Plasma membrane microdomains: Organization,function and trafficking (Review)

The plasma membrane consists of a mosaic of functional microdomains facilitating a variety of physiological processes associated with the cell surface. In most cells, the majority of the cell surface is morphologically featureless, leading to difficulties in characterizing its organization and microdomain composition. The reliance on indirect and perturbing techniques has led to vigorous debate concerning the nature and even existence of some microdomains. Recently, increasing technical sophistication has been applied to study cell surface compartmentalization providing evidence for small, short-lived clusters that may be much less than 50 nm in diameter. Lipid rafts and caveolae are cholesterol-dependent, highly ordered microdomains that have received most attention in recent years, yet their precise roles in regulating functions such as cell signalling remain to be determined. Endocytosis of lipid rafts/caveolae follows a clathrin-independent route to both early endosomes and non-classical caveosomes. The observation that a variety of cellular pathogens localize to and internalize with these microdomains provides an additional incentive to characterize the organization, dynamics and functions of these domains.     

Plasma membrane microdomains: organization, function and trafficking

The plasma membrane consists of a mosaic of functional microdomains facilitating a variety of physiological processes associated with the cell surface. In most cells, the majority of the cell surface is morphologically featureless, leading to difficulties in characterizing its organization and microdomain composition. The reliance on indirect and perturbing techniques has led to vigorous debate concerning the nature and even existence of some microdomains. Recently, increasing technical sophistication has been applied to study cell surface compartmentalization providing evidence for small, short-lived clusters that may be much less than 50 nm in diameter. Lipid rafts and caveolae are cholesterol-dependent, highly ordered microdomains that have received most attention in recent years, yet their precise roles in regulating functions such as cell signalling remain to be determined. Endocytosis of lipid rafts/caveolae follows a clathrin-independent route to both early endosomes and non-classical caveosomes. The observation that a variety of cellular pathogens localize to and internalize with these microdomains provides an additional incentive to characterize the organization, dynamics and functions of these domains.     

Inhibition of sphingomyelin synthase (SMS) affects intracellular sphingomyelin accumulation and plasma membrane lipid organization

Sphingomyelin plays a very important role both in cell membrane formation that may well have an impact on the development of diseases like atherosclerosis and diabetes. However, the molecular mechanism that governs intracellular and plasma membrane SM levels is largely unknown. Recently, two isoforms of sphingomyelin synthase (SMS1 and SMS2), the last enzyme for SM de novo synthesis, have been cloned. We have hypothesized that SMS1 and SMS2 are the two most likely candidates responsible for the SM levels in the cells and on the plasma membrane. To test this hypothesis, cultured cells were treated with tricyclodecan-9-yl-xanthogenate (D609), an inhibitor of SMS, or with SMS1 and SMS2 siRNAs. Cells were then pulsed with [14C]-L-serine (a precursor of all sphingolipids). SMS activity and [14C]-SM in the cells were monitored. We found that SMS activity was significantly decreased in cells after D609 or SMS siRNA treatment, compared with controls. SMS inhibition by D609 or SMS siRNAs significantly decreased intracellular [14C]-SM levels. We measured cellular lipid levels, including SM, ceramide, phosphatidylcholine, and diacylglycerol and found that SMS1 and SMS2 siRNA treatment caused a significant decrease of SM levels (20% and 11%, respectively), compared to control siRNA treatment; SMS1 but not SMS2 siRNA treatment caused a significant increase of ceramide levels (10%). There was a decreasing tendency for diacylglycerol levels after both SMS1 and SMS2 siRNA treatment, however, it was not statistical significant. As shown by lipid rafts isolation and lipid determination, SMS1 and SMS2 siRNA treatment led to a decrease of SM content in detergent-resistant lipid rafts on the cell membrane. Furthermore, SMS1 and SMS2 siRNA-treated cells had a stronger resistance than did control siRNA-treated cells to lysenin (a protein that causes cell lysis due to its affinity for plasma membrane SM). These results indicate that both SMS1 and SMS2 contribute to SM de novo synthesis and control SM levels in the cells and on the cell membrane including plasma membrane, implying an important relationship between SMS activity and cell functions.     

