Sphingolipid storage induces accumulation of intracellular cholesterol by stimulating SREBP-1 cleavage

We showed previously that the intracellular transport of sphingolipids (SLs) is altered in SL storage disease fibroblasts, due in part to the secondary accumulation of free cholesterol. In the present study we examined the mechanism of cholesterol elevation in normal human skin fibroblasts induced by treatment with SLs. When cells were incubated with various natural SLs for 44 h, cholesterol levels increased 25-35%, and cholesterol esterification was reduced. Catabolism of the exogenous SLs was not required for elevation of cholesterol because (i) a non-hydrolyzable and a degradable SL analog elevated cellular cholesterol to similar extents, and (ii) incubation of cells with various SL catabolites, including ceramide, had no effect on cholesterol levels. Elevated cholesterol was derived primarily from low density lipoproteins (LDL) and resulted from up-regulation of LDL receptors induced by cleavage of the sterol regulatory element-binding protein-1. Upon SL treatment, cholesterol accumulated with exogenous SLs in late endosomes and lysosomes. These results suggest a model in which excess SLs present in endocytic compartments serve as a "molecular trap" for cholesterol, leading to a reduction in cholesterol at the endoplasmic reticulum, induction of sterol regulatory element-binding protein-1 cleavage, and up-regulation of LDL receptors.     

Sphingolipid metabolism in neural cells

Sphingolipids were discovered more than a century ago in the brain. Cerebrosides and sphingomyelins were named so because they were first isolated from neural tissue. Although glycosphingolipids and especially those containing sialic acid in their oligosaccharide moiety are particularly abundant in the brain, sphingolipids are ubiquitous cellular membrane components. They form cell- and species-specific profiles at the cell surfaces that characteristically change in development, differentiation, and oncogenic transformation, indicating the significance of these lipid molecules for cell-cell and cell-matrix interactions as well as for cell adhesion, modulation of membrane receptors and signal transduction. This review summarizes sphingolipid metabolism with emphasis on aspects particularly relevant in neural cell types, including neurons, oligodendrocytes and neuroblastoma cells. In addition, the reader is briefly introduced into the methodology of lipid evaluation techniques and also into the putative physiological functions of glycosphingolipids and their metabolites in neural tissue.     

Sphingolipid metabolism in Bacteroideaceae.

The lipid composition of the anaerobic Bacteroides thetaiotaomikron has been analyzed. Sphingomyelin, ceramide phosphinicoethanolamine, free even-numbered and branched chain sphingosine bases and ceramide represented about 50% of the total lipid extract. The main ester phospholipid was phosphatidylethanolamine. The alkali-stable sphingophospholipids were predominantly N-acylated with 3-hydroxypalmitic acid, whereas the ester phospholipids are preferentially substituted with normal even and odd-numbered and branched-chain fatty acids. When Bacteroides was grown in a medium supplemented with labelled palmitic acid, this fatty acid was utilized for acylation reactions and to a large extent for the de novo synthesis of sphinganine. This long-chain base was incorporated into the sphingolipids and was also present in free form. The 3-hydroxypalmitic acid present in sphingolipids is not derived from palmitic acid, since labelled palmitate did not serve as a precursor. Free sphinganine added to the culture medium was also utilized efficiently for the biosynthesis of the sphingolipids by growing Bacteroides cultures. The 3H/14C ratio in sphingomyelin and ceramide phosphinicoethanolamine is the same, when [1-14C]palmitic acid and [3-3H]sphinganine serve as precursors. Sphingomyelin, which is usually only present in higher animals, is synthesized de novo in this Bacteroides strain.     

Sphingolipid metabolism in neural cells

Sphingolipids were discovered more than a century ago in the brain. Cerebrosides and sphingomyelins were named so because they were first isolated from neural tissue. Although glycosphingolipids and especially those containing sialic acid in their oligosaccharide moiety are particularly abundant in the brain, sphingolipids are ubiquitous cellular membrane components. They form cell- and species-specific profiles at the cell surfaces that characteristically change in development, differentiation, and oncogenic transformation, indicating the significance of these lipid molecules for cell-cell and cell-matrix interactions as well as for cell adhesion, modulation of membrane receptors and signal transduction. This review summarizes sphingolipid metabolism with emphasis on aspects particularly relevant in neural cell types, including neurons, oligodendrocytes and neuroblastoma cells. In addition, the reader is briefly introduced into the methodology of lipid evaluation techniques and also into the putative physiological functions of glycosphingolipids and their metabolites in neural tissue.     

