g(m1)-ganglioside and stearic-acid

Sphingolipid ceramide N-deacylase catalyzes a reversible reaction in which the amide linkages of the ceramides of various sphingolipids are cleaved or synthesized. Hydrolysis of sphingolipids by the enzyme proceeded efficiently at acidic pH in the presence of high concentrations of detergents, whereas the reverse reaction tended to be favored at neutral pH with a decrease in the detergent concentration. Although the catalytic efficiency (V(max)/K(m)) of the hydrolysis and reverse reactions was changed mainly by the concentration of detergents in the reaction mixture, V(max) and K(m) for the reverse reaction were relatively higher than those for the forward reaction, irrespective of the detergent concentration. The reverse reaction proceeded most efficiently when the molar ratio of lyso-sphingolipids and fatty acids was fixed at 1 : 1-2, the yield of the reaction exceeding 70-80%. The reverse and exchange (transacylation) reactions did not require ATP, CoA, metal ions or addition of organic solvents. Studies using inhibitors and chemical modifiers of the enzyme protein suggested that both the hydrolysis and condensation reactions are catalyzed at the same catalytic domain. These results indicate that the reverse hydrolysis reaction of the enzyme is unique, being completely different from those of lipases, proteases and glycosidases reported to date.

Topics: Adenosine Triphosphate; Amidohydrolases; Animals; Brain; Catalysis; Cattle; Coenzyme A; Dose-Response Relationship, Drug; Fatty Acids; G(M1) Ganglioside; Hydrogen-Ion Concentration; Hydrolysis; Isomerism; Kinetics; Mass Spectrometry; Protein Binding; Protein Structure, Tertiary; Pseudomonas; Stearic Acids; Time Factors

A quartz crystal microbalance (QCM) was used to study the adhesion behavior of supramolecular aggregates at supported planar bilayers (SPBs). The QCM technique is a suitable method to detect the adsorption of biomolecules at the quartz surface owing to its sensitivity for changes in mass and viscoelastic properties. To simulate biomembranes, the quartz plates were coated with highly ordered lipid films. Therefore, a combination of self-assembled monolayers and Langmuir-Blodgett films was used. Firstly, the adsorption of liposomes coupled with the lectin concanavalin A was investigated at glycolipid-containing model membranes. Using different carbohydrates, it was possible to determine specific and nonspecific parts of the interactions. The adhesion occurred owing to specific lectin-carbohydrate interactions (about 20%) and to nonspecific interactions (about 80%). The composition of the liposomes was changed to simulate the structure of a native biomembrane consisting of the glycocalix, the lipid-protein bilayer, and the cytoskeleton. An artificial glycocalix was created by incorporating poly(ethylene glycol) into the liposomes. Liposomes which were intravesicular polymerized with polyacrylamide or polyacrylcholate simulated the cytoskeleton. It was determined that the modified liposomes had significant lower interactions with SPBs. The adsorption was reduced by approximately 80% compared to unmodified liposomes. Secondly, a model was developed for the detection of interactions between simple or mixed bile salt micelles and model membranes. It was found that simple bile salts did not adsorb at model membranes. Binary systems consisting of bile salt and phospholipid induced only small interactions. On the other hand, ternary systems consisting of bile salt, phospholipid, and fatty acid showed strong interactions. A dependence on the chain length of the fatty acid was observed. Thirdly, the interaction between ganglioside-containing model membranes and cholera toxin (beta-subunit) was investigated. Different ganglioside fractions showed varying adsorption in the following sequence: GM1 > GD1a > GD1b > GT1b.

Topics: 1,2-Dipalmitoylphosphatidylcholine; Biophysics; Carbohydrate Conformation; Carbohydrate Sequence; Cholera Toxin; Concanavalin A; G(M1) Ganglioside; Gangliosides; Indicators and Reagents; Lauric Acids; Lipid Bilayers; Models, Biological; Models, Molecular; Molecular Conformation; Molecular Sequence Data; Phosphatidylcholines; Stearic Acids; Weights and Measures

Topics: Animals; Autoradiography; beta-N-Acetylhexosaminidases; Biotinylation; Caprylates; Carbohydrate Sequence; Carbon Radioisotopes; Cells, Cultured; Chromatography, High Pressure Liquid; Chromatography, Thin Layer; Fibroblasts; G(M1) Ganglioside; Gangliosides; Magnetic Resonance Spectroscopy; Microscopy, Immunoelectron; Molecular Sequence Data; Neuraminidase; Spectrometry, Mass, Fast Atom Bombardment; Spectrometry, Mass, Matrix-Assisted Laser Desorption-Ionization; Stearic Acids

It was previously shown that sphingomyelin and gangliosides can be biosynthesized starting from sphingosine or sphingosine-containing fragments which originated in the course of GM1 ganglioside catabolism. In the present paper we investigated which fragments were specifically re-used for sphingomyelin and ganglioside biosynthesis in rat liver. At 30 h after intravenous injection of GM1 labelled at the level of the fatty acid ([stearoyl-14C]GM1) or of the sphingosine ([Sph-3H]) moiety, it was observed that radioactive sphingomyelin was formed almost exclusively after the sphingosine-labelled-GM1 administration. This permitted the recognition of sphingosine as the metabolite re-used for sphingomyelin biosynthesis. Conversely, gangliosides more complex than GM1 were similarly radiolabelled after the two treatments, thus ruling out sphingosine re-utilization for ganglioside biosynthesis. For the identification of the lipid fragment re-used for ganglioside biosynthesis, we administered to rats neutral glycosphingolipids (galactosylceramide, glucosylceramide and lactosylceramide) each radiolabelled in the sphingosine moiety or in the terminal sugar residue. Thereafter we compared the formation of radiolabelled gangliosides in the liver with respect to the species administered and the label location. After galactosylceramide was injected, no radiolabelled gangliosides were formed. After the administration of differently labelled glucosylceramide, radiolabelled gangliosides were formed, regardless of the position of the label. After lactosylceramide administration, the ganglioside fraction became more radioactive when the long-chain-base-labelled precursors were used. These results suggest that glucosylceramide, derived from glycosphingolipid and ganglioside catabolism, is recycled for ganglioside biosynthesis.

Topics: Animals; G(M1) Ganglioside; Gangliosides; Glucosylceramides; Liver; Male; Rats; Rats, Inbred Strains; Sphingomyelins; Sphingosine; Stearic Acids