The fat controller: roles of palmitoylation in intracellular protein trafficking and targeting to membrane microdomains (Review)

The attachment of palmitic acid to the amino acid cysteine via thioester linkage (S-palmitoylation) is a common post-translational modification of eukaryotic proteins. In this review, we discuss the role of palmitoylation as a versatile protein sorting signal, regulating protein trafficking between distinct intracellular compartments and the micro-localization of proteins within membranes.     

Lipid microdomains and membrane trafficking in mammalian cells

This overview summarizes the data for how epithelial cells sort and deliver proteins and lipids to the apical and basolateral cell surface domains. The basolateral pathway uses a Rab-SNARE mechanism for docking and fusion, while the apical route employs a different machinery. This latter mechanism is based on lipid microdomains, composed of clusters of sphingolipids and cholesterol, which function as rafts for apical delivery. The sphingolipid-cholesterol raft mechanism seems to be employed generally by mammalian cells to transport raft-associated proteins to their post-Golgi destinations.     

The structural organization of skeletal proteins influences lipid translocation across erythrocyte membrane

In order to define the influence of skeletal protein organization on transmembrane phospholipid movement in erythrocyte membranes, we measured the translocation rate of lysophosphatidylcholine in pathologic red cells. A simple method based on the differential extraction of lysophosphatidylcholine from the red cell membrane by saline and albumin solutions was used to quantitate the translocation rate. Two groups of pathologic red cells were chosen for these studies: red cells with quantitative deficiencies of the skeletal proteins, spectrin and protein 4.1, and sickle erythrocytes in which controlled reorganization of the membrane was induced by hemoglobin polymerization. Marked increase in lipid translocation rate was seen in red cells having quantitative deficiencies of spectrin and protein 4.1. The magnitude of the increase in translocation rate in spectrin-deficient red cells was related to the magnitude of protein deficiency. Translocation rate in sickle erythrocyte membranes increased by 50% upon deoxygenation as a result of sickle hemoglobin polymerization. No increase in translocation rate was seen in normal cells upon deoxygenation. By manipulating the extent of membrane reorganization that occurred following deoxygenation of sickle cells, we have been able to show that skeletal reorganization induced by hemoglobin polymerization and not hemoglobin polymerization per se is responsible for the increase in translocation rate. Together, these findings imply that the structural organization of membrane skeletal proteins plays an important role in regulating the rate of transbilayer movement of lipids across the erythrocyte membrane.     

Protein folding and translocation across the endoplasmic reticulum membrane (Review)

Proteins destined for secretion are translocated across or inserted into the endoplasmic reticulum membrane whereupon they fold and assemble to their native state before their subsequent transport to the Golgi apparatus. Proteins that fail to fold correctly are translocated back across the endoplasmic reticulum membrane to the cytosol where they become substrates for the cytosolic degradative machinery. Central to translocation is a protein pore in the membrane called the translocon that allows passage of proteins in and out of the endoplasmic reticulum. It is clear that the conformation of the polypeptide chain influences the translocation process and that there is a temporal relationship between modification of the chain, translocation and folding. This review will consider when and how the polypeptide chain folds, and how this might influence translocation into and out of the ER; and discuss how protein folding might affect post-translational modification of the polypeptide chain following translocation into the ER lumen.     

Implications of lipid microdomains for membrane curvature, budding and fission.

Recent studies have highlighted the importance of monolayer and bilayer curvature for the budding and fission of biological membranes. Other lines of research, addressing the structure of planar biological membranes, have revealed the existence of cholesterol-based membrane microdomains. Here, we comment on the significance of microdomains for curved membranes, with special emphasis on budding and fission.     

Lipid lateral diffusion and membrane organization

It is shown that investigating the lateral motion of lipids in biological membranes can provide useful information on membrane lateral organization. After labeling membranes with extrinsic or intrinsic lipophilic fluorescent probes, fluorescence recovery after photobleaching experiments strongly suggests that specialized cells like spermatozoa, eggs and epithelia exhibit surface membrane regionalization or macrocompartmentation and that lateral microheterogeneities or lipid microdomains exist in the plasma membrane of many cellular systems.     

