Structure of tanacetan,a pectic polysaccharide from tansy Tanacetum vulgare L

Tanacetan TVF was found to have a branched structure with a backbone of linear -1,4-D-galacturonan. The ramified regions consist of linear -1,2-L-rhamno--1,4-D-galacturonan as the core. The side chains appear to attach to the 4-position of the L-rhamnopyranose residues. They are present as single -galactopyranose residues or a branching -1,4-galactopyranan bearing 4,6-substituted -D-galactopyranose residues as branched points. In addition, the ramified regions contain side chains of a branched -1,5-arabinofuranan possessing 2,5- and 3,5-substituted -L-arabinofuranose residues as branching points. Some side chains of rhamnogalacturonan appear to be arabinogalactan which contains branched sugar chains of -1,5-arabinofuranan attached to the linear chains of -1,4-galactopyranan by 1,3- and 1,6-linkages. The residues of -L-arabinofuranose seem to occupy the terminal positions of the arabinogalactan side chains.     

Structure of the O-specific polysaccharide of the Yersinia enterocolitica serovar O:4.32 lipopolysaccharide. Serologic relations of lipopolysaccharides of Y. enterocolitica O:4.32 and Y. intermedia O:4.33

O-Specific polysaccharide has been isolated on mild acid hydrolysis of the lipopolysaccharide from Yersinia enterocolitica O: 4.32 (strain 96) and shown to consist of yersiniose B (3,6-dideoxy-4-C-(1-hydroxyethyl)-D-xylo-hexose, YerB) acetylated at C1' and 2-acetamido-2-deoxy-D-galactose residues in a molar ratio 1:2. Acid hydrolysis, methylation and 13C NMR studies indicated the polysaccharide to be composed of trisaccharide repeating units of the following structure: (sequence; see text) The data obtained revealed structural and serological interrelation between O-antigens of Y. enterocolitica O:4.32 and Y. intermedia O:4.33.     

Structural studies of arabinogalactan and pectin from Silene vulgaris (M.) G. callus

Arabinogalactan and pectin (named silenan) were isolated from Silene vulgaris (M.) G. callus. Fractionation by ion-exchange chromatography on DEAE-cellulose and digestion with pectinase demonstrated that silenan from S. vulgaris callus (80% of D-galacturonic acid) and silenan from the aerial part of the campion S. vulgaris are similar: both pectins contain a high quantity of homogalacturonan segments. The NMR spectral data and mass spectrometry of the purified polysaccharide and its fragment obtained by Smith degradation confirmed that the core of the arabinogalactan consisted of the different segments of β-1,3-D-galactopyranan. Some of the β-galactopyranose residues of the backbone are branched at O-6. The side chains of the arabinogalactan were shown to contain residues of terminal and 3-O-substituted β-galactopyranose, terminal α-arabinofuranose and α-rhamnopyranose, and 2-O-substituted α-rhamnopyranose. The α-rhamnopyranose residues in the sugar chain appeared to be 2-O-glycosylated by the β-1,4-D-galactopyranosyl uronic acid residues. Published in Russian in Biokhimiya, 2006, Vol. 71, No. 6, pp. 798–807.     

Forming and immunological properties of some lipopolysaccharide-chitosan complexes

The complex formation of lipopolysaccharide (LPS) with chitosan (Ch) was demonstrated using sedimentation velocity analysis in the analytical ultracentrifuge, centrifugation in glycerol gradient and isopicnic centrifugation in cesium chloride. An addition of Ch to the Escherichia coli and Yersinia pseudotuberculosis LPS solutions was found to result in formation of the stable LPS-Ch complexes. The interaction is a complicated process and depends on time and reaction temperature, as well as on the molecular weight of chitosan. A stable LPS-Ch complex could be formed only after preliminary incubation of the initial components at an elevated temperature (37 degrees C). It should be noted that process of LPS complexation with Ch is accompanied by additional dissociating of LPS. The complex formation was shown to be a result not only of ionic binding, but also of other types of interactions. The interaction of Ch with LPS was shown to modulate significantly the biological activity of LPS. The LPS-Ch complex (1:5 w/w) was shown to possess much lower toxicity in a comparison with the parent LPS at injection to mice in the similar concentration. The LPS-Ch complex was shown to maintain an ability to induce of IL-8 and TNF, but induction of IL-8 and TNF biosynthesis by the LPS-Ch complex was lower than that by the parent LPS. The complex LPS-Ch, similarly to the parent LPS, was found stimulated the formation of the IL-8 in the dose-dependent manner in the human embryonal kidney cells (HEK 293 cells) transfected with TLR4 in combination with MD2.     

Action of β-galactosidase in medium on the Lemna minor (L.) callus polysaccharides

The callus culture of duckweed cultivated on medium containing different concentrations of β-galactosidase was shown to produce the following polysaccharides: pectin lemnan LMC, intracellular AG1, and extracellular AG2 arabinogalactans. The samples of lemnan with 46% galactose residue reduction and 9-46% increased galacturonic acid residue content were obtained at β-galactosidase concentrations of 10⁻³-10⁻¹ mg/mL. The most substantial alterations in the sugar composition of pectin were found to occur in the fraction with a molecular mass of 100-300 kDa. Low concentrations of enzyme failed to influence the sugar composition of intracellular arabinogalactan, whereas high concentrations were shown to decrease the amount of arabinose residues in AG1 and to cause galactan formation. Extracellular galactan was found to be produced on the medium with 10⁻¹ and 1 mg/mL β-galactosidase whereas extracellular arabinogalactan AG2 was shown to be biosynthesized without β-galactosidase or at a β-galactosidase concentration of 10⁻³ mg/mL. Alterations in the sugar composition of polysaccharides were shown to be connected with the increasing activity of α-l-arabinofuranosidase and β-galactosidase, and with the decreasing activity of intracellular polygalacturonase.     

