Kv7.5 contributes to the spatial regulation of KCNE3. This new scenario could greatly assist in determining the physiological relevance of putative KCNE3 interactions in nerve and muscle. Muscle Nerve 45: 48–54, 2012     

Prolonged Morphine Treatment Alters Expression and Plasma Membrane Distribution of β-Adrenergic Receptors and Some Other Components of Their Signaling System in Rat Cerebral Cortex

β-Adrenergic signaling plays an important role in regulating diverse brain functions and alterations in this signaling have been observed in different neuropathological conditions. In this study, we investigated the effect of a 10-day treatment with high doses of morphine (10 mg/kg per day) on major components and functional state of the β-adrenergic receptor (β-AR) signaling system in the rat cerebral cortex. β-ARs were characterized by radioligand binding assays and amounts of various G protein subunits, adenylyl cyclase (AC) isoforms, G protein-coupled receptor kinases (GRKs), and β-arrestin were examined by Western blot analysis. AC activity was determined as a measure of functionality of the signaling system. We also assessed the partitioning of selected signaling proteins between the lipid raft and non-raft fractions prepared from cerebrocortical plasma membranes. Morphine treatment resulted in a significant upregulation of β-ARs, GRK3, and some AC isoforms (AC-I, -II, and -III). There was no change in quantity of G proteins and some other signaling molecules (AC-IV, AC-V/VI, GRK2, GRK5, GRK6, and β-arrestin) compared with controls. Interestingly, morphine exposure caused a partial redistribution of β-ARs, G_sα, G_oα, and GRK2 between lipid rafts and bulk plasma membranes. Spatial localization of other signaling molecules within the plasma membrane was not changed. Basal as well as fluoride- and forskolin-stimulated AC activities were not significantly different in membrane preparations from control and morphine-treated animals. However, AC activity stimulated by the beta-AR agonist isoprenaline was markedly increased. This is the first study to demonstrate lipid raft association of key components of the cortical β-AR system and its sensitivity to morphine.     

Biochemical and morphologic evidence of the interaction of oligodendrocyte membrane rafts with actin filaments

Cytoskeletal structures under the cell membrane carry out pivotal roles in the maintenance and remodeling of the cell structures. Reforming of the cytoskeletal networks after partial extraction of membrane components could be a good clue to identify molecular components pertaining the interaction of cytoskeleton with membrane. A detergent extract from 3-week-old rat brain membrane fraction was found to make an actin-based gel upon incubation at 25 degrees C. Some protein components of the gelation products were recovered in a Triton-insoluble low-density microdomain fraction (raft) after depolymerization of actin filaments. Some of these proteins were identified as 2',3'-cyclic nucleotide-3'-phosphodiesterase (CNPase), proteolipid protein (PLP), and myelin oligodendrocyte glycoprotein (MOG) through electrospray time-of-flight (ESI-TOF) analysis and Western blotting. Because these proteins are well-known marker proteins of oligodendrocytes, localization of these proteins and cholesterol, a raft-localized lipid, with actin filaments was studied using cultured oligodendrocytes. Clear colocalization of these proteins and cholesterol with actin filaments was observed after Triton treatment at 4 degrees C before fixation. These results indicate that raft microdomains participate in the formation of cell shape through interaction with microfilaments in oligodendrocytes.