Formation of N-type (Cav2.2) voltage-gated calcium channel membrane microdomains: Lipid raft association and clustering

Voltage-gated calcium channels (Ca(v)s) comprise a pore-forming α? with auxiliary α?δ and β subunits which modulate Ca(v) function and surface expression. Ca(v)α? and α?δ are present in signalling complexes termed lipid rafts but it is unclear whether α?δ is obligatory for targeting Ca(v)s to rafts or to what extent this influences cell surface organisation of Ca(v)s. Here, we have used imaging, biochemistry and electrophysiology to determine localisation and raft-partitioning of WT and functionally active HA-epitope tagged α?δ-1 and Ca(v)2.2 subunits expressed in COS-7 cells. We show that α?δ-1 not only partitions into lipid rafts itself but also mediates raft-partitioning of Ca(v)2.2/β(1b) complexes. Ca(v)α?δ-1, Ca(v)2.2/β(1b) and Ca(v)2.2/β(1b)/α?δ-1 complexes are all organised into cell surface clusters although only in the presence of α?δ-1 do they co-localise with raft markers, caveolin and flotillin. Such clusters persist in the presence of 3-methyl-β-cyclodextrin even though the raft markers disperse. However, clustering is profoundly sensitive to disruption of the actin-based cytoskeleton by cytochalasin-D. We conclude that α?δ-1, and likely other α?δ subunits, is necessary and sufficient for targeting Ca(v)s to lipid rafts. However, formation of clusters supporting "hotspots" of Ca(v) activity requires aggregation of macromolecular complexes containing raft components, stabilised by interactions with the cytoskeleton.     

Fluorescence-quenching and resonance energy transfer studies of lipid microdomains in model and biological membranes (Review)

Measurements of contact-dependent fluorescence quenching and of fluorescence resonance energy transfer (FRET) within bilayers provide information concerning the spatial relationships between molecules on distance scales of a few nm or up a few tens of nm, respectively, and are therefore well suited to detect the presence and composition of membrane microdomains. As described in this review, techniques based on fluorescence quenching and FRET have been used to demonstrate the formation of nanoscale liquid-ordered domains in cholesterol-containing model membranes under physiological conditions, and to investigate the structural features of lipids and proteins that influence their partitioning between liquid-ordered and liquid-disordered domains. FRET-based methods have also been used to test for the presence of ‘raft’ microdomains in the plasma membranes of mammalian cells. We discuss the sometimes divergent findings of these studies, possible modifications to the ‘raft hypothesis’ suggested by studies using FRET and other techniques, and the further potential of FRET-based methods to test and to refine current models of the nature and organization of membrane microdomains.     

Membrane microdomains,caveolae, and caveolar endocytosis of sphingolipids (Review)

Caveolae are flask-shape membrane invaginations of the plasma membrane that have been implicated in endocytosis, transcytosis, and cell signaling. Recent years have witnessed the resurgence of studies on caveolae because they have been found to be involved in the uptake of some membrane components such as glycosphingolipids and integrins, as well as viruses, bacteria, and bacterial toxins. Accumulating evidence shows that endocytosis mediated by caveolae requires unique structural and signaling machinery (caveolin-1, src kinase), which indicates that caveolar endocytosis occurs through a mechanism which is distinct from other forms of lipid microdomain-associated, clathrin-independent endocytosis. Furthermore, a balance of glycosphingolipids, cholesterol, and caveolin-1 has been shown to be important in regulating caveolae endocytosis.     

