Fluorescent derivatives of ganglioside GM1 function as receptors for cholera toxin

A fluorescent derivative of ganglioside GM1 was prepared by oxidation of the sialic acid residue with sodium periodate and reaction of the resulting aldehyde with Lucifer yellow CH. The biological activity of the fluorescent derivative was compared with that of native GM1 using GM1-deficient rat glioma C6 cells. When the cells were exposed to either native or fluorescent GM1, their ability to bind 125I-labeled cholera toxin was increased to a similar extent. This increase in binding was directly proportional to the amount of ganglioside added to the medium. The affinity of the toxin for cells treated with either native or fluorescent GM1 also was similar. More importantly, the fluorescent GM1 was as effective as native GM1 in enhancing the responsiveness of the cells to cholera toxin. Thus, the ganglioside-treated cells exhibited a 9-fold increase in toxin-stimulated cyclic AMP production over cells not exposed to GM1. There was a similar increase in iodotoxin binding and toxin-stimulated cyclic AMP accumulation in cells treated with other GM1 derivatives containing rhodaminyl or dinitrophenyl groups. On the basis of these results, it is clear that these modified gangliosides retain the ability to function as receptors for cholera toxin. Consequently, fluorescent gangliosides are likely to be useful as probes for investigating the dynamics and function of these membrane components.     

Neoglycolipid analogues of ganglioside GM1 as functional receptors of cholera toxin.

We synthesized several lipid analogues of ganglioside GM1 by attaching its oligosaccharide moiety (GM1OS) to aminophospholipids, aliphatic amines, and cholesteryl hemisuccinate. We incubated GM1-deficient rat glioma C6 cells with each of the derivatives as well as native GM1 and assayed the cells for their ability to bind and respond to cholera toxin. On the basis of the observed increase in binding of 125I-labeled cholera toxin, it was apparent that the cells took up and initially incorporated most of the derivatives into the plasma membrane. In the case of the aliphatic amine derivatives, the ability to generate new toxin binding sites was dependent on chain length; whereas the C10 derivative was ineffective, C12 and higher analogues were effective. Increased binding was dependent on both the concentration of the neoglycolipid in the medium and the time of exposure. Cells pretreated with the various derivatives accumulated cyclic AMP in response to cholera toxin, but there were differences in their effectiveness. The cholesterol and long-chain aliphatic amine derivatives were more effective than native GM1, whereas the phospholipid derivatives were less effective. The distance between GM1OS and the phospholipid also appeared to influence its functional activity. The neoglycolipid formed by cross-linking the amine of GM1OS to phosphatidylethanolamine (PE) with disuccinimidyl suberate was less effective than the neoglycolipid formed by directly attaching GM1OS to PE by reductive amination. Furthermore, insertion of a C8 spacer in the former neoglycolipid rendered it even less effective.(ABSTRACT TRUNCATED AT 250 WORDS)     

Glycosphingolipids and lysosomal storage disorders as illustrated by gaucher disease

Glycosphingolipids are important building blocks of the outer leaflet of the cell membrane. They are continuously recycled, involving fragmentation inside lysosomes by glycosidases. Inherited defects in degradation cause lysosomal glycosphingolipid storage disorders. The relatively common glycosphingolipidosis Gaucher disease is highlighted here to discuss new insights in the molecular basis and pathophysiology of glycosphingolipidoses reached by fundamental research increasingly using chemical biology tools. We discuss improvements in the detection of glycosphingolipid metabolites by mass spectrometry and review new developments in laboratory diagnosis and disease monitoring as well as therapeutic interventions.     

Glycosphingolipids and drug resistance

Drug resistance, an all too frequent characteristic of cancer, represents a serious barrier to successful treatment. Although many resistance mechanisms have been described, those that involve membrane-resident proteins belonging to the ABC (ATP binding cassette) transporter superfamily are of particular interest. In addition to cancer, the ABC transporter proteins are active in diseases such as malaria and leishmaniasis. A recent renaissance in lipid metabolism, specifically ceramide and sphingolipids, has fueled research and provided insight into the role of glycosphingolipids in multidrug resistance. This article reviews current knowledge on ceramide, glucosylceramide synthase and cerebrosides, and the relationship of these lipids to cellular response to anticancer agents.     

