Localization of Acetyl Groups in the Macromolecule of Glucomannan Obtained from Roots of Eremurus zangezuricus

Water-soluble glucomannan from roots of Eremurus zangezuricus Mikheev was studied. The polysaccharide contains D-glucose, D-mannose, and acetyl groups in the molecular ratio of 1 : 2.8 : 0.38. ¹³C NMR studies showed that the polysaccharide under study is a linear, partly acetylated 1,4--D-glucomannan. The acetyl groups are attached to the C2 and C3 of mannopyranose units. The polymer contains, on average, one acetyl group per seven mannose units. The glucomannan of E. zangezuricus has the following parameters: []_D = –37.5°, [] = 3.73 dl/g, and Mw = 151 kDa.     

Structure and characteristics of glucomannans from Eremurus iae and E.zangezuricus: detection of acetyl group localization in macromolecules]

Water-soluble glucomannans from roots of Eremurus iae and E. zangezuricus were studied. These polysaccharides were shown to contain 28.8; 69.0, and 2.2% (E. iae) and 22.6; 74.8, and 2.6% (E. zangezuricus) of D-glucose, D-mannose and acetyl groups, respectively. Their IR spectra were identical and revealed the presence of 1,4-beta-glycosidic bonds and ester carbonyl groups. 13C-NMR spectroscopy revealed both polysaccharides to be linear partially acetylated 1,4-beta-D-glucomannans. Acetyl groups substituted C-2- and C-3-hydroxyls of mannopyranose residues. Comparison of 13C-NMR data and the results of correlation analysis enables a conclusion to be made that acetyl groups can substitute no more than one OH-group in the mannopyranosyl residue. [alpha]D = -34.0 degrees, [eta] and molecular weights (MW) for E. iae polysaccharide were determined to be -34.0, 6.5 dl/g, and 265.5 kDa, respectively, and for E. zangezuricus polysaccharide -38.2, 5.4 dl/g, and 233.5 kDa, respectively. A correlation between intrinsic viscosities of polysaccharides and their molecular masses determined by HPLC was revealed.     

Cell-free biosynthesis of the O-acetylated N-acetylneuraminic acid capsular polysaccharide of group C meningococci.

A cell-free system was established to study the biosynthesis of group C meningococcal capsular polysaccharide, an alpha-2 leads to 9-linked N-acetylneuraminic acid (NeuAc) homopolymer containing O-acetyl groups at either C7 or C8. Sialyltransferase activity, isolated from group C meningococcus strain C-11, catalyzed incorporation of [14C]NeuAc from CMP (CMP--[14C]NeuAc) into polymeric form. This sialyltransferase was stimulated by addition of meningococcus group C and Escherichia coli K92 capsular polysaccharides, the latter being an alpha-2 leads to 8- and alpha-2 leads to 9-linked NeuAc heteropolymer. Group C meningococcal sialyltransferase did not require divalent ions but was stimulated by Mn2+. Attempts to demonstrate a lipid-soluble intermediate in the biosynthesis of this NeuAc polymer were unsuccessful. Meningococcal group C sialyltransferase incorporated NeuAc into a membrane-associated product. The polysaccharide can be extracted from the membrane-bound fraction with Triton X-100. The newly synthesized polysaccharide coprecipitates with authentic group C antigen in meningococcal group C antiserum and is degraded by sodium metaperiodate, indicating that the NeuAc polymer synthesized by the cell-free system consists of alpha-2 leads to 9 linkage. Meningococcal group C spheroplast membranes contain an O-acetylase that can catalyze the transfer of acetyl groups from acetyl coenzyme A to the in vitro-synthesized polysaccharide.     

Structural determination and biosynthetic studies of the O-antigenic polysaccharide from the enterohemorrhagic Escherichia coli O91 using 13C-enrichment and NMR spectroscopy.

