Structural studies of the acidic oligosaccharide units from bovine glycophorin

The O-glycosidically-linked carbohydrate units of glycophorin from bovine erythrocyte membrane were released by alkaline borohydride treatment. These oligosaccharides were separated into the neutral fractions and the acidic fractions by ion-exchange chromatography followed by gel filtration. The two acidic fractions (fractions 10 and 13) which have the smallest molecular weight in acidic oligosaccharides, were further purified by gel filtration on Bio-Gel P-4 column. Two acidic oligosaccharides (fractions 10-I and 10-II), heptasaccharides, were separated by gel filtration on a Bio-Gel P-4 column from fraction 10. These structures were determined by methylation analyses, nitrous acid deamination after hydrazinolysis and Smith degradation after desialylation. In addition, the structures were also analyzed by direct-probe mass spectrometry of the permethylated derivatives before and after desialylation. These studies indicated that one of them (fraction 10-I) was NeuNGcα(2→3)Galβ(1→4)GlcNAcβ(1→3)Galβ(1→4)GlcNAcβ(1→3)Galβ(1→3) GalNAcol and another heptasaccharide (fraction 10-II) was Galβ(1→4)GlcNAcβ(1→3)Galβ(1→3) [NeuNGcα(2→3)Galβ(1→4)GlcNAcβ(1→6)]GalNAcol. Athough another acidic fraction (fraction 13) was obtained as a single peak on a Bio-Gel P-4 column, it appeared to be the mixture of a heptasaccharide, NeuNGcα(2→3)Galβ(1→4)GlcNAcβ(1→3 or 6)[Galβ(1→4)GlcNAcβ(1→6 or 3)]Galβ(1→3)GalNAcol and an oligosaccharide similar to fraction 10-II, by analysis of two products obtained by Smith degradation after desialylation.     

Subcomponents C1q of the first component of guinea pig and mouse complement: Comparative study of their asparagine-linked sugar chains

Guinea pig and mouse C1q, subcomponents of the first component of complement, contained six asparagine-linked sugar chains on the C-terminal non-collagenous globular regions of each molecule. After N-acetylation and successive NaB³H₄-reduction of asparagine-linked sugar chains liberated by hydrazinolysis, their structure was analysed by sequential exoglycosidase digestion in combination with sugar composition analyses. The sugar chains of C1q molecules of both animals were very similar and composed of the biantennary complex type sugar chains with the following outer chains in various combinations: (± NeuNAcα → )Galß1 → GlcNAcß1 → and Galß1 → Galß1 → GlcNAcß1 →. These chain moieties were found to be linked to a common core structure of Manα1 → (Manα1 → )Manß1 → GlcNAcß1 → (Fucα1 → )GlcNAc.     

NMR study on the hydroxy protons of the Lewis X and Lewis Y oligosaccharides

The ¹H NMR chemical shifts and NOEs of hydroxy protons in Lewis X trisaccharide, β-d-Galp-(1 → 4)[α-l-Fucp-(1 → 3)]-β-d-GlcpNAc, and Lewis Y tetrasaccharide, α-l-Fucp-(1 → 2)-β-d-Galp-(1 → 4)[α-l-Fucp-(1 → 3)]-β-d-GlcpNAc, were obtained for 85% H₂O/15% (CD₃)₂CO solutions. The OH-4 signal of Galp in Lewis X and OH-3, OH-4 signals of Galp, and OH-2 signal of Fucp linked to Galp in Lewis Y had chemical shifts which indicate reduced hydration due to their proximity to the hydrophobic face of the Fucp unit linked to GlcpNAc. The inter-residue NOEs involving the exchangeable NH and OH protons confirmed the stacking interaction between the Fucp linked to the GlcpNAc and the Galp residues in Lewis X and Lewis Y.     

Synthesis and binding analysis of unique AG2 pentasaccharide to human Siglec-2 using NMR techniques

Siglec-2 is a mammalian sialic acid binding protein expressed on B-cell surfaces and is involved in the modulation of B-cell mediated immune response. We synthesized a unique starfish ganglioside, AG2 pentasaccharide Galfβ(1–3)Galpα(1–4)Neu5Acα(2–3)Galpβ(1–4)Glcp, and found that the synthetic pentasaccharide binds to human Siglec-2 by performing ¹H NMR experiments. Saturation transfer difference NMR experiments indicated that the C7–C9 side-chain and the acetamide moiety of the central sialic acid residue were located in the binding face of human Siglec-2. We determined the binding epitope of AG2 pentasaccharide to human Siglec-2, as the Galpα(1–4)Neu5Acα(2–3)Galp unit.     

