Ceramide-enriched membrane domains--structure and function

Membrane lipids seem to be organized and not randomly distributed in the cell membrane. In particular, sphingolipids seem to interact with cholesterol in the outer leaflet of the cell membrane resulting in the formation of distinct membrane domains, i.e. rafts. The generation of ceramide within rafts alters their biophysical properties and results in the formation of large ceramide-enriched membrane platforms. These platforms serve to cluster receptor molecules and to organize intracellular signalling molecules to facilitate signal transduction via a receptor upon stimulation. Thus, ceramide-enriched membrane domains amplify not only receptor-, but also stress-mediated signalling events. Although many receptors cluster, the molecular mechanisms mediating this important and general event in signal transduction need to be identified.     

Ceramide: physiological and pathophysiological aspects

Ceramide generated in the cell membrane has been shown to be central for the induction of apoptosis by death receptors and many stress stimuli such as gamma-irradiation, UV-light or infection with pathogens. Ceramide reorganizes cell membranes and forms large ceramide-enriched membrane domains that serve the spatial and temporal organization of the cellular signalosome upon activation. Thus, ceramide-enriched membrane domains mediate clustering of CD95 and DR5 to facilitate apoptosis, and they are also critically involved in apoptosis after irradiation, UV-light and infection with Pseudomonas aeruginosa. Since ceramide-enriched membrane domains amplify signals, their function is not restricted to the induction of apoptosis and it was shown that ceramide-enriched membrane domains are also involved in internalization of pathogens and the control of cytokine release from infected epithelial cells. Recent studies support the notion that changes of the ceramide metabolism are also critically involved in human diseases, for instance neurological disorders, cancer, infectious diseases and Wilson's disease.     

Sphingomyelinases: enzymology and membrane activity

This paper reviews our present knowledge of sphingomyelinases as enzymes, and as enzymes acting on a membrane constituent lipid, sphingomyelin. Six types of sphingomyelinases are considered, namely acidic, secretory, Mg(2+)-dependent neutral, Mg(2+)-independent neutral, alkaline, and bacterial enzymes with both phospholipase C and sphingomyelinase activity. Sphingomyelinase assay methods and specific inhibitors are reviewed. Kinetic and mechanistic studies are summarized, a kinetic model and a general-base catalytic mechanism are proposed. Sphingomyelinase-membrane interactions are considered from the point of view of the influence of lipids on the enzyme activity. Moreover, effects of sphingomyelinase activity on membrane architecture (increased membrane permeability, membrane aggregation and fusion) are described. Finally, a number of open questions on the above topics are enunciated.     

Effect of membrane and cytoskeleton modification on the heat response of BP-8 murine sarcoma cells

Summary Mammalian cells subjected to hyperthermia in the presence of glycerol exhibit greatly enhanced resistance to thermal death. The mechanisms responsible for this effect remain unknown, but it has been suggested that glycerol may act by stabilizing cell membranes or by preventing heat induced disruption of cytoskeletal networks. To test these hypotheses, BP-8 murine sarcoma cells were treated with various combinations of glycerol, procaine, colcemid, and cytochalasin B, followed by 1 hour in vitro heating at temperatures ranging from 37°C to 45.5°C. After heating, the tumor cells were inoculated intraperitoneally into mice and cell survival was evaluated in vivo with the¹²⁵I-iododeoxyuridine prelabeling assay. Addition of 5% glycerol to the incubation medium caused a pronounced increase in the heat resistance of BP-8 cells. Exposure to colcemid (microtubule disrupting agent) or cytochalasin B (micro-filament disrupting agent) did not influence the thermal response of control cells, nor did it counteract the protective effects of glycerol. This suggests that the ability of heat to dissociate cytoskeletal networks may not be an important factor in cellular heat death. In contrast, treatment with the membrane modulator procaine induced significant thermal sensitization in control cells, and caused a complete reversal of the protective action of glycerol. These findings are consistent with the hypothesis that membranes play an important role in the genesis of cellular heat death.Abbreviations ¹²⁵IUdR iodine-125 labeled iododeoxyuridine - EBSS Earle's balanced salt solution This work was supported by Grant CA 21673 from the National Cancer Institute, NIH.     