Glycosphingolipids and drug resistance

Drug resistance, an all too frequent characteristic of cancer, represents a serious barrier to successful treatment. Although many resistance mechanisms have been described, those that involve membrane-resident proteins belonging to the ABC (ATP binding cassette) transporter superfamily are of particular interest. In addition to cancer, the ABC transporter proteins are active in diseases such as malaria and leishmaniasis. A recent renaissance in lipid metabolism, specifically ceramide and sphingolipids, has fueled research and provided insight into the role of glycosphingolipids in multidrug resistance. This article reviews current knowledge on ceramide, glucosylceramide synthase and cerebrosides, and the relationship of these lipids to cellular response to anticancer agents.     

Glycosphingolipids of human plasma

A number of glycosphingolipids, including 10 gangliosides, not previously identified in human plasma have been characterized. The plasma contains 2 micrograms of lipid-bound sialic acid/ml plasma and 54% of the gangliosides are monosialo, 30% disialo, 10% trisialo, and 6% tetrasialo. Individual glycosphingolipids were purified by high-performance liquid chromatography and thin-layer chromatography, and were characterized on the basis of their chromatographic mobility, carbohydrate composition, hydrolysis by glycosidases, methylation analysis, and immunostaining with anti-glycosphingolipid antibodies. The monosialogangliosides were identified as GM3, GM2, sialosyl(2-3)- and sialosyl(2-6)lactoneotetraosylceramides, sialosyllacto-N-nor-hexaosylceramide, and sialosyllacto-N-isooctaosylceramide. The major gangliosides in the polysialo fractions contained a ganglio-N-tetraose backbone and were identified as GD3, GD1a, GD1b, and GQ1b. The most abundant neutral glycosphingolipids were glucosyl, lactosyl, globotriaosyl, globotetraosyl and lactoneotetraosylceramides. The other neutral glycosphingolipids, tentatively identified by immunostaining with monoclonal antibodies, contained H1, Lea, Leb, and lacto-N-fucopentose III (X hapten) structures.     

Glycosphingolipids in membrane architecture

As part of a program to investigate the behavior and interactions of glycolipids in biological membranes we have synthesized spin-labeled derivatives of 2 families of carbohydrate-bearing ceramides (glycosphingolipids): simple neutral glycolipids and gangliosides. Galactosyl ceramide has been synthesized with the spin label at 3 different positions on the fatty acid chain. It has been studied in bilayers of various different lipids and lipid mixtures and compared to the corresponding phospholipid spin labels. Considerable similarity has been found between the behavior of galactosyl ceramide and phosphatidylcholine. These similarities include a negligible flip-flop rate, a flexibility gradient in the acyl chains, and exclusion from phosphatidylserine domains in the face of a Ca²⁺-induced lateral phase separation. Evidence for dramatic clustering of simple neutral glycolipids has not been found. Glycosphingolipids do seem to have the capacity to increase rigidity in fluid lipid bilayers. A general procedure has been developed for covalent attachment of a nitroxide spin label to the headgroup region of complex glycolipids such as gangliosides. Studies of beef brain gangliosides labeled in this manner and incorporated into bilayers of phosphatidylcholine indicate that the headgroup oligosaccharides are in rapid, random motion as opposed to being in any way immobilized. This headgroup mobility depends very little on the fluidity or rigidity of the bilayer. However, headgroup mobility decreases, perhaps as a result of cooperative headgroup interactions, with increasing bilayer concentration of unlabeled ganglioside.     