The structure of the O-antigenic polysaccharide from the enterohemorrhagic Escherichia coli O91 has been determined using primarily NMR spectroscopy on the (13)C-enriched polysaccharide. The O-antigen is composed of pentasaccharide repeating units with the following structure: -->4)-beta-D-Galp-(1-->4)-beta-D-GlcpNAc-(1-->4)-beta-D-GlcpA-6-N- Gly -(1-->3)-beta-D-GlcpNAc-(1-->4)-alpha-D-Quip-3-N-[(R)-3-hydroxy butyra mido]-(1-->. The bacterium was grown with D-[UL-(13)C]glucose in the medium which resulted in an overall degree of labeling of approximately 65% in the sugar residues and approximately 50% in the N-acyl substituents, indicating some metabolic dilution in the latter. The (13)C-enrichment of the polysaccharide proved valuable since NMR assignments could be made on the basis of (13)C, (13)C-connectivity in uniformly labeled residues. The biosynthesis of the (R)-3-hydroxybutyramido substituent via C(2) fragments was identified by NMR spectroscopy. The (R)-configuration at C3 is in accord with fatty acid biosynthesis. Additional cultures with specifically labeled D-[1-(13)C]glucose or D-[6-(13)C]glucose corroborated the direct incorporation of glucose as the building block for the hexose skeletons in the polysaccharide and the biosynthesis of acyl substituents occurring via the triose pool followed by decarboxylation to give acetyl building blocks labeled with (13)C at the methyl group.     

Acetylated methylmannose polysaccharide of Streptomyces.

A polysaccharide composed of 3-O-methyl-D-mannose and D-mannose in a molar ratio of approximately 10:1 and containing 3 to 4 esterified acetyl residues has been isolated from Streptomyces griseus. This acetylated methylmannose polysaccharide (AMMP) is similar to the methylmannose polysaccharide (MMP) of Mycobacterium smegmatis (Gray, G. R., and Ballou, C. E. (1971) J. Biol. Chem. 246, 6835-6842) in its size and composition, the absence of acidic or basic groups, and the lack of a reducing end. It is different, however, in its content of esterified acetyl residues, and it is slightly different in its structure and in its gel filtration properties. The structure of AMMP has been established by proton magnetic resonance spectroscopy, and by combinations of methylation analysis and Smith degradation utilizing non-radioactively labeled polysaccharide and [3H]methyl-labeled polysaccharide obtained from cells grown in the presence of L-[methyl-3H]methionine. It is concluded that AMMP is a linear, nonreducing, neutral polysaccharide composed of a terminal D-mannose residue linked alpha(1 leads to 4) to a chain of 10 consecutive alpha(1 leads to 4)-linked 3-O-methyl-D-mannose residues. The reducing terminal 3-O-methyl-D-mannose residue exists, at least in part, as its alpha-methyl glycoside. The positions of attachment of the ester residues have not been established.     

Studies in vitro on the uptake and degradation of sodium hyaluronate in rat liver endothelial cells.

Rat liver endothelial cells in primary cultures at 7 degrees C bind radioactively labelled sodium hyaluronate (HA; Mr 400 000) specifically and with high affinity (Kd = 6 X 10(-11) M). Maximal binding capacity is approx. 10(4) molecules per cell. Inhibition experiments with unlabelled HA and oligosaccharides from HA indicate that each molecule is bound by several receptors acting co-operatively and that the single receptor recognizes a tetra- or hexa-saccharide sequence of the polysaccharide. At 37 degrees C the liver endothelial cells endocytose the HA. The process combines the features of a receptor-mediated and a fluid-phase endocytosis. The rate of internalization does not show any saturation with increasing HA concentration, but is approximately proportional to the polysaccharide concentration at and above the physiological concentration. At 50 micrograms of free HA/l each liver endothelial cell accumulates 0.1 fg of the polysaccharide/min. Fluorescent HA accumulates in perinuclear granules, presumably lysosomes. Degradation products from HA appear in the medium about 30 min after addition of the polysaccharide to the cultures. The radioactivity from HA containing N-[3H]acetyl groups or 14C in the sugar rings is recovered mainly as [3H]acetate and [14C]acetate respectively. Estimations of the capacity of liver endothelial cells to internalize and degrade HA in vitro indicate that these cells may be primarily responsible for the clearance of HA from human blood in vivo.     

Structural studies of the O-antigenic polysaccharides from the enteroaggregative Escherichia coli strain 522/C1 and the international type strain from Escherichia coli O 178

The structure of the O-antigenic polysaccharide (PS) from the enteroaggregative Escherichia coli strain 522/C1 has been determined. Component analysis and (1)H and (13)C NMR spectroscopy techniques were used to elucidate the structure. Inter-residue correlations were determined by (1)H,(1)H-NOESY and (1)H,(13)C-heteronuclear multiple-bond correlation experiments. The PS is composed of pentasaccharide repeating units with the following structure: [ structure: see text]. Analysis of NMR data reveals that on average the PS consists of four repeating units and indicates that the biological repeating unit contains an N-acetylgalactosamine residue at its reducing end. Serotyping of the E. coli strain 522/C1 showed it to be E. coli O 178:H7. Determination of the structure of the O-antigen PS of the international type strain from E. coli O 178:H7 showed that the two polysaccharides have identical repeating units. In addition, this pentasaccharide repeating unit is identical to that of the capsular polysaccharide from E. coli O9:K 38, which also contains O-acetyl groups.     