Interaction among molecules in mixtures of ceramide/stearic acid,ceramide/cholesterol and ceramide/stearic acid/cholesterol

To elucidate the interaction among the molecules which constitute intercellular lipids of stratum corneum, the phase diagrams in the binary mixtures of N-octadecanoyl-phytosphingosine (CER)/stearic acid (SA) and CER/cholesterol (CHOL) were studied by differential scanning calorimetry and by small- and wide-angle X-ray diffraction. These phase diagrams are mostly expressed by a eutectic type one. However, from their detailed analyses, it was revealed that in the phase diagram of CER/SA a new solid structure is formed just above the eutectic temperature. The lamellar spacing of the new structure is nearly equal to the length given by the sum of the two molecules of CER and/or SA, that is, in the lipid bilayer the hydrocarbon chains of CER and SA lie almost perpendicular to the lipid bilayer surface and the two kinds of molecules distribute homogeneously. On the other hand, in the binary mixture of CER/CHOL, CHOL molecules are apt to be isolated from the mixture. In a ternary mixture composed of equimolar lipids of CER, CHOL and SA, it was found that a pseudo-hexagonal structure takes place even in the solid state. This fact indicates that the three components are miscible and the hydrocarbon chains lie perpendicular to the lipid bilayer surface. We can draw the conclusion that the multi-component mixtures containing ceramide are apt to form the lamellar structure where even in the solid state the hydrocarbon chains lie perpendicular to the lipid bilayer surface and the components with hydrocarbon chains distribute homogeneously.     

Roles of ESCRT in autophagy-associated neurodegeneration

Autophagy is a regulated pathway for bulk degradation of cytoplasmic contents and organelles, an important process involved in many physiological and pathological conditions in multiple organs, including the nervous system. It has been proposed that developing autophagosomes fuse with late endosomal compartments before their fusion with lysosomes; however, little is known about the functional relationship between the autophagy and endocytic pathways. In the endosomal-lysosomal pathway, a key step in sorting transmembrane cargo proteins is regulated by multimeric complexes called ESCRT (endosomal sorting complex required for transport). We recently reported that dysfunction of ESCRT-III, either by depletion of its essential subunit mSnf7-2 or by expression of a mutant CHMP2B protein associated with frontotemporal dementia linked to chromosome 3 (FTD3), caused autophagosome accumulation and dendritic retraction before neurodegeneration in cultured mature cortical neurons. This defect is likely a result of an abnormal fusion process between autophagosomes and endosomal compartments or lysosomes. This study suggests that defects in the late steps of the autophagy pathway may contribute to the pathogenesis of FTD and potentially other neurodegenerative diseases.     

Sphingolipid/cholesterol regulation of neurotransmitter receptor conformation and function

Like all other monomeric or multimeric transmembrane proteins, receptors for neurotransmitters are surrounded by a shell of lipids which form an interfacial boundary between the protein and the bulk membrane. Among these lipids, cholesterol and sphingolipids have attracted much attention because of their well-known propensity to segregate into ordered platform domains commonly referred to as lipid rafts. In this review we present a critical analysis of the molecular mechanisms involved in the interaction of cholesterol/sphingolipids with neurotransmitter receptors, in particular acetylcholine and serotonin receptors, chosen as representative members of ligand-gated ion channels and G protein-coupled receptors. Cholesterol and sphingolipids interact with these receptors through typical binding sites located in both the transmembrane helices and the extracellular loops. By altering the conformation of the receptors (“chaperone-like” effect), these lipids can regulate neurotransmitter binding, signal transducing functions, and, in the case of multimeric receptors, subunit assembly and subsequent receptor trafficking to the cell surface. Several sphingolipids (especially gangliosides) also exhibit low/moderate affinity for neurotransmitters. We suggest that such lipids could facilitate (i) the attachment of neurotransmitters to the post-synaptic membrane and in some cases (ii) their subsequent delivery to specific protein receptors. Overall, various experimental approaches provide converging evidence that the biological functions of neurotransmitters and their receptors are highly dependent upon sphingolipids and cholesterol, which are active partners of synaptic transmission. Several decades of research have been necessary to untangle the skein of a complex network of molecular interactions between neurotransmitters, their receptors, cholesterol and sphingolipids. This sophisticated crosstalk between all four distinctive partners may allow a fine biochemical tuning of synaptic transmission.     

Sphingolipid storage impairs autophagic clearance of Alzheimer-associated proteins

Recent work from our laboratory demonstrates that the accumulation of sphingolipids (SLs) decreases the capacity of cells to clear potentially amyloidogenic fragments of the amyloid precursor protein (APP) during autophagy. APP is a type I membrane protein and could undergo sequential proteolytic processing by β- and γ-secretase resulting in the generation of the amyloid β-peptide (Aβ). Genetic, molecular and biochemical evidence indicates that the accumulation of toxic Aβ aggregates plays a critical role in the degeneration of neurons during the pathogenesis of Alzheimer disease (AD). Thus, SL storage could promote the accumulation of Ab in endosomal and lysosomal compartments and thereby induce characteristic cytopathological changes of AD.     

