Glycoproteins and glycolipids of oxyntic cell microsomes II. Glycopeptides and glycolipids

Glycosylated compounds associated with the carbohydrate-rich tubular membrane system of the oxyntic cell were investigated. Two glycopeptide fractions, designated Peaks A and B, were isolated from pronase digests of bullfrog oxyntic cell microsomes. Molecular sieve chromatography and cellulose acetate electrophoresis revealed that, although somewhat heterogeneous, each peak was composed primarily of glycopeptides with similar molecular weights and net charge densities. Peak B glycopeptides had a mean molecular weight of about 6000 and contained 70% of the recovered carbohydrate in the following molar ratios: hexose, 1.00; $\text{N-}\text{acetylhexosamine}$, 0.71; fucose, 0.61; sialic acids, <0.03. Peak a glycopeptides were considerably larger (molecular weight approx. 100 000) and contained carbohydrates in molar ratios similar to those of Peak B. In both peaks galactose and $\text{N-}\text{acetylglucosamine}$, respectively, were the predominant hexose and amino sugar isomers.The glycolipid content of bullfrog oxyntic cell microsomes was assessed by qualitative and quantitative thin-layer chromatography. The most abundant glycolipids were monoglucosylceramides (0.098 mole/mole phospholipid) and monogalactosylceramides (0.046 mole/mole phospholipid). Small quantities of sulfatides and gangliosides were also present.A compilation of available data regarding the chemical composition of the microsomes revealed that these membranes resemble plasma membranes in having high molar ratios of cholesterol to phospholipid (approx. 1.0) and large quantities of carbohydrate (225 μg/mg protein). The possible significance of these compositional features in protecting the oxyntic cell is discussed.     

Enzymatic synthesis of blood-group Lewis-specific glycolipids.

A blood-group Lewis precursor glycolipid was isolated from the plasma of a Lewis-negative individual [Le(a--b--)] and treated with fucosyltransferases from human gastric mucosa and GDP-fucose. Subsequently the glycolipid was adsorbed onto Le(a--b--) erythrocytes and the presence of blood-group Lewis antigens was assessed by passive hemagglutination with anti-Lewis sera. It was shown that the precursor glycolipid was enzymatically transformed to blood-group Lewis a (Lea) and Lewis b (Leb) specific glycolipids. Leb-glycolipid was also synthesized by fucosylation of an isolated Lea-glycolipid. Moreover Le(a--b--) erythrocytes were shown to develop Lea and Leb activities when subjected to enzymatic fucosylation, thus showing that Lewis-negative cells carry blood-group Lewis precursor glycolipid on the surface of their membrane. Le(a + b--) erthrocytes, upon enzymatic fucosylation, acquired Leb activity.     

Synthetic glycolipids and the lectin-mediated aggregation of liposomes.

Synthetic mannose-containing glycolipids utilizing the cholesterol nucleus as a lipid anchor, and either the 6-aminohexyl- or the 6-(6-aminohexanamido)hexyl-1-thio-alpha-D-mannopyranosides as the carbohydrate ligands, have been synthesized and incorporated into small unilamellar liposomes. Incorporation of these cholesterol-mannoside derivatives at concentrations up to 14 mol% apparently does not affect the physical characteristics of the liposomes. Addition of concanavalin A to a suspension of liposomes containing the long chain cholesterol-mannose derivative causes an increase in light-scattering at 360 nm. As the increase in absorbance is completely reversed by the addition of alpha-methylmannoside, aggregation rather than fusion of the liposomes appears to be occurring. Liposomes containing 14 mol % of the short chain (6-aminohexyl-) derivative are aggregated by concanavalin A indicating that the lectin can approach to within 10 A of the lipid bilayer. Preliminary results suggest that the aggregation of vesicles containing either the long or short chain derivatives is highly dependent on the density of the sugar in the membrane.     

A new class of potent antiproliferative glycolipids.

The synthesis and biological activities of a new class of antiproliferative glycolipids with an unexpected broad spectrum of activity, including a human multidrug resistant cell line, are described. Chemically these compounds are glycolipids derived from N-acetyl-D-glucosamine and glycyrrhetinic acid (beta-aglycone). Peptidation of the glucoacids allyl 3 beta-[[2-acetamido-3-O-[(R)-1-carboxyethyl]- 2-deoxy-4,6-O-isopropylidene-beta-D-glucopyranosyl]oxy]-11-oxo-12- oleanen-30-oate and (R,S)-2-methoxy-3-(octadecyloxy)propyl-2-acetamido-3-O-[(R)-1-carb oxyethyl]- 2-deoxy-4,6-O-isopropylidene-beta-D-glucopyranoside was successfully achieved after activation with O-benzotriazolyl-N,N,N',N' -tetramethyluronium hexafluorophosphate.     

Synthesis of glycolipids

The chemical syntheses of naturally occurring glycolipids derived from sphingosine bases and glycerol derivatives, and the syntheses of polyisoprenoid lipid intermediates and other miscellaneous glycolipids recorded up to the end of 1977 are reviewed.     