The role of sphingomyelin and sphingomyelin synthases in cell death,proliferation and migration—from cell and animal models to human disorders

Sphingomyelin constitutes membrane microdomains such as lipid raft, caveolae, and clathrin-coated pits and implicates in the regulation of trans-membrane signaling. On the other hand, sphingomyelin emerges as an important molecule to generate bioactive sphingolipids through ceramide. Sphingomyelin synthase is an enzyme that generates sphingomyelin and diacylglycerol from phosphatidylcholine and ceramide. Although ceramide has a well-known role as a lipid mediator to regulate cell death and survival, the only known biological role of sphingomyelin regulated by sphingomyelin synthases was limited to being a source of bioactive lipids. Here, we describe the basic characters of sphingomyelin synthases and discuss additional roles for sphingomyelin and sphingomyelin synthase in biological functions including cell migration, apoptosis, autophagy, and cell survival/proliferation as well as in human disorders such as cancer and cardiovascular disorders. It is expected that a better understanding of the role of sphingomyelin regulated by sphingomyelin synthase will shed light on new mechanisms in cell biology, physiology and pathology. In the future, novel therapeutic procedures for currently incurable diseases could be developed through modifying the function of not only sphingolipids, such as sphingomyelin and ceramide, but also of their regulatory enzymes. This article is part of a Special Issue entitled New Frontiers in Sphingolipid Biology.     

Distinct stress and cell destruction pathways are engaged by TNF and ceramide during apoptosis of MCF-7 cells

Ceramide has been proposed to be an important signaling intermediate in tumor necrosis factor (TNF)-induced apoptosis in human MCF-7 breast adenocarcinoma cells. We compared cell death and signal transduction pathways induced by TNF and ceramide in TNF-sensitive, parental MCF-7 cells to those in TNF-resistant, MCF-7 cells (3E9). TNF caused proteolysis of the caspase substrate, polyADP-ribose polymerase (PARP) in parental cells, but not in 3E9 cells. Both apoptosis and PARP cleavage were strongly prevented by co-incubation with caspase inhibitors. In contrast, ceramide-induced cell death was neither affected by TNF resistance nor was it associated with PARP cleavage, and death could not be prevented by co-incubation with caspase inhibitors in either cell line. TNF was able to activate JNK/SAPK approximately 30-fold and approximately 5-fold in parental MCF-7 and 3E9 cells, respectively; in contrast, cell-permeable ceramide only weakly stimulated JNK/SAPK activity in either cell type. Although JNK was activated by TNF, pharmacological blockade of the JNK pathway did not inhibit TNF- or ceramide-mediated cell death. Using mass spectroscopic analysis for ceramide, no increase, rather, a decrease in total ceramide content in TNF-treated parental cells was observed. These results suggest that the cell death signaling and execution pathways utilized by ceramide are distinct from those activated by TNF in MCF-7 cells.     

Autophagy paradox and ceramide

Sphingolipid molecules act as bioactive lipid messengers and exert their actions on the regulation of various cellular signaling pathways. Sphingolipids play essential roles in numerous cellular functions, including controlling cell inflammation, proliferation, death, migration, senescence, tumor metastasis and/or autophagy. Dysregulated sphingolipid metabolism has been also implicated in many human cancers. Macroautophagy (referred to here as autophagy) “self-eating” is characterized by nonselective sequestering of cytosolic materials by an isolation membrane, which can be either protective or lethal for cells. Ceramide (Cer), a central molecule of sphingolipid metabolism, has been extensively implicated in the control of autophagy. The increasing evidence suggests that Cer is highly involved in mediating two opposing autophagic pathways, which regulate either cell survival or death, which is referred here as autophagy paradox. However, the underlying mechanism that regulates the autophagy paradox remains unclear. Therefore, this review focuses on recent studies with regard to the regulation of autophagy by Cer and elucidates the roles and mechanisms of action of Cer in controlling autophagy paradox. This article is part of a Special Issue entitled New Frontiers in Sphingolipid Biology.     

Ceramide-dependent caspase 3 activation is prevented by coenzyme Q from plasma membrane in serum-deprived cells