Glycosphingolipids and insulin resistance

Obesity is associated with an increased risk for insulin resistance, a state characterized by impaired responsiveness of liver, muscle and adipose tissue to insulin. One class of lipids involved in the development of insulin resistance are the (glyco)sphingolipids. Ceramide, the most simple sphingolipid, directly inhibits phosphorylation of the insulin signaling mediator Akt/Protein Kinase B. More complex glycosphingolipids, so-called gangliosides, block phosphorylation of the insulin receptor and down-stream signaling, possibly by exclusion of the insulin receptor from specific membrane domains. Pharmacological inhibition of glycosphingolipid synthesis is found to markedly improve insulin sensitivity in rodent models of insulin resistance. Partial glycosphingolipid reduction is well tolerated and may thus offer an attractive new treatment modality for obesity-induced insulin resistance and type II diabetes.     

Glycosphingolipids and cell death

Sphingolipids have been implicated in various cellular processes including growth, cell-cell or ligand-receptor interactions, and differentiation. In addition to their importance as reservoirs of metabolites with important signaling properties, sphingolipids also help provide structural order to plasma membrane lipids and proteins within the bilayer. Glycosylated sphingolipids, and sphingomyelin in particular, are involved in the formation of lipid rafts. Although it is well accepted that ceramide, the backbone of all sphingolipids, plays a critical role in apoptosis, less is known about the biological functions of glycosphingolipids. This review summarizes current knowledge of the involvement of glycosphingolipids in cell death and in other pathological processes and diseases.     

Spider toxin and the glutamate receptors.

A neurotoxin (JSTX) was isolated from the venom of spider (Nephila clavata). JSTX blocked both the excitatory postsynaptic (EPSPs) and glutamate-induced potentials in lobster neuromuscular synapse and squid giant synapse. In mammalian central nervous system, JSTX blocked the EPSPs in CA1 pyramidal neurons resulting from stimulation of Schaffer collateral/commissure input. Pharmacological investigation showed that JSTX preferentially suppressed quisqualate/kainate receptor subtypes but was much less effective on NMDA receptor. Using synthesized spider toxins we studied the structure-activity relationship and found that the 2,4 dihydroxyphenylacetyl asparagine in the toxin structure was responsible for suppressive action, while the remaining part containing a polyamine was related to the agonist binding site with the polycationic part enhancing the toxic activity. Labeling of synthesized JSTX was used for histochemical as well as biochemical studies. Using autoradiography, 125I-JSTX-3 was found to bind at the lobster neuromuscular synapse. Histochemical study utilizing the interaction of biotinylated JSTX-3 with avidin showed specific binding of the toxin in rat cerebellum and hippocampus. JSTX-3-binding protein was purified from rat brain by affinity chromatography. SDS-PAGE of the affinity purified protein showed at least 4 bands ranging from 40 to 70 kDa.     

Glycosphingolipids govern gene expression

To elucidate the biological significance of the lactosylceramide (LacCer) branching in glycosphingolipid (GSL) biosynthesis, we established ganglioside GM3- and lactosylsulfatide SM3-reconstituted cells by introducing the GM3 synthase gene and the sulfotransferase gene, respectively. In SM3-expressing cells, the reduction of beta1 integrin mRNA expression, the reduced adhesivity to fibronectin and laminin, and the suppression of anchorage-independent growth (tumorigenic potential) were observed. On the other hand, in GM3-expressing cells, anchorage-independent growth was promoted and the expression of PDGF alpha receptor mRNA was specifically reduced. Interestingly enough, no change in anchorage-dependent growth was observed in these cells, and tumorigenic signals were controlled selectively in both positive and negative directions. Thus, the spatio-temporal, gene expression control mechanism by individual GSL molecules accumulating in the cell membrane microdomain (raft) has been proven.     

Glycosphingolipids of porcine pancreas

Neutral and acidic glycosphingolipids were purified from porcine pancreas by chromatography on columns of DEAE-Sephadex and Iatrobeads. The chemical structures of the purified glycolipids were determined by carbohydrate analysis, methylation analysis, enzyme treatment, fatty acid analysis, NMR and IR. The major glycolipid of porcine pancreas was Gal(alpha,1-4)Gal(beta,1-)ceramide. Gangliosides GM3 and GD3 were major acidic components and galactosylceramide 3-sulfate was also found.     

