Gas chromatographic assay of iduronic and glucuronic acids as aldonic acid butaneboronates

A gas chromatographic procedure has been developed for the analysis of uronic acids as aldonic acid butaneboronates. With these derivatives, aldoses frequently accompanying uronic acids in polysaccharide hydrolyzates are readily separated and measured. The method has been applied to the assay of iduronic and glucuronic acid released by enzymes associated with various mucopolysaccharidoses.     

Differential gas-liquid chromatography method for determination of uronic acids in carbohydrate mixtures

An integrated gas-liquid chromatography method is described for the quantitation of mixtures containing simple monosaccharides in addition to mannuronic, glucuronic, and/or galacturonic acids. A hydrolyzed sample is divided into two portions. One portion is analyzed by the standard aldononitrile method. Glucuronic, galacturonic, and mannuronic acids are converted into compounds that do not chromatograph in the region of the standard aldononitrile acetates. Thus, this analysis gives an accurate estimation of the neutral monosaccharide content. The second portion is analyzed by a modified alditol acetate procedure. The reduction step is repeated three times to convert mannuronic, galacturonic, and glucuronic acids to their corresponding alditols via their intermediate lactones. The results of this gas-liquid chromatography analysis reflect the sum of the monosaccharides present plus their corresponding uronic acids. The difference between the values obtained by the aldononitrile acetate method and the modified alditol acetate method, therefore, is a measure of the uronic acid(s) present.     

Automated analysis of alditols by anion-exchange chromatography with photometric and fluorimetric postcolumn derivatization

Eight alditols were separated in ca. 80 min as their borate complexes by stepwise elution with three borate buffers on a column packed with Hitachi 2633 resin. The alditols in the eluate were derivatized automatically to colored, fluorescent products by applying sequential reactions of periodate oxidation and Hantzsch condensation, and the products were detected either photometrically or fluorimetrically. This automated method allowed simultaneous determination of 20–500 and 20–200 nmol amounts of alditols by photometric and fluorimetric monitorings, respectively. The lower limits of detection were ca. 2 and 0.5 nmol, respectively. The interference by aldoses was slight. Aldoses may be also determined as alditols by direct injection of aqueous solutions to which excess amounts of sodium borohydride have been added. This method was applied with success to urinary alditol assay and to molecular weight determination by end group analysis.     

The specific nature of plant cell wall polysaccharides

Polysaccharide compositions of cell walls were assessed by quantitative analyses of the component sugars. Cell walls were hydrolyzed in 2 n trifluoroacetic acid and the liberated sugars reduced to their respective alditols. The alditols were acetylated and the resulting alditol acetates separated by gas chromatography. Quantitative assay of the alditol acetates was accomplished by electronically integrating the detector output of the gas chromatograph. Myo-inositol, introduced into the sample prior to hydrolysis, served as an internal standard.     

Studies on a microchemical method for the determination of the degree of polymerization of neutral oligo- and polysaccharides. I. Quantitative separation of trace amounts of alditols from mixtures with a large excess of monosaccharides.

A method has been devised for the quantitative separation of trace amounts of alditols from mixtures with large amounts of monosaccharides, using a strongly basic ion-exchange resin. Ten kinds of common reducing monosaccharides used were strongly retained by a very basic anion-exchange resin in the hydroxyl form, whereas the corresponding alditols showed no significant affinity for the basic resin. Model studies showed excellent recoveries of alditol from known mixtures of alditol and the corresponding aldose at ratios in the range from 1 : 1X10(3) TO 1 : 1X10(4) (by weight). Application of this procedure to dextrans after reduction and hydrolysis resulted in quantitative separation of the terminal alditol.     

