Non-reducing Terminal Positions Research Articles

Plant mucilages. XIX. Isolation and characterization of a mucous polysaccharide, "Lilium-Lo-glucomannan," from the bulbs of Lilium longiflorum.

A mucous polysaccharide, named Lilium-Lo-glucomannan, has been isolated from the bulbs of Lilium longiflorum THUNB. It was homogeneous on glass-fiber paper electrophoresis and in ultracentrifugal analysis. The component sugars of it were D-mannose and D-glucose in the molar ratio of 5 : 2, and its molecular weight was estimated at 263000. Methylation, periodate oxidation, and partial acetolysis studies suggested that the polysaccharide is mainly composed of β-1→4 linked aldohexopyranose residues and it contains about ten aldohexose units per non-reducing terminal group on the average. D-Mannose units occupy non-reducing terminal positions and branch points linked through positions 2 or 3. The O-acetyl groups in the polysaccharide were identified and determined as the content of 3.2%. They were located in positions 6, 2, 6, 3, 6, and 2, 3, 6 of a part of D-mannose units, and 6 and 2, 3, 6 of a part of D-glucose units.

Plant mucilages. XXI. Isolation and characterization of a mucous polysaccharide, "Lilium-Ma-glucomannan," from the bulbs of Lilium maculatum.

A mucous polysaccharide, named Lilium-Ma-glucomannan, has been isolated from the bulbs of Lilium maculatum THUNB. It was homogeneous on glass-fiber paper electrophoresis and by ultracentrifugal analysis. The component sugars of the glucomannan were D-mannose and D-glucose in the molar ratio of 7 : 4, and its molecular weight was measured at 184000. Methylation, periodate oxidation, and partial acetolysis studies suggested that the polysaccharide is mainly composed of β-1→4 linked aldohexopyranose residues and it contains about seven aldohexose units per one end group on the average. D-Mannose units occupy non-reducing terminal positions and branching points linked through positions 2 or 3. The O-acetyl groups in the glucomannan were identified and determined as the content of 4.7%. They were located in positions 2, 3, 6, 3, 6, and 2, 3, 6 of a part of D-mannose units, and 6 and 2, 3, 6 of a part of D-glucose units.

The structures of the carbohydrate moieties of the alpha subunit of human chorionic gonadotrophin.

The alpha subunit of human chorionic gonadotrophin was reduced with dithiothreitol followed by carboxymethylation with iodoacetic acid. The modified glycoprotein was hydrolysed with trypsin to give various peptides, the identities of which were established, and glycopeptides. The glycopeptides were separated by gel filtration and ion-exchange chromatography; they were subjected to component analysis and were found to represent the two carbohydrate moieties in the parent glycoprotein. Sequential removal with glycoside hydrolases of monosaccharide units from the glycopeptides demonstrated (1) that galactose, mannose, glucosamine (2-amino-2-deoxyglucose) and neuraminic acid (5-amino-3,5-dideoxy-glycero-galacto-2-nonulosonic acid) residues possess the D configurations, (2) that the glucosamine units are N-acetylated and (3) the order of the monosaccharide units in the chain, the neuraminic acid units being furthest from the peptide backbone of the subunit and substituting the D-galactose units. Methylation analysis of the glycopeptides by adaptation of the Hakomori technique demonstrated that: (4) D-galactose, D-mannose and N-acetylglucosamine (2-acetamido-2-deoxy-D-glucose) units exist in the pyranose forms; (5) the D-galactopyranose units are linked in the 1 and 6 positions; (6) the D-mannopyranose units exist in several forms, one in a terminal non-reducing position, one as 1,2-linked residues and some as 1,6-linked branch points; (7) the N-acetylglucosamine units are 1,6-linked. On the basis of the results of methylation and enzymic analysis, structures are proposed for the carbohydrate moieties and the assignments are compared with other data previously obtained by periodate-oxidation studies [Kennedy et al. (1974) Carbohydr. Res. 36, 369-377].

Plant mucilages. XIII. Isolation and characterization of a mucous polysaccharide, "Lilium-S-glucomannan," from the bulbs of Lilium speciosum.

A mucous polysaccharide, named Lilium-J-glucomannan, has been isolated from the bulbs of Lilium japonicum THUNB. It was homogeneous on glass-fiber paper electrophoresis, by ultracentrifugal analysis, and on gel chromatography. The component sugars of it were D-mannose and D-glucose in the molar ratio of 5 : 2, and its molecular weight was measured to be 318000. The O-acetyl groups in the glucomannan were identified and determined as the content of 5.0%. They were located in positions 2, 3, and 6 of a part of D-mannose units. Methylation, partial acetolysis, and periodate oxidation studies suggested that the glucomannan is mainly composed of β-1→4 linked aldohexopyranose residues and it contains about seventeen aldohexose units per one non-reducing group on the average. D-Mannose units occupy non-reducing terminal positions and branching points linked through positions 2 or 3. A few D-glucose residues are also present as branching points linked through position 3. The comparison of the structure and the property of the glucomannan with those of the other five Lilium-glucomannans was described.