Structure of the exopolysaccharide produced by Streptococcus thermophilus S3

The exopolysaccharide of Streptococcus thermophilus S3, produced in skimmed milk, is composed of D-galactose and L-rhamnose in a molar ratio of 2:1. The polysaccharide contains 0.4 equiv of O-acetyl groups per repeating unit. Linkage analysis and 1D/2D NMR (1H and 13C) studies on native and O-deacetylated EPS together with nanoES-CID tandem mass spectrometry studies on oligosaccharides generated by a periodate oxidation protocol, show the polysaccharide to have the following structure: [structure: see text].     

Structure of the K95 antigen from Escherichia coli O75:K95:H5, a capsular polysaccharide containing furanosidic KDO-residues

The structure of the K95 antigenic capsular polysaccharide (K95 antigen) of Escherichia coli O75:K95:H5 was elucidated by determination of the composition, 1H- and 13C-n.m.r. spectroscopy, periodate oxidation, and methylation analysis. The K95 polysaccharide, which contains furanosidic 3-deoxy-D-manno-2-octulosonic acid (KDOf) residues, consists of----3)-beta-D-Rib-(1----8)-KDOf-(2----repeating units, has a molecular weight of approximately 25,000 (approximately 65 repeating units), and is randomly O-acetylated (1 acetyl group per repeating unit at unknown positions).     

Characterization of the lipopolysaccharide O antigens of Actinobacillus pleuropneumoniae serotypes 9 and 11: antigenic relationships among serotypes 9, 11, and 1.

The antigenic lipopolysaccharide O polysaccharides of capsular serotypes 9 and 11 were examined by chemical, immunological, and nuclear magnetic resonance methods. Immunodiffusion tests carried out on these O antigens indicated that both contained common epitopes which were also shared by Actinobacillus pleuropneumoniae serotype 1. Chemical analysis and high-field nuclear magnetic resonance spectroscopy showed that the O antigens of serotypes 9 and 11 were high-molecular-weight polymers consisting of a backbone of repeating trisaccharide units composed of alpha-L-rhamnopyranosyl and alpha-D-glucopyranosyl residues (2:1). One of the alpha-L-rhamnose units forms a branch point and is stoichiometrically substituted with terminal 2-acetamido-2-deoxy-beta-D-glucose residues in the serotype 11 O polysaccharide, but only to the extent of 25% in the serotype 9 O polysaccharide. Thus, the serotype 9 O polysaccharide contains two different repeating units: a tetrasaccharide unit with the same structure as that of the serotype 11 O polysaccharide and a trisaccharide unit: [formula: see text] where R = beta-D-GlcpNAc for serotype 1 and 11 O polysaccharides, and R = H (75%) and R = beta-D-GlcpNAc (25%) for serotype 9. The structure of the previously determined serotype 1 O polysaccharide (E. Altman, J.-R. Brisson, and M. B. Perry, Biochem. Cell. Biol. 64:17-25, 1986) is identical to that of the serotype 11 O polysaccharide. We propose a more complete serotyping scheme for A. pleuropneumoniae which includes designation of both the capsular (K) and O antigens.     

Somatic antigens of Pseudomonas aeruginosa. The structure of O-specific polysaccharide chains of the lipopolysaccharides from P. aeruginosa O5 (Lányi) and immunotype 6 (Fisher)