Sulfated glycolipids and cell adhesion

The adhesive glycoproteins laminin, thrombospondin, and von Willebrand factor bind specifically and with high affinity to sulfatides, and it is this binding that probably accounts for their ability to agglutinate glutaraldehyde-fixed erythrocytes. The three proteins differ, however, in the inhibition of their binding to sulfatides by sulfated polysaccharides. Fucoidan strongly inhibits binding of both laminin and thrombospondin, but not of von Willebrand factor, suggesting the involvement of laminin or thrombospondin, or other unknown sulfatide-binding proteins in specific cell interactions that are also inhibited by fucoidan. Thrombospondin adsorbed on plastic promotes the attachment and spreading of some melanoma cells. Interestingly, fucoidan and an antibody against the sulfatide-binding domain of thrombospondin selectively inhibit spreading but not attachment to thrombospondin-coated surfaces. Sulfatides, but not neutral glycolipids or gangliosides, when adsorbed on plastic also promote attachment and spreading of some cultured cell lines. Direct adhesion of melanoma cells requires high densities of adsorbed sulfatide. In the presence of laminin, however, specific adhesion of some cell types to sulfatide is strongly stimulated and requires only low densities of adsorbed lipid, suggesting that laminin is mediating adhesion by crosslinking receptors on the cell surface to sulfatide adsorbed on the plastic. Although thrombospondin also binds to sulfatides and to melanoma cells, it does not enhance but rather inhibits direct and laminin-dependent melanoma cell adhesion to sulfatide, presumably because it is unable to bind simultaneously to ligands on opposing surfaces. Thus, sulfated glycolipids can participate in both laminin- and thrombospondin-mediated cell adhesion, but their mechanisms of interaction are different.     

Computer modelling of glycolipids at membrane surfaces.

Interactions of membrane anchored molecules such as glycolipids with a membrane surface are important in determining headgroup conformation. It is therefore essential to represent these membrane surface interactions in molecular modeling studies of glycolipids and other membrane bound molecules. We introduce here an energy term that represents the interaction of molecules with a membrane bilayer. This membrane interaction energy term has been added to the potential energy function of a molecular dynamics and mechanics program and has been parameterized using partition coefficients between an aqueous solution and a vesicular membrane for two model glycolipids.     

Bacterial glycolipids. Glycosyl diglycerides in Gram-positive bacteria

1. The lipids of ten Gram-positive bacteria have been isolated and the presence in each of a glycosyl diglyceride was established. 2. The glycolipid fractions were isolated and deacylated to give water-soluble glycosides which were purified by paper chromatography. Partial structures for the glycosides have been deduced from chemical and enzymic studies. 3. Nine of the glycosides were disaccharides glycosidically linked to the 1-position of glycerol: the remaining glycoside contained a trisaccharide similarly linked to glycerol.     

Plastids and glycolipids in the stemwood of Pinus sylvestris L.

Summary The ultrastructure of plastids in xylem ray parenchyma cells of Pinus sylvestris L. was studied and compared with the glycolipid composition of the stemwood. Seasonal changes of the ultrastructure were studied by taking samples regularly throughout the year. The plastids resemble amyloplasts. They usually have one large starch grain, and considerable variation in structure and starch content was observed, especially in the innermost sapwood and in the sapwood-heartwood transition zone. Electron-dense deposits were observed attached to the plastid membranes and envelopes, especially in the transition zone, from April to November. The plastids were aggregated near the nucleus and the starch disappeared during the winter (January–March). The glycolipids, monogalactosyldiacylglycerol (MGDG) and di-galactosyldiacylglycerol (DGDG), were present only in the sapwood, in trace amounts. The glycolipid content was slightly greater in the outer sapwood than in the sapwood-heartwood transition zone. DGDG was the dominant lipid of the two.     

Isolation and characterization of novel neutral glycolipids from Thermoplasma acidophilum.

Several novel neutral glycolipids (GL-1a, GL-1b, GL-2a, GL-2b and GL-2c) were isolated from Thermoplasma acidophilum by high-performance liquid chromatography using phenylboronic acid-silica and preparative thin-layer chromatography. The tentative structures of these lipids were characterized by the combination of gas-liquid chromatography, the methylation procedure, and (1)H-NMR and FAB-mass spectrometries. The lipophilic portion of the neutral glycolipids was composed of a simple molecular species named caldarchaeol (dibiphytanyl-diglycerol tetraether). The sugar moieties of these glycolipids were composed of gulose and glucose which formed monosaccharide residues on one side or both sides of the core lipids. Gulose was attached to the terminal glycerol OH group of the core lipid with a beta-configuration and glucose being attached with an alpha-configuration. The proposed structure of GL-1a was gulosylcaldarchaeol and that of GL-1b was glucosylcaldarchaeol. The structures of GL-2a, GL-2b, and GL-2c were the analogs of the caldarchaeol derivatives attached by a variety of gulosyl residues or glucosyl residues on both sides of the terminal OH groups.