Plant mucilages. IX. The location of the O-acetyl groups and the nature of the branches in bletilla-glucomannan.

Bletilla-glucomannan, the mucous polysaccharide isolated from Bletilla striata REICHENBACH fil., was found to contain 4.2% of O-acetyl group. The O-acetyl groups were located in position 3 of most of the glucose units. Methylation study provided the evidences that the polysaccharide is mainly composed of β-1→4 linked aldohexopyranose residues having a branched structure with 1→2 branch point at a part of mannose units, and mannose units occupy non-reducing terminal positions in the molecule.

Structural investigation of the carbohydrate element of human pituitary follicle-stimulating hormone by methylation analysis.

A preparation of human follicle-stimulating hormone has been subjected to methylation analysis by using the methyl sulphinyl carbanion-dimethyl sulphoxide-methyl iodide method. The hydrolysis products of the methylated glycoprotein were reduced, acetylated, analysed by gas-phase chromatography and mass spectrometry and identified by comparison with standards. Methylation analysis demonstrated that (1) the d-galactose, mannose, fucose and 2-amino-2-deoxyglucose units exist in the pyranose forms, (2) the 2-amino-2-deoxyglucose units are N-acetylated, (3) the fucopyranose units occupy terminal non-reducing positions, (4) the d-galactopyranose units are linked in the 1- and 2-positions, (5) the mannopyranose units exist in three forms, some as terminal non-reducing residues, some as 1,6-linked residues and some as 1,3,4-linked branch points, and (6) the 2-acetamido deoxyglucopyranose units are 1,6-linked. These structural assignments are compared with other data previously obtained for the carbohydrate moieties of follicle-stimulating hormone.

Enzymic degradation of keratosulphates.

1. A multienzyme system capable of degrading keratosulphates to yield galactose, N-acetylglucosamine and sulphate was found in the liver extract of a marine gastropod, Charonia lampas. 2. During the degradation, neither oligosaccharides nor sulphated sugars were produced. 3. It is suggested that the degradation could be attributed to the concerted action of beta-galactosidase, beta-N-acetylglucosaminidase and a sulphatase (sulphohydrolase), tentatively designated keratosulphatase. 4. Two forms of keratosulphatase (I and II) were separated by DEAE-Sephadex column chromatography. Both forms could release all the sulphate from keratosulphates and neither appeared to be identical with glycosulphatase or chondrosulphatase, both of which are also present in Charonia lampas. 5. beta-Galactosidase and beta-N-acetylglucosaminidase could degrade keratopolysulphate to a greater extent in the presence of keratosulphatase than in its absence. 6. It is suggested that keratosulphate was first desulphated by the action of keratosulphatase, and the desulphated polymer was then degraded to galactose and N-acetylglucosamine by the action of beta-galactosidase and beta-N-acetylglucosaminidase. 7. beta-Galactosidase alone released a small amount of galactose from shark cartilage keratopolysulphate, but beta-N-acetylglucosaminidase alone did not release N-acetylglucosamine. This indicates that unsulphated galactose residues occupy all the non-reducing terminal positions in keratopolysulphate chains.

The Composition and Structure of the Carbohydrate of Pineapple Stem Bromelain

Abstract Two major components of pineapple bromelain, purified to electrophoretical homogeneity, appeared to have the same oligosaccharide group consisting of d-glucosamine, d-mannose, d-xylose, and l-fucose in ratios of 2:2:1:1. By exhaustive proteolysis of the bromelains, glycopeptides containing only Asx, Glx, and Ser were obtained. Periodate oxidation, methylation, and glycosidase digestion showed that the oligosaccharide chain has a highly branched structure in which all the neutral sugars are in nonreducing terminal positions and both N-acetyl-d-glucosamine residues occur in internal positions.

Studies on the Biosynthesis of Mannan in Micrococcus lysodeikticus: I. Characterization of Mannan-14C Formed Enzymatically from Mannosyl-1-Phosphoryl-Undecaprenol

Abstract Previous studies had suggested that mannosyl-1-phosphosphoryl-undecaprenol was an intermediate in the transfer of mannosyl units from GDP-mannose to mannan. In this report Triton X-100 and EDTA were used as selective inhibitors of the enzymatic synthesis of mannan. As a result of these studies the hypothesis that mannosyl-1-phosphoryl-undecaprenol was an obligatory intermediate in mannan biosynthesis was confirmed. The distribution of radioactive mannosyl units in mannan prepared in vitro was analyzed with the techniques of exhaustive methylation, acetolysis, and enzymatic digestion. Exhaustive methylation revealed that only the nonreducing terminal positions had become labeled as a result of the enzymatic reaction. Mannan formed in vitro was degraded by acetolysis to primarily disaccharides and trisaccharides; in both types of oligosaccharides the radioactivity was concentrated in the nonreducing termini. Enzymatic digestion with α-mannosidases released a large proportion of the radioactivity present in mannan formed enzymatically and thereby confirmed the results of methylation and acetolysis. As a result of exhaustive methylation the mannan was found to contain 1 → 2, 1 → 3, and 1 → 6 mannosidic linkages and the extent of branching in the polysaccharide was low.