Determining the polysaccharide composition of plant cell walls

The plant cell wall is a chemically complex structure composed mostly of polysaccharides. Detailed analyses of these cell wall polysaccharides are essential for our understanding of plant development and for our use of plant biomass (largely wall material) in the food, agriculture, fabric, timber, biofuel and biocomposite industries. We present analytical techniques not only to define the fine chemical structures of individual cell wall polysaccharides but also to estimate the overall polysaccharide composition of cell wall preparations. The procedure covers the preparation of cell walls, together with gas chromatography-mass spectrometry (GC-MS)-based methods, for both the analysis of monosaccharides as their volatile alditol acetate derivatives and for methylation analysis to determine linkage positions between monosaccharide residues as their volatile partially methylated alditol acetate derivatives. Analysis time will vary depending on both the method used and the tissue type, and ranges from 2 d for a simple neutral sugar composition to 2 weeks for a carboxyl reduction/methylation linkage analysis.     

A simple and rapid preparation of alditol acetates for monosaccharide analysis

A simple and rapid method is described for the preparation of alditol acetates from monosaccharides. It can be performed in a single tube without transfers or evaporations. Monosaccharides are reduced with sodium borohydride in dimethyl sulphoxide and the resulting alditols acetylated using 1-methylimidazole as the catalyst. Removal of borate is unnecessary and acetylation is complete in 10 min at room temperature. Monosaccharides are quantitatively reduced and acetylated by this procedure. The alditol acetates are completely separated by glass-capillary, gas-liquid chromatography on Silar 10C. The method has been applied to the analysis of monosaccharides in acid hydrolysates of a plant cell-wall.     

Antigenic polysaccharides of bacteria of the genus Shigella. The structure of the polysaccharide chain of Shigella boydii type 14

A specific acidic polysaccharide has been isolated from the Shigella boydii type 14 antigenic lipopolysaccharide after mild hydrolysis followed by chromatography on Sephadex G-50. The polysaccharide consists of the D-glucuronic acid, 2-acetamido-2-deoxy-D-glucose and D-galactose residues in the ratio 1:1:3. From the results of methylation analysis and partial acid hydrolysis, the structure of the repeating unit of the specific polysaccharide was deduced as follows: (-6DGalp alpha 1-4DGlcAp beta 1-6DGalp beta 1-4DGalp beta 1-4DGlcNAcp beta 1-)n. The 13C NMR spectra of native and carboxyl-reduced polysaccharides, as well as of oligosaccharides produced by partial acid hydrolysis fully confirmed the proposed structure. The approach was suggested to determine the type of substitution of uronic acid moieties in polysaccharide chain by use of chromato-mass-spectrometry of acetylated methyl esters of partially methylated aldonic acids. Serological characteristics of Sh. boydii LPS type 14 and its modified derivatives are discussed.     

Automated hypoiodite oxidation of carbohydrates

An automated system is described for the hypoiodite oxidation of aldoses and substituted aldoses to the corresponding aldonic acids. Automated determination of the glyoxylic acid and formaldehyde obtained on oxidation with periodate enables the 3-O-, 4-O-, and 6-O-substituted aldonic acids to be distinguished. The method is applied to the analysis of oligosaccharides in column eluates.     

myo-Inositol Synthesis from [1-H]Glucose in Phaseolus vulgaris L. during Early Stages of Germination

Radiolabeled d-[1-³H]glucose was fed by imbibition under sterile conditions to bean (Phaseolus vulgaris L.) seeds. After 72 and 96 hours of feeding, the ³H was located in uronic acid and pentose residues as well as hexose residues of cell wall polysaccharides in growing hypocotyl and root. Free myo-inositol present in cotyledons, hypocotyl, and root also contained ³H, showing that de novo synthesis of myo-inositol from [1-³H]glucose did occur during the first 72 hours of germination. More than 90% of the labeled, free myo-inositol was present in the cotyledons. The ³H percentage in trifluoroacetic acid-soluble arabinose residues of cell wall polysaccharides from 72-hour-old bean hypocotyls was only half of their mole percentage. On the other hand, ³H percentages in hexose residues were higher than their mole percentages. The results suggest that myo-inositol is synthesized from reserve sugars during the very early stages of germination, and that the newly synthesized myo-inositol, as well as that stored in cotyledons, can be used for the construction of new hypocotyl and root cell wall polysaccharides after conversion into uronic acids and pentoses via the myo-inositol oxidation pathway.     