Lipopolysaccharides were isolated from dry bacterial cells of Pseudomonas aeruginosa O5a,b,c, O5a,b,d, O5a,d (Lányi classification) and immunotype 6 (Fisher classification) by the Westphal procedure. Their polysaccharide chains were built up of trisaccharide repeating units containing D-xylose, 2-acetamido-2,6-dideoxy-D-galactose and a new sialic acid-like sugar, the di-N-acyl derivative of 5,7-diamino-3,5,7,9-tetradeoxy-L-glycero-L-manno-nonulosonic (pseudaminic) acid. Formyl, acetyl and (R)-3-hydroxybutyryl groups were identified as the N-acyl substituents of the last monosaccharide; O5a,b,c and O5a,b,d lipopolysaccharides also contained O-acetyl groups. The glycosidic linkage of pseudaminic acid was extremely labile towards acids, and mild acid degradation of the lipopolysaccharides produced, instead of the O-specific polysaccharides, their trisaccharide fragments with pseudaminic acid at the reducing terminus. Similar degradation of immunotype 6 lipopolysaccharides, followed by oxidation with sodium metaperiodate, resulted in a disaccharide fragment due to destruction of xylose. In contrast the glycosidic linkage of pseudaminic acid proved to be more stable towards treatment with hydrogen fluoride than those of xylose and N-acetylfucosamine. As a result, solvolysis of immunotype 6 lipopolysaccharide with hydrogen fluoride in methanol gave methyl glycosides of a disaccharide and a trisaccharide with pseudaminic acid at the non-reducing terminus. Mild acid hydrolysis of these oligosides afforded free 5-N-acetyl-7-N-formylpseudaminic acid, which was identified by the 1H ande 13C nuclear magnetic resonance data, as well as by the mass spectrum of the corresponding fully methylated aldonic acid. As a result of the identification of all oligosaccharides obtained and comparative analysis of the 13C nuclear magnetic resonance spectra of the oligosaccharides and lipopolysaccharides the following structures were established for the repeating units of the polysaccharide chains of the lipopolysaccharides: (Formula: see text) where D-Xyl = D-xylose, D-FucNAc = 2-acetamido-2,6-dideoxy-D-galactose, Pse5N7NFm = 5-amino-3,5,7,9-tetradeoxy-7-formamido-L-glycero-L-manno-nonulosonic+ ++ acid (7-N-formylpseudaminic acid). All the polysaccharides have an identical carbohydrate skeleton and differ from each other by the acyl substituent at N-5 of pseudaminic acid [acetyl or (R)-3-hydroxybutyryl group] or by the presence or absence of the O-acetyl group at position 4 of N-acetylfucosamine. The data obtained account properly for the O specificity of the studied P. aeruginosa strains.     

Utilization of Citrate, Acetylcarnitine, Acetate, Pyruvate and Glucose for the Synthesis of Acetylcholine in Rat Brain Slices

Slices of rat caudate nuclei were incubated in saline media containing choline, paraoxon, unlabelled glucose, and [1,5-14C] citrate, [1-14C-acetyl]carnitine, [1-14C]acetate, [2-14C]pyruvate, or [U-14C]glucose. The synthesis of acetyl-labelled acetylcholine (ACh) was compared with the total synthesis of ACh. When related to the utilization of unlabelled glucose (responsible for the formation of unlabelled ACh), the utilization of labelled substrates for the synthesis of the acetyl moiety of ACh was found to decrease in the following order: [2-14C]pyruvate greater than [U-14C]glucose greater than [1-14C-acetyl]carnitine greater than [1,5-14C]citrate greater than [1-14C]acetate. The utilization of [1,5-14C]citrate and [1-14C]acetate for the synthesis of [14C]ACh was low, although it was apparent from the formation of 14CO2 and 14C-labelled lipid that the substrates entered the cells and were metabolized. The utilization of [1,5-14C]citrate for the synthesis of [14C]ACh was higher when the incubation was performed in a medium without calcium (with EGTA); that of glucose did not change, whereas the utilization of other substrates for the synthesis of ACh decreased. The results indicate that earlier (indirect) evidence led to an underestimation of acetylcarnitine as a potential source of acetyl groups for the synthesis of ACh in mammalian brian; they do not support (but do not disprove) the view that citrate is the main carrier of acetyl groups from the intramitochondrial acetyl-CoA to the extramitochondrial space in cerebral cholinergic neurons.     