Glycosphingolipids of human aorta

The structures of the main gangliosides of human aorta (intima and media) were elucidated. The main component (67%) was identified as N-acetylneuraminosyl-lactosylceramide (ganglioside GM3). The aorta tissue contained also gangliosides GM1, GD3, GD1a, and GT1. All sialic acid residues in gangliosides were present as N-acetyl-neuraminosyl derivatives. Among neutral glycosphingolipids of human aorta, the main components were identified as glucosylceramide, lactosylceramide, globotriaosylceramide and globotetraosylceramide. The preliminary data suggest that the composition of the investigated glycosphingolipids in tissue might vary upon atherosclerosis lesions of aorta.     

Glycosphingolipids govern gene expression

To elucidate the biological significance of the lactosylceramide (LacCer) branching in glycosphingolipid (GSL) biosynthesis, we established ganglioside GM3- and lactosylsulfatide SM3-reconstituted cells by introducing the GM3 synthase gene and the sulfotransferase gene, respectively. In SM3-expressing cells, the reduction of β1 integrin mRNA expression, the reduced adhesivity to fibronectin and laminin, and the suppression of anchorage-independent growth (tumorigenic potential) were observed. On the other hand, in GM3-expressing cells, anchorage-independent growth was promoted and the expression of PDGFα receptor mRNA was specifically reduced. Interestingly enough, no change in anchorage-dependent growth was observed in these cells, and tumorigenic signals were controlled selectively in both positive and negative directions. Thus, the spatio-temporal, gene expression control mechanism by individual GSL molecules accumulating in the cell membrane microdomain (raft) has been proven. Published in 2004. This revised version was published online in August 2006 with corrections to the Cover Date.     

Glycosphingolipids and cell death

Sphingolipids have been implicated in various cellular processes including growth, cell-cell or ligand-receptor interactions, and differentiation. In addition to their importance as reservoirs of metabolites with important signaling properties, sphingolipids also help provide structural order to plasma membrane lipids and proteins within the bilayer. Glycosylated sphingolipids, and sphingomyelin in particular, are involved in the formation of lipid rafts. Although it is well accepted that ceramide, the backbone of all sphingolipids, plays a critical role in apoptosis, less is known about the biological functions of glycosphingolipids. This review summarizes current knowledge of the involvement of glycosphingolipids in cell death and in other pathological processes and diseases. Published in 2004. This revised version was published online in August 2006 with corrections to the Cover Date.     

On the role of polysialoglycosphingolipids as tetanus toxin receptors. A study with lipid monolayers

Lipid monolayers of different compositions were used to study the interaction of tetanus toxin with membrane lipids and to evaluate the role of polysialoglycosphingolipids as membrane receptors. At neutral pH, the toxin binds to dioleoylglycerophosphocholine monolayers and inserts into the phospholipid layer. This effect is potentiated by acidic phospholipids without an apparent preference for a single class of phospholipids. Polysialoglycosphingolipids further increase the fixation and penetration of tetanus toxin in lipid monolayers, but no specific requirement for a particular ganglioside was identified. The ganglioside effect is abolished in the presence of other nervous tissue lipids: cerebrosides and glycosphingolipid sulfates are partially responsible for this effect. The penetration of tetanus toxin in the lipid monolayer is pH dependent. It increases with lowering pH, it is facilitated by acidic phospholipids and by glycosphingolipid sulfates and it is mediated both by hydrophobic and electrostatic interactions as deduced from an analysis of the effect of ionic strength. Fragment B of tetanus toxin the low-pH-driven lipid interaction of the toxin. On the basis of the present findings, the possible role of polysialoglycosphingolipids in the neurospecific binding of tetanus toxin is discussed.