Coenzyme Q (CoQ) is the key factor for the activity of the eukaryotic plasma membrane electron transport chain. Consequently, CoQ is essential in the cellular response against redox changes affecting this membrane. Serum withdrawal induces a mild oxidative stress, which produces lipid peroxidation in membranes. In fact, apoptosis induced by serum withdrawal can be prevented by several antioxidants including CoQ. Also, CoQ can maintain cell growth in serum-limiting conditions, whereas plasma membrane redox system (PMRS) inhibitors such as capsaicin, which compete with CoQ, inhibit cell growth and induce apoptosis. To understand how plasma membrane CoQ prevents oxidative stress-induced apoptosis we have studied the induction of apoptosis by serum withdrawal in CEM cells and its modulation by CoQ. Serum-withdrawal activates neutral sphingomyelinase (N-SMase), ceramide release and caspase-3-related proteases. CoQ addition to serum-free cultures inhibited a 60% N-SMase activation, an 80% ceramide release, and a 50% caspase-3 activity induced by serum deprivation. Caspase activation dependent on ceramide release since C 2 -ceramide was only able to mimic this effect in 10% foetal calf serum cultured cells but not in serum-free cultures. Also, in vitro experiments demonstrated that C 2 -ceramide and ceramide-rich lipid extracts directly activated caspase-3. Taken together, our results indicate that CoQ protects plasma membrane components and controls stress-mediated lipid signals by its participation in the PMRS.     

Structure, function and membrane interactions of plant annexins: An update

Knowledge accumulated over the past 15 years on plant annexins clearly indicates that this disparate group of proteins builds on the common annexin function of membrane association, but possesses divergent molecular mechanisms. Functionally, the current literature agrees on a key role of plant annexins in stress response processes such as wound healing and drought tolerance. This is contrasted by only few established details of the molecular level mechanisms that are driving these activities.In this review, we appraise the current knowledge of plant annexin molecular, functional and structural properties with a special emphasis on topics of less coverage in recent past overviews. In particular, plant annexin post-translational modification, roles in polar growth and membrane stabilisation processes are discussed.     

Effects of ceramide and other simple sphingolipids on membrane lateral structure

The available data concerning the ability of ceramide and other simple sphingolipids to segregate laterally into rigid, gel-like domains in a fluid bilayer has been reviewed. Ceramides give rise to rigid ceramide-enriched domains when their N-acyl chain is longer than C12. The high melting temperature of hydrated ceramides, revealing a tight intermolecular interaction, is probably responsible for their lateral segregation. Ceramides compete with cholesterol for the formation of domains with lipids such as sphingomyelin or saturated phosphatidylcholines; under these conditions displacement of cholesterol by ceramide involves a transition from a liquid-ordered to a gel-like phase in the domains involved. When ceramide is generated in situ by a sphingomyelinase, instead of being premixed with the other lipids, gel-like domain formation occurs as well, although the topology of the domains may not be the same, the enzyme causing clustering of domains that is not detected with premixed ceramide. Ceramide-1-phosphate is not likely to form domains in fluid bilayers, and the same is true of sphingosine and of sphingosine-1-phosphate. However, sphingosine does rigidify pre-existing gel domains in mixed bilayers.     

Sphingomyelinase dependent apoptosis following treatment of pancreatic beta-cells with amyloid peptides Aß1-42 or IAPP

Amyloid peptides interfere with survival of pancreatic beta-cells. In some cells apoptosis is paralleled by ceramide-dependent alterations of ion channel activity. The purpose of the present study was to elucidate the dependence of amyloid peptides Aß_1-42 and islet amyloid polypeptide (IAPP)-induced cell death on ceramide formation and ion channel activity in murine pancreatic islet cells. As disclosed by TUNEL (terminal dUTP nick-end labelling) and cleaved caspase 3 staining, apoptotic cell death was induced by Aß_1-42, IAPP and exogenously added C2-ceramide in islet cells from wild type mice. In islet cells from acid sphingomyelinase-deficient mice (ASMKO) Aß_1-42 and IAPP but not exogenously added N-acetyl-d-sphingosine (C2-ceramide, 20 μM) failed to stimulate apoptosis. Immunofluorescent staining revealed a stimulatory effect of Aß_1-42 on ceramide formation. According to patch clamp experiments, administration of Aß_1-42 and IAPP significantly decreased outwardly rectifying whole cell currents in wild type but not in ASMKO islet cells. C2-ceramide but not inactive di-ceramide (20 μM) mimicked the inhibitory effect on Kv channel current. In conclusion, amyloid peptides induce apoptosis of pancreatic islet cells at least in part through activation of acid sphingomyelinase resulting in production of ceramide and subsequent inhibition of ion channel activity.     