Rate studies of polysaccharide biosynthesis from guanosine diphosphate α-d-glucose and guanosine diphosphate α-d-mannose

With enzyme preparations from Phaseolus aureus seedlings, the initial rate of (14)C-labelled polysaccharide formation from GDP-alpha-d-[(14)C]glucose is not increased by additions of GDP-alpha-d-mannose. However, final incorporation is increased by addition of GDP-alpha-d-mannose, since the total reaction-time is extended. In contrast, the initial rate of (14)C-labelled polysaccharide formation from GDP-alpha-d-[(14)C]mannose is increased by all concentrations of GDP-alpha-d-glucose that are less than that of the GDP-alpha-d-[(14)C]mannose. Maximum stimulation of the initial rate occurs at a GDP-alpha-d-[(14)C]mannose/GDP-alpha-d-glucose concentration ratio of about 4:1. However, eventual incorporation from GDP-alpha-d-[(14)C]mannose is decreased by the addition of GDP-alpha-d-glucose, since the reaction rate falls off sharply after about 2min. Reciprocal plots of (14)C-labelled polysaccharide formation from GDP-alpha-d-[(14)C]mannose result in biphasic graphs. The two straight-line portions of the plot are joined by a curved line in the concentration range between 2-3 and 50mum. Extrapolated K(m) values for the two linear components are 0.4-1.0 and 700-1500mum. The effect of GDP-alpha-d-glucose on the kinetics of (14)C-labelled polysaccharide formation from GDP-alpha-d-[(14)C]mannose is complex, and depends on relative concentrations of the two sugar nucleotides. (14)C-labelled polysaccharide formation from GDP-alpha-d-[(14)C]glucose also results in biphasic reciprocal plots. One component appears to have K(m) about 2-3mum, the other about 200-400mum. In this reaction, GDP-alpha-d-mannose appears to be a competitive inhibitor with K(i) 20-30mum. With particulate preparations of P. aureus, GDP-alpha-d-[(14)C]glucose appears to be a precursor for the synthesis of one polysaccharide, a glucomannan, the mannose moieties of which are derived from an intermediate existing in the particulate preparation. From the rate results, GDP-alpha-d-[(14)C]mannose appears to be a precursor for at least two polysaccharides, one of which is a glucomannan.     

Structural studies of the polysaccharide from Aloe plicatilis Miller

The interior part of the leaves of the succulent Aloe plicatilis Miller (Liliaceae) consists of a transparent jelly containing mainly an acetylated glucomannan. Structural studies show that glucose and mannose, which are present in the ratio 1:2.8, are (1 → 4)-linked and that there is no branching. The hexose residues are randomly and variously substituted at positions 2,3,6, 2,3, 2, and 3 with acetyl groups; a small proportion of the sugar units is unsubstituted.     

Structural studies of the extracellular polysaccharide produced by Butyrivibrio fibrisolvens strain H10b

The extracellular polysaccharide produced by Butyrivibrio fibrisolvens strain H10b, when grown under strictly anaerobic conditions with glucose as carbohydrate source, has been studied by chemical and spectroscopic techniques. The results demonstrate that the polysaccharide consists of hexasaccharide repeating units with the following structure: [structure: see text] The isolated polysaccharide was found to be approximately 65% acetylated at O-2 of the 3-O-[(S)-1-carboxyethyl]-beta-D-Glcp residue. The absolute configuration of the 1-carboxyethyl groups was determined by circular dichroism.     

O-acylation of hydroxyproline residues: effect on peptide-bond isomerization and collagen stability

In collagen, strands of the sequence XaaYaaGly form a triple-helical structure. The Yaa residue is often (2S,4R)-4-hydroxyproline (Hyp). The inductive effect of the hydroxyl group of Hyp residues greatly increases collagen stability. Here, electron withdrawal by the hydroxyl group in Hyp and its 4S diastereomer (hyp) is increased by the addition of an acetyl group or trifluoroacetyl group. The crystalline structures of AcHyp[C(O)CH3]OMe and Achyp[C(O)CH3]OMe are similar to those of AcHypOMe and AcProOMe, respectively. The O-acylation of AcHypOMe and AchypOMe increases the 13C chemical shift of its Cgamma atom: AcHyp[C(O)CF3]OMe congruent with Achyp[C(O)CF3]OMe > AcHyp[C(O)CH3]OMe congruent with Achyp[C(O)CH3]OMe > or = AcHypOMe congruent with AchypOMe. This increased inductive effect is not apparent in the thermodynamics or kinetics of amide bond isomerization. Despite apparently unfavorable steric interactions, (ProHypGly)(10), which is O-acylated with 10 acetyl groups, forms a triple helix that has intermediate stability: (ProHypGly)(10) > {ProHyp[C(O)CH3]Gly}(10) > (ProProGly)(10). Thus, the benefit to collagen stability endowed by the hydroxyl group of Hyp residues is largely retained by an acetoxyl group.     