Lipid synthesis and transport are coupled to regulate membrane lipid dynamics in the endoplasmic reticulum

Structural lipids are mostly synthesized in the endoplasmic reticulum (ER), from which they are actively transported to the membranes of other organelles. Lipids can leave the ER through vesicular trafficking or non-vesicular lipid transfer and, curiously, both processes can be regulated either by the transported lipid cargos themselves or by different secondary lipid species. For most structural lipids, transport out of the ER membrane is a key regulatory component controlling their synthesis. Distribution of the lipids between the two leaflets of the ER bilayer or between the ER and other membranes is also critical for maintaining the unique membrane properties of each cellular organelle. How cells integrate these processes within the ER depends on fine spatial segregation of the molecular components and intricate metabolic channeling, both of which we are only beginning to understand. This review will summarize some of these complex processes and attempt to identify the organizing principles that start to emerge. This article is part of a Special Issue entitled Endoplasmic reticulum platforms for lipid dynamics edited by Shamshad Cockcroft and Christopher Stefan.     

Partitioning of the serotonin transporter into lipid microdomains modulates transport of serotonin

The serotonin transporter (SERT) is an integral membrane protein responsible for the clearance of serotonin from the synaptic cleft following the release of the neurotransmitter. SERT plays a prominent role in the regulation of serotoninergic neurotransmission and is a molecular target for multiple antidepressants as well as substances of abuse. Here we show that SERT associates with lipid rafts in both heterologous expression systems and rat brain and that the inclusion of the transporter into lipid microdomains is critical for serotonin uptake activity. SERT is present in a subpopulation of lipid rafts, which is soluble in Triton X-100 but insoluble in other non-ionic detergents such as Brij 58. Disaggregation of lipid rafts upon depletion of cellular cholesterol results in a decrease of serotonin transport capacity (V(max)), due to the reduction of turnover number of serotonin transport. Our data suggest that the association of SERT with lipid rafts may represent a mechanism for regulating the transporter activity and, consequently, serotoninergic signaling in the central nervous system, through the modulation of the cholesterol content in the cell membrane. Furthermore, SERT-containing rafts are detected in both intracellular and cell surface fractions, suggesting that raft association may be important for trafficking and targeting of SERT.     

Lysosome membrane lipid microdomains: novel regulators of chaperone-mediated autophagy

Chaperone-mediated autophagy (CMA) is a selective mechanism for the degradation of soluble cytosolic proteins in lysosomes. The limiting step of this type of autophagy is the binding of substrates to the lysosome-associated membrane protein type 2A (LAMP-2A). In this work, we identify a dynamic subcompartmentalization of LAMP-2A in the lysosomal membrane, which underlies the molecular basis for the regulation of LAMP-2A function in CMA. A percentage of LAMP-2A localizes in discrete lysosomal membrane regions during resting conditions, but it exits these regions during CMA activation. Disruption of these regions by cholesterol-depleting agents or expression of a mutant LAMP-2A excluded from these regions enhances CMA activity, whereas loading of lysosomes with cholesterol significantly reduces CMA. Organization of LAMP-2A into multimeric complexes, required for translocation of substrates into lysosomes via CMA, only occurs outside the lipid-enriched membrane microdomains, whereas the LAMP-2A located within these regions is susceptible to proteolytic cleavage and degradation. Our results support that changes in the dynamic distribution of LAMP-2A into and out of discrete microdomains of the lysosomal membrane contribute to regulate CMA.     

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 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.     

Plasma membrane microdomains regulate turnover of transport proteins in yeast

In this study, we investigate whether the stable segregation of proteins and lipids within the yeast plasma membrane serves a particular biological function. We show that 21 proteins cluster within or associate with the ergosterol-rich membrane compartment of Can1 (MCC). However, proteins of the endocytic machinery are excluded from MCC. In a screen, we identified 28 genes affecting MCC appearance and found that genes involved in lipid biosynthesis and vesicle transport are significantly overrepresented. Deletion of Pil1, a component of eisosomes, or of Nce102, an integral membrane protein of MCC, results in the dissipation of all MCC markers. These deletion mutants also show accelerated endocytosis of MCC-resident permeases Can1 and Fur4. Our data suggest that release from MCC makes these proteins accessible to the endocytic machinery. Addition of arginine to wild-type cells leads to a similar redistribution and increased turnover of Can1. Thus, MCC represents a protective area within the plasma membrane to control turnover of transport proteins.