Role for the disulfide-bonded region of human immunodeficiency virus type 1 gp41 in receptor-triggered activation of membrane fusion function

The conserved disulfide-bonded region (DSR) of the human immunodeficiency virus type 1 (HIV-1) fusion glycoprotein, gp41, mediates association with the receptor-binding glycoprotein, gp120. Interactions between gp120, CD4 and chemokine receptors activate the fusion activity of gp41. The introduction of W596L and W610F mutations to the DSR of HIV-1_QH1549.13 blocked viral entry and hemifusion without affecting gp120-gp41 association. The fusion defect correlated with inhibition of CD4-triggered gp41 pre-hairpin formation, consistent with the DSR mutations having decoupled receptor-induced conformational changes in gp120 from gp41 activation. Our data implicate the DSR in sensing conformational changes in the gp120-gp41 complex that lead to fusion activation.     

Potential roles of membrane fluidity and ceramide in hyperthermia and alcohol stimulation of TRAIL apoptosis

We recently reported that a mild heat shock induces a long lasting stimulation of TRAIL-induced apoptosis of leukemic T-lymphocytes and myeloid cell lines, but not normal T-lymphocytes, which correlates with an enhanced ability of TRAIL to recognize its receptors. As shown here, this phenomenon could be inhibited by the xanthogenate agent D609, a sphingomyelin/ceramide pathway inhibitor. A caspase-dependent and D609-sensitive two-fold increase in ceramide level was elicited by heat shock plus TRAIL combined treatment. One day after heat shock, a similar increase in ceramide was induced by TRAIL. Sphingolipids/ceramides are known to regulate membrane integrity, and heat shock increases membrane fluidity. In this regard, the heat shock plus TRAIL combined treatment resulted in a D609-sensitive membrane fluidization which was far more intense than that induced by heat shock only. We also report that membrane fluidizers, that mimic the effect of heat shock, such benzyl alcohol and ethanol, potently stimulated TRAIL-induced apoptosis. As heat shock, these alcohols increased, in a D609-sensitive manner, membrane fluidity in the presence of TRAIL, the recognition of TRAIL death receptors, and ceramide levels. These results suggest that stress agents that trigger ceramide production and an overall increase in membrane fluidity are stimulators of TRAIL apoptosis.     

Pay attention to membrane tension: Mechanobiology of the cell surface

The cell surface is a mechanobiological unit that encompasses the plasma membrane, its interacting proteins, and the complex underlying cytoskeleton. Recently, attention has been directed to the mechanics of the plasma membrane, and in particular membrane tension, which has been linked to diverse cellular processes such as cell migration and membrane trafficking. However, how tension across the plasma membrane is regulated and propagated is still not completely understood. Here, we review recent efforts to study the interplay between membrane tension and the cytoskeletal machinery and how they control cell form and function. We focus on factors that have been proposed to affect the propagation of membrane tension and as such could determine whether it can act as a global or local regulator of cell behavior. Finally, we discuss the limitations of the available tool kit as new approaches that reveal its dynamics in cells are needed to decipher how membrane tension regulates diverse cellular processes.     

Ceramide inhibits the potassium channel Kv1.3 by the formation of membrane platforms

Previous studies suggested a central role of sphingomyelin- and cholesterol-enriched membrane rafts in the initiation of signaling via many receptors. Here, we investigated the role of membrane rafts for the function of the voltage-gated potassium channel Kv1.3. We demonstrate that Kv1.3 localizes in the cell membrane to pre-existing small, sphingolipid- and cholesterol-enriched membrane rafts. Transformation of these small rafts to large ceramide-enriched membrane platforms was achieved by stimulation of the endogenous acid sphingomyelinase, addition of exogenous sphingomyelinase or treatment of the cells with C(16)-ceramide and resulted in clustering of Kv1.3 within ceramide-enriched membrane platforms and inhibition of the channel's activity. Likewise, disruption of pre-existing small rafts inhibited Kv1.3 activity. This indicates that intact small membrane rafts are required for Kv1.3 activity and an alteration of the lipid environment of rafts inhibits Kv1.3. These data, thus, may suggest a novel concept for the regulation of ion channels by the cell membrane composition.     

Binding protein for Escherichia coli heat-stable enterotoxin II in mouse intestinal membrane

Abstract The protein binding Escherichia coli heat-stable enterotoxin II (STII) was isolated from cell membranes of mouse intestine. The binding of ¹²⁵I-labeled STII to the proteins was inhibited by unlabeled STII, showing that it is specific. Proteins cross-linked with ¹²⁵I-STII were purified by column chromatography on hydroxyapatite and TSK gel. Analyses of the purified protein by SDS-polyacrylamide gel electrophorosis and gel filtration showed that the molecular mass was 25 kDa.     