Chemical ionization mass spectrometry of trimethylsilylated carbohydrates and organic acids retained in uremic serum

After appropriate sample pretreatment and derivatization, uremic serum was investigated by combined high resolution gas chromatography and mass spectrometry, using both electron impact and chemical ionization methods. Electron impact and chemical ionization spectra of a number of identified (trimethylsilylated) carbohydrates and organic acids are compared. The utilization of chemical ionization mass spectrometry, with isobutane as the reagent gas, is discussed in detail. The influence of the reagent gas pressure on the total ion current and on the spectral appearance was studied. The identification of compounds, based on electron impact mass spectral data, was confirmed and often aided appreciably by using this technique. The chemical ionization spectra of trimethylsilyated alditols and aldonic acids, as well as of other organic acids showed protonated molecular ions, whereas aldoses did not. Differences with electron impact spectra are found mainly in the high mass region. The loss of one or more trimethylsilanol groups becomes the predominating fragmentation route at higher reagent gas pressures.     

Soluble Cell Wall Polysaccharides Released from Pea Stems by Centrifugation : II. EFFECT OF ETHYLENE

The effect of ethylene on cell wall metabolism in sections excised from etiolated pea stems was studied. Ethylene causes an inhibition of elongation and a pronounced radial expansion of pea internodes as shown by an increase in the fresh weight of excised, 1-cm sections. Cell wall metabolism was studied using centrifugation to remove the cell wall solution from sections. The principal neutral sugars in the cell wall solution extracted with H₂O are arabinose, xylose, galactose, and glucose. Both xylose and glucose decline relative to controls in air within 1 hour of exposure to ethylene. Arabinose and galactose levels are not altered by ethylene until 8 hours of treatment, whereupon they decline in controls in air relative to ethylene treatment. When alcohol-insoluble polymers are fractionated into neutral and acidic polysaccharides, xylose and glucose predominate in the neutral fraction and arabinose and galactose in the acidic fraction. Ethylene depresses the levels of xylose and glucose in the neutral fraction and elevates arabinose and galactose in the acidic fraction. Ethylene treatment does not affect the level of uronic acids extracted with H₂O; however, the level of hydroxyproline-rich proteins in this water-extracted cell wall solution is increased by ethylene. Extraction of sections with CaCl₂ results in an increase in the levels of neutral sugars particularly arabinose. Ethylene depresses the yield of arabinose in calcium-extracted solution relative to controls in air. Similarly, extraction with CaCl₂ increases the yield of extracted hydroxyproline in ethanol-insoluble polymers and ethylene depresses its level relative to controls. Metabolism of uronic acids and neutral sugars and growth in response to ethylene treatment contrast markedly with auxin-induced polysaccharide metabolism and growth. With auxin, sections increase mostly in length not radius, and this growth form is associated with an increase in the levels of xylose, glucose, and uronic acids. With ethylene, on the other hand, stem elongation is suppressed and expansion is promoted, and this growth pattern is associated with a decrease in xylose and glucose in the ethanol-insoluble polysaccharides.     

Studies on the blood-anticoagulant activity of sulphated polysaccharides with different uronic acid content

The anticoagulant activities of sulphated alginic acids, amylose, cellulose, chitosan, curdlan, dextran, guaran, laminaran and locust bean gum have been studied. The alginic acids have been partially reduced and some of the neutral polysaccharides have been partially oxidised at C-6 of the glycopyranosyl residues. The activities of sulphated polymers containing different proportions of uronic acid and neutral sugar residues have been compared.The results suggest that polysaccharides with an average of at least one sulphate group on each monomeric unit, a molecular weight higher than 10 000 and a high proportion of sulphated primary hydroxyl functions will display activity in the activated, partial thromboplastin time assay (APTT). Sulphated guaran and locust bean gum had the highest activities of the polymers investigated (70 IU/mg, heparin has 130-50 IU/mg). In the concentration range investigated, none of the sulphated polymers showed any significant activity in an anti-factor X_a assay.     