N-[1-C]acetylimidazole as a reagent for tyrosyl modification in protein NMR studies: Acetylation of cytochrome c

The reaction of N-[1-¹³C] acetylimidazole with cytochrome c and guanidinated cytochrome c was evaluated as a means of introducing NMR-detectable groups as conformation-dependent probes. Resonances from both N-[1-¹³C]acetyl lysyl and O-[1-¹³C]acetyl tyrosyl groups were observed when ferricytochrome c was acetylated. However, only O-[1-¹³C]acetyl tyrosyl resonances were seen with acetylated guanidinated ferricytochrome c. Chemical shifts of the four O-[1-¹³C]acetyl tyrosyl groups were conformation dependent and ranged from 172 to 176 ppm. A convenient method for the preparation of N-[1-¹³C]acetylimidazole is described.     

N-[1-13C]acetylimidazole as a reagent for tyrosyl modification in protein NMR studies: acetylation of cytochrome c

The reaction of N-[1-¹³C] acetylimidazole with cytochrome c and guanidinated cytochrome c was evaluated as a means of introducing NMR-detectable groups as conformation-dependent probes. Resonances from both N-[1-¹³C]acetyl lysyl and O-[1-¹³C]acetyl tyrosyl groups were observed when ferricytochrome c was acetylated. However, only O-[1-¹³C]acetyl tyrosyl resonances were seen with acetylated guanidinated ferricytochrome c. Chemical shifts of the four O-[1-¹³C]acetyl tyrosyl groups were conformation dependent and ranged from 172 to 176 ppm. A convenient method for the preparation of N-[1-¹³C]acetylimidazole is described.     

Antigenic polysaccharides of bacteria. 18. Structure of O-specific polysaccharide chains of Pseudomonas aeruginosa 05 (Lányi) lipopolysaccharide

Polysaccharide chains of P. aeruginosa O5a, b, c, O5a, b, d and O5a, d (Lányi classification) lipopolysaccharides contain D-xylose, N-acetyl-D-fucosamine (FucNAc) and a derivative of 5,7-diamino-3,5,7,9-tetradeoxy-L-glycero-L-manno-nonulosonic acid (pseudaminic acid, PseN2) carrying acetyl or (R)-3-hydroxybutyryl (Hb) and formyl (Fm) groups as N-acyl substituents. Degradation of the lipopolysaccharides with dilute acetic acid caused depolymerisation of the polysaccharide chains as a result of cleavage of glycosidic linkage of pseudaminic acid to give trisaccharides representing chemical repeating units of the polysaccharides. Basing on analysis of the trisaccharides using 1H and 13C NMR spectroscopy and mass-spectrometry, the following structures of the polysaccharide chains were established: (Formula: see text). O5a, d polysaccharide is identical to P. aeruginosa immunotype 6 O-specific polysaccharide.     

Characterization of water-soluble hemicelluloses from spruce and aspen employing SEC/MALDI mass spectroscopy

Partly depolymerized hemicelluloses isolated from wood chips of spruce and aspen employing microwave treatment were resolved using size-exclusion chromatography (SEC) into oligo- and polysaccharide fractions containing components with a narrow range of sizes, as determined by MALDI mass spectroscopy. The degree of substitution with acetyl moieties (DS) was also calculated on the basis of the MALDI-MS spectra obtained prior to and following deacetylation. For spruce hemicelluloses, the low molecular mass fraction contained small arabino-4-O-methylglucuronoxylan oligosaccharides, with DP values ranging from 4 to approximately 20, separated primarily on the basis of their charge density. The fraction eluted last consisted of an O-acetyl-(galacto)glucomannan polysaccharide of peak-average DP value (DP(p)) 14. The degree of substitution with acetyl groups (DS) decreased with decreasing DP, a value DS of 0.39 being obtained for the fraction with DP(p) 12. For the aspen hemicelluloses, the SEC fractions eluted first contained an acidic O-acetyl-4-O-methylglucuronoxylan polysaccharide with DP ranging from 10 to approximately 28 and an average DS of approximately 0.75. The fractions eluted last consisted of oligosaccharide mixtures composed primarily of small neutral O-acetyl-xylooligosaccharides (DP(p) 6, DS 0.41), together with minor quantities of an O-acetyl-glucomannan.