Acetolysis of disaccharide derivatives

The acetolysis of aldobi-itols and aldobionic acids containing α- and β-(1→2), χ-and β-(1→4), and β-(1→6) linkages has been studied. Cleavage of the (1→4)- and (1→6)-linked derivatives occurred more slowly than for the parent disaccharides. The reverse situation was found for (1→2)-linked aldobi-itols and methyl esters of aldobionic acids.     

Inhibition of neutrophil adhesion by pectic galacturonans

The inhibition of the adhesion of neutrophils to fibronectin by the fragments of the main galacturonan chain of the following pectins was demonstrated: comaruman from the marsh cinquefoil Comarum polustre, bergenan from the Siberian tea Bergenia crassifolia, lemnan from the duckweed Lemna minor, zosteran from the seagrass Zostera marina, and citrus pectin. The parent pectins, except for comaruman, did not affect the cell adhesion. Galacturonans prepared from the starting pectins by acidic hydrolysis were shown to reduce the neutrophil adhesion stimulated by phorbol 12-myristate 13-acetate (1.625 microM) and dithiothreitol (0.5 mM) at a concentration of 50-200 microg/ml. The presence of carbohydrate chains with molecular masses higher than 300, from 100 to 300, and from 50 to 100 kDa in the galacturonan fractions was proved by membrane ultrafiltration.     

Phagocytosis-stimulating effect of polysaccharides isolated from ginseng tissue culture

Materials characterizing immunostimulating activity of a polysaccharide fraction isolated from two lines of the ginseng tissue culture are presented. It was shown that under the drug action, the effector functions of polymorphonuclear leukocytes and macrophages activated.     

Isolation and characterization of polysaccharides from Tansy

Using extraction with 0.75% aqueous ammonium oxalate, the following polysaccharide fractions were isolated: tanacetans TVF, TVS, and TVR from floscules, sprouts, and roots, respectively, of Tanacetum vulgare L., spread throughout the European North of Russia. The sugar chain of tanacetan TVF consists of D-galacturonic acid (61.4%), arabinose (14.7%), galactose (10.2%), and rhamnose (3.7%) as the main constituents as well as xylose, glucose, mannose, apiose, and 2-O-methylxylose in trace amounts. Tanacetans TVS and TVR were shown to differ in the sugar quantitative composition. They contain 67 and 28% galacturonic acid, respectively. A partial acid hydrolysis of the tanacetan TVF gave a polysaccharide fragment TVF1, alpha-1,4-D-galacturonan (GalA 98.2%). Digestion with pectinase (alpha-1,4-D-polygalacturonase) resulted in fragment TVF3, containing residues of arabinose (27.1%) and galactose (17.3%). NMR spectroscopy allowed detection of the terminal residues of alpha-Araf and beta-Galp as well as of the residues of alpha-Araf substituted in 3,5- and 5-positions. Thus, tanacetan TVF was proved to be a pectic polysaccharide.     

Structural studies of the pectic polysaccharide from duckweed Lemna minor L

The pectic polysaccharide of duckweed Lemna minor L. termed lemnan (LM) was shown to contain the ramified, "hairy" region. Using partial acid hydrolysis and Smith degradation followed by NMR spectroscopy of the fragments obtained, some structural features of the hairy region of LM were elucidated. Partial acid hydrolysis of LM afforded the crude polysaccharide fraction LMH that was separated into two polysaccharide fractions: LMH-1 and LMH-2. In addition, the oligosaccharide fraction LMH-3 contained 97% D-apiose was obtained from the supernatant. A further more rigorous acidic hydrolysis of LMH led to the crude polysaccharide fraction LMHR which was separated in to two fractions: LMHR-1 and LMHR-2. Smith degradation of LMH afforded the polysaccharide fragment LMHS differed in low contents of apiose residues. Unfortunately, NMR-spectroscopy failed to provide significant evidence concerning the structure of LMH-1 due to the complexity of the macromolecule. The structure of the 1H/13C-NMR spectroscopy including the correlation 2D NMR spectroscopy. As a result, alpha-1,4-D-galactopyranosyluronan was confirmed to be the main constituent of the LM backbone. In addition, the ramified, "hairy" region of the macromolecule appeared to contain segments consisting of residues of terminal and beta-1,5-linked apiofuranose, terminal and alpha-1,5-linked arabinofuranose, terminal and beta-1,3- and beta-1,4- linked galactopyranose, the terminal and beta-1,4-linked xylopyranose, and beta-1,4-linked 2-mono-O-methyl xylopyranose. Analytical and NMR-spectral data of LMHS confirmed the presence of considerable amounts of the non-oxidized of 1,4-linked D-galactopyranosyl uronic acid residues. Thus, some side chains of the ramified region of lemnan appeared to attach to D-galactopyranosyl uronic acid residues of the backbone.