Specific detection of N-acetylglucosamine-containing oligosaccharide chains on ovine submaxillary asialomucin

Human milk β-N-acetylglucosaminide β1 → 4-galactosytransferase (EC 2.4.1.38) was used to galactosylate ovine submaxillary asialomucin to saturation. The major [¹⁴C]galactosylated product chain was obtained as a reduced oligosaccharide by β-elimination under reducing conditions. Analysis by Bio-Gel filtration and gas-liquid chromatography indicated that this compound was a tetrasaccharide composed of galactose, N-acetylglucosamine and reduced N-acetylgalactosamine in a molar ratio of 2:0.9:0.8. Periodate oxidation studies before and after mild acid hydrolysis in addition to thin-layer chromatography revealed that the most probable structure of the tetrasaccharide is $\text{Gal}\text{β1 → 3([}{}^{14}\text{C}\text{]}\text{Gal}\text{β1 → 4}\text{GlcNac}\text{β1 → 6)}\text{GalNAcol}$. Thus it appears that Galβ1 → 3(GlcNAcβ1 → 6)GalNAc units occur as minor chains on the asialomucin. The potential interference of these chains in the assay of α-N-acetylgalactosaminylprotein β1 → 3-galactosyltransferase activity using ovine submaxillary asialomucin as an receptor can be counteracted by the addition of N-acetylglucosamine.     

Structural and immunochemical identification of Leb glycolipids in the plasma of a group O Le(a-b-) secretor

Total non-acid glycosphingolipids were isolated from the plasma of a healthy red blood cell group O Le(a-b-) salivary ABH secretor individual. Glycolipids were fractionated by HPLC and combined into eight fractions based on chromatographic and immunoreactive properties. These glycolipid fractions were analysed by thin-layer chromatography and tested for Lewis activity with antibodies reactive to the type 1 precursor (Le^c), H type 1 (Le^d), Le^a and Le^b epitopes. Fractions were structurally characterized by mass spectrometry (EI-MS and LSIMS) and proton NMR spectroscopy. Expected blood group glycolipids, such as H type 1, (Fuc1-2Gal1-3GlcNAc1-3Gal1-4Glc1-1Cer) were immunochemically and structurally identified. Inconsistent with the red cell phenotype and for the first time, small quantities of Le^b blood group glycolipids (Fuc1-2Gal1-3(Fuc1-4)GlcNAc1-3Gal1-4Glc1-1Cer) were immunochemically and structurally identified in the plasma of a Lewis-negative individual. These findings confirm recent immunological evidence suggesting the production of small amounts of Lewis antigens by Lewis negative individuals. Abbreviations: HPLC, high performance liquid chromatography; TLC, (high performance) thin layer chromatography; EI-MS, electron impact ionisation mass spectrometry; LSIMS, liquid secondary ion mass spectrometry; NMR, nuclear magnetic resonance spectroscopy. The sugar types are abbreviated to Hex for hexose, HexNAc forN-acetylhexosamine and dHex for deoxyhexose (fucose). The ceramide types are abbreviated to d for dihydroxy and t for trihydroxy base, n for non-hydroxy and h for hydroxy fatty acids; LCB, long chain base.     

N-andO-alkylation of glycoconjugates and polysaccharides by solid base in dimethyl sulphoxide/alkyl lodide

O-Methylation of simple neutral oligosaccharides is readily accomplished in dimethyl sulphoxide containing solid sodium hydroxide and methyl iodide [Cincanu I, Kerek F (1984) Carbohydr Res 131209-17]. This procedure has been extended to 2-acetamido-2-deoxy sugars and sialic acid-containing oligosaccharides. CompleteO-andN-methylation was in most cases achieved in 15 min. Esterification of carboxylic groups in uronic acids was fast and resulted in concomitant -elimination. The method is also suitable for methylation of glycoproteins and glycosphingolipids. Polysaccharides can also be methylated by this technique. Analysis of the products by gas-liquid chromatography and mass spectrometry showed no degradation products.Abbreviations lacto-N-tetraose LcOse₄, Gal3GlcNAc3Gal4Glc - lacto-N-fucopentaose III III³Fuc-nLcOse₄, Gal4[Fuc3]GlcNAc3Gal4Glc - trihexosylceramide GbOse₃Cer, Gal4Gal4Glc1-1Cer - globoside GbOse₄Cer, GalNAc3Gal4Glc1-1Cer - FAB-MS fas atom bombardment mass spectrometry     