Sphingolipid storage impairs autophagic clearance of Alzheimer-associated proteins

Recent work from our laboratory demonstrates that the accumulation of sphingolipids (SLs) decreases the capacity of cells to clear potentially amyloidogenic fragments of the amyloid precursor protein (APP) during autophagy. APP is a type I membrane protein and could undergo sequential proteolytic processing by β- and γ-secretase resulting in the generation of the amyloid β-peptide (Aβ). Genetic, molecular and biochemical evidence indicates that the accumulation of toxic Aβ aggregates plays a critical role in the degeneration of neurons during the pathogenesis of Alzheimer disease (AD). Thus, SL storage could promote the accumulation of Ab in endosomal and lysosomal compartments and thereby induce characteristic cytopathological changes of AD.     

Sphingolipid metabolism during epidermal barrier development in mice

In rodents, a competent skin barrier to water loss is formed within 2 or 3 days prior to birth. Acquisition of barrier function during rat gestation correlates with the formation of a stratum corneum enriched in ceramides, cholesterol, and fatty acids (Aszterbaum, M., G. K. Menon, K. R. Feingold, and M. L. Williams. 1992. Ontogeny of the epidermal barrier to water loss in the rat: correlation of function with stratum corneum structure and lipid content. PEDIATR: Res. 31: 308-317). We analyzed the formation and epidermal localization of glucosylceramides during embryonic skin barrier development in Balb/c mice. Using immunohistochemistry, epidermal glucosylceramides were hardly detectable 3 days prior to birth. After further 24 h of gestation the level of glucosylceramides was maximal and decreased with increasing gestational age. In parallel, glucosylceramides were targeted to the apical side of the outermost granular keratinocyte layer. A spectrum of five distinct epidermal ceramides was present 2 days prior to birth. With ongoing gestation the composition of the ceramide fraction changed markedly. Most importantly, the level of omega-hydroxylated acylceramides decreased paralleled by the formation of the corneocyte lipid envelope. This structure consists of omega-hydroxylated ceramides and fatty acids bound to surface proteins of the corneocytes. The covalent attachment of ceramides or glucosylceramides correlated with the maturation of the stratum corneum and might contribute to its chemical and enzymatic resistance.     

Connecting cell-cycle activation to neurodegeneration in Drosophila

Studies in cell-culture systems and in postmortem tissue from human disease have suggested a connection between cell-cycle activation and neurodegeneration. The fruit fly Drosophila melanogaster has recently emerged as a powerful model system in which to model neurodegenerative diseases. Here we review work in the fly that has begun to address some of the important questions regarding the relationship between cell-cycle activation and neurodegeneration in vivo, including recent data implicating cell-cycle activation as a downstream effector of tau-induced neurodegeneration. We suggest how powerful research tools in Drosophila might be utilized to approach fundamental questions that remain.     

Cholesterol surrogates: a comparison of cholesterol and 16:0 ceramide in POPC bilayers

Experimental evidence indicates that, under some circumstances, "surrogate" molecules may play the same role as cholesterol in ordering membrane lipids. The simplest molecule in this class is Ceramide. In this article, we describe atomic-level molecular dynamics simulations designed to shed light on this phenomenon. We run simulations of hydrated phosphoryl-oleoyl phosphatidylcholine (POPC) bilayers containing cholesterol, and containing ceramide, in concentrations ranging from 5% to 33%. We also perform a simulation of a pure POPC bilayer to verify the simulation force fields against experimental structural data for POPC. Our simulation data are in good agreement with experimental data for the partial molecular volumes, areas, form factors, and order parameters. These simulations suggest that ceramide and cholesterol have a very similar effect on the POPC bilayer, although ceramide is less effective in inducing order in the bilayer compared with cholesterol at the same concentrations.     

Thematic review series: Lipid droplet synthesis and metabolism: from yeast to man. Lipid droplet-based storage fat metabolism in Drosophila

The fruit fly Drosophila melanogaster is an emerging model system in lipid metabolism research. Lipid droplets are omnipresent and dynamically regulated organelles found in various cell types throughout the complex life cycle of this insect. The vital importance of lipid droplets as energy resources and storage compartments for lipoanabolic components has recently attracted research attention to the basic enzymatic machinery, which controls the delicate balance between triacylglycerol deposition and mobilization in flies. This review aims to present current insights in experimentally supported and inferred biological functions of lipogenic and lipolytic enzymes as well as regulatory proteins, which control the lipid droplet-based storage fat turnover in Drosophila.