The 6-O-Methylglucose-containing Lipopolysaccharide of Mycobacterium phlei: Identification of d-Glyceric Acid and 3-O-Methyl-d-Glucose in the Polysaccharide

Abstract The polysaccharide containing 6-O-methylglucose, from Mycobacterium phlei, is an acidic molecule with at least seven 6-O-methyl-d-glucopyranosyl residues linked α-1,4', and with a side chain of at least three α-1,4'-d-glucopyranosyl units. A simplified procedure is described for isolating the polysaccharide (MGP) from acetone-dried M. phlei cells with improved yield. Exhaustive α-amylase digestion of the polysaccharide released glucose, maltose, and a disaccharide. The last yielded d-glucose and 3-O-methyl-d-glucose after acid hydrolysis; while hydrolysis, after reduction with sodium borohydride, gave glucitol and 3-O-methylglucose. Methylation analysis established that the disaccharide was 3-O-methyl-α-d-glucopyranosyl-(1 → 4)-d-glucose. Limited α-amylolysis of MGP yielded a trisaccharide and a tetrasaccharide, each containing 1 mole of 3-O-methylglucose at the nonreducing end. The trisaccharide was digested by α-amylase to the disaccharide 3-O-methylglucosyl-(1 → 4)-glucose and glucose, while α-amylolysis of the tetrasaccharide gave these products plus maltose. A glucoamylase preparation converted the tetrasaccharide to the trisaccharide and glucose. That 3-O-methylglucose was at the nonreducing terminus of each saccharide was shown by partial acid hydrolysis studies and by the products of exhaustive propylation, which yielded 3-O-methyl-2,4,6-tri-O-propylglucose. Propylation of the intact polysaccharide and analysis of the fully alkylated methylglucosides by gas-liquid chromatography established that 3-O-methylglucose and glucose were in the nonreducing terminal positions. After α-amylase digestion, glucose was the only terminal residue. Glucoamylase removed an additional glucosyl residue, which had been linked α-1,4' to a 6-O-methylglucosyl residue. An organic acid having the chromatographic and electrophoretic properties of glyceric acid was isolated from acid hydrolysates of MGP. The glyceric acid was oxidized by 1 mole of sodium periodate, with the release of 1 mole of formaldehyde and 1 of glyoxalate. It was shown to have the d configuration. 3-O-Methylglyceric acid was obtained by hydrolysis of methylated MGP, showing that the linkage to the polysaccharide involved the 2-hydroxyl group. MGP was converted to the hydroxamate, and a Lossen rearrangement was performed in water at neutral pH. The reducing sugar thus formed was reduced with sodium borotritide, and the radioactive polyol obtained by acid hydrolysis was identified as glucitol. Thus, the glyceric acid must be attached glycosidically to a glucose residue. The intact lipopolysaccharide, MGLP, was not associated with purified M. phlei cell wall or particulate preparations. The material was recovered quantitatively from the high speed supernatant, apparently in free form. An attempt to degrade the main chain enzymatically with extracts from M. phlei was unsuccessful, and a search both for low molecular weight oligosaccharides containing 6-O-methylglucose and for large polysaccharides into which MGLP might have been incorporated was unproductive. Thus, our investigations have failed to suggest a structural or metabolic function for the lipopolysaccharide. MGLP, isolated from the cultural filtrate of M. phlei cells in the stationary phase, was indistinguishable from the intracellular molecule. It was released into the medium during all stages of the growth cycle, the kinetics following those for the appearance of low molecular weight carbohydrates and of mannose- and arabinose-containing polysaccharides.

A MUCOID ISOLATED FROM BOVINE RED CELLS EXHIBITING STRONG PNEUMOCOCCUS TYPE XIV CROSS-REACTIVITY.

IT is well known that all human and some animal red cells are agglutinated by anti-Type XIV pneumococcus serum1–3. The chemical nature of this phenomenon has been elucidated by Watkins and Morgan4 by means of haemagglutination inhibition tests and has been interpreted as being due to the presence of O-β-D-galacto-pyranosyl-(1->4)-N-acetyl-D-glucosamine in terminal non-reducing position. This structure is considered to be an essential part of the human ABH—and Lewis blood group precursor substance, concluded from studies on the secreted material5.

Structure of a galactomannan-peptide allergen from trichophyton mentagrophytes

A galactomannan-peptide allergen isolated from the pathogenic fungus Trichophyton mentagrophytes has been shown to contain d-galactose (9%), d-mannose (73%) and protein (9%). A molecular weight of 40 000 was suggested, indicating a basic structure of about 200 mannose units. d-Galactose occurred only in non-reducing terminal positions and in the furanose form. In addition, an equal proportion of d-mannopyranose terminal units was present. Approximately equal numbers of terminal units, chain units and branch points were found, the predominant linkages in the chain being 1 → 2 and 1 → 4, in equal proportions. N-Terminal amino acid assay indicated the presence of at least three major peptide chains ending in threonine, glycine and alanine.