Auxin-induced Changes in Avena Coleoptile Cell Wall Composition

Sugar and uronic acid residues were derived from wall polysaccharides of oat (Avena sativa, var. Victory) coleoptiles by means of 2 N trifluoroacetic acid, 72% sulfuric acid, or enzymic hydrolysis. The products of hydrolysis were reduced and acetylated to form alditol acetates which were analyzed using gas chromatography. Time-course studies of auxin-promoted changes in various wall fractions indicate that when exogenous glucose was available, increases in certain wall constituents paralleled increases in length. However, under conditions where exogenous glucose was not available, and where wall synthesis was limited, such correlations with growth were not apparent. Under these latter conditions total wall weight initially increased slightly, then decreased. These changes in weight were the net of increases in cellulose and some noncellulosic constituents and a decrease of over 75% in noncellulosic glucose. When coleoptile sections were preincubated without exogenous glucose for 8 hours to deplete endogenous wall precursors and subsequently treated with auxin, there were no detectable increases in wall weight. There was instead an auxin-promoted decrease in wall weight, and this decrease paralleled a decrease in noncellulosic glucose. There were no significant changes in other wall components. The auxin-promoted decreases in noncellulosic glucose are interpreted as a possible step in the mechanism of growth.     

Carbohydrate analysis of water-soluble uronic acid-containing polysaccharides with high-performance anion-exchange chromatography using methanolysis combined with TFA hydrolysis is superior to four other methods.

Sulfuric acid hydrolysis according to the Saeman procedure, TFA hydrolysis, and methanolysis combined with TFA hydrolysis were compared for the hydrolysis of water-soluble uronic acid-containing polysaccharides originating from fungi, plants, and animals. The constituent sugar residues released were subsequently analyzed by either conventional GLC analysis of alditol acetates or high-performance anion-exchange chromatography with pulsed-amperometric detection. It was shown that TFA hydrolysis alone is not sufficient for complete hydrolysis. Sulfuric acid hydrolysis of these polysaccharides resulted in low recoveries of 6-deoxy-sugar residues. Best results were obtained by methanolysis combined with TFA hydrolysis. Methanolysis with 2 M HCl prior to TFA hydrolysis resulted in complete liberation of monosaccharides from pectic material and from most fungal and animal polysaccharides tested. Any incomplete hydrolysis could be assessed easily by HPAEC, by the detection of characteristic oligomeric products, which is difficult using alternative methods currently in use. Methanolysis followed by TFA hydrolysis of 20 micrograms water-soluble uronic acid containing polysaccharides and subsequent analysis of the liberated sugar residues by HPAEC allowed us to determine the carbohydrate composition of these polysaccharides rapidly and accurately in one assay without the need for derivatization.     

On the carbohydrate—protein linkage group in vitreous humor hyaluronate

Fractional molar ratios of serine, threonine and aspartic acid to neutral sugars in the purified bovine vitreous humor hyaluronate, and a 4–5-fold increase in the percentage of these amino acids and the absence of sugar alditols in hyaluronate reduced with NaBH₄---PdCl₂ after alkali treatment indicated the absence of a carbohydrate—protein linkage. Gel filtration behavior, a decrease in intrinsic viscosity of reduced hyaluronate to about one-half and a significant decrease in its specific rotation suggested that the two antiparallel chains of the hyaluronate double helix may come apart upo reduction. The vitreous humor hyaluronate contained 109.2 ppm of “bound” silicon. It is suggested that the bound silicon may bridge the two antiparallel chains through the neutral sugars and/or through the hydroxyl group of the uronic acid moiety.     