Tests of integrin transmembrane domain homo-oligomerization during integrin ligand binding and signaling

Integrin transmembrane (TM) and/or cytoplasmic domains play a critical role in integrin bidirectional signaling. Although it has been shown that TM and/or cytoplasmic α and β domains associate in the resting state and separation of these domains is required for both inside-out and outside-in signaling, the role of TM homomeric association remains elusive. Formation of TM homo-oligomers was observed in micelles and bacterial membranes previously, and it has been proposed that homomeric association is important for integrin activation and clustering. This study addresses whether integrin TM domains form homo-oligomers in mammalian cell membranes using cysteine scanning mutagenesis. Our results show that TM homomeric interaction does not occur before or after soluble ligand binding or during inside-out activation. In addition, even though the cysteine mutants and the heterodimeric disulfide-bounded mutant could form clusters after adhering to immobilized ligand, the integrin TM domains do not form homo-oligomers, suggesting that integrin TM homomeric association is not critical for integrin clustering or outside-in signaling. Therefore, integrin TM homo-oligomerization is not required for integrin activation, ligand binding, or signaling.     

Ceramide biosynthesis in keratinocyte and its role in skin function

The enucleate layer of the epidermis, i.e. the stratum corneum, is responsible for certain critical protective functions, such as epidermal permeability barrier function. Within the epidermal membrane lamella component, ceramides are the dominant lipid class by weight (over 50%) and exhibit the greatest molecular heterogeneity in terms of sphingoid base and fatty acid composition. It is now evermore important to understand how ceramide production and functions are controlled in the epidermis, since decreased epidermal ceramide content has been linked to water loss and barrier dysfunction. During the past several years, critical enzymes in ceramide biosynthesis have been identified, including ceramide synthases (CerS) and ceramide hydroxylase/desaturase. In this review, we describe the molecular heterogeneity of ceramides synthesized in the epidermis and their possible roles in epidermal permeability barrier functions. We also describe recent studies that identified the family of CerS (CerS1–CerS6) in mammals. We further focus on the roles of specific isoforms of these enzymes in synthesizing the epidermal ceramides, especially in relation to chain-length specificity. In addition, we provide experimental information, including our recent findings, as to how applying ceramide or ceramide-containing substances to skin, orally or directly, can benefit skin health.     

Ceramide synthase-dependent ceramide generation and programmed cell death: involvement of salvage pathway in regulating postmitochondrial events

The sphingolipid ceramide has been widely implicated in the regulation of programmed cell death or apoptosis. The accumulation of ceramide has been demonstrated in a wide variety of experimental models of apoptosis and in response to a myriad of stimuli and cellular stresses. However, the detailed mechanisms of its generation and regulatory role during apoptosis are poorly understood. We sought to determine the regulation and roles of ceramide production in a model of ultraviolet light-C (UV-C)-induced programmed cell death. We found that UV-C irradiation induces the accumulation of multiple sphingolipid species including ceramide, dihydroceramide, sphingomyelin, and hexosylceramide. Late ceramide generation was also found to be regulated by Bcl-xL, Bak, and caspases. Surprisingly, inhibition of de novo synthesis using myriocin or fumonisin B1 resulted in decreased overall cellular ceramide levels basally and in response to UV-C, but only fumonisin B1 inhibited cell death, suggesting the presence of a ceramide synthase (CerS)-dependent, sphingosine-derived pool of ceramide in regulating programmed cell death. We found that this pool did not regulate the mitochondrial pathway, but it did partially regulate activation of caspase-7 and, more importantly, was necessary for late plasma membrane permeabilization. Attempting to identify the CerS responsible for this effect, we found that combined knockdown of CerS5 and CerS6 was able to decrease long-chain ceramide accumulation and plasma membrane permeabilization. These data identify a novel role for CerS and the sphingosine salvage pathway in regulating membrane permeability in the execution phase of programmed cell death.     

Sorting and function of peroxisomal membrane proteins

Peroxisomes are subcellular organelles and are present in virtually all eukaryotic cells. Characteristic features of these organelles are their inducibility and their functional versatility. Their importance in the intermediary metabolism of cells is exemplified by the discovery of several inborn, fatal peroxisomal errors in man, the so-called peroxisomal disorders. Recent findings in research on peroxisome biogenesis and function have demonstrated that peroxisomal matrix proteins and peroxisomal membrane proteins (PMPs) follow separate pathways to reach their target organelle. This paper addresses the principles of PMP sorting and summarizes the current knowledge of the role of these proteins in organelle biogenesis and function.