The Conformational Properties of the Glc3Man Unit Suggest Conformational Biasing within the Chaperone-assisted Glycoprotein Folding Pathway

A major puzzle is: are all glycoproteins routed through the ER calnexin pathway irrespective of whether this is required for their correct folding? Calnexin recognizes the terminal Glcα1-3Manα linkage, formed by trimming of the Glcα1-2Glcα1-3Glcα1-3Manα (Glc₃Man) unit in Glc₃Man₉GlcNAc₂. Different conformations of this unit have been reported. We have addressed this problem by studying the conformation of a series of N-glycans; i.e. Glc₃ManOMe, Glc₃Man₄,₅,₇GlcNAc₂ and Glc₁Man₉GlcNAc₂ using 2D NMR NOESY, ROESY, T-ROESY and residual dipolar coupling experiments in a range of solvents, along with solution molecular dynamics simulations of Glc₃ManOMe. Our results show a single conformation for the Glcα1-2Glcα and Glcα1-3Glcα linkages, and a major (65%) and a minor (30%) conformer for the Glcα1-3Manα linkage. Modeling of the binding of Glc₁Man₉GlcNAc₂ to calnexin suggests that it is the minor conformer that is recognized by calnexin. This may be one of the mechanisms for controlling the rate of recruitment of proteins into the calnexin/calreticulin chaperone system and enabling proteins that do not require such assistance for folding to bypass the system. This is the first time evidence has been presented on glycoprotein folding that suggests the process may be optimized to balance the chaperone-assisted and chaperone-independent pathways.     

Substrate recognition of the catalytic α-subunit of glucosidase II from Schizosaccharomyces pombe

The recombinant catalytic α-subunit of N-glycan processing glucosidase II from Schizosaccharomyces pombe (SpGIIα) was produced in Escherichia coli. The recombinant SpGIIα exhibited quite low stability, with a reduction in activity to <40% after 2-days preservation at 4 °C, but the presence of 10% (v/v) glycerol prevented this loss of activity. SpGIIα, a member of the glycoside hydrolase family 31 (GH31), displayed the typical substrate specificity of GH31 α-glucosidases. The enzyme hydrolyzed not only α-(1→3)- but also α-(1→2)-, α-(1→4)-, and α-(1→6)-glucosidic linkages, and p-nitrophenyl α-glucoside. SpGIIα displayed most catalytic properties of glucosidase II. Hydrolytic activity of the terminal α-glucosidic residue of Glc₂Man₃-Dansyl was faster than that of Glc₁Man₃-Dansyl. This catalytic α-subunit also removed terminal glucose residues from native N-glycans (Glc₂Man₉GlcNAc₂ and Glc₁Man₉GlcNAc₂) although the activity was low.     

Receptors for glucocorticoids in lung tissue

Gas chromatography-mass spectrometric identification of partially methylated aminosugars has been developed: (a) various kinds of O-methylated 2-deoxy-2-(N-methyl)-acetamidohexitols were prepared from partially O-(1-methoxy)-ethylated 2-deoxy-2-acetamidohexoses, and their gas chromatography-mass spectrometric patterns were determined; (b) permethylated glycolipids gave a satisfactory yield of 2-deoxy-2-N-methyl-amidohexoses by acetolysis with 0.5 n sulfuric acid in 95% acetic acid, followed by aqueous hydrolysis; (c) the resulting partially methylated aminosugars and neutral sugars were analyzed after borohydride reduction and acetylation according to the procedure of Lindberg and associates (Björndal, Lindberg and Svennson, 1967; Björndal, Hellerqvist, Lindberg and Svensson, 1970).This method was successfully applied to analysis of aminosugar linkages in blood group B-active ceramide pentasaccharide from rabbit erythrocytes and in Forssman antigen of equine spleen. The structure of blood group B-active glycolipid of rabbit erythrocyte was found to be Galα1 → 3Galβ1 → 4G1cNAcβ1 → 3Ga11 → 4Glc → Cer, and that of Forssman antigen to be GaNAcα1 → 3GalNAcβ1 → 3Galα1 → 4Ga11 → 4Glc → Cer.     