Human umbilical cord hyaluronate neutral sugar content and carbohydrate-protein linkage studies

Paper chromatography of neural sugars and gas chromatography of their aldononitrile acetates indicated the presence of fucose, arabinose and a small amount of glucose in purified human umbilical cord hyaluronate. The molar ratios of serine, threonine and aspartic acid to neural sugars were not unity, suggesting the non-involvement of the neutral sugars and the amino acids in a carbohydrate-protein linkage. The same was indicated by an increase in the percentage of the aforementioned amino acids and by the absence of sugar alditols in umbilical cord hyaluronate reduced with NaBH₄-PdCl₂, after alkali treatment. This reduction caused a decrease in the intrinsic viscosity and molecular weight to about one-half and an appreciable decrease in the specific rotation of hyaluronate, suggesting a separation of the two antiparallel chains of the double helical hyaluronate. The umbilical cord hyaluronate contained bound silicon and it is possible that this bound silicon may cross-link the two chains at interspersed intervals through the uronic acid moiety and/or through neutral sugars.     

Cell wall carbohydrates in Phycomyces blakesleeanus burgeff

The carbohydrate composition of the cell walls from spores, mycelium and sporangiophores of Phycomyces blakesleeanus was analyzed. Spore wall polysaccharides contained over 50% glucose, about 20% uronic acids, 10% mannose and 10% amino-sugars. During the growth of the hyphae amino-sugars became the main carbohydrate (45%); uronic acids contributed some 25%, glucose and fucose 10% and galactose nearly 6%. Sporangiophores contained almost 90% aminosugars and some 6% uronic acids. Traces of rhamnose were found in all wall preparations. A similar picture emerged from studies on the incorporation of [U-¹⁴C]-glucose into wall materials.Furthermore we looked for a GDP-fucose synthesizing system and found an increasing activity during early germination. This rise in activity was inhibited by cycloheximide but not by 5-fluorouracil.     

A new core tetrasaccharide component from the lipopolysaccharide of Rhizobium trifolii ANU 843

A second core oligosaccharide fragment has been isolated and characterized from the lipopolysaccharide (LPS) of Rhizobium trifolii ANU 843. The oligosaccharide is a tetrasaccharide composed of galactose, galacturonic acid, mannose, and 3-deoxy-D-manno-2-octulosonic acid. The mannose residue is alpha-linked to the 4-position of 3-deoxy-D-manno-2-octulosonic acid and the galacturonic acid residue is alpha-linked to the 6-position of mannose. The galactose residue, which is acetylated at the 4-position, is attached to the 4-position of mannose by an alpha-linkage. All of the aldoses are in the pyranose form. The composition of the tetrasaccharide was determined by gas-liquid chromatography of the alditol acetate derivatives of the component monosaccharides. The configuration of anomeric linkages was determined by 1H NMR spectroscopy. Fast atom bombardment-mass spectrometry (FAB-MS) was performed on acetylated, per(trideutero)acetylated and underivatized tetrasaccharide giving sequence information in addition to information on the residue which was acetylated. Similar studies were performed on the oligosaccharide after reduction with sodium cyanoborohydride and peracetylation with labeled and unlabeled acetic anhydride as before. Further linkage and sequence analysis was obtained from methylation analysis, and from electron impact mass spectrometry of the per(trideutero)acetylated oligosaccharide and from collision-induced dissociation fast atom bombardment tandem mass spectrometry using linked scans at constant B/E on the cyanoborohydride-reduced, per (trideutero)acetylated oligosaccharide. The exact location of the acetyl group was deduced from 1H NMR double resonance experiments in conjunction with mass spectrometric data.     

Conformations of acyclic sugar derivatives : Part II. Determination of the conformations of alditol acetates in solution by the use of 250-MHz n.m.r. spectra

The p.m.r. spectra of all the fully acetylated pentitols and several fully acetylated hexitols have been analysed. Computation by iterative analysis and recourse to 250-MHz spectra were required in several cases. The vicinal coupling constants were used to determine the conformations of these compounds in solution. The planar zigzag conformation was found to be predominant only in those configurations (arabino, manno) which do not possess parallel 1,3-interactions between acetoxyl groups on alternate carbon atoms. The other compounds were found to be mixtures of two or more conformers, none of which has the planar zigzag conformation, except in the case of hexa-O-acetylallitol. The conformations of alditols in the crystalline state and of the alditol acetates in solution are compared.