Structural characterization of glycolipids of rat small intestine having one to eight hexoses in a linear sequence

Eight different fractions containing glycolipids with 1 to 8 hexoses in a linear sequence were isolated from rat small intestine. The structure of the major components was established by mass spectrometry and proton nuclear magnetic resonance spectroscopy of the permethylated and permethylated-reduced (LiAlH₄) derivatives and by gas-liquid chromatography of degradation products of the native and permethylated or permethylated-reduced glycolipids. The major compounds were glucosylceramide, lactosylceramide, globotriaosylceramide, and a novel tetrahexosylceramide with the structure Gal α 1 → 3Galα1 → 4Galβ1 → 4Glcβ1 → 1Cer. In addition four minor compounds having five to eight hexoses were identified with the probable structures Galα1 → 3Galα1 → 3Galα1 → 4Galβ1 → 4Glcβ1 → 1Cer, Galα1 → 3Galα1 → 3Galα1 → 3Galα1 → 4Galβ1 → 4Glcβ1 → 1Cer, Gal1 → 3Gal1 → 3Gal1 → 3Gal1 → 3Gal1 → 4Gal1 → 4Glc1 → 1Cer, and Gal1 → 3Gal1 → 3Gal1 → 3Gal1 → 3Gal1 → 3Gal1 → 4Gal1 → 4Glc1 → 1Cer. In the pentahexosylceramide fraction a novel fucolipid was also present having the probable structure Fucα1 → 2Galα1 → 3Galα1 → 4Galβ1 → 4Galβ1 → 1Cer. The lipophilic part of the glycolipids was composed of trihydroxy 18:0 and dihydroxy 18:1 long-chain bases in combination with nonhydroxy and hydroxy 16:0–24:0 fatty acids. Glycolipid studies of isolated mucosal epithelial cells and the nonepithelial intestinal residue revealed a specific cell distribution of these hexosyl compounds. The two major components, glucosylceramide and globotriaosylceramide, were mainly located in the epithelial cells together with small amounts of lactosylceramide and tetrahexosylceramide. The epithelial cells practically lacked however the penta- to octahexosylceramides. The nonepithelial residue contained all hexosyl compounds. The fucolipid was exclusively present in the epithelial cells.     

Glycosphingolipid expression in human skeletal and heart muscle assessed by immunostaining thin-layer chromatography

In this study the comparative TLC immunostaining investigation of neutral GSLs and gangliosides from human skeletal and heart muscle is described. A panel of specific polyclonal and monoclonal antibodies as well as the GM1-specific choleragenoid were used for the overlay assays, combined with preceding neuraminidase treatment of gangliosides on TLC plates. This approach proved homologies but also quantitative and qualitative differences in the expression of ganglio-, globo- and neolacto-series neutral GSLs and gangliosides in these two types of striated muscle tissue within the same species. The main neutral GSL in skeletal muscle was LacCer, followed by GbOse3Cer, GbOse4Cer, nLcOse4Cer and monohexosylceramide, whereas in heart muscle GbOse3Cer and GbOse4Cer were the predominant neutral GSLs beside small quantities of LacCer, nLcOse4Cer and monohexosylceramide. No ganglio-series neutral GSLs and no Forssman GSL were found in either muscle tissue. GM3(Neu5Ac) was the major ganglioside, comprising almost 70% in skeletal and about 50% in cardiac muscle total gangliosides. GM2 was found in skeletal muscle only, while GD3 and GM1b-type gangliosides (GM1b and GD1) were undetectable in both tissues. GM1a-core gangliosides (GM1, GD1a, GD1b and GT1b) showed somewhat quantitative differences in each muscle; lactosamine-containing IV3Neu5Ac-nLcOse4Cer was detected in both specimens. Neutral GSLs were identified in TLC runs corresponding to e.g. 0.1 g muscle wet weight (GbOse3Cer, GbOse4Cer), and gangliosides GM3 and GM2 were elucidated in runs which corresponded to 0.2 g muscle tissue. Only 0.02 g and 0.004 g wet weight aliquots were necessary for unequivocal identification of neolacto-type and GM1-core gangliosides, respectively. Muscle is known for the lowest GSL concentration from all vertebrate tissues studied so far. Using the overlay technique, reliable GSL composition could be revealed, even from small muscle probes on a sub-orcinol and sub-resorcinol detection level. Abbreviations: ATCC, American Type Culture Collection; GSL(s), glycosphingolipid(s); HPLC, high performance liquid chromatography; HPTLC, high performance thin layer chromatography; Neu5Ac, N-acetylneuraminic acid; Neu5Gc, N-glycolylneuraminic acid [78]; PBS, phosphate buffered saline. The designation of the following glycosphingolipids follows the IUPAC-IUB recommendations [79] and the ganglioside nomenclature system of Svennerholm [80]. Lactosylceramide or LacCer, Gal1-4Glc1-1Cer; gangliotriaosylceramide or GgOse3Cer, GalNAc1-4Gal1-4Glc1-1Cer; gangliotetraosylceramide or GgOse4Cer, Gal1-3GalNAc1-4Gal1-4Glc1-1Cer; globotriaosylceramide or GbOse3Cer, Gal1-4Gal1-4Glc1-1Cer; globoside or globotetraosylceramide or GbOse4Cer, GalNAc1-3Gal1-4Gal1-4Glc1-1Cer; Fo or Forssman GSL, GalNAc1-3GalNAc1-3Gal1-4Gal1-4Glc1-1Cer; paragloboside or lacto-N-neotetraosylceramide or nLcOse4Cer, Gal1-4GlcNAc1-3Gal1-4Glc1-1Cer; lacto-N-norhexaosylceramide or nLcOse6Cer, Gal1-4GlcNAc1-3Gal1-4GlcNAc1-3Gal1-4Glc1-1Cer; GM3, II3Neu5Ac-LacCer; GM2, II3Neu5Ac-GgOse3Cer; GM1 or GM1a, II3Neu5Ac-GgOse4Cer; GM1b, IV3Neu5Ac-GgOse4Cer; GD3, II3(Neu5Ac)2-LacCer; GD1a, IV3Neu5Ac,II3Neu5Ac-GgOse4Cer; GD1b, (II3Neu5Ac)2-GgOse4Cer; GD1, IV3Neu5Ac,III6Neu5Ac-GgOse4Cer; GT1b, IV3Neu5Ac,II3(Neu5Ac)2-GgOse4Cer; GQ1b, IV3(Neu5Ac)2, II3(Neu5Ac)2-GgOse4Cer.     

Glycosphingolipids of leukocytes are unbranched at the galactopyranosyl residue and contain fucosylα-1-3-N-acetylglucosamine structures

Glycolipids of peripheral leukocytes which had been used for the production of interferon were separated into oligoglycosylceramides, polyglycosylceramides and polyglycosylpeptides (erythroglycan). Neutral oligoglycosylceramides comprised glucosylceramide, galactosylceramide, lactosylceramide, lactotriaosylceramide, globotriaosylceramide andneolactotetraosylceramide. Globotetraosylceramide was not detected. Glycolipids which were more complex thanneolactotetraosylceramide belonged exclusively to theneolacto series of compounds and were essentially unbranched at galactopyranosyl residues. The polyglycosylceramide fraction contained a glycolipid with a probable structure Gal1-4(Fuc1-3) GlcNAc1-3Gal1-4GlcNAc1-3 Gal1-4GlcNAc1-3Gal1-4Glc1-1ceramide. Polyglycosylpeptides were found only in trace amounts and were also unbranched at galactopyranosyl residues. All glycoconjugates studies did not contain significant amounts of carbohydrate structures derived from ABH immunodominant groups.Nomenclature Gal1-4Gal1-4GlcCer Lactotrioasylcermide (LcOse₃Cer) - Gal1-4Gal1-4GlcCer globotriaosylceramide, (GbOse₄Cer) - GalNAc1-3Gal1-4 Gal1-4GlcCer globoside (globotetraosylceramide, GbOse₄Cer) - Gal1-4GlcNAc1-3Gal1-4GlcCer paragloboside (lacto-N-neo tetraosylceramide,nLcOse₄Cer)     

Microscale analysis of glycosphingolipids by TLC blotting/secondary ion mass spectrometry: a novel blood group A-active glycosphingolipid and changes in glycosphingolipid expression in rat mammary tumour cells with different metastatic potentials

The glycosphingolipid compositions of rat mammary tumour cell lines with different metastatic potentials for the lung [a parental tumour cell line (MTC) and its subclones MTLn2 (a non metastatic subclone) and MTLn3 (a subclone with high metastatic potential to the lung)] were studied using a newly developed TLC blotting/secondary ion mass spectrometry system and crude glycosphingolipids obtained from 0.5–1×10⁷ cells of each cell line. G_M3 and G_M2 were the major components of the MTC cell line, but they were very minor components in the MTLn2 and MTLn3 cell lines, G_Dla being the major ganglioside. HexNAc-fucosyl-G_Mla was found in the MTLn2 cells by the TLC blotting/SIMS method, and the terminal sugar linkage was shown to be a blood group A-type structure by immunostaining. These findings suggest that the ganglioside is a novel type of blood group A-active ganglioside, GalNAc1-3(Fuc1-2)G_Mla. No blood group A-active lipid was present in MTLn3 cells, whereas Hex-G_Mla and neutral glycosphingolipids with more than 5 sugar residues were. Abbreviations: TLC, thin-layer chromatography; HPTLC plate, high performance thin-layer chromatography-plate; PVDF, polyvinylidene difluoride; SIMS, secondary ion mass spectrometry; GC-MS, gas chromatography-mass spectrometry; C16:0, hexadecanoic acid; C18:0, octadecanoic acid; C22:0, docosanoic acid; C24:0, tetracosanoic acid; d18:1, 2-amino-4-octadecene-1,3-diol; Hex, hexose; HexNAc,N-acetylhexosamine; Gal, galactose; Glc, glucose; GalNAc,N-acetylgalactosamine; Lac, lactose; NeuAc,N-acetylneuraminic acid; Cer, ceramide; Glob, globoside; iGlob, isogloboside; GlcCer, glucosylceramide; LacCer, lactosylceramide; Gb₃Cer, Gal1-4Gal1-4Glc1-1Cer; Gb₄Cer (Glob), GalNAc1-3Gal1-4Glc1-1Cer; iGb₃Cer, Gal1-3Gal1-4Glc1-1Cer; iGb₄Cer (iBlob), GalNAc1-3Gal1-4Glc1-1Cer; Ganglio-series gangliosides are named according to Svennerholm [1].     

Structure identification of the complex-type,asparagine-linked sugar chains of β-d-galactosyl-transferase purified from human milk

The asparagine-linked sugar chains of human milk galactosyltansferase were quantitatively released as oligosaccharides from the polypeptide backbone by hydrazinolysis. They were converted into radioactive oligosaccharides by sodium borotritiate reduction after N-acetylation, and fractionated by paper electrophoresis and by Bio-Gel P-4 column chromatography after sialidase treatment. Structural studies of each oligosaccharides by sequential exoglycosidase digestion and methylation analysis indicated that the galactosyltransferase contains bi, tri-, and probably tetra-antennary, complex-type oligosaccharides having α-d-Manp-(1→3)-[α-d-Manp-(1→6)]-β-d-Manp-(1→4)-β-d-GlcpNAc-(1→4)-α-d-[Fucp-(1→6)]-d- GlcNAc as their common core. Variation is produced by the different locations and numbers of the five different outer chains: β-d-Galp-(1→4)-d-GlcNAc, α-l-Fucp-(1→3)-[β-d-Galp-(1→4)]-d-GlcNAc, α-NeuAc-(2→6)-β-d-Galp-(1→4)-d-GlcNAc, α-l-Fucp-(1→3)-[β-d-Galp-(1→4)]-β-d-GlcpNAc-(1→3)-β-d-Galp-(1→4)-[α-l-Fucp-(1→3)]-d- GlcNAc, and α-NeuAc-(2→6)-β-d-Galp-(1→4)-β-d-GlcpNAc-(1→3)-β-d-Galp-(1→4)-[α-l-Fucp-(1→3)-β-d-GlcNAc.     

Arabinogalactan protein cluster from Jatropha curcas seed embryo contains fasciclin,xylogen and LysM proteins

An non-GPI-anchored AGP cluster (Y2) was isolated from the seeds of Jatropha curcas L. (Euphorbiaceae) composed of 4.8% polypeptides (mainly Ala, Ser, Gly, Hyp, Glu) and a carbohydrate moiety composed of Gal, Ara, GlcA, Rha, Man and GlcN. Besides the typical structural features of arabinogalactan proteins, typical N-glycan linker of the complex type (GlcNAc₄Man₃Gal₂Fuc₁Xyl₁) were identified. O-glycosylation occurred mainly via Hyp and to a lesser extent via Thr and Ser. N-glycans from the complex type, carrying at the innermost GlcNAc at position O-3 one α-Fuc-residue, were also present.     

Immunochemistry of the Lewis-blood-group system: Partial characterization of Lea-, Leb-, and H-type 1 (LedH)-blood-group active glycosphingolipids from human plasma

Four different H-type 1 (Le^dH) blood-group-active glycosphingolipids (Le^dH-I–IV) have been isolated from the plasma of blood-group O Le(a?b?) secretors. The agglutination of O Le(a?b?) erythrocytes from secretors by 50 μl of 4 hemagglutinating units of caprine anti-Le^dH (anti-H-type 1) serum was inhibited by 0.02 μg of each of all four glycolipids. No Le^a or Le^b activities or reaction against Ulex europaeus lectin could be found. Le^dH-I, -II, -III, and -IV at 0.05, 0.01, 0.01, and 0.02 μg each are sufficient for incubation in order to convert 9 × 10⁷ O Le(a?b?) erythrocytes from nonsecretors into H-type 1 (Le^dH)-positive cells. Structural analysis of the H-type 1 glycolipids was performed in comparison to that of Le^a- and Le^b-blood-group-active glycolipids from human plasma isolated previously: Gas chromatography of peracetylated alditols revealed sugar composition. Combined gas chromatography-mass spectrometry established the glycosidic linkages. Together with the results obtained by direct inlet mass spectrometry of permethylated glycosphingolipids and by 360-MHz ¹H nuclear magnetic resonance spectroscopy (Egge, H., and Hanfland, P., 1981, Arch. Biochem. Biophys., 210, 396–404; Dabrowski, J., Hanfland, P., Egge, H., and Dabrowski, U., 1981, Arch. Biochem. Biophys., 210, 405–411) the complete structures of the oligosaccharide chains of the Le^a-, Le^b-, and H-type 1-active glycolipids were established: Galβ1 → 3GlcNAc(4 ← 1αFuc)β1 → 3Galβ1 → 4Glcβ1 → 1 Cer for the Le^a antigens; Fucα1 → 2Galβ1 → 3GlcNAc(4 ← 1αFuc)β1 → 3Galβ1 → 4Glcβ1 → 1 Cer for the Le^b antigens; and Fucα1 → 2Galβ1 → 3GlcNAcβ1 → 3Galβ1 → 4Glcβ1 → 1 Cer for the H-type 1 (Le^dH) glycolipids. The diverse antigens of the same blood-group specificity obviously differ from one another in their lipid residue. In addition, plasmatic neolactotetraosylceramide could be identified, differing from that of human erythrocytes by a slower migration behavior in thin-layer chromatography.     

Binding of the galactose-specificPseudomonas aeruginosa lectin,PA-I,to glycosphingolipids and other glycoconjugates

The carbohydrate-binding specificity ofPseudomonas aeruginosa lectin I (PA-I) in iodinated or biotinylated form was studied. A large number of glycosphingolipids, as well as some glycoproteins and neoglycoproteins were used as ligands. Also, inhibition by free saccharides of PA-I binding to glycosphingolipids was tested. It was found that the lectin binds most strongly to terminal and nonsubstituted Gal3Gal- or Gal4Gal-structures.Abbreviations PA-I Pseudomonas aeruginosa lectin I - Cer ceramide - lactosylceramide Gal4GlcCer - iso globotriaosylcerami Gal3Gal4GlcCer - globotriaosylceramide Gal4Gal4GlcCer - globoside or globotetraosylceramide GalNAc3Gal4Gal4GlcCer - Forssman glycolipid GalNAc3GalNAc3Gal4Gal4GlcCer - P1 glycolipid Gal4Gal4GlcNAc3Gal4GlcCer - lactoneotetraosylceramide Gal4GlcNAc3Gal4GlcCer - B5 glycolipid Gal3Gal4GlcNAc3Gal4GlcCer - gangliotetraosylceramide Gal3GalNAc4Gal4GlcCer - GM1 Gal3GalNAc4(NeuAc3)Gal4GlcCer - RBC red blood cells - BSA bovine serum albumin - PBS phosphate-buffered saline - SDS sodium dodecyl sulfate - TLC thin-layer chromatography - HPLC high pressure liquid chromatography - MS mass spectrometry - FAB fast-atom bombardment - EI electron impact     

Isolation and characterization of a Forssman antigen-binding lectin from velvet bean (Mucuna derringiana) seeds

A Forssman antigen (GalNAc1-3GalNAc1-3Gal1-4Gal1-4Glc1-1Cer)-binding lectin has been purified from velvet bean (Mucuna derringiana) seeds by a combination of affinity chromatography and reversed phase HPLC. This lectin agglutinates both native and trypsin-treated sheep erythrocytes as well as trypsinized rabbit erythrocytes, but neither native rabbit nor human erythrocytes, irrespective of blood group type. SDS-PAGE and gel filtration chromatography reveal the lectin to be a homodimer consisting of two 54 kDa subunits linked by non-covalent bonds. The results obtained by quantitative precipitation, haemagglutination inhibition and TLC overlay assays indicate that theMucuna lectin specifically recognizes Forssman antigen and Forssman disaccharide (GalNAc1-3GalNAc)-related structures. Abbreviations: The abbreviations and the trivial names used are: AH, 6-aminohexyl; BSA, bovine serum albumin; Cer, ceramide; HPLC, high performance liquid chromatography; PAGE, polyacrylamide gel electrophoresis; PBS, 10mm phosphate-buffered saline, pH 7,2, containing 0.15m NaCl; PMSF, phenyl methyl sulfonyl fluoride; SDS, sodium dodecyl sulphate; TFA, trifluoroacetic acid; TBS, 20mm tris-buffered saline, pH 7.2; TLC, thin-layer chromatography; A disaccharide, GalNAc1-3Gal; A trisaccharide, GalNAc1-3[Fuc1-2]Gal; Forssman disaccharide, GalNAc1-3GalNAc; CDH (ceramide dihexoside or lactosyl ceramide) Gal1-4Glc1-1Cer (LacCer); CTH (ceramide trihexoside or globotriosyl ceramide), Gal1-4Gal1-4Glc1-1Cer (GbOse₃Cer or Gb₃); globoside (globotetraosyl ceramide), GalNAc1-3Gal1-4Gal1-4Glc1-1Cer (GbOse₄Cer or Gb₄); Forssman antigen (globopentaosyl ceramide), GalNAc1-3GalNAc1-3Gal1-4Gal1-4Glc1-1Cer (GbOse₅Cer).     

Different binding capacities of influenza A and Sendai viruses to gangliosides from human granulocytes

The structures of gangliosides from human granulocytes were elucidated by fast atom bombardment mass spectrometry and by gas chromatography/mass spectrometry as their partially methylated alditol acetates. In human granulocytes besides G_M3 (II³Neu5Ac-LacCer), neolacto-series gangliosides (IV³Neu5Ac-nLcOse₄Cer, IV⁶Neu5Ac-nLcOse₄Cer and VI³Neu5Ac-nLcOse₆Cer) containing C_24:1, and to some extent C_22:0; and C_16:0 fatty acid in their respective ceramide portions, were identified as major components. In this study we demonstrate that gangliosides from human granulocytes, the second most abundant cells in peripheral blood, can serve as receptors for influenza viruses A/PR/8/34 (H1N1), A/X-31 (H3N2), and a parainfluenza virus Sendai virus (HNF1, Z-strain). Viruses were found to exhibit specific adhesion to terminal Neu5Ac2-3Gal and/or Neu5Ac2-6Gal sequences as well as depending on the chain length of ganglioside carbohydrate backbones from human granulocytes, these important effector cells which represent the first line of defence in immunologically mediated reactions. Abbreviations: FAB-MS, fast atom bombardment mass spectrometry; GC/EIMS, gas chromatography/electron impact mass spectrometry; GSL(s) glycosphingolipids; HPTLC, high performance thin-layer chromatography; Neu5Ac,N-acetylneuraminic acid [26], PFU, plaque forming unit. The designation of the following glycosphingolipids follows the IUPAC-IUB recommendations, and the ganglioside nomenclature system of Svennerholm was used. LacCer or lactosylceramide, Gal1-4Glc1-1Cer gangliotetraosylceramide or GgOse₄Cer, Gal1-3GalNAc1-4Gal1-4Glc1-1Cer; lacto-N-tetraosylceramide or nLcOse₄Cer, Gal1-4GlcNAc1-3Gal1-4-Glc1-1Cer; lacto-N-norhexaosylceramide or nLcOse₆Cer, Gal1-4GlcNAc1-3Gal1-4GlcNAc1-3Gal 1-4-Glc1-1Cer; G_M3, II³Neu5Ac-LacCer; G_M1, II³Neu5Ac-GgOse₄Cer; G_D1a, IV³Neu5Ac, II³Neu5Ac-GgOse₄Cer; G_D1b, II³(Neu5Ac)₂-GgOse₄Cer; G_T1b, IV³Neu5Ac, II³(Neu5Ac)₂-GgOse₄Cer; G_Q1b, IV³(Neu5Ac)₂, II³(Neu5Ac)₂-GgOse₄Cer; sialyllacto-N-tetraosylceramide, IV³Neu5Ac/IV⁶Neu5Ac-nLcOse₄Cer; sialyllacto-N-norhexaosylceramide or i-active ganglioside, VI³Neu5Ac-